Organophosphorus Chemistry

Organophosphorus Chemistry Volume 19

A Specialist Periodical Report

Organophosphorus Chemistry Volume 19

A Review of the Literature Published between July 1986 and June 1987 Senior Reporters

8. J. Walker, Department of Chemistry, David Keir Building, The Queen's University of Belfast J. B. Hobbs, The City University, London Reporters

C. W. Allen, University of Vermont, U . S . A . 0 . W. Allen, Sheffield City Polytechnic 0 . Dahl, University of Copenhagen, Denmark R. S . Edmundson, formerly of University of Bradford C . D. Hall, King's College, London J. C. Tebby, Noith Staffordshire Polytechnic, Stoke-on-Trent

SOCIETY OF CHEMISTRY

ISBN 0-85 186- 176-8 ISSN 0306-07 13

Copyright 0 1988 The Royal Society of Chemistry All Rights Reserved N o part of this book may be reproduced or transmitted in any form or by any means - graphic, electronic, including photocopying, recording, raping, or information srorage and retrieval systems - wirhour written permission from The Royal Society of Chemistry

Published by The Royal Society of Chemistry Burlington House, Piccadilly, London W l V OBN Printed in England by Staples Printers Rochester Limited, Love Lane, Rochester, Kent.

Introduction A major event of 1986 was the 10th International Conference on Phosphorus Chemistry held at the University of Bonn in West Germany. The proceedings. which cover a very wide range of biological, inorganic and organic aspects o f the subject, have been published in PhOSPhOrUS Sulfur. 1987. Volume 30. We l o o k forward to the 11th Conference at Tallinn, USSR in 1989. Activity in the areas o f quinquevalent phosphorus acid:; and tervalent phosphorus acids continues at a high level. The use of phosphoramidites, and particularly cyanoethyl phosphoramidites. for the solid-phase synthesis of oligodeoxyribonucleotides is now well established, and there have been extensive studies on the preparation, stability, and effective use of these reagents. However, the use of nucleoside H_-phosphonate intermediates for oligonucleotide synthesis is also gaining ground. and offers certain useful advantages, and very short cycle times f o r automated synthesis have been reported. Oligonucleotide analogues containing triester linkages or methylphosphonate linkages are arousing considerable interest for the potential they offer for binding to target sequences in RNA in order to prevent translation of specific gene products. Much effort is being expended to devise methods for attachment of reporter yr-oups and biospecific affinity ligands to oligonucleotides, largely a s a response to the burgeoning demand for highly Specific diagnostics in modern biotechnology. A concerted attack is being made to pin down the s ~ c u c t u r a lrequirements of the active site of the 'ribozyme', as derived from the intervening sequence in ribosomal RNA in Tetrahvmena. These studies have afforded completely new insights into the functions of RNA, and the number of enzymes found to be dependent upon RNA for their catalytic activity is increasing. Although many reports concerning pn-bonded phosphorus have appeared, interest in this area does seem to be passing its peak. There has also been a significant decline in the number o f publications dealing with hypervalent phosphorus chemistry, but the

Vi

Inrroducrion

structural and mechanistic principles established in this a r e a are now being applied to the chemistry o f a variety of other elements in Groups 14, 15 and 16. One of the more striking examples of this is to be found in a paper by Arduengo dealing with the synthesis, structure, and chemistry of 10-Pn-3 compounds (Pn = N, P , A S , sb). In addition. the debate on the importance of stereoelectronic effects on the mechanism of nucleophilic substitution at tetrahedral phosphorus has intensified with three papers €rom Gorenstein and his CO-WOCkeKS. defending their position and providing new evidence to support the concept. In spite of all the previous work, sLudies o f the mechanism of the Wittig rc?action continue to produce novel results. Perhaps the most significant of these is the report by Vedejs that in some cases (E)-alkene can be the kinetically-favoured product. In combination with studies of the effect on Wittig stereochemistry of varying ylide P-substituents this may provide even greater control of olefin stereochemistry. Maryanoff has shown that Wittig reactions o f equimolar mixtures of ylide and lithium salts can show ’fsalt-free” behaviour at low concentrations and a theoretical study comparing the reactions of phosphorus and sulphur ylides with carbonyl compounds identifies the factors which control the different reaction pathways observed for these ylides. There has been renewed interest in the applications o f arsonium ylides in synthesis. Interesting new chemistry continues to arise from decomposition (thermal O K photochemical) of phosphorus(II1) azides and there have been some developments in using monophosphazenes a s synthetic intermediates. In cyclophosphazene studies. the detection of threecoordinate intermediates in SN1(CB) reactions and the use of 2 - D

31P n.m.r. in unravelling complex mixtures are noteworthy. A wide range of alkyl O K aryl phosphazene polymc3rs are now available from thermolysis of phosphoranamines o r derivatives of alkyl phosphazene systems. Important contributions in the theoretical area include a@ initio MO calculations on phosphines, and the application o f molecular mechanics to phosphorus compounds. Several kinetic studies related to the stereochemistry of nucleophilic substitution have appeared, and similarities between reactions at phosphorus and silicon noted and interpreted using frontier orbitals. 31P N.m.r. spectroscopy has been applied to determine c+nantiomeric selectivity and purity by several groups, and unusually large effects on 31P chemical shifts in two-coordinate P = C

vii

Inrmducrion c o m p o u n d s . o n c h a n g i n g t h e n a t u r e of g r o u p s w h i c h a r e n o t d i r e c t l y bonded t o t h e p h o s p h o r u s d t o m . have b e e n n o t e d .

J.B.

Hobbs and B . J .

Walker

Contents CHAPTER 1

1

Phosphines and Phosphonium Salts By D.W.

Allen

Phosphines 1.1

Preparation 1.1.1 1.1.2

1.1.3 1.1.4

1.1.5 1.2

Nucleophilic Attack at Carbon Nucleophilic Attack at Halogen Nucleophilic Attack at Other Atoms Miscellaneous Reactions

Halogenophosphines 2.1 2.2

3

From Halogenophosphines and Organometallic Reagents From Metallated Phosphines By addition of P-H to Unsaturated Compounds By Reduction Miscellaneous Methods

React ions 1.2.1 1.2.2 1.2.3 1.2.4

2

1

Preparation Reactions

Phosphonium Salts 3.1 3.2

Preparation Reactions

1

1

1 6 7 9 9

9 10 12 13 16 16 19 20 20 24

4

pa-Bonded Phosphorus Compounds

25

5

Phosphirenes, Phospholes, and Phosphorins

34

References

36

CHAPTER 2 1

Pentaco-ordinated and Hexaco-ordinated Compounds By C.D. H a l l Introduction

47

Structure, Bonding, and Ligand Reorganization

47

Acyclic Phosphoranes

49

Ring Containing Phosphoranes

51

Organophosphorus Chemistry

X

4.1 4.2

5

CHAPTER 3

Monocyc 1 ic Phosphoranes Bicycl ic and Tricycl ic Phosphoranes

51 5Y

Hexaco-ordi ndte Phosphorus Compounds

65

References

68

Phosphine Oxides and Related Compounds Bg B , < ' . WaikcJr

1

Introduction

70

2

Preparation of Acyclic Phosphine Oxides

70

3

Preparation of Cyclic Phosphine Oxides

73

4

Structure and Physical Aspects

78

5

Reactions at Phosphorus

.7 8

6

Reactions at the Side-Chain

80

Phosphine Oxide Complexes and Extractants

83

References

85

7

CHAPTER 4

Tervalent Phosphorus Acids Bg' 0 . DakI

1

Introduction

a7

2

Nucleophilic Reactions

87

2.1 2.2 2.3

87

3

Attack on Saturated Carbon Attack on Unsaturated Carbon Attack on Nitrogen, Chalcogen, or Halogen

89 89

Electrophilic Reactions

92

3.1 3.2 3.3

92 98

3.4

Preparation Mechanistic Studies Use for Nucleotide, Sugar Phosphate, or Phosphoprotein Synthesis Miscellaneous

101 104

4

Reactions involving Two-co-ordinate Phosphorus

107

5

Miscellaneous Reactions

111

References

115

xi

Contents CHAPTER 5

Quinquevalent Phosphorus Acids By R . S .

Edmundson

1

Phosphoric Acids and their Derivatives 1.1 Synthesis 1.2 Reactions and Uses

121 121 126

2

Phosphonic and Phosphinic Acids and their Derivatives

140

2.1 2.2

Synthesis Reactions and uses

References

CHAPTER 6 1 2

140

157

178

Nucleotides and Nucleic Acids By J . R . Hobbs Introduction

184

Mononucleotides

184

2.1 2.2

184

Chemical Synthesis Cyclic Nucleotides

197

3

Nucleoside Polyphosphates

201

4

Oligo- and Poly-nucleotides

215

4.1 4.2

237

5

24 0

5.1 5.2

240 24 1 247 252 266

5.3

CHAPTER 7 1 2

215

Other Studies

5.4 5.5 6

Chemical Synthesis Enzymatic Synthesis Affinity Separation Affinity Labelling Post-Synthetic Modification Sequencing and Cleavage Studies Metal Complexes

Analytical Techniques and Physical Methods

271

References

274

Ylides and Related Compounds By B . J . W a l k e r Introduction

288

Methylenephosphoranes

288

2.1 2.2

Preparation and Structure Reactions

288 288

2.2.1 2.2.2 2.2.3

288 297 297

Aldehydes Ketones Miscellaneous Reactions

xii

Organophosphorus Chemistry 3

Reactions of Phosphonate Anions

308

4

Selected Applications in Synthesis

313

4.1 4.2 4.3 4.4

4.5

4.6

Carotenoids, Retinoids and Related Compounds Leukotrienes and Related Compounds Macrolides and Related Compounds Pheromones Prostaglandins Miscellaneous Reactions

References

CHAPTER 8

313 313 316 319 319 319 326

Phosphazenes By C . W .

Allen

1

Introduction

330

2

Acycl ic Phosphazenes

330

3

Cyclophosphazenes

336

4

Cyclophospha(thia)zenes

34 6

5

Miscellaneous Phosphazene-Containing Ring Systems

347

6

Poly(phosphatenes)

348

7

Molecular Structures of Phosphazenes

358

References

360

CHAPTER 9

1

Physical Methods By J . C . Tebby Theoretical Studies 1.1

1.2

2

Based on Molecular Orbital Theory Based on Molecular Mechanics Theory

373 373 376

Nuclear Magnetic Resonance

378

2.1 2.2

Biological Applications and References Chemical Shifts and Shielding Effects

378 379

2.2.1

379 380 381 383 383 383 384

2.2.2 2.2.3 2.2.4

PhosphoSus - 3 1 6pof n compounds 6pof n4 compounds 6p of n5 compounds Selenium - 7 7 and Oxygen - 17 Carbon - 1 3 Hydrogen - 1

2.3

Restricted Rotation and Pseudorotation

384

2.4

Studies of Equilibria, Configuration and Conformation

384

...

XI11

Contents 2.5

Spin-Spin Coup1 ings 2.5.1 2.5.2 2.5.3 2.5.4 2.5.5

2.6

J PSe) and J(PTe) J PP)

J PF) and J(PN) J PC) J(PH)

CIDNP and Nuclear Quadrupole Resonance

387

387 387 387 389 390 390

3

Electron Spin Resonance

391

4

Vibrational and Rotational Spectroscopy

392

4.1

Vibrational Spectroscopy 4.1.1 4.1.2 4.1.3

4.2 5

Rotational Spectroscopy

Electronic Spectroscopy 5.1 5.2 5.3

6

Absorption Spectroscopy Fluorescence Spectroscopy Photoelectron and Fluorescence Spectroscopy

Diffraction 6.1

394 395 395 395 395 396 396

n: n n: n

396 397 399 401

6.1.4 6.2

392 392 394

X-ray Diffraction 6.1.1 6.1.2 6.1.3

7

Group Frequencies and Assignments Bonding and Co-ordination Stereochemistry

392

Compounds Compounds Compo nds and 'n Compounds

Electron Diffraction

401

Dipole Moments, Kerr Effects, Cyclic Voltammetry and Polarography 401 7.1 7.2

Dipole Moments and Kerr Effect Cyclic Voltammetry and Polarography

401 402

8

Mass Spectrometry

402

9

Acidities, Basicities, and Thermochemistry

406

Chromatography

406

10.1 10.2

406 408

10

Gas-Liquid Chromatography Liquid Chromatography 10.2.1 10.2.2

11

High Performance Liquid Chromatography 4 0 8 Thin Layer Chromatography 408

Kinetics

409

References

412

AUTHOR INDEX

422

Abbreviations AI BN CIDNP CMX)

CP

DAD DBN DBU Dcc

DIOP DMF

DMSO

m EDTA

E.H.T. ENU FID g.1.c.-m.s. HMPT

h.p.1.c. i.r. L.F.E.R. MIND0

rn E.1D

PG< 1

MS-nt MS-tet NBS

n.q.r. p.e. PPA SCF

TBDMS TDAP

TFAA Tf23 THF Thf

ThP TIPS t.1.c. TPS-Cl TPS-nt TPS-tet TsOH U.V.

bisazoisobutyronitrile Chemically Induced Dynamic Nuclear Polarization Complete Neglect of Differential Overlap cyc lopentadienyl diethyl azodicarboxylate l15-diazabicyc lo !4.3.0 ]non-5-ene l15-diazabicyclo5 -4.0hndec-5-ene dicyclohexylcarbodi-imide [(2,2-dimethyl-l,3-dioxolan-4,5-diyl)bis-(methylene)1 bis(dipheny1phosphine) dimethylformamide dimethyl sulphoxide 4,4'-dimethoxytrityl ethylenediaminetetra-acetic acid M e n d e d Huckel Treatment N-ethyl-Wnitrosourea Free Induction Decay gas-liquid chromatography-mass spectrmtry hexmthylphosphortriamide

high-performance liquid chromatography infrared Linear Free-Energy Relationship W f i e d Intermediate Neglect of Differential Overlap 4-rronmthoxytrityl Wlecular Orbital mesitylenesulphonyl chloride mesitylenesulphonyl-3-nitro-l,2,4-triazole mesitylenesulphonyltetrazole Wbramsuccinimide nuclear quadrupole resonance photoelectron plyphosphoric acid Self-consistent Field t-butyldimethylsilyl tris(diethy1amino)phosphine

trifluoroacetic acid

trifluoremethanesulphonic anhydrick

tetrahydrofuran 2-tetrahydrofuranyl 2-tetrahydropyranyl tetraisopropyldisiloxanyl thin-layer chromatography tri-isopropylbenzenesulphonylchloride tri-isopropy1benzenesu1phony1-3-nitro-1,2,4-triazo1e tri-isoproply!xnzenesulphonyltetrazole to1uene-p-su1phonic acid ultraviolet

* Abbreviations used in Chapter 6 are detailed in Biochem. .1.,1970,120,449and 1978,171,l

I

Phosphines and Phosphonium Salts BY D. W. ALLEN

1 Phosphines 1.1 P r e p a r a t i o n 1.1.1 From H a l o g e n o p h o s p h i n e s a n d O r g a n o m e t a l l i c R e a g e n t s . -

The

G r i g n a r d p r o c e d u r e h a s been employed i n t h e s y n t h e s i s o f a r a n g e o f p h o s p h i n e s b e a r i n g 1-adamantyl and 1-adamantylmethyl ents.

substitu-

However, i t was n o t p o s s i b l e t o p r e p a r e t r i s - ( 1 - a d a m a n t y 1 ) -

p h o s p h i n e by t h i s r o u t e , pr e s um a bl y due t o t h e e f f e c t s o f s e v e r e

s t e r i c crowding.'

Treatment of t h e inexpensive fermentation

a l c o h o l (S)-(-)-2-methylbutan-l-ol

with phosphorus tribromide i n

pyridine r e a d i l y a f f o r d s t h e corresponding c h i r a l a l k y l halide; t h e r e l a t e d G r i g n a r d r e a g e n t h a s b e e n u s e d i n t h e p r e p a r a t i o n of t h e new c h i r a l p h o s p h i n e s ( 1 ) . 2 An u n u s u a l r e a r r a n g e m e n t o c c u r s i n t h e r e a c t i o n o f t h e G r i g n a r d r e a g e n t d e r i v e d from 2-bromobenzylt r i m e t h y l s i l a n e w i t h bis(dimthy1amino)chlorophosphine w h i c h , i n addition t o t h e expected product ( 2 1 ,

benzylic phosphine ( 3 ) prepared

.

a l s o g i v e s rise t o t h e

The 2 - b r o m o b e n z y l p h o s p h i n e s

(4)

have been

t h e u s e of t h e b e n z y l i c G r i g n a r d r e a g e n t d e r i v e d from

o-bromobenzyl bromide $ O r g a n o l i t hium r e a g e n t s a l s o c o n t i n u e t o b e u s e d i n t h e s y n t h e s i s o f new p h o s p h i n e s .

M e t a l l a t i o n o f ethyl(2-bromopheny1)thioether

w i t h b u t y l l i t h i u m f o l l o w e d by t r e a t m e n t w i t h c h l o r o d i p h e n y l p h o s p h i n e a f f o r d s the p o t e n t i a l l y bidentate ligand (5).5

A similar r o u t e h a s

been employed i n t h e s y n t h e s i s o f t h e p h o s p h i n o c a r b o r a n e s ( 6 1 6 and A very convenient, high y i e l d route t h e p h o s p h i n o s y d n o n e s (7).7

t o t h e p h e n a c y l p h o s p h i n e ( 8 ) is a f f o r d e d by t h e r e a c t i o n o f c h l o r o -

d i p h e n y l p h o s p h i n e w i t h p h e n a c y l l i t h i u m , w h i c h is g e n e r a t e d by t r e a t m e n t o f a c e t o p h e n o n e w i t h 1i t h i u m d i i s o p r o p y l a m i d e . 1 . 1 . 2 P r e p a r a t i o n o f P h o s p h i n e s f r o m Met a l l a t e d P h o s p h i n e s . I n t e r e s t c o n t i n u e s i n t h e p r e p a r a t i o n of complexes of metallop h o s p h i d e r e a g e n t s w h i c h are s t a b i l i s e d i n t h e p r e s e n c e o f c h e l a t i n g d i - or t r i - a m i n e

ligands.

T h i s approach h a s been u s e d i n

t h e case o f t h e l i t t l e s t u d i e d magnesium p h o s p h i d e s by t r e a t m e n t o f

p h e n y l p h o s p h i n e w i t h (n-butyl)(s-buty1)magnesium

1

i n t h e p r e s e n c e of

2

'"'1

Ph,P

Orpmophosphorus Chemistry

0'

HS , i Me

CH2C--- H

- tE'

P I NMe,), 3- n

( 2 )

(1 n:0-2

r

Ph2PC-

CCH,R

\

/

Blbl10

( L ) R = M e , B u t , or Ph

(5)

( 6 ) R = M e S or Et2N

n "Me2

MqN,

Ph,PCH,COPh

PhHP'.

(8)

Ph HPCH,PHPh

(12)

(11)

(10)

'PHPh

(9)

P h P C H2lnP Me P h

Ph,P (CH,),PPh,

.Mg

PMe2

(15)n:2 or 3

J-O JJ7f

/

CH,PAr2

CH2PAr2

(16) A r = m - t o l y l

Aiz P

PAr,

(17)Ar,P= 5 - d i benzophospholyl

or Ph

I : Phosphines and Phnsphonium Salts

3

TMEDA w h i c h r e s u l t s i n s e l e c t i v e m o n o m e t a l l a t i o n t o g i v e t h e complex ( 9 ) , '

a n d a l s o f o r t h e i s o l a t i o n o f c o m p l e x e s of l i t h i u m

E v i d e n c e h a s b e e n p r e s e n t e d for t h e p a r t i c i p a t i o n of an e l e c t r o n - t r a n s f e r mechanism i n t h e r e a c t i o n s d i p h e n y l p h o s p h i d e . lo

of lithium diphenylphosphide with optically-active halides,"

alkyl

a n d a f r e e r a d i c a l c h a i n m e c h a n i s m is i n v o l v e d i n t h e

p h o t o s t i m u l a t e d r e a c t i o n o f a crown e t h e r c o m p l e x of p o t a s s i u m d i p h e n y l p h o s p h i d e w i t h t - b u t y l m e r c u r y c h l o r i d e i n HMPA, w h i c h r e s u l t s i n t h e f o r m a t i o n o f t-butyldiphenylphosphine. l 2 r e l a t i v e r e a c t i v i t y o f 1-adamantyl and p - a n i s y l

The r a d i c a l s towards

t h e d i p h e n y l p h o s p h i d e i o n h a s been s t u d i e d , t h e 1-adamantyl r a d i c a l

.

s h o w i n g much g r e a t e r s e l e c t i v i t y l3

Numerous a p p l i c a t i o n s o f m e t a l l o p h o s p h i d e r e a g e n t s i n t h e

A s is u s u a l , l i t h i o s y n t h e s i s of phosphines have been r e p o r t e d . p h o s p h i d e r e a g e n t s h a v e f o u n d g r e a t e r a p p l i c a t i o n t h a n t h o s e of t h e more r e a c t i v e a l k a l i metals.

W h e r e a s l i t h i u m metal i n THF,

a s s i s t e d by u l t r a s o u n d , c a u s e s c l e a v a g e o f a p h e n y l g r o u p f r o m e a c h o f t h e d i p h e n y l p h o s p h i n o moieties o f t h e d i p h o s p h i n e s

(

10, g

=

1-5),

i r r e s p e c t i v e of t h e length of t h e bridging group and r e l a t i v e q u a n t i t y o f l i t h i u m , 1 4 t h e u s e o f sodium n a p h t h a l e n e , a g a i n w i t h u l t r a s o n i c a s s i s t a n c e , e n a b l e s t h e s e l e c t i v e c l e a v a g e of o n l y o n e p h e n y l g r o u p f r o m t h e d i p h o s p h i n e s ( 1 0 , n_ = 2 - 6 1 ,

thus providing a

r o u t e f o r t h e s y n t h e s i s o f t h e unsymmetrical diphosphines (11).

15

D i f u n c t i o n a l l i t h i o p h o s p h i d e r e a g e n t s h a v e been employed i n t h e s y n t h e s i s o f a w i d e r a n g e o f new s y s t e m s .

Metallation of t h e

d i p h o s p h i n e ( 1 2 ) ( p r e p a r e d i n a t h r e e stage p r o c e d u r e f r o m b i s -

(dich1orophosphino)methane) g i v e s a d i p h o s p h i d e w h i c h o n t r e a t m e n t

with a,w-dihaloalkanes cycl ic diphosphines

(

g i v e s rise t o f i v e - ,

1 3 ) 16.

s i x - a n d s e v e n membered

The 1i t h i u m - i n d u c e d

c l e a v a g e of p h e n y l

g r o u p s f r o m b i s ( diphenylphosphino)methane, n o t e d a b o v e , would s e e m

t o p r o v i d e a more d i r e c t r o u t e t o t h e s e s y s t e m s .

The d i p h o s p h i d e

r e a g e n t h n e r a t e d by l i t h i u m - c l e a v a g e o f 1,3-bis(diphenylphosphino)-

p r o p a n e h a s b e e n e m p l o y e d i n t h e s y n t h e s i s o f m a c r o c y c l e s , __ e.g., ( 1 4 ) , u n d e r h i g h d i l u t i o n c o n d i t i o n s t o minimise polymerformation. l7

D i f u n c t i o n a l l i t h i o p h o s p h i d e r e a g e n t s have a l s o been

u s e d i n t h e s y n t h e s i s of l i n e a r o l i g o p h o s p h i n e l i g a n d s , e.g., ( 1 5 ) . l8

The r e a c t i o n s o f l i t h i u m d i a r y l p h o s p h i d e s w i t h a l k y l

h a l i d e s , t o s y l a t e s and m e s y l a t e s c o n t i n u e t o b e w i d e l y employed i n t h e s y n t h e s i s o f new c h e l a t i n g l i g a n d s .

Among new d i p h o s p h i n e s

p r e p a r e d i n t h i s way a r e t h e t r a n s - s p a n n i n g l i g a n d (16) ( t h e m - t o l y l s u b s t i t u e n t s are s a i d t o improve t h e s o l u b i l i t y o f r e l a t e d

4

Organophosphorus Chemistry

c o m p l e x e s ) , l9 t h e p o l y m e r - b o u n d c h i r a l DIOP s y s t e m ( 1 7 ) ,20 a n d a r a n g e o f c h i r a l d i p h o s p h i n e s d e r i v e d f rom c a r b o h y d r a t e

s y s t e m s , 1-24 3 ,( 1 8 ) 2 1 a n d ( 1 9 ) 2 2 . L i g a n d s o f t h e l a t t e r t y p e are f l e x i b l e a n d c a p a b l e o f c i s o i d or t r a n s o i d c o o r d i n a t i o n t o a

metal.

The f o r m a t i o n o f t h e p h o s p h i n e - s e l e n i u m l i g a n d ( 2 0 ) i n t h e

r e a c t i o n o f l i t h i u m d i m e t h y l p h o s p h i d e w i t h methyl(2-bromopheny1)s e l e n i d e p r o v i d e s a f u r t h e r example of t h e d i s p l a c e m e n t of h a l o g e n a t t a c h e d t o a n aromatic s y s t e m b y p h o s p h i d e r e a g e n t s . 2 5

Both m o n o l i t h i o - and monosodio- d e r i v a t i v e s of p h o s p h i n e an d p r i m a r y

p h o s p h i n e s have been u s e d i n t h e p h o s p h i n y l a t i o n o f h a l o a l k y l pyridines

t o g i v e t h e P H - f u n c t i o n a l mixed-donor

which have been s u b s e q u e n t l y e l a b o r a t e d

ligands (21),

addition t o vinyl

p y r i d i n e s t o g i v e more c o m p l e x p o l y d e n t a t e s y s t e m s .26 The s o d i u m d i p h e n y l p h o s p h i d e - t o s y l a t e or - m e s y l a t e r o u t e h a s b e e n a p p l i e d t o t h e s y n t h e s i s o f c h i r a l phosphines based on carbohydrate

r e s i d u e s , 2 7 t h e c h i r a l d i p h o s p h i n e s ( 2 2 ) which are d e r i v e d from

tartaric a c i d , 2 8 and a range of c h i r a l unsymmetrical diphosphines, e.g., -

( 2 3 ) , i n w h i c h t h e d i c y c l o h e x y l p h o s p h i n o m o i e t y is f o r m e d

by c a t a l y t i c h y d r o g e n a t i o n o f t h e more e a s i l y i n t r o d u c e d d i p h e n y l A p r o c e d u r e h a s been d e v e l o p e d for t h e

phosphino

s y n t h e s i s of t h e c h i r a l phosphino-mercaptan l i g a n d ( 2 4 ) from t h e r e a c t i o n of e t h y l e n e s u l p h i d e a n d s o d i u m methyl(pheny1)phosphide.

31

P o t a s s i u m d i a r y l p h o s p h i d e r e a g e n t s h a v e been employed i n t h e

s y n t h e s i s of t h e t e t r a p h o s p h i n e ( 2 5 ) ,32 t h e heterocycloalkylmethylp h o s p h i n e ( 2 6 ) 3 3 a n d t h e DIOP a n a l o g u e Magnesium o r g a n o p h o s p h i d e r e a g e n t s a re p r o b a b l y i n v o l v e d a s intermediates i n t h e electroreduction of chlorophosphines at a s a c r i f i c i a l magnesium a n o d e i n t h e p r e s e n c e o f a l k y l h a l i d e s , which r e s u l t s i n t h e f o r m a t i o n of moderate t o good y i e l d s o f 35 t e r t i a r y phosphines

.

The use o f m e t a l l o p o l y p h o s p h i d e r e a g e n t s i n t h e s y n t h e s i s o f c y c l i c a n d a c y c l i c p o l y p h o s p h i n e s c o n t i n u e s , a n d s y s t e m s of every-increasing

c o m p l e x i t y a r e b e i n g d e v i s e d . 36-47

p r o g r e s s i n t h i s area h a s b e e n r e v i e w e d .

48

Recent

I n c r e a s i n g i n t e r e s t is b e i n g shown i n t h e u s e of r e a g e n t s

o b t a i n e d by m e t a l l a t i o n o f a n a t o m or g r o u p a d j a c e n t t o p h o s p h o r u s . A much i m p r o v e d r o u t e t o t h e m o n o x i d e ( 2 8 ) of b i s ( d i p h e n y 1 -

p h o s p h i n o ) m e t h a n e is o f f e r e d by m e t a l l a t i o n a t t h e m e t h y l g r o u p o f t h e commercially a v a i l a b l e methyldiphenylphosphine oxide, followed b y t r e a t m e n t w i t h c h l o r o d i p h e n y l p h o s p h i n e . 4 9 The r e a c t i o n s of

bis(dipheny1phosphino)methane

w i t h p a l l a d i u m - or p l a t i n u m -

I : Phosphines and Phosphonium Salts CH,PPh2

5

FHZPPh2

c H 3 0 ~ ~ . . 0 ~ 0 c H 3O

CH3O

P ScMc M q

'OCH,

I

I

OCH,

OCH,

(211n= 1 or 2 R = HI P r i ,

I201

( 19 1

B u t , o r Ph

PhMePCH,CH,SH Ph,P'

R

( 2 2 ) R ' PhCH2 ,CHO COR OT CH3

,

PPh;,

( 2 3 ) RzC02R or CONHPh

(26)

Li

II

PhzPCH2PPh,

Fe

(29)

(28)

O : P R 2 g

( 2 7 1 A r : m-to

&

0

(31) X

(24)

C I or Br

ONa (33)

(32)

R=NR;! , a l k y l ,or Ph

Rp(CH, I3P(M

1(CH l2PHMe

(31)

L0,L<

McN -0

i

Me

CH~CH,PR'R~ PhzP ( 3 6 ) (35) R = H or Ph 1

R2=Ph

6

Organophosphorus Chemistry bis(acety1acetonate) unexpectedly give

c o m p l e x e s of t h e b i s -

(dipheny1phosphino)methanide a n i o n .50 V a r i o u s a l k a l i metal b i s a n d t r i s - (diorganophosphino)methanide r e a g e n t s h a v e b e e n u s e d i n t h e s y n t h e s i s o f a wide r a n g e of complexes o f

l a n t h a n u m , 5 3 g e r m a n i u m , t i n a n d l e a d , 5 4 - 5 9 a n d a l s o m e r c u r y .60 The phosphino-Grignard r e a g e n t ( 2 9 ) h a s been s i m i l a r l y used t o p r e p a r e

intramolecularly-coordinated p h o s p h i n e - o r g a n o t i n c o m p l e x e s .6

Metallation of ferrocenyldiphenylphasphine

with butyllithium

r e s u l t s i n t h e f o r m a t i o n o f a m i x t u r e of isomeric d i l i t h i a t e d d e r i v a t i v e s ( 3 0 ) which h a v e been u s e d t o p r e p a r e v a r i o u s p o l y p h o s p h i n o f e r r o c e n e s a n d a l s o f e r r o c e n o p h a n e s b a s e d on b r i d g i n g p h o s p h o r u s o r s u l p h u r atoms .62

Treatment of the g-halophenyl-

p h o s p h i n i t e esters ( 3 1 ) with sodium i n dioxan r e s u l t s i n a r e a r r a n g e m e n t t o form t h e g - p h o s p h i n o p h e n o l a t e ( 3 2 ) which w i t h c h l o r o t r i m e t h y l s i l a n e y i e l d s t h e 2-t r i m e t h y l s i l o x y p h o s p h i n e s

( 33 )!

1 . 1 . 3 P r e p a r a t i o n o f P h o s p h i n e s by A d d i t i o n o f P-H t o U n s a t u r a t e d Compounds.-

A procedure h a s been r e p o r t e d for t h e a d d i t i o n of

primary and secondary phosphines t o t e r m i n a l a l k e n e s i n t h e absence of i n i t i a t o r s or c a t a l y s t . 6 4

The r a d i c a l - i n d u c e d

addition of

s e c o n d a r y p h o s p h i n e s t o e s t e r s o f v i n y l - or a l l y l m e t h y l - p h o s p h i n i c

a c i d is a key s t e p i n t h e s y n t h e s i s o f t h e p o l y d e n t a t e phosp h i n e s ( 3 4 ) which are t h e n a b l e t o u n d e r g o f u r t h e r a d d i t i o n

r e a c t i o n s t o g i v e o t h e r , more c o m p l e x , h y b r i d d o n o r l i g a n d ~ . The ~ ~ p h o s p h i n o a l k y l s i l o x a n e s ( 3 5 ) have been p r e p a r e d by a d d i t i o n of primary and secondary phosphines t o a v i n y l s i l o x a n e p r e c u r s o r .

(361, i s

A r a n g e o f new p o l y d e n t a t e p h o s p h i n e l i g a n d s , e.g.,

accessible

via

t h e base-catalysed

66

a d d i t i o n of primary and secondary

p h o s p h i n e s t o 1 ,1-bis(dipheny1phosphino)ethene . 6 7

Base-catalysed

a d d i t i o n o f d i p h e n y l p h o s p h i n e t o a c e t y l e n e i n t h e p r e s e n c e of a

phase-transfer c a t a l y s t has given very high y i e l d s of 1,2-bis(dip h e n y l p h o s p h i n o ) e t h a n e . 68

Addit i o n of s e c o n d a r y p h o s p h i n e s t o

u n s a t u r a t e d d i c a r b o n y l compounds p r o v i d e s a r o u t e t o carbofunctional phosphines.

Thus, e.g.,

addition of diphenylphosphine

t o maleic a n h y d r i d e , f o l l o w e d by h y d r o l y s i s o f t h e i n t e r m e d i a t e a d d u c t , h a s g i v e n t h e p h o s p h i n o d i c a r b o x y l i c a c i d ( 3 7 ) . 6 9 The a d d i t i o n o f p h e n y l p h o s p h i n e t o t h e 6-diethylaminoethylcyclopentenyl ketone (38) r e s u l t s i n t h e b i c y c l i c system (39).70

V a r i o u s isomeric

h y d r o x y p h o s p h o l a n e o x i d e s (40) a r e f o r m e d i n t h e a c i d - c a t a l y s e d

r e a c t i o n of p h e n y l p h o s p h i n e w i t h d i b e n z o y l e t h a n e . 7 1

The

(hydroxypolyfluoroalky1)phosphines ( 4 1 ) a r e f o r m e d i n t h e a d d i t i o n o f p h o s p h i n e t o v a r i o u s p o l y f l u o r o a l d e h y d e s . 72 A d d i t i o n t o t h e

I : Phosphines und Phosphoniurii Salts

7

CZN bond of p e r f l u o r o a l k y l n i t r i l e s h a s a l s o r e c e i v e d s t u d y .

Whereas t h e a d d i t i o n of d i p h e n y l p h o s p h i n e is r e l a t i v e l y s t r a i g h t f o r w a r d , g i v i n g t h e iminophosphines ( 4 2 ) as t h e p r i m a r y p r o d u c t , 73 t h a t o f p h e n y l p h o s p h i n e is much more c o m p l e x , r e s u l t i n g i n a w i d e range of products.74

T h e r e have a l s o been s e v e r a l r e p o r t s o f t h e

a d d i t i o n o f s e c o n d a r y p h o s p h i n e s t o a l k y l i s o t h i o c y a n a t e s , which have given a range of c h i r a l phosphines, e.g., 1.1.4

(43).75-77

P r e p a r a t i o n o f P h o s p h i n e s by R e d u c t i o n . - T r i c h l o r o s i l a n e

r e m a i n s t h e m o s t w i d e l y u s e d r e a g e n t f o r t h e r e d u c t i o n of p h o s p h i n e o x i d e s , h a v i n g b e e n e m p l o y e d i n t h e p a s t y e a r i n t h e p r e p a r a t i o n of 80 t h e b i d e n t a t e d i p h o s p h i n e l i g a n d s ( 4 4 ) , 7 8 ( 4 5 ) , 7 9 and ( 4 6 ) . I n c o m b i n a t i o n w i t h p y r i d i n e , it h a s also been u s e d f o r t h e r e d u c t i o n o f t h e benzo-7-phosphanorbornene

s y s t e m ( 4 7 ) which

p r o c e e d s w i t h r e t e n t i o n of c o n f i g u r a t i o n a t phosphorus t o g i v e t h e c o r r e s p o n d i n g b i c y c l i c p h o s p h i n e s , which are found t o have markedly d e s h i e l d e d 3 1 P n u c l e i i . 8 1

R e d u c t i o n o f t h e d i m e r ( 4 8 ) of

2-phenylisophosphindoline o x i d e w i t h t h e trichlorosilane-pyridine r e a g e n t p r o c e e d s w i t h c l e a v a g e of a carbon-carbon

s i n g l e bond t o

f o r m t h e d i p h o s p h i n e ( 4 9 ) or t h e r e l a t e d m o n o p h o s p h i n e m o n o x i d e ,

d e p e n d i n g on c o n d i t i o n s . 8 2

P h e n y l s i l a n e h a s been u s e d f o r t h e

s y n t h e s i s o f t h e d i p h o s p h i n e s (50) f r o m t h e r e l a t e d o x i d e s w h i c h

are o b t a i n e d from t h e r e a c t i o n o f t h e a p p r o p r i a t e d i f l u o r o b e n z e n e The 2 -

w i t h t h e s o d i u m s a l t o f d i p h e n y l p h o s p h i n e o x i d e i n DMF.83

p h o s p h a a d a m a n t a n e ( 5 1 ) h a s b e e n p r e p a r e d by r e d u c t i o n o f t h e corresponding phosphine o x i d e with l i t h i u m aluminium hydride.

84

T h i s r e a g e n t h a s a l s o b e e n u s e d f o r t h e r e d u c t i o n of t h e D i e l s A l d e r a d d u c t of d i e t h y l v i n y l p h o s p h o n a t e w i t h 1 , 3 - d i p h e n y l i s o benzofuran t o form t h e isomeric primary phosphines (521, which on f l a s h vacuum p y r o l y s i s u n d e r g o r e t r o - D i e l s A l d e r p r o c e s s e s t o f o r m t h e e l u s i v e vinylphosphine (53).

T h i s compound i s r e p o r t e d t o b e

s u r p r i s i n g l y s t a b l e , w i t h a h a l f - l i f e of e i g h t d a y s i n a n e u t r a l solvent. noted.85

N o t a u t o m e r i s m i n v o l v i n g t h e p h o s p h a - a l k e n e ( 5 4 ) was Conversion of phosphine o x i d e s and s u l p h i d e s , and a l s o

d i c h l o r o p h o s p h o r a n e s , i n t o t e r t i a r y p h o s p h i n e s can b e a c h i e v e d by h e a t i n g w i t h w h i t e m i n e r a l o i l i n t h e p r e s e n c e of a c t i v a t e d c a r b o n . 86 P r o c e d u r e s f o r t h e r e d u c t i o n o f p h o s p h i n e s u l p h i d e s u s i n g i r o n powder8'

( i n t h e f o r m a t i o n o f 1,2-bis(dirnethylphosphino)-

e t h a n e ) , and a l s o t r i e t h y l p h o s p h i t e , 8 8 have been r e p o r t e d .

Organophosphorus Chemistry

8

HOOC CHCH2COOH

I

Ph

PPh,

(37)

P

h

G

/

Ph

“o

(38)

o Ph H

(39)

P (CH ROH l 3 (L1)R=CF3,C,F, or (CF21,,H

(40)

- - dPP

Ph2P S‘

(43)

a+ R

Ph*rCH2CH2CH2r 4 Ph I

I

I

I

Ar

Ar

‘p4 0

( 4 6 ) A r = o - MeOC6H,

CHj=CHPH,

(521

O@

P’h

( 481

(531

CH,CH =PH

(54)

I: Phosphines and Phosphonium Salts

9

1.1.5 M i s c e l l a n e o u s Methods of P r e p a r i n g P h o s p h i n e s . - V a r i o u s

dialkyl(1-adamanty1)phosphines

of 1-adamantylphosphine

have been p r e p a r e d by a l k y l a t i o n

A s t e r e o s e l e c t i v e m o n o a l k y l a t i o n of

p h e n y l p h o s p h i n e c o o r d i n a t e d t o a metal h e l d i n a c h i r a l e n v i r o n ment h a s b e e n a c h i e v e d .

Phase-transfer

c a t a l y s i s h a s been

employed i n t h e development o f a p r o c e d u r e f o r t h e a l k y l a t i o n o f diphenylphosphine i n a t w o phase system.91 A r o u t e t o s u b s t i t u t e d e.g., aryldiphenylphosphines bearing a v a r i e t y of s u b s t i t u e n t s , COR, o r CN, i s p r o v i d e d by t h e r e a c t i o n s of t r i m e t h y l s i l y l or t r i m e t h y l s t annyl-diphenylphosphine w i t h t h e a p p r o p r i a t e

CO,Me,

s u b s t i t u t e d a r y l h a l i d e i n b e n z e n e i n t h e p r e s e n c e o f t h e complex (Ph,P),PdCl, as c a t a l y s t . Thus, e . g . , t h e r e a c t i o n of methyl o - i o d o b e n z o a t e g i v e s t h e p h o s p h i n e ( 5 5 1 , a n d t h a t of p - c h l o r o i o d o b e n z e n e g i v e s E-chlorophenyldiphenylphosphine.

Unfortunately, the

r e a c t i o n c o n d i t i o n s are n o t c o m p a t i b l e w i t h t h e p r e s e n c e o f s u b s t i t u e n t s s u c h as NO,,

CHO, NH, o r OH.92

The t h e r m a l d i s p r o -

p o r t i o n a t i o n o f d i a l k y l p h o s p h i n e o x i d e s promoted by t e t r a c h l o r o m e t h a n e a f f o r d s a c o n v e n i e n t s y n t h e s i s of d i a l k y l p h o s p h i n e s . 93

F u r t h e r examples of t h e aminomethylation of secondary phosphines

have appeared, providing routes t o heterocyclic systems, e.g., ( 5 6 ) , 9 4 and t h e c h i r a l diphosph.ines ( 5 7 ) .95

The c a r b o x y e t h y l -

58), e a s i l y a c c e s s i b l e t h e a l k a l i n e h y d r o l y s i s of t h e r e l a t e d e t h y l ester, h a s found a p p l i c a t i o n i n W i t t i g

phosphine

(

procedures, r e a d i l y forming t h e precursor quaternary salts. In Wittig r e a c t i o n s , t h e c a r b o x y l i c a c i d group not o n l y promotes an increase i n g-stereoselect i v i t y , but a l s o f a c i l i t a t e s t h e

r e m o v a l of t h e c o r r e s p o n d i n g p h o s p h i n e o x i d e . 96

An i m p r o v e d r o u t e

f o r t h e s u l p h o n a t i o n of t r i p h e n y l p h o s p h i n e h a s been d e s c r i b e d .

97

The h e t e r o c y c l i c s y s t e m (59) is f o r m e d i n t h e r e a c t i o n s o f Ox i d a t i v e

b i s p h o s p h i n o a c e t y l e n e s w i t h N , N' - d i m e t h y l t h i o u r e a .

a d d i t i o n o f w h i t e p h o s p h o r u s t o a bis(dialky1phosphido)zirconocene

c o m p l e x h a s r e s u l t e d i n t h e c o m p l e x (60) w h i c h c o n t a i n s a n u n u s u a l 99 hexaphosphine l i g a n d .

1.2 R e a c t i o n s o f P h o s p h i n e s 1.2.1 N u c l e o p h i l i c A t t a c k a t C a r b o n . K i n e t i c d a t a have been p r e s e n t e d w h i c h r e v e a l t h a t w-haloalkyldiphenylphosphines (61) undergo a n c h i m e r i c a l l y - a s s i s t e d i n t r a m o l e c u l a r c y c l isat ion t o form t h e c y c l i c s a l t s (62) w i t h ' r i n g - s i z e p r e f e r e n c e i n t h e o r d e r 5 > 6 > 3 > 4. Comparison w i t h t h e r e l a t e d c y c l i s a t i o n r e a c t i o n s o f w-haloalkylphenylsulphides i n d i c a t e t h a t t h e p h e n y l t h i o - a n d d i p h e n y 1p h o s p h i n o - g r o u p s h a v e si m i 1ar i n t ram l e c u l ar

10

Organophosphorus Chemistry

n u c l e o p h i l i c i t ies. loo

The r e a c t i o n o f t r i s - p - a n i s y l p h o s p h i o e

with

n e o p e n t y l i o d i d e a t 15OOC i n t h e a b s e n c e o f a s o l v e n t s u r p r i s i n g l y

l e a d s t o t h e f o r m a t i o n o f e i g h t phosphonium s a l t s ( 6 3 ) as a r e s u l t o f n u c l e o p h i l i c a t t a c k by u n r e a c t e d p h o s p h i n e o n t h e p-methoxy substituents present in the initially-formed triarylneopentylphosphonium s a l t . lo'

The h y d r o x y a l k y l p h o s p h o n i u m c a t i o n s ( 6 4 )

have been c h a r a c t e r i s e d as i n i t i a l p r o d u c t s i n t h e r e a c t i o n s of

tris(2,6-dimethoxyphenyl)phosphine

w i t h a r a n g e of t e r m i n a l

e p o x i d e s i n e t h a n o l a t room t e m p e r a t u r e . the presence

On h e a t i n g i n e t h a n o l i n

o f e t h o x i d e i o n , t h e above c a t i o n s undergo

c o n v e r s i o n s n o t i n v o l v i n g P-C

cleavage t o give a v a r i e t y of

p r o d u c t s , d e p e n d i n g on t h e s t r u c t u r e o f t h e o r i g i n a l e p o x i d e . l o 2 N u c l e o p h i l i c a t t a c k b y t r i p h e n y l p h o s p h i n e a t t h e B-carbon o f a,B-unsaturated

c a r b o n y l compounds l e a d s t o t h e f o r m a t i o n of

b e t a i n e s which can b e t r a p p e d i n t h e p r e s e n c e o f a s i l y l a t i n g a g e n t t o g i v e t h e r e l a t e d phosphonium s a l t s ,

%.,

(651, t h e

W i t t i g r e a c t i o n s of w h i c h e n a b l e 8 - f u n c t i o n a l i s a t i o n o f e n o n e s .

103

T r i p h e n y l p h o s p h i n e h a s b e e n shown t o i n i t i a t e t h e p o l y m e r i s a t i o n o f m a l e i m i d e s a n d o f maleic a n h y d r i d e

via

i n i t i a l a t t a c k at carbon

t o form z w i t t e r i o n i c e n t i t i e s ( 6 6 ) which u n d e r g o a n i o n i c p o l y m e r i -

s a t i o n i n DMF a t 60°C.104

The z w i t t e r i o n i c s y s t e m ( 6 7 ) i s f o r m e d

i n t h e react i o n o f t r i b u t y l p h o s p h i n e w i t h v i n y l a c e t y l e n e . l o 5 R a d i c a l c a t i o n s f o r m e d f r o m p o l y n u c l e a r aromatic h y d r o c a r b o n s by s i n g l e e l e c t r o n t r a n s f e r p r o c e s s e s c a n b e t r a p p e d by t r i p h e n y l p h o s p h i n e . lo6 R e v e r s i b l e pseudo f i r s t o r d e r k i n e t i c s have been observed i n t h e reactions of triethylphosphine and diethylphenylp h osphine w i t h c a r b o n d i s u l p h i d e , which g i v e rise t o t h e z w i t t e r i o n i c a d d u c t s ( 6 8 ) . l o 7 N u c l e o p h i l i c a t t a c k by t r i m e t h y l phosphine at t h e thiocarbonyl group o f coordinated x a n t h a t e s has

also been r e p o r t e d . 1.2.2 N u c l e o p h i l i c A t t a c k a t H a l o g e n . -

Tris(dimethylamin0)-

phosphine h a s been u s e d t o g e n e r a t e t h e d i c h l o r o m e t h y l e n e y l i d e ( 6 9 ) f r o m trichloromethyltriphenylphosphonium c h l o r i d e , w h i c h i s ,

o f c o u r s e , e a s i l y a c c e s s i b l e from t h e r e a c t i o n o f t r i p h e n y l p h o s p h i n e w i t h t e t r a c h l o r o m e t h a n e . l o g The s a l t ( 70), i n v o l v i n g a r e s o n a n c e - s t a b i l i s e d c a t i o n , is formed i n t h e r e a c t i o n o f

dimethylaminomethyldi(t-buty1)phosphine w i t h t e t r a c h l o r o m e t h a n e a t l o w t e m p e r a t u r e . 'lo The n a t u r e o f t h e p r o d u c t i s o l a t e d f r o m t h e r e a c t i o n of t r i p h e n y l p h o s p h i n e w i t h i o d i n e is d e p e n d e n t on t h e nature of solvent.

When t o l u e n e is u s e d , t h e s a l t [ P h , P I l I ,

is

i s o l a t e d i n l o w y i e l d , w h e r e a s w i t h d i c h l o r o m e t h a n e , t h e much more

I : Phosphinrs and Phosphonium Salts

II R’

COONa I ,CH2PPhz RCHN \ CH,PPh,

R’ 1

(561 R = H , E t , Pr’or Bu

(55)

2

(571

R = P h , a l k y l or CH,CO,E t

R

RP ,

(58)

Ph,P(CH,

S-C,

P-P’

I

P-PR,

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+n

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Ap-YMeR,P -’ I

Cp Zr-P,

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[ 62)

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1

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Ph, P=CC I “S

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( 69)

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S R,’P

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(73)

R’= But

=S

RZ: Mc,Pr, or P r ‘

( Me3Si

N PR

l7L) R : allyl, bcnzyl

or Ph

Mc,Si N=PR,Br (751

12

Organophosphorus Chemistry complex s a l t ( 7 1 ) is i s o l a t e d . 111

The react i o n b e t w e e n t r i p h e n y l phosph i n e and t e traiodome t hane h a s been u s e d f o r t h e i n - s i t u g e n e r a t i o n of t h e d i - i o d o m e t h y l e n e y l i d e ( 7 2 ) w h i c h i n t h e

p r e s e n c e of a l d e h y d e s l e a d s t o t h e f o r m a t i o n o f d i - i o d o a l k e n e s . '12 A d v a n t a g e s a r e c l a i m e d f o r t h e u s e o f 1,2-bis(diphenylphosphino) e t h a n e i n c o m b i n a t i o n w i t h bromine o r i o d i n e f o r t h e s y n t h e s i s o f a l k y l h a l i d e s from a l c o h o l s . between t h e d i p h o s p h i n e

,

Having c a r r i e d o u t t h e r e a c t i o n

halogen, and a l c o h o l i n dichloromethane

a s s o l v e n t , t h e u n w a n t e d p h o s p h i n e o x i d e i s p r e c i p i t a t e d by

a d d i t i o n of a p e n t a n e - e t h e r m i x t u r e , t h e d e s i r e d a l k y l h a l i d e b e i n g e a s i l y r e c o v e r e d from t h e s u p e r n a t a n t l i q u i d . l 1 3 n.m.r.

A

31p

s t u d y of t h e i n t r o d u c t i o n o f i o d i n e i n t o c a r b o h y d r a t e s

u s i n g t h e triphenylphosphine-iodine-imidazole s y s t e m i s c o n s i s t e n t w i t h t h e p r e v i o u s l y a s s u m e d m e c h a n i s m . '14

The m e c h a n i s t i c d e t a i l s

of t h e f o r m a t i o n o f 1 , 4 - o x a t h i a n e s by c y c l o d e h y d r a t i o n r e a c t i o n s p r o m o t e d by t h e t r i p h e n y l p h o s p h i n e - t e t r a c h l o r o m t h a n e c o m b i n a t i o n h a v e been i n v e s t i g a t e d u s i n g s p e c i f i c d e u t e r i u m l a b e l 1i n g i n c o m b i n a t i o n w i t h 'H a n d

13C

n.m.r.

studies.'15

Polymer-bound

triarylphosphine-halogen r e a g e n t s h a v e b e e n u s e d f o r t h e e s t e r i f i c a t i o n o f c a r b o x y l i c a c i d s u n d e r m i l d c o n d i t i o n s . '16 The s t a b l e t h i o p h o s p h o r y l a t e d t h i o k e t e n e s ( 7 3 ) have been i s o l a t e d from t h e r e a c t i o n s of alkyldi(t-buty1)phosphines

a n d c a r b o n d i s u l p h i d e . '17

with tetrachloromethane

Treatment of t h e b i s ( t r i m e t h y l s i l y 1 ) -

aminophosphines ( 7 4 ) w i t h bromine r e s u l t s i n t h e f o r m a t i o n o f t h e bromophosphazenes

(

.

7 5 ) l1

1.2.3 N u c l e o p h i l i c A t t a c k a t O t h e r Atoms.-

A s a consequence o f its

g r e a t e r n u c l e o p h i l i c i t y , a n d t h e a q u e o u s s o l u b i l i t y of i t s o x i d e , triethylphosphine o f f e r s s i g n i f i c a n t advantages over tr ibutylp h o s p h i n e a n d t r i p h e n y l p h o s p h i n e a s a c o m p o n e n t of some of t h e p h osphine- based combined r e a g e n t s which ha ve been d e v e l o p e d i n recent years. Applications i n peptide chemistry, i n reactions i n v o l v i n g t h e c l e a v a g e o f d i s u l p h i d e s , a n d i n t h e h y d r o l y s i s of The t r i b u t y l p h o s p h i n e -

o x i m e s h a v e now b e e n d e s c r i b e d . '19

d i p h e n y l d i s u l p h i d e c o m b i n a t i o n h a s b e e n u s e d as a " s e l f - d r y i n g " agent capable of reducing ketoximes and secondary a l i p h a t i c n i t r o compounds t o t h e c o r r e s p o n d i n g i m i n e s u n d e r s t r i c t l y a n h y d r o u s c o n d i t i o n s a t room t e m p e r a t u r e . F u l l d e t a i l s o f t h i s work h a v e now a p p e a r e d . 120 T r iphenylphosphine-dialkyl a z o d i c a r b o x y l a t e

c o m b i n a t i o n s h a v e b e e n u s e d i n t h e s y n t h e s i s o f g l y c o s y l esters.

12 1

Q u i n ' s group h a s explored t h e o x i d a t i o n r e a c t i o n s of t h e b i c y c l i c

1 : Phosphines and Phosphonium Salts

13

p h o s p h i n e s ( 7 6 1 , w h i c h a r e a c c e s s i b l e f r o m t h e r e a c t i o n s of d i l i t h i u m cyclooctatetraenide with dichlorophosphines.

When t h e

e x o c y c l i c s u b s t i t u e n t a t p h o s p h o r u s i s s t e r i c a l l y c r o w d e d , as i n t h e case o f ( 7 6 ;

R = 2,4,6-BuL3C6H2),t h e r e a c t i o n with t - b u t y l -

h y d r o p e r o x i d e i n c h l o r o f o r m a t room t e m p e r a t u r e g i v e s t h e r e l a t e d b i c y c l i c p h o s p h i n e o x i d e (77), w h i c h s l o w l y d e c o m p o s e s i n s o l u t i o n t o g i v e p r o d u c t s d e r i v e d f r o m t h e pT-bonded i n t e r m e d i a t e [R-P=Ol e.g.,

.1 2 2

However, f o r less b u l k y s u b s t i t u e n t s a t p h o s p h o r u s

,

But o r P h , t h e r e l a t e d o x i d a t i o n r e a c t i o n s c o n d u c t e d a t

-15OC p r o c e e d

via

a rearrangement p r o c e s s t o g i v e t h e phosphonin

o x i d e s ( 7 8 1 , h a v i n g a n e n d o c y c l i c t r a n s - d o u b l e bond as p r e d i c t e d by o r b i t a l symmetry c o n s i d e r a t i o n s .

A t room t e m p e r a t u r e s , t h e s e

undergo f u r t h e r rearrangement t o form t h e dihydrophosphindole o x i d e s ( 7 9 1 , w h i c h are a l s o o b t a i n e d o n o x i d a t i o n of t h e b i c y c l i c s y s t e m s ( 7 6 ) w i t h hydrogen p e r o x i d e i n methanol at 0°C. c o n t r a s t , o x i d a t i o n of ( 7 6 ;

In

R = BuL o r P h ) w i t h o x y g e n l e a d s t o

o t h e r p r o d u c t s , i n c l u d i n g (80). 123 The m i x e d p h o s p h i n y l - t h i o p h o s p h i n y l m e t h a n e s (81) h a v e b e e n p r e p a r e d b y t h e c a r e f u l

o x i d a t i o n o f p r e c u r s o r phosphino-thiophosphinylmethanes h y d r o g e n p e r o x i d e . 124

with

A k i n e t i c s t u d y o f t h e o x i d a t i o n of

p h o s p h i n e s c a t a l y s e d b y p l a t i n u m ( 0 )c o m p l e x e s d o e s n o t s u p p o r t t h e v i e w t h a t t r a c e s o f p r o t i c s u b s t a n c e s may p l a y a k e y r o l e i n t h e c a t a l y t i c co-oxygenation r e a c t i o n .

I t is shown t h a t m a r k e d

r e d u c t i o n s i n r a t e o c c u r when p h o s p h i n e s a r e o x i d i s e d i n t h e p r e s e n c e o f m o i s t u r e , a l c o h o l s , or s t r o n g e r p r o t i c a c i d s .

I t has

b e e n s u g g e s t e d t h a t a g e n e r a l mechanism, i n v o l v i n g i n t r a m o l e c u l a r n u c l e o p h i l i c a t t a c k by c o o r d i n a t e d “ p e r o x o ” o n two c o o r d i n a t e d p h o s p h i n e m o l e c u l e s , f o l l o w e d by r e d u c t i v e e l i m i n a t i o n f r o m t h e i n t e r m e d i a t e m e t a l l a c y c l e , may a p p l y t o many t r a n s i t i o n metal125

catalysed oxidation processes.

1.2.4 M i s c e l l a n e o u s React i o n s of P h o s p h i n e s

.-

Reviews have appeared

o f t h e c h e m i s t r y o f t h e 5,10-dihydrophenophosphazine (82)

system

t h e fluxional p r o p e r t i e s of n’-cyclopentadienyl-

p h o s p h i n e s , 127 a n d t h e s t e r e o c h e m i s t r y o f m a c r o c y c l i c p o l y A procedure f o r t h e

p h o s p h i n e s a n d t h e i r r e l a t e d c o m p l e x e s . 128

i n -situ

r e s o l u t i o n o f c h i r a l d i p h o s p h i n e s h a s been d e v e l o p e d which

i n v o l v e s t h e u s e o f a c h i r a l i r i d i u m complex which s e l e c t i v e l y

reacts w i t h o n e e n a n t i o m e r o f t h e d i p h o s p h i n e , l e a v i n g t h e o t h e r e n a n t iomer i n s o l u t i o n f o r s u b s e q u e n t c o n v e r s i o n t o a c a t a l y t i c a l l y The c o m p l e x e s (83) o f a c t i v e species as required.12’

Organophosphorus Chemistry

14 1,l-bis(dipheny1phosphino)ethane

h a v e b e e n p r e p a r e d by t h e

r e a c t i o n s o f r e l a t e d c o m p l e x e s of t h e b i s ( d i p h e n y l p h o s p h i n 0 ) methanide i o n w i t h c h l o r o m e t h y l m e t h y l e t h e r a t 8 0 ° C , and f u r t h e r e x a m p l e s of M i c h a e l a d d i t i o n s t o t h e v i n y l g r o u p o f t h e l i g a n d have been d e s c r i b e d . 130

The e s t e r ( 8 4 ) h a s b e e n p r e p a r e d f r o m

m-diphenylphosphinobenzoic a c i d , t h e d i s p o s i t i o n o f t h e p h o s p h i n o group promoting t h e rhodium-catalysed i n t r a m o l e c u l a r hydro-

f o r m y l a t i o n o f t h e e n d o c y c l i c d o u b l e bond i n a s p e c i f i c manner.131 F u r t h e r examples have been d e s c r i b e d of t h e c l e a v a g e o f phosphorus-carbon bonds of t e r t i a r y phosphines i n t h e presence of t r a n s i t i o n metals. 132-137

Of s p e c i a l n o t e is t h e p r e f e r e n t i a l

cleavage of the phosphorus-acetylenic

c a r b o n bond o f a l k y n y l d i -

p h e n y l p h o s p h i n e s , 136 a n d t h e c l e a v a g e o f a d i p h e n y l p h o s p h i n o g r o u p i n p l a t i n u m c o m p l e x e s o f bis(dipheny1phosphino)methane

w i t h s o d i u m h y d r o x i d e i n l i q u i d ammonia as s o l v e n t .

on treatment Coord i n a -

t i o n o f t h e p h o s p h o r u s a t o m o f t h e diphenylphosphinosilylmethane

( 8 5 ) t o a ruthenium acceptor suppresses t h e usual proton-induced

c a r b o n - s i l i c o n c l e a v a g e r e a c t i o n s undergone by t h i s m o l e c u l e , e n a b l i n g f u r t h e r e l a b o r a t i o n a t s i l i c o n t o b e c a r r i e d o u t . 138

Mystery s u r r o u n d s t h e mechanism o f t h e r e a r r a n g e m e n t o f t h e

p h o s p h i n e ( 8 6 ) t o t h e p h o s p h i n e o x i d e (871, w h i c h p r o c e e d s o n heating t h e former i n toluene.

I t h a s b e e n shown t h a t t h e

via

a c l a s s i c a l SN2 p r o c e s s i n v o l v i n g p h o s p h o r u s as a n u c l e o p h i l e , and t h e o p e r a t i o n o f a r a d i c a l c h a i n p r o c e s s h a s also been r u l e d o u t . That t h e r e l a t e d methyl e t h e r reaction does not proceed

o f ( 8 6 ) d o e s n o t u n d e r g o t h e r e a r r a n g e m e n t may p o i n t t o a p a t h w a y i n v o l v i n g o x i d a t i v e a d d i t i o n o f t h e hydroxy group t o phosphorus

t o g i v e a n i n t e r m e d i a t e p h o s p h o r a n e . 139

Polymer-bound t r i a r y l -

p h o s p h i n e s h a v e been u s e d t o r e d u c e o z o n i d e s o f a l k e n e s t o form c a r b o n y l c o m p o u n d s . 140 The r e a c t i o n s o f t r i p h e n y l p h o s p h i n e w i t h

(dialkoxyphosphory1)dichloroacetaldehydes l e a d t o t h e f o r m a t i o n Various p r o d u c t s

of t h e dichlorovinylphosphonates ( 8 8 ) . 14'

a r i s i n g f r o m P-P c l e a v a g e h a v e b e e n i s o l a t e d f r o m t h e r e a c t i o n s o f t e t r a a l k y l d i p h o s p h i n e s w i t h h e x a f l u o r o a c e t o n e . 142 The p h o s p h i n a t e s ( 8 9 ) a r e formed i n t h e r e a c t i o n s o f a l d e h y d e s or k e t o n e s w i t h Condensation r e a c t i o n s o f

b i s ( t r imethylsi1oxy)phosphine. 143

bis(hydroxymethy1)phenylphosphine c o n t i n u e t o b e e m p l o y e d i n t h e s y n t h e s i s o f h e t e r o c y c l i c s y s t e m s . 144-147 T h u s , e . g . , w i t h

-

t-butyldichlorophosphine , t h e d i o x a d i p h o s p h o r i n a n e ( 9 0 1 is formed,144 and t h e r e a c t i o n w i t h t r i e t h y l o r t h o f o r m a t e r e s u l t s i n

is

I : Phosphines und Phosphonium Salts

(76)

(771

Q O4

‘R

(79)

Ph,PCH,Si Me2H

(80) R

E\ N

N

R’

C(CI)=CHCI

o

( 8 1 ) n : l or 2

‘

Me H

(86)

(85)

0 II (RO),P-

Ph or But

R2

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(88)

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( 8 9 ) R’: a l k y l R2=H or a l k y l

r 9CHOEt

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0’ (91)

fl

0

(92)

Me2PX Me

(93) X = S,Se or Te

16

Organophosphorus Chemistry

t h e d i o x a p h o s p h o r i n a n e ( 9 1 ) 147

The s t e r e o c h e m i s t r y o f t h e

r e d u c t i o n o f t h e k e t o group o f t h e phosphorinanone ( 9 2 ) h a s been shown t o d e p e n d o n t h e n a t u r e o f t h e r e d u c i n g a g e n t . 14 8 Q u a t e r n a r y ammonium s a l t s o f s u l p h o n a t e d t r i a r y l p h o s p h i n e s h a v e been proposed a s components o f p h a s e - t r a n s f e r s y s t e m s . The r e a c t i o n s o f p o l y p h o s p h i n e s c o n t i n u e t o b e s t u d i e d .

Tetra-

methyldiphosphine undergoes exchange r e a c t i o n s with dimethyldis u l p h i d e , - s e l e n i d e , and - t e l l u r i d e t o g i v e t h e dimethylphosphinite

e s t e r s ( 9 3 ) . 150 (94;

R = e.g.,

The d y n a m i c s t e r e o c h e m i s t r y o f t h e d i p h o s p h i n e s L-menthyl)

i n s o l u t i o n h a s been i n ~ e s t i g a t e d . ' ~ ~

The r e a c t i o n o f t h e p h o s p h i n o - c h l o r o b o r a n e

(95) w i t h d i - i s o p r o p y l -

boron d i c h l o r i d e r e s u l t s i n t h e format ion of t h e phosphino-borane

c l u s t e r ( 9 6 ) w h i c h may o f f e r p o s s i b i l i t i e s f o r t h e p r e p a r a t i o n o f more c o m p l e x p h o s p h o r u s - b o r o n c l u s t e r s . 152 2 Halogenophosphines 2.1 Preparation.-

A d e t a i l e d procedure h a s been d e s c r i b e d f o r t h e

p r e p a r a t i o n of 1,2-bis(dichlorophosphino)ethane f r o m t h e r e a c t i o n of white phosphorus, phosphorus t r i c h l o r i d e and e t h y l e n e i n an a u t o c l a v e a t 200°C.153

A series o f a l k y l - a n d a r y l -

dichloro-

p h o s p h i n e s h a s bee n p r e p a r e d by t h e r e a c t i o n s o f p r i m a r y p h o s p h i n e s

.

w i t h h e x a c h l o r o e t h a n e 154

R o u t e s t o d i a l k y l - and a l k y l a r y l -

c h l o r o p h o s p h i n e s a r e p r o v i d e d by e x c h a n g e r e a c t i o n s b e t w e e n c h l o r o d i p h e n y l p h o s p h i n e a n d t e t r a o r g a n o d i p h o s p h i n e s 155 F u r t h e r

.

procedures have been d e s c r i b e d f o r t h e formation of diphenylchlorophosphine and phenyldichlorophosphine by t h e deoxygenation of t h e r e l a t e d p h o s p h i n y l a n d p h o s p h o n y l h a l i d e s w i t h t e r v a l e n t p h o s p h o r u s c o m p o u n d s . 15' A v a r i a t i o n o f t h e w e l l - k n o w n s y n t h e s i s o f p h o s p h e t a n e o x i d e s h a s been d e s c r i b e d which i n v o l v e s t h e

-in-situ

generat ion of a r y l d i c h l o r o p h o s p h i n e s from t h e r e a c t i o n of

t h e aromatic h y d r o c a r b o n , p h o s p h o r u s t r i c h l o r i d e , a n d a l u m i n i u m c h l o r i d e , t h e r e s u l t i n g complex t h e n b e i n g t r e a t e d w i t h t h e a p p r o p r i a t e a l k e n e . 157

The d i r e c t a r y l a t i o n of p h o s p h o r u s

t r i c h l o r i d e w i t h a n aromatic h y d r o c a r b o n i n t h e p r e s e n c e of aluminium t r i c h l o r i d e h a s also been u s e d f o r t h e j o i n t p r o d u c t i o n 158

o f b o t h a r y l d i c h l o r o p h o s p h i n e s and d i a r y l c h l o r o p h o s p h i n e s .

Aryldichlorophosphines can a l s o be prepared by t h e reaction of

aryl(methy1)dichlorosilanes w i t h p h o s p h o r u s t r i c h l o r i d e a n d aluminium t r i c h l o r i d e . A c o n v e n i e n t r o u t e f o r t h e s y n t h e s i s of l-adamantyldichlorophosphine ( 9 7 ) i n v o l v e s t h e r e d u c t i o n . o f

l-adamantylthiophosphonyl d i c h l o r i d e u s i n g t r i p h e n y l p h o s p h i n e .

160

1: Phosphines and Phosphonium Salts

17 BR

R\

P-P,

’

R‘*N\

R

R’

P ( S i Me3I2

8-

RB

CI’

Ph

(94)

(951

4

PC I,

( 9 6 ) R = Pr’,N

+q+ PCI

R1x0siMe3 OR^

R‘

(100) R’= MqSi , CN 2 R = H or Me 3 R =Me,Si,Me

, or

Me

, or

Et

6 r 2 PCH,C(R)=C(R) CH28r (103) R = H or Me

C IC H2CH=C

M e C H2PCI

(106)

P h C E CPXz (109) X = CI or Br

Br,PCH=

C(R)C(R )=CH2 (1041

Br CH= CPh

‘PBr

Br CH

=CR/

(105)R=Me ,But,or Ph

CIoCH=CHPCL2

S

(1 07)

CI, PC(R F C H C I

(108) R = Ph or

But

X , P E CPX, (110)

(111) R = OMe or Me,N

Organophosphorus Chemistry

18 V a r i o u s c h l o r o p h o s p h i n e s b e a r i n g L-menthyl

s u b s t i t u e n t s h a v e been

p r e p a r e d by a l k y l a t i o n of d i c h l o r o p h o s p h i n e s w i t h G r i g n a r d reagent s

.

The p h o s p h o r u s e p i m e r s of ( - ) - m e n t h y l ( p h e n y 1 ) c h l o r o -

p h o s p h i n e h a v e b e e n c h a r a c t e r i s e d by 'P n . m . r . s p e c t r o s c o p y . 162 P a r t i a l a r y l a t ion of phosphorus t r i c h l o r i d e with m e s i t y l l i t h i u m

a t -78OC p r o v i d e s c o n v e n i e n t r o u t e s t o mesityldichlorophosphine ( 9 8 ) , 163 a n d dimesitylchlorophosphine (99). 164 A new a p p r o a c h t o f u n c t i o n a l i s e d a l k y l d i c h l o r o p h o s p h i n e s i s a f f o r d e d by t h e

r e a c t i o n s of s i l y l a t e d k e t e n e a c e t a l s ( 1 0 0 ) w i t h p h o s p h o r u s trichloride, giving, e . g . ,( 1 0 1 ) .

T r e a t m e n t of t h e l a t t e r w i t h a n

appropriate base generates functionalised phosphaalkenes, e.g.,

( 1 0 2 1 , w h i c h can b e t r a p p e d w i t h d i a z o a l k a n e s or d i e n e s t o g i v e

v a r i o u s h e t e r o c y c l i c compounds i n v o l v i n g t w o - c o o r d i n a t e p h o s 165 phorus

.

I n t e r e s t continues i n t h e synthesis of alkenylhalogenophosphines.

Dehydrobromination of t h e a l l y l i c dibromophosphines

1 0 3 1 h a s g i v e n t h e alkadienyldibromophosphines

( 1 0 4 1. 166 The (_E,g)-dialkenylbromophosphines ( 1 0 5 ) h a v e b e e n o b t a i n e d i n > 9 0 % y i e l d by t h e p h o t o i n i t i a t e d r e a c t i o n s o f ( g ) - a l k e n y l d i b r o m o (

phosphines with a 1 k ~ n e s . l ~ P h~o s p h i n e h a s b e e n u s e d t o r e d u c e t h e i o n i c a d d u c t formed between i s o p r e n e and p h o s p h o r u s p e n t a c h l o r i d e t o g i v e t h e a l l y 1ic d i c h l o r o p h o s p h i n e

(

1 0 6 ) . 16'

A similar

r e d u c t i o n of t h e p h o s p h o r u s p e n t a c h l o r i d e a d d u c t of 2 - c h l o r o - 5 v i n y l t h i o p h e n , u s i n g methyldichlorophosphite, h a s g i v e n t h e

s u b s t i t u t e d vinyldichlorophosphine

(

107 1.

The c h l o r o v i n y l d i -

c h l o r o p h o s p h i n e s ( 1 0 8 ) are formed i n t h e p h o t o i n i t i a t e d r e a c t i o n 170 of p h e n y l - a n d t - b u t y l - a c e t y l e n e w i t h p h o s p h o r u s t r i c h l o r i d e . I n c o n t r a s t , t h e t h e r m a l r e a c t i o n s o f p h e n y l a c e t y l e n e and phosphorus t r i h a l i d e s in an i n e r t solvent y i e l d t h e alkynyldihalogenophosphines

(

109 1. 17'

The r e a c t i o n s o f d i l i t h i u m - a c e t y l i d e

w i t h a r a n g e o f bis(dialky1amino)chlorophosphines h a v e g i v e n t h e

dialkylaminophosphinoacetylenes

(

110 ;

X = NR, 1 , w h i c h o n t r e a t m e n t

w i t h hydrogen c h l o r i d e a r e c o n v e r t e d i n t o t h e r e l a t e d b i s ( d i c h 1 o r o phosphine) (110;

The l a t t e r h a s b e e n shown t o u n d e r g o a n

X = Cl).

e x c h a n g e r e a c t i o n w i t h a r s e n i c t r i f l u o r i d e t o g i v e t h e corresp o n d i n g b i s ( d i f 1 u o r o p h o s p h i n e ) ( 1 1 0 ; X = F). 172 The 2 - s u b s t i t u t e d a r y l d i c h l o r o p h o s p h i n e s (111;

X = C1) also undergo exchange

r e a c t i o n s , ( i n t h e p r e s e n c e of s o d i u m f l u o r i d e i n a c e t o n i t r i l e containing a crown-ether)

(111, X = F ) .

,

to give the difluorophosphines

S u r p r i s i n g l y , 2-methoxyphenyldifluorophosphine

undergoes a spontaneous d i s p r o p o r t i o n a t i o n r e a c t i o n t o form t h e

I : Phosphines and Phosphonium Salts

19

r e l a t e d 2-methoxyphenyltetrafluorophosphorane a n d t e t r a k i s ( g 173

methoxyphenyllcyclotetraphosphine.

2.2 R e a c t i o n s o f Ha1ogenophosphines.-

O z o n a t i o n h a s b e e n shown t o

b e a n e f f i c i e n t method f o r t h e o x i d a t i o n o f h a l o g e n o p h o s p h i n e s ) p a r t i c u l a r l y f o r t h o s e i n v o l v i n g b u l k y o r g a n i c s u b s t i t u e n t s . 174 S t u d i e s o f t h e s t e r e o c h e m i s t r y of n u c l e o p h i l i c s u b s t i t u t i o n o f c h l o r i n e from t h e 7-phosphanorbornene

halogenophosphine system

( 1 1 2 ) h a s p r o v i d e d some i n t e r e s t i n g r e s u l t s . nucleophiles

With oxygen

s u b s t i t u t i o n p r o c e e d s w i t h c o m p l e t e r e t e n t i o n of

c o n f i g u r a t i o n a t p h o s p h o r u s , c o n s i s t e n t w i t h a mechanism i n v o l v i n g

a p h o s p h o r a n i d e i n t e r m e d i a t e , t h e d e c a y o f w h i c h is i n a c c o r d a n c e w i t h a pathway i n v o l v i n g a p i c a l e n t r y , p s e u d o r o t a t i o n , and a p i c a l d e p a r t u r e a s would b e t h e case f o r r e t e n t i o n o f c o n f i g u r a t i o n i n r e a c t i o n s i n v o l v i n g t r u e t r i g o n a l b i p y r a m i d a l i n t e r m e d i a t e s . 17' I n c o n t r a s t , t h e r e l a t e d r e a c t i o n s o f s e c o n d a r y amine n u c l e o p h i l e s o c c u r w i t h b o t h r e t e n t i o n and i n v e r s i o n a t p h o s p h o r u s , t h e d i f f e r e n t b e h a v i o u r of a m i n e s b e i n g a t t r i b u t e d t o t h e l o w e r a p i c o p h i l i c i t y of nitrogen in t h e t r i g o n a l bipyramidal i n t e r mediates t h a t develop from t h e i n i t ially-formed phosphoranide s p e c i e s . 176

The 1 - c h l o r o p h o s p h i r a n e s

(

113) do not undergo t h e

expected nucleophilic displacement reactions at phosphorus, leading i n s t e a d t o a s e r i e s o f r i n g - o p e n e d p r o d u c t s , e x c e p t i n t h e case o f one r e a c t i o n w i t h l i t h i u m aluminium h y d r i d e , which results i n t h e e x p e c t e d c y c l i c s e c o n d a r y p h o s p h i n e . 177 oxygen- and n i t r o g e n - n u c l e o p h i l e s

T h e r e a c t i o n s of

with halogenophosphines continue

t o b e u s e d t o p r e p a r e new, o f t e n c h i r a l , l i g a n d

e.g.,

(114)l8'

a n d (115).181

r e a c t i o n o f 2-butyne-1,4-diol

Contrary t o earlier r e p o r t s , t h e with chlorodiphenylphosphine l e a d s

bo t h e 2,3-bis(diphenylphosphinyl)-l,3-butadiene

( 1 1 6 ) . 182 Diisopropylaminodichlorophosphine h a s b e e n u s e d f o r t h e m o d i f i c a t i o n o f g u a n i n e b a s e s . 183 The r o l e o f d i c h l o r o p h o s p h i n e i n t e r mediates h a s been considered i n t h e r e a c t i o n s of phosphorus t r i c h l o r i d e w i t h a r y l h y d r a z o n e s which c a n l e a d t o t h e f o r m a t i o n o f b o t h d i a z a p h o s p h o l e s a n d i n d o l e s . 184 V a r i o u s h e t e r o c y c l i c systems, e . g . , ( 1 1 7 ) ) h a v e b e e n p r e p a r e d by t h e r e a c t i o n s o f bis(dich1orophosphino)methane w i t h h y d r a z i n e s . 185 The b i s ( d i f l u o r o p h o s p h i n o ) l i g a n d s ( 1 1 8 ) h a v e b e e n o b t a i n e d f r o m t h e react i o n s of bis(dif1uorophosphino)sulphide w i t h a p p r o p r i a t e d i o l s a n d d i t h i o l s . 186 The N-( dich1orophosphino)diamine ( 119 1, a c c e s s i b l e f r o m t h e r e a c t i o n s of r e l a t e d t r i m e t h y l s i l y l a r n i n o

20

Organophosphorus Chemistry

compounds w i t h p h o s p h o r u s t r i c h l o r i d e , i s f o u n d t o u n d e r g o a n intramolecular n u c l e o p h i l i c displacement p r o c e s s to form t h e s t a b l e 18 7 ( 120 1 .

phosphenium s a l t

The u s e o f chloromethyldichlorophosphine i n t h e s y n t h e s i s

’**

of a z a p h o s p h o l e s y s t e m s h a s b e e n r e v i e w e d . Various chloroalkylp h o s p h o n a t e s and - p h o s p h i n a t e s have been i s o l a t e d from t h e r e a c t i o n s o f t h e chloroalkyldichlorophosphines ( 1 2 1 ) w i t h t r i e t h y l

o r t h o f o r m a t e . 18’

A mixture of t h e phosphinyl chloride

(

122) and

methylphosphonic d i c h l o r i d e is formed i n t h e r e a c t i o n o f methyldichlorophosphine with paraformaldehyde.

The h e t e r o c y c l i c

s y s t e m ( 1 2 3 ) arises i n t h e r e a c t i o n of et hyl di c h lo ro p h o sp h in e with

1,”-dibutyl-2,3-butanediimine

i n t h e p r e s e n c e of water. l g l ’ l g 2

The c o r r e s p o n d i n g c y c l i c a m i n o p h o s p h i n e c a n b e o b t a i n e d o n

r e d u c t i o n w i t h t r i c h l o r o s i l a n e . l g 3 The r e a c t i o n

of diorgano-

c h l o r o p h o s p h i n e s w i t h dialkylphosphinoacetylenes h a s g i v e n t h e

h e t e r o c y c l i c s y s t e m ( 1 2 4 ) . lg4 Phospholanium s a l t s ( 1 2 5 ) are f o r m e d , t o g e t h e r w i t h o t h e r p r o d u c t s , i n t h e r e a c t i o n s of

d i a l k y l i o d o p h o s p h i n e s w i t h THF,Ig5 a n d t h e s a l t s ( 1 2 6 ) h a v e been i s o l a t e d from t h e r e a c t i o n s of alkyldiiodophosphines with t e r t i a r y a m i n e s . l g 6 An e l e c t r o c h e m i c a l p r o c e d u r e f o r t h e s y n t h e s i s of cyclopolyphosphines h a s been developed following an i n i t i a l s t u d y o f t h e e l e c t r o r e d u c t i o n o f a l k y l - a n d aryl-dichlorophosphines. l g 7 C a t h o d i c r e d u c t i o n o f halogenodiphenylphosphines i n d r y a c e t o -

nitrile

l e a d s t o t h e e x c l u s i v e f o r m a t i o n of t e t r a p h e n y l d i -

phosphine. The u s e o f isocyanatodiorganophosphines i n t h e s y n t h e s i s of

oxazaphospholine and oxazaphosphole d e r i v a t i v e s c o n t a i n i n g f o u r and f ive-coordinate

p h o s p h o r u s h a s been reviewed.

’’’

3 Phosphonium S a l t s

3 . 1 P r e p a r a t i o n . - The r e a c t i o n s o f t r i p h e n y l p h o s p h i n e h y d r o b r o m i d e w i t h c h l o r o a l k a n e s i n DMF g i v e much b e t t e r y i e l d s of t h e a l k y l t r i phenylphosphonium s a l t s t h a n a r e o b t a i n e d i n t h e d i r e c t r e a c t i o n s o f t h e c h l o r o a l k a n e s w i t h t r i p h e n y l p h o s p h i n e . 2oo A new r o u t e t o

a-alkoxyalkylphosphonium s a l t s is a f f o r d e d by t h e r e a c t i o n s of

acetals with triphenylphosphine,

trifluoride-etherate,

i n t h e p r e s e n c e of b o r o n

in toluene solution.201

Conventional

q u a t e r n i z a t i o n p r o c e d u r e s h a v e b e e n u s e d i n t h e s y n t h e s i s of t h e unsaturated macrocyclic tetraphosphonium salt (127)

(which can b e 202

c a t a l y t i c a l l y reduced t o t h e corresponding s a t u r a t e d system), t h e water-soluble

l u m i n e s c e n t d i p h o s p h o n i u m s a l t ( I28 1 ,203 t h e

1: Phosphines and Ph osphon iurn Salt J

Ph Me3Si

21

>6.<," CI

(1131 R = A r y l

19

PPh2

Ph, P

C H2 0 PPh 2

I

R'-

CH

(1111R'= Me, Pr' or 2

Ph

R = H or SR Me

N-N

0 (115)

(1161

I

CH~R'

Me

II

- NPPh,

/

Me

(117 1 Me

F2PX(CH, 1,XPF2 (118) X = 0 or S n = 2- 6

M e2NCH2CH,N( Me1 PCI, (119)

CIMe2 (1201

0 C In C H3-nP C I (121) n = l - 3

II ,Me

ClCH P

'CI (1221

1

+

R P( N R2,),

R'

R ' (1251

(126)

(124) R ' = a l k y l or a r y l

R 2 = E t or Bu

(1281

(129) R z a l k y l or Ph

21 -

22

Organnphospho rus Chemistry

o-isocyanobenzylphosphonium

salts

(

129 1 , 2 0 4 a n d a r a d i o l a b e l l e d

.

E - i o d o b e n z y l t r i p h e n y l p h o s p h o n ium s a l t 2 0 5

On d i s s o l u t i o n i n DMF, t h e s a l t ( 1 3 0 ) isomerises t o t h e a l l e n y l s y s t e m ( 1 3 1 1 , t h e r e a c t i o n b e i n g r e v e r s e d o n h e a t i n g . 206

quaternary

B o t h mono- a n d d i -

s a l t s h a v e b e e n o b t a i n e d f r o m t h e r e a c t i o n s of t h e

c y c l i c diphosphine

( 132) w i t h iodomethane. 207 Various r o u t e s t o t h e c h i r a l phosphonium s a l t ( 1 3 3 ) from a p r e c u r s o r c h i r a l a l c o h o l

h a v e b e e n d e v e l o p e d . 208

A d d i t i o n o f 1i t h i u m d i p h e n y l p h o s p h i d e

to 1-vinyl-2-carboranes,

f o l l o w e d by

quaternization of the

r e s u l t i n g phosphines with iodomethane, h a s l e d t o t h e s y n t h e s i s of a r a n g e of B-(g-carboranyl)ethylphosphonium

s a l t s . 209

Heteroarylmethylphosphonium s a l t s , e . g . , ( 1 3 4 ) , h a v e b e e n t r i p h e n y l p h o s p h o n i u m c h l o r i d e .210

p r e p a r e d from 3-chloro-2-oxopropyl

Heating 1-chloroanthraquinone with triphenylphosphine at 165-170°C g i v e s t h e a r y l p h o s p h o n i u m s a l t ( 1 3 5 ) .211

The f o r m a t i o n

of arylphosphonium salts from t h e n i c k e l ( I 1 ) - c a t a l y s e d

reactions

of various 2-substituted a r y l halides with t e r t i a r y phosphines i n r e f l u x i n g e t h a n o l h a s r e c e i v e d f u r t h e r a t t e n t i o n , and t h e structural features required in the ortho subst ituent in order t h a t h a l i d e r e p l a c e m e n t o c c u r s under t h e s e c o n d i t i o n s h a v e been established.212 (

The r e a c t i o n s o f t h e t e t r a t h i a n e d i i m i n i u m s a l t s

136 ) w i t h t r i p h e n y l p h o s p h i n e h a v e g i v e n t h e N , N _ - d i a l k y l t h i o -

carbamoylphosphonium s a l t s

( 1 3 7 ) . 213 The t r i m e t h y l s i l y l m e t h y l (dialky1amino)phosphonium s a l t s ( 1 3 8 ) h a v e b e e n p r e p a r e d b y t h e reaction o f t r i m e t h y l s i l y l chloride with t h e tris(dialky1amino)Phosphonium s a l t s i n v o l v i n g u n u s u a l p h o s p h o n i u m m e t h y l i d e . 214 c o u n t e r i o n s c o n t i n u e t o b e i n v e s t i g a t e d , some h a v i n g a p p l i c a t i o n

as n o v e l s y n t h e t i c r e a g e n t s .

The h y d r o g e n d i f l u o r i d e s a l t ( 1 3 9 )

h a s b e e n u s e d f o r t h e f l u o r i n a t i o n of o r g a n i c s u b s t r a t e s , 2 1 5 a n d t h e tetra-alkylphosphonium

i o d i d e - t r i o r g a n o t i n h a 1i d e a d d u c t s

( 1 4 0 ) are found t o c a t a l y s e t h e c y c l o a d d i t i o n o f c a r b o n d i o x i d e

t o o x i r a n e s , l e a d i n g t o t h e f o r m a t i o n of f ive-membered c y c l i c c a r b o n a t e s u n d e r n e u t r a l a n d m i l d c o n d i t i o n s . 216 The r e a c t i o n o f t e t r a p h e n y l p h o s p h o n i u m i o d i d e w i t h a n t i m n y t r i i o d i d e i n aceton i t r i l e r e s u l t s i n t h e f o r m a t i o n o f t h e s a l t ( 1 4 1 ) . 217 The s a l t

+

CH,PH,Cl-

h a s been i s o l a t e d from t h e r e a c t i o n of methyldichloro2 18

phosphine with ethylene glycol i n dichloromethane.

I : Phosphines und Phosphoniuni Salrs

+

CPh Br-

Ph,PCH,C=

23

Ph36CH=C =CHPh

A

Br-

,PBuf

But P,

N

mu But

(131 1

(130)

(132 1

;

Me

Ph 1-C H+z

\

(133)

0

(134)

s- s

(135)

S

II

+

** Cl0,-

Ph,P-CNR,

( Et2NI36CH,SiMc, C<

(138)

(1371

PI-

0

/ \

Me

Ph

/

(143 1

(1d2)

RCONHC= CHCl

0

-

+

I+

PPh,

X-

(1f.4) R = Me or Ph

+

fpPh3 CIO,

dPPh3 Se&N c'oL

(1451

(1461 (1L7)

Ph,;

- CR' R'COC, X-

( 1 4 8 ) R'

F,,

+,

, Rz=a l k y l , a l l y l or bentyl

S

II

Ph2P-CH

I

- 6Ph3 x-

CO Me (149)

+

C H 3 C E CPPh, (150)

Organophosphorus Chemistn

24

3 . 2 R e a c t i o n s of' P h o s p h o n i u m S a l t s . -

A study of t h e k i n e t i c

a c i d i t y o f a series of a l k y l t r i ( t-buty1)phosphonium s a l t s h a s r e v e a l e d t h a t t h e s e compounds a r e s l i g h t l y l e s s a c i d i c t h a n t h e corresponding nitroalkanes.

l9

Ring-opening o c c u r s on a l k a l i n e

h y d r o l y s i s of t h e s a l t ( 1 4 2 ) t o f o r m ( 1 4 3 ) . 220 V a r i o u s p r o d u c t s h a v e b e e n i s o l a t e d f r o m t h e a l k a l i n e h y d r o l y s i s of t e t r a arylphosphoniurn s a l t s b e a r i n g c a r b o n y l s u b s t i t u e n t s . 221 Nucleop h i l i c a d d i t i o n t o u n s a t u r a t e d phosphonium s a l t s c o n t i n u e s t o b e e x p l o i t e d i n t h e s y n t h e s i s of n e w s y s t e m s . subst ituted-vinylphosphonium salt

(

T r e a t m e n t of t h e

1 4 4 ) w i t h sodium hydrogen

s e l e n i d e , f o l l o w e d by a c i d , g i v e s t h e s e l e n a z o l y l p h o s p h o n i u m

salts

( 145). 222

A d d i t i o n of h y d r a z i n e s t o p r o p y a r g y l t r i p h e n y l -

phosphonium bromide h a s g i v e n phosphonium s a l t s o f v a l u e i n t h e s y n t h e s i s o f f u s e d p y r a z o h e t e r o c y c l e s . 223

Nucleophilic

a d d i t i o n s t o t h e cyclobutenylphosphonium s a l t ( 1 4 6 ) h a v e been u s e d t o g e n e r a t e y l i d e s of v a l u e f o r t h e s y n t h e s i s o f 1 , 2 - d i s u b s t i t u t e d cyclobutanes. 224

T h i s s a l t a l s o acts as a d i e n o p h i l e w i t h c y c l o -

p e n t a d i e n e t o g i v e t h e b r i d g e h e a d phosphonium s a l t ( 1 4 7 ) which undergoes a l k a l i n e h y d r o l y s i s very s l o w l y , w i t h l o s s of a phenyl group. 225

The B - k e t o p h o s p h o n i u m s a l t s ( 1 4 8 ) h a v e b e e n shown t o

u n d e r g o a n u n u s u a l a d d i t i o n - e l i m i n a t i o n r e a c t i o n on t r e a t m e n t w i t h c a r b o n n u c l e o p h i l e s t o g i v e n o v e l f l u o r o a l k e n e s . 226

Both

k e t o - a n d e n o l - f o r m s of t h e s a l t (149) h a v e b e e n o b s e r v e d i n s o l u t i o n . 227

The p o l a r o g r a p h i c r e d u c t i o n o f t h e v i n y l t r i p h e n y l -

phosphoniurn and t h e a l kynyl phos phoni um ( 1 5 0 ) c a t i o n s h a s r e c e i v e d d e t a i l e d study.228 I n t e r e s t c o n t i n u e s i n t h e u s e o f p h o s p h o n i u m s a l t s as p h a s e transfer catalysts.

Tetraphenylphosphonium bromide h a s been used t o e n h a n c e t h e r e a c t i v i t y of p o t a s s i u m f l u o r i d e i n n u c l e o p h i l i c

f l u o r i n e t r a n s f e r r e a c t i o n s , g i v i n g l a r g e rate a c c e l e r a t i o n s i n 229 A a p r o t i c s o l v e n t s such a s 1,2-dimethoxyethane.

non-dipolar

c o n s i d e r a t i o n of t h e s t a b i l i t y of q u a t e r n a r y ammonium a n d p h o s phonium s a l t s u n d e r p h a s e t r a n s f e r c o n d i t i o n s i n t h e p r e s e n c e o f a q u e o u s a l k a l i h a s r e v e a l e d t h e e x p e c t e d lower s t a b i l i t y o f t h e p h o s p h o n i u m s a l t s . The e x t e n t o f a l k a l i n e d e g r a d a t i o n c a n b e m i n i m i s e d b y t h e a d d i t i o n o f a molar e x c e s s of t h e r e l a t e d s o d i u m 2 30 s a l t , which s u p p r e s s e s t h e e x t r a c t a b i l i t y of t h e h y d r o x i d e i o n . The p h a s e t r a n s f e r p r o p e r t i e s o f p o l y m e r - b o u n d p h o s p h o n i u m s a l t s 231,232 have a l s o received study.

25

I : Phosphines and Phosphonium Salts QT-Bonded

P h o s p h o r u s Compounds

T h i s area c o n t i n u e s t o a t t r a c t c o n s i d e r a b l e i n t e r e s t .

A review

h a s a p p e a r e d w h i c h c o v e r s compounds i n w h i c h p h o s p h o r u s i s involved i n pT-bonding with a second phosphorus atom, or a r s e n i c , a n t i m o n y or s i l i c o n . 2 3 3

A t h e o r e t i c a l study of t h e species

HP=PH a n d H,P=P h a s b e e n r e p o r t e d . 2 3 4

The b i s - i m i d a z o l i n e

(151)

h a s b e e n u s e d f o r t h e r e d u c t i o n o f 2,4,6-tri-t-butylphenyldichlorophosphine t o g i v e t h e diphosphene (152;

t-butylphenyl).

R = 2,4,6-tri-

R e d u c t i o n of l e s s b u l k y d i h a l o g e n o p h o s p h i n e s

r e s u l t s i n t h e f o r m a t i o n of m i x t u r e s of c y c l o p o l y p h o s p h i n e s . 2 3 5 R o u t e s t o t h e new s t a b l e d i p h o s p h i n e s ( 1 5 3 ) a n d ( 1 5 4 ) , b e a r i n g

pentamethylcyclopentadienyl s u b s t i t u e n t s , h a v e b e e n d e v e l o p e d . 236 , 2 3 7

X-ray s t u d i e s r e v e a l t h a t t h e p e n t a m e t h y l -

c y c l o p e n t a d i e n y l s u b s t i t u e n t s a r e a-bonded t o p h o s p h o r u s , b u t n.m.r.

s t u d i e s are c o n s i s t e n t with f l u x i o n a l behaviour i n

solution.

T r e a t m e n t of t h e s e compounds w i t h c a r b o n - o r n i t r o g e n -

nucleophiles r e s u l t s in displacement of t h e pentamethylcyclopentadienyl substituent, enabling, for the f i r s t t i m e , s u b s t i t u t i o n a t t h e c a r b o n - p h o s p h o r u s b o n d of d i p h o s p h e n e s . 2 3 7 The p h o s p h i d e r e a g e n t ( 1 5 5 ) h a s b e e n u s e d t o p r e p a r e a r a n g e o f p -bonded s y s t e m s , i n c l u d i n g d i p h o s p h e n e s , p h o s p h a - a r s e n e s , phospha-stibines and o t h e r systems,

9i t s

a p p r o p r i a t e d i c h l o r o m e t a l l o compounds.

reactions with

When t r e a t e d w i t h b u l k y

dialkylaminodichlorophosphines, t h e dialkylamino-substituted diphosphenes (156) are

T h e s e compounds are u s e f u l

intermediates f o r t h e synthesis of other diphosphenes.

Treatment

w i t h c a r b o n , n i t r o g e n or s u l p h u r n u c l e o p h i l e s r e s u l t s i n d i s p l a c e ment of t h e d i a l k y l a m i n o g r o u p ,240 a n d t r e a t m e n t w i t h h y d r o g e n c h l o r i d e i n e t h e r a t -78OC l e a d s t o t h e c h l o r o - s u b s t i t u t e d d i p h o s p h e n e ( 1 5 7 ) f r o m w h i c h a r a n g e o f new d i s p h o s p h i n e s h a s 241 b e e n p r e p a r e d by r e a c t i o n s w i t h n u c l e o p h i l i c r e a g e n t s . Reagents similar t o (155) have a l s o been used t o prepare t h e X 3 - A 5 diphosphorus system (158) and o t h e r , r e l a t e d , phosphorusn i t r o g e n and phosphorus-sulphur systems. 242 I n t e r e s t c o n t i n u e s

i n t h e s y n t h e s i s a n d s t u d i e s o f t h e r e a c t i v i t y of d i p h o s p h e n e s which b e a r a complexed m e t a l l o - s u b s t i t u e n t a t one o f t h e phosphorus atoms.243-247 A f u l l survey of t h e r e a c t i v i t y of t h e diphosphenes (152;

R = 2,4,6-tri-t-butylphenyl

o r tris(trimethylsily1)methyl)

towards e l e c t r o p h i l i c and nucleophilic reagents has appeared.

248

F u l l d e t a i l s h a v e b e e n p u b l i s h e d o f t h e r e a c t i o n s of d i p h o s p h e n e s w i t h d i a z o a l k a n e s and c a r b e n e s , which p r o v i d e a g e n e r a l method f o r

26

Organophosphorus Chumistr!

Et

Et

R-P=P-R Et

Et

(1521

( 1 51)

Me

(1531

Me /

S i Me3

P

\

c , p = p & +

/R

ArP=P-OSiR3

\R

%

Li

Ar P

- PAr

\ C/

/ \

R

R

(159) R = H , A r or halogen

@p.; (1 60)

(1611

(162 )

I : Phosphines and Phosphonium Salts

27

t h e preparation of highly s u b s t i t u t e d diphosphiranes (159) .249 An e l e c t r o c h e m i c a l s t u d y o f d i p h o s p h e n e s h a s shown t h a t w h e r e a s i t is e a s y t o c h a r a c t e r i s e t h e r a d i c a l a n i o n r e d u c t i o n p r o d u c t s o f t h e s e s y s t e m s , i t is much more d i f f i c u l t t o d e t e r m i n e t h e n a t u r e of the products of electrochemical oxidation.

Some e v i d e n c e of

t h e f o r m a t i o n o f u n s t a b l e r a d i c a l c a t i o n s h a s been o b t a i n e d . 2 5 0 The c o o r d i n a t i o n c h e m i s t r y of d i p h o s p h e n e s h a s c o n t i n u e d t o

a t t r a c t i n t e r e s t .251-254 The d i r e c t u t i l i s a t i o n of u n h i n d e r e d p h o s p h a - a l k e n e s - a l k y n e s i n s y n t h e s i s may now b e p o s s i b l e ,

and

f o l l o w i n g a n improved

r o u t e f o r t h e i r p r e p a r a t i o n by t h e s t e p w i s e d e h y d r o h a l o g e n a t i o n o f a l k y l d i c h l o r o p h o s p h i n e s u n d e r f l a s h vacuum t h e r m o l y s i s c o n d i t i o n s , t h e e l i m i n a t e d h y d r o g e n c h l o r i d e b e i n g removed i n a gas-absorption t r a i n involving a heterocyclic base.

The p r o d u c t s a r e c o n d e n s e d f r o m t h e gas p h a s e a t -120OC. The s t a b i l i t i e s o f s u c h u n h i n d e r e d compounds a r e g r e a t e r t h a n e x p e c t e d ; t h u s , g., t h e p h o s p h a - a l k y n e MeCEP i s r e p o r t e d t o be s t a b l e f o r t h r e e d a y s i n s o l u t i o n a t room t e m p e r a t u r e . 2 5 5 Two g r o u p s h a v e r e p o r t e d t h e

f o r m a t i o n o f s t e r i c a l l y - c r o w d e d p h o s p h a - a l k e n e s by t h e c o n d e n s a t i o n of t h e p r i m a r y p h o s p h i n e ( 1 6 0 ) w i t h c a r b o n y l c o m p o u n d s , a d i r e c t analogy with S c h i f f ' s base condensation i n nitrogen chemistry.256 9257 A s noted above f o r r e l a t e d diphosphenes, t h e p r e s e n c e o f t h e pentamethylcyclopentadienyl s u b s t i t u e n t a t

phosphorus of t h e phospha-alkene (161) p r o v i d e s a very r e a c t i v e c a r b o n - p h o s p h o r u s b o n d . 258 A d e t a i l e d p r o c e d u r e f o r t h e s y n t h e s i s o f t h e c h l o r o p h o s p h a - a l k e n e ( 1 6 2 ) h a s b e e n d e s c r i b e d . 259

The

r e a c t i v i t y of t h e c h l o r o p h o s p h a - a l k e n e ( 1 6 3 ) c o n t i n u e s t o b e explored.

Access t o a v a r i e t y of new p h o s p h a - a l k e n e s

is a f f o r d e d

260,261

by n u c l e o p h i l i c d i s p l a c e m e n t of c h l o r i n e f r o m t h i s compound.

-

I t s r e a c t i o n w i t h t h e a n i o n BsHe l e a d s t o t h e s y n t h e s i s o f a nidomethylenephosphahexaborane. 2 6 2 T h e d i p h o s p h i r a n e ( 1 6 4 ) i s f o r m e d i n t h e r e a c t i o n of ( 1 6 3 ) w i t h t h e a n i o n [ H F e ( C 0 ) 1 , l r 2 6 3

The

Diels-Alder r e a c t i o n s of (163) with appropriate a c y c l i c dienes p r o v i d e a g e n e r a l r o u t e t o f u n c t i o n a l i s e d A ' - p h o s p h o r i n s , e.g., With ( 1 6 5 ) , f o l l o w i n g "aromat i s a t i o n " o f t h e i n i t i a l a d d u c t s 264 c y c l o p e n t a d i e n e , t h e p h o s p h a n o r b o r n e n e ( 1 6 6 ) is f o r m e d . 2 6 5 A p p e l ' s

.

group h a s e x p l o r e d v a r i o u s v a l e n c e i s o m e r i s a t i o n p r o c e s s e s of u n s a t u r a t e d p h o s p h o r u s compounds w h i c h l e a d t o new p h o s p h a - a l k e n e systems.

T h u s t h e b i s p h o s p h i n e ( 1 6 7 ) r e a r r a n g e s a t 40°C i n THF

s o l u t i o n t o g i v e t h e racemic b i s p h o s p h a - a l k e n e ( 1 6 8 ) w h i c h t h e n u n d e r g o e s a s l o w , i r r e v e r s i b l e c o n v e r s i o n i n t o t h e r e l a t e d meso-

28

OrganophosphoruJ Chmiisrn,

CIP-

( Me3Si),C=PC\

\/

PCHISiMe3l2

Me

'' Q

C0,Me

(165 1

(1631 Me3Si

SiMe3 ( 1 6L1

Me3Si ( 167 1 Ar = 2 ,4 ,6 But3CgH

-

(1661

Ar

P ''

I

/p\c

Ar

-*rpDph ArP

*CPh

(169) A r = 2 , d J 6 -Buf,C,H,

A r P=C=O

(172) A r = 2 , L J 6 But3C,H2

[ 168 1

+

Ph

(171) R = M e or Ph

(1701

-

Me3SiPR

I

Me3Si PR [ 173)R=Me3Si I Pr

', or

OSiMe3 ArPPPR

I

Ar P&PR OSiMe3

Ph

(174)

CQ

But P=CH6ut

Me,SiN( R )P=C(SMc)2 F

[ 175)

[ 176) R = But or Me,Si

/

C=PC,F, (177)

I : Phosphines and Phosphonium Salts

29

f o r m . 266 S i m i l a r l y , t h e b i s p h o s p h i n e ( 1 6 9 ) r e a r r a n g e s t o form t h e bis(phosphamethy1ene)cyclobutene s y s t e m ( 1 7 0 ) . 267 Cope r e a r r a n g e m e n t s of p h o s p h a - a l k e n e s b e a r i n g u n s a t u r a t e d s u b s t i t u e n t s

a t c a r b o n , e.g.,( 1 7 1 ) , h a v e a l s o b e e n r e p o r t e d . 2 6 8 The r e a c t i o n s o f t h e phosphaketene ( 1 7 2 ) w i t h t h e d i p h o s p h i n e s (173) g i v e t h e valence-stable

b i s ( p h o s p h a - a l k e n e s ) ( 1 7 4 ) . 269

s y n t h e s i s o f t h e new p h o s p h a - a l k e n e s been r e p o r t e d .

(

Routes f o r t h e 175)270 and ( 176)271 have

The p e r f l u o r o p h o s p h a - a l k e n e ( 1 7 7 ) h a s b e e n

p r e p a r e d by t h e t h e r m a l e l i m i n a t i o n o f t r i m e t h y l t i n f l u o r i d e f r o m

bis(pentafluoroethy1)trimethylstannylphosphine.

The P=C l i n k i n

t h i s m o l e c u l e is more p o l a r t h a n t h a t i n t h e r e l a t e d p h o s p h a -

a s i n d i c a t e d b y t h e r e a c t i v i t y of ( 1 7 7 ) t o w a r d s The r e a c t i v i t y o f t h e r e l a t e d arsaa l k e n e , CF3As=CF,, is greater s t i l l , t h i s compound u n d e r g o i n g

a l k e n e , CF,P=CF,,

p r o t i c a c i d s and d i e n e s . 272

c y c l o a d d i t i o n w i t h t h i o p h e n . 273

The s t r u c t u r e of CF,P=CF,, a n d 2 74

of its c y c l i c dimer, have been s t u d i e d i n t h e gas-phase.

P h o t o l y s i s o f t h e a-diazomethylenediphosphine

phosphino-subst i t u t e d phospha-alkene

(

(178) has given t h e

179) i n almost q u a n t i t a t i v e

y i e l d , v i a t h e r e a r r a n g e m e n t of a n i n t e r m e d i a t e d i p h o s p h i n o -

.

c a r b e n e-255

A t h e o r e t i c a l treatment of phosphinocarbenes has a l s o

b e e n p r e s e n t e d .276

The P H - f u n c t i o n a l

phospha-alkenes

been c o u p l e d t o form t h e b i s ( p h o s p h a - a l k e n e )

(

180 1 h a v e

s y s t e m ( 1 8 1 ) on

t r e a t m e n t w i t h m e r c u r y ( 11) b i s ( t r i m e t h y l s i l y l ) a m i d e .277

Strong

b a s e s s u c h a s DBU p r o m o t e t h e r e a r r a n g e m e n t o f ( 1 8 2 ) t o ( 1 8 3 ) . 2 7 8 I n t e r e s t c o n t i n u e s i n t h e s y n t h e s i s a n d s t u d y o f t h e r e a c t i v i t y of i n which a complexed t r a n s i t i o n m e t a l - s u b s t i t u e n t is p r e s e n t a t p h o s p h o r ~ s , ~a n~d ~a l- s~o ~i n~ t h e g e n e r a l c o -

phospha-alkenes

ordination chemistry of phospha-alkenes.

282

F u r t h e r e x a m p l e s o f p h o s p h a - a l l e n e s (184) h a v e b e e n p r e p a r e d b y W i t t i g r e a c t i o n s o f t h e p h o s p h a k e t e n e (172). 2 8 3 The f i r s t

r e s o l u t i o n of t h e d i s s y m m e t r i c d i p h o s p h a - a l l e n e

system

(

185) h a s

b e e n a c h i e v e d b y c h r o m a t o g r a p h y on a column h a v i n g a c h i r a l s t a t i o n a r y phase. T h i s compound u n d e r g o e s racemisat i o n on e x p o s u r e t o l i g h t . 2 8 4 P h o s p h a - a l l e n e s are a l s o p r o v i n g t o b e o f i n t e r e s t

as ligands.285*286

The f i r s t p h o s p h a c u m u l e n e ( 1 8 6 ) h a s b e e n

p r e p a r e d by t h e r e a c t i o n o f a l i t h i o a l l e n e r e a g e n t w i t h 2 , 4 , 6 - t r i t-butylphenyldichlorophosphine. 287 A 5 - P h o s p h a - a l l e n e s h a v e b e e n p r o p o s e d a s i n t e r m e d i a t e s i n t h e phospha-Cope r e a r r a n g e m e n t s of 288 some allyl(alkyny1)phenylphosphine o x i d e s .

R

The c h e m i s t r y o f p h o s p h a - a l k y n e s ,

e s p e c i a l l y t h a t of (187;

= B u t ) , c o n t i n u e s t o d e v e l o p , t h e s e compounds o f t e n b e i n g u s e d as

30

NZ

II

R,PC PR

( R2N1,C =PH

(178) R = Pr’*N

Ar P = C

ArP=C=CHR

( 1 8 d ) R = Ph or CO,Et A r : 2 , L , 6 -Buf,C,H2

RC=

(179 1

(180) R = Me or E t

=PAr

r P (Me2NI2P

A r = 2 , L, 6 - BU’$&

(1861R’=H 2 or Ph R = H , M t , o r Ph

( N Me,),

‘A (190 1

1R 2

( 1 8 5 ) A r = 2 , L , 6 - 6 ~ ? ~ C ~(1861 H ~ R’R2=Me3Si,or Ph

P

(107)

ArP=C=C=CR

0

\I

P=C-C--C=P R (191)

R

1 : Phosphines and Phosphonium Salts

31

i n t e r m e d i a t e s f o r t h e s y n t h e s i s of o t h e r p n - b o n d e d s y s t e m s . D i e l s - A l d e r r e a c t i o n s o f (187;

R

=

But) with c y c l i c dienes lead

t o a d d u c t s which decompose s p o n t a n e o u s l y t o g i v e X 3 - p h o s p h o r in s

( 1 8 8 ).289

The f i r s t t r i p h o s p h a b e n z e n e s y s t e m (189) is f o r m e d i n

t h e r e a c t i o n o f (187;

R = B u t ) w i t h t h e c y c l i c b i s - y l i d e (190)?90 T h e area o f g r e a t e s t a c t i v i t y h a s b e e n t h e r e a c t i o n s u n d e r g o n e by phospha-alkynes

i n t h e p r e s e n c e o f t r a n s i t i o n metals.

c o m p l e x e s of p h o s p h a - a l k y n e s

The f i r s t

i n which t h e p h o s p h o r u s l o n e p a i r is

c o o r d i n a t e d t o t h e metal h a v e b e e n i s o l a t e d f r o m ( 1 8 7 ;

R = a d a m a n t y l ) . 291 F u r t h e r c o m p l e x e s o f (187; R = B u t ) i n w h i c h t h e l i g a n d is b o u n d t o t h e metal i n a s i d e w a y s - o n manner h a v e a l s o b e e n i s o l a t e d . 2 9 2 C o o r d i n a t e d p h o s p h a - a l k y n e s h a v e b e e n shown t o undergo carbonylation at carbon i n t h e presence of carbon monoxide t o form new l i g a t e d s y s t e m s , e . g . ,

(191) .293s294 The

f o r m a t i o n o f n - c o m p l e x e s o f X3-l,3-diphosphacyclobutadienes b y

t h e metal-induced studied.295

d i m e r i s a t i o n of phospha-alkynes c o n t i n u e s t o be

The a b i l i t y o f s u c h c o o r d i n a t e d d i p h o s p h a c y c l o b u t a -

d i e n e s t o form f u r t h e r complexes

a l s o b e e n e x p l o r e d . 296

t h e phosphorus lone p a i r s has

T h e f i r s t monophosphacyclobutadiene

c o m p l e x (192) h a s b e e n o b t a i n e d f r o m t h e r e a c t i o n o f t h e p h o s p h a -

a l k y n e (187;

R = B u t ) w i t h bis(trimethylsily1)acetylene

in the

p r e s e n c e o f a b i s ( e t h e n e ) c y c l o p e n t a d i e n y l c o b a l t c o m p l e x .297

A c t i v i t y a l s o c o n t i n u e s i n t h e c h e m i s t r y o f compounds i n w h i c h

p h o s p h o r u s is i n v o l v e d i n pn-bonding w i t h a h e a v i e r g r o u p I V e l e m e n t , u s u a l l y s i l i c o n o r germanium, a nd o c c a s i o n a l l y t i n . T h i s area h a s b e e n r e v i e w e d . 2 9 8 F u l l d e t a i l s h a v e now a p p e a r e d o f t h e s y n t h e s i s and r e a c t i v i t y o f s t a b l e , s t e r i c a l l y - c r o w d e d phospha-

.

~ i l e n e s ~300 ~ ' a n d - g e r m e n e s 301

The g e r m a p h o s p h e n e ( 193 1 is i n d e f i n i t e l y s t a b l e a t t e m p e r a t u r e s up t o 100°C. I t also exhibits

t e m p e r a t u r e - d e p e n d e n t t h e r r n o c h r o m i s m . However, o n h e a t i n g a t 140°C i n b e n z e n e i n a s e a l e d t u b e , it is c o n v e r t e d i n t o t h e c o l o u r l e s s a n d v e r y s t a b l e g e r m a p h o s p h i n e (194) . 3 0 2

The p a s t y e a r h a s s e e n s i g n i f i c a n t p r o g r e s s t o w a r d s t h e s y n t h e s i s of p h o s p h o r u s - b o r o n p n - b o n d e d s y s t e m s . The c r o w d e d

p h o s p h i n o - b o r a n e . ( 1 9 5 ) h a s b e e n p r e p a r e d f r o m t h e r e a c t i o n of f l u o r o d i m e s i t y l b o r o n w i t h l i t h i u m d i p h e n y l p h o s p h i d e , and i s o l a t e d

as a yellow c r y s t a l l i n e s o l i d .

An X - r a y s t u d y r e v e a l s t h a t t h e r e

may b e some d o u b l e b o n d c h a r a c t e r a s a r e s u l t o f i n t r a m o l e c u l a r P + B c ~ o r d i n a t i o n . ~ ' T~ r e a t m e n t o f t h e r e l a t e d s e c o n d a r y p h o s p h i n e s (196) w i t h t - b u t y l l i t h i u m i n t h e p r e s e n c e o f c r o w n

e t h e r s h a s l e d t o t h e i s o l a t i o n o f a series of s o l v a t e d l i t h i o -

32

Organophosphorus Chemistry

B-

Ge=PAr

PPh,

But (193)Ar:2,L, 6 -But3C,HZ

(194) Ar = M e s i t y l

(195)

L

(196) R = Ph C,H,, , or M e s i t y l

(197) Ar= MesityL R = C,Hn or Mesityl

R,N

RP=M(CO),

Me

Ph

(2021

(203 1

Ph

Ph (205)

Ph

(1 9 8 )

-P

+

-X

II

Ph

(206)

AICI,

0

I207 1

-

I : Phosphines and Phosphonium Salts phosphide complexes.

An X - r a y

33 s t r u c t u r a l study of t h e complexes

( 1 9 7 ) r e v e a l s t h e p r e s e n c e of o n l y one s t e r e o c h e m i c a l l y a c t i v e lone p a i r a t phosphorus, implying t h e e x i s t e n c e of a phosphorusboron d o u b l e bond.304

More t r a d i t i o n a l a p p r o a c h e s t o t h e s y n t h e s i s of phosphaborenes have r e s u l t e d i n t h e i s o l a t i o n of t h e r e l a t e d d i m e r s ( 1 9 8 ) ,305s306 w h i c h , o n t h e e v i d e n c e of mass s p e c t r o m e t r y , a p p e a r t o g e n e r a t e t h e p h o s p h a b o r e n e s i n t h e gas p h a s e . 306 I n t e r e s t h a s a l s o continued in t h e s y n t h e s i s and c h a r a c t e r i s a t i o n o f t h e h 3 - t h i o x o p h o s p h e n e s y s t e m RP=S,307-309 a n d t h e r e l a t e d s e l e n i u m s y s t e m . 309 A k i n e t i c s t u d y o f t h e t h i a t i o n o f c a r b o n y l compounds b y L a w e s s o n ' s reagent h a s i n d i c a t e d t h e i n t e r m e d i a c y o f t h e t h r e e c o o r d i n a t e d i t h i o x o p h o s p h o r a n e (199).310

There has

a l s o b e e n c o n s i d e r a b l e e f f o r t d i r e c t e d t o w a r d s t h e s y n t h e s i s o f new

X3-RP=NR s y s t e m s , 3 1 1 - 3 1 5

and s t u d i e s o f t h e i r r e a c t i v i t y and

c o o r d i n a t i o n c h e m i s t r y . 316-318

of t r a n s i e n t As-phosphonitriles,

Further evidence for t h e formation R,P-N,

from t h e p y r o l y s i s of

a z i d o p h o s p h i n e s h a s b e e n a d d u c e d . 19-321 The d e v e l o p i n g area o f p h o s p h i n i d e n e c h e m i s t r y h a s b e e n

c o n s i d e r e d i n s e v e r a l r e v i e w s .322-324

Of p a r t i c u l a r i n t e r e s t are

t h e t e r m i n a l p h o s p h i n i d e n e c o m p l e x e s (200) w h i c h a r e e a s i l y accessible & v

t h e t h e r m a l d e c o m p o s i t i o n of r e l a t e d 7 - p h o s p h a n o r -

bornadiene complexes.

However, t h e f r e e p h o s p h i n i d e n e s , RP:, are

poorly characterised, i n s p i t e of t h e i r probable i n t r i n s i c l o w r e a c t i v i t y . 3 2 4 The r e a c t i v i t y o f t h e v a r i o u s t y p e s o f p h o s p h i n i d e n e complexes

h a s c o n t i n u e d t o r e c e i v e a t t e n t i o n .325-329

Similarly,

t h e c h e m i s t r y o f p h o s p h e n i u m i o n s , R,P+, c o n t i n u e s t o d e v e l o p .

T h e s e s p e c i e s h a v e b e e n shown t o b e f o r m e d i n t h e e l e c t r o c h e m i c a l o x i d a t i o n o f c y c l o t e t r a p h o s p h i n e s .330 A series o f new p h o s p h e n i u m

s a l t s (201) h a s b e e n p r e p a r e d b y t h e r e a c t i o n of ( 2 0 1 ; X = Cl) w i t h v a r i o u s t r i m e t h y l s i l y l d e r i v a t i v e s . 331 F u r t h e r examples o f

t h e r e a c t i o n s o f phosphenium i o n s w i t h c y c l i c d i e n e s have a p p e a r e d ,

a n d o f f e r a new a p p r o a c h t o t h e s y n t h e s i s o f p h o ~ p h e t a n e s'333 .~~~

E v i d e n c e for t h e f o r m a t i o n o f t h i o p h o s p h e n i u m c a t i o n s [ ArPSArI' b e e n p r e s e n t e d . 3 34

has

34

Organophosphorus Chemistry

5 P h o s p h i r e n e s , P h o s p h o l e s and P h o s p h o r i n s The m e t h y l t r i p h o s p h i r e n e s y s t e m ( 2 0 2 ) h a s b e e n p r e p a r e d i n t h e coordination sphere of a

A convenient route t o t h e

r i n g - u n s u b s t i t u t e d p h o s p h o l e ( 2 0 3 ) i s a f f o r d e d by t h e r e a c t i o n o f d i l i t h i o ( p h e n y 1 I p h o s p h i d e w i t h t h e r e a d i l y a v a i l a b l e 1,4-

d i c h l o r o b u t a - 1 , 3 - d i e n e . 336

The r e a c t i v i t y o f t h e c o o r d i n a t e d l i t h i o p h o s p h i d e ( 2 0 4 ) , o b t a i n e d from t h e r e a c t i o n o f 3,4-dimethyl-

p h o s p h o l y l l i t h i u m w i t h t u n g s t e n h e x a c a r b o n y l , h a s been e x p l o r e d ? 3 7 The e a s i l y - a c c e s s i b l e b i s ( p h o s p h o 1 e n e ) ( 2 0 5 ) h a s b e e n c o n v e r t e d i n t o t h e r e l a t e d b i s ( p h o s p h o 1 e ) ( 2 0 6 ) by s u c c e s s i v e b r o m i n a t i o n 338 Isophosphindoles, e g . , ( 20 7 ) , h a v e b e e n o b t a i n e d f r o m t h e r e a c t i o n s o f tris(trimethylsily1)phosphine

.

and dehydrobrornination.

with unsaturated d i ( a c i d c h l o r i d e s ) .

In the reaction with

p h t h a l o y l c h l o r i d e , t h e r e l a t e d i s o p h o s p h i n d o l e dimer is isolated.339

F u r t h e r r e p o r t s of t h e s y n t h e s i s o f h i g h l y -

s u b s t i t u t e d d i b e n z o p h o s p h o l e s y s t e m s h a v e a p p e a r e d . 340 '341

addition of t h e 1,4-dithiolium-4-olates

Cyclo-

( 2 0 8 ) w i t h t h e phospha-

a l k e n e ( 1 6 2 ) g i v e s a n i n i t i a l a d d u c t which t h e n u n d e r g o e s e l i m i n a t i o n t o form t h e 1 , 3 X 3 - t h i a p h o s p h o l e s ( 2 0 9 ) . 342 1,2,4-thiadiphosphole

The s t a b l e

( 2 1 0 ) h a s b e e n i s o l a t e d as a y e l l o w ,

d i s t i l l a b l e l i q u i d from t h e r e a c t i o n o f l i t h i u m b i s ( t r i m e t h y 1 s i l y l ) p h o s p h i d e , carbon d i s u l p h i d e and t r i m e t h y l s i l y l c h l o r i d e a t

-78°C.343

P h o s p h o l y l a n i o n s h a v e b e e n e m p l o y e d i n new s y n t h e t i c

a p p r o a c h e s t o m o n o p h o s p h a f e r r o c e n e s ,344 ' 345 , e.g.,

(211).344

The

c h e m i s t r y of s u c h s y s t e m s , a n d t h e r e l a t e d d i p h o s p h a f e r r o c e n e s , h a s c o n t i n u e d t o a t t r a c t i n t e r e s t , and s t u d i e s hav e b e en r e p o r t e d o f

t h e i r o x i d a t i o n , 3 4 6 p r o t o n a t i o n ,347-349 c o m p l e x f o r m a t i o n , 3 5 0 a n d electrophilic substitution

The p o l y p h o s p h a -

f e r r o c e n e (212) is r e p o r t e d t o be a i r - s t a b l e , d e c o m p o s i t i o n when h e a t e d t o 2

7

0

~

~

.

s u f f e r i n g only s l i g h t ~

~

~

The c h e m i s t r y o f a z a p h o s p h o l e s y s t e m s a l s o c o n t i n u e s t o d e v e l o p . F l a s h vacuum p y r o l y s i s o f t h e 1 , 3 - a z a p h o s p h o l i n e s ( 2 1 3 ) ( f o r which' s e v e r a l p r e p a r a t i v e r o u t e s a r e a v a i l a b l e )354 g i v e s r i s e t o t h e lH-l,3-azaphospholes ( 2 1 4 ) , a new h e t e r o a r o m a t i c s y s t e m . 355 An a l t e r n a t i v e approach t o 1,3-azaphospholes

is a f f o r d e d by t h e

r e a c t i o n s of o x a z o l i u m s a l t s (and r e l a t e d b e t a i n e s ) w i t h t r i s The a n a l o g o u s reactions o f ( t r i m e t h y l s i l y l I p h o s p h i n e . 356-358

o x a d i a z o l i u m s a l t s p r o v i d e a new r o u t e t o 1 , 2 , 4 - d i a z a p h o s p h o l e s ( 2 1 5 ) . 3 5 8 9 3 5 9 The r e a c t i o n s o f 1 , 2 , 4 - d i a z a p h o s p h o l e s ( 2 1 5 ;

R1 = H ) a n d r e l a t e d 1 , 2 , 3 - d i a z a p h o s p h o l e s w i t h b u t y l l i t h i u m h a v e

35

I : Phosphines and Phosphonium Sulrs

0R k $S A r (2091

(2081 R = Me, Ph or NR

-+

Fe

I

2M eN2H C@ )

(212 1

(2111

c

(2101

( 2 1 3 ) R' , R: H , a l k y l or Ph

phQph

N5 R H

RL

(214) R = H , a l k y l or Ph

Ph

( 2 1 5 ) R1=H or Me 2 R = M e or E t

6

Ar

mQ9 Ar

;i's

Ph

(219 1

( 217 1

CN ' AI

pdAr

(220)

Me

RN,p

Ph

S

Ar

(2161

R

APPh2

H R " Yp"/N O

NH,

( 2 2 1 ) R = H a l k y l or P h

Ph2 (222)

36

Organophosphorus Chemistry

been compared, the former undergoing ring-metallation at the 5-position and the latter undergoing addition to the P=C bond.360 Various cycloaddition reactions of 1,2,3-diazaphospholes have also been i n ~ e s t i g a t e d . ~ ~ l Further - ~ ~ ~ work has been reported on the chemistry of the 1 , 3 , 2 - d i a ~ a p h o s p h o l eand ~ ~ ~ lY2,4,3-triazaphosp h 0 1 e ~systems. ~~ Three new valence-isomers of the h3-phosphorin system have been characterised. 366 A study of the reactions of X3-phosphorins, e.g., (216), with diazoalkanes has shown that these compounds behave in a totally different way to other P=C systems in that they do not undergo cycloaddition reactions, but instead give rise to products (the nature of which depends on the solvent) which arise by attack at phosphorus.367 Thermal decomposition of certain bicyclic phosphins sulphides, e.g., (217), in toluene or benzene provides a route for the synthesis of the elusive phosphorin-1-sulphide system (218), which can be trapped with dienophiles to give phosphabarallene derivatives, and also react with nucleophiles at The first synthesis of 1,2-dihydro-1,2X3-azaphosphorins (219) has been achieved in the reactions of simple imines with dichlorophenylphosphine 370 A route to the triaryl-1,3X3-azaphosphorins (220) is provided by the reactions of 3-azapyrylium salts with tris(trimethylsily1)phosphine. On treatment with acetylenic esters, these compounds give a Diels-Alder adduct which eliminates a nitrile with the formation of a X3-phosphorin. 371 The reactions of the B-enaminophosphines (221) with ethyl azidoformate give intermediate phosphazenes which, on heating to 150°C, undergo cyclisation to form the first examples (222) of the 1,3,4-diaza-X5-phosphorin system. 372

.

References 1 2 3 4 5 6

7 8 9 10

M.Hackett and G.M.Whitesides, Organometallics, 1987, 6 , 403. H.Brunner and H-Leyerer, Bull. Soc. Chim. Belq., 1987, 96, 353. H.P.Abicht, H.Schmidt, and K.Issleib, Z.Chem., 1985, 25, 410. K.Jurkschat and H.P.Abicht, Z.Chem., 1985, 25, 338. A.Benefie1 and D.M.Roundhil1, Inorg. Chem., 1986, 2,4027. L.I.Zakharkin, A.V.Kazantsev, and M.G.Meiramov, Koord. Khim., 1985, fi,1084 (Chem. JLbstr., 1986, 105,42 929). T.Fuchigami,C.S.Chen, T.Nonaka, M.Y.Yeh, and H.J.Tien, Bull. Chem. Soc. 1986, 2, 483. S-E.Bouaoud, P.Braunstein, D.Grandjean, D.Matt, and D.Nobe1, Inorg. Chem., 1986, 25, 3765. E.Hey, L.M.Engelhardt, C.L.Raston, and A.H.White, Angew. Chem., Int. Ed. Engl., 1987, 2, 81. R . E . W v e y , K.Wade, D.R.Armstrong, G.T.Walker, R.Snaith, W.Cleqg and D.Reed, Polyhedron, 1987, 5 , 987.

s,

1 : Phosphines and Phosphnnium Salts 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30

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37

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.

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I : Phosphines and Phosphonium Salts

240 241

43

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2 96 2 97 298

2 99 300 301 302 303 304 305 306 307

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M.Andrianarison, C.Couret, J.-P-Derclercq, A.Duborg, J.Escudie, and J. Satge, J. Chem. Soc., Chem. Commun., 1987, 921. X.Feng, M.M.Olmstead, and P.P.Power, -Inorg. Chem., 1986, 4616. R.A.Bartlett, X.Feng, and P.P.Power, J.Am. Chem. Soc., 1986, 108,6817. P.Kolle, H.Nbth, and R.T.Paine, Chem. Ber., 1986, 119,2681. A.M.Arif, J.E.Boggs, A.H.Cowley, J.<.Lee, M.Pakulski and J.M.Power, J.Am. Chem. SOC., 1986, 108,6083. E.Lindner, K.Auch, G.A.Weiss, W-Hiller, and R.Fawzi, Chem. Ber., 1986, 119,

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.

I : Phosphines and Phosphonium Salts

45

314 U.Dressler, E.Niecke, S.Poh1, W-Saak, W.W.Schoeller, and H.-G.Schafer, J.Chem. SOC., Chem. Comun. , 1986, 1086. 315 E.Niecke, D.Gudat, and E.Symalla, Angew. Chem., Int. Ed. Engl. , 1986, 25, 834. 316 P-B-Hitchcock,M.F.Lappert, A.K.Rai, and H.D.Williams, J.Chem. SOC., Chem. Commun., 1986, 1633. 317 P.B.Hitchcock, H.A.Jasim, M.F.Lappert and H.D.Williams, J.Chem. SOC., Chem. Comun., 1986, 1634. 318 O.J.Scherer, K.GObe1, and J.Kaub, Angew. Chem., Int. Ed. Engl., 1987, 26, 59* 319 J.-P.Majora1, G.Bertrand, A.Baceiredo, and E.O.Mavarez, Phosphorus S u l f u r , 1986, 2, 75. 320 J.Boske, E.Niecke, E.Ocando-Mavarez, J.-P-Majoral,and G-Bertrand, Inorg. Chem., 1986, 3, 2695. 321 J.P.Majora1, G.Bertrand, E.Ocando-Mavarez, and A-Baceiredo,Bull. SOC. Chim. Belg., 1986, 95, 945. 322 G.Huttner and K.Evertz, Acc. Chem. Res., 1986, 19,406. 323 G.Huttner, Pure Appl. Chem., 1986, 585. 324 F.Mathey, Angew. Chem., Int. Ed. Engl., 1987, 26, 275. 325 N.H.T.Huy and F.Mathey, Organometallics, 1987, 6 , 207. 326 N.H.T.Huy, J.Fischer, and F.Mathey, J.Am. Chem. SOC., 1987, 109, 3475. 327 A.M.Arif, A.H.Cowley, M.Pakulski, N.C.Norman and A.G.Orpen, Organometallics, 1987, 6 , 189. 328 A.M.Arif, A.H.Cowley, M.Pakulski, and G.J.Thomas, Polyhedron, 1986, 2, 1651. 329 G.Huttner, J.Organomet. Chem., 1986, 3 2 , C11. 330 H. -G;.Schafer , W. W.Schoeller, J-Niemann, W.Haug , T.Dabisch and E-Niecke, J.Am. Chem. Soc., 1986, 108,7481. 331 M.R.Mazieres, C.Roques, M.Sanchez, J.P.Majora1 and R-Wolf, Tetrahedron, 1987, 3, 2109. 332 S.A. Weissman, S.G .Baxter, A.M.Arif and A.H .Cowley, J .Chem. SOC - , Chem. Comun., 1986, 1081. 333 S.A.Weissman and S.G.Baxter, Tetrahedron Lett., 1987, 28, 603. 334 E.Lindner and G.A.Weiss, Chem. Ber., 1986, 119,3208. 335 G.Capozzi, L.Chiti, M.Di V d r a , M.Peruzzini, and P.Stoppioni, J.Chem. Soc., Chem. Comun., 1986, 1799. 336 A.J.Ashe 111, S.Mahmoud, C.Elschenbroich, and M.W&isch, Angew. Chem., Int. Ed. Engl., 1987, 26, 229. 337 S.Holand, F.Mathey, and J.Fischer, Polyhedron, 1986, 5 , 1413. 338 F.Mercier, S.Holand and F-Mathey, J.Organomet. Chem., 1986, 316, 271. 339 R.Appe1, C.Casser, F.Knoch and B.Niemann, Chem. Ber., 1986, 119,2915. 340 Sir J-Cornforth and A.D.Robertson, J.Chem. SOC., Perkin Trans 1, 1987, 867. 341 Sir J-Cornforth,L.M.Huguenin and J.R.H.Wilson, J.Chem. SOC., Perkin Trans. -1, 1987, 871. 342 G.Mkk1, E.Eck1, U.Jakobi, M.L.Ziegler, and B.Nuber, Tetrahedron Lett., 1987, 28, 2119. 343 R.Appe1 and R.MOors, Angew. Chem., Int. Ed. Engl., 1986, 25, 567. 344 R.M.G. Roberts and A.S.Wells, Inorg. Chim. Acta, 1986, 120. 53. 345 E.Roman, A.M.Leiva, M.A.Casasempere, C.Charrier, F.Mathey, M.T.Garland and J.Y. Le Marouille, J.Organomet. Chem., 1986, 309, 323. 346 R.M.G.Roberts, J.Silver and A.S.Wells, Inorg. Chim. Acta, 1987, 126. 61. 347 R.M.G.Roberts, J.Silver and A.S.Wells, Inorg. Chim. Acta, 1986, 118, 135. 348 R.M.G.Roberts, J-Silver and A.S.Wells, Imrg. Chim. Acta, 1986, 119, 1 . 349 R.M.G.Roberts, J.Silver and A.S.Wells, Inorg. Chim. Acta, 1986, 119, 171. 350 R.M.G.Roberts, J.Silver and A.S.Wells, Inorg. Chim. Acta, 1986, 119, 165. 351 R.M.G.Roberts, and A.S.Wells, I n Q K g . Chim. Acta, 1987, 126, 67. 352 R.M.G.Roberts, and A.S.Wells, Imrg. C h i m . Actr, 1987, *, 93. 353 0.J.Scherer and T.BrUck, Angew. Chem., X n t . Ed. Engl., 1987, 26, 59. 354 J.Heinicke and A.Tzschach, Z.Chem., 1986, 407. 355 J.Heinicke, Tetrahedron Lett. , 1986, 2, 56%. 356 G.Mbi-kl and G . I t r a h e d r o n Lett., 1986, 27, 4419.

z,

~~

46

Organophosphorus Chemistry

357 358 359 360

G.Mark1 and G.Dorfmeister, Tetrahedron Lett., 1987, 28, 1089. G.M&kl and S.Pflaum, Tetrahedron Lett., 1987, 28, 1511. G.&rkl and S.Pflaum, Tetrahedron Lett., 1986, 4415. S.Kersch1, B-Wrackmeyer,A.Willhalm, and A.Schmidpeter, J.Organomet. Chem.,

36 1

B.A.Arbuzov, E.N.Dianova, R.T.Galiaskarova, and A-Schmidpeter,Chem. Ber.,

362 36 3 364

El

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365

M.

a,

Pentaco-ordinated and Hexaco-ordinated Compounds BY C . 1.

D. HALL

Introduction. - The year has elapsed with a significant decline

in the number of publications in the area of hypervalent phosphorus chemistry and with the emphasis still focussed on monocyclic and bicyclic phosphoranes containing small (four or five-membered) rings. The proceedings of the International Conference on Phosphorus Chemistry (Bonn, 1986) however, contain numerous articles dealing 1 with pentaco-ordinate and hexaco-ordinate phosphorus compounds which suggests that a healthy world-wide interest in the topic is being maintained. Furthermore, the principles established in hypervalent phosphorus chemistry continue to be applied to the chemistry of hyDervalent molecules of other elements with a notable contribution from Corriu on comparison of factors controlling nucleophilic substitutions at silicon and phosphorus2 and from Barton et al. on the utility of pentavalent organobismuth reagents. In the former paper Corriu concludes that retention or inversion during nucleophilic substitution at silicon is controlled b y a frontier orbital process and that the same conclusion can be extended to the mechanism of nucleophilic substitution at halogenophosphorus compounds. Thus the kinetic data show that the interaction between an incoming nucleophile and the leaving group is very deep when they are both apical (inversion) whereas the influence of the nucleophile is minimal when it effects a 9 0 " angle to the leaving group,

=.

gives rise to retention. This concept is used to rationalize the similarities in kinetics and stereochemistry of the displacement of halogen from phosphorus and silicon and leads to the suggestion that it is not possible to extend the Westheimer hypothesis o n the hydrolysis of phosphates and ~ h o s p h o n a t e s ~ to the general case of nucleophilic displacement at P-X bonds. 2. Structure, Bonding and Ligand Reorganization. - In a paper dealing with the synthesis and structure of new ring systems derived from elements of main groups I V (Si, Ge and Sn) and V (As and Sb) structures ranging between the ideal geometries of tbp and rp were

reported.

Thus a series of symmetrically substituted phenyl-

arsoranes (1-4) showed a structural displacement from tbp to rp in 47

48

Organophosphorus Chemistry

't

0

0

I /O Ph-As

I /O Ph-As

9

( 1 ) 18'/.RP

Sb

PhPh

(R,),PF, (9)

R,= C2F5,C,F,

t

0-35' C

ArLi

(R,l,ArPF,

H20

( RF)2ArP=0

(11 1

(10)

(12)

A r = P h , p- to1

+-

t -

( PhO ),PPC I,

( 13)

8,'

P,-22.6,

- 29.6

(PhO 1,P CI (1L) &3'P, - 2 2 . 7

49

2: Pentaco-ordinated and Hexaco-ordinated Compounds

line with reduced electron pair repulsions between the ring oxygen atoms, effected by delocalization of the lone pairs into the aromatic rings.6 In the case of compounds of antimony, recent work has shown that a rectangular pyramid devoid of lattice effects is

stabilized in the same way as other main group elements by forming a bicyclic system composed of two unsaturated rings containing like

donor atoms in any one ring. For example, X-ray analysis of stiborane (5) revealed a tbp structure whereas the bicyclic compound Thus the unique sp geometry of PhsSb may be (6) had r p geometry.' more firmly ascribed to lattice stabilization with antimony in general falling into the established pattern for Group V elements. The apicophilicity of the 2,2,3,3-tetrafluoropropoxy group has been shown to exceed that of the cyano group on the basis of variable temperature 1 3 C and I9F n.m.r. of the acyclic; phosphorane

(7).8 At low temperature the molecule has a tbp structure with the two cyano groups equatorial and two sets of non-equivalent fluoroalkoxy groups in the ratio of 2:l.

3. Acyclic Phosphoranes. - The structures of the chlorofluorophosphoranes, PClnF5-n - - (8)with 2 = 1-4 have been determined by electron diffraction in the gas phase.' Both P-F and P-C1 bonds were found to lengthen as 11 increased (k. with an increasing ratio of Cl/F substituents) and this effect was more pronounced for the apical bonds relative to the equatorial bonds (Table 1). Angular distortions from the tbp geometry were small (1-2") in all cases. Table 1 Bond lengths (prn) Bond PFeq. PFap. "leq. PCla

PF 5 153.4 157.7

-

-

C~PFI,

C12PF3

C13PF2

C14PF

Cl5P

153.5 158.1 200.0

153.8

-

-

-

159.6

159.7

-

-

159.3 200.2

-

200.6

-

201.1 210.7

202.3 212.7

Tris-(perfluoroalky1)-bis-difluorophosphoranes (9) have been found to react with aryl lithiums (10) to give (11) with displacement of a perfluoroalkyl group rather than the expected displacement of Hydrolysis of (11) with the calculated amount of water fluorine.'' gives the corresponding phosphine oxides (12). The reaction of PC15 with phenol has been re-examined using molar ratios from 1 : l to 5:l (PhOII : PC15). Under the former conditions

Organophosphorus Chemistry

50

( E t0l2PPh3

(171, S 3 ' p ,

(15)

- 38.2

(191

4

(EtO),PPh, (15)

+

+

Ph3POEt

Sc CH ),OH

(221

1 4 -1

2: Pentaco-ordinated and Hexaco-ordinated Compounds

51

tetraphenoxyphosphonium hexachlorophosphate (13) was formed whereas at 4:l and 5:l the product was exclusively the phosphonium chloride 11 (14). The cyclodehydration of diols by diethoxytriphenylphosphorane (15) has been extended to 1,2,4-triols (e.g. - 16) affording thermodynamitally stable monocyclic phosphoranes (e.g. 17 and 18) which thermolyse v i a extrusion of phosphine oxide to form a mixture of the epoxide (19, 81%) and 3-hydroxy-tetrahydrofuran (20, 19%). 12 The reactions of (15) with a range of mercaptoethanols (21) give mixtures of cyclic sulphides (23) and hydroxyalkyl ethyl sulphides ( 2 4 ) and the ratio of products is influenced substantially by temperature. l3 Low temperature (-25°C) favours cyclisation v i a the oxythiophosphoranes (22) as illustrated by Table 2.

Temp : - 2 5 ° C

Temp : ambient

n

%(23)

%( 24 )

n

%(23)

2

28

72 50 35

2

63 40 >99 35

3 4

50

5

65

63

37

3 4 5

w( 24) 37 trace >1 30

Finally in this section the mechanism of formation of acyclic phosphoranes (28) from the corresponding trico-ordinate phosphorus compounds (25) and sulphenate esters (26) has been reported in a preliminary form from which it is clear that oxythiophosphoranes (27) 14 are intermediates in the reaction. 4.

Ring Containing Phosphoranes

- The ability of trifluoromethyl groups to stabilise pentaco-ordinate structures emerges once again in the reactions of P-haloylides (29) with carbonyl compounds (30). The reactions are (2+2], non-concerted but stereoselective cycloadditions which lead t o the formation of 2-halo-1,2-A5-oxaphosphetanes On heating these compounds are converted to vinylphosphine oxides (33) v i u the chloroalkylphosphine oxides (32). A s the electron accepting power of,the substituents on the CI, atom decreases, the stabilities of (31) decrease and they are readily rearranged into (32). The hydrolysis of (31) gives 2-hydroxyalkylphosphine oxides (34) and the chlorine is readily replaced by

4 . 1 Monocyclic Phosphoranes.

Organophosphorus Chemistry

52

0

R1R211P

CR3=C(CF3)RL (331

o -C(CF, I

0

)R

>160°

------+

R’R2h-CHR3

I

II

R’R+-CH-C(CF,

I,

I

R”

CI

)RL

CI

(311

R’=But;

R2=Et,N

or But ; R3= H or Me ; RL=CF3 or Ar

(311

I

OR

;Ch?

R P-0

d R,P=CH R ’

k5

1-2

R

R

I351

+

R ,PO

(36)

+ R2CH=0 kg

(371

R = Ph or 6””; R’= Pr” ; R 2 = P h , Pen or But

R’ # R 2

t

R,PO

2: Pentaco-ordinuted und Hexaco-ordinared Conipounds

x=p/D3 To

( EtO ),P=X

0

(bOa,b)(a)X=O (bl X= S

2 OH-

*p-0

_____+

-0 1 '

ti'

- O 7

_____)

'0-

LOR

L

'P-0

I

OH

O 'R ILL)

(L3 1

Ph'

-0\/O

OH

54

Organophosphorus Chemistry

methoxy or phenoxy groups on reaction with methanol or phenol in the presence of triethylamine to form (35). The topic of oxaphosphetan chemistry is of course central t o t h e elegant work of Maryanoff et al. on the mechanism of the Wittig reaction. This continues with the observation of diastereomeric 1,2-oxaphosphetanes (36) and ( 3 7 ) by high field variable temperature n.m.r. and in a number of instances the reaction of non-stabilised phosphorus ylides with aldehydes showed a non-correspondence between the relative proportions of c i s - and trans-oxaphosphetanes at low temperature and the final proportion of 5 and Ealkenes resulting in an exaggerated production of _E-alkene by a phenomenon termed "stereochemical drift". l6 Hence there is a measure of thermodynamic control in these reactions. Analogous experiments designed to evaluate the reactions of semi-stabilised and stabilised ylides did not generate key information since the intermediates (oxaphosphetanes or betaines) could not be observed thus making it impossible to frame mechanistic conclusions. It follows that the determination of E/Z alkene ratios alone in the Wittig reaction cannot yield a sound mechanistic picture since one cannot tell unambiguously whether the reaction is under kinetic or thermodynamic control. The debate on the subject of stereoelectronic effects on the hydrolysis of phosphates, phosphonates and phosphinates is maintained with three papers from Gorenstein et al. in which pentaco-ordinate phosphorus compounds feature as intermediates. In the first ,17 the results of hydrolysis reactions suggest that the reactivity differences between the bicyclic phosphate (38a) and the phosphorothionate (38b) and their acyclic counterparts (39ab) can be accounted f o r by stereoelectronic (trans-antiperiplanar) effects in the intermediates (40ab) and the results of structural investigations are consistent with the stereospecificity observed in the hydrolysis of (40b). Subsequently, a reinvestigation of the product distribution during the hydrolysis of ethyl and methyl ethylene phosphates (42) confirmed earlier suggestions by Gorenstein that the stereoelectronic effect i s an important factor (uia 43) in the rate enhancements observed for these reactions.18 With (42a) the increase in the exocyclic cleavage product (MeOH) with increasing base strength was shown to be due to an artifactual side reaction involving the hydrolysis product (44) and a second molecule of (42). This appears t o invalidate the argument of Kluger and Thatcher" that the increasing amount of exocyclic cleavage with base strength is inconsistent with a stereoelectronic effect. More positive support for the contributions of stereoelectronic effects comes however, from a study of the

2: Pentaco-ordinated and Hexaco-ordinated Compounds

55

MeMMe 0

0

5T

________)

R'O (51a , b ) (diastereomeric mixture)

(52)

6 31 P I - 45.5 (CD3COCD3) 6 ' P , -43.0(CD3SOCD3)

T = thymidin -1-yl

R =t r i t y l R'= acetyl

a0-siMe3 R

NHSi Me3

t 551

H

H

(571

f

\

R = F , M e ,Ph or

1 - adamantyl

H (56)

Me

Me

I

- S'Me3 o=c \ /N

N-

I

Me

SiMc3

I591

I

+

N ~""33~~2

(58)

O=C(

>PBun3 N

I

Me

(60)

+

Me3SiF

56

Organophosphorus Chemistry

rates of base-catalysed hydrolysis of (45) and (46) relative to

their acyclic counterparts (47) and (48).20

The cyclic ester (45) hydrolyses 6.2 x l o 3 times faster than (47) corresponding to a free energy of activation difference ( 6 h G ' ) of 5.2 kcal mol-I) which provides a good estimate of ring strain in the cyclic esters. On the other hand, (46) hydrolyses 1.5 x l o 6 times faster than (48) corresponding to, 6AG' = 8.4 kcal mol-' (35.1 kJ mol-I). It is proposed that the latter value is derived from a ring strain effect (-5.2 kcal mol-') a n d a stereoelectronic effect (-3.2 kcal mol-')

which is available to (46) v i a (49) but not to ( 4 5 ) v i a (50). The synthesis of the first dinucleotide with pentaco-ordinated phosphorus as the internucleoside linkage (52) has been described21 and 3 1 P n.m.r. reveals that rapid stereomutation occurs through pseudorotation which requires the dioxaphospholene ring to become

diequatorial during the interchange. Monocyclic phosphoranes (53) do not show inhibition of pseudorotation even at -93°C. This shows that the steric effects of substituents on the benzene ring is not the only factor involved in the inhibition and it seems that the incorporation of a rigid ring system in the pentaoxyphosphorane structure (as in 54) is an important requisite to slow pseudorotation in these systems. 22 The synthetic utility of the N,c-bis-(trimethylsilyl) derivative of o-aminophenol (55) has been clearly demonstrated in the prepara-

tion of a number of monocyclic (e.g. 56) and bicyclic (57) phosphoranes. 23 The spirophosphoranes (57) also result from a spontaneous disproportionation of (56). The same paper also describes the reaction of tri-n-butyldifluorophosphorane (58) with -N,N-'-dimethyl-N,N_'-bis-trimethylsilyl urea (59) to form (60). The synthesis and chemistry of vinylphosphoranes has been thoroughly explored as reported in a comprehensive paper by Labaiudiniere and Burgada.24 On heating (usually at 160°C) aryloxy-

vinylphosphoranes (61) evolve into a mixture of spirophosphoranes (62ab), cyclic phosphate ester (63) and the novel vinyl phosphonate (64). The yield of the spirophosphoranes and the reaction time both decrease as the electron withdrawing capacity of Z increases and with highly electron withdrawing substituents (e.g. - p-NO2) the vinyl phosphonate (64) becomes the major product. Furthermore when the carboxylate group a to phosphorus is replaced by H or Ph, no spirophosphorane (62) is obtained. The hydrolysis of ( 6 2 ) is also reported and under mild conditions leads to (65) and eventually (66). The vinylphosphoranes are prepared by the reaction of cyclic

2: Pentaco-ordinated and Hexaco-ordinated Compounds

57

n

161)

(62a 1

+

Z

L

go;P-OMe

+

Mc02CC=CC02Me

0

(69)

ArOH

(61 1

(E

- form)

168)

(67)

(Et0)2PCIPh)=CHBr

-

+

2PhCOCN (70)

0 OC

____) Ph H

Ph (71) 6

31P,-11.4

58

Organophosphorus Chemistry

PhP(OMe12 ( 72 1

+

(68) L

CO, Me (75)

2: Pentuco-ordinated cind Hexaco-ordinutrd Compounds

59

phosphites (67) with dimethylacetylene dicarboxylate (68) in the presence of the appropriate phenol. Monocyclic vinylphosphoranes (71) may also be obtained through

the reaction of vinylphosphonites (69) with benzoyl cyanide (70). 2 5 There was no mention of c i s o r trans isomerism in the ring system and only one high field 3 1 P n.m.r. signal was reported. On the other hand, the reaction of dialkyl phosphonites (72) with

(68) in the absence of a proton source proceeded u i a (73) and (74) to f o r m (75).26 The pentaco-ordinate structure (74) was sufficiently stable at-70°C to enable its conversion to the 0x0-phosphole (76) by treatment with H B r . 4.2 Bicyclic and Tricyclic Phosphoranes. - The previously unknown tricyclic phosphoranes (80) have been prepared by the reaction of

phosphorodichloridites (77) with 2-hydroxyacetophenone (78). 27 The reactions proceed v i a the bis-(o-acetylpheny1)phosphites (79) which cyclise gradually into the tricyclic phosphoranes in the rate sequence, R = Ph > > Et2N EtO > PhO which is thought to indicate initial nucleophilic attack by trico-ordinate phosphorus on the carbonyl carbon of (79). The stability of spirophosphoranes with an exocyclic P-P bond (83) depends upon the electronic nature of the substituents, X , in the aromatic ring of the imino group.28

Electron donating substi-

tuents (e.g. - X = Me) promote rearrangement to the P-N compound (84) whereas for X = p - N O , , the P-P bond is stable for several months. A special case is found for X = rn-CF3 in which ( 8 3 ) rearranges into a mixture of (84) and (85). Spirophosphoranes (86) with a P-H bond react with ally1 or aryl isothiocyanates (87) to form a range of imidothiazolidines (91)

together with the phosphoramidate (92). The mechanism proposed for this reaction involves addition to the C=N bond of (87) to form (88) followed by rearrangement through ( 8 9 ) to (90) which subsequently fragments to (91) and (9~1.~' Phosphatranes as stabilising structures f o r hypervalent phosphorus compounds is an area which continues to attract attention. For example, 'H, 1 3 C and 3 1 P n.m.r, data reveal the existence of pentaco-ordinate phosphorus mono- and divalent cations, (93) and In a comprehensive paper dealing with the ( 9 4 ) respectively.30 synthesis, structure and chemistry of 10-Pn-3 systems (95a) - in equilibrium with (95b)

-

reactions with alcohols, a-dicarbonyl

compounds, halogens, transition metals, protic acids and acetylenes

Organophosphorus Chemistry

60

-+I

R2

I

I

R'

R'

R2

R + R 'Y'

(931 Y = O o r

&o

$/A*

I

N-Pn.

R

S

(94)Y = O ; R = H , E t Y 2 S ; R - H ,Me,Et 4

0.

f--

-Pn"

4@2 "N

R

(95a)

P n = Pnictogcn I P, A s , S b l ( 9 S b ) R = B u t , P h or 1 - a d a m a n t y l

% (95a) Pn=P R = But

i- CF,CSCCF, (96)

\ -78

*C

(y'

(98)

2: Pentaco-ordinared and Hexaco-ordinared Compounds

(a 1 X = NMe (blX=S

1103 1

(c)X=O

Me

L

OSi Me,But

+

T5CpM(CO$X (107) M=Fe, X = C l ,Br M:Ru,X: C I

(106)

61

THF RT

A

CI

+

l+

62

Organophosphorus Chemistry

are described. 31 In general the arsenic and antimony systems behavc-) similarly but offer different chemistry to that of the 10-P-3 systems. Among the unusual observations is an interesting C-C bond forming reaction with hexafluorobutyne (96) to form (98) Y ~ U(97)

with Pn = P. With Pn = Sb however, the reaction proceeds to give (99). Phosphorus compounds with co-ordination numbers from 2 to 6 were characterised and a trend for the 3 1 P - 1 5 N coupling constants

was observed ranging from 93.4 Hz for dico-ordination through c u . 10 Hz for pentaco-ordinate structures to <1 Hz for a s i x

co-ordinate system (100). Dibenz [c,f][1,5]azaphosphocine-12-oxides (10la-c) and (102) have been prepared and their reactions with SOC12 and ButMe2SiOTf have been examined by a combination of ' H and 3 1 P n.m.r.32 In the case of (101a) and (102) the n.m.r. data are consistent with the formation of bicyclic phosnhoranes (103-104) which contain a transannular hypervalent P-NMe bond. The bicyclic aminophosphorane (105) in its open chain form (106)

behaves both as a monodentate ligand towards n5-CpPe(CO),X (107) by disnlacement of X and as a P/N bidentate ligand by displacement of CO and X to yield the cationic derivatives (108) and (109) respectively.33 With M = Ru only the latter behaviour is observed leading to (109) with M = Ru. Both (108) and (109) could be converted to (110) which on abstraction of the N-borne proton by LiMe led to quantitative formation of the phosphoranide adducts (111).

The adduct (112) obtained from mercuric thiocyanate and hexafluoroacetone reacts withdiphenylphosphinous chloride (113) to form the bicyclic phosphorane ( 1 1 4 ) . ~ ~In the same paper the reaction of mercuric cyanide with hexafluoroacetone and (113) in the presence of triethylamine is found to give the bicyclic phosphorane (115). Both compounds were characterised by multinuclear n.m.r. and by &-ray structural analyses. The diazaphosphetidine ring system continues to attract atteQtion as exemplified by the reaction of dialkyl phosphoroisocyanatidites (116) with the trifluoroacetoacetic ester (117) which proceeds v i a the cyclic phosphinimine (118) to the dimeric diazaphosphetidine (119).35 In a related paper a range of dialkyl and diary1 phosphoroiso-

cyanatidites (120) have been shown to react with alkyl or aryl isocyanates (121) to give diazaphosphetidines (123) presumably v i a (122). 36 The compounds were characterised by analysis, mass spectra

and n.m.r. f o r which h 3 ' P values were in the region of -75 p.p.m.

2: Pentaco-ordinuted and Hexaco-ordinatud Compounds

63

Ph

i-iL

j

IllO),Y = PF6-, BPhL-

(RO1,PNCO

(116)

+

R * CHFZCF2 CH,

(lll),M=Fc,Ru

CF,COCH,CO,Et

(117)

xf (1191

\

I L

64

Organophosphorus Chemist-

2IRO),PNCO

+

2 R'NCO

(1201

I1211

0

RO OR (123 1

R z M e , E t , Ph

R'=CICH2 , BrCH, ,Me, Ph p- MeC6HL p- CIC6HL

CH2NEt2

I

Me0

(126)

CH2NEt2

(1241

6 3 ' P J- 4 0

/ 1

2

(125 1

2: Pentaco-ordinaredand Hexaco-ordinated Compounds

65

The first representative of x-phosphorylated aminals (126,

+128 p.p.m.) has been obtained in good yield ( 8 0 % ) through distillation of (124) which probably decomposes v i a rearrangement of in this section, the reaction of (127a or b ) with ( 1 2 5 1 . ~Finally ~ b3IP =

lithium-bis(trimethylsily1)amide (128) in ether at 25°C has been

shown to generate two new dispiro compounds (129ab).38 The mass spectra andX-ray analysis of these compounds are presented and discussed in considerable detail.

5. Hexaco-ordinate Phosphorus Compounds. - Ultraviolet irradiation of a mixture of o-chloranil (130), tetrachlorocatechol (131) and white phosphorus in boiling benzene gives the spirophosphorane (132)

which on treatment with triethylamine gives the corresponding phosphorate (133) in 76% yield.39 The reaction is general but the yields of phosphorate are strongly dependent upon the substituents in the quinone and catechol rings. Thus with 3,6-di-t-butyl-orthobenzoquinone and the corresponding catechol, the yield of the phosphorate

dropped to 10%. However, the synthesis of the whole range of phosphoranes (135) and phosphorates (136) was achieved by the use of

catechols (134) alone by boiling with white phosphorus in the presence of cupric chloride. The yields in this case varied from 43

t o 60%. The elegant work of Cave11 et al. has been amplified by the preparation of three neutral hexaco-ordinate phosphorus compounds 40 (139a-c) by reaction of (137a-c) with the silylcarbamate (138). The crystal and molecular structure of (139c, ft = 3 ) shows the sixcoordinate nature of the phosphorus atom and also that the unique fluorine atom lies in the plane containing F , C F 3 , the phosphorus centre and the planar carbamate ligand as illustrated in (140). Multinuclear n.m.r. was used to elucidate the structures of all three compounds and showed that they were fluxional in solution at ambient temperatures but static at moderately low temperatures. Further to this work, two series of hexaco-ordinate phosphorus compounds (141 and 142) involving the pentan-2,4-dionato (acac) ligand have been prepared and compared to the known F~,P(acac).~l A l l are stable, crystalline solids with six-coordinate geometry as demonstrated by 3 1 P and 1 9 F n.m.r. and substantiated by &ray analysis of (141, b and c). In contrast to the preceding paper, the crystal structure of (141c, 2 = 3) shows the unique fluorine atom occupies a position which is perpendicular to the central plane containing two C F 3 groups and the acac ligand. The latter is planar

66

Organophosphorus Chemistry

Me

I

F3p\/N\PF2X / N-

I

Me 1127) 1 a ) X = F

Me

I

( b l X = Me0

SiMe,

I

Me

I

+ I

Li N I S i Me3I2 (128

Me

1

I

SiMe, ( 129 a , b )

I132 1

I

Me

2: Pentaco-ordinated and Hexaco-ordinated Compounds

\ /

+ OH (13La-el ( ba )) R = 3,5-di-Bu' 3,6-di-But ( c ) R= tetra - C l

67

5

CUClz

(136)

( d ) R=G-(Phl,C-

(el R = phenylene

[

n

a

>

P

/ 2

o HO n R

'

n

-

+

5CuCl

+

5 HCI

( 1 351

(CF31,PF5-,

+

Me3SiOCNMe2

( 137a - c )

(138)

(a)n=l

(bln = 2 ( c In = 3

(1Lla-c) ( a ) n = l ; ( b I n ~ 2 ;( c I n = 3

0

II

FL-n(CF3lnPOCNMe2 (139a- c 1

Organophosphorus Chemistry

68

but folded about t h e 0-0 axis by approximately 2 7 " t.owards t h e unique fluorine.

References

1

2 3 4 5 6 7

Phosphorus Sulfur, 1987, 30, ( 1 - 4 ) . R.J.P.Corriu, Phosphorus S u Z f u r , 1986, 2 7 , 1 . D.H.R.Barton, N.Yadov-Bhatnagar, J.-P.Fzet, J.Khamsi, W.B.Motherwel1, and S.P.Stanforth, Tetrahedron, 1987, 43, 323. F.H.Westheimer, Ace. Chem. Res., 1968, 1,70. R.R.Holmes, R.O.Day, V.Chandrasekhar, S.Shafeizad, J.J.Harland, D.N.Rau, and J.M.Holmes, Phosphorus Sulfur, 1986, 2 8 , 91. R.R.Holmes, R.O.Day, and A.C.Sau, OrgZometaZlics, 1985, 714. R.R.Holmes, R.O.Day, V.Chandrasekhar and J.M.Holmes, Inorg. Chem., 1987, 6 ,

4,

157.

20 21

Yu.G.Shermolovich, N.P.Kolesnik, S.V.Iksanova, V.V.Trachevskii, and L.N.Markovskii, J . Gen. Chem. U.S.S.R. ( E n g l . t r a n s l . ) , 1986, 6, 1050. C.Macho, R.Minkwitz, J.Rohmann, B.Steger, V.Wb'lfe1, and H.Oberhammer, Inorg. Chem., 1986, 2,2828. N.V.Pavlenko, G.I.Matyushecheva, V.Ya.Semenii, and L.M.Yagupol'skii, J . Cen. Chem. U.S.S.R. (EngZ. t r a n s l . ) , 1987, 1, 99. J.Gloede and R.Waschke, Phosphoms SuzTur, 1986, 27, 341. J.W.Kelly and S.A.Evans, Jr., J . h e r . Chem. Soc.,I986, 108, 7681. P.L.Robinson, J.W.Kelly, and S.A.Evans, J r . , Phosphorus S m u r , 1987, 2,59. N.Lowther, P.E.Crook and C.D.Hal1, Phosphoms Sulfur, 1987, 3 0 , 405. O.I.Kolodyazhnyi, J . Gen. Chem. U.S.S.R., (Engl. t r a n s l . ) , 1-6, 6 , 246. B.E.Maryanoff, A.R.Reitz, M.S,Mutter, R.R.Inners, H.R.Almond Jr., R.R.Whittle, and R.A.Olofson, J. Amer. Chem. SOC., 1986, 108,7664. T.Fanni, K.Taira, D.G.Gorenstein, R.Vaidyanathaswamy, and J.G.Verkade, J . h e r . Chem. Soc., 1986, E 8 - , 631 1 . D.G.Gorenstein, A.Chang, and Ji-C.Yang, Tetrahedron, 1987, 4 3 , 469. a) R.Kluger and G.R.J.Thatcher, J . A m e r . Chem. SOC., 1985, m 7 , 6006. b) R.Kluger and G.R.J.Thatcher, J , &g. Chem., 1986, 2, 2 O r Ji-C.Yang and D.G.Gorenstein, Tetrahedron, 1987, 4 3 , 4 7 9 . L. H.Koole, H.M.Moody , and H.M. Buck, RecueiZ Trav.Chim. Pays-Bas. , 1986, 105,

22

W.M.Abdou, M.R.H.Mahran,

8 9 10

I 1 12 13 14 15 16

17 18 19

196.

R. Bartsch, J.-V.Weiss, 2 7 , 345.

23

53.

T.S.Hafez, and M.M.Sidky, Phosphorus Sulfur, 1986, and R.Schmutzler, 2. anorg. a l l g . Chem., 1986,

537,

L.Labaudiniere and R.Burgada, Tetrahedron, 1986, 42, 3521. Yu.G.Trishin, I.V.Konovalova, L.A.Burnaeva, A.F.Afanasov, V.N.Chistokletov, and A.N.Pudovik, J . Gen. Chem. U.S.S.R., (EngZ. transi!. ) , 1986, 56, 2471. 26 J.C.Caesar, D.V.Griffiths, and .J.C.Tebby, Phosphorus Sulfur, 1987, 2 9 , 123. (Engl. t r a n a . ) , 1986, 27. E.E.Korshin and F.S.Mukhametov, J . Gen. Chem. U.S.S.R.,

24

25

56, 846. S.K.Tupchienko,

T.N.Dudchenko, and A.D. Sinitsa, J . Gen. Chem. U.S.S.R. (EngL. t r a n s l . ) , 1986, 5 6 , 2228. 29 L I .Mizrakh , L YcPolonskaya , A. N Gvo zd ekskii , and A.M. Va s i 1 ' ev , J . Gen. Chem. U.S.S.R. ( E n g l . t r a n s l . ) , 1986, 56, 6 2 . 30 L.E.Carpenter 11, B.de Ruiter, D.van Aken, H.M.Buck, and J.G.Verkade, J . Amer. Chem. Soc., 1986, 4918. 31 A.J.Arduengo 111, C.A.Stewart, F.Davidson, D.A.Dixon, J.V.Becker, S.A.Culley, and M.B.Mizen, J . Amer. Chem. SOC., 1987, 109, 627. 32 Kin-ya Akiba, K.Okada, and K.Ohkata, T e t r a m r o n L e t t e r s , 1986, 2 7 , 5221. 3 3 P.Vierling, J.G.Riess, and A.Grand, Inorg. Chem., 1986, 2 5 , 4 1 4 4 7 34 H W Roesky , V W Pogat zki , K ,S Dha t ha thr eyan , A. Thie1 , H .KSchmid t , M. Dyrbu s ch , M.Noltemeyer, and G.M.Sheldrick, Chem. Ber., 1986, 119, 2687. 3 5 I. V Konovalova , L.A. Burnaeva , E G. Yarkova , N .M. K a s h z o v a , and A . N. Pudovik, J . Gen. Chem. U.S.S.R., (Engl. transl. ), 1986, 6, 1094.

28

.

.

.

5,

.. .

..

.

.

2: Pentaco-ordinared and Hexaco-ordinated Compounds 36

37 38 39 40 41

69

B.N.Kozhushko, E.B.Silina, V.V.Doroshenko, N.K.Mikhailyuchenko, and V.A.Shoko1, J. Gen. Chem. U.S.S.R., (Engl. t r m t s l . ) , 1986, 5 6 , 1555. S.A.Terent'eva, M.A.Pudovik, and A.N.Pudovik, J . Gen. Chem.T.S.S.R., (Engl. t r a n s l . ) , 1986, 56, 632. K.Utvary, K.Galle, A,Cowley, and A.Arif, Monatshefte fur Chemic., 1Y86, 117, 1245. M.I.Kabachnik, D.I.Lobanov, N.V.Matrosova, and P.V.Petrovskii, J . Gen. Chem. (Engl. t m s l . ) , 1986, 56, 1297. U.S.S.R., R.G.Cavel1 and L.V.Griend, Inorg. Chern., 1986, g,4 6 9 9 . N.Burford, D.Kennepoh1, M.Cowie, R.G.Bal1, and R.G.Cavel1, Inarg. Chem., 1987, 26, 650. -

Phosphine Oxides and Related Compounds BY B. J. WALKER 1

Introduction

In spite of the detailed studies by Warren and his co-workers, i t has not been possible to conveniently control the stereochemistry o f phosphine oxide-based olefination.

The beginnings of such control

may be forthcoming in the report31 that high stereoselectivity can be introduced in certain cases through modification o f the phosphorus substituents. 2

Preparation o f Acyclic Phosphine Oxides

Full details of reactions of Z - ( d i p h e n y l p h o s p h i n y l ) - 1 , 3 - b u t a d i e n e (2)

(generated by thermolysis of the butadiene (1)) with various

dienophiles have been rep0rted.l

The reactions provide a route to a

variety o f functionalized (1-cyclohexeny1)diphenylphosphine oxides ( 3 ) in moderate to good yields.

The ( 1 - c y c l o b u t e n y 1 ) d i p h e n y l -

phosphine oxide ( 1 ) also acts as a dienophile, forming Diels/Alder adducts (4) with cyclopentadiene (Scheme 1).

The phosphine oxide

(7). and the phosphine ( 8 ) and phosphine oxide ( 9 ) are formed

regiospecifically on basic hydrolysis o f the cyclic tetraphosphonium salts (5) and

(6).

respectively.’

The reaction of 2-butyne-1.4-diol

with chlorodiphenylphosphine. previously reported to give 2 , 3 - b i s ( d i p h e n y l p h o s p h i n y l ) - 1 , 3 - b u t a d i e n e , is now shown to give the

1.4-isomer

This is analogous to a similar reaction with

phenylsulphenyl chloride and presumably involves a double sigmatropic rearrangement (Scheme 2). disappointingly

The diene (10) is

unreactive in Diels/Alder reactions.

The mechanism

of thermal rearrangement o f phosphine (11) to the phosphine oxide 70

3: Phosphine Oxides and Related Compounds

71

iiii

eagents :

I,

Heat ; 1 1 ,

H

‘R2

Scheme 1

n

Ph2P+

+PPh2

W

( 5 ) X = CH=CH ( 6 ) X = CH2CH2

0

0

II

II

Ph2PCk$CHzPPh2

/

X = CH=C H

\

(7)

X = CH2CH2

Y

II

Y

II

PhZPCH,CH,CH2CH,PPh 2

( 8 ) Y = lone pair (9) Y = O

Organophosphorus Chemistry

72

foH

Reagene:

I ,

2 PhZPCL, p y r i d i n e , T H F , 0

OC

Scheme 2

3: Phosphine Oxides and Related Compounds

73

(13). which involves a formal nucleophilic substitution at

phosphorus, has been investigated.

Radical and intermolecular

mechanisms are ruled out by isotope studies and the authors conclude that reaction probably occurs via (12).

A

variety o f amino

acid-derived thiocarbamoylphosphine oxides (14) have been prepared by the reaction of diphenylphosphine oxide with the corresponding isothiocyanates.

The reactions of secondary phosphine oxides with

vinyl halides in the presence o f t e t r a ( t r i p h e n y 1 p h o s p h i n e ) p a l l a d i u m provide a new route to alkenylphosphine oxides. Chi.ral h.p.1.c. on bonded (R)-N-(3,5-dinitrobenzoyl)phenyl glycine has been used to separate enantiomers o f racemic tertiary phosphine oxides on a preparative (about 1 g) scale.’ (2)-(9-Methoxypheny1)phenylvinylphosphine oxide ( 1 5 ) has been

prepared from ( 5 ) - p - m e t h o x y p h e n y 1 ) m e t h y l p h e n y l p h o s p h i n e oxide (Scheme 3 ) and used in the synthesis of a number of novel, optically pure phosphine ligands (e.g. - 16, Scheme 4 ) . 8 3 A

Preparation of Cyclic Phosphine Oxides.

potentially useful new route to the phosphirane oxide (18) has

been reported.’

Reaction of the a-bromoalkylphosphine oxide (17)

with base gives ( 1 8 ) and the olefinic by-product (19).

The

of stereochemistry of (18) was deduced from the (Z)-stereochemistry -

(19) (which is presumably derived from allowed conrotatory

ring-opening of (18)) and from the product of a Pummerer reaction of (18).

Oxidation o f P-tertbutyl- and P-phenyl 9-phosphabicyclo-

[6.1.0]nona-2,4,6-trienes (20) with peroxide offers a route to

phosphonin oxides (22) . l o However, these last compounds undergo intramolecular cyclization at 2S0C to give trans-3a. 7a-dihydrophosphindoles (23).

Oxidation of (20. R=Ph) with oxygen provides

instead anti-9-phenyl-9-phosphabicyclo[4.2.l]nona-2,4,7-triene-9oxide ( 2 4 ) .

the structure of which is supported by an X-ray analysis

74

Organophosphorus Chemistry

i

+

PhIty-Mc

0 I , I I

Me-S-Ph

~

II

I

I

AT

Reagents :

I ,

1 1 ,

CuCl

;

I I I

,

xylene

I

reflux

Scheme 3

0 (15)

-b

It

(PhDy-CCH2CHZ),PPh I

AT Ph

4

AT

Reagents :

I ,

NMe

J

b’

LDA ;

II

8

Ar

OMe

=

II

P h m P -CCH2CH2-S-Ph

NMc

Ar

0

II

PhPHZ, KOH, R T , 5 h ;

II

I

H S I C L ~ ,R 3 N

Scheme C

, MeCN

Ill

75

3: Phosphine Oxides urid Related Compounds of a phosphine derivative.

Attempts to stabilize either the

phosphonin structure (22) o r the phosphirane structure (21) by steric effects have also been reported.” 2,4,6-tri(tertbutyl)phenyl

Oxidation of the

substituted triene (25) with tertbutyl

hydroperoxide gave the corresponding phosphonin oxide (26) which slowly decomposed to give cyclooctatetraene; possibly by retrocycloaddition through elimination of A r P = O .

Apart from

reporting only the second example o f a phosphirane oxide, this paper also contains useful and interesting 31P and l 8 O n.m.r. chemical shift data. Reactions of aryl and alkyl dialkylphosphinites with dimethyl acetylenedicarboxylate followed by treatment with hydrogen bromide give various amounts o f phosphole oxides (27).12

These last

compounds are difficult t o isolate from the reaction mixture. partly because they readily add water to give the phospholenes (28) (Scheme 5).

Various stereoisomers of hydroxyphospholane oxides

(29)

have

been obtained from the reaction of 1,4-diketones with phenylphosphine. l 3 The a n t i - 7 - p h o s p h a n o r b o r n e n e

phosphinite (30) is

converted stereospecifically to the corresponding syn-7phosphanorbornene oxide (32) by an Arbusov reaction with the appropriate alkyl halide.14

The phosphinite (30) and the

corresponding chloride ( 3 1 ) are both converted, by hydrolysis at

room temperature, to the secondary phosphine oxide

(33).

Phosphorin

sulphides (35). generated by thermolysis of the 1-phospha-2thiabicyclic compounds (34). can be trapped with dienophiles to give 36 1. l5 phosphine sulphides (3.

The hexaoxide ( 3 8 ) has been obtained from the remarkably air-stable hexa(tertbuty1)octaphosphine (37) by oxidation with peroxides o r peracids at room temperature.16

76

Organophosphorus Chemist?

(201 R = P h , But

Ph

O4

(23)

(24)

( 2 5 ) X = \one pair

(26) X = 0

Reagents :

‘R

I,

M c O Z C C E CCOZMe ; ii , H Br ;

III

, H20

Scheme 5

77

3: Phosphine Oxides und Relared Compound.$

(291

-

X .Op

Ph \

p//o

R I

X = OMe

Me*Me

\'40

N Me

(301 X = OMe (31) X = CI

(32 1

78

Organophosphorus Chemistry

3 . Structure and Physical Aspects An ab initio study o f the tautomeric equilibrium (39) has been reported.17

Generally the results are somewhat different from those

expected by comparison with experimental observations; this is rationalised in terms o f solvent and substituent effects.

Ab initio

calculations have been carried out on F P = O (in the gas phase) and the report includes an investigation. by mass spectrometry and infrared, o f the same molecule isolated in an argon matrix.18 The conformation of 2-phosphorus-substituted-1.3-dithiane derivatives

(40)

has been studied using 1 3 C n.m. r . spectroscopy.”

The results indicate that the axial preference is Ph2P(S)>Ph2P(0) and are explained by a combination of the anomeric effect and the relative bulk and electronegativities of sulphur and oxygen.

Other

applications o f n.m.r. include investigations of the isomerisation

of 2-thioxo-(41) and 2 - s e l e n o - ( 4 2 ) - 2 - p h o s p h a b i c y c l o [ 4 . 4 . O l d e c a n 5-ones in the presence o f acid and base by 31P n.m.r.” and the nuclear shielding o f selenium in phosphole selenides by 77Se n.m. r . 21 Although previously reported as the arsin oxide structure (43).

X-ray structural and spectroscopic investigations now show that the compound actually exists as an arsorane-type s t ~ u c t u r ein the solid state and in dilute solution.22

The conformational equilibria of

various phosphine oxides has been investigated using calculated and experimental dipole moments. 23 5

Reactions at Phosphorus

Attempts to use silanes to reduce the dimer (44) of Z-phenylisophosphindole oxide to the corresponding phosphine (which is a potential precursor of the isophosphindole system) lead instead to carbon-carbon bond cleavage and formation of the diphosphine monoxide (45).24

An n.m.r. study of the interactions of

3: Phosphine Oxides and Related Compounds

R

79

\

( 3 7 ) X = lone p a i r

138) X - 0

H,P=X

H,P-X-H (391 X = O , CH2

X

pTPPh* y-S

X = O , S

phm Ph

II

(LO) Y = Me2C, S

NH

, CH,

H S I C ~ ~

PY 25

O C

x

80

Organophosphorus Chemistry

d i b e n z [ c , f l [ l , 5 1 a z a p h o s p h o c i n e 12-oxide derivatives ( 4 6 ) and ( 4 7 )

with thionyl chloride or dimethyltertbutylsiloxytriflate indicates that transannular species (e.g. - 4 8 , R=Me) are formed.Z5

Photo-

induced cleavage of acylphosphine oxides ( 4 9 ) has been shown by chemically induced dynamic electron polarisation to involve a Type I reaction.2 6 6

Reactions at the Side-Chain

The reaction of ketones with the lithio derivatives of allyl-(50) or (l-buten-3-~1)-(51) diphenylphosphine oxide provides a convenient synthesis o f 1.3-dienes with high (E)-stereoselectivity. 27 -

An

approach based on Whitham's method of interconverting alkene isomers

via their epoxides provides the first viable synthesis o f (E,E)-1,5-cyclooctadiene ( 5 4 ) (Scheme 6)

The diastereomeric

phosphine oxides (52) and ( 5 3 ) were separated and then identified by formation of their (-1-menthoxyacetic esters.

Fortunately only the

oxide ( 5 2 ) gives a volatile alkene on base treatment, hence separation of ( 5 2 ) and (53) is not required for the synthesis of (54).

The reactions of (a-1ithioalkyl)diphenylarsine oxides ( 5 5 )

with electrophiles have been investigated and provide routes to a variety of organoarsenic compounds. 29

Reduction of arsine oxides

and treatment with halogens leads t o A s - C bond cleavage and hence a synthesis of a variety of halogen compounds (Scheme 7).

The

reaction of ( 5 5 ) with certain carbonyl compounds is highly stereoselective. for example benzaldehyde gives almost exclusively the erythro-adducts (56).30

(a-Lithioalkyl )diphenylphosphine oxides

( 5 7 ) on the other hand generally show low stereoselectivity on

reaction with carbonyl compounds.

However, Kauffmann has now

shown31 that the introduction of an ortho-substituent in the phenyl groups of ( 5 7 ) greatly increases diastereoselectivity in these reactions, for example, reaction of ( 5 8 ) with benzaldehyde

3: Phosphine Oxides and Related Compounds

81

0

Cl

( 4 6 ) R = Me

( d 81

I

II

( 4 7 )R = Ph

Is

Ar, P C O A r

Scheme 6

82

Organophosphorus Chemistn

0

ll

Ph As

'PR'

0

0H

II,llI

/C--- H Ho \Ph

II

Ph2AsC(Li)HR' 4 (55)

Reagents : I , R2X ;

11,

PhCHO;

III

, H20

;

I V ,

L I A I H ~; v

-

Scheme 7

0 II

(58) Ar =

2

OMe

@,

0

PhCHO

Ar2PC(Li)R

(57)Ar: P h

,x2

R=Pr"

R'

R'

UMe

OMe

(60)

0

II

R ~ L I

t

(611 0

Ph2!

ph2pYsR

SR

R'

II

wSR

Ph2P

-

83

3: Phosphine Oxides and Related Compounds gives the ervthro-adduct (59) exclusively.

This has obvious

implications for the use of phosphine oxides in olefin synthesis as well as for the mechanism of the Wittig reaction.

Of further

interest is the increase in selectivity towards other aldehydes caused by changing lithium to chromium or titanium as the counter ion in (57). The carbanions

(60).

derived from a-methoxyallylphosphine

oxides. react with Si, S and P electrophiles to give the products (61) of y-attack highly regioselectively in almost all cases. 3 2 Full details have appeared of the generation o f the a-thioalkylphosphine oxide carbanions (63) via - nucleophilic addition to a-thiovinylphosphine oxides

( 6 2 ) . 33

The reactivity,

particularly the regiochemistry, of y-thioalkylphosphine oxide carbanions

(64)

has also been reported.

The enolate

(66)

formed o n

reaction of (E ) - b u t - 2 - e n y l d i p h e n y l p h o s p h i n e oxide carbanion

(65)

with 2-methylcyclopent-2-enone can be trapped by vinyl sulphones to give ( 6 7 ) highly stereoselectively and in excellent yield. 34 phosphine oxides (66)

(68)

The

and (70) (which are formed in a similar way to

from the reaction of cyclopenten-3-one with the carbanions of

(E)- and

(Z)-(but-2-eny1)diphenylphosphine

oxides, respectively) can

be cyclized stereospecifically to the bicycloheptanes

(69)

and (71)

or, in the case of (70). to the bicyclooctanol (72) (Scheme 7

Phosphine Oxide Complexes and Extractants

The structure of the stable complex (73) of triphenylphosphine oxide with 5-methyl-6-phenyl-l,2,3-oxathiazin-4(3H)-one 2.2-dioxide has been investigated by X-ray and n.m. 1:. spectroscopic methods.36 Trimethyl- and triphenylphosphine oxides have been used as probe molecules in studies o f adsorption sites on surfaces by 31P n.m.1. spectroscopy. 37 Diphenylphosphine oxide platinum(I1) complexes (75) are

Organophosphorus Chemistry

84

(701

(711

0

0

\IL @IPh2 \

v

'H H Me (72)

Reagents :

I

K O B u t , THF

pp"2

,

RT ;

/ \PtU2

cH2\ p /

Ph2

II

- 78

L D A ,THF

-

OC

0

II

Ph2P

NoOH

NH 3

:2

\ / \

/Pt\,/Pt\ Ph2McP

PMePh,

/

PPh2 H2

I/ 0

3: Phosphinr Orities arid Relutetl Conipounds

85

reported to be formed on reaction of the phosphine complex (74) with sodium hydroxide in

Uses

of phosphine oxides and

sulphides in the solvent extraction of metals include the use of tri(isobuty1)phosphine and triarylphosphine sulphides in the extraction of Pd( I I I 3 ’

and Hg( 1 1 ) ,40 respectively, from hydrochloric

acid. REFERENCES T. Hinami, T. Chikugo, and T. Hanamoto, J . Org. Chem., 1986, 1. 2210 2. H. Vincens, J.T.G. Moron, R. Pasqualini, and U. Vidal, Tetrahedron Lett., 1987, ;rS, 1259. T. Pollock and H. Schmidbaur, Tetrahedron Lett., 1987, 28, 1085. 3. 4. P . Beak and D. Loo, J. Am. Chem. SOC., 1986, 108,3834. 5. U. Kunze and R. Burghardt, Phosphorus Sulfur, 1987, 29, 373. Y. Xu. J. Xia, and H. Guo, Synthesis, 1986, 691. 6. 7. A. Tambute, P. Gareil, H. Caude, and R. Rosset, J. ChromatoKr., 1986, 363, 81. 8. C.R. Johnson and T. Imamoto, J . OrK. Chem., 1987, 52, 2170. 9. T. Oshikawa and H . Yamashita, Bull. Chem. SOC. Jpn., 1986, 59, 3293. 10. L.D. Quin, N.S. Rao, R.J. Topping, and A.T. UcPhail, J. Am. Chem. SOC., 1986, 108,4519. 11. L.D. Quin, E-Y. Yao. and J. Szewczyk, Tetrahedron Lett., 1987, 28, 1077. 12. J.C. Caesar, D.V. Griffiths, and J.C. Tebby, Phosphorus Sulfur, 1987, 29, 123. 13. V.I. Vysotskii and H.F. Rostovskaya, Zh. Obshch. Khim., 1986, 56, 1046 (Chem. Abstr., 1987, 106,84731). 14. L.D. Quin and G. Keglevich, J. Chem. Soc.. Perkin Trans.2, 1986, 1029. 15. H. Tanaka and H. Hotoki, Bull. Chem. SOC. Jpn., 1987, 60, 1558. 16. H. Baudler and J . Gemeshausen, Agnew. Chem., Int. Ed. Engl., 1987, 348. 17. H.T. Nguyen and A.F. Hegarty, J. Chem. SOC.. Perkin Trans.2, 1987, 47. 18. R. Ahlrichs, R. Becherer, H. Binnewies, H . Borrmann, H. Lakenbrink, S. Schunck, and H. Schnockel, J. Am. Chem. SOC., 1986, 108, 7905. 19. H. Hikolajczyk, P. Graczyk, and P . Balczewski, Tetrahedron Lett., 1987, 28, 573. 20. Yu. G. Bozyakov, G.P. Revenko, and A.P. Logunov, Zh. Obshch. Khim., 1986, 56, 1973 (Chem. Abstr., 1987, 107, 59107). 21. D.W. Allen and B.F. Taylor, J. Chem. Res., Synop., 1986, 392. 22. H.K. Bathla, S.S. P a m a r , H.K. Saluja, A.H.Z. Slawin, and D.J. Williams, J. Chem. SOC.. Chem. Cormnun., 1987, 685. 23. 1.1. Patsanovskii, E.A. Ishmaeva, E.N. Sundukova. A . N . Yarkevich, and E.N. Tsvetkov, Zh. Obshch. Khim., 1986, 5 6 , 567 (Chem. Abstr., 1987, 107, 84724). 24. L.D. Quin and F.C. Bernhardt, 3 . O r g . Chem., 1986, 3235. 25. K. Akiba, K. Okada, and K. Ohkata, Tetrahedron Lett., 1986, 21, 5221. 26. J . E . Baxter, R.S. Davidson, H.J. Hageman, K.A. Hclauchlan, and D.G. Stevens, J. Chem. Soc., Chem. Commun., 1987, 73. 27. Y. Ikeda, J. Ukai, N. Ikeda, and H . Yamamoto, Tetrahedron, 1987, 4 3 , 723. 28. D. Boeckh, R. Huisgen, and H. Noth, J. Am. Chem. S o c . , 1987, 109, 1248. 29. T. Kauffmann, R. Joussen, and A. Woltermann, Chem. Bet-.,1986, 119, 2135. 30. T. Kauffmann, G. Kieper, and N. Klas, Chem. Ber., 1986, 119, 2143. 31. T. Kauffmann and P. Schwartze, Chem. Ber., 1986, 119, 2150. 32. D.K. Devchand, A.W. Hurray, and E. Smeaton, Tetrahedron Lett., 1986, 1, 4635.

a,

a,

a,

86

Orgunophosphorus Chemistrv

33. J.I. Grayson, S. Warren, and A.T. Zaslona, J . Chem. SOC.. Perkin Trans.1, 34. 35. 36.

1987, 961.

J . Chem. SOC., Chem. Commun., 1987, 92. R.K. Haynes and A.G. Katsifis, J . Chem. S O C . , Chem. Comun., 1987, 340. M.C. Etter. R.D. Gillard, W.B. Gleason, J.K. Rasmussen, R.W. Duerst, and R.B. Johnson, J. Org. Chem., 1986, S l , 5405. 37. L. Beltusis, J . S . Frye, and G.E. Maciel, J. Am. Chem. S O C . , 1986, E,

38. 39. 40.

R.K. Haynes and S.C. Vonwiller,

7119. N.W. Alcock, P. Bergmini, T.J. Kemp, and P.G. Pringle, J. Chem. S O C . , Chem. Comun., 1987, 235. Y. Baba, H. Ohshima, and K. Inoue, Bull. Chem. S O C . J p n . , 1986, 59, 3829. Y . Baba, Y. Umezaki, T. Ueda, and K. Inoue, Bull. Chem. S O C . Jpn., 1986, 59, 3835.

4

Tervalent Phosphorus Acids BY 0 . DAHL

Introduction

Proceedings of the 10th International Conference on Phosphorus Chemistry, Bonn 1986, have been published. The conference covered all areas of phosphorus chemistry, including several papers on tervalent phosphorus acid chemistry. The same holds for the proceedings from a more specialised meeting, the 7th International Round Table on Nucleosides, Nucleotides and Their Biological Applications, Konstanz 1986.2 Reviews of interest f o r this chapter include one by Schmidpeter on preparative routes to two-co-ordinate azaphospholes and some of their characteristic one by Arduengo I11 on some 10-P-3 and similar pnictogen c o m p o ~ n d s ,and ~ two by Pudovik, one on reactions of tervalent phosphorus acids derivatives with 1-nitro-1-alkenes, the other on reactions of isocyanato- or alkylideneamino-phosphine derivatives with compounds containing multiple bonds.

reaction^,^

2 Nucleophilic Reactions

2.1 Attack on Saturated Carbon.- A kinetic study on the Arbuzov reaction in propylene carbonate, using a conductivity method, gave reliable kl and k2 values for several compounds (1).7 Triethyl trithiophosphite ( 2 ) reacts slowly with methyl iodide at room temperature to give the normal Arbuzov product.8 This is contrary to earlier results of high-temperature reactions where 87

88

x\ Y’

P-OMe

+

-

+ ,Me

X,

kl

Me1

P

Y’

( 1 ) X . Y =OMe.Et , P h

lk2 X

\ p 40

Y/

‘Me

0 PhP(OR),

t

6rCH2C=CH

II

--j

1-

‘Me

PhP-CH2CECH

I

+

R

Me1

+ PhP-CzCCH, I

+

4: Trrvalent Phosphorus Acids

89

ethylthio groups were substituted. An example of concomitant substitution and Arbuzov reaction is found for reactions of some 4 9 chlorobutyramides ( 3 ) with triethvl phosDhite. Dialkyl phenylphosphonites (4) with 3-bromopropyne gave mixtures of the normal Arbuzov product ( 5 ) , with the rearranged products (6), ( 7 ) , and (8).l0 Phosphinothricin ( 9 ) and the corresponding phosphonic acid (10) have been prepared by classical Arbuzov reactions. A phosphonate analogue (11) of a bacteria membrane component CMP-KDO has been prepared, the key reaction being 12 an Arbuzov reaction with a $-lactone (12). 2.2 Attack on Unsaturated Carbon.-Low-temperature addition of triethyl phosphite to ally1 ironcarbonyl complexes, e . g . (13), proceeds regio- and stereospecifically to phosphonium salts (14) which are easily converted to Z-alkenylphosphonates;l3 similar reactions occur with hexadienyl ironcarbonyl complexes. Tetraethyl acetylenediphosphonate (15) may conveniently be prepared from ( 16 ) , thereby avoiding dichloroacetylene.l4 Trialkyl phosphites and a-halogenoketones in alcoholic media give varying amounts of vinyl phosphates like (17) in aprotic media, but a-hydroxyphosphonates (18) are formed instead of 8-ketophosphonates. l5 A mild procedure to prepare bis( 1-hydroxyalky1)phosphinic acids (19) is from bis(trimethylsily1oxy)phosphine (20).l6 The intermediate (21) is converted in s l t u to the ter-

valent ester by trimethylsilyl chloride. The preparation of 1-aminoalkanephosphonic acids from protected ammonia, an aldehyde, and a phosphite is well known: a series of aminoarylmethanephosphonic and phosphinic acids have been similarly prepared, using thiophosphoric amides as the ammonia donor. l7 Phosphites and phosphonites containing g-acetyl or g-formy1 groups are unstable towards cyclisation, e.g. (22) gives

(24): the _o-acetyl analogue (23) , however gave ( 25). l8 Triethyl trithiophosphite reacts with benzaldehyde to give in part a 1:l addition product ( 26 ) .l9

2.3 Attack on Nitrogen, Chalcogen, or Halogen.- Tervalent phos-

phorus acid chlorides, e.g. (27) or (28), are difficult to oxidise with high yields: ozone has been reported to be an ideal reagent for this. 20Phosphoro fluoridates ( 29 ) are obtained pure in high yields by fluoridation of the silyl phosphites (30) with sulphuryl chloride fluoride.21

Orgunophosphorus Chemistry

90

HOOC

-!

0

NH2

-R

OH

( S ) R = M e (10)R=OH

HO

HO HO (11)

(13 1

(14)

zoo c NaHC03

4: Tervalent Phnsphoru.q .4cids

dRk0 (Me,SiO)zPH

OSiMe3

I

OSiMe3

I

MqS i CI

R1R2C-P(0)OSiMej

I

R1$C-P(OSiMe3)2

H

(20)

(24)

(21)

(25)

(22) R =H ( 2 3 ) R =Me

PhOPCl2

(28)

92

Organophosphorus Chemistp A detailed mechanistic study on the thermal reaction of triethyl phosphite with carbon tetrachloride concludes that the mechanism is nucleophilic attack on C1 (SN(C1)), and not a radical reaction ( SRNl) .22 Triethyl trithiophosphite ( 31 ) probably also reacts with carbon tetrachloride by an ionic mechanism, however sulphur seems to be the more halophilic center. When one ethylthio group is substituted with a diethylamino group, as in ( 32 ) , phosphorus has again the higher nucleophilicity.23

3 Electrophilic Reactions 3.1 Preparation.- A simple method €or the preparation of methyl phosphorodichloridite ( 33 ) has been described: 24 the best yield of (33), 55%, was obtained when trimethyl phosphite and phosphorus trichloride were mixed in a 1:l molar ratio. Tris(t-butyldimethylsilyl) phosphite (34) has been prepared and used f o r the preparation of alkyl phosphonates by Arbuzov reactions.25 The intermediate disilyl phosphonates derived from (34) are more hydrolytically stable and therefore easier to purify than those prepared from tris(trimethylsily1) phosphite. A convenient, high yield synthesis of aminomethanephosphonic acid (35) has been described from N-hydroxymethylbenzamide, trimethyl phosphite, and phosphorus trichloride.26 A series of tervalent phosphorus acid derivatives of substituted ethylenediamine ( 36 ) , 2-aminoethanol ( 37) and ( 38 ) , or l12-ethanediol (39 ) have been prepared, in order to study donor-acceptor interactions between the 2-substituent and p h o s p h ~ r u s .In ~ ~ one case a stable complex ( 4 0 ) was formed and characterised by X-ray crystallo-

graphy. Recent interest in myo-inositol 1,4,5-triphosphate (41) stems from the discovery that it is a secondary messenger f o r intracellular calcium release. The triphosphate and several analogues have been prepared via phosphites, using (42) followed by 3-hydroxypropionitrile,2 8 (43 1 , 29 or ( 441. 30 Some new acetylenebisphosphonous acid derivatives (45) and (46) have been prepared as shown, and an X-ray structure determination made on ( 45 ) , R2N = morpholinyl.31-The unstable tetrafluoro derivative (47) could not be prepared from (46) but was obtained from the tetrachloro analogue.31 Tervalent phosphorus acid iodides (48)react readily with aldehydes or ketones in the presence of triethylamine to give vinyl phosphites ( 49 ) 32 Similar s

4: Tervalent Phosphorus Acids

(RO)2P-OSiMe3

+

93

S0,CIF

( 3 0 ) R = Et ,CF3CH2,Pri.Ph

+

(EtS),P

CCI4

(31) EtSCI

4-

(31)

+

(EtS),P-NEt,

CCL,

-

-

(EtS)ZP-CCL3

(EtS),PCl EtS, P-CI Et,N

/

+

EtSCl

EtSSEt

+

EtSCCI,

Me

Me

(36)

+

[PhCONHCH2O-P(0-)2]

PhCONHCH20H t PC13 + ( M e 0 I 3 P

Me2NCHzCH2NSiMe3 4-

Me,SiCI

(29)

(32)

I

+

(R0)2P(0)F t SO,

I

PCl3

4

Me

[ M~NCH~CH~N-PCIZ]

J

I

[;,PCI N\

'

Me ' M e

CI-

94

Organriphosphorus Chemistry

Me I MeOCHz CH, NSiMe,

Me NCH CH,OS i Me,

MeOC H2C H, OSiMe

(38)

(37)

(39) CI

'

NCCHzCH20P'

(NCCH, CH20)2PCI

NPri2

(45) t

F\ PC W P , NF

AsF~

F2PCSCPFz

R t N' NR2 ( 4 6 ) R,N = E t , N , O ~

X2PI

+

r t

R'COCHRtR3

( 4 8 ) X = EtO,BuO,EtzN

Et3N

(47)

N

R' I

X2P-O-C=CRZR3

(49)

4: Tervuknt Phosphorus Acids

95

reactions of dialkyl phosphorochloridites with cx,p-unsaturated

ketones give butadienyl phosphites, e . g . (50).33 Two papers have appeared which describe the preparation and properties of some trialkyl 34 or triaryl 35 trimetaphosphites (1,3,5,2,4,6-trioxatriphosphorinanes) (51). The alkyl substituted compounds are easily hydrolysed in contrast to the hindered aryi compounds, and the crystal structures of (51), R1 = Me and But, have been determined.35 A series of benz-l,3,2-dioxaphospholens ( 52 ) have been prepared by standard methods. 36 More interesting are the results of hydrolysis of (521, X = C1 or NR2, where the normal secondary phosphite (53) is formed, with no 31P n.m.r. evidence for the presence of the earlier postulated tervalent tautomer ( 54 1. 36 Hydrolysis with less than one equivalent of water gave (55), and probably the 31P n.m.r. signal for this compound (120 ppm) was previously taken as evidence f o r the presence of (54). The secondary phosphite (53) is spontaneously hydrolysed by moist air to (56). The reaction of 2-butyne-1,4-diol with chlorodiphenylphosphine has been reinvestigated. The product is the 2,3-bis(diphenylphosphinoyl ) -l13-butadiene ( 57) instead of the 1,4-isomer.37 The proposed mechanism is a double [2,31-sigmatropic rearrangement of the bisphosphinous ester (58). Phosphitylation of carbaxamides (59) with dialkyl phosphorochloridites gave products of N- o r 0attack depending primarily on the R3 s u b ~ t i t u e n t .Both ~~ compounds rearrange to (60) upon heating, the enol phosphite being the least stable; the rearrangement is catalysed by amine hydrochlorides. Similar products are obtained as a result of N- or Sattack on thioamides.39 Tetrachloromethylenebisphosphine (61) with primary amines gave l12,4-azadiphosphetidines ( 62 ) 40 These polymerise on heating, but a thermally stable compound (64) was obtained via the very labile (63). Similar reactions of methylenebisphosphines (61) or ( 65 ) with hydrazine or 1,2-dimethylhydrazine gave l12,3,5-diazadiphospholans ( 66 ) - ( 69 ) ;41 with phthalohydrazide compounds analogous to (66) and (67) were also prepared. An X-ray structure analysis of (68), R = But was made and showed an all-trans configuration of the substituents.41 The phosphorus trichloride-aniline system is still being examined for new compounds, and (70)or (71) was the main product under slightly different conditions;4 2 the structure and Configuration ( a l l - e ) of (70)have been established by X-ray crystallography. Benzene-1,2,3-triamine (72) with tris(dimethy1amino)phos-

.

Organophosphorus Chemist?

96

OR

( 5 2 ) X=CI,OR.NR,

(53)

boH

+ H20

'H

(56)

2 Ph2PC\

+

b o \ P 0' - O H

p//o

H O '

(54)

HOCH2C=CCH20H

R2

I ( R10)tP-N-COR3

(R'O)2PCI

+

"=Y R2NHCOR3

0 R3 II I (~'0 P-C=NR~ )~

4: Tervalent Phosphorus Acids

97

R

Et2NH

(63)

-

H

R

\

But

I

II

Et2N-PflN\P-NEt2

/

Y-7

P

Me

\

H

" \R P

(68)

N-N

I

CI

/

/

CI-P

v

MeNHNHMe

/

CH3COCI

But

(64)

(61)

1

But

N\

v P-CI

(63)

Me Me NHN HMc

\

,pvp\ CI

''

' R

/

Cl

PCH2 P

\

MP I

____c

R

( 6 5 ) R = P r ' , But

,Me

N-N

McNHNHMe

\

% @ ,,

R

R

(69)

98

Orgunophosphorus Chemistry phine gave the first linear A3-tetraphosphazene (73), which has been characterised by X-ray crystal structure analysis of its tetrasulphide.43 The first examples of 1,2-dihydro-l,2-h3-azaphosphorines ( 74 )

have been prepared and characterised.4 4 2-Chloro-l,3,2-dioxaphospholan (75) has been recommended for preparation of N,N'-diarylureas as shown.45 The synthesis of pyrroles from N-alkylhydrazones, or indoles from N-arylhydrazones, using phosphorus trichloride, has been studied.4 6 In both cases 1,2,3-diazaphospholes (76) or (77)are intermediates.

3.2 Mechanistic Studies.- Two papers have appeared which address the stereochemistry of substitution reactions on phosphorus in anti-7-chloro-7-phosphanorbornene derivatives (78). Contrary to results for most other systems, the reactions of (78) with methanol, 2,2,2-trichloroethanol, methoxide or phenoxide ions, or water gave products with complete retention,47 like previously described reactions of (78) with Grignard reagents or bromide ions, but secondary amines gave mixtures of stereoisomers.4 8 The stereochemical assignments were based mainly on 3Jpp and 2Jcp coupling constants which are very sensitive to the phosphorus lone-pair orientation. An addition-elimination mechanism (Scheme 1) was proposed to explain the stereochemistry. By using the usual preference rules for Berry pseudorotations, i - e . a small ring prefers an apical-equatorial position, and a more apicophilic group lowers the energy of a phosphorane with this group at the apex, the retention for anion nucleophiles (lone-pair in place of H in Scheme 1) is explained, since a lone-pair has a very low apicophilicity, and therefore 'tCl should not occur. The difference in stereochemistry for alcohols and amines was explained by the low apicophilicity of NR2 which, contrary to O R , would allow phosphoranes with apical H to compete and thus give some inversion. This latter explanation seems less satisfactory since both OR and NR2 are less apicophilic than H. However, other reasonable mechanisms for the puzzling stereochemical results, e . g . exchange of substituents or thermal isomerisations, seem ex-

cluded by additional experiments. The rates of reaction of nucleoside phosphoramidites (79) with a protected nucleoside ( 8 0 ) , catalysed by tetrazole, have been measured to study the influence of different substituents at p h o s p h o r u ~ .The ~ ~ rates are as expected for the R1 substituents ( s e e diagram), but the variation with the amino substituents does

4: Tervulent Phosphorus Acids

MezN NH2

\

y e 2 P-

N-P

R

I

Ar NH2

_ . )

Me

(74)

I

(75)

NHAr I

co I

Ar NH2

COZ

OCONH Ar

c---

NHAr

R1\ /

C=NNHR~

+

PhCH2

Ph

+

(77)

PC13

Ph

Ph

Organophosphorus Chemisrry

2”?, 0”

Nu

+

HNu

+

‘NR

( 7 8 ) R = M e , Et

ROH , RO- 100% Rz NH 50 -70%

H

Nu

I

P’

CI

1-

* ”CI

CI

Nu

/’ \p H

.=

Nu

‘P’

tention

Scheme 1

4: Tewalent Phosphorus Acids

10 I

not follow the leaving group ability, as was found in earlier model experiments. Additional results, e - g . of inhibition by tetrazolide anions (81), were used as evidence for the proposed mechanism (Scheme 2), in which tetrazole is both an acidic and a nucleophilic catalyst.

3.3 Use for Nucleotide, Sugar Phosphate, o r Phosphoprotein Synthesis.- This year quite a number of new tervalent phosphorus reagents have been introduced for the preparation of modified oli-

gonucleotides, besides several new reagents for regular oligonucleotide synthesis. The same or similar reagents find increasing use for preparation of sugar phosphates or phosphoproteins; the three topics are therefore treated together in this chapter. Several dialkyl phosphoramidites have been prepared and used for phosphorylation purposes: these include ( 8 2 1 , 50r51 (83),50 (84),50 ( 8 5 ) , 5 2 (86),53 and (87),54 which all gave phosphoric acid monoesters after oxidation and deblocking. In case of ( 8 4 ) and (85) the presence of benzyl groups influenced the oxidation procedure: the usual agent, iodine/water/lutidine, gave low yields of phosphates, but peracids, e.g. MCPBA, were satisfactorY. 5 0 r 5 2 The reagents ( 8 2 ) , (83), ( 8 6 ) , and (87) have been used to 5'-phosphorylate protected oligonucleotides on a solid support, and (84) and (85) to phosphorylate hydroxy groups of amino acids or a peptide. Other dialkyl phosphoramidites used for 5'-phosphorylation of protected oligonucleotides on solid supports are ( 88), 55 (89) ,56 (go),57 and (91). 58 These on deblocking give 5'-phosphodiesters with a free functional group on the end of an alkyl chain: the functional group can be used to attach e.g. biotin or fluorescein to the oligonucleotide for marker purposes. The dialkyl phosphorochloridites ( 92 )59 and ( 93 ) 6o have been used to phosphorylate N-protected amino acids and nucleosides, respectively. The "salicylchlorophosphite" (94) introduced last year for preparation of nucleoside H-phosphonates is also very useful to prepare anomerically pure a-glycosyl phosphates,61 a( 16) glucosamine 'phosphodiesters,6 2 and nucleopeptides,63 v i a the corresponding H-phosphonates. Tyrosine H-phosphonate, however was better prepared using (95).63 The cyanoethyl phosphorodiamidite (96) finds increasing use in the preparation of nucleoside phosphoramidites. Two improved preparation procedures for (96) have appeared,50f 6 4 as well as a full paper on DNA synthesis using (96) and the in s i t u

Organophosphorus Chemistn

102

DM70v

OM T

HO

+

0

‘

P-NR

R’ 0’

0

C Y CN

-0

‘P

R’O’

0

\

2

(79)

SiBu‘ Ph2

O\

(80)

Me

I

R ’ = M e > CH2CH2CN > CHCH,CN > CCH2CN I >> Me

NR2,= NEt2 > N P r i 2 >

N’O

N

n

0 >

LJ

NMePh

H

\

P

- NR,,

N’O

\+/

+

a CI

Me

I

H

P

/ \

R’O

R’O

N’ 0

+

NR22

H

\

/N\N

/

N-N

R‘ 0

Scheme 2

SiBu‘Ph2

4 : Ter vulrnr Phosphorus A d s

(82)

1

CI

DMTOCH2 CH 2 SO2 CH 2 CH2 0

CH20

Ph 3 C SCH2 C H2 0

\

/

120

\

/

\

P- NP rI2

NC CH2 CH2 0

CF,CONH(CH,

(84) R = P r ' ( 8 5 ) R = Et

P-N

/

Me0

n 0

=

MMTNH(CH2)3 0

\

P-NPr ' 2

NCCHzCHz 0

/

P-NPr

'2

Me0

(88)

(89)

MeOCO(CH2)110

DMTO( CH2) 3 0

\

\

P-NPrI2

/

RO

(90) R=Me.CH2CH2CN

(RO)? PCI (92) R =Me.Et.Ph

/

Me0

(91)

P-NPr

l2

104

0r~anc~phosphoru.s Chemistry

approach,65 and two papers on its use for RNA The similar, but more sterically hindered, reagent (97) has been used to obtain 3',5'-deoxynucleotide dimers unprotected at the 3'-OH group, and for preparation of oligomers by phosphoramidite solution chemistry. 68 The methoxy analogue (98) has been applied in the synthesis of ribonucleoside phosphoramidites.69 Several alkyl phosphorodiamidites (99) have been prepared as shown and used without purification to prepare deoxynucleoside phosphoramidites.70 The ethyl phosphoramidochloridite ( 100) has been used to prepare deoxynucleoside ethyl phosphoramidites; these enabled the synthesis of dimers and a DNA-fragment which after deblocking contained a phosphotriester linkage.71 A new method to prepare oligonucleotides, employing thiophosphites, has been introduced.7 2 The new monomer units, nucleoside thiophosphites ( 101), are prepared from ( 102), and (101) activated for coupling by an excess of iodine in pyridine. Oxidation to (103) occurs on subsequent addition of water. The coupling rates are high, and the cyanoethyl thiophosphites ( 104 ) 7 3 gave coupling yields approaching those of phosphoramidites. The relatively new H-phosphonate method continues to be developed. Monomers (105) have been prepared using tris(l,2,4-triazolyl )phosphine ( 106), 74 or the previously described trisimidazolide (107),75r76 The method has been used for DNA74r75 as well as RNA76 synthesis, and some mechanistic studies have appeared concerning activation34 and adverse effects of premixing H-phosphonate and catalyst.77 The formation of (108) and (109) from H-phosphonates and their use to prepare phosphonate derivatives have been described.77 A solid support synthesis of a sugar phosphate tetramer, a teichoic acid, has been achieved using (110) as a building block. 78 Protected deoxyguanosine derivatives react with ( 111 ) , which is a likely impurity in standard reagents used to prepare phosphoramidites, to give ( 112). 79 Miscellaneous.- The photochemical and thermal behaviour of some new phosphorus azides ( 113) has been studied.8o The primary product of photolysis, the phosphanitrile (1141, is unstable towards oligomerisation or rearrangement, but may be trapped with trimethylsilyl chloride. The g-metallated aryl phosphorodiamidi81 tes (115) rearrange spontaneously to (116). 3.4

4: Tervalenl Phosphorus Acids

I05

Me

I

NCCHzCOP( NEt2)2

I

Me

(98)

(97)

EtOP

/

CI

'

NPri2

+ 0, R'O'

R30H

i) I 2 / P y

i i ) ti20

P-SR2

(101) R' = Me.R2 =Et ,Pr P r ' , Bu' (104) R' = NCCHzCH2 ,R = But

R' OP

'CI

'SR2

( 102 1

D"To , O

R'O

/p OR^

NP\

(103)

106

Organophosphorus Chemistry

( DMTov NIN?)~

N

(106)

DMTov DMTov 0

‘3rd

\P-0

-+ 0

0,

Me3Si 0

/

P-OR

0-

(109) R =Me3Si,S’-dT

(108)

0 I?

NC CHzCH2 0 ’ ( 110)

x\ Y’

P-N3

-

OSiMe2Bu‘ (112) R = M e . P r ‘ . P h

-

N SiMe 3

hV

Y’

‘CI

4: Tendent Phosphorus Acid5

in

107

New tervalent phosphorus acid derivatives for use as ligands asymmetric hydrogenation reactions are ( 117 ) ,82 ( 118 ) ,82

( 1 1 9 ) , and ~~ ( 1 2 0 ~ ~ ~ 4 Reactions involving Two-co-ordinate Phosphorus

Phosphoryl fluoride (121) has been generated in the gas phase and characterised by mass and matrix infrared spectroscopy.85 Chloromethyldichlorophosphine (122) is a useful starting material for the preparation of 1,3,4-diazaphospholes, e.g. (123): a 1,3,4thiazaphosphole (124) is similarly obtained from (122) and thiobenzamide. 86 A series of 4,6-diamino-l,3,5-triaza-2-phosphapentalenes (125) has been prepared and the X-ray crystal structure determined in one case.a7 The 1,2,3-diazaphospholes ( 126 ) and diphenyldiazomethane gave the bicyclic products (127), presumably v i a the [ 2+3] cycloaddition products shown: 88 methanol opened the three-membered ring to give (128). Aminoiminophosphines with bulky substituents can be very stable, e . g . (129) is not decomposed at its m.p., 203-205O C. There is a very slow H-exchange between the two nitrogen atoms, and an X-ray crystal structure study could not locate the proton.89 Some N-phosphino aminoiminophosphines (130), as well as (131), have been prepared, and their structures studied, including an Z-ray crystal structure determination in one case. The N , P-diamino iminophosphine (132) has been prepared as shown and its crystal structure determined.’l It has an unusual long P = N bond and adds readily carbon dioxide or carbon disulphide to give (133). An unusual reaction occurred when (134) was treated with N-haloamines; the t-butyl group was displaced to give the aminoiminophosphine (135).92 A study of the limitations of two preparative routes to iminophosphines and the chemical properties of iminophosphines has been p~blished.’~One route, substitution of a bis( trirnethylsily1)amino group of (136) with alkyl or aryl lithiums, gave iminophosphines (137) when R1 and R2 were both large ( e . g . R1 = Me3Si, R2 = 2,4,6-tri-t-butylphenyl), but addition products (138) otherwise. The other route, thermal elimination of trimethylsilyl chloride from (139), seems more general, but is limited by the availability of the starting material: thus (139) could not be prepared for R1 = R2 = 2,4,6-tri-t-butylphenyl. Chemical properties examined are addition reactions with methanol or dimethyl-

108

Organophosphorus Chemisrn

R'

Phz P-0,.

CHO-PPh2 R2/CHg;PPh2 I

cox,( I PPh, (117) X = OEt .OC2H&OEt NH Bu

.

(118) R' = H.Me R 2 = Me,Pr',BuS.Bu', PhCHz .Ph R3 = M e , E t

Me I

N- PPh2 - w I y O - P P h 2 0-PPh2

PPhz

(120)

(119)

P(0)Br2F

CICHZPCI, (122)

+

+

R + I H,N=C-NH,

-

1000 - 1250 K

2Ag

O=P-F (121)

H

CI-

-----)

CN;rR P-N

(123) R =Me,Ph

=ANYR P-NH

4: Tervalenr Phosphorus Acids

I 09

(126) R =Me,Ph MeCO, PhCO

(127)

+

MeOH

-

Me

Y-" " I

Ph kP,O PhM e

%

PBut2 P=N' R2N'

P=N

P8u'z

'

Organophosphorus Chemisrrv

110

But

/

+

P=N (134)

(Me 3

, P=N’ Si ) z N

a

-

R2 N

/

+

P=N

(135) RzN = (Me3Si)2N, But( Me 3s i 1N ,

R’

R Z PClz

R Z = Bu‘ , Ph , mesit yl

R’=

R2N-X

+

, SiMe, LiN ‘R’

-

CI

I

RZ-P-N-R’

SiMc3

1

( 1 39)

Bu‘X

4: Tervalent Phosphorus Acids

Ill

amine to give (1401, oxidation with chlorine to (141), and oxidation with chalcogens to (142). The molecular structure of (1371, R1 = t-butyl, R2 = 2,4,6-tri-t-butylphenylhas been determined by X-ray crystallography.93 In another study of the preparation of iminophosphines via (139) it was found that with smaller substituents than 2,4,6-tri-t-butylphenylon nitrogen, the iminophosphines (137) were unstable with regard to the cyclodimers ( 143 ) .94 The iminophosphine ( 144 ) has been prepared from dichloro( pentamethylcyclopentadienyl)phosphine and t-butylamine.95 One iminophosphine, two diphosphenes, and four sulphuranylidenephosphines (145) have been prepared as shown.96

The phosphenium ions (146) and norbornadiene (147) gave the cycloaddition products ( 148). 97 The stereochemical result of the reaction for R1 = Pri2N, R2 = C1, with the bulkier diisopropylamino group at the more substituted side of the phosphetane ring, is explained by puckering of the ring to place the larger group in a pseudo-equatorial position. Hydrolysis of ( 148) gave the inverted products ( 149 ) . With cyclo-octa-l15-diene,only the more reactive chlorophosphenium ion reacts to give the tricyclic the diisopropylamino group is again at the phosphetane ( 150); more substituted side, as shown by an X-ray crystal structure determination. A series of new, unsymmetric phosphenium ions (151) 99 and known symmetrical ions ( 152) have been prepared as shown. Several other ions (X = NCS, neopentyl-0) were unstable. A new, reasonable diphosphene, (153), has been prepared and its crystal structure determined.loo The bond between the pentamethylcyclopentadienyl group and phosphorus "walks" around the ring by [1,5]-sigmatropic shifts in solution even at -80° C, and the group is readily displaced by lithium amides or lithium alkyls to give (154) and (155). The reactions of two diphosphenes ( 1 5 5 ) , X = tris(trimethylsily1)methyl or 2,4,6-tri-t-butylphenyl, with some proton donors and lithium alkyls have been studied."' Diazoalkanes or halocarbenes gave diphosphirans (156) with the diphosphene shown, with some concomitant formation of phosphaalkenes ( 157 ) .

'*

5 Miscellaneous Reactions

Flash vacuum pyrolysis of some 2-aryloxy-1,3,2-dioxaphospholans ( 158) gave cyclic phosphonates, e. 9. ( 1591, presumably via aryl metaphosphates ( 160). lo3 The reactions of t-butoxy radicals with

112

Organophosphorus Chemistry

CI

I

R~P=NR’

I

R2 P

/ NHR’

HX

c-

P=N’

R2

‘X

( 1 4 0 ) X =OMe.NMe,

CI

R‘

(141)

’

(137)

R2 p 4NR’ +X

(142)

C l SiMe3 BU~-PI N-R’ I

-+

[gut,P=N/R’]

-

(139) R’ = Me3Si, Bu‘MezSi,

BU:,

,P-N, But

-

1 adamantyl. mesi t yl

P=N

’But

Me

Me

P

+NR’

/ \

Me

c\-x=o

__t

‘R’ (145)

R’

4: Tervalenf Phosphorus Acids

R’,

R2

113

- & r.!.

’

p + +

(1471

2

4

p, ‘\Rl

R

(149)

(148)

CI ‘P+ Pr’zN’

+

CI-

42) +‘ P

NPri2

(150)

CI ‘P+

R,N’

+

Me3SiX

X

__c

‘P+ R~N’ (1511

R = Pr‘, X = NMez,CN, N=P(NMez)3 R = E t , X = Nblez.CN

R2 N = EtzN, Pr’zN

(152)

Me

he (153)

I14

Organophosphorus Chemistr?/

(153)

LiX d

P=P X

/

CsMes

LiX __t

X

/

(154)

/

/

P=P

X

(155)

X = (Me,Si),N.6u~(Me3Si)N.(Me3Si),CH. ( M e 3 S i I 3 C

/

P=P

/

Ar

+

R'R~C:

Ar

-

Ar

\

Ar P-P'

X

#'

R' R 2

+

/

P=CR'R~

Ar

Ar =

Ar

= 1-

naphtyl

7 0 0 ' C , 0.001 m m Hg

-

(158) Ar = 1 - naphthyl , 2 biphenyl 2 -bcnryl phcnyl. 2 . 4 . 6 - Bu'jCgHz

ArO-P P=O \ OH

4O +O

4: Tervulent Phosphorus Acids

I15

a large number of phosphites have been studied in order to find good inhibitors for autoxidation of polymers:104 the best are acyclic triaryl phosphites, which consume the t-butoxy radicals by substitution and form stable aryloxy radicals. Photolysis of ally1 phosphites, e.g. (161), probably occurs via phosphoranyl l13-biradicals. A method to convert carboxylic acids to dithiophosphonates under mild conditions has been evaluated. The carboxylic acid is converted to a thiohydroxamic acid anhydride (162) which when stirred with triphenyl trithiophosphite gave (163) in 26-70% yield. The proposed radical mechanism is initiated by phenylthio radicals which attack (162) to liberate R' radicals which are trapped by the thiophosphite. References

1.

2.

3. 4.

Phosphorus Sulfur, 1987, 30, 3-850. Nucleosides Nucleotidcs, 1987, 6, 1-542. A. Schmidpeter, Phosphorus Sulfur, 1986, 2 8 , 71-89. A. J. Arduengo 111, C. A. Stewart, F. Davidson, D. A. Nixon,

J. Y. Becker, S. A. Culley, and M. B. Mizen, J. Am. Chem. SOC., 1987, 109, 627-647. 5. R. D. Gareev and A . N. Pudovik, J. Gen. Chem. USSR, 1986, 56, 211-220. 6. A. N. Pudovik, I. V. Konovalova, and L. A. Burnaeva, Synthesis, 1986, 793-804. 7. E. S. Lewis and €9. A. McCortney, Can. J. Chem., 1986, 64, 1156. 8. V. A. Al'fonsov, G. U. Zamaletdinova, E. S. Batyeva, and A . N. Pudovik, J. Gen. Chem. USSR, 1986, 56, 634. 9. P. A. Gurevich, V. V. Moskva, and G. Yu. Klimentova, J. Gen. Chem. USSR, 1986, 5 6 , 2148. 10. S. A. Abdulganeeva, K. B. Erzhanov, and T. S. Sadykov, J. Gen, Chem. USSR, 1986, 56, 1100. 11. E. W . Logusch, Tetrahedron Lett., 1986, 27, 5935. 12. D. W. Norbeck, J. B. Kramer, and P. A. Lartey, J. Org. Chem., 1987, 5 2 , 2174. 13. A. Hafner, W. von Philipsborn, and A. Salzer, Helv. Chim. Acta, 1986, 69, 1757. 14. R. M. Acheson, P. J. Ansell, and J. R. Murray, J. Chem. Res. (S), 1986, 378.

116

Organophosphorus Chemist?

15. G. Keglevich, I. Petnehazy, L. TUke, and H. R. Hudson, Phosphorus Sulfur, 1987, 29, 341. 16. P. Majewski, Synthesis, 1987, 555. 17. C . Yuan and Y. Qi, Synthesis, 1986, 821. 18. F. S. Mukhametov, E. E. Korshin, R. L. Korshunov, Ya. Ya. Efremov, and T. A. Zyablikova, J. Cen. Chem. USSR, 1986, 56, 1574. 19. V. A. Al'fonsov, I. S. Nizamov, E. S. Batyeva, and A . N. Pudovik, J. Gen. Chem. USSR, 1986, 5 6 , 630. 20. A.-M. Caminade, F. el Khatib, A. Baceiredo, and M. Koenig, Phosphorus Sulfur, 1987, 29, 365. 21. W. Dabkowski and J. Michalski, J. Chem. SOC., Chem. Commun., 1987, 755. 22. S. Bakkas, M. Julliard, and M. Chanon, Tetrahedron, 1987, 43, 501. 23. 0. G. Sinyashin, Sh. A. Karimullin, V. P. Kostin, E. S. Batyeva, and A. N. Pudovik, J. Gen. Chem. USSR, 1986, 56, 1505. 24. Z. Tashma, I. Ringel, J. Deutsch, S. Cohen, M. Weisz, and J. Katzhendler, Nucleosides Nucleotides, 1987, 6 , 589. 25. J.-L. Montero, J.-L. Clavel, and J.-L. Imbach, Tetrahedron Lett., 1987, 2 8 , 1163. 26. M. J. Pulwer and T. M. Balthazor, Synth. Commun., 1986, 16, 733. 27. G. Bettermann, D. Schomburg, and R. Schmutzler, Phosphorus Sulfur, 1986, 2 8 , 327. 28. A. M. Cooke, B. V. L. Potter, and R. Gigg, Tetrahedron Lett., 1987, 2 8 , 2305; M. R. Hamblin, B. V. L. Potter, and R. Gigg, J. Chem. SOC., Chem. Commun., 1987, 626. 29. C. E. Dreef, G. A. van der Marel, and J. H. van Boom, Recl. Trav. Chim. Pays-Bas, 1987, 106, 161. 30. C. B. Reese and J. G. Ward, Tetrahedron Lett., 1987, 28, 2309. 31. J. Svara, E. Fluck, J. J. Stezowski, and A. Maier, 2 . Anorg. Allgem. Chem., 1987, 545, 47. 32. M. M. Kabachnik, 2. S. Novikova, E. G. Neganova, and I. F. Lutsenko, J. Gen. Chem. USSR, 1986, 5 6 , 688. 33. D. M. Malenko and A. D. Sinitsa, J. Gen. Chem. USSR, 1986, 5 6 , 195. 34. P. J. Garegg, J. Stawinski, and R. Stremberg, J. Org. Chem., 1987, 5 2 , 284.

4: Tervalent Phosphorus Acids

117

35. D. W. Chasar, J. P .

Fackler, A. M. Mazany, R. A . Komoroski, and W. J. Kroenke, J. Am. Chem. SOC., 1986, 108, 5956. 36. E. E. Nifant'ev, T. S . Kukhareva, 1. A. Soldatova, and T. G. Chukbar, J. Gen. Chem. USSR, 1986, 56, 2199. 37. T. Pollok and H. Schmidbaur, Tetrahedron Lett., 1987, 28, 1085. 38. A . D. Sinitsa, D. M. Malenko, L. A. Repina, R.

A . Loktionova, and A. K. Shurubura, J. Gen. Chem. USSR, 1986, 56, 1113. 39. D. M. Malenko and A . D. Sinitsa, J. Gen. Chem. USSR, 1986, 56, 1467. 40. E. A. Monin, Z . S. Novikova, A. A. Borisenko, M. M. Kabachnik, 1. F. Lutsenko, A . N. Chernega, M. Yu. Antipin, and Yu. T. Struchkov, J. Gen. Chem. USSR, 1986, 56, 1753. 41. D. J. Brauer, F. Gol, S . Hietkamp, and 0. Stelzer, Chem.

Ber., 1986, 119, 2767.

L. Thompson, A . Tarassoli, R. C. Haltiwanger, and A . D. Norman, Inorg. Chem., 1987, 26, 684. 43. J. M. Barendt, R. C. Haltiwanger, and A. D. Norman, Inorg. Chem., 1986, 25, 4323. 44. C. Bourdieu and A. Foucaud, Tetrahedron Lett., 1986, 27, 42. M.

4725.

45. C. Chiriac, Rev. Roum. Chim., 1987, 32, 29.

46. G. Baccolini and C. Sandali, J. Chem. SOC., Chem. Commun., 1987, 788; G. Baccolini, R. Dalpozzo, and E. Errani, Tetrahedron, 1987, 43, 2755. 47. L. D. Quin and G. Keglevich, J. Chem. SOC., Perkin Trans. 11, 1986, 1029. 48. J. Szewczyk and L. 0. Quin, J. Org. Chem., 1987, 52, 1190. 49. B. H. Dahl, J. Nielsen, and 0. Dahl, Nucleic Acids Res., 1987, 15, 1729.

50. W. Bannwarth and A. Trzeciak, Helv. 175.

Chim. Acta, 1987, 70,

51. T. Horn and M. S. Urdea, DNA, 1986, 5, 421. 52. J. W. Perich and R. B. Johns, Tetrahedron Lett., 101. 53. T. Horn and M. S. Urdea, Tetrahedron Lett.,

1987, 28,

1986, 27, 4705.

54. B. A . Connolly, Tetrahedron Lett., 1987, 28, 463. 55. J. M. Coull, H. L. Weith, and R. Bischoff, Tetrahedron Lett., 1986, 27, 3991. 56. B. A . Connolly, Nucleic Acids Re$.,

1987, 15, 3131.

57. F. Seela and K. Kaiser, Nucleic Acids Res., 1987, 15, 3113.

118

Organophosphorus Chumistp

58. J. N. Kremsky, J. L. Wooters, J. P. Dougherty, R. E. Meyers, M. Collins, and E. L. Brown, Nucleic Acids Res., 1987, 15, 2891. 59. J. W. Perich, P. F. Alewood, and R. B. Johns, Synthesis, 1986, 572. 60. Y. Hayakawa, S. Wakabayashi, T. Nobori, and R. Noyori, Tetrahedron Lett., 1987, 28, 2259. 61. J. P. G. Hermans, E. de Vroom, C. J. J. Elie, G . A . van der Marel, and J. H. van Boom, Recl. Trav. Chim. Pays-Bas, 1986, 105, 510. 62. P. Westerduin, G. H. Veeneman, G . A. van der Marel, and J. H. van Boom, Tetrahedron Lett., 1986, 27, 6271. 63. E. Kuyl-Yeheskiely, C. M. Tromp, A. H. Schaeffer, G . A . van der Marel, and J. H. van Boom, Nucleic Acids Res., 1987, 15, 1807. 64. J. Nlelsen and 0. Dahl, Nucleic Acids Res., 1987, 15, 3626. 65. J. Nielsen, M. Taagaard, J. E. Marugg, J. H. van Boom, and 0 . Dahl, Nucleic Acids Res., 1986, 14, 7391. 66. R. Kierzek, M. H. Caruthers, C. E. Longfellow, D. Swinton, D. H. Turner, and S. M. Freier, Biochemistry, 1986, 25, 7840. 67. H. Tanimura, M. Sekine, an8 T. Hata, Chem. Lett., 1987, 1057. 68. J. E . Marugg, J. Nielsen, 0. Dahl, A . Burik, G. A. van der Marel, and J. H. van Boom, Recl. Trav. Chim. Pays-Bas, 1987, 106, 72. 69. T. Tanaka, K.-I. Fujino, S. Tamatsukuri, and M. Ikehara, Chem. Pharm. Bull. Tokyo, 1986, 34, 4126; T. Tanaka, S. Tamatsukuri, and M. Ikehara, Nucleic Acids Res., 1986, 14, 6265. 70. S. Hamamoto and H. Takaku, Chem. Lett., 1986, 1401. 71. K. A. Gallo, K.-L. Shao, L. R. Phillips, J. B. Regan, M. Koziolkiewicz, B. Uznanski, W. J. Stec, and G. Zon, Nucleic Acids Res., 1986, 14, 7405. 72. M. Fujii, H. Nagai, M. Sekine, and T. Hata, J. Am. Chem. SOC. 1986, 108, 3832. 73. M. Fujii, H. Nagal, M. Sekine, and T. Hata, Tetrahedron Lett., 1987, 1435. 74. B. C. Froehler, P. G. Ng, and M. D. Matteucci, Nucleic Acids Res., 1986, 14, 5399. 75. P. J. Garegg, I. Lindh, T. Regberg, J. Stawinski, and R. Strbmberg, Tetrahedron Lett., 1986, 27, 4051. 76. P. J. Garegg, I. Lindh, T. Regberg, J. Stawinski, and R. Strbnberg, Tetrahedron Lett., 1986, 27, 4055.

4: Tervalenf Phosphorus Acids

119

77. E. de Vroom, M. L. Spierenburg, C. E. Dreef, G. A. van d e r Marel, and J. H. van Boom, Recl. Trav. Chim. Pays-Bas, 1987, 106, 65. 78. P. Westerduin, G. H. Veeneman, Y. Pennings, G . A . van der Marel, and J. H. van Boom, Tetrahedron Lett., 1987, 28, 1557. 79. M. J. Damha and K. K. Ogilvie, J. Org. Chem., 1986, 51, 3559. 80. J. BUske, E. Niecke, E. Ocando-Mavarez, J.-P. Majoral, and G. Bertrand, Inorg. Chem., 1986, 25, 2695. Heinicke, E. Nietzschmann, and A. Tzschach, 3 . 81. J. Organometal. Chem., 1986, 310, C17. 82. A. Karim, A. Mortreux, and F. Petit, J. Organometal. Chem., 1986, 312, 375; A. Karim, A. Mortreux, F. Petit, G . Buono, G. Pfeiffer, and C. Siv, J. Organometal. Chem., 1986, 317, 93. 83. E. Cesartotti, A. Chiesa, L. Prati, and L. Colombo, Gazz. Chim. Ital., 1987, 117, 129. 84. H. Pracejus, G . Pracejus, and B. Costicella, J. Prakt. Chem., 1987, 329, 235. 85. R. Ahlrichs, R. Becherer, M. Binnewies, H. Borrmann, M. Lakenbrink, S. Schunck, and H. SchnUckel, J. Am. Chem. SOC., 1986, 108, 7905. 86. K. Karaghiosoff, C. Cleve, and A. Schmidpeter, Phosphorus Sulfur, 1986, 28, 289. 87. K. Karaghiosoff, W. S. Sheldrick, and A . Schmidpeter, Chem. Ber., 1986, 119, 3213. 88. B. A . Arbuzov, E. N. Dianova, R. T. Galiaskarova, and A . Schmidpeter, Chem. Ber., 1987, 120, 597. 89. P. B. Hitchcock, M. F. Lappert, A . K. Rai, and H. D. Williams, J. Chem. SOC., Chem. Commun., 1986, 1633. 90. L. N. Markovskii, V. D. Romanenko, E. 0. Klebanskii, M. I. Povolotskii, A. N. Chernega, M. Yu Antipin, and Yu. T. Struchkov, J. Gen. Chem. USSR, 1986, 56, 1524. 91. U. Dressler, E. Niecke, S . Pohl, W. Saak, W . W. Schoeller, and H.-G. Schafer, J. Chem. SOC., Chem. Commun., 1986, 1086. 92. V. D. Romanenko, A . B. Drapailo, A . V. Ruban, and L. N. Markovskii, J. Gen. Chem. USSR, 1986, 56, 2473. 93. L. N. Markovskii, V. D. Romanenko, A. 8. Drapailo, A. V. Ruban, A. N. Chernega, M. Yu. Antipin, and Yu. T. Struchkov, J. Gen. Chem. USSR, 1986, 56, 1969. 94. E. Niecke, M. Lysek, and E. Symalla, Chimia, 1986, 40, 202. 95. D. Cudat, E. Niecke, B. Krebs, and M. Dartmann, Organometallics, 1986, 5, 2376.

120

Organophosphorus Chemistry

96. F. Zurmiilen and M. 1987, 26, 83.

Regitz,

97. S. A. Weissman and S. C. 28, 603.

Fmgew. Chem.,

Int. Ed.

Engl.,

Baxter, Tetrahedron Lett.,

1987,

98. S . A. Weissman, S. G. Baxter, A. M. Arif, and A. H. Cowley, J. Chem. SOC., Chem. Commun., 1986, 1081. 99. M. R. Mazieres, C. Roques, M. Sanchez, J.-P. Majoral, and R.

Wolf, Tetrahedron, 1987, 43, 2109. 100.P. Jutzi, U. Meyer, B. Krebs, and M. Dartmann, Angew. Chem., Int. Ed. Engl., 1986, 25, 919.

101.A. H. Cowley, J. E. Kilduff, N. C. Norman, and M. Pakulski, J. Chem. SOC.,

102.G.

Dalton Trans., 1986, 1801.

Etemad-Moghadam,

J.

Bellan,

Tetrahedron, 1987, 43, 1793.

C.

Tachon,

and M.

103.5. I. G. Cadogan, A. H. Cowley, I. Gosney, M. S. Yaslek, J. Chem. SOC.,

104.K.

Schwetlick, T.

Chem.,

Kdnig,

1986, 26, 360.

Koenig,

Pakulski, and

Chem. Commun., 1986, 1685. C.

Rilger, and

J.

Pionteck, 2 .

105.W. G. Bentrude, S.-G. Lee, K. Akutagawa, W.-Z. Charbonnel, J. Am. Chem. SOC., 1987, 109, 1577. 106.D. H. R. Barton, D. Bridon, Lett., 1986, 27, 4309.

and

S.

Z.

Ye,

and Y.

Zard, Tetrahedron

5

Quinquevalent Phosphorus Acids BY R. S . EDMUNDSON

The relative activities in the areas of, on the one hand,phosphoric acid chemistry, and on the other, that of phosphonic and phosphinic acids, are much as they were during the period covered by the previous Keport. Two reviews, the first describing halogenophilic reactions of four- and f ive-coordinate phosphorus, and the second, describing the chemistry of phosphorylated isothiocyanates and derived compounds,2 cover aspects of the chemistry of all the groups of acids included in the present Chapter.

1. Phosphoric Acids and their Derivatives.

1.1 Synthesis of Phosphoric Acids and their Derivatives.-Several conventional reaccion systems based on perfluorinated alcohols have provided new fluorinated compounds, and it is noteworthy that the oxidation of the tervalent chlorides RfOPC12 by N204 is recorded as yielding the dimeric dianhydrides (1,3,2,4-dioxadiphosphetane 2,4-dioxides) ( 1 ) which presumably exist in the trans form. The compounds (2; R=OH or C 1 ) and ( 3;R=OH o r Cl 1 were 4 prepared conventionally from the diol. The electrochemical oxidation of mixtures of trialkyl phosphite (R1O)3P and dialkyl phosphate salt (R20)2P(0)OM yields the pyrophospha te ( R1O f 2 P ( 0)OP(01 ( O H 2 1 almost quantitatively . A procedure for the preparation of alkyl dihydrogen phosphates based on the generation of metaphosphate from a phosphonic acid is referred to later. Monoisoprenoid pyrophosphates have been prepared by the interaction of homoallylic tosylates and tris(tetrabuty1ammonium) pyrophosphate, as well as from the same phosphate reagent and allylic halides; derivatives of methanedi- and difluoroethanediphosphonic acids were similarly prepared. A reaction between mono(tetrabuty1ammonium) phosphate and allylic sulphonium salts catalyzed by C u ( 1 ) salts allows the preparation of monoisoprene dihydrogen phosphates without the involvement of lengthy purification procedures. 121

122

Orgunophosphorus Chemistry

phIo\ Me

Me

S

1

Ph

Me

Reagents

Me

S

Me

A"

OR NHzMe

I ,

R O - , R O H ; ii. H2'80.CF3COOH; 1 1 t . M e 3 S i l or

V,

R O H . CF-jCOOH

Scheme 1

NH3(l), N o , tv.L i"0H

5: Quinquevalent Phosphorus Acids

123

A newly described procedure for the synthesis of the mixed anhydrides (R'O) (R20)P(O)OSO2R3 involves the interaction of the sulphonyl chlorides R3SO2C1 and the stannyl esters (RIO)(R20)P(0)DSnMe3 at 20° in dichloromethane in the presence of 1-methylimidazole. Mixed phosphoric-carboxylic anhydrides are 8 a l s o preparable by this route. A useful synthesis of unsymmetrical dithiopyrophosphates has been explored in the 1,3,2-dioxaphosphorinane series;dialkyl (including cyclic) trimethylsilyl phosphites and dialkoxythiophosphoranesulphenyl chlorides react together with full stereospecificity to give good quality products in high yield^.^ -O,O,O-Triaryl _ thiophosphates have been prepared using phase-transfer techniques." Isotopically chiral [ l6O, (or I 7 O ) jthiophosphate monoesters of either (Elp o r ( S ) p absolute configuration have been synthesized by methods similar to those employed in previously published routes to isotopically chiral phosphate esters, but here described in f u l l because o f the experimental difficulties encountered (Scheme 1 ).I1 Reports have appeared on the synthesis of the 5-alkenyl phosphorothioates ( 4 ) by the phosphorylation of monothioketones,12 and of the [~3-arylamino-2-dialkoxyphosphinothioyl~thio]crotonic esters ( 5 ) from the appropriate chloroalkene and metal dithiophosphate salt . I 3 In the enolization of unsymmetrical ketones under kinetic conditions, i t is known that loss of proton occurs from the less substituted a - C to give the l e s s strongly branched enolate which, under thermodynamic conditions, then yields the more strongly branched enolate anion. The phosphorylation of phosphine enols ( and their sulphides) ( 6 ; n=O or 1 ; R=iPr) and phosphoric amides ( 6 ; n=O or 1 ; R =Et2N) and esters ( 6 ; n=O, R ZOEt) has been examined with a view to the synthesis of enol phosphates possessing a second phosphorus centre. It was found that the isomerization of the one enolate ( 7 ) into the other ( 8 ) depended on the electron-acceptor power and the valency of the original phosphorus centre. Thus, products of type ( 9 ) were obtained for ( 6 ; n=O, K=Et2N), type ( 1 0 ) from ( 6 ; n=O, R=OEt; n=l, R = i P r or 14 Et2N), and a mixture of types ( 9 ) and ( 1 0 ) from ( 6 ; n=O;R=iPr). Compounds of types (11),15(12),16and ( 1 3 ) and (14)'~ have been prepared from the appropriate silicon, germanium, or tellurium halide and a s a l c of a dithiophosphoric acid. The compounds were for the most part characterized spectroscopically, but the structures of ( 1 2 ; R 1=Me, R2=Ph, n=3), ( 1 3 ; X=Br,

124

Organophosphorus Chemistry

S

0

II ( R'O),PSCR2=CHCOR3

It

"kS

ArNH

( OR) COOEt

125

5: Quinquevalent Phosphorus Acids

S

S

Me

II

II

R' TeX2 [ SP(OR2)2]

R' 2Te[ SP(OR2)212 R1 = a r y l , R Z = a l k y l

x = C l ,Br

R' = aryl RZ = alkyl

(15)

(14)

(13)

0

ox

II

P

( TolNMe), P(OEt),,,

(18)

(16)

0

II

NH-

(Me3Si0)2P-NHf6-NH)

II

0

(19) n = o - 4

0 II

P(OSiMe3)2

n

0

OSiMe3 0

(Me,SiO),

0

(20) n = 0 - 4

126

Organophosphorus Chemisrp

R 1 =C6H40Me-4, R 2=Me) and (14; R l - p h , R2 Me) were determined by X-ray analysis. 5,5-Dimethyl-2,4-dioxo-l,3,2-oxazaphosphospholidines ( 1 5 ) are obtained when the acid chlorides R1P(0)Cl2 and the amide HOCMe CONHMe interact in the presence of AgBF4, and also for (15;R? =OPh) by the action of heat on the product from hexamethyldisilazane and the phosphoramidate ( PhO) (RNH)P(0)OCMe2COOEt.18' A l l four compounds (16; X , Y = 0 , O ; 0 , s ; S , O ; S , S ) have been identified as products from the reaction between Me2NP(S)C12 and salicylanilide. l 9 In a continuation of a study of the reactions which occur when aromatic amines are acted upon by phosphoryl chlorides, the compounds (17;n_=1)and ( 1 7 ; = = 1 and 2) have been obtained from the ortho and isomers, respectively, of N,N-dimethyltoluidine. Analogous compounds have also been obtained from the para isomer from which, additionally, the cyclic compound (18; X=O, Y=C1) is formed; the corresponding cyclic thiophosphoryl chloride was also isolated from a reaction using PSC13.20 Diastereoisomers of 6 - p h e n y l c y c l o p h o s p h a m i d e have been characterized.21 The reaction between hexamethyldisilazane and P4Ol0 yields a mixture of nitrogen-containing ( 1 9 ) and nitrogen-free (20) polyphosphorus compounds; the two groups can be separated and fractionated. A similar reaction using hexamethyldisilathiane yields the tris(trimethylsily1) esters (Me3Si0)3P(X) ( X = O or S ) .22

1.2 Reactions and uses of Phosphoric Acids and their Derivatives.Bis(5-nitro-2-pyridinyl) 2,2,2-trichloroethyl phosphate in acetonitrile has been employed as a reagent for the dehydration 23 of 6-amino acids to give 6-lactams. Diels-Alder reactions can be carried out using transi ( d i e t h o x y p h o s p h i n y l ) o x y ; - 1 , 3 - p e n t a d i e n e in the presence of Lewis acids.24 Whilst the phosphonate (22) tends to be formed preferentially by the reaction between triethyl phosphite and 9-dichloroatetone at high temperatures, the reaction at 100" furnishes 3-chloro-2-i (diethoxyphosphiny1)oxyj-1-propene (21); the use of this enol phosphate in a new 'one-pot' cyclopentenone annelation sequence has been described, and is exemplified in Scheme 2 . The reaction between the cyclohexanone (23;R=COOMe) and (21) yields the phosphate (24;R=COOMe), from which the phosphate group can be removed by acidolysis to give (25;R=COOMe),but

127

5: Quinquevalent Phosphorus Acids

0

R

II

R = COOMe

0

R = H

I,

(21)

II,III

(23)

(24)

ii, iii ,vi

R

R

I

Reagents

i,K H ,TH F,H MPA. l i , L I N P r 1 2 , T H F , IV,

5.1. KOH a q , h e a t ,

VI,

111.

(21). (Ph3PiPd,THF,

10'1. H C I . a c e t o n e , h e a t ,

VI,

E t O H , heat

10.L NaOH aq

Scheme 2

CN

0

J

iii

CN

Reagents: i . ( Et O ) zP( O)CN, Li CN; i i . BF3. E t Z O . i i i , O . S M HCI a q

Scheme 3

,

128

Organophosphorus Chemistry

under basic conditions cyclization occurs to give the cyclopentenone (26). The latter is also obtainable from (23) by the 'one-pot' procedure. 25 The rearrangement reactions of cyanophosphates have been further examined. The starting materials, (281, are conveniently obtained, sometimes in situ, by the reaction between an enone and diethyl phosphorocyanidate in the presence of LiCN. Under the influence of boron trifluoride etherate, rearrangement of the esters (28) occurs to give the isomeric phosphates (29;Scheme 3 1 , from which the phosphate group can be removed by mild acidolysis. In certain cases, other isomeric esters e.g. ( 3 0 ) appear as the normal products of the initial step, and compounds of type (29; -n=l) are obtainable from ( 2 7 ; ~ = 1 by ) modification of the experimental conditions.26 It has been possible to prepare dihydrofuranones from the products of the rearrangement of acyclic enone cyanophosphates; thus ( 3 1 ) gives (33;R=Me or Ph) via (32). It form of the is of interest that i t is specifically the cyanophosphate ( 3 2 ) which is formed, leading to the supposition that the rearrangement occurs as in S ~ h e m e 4 . ~ 'If benzene is added to the reaction mixture from (31;R=Me) the compounds (34; R1=CN, R2=Ph)(50%) and (34; R1=Ph, R2=CN)(5%) can be isolated each in the ( 2 ) form. In a behaviour reminiscent of that of fluorinated alcohols, pentafluorophenol generates pentafluorophenyl ethers, rather than esters, in its reactions with fluorinated benzylic phosphorodichloridates?Differences in reactivity at primary a n d secondary carbon centres when p-toluenesulphonic acid acts upon trialkyl phosphates in solution, allows the selective removal of a secondary 29 alkyl group in the presence of a primary alkyl group. Consideration has been given to the design of potential phosphorylating agent molecules, particularly compounds based on the heterosubstituted dihydrophosphole systems (35) where A= O(generally), B=C1 or OR, X=CH or CMe, D=H or C 1 , or XD is part of another (fused) hetero ring, and Y and Z are 0, S , or NMe, derived from enediols, a-hydroxy acids and a-mercaptoacids. 30 The (many) authors conclude that there is still scope for the development of new reagents. The rearrangement of phosphates under the influence of basic reagents to give compounds with P-C bonds has been further exemplified by the report that triaryl phosphates may thus be converted into tris( 2-hydroxyaryl Iphosphine oxides. 31 A study has

(z)

5: Quinquevalent Phosphorus Acids

129

OE t

OE t Scheme 4

L

RZ

(35)

(34)

OH

Me

Reagents: i , LiNPri2, toluene at

-

7 8 O C , i i . CF3COOH at

Scheme 5

-

78OC

130

Organophosphorus Chemistry

been carried out on the phosphate-phosphonate rearrangement which is illustrated in Scheme 5 . Enantiornerically pure ( s ) - ( t ) - and (S)-(-)-l-phenylethanol were converted into enantiomerically and ( S ) - ( - ) phosphates. When the ( H I - ( + ) pure ( & I - ( + ) stereoisomer ( 3 6 ) was subjected to the action of lithium diisopropylamide, the ( S ) isomer of the phosphonate (37) was obtained. The configuration of the product was ascertained by an X-ray analysis of the (El-1-phenylethylammoniurn salt of resolved PhMeC(OH)P(O)(OEt)OH, in turn prepared via its trimethylsilyl ester and its subsequent conversion into ( 3 7 ) with diazoethane. The rearrangement occurs with retention of configuration at carbon and with 95% e.e. 32 Bis (trimethylsilyl) peroxide oxidizes tervalent phosphorus compounds with retention of configuration at phosphorus, but oxidatively desulphurizes thiophosphoryl compounds with inversion of configuration.33 Interest continues unabated in the fine details of the mechanisms of nucleophilic displacements at phosphoryl centres in both acyclic and cyclic systems. A comparison of the molecular parameters of an 'average' phosphate triester with those of an 'average' phosphate monoester monoanion has revealed some interesting features; in particular, the P - 0 bond lengths and OPO bond angles in the monoanion are compatible with an early stage ( a 20-30% advancement was suggested) in the fragmentation of R O P ( O ) ( O H I O - into ROH and metaphosphate anion.34 Russian workers have carried out a theoretical study on the reactions between metaphosphate anion and nucleophiles. 3 5 Evidence €or the existence, however transitory, of the thiornetaphosphate anion, is now being sought. Solvolysis of 4-nitrophenyl ( R ) - [ l 6 O , l 8 0 ] thiophosphate dianion in ethanol at 0" gives ethyl [ l60,l80jthiophosphate, the enantiomeric content of which corresponded to thiophosphoryl transfer with 80% racemization and 20% inversion. The simplest interpretation of this result is that the reaction proceeds largely through a thiometaphosphate anion ( 38 1 . 36 Mention was made in last year's Report of a controversy which has developed around details of the mechantsm of hydrolysis of ethylene methyl phosphate 139) which, fundamentally, can occur either endocyclically to give ( 4 0 ) or exocyclically to give (41). The controversy is concerned essentially with the extent of methanol formation at higher concentrations of base or of (39)

5 : Quinquevalent Phosphorus Acids

0

11 HOCHtCHzOP-OMe

1 OH

16

180//

(38)

+

(

39)

U

II,OMe

HOCH2CH20P

‘0-

__t

0 11

0

0-

0-

11

HOCH,CH, OPOCH2CHz0POMe 1 1 (42)

Scheme 6

0

0

II

HOCH2 C H2 OP-OMe

I

0

II

II

HO__+

- McOH

HOCH2 CH20POCH2CH 20P-OMe 1

1

0-

OMe

-0

0

0

[:;&CH2CH2OP-OMeII1 0Scheme 7

132

Organophosphorus Chemistry

and s o with the relative extents of endo and exo-cyclic cleavage. Kluger et a1 (see Organophosphorus Chem., 18, 141) subscribe to the view that under such conditions the source of increased methanol formation stems from increased exocyclic fission. Gorenstein et a137have now repeated their earlier work and also Kluger's experiments. They showed that at higher alkali concentrations the formation of methanol can increase quite substantially, and they attribute this to a dimerization ( and oligomerization) reaction leading to (42). According to Kluger et a1 the formation of (42) occurs as indicated in Scheme 6 , but the process favoured by Gorenstein et a1 is that shown in Scheme 7. Gorenstein et a1 maintain that the stereoelectronic theory continues as a viable explanation for a 'significant' portion of the rate acceleration in five-membered cyclic phosphate esters (see also ref. 171 ) . The stereoelectronic factor has also been called upon to account, at least in part, for the rates of hydrolysis of the bicyclic esters (X)P(OCH2j3CMe (X=O or S ) ; the rate enhancements relative t o the triethyl esters are 5.2 x lo3 when X=O, and 8.1 x lo2 for X=S. The expected monocyclic 1,3,2-dioxaphosphorinane hydrolysis products were determined spectroscopically. For the bicyclic esters, the lowering of the activation energy on formation of the transition state cannot be ascribed totally to the release of ring strain. In the transition state (43) the two equatorial ring oxygens have lone electron pairs approximately antiperiplanar to the breaking apical P-0 bond, whereas such a configuration for the acyclic triethyl ester would require the 'freezing' of one conformation which, entropically, is not a favoured process. 38 Coming to the fore this year has been a comparison between the stereochemistries of nucleophilic substitutions at silicon and phosphorus, reviewed in two conference papers. 39 '40 The authors lay stressonthe fact that the concepts proposed by Westheimer concerning the formation of pentaco-ordinate intermediates, and their pseudorotation and degradation were derived from studies on the hydrolysis of cyclic phosphate (as well as phosphonate and ph0sphinate)esters , but have been applied to a much wider range of substitution reactions of both cyclic and acyclic compounds with the assumption that those concepts, (which originally dealt only with oxygen-bonded groups) still apply. The notion that all phosphorus compounds based on the

5: Quinquevalent Phosphorus Acids

133

five-membered ring react with nucleophiles faster than do similar compounds with six-membered rings, or acyclic compounds, has also been questioned. From a study of the behaviour of the cyclic phosphoryl chlorides (44;R = C 1 , nzl or 21, and also of diethyl phosphorochloridate, towards H 2 0 , EtOH, PhOH, and Et2NH, i t is evident that for the five-membered ring compound the reaction rates are essentially independent of the nature o f the nucleophile, and the large kinetic factor essential to the elaboration of Westheirner's concepts is not confirmed when the attacking nucleophile and the leaving group are different. A wide range of reaction rates was observed for both the six-membered ring compound, and the acyclic ester. F o r any given leaving group, the reactivity is related to the stereochemistry of the reaction, as i t is for silicon compounds. The conclusion reached was that the hydrolysis of cyclic phosphorus esters represents a special case in the overall picture of the nucleophilic mechanistics, and as such, they behave differently from other reactions and it is difficult to extend Ilestheimer's co?ceFts to these compounds. 41 The polymerization of monomeric cyclic esters of phosphoric acid has been discussed.42 The compound ( 1 5 ; R1=OPh, R 2=Me) reacts extremely rapidly with alcohols. Thus,with methanol initial exocyclic displacement of phenol is followed by ring opening by P-N bond fission and the formation of (45; R1=OMe, R2=Me). Reaction of the same substrate with diethylamine affords ( 1 5 ; R1=NEt2, R2=Me) but subsequent ring opening does not take place in the presence of an excess of the nucleophile, although ring opening does occur when the product is acted upon by methanol. 18 The reactions between the phosphorochloridate (46;R-Cl) and imidazole or benzimidazole yield single products of different stereochemistries, and arguments have been presented to suggest that the former reaction occurs with retention of configuration. Only the benzimidazole derivative isomerizes when recrystallized or melted. Not surpri-singly, both phosphoramidates undergo fast (in reality, almost instantaneous) acid-catalyzed methanolysis. but evidence could not be advanced for the participation of a phosphaacyclium cation in such reactions.43

Dibutyl ~-(1,5-dihydro-2,3-dimethyl-5-oxo-l-phenylpyrazol-4-y1)phosphoramidate has been prepared as a new extractant for Sc(II1) and H g ( I 1 ).44 Uialkyl phosphorohydrazidates react with

Organophosphorus Chemistry

134

Reagents.

I ,

NHtNH2 ; i i , ButOCL, ButOH

Scheme 8

0 II

0

II

F P-NE t - PF,

t Me3SiOMe

(47)

1

0 II

F, PNEt SiMe3

Mc3SiOMc

Me0 - P

II 0

1

- Me3SiF

NF

'NEt SiMe,

+

0

II F, POM e

1

Me3SiOMe -Mc3SiF

(

PF

II 0

5: Quinquevulenr Phosphorus Acids

-p-benzoquinone

13s

in cold dilute solution in non-polar solvents to give the quinone dihydrazide, not isolable, however, at room temperature, when the products include dialkyl hydrogen phosphonate and q ~ i n h y d r o n e . ~The ~ simple sequence given in Scheme 8, based on the formation and decomposition of a phosphorohydrazidate, allows stereoisomeric interconversion for the phosphorochloridate.46 The chemistry of phosphoric hydrazides has been reviewed.47 The fission o f P-N bonds in imidodiphosphoryl difluorities (47) by the action of alkoxysilanes has been observed.48 The reaction between carbamates and phosphoryl chlorides contrasts with that which occurs using phosphinic chlorides. The reaction between (48;R=Bu) and (49;M-H) can occur in the presence of Et3N, and gives (SO;R=Bu)whereas the use of the phosphoryl chloride (48;K-OBu) necessitates the involvement of the salt (49; M-Na) N-phosphorylated derivative (50;R-Bu) is formed; when only the under the same conditions, the phosphinic chloride yields a mixture of land 0 (51; R=Bu) d e r i v a t i ~ e s . ~ ~ Studies have continued on the migrations of groups possessing the thiophosphoryl bond. In the reaction between 1 (52; R - H ) and (53; R2=Et, X = Y - S ) the use of tlc and 31P n.m.r. spectroscopy has allowed the detection o f (54, 55, and 57; R2=Et, X = Y = S ) ; the compounds (57) were the only isolable ones. The compounds (54; R1=H) are unstable and rearrange by S to N thiophosphoryl migration to (55), also unstable, and to (571, presumably (56). Overall, this latter rearrangement is a 1 - 4 S-to-0 thiophosphoryl migration, a type reported for the first time. The marked instability o f the compounds (54) and (55) when R1=H and X = Y = S precluded a more detailed examination of the individual stages and products, and the possibility of reducing the number of rearrangement pathways was considered. Using the iminoethers (52; R1=Me) the only isolable products were of the type ( 5 5 ; R1=Me, X = Y = S ) formed through the participation of (541, detected spectroscopically. For (52; R1=Pr) reaction with (53; R 2=Pr, X = Y = S ) gave the compound (54) as a mixture of (E) and (&'I forms, and stable up to 120". For the reactants ( 5 2 ; R1=Me) and ( 5 3 ; R2=Et or Pr, X=S, Y = O ) , reaction occurs at sulphur (product (54) ) which readily isomerizes to (55;R1=Me,X=S, Y = O ) . Products from the reaction of PhCONHOPr and (R0)2P(0)H-CC14-Et3N have the structure (54; R1=Pr, X = Y = O ) and show no tendency to isomerize, even during distillation. The rearrangements of benzohydroximoyl phosphates and thiophosphates are irreversible

136

Organophosphorus Chemistry

0

0 II R2PCI

PhNMCOOMe

(48)

(49)

II

R, PNPhCOOMe ( 50)

0

II R z POC(OMe)=NPh (51)

+

Ph-C =NOR’ I CI

( R20),PXYNa

(53)

(52)

+ ( E ) - (54)

I

(R’O), P-N-CPh II I II Y

( ZI - ( 5 4 )

(56)

I

Y

OR’X

(55)

X

II II ( R2 0 )PONHC ~ Ph

(57)

5: Quinquevalent Phosphorus Acids

137

at 150-180°, and clearly depend on the nature of the groups X , Y , and R2.50 In spite of having a structure which suggests the capability of 1-3 S-to-N rearrangement, the tris(phosphinothioy1thio)-s-triazenes (58; X=S) do not tautomerize. Rather, when heated they ( __ e.g. R2=OR1, R1=iPr, X = S ) decompose to g,O-dialkyl p h o s p h o r i s o t h i o c y a n a t i d o t h i o a t e s ( 5 9 ) . The treatment of the triazines with hydrogen dithiophosphates affords trithiopyrophosphates. When X = O , the tautomeric S-to-N migration is observable by 31P n.m.r. spectroscopy, and proceeds in a stepwise manner to give, ultimately, the N,_N,_N-tris(thiophosphory1ated) compound ( 6 0 ) . The rearrangement appears to be intermolecular as judged from crossover experiments. The predominance of either 5 or derivative depends on R1 and the !-substituted compound predominates when R 1 is iPr. 5; Alkylation (RCH2C1-Et3N) of the amides (61) can potentially yield the Ij, 2, or P-alkylated compounds, ( 6 2 1 , (631, or ( 6 4 ) . I n practice, for those compounds with E = C , the products are of type (631 but have the structure (64) when E is PhP. 52 The facile rearrangement of the unstable compounds (661 into the isolable (thiolurea derivatives ( 6 7 ) has previously been recorded. An increase in the size of the group R2 reduces the extent of the isomerism; depending also on the nature of the group R 2 further reaction with the acid ( 6 5 ) may give a mixture of thiophosphate and thiopyrophosphate esters. Using compounds in the 4-methyl-1,3,2-dioxaphosphorinane system, the formation of (67; R2=Ph or PhCH2) from the cyclic acid was shown to be stereospecific. The stereochemistries of the products were assigned on the basis of CD spectra and chemical correlations with 0-methyl 2-1-naphthyl hydrogen anilides in the same series. Using phosphorothioate, i t was demonstrated that the S-to-N migration 53 proceeds with full retention of configuration at phosphorus. The reaction between aryl cyanides and 2,O-dialkyl hydrogen dithiophosphates yields ultimately the N-phosphorylated compounds ( 6 9 ) rather than the addition compounds (68) - a report that contradicts earlier literature. Methylation of the compounds ( 6 9 ) as their tetrabutylammonium salts gives the N-methyl rather than the 5- or P-methylated products. 54

Organophosphorus Chemistry

138

-

@'yNTs*

Heat

N+fN

S

II

.

(PriOI2PSPr'

+

(59)

c-)

@ I

VNYS @fNYNh3 S

x

II

s II

$z P-NHE R' (61)

S II (PriO),PNCS

R~~P-N-ER' I CHzR (62) SCH2R

X

II I + F$2P-N=ER' (63 1

(60) XCHzR

RzZd=NER1

5: Quinquevalent Phosphorus Acids

Y

II

X

( R'O), P-NR2-C

+

S

II ( R ' 0l2PSH

+

R2 CN

[(R' O)P(=O)z]2

-

+

S

II

[(R'O)z P S C R h H ]

II

- NHR'

RZNHCSNHR2

-

s

II

s I1

( R'O)z PNHCR'

140

Organophosphorus Chemistry

2. Phosphonic and Phosphinic Acids and their Derivatives. 2.1.Synthesis of Phosphonic and Phosphinic Acids and their Derivatives.-The chemistry of the d i h y d r o p h e n o p h o s p h a z i n e s has been reviewed,55 and an account of arylphosphonic and arylphosphonothioic acids and their derivatives has been published. 56 Conventional Arbuzov reactions have been employed in the synthesis of E-phosphinothricin; 5 7 (aminoalkyl)phosphonic acids ( including alafosfalin) ; 58 a-phosphonylated derivatives of aryloxyacetic acids; 59 and 2-t-butyl 4-(diethoxyphosphiny1)-3oxobutanethioate, useful as a reagent in the synthesis of (E)-4-alkenyl-3-oxo esters and macrolides .60 Mixtures of esters of the three phosphonic acids (70-72), separable by chromatographic methods but not by distillation, are the products from reactions between dialkyl phenylphosphonites and propargyl bromide. 61 Keactions between tervalent phosphorus-containing formals and chloroformic esters lead L O the novel phosphinic esters (731, ana the bis(forma1)phosphinic esters (74) were obtained in a similar way.62 Interaction of dialkyl (trichloromethyl )phosphonates and trialkyl phosphites at 80-160" yields tetraalkyf esters of d i c h l o r o m e t h y l e n e d i p h o s p h o n i c acid, but the presence of an alcohol

in the reaction mixture results in the formation of trialkyl phosphate and dialkyl (dichloromethyl )phosphonate.6 3 The alkylation of diethyl phosphonate with allylic halides has been performed using phase transfer systems; possible isomerism to propenylphosphonic diesters is controlled by the nature of the base component. 64 lnternal arylat ion in the phosphinates ( 7 5) i s catalyzed by P d ( 0 ) and yields the cyclic phosphinates (76; ~ = 0 , 1or 2 ; R-lower alkyl or Ph).65 Ally1 acetates and carbonates react with dialkyl phosphonates in the presence of Ni(0) catalyst and _ N,O-bis( _ trimethylsilyl Iacetamide to give the phosphonates (77)." P d ( L 1 ) catalysts in combination wirh Ar3P and Et3N also assist in the C-arylation and C-vinylation of ethenylphosphonates on the B-carbon.67 The most novel observation in this area concerns the direct displacement of the trifluoromethoxy group on treatment of aryl trifluoromethyl ethers with Pd(PPh3I4-dialkyl phosphonate 68 l~-iiiechylrnor~l~oline to form d i a l k y l arylphosphonates. together with Experirnencal modifications to the synthesis of dialkyl phosphonates by the aFrect 5-phosphorylation of active methylene compounds have been ~uggested.'~A new procedure for the

C-

5: Quinquevalent Phosphorus Acids

0 I1

14 1

I

(72) A=C=CMe

OR

R’O, / Me3SiO

( 7 1 ) A = CH=C=CHz

(70) A = C H Z C S C H

Ph-P-A

PCH(OR’),

t

CICOORZ

4

II/

CH(OR’),

R ’ O P\ COOR‘

t

Me3SiCI

(73) (R10)2PCH(OR2)z

+

0 II

CICH(OR2),

R’OP[CH(OR2)2]2

4-

R’CI

(74)

0 II

+ (Et0)2P(0)H ph-YoCX Ph

0

R 1 IIC C H R 2 B r

Reagents:

-

OLi

Li

f?’C=C, I

i. ( M e 3 S i ) , N L i , then But

’

R2

Li

ti

; ii , ( R 3 0 ) 2 P ( 0 )C I

Scheme 9

0

II

ph-Yp(oE t)2 Ph (77)

0 II

(R30),PCHR2COR’

at

-

110’

I42

Organophosphorus Chemist q1

pnosphorylation of ketones commences with a-bromoketones which are treated so as to remove ( i n order) a proton and the halogen to furnish a diliihio enolate. The method (Scheme 91 complements the Arbuzov reaction since i t allows the use of secondary halogenoketones and phosphoryl halides with highly electronegative groups, both of which are features which tend to render application of the Arbuzov procedure unsuccessful. 7 0 ‘The conversion of alkenes into phosphonic dichlorides by treatment with PC15 followed by S O 2 has been extended to include enarnines.71 The sulphoxides ( 78 1 afford the alkenephosphonic aichlorides ,79).72 Acetic acid esters react with PC15 by attack at the carbonyl oxygen to give ( 8 0 ) and ( 8 1 1 , and also phosphoro(di)chloridates by attack at the ester oxygen.73 G-Acetyl-N1,N2 dimerhylisourea gives the compound (82) when treated with PCls f ol lowed by SO2. 74 Attempts to chlorophosphonylate acetylenes can result in the fission of C-C bonds. t-Butylphosphonic dichloride can be the main product when compounds of ‘Iype ( 8 3 ) are treated with PC13-02, and i t is the only product from 5,5-dimethyl-1,3-hexadiene. The 75 extent of C-C bond fission is much less for methylacetylenes. (Trichloromethy1)phosphonic dichloride adds to the 1,4-positions of 1,3-butadienes to give the phosphonic dichlorides (84).7 6 With the exception of trimethylphosphate, which suffers demethylation, trialkyl phosphates can be converted into dialkyl alkylphosphonates by the action of lithiumalkyls.7 7 When treated with C02, the anions from alkylphosphonic diesters afford a-[dialkoxyphosphinyl)carboxylic acids, from which the (2-oxoalky1)phosphonic diesters are obtainable.7 8 Lithiated phosphonates may be used to prepare (1-formylalky1)phosphonic diesters by the action of ethyl formate, also obtainable by a carbocationic route through ( 2,2-dialkyloxiranyl )phospnonic diesters. 7 9 Lithium diisopropylamide seems to be the current reagent of choice for the preparation of phosphonate carbanion reagents. The anions so generated have been used in the synthesis of (2-oxoalkyliphosphonic diesters,80 and in the preparation of a variety of a-mono- and aa-di-silylated alkylphosphonic diesters.81 ’ 82 ( a - S i l y l a l k y l i p h o s p h o n i c diesters can be alicylated their anions) but the ease of removal of the silyl group by ethanolic ethoxide is an interesting feature of their chemistry and suggests the possible use of the silyl group for protection purposes. Their use in the synthesis of vinylphosphonic esters has a l s o been

(e

5: Quinquevalent Phosphorus Acids

R'SCHR2Me

II 0

3pc'5,

143

t so2 ( R ' S ) R ~ C = C H P C I ~ P C I ~ __t

(78)

R' CH=CR2CR3=CHR4

0 II

+ CuCl

1

McCN

0 II

R ' C H C I C R 2 = C R 3 C H R 4 C C l t P C I2

(84)

0

>C H IPI C

R'S R2

12

144

Organophosphorus Chemistry

explored (Scheme 10). 8 2 (See also ref.. 153 for a discussion on the properties of phosphonate carbanions). 4-(Diethoxyphosphinyl)-l-penten-3-0ne (85) has been prepared and used as a kinetic ethyl vinyl ketone equivalent in the Robinson annelation reaction, but the ester has the unfortunate property of very rapid polymeritabi l i ty . 83 The treatment of trialkyl esters of 4 - c h l o r o - 2 - p h o s p h o n o b u t a n o i c acid with potassium affords esters of 1-phosphonocyclopropane-1-carboxylic acid.84 The Grignard reagent from diethyl (chloromethylIphosphonate has been obtained from diethyl (iodomethy1)phosphonate and isopropylmagnesium chloride in THF at - 7 O O and its reactions with halogens and PhSeHal studied. The reaction between dimethyl (1-1ithioethyl)phosphonate and (?)-(-)-menthy1 p t o l y l sulphinate leads to &he sulphinylated phosphonate with appreciable asymmetric inductive formacion of the (S),(S)sdiastereoisomer (86). 8 6 Several a-fluorinated methylphosphonic diesters have been prepared using chloro(di)fluoromethane. A useful synthesis of diethyl (f1uoromethyl)phosphonate involves direct fluorination of diethyl (1ithiomethyl)phosphonate with perchloryl fluoride at low temperatures. 87 Tetraalkyl ( fluoromethylene )diphosphonates have been employed in the synthesis of 1-fluoro-1-phosphonoalkenes and (1-fluoroalkyl)phosphonic acids (Scheme 11 1 . 8 8 Yet another procedure utilizes the ability of organocuprate reagents to cleave the enol phosphate moiety in the fluorinated l-[(diethoxyphosphinyl)oxyj-l-alkene-l-phosphonates ( 8 7 ) .89

Anodic methoxylation of (dialkoxyphosphiny1)methyl alkyl sulphides (88; X = S ) yields 0,S-acetals of (dialkoxyphosphiny1)formaldehyde (89; X=S) and the process may be taken a stage further t o give the ortho esters ( 9 0 ) of (dialkoxyphosphinyl)formic acid.90 The Grignard reagents derived from dialkyl 2-bromophenyl phosphates rearrange to yield the brornomagnesio derivatives of dialkyl (2-hydroxypheny1)phosphonates; a 2,4-dibromophenyl ester rearranged specifically to the 2-p0sition,~l The related migration of phosphorus from oxygen to carbon in enol phosphates can be achieved by che action of lithium diisopropylamide; an intermediate enol phosphate (91) i s known to be formed. 9 2 Allylic phosphites and related tervalent phosphorus compounds (92) undergo rearrangement in the presence of NiC12 to yield allyl93 phosphonates or -phosphinates together with fission products. New data on the addition of hydrophosphoryl compounds to multiple bonds have been reviewed.94 The addition of dialkyl

5: Quinquevalent Phosphorus Acids

0

II

( R’O), PCH, R 2

.1.11..

0

0 R2 II I

II

(R’ O),P-C-SiR3,

(R’0)2PCHR2SiR33

0

II (R’ 0),PCMeR2SiR33

0

~ 2 H=

1

i ,ii

vi

0 II

(R’ 0)2PCHMeR2

Reagents.

I,

LrNPr12,

VI,

11.

R3SiCI;

EtONa,EtOH

111,

H30+.

IV.

M c C H O . THF

at

-80’- v , M e 1 ,

Scheme 10

A! ---

Me

I

146

Organophosphorus Chemistry

0

! [ ( ~ ro)ZP],CHF i

II

R'

F

-%

0

II

( PriO)zPCHFCHR' R 2

1

R2

1

iv

IV

0 II

0 II

pH::

(HO), PCHFCHR'R2

F Reagents' i , BuLi ; ii, R1COR2 ; iii , H 2

- Pd ;

i v , MejSiBr , then McOH

Scheme 11

0 II (EtO)zPCHzXMe

MeOH

OMc Ze

XMe

II (EtO)zPCHz

\

OMe

McOH OMc

0

II

OMe

I

(Et0)2P-CH-XMe

I

OMe

0

5: Quinquevalent Phosphorus Acids

147

phosphonates to 1,l-diethoxy and 1,l-diethylthio-ethene, and t o enamines, has been studied from the point of view of the nature of the phosphonate. Such compounds based on the 1,3,2-dioxaphospholane ring react exothermically in non-polar solvents,and they are thus more reactive than diphenyl phosphonate and hydrogen phosphonates possessing six and seven-membered phosphoruscontaining rings. 9 5 (1-Hydroxyalky1)phosphonic diesters have been prepared in dry heterogeneous systems by the action of dialkyl phosphonates on aldehydes or ketones in the presence of y-A1203-KF. The same system converts a-chloroketones into epoxyphosphonates. 9 6 'he nature of the reaction product from dialkyl phosphonates and fluorinated carboxylic anhydrides appears to depend on the starting materials. Thus, whereas the reaction between lower dialkyl phosphonates and heavily fluorinated carboxylic anhydrides appears to give (93; R 2-CORf, R3=Rf),97 the use of bis(2,2,3,3-tetrafluoropropyl) phosphonate and trif luoroacet ic anhydride is thought to yield (93; R1=CHF2CF2CH2, R2=H, R 3 - C F 3 ) on che basis of the absence of characteristic ir carbonyl absorption. 98

Interesting phosphonic esters have been obtained from acetald01~~ and derivatives of D-erythrose and D-threose''' on reaction with dimethyl phosphonate. In the former case, the products are mixtures of the diastereoisomeric phosphonates (1%,3E)-(94; K1=OH, R2=H) and (lRS,3%)-(94; R1=H, R2=OH). These, in the presence of Et 3 N undergo intramolecular transesterification to give dfastereoisomeric 3-hydroxy-2-methoxy5-methyl-2-oxo-1,2-oxaphospholanes (95) studied spectroscopically; the same compounds are a l s o formed if, in the initial step, NaOMe is employed as catalyst. The benzylidene derivatives of 1 9 4 ) ~ 4 - d i e t h o x y p h o s p h i n y l - 6 - m e t h y l - 2 - p h e n y l - l , 3 - d i o x a n e ~ were studied for configuration assignment purposes. In the second study, the Et3N-catalyzed addition of dimethyl. phosphonate to ( 9 6 ) gave a 1 1 mixture of (15)and (15)-2,4-2-benzylidene-lC-(dimethoxyphosphiny1)-e-erythritols (97) and (98). Using D-threose, the same sequence gave a product with diastereoisomeric ratio 1:9, a difference in behaviour which was correlated with the accessibility of the carbohydrate carbonyl group to the dimethyl phosphonate nucleophile. The acid-catalyzed cyclization of (15)and ( l R ) - l - C - ( d i m e t h o x y p h o s p h i n y l ) - _ D - e r y t h r i t o l gave 101 the P-epimers of ( 9 9 ) .

I48

Organophosphorus Chemistry

-

(92)

+

(R’O)ZP(O)H

(RfCO)20

0 R2 II I

0 II

(R’O)2P-C-OP(OR1

1

R3

(93)

R‘

OH

O=P(OMe)2

1OR’

k:x” 0

(97) OH

h0ch2

0 =P(OMe), O

H

R2

HO OH

(99)

(98) OH

OH

&JCH0 H OR

(100) EtOH

- H20

l2

5 : Quinquevalent Phosphorus Acids

149

The behaviour of salicylnldehyde in the Abrarnov r e a c t . i o r i

i s , as might be expected, a lirtle unusual; when acted upon by

dialkyl phosphonates the ultimat-e products are [a-hydroxy-a(2-hydroxyphenyl )methyl Iphosphonic monoalkyl esters, (1Cl)thouqht t o b e formed through cyclic intermediates. I f the reaction is carried out in the presence of a trace of Et3N or CF3C@OH the intermediate diesters ( 1 0 0 ) can be isolated. The latter can also be obtained (100; RZEt) as its b i s ( t r i r n e t h y l s i l y l ) e t h e r , hydrolysable to (100; RZEt), i n a reaction between salicylaldehytie trimethylsilyl ether and diethyl trimethylsilyl phosphite; alternatively, the bis(trirnethylsily1) ether bis(trimethylsily1) ester can be prepared using tris( trirnethylsilyl) phosphite.lo2 Bis(1-hydroxyalky1)phosphinic acids have been prepared by the method outlined in Scheme 12. Following the predictable initial reaccion between an aromatic aldehyde and the diene phosphinic acid (102) cyclization occurs subsequently to give the dihydro-1 ,2-oxaphosphole ( 1 0 3 1 .Io4 Using NaOBr, NaOCl , and perchloryl fluoride , and reductions with SnC12, a series of halogenated derivatives of triethyl phosphonoacetate (104;X,Y=HF, HBr, HCL, F2, C 1 2 , f3r 2' FC1, FRr, o r ClBr) have been prepared.lo5 Phosphonic acid monoesters are obtainable by initial treatment of a phosphonous acid with an alcohol in the presence of DCC and d i r n e t h y l a r n i n o p y r i d i n e , followed by oxidation of the phosphonous acid monoester with NaI04.'06 Mono and diethyl esters of (a-aminobenzy1)phosphonic acids (105; R2,H or Et) have been prepared from the aldehyde R3C6H4CH0, the amine K2NH2 , and diethyl phosphonate;!07 the corresponding diphenyl esters were prepared from the aldehyde, diethyl phosphoramidate, and triphenyl phosphite in the presence of BF3.Et20, followed by acid hydrolysis of the intermediates Variations to this last procedure (106; R1=Et, X--@, R2-OPh). include the use of diethyl phosphoramidothioate, and of diphenyl phenylphosphonite a s a route to phenyl (a-arninobenzyl)phenylphosphinates via (106; X=S, R1=Et, K2=@Ph o r Ph) .lo9 A useful synthesis of [a-( (Ij-benzyloxycarbony1)amino)alkyllphosphosphonic monoesters consists of the treacrnent of the corresponding free acids with a primary or secondary alcohol in DMF with a slight excess of S0Cl2 at around Oo.llo Alkylation of the anion from the Schiff base (107;K-H) (from (+)-camphor and diethyl (aminomethy1)phosphonate) with

150

OrKantiphosphcirus Chemistn

(Me3Si0I2PH

-

ii

I

_c

R’ I

Me3SiOC

No

7 7

A2\

L

P

-!L( H O C R ‘ R ~ ) ~ P ( O ) O H

‘OSiMe,

Me3Si OC

1

R2 Reagents

i , RIRZCO;

11,

M c 3 S i C I . E t 3 N , iii. E t O H , h e o t

Scheme 12

Mc,C=C=C

> /

0’

-

-

H P’ ‘H

ArCHO

OH

fH+

MezC =C =C

/H

0-

I

OH

/H \

Me 2 C =C =C

0

“#“,o-

Me,C+

O4

’OH

‘CH(0H)Ar

P ‘CHAr

I

OH

1 1

IS1

5: Quinquevulerit Phosphorus Acids

0

+

II H3NCHRCOCHz P-OH

I 0-

(109)

Me, C=C=CR-P

0 II O ,H ‘H

__L CHC13 HCI or McNOZ

M & ;=y Me (111 1

152

OrRanophosphorus Chemistry

a n alkyl halide RX yields the derivatives (107;R-Me,Et, iPr,

allyl, PhCH2, G . 1 having an excess of that diastereoisomer with the ( 5 ) configuration at the phosphonate carbon. Acidolysis of the products affords (a-aminoalky1)phosphonic acids with 11-77X e.e."' Optically active 4-diethoxyphosphinyl -3-(l-hydroxyethyl ) 2-azetidinone (108) has been synthesized as a potential precursor to (1-aminoa1kyl)phosphonic acid derivatives; the starting materials were (2~,3R)-2-bromo-3-hydroxybutanoic acid and (effectively) diechyl [ ( ( 4 - m e t h o x y p h e n y l ) a m i n o ) m e t h y l j p h o s p h o n a t e or the corresponding 4-methoxybenzyl compound. 1-Aminoalkyl(chloromethy1)phosphinic acids ( 1 0 9 ) are obtainable from PhCH20CONH2, RCHO, and C1CH2PC12, followed by deprotection.'13 An efficienc synthesis of (3-amino-2-0xoalkyl)phosphonic diesters and acids ( 1 1 0 ) involves the interaction of dialkyl methylphosphonate carbanion with PJ-BOC-a-aminocarboxylic esters and subsequent deprotection with Me 3SiBr (phosphorus ester groups) and MeOH ( R O C 1 .'I4 The synthesis of heterocyclic phosphorus ( and sulphur) compounds with P-C bonds ( with 29 references on phosphorus compounds 1 has been briefly reviewed .'I5 Recent descriptions include those of the synthesis of the hydrogen phosphonate (1111 ,I1' and the cyclization of the functionalized 1,b-dienes (112) to give (113), o r (114) and ( 1 1 5 ) (see 'Organophosphorus The cyclization of 1,5-diketones by Chemistry', 17, 153) .'I7 their reaction with hydrophosphoryl compounds to give the phosphorinanes ( 1 1 6 ) has been further exemplified, a s has that of the 1,b-dienes ( 1 1 7 ) with ROP(0)H2 to give the related compounds (118) 2,6-Dipheny1-4-oxo-4-hydroxy-1,4-thiaphosphorine (119) has been prepared as indicated and converted into several 119 conventional derivatives. D i h y d r o b e n z o x a p h o s p h o l e s have been obtained from aromatic 2-carbonyl-containing phosphites (Scheme 1 3 ) . The presumed intermediate ( 1 2 0 ) from diethyl phosphorochloridite and salicylaldehyde could not be detected spectroscopically, but was evidently converted rapidly into the dihydrooxaphosphole (121) as a 2:l diastereoisomeric mixture. On the other hand, spectroscopic observations did seem to suggest an intermediate of structure (122; R1=OEt, R2=Et) to be formed from 2-hydroxyacetophenone, but above room temperature this also rapidly disappeared to give

s.

5: Quinquevalent Phosphorus Acids

153

R’ + R 2 = (CH2 14 or R ’ = P h R 2 = H,Me,Bu,PhCHz

etc.

0 II

(PhCCl =CH),POMe

t.Na2S.EtOH ti,

H~O+

Oe

‘OH

(119)

I54

Orguntphvsphorus Chemistn

the diphosphorus compounds 1124; R1 alkoxy or Ph, R 2 a l k y l ) possibly & y ( 1 2 3 ). I 2 ' Miscellaneous syntheses include those of diethyl (3-cournarinyl )phosphonates;121 a l k y l 2-( (alkoxymethylphosphinyl 1 oxy iacrylates ( 1 25) hexyl arvl (4-penten-1-yl Jphosphinates bv phospha-Cope rearrangements i n the presence of hexanol;123 diethyl 1 j (2-tetrahydropyranvl 1oxy:methyl ,phosphorlate;124 dialkyl [ 3-(dialkoxyphosphinyl )-Z-alkenejphosphonates I 1261 (perfluoroalkyllphosphonic and bis(perfluoroalkyl1phosphinic acids;126 e t h e n y l i d e n e b i s ( p h o s p h 0 n i c acid) and i t s tetraalkyl esters ; 2- ( d ia lkoxyphosph i ny 1 1 - 2-d i azoace tami de s ; 1 2 8 u , w - d i h y d r o x y a l k y l - a , a - d i p h o s p h o n i c acids (127) and their e.g. (127;R--Ph, 2 - 1 ) to i 1 2 8 ) cyclization to dihydrooxaphospholes, __ and subsequent hydrolysis to the unsaturated bis(phosphonic acid) (129);''' and the [ (diacyl )methyl lphosphonates ( 1 30) .'") (I-Hyaroxyethyl )phosphinic acid has been resolved wi th 1- ( 1 -naphthyll ethy lamine.13' B i s ( p e r f l u o r o a l k y 1 ) p h o s p h i n i c amides may be p r e p a r e d by the action of an arnine on the appropriate phosphinic chloridc, but subsequent displacement of one perfluoroalkyl group by excess amine appears to be possible. Interaction of a phosphinic chloride and phosphinic arnide in the presence of Et3N or pyridine affords the stable salts 1 1 3 2 ) which lose base only on distillation over H2S04 to give the free imide (133).132 Diphenylantimony(I11) diphenylphosphinate (134;X:O) and the corresponding phosphinothioate t134;X-S) have been prepared and their structures determined by &-ray analysis.133 The bis(trimethylsily1) esters of alkylphosphonotrichioic acids (136) b¶ = E i , have been obtained & y their disodium salts from 1,3,2,4-dithiadiphosphetane 2,4-disulphides (135); the silyl esters may also be prepared from the tervalent compound (137) by stepwise sulphurization. Some possibility appears to exist f o r the novel diad tautomeric shift between (138) and (139). A reaction between the compounds ( 1 3 6 ; M = S i ) and MegSnCl affords the corresponding tin cornpounds (136; M=Sn) also obtainable from (135) and iMe3Sn)2S.134 The remarkable ring compounds (140) have been obtained through reactions between (136; M-Si or Sn, R=Me or tBu) and the sulphur dichlorides SxC12 (x-3-51. 'The sulphur heterocycles are fairly stable in Fhe crystalline state but disproportionate in solution. 1 3 5 The compound (135; R - M e ) 136 also reacts with a,~-alkanediolsto give the acids (141;q-2-4).

I55

5: Quinquevalent Phosphorus Acids

R=COCH3

Reagents

1 ii

I.

(EtO),P(O)CL,Et3N,

11, (

R20)R'PCI.Et3N

Scheme 13

0 It

90

R20,

NP,

Me

OC=CHz

R3 I

I

COOR' (125)

0

II

(R'O),PCH,C=CHOP(ORZ)~

(126)

156

Organophosphorus Chemistry

(C3 F7)2P(O)CI

t

RNHz

(131 1

X

II

S

5

II

RP(SMMe 3)2

PhzSb.OPPh2 ( 134)

5

(136)

( 1 35)

s

SiMe3

II/

RP

\

SSiMe3 / 1 . RP \

SiMe3

(139)

(138)

R'

R2CSSH

51me3

5: Quinquevalent Phosphorus Acids

Lawesson's reagent (135; K-4-heOC6H4) converts the ketones KZCOCH=CK1NH2 into the 1,3,2-thiazaphosphorines (142;X=S1 together wich, in some cases, traces of the corresponding 1 , 3 , 2 oxazaphosphorine. The crystal structure of the thiaza compound ( 142; X-S, R1 - C F 3 , R2-Ne ) was determined. 37 Stereoisomeric forms of alkyl-1-menthylphosphinothioic chlorides have been prepared and studied in detail by spectroscopic and crystallographic methods The reaction between dithiocarboxylic acids and dialkyl phosphorochloridites takes a fairly involved course, but the outcome is the formation of the monothio phosphonic 2,S-diesters (145). Spectroscopic techniques indicated the formation of the tervalent esters (143) and their conversion into (145) v i a (144) consistent with the results of earlier work.139 2 . 2 . Reactions and uses of Phosphonic and Phosphinic Acids and their Derivatives.-The ester (146; R1-Et, X=Cl) i s thought to react with arylthiolate anions as indicated in (147) to give ( 146;K1=Et, X-SAr 1 . Diethyl (p-toluenesulphonylethynyl )phosphonaLe (146; K1=Et, X=SO2C6H4 Me-p) reacts with pyridinium 1,l-dicyanomethylides to give indolizines, and with anthracene in a IlielsAlder rea~ti0n.l~'The ester (146; R1=Et, X=C1) is also reported to reacc with alkoxides, but with fission of the P-C bond; EtO-

gives triethyl phosphate, chloroacetylene, and 20% of the ester ( 148;K2-OEt). This behaviour contrasts with that in the attack by the less nucleophilic phenoxide anion when (146;X=OPh)and the (148;K2=Ph) are obtained. According to this account products from (146; X=C1) and thioalkoxides R2S- are ( 146;X=SR2), the thio analogues of ( 1 4 8 1 , and (149). No reactions occur under normal conditions with the weakly basic nucleophiles such as AcO-, I - , or NCS-. Photolysis o f nitrobenzylphosphonate dianions results in fission of the P-C bond, the reaction being most pronounced for the para isomer. 142 Evidence for the generation of metaphosphate anion in this process rests on the formation of alkyl phosphate dianions, sometimes in high yields, when the homolysis is performed in the presence of a large amount of an alcohol.143 In some ways the most interesting case of P-C bond fission reported this year is that in the biodegradation of alkylpho'sphonic acids t o alkanes and alkenes by E.coli. I t is noteworthy that acids with bulkier carbon groups such as iPr or tBu, are not

158

Organophosphorus Chemistry

0 ( I?'0

II P C( S R )=CHSR2

M e 2 NC [P(O)( OE t

I2l3

( 150)

( 149)

+

Me NC H[WOM OE t I,],

I-

(152) R C HO - T i C14 7

McN-0

0 II

W

( E t 0)ZPCHz COO€t

RC HO - C I T i ( OPr 13 Na H

0 II

-

R# H

Scheme 14

0 II

(EtO)2PCH20CH2CH2SiMe3

lii

-

0 II

( E 101, PCHOC H, C H, S i Me

I

S iMe3 Reagents : i , BusLi, ii,

0

i,ii

m3sic1;

iii , ~

1

~

Scheme 15

0

~

2

#p(oEt)2 R. 'COOEt

p(oE )2 COOPri

5: Quinquevalent Phosphorus Acids

159

degraded, nor are mono or diesters when the parent acid i s , for example, ethylphosphonic acid. Phenylphosphonic acid is degraded to benzene. 144 Phosphorus-carbon bonds are a1 so broken during the insertion of the methylene moiecy into the P-C bond of (acyloxyimino)phosphonates by diazomethane.145 The treatment of (150) with H C I or Me3SiBr gives ( 1 5 1 ; R = H or Me3Si but rather unexpected i s the action of Me1 on ( 1 5 0 ) which yields ( 1 5 2 ) ; i t i s therefore interesting to note that with dimethyl sulphate or methyl -toluenesulphonate, ( 1 5 0 ) yields the expected quaternary salts.'" C - C ( N ) bond fission and dephosphonylation can each occur on the addition of piperidine or morpholine to 2-aryl-1,l-dicyano2 - ( d i i s o p r o p o x y p h o s p h i n y l )ethenes ( 1 5 3 ) .I4' Depending on the nature of the catalytic titanium compound, triethyl phosphonoacetate can react with aldehydes to In give products having different geometries (Scheme 1 4 ) another synthesis of alkenephosphonates, activation of an otherwise unreactive phosphonate ester in Knoevenagel reactions can be achieved through inicial silylation. (Scheme 1 5 ) .149 An X-ray analysis of (155; R=p-tolyl) has confirmed the previously described transformation of ( 1 5 4 ) into (155).I5' An intramolecular Diels-Alder reaction occurs when the allenephosphonic ester (156; R=H, Ar-1-naphthyl) is heated; the product is che 1,2-oxaphosphole 2-oxide ( 1 5 7 ) of which only one stereoisomer was isolated. This process does not occur when either Ar=Ph or RzMe.I5l Dineopentyl phosphonate anion is methylated to dineopentyl rnethylphosphonate by Me1 or even trimethyl phosphate. The treatmenc of dimethyl phosphonate with NaH in THF or benzene at room temperature results in demethylation to monomethyl hydrogen phosphonate anion and concomitant formation of dimethyl methylphosphonate. Such side reactions are less important for diethyl phosphonate, and do not appear t o take place for dineopentyl phosphonate, nor do they occur when the base is BuLi, or if 152 the NaH reaction i s performed a t -78". The dependence of the stability and basicity of phosphonate carbanions on their structure has been examined. Most a-phosphonyl carbanions appear to form stable 'dimers' ( 1 5 9 ) ar low temperatures in a self-condensation determined largely by steric interactions ( of K 1 I or electronic effects (of K ~ ) .Some phosphonic carbanions e.g. (158; R1=Et, R2=Cl 1 degrade readily

Organophosphorus Chemistry

I60

R2NH(

(153 1

R+c

C12P II

0

(154)

heat

0 (155) OAr

5: Quinquevalent Phosphorus Acids

161

without dimerization; others e.g. (158; R1=iPr, R 2 = H ) are stable at O* for several hours, and yet others e.g. (158; R1=Me, Et, or iPr, R2=Ph or Me3Si) are described as'stable' Carbanions (fluoromethyllphosphonic diesters are conveniently from generated using lithium diisopropylamide at low temperatures, and although they are relatively stable at - 7 0 " they tend n o t to survive temperatures as high as 0 " ; their relative stabilities decrease in the order PhCHF- > PCF2- > PCClF- . 8 7 Allylphosphonic carbanions, generated using BuLi. react normally with electrophiles at the a-carbon to give (160). The behaviour of the ( a c e t y l o x y a l l y 1 ) p h o s p h o n i c diesters (162) towards nucleophiles has been examined. With the knowledge that the acetate anion is a good leaving group i t was predicted that its loss from (162) would thus assist in the formation of an allylphosphnnic carbocation which would be stabilized by Pd(0) and which would react with nucleophiles at the y-carbon to give (16l)(assisted umpolung). These predictions were borne out and the compounds ( 1 6 1 ) were indeed prepared in this way.154 The t e t r a h y d r o p h o s p h o n o f u r a n o n e (1631, synthesized as indicated, is a versatile reagent f o r the preparation of a , B-difunctionalized-y-lactones The alkylation, acylation, and silylation reactions of dialkyl ( f l u o r o m e t h y 1 ) p h o s p h o n a t e s have been s t u d ~ e d . ' ~In ~ the alkylation of the carbanions from tecraalkyl ( c h l o r o m e t h y l e n e ) d i p h o s p h o n a t e s , fission o f the P-C bond occurs on lichiation with BuLi, but the extent of the degradation can be reduced if ( a ) tetraisopropyl esters arc used, ana ( b ) either t-butyllithium is employed as base, or even the thallium salts are used. 157 (1-Hydroxycycloalky1)phosphonic diesters suffer both dehydration and ensuing chlorination when treated with either Pc1 or sO2cl2. 158 ?he P-C bond in (1-oxoalkyliphosphonic derivatives is well known to be susceptible to fission by the-action of amines and, particularly under basic conditions, by alcohols. However, thiols have been shown to add to dialkyl acetylphosphonates in the predicted manner. On the other hand. the treatment of diethyl acetylphosphonate with triethylamine has been reported to give the phosphonate (164) According to other workers, analogues of diethyl acetylphosphonate %.(165), rearrange under the influence of triethylamine, in this case to (166).160 (See a l s o references 97 and 98 for structural analogues).

Organophosphorus Chemistry

162

0

0

II I1 ,OR1 (R~O)~PCHR~P, CH* R’

E

(160)

T

0

i Pd(PPhg)h

,~Tms

OAc ( 162)

CH3C

* NTms

ii NuH

5: Quinquevalent Phosphorus Acids

NaH

163

i

PhStBr

0

R (165)

OH

0

164

Organophosphorus Chemistry

A r o y l cnloi-ides (with certain exceptions) and trialkyl phosphices react together t o give dialkyl aroylphosphonates (167) in an initial Arbuzov reaction, but this is merely the first step in a rather complex sequence (Scheme 16). Further interaction of dimethyl aroylphosphonate (167;R':Mei with an excess of trimethyl phosphite yields che diphosphorus tetrrnalkyl esters (170) and the benzylphosphonic ester (169; K 1 :Me, X=OCOPh) possibly reached through the inreroiediate (168; R1 = K 2 Me). I n the absence of acidea HX, the intermediate (168) decomposes at higher temperatures by l o s s of trialkyl phosphate to yield a novel ylide (172) formed from the carbene (171) and trimethyl phosphite. This interpretation of events has received some support from the finding that the interaction o f trimethyl phosphite and dimethyl (2-ethylbenzoy1)phosphonate at 100" affords both (172;R1=R2-Me, Ar-2-EtC 6H 41 and 1-(dimethoxyphosphinyl )indane (173) which could only have arisen through an intermediate species such a s (171). The reluctance of some aroyl chlorides to react normally with trialkyl phosphites may be due, at least partly, to the stability of the respective species ( 1 6 8 ) . I n the absence of an excess of aroyl chloride, further reaction with ( 1 6 8 ) is (sometimes) possible and leads, once again, to the diphosphorus tetraalkyl esters ( 1 7 4 ) .161 The treatment of dialkyl (3-chloroalkenyl)phosphonates with nucleophiles (RO-, R21UH, K 3 N ) results in prototropic isornerization to the (3-chloro-2-alkeny1)phosphonate diester rather than replacement of halogen.'" The same phenomenon occurs when allylphosphonic dichlorides are treated with Et3N. The Wolff rearrangement of (1-0x0-2-diazoalky1)phosphonic diesters e.g. ( 1 7 5 ) under photochemical o r thermal conditions has been observed The blue, oily l-methylcarbamoyl-l-nitroso(diethoxyphosphinyl )ethane (176) forms a colourless dimer in the solid state; migration of the nitroso group occurs when the compound is treated with HCl. lh5 It is possible to arylate the intermediates thought to be formed during the Pummerer rearrangement of phosphonylmethyl166 sulphoxides; the products are esters of the type (177). 2 The esters' (177;K =Me) have also been obtained in Friedel-Crafts reactions between diethyl [ c h l o r o ( m e t h y l t h i o ) m e t h y l : p h o s p h o s p h o n a t e (178;X-Cl) with benzene in the presence of TiC14, or better, SnC14. The ester (178;X:OCOCF3) reacts with terminal alkenes in the presence of CF3COOH to give dialkyl (3-alkeny1)-

5: Quinquevalent Phosphorus Acids

165

0

0

II

( R20)2POCHArP(OR’)*

(167)

O-i(OR2 I

-C - P ( 0 R ’ [Ar

II

0 (168)

0 II

II

( R 10)2 P COA r

(170)

:j

1

ii

1

- RZCl

(174)

Reagents : i . ( $ 0 ) 3 P ; i i , A r C O C l

Scheme 16

Organophosphorus Chemistrj*

166

0 II

( RO 12 P COC Nz COOMe

(1 75)

lhv 1

COOMe

]

0 II

0 II

( RO)2 P CH2COOMe

( RO)2PCH(COOMe)2

0 NO

II

I

(Et0)z P-CCONHMe

I

Me (176 1

0

II ( R10 ) 2P C HA r SR (177)

HCl

0 II (EtOI2 PCHMcCON(N0)Me

5: Quinquevulenr Phosphorus Acids

167

phosphonates. 167 Various combinations of reactants allow the synthesis of the phosphinic chlorides ( 1 7 9 ; Scheme 171 convertible, as indicated,inro the (1-hydroxyalkvllphosphinic acids ( 1 8 1 ) . However, the replacement of the ketone reactant by an aromatic aldehyde or ketone leads to the (chlorobenzyliphosphinic acids (182). ?'he isolation of the ester ( 1 6 3 ) after addition of methanol to the reaction mixture from propionic acid, dichlorophenylphosphine, and p-methoxybenzaldehyde, has been advanced a s evidence for the pathway (180j'(182)\(181j.168 Scheme 18 shows the mode of addition of two unsaturated and the alcohols to (1-vinylalleny1)phosphonic diesters subsequent Claisen rearrangement of the two adducts,(1841 and ( 1 8 5 1 , 169 each of which was obtained as a i (E l mixture. 'The hydrolysis of phosphonic and phosphinic esters and other derivatives is a topic which h a s received comparatively little attention during the year. One important study has been that on 2-phenyl-1,Z-oxaphospholane 2-oxide (186) and 2-phenyl1,3,2-dioxaphospholane 2-oxide ( 1 8 7 ) . The former hydrolyses 6.2 x l o 3 times faster than ethyl ethylphenylphosphinate, but the 1,3-dioxa compound hydrolyses 1 . 5 x l o 6 times faster than diethyl ethylphosphonate. The difference in free energy of actfvacion for the phosphinate esters (s. 5.2 Kcal. mol.-') is taken as representing the ring strain energy, and the larger -1 difference for the phosphonate esters (s. 8.4 Kcal. mol. ) i s thought to be made up of the ring strain energy together with E. 3.2 Kcal. mol.-l, . I 7 ' the stereoel.ectronic effect In the alkaline hydrolysis of the diarylphosphinic esters (XC6H4j2P(OjOC6H4Y ( X , Y - H , N O 2 , Me, o r Br) the influence of the substituents X and Y of the 'acid' and 'alcohol' parts is additive.17' The influence of structural factors in the esters K12P(X)YMe where X , Y - 0 , O ; S,O; 0 , s ; o r S,S, on the alkaline hydrolysis rate has been examined; the thiophosphoryl esters are only slightly ( ~ O O X . " ~ 0-Ethyl d i p h e n y l p h o s p h i n o t h i o a t e is oxidatively desulphurized by COCL2, in contrast to g,g,g-triethyl phosphorothioate and 9,O-diethyl phenylphosphonothioate, which show a 173 distinct lack of reactivity.

(z)

168

Organophosphorus Chemistry

0 II R’-P-CI

I

R2-C -OH

I

R’ PClz

’/

\L

R3

P

( 179)

0 II O ,H R’P

R’-P

(160)

II

R2-C R3= A r

I I

-OH -OH

R3 (181)

0

II

H ‘

R~-P-

OH

R2- C -

Cl

I

I

1OO’C

0 II P h - P - OMe

I

H-C-OH

Ar

I 4- CH3CsH4

(1 62)

(183) Reagents : i, MeCOOH , or H 2 0 , or RP(O)H(OH) ; i i , MeCOCl ; iii , &OR3;

2

iv , H20

Scheme 17

i or ii 4

OR

iii 4 (184)

1

iii

(1851

0 Reagents:

1,

HC=CCH2OH ; ii , l-$C=CHCH20H

; iii, H e a t , 150’

Scheme 18

-c-

w0

5: Quinquevalent Phosphorus Acids

169

Ph \

P-P

/

Ph

(190)

(186) X = C H 2 (189)

(187) X = 0

S II ,SSPh AnP, CI

11

AnP:

S

,

II SNa

AnP,

i , PhSCl

OR

(188 1

S

Reagents:

SSPh

at

OR

50' ; i i , R O -

Scheme 19

170

Organophosphorus Chemistrv

Lawesson's reagent i s acted upon by PhSCl to give intermediate chlorides convertible into the 9-alkyl SS-phenyl phosphorodithioate esters (188) obtainable by an alternative route (Scheme 1 9 ) An examination of metal complexes of substances resembling 1.awesson's reagent has suggested that i t is itself not an active sulphurization agent for benzophenone. However. (189) does convert benzophenone into the thioketone. 3 1 P n.nl.r. evidence suggests that Lawesson's reagent is in rapid equilibrium with the dithioxophosphorane monomer (190) which i s the active agent A reaction between the tetrathiobisphosphonic acids (141) and cyanides yields ultimately thioamides and the r i n g compounds ( 1 9 1 ; ~ = 2 or 3).176 Reactions of bis(trimethylsily1 1 and bis(trimethylstanny1) esters of phosphonotrithioic acids 1136) have been reported. 1 3 4 The full results have been published of a detailed 31P n.m.r. and stereochemical study of the chlorinolysis of S-methyl t-butylphenylphosphinothioate.'77 rhis involves fission of the P-S bond with the favoured stereochemistry being that of retention of configuration at phosphorus. Intermediates, thought to be (192-194) were detected, the last two being confirmed by independent synthesis from a PI1I-0-P1" anhydride and MeSCl or C 1 2 . In a manner reminiscent of the behaviour of the tervalent esters ( 1 4 3 1 , che tervalent esters (1951 are converted into the thiophosphonic amides (196) when heated, and are formed along with the latter in the reaction illustrated.178 The mechanism of the rearrangement of an a-thiophosphoryl trifluoroacetate (197) has been investigated using 170 and l80labelling techniques.179 The main product from the treatment of the ester ( 1 9 7 1 , labelled a s indicated, with acetic acid is the 5-trifluoroacetate (200;R=COCF3) (Scheme 20) which is labelled in the phosphoryl group ( 8 0 % ) and in the carbonyl group (20%). Compound (200; R = H ) is a minor, though still substantia1,by-product. It was suggested that (199) is the key intermediate which is not produced by any concerted process but rather through the participation of ion-pairs (198). The reaction between the allenephosphonic diesters (201) and hydrogen dithiophosphates can occur along two pathways (Scheme 21). When R1-Et and R2=Me, the addition step is not important, and the main process is one of dealkylation. Only the introduction of two Me groups at the phosphonic ester y-carbon

5: Quinyuevalmr Phosphorus Acids

171

s s-s R-P

II/

's-s/

\

P-R

11

+

Me3MX

S

M = Si or Sn

[But PhP(SMe)OP(O)PhBu']+Cl-

[But PhP(0)SCI Me]+ CI-

(192)

(193)

[Bu

P h P ( C I 10P (0 PhM c ] + C I -

(194)

(Et2N),PCI

+

S II

MeNHCPh

(Et,N), PSCPh=NMe

(195)

+

S II (Et 2 Nl2 PCPh=NMe (196)

172

Organophosphorus Chemistry

= 170or 180

--& : 1 SR

Me Scheme 20

0

(OEt

2

(200)

0 II

(R2 O), P-C-CH=CR32

I1

CHCH2SP(S)(OR1 12

(205)

S

t

0

II (R20)2PCH=C=CR32

(201)

II (R’ 012 P SR2

+

( R ’ O),P(S)SH

0

R2 0, II PCH=C=CH2 HO’

1

R 3 = Me

S

(202)

+

R3= H

(203) Scheme 21

5: Quinquevalent Phosphorus Acids

173

activates the addition process but even then only to a relatively small extent, the yields of ( 2 0 2 ) being E. 25%. The yields of the ester (203) and of the dihydro-1,2-oxaphosphole (204) are 5-7%. With the introduction of a vinyl group at the allene a-carbon addition to the vinyl group becomes the main reaction (giving (205)1 with the dealkylation process of secondary importance. 180 The treatment of arylmagnesium bromides with diphenyl phosphorazidate yields labile products which, in the presence of PreOH-HC1, or MeOH-KOH, or better, lithium aluminium hydride or NaA1H2 (OC2h40Me 1 2 , affords arylamines.18’ The prochiral d i p h e n y l p h o s p h i n y l a m i n e s are asymmetrically reduced by chiral hydride reagents to give chiral diphenylphosphinic amides with high e.e.18’ Diels-Alder reactions, including the dimerization, of 1-aminophosphole 1-oxides (207) have been observed. The dimers (208), and the products from Pj-phenylmaleimide, (209), undergo oxygen insertion when treated with MCPBA to give 5,6-oxaphosphabicyclo[2,2,2;octanes e.g. (210). The crystal structures of the monohydrate of (208;R=Me)and (210;K=Me)were determined. In boiling toluene compounds of type (210) lose the bridging phosphorus, although this is not released immediately as a separate entity. The presence of benzylaniine during the pyrolysis assists in the breakdown, and the products (211;X=NMe2 or NHCH2Ph) have been detected. However, agents normally effective for the trapping of metaphosphate or metaphosphonate were unable to 183 trap a species such as Me2NP(=0I2. A further reaction of (1-vinylal1ene)phosphonic diesters, this time with Lhe imidophosphites (2121, is of interest in providing examples of 5-phosphorylated-dihydro-1,Z-azaphosphepines. When K-Me the reaction pathway leads to the isolable (2131. On the other hand, the product from (212;R=Et) appears to be the 1,2-azaphosph(V)orine (214). This communication also describes other similar compounds obtained by variations in the C substituents in (212).184 N-Aryl-2-(diphenoxyphosphiny1)hydroxylarnines are useful reagents for the direct conversion of amines into hydrazines. When treated with sodium methoxide in methanol, the c-methanesulphonates of (aminophosphinoy1)hydroxylamines (215;R1=NHPh or NMe2 1 readily rearrange to the phosphorohydrazidic

Organophosphorus Chemistry

174

P h2P (O)N=C R’R2

(206)

MCPBA

U

RzN,

Il,O

Mep h

H

Me&

0 (210)

0 NPh

O=P-NHCHz

I

Ph

X

(211) ( a ) X = NMez ( b ) X = NHCHzP h

175

5: Quinquevalent Phosphorus Acids

0 CH=CHz II I

(EtO), P-C=C=CMe2

t +

R

=

Et

(RO)2PN=C(NEti!)Ph

176

Organophosphorus Chemistry

esters 1216; Kl-NHPh or NMe2J. W i t h pyridine in MeOH (10% v/v), the speeds of these reactions (t$= 70 and 6 m. respectively, at room temperacure) contrast markedly with that of the mesylate of N-(diphenylphosphinoy1)hydroxylamine (215;R=Ph)for which

x.

z.

t$12 days. The results are thought to simply represent a greater migratory aptitude of PhNH and NMe2 relative to that of Ph, and indeed no migration of the Ph group in (215) was observed. If, in place of methoxide in methanol, the amines K2NH2 are employed, then the products have the structure (217; K1=NHPh or NMe2, K2-Me or tBu3.186 On the other hand, the products resulting from the treatment of the compounds (215; R1=alkyl) with a primary aliphatic amine R 2NH2 (R2=Me or tBu) or NaOMe (for which the reaction is extremely rapid) are the anilides (219;X=NHK2 or Me); the extent of alkyl migration, by contrast, is ~ 2 % .The preferred migration of Ph suggested the possible participation of a phenonium ion-like transition state leading, in turn, to a metaphosphonimidate intermediate (2181 The migration of an anilino group also occurs when the (1-chloroalky1)phosphonamidic esters (220) are treated with NaOMe in MeOH, and the reaction is accompanied by demethylation to the monomethyl esters (222;R3=H). With a decrease in the bulk of the phospnonic carbon moiety (220; a,b,c) the initially very fast rearrangement becomes progressively slower, the extreme reaction rates differing by a factor of 3000; at the same time, the extent of demethylation increases until for (220a) i t is the principal reaction. Although the participation of a pentaco-ordinate intermediate (221) seems an attracttve mechanism, che fact that sodium ethoxide in ethanol is a more effective reactant suggests that RO- acts as a base rather than as a nucleophile, and the preferred mechanism is one involving initial l o s s of a proton leading to the azaphosphiridine (223)(although this could not be detected) followed by reaction with KO- as a nucleophile through anocher pentaco-ordinate intermediate. The rearrangement has preparative interest for the synthesis of 188 [(arylamino)alkyljphosphonic acid derivatives. The behaviour of the phosphonamidic chloriaes (224, 225; 2 R1=H, 2-Me, 2,4,6-Me3, or 2,4,6-iPr3) towards the amines R NH2 2 (R =iPr or tBu) to give the diamides (226) or (227) shows some interesting features. For the group (224), an increase in steric bulk throught the series (a),(b),(c), and (d) results in a decrease in the reaction rate; the reactions of ( a ) and (d)

5: Quinquevalent Phosphorus Acids

Ph

R'

I77

0 II

'PNHOMS

'

(215 1

CI R ' R2

0 j

-

- OR3

NHPh

R'

# f ! - - O R 3I OMe

PhNH

(221)

(220)

1 0 N

fast

N

Ph

OR^

Ph

(223)

(b) R ' = H , R2=Me

- Q-

(a) R'=R2=Me

R'

P-CI X

( 2 2 4 ) X = NMc2

$NH2

0

LI " R 2

X

( 2 2 6 ) X =NMcz ( 2 2 7 ) X =NHBu'

( c ) R'=R2=H

(a) RLH (b)

R1=2-Me

(c)

R' = 2 , 4 , 6

(d)

R1 = 2 . 4 . 6 -Pri-,

- Mc3

178

Organophosphorus Chemistty

with cBuOH differ in rate by a factor of c . 7 0 . Such a sensitivity to bulk is characteristic of a n SN2(P) process. However, the reaction rates for the members of each pair ( 2 2 5 ; a and b ) and

( 2 2 5 ; ~and d)differ little, but the the members of the pair

with bulkier aryl groups react faster by a factor of s.100; for these examples a mechanism involving elimination-addition with metaphosphonate formation is favoured. Keactions between ( 2 2 5 a ) and bulky nucleophiles e.g. tBuOH or iPr2NH, or weak nucleophiles such as F3CCH20H, are rapid, even at 0' i n

dichloromethane.

References

B . V . , Russ. Chem. Rev. ( E n g l . T r a n s l . ) , 1985, 54, l , > O l . Lamalov. R.M., Z i m i n , M.G., a n d P u d o v i k , A . N . , Russ. Chem. R e v . ( E n g l . T r a n s . ) -

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12. 13. 14. 15. 16.

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z,

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a n d B e r m a n , C.B., J . Chem. E n g . D a t a , 1987, 3 2 , ? 7 9 . I a g r o s s i , A . . a n d R o u s , A . , J . Arner. Chem. S O C . , 19HO,

I_(/?.

K u z e n a s t i e v a , L . Y a . , S m i r n o v a , T.V., a n d K u z n e t s o v a , S.Yu., J . Gen. Chem. USSR ( E n g l T r a n s l . ) , 1986, 933. C h u r u s o v a . S . G . , Kozlov, V.A., Gr-apov. A . F . , a n d M e l ' n i k o v , N . N . , J . G e n . Chem. U S S R ( E n g l . T r d n s l . ) , 1985, 55, 2495. Novikova, Z.S., K u r k i n , A.N., a n d L u t s e n k o , I . F . , J . Gen. Chem. U S S R ( E n g l . T r a n s l . ) , 1985, 55, 2405. H a o , R . J . , S r l v a s t a v a , G . , arid M e h r o t r a , R . C . , I n o r g . Chim. A c t a , 1986, 111, 163. C h a d h a , R . K . , D r a k e , J . E . , arid S a r k o u , A . B . , 2 . O r g a n o m e t . Chem., 1 9 8 7 .

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19. 20. 21. 22.

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I,

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1985, 1674. 23. Kim, S . , C h a n g , S . B . , a n d L e e , P . H . , T e t r a h e d r o n L e t t . , 1987, 2735. 24. L i u , H - J . , a n d F e n g , W.M., S y n t h e t i c . Commun., 1986, 1485. A s s e r c q , J . - M . , L o h , J - P . , a n d G l a s e , S . A . , J . Org. Chem., 25. W e l c h , S . C . , 1987. 1440. 2 6 . K u r i h a r a , T . , M l k i , M., Y o n e d a . R . , a n d H a r u s a w a , S . , Chem. P h a r m . B u l l . , 1986, 2747.

g,

2,

3,

2,

5: Quinquevalent Phosphorus Acids

179

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34,

5

11,

108,

s,

108, g, g,

27,

2,

s,

e,

s,

2,

105,

180

Organophosphorus Chemistry

65. Xu, Y. and Zhang, J., Tetrahedron Lett., 985, 26, 4771. 66. Lu, X. and Zhu, J., Synthesis, 1986, 563. 67. Xu, Y., Jin, X., Huong, G., and Wang, Q., Huaxue Xuebao, 198b, 44. 183; Chem. Abstr., 1986, 106, 5148. 68. Petrakis. K.S.. and Naeabhushan. T.L.., J. Amer. Chem. S u c . , 1987, 109, 2831. 69. Kandil, A.A., Porter, T.M., Slessov, K.N., Synthesis, 1987, 411. 70. Sarnpson, P., Hammond, G.B., and Wiener, D.F., J. Org. Chem., 1986, 43Ur’. 71. Rozinov, V.G., Pensionerova, G.A., Izhboldina, L.P., and Donskikh, V.I., J . Gen. Chern. USSR (EnR1. Transl.), 1985, 55, 2335. 72. Rozinov, V.G., Kolbina, V.E., Rybkina, V.V., and Donskikh, V.I., J . Gen. Chem. USSR (Engl. Transl.), 1985, 2 , 1903. 73. Mokva, V.V., Novruzov, S.A., Isrnailov, V.M., and Musaev, Sh. A . , Azerb. Khim. Zh.. 1985, 40; Chem. Abstr.. 1986, 105, 226785. 74. Dmitrichenko, M.Yu., Donskikh, V.I., Rozinov, V.G., Rybkhina, V.V., and Sergienko, L.M., J. Gen. Chem. USSR (EnR1. TI-ansl.),1985, E, 1672. 75. Shvedova, Yu. I., Dogadina, A.V., Ionin, B.I., Petrov, A.A., J. Gen. Chem. USSR (Engl. Transl.). 1985, 2 , 1663. 76. Startsev, V.V., Zubritskii, L.M., Lukin, M.G., and Petr-ov, A.A.. J. Gen. Chem. USSR (Engl. Transl.), 1985, 55, 1660. 77. Teulade, M.P., and Savignac, P., Tetrahedron Lett., 1987, 2,405. 78 . Coutrot, P., and Ghribi, A., Synthesis, 1986, 661. 79. Teulade, M.-P. and Savignac, P., Synth. Commun., 1987, 11, 125. 80. Aboujaoude, E.E., Collignon, N . , Teulade, M.-P., and Savignac, P., Phos horus Sulfur, 1985, 2 5 , 57. 81. Abouyaoude. E.E., Lie/tJe/,S., Collignon, N., Teulade, M.-P. and SavignaL,P., Synthesis, 1986, 934. 82. Savignac, P., Teulade, M.-P., and Collignon, N., J. Organomet. Chrm., 1987, 323, 135. 83. Kuo, F. and Fuchs, P.L., Synth. Commun., 1986, Is, 1745. 84. Ismailov, V.M., Guliev, A.N., and Moskva, V.V., J. Gen. Chem. USSR (Engl. Transl.), 1985, 55, 2127. 85. Coutrot, P., Youssefi-Tabrizi, M., and Grison, C., J . Organomet. Chem., 1986, 316, 13. 86. Mikorajczyk, M., Midura, W., Miller, A . , and Wieczorek, Tetrahedron, 1987, 43, 2967. 87. Blackburn, G.M.. Brown D., Martin, S.J., and Parratt, M.J., J. Chern. SOC., Perkin Trans. 2 , 1987, 181. 88. Blackburn, G.M., and Parratt, M.J., J. Chem. S O C . , Perkin Trans. 1 , 1986, 1417. 89. Ishihara, T., Maekawa, T., Yamasaki, Y., and Ando, T., J . Org. Chem., 1987, g ,300. 90. Costisella, €3.. and Keitel, I., S nthesis, 1987, 44. 91. Heinicke, J . , BAhle,I., and Tzsch:ch, A., J. Organomet. Chem., 1986, 317, 11. 92. K m o n d . G . B . , Calogeropoulou, T., and Wiemer, D.F. , Tetrahedron Lett. , 1986, 11, 4 2 6 5 . 93. Lu, X. and Zhu, J., J. Organomet. Chem., 1986, 2,239. 94. Zimin, M.G.. Cherkasov, R.A., and Pudovik, A.N., J. Gen. Chem. USSR (Engl. Transl.), 1986, 56, 859. 95. Ovchinnikov, V.V., Cherezev, S.V., Cherkasov, R.A., and Pudovik, A.N., J. Gen. Chem. USSR (Engl. Transl.), 1985, 55, 1109. 96. Texrer-Boullet, F., and Lequitte, M., Tetrahedron Lett., 1986, 3515. 97. Aleinikov, S.F., Krutikov, V.I., Golovanov, A.V., and Lavrent‘ev, A.N., J. Gen. Chem. USSR (Engl. Transl.), 1985, 55, 2485. 98. Aleinikov, S.F., Krutikov, V.I., Golovanov, A.V., Lavrent’ev, A.N., J. Gen. Chem. USSR (Engl. Transl.), 1986, 56. 1046. 99. Wrablewski, A. E., Liebigs Ann. Chem., 1986, 1448. 100. WrGblewski, A.E., Liebigs iInn. Chem., 1986, 1854. 41, 791. 101. Wrgblewski,,A.E., 2 . Naturlrorsch.,Teil B, 1986, 102. Nifant’ev E . E . , Kukhareva, T.S., Popkova, T.N., and Davydochk.ina, O.V., J. Gen. Chem. USSR (Engl Transl.), 1986, 56, 264. I

s,

c,

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z,

so,

_-

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2,

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z,

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g,

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312,

309,

g, g,

56,

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286.

2,

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108.

2,

Nucleotides and Nucleic Acids BY J. B. HOBBS

1

Introduction

The e f f i c i e n c y of p r e s e n t m e t h o d s of o l i g o n u c l e o t i d e synthesis has not discouraged workers in the field from developing new methods, such a s the use of nucleoside H-phosphonates, or seeking to optimise current procedures, while the applications of oligonucleotides of defined sequence in research and biotechnology are constantly increasing. has

explained

"Why

Westheimer, in a published

Nature

c h o s e phosphates".'

lecture, Nature's

utilization o f n u c l e o s i d e p h o s p h a t e s i n u n e x p e c t e d w a y s i s emphasized

by

continuing revelations of t h e r6les of cyclic

nucleotides i n gating conductances in the membranes of receptor cells involved in vision2 and olfaction3 and t h e rble of tRNA in the biosynthesis of chlorophyll!4 symposium

As

usual, several valuable

reports have appeared a s journal issues o r in book

form,5 and a n e w book o n t h e organic chemistry of the nucleic acids has been pub1 ished.6 2 2.1

Mononucleotides

Chemical Synthesis -

In a general synthesis of nucleoside

3 ' -monophospha tes , a base -unprotec t e d 5 *-g-t - but y 1 d i met h y 1 s i 1 y 1 -

2 '-deoxynucleoside is treated successively with t-butylmagnesium chloride and diallyl phosphorochloridate, or alternatively a base-

protected 5'-~-dimethoxytrityl-2'-deoxynucleoside

is treated with

bis(ally1oxy) chlorophosphine and the resulting phosphite oxidised with

t-butyl

hydroperoxide.

'

T h e products ( 1 ) o r

(2) are

deprotected by standard methods, the ally1 group being removed with pa 1 1ad iurn

(

t r i ph e ny 1 piles ph i ne ) - n- b u t y 1a m i ne - form ic acid.

Yields are high, and the procedures a r e equally adaptable for

184

I85

6: Nucleotides and Nucleic Acids preparing nucleoside 5 .-monophosphates.

The nucleoside 6 -monophosphates of several 2-deoxy-fi- D allopyranosyl n u c l e o s i d e s ( 3 ) h a v e b e e n p r e p a r e d

using the

standard phosphoryl chloride-trimethyl phosphate procedure8.

The

4’,6’-monophosphate o f ( ( 3 ) ; B = C y t ) w a s a l s o p r e p a r e d , a s a n analogue of c C M P , by cyclisation o f the 6’-phosphate with DCC. The U M P analogue ( ( 3 ) ; antitumour activity

B=clra) showed moderate antiviral and

vitro.

A

series of derivatives of 5’-dUMP

containing quinone rings attached t o the 5-position of the base (4)

was

prepared

bis( methylated)

by

treating the

hydroquinones

corresponding nucleosidyl

with

phosphory 1

c h l o r ide

in

acetonitrile-pyridine-water, followed by oxidation using silver oxide and nitric acid.’

A l l the nucleotides showed high affinity

for thymidylate synthetase from Lactobacillus casei and L l Z l O leukaemia cells, and the dimethylbenzoquinone-containing compound behaved a s an active-site-directed alkylating agent enzyme.

None o f the compounds w a s active in antitumour or

antiviral assays. followed

for the

by

M e r c u r a t i o n of d U M P a t t h e 5 - p o s i t i o n ,

treatment

with

allylamine

and

potassium

tetrachloropalladate affords 5-(3-aminoallyl)-dUMP, (5) which when

treated w i t h t h e N-hydroxysuccinimide ( N H S ) ester of 3-carboxy2,2,5,5-tetramethyl-3-pyrrolin-l-oxyl

dUMP derivative (6).1°

affords the spin-labelled

Both ( 5 ) and (6) w e r e good competitive

inhibitors for thymidylate synthetase, with ( 6 ) displaying changes in t h e e.p.r. spectrum indicative of spin label immobilization upon binding t o t h e enzyme.

From this and other results, the

depth of t h e cavity i n which a substituent a t the 5-position of dUMP becomes bound was estimated.

2’,3’-Secouridine-2‘,3‘-di-~-acetate has been phosphorylated

using 4-nitrophenylphosphorodichloridate to afford ( 7 ) , after hydrolysis

and

deprotection.’

The

4-nitrophenyl

ester

of

secouridine 3’-phosphate (8) was prepared similarly from 2’,5’-di-

0-monomethoxytrity1)-secouridine.

Both

(7) and (8) (which are

diastereoisomers) were hydrolysed very slowly

by snake venom

186

Organophosphorus Chemist?

0

Hoi:-oII

I

0

n

I

7=

0-P-0

II

0

HO HO

( 1 ) R=TBDMS ; B = B a s e ( 21 R = DMTr ; 8 = P r o t e c t e d Base

( 3 ) 8-Ade ; Ura; Cyt

R'O

R20

(71 R1= 4 - NO,C,H,OP

-

I

( 0 OH ) ; R2= H

( 8 ) R'= H ; R2=4 N02C,H,0P( 0)OH

1

0

It

0

II

R-C-P-0

I

Me*

0 0

x

CH=CH-CH~NHZ

0

( 6 ) R =CH=CH-CH2-N-C

"

(5) R

5

I

Me

N-O'

Me Me

NH2

I

OH (13)

1

2

I

-H HO

R2

( 9 ) R = E t O ; R = O H ; B = G u a or (10) R ' = H O ; RZ=O H ; B=Gua or (11 1 R'= H2N; R2s OH ; B = Gua or (12) R ' = HO ; R2a H ; B = G u a o r

Adc Ade Adt Adc

6: Nucleorides and Nucleic Acids

187

p h o s p h o d i e s t e r a s e , a n d i n h i b i t e d c o m p e t i t i v e l y t h e h y d r o l y s i s of

e s t e r of

the 4-nitrophenyl

5 -dTMP.

Neither

h y d r o l y s e d by c a l f s p l e e n p h o s p h o d i e s t e r a s e , competitively t h e h y d r o l y s i s of dTMP.

Thus

both

t h e 4-nitrophenyl

diastereoisomers

(8) was

( 7 ) nor

though each inhibited e s t e r of

recognized

were

by

3 -

both

p h o s p h o d i e s te r a s e s .

S e v e r a l p u r i n e n u c l e o s i d e 5 ’ - p h o s p h o n o f o r m a t e s p e c i e s havc: been p r e p a r e d f o r i n v e s t i g a t i o n a s a n t i v i r a l a g e n t s . ( o r 2 ’ , 3 ~ - ~ , ~ - i s o p r o p y l i d edneer i v a t i v e s

Unprotected

o f ) adenosine and

g u a n o s i n e were t r e a t e d w i t h ( e t h o x y c a r b o n y l ) p h o s p h o n i c d i c h l o r i d e i n t r i m e t h y l phosphate t o a f f o r d ( 9 )o n work-up.12 treatment

with

or

hydroxide

methanolic

Subsequent

ammonia

hydroxycarbonylphosphonates

( 1 0 ) o r aminocarbonylphosphonates

respectively.

treatment

Analogous

of t h e

gave (11)

corresponding

2

’-

deoxynucleoside-3’-~-acetates a f f o r d e d t h e p h o s p h o n o f o r m a t e s ( 1 2 ) , which d i s p l a y e d s i g n i f i c a n t a c t i v i t y a g a i n s t herpes simplex v i r u s

in

(HSV)-2

(S)-9-(3-Hydroxy-2-phosphonomethoxypropyl)

vitro.

adenine ( 1 3 ) , presumably prepared

(S)-9-(2,3-

treatment of

d i h y d r o x y p r o p y l ) a d e n i n e w i t h chloromethylphosphonodichloridate,

as a novel

has been d e s c r i b e d agent,

a c t i v e

a g a i n s t

A

retroviruses.13

a

s e l e c t i v e broad-spectrum

range

phosphonate

of

isostere

monophospho-3-deoxy-D-manno-2-octulosonic of outer-membrane

v i r u s e s (14) of

acid

(

151,

antiviral and

also

cytidine

5‘-

a component

lipopolysaccharide of Gram negative bacteria,

has been prepared moiety

DNA

coupling t h e protected sugar phosphonate

t o ~4-benzoyl-2’,3’-isopropylidenecytidine u s i n g

t r i p h e n y l p h o s p h i n e a n d d i i s o p r o p y 1 a z o d i c a r b o x y 1a t e .

The

p h o s p h o n a t e ( 1 4 ) was a w e a k i n h i b i t o r o f t h e s y n t h e t a s e r e p o n s i b l e for t h e biosynthesis of (15).

S e v e r a l d e r i v a t i v e s o f 1‘-deoxy-

1 ’-phosphono-1-B-D-fructofuranosyluracil methyl

ester

(17),

the

( 16 )

3’-deoxy-analogue

,

including

(18), and

t h e

the 0 2 , 2 ‘ -

a n h y d r o - a n a l o g u e s of ( 1 6 ) a n d ( 1 7 ) , h a v e b e e n p r e p a r e d b y s t a n d a r d methods,

w i t h t h e anhydro-species s e r v i n g as i n t e r m e d i a t e s i n t h e

s y n t h e s e s of t h e o t h e r c o m p o u n d s . I 5

188

Organophosphorus Chemistr?.

Hoy$ioH ' ROfoR

0 - P-0-(Nucleoside-

OR I

HO

0 II

5')

-0 I

(19) R=Stearoyl ;Palmitoyl;Oleoyl

( 1 6 ) R1=H ; R 2 = OH (17)R':Mt;R2-OH

(18) R ' = M c ; RZ= H

O

ArA I

fcL;2ph

HO

OH

TBDMsow TBDMSO

R

( 2 1 ) R = H or OTBDMS

--OC6HLNO2-4

(22) (dThd-3/10

I 0--P.'

-.y'"

(dlhd H2@

#

- 3/10 I

p---0

04h

S

P P h

(24)

6: Nucleotides and Nucleic Acids

I89

5 ‘-Phosphatidylnucleosides

(

efficiently by using phospholipase phase

system

to

transfer

the

1Y D

)

have

been

p r e pa r c d

f r o m StrepgEySc? in a t w o -

phosphatidyl

phosphatidylcholines t o t h e 5 ‘ - h y d r o x y g r o u p o f

residue

of

a n u m b e r of

nucleoside acceptors, including adenosine, uridine, cytidine, 2 deoxyadenosi ne , 2

’-

deoxy thymidi ne , -_a ra - c y ti d in e , 5 - f 1 uor o u r id i n e

and 2 ’ - d e o x y - 5 - fl u o r o u r i d i n e , b r e d i n i n a n d n e p l a n o c i n A.16 Cytidine 5‘-monophosphosialate has been prepared f r o m CTP and 8 acety 1 neuramin ic a c id

u s i ng

c y t id i n e

5

‘-

m o n o p h o sp h o s i a 1 at e

synthase i m m o b i l i s e d o n a m i n o p r o p y l s i l i c a , a s p a r t of t h e synthesis of a trisaccharide using immobilized enzymes.17 Arabinof uranosyladenine-5 *-monophosphate

(

ais - A M P

ha s

9-B -D-

bee n

coupled t o poly (L-lysine) o r g a l a c t o s y l - p o l y ( L - l y s i n e ) using the

water-soluble l - e t h y l - 3 - d i m e t h y l a m i n o p r o p y lcarbodiimide ( E D C ) . The latter con jugate delivered the =-AMP

specif ical ly to 1 iver

cells, while the poly(l-lysine) conjugate w a s l e s s specific, inhibiting DNA synthesis in liver, intestine and bone marrow. Methyl 4-chlorobut-2-ynoate reacts with A M P , ADP o r ATP to afford

the

corresponding

chloromethylpyrimido[2,l-i

3- B-~-ribofuranosyl-7~-1-0~0-9-

I purine 5‘-phosphates ( 2 0 ~ ~ ’The

analogue ( 2 0 ; ~ = 2 ) w a s a substrate for pyruvate

ADP

kinase, and the

ATP analogue (20;1=3) w a s a substrate for hexokinase, adenylate kinase, and myosin ( w h i c h became irreversibly modified).

N2-

Benzoylated sugar-protected guanosine and 2’-deoxyguanosine react

with di ch loro- (N,N-diisopropy 1amino) phosphine in the presence of

N-ethy ldiisopropylamine t o give tr icy cl i c phosphi ty 1 ated guan i ne derivatives (21).20

Reaction is thought to occur initially at N-

1 followed by cyclisation, and other N2-acylated guanosine species react t o g i v e products analogous t o (21).

Reaction does not

occur if 0-6 is protected, or t h e 2-amino group is unprotected or tritylated.

The ribonucleoside product is converted back to the

starting material by brief treatment with trichloroacetic acid, the phosphite thus acting as a protecting group. In a n e w m e t h o d o f

preparing isotopomeric monoalkyl

190

Organophosphorus Chemisrry

[ l6O,

’0,”0 1

phosphates,

of ( R )-2’-deoxythymidine 3 -P ( 2 2 ) w i t h s t y r e n e [ 180] o x i d e i n

treatment

(4-nitrophenyl) phosphorothioate [170] H20

containing

DMF

[160,170,1801

p h o s p h a t e

diastereoisotopomeric

intermediate

afforded i n

( 2 3 )

purity.”

d e p i c t e d i n Scheme 1 .

’-

( R )-2’-deoxyt.hymldine P good y i e l d and h i q h

The

proposed

mechanism

I n t h e c r u c i a l s t a g e a t t a c k of

(23) is

followed

by

pseudorotation

1s

[170] ~

~ o n(

bring

the

to

sulphur atom t o t h e a p i c a l p o s i t i o n from which it is expelled; elimination of s t y r e n e sulphide then y i e l d s (23). c o n f i g u r a t i o n of

The a b s o l u t e

( 2 3 ) w a s determined v i a cyclisation t o t h e

cyclic monophosphate,

m e t h y l a t i o n a n d 31P n.m.r.

3‘,5‘-

spectroscopy.

T r e a t m e n t of a d e n o s i n e w i t h t h i o p h o s p h o r y l c h l o r i d e i n t r i e t h y l phosphate,

f o l l o w e d by m e t h a n o l ,

and p a r t i a l a l k a l i n e h y d r o l y s i s

o f t h e r e s u l t a n t t r i e s t e r a f f o r d s a racemic m i x t u r e of

(R ) and -P ( S ) m e t h y l a d e n o s i n e S ‘ - p h o s p h ~ r o t h i o a t e . ~ ~I n c u b a t i o n w i t h -P s n a k e venom p h o s p h o d i e s t e r a s e w h i c h p e r f o r m s s e l e c t i v e h y d r o l y s i s

) d i a s t e r e o i s o m e r ( 2 5 ) , p e r m i t t e d t h e (FP) a n d (5,) -P c o n f i g u r a t i o n s t o be a s s i g n e d i n t h e 31P n.m.r. s p e c t r u m a n d o n

of

the

h.p.1.c.

(S

traces.

Then,

bovine i n t e s t i n a l 11’0]

H20,

when t h e r a c e m a t e w a s i n c u b a t e d w i t h

mucosal

5’-nucleot i d e phosphodiesterase,

it c o u l d b e shown t h a t o n l y t h e

(S,)

was h y d r o l y s e d .

The r e s u l t a n t [180] AMPS formed

methylated,

shown

and

by

31P

n.m.r.

to

have

was i s o l a t e d , had

configuration (26), indicating t h a t t h e hydrolysis of

the

interm ed iate

monomethoxytrityl-2’-deoxyadenosine phosphoroanilidate,

s e p a r a t i o n of

. with

T r e a t m e n t

(S,)

(25) to ( 2 6 )

had p r o c e e d e d w i t h r e t e n t i o n o f c o n f i g u r a t i o n , p r e s u m a b l y nucleotidyl-enzyme

in

diastereoisomer

of

a

S’-O-

4-nitrophenylchloro-

the resulting diastereoisomers,

thiation w i t h sodium hydride and carbon d i s u l p h i d e , and f i n a l l y R 1 n u c l e o s i d y l 3‘m e t h y l a t i o n w i t h m e t h y l i o d i d e a f f o r d e d t h e ( -P ( 5 - m e t h y l ) ( 4 - n i t r o p h e n y l ) p h o s p h o r o t h i o a t e ( 2 7 ) a n d i t s (S,)

d i a s t e r e o i somer.

T r e a t m e n t

of

( 2 7 )

w i t h

3 ’ - 0 - t -

b u t y l d i m e t h y l s i l y l - 2 ’-deoxyadenosine a c t i v a t e d w i t h b u t y l l i t h i u m t h e n a f f o r d e d t h e (Ft.,)

diastereoisomer (28), t h e nitrophenolate

being expel led stereospecifically with inversion a t The (S ) d i a s t e r e o i s o r n e r o f ( 2 7 ) w a s s i m i l a r l y c o n v e r t e d t o t h e -P

1

6: Nucleotides and Nucleir Acids

191

( S ) d i a s t e r e o i s o m e r of ( 2 8 1. A s s i g n m e n t s of c o n f i g u r a t i o n were -P made b y 31P n . m . r . , a n d a l s o by u n b l o c k i n g ( 2 8 ) t o a f f o r d t h e

dinucleosidyl

phosphorothioate,

by

nuclease

P1

and

demethylation

of

(28) could

thus

of

which w a s r e s i s t a n t

(R

to hydrolysis

configuration.

)

P be performed

using

The?-

thiophenolate,

a l b e i t s l o w l y , a n d w i t h some c o n c o m i t a n t a t t a c k a t C - 5 ’ .

The p r o t e c t e d d i ( d e o x y t h y m i d y l y 1 ) p h o s p h i t e ( 2 9 ) e x h i b i t s two signals

in

the

diastereoisomers, the

product,

n.m.r.

31P

spectrum,

corresponding

b u t when t r e a t e d w i t h 2 , 3 - b u t a n e d i o n e

formulated

as

(30),

exhibits

only

a

to

its

a t O°C, single

I t is thought t h a t t h i s is due to pseudorotation

resonance.24

leading t o r a p i d s t e r e o m u t a t i o n a t t h e c h i r a l phosphorus atom. T h i s m u s t r e q u i r e d i e q u a t o r i a l l o c a t i o n of t h e d i o x a p h o s p h o l e n e r i n g i n s o m e rotamers,

a n arrangement which i s g e n e r a l l y regarded

as disfavoured due t o ring s t r a i n . T h e p o t e n t i a l of n u c l e o s i d e H - p h o s p h o n a t e s

€or t h e s y n t h e s i s

of o l i g o n u c l e o t i d e s , r e p o r t e d l a s t y e a r , 2 5 h a s b e e n e x t e n s i v e l y explored.

On t r e a t men t o f 5 ‘ - 2 - d i m e t h o x y t r i t y 1- 2 ’ - d e o x y t hym i d i n e -

3’-H-phosphonate TPS-tet,

( 3 1 ) w i t h a v a r i e t y o f c o u p l i n g a g e n t s (TPS-C1,

bis(2-oxo-3-oxazolidinyl)

diphenyl phosphorochloridate,

p h o s p h o r o c h l o r i d a t e ) a c o m p l e x p a t t e r n a p p e a r s i n t h e 31P n.m.r. spectrum which h a s been a s c r i b e d t o t h e t r i m e t a p h o s p h i t e ( 3 2 ) i n which t h e n u c l e o s i d e r e s i d u e s a r e s t e r i c a l l y n o n - e q u i v a l e n t . 2 6

Model an

reactions

anhydride

using

(33) is

e t h y l g-phosphonate formed

with

the

suggest

that

initially

condensing agent,

and

s u b s e q u e n t l y r e a c t s w i t h more p h o s p h o n a t e t o f o r m t h e s y m m e t r i c a l pyrophosphonate 134), which d o e s n o t react f u r t h e r i n t h e a b s e n c e

of p y r i d i n e ,

b u t w h i c h i s c o n d e n s e d w i t h more p h o s p h o n a t e m o n o m e r

to form (32) i n its presence. the diethyl

(32) is t r e a t e d with ethanol,

nucleosidyl-3’-phosphonate,

phosphonate a n d proportions,

If

s t a r t i n g material

presumably

a

initial

monoethyl

nucleosidyl-3’-

(31) are formed formation

of

i n

equal

the diethyl

p h o s p h o n a t e a n d (34), w h i c h i s t h e n a t t a c k e d t o g i v e t h e m o n o e t h y l compound a n d

(31).

T h e s e r e a c t i o n s may e x p l a i n why c o u p l i n g

192

Organophosphorus Chemistry

( 5 ' - MMTr- dAdo-3')O

I

125) R = OMc 1 2 6 ) R=180

(

27)

OMe

Thy

R 2 0 $ : - f - o J i ~R'3 Ac 0

( 3 5 ) R ' = H ; R * * D M T r ; R3:8t

130) R*,

P 1

NO,

0,

P I

136) R'z Me,CCO; R2: DM Tr ; R3=B t ( 3 7 ) R' = 4-CIC6H,C0 ; R2=R3=TBDMS ( 3 8 ) R'g 2-02NC6H,S; R2:R3sTBDMS (39) R' = DMTr; R2: R3: TBDMS ( 4 0 ) R'z H ; R2s DM Tr ; R 31 Polymer

,OR

10

P

I

141

OR

n n

( 3 2 )R: 5'-DMTr - d T h d - 3'-

O;N L J U

N

0

R'O - P

II

1

(33)

R'x

(12)

- OR

H

0

II

A r S O y or ( P h O ) , P -

[R as in ( 3 2 ) ]

R'= NH, ; MeNH ; Bu"NH ;

;

2

NMe, R ZDMTr; 3

R = Polymer

R': CCI,CH,OCO; R2=DMTr ;R360T 0

II

, ( 3 4 ) R ' = R U - P -I

H

6: Nucleorides and Nucleic Acids

193 is pre-activated

y i e l d s a r e lower when t h e i j - p h o s p h o n a t e

with

c o u p l i n g a g e n t b e f o r e a d d i n g t h e n u c l e o s i d i c c o m p o n e n t t h a n when adding t h e c o u p l i n g a g e n t component.

i n t h e presence of

the nucleosidic

triesters are not

Since phosphite

formed

in

the

l a t t e r case, t h e n u c l e o s i d e component presumably a t t a c k s (33)or

(34) t o g i v e c o u p l e d p r o d u c t b e f o r e

(32) is formed.

Pivaloyl

chloride i s o f t e n used, w i t h pyridine, t o couple n-phosphonates s u c h a s ( 3 1 ) t o 3 ’ - ~ - b e n z o y l - 2 ’ - d e o x y t h y m i d i n e( f o r i n s t a n c e ) t o afford

(351, b u t

it

has

now

been

established

that

the

H_-

phosphonate i s n o t i n e r t t o t h e c o u p l i n g a g e n t , b u t i n s t e a d reacts s l o w l y t o g i v e t h e p i v a l o y l p h o s p h o n a t e (36).*’ f o r t h e u s e of

t h i s method r e m a i n

to be established.

silylated dinucleosidyl b i s (t r i m e t h y l s i l y l )

3-phosphate

acetamide,

chlorobenzoy1 ch lor id e , or dimethoxytrityl and

The i m p l i c a t i o n s

p i v a l o y l c h l o r i d e i n o l i g o n u c l e o t i d e s y n t h e s i s by

chloride,

S i l y l a t i o n of t h e s u g a r -

analoglie of

f o l lowed

by

(35) w i t h El?-

treatment

with

4-

2 - n i t r o p h e n y 1s u 1p h e n y 1 c h 1 o r i d e o r

a f f o r d s (371, ( 3 8 )

and t r i e t h y l a m i n e ,

(391, r e s p e c t i v e l ~ . ~ ’ The n i t r o p h e n y l s u l p h e n y l

group is

r e a d i l y r e m o v e d f r o m ( 3 8 ) by o x i m a t e i o n s .

A similar reaction is

observed w i t h t h e

(31).

polymer-bound

5’-c-TBDMS

analogue of

n u c l e o s i d e H-phosphonate

O x i d a t i o n of

d i e s t e r (40) u s i n g ammonia

o r p r i m a r y or s e c o n d a r y a m i n e s i n c a r b o n t e t r a c h l o r i d e a f f o r d s a number

of

phosphoramidates

phosphoramidate

(41).*’

( 4 1 ; R = N H 2 ) were

but

A l l

stable

i n

the

ammonia

parent i n

the

c o n d i t i o n s n o r m a l l y u s e d f o r d e a c y l a t i o n o f b a s e s , a n d a l l were s t a b l e t o d i g e s t i o n b y s p l e e n a n d s n a k e venom p h o s p h o d i e s t e r a s e s . T r e a t m e n t of ( 4 0 ) w i t h s u l p h u r i n c a r b o n d i s u l p h i d e a f f o r d e d t h e p h o s p h o r o t h i o a t e , w h i l e t r e a t m e n t w i t h a n h y d r o u s m e t h a n o l o r nbutanol

i n t h e presence of carbon t e t r a c h l o r i d e and base afforded

the corresponding phosphotriesters.

When

( j l ) is coupled t o

2,2 , 2 - t r i c h l o r o e t h o x y c a r b o n y l p h o s p h o n i c a c i d disulphonyl

chloride,

separable b y

(42)

is

m e s i t y 1e n e -

and t h e p r o d u c t coupled i n t u r n t o 3’-0-

(1,3-benzodithio1-2-y1)-2’-deoxythymidine, phosphonate

w ith

formed

h.p.1 . c . ~ ’

The

as

a

mixture

corresponding

d i m e t h o x y t r i t y l a d e n i n e a s t h e b a s e of

t h e of

r e s u l t a n t diastereoisomers

compounds

t h e 5’-residue

with

z6-

were a l s o

Organophosphorus Chemist r?:

194 prepared.

When a single diastereoisomer w a s deprotected with

zinc, silylated with trimethylsilyl chloride and then oxidiscd with

sulphur,

a

single diastereoisomer

the ~ ~ r o t e c t ~ d

of

phosphorothioate, d(Ap(s)T), was formed in high yield, showing that n o racemisation had occurred. 311,

The chemical shifts i n the

n.m.r. spectra of starting material and product suggested that

the chirality at phosphorus had been retained throughout, and th(. mechanism depicted of serine,

1

n Scheme 2 w a s suggested.

The hydroxy groups

threonine and tyrosine, both in protected monomers

and in protected oligopeptides, have been converted t o their phosphonates

and

coupled

with

g-

3 -9-tetrahydropyranyl-2

-

deoxythymidine using pivaloyl chloride, after which subsequent oxidation with i o d ~ n cafforded the protected nucleopeptides.

’’

5‘-O-Dimethoxytrityl-2‘-deoxynucleosidyl-3‘-methyl-

phosphonates have been coupled t o 3 ’-g-(1 -menthoxycarbonyl ) -2 ’ deoxynucleosides

ILI

s ing

r J , rJ- b i s ( 2 -

O X -~ 3

-

X z ~o

O

1 i d iny 1

)

phosphorodiamidic chloride and N-methylimidazole t o afford the methylphosphonate

(43)

diastereoisomers.32

as

a

(generally) separable

T h e chiral

menthyl

pair

of

group facilitates

resolution, and can subsequently be removed selectively without cleaving the base-protecting groups t o afford good yields of the protected dimers.

A mixture of t h e diastereoisomers of’ ( 4 4 ) ,

formed by oxidising the corresponding phosphite with iodine in [’*O]

H20, could not be separated chromatographically, but on

desilylation with fluoride the diastereoisomers of ( 4 5 ) were easily separated o n silica

After deblocking s a m p l e s of

each to assign the configuration using 31P n.m.r. spectroscopy, the

( R ) and ( S ) diastereoisomers of ( 4 5 ) were converted to their 3’-P -P methoxydiisopropylphosphoramidites f o r u s e a s d i m e r b l o c k s in solid phase oligonucleotide synthesis. of

5‘-0-(2’-deoxythyrnidyl)

The ( -P S

)

diastereoisorner

3’-0-(2’-deoxyadenosyl)

phosphorothioate (46) w a s hydrolysed specifically by mung bean nuclease, and when this reaction w a s performed i n [ l 8 0 ] H Z O , stereochemical a n a l y s i s o f

the

2’-deoxythymidine

phosphorothioate] formed showed it to have the

(S

-P

)

5,-[180-

configuration

6: Nucleotides and Nucleic Acids

NucO

Scheme 2

OMc

( d 3 ) B,= Thy or C y t B Z 8,- Thy C y t B Z JAdeezor GuaEu’

(LLI R = TBDMS ( 4 5 ) R = OH

R = 1 - Menthoxycarbonyl

0,

.o

P’A s

I

HO

(46)

A dc Bz

cytBz

AcO OAc ( L 7 ) R = 9 -(L-octadccyl oxyphcnyl) xanthcn 9 - y l

-

196

Organophosphorus Chemistry

(e. a s in

(26)) and thus that hydrolysis had proceeded with

inversion a t t h e p h o s p h o r u s atom.34

Using appropriately

protected starting materials, and phosphotriester methods, t h e fully protected UpU species (47) has been synthesized.35

After

removal of the phosphate-protection with fluoride, treatment of (47) with methanolic ammonia results in specific displacement of the

6-methyl-2-pyridyl

function,

converting the

3'-base

to

cytosine, while treatment with aqueous ammonia displaces both the 6-methyl-2-pyridyl group and the 2,4,6-trimethylphenyl group, converting

both

bases

t o cytosine.

deprotection protocols can lead UpU, UpC or CpC.

to

Thus,

alternative

the conversion of (47) to

Treatment of (48) with 4-toluenesulphonic acid

to r e m o v e the pixy1 group resulted in isomerisation of the

internucleotidic link with l o s s of 2-chlorophenolate, and a l s o

fracture of the internucleotidic link,presumably via formation of

a phosphotriester intermediate in which the 2'-hydroxy group had expelled 2-chlorophenolate by transester if ication. 36

A number o f

analogues of ApG have been synthesized using the phosphotriester approach a n d t h e i r a b i l i t y t o p r i m e t h e s y n t h e s i s of m R N A catalysed by influenza virus RNA polymerase has been studied.37

Highly reactive phosphoramidates of mono- and dinucleotides have

reportedly been

deoxythymidylic acid

prepsred

by

[ d(pT(0Ac) 1 ]

condensing

3.-2-acetyl-2'-

, or d[ pTpT(O4c)) with g-methyl-

imidazole ( t o give ( 4 9 ) ) o r 4 - g , N - d i m e t h y l a m i n o p y r i d i n e

tr ipheny lphosphine a n d

2 ,2 ' -d i p y r i d y 1 d i s u 1 p h i d e .

*

using Upo n

treatment w i t h a l i p h a t i c a m i n e s , r a p i d d i s p l a c e m e n t of _Nmethylimidazole or dimethylaminopyridine takes place to form new phosphoramidates.

T h e parameters affecting reaction rates and

yields of phosphoramidates prepared using triphenylphosphine and 2,2'-dipyridyl

d'isulphide h a v e b e e n studied.39

The Perkow

react ion o f 5 '-g- ace ty 1- 3 ' - 9 - t osy 1 - 2 '-ke t ou ridine with t r ime th y 1

phosphite afforded the enol phosphate (50) in low yield.40 catalytic

hydrogenation

of

(501,

dideoxyuridine could be obtained.

only

upon

5'-9-acetyl-2',3'-

I97

6: Nucleotides and Nucleic Acids Heavy-atom

s u b s t i t u t i o n s o f AMP i n t h e b a s e a n d sugar r l n y s

t o a f f o r d (L,-2HIAMP, [9-l5N]AMP,

1 ,-2HlAMP,

11 * - 1 4 C ] A M P , [ 1

' -

2 H , 1 c-'4C]AMP a n d [ 9 - I 5 ~ , l, - 1 4 C ] A M P h a v e b e e n p e r f o r m e d , m o s t l y using enzymic methods, in

i n order t o study kinetic isotope e f f e c t s

t h e N-glycohydrolase

a c t i v i t y of

v a r i a t i o n i n t h e p r e s e n c e of

an

AMP n u c l e o s i d a s e ,

allosteric

and t h e i r

activator.41

The

s e l f - a s s o c i a t i o n a n d p r o t o n a t i o n o f 5'-AMP h a v e b e e n c o m p a r e d w i t h those of

3'-AMP,

2 '-AMP

and t u b e r c i d i n - 5 '-monophosphate

AMP) b y m o n i t o r i n g t h e c o n c e n t r a t i o n - d e p e n d e n t sugar-ring suggest

protons

that

stacking,

i n four

all

the

lH n . m . r .

s h i f t s of

spectra.42

monophosphates

base and results

exhibit non-cooperative

and t h a t no hydrogen-bonding

p h o s p h a t e m o n o a n i o n o c c u r s i n 5'-AMP.

The

(7-deaza-

between

N-7

and

the

I n 50% a q u e o u s d i o x a n ,

the

lowering o f s o l v e n t p o l a r i t y f a c i l i t a t e s t h e removal of t h e proton f r o m 5'-AMP p r o t o n a t e d a t N-1, w h i l e t h e d i a n i o n i c p h o s p h a t e g r o u p b e c o m e s more b a s i c . monoanion o f pH

range.

I n c o n s e q u e n c e , t h e pH r a n g e o v e r w h i c h t h e

AMP i s s t a b l e i s e x t e n d e d i n t o t h e p h y s i o l o g i c a l A comparable

situation

may

obtain

in

regions

of

causing a phosphate group

lowered d i e l e c t r i c c o n s t a n t i n p r o t e i n s ,

which is d i a n i o n i c i n b u l k s o l u t i o n t o become a n e f f e c t i v e p r o t o n acceptor.

T h e k i n e t i c s o f h y d r o l y s i s o f AMP a t h i g h t e m p e r a t u r e

h a v e b e e n i n v e s t i g a t e d , t h e m a i n p a t h w a y a p p a r e n t l y i n v o l v i n g loss of p h o s p h a t e from t h e p h o ~ p h o m o n o a n i o n . ~ ~ T h e f r e e e n e r g y of h y d r o l y s i s o f t y r o s y l a d e n y l a t e h a s been d e t e r m i n e d . 4 4

An e p o x i d i s e d

form

(51) of

t h e hypermodified nucleoside

queuosine h a s been i s o l a t e d from tRNATYr

of p " g L i c h i a

~ 0 1 1 , ~ ~

a n d a new f l u o r e s c e n t t r i c y c l i c n u c l e o s i d e ( 5 2 ) h a s b e e n o b t a i n e d .

from t h e t R N A o f

Sulpholobus s o l f a t a r i c u s and o t h e r thermophilic

a r c h a e b a c t e r i a . 46 2.2

C y c l i c N u c l e o t i d e s - T h e m e c h a n i s m of r e a c t i o n o f 3'-UMP

N-benzoylimidazole h a s been i n v e s t i g a t e d . 4 7 base,

t h e r e a c t i o n p r o c e e d s m a i n l y &y

f o r m a t i o n of t h e mixed

benzoic-phosphoric a n h y d r i d e t o form u r i d i n e - 2 and i t s !i'-C-benzoylated

derivative,

with

I n t . h e a b s e n c e of

',3 '-m o n o p h o s p h a t e

while i n t h e presence of

Organophosphorus Chemistry

I98

Acoy---

Ura

0

0 II

0- POMe

I

(49)R=3'-0-Acor 3 ' -

dThd

- 5'

(501

0-AC - d ( TpT)- 5'

Me0

NH

I

I

I

Me

Rib

(52) Rib

Adc

R'O 1

2

( 5 5 ) R : T o s ; R =Me, 8 u

, PhCH2

Adt

( 5 3 ) R = H ; X: F , C I ,Br (5L)R*Me;X * B r , I R:PhCH,;X= I

RL

,I , CF, 56) R': Tos ; R2= H , R3= Ph I C,H,,,C6H,, or R2=R3sE t NH

2

(57) R'zTos ; R OMe ; S E t ; N E t 2 ; X i s absent (58) R': H ; R2: OMe ; SEt ; NEt, ; X = O or S

0'1 HO

OH (59)

6: Nucleotides and Nucleic Acids

199

strong organic bases,

deprotonatlon

of

t h e 2.-

and

functions favours benzoylation a t these positions, of

5 -hydroxy

while formation

t h e p h o s p h a t e d i a n i o n , a weakcr n u c l e o p h i l e t h a n t h e monoaniun,

renders

f o r m a t i o n of

t h e mixed a n h y d r i d e more d i f f i c u l t ,

t o s u p p r e s s f o r m a t i o n of

A number

prepared

using

antiviral

5-halo-2’-deoxyuridine-3’, 5 ’ - m o n o p h o s p h a t e s

of

( 5 3 ) a n d some o f

m e t h y l o r benzyl e s t e r s ( 5 4 ) h a v e b e e n

their

standard methods,

properties

and

examined.48

trif luoromethyl-2 ‘-deoxyuridine highly

tendinq

t h e c y c l i c phosphate.

active against

and

t h e i r

While t h e i r

c e r t a i n tumour

antitumour

5-fluoro-

and

5 ’-phosphates lines,

cell

and

their

5-

werv 3’,5’-

c y c l i c p h o s p h a t e s w e r e much less p o t e n t , s u g g e s t i n g t h a t t h e y d o n o t a c t a s p r o d r u g s of t h e 5 ’ - m o n o p h o s p h a t e s .

Against. v a c c i n i a

v i r u s , h o w e v e r , t h e c y c l i c p h o s p h a t e s ( 5 3 ) w e r e more p o t e n t t h a n corresponding

the

5‘-monophosphates,

although t h i s

order

was

reversed f o r herpes simplex v i r u s .

2

with

' -g-Tosy 1a d e n o s i n e - 3 ‘ ,5 - m o n o p h o s p h a t e ‘

alkyl

tosylates

in

the

presence

of

has

t r ea t ed

he e n

quaternary

ammonium

hydroxide t o a f f o r d ( 5 5 ) , or w i t h p r i m a r y o r s e c o n d a r y a m i n e s i n t h e p r e s e n c e of t r i p h e n y l p h o s p h i n e a n d c a r b o n t e t r a c h l o r i d e t o a f f o r d ( 5 6 ) , a s m i x t u r e s of d i a s t e r e o i s o m e r s . 4 9

Removal o f t h e

tosyl

afforded

group

using

corresponding a l k y l

sodium

naphthalide

then

the

e s t e r s o r a m i d a t e s o f cAMP i n g o o d y i e l d .

Alternatively,treatmen t o f 2

’-g-tos y l a d e n o s i n e

with appropriate

phosphite r e a g e n t s has been used t o prepare t h e cyclophosphites ( 5 7 ) which on o x i d a t i o n w i t h aqueous i o d i n e or s u l p h u r , by

detosylation

as above,

or cyclothiophosphates

followed

give t h e corresponding cyclophosphates (581,

r e s p e ~ t i v e l y . ~ I~n

a

simple

s y n t h e s i s o f t h e a l k y l t r i e s t e r s of CAMP, t h e t r i - n - b u t y l a m m o n i u m

s a l t o f cAMP i s t r e a t e d w i t h t h e c o r r e s p o n d i n g a l k y l b r o m i d e i n N,N-dimethylacetamide

a t elevated temperatures.

Y i e l d s a re

g e n e r a l l y good, t h e r e a c t i o n being r e g i o s e l e c t i v e f o r f o r m a t i o n of t h e m o r e t h e r m o d y n a m i c a l l y s t a b l e isomer w i t h t h e a l k y l ‘ g r o u p i n the axial position.

Treatment

of

lI3-bis(2-hydroxyethyl)

200

Organophosphorus Chemistry

adenosine-3‘,5 ’-phosphate w i t h sodium h y d r o x i d e f a i l e d t o e l i c i t the usual

Dimroth

pyrimidine

ring

rearrangement.52

occurred,

with

Instead,

loss

of

opening

ethylene

of

the

oxide and

f o r m a t e a s t h e major p a t h w a y s , t o f o r m ( 5 9 ) .

The

3 ’, 5 ’ - c y c l i c

phosphates

of

2

’, 3 ’ - s e c o a d e n o s i n e

and

2‘,3 ’-secoguanosine ( 6 0 ) have been p r e p a r e d by c y c l i s a t i o n o f t h e 5 ‘-phosphates

of

t h e corresponding

seconucleosides.53

T h e CAMP

analogue was c o n v e r t e d t o 8-bromo-2’, 3 ‘ - ~ e c o a d e n o s i n e - 3 ~ , 5 ’ a n d t o 2’,3’-secoinosine-3’,5’-phosphate

p h o s p h a t e by b r o m i n a t i o n , using

nitrous

acid.

The

s e c o - 3 ’,5 ‘ - c y c l i c

phosphates

were

r e s i s t a n t t o m a m m a l i a n cAMP p h o s p h o d i e s t e r a s e s , b u t w e r e s l o w l y hydrolysed by c y c l i c n u c l e o t i d e p h o s p h o d i e s t e r a s e s from h i g h e r

2 ‘ - ~ - M e t h y l a n t h r a n i l o y l - - c G M Pu n d e r g o e s a 4 5 % d e c r e a s e i n

plants.

f l u o r e s c e n c e w h e n c l e a v e d b y b r a i n cGMP p h o s p h o d i e s t e r a s e i n t h e presence of calmodulin,

a property

which h a s been u t i l i z e d i n

developing a c o n t i n u o u s f l u o r e s c e n c e a s s a y of t h e h y d r o l y s i s of cGMP b y c y c l i c n u c l e o t i d e p h o s p h o d i e s t e r a s e . 5 4

The d y n a m i c s o f

cGMP m e t a b o l i s m

may

b e m o n i t o r e d by

m e a s u r i n g t h e r a t e o f i n c o r p o r a t i o n o f l 8 O f r o m [180]H 2 0 i n t o t h e a-phosphoryl

g r o u p s of g u a n i n e n u c l e o t i d e s , a n d t h i s t e c h n i q u e h a s

been u s e d t o show t h a t t h e m e t a b o l i c

calls

increases

to

up

4.5-fold

f l u x o f cGMP i n r e c e p t o r

i n

correlation

with

the

i l l u m i n a t i o n o f o c u l a r p h o t o r e c e p t o r s . 55

(Rp)

Once a g a i n t h e

and (S

-P

)

d i a s t e r e o i s o m e r s of a d e n o s i n e

3 ’ , 5 ’ - p h o s p h o r o t h i o a t e (CAMPS) h a v e p r o v e d u s e f u l i n e l u c i d a t i n g hormone-directed messenger

‘.

cellular

While

responses

( S )-CAMPS m i m i c s

involving

cAMP

as

’second

t h e n o r m a l l y CAMP-mediated

-P response t o e x t r a c e l l u l a r glucagon by p h o s p h o r y l a t i n g c y t o s o l i c i n rat hepatocytes, ( R )-CAMPS a n t a g o n i s e s t h i s -P r e s p o n s e , 5 6 a n d a 1 so i n h i b i t , s g l u c o n e o g e n e s i s . 5 7 A n a 1o g o u s 1 y ,

proteins

( S )-CAMPS a c t i v a t e s

CAMP-dependent p r o t e i n k i n a s e i s o l a t e d f r o m -P Leydig t u m o u r c e l l s , a n d a c t i v a t e s s t e r o i d b i o s y n t h e s i s i n t h e intact

cells,

while

the

(R ) - d i a s t e r e o i s o m e r -P

inhibits

these

6: Nucleotides and Nucleic Acids

20 1

responses. ’8 3.

Nucleoside Polyphosphates Nucleoside

5’-diphosphates (61), 5 ’ - m e t h y l e n e d i p h o s p h o n a t e s

(62) and ATP have been prepared in generally g o o d yields

by

displacement of the tosyl group from the corresponding !i’-
The a m i n o groups of the guanine and cytosine

bases were protected by the dimethylaminomethylene function during the

reactions,

and

masking

the

sugar

as

the

2‘,3‘-9,c)-

isopropylidene derivative gave a n increased yield of ADP.

The

attempted use of this method to prepare pyrimidine nucleoside 5’triphosphates afforded poor yields, however. action

of

a

water-soluble

In a study of the

carbodiimide on

adenosine

5’-

polyphosphates, treatment of A M P , ADP or ADP with EDC afforded the expected diadenosine-5 ’-5’-polyphosphates A( 5’)p2A, A( 5 ‘)p4A and

A(5 ‘)p6A, respectively, a s major products, i n yields which were significantly increased in the presence of Mg2+ ions.60

However,

with adenosine 5‘-tetraphosphate the major nucleotidic product was AMP.

It

was

proposed

that

in

the

latter

case

the

trimetaphosphate derivative ( 6 3 ) is formed, after which hydrolytic attack at PB either regenerates the starting material or liberates AMP with concomitant formation of trimetaphosphate.

In the other

cases, all the observed products could be rationalised as arising -a

terminal phosphorylurea of type (64). The hydrolysis of nucleoside polyphosphates by macrocyclic

polyarnines continues to stimulate interest.

1 , 4 , 7, 13, 16, 1 9 -

Hexaaza-lo, 22-dioxocyclotetraeicosane catalyses the hydrolysis of ATP w i t h f o r m a t i o n o f t h e p h o s p h o r y l a t e d m a c r o c y c l e a s a n intermediate, and the entropies of activation for this process at pH3 and pH7, and for the solvation of t h e intermediate at pH7, have been determined.61 strength, although Na’

T h e reaction is insensitive t o ionic and C1- ions depress the rate at pH7.

202

Organophosphorus Chemistry

HO-

0

0

P-X-

P -0

II

I

( 6 0 ) B = Ade,Gua

i

- ( N U C- 5’)

HO

HO

HO

II

(61) X = 0 ; N uc: Urd, C y d , Guo, Ado,dThd

, d Ado

(62) X = CFz ; N U C= A d o X * CH,; Nuc = A d o

0

II

I

R’

4 65)

(66)

0 HO -C

II

- 0-

II

P - 0-

I

0-

0

0- P

0 II

I

0

ii - 0 - PI

-0

-0

(67)

R’S

I

( 69

1 R’= 4 - NO,C,H,CH,

s

0

I

I

2

; R absent

( 70) R’, R 2 absent

(71 1 R’ a b s e n t , R2rP0,

P

4

*\\

0 .

0 .

l

,o-

0,

l

(721

( A d o - 5’)

4: Nucleotides and Nucleir Acids

203

Analogues of the macrocycle in which the oxygen atoms are replacc3d by nitrogen atoms, or removed, enhance the rates of hydrolysis of ATP at pH3 and pH7.

Using analogues o f ATP and A(5’)p4A

as

potential substrates, it has been shown that adenosine nucleotidcs with a readily hydrolysable link between P a and P y (i.e. - A’rP, adenylyl

imidodiphosphate,

adenosine

5 ’ - (

, B

a

-

methyleneltriphosphate) a r e hydrolysed rapidly with l o s s of t h e terminal phosphoryl group, while those with a non-hydrolysable link in the s a m e position (i.e. - (5’-adenylyl)difluoromethylenebis(5’-adenylyl)dichloromethylenediphosphonatc~)

diphosphonate and

are hydrolysed very slowly to release AMP.62

It has been argued

that, while phosphoryl transfer to the macrocycle could occur an associative SN2P o r a dissociative SNIP mechanism,

V

J

it is

difficult t o reconcile the former mechanism with the observed selective c l e a v a g e

at

symmetrically (65).

The polyprotonated macrocycle may facilitate

Py

rather

than

P,

i f

is bound

ATP

proton transfer from Py-OH t o t h e BY-bridging oxygen a t o m , or a P y , -oxygen a t o m , potentiating phosphoryl transfer t o the nitrogen atom

of t h e macrocycle via a dissociative process.

It is

evidently capable of acting a s a ’protoenzyme’, and it will be interesting to see whether studies with chiral phosphates can shed further light on the mechanism.

(S)-6-(Hydroxymethyl)-1,5,10,14-

tetraazacyclooctadecane (66) has been prepared, starting from Lornithine,

and

appears

to

bind

ATP

strongly

with

1:l

stoicheiometry, as evidenced by downfield shifts in the 31P n.m.r. spectrum when ATP is mixed with (66) at pH 6.8.63 Heat-conduction m i c r o c a 1 o r i m e t r y u t i 1 i z ny t h e A T P a s e activity of heavy meromyosin has been employed t o determine the thermodynamics

of

orthophosphate.64

the

hydrolysis

A n e w model

of

ATP

to

ADP

and

for the molecular mechanism of

FIFO H+-ATPase/ATP synthase makes specific proposals regarding

proton flow through the enzyme following conformational changes at the F1/Fo interface, and the resultant protonation of phosphoryl

oxygens leading t o loss of water and phosphorylation of ADP.65

Using biotin carboxylase from E.coli in t h e absence of biotin, a

204

Organophosphorus Chemistry

b i c a r b o n a t e - d e p e n d e n t ATPase a c t i v i t y h a s b e e n d e m o n s t r a t e d , correlates

with

the

activity

of

biotin

carboxylation

which

in

the

p r e s e n c e of b i o t i n , a n d a p p e a r s t o b e a g e n u i n e p a r t i a l a c t i v i t y o f t h e enzyme.66

I t h a s t h e r e f o r e been proposed t h a t b i c a r b o n a t e

i s p h o s p h o r y l a t e d b y ATP t o g i v e c a r b o x y l p h o s p h a t e ( 6 7 ) i n t h e first

s t e p

of

t h e

reaction,

r a t h e r

than

b i o t i n

being

p h o s p h o r y l a t e d b y ATP p r i o r t o r e a c t i o n w i t h b i c a r b o n a t e , a n d t h a t t h i s may b e a common m e c h a n i s m f o r e n z y m e s e m p l o y i n g c a r b o n a t e f o r carboxylation.

seems q u i t e c o n s i s t e n t w i t h t h e

The p r o p o s a l

c o n c l u s i o n s drawn from a s t u d y of carbamoyl phosphate s y n t h e t a s e , which

[ Y -180]

used

ATP

and

monitored

BY-bridge

exchange i n t h e p r e s e n c e a n d a b s e n c e o f

-B-nonbridge

bicarbonate

and o t h e r

s u b s t r a t e s . 67

E n z y m i c m e t h o d s h a v e b e e n u s e d t o p r e p a r e f o u r ADP s p e c i e s w i t h l80 l a b e l l i n g i n t h e ap - b r i d g e p o s i t i o n , o r i n n o n - b r i d g e p o s i t i o n s , o r b o t h , a n d s i x ATP s p e c i e s w i t h l 8 0 i n t h e B Y - b r i d g e p o s i t i o n , or i n n o n - b r i d g e p o s i t i o n s , or i n b o t h , i n o r d e r t o ree v a l u a t e t h e 180-isotope s h i f t e f f e c t i n t h e 31P n.m.r. t h e t e r m i n a l phosphate groups.68 position

was

found

phosphorus atom Following

to cause a

than

for

the central

shift

different

exchanged

with

for

the terminal

phosphorus

binding t o t h e active site of

[y--1804]ATP b e c o m e

atom

in

ATP.

m y o s i n , t h e l80 atoms o f

surrounding

water

by

t w o

p a t h w a y s d i s t i n g u i s h e d k i n e t i c a l l y b y t h e i n f l u e n c e of

actin, and t h e temperature has

larger

s l g n a l s of

180 i n a b r i d g e

Interestingly,

been

examined

in

dependence of t h i s ‘isotope washout’

order

to

characterise

the

pathways.69

D u r i n g t h e s y n t h e s i s o f ATP f r o m A D P a n d 1 1 8 0 ] o r t h o p h o s p h a t e i n submitochondrial particles, labelled

species

have

u n e x p e c t e d d i s t r i b u t i o n s of

been

observed,

possibly

due

[ 180]-

to

the

incomplete randomization o f phosphate oxygens d u r i n g r e v e r s i b l e c y c l e s o f h y d r o l y s i s and s y n t h e s i s o f t h e enzyme-bound

else

to

a

s l o w

transition

between

high-

and

ATP, o r

low-exchange

pathways. 7 0

Once a g a i n ,

chiral

nucleotides have found wide application

6: Nucleorides and Nucleic Acids for

205

e l i c i t i n g t h e s t e r e o c h e m i c a l c o u r s e of r e a c t i o n .

method

for

the

analogues of

synthesis

the

of

~n a r a p i d

diastereoisomers

of

a -thio

r i b o - and deoxyribonucleoside d i - and t r i p h o s p h a t e s ,

t h e unprotected nucleoside is treated with thiophosphoryl chloride in t r i e t h y l phosphate a t l o w temperature i n t h e presence of 2,6lutidine,

a n d

t h e

r e s u l t a n t

phosphorodichloridothioate

treated

c r u d e

n u c l e o s i d y l

b r i e f 1y

with

5‘-

( s a y ) t r i -n-

o c t y l a m m o n i u m p y r o p h o s p h a t e i n DMF, p r i o r t o a q u e o u s q u e n c h i n g a n d s e p a r a t i o n of t h e ( R ) and ( S ) n u c l e o s i d e 5 ’ - ( l - t h i o ) t r i p h o s p h a t e -P -P p r o d u c t s u s i n g r e v e r s e p h a s e h . p . l . ~ . ~ ‘ An o x y g e n i s o t o p e may b e introduced,

i f

(gp)-isomer of action

desired,

by quenching i n l a b e l l e d water.

[ a - 1 7 0 , a - l 8 0 , nf? -180] ATP ( 6 8 ) i s c l e a v e d b y t h e

argininosuccinate

of

The

synthetase

i n

the

presence

of

c i t r u l l i n e a n d a s p a r t a t e t o a f f o r d ( S ) - [ 160,170,180]AMP, t h u s -P demonstrating t h a t net inversion occurs a t phosphorus, without t h e formation of

a n a d e n y l y l a t e d e n z y m e p r i o r t o t h e s y n t h e s i s of

citrulline adenylate.72

In t h i s study,

t h e preference of

the

e n z y m e f o r t h e ( R ) i s o m e r o f ATPBS a s s u b s t r a t e i n t h e p r e s e n c e -P o f Mg2+ i o n s , a n d f o r t h e ( S ) isomer i n t h e p r e s e n c e o f C d 2 + i o n s

-P

was a l s o d e m o n s t r a t e d ,

i n d i c a t i n g t h a t t h e enzyme p r e f e r s thePC

screw s e n s e c o n f i g u r a t ’ i o n o f

as substrate.

the B

,Y-bidentate

Using (gp)-[a-170]dATP,

metal-ATP

complex

it h a s been shown t h a t

deoxyadenylyl t r a n s f e r t o t h e aminoglycoside a n t i b i o t i c tobramycin catalysed

by

inversion of nucleotidyl

gentamycin

nucleotidyltransferase proceeds

t h e configuration a t phosphorus, transfer.73

Using

probably

( g p ) - [ a- 1 8 0 ] A T P ,

it

with direct

was

also

d e m o n s t r a t e d t h a t c y c l i s a t i o n t o [ 180]cAMP b y a d e n y l a t e c y c l a s e from Bordetella p e r t u s s i s a l s o proceeds w i t h inversion.

I n a s t u d y o f t r a n s c r i p t i o n u s i n g T7 R N A p o l y m e r a s e , ATPoS

was a

incorporated inhibitor.74

good

substrate

for

t h e enzyme,

becoming

(Sp)-

readily

w h i l e ( R )-ATPaS w a s n e i t h e r s u b s t r a t e n o r -P Analysis of t h e stereochemistry of t h e

i n t o RNA,

internucleotidic phosphorothioate links using chirality-specific n u e l e a s e s r e v e a l e d t h a t t h e 1 i n k s f o r m e d h a d ( ~ ~ ) - c O l ng fu r a t i o n , the polymerisation

r e a c t i o n having t h u s proceeded

with inversion

206

Organophosphorus Chemistry I n t e r e s t i n g l y , t h e s t e r e o c h e m i c a l s e l e c t i v i t y s h o w n by

a t Po.

for

the nucleases was

RNA

links

(R ) -- P

phosphorothioate-substituted

in the

less s t r i n g e n t t h a n

t h a t observed using dinucleotide

mode 1 s .

Sa l a c t o s e - 1 - p h o s p h a t e u r i d y l y 1 t r a n s f e r a s e a c c e p t s

[2-14C]

UDPaS-glucose

as

a

substrate,

t o a f f o r d a UMPS-enzyme

phosphate

displacing

intermediate

(R

)

-

~-P glucose-l-

i n

which

a

h i s t i d i n e r e s i d u e h a s become t h i o p h ~ s p h o r y l a t e d . ~ ~ On t r e a t m e n t with

t-butoxide

(R ) u r i d i n e - 3

-P

', 5

i n

the

DMSO,

'-phosphorothioate,

is

nucleotide and,

released

as

since this cyclisation

p r o c e e d s w i t h i n v e r s i o n , t h e o r i g i n a l t r a n s f e r of t h e t h i o u r i d y l y l m o i e t y t o t h e e n z y m e m u s t also h a v e p r o c e e d e d w i t h i n v e r s i o n . Since,

moreover,

t h e o v e r a l l r e a c t i o n t o form UDPaS-galactose

was

a l r e a d y k n o w n t o p r o c e e d w i t h r e t e n t i o n of c o n f i g u r a t i o n , t r a n s f e r of

the

thiouridylyl

phosphate must

moiety

from

the

to

enzyme

a l s o proceed with inversion,

galactose-l-

thus defining the

s t e r e o c h e m i c a l c o u r s e of r e a c t i o n a t p h o s p h o r u s i n b o t h s t a g e s of t h e double-displacement

(Rp)

mechanism.

~ , - [ Y - ~ ~ O , ~ ~ O ] Ah T a sP bYeSe n p r e p a r e d b y a n o v e l h i g h -

yield route:

adenosine is t r e a t e d with thiophosphoryl chloride i n

t r i e t h y l ' p h o s p h a t e ( a p r o c e s s m o r e s p e c i f i c for p h o s p h o r y l a t i n g the 5'-position

in

t h a n using phosphoryl c h l o r i d e ) , and t h e n worked

t o a f f o r d [1802]AMPS,

up [ 1 8 0 ] H 2 0 [180]H,0

nitrobenzyl)

t o give [

703]

which is o x i d i s e d w i t h bromine

[1803]AMP.76

This

thiophosphate using

is c o u p l e d

to

S-(4-

diphenylphosphoro-

c h l o r i d a t e (DPPC), t o g i v e (691, w h i c h i s r e d u c e d w i t h s o d i u m a n d l i q u i d ammonia ( g i v i n g ( 7 0 ) ), a n d PEP

to

give

and t h e n treated

an with

(Rp)

phosphorylated with pyruvate kinase and

(Rp)-ATP5S e x c l u s i v e l y t o l e a v e

(3,)

( S

-P

hexokinase and

D-glucose,

(sp)-ATPY S

-'80,8-170,]ATPyS

5,-[a-1802,aB

m i x t u r e o f ATPBS i s o m e r s ,

or,

(71).

which removes

more

accurately,

Finally,

(71) is

t r e a t e d w i t h methionyl-tRNA s y n t h e t a s e and m e t h i o n i n e , which f o r m s the

adenylyl

enzyme

thiopyrophosphoryl isolated,

effect

moiety

i n high yield,

and

scrambles

displaced,

t h e

ends

permitting

the reverse reaction.

of

(72) t o

t h e be

Th1.s i s , i n

( g p ) - 5 ' - [ Y - ~ ~ o , ~ ~ O ] - A T Pt h~eS ,o t h e r i s o t o p i c a l l y l a b e l l e d

6: Nucleotides and Nucleic Acids

207

oxygen a t o m s being superfluous for its use in determining tht stereochemistry of phosphoryl transfer.

(Sp)-[By - 1 7 0 , ~- I 7 ( ) ,

Y -180]ATPYS i s a substrate for the nucleoside 5 '-triphosphat-ase

activity o f transcription termination factor

from ~ . c o il. 7 7

p

Analysis of t h e [ 170,180] thiophosphate released s h o w s it t o possess

(R

-P

)-chirality,

indicating

that

transfer

the

of

thiophosphoryl moiety t o water occurs w i t h inversion, and thus probably directly without formation of a phosphoenzyrne or phosphoRNA intermediate.

(Sp)-[ Y-1702,180] ATPY

S

has been used to

investigate the stereochemistry of thiophosphoryl transfer to the C-3

o x y g e n a t o m o f m e v a l o n a t e 5 - d i p h o s p h a t e c a t a l y z e d by

mevalonate

c a r b o x y 1 a s e.

5 - d i ph o s p h a t e

The

C - 3

thiophosphorylated mevalonate-5-diphosphate loses carbon dioxide and, a s demonstrated by analysis, (Hp)-[1 7 0 , 1 8 0 ] thiophosphate, showing that

thiophosphoryl transfer had proceeded with inversion

at phosphorus, probably directly and without the intermediacy of a thiophosphoryl-enzyme species.

(Rp)-[y -1802] ITPyS has been used

as a substrate for P E P carboxykinase from rat liver cytosol, forming

(S

-P

)-thio[l*O] PEP a s demonstrated by transfer of t h e

thiophosphoryl

group

to

ADP

using

pyruvatt

kinase

stereochemical analysis of the resulting [ y-180]ATPyS.79

and Again

thiophosphoryl transfer had thus occurred with inversion, probably directly without involving a thiophosphoryl-enzyme intermediate. The ( R

S -P ) and ( -P

diastereoisomers of ATPaS and A T B S , and

also A T P y S , h a v e b e e n t e s t e d a s s u b s t r a t e s o f d y n e i n f r o m T h e ( S ) isomer of ATPBS w a s preferred a s -P in the presence of Mg2+ ions, and t h e ( R ) isomer with

Tetrahymena_cilia.80 substrate

-P

Cd2+ ions, but n o comparable stereospecificity was shown with the stereoisomers o f ATPaS.

W h e n p r o c h i r a l ADPB S w a s u s e d as a

substrate €or the reverse reaction of N1'-formyltetrahydrofolate

synthetase in the presence o f Mg2+ ions, isolation of the ATPBS formed and stereochemical analysis showed that the ( S

-P ) isomer of

[Mg.ATPBSI2-, having A s c r e w sense, had been formed, consistent with t h e enzyme's preference for (Sp)-[ Mg.ATP6SI2- a s substrate for the forward reaction.81

The

fix

screw sense isomers (R -P

)

also

Organophosphorus Chemistry b i n d e f f i c i e n t l y t o t h e enzyme, b u t n o n - p r o d u c t i v e l y

The s u b s t i t u t i o n - i n e r t

triamminecobalt

(111) ATP

exists as

four t r i d e n t a t e complexes (731, s e p a r a b l e o n cycloheptaamylose c o l u m n s , i n w h i c h t h e a b s o l u t e c o n f i g u r a t i o n s a t . Pa a n d P R h a v e now

b e e n e s t a b l i s h e d by c o m p a r i n g t h e

d i f f e r e n c e s o b s e r v e d i n t h e 31P n.m.r. [aJ80]ATP

[180]-induced

s h i f t

(R~)-

s p e c t r u m when e i t h e r

a r e m i x e d w i t h ATP w h e n p r e p a r i n g t h e

o r (sp)-[B-’80]ATP

I n preparing t h e s t a r t i n g m a t e r i a l s , it w a s found

complexes.82

t h a t d e s u l p h u r i z a t i o n of c h i r a l ADPaS a n d ATPBS u s i n g b r o m i n e i n [ 180]H20 a t

pH3 o c c u r s

with

near-quantitative

w i t h o u t s c r a m b l i n g t h e l8O l a b e l i n t r o d u c e d .

inversion,

and

The isomers ( 7 3 )

s h o u l d p r o v e v a l u a b l e i n p r o b i n g t h e s u b s t r a t e s p e c i f i c i t y of e n z y m e s w h i c h u t i l i s e t r i d e n t a t e [Mg.ATPI2- a s s u b s t r a t e :

for i n s t a n c e ,

kinase,

isomer.

The

is preferentially

BY-bidentate

therefqre thought

and

that

inactivates

a, B , Y - t r i d e n t a t e

the

natural

t h e enzyme.83

substrate,

recognized by t h e enzyme a s i t s B,y-bidentate studies

on

the

conformational

diastereoisomers

of

described,84

the syntheses

and

B,y

bidentate complexes of

exo

chromium (III).ATP complex h a s h i g h e r

a f f i n i t y f o r b i n d i n g t o (Na++K+)ATPase t h a n t h e Cr(III).ATP complex,

creatine

i n h i b i t e d by t h e n

complex.

isomerization

-bidentate of

is

I t

[Mg.ATPI2-,

is

Kinetic the

four

Cr(III).ATP have

been

the

of

y-monodentate

and

,Y

-

C r ( I I I ) I T P , a n d t h e s e p a r a t i o n of t h e i r

s t e r e o i g o m e r s , h a v e b e e n r e p o r t e d . 85 5 ,6 - D i h y d r o - d T T P

( 7 4 ) a n d 5 ,6 - d i h y d r o x y - d T T P

(

75) have been

p r e p a r e d b y c a t a l y t i c r e d u c t i o n o f dTTP o v e r r h o d i u m - a l u m i n a ,

and

b y t r e a t m e n t of dTTP w i t h b r o m i n e w a t e r f o l l o w e d b y s i l v e r o x i d e , r e s p e c t J v e l ~ . ~T ~he d i h y d r o n u c l e o t i d e ( 7 4 ) was i n c o r p o r a t e d i n

place

of

dTTP

during

fragment o f E.coli dTTP,

without

primer

apparent

diastereoisomers,

elongation

catalysed

DNA p o l y m e r a s e I , a l b e i t a t

selectivity

suggesting that

for

cellular

by

Klenow

a lower r a t e t h a n the

(5R)

o r

(5.5)

(74) produced

r a d i a t i o n c o u l d a l s o b e c o m e i n c o r p o r a t e d i n t o DNA.

by

The t h y m i d i n e

g l y c o l d e r i v a t i v e ( 7 5 ) w a s n o t a s u b s t r a t e f o r Klenow f r a g m e n t .

6: Nucleotides and Nucleic Acids

209

Two new procedures for preparing C-5 biotinylated derivatives of dUTP start from 5-~nercurateddUTP, which in one case is coupled

with ( y - b i o t i n y l ) - 6 - a m i n o h e x y l acrylate in the presence of lithium tetrachloropalladate,87

and

in

the

other

treated

is

with

allylamine to form 5-(3-aminoallyl)dUTP which is then N-acylated by the y-hydroxysuccinimide

(NHS)

ester of biotin, or of 2-

(biotinamido)ethyl-l,3 ‘-dithiopropionate.88

In the last c a s e ,

this means that biotin is attached to dUTP by a chain containing an easily reducible disulphide link (76). species c o u l d

be

used

a s substrates

permitting the biotinylation of DNA.

All three biotin-dUTP i n nick

translation,

5-(3-Aminoallyl )dUTP has

also b e e n t r e a t e d w i t h t h e N H S e s t e r of 4 - c a r b o x y - 2 , 2 , 6 , 6 tetramethylpyrrolidin-1-oxyl

(4-carboxy-TEMPO) t o introduce the

spin-label at the 5-position of dUTP, and similarly spin-labelled derivatives of dUTP and UDP have been prepared by treating 4-thiodUTP and 4-thio-UDP, respectively, with 4-iodoacetarnido-TEMPO and an epoxide derivative of nucleotides

The three spin-label led

were s u b s t r a t e s f o r D N A p o l y m e r a s e I, t e r m i n a l

deoxynuc leot idy 1 t r a ns f e ra se , and PO 1 y nu c 1 eo t ide phosphor y 1 ase , respectively,

per m itt ing

s p i n - 1 a b e 1 1 ing

of

cop01yme ric

polynucleotide products at levels from 2 to 6%. A review of enzymic, chemical and combined syntheses of nucleotides

9

radiolabelled with

Tr it ia ted prepared

by

-et hy 1 - 2

I-

phosphorus-32 has appeared.90

deoxy thy m 1 d 1 ne - 5 ‘-t r i p h o s p ha t e ha s been

p h o s p h o r y 1 at i n g

e4- e t h y 1 - 5 - n y d r o x y m e t hy 1 - 2

‘-

deoxyuridine consecutively with carrot phosphotransferase, and carbonyldiimidazole

and

pyrophosphate,

to

obtain

the

5

’-

triphosphate, which was then reduced with tritium gas over Adams’ catalyst . 9 ’ The inhibition of reverse transcriptases by sugar-modified nucleoside 5‘-triphosphates is attracting much interest, not least for t h e h o p e i t o f f e r s of c o n t r o l l i n g r e t r o v i r a l d i s e a s e s including

AIDS.

dideoxythymidine

The

(

5’-triphosphates

of

3’-azido-2‘,3’-

’AZT‘), 9 2 , 9 3 as well as the analogous 3’-amino-,

210

Organophosphorus Chemistry

RZ

R1

0

0

'*.

1

0

/p\o

0

H,N-,CoH3N"

0 '

;--[

- P=O 1 1

0

\p'O

RL R3 2 3 L R = R = R :Aexo 2 R = A d o - 5 ' ; R ' = R 3 = R' : A endo 1 2 L R?-Ado - 5 ' ; R = R :R : A e n d o 1 2 3 RiAdo -5'; R = R = R : Aexo S

I

_PEP

_P_P_P

(71) R = H

1

(75)

(73)R=Ado-5';

dRib-5'-

I

dRib-5'-

:\ 0 ' 0

R = OH 0

0

(761 d C O N H 2

CH2

Y

I

Ad e

Ade Dpa

R ( 8 1 ) R . L -MeC,H,S

(82)R=OH

M S E = MeS02CH2CH,

6: Nucleotides and N u c l e i Acids 3’-fluoro-, a n d

21 1

2’,3’-dideoxy-analogues of d T T P g 3 a r e all

powerful inhibitors of human immunodeficiency virus ( H Z V ) reverse transcriptase, and other studies have identified these, or closely related compounds, a s inhibitors o f reverse transcriptases from Rauscher virus.95

murine

leukaemia

virus94

and

avian

myeloblastosis

For the most part, inhibition appears to be competitive

against dTTP a s substrate €or these e n z y m e s rather than due to incorporation leading to chain termination.

However, A M V reverse

transcriptase and a number o f other polymerising enzymes (terminal deoxynucleotidyl transferase,9 5 Klenow fragment, T4 D N A polymerase

and calf thymus D N A polymerase a ) 9 6 can recognize and incorporate a number of these sugar-modified analogues, particularly 3’-amino2 ’,3 ’-dideoxynucleoside 5 ‘-triphosphates a n d s o m e of t h e i r 3

‘-

derivatives, with resultant blockage of further chain elongation. Syntheses of the 5’-triphosphates of 3‘-amino- and 3’-azido-(E)-5(2-bromovinyl)-Z ’, 3 ’-dideoxyuridine have been described.97 replication

and

UV-induced

DNA

repair

synthesis

in

DNA

human

fibroblasts are sensitive t o aphidicol in, thus implicating the aphidicolin-sensitive D N A polymerases a and

6

in these processes.

Since both processes a r e relatively insensitive to N2-(4-nbutylpheny1)-dGTP which is a strong inhibitor of D N A polymerase a ,

and more sensitive t o inhibition by 2‘,3‘-dideoxy-TTP than D N A polymerase a

,

D N A polymerase 6 is implicated in these

A number of 2 ’ - d e o x y - 2 ’ - h a l o c ~ e n a t e d

function^.'^

ribo- and ?La-nucleoside-5 ’-

triphosphates have been investigated as alternative substrates or mechanism-based inhibitors of r i b o n u c l e o t i d e r e d u c t a s e f r o m Lactobacillus leishmanii.99 fluoronucleotides

gave

In the pyrimidine series, the 2’-

mainly the normal 2‘-deoxynucleotide

product of r e d u c t i o n , w h i l e 2 ’ - c h l o r o n u c l e o t i d e s a c t e d a s mechanism-based inhibitors t o inactivate the enzyme (although partitioning between these modes of reaction was pH-dependent, and thought

to be

reductase).

dependent These

on

results

the

protonation

are

consistent

s t a t e of with

a

the

model

postulating a radical cation intermediate, reported previously . 2 5 5-Deazaflavin adenine dinucleotide has been prepared using a

Organophosphorus Chemistry

212 modified p h o s p h o t r i e s t e r a p p r o a c h

i n which

2 , 3 , 4 - t r i s - O--

tetrahydropyranyl-7-dea~ariboflavin was t r e a t e d s u c c e s s i v e l y w i t h b i s ( 1-benzotriazolyl) phosphoromorphol i d a t e , 2-cyanoethanol, triethylamine t o a f f o r d (77).’0° acidic deblockiny,

then

R e a c t i o n w i t h AMP,

afforded

the deslred

and

f o l l o w e d by

material.

The

antitumour e f f e c t of t i a z o f u r i n i s r e l a t e d t o i t s anabolism t o thiazole-4-carboxamide

adenine

dinucleotide

(TAD),

a

powerful

IMP d e h y d r o g e n a s e , a n d s e v e r a l p h o s p h o d i e s t e r a s e -

i n h i b i t o r of

r e s i s t a n t analogues of

TAD ( 7 8 - 8 0 ) h a v e b e e n p r e p a r e d b y c o u p l i n g

the appropriate phosphonates with phosphoramidate s p e c i e s ( f o r ( 7 8 ) a n d ( 7 9 ) ) , or c o u p l i n g s u g a r - p r o t e c t e d t i a z o f u r i n t o s u q a r -

protected

adenosine

(80)).lo1

dehydrogenase,

5 -methylenediphosphonate

three

A l l

while

were

analogues

being

more

using

DCC

(for

to

IMP

inhibitory

resistant

t o

hydrolysis

by

p h o s p h o d i e s t e r a s e t h a n TAU, w i t h ( 8 0 ) b e i n g t h e m o s t s t a b l e .

A n u m b e r o f d n a l o g u e s of GTP, m o d i f i e d i n t h e t r i p h o s p h a t e

chain,

have been

transducin,

t h e

photoreceptors,

€or t h e i r a b i l i t y t o i n t e r a c t

examined s i g n a l

i n order

coupling

i n

with

v e r t e b r a t e

t o e x p l o r e t h e s p e c i t i c i t y of

the

y -

I n a s t u d y which a l s o i n v o l v e d GDP

phosphate binding region.lo2 species modified

p r o t e i n

i n the diphosphate chain,

t h e i n t e r a c t i o n of

p r o t e i n s y n t h e s i s i n i t i a t i o n f a c t o r 2 f r o m Xenopus l a e v i s o o c y t e s w i t h GDP a n d GTP a n a l o g u e s w a s e x a m i n e d . l o 3

The

three

possible

pyrophosphate-linked

dimers

deoxyadenosine-3 ‘ , 5 ‘-bis(phosphate1 h a v e b e e n p r e p a r e d p h o s p h o t r i es t e r

was

treated

successively and

triazoly1)phosphorothioate

2’-

g6 - D ip h e ny 1ace t y 1- 2 *- d e o x y a d e n o s i n e

approach.

phosphorochlor i d a t e,

of

using a

bis[2-(methylsulphonyl)ethyl]

with

2 - 4 - m e t h y 1 p h e n y 1 -0,9-b i s i n

aqueous p y r i d i n e t o g i v e ( 8 1 ) .

dioxan,

and

O x i d a t i o n of

(

1- b e nz o-

subsequently

with

(81) usinq aqueous

i o d i n e t h e n a f f o r d e d ( 8 2 ) , a n d o x i d a t i o n of ( 8 1 ) u s i n g i o d i n e i n p y r i d i n e i n t h e p r e s e n c e of ammonia, g a v e

the

(82),

f o l l o w e d by d e b l o c k i n g w i t h

3’-3’-pyrophosphate

(83) i n

high yield.

A

m i n o r v a r i a t i o n i n t h e o r d e r of p h o s p h o r y l a t i o n a l l o w e d ( 8 4 ) t o b e

6: Nucleotides and Nucleic- Acid5

I

I

Hd

HO

213

Ht)

I

OH

(831

AdeDPa

-0

CH,O(CH, ),CH,

I

0

II

CHzO-P-O-P-

I

I

-0

O - y t dCYt

-0

HO

&

( 8 5 ) R = CH,(CH,l,,CO ; n : 15 or 17 ( 8 6 ) R CH, ; 17

0

II

0

wAde

II -;

0 - P -I0 - P - 0

-0

0

0

I

o=p-o-

I

(88) Ac-

X

- Ala-

Ser - Y

I

-0

- OMe

PPPA (891 X m i s s i n g , Y : L e u or X r A r g , Y m i s s i n g or X : L e u , Y m i s s i n g

F

DMTrO

0- P -0Mc 0 PSiMe3 5 -cc I

(92)

I CCI,

Thy

(901 R

='a

(91) R = O - C C = C C I ~

I

CCI,

(931 R = C I

(94)R = H

, (951 R = I

OH

Organophosphorus Chemist?

2 14 prepdred

as

prepared

intcrrnt,diat~ for

an

pyrophosphate,

the

whi l r

making

3 -5 - 1inked

tht.

-1 inkcd

5 -5

could

pyrophosphate

be-.

from ( 8 4 ) a n d (82).

(5 - a d e n o s y l 1 t e t r a p h o s p h a t e

p4-Bis

P’,

p4n)

(A(5 )

and

t r i p h o s p h a t p ( A (5 ) p 3 R ) h a v e b e e n p r e p a r t l d

P1 , g 3 - b i s ( 5 - a d e n o s y l )

by c o n d e n s i n g A D P w i t h i t s e l f or w i t h A M P u s i n g c a r b o n y l h i s ( l , L , 4 -

o r c a r b o n y I b i s ( b e n zi IT ida z o l e

t r i a z o le

continues to

attract

polyamines a

marked

is o b s e r v c d . l o 6

much

interest:

enhancement of It

).

t t l t r a ph ospha t c

The

in t h e presence

intramolecular adenine stdcking

is a p o w e r f u l

a c t i v a t o r of

the

proposal

shock

to

that

heat

proteins

acts

it

shock

no

c

and

longer

3

~

an

appears

to

with

dNTP

and

i n h i b i t o r s . lo’) s u b s t r a t e - and

A(5

from

of

hexaphosphate

primer-bindiny

pentaphosphate,

inhibitors

to

to

bind

Terminal

which

being

the

t h e

of

to act a s an

kina5e

from

compete

enzyme,

the

partic ~ l a r l y 5trong

human

both to the

enzyme,

affinity

a n d also t h e t e t r a p h o s p h a t e ,

adenosine

in

heat

of

t h y m u s is i n h i b i t e d b y t h e

domains

by periodate,

formed

tenable.’”

The> p e n t a p h o s p h a t e a p p e a r s t o b i n d

following oxidation The

being

-

moleculrs

Howeve>r,

formation

o l i g o p h o s p h a t e 5 A ( 5 ) p n A (n_=2-6),

substrate

pentaphosphate

the

be

deoxynucleotidyl transferase frcm calf bis(5’-adenosyl)

,

alarmone

stimulating

5 -

cytosolic

n u c l e o t i d a s e s in A r t e m i a e m b r y o s a n d i n r a t l i v e r . ’ ( ” response

Mg2+ or

of

and,

label. l 1

w erc p o w e r f u l

liver

cells,

and

) p 5 ( d T ) a n d A(5 ) p 6 ( d ‘ I ’ ) s t r o n g l y i n h i b i t e d t h y m i d y l a t e k i n d 5 e peripheral

patterns

of

bisubstrate binding

cells

blast

inhibition analogues

of

leukaemic

indicate

t h a t

for t h e entymes,

sites s i m u l t a n e o u s l y ,

patients.”’

t h e s e blocking

species both

The a c t

a s

substratc-

and suygest t h a t i n t h e s e enLymes,

p h o s p h o r y l t r a n s f e r f r o m A ‘ r P t o t h e a c c e p t o r n u c l e o s i d e is d i r e c t , rather than proceeding

v s a double-displacement

s t u d y of t h e i n h i b i t i o n c h a r a c t e r i s t i c s of from Lactobacillus

mechanism.

deoxynucleoside

A

kinases

a c i d o p h i l u s b y d N T P species ( t h e e n d - p r o d u c t s )

a n d ( d N ) ( 5 ) p 4 A species f c u n d t h a t t h e s e c c m p o u n d s a r e u s e f u l f o r d i s t i n g u i s h i n g t h e k i n e t i c m e c h a n i s m s of sequential pathways.

k i n a s e s w h i c h follow

6: Nudeorides and Nucleic Acids

21s

L i p i d c o n j u g a t e s of E - C D P by

treating

( 8 5 ) and

appropriate ph~spholipid.”~

The compound

be

E-cytidine

much

more e f f e c t i v e t h a n

leukaemias.

metabolite

A

species in

( 8 6 ) have been prepared

gig-cytidine- 5 - p h o s p h o r o m o r p h o l i d a t e

the

with

the

(85;n=15) wa5 f o u n d t o against

certain

mouse

which appears t o b e dn intermediate

7-dehydroxylation

of

bile

acids appears,

on

thc

b a s i s o f e v i d e n c e o b t a i n e d b y e n z y m i c d e g r a d a t i o n a n d g.1.c.-m.s. analysis,

t o have t h e structure

S e v e r a l ATP v - p e p t i d y l

(88). l1

esters ( 8 9 ) h a v e b e e n p r e p a r e d as p o t e n t i a l m u l t i s u b s t r a t e a d d u c t i n h i b i t o r s of c A M P - d e p e n d e n t p r o t e i n k i n a s e b y c o u p l i n g t h e s e r y l phosphate

of

the

preformed

oligopeptide

to

A DP

activated

with

ca r b o n y 1 d i i m i d a z o l e .

4.

4.1

Oligo:

and Poly-nucleotides

- Chemical S y n t h e s i s -

An e x c e l l e n t r e v i e w

i n t e r alia,

review dealing, containing

the

of

chemistry

with t h e synthesis of oligonucleotides

solid-phase

,

synthesis

of

DN A

via

base-protected

5

synthesis,

have been surveyed.

deoxynucleoside

derivatives has been further developed.

a

ch e m i c a l l y

Recent improvements

oligonucleotide

together with developments i n apparatus

The

as has another

i n t e r n u c le o t i d i c l i n k s , o r b e a r i n g

modified

r e a c t i v e g r o u p s or i n t e r c a l a t i n g a g e n t s . l 1 in

the organic

of

chemistry underlying D N A synthesis has appeared,

‘-g - d i m e t h o x y t r i t y l - 2

I.1 - p h o s p h o n a t e

T y p i c a l l y , t r e a t m e n t of ’-deoxynucleoside

with

t r i s ( t r i a z o l y 1 ) p h o s p h i t e l l 9 or tris ( i m i d a z o l y l ) p h o s p h i t e , 1 2 ’ formed

& situ

heterocyclic phosphonate

from

base,

phosphorus

( e . g . ( 31) )

preferred

solid

coupling

notwithstanding

the

and

the

support, agent

2 ’-deoxynucleoside

with out

considerations

of

pivaloyl t h e noted

appropriate

nucleoside

following aqueous work-up.

coupled to a base-protected position to a

trichloride

affords t h e corresponding

3

bound

i t s 3 ’-

chloride being

range above. 27

’-g-

T h i s is t h e n

the

available,120 The

requires n o protection a t phosphorus, and n o capping step.

method The

216

Organophosphorus Chemisty

P r o d u c t o f coupling

(e.9.

dichloroacetic

in

next

coupliny

minutes120

acid step.

Cycle t i m e s

have been

elongation,

a

( 4 0 ) ) is t h e n d e t r i t y l a t e d

dichloiomethane,

reported!

of

in

four the

A t

using L-2.5%

preparation minutes119 completion

s t e p serves t o oxidise

single cxidaticn

for

the

and

seven

of

chain

all t h e

H-

phosphonate links t o t h e corresFonding

phosphates,

aqueous Fyridine h a s proved t o b e t h e

p r e f e r r e d r e a g e n t . ' 19-'

Rerroval

from

the

polymer

and

deblocking

and iodine in

follow

procedurestand oligonucleotides as long as 107-mers prepared i n t h i s way.119

Using

base-protected

*'

established have been

2 -0-TBDMS-

ribonucleosides as s t a r t i n g materials, t h e s a m e p r o c e d u r e h a s b e e n utilized

to

oligoribonuclectides.122

prepare

In

a

comparative

study of a g e n t s f o r t h e oxidation of t h e H-phosphonatelinkage,

(31)

a n d its m e t h y l e s t e r were u s e d a s r r o d t l c o m p c u n d s € o r c x i d a t i o n b y dipyridyl

disulphide,

Oxidation but

the

using species

fcrmed

toc

phosphodiester

hexachloroacetone,

was

hexachloroacetone,

dipyridyl disulphide

formed a s

(e.g.(90)) undergc

be

to

n.m.r.

some c o n c o m i t a n t d e m e t h y l a t i o n

iodine.' 21 silylation,

practicably

spectrcscopy

an Intermediate,

and prior

hydrolysis

-

slowly 'P

requires

the

to

useful.

Using

suggested t h a t

~ r i o rt o h y d r o l y s i s . w a s cbserved.

(91)

Hobever,

P r e s i l y l a t i o n of

t h e p h o s p h o n a t e i n c r e a s e d t h e r a t e o f r e a c t i o n , t h e p a t t e r n of b y Froduct

formaticn

intermediate,

sugqesting

prior t o forminq

t h a t

(92)

(91) or t h e

was

formed

a s

chlorophocphate

a n

( 93 ) .

Oxidation with iodine i n aqueous pyridine w a s also accelerated by p r e s i l y l a t i o n of t h e p h o s p h o n a t e , a n d w a s l u d q e d t h e b e s t m e t h o d , with

the

intermediate

iodophosphate

(95)

undergoing

rapid

hydrolysis to give t h e phosphodiester. Presently, widely-used

m e t h o d is t h e

most

p r c c e d u r e i n oliqcdeoxyribonucleotide s y n t h e s i s .

though,

t h e phosphoramidite

In

a s t u d y of t h e t h e r m a l s t a b i l i t y of scme a l k y l p h o s p h o r o d i a n i d i t e s ( 9 6 ) - ( 101)

of

potential

phosphoramidites,

utility

f o r

preparing

nuclec5idyl

a l l e x c e p t ( 9 6 ) a n d (101) were t h e r m a l l y s t a b l e ,

b u t ( 9 6 ) a n d ( 1 0 1 ) d e c o m p o s e a t o r b e l o w room t e m p e r a t u r e t o t h e corresponding

alkenes

and

y-phosphonic

formed t h e a l k y l p h o s p h o n i c

diamides

diamides,

(102) and

w hich

in

(103).123

turn

An

6: Nucleotides and Nucleic Acids

217

0 It

ROPI NR’,)~

~~22)

R’CH~CH~P(

(96) R = C Y C H 2 C N ; R’: E t (971 R : C H , C H ~ ; R’= P r ’

(102) R’zCN ; R Z =E t ( 1 0 3 ) R1=MeS02 ; R Z = E t or P r ’

198) R-CHMeCH2CN ; R’: E t (99) RsCMe2CH2CN ; R’= E t

(100) R: CMe2CH2CN ; R’= P r ’ (101) R=CH2CH2S0fic ; R’x Et o r P r ’

(105) X i s absent (106)X = H +

N

OR1 (107)

1

(109) R * M M T r ; R 2 = R 3 = C H 2 C H 2 C N (110) R’:DMTr; R2:2-ClCSHL;R3=Me

(111) X - B r or C l ; ~ = 2 , n = 3 (112) X = B r ; m = 3 I n - 2

R

\

N I I

(113) X = OH (111) x C I N (115) X

N’ V

yNo2 N

Me (116) R x N O z (117) R = CF,

218

Organophosphorus Chemistry

improved treated

diisopropylamine

the

in

with

which

in cther,

of

presence

in

acetonitril~~,,ind

h a s D P P ~ c l e ~ c r i b c d . ’ * ~T r e a t m e n t 0 1

p e r m i t s the

tetrazole

deoxyribonucletside

L‘,

phosphoru5 trichloridt,

2-cyanoethanol

5 -0-dimethohytrit yl-2 -deoxynucleosides

base-protc,ctcld in

of ( 9 7 1 ,

synthesis

succc5sively

L)hosphorllmiditEs

z t u

(104)

u5e

for

with

(07)

preparation in

of

pclymer

s u p p o r t e d oligodecxyribonucleotidt, sb n t h c s i s . ’ l 5

O n l y t r a c e s of

3 -3

guanine

-coubled

requires

by-products

protection

a t

carbamoyl groJ1’ i n arrino group,

are by

O6

tht.

to

addition

formed, but

the

4-nitrophenylethyl

(104) t o prey a r e o l i g o n u c l e o t i d e s o n

a

diphenyl

01

by-products. long

2-

a t thi.

conventional prctection

t o s u p p r e s s t h t l f o r m a t i o n of

rinq

II%inq

chain alkylainin(

-

c o n t r o l l e d pore glass ( L C A A - C P G 1 s u p p o r t , e f f i c i e n t s y n t h e s e 5 w i t h c y c l e t i m e s of 1 0 - 1 2 . 5 a

similar

nucleotides phase

to

way both

t h e

to

above,

v x block-coupliny

synthesis,

s t u d i e s of

minutps w e r e achieved.

(97),

has

also

reaction

T h e u%c> of

prepare

in

solution,

and

bcen

of

a 5olid-

in

In

n u m b e r of

a

( 9 0 ) in

oligodt cxyriho-

mc,chanl%tlc-

3 -

2 -deoxythymidint

p h o s p h o r a m i d i t e s p e c i e s , of g e n e r a l t c p e ( l O S ) , w i t h P j 6 - b e n z o y l - 3

~ - t - b u t y l d i p h e n y l s i l y l - 2 - d e o x y a d e n o s i n e , t h e r a t e of c o u p l i n q to

found

depend

phosphoramidite

in

k h e t h e r

b e f o r e

or

t c t r a z o l e

a f t e r

addition

’”

of

addcd the,

The results obtained a r e accommodated in a

which

tetrazole

initially

f o r m t h e t e t r a z o l i d e s a l t of

protonates

to

thr,

d d e n o ~ i n c ~

(106) by

tetrazole then

the

mechanism

phosphor dmidite

(106) i n a rapid equilibrium

is r e v e r s e d b y a d d e d t e t r a z o l i d e .

which

was

a n d also t o b e i n h i b i t e d b y d i a l k y l a m monium t e t r a z o l i d c .

component,

salts.

o n

-

wd5

affords

the

Nucleophllic

to

reaction attack

phosphorotetrazolldite

on

(1071

w i t h d i s p l a c e m e n t of t h e d i a l k y l a m i n e m o i e t y a s a d i a l k y l a m m o n i u m ion,

a n d ( 1 0 7 ) reacts w i t h t h e a d e n o s i n e

coupled basicity

state

product.

of

5N H I

facilitates

tetrazole,

low

R

reactivity

being

a 2-chlorophenyl

since

moderately observed

group.

component t o afford t h e

ccupling increases wlth increasing

enhanced

displacemrnt

was

and

T h e r a t e of

of

protonation t h e

in

the

transition

dialkylammonium

ion

s e n s i t i v e t o steric h i n d r a n c e

when

p h o s p h t e oxygen

by

with

w a s blocked by

6: Nucleotides and Nucleic Acids

219

B i s ( trimcthylsi l y l ) peroxidr., t - h d t y 1 hydropt:roxide,

hydroFeroxide and N-methylmorphol ine-!-oxide

cumene

have been cxplored as

nonaqueous agents f o r oxidi5ing phosphites such a s (108) to th(. corresponding phosphates, as an alternative to the aqueous iodine which

is

normally used.128

B i s

( T M S ) peroxide was particularly

effective, especia11y in thc presence of TMS-trif late, dnd w d 5 also s u c c e s s f u l l y used

for t h i s p u r p o s e

in a sol id-pha5c’

synthesis. In s o m e solid-phase o l i g o d e o x y r i b o n u c l e o t i d ~s y n t h e s ~ s dimoric phosphoiamidite synthons such a s prepared by

(

109)1L9 and ( 1 1 0 ) ’ 3 0 ,

s t a n d a r d s o l u t i o n m e t h o d s , h a v e b e e n used

blockwise elongation.

In t w o lengthy g e n e syntheses,131

for 32

however, most of the sequences were assembled using standard protected dinucleotide synthons, employing MS-nt

ds

agent .

Bi s ( 2 ,4 , 6-trihalophenoxy 1 trich lorophosphoranes

tr i s ( L ,4 ,6 - t ri br omop he noxy ) d ic h 1 or op ho sphora ne

(

1 1L )

(

coup1 ing

11 1 )

and

have been

described a s n e w condensing agents for internucleotidic bond formation in the phosphotriester approach.

Reaction of the

protected 2 -deoxynucleoside 3 -(S-phenyl) phosphorothioate (113) with these reagents appears, on3+ n.m.r. spectroscopic evidence, to afford the phosphorochloridate (114), which reacts with 3 nitro-lfL,4-triazole added as catalyst t o g i v e (115), which then reacts with the 5 -hydroxy group of a second nucleosidic component to complete the coupling. rapid and afford high yields. preferred

to

the

The reactions a r e reportedly very T h e dichlorophosphorane ( 1 1 2 ) is

trichlorophosphoranes

( 1 13 )

bec-ause t h e

phosphorochloridate by-products formed from the latter reagents compete t o phosphorylate the 5 -hydroxy group. (mesitylene-2-sulphony1oxy)benzotriazole

4,6-Dinitro-l-

(116), l-(mesitylene-2-

sulphonyloxy)-4-nitro-6-trifluoromethylbenzotriazole

( 1 1 7 ) and 1 -

(mesitylene-L-sulphonyl)-4-nitro-lf2,3-triazole, a n isomer o t M S -

nt, have also been found to be highly effective condenslng agents in oligonucleotide yynthesis by the phosphotriester method, being

220 more

Organophosphorus Chemistry reactive than MS-nt, currently the most widely-used

reagent.'j5

Both (1161, which w a s particularly reactive, and

(117) are also powerful sulphonatinq agents, but failed to effect

significant 5'-sulphonation of t h e 5'-hydroxy component in the reaction i n the short time that was required for near-quantitative coupling to occur.

Using reagents ( 1 1 2 ) or (116), it is possibl(:

that the speed of 'phosphotric'st-er synthesis will approach that

of phosphite triester synthesis.

In a new variant of the latter,

nucleoside 3 '-(benzotriazolyloxy)(methoxy)phosphines have been employed a s monomer units for synthesis, giving rapid reactions with high coupling yields in the presence of basic catalysts.136 The u s e o f o x y g e n - n u c l e o p h i l i c c a t a l y s t s , s u c h a s

4-

substituted d e r i v a t i v e s of p y r i d i n e - a n d quinoline-!-oxide, substantially increases the rate of phosphotriester bond formation in coupling reactions using MS-cl, MS-nt, or TPS-cl as condensiny agents, and also in the hydroxybenzotriazole approach.13'

This

observation has been exploited further by developing phosphateprotecting groups carrying catalytic functions, and ( 1 1 8 ) and (119) have been protocols.13*

synthesized for this purpose using

standard

Both condense very rapidly with 5'-hydroxy-bearing

nucleosidic species in t h e presence of arylsulphonyl chloride o r arylsulphonyl-3-nitro-1,2,4-triazole,

the highest rate of reaction

being observed w it h t h e 1 -ox ido-4 - a 1 koxy- 2 -p ico 1 y 1 derivatives. An intermediate of type (120) is thought to be involved.

The use

of these groups is claimed t o minimise t h e quantity o f 5'-0sulphonated by-products formed.

W h e n deblocking t h e products,

the groups are removed using piperidine or thiophenolate. The synthesis and utilization of nucleoside phosphorothioates

in

reviewed.' 3 9 group

has

the

synthesis

of

oligonucleotides

has

been

The 3 - ( imidazol- 1 -y lmethy 1 ) - 4 ,4"-dimethoxytrit y 1

been

introduced a s a

5*-OH-protecting group

catalytically active in effecting internucleotidic bond formation in the phosphorothioester approach.14'

The protected nucleoside

(121) reacts unusually rapidly with g,g-diphenylphosphorodithioate

6: Nucleotides and Nucleic Acids

22 1

o'cH29 R

(118) R = H (119) R = A l k o x y

(120)

OMe

OMe

*B

1

5)R

Et

6)R':Bu'

SR1

.

I

Prn , P r '

t

I

Bu ; R2=Me

; R2=CH,CH2CN

-

2 CI C6HL0 (127) R1z MMTrOCH2CH2; R 2 z Ph (128) R ' = TrOCH,CH, ; R Z z H

,

OCH2CH2CN

,OMe TrSCH2CHzO- P

RO-P,

N Pr' (129)

RO-

, OMe

H p\NPr'z (131) MMTr N(CH2I3 (1 34) R = McOOC(CHt)ll

(1301 R = DMTrOCH2CH,S02CH,CH, ( 132 1 R = CF, CONHCH,CH,

0

H II MMTrNCH2CH20 - P - O H

I

OC,H,CI (133)

-2

222

Organophosphorus Chemistr?> niesitylenedisulphonyl chloride t o give

i n a conden5ation iising pi obdbl y

(12L),

due

imidazolc= m o i e t y .

t o

ntighbouring-group

A f t e r i c m o v a l of

a c ; s i s t a n c e by

phosphinic a c i d , ( 1 2 3 ) condenses w i t h a 5 -OH-bearing i n t h e presence of

within

thirty

seconds.

studies.

The

coupled

product

y i e l d of

An i n t e r m e d i a t e of

( 1 2 4 ) h a s b e e n p r o p o s e d o n t h e b a s i s o f 3 1 P n.m.r.

phenylthio qroup,

nucl~oside

isodurenedi5ulphonyl c h l o r i d e and 2 equivalents

of d i i s o p r o p y l e t h y l a m i n e t o g i v c a n e a r - q u a n t i t a t i v e

coupled product

the

one thiophenyl group with

contains

an

the

type

spcctroscopic

internucl~otidic

a n d r e a c t i o n w i t h a l a r g e e x c e s s of b i s ( t r i h u t y 1

tin) oxide has been

found t o he a very e f f i c i e n t agent

dephenylthiolation

such compounds,

of

affording

the

for

tributyl-

stannyl p h o s p h a t e which i s decomposed by s u c c e s s i v e t r e a t m e n t s with

t r i m e t h y l s i l y l

c h l o r i d e

water

and

qive

t o

t h e

phosphodiester

In

t h e

synthesis, an

phosphorothioite

method

oligonucleotide

of

an appropriately protected nucleoside

is treated

with

(alkylthio)methoxychlorophosphine t o a f f o r d a p h o s p h o r o t h i o i t e

such a s (125).142

_04 , 3 - g - d i b e n z o y l - 2 lutidine, effects

T r e a t m e n t of

(125) with iodine together with

-deoxythymidine

i n d i c h l o r o m e t h a n e c o n t a i n 1 ng

arid s u b s e q u e n t a d d i t i o n o f

oxidative

coupling

and

a small

oxidation

amount of t h e

of

water,

resulting

phosphite t o a f f o r d t h e methyl p h o s p h o t r i e s t e r a s product.

If

s i l v e r acetate is used i n s t e a d of i o d i n e , t h e d i n u c l e o s i d y l methyl phosphite

is

formed,

aqueous i o d i n e .

requiring

a

further oxidation

step with

The method is r e a d i l y a d a p t e d t o s o l l d - p h a s e

s y n t h e s i s , a n d ( t - b u t y 1t h i o ) ( 2 - c y a n o e t h o x y ) c h l o r o p h o s p h i n e been

used t o prepare

phosphorothloites

such as

has

( 1 2 6 ) for t h l s

purpose.

The

g-met h o x y t r i t y l o x y e t h y 1a n i 1 i n o l 4 4

groups h a v e b e e n u s e d a s p r o t e c t i n g phosphates

introduced

nucleotide

synthesis

at on

the

final

a polymer

a n d t r it y loxyamino' 45

groups

for

5'-terminal

of

oligodeoxyribo-

support.

Conventional

stage

condensation methods w e r e used t o p r e p a r e t h e phosphoramidates

6: Nucleorides and Nucleic Acids

223

(127) and (128), which were then debenzoylated, converted to their 3'-(2-chlorophenyl)phosphate

derivatives, and

terminal elongation stage of a conventional

used

in t h e

directed

3'-+5'

phosphotriester o l i g o n u c l e o t i d e s y n t h e s i s o n a p o l y s t y r e n e support.

After unblocking the internucleot idic phosphates and

release from t h e polymer , the lipophilic phosphoramidate moiety facilitated

separation

chromatography.

of

the

products

by

reverse-phase

Both protecting groups were subsequently easily

removed w i t h acetic acid.

T h e use o f ( 1 2 8 ) w a s preferred, since

the s t e r i c bulk of t h e a m i d a t e m o i e t y i n ( 1 2 7 ) s u p p r e s s e d dearylation at t h e phosphorus atom by 0 ~ i m a t e . l ~ T ~ h e 2-(2pyridyllethyl

group has also been introduced as a new protecting

group for internucleotidic phosphate.146

It i s stable t o weak

alkali, acetic acid, and oximates, and may b e removed at t.he conclusion of oligonucleotide synthesis by treatment with methyl iodide in acetonitrile, which forms the N-methylpyridinium species and p e r m i t s r e a d y B - e l i m i n a t i o n .

It i s c l a i m e d t h a t n o

alkylation

this

of

bases

allyloxycarbonyl

occurs during

group

has

been

used

procedure.

to

protect

The sugar

hydroxy functions, and a l s o a m i n o and imide functions of bases, while

the

allyl

group,

introduced

has

allyloxydichlorophosphine,

been

via

used

to

the

use

protect

of the

internucleotidic l i n k i n a ' p h o s p h i t e ' s y n t h e s i s o f a n a l l y l dinucleosidyl phosphotriester.147

The allyl and allyloxycarbonyl

groups are removed using t e t r a k i s ( t r i p h e n y l p h o s p h i n e ] p a l l a d i u m in the presence of butylamine and acetic acid. methoxy-4-phenoxybenzoyl

T h e uses o f

3-

g r o u p s 1 4 8 a n d 4 , 4 ',4"-tris(benzyloxy)

trityl groups149 t o protect the a m i n o functions of nucleic acid bases during oligonucleotide synthesis have been described. more t h o r o u g h s u r v e y o f

base protecting g r o u p s useful

A

in

oligonucleotide synthesis proposed that the phenoxyacetyl group be used for protection of adenine and guanine a m i n o groups, and isobutyryl for the amino group of cytosine, the

recommendations

being based on the efficiency of introduction of these groups and their half-lives under deprotection conditions.150

T h e groups

were u s e d , s u c c e s s € u l l y in phosphotriester and phosphoramidite

224

Organophosphorus Chemistry

solid phase oligonucleotide syntheses, and a t the conclusion of synthesis a single treatment with a m m o n i a sufficed to deprotect the bases, remove the oligomer from t h e support, and r e m o v e t h e

chlorophenyl o r c y a n o e t h y l p h o s p h a t e - p r o t e c t i n g g r 0 ~ p s . l ~ ~ Various strategies have been considered in order t o prevent guanine modification and consequent chain cleavage during the solid phase synthesis o f oligonucleotides using phosphoramidite derivatives.152

Phosphitylation o f t h e g u a n i n e base a t an

unprotected 06-position may

result in chain cleavage

if

the

phosphitylation is not eliminated before the nucleotide is exposed to water during oxidation with aqueous iodine.

While blocking

the 06-position with t h e cyanoethyl or 4-nitrophenylethyl group affords a n effective

if

laborious solution, t h e b e s t way may be to

follow the coupling stage with a

capping step using acetic

anhydride and 4-dimethylaminopyridine prior to the oxidation step. The capping reagent acts a s a source o f acetate and removes

06-

phosphitylation to regenerate the guanine base. 2-(?-Trityl) m e r c a p t o e t h o x y m e t h o x y m o r p h o l i n o p h o s p h i n e

(

129)

has been used to introduce a 5’-phosphate group at the terminus of an oligonucleotide synthesised by the solid phase phosphoramidite method.153

After

(129) has been used in t h e final stage of

addition in place of a nlicleosidyl

3’-phosphoramidite, followed

by capping, the oligonucleotide is oxidised, cleaved from the CPG phase,

and all

protecting

mercaptoethyl) group removed.

groups

but

the

5’-(2-trityl-2-

After purification by reverse-

phase h.p.l.c., oxidation w i t h silver nitrate o r aqueous iodine removes t h e b l o c k i n g

g r o u p t o leave t h e 5’-phosphorylated

oligonucleotide. ( 2 - C y a n o e t h o x y )- 2 - ( 2 ‘ - 2 - d i m e t h o x y t ri ty l o x y ethylsulphonyl) e t h o x y - N , N - d i i s o p r o p y l a m i n o p h o s p h i n e

( 1 3 0 ) has

been used for the s a m e p ~ r p 0 s e . l ~ ~ After addition at t h e 5 ’ -

terminus, capping and oxidation, release of the dimethoxytrityl cation with dichloroacetic acid permits the efficiency of the 5 ’phosphorylation t o be assessed, and t h e residue of the blocking group is subsequently removed by 6 -elimination using hydroxide.

sodium

Analogously, primary a m i n o groups linked t o a 5‘-

6: Nucleotides and Nucleic Acids

225

phosphorylated oligodeoxyribonucleotide have been introduced using

3-(tj-monomethoxytrityl) a m i n o p r o p o x y m e t h o x y d i i s o p r o p y l a m i n o -

p h ~ s p h i n e l (~ 1~3 1 ) or 2-(Ij-trifluoroacetyl )aminoethoxy(2cyanoethoxy)di isopropy laminophosphine ( 132).l 56

After unblocking

the a m i n o groups a t the completion of synthesis using standard methods, they were used a s attachment points for reporter groups such

as

dansyl

chloride156 or

biotin.155i156

For

the

affinity

ligands

attachment

of

a

such

as

5‘-(2-

aminoethy1)phosphcryl terminus to an oligonucleotide as the final stage o f a solid phase phosphotriester synthesis, the reagent (133) h a s

been

used.157

In

an

alternative

approach

to

introduction of a 5,-aminoalkyl terminus, the 5’-detritylated oligonucleotide still bearing phosphate- and base-protection and attached t o t h e s o l i d p h a s e carbonyldiimidazole

is t r e a t e d

successively with

and hexane-lI6-diamine t o introduce a

aminohexylcarbamoyl group.158

The carbamate

6-

1 ink reportedly

withstands the normal deprotection sequence, and the process is efficient.

In order to immobilize DNA &v

terminus , m et h y 1

attachment at the 5 ’ -

1 2 - ( m e t hoxy -Ej ,Ij-di 1 sopr opy 1 a m i nophosphino y 1 )

dodecanoate(l34) has been used in the s a m e way a s reagents (129)( 1 3 2 ) to attach a n alkanoate moiety a t t h e 5’-terminus of an

o1igonucleotide.l5’

After deprotection and hydrolysis t o g i v e

the carboxylic acid (1351, condensation with the aminc group of 3aminopropane-1 ,2-diol using a water-soluble carbodiimide fol lowed by oxidation with periodate afforded (136).

Both (135) and (136)

were conjugated with biotinyl hydrazide using standard methods, and also attached to latex microspheres impregnated with Nile Red for flucrimetric detection

and derivatized to bear hydrazide

groups on the surface, using standard condensation methods.

The

immobilised oligonucleotides were then used as templates for the attachment o f

a 98-mer using T4 polynucleotide ligase and an

oligonucleotide splint. complementary D N A

T h e immobilized D N A hybridized with

in solution a t r a t e s c o m p a r a b l e t o those

observed for homogeneous hybridization reactions. 160 Protected o l i g o d e o x y r i b o n u c l e o t i d e b l o c k s b e a r i n g 3

’-

226

Organophosphorus Chemistry

terminal

phosphate

condensations

groups

have

been

suitable

made

by

for

block

subsequent

preparing

substituted

a

p h o s p h o r o a n i l i d a t e t y p e ( 13 7 ) w h i c h becomes i m m o b i l i z e d a s ( 1 3 8 ) on

treatment

with

conventional

aminomethylated

polystyrene.161

phosphotriester synthesis,

Fol lowing

a

t h e complete protected

oligonucleotide block is removed from t h e s u p p o r t u s i n g isoamyl nitrite.

I n t h e capping steps, acetic a n h y d r i d e was used w i t h

p y r i d i n e r a t h e > r t h a n DMAP, s i n c e u s e o f t h e l a t t e r b a s e a c e t y l a t e d the

phosphoramidate

nucleotides bearing

and

cleaved

3’-phosphate

the

1i n k .

01 i g o d e o x y r i b o -

t e r m i n u s have a l s o been prepared

by s y n t h e s i s i n g o l i y o m e r s b e a r i n g a s i n g l e 3 ’ - t e r m i n a l chemical

or

enzymic

methods,

followed

by

u r i d i n e by

oxidation

of

the

r i b o n u c l e o s i d e r e s i d u e w i t h p e r i o d a t e a n d b a s i c H - e l i m i n a t i o n of A n u m b e r of

t h e o l i g o n u c l e o t i d e - 3 ‘-phosphate.162 benzotriazole-activated been

prepared

and

phosphorylating reagents

tested

s y n t h e s i s of

s h o r t RNA

modification

at

While

the

compounds

acetyluridine i n

for

their

fragments,

lactam

efficacy

l-hydroxy-

139-1 4 0 ) have

in

the

solution

and t h e i r tendency t o cause

function

of

uridine

(139) caused

modification

the

of

presence

(

base,

of

they

residues.163

2’,3‘,5’-tri-9phosphorylated

n u c l e o s i d i c s u g a r h y d r o x y g r o u p s s o much f a s t e r t.han n o r e a c t i o n

a t t h e lactam f u n c t i o n was o b s e r v a b l e i n t h e t i m e d u r i n g which p h o s p h o r y l a t i o n o f t h e s u g a r w a s c o m p l e t e , a n d a n y e x c e s s of

was e a s i l y

mopped

up

by

addition

nucleosidic

component

to

be

of

coupled

excess i n

of

second

t-he p r e s e n c e o f g -

methylimidazole d u r i n g t h e second c o u p l i n g s t a g e . that

t h e

(139)

I t was found

(139;R=CF3) r e a c t e d f a s t e r t h a n (139;R=H), o b v i a t i n g t h e n e e d

for N-methylimidazole previously,25

during

t h e u s e of

t h e second

stage.

As

reported

t h e s e compounds had been c a l l e d i n t o

question on a c c o u n t o f t h e i r a b i l i t y t o react w i t h b a s e l a c t a m functions. using

the

similarity

0 1i g o r i b o n u c l e o t i d e

phosphoramidite

s y n t h e s e s o n pol y m e r i c s u p p o r t s

approach

have

shown

considerable

t o t h e p r o c e d u r e s u s e d i n oligodeoxyribonucleotide

s y n t h e s i s , b u t w i t h t h e 2 , - h y d r o x y f u n c t i o n p r o t e c t e d v a r i o u s l y by tetrahydropyranyl groups.

,

2-nit robenzyl

65 and tetrahydrofurany1166

I n t h e l a s t c a s e , t h e u s e of

5-(4-nitrophenyl)tetrazole

6: Nucleotides and Nuc-leic Acids

227

0 R-C(

II

CH ) 0

0

l2

II

- PI

OHCCHzNH

1 0 -

0

- -

DMT

O C H ,COR

OC,H,CI

-2

(137) R = OCH,CCI R = NHCH2- Polystyrene "6 LOTht

q

T-7 N

DMTrO

O

H

I

Pr I2N- P - OCH, CH2CN (1L3)

0

0 Me O = P - S C H 2 C H 2 0 ! N e t - E t

I

I

(139) X = 0 ; R =H ,CF,,NO, (1LO) X = S ; R z C F , , N O 2

N\N

*

H

R

R

( 138)

-0

- 5')

-0 (135)R:OH (136) R

*B

0 -(Oligonucleotide

Et

T7 N

-I

228

Organophosphorus Chemistry

in place> of tetraLole significantly decreased the t i m e requlred for coupling.

In solid phase synthesis of oligoarabinonucleotides

by the phosphoramidite approach, t h e 2 -hydroxy f unction was protected by t h e a c e t y l g r o u p in a n o t h e r w i s ~c o n v e n t i o n a l procedure.167

In solution synthesis of oligoribonuclcotides by

the p h o s p h o t r i e s t e r a p p r o a c h , 4 - m e t h o x y b e n z y l 1 6 * a n d

3,4-

d i m e t h o ~ y b e n z y l 'groups ~~ have been used t o block the 2 -hydroxy functions, t h e f o r m e r b c i n q r e m o v e d , a t t h e c o n c l u s i o n of synthesis, using trityl fluoroborate, and the latter

sing

1100.

The 4,4 , 4 " - t r i s ( 4 , 5 - d i c h l o r o p h t h a l i m i d o ) t r i t y l group has been

utilized as a new 5 -hydroxy-protc>cting group in the synthesis of oligoribonucleotides bearing

3 - or

5 -terminal

phosphates.' 7"

It i s removed using hydrazine, or by successive treatments with

ammonia and dilute mineral acid. oligoribonucleotides

has

A

u sed

new solid-phase synthesis of ba se - protected

2 -

0-

tetrahydrofuranyl-3 - ~ - ( 2 - c h l o r o p h e n y l ) p h o s p h o r o - 4 - a n i s i d a t eunits to extend in the 3'-direction a nucleotide anchored by its 5 terminus to the support (141).171

Removal of the anisido moiety

from ( 1 4 1 ) with isoamylnitrite affords a phosphate oxygen for coupling t o the next monomer unit using MS-nt.

This approach

avoids the use o f zinc bromide for detritylation a s in syntheses in the 5 -direction, but the cleavage of the p-anisidate is slow.

Recent developments in automated synthesizing systems for nucleic acids have been reviewed.' 72 Oligomers containing o n 1 y

a-2 -deoxyr ibonuc leot ides have

been prepared using a solution phosphotriester method in which phosphate was protected by the lipophilic 2-chloro-4-tritylphenyl group

and

the

guanine

base

dipheny 1 carbamoy 1 der ivat i ve

as

its

2-N-palmitoyl-6-9-

The a - 0 1 igor ibonuc leot ides were

more resistant t o nuclease S 1 and calf spleen and snake venom phosphodiesterases t h a n t h e u s u a l B - 0 1 i g o r i b o n u c l e o t i d e s identical sequence.

A

of

pentamer sequence containing only L-

ribonucleotides has been prepared by a phosphotriester approach

using 2 -chlorophenyl - 0 , O -bi s ( 1 - b e n z o t r i a z o 1 y 1 p h o s p h a t e .

6: Nudeorides arid Nuclric Acids

229 2 -i ,3 -i

l ’ h r e e f u r t h r r s y n t h e s e s of

s t r u c t u r e s s i m i l a r t o thosc, found a t

RNA

becLn

have

tiPscrihed.

first, a n d t h e 2 - 5 - l i n k a1 t h o u g h

approach,

cas,.175t176

In

two,

using

splice sit€, i n

the

3 -5 -link

lari<3t formtJd

is

then constructed using a phosphoramiditc,

t h e

procedurcs

In t h e t h i r d method,

concomitantly

linked t r ~ r i ~ ~ o n l ~ c l ~ ~ o t l d € , ~ , t h e

vary

both

somewhat

in

each

links a r e construct<,d

2 , 3 - g , ~ - i s o ~ ) r o p y l i d e n e a d e n o s i n t5.

- ( O -

a 1l y 1 ) p h o s p h o r o c h l o r i d i t e . 01 i g o d eo x y r i b o n u c 1 eo t i d e s

con t a in

i

ng

5 - m et h y 1

a

-

rj ,

r\l

-

( 1 4 3)

ethanocytosine b a s e ( 142) have been p r e p a r e d by p r e p a r i n g

( b y t r e a t m e n t of t h e c o r r e s p o n d i n g 2 - d e o x y t h y m i d i n e c o m p o u n d w i t h phosphoryl c h l o r i d e and t r i a z o l e ) , r e s i d u e i n a 21-mer

incorporating it a s t h e c e n t r e

p r e p a r e d by t h e p h o s p h o r a m i d i t e a p p r o a c h ,

and

t h e n d i s p l a c i n g t r i a z o l e w i t h e t h y l e n e i m i n e prior t o d e p r o t e c t i o n Upon h y b r i d i z a t i o n t o o l i g o d e o x y r i b o n u c l e o t i d e s of

with base.178

complementary s e q u e n c e b u t w i t h d i f f e r e n t b a s e s o p p o s i t e ( 1 4 2 ) , cross-linking cytosine. diminished

by

p o s i t i o n of

mer

of

occurred,

the

by

but

not

exclusively

cross-linking

was

mismatched

bases

of

(142) i n t h e sequence.

I n a similar

around

exercise,

f o l l o w e d b y o x i d a t i o n of

t h e

21-mer

a L1-

c o n t a i n i n g

tendency t o c r o s s - l i n k

a

6 -

method,

t h e m e t h y l t h i o m o i e t y w i t h MCPBA a n d

ethyleneimine.17’

Upon

otherwise complementary oligonucleotides,

lower t h a n t h a t o f

the

(144) r e s i d u e a t t h e seventh p o s i t i o n has been

r i b o s i d e r e s i d u e by t h e Ij-phosphonate

with

to

slgnificantly

a c i d i n t e r r u p t e d b y t h e p r e s e n c e of a n

s y n t h e s i z i n g

methylthiopurine

displacement

of

presence

L -deoxythymidylic

N, 6c6-ethanoadenine

prepared

p r e d o m i n a n t 1y

The e f f i c i e n c y

hybridization

with

(144) showed a s p e c i f i c

to cytosine, although its reactivity was

(142).

Once a g a i n , many s y n t h e s e s o f o l i g o n u c l e o t i d e s c o n t a i n i n g u n u s u a l or m o d i f i e d r e s i d u e s h a v e b e e n d e s c r i b e d .

These have

i n c l u d e d 5 - m e t h y l d e o x y c y t idine180-184,deoxyinosine1 8 0 , 1 8 2 ,

84,186,

d e o x y u r l d l n e l 8 0 1 8 4 , z 6 - m e t h y l d e o x y a d e n o s i n e l 82-1 8 4 , 2 - a r n i n o d e o x y a d e n o s i n e ’ 82 1 8 4 , 2 - a m 1 n o p u r

i

n e d e o x y r ibos i d e 1 8 4 ,

5-f 1u o r o -

230

Organophosphorus Chemisrrv *6

0

0 (148)

-0 (1C9) (150) (151 1 (153 ) (154

-0

-0

R'=H ; R2=N3; 8'=C u a ; B z = C y t R'= PO,H, ; RZ=NH2; B ' = G u a ; B 2 = C y t R'= P03H, ; R2=NH,; B ' = C y t ; B 2 = G u a R'x H; Rz=NH, ; 6'=G u a ; 62=C y t R'= PO,H,; R'zN,; 6': G u a ; B 2 s C y t Cvt

Cvt

Gua

-0

-0

-0

1152)

-0

( 1 53 1

Gu a

Gua

'0

1 CHZ

Ho

OH

HO

(155)

0

0

I

I -0

H 11 II HSC?CH2N -P-O-P-O-(Ado-5')

-0

(158)

(156) n = 2 (157) n = 1

OH

1 c=o 1 c=o 1

CH, &

6: Nudeotides and Nudeic Acids

23 1

deoxyuridine,’81 5 - b r o m o - d e o x y u r i d i n e a n d - d e o x y c y t i d i n e , ’ 84 5 iododeoxyuridine , 18’

inosine,

dea z an c b u 1 a r i n c

tu b e r ci d i n ,

a nd

7 - d e a I ai n o s i n e ,

tubericidin’911 droxyxanthosine,’90 N’-methyldeoxyguanosine

’d

nebu 1a r 1 ne,

e ox y n e b u 1 a r i n e ,

7-

d eo x y -

N4-rnethyldeoxycytidi n e , l a 3 ,

and 3-deazadeoxyadenosine,185 pyrid- L-oncl-

deoxyr ibos ide, py r i mid-2 -one devxyr 1 bos i d e and 4-am i nopyr id -2 -one

deox y r i bos id c ,

’

8- h y d r o x y d e o x y q u a no s i n e ,

thymidine,1y4 g 6 - , l k y l d e o x y g u a n o s i n e

0

- me t h y 1 d e ox y -

species,195, dnd

a n d l I 4 - a n h y d r o - 2 - d e o x y - g - r i b i t o l, a s

propanediol

1,I-

no-base

For the most part, the synthesis involved s o l id-

residues).lg6

phase p h o s p h o t r i e s t e r o r p h o s p h o r a m i d i t e m e t h o d s .

The 2-amino

functions of 2-arninodeoxyadenosine and 2-aminopurine deoxyriboside were b l o c k e d by i s o b u t y r y l g r o u p s , a n d

O6

protected by a 4 -nit ropheny 1ethy 1 group.

of d e o x y x a n t h o 5 i n e w a s

8-Hydroxydeoxyg ua nos i ne

was introduced a s its 8-methoxy derivative, and subsequently unblocked w i t h triethylamine.

Particular c a r e needed t o be taken

with 4-C)-methyl deoxythymidine dnd 6-9-alkyldeoxyguanosine species due t o their instability.

T h c oligonucleotides w e r e variously

investigated, i n the, m a i n , for t h e e f f e c t s of t h e

odd

bases o n

the ability of restriction endonucleases t o cleave a t their target sequences, o n t h e s t a b i l i t y of o l i g o n u c l e o t i d e d u p l e x e s , a n d o n the polymerase-catalyzed synthesis of a complementary strand. 0 1 igodeoxy r i bonucl eo t ide s c o n t a 1n 1 ng 5 - 5- p h o sph o r ot h i o a t e links

have

been

prepared

by

treating

base-protected

deoxynucleoside 3 - t h i o p h o s p h a t e s w i t h a ~ w i t t e r i o n i c 5 - i o d o 2 ,5 -dideoxynucleoside derivative (145) i n DMF.

T h e presence of

the zwitterionic moiety i n (145) enhances considerably the rate, of reaction

of

the

position.19’ phosphoramidate hybridising

incoming

sulphur

nucleophile

at

the

5 -

0ligodeoxyribonucleotides containing a 3 -5 -

or

pyrophosphate

link

have been

(sdy) a n oligonucleotide possessing

formed

by

a 3 -terminal

phosphate g r o u p a n d a n o t h e r c o n t a i n i n g a 5 ’ - t e r m i n a l a m i n o o r phosphate group t o a complementary oligonucleotide, the sequences being chosen so that t h e t w o termini lie adjacent.”’ ligation

w i t h EDC t h e n s e a l s t h e

Chemical

nick’ t o form the modified

232

Organophosphorus Chemistry

internucleotidic link.

Diastereoisomerically pure ( K

?

)

and ( S

P

)

d(GGsAATTCC), c o n t a i n i n g a s i n y l e p h o s p h o r o t h i o a t e 1 ink a t t h e posltion indicated, have been prepared by a sol id-phase procedure using u n i t s o f t y p e ( 1 0 4 ) a n d a s i n g l e e t h y l p h o s p h o r a m l d i t e oi type (1461, which, following addition, w a s oxidised with sulphur t o form the phosphorothioate unit.lY9

The racemlc assembled

oligorner w a s c l e a v e d f r o m t h e s u p p o r t , t h e t r i t y l , b a s e , a n d cyanoethyl groups removed, and the crude g-ethyl phosphorothioate products s e p a r a t e d a n d pllrified b y h.p.1.c. b e f o r e r e m o v a l o f t h e ethyl g r o u p w i t h a m m o n i a . complementary

Spectroscopic studies of the self-

octamers suggested that the

(! ) conf iguration P caused the greatest structural perturbation in comparison with the

unmodified p a r e n t d u p l e x .

Several oliqodeoxyribonucleot~dcs

containing a single ethylated interndcleotide phosphatc, have been prepared, e i t h e r a s d e s c r i b e d a b o v e u s i n g (146)(but w i t h o u t t h e thiation step) in a procedure with separated the diastereoisomers of d[GGAA(Et)TTCC]’”

o r by

nucleotidic 2 - c h l o r o p h e n y l

transesterification of a n inter-

blocking

g r o u p using

ethanol ( f o r d [ T ( E t ) T ] a n d d [ p T ( E t ) T ] ) phos phot r i e s tt‘r a p p r o a c h

(

for

absolute c o n f i g u r a t i o n of ( R assigned e i t h e r by

-P

)

or

d [ ‘1’TT ( E t ) T C T A T TT ]

and

( S

-P

fluoride and

by a s o l u t i o n - p h a s e

.

)

‘r h e

)-d[GGAA(Et)TTCC] c o u l d b e

i d e n t i f i c a t i o n of

the nuclease digestion

products with samples of k n o w n absolute configuration generated by stereospec i f i c

ox i d a t 1 o n

of

the

c o r r e s P O nd i n g

9- e t h y 1 a t e d

p h o s p h o r o t h i o a t e ~ , ~ ~o’r b y u s i n g a t w o - d i m e n s i o n a 1 n u r l e a r Overhauser e f f e c t i n t h e (Kp)-(R

-P

)

nor

the

’H

n.m.r.

spectrum.202

(Sp)-(Sp) duplexes

could

Npither be

cleaved

the by

restriction endonuclease e R 1 , although the unmodified duplex w a s cleaved readily.”’

While d[T(Et)T] w a s not phosphorylated by T 4

polynucleotide k i n a s e , t h e e t h y l a t e d decarner w a s p h o s p h o r y l a t e d readily, showing that the e n z y m e requires t o recognize a negative charge o n t h e

3‘-phosphate of the residue which

phosphorylate. 201

i t 1s t o

It also demonstrates that postlabelling assays

of DNA d a m a g e employing polynucleotide kinase cannot b e applied t o dinucleoside produced a

a 1 k y 1 p h o s p h o t r i e s t e r s.

The ethylat ed d e c a m e r

high frequency of strand breaks o n exposure t o alkali,

6: Nucleotides and Nucleic Acids

233

and could also act as a primer for DNA synthcsis when annealed t o a single-5trandrd plasmid template, affording a method for s l t r 3 specific incorporation of phosphoti iesterc, into v l r a l vrac-tor5. Solid-phase s y n t h e s e s of

o l i g o d e o x y r i b o n u c l c o ~ i d ~mc~thyl-

phosphonatcs hacc been performed u 5 i n y (147),

monomer unlts of t y p e

p r e p a r e d by t r e a t l n q t h e p r o t e c t e d

methylphosphonic

b

1

( i

m

1da

zo t i d e 1 .

’

n u c l e o s i d e with

The

conde nsa t i on

reactions, which were cdtdly/ed b y tetrazole, were appreciably more

efficient

on a polystyrene support than on C P G .

conventionally immobilized 3 -terminus w a s employed.

R

5incjlc

A

phosphodiester link w a s introduced at the 5 -end of the sequences synthesized, condensation,

us 1ng

p h o s p h o t r i c’s t e r

since

after deprotection

or

the

phosphor dm resulting

id 1

te

sinqly

charged oligomers are conveniently purified on DEAE-cellulose, and additionally cannot otherwise be polynucleotide

kinase,

01 igodeoxyribonucl eoside

for

5 -phosphorylated by

reasons

described

the ‘r4 dbovc.

m e t h y 1 ph o s ph o n a t e s c o m p 1 e ment a ry to

sequences including the initiation codons of certain genes encoded by vesicular stomatitis virus ( V S V ) have been found to inhibit specif ical ly the corresponding v i ra 1 proteins in VSV-inf ected cells in a concentration-dependent manner, without affecting cellular protein synthesis in non-infected cells.L04

They may

therefore be useful for studying the expression of viral genes and controlling virus production.

Normal phosphate-containing oligo-

deoxyr ibonuc leot ides c o m p 1 ementar y t o the

1 n 1 t iat i on

r ey ion of a

VSV protein have been ligated t o p C p at their 3 -termini, which were then dephosphorylated, oxidised with periodate, and condensed with poly( L-lysine), using sodium cyanoborohydride to render the covalent binding ~ r r e v e r s i b l e . ~ ’ ~The resulting ol igonuc leot idepoly(L-lysine) conjugates strongly inhibited the synthesis of viral proteins in infected cells and showed strong specific antiviral activity against VSV at low concentrations in the cell culture medium.

Oligodeoxyribonucleotides complementary t o a

primer binding site o n H I V R N A , o r to certaln splice sites in the m R N A sequence of H I V , have been found capable of inhibiting the

replication and expression of the virus in cultured cells. 2 0 6

234

Organophosphorus Chemistry Methods

ot .2-

f o r t h e chemical207 and enzymic208 synthc.sis

5 A ’ ( p p p A ( 2 ‘ ) p R ( L’ ) P A )

have b e e n

kpy prnt.oc:ol

reviewed and

:i

P h o s p h o t r i e s t e i - m e t h o d s h a v e b e e n u s e d t o [>repart.

described.

’core t r i m t r ’ ( A ( L ) p A ( 2 ) [ ) A ) a n d including

t h o s e

dcoxyadenosine’l’

of

various

8-bromo-,

w i t h

residues a t t h e 3’-terminus.

pA(L’)pA(Z‘)pA v a r i o l u s l y

its

dnalocju~s,

8-hydr0xy-,~’’

s u b s t i t u t e d

and

3‘-

Usiny analoqucs of

3 ‘-deoxyadenosinc

w i t h

r e s i d u e s i n p l a c e of a d e n o s i n e , i t h a s b e e n s h o w n t h a t . i n o r d e r t o be d e g r a d e d by t h e c y t o p l a s m i c 2 - p h o s p h o d i e s t e r a s e a c t i v i t y i n a n analogue must have a f r e e 3’-hydroxy

m o u s e 1, c e l l s , the

penultimate

residue,L11 and

s u b s t i t u t e d w i t h =&-adenosine

using

analogues

i t was shown t h a t

group must be i n t h e &o-confiyuration.2i2 s y n t h e s i s of

2-5A

group in

variously

3 ‘-hyciroxy

this

on

the,

s t a r t s by c o n d e n s i n g ApA w i t h t u b , e r c i d i n

A new v a r i a n t

(7-

d c a z a a d e n o s i n e , c7A)-5’-phos$horimidazol i d a t e i n t h c [ j r e s u n c e of Pb2+

ions,

nuclease

yiving

ApA(2 ‘ ) I ) ( C ~ A ) . ~ ’

t o q i v e pA(2 )p(c’A), which

P1

and so on.

condensation,

reportedJ5 previously

I[

is

This

diyest-etl

is used

i n

This procedure[toyether

t h t , n<.xt

with dnothpr

was u s e d t o make a n a l o g u e s o f

2-5A s i n g l y

or d o u b l y

substituted

a b i l i t y of

t h e substituted analogues t o bind to ribonuclease

mouse

c e l 1 s

L

w a s

by

tubercidin

r e l a t i v e l y

residues.213

unimpaired,

with

While

thc L of

s u b s t i t u t i o n

of

t u b e r c i d i n for a d e n o s i n e a t a n y r e s i d u e b u t t h e s e c o n d d r a s t i c a l l y reduced

a b i l i t y to a c t i v a t e

the

R N a s e L.

A

related

analogue

p G ( 2 ) p ( c 7 A )( 2 ) p ( c ’ A ) s h o w c d s e v e r e l y d i m i n i s h e d a b i l i t y t o b i n d

t o RNase L.L14 adenosine,

I n a n a l o g u e s of

replacement

of

ppA(2 ) p A ( L )PA c o n t a i n i n g

adenosine by

8-bromo-

8-brornoadenosine

i n

p o s i t i o n s o n e or t w o d e c r e a s e d t h e a b i 1i t y of t h c a n a l o g u e t o b i n d

t o RNase Indeed, only

L,

while

replacement

t h e analogue with

i n

position

8-bromoadenosine

three

in the

did

third

w a s t e n t i m e s more e f f e c t i v e as a n i n h i b i t o r of

not.L15 position

tran5lation

t h a n 2 - 5 A itseli.

I t i s t h o u g h t t h a t c h a n g e s i n the’ b a s e - s u q a r

torsional

the

angle i n

8 - b r o m o a d e n o s i n e - s u b s t ~ t u t e dc o m p o u n d s

m o d u l a t e b i n d i n q t o RNase L , a n d i t s a c t i v a t i o n . p p p A ( 2 ) p A ( L )pA(:!’)p4 3 -terminal

‘I’he t e t r a m f ’ r

has been conjugated to poly(L-lysine) a f t e r

oxidation with periodate,

as described above,

and t h e

'35

6: Nucleotides and Nuclcic Acid.\ conjuqate infected

LILIO

not.L16

~ 1 1 c c

cell-frcc bt:

proved

t a f

ct.11

1

n

nliihitinq

I

g r r ~ w t h 1 n VSV-

viral

i ~ l t l ~ o l ~ q~ tui n c o n l l ~ g a t e 2d - S R wd:;

culturcs,

o n j u q a t r , was a c t . i v e

r a d i o b i n d i n g assay.

i n tiinding

,3F)Fi
It

in

t o ~ < N a s ( I' ,

,I

t h a t p o I y ( l , - l y s i n ( - . ) niciy

a g e n e r a l l y u s c ~ f u l v r h i c l e f o r - t h e d e l i v c r y of o l i q o n u c l e o t i d c s

t o i n t a c t cells.

is

fective

A f u r t h c t r p o s s i h l t , , + n t . i v i r a l a c t i v i t y (if 2 - 5 A

by

s u g g e s t e d

t h e

f i n d i n q

t r a n s c r i p t a s e s f r o m a nl.irnt)ttr o f B i s ( 3 '-5 ' ) c y c l i c d i g u a n y l synt-hesis i n Acetobacter

t h a t

which

acid,

I C

i t

i n h i b i t s

r
s o u r - c e s . '17

viral

r c g u l a t e s cel lulosc:

x y l i n u m b y a c t i v a t i n g c e l l u l o s c :;ynt.hds(:,

i s f o r m e d e n z y m i c a l l y f r o m G T P v i a pppGpG a s i n t . e r m e d i a t c . 2 1 R ~

T h e c h e m i c a l s y n t h e s i s w a s re[)ortt,tl l a s t y e a r . 2 5

3 ' - 5 . - 1 i n k c d c y c l i c trimc:r

nor t h e

could

replace

N e 1 t h c . r cGMP

t h e c y c l i c di1nc.r

a s a c t i v a t o r , a n d i t w i l l b e i n t e r e s t i n q t o s e e i f t h i s class o f nucleotides t u r n s o u t t o be widespread i n nature.

Non-enzymic been

has

t e m p l a t e - d i r c > c t . e d 01 i g o n u c l e o t i d e : s y n t h e s i s

s t u d i e d u s i n g d(C7-G-C7)

as a t . e i n p l a t e . 2 1 Y

Upon

incubation

L - m e t h y 1 ) i m i d a zo 1 i d a t e s ,

w i t h g u a n o s i n e - a n d cg t i d 1 n e - 5 ' - p h o s p h o r

(

o l i g o g u a n y l a t c s u p t o ( L ) G ) ~a r e f o r m e d ,

t o g e t h e r w i t h s e q u e n c e s of

f o r m u l a ( ~ G ) , C ' ( P S ) ~c, o n t a i n i n g u p t o t h i r t e e n g u a n y l a t e

general

W h e r e t h e s e c o n t a i n e d rnorc t h a n s e v e n g u a n y l a t e s ,

units.

were c o m p l c x t t . l y giving the that

d e g r a d e d a t t h e C/G

(~G)~@pw a se l l a s (pG),pCp as m a j o r p r o d u c t s ,

l i n k s formed a t t h c product

synthesis

junction does

t e r m i n u s of t h e t e m p l a t e . monomers that

were e x c l u s i v e l y

not

thc-.y

j u n c t i o n by p a n c r e a t i c HNasc,

necessarily

Similar

showing that

3'-5',

begin

studies i n

and a l s o

a t

which

the the

3'-

same'

were o l i g o m e r i s e d o n p o l y ( C , G ) r a n d o m c o p o l y m e r s s h o w e d

the e f f i c i e n c y

of

monomer

incorporation

i n t o

thc' n e w l y

s y n t h e s i z e d o l i y o m e r s w a s g r e a t e r f o r t h e g u a n y l a t e t h a n for t h e c y t i d y l a t e , b u t d e c r e a s e d f o r b o t h as t h e g u a n i n e c o n t e n t o f template

increased.220

The

formation i n t h e products

~ 4 1 2 )was h i g h . t h e Mg2+

The

reyiospecif i c i t y

i d e n t i f i e d ( m a i n l y Gn,

study

_

was

bedevilled by

of

3 '-5

'

the

1i n k a q e

G n - l C a n d Gn-2C2r -

t h e f a c t t h a t at

c o n c e n t r a t i o n r e q u i r e d for r e a c t i o n t o o c c u 1 - , t h e r e i s a n

0rganophosphoru.t Chemist?

236 increasing

t(.ndericy

t h e t e m 6 ) l a t r t o f o r m sc2l f - 5 t r i c t u l c

for

i n c r t ~ a s i n gg u a n i n e c o n t c ’ n t , [)rodlict% o f

15omerizdtion,

sell - s t r l i c t u r o

must

polynucleotititx

of

be

a l ~ t h o r sc o n c l u d i n g

the

ovc’rcome

self-replication

i f

I S

t r a n 5 1 t i o n

polymtlrisation in

aqueous

to occur

of

series) c y a n o g e n

o l i g o a d e n y l a t e s on a

5 0 l u t i o n . ~ ~ ’

that

.

Jn t h e presence d

metal

b r o m i d e

frorn the t h e

e f f e c t s

acid t e m p l a t e

polyuridylic

Probably

the,

tcmplatcx

non-eniymlc

e f f i c i e n t

i m i d d L o l t . a n d a d l v a l e n t m e t a l i o n (Mg2+ o r

first

wlth

and dl50 to form duplcxrs with

N-cyanoimldazole

or

N,N

irninodiimidarole, formed 1 : sitg, a r e the t r u e condensing agents, giving r i s e t o p h o s p h o r i m i d a z o l i d a t e s or species a s d e p i c t e d i n

(148).

PA)^ a s s u b s t r a t e , o l i g o m e r s u p

Using

PA)^^, w e r e

obtained,

t h e n a t u r e of

strongly dependent on t h e metal Ni”

the

m i x t u r e s of h i g h e s t

2 -5

p r o p o r t i o n

p r e d o m i n a n t l y 5 -5

3

pyrophosphatkx

3 -deoxyguanosine

3 -Amino azido-3

o f

-deoxy-CMP

phosphorylated

EDC

u s i n g

w i t h phosphoryl

-5

octamer,

w i t h Co2+, Z n 2 + a n d

ion used: l i n k s were

3 -5

and

to th?

t h e linkaqes furmed being

formed,

l i n k s ,

N i l +

w h i l e

affording

MnLt

yave

links.

has

t o

been

condensed

( 1 4 9 )

g i v e

chloride in triethyl

w i t h

3 -

w h i c h

w a s

phosphate

and

t h e n r e d u c e d w i t h t r i p h e n y l p h o s p h i n e a n d a m m o n i a t o g i v e pGNHpCNH 2 When t h e s e ( 1 5 0 ) .2 2 L S i m i l a r l y , p C N H p G N H 2 ( 1 51 ) w a s p r e p a r e d .

were

incubated

separately

with

EDC

a t

(150) afforded

pH7.5,

oligomers up t o f i f t e e n d i m e r u n i t s long, c o n t a i n i n g a l t e r n a t i n g 3 (N)-+5

(P) phosphoramidate l i n k s ,

i n high yield,

while (152)

g a v e a much lower y i e l d o f o l i g o m e r s u p t o s e v e n dimer u n i t s l o n g , but

a

much

h i g h e r

of

y i e l d

t h e

c y c l i s e d

d i n u c l e o s i d e

diphosphoramidate.

The d i f f e r e n c e is thought t o be r e l a t e d to

the

forms

fact

that

GpC

promoting o l i g o m e r i s a t i o n intramolecular

more of

stable

mini-helices

EDC-activated

than

CpG,

( 15 0 ) a s o p p o s e d t o

c y c l i s a t i o n i n a c t i v a t e d ( 15 1 ) .

The r e a c t i o n of

EDC w i t h t h e 3 ’ - a ~ , i n og r o u p s of ( 1 5 0 ) a n d ( 1 5 1 ) a l s o g a v e r i s e t o

Some 3 - q u a n i d i n i u m

adducts,

h a s a l s o been shown t h a t condensation

of

(153)

preventing

3 -terminal

ligation.

It

( 1 5 2 ) a c t s a s a template t o c a t a l y s e t h e and

(154),

using

EDC

under

slmilar

6: Nucleotides and Nucleic Acids

237

conditions t o t h e previous study.2L3

Since t h e reaction product

i s i d e n t i c a l t o t h e t e m p l a t e - i.e. - it d i r e c t s i t s own s y n t h e s i s is an autocatalytic reaction,

this

support t h i s interpretation:

catalytic reaction.

I n another example,

kinetics

3 -3'-pyrophosphate being

(153) w a s activated with

t o g i v e t h e 3 -5 - j o i n e d h e x a m e r a n d

EDC a n d c o n d e n s e d w i t h ( 1 5 4 1 ,

these products

the reaction

it can a l s o continue t o p a r t i c l p a t e i n t h e auto-

a s t a b l e duplex,

the

and

although t h e template (152) can form

formed

from

(153), the

proportions

t e r n p e r a t ~ r e - d e p e n d e n t . ~ ~ S~ i n c e

(154) are complementary,

blunt-end

(

of

153) and

ligation of t h e duplexes to

g i v e t h e 3 - 5 - l i n k e d h e x a m e r i s f a v o u r e d a t lower t e m p e r a t u r e s , but a t higher temperatures dissociation of pyrophosphate formation.

is added

at

present i n

the

start

the duplex favours

I f , however, t h e 3 -5 - l i n k e d hexamer of

the

large e x c e s s ,

reaction,

with

then auto-catalytic

(153) and

(154)

s y n t h e s i s of

the

hexamer i s o b s e r v e d .

4.2

E n z y m a t i c S y n t h e s i s -1

units

of

Copolymers containing

2-amino-2'-deoxyadenylate a n d

e i t h e r

alternating 5-bromo-2

' -

deoxyuridylate or 5-iodo-2 ' - d e o x y u r i d y l a t e h a v e b e e n p r e p a r e d by polymerising

2-NH2-dATP

and

e i t h e r

5-Br-dUTP

or

5-I-dUTP,

r e s p e c t i v e l y , w i t h D N A p o l y m e r a s e I ( E . c o l i ) i n t h e p r e s e n c e of poly[d(A-T) s t u d y of

I

.225

their

The copolymers

high s a l t concentrations. which

were

used

for

spectroscopic

interconversions between B and A conformations i n

Ij6-methyladenine

Copolymer analogues of poly[d(A-T) ] replaces

t h e

adenine

bases,

or

in 5-

e t h y l u r a c i l or 5 - m e t h o x y m e t h y l u r a c i l replace t h e t h y m i n e b a s e s , h a v e b e e n p r e p a r e d s i m i l a r l y , t o i n v e s t i g a t e t h e e f f e c t s of t h e m o d i f i c a t i o n s on t h e a l t e r n a t i n g conformation of While a l l

poly[d(A-T)

the m o d i f i c a t i o n s d e s t a b i l i z e d t h e d u p l e x e s i n v a r y i n g

degrees, t h e e f f e c t s on t h e a l t e r n a t i n g c o n f o r m a t i o n of p o l y [ d ( A T)],

as indicated by

salt-dependent. alkene

31p n . m . r .

spectroscopy,

( E ) - 5 - ( l - A l k e n y l 1-dUTP

substituent ranged

tested f o r t h e i r a b i l i t y

from propenyl

were v a r i e d a n d

species

i n

to octenyl

which

the

have been

t o b e i n c o r p o r a t e d w i t h dATP b y K l e n o w

f r a g m e n t i n t h e p r e s e n c e of p o l y [ d ( A - T ) ] , 2 2 7

A l l the alkenyl-

238

Organophosphorus C hernis i r! 1p t o h r x e n y l

dU'1'P species

weic

P r o p e n y I IdUTP) incorporation sub5tituent

1

( a n d also 5 - v i n y l - d u ~ P a n c j ( 2 ) 5 ( 1 d

incorpoi ated,

diminish(.d

I though

non-1 inc.arly

ncreased.

G4-Methyl-L

incorporated i n t o p o l y [ d ( A - ' I ' )

1

the

a s

ef f i c i e n c - y

t h e

-deoxythymidint,

has

of

the

lenytil o t

i,f,en

( 5 - 1 0 8 ) r e p l a c e m e n t of

i n partial

d e o x y t h y m i d i n e b y c o p o l y m e r i s a t i o n o f d A T P , d T ' I ' P , a n d ~ 4 - r n e t h y -l dTTP b y K l e n o w re5ulting

fragment

copolymer

using poly

was

Id(A-T)] a s templatc'.LL8

resistant

the

to

3 -5

a c t i v i t y of

K l e n o w f r a g m e n t a n d T 4 DNA p o l y m e r d s e ,

observation

supporting

and

~n

into p o l y [ d ( G - C ) ] cannot

be

b u t when m i s i n c o r p o r a t f d

thymidine

it

O4-Ethyl-L and

removed

by

the

bases,

a t

polymerases

mutant

o€

5 -exonuclease

[ d ( A - T ) ] i n p l a c e of

proofreading

e x o n u c l e a s ~ . ~ ~ ~

gaps

genrratcd

by u s i n g G4-ethyl-dTTP

for t h e g a p - f i l l i n g

with

reaction

catalysed

M ~ ~ r O c o c c u ~ - l ~ t e ou rs, ,

T h i s process c a n b e u s e d t o g e n e r a t e h i g h 0 1 1g o d e o x y r

p 1a s m i d s .

recessed

gig-uridine,

uridine,

residue,

or

ib

o n u c 1e o t i d e s

3 -termini

recoqnized

3 -termini

bearing

L -deoxy-xylg-thymidinc

i

th

hair-pin

a s

the

3

-

methods.231

polymerase enzymes t o recoqnise t h e s e

as p r i m e r s t o p e r f o r m region,

w

decxythymidine,

have been preparrd using solid-phase

Upon t e s t i n g t h e a b i l i t y o f

single-stranded

a t

and o t h e r

self - c o m p l e m e n t a r y s e q u e n c e s f o l d i n g t o f o r m

partially

structures,

terminal

d e o x y c y t i d i n e by

3 4

into poly

f r o m E>_oJl,

p a r t i c u l a r l y , AMV.L30 leve1s

the

single-stranded

dNTP s p e c i e s a s s u b s t r a t e s DNA

by

-deoxycytidine

-deoxythymidine h a s been m i s i n s e r t e d o p p o s i t e a d c n i nc

guanint-

r e s t r i c t i o n s i t e s i n d u p l e x DNA,

by

i n place of

removed

activity,

is

the

it w a s shown t h a t y4-amino-2

a n a n a l o y o u 5 .,tudy,

fragment

that

former

polymer i51ny

Klenow

n o t ion

thr

prootreading domains i n Klenow f r a g m e n t are s e p a r a t e sites.

misincorporated

the

'I'he

exonucl(1dse

fill-in

synthesis opposite the

i t w a s f o u n d t h a t DNA p o l y m e r a s e a

deoxythymidine and uridine,

readily

and reverse transcriptdse

from Moloney m u r i n e leukaemia v i r u s r e c o g n i z e d deoxythyrnidine,

but

t h e o t h e r t e r m i n i were r e c o g n i z e d p o o r l y o r n o t a t a l l .

Riboadenosine r e s i d u e s

place

of

have been

deoxyriboadenosine

by

substituted

nick-translation

i n t o DNA i n u s i n g ATP,

6: Nucieotides and Nudeic Acids

239

cesulting in thc sdrprising 1 indiny t h a t D N A containlny morr t h,ln 5% of r i b o n u c l c o t i d e s c a n n o t f o r m n l ~ c l e o s o m e s . ~ In ~ ~ tact, level of r 1 bosubst formation.

it

ution

a5

1ow

a 5 0.4%

RibosIJbstitution resulted in a chanqe i n mobi 1 ity

electrophoresis

I

it

i m p a i red nucl ~ ’ ~ s o m r > 01)

n pol yacry lam ide g e 1 s , s u y q e s t ing a 1 ter a t 1 on5

1

n

helical structure, and hence that nuclcosome formation may h c vc’ry sensitive t o perturbdtions of t h i s typc.

A number of d < ~ r i v a t i v r ~ ~ ,

of d A T P b e a r i n g b i o t i n a t t a c h e d t o t h e 6 - a m i n o grotip y ~ Ie i n k t ~ r ~ , of 3-17 a t o m s , and 01 dCTP bearing biotin attached t o th(, 4-amino l i n k e r s of

group

incorporated labelled

DNA

3-14 atoms have been

s y n t h e 5 i / e d
i n t o D N A by n i c k - t r a n ~ l a t i o n . ~ ~T ~ h e resultant probes

hybridized

efficiently to

tdrqt’t

I)NA

sequences. ( 15 5 ),

NL,3-Ethenoguanosine

1

ormed

by

treating

6-9-

ethylguanosine w i t h b r o m o a c e t a l d e h y d c , h a s b e e n c o n v e r t e d to

I

t5

5 ’-monophosphate u s i n g 4 - n i t r o p h e n y l p h o s p h a t e a n d whclat s h o o t phosphotransferase,

and thence t o its diphosphate which

could h c

copolymerised with CDP o r ADP using polynucleotide phosphoryldse from M.luteus.234

T h e resulting polymers contained between 6 and

3 2 % of ( 1 5 5 1 , a n d e x h i b i t e d f l u o r e s c e n c e i n p r o p o r t i o n t o

content.

th15

I t i s t h o u g h t t h a t ( 1 5 5 ) m a y b e of relevance’ ~n vlnyl

chloride-induced c a n c e r . Terminal deoxynucleotidyl transferase (TDTase) has been used to add [a-32P]dCTP t o the 3 -OH termini of oligo(dT)12-181 t o form radiolabelled oliqomers w i t h a continuum of chain lengths ranging from t h e 13-mer t o over 100 residues long.235 with

o l i g ~ ( d T ) ~l a~ b-e l~l ~ ed

using

When this is mixed

[v -3LP] ATP and T 4

polynucleotide k i n a s e , a n d t h e m i x t u r e s e p a r a t e d o n a s e q u e n c i n g gel, a c o n t i n u o u s

ladder

represents t h e 1 2 - m e r .

i s f o r m e d , i n w h i c h t h e bottom rung

T h i s serves a s a s c a l e for u s e in t h e

purification and identification o f synthetic oligonucleotides. A

number

of o l i g o r i b o n u c l e o t i d e s c o m m e n c i n g

with

the

sequence AUG have been prepared by stepwise ligation of p N p units

240

Organophosphorus Chemistn,

to AUG using T 4 RNA llgase.236 used to

T h e sequences synthesised were

investigate t h e changes in the energetics of

formation w h e n a n A - U p a i r

i s r e p l a c e d by a G - U

helix

mismatch.

Reaction conditions have been defined which optimise the ligation of sing le-stranded o 1 igodeoxyr i bonuc 1 eotides by T 4 RNA 1 igase2 3 7 . These include the use of polyethylene glycol as a n additive to increase macromolecular crowding, a stratagem which seems widely applicable for increasing enzyme-DNA interactions.238

Oligomers

of uridylic acid of varying chain lengths have been prepared using UDP and polynucleotide phosphorylase, 5'-end-label led with

[y - 3 2 ]

ATP and polynucleotide kinase, and then ligated with RNA ligase to form circles.239

T h e strength of binding of cyclised (U),("=7-

15) t o poly ( A ) w a s found t o be far weaker than that of linear oligomers of equal

length, which may be significant for the

function of loop structures in tRNA and other RNA species. The

dodecamers

d(TTTCGACTTCGA1

and

d( T C G A A A T C G A A G ) ,

synthesized chemically, form a concatemeric DNA-like duplex when mixed in equirnolar quantities, and chemical and enzymic ligation using T4 DNA ligase affords a polymer coding for the polypeptide (

Phe -Asp )

-

'.

5. Other Studies 5.1 Affinity Separation -

In a n e w e n z y m a t i c procedure

for

linking DNA to cellulose, terminal deoxynucleotidyl transferase is

used t o add a poly

( d A ) tail t o the 3 -ends of a segment of

double-stranded DNA.241

T h e poly(dA) tail i s then hybridized to

oligo(dT)-cellulose, and the g a p between the 3 '-terminus o f the oligo(dT) a n d t h e 5 - t e r m i n u s o f a D N A s t r a n d f i l l e d in a n d ligated using denaturation

Klenow

fragment and T 4 DNA

ligase.

Thermal

then separates the DNA strands t o leave a single

strand linked specifically and covalently 9i t s 5'-end t o the

cellulose matrix.

Affinity purification of sequence-specific DNA

binding proteins can

be performed

by synthesizlng complementary

ol igodeoxyribonucleotides containing a recogn it i o n site for the

6: Nucleotides and Nucleic Acids protein

of

oligomers,

24 1

i n t ~ r e s t ,annealing and then

coupling

cyanogen bromide.L42

and

ligatinq

the oligomers

t o

When a p a r t i a l l y - p u r i f i e d

them

to

give

Sepharase with protein

f raction

combined w i t h n o n - s p e c i f i c c o m p e t i t o r DNA i s p a s s e d t h r o u g h t h e column, o n l y p r o t e i n s b i n d i n g s p e c i f i c a l l y t o r e c o g n i t i o n sites o n t h e Sepharose-immobi

11

z e d DNA a r e r e t a i n e d .

t h e c a t a l y t i c s u b u n i t of

MI R N A ,

h a s been l i n k e d t o a g a r o s e beads

ribonuclease P (E.coli)

o x i d a t i o n of t h e

3 -terminal

r e s i d u e w i t h p e r i o d a t e and condensation w i t h a g a r o s e - a d i p i c dihydrazide.243

acid

The r e s u l t i n g column c o u l d b e used t o o b t a i n C5,

t h e p r o t e i n c o m p o n e n t o f R N a s e P,

a single step.

from crude e x t r a c t s of E.coli

Interestingly,

a l t h o u g h M1 R N A

is

active

in in

t h e immobilised M1 w a s inactive

solution i n t h e absence of C5, u n l e s s C5 w a s p r e s e n t .

Pre-mRNA,

t h e f o r m of mHNA p r i o r t o m a t u r a t i o n a l s p l i c i n g ,

h a s b e e n s y n t h e s i z e d i n t h e p r e s e n c e of a l o w l e v e l o f a b i o t i n it with a few b i o t i n residues.L44

UTP c o n j u g a t e i n o r d e r t o l a b e l

T h e b i o t i n y l a t e d pre-mRNA w a s t h e n i n c u b a t e d a s a s u b s t r a t e f o r s p l i c i n g w i t h a n u c l e a r e x t r a c t f r o m HeLa c e l l s , a n d t h e e n t i r e r e a c t i o n m i x t u r e t h e n f r a c t i o n a t e d by s e d i m e n t a t i o n o n gradient.

Passage of

glycerol

t h e fractions over streptavidin-agarose

beads t h e n p e r m i t t e d r e t e n t i o n o f t h e b i o t i n y l a t e d RNA t o g e t h e r w i t h a t t a c h e d small r i b o n u c l e o p r o t e i n p a r t i c l e s w h i c h a r e t h o u g h t

to

be

integral

components

of

t h e

spliceosome

complex

r e s p o n s i b l e f o r s p l i c i n q pre-mRNA.

5.2

Affinity Labelling -

Treatment

of

dUMP

t e t r a f l u o r o b o r a t e i n DMF y i e l d s 5 - n i t r o - d U M P I w i t h z i n c t o g i v e 5-amino-duMP, with

sodium

azide

to

afford

with

nitronium

w h i c h may b e r e d u c e d

and t h e n d i a z o t i z e d and t r e a t e d 5 - a ~ i d o - d U M P . ~ ~F~o l l o w i n g

c o n v e r s i o n t o t h e t r i p h o s p h a t e w i t h DPPC a n d p y r o p h o s p h a t e ,

5-

azido-dUTP p r o v e d t o b e a n e f f e c t i v e p h o t o a f f i n l t y l a b e l f o r DNA polymerase I from E.coli,

b i n d i n g t o t h e a c t i v e s i t e of t h e e n z y m e

w i t h h i g h e r a f f i n i t y t h a n dTTP.

Moreover,

i n t h e a b s e n c e of

242

Orgunophosphorus Chemistry

irradiation,

it acts as an effective

alternative

dTTP f o r t h e e n z y m e , p e r m i t t i n g t h e s y n t h e s i s of DNA.245fL46

template,

photoactivable

26-base

f r a g m e n t w a s p r e p a r e d i n t h i s way, repressor

lac

Using a s v n t h e t i c 26-mer a

protein

upon

operator

duplex

and became c r o s s - l i n k e d wlth

to

o p e r a t o r s e q u e n c e as

pair

irradiation

p h o t o a c t i v i t y o f 5-azido-dUMP

\ub\tratc

photoactivdblc

U.V.

t o 1%

light.L46

The

i s s t a b l e t o e x t r e m e s of p H , d n d t h e

t r i p h o s p h a t e c a n b e u s e d e v e n i n t h e p r e s e n c e o f DTT, u n l i k e some other

azide-containing

Azidoguanosine-3

photoaf f i n i t y

-phosphate-5

8-

-[ 32P]phosphate h a s

been

used

t o

p h o t o l a b e l t h e ppGpp b i n d i n g s i t e o n D N A - d i r e c t e d R N A p o l y m e r a s e from

E.coli,

labelled,L47

The

of

p r e s e n c e of

3 -9-(4-Benzoyl)

labelling. been

the o-subunit

the

enzyme being

ppGpp d e c r e a s e d

most

the

t h e

degree

of

benzoyl c y t i d i n e - 5 - t r i p h o s p h a t e h a s

p r e p a r e d b y c o n d e n s i n g CTP w i t h 4 - b e n z o y l b e n z o i c

carbonyldiimidazole,

heavily

assignment

of

t h e

acid using

position

of

e s t e r i f i c a t i o n b e i n g b a s e d o n t h e d o w n f i e l d s h i f t of t h e 3 - p r o t o n of t h e s u g a r r i n g . 2 4 8

The r e a g e n t was b o t h a s u b s t r a t e a n d a n

effective photoaffinity label

for CMP-N-acetylneuraminic

synthetase from E.coli

liver,

or

rat

photoincorporation

acid being

s u p p r e s s e d b y t h e p r e s e n c e of C T P .

I t m u s t be e m p h a s i z e d t h a t o n l y n o v e l o r u n u s u a l n u c l e o t i d i c

affinity

l a b e l s are considered i n t h i s

Section:

commonly-used

l a b e l s e m p l o y e d i n a r o u t i n e way a r e n o t r e p o r t e d h e r e , a n d t h e i n t e r e s t e d r e a d e r i s a d v i s e d t o s e e k o t h e r s o u r c e s of

information.

O x i d a t i o n o f ADP w i t h MCPBA a f f o r d s a d e n o s i n e - 1 - o x i d e - 5 diphosphate.

’-

T r e a t m e n t w i t h sodium h y d r o x i d e , f o l l o w e d by c a r b o n

d i s u l p h i d e , a f f o r d s 2-thio-ADP1

which upon

a l k y l a t i o n by

1,4-

d i b r o m o b u t a n e d i o n e g i v e s 2- ( 4 - b r o m o - 2 , 3 - d i o x o b u t y 1t h i o ) a d e n 0 s i n e

5’-diphosphate

allosteric

(156), which is a n e f f e c t i v e a f f i n i t y l a b e l f o r t h e

ADP-binding

site

dehydrogenase from p i g heart.249

of

NAD+-dependent

isocitrate

The c o r r e s p o n d i n g monophosphate

( 1 5 7 ) i s a n a f f i n i t y l a b e l f o r a n a l l o s t e r i c A D P - b i n d i n g ’ s i t e of g l u t a m a t e dehydrogenase from b o v i n e 1i v e r . 250

6: Nucleotides and Nucleic Acids

243

And now: affinity unlabelliny!

p 1 - ( 5 -Adenosyl ) - p 2 - N - ( 2 -

mercaptoethyl) d i p h o s p h o r a m i d a t e ( 1 5 8 ) h a s b e e n p r e p a r e d by condensing ADP with bis(2-aminoethy1)disulphide using D C C ,

and

subsequent reduction of the disulphide bond with borohydride.L51 This agent binds to a nucleotide-binding site of F1-ATPase which has

been

inactivated by

the attachment

of

a

4-nitro-L,1,3-

benzoxadiazolyl group t o the phenolic hydroxyl of tyrosine 8-311 in the hydrolytic site, and re-activates the enzyme by removal of the blocking group. mechanism,

The reactivation kinetics suggest a dual-path

the rapid path (involving binding

of

( 1 5 8 ) at

the

nucleotide-binding site) being suppressed by the presence of A D P or A T P .

T h e product o f the reaction i s thought to be ( 1 5 Y ) .

The observed reactivation establishes that tyrosine 6 -311 must be located close t o t h e triphosphate chain of ATP bound

at the

hydrolytic site. 3,3 -Dithiobis[3 ( 2 ) - g - { 6 - ( p r o p i o n y l a m i n o ) h e x a n o y l J A T P ] (160) has been prepared by coupling the dicarboxylic acid formed

from 3 , 3 ' - d i t h i o b i s ( p r o p i o n i c ester) a n d

acid) b i s ( t j - h y d r o x y s u c c i n i m i d e

6-aminohexanoic acid

diimidazole. 2 5 2

to

ATP

using

carbonyl

Both myosin subfragment 1 and heavy meromyosin

hydrolyse ( 1 6 0 ) t o the bis(diphosphate) (161), and on addition of excess vanadate ion both enzymes are inactivated by the formation of a stable vanadate-(161) complex a t t h e active site.

Uslng

this agent, dimers of both proteins cross-linked by vanadate-(161) have b e e n o b t a i n e d , a result which has p e r m i t t e d a n upper limit to be estimated for t h e distance of t h e ATP-binding site of myosin from the surface of the protein. Two Russian reviews on chemical and biochemical aspects of the use of reactive nucleotides and oligonucleotides as affinity reagents and for complementarily addressed modification of nucleic acid s e q u e n c e s h a v e a p p e a r e d . 2 5 3

S o m e of t h e s e a r e w e l l

exemplified i n a study i n which sixteen different derivatives of AMP,

ADP, A T P ,

G M P , G D P , o r GTP m o d i f i e d a t t h e t e r m i n a l

Organophosphorus Chemistp

244 phosphates

to behave as

phosphorylating agents

(phosphor-

imidazolidates or trimetaphosphate5), alkylating agents (nitrogen mustards) or condensing

aqents

(benzaldehydic m o i c t i e s ) were

investigated as affinity labels f o r R N A polymerase in the presence of promoter-containing templates.254

Treatment of the e n z y m e

with the label w a s followed by addition of a n pyrimidine nucleoside triphosphate.

If

labrllcd

the affinity label became

attached at t h e active site, and its purine base and that of the added

pyrimidine

nucleotidc

corresponded

to

the

nucleotide

sequence o f the promoter, synthesis occurred t o aive the enzymebound radioactive dinucleotide Enz-(p)nPu( 32P]pPy, whi le residues of affinity reagent binding outside the active site remained nonradioactive.

Reagents w i t h only a short

arm

between the

terminal phosphate and the reactive group were found to label only the 6-subunit of the enzyme, while reagents w i t h a longer labelled the u-subunit also. last study,

I

arm

One of the species used in this

-[ N - 2 - c h l o r o e t h y l --N - m e t h y l a m i n o )] b e n ~ y l a m i d o - A T P

(162) has also been used f o r the affinity l a b e l l ~ n go i a form of Na',

K'-ATPase,

enzyme.255

becoming bound to the catalytic 11-subunit o f the

An oligoribonucleotide AUGU6, derivatized t o bear a

similar alkylating function at the terminal uridine residue ( 1 6 3 ) has been used for the affinity labelling of E.coli ribosomes wlthin the initiation and pretranslocational complexes formed during

protein

synthesis.256

The

patterns of

labelling of

ribosomal proteins varied considerably between the two complexes. The platinated oligonucleotide d[ (pT),pC[Pt2+(NH3)20H][PT)7]

1s an

affinity label for the template site of

a

D N A polymerase

from

human placenta, and has been used in a competitive bindlng assay in which the ability of other oligonucleotides t o bind t o the

template site and prevent inactivation w a s measured.257

The

affinity of oligo(deoxythymidy1ate) for the binding slte rose with increasing chain length, and, while partial ethylation at the internucleotidic phosphates did not alter t h e blnding afflnity greatly from that of the corresponding non-ethylated compound, complete ethylation caused a substantial drop ~n the affinity. It was thought that a single charged internucleotidic phosphate of

6: Nucleotides and Nucleic Acids

245

t h e t e m p l a t e i s r e q u i r e d f o r a n t l e c t r o s t a t i c c o n t a c t w i t h tiicx enzyme.

The same approach h a s been

e f f i c i e n c y of

s p e c i e s , b y m e a s u r i n g t h e d e g r e e of to

the

enzyme

against

t o detcyrmine

used

the

DNA p o l y m e r a s e a w i t h dNTP

c o m p l e x f o r m a t i o n of

protection which they a t f o r d

inac-tivation

by

2 -deoxythymidlne-5

-

phosphor imidazol i d a t e . 258

The

accessibility

transcription

of

complexes

leading

the

has been

protection technique.‘”

end of

monltored

by

nascclnt a

RNA

~n

photoatf i n i t y

The a z i d o a r y l a t e d ApU d e r l v a t l v e ( 16 4 )

w a s u s e d a s a p r i m e r f o r t r a n s c r i p t i o n c d t a l y s e d by RNA p o l y m e r a s e in

t h e

presence

triphosphates.

a

of

t e m p l a t e

DNA

After transcription

s y s t e m w a s t r e a t e d w i t h t h i o l s ( e.g. azide groups,

of t h e

and then

thiophosphate

the

using

t h e

released

phenylmercuric

chain

sequencing g e l s with t h a t from t h e control

(3 - s u b u n i t s

and

by

portions cleavage

acetate,

lengths obtained w a s

a d d i t i o n of t h i o l s w a s m a d e .

the

were i n a c c e s s i b l e t o

01 i g o n u c l e o t i d e

were

transcripts

link

d i s t r i b u t i o n of

t h e fi

a z i d e groups which

Subsequently

covalently-bound

r i b o n u c l ~ o s l d e

limited period,

DTT) t o r e d u c e t h e a c c c s s i b l e

irradiated to label

enzyme using t h e

the thiols.

and

for a

of

a t

and

compared

experimclnt

the the t h e on

i n which no

T h e a c c e s s i b i l i t y of t h e l e a d i n g

e n d o f t h e R N A w a s t h u s m o n i t o r e d as a f u n c t i o n of

chain length,

and t h e r e s u l t s s u g g e s t e d t h a t t h e l e a d i n g e n d of t h e t r a n s c r i p t may d i v e r g e f r o m t h e D N A t e m p l a t e w h e n t h e t r a n s c r i p t bases long.

A f f i n i t y 1 a b e 11 i n g

of

RNA

HeLa c e l l s b y n a s c e n t t r a n s c r i p t s h a s b e e n a c h i e v e d t h e t r a n s c r i p t i o n i n t h e p r e s e n c e of transcription

4-thio-UDP

l e n g t h by t h e i n c l u s i o n o f

is 12-14

polymerase II from by p e r f o r m i n g (limiting the

3 -2-methyl-GTP

as chain

terminator) and then i r r a d i a t i n g t h e system t o cross-link thiouridine residues to the

were

found

t o be

residue i n tRNAPhe

of

E.coli

intramolecular cross-linking of

a denatured

c o n d i t l o n s .261

The s u b u n i t s

labelled predominantly.

form

of

The

has been used

11,

t h e 4a n d 11,

4-thiouridine

similarly to effect

i n order to study t h e characteristics

the

tHNA

which

occurs

under

certain

T h e 3-(3-amino-3-carboxypropyl)uridine r e s i d u e

1

246

0

0 II

0

S

II

Organophosphorus Chemistry

H - ( - l )OOwn A d e

0

i

-N-P-O-P-O-(Ado-S’) H I I

-0

OH

i o=c

( CH2 15

i

-0

II

(159) (1601n.3 (161 In = 2

CICH2CH2 0 0 0 ‘ N ~ C H ~ N - PH- O 11- P - O -II - P - O II- - ( A ~ ~ -

I

/

Me

-0

( A U GUS- 3% 0

I1

- pI -0

1

-0 (162)

0 0

t;

HNccH2cH2s

Ura

1

-0

5’)

6: Nucleotides and Nucleic Acids

247

found in the variable loop of elongator tRNAMet f r o m been

condensed

with

3 , 3 -dithiobispropionic

&coJi

acid

has

bir(N-

hydroxysuccinimide ester) to give (165) which becomes cross-linked to protein upon incubation with methionyl-tRNA synthetase, with concomitant

loss of the enzymic activity.26L

Self -complementaiy

oligodeoxyribonucleotides containing 5-bromodeoxyuridine in place

of deoxythymidine in various positions within and outside the recognition sequences for restriction endonucleases KO K I and Eco

R V have been synthesized, and are cleaved by the e n z y m ~ sa t the

appropriate recognition sequences.263

Upon irradiation, a modest

yield of photo-crosslinking to the enzymes is observed. 5.3

Post-anthetic Modification -

reporter molecules,

'rhe l a b e l l i n g of

DNA

with

or affinity ligands such a s biotin, has

attracted much attention.

Cytosine residues in single-stranded

regions of DNA have been biotinylated by treatment with bisulphite at pH 4.5, followed by addition of biotin h y d r a ~ i d e . ~Since ~~ this reaction takes place specifically in single-stranded regions, they can be labelled selectively without affecting sequences, required for hybridization. of biotin

molecules

to

a

A method of attachment of a number DNA hybridization probe consists in

effecting mutiple attachment of 6-(N-biotinyl)aminoheptanoate to a large basic molecule (histone H1, cytochrome c , polyethyleneimine) which is linked t o DNA via a bifunctional cross-linking reagent

(3. glutaraldehydc).265

sensitive.

T h e resultant probe is extremely

Midivariant RNA - which can be autocatalytically

replicated by Q B

replicase - has been 5'-[ 3 2 P ] phosphorylated,

converted to its 5 ~ - p h o s p h o r i m i d a z o l i d a t e using EDC and condensed

first with 2,2'-dithiobis(ethylamine) and then with N-hydroxy-

succinimidobiotin t o give ( 1 6 6 ), avidin.266 to any

which combined readily with

Since the avidiii - (166) complex should bind readily

biotinylated probe,

and

subsequent reduction of the

disulphide link will release the midivariant RNA for amplification by

QB

replicase, the RNA moiety of (166) represents an amplifiable

reporter group, giving an assay system of extreme sensitivity.

248

Organophosphorus Chemistry Initiator (tRNAfMet) dnd elongator tRNA molecules of E.coli

have been oxidised with periodate at the 3 -terminal adenosine and then condensed with 4-amino-TEMPO to afford, after reduction wlth borohydride, a spin-labelled terminus o f type

(

167).267

~.p.r.

spectroscopy indicated a d i f f e r e n t motional behaviour of t h e 3 terminus of tRNAfMet f r o m that of the elongator tRNA species, suggested that the terminus was constrained or folded back, rather than freely rotating.

The

penultimate cytidinc residue of the

-CCA terminus o f tRNATYr has been replaced by 2-thiocytidine by degrading the terminus by t w o cycles o f periodate, lysine ( p H 9 ) and alkaline phosphatase treatments, and then restoring it using 2-thio-CTP, ATP, and ATP(CTP): tRNA

nucleotidyltransferase.L68

After aminoacylation with tyrosyl-tRNA synthetase, the sulphur atom was alkylated using N-(iodoacetylaminoethyl)-5-naphthylamine-

1-sulphonic a c i d t o i n t r o d u c e a f l u o r e s c e n t l a b e l , a n d t h e interaction of the tyrosyl-tRNA with the elongation factor Tu.GTP complex studied by changes in fluorescence intensity. Once

again

painstaking

cleavage,

m o d i f i c a t i o n and

reassembly with nucleases, phosphatase, kinase and ligase have resulted i n t h e construction of a large number of specifically modified

tRNA species for

activity relationships.

investigation o f their structure-

In the most complex manipulation, yeast in

t h e c o u r s e of

constructing variants in the T-stern and loop.269

Other studies

tRNAASp

was

cleaved

into four

sections

have concentrated o n t h e anticodon loop the highly-conserved uridine-33

has

:

in tRNAPhe from yeast

been

replaced

n u c l e o ~ i d e sand ~ ~ ~t h e anticodon sequence altered.271

by

other

Similar

substitutions were performed in yeast tRNATyr,272 and the size of the anticodon

loop w a s altered in yeast tRNAAla 2 7 3 .

The

modified tRNA molecules were generally tested for their ability to be charged b y their cognate aminoacyl-tRNA synthetases, o r t o support protein synthesis by interacting with the ribosome.

one case271 a modified t R N A

In

w a s able t o recognize a 2-base codon,

thus demonstrating how the ribosomal are sometimes observed, might occur.

reading f rameshifts,

which

6: Nucleotides and Nucleic Acids In

several

249

studies,

an

oligonucleotide

has

been

site-

s p e c i f i c a l l y m o d i f i e d w i t h a mutagen or s i m i l a r a g e n t and t h e n incorporated enzymically e n t i r e genome, instance,

of

the

larger

DNA d u p l e x ,

complementary

strand

and

1n

For

the presence

4 -hydroxymethyl-4,5

fragment a t a central location.

i r r a d i a t i o n t o form an i n t e r s t r a n d cross-link, s u b s t r a t e f o r ABC e x c i n u c l e a s e

After further

t h e d u p l e x was used

from E.coli,

enabling the

p h o s p h o d i e s t e r b o n d s c l e a v e d i n t h e c o u r s e o f DNA r e p a i r of l e s i o n by t h i s e n z y m e t o b e i d e n t i f i e d . 2 7 5 carcinogen

,8-

t o form photoadducts a t t h e i n t e r n a l thymine

Further l i g a t i o n a f f o r d e d a 40-base p a i r duplex w i t h

the psoralen-T

as a

or even an

the modification.

d(TCGTAGCT) was p r e p a r e d a n d i r r a d i a t e d

trimethylpsoralen, base.274

into a

t o s t u d y t h e e f f e c t of

4-aminobiphenyl,

tetradeoxynucleotide,

has

attached

to

the

I n a s i m i l a r way, t h e C-8

of

guanine

in

a

b e e n l i g a t e d i n t o a c o m p l e t e M13 mp 1 0

genome f o r s t u d i e s i n s i t e - s p e c i f i c r n u t a g e n e s i s . 276

Some p r o d u c t s o f r e a c t i o n o f m i t o m y c i n C w i . t h t h e g u a n i n e bases i n polynucleotides

have been

identified.

In anaerobic

c o n d i t i o n s i n t h e p r e s e n c e of a c h e m i c a l o r b i o c h e m i c a l r e d u c t a n t , mitomycin C i s a c t i v a t e d a n d a t t a c k e d by

t h e 2-amino

group of

d e o x y g u a n o s i n e r e s i d u e s i n DNA w i t h o p e n i n g o f t h e a z i r i d i n e r i n g , giving ( 1 6 8 ~ ~ ” Under r e d u c t i v e c o n d i t i o n s , a n d p a r t i c u l a r l y when a c t i v a t e d b y s o d i u m d i t h i o n i t e , f u r t h e r r e a c t i o n c a n o c c u r with

poly[ d(G-C)] and

anion

radical

DNA,

affording

a covalent cross-linked

I t is thought t h a t reduction t o t h e semiquinone

adduct (169).278

is

f o l l o w e d by

conjugated iminium system,

loss

of

carbamate to

give

a

w h i c h i s a t t a c k e d by t h e 2 - a m i n o g r o u p

of a n o t h e r 2 ‘ - d e o x y g u a n o s i n e r e s i d u e t o f o r m t h e o b s e r v e d p r o d u c t . I n a c i d i c c o n d i t i o n s a t pH4, a n o t h e r mode o f a c t i v a t i o n o c c u r s , a n d t h e a r r a y of p r o d u c t s o b s e r v e d f r o m t h e r e a c t i o n s o f DNA or ia an d ( G p C ) w i t h m i t o m y c i n C a r e b e s t r a t i o n a l i s e d a s a r i s i n g vi n i t i a l a d d u c t of t y p e ( 1 7 0 ) i n w h i c h a l k y l a t i o n of a g u a n o s i n e r e s i d u e a t N-7 h a s o c c u r r e d f o l l o w i n g p r o t o n a t i o n of t h e a z i r i d i n e ring.279

S u b s e q u e n t l y loss o f

t h e sugar moiety can occur to

l e a v e t h e g u a n i n e a d d u c t ( t h e p r o d u c t o b t a i n e d f r o m DNA) or else

250

Organophosphorus Chemistry

tRNA - C p C p - O y j Adt

JL I

'0

(167)

Me

% N

NH2

Me

(168) R = O C O N H z (169) R - N2-(dGuo1

dRib (1701

NH,

(1 7 2 1

Rib

- 5'- fl (171)

6: Nucleotides and Nucleic Acids

25 1

hydrolysis of the imidazolium ring w i t h attached sugar may occur.

isomerisation o f the

Upon reaction with malonaldehyde, G M P

affords the fluorescent pyrimidopurlnone (1711, and t h e s a m e adduct can be isolated from RNA treated with m a l ~ n a l d e h y d e . ’ ~ ~ Spectroscopic analysis suggests that a d i m e r i c adenine photoproduct

formed in

u.v.-irradiated

poly(dA) has the structure (172).281

d(ApA), d(pApA) and

It is thought t o arise a%

hydrolytic cleavage of an azetidine photoproduct initially formed between “7)

and C ( 8 ) of t h e 5‘-adenine base and C(6) and

C(5) of

the 3’-adenine, and is degraded by acid t o form 4,6-diamino-5guanidinopyrimidine.

Direct irradiation of d(TpT) o r t h e (6-4)-

photoproduct o f d(TpT) with high-intensity U.V. light affords a photoproduct

whose

pyrimidinone

(173).282

structure has been assigned a s t h e 1)ewar While

the

(6-4)-photoproduct

was

converted quantitatively t o ( 1 7 3 ) , it w a s formed from d(TpT) in addition t o cyclobutane dimers.

Its significance a s a possible

cause of mutagenesis awaits evaluation.

The Y-irradiation of

DNA i n anoxic solutions or i n HeLa cells leads t o the formation of 5,6-dihydro-2 ‘-deoxythymidine residues ( c f . (74)) with preferential formation

of

the

( E ) d i a s t e r e o i ~ o m e r . ~ ~I~n

contrast,

irradiation of deoxythymidine affords equal quantities of the ( R ) and of

(S)

isomers.

radical

Evidence for the formation in X-irradiated DNA

precursors

of

thymine

glycol,

6-hydroxy-5,6-

dihydrothymine and 5-hydroxymethyluraci 1 has been obtained by a spin-trap method employing 2-methyl-2-nitrosopropane and e.p.r. spectroscopy .284

8-Hydroxy-2 ’-deoxyguanosine has been s h o w n t o

accumulate in the DNA of cells exposed t o the tumour promoter tetradeconylphorbol a c e t a t e .

’

T h i s a g e n t st im u 1 a t e s t h e

formation of superoxide anion radical, which gives rise in turn to hydroxyl radical which is probably the active agent.

8-Hydroxy-

2’-deoxyguanosine i s also f o r m e d i n cellular D N A exposed t o the

carcinogen 4-nitroquinoline-l-oxide,

probably

t h e agency of

4-hydroxyaminoquinol ine- 1-oxide as t h e active intermediate. Exposure

of

DNA

in

a q u e o u s solution287

or

in h u m a n

cell

cultures288 t o Y -irradiation resulted i n t h e formation of 8,5’-

252

Organophosphorus Chemist?

cyclo-2 -deoxyquanosine residucs (174). ratio of

5 (R)

:

5

( S )

In c e l l

diastereoisomers

culture the

formed was

1:3,

the

stereochemistry being assigned in the nucleosidic- products of the degraded D N A using ' H

n.m.r.

hydrogen atom from C - 5 irradiation

1s

It is thought that abstraction of a

by a hydroxyl radical generated by Y -

followed by formation of a C ( 5 ) - C ( 8 ) covalent bond

and oxidation of the resulting N-7-centred radical.

in addition

to the foregoing, a considerable number of free-radical-induced base-derived species in D N A have been detected and characterised following exposure of D N A to ionising radiation in nitrous-oxidesaturated s o 1 u t i o n , h y d r o 1 y s i s , t r i m e t hy 1 s 1 1 y 1 a t ion of t h e

products, a n d a n a l y s i s u s i n g g . 1 . c . - m . s .

with

selected-ion

monitoring.*'' 5.4

-

Sequencing and Cleavage Studies

Two n e w reviews of D N A

sequencing a r e in s o m e sense complementary, the one dealing w i t h the basics of end-labelling and cleavage,290 and the other more with strategy.lgl

Now that 1984 has c o m e and gone it should c o m e

as n o surprise that the Japanese are proposing t o commission a n automated

super-sequencer

million bases a day.292

and S a n g e r s

next year, capable of sequencing a

It will use a radiolabelling strategy,

dideoxy termination

technique.

With

such

technology available, the notion of sequencing the entire human genome no longer seems so far-fetched. The mechanism of DNA strand-breakage by piperidine at N-7alkylated guanine sites as used in the original version of MaxamGilbert sequencing has been investigated, the authors concluding that

their

observations supported

proposed by Maxam and Gilbert.293

the

mechanism

originally

Alkaline hydrolysis of the

y-

alkylated guanine affords the formamidopyrimidine (175), and opening of t h e sugar ring with displacement of the base residue then generates (176).

Piperidine-catalysed 6-elimination then

expels 5'- and 3'-phosphate

termini,

leaving (177).

alkali effected the ring-opening t o give ( 1 7 5 1 ,

Aqueous

but did not break

the p h o s p h o d i e s t e r b a c k b o n e , a n d w h i l e N - m e t h y l p i p e r i d i n e

6: Nucleotides and Nucleic Acids

253

y o

0

0 II

HO*/ C H N

II

--%-" 7irpal 0

-O

- O - ~ - o y -0 I

0

I

I

0-P-0-

O=P-OO-

O%.

O 2

I

I

(175)

( 176)

HO OH

T

H

H,C

O

I

= C-

1 CH=CH -CH=N

(177)

I

0

"NF s -0 - IIP - 0 ( 17- mcr- 5' 1 I

0

-0

(178)

H

I

d R i b- 5'-

ppp

0 11

(179)

0 II

HO

0 =p-o-

I

OR'

o=p-oI OR'

O=P-OO-

I

'3

254

Organc~phosphorusChemislry

catalyzed

strand

bieakaqe

dpurinic

a t

sites,

could

i t

not

s u b s t i t u t e for p i p e r i d i n e i n forming ( 1 7 6 ) .

An

improved

protocol

has

been

given

one-1 a n e

the'

for

s e q u e n c ? a n d l y s i s 2 Y 4 of oligodeoxyrihonucleotidcs r e p o r t c 3 d l a y t year.25

I n a v a r i a n t o f t h e d i d e o x y s e q u e n c i n c 7 t e c h n i q u e , the'

duplex DNA t o b e s e q u e n c e d l e a v e a 3 -0vcrhancj d

15

u i t

w i t h a r e s t r i c t i o n cnLynir’ t o

w h i c h i s e x t e n d e d w i t h ‘rDTase a n d dATP t o a d d ‘rhe DNA i s t h e n

s h o r t poly(dA)

cut

with

a

%ccond

r e s t r i c t i o n e n z y m e t o e n s u r e t h a t 5 e q u e n c i n g o c c u r s f r o m o n e vntl T h e s e q u e n c i n g r e a c t i o n is t h e n p r i m e d w i t h a n o l i g o ( d ‘ r )

only. primer

3 -end

which has a t its

to t h e overhang generated

by

d(T16TCGA) f o r _ P _s _t I - g e n e r a t e d performed i n t h e usual enzymatically

way.

generated

a base pair

anchor

complemcntary

t h e f i r s t restrict ion

-

(t,.y.

enzyme'

sites),and dideoxy sequencing is Another

primers

for

improved s t r a t a g e m employs consecutive

dideoxy

DNA

t e r m i n a t o r s e q u e n c i n g : a f t e r u s e o f a u n i v e r s a l p r i m e r t o r on(. r o u n d of

it i s synchronously extended a t

sequenciny,

using Klenow f r a g m e n t t o a p o i n t

d

known r a t f .

d o w n s t r e a m of

immediately

a

r e s t r i c t i o n s i t e p r e s e l e c t e d f r o m t h e s e q u e n c e e s t a b l i s h e d i n thc, i n i t i a l r o u n d of s e q u e n c i n g . 2 9 6 enzyme

then generates short primers

u s e i n t h e n e x t r o u n d of can

Cleavage w i t h the r e s t r i c t i o n

leap-frog

along a

l o n g t r a c t o f DNA.

e l i m i n a t e t h e need f o r subcloning.

s i t e s i n v o l v e s t h e u s e of terminators,*” Minus‘ a n d However,

w i t h homogent,ous

A

Both t h e s e methods

3 -2-methylribonucleotides a s c h a i n

and combines t h e principles of Sanger s also

u t i l i z e s

methylnucleotide-blocked transcription,

tor

m e t h o d of m a p p i n g p r o m o t e r

dideoxy terminator’ techniques it

5 -ends

sequencing, and thus with repetition one

referred

OK

by

as

t h e

a

p r e l u d e

authors

a s

Plus and

sequencing.

DNA

pyrophosphorolysis

t e r m i n i t o

f

of

t o

3

-0-

f u r t h e r

Lock-%tep

transcription.

I n a p r o c e d u r e f o r a u t o m a t e d DNA s e q u e n c i n g w i t h o u t t h e u s e of

radioactivity,

a

17-mer

primer

bearing

a

5’-S-trityl

3-

mercaptopropylphospho t e r m i n u s ( p r e p a r e d u s i n g a r e a g e n t s i m i l a r

255

6: Nucleotides and Nucleic Acids

to ( 1 2 9 ) ) is detritylated with silver nitrate, treated with DTT and condensed with 5-iodoacetamidof luorescein t o give This w a s t h e n used

in

dideoxy

(

178).lY8

sequencing reactivns, the

fluorescent bands in the sequencing gels being excited by laser and

the sequence data read directly into a computer.

'I'he

sensitivity of detection was of the order of attomoles per band. A method

for the direct determination of

the specific

activity of HNA uniformly label led with phosphorus-32 is based on the premise that upon its decay to Sulphur-32, the phosphodicJster bond is broken.299

Analysis of the rate of decay of a full-

length molecule using gel electrophoresis and autoradiography therefore permits the proportion of labelled phosphate residues in the R N A to be determined accurately. In an elegant new method for sequence-specific cleavage of single

stranded

DNA

to

complementarily-addressed

nucleotide

resolution

using

a

reaqent, 5 - [ [ (3-methy1thio)propionyll

aminoj-trans-1-propenyl1dUTP ( 1 7 9 ) has been prepared from 5 - ( 3 aminoallyl )dUTP and t h e NHS ester of 3-methylthiopropionic acid, and incorporated into DNA (opposite a single adenine base in a 3 4 mer

template) using Klenow fragment and a suitable primer.300

Upon treatment of the duplex with cyanogen bromide, work-up using piperidine in Maxam-Gilbert cleavage conditions, and analysis b y gel electrophoresis, t h e original template strand w a s found to have been cleaved regiospecifically at a guanine base residue (one of a run of four) t w o base-pairs to t h e 5'-side of the analogue, the efficiency of complementary strand cleavage being 11%.

The

products f o r m e d w e r e consistent with a mechanism in which the sulphonium species formed using cyanogen bromide alkylates the guanine residue at N-7 with consequent depurination. Site-directed cleavage of RNA has been effected

the use

of complementary chimaeric oligonucleotides, containing blocks of 2 '-deoxyribonucl eot ides a n d 2 '-9- m e t h y 1 r i b o n u c 1 e o t d e s

syn-

thesized using a solid-phase phosphoramidite method, and ribo-

256

Organophosphorus Chemistry

nuclease H.

For instance, when

hybridized with resulted

5 - "PIpACUUACCUG,

mainly

in

cleavage

5 -m(C)d(AGGT)m(AAGU)-3 w a s

treatment with ribonucledse H

between

and

U8

Gq

of

the

oligoribonucleotide, and in general cleavage occurs at a position in t h e oligoribonucleotide corresponding to the 5 -end of an

ol igodeoxyr i bonuc 1 eot ide b 1 oc k strand. 301

in

the c o mp 1 erne nt ar y c h i mae r i c

A deoxyribonucleotide tetramer seems to constitute a

sufficiently short tract for recognition by the enzyme.

The

technique has been tested in longer tracts of RNA, and specific cleavage could be obtained in both stem and loop regions, showing that secondary structure does not preclude its a p p l i ~ a t i o n . ~ ~ ' The observations regarding specificity of cleavage are consistent with t h e finding that a tract of RNA joined at its 3 -end t o a tract

of

DNA

and

hybridised

along

the

entire

length

to

complementary DNA is cleaved specifically in the DNA-RNA hybrid region d o w n as far as the phosphodiester bond at the RNA-DNA Junction by

RNase H ( 7 0 ) from yeast.303

The oligonucleotide

d(GTTCGG), a n analogue of the 1$CG loop of tRNA, has been used as a probe together with RNase H to investigate possible interactions of the T$CG loop w i t h 5s ribosomal RNA and its complexes with protein, by monitoring the cleavage sites produced.304

The use

of o l i g o d e o x y r i b o n u c l e o t i d e s complementary t o fragments of the sequences of inter t eron-Y mRNA and prothymos in a with RNase H ,

has permitted

the

mRNA, together

identification for

mapping

purposes o f specific mRNA species in a bulk population of mRNA, without

requiring the prior

clones.305

i s o l a t i o n of

T h e translation of

mRNA

full-length

DNA

in cell-free protein-

synthesizing systems can be arrested by treatment with oligodeoxyribonucleotides complementary to the mRNA sequence together with RNase H. 3 0 6 Using synthetic single-stranded oligonucleotides containing an E2g R I restriction sequence,

it has been s h o w n that the

restriction

single-stranded

endonuclease

cleaves

DNA

at

the

restriction site at a rate comparable to that at which it cledves double-stranded DNA.3o7

The possibility of intermolecular duplex

6: Nucleotides and Nucleic Acids formation

257

e x c l u d e d by

was

immobilising a

3 -end-lahel led

single-

s t r a n d e d o l i q o n u c l e o t l d e o n c e l l u l o s e u s i n g a m e t h o d s i m i l a r to that

described

r e l e a s e of release

above.L41

the label

was

Treatment

350

with

H I

caused

the

f r o m t h e c e l l u l o s e , a n d a l t h o u q h t h v r a t e of

increased

by

the

presence

of

the

complementary

t h e f o r r n a t l o n of d u p l e x s t r u c t u r e is c l e a r l y n o t a n a

sequence,

p r i o r i r e q u i r e m e n t f o r c l e a v a g e b y t h i s e n d o n u ~ l e a s e . ~ ' ~ '1'4 u.v.-endonuclease double-stranded

has been found t o cleave single-strdndcd with

DNA

equal

specificity

f o r

and

pyrimidine

photodimers, p e r m i t t i n q t h e i r p o s i t i o n s t o b e mapped, and a l s o t h e influence of neighbourinq bases on t h e s u s c e p t i b i l i t y to formation of p h o t o d i m e r s t o b e e v a l u a t e d . 3 0 8

Much a t t e n t i o n i s p r e s e n t l y b e i n g f o c u s s e d o n t h e c l e a v a g e of DNA b y c h e m i c a l a g e n t s .

has been reviewed.309 activated

The c h e m i s t r y o f

C l e a v a g e of

iron-bleomycin

a c t i v a t e d bleomycin

poly[d(A-((Sl-2,-3H]UI

)I

with

affords exclusively tri-tiated trans-

3 ( u r a c i l - l '-yl )propenal i n w h i c h t h e t r i t i u m l a b e l i s c o m p l e t e l y retained.310

of

t h e product

synthesized

w h e n p o l y ( d ( A - { ( R ) - [ 2 , - ~ H ] U )]

In contrast,

t h e u r a c i l propenal

obtained

i s u n l a b e l led.

was e s t a b l i s h e d b y

model

compounds.

If

i s used,

The s t e r e o c h e r n i s t r y

comparison

with

unambiguously

is used

poly[d(A-[ 3,-l80]T) ]

i n s t e a d , and t h e 5'-monophosphate t e r m i n i formed on c h a i n cleavage hydrolysed

using

alkaline

phosphatase

and

t h e

resulting

3 1 P n.m.r.,

t h e o x y g e n i s o t o p e is f o u n d

to be retained i n t h e orthophosphate,

i n d i c a t i n g t h a t C(3')-0 bond

o r t h o p h o s p h a t e e x a m i n e d by

cleavage occurs.

When D N A ,

p o l y ( d ( A - T ) ] o r d(CGCGCG) is c l e a v e d

with a c t i v a t e d iron-bleomycin

i n s o l u t i o n s s a t u r a t e d w i t h 1802,

and g l y c o l i c a c i d is r e l e a s e d from t h e 3'-phosphoglycolate formed

on

chain

phosphatase,

breakage

silylated,

and

using

nuclease

analysed

using

P1

and

g.1.c.-m.s.,

f o u n d t o be s i n g l y l a b e l l e d w i t h 180 a t t h e C-1 p o s i t i o n , l a b e l a t C-2.311

A pulse-chase

t h a t t h e atom of o x y g e n - 1 8 a c t i o n of resolved

iron-bleomycin

termini

alkaline

experiment with

it

1602 e s t a b l i s h e d

w a s i n t r o d u c e d as a e r i a l oxygen.

and oxygen

into t w o kinetic events,

i n

cleaving

however

:

is

with no

DNA

has

The be'en

strand scission,

258

Organophosphorus Chemistry

monitored viscometrical ly and

f 1 uorimetrical l y ,

precedes the

release o f base propenals f r o m DNA, indicating that a moderately

stable intermediate must be formed.312 tritium from the ( K ) - [ L * - 3 H ]

In addition, the loss of

position of tritiated I)NA

occurs

concomitantly with strand scission, indicating that t h e base propenal precursor retains the bond between the sugar remnant and the 3 ’-phosphate.

A1 1 these observations are accommodated

postulated mechanism

(

Scheme 3 ) .

the

in

Abstraction of hydroqen from

C-4

’

followed by reaction with aerial oxygen and acquisition of a hydrogen atom yields the 4‘-hydroperoxide (180). A Cricgee-type rearrangement then generates (181) which undergoes stereospecific __ anti-elimination

lost also.

o f t h e phosphoglycolate terminus, with H R being

Possibly a specifically-positioned base which is part

of the bleomycin-DNA complex mediates this process.

The long-

lived intermediate is postulated to be (182), breaking down slowly to give the base propenal (183) and a 5’-phosphate terminus.

It

is w o r t h n o t i n g t h a t C r i e g e e - t y p e r e a r r a n g e m e n t o f a 4 ’ -

hydroperoxy nucleoside has been shown to afford stereospecifically the trans base propenal, in support o f this mechanism.313 .alkali-labile product

An

which accompanies the release of cytosine

during t h e degradation by iron-bleomycin of d(CGCGCG) has been isolated, reduced w i t h borohydride, and degraded w i t h nucleases

and alkaline phosphatase to give p e n t a n e - l , 2 , 3 , 5 - t r ? t r a 0 1 . ~ ~ ~ The products observed support tne proposed alternative pathway of degradation by bleomycin 4‘

:

abstraction of a hydrogen atom from C -

leads instead to the 2’-deoxy-4’-hydroxycytidine species (184)

which loses the base t o give t h e alkali-labile product (185).

A

study of the degradation of d(CGCT3A3GCG) by iron-bleomycin in the presence of reducing agents s u c h a s ascorbic acid has s h o w n that under these conditions, bleomycin acts catalytically to cleave the 0 1 i g o m e r . ~ ~ W~h i l e t h e s p e c i f i c i t y o f c l e a v a g e f o r d ( G p C ) sequences was maintained, modification of the bleomycin structure caused

changes

in

positional

selectivity

in

the

duplex.

Metalloporphyrins linked t o intercalating moieties (acridine, 9 -

amino-7-methylimidazo[4,5-f I q u i n ~ l i n e , ~ o~ r~

2

-am i no-6 -

methyldipyrido[ 1,2-a:3 ‘ , 2 , - d ] i m i d a z ~ l e ) have ~ ~ ~ been synthesized

6: Nucleotides and Nucleic Acids

259

0

0

I

/

-' 0

II RO-P-0

o=p-o-

I

0 II

OR' (18L) +HZO

t

0

0

- H20

I

O=P-OO-

I

o=p-oI

(185)

I

OR

OR

0

4

0

II

: It

Ro--0- O

l

e

o

A 2

Ro

0

-O

t

-

7

.

RO-

H

I

-0

+

( 1 88)

I

II

P-OH

o=p-o-

I

OR' (1871

R'O

I -o-p=o

(190) (Complex from R ~ - [ ~ - ' ' O ]A D P )

(189)

0

HO

cm

(1911

llo

im

(192)

260 as

Organophosphorus Chemisrp functional

a n a l o g u e s of

species g a v e u n i f o r m with

apparent

pro penal^,^^^

base-

formationof o t h e r s

The

5’-terminal

of

DNA,

no

base

sequence

a n d 3 ‘-non-phosphatt.

of

activity

1 ,lC>-phenanthroline-copper

hydrogen peroxide i n d i c a t e t h a t

t o 3 -phosphornonoester

methylene-2g-furanone t h a t a b s t r a c t i o n of

lon

Studies on t h e oxidation

j1

p ~ l y [ d ( A - T ) ] ~a~n ’d d ( C G C G A A T T C G C G ) 3 2 0 b y

precursor

but

s i m i l a r

these

of

l7

nuclease

presence of

s o m e

cleavaqe

phosphates

showed

w i t h 5‘-phosphate

[ (OP2)Cu+] h a s a l s o b e e n rc’viewed.

of

While

sequence-neutral

reportedly

specificity to bleomycin, termini produced.

bleornycin.

and

termini

t h i s agent

i n

the

a

fol lowing cleavage,

i s f o r m e d , d n d t h a t 5-

(186) is an end-product.

It

is be1 ieved

w h i c h is l o c a t e d

a h y d r o g e n a t o m f r o m C-1

in

t h e m i n o r g r o o v e o f D N A , f o l l o w e d b y o x i d a t i o n w i t h 1 0 5 s of b d % ( ’ generates

(1871, a f t e r

elimination

affords

phosphomonoester pathway, leading

3 -phosphate

t h e

precursor

to

although an a l t e r n a t i v e pathway v

to

phosphoglycolate

groove

and

intact

termini

by 6 thc

-

3 -

may

s oxidation a l s o

c)ccur.

a t C-4 Since

is observed f o r (OP)2Cu+, it must bind i n t h e

recognize

conformational

of

variability.

DNA c l e a v a g e by

c e l l s appear generally

in vitro studies, -__

(186) and

seems t o b e t h e p r i n c i p a l

This

c h a r a c t e r i s t i c s and mechanism in

loss o f

the

terminus.

sequence-specificity minor

which

(1881,

similar

with the exception that

a l d e h y d e t e r m i n i a n d more 5 - p h o s p h a t e

The

neocarLinostatin

to those observed i n fewer

nucleoside

5 -

t e r m i n i a r e formed i n vivo

than i n vitro.321

Chiral

recognition,

l i k e sequence recognition,

a f t e r p r o p e r t y i n DNA c l e a v a g e a g e n t s , 1 , 1 0 - p h e n a n t h r o l i n e ) c o b a 1t ( I I1 ) agent,

1s

a

and

A-tris(4,7-diphenyl-

p h ot oa ct

i

v a b 1e

c 1e a v a g e

s h o w i n g s p e c i f i c c l e a v a g e of D N A a t s i t e s w h i c h a r e t h o u g h t

to have a left-hand h e l i c a l conformation.322 genome o f appear,

is a sought-

simian virus (SV)40,

intriguingly,

c o n t r o l of

When a p p l i e d t o t h e

t h e s e g m e n t s c l e a v e d by t h i s a g e n t

t o c o r r e l a t e w i t h r e g i o n s i m p o r t a n t for t h e

gene expression.

Bi s(n e t r o p s i n ) s u c c i n a m i d e c o n ] u q a t e d

6: Nudeorides and Nuc.leic Acids

26 1 c - h i r a l r e c o g n i t i o n oj r i y i i t -

w i t h EDTA s h o w 5 s e q u e n c e - s p e c i f i c -

c l e a v e d i n t h e presenctl o f

h a n d e d d o u b l e h c > l i c a l DNA,

which

FeLt

Two a n a l o g u e s , ( L S , j S ) - a n d ( L R , j H ) -

i o n s , o x y g e n a n d DTT.

15

dihydroxybis(netropsin)succinamide h a v e b e e n c o n s t r u c t e d , a n d wt1c.n c o v a l e n t l y b o n d e d t o EDTA a t o n e e n d t h e y b i n d t o d n d c l e a v e t h e , same

cumulative

A-T

base

r u n s as

pair

the

structural

c-ompound,

p a r t i c u l a r l y f o r the

although t h e binding efficiency is decreased, ( ~ ~ , 3 ~ ) - i s o m e r . ~ X -' R~a y

parent

analysis

of

quinoxaline

a n t i b i o t i c - oligodeoxyribonucleotide c o m p l e x e s h a s ~ h o w nt h a t H o o g s t e e n b a s e p a i r s o c c u r f l a n k i n g t h e p o i n t s of t h e quinoxaline been

bis intercalators,

found t o show

hyperreactivity

diethyl pyrocarbonate,

Hoogsteen

sequencing of

N-7

for Hoogsteen

required It

i n t e r c a l a t i o n by

b a s e p a i r 5 h a v e now

the

to

d u e t o e x p o s u r e of

i n t h e --conformation handed he1 ices.jL4 pyrocarbonate

and t h e s e

reagent

t h e p u r ~ n eb a s e s pairing

in

right-

has t h e r e f o r e been suggested t h a t d i e t h y l

may p r o v i d e a s e n s i t i v e p r o b e f o r t h e p r e s e n c e o f

pairs

i n

solution.

Tracts

of

alternating

d(A-T),

-

sequence c o n t i g u o u s t o DNA o f e f f e c t i v e l y random s e q u e n c e h a v e been

found

to

be

to

hyperreactive

osmium

tetroxide,

anothpr

reagent which can b e used

f o r sequencing, and a l s o p r e f e r e n t i a l l y

cleaved

nuclease

by

micrococcal

alternating tract.325

uniformly

throughout

t h e

The a l t e r n a t i n g sequence i s thought t o

ddopt a c h a r a c t e r i s t i c c o n f o r m a t i o n s u b l e c t t o e a s y t o r s i o n a l deformation.

'Footprinting use

of

h a s become a widely-used

e s t a b l i s h e d

r e a g e n t s

investigations is not

considered

f o r

technique, and t h e

r o u t i n e

f o o t p r i n t i n g

i n t h i s report.

The u s e ot

hydroxyl r a d i c a l s , generated from hydrogen peroxide using a n ironEDTA c o m p l e x i n t h e p r e s e n c e o f s o d i u m a s c o r b a t e ,

for footprinting

r e p r e s e n t s a n i n n o v a t i o n w h i c h may f i n d w i d e a p p l i c a t i o n . 3 1 6

DNA

was c l e a v e d w i t h v i r t u a l l y n o s e q u e n c e d e p e n d e n c e , a n d h y d r o x y l radical

footprintlng

f o o t p r i n t i n g methods.

revealed

or

Co3+

not

detected

Cationic metalloporphyrins

much a t t e n t i o n a s DNA-cleavage Fe3+,

contacts

complexes

of

agents,

by

are a t t r a c t i n g

and incubatlon of

meno-tetrakis

other

Mn3+,

(N-methyl-4-

262

Organophosphorus Chemistp

pyridiniumyl Iporphine w i t h D N A i n t h e p r e s e n c e of a.,corhat(>, superoxide, o r iodosobenzene results in strand cleavage at s l t e s The resultant cleavage. patterns

of minimum structure (AT)3.327

on sequencinq gels are asymmetric, indicating that binding and strand scission are highly directional.

Methylpyrroporphin X X I

ethyl ester has been linked % a 6-aminohexan-1-01 spacer to the 3 -terminus of d(Tp), or t o the 5-terminus of d [ p ( T ~ ) ~in ] the

final stages of phosphotriester synthesis

:

the latter compound

also bore an acridine ring linked at the 3 -terminus.3L*

In the

presence of iron ions, oxygen and a reducing agent, both compounds cleaved poly(dA) and poly(A),

but not poly(dT),

the reaction

yields being higher at lower temperatures where the duplexes were stable.

T h e acridine derivative w a s less efficient at low

temperature but maintained its ability t o cleave D N A to high temperatures, d u e t o extra stabilization by intercalation. N , !

The

-dimethyl-2,7-diazapyrenium cation has been reported to effect

efficient

single-strand nicking

double-stranded DNA

of

upon

irradiation with visible light in the presence of oxygen. 3 L 9 A

transcription

assay

giving

data

on

the

sequence

specificity a n d k i n e t i c s of d r u g - D N A i n t e r a c t i o n s o f f e r s a valuable alternative to footprinting : blockage of transcription occurs when a drug is bound t o its target site, and thus the rate

of chain g r o w t h past the binding

site measures the rate of

dissociation of the drug from the site.330

Electrophoresis of

the RNA transcripts on denaturing polyacrylamide gels thus reveals the sites of drug binding and the dissociation rate. The

self-splicing

reaction

RNA(pre-rRNA) of Tetrahymena have attention.

of

the

i m m a t u r e ribosomal

continued t o c o m m a n d

much

In this reaction guanosine or a guanosine nucleotide

attacks a p h o s p h o d i e s t e r b o n d a t t h e 3’-end o f t h e 5 ’ - e x o n ( sequence

- - CpUpCpUpCpUpA - - - ) cleaving t h e UpA bond (the

5’-

splice site) t o leave a 3’-terminal uridine and the guanosine

cofactor attached to the 5‘-terminus of a n intervening sequence (IVS)-3 ’-exon intermediate.

The 3’-OH

of the 3‘-terminal uridine

6: Nucleotides and Nucleic Acids

263

then performs transesterification at a G p u sequence (the 3 -splice site) to join the 5 5 -(p)GpA

-

-

-

and 3 -cxons and leave the I V S with sequence

- G414-3

-

.

L -Deoxyguanosine

and

,3

dideoxyyuanosinr klave been s h o w n t o inhibit competitively the self-splicing reactiun,

the kinetic data indicatiny

that the

ribose hydroxy-groups a r e necessary for optima 1 bindiny to the i s necessary

pre-rKNA, and that tht. 2 - O H

for thp reaction.'jl

Both nucleosides ctlso suppressed reactivity at the 3 -5plice site

which i s v e r y l a b i l e t o s i t e - s p e c i f i c h y d r o l y s i s . 3 3 2 previously postulated

~ ' h r x

IVS-3 -exon intermediate has been irolated

and characteriLed, and found to be competent to undergo the second stage of the splicing reaction.332t333. of

the

The hlgh susceptibility

3 -splice site t o hydrolysis permits

molecule

c o n t a i ~ i n g the

terminating

at

a

5 -exon

guanosine

still

isolation of

linked

residue.

to

the

'This c a n

IVS,

undergo

cyclisation at the normal 5 -splice site, as well as at the normal self-cyclisation site of the IVS sequence, which is a l s o located

at t h e end of a n o l i g o ( p y r i r n i d i n e ) s e q u e n c e .

It has thus b e e n

proposed that both reactions occur at the s a m e active site which binds by hybridization the oligo(pyrimidine) sequence

for attack

by the 3 -terminal quanosine or an added guanosine n u c l ~ o t i d e . ~ ~ ~ Oxidation of the 3 -terminal quanosine with periodate or tht. addition of periodate-oxidised guanosine both promote the cleavage reaction at the

5 - s p l i c e site, but

without cyclisation,

or

covalent attachment of the oxidised guanosine to the I V S . ~ ~ The ~ cis-diol of an intact ribose moiety is thus not essential for the __ catalysis of

hydrolysis,

although

t h e i n t e r v e n t i o n of

an

intermediate s u c h a s ( 1 8 9 ) c o u l d not b e e x c l u d e d , a n d w o u l d account for t h e observations made. splice

site

is

recognized

T h e proposal that the 5 -

base-pairing

of

the

oligo

(pyrimidine) sequence immediately upstream of t h e site t o a n

internal 5 -exon-binding site in the I V S i s supported by the finding that

if

the pre-mRNA is incubated w i t h C p U o r pCpU (but

not other pNpU species), t h e RNA

is

cleaved precisely at the 3

-

splice s i t e with attachment of the dinucleotide at the 5 -end of the 3 -exon.3J5

T h e dinucleotide, having the sequence o f the

264

Organophosphorus Chemistry

last t w o residues of the 5 -exon, binds and is ligated in its place.

Moreover, a truncated IVS lacking the first 21 residues

and also the last 5 of its normal preautocyclizatlon sequence h a s been shown to catalyse the reaction pCpUpN + G

pCpU + G p N

reversibly ( N

=

A,C,U,G).336

This represents a mini-exon

ligation r e a c t i o n , w i t h p C p U a c t i n g a s t h e 5 ’ - e x o n a n d t h e phosphodiester bond o f GpN as the 3 - s p l i c e site.

T h e reverse

process represents the first stage of the self-spl icing reaction. Comparable reactivity has been

demonstrated

in a n even more

heavily truncated core of the I V S , 3 3 7 and it will be interesting to see what the catalytically competent minimum looks like!

The

L-19 IVS (missing the first 19 residues of the 5‘-end of the IVS), previously found t o have poly(C) polymerase activity a s reported last year,25 performs a similar reaction t o the above, cleaving

HNA at sequences resembling the 5’-splice site o f pre-rRNA (i.e. after ... CpUpCpU) w i t h

t h e a d d i t i o n of

quanosine

residue

nucleotide

generated.338

to

the

a

new

free guanosine or 5’-terminus thus

In t h i s s e n s e , it a c t s like a restriction

endonuclease for RNA and, moreover, site-specific mutagenesis of the ‘guide sequence’ (which binds the recognition sequence) can be performed t o alter the restriction site specificity predictably.

When L-19 IVS is incubated with oligocytidylate bearing a 3’-

terminal phosphate, it becomes bound to the ’guide sequence’ with transfer of the phosphoryl group to the terminal quanosine of the IVS, the pH-dependence indicating greatest activity with the monoanion of t h e p h o s p h a t e m ~ n o e s t e r . ~ ~ ’T h i s p h o s p h o r y l transfer

is

reversible.

In

the

presence

of

other

oligo(pyrimidines) such a s UpCpU which can bind t o t h e guide sequence, phosphoryl transfer can occur t o the 3‘-OH group, and thus the L - 1 9

I V S can act a s a phosphotransferase, transferring

the 3*-terminal phosphate from oligo(cytidy1ate) t o U p C p U with multiple turnover.

At acidic pH ( 4 - 5 ) t h e phosphorylated L-19

IVS undergoes s l o w hydrolysis to give orthophosphate, thus acting

6: Nucleotides and Nucleic Acids

265

as a n a c i d phosphatase.

What more c a n i t d o ? !

p o l y m e r a s e a c t i v i t y o f L-19 the

possibility

of

a

The o b s e r v e d RNA

IVS h a s p r o m o t e d C e c h t o s p e c u l a t e o n

'ribozyme'

with

similar

activlty

but

dependent o n a n e x t e r n a l t e m p l a t e and a b l e t o i n c o r p o r a t e a l l f o u r ribonucleotides,

and possibly a b l e t o s e l f - r e p l i c a t e ,

have b e e n i m p o r t a n t

in prebiotic

which could

nucleic acid replication.340

Another e n t e r t a i n i n g speculation has argued t h a t hot-water s p r i n g s would

present

the

m o s t

likely

scenario

for

such

prebiotic

e v e n t s . 341

The

of

splicing

involves

nuclear

the formation of

a t which 2'-5'-,

,

3,-5'-

mRNA

precursors

in

eukaryotes

' l a r i a t RNA', p o s s e s s i n g a branch s i t e phosphodiester bonds are a l l

and 5'-3.-

a t t a c h e d t o t h e same n u c l e o s i d e

residue,

a n d i s m e d i a t e d by

a

multicomponent c o m p l e x w h i c h h a s b e e n t e r m e d a ' s p l i c e o s o m e ' . 3 4 2 Studies of

the

in vitro splicing

a r a b b i t g l o b i n pre-mRNA

of

intron w i t h base changes a t t h e normal

branch-point

adenosine

n u c l e o t i d e h a v e shown t h a t w h i l e a l l f o u r n u c l e o t i d e s c a n b e used

as b r a n c h a c c e p t o r s , to

uridine

and

adenosine and c y t i d i n e residues a r e preferred

g ~ a n o s i n e . ~ R ~ e~p l a c e m e n t

adenosine

of

by

guanosine or u r i d i n e c a n r e s u l t i n a d i f f e r e n t a d e n o s i n e r e s i d u e O n l y when a d e n o s i n e o r c y t i d i n e

being used a s branch a c c e p t o r .

formed t h e b r a n c h p o i n t s c o u l d t h e s e c o n d s p l i c i n g s t e p ( r e l e a s e

of

t h e 3'-exon

from

the tail

of

the

l a r i a t ) occur.

o b s e r v a t i o n s h a v e b e e n m a d e i n c o m p a r a b l e s t u d i e s of

Similar

the splicing

of a d e n o v i r u s pre-mRNA. 3 4 4 A self-splicing

i n t r o n of p r o k a r y o t i c o r i g i n h a s been found

i n t h e p r i m a r y t r a n s c r i p t f r o m t h e t h y m i d y l a t e s y n t h e t a s e g e n e of bacteriophage

T4,

and

shows

resemblance t o i n t r o n s o f However,

strong

structural

t h e Tetrahymena t y p e

and (

functional

-Class I

t h e f i n a l c y c l i s a t i o n . p r o c e s s of t h e i n t r o n i n v o l v e s loss

o f GpU f r o m t h e 5 , - e n d ,

r a t h e r t h a n a 15-mer as w i t h Tetrahymena.

I n a d i f f e r e n t t y p e of

cleavage and

ligation process,

RNA

c o m p l e m e n t a r y t o s a t e l l i t e RNA o f t o b a c c o r i n g s p o t v i r u s h a s b e e n found

t o

cleave

autolytically

at

a

specific

-ApG-

sequence,

Organophosphorus Chemistry

266 apparently

to

generate

f r a g m e n t s with

a d e n o s i n e - 2 , 3 -cycl ic

phosphate and 5 -quanosine termini, which after purit ication can 1 igate spontant,ously to reyenerate the A p G phosphodiester bond.

Another

RNA

molecule

with

catalytic actlvity

hds

tlceen

reported : 2.5s RNA, t h e nucleic a c i d c o m p o n e n t o f 1,4-n-ylucan branching e n z y m e f r o m rabbit m u s c l e , cdtalyses the branching reaction in the absence of the protein component.347

Partial

digestion w i t h pancreatic K N a s e afforded a large guanine-rich double-stranded

f ra g m e n t

which

reaction, albeit at a much

al s o

catalysed

s l o w e r rate.

component of RNase P from Bacillus subti% found markedly different f r o m that

the

branchinq

T h e catalytic H N A has been s e q u e n c d and

of RNase

P f r o m E.5011,

although phylogenetically consistent folding for portions of both molecules cculd be derived. 348 On incubation of 32P-label led oligo(dA) w i t h E . c o l & type I DNA topoisomerase, the enzyme becomes covalently linked sv

a 5

-

phosphate t o a n oliyo(dA) s e g m e n t , and t h e labelled sc.yment c a n then be transferred t o the 3 -OH t e r m i n u s of a linear o r nicked duplex DNA molecule subsequently added to the reaction mixturf a 3 the phosphodiester bond i s re-made.349

T h i s suggest5 that the

covalent p r o t e i n - D N A c o m p l e x o b s e r v e d p r e v i o u s l y i s a t r u e intermediate i n the topoisomerisation reaction. 5.5

Metal Complexes -

Observation

of

coupling b e t w e e n the Mn2+ ion and " O a t o m s

the superhyperfine bound t o phosphorus a s

a means of identifying oxygen ligands in metal-nucleotide-protein complexes has been r e v i e w e d 3 5 C dnd used t o d e m o n s t r a t e that in three Ha-L"-encoded

p21 proteins, bound M n 2 + ions a r e directly

coordinated t o the PB oxygen a t o m s of bound [ 6 - 1 7 0 4 ] G D P but not t o

the P a oxygen a t o m s of ( -P R 1 or ( S P ) - [ a - 1 7 0 ] G C P or la-170~]GDP.3s1 A similar study using pyruvate kinase in the presence of oxalate as a s u r r o g a t e f o r pyruvate

indicated that bound M n 2 + w a s

coordinated t o P y - o x y g e n o f A T P , b u t n c t t o Pa atorrs. 352

cr Pa

oxygen

6: Nudeorides and Nucleic Acids The

267

,P - b i d e n t d t e t e t r a a q u o r h o d l u m

11

( 1 1I ) c o m p l e x e 5 o f Rill'

and (Rp)-[~-180]ADP have been prepared as exchange-inc,rt of

t h e corresponding

separated

by

Mg2+ c o i i i p l e x e s ,

reverse-phase

h.p.l.c.,

ana1oyuc.s

t h e screw s e n s r i 5 c ) m ~ r s and

the

s t r r ec c . h c . m i 5 t r y

a s s i g n e d o n t h e b a s i s of t h e 1 8 0 - i 5 u t o p i c s h i f t s o f t h e P , - s i g n a l 5 in

the

31P

n-m-r.

k i n a s e bound t h e A

spectra.353

Rrginine

kinase

and

cre'dt

1

nc'

screw s e n s e i ~ o m e r ( 1 9 0 ) more t i g h t l y t h a n t h v

b

isomer, w i t h c o m p a r a b l e b i n d i n g a f f i n i t i e s t o t h o s e s h o w n f o r

t h e c o r r e s p o n d i n g C r ( H 2 0 I 4 A D P s c r e w sense i s o m e r s .

The quenching

o f t h e l u m i n e s c e n c e of E u 3 + b o u n d t o a C a 2 + - b i n d i n g s i t e of

+ Mg'+)-ATPase

of

(Cd"

s a r c o p l a s m i c r e t i c u l u m by t h e s u b s t i t u t i o n - i n e r t

b i d e n t a t e C r ( I I 1 ) - A T P c o m p l e x b o u n d a t t h e ATP h y d r o l y t i c s i t < ' h a s been u s e d t o e s t i m a t e a n upper l i m i t t o t h e distanc-e between t h e

two

metal

formycin-5

ions.354

of t h e plasma

fluorescence complex

The

(111) complexes

terbium

of

ATP

and

- t r i p h o s p h a t e a r e i n e r t t o h y d r o l y s i s b y t h e H+-ATPase

upon

Schizosaccharomyces pmb_e,

membrane of

the

e n h a n c e m e n t of binding

to

t h e

formycin

active

and t h c

triphosphate-Tb( I 11)

site

has

been

used

t o

c h a r a c t e r i z e t h e binding site.355

An i n v e s t i g a t i o n b y F T - 1 . r .

spectroscopy indicates that i n

t h e p r e s e n c e o f Mg2+ i o n s , t h e p h o s p h a t e g r o u p o f GMP a s s u m e s a n

almost g a u c h e - g a u c h e

conformation,

while

t h e hydrated

magnesium

i o n i s c o o r d i n a t e d d i r e c t l y t o N-7 o f t h e base a n d i n d i r e c t l y t o O6

of

t h e base a n d p h o s p h a t e oxygen v i a hydrogen-bonded

molecules.356 that

Co2+

Data f r o m 31P a n d 'H

ions bind

t o AMP

to

spectroscopy suggest

form at

least t w o different

complexes which are i n temperature-dependent there

is direct

coordination

water

n.m.r.

t o N-7

of

equilibrium : i n one, adenine and

indirect

coordination t o phosphate, and i n t h e o t h e r t h i s arrangement is reversed.3s7

A

similar s i t u a t i o n of

sphere cobalt-phosphate complexes,

inner-sphere

and outer-

c o m p l e x a t i o n seems t o e x i s t i n

cobalt-CMP

Vanadocene d i c h l o r i d e ,

an antiturnour agent, i n t e r a c t s

s e l e c t i v e l y w i t h t h e p h o s p h a t e moieties o f n u c l e o t i d e s a s r e v e a l e d by

the

shortening

of

31P

nuclear

relaxatlon

times.358

The

268

Organophosphorus Chemistry

temperature dependence o f the relaxation rates suggest l a b 1 I P outer-sphere complexation.

T h e stability data for complexes of

divalent metal ions with ATP, together with results from 'H n.m.r. and

U.V.

investigations, suggest that t w o types of back-bound

macrochelates a r e formed coordination

and

coordination.359

:

o n e (1911 with inner-sphere N-7-metal

( 1 9 2 ) with

one

outer-sphere N-7-metal

Due to the metal back-binding to the base

residue the stabilities of the [M.ATPI2- complexes are generally greater than those for complexes of the s a m e metal w i t h CTP, UTP or dTTP.

While Mg2+ ions show little tendency to form these N-7

coordinated macrochelates (a small proportion of type (192)), cu2+ ions s h o w a strong tendency t o form macrochelates of type ( 1 91 ) , and Mn2+ ions form a small proportion of each type, the remainder being 'open

chelates.

The extent of macrochelate formation for

divalent metal complexes of 1 ,y6-etheno-ATP is greater than that for the corresponding

[ M.ATPI2-

complexes.360

A

number

of

complexes f o r m e d between divalent metal ions and ATP at pH 3.5 and pH 7 . 2 have been isolated and studied by FT-i.r. spectroscopy and other

methods,

and

it a p p e a r s t h a t m e t a l

exclusively through a , fi and

Y

binding

occurs

-phosphate oxygen a t o m s when N - 1

of

adenine is p r ~ t o n a t e d . ~ In ~ ~ the complexes formed by ADP and ATP

with molybdenum ( V I ) oxoactions in acidic solutions, complexation occurs predominantly through the phosphate groups.362

N.m.r.

spectroscopic investigations of the c o m p l e x formed by M g L t ions with A(5 )p4A suggest that the metal ion coordinates to the phosphates t o stabilise a ring-stacked conformation.363

B-

With

co3+ ions, t w o different bidentate complexes are formed, one coordinating to the B -phosphates t o stabilise the ring stacking and the other to adjacent a - and B-phosphates to destabilise it. Chiral metal complexes which bind stereoselectively to lefthanded

helical

conformations

have

been

reviewed.364

Tris(tetramethylphenanthro1ine) ruthenium ( 1 1 ) has been found t o

bind selectively t o A-form helices (such a s poly(rG).poly(dC) rather than B-form helices (such as poly[ d(G-C)]) with preference for t h e A-enantiomer, and o n irradiation with visible light it

6: Nucleorides and Nucleic Acids

269

s e n s i t i s e s s i n g l e t oxygen t o c l e a v e t h e n u c l e i c acid.365

I t may

t h u s p r o v e v a l u a b l e f o r d e t e c t i n g A-form s e c o n d a r y s t r u c t u r e i n The

DNA.

substitution-inert

t r 1 s ( b 1p y r i d y 1 ) F c ( I I

enantloselectively

a nd

)

tr

1

i n v e r s i o n - l a b i Le

s ( p h e n a n iz h r o 1 i n e ) F e

comp1t.xes (

I 1)

b

i

nd

t o DNA by m a i n l y e l e c t r o s t a t i c a s s o c i a t i o n ,

l e a d i n g t o a n e x c e s s of t h e A-enantiomer

The c o m p l e x e s f o r m e d by

cis-

a s s h o w n by C D . 3 6 6

and trans-dichlorodiammino-

p l a t i n u m ( 1 1 ) (DDP) a n d r e l a t e d c o m p o u n d s w i t h n u c l e o t i d e s h a v e been i n v e s t i g a t e d .

T h e r e a c t i o n s o f AMP, ADP a n d ATP w i t h

cis-

but disagreements are evident

DDP f o l l o w b i p h a s i c

t o t h e mode o f b i n d i n g o f t h e p l a t i n u m t o t h e n u c l e o t i d e s .

as 1t

a p p e a r s t h a t d i m e r i c c o m p l e x e s of g e n e r a l f o r m u l a P t L 2 ( 5 ’ - A M P ) 2

(L = monoamine l i g a n d ) a r e f o r m e d a t n e u t r a l i t y , wit.h c o o r d i n a t i o n of t h e p l a t i n u m a t o m t o N-7 o f t h e a d e n i n e r i n g , a n d r e s t r i c t e d

rotation h a s been observed about t h i s bond, bulky.368

N o

such

restricted

e v e n when L i s n o t

r o t a t i o n is observed

c o r r e s p o n d i n g GMP c o m p o u n d s u n l e s s L i s b u l k y , s u g g e s t e d t h a t t h e s e l e c t i v i t y of have a s t e r i c o r i g i n .

i n

the

and it has been

DDP f o r g u a n i n e r e s i d u e s m a y

I n t h e c o r r e s p o n d i n g ATP c o m p l e x e s , FT-

i . r . d a t a have been i n t e r p r e t e d as i n d i c a t i n g f u r t h e r c o o r d i n a t i o n at

N-1

of

the

purine

ring.361

Others

have

postulated

that

l i g a t i o n b y t h e p h o s p h a t e c h a i n o c c u r s , 3 6 7 b u t pKa a n d o t h e r d a t a have b e e n i n v o k e d t o a r g u e t h a t h y d r o g e n - b o n d i n g t h e aminated ligand and t h e phosphate group, p l a t i n u m d o e s n o t occur.368 platinum by

N-7

occurs between

and t h a t

ligation to

Convincing evidence f o r c h e l a t i o n of

and t h e phosphate group has,

however,

been

o b t a i n e d f o r s o m e m o n o m e r i c c o m p l e x e s o f t h e t y p e P t L 2 ( 5 >-NMP) c o n t a i n i n g IMP o r GMP, b u t t h e i r m o d e o f f o r m a t i o n a n d i n s t a b i l i t y render

t h e i r wider

significance unlikely.369

I n An

v i t r o

c o m p e t i t i o n e x p e r i m e n t s , D N A r e a c t s more r a p i d l y w i t h DDP t h a n

does A ( 5 ’ ) p 4 A , a n d t h e c o m p l e x e s f o r m e d a r e s t a b l e , a n d d o n o t exchange

platinum.370

However,

the platinum

complex

of

the

proposed p l e i o t y p i c a c t i v a t o r i s s t a b l e t o h y d r o l y s i s , and c o u l d accumulate i n cells during cancer chemotherapy w i t h e - D D P .

270

Organophosphorus Chemistry Trans-DDP reacts with d(GpTpG) in a similar fashion to c s ___

DDP with the platinum atom becoming ligated by N-7 o f both guanine basc>s.371

Since thc-.~trans-isomer has little a n t i n ~ o p l a s t i c _ _ _ _

activity, the crucial lesions formed in DNA a r e thought t o be those in which the platinum is coordinated to contiguous G - G o r A G bases.

Cis-DDP has

resulting

G ( 4 ) - G ( 51 c h e l a t e

sequence.j7*

been reacted

with d(ECGGATCGC), and the

a n n e a led

M e l t i n g and 'H

n.rn.r.

to

the

complementary

studies indicated that

platination h a d destabilized the duplex, introducing a kink in the structure.

T h e sequence d(TCTAGGCCTTCT) has been pl atinated

similarly, phosphorylated with polynucleotide kinase, and ligated into gapped heteroduplex DNA to produce site-specif ic platination in the M13 genome.373

The platinated duplex was not cleaved by a

restriction e n z y m e (St!

I ) which normally recognizes the non-

platinated guanines as part of its restriction sequence. Investigation of the reaction of and c&-[C12enlPt(lI DNA

Cis- and

trans-DDP,3 7 4 , 3 7 5

)376 (which reacts similarly to cis-DDP) with

indicate that a transient monofunctional platinum-DNA adduct

is formed initially, and the kinetics suggest that m o r e than o n e primary adduct is formed.374 trapped with thiourea.376

The monofunctional adducts can be Otherwise, they form bifunctional

adducts, the second chlorine atom being lost by

hydrolysis374r375

before t h e crosslinking reaction ( w h i c h c a n a l s o be to exogenous guanosine375 o r i n t e r c a l a t i n g a g e n t s 3 7 7 ) t a k e s place. frequency of

occurrence of

G-G-adducts

The

is inconsistent with

reaction by random initial reaction a t any guanine base followed by c r o s s l i n k i n g t o t h e n e i g h b o u r i n g b a s e , a n d i t h a s b e e n suggested that the adducts finally observed result from t h e drug 'walking' along t h e double helix.376

_Cis_ and trans-DDP depart

from a c o m m o n reaction path after formation of the monodentate

adduct. 3 7 4

Evidence has been obtained, using a f ootpr inting

approach, that the gold antitumour compound the N-7 position of guanine bases in DNA.378

Et3PAuBr3 binds to

6: Nuclrotides and Nucleic Acids

6

27 1

Analytical Techniques and Physical Methods The r e s o l u t i o n of n u c l e i c a c i d s by

reviewed. 379

h.p.1.c.

has been

High-performance charge transfer chromatography,

employing acriflavin o r proflavin coupled by a

linker to the

silica stationary phase, i s reported t o give good separation of oligonucleotides up to 17 residues long,380 and the use of reverse phase

ion

pair

chromatography,

tetrabutylammonium

particularly

using

phosphate as ion-pair reagent, has been found

superior t o conventional reverse-phase h.p.1.c.

for separating

01 igodeoxyribonucleotides. 381 31P N.m.r. spectroscopic studies of mononucleotides have included determination of the pKa value of l-(3-phospho-a-D-

ribofuranosyl)-5,6-dimethylbenzimidazole

from the nucleotide group

cf c o b a l a m i n ~ ,investigation ~~~ of the effects of monovalent cations o n t h e s e l f - a s s o c i a t i o n o f C M P a n d G M P i n a q u e o u s solution,383

and

the

measurement

of

rate constants

thermodynamic p a r a m e t e r s f o r t h e f o r m a t i o n complexes with p21 and adenylate kinase.384 31P n.m.r.

and

of nucleotidic Comparison of the

saturation transfer technique w i t h a radioisotope

tracer method for the measurements of ATP-phosphocreatine exchange catalysed by creatine kinase has s h o w n that both methods give similar

results except

phosphocreatine may change

-

31P

:

at

low

temperatures or

at

high

creatine ratios, when the rate-determining step

N.m.r.

data

for

deoxyribonucleoside phosphates dimenzional n.m.r.

protected have

been

deoxycytidylyl-

tabulated. 3 8 6

Two-

methods for determining nucleic acid structure

have b e e n d e s c r i b e d 3 8 7 a n d a p p l i e d t o s e l f - c o m p l e m e n t a r y o l i c ~ o d e o x y r i b o n u c l e o t i d e sand ~ ~ ~ poly [ d(G-m5C) 1 . 3 8 9

of

n.m.r.

and

d(GGAATTCC)

U.V.

with

Comparison

data for the self-complementary the

5’-end,

the

3’-end, and

sequence

both

ends

phosphorylated s h o w s that while 3 ’-phosphorylation has little

272

Organophosphorus Chemistry

effect, 5 -phosphorylation cases a small change in phc3sphodiestc.r torsion a n g l e s t o i m p r o v e b a s e formation.390

31P N.m.r.

has

stacking and also

been

favour hellx

used

monitor

to

conformational changes in the RNA fragment r(CGm5CGCG),391 and in DNA during the B-to-A transition,392 upon base protonatlon,393 upon the binding

of cationlc porphyrins,394 and

upon

inter-

calation by p r o p i d i u n ~ . ~ The ~ ~ binding of actlnomycin D to GC sequences i n d ( T G C G C A ) 3 9 6 a n d of a c l a c i n o m y c i n A a t t h e T A sequence in d(CCTAGG)397 have also been investigated.

While

studies of nucleotide compartmentation and metabolism in whole tissue are omitted in this report, a review covering the use of 3 1 p n.m.r. spectroscopy in the understanding of disease"*

demands

mention. Fast a t o m bombardment (FAB)-m.s. in the negative ion mode has been used for t h e characterization and sequencing of short oligonucleotides399 although it has been stated that n o direct way exists o f determining the direction of a small oligonucleotide sequence

by

this

te~hnique.~"

However,

in

studies

of

dinucleotides it has been reported that during metastable ion decomposition or collisionally-activated decomposition species, the base

is eliminated

of ( M - H ) -

preferentially from the 3 ' -

terminus, a1 lowing isomeric dinucleotides to be di~tinguished.~'~ The presence of a base such as DBN to abstract dissociable protons enhances the molecular ion intensity.402

FAB-m.s. has also been

used t o determine the positions of l 8 O a t o m s in isotopically labelled nucleotides t o monitor isotopic scrambling in exchange

reactions. 4 0 3

It has been proposed o n t h e basis, mainly, of X-ray data, that transitions between B-, A- and Z- conformations in DNA a r e essentially d i c t a t e d by phosphate groups.404

t h e e c o n o m i c s of hydration of the

In B-DNA, under conditions of high water

activity, the phosphate groups are

>,

0

6 A apart and are individually

hydrated, but addition of water o r organic solvents lowers the activity of water, promoting the A- and Z-forms in which the

6: Nucleatides and Nucleic Acids

273

phosphate groups are closer and bridged by water molecules, thus making for more economical hydration.

Studies on poly[d(A-T)] in

the presence of Cs’ ions, in w h i c h transitions between B -

and C-

(alternating pnosphodiester geometry with a dinucleotidc repeat unit) forms were monitored by i.r. absorption and linear dichro15n1 ds

a function of hydration405 and comparable studifls on poly[d(Gprovide evidence of changes i n phosphate geometry with

changing hydration and salt content.

While X - r a y diffraction

studies are normally omitted from this Report, the determination of the structure of the DNA-Ecg R 1

endonuclease rpcogniticln

complex

mention

at

3;

resolution407 merits

as

an

Lmportant

milestone in the study of DNA-protein interactions. Alternating field gel electrophoresis is a valuable means of separating large

DNA molecules, and techniques employing f i e l d unidirectional pulsed f ~ e l d , ~ and ” modifications

inversion,4 0 8 a

of orthogonal field alternation410 have been described. Electroporation

- t h e use of a high voltage electric

discharge - can render cell membranes permeable to nucleotides and has been

used t o introduce gra-CTP into leukaemia cells.411

While s o m e cells were lysed by the pulse, most remained viable. Nucleic acids have been introduced into epidermal cell s of onion by

firing them

diameter!412

in a d s o r b e d

upon

tungsten

‘bullets

o f 4~

Viral and plasmid DNA introduced in this way w a s

subsequently expressed genetically.

DNA binds strongly t o the

surfaces of micelles and vesicles coated with lipopolyamines and l i p ~ i n t e r c a l a n t s ,and ~ ~ ~ its incorporation into 1 ipid vesicles

formed by sonication is greatly enhanced by the presence of excess

of a basic protein ( l y s o ~ y m e ) ~ ’ ~ .This effect could have been

important for the formation of primordial cells during evolution. The orientation of DNA molecules

has been monitored by

labelling one terminus with biotin-dUTP, binding the labelled DNA to avidin-ferritin, and imaging the resultant complex by electron microscopy.

Knowing “which end is which“ permits precise mapping

Organophosphorus Chemistry

274

a n d q u a n t i f i c a t i o n o f s i t e s o f DNA s e c o n d a r y s t r u c t u r e o r p r o t e i n DNA i n t e r a c t i o n . 4 1 5

References

1 2

3 4 5

6 7 8 9 10 11

12 13 14 15 16 17 18 19

20 21 22 23 24

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2,

276 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87

Organophosphorus Chemistry A. A m e s 1 1 1 , T . F W a l s e t h , R . A . Heyman, M. Barad, H.M. G r a e f f , a n d N . D . G o l d b e r g , J . B i o l . C h e m . , 1 9 8 6 , 261, 1 3 0 3 4 . P.A. C o n n e l l y , L.H.P. B o t e l h c , R.B. S i s k , a n d J . C . G a r r i s o n , J. B i o l . C h e m . , 1 9 8 7 , 262, 4 3 2 4 . C.J. D r a g l a n d - M e s e r v e , M.C. 0 1 i v e i r i , a n d L . H . P . B o t e l h o , Biochem.J., 1 9 8 6 , 237, 4 6 3 . M.E. P e r e i r a , D . L . S e g a l o f f , M . A s c o l i , a n d F . E c k s t e i n , 3. B i o l . C h-e m . , 1 9 8 7 ,~262, 6 0 9 3 .~ _ V.J. D a v i s s o n , D.R. D a v i s , V.M. D i x i t , a n d C.D. P o u l t e r , J- O r g . C h e m . , 1 9 8 7 , 52, 1 7 9 4 . K.E. Ng a n d L . E . O r g e l , N U C l e i c A c i d s R e s . , 1 9 8 7 , 1 5 , 3 5 7 3 . M.W. H o s s e i n i , J.-M. L e h n , L. M a g g i o r a , K.B. M e r t e s , a n d M.P. Mertes, J . Am. Chem. S O C . , 1 9 8 7 , 109, 5 3 7 . G.M. B l a c k b u r n , G . R . J . T h a t c h e r , M.W. H o s s e i n i , and J.-M. L e h n , T e t r a h e d r o n L e t t . , 1 9 8 7 , 2,2 7 7 9 . J . F . M a r e c e k a n d C . J . B u r r o w s , T e t r a h e d r o n L e t t . , 1 9 8 6 , iz, 5943. E. Gajewski, D.K. S t e c k l e r , a n d R.N. Goldberg, 3. B i o l . C h e m . , 1 9 8 6 , 261, 1 2 7 3 3 . G.A. S c a r b o r o u g h , ? r o c . N a t l . A c a d . S c i . USA, 1 9 8 6 , f33, 3688. I . C l e m e n t a n d V. R u b i o , A r c h . B i o c h e m . B i o g h y s . , 1 9 8 6 , 251, 465. T.D. M e e k , W.E. K a r s e n , a n d C.W. d e B r o s s e , B i o c h e m i s t r y - , 1987, 26, 2584. W. v o n - ; i e r S a a l a n d J.J. V i l l a f r a n c a , B i o o r q . Chern., 1 9 8 6 , 1 4 . 28. K.K. S h u k l a , H.M. L e v y , F. H a m i r e z , a n d J . F . M a r e c e k , ~. J . B i o l . C h e m . , 1 9 8 6 1 261, 1 2 1 4 1 . J.J. S i n e s a n d D.D. Hackney, B i o c h e m i s t r y , 1986, 25, 6144. R.S. Goody a n d M . I s a k o v , T e t r a h e d r o n L e t t . , 1 9 8 6 7 2 7 , 3599. T . L . C h a p m a n , T.B. S h u l l , a n d F.M. R a u s h e l , B i o c h e m i s t r y , 1986, 25, 4739. J . E . V F n P e l t , R . I y e n g a r , a n d P.?.. F r e y , J . B i o l . C h e m . , 1 9 8 6 , 261, 1 5 9 9 5 . A.D. G r i f f i t h s , B.V.L. P o t t e r , and I.C. Eperon, N u c l e i c A c i d s R e s . , 1 9 8 7 , 15, 4 1 4 5 . A. A r a b s h a h i , R.S. B r o d y , A. S m a l l w o o d , T.-C. T s a i , a n d P.A. F r e y , B i o c h e m i s t r y , 1 9 8 6 , 25, 5 5 8 3 . R.C. B e t h e l 1 a n d G . L o w e , J. Chem. SOC. Chem. Commun., 1 9 8 6 , 1341. B . L . S t i t t a n d M . R . Webb, J . B i o l . C h e m . , 1 9 8 6 , 261, 1 5 9 0 6 . R. I y e n g a r , E. C a r d e m i l , a n d P.A. F r e y , B i o c h e m i s t r y , 1 9 8 6 , 25 , 4693. J . M . K o n o p k a , H.A. L a r d y , a n d P.A. F r e y , B i o c h e q L s t r y , 1 9 8 6 , 25, 5571. T . S h i m i z u a n d K . F u r u s a w a , B i o c h e m i s t r y , 1 9 8 6 , 2,5 7 8 7 . M.R. M e j i l l a n o a n d R.H. H i m e s , Biochem. B i o p h y ~ - R e s . Commun., 1 9 8 6 , 1 3 9 , 9 6 7 . D.C. Speckhard7V.L. P e c o r a r o , W.B. K n i g h t , a n d W.W. C l e l a n d , J- Am. Chem. S O C . , 1 9 8 6 , 108, 4 1 6 7 . H. Pauls, E.H. S e r p e r s u , U. K i r c h , a n d W. Schoner, -E u r . J . B i o c h e m . , 1 9 8 6 , 157, 5 8 5 . K.J. G r u y s , P.R. G r e g o r y and S.M. S c h u s t e r , J. I n o r g . Biochem., 1986, 28, 67. K . J . G r u y s a n d S.M. S c h u s t e r , J. I n o r g . B i o c h e m . , 1 9 8 6 , 22, 75. H . I d e , R.I. M e l a m e d e , a n d S.S. Wallace, B i o c h e m i s t r y , 1 9 8 7 , 26, 964. P.S. Nelson, C. Bahl, and I. Gibbons, Nucleosidgs N u c l e o t i d e s , 1986, 5 , 233.

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89 90 91 92

93 94

95

96 97 98 99

100 101

102

103

104

105 106 107 108 109

110 111 112

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144,

138,

XL,

261, 261,

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278 11 3 114 115 116 117 118 119

12 0 121 122

123 124 125

126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141

Organophosphorus Chemistry H o n g , S.-H. A n , D . J . B u c h h e i t , A. Nechaev, A.J. K i r i s i t s , C . K . west a n d W.E. B e r d e l , &-_Med. C h c m . , I ' j 8 6 , 2 2 , 2038. J.P. C o l e m a n , W.B. w h i t e , B. E g e s t a d , J . S J o v d l l , a n d P.B. Hylemon, J,-Biol. C h c m . , 1 0 8 7 , 262, 4 7 0 1 . T . B . J o h n s o n a n d J . K . C o w a r d , J. O r g . C h e m . , 1 9 8 7 , 52, 1 7 7 1 . E. S o n v e a u x , B i o o r g . C k m . , 1 9 8 6 , 274. N.T. T h u o n q a n d U. A s s e l i n e , --B i o -__ chem-i e , 1 Y 8 5 , 6.2, 6 7 3 ; s e e a l s o IJ. A s s e l i n e , N.T. T h u o n g , a n d C . H e l k n e , N u c l e o s i d e s ________ Nucleotides, 1986, 5 , 45. H . S e l i q e r , Chem. S c r . , 1 9 8 6 , 2 6 , 5 6 1 , 5 6 9 . B.C. F r o e h l e r , P.G. N q , a n d M X . ~ a t t e u c c i , ~ u c l e i cp r & d s R e s , 1986, 1 4 , 5399. E. G a r e g T , I . L i n d h , T . R e q b e r y , J . S t a w i n s k i , R . S t r B m b e r g a n d C. H e n r i c h s o n , T e t r a h e d r o n & g t t . , 1 9 8 6 , 22, 4051. P . J . G a r e g g , T . R e g b e r g , J . S t a w i n s k i , a n d H. S t r B m h e r q , ____-J . Chem. S O C . , P e r k i n T r a n s . I . , 1 9 8 7 , 1 2 6 9 . P.J. Garegq, I Lindh, T. Reqberq, J. S t a w i n s k i , H. S t r B m b c r q , a n d C. H e n r i c h s o n , T e t r a h e d r o n L e t t . , 1 9 8 6 , 27, 4055. J. N i e l s e n , J.E. Maruqq, J.H. v a n B o o m , J. H o n n e n s , M . T a a q a a r d , a n d 0 . D a h l , J . Chem. R e s . , S y n o p 2 1986, 26. J . N i e l s e n a n d 0. D a h l , N u c l e i c Acids R e s . , 1987, 3626. J. N i e l s e n , J . E . M a r u g g , M . T a a q a a r d , J . H . v a n B o o m , a n d 0. Dahl, Reel. T r a v . C h i m . P a y s - B a s . , 1986, 33; J. Nielsen, M. T a a q a r d , J.E. Marugg, J.H. v a n B o o m , a n d 0. Dahl, Nucleic Acids R e s . , 1986, 7391. J.E. M a r u g q , J . N i e l s e n , 0. D a h l , A. B u r i k , G . A . van der Marel, a n d J . H . v a n Boom, Reel. T r a v . C h i m , P a y s - B a s . , 1987, ___ 106, 72. N u-c.-l -e-i -c A c-i __ d s Hes., B.H. D a h l , J . N i e l s e n , a n d 0. D a h l , _1987, 15, 1729. Y. H a y a k a w a , M . U c h i y a m a , a n d R . N o y o r i , T e t r a h e d r o n L e t t . , 1986, 27, 4191, 4195. A. Wulter, J. B i c r n a t , a n d H. Koester, N u c l e o s i d e s N u c l e o t i d e s , 1986, 5 , 65. K. Miura, K. S a w a d a i s h i , H. Inoue, a n d E. O h t s u k a , Chem. P h a r m . B u l l . , 1 9 8 7 , 3 5 , 8 3 3 . S. I w a i , A . I m u r a , Y . I n o u e , H . I n o u e , K . M i u r a , T . T o k u m a q a , M . I k e h a r a , a n d E. O h t s u k a , C h e m . P h a r m . B U L L . , 1 9 8 6 , 34, 4 7 2 4 . M. I k e h a r a , K . F u j i m o t o , Y . A o y a m a , K . Y a n a s e , J . M a t s u q i , T. I n a o k a , T . T o k u n a q a , S. U e s u g i , S. I w a i , a n d E. O h t s u k a , Chem. P h a r m . B u l l . , 1 9 8 6 , 34, 2 2 0 2 . J. M a t s u z a k i , H . Hotoda, M. S e k i n e , a n d T. H a t a , T e t r a h e d r o n L e t t . , 1 9 8 6 , 27, 5 6 4 5 . H. Hotoda, T. Wada, M. S e k i n e , a n d T. H a t a , Tetrahedron L e t t . , 1987, 28, 1681. K . G . D e v i n e a n d C.B. Reeye, T e t r a h e d r o n L e t t . , 1 9 8 6 , 27, 5529. B.J. H a m i l l a n d D.J. P i c k e n , W o r l d B i o t e c h . Rep., 1 9 8 5 , 7 3 5 ( C h e m . A b s . , 1 9 8 6 , 105, 1 7 2 8 5 7 ) V . A . E f i n o v a n d O.G. C h a k h m a k h c h e v a , E L o o r g . K h i m . , 1 9 8 5 , 11, 1 0 8 7 ( C h e m . A b s . , 1 9 8 6 , 105, 6 7 4 4 ) . V . A . E f i m o v , A.A. B u r y a k o v a , I . Y . D u b e y , N . N . P o l u s h i n , O . G . C h a k h m a k h c h e v a , a n d Yu.A. O v c h i n n i k o v , N u c l e i c A c i d s R e s . , 1986, 1 4 , 6525. M. S e k i n e a n d T. H a t a , Y u k i Gos~;~~Kga~;ajku K y o k a i s h i , 1 9 8 6 , 4 4 , 2 2 9 ( C h e m . A b s . , 1 9 8 6 , 105, M . S e k i n e a n d T. Hata, J . Or Chem., 1 9 8 7 , 5 2 , 946 H. T a n i m u r a , M . S e k i n e , a n d g T . H a t a , T e t r a h y d r o n , 1 9 8 6 , 42, 4 1 7 9 . C.1.

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6: Nuckeoridus and Nur-leic Acids

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379

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14,

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198 199 200

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211 212 213 214 215 216 217 218

219 220 221 222 223 224 225 226 227 228 229 230 231

28 1

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iz,

I _ _ -

2 36 2 37

238

239 240 241 242 243 244 245 246 247 248 249 250 251 2 52 253

254 255 256 257

258 259

14,

14,

Xl,

Xl,

2l5,

s,

6: Nucleotides und Nucleic Acids 260

261 262 263 264 265 266 267 268 269 270

27 1 272 273 274 275 276 277 278 279 28 0 281 282 283 284 285 286 287 288 289 290 291 292

2 83

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J.

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2,

163,

Lo?,

Organophosphorus Chemistry

2 84 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 3 10 31 1 312 31 3 314

315 316 317 318 319 32 0 321 322 323 324 325

s., 868,

W - B . M a t t e s , J.A. H a r t l e y , a n d K.W. Kohn, ~ i o c h & p~ , i o p h y 1986, 71. B . J . B . A m b r o s e , M . M . C a s t r o , a n d R.C. P l e s s , !pal. ~iochem., 1 9 8 6 , !I, 2 4 . n a l . Biochem., R.L. S t a l l a r d , U . C e r t a , a n d W . B a n n w a r t - h , A --- - -- - .. 1 9 8 7 , Jl?, 1 9 7 . M. S p e e k , H . I l v e s , a n d A . L i n d , A n a l . B i o c h e ; . , 1986, 158, 242. G . A . K a s s a v e t i s , P.G. Z e n t n e r , a n d E . P . G e i d u s c h e k , J . Blol. 1986, 14256. W. A n s o r q e , B. S p r o a t , J . S t e g e m a n n , c. S c h w a g e r , a n d M. Zenke, N u c l e i c - A c i d s H e s . , 1987, 4593. D . M . M u e l l e r a n d G.S. G e t z , A n a l . B i o c h e m . , 1 9 8 7 , 521. B.L. l v e r s o n a n d P.B. D e r v a n , J . A m . C h e m . S O C . , 1 9 8 7 , 109, 1241. H . I n o u e , Y . H a y a s e , S . I w a i , a n d E. O h t s u k a , F E B S L e y t , , 1987, 327. S. S h i b a h a r a , S. M u k a i , T. N i s h i h a r a , H . I n o u e , E. O h t s u k a , a n d H. M o r i s a w a , N u c l e i c Acids R e s . , 1987, 4403. R. K a r w a n a n d U. W i n t e r s b e r q e r , FEBS L e t t . , 1 9 8 6 , 206, 1 8 9 . S. L O r e n Z , R . K . H a r t m a n n , N . P i e l , N. U l b r i c h , a n d V.A. Erdmann, E u r . J. B i o c h e m . , 1 9 8 7 , 1 6 3 , 239. S.L. B e r q e r , A n a l . B i o c h e m . , 1 9 8 7 T - m , 2 7 2 . J . M i n s h u l l a n d T. H u n t , N u c l e i c A c i d s R e s . , 1986, 14, 6433. N . B i s c h o f b e r g e r , P.G. N g , T.R. W e b b , a n d M . D . Matteucci, Nucleic Acids Res., 1987, 709. W. S a u e r b i e r , B i o c h e m . B i o p h y s . R e s . Commun., 1986, 204. 383. S.M. H e c h t , A c c . Chem. R e s . , 1 9 8 6 , S. A j m e r a , J . C . Wu, L. W o r t h J r . , L.E. R a b o w , J . S t u b b e , a n d J.W. K o z a r i c h , B i o c h e m i s t r y , 1986, 25, 6586. G.H. McGall, L.E. Rabow, J . S t u b c e , a n d J.W. K o z a r i c h , J . A m . Chem. S O C . , 1 9 8 7 , 1 0 9 , 2 8 3 6 . R.M. B u r g e r , S.J. ProjanT-S-B. Horwitz, and J. Peisach, J . B i o l . C h e m . , 1 9 8 6 , 261, 1 5 9 5 5 . I . S a i t o , T. M o r i i , a n d T. M a t s u u r a , J. O r g . _ C_ h e_m _., 1 9 8 7 , 52, 1008. L. R a b o w , J. S t u b b e , J . W . Kozarich, and J.A. G e r l t , J . Am. Chem. S O C . , 1 9 8 6 , 7130. H . S u q i y a m a , R.E. K i l k u s k i e , L.-H. C h a n g , L.-T. M a , S.M. H e c h t , G.A. v a n d e r M a r e l , a n d J . H . v a n B o o m , J . A m . C h e m . Soc., 1986, 3852. J.W. L o w n , S.M. S o n d h i , C.-W. O n g , A. S k o r o b o g a t y , H. K i s h i k a w a , a n d J.C. D a b r o w i a k , B i o c h e m i s t r y , 1 9 8 6 , 5111. Y. Hashimoto, H. Iijima, Y. Nozaki, a n d K. Shudo, B i o c h e m i s t r y , 1 9 8 6 , 25, 5 1 0 3 . D . S . S i q m a n , A c c . Chem. R e s . , 1 9 8 6 , 180. 1 9 8 7 , Lgz, T . E . G o y n e a n d D.S. S i q m a n , J . A m . C h e m . SOC., 2846. M. K u w a b a r a , C. Y o o n , T . G o y n e , T . T h e d e r a h n , a n d D . S . S i g m a n , B i o c h e m i s t r y , 1 9 8 6 , 25, 7 4 0 1 . L.S. Kappen, T.E. E l l e n b e r q e r , and I.H. Goldberq, Biochernistr , 1987, 26, 384. M U l l e Z , A.L. Raphael, and J.K. Barton, Proc. N a t l . B.C. Acad. S c i USA, 1 9 8 7 , 1764. J.H. G r i f f i n a n d P.B. D e r v a n , J . A m . C h e m . S O C . , 1 9 8 6 , 5008. D. M e n d e l a n d P.B. D e r v a n , P r o c . N a t l . Acad. S c i . USA, 1 9 8 7 , 84, 910. J.A. McClellan, E. P a l e c e k , a n d D.M.J. L i l l e y , Nucleic Acids Res., 1986, 9291.

m.,

261,

15,

215,

162,

15,

15,

141,

19,

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108,

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6: Nucleotides and N u d e i c .4cids 3 26 327 328 329 330 331 332 333 334 335 3 36 3 37 338 339 340 341 342 343 344 345 346 347 348 349 350 351 352 353 354 355 356 357 358 395 36 0 361

285

T u l l i u s a n d B.A. D o m b r o w s k i , P r o c . N a t l . A c a d . Stir 1986, 83, 5469. B. W a r d , A . - C k o r o b o g a t y , a n d J.C. D a b r o w i a k , ~ -i o c-hem -istry, 1986, 25, 6 8 7 5 . T. L e D o a n , L . P e r r o u a u l t , C . H e l e n e , M . C h a s s l g n o l , a n d N.T. T h u o n g , B i o c h e m i s t r y , 1 9 8 6 , 2 5 , 6 7 3 6 . A.J. B l a c k e r , J. J a z w i n s k i , T . - M T L e h n . a n d F.X. W l l h c l m . J . Chem. S O C . , Chem. Commun., 1 9 8 6 , 1 0 3 5 . D . R . P h i l l i p s a n d D.M. C r o t h c r s , B ' g g h e m i s t r y , 1 9 8 6 , 2>, 7355. B.L. B a s s a n d T.R. C e c h , B-_i o c -_ h em-i_s tr y , 1 9 8 6 , 25, 4 4 1 3 . I . I n o u e , F.X. S u l l i v a n , a n d T.R. C e c h , J . M o l . B i o l . , 1 9 8 6 , __ 189, 143. K.-P. Kister a n d W.A. E c k e r t , N u c l e i c A c i d s E.,1 9 8 7 , 1 5 , 1905. P . S . K a y a n d T . I n o u e , N ~ ~ A~c i d gs Res., ~ c 1987, 15, 1559. G. G a r r i g a , A.M. Lambowitz, T.I. Inoue, a n d T.R. Ccch, N a t u r e ( L o n d o n ) , 1 9 8 6 , 322, 8 6 . P . S . K a y a n d T. I n o u e , N a t u r e ( L o n d o n ) , 1 9 8 7 , >&?, 3 4 3 . J . W . S z o s t a k , N a t u r e ( L o n d o n ) , 1 9 8 6 , E, 8 3 . A . J . Z a u g , M . D . B e e n , a n d T.K. C e c h , N a t u r e ( L o n d n J , 1986, 324, 4 2 9 . A . J . Z a u g a n d T.R. C e c h , B i o c h e m i s t r y , 1 9 8 6 , 25, 4 4 7 8 . T.R. C e c h , P r o c . N a t l . A c a d . S c i . US&, 1 9 8 6 , 83, 4 3 6 0 . E . G . N i s b e t , N a t u r e ( L o n d o n ) , 1 9 8 6 , 322, 2 0 6 . P . A . S h a r p , S c i e n c e , 1 9 8 7 , 235, 7 6 6 . H . H o r n i g , M . A e b i , a n d C. W e i s s m a n n , N a t u r e ( L o n d o n ) , 1 9 8 6 , 324, 589. G.A. F r e y e r , J. A r e n a s , K.K. P e r k i n s , H.M. F u r n e a u x , L. Pick, B. Young, R . J . Roberts, a n d J. H u r w i t ~ , J . B i o l . Chem., 1 9 8 7 , 262, 4 2 6 7 . F.K. C h u , G.F. M a l e y , a n d F . M a l e y , B i o c h e m i s t r y , 1 9 8 7 , 26, 3050. J.M. B u z a y a n , W.L. G e r l a c h , a n d G. B r u e n i n g , N a t u r e ( L o n d o n ) , 1 9 8 6 , 322, 3 4 9 ; J . M . B u z a y a n , A . H a m p e l , a n d G . B r u e n i n g , N u c l e i c A c i d s R e s . , 1 9 8 6 , 14, 9 7 2 9 . T.A. S h v e d o v a , G . A . K o r n e e v a , V.A. O t r o s h c h e n k o , a n d T.V. Venkstern, Nucleic Acids Res., 1987, 1745. C. R e i c h , K . J . G a r d i n e r , G . J . O l s e n , B. P a c e , T.L. M a r s h , a n d N . R . P a c e , J. B i o l . C h e m . , 1 9 8 6 , 261, 7 8 8 8 . Y.-C. T s e - D i n h , J . B i o l . C h e m . , 1 9 8 6 , 261, 1 0 9 3 1 . H.R. K a l b i t z e r , i n 'Metal I o n s i n B i o l o g i c a l S y s t e m s , V o l . 22 ( E d . H. Sigel), D e k k e r , N e w Y o r k , 1 9 8 6 . J. F e u e r s t e i n , H . R . K a l b i t z e r , J . J o h n , R.S. G o o d y , a n d A . W i t t i n g h o f e r , E u r . J . B i o c h e m . , 1 9 8 7 , 162, 4 9 . D.T. L o d a t o a n d G . H . R e e d , B i o c h e m i s t r y , 1 9 8 7 , 26, 2 2 4 3 . A.L. S h o r t e r . T . P . H a r o m v , T. S c a l z o - B r u s h , W.B. K n i q h t , D. Dunaway-Mariano, a n d M . S u n d a r a l i n g a m , B i o c h e m i s t r y ; 1 9 8 7 , 26, 2060. T.P. H e r r m a n n , P. G a n g o l a , a n d A.E. Shamoo, E u r . J . B i o c h e m . , 1 9 8 6 , Yjg, 5 5 5 . M. R o n j a t , J . J . L a c a p e r e , J.-P. D u f o u r , a n d Y . D u p o n t , J . B i o l . C h e m . , 1 9 8 7 , 262, 3 1 4 6 . T. T h e o p h a n i d e s a n d M. P o l i s s i o u , M a n e s i u p , 1 9 8 6 , 5 , 2 2 1 . J . L . L e r o y a n d M . G u e r o n J . A m . C h e m g S o c . , 1 9 8 6 , LlH, 5 7 5 3 . J.H. T o n e y , C.P. B r o c k , a n d T . J . M a r k s , J . A m . C h e m . S O C . , 1 9 8 6 , il3, 7 2 6 3 . H . S i g e l , E u r . J . B i o c h e m . , 1 9 8 7 , 165, 6 5 . H. S i g e l , K . H . S c h e l l e r , V. Scheller-Krattiger, a n d B. P r i j s , J. A m . C h e m -_-_ . S o c . , 1 9 8 6 , Lgg, 4 1 7 1 . H.A. Taimir-Rlahi, M.J. B e r t r a n d , a n d T. Theophanides, C a n . J . C h e m . , 1 9 8 6 , 64, 9 6 0 . T.D.

-_ USA,

15,

Organophosphorus Chemistry

286 362 363 364 365 366 367 368 369 37 0 371 372 373 374 375 376 377 378 379 38 0 381 382 383 384 385 386 387 388

C.F.G.C. G e r a l d c s , M. M a r g a r i d a , a n d C.A. C a s t r o , J. I n o r g . Biochem., 1 9 8 6 , 2 8 , 319. N.H. K o l o d n y a n d L . J . Col-1-ins, J . B i o l . C h e m . , 1 9 8 6 , 251, 14571. J . K . B a r t o n , S c i e n c e , 1986, G , 727. H.-Y. M e i a n d J.K. B a r t o n , __J. Am. C h e m --. S O C . , 1 9 8 6 , 128, 7414. H . H a r d a n d B. NordGn, B i o p o l y m e r s , 1 9 8 6 , 2 5 , 1 2 0 9 . R.N. B o s e , R.D. C o r n e l i u s , and-R.E. V i o l a , J . Am. Chem. S O C . , 1 9 8 6 , Log, 4 4 0 3 . M . D . R e i l y a n d L.G. M a r z i l l i , J. A m . C h e m . S O C . , 1 9 8 6 , 128, 6785. M.D. R e i l y a n d L.G. M a r z i l l i , J . A m . C h e m . Soc., 1 9 8 6 , L O , 8299. A. B a c h m e i e r , G. J u s t , a n d E. H o l l e r , F u r . J. B i o c h e m . , 1986, 621. J.L. v a n d e r Veer, G.J. L i g t v o e t , H . v a n d e n E l s t , a n d J . R e e d i j k , J . A m . C h e m . S O C . , 1 9 8 6 , 1.8, 3 8 6 0 . B. v a n H e m e l r y c k , E. G u i t t e t , G. C h o t t a r d , J . - P . G i r a u l t , F. L a l l e m a n d , J. I g o l e n , a n d J.-C. H e r m a n , T. H u y n h - D i n h , J . - Y . C h o t t a r d , B i o c h e m . B i o p h y s . . R e s . Commun., 1 9 8 6 , 138, 7 5 8 . A.L. P i n t o , L.J N a s e r , J . M . E s s i g m a n n , a n d S.J. L i p p a r d , J . Am. Chem. S O C . , 1 9 8 6 , 7405. W. S c h a l l e r , H. K e i s n e r , a n d E. H o l l e r , B i o c h e m i s t r y , 1 9 8 7 , 26, 943. J.-L. B u t o u r a n d N.P. J o h n s o n , B i o c h e m i s t r y , 1 9 8 6 , 25, 4 5 3 4 . A . E a s t m a n , B i o c h e m i s t r y , 1 9 8 6 , 25, 3 9 1 2 . J.-M. M a l i n g e a n d M. L e n g , P r o c . N a t l . Acad. S c i . USA, 1 9 8 6 , 83, 6317. 9. W a r d a n d J . C . D a b r o w i a k , J . A m . C h e m . S O C . , 1 9 8 7 , 109, 3810. L.W. M c L a u g h l i n , T r e n d s A n a l . C h e m . , 1 9 8 6 , 5 , 2 1 5 . P.A.D. E d w a r d s o n , C.R. Lowe, a n d T . A t k i n s o n , J . C h r o m a t o g r . , 1 9 8 6 , 338, 3 6 3 . K. M a k i n o , H . O z a k i , T. M a t s u m o t o , T . T a k e u c h i , T. F u k u i , a n d H. H a t a n o , N i p p o n K a g a k u - K a i s h i , 1 9 8 6 , 1 0 4 3 ( C h e m . A b s . , 1 9 8 7 , 196, 1 9 6 7 1 9 ) . K.L. B r o w n , J . Am. Chem. S O C . , 1 9 8 7 , 2277. J . A . W a l m s l e y a n d B.L. S a g a n , B i o 01 mers, 1 9 8 6 , 25, 2 1 4 9 . W. K l a u s , I . S c h l i c h t l i n g , R* .yTA. W i t t i n g h o f e r , P. 1 9 8 6 , 367, R d s c h , a n d K.C. Holmes, B i o l . Chem. H o p p e - S e y l e r , 781. V . V . K u p r i y a n o v , N . V . L y u l i n a , A. Ya. S t e i n s c h n e i d e r , M . Yu. Z u e v a a n d V.A. S a k s , FEBS L e t t . , 1 9 8 6 , zgg, 8 9 . L. E r n s t , N u c l e i c A c i d s R e s . , 1 9 8 7 , 361. R . V . H O S U r , C u r r . S c i . , 1 9 8 6 , 55, 5 9 7 . V. S k l e n a r , H . M i y a s h i r o , G. Z o n , H.T. M i l e s , a n d A. B a x , FEBS L e t t . , 1 9 8 6 , Z g g , 9 4 ; A . O t t e r , J.W. L o w n , a n d G . Koty';;ioysgn. ,Reson. C h e m . , 1 9 8 6 , 24, 2 5 1 ; M . D e l e p i e r r e , B. d E s t a i n t o t , J . I g o l e n , a n d B.P. Roques, 1986, 571; S. T a k a h a s h i , N. Eur. J . Biochem., N a g a s h i m a , Y. N i s h i m u r a , a n d M . T s u b o i , C h e m . P h a r m . D u l l . , 1 9 8 6 , 34, 3 9 8 7 . V. S k l e n a r , A. B a x , a n d G. Z o n , J. A m . C h e m . S O C . , 1 9 8 7 , 109, 2221. M. B o w e r , M.F S u m m e r s , B. K e l l , J . H o s k i n s , G . Z o n , a n d W . D . W i l s o n , N u c l e i c Acids R e s . , 1987, 3531. F. C e o l i n , F. B a b i n , T. H u y n h - D i n h , J . I g o l e n , G . B l o c h , S. Tran-Dinh, a n d J.M. N e u m a n n , J. A m . C h e m . S o c . , 1 9 8 7 , LO_), 2539, J. K y p r , V . S k l e n a r , a n d M . V o r l i c k o v a , B i o p o l y m e r s , 1 9 8 6 , 25, 1 8 0 3 . -

151,

122,

109,

15,

lal,

389 39 0 391 392

15,

6: Nucleotides and Nucleic Acids 393 394

395 396 397 398 399

4 00 401 402 403 404 405 40 6 407 408 409 4 10 411

287

D.L. B a n v i l l e , L.G. M a r z i l l i , a n d W.D. W i l s o n , ___ B i o c_ h_ emistry, 1 9 8 6 , 25, 7 3 9 3 . D.L. B a n v i l l e , L.G. M a r z i l l i , <J.A. S t r i c k l a n d , a n d W . D . W i l s o n , H i o p o l y m e r s , 1 9 8 6 , 2 5 , 1 8 3 7 ; L.G. M a r z i l l i , D.1,. Banville,-c. ~ , n ~ - W~. D . ~ W d i i s o n , J. Am. Chem. SOC., 1 9 8 6 , 108, 4188. W.D. W i l s o n , R.L. J o n e s , G . Z o n , D.L. B a n v i l l e , a n d I,.G. M a r z i l l i , B i o p o l y m e r s , 1 9 8 6 , 25, 1 9 9 7 . W.D. W i l s o n , R.L. J o n e s , G . Z o n , E.V. S c o t t , D.L. B a n v i l l e a n d L.G. M a r z i l l i , J . A m . C h e m . S O C . , 1 9 8 6 , _1_gg,7 1 1 3 . S. T a k a h a s h i , N. N a g a s h i m a , Y. N i s h i m u r a , a n d M . Tsuboi, Chem. P h a r m . B u l l . , 1 9 8 6 , 24, 4 4 9 4 . G . K . R a d d a , S c i e n c e , 1 9 8 6 , 233, 6 4 0 . L. G r o t j a h n , S p r i n g e r Proc. Phys., 1986, 9 (Chem. A b s . , 1 9 8 6 , l_O> 2, 2 7 2 1 4 1 7 L.R. P h i l l i p s , K . A . G a l l o , G . Z o n , W . J . S t e c , a n d 8. U z n a n s k i , O r g . M a s s S p e c t r o m . , 1 9 8 5 , 20, 7 8 1 ; F. S o e l e r a n d K . J a n k o w s k i , S p e c t r o s c o p y , 1 9 8 5 , 4, 3 5 . A.M. Hoqq, J.G. K e l l a n d , J.C. Vederas, a n d C. Tamm, H e l v . C h i m . A c t a . , 1 9 8 6 , 63, 9 0 8 . R.L. C e r n y , M.L. G r o s s , a n d I,. G r o t j a h n , A n a l . B i o c h e m . , 1 9 8 6 , 156, 4 2 4 . A. S a n d s t r B m a n d J . C h a t t o p a d h y a y a , J . C h e m . S O C . , C h e m . Commun., 1 9 8 7 , 8 6 2 . D.H. R u s s e l l , A n a l . Chem., L.M. M a l l i s , F.M. R a u s h e l , a n d 1 9 8 7 , 52, 9 8 0 . W. S a e n g e r , W . N . H u n t e r , a n d 0. K e n n a r d , N a t u r e ( L o n d o n ) , 1 9 8 6 , 324, 3 8 5 . S. A d a m , P . B o u r t a y r e , J . L i q u i e r , J . A . ' r a b o u r y , a n d E. T a i l l a n d i e r , B i o p o l mers, 1 9 8 7 , 2 6 , 2 5 1 . P.B. K e l l e r a n d K . A Y H a r t m a n , N u z e i c A c i d s R e s . , 1 9 8 6 , 88167. J . A . M c C l a r i n , C.A. F r e d e r i c k , B.-C. W a n g , P. G r e e n e , H . W . B o y e r , J . G r a b l e , a n d J . M . R o s e n b e r g , _S cie -n. ce, 1 9 8 6 , 234, 1 5 2 6 . H.J.S. Dawkins, D.J. F e r r i e r , a n d T.L. Spencer, N u c l e i c Acids R e s . , 1 9 8 7 , 1 5 , 3634. M u g a v e r o , a n d J. J.C. S u t h e r l a n d , D.C. M o n t e l e o n e , J.H. Trunk, A n a l . B i o c h e m . , 1 9 8 7 , la, 5 1 1 . G . C h u , D. V o l l r a t h , a n d R . W . D a v i s , S c i e n c e , 1 9 8 6 , 224, 1 5 8 2 ; F.D. M c P e e k J r . , J . F . C o y l e - M o r r i s , a n d R.M. G e m m i l l , A n a l . B i o c h e m . , 1 9 8 6 , 156, 2 7 4 . J.A. Sokoloski, M.M. J a s t r e b o f f , J.R. Bertino, A.C. 1 9 8 6 , ISg, S a r t o r e l l i , a n d R. N a r a y a n a n , A n a l . B i o c h e m . ,

14,

272.

412 413 414 415

T.M.

84, B.

K l e i n ,

1978.

Theveny

E.D.

a n d B.

Wolf,

Revet,

R.

Wu,

a n d

N u c l e i c A c i d s Res.,

J.C.

1987,

S a n f o r d ,

15, 9 4 7 .

7

Ylides and Related Compounds BY B. J . WALKER Introduction Although the mechanism of the Wittig reaction continues t o be a topic of wide interest and a number of novel synthetic applications o f ylides have been reported (notably an increasing use o f arsonium ylides) the year has been mainly one of consolidation. 1

2 Methylenephosphoranes Preparation and Structure.- The electronic structures and energies of a number of model fluorine-substituted ylides (e.g. - 1) have been determined from ab initio calculations at the SCF level.’ M.O. calculations of ylide structures are also included in a number of reports dealing mainly with theoretical studies o f reactions of ylides (see section 2.2.1). A study of the kinetic acidity (through H-D exchange) o f a small number of tetraalkylphosphonium salts has been reported. A review of methods of generation o f ylides by desilylation reactions contains some information concerning phosphorus ylides. The previously unknown arenecarbodithioate ylides (2) have been phosphonium ylides ( 3 ) prepared and their reactions ~ t u d i e d . The ~ have been silylated and deprotonated to give the corresponding silylated ylides ( 4 ) .5 Attempts to convert the chlorosilylated ylides (4, R 2 = C 1 ) into the cumulene ylides ( 6 ) by dehydrohalogenation led instead to formation of the cyclic ylides (5) (Scheme 1). the structure of which was confirmed by &-ray analysis in one case. The C-substituted diphosphetes (7) have been synthesised and their chemistry and n.m.r . spectra studied.6 The reaction of tri(4-rnethoxypheny1)phosphine with neo-pentyl iodide gives a mixture o f eight different phosphonium salts, probably via intermediate ylides of the type (81.’ 2.2 Reactions of Methylenephosphoranes -_ 2.2.1 Aldehydes.- A recent ab initio theoretical study compares the reactivity o f the simplest phosphonium and sulphonium ylides towards formaldehyde.8 The calculations predict stability f o r

2.1

oxaphosphetan, but not f o r betaine, intermediates and suggest that the different reactivity of the two types of ylide is due to both kinetic and thermodynamic reasons. An important factor in alkene 288

7: Ylides and Related Compounds

289

S

II

P%P=CHSCAr

Reagents:

I,

1 2 R2R SiCl;

1 1 ,

K H , THF,

111,

ButLi

,

TMEDA

Scheme 1 R*

(7 R

2

= Ph , Me

X 3 P =CH( CHz),CH,

( 9 ) X - Ph (10) X = n-Butyl

290

Organophosphorus Chemistry

H

I

Reagen+s : i , B u L i ; i i , T i ( O P r ' I L ; i l l , R C H O ; t v , M e I

Scheme 2 CH,CH, COO-

I

PhZPcCHR

CHSMe

Reagents : i , ( C F CH 0 ) P ( 0 ) C H M c C 0 2 M e , K H M O S ;

3

2

2

(16)

Scheme 3

,

PhjP=CMeCOZMc

7: Rides and Related Compounds

29 1

formation from the four-membered Cyclic intermediate appears to be

facile exchange of oxygen and carbon between apical and equatorial sites via pseudorotation; this is much more difficult for sulphuranes than for oxaphosphetans. A study of the kinetics and linear free energy relationships of the reaction of semi-stabilized ylides with substituted benzaldehydes has been reported.' The authors conclude that the alkene formation step (rather than oxaphosphetan formation) is most likely to be the rate-determining step. Maryanoff and Reitz have reviewed aspects of their excellent work on the mechanism of the wittig reaction of reactive y1ides.l' They conclude that the increase in (E_)-alkene formed from trialkylphosphonium ylides over that formed from triphenylphosphonium ylides is mostly due t o thermodynamic control (i.e. greater reversibility of oxaphosphetane to ylide and aldehyde in the former case). However, Vedejs has now shown that in some cases (El-alkene can become the kinetically-favoured product. A very extensive kinetic study of the Wittig reaction of benzaldehyde with triphenyl-(9) and tri-n-butyl-(10)-butylidene ylides using 13C, ' H and 31P n.m.r. spectroscopy has provided a detailed picture of the processes involved .I2 These results have confirmed earlier reports that in many cases the relative proportions of cis- and transoxaphosphetans observed at low temperature (where elimination to alkene is precluded) do not correspond to the final proportions of and (El-alkenes obtained. A a'synergistic'teffect between Cisand trans-oxaphosphetans is again proposed to explain increases in the proportions of (E)-alkene. however no suggestion is made as to the nature of this effect. In spite of the care with which these experiments have been designed and carried out. one is tempted to suggest that a s o far unobserved isomerisation mechanism is contributing to the proportions of alkene isomers formed in some cases. Concentration also appears to have a marked effect on the stereochemistry of the Wittig reaction under certain conditions.13 At low concentrations reactions of 1:l y1ide:lithium salt mixtures with aldehydes provide alkene stereochemistries identical to "salt-free" reactions and proportions of (E)-alkene only begin to increase when a certain concentration is exceeded. Although changes in lithium salt-ylide ratios are known to effect stereochemistry. these latest results indicate that many reported variations in stereochemistry in Wittig reactions will have to be reassessed. Methods for controlling stereochemistry in the Wittig reaction

(z)-

continue to be reported,

Reaction of the titanium derivative (11)

292

Reagents:

Organophosphorus Chemistry

i , R 3 S i O T f , P h 3 P ; i i , Bu"Li , T H F , -78 "C THF

,

0

Scheme

Reagents : i

,

;

III,

R C H O ; iv,(Bu"LN+F,-

OC

R3SiOTf

, Ph3P

4

; i i ,BunLi ; iii , 0HC(CH2),-

Scheme 5

C02Me

7: Ylides and Related Compounds

293

OR R’

A

CHO

+

OR

OR

OSi MePh,

OSiMePh2

s y n -(19l

u n t i - (19)

R3

R‘

R3

R3

R2

OSiMcPh,

R2

syn- ( 2 1 1

R ( C H=CN ),CHO n=0,l

Ph

+

AS CH ZCH=CH

unti-(21)

COCH,

Br-

(22)

i

K2C03, Et20

OSiMePh2

,

H20, 0

OC

294

Orgunophosphorus Chemistry

o f allyldiphenylphosphine with aldehydes followed by treatment with

methyl iodide provides a synthesis of 1,3-dienes in high yield and

with high stereoselectivity (Scheme 2) .14 The stereochemistry is explained by an allylic rearrangement a cyclic transition state (12). Replacement o f triphenyl-substituted by diphenyl(2 carboxyethy1)-substituted

phosphorus in Wittig reagents ( 1 3 ) increases ( E ) - selectivity with semistabilized ylides and gives a water soluble phosphine oxide by-product. The authors suggest that either a Schlosser-type equilibration of the isomeric oxaphosphetans takes place (this seems unlikely in view o f the relatively low basicity of the carboxylate anion) or that the mechanism involving C - P bond breaking which has been suggested by Bestmann is responsible. An explanation not considered in that modification of the phosphorus substituents in this way leads to the threo-oxaphosphetane being kinetically-preferred and hence t o enhanced (E)-selectivity. The use of methanol as a solvent for

Wittig reactions o f stabilized ylides in known to increase (Z)-selectivity. It is now reported that highly (z)-stereoselective olefination of carbohydrate-derived alkoxyaldehydes can be achieved under these conditions. l6 The stereochemistry o f Wittig reactions of reactive and semi-stabilized ylides generated using alkali metal carbonates has been investigated. l 7 For reactive ylides in methanol containing small quantities o f water, moderate (E)-selectivity was observed; this selectivity was reversed under anhydrous, aprotic conditions. Both phosphonate and phosphonium salt-based olefinations can be accomplished using ZnO or MgO as the basic catalyst.18 The (z)-(lS) and (E)-(16) alkenes have been prepared

with high stereoselectivity by olefination using the phosphonate (14) and corresponding ylide,respectively (Scheme 3 ) .19 A combination of phosphoniosylation and Wittig reaction has

been developed as a method for $-functionalization of enones (Scheme 4 ) ” and for the synthesis o f trienes (17) useful for the

construction of tricyclic systems through intramolecular Diels/Alder The reactions of a-alkoxyaldehydes with reactions (Scheme 5). the @-silylphosphonium ylide (18) give exclusively the vinylation products (19) with high anti-selectivity. rather than the normal This &-selectivity is also observed for Wittig product.” similar reactions of a,€3-epoxyaldehydes (20) to give (21).23

The synthesis of conjugated dienones using ylide o r phosphonate methods can be difficult. However, the arsonium salt (22) is reportedZ4 to provide a general route to dienones and trienones

7: Hides and Related Compounds

R ( CH =CH

1 CHO

+

Ph

295

A', CH,CON

Br-

R' R 2

(231

K 2 C 4 , THF, H 2 0 , 25

R(CH=CH I,+,CONR' (24)

R~

OC

296

A

[‘

Organophosphorus Chemistry

0

EtOI2PtiPPh.] II

(311

(301

Reagents :

I

, ( E t O 1 2 P ( 0 ) L ~;

11,

R’CHO ;

III

,

BULI ;

IV,

R2CH0

Scheme 6

Reagents : i

,

2 x Base ;

II

, R’CHO

;

III

, RN,

+ -

OMe

Scheme 7

w’

Ph,P

OH

OLi

Me Reagents:

I ,

Ph2PLi ; Me1 ; CHjCOZH

Scheme 8

L I0

7: Ylides and Related Compounds

297

through reaction with the corresponding aldehyde in the presence of

potassium carbonate.

Similarly the arsonium salt (23) can be used

to prepare all (H)-unsaturated amides (24) and this method h a s been applied to the synthesis of a number of natural amides.25 A new route to a number o f polyene systems is provided by the Wittig reaction of (25) with the readily available fumaraldehyde ,

monodimethyl acetal (26). 2 6 The oliyomers (29) have been prepared by wittig reaction of salts (27) with aldehydes ( 2 8 1 . ’ ~ Both

symmetrical and unsymmetrical 1 . 2 - b i s ( y l i d e n e ) c y c l o b u t a n e s (31) have been synthesised by a double olefination o f the [2-(diethoxyphosphinyl)cyclobutylltriphenylphosphonium

ylide ( 3 0 ) (Scheme 6) . 2 8 1,4-disubstituted 1,3-diynes in moderate to excellent yields has been reported.29 Wittig reactions o f the cummulene ylide ( 3 2 ) with aldehydes give cummulenes which are isomerised to the diyne on treatment with quaternary ammonium methoxide (Scheme 7). A wide range of a-hydroxyketones can be dehydroxylated in good yield by reaction with lithium diphenylphosphide followed by treatment with methyl iodide (Scheme 8 ) . 3 0 The ceaction follows a similar route to that of V e d e j s ’ method of oxirane to alkene conversion. 31 Under specified conditions the amino acid-derived aldehydes ( 3 3 ) can be converted by the Wittig reaction to the corresponding allylic amines without l o s s of optical purity.32 A wide range of alkyl- and aryl-substituted A one-pot synthesis o f

1.1-diiodoalkenes has been prepared by the reactions o f

t r i phenyl phos ph i ne/ te t r a i odome thane with aldehydes , p r esuma b 1y &y in situ formation of d i i o d o m e t h y l e n e t r i p h e n y l p h o s p h o r a n e .

2 . 2 . 2 Ketones.- Wittig methylenation is preferred to the Peterson method for formation of the d i h y d r o m e t h y l e n e - 1 . 2 . 3 - t r i a z o l e (34) from the corresponding carbonyl compound. 3 4 Protection o f the indolic NH groups by tosylate leads to greatly improved ylides from Wittig methylenations of indolic ketones. 3 5 High pressure conditions have now been applied to Wittig reactions of stabilized ylides. 3 6 A s previously predicted37 the

effect in these cases is much more dramatic than in the case of semi-stabilized ylides due to the rate-determining first step in the reaction o f stabilized-ylides. The method allows formation o f alkenes from a variety of unreactive ketones, including a number of hindered steroids. A variety of benzo-fused five- and six-membered heterocycles have been prepared by intramolecular Wittig reaction o f the (ortho-substituted b e n z y 1 ) t r i p h e n y l p h o s p h o n i u m salts ( 3 5 ) . 3 8

2.2.3 Miscellaneous Reactions.- Examples of ylide-anions of the type

298

Organophosphorus Chemistry

XHNycHo + Ph,P=CH,

XHN

% II

R

N=N

i2 +

773-0R

RL (351 X = 0 , NH

R'

R2

I

iii , i v

Rcagcn+s :

I

,

NCINISIM~; ~ )i ~i , Br(CH2)5
0

;

111,

0.1M HCI ;;v,{> H

Scheme 9

7: Mides and Related Compounds

CN

A

Ph,P=C-X

Na+ (36)X = C N

CN

299

Na00C

OH

0-

CN

OH

WR3

OSiMe3

ph3 P +zR3

R

R

I R'

VII,

Reagents : vi,

I ,

/O\

R'CH-CR2R3

[CH20],,

vII

;

11,

H30+;

111,

H20 ; iv,Me3SiCL ; v

, -OH Scheme 10

,

Heat;

ii

300

Organophosphorus Chemistry

oz;--;

+

Ph3P=CMeCOOR

I

I

Me

Me

PhHC

H (41)

/c

+

Ph3P=C=C=NPh

R \C

(42)

R=

Reagents

,

““i, Ph

k,

>CHPh

II

0

H

O=Cl”,{

: I , RCOCL , P y ;

H

i t ,

MeONa,MeOH

Scheme 11

4

co

PPh,

(43)

7: Ylides und Reluted Compounds

(36)

are rare and in some cases disputed.

30 1 Bestmann has now

generated the cyanomethylene analogue (36, X = C N ) by deprotonation of the corresponding ~ l i d e . ~ ’A s might be expected ( 3 6 , X = C N ) is highly reactive and can be alkylated to give a variety of synthetically useful intermediates (Scheme 9). Alternatively the reaction of (36, X = C N ) with epoxides can be used to prepare y-hydroxynitriles (37). y-butyrolactones ( 3 8 ) . and y-methylene-butyrolactones ( 3 9 ) by employing different work-up procedures (Scheme 10) .40

The reactions o f ylides with various diones have been studied.

The reaction of cyclic anhydrides ( 4 0 ) with a-alkoxycarbonylethylidenetriphenylphosphoranes generally gives mixtures o f Eand endo-enol lactones,41 althouqh in some cases these initial products underqo rinq-openinq. However, similar reactions of (E)-Z-benzyl-

i d e n e o x a z o l i d i n e - 4 , 5 - d i o n e (41) qive new ylide adducts instead of Wittiq products.42 Ylide-adducts (43) are also formed in the reaction of cyclic 1,3-diones with N - p h e n y l i m i n o k e t e n y l i d e n e t r i phenyl phospho r ane ( 4 2 ) . 43 A variety of chromones ( 4 5 ) have been prepared from phosphoranes ( 4 4 ) by acylation. intramolecular olefination and A route to a number of different 5-(e.q. hydrolysis (Scheme ll).44 4 7 ) and 6-(e.q. 4 8 ) membered nitroqen heterocycles is provided by the reaction o f Z - ( i m i n o e t h y l i d e n e ) p h o s p h o r a n e s ( 4 6 ) with dicarbonyl dichlorides, mono- and dicarboximidoyl chlorides, and N,N-bis(chloroformyl)amines.45 The reaction of ( 4 6 ) with N-phenylbenzonitrile imide ( 4 9 ) provides a one-step synthesis o f

salts ( 5 0 ) (Scheme 12). Further investiqations o f the reactions of azine phosphoranes ( 5 1 ) . now witt ketenes and isocyanates, have provided new routes to a variety o f heterocyclic systems . 4 6 The reactions of B-carbonylphosphonium salts (52) with nucleophiles provide one-pot syntheses o f , for example, tetrasubstituted f luoroalkenes ( 53)47 and f luoroenynes (54)48 (Scheme 13). Unlike their previously reported reactions with perfluoroacyl 1,3.4,5-tetraaryl-l,2.4-triazolium

fluorides, fluorophosphoranium salts ( 5 5 ) react with perfluoroacyl chlorides to uive the betaines ( 5 6 ) .49 Subsequent haloqenation o f

( 5 6 ) provides a new route to a.a-dihalogenofluoromethyl perfluoroalkyl ketones ( 5 7 ) (Scheme 14). The optically active cyclopentane diol derivative ( 6 0 ) . a key synthetic intermediate. ha been prepared from tartaric acid Viq reaction of the methyl trimethylsilyl ester (58) with phosphorane ( 5 9 ) . followed by therma

302

Organophosphorus Chemistry

Ph

(46 1

( 501

+

Yh c I-

Ph

Scheme 12

R

Me

Ph,P

COOMc

Ph (51)R=H,Mc

Nuc

Ph, P=CR' R

li, i

Ph3P0

+

(53)

PhP 3

\CR'R~

I oc\

Rf

(54) Reagents

I

, PhLi ; 1 1 ,

RZI;

111

, (RtCOI2O ; i v , Nuc ; v , R 3 C G C L I

Scheme 13

R, COO-

303

7: Hides and Related Compounds

[ Bu36CFb6u3]

--&

X-

[Bu3F'CFPBu3] + +

X - CI-

I

(55)

co Rf

1 +

0I

6u3p+Rf F

R,COCFX,

+

Bu3PX,

(57)

Reagents :

i , RfCOCl ;

Ii

,

X2

,0

OC

Scheme 14

C 00 S iMe *COOMc

(58)

+

Ph3P=CHSiMe3

I

(59)

+

&,PXCI

Organophosphorus Chemistry

304

-I-

Ph3P=CHCH=CHCOOMe

R , C E CCOOMe

I61 1 ,COOMe Ph,P=C C '

/

=CH.CH=CHCOOMe

Rf

Reagents :

CHZCIZ

I ,

, r.+. ;

11,

xylene

Scheme

Ar,P

R'

+ \7AR2

, reflux 15

Ar3&H,CR'R'OH

1"+

( 67 1

+

Ar36CH=CR'R2

Reagents :

I

, ROH

A r , h

clo;

ClO, 35

(62)

+ Ar,PCH,CR'R20€t

'C ; I I EtOH , 100 'C ;

ClO, III

HCIOI

OR

7: Hides and Related Compounds

305

epimerization and intramolecular Wittig reaction.50

A new route to methyl 2-perfluoroalkyl-6-methoxybenzoates (63) from stabilized ylides has been reported.51 The ylide (62). prepared in excellent yield from the ylide ( 6 1 ) and the appropriate methyl 2-perfluoroalkynoate. UndeKgOeS intramolecular Wittig-type reaction on refluxing in xylene (Scheme 15). The adduct (65, X = N ) , formed from the reaction o f the phosphine imine (64, X = N ) with dimethyl acetylene dicarboxylate. undergoes cyclization on heating with base to give the 3H-k5-phosphole ( 6 6 , X = N ) . ” The analoguous phosphonium ylide ( 6 5 . X=CH) undecgoes a similar reaction, but only the hydrolysis product of the 3H-X5-phosphole ( 6 6 , X = C H ) was isolated. Reactions of t r i s ( 2 . 6 - d i m e t h o x y p h e n y 1 ) p h o s p h i n e with epoxides occur readily to give 8-hydroxyalkylphosphonium salts (671, but no Wittig products.53 Heating the adducts (67) gives a variety of products (Scheme 16). but none from P-C cleavage. An obvious explanation of this is that the electron-donating methoxy groups preclude attack o f oxygen at phosphorus to form a oxaphosphetane, although the authors suggest steric factors may also be important. The reaction of optically active N-acyl or N-sulphonyl aziridines with ethoxycarbonyltriphenylphosphoranes gives isolable ylides ( 6 8 ) as the major p r ~ d u c t . ~ ‘ These compounds can be used in wittiq reactions to provide a useful synthesis of optically pure unsaturated aminoacids. A study of the effect of changing the halogen atom on the reaction of methylene ylide with epihalogenohydrins to give oxaphospholanes ( 6 9 ) has been reported.55 The sequence developed by Cava €or the preparation of unsymmetrical heterofulvalenes has been applied to the synthesis of (70) and (71).56 Bestmann has extended his study of the reactions of ylides with alkylchloroboranes.57 The adducts (721, which are the initial products o f reactions with alkyldichloroboranes, provide a variety of derivatives on reduction o r further reaction with ylides. The reactions of tautomeric furoxans (73) with ester-stabilized phosphonium ylides have been investigated.58 As with most similar

reactions the pathways are complex, however a common initial reaction is deoxygenation of the furoxan to the correspondinq furazan through a Wittig-type reaction. A number of o-halogenoalkyl carbonyl ylides based on (74) have been used to 59 study lithium-halogen exchange-initiated cyclization reactions. The phosphorane substituent in (74) has the advantage that it is

Organophosphorus Chemistry

306

COOEt

-k

Ph P=CHCOO E t

N 'H X

-- H

HNX

(68)

ph3rzax#"x X

0

X

(69)

Ph3P=CR1R2

+

R3BCI,

-78

"c

Ph36 -CR1R2

___)

I

CI,BR -

(72)

I

(73)

COOEt

COOEt

I

I

Lx

CHCOC= PPh3

CHCOC=PPh3

I

RLI ___+

/\

Mcs =

"'v Me

0COOEt

I

L iCHCOC=PPh3

7: Ylides and Related Compounds

CI

I

Et,Zr

/CH2

\

‘

/

CH2

PR,

307

Et,M

2‘ ‘CH=PR3

(78)

Zr , Hf R = Me, N M e 2 , N E t 2

MsTi,

308

Organophosphorus Chemistry

reactive towards the required Michael addition reaction. while being resistant t o direct nucleophilic attack on the functional group. The synthesis and reactions o f compounds containing ylide-metal bonds continue to be an area of active interest. Examples include the synthesis of new tellurium compounds,60 the first example (75) of a phosphonium ylide complex of dioxomolybdenum(VI)61 and the hafnium and zirconium63 complexes (76), ( 7 7 ) and (78). A number of different methylene-bridged dinuclear gold(II1) complexes (e.g. - 79) containing terminal and bridging ylide ligands have also been prepared. 64 &-Ray photoelectron spectroscopic studies of gold and copper complexes of methylene ylide have been reported. 6 5 A new route to the rarely accessible metallocyclobutabenzene compounds ( 8 1 ) is provided by the reaction of methylene ylide with the appropriate metal-aryne complex,66 although formation of (81) competes with H-transfer from the intermediate (80) to give the metallocene-substituted ylide (82). The rhenium-ylide complex (83) can be deprotonated to give the metal-substituted ylide (84). which reacts stereospecifically with methyl triflate to form the methylated complex ( 8 5 ) (Scheme 17). 67 Bis(y1ide)nickel Catalysts of type (86) have been used to control polymer molecular weight in poly(ethene) synthesis.68 3 Reactions of Phosphonate Anions detailed study of lithiated methyl diethylphosphonoacetate by i.r. and ’H. 13C and 31P n.m.r. in THF and in acetonitrile indicates that the carbanion exists as mixtures of monomeric ion-pairs, agregates. free-ions and triple ions depending on the solvent used. 6 9 These results may be important in phosphorus-based olefinations in view of the evidence that the rate of formation of the initial diastereomeric adducts in the Wittig reaction depends on the structure of the carbanion. Convincing evidence that earlier reports” of the generation of phosphonate dicarbanions (87) are in error has been p ~ b l i s h e d . ~ ’Under the reaction conditions

A

previously described only the monocarbanion appears to be generated. However, the dianion (87) can be formed by successive treatment of the parent phosphonate with NaH and BuLi and it does give increased yields of alkenes in Wittig reactions compared to the monocarbanion. a-Lithioalkylphosphonates ( 8 8 ) can be generated from trialkyl phosphates by treatment with 2 mole equivalents of the appropriate alkyll ithium.72 a- (Diethoxyphosphinoyl)-y-butenol ide

7: Ylides a d Related Compounds

ON”

0

309

Re.

I

;‘PPh, C H,PP h3

(83)

Reagents :

I ,

BULI I T M E D A ;

11,

MeOS02CF3

Scheme 17

PhPt

(86)

(RO),P

+

0 R’CH2Li

(09)

II

+( R O ) z P C H z R ’

R’CH~L~

(90) x=so3( 9 1 ) X = S0,Et

0

II

( R 0 ) 2 P C H L i R’

310

Organophosphorus Chemistry

(92 1

R 26 Reagents :

K 2 C 0 3 , DMF ;

I

11

0

, Na , DME

Q

S c h e m e 18

0

II

(Et012PCHR’Li

( EtO) P 21 I

0

II

OEt

0,

(Et0)2PCHR’CH=NPh

,NPh Li

1“ R’

0, ,NPh Li

H Reagents

:

I

~

EtOCH=NPh

, THF

;

11,

P r I2NLi, T H F ,

Scheme 19

-

7 8 OC;

III

, R2CHO;

IV,

H30+

7: Ylides and Related Compounds

(89)

31 1

undergoes Michael addition of various nucleophiles to give the

COKreSpOnding phosphonate carbanion, which has been used in the synthesis o f y-butyrolactones and lignans.73 A new, high yield route to certain 8-ketophosphonates is worth noting.74 The reactions of both ylides and phosphonate carbanions with gyoxal acetal have been studied and shown to provide routes to a-func t iona 1 i zed a ldehydes . 7 5 The d i e thy 1phos pho ry 1 methanesulphonates (90) and (91) can be used to generate a,@-unsaturated sulphonates by normal olef ination reactions.76 Much higher (E_)-stereoselectivity is observed using the phosphonate (91) than (90). A new route to 3(2H)-fucanones (93). involving intramolecular olefination of y - ( a c y 1 o x y ) - 8 - k e t o p h o s p h o n a t e s (92). has been developed.77 The choice o f conditions, especially the b a s e used, is critical in these reactions (Scheme 18). Phosphonate-based olefin syntheses have been carried out by passing the gaseous reagents through a column packed with potassium Carbonate (gas-liquid phase-transfer catalysis conditions) .78 Yields were moderate and (E)-alkenes were formed stereoselectively. Reactions of phosphonate carbanions with ethoxymethyleneaniline, followed by treatment with base, lead to lithiated enaminoalkylphosphonates (94).79 Further reaction of (94) with aldehydes, followed by hydrolysis, provides a,@-unsaturated a-substituted aldehydes in good yield (Scheme 19). Various reactions involving phosphonate carbanions have been used to prepare vinylphosphonates. Reactions of ester-stabilized phosphonate carbanions with aldehydes in the presence of titanium tetrachloride are known to give Knoevenagel products having the thermodynamically-preferred (E_)-configuration. It is now reported that the (Z)-isomers (95) can be formed almost exclusively from similar reactions in the presence of tri(isopropoxy)titanium chloride and sodium hydride." In an attempt to synthesize dihydrogen phosphonomethyl-substituted ethenylphosphonic acids (96) the reaction of bis(diethy1 phosphonomethy1)phosphinic amide carbanions (97) with aldehydes has been investigated.81 A synthesis

of a-hydroxy esters (99) is provided by Peterson olefination of the a-trimethylsilyl-substituted phosphonate (98) followed by hydroxylation with catalytic amounts of osoq (Scheme 2 0 ) The reactions of a-fluoromethanephosphonate carbanions (100) have been investigated. The thermal stability decreases in the order X=H > X = F > x=c1, the last two carbanions being unstable a t Loom t e r n p e r a t u ~ e . ~A ~ variety of functionalized

3 12

Organophosphorus Chemistry

0

II

( E+O12PCH2COO E t

N a H , C l T i IOPr’13

COOPr‘

RCHO

H

(95 1

0

(96)

(R0)2PCHOCHZCH,SiMe3

I

197)

0

1 I1 ( R O I 2II P - C - OCH2CH2SiMe3 I

II

Si Me3

CR’R,

1

iii

R’ ‘C.COOCH2CH2Si Rz/

I

Scheme

0

II-

( RO), P C F X

(100) 0

20

Me3

7: Ylides and Related Compounds

313

a-fluoroalkylphosphonates have been prepared by the reaction o f diisopropyl fluoromethylphosphonate carbanion (100. R = isopropyl, X=H) with electrophiles. Generally reactions with aldehydes and ketones gave 6 - h y d r o x y a l k y l p h o s p h o n a t e s : 8 4 however, reactions with formaldehyde and acetaldehyde gave the vinylphosphonate (101) and a mixture of (102) and (103). respectively. Reactions o f the analogous bisphosphonate carbanion (104) with aldehydes and ketones provide a new general synthesis of 8-fluorovinylphosphonates ( 105 ) . 85 Regitz's method of generating vinylidene carbenes from diethyl didzomethylphosphonate carbanions and ketones has been used to synt hes ise f urans (Scheme 2 1 ) 86 and cyc lohepta [ b I pyr K O 1- 2 -ones ( 106 ) . 87 Opt i ca 1 ly act ive 4 - d i e thoxyphos phi ny 1 - 3 - ( 1-hydr oxye t hy 1) 2-azetidinone ( 1 0 8 ) has been prepared by base-induced cyclization of the epoxide phosphonate (107). 4 Selected ARPlications in Synthesis 4.1 Carotenoids. Retinoids and Related ComPounds.- Phosphorus-based olefinations continue to be extensively used in syntheses of retinoids. Examples include retinal analogues ( L g . 109) with locked 6,7-conformations,89 aromatic and ring-fused analogues, 90 the 11.13-bridged analogues (110) and ( 1 1 1 1 , 91 and 5-methoxyretinal (112) reduction o f the cyano analogue.92 In this last synthesis some isomerisation of the a- to the 8-isomer occurred during the reduction step. The use of the oxido-allylic phosphoranes (113) in "salt-free" Wittig reactions leads to high (Z)-selectivity and this method has been applied to the synthesis o f l l - c i s - ~ e t i n o i d s . ~ ~ The diene ester phosphorane (115). previously used by Vedejs for triene synthesis, has now been applied to the synthesis of a variety of all (IZ)-polyenes using the readily available enal (114) as the initial carbonyl component (Scheme 22) .94 Both ylide-based and phosphonate-based olefinations have been used as key reactions

in a total synthesis of the mycotoxin citreomontanin (116) and its isomer (117). 95

Leukotrienes and related Compounds.- A recent review o f the leukotrienes contains much information on synthesis, including the use of the wittig reaction.96 What are now standard Wittig methods continue t o be used widely in leukotriene synthesis, for example, to prepare the 20-(g-trif1uoroacetamido)phenyl derivative o f LTAi7 and in a new 4.2

Organophosphorus Chemistry

3 14

0

II

(EtO),PCH=N,

+

R'COCR2( O M e I 2

* OMe

R'

1

Me0

t R e a g e n t s : I , Bu OK

, THF,

-LO ' C ;

11,

H30+

Scheme

0

(EtO),PCH=N, II

+

0

*[ %'D] 21

C

X

Me

J

7: Ylides and Related Compounds

315

CHO

(110) n = 2 (111 I n = 3

R'

i

Ph3P=CH(113 1

C=CHCH20H

R'=

H

,M e

(114)

COOMc

Reagents : i , Ph3P=C

4

'COOMe

; i i , 1 2 , C H C 1 3 , Zh ;

(115)

iv , M n 0 2 ; v , Ph3P=CHCOOMe

Scheme 22

. .

III

,

DIBAL;

316

Organophosphorus

Chemistq

LoUte to (+)-LTB4.98 This also applies to the synthesis of HETE derivatives and metabolites. for example, ( B ) . and (5)-isomers of 8 and 1 2 - h y d r o x y e i c o s a t e t r a e n o i c acids. 99 loo ~ ( 5 ) and ~~(SI-HETE methyl esters,l o o and 5(S), 2 0 and l5(s) 20-dihydroxyeicosatetraenoic acids.”’ Extensive use of the Wittig reaction has also been made in syntheses o f both enantiomers o f the epoxygenase metabolites 8 , 9 - and 11.12-epoxyeicosatrienoic acids‘” and of (118). a possible biosynthetic precursor o f lipoxins.lo3 The four ChiKal stereoisomers of 14.15-oxide-5(g), 8(z), ll(Z)-eicosatrienoic acid have been synthesized using a Wittig reaction of the phosphonium salt (119) to construct the polyene chain.lo4 In view of the tendency to use well established methods in these syntheses, a report that arsonium salts have been used as olefination reagents in a synthesis of LTA4 methyl ester (120) is worth noting.“’ 4 . 3 Macrolides and Related Compounds.- Intramolecular olefination of complex phosphonates has become the method of choice to construct a variety of natural macrocyclic ring systems. Examples include the synthesis o f methynolide (121),lo6 the aglycone of the 12-membered rnacroli.de methymycin, and tylonolide (122). the aglycone o f the 16-membered tylosin.lo7 The method has also been used in the synthesis of pikromycin, a 14-membered macrolide antibiotic. and the first total synthesis of (-)-asperdiol involves cyclization the phosphonate (123).’09 The macrocyclic system (125). a model system related to the rubradirin group of polypeptide biosynthesis inhibitors, has been synthesized by cyclization of the phosphonate (124).‘10 However, the yield is low and the B-elimination product (126) is also formed. A highly stereoselective total synthesis of the cembranolide diterpene anisomelic acid involves a (z)-selective intramolecular olef ination of the phosphonate (127).’11 Olefination-dimerisation of a-aldehydo phosphonates has been used as a method of macrocyclic synthesis in spite of the difficulties involved in the synthesis of the appropriate phosphonate (128). I t is now reported that these intermediates can be generated by DMAP-catalyzed ester exchange o f phosphonoacetates with lactols and this method has been used to synthesized the 112 16-membered macrodiolide (-)-pyrenophorin (129). Phosphonate-based olefinations continue to be used to generate intermediates suitable for macrocyclization. For example, reaction of the phosphonate (130) is a key step in the first synthesis of mycinolide V. the aglycone of a mycinamycin series macrolide 8

~

317

7: Ylides and Related Compounds Me OMc

0 Me

(

121)

OH

318

Organophosphorus Chemistry

OR CHO

R

;"'"p"$ OMe M e

Me0

'c1

OMe

+

0

I!

(R0)2PCH2COOMe

0

-CO CHZ P(0R 12

(129) X = O

7: Ylides and Related Compounds

32s

0

OR2

Ph,P

Me *

1159)

CHO

1160)

(-&.o R (161) X = NH

, S ,O

(162)

Na H

0

0

(164)

I1 6 5 )

Organophosphorus Chemistry

320

0 Me

Reagents : i

, N a H , R1R 2CO

Me

THF ; ii

Me

BuLN+F-; i i i , C u O C O C F 3

Scheme

23

OR

I

Ph,P=CH( CH2),CE CCH2C.

\=

(133)

Me

H

I

I

OHC

OR (134)

^v" OR

7: Hides and Related Compounds

32 I

\

Br-

(1371

0

II

T C O O E t Me (138)

T

COOEt T

(139)

322

Organophosphorus Chemistry

phosphonate ( 1 4 6 ) with the appropriate aldehyde (Scheme 24) .I2-’ Methodogy involving the phosphonate ( 1 4 8 ) previously used in the synthesis o f dihydrocompactin has now been applied to the synthesis o f the closely related ( t ) - dihydromevino1in.lZ8 A new convergent total synthesis of (+)-compactin involves generation o f the novel

phosphorane (151) by Y alkylation of the enolate-phosphorane (149) with (150). followed by Wittig reaction of (151) to give ( 1 5 2 ) (Scheme 25).12’ This last product can be cyclized and functionalized to give (+)-compactin.

The acetylenic polyenes

(154). (155). (1571, and (158) (naturally occurring in the red algae

-~ Laurencia _____ okamuri) have been synthesized by Wittig reactions of the salts (153) and (156). followed by separation of the major. (154) and (157), and minor. (155) and (158). isomers (Scheme 26).I3O The reaction of the ylide (159) with a variety of model aldehydes has been studied with a view to predicting the

applicability o € such an approach to the synthesis of a number o f biologically active acyltetramic acids.131 Sequential Wittig reactions with ( 1 - e t h o x y c a r b o n y 1 ) e t h y l i d e n e t r i p h e n y l p h o s p h o r a n e have been used to prepare verrucosal (160).13’ The attempted olef ination of a variety of monocyclic and bicyclic B-lactams with stabilized phosphonium ylides and phosphonate carbanions has been reported. 133 Successful conversion to the alkene depends on both the phosphorane reactivity and the B-lactam structure. The Wittig reaction has been used to prepare a variety of ( E ) - 2 - hydroxy- 4 -substituted s t i 1 b e n e ~ land ~ ~st i 1beno id heterocycles ( 161)135 in spite of the potential problems associated

with the presence of the phenolic group in the former case. Both Wittig and phosphonate-based olefinations have been used to prepare a large number of pyrrolyl- and 3 - c h l o r o p y r r o l y l p o l y e n e s (e.9. 162). 136 The key step in a synthesis of the ribasine skeleton is the

formation of the azepin ring by an intramolecular Wittig reaction of the salt (163). Met hano br idged te trahydr oannu 1enes have been

synthesized by Wittig reaction of the dialdehyde (164) with the ylide (165) followed by oxidative coupling.138 A variety o f related [1,3]-cyclophanpolyenediynes have also been prepared vy&

double

Wittig reactions of the salt (166). A Wittig reaction of the stabilized ylide (167) with (E)-cinnamaldehyde has been used to prepare one isomer of the fungicidal natural product strobilurin. 13’

7: Ylides and Related Compounds

323

LCN

11431

Ac 0

OMe

OMe

R’vL

CHO

Reagents :

I,

KOBut

Et

RO’

(1421

I

THF, 0

OC

;

11,

CF,COOH

Scheme 2 4 McOOC

.SIR,

324

Organophosphorus Chemistry

0 Ts-OCH

‘‘7

I

-

1

P +,Ph3

(150)

(151 1

Scheme 25

7: Ylides and Related Compounds

32s

0

OR2

Ph,P

Me *

1159)

CHO

1160)

(-&.o R (161) X = NH

, S ,O

(162)

Na H

0

0

(164)

I1 6 5 )

326

Orgunophosphorus Chemistry

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a,

7: Ylides and Related Compounds

43. 44. 45. 46. 47. 48. 49. 50. 51. 52. 53. 54.

55. 56. 57. 58. 59. 60. 61. 62. 63. 64. 65. 66. 67. 68. 69.

32 7

F.H. Soliman and Kh. H . Khalil, Phosphorus Sulfur, 1987, 29, 165. Y. Le Floc'h and H . Lefeuvre, Tetrahedron Lett., 1986, 27, 5503. L. Capuano, B. Dahm. and V. Schramm, Chem. Bet., 1986, 119, 3536. E . E . Schweizer, J.E. Hayes, A. Rheingold, and X. Wei, J. Org. Chem., 1987, 5 2 , 1810. Y . Shen and W. Qui, Tetrahedron Lett., 1987, 28, 449. Y . shen and W . Qui, J. Chem. SOC.. Chem. C o m n . , 1987, 703. I.H. Jeong, D.J. Burton, and D.G. Cox, Tetrahedron Lett., 1986, 21, 3709. H.J. Bestmann and T. Hoenius, Axnew. Chem., Int. Ed. Engl., 1986, 25, 994. W. Ding, P. Zhang, and W. Cao, Tetrahedron Lett., 1987, 28, 81. J. Barluenga, F. Lopez, and.F. Palacios, J. Chem. SOC., Chem. Commun., 1986, 1574. U. Wada and A. Tsuboi, J. Chem. S O C . , Perkin Trans.1, 1987, 151.

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-

H. Schmidbaur, R. Pichl, and G. Huller, Angew. Chem., Int. Ed. Engl.. 1986, 2 5 , 574. H. Schmidbaur, R. Pichl, and G. nuller, Chem. Ber., 1987, 120, 39. H. Schmidbaur and C. Hartmann, AnKeW Chem.. Int. Ed. Engl., 1986, 2 5 , 575. Y. Yamamoto and H. Konno, Bull. Chem. SOC. Jpn., 1986, 1327. H.J.R. de Boer, 0.S. Akkermann, F. Bickelhaupt, G. Erker, P . Czisch, R. Hynott, J.U. Wallis, and C. Kruger, Angew. Chem., Int. Ed. Engl., 1986,

z,

25, 639.

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a,

75. 76. 77. 78. 79. 80. 81. 82. 83. 84.

1986, 2?.

4265.

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328

Organophosphorus Chemistry

85.

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86.

S.R. Buxton, K.H. Holm, and L. Skattebol, Tetrahedron Lett., 1987,

87. 88. 89.

1417. 2167.

g,

J.C. Gilbert and B.K. Blackburn, J. Org. Chem., 1986, 5 l , 4087. H. Shiozaki and H. Hasuko, Bull. Chem. SOC. Jpn., 1987, 6 0 , 645. R. van der Steen, P.L. Biesheuvel, R.A. Hathies, and J . Lugtenburg, JAm. Chem. S O C . , 1986, 108,6410. 90. A.E. Asato, H. Denny, and R.S.H. Liu, J. Am. Chem. S O C . , 1986, 108,5032. 91. A. Albeck, N. Friedman, H. Sheves, and H. Ottolenghi, J. Am. Chem. S O C . . 92. 93. 94. 95. 96. 97. 98. 99. 100. 101. 102. 103. 104. 105.

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w.,

w., w ., 1986, 2 7 ,

4161.

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m,

m.,

a,

a.

7: Ylides and Related Compounds

32')

123. S . W . Djuric, H . Hiyano, and J . P . Snyder, Tetrahedron Lett., 1986, 2 7 , 4403. 124. A. Takahashi and H. Shibasaki, Tetrahedron Lett., 1987, 8 , 1893. 125. R.K. Boeckman, J r . , E.J. Enholm, D.H. Demko, and A.B. Charette, J. Org. Chem., 1986, 5.1, 4743. 126. S. Nishiyama, H. Toshima, H. Kanai, and S. Yamamura, Tetrahedron Lett., 1986, 2 7 , 3643. 127. R.K. Boeckman, Jr., J.E. Starrett, Jr., D.G. Nickell, and P . - E . Sum, tl, Am. Chem. SOC., 1986, 108,5549. 128. S.J. Hecker and C.H. Heathcock, J. Am. Chem. SOC., 1986, 108, 4586. 129. G.E. Keck and D.F. Kachensky, J. O r g . Chem., 1986, 2 , 2487. 130. H. Kigoshi, Y . Shizuri, H. Niwa, and K. Yamada, Tetrahedron, 1986, 42, 3781. 131. R.E. Ireland and R.B. Wardle, J . Org. Chem., 1987, 52, 1780. 132. L.L. Klein, Tetrahedron Lett., 1986, 4545. 133. M.L. Gilpin, J.B. Harbridge, and T.T. Houarth, J. Chem. SOC., Perkin Trans.1. 1987, 1369. 134. A. Hylona, J. Nikokavouras, and I . H . Takakis, J. Chem. Res.,Synop., 1986, 433. 135. V.H. Rawal, R.J. Jones, and H.P. Cava, J. Org. Chem., 1987, 52, 19. 136. F.R. Ahmed and T.P. Toube, J. Chem. Res. Synop., 1986, 440. 137. R. Alonso, L. Castedo, and D. Dominguez, Tetrahedron Lett., 1986, 21, 3539. 138. J . Ojima, E. Ejiri, T. Kato, M . Nakamura, S. Kuroda, S . Hirooka, and H. Shibutani, J. Chem. SOC., Perkin Trans.1, 1987, 831. 139. K. Beauternent and J.H. Clough, Tetrahedron Lett., 1987, 28. 475.

-

x,

Phosphazenes BY 1.

Introduction

C. W . ALLEN

T h i s c h a p t e r c o v e r s t h e l i t e r a t u r e o f phosph[v)azenes.

The

m a j o r p o i n t s o f i n t e r e s t c o n t i n u e t o be m a t e r i a l s w h i c h a r e o r are related t o cyclo-

and polyphosphazenes.

Numerous h i g h l y

f o c u s e d r e v i e w s h a v e a p p e a r e d a n d w i l l be q u o t e d i n t h e a p p r o p r i a t e s e c t i o n s below.

P u b l i c a t i o n s o f more g e n e r a l

i n t e r e s t i n c l u d i n g a two volume monograph c o n t a i n i n g comprehens i v e r e v i e w s o f t h e c h e m i s t r y o f i n o r g a n i c r i n g systems c o v e r i n g the period of

1969 t o t h e e a r l y e i g h t i e s

1

,

s e l e c t e d papers from

t h e 4 t h I n t e r n a t i o n a l Symposium o n I n o r g a n i c R i n g Systems ( O r s a y 198512 a n d a l l p a p e r s and p o s t e r s from t h e 1 0 t h I n t e r n a t i o n a l C o n f e r e n c e o n P h o s p h o r u s C h e m i s t r y (Bonn 198613 have a p p e a r e d i n the l a s t year. 2.

A c y c l i c Phosphazenes Numerous p u b l i c a t i o n s h a v e b e e n d e v o t e d t o a c y c l i c p h o s p h a z -

nes (phosphazo d e r i v a t i v e s ,

phosphine imines,

phosphoranimines)

with a s h i f t towards r e a c t i o n s o f molecules c o n t a i n i n g the

phosphazene u n i t b e i n g noted.

Reviews o f t h e a z i d e p h o t o l y s i s

r o u t e t o t h e p h o s p h o r u s - n i t r o g e n t r i p l e bond (phosphazynes) have appeared.4s5

Following a trend noted i n l a s t year's

review,

high

l e v e l m o l e c u l a r o r b i t a l c a l c u l a t i o n s h a v e been a p p l i e d t o m o d e l a c y c l i c phosphazenes.

A n a b i n i t i o s t u d y o f t h e H3PN+ e n e r g y

s u r f a c e shows l o c a l m i n i m a c o r r e s p o n d i n g t o s t r u c t u r e s r e l a t e d by 1 , Z - h y d r o g e n the series.

s h i f t s w i t h HPNH2+ b e i n g t h e g l o b a l minimum i n

These c a l c u l a t i o n s do n o t s u p p o r t t h e o c c u r a n c e o f

330

8: Phosphazenes

33 1

p h o s p h o n i t r e n e s as i n t e r m e d i a t e s i n azidophosphonium i o n p h o t o l y sis.6

S i m i l a r c a l c u l a t i o n s o n t h e H3PNH, H2PNH2 t a u t o m e r i c

e q u i l i b r i u m i n t h e gas phase p r e d i c t t h a t , s o l u t io n behavior, phosphazene.

as opposed t o o b s e r v e d

t h e a m i n o p h o s p h i n e i s more s t a b l e t h a n t h e

The c a l c u l a t e d p h o s p h o r u s - n i t r o g e n d i s t . a n c e a n d

v i b r a t i o n a l f r e q u e n c y f o r H3PNH f i t w e l l w i t h t y p i c a l v a l u e s . 7 Experimental i n v e s t i g a t i o n s of

the nature o f the phosphorus-

n i t r o g e n b o n d i n a c y c l i c p h o s p h a z e n e s h a v e a l l i n v o l v e d nmr

In a d e t a i l e d nmr (31P,

spectroscopy.

15N a n d 1 3 C ) s t u d y o f a

s e r i e s o f N-(arylsulfony1)-triphenyl-phosphazenes, l a t i o n s o f t h e 31P s h i f t , w i t h Hammett

'JpN

linear corre-

s e v e r a l o f t h e 13C s h i f t s a n d o f

u c o n s t a n t s and a l i n e a r c o r r e l a t i o n o f

Similar c o r r e l a t i o n s with

'JpN w i t h t h e 31P s h i f t w e r e 15N s h i f t s c o u l d n o t b e o b t a i n e d .

V a r i a t i o n s i n t h e nmr p a r a m e -

t e r s w e r e c o n s i d e r e d t o be c o n s i s t e n t w i t h b o t h d - o r b i t a l a n d p h o s p h o r u s - c a r b o n o* p a r t i c i p a t i o n i n t h e p h o s p h o r u s - n i t r o g e n bond.

The e l e c t r o n w i t h d r a w i n g a b i l i t y ,

u-constants,

q u a n t i f i e d i n terms o f

o f s e v e r a l h e t e r o c y c l i c u n i t s have been e s t i m a t e d

f r o m t h e 31P c h e m i c a l s h i f t s i n N - h e t a r y l t r i p h e n y l p h o s p h a z e n e s . E l e c t r i c f i e l d a n d m a g n e t i c a n i s o t r o p y e f f e c t s become i m p o r t a n t i n c a s e s where t h e phosphazene i s i n t h e a - p o s i t i o n o f

the

The 19F a n d 31P c h e m i c a l s h i f t s o f 6 2 m o n o p h o s p h a -

hetarene."

z e n e s o f t h e t y p e RR'PF=NC6H4X w e r e r e l a t e d t o s u b s t i t u e n t e l e c t r o n e g a t i v i t i e s . 11,12

The p o l a r n a t u r e o f t h e p h o s p h o r u s -

n i t r o g e n b o n d i n R3P=NN=CPh2 was e s t a b l i s h e d b y 1 3 C a n d "P spectroscopy.

nmr

13

B o t h p h o t o l y t i c a n d t h e r m a l r e a c t i o n s o f f i v e new p h o s p h o r u s ( I I 1 ) a z i d e s , RR'PN3, nes,

RR'PN,

proceed t h r o u g h t r a n s i e n t phosphazy-

r a t h e r than following the Staudinger reaction.

14

332

Orgunophosphorus Chemistrv

I n addition to cyclo-

and polyphosphazene formation,

2,3

tri-

m e t h y l s i l y l m i g r a t i o n l e a d i n g t o methylene(imino)phosphoranes ( l a ) o r b i s ( i m i n o ) p h o s p h o r a n e s \ ( l b ) were o b s e r v e d .

Trapping o f

t h e phosphazynes w i t h t r i m e t h y l s i l y l c h l o r i d e g i v e s t h e phosphaz e n e s RR’PC1=NSiMe3. i n a variety of

The S t a u d i n g e r r e a c t i o n h a s b e e n e m p l o y e d

systems5 f o r example t h e r e a c t i o n o f a wide r a n g e

o f diorganofluorophosphines w i t h s u b s t i t u t e d p h e n y l a z i d e s p r o v i d e s t h e m o n o p h o s p h a z e n e s , R2PF= NC6HqX. difluorophosphines

RPF2(R=(CH2I5N,

S e l e c t e d monoorgano-

ET2N) r e a c t w i t h n i t r o p h e n y l -

a z i d e s t o form monophosphazenes b u t o t h e r s u b s t i t u e n t s l e a d t o d i m e r i z a t i o n t o t h e d i a ~ a d i p h o s p h e t i d i n e s . ~One ~ ~ ~p~o t t r a n s f o r m a t i o n o f a l k y l h a l i d e s t o t h e a z i d e f o l l o w e d by a d d i t i o n o f t r i e t h y l p h o s p h i t e g i v e s p h o s p h a z e n e s w h i c h may be t r a n s f o r m e d t o amines,

p h o s p h o r a m i d a t e s o r _N , N - d i a l k y l p h o s p h o r a m i d a t e s . l6

The

r e a c t i o n o f t r i m e t h y l p h o s p h i t e w i t h 2-chloro-N-azidomethy12,6d i e t h y l a c e t a n i l i d e g i v e s t h e expected iminophosphorane which upon a c e t y l a t i o n s e r v e s as a g r o w t h i n h i b i t o r f o r t u r f g r a s s . ”

The

r e a c t i o n o f phenylazide with the phosphine centers i n phosphole dimers g i v e s t h e diphosphazene 2 which can undergo Et3N c a t a l y z e d

c i s - t r ans isomerization

o f t h e phosphazenes r e l a t i v e t o one

a n o t h e r o r r i n g c o n t r a c t i o n t o 3 a t 5Oo.l8

The 192 a d d i t i o n

p r o d u c t s o f 1,2,4,3-triazaphospholes u n d e r g o t h e S t a u d i n g e r r e a c t i o n t o g i v e 4.19

The s y n t h e s i s o f 3 - h y d r o x y a c y l

p h o r a n e s , RR’C(OH)CH2C(O)N=P”’’ s t a r t i n g from t h e azide.*’

iminophos-

can be c o n v e n i e n t l y accomplished

The f o r m a t i o n o f (Ph3P=N-N=N)2C=C(CN)-

C02Me f r o m t h e d i a z i d e a n d t r i p h e n y l p h o s p h i n e f o l l o w e d b y e l i m i n a t i o n o f n i t r o g e n t o g i v e t h e d i p h o s p h a z e n e h a s been r e p o r t e d . The u s e o f Ph3PCH2CH2PPh3 i n p l a c e o f t r i p h e n y l p h o s p h i n e l e a d s t o t h e c y c l i c s p e c i e s 5 w h i c h upon h y d r o l y s i s y i e l d s

8: Phosphazenes

333

(1) (a) E = N ( b ) E = CH

n ph2ii NC

0

Ph

X-P-N

II

NR'

N-P-X \p/

I

I\

NR'

N

I

iPh2

x

N

II

McN-P-P=P

I

N

C02Mc

334

Organophosphorus Chemist?

*’

P h 3 P ( 0 )CH2CH2PPh2=NC (NH2 )=C (CN )C02ME.

compounds s u c h a s ( E t o l 3 P = N P ( 0 ) ( O E t ) 2 , cides,

u t i l i z e s the r e a c t i o n of

A one p o t s y n t h e s i s o f

which a r e used as b i o -

the phosphite,

s o d i u m a z i d e and an organoammonium h a l i d e . ”

(Et0I3P,

with

The r e a c t i o n o f

t r i e t h y l p h o s p h i t e w i t h 2,3-diphenylpyrazine-3,3-bis(sulfonylazide) gives the expected phosphinimine.23 of

Some k i n e t i c s t u d i e s

t h e S t a u d i n g e r r e a c t i o n have been r e p o r t e d .

I n the rea c t i o n

o f p h o s p h i t e s o f t h e form (Et0)2PX w i t h p h e n y l a z i d e ,

the induc-

t i v e e f f e c t of X is only important i n the f i r s t step o f the react i o n l e a d i n g t o (EtO)2P(X)N3Ph.24

In the reactions of

c a t i o n i c s p e c i e s R(Et2N)P+ w i t h p h e n y l a z i d e , f i r s t - o r d e r w h e r e R=C1 a n d s e c o n d - o r d e r

the

the reaction i s

when R = E t 2 N .

The f o r -

m a t i o n o f t h e i n i t i a l a d d u c t , R(Et2N)PN3Ar i s r a t e l i m i t i n g f o r R=C1 w h i l e t h e f o r m a t i o n o f t h e p h o s p h a z e n e

via

nitrogen elimina-

t i o n f r o m t h e a d d u c t i s r a t e l i m i t i n g when R z E ~ ~ N . ’ ~ O t h e r s y n t h e t i c r o u t e s t o l i n e a r phosphazenes have a l s o been explored. R2SiFNH2

The K i r s a n o v r e a c t i o n o f PX5(X=F,C1) (R=CMe3,

Mixed chloro-fluoro

d e r i v a t i v e s c a n be o b t a i n e d by exchange r e a c -

tions o f the perfluoro derivative.

S u b s t i t u t i o n a t p h o s p h o r u s by

a l c o h o l a t e s and s i l y l a m i n e s occurs.26 C(CN)*

with

CHMe2) g i v e s t h e e x p e c t e d p h o s p h a z e n e s .

The r e a c t i o n o f (F3C)2C=

w i t h PC15 y i e l d s ( F 3 C ) , C C 1 C ( C N ) = C C 1 = N P C l 3

w h i c h c a n be

d e r i v a t i z e d a t t h e p h o s p h o r u s c e n t e r by r e a c t i o n w i t h Me3SiNMe2. 27

O r g a n o f l u o r o n i t r i l e s r e a c t with phosphorus y i e l d s

t o g i v e t h e i m i n o p h o s p h o r a n e s , Ph3P=NCFfC=CHCOR, w h i c h a r e q u a n t i t a t i v e l y c o n v e r t e d t o t h e B - d i k e t o n e s by a c i d h y d r o l y s i s . 2 8 T h e r m a l d e a l k y l a t i o n o f [Me2NPF (NMeR ) R ’ ) ‘XMe2NPF(=NR)R’ .29

gives

E l i m i n a t i o n o f water occurs i n the r e a c t i o n

o f 3-amino-4-(4-chlorophenyl)-furazan

with t r i o r g a n o p h o s p h i n e

8: Phosphazenes

335

m-

o x i d e s t o g i v e t h e p h o s p h i n e irnine w h i c h upon o x i d a t i o n w i t h c h l o r o p e r o x y b e n z o i c a c i d e l i m i n a t e s t h e p h o s p h i n e o x i d e and y i e l d s t h e c o u p l e d p r o d u c t 6.30

The r e a c t i o n o f t h e d i c y a n o -

p h o s p h i d e i o n w i t h d i p h e n y l p h o s p h i n o a n i l i d g i v e s PhN=PPh2PCNw h i c h s u b s e q u e n t l y c o n v e r t s t o PhN=PPh2P=PPh2-NPhfurther

and upon

r e a c t i o n g i v e s the n o v e l triazaphosphole d e r i v a t i v e 7 . 31

Reactions o f the phosphorus(III)imines, e.g. phosphoranes -

RP=NR’,

lead t o imino-

t r e a t m e n t w i t h d i m e t h y l a m i n e g i v e s RPH(NMe2)=NR’

which i s i n t a u t o m e r i c e q u i l i b r i u m w i t h t h e aminophosphine,

oxi-

d a t i o n w i t h c h l o r i n e g i v e s RPC12=NR’ w h i l e o t h e r o x i d a t i v e r o u t e s

give R P ( X ) = N R ’ ( X = O , S , S ~ -) 3 2

I n t e r e s t i n g r e a c t i o n s o f carbon

t e t r a c h l o r i d e or t o s y l a z i d e w i t h X 3 - d i a z a d i p h o s p h e t i n e , (R=i-Prl

N=PNR2’

R’=SiMe3), (X=C1,N3)

(R2NPNR’ ) 2

l e a d t o t h e l i n e a r p h o s p h a z e n e s XPNR2(=NR)-

which dimerize t o 8 .

The r e a c t i o n o f t h e

p h o s p h e t i n e h a v i n g R=R’=SiMe3 w i t h c a r b o n t e t r a c h l o r i d e g i v e s a s i m i l a r l i n e a r s p e c i e s w h i c h r e a r r a n g e s t o 9. 32 Numerous r e a c t i o n s o f a c y c l i c phosphazenes h a v e been i n v e s t i gated i n order t o e i t h e r d e r i v a t i z e the molecule or transform the p h o s p h o r u s - n i t r o g e n bond.

Triarnino(imino)phosphoranes, which can

b e p r e p a r e d f r o m C13P=NCMe3, t h a t o f DBU.

h a v e b a s i c i t i e s 1 5 0 0 t o 10,000

The u s e o f t h e s e b a s e s i n e l i m i n a t i o n a n d c o n d e n -

s a t i o n r e a c t i o n s has been d i s c u s s e d . 3 3 PhS02N=PC13,

times

The r e a c t i o n s

C13C(0)N=PC13 a n d NO C H N=PC13 w i t h t r i m o r p h o l i n o 2 6 4

methane p r o c e e d i n a s t e p w i s e f a s h i o n t o y i e l d m o r p h o l i n e d e r i v a t e s o f each o f t h e phosphazenes.34

The r e a c t i o n o f

C13CC(0)N=PC13 w i t h (Me2N)2CH2 s t o p a t t h e d i s u b s t i t u t e d s t a g e . S i m i l a r r e a c t i o n s o f C13CCC12N=PC13 h a v e b e e n d e s c r i b e d . 34 A d d i t i o n a l s t u d i e s o f t h e i n t e r a c t i o n o f sodium m e t h o x i d e w i t h the b i s (triphenylphosphine)

n i t r o g e n ( + 1 ) c a t i o n (PPN’)

have been

336

Organophosphorus Chemistry

reported.

The p r o d u c t ,

Ph2P(0)NPPh3 c a n s e r v e as l i g a n d t o

t u n g s t e n , b i n d i n g t h r o u g h t h e oxygen atom w h i c h h a s c o n s i d e r a b l e n e g a t i v e c h a r g e due t o t h e z w i t t e r i o n i c c h a r a c t e r o f t h e The r e a c t i o n o f C12P(0)N=PC13 w i t h N204 o r N203 l e a d

ligand.35

t o Cl2P(O)NPCl2ONO. 36

The p h o s p h o r y l g r o u p i n p h o s p h o r y l p h o s p h a -

z e n e s c a n b e d e o x y g e n a t e d b y r e a c t i o n w i t h PC15 t o g i v e s a l t s o f the type

[ ( PhO ),C1

f u r a n s ,39

3-mPNP(OPh n C 1 3 - n l

-

-

-

+PC16-. 37

P y r a n s 38 b e n z o -

t h i ~ p h e n e sa~n d~ i n d 0 1 e s ~w~i t h t r i p h e n y l p h o s p h i n i r n i n o

s u b s t i t u e n t s undergo c y c l o a d d i t i o n r e a c t i o n s w i t h a c e t y l e n e s w i t h o u t d i s r u p t i o n o f t h e p h o s p h o r u s - n i t r o g e n bond.

The m e t h y l

g r o u p a t t h e p h o s p h o r u s c e n t e r i n p h o s p h o r a n i m i n e s , Me3SiN= P(OCH2CF3)(CH3)R

c a n be l i t h i a t e d and a l l o w e d t o r e a c t w i t h

e l e c t r o p h i l e s t o g i v e o r g a n o p h o s p h i n e and o r g a n o s i l a n e

derivative^.^^-^^

I r o n and chromium c a r b o n y l complexes o f

p h o s p h i n e f u n c t i o n a l i z e d p h o s p h o r a n i m i n e s , Me3SiN=P(OCH2CF3)MeCH2PRR',

have been p r e p a r e d w i t h o u t d i s r u p t i o n o f

phosphorus-nitrogen unit.41

the

The r e a c t i o n o f t h e l i t h i a t e d i n t e r -

mediate w i t h dichlorosilanes gives bis-[[phosphoranimino)s i l a n e s ] .42 RCH2SiR3,

The s i l y l a t e d p h o s p h o r a n i m i n e s , Me3SiN=P(OCH2CF3)-

a r e v e r y t h e r m a l l y s t a b l e a n d do n o t y i e l d

p o l y p h o s p h a z e n e s o n t h e r m o l y s i s .42

Transsilylation reactions of

Me3SiN=P(OCH2CF3)Me2 w i t h c h l o r o s i l a n e s ,

d i c h l o r o s i l a n e s and

d i c h l o r o s i l o x a n e s h a v e b e e n a c c o m p l i s h e d y i e l d i n g new s i l y l a t e d phosphoranimines and

his-[( p h o s p h o r a n i m i n o ) s i l a n e s ] .43

range o f r e a c t i o n s a v a i l a b l e t o 5-silylphosphoranimines summarized.44

The has been

The r e a c t i o n s o f Ph3P=NH w i t h s i l y l s t a n n a n e s

l e a d s t o Sn(N=PPh3)4.45

The r e a c t i o n o f Me3SiN=PR3 w i t h t r a n -

s i t i o n m e t a l h a l i d e s p r o v i d e s a r o u t e t o Ti(C5H5)C12N=PPh3,46 t h e t u n g s t e n d e r i v a t i v e s WF5N=PR3 a n d WF4(N=PR3l2

and

(R=p-CH3C6H4;

Me;

8: Phosphazenes

337

(CMe3)2NH) . 4 7

A l k y l a n d a r y l d e r i v a t e s o f RR’R’P=NSiMe3

w i t h g e r m a n i u m t e t r a c h l o r i d e t o g i v e RR’R”P=NGeC13 with the dimer

react

which c o e x i s t

S t a b i l i z a t i o n o f t h e unknown

PH(=NAr)2 l i g a n d a s i t s n i c k e l (11) c h l o r i d e complex has been reported49.

The r e a c t i o n o f t h e p h o s p h a ( I I 1 ) z e n e ( M e 3 S i ) 2 N P =

NSiMe3

F e 3 ( C 0 ) 1 2 g i v e s t h e t w o c o m p l e x c l u s t e r s 11 a n d 1 2 .

with

50

I n c r e a s i n g i n t e r e s t h a s b e e n shown i n r e a c t i o n s o f t h e phosphazene bond i n a c y c l i c m a t e r i a l s . have been d i s c u s s e d above.

Some o f

these reactions

T r e a t m e n t o f Me3CPBr2=NCMe3 w i t h

magnesium l e a d s t o t h e n o v e l three-membered

r i n g 13 which

undergoes a c i d catalyzed i s o m e r i z a t i o n t o the diazadiphosphetid i n e (Me3CPNCMe3)2.51

The r e a c t i o n o f v i n y l i m i n o p h o s p h o r a n e s

w i t h a-bromoketones p r o v i d e s a r o u t e t o p y r r o l e ~ . ~ ~ Dimethylacetylene dicarboxylate i n s e r t s i n t o the phosphorusn i t r o g e n double bond.53954

The r e a c t i o n o f (ET2N)2P(CC1J)=NH

with carboxylic acids gives the a c i d anhydrides while r e a c t i o n w i t h a l d e h y d e s g i v e s RCH=NP(O) ( N E t 2 ) 2 5 5 a n d w i t h s e l e c t e d ’ k e -

t o n e s t o y i e l d Ph ( C F 3 ) C = N P ( 0 ) ( N E T 2 ) 2 . 5 6 t e t r a a l k y l d i p h o s p h i n i m i n e s , RR’PP(=NX)R2”

The d e c o m p o s i t i o n o f leads t o diphosphines

b y t h e e l i m i n a t i o n o f R2PNHR1 w h i c h i n t u r n c a t a l y z e s t h e proce~s.~’

A Wittig-type

r e a c t i o n o f RCH=CPhN=PPh3 w i t h R’NCO

gives the conjugated carbodiimides, Dialkylbenzylphosphines imines,

.

RCH=CPhN=C=NR’ 58

PhCH2PRR’=NR”,

react with alde-

h y d e s t o g i v e o l e f i n s b u t w i t h k e t o n e s o n l y O/NR” observed.59

exchange i s

The r e a c t i o n o f Ph2(PhNH)P=NPh w i t h t h e

d i m e t h y l s u l f i d e borane adduct gives the boron-nitrogen-phosphorus h e t e r o c y c l e s 14.60

The r e a c t i o n o f t h e t r i p h e n y l p h o s p h i n i m i n o

h y d r a z o n e PhNHN=C(C02Me)N=PPh3 w i t h a c y l h a l i d e s f o l l o w e d b y t r e a t m e n t w i t h base r e p r e s e n t s a r o u t e t o 1 , 2 , 4 - t r i a z o l e ~ . ~ ~

338

Organophosphorus Chemistry

CI,

R R'R"P =N

N=PRR'R"

'Ge'

/p\

Mc3C

NCMe3

NR, (13)

(11)

Ph

(121

H,

Ph

\

Ph2P\/N-B'-N

7 h 2

N--8-N Ph H, (14)

Ph

n

n

HN,

N4

I

- N,

,N-(CH,), P N'

,NH P

' 4 N

1

II

N

II

(15)

0d 0 C H 'P' N4"

I

CI,P,

'N'

II

PCI,

8: Phosphazenes

339

I n addition t o previously noted applications,

(Me3Si)2NP-

(=NSiMe3)2 a c t s a s a c o c a t a l y s t ( w i t h N i ( 0 ) complexes) p o l y m e r i z a t i o n o f a l k y l o l e f i n s by 2,w [(R2R’P)2Nl+X-

coupling.62

for the

Iminium halides

have been used i n t h e p r e p a r a t i o n o f c u r a b l e

f l u ~ r o e l a s t o m e r s . ~O~t h e r e x a m p l e s o f l i n e a r p h o s p h a z e n e s a s s u b s t i t u e n t s o n i n o r g a n i c r i n g s y s t e m s may b e f o u n d i n s e c t i o n s 3,4

and 5.

3.

Cyclophosphazenes A v a l u a b l e , comprehensive r e v i e w o f cyclophosphazene che-

m i s t r y c o v e r i n g t h e p e r i o d o f 1969 t o t h e e a r l y e i g h t i e s h a s appeared64 and a d e t a i l e d r e v i e w o f t h e o r g a n o m e t a l l i c c h e m i s t r y o f c y c l o p h ~ s p h a z e n e sh~a ~ ve appeared.

More h i g h l y f o c u s e d

r e v i e w s i n c l u d e phosphazene r e s e a r c h a t t h e I n d i a n I n s t i t u t e o f S c i e n c e ( w i t h e m p h a s i s o n a m i n o l y s i s r e a c t i o n s ) ,66 t h e s y n t h e s i s o f cyclophosphazenes t h r o u g h phosphazyne i n t e r m e d i a t e s 4 ’

and

p o l y m e r s d e r i v e d from o r g a n o f u n c t i o n a l p h o s p h a ~ e n e s . ~ ~ E x t e n d e d H G c k e l c a l c u l a t i o n s o n (NPF214 s u g g e s t t h a t t h e i n p l a n e p h o s p h o r u s and n i t r o g e n based o r b i t a l s a r e s i g n i f i c a n t l y s p l i t i n energy l e a d i n g t o n-charge t e r e d o n t h e n i t r o g e n atoms.68 a r e r e p o r t e d i n s e c t i o n 7,

d e n s i t y b e i n g l a r g e l y cen-

While s p e c i f i c c r y s t a l structures

s e v e r a l papers have appeared r e p o r t i n g

c o r r e l a t i o n s o f s t r u c t u r a l and s p e c t r o s c o p i c p r o p e r t i e s .

A

systematic survey o f attempts t o c o r r e l a t e s t r u c t u r a l parameters (bond l e n g t h s , a n g l e s and d i h e d r a l a n g l e s ) w i t h a b r o a d c r o s s s e c t i o n o f p h y s i c a l ( e l e c t r o n e g a t i v i t y , b a s i c i t y ) and spectroscop i c (NMR s h i f t s a n d c o u p l i n g c o n s t a n t s ,

NQR) p r o p e r t i e s f o r

c y c l o t r i p h o s p h a z e n e s has been p r e ~ e n t e d . ~ ’ S p e c i f i c systems e x p l o r e d i n more d e t a i l i n c l u d e :

the c o r r e l a t i o n o f 35Cl

NQR

f r e q u e n c i e s with s t r u c t u r e and phase changes f o r amino and s p i r o -

Orgarlophosphorus Chemisrry

340

c y c l i c p h o s p h a ~ e n e s ~ ' , t h e r e l a t i o n o f s t r u c t u r e t o NMR p r o p e r t i e s f o r s p i r o c y c l i c d e r i v a t i v e s 7 1 ,72, a c o m p a r i s o n o f s t r u c t u r e s

f o r ansa d e r i v a t i v e s 7 3 and c o r r e l a t i o n o f s t r u c t u r e and c o n f o r m a t i o n o f t h e e x o c y c l i c t r i p h e n y l p h o s p h a z o (Ph3P=N) solution.74975

function

in

R e s t r i c t e d r o t a t i o n a b o u t t h e phosphazene bond

i n t h e e x o c y c l i c N=PPh

s p e c t r u m a s l o w as

m o e i t y i s n o t o b s e r v e d i n t h e 31P NMR

I -50 C.75

shows t h a t t h e p l o t o f

Consideration o f add i t i o n a l data

t h e e x o c y c l i c P-N b o n d l e n g t h a g a i n s t t h e

sum o f i n t e r b o n d a n g l e s a b o u t n i t r o g e n g i v e s a s c a t t e r e d r a t h e r than a l i n e a r plot.76

The NMR d a t a (31P,

f o r numerous

13C)

s p i r o c y c l i c p h o s p h a z e n e s h a s b e e n ~ o l l e c t e d . ' ~ The mass s p e c t r a o f methylchlorocyclotriphosphazenes has been r e p o r t e d . 7 7

A

s t u d y o f t h e t e m p e r a t u r e dependence o f t h e v a p o r p r e s s u r e f o r S e r i e s N,P3Cl,-,(OCH2CF,CF,H), v a p o r i z a t i o n . 78

(?=1-6) g i v e s AH

0

a n d AS

0

the

of

P o t e n t i o m e t r i c and conductome t r i c a c i d - base

t i t r a t i o n s o f s e v e r a l cyclophosphazenes i n three d i f f e r e n t s o l v e n t s h a v e b e e n i n v e s t i g a t e d . 79 constants for

B a s i c i t y subs t it u e n t

s e v e r a l s p i r o c y c l i c d e r i v a t i v e s have been and show, f o r example, a v a r i a t i o n o f 4 p K a I u n i t s i n

t h e s e r i e s N3P3[0(CH2)301 X 4

(X=NHET,

morph.,

cyclopropylamine)

.8 0

Reports concerning modifications o f the c l a s s i c synthesis o f c h l o r o c y c l o p h o s p h a z e n e s ( a m m o n l y s i s o f PC15) c o n t i n u e t o appear.

Specific details include:

a m i n e (e.9. p y r i d i n e ) complex81,

i n i t i a l f o r m a t i o n o f a PC15-

r e a c t i o n with p y r i d i n e

hydrochloride/ammonium c h l o r i d e mixtures8* and m u l t i p l e a d d i t i o n o f PC15 d u r i n g t h e c o u r s e o f t h e r e a c t i o n . 8 3

A recipe for puri-

f i c a t i o n o f p o l y m e r i z a t i o n g r a d e (NPC12)3 h a s b e e n d i s ~ l o s e d . ' ~ T h e r m o l y s i s o f p h o s p h o r u s (111) a z i d e s l e a d s t o [NP(CMe3)23 other oligiocyclophosphazenes through cyclodiphosphazene

and

34 1

8: Phosphazenes i n t e r m e d i a t e s . l4

Thermolysis of

the s i l y l a t e d phosphoranimine,

MejSiN=P(OCH CF )MeCH2E ( E = R 2 P ~ R M e 2 S i ) g i v e s c y c l o p h o s p h a z e n e s 2 3

o r low molecular weight l i n e a r

material^.^'

Nucleophilic s u b s t i t u t i o n processes continue t o represent the most v a l u a b l e s y n t h e t i c pathways t o cyclophosphazene d e r i v a t i v e s . New p s e u d o h a l o g e n d e r i v a t i v e s a r e a v a i l a b l e i n c l u d i n g N3P3(OPh)5CN a n d t r a n s - N 3 P 3 ( N M e 2 ) 3 ( C N ) 3 .85 vatives of

Isocyanato d e ri -

t h e t y p e N3P3C14X(NCO) (X=C1,NH2)

have been r e p o r t e d . 8 6

The r e a c t i o n s o f a r o m a t i c P r i m a r y m i n e s N H 2 C 6 H 4 - p - X [ X = ~ , M e , 0 M e ) , w i t h (NPC12)3 h a v e b e e n s t u d i e d i n d e t a i l . disubstitution,

A t the stage o f

a l l i s o m e r s a r e formed w i t h t h e non-gerninal spe-

c i e s p r e d o m i n a t i n g b u t i n t h e presence o f Et3N t h e geminal d e r i v a t i v e i s formed e x c l u s i v e l y .

F o r X=OMe,

three isomers o f the

t r i s u b s t i t u t e d m a t e r i a l a r e formed w h i l e a l l t e t r a k i s d e r i v a t i v e s a r e e x c l u s i v e l y geminal.

The p e n t a a n d h e x a s u b s t i t u t e d d e r i v a t i -

ves a s w e l l a s t h e d i m e t h y l a m i n o v a t i v e s were a l s o r e p o r t e d . 8 7

o r methoxy, a r o m a t i c amino d e r i -

The k i n e t i c s o f t h e s e r e a c t i o n s

h a v e been e x a m i n e d a n d f o u n d t o f o l l o w a b i m o l e c u l a r SN2(P) E v, i d m e c h a n i s m i n THF a n d a c e t ~ n i t r i l e . ~ ~ ~ e~n c e f o r a c h a n g e i n m e c h a n i s m t o a b a s e c a t a l y z e d E1(C8) E t 3 N was p r e s e n t e d .

The t h r e e c o o r d i n a t e P ( v )

i n v o l v e d was t r a p p e d w i t h t r a c e w a t e r N3P3Cl4(NHC6H4Me)E

process i n the presence of intermediate

or a d d e d m e t h a n o l t o y i e l d

w h e r e E=O- a n d OMe r e s p e c t i v e l y .88989

r e p o r t i n d i c a t e s t h a t t h e r e a c t i o n o f 2,2-N3P3C14Ph2

A brief

with alkyla-

m i n e s goes by a one s t e p SN2(P) mechanism i n a c e t o n i t r i l e a n d t h r o u g h a d i s t i n c t p e n t a c o o r d i n a t e d i n t e r m e d i a t e i n THF.89 A d d i t i o n a l c o m p l e x i t i e s i n t h e r e a c t i o n s o f p r i m a r y amines have been uncovered i n a s t u d y o f t h e r e a c t i o n s o f 2 - s u b s t i t u t e d e t h y l a m i n e s w i t h (NPC12),.90

The r e a c t i o n s o f 2 - h a l o e t h y l a m i n e s

p r o v i d e t h e s e r i e s N3P3C16-n(NHCH2CH2X)n ( n = 1 , 2 , x = C l , B r ; n = 4 , x=Cl). I n contrast t o the corresponding reactions o f ethylamine where t h e n o n - g e m i n a l substitution,

isomers predominate a t the b i s stage o f

t h e g e m i n a l 2 - h a l o a m i n o d e r i v a t i v e s a r e formed.

In

a c e t o n i t r i l e n o n - g e m i n a l as w e l l a s t h e g e m i n a l p r o d u c t s a r e obtained.

A t

the stage of

product i s obtained.

The d i m e t h y l a m i n o d e r i v a t i v e s , N3P3-

(NMe2)6-,(NHCH2CH2NMe2)n contrast,

t e t r a s u b s t i t u t i o n only the geminal

w e r e a l s o p r e p a r e d . By way o f

(n=1,2,4),

the r e a c t i o n s w i t h 2-methoxyethylamine

(NHCH2CH20Me)2.90

The a z i r i d i n o l y s i s p a t t e r n s i n ( N P C 1 2 ) 3 , 4

l e a d i n g t o N3P3C16-n

(NC2H4)n

(2=1-6)

a n d N4P4Clg-n(NC2H4)n

(2=1-8) have been s t u d i e d i n d e t a i l . 9 1 t h e s e r e a c t i o n s has been p r o b e d . e q u a l amounts o f formed.

The s o l v e n t d e p e n d e n c e o f

In the t r i m e r i c series roughly

t h e g e m i n a l and n o n - g e m i n a l d e r i v a t i v e s a r e

I n terms o f f u r t h e r r e a c t i v i t y ,

gem was d e d u c e d .

g a v e 2,4-N3P3C14-

For the

tetramers,

2,6

the series trans > c i s z d i s u b s t i t u t i o n was p r e -

f e r r e d i n e t h e r o r benzene w h i l e an e q u a l m i x t u r e o f 2,4 d i s u b s t i t u t e d m a t e r i a l s was o b s e r v e d i n h e x a n e . was p r e f e r r e d a n d o n l y s m a l l a m o u n t s o f were observed.91 6C1-

(6 = 4 - d i m e t h y l a m i n o p y r i d i n e ,

the geminal derivatives

octane),

(N3P3E16)6+

1-methylimidazole, The r e a c t i o n s

were r e p o r t e d . 9 2

o f t h i o u r e a w i t h (NPCl2l3 have been examined. pyridine,

The t r a n s i s o m e r

T h r e e new a m i n o p h o s p h a z e n e s a l t s ,

1,4-diazabicycl0[2.2.23

and 2,6

I n C2H4C12 o r

N3P3[NHC(S)NH21 6 , i s f o r m e d w h i l e i n a c e t o n e s p i r o -

c y c l i c d e r i v a t i v e s i n v o l v i n g b o t h n i t r o g e n and s u l f u r b o n d i n g t o t h e p h o s p h a z e n e w e r e s u g g e s t e d .93*94 C o m p l e x e s o f p h o s p h a z e n e s w i t h Ag+,Cu2+

the thiourea

a n d Hg2+ h a v e m e t a l i o n s c o o r d i n a t e d

t o b o t h n i t r o g e n and s u l f u r c e n t e r s . 9 4

decomposition

Of

t h e t h i o u r e a p h o s p h a ~ e n e s ~a n ~ d, ~t h~ e i r m e t a l c o m p l e x e s 9 4 were

343 s t u d i e d u s i n g DTA.

The r e a c t i o n s o f p o l y a m i n e s w i t h ( N P C 1 2 ) J

continue to a t t r a c t attention. [NH(CH2)4NHI

The i n t e r a c t i o n o f N 3 P 3 C l 4 -

with N-ethylpropylenediamine

gives the mixed d i s p i r o

d e r i v a t i v e N3P3C12 [NH(CH2)4Nl-d [NH(CH2

1 3 N E t l .96

amino d e r i v a t i v e ,

,

N3PJC14[NH(CH2)JNHI

The s p i r o p r o p y l -

reacts w i t h long chain

d i a m i n e s t o g i v e s p e c i e s i n w h i c h two c y c l o t r i p h o s p h a z e n e s a r e l i n k e d b y t h e d i a m i n e , N3P3C1J[NH(CH2)3NHI NH(CH ) NHN3P3Cl3-

2 2

“H(CH2)3NHj

( ~ = 7 - 9 ) . ~ ’ The d e c i p t i v e s i m p l e 31P NHR s p e c t r a o f

The t h e s e m a t e r i a l s a r e r e s o l v e d i n t o ABC s y s t e m s a t 202 M H z . ~ ~ r e a c t i o n s o f N3PJC14[NH(CH

) NH] 2n g i v e s t h e b r i d g e d s p e c i e s 15 ( X 2

( ~ = 2 , 43 9~8 ~ ) ,w i t h s p e r m i n e

1

NH;

r e a c t i o n w i t h a z i r i d i n e g i v e s 1 5 (X2=NH(CH

2 2

show s i g n i f i c a n t l y N3P3C14(NC2H,)2.98

= NH(CH

2n

1

Y=Cl).

NH,

Further

Y=NC2H4) w h i c h

improved anticancer a c t i v i t y r e l a t i v e t o The s p e r m i n e b r i d g e d t e t r a c h l o r o d e r i v a t i v e ,

1 5 ( X = Y = C l ) r e a c t s w i t h a z i r i d i n e t o y i e l d 1 5 (X=Y=NC2H4) w h i c h has s u p e r i o r a n t i c a n c e r a c t i v i t y s i x murine tumor systems.

( c o m p a r e d t o N3P3C12(NC2H4)4) i n

The i m p r o v e m e n t i n e f f e c t i v e n e s s

r e l a t e d t o lower toxicity.99

The r e a c t i o n o f

is

the l i t h i u m enolate

o f a c e t a l d e h y d e w i t h (NPC12)4 g i v e s N4P4C18-n(OCH=CH2)11

-

(n=l,Z).

The p o w e r o f m o d e r n NMR t e c h n i q u e s was d e m o n s t r a t e d i n t h e q u a l i t a t i v e and q u a n t i t a t i v e a n a l y s i s o f t h e m i x t u r e o f b i s i s o m e r s w h i c h was a c c o m p l i s h e d b y a c o m b i n a t i o n o f J - r e s o l v e d

homonuclear

2-0 NMR, 31P h o m o n u c l e a r s h i f t c o r r e l a t e d 2-0 NMR a n d m i x t u r e simulation techniques.

A l l f i v e i s o m e r s were d e t e c t e d and as

opposed t o a l l o t h e r t e t r a m e r i c d e r i v a t i v e s , i s o m e r i s one o f

t h e 2 , 4 - d e r i v a t i v e ~ . ~ The ~ ~

the predominant

cis

isomer fs found

i n g r e a t e r t h a n s t a t i s t i c a l a m o u n t s i n N3P3C13(0CH=CH2)3. loo The e n o l a t e d e r i v e d f r o m a c e t o a c e t i c e s t e r r e a c t s w i t h

( NPC12 1

t o g i v e N3P3Cl6-,(0C

( CH3) =CHC ( 0I O E t In (!=3,6). lo’The

-

344

Organophosphorus Chemistry

r e a c t i o n of 2-chloroethanol

w i t h [ N P C 1 2 ) 3 p r o v i d e s 2,2-N3P3C14-

( O C H ~ C H , C ~ ) , . ~ ~ H y d r o x y t r y p t a m i n e s a l t s a r e u s e d t o p r e p a r e 16 [ 2 = 1 , 3 ) . lo'The p r o p a r g y l a l c o h o l a t e s N 3 P 3 ( 0 C H 2 C = ~ ~ ) (R=H,Me 6 ,Ph) h a v e b e e n p r e p a r e d f r o m (NPC12)3 a n d t h e s o d i u m s a l t o f

the

a l c o h 0 1 . l ~ ~The u t i l i t y o f p h a s e t r a n s f e r c a t a l y s i s i n p h o s p h a zene c h e m i s t r y has been d e m o n s t r a t e d i n t h e s y n t h e s i s o f N3P3C150Ar ,lo4 N3P3C16,n(OAr)n

-

-

("=1-4)

, l o 5 N3P3C16-n(OCH2CFj)n

a n d m i x e d OCH2(CF ) x ( X = H , F; Y = 1 - 1 0 ) - a l k o x y o r 2 Y a r y l o x y c y c l o p h o s p h a z e n e s ( l o w t e m p e r a t u r e h y d r a u l i c f l u i d s ) lo7 (n=l-4)lo6

from t h e a l c o h o l a t e s .

E x c e s s NaOCH2CF3 ( f o l l o w e d b y a c i d i f i c a -

t i o n ) C o n v e r t s N3P3(0CH2CF3)6 t o N3P3(0CH2CF3)50H.

The same

p r o d u c t c a n b e o b t a i n e d f r o m t h e r e a c t i o n o f N3P3C150- w i t h NaOCH2CF3 a n d HC1.108

F u r t h e r examples o f t h e g e m i n a l t o non-

g e m i n a l r e a r r a n g e m e n t have been n o t e d i n t h e a l c o h o l y s i s o f 2,2-N3P3C14(NH2)2 tions of

w i t h NaOMe, NaOEt a n d NaOCHMe2.109

The r e a c -

(NPCl2I3 w i t h polyethylene g l y c o l a l k y l e t h e r s y i e l d

h e x a s u b s t i t u t e d d e r i v a t i v e s w h i c h c a n be u s e d as phase t r a n s f e r The r e a c t i o n w i t h g l y c e r o l y i e l d s t h e s p i r o c y c l i c c a t a l y s t s . 'lo (17) and b r i d g e d (18) d e r i v a t i v e s . ' "

N3P3C14R2 (R=Ph, s u m m a r i z e d . 11'

The i n t e r a c t i o n s o f

NHCMe3) w i t h d i f u n c t i o n a l r e a g e n t s h a v e been The r e a c t i o n o f d i h y d r o x y p r o p a n e w i t h

N3P3C14(NHCMe3)2 g o e s t h r o u g h t h e i s o l a b l e N3P3(NHCMe3)2C130(CH2)30H t o t h e e x p e c t e d s p i r o c y c l i c d e r i v a t i v e ,

the structure of

w h i c h was e s t a b l i s h e d b y x-ray

The s t r u c t u r e o f

crystallography.

t h e s p i r o c y c l i c s p e c i e s i n i t i a l l y was a s s i g n e d a s t h e a n s a ( 2 , 4 ) d e r i v a t i v e f r o m 1 3 C a n d b a s i c i t y data."' wood a n d wood c o m p o n e n t s w i t h ( N P C l 2 I 3 , N3P3C13(0CH2CF3)3 o c c u r s c e l l u l o s e . '13

via

The m o d i f i c a t i o n o f N3P3C150Ph a n d

f o r m a t i o n o f P-0 b o n d s w i t h

Lignosulfonates

r e a c t with chlorophosphazenes t o

345

8: Phosphazenes g i v e h e a t and flame of

resistant materials. 113y114

2- a n d p-LiC6H4C(Me)=CH2

The r e a c t i o n

w i t h ( N P F 2 I 3 g i v e s r i s e t o t h e a-

m e t h y l s t y r e n e d e r i v a t i v e s N3P3F6-n[C,H4C(Me)=CHJ

-

(p=1,2).

Both

g e m i n a l and n o n - g e m i n a l d i s u b s t i t u t e d m a t e r i a l s a r e formed w i t h t h e c i s isomer predominating.1159116

A brief

report o f a

m u l t i s t e p s y n t h e s i s o f N3P3F5C6H4CH=CH2 i n v o l v i n g h y d r o s t a n n a t i o n o f N3P3F5C6H4C(OMe)=CH2 f o l l o w e d b y 6 - e l i m i n a t i o n a b l e . '16

The s y n t h e s i s o f N3P3F5C6H4C(0)R

i s avail-

(R=H,Me)

has been

accomplished u s i n g the a r y l l i t h i u m reagent i n the form o f the a c e t a l f o l l o w e d by r e m o v a l o f t h e p r o t e c t i n g group.1169117

The

s y n t h e s i s o f t h e m e t h y l s i l y l and m e t h y l s i l o x y l phosphazenes N 3 P 3C 1 5 R ,

2,2-N 3P 3 C 1 4R 2 a n d 2,2-N3P3C14(Me)R

CH2SiMe20SiMe3,

and CH2SiMe(OSiMe3I3b)

(R=CH2SiMe3,

involves,

i n t h e case o f

t h e mono a n d s y m m e t r i c a l d i s u b s t i t u t e d d e r i v a t i v e s , the appropriate Grignard reagent.

addition o f

The m i x e d d e r i v a t i v e c o u l d be

p r e p a r e d e i t h e r by r e a c t i o n o f t h e m o n o s u b s t i t u t e d d e r i v a t i v e w i t h methylmagnesium c h l o r i d e o r by t h e r e a c t i o n o f

(N3P3C14Me)2Cu-

(RI).

the

anion with the appropriate organosilicon iodide

The r e m a i n i n g c h l o r i n e a t o m s i n a l l t h e new d e r i v a t i v e s

c a n b e r e p l a c e d by t h e t r i f l u o r e t h o x y m o i e t y , h o w e v e r o f C-Si

some c a s e s

bond c l e a v a g e were a l s o o b s e r v e d i n t h e s e r e a c t i o n s . ' 1 8

The r e a c t i o n o f c o p p e r p h o s p h a z e n e a n i o n s w i t h k e t o n e s l e a d s t o d e r i v a t i v e s o f t h e t y p e 2,2-N3P3C14(R)CR1R20H.

The a s y m m e t r y a t

t h e e x o c y c l i c p o s i t i o n s r e s u l t s i n d i a s t e r e o t o p i c PC12 g r o u p s a n d hence

3Jpc-2pc-2

was o b s e r v e d i n t h e 31P nmr s p e c t r a . 8 6 9 1 1 9

o r g a n o m e t a l l i c phosphazenes c o n t i n u e t o be d i s c o v e r e d . b i s ( b e n z e n e ) c h r o m i u m b r i d g e d phosphazene,

New

A

N3P3F4(n-C6H5)2Cr,

p r e p a r e d f r o m (NPF2)3 a n d t h e 1,l'-dilithioorganometallic.

was

120

The s t e r e o c h e m i c a l p a t h w a y f o l l o w e d i n t h e r e a c t i o n s o f m e t a l l o -

346

Organoph osyh o rus Chem is1n f e r r o c e n y 1-

cenylphosphazenes i s complex.

The t r a n s a n n u l a r

p h o s p h a z e n e , 2,4-N3P3F4[C5H4)2Fel

r e a c t s w i t h mono o r d i l i t h i o -

f e r r o c e n e by s u c c e s s i v e r e p l a c e m e n t o f

f l u o r i n e atoms g e m i n a l t o

t h e o r g a n o m e t a l l i c g r o u p t o g i v e 1 9 (M=Fe:X=z=F, Z=F,

X=Y=C5H4FeC5H5).

Y = C ~ H ~ F ~ C ~ H ~

The same p a t h w a y i s f o l l o w e d b y t h e r u t h e -

n o c e n y l a n a l o g i n i t s r e a c t i o n s w i t h mono o r d i l i t h i o r u t h e n o c e n e .

I n the tetrameric series, 2,6-N,P4F6[(C5H4)2Fe~ (M=Fe,X=F,

,

Y=C5H4FeC H 5 5

g o u s compound 2 0 (M=Ru,

the transannular

ferrocenyl

derivative,

gives the non-geminal d e r i v a t i v e 20 w h i l e i n t h e ruthenium system t h e analoX=F,

Y=C5H4RuC5H5) a n d t h e d o u b l e t r a n -

s a n n u l a r d e r i v a t i v e 2 1 a r e formed.

M i x e d m e t a l l o c e n y l p h e n y l and

m e t h y l d e r i v a t i v e s have a l s o been p r e p a r e d . l Z 1

The r e a c t i o n o f

N3P3F5Ph w i t h d i l i t h i o f e r r o c e n e g i v e s t h e n o n - g e m i n a l d e r i v a t i v e

19 (M=Fe,

X=Y=F,

19 (M=Fe,

X=Y=Z=F) r e a c t s w i t h m e t h y l l i t h i u m t o g i v e t h e g e m i n a l

Z=Ph).

d e r i v a t i v e 1 9 (M=Fe,

The t r a n s a n n u l a r f e r r o c e n y l

X=Me,

Y = Z = F ) and w i t h sodium t r i f l u o r o -

e t h o x i d e t o g i v e t h e n o n - g e m i n a l d e r i v a t i v e 1 9 (M=Fe, Z=OCH2CF3).

derivative

X=Y=F,

Additional t r i f l u o r o e t h o x i d e s u b s t i t u t i o n s occurs

geminal t o the metallocenyl u n i t eventually leading t o the e n t i r e Another s e r i e s o f t r i f l u o r o e t h o x y d e r i v a t i v e s o f 1 9 (M=Fe) .lZ1 r o u t e t o o r g a n o m e t a l l i c phosphazene d e r i v a t i v e s i n v o l v e s t h e r e a c t i o n o f the cyclophosphazene anion,

N3P3C14Ph(BEt3)-Li+

with

cyclopentadienyl metal i o d i d e s t o g i v e the geminal d e r i v a t i v e s 22 (n=3,M=Cr,Mo,W;

5=2, M=Fe,Ru) .122

Reactions a t the exocyclic p o s i t i o n of

phosphazenes r e p r e s e n t

t h e o t h e r m a j o r r o u t e t o new c y c l o p h o s p h a z e n e d e r i v a t i v e s .

The

S t a u d i n g e r r e a c t i o n o f t h e a z i r i d i n y l phosphazene a z i d e s , 2,2-N3P3(NC2~4)4(N3)2,

w i t h p h o s p h i n e s o c c u r s a t o n l y one o f t h e

a z i d e g r o u p s r e s u l t i n g i n f o r m a t i o n o f N3P3(NC2H4)4(N3)N=PR3. 123

8: Phosphazenes

CI,P\ N ‘’

347

PCI,

FP,-N=PF

CI,P‘ (21)

(20)

MtO

’

\N

‘N’

’

FhZ

\c/o

\P=N

IIPCI,

I

-C

do “H

-/ C.

N

N‘

348

Organophosphorus Chemistry

The r e a c t i o n s o f carbamates.86

i s o c y a n a t o phosphazenes w i t h a l c o h o l s g i v e s The r e a c t i o n o f

i n a c e t o n i t r i l e gives,

( N P C 1 2 ) 3 w i t h AgNCO a n d a l c o h o l s

i n a d d i t i o n t o the carbamates, the novel

s p i r o c y c l i c d e r i v a t i v e 23 v i a s o l v e n t a t t a c k . 8 6

Quaternization

o f n u m e r o u s t r i m e r i c a n d t e t r a m e r i c c y c l o p h o s p h a z e n e s w i t h Me1 o r

for t h e p i p e r i d i n o

Ph3P o c c u r s a t t h e e x o c y c l i c p o s i t i o n s e x c e p t

d e r i v a t i v e where t h e e n d o c y c l i c n i t r o g e n atoms were t h e r e a c t i v e sites.lZ4

The q u a t e r n i z e d s p e c i e s w e r e a l l o w e d t o r e a c t w i t h t h e

lithium s a l t of

7,7,8,8-tetracyanoquinodimethane

g e n e r a t e TCNQ-phosphazene s a l t s . t h e s e s a l t s was m e a s u r e d . 1 2 4

(TCNQ) t o

The e l e c t r i c a l c o n d u c t i v i t y o f

Carbon c h a i n polymers w i t h

c y c l o p h o s p h a z e n e s a s s u b s t i t u e n t s were d e r i v e d f r o m p o l y m e r i z a t i o n o f N3P3F5C6H4C(Me)=CHz,116 N3PJ(OCH2C=CR)6.103

N 3 P 3 F 5 C 6 H4 CH=CH2116 a n d

Weak 1 : l c o m p l e x e s o f N 3 P 3 ( 0 P h I 6 w i t h

TaF5 h a v e b e e n d e t e c t e d b y nmr s p e c t r o s c o p y . 1 2 ' o f B-arylamides

The t r e a t m e n t

w i t h ( N P C l 2 l 3 g i v e s 3,4-dihydroisoquinolines

dehydration ring-closure

by a

route.Iz6

Numerous a p p l i c a t i o n s o f c y c l o p h o s p h a z e n e s , i n a d d i t i o n t o t h o s e q u o t e d above,

have been noted.

Use a s f l a m e r e t a r d e n t s h a s

b e e n r e p o r t e d f o r many s y s t e m s i n c l u d i n g :

derivatives o f

( N P C l 2 I 3 w i t h b i f u n c t i o n a l t h i o l s o f t h e t y p e AH(CR1R2)1?SH

)I

(~=3-12) com2 n b i n e d w i t h (C1CH2CHC1CH20)3P0 f o r r a y o n , I z 8 c h i t s a n - c h l o r o p h o s (A=O,NH;

m=1-4)

f o r polymers,127

[NP(OR1)(OR

p h a z e n e d e r i v a t i v e s for t e x t i l e s a n d p l a s t i c p r o d u c t s tris(2-phenylenedixoyl-phosphazenes

for 2-cyanoacrylate

a d h e s i v e s , 130 b r o m o p h e n o x y p h o s p h a z e n e s f o r i n j e c t e d m o l d e d d i c y c l o p e n t a d i e n e p o l y m e r s , 131 d i a m i n o p h o s p h a z e n e s f o r textiles

,

a m i n o p r o p y l t r i e t h o x y s i l a n e - p h ~ s p h a z e n e s a~n~d~ o t h e r

c h l o r o p h o s p h a ~ e n e s ~f o~ r ~ wood ~ ~ ~ ~a n d a l k o x y p h o s p h a z e n e s f o r

8: Phosphazenes

349

s e m i c o n d u c t o r d e v i c e s . 134

C u r i n g o f epoxy r e s i n s w i t h

c y c l o p h o s p h a z e n e s h a s b e e n r e p o r t e d u s i n g a m i n o p h e n o x y , 135 a l l y l o x y , 136 d i a m i n o t e t r a o r g a n o ( a 1 k o x y , a r y l o x y , a l k y l t , h i o

and

a r y l t h i ~ ) 'a~n d~ i s o p r o p y l a r n i n o p h o s p h a z e n e s . 138 Propoxyphosphazene c a t a l y s t s have been used as c a t a l y s t s i n oxaz o l i n e d e r i v a t i v e p o l y m e r i z a t i o n . 139

Heat r e s i s t a n t elastomers

h a v e b e e n c l a i m e d t o be p r e p a r e d b y g r a f t tion of

and b l o c k c o p o l y m e r i z a -

( N P C 1 2 ) 3 w i t h c y c l o s i l o x a n e s u s i n g C1S03H a s a

c a t a l y s t . 140

F l u o r o a l k o x y p h o s p h a z e n e s a r e v e r y p r o m i s i n g pump

o i l materials.1419142

The u s e o f p h o s p h a z e n e d e r i v a t i v e s a s d e n -

t a l m a t e r i a l s h a s b e e n r e p o r t e d . 143 4.

Cyclophospha(thia)zenes Cyclophospha(thia1zene chemistry covering the period of

t o t h e e a r l y e i g h t i e s has been reviewed.14' n i t r o g e n a t o m s o f 1,3- a n d 1 , 5 - ( P h 2 P N ) 2 ( S N )

1969

The e n d o c y c l i c s e r v e as b a s i c s i t e s

i n r e a c t i o n s w i t h L e w i s and p r o t o n i c a c i d s . 1 4 5

S e l e c t i v e 15N

l a b e l i n g e x p e r i m e n t s show t h a t n o n i t r o g e n a t o m s c r a m b l i n g o c c u r s i n t h e t h e r m o l y s i s o f t h e b i c y c l i c m a t e r i a l 24.146

The r e a c t i o n s

o f t h i a z e n e s w i t h p h o s p h i n e s c a n l e a d t o t h i a z e n e s w i t h endoe x o c y c l i c p h o s p h a z e n e m o i e t i e s . 144

or

Reactions reported t h i s year

f o c u s o n f o r m a t i o n o f c y c l o t h i a z e n e s w i t h e x o c y c l i c phosphazene substituents.

I n t h e r e a c t i o n o f S4N4 w i t h a m i x t u r e o f

(p-CH3C6H4)PPh2, obtained.

Ph3P a n d

a m i x t u r e o f t h e RPh2P=NS3N3 d e r i v a t i v e s a r e

I f however, t h e p - t o y 1 g r o u p i s r e p l a c e d by t h e

m o r p h o l i n e m o i e t y a m i x t u r e o f (morph)Ph2P=NS3N3 a n d 1,5-(Ph3P=N)2S4N4

i s formed.

By way o f f u r t h e r c o n t r a s t ,

the

r e a c t i o n w i t h two m o l a r e q u i v a l e n t s o f t h e t o l y l d i p h e n y l p h o s p h i n e g i v e s 1,5- [_p-CH3C6H4)Ph2P=d (Ph3P=N)S4N4 a n d [p-CH

-

C H ) P h 2 P = d (Ph3P=N)2S+S4N5-. 3 6 4

147

The r e a c t i o n o f Ph3P w i t h

350

Organophosphorus Chemist n

t h e b i c y c l i c t h i a z y l h e t e r o c y c l e PhCN5S3 p r o d u c e s a c y c l o t h i a z e n e , 25, w i t h t h e t r i p h e n y l p h o s p h a z o g r o u p i n t h e endo p o s i t i o n .

The

corresponding r e a c t i o n with t r i p h e n y l a r s i n e produces both the endo a n d exo c o n f i g u r a t i o n a l

isorners.14'

The r e a c t i o n s o f

(1=1,2) w i t h R L i (R=Me, Me3C) f o l l o w e d b y

(NPCl2),(NS0Ph),-,

i s o p r o p a n o l a r e complex g o i n g t h r o u g h an i n i t i a l m e t a l - h a l o g e n exchange and l e a d i n g t o hydridoisopropoxycyclophospha(thia)zenes,

NPH(OPri)(NPC12)1~NSOPh)z-~

(n=O,l),

various a l k y l s u b s t i t u t e d derivatives.149 [NP(NH2)l 2 ( N S 0 z ) -

and m i x t u r e s o f The s o d i u m s a l t o f t h e

a n i o n has been p r e p a r e d and t h e d i s s o c i a t i o n

c o n s t a n t o f t h e p a r e n t a c i d has been measured.15' 5.

M i s c e l l a n e o u s P h o s p h a z e n e - C o n t a i n i n g R i n q Systems Due t o t h e i n t i m a t e r e l a t i o n s h i p b e t w e e n m o n o p h o s p h a z e n e s a n d

c y c l o d i p h o s p h a z a n e s , t h e r e a r e numerous examples o f m i s c e l l a n e o u s r i n g s y s t e m s c o n t a i n i n g endo

or e x o c y c l i c p h o s p h a z e n e u n i t s i n a

r e v i e w cyclophosph( v)azanes.151

The c h e m i s t r y o f t r i a z a p h o s p h o -

l e s i n c l u d i n g p h o s p h a z e n e i n t e r m e d i a t e s i n some o f t h e i r r e a c t i o n s has been reviewed.15'

The s y n t h e s i s o f t h e f i r s t

m o n o u n s a t u r a t e d d i a z a d i p h o s p h e t i n e s 26 ( R = i P r ; Z=N( i P r ) 2 ) 3 3 (R=Me3Si,

a n d t h e r e l a t e d 1, 3 - d i a z a - 2 X 5 ,

Z=X=CH(SiMe3)2,

X=C1,N3;

Y=:;

4X5 d i p h o s p h e t e n e 26

Y=NSiMe3)l4 have been p r e p a r e d .

L i t h i a t i o n o f one o f t h e P - m e t h y l g r o u p s i n Me2Si(C1)CH2CH2SiMe2N=P(OCH2CF3)Me2 i s f o l l o w e d b y a n i n t r a m o l e c u l a r r e a c t i o n w i t h t h e t e r m i n a l s i l i c o n - c h l o r i n e bond t o form t h e c y c l i c r n o n ~ p h o s p h a z e n e . ~ The ~ imidophosphonate, 2 7 , w h i c h is i n e q u i l i b r i u m w i t h i t s dimer, undergoes,

upon d i s t i l l a t i o n ,

r e a r r a n g e m e n t t o t h e a m i d o p h o s p h i t e b y m i g r a t i o n o f t h e -CH2NEt2 group from the phosphorus t o the n i t r o g e n center.lS3 PhP(0)(NHCONHNMe2)

Heating of

i n t h e p r e s e n c e o f MeX y i e l d s t h e m o n o p h o s p h a -

35 1

8: Phosphazenes

z e n e 28 w h i c h i s i n e q u i l i b r i u m w i t h t h e h e a v i l y f a v o r e d t a u t o m e r formed by m i g r a t i o n o f t h e h y d r o x y l p r o t o n t o t h e phosphazene n i t r o g e n atoms.154

The 4 + 2 c y c l o a d d i t i o n r e a c t i o n o f N-

vinyliminophosphoranes with electron d e f i c i e n t acetylenes gives 1 ,2-X5-azaphosphorines(29) .155

S2P(N3l2-

The r e a c t i o n o f P q S l 0 w i t h t h e

a n i o n 1 5 6 o r b e n z ~ n i t r i l e ’ ~ ’l e a d s t o r e p l a c e m e n t o f a

e n d o c y c l i c s u l f u r a t o m b y a n i t r o g e n a t o m t o g i v e t h e P4S9Nm o n o p h o s p h a z e n e a n i o n (30).

The d i p h o s p h a z e n e c o n t a i n i n g r i n g ,

5 , h a s been p r e p a r e d by t h e S t a u d i n g e r r e a c t i o n . 2 1

Further

examples o f c y c l o p h o s p h a z e n e s w i t h e n d o c y c l i c m e t a l atoms have been r e p o r t e d .

The r e a c t i o n o f t h e l i n e a r p h o s p h a z e n e s a l t ,

“H2PPh2NPPh2NH21+C1-

n = 5 ; M=W, n = 6 ) a n d

w i t h m e t a l c h l o r i d e s y i e l d s 3 1 (E=N,M=Nb, w i t h C13MoN p r o v i d e s 30 (E=N1 M=Mo,

The r e a c t i o n s o f Me3SiNPPh2CH2PPh2NSiMe3 w i t h SeOC12 t o g i v e 32 (M=Se,

X = C l , 1 = 2 ) , w i t h TeC14 t o g i v e 32 (M=Te,

w i t h W X 6 t o g i v e 32 (M=W,

X=F,Cl,

X = C l , n=2), a n d

n = 4 ) have been r e p o r t e d .

The

d e h y d r o h a l o g e n a t i o n o f t h e c h l o r o t u n g s t e n d e r i v a t i v e w i t h DBU g i v e s 31 (E=CH,

M=W,

X=C1, n = 3 ) . 1 5 9

6. P o l y ( p h o s p h a z e n e s ) This s e c t i o n i s devoted t o polymers c o n t a i n i n g open-chain phosphazenes.

C y c l o l i n e a r and c y c l o m a t r i x phosphazene p o l y m e r s

a r e c o v e r e d i n s e c t i o n 3.

Reviews i n c l u d e an overview o f synthe-

sis, u n i q u e p r o p e r t i e s a n d a p p l i c a t i o n s o f p o l y ( o r g a n o p h o s phazenes),16’

a summary o f t h e c u r r e n t s t a t u s o f p o l y ( p h o s -

phazene) chemistry,161 t h e p r e p a r a t i o n o f poly(phosphazenes) w i t h o r g a n o m e t a l l i c s u b ~ t i t u e n t sa ~n d~ t h e c h e m i s t r y o f f l u o r a l k o x y and a r y l o x y phosphazene rubbers.16’

Reviews i n l e s s a c c e s s i b l e

sources i n c l u d e a survey o f the p r e p a r a t i o n o f poly(organoh o s p h a z e n e s ) a n d a p p l i c a t i o n s t o p h a r m a c e u t i c a l s ( i n C h i n e s e ) 16’

Organophosphorus Chemistry

352

SiMe3 (28)

(29)

A

E Phzp/’

Ph2i iPh2

‘PPhz

N

N

M ‘’ Xn

(32)

F

/Q

4“B

P ‘

N

CN (33)

I

II

F2\N/p\F

(34)

..-‘

8: Phosphazenes

353

a l o n g w i t h p h o s p h a z e n e p o l y m e r i z a t i o n ( i n F i n n i s h ) .164 The s y n t h e s i s o f p o l y ( p h o s p h a z e n e s ) poly(dichlorophosphazene),

(NPC12),,

i n general,

and

i n p a r t i c u l a r i s the

focus

o f several recent investigations.

I n the r i n g opening polymeri-

zation of

is a b s e n t a t low c o n v e r s i o n

(NPC12)3,

chain transfer

b u t t h e p o l y d i s p e r s i t y i n c r e a s e s t o 1.39 a t 7 4 % c o n v e r s i o n . 165 The e f f e c t s o f v a r i o u s a d d i t i v e s on t h e p o l y m e r i z a t i o n o f (NPCl2I3 have been i n v e s t i g a t e d .

The t e t r a m e r ,

(NPC12)4,

has

b o t h c a t a l y t i c and i n h i b i t i n g e f f e c t s o n t h e p o l y m e r i z a t i o n . 1 6 6 The c a t a l y t i c e f f e c t

o f Ph4Sn h a s b e e n t r a c e d t o p h e n y l e x c h a n g e

between phosphorus and tin.167 (NPC12)3

The s o l u t i o n p o l y m e r i z a t i o n o f

i n CS2 p r o v i d e s a h i g h m o l e c u l a r w e i g h t ,

p r o d u c t .168

uncross-linked

P h o s p h a z e n e p o l y m e r s w i t h PXC12 (X=O,S)

a r e o b t a i n e d by t h e s e l f - c o n d e n s a t i o n

end g r o u p s

r e a c t i o n o f C12P(X)N=PC1

3

( w i t h e l i m i n a t i o n o f PXC13) i n a n i n e r t s 0 1 v e n t . l ~ ~P l a s m a p o l y m e r i z a t i o n o f (NPCl2I3 proceeds a t lower temperature b u t gives lower molecular weight products than thermal p 0 1 y m e r i z a t i o n . l ~ ~ The s t a b i l i t y o f ( N P C l 1 i n solution i s m a r k e d l y i m p r o v e d b y 2n a d d i t i o n o f a n o r g a n o m e t a l l i c h a l i d e (M=Si,Ge,Sn,Ti) and a t e r t i a r y amine t o t h e solution.171 (NPC1 )

211

Recipes f o r the p u r i f i c a t i o n of

have been reported.849172

S e v e r a l o t h e r monomers h a v e

been d i r e c t l y c o n v e r t e d t o poly(phosphazenes).

The e f f e c t

of

organometallic s u b s t i t u e n t s on the p o l y m e r i z a t i o n o f c y c l o p h o s p h a z e n e s has been examined.

The r e l e a s e o f r i n g s t r a i n

i n d u c e d by t r a n s a n n u l a r b r i d g i n g f e r r o c e n y l o r r u t h e n o c e n y l groups i s an important f a c t o r i n the p o l y m e r i z a t i o n o f cyclotetramers with transannular substituents but the e f f e c t i s less s i g n i f i c a n t i n the t r i m e r i c series.173 weight

e.e x t e n t

A study of molecular

o f r e a c t i o n f o r the formation of

354

Organophosphorus Chemistry

(RR'PN),

-

(R,R'=Me,Et

,Ph)

b y t h e r m o l y s i s o f Me3SiN=P(OCH2CF3)RR'

i n d i c a t e s t h a t a c h a i n g r o w t h mechanism i s o p e r a t i v e . 1 7 4 9 1 7 5 C o t h e r m o l y s i s o f Me3SiN=P(OCH2CF3)Me2 w i t h Me3SiN=P(OCH CF )Me2 3 CH2E (E=R2P; [(NPMe

R M e 2 S i ) g i v e s h i g h MW s p e c i e s o f t h e t y p e

1

1

(NPMeCH E ) 40 The p o l y m e r i z a t i o n o f 2 Y 2' RP(0)(NH,)2 gives poly(oxaphosphazanes) which are i n e q u i l i b r i u m

2x

w i t h t h e h y d r o x y p h o s p h a z e n e s w h i c h c a n be c o n v e r t e d t o t h e

m e t h o x y p h o s p h a z e n e s by r e a c t i o n w i t h d i a ~ o r n e t h a n e . ' ~ ~ The e l i m i n a t i o n o f NOCl f r o m C12P(0)N=PC120N0 l e a d s t o C l 2 P ( 0 ) CNPCl203 nN0.36 R e a c t i o n s i n w h i c h t h e c h l o r i n e a t o m s i n (NPC1 ) a r e r e p l a c e d by 2 n other f u n c t i o n a l i t i e s represent another route t o poly(phosphazenes).

L i q u i d c r y s t a l l i n e p o l y m e r s have been

o b t a i n e d from the r e a c t i o n s of

(NPC1 )

2n

with phenolates

which a r e chain extended w i t h 2-chloroethanol s p a c e r s 1 7 7 o r w i t h NaO(Et0)3PC6H40Me. 17'

polybis(pyroly1)phosphazenes

flexible

The p r e p a r a t i o n o f

from the potassium s a l t of p y r r o l

a n d (NPC12)n h a s b e e n r e p o r t e d .

The m a t e r i a l becomes s e m i c o n -

d u c t i n g upon e l e c t r o c h e m i c a l o x i d a t i o n w h i l e more h i g h l y c o n d u c t i n g m a t e r i a l s a r e o b t a i n e d by t h e r m o l y s i s o f

the parent

Expoxy phosphazenes a r e o b t a i n e d f r o m t h e r e a c t i o n s

p o l y m e r . 179

o f (NPC12)11 w i t h e p i c h l o r o h y d r i n u s i n g F r i e d e l - C r a f t s catalysts.

The r e a c t i o n s o f

(NPC1 1 w i t h h y d r o x y c a r b a z o l e s 2 n

or h y d r o x y - o r aminonapthalenes have been r e p o r t e d t o g i v e p o l y mers u s e f u l as p h o t o c o n d u c t i n g m a t e r i a l s . 1 8 1

Controlled release

o f d r u g s appended t o b i o d e g r a d a b l e p o l y ( p h o s p h a z e n e s ) h a v e been examined.

The d r u g may b e i o n i c a l l y a s s o c i a t e d w i t h a p h o s p h a -

zene s u b s t i t u e n t s 1 8 2

o r c o v a l e n t l y bound t h r o u g h spacers as i n

t h e case o f t h e e t h y l e s t e r s o f p h e n y l a c e t y l l y s i n e and naproxen. la3

The r e l e a s e o f t h e n a p r o x e n d e r i v a t i v e was

8: Phosphazenes

355

c o n t r o l l e d b y t h e r a t e o f h y d r 0 1 y s i s . l ~ ~A r e c i p e f o r

t h e manu-

f a c t u r e o f a l k o x y p h o s p h a z e n e p o l y m e r s h a s b e e n d i s c l o s e d . la5 The r e m a i n i n g m a j o r s y n t h e t i c r o u t e t o new p o l y p h o s p h a z e n e d e r i v a t i ves i s t h e r e a c t i o n o f o r g a n o s u b s t i t u e n t s on t h e poly(phosphazene1. (NPMePh),

-

The l i t h i a t i o n o f t h e m e t h y l g r o u p s i n

p r o v i d e s a n i o n s w h i c h c a n be r e a c t e d w i t h v a r i o u s

f u n c t i o n a l c h l o r ~ s i l a n e os r ~ k~e t ~o n~e s~ (~i n c l u d i n g f e r r o c e n y l k e t o n e s ) t o y i e l d a l c o h o l s a s s u b ~ t i t u e n t s . ~ ' No c h a i n c l e a v a g e was o b s e r v e d i n t h e s e d e r i v a t i z a t i o n r e a c t i o n s .

Grafting of

1-

s e l e c t e d o r g a n i c polymers t o p o l y Cbis (4-isopropylphenoxy phosphazenes]

c a n be a c c o m p l i s h e d by f o r m i n g a p e r o x i d e a t t h e

i s o p r o p o x y s i t e and h e a t i n g t h i s m a t e r i a l w i t h s t y r e n e .

The

r e s u l t i n g m a t e r i a l s show i n c r e a s e d t h e r m a l s t a b i l i t y o v e r p o l y s t y r e n e . 187 e.g. -

Quaternization o f poly(phosphazene)

derivatives,

a m i n o p h o s p h a z e n e , b y Me1 o r PhjP p r o v i d e s p o l y m e r i c s a l t s

w h i c h c a n be c o n v e r t e d t o tetracyanoquinodimethane(TCNQ)

salts.

The e l e c t r i c a l c o n d u c t i v i t i e s o f t h e m a t e r i a l s h a v e b e e n Radiation cross-linking r e p o r t e d . lZ4 phospharenes and methylamino b e e n examined.188

o f 2-methoxyethoxyl

o r t r i f l u o r o e t h o x y d e r i v a t i v e s has

The g e l f o r m a t i o n b e h a v i o r o f a r y l a m i n o o r

a r y l o x y phosphazenes exposed t o r a d i a t i o n h a s been s t u d i e d q u a n t i t a t i v e l y . lag C h a r a c t e r i z a t i o n o f v a r i o u s p o l y ( p h o s p h a z e n e s ) h a s been t h e focus o f several investigations. s t r u c t u r e o f (NPC12),

A redetermination o f the c r y s t a l

i n d i c a t e s a g l i d e conformation r a t h e r than

t h e 2/1 h e l i x conformation p r e v i o u s l y proposed. controversial level,

A t a more

t h i s s t u d y s u g g e s t e d a l t e r n a t i v e s i n g l e (167

pm) a n d d o u b l e ( 1 4 4 pm) p h o s p h o r u s - n i t F o g e n bonds.19' e l e c t r o n i c s t r u c t u r e o f (NPC12),,

The

i n c l u d i n g band s t r u c t u r e ,

was

356

Organophosphorus Chemistr?;

p r o b e d u s i n g c a l c u l a t i o n s o f t h e SCF-CONDO

Poly[bis(trifluoroethoxy)phosphazenel

,

type.191

PBFP,

h a s been t h e s u b j e c t

o f numerous i n v e s t i g a t i o n s w i t h m o r p h o l o g i c a l s t u d i e s r e c e i v i n g t h e most a t t e n t i o n .

P r o p e r t i e s o f PBFP s u c h a s c r y s t a l l i n i t y

l e v e l s a n d t r a n s i t i o n t e m p e r a t u r e s h a v e b e e n shown t o v a r y w i t h the r e a c t i o n time used i n i t s preparation.

The o b s e r v a t i o n t h a t

t h e c r y s t a l l i n i t y c a n b e l o w e r e d by r e a c t i o n w i t h e x c e s s sodium t r i f l u o r o e t h o x i d e has been r e l a t e d t o s i d e group cleavage reactions.lo8

C h a n g e s i n s o l u t i o n g r o w n c r y s t a l s o f PBFP w h i c h

o c c u r upon h e a t i n g t h r o u g h t h e t h e r m o t r o p i c t r a n s i t i o n i n v o l v e c h a i n e x t e n s i o n . 192

Phase changes i n p o l y ( d i p h e n o x y p h o s p h a z e n e )

a l s o h a v e b e e n s t u d i e d . 19' crystals192

F r a c t u r e s u r f a c e m o r p h o l o g i e s i n PBFP

a n d s o l u t i o n c a s t f i l m s 1 9 3 h a v e been s t u d i e d by R e l a x a t i o n b e h a v i o r i n t h e 'ti

scanning elecron microscopy.

NMR

o f PBFP h a s b e e n r e l a t e d t o v a r i a t i o n s i n c h a i n m o t i o n i n d i f f e r e n t ( c r y s t a l l i n e , amphorous, molecules.194

a.) states

of the

Molecular motions i n a series of poly-

( d i a l k o x y p h o s p h a z e n e s ) h a v e b e e n s t u d i e d b y N M R a n d show a weak dependence o f t h e m o t i o n o f t h e s u b s t i t u e n t s and f l e x i b i l i t y o f t h e m a i n c h a i n . 195

Single c r y s t a l s of poly[bis(phenylphenoxy)l-

and C b i s ( d i m e t h y 1I p h o s p h a z e n e l have been examined by t r a n s m i s s i o n e l e c t r o n microscopy l e a d i n g t o l a t t i c e imaging.

The a r y l o x y

d e r i v a t i v e s exhibited thermotropic behavior but the methyl de ri v a t i v e s d i d not.196

DSC a n d X - r a y

s t u d i e s o f t h e phase t r a n -

s i t i o n s o f p o l y [ b i s - ( 4 - i s o p r o p y l p h e n o x y ) p h o s p h a z e n e l show t h a t p h a s e t r a n s i t i o n b e h a v i o r upon g o i n g t h r o u g h t h e mesophase d e p e n d s o n t h e h e a t i n g r a t e . 19'

Dilute solution characterization

using such techniques such as l i g h t s a t t e r i n g , h a v e b e e n a p p l i e d t o PBFP.

gpc,

viscosity

P o l y m e r i c a g g r e g a t e s were d e t e c t e d i n

8: Phosphazenes

357

solution.198

S i m i l a r measurements a p p l i e d t o p o l y -

(alkyl/aryl)phosphazenes, [(R(Ph)PN)x(R2PN)yln -

mations for

(NPRR’

(R=Me,Et),

In(R,R’=Me,Et

and

show r a n d o m c o i l s o l u t i o n c o n f o r -

these-materials.174’175

The c r o s s - l i n k i n g

a n d mechanism o f e x p o x y r e s i n - p o l y e s t e r poly(phosphazene)

,Ph)

-

kinetics

blends containing

f i r e p r o o f i n g a g e n t s h a v e b e e n i n v e s t i g a t e d . 199

Complexes between a l k a l i m e t a l s a l t s and phosphazenes h a v i n g p o l y e t h e r s i d e c h a i n s show g r e a t p r o m i s e a s p o l y m e r i c e l e c t r o l y t e s f o r b a t t e r i e s and hence have been t h e s u b j e c t o f i n t e n s e study.

The b a s i c s y n t h e s i s a n d c o n d u c t i v i t y o f t h e s e m a t e r i a l s

have been d e s c r i b e d 2 0 0 9 2 0 1 and patented.’02

The c o n d u c t i v i t y o f

t h e s e s y s t e m s was h i g h e r t h a n s e v e r a l o r g a n i c p o l y m e r - m e t a l s a l t complexes.203

Cross-linked m a t e r i a l s derived from r e a c t i o n s o f

(NPC12)s1 w i t h p o l y e t h y l e n e g l y c o l d i a l k o x i d e s h a v e s i m i l a r c o n d u c t i v i t i e s but improved dimensional s t a b i l i t y r e l a t i v e t o the uncross-linked

materials.204

I o n t r a n s p o r t numbers f o r t h e

phosphazene based e l e c t r o l y t e s have been measured.205

Another

a r e a o f g r o w i n g i n t e r e s t i n polyphosphazene c h e m i s t r y i s t h e use a s membranes.

A l c o h o l s e x h i b i t h i g h d i f f u s i o n c o e f f i c i e n t s and

l o w a c t i v a t i o n e n e r g y f o r d i f f u s i o n a c r o s s PBFP membranes.206 Gas p e r m e a b i l i t y a n d s e l e c t i v i t y b e t w e e n O 2 a n d N2 w e r e m e a s u r e d f o r v a r i o u s p o l y ( o r g a n o p h o s p h a z e n e ) membranes. m e a b i l i t y was o b s e r v e d f o r [NP(NHPr”) ( N H E t ) ] s e l e c t i v i t y f o r [NP(OC6H4C1)J

E.207

-

The h i g h e s t p e r and t h e h i g h e s t

Mechanical p r o p e r t i e s such

t e a r 2 0 8 and t e n s i l e s t r e n g t h e l o n g a t i o n 2 0 9 have been d e t e r m i n e d

for f l u o r o a l k o x y p h o s p h a z e n e p o l y m e r s . A c o u l o m e t r i c m e t h o d f o r d e t e r m i n a t i o n o f t r a c e c h l o r i n e i n phosphazene p o l y m e r s has been d e s c r i b e d .210 I n a d d i t i o n t o t h e s t u d i e s c i t e d above,

numerous r e f e r e n c e s

358

Organophosphorub Chemistn

t o a p p l i c a t i o n s o f poly(phosphazenes1 have appeared. polyfluoroalkoxy foams211

and a r y l o x y phosphazene rubbers16’

have been surveyed.

a r e a v a i l a b l e .212 for

water-insoluble

The u s e s o f and

R e c i p e s f o r p r o d u c t i o n o f t h e s e foams

Amidophosphosphazene p o l y m e r s have been used fiber

f i r e p r o o f i n g agents.

9214

Fluoroalkoxyphosphazenes are s u i t a b l e m a t e r i a l s for

denture

1 i n i n c ~ T ~ ~ P h y s i cp ar ol p e r t i e s o f e x p o x y r e s i n s s u c h a s h e a t resistance,

crack resistance,

etc. -

o f p o l y ( p h o s p h a z e n e s ) .216-218

are improved with the a d d i t i o n

A r y l o x y p h o s p h a z e n e s have been used

a s oxygen r e a c t i v e b a r r i e r l a y e r s i n r e s i s t systems.219

butylamino(bromo)phenoxy

Mixed

phosphazene p o l y m e r f i l m s have

increased c o ld resistance

.*”

P i p e r i d i n o o r phenoxyphosphazenes

have been used as c o a t i n g f o r f e r t i l i z e r g r a n u l e s i n o r d e r t o e f f e c t slow r e l e a s e o f urea.221 7.

M o l e c u l a r S t r u c t u r e s o f Phosphazenes The f o l l o w i n g s t r u c t u r e s h a v e b e e n d e t e r m i n e d b y X - r a y

diffraction.

A l l d i s t a n c e s a r e i n p i c o m e t e r s and a n g l e s - i n degrees.

Comments

Compound Ph2P[OW(CO)J

NPPh3

33 Sn(NPPh3)4 Ti(C5H5)C12NPPh3 Cis-W(NPMe3)2F4

Av.PN

1 5 8 . 2 ; L PNP 1 3 8

PN 1 5 9 . 4

Reference 35 39

(6)

PN 1 5 5 . 9 ( 9 ) , 1 5 3 . 2 ( 7 ) ; L SnNP 1 3 3 . 1 ( 4 ) , 1 4 3 . 7 ( 6 )

45

PN 1 5 6 ( 1 ) ;

46

PN 1 6 3 . 2 ( 7 ) ,

L T i N P 174.7(9) 160.9(8)

47

11

PN 1 5 9 . 7 ( 8 )

50

12

PN(endo) 1 6 0 . 5 ( 5 ) ; PN(endo) 1 7 4 . 2 ( 5 ) , 173.0(5); PN(ex0) 165.9(5), 169.2(6)

50

P r e l i m . Comm. PN 158.1(2), 1 5 6 . 2 ( 2 ) , 157.1(2)fOPO 98.3(2)

71

N3

~ i4 3CNH ~( C H ,ol ~

71

P r e l i m . Comm. PN 1 5 9 . 3 ( 2 ) , 1 5 5 . 4 ( 2 ) LOPN (exo) 95.6(2)

158.5(2)

P r e l i m . Comm. PN 1 5 6 . 8 ( 2 ) , 1 5 5 . 6 ( 3 ) , L OPN(exo 95.7 ( 4 ) P r e l i m . Comm. PN 1 5 6 . 3 ( 2 ) , 158.7, LOP0 97.8(1)

156.8(2)

157.2(1)

P r e l i m . Comm. PN 1 6 1 . 9 ( 3 ) , 1 5 5 . 5 ( 3 ) , f NPN(ex0) 103.8(2)

2,2-N3P3C14(NH2)N=PPh3

N3P3C15N=PPh 3

34

158.4(3)

71

71

71

PN(endo) 155.7(2)-161.7(2); PN(ex0) 160.7(4)-163.1(3); L NPN(exo) 1 0 5 . 0 ( 2 ) , 1 0 3 . 8 ( 2 ) ; c o m p l e x H- b o n d i n g

74

P=N(exo) 156.2(3); PN(ex0) 157.3(3), 162.6; PN(endo) 154.6-163.3 Type 1 1 1 C o n f o r m a t i o n

74

Redetermination; PN(exo) 158.0, 157.1; PN(endo) 155.6, 157.8, Type I C o n f o r m a t i o n

74,75 158.0

Bicyclic; PN(bridge)170.6(4), 172.5(4) PN(exo) 162.8(4)-165.6 ( 4 ) PN(endo) 158.1(4)-161.5(4)

76

Prelim.

Comm;

111

Prelim.

Comm.;

no d a t a s u p p l i e d no d a t a s u p p l i e d

112

PN 1 6 2 . 3 ( 2 ) , 155.1(1), 153.9(5), 1 5 8 . 1 ( 5 ) ; L CPC 1 0 5 . 5 ( 2 ) L NPlN 113.7(2) s l i g h t l y puckered ring

118

PN 1 6 2 . 5 ( 2 ) , 155.3(2), 158.7 (21, 155.8( 3 ) ; L CPlC 1 0 6 . 3 ( 2 ) ; L N P l N 114.0(2) puckered ring

118

PN 1 5 9 . 2 ( 3 ) , 155.8(3); N1 (between Ph) d i s p l a c e d from r e s t o f r i n g ; L P N l P 110.8(2)

120

3 60

Organophosphorus Chemisrn

21

N1 ( b e t w e e n Cp) d i s p l a c e d from r e s t o f r i n g ; PN 1 5 2 . 1 ( 2 ) - 1 5 6 . 9 ( 2 ) ; L PNlP 1 1 1 . 0 ( 2 )

121

N1 ( b e t w e e n Cp) d i s p l a c e d from r e s t o f r i n g ; PN 1 5 8 . 2 ( 4 ) - 1 6 0 . 2 ( 4 ) ; L PNlP 109.6(2)

121

D i s t o r t e d (NP)4 r i n g ; 156.5(3); LNPN(Av) 121.9(2)8 L PNP(Av) 1 3 4 . 2 ( 2 )

121

PN(Av)

PN 1 6 5 . 2 ( 3 ) , 1 5 4 . 9 ( 2 ) , 1 5 8 . 2 ( 3 ) i L PNP ( a d j a c e n t t o M) 1 2 1 . 7 ( 1 )

122

PN 1 6 4 . 7 ( 6 ) , 1 5 5 . 0 ( 6 ) , 1 5 8 . 1 ( 6 ) ; PNP ( a d j . t o M) 1 2 3 . 8 ( 4 )

122

PN 1 6 4 . 4 ( 4 ) , 1 5 4 . 5 ( 4 ) , 1 5 8 . 1 ( 4 ) ; L PNP ( a d j . t o M ) 1 2 3 . 6 ( 3 )

122

PN 1 6 4 . 4 ( 3 ) , 154.3(3), 157.8(3); L PNP ( a d j . t o M) 1 2 3 . 4 ( 1 )

122

PN 1 6 0 . 1 ( 2 )

222

PN 1 6 2 . 0 ( 6 ) , 159.6(6); I PNP 1 3 0 . 0 ( 4 )

157

PN 1 5 8 . 7 ( 3 ) , PNP 1 3 3

156

L

158.1(3);

Redetermination; Glide C o n f o r m a t i o n ; PN 1 4 4 ( 5 ) , L N P N 1 1 5 ; L PNP 1 3 1

167(6);

190

References 1. " T h e C h e m i s t r y o f I n o r g a n i c Homo- a n d H e t e r o c y c l e s " , V o l . 1 , 2 , E d s . 11. H a i d u c a n d 0 . 5 . S o w e r b y , A c a d e m i c P r e s s , London U.K., 1987.

2.

Phosphorus S u l f u r ,

3.

Phosphorus S u l f u r , B e r t r a n d , J.P. 1 9 8 6 , l9, 1 7 .

I . G.

5.

1986,

28.

1387,

30.

M a j o r a l and A.

J.P. M a j o r a l , G. B e r t r a n d , A . P h o s p h o r u s S u l f u r , 1 9 8 6 , 27,

B a c e i r e d o , Acc.

B a c e i r e d o and E.O. 75.

Chem.

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R.T. Boere, G.Ferguson and R.T. O a k l e y , A c t a C r y s t a l l o g r . , S e c t . C : C r y s t . S t r u c t . Cornmun., 1 9 8 6 , C42, 900.

.,

Plast.,

,

U.S.

US 4 6 0 2 0 4 8 A

Abst., (Chem.

O a i m o n , T . S a s a k u r a a n d S. Tamura, Jpn. K o k a i T o k k y o Koho JP 6 1 / 2 6 6 6 7 0 A2 (Chem. A b s t . , 1 9 8 7 , 106, 2 1 5 4 6 8 b ) .

JP 6 1 / 1 1 5 9 2 9

H i r a o k a a n d K.N. 386.

A2 (Chem.

Chiong,

Abst.,

J.

Vac.

1987,

Sci.

106,

Abst.,

196953).

Technol.,

B,

1987,

9

Physical Methods BY J. C. TEBBY

The

need

to

refer t o co-ordination

a l o n e is now w i d e l y authors

n2,

n',

co-ordination are

represents

n',

of

with

nature.

a

terminology

more

varied

apical

stereochemical

or

alkyl

and

radial of

description

equatorial

can

preferences

be

has the

reserved

to

o f s u b s t i t u e n t s o n n'

membered a n d r e l a t e d r i n g s . u s e d f o r n'

" p h o s p h i n e " for

are

2

used

in

As

each In the

aryl,

X

been

represent for

retained

atoms

of

the any

the

atoms t h a t

so t h a t t h e t e r m s a x i a l

describe

and

conformational element

in

six

T h e n o n - I UPAC n o m e n c l a t u r e " p h o s p h a n e "

p h o s p h o r u s compounds i n g e n e r a l , phosphanes

which

possess

r e s e r v i n g t h e term

three

p h o s p h o r u s and t h e term " p h o s p h i t e " studies

of

general

carbon/hydrogen

f o r phosphanes which

posseas t h r e e chalcogenide bonds t o phosphorus. theoretical

to

p r e v i o u s volumes t h e

a u b s t i t u e n t e o n n'

possess t r i g o n a l bipyramidal geometry,

studies

in

t h e above order.

hydrogen,

and Y and

contains

the

e l e c t r o n e g a t i v e s u b a t i t u e n t , Ch r e p r e s e n t s c h a l c o g e n i d e

of

to

Many

volumes

Compounds

in

groups

bonds

previous

phosphorus.

dealt

represents

R

with

( u s u a l l y o x y g e n or s u l p h u r ) ,

is

chemists.

and n b , w i l l c o n t i n u e t o be u s e d f o r

n'

number

usually

the letter

formulae,

phosphorus

H o w e v e r for c o n s i s t e n c y

sigma bonds.

subsection

number r a t h e r t h a n t o v a l e n c y

by

j o u r n a l s now u s e o i n o r d e r t o r e f e r t o t h e n u m b e r o f

and

abbreviations the

acknowledged

Uhilst Section one

interest,

theoretical

r e l a t i n g t o s p e c i f i c p h y s i c a l methods w i l l be found i n t h e

a p p r o p r i a t e s e c t i o n as u s u a l .

I

Theoretiul Studies

1 . 1 S t u Q e a B a s e d on M o l e c u l a r O r b i t a l T h e o r y .

b e e n t h e s u b j e c t of g b i n i t i o G a u s s i a n 8 0 electronic

structures.'

In

the

373

-

Phosphi nes

have

HO c a l c u l a t i o n s of t h e i r

c a s e of a m m o n i a ,

hydrogen atom

374

repulsions

account

t h e 2s e l e c t r o n s of

t h e HNH bond

for

phosphorus minimises t h e s e repulsions

and

also

alkylphosphines

i n phosphine

Whilst

utilising

of

b o n d s t o s e c o n d row e l e m e n t s are

The P-N

C-P

bonds

bonds but

Thus i n

do

contrast

t o

to

H 0 ' s

the

r a n g e of

angles

Thus

basicities

caused

by

alkyl

s u b s t i t u t i o n i n PH3

than

for

larger

alkyl

changes i n proton a f f i n i t i e s is

It

HOMO

also

a

nitrogen

t h r o u g h t h e bond general

at

electron

that

density

h y p e r c o n j u g a t i o n w h i c h i s most

less i m p o r t a n t

for

P-Me

stabilised

the

3s

by

strongly influenced parts

of

The

orbital

by bonding the

is replaced

This involvement a

dramatic

ethynyl ring

phosphines

and

effect,

orbitals

of

destabilisation

of

also

was

bond

on

that

orbital

whilst

or

For of

the

is

i t may a l s o b e

interactions

2pF

HOMO.

i n

with

fluoromethyl

The

effects

the n-orbitals

cyanophosphines

produced

of of a

interaction with the

is

a

resultant

effect

on

the charge

There

little

orbital.

o r b i t a l s and t h e r e

Whilst

phenylphosphines ring

i s much HOMO

t h e l a t t e r i n t h e nr

particularly

d i s t r i b u t i o n within t h e phenyl

the

but

example,

studied

but

i n

o r b i t a l s a n d t h e 3s o r b i t a l o f

3pT

HOMO

of

antibonding

of

the

change

i n the anions

t h e r e was a n a n t i b o n d i n g the

a much

i n

angle effect

energy

by non-bonding

stabilisation

groups

stabiliaing

produces

increase

contribution

molecule. the

or

The c a l c u l a t i o n s a l s o show

prominent

eroups

phosphorus reduces t h e involvement

is

feature

phosphorus

p h o a p h i n e s t h e c l o s e n e s s of

unsaturated

The

the

contributions

vary considerably t h e r e is u s u a l l y l i t t l e

contributions

behave

groups accounts e n t i r e l y f o r the

the

other

NHs

not

substituents

p r o t o n a t i o n produce q u i t e marked c h a n g e s i n t h e A 0 wider

on

t h e HOMO

)

a r e characteristic of

p o l a r i s a b l e a n d m o d i f i c a t i o n of

highly

f o r bonding localised

contribution thus accounting for

character

a s weak c o u n t e r p a r t s

bonds

This allows

3s a t o m i c o r b i t a l ( A 0

the

forcing

t h e bonds i n phosphine

wholly on p-orbitals

has an appreciable p-orbital

i t s marked d i r e c t i o n a l simply

and

phosphines 1s non-bonding and e x t e n s i v e l y

phosphorus

also

rely

thus

whereas t h e l a r g e atomic core

t h e HPH b o n d a n g l e t o f a l l t o n e a r l y 9 0 ° T h e HOMO o f

106 7 "

angle of

i n t o a bonding role,

This effect

was less f o r

the

phoaphide a n i o n b u t s l i g h t l y enhanced for t h e phosphonium i o n which

also

produced

influences (

i n

its

appreciable

of

p-substituents

moat

favourable

phosphonium salts,

polarisation

of

on t h e phenyl

r i n g of

t h e phenyl

conformation f o r conjugation)

were a l s o e v a l u a t e d .

ring

The

phenylphoaphine

T h e r o l e of d-'fI

and t h e i r bonding

18

3 75

quite and

l i m i t e d a n d a p p e a r s t o be valence

total

utilisation INDO a n d

INDO13

conformational

analysia

population

conformers

of

conJugation

with

the

of

methods

with

phenyl

the

'

have

is

the

MNDO s t u d i e s

is

considerable

t o the low-lying

of

electrostatic Simple

harmonic

oscillator

crystallographic

d a t a of

the contribution

of

thiourea

moiety

lone

bonded

complexes

PFJ a n d PCl3

of

the

P-C1

bond

0'

N,N-disubstituted

(HOSE

set,

t o

An

the

mechanism

electron

showed

without

density and

were

study

oxyphosphoranes a s one

with

an

obtained

i n t e r v e n t i o n of

for

course

carbon

with

(activation

prefer.

The s t e p t h a t

sulphur

in

the

25

energy

functions

fragments

of

reaction

the

apical

no

oxygen

evidence

for

phosphorus

t h e ease w i t h which t h e oxygen c a n m i g r a t e

phosphine

1s

and

controlled the

by

aulphide.

the

'

olefin.

In contrast leaving The

the

the

The

from

the cyclic

form

reaction

and

strongly

conditioned

apical to a radial orientation.

and

A

which sulphonium y l i d e s

W i t t i g r e a c t i o n i s t h e r i n g o p e n i n g of oxide

and

'

o v e r t h e Corey-Chaykovsky

kcal/mol)

kinetically differentiates the

a

Spatial

various

intermediate t o by

the

using

T h e W i t t i g p a t h w a y was

a c t i v a t i o n e n e r g y 5. 2 k c a l / m o l )

(

pathway

Wittig of

were s h o r t e r when t h e

tone with an

atom)

a stable betaine.

favoured

the

analysis

b a s i c set a l s o found only

using a 4-3lG'

intermediates

apical

the

'

of

formaldehyde,

polarisation

compared i n o r d e r t o a s c e r t a i n t h e initio

that

t h e e x i s t e n c e of a n o x y p h o s p h o r a n e

confirmed

populations

'

based on

was a l a r g e c o n t r i b u t i o n o f a p o l a r f o r m

There

s t r u c t u r e was o p t i m i s e d

similar ab

whilst

complex

model)

thiourea8

The bonds t o p h o s p h o r u s i n t h e o x y p h o s p h o r a n e electron

of

indicated that

t h e NH g r o u p d e p e n d s on t h e c o n f o r m a t i o n of

appeared.

basic

in

properties

a l a r g e r o l e i n t h e PF3

r e a c t i o n between methylenephosphorane 3-2lG'

pair

and chemical

calculations

Several studies relating have

a

The r o l e o f

when t h e m o l e c u l e i s i n a n a n t i p e r i p l a n a r c o n f o r m a t i o n . rection

to

Proforontial

e l e c t r o n d e n s i t y from t h e amine

orbital

i n t e r a c t i o n s played

applied

I)

(

and i t s phosphonium s a l t s h a s

hydrogen

t r a n s f e r of

unoccupied

been

the

'

indicated.

physical

ammonia a n d m e t h y l a m i n e w i t h p h o s p h i n e , there

polarisation

Nevertheless.

phosphorus

rings

N, N - d i m e t h y l a m i n o d i p h e n y l p h o s p h i n e

been discussed

between

sigma bonds

phanylphaephinoe

overlap i n determining

N 2 , - P 3 d

of

the

d e n s i t y is m o r e t h a n d o u b l e f o r P h P F 2

d-function CND0/2,

intermediate

in

capacity

is

from an

Corey-Chaykovsky

group properties structures

of

of

the

several

376

Organophosphorus Chemist#

f l u o r i n a t e d phosphonium y l i d e s have been s t u d i e d . in

the

ylide (2; (2;

parent

X

=

X

= F,

Y

=

bistrifluoromethyl

X =

more

X = Y = CFa).

(2;

= F)

Y

is

it

but

HI

ylide

difluoro ylide (2;

The c a r b o n a t o m

Y = H) i s m o r e p y r a m i d a l t h a n t h a t

planar

i n the

in

the

On t h e o t h e r h a n d t h e

more c l o s e l y r e s e m b l e s t h e

structure

of i s o l a t e d H l P a n d c a r b e n e CF2. a

Studiea

1.2

Based

- The m o l e c u l a r

on Molecular Mechanics Theory.

m e c h a n i c s a p p r o a c h is f u n d a m e n t a l l y q u i t e d i f f e r e n t f r o m MO t h e o r y . T h e e n e r g i e s of t h e summing

the

together

molecules

calculated

with

interactions.

the The

being

energies energies

arising

are

and

their

force

are

determined

from

calculated

w h i c h c o n t a i n s a d a t a b a s e of t h e angles

studied

normal

constants,

intramolecular

using a Force Field

bond

lengths

and

distance.

f r o m MO t h e o r y ,

data,

to

to

adjusted

molecules

being

if

or even e s t i m a t e s based on t r e n d s

more

by

specific

achieving

data

is

iterative

There a r e s e v e r a l

minimisation,

Newton-Raphson method.

available

such

established

well

as

the

Simplex

for

the

of

the

of

is(a r e )

generated.

rotated,

b o n d s a n d a t o m s may b e d i s p l a y e d i n a

method

and

and i n t e r a t o m i c d i s t a n c e s , be measured.

bond a n g l e s ,

most

may

of

of the

the

Molecules variety

the

methods

A f t e r c h e c k i n g f o r g l o b a l minima

conformation( s)

r e l a t i o n s h i p s &.may

energy

adjustments

stable

and colours,

found

One of t h e f i r s t u s e s of t h e m o l e c u l a r

studied. appropriate

stereochemistry.

and

The p a r a m e t e r s i n t h i s F o r c e F i e l d

m e c h a n i c s p r o g r a m i s t h e m i n i m i s a t i o n of t h e t o t a l molecule

coulombic

T h i s d a t a may o r i g i n a t e f r o m s p e c t r o s c o p i c

give sensible end-results.

may b e

bond

together with the rotational

e n e r g y b a r r i e r s a n d e q u a t i o n s r e l a t i n g Van d e r W a a l s a n d energies

by

e n e r g i e s of t h e c o n s t i t u e n t b o n d s

strain

be

sizes

dihedral angle

The e n e r g i e s c a l c u l a t e d a r e n o t

a b s o l u t e a n d m u s t b e c o m p a r e d o n l y w i t h e n e r g i e s of o t h e r m o l e c u l e s calculated

t h e same p r o g r a m .

by

a r e r e g u l a r l y used t o perform combined

with

partial

charge calculations,

electrostatic isopotential energy

Molecular mechanics c a l c u l a t i o n s

conformational

maps

and

for

p a t h w a y s f o r d o c k i n g two m o l e c u l e s .

analyses

predicting

quality

of

when

the

lowest

T h e g r a p h i c d i s p l a y of

t h e r e s u l t s i s o n e of t h e m o s t s t r i k i n g f e a t u r e s of most The

and,

f o r t h e g e n e r a t i o n of

programs.

t h e graphics v a r i e s considerably depending on t h e

program and t h e hardware,

Q u i t e l o w c o s t t e r m i n a l s c a n be used f o r

s t r u c t u r e b u i l d i n g and i n i t i a t i n g c a l c u l a t i o n s but one high q u a l i t y

377

9: Physical Methods

(3)

Sms -P

=C

=C

=C

/R ‘R (9)

(8)

(10)

R’

Rz>P (12 1

K

(13)

/y\

R-P-P-R (14)

Ph Ph

(15)

(16)

(17)

378

graphics

terminal

needed

is

for

viewing

and

comparing

the

s t r u c t u r e s gene r a t e d There

have

conformational mechanics

been

several

a n a l y s i s of

programs.

chlorophosphite ( 3 ;

I t X

literature

phosphorus

reports

compounds

using

one

carbon out of

mixture of

h a s b e e n shown t h a t c y c l i c f i v e membered

repectively,

have

'

m e m b e r e d h 3 a n d A'

been

examined

Cartesian coordinates for the

was

t o

larger

f r a g m e n t s based on X-ray t o

simulate

uniaxial

the

rings data

molecular

hydrophobic

by

seven

defining

one

of

on

the

5)

and

(I(

The

membered

ring

or

two p l a n a r

The Monte C a r l o method

l o

shapes

environment.

calculations

S)

=

method

was

used

d i a l k y l phosphonates i n a

The

surrounding

molecules

e x e r t e d a s t r o n g i n f l u e n c e on t h e o r d e r i n g p a r a m e t e r s . " mechanics

Y

=

P-heterocycles

by t h e Cremer-Pople

c a l c u l a t i o n of extended

X

whereas t h e oxathiaphosphite i s a

the ring,

these conformations

Seven and e i g h t

the

Y = 0) h a s a n e n v e l o p e c o n f o r m a t i o n w i t h a n

=

a x i a l c h l o r i n e atom and t h a t t h e sulphur analogue ( 3 ; has

on

molecular

structural

Molecular

solution

of

duplex

o l i g o n u c l e o t i d e s have a l s o been reported

2 2.7

Nuclear Hagnetic Resonance

Biological

the o f ~n

study

of

phosphate samples.

here,

phosphorus-31

is

it

although

the

nervous

system

recommended

as

n.m.r

pK.

ppm d o w n f i e l d o f a b s e n c e of

concerning

p r o c e s s e s a r e t o o numerous t o

be

has

been

reviewed

Triethyl

l 3

an internal reference i n biological reduction

in

e s t i m a t e s from t h e f i t t e d curves.

the

standard

I t a p p e a r s 0 44

8 5 % H s P O ~ , a n d h a s a l i n e w l d t h of o n l y 0 0 2 7 p p m i n e x p o n e n t i a l m u l t i p l i c a t i o n o f t h e FID.

t h e advantage t h a t i t is miscible with water, i n d e p e n d e n t of

Reports

spectroscopy t o the study

is noted t h a t its application t o the

I t s u s e l e a d s t o a two f o l d

d e v i a t i o n of the

of

v i t r o and i n v i v o m e t a b o l i c

reported

-

ADDlications and References.

application

s o l v e n t and i s

constant

within

i o n i c s t r e n g t h s found i n t h e physiological

I t a l s o has

its chemical s h i f t the

variation

1s

of

9: Physical Methods

379

2.2 Chemical S h i f t s and S h i e l d i n g E f f e c t s 2.2.1

Phosphorus-31

reference

-

Positive s h i f t s a r e downfield of

85% phosphoric acid,

and a r e usually

the external

given

without

the

appellation p p m of

6r

n2

compounds

compounds p o s s e s s i n g covered of

The a

by e a c h t y p e o f

t h i s group

dependent

have

on

than t h e element

have

shifts

listed

nature

of

s i n g l y bound

The

chemical

t h e e l e m e n t bound t o

phosphorus

groups a t carbon cause strong deshielding

-

300

400)

( w i t h 6~

whilst

two n i t r o g e n p -

often negative) (6)

structure

prepared

r e c e n t l y and th'y

stated

i n

standard

earlier

of

substituents more

paper

uses

lie

the

trimethyl

which has In

2 2

have a p-r

400

( 1 3 ; R'=

phosphide have

t h e sp2

245)

s.2 3 3

as

6

~2 5 3 )

when

they

supermesityl

have

P=Sb

4

the of

The i n f l u e n c e

found

f o r (9, R = Ph)

i n 6~

eA

-121

carbon atom

(

"

values

been

-

been

are (Sms)

343 3

for

the

than they

assigned

to

S e v e r a l n 2 c o m p o u n d s w i t h PP

well

a P=P bond a p p e a r

On t h e o t h e r h a n d a P - P

t o 520.19 and

the

diphosphabutadiene

for which t h e amine g r o u p s must be h e l d

of

135 3 , ' '

bond

compound p o s s e s s i n g a P=Si

t h e r e l a t e d a n t i m o n y compound

resonates

at

low

very

field

(6r

c o n t r a s t t h e p h o s p h o n i u m compound ( 1 2 ) w h i c h c a n n o t

bond g i v e s

resonate H,

the

have t h i s e f f e c t

1

very high f i e l d s h i f t ,

The p o t a s s i u m p h o s p h i d e s groups

t o

Whereas t h e t r i - t - b u t y l

a

-

Those possessing

region

bond h a s a c h e m i c a l s h i f t

630 5 )

a (7)

phosphite

Thus t h e

variations

has a highfield s h i f t , 2 o

u~ s u a l l y

shielding

chemical s h i f t s

s l i g h t l y downfield

phosphaalkene

The

s i n g l e bond d o e s n o t responsible

silicon 6

Note t h e s h i f t of

i n o r b i t a l symmetries i n

large

with

which i n c o r p o r a t e s

closer

bonds have been prepared downfield

keeping

(160

more

( 8 ; R = P h , T m s ) h a v e 6~ v a l u e s 1 5 6 . 7 a n d

corresponding mesityl difrerencea

Two

phosphorus (

fluoro analogues

as i n a cumulene

which

do to each other.

is

shift

carbon is not diminished

on t h e sp'

distant

respectively

(77)

i n

6~ 2 0

ring resonates

I-phosphacumulenes

(10)

more

c o m p o u n d s i n t h e C-P=CCZ c l a s s

made

of

a l s o have upfield

phosphaalkene

A

within a fluorenyl other

I '

compound ( 7 , X = F) the

ranges

t o t h e carbon atom

groups produce g r e a t e r

Several

betaine

pentafluoro

two c o - o r d i n a t e

of

been reviewed and t h e

s t r u c t u r e a s d e f i n e d by t h e c o n n e c t i v i t i e s

been

the

chemical

P=C b o n d

(13)

i n the region 43

R2= tBu) have

6~

-60

"

similar t o t h a t for a l k y l phosphines

-180.

possessing 22 and

Note

"

two

bulky

alkyl

t h o s e w i t h P H g r o u p s &e that

this

trend

is

380

6r

Organophosphorus Chemistr!

nJ

of

membered

compounds

phosphorus the

phosphorus

(14,

R = SmS,

b e e n s a v e r a l s t u d i e s of

have

heterocycles

atoms ( 1 4 )

containing

= CH2),

eg -141

and a t even h i g h e r

field

a hydrogen atom o r a s i l y l group ( 1 4 ,

initio

calculations

of

shielding

constants

2 2 8 ppm a n d t h a t

t h e v e r y l a r g e s h i e l d i n g i n Pa

0’ c o n t r i b u t i o n

i n t h e HOMO

The

diphosphine

(

15)

for the dl

’’

has

66 8

6r

when

f o r phosphirine when

phosphorus

Y = PH or PTms) indicate

s h i e l d i n g c o n s t a n t i s more p o s i t i v e i n

isotropic

6~

three

three2’

u p f i e l d i n t h e r a n g e -90 t o - 1 7 8

atom bears an a l k y l group,

Y

or

two“

Like the monophosphirines,”

a r e well

and t r i p h o s p h i r i n e s

bears

There

phosphorus

P4

Ab

2 7

that

the

than i n PHJ

is due t o

a

The marked

by

small

downfield

s h i f t caused by t h i s p o l y c y c l i c

s y s t e m r e s e m b l e s t h a t c a u s e d by t h e

phosphanorbornene s t r u c t u r e

In contrast

phosphine

(16)

2 7

t r i s ( 2 - and

closely resembling very

high

a

restraints,

field

polycyclic

the

tertiary

the bicyclo(2 2 2loctane ring

also

the

system

of

additional

(171, 6r

phosphine

7)

tris

the

normally appear

presence

3 ’

of

tertiary

and

The p h o s p h i r i n e s

However,

’O

appears t o reduce t h e shielding e f f e c t signals

acyclic

3-fury1)phosphines

(2,6-difluorophenyl) phosphines a t

the

h i g h l y s h i e l d e d p h o s p h o r u s a t o m ( 6 -~7 4

a

has

-130

2,

The s t e r i c r e s t r a i n t s o f moves

the

phosphorus

a n d p h o s p h i t e g r o u p s of ( 1 8 ) t o h i g h e r

phosphine

The c h e m i c a l

shifts

of

f i e l d r e l a t i v e t o t h e acyclic analogues

3 2

the

of a n t i - 7 - p h o s p h a n o r b o r n e n e

P-chloro

and

P-bromo

analogues

e x h i b i t t h e reverse trend t o t h e phosphines and t h e s i g n a l s a t higher

Solid

state “P

showed t h e p r e s e n c e became e q u i v a l e n t A

n m. r

of

i n solution. cation

mesomeric

well

upfield

’‘

has

been

examples

resonance (22;

by

prepared

a n d c o r r e s p o n d s more

of

a new c l a s s of O’h’

carbene,

structures Y =

which

assigned (

6r

the 20)

ylide

(22a-c)

closely

to

the

”

have

and

compound,

w h i c h may b e

phosphaacetylene/nltrile

been characterised.

Y = CTms) g i v e s a n u p f i e l d s i g n a l a t -41’‘

analogue (22;

and

However i t s p h o s p h o r u s s i g n a l

t e r t i a r y phosphine s t r u c t u r e ( 2 1 ) . Two

phosphorus atoms

of t h e c o r r e s p o n d i n g 0 3 h ’ p h o s p h o r a n a s w i t h t h r e e

c a r b o n b o n d s ( 8 0 t o 2 0 5 ppm)

represented

t h e t r i o x a t r i p h o s p h o r i n a n e (19)

of

three non-equivalent

phosphonium s t r u c t u r e ( 2 0 )

is

appear

f i e l d than usual ”

but

N) r e s o n a t e s d o w n f i e l d a t 6 r 2 4 6

”

the

Compound rlitroBen

38 1

9: Physical Merhods

6 p

of

n'

comoounds

Studies

of

chemical s h i f t s are properties

of

influenced

the

heteroarene

electric field effects g r o u p is b o u n d substituent

(23)

effects

(24)

t o

a

is

the trends directly

that

the

the

''

bonds.

when

of

the

phosphorus

LFER s t u d i e s o f

moves

and a l k y a t i o n upfield

rationalised

of

i n terms o f

phosphorus

phosphorus the

2-ni

either

shift move

30

of

the

ppm,

of

role of

d is s o c ia t ion

'*

o n 6~ with

The

phosphorus This

positive

charge

TBP

of

was on

nitrogen

for

structure

whereas

a l l

the

of

also the

trialkylphosphrne used

t o

rings

have

r i n g s a five-membered

d o e s a seven-membered

determine

technique

has

also

neighbouring group participation (

26),

"

to

and

t o

been

the

been

i n the

possible

metathiophosphate.

prepared.

r i n g causes

r i n g too but

of

large

a l k a l i n e h y d r o l y s i s of a

and

This

a

''

l a b e l l i n g were acid

gives

(27) which have a d d i t i o n a l s p i r o

diaminopolymethylene

(

1, 1

''

linked)

Compared t o t h e

marked

deshielding

t o a much l e s s e r e x t e n t .

a n s a ( 1 , 3 l i n k e d ) c o m p o u n d was a l s o o b t a i n e d . " 6p

i n

and P-0

shifts

balanced

thiophosphates

Cyclotriphosphazenes

as

bound

(25) which have a n

co-ordination

telluride

r e a r r a n g e m e n t of t h e p h o s p h o n a t e s

six-membered

the

is

ring

coordination

more

ribofuranosyl cyclic phosphate."

to

as

is o p p o s i t e t o

haloalkylphosphonates

downfield

d o w n f i e l d upon a l k y l a t i o n

regiospecificity

applied

aryl

an increase of

a

Novel

o c c u p a n c y f o r P-OAr

i n transannular

producing

''

ppm

This

trophenyl

for

I s o t o p i c s h i f t s due t o "0 the

aza

I t s h o u l d a l s o be n o t e d t h a t a l k y l a t i o n ( a t Te)

"

tellurides

an

The r e s u l t s a r e e x p l a i n e d

than

tris(dimethylamino) phosphine

upfield

If

range

diphenylphosphinates

bicylic phosphites

rather

phosphorus o r an increase

to

phosphazene

downfield

substituted

ethyl

7

ca.

Y increase

atom.

amino group s u i t a b l y positioned produced

short

the

t o have a s t r o n g i n f l u e n c e

inductive effects

protonation

"P

the

by

heterarene of

t e r m s o f d i f f e r e n t d e g r e e s of d - o r b i t a l showed

also

for the aryl

6~

properties

observed t o

but

a n i s o t r o p y when

shift

are reported

found

electron-accepting

that

to t h e phosphazene group t h e through-space

downfield

effects

I t

rinss

to the @-position of

lead

for a s e r i e s of

indicated

o n l y by t h e e l e c t r o n - w i t h d r a w i n g

and magnetic

is adjacent

substituent

not

o constants

the

N-hateroaryltriphanylphosphinimides

The u s e f u l n e s s

An

of

for d i s t i n g u i s h i n g axial and e q u a t o r i a l phosphoryl groups i n t h e

oxaaaphoaphorines

has

been

a n a l o g u e s t h e i m p o r t a n c e of

evaluated"

and

taking i n t o account

for

t h e monocyclic

the orientation

of

382

Organophosphorus Chemistrv

SmsO\

P

BuzP =CHNMe2 1 *

,O,p,OSms

I

i

Op,O /

I

OSms

(21)

(19)

Ph,P =NArhct

(23)

n

N


Me

‘c-P

P-z

\

OEt

Ph’i] -‘COCF,

(24)

(25)

( 2 6)

X?

OH (27)

S

Ph Y

’

$P=C X

(30)

(29)

(28)

(32)

/z

II I

/

Y-P-N

z‘

,N-P-Y R

I II S

(33)

R

9: Ph?~sircilMethods

the of

383

substituent

on n i t r o g e n emphasized

The d o w n f i e l d p o s i t i o n

"

t h e c y c l i c phosphonates (28) which have a n

to

the

phosphoryl

attributed t o compounds and have 6~

(

group,

hydrogen

Y = H,

29,

n5 compounds

of

''

bonding OTms)

C02R,

11 2 t o - 1 5

6r

1

have been prepared

thiohydroxyphosphorane

and

P-alkoxy

gave ( 3 0 ,

(31,

6s.

Thus w h i l s t phosphine

and Oxygen-17.

to

sensitive

CFJ)

X=

X=

of

and -270,

-268

deshielded

2-thienylphosphine

selenide)

selenium

groups

+&

selenide

"

6s.

phosphites, molecules

46 2 A

the anion

conformation, d o w n f i e l d of

signal

from

tri-3-furyl-

thienyl

whilst

of

rings

In contrast

(-168

resonate

at

2. 2 . 3 C a r b o n - 1 3

The " C

n m.r

spectra

of i n

in

a

ring

6~ o f

t h e amino

field

at

R= a l k y l , the

relevant

ylidic

chair

Exocyclic

i n phosphates

oxygen than for

Other trends a r e a l s o reported

chemical s h i f t s of

p-n

bonded

s u c h a s i o d i n e bound

carbon

of

Compounds

t o carbon have

From t h e c o r r e l a t i o n o f

"

"

t h e alkane region (38 the

6~ a n d

a c a r b o n , i t was i n f e r r e d t h a t i n d u c t i v e e f f e c t s o f

t h e a m i n o g r o u p h a d a c o n t r o l l i n g i n f l u e n c e o n 6r (33;

a boat

a

from an a x i a l l y o r i e n t a t e d P=O is

higher

( s .1 0 0 )

of

with

t o 103) i n keeping with a considerable y l i d i c c h a r a c t e r moat d o w n f i e l d s i g n a l s

cyclic bicyclic

group which is p a r t

phosphoranes ( 3 2 ) a r e mostly u p f i e l d of

which have l a r g e atoms ( 2 )

phenyl

( 2 ,6 - d i m e t h o x y p h e n y l ) p h o s p h i n e

that i n an equatorial orientation. t o

tris

for

by o r t h o s u b s t i t u t i o n of

that

the signal

is

atoms

t h e s i g n a l of

P=O

a

shift

and

the "0

of

14 2 and

are very similar,

and

p h o s p h i t e s or t h i o p h o s p h a t e s .

A'U'

chemical

selenide

The

"

"

p h o s p h a t e s a n d t h i o p h o s p h a t e s showed t h a t the

found

by

6

has a signal a t

6~

had

C1)

-14

~ u x t a p o s e dc h a l c o g e n i d e

tris

for

study

conformation appears upfield

was

X=

6~

well u p f i e l d a t -354

appears

is

the

of

triphenylphosphine

tri-2-furylphosphine

TmsO) 2PH

(

oxaphosphetanes

OHe)

The s e l e n i u m

t h e presence

selenide,

from

The c h l o r o p h o s p h o r a n e ( 3 0 ,

moves d o w n f i e l d t o 1 7 4 on t h e g e n e r a t i o n o f

very

has been

a 1ko x y c a r b o n y l p h o s p h o r u s

The

Some new P - h a l o

14 and on r e a c t i o n with methanol

2 . 2. 2 S e l e n i u m - 7 7

group ~ 1 s

' O

( 3 0 ) have been p r e p a r e d novel

hydroxyl

o(

compared t o t h e t r a n s i s o m e r s ,

Y = Ph)

"

carbon

The u s e o f assisted

f o r t h e compounds

a n y l i d e 92% e n r i c h e d

with

''C

s revealing k i n e t i c s t u d y of a l l

i n t e r m e d i a t e s i n t h e m e c h a n i s m of

the

Wlttig

reaction

"

3 84

Organophosphorus Chrmisrq

The

solvation

of

diphosphoryl n. m. r .

w a s s t u d i e d b y '.'C

3.2.4 H y d r o g e n - I . tris

the

increasing

chalcogenide

Ch= O , S , S e )

substituent constants,

positive

number.''

(34;

charge

on

for t h e m e t h i n e

6"

The l i n e a r r e l a t i o n s h i p o f

phosphine

t h e chalcogenide

compounds a t d i f f e r e n t t e m p e r a t u r e s

'* of

w i t h t h e sum of

terms

was e x p l a i n e d i n

of

phosphorus with increasing atomic

When t h e c o u p l i n g c o n s t a n t s c o u l d n o t

be measured i n

an

'H n. m. r . s t u d y o f t h e s t e r e o c h e m i s t r y of t h e b i c y c l i c h e t e r o c y c l e s

( 3 5 ) , c o n f o r m a t i o n a l a s s i g n m e n t s w e r e m a d e o n t h e b a s i s of t h e p e a k w i d t h s of h y d r o x y l s i g n a l s .

3.3

Restricted

about and

R o t a t i o n and P s e u d o r o t a t i o n

t h e P-N bond o f could

( 3 6 ) ."

by

H, I!

rotation,

steric

thiophosphonamides

"

bis( dichloro-

which

factors

i n solution

(38;

g=

be

determined

for t h e

studied

the 31P n m r

spectra

down t o - 9 0 " , i t was

of t h e c o n f o r m e r ( 3 7 ) c o u l d n o t

i s r a p i d when o n e o f

2D

the

2)

Correlated Low

rotation

studied,"

"

rings but compound.''

t o

been

phosphino) phenylamines,

3).

FP

also

From t h e symmetry o f

P s e u d o r o t a t i o n i s s l o w on hydridophosphorane

Restricted

for t h e b e n z o t h i a z o l o n e

appears

has

deduced t h a t s i g n i f i c a n t q u a n t i t i e s be p r e s e n t

-

s e l e c t e d aminophosphines has been

be o b s e r v e d a t room t e m p e r a t u r e

Restricted

essentially

of

"

time

the rings is

spectra

were

n m r

temperature

tri(fluoroa1koxy)phosphorane

n m r

scale

for

six-membered

for

recorded

spectroscopy

indicated

a

of

preference

a

ring

t h e phosphorane (39)

two

spans

radial

former dicyano-

for a t

the

was

sulphur

and

i n t h e g r o u n d s t a t e w i t h c o r r e s p o n d i n g w e a k e n i n g of P - 0 s t u d y of

series of s i x co-ordinate dissociative ring.

"

2.4

Stu d i e a

Valence

mechanism

of

phosphines (42)

have

fluxional

isomerisations

of

a

c o m p o u n d s ( 4 0 ) , s h o w e d t h e o p e r a t i o n of

y&

Ea u i 11b r i e .

isomerism

the

beween

stability

phosphorus

A detailed

interaction

eight-membered

of

lack

t o

"

transannular

that A

b p and a

attributed bond

a

indicated

positions

g=

(38,

the

s t r u c t u r e with t h e cyano groups occupying r a d i a l positions," s t u d y of

the

which h a s two s p i r o five-membered

beween been

o p e n i n g of t h e f o u r - m e m b e r e d

Configuration phoaphaalkenes studied

by

and (

-

Conformation. 41)

variable

and

a

nitrogen

bicyclic

temperature

"P

385

9: Physical Methods

R-N

(36)

(461

386

''

n . m. r

The

diphosphine but

low

stability

of

to four centred association i n

chain

tautomerism

involving

alkylphosphonates," and

sulphur

i n

by 3 1 P

studied

chlorinated

borate

and phosphorus

triazene n m r

tautomerism

compounds

as

spectroscopy

phosphate have been i n t e r p r e t e d

P"OP( 0 )O E t z tetraoxy

co-ordinate

between

variable

i n t e r m s of

Rlng

nitrogen have been

temperature

bonds which a r e i n e q u i l i b r i u m with salts

the

formation

p o s s e s s i n g two or t h r e e

phosphoranes

quasi-phosphonium

co-ordinate

''

b i s tx-hydroxy

shown i n ( 4 4 ) ' ' The

diethyl

five

of

catechol-dichlorophosphoranes i n t h e p r e s e n c e o f

spectra of

novel

solvents

derivatives

n.m.r of

of t h e c y c l i c

the configuration

to i n v e r s i o n i n h y d r o c a r b o n s o l v e n t s

is a t t r i b u t e d

(43)

and

their

the

dissociated

corresponding

compounds i n v o l v i n g t h e a d d i t i o n o f

another

six

phosphate

group."

T h i s l a t t e r o b s e r v a t i o n a d d s c r e d i b i l i t y t o new p r o p o s a l s

for

mechanisms

the

groups discussed

of

nucleophilic

i n the section

Enantiomeric excess determined

by

measuring n m r.

the

''

ratios

The method

n.m r

was

technique

enantiotopic

of

powerful

menthyl

''

and

the

groups

phosphinates state.

''

to

determine

(451,

of

stereochemistry (46; The

Ch

diphosphonate

signals

accumulation

'*

The

was

spectra

of

shown

"

and

racemic

and (

of

the

the

was

was u s e d t o heterocyclic

t o

of

the solid have

the

the phosphorus

to

shown

p h o s p h a z e n e s b 2 were s t u d i e d l i k e w i s e The

eight-membered

attributed

diadamantylphosphi n i c a c i d chlorides'

of their

inversion

techniques

i n s t a b i l i t y of o n e o f

Diestereotopis m

pent-I, 3-dienephosphonates,

P

and/or

was

and

the saturation transfer

i n solution with that (47)

The

enantiomers

stereochemistry

2D n m. r the

of

= S, S e )

shown

during

of

3 1 P and 13C

studies

diastereotopic

D

of

"P

the

dimenthylphosphine and with

ring

T h e same r a n g e

of

of

of

and

purity

2D ' H ,

of

variety

the

together

atereochemistry mobility.

application

L

chloro-

by 3 1 P

phosphonates

technique

i n

and

existence

established." compare t h e

the

been

d i c h l o r i d e and

enantiomeric

used f o r t h e c h a r a c t e r i s a t i o n

dioxaphosphorinanes technique

of

the

has been used i n a

dichloromenthylphosphine sulphides,

of

phosphoryl

t h i o l s and amines have

diastereoisomeric

example

The

"

spectroscopy

a t

i n t h i s chapter

them with methylphosphonic

determination

p r o s t a n o i d s is another n m r

alcohols,

of

reacting

substitution

on k i n e t i c s

conformational by

conf

i i

someri c

gurations

of

vinyloxyi chlorocyclotetra-

u a i n g 2 D n . m. r .

1, 2 - d i - t - b u t y l - I ,

spectroscopy. 2-di-neo-pentyl

387

diphosphine

dioxide,

and

I , 3, 5 - d i o x a p h o s p h o r i n a n e s b '

conformational of

dialkyl

on

the

a

were

mixture used

of

as

stereoiaomers

of

of

a

the

basis

The c o n f i g u r a t i o n of m o l e c u l a r

analyses.

phosphites has been s t u d i e d , " conformations

and

associates solvent

and t h e e f f e c t of

configurations

of

phosphonium-

ethanesulphonate b e t a i n e s o b has been reported. Spin-Spin

2.5

J-resolved

-

Couplings.

spectra

to

number

A

compounds a r e g i v e n i n t h e p r e v i o u s 2. 5 . 1 J(PSe)

and J(PTe).

or

heteroaryl

aryl

applications

that

have

is l a r g e r

'JPs.

repectively)

' J P T . = 1600 Hz.

tri-t-butylphosphine

-

J(PP) had

'' '

P'NP'

The

(48)

coupling was

Ha,

vicinal

whilst couplings

are

Van d e r W a a l s

dihedral

angle

effects

However,

coordinate phosphorus

(50) a r e i n the range

Hz

37

for

and

pair

atom

is

The

''

the

is

there

four

have

been

of

(51)

respectively) s-character

are

-

92

The

9 o

a

qulte

diphospha-

favourable

t o transmit

electrons

directed bond

rigid

on

away

couplings

from in

0"

coupling

each

three

the

other

phosphazenyl

found t o c o r r e l a t e with t h e s o l i d

2.5. 3 J ( P F ) a n d J ( P N ) . T h e P F a n d P C F c o u p l i n g s i n s i x compounds

and

t h i s c a s e t h e two phosphorus atoms a r e

t h e r e a r e t h r e e pathways

"

isomer)

PP c o u p l i n g s i n t h e

-

lone

s t a t e conformations

I0 Hz ( t r a n s

Seminal

In

the

atom.

linear

t h e phosphorane

35

phosphorus

cyclotriphosphazenes

stabilised

c o u p l i n g s a r e o n l y I 6 - 2 9 Hz

distances,

and

the

-

The

the vicinal

bicycle( 2 , 2 , 2 ) o c t a n e s .

within

dotoluene

t e l l u r i d e had

In contrast

only 6

(u isomer)

Ha

for

Hz

70

PP geminal c o u p l i n g of

13

and

T r i -t-butylphosphine

conformationally mobile polyphosphines 113

s e l e n i d e has

O 7

tetraphosphazene I 0

for

strong electron-accepting

t h e t r i m e t h y l a n a l o g u e ( 6 8 4 Hz a n d 7 1 1 Hz f o r C D C 1 3

(49)

2D

c o u p l i n g 1 7 1 2 Hz) w h i c h i s o n l y s l i g h t l y l a r g e r t h a n t h a t o f

solutions

2 , 5 .2

of

organophosphorus

section.

The c o u p l i n g c o n s t a n t

groups

On t h e o t h e r h a n d ,

properties.'' a P-Se

of

s t e r e o c h e m i c a l s t u d i e s of

(922-936

large

f o r b o t h a p i c a l and r a d i a l p o s i t i o n s .

a p p e a r s t o be s u b s t a n t i a l

and

co-ordinate 745-156

and t h e s t r u c t u r e s cannot

w h o l l y d e s c r i b e d i n terms of t h e p r e s e n c e

of

Hz

Thus mrxing of

a 3-centre

be

2-electron

388

Organophosphorus Chemistry

(49 1

Me

(57 1

(56)

Me

I

Mt

(59)

(60)

9: Physical Methods

p-orbital

bond w i t h s u b s t a n t i a l

The ''N Hz,

3 89

whereas

the

geminal

a t t r i b u t e d t o N-P=P phosphole

for

was

''

showed

The

the

zero.

n . m. r .

spectra

reviewed.

of

the configuration

spectra

labelled

phosphorus

was

enriched

be considerably diethylamino

configuration.

cyclophosphazenes

e.g.

substituents

hexachlorocyclotriphosphazene compound.

"N

of

t o

an &

with

latter

The

"

have

been

d i r e c t PN c o u p l i n g i s v e r y s e n s i t i v e t o t h e n a t u r e

The

the

"N

The

coupling

t h a n t h e c o u p l i n g ( 7 5 Hz) f o r t h e

group

86

compound ( 5 2 ) had ' J ( P " N )

coupling

conjugation.

(53)

dimers

s m a l l e r ( 4 8 Hz)

of

ionic character."

e n r i c h e d two c o - o r d i n a t e

For t h e p y r r o l e compounds

(

for

the

for

hexafluoro

Me o r S') , e v e n

Y=

54;

Hz

-3

Hz

72

and

the

s u b s t i t u t i o n o f m e t h y l f o r s u l p h i d e a l t e r s ' J P M f r o m 5 6 t o 1 3 Hz. The

nitrogen

coupling. 2.5.4

substituents

''

J(PC).

The

direct

one-bond

and a r e l a r g e r t o exocyclic carbon atoms ( p h e n y l o r equivalent

endocyclic

carbons.qq

phosphonates (55) can vary coupling

in

coupling

from

t-butyl)

to

208

Ha. l o o

300

over

f o r P-fluorophosphonium y l i d e s a r e characterised

Thi s

by l a r g e

A study of

t h i s range."'

I-hydroxycycloalkylphoaphonates w i t h r i n g s i z e s v a r y i n g from showed

membered

that ring

a

possess

the and

direct

smallest PC

direct

largest

coupling

was

for

eleven.

the

c o u p l i n g of

a p i c a l a n d o v e r 1 7 0 Ha when i t

is

than

This coupling f o r acetylenic

couplings which o v e r l a p t h e lower end of 12

n3

a r e s e n s i t i v e t o t h e bond a n g l e a t p h o s p h o r u s

7-phosphanorbornenes t o

''

h a v e a m a r k e d i n f l u e n c e on t h i s

also

s. 120

I02

4

to

for the five

Phenylphosphoranes

when t h e p h e n y l g r o u p i s

radially

orientated.103

This

d i f f e r e n c e has been used t o a s s e s s t h e r e l a t i v e a p i c o p h i l i c i t i e a of methyl

groups

and

phosphorane 156) carbon

p h e n y l groups."'

t h a t t h e PC c o u p l i n g t o

carbon of

PC

couplings

-

etereochemietry carbon

is

atom

electrons. couplings

radial

sp3

i t s isomer ( 5 7 ) . " '

S t u d i e s of r i g i d h e t e r o c y c l i c geminal

study of the

A

the

2 1 5 HI, w h i c h i s c o n s i d e r a b l y l a r g e r t h a n t h e c o u p l i n g

wa6

t o t h e sp'

substituted

revealed

l o *

i n

phosphines have confirmed

phosphines

are

reliable

of

when

the

the coupling being considerably larger directed

towards

the

phosphorus

I t w o u l d seem l i k e l y t h a t t h e

recorded

for

2-alkoxyvinylphosphanes

the (

58)

isomers compared

t o

much

of the

that

probes

lone

p a i r of

larger

geminal

several

series

corresponding

of

2

390

isomers

a r e due t o t h e same phenomenon

are a manifestation of co-ordinate the

compounds t h e o p p o s i t e

spectra

of

primary

would

involve

i n which c a s e t h e couplings

preferences

trend has

2-alkylaminovinyl

oxides exhibited The

conformational

difference

inter-

intra-

and

than

expected

molecular

n m r ,

An

reported

-phosphonates

l a r g e r PC S e m i n a l c o u p l i n g s

structural

For t h e f o u r

lo'

been

&

the

isomers

for these

compounds

hydrogen bonding,"'

X-ray

lo'

MNDO s t u d y o f

chiral

t-butylmenthylthiophosphoryl compounds

2

larger

t~ o ~ b e

couplings vicinal than

of

for

geminal

assumptions.'12

The sum o f

appear

atom.

s t u d y of

A

of 'Jen

with 'JPW

i n the of

The

the

Fermi

the

the

vicinal and

3

contact

of

pressure

'"

on

plot

to

vinyl

the

n m. r

JIM increasing

was

Further

phosphorinan

g e o m e t r i e s of

Nuclear

have been d e t e c t e d

phosphates

attributed reports

distinguish oxides"L phosphorus

readily

chlorine-35

NQR

were arraigned o n t h e b a s i s

(

to

on t h e

chair

and

and f o r t h e compounds"'

60).

Quadrupole Resonance.

b y t h e CIDNP

diphenylphosphinite

t r a n s i t i o n s were

difference

couplings

of

of

mechanism d o e s n o t

f i v e b o n d PH c o u p l i n g ( I . 5 Hz) w a s o b s e r v e d f o r a

A

s e r i e s of p r o p e n y l d i t h i o and

both

factor since the correlation

solvent

PH

conformations

1

zig-zag that

"

effect

unchanged with

with

indicates

The

have appeared.

by

previous

dioxaphosphorinanes has

was

a s s i g n m e n t of

(27)

i n n'

'JPC

i n c h l o r o f o r m showed

application of

methyl

are larger

of

PC c o u p l i n g s

diphenylphosphine

hydrogen-bonding

CIDNP

PC The

dependence on t h e e l e c t r o n i c s t r u c t u r e

through t h e ori g i n

2. 5. 5 J ( P H ) .

2, 6

of

t o be t h e o n l y c o n t r o l l i n g

twist-boat

reverse

t o determine the stereochemistry

relationship

have a s i m i l a r phosphorus

spectra

'''

studied

and l a r g e r values appear associated

linear

A

did not pass

whilst

used

the

geminal and v i c i n a l

stereospecificity

geometry n3

been

showed

various

' I s

been investigated

the

-

couplings

p h o s p h o l e s (59) were

couplings

The

' l o

of arylpentafluorocyclophosphazenes

PC c o u p l i n g s

The

compounds

SCPI

oxazaphosphorinanes have a l s o

the

ring fusion

the

cf

c r y s t a l l o g r a p h i c and

propenylphosphonates. J

Thus

and -phosphine

phenomenon with

detected

for

-

Radical the

ion pairs

reaction

I - n i t r o p r o p e n e . "* i n

spectroscopy.

of

Phase

chlorocyclotriphoaphaaenes

The c h l o r i n e f r e q u e n c i e s

of b o n d l e n g t h s a n d n o n - e q u i v a l e n c e

from

9: Physicwl Methods

a n X-ray very

39 1

crystallographic

interesting

observed

study

spectra;

The s i x - m e m b e r e d s p i r o

at

room

temperature a

i n a c c o r d a n c e w i t h t h e p r e s e n c e of

mirror

and gave o n l y two s i g n a l s o v e r t h e same t e m p e r a t u r e

''C1

g e m i n a l 1y s u b s t

f r e q u e n c i e s of

t r i e n e s were

related

3 Gamma

t o P-C1

of

radiolysis

e

s p e c t r a of

r

8

corresponding

anion

phosphorus

trichloride A

1 2 '

planar

a

T-shaped '"The

in

Y

=

temperature

interpreted

the

with

the

presence

C1,

of

indicated

of " 0

is

a quinone gives t h e

8

1300

r

at1

G

s t u d y of

that

the

the

unpaired C1)

=

( 6 1 , Y = HI

S p e c t r a of d i ( supermesityl) phosphonyl A,

CNDO

atom

The p h o t o l y s i s of

single crystal e

H, O R )

oxidation

t h e a i d of

phosphorus

"'

the

independent

w i t h s p e c t r a p o s s e s s i n g ap and

to

electrochemical

whereas t h e monochlorophosphine

= t B u 3 C b H ~ ) possessed

= HI

The

2 2

a

gave

attributed

u* o r b i t a l a n d t h a t t h e t r i c h l o r i d e ( 6 1 , Y

t h e r e l a t i v e s i g n s of delocalised

was

indicated that

theoretical

electron occupies

R

-

lengths

formed by

were

Y = C1)

radical cations (61,

(61;

The

c h l o r o c y c 1o t r i p h o s p h a z a

P - N n - c o n ~ u g a t i o ni s weak

radical cation (61,

spectrum

t ut ed

which

radical

The r e s u l t s

pyramidal and t h a t

pyramidal

i

symmetry

range

1. 2 - b i s ( d i p h e n y l p h o s p h i n o ) e t h a n e

signal

cyclotetraphosphines,

G

bond

radical cations,

calculations

R

but The

E l e c t r o n S p i n Resonance

non-resolved

is

plane,

s p i r o r i n g h a s d i a d a x e s of

compound w i t h a seven-membered

50

has

i s l o s t a t 260K when f o u r s i g n a l s a p p e a r i n t h e s p e c t r a

this

of

ring

two s i g n a l s a r e

radical

(

is

62,

unique l i n e width v a r i a t i o n s which a l l o w e d A.

and

enriched

t o

be

species

w h i c h is i n a g r e e m e n t

determined

indicated that

e s r

The

the electron is

w i t h MO a b i n i t i ~c a l c u l a t i o n s o n

w i t h imposed p l a n a r geometry

The

preferred

geometry

of t h i s l a t t e r r a d i c a l i s p y r a m i d a l E.s r

s p e c t r o s c o p y was u s e d t o c o m p a r e t h e s t r u c t u r e s of

phosphoranyl (18;

R =

sinule

cc1J)

r a d i c a l s d e r l v e d f r o m t h e r e a c t i o n of with tert-butoxy

crystal

phosphoramidates (63; showed

the

0 . 8

r

X =

formation

C1,

of

radicals

study

0'

F,

of

Y

=

radicals

and o r t h o

quinones

2-irradiated morpholino,

or

the

the heterocycle

trigonal

"'

A

halothiopyrrolidino) bipyramidal

392

Organophosphorus Chemistry

radicals

which have t h e u n p a i r e d

orientation.

Weak

P-Hal

thiophosphoryl

radicals."'

electron i n a radial (equatorial)

bonds

react w i t h t e t r a p h e n y l d i p h o s p h i n e various

radicals

and

model, away

dissociation photoexcited

diphosphite

64)

(

t o

ketones t o

give

E.s. r .

of

spectra

phosphazene

c o m b i n e d w i t h a b i n i t i g c a l c u l a t i o n s of t h e h y d r o g e n

(67)

a x radical with t h e unpaired

indicated from

and

such a s ( 6 5 ) and ( 6 6 ) with phosphorus s p l i t t i n g s

of c a I 5 a n d 2 7 G r e p e c t i v e l y . " ' radical

allowed

Carbenes

the

-X - i r r a d i a t i o n

heterocyclic

of

It

ring.'"

2'-deoxyguanosine

electron has

polarised

been

5'-monophosphate

shown t h a t at

15

p r o d u c e s n a n i o n r a d i c a l s of t h e g u a n i d i n e b a s e . ' "

4

Vibrational

4. I V i b r a t i o n a l

4. 1. 1

Group

and R o t a t i o n a l SDectroscoDY

SD9ctroSco~y.

Frequencies

-

and

Assignments.

The d i c h l o r o p h o s p h i n o

g r o u p h a s been shown t o p r o d u c e a d e c r e a s e i n frequency

cm-'

bound t o a d o u b l e b o n d . l J '

i n t h e 1 . r,

related mode.

when

of

spectra

sulphides

'*

(34)

has

in

groups

assigned

- I . r.

various

compounds h a s been r e p o r t e d .

the

C=C

stretching

An i n t e n s e b a n d a t 9 3 5

t r i s (diphenylphosphory1)methane been

4. 1. 2 Bon d i n g a n d C o - o r d i n a t i o n . thiocyanato

"'

t o

a P-C

evidence on t h e bonding

three

i . r.

spectroscopy.

intermolecular

co-ordinate

on t h e

of

nature

the

spectral

group^.^"

organic

Hydrogen-bonding

low

T h e r e was e v i d e n c e

b o n d i n g of SH t o t h i o l s u l p h u r

of

van."'

1.r.

SH

t o S=P.

s t u d i e s of

(68)

Changes i n V P - m

intermolecular

h y d r o g e n b o n d i n g of p h o s p h o r y l

p o l a r i t y of

hydrogen

were l a r g e r t h a n

V P - a

groups

or t o

t h e phosphoryl

i n an adamantane s t r u c t u r e i n c r e a s e s its b a s i c i t y .

attributed t o a higher

i n

spectroscopy a t

f o r i n t r a m o l e c u l a r hydrogen

and

s u b s t i t u t e d p h e n o l s s h o w e d t h a t t h e i n c o r p o r a t i o n of group

of

were f o u n d t o h a v e a s i m i l a r d e p e n d e n c e

a c i d s was i n v e s t i g a t e d b y i . r .

bonding

compared

manifestations

bis-dithiophosphonic temperaturep.

of

phosphorus

T h e h y d r o g e n b o n d i n g p r o p e r t i e s of The

interactions

aad

stretching

p h o s p h o r y l and s u l p h i n y l compounds w i t h d e c a n o l hdve been by

K

T h i s was

t h e bond a r i s i n g f r o m c h a n g e s i n

9: Physical Methods

393

( 66 )

H

(68)

(67 1

c'Eo 0>P-OPh

CI

/sms

Sms'P=P

OH

ph*ph

0

PCI 3

+

(73)

(72)

(751

0 OR )2

p (o :

\ /

PPh,

[

- \/ '

0

I

>P-Y

P;y,/

X

R' (77)

'R

Organophosphorus Chemistrv

394

the hybridisation p. -d.

of

t h e phosphorus atom r a t h e r

Various macrocyclic phosphonamide

groups,

showing

U P - o

ethers,

which i n c o r p o r a t e phosphonate and

was

due

t h e u t i l i s a t i o n of

its

t o

peculiar

the phosphoryl

sandwich

s p h e r e a n d g o o d s h i e l d i n g of ring

1 . r . a n d 'H n m . r .

bis-a-hydroxyalkylphosphlne

4. 1. 3 S t e r e o c h e m i s t r y v o l u m e of

normal

oxides.

'"

taken

into

and

O q

phosphate

A

''

showed

A

aided

that

twist-boat

the

when dipole

planar

the

butene

'"

f i r s t time.

a l s o has t o

and

group

be

axial-equatorial

(70)

and

its

Kerr e f f e c t m e a s u r e m e n t s stabilises

t r a n s 1,2 epoxy-

studies

the

of

flexible various

propylphosphonic

acid

have a l s o been reported.

d i and tri

c o n s t a n t s have '42

probe

Spectroscopic

( - )

oxazaphosphorinanes

dioxaphosphepine

moment

4. 2 R o t a t i o n a l S p e c t r o s c o ~ y .

rotational

t o

indicate

planar-a-trans

the H-substituent

using UP-a

of

study by

a

s t u d y of

been

interconversion

vinylphosphonates occupy

conformational

o x a a a p h ~ s p h o l e s ' ~ ~a n d

a n d i t s mono,

data of groups

C=C

conformers.

derivatives"'

of

analogue

The b a r r i e r s t o r o t a t i o n have

function f o r trans-gauche

t h e o r i e n t a t i o n of

account

preferences

of

"

and i t s p e n t a d e u t e r i a t e d

a n d n m. r

I r.

that

study

derivatives

f o r t h e t r a n s conformer have been a s s i g n e d and

P=O

conformation concludes

t o the

boron

Host o f t h e f u n d a m e n t a l s a p p e a r e d a s d o u b l e t s

modes

the

which

- The v i b r a t i o n a l s p e c t r a a n d d e p o l a r i s a t l o n

estimated and a p o t e n t i a l that

ionophoric a c t i v i t y

s t r u c t u r e with a hydrophobic

of

8ome f o r t h e g a u c h e c o n f o r m e r suggested

in

Only one

the calcium ion.'"

ethyldifluorophosphine

have been obtained The

decrease

groups.

s p e c t r o s c o p y was a p p l i e d

t a u t omer i s m

chain

a

complex c a l c i u m i o n s c a u s i n g

t h e compounds (69) showed s u b s t a n t i a l

of

than any changes i n

' ''

bondi ng

-

The microwave s p e c t r a o f

phosphine

d e u t e r i a t e d forms h a v e b e e n r e c o r d e d . been

independently

evaluated

for

The the

9: Phvsical Methods

5

395

Electronic SDectroscoEy

5. 1 A b s o r D t i o n S D e c t r o s c o D y . at

343

nm

(7640)

and

d i p h o s p h a a l k e n e (71) has bands

- The

452

nm

(7230)

both

slightly shorter

at

w a v e l e n g t h and i n t e n s i t y t h a n t h e t r a n s i ~ o m e r . ' ~ ' The f o r m a t i o n a

hydrogen

bonded

complex

nm.124

established

The

aao

of

phosphite

The f o r m a t i o n o f a phosphonium

a band a t 242 was

tripropyl

and

h y d r a t e was s t u d i e d b y m o n i t o r i n g t h e i n t e n s i t y o f

octafluoropentanal (72)

between

quinone

ylide

through i t s long wavelength absorption a t 620

(73)

compounds

are

red

or

violet,

the

colour

d e p e n d i n g o n t h e n a t u r e of t h e a r y l s u b s t i t u e n t Y.

The d i m e t h y l a m i n o

derivative

band which c a n be

has

an

intramolecular

charge-transfer

used a s a solvatochromism i n d i c a t o r of s o l v e n t donor

power.

The

band

Potential

dyes

q u i n o l i n i urn

N - d i m e t h y l e n e t r i p h e n y l p h o s p h o n i um

spectra with

v.."

5 6 2 nm

o n c e SDe c t r o e c o p y.

The

anthracene

acidic

media

concentration. (A'".

535,

to lo-'

bisphosphonium and

give

a

The

I"

system

luminescence.

"*

as

2-styryl

have

vi sib l e

-

have good chromophoric p r o p e r t i e s . (Arm

exhibit

a

416b.14'

s a l t s ( 7 5 ) are s t a b l e i n n e u t r a l and

phosphates

(

fluorescence

76)

Distortion

causes

p-anisyl),

H concentration

violet-blue

q 0. 3 1 - 0. 4 1 ) .

conjueated

such salts

- O x a p h o s p h i n d o l e s (74) i n which t h e

i n particular (74; R

lo-'

blue fluorescence a t

proton

I"

p h o s p h o r u s a t o m i s two c o - o r d i n a t e The a r y l d e r i v a t i v e s ,

and

2 5 . 5 7 5 when h e x a n e i s t h e

s h i f t s f r o m v...

s o l v e n t t o 21 810 f o r w a t e r . ' 4 '

polarity

have

of

the

bathochromic

at

very

low

luminescence spectra coplanarity shift

and

of

fall

the in

5.

3 P h o t o e l e c t r o n a n d F l u o r e s c e n c e S D e c t r o s c o D y. - T h e p h o t o e l e c t r o n (PE) s p e c t r a of and t r a n s p h o s p h a a e n e (HP=NH) h a v e b e e n t h e s u b j e c t o f a t h e o r e t i c a l MO s t u d y .

and

nitrogen

lone

pairs

of

T h e i o n i r a t i o n of t h e electrons

effects

ecncountered

The

s p e c t r a of t h e d i h e t e r o p h o s p h o l a n e s ( 7 7 ;

and t h e i r a c y c l i c The

largest

phoaphorus l o n e p a i r . increase

indicated

that

states the

change

were X =

in

p o t e n t i a l u p o n r i n g c l o s u r e was r e l a t e d t o c o n f o r m a t i o n a l

ionisation effects.

analogues

ionic

phosphorus electronic

analysed. 0,NMe)

the

the

reorganisation

PE

i n

and

i n

IPI

and

contribution

t o

the

HOMO

The c y c l i c a m i d e a ( 7 7 ; X = 0, a

decrease

in

IPI

came

Y= NRz)

from

the

showed a n

compared t o t h e a c y c l i c

396

Organophosphorus Chemistry

analogue.

T h e PE s p e c t r a o f

R=

C,Si,

the

spiro

methyl and

hydrogen

interactin

which c o u l d n o t be d e t e c t e d i n t h e s p e c t r a

photoelectron

(78;

polyphosphines

Y=

h a v e b e e n a s s i g n e d w i t h t h e a i d o f MO c a l c u l a t i o n s o n

tBu)

analogues.

spectra

of

Theory

indicated

triphenylphosphonium

a

small

”’

spiro

The X - r a y

methylide

was

not

a l t e r e d upon c o m p l e x a t i o n w i t h g o l d o r c o p p e r . ” 3 X-ray

i n c o m b i n a t i o n w i t h CD a n d I R s p e c t r o s c o p y

fluorescence

was u s e d f o r t h e c o n f o r m a t i o n a l The n - d o n o r

power

dialkylphenylphosphines.

a n a l y s i s of

dialkylphosphino

group i n t h e conformer

c o n j u g a t i o n was a q u a r t e r o f t h a t o f

f a v o u r i n g p-n The

the

of

fluorescence

conformers with t h e phosphorus lone p a i r i n and with

the

phenyl

ring

the

MezN

group,

c o r r e s p o n d e d t o a n e q u i l i b r i u m m i x t u r e of

spectra and

indicated

a

out

lower

c o n j u g a t e d c o n f o r m e r t h a n t h a t e s t i m a t e d b y UV a n d ~ p e c t r o a c o p y . ~ ’An ~ X-ray

of

conjugation

proportion of carbon-I3

emission spectroscopic study of

the

n m.r.

phosphines

a n d t h e 1 r c h a l c o g e n i d e s showed q u a n t i t a t i v e r e l a t i o n s h i pa b e t w e e n t h e

K.

phosphorus

emission l i n e s h i f t and t h e charge on phosphorus.

relationship

of

P-substituent

o c o n s t a n t s were a l s o e x a m i n e d . “ 5

6

latter

t o

bond

polarities

D r f f r a c t i on.

-

book

A

on

of

of

of

n 2 ComDounds .

i n v e s t i g a t i o n s o f two c o - o r d i n a t e

w h i c h o r i g i n a t e from t h e g r o u p s i n B o n n several

studies of

sym-tri-t-butylphenyl ene.”’,

pentadienyl are

and

a

(Sma)

subatituents,

cyclopentadienyl)

’”

ag.

Tokyo.

observed diphosphene.

introduces

in

a

number

There

a

have and

tetraphosphatri-

a diphosphabutene,’”

triphosphabutadiene’”.

substituent i n (79) also

and

the

c o m p o u n d s many

compounds w i t h t h e u s u a l t r i m e t h y l s i l y l

a diphosphahexadiene,

butadiene’” which

Within

bonds.

There h a s been a marked i n c r e a s e i n

cryatallographic

been

Russia.”’

t h e f o l l o w i n g s u b s e c t i o n s t h e compounds a r e r e v i e w e d i n t h e

s e q u e n c e of d e c r e a s i n g n u m b e r of P-C

L. I.I

The

overall

m o l e c u l a r s t r u c t u r e of

the

o r g a n o p h o s p h o r u s compounds h a s b e e n p u b l i s h e d i n each

and

Diffraction

X-ray

6.7

the

a diphospha-

The p e n t a m e t h y l c y c l o fluxional

related

(bis

properties’” pentamethyl-

A phosphaalkene i n which

the

PIC

397

9: Physical Methods

carbon

atom

has

been incorporated

studied.

'''

The

structures

of

i n a four-membered

the

and

p h o s p h a a l k e n e (80) i n which t h e c a r b o n b e a r s been

' ''

compared.

The

crystal

( 8 1 )' '' a n d t h e p h o s p h a c u m u l e n e di-t-butylphosphino

phenyl

structures

8)

(

of

have

r i n g has been

isomers

of

the

and hydrogen have the

been

phosphaallene

determined.

Two

g r o u p s bound t o n i t r o g e n i n t r o d u c e d t h e n e c e s s a r y An & - r a y

structure

bulk t o give a s t a b l e c r y s t a l l i n e phosphazene.

1 6 '

of

system t o divide i n t o a

the

phosphapentalene

(82)

p o s i t i v e l y charged a z a a l l y l

showed t h e

T

g r o u p and a n e g a t i v e l y c h a r g e d

6.1.2

n3

ComDounds

The

c r y s t a l s t r u c t u r e of

one stereomer

phosphine ( 8 3 ) h a s been d e t e r m i n e d and t h e d e f o r m a t i o n conformational dimeric

analysis

described

R=

(84,

phosphaallene

structures

X-ray

1 7 0

for

the i n

and have

confirms

exceptionally

a

related

been determined

to

found

certain restrained polycyclic

the

the 9

have the

phosphine

compounds,

such a s the

low

"P

field

n m r

2 9 1 1 0 b

The

molecular

I, 2-di phosphi nes

di phosphetane,

l 7

have a l s o been slightly

was

crystallography

d i p h o s p h i n e (151, which p o s s e s s signals.

CPh2)"'

Y = NPh)"'

(85)

dioxadiphosphaphosphorinane

g e o m e t r y shown

Y=

Ph,

of

parameters

The c r y s t a l s t r u c t u r e s of

l b 7

p h e n y l i m i n o compound (84, R = b e n z y l , The

phosphole

'"

ring.

'

structures

have

been

a diazaphospholane,

studied Sip

highly

and

'

'''

A

large

ringed a

and a diazadi phospholane'

crowded

PP b o n d s ,

and

diphosphi rane, diphosphasilirane

'

had

w i t h p u c k e r i n g of

t h e phenyl

r i n g s of

t h e p h o s p h o r u s s u p e r m e s i t y l s u b ~ t i t u e n t s . ' ~ ' The

structure

of

new

the

elongated

A

acyclic

of

r e v i ewed

(86)"'

methano- bridged diphospha heterocycle

has been

established The c o n f o r m a t i o n s

of

two

bis-dia~adiphosphetidine'~' have

trioxatriphosphorinane conformation

with

environments

i n

(88)

three

was

The s t u c t u r e s o f

n'

with

0 '

t o

been

have

atoms

a i n

s o l i d s t a t e n.m.r.

has a l s o been s t u d i e d .

compounds have

a l s o been c r y s t a l l o g r a p h i c

~ i l o p h o a p h i r a n e ' ~ ~ ,a

found

phosphorus

agreement

b i c y c l i c compound (18; R = C C 1 3 ) have

The

structures

d i p h o s p h a d i b o r e t a n e ~ ' ~ ~ * ' a~ ~d,i a z a p h o s p h e t i d i n e ' 7 a

amine l i n k e d

(87)

t h e bis-dichlorophosphinoaminobenzene

of

i n t h e c r y s t a l and i n s o l u t i o n have been compared.''

s t u d i e s of

been

and a n

studied.

The

distorted

boat

non-equivalent results

The

"

''I

reviewed

"

There

a bismethylenephosphorane

chlorodiazaphospholium

salt,

"'

and

a

Organophosphorus Chrmistn

398

Smr /p

=CHPh

Sms

/

P =C

=CPh,

(81 1

(80)

R

I

Et

Me2N I

/OH

>P-CH Ph

P ‘C=Y

Y=C’

‘P’

‘Ph

I

R

(83)

(84)

Me2N

(62)

.Me

(86) Ph,P =N

(90)

OR

RO+

/SAr

-!yo

0-P

‘OR

(88) (89) Ph

9: Phyyicul Methods

399

''

diphenylphosphinodimesitylborane. 6, 1.3

nr

ComDounds

The

n-hydroxyphosphonium intermediates

in

salt

the

structure

of

a

was

to

identify

used

Wittig

reaction

t r i p h e n y l p h o s p h o n i u m s a l t s examined

'

perchlorate,

selenobetaine

derived

carbodiphosphorane, p h o s p h o n i urn

from

the

and

l a b

met h y l i d e

dioxomolybdate.'" distannate

tj,K-diethylthiocarbamoyl

a

addition

products

was f o u n d

'"

structure

betaine,

of

selenium

the

reaction

t o have a

The s t r u c t u r e o f

y l i d e ( 8 9 ) h a s also b e e n e s t a b l i s h e d

( 9 0 )'"

have

been

established

c a t i o n has been used a s a thionitrite (911

anions.'"

has t r a n s

conformation, one r i n g selenidea

i n

a

have

s e l e n i d e (209 4

rings

twist

One

is

one of

for of

inclusion

of

a

had

both

(

chloride,

compounds.'"

The

PhaPO)

have

bicyclic

been

chlorophoaphenium

'

include

chloride, and

anion,

salt

' ''

the

' ''

determined.

phosphinamides

various

in

a

chair

s u b s t i t u e n t s had

structures

of

two

tri-2-furylphosphine whilst

an

eight

a crown c o n f o r m a t i o n . ' " bonds and a r e d u c t i o n of

'"

structures

diphenylthiophosphinate

of

group i n t h e adamantanone s k e l e t o n

They

-)nenthylphenylthiophosphinyl

the

the sulphide

r e p o r t s on t h e c o n f i g u r a t i o n s of

chlorides.

thiophosphinyl

rings

found,"

t h e e n d o c y c l i c C-P

There have been t h r e e thiophosphinic

t h a t of

study

The

Iq'

the shortest

t h e a n g l e formed by t h e s e bonds

and

the stabilised

and

the

t h e P=Se bond o f

phosphoryl

leads to a lengthening of

the

pentacyclic

two i s o m e r s of

membered c y c l i c p h o s p h i n e s e l e n i d e p o s s e s s e d The

a

of

diphosphoraneiminium

two a x i a l phenyl

conformation studied,

The

ion

o t h e r which had

been pm)

counter

The s t r u c t u r e

fused the

to

l q 0

T h e s t r u c t u r e of a s t a b i l i s e d p h o s p h a z e n e , ' "

imine

a

't.'

diazastannylenes"',

Another product

dibetaine

from

with

-detected

Amongst a number o f

' 7 ' 1 8 3

were

diastereomeric n m.r

methylene-I-boraadamantane

a

I'

trapped

RP

t-butyl-l-menthyl-

corresponding an

antimony

and

two

diphosphetes

from

obtained

dimenthyl

of

Structural

derived

menthyl

a s t u d y of t h e e p i m e r s o f

the

of

Y = H,

(92;

of

investigations

phosphole

from

complex

dimera'"

and

reaction

a

with

I, ~ - c y c l o o c t a d i e n e z o ' have a l s o been reported. A , s t r u c t u r a l a t u d y of

a trismorpholinophenacylphosphonium

a n d i t s y l i d e s h o w e d t h a t t h e P-C

bond o f

t o t h e n i t r o g e n which h a s t w o s m a l l a d j a c e n t bond a n g l e s and n o t nitrogen with t h e highest

tetragonal

salt

the ylide is antiperiplanar

character.

the

This contrasts with

400

Orgunophosphorus Chemistry

previous

results.

The

c o n ~ u g a t i o ni s l e s s phosphonium

ylide.

s t e r e o c h e m i s t r y of configuration of have

i n

been

In

lo’

unfavourable

of

support of

addition

Ph),

’*

of

a

t o

the

20

and

a

crown

7

(931,

tetraaaadiphosphonium

salt,

”’

the

cyclophosphazenes

been

investigated.

a

21’

and a phenylchromium bridged hydrogen-bonding and

the

have

thiophosphoramidate

a

s a l t of

configurations determined.

derivative of

lone

pair

-N, Y - d i met h y l - 1 -

heterocycles

t o l u i d ines

(48)

tetraphosphazane

has

~ t u d y , ~a ’s h a v e n u m e r o u s

two

isomeric

acid,

the

dialkylamino

a

2 2 0

related

N-phenyl-

The bond l e n g t h s the

nitrogen

There have

R = CHaPh, from

Y=

cyclodiphosphaaene”

and

reaction

of

’’

The

a crystallographic

The

structure

and

amides

A

systematic

triphosphazenezZ4 have been reported.

been

SNe)”’

the

s u b j e c t of

cyclophosphazenes.

tris

a

diastereomer

i n t e r a c t i o n of

the

a 2 1 6

cyclic

of

thi ophosphorylt r i c h l o r i d e .

been

of

include

structures

obtained

and

and a

2 1 7

with t h e a x i a l phosphorus s u b s t i t u e n t . “

membered

*’’

number

of

r e p o r t s on a dithiodiaaadiphosphetane ( 3 3 ; eight

(9b)

The

and

bicyclic

a dibromo-2-hydroxyphenyl

D-gluconic

of t h e l a t t e r were c o n s i s t e n t w i t h n - u *

Y=

(

cyclotriphosphazene,

( 9 5 ) have a l s o been determined.

oxaza-phosphorinane

be The of

They

cyclotriphosphaaene.

6-phanylcyclophosphamide’

of

t o

33;

A

reported.

methylsilane

in

been

an The

studies

a fused

thiazaphosphorin

been

cyanocyclotriphosphazene,

’“

’ O ‘

diazadiphosphetane 2’’

S

there

found

Crystallographlc

a trans

”

also

have

was

the the

bonding t o electron-acceptors.’Oq

triphosphabenzene214have

phosphates“’

and

compound.

(69)

ether

that

trrphenyl-

establishing

glycosyl

a triaminophosphonium dititanylmethyllde,

phosphate”’

the

3, 8-diphosphonate,

phenenthroline

f o r co-ordinative

phosphonamides

The

conclusion

than

a fl-formylphosphonateZo‘

1 4 c r o w n 5 e t h e r was a l s o s t u d i e d . ” ’ cyclic

the

ylide

e t h y l l,1-phenylhydroxyethylphosphonate2’’

(-1

phosphonate2’’

conformation

type

t h e oxime of

studies

a-guanine

structures this

of

of

a

a

cyclo-

study

of

the

c r y s t a l d a t a f o r t e t r a f l u o r o and t e t r a c h l o r o t r i p h o s p h a z e n e s r e v e a l e d a

correlatfon

of

triphosphazenes five-,

six-

diamines,

and a l s o

e.g. (

and

271

established.

t o

basicities.”’

Several

monospiro

have been examined where a d d i t i o n a l s a t u r a t e d

seven-membered

~ b . t 2 0 # 2 2 ~

a n d PNP bond a n g l e s t o t h e g r o u p

NPN

endocyclic

electronegativities

An A

hexachlorotetraphosphaaene

example

rings of

originate

an

ANSA

from

structure

diols was

and also

diaziridotetrachlorotriphosphazene

and

have

The

also

been

investigated.”’

40 1

9: Physical Methods

c r y s t a l s t r u c t u r e of 6 . 1. 4

n'

and

n6

five-co-ordinate (96),

which

a dithiazaphosphazene ComDounds.

compounds.

has

a

most

pentaphenylphosphorane, CFJ)

'

There They

have

been

include

interesting and

2 q

has been r e p o r t e d . 2 2 a

the

the

source-

carbon

and

97;

X=

(

The b i c y c l i c c a r b o x a m i d e

an

apical

position.

The

ring i n a half-twist structure

of

a

conformation fused

'

t h i ohydroxyphosphorane'

Electron

t o

"'

cyclohexene.

phosphorane,"'

its

a six-membered and

The

the

first

been d e termi ned.

have

The s t e r e o c h e m i s t r y o f e s t a b l i s h e d by X - r a y

similar

bicyclic

methylene

a t o m is p l a n a r ,

nitrogen

e n d o c y c l i c a n g l e i s e n l a r g e d t o 132" and i t is p a r t o f

6.2

dioxide

(98) h a s a n e a r l y i d e a l t b p s t r u c t u r e w i t h t h e

phosphorane i n

s t u d i e s of

monocyclic-phosphorane

which h a s a n a p i c a l hydrogen

group

several

carboxy-phosphorane

the

hexaco-ordinate

(51)

betaine

was

crystallography.P3

- A gas phase conformational

Diffraction.

a n a l y s i s of

n-styryldichlorophosphine i n d i c a t e d t h e p r e s e n c e o f a n e q u i l i b r i u m o f e i t h e r ~ 1 a8n d e c l i p s e d c o n f o r m e r s o r ~ 1 a8n d t r a n s

7

D i p o l e Moments.

Kerr Effects,

conformer^.^"

Cyclic Voltammetry

and Polarography

7.1

Moments

DLpole

and is

t-butylphosphaethyne

Kerr

esu i n cyclohexane.

The a n i s o t r o p y o f

both

and

the

electron

molecule

is

8.07

An.2s'

The

have

of

been

applied

to

phosphate

of

of

the

has

initio

(5. 3

of for

A')

C=P

been

bond

have

been

of

publi~hed."~ analysis

of

the

The

oxides these

f o r t h e i n t e r p r e t a t i o n of t o

the

dimethyl

and d i a r y l m e t h y l p h o s p h i n e

applied

in

polarisability

calculations

5, 6 - b e n a o - I , 3, 2 - d i o x a p h o s p h e p i n s .

t h e o x i d e i s a n equilibrium of

moment

i s 104 x

methyl phosphinate,

conformational

The g r a p h i c a l method

m o m e n t s a n d Kerr E f f e c t s analysis

the

ab

m o m e n t s of

m o m e n t s of n e a r l y 5 0 d i a l k y l

compounds.

polarisability

polarity

results dipole

phosphonate and t r i m e t h y l dipole

dipole

i s 0.46 D and t h e l o n g i t u d i n a l

The and

The

C = P bond i n d i c a t e d a h i g h asymmetry of

the

density."'

adamantylphosphaethyne stereochemistry

-

Effect

1.24 D and t h e Kerr c o n s t a n t

dipole

conformational

In a polar solvent

t h e c h a i r conformer and

two

flexlble

402

Organophosphorus Chemistn

forms.

'"

These

conformational

Cyclic

controlled the

VoltammetrY

formation phenyl

of

and

of

fluoro,

Ph2P < <

as

mono

f o l l o w i n g s e q u e n c e of

chlorodiphenylphosphine c h l o r o and bromo Nucleophilic

the

and

exclusive

dipole

P o t e n t i ometri c and conduct imetric vinyl triphenylmethanolic have been

indicate

and

diphenylphosphine substitution

benzene

gives

'''

product.

diphosphorylated

P( S) He2 :: PNRHe2

P( 0 )He2 <

cyclotriphosphaaenes

Cyclic

indicates

the

'*'

P( S e ) Me2 <

measurements

Studies

of

have

the

propargylt riphenyl-

< P'Ph3

P'He3

been

made

electrosorption

p h o s p h o n i um

cations

on of

from

s o l u t i o n s a t dropping and hanging mercury drop e l e c t r o d e s published.

voltammetry, differential

Differential

2 4 2

using

accumulation time,

mercury

drop

g a v e 8 - 100 f o l d

pulse

pulse

adsorptive

electrodes increase

'"

polarography

used f o r t h e determination of metabolites.

NAD',

i n

stripping

a

and

2

minute

sensitivity

over

The l a t t e r t e c h n i q u e h a s b e e n NADP'244

and

various

adenine

"'

Mass S p e c t r o m e t r y

8 base

in

peaks

the

bis( diethylamino) phosphanes

mass (

99;

spectra

X=

NEt2)

s h o w i n g t h e r e a d y l o s s of t h e o r g a n l c base

peaks i n t h e s p e c t r a of

X=

Br)

are

formed

dichlorophosphanes the

by

other

hand

of

ethene

alkenyl-

of

all contain the

and ions

arylPX2'

g r o u p bound t o p h o s p h o r u s .

The

t h e correspondlng dibromophosphanes

(99;

the

elimination

more r e a d i l y f r a g m e n t w i t h

( t r i c h l o r o m e t h y l ) phosphane molecules

The

e l e c t r o n a c c e p t i n g shown b e l o w . 2 b o

< < NO2

On

7 0 ) .' ' '

- C y c l i c voltammetry and

PolarograDhu.

diphenylphosphini te.

voltammetry

The

(

the diphenylphosphide anion a s an intermediate i n

tetraphenyldiphosphine

He2P < <

were a l s o u s e d i n t h e

methods

dioxaphosphepins

c o u l o m e t r y of

potential

t h e cathodic reduction of and

physical

of

a I4 c r o w n 5 p h o s p h o n a t e h a s b e e n m e a s u r e d . ' "

moment o f 7.2

combined

analysis

of

HBr,

loss

of

chlorodiethylphosphane fragment

with

loss

respectively t o give their

of

and one

whilst

the

diethyland

b a s e peaks."'

two Not

9: Physical Methods

403

s u p r i s i n g l y t h e s p e c t r u m of t h e b i s 1 , 2 - d i c h l o r o p h o s p h a n e dominated

by r e t r o c y c l o a d d i t i o n ,

The d i p h o s p h a c y c l o b u t a n e involves

loss

resultant

of

bis

pathways.‘” produced

evidence

examined.

i n

spectrometry

It

has

phosphinates

’“

P-N

bonds

For

diphosphadiboretane

of

shown

carboxylic

of

both

that

the

organic‘”

latter

group

of

effect

some been

thiolo

and

(109)

compounds,

for

the

nitro

were

are

isomeric

(105).

but

a good

elimination

the

of

for

of

dialkyl

example

found

whilst

t o

alkyl groups

Selected

been

Thus,

and t h a t

resistant

elimination of

has

with

oxides

phosphorus

thiono

phosphates.’”

groups

nitrobennylthiophosphonates

and

by mass s p e c t r o m e t r y , ’ ”

methylphoaphonates have been studied,”’and orthg

of have

c o n t a i n i n g f r a g m e n t s were

bound t o p h o s p h o r u s o c c u r s f o r t h e p h o a p h i n a t e s , the

spectra

chlorides

of (103)

t o P z N containing fragments

phosphorylcarbamates

the

mass

The

“

The

variety

The mass s p e c t r a o f c y c l i c p h o s p h i n e

extrusion

been

a

the alkyl s a l t s especially those

may b e d i s t i n g u i s h e d

cleavage.

the

of

spectra of

’’

the

by

is

which

a s shown i n ( 1 0 1 )

fragments

i o n s c o r r e s p o n d i n g t o P-N

the

evidence

fragments.

’

ions corresponding

lower c h a i n l e n g t h s . show

of

’

benzene

fragmentation

am1 n o p h o s p h o n i um

tri alkyl-

Whilst

complex

possibly

(102)

f o r SmsP=BNC* H I a .

and

always observed, observed

trimethylamine

Mass

tri phenyl-

a

undergoes

phosphaquinone

(100)

with t h e elimination of

dimethyl

the

nitro

isomer g i v e s s t r o n g m o l e c u l a r i o n s a n d a b u n d a n t i o n s c o r r e s p o n d i n g t o

e l i m i n a t i o n of t h e n i t r o b e n a y l g r o u p ,

is

dominated

by

M

the

i n v o l v i n g a t t a c k of s u l p h u r

shown has

i n been

(105)

’”

A

again

facile

bond with

r i n g with t h e adamantyl moiety.”’

s t u d y of t h e E . I .

Me,

the

P-C

adamantylphosphonate a l s o rearranges phrnyl

CDj,

One)

intrn8ities

that

”‘

spectrometry

of

c h a r a c t e r i s a t 1o n liquid-phase

systems.

of

the aryl

alkyl the

has a

been study

but

product

and

diphenyl

of

incorporation

a

t o

ntermedi a tes

of

Y=

H,D,

X=

Y = Me, 2 = F ) a n d i t s

applied i

the i

n

direct r e a c ting

iodolactonisation,

poaks corresponding t o r e a c t a n t

and t h e iodolactone

as

There has been a d e t a i l e d

of S o m a n ( 1 0 6 ;

s h o r t -11 v e d

In

ring

compounds

phosphonates

cleavage

s p e c t r a of some p i n a c o y l c o m p o u n d s ( 1 0 6 , including

deuteriated analogues.

PAB

t h e o r t h o isomer

can be r a t i o n a l i s e d a s

which

r a n g e of a d a m a n t y l p h o s p h o r y l

Once

exhibit

t h e s p e c t r a of

ion

a t t h e o r t h o carbon of

wide

investigated.

phosphonamides

NO2

-

(

the

1071, i n t e r m e d i a t e s

was m o n i t o r e d o v e r 24 h.

Diiodo

and

404

Organophosphorus Chemisty

RPX,

m p C l 2

PCI 7

(99) (100)

(101)

cx3

(X,C),C

I

-ex-0 (106)

0

II

-PYZ

(1021

0

II

(RO 12 P -X

(CH 2 1n C H (107)

=C H2

9: Physical Methods

monoiodo

405

phosphonium

evidence f o r the (108)

give

cleavage bond

stable

of

intermediates

formation

of

molecular

t h e P-S and C-S

cleavage.’”

ions

observed but The a l k e n y l

and

dithiophosphate

w i t h H t r a n s f e r a s shown ( 1 0 9 )

full

of

the

bond

was

readily

cleaved

compounds showed s t r o n g m o l e c u l a r very abundant catecholP’ discussed

g r o u p was n o t but

it

above

the

labelled

with

the

molecules. enabled the

must

Nevertheless isomers

myo-inositol

t o

be

1,2-cyclic

have

The

(

were

of

the

when

simultaneously.’bJ been i n v e s t i g a t e d . The

mass

diphosphetidines the

loss

of

A l l

and

effect

the nitro

e s t e r (111, X =

NO2)

JhS, “S,

“0,

indicate

extensive

i n

the

a t

spectra the

A l l

t o determine

two

which

isomers

of

GC/HS

of

by

P o s i t i v e and negative

used

showed

least

ion FAB

t h e amounts

of

2 b 2

c h l o r o spiroamino-cyclotriphosphazenes h a s been

temperature

that

the ortho

loss o f

i n t e r a c t i o n of

present

derivatives

c a r r i e d by t h e v a r i o u s showed

t o that

112)

d:stingui~hed.~”

d e t e r m i n e d by mass s p e c t r o m e t r y raising

the

during preparation

purity

the

was f a c i l e

phosphate have been determined

been described

epimers produced

a

dithio

Scrambling experiments

involve

ions

per-trimethylsilyl

spectra

SH

The mass s p e c t r a o f

monothiophosphates

mechanism

bond

been

an o r t h o c h l o r i n e gave base peaks

isomerisation prior t o fragmentation that

of

With r e g a r d

C1.2bo

has

t h e l a t t e r compounds

loss

interesting t o note

compounds

gave C-S

catechol thio,

reported for the ortho nitrophenyl

related

c o r r e s p o n d i n g t o loss o f a n d ’H

of

t o

P-O(R)

i o n s and t h e a r y l e s t e r s (111) gave

ions

was

For

and

also There

2 ’ g

fragmentation patterns

p h o s p h a t e s and phosphoramidates ( 1 1 0 )

P-N

was n o

fragments corresponding

cleavage but study

there

thiophosphates

bonds a r e o b s e r v e d i n a d d i t i o n t o

related

A

were

*”

dimers

of

This the

ions. two

A

was

probe study

chlorine

achieved

and of

by

carefully

measuring t h e current fragmentation

atoms

are

I n addition pentaphenoxy

lost

patterns

they

depart

cyclophosphaaenes

have

”‘

spectra

of

several

five

co-ordinate

have a l s o been analysed.’” alkylamino

radicals

difluoroalkylaminophosphinimine.

or

from

fluorodiaza-

Base peaks a r o s e dissociation

t o

from the

406

9

Acidities.

A comparison of phosphite 17.4

the ionisation constants

(113)

i n

B a s i c i t i e s and Thermochemistr~

showed

thf

DBU

than

and

are

salts

have

v a l u e s of

on

was

group

as

A

i n

reagents

basic

electron

study

of

catalysts

those

of

were

constants

of

(

(methylphosphonic acid) The

pK.

reviewedz7'

(116)

showed t h a t

acidity

constants

The d i s s o c i a t i o n

2 7 0

and phosphinic a c i d s ,

2 7 1

et hylenedi a m i n e t e t r a k i s-

and

have been determined.

The l a t t e r were weaker

found

marked.

the effects

that

of

oxygen

the

of

constraints

have

been

which maintain pyramidal

aminophosphoranes have been studied

basicity of

apical nitrogen

It

atoms c a n b e q u i t e

07'

Increased heats

hydroxytetraoxyphosphoranes

of

values

and

n i t r o g e n o n t h e b a s i c i t y of

s e n s i t i v i t y i s c l a i m e d for t h e d e t e r m i n a t i o n

c o m b u s t i o n of

pressure

chloro-organic phosphonates

'''

10 10.1

n m. r

t h a n EDTA a n d E N H T P . 2 7 J

acids

DTA.

t h e compounds

acids

T h e pK.

2 * a

by ' H

diphenylthiophosphoryl

hydrazides

picolylamino) salicylphosphonic

a-f l u o r i n a t e d p h o s p h o n i c

was

of

The charge

The d i p h e n y l p h o s p h o r y l

than of

state

a l t e r i n g the group R caused larger changes i n the t h a n t o Lhe b a s i c i t y c o n s t a n t s

organic

negative

determined

base mixtures.

series

for

basic

nitroalkanes

of

the transition

accepting a

20 9 and

a l k y l ( t r i - t - b u t y l ) phosphonium

than

(115)

acid-quenched

more

2 ' q

2,3-butylene The

3 33 i n d i c a t e s a h i g h d e g r e e

the a-carbon

of

and

1 , 5 0 0 t o 1 0 , 000 t i m e s m o r e

are

recommended

t h e Horner

integration group

(114)

b e e n shown t o be s l o w e r

development

diethyl

2 b 6

The k i n e t i c a c i d i t i e s o f

H a m m e t t p v a l u e of

of

l a t t e r t o be more a c i d i c (pK.

respectively)

triaminophosphinimines synthesis

the

of

20

organophosphorus

-

40

compounds.27b

by t h e a m i n a t i o n o f

at

been studied

the

addition

of

formation

dimethylphosphite

the

of

solid

aminomethylene-

can be followed by

Chr&oPrsphy

G a s L i a u i d C h r omatogrgEhy. -

association

by

The

of

c o m p o u n d s i n a bomb w i t h a n

between by

The

trioctylphosphine

g . l c.

Strongly

thermodynamics oxides

negative

of

molecular

and haloalkanes deviation

from

have ideal

9: Physical Methods

407

X 4

(113

(112)

(111)

Y

Catalyst

JyY

-

(118)

(117)

-

Nu

6\l,Y

Nu

Catalvst

\O

(119)

0

II

YCO(CH,), P(OE t 1,

C a t a l y s t +Y

Catalyst

L

(122 1

(121 1

(120)

(12 3 1

(124)

408

Organophosphorus Chemist n

behaviour

i n t e r p r e t e d i n terms of

WBS

for ethers, chlorides,”‘

t h e a n a l y s i s of

the

thermodynamic

10,2 L i a u i d Chromatography. of

tributyl

-

phase based on

t h e o t h e r hand acid

the

optical

its

and

by

inorganic

can

phosphate.

and i t s phosphate 1 0 . 2. I

achieved

specifically

stationary

bonded

t o

phase

prepared

of

Lawesson‘s

coupling reagent,’” the

of

naturally-occurring spectrofluorimetry,

from

reaction

with

from

p h o s p h a t e s and alumina

using

Enantiomeric

tertiary

as

a

was

of

2 q

used

t o

enhanced

racemisation phosphates,“’

the

and a v a r i e t y of

other

In

combination

study

the

by

free

f o r t h e e s t i m a t i o n of

inositol

thiamin,”’

phosphates. HPLC

n i t r o b e n z o y l p h e n y l g l y c i ne

reagent

separation

m o n o m e r i s a t i o n of g r a m i c i d i n A

time

with dependent

phosphatidylcholine

in

l i p i d c o n c e n t r a t i o n induced monomerisation and enhanced emission intensity.

’”

1 0 , 2. 2 T h i n Laver Chromatouraphu. separation

of

the

This technique has been applied

products

from

recoil atoms with tetrachloromethane,’q4 d e t e c t i o n of

On

diastereoisomers

organic

o n a r a p i d method

phytic acid,“’

and

’”

There have been r e p o r t s on an

orthophosphate,’“

metal

the the

Chromatography.

determination

the

using

displaced

aminopropylsilica

HPLC m e d i a t e d t e s t

fluorescent

acids

were s e p a r a t e d i n 9 6 % y i e l d a n d 9 9 % p u r i t y u s i n g a

oxides

High

-amino

esters a r e a l s o reported.”’

chiral

t . h. f .

a series

L i q u i d c h r o m a t o g r a p h i c a n a l y s i s of t h i a m i n

High Performance L i a u i d

phosphine

peptide

was

’”‘

for

I-hydroxyethylphosphlnic

of

resolution

I t has been found t h a t

be

and c a l c u l a t i o n s

by l i q u i d c h r o m a t o g r a p h y on a c h i r a l

f o l l o w e d by s e p a r a t i o n o f

chromatography.”’

phosphonates

been

vaporization

N-( 3 , 5 - d i n i t r o b e n z o y l )

esters

I-naphthylethylamine

of

The e n a n t i o m e r i c r e s o l u t i o n o f

p h o s p h i n e o x i d e s was a c h i e v e d

stationary

phosphate’”’

parameters

’”’

c y c l o t r i phosphazenes

There have a l s o

d i and trichloromethanephosphonate e s t e r

r e p o r t s on t h e p r o p e r t i e s of of

a s s o c i a t i o n w h i c h was g r e a t e r

t h i o e t h e r s and t e r t i a r y a m i n e s . ” ”

ammonium

salts

polyphosphates

determination of

of

thio

and

phosphorus

the

of

2’7

separation

alkali

seleno phosphates,”’

i n f i s h products‘”

l e c i t h i n i n foods.

t o

t h e r e a c t i o n s of

and t h e

the

9: Phvs i c u 1 Methods

31 The

409

Kinetic&

kinetics

and

mechanism

(117)

amidocyclophosphite parameters

of

The n a t u r e

of

t h e polymers The

compound ( 1 1 7 ,

R= E t )

role

medium,

the

structure

and

concluded

that

species of

produced

the

of

rates have

aprotic

The

protogenic

amide a l c o h o l

the

of

diethylamino

F o l l o w i n g a s t u d y of

of

the

complex

the

reagents,

and

the

reagents,

it

was

was

the

most

reactive

Arbusov r e a c t i o n have been d e t e r m i n e d and t h e former

triethylphosphine with

and

constant

for

tertiary

butoxy

activation

abstraction

the

The

' O 0

order

kinetics from

Solvat

i

on

phosphine by t h e The

' 0 2

relationships of

of

The a b s o l u t e r a t e

' O '

determined

addition

reaction

with carbon disulphide

hydrogen

been

LFER

and

have

kinetics,

been used i n a

dialkyl

phosphites

t o

cyclohexylimine rate

constants

tetracyanoquinodimethane

(

transfer

of

for

TCNQ) w i t h

t o t h e b a s i c i t y of

alkaline hydrolysis the nature of

of

has

t h e mechanism of

related

cases

pseudo-first

radical

parameters

The

most

n i t r i l e solutions are small

the

crotonaldehyde

i n

diethylphenylphosphine

reversible

effects i n various

phase

and

organisation

found t o be r a t e - d e t e r m i n i n g

was

determined

Rate c o n s t a n t s f o r t h e a l k y l a t i o n and d e a l k y l a t l o n s t e p s

2 9 q

s t u d y of

the

by a n i o n i c and c a t i o n i c c a t a l y s t s alcoholysis

been determined

molecular

the Michaelis

occurs

of

polymerisation

s t u d i e d and t h e thermodynamic

e n d o t h e r m i c and d r i v e n by a p o s i t i v e change i n e n t r o p y

a r e compared of

the

been

r i n g c h a i n i n t e r c o n v e r s i o n have been

is

reaction

of

have

the

complexation

stabilised

the l a t t e r

phosphonium The h a l f

' O '

of ylides

l i v e s of

a l k y l t r i b u t y l q u a t e r n a r y phosphonium

salts

the in

c o n d i t i o n s a r e r e p o r t e d and found t o be dependent on

t h e h a l i d e ion.

The r e a c t i o n o c c u r r e d i n

the

organic

p h a s e w i t h water b e i n g e x t r a c t e d f r o m t h e a q u e o u s p h a s e a s q u a t e r n a r y phosphonium

hydroxide

unimportant."' introduction

Interfacial

In contrast t o of

alkyl

hydrolysis

of

of

the

trend

t e t r a p h e n y l p h o s p h o n i um

alkaline

bromide.

benayltriphenylphosphonium

involving

desolvation

c o n t r i b u t e t o an increase

found

produced

t o by

be the

hydrolysis

of

b r o m i d e i n DMSO w a s f a s t e r t h a n t h e

and

i n volume.

' O '

The

rates

of

s a l t s are strongly retarded

by a n i n c r e a s e i n p r e s s u r e i n accordance with a mechanism

were

phenomena usual

groups,

3-bromopropyltriphenylphosphonium hydrolysis

the

two

fragmentation

or

three

each

of

step which

' O '

N u c l e o p h i l i c s u b s t i t u t i o n b y p h e n o x i d e of t h e c h l o r i n e a t o m

i n

410

Organophosphorus Chemistry

chloromethyldiarylphosphine reaction

at

The of

t h e @-carbon atom

electronic a

been s t u d i e d

and

phenyl

The c a t a l y t i c a c t i v i t y was of

the a r y l groups

catalytic

p o l a r i s a b i l i t y t h a n mononuclear p y r i d i n e s

(118).

has involved

This

mechanism

of

been

The

benzo

the

derivatives

The g e n e r a l l y a c c e p t e d

'lo

t h e s o l v o l y s i s of

phosphoryl

intermediates such as

challenged

and

evidence

for

a

t o five

s i x c o - o r d i n a t e d s p e c i e s ( 1 1 9 ) a n d (720,121) h a s b e e n p r e s e n t e d (120)

I t i s p r o p o s e d t h a t o v e r a l l i n v e r s i o n i s o b s e r v e d when w h e r e a s (121) l e a d s t o r e t e n t i o n o f

intermediate

r a t e equations i n d i c a t e f o r a v a r i e t y of

reaction profiles and

the

relative

rates

of

formation

intermediates.

' I '

The r a t e s o f

esters

up

to

were

entropy of

diphenylphosphinates

are

The

facile

catalysis

alkaline

phosphonates

by

the

-M-- d i e t h y l a m i n o

(

enolate

is Also

' I '

thionophosphonates,"'

ethyl-

and vinyl-

The n e e d t o u n d e r s t a n d stereochemistry considerable elements

of

been found t h a t

been

of

t o

t h e r a t e s of t h e thermal

phosphonates,'"

the stereochemistry of

for and

isomerisation of properties

of

d e c o m p o s i t i o n of

have been s t u d i e d

substitution

Comparisons with

due

intramolecular

the inhibitory and

and

acetylalkyl-

attributed

r e w a r d i n g a n d marked

p h o s p h o r u s a t o m of

the

the

rates

and

phosphorus is of

a t

chemistry

of

other

I t has

s i m i l a r i t l e s noted.

nucleophilic

substitution

a t

a p h o s p h o r y l g r o u p c a n bo e x p l a i n e d u s i n g t h e

same f r o n t i e r o r b i t a l terms a s

those

used

for

silicon

compounds.

T h e m e t h o d i n v o l v e s N g u y e n T r o n g Anh a n d C. H i n o t e x t e n s i o n of the

these

The a m i n o l y s i s

the factors controlling

nucleophilic

importance.

has

of

phosphinate

catalysed

'"

hydrolysis

122)

chlorocyclohexenylphosphonate~,''~ p e r e s t e r s of

of

activation.'"

general-base

diamines t h i s occurs intramolecularly carboxyalkyl-

depending

decomposition

hydrolysis

an The

10 t i m e s f a s t e r f o r t h e t h i o n o p h o s p h i n a t e s

mainly t o a l a r g e r negative

of a r y l

alkaline

is

configuration

on

tho

been

t o

The c a t a l y t i c e f f e c t s

' 0 9

double s u b s t i t u t i o n has

has

related

mechanism i n v o l v i n g i n t e r m e d i a t e s w i t h e x t e n d e d c o - o r d i n a t i o n and

SN2

which i s a t t r i b u t e d t o a h i g h e r

activity

m e c h a n i s m f o r n u c l e o p h i l i c c a t a l y s i s of compounds

rate

isocyanate

linearly

p y r i d i n e s have a l s o been s t u d i e d

higher

Although t h e

the

t r i a r y l p h o s p h i n e o x i d e on t h e r e a c t l o n

hydrazide

properties

various

have

has

' O n

c a t a l y t i c e f f e c t of

diphenylphosphinic

investigated of

oxides

group is electron-accepting i t reduces

phosphorus

approach.

In

transition

nucleophile

a n d t h e L U M O is t h e

state

the

HOMO

is

a* a n t l b o n d i n g o r b i t a l

Sal'em's

centred on t h e of

the

bond

41 1

9: Physical Methods between

phosphorus

The b i g l o b e o f t h e L U M O

and t h e l e a v i n g group.

i s l o c a t e d i n t h i s bond a n d when b o n d i n g o v e r l a p b e t w e e n t h i s o r b i t a l a n d t h e HOMO p r e d o m i n a t e s o v e r a n t i b o n d i n g i n t e r a c t i o n s i n v o l v i n g t h e l e a v i n g g r o u p ( a s o f t e n o c c u r s when f l u o r i d e i s

of

retention

configuration

i n t e r a c t i o n s predominate

occurs;

(as

the

whereas

often

occurs

leaving

when when

group)

the antibonding

is

chloride

the

l e a v i n g g r o u p ) t h e n u c l e o p h i l e i s r e p e l l e d and r e a c t i o n o c c u r s a t t h e

of

backside

this

bond,

Thus

a

more

delocalised

i.e. when

inversion contrast group.

the

&.

occurs,

nucleophile.

of

amount

inversion.

and

the

leaving

is

group

strong

for

b o t h g r o u p s a r e i n a p i c a l p o s i t i o n s o f a t . b. p.

In

electronic

interaction

is

very

smallest

when t h e n u c l e o p h i l e a f f o r d s a 9 0 " a n g l e

when to

retention

the

leaving

I

The i n f l u e n c e o f s t e r e o e l e c t r o n i c the

isomers.

alkaline

a s shown,

c h a i r conformer, equatorial

are very

similar

leavin$

a pseudo a x i a l

position

have

been

phosphinic chlorides. hydrolysis

probably

of

involve

a

The f a s t e r r e a c t i o n i s a t t r i b u t e d t o

group. which

which h a s t h e

allows

leaving

favourable

3 2 0

found

to

be

additive,

which

R e p o r t s have a p p e a r e d on

phosphono u r e a s ,

t h e o a o n o l y s i s of c y c l o p h o s p h a m i d e

group

in

stereoelectronic

A r y l s u b s t i t u e n t e f f e c t s on t h e h y d r o l y s i s

3 1 9

phosphates

and

t h e r e i s a 30% d i f f e r e n c e b e t w e e n t h e compounds w i t h

r e a c t i o n of a t w i s t - b o a t c o n f o r m e r effects.

e f f e c t s has been i n v e s t i g a t e d

d i o x a p h o s p h o r i n a n e s ( 1 2 3 ) and i t s

of

hydrolysis

W h e r e a s t h e r a t e s o f h y d r o l y s i s of t h e i s o m e r s w i t h a n a x i a l

l e a v i n g Qroup, an

the

n u c l e o p h i l e c a n have a l a r g e r a n t i b o n d i n g

k i n e t i c d a t a i n d i c a t e t h a t t h e e l e c t r o n i c i n t e r a c t i o n between an

incoming n u c l e o p h i l e

for

of

nature

i n t e r a c t i o n which l e a d s t o a n i n c r e a s e i n t h e The

The m a g n i t u d e of t h e

leading t o inversion.

i n t e r a c t i o n s a r e a l s o d e p e n d e n t on t h e

the

of

triaryl

contrasts t o kinetics

of

t h e cascade r e a c t i o n s involved i n metabolites,322

the

reaction

of

b u t a n o l w i t h p h o s p h o r y l t r i c h l o r i d e , 3 2 3 and t h e s t e r i c e f f e c t s on t h e a l c o h o l y s i s of a l k y l p h o s p h o r o d i c h l o r i d a t e s . 3 2 4 The with

u. v.

i n i t i a t e d r e a c t i o n of t h e b i c y c l i c p h o s p h o r a n e ( 1 2 4 )

d i a l k y l d i s u l p h i de

formation

of

involves

cleavage t o form a l k y l t h i o r a d i c a l s kinetics

hydrogen

a phosphoranyl r a d i c a l .

is

abstraction

with

the

I t is c o n c l u d e d t h a t S-S bond rate

determining.

32'

The

of i s o m e r i s a t i o n s i n d u c e d b y t h e r e a c t i o n s o f h y d r o p e r o x i d e

w i t h d i c a t e c h o l and d i p i n a c o l y l h y d r o p h o s p h o r a n e s have b e e n compared. The l a t t e r a r e n e a r l y t w i c e a s r e a c t i v e . 3 2 6

Organophosphorus Chemistry

412 References 1 2

10 11

12

13 14 15 16

17

18 19a 19b 19c 20 21 22 23 24 25

26

27 28 29 30 31 32

a,

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a,

zg

si

a,

as

9: Physical Methods

33 34 35 36 37 38 39

40 41 42 43 44 45 46 47 48 49 50

51 52 53

sa 55 56

57 58 59

60 61 62 63

64

65

66 67 68

413

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-

-

4 14 69 70

71 72

73 74 75 76 77

78 79 80

81 82 83 84

85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102

103

104

Organophosphorus Chernisr ry

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1986,

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322 323 324 325 326

42 1

R . J . P . C o r r i u g P h o s p h o r u s S u l f u r , 1 9 8 b 9 27, 1. K . T a i r a ? K . L a i a n d D.G. G o r e n s t e i n . T e t r a h e d r o n , 1 9 8 6 - 42, 2-79. N.A. S u k h o r u k o v a , V . A . B a r a n s k i 1 and A . V . K a l a t a i n a , Z h . Obshch. K h i m . , 1785, 559 1 8 7 9 . G.R.J. T h a t c h e r ! D i s s . A b s t r . I n t . B V 1 9 8 6 , 471 2 4 4 2 . S . M . L u d e m a n ~ V . L . B o y d , J.B. R e g a n t k . A . G a l l o , G . Zon a n d I<. I s h i i , m s E X D . C l i n . R e s . , 1 9 8 6 , 2,5 2 7 . N.N. L e b e d e v , A.N. K l o c h k s v a n d U . P . : ; a v e l ’ # a n o v 3 Zh. O b s h c h . K h i m . , 1 7 8 6 , 56, 3f5. L . F . K a s u k h i n a n d U.P. K u k h a r ~ 2 h . O b s h c h . Kh1rn.B 19869 56, 9 7 0 . W.G. B e n t r u d e , 1 . K a w a s h i m a , B . A . K e y s , f l . G a r r ~ u s s i a n W~. H e i d e a n d [ I . A . W e d e g a e r t n e r , J . Am. Chem. S o c . . 1 9 8 7 , 109, 1 2 2 7 . F.M. 4 k h m e t k h a n o v a l L . Z . R o l ’ n i k . E . V . P a s t u s h e n k u , M . W . P r o s k u r n i n a . S.’;. Z l o t - s k i 1 a n d D.L. Rakhmankulov, Zh. Obshch. K h i m . ~ 1985, 2039.

s7

Author Index I n t h i s i n d e x t h e number g i v e n i n p a r e n t h e s i s is t h e C h a p t e r number o f t h e c i t a t i o n and t h i s i s f o l l o w e d b y t h e r e f e r e n c e number or numbers o f t h e relevant c i t a t i o n s w i t h i n t h a t chapter

Abad, C. ( 9 ) 293 A b e l - H a l i m , F.M. ( 9 ) 306 Abdel-Magid, A . ( 5 ) 182 Abdou, W.M. ( 2 ) 22 ( 9 ) 66 Abdulganeeva, S . A . ( 5 ) 61 Abed, O.H. ( 9 ) 307 A b e i j o n , C . ( 6 ) 248 A b i c h t , H.P. ( 1 ) 3, 4, 61 Aboujaoude, E.E. ( 5 ) 8 0 ,

8 1 , 153: ( 7 ) 79; ( 9 ) 117 Abuaf, P . ( 9 ) 12 A b u r a t a n i R . ( 1 ) 284 Acheson, D.M. ( 5 ) 140 Acheson, R.M. ( 4 ) 14

Achiwa, K . ( 1 ) 30 Ackermann, E . ( 8 ) 21:

( 9 ) 191

Ackermann, K.E.

262

(9)

Adam, S. 405 Adams, R.J., Jr. ( 8 ) 81, 8 2 , 84 Adamek, C . ( 1 ) 40 Adamova, G.M. ( 9 ) 124 Ades, C . ( 9 ) 143 A d l i n g t o n , R.M. ( 7 ) 54 Aebi, M. ( 6 ) 343 A f a n a s ' e v a , A.N. ( 8 )

136

Afanasov, A.F. ( 2 ) 25 Agafonov, S . V . ( 5 ) 56 Agarwal, K. ( 6 ) 32 Agashkin, O . V . ( 9 ) 116 Agrawal, S. ( 6 ) 156 Ahderinne, R . ( 9 ) 289 Ahlehelm, A . ( 7 ) 38 A h l r i c h s , R. ( 3 ) 18:

( 4 ) 85

A h l u w a l i a , G.S.

101

(6)

Ahmed, R . ( 7 ) 136 Ahrned, Z . A . (Y) 245 Aladzheva, I.M. ( 1 )

227

A l a p i s h v i l i , M.G.

(8)

102

A l b e c k , A. ( 7 ) 91 A l b e r t i , A. ( 9 ) 129 Albrecht, S. ( 5 ) 63; ( 8 ) 22 A l c o c k , N.W. ( 1 ) 1 2 9 , 737; ( 3 ) 38 A l e i n i k o v , S.F. ( 5 )

9 7 , 98: ( 9 ) 144

Aleksandrov,

84

A.M.

(1)

Aleshnikova, T.V.

(5) 49: ( 9 ) 252 Alewood, P . F . ( 4 ) 59 V.A. ( 1 ) 178; ( 4 ) 8 , 19;

Al'fonsov,

( 5 ) 159

Al-Hakim,

A.H.

265

(6)

A l i , R . ( 9 ) 133 A l i g , 8. 19) 248 Alikhanova, N.O. ( 8 )

165

(8) 71, 72: ( 9 ) 4 6 , 225 A l l c o c k , H.R. ( 8 ) 6 5 , 8 1 , 8 5 , 118, 120, 1 2 1 , 122, 1 2 4 , 160, 161, 168, 173, 1 7 8 , 1 8 8 , 200; ( 9 ) 215, 216, 217 A l l e n , C.A. ( 8 ) 206 A l l e n , C.W. ( 8 ) 6 4 , 6 7 , 90, 100, 115, 116, 117; ( 9 ) 8 2 , 112 A l k n b a i s i , A.H.

422

( 1 ) 2 2: ( 3 ) 21: ( 9 ) 5 3 A l l e n , T.L. ( 1 ) 2 4 A l l e n d e , J . E . ( 6 ) 103 Al-Madfa, H.A. ( 8 71 9 111: ( 9 ) 225 Almond, H . R . ( 9 ) 83 Almond, H.R., Jr. ( 2 ) 16: ( 7 ) 12 A l o n i , Y . ( 6 ) 218 Alonso, R . ( 7 ) 137 A l l e n , D.W.

Alonso, A . A . ( 1 ) 1 3 A l p a r o v a , M.V. ( 9 ) 108 Al-Rawi, J.M.A. ( 9 ) 111 Al-Razzak, L.A. ( 6 ) 9 Al-Resayes, S . I . ( I )

294

A l s t e r , D. Altenbrimn, Altman, S . A l u n n i , S.

2

(6) 8. (6) (1)

221, 212 ( 1 ) 144 243 219: ( 7 )

Ajrnera, S. ( 6 ) 310 Akhmetkhanova, F.M.

326

(9)

Akhmetova, G.M. ( 1 ) 70 A k i b a , K. ( 3 ) 25 A k i b a , K i n - y a ( 2 ) 32 Akkerrnann, 0 . 5 . ( 7 ) 66 Aksenova, T.B. ( 9 ) 299 Aksnes, G . ( 9 ) 247 Akutagawa, K. ( 4 ) 105 Ambrose, B . J . B . ( 6 ) 294 Arnes, A., I 1 1 ( 6 ) 55 Arnouroux, R. ( 7 ) 75 Amrani, V . ( 1 ) 21 Arnrute, S.B. ( 6 ) 109 Aoyarna, T . ( 5 ) 181 Aoyama, Y. ( 6 ) 132 An, S.H. ( 6 ) 113 Anan'eva. L . G . ( 8 ) 176 Anastropoulos, A. ( 1 ) 2 2 8 : ( 9 ) 242

423

Author Index

A n c h i s i , C. ( 8 ) 110 Anderson, T.P. ( 9 )

287

Ando, T . ( 5 ) 89 Andrade, J. ( 1 ) 28 A n d r i a n a r i s o n M. ( 1 )

298, 301, 302 ( 9 ) 19c A n g e l e t t i , E. ( 7 ) 78 Angelov, Kh. ( 9 ) 316 A n s e l l , P.J. ( 4 ) 14 ( 5 ) 140 Ansorge, W. ( 6 ) 298 A n t i p i n , I.S. ( 9 ) 2 6 6 A n t i p i n , M.Yu. ( 1 ) 195; ( 4 ) 4 0 , 9 0 , 93: ( 5 ) 150: ( 8 ) 31: ( 9 ) 1 2 7 , 166 A n z a i , S. ( 8 ) 143 Appel, R . ( 1 ) 1 0 9 , 1 5 1 , 259, 261, 266, 267, 268, 269, 283, 285, 339, 343: ( 8 ) 39; ( 9 ) 19b, 6 9 , 70, 157, 159, 160, 1 6 2 , 163, 1 6 8 , 171, 180 Appelhans, A.D. ( 8 ) 206 A p p e l t , A. ( 1 ) 51, 52, 53, 54, 55, 56 A p p l e b u r y , M.L. ( 6 ) 2 A r a b s h a h i , A . ( 6 ) 75 Arakawa, Y. ( 5 ) 29 Arbuzov, B.A. ( 1 ) 145, 1 4 6 , 147, 361, 362, 363; ( 4 ) 88; ( 5 ) 1 3 0 , 164; ( 9 ) 1 0 , 71 8 4 , 139, 218, 220, 238 Arbuzova, M.V. ( 5 ) 49; (9) 252 Arduengo, A.J., I11 ( 2 ) 31; ( 4 ) 4 Arenas, J . (6) 344 Arenz, T. ( 7 ) 57 Arezzo, F. ( 9 ) 292 A r g y r o p o u l o s , N.G. ( 7 ) 58 A r i a s - P e r e z , M.S. ( 9 ) 109, 141 A r i f , A. ( 2 ) 38 A r i f , A.M.. ( 1 ) 59, 279, 306, 327, 328, 332; (4) 98: ( 9 ) 176, 202 A r m s t r o n g , D.R. ( 1 ) 10 A r n d t , V . ( 1 ) 39 A r s h i n o v a , R.P. ( 9 ) 1 0 , 139, 238 A r t y u s h i n , 0.1. ( 1 ) 194

H. ( 7 ) 61; ( 9 ) 188 Asaka, M. ( 6 ) 171 Asato, A.E. ( 7 ) 90 A s c o l i , M. ( 6 ) 58 Ashby, E . C . ( 1 ) 11 Ashe, A.J. 111 ( 1 ) 150, 336 A s h l e y , G.W. ( 6 ) 99 Ashton, P.R. ( 1 ) 212 A s s e l i n e , U. ( 6 ) 117 Assercq, J.-M. (5) 25

Arzoumanian,

Astrina, V.I.

(8)

101

A t k i n s , J.F. ( 6 ) 271 A t k i n s o n , T . ( 6 ) 380 Atovmyan, L.O. ( 9 )

209

A t t a l i , S. ( 1 ) 254 A t t o u , M. ( 9 ) 280 Atwood, J . L . ( 1 ) 99 A u b e r t , F . ( 7 ) 97 Auch, K . ( 1 ) 307 A u s t i n , P.E. ( 8 )

124, 200, 201, 202 Ayed, N. ( 9 ) 111 Azadani, M.N. ( 1 ) 140 Azuhata, T . ( 5 ) 125 Azzouz, A. ( 9 ) 280

Baba, A. ( 1 ) 216 Baba, Y. ( 3 ) 39, 40 B a b i c , D. ( 8 ) 189 B a b i n , F . ( 6 ) 391 B a b k i n a , G.T. ( 6 )

2 56

B a c c o l i n i , C.

(I )

Baccolini, G.

(4)

184 46

( 1 ) 174 275, 319, 321; ( 4 ) 20; (8) 4 , 5; ( 9 ) 36, 37 Bacher, A. ( 9 ) 292 Bachmeier. A. ( 6 ) 370 Badanyan, Sh. 0 ( 5 ) 169 B a h l , C. ( 6 ) 87 B a d i a , M.C. ( 5 ) 106 Bahrmann, H . ( 1 149 B a i l e y , J.M. ( 6 249 B a k a r , M.A. ( 1 ) 291 Baker, R. ( 7 ) 1 7

B a c e i r e d o , A.

B a k h t i y a r o v a , I.V.

( 9 ) 303

Bakkas, S. ( 4 ) 22 Bakker, C.G. ( 6 )

106

Bakos, J. ( 9 ) 77 Bakuradze, R.Sh. ( 8 )

166

Balanescu, M.

128

B a l c h , A.L.

58

(8)

( 1 ) 57, (3)

Balczewski, P.

19

(7)

B a l d w i n , J.E.

54

B a l d y , A . ( 9 ) 188 B a l g o b i n , N. ( 5 ) 30 B a l l , R.G. ( 2 ) 41 B a l s z u w e i t , A. ( 9 )

50

B a l t h a z o r , T.M.

(4)

26

B a l t u s i s , L . ( 3 ) 37 Balzarini, J. (6)

9 , 1 3 , 48

Banmohamed, N. ( 8 )

156

Bannard, R.A.B.

39

Bannwarth, W.

50; ( 6 ) 295

(9) (4)

(6) 393, 394, 395, 396 Bao, J. ( 6 ) 273 Barad, M. ( 6 ) 55 B a r a n s k i i , V.A. ( 5 ) 171; ( 9 ) 320 Bard, A.J. ( 1 ) 250 Bare, L.A. ( 6 ) 272 B a r e n d t , J.M. ( 4 ) 43; ( 9 ) 636, 88 B a r l u e n g a , J. ( 1 ) 372; ( 7 ) 52; ( 8 ) 53, 54 B a r r a n s , J . ( 1 ) 365 ( 8 ) 19

Banville,’ D.L.

B a r r i o l a , A.

(8)

201

B a r r o s , A.A. ( 9 ) 243 B a r r y , D.W. ( 6 ) 92 Barsegyan, S.K. ( 1 )

105

E a r t h , V. ( 9 ) 69 Bartholemew, B. ( 6 )

260

B a r t l e t t , R.A.

1 6 4 , 304

(1)

Organophosphorus Chemistry

424

( 1 ) 120: ( 2 ) 3: ( 4 ) 106 B a r t o n , J.K. ( 6 ) 322, 364, 365 B a r t s c h , R . ( 2 ) 23 Bass, B.L. ( 6 ) 3 3 1 B a s s i , B. ( 6 ) 18 Bastow, K . F . ( 6 ) 93 Basu, A . K . ( 6 ) 276 B a t h l a , H.K. ( 3 ) 22 B a t r a , S . P . ( 6 ) 250 B a t y e r a , E.S. ( 1 ) 178: ( 4 ) 8 , 1 9 , 23; ( 5 ) 159 B a u d l e r , M. ( 1 ) 36, 3 7 , 38, 39, 4 0 , 41, 48: ( 3 ) 16: ( 9 ) 24, 25, 26, 152 Bauer, J . ( 5 ) 30 Bauer, W. ( 1 ) 47 Bax, A . ( 6 ) 388, 389 B a x t e r , J . E . ( 3 ) 26 B a x t e r , S.C. ( 4 ) 9 7 , 98 B a x t e r , 5 . G . ( 1 ) 332, 333: ( 9 ) 202 Bay, W.E. ( 1 ) 64 Baynard, B. ( 6 ) 205, 216 B a y e r , € . A . ( 6 ) 264 Baze, M.E. ( 7 ) 104 Bazhanova, Z . G . ( 9 ) 151 B e a b e a l a s h v i l l i , R.S. ( 6 ) 9 5 , 96 Beak, P . ( 1 ) 139: ( 3 ) 4 B e a u c o u r t , J . P . ( 7 ) 97 Beautement, K. ( 7 ) 139 Beccard, B. ( 9 ) 126 Becher, R . ( 1 ) 38 Becherer, R . ( 3 ) 18; ( 4 ) 85 B e c k e r , G. ( 1 ) 290: ( 9 ) 1 6 9 , 214, 234, 235 ( 2 ) 31 B e c k e r , J.V (4) 4 B e c k e r , J.Y 9 ) 235 Becker, V . Beckh, H.J. ( 1 ) 367: ( 9 ) 29 B e g l e y , M.J. ( 5 ) 133 B e k k e r , A . R . ( 9 ) 299 Belakhov, V . V . ( 5 ) 104, 116; ( 9 ) 117 B e l e n k o v , V.N. ( 1 ) 221 B e l e t s k i i , I . P . ( 5 ) 35 B e l f o r t , N.M.-T. (6) B a r t o n , D.H.R.

108 Beu, A .

( 1 ) 17

Beu, A . T . ( 8 ) 170 B e l l , G . A . ( 1 ) 186 Bellan, J. ( 1 ) 249;(4) 102; ( 8 ) 13: ( 9 ) 25 B e l l a n a t o , J . ( 9 ) 109,

141

B e l ' s k i i , V.E. B e l y a e v , Yu.P. Belyaeva, T . N .

( 9 ) 314 ( 8 ) 218 ( 1 ) 167,

Belyakov, V . N .

( 8 ) 93,

170

9 4 , 95 Belykh, O.A. 163 Bendayan, A . Benefiel, A. Benn, R . ( 1 )

( 5 ) 162,

( 1 ) 179 (1) 5 245 B e n t r u d e , W.G. ( 4 ) 105; ( 6 ) 48; ( 9 ) 4 8 , 6 4 , 325 Benziman, M. ( 6 ) 218 Berchadsky, Y . ( 9 ) 126 B e r d e l , W.E. ( 6 ) 113 B e r d n i k o v , E.A. ( 5 ) 180 B e r e s , J. ( 6 ) 4 8 , 52 Beresenev, E.N. ( 8 ) 150 B e r g a m i n i , P. ( 1 ) 137: ( 3 ) 38 B e r g e r , R . A . ( 9 ) 262 B e r g e r , S.L. ( 6 ) 305 B e r g e r e t , W. ( 9 ) 58 B e r g t o l d , D.S. ( 6 ) 289 B e r h a r d , S.L. ( 6 ) 259 Berman, C.B. ( 5 ) 10 B e r n a r d i n e l l i , G. ( 9 ) 125 B e r n e t , B. ( 9 ) 208 B e r n h a r d t , F.C. ( 1 ) 81, 8 2 ; ( 3 ) 24; ( 9 ) 9 9 , 106 B e r n i e r , J.L. ( 1 ) 210 B e r r a k , A . ( 9 ) 280 B e r r i e r , A . ( 1 ) 88 Berry-Lowe, S. ( 6 ) 4 B e r t i n o , J.R. ( 6 ) 411 B e r t r a n d , G . ( 1 ) 275, 319, 321; ( 4 ) 80: ( 8 ) 4 , 5 , 1 4 , 32; ( 9 ) 3 6 , 37 B e r t r a n d , J.R. ( 6 ) 173 B e r t r a n d , M.J. ( 6 ) 361 B e r z i n , V.A. ( 6 ) 256 B e s t e r , A.J. ( 9 ) 292 Bestmann, J . J . ( 7 ) 39, 40, 5 0 , 57 Betheu, R . C . ( 6 ) 76 B e t t e r m a n n , G . ( 1 ) 187: ( 4 ) 27; ( 9 ) 181, 212 Beuster, A. ( 8 ) 15

Bel'tsova, T.G. ( 8 ) 113, 1 5 3 Bhattacharyya, A.

( 6 ) 91

Bhowmick, A . K .

(8)

208

(1) 282, 299: ( 7 ) 66 Bickle. T.A. (6) 192 B i d d l e s t o n , M. ( 9 ) 92 B i e r n a t , J . ( 6 ) 129

B i c k e l h a u p t , F.

B i e s h e u v e l , P.L.

( 7 ) 89

B i l k e , 5. ( 9 ) 11 B i n d e r , D. ( 1 ) 253,

252

B i n d e r , J . ( 5 ) 149:

( 7 ) 82

B i n g e r , R . ( 1 ) 295 B i n n e w i e s , M. (3) 18; ( 4 ) 85 B i s b a l , C. ( 6 ) 216 Bischofberger, N.

( 6 ) 307

Bischoff, R.

( 6 ) 156

( 4 ) 55:

(7)

B l a c k b u r n , B.K.

87

B l a c k b u r n , G.M. ( 5 ) 87, 88, 156: ( 6 )

62; ( 7 ) 83, 8 4 , 85; ( 9 ) 272 (6) 329 B l a k e , K . R . ( 6 ) 204, 203 B l a n c , A . ( 7 ) 75 B l a t t e r , K . ( 1 ) 366; ( 9 ) 31 Blinova, G.G. (9) 40, 279 B l o c h . G . ( 6 ) 391 B l o i s , F . ( 6 19 B l a c k e r , A.J.

Blonsky, P.M

(8)

200, 201, 202, 205 Blum, H. ( 5 ) 129 6 ) 10, Bobst, A.M. 89 Boche, G. ( 5 185 Bock, H . ( 9 ) 240 B o d a l s k i , R. ( 7 ) 70 Boeckh, D. ( 3 ) 28 Boeckman, R . K . ,

Jr.

( 7 ) 1 2 5 , 127 Boedecker, J . ( 8 ) 10 ( 9 ) 38

425

Author Index

Boehm, M.F. Boere, R.T.

( 7 ) 121 ( 8 ) 146,

148, 223 ( 1 ) 162, 243, 245, 247, 281 ( 5 ) 138; ( 9 ) 110, 197, 198 Bogachev, V.S. ( 6 ) 197 Boggs, J . E . ( 1 ) 306: ( 9 ) 177 Bohle, I . ( 5 ) 91 B o h l e n , R . ( 9 ) 52, 6 4 , 230 Boisdon, M . - T . (1) 365: ( 8 ) 19 B o l d e s k u l , A.E. ( 9 ) 270 B o l d e s k u l , E . T . ( 9 ) 127 B o l d e s k u l , I . E . ( 1 ) 271; ( 9 ) 1 3 4 , 166 B o l o g n e s i , A. ( 8 ) 187, 197 B o l o g n e s i , O.P. ( 6 ) 92 Bone, R . ( 6 ) 111 Bonnet, J.-J. ( 1 ) 135, 275 Bookham, J . L . ( I ) 67; ( 9 ) 90 Books, J.T. ( 8 ) 209 B o o s a l i s , M.S. ( 6 ) 190 Borah, 8. ( 6 ) 225 B o r d i e u , C . ( 1 ) 370 B o r i s e n k o , A.A. ( 4 ) 4 0 ; ( 9 ) 114 B o r i s o v , E.V. ( 9 ) 299 B o r n a n c i n i , E.R.N. ( 1 ) 13 Borowy-6orowski, H. ( 6 ) 195 Borrmann, H. ( 3 ) 18: ( 4 ) 85 Bortun, A . I . ( 8 ) 93, 94, 95 Bose, R.N. ( 6 ) 367 Boske, J . ( 1 ) 320: ( 4 ) 80; ( 8 ) 1 4 , 32 Bosma, E . ( 9 ) 228 B o so l d , F . ( 5 ) 185 Bosyakov, Yu. G . ( 9 ) 116 B o t e l h o , L.H.P. (6) 56, 57 B o t t , S.G. ( 1 ) 99 B o t t a , M. ( 7 ) 94 Bouaoud, 5.-E. (1) 8 B o u r d i e u , C . ( 4 ) 44 Bourque, K. ( 9 ) 102 B o u r t a y r e , P. ( 6 ) 405 Bower, M. ( 6 ) 390 Bowmer, T.N. ( 8 ) 179 Boyd, B.A. (8) 44 Boyd, V . A . ( 9 ) 322

Boese, R .

B a y e r , H.W. ( 6 ) 407 Bozyakov, Y u . G . ( 3 ) 20 Braco, L . ( 9 ) 293 B rady , A . ( 7 ) 61 Braga, D. ( 1 ) 204 B r a u e r , O . J . ( 1 ) 185;

B u l a i , A.Kh. ( 9 ) 259 Buncel, E. ( 9 ) 39 Bundel, Yu. G . ( 7 )

119

Bungar dt, D. ( 1 ) 243

280, 281

( 4 ) 4 1 ; ( 9 ) 173 B raun, S . ( 6 ) 218 B r a u n s t e i n , P. ( 1 ) 8

Buono, G . ( 4 ) 82 B u r d s a l l , D.C. ( 5 )

B r e d i k h i n a , Z.A.

B u r f o r d , N. Burgada, R .

184

(5)

B r e l ' , V . K . ( 5 ) 150 Brennan, C . A . ( 6 ) 184 Brennan, D . J . ( 8 ) 118; ( 9 ) 216 B r i d o n , 0 . ( 4 ) 106 B r i x n e r , 0.1. ( 6 ) 52 B r o c k , C.P. ( 6 ) 358 B r o d e r , S . ( 6 ) 92 B rody , R.S. ( 6 ) 75 B r o n s k i l l , P.M. ( 6 )

239

B rook s , D.W. ( 1 ) 113 B rook s , P. ( 1 ) 14 B ros s as , J. ( 8 ) 127 B r o s t , R . D . ( 1 ) 138 Brousseau, R . ( 6 ) 237 B r o v a r e t s , V . A . ( 1 ) 222 Brown, D . ( 5 ) 87: ( 7 )

83

Brown, D.E.

( 9 ) 82

( 8 ) 100;

( 4 ) 58; ( 6 ) 159 Brown, J.M. ( 1 ) 22, 2 3 , 24, 7 9 , 129 Brown, K.L. ( 6 ) 382 Brown, S.J. ( 1 ) 215 B roz da, 0. ( 6 ) 211 B ruc k , T . ( 1 ) 353 B ruc e, A.G. ( 6 ) 271 B ruc e, G.C. ( 1 ) 138 B ruc he, L. ( 8 ) 61 B r u c k , B. ( 1 ) 151 B r u e c k , B. ( 9 ) 70 B r u e n i n g , G. ( 6 ) 346 B runner, H. ( 1 ) 2 Bube, T . ( 7 ) 113 Bubnov, N.N. ( 9 ) 127 Buchanan, G.W. (9) 102 Buchheit, D.J. ( 6 ) 113 Buck, H.M. ( 2 ) 2 1 , 30: ( 6 ) 24; ( 9 ) 41, 128 B uc k land, S . J . ( 5 ) 173 B udat, 0 . ( 8 ) 51 Bukachuk, O.M. ( 1 ) 211, 221 B u k r i n s k a y a , A.G. ( 6 ) 253

Brown, E.L.

127

( 2 ) 40 ( 2 ) 24: ( 5 ) 160; ( 9 ) 105 B u r g e r , R.M. ( 6 ) 312 B u r g e t , G . ( 8 ) 30 Burghardt, R . ( 1 ) 75, 77; ( 3 ) 5 Burik, A. ( 4 ) 68: ( 6 ) 126 B u r i n , S . V . ( 8 ) 104, 105 Bur ke, S.D. ( 1 ) 131 Burnaeva, L.A. ( 1 ) 199; ( 2 ) 2 5 , 35: (4) 6 Bur ns, H.D. ( 1 ) 205 Burova, O.N. ( 9 ) 40 Bur r ow s, C.J. ( 6 ) 6 3 B u r s k i c , J . ( 9 ) 73 B u r t o n , D.J. ( 7 ) 49 Bur yakova, A.A. ( 6 ) 138 B u s i , C. ( 6 ) 18 B u s y g i n , I.G. ( 5 ) 137: ( 9 ) 213 B u t i n , B.M. ( 1 ) 70, 220; ( 9 ) 60 B u t i n , M.B. ( 1 ) 148 B u t l e r , I.R. ( 1 ) 62 B u t o u r , J.-L. (6) 375 Buwalda, P.L. ( 8 ) 86, 119 Buxton, S.R. ( 7 ) 8 6 Buzayan, J.M. ( 6 ) 346 Bychkov, V . T . ( 9 ) 229 B y r d , R.A. ( 6 ) 202 C a b r a l , J.O. ( 9 ) 243 Cadogan, J . I . G . ( 4 )

103

Caesar, J.C.

( 2 ) 26;

( 3 ) 12

C a i r n s , S.M. ( 9 ) 3 C aloger opoulou, T ( 5 )

92; (7) 74

.

Camellini, M.T.

136

Cameron, T.S.

(1)

( 8 ) 76

Organophosphorus Chemistry

426

Caminade, A.-M. (1) 174, 254, 263, 286; (4) 20; (9) 143 Campino, T. (1) 107; (9) 301 Campos, A. (9) 293 Canales, 3. (6) 107 Cao, W . (7) 51 Capasso, J.M. ( 6 ) 248 Capdevila, J. (7) 99, 101, 102 Capozzi, G. (1) 335 Capuano, L. (7) 38, 45; (9) 190 Caputo, R. (1) 116 Carbon, P. (6) 269 Cardemil, E . (6) 78 Carlson, R.K. (7) 122 Carmona, E. (1) 108 Carpenter, L.E., 1 1 1 ( 2 ) 30: (9) 41, 54 Carr, L.J. ( 8 ) 107 Carretero, J.C. (7) 76 Carrie, R . (1) 255, 264: (7) 26: ( 8 ) 21; (9) 172, 191 Carty, A.J. (1) 136 Caruthers, M.H. (4) 66; 164, 180 Carvallo, P. (6) 103 Casasempere, M. A. (1 ) 345 Casser, C. (1) 261, 339; (9) 159, 171 Castells, R.C. (9) 278 Castedo, L . (7) 137 Caster, K.C. ( 8 ) 18; (9) 113 Castera, P. ( 8 ) 98 Castro, C.A. (6) 362 Castro, M.M. (6) 294 Catellani, M. ( 8 ) 187 Cates, L.A. ( 8 ) 154 Cattani-Lorente, M. (9) 125 Caude, M. (3) 7; (9) 282, 286 Cava, M.P. (7) 135 Cavell, R.G. ( 2 ) 40, 41; (9) 93 Cavell, R.G. (9) 93 Cech, D. (6) 181 Cech, T.R. (6) 331, 332, 335, 338, 339, 340 Ceolin, F. (6). 391 Cerny, R.L. (6) 401 Certa, U. (6) 295 Cesartotti, E. (4) 83 Cha, J.K. (7) 95 Chabane, A. (1) 365: ( 8 ) 19

Chadha, R.K. ( 5 ) 16, 17 Chai, W. (9) 257 Chaikovskaya, A . Ya. (9) 137 Chakhmakhcheva, 0.G . (6) 137, 138 Chakraborty, T.K. (7) 114 Chakrovary, P.K. (5) 114 Chakravarty, R . (6) 112 Chambers, R.W. (6) 195 Chandrasekaran, S. (9) 54 Chandrasekhar, V. ( 2 ) 5, 7 Chang, A. (2) 18; (5) 37 Chang, L.-H. (6) 315 Chang, S.B. (5) 23 Chanon, M . (4) 22 Chapman, T.L. (6) 72 Charbonnel, Y. ( 4 ) '105 Charczuk, R. ( 6 ) 192 Charette, A.B. (7) 125 Charrier, C. (1) 345 Charubala, R. (6) 211 Chasar, D.W. (4) 35: ( 9 ) 34 Chassignol, M. (6) 328 Chastrette, F. (7) 75 Chastrette, M. (7) 75 Chatani, Y. ( 8 ) 190 Chattopadhyaya, J. ( 5 ) 30; ( 6 ) 35, 36, 37, 402 Chekhlov, A.N. (5) 150 Chen, C.S. (1) 7 Chen, K. (9) 62 Chen, 4. (5) 19 Cheng, C.Y. (5) 20: ( 9 ) 223 Cheng, Y.-C. ( 6 93 111 Cherches, G. Kh ( 8 ) 221 Cherepinskii, V D. (9) 218 Cherezev, S . V . 5) 95 Cherkasov, R.A. ( 5 ) 52, 94. 95. 136. 176, 180; ( 9 ) 274, 303 Chernega, A.N. (1) 195; ( 4 ) 40, 90, 93; ( 5 ) 150: (8) 31; (9) 127, 166 Chernov, A.N. (1) 169 Chernov, P.P. (1) 362 Chernova, A.V. (9) 132 Chernova, T.M. (9) 270 Chervin, 1.1. (5) 145 Chezlov, I . V . (9) 277 Chiba, M. (1) 30 Chichester-Hicks, S.V. ( 8 ) 179 1

Chidgeavadze, Z.G. ( 6 ) 95, 96 Chiesa, A. (4) 83 Chikugo, T . (1) 225; (3) 1; ( 5 ) 155: (7) 73 Chino, Y. (6) 172 Chiong, K.N. ( 8 ) 219 Chiriac, C. (4) 45 Chiti, L. (1) 335 Chistokletov, V.N. ( 2 ) 25 Chiu, K.W. ( 9 ) 192 Chivers, T . ( 8 ) 144, 145 Chizhov, V.M. (5) 56 Chocron, S. (1) 132, 134 Chojnowski, J. (5) 33 Choo, K.Y. (9) 302 Chottard, G. (6) 372 Chottard, J.-C. ( 6 ) 372 Chou, T.-S. (1) 15 Chou, W.N. ( 8 ) 9, 9 Chowdary, 0. (6) 277, 278 Christodoulou, A. (1) 228; (9) 242 Christodoulou, C. (6) 156 Chu, B.C.F. (6) 226 Chu, F . K . (6) 345 Chu, G. ( 6 ) 410 Chuan, H. (6) 251 Chukbar, T.G. (4) 36 Chupp, J . P . ( 8 ) 17 Church, J.S. (9) 7 38 Churusova, S.G. (5) 13; (9) 118 Ciampolini, M. (1) 128 Cibiskova, N . T . (9) 222 Cielens, J.E. (6) 256 Cilliers, J.J.L.(9) 291 Clancy S. ( 8 ) 205 Clark, J.H. ( 1 ) 215, 299 Clavel, J.-L. (4) 25 Cleave, C. (9) 30 Clegg, W . (I) I0

427

Author Index

C l e l a n d , W.W. ( 6 ) 82 Clement, I . ( 6 ) 66 C l e ve , C . ( 1 ) 188; ( 4 )

86

C l o u e t , G. ( 8 ) 127 Clough, J.M. ( 7 ) 139 Cobb, J.E. ( 1 ) 131 Coburn, M.D. ( 8 ) 29 Cohen, E.A. ( 9 ) 142 Cohen, J.S. ( 6 ) 225 Cohen, S. ( 4 ) 24 Cohrs, M.P. ( 6 ) 282 C o l e , W.M. ( 8 ) 172, 185 Coleman, J . P . ( 6 ) 114 C o l e t t i - P r e v i e r o , M.A.

( 9 ) 284

C o l l i g n o n , L . ( 9 ) 117 C o l l i g n o n , N. ( 5 ) 80,

8 1 , 153; ( 7 ) 79 C o l l i n s , L.J. ( 6 ) 363 C o l l i n s , M . ( 4 ) 58; ( 6 ) 159 Colman, R.F. ( 6 ) 249, 2 50 Colombo, L . ( 4 ) 83 Colquhoun, I . J . ( 1 ) 6 7 , 124; ( 9 ) 59, 90 Combs, P. ( 5 ) 114 Cornrnenges, G. ( 9 ) 263 C o n o l l y , B.A. ( 4 ) 54, 56 ( 6 ) 1 5 3 , 155 C o n n e l l y , P.A. ( 6 ) 56 C o n t r a c t o r , S.R. ( 8 ) 73; ( 9 ) 226 Cook, R.D. ( 5 ) 172; ( 9 ) 312, 313 Cook, S . J . ( I ) 23, 24 Cooke, A.M. ( 4 ) 28 Cooke, M.P., J r . ( 7 ) 59 Cooney, D.A. ( 6 ) 101 Coons, D.E. ( 1 ) 262 Cooper, G.R. ( 1 ) 130 Copper, J.R. ( 9 ) 285 Corda, L . ( 8 ) 110 Cordes, A.W. (8) 148 Cordes, R.E. ( 8 ) 76 C o r d i e r o , M.L. ( 5 ) 144 Corey, E.J. ( 7 ) 103 C o r n e l i u s , R.D. ( 6 ) 167 Cornforth, S i r J. (1) 340, 341 C o r n i l s , B. ( 1 ) 149 Corrado, E. ( 1 ) 116 C o r r i u , R.J.P. ( 2 ) 2: ( 5 ) 39, 41: ( 9 ) 318 C o r s e t , J . ( 7 ) 69 Cosquer, P . ( 1 ) 264 C o st e ro , A.A. ( 7 ) 33 C o st e ro , A.M. ( 1 ) 112

Costisella, 6 . ( 1 ) 181;(43 84: ( 5 ) 90, 146 C o t t o n , F.A. ( 1 ) 111 C o u l l , J.M. ( 4 ) 55; ( 6 )

156

Couret, C.

302

( 1 ) 298, 301,

C o u r e t , H . ( 9 ) 19c C o u t r o t , P . ( 5 ) 78, 85 Coward, J . K . ( 6 ) 115 Cowie, M. ( 2 ) 41 Cowley, A.H. ( 1 ) 59, 223,

248, 250, 279, 306, 327, 328, 332: (2) 38: ( 4 ) 9 8 , 101, 103; ( 9 ) 177, 202 Cox, D.G. ( 7 ) 49 C o y l e - M o r r i s , J.F. ( 6 ) 410 C r a i g , D.C. ( 1 ) 14 C r a i n , P.F. ( 6 ) 4 5 , 46 C r e a r y , X . ( 5 ) 179; ( 9 ) 44 Cremlyn, R.J. ( 8 ) 23 C r e s s w e l l , C.J. ( 1 ) 161; ( 5 ) 138 Crisp, G . T . ( 1 ) 90 Crocco, G.L. ( 7 ) 67 Crook, P . E . (2) 14 Cropper, P . E . ( 1 ) 212 C r o t h e r s , D.M. ( 6 ) 330 Cudat, D. ( 4 ) 95 C u l l e n , W.R. ( 1 ) 62 C u l l e y , S.A. ( 2 ) 31. (4) 4 C u l l i s , P.M. ( 5 ) 1 1 , 36: ( 9 ) 45 Curnrnins, J.H. ( 6 ) 22, 34 Curnrnings, D.G. ( 8 ) 206 Cz i s c h, P. ( 7 ) 66 Dabis c h, T .

123

( 1 ) 330: ( 9 )

Dabrowiak, J.C.

327, 378

Dabkowski, W .

(5) 8

Dahl, B.H.

127

( 6 ) 316,

( 4 ) 21;

( 4 ) 49: ( 6 )

Dahl, 0. ( 4 ) 49, 6 4 ,

6 5 , 6 8 ; ( 6 ) 123, 124, 125, 126, 127 Dahm, 0 . ( 7 ) 45; ( 9 ) 190 Dahmus, M.E. ( 6 ) 260 Daimon, M. ( 8 ) 214 Dai nes , R.A. ( 7 ) 114 D a k t e r n i e k s , 0. ( 9 ) 63a

D a l a l , M. ( 6 ) 101 D a l l e y , N.K. ( 6 ) 8 D alpozzo, R. ( 1 )

184: ( 4 ) 46 ( 1 ) 183 ( 4 ) 79; ( 6 ) 20, 152, 167

Dernha, M.J.

(1)

Danchenko, E.A.

72; ( 9 ) 32, 91

(5)

Oanchenko, M.N.

139

Dangyan, Yu.M.

169

(5)

( 1 ) 96: ( 7 ) 1 5 , 55

D a n i e l , H.

Danion, D. ( 8 ) 21;

( 9 ) 191

D annals, R.F.

(1)

205

Daouk, W.A. ( 9 ) 313 Daran, J.-C. ( 1 )

286

D a r d o i s e , F. ( 9 ) 58 Darensbourg, D.J.

( 8 ) 35

D a r r , E. ( 1 ) 39 Dartiguenave, Y.

(1)

275

( 1 ) 237, 258, 312; ( 4 ) 9 5 , 100; ( 9 ) 1 9 a , 161, 193 D avidson, F. ( 2 ) 31: (4) 4 D avidson, R.S. ( 3 ) 26: ( 5 ) 173 D avies, R.J.H. ( 6 ) 281 D a v i s , D.R. ( 6 ) 4 5 , 59 D a v i s , R.W. ( 6 ) 410 D avisoon, V.J. ( 5 ) 6 ; ( 6 ) 59 Dartrnan, M.

Davydochkina, O . V .

( 5 ) 102

Dawkins, H. J.S.

408

Day, R.O.

7

(6)

(2) 5, 6 ,

D a y r i t , F.M. ( 1 ) 22 Dean, N.M. ( 9 ) 290 de Boer , H.J.R. ( 7 )

66

de Brosse, C.W.

67

(6)

Decedue, C.J. ( 6 ) 9 de C l e r c q , E. ( 6 ) 9 ,

1 3 , 48

Organophosphorus Chemistry

428

J.-P. ( 1 ) 144, 302; ( 9 ) 78, 170 Degener, H.J. ( 9 ) 174, 175 D e g e n h a r d t , C.R. ( 5 ) 127 detlaseth , P.L. (6) 18ODe J a e g e r , R . (8) 36, 169 D e l e p i e r r e , M. ( 6 ) 388 D e l l a r i a , J . F . ( 7 ) 32 Delrnas, M. ( 7 ) 17 Demande, F r . (8) 127 Demidov, V . V . ( 6 ) 43 Dernko, D.M. ( 7 ) 125 Dernuth, A.A. M. ( 1 ) 47 den H a r t o g , J . A . J . ( 6 ) 100 D e n i s , J.-M. ( 1 ) 255 Denmark, S.E. ( 7 ) 19 Denny, M. ( 7 ) 90 Depezay, J.C. ( 7 ) 98 D e p p i s c h , B. ( 1 ) 253 De Riese-Meyer, L . ( 9 ) 26 de R u i t e r , B. ( 2 ) 30; ( 9 ) 4 1 , 228 Dervan, P.B. ( 6 ) 300, 323, 324 de S a r l o , F . ( 9 ) 172 D e s b o i s , M. ( 1 ) 97 Deschenaux, R . ( 1 ) 20 D e s o r c i e , J.L. (8) 65 D e s t r i , 5 . ( 8 ) 187 D e t l o f f , B.S. ( 7 ) 112 D e t t l o f f , M.L. ( 8 ) 138 D e u t s c h , J. ( 4 ) 24 D e u t s c h , F.W. (8) 112 D e u t s c h , W.F. (8) 71, 72, 8 0 ; ( 9 ) 4 6 , 225, 241 Devanesan, P. ( 6 ) 89 Devanesan, P.D. ( 6 ) 10 Devchand, D.K. ( 3 ) 32 D e v i n e , K . G . ( 6 ) 135 D e V i s s e r , A.C. ( 8 ) 183, 184 de Vroorn, E. ( 4 ) 6 1 , 77 : ( 6 ) 163, 218 D e x i a n , W. ( 7 ) 9 Declercq,

D h a t h a t h r e y a n , K.S.

L1

34; ( 9 ) 225, 228, 232 Dhawan, 8. ( 5 ) 31 D i a n o v a , E.N. ( 1 ) 36 , 362, 363: ( 4 ) 88 D i e m e r t . K . ( 9 ) 246 D i e t l , 5. ( 1 ) 287: ( 9 ) 18 D i Giacorno, R. ( 9 ) 63a D i u o n , K.B. ( 9 ) 133 D i Marco, P . ( 8 ) 181

D i n g , W . ( 7 ) 51 D i r k s e n , M.-L. ( 6 ) 288 D i t r i c h , K. ( 7 ) 1 1 3 D i V a i r a , M. ( 1 ) 335 D i x , D.B. ( 6 ) 270 D i x i t , V . M . ( 6 ) 59 D i x o n , D.A. ( 2 ) 3 1 : ( 7 ) 1;

(9) 8

D i z d a r o g l u , M.

288, 289

( 6 ) 287,

DJUTlC, S.W. ( 7 ) 123 D r n i t r i c h e n k o , M.Yu. ( 5 )

74

D r n i t r i e v , V . I . ( 9 ) 154 D o c k n e r , T . ( 1 ) 86 D o g a d i n a , A.V. ( 1 ) 1 6 6 ,

167, 170; ( 5 ) 75, 141, 162, 163; ( 9 ) 100 D o l e n c e , E.K. ( 7 ) 122 D o l e n k o , G . N . ( 9 ) 154, 155 D o l i n n a y a , N . G . ( 6 ) 198 Dornbrowski, B . A . ( 6 ) 326 Dorninguez, D . ( 7 ) 137 D o n a t h , C h . ( 9 ) 222 Dong, L . ( 6 ) 49 D o n s k i k h , V . I . ( 5 ) 71, 72, 74 Donxia, L. ( 7 ) 9 D o r f r n e i s t e r , G. ( 1 ) 356, 357, 371 D o r o n i n , S.V. ( 6 ) 258 Doroshenko, V . V . ( 2 ) 36 D o u g h e r t y , J . P . ( 4 ) 58: ( 6 ) 159, 160 Drach, B.S. (1) 222 Dragland-Meserve, C.J. ( 6 ) 57 D r a k e J.E. ( 5 ) 1 6 , 17 D r a p a i l q , 4.a. (1)' 300, 311: ( 4 ) 93: ( 8 ) 31: ( 9 ) 21 D r e e f , C.E. ( 4 ) 29, 77 D r e s l e r , S . L . ( 6 ) 98 D r e s s l e r , U. ( 1 ) 374; ( 4 ) 91 D r i t i n a , G.J. ( 7 ) 77 D u b e n d o r f f , J.W. ( 6 ) 180 Dubenko, L.G. ( 8 ) 55, 56 Dubey, I.Y. ( 6 ) 138 D u B o i s , D.A. (8) 44 Duborg, A . ( 1 ) 302 D u b r e u i l , Y.L. ( 6 ) 261 Dudchenko, T.N. ( 2 ) 28 Duddeck, H. ( 9 ) 80, 255 D u e r s t , R.W. ( 3 ) 36 D u e s l e r , E.N. ( 1 ) 152 D u f o u r , J . - P . ( 6 ) 355 Du Mont, W.W. ( 9 ) 87 Dunaway-Mariano, D, ( 6 ) 353

Dunn, E.J. Dupont, Y. D q r i g , J.R. D G s t e r , 0. Dutschrnan,

93

( 9 ) 39 ( 6 ) 355 ( 9 ) 138 ( 1 ) 37 G.E. ( 6 )

D u t u s t a , J.P. ( 9 ) 78 D u r a n , H.L. ( 6 ) 230 D y a t k i n a , N.B. ( 6 )

97

D y r b u s c h , M.

( 9 ) 232

( 2 ) 34:

Dzhandzugazyan, K . N .

( 6 ) 255

Dziegielewski,

( 9 ) 122

J.O.

Eastman, A. ( 6 ) 376 6 ) 269 E b e l , J.P. E c k e r t , W.A (6)

333

( 1 342 ; ( 9 ) 248 E c k s t e i n , F. ( 6 ) 58, Eckl, E.

102 Edrnonds, C.G.

4 5 , 46

Edwardson,

( 6 ) 380

(6)

P.A.D.

A.I.

(9)

Efrernov, M.V.

(9)

Efrernov,

132 31 4

E f r e m o v , Ya.Ya.

(4)

Efrernov,

(5)

18

Yu.Ya.

120, 184

E f i n o v , V.A.

'137, 138

(6)

Egan, W . ( 6 ) 202 E g e r t , E. ( 8 ) 47 E g e s t a d , 6. ( 6 ) 114 E i s e n s t e i n , 0. ( 7 ) 8

(9) 7

E j i r i , E. ( 7 ) 138 E l - B a t o u t i , M. ( 9 )

306

E l - D i n , G.N. ( 7 ) 36 E l e f r i t z , R.A. (8)

185

Elgarnal, A . ( 9 ) 80 E l g a m a l , M.H.A. (9)

255

E l G h a r b i , R. ( 7 ) 17 E l i a s , A . J . ( 8 ) 147 E l i e , C.J.J. ( 4 ) 61 E l i e l , E . E . ( 9 ) 54 E l - K a t e b , A.A. ( 7 )

42

Author Index

429

E l K h a t i b , F . ( 4 ) 20:

( 9 ) 143

E l l e n b e r g e r , T.E. ( 6 ) 321 E l l e r m a n , J. ( 1 ) 47 E l - M a l e k , H.A.A. ( 7 ) 42 e l Manouni, D. ( 5 ) 160 E l s c h e n b r o i c h , C. ( 1 ) 336 Endo, M. (8) 58 Endoh, D. ( 6 ) 284 E n g e l h a r d t , L.M. (I) 9 Enholrn, E.J. ( 7 ) 125 E n i i s , M.D. ( 7 ) 104 Eperson, I . C . ( 6 ) 74 E r i t j a , R . ( 6 ) 187,

190, 196 Erker, G . ( 7 ) 65 E r n s t , L . ( 6 ) 386: 9 ) 21 2 E r r a n i , E. ( 1 ) 184: ( 4 ) 46 E r y a n , M.A. ( 8 ) 104 105 Erzhanov, K.B. ( 1 ) 70, 148, 220: ( 9 ) 6 3 Erzhanova, K.B. ( 5 ) 61 E r a 3 t o v , O.A. ( 1 ) 145, 146, 147: ( 9 ) 71, 84 Essignmann, J.M. ( 6 ) 276, 373 E s c u d i e , J . ( 1 ) 298, 301, 332; ( 9 ) 19c Etemad-Moghadharn, G. ( 1 ) 160, 249; ( 4 ) 102: ( 9 ) 25 E t l i s , V . A . ( 5 ) 122 E t o , M. ( 5 ) 167 E t t e r , M.C. ( 3 ) 36 Evans, F.E. ( 6 ) 276 Evans, R.K. ( 6 ) 245, 246 Evans, S . A . ( 1 ) 115: ( 2 ) 1 2 , 13 Evertz, K. 1 ) 322 E v s t i g n e e v a R.P. ( 7 96 Ewig, C.S. ( 9 ) 236

Fabre, J.M. ( 7 ) 56 F a c z h i n , G. ( 1 ) 2Q4 F a c k l e r , J.P. ( 4 ) 35;

( 9 ) 34

F a l c k , J.R.

( 7 ) 9 9 , 101,

102

F a n n i , T. ( 2 ) 17; ( 5 ) 38 F a r a h , S. ( 5 ) 172; ( 9 )

31 2

F a r r i s , C.L.

(8) 215

Fassbender, F.J.

39

( 8 ) 38,

F a t h i , R . ( 9 ) 43 Faulhammer. H.G. ( 6 )

268

F a u l s t i c h , H ( 6 ) 18 Fauq, A . ( 7 ) 109 F a u r e , R. ( 1 179 F a v r e , A . ( 6 261 F a w c e t t , J. 9 ) 192 F a w z i , R . ( 1 307 F e d e r o v , S.G ( 8 ) 78;

( 9 ) 281

( 5 ) 119: ( 8 ) 176 Feng, H. ( 1 ) 34 Feng. W.M. ( 5 ) 24 Feng, X. ( 1 ) 303, 304: ( 9 ) 182 Ferguson, G. (8) 222 F e r i n g a , B.L. ( 9 ) 74 Fedorova, G . K .

F e r n a n d e z - I b a n e z , M.

( 9 ) 1 0 9 , 141 ( 9 ) 301 ( 8 ) 108, 198 F-erraboschi, P . ( 1 ) 140 F e r r e r , P. ( 1 ) 112: ( 7 ) 33 F e r r e r i , C . ( 1 ) 116 F e r r i e r , D.J. ( 6 ) 408 Feshchenko, N.G. ( 1 ) 195, 196: ( 8 ) 176 F e r s h t , A.R. ( 6 ) 44 F e t t e r , A.P. ( 9 ) 117 F e u e r s t e i n , J . ( 6 ) 351 F i d d e r , A. ( 6 ) 163 F i e l d h o u s e , J.W. ( 8 ) 171 F i g u e r u e l o , J.E. ( 9 ) 293 F i l i p p e s c h i , 5. ( 8 ) 99 F i l i p p o v a , E . A . ( 9 ) 140 Fincharn, J.K. ( 8 ) 74, 75, 109; ( 9 ) 224 F i n e t , J.-P. ( 2 ) 3 F i n k , G . ( 8 ) 62 F i n k , J. ( 1 ) 366 F i n k e l m a n n , H. ( 8 ) 77 F i s c h , J. ( 6 ) 160 F i s c h e r , J . ( 1 ) 326 F i s c h e r , M. ( 9 ) 191 F i s h e r , M . ( 8 ) 27 F i t z , T. ( 7 ) 122 F i t z p a t r i c k , N.J. ( 8 6 Fernando, F. Ferrar, W.T.

F i t z p a t r i c k , R.J. ( 8 ) 188 Fiurne, L . ( 6 ) 18 F l i e s s , A. ( 6 ) 263 F l o d , E.C. (8) 198 F l o r e n t j e v , V.A. ( 6 )

95

F l o r i n , N. ( 8 ) 128 F l o y d , R . A . ( 6 ) 285 F l u c k , E . ( 1 ) 98,

172, 218, 290: ( 4 ) 31; ( 7 ) 6: ( 9 ) 1 0 1 , 1 7 8 , 200, 214 F o e l l i n g , P . ( 9 ) 160 Fogg, A.G. ( 9 ) 243 F o h l e n , G. (8) 135 F o l c h e r , G. ( 8 ) 97 F o l e s t , J.C. ( I ) 35 Fornakhin, E.V.

(5)

5 0 , 51

F o n t a i n , E. ( 5 ) 30 F o n t a i n e , C. ( 6 ) 175 F o r d , R . (8) 4 0 , 175,

186

F o r m a k h i n , E.V.

72

(9)

Foss, V.L. ( 8 ) 57 Fossey, J . ( 9 ) 126 Foucaud, A . ( 1 ) 370:

( 4 ) 44: ( 7 ) 18 (6) 175

F o u r r e y , J.L.

Frankenberger, W.T. ( 9 ) 288 F r a t t i n i , M.G. ( 6 )

98

F r e d e r i c k , C.A.

407

Freedman, L.D.

126: ( 5 ) 55

Freeman, G . A . Freeman, H.S.

126: ( 5 ) 55

(6) (1)

( 6 ) 92 (1)

Freeman, S . ( 5 ) 189 F r e i e r , S.M. ( 4 ) 66:

( 6 ) 164, 236 ( 6 ) 73, 7 5 , 79 F r e y e r , G.A. ( 6 ) 344 F r i d l a n d , S.V. ( 1 ) 168; ( 9 ) 132 Friedman, N. ( 7 ) 91 F r i t z , G . ( 1 ) 4 2 , 43, 4 4 , 45 F r i t z , H. ( 9 ) 98 F r o e h l e r , B.C. ( 4 ) 74: ( 6 ) 29, 116 F r e y , P.A.

Organophosphorus Chemistry

430

Frornent, F . ( 7 ) 69 Frost, J.W. ( 5 ) 144 Frye, J.S. ( 3 ) 37 Fu, J.M. ( 9 ) 12 Fuchigarni, T . ( 1 ) 7 Fuchs, P.L. ( 5 ) 83: ( 7 ) 31

Fujii, K. ( 1 ) 10 Fujii, M. ( 4 ) 72, 73;

( 6 ) 30, 142, 143 Fujii, T . ( 6 ) 94 Fujirnoto, K . ( 6 ) 132 Fujino, K. ( 6 ) 166 Fujino, K.-I. ( 4 ) 69 Fujita, K . ( 5 ) 158 Fujiwara, 1. ( 9 ) 207 Fukui, T. ( 6 ) 381 Fukukawa, K . ( 6 ) 16 Fukumrnot, H. ( 7 ) 41 Fukuyama, K . ( 1 ) 78: ( 7 ) 41 Fukyarna, S. (8) 216, 217 Fuller, R.W. ( 6 ) 101 Furlong, E.A. ( 6 ) 283 Furrnan, P.A. ( 6 ) 92 Furneaux, H.M. ( 6 ) 344 Furubayashi, K. ( 9 ) 115 Furukawa, A. ( 8 ) 117 Furusawa, K. ( 6 ) 80 Fyfe, J.A. ( 6 ) 92

Gafurov, E.K. ( 1 ) 209 Gaines, D.F. ( 1 ) 262 Gait, M.J. ( 6 ) 156 Gaitzsch, T. (9) 180 Gajewski, E . ( 6 ) 64 Galiaskarova, R.T. ( 1 ) 361, 362; ( 4 ) 88

Galindo, A. ( 1 ) 108 Galkin, V . I . ( 9 ) 303 Gallagher, M.J. ( 1 ) 14 Galle, K. ( 2 ) 38 Gallo, K.A. ( 4 ) 71: ( 6 ) 200, 399:

( 9 ) 322

Gallos, J.K. ( 7 ) 58 Galvez-Ruano, E. ( 9 ) 109, 141

Garnbero, C . ( 1 ) 140 Garnper, H. ( 6 ) 27A, 275 Ganapathiappan, S. (8) 87 85, 89

Gandru, K. (1) 106 Gangola, P. ( 6 ) 354 Garanti, L. ( 8 ) 61 Garcia, J.L. ( 9 ) 150 Gardiner. K.J. ( 6 ) 348

Gareev, R.D. ( 4 ) 5 ( 7 )

Gilson, G.J.P. ( 6 )

Gareev, R.F. ( 9 ) 266 Garegg, P . 3 . ( 1 ) 114:

Giral, L . ( 7 ) 56 Girault, J.-P. ( 6 )

119

( 4 ) 34, 75, 76: ( 6 ) 26, 120, 121, 122 Gareil, P. ( 3 ) 7; ( 9 ) 286 Garia-Ochoa, S . ( 7 ) 16 Garibina, V . A . ( 5 ) 141: ( 9 ) 100 Garland, M.T. ( 1 ) 345 Garriga, G . ( 6 ) 335 Garrison, J.C. ( 6 ) 56 Garroussian, M. ( 9 ) 325 Gaset, A . ( 7 ) 17 Gasparyan, G.Ts. ( 1 ) 105 G w t i e r , J.C. ( 9 ) 58 Gavina, F. ( 1 ) 112: ( 7 )

33

Gebert, P.H. ( 8 ) 215 Gebeyehu, G. ( 6 ) 101, 233

Gebura, M . ( 8 ) 188 Geiduschek, E.P. ( 6 ) 297

Gemrnill, R.M. ( 6 ) 410 Geoffroy, M. ( 9 ) 125 Geraldes, C.F.G.C. ( 6 ) 362

Gerlach, W.L. ( 6 ) 346 Gerlt, J.A. ( 6 ) 314 Gerrna, H. ( 9 ) 55 Gerrnain, G . ( 1 ) 144; ( 9 ) 78, 170

German, G. ( 6 ) 97 Germeshausen, J. ( 1 ) 38, 41: ( 3 ) 16

Gerry, M.C.L. ( 9 ) 142 Gesteland, R.F. ( 6 ) 271

Gettleman, L. (8) 215 Getz, G.S. ( 6 ) 299 Gevaza, Yu. I. ( 5 ) 115 Ghawi, L. ( 5 ) 172; ( 9 ) 31 2

Ghosez, L . ( 7 ) 76 Ghribi, A . ( 5 ) 78 Gibbons, I . ( 6 ) 87 Gigg, R . ‘ ( 4 ) 28 Gieren, A . ( 9 ) 174, 175 Gilbert, J.C. ( 7 ) 87 Gilbert, W. ( 6 ) 290, 414

Gillarn, I.C. Gillard, R.D. Gilrnore, W.F. Gilpin, M.L.

( 6 ) 233 ( 3 ) 36 ( 7 ) 81 ( 7 ) 133

108

372

Giro, G. ( 8 ) 181 Gish, B.G. ( 9 ) 262 Gladysz, J.A. ( 7 ) 67

Glase, S . A . ( 5 ) 25 Gleason, W.B. ( 3 ) 36 Gleiter, A . ( 1 ) 40; ( 9 ) 152

Gleria, M. (8) 110, 187, 197

Gloede, J.

2 ) 11. ( 5 ) 59 Gobel, K. ( ) 318: ( 8 ) 50 Godguadze, s.A. ( 8 ) 165 Godovika, T S. ( 6 ) 38 Godovikov, N.N. ( 5 ) 168 Godovikova, T.S. ( 6 ) 39 Goetz, J. ( 5 ) 30 Gol, F. ( 1 ) 185: ( 4 ) 41; ( 9 ) 173 Gold, G.H. ( 6 ) 3 Goldberg, I . H . ( 6 ) 321 Goldberg, N.D. ( 6 ) 55 Goldberg, R.N. ( 6 ) 64 Gol’dfarb, E . I . ( 9 ) 72 Gol’din, G.S. (8) 78: ( 9 ) 281 Goldkorn, T . ( 6 ) 241 Goldwhite, H. ( 1 ) 235 Gololobov, Yu.G. ( 8 ) 24 Golovanov, A.N. ( 5 ) 97, 98 Golovanov, A . V . ( 1 ) 190 Golubov, M . I . ( 9 ) 270 Gomelya, N.D. ( 1 195 Gonbeau, D. ( 9 ) 50 Gong, P. ( 6 ) 273 Goodchild, J. ( 6 206 Goodman, M.F. ( 6 187, 190, 196

43 1

Author Index

G o o d r i d g e , R.J. ( 9 ) 47 Goody, R . S . ( 6 ) 71, 351,

384

Goppert, K . E . ( 8 ) 198 G o r d i l l o , 6. ( 9 ) 269 G o r e n s t e i n , D . G . (2) 1 7 ,

1 8 , 20; ( 5 ) 37, 38, 170: ( 9 ) 1 2 , 319 Gorvunov, N.1. ( 8 ) 218 Goryunov, E . I . ( 5 ) 28 Gosney, I . ( 4 ) 104 L o s s e l i n , G. ( 6 ) 176, 21 2 Gouasmia, A . ( 7 ) 56 Gough, S . ( 6 ) 4 Gouygou, M. ( 1 ) 160 Goyne, T . ( 6 ) 320 Goyne, T . E . ( 6 ) 319 Graaskamp, J . M . ( 8 ) 118, ( 9 ) 216 G r a b l e , J . ( 6 ) 407 Grabowski, P . J . ( 6 ) 244 Gracher, M.A. ( 6 ) 254 Gracher, M.K. ( 9 ) 299 Graczyk, P. ( 5 ) 19 Gradov, V . A . ( 1 ) 158 G r a e f f , R.M. ( 6 ) 55 G r a f f e u i l , M. ( 8 ) 98 Graham, J.B. ( 8 ) 148 Grand, A. ( 2 ) 33 G r a n d j e a n , 0 . (1) 8 Grapov, A.F. ( 5 ) 1 3 ; ( 9 ) 118 G r a v i e r , r . ( 7 ) 98 Grayson, J . I . ( 3 ) 33 Gree, R . ( 7 ) 26, 101 G r e e l e e , W.J. ( 5 ) 114 Greene, P . ( 6 ) 407 Gregory, P . R . ( 6 ) 84 Gren, E.J. ( 6 ) 256 Grey, A.E. ( 8 ) 206 G r i b o v , L.A. ( 9 ) 2 G r i e n d , L.V. ( 2 ) 40 G r i f f i n , J.H. ( 6 ) 323 G r i f f i t h s , A.D. ( 6 ) 74 G r i f f i t h s , D . V . ( 2 ) 26; ( 3 ) 12: ( 5 ) 161; ( 9 ) 86 G r i q o r y a n , N.Yu. ( 1 ) 68 G r i l l e r , 0. ( 9 ) 129 G r i m , 5.0. ( 1 ) 124: ( 9 ) 59 G r i m a l d o Moron, J.T. ( 1 ) 202 Grison, C . ( 5 ) 85 Grobe, J , ( 7 ) 272, 273, 274: ( 9 ) 16 Grolleman, C.W.J. ( 8 ) 183, 184 Gross, H. ( 5 ) 146

Gross, M . L .

( 6 ) 401 Grossrnann, G.Z. ( 9 ) 96 Grot.iahn, L . ( 6 ) 399,

401

Gruys, K.J. ( 6 ) 8 4 , 85 Gryaznov, S.M. ( 6 ) 240 Gryaznova, 0 . 1 . ( 6 ) 198 Gryaznova, T . V . ( 1 ) 191,

1 9 2 , 193

Guaglianone, P . ( 6 ) 88 Gubanov, V . A . ( % ) 166 Gudat, D. ( 1 ) 258, 260,

312, 313, 315: ( 9 ) 161 Guedon, G.F. ( 6 ) 108 Guenchg, G . ( 8 ) 97 GuCron, M. ( 6 ) 357 Guqa, P . ( 6 ) 21 G u i t t e t , E. ( 6 ) 175, 372 G u l i e v , A.N. ( 5 ) 84 Gumport, R . I . ( 6 0 184 Gunduz, N. ( 8 ) 79, 8 0 , 112: ( 9 ) 225, 241 Gundur, T . ( 8 ) 79, 80, 112; ( 9 ) 2 2 5 , 241 Guo, H. ( 3 ) 6 Gupta, R . ( 6 ) 46 Gupta, S.V. ( 6 ) 226 G u r a r i i , L . I . ( 9 ) 218, 220 G u r e v i c h , I.E. ( 5 ) 163 G u r e v i c h , P.A. ( 4 ) 9 G u r s k i i , M. ( 9 ) 185 Guseinova, F . I . ( 1 ) 141 Gutierrez-Puebla, E. ( 1 ) 108 G v o z d e k s k i i , A.N. ( 2 ) 29

Hahn, J . ( 1 ) 3 9 ;

( 5 ) 1 3 4 , 135 ( 5 ) 133 ( 6 ) 160 ( 8 ) 44 E. ( 6 ) 261 H a j j , A.N. ( 9 ) 313

Haiduc, I . Haines, L . H a i n i , R. Hajnsdorf,

(8)

H a l a s a , A.F.

171

H a l e , K.J. ( 1 ) 121 H a l e y , B.E. ( 6 ) 245,

246, 247

H a l l , C.D. H a l l , T.J.

( 9 ) 239

(2) 14

( 1 ) 198:

H a l t i w a n q e r , R.C.

( 4 ) 4 2 , 43; ( 9 ) 63a, 88, 179 ( 7 ) 107, 108 Hamada, Y . ( 9 ) 206 Harnamoto, 5. ( 4 ) 70; ( 6 ) 146 Hambley, T . W . ( 9 ) 47 Harnblin, M.R. ( 6 ) 34 Hamelin, J . ( 1 ) 165, 264

Hamada, T.

H a m i l l , B.J.

136

Hammerschrnidt, F. ( 5 ) 32: ( 9 ) 205 Hammond, G.B. ( 5 )

70, 92: ( 7 ) 74

Hampel, A. ( 6 ) 346 Hanamoto, T . ( 1 )

225; ( 3 ) 1

Handoo, H.L.

106

Hanessian, S. Haase, D. ( 1 ) 217 H a c k e t t , M. ( 1 ) 1 H a c k l i n , H. ( 9 ) 64 Hackney, D.D. ( 6 ) 70 Haddon, R.C. ( 8 ) 179 H a d z i y e v , D . ( 9 ) 292 Haegele, G. ( 5 ) 138;

( 9 ) 76, 8 3 , 110, 1 9 7 , 198 Haenni, A.L. ( 6 ) 268 Haenel, P . ( 9 ) 240 H a e r t l e , T. ( 6 ) 219 H a f e z , T.S. ( 2 ) 22 H a f n e r , A. ( 4 ) 13 H s g e l e , G . ( 1 ) 1 6 1 , 162 Hageman, H.J. ( 3 ) 26 Hagnauer, G.L. ( 8 ) 174, 189

(6)

94

(1) (7)

Hanqzhou, G. ( 9 ) 260 H a n i , M. ( 9 ) 80 H a n i , R. ( 1 ) 118;

( 8 ) 41, 1 7 4 , 175

H a n i k a , G. ( 1 ) 54 Hanke, W . ( 1 ) 95 Hanna, A.G. ( 9 ) 80,

255

Hanna, M.T. ( 9 ) 306 Hara, M. ( 8 ) 203 H a r b r i d g e , J.B. ( 7 )

133

Hzrd, H. ( 6 ) 366' Hardy, L . C . ( 8 ) 205 H a r g e r , M.J.P. (5)

186, 187, 1 8 8 ,

432

189 H a r g i s , J.H. ( 1 ) 198: ( 9 ) 239 H a r i c h , K.C. ( 8 ) 77 H a r l a n d , J.J. ( 2 ) 5 Harmenberg, J. ( 9 ) 292 Haromy, T.P. ( 6 ) 353 H a r r i s , G. ( 6 ) 99 H a r r i s , J . ( 6 ) 285 H a r r i s , P.J. ( 8 ) 77 H a r r i s , R.K. ( 1 ) 161: ( 5 ) 138 H a r r i s , S.M. ( 7 ) 29 H a r r i s o n , B. ( 6 ) 238 H a r t l e y , J.A. ( 6 ) 293 Hartmann, C. ( 7 ) 64 Hartman, K.A. ( 6 ) 406 Hartman, H. ( 7 ) 38 Hartmann, W. ( 5 ) 59 H a r u i , N. ( 1 ) 224: ( 7 ) 28 Harusawa, S. ( 5 ) 26, 27 Hatakeyama, '5. ( 7 ) 112 Hashida, T . ( 1 ) 251 Hashirnoto, H. ( 1 ) 50 Hashirnoto, Y . ( 6 ) 317 Hashizume, T . ( 6 ) 46 Hasim, H.A. ( 8 ) 49 Hata, T. ( 4 ) 67, 72, 73; ( 6 ) 30, 133, 134, 139, 140, 141, 142, 143, 149, 170 Hatano, H. ( 6 ) 381 H a t t o r i , M. ( 1 ) 29 Haug, B.L. ( 6 ) 226 Haug, W. ( 1 ) 330: ( 9 ) 123 Haupt, E.T.K. ( 9 ) 79 Havranek, M. ( 6 ) 90 Hayakawa, Y . ( 4 ) 60: ( 6 ) 7, 128, 147, 177 Hayase, Y. ( 6 ) 171, 301 H a ya s h i , K . ( 6 ) 238 Hayatsu, H. ( 6 ) 229 Hayes, J.E. ( 1 ) 223; ( 7 ) 46 Haynes, R.K. ( 3 ) 34,35 H e a r s t , J.E. ( 6 ) 274, 275 Heath, G.A. ( 1 ) 250 Heathcock, C.H. ( 7 ) 128 Hecht, S.M. ( 6 ) 309, 315 Hecker, S . J . ( 7 ) 128 Heckmann, G. ( 1 ) 98, 290: ( 9 ) 214 H e g a r t y , A.F. ( 1 ) 276: ( 3 ) 17; ( 8 ) 7 Heide, W. ( 9 ) 325 H e i k k i l a e , .I.( 6 ) 37 H e i l , B. ( 9 ) 77

Organophosphorus Chemistry

Heine, 3. ( 9 ) 64 H e i n i c h a r t , J.P. ( 1 ) 210 H e i n i c k e , J. ( 1 ) 63, 354, 355; ( 4 ) 81: ( 5 ) 91: ( 9 ) 147 Hei nz e, J. ( 7 ) 27 H'elzne, C. ( 6 ) 117, 328 H e l l e r , J. ( 8 ) 182 Hellman, M.Y. ( 8 ) 179 Henderson, R.A. ( 1 ) 153 Hennawy, I . T . ( 7 ) 42 Henner, W.D. ( 6 ) 283 Henri c hs on, C. ( 6 ) 120, 122 H e r b s t , R . ( 8 ) 47 Herc ouet, A. ( 1 ) 200 H e r d e r i n g , W. ( 6 ) 33 H e r g e n r o t h e r , W.L. ( 8 ) 171 H e r i n g , G . ( 5 ) 30 Herman, F. ( 6 ) 372 Herman, T.M. ( 6 ) 88 Herrnans, J.P.G. ( 4 ) 61 Herradon, 6. ( 1 ) 208; ( 7 ) 16 Herrmann, E . ( 5 ) 44, 63: (8) 22, 37 Herrmann, T.P. ( 6 ) 354 Heubel, J . ( 8 ) 36 Heuer, L . ( 1 ) 173 Hey, E. ( 1 ) 9, 99 Heydt, H. ( 1 ) 308, 309 Heyman, R.A. ( 6 ) 55 Hietkarnp, S. ( 1 ) 18, 65, 185: ( 4 ) 41 H i g g i n s , S . J . ( 1 ) 49 H i g u c h i , T. ( 9 ) 164, 165 H i l l , T . G . ( 9 ) 61, 63a H i l l e r , W. ( 1 ) 307 Himes, R.H. ( 6 ) 81 H i r a o k a , H. ( 8 ) 219 H i r a o k a , N. ( 6 ) 238 H i r o o k a , S. (7) 138 H i r o t a , S. ( 1 ) 78 H i r o t s u , K . ( 9 ) 164, 165 H i r s c h b e r g , C.B. ( 6 ) 248 H i t c h c o c k , P.B. ( 1 ) 291, 293, 294, 296, 316, 317; ( 4 ) 89; ( 8 ) 49 Ho, C.K. ( 6 ) 44 Hobbs, J.B. ( 6 ) 25 Hodge, P. ( 1 ) 104 Hoeve, W. ( 9 ) 225 Hoffmann, M. ( 5 ) 110 Hoffmann, R . ( 8 ) 68 Hoffmann, R.W. ( 7 ) 113 Hogg, A.M. ( 6 ) 400 Holand, 5. ( 1 ) 337, 338 Hol brook , S.R. ( 6 ) 275

H ole, E.O. ( 9 ) 131 H o l l e r , E. ( 6 ) 370, 2 74 Holm, K.H. ( 7 ) 86 Holmes, J.M. ( 2 ) 5, 7 Holmes, K . C . ( 6 ) 384 Holmes, R.R. ( 2 ) 5, 6, 7 H o l t z c l a w , J.R. ( 9 ) 253 H oly, A. ( 6 ) 13 H z l z l , W. ( 1 ) 177 Hong, C.I. ( 6 ) 113 Honjo, M. ( 9 ) 207 H iinle, W. ( 1 ) 45 Honnens, J. ( 6 ) 123 Hope, E.G. ( 1 ) 25 Hopf, H. ( 7 ) 92 H o r i c h i , T . ( 8 ) 140 Horn, T . ( 4 ) 51, 53: ( 6 ) 154 H o r n i g , H. ( 6 ) 343 H o r o w i t z , D.M. ( 6 ) 190 H o r w i t z , 5.6. ( 6 ) 31 2 Hosang, 0. ( 9 ) 98 H oskins, J. ( 6 ) 390 H o s s e i n i , H.E. ( 9 ) 16 H o s s e i n i , M.W. ( 6 ) 61, 62 Hosoda, A. ( 7 ) 93 Hotoda, H. ( 6 ) 133, 134 H oussin, R. ( 1 ) 210 H o v a t t e r , K.R. ( 6 ) 232 Howard, F.B. ( 6 ) 225 Howarth, T . T . ( 7 ) 133 Hoz, S. ( 9 ) 39 Huaming, Z . ( 7 ) 9 Huang, D.-D. ( 6 ) 4 Huang, M.H.A. ( 9 ) 285 Huang, Y . ( 6 ) 249: ( 7 ) 105 (7) Huang, Y.-Z. 24, 25 Huber, 5. ( 9 ) 23 Hubner, T. ( 9 ) 174, 175 Huch, V. (8) 45: ( 9 ) 187, 189 Hudson, H.R. ( 4 ) 15

Author Index

Huguenin, L.M. ( 1 ) 341 Huisgen, R. ( 3 ) 28 Hull, R. ( 6 ) 265 Hulst, A.G. ( 9 ) 254, 256

Hunerbein, J. ( 1 ) 151; ( 9 ) 70

Hung, S.C. ( 1 ) 15 Hunt, T . ( 6 ) 306 Hunter, W.N. ( 6 ) 404 Huong, G. ( 5 ) 67 Hurst, W . ( 9 ) 292 Hursthouse, M.B. ( 1 )

133; ( 8 ) 70, 71, 72, 73, 74, 75, 109, 111, 112; ( 9 ) 4 6 , 56, 1 2 0 , 224, 225, 226 Hurwitz, J. ( 6 ) 344 HUSS, S . ( 6 ) 1 7 6 , 212 Hussain, W. ( 1 ) 153 Hussong, R. ( 1 ) 308, 309 Hutchins, R.O. ( 5 ) 182 Hutchinson, D.W. ( 5 ) 157 Huttner, G. ( 1 ) 322, 323, 329: ( 8 ) 45 Huy, N.H.T. ( 1 ) 325, 326 Huynh-Dinh, T . ( 6 ) 372, 39 1 Hylemon, P.B. ( 6 ) 114

Iagrossi, A. ( 5 ) 1 1 , 36 Ibrahim, E.H. ( 9 ) 56 Ibsn’ez, F . ( 1 ) 107 Ide, H. ( 6 ) 86 Igau, A. ( 1 ) 275 Ignat’ev, S.N. ( 9 ) 84 Ignat’ev, Yu.A. ( 5 ) 5 Ignatov, M.E. ( 8 ) 125 Iqolen, J. ( 6 ) 372, 388, 391

Iio, H. ( 7 ) 22, 23 Iino, Y . ( 8 ) 52 Iijimo, H. ( 6 ) 317 Ikedo, M. ( 5 ) 167 Jkeda, N. ( 3 ) 27: ( 7 ) 14

Ikeda, S. ( 6 ) 112 Ikeda, Y. ( 3 ) 27: ( 7 ) 14

Ikemura, T. ( 6 ) 280 Iksanova, S.V. ( 1 ) 239; ( 2 ) 8: ( 9 ) 6 5 , 94

Ikehara, M. ( 4 ) 69; ( 6 )

131, 132, 144, 145, 157, 1 6 1 , 165 166, 182

433

Ilamov, R . G . ( 9 ) 72 Ilves, H. ( 6 ) 296 Il’yasov, R.N. ( 1 ) 70 Imai, J. ( 6 ) 176, 207 Imai, K . ( 6 ) 168, 169 Imamoto, T . ( 1 ) 80; ( 3 ) 8

Imamura, S. ( 6 ) 16 Imao, K . ( 6 ) 15 Imbach, J.-L. ( 4 ) 25: ( 6 ) 173, 176, 212

Imura, A. ( 6 ) 131 Inamoto, N. ( 1 ) 251,

284, 288: ( 5 ) 123: ( 9 ) 164, 165 Inanarni, 0 . ( 6 ) 284 Inaoka, T . ( 6 ) 32 Indzhikyan, M.A ( 5 ) 64 Indzhikyan, M.G ( 1 ) 68, 9 1 , 1 0 5 , 206 ( 8 ) 103 Inners, R.E. ( 7 12 Inners, R.R. ( 2 1 6 ; ( 9 ) 183 Inocencio, P.A. ( 5 ) 1 9 ( 9 ) 44 Inokawa. 5 . ( 5 ) 158 Inoue, H. ( 6 ) 1 3 0 , 13 1 7 1 , 186, 1 9 3 , 301 302 Inoue, I. ( 6 ) 332 Inoue, K . ( 3 ) 39, 40 Inoue, T . ( 6 ) 334, 336 Inoue, T . I . ( 6 ) 335 Inoue, Y. ( 6 ) 131 Inshakova, V.T. ( 1 ) 159 Iogrossi, A. ( 9 ) 45 Ionin, €3.1. ( I ) 166, 167, 170 ( 5 ) 75, 1 0 4 , 116, 141, 1 5 0 , 162, 163; ( 9 ) 1 0 0 , 117 Ionkin, A.S. ( 1 ) 147: ( 9 ) 84 Ireland, R.E. ( 7 ) 131 Irie, M . ( 5 ) 167 Isaacs, N.S. ( 7 ) 36; ( 9 ) 307 Isaev, V.B. ( 8 ) 104, 105 Isaeva, G.M. ( 1 ) 148, 220; ( 9 ) 60 Isakov, M. ( 6 ) 71 Ishibashi, H. ( 5 ) 167 Ishida, M. ( 7 ) 4 Ishihara, T . ( 5 ) 89 Ishii, K . ( 9 ) 322 Ishizaki, Y. ( 6 ) 238 Ishmaeva, €.A. ( 3 ) 23: ( 9 ) 234, 235, 237 Islamov, R.G. ( 5 ) 51 Ismailov, V.M. ( 1 ) 141; ( 5 ) 73, 84

Isono. J. ( 6 ) 51 Issleib, K. ( 1 ) 3 , 256

Itakura, K. ( 6 ) 190 Itani, A. ( 5 ) 172 Ito,

s.

( 8 ) 213

Ito, T . ( 6 ) 169 Itzstein, M.V. ( 7 ) 80

Ivanov, S. ( 9 ) 316 Ivanov, S.K. ( 9 ) 78 Ivanova, N.L. ( 9 ) 299

Iverson, B.L. ( 6 ) 300 Ives, D.H. ( 6 ) 112 Iwai, S . ( 6 ) 1 3 1 ,

132, 161, 171, 186, 1 9 3 , 301 Iwamoto, N. ( 5 ) 1 4 2 , 143 Iwata, Y . ( 6 ) 94 Iyengar, R. ( 6 ) 7 3 , 78 Izba, W . G . ( 8 ) 129 Izhboldina, L . P . ( 5 ) 71

Jablonski, J.-A. ( 6 ) 150

Jackson, L.A. ( 8 ) 77 Jacobs, K . ( 6 ) 160 Jageland, P.T. ( 5 ) 138

Jakob, P. ( 5 ) 30 Jakobi, U. ( 1 ) 342 Jamali, H.A.R. ( 5 ) 161

James, T.L. ( 6 ) 199 James Privett, J.A. ( 8 ) 148

Jamoulle, J.C. ( 6 ) 207, 213, 214

Jankowski, K . ( 6 ) 399

Jannakoudakis, 0. ( 1 ) 228: ( 9 ) 242

Janssen, R.A.J. ( 9 ) 128

Jasim, H.A. ( 1 ) 317 Jastreboff, M.M. ( 6 ) 41 1

Jawad, H. ( 1 ) 75 Jay, D.G. ( 6 ) 414 Jazwinski, J. ( 6 ) 329

Jeong, I.H. ( 7 ) 49 Jenkins, 1.0. ( 9 ) 103

Organophosphorus Chemistry

434

Jensen, D.E. ( 6 ) 234 J h u r a n i , P . ( 6 ) 231 J i a n g , H. ( 6 ) 288 J i b r i l , I . ( 8 ) 46 J i n , X. ( 5 ) 67: (9) 81 J i n , Y . ( 6 ) 273 J i n g , G . ( 6 ) 235 J i r i c n y , J. ( 6 ) 189 John, J. ( 6 ) 351 Johns, D.G. ( 6 ) 101 Johnson, C . R . ( 1 ) 80:

( 3 ) 8 . ( 8 ) 172, 185 Johnson, E.C. (6) 2 Johnson, J.D. ( 6 ) 54, 246 Johnson, N.P. ( 6 ) 375 Johnson, R.B. ( 3 ) 36 Johnson, R.D. ( 9 ) 138 Johnson, T.B. ( 6 ) 115 Jones, A.S. ( 6 ) 11. ( 9 ) 219 Jones, C . R . ( 9 ) 12 Jones, R . A . ( 1 ) 59 Johns, R.B. ( 4 ) 52, 59 Jones, R . J . ( 7 ) 135 Jones, R . L . ( 6 ) 395, 396 Jordaan, A.M. (9) 292 Jordan, A.D., J r . ( 7 ) 13 Jordan, F. ( 9 ) 4 3 Jorgensen, T.J. ( 6 ) 283 J o s h i , R.L. ( 6 ) 268 J o s t , K.H. ( 9 ) 222 Joussen, R . ( 3 ) 29 J u a r i s t i , E. ( 9 ) 269 J u i l l a r d , M. ( 4 ) 22 J u l i a , M. ( 5 ) 7 Juneau, M.K. ( 8 ) 82, 84 Jung, S.H. ( 1 ) 103: ( 7 ) 20, 21 J u r k s c h a t , K. ( 1 ) 4 , 6 1 , 144: ( 9 ) 78, 170 J u s t , G. ( 6 ) 370; ( 7 ) 100, 120 J u t z i , P. ( 1 ) 127, 236, 2 5 7 ; ( 4 ) 100: ( 9 ) 19a J y - S h i h Wang ( 5 ) 21

Kaba, L . ( 6 ) 261 Kabachnik, M . I . ( 1 ) 227: ( 2 ) 39: ( 5 ) 168: ( 9 )

127

( 1 ) 207: ( 4 ) 32, 40: ( 5 ) 28; ( 9 ) 89 Kachensky, D.F. ( 7 ) 129 Kachkovskaya, L.S. ( 1 ) 265, 277 Kabachnik, M.M.

Karpova. G . G .

K a d e d i i , L . I . ( 5 ) 165 K a d l u b a r , F . F . ( 6 ) 276 Kadonga, J.T. ( 6 ) 242 Kadyrov, R . A . ( 9 ) 10,

255, 256

( 1 ) 51, 52, 53, 54, 55,

Karsch, H.H.

56 Karsen, W.E. ( 6 ) 67 Karwan, R . ( 6 ) 303 K a r w a t z k i , A . ( 8 ) 15 Kasaharn, M. ( 8 ) 6’3 K a s a i , H. ( 6 ) 193,

2 38

Kaga, K . ( 7 ) 4 K a i s e r , K . ( 4 ) 57: ( 6 )

196

K a i s e r , M . ( 9 ) 80 K a j i n o , 11. ( 6 ) 147 K a j i w a r a , M . ( 8 ) 180,

286

K a j i w a r a , N. ( 8 ) 137 K a k i u c h i , H. ( 1 ) 231 K a l a b i n a , A.V. ( 5 ) 171:

( 9 ) 320

350, 351

(6)

K a l ’ c h e n k o , V.I. ( 9 ) 67 Kalibabchuk, N . N . ( 1 ) 110: ( 9 ) 35 K a l i n i c h e n k o , E.N. ( 6 )

210

Kamaike, K. ( 6 ) 168 Kamal, M.M. ( 9 ) 245 Karnalov, A.M. ( 5 ) 2 K a m i n s k i , J. ( 1 ) 235 K a m i n s k i , R . ( 9 ) 261 K a n a i , H. ( 7 ) 126 Kanaya, E. ( 6 ) 221 K a n d i l , A . A . ( 5 ) 68 K a n j o l i a , R.K. ( 9 )

Katsyuba, S . A .

140

249

K a p l a n , B.E.

Katzurina, V.P.

220

Kaub, J.

( 6 ) 187,

50

1 9 0 , 196

30, 31

(8)

( 1 ) 318: ( 8 )

Kauffmann,

K a p l a n , M.L. Kapoor, P.N. Kappen, L.S. Karaghiosoff,

( 8 ) 179 ( 1 ) 19 ( 6 ) 321 K. (1) 188. 364; ( 4 ) 8 6 , 87; ( 9 ) 30, 167 Karanewsky, D.S. (5) 106 K a r a s i k , A.A. ( 1 ) 145 Kardanov, N.A. ( 5 ) 168 Karelov, A.A. ( 9 ) 4 K a r g i n , Yu.M. ( 5 ) 5 K a r i m , A . ( 1 ) 180; ( 4 ) 82 K a r i m u l l i n , 5h.A. ( 4 ) 23 Karkozov, V . G . ( 8 ) 136 K a r l , R. ( 5 ) 30 K a r l s o n , U. ( 9 ) 288 K a r l s s o n , A.H.J. ( 9 ) 292 Karolak-Wojciechowska, (9) 5

(9)

( 8 ) 47, 158, 159: ( 9 ) 264 K a t t i , S.B. ( 6 ) 32 K a t z h e n d l e r , J. ( 4 ) 24 K a t t i , K.V.

K a n n a n j a r a , C.G. ( 6 ) 4 K a n n e r t , G. ( 1 ) 132,

134

(5) 128, 145, 165 K a s h k i n , A . V . ( 5 ) 28 Kashtanova, N.M. ( 2 ) 35 KasDruk, 6 . 1 . ( 9 ) 317 K a s s a v e t i s , G.A. ( 6 ) 297 K a s u k h i n , L . F . (8) 24, 25: ( 9 ) 324 Katoaka, 5 . ( 6 ) 51 K a t o , H. ( 6 ) 147 K a t o , M. ( 6 ) 51 K a t o , 5. ( 7 ) 4 K a t o , T . ( 7 ) 138 K a t s i f i s , A.G. ( 3 ) 35 Kashernirov, B.A.

207

K a l b i t z e r , H.R.

(6)

T.

( 3 ) 29,

Kavsan, V . M . ( 6 ) 95 Kawasaki, T . ( 9 ) 292 Kawase, Y. ( 6 ) 186 Kawashima, T . ( 1 ) 288-

( 5 ) 123; ( 9 ) 325

Kawazoe, Y . ( 6 ) 286 Kay, P.B. ( 9 ) 104 Kay, P.S. ( 6 ) 334,

336

(1) 1 7 1 , 194: ( 9 ) 107 Kazantsev, A.V. ( 1 ) 6 , 209 Kazimierczuk, Z. ( 6 ) 53 Kazmierczak, K . (1 ) 39 Kaznetsova, S.Ya. ( 9 ) 258 K e a t , R. ( 8 ) 75; ( 9 ) 9 2 , 224 Kazankova, M.A.

,J .

435

Author Index

Keck, G.E. ( 7 ) 129 Keck, H. ( 9 ) 251 Keglevich, G . ( 1 ) 175:

( 3 ) 14: ( 4 ) 1 5 , 4 7 ; (8) 18; ( 9 ) 33 Kehne, A . ( 6 ) 33, 191 Keitel, 1. ( 5 ) 90 Kell, B . ( 6 ) 390 Kelland, J.G. ( 6 ) 400 Keller, H. ( 9 ) 200 Keller, K. (8) 26 Keller, P.B. ( 6 ) 406 Kelley, J.A. ( 6 ) 101 Kellner, K. ( 1 ) 95 Kellogg, R.M. ( 9 ) 74 Kelly, J.W. ( 1 ) 115; ( 2 ) 12, I 3 Kemmitt, R.S.W. ( 9 ) 192 Kernmitt, T . ( 1 ) 25 Kemp, T . J . ( 1 ) 137: ( 3 ) 38 Kennard, 0. ( 6 ) 404 Kennepohl, D. ( 2 ) 41 Kent, A.G. ( 1 ) 23 Kent, D . E . ( 9 ) 272 Kerschl, S . ( 1 ) 360 Kessler, H. ( 9 ) 76 Keys, B.A. ( 9 ) 325 Khachatryan. R . A . ( 1 ) 6 8 , 9 1 , 206: ( 5 ) 64 Khairullin, V.K. ( 1 ) 169 Khalil, F.Y. ( 9 ) 306 Khalil, Kh.M. ( 7 ) 43 Khalimskaya, L.M. ( 6 ) 38

Khamsi, J. (2) 3 Khanna, R.J. ( 1 ) 124 Khanna, R.K. 9 1 ) 12 Khaskin, B.A. ( 5 ) 147: ( 9 ) 259

Khatib, F.E1. ( 1 ) 174 Khawli, L . A . ( 5 ) 105 Khokhlov, P.S. ( 5 ) 1 2 8 , 1 4 5 , 165

Khoshdel, E. ( 1 ) 104 Khusainova, N.G. (5) 1 8 0 , 184

Kibala, P . A . ( 1 ) 111 Kibardin, A.M. ( 1 ) 191, 192, 193

Kido, M . ( 9 ) 206 Kielbasinski, P. ( 5 ) 53

Kieper, G . ( 3 ) 30 Kierzek, R . ( 4 ) 6 6 ; ( 6 ) 164, 236

Kigoshi, H. ( 7 ) 130

Kilduff, J . E . ( 1 ) 248,

250: ( 4 ) 101 Kilic, E. ( 8 ) 79, 8 0 , 112: ( 9 ) 225, 241 Kilkuskie, R.E. ( 6 ) 31 5 Kim, C . (8) 178 Kim, S. ( 5 ) 2 3 Kim, T . V . ( 8 ) 25 Kimbro, K.S. ( 6 ) 98 Kinoyan, F.S. ( 7 ) 206 Kinzel, E . ( 1 ) 28 Kirisits, A.J. ( 6 ) 113 Kirch, U . ( 6 ) 83 Kireev, V . V . ( 8 ) 1 0 1 , 1 0 2 , 104, 105, 106, 113, 167, 195 Kirk, K . ( 9 ) 1 4 Kise, H. ( 9 ) 304 Kishikawa, H. ( 6 ) 316 Kisilenko, A.A. ( I ) 196 Kister, K.-P. ( 6 ) 333 Kitade, Y . ( 6 ) 211 Kitaev, Yu. P . ( 9 ) 151 Kitajima, Y. ( 5 ) 155. ( 7 ) 73 Klas, N. ( 3 ) 30 Klaus, W. ( 6 ) 384

Klebanskii, E.O.

(1)

238, 239, 240, 241. ( 4 ) 90: ( 9 ) 2 2 , 9 4 , 166 Klein, J . A . (8) 170 Klein, L . L . ( 7 ) 132 Klein, T . M . ( 6 ) b12 Kleiner, H.J. ( 1 ) 156 Klevan, L . ( 6 ) 233 Kliebisch, U . ( 8 ) 26 Klimentova, G.Yu. ( 4 ) 9

Klingebiel, U . ( 8 ) 26 Klobuear, W.D. (8) 84 Klochkov, A.N. ( 9 ) 323 Klose, G .

( 9 ) 11 Klosinski, P . ( 5 ) 42: ( 9 ) 298 Kluge, A.F. ( 5 ) 124 Kluger, R . ( 2 ) 1 9 a , 1% Knebl, A. ( 9 ) 214 Knight, W.8. ( 6 ) 82, 353 Kniper, M. ( 8 ) 127 Knebl, A . ( 1 ) 290 Knoch, F. ( 1 ) 151, 261, 266, 267, 268, 269, 283, 285, 339: ( 8 ) 3 9 ( 9 ) 196, 6 9 , 70, 157, 158, 159, 160, 162, 163, 168, 171, 180 Knockel, P. ( 5 ) 117 Knoebel, R. ( 9 ) 234, 235

Knorrie, D.G.

253

(6)

KO, Y . Y . C . ( 9 ) 172 Kobayashi, 5 . ( I ) 232

Kobayashi, T . (8) 52, 155

Kobayshi, Y. ( 7 ) 93 Kobbani, A. ( 9 ) 313 Kobets, N.D. ( 6 ) 253 Kochta, J . ( 1 ) 268: ( 9 ) 158

Kodera, H. ( 8 ) 63 Koeckritz, A . (8) 10: ( 9 ) 38

Koeckritz, P . ( 9 ) 38 Koeckkritz, P. (8) 1 0 Koelle, P . ( 9 ) 176 Koenig, M. ( 1 ) 160, 1 7 4 , 249: (4) 2 0 , 102: ( 9 ) 2 5 , 143

Koerwitz, F.L. ( 7 ) 77 Koester, H. ( 6 ) 129 Kohda, K. ( 6 ) 286 Kohn, K.W. ( 6 ) 293 Koizumi, M. ( 6 ) 161 Kojima, M. ( 8 ) 1 9 2 , 193

Kolbina, V.E. ( 5 ) 72 Kolesnik, N.P. ( 2 ) 8 ( 9 ) 65

Kolesova, V . A .

( 5 ) 49: ( 9 ) 252 r Koll, 8. ( 1 ) 39, 40 KGlle, P. ( 1 ) 305 Kolling, E . ( 7 ) 92 Kolocheva, T . I . ( 6 ) 254 Kolodii, Ya. I. ( 9 ) 295 Kolodny, N.H. ( 6 ) 363

Kolodyazhnyi, 0.1.

( 1 ) 110, 117, 271, 278: ( 2 ) 15: ( 9 ) 1 7 , 25, 35, 51 Komlev, I . V . ( 9 ) 149 Komoroski, R . A . ( 4 ) 35; ( 9 ) 34 K6nig, T . ( 4 ) 104 Konno, H . ( 7 ) 65: ( 9 ) 153 Konovalova, I . v. (1 ) 199; (2) 25, 35; (4) 6 Koole, L.H. (2) 21: ( 6 ) 24 Kormachev, V . V . ( 1 ) 158 Korneeva, G.A. ( 6 ) 347

Organophosphorus Chemistry

436

( 5 ) 136,

K o r o l e v , O.S.

176

K o r o l e v a , O.N. ( 6 ) 240 Korshak, V . V . ( 8 ) 165,

167

(2) 27; ( 4 ) 18; ( 5 ) 120 Korshunov, R.L. ( 4 ) 18; ( 5 ) 120, 184 Koshman, D . A . ( 1 ) 211 K o s l o v , E.S. ( 8 ) 55, 56 Kostin, V.P. ( 4 ) 23 K o t t w l t z , B. ( 9 ) 246 K o v k s , T . ( 6 ) 227 K o z a r i c h , J.W. ( 6 ) 310, 311, 314 K o z i a r a , A . ( 8 ) 16 Kosova, G.N. ( 8 ) 167 Kotovych, G. ( 6 ) 388 K o w a l s k i , J. ( 5 ) 33

K o r s h i n , E.E.

Kozenasheva, L . Ya.

( 5 ) 12 Kozhushko, B.N.

36

(2)

(1) 103, ( 7 ) 20, 21, 110 K o z i o l k i e w i c z , M. ( 4 ) 71; ( 6 ) 200 K o z l o v , E.S. ( 9 ) 127 K o r o l e v , O.S. ( 9 ) 135 K o z l o v , V.A. ( 5 ) 13; ( 9 ) 118 K r a a i j k a m p , J.G. ( 1 ) Kozikowski, A.P.

282

Kraemer, R . ( 9 ) 111 Kraevskll, A.A. (6)

97

Kramer, F.R. Kramer, J.B.

(6) 14

( 6 ) 266 ( 4 ) 12:

K r a n n i c h , L.K.

249

(9)

Krasnomolova, L.P.

116 74

Krause, N. ( 7 ) 92 K r a v t s o v a , S.F. ( 8 ) 78;

( 9 ) 281

208

( 9 ) 73,

K r a w i e c k a , B. ( 5 ) 177 Krayevsky, A . A . ( 6 ) 95,

96

( 1 ) 237, 258, 312 ( 4 ) 9 5 , 100; ( 9 ) 1 9 a , 1 6 1 , 193

Krebs, B.

Kudryavtsev, A.A.

28

(8)

Kudrya, T.N. ( 9 ) 137 Kudryova, T.N. ( 9 ) 209 Kudyakov, N.M. ( 1 ) 66 Kudyakov, N . V . ( 9 ) 155 Kueckelhaus, W. ( 9 ) 7 6 ,

8 3 , 110, 197, 198

K u h l b o r n , S. ( 9 ) 251 Kuhm, P. ( 1 ) 98 Kuhn, N. ( 9 ) 42 Kuhn, R . ( 9 ) 193 Kuhn, W . ( 9 ) 64 Kukalenko, S.S. ( 5 ) 128 Kukhareva, T.S. ( 4 ) 36;

( 5 ) 102

(9)

K r a t i k o v , V . I . ( 9 ) 144 K r a t z e r , R.H. ( 1 ) 7 3 ,

Krawczyk, E.

J.N. ( 4 ) 58: ( 6 ) 159, 160 K r i l o v , M. ( 9 ) 7 9 K r i s h n a m u r t h y , S.S. ( 8 ) 6 6 , 8 7 , 88, 89: ( 9 ) 264 K r i t z y n , A.M. ( 6 ) 95 K r i v c h u n , M . N . ( 1 ) 170 Kroenke, W.J. ( 4 ) 35: ( 9 ) 34 K r o t o , H.W. ( 9 ) 16 K r u e g e r , W. ( 9 ) 204 K r u g e r , C . ( 7 ) 66 Krupp, G. ( 6 ) 4 K r u t i k o v , V.1. ( 5 ) 97, 98 K r y a k , D. ( 6 ) 89 K r y n e t s k a y a , N.F. ( 6 ) 162 K u b j a c e k , M. ( 9 ) 265 K u c h e l , P.W. ( 9 ) 14 Kuchen, W. ( 9 ) 246, 251 K u c h i n o , Y . ( 6 ) 193 Kuchkovskaya, L.S. ( 9 ) 20 K u c k e l l h a u s , W. ( 1 ) 1 6 1 , 162; ( 5 ) 138 Kremsky,

Kukhanova, M.K.

96

( 6 ) 95,

Kukhar, V . P . ( I ) 8 4 , 271, 278; ( 8 ) 25, 34. ( 9 ) 1 7 , 25, 136, 1 9 6 ,

324

Kulak, Kurnar, Kumar, Kumar, Kumara

89

T . I . ( 6 ) 210 A.' ( 9 ) 219 D. ( 8 ) 135 S. ( 6 ) 281 Swamy, K . C . ( 8 )

Kumarev, V.P. ( 6 ) 197 Kume, A . ( 6 ) 30 Kunze, U. ( 1 ) 75, 76,

77: ( 3 ) 5 Kuo, F. ( 5 ) 83

K - J p a r a t , G. ( 9 ) 24, 25 K u p r i y a n o v , V.V. (6)

385

Kurchenko, L.P. ( 8 ) 92 Kurguzova, A.M. ( 9 ) 314 K u r i h a r a , T . ( 5 ) 26, 27 K u r k i n , A.N. (51 14 K u r k u , A . ( 9 ) 313 Kuroda, S . ( 7 ) 138 Kusmierek, J . T . ( 6 ) 2 3 3 Kusnetsov, A.L. ( 1 ) 66 K u r t z , A.L. ( 7 ) 119 Kusnezova, S.A. ( 6 ) 181 K u t a t e l a d z e , T . V . ( 6 ) 95 Kutrev, G.A. ( 9 ) 135 K u t y r e v , A . A . ( 5 ) 45 K u t y r e v , G . A . ( 5 ) 136,

176

Kuwabara, M.

320

( 6 ) 284,

Kuyl-Yeheskiely,

63; ( 6 ) 27, 31

E. ( 4 )

Kuznetsova, S.Yu. ( 5 ) 12 Kvashenko, A . P . ( 8 ) 9 3 ,

95

Kvasyuk, E . I . ( 6 ) 210 Kwon, S. ( 8 ) 188, 201 K y p r , J. ( 6 ) 392

L a 5 a r r e , J.F.

( 8 ) 96, 97 99, 123; ( 9 ) 263

L a b a u d i n i e r e , L . ( 2 ) 24;

( 9 ) 105

Lacapere, J.J. ( 6 ) 355 L a c a t u s , S. ( 8 ) 128 L a F a i l l e , L. ( 8 ) 96; ( 9 )

263

L a f o n t , D. ( 1 ) 21 L a i , K. ( 9 ) 319 L a i , R . ( 7 ) 6 1 ; ( 9 ) 188 L a k e n b r i n k , M. ( 3 ) 18: ( 4 )

85

L a l l e m a n d , J.-Y. ( 6 ) 372 Lambowitz, A.M. ( 6 ) 335 L a n d g r a f , B. ( 5 ) 30 L a n d i n i , D. ( 1 ) 230; ( 9 )

305

Langen, P. ( 6 ) 97 L a n g e r b e i n s , K. ( 9 ) 26 Langlois d'Estaintot, B . ( 6 ) 388 Languin-Micas, D. ( 7 ) 98 Lanneau, G.F. ( 5 ) 40, 41; ( 9 ) 311 L a p i e n i s , G. ( 5 ) 42; ( 9 )

298

LaPlanche, L.A. ( 6 ) 199 Lappe, P . ( 1 ) 149

437

Author Index

( 1 ) 99, 235, 316, 317; ( 4 ) 89; ( 8 ) 49 L a p t e r a , L . I . ( 9 ) 132 L a r i n a , N . I . ( 8 ) 210 L a r o c k , R . C . ( 7 ) 122 L a r t e y , P.A. ( 4 ) 12: ( 6 ) 14 Lasko, D.D. ( 6 ) 276 Lasne, M.-C. ( 1 ) 85 L a s s o t a , P. ( 6 ) 53 Latharn, I . A . ( 8 ) 46 L a t i m e r , L.J.P. ( 6 ) 226 L a t s c h a , H.P. ( 1 ) 197 L a v i g n e , G . ( 1 ) 135 L a v k i n , K.D. ( 8 ) 1 2 1 , 173

L a p p e r t , M.F.

L a v r e n t ' e r , A.N.

(1)

190; ( 5 ) 9 7 , 98; ( 9 ) 40, 279 L a v r i k , 0.1. ( 6 ) 257, 258 L a v r o v a , E.E. ( 1 ) 89 Lawesson, S . O . ( 5 ) 5 4 , 174 Lawson, J . P . ( 7 ) 118 Lay, J.O., J r . ( 6 ) 276 L a z e r e t t i , P . ( 9 ) 28 Lazhko, E.I. ( 1 ) 194; ( 9 ) 107 Lebbe, T . ( 1 ) 65 Lebedev, A . V . ( 6 ) 39 Lebedev, N.N. ( 9 ) 323 Lebedev, V.A. ( 9 ) 229 Lebedeva, O.E. ( 5 ) 136 Le B i g o t , Y. ( 7 ) 17 L e b l e u , B. ( 6 ) 205, 216 LeBoeuf, R.J., Jr. ( 8 ) 21 5 Le B o t , S. ( 7 ) 61 Lechner-Knoblauch, U.

( 9 ) 240

L e c l e r q , D. ( 5 ) 41 Le Corre, M. ( 1 ) 9 6 ,

200; ( 7 ) 1 5 , 55

L e Doan, T . ( 6 ) 328 Lee, J.-G. ( 1 ) 306;

( 9 ) 177

Lee, J.S. ( 6 ) 226 Lee, M.S. ( 6 ) 279 Lee, S.-G. ( 4 ) 105 Lee, Y.C. ( 6 ) 52 . Lee, Y.E. ( 9 ) 302 L e i b n i t z , P. ( 8 ) 157 L e i g h , G.J. ( 1 ) 153,

291

L e i g h , J.G. ( 8 ) 46 L e i s s r i n g , E. ( 1 ) 9 4 ,

256

L e i v a , A . M . (1) 345 L e f e u v r e , M . ( 7 ) 44 L e f e v e r , E . ( 6 ) 88 Le F l o c ' h Y. ( 7 ) 44 Lehn, J.-M. ( 6 ) 6 1 ,

62

Lehn, T.-M. ( 6 ) 329 Lehrman, S.N. ( 6 ) 92 L e l a n d , J.K. (1) 250 L e l l o u c h e , J.D. ( 7 )

97

L e m a i t r e , M. ( 6 ) 205 L e M a r o u i l l e , J.Y. ( 1 ) 345 L e M e r r e r , Y . ( 7 ) 98 Lemrnen, P. ( 5 ) 30 Leng, M. ( 6 ) 377 L e n g y e l , P. ( 6 ) 208 Lenz, G . ( 9 ) 180 Leon, 0 . ( 6 ) 262 Leone-Bay, A. ( 7 ) 30 Leonov, A . A . ( 5 ) 141; ( 9 ) 100 L e o n t ' e v a , I.V. ( I )

227

L e q u i t t e , M. ( 5 ) 96 L e r o y , J . L . ( 6 ) 357 L e s i a k , K . ( 6 ) 207,

213, 215

L e s k e l a , M. ( 8 ) 164 L e s n i k o w s k i , Z.J. ( 6 )

23

Leung, P.H. ( 1 ) 31 Leung, W.-C. ( 6 ) 235 L e Van, D. ( 1 ) 273, 274: ( 9 ) 16 Levason, W. ( 1 ) 25 L e v i n , B.V. ( 8 ) 125 L e v i n , M.L. ( 8 ) 124 L e v i n , Ya. A . ( 9 ) 145 L e v i n a , A.S. ( 6 ) 257 L e v i n s k a y a , O.A. ( 8 )

210

( 8 ) 78; ( 9 ) 281 Levy, H.M. ( 6 ) 69 L e w i n , R . ( 1 ) 69 L e w i s , E.S. ( 4 ) 7 ; ( 5 ) 152; ( 9 ) 300 Ley, S.V. ( 5 ) 60; ( 7 ) 115 L e y e r e r , H. ( 1 ) 2 L i , B.F.L. ( 6 ) 194 L i , J . ( 7 ) 105 L i , R . ( 1 ) 34 L i , V.S. (8) 154 L i , W. ( 6 ) 273

Levites, E.I.

L i , W.S. ( 7 ) 114 L i a o , A. ( 5 ) 152 Liebrnan, P . A . ( 6 ) 2 L i g t j d , S. ( 5 ) 81; ( 9 )

117

L i g t v o e t , G.J. ( 6 ) 371 L i k h t e r o v , V . R . ( 5 ) 122 L i l l e y , D.M.J. ( 6 ) 325 L i n d , A . ( 6 ) 296 Lindermann, R . J . ( 7 ) I 1 8 L i n d h , 1 . ( 4 ) 75, 76; ( 6 )

1 2 0 , 122

L i n g Kang L i u ( 5 ) 21 L i n d n e r , E. ( 1 ) 33, 307

3 34

L i o r b e r , B.G. ( 5 ) 164 Liprnan, R . ( 6 ) 277, 278,

279

S.J. ( 1 ) 1 7 ; ( 6 ) 373 L i p p s , W . ( 1 ) 149 L i q u i e r , J . ( 6 ) 405 Lisman, J.E. ( 6 ) 2 L i s t v a n , V.N. ( 1 ) 203; ( 9 ) 148 L i t v i n o v , I . A . ( 9 ) 220 L i u , A. ( 6 ) 234 L i u , D.K. ( 6 ) 217 L i u , H.-J. ( 5 ) 24 L i u , L.K. ( 9 ) 221 L i u , R.S.H. ( 7 ) 90 L i u , X.-Y. ( 6 ) 47 L i , D. ( 5 ) 144 L i v a n t s o v , M.V. ( 1 ) 189; ( 5 ) 62 L i v i n g s t o n , D.C. ( 6 ) 201 L l ' i n , E . G . ( 8 ) 125 Lobanov, D.I. ( 2 ) 39 L o c h n e r , A . ( 9 ) 292 Lochschrnidt, S . ( 9 ) 2 3 L o d a t o , D.T. ( 6 ) 352 Loganov, A.P. ( 9 ) 116 Logunov, A.P. ( 3 ) 20 Logusch, E.W. ( 4 ) 1 1 ; ( 5 ) 57 Loh, J . - P . ( 5 ) 25 Loktionova,.R.A. ( 4 ) 38 L o n g f e l l o w , C . E . ( 4 ) 66; ( 6 ) 164 Loo, D. ( 3 ) 4 Loo, D e k a i , ( 1 ) 139 Loo, 5 . ( 5 ) 144 Lopez, F. (1) 372; ( 7 ) 52; ( 8 ) 53, 54 Lopez, L . ( 1 ) 365; ( 8 ) 1 9 L o p u s i h k s i , A. (51 9 L o r a , S . ( 8 ) 181 L o r e n z , S. ( 6 ) 304 Lowe, C.R. ( 6 ) 380 Lippard,

Organophosphorus Chemistry

438

Lo'tte, G . ( 6 ) 76 Lown, J.W. ( 6 ) 316, 388 L o w t h e r , N. (2) 14 Lu, w. ( 9 ) 85 Lu, X . ( 5 ) 6 6 , 9 3 , 154 Lucy, A.R. ( 1 ) 79 Ludernan, S.M. ( 9 ) 322 Ludwig, E.G. ( 1 ) 150 Lugan, N. ( 1 ) 135 L u g te n b u r g , J . ( 7 ) 89 L u i s , S . V . ( I ) 112; ( 7 )

33

Lukacs, A. I I I ( 8 ) 131 Lukashev, N . V . ( 1 ) 194 Lukhtanov, E.A. ( 6 ) 254 L u k i n , M.G. ( 5 ) 76 L u l y , J.R. ( 7 ) 32 L u l u ky a n , R.K. ( 5 ) 64 Lumin, S. ( 7 ) 9 9 , 101,

102

L u s s e r , M. (1) 60 L u t s e n k o , I . F . ( 1 ) 171,

189, 1 9 4 , 207; ( 4 ) 3 2 , 40; ( 5 ) 1 4 , 62 L u ts e n k o , S . V . ( 6 ) 255 Lynch, M. ( 1 ) 136 Lysek, M. ( 4 ) 94 L y u l i n a , N.V. ( 6 ) 385

Ma, L . ( 6 ) 49 Ma, L.-1. ( 6 ) 315 Maah, M.J. ( 1 ) 291,

293, 296

Maartrnann-Moe,

203

K. ( 9 )

McAtee, R.E. ( 8 ) 206 M c C a f f re y , R.R. ( 8 )

206

M c C l a r i n , J.A. ( 6 ) 407 M c C l e l l a n , J.A. (6)

325

(6) 4 5 , 4 6 , 281 Macho, C. ( 2 ) 9 M a c i e l , G.E. ( 3 ) 37 McCortney, B.A. ( 4 ) 7 ; ( 9 ) 300 McDowell, R.S. ( 9 ) 6 McEwan, D.M. ( 1 ) 130 McFarlane, W. ( 1 ) 6 7 , 124; ( 9 ) 59, 90 McGall, G.H. ( 6 ) 311 McGinn, M.A. ( 1 ) 276 MacKay, J.A. ( 8 ) 90 McKenna, C.E. ( 5 ) 105 McKernan, P.A. ( 6 ) 8,

McCloskey, J.A.

12

McLaughlan, K.A. M c Laughli n, L.W.

379

M ac Laughli n, S.A.

136

( 3 ) 26

(6)

(1)

McLennan, A.G. ( 6 ) 108 McMsnus, N.T. ( 5 ) 17 McManus, S.P. ( 1 ) 100 McPeek, F.D. 3 f . ( 6 )

41 0

( 1 ) 123: ( 3 ) 10; ( 5 ) 183: ( 9 ) 106, 201 M ac quarrie, D. J. ( 1 ) 229 McRae, G.A. ( 9 ) 142 M.addox, P.J. ( 1 ) 129 Mzding, P. ( 1 ) 87 Maekawa, T . (5) 89 M a e r k l , G. ( 9 ) 1 8 , 29, 248 Magdeeva, R.K. ( 9 ) 117 Maggiora, L. ( 6 ) 61 M a g i l l , J.H. ( 8 ) 192, 193, 196 Magnusson, E. ( 9 ) 1 Mahmood, T . ( 5 ) 3, 4 , 126 Mahmoud, S . ( 1 ) 336 Mahran, M.R. ( 7 ) 42: ( 9 ) 66 Mahran, M.R.H. ( 2 ) 22 Maia, A. ( 1 ) 230; ( 9 ) 305 M a i e r , A. ( 1 ) 172; ( 4 ) 31 M aj ews k i , P. (1) 93, 143: ( 4 ) 16: ( 5 ) 103; ( 9 ) 247 M a j o r a l , J.-P. ( 1 ) 254, 263, 286, 319, 321, 331; ( 4 ) 80, 99; ( 8 ) 4 , 5 , 1 4 , 32; ( 9 ) 37 Makarov, A.M. ( 9 ) 294 Makino, K . ( 6 ) 381 Maksimov, A.S. ( 8 ) 104, 105 Maksirnova, S . I . ( 9 ) 222 Makowka, B. ( 9 ) 26 Malavand, C. ( 8 ) 19 Malavaud, C. ( 1 ) 365 Malenko, D.M. ( 4 ) 3 8 , 39; , ( 5 ) 178 Maley, F. ( 6 ) 345 Maley, G.F. ( 6 ) 345 M al inge, J.-M. ( 6 ) 377 M a l l i s , L.M. ( 6 ) 403 M a l v i , C . ( 6 ) 173 Mamesh, R. (8) 126

MI-Phail, A.T.

Mang, M.N. ( 8 ) 122 Marchenko, A.P. ( 8 ) 28 Marco, J.A. ( 1 ) 112:

(7) 33

Marecek, J.F.

69

( 6 ) 63,

M a r g a r i d a , M. ( 6 ) 362 M z r k l , G . ( 1 ) 177, 287,

342, 356, 357, 358, 359, 367, 371 M a r k o v s k i i , L.N. ( 1 ) 72, 238, 239, 240, 241, 257, 265, 277, 300, 311; ( 2 ) 8; ( 4 ) 90; ( 8 ) 31: ( 9 ) 1 5 , 1 7 , 20, 21, 22, 25, 32, 6 5 , 6 7 , 9 1 , 94 Marks, T.J. ( 6 ) 358 Marquez, V.E. ( 6 ) 101 Mar r e- Mazier es, M.R. ( 8 ) 13 Marsh, T.L. ( 6 ) 348 M a r s h a l l , A.S. ( 8 ) 108, 198 M a r s h a l l , J.A. ( 7 ) 111 M a r s h a l l , J.H. ( 8 ) 179 M a r t h , C . ( 7 ) 11 M a r t i n , D. ( 6 ) 189 M a r t i n , J.W.L. ( 1 ) 31 M a r t i n , R.A. Jr. ( 9 ) 292 M a r t i n , S.J. ( 5 ) 87; (7) 83 M a r t in-Lomas, M. ( 1 ) 208; ( 7 ) 1 6 M a r t i n s o n , H.G. ( 6 ) 232 Marugg, J.E. ( 4 ) 6 5 , 68; ( 6 ) 123, 1 2 5 , 126, 163 Maruyama, T. ( 9 ) 207 Mar yanoff, 8. ( 9 ) 57 Maryanoff, B.E. ( 2 ) 16; ( 7 ) 1 0 , 1 2 , 13: ( 9 ) 183 M a r z i l l i , L.G. ( 6 ) 368, 369, 393, 394, 395, 396 Maslennikov, I . G . ( 1 ) 190 Maslennikova, V . I .

117

(9)

M a s o t t i , H. ( 1 ) 179 M a s t a l e r z , P. ( 5 ) 113 Mastr yukova, T.A. ( 1 )

227

Masuko, H.

88

( 5 ) 112; ( 7 )

Masuko, T . (8) 194 M a t e s i c , D. (6) 2 Matevosyan, G.L. ( 9 )

Author Index

439

277, 294 ( 1 ) 324, 325, 326, 337, 338, 345 M a t h i e s , R . A . ( 7 ) 89 M a t h i e u , R . ( 1 ) 254, 263, 286, 292 M a t h i s , R. ( 1 ) 365 Mathey, F.

M a t n i s h y a n , A.A.

(8)

103

M a t r o s o v a , N.V. ( 2 ) 39 Matsudarn A. ( 6 ) 16 Matsuda, H . ( 1 ) 216 Matsuda, I . ( 1 ) 251 Matsuda, T. ( 9 ) 285 M a t s u g i , J . ( 6 ) 132 Matsurnoto, T . ( 6 ) 381 M a t s u r a , A . ( 8 ) 216 Matsuura, T. ( 6 ) 313 M a t s u z a k i , J . ( 6 ) 133 Matt, 0 . (1) 8 Mateeva, E . D . ( 7 ) 119 M a t t e r n , G. ( 1 ) 253 M a t t e s , W.B. ( 6 ) 293 M a t t e u c c i , M.D. ( 4 ) 74:

( 6 ) 1 1 9 , 178, 1 7 9 ,

307

M a t t i o d a , G. ( 7 ) 75 M a t t i o l o , A. ( 6 ) 18 M a t t r a s , H. ( 9 ) 284 Matyushecheva, G . I .

( 2 ) 10; ( 5 ) 132

Matyushichev, I.Yu.

277

(9)

Maudgal, P.C. ( 6 ) 1 3 Mavarez, E . O . ( 1 ) 319; ( 8 ) 5 ; ( 9 ) 37 Maxam, A.M. ( 6 ) 290 Mayer, K.K. ( 1 ) 367:

M e i , H.-Y. ( 6 ) 365 M e i c h s n e r , G. ( 7 ) 34 M e i d i n e , M.F. ( 1 ) 292 Meijboom, N . ( 1 ) 69 M e i l l e , S . V . ( 8 ) 197 Meirarnov, M.G. ( 1 ) 6 M e i s e l , M. ( 8 ) 157; ( 9 )

222

M e i s t e r , J . J . ( 8 ) 174 M e j i l l a n o , M . R . ( 6 ) 81 Melamede, R . I . ( 6 ) 86 M e l ' n i c h u k , E.A. ( 1 )

196

Mel'nik,

Ya. I. ( 9 )

295 M e l ' n i k o v , N.N.

( 9 ) 118

( 5 ) 13: (9)

M e l ' n i k o v a , L.N.

4 0 , 279

Mendel, D. ( 6 ) 324 Menu, M.J. ( 1 ) 275 Menzel, J. ( 9 ) 163 M e r r i e r , F. ( 1 ) 338 M e r t e s , K.B. ( 6 ) 61 M e r t e s , M.P. ( 6 ) 9 , 61 M e t e l e r , V.G. ( 6 ) 240 Metz, J.T. ( 9 ) 12 M e t z g e r , J. ( 9 ) 188 Mestdagh, H . ( 5 ) 7 Meyer, H.J. ( 5 ) 54 Meyer, U. ( 1 ) 236,237; ( 4 ) 100; ( 9 ) 19a Meyers, A . I . ( 7 ) 118 Meyers, D.Y. ( 8 ) 198 Meyers, R . E . (4) 58;

( 6 ) 159

(9)

Mezentseva, G.A.

149

( 9 ) 29

Mhaskar, D. ( 6 ) 187 M i c h a l s k i , J . ( 4 ) 21;

( 9 ) 34

M i c h a e l i , D. ( 6 ) 218 M i c h e l i n , R . A . ( 1 ) 204 Michman, M. ( 1 ) 132, 134 M i d u r a , W . ( 5 ) 86 M i f t a k h o v , M.N. ( 1 )

Mayer, R. ( 6 ) 218 Mazany, A.M. ( 4 ) 35:

( 1 ) 331;

M a z i e r e s , M.R.

( 4 ) 99

Mazo, A.M. ( 6 ) 95 Mazzah, A . ( 8 ) 36 Meares, C.F. ( 6 ) 259,

260

Medvedeva, L.Ya.

(8)

150

Meek, T.D. ( 6 ) 67 Meerssche, M.V. ( 9 )

78

Meetsma, A.

( 9 ) 227

( 8 ) 8 6 , 91:

( 5 ) 8 , 9 , 177

168

Mikhailopulo,

210

(6)

I.A.

M i k h a i l o v , B.M.

185

M i k h a i l o v , G.Yu.

171

(9) (1)

M i k h a i l o v , Yu. 6. ( 1 )

191, 1 9 2 , 193

M e g i t z , M. ( 4 ) 96 M e h r o t r a , M.M. ( 7 )

Mikhailyuchenko, N.K.

M e h r o t r a , R.C.

M i k i , M.

103

( 5 ) 15

( 2 ) 36

( 5 ) 26, 27

h i k i , Y . ( 1 ) 288; ( 5 ) 123 M i k i t y u k , A.D. ( 5 ) 128 145 M i k o l a j c z y k , M. ( 3 ) 1 9 ( 5 ) 53, 86 M i l a s h v i l i , M.V. ( 8 ) 167 M i l c z a r e k , W. ( 1 ) 295 M i l e s , H . T . ( 6 ) 225, 388 M i l l e r , A . ( 5 ) 86 M i l l e r , D. ( 6 ) 108 M i l l e r , E.J. ( 9 ) 204 M i l l e r , P . S . ( 6 ) 203, 204 M i l l h a u s e r , G. ( 1 ) 235 M i l l s , J.S. ( 6 ) 54 Minarni, T. ( 1 ) 78, 244, 225: ( 3 ) 1: ( 5 ) 155; ( 7 ) 28, 73 M i n k w i t z , R. ( 2 ) 9 Minsek, D. ( 5 ) 152 M i n t o , F. ( 8 ) 181 M i n s h u l l , J . ( 6 ) 306 M i r s k o v , R.G. ( 1 ) 66 M i r o n o v , B.S. ( 5 ) 5 M i s h r a , R.K. ( 6 ) 148 M i s h r a , S.P. ( 9 ) 125 M i s r a , K. ( 6 ) 148 Mitorno, S. ( 9 ) 304 M i t r a n o , J.R. ( 8 ) 84 M i t r o p o l ' s k a y a , G.I. ( 8 ) 8 3 , 1 6 7 , 220 M i t s u y a , H . ( 6 ) 92 M i u r a , K . ( 6 ) 1 3 0 , 131, 1 8 6 , 193 Miyagawa, M. ( 8 ) 216, 217 Miyano, M. ( 7 ) 123 M i y a s a k i , M. ( 9 ) 12 M i y a s h i r o , H . ( 6 ) 388 Mizen, M.B. ( 2 ) 31; (4) 4 M i z h i r i t s k i i , M.D. ( 5 ) 22 M i z o b u c h i , T . ( 7 ) 22, 23 M i z r a k h , L . I . ( 2 ) 29 M k r t c h y a n , G.A. ( 1 ) 206 Modak, M.J. ( 6 ) 109, 110 Modro, T . A . ( 5 ) 34 Modyanov, N.N. ( 6 ) 255 M o e g e l i n , W . ( 9 ) 50 Moenius, T . (7) 50 M b h r i n g , V.M. (8) 62 Mohtacherni, R . ( I )

Organophosphorus Chemistry

440 132, 134

Moison, H. (7) 18 MJkhov, V.M. ( 8 ) 136 Mokva, V . V . (5) 73 Molko, D. (6) 150, 151 M o l o s t o v , V . I . (9) 4 Monoe. A . (1) 108 Monin, E.A. 91) 207; (4) >

I

4 0 ; (9) 89

Monteleone,

409

D.C (6)

4) 25 Montero, J.-L. Moody, H.M. (2) 21: ( 6 ) 24

7) 71 M 3 o r h o f f , C.M. Moors, R : ( 1 ) 343 M o r i , F . ( 6 ) 193 M o r i , S. (5) 181 M o r i i , T . (6) 313 Morirnoto, T . ( 8 ) 139, 141

Morisawa, H. (6) 302 M o r i t a , H.(7) 122 M o r i t a , Y . ( 1 ) 27 M o r i z a n e , (5) 158 M 3 r k o v n i k , Z.S. (9) 184 Morokovnik , Z S . ( 1 21 3 Miron, J.T.G. (3) 2 M o r r i s , J.C. ( 6 ) 297 Mortensen, 3. ( 7 ) 27 M o r t r e u x , A . (1) 180:

.

(4) 82

Morvan, F. (6) 173 Moskva, V . V . (1) 141;

(4) 9; (5) 45, 84; (9) 1 0 8 Mosset, P. (7) 99, 101, 102

M o t h e r w e l l , W.B. (1) 120: (2) 3 M o t o k i , H. ( 3 ) 15 M o t o k i , S. (1) 368, 369: ( 8 ) 58 Morozova, N.Yu. (9) 276 M o t s a r e v , G . V . (1) 159 Moyer, J.D. (9) 290 Mueqge, C. (1) 144; ( 9 )

170

Muehlbacher, M. (5) 6 M u e l l e r , D.M. ( 6 ) 299 M u e l l e r , E.P. ( 8 ) 20 M i l e l l e r , G. (9) 2 3 , 211 M u e l l e r , W.B. ( 8 ) 211 Mugavero, J.H. ( 6 ) 409 Mugge, C. (9) 78 M u j i c a , C . (1) 46 Mukai, S. ( 6 ) 302 Mukhametov, F.S. (2) 27;

(4) 18; (5) 120

Mukmenev, E.T.

220

Mullen, Mfiller, Muller, MGller,

(9) 218,

K . (7) 27 B.C. ( 6 ) 322 E.P. (9) 231

G. ( 1 ) 52, 53, 55, 214; ( 7 ) 5, 62, 63: ( 9 ) 186 M u l l i e z , M. (5) 18 Mulvey, R.E. (1) 10 Munson, K.B. (6) 252 MGnstedt, R . ( 8 ) 59 Murakami, A . ( 6 ) 203 M u r r a y , A.W. ( 3 ) 32 M u r r a y , J.R. (4) 14 M u r r a y , W.T. (1) 115 Musaev, S h . A . (5) 73 MlJshtakova, S.P. (9)

2

Mustaev, A . A .

255

( 6 ) 254,

( 2 ) 16; (7) 12, 13; (9) 183 Myagkova, G.I. (7) 96 Myasoedov, E.M. ( 8 113 Mylona A . (7) 134 M y n o t t , R. (1) 295 297 : ( 7 ) 66

M J t t e r , M.S..

..

Nagabhushan, T L

68

(5)

Nagahara, Y . (1) 78 Nagai, H. (4) 72, 73:

(6) 142, 143 Nagarajan,K. (9) 98 Nagasawa, K . ( 8 ) 130 Nagase, 5. ( 9 ) 165 Nagashima, N. (6) 388, 397 N e g e l , A . ( 8 ) 15 N a g e l , U. (1) 28 Naim, A.a. (1) 104 Nakacho, Y. ( 8 ) 142 Nakada, C. ( 8 ) 130 Nakahara, J.H. ( 1 ) 73, 74 Nakajima, N. (7) 108 Nakarnura, M. (7) 138 Nakamura, T . ( 6 ) 3 Nakamura, Y. (1) 27, 50 Nakane, H. (6) 94 Nakane, M. (8) 58 N a k a n i s h i , K. ( 6 )

278, 279

N a k a t a n i , K. Nakazawa, M.

(5) 158 (6) 238

Narayanan, K .

(7)

Narayanan, R .

(6)

122

411

Narayana Swamy, P.Y. ( 8 ) 89 N a r d i l l o , A.M. ( 9 )

278

N a r u l a , C. K . Nasakin, O.E.

259

(1) 152 (9)

Naser, L . J . (6) 373 Naskanaga, 1. ( 8 )

141

Nataniel, T.

(5)

Naumov, V . A .

(9) 156,

134, 135

233

Navech, J. ( 9 )

111

55,

Nazran, A.S. (9) 129 N e a l , T.R. (5) 6 Neamati-Mazraeh, N.

(1)

loo

Nechaev, A . (6) 113 Nedelec, J.Y. (1)

35

N s e l s , J. ( 8 ) 157 Naganova, E.G. (4) 32: ( 8 ) 57 N e g i s h i , K . (6) 229 Negrebetskii, V.V.

(9) 67

N e i c k e , E. ( 8 ) 51 N e i d l e i n , R. ( 9 ) 174,

175

( 8 ) 41, 42, 43, 44 N e l s o n , P.S. (6) 87 N z s t e r o v , V.Yu. (9)

N e i l s o n , R.H.

233

Neugebauer, D.

186

Neurnann,

391

(9)

J.M. ( 6 )

(1) 218; (7) 6; ( 9 ) 214 N e u m f i l l e r , B.B. (1)

N e u r n c l l e r , 8.

"() N e v i n s k y , G.A.

257, 258

Nevstad, G.O.

203

Ng. K.E. Ng. P.G.

(6) (9)

( 6 ) 60

(4) 70: (6) 119, 231, 307

Nyguyen, M . T . ( 1 ) 276 (3) 1 7 ; ( 8 ) 6, 7

441

Author Index Nquyen, T . T . ( 9 ) 232 Nichols, G.M. ( 8 ) 107 Nickell, D.G. ( 7 ) 127 Nicolaides, D.N. ( 7 ) 58 Nicolaou, K,C. ( 7 ) 114 Nicolas, J.C. ( 9 ) 284 Niecke, E. ( 1 ) 258, 260,

270, 312, 313, 314, 315, 320, 330: ( 4 ) 80, 9 1 , 9 4 , 95; ( 8 ) 1 4 , 32; ( 9 ) 1 2 3 , 161 Nielsen, 3 . ( 4 ) 4 9 , 6 4 , 6 5 , 6 8 ; ( 6 ) 123, 124, 725, 126, 127 Nielsen, P. ( 9 ) 292 Nielsen, R.H. ( 8 ) 174, 1 7 5 , 186 Niemann, B. ( I ) 339: ( 9 ) 19b Niemann, J . ( 1 ) 330- ( 9 ) 123 Nietzschmann, E. ( 1 ) 63; ( 4 ) 81 Nifant'ev, E.E. ( 4 ) 36; ( 5 ) 102; ( 9 ) 114, 1 1 7 , 299 Niitsu, T. ( 1 ) 251, 284 Nikiforova, T.P. ( 8 ) 113 Nikitin, E.V. ( 5 ) 5 Nikogosyan, L . L . ( 8 ) 103 Nikokavouras, J . ( 7 ) 134 Nikolaev, A.F. ( 8 ) 136 Nikolaev, E.G. ( 9 ) 259 Nikonov, G.N. ( 1 ) 1 4 5 , 146: ( 9 ) 71 Nikula, M.G. ( 1 ) 221 Nisbet, E.G. ( 6 ) 341 Nishihara, T. ( 6 ) 302 Nishii, K . ( 8 ) 216, 217 Nishimura, S . ( 6 ) 193, 286 Nishimura, Y . ( 6 ) 388, 397 Nishiuchi, K. ( 8 ) 139 Nishiyama, S. ( 7 ) 126 Nitta, M. ( 8 ) 52, 155 Nitta, Y . ( 5 ) 29

Niwa, H. ( 7 ) 130 Niwas, S. ( 6 ) 11 Nixon, O.A. ( 4 ) 4 Nixon, J . F . ( 1 ) 291,

292, 293, 296, 294: ( 9 ) 16 Nizamov, I . S . ( 1 ) 1 7 8 , 159; ( 4 ) 19 N3be1, D. ( 1 ) 8 Nobori, T . ( 4 ) 60; ( 6 ) 7 , 177 Noeth, H. ( 9 ) 176 Nogami, I . ( 8 ) 132 Noltemeyer, M. ( 2 ) 34

( 8 ) 26, 156

Noltmeyer, V.A. ( 9 ) 232 Nomura, R . ( 1 ) 78 Nonaka, T. ( 1 ) 7 Norbeck, D.W. ( 4 ) 1 2 ; (6) 14

Nord, L.D. ( 6 ) 8 NDrddn, B. ( 6 ) 366 Norman, A.D. ( 4 ) 4 2 , 43; ( 9 ) 636, 179

Norman, N.C. ( 1 ) 233,

248, 250, 327; ( 4 ) 101 Normant, J.F. ( 5 ) 117 Normsnton, F . B . ( 1 ) 153 Nortey, S.O. ( 7 ) 1 3 NEth, H. ( 1 ) 1 5 2 , 305;

( 3 ) za Nouvel, J. ( 1 ) 97 N3vikova, T.I. ( 8 ) 8 3 Novikova, Z.S. ( 1 ) 207: ( 4 ) 32, 40: ( 5 ) 14: ( 9 ) 89 Novruzov, S.A. ( 5 ) 73 Nowell, I.W. ( 9 ) 53 NcJyori, R . (4) 6 0 ; ( 6 ) 7 , 1 2 8 , 1 4 7 , 177 Nozaki, T. ( 1 ) 216 Nozaki, Y . ( 6 ) 317 Nuber, B. ( 1 ) 287, 342 ( 9 ) 18 Nuretdinova, O.N. ( 9 ) 140 Nussbaurn, S . ( 1 ) 132

Oakley, R . T .

(8) 146, 1 4 8 , 222; ( 9 ) 130

Ojayashi, A. ( 6 ) 238 Ojerhammer, H. ( 1 ) 274; ( 2 ) 9

Ocando-Mavarez, E . ( 1 )

320, 321; ( 4 ) 80 O'Connor, B. ( 7 ) 120 Odreman, A . ( 9 ) 188 Oeberg, 6. ( 6 ) 37 Oesterhelt, D. ( 7 ) 92 Offermann, W. ( 9 ) 64 Ogasawara, M. ( 6 ) 9 4 Ogawa, K . ( 9 ) 207 Ogilvie, K . K . ( 1 ) 183: ( 4 ) 79; ( 6 ) 20, 152, 167 Ohannesian, L . ( 1 ) 88 Ohashi, M. ( 8 ) 143 Onashi, 0 . ( 9 ) 1 6 Ohkata, K . ( 2 ) 32; ( 3 ) 25 Ohms, G. ( 8 ) 37 Ohshima, M. ( 3 ) 39

Ohtsuka, E. ( 6 ) 130,

131, 1 3 2 , 1 6 1 , 171 186, 193, 301, 302 Oikawa, Y. ( 7 ) 106, 1 0 7 , 108 Oishi, H . ( 9 ) 207 Ojima, J . ( 7 ) 138 Okada, K . ( 2 ) 32; ( 3 ) 25 Okada, Y . ( 1 ) 78 Okamaoto, K . ( 8 ) 137 Okamoto, Y . ( 1 ) 284; ( 5 ) 1 2 5 , 142, 143 Okeya, S. ( 1 ) 50 Okruszek, A. ( 6 ) 21 Olah, G.A. ( 1 ) 88 Olenia, V.F. ( 8 ) 78 Olina, V.F. ( 9 ) 281 Oliveiri, M.C. ( 6 ) 57 Oliveros, L . ( 9 ) 282 Olmstead, M.M. ( 1 ) 164, 303; ( 9 ) 182 Ologson, R.A. ( 2 ) 1 6 ; ( 7 ) 12: ( 9 ) 183 Olomucki, A . ( 6 ) 1 9 Olomucki, M. ( 6 ) 19 Olsen, G.J. ( 6 ) 348 Olsen, J . I . ( 6 ) 52 O'Mahony, M.J. ( 7 ) 117 Ong, C.-W. ( 6 ) 316 Ono, A. ( 6 ) 183, 1 8 5 Ono, K . ( 6 ) 9 4 Orahovats, A.S. ( 5 ) 751 Oram D.E. ( 1 ) 57, 58 O'Regan, M.B. ( 8 ) 6

Oretskaya,-T.S. ( 6 ) 162, 240

Orezkaja, T.S. ( 6 ) 181

Orgel, L.E.

( 6 ) 60, 219, 220, 222, 223 266 Orlova, I.E. ( 8 ) 106 Orpen, A.G. ( 1 ) 327 Ortiz, J . ( 1 ) 235 Osapay, G. ( 5 ) 58 Oscando-Marevez, E. ( 8 ) 1 4 , 32 Oshikawa, T . ( 1 ) 163; (3) 9 Oshima, K . ( 1 ) 201 Osipova, T . I . ( 6 ) 105

Otroshchenko, V.A. ( 6 ) 347

Otter, A. ( 6 ) 388 Ottolenghi, M. ( 7 ) 91

442 O t v E s , L . ( 6 4 8 , 227 OJzounis, D . ( 1 ) 37 Ovakirnyan, M Z . ( 1 ) 105 Ovasapyan, L A. ( 8 ) 103 Ovchinnikov, V.V. ( 5 ) 95; ( 9 ) 266 O,dchinnikov, Y u . A . ( 6 ) 138, 255 O v r u t s k i i , D.G. ( 5 ) 45 O v r u t s k i i , V.M. ( 5 ) 47; ( 9 ) 270 Ovsepyan, S . a . ( 5 ) 64 Owens, G . F . ( 6 ) 217 Owens, J . R . ( 6 ) 247 Oyamada, Y . ( 8 ) 58 Ozaki, H . ( 6 ) 381 Ozaki, K . ( 6 ) 30 O z t a s , S . ( 8 ) 79

Paasch, J . ( 8 ) 38 Pace, B. ( 6 ) 348 Pace, N.R. ( 6 ) 348 P a c i o r e k , K . J . L . ( 1 ) 73, 74 P a g n i e z , G . ( 8 ) 169 P a i l o u s , N. ( 9 ) 143 P a i n e , R . T . ( 1 ) 152, 305; ( 9 ) 176 P a k u l s k i , M. ( 1 ) 248, 250, 306, 327, 328: ( 4 ) 101, 103; ( 9 ) 7 3 , 177 P a l , 8.C. ( 6 ) 91 P a l a , M. ( 8 ) 35 P a l a c i o s , F. ( 1 ) 372; ( 7 ) 52: ( 8 ) 5 3 , 54 P a l e c e k , E . ( 6 ) 325 P a l k i n a , K . K . ( 9 ) 222 Palurnbo, G. ( 1 ) 116 Pandey, V. ( 6 ) 110 Pandey, V.N. ( 6 ) 109 P a n e t h , P . ( 9 ) 261 P a n k r a t o v , A.N. ( 9 ) 2 Panosyan, G.A. ( 5 ) 6 4 , 169 Panov, A . M . ( 9 ) 154 Panova, L . A . ( 9 ) 279 P a o l e t t i , C . ( 6 ) 173 P a o l e t t i , J . ( 6 ) 173 Papahatjis, D.P. ( 7 ) 114 P a r a k i n , O.V. ( 5 ) 5 Paramonov, V.I. 158 P a r a r v e z , M. ( 8 ) 8 5 P a r k , J . S . ( 7 ) 81 P a r k e r , J . A . ( 8 ) 135 P a r k e s , H.G. ( 8 ) 7 1 , 72, 73, 74, 7 5 , 1 0 9 , 111, 112; ( 9 ) 46, 56, 9 2 ,

Organophosphorus Chemistry

224, 225, 226 P a r k i n , D.W. ( 6 ) 41 Parrnar, 5.5. ( 3 ) 22 P a r r a t t , M.J. ( 5 ) 8 7 , 88, 156; ( 7 ) 8 3 , 89, 85 P a r r i n e l l o , G . ( 1 ) 20 P a r t y n o v , I.V. ( 5 ) 150 P a r v e z , M. ( 8 ) 118, 120, 121: ( 9 ) 215, 216, 21 7 Pashkovich, K . I . (5) 137: ( 9 ) 213 P a s q u a l i n i , R . ( 1 ) 202: (3) 2 Pastushenko, E.V. ( 9 ) 326 P a t h a k , T. ( 5 ) 30; ( 6 ) 36 P a t s a n o v s k i i , 1.1. ( 3 ) 23; ( 9 ) 234, 235, 237 P a u l e n , W. ( 9 ) 69 P a u l s , H. ( 6 ) 83 P a u l y , G.T. ( 6 ) 89 P a v e l , G.V. ( 5 ’ 118 Pavlenko, N.V. ( 2 ) 10. ( 5 ) 132 Pavlov, B . A . ( 5 ) 164 P a v l o v a , S.S.A. ( 8 ) 165 Pawlak, J . ( 6 ) 278 P a y a r d , M. ( 9 ) 25 Pechkovskii, V.V. ( 8 ) 22 1 P e c o r a r o , V . L . ( 6 ) 82 P e d e r s e n , U. ( 9 ) 287 P z d u l l i , G.F. ( 9 ) 129 P e i f f e r , G . ( 1 ) 179 P e i s a c h , J , ( 6 ) 312 P e l c z e r , I . ( 9 ) 77 P e l l e r i n , B. ( 1 ) 255 P e l l o n , P. ( 1 ) 165, 264 P e l t i g r e w , F.A. ( 8 ) 212 Penczek, S . ( 5 ) 42 Penning, T.W. ( 9 ) 75 P e n n i n g s , Y . ( 4 ) 78 P e n s i o n e r o v a , G A. ( 5 ) 71 P e n t o n , H.R. ( 8 ) 162, 212 P e r e i r a , M.E. ( 6 ) 58 P a r i c h , J.W. ( 4 ) 52, 59 P e r i c h o n , J . ( 1 ) 35 P e r i n g e r , P . ( 1 ) 60; ( 8 ) 20: ( 9 ) 231 P e r k i n s , K.K. ( 6 ) 334 P e r l y , 8. ( 8 ) 97 P e r r i n , P . ( 7 ) 97 P e r r o c h e a u , J . ( 1 ) 255 P e r r o u a u l t , L. ( 6 ) 328 P e r u z z i n i , M. ( 1 ) 335 P e s c h e r , P . ( 9 ) 282 P e t e r , R . ( 5 ) 148; ( 7 ) 80

.

P e t e r s , K . ( 8 ) 21; ( 9 ) 191 P e t i t , F. ( 1 ) 180; ( 4 ) 82 Petnehazy, I . ( 4 ) 15 P e t r a k i s , K.S. ( 5 ) 68 P e t r e n k o , V.S. ( 8 ) 24 Petrov, A.A. ( 1 ) 166, 167, 170: ( 5 ) 7 5 , 7 6 , 150 162; ( 9 ) 100 Petrov, K.A. ( 5 ) 55 P e t r o v a , J . ( 9 ) 79 Petrovskii, P.I. ( 5 ) 168 Petrovskii, P.V. ( 1 ) 105, 227: ( 2 ) 39- ( 5 ) 28; ( 8 ) 166 P e t r u s k a , J. ( 6 ) 1 8 7 , 196 P e t r z e b o w s k i , M. (5) 9 P e t t e r , W . ( 8 ) 20; ( 9 ) 231 P e z z i n , G . ( 8 ) 181 Pfeiffer, G. (4) 82 Pflaurn, S. ( 1 ) 358 359 P f l e i d e r e r , W. ( 6 ) 210, 211 Pharn, T.N. ( 1 ) 11 P h i l l i p s , D.R. ( 6 ) 330 P h i l l i p s , L.R. ( 4 ) 71: ( 6 ) 200, 399 P h i l l i p s o n , D.W. ( 6 ) 45, 4 6 , 281 Piccinni-Leopardi, C. (1) 144; ( 9 ) 7 8 , 170 P i c h l , R . ( 1 ) 214; ( 7 ) 5 , 6 2 , 63: ( 9 ) 211 P i c k , L. ( 6 ) 344 P i r k e n , D.J. ( 6 ) 136 P i e r r o t , M. ( 7 ) 61; ( 9 ) 188 P i e t r u s i e w i c z , K.M. (7) 70 Pinchuk, A.M. ( 8 ) 28; ( 9 ) 209 Pingoud, A . ( 6 ) 263

443

Author Index

P i n t o , A.L. ( 6 ) 373 P i n t o , R.M. ( 6 ) 107 P i o n t e c k , J . ( 4 ) 104 P l a t o n o v , V . A . ( 9 ) 276 P l a t t n e r , 5 . 3 . ( 7 ) 32 P l a t z e r , N. ( 9 ) 58 P l e n i o , H. ( 8 ) 27 P l e s s , R.C. ( 6 ) 294 P l y a m o v a t y i , A.Kh. ( 9 )

9

P l y s h e v s k i i , S . V . ( 8 ) 221 Podda, G . ( 8 ) 110 Podkopaeva, T.L. ( 6 ) 210 Podust, V.N. ( 6 ) 257, 258 P o e c h l a u e r, P . ( 8 ) 20:

( 9 ) 231

P o e t z s c h , M. ( 8 ) 220 P o g a t z k i , V . W . ( 2 ) 34:

( 9 ) 232

Pogosyan, A . A . ( 8 ) 103 P o h l , S. ( 1 ) 217, 314;

( 4 ) 91

P o ka tu n , V.P. ( 5 ) 56 Pokrovskaya, E.N. ( 8 )

113, 133

Pokrovskaya,

169

I.K.

(1)

(5) 164; ( 5 ) 130: ( 9 ) 274 P o l i s s i o u , M. ( 6 ) 356 P o l l o k , T . ( 1 ) 182; ( 3 ) 3 ; ( 4 ) 37 P o l o n s k a y a , L . Yu. ( 2 ) 29 P o l o zo v , A.M. ( 5 ) 130, 164 P o l u s h i n , N.N. ( 6 ) 138 Polezhaeva, N.A.

Polyachenko, L .K.

257; ( 9 ) 1 7 , 25 Pon, R . T . ( 6 ) 152

( 1)

Pomerantz, M. ( 8 ) 8, 9 Popkova, T.N. ( 5 ) 102 Poponova, R . V . ( 9 ) 124 Popova, G . V . ( 8 ) 102 Porkhun, V . I . ( 9 ) 124 Poromarchuk, M.P. ( 8 ) 25 P o r t e , A.L. ( 8 ) 70; ( 9 )

120

P o r t e r , T.M. ( 5 ) 69 P o r z , C. ( 1 ) 269; ( 9 )

157

Porzo, W. ( 8 ) Potaman, V.N. Potapov, V.K. P o t i n , P. ( 8 ) P o t t e r , B.V.L.

197 (6) 43 ( 6 ) 240 169 ( 4 ) 28; ( 6 ) 2 2 , 34, 74 P o u l t e r , C.D. ( 5 ) 6 ; ( 6 ) 59 P o v o l o t s k i i , M.I. ( 1 )

241, 257, 271: ( 4 ) 90; ( 9 ) 1 7 , 25 P o w e l l , C . ( 6 ) 1 9 9 , 202 Power, J.M. ( 1 ) 5 9 , 306: ( 9 ) 177 Power, P.P. ( 1 ) 164, 303, 304; ( 9 ) 182 P r a c e j u s , G. ( 1 ) 181; ( 4 ) 84 P r a c e j u s , H. ( 1 ) 181: ( 4 ) 84 P r a t i , L . ( 4 ) 83 P r e s c h e r , G. ( 1 ) 28 P r e s t w i c h , G . D . ( 7 ) 121 P r e v i e r o , A . ( 9 ) 284 P r i d a n , V . E . ( 9 ) 146 P r i e t o , A . ( 9 ) 141 P r i h o d a , J . ( 5 ) 44 P r i j s , 6. ( 6 ) 360 P r i k h o d ' k o , Yu.V. ( 5 ) 118 P r i n g l e , P.G. ( 1 ) 137: ( 3 ) 38 P r i s h c h e n k o , A.A. ( 1 ) 189; ( 5 ) 62 P r i v i h a d a , J . ( 8 ) 37 P r o j a n , S.L. ( 6 ) 312 P r o k l i n a , N.V. ( 5 ) 119 P r o k o f ' e v , A.I. ( 9 ) 127 P roc k op, D.J. ( 6 ) 241 P r o s k u r n i n a , M.V. ( 9 ) 326 P r o t s , 0.1. ( 9 ) 295 P r o t s e n k o , L.D. ( 5 ) 47 P r o z i o , W. ( 8 ) 187 P r u d n i k o v a , O . G . ( 5 ) 150 P s c h e i d t , R.H. ( 6 ) 267 P udov ik , A.N. ( 1 ) 169, 1 7 8 , 1 9 1 , 192, 193, 199; (2) 25, 35, 37; ( 4 ) 5 . 6 . 8. 19. 23: ( 5 ) 2; 5 ; 50, 51, 52, 94, 95, 136, 159, 176, 1 8 0 , 184; ( 8 ) 153: ( 9 ) 7 2 , 119, 234, 235, 303 P udov ik , M.A.

153

( 2 ) 37: ( 8 )

P u e r t a , C . ( 1 ) 108 P u g n i e r e , M. ( 9 ) 284 P u l w e r , M.J. ( 4 ) 26 Purdon, J.G. ( 9 ) 39 P u r y g i n , P.P. ( 6 ) 105

O i , Y. ( 4 ) 1 7 ; ( 5 ) 108, 109 Quashie, S . ( 1 ) 279

( 7 ) 34: ( 9 ) 83 Qui, M. ( 6 ) 273 Qui, W . ( 1 ) 226: ( 7 ) 4 7 , 48 Quin, L . D . ( 1 ) 8 1 , 8 2 , 1 2 2 , 123, 157, 1 7 5 , 176; ( 3 ) 1 0 , 1 1 , 74, 24: ( 4 ) 4 7 , 48: ( 5 ) 183; ( 8 ) 18: ( 9 ) 33, 9 5 , 9 9 , 106, 1 1 3 , 201 O u i n l a n , B.A. ( 5 ) 17 Quast. H.

Rabanol, R.M. ( 1 ) 208 Rabow, L.E. ( 6 ) 310,

311, 314

Radda, G.K. ( 6 ) 398 R a d e g l i a , R . ( 8 ) 10:

( 9 ) 38

Rademacher, P. ( 1 ) 260 Rae, A.D. ( 1 ) 14 R a e v s k i i , O.A. ( 9 )

137, 209, 210

R a f t o s , J.E. ( 9 ) 14 R a h i l , J . ( 5 ) 172 R a i , A.K. ( 1 ) 316: ( 4 ) 89 R a k h l i n , V . I . ( 1 ) 66 Rakhmankulov, D.L. Ramachandran, K.L. ( 6 )

158

Ramirez, F. ( 6 ) 69 Rampoldi, A , ( 9 ) 305 R a n a i v o n j a t o v o , H. ( 1 )

298: ( 9 ) 19c

R a n d a l l , S.K. ( 6 ) 196 R ankin, D.W.H. ( 1 )

186 ( T ) 123: ( 3 ) 10; ( 9 ) 106 Rao, P.Y. ( 6 ) 233 Rao, R.J. ( 5 ) 1 5 Raphael, A.L. ( 6 ) 322 Rasch, 0 . ( 6 ) 40 R askina, A.D. ( 1 ) 159 Rasmussen, J.K. ( 3 ) 36 Raston, C.L. ( 1 ) 9 R a t o v s k i i , G.V. ( 9 ) 154 Rau, D.N. ( 2 ) 5 Rauchfuss, T.B. ( 1 ) , 310; ( 5 ) 175 Rauschenbach, P. ( 9 ) 292 Raushel, F.M. ( 6 ) 72, 40 3 Rao, N.S.

444

Organophosphorus Chemistry

Ra:iert, H . T ( 1 ) 205 Rawal, V.H. ( 7 ) 135 Rawls, R.H. ( 8 ) 215 Rayner, B. 6 ) 173 Read, G. ( 1 'I25 Reddy, M.P. ( 6 ) 203, 204 9 ) 200 R e d i t z , M. Redmore, D. ( 5 ) 31 Reed, D : ( 1 ) 10 Reed, G.H. ( 6 ) 352 R e e d i j k , J . ( 6 ) 371 Reese, C . B . ( 4 ) 30: ( 6 )

135, 194

Reetz, M.T.

80

Regan, J.B.

( 5 ) 148: ( 7 )

( 4 ) 71; ( 6 ) 200: ( 9 ) 322 Regberg, T . ( 1 ) 114; ( 4 ) 7 5 , 76; ( 6 ) 26, 120, 1 2 1 , 122 R e g i t z , M. ( 1 ) 242, 289, 295, 297, 308, 309, 366 R e i ch , C . ( 6 ) 348 Reid, R.S. ( 6 ) 226 R e i k h s f e l ' d , V.O. ( 5 ) 22 R e i l y , M.D. ( 6 ) 368, 369 Reimschussel, W. ( 9 ) 261 Reineke, K.E. ( 1 ) 64 R e i s f e l d , A . ( 6 ) 264 R e i sn e r, H. ( 6 ) 374 R e i ss e , J . ( 9 ) 78 R e i t z , A.B. ( 2 ) 16: ( 7 ) 1 0 , 1 2 , 13; ( 9 ) 5 7 , 183 R e i z i g , K . ( 1 ) 243, 245, 247, 281 Remy, P.M. ( 6 ) 108 Repina, L . A . ( 4 ) 38 Revenko, G.P. ( 3 ) 20 Revet, B. ( 6 ) 415 R h e i n g o l d , A. ( 1 ) 223: ( 7 ) 46 R h e i n o o l d . A . L . ( 8 ) 35: ( 9 i 204 Richter, H. 9 ) 178 R i c h t e r , W.J ( 9 ) 98 R i d e o u t , J.L ( 6 ) 92 R i d i n g , G.H. ( 8 ) 6 5 , 1 2 0 , 120, 122, 173: ( 9 ) 217 R i d l e y , D.D. ( 9 ) 47 Riede, J. (1 52 Riemer, M. ( 1 ) 94 R i e s e l , L. ( 5 ) 48; ( 8 ) 11, 12, 15 R i e s s , J.G. ( 2 ) 33; ( 9 ) 275 R i f f e l , H. ( 1 ) 218, 290; ( 9 ) 169, 1 7 8 , 200, 214

R i n g e l , I . ( 4 ) 24 R i p o l l , J . - L . ( 1 ) 85 R i v e r o , R.A. ( 1 ) 121 Robbins, J . H . ( 6 ) 288 R o b e r t , J.B. ( 9 ) 78 Roberts , R.J. ( 6 ) 344 Roberts , R.M.G. ( 1 ) 344,

346, 347, 348, 349, 350, 351, 352 Roberts on, A.D. ( 1 ) 340 Robins, M.J. ( 6 ) 99 Robins, R.K. ( 6 ) 8, 12 Robinson, N.G. ( 7 ) 54 Robinson, P.L. ( 2 ) 1 3 Robinson, P.R. ( 6 ) 2 Rochev, V.Ya. ( 8 ) 167 Rodionova, G.N. ( 9 ) 149 Roesch, W. ( 9 ) 31 Roes c henthal er, G . V . ( 9 ) 52, 6 4 , 230 Roesky, H.W. ( 2 ) 34; ( 8 ) 27, 47, 156, 158, 159: ( 9 ) 232 Rogers, M.D. ( 5 ) 121 Rohmann, J. ( 2 ) 9 Rolande, C. ( 5 ) 7 R o l ' n i k , L.Z. ( 9 ) 326 Romakhin, A.S. ( 5 ) 5 Roman, E. ( 1 ) 345 Romanenko, V.D. ( 1 ) 238, 239, 240, 241, 257, 265, 277, 300, 311: ( 4 ) 9 0 , 9 2 , 93: ( 8 ) 31; ( 9 ) 1 5 , 1 7 , 20, 21, 22, 9 4 , 166 Romanov, G . V . ( 5 ) 5 Romming, C . ( 9 1 203 R o n j a t , M. ( 6 ) 355 Roongta, V . ( 9 ) 12 Roques, B.P. ( 6 ) 388 Roques, C. ( 1 ) 331: ( 4 ) 99 Rosch, P . ( 6 ) 384 Rasch, W. ( 1 ) 289, 295, 366 Ros c henthal er , G. - V . ( 1 ) 142 Rose, H. ( 9 ) 92 Rose, S.H. ( 8 ) 107 Rosenberg, I . ( 6 ) 1 3 Rosenberg, J.M. ( 6 ) 407 Rosendahl, M.S. ( 6 ) 180 R o s e n t h a l , A . ( 6 ) 181 Ross, P. ( 6 ) 278 Ros s et, R . ( 3 ) 7; ( 9 ) 282, 286 R o s s i , R.A. ( 1 ) 1 3 Rostovskaya, M.F. ( 1 ) 71: ( 3 ) 13; ( 9 ) 250 Roth, A. ( 5 ) 114

(6)

Rothenberg, J.M.

264

R o u n d h i l l , D.M. ( 1 ) 5 ROUS, A. ( 5 ) 11 ROUS, A.J. ( 9 ) 45 R oussis, V . ( 7 ) 77 Roy, A.K. ( 1 ) 118; ( 8 )

4 1 , 1 7 4 , 175, 186

R oynal, S. ( 9 ) 58 Rozhnov, V.B. ( 9 ) 116 R ozinov, V.G. ( 5 ) 71,

7 2 , 74

Rozozina, I . N . ( 9 ) 144 Ruban, A . V . ( 7 ) 241,

257, 300, 311; ( 4 ) 93; ( 8 ) 31: ( 9 ) 1 7 , 21, 25 Rubio, V. ( 6 ) 66 R udyi, R.B. ( 9 ) 67 RGger, C . ( 4 ) 104 Rumyantseva,

125

Rusch, J.W.

277

Z.G.

(8)

( 8 ) 91:

(9)

R u s s e l l , D.H. ( 6 ) 403 R u s s e l l , D.R. ( 9 ) 192 R u s s e l l , G.A. ( 1 ) 12 R u t t . J.S. ( 8 ) 85; ( 9 )

21 5

Ruzanov, I . A . ( 8 ) 150 Ryabokobylko, Yu.S. ( 9 )

124

Ryabov, B . V . ( 5 ) 163 Rybakov, V.N. ( 6 ) 197 R ybkina, V.V. ( 5 ) 72 R y c r o f t , D.S. ( 8 ) 7 5 -

( 9 ) 9 2 , 224

R y l ' t s e v , E.V. Rymareva, T . G . R yte, A.S. ( 6 ) R yte, V.C. ( 6 )

Saak, W.

( 4 ) 91

( 9 ) 134 ( 5 ) 147 253 39

( 1 ) 217, 314;

S a a l f r a n k , R.W. ( 8 ) 21 S a a l f r a n k , W.R. ( 9 ) 191 Sabatino, P . ( 1 ) 204 Sachs, W. ( 1 ) 260 Sadykov, A.R. ( 5 ) 50 Sadykov, T.S. ( 4 ) 10;

( 5 ) 61

Saegusa, T . Saenger, W. Safiullina, 136; ( 9 ) Sagan, B.L. Sagar, R.V.

( 1 ) 232

( 6 ) 404 N.R. ( 5 )

135 ( 6 ) 383 ( 8 ) 172

Author Index

S n g i , J . ( 6 ) 227 Sagstuen, E. ( 9 ) 131 S t . C l a i r , M.H. ( 6 ) 92 S a i n z - D i a z , C . I . ( 9 ) 109 S a i t o , I . ( 6 ) 313 S a i t o , S . ( 1 ) 27 S a i t o , T . (8) 58 Sakamoto, N. ( 8 ) 137 Sakaya, T . ( I ) 232 Saks, V.A. ( 6 ) 385 S a k u r i , K . ( 7 ) 112 Salem, G . 9 1 ) 90 S a l i y a , H.K. ( 3 ) 22 S a l z e r , A. ( 4 ) 13 Sarnaha, M. ( 9 ) 313 Samanta, H. ( 6 ) 208 Sampson, P . ( 5 ) 70: ( 7 )

77

Samukov, V . V . ( 6 ) 39 Sancar, A . ( 6 ) 274,

275

Sanchez, M.

( 1 ) 254, 331; ( 4 ) 99: (8) 1 3 , 123 Sandakov, V.B. ( 5 ) 147 S a n d a l i , C . ( 4 ) 46 Sandberg, A . S . ( 9 ) 289 Sandstrom, A . ( 6 ) 402 Saneyoshi, M. ( 6 ) 94 Sangokoya, S.A. ( 1 ) 124 S a n t a n i e l l o , E. ( 1 ) 140 Santo, K . ( 5 ) 27 Santos, J.G. ( 1 ) 107; ( 9 ) 301 Sappa, E . ( 1 ) 136 S a r i n , P.S. ( 6 ) 206 S a r k a r , A.B. ( 5 ) 17 Sarkou, A . B . ( 5 ) 16 Sarngadharan, M.G. ( 6 ) 93 S a r r o f f , A. ( 1 ) 14 S a r t o r e l l i , A.C. ( 6 ) 41 1 S a sa ki , M. (5) 131; ( 9 ) 283 Sasakura, T . (8) 213, 214 Sassus, J.L. (8) 98 S a ta v, J.G. ( 6 ) 109 Satge, J . ( 1 ) 298, 301, 302; ( 9 ) 19c S a t o , F . ( 6 ) 284 Sato, H. ( 7 ) 4 S a t o , K . (8) 194 S a to , R . ( 6 ) 172 Sato, T . ( 1 ) 251; ( 5 ) 167 Sato, Y . ( 9 ) 207 Satoh, K . ( 7 ) 112 Sau, A.C. ( 2 ) 6

445

S a u e r h i e r , W. ( 6 ) 308 S a v a l ' y a n o v , V.P. ( 9 ) 3 2 3 Savignac, P . ( 5 ) 7 7 , 7 9 ,

80, 8 1 , 8 2 , 153: ( 7 ) 72 S av i gnac , Ph. ( 7 ) 7 9 : (9) 117 S awadai s hi , K . ( 6 ) 130 Sawai, K . ( 6 ) 94 Sayadyan, S.V. ( 1 ) 6 8 , 91 S c alz o-B rus h, T . ( 6 ) 353 Scamrov, A.V. (6)95 Scarborough, G.A. ( 6 ) 65 S c haefer, H.F. ( 1 ) 234 S c h a e f f e r , A.H. ( 4 ) 63: ( 6 ) 31 S c h z f e r , H. ( 1 ) 252, 253 S z h a f e r , H.-G. ( 1 ) 314, 3 30 S c h a l l e r , W . ( 6 ) 374 Scheide, G.M. (8) 175 S c h e i n e r , A . C . (1) 234 S c h e l l e r , K.H. ( 6 ) 360 Scheller-Krattiger,

v.

( 6 ) 360 Schenk, R . ( 7 ) 27 S c herer, D.J. ( 1 ) 318, 353- (8) 50 S c h e v a l i e r , M. (8) 146 Schlichtling, I. (6) 384 S c h l o v e r , V.E. ( 9 ) 195 Schmidbaur, H. ( 1 ) 1 6 , 1 8 2 , 214: ( 3 ) 3: ( 4 ) 37; ( 7 ) 5 , 6 2 , 6 3 , 6 4 ; ( 9 ) 1 8 6 , 211 S c hm i dpeter, A. ( 1 ) 188, 360, 361, 364; ( 4 ) 3 , 8 6 , 8 7 , 88; (8) 30, 1 5 1 , 152: ( 9 ) 2 3 , 30 167Schmidt, H. ( I ) 3, 256 Schmidt, H.G. (2) 34: ( 9 )

232 Schmidt, M. ( 7 ) 39, 40 Schmidt, S.P. ( 1 ) 113 S c hm utz l er, R . ( 1 ) 142, 173, 187; ( 2 ) 23: ( 4 )

27; ( 9 ) 181, 212

S c h n a t t e r e r , S . ( I ) 16 S c hneider, D.F. ( 7 ) 71 S c hneiders , H. ( 9 ) 198

Schneiderwind-St~cklein, R . ( 5 ) 30

S c hngc k el , H.

( 4 ) 85

( 3 ) 18;

(1) 314, 330; ( 4 ) 91; ( 9 ) 123 S c h G l l k o p f , U. ( 5 ) 111 S c holz , U. (8) 47

Schoeller, W.W.

Schomburg, D. ( I ) 1 7 3 ,

787: ( 4 ) 27; ( 9 ) 5 2 , 1 8 1 , 212, 230 Schgn, A. ( 6 ) 4 Schoner, W. ( 6 ) 8 3 Schramm, V . ( 7 ) 45: ( 9 ) 190 Schramm, V . L . ( 6 ) 41 S c h r e i b e r , E.P. (8) 202 Schr oeder , S.A. ( 9 ) 12 Schuber t, F. ( 6 ) 181 Schuck, R . ( 9 ) 76 Schuhn, W. ( 1 ) 285: ( 9 ) 1 9 6 , 160 S c h u l h o f , J . C . ( 6 ) 150, 151 Schulman, L.H. ( 6 ) 262 Schulze, 3. ( 9 ) 16 Schumann, H. ( 1 ) 132, 134; ( 9 ) 42 Schunck, S. ( 3 ) 18: ( 4 ) 85 S c h u s t e r , S.M. ( 6 ) 8 5 , 86 Schu'tze, R . ( 5 ) 111 Schwager, C . ( 6 ) 298 Schw ar tz, A . W . ( 6 ) 104 Schwarz, R . ( 5 ) 30 Schwartze, P . ( 3 ) 31 Schweizer, E . E .

(1)

Semenii, V.Ya.

(2)

223; ( 7 ) 46 Schweizer, M.P. ( 6 ) 52 S c h e p l e r , D. ( 6 ) 9 Schwesinger, R . (8) 33; ( 9 ) 267 Schwetlick, K . (4) 104 Scopelianos, A . G . (8) 168 S c o t t , E.V. ( 6 ) 396 S c o t t , S.L. (8) 148 Seega, J . ( 1 ) 161, 162; (5) 138; ( 9 ) 76: 197, 198 S e e l , F . ( 9 ) 193 Seela, F . ( 4 ) 57: ( 6 ) 33, 191, 196 Seeley, A . ( 9 ) 102 Seeman, N.C. ( 6 ) 188 Sejpka, H. ( 1 ) 287; ( 9 ) 18 Sekine, M. ( 4 ) 67, 7 2 , 73; ( 6 ) 30, 133, 134, 1 3 9 , 140, 141, 1 4 2 , 1 4 3 , 149, 170 S e l i g e r , ti. ( 6 ) 118 Sell, M . ( 1 ) 173

446

1 9 : (5) 132 Semple, G . ( 5 ) 157 Sendyorev, M . V . ( 1 ) 1 6 6 , 1 6 7 , 170 S m e l t , S . ( 9 ) 297 Sengokoya, S . A . ( 9 ) 59 Seno, M. ( 9 ) 304 Seppala, E. (8) 164 Sera, A. ( 9 ) 115 S e r d o h o v, M . V . ( 9 ) 1 2 4 Seres, J. ( 5 ) 58 S e g a l o f f , D . L . ( 6 ) 58 Sergeeva, N . M . ( 9 ) 117 Sergeeva, M . V . ( 9 ) 185 S e r g i e n k o , L .M. ( 5 ) 7 4 S e r g i o , S . ( 9 ) 268 Seridi, L . ( 9 ) 280 S e r p e r s u , E.H. ( 6 ) 83 Seseke, U. ( 8 ) 4 7 , 1 5 8 , 159 Seto, H. ( 6 ) 280 S e t z e r , W.N. ( 9 ) 48 Seyden-Penne, J . ( 7 ) 67 Shabana, R . ( 5 ) 5 4 , 174 Shabarova, Z . A . ( 6 ) 1 6 2 , 1 8 1 , 1 9 8 , 240 S h a e f e r , H.G. ( 9 ) 123 S h a f e i z a d , 5. ( 2 ) 5 S h a i d u r o v , V . S . (5) 28 Shaqidullin, R.R. ( 1 ) 1 6 9 : ( 9 ) 9 , 1 3 9 , 140 S h a g r a l e e v , F.Sh. ( 9 ) 1 0 8 S h a k i r o v , I . K h . ( 9 ) 140 Shalamov, A . L . ( 9 ) 1 9 4 Shamoo, A . E . ( 6 ) 354 Shao, K . ( 6 ) 200 Shao, K.-L. ( 4 ) 71 Sharma, N.D. ( 6 ) 281 Sharp, P . A . ( 6 ) 2 4 4 , 342 S h a r u t i n , V . V . ( 9 ) 229 Shaw, B.L. ( 1 ) 4 9 , 1 3 0 Shaw, J.C. ( 8 ) 1 1 5 , 1 1 6 , 1 1 7 : ( 9 ) 112 Shaw, L.S. ( 8 ) 7 0 , 7 1 , 7 2 , 73, 74, 7 5 , 79, 80, 109, 111, 112. ( 9 ) 4 6 , 56, 1 2 0 , 2 2 4 , 2 2 5 , 2 2 6 , 241 Shaw, R . A . ( 5 ) 2 0 : ( 8 ) 6 9 , 70, 71, 72, 73, 74, 75, 7 9 , 80, 109, 111, 112: ( 9 ) 4 6 , 56, 9 2 , 120, 121, 2 2 3 , 2 2 4 , 2 2 5 , 2 2 6 , 241 Shayhan, F. ( 9 ) 313 S h c h e r b i n a , T.M. ( 5 ) 28 Sheardy, R . D . ( 6 ) 188 S h e e l y , R.M. ( 9 ) 292 Sheenson, V . N . ( 9 ) 2 S h e l d r i r k , G.M. (2) 3 4 : ( 8 ) 27, 4 7 , 156: ( 9 ) 232

Organophosphorus Chernistr?,

S h e l d r i r k , W.S. ( 1 ) 3 6 4 : ( 4 ) 8 7 : ( 9 ) 167 Shen, Y . ( 1 ) 2 2 6 ; ( 7 ) 4 7 , 4R Shenoy, S.J. ( 9 ) 98 Sherman, W.R. ( 9 ) 262 Shermolovich, Y u . G . ( 1 ) 7 2 : (2) 8. ( 9 ) 3 2 , 6 5 , 91 Sheshina, G.M. (8) 218 Shpvchenko, I . V . ( 1 ) 2 7 1 , 278 Shevchenko, M . V . ( 8 ) 34 Shevchuk, M . I . ( 1 ) 2 1 1 : ( 9 ) 146 Shpvenkn, 1 . V . ( 9 ) 1 7 , 25 Sheves, M. ( 7 ) 91 S h i , I.. ( 7 ) 2 4 , 2 5 , 105 S h i , Y . ( 1 ) 34 S h i h a h a r a , S . ( 6 ) 302 S h i b a s a k i , M. ( 7 ) 1 2 4 S h i h a t a , Y . ( 9 ) 206 Shibayama, K . ( 1 ) 251 S h i b u t a n i , M. ( 7 ) 138 S h i g e h a r a , K . (8) 203 S h i h , Y.E. ( 9 ) 221 Shikhanova, L.N. (8) 218 Shimizu, T . ( 6 ) 80 Shimkus, M.L. ( 6 ) 88 Shimotakahara, S . ( 6 ) 277 Shiornoto, K . ( 8 ) 1 8 0 S h i o r i , T . (5) 181 S h i o z a k i , M. ( 5 ) 1 1 2 : ( 7 ) 88 S h i r n i n a , T . A . ( 8 ) 166 S h i z u r i , Y . ( 7 ) 130 Shade, 0 . (8) 23 S h o k o l , V . A . (2) 36 Shopova, N . ( 9 ) 316 S h o r t e r , A . L . ( 6 ) 353 Shreeve, J.M. ( 5 ) 3 , 4 , 126 S h r i v e r , D.F. ( 8 ) 2 0 0 , 2 0 1 , 2 0 4 , 205 Shudo, K . ( 6 ) 317 Shuqar, D . ( 6 ) 53 Shukla, K . K . ( 6 ) 69 S h u l l , T.B. ( 6 ) 7 2 Shumeiko, A . E . ( 8 ) 9 2 Shurubura, A . K . ( 4 ) 38 Shuto, S . ( 6 ) 1 6 Shvedova, T . A . ( 6 ) 347 Shvedova, Yu. I . (5) 7 5 Sibbele, S . ( 9 ) 173 S i b i n s k a , A. ( 6 ) 23 S i c k i n g e r , A. ( 1 ) 33 S i d k y , M.M. ( 2 ) 2 2 : ( 7 ) 42

S i d o r o v , V . I . ( 8 ) 133 S i d o r o v , V . V . ( 8 ) 113 S i e p a k , 3. ( 9 ) 271 S i g a l o v , M.V. ( 1 ) 6 6 Siqel, G . A . ( 1 ) 1 6 4 Siqel, H. ( 6 ) 4 2 , 3 5 9 , 360 Sigman, D . S . ( 6 ) 3 1 8 , ' 3 1 9 , 320 Silaghi-Dumitrescu, L . ( 9 ) 199 S i l i n a , E.B. (2) 36 S i l l e r o , A . ( 6 ) 107 Sillero, M . A . G . ( 6 ) 107 S i l e r , J. ( 1 ) 3 4 6 , 3 4 7 , 3 4 8 , 3 4 9 , 350 Silver, P . A . ( 8 ) 131 S i l v e s t r u , C. ( 5 ) 1 3 3 ; ( 9 ) 199 Simmonnin, M.-P. ( 7 ) 69 Simmons, 0 . (8) 35 Simms, D . A . ( 6 ) 233 Simon, E . s . ( 1 ) 120 Simon, G . ( 9 ) 193 Simon, J . ( 1 ) 36 Slmova, S.D. ( 5 ) 151 S i r n u l i n . Yu.N. ( 9 ) 276 Sines, 3 . 3 . ( 6 ) 7 0 S i n q e r , B. ( 6 ) 228 Sinqh, G . ( 1 ) 1 0 1 ; ( 7 ) 7 S i n q h , R . K . (5) 121 S i n g l e r , R.E. ( 8 ) 1 7 7 , 189 S i n i t s a , A.D. ( 2 ) 2 8 ; ( 4 ) 3 3 , 3 8 , 3 9 : (5) 1 3 9 , 178 S i n o i l , D. ( 1 ) 2 1 , 22 S i n y a s h i n , O . G . ( 4 ) 23 S i p p e l ' I . (5) 180 S i s k , R.B. ( 6 ) 56 S i t d i k o v a , T.Sh. ( 9 ) 108 S i v , C. ( 1 ) 1 7 9 : ( 4 ) 82 S j o v a l l , J . ( 6 ) 114 S k a t t e h o l , L . ( 7 ) 86 Skheide, G.M. ( 8 ) 4 4 S k l e n a r , V . ( 6 ) 388, 389 , 392 Skorobogaty, A. ( 6 ) 3 1 6 , 327 Skowronska, A . ( 9 ) 7 3 S k r z y p c z y 6 s k i , Z. ( 5 ) 8 S l a v i c h , V.M. ( 9 ) 295 S l a w i n , A.M.Z. ( 3 ) 22 Slessov, K.N. ( 5 ) 6 9

Author Index

447

S l e s s o v , K . N . ( 5 ) 69 S l o a n , U . D . ( 1 ) 133 S l o v ' e r , A.V. ( 9 ) 32 S l u k a , P. ( 5 ) 30 S m a a r d i j k , Ab.A. ( 9 ) 74 Smallwood, A. ( 6 ) 75 Smart, B.E. ( 7 ) 1 : ( 9 )

8

Smeaton, E . ( 3 ) 32 Smerdon, M.J. ( 6 ) 252 Srnirnov, N.N. (8) 218 Srnirnov, V.N. ( 5 ) 50 Smirnova, T.V. ( 5 ) 1 2 ;

( 9 ) 258

S r n i t , C.N. ( 1 ) 299 Srnit, P. ( 6 ) 100 S m i t h , A . ( 5 ) 186, 187 Smith, A.B. ( 1 ) 121 Smith, D . L . ( 6 ) 45 Smith, C.G. (8) 8 , 9 S m i t h , S . J . ( 1 ) 235 S r n i t h u r s t , P.G. ( 1 ) 212 S n a i t h , R . ( 1 ) 10 S n e l , J.J.M. ( I ) 8 3 Snyder, J.D. ( 7 ) 123 Sobanov, A.A. ( 9 ) 303 S o d e r q u i s t , J . L . ( 7 ) 32 S o e l e r , F. ( 6 ) 399 Sohar, P . ( 9 ) 77 S o k o l o s k i , J.A. ( 6 ) 411 S o k o l o v , V.V. ( 1 ) 170 Sokolova, N . I . ( 6 ) 198 S o k o l ' s k a y a , I . B . (8) 195 S o l d a t o v a , I . A . ( 4 ) 36 Soliman, F.M. ( 7 ) 43 S E l l , D. ( 6 ) 4 Solodovnikov, S . P . ( 9 )

127

S o l o t n o v , A . F . ( 9 ) 137 S o l o v e t s k a y a , L.A. ( 9 )

117

S o l o v ' e v , A.V.

( 9 ) 91

Somrnerlade, R . H .

185

( 1 ) 72; (5)

Sondhi, S.M. ( 6 ) 316 Songstad, J. (8) 13; ( 9 )

203

S.onnemans, M.H.W. ( 9 ) 128 Sonveaux, E . ( 6 ) 116 SooChan, P. ( 6 ) 233 Soonq, D.S. ( 8 ) 170 S o p c h i k , A.E. ( 9 ) 48 S o r o k i n a , S.F. ( 9 ) 114 S o u r n i e s , F . ( 8 ) 97, 99 S o u v e r a i n , D. (8) 189 Sowerby, D.B. ( 5 ) 133 Sowers, L . C . ( 6 ) 187 Spears, L . G . ( 5 ) 152 Speckhard, D.C. ( 6 )

82

Speek, M. ( 6 ) 296 Spencer, T . L . ( 6 ) 408 S p e n g l e r , S . J . ( 6 ) 234 S p i e g e l , G.U. ( 1 ) 26, 65 S p i e r e n b u r g , M.L. ( 4 ) 7 7 ; ( 6 ) 27 Spinosa, G. ( 6 ) 18 Sporns, P. ( 9 ) 292 S p r e a f i c o , F . (8) 99 S p r i n g e r , H. ( 1 ) 149 S p r i n z l , M. ( 6 ) 268 S p r o a t , B . ( 6 ) 298 S q u i r e , D.R. (8) 189 S r i n i v a s a n , M. (8) 126 S r i v a s t a v a , G. ( 5 ) 15 S t a l l a r d , R.L. ( 6 ) 295 Stam, C.H. ( 1 ) 282 S t a m b o u l i , A . ( 7 ) 75 Stamos, I.K. ( 5 ) 166 Stanforth, S.P. ( 2 ) 3 Staninets, V . I . ( 5 ) 115 S t a n k e v i c h , I . V . (8) 166 S t a n n e t t , V.T. (8) 189 S t a r r e t t , J . E . Jr. ( 7 )

127

S t a r t s e v , V.V. ( 5 ) 76 Starzewski, K.A.O. ( 7 ) 68 S t a w i n s k i , J. ( 1 ) 114; ( 4 ) 34, 75, 6 ; ( 6 ) 26, 120,

121, 122

4 ) 71; ( 6 ) 21, 399 S t e c k l e r , D. K . ( 6 ) 64 S t e e l e , D.L. ( 8 ) 138 S t e i n , S.M. ( 8 ) 179 S t e i n k e , W. ( 5 ) 59

S t e c , W.J.

199, 200

S t e i n s c h n e i d e r , A.Ya. ( 6 ) 385 Stegemann, J . ( 6 ) 298 S t e g e r , B . ( 1 ) 274;

(2) 9

S t e l t e n , J . ( 9 ) 64 S t e l z e r , 0. ( 1 ) 1 8 , 2 6 ,

6 5 , 185; ( 4 ) 4 1 ; ( 9 ) 173

Stepanova, Yu.2.

234, 235

(9)

Stephens, F.S. ( 1 ) 90 S t e r c h o , Y.P. ( 5 ) 182 Sterrn, 0. (8) 1 1 , 12 S t e r n b e r g , J . A . ( 7 ) 19 S t e t t e r , K . O . ( 6 ) 46 S t e v e n s , D.G. ( 3 ) 26 S t e w a r t , C.A. ( 2 ) 31:

(4) 4

Stezowski,

J.J.

172; ( 4 ) 31

(1)

S t r e i t w i e s e r , A. J r . (9) 6 S t r ; ' t v e e n , B. ( 9 )

72

S t i l l e , J.K. ( 1 ) 20, 92 S t i n n e t t , S . J . (8) 81 S t i t t , B . L . ( 6 ) 77 S t o b a r t , S.R. ( 1 )

138

S t o j a o r a , D. ( 9 ) 79 S t o l a r s k i , R . ( 6 ) 53,

2 34

S t o l l , K.

4 4 , 45

( 1 ) 42, 43,

S t o p p i o n i , P.

335

(I)

S t o r k , G.A. ( 6 ) I00 S t r a e h l e , J . ( 8 ) 68 S t r e r n l e r , K.E. ( 5 ) 6 Strepikeev, Yu.A. ( 5 )

49: ( 9 ) 252

Streusland, 8.3.

(9)

S t r i c k l a n d , J.A.

(6)

138

394

S t r i d h , S. ( 6 ) 37 S t r i t t , H.-P. (1)

197

( 1 ) 114; ( 4 ) 34, 76: ( 6 ) 26, 120, 1 2 1 , 122 S t r o n g , J.M. ( 9 ) 292 S t r u c h k o v , Yu.T. ( 1 ) 195, 213; ( 4 ) 4 0 , 9 0 , 93; ( 5 ) 137, 150; (8) 31: ( 9 ) 127, 166, 184, 185, 194, 195, 213, 218, 220

Strzrnberg, R .

S t r u s z c z y k , H.

114, 129

(8)

S t r y e r , L . ( 6 ) 102 S t r z a l k o , T . ( 7 ) 69 S t u a r t , A.L. ( 6 ) 226 Stubbe, J. ( 6 ) 9 9 ,

310, 311, 314 ( 5 ) 48; (8) 15 S t u r m e r , R . ( 7 ) 113 Sudheendra Rao, M . N . ( 8 ) 147 Sugimoto, N. ( 6 ) 2 36 Sugiyama, H. ( 6 ) 315 Sturm, D.

Sukhorukova, N.A.

( 9 ) 320

Sukorukhova, N.A.

171

(5)

Sukuma, 1. ( 6 ) 13 Sulaiman, 5 . 7 . ( 9 )

244

S u l l i v a n , F.X.

332

(6)

448

Organophosphorus Chemistry

S u l z e r , G.M. ( 8 ) 82 Sum, P.E. ( 7 ) 127 Summers, M.F. ( 6 ) 799,

202, 390

Sundaralingam, M.

353

(6)

( 3 ) 23; ( 9 ) 237 Suri, 8. ( 6 ) 192 S u r p i n a , N.Ya. ( 8 ) 136 SGss-Fink, G . ( 8 ) 60 Sut, A . ( 5 ) 53 S u t h e r l a n d , J.C. ( 6 ) 409 Suvorov, N.N. ( 8 ) 702 S u zu k i , K. ( 6 ) 15 S u zu k i , M. ( 1 ) 232 Svara, J. ( I ) 172, 218; ( 4 ) 31; ( 9 ) 101, 200 S v i r i d o v , D.B. ( 9 ) 124 Swain, C . J . ( 7 ) 117 Swamy, 8. ( 1 ) 32 Swann, P.F. ( 6 ) 194 Swinbourne, F . J . ( 8 ) 23 Swinton, D. ( 4 ) 66: ( 6 ) 164 S ym a l l a , E . ( 1 ) 270, 315; ( 4 ) 9 4 ; ( 8 ) 51 S z a l o n t a i , G . ( 9 ) 77 S za m e i t a t , J . ( 1 ) 272; ( 9 ) 16 Szewczyk, J . ( 1 ) 122, 157, 176; ( 3 ) 11: ( 5 ) 183: ( 9 ) 9 5 , 201 Szewczyk, K.M. ( 5 ) 183; ( 9 ) 201 S z i l s g y i , I . ( 5 ) 58 Szostak, J.W. ( 6 ) 337 Sundukova, E.N.

( 4 ) 65: ( 6 ) 123, 125 Taboury, J.A. ( 6 ) 405 Tachon, C . ( 1 ) 249; ( 4 ) 102 Tada, M. ( 6 ) 286 Tada, Y. ( 8 ) 141, 142 T a g u c h i , T. 9 7 ) 9 3 Taguchi, Y . ( 6 ) 206 T a i l l a n d i e r , E. ( 6 ) 405 T a i r a , K. ( 2 ) 17: ( 5 ) 38; ( 9 ) 319 T a j m i r - R i a h i , H.A. ( 6 ) 361 Takahashi, A . ( 7 ) 124 Takahashi, H. ( 1 ) 29 Takahashi, M. ( 6 ) 229 Takahashi, S. ( 6 ) 338, 397

Taagaard, M.

Tak ak i s , I . M . ( 7 ) 134 Takaku, H. ( 4 ) 70: ( 6 )

146, 168, 169, 209 5. ( 5 ) 142, 143 Takano, 5 . ( 7 ) 112 Takeda, A . ( 7 ) 41 Takeda, H. ( 8 ) 213 Takesue, T. ( 6 ) 280 Takeuchi, 1. ( 9 ) 206 Takeuchi, T . ( 6 ) 381 T a l , D. ( 6 ) 248 T a l l e y , J . J . ( 5 ) 10 Tarnatsukuri, S . ( 4 ) 6 9 ; ( 6 ) 157, 165, 166, 182 Tambute, A . ( 3 ) 7: ( 9 ) 282, 286 Tamrn, C . ( 6 ) 1 9 1 , 400 Tamura, S . ( 8 ) 214 Tanaka, H. ( 1 1 368, 369: ( 3 ) 15; ( 6 ) 11 Tanaka, K . ( 8 ) 191 Tanaka, T . ( 4 ) 69; ( 6 ) 144, 145, 157, 165, 1 6 6 , 182: ( 7 ) 1 0 6 , 107, 208 T a n i e l i a n . O.V. 1 9 ) 313 Taniguc hi, Y. ( 1 ) 224; ( 7 ) 28 Tanimura, H. ( 4 ) 67; ( 6 ) 141 Taqui, M.M. ( I ) 32 T a r a s s o l i , A . ( 4 ) 42: ( 9 ) 179 Tarusova, N.B. ( 6 ) 105 T a r z i v o l a , T.A. ( 5 ) 164 Tashma, Z . ( 4 ) 24 Tatsuoka, T. ( 6 ) 15 Taudien, 5. ( 8 ) 15 Tay, M . K . ( 7 ) 79 T a y l o r , B.F. ( 1 ) 212; ( 3 ) 21; (9) 53 T a y l o r , J.-5. ( 6 ) 282 T a y l o r , R . ( 1 ) 49 Tebby, J.C. ( 2 ) 26; ( 3 ) 12: ( 5 ) 161: ( 9 ) 86 Tedder, J.B. J r . ( 8 ) 81, 82 Teoule,. R . ( 6 ) 150, 151 Temerk, Y.M. ( 9 ) 245 Tener, G.M. ( 6 ) 233 T e r e n t ' e v , P.B. ( 9 ) 259 Takamuku,

T e r e n t ' e v a , E.A.

(8)

T e r e n t ' e v a , S.A.

(2)

210 37

T e s s i e r , D.C.

237

(6)

Teulade, M.P.

(5) 77, 7 9 , 8 0 , 8 1 , 8 2 , 153; ( 7 ) 72; ( 9 ) 117

Texier-Boullet,

F.

( 5 ) 9 6 ; ( 7 ) 18 Thanappan, A . ( 5 ) 46 T hatcher , G.R. J . ( 2 ) 1 9 a , 19b; ( 6 ) 62: ( 9 ) 321 Thederahn, T. ( 6 ) 320 Thenet, S. ( 6 ) 173 Theophanides,

T.

( 6 ) 356, 361 Theveny, B. ( 6 ) 415 T h i e l , A. ( 2 ) 34: ( 9 ) 232 Thiern, J . ( 6 ) 1 7 , 40 T h i j s , L . ( 7 ) 116 Thomas, B. ( 8 ) 1 1 , 12; ( 9 ) 96 Thomas, C . J . ( 8 ) 147 Thomas, G.J. ( 1 ) 328 Thorn;, F. ( 6 ) 18 Thompson, M.L. ( 4 ) 42: ( 9 ) 179 T hor nton, P. ( 1 ) 133 Thorsen, M. ( 9 ) 287 T h u i l l i e r , A. (1) 85 Thuong, N.T. 9 6 ) 117, 328 Thurn, H. ( 1 ) 218 Tien, H.J. ( 1 ) 7 T i l i c h e n k o , M.N.

(5)

118

Timmerman, H. ( 8 )

183, 184

Timofeev, A.M.

168

Timofeeva, G . I .

165

Timokhin, B.V.

1

(5) (8)

(5)

Ting, R.Y.C. ( 6 ) 93 T i r i p i c c h i o , A. (1)

136

T i t s k i i , G.D.

92

(8)

T i t t m a n , R. ( 1 ) 76 T i u s , M.A. ( 7 ) 109 T j i a n , R. ( 6 ) 242 Tkachenko, S.E. ( 9 )

308

Tkachev

V.V. ( 9 )

209, ' 21 0

Author Index

449

T o c h i l k i n a , L.N. ( 9 ) 137 TGke, L . ( 4 ) 15 T o k i , S. ( 5 ) 142 Tokoroyama, T . ( 7 ) 23 Tokumaga, T . ( 6 ) 131 Tokunaga, T . ( 6 ) 132 Tolman. R . L . ( 6 ) 99 Tomasz, M. ( 6 ) 277, 278,

279

tom D i e c k , H. 9 ) 79 Tomita, K . ( 9 ) 207 Tomita, T . ( 5 ) 123 Toney, J.H. ( 6 358 Tonge, 3.5. ( 8 201.

204

Toppin, C.R. ( 6 ) 89 Topping, R.J. ( 1 ) 123:

( 3 ) 10: ( 9 ) 106 Tordom P. ( 9 ) 126

T o r o c h e s c h i n i k o v , V.N. ( 8 ) 57 T o r r e n c e , P.F. ( 6 ) 207,

211, 212, 213, 214, 21 5 Toshima, H. ( 7 ) 126 T o s s e l l , J . A . ( 9 ) 28 T o s s i n g , G. ( 1 ) 161, 162: ( 5 ) 138; ( 9 ) 7 6 , 1 1 0 , 197, 198 T o t h , 1. ( 9 ) 77 Toube, T.P. ( 7 ) 136 Toupet, L . ( 9 ) 172 Tourbah, H . ( 7 ) 26 Toyota, K. ( 1 ) 251, 284, ( 9 ) 164, 165 T r a c h e v s k i i , V.V. ( 2 ) 8: ( 9 ) 6 5 , 91 T a l d i , P . ( 8 ) 110 Tran-Dinh, S. ( 6 ) 391 T r e d e r , W. ( 6 ) 17 T r e n t ' e v a , S.A. ( 8 ) 153 T r i b o l e t , R . ( 6 ) 42 T r i f o n o v , L . S . ( 5 ) 151 T r i p p e t t , S . ( 9 ) 104 T r i s h i n , Yu. G . ( 2 ) 25 T r i z n o , M.S. ( 8 ) 199, 218 T r o m e t i n , A. ( 5 ) 160 Tromp, C.M. ( 4 ) 63; ( 6 ) 31 Tromp, M. ( 6 ) 27 T r o s t y a n s k a y a , I.G. ( 9 ) 107 T r o t s c h - S c h a l l e r , I . ( 1) 177 Trostyanskaya, I . G .

171

Trunk, J . ( 6 ) 409 T r z e c i a k , A . ( 4 ) 50 T s a i , T.-C. ( 6 ) 75 Tsao, C.-H. ( 1 ) 1 5

(1)

Tsao, K .

( 9 ) 260 Tse-Dinh, Y . - C . ( 6 ) 34 9 Tseng, C . K . H . ( 6 ) 101 T s ' o , P.O.P. ( 6 ) 204 T s u b o i , A . ( 1 ) 102; ( 7 ) 53 T s u b o i , M. ( 6 ) 388, 397 Tsuboi, 5. ( 7 ) 41 T s u c h i y a , H . ( 6 ) 168 T s u c h i y a , S . ( 9 ) 304 Tsukamoto, M . ( 7 ) 22 T s v e t k o v , E.N. ( 3 ) 23; ( 9 ) 237, 308 Tsymbal, I . F . ( 8 ) 28: ( 9 ) 134 Tuckmantel, W. ( 1 ) 201 Tudose, A. ( 5 ) 107 T u l l i u s , T.D. ( 6 ) 326 T u m a n s k i i , B . L . ( 9 ) 127 Tundo, P. ( 7 ) 78 Tunney, S.E. ( 1 ) 92 Tupchienko, S.K. ( 2 ) 28 T u r , D.R. ( 8 ) 1 6 5 , 166 Turakyan, M.R. ( 5 ) 169 T u r c a n t , A . ( 7 ) 55 T u r n e r , D.H. ( 4 ) 66; ( 6 ) 1 6 4 , 236 Tuzun, M. ( 8 ) 79, 112; ( 9 ) 225, 241 Tzschach, A . ( 1 ) 63, 144; ( 4 ) 8 1 ; ( 5 ) 91; ( 9 ) 1 4 7 , 170

Ubasawa, A. ( 6 ) 189 Uchiyama, M . ( 6 ) 128,

147

Ueda, 5 . ( 6 ) 16 Ueda, T . ( 3 ) 40; ( 6 ) 1 6 ,

183, 185

U e n i s h i , J . ( 7 ) 114 U e s u g i , 5 . ( 6 ) 132 Ueyama, N. ( 5 ) 29 U g i , I . ( 5 ) 30 U h l , W . ( 9 ) 169 Uhlenbeck. O . C . ( 6 )

270, 272 U k a i , J . ( 3 ) 27; ( 7 ) 14 U k h i n , L,Yu. ( I ) 213: ( 9 ) 184 U l ' m a s o v , T.L. ( 6 ) 43 Umarova, 1.0. ( 9 ) 209, 210 Umezaki, Y . ( 3 ) 40 Urdea, M.S. ( 4 ) 51, 53; ( 6 ) 154 U r g e l l e s , M. ( 1 ) 125

U r p f , F. ( 1 ) 119 Uschmann, J . ( 9 ) 152 Ushakov, A . A . ( 1 ) 159 Usman, N. N. ( 6 ) 152,

167

U s t y n y k , Y.A. ( 9 ) 107 U t i m o t o , K . ( 1 ) 201 U t v a r y , K . ( 2 ) 38; ( 9 )

265

Uyzbaev, K . M . ( 1 ) 209 U z n a n s k i , B. ( 4 ) 71;

( 6 ) 1 9 9 , 200, 399

Vaidyanathawamy, R .

( 2 ) 17; ( 5 ) 38

V a g h e f i , M.M. ( 6 ) 12 Valeeva, T.G. ( 9 ) 145 V a l l e , L . ( 9 ) 269 V a l v e r d e , 5. ( 1 ) 2 0 8 t

( 7 ) 16

Van Aken, D. ( 2 ) 30: ( 9 ) 41 Van B o e c k e l , C . A . A .

( 6 ) 174

van B o l h u i s , F . ( 8 ) 86, 9 1 ; ( 9 ) 225,

227, 228

van Boom, J.H. ( 4 ) 29, 61, 62, 63, 65,

6 8 , 7 7 , 78 ( 6 ) 27, 28, 31, 100, 123, 125, 1 2 6 , 1 6 3 , 174, 218, 315 Van C l e v e , M.D. ( 6 ) 184 van de Grampel, J.C. ( 8 ) 86, 91, 119, 149 ( 9 ) 225, 227, 228 Vande G r i e n d , L . ( 9 ) 93 van den E l s t , H . ( 6 ) 27, 371 van d e r H u i z e n , A . A . ( 8 ) 86, 91; ( 9 )

227

van d e r Goot , H.

1 8 3 , 184

(8)

van d e r Knaap, Th.A.

( 1 ) 282

van d e r M a r e l , G.A.

( 4 ) 29, 6 1 , 6 2 , 6 3 , 6 8 , 77, 78; ( 6 ) 27, 2 8 , 31, 100, 126, 143, 218, 315

van d e r P l a s , H.C. ( 6 ) 100

Organophosphorus Chemistry

V a n d e r s l i c e , J.T. ( 9 ) 285 van d e r Steen, R . ( 7 ) 89 van d e r Veer, J . L . ( 6 ) 371 van d e r Woerd, R . ( 6 ) 104 Van Doorn, J.A. (1) 69 Vandyukova, 1.1. ( 9 ) 9 Van G a s t e l , F . ( 1 ) 135 van Hemelryck, B. ( 6 ) 372 Van Houten B. ( 6 ) 274, 275 Van Koten, G . ( 1 ) 282 Van Meerssche, M. ( 1 ) 144; ( 9 ) 170 Vann, W.F. ( 6 ) 248 Van N i e k e r k , P . J . ( 9 ) 291 Van O o r t , A.B. ( 1 ) 83 Van P e l t , J.E. ( 6 ) 73 Van Wazer, J.R. ( 9 ) 235 van Westrenen , J. ( 6 ) 174 V a p r i o v , V . V . (8) 92 Varenne, J . ( 6 ) 175 Vargaz, M . ( 1 ) 235 Vargo, J.M. (8) 215 V a r r e , C. ( 1 ) 97 V a s e l l a , A. ( 9 ) 208 Vashevka, D.S. (8) 199 V a s i l ' e v , A.M. ( 2 ) 29 V a s i l ' e v , V.P. ( 9 ) 273 V a s i l ' e v a , T.V. ( 1 0 158 Vasyana, L.K. ( 9 ) 299 Vasyanina, M.A. ( 1 ) 169 Vdovenko, S . I . ( 9 ) 135 V e d e js , E. ( 7 ) 3, 1 1 , 31 Vederas, 3 . C . ( 6 ) 400 Veeneman, G.H. ( 4 ) 62, 78 V e i t h , M . (8) 45 V e i t s , Yu. A . ( 8 ) 57 V e i r o , D. ( 6 ) 277 V e i t h , M. ( 9 ) 187, 189 Veniaminova, A.G. ( 6 ) 256 Venkataraman, H . ( 7 ) 95

V enk s tern, T . V . ( 6 ) 347 V e n t u r e l l o , P . ( 7 ) 78 ( 6 ) 277, V erdi ne, G.I.. 278, 279 Verkade, J.G. ( 2 ) 17, 30; ( 5 ) 38; ( 9 ) 41, 54 V e r n e t , T . ( 6 ) 237 V e r r i e r , M. ( 9 ) 143 V e r t a l , L . ( 1 ) 235 V i c t o r , T. ( 9 ) 292 V i d a l , M. ( 1 ) 202 ( 3 ) 2 Vidaud, L . (8) 96, 97 V i e r l i n g , P. ( 2 ) 3 3 V i e r s o n , F.J . ( 9 ) 228 V i l a , F . ( 9 ) 126 V i l a r r a s a , J. ( 1 ) 119 V i l c e a n u , R.(8) 128 V i l k o v , L.V. ( 9 ) 156 V i l l a f r a n c a , J. J. ( 6 ) 68 V i l l e m s , N. ( 9 ) 151 V inc ens , M . ( 1 ) 202; (3) 2 V i n c e n t B.R. (8) 76 V inogradov a, S.V. ( 8 ) 165, 166 V i o l a , R.E. ( 6 ) 367 Vioque, A. ( 6 ) 243 V i s s e r , G.M. ( 6 ) 174 V lad, 2 . ( 5 ) 107 V l a d i m i r o v , S.N. ( 6 ) 256 V las s ov , V.V. ( 6 ) 253 V o e l l e n k l e , H. ( 9 ) 205 Vogelbacher, U.-J. ( 1 ) 366

Volatron,

7

F.

( 7 ) 8: ( 9 )

V olk ov , E.M. ( 6 ) 162 V ol k ov , T.I. (8) 199 V G l l e n k l e , H. ( 5 ) 32 V o l l r a t h , D. ( 6 ) 410 V o l o d i n , A . A . ( 8 ) 104, 135, 106, 113 V o l z , P. ( 9 ) 163 Von A l lwij rden, U . ( 1 ) 142 von d e r S aal, W. ( 6 ) 68 Van I t z s t e i n , M. ( 5 ) 148; ( 9 ) 103 Von J a n t a - L i p i n s k i , M. ( 6 ) 97 von K i e d r o w s k i , G. ( 6 ) 224 von P h i l i p s b o r n , W. ( 4 ) 13 v m S c hnerinq, H.G. ( 1 ) 45, 46; ( 8 ) 21; ( 9 ) 191 V o n w i l l e r , S.C. ( 3 ) 34 V o r l i c k o v a , M , ( 6 ) 392 V oronts ov , E.D. (8) 102

Voronkov, M.G. ( 1 ) 66: ( 9 ) 155 Vyncke, W . ( 9 ) 296 Vysotskii, V . I . (1) 71; ( 3 ) 13; ( 5 ) 118: ( 9 ) 250

Waanders, P.P. ( 7 ) 116 Wachter, L. ( 6 ) 158 Wada, A. ( 6 ) 292 Wada, H. ( 7 ) 41 Wada, M. ( 1 ) 102; ( 7 ) 53 Wada, T . ( 6 ) 134 Wade, K. ( 1 ) 10 W:3dsworth, W.S. ( 5 ) 43, 45 Wagner, H.N. ( 1 ) 205 Wagner, M. ( 9 ) 193 Wakabayashi, S. ( 4 ) 60; ( 6 ) 7 Walker , 8.3. ( 7 ) 37 Walker D.J. ( 7 ) 118 Walker, G.T. ( 1 ) 10 Walker, N.P.C. ( 1 )

133

Walker, P.A. ( 6 ) 130 Walker, R . T . ( 6 ) 1 1 , 227: ( 9 ) 219 Walker, V. ( 6 ) 277 Wallace, S . S . ( 6 ) 8s W a l l i s , J.M. ( 7 ) 66 Walmsley, J.A. ( 6 ) 393 Walseth, T.F. ( 6 ) 55 W s l t e r s , J.D. ( 6 ) 54 Wambsgans, A. ( 5 ) 182 Wamhoff, H. (8) 38, 39 Wang, 8.-C. ( 6 ) 407 Wang, C . ( 6 ) 50 Wwig, D. ( 6 ) 273 Wmg, J.H. ( 6 ) 251 Wang, J.S. ( 9 ) 221 Wang, Q. ( 5 ) 67;

45 1

Author Index

( 6 ) 4 9 ; ( 9 ) 81 Wdnq, Q . - S . ( 6 ) 239 Wmg, 0.-W. ( 6 ) 47 Wang, I].-Z. ( 6 ) 47 Waig, W. ( 6 ) 4 Wmg, X . ( 6 ) 4 9 : ( 9 ) 315 W j i g , Y . ( 6 ) 4 7 : ( 7 ) 105 Wang, Z.-W. ( 6 ) 47 Wang, Z . Y . ( 7 ) 100 W m i , A . A . ( 6 ) 230 Wangjian, ( 9 ) 260 Wannagat, U. (8) 59 W3rd, B. ( 6 ) 3 2 7 , 378 Ward, J.A. ( 7 ) 122 Ward, J.G. ( 4 ) 30 Wardle, R.B. ( 7 ) 131 Warner, S . ( 1 ) 17 Warren, S . (3) 53 Waschke, R . ( 2 ) 11 Wasiak, J . ( 5 ) 8 Watanabe, T . ( 6 ) 144 W a t k i n s , C.L. ( 9 ) 249 W a t k i n s , D.a. ( 9 ) 56 Watson, J.J. ( 6 ) 285 Watt, D.S. ( 7 ) 122 Webb, M.R. ( 6 ) 7 7 W?bb, T.R. ( 6 ) 1 7 8 ,

Wt211s, A.S.

Wsber, G . Weber, J . Wc:ber, D. W*?ber L . (

Whiteside, R.C.

1 7 9 , 2 3 1 , 307 ( 9 ) 1 7 4 , 175 ( 9 ) 125 ( 1 ) 46 1 243, 244, 245, 246, 247, 280, 231 Weber, U. ( 9 ) 234 Wedegaertner, D.a. ( 9 )

375 W e f e r l i n g , N. ( 1 ) 159 Wegner, P. ( 1 ) 33 Wei, L . ( 1 ) 17 Wei, X . ( 7 ) 46 w 2 1 , xu. ( 1 ) 223 Weinberg?r-Ohana, P .

( 6 ) 218

W e i n f e l d , M. ( 6 ) 201 Weinhold, K . ( 6 ) 92 W..inhouse, H. ( 6 ) 218 Weiss, 6. (8) 21: ( 9 )

191

Weiss, G.a.

334

( 1 ) 337,

Weiss, J.-V. ( 2 ) 23 Weissmann, C . ( 6 ) 343 Weissmann, S.A. ( 1 )

332, 333. ( 4 ) 9 7 , 9 3 : ( 9 ) 202

Weisz, M. ( 4 ) 24 W e i t h , H.L. 9 4 ) 55; ( 6 ) 156 W..lch, S . C . ( 5 ) 25

( 1 ) 344, 346, 3 4 7 , 348, 349, 350, 3 5 1 , 752 W e l l s , B.D. ( 6 ) 267 Wells, T . N . C . ( 6 ) 44 W e l t r o w s k i , M. (8) 129 Wzn, X . ( 7 ) 24 W?ng, L . (1) 34 Werbelow, L . ( 9 ) 126 W,:solek, D.M. (5) 133 Wessely, H . J . ( 9 ) 169 W r s t , C . R . ( 6 ) 113 W?st, F . G . ( 7 ) 3 West, M. ( 6 ) 285 Wzsterduin, P. ( 4 ) 6 2 , 73 Westheimer, F.H. ( 2 ) 4 ; (6) 1 W e s t k a e m x r , R.B. ( 6 ) 106 W e t t e r m a r k , U.G. ( 8 ) 4 2 , 4 3 , 44, 175 Whanq, C . M . (9) 138 Wheeler, R . A . (8) 68 ( 7 ) 35 W'ieeler, W.J. W h i t e , A.H. ( 1 ) 9 W h i t e , W.B. ( 6 ) 114 W ' i i t e f i e l d , J . ( 8 ) 108

138

Jr. (8)

W ' i i t e s i d e s , G.M. ( 1 ) 1 W h i t t l e , R.R. ( 2 ) 1 6 ; ( 7 ) 12; ( 8 ) 121, 122; ( 9 )

183

Widener, R.K. ( 7 ) 59 Wieczorek ( 5 ) 8 5 Wiemer, D.F. ( 5 ) 9 2 : ( 7 )

7 4 , 77

Wiener, D.F. ( 5 ) 7 0 W i f e , R.L. ( 1 ) 8 3 W i l c h e k , M. ( 6 ) 264 W i l d , S.B. ( 1 ) 3 1 , 90 W i l e n z , R. ( 8 ) 177 W i l h e l m , F.X. ( 6 ) 329 W i l l h a l m , A . ( 1 ) 360 W i l l i a m s , A . ( 5 ) 188 W i l l i a m s , D.J. ( 3 ) 22 W i l l i a m s , H.D. ( 1 ) 3 1 6 , 317: ( 4 ) 8 7 : ( 8 ) 4 9 W i l l i a m s , I . D . ( 1 ) 17 W i l l i n g h a m , R.A. ( 8 )

177

W i l l s o n , M.

( 9 ) 263

Wils,

2 56

E.R.J.

( 8 ) 9 6 , 123;

( 9 ) 254,

W i l s o n , A.W. ( 1 ) 205 W i l s o n , J.R.H. ( 1 ) 341 W i l s o n , W.D. ( 6 ) 1 9 9 ,

202, 390, 393, 394,

3 9 5 , 396 (6)

Wilson, Y.A.

101

W i l t , M. ( 8 ) 1 5 8 W t l t i n g , T . (8) 86, 91; (9) 227 Winkhaus, V . ( 1 ) 2 6 6 , 2 6 7 , 283 Winkhaus, W . ( 9 :

162

Winkler, F. ( 6 )

265

W i n t e r , H. (8) 149 Winter, N.J. ( 9 1

126

u.

Wintersberger,

( 6 ) 303

Wisian-N,.i l s o n , P . ( 1 ) 118; ( 8 )

40, 4 1 , 4 2 , 174, 1 7 5 , 186

Witczak,

8

M.K. ( 8 )

W i t t e , J. ( 7 ) 6 8 W i t t e n b e r g , W.L. ( 6 ) 270 WiCtinghnfer, A.

( 6 ) 3 5 1 , 384

E.

Wojna-Tadeusiak,

( 5 ) 177

(5)

W o j t o i v i c z , H.

113

R. ( 1 ) 3 3 1 ; ( 4 ) 9 9 : ( 5 ) 18 W a J l f , S.F. ( 6 ) 160

Wolf,

Wolfenden, R . 111 W o l f e s , H. ( 6 )

263

Wo1fs5ergerf W 1 5 5 : (8) 4 8 Wslke, J . G. C

1 8 3 , 184

.

W o l t e r , A. ( 6 ) Wqiltermann, A. 23 Wong, A. ( 6 ) 211 Wong, J.T.F. ( 6 )

239

Wong, P . K . ( 6 ) 285 Wood, G.L. ( 1 ) 152 Wood, S.G. ( 6 ) 189 WJods, M. ( 9 ) 264 Woodside, A . B . ( 5 )

6

Wsodward,

296

Woodward

60;

C. (1

)

P.R.

(5)

( i )115

452

Organophosphorus Chemistry

( 6 ) 247 ( 4 ) 58; ( 6 )

WuDdy, A . Y . M . Wooters, J.L.

159

W $ i r t h , L . J r . ( 6 ) 310 W o i n i a k , L . ( 5 ) 33 Wrackrneyer, 6 . ( 9 ) 97 W r b b l e w z k i , A.E. ( 5 ) 9 9 ,

130, 101: ( 9 ) 49 W c l , J . ( 6 ) 50 Wu, J.C. ( 6 ) 251, 310 W.1, R . ( 6 ) 273 W J , Y. ( 7 ) 105 Wuns-h, M. ( 1 ) 336 Wynb?rg, H. ( 9 ) 74

Xia, Xia, Xia, Xie, Xu, Xu, Xu,

J. ( 3 ) 6 W . ( 7 ) 24 Y . ( 7 ) 110 L . ( 5 ) 19 C . ( 6 ) 49 3.-F. ( 6 ) 47 Y. ( 3 ) 6: ( 5 ) 6 5 ,

6 7 ; ( 9 ) 81 ( 6 ) 47

K ~ J , Y.-Z.

Yadagiri, P.

101, 102

(2) 3

N.

Yagi, T. ( 8 ) 142 Y a g u p o l ' s k i i , L.M.

1 0 ; ( 5 ) 132

(2)

Yakirnova, I . A . ( 6 ) 105 Yaklakov, M.G. ( 8 ) 101 Yakovlev, A.A. ( 5 ) 104 Yaqabe, T. ( 8 ) 191 Yamadea, A . ( 8 ) 203 Yarnada, E. ( 6 ) 171 Yamada, H . ( 9 ) 115 Yarnada, K. ( 7 ) 13;3 Yamada, Y . ( 6 ) 144, 145 YamagiJchi, Y. ( 1 ) 234 YaTarnoto, H. ( 3 ) 27; ( 7 ) 14 Yamaji, N. ( 6 ) 51 Yamanoto, Y . ( 7 ) 6 0 , 65;

( 9 ) 153

Yarnamura, Yamanaka, Yamasaki, Yarnashita, Yaqashita,

158

2 4 , 25 Yang, 3 . T . ( 5 ) 17d Yang, Ji.-C. (2) 1 8 , 29 Yang, L . ( 7 ) 105 Yanq, Z.W. ( 6 ) 175 Y a n o v s k i i , A . I . ( 9 ) 185, 194 Yao, E.-Y. ( 3 ) I 1 Yao, En-Yun ( 1 ) 122, 157 YaIzhong, L. ( 7 ) 9 Y a r k e v i c h , A.N. ( 3 ) 2 3 ; (9) 237, 398 Yarkova, E.G.

(2) 35;

( 5 ) 135, 176

Y a r t s e v a , I . V . ( 6 ) 97 Yaslek, S. ( 4 ) 103 Y a t s i m i r s k i i , K.B. (5)

35

( 7 ) 99,

Yadov-Bhatnagar,

Yamkovoy, V . I . ( 6 ) 256 Yan, L . ( 9 ) 257 Yaiagawa, H . ( 6 ) 221 Yanase, K . ( 6 ) 132 Yanchuk, N . I . ( 9 ) 3 0 9 , 3 10 Yang, J . ( 5 ) 37: ( 7 )

( 7 ) 126 ( 6 ) 102 ( 5 ) 89 ( 1 ) 163 M. ( 3 ) 9: ( 5 )

S. G. Y. K.

Yamashita, S. ( 8 ) 191 Yama,3hjita, H. ( 8 ) 58

Y a t s u y a q a g i , K . (8) 190Yde, B. ( 9 ) 287 Ye, M. ( 9 ) 257 Ye, W.-Z. ( 4 ) 105 Yeh, M.Y. ( I ) 7 Yeung, L . ( 9 ) 172 Yeung Lau KO, Y.Y.C. ( 1 ) 263, 264 Y i , N. ( 7 ) 32 Yilrna, H . (8) 73 Yilrnsz, H. ( 9 ) 226 Y o k o i , M. ( 7 ) 4 Yokoyama, T . ( 8 ) 134 Yoneda, R . ( 5 ) 26, 27 Yonemitzu, 0 . ( 7 ) 106,

107, 108

Yoneda, Y . ( 8 ) 216, 217 Yoon, C . ( 6 ) 320 Yoshida, S . ( 6 ) 239 Y o s h i f u j i , M. ( 9 ) 164,

165

Y o s h i z a k i , Z. ( 9 ) 13 Young, 0 . ( 6 ) 344 Yount, R . G . ( 6 ) 2 5 2 Y o u s i f , N.M. ( 5 ) 174 Y o s h i f u j i , M. ( 1 ) 251,

184

Youssefi-Tabrizi,

(5) 85

M.

( 4 ) 17: ( 5 ) 108, 109 Yddelevich, V . I . ( 5 ) 185; ( 9 ) 117 Y u f i t , D.S. ( 1 ) 213

Yuai, C.

( 5 ) 137: ( 9 ) 134, 213 Yu-Gui, L . ( 9 ) 260 Yun-Er S h i h ( 5 ) 21 Yurchenko, A . G . 83 Yurchenko, L.V.

(1)

(6)

253 Yurzhenko, ( 1 ) 87

Yu.R.

Z a b i r o v , N.G.

52

(5)

Z a b m t i n a , E.Ya.

9.1) 363 ( 1 ) 367; ( 9 ) 27 Zaitseva, G.A. ( 9 ) 173 Zakharkin, L . I . ( 1 ) 6 , 239 Zakharov, L . S . ( 5 ) 2a Zahn, T .

Z a m a l e t d i n o v a , G.U. (4) 8 Zamecnik, P.C. ( 6 )

206

Zank, G . A .

( 1 ) 310

Zard, S . Z .

( 1 ) 120;

( 5 ) 175 ( 4 ) 106

Z a r y t o v a , V.F.

35, 3 9 , 253

(6)

Zaslona, A . T . ( 3 ) 33 Zaug, A.J. ( 6 ) 338, 339 Z a u l i n , P.M. ( 9 )

277

Z a v l i n , P.M.

234

Zayakina, G.V.

162

(9) (6)

(5) 149; ( 7 ) 82 Z e c z h i , G . ( 8 ) 61 Zelenev, Yu.V. ( 8 ) 195 Zeman, A . ( 5 ) 4.i Z b i r a l , E.

Zemlyanoi, V.N. ( 1 ) 84 ( 9 ) 136 Zeng. K . ( 6 ) 273 Zenga, H. ( 0 ) 163 Zenke, M. ( 6 ) 298 Z e n t n e r , P.G. ( 6 )

237

Z h a i , C. ( 9 ) 85 Znang, J . ( I ) 34;

( 5 ) 65: ( 7 ) 25

Author Index

( V ) 62 Zhang, L. ( 6 ) 49, 50 Zhang, P. ( 7 ) 51 Zh m g , 5 . 4 . ( 6 ) 239 Zhao, Y. ( 9 ) 257 Zheleznova, L.V. ( 9 ) 72 Z h i v o g l a z a v a , L.E. ( 9 ) 146 Znong, W. ( 1 ) 34 Zhou, X.-X. ( 5 ) 3~3; ( 6 ) 35 Znu, J. ( 5 ) 66, 93, 154 Z i e g l e r , C.B., Jr. ( 7 ) 23 Z i e g l e r , M.L. ( 1 ) 287, 342, 367; ( 9 ) 18, 2 9 Z i e h l e r - M a r t i n , J.P. (6) 190 Z i e l i n s k i , W.S. ( 6 ) 222, 223 Ziemer, 6. ( 8 ) 157 Z i m i n , M.G. ( 5 ) 2, 53, 51, 9.1, 72 Zimm, 5 . ( 9 ) 232 Zimmerman, 5 . 6 . ( 6 ) 238 Zi n b o , M. ( 9 ) 262 Z l o t - s k i i , 5 . 5 . ( 9 ) 326 Zon, G. ( 4 ) 71; ( 6 ) 199, 290, 202, 388, 389, 390, 394, 395, 396, 397:(9)

322

Zora, J.A. 91) 291 Zozensheva, L.Ya. ( 9 ) 258 Zschunke, A. ( 1 ) 144; ( 8 ) 11, 12; ( 9 ) 78, 170 Zubareva, V.E. ( 9 ) 137 Z u b r i t s k i i , L.M. ( 5 ) 76 Z u c h i , Gh. ( 5 ) 107 Zueva, M.Yu. ( 6 ) 385 Zurrnklhlen, F . ( 1 ) 242; ( 4 ) 9.5 Z v e r e v , V . V . ( 9 ) 151 Zwanenburg, 6. ( 7 ) 116 Zw i e r z a k , A. ( 8 ) 16 Z y a b l i k o v a , T . A . ( 4 ) 18: ( 5 ) 120 Z y b i l l , C . ( 9 ) 186 Zykova, T . V . ( 1 ) 141

453