National Institute of Science Communication Dr K. S. Krishnan Marg New Delhi 110012, India
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National Institute of Science Communication Dr K. S. Krishnan Marg New Delhi 110012, India
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Chemicals of Life Parol R. Sheth
©National Institute of Science Communication First Edition: January 2000 ISBN: 81-7236-198-X
Foundation of Biotechnology Series
Book No. 5 Volume Editor
Parvinder Chawla
Cover Design Illustrations
Pradip Banerjee Neeru Vijan, Malkhan Singh, Harjit Singh and Yogesh Kumar Supriya Gupta, Rohini Raina, Shiv Kumar Marhkan, Neeta Sahney and J. Singh C.M. Sundaram, S. Bhushan, S.c. Mamgain, G.C. Porel, Rajbir, Suraj Pal and Om Pal
Production Printing
Designed, Printed and Published by National Institute of Science Communication (CSIR) Under the project, Dissemination of Biotechnology Information sponsored by Department of Biotechnology (Govt. of India)
Price: Rs. 30/-
Foreword A variety of lifeless biomolecules are found in living organisms which serve as building blocks of the intricate structure of cells. Called the chemicals of life, they are present in four forms: proteins, nucleic acids, carbohydrates and lipids. The cellular machinery of living organisms is, in fact, organized around these biomolecules all of which have specific shapes and.functions. Collections of these inanimate chemicals of life constitute living organisms where they interact with one another to maintain and perpetuate the living state. The National Institute of Science Communication (NISCOM) is bringing out popular science books under a new series entitled 'Foundations of Biotechnology' as a part of the project on 'Dissemination of Biotechnological Information' sponsored by the Department of Biotechnology CD Bn, Govt. of India. This venture is yet another step taken by the Institute to make both students and laymen understand the science underlying the wonders achieved by applying hi-tech methods. Attractively illustrated and written in extremely simple and lucid style, these books would certainly help in percolating the awareness of biotechnology down to the school level. By introducing the vast subject of biotechnology especially to children of classes VII to X, it is hoped that many would be initiated to take up this subject for an adv~nced study as it is the time for them to decide upon their career options.
Keeping up with its major mandate of disseminating scientific information to large masses, NISCOM has undertaken this very important venture of popularizing the basic concepts essential to the understanding of sophisticated biotechniques. I firmly believe that these books would enhance the reader's curiousity to know more about this interesting multidisciplinary subject.
rl~~ (Manju-Sharma) Secretary to the Govt. of India Deptt. of Biotechnology
Preface Writing 'Chemicals of Life' was the most satisfying experience for me. It reminded me of my student days when I got introduced to biochemistry, a subject which deals with the study of biomolecules that control the biological functions of any living system. These chemicals of life occur in the cells of all plants and animals including us. Living things are full of chemical compounds including the many common elements such as hydrogen, nitrogen and oxygen. Biochemists try to determine the structure of such compounds and establish their biological functions. All organisms contain compounds which help form the various substances in a cell and enable it to function properly. Certain inorganic substances such as minerals and water also play a role in the cell's growth and maintenance. The book attempts to make both students and laymen understand the basis of living things - the chemicals of life without which there would be no life on this earth. The purpose of writing this book is to introduce the basic concepts of biochemistry, generate curiosity, inculcate interest in the subject and disseminate scientific information to masses.
Acknowledgements I am indebted to many persons who assisted me in the completion of this book. I heartily thank Mr S.K Nag, Chief Investigator, DBT project and Head, Popular Science Division of NISCOM for extending an invitation to write this book. My thanks are also due to Dr. , G.P. Phondke, Director, NISCOM. I appreciate the help rendered to me by Ms Parvinder Chawla for the excellent editing of the book. I cannot forget one name which needs a special mention, late Dr. Anil R Sheth, my "guru" and my Ph.D. guide who has imparted me constant inspiration. Thanks to Rajen, my loving husband for extending calmness and quiet confidence during the writing of this book. The acknowledgement would rather be incomplete without the mention of my son Miten who was ever willing to bear with my busy writing schedules. Bringing out any publication is not a one-man show. It is a joint effort of many individuals having expertise in varied fields. This includes the team of competent artists and production and printing staff of NISCOM. I am indebted to all of them for a splendid job.
ontents Origin of Life
1
Water - the Life Source
7
Proteins - the Vital, Functional Biomolecules
... 13
Nucleic Acids - the Threads of Life
... 26
Carbohydrates - the Energy Molecules
... 32
Lipids - the Large Oily Molecules
... 40
Vitamins, Minerals & Hormones
... 49
Oripin of ,Cife cules. When these molecules are isolated and ~l living things are composed of lifeless molexamined individually, they conform to all the physical and chemical laws that de.scribe the behaviour of inanimate matter. Yet, living organisms that contain the lifeless molecules, possess extraordinary attributes not shown by collections of inanimate matter. They are complicated and highly organized; they possess intricate internal structures and contain many kinds of complex molecules. Furthermore, living organisms occur in millions of different species. Each component part of a living organism appears to have a specific purpose or function. Even individual chemical compounds in cells have specific functions. Living organisms have the ability to extract, transform and use energy from their environment, either in the form of organic nutrients or the radiant energy of sunlight. With the help of these qualities, they can also build and maintain their own intricate energy-rich structures to do mechanical work, locomotion and transport materials. But the most extraordinary attribute ofliving organisms is their capacity for precise self-replication.
2
Chemicals of Life
Philosophers believe that living organisms are endowed with a mysterious and divine life-force - "vitalism". But modern science seeks a rational explanation to determine how the collections of inanimate molecules that constitute living organisms interact with one another to maintain and perpetuate the living state. Let us see how these lifeless molecules came into being. It is a long story. This is the chemical evolution which refers to the origin and development of organic molecules from the inorganic precursors in the presence of energy. We now know that the earth was first formed about 4,800 million years ago. It is believed that chemical evolution took piace on the earth for at least the first 1,000 million years of its life. The first living cells arose perhaps about 3,500 million years ago. Then began the process of biological evolution which still continues. It is believed that the earliest living cells used organic compounds of the rich organic "soup", as building blocks for their own structures. Gradually, through the ages, the organic compounds of the primitive sea were consumed and the living organisms began to learn how to make their own organic biomolecules. Scientists suggest that the universe came into being some 20 billion years ago. An explosion hurled hot, energy-rich subatomic particles in space. Gradually, the universe cooled, these elementary particles combined to form positively charged nuclei to which negatively charged electrons were attracted. Thus were created the hundred or more chemical elements. Only 27 of these natural elements are essential for different •..
I
Origin of life
Living organisms arose from lifeless molecules
3
4
Chemicals of life
forms of life. Carbon, hydrogen, nitrogen and oxygen are the major elements that combine to form a great variety of molecules. These are the biomolecules found in living organisms. Even the simplest and smallest cells, the bacteria, contain a very large number of different organic molecules. It is a mind-boggling fact that a single cell of the common bacterium Escherichia coli contains about 5,000 different kinds of organic compounds. And all these biomolecules have specific functions in cells. Living cells are self-regulating chemical engines, tuned to operate on the principle of maximum economy. They capture, store and transport energy in a chemical form, largely as adenosine triphosphate (ATP). ATP functions as the major carrier of chemical energy in the cells. ATP can transfer its energy to certain other biomolecules and become the energydepleted adenosine diphosphate (ADP). The molecular machinery of the cells is made up of organic compounds of carbon. Perhaps, the versatility of the element carbon is the major factor in the selection of carbon compounds during the origin and evolution of living organisms. Water is the most abundant single compound in all types of cells and organisms. Inorganic salts and mineral elements also constitute a small fraction of solid matter in the cells. However, nearly all the solid matter in all kinds ofcells, is organic and is present in four forms: proteins, nucleic acids; DNA and RNA, carbohydrates and lipids. These four classes of biomolecules are all relatively large structures with high
5
Origin of Life
Lipids Proteins
Nucleic acids
Carbohydrates
The four classes of biomolecules
6
Chemicals of life
molecular weights and are therefore called macromolecules. Surprisingly, over 90 per cent of the solid organic matter of living organisms, containing many thousands of different macromolecules, is constructed from only about three dozen different kinds of simple, small organic molecules. These simple organic compounds of which living organisms are constructed, are unique to life.They differ in shape and size and their chemical reactivity enable them not only to serve as building blocks of the intricate structure of cells,- but also to participate in their dynamic, self-sustaining transformations of energy and matter. They are the chemicals of life and they perform the most difficult and intricate tasks. Nearly all the biomolecules are the derivatives of hydrocarbons, compounds of carbon and hydrogen. One or more hydrogen atoms of hydrocarbons may then be replaced by different kinds of functional groups to yield different families such as alcohols, amines, acids etc. The functional groups attached to the carbon chains determine their chemical properties. Most ofthe biomolecules are polyfunctional containing two or more different kinds offunctional groups. For example, amino acids have an amino group and a carboxyl group. The chemistry of living organisms is organised around these biomolecules all of which have specific shapes and dimensions.
Water -
the £ije loree i
different from that of the inanimate matter of the chemical of living matter is very earth's crust.composition The difference in the elementary composition of the earth's crust is even more striking when we consider the composition by weight of the dry or solid portion of living matter, excluding its water content. Water in living systems make up 70 per cent or more of the weight of most forms of life. Carbon makes up from 50 to 60 per cent by weight of the solid matter of living cells, nitrogen almost 8 to 10 per cent, oxygen about 25 to 30 per cent and hydrogen almost 3 to 4 per cent. In contrast, carbon, hydrogen, oxygen and nitrogen, the elements predominating in living organism together make up much less than 1 per cent of the mass of the earth's crust. But on the other hand, eight of the ten most abundant elements in the human body are also among the ten most abundant elements in seawater. Perhaps, seawater was the liquid medium in which living organisms first arose in the early history of the earth. Water is thus the great mother of us all. It pervades aU portions of every cell. Water is the medium in which transport of nutrients, the reactions
TIe
8
Chemicals of life
'. Water(
Oxygen
"u
.
1>
u••
•
• Carbon' •
0
0
-
.
o
C
I CalciumSulphur I \ Potassium / I sbdium Chlorine Magnesium
What is human body composed of? Gosh, 65%of it is just water! (inset)
Water - the Life Force
9
of metabolism and the transfer of chemical energy occurs. In fact, all aspects of cell structure and function . are necessarily adapted to the physical and chemical properties of water. We take water for granted as aN inert, bland liquid convenient for practical purposes. However, we cannot live without water. You probably think your body feels firm and solid because it is full of strong bones and muscles. But, in fact, 65 per cent of our body is made up of water. A 60 kilogram man has approximately 34 litres of water in his tissues. Our blood is mostly made of water. Water also helps to keep our muscles and joints running smoothly. Some of this water is lost because we breathe it out. We lose water when we sweat and pass out urine. We need to drink about 2-3 litres of water everyday. However, a person's water requirements vary considerably according to the climate, dietetic habits, activities and body structure. Water is a simple compound containing two parts of hydrogen with one of oxygen. The structural formula of water is H20. The water that we drink from the tap comes a long way. It has travelled as rain through the atmosphere, has flowed along the ground into a river or it may have spent part of its journey underground. On the way, it picks up many substances which dissolve in it. Some substances which dissolve in water are minerals. These are chemicals in the rocks. Water contains traces of calcium, sodium, magnesium and iron depending upon the soil from which it is obtained. These are minerals that are essential for good health.
10
Chemicals of life
These minerals are often called trace elements. Fluoride is one such trace element that may be found in water. It helps us to grow strong teeth. Soft water contains small amounts of minerals and it lathers easily while hard water contains a higher proportion of calcium salts and does not lather easily. Why has the nature chosen water and not any other solvent or liquid to be a part of any living organism? Water is a chemically stable substance but has rather unusual properties. It has a higher melting point, boiling point and heat of vaporisation than most common liquids. This fact indicates that there are strong forces of attraction between adjacent water molecules because of the strong hydrogen bonding. Why should liquid water show such strong intermolecular attraction? The answer lies in the structure ofwater molecule. Each of its two hydrogen atoms shares an electron pair with the oxygen atom. The polarity and hydrogen bonding properties makes water a potent solvent. Water ionises very slightly to form H+ and OH- ions. In dilute aqueous solutions, the concentrations of hydrogen and hydroxyl ions are inversely related. The hydrogen ion concentration of biological systems is usually expressed in terms of pH. The ionisation products H+ and oH-profoundly influence the properties of many important components of cells, such as proteins, nucleic acids, lipids and enzymes. The catalytic or speeding up .activity of enzymes is strongly influenced by pH. Living organisms have been smart enough to exploit the unusual properties of water. The high specific heat of water is useful to the cell since it allows water to act
Water - the Life Force
';J- Hydrogen
11
bond
Water molecules form hydrogen bonds with one another
as a "heat buffer", keeping the temperature of an organism constant even when the air temperature fluctuates. Vie humans use the property of high heat of vaporisation of water as a means of losing excess body heat by evaporation of sweat. Plants use the property of hydrogen bonding as a means of transporting dissolved nutrients from roots up to the leaves during the process of transpiration. Even the fact that ice has a lower
12
Chemicals of life
density than liquid water and, therefore floats has important biological consequences in the life cycles of aquatic organisms. Most importantly, the biological properties of macromolecules, the proteins and nucleic acids, derive from their interactions with water molecules of the surrounding medium. All the important functions of the body depend on the presence of a proper amount of water. For example, blood plasma contains 92 per cent of water, the red blood cells contain 70 per cent of water, the digestive secretions or juices are mainly water and urine too contains about 97 per cent of water. Healthy kidneys regulate body water efficiently. With an excess there is increased formation of urine and during deprivation the secretion of urine is diminished. The colour of the urine is a practical guide to the adequacy of fluid intake; in a healthy person, pale yellow urine indicates an adequate intake. In acute vomiting and diarrhoea, excessive loss of water and electrolytes may have to be replaced. Water intake also affects the bowels. The commonest cause of constipation is inadequate intake of water. Almost all food-stuffs except pure fat contain varying amounts of water. All liquids, including tea, coffee, aerated drinks, contain water. Fruits and vegetables also contain a high proportion of water. Water which we consume in various forms is absorbed only slightly from the stomach but it is rapidly absorbed from the small intestine and to a lesser extent from the large intestine. A balance is maintained between the intake and the excretion of water. Any excess water is excreted.
ProteiNs lunctioNal
-"tlte
Vital
Hi(Jl11olecJlles
large molecules. And amongst these, proteins 'TIeconstitute major classes ofbiomolecules in cellsmatter are very the largest fraction of living in all types of cells. They constitute 50 per cent or more of the dry weight of cells in an organism. There are thousands of different proteins in each species of an organism and there are perhaps 10 million different species. Proteins consist of very long polypeptide chains having from 100 to over 1,000 amino acid units joined by peptide linkages. They are relatively large structures with high molecular weights ranging from 5,000 to over one million. The name protein in Greek is proteios which means llfirstllOF- "foremostll. They are the direct products and effectors of gene action in all forms of life and are the most versatile of all biological molecules. Their building blocks are amino acids just as glucose is the building block of starch or lipids are the building blocks of fatty acids or deoxynucleotides and ribonucleotides are the building blocks of DNA and RNA The amino acids include two functional groups; an arnino
Chemicals of life
14
Amino acid Protein
Amino acids are the building blocks of proteins
------- ~
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---._--
------------
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Proteins - the Vital, Functional Biomolecules
15
group and a carboxyl group in a basic hydrocarbon chain. Regardless of the function or biological activity, proteins are built from the same basic set of 20 standard amino acids which by themselves have no intrinsic biological activity. Then, you may wonder as to what is it that gives one protein an enzymatic activity, another protein a hormone activity and still others antibody activity. How do these differ chemically? Quite simply, proteins differ from each other because each has a distinctive sequence of its amino acid 'units'. The amino acids are the alphabets protein structures, since they can be arranged in an almost infinite number of sequences to make an infinite number of proteins. All proteins contain carbon, hydrogen, nitrogen and oxygen while some also contain iron, phosphorous and sulphur. The amino acids within are linked together int(}long chains called polypeptides. A few of these are straight but most are bent into three dimensional shapes. Proteins can be divided into two major classes on the basis of their shape and certain physical characteristics - globular proteins and fibrous proteins. In globular proteins the polypeptide chain or chains are tightly folded into compact spherical or globular shapes. These are soluble in water and they diffuse readily. Nearly all of the 2,000 or more enZYlnes are globular proteins, as are the blood transport proteins, antibodies -the body's defence proteins, and nutrient storage proteins.
16
Chemicals of llie
Fibrous proteins are insoluble in water and are long and stringy molecules with the polypeptide chains extended along one axis rather than folded into a globular shape. Most fibrous proteins serve as structural proteins and have a protective role to play. Amongst all the proteins present in the body, the fibrous proteins may constitute one-half or more of the total body proteins in higher animals. They provide external protection since they are the major components of the outer layer of skin, hair, feathers, nails and horns. Fibrous proteins also provide support, shape and form, since they are major organic components of connective tissues, including cartilage, tendons, bone and deeper layers of the skin. These stringy proteins are three dimensional but they have simpler structures than those of the globular proteins. There are four kinds of fibrous proteins that have protective or structural function in animals. These include a-keratin, ~-keratin, collagen and elastin. The a-keratins are the characteristic insoluble, tough proteins found in hair, wool, feathers, scales, horns, hooves and tortoise shells. The best example of ~-keratin proteins is the silk fibroin. Collagen is the most abundant protein in vertebrates. It is found in tendons, silk fibres, blood vessels, bone and cartilage. Collagen fibres do not stretch yet they have great tensile strength. On partial hydrolysis, collagen is converted into gelatin, a soluble digestible mixture of polypeptides. Elastin is a characteristic protein of connective tissues which has elastic properties. Myosin, actin and tubulin are units of intracellular filamentous
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_~:~BdqIJ~lsB~l q1!MIBJ!ludp!dno.ill dUldq ~Od::~A~d.r°~~ •• G pUE dJUdnbdS liMO . ill( 10 Sdnp!Sdl PPE OUIU1E £SI 10 um J d ~ms 1no A.ueJ 01 A2jd~d iUq~ldEU~~!l:IOJ n ·){.lOM JElnndJ -D1IUldq1 OlllodsuEll slTSdJUBqu1dp~;~~: EPpuoqJ . SIl dpsnUl dq1 liT Ud.8A:xO un :UdJ dpsnUI U! puno]· U!d10ld.8~Du~a~u~~lSd~~~r~IT? travel through the rest ~rhe BOdY,frlg9~up un:: oxygen to the tissues. In the tissues, haemoglobin takes up carbon dioxide and releases it in the alveoli of the lungs. The carbon dioxide is then exhaled. Besides carrying oxygen and transporting carbon dioxide, haemoglobin also transports protons - hydrogen ions, from the body to the lungs for subsequent excretion. Lack of haemoglobin or hereditary abnormalities in haemoglobin may result in anaemia. Some poisons like the aniline dyes or other chemicals combine with haemoglobin in such a way that it can no longer combine with oxygen turning the blood to bluish- brown. Carbon monoxide, a poisonous gas, on the other hand readily mixes with haemoglobin making the blood bright red. But the gas keeps blood from taking up oxygen. Chemical poisons may also cause haemolysis or breakdown of red blood cells. Haemolysis in small amounts isa normal body process. About 0.8 of 1 per cent of all red cells in our body are haemolysed or broken down each day. However, the process is usually balanced by the
red blood cell production in the bone marrow, the centre part of the bone.
(q) UFllQld .illlnqo13 B 'U!qollfowdH pUB (B) U!dlQld snolq-g: B 'udlfcnOJ
Chemicals of Life
20
oC/db M ogt;g o'fPUo + ~4~~ Substrate
Enzy~e
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oo 0 + DD Product
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. Substrate-enzyme
Enzyme
Enzymes speed up chemical reactions
Other globular proteins are enzymes whose biological function is to speed up the chemical reactions. They possess a specific catalytic activity. Most of the chemical reactions of organic molecules are catalysed or speeded up by enzymes. There is a family of over 2000 different enzymes, each capable of catalysing a different kind of chemical reaction. Although enzymes are proteins, some must be attached to certain non-protein molecules in order to function. Many of these non-protein molecules are memls, such as copper, iron or magnesium. These occur as trace elements in nature. Others are organic compounds called coenzymes. If a coenzyme is tightly attached to the protein part of an enzyme, the unit is called a prosthetic group. Neither the coenzyme nor the protein part of a prosthetic group can function alone.
Proteins - the Vital, Functional Biomolecules
21
Without enzymes, the chemical reactions in all living things would occur slowly or not at all, and no life would be possible. Although enzymes of different plants and animals have different protein structures, they function in similar ways. Enzyme molecules function by altering other molecules. They combine with the altered molecules to form a complex structure in which chemical reactions takes place. The enzyme remains unchanged and simply separates from the product of the reaction. Thus, enzymes serve as biological catalysts. A single enzyme molecule can perform its entire function a million times a minute. The chemical reactions occur thousands or even million times faster with enzymes than without them. All living cells make enzymes. Our body has thousands of enzymes and each kind does a specific job. Without enzymes, we cannot breathe, see, move or digest food. What happens to the food we eat? Enzymes in the digestive system breakdown food for use in the body. The pancreatic enzymes trypsin, chymotrypsin and elastase act on proteins in the duodenum. They convert the bigger molecules into small peptide chains known as the oligopeptides and amino acids. In the small intestine, oligopeptides are further digested by the intestinal cells. The intestinal enzymes, peptidases, further break down the amino acids into single amino acids and are then absorbed. Absorbed amino acids reach the liver through blood vessels where some amino acids are converted back to proteins. Others reach the tissues through blood circulation and are utilised for protein synthesis. Pepsin secreted by the
22
Chemicals of life
walls of the stomach, acts on proteins. Amylase secreted by the salivary glands in the mouth splits carbohydrates into simpler chemicals. Lipase is secreted by pancreas into the small intestine where it breaks down fats. Photosynthesis in plants also depends on the action of enzymes. Many enzymes breakdown complex substances into simpler ones, others build complex compounds from simple ones. Most enzymes remain in the cells where they were formed, but some work elsewhere. For example, lipase from pancreas travels to the small intestine to breakdown fats. An enzyme's structure can easily be destroyed by heat, acids or alkalis. Scientists believe that a high body temperature such as 42°C may cause death because the heat makes vital enzymes inactive. Many deadly poisons damage important enzymes. Hereditary diseases may occur in people born without certain enzymes or the presence of an abnormality in the synthesis of enzymes. When cells are injured, by impairment of blood supply or by inflammation, cer~ tain enzymes leak into the blood. Measurement ofthe activity of such enzymes can help diagnose important medical disorders such as, anaemia, cancer, heart disorders etc. Enzymes can also be used in therapy; to help clean wounds, dissolve blood clots, check allergic reactions and so on. If your diet lacks adequate amounts of coenzymes; the vitamins, the enzymes cannot function properly and various body disorders may develop.
23
Proteins - the Vital, Functional Biomolecules
Seeds ofmany plants store nutrient proteins that are required for the growth of the embryonic plant, such as the seed proteins of wheat, corn and rice. These are the nutrient and storage proteins. Other examples are the eggwhite protein ovalbumin or casein, the major protein of milk. Animal tissues contain ferritin that stores iron.
A
~'-.
Antigen binding sites "-
Living organisms as well as our body has special soldiers for defence. The func- Structure of an antibody tion of defence proteins is to defend organisms against invasion by other species or protect them from injury. There are immunoglobulins or antibodies which are specialised proteins made by the white blood cells. The defence proteins can recognise and conquer the invading bacteria, viruses or foreign proteins from another species. Fibrinogen and thrombin prevent blood loss in an injury and help in forming clots. Snake venoms, bacterial toxins and toxic plant proteins such as ricin, also function as defence proteins. The regulatory proteins are the ones that help regulate cellular or physiological activity. This group includes many hormones, such as insulin, which regulates the sugar metabolism, growth hormone and other hormones of the pituitary gland, situated in the
24
Chemicals of Life
brain, parathyroid hormone which regulates calcium and phosphate transport. The functions of certain proteins are rather exotic. Have you heard of monellin? It is a protein of an African plant and has an intensely sweet taste. The blood plasma of some Antarctic fish contains "antifreeze" proteins which protect their blood from freezing. The wing hinges of some insects are made of resilin, a protein that has perfect elastic properties. Extraordinarily, they are all made from the same amino acids and yet they have very different properties and functions. Proteins which perform the same function in different species, for example haemoglobin which has the same oxygen-transport function in different vertebrates, are known as homologous proteins. Homologous proteins from different species usually have polypeptide chains that are identical or nearly identical in length. These proteins show sequence homology, that is, certain critical positions in the polypeptide chains of homologous proteins contain the same amino acids, regardless of the species. In other positions of homologous proteins, the amino acid may differ. The more closely related the species, the more identical would be the amino acids sequences of their homologous proteins. Thus, the sequences of homologous proteins indicate that organisl:ns containing them arose from a common ancestor but underwent changes as different species diverged during evolution. Proteins are necessary for the growth and repair of tissues.For example, the inner layer ofthe intestine, the
Proteins - the Vital, Functional Biomolecules
25
epithelium, is shed at regular intervals and proteins are required for its regeneration. Fats and carbohydrates cannot be substituted for proteins as they do not contain nitrogen. Proteins from the food, supply raw materials for the formation of digestive juices, hormones, plasma proteins, haemoglobin, vitamins and enzymes. Each gram of protein supplies 4 kilocalories. Therefore, it is very important to eat a balanced diet. Protein-rich foods such as meat, fish, poultry, eggs and milk are 'first class' proteins. Pulses, wheat, millet and vegetables are a must for growing strong and healthy.
/Vuc/eic Acids -
the
<::hreads of J;ife
macromolecules, that have molecular weights proteins, areNucleic also informational anging up tonucleic several acids billion. acids are of two types; the deoxyribonucleic acid or DNA and the ribonucleic acid or RNA. Both have the same universal functions in all cells that is, to participate in the storage, transmission and translation of genetic information. DNA serves as a repository of genetic information whereas different kinds of RNA's help translate this information into various protein molecules.
!J·ke
DNA is the chemical basis of heredity and is organised into genes, the fundamental units of genetic information. DNA is mainly found in the nucleus of a cell. But RNA may be found throughout the cell. Even bacterial cells which do not have a nucleus contain DNA and RNA. Certain viruses contain only Rl~Aand other viruses contain only DNA. Chromosomes are the cell bodies which control the heredity of an animal or a plant as they are the carriers of DNA, the genetic material. When a cell divides, the chromosomes in its nucleus
Nucleic Acids -
the Threads of Life
27
are duplicated exactly and passed on to the daughter cells. The DNA in the chromosomes furnishes the daughter cells with a complete set of 'instructions' for the cell's own development and the development of their descendants. The basic unit of a DNA molecule called nucleotide contains a phosphate, a sugar called 'deoxyribose' and nitrogen compound called base. These nucleotides comprising phosphate-sugar-base are repeated hundreds of thousands of times to form long coiled chain which looks like a twisted ladder. Each rung of the ladder consists of two matching bases and the sides have sugar and phosphate molecules. It was in 1953that James D. Watson, an American and Francis H.C. Crick, an Englishman together made a model of the DNA molecule. They showed that it resembled a twisted ladder; a dou ble helix. The fundamental chemical structure is common to all DNA. However, there are four different bases in DNA - adenine, guanine, thymine and cytosine. The exact proportions of each ofthe bases and the precise order in which they are arranged are unique for each species. It is this exact order and composition that must be faithfully copied each time a cell divides. RNA exists as single strands and consists of long chains of repeating phosphate-sugar-base units. However, the sugar in RNA is 'ribose' rather than 'deoxyribose' as in DNA and the bases are adenine, guanine, cytosine and uracil rather than thymine. DNA never leaves the nucleus of a cell. But proteins are produced
Chemicals of Life
28
Phosphate-sugar
backbone-f
l
The structure of the double helix
Nucleic Acids -
the Threads of Life
29
in the cytoplasm, the part ofthe cell outside the nucleus. Transmitting DNA's information to the cytoplasm is the task of RNA It, therefore, plays an important role in the formation of proteins. Some RNA molecules called the messenger RNA (mRNA) leave the nucleus carrying instructions for making proteins and go to ribosomes_ in the cytoplasm, where proteins are made. To understand the making of proteins, itis important to first understand how mRNA is formed. When RNA copies DNA's blueprint for making a protein, the DNA ladder first splits lengthwise through its bases. Half the ladder serves as a mould to form mRNA. Free RNA bases, with their attached sugars and phosphates, match up with the exposed DNA bases. A strand of messenger RNA thus begins to form. This RNA is a copy of the DNA's blueprint for the polypeptide chain. Now, this mRNA leaves the cell's nucleus and enters the cytoplasm of the cell and goes to the ribosomes; the cell's centres of protein production. A ribosome moves along the mRNA, "reading" the information. The mRNA acts as a guide to line up the amino acids in the exact order called for by the DNA of.the genes. The amino acids are then linked together one by one to form the polypeptide chain. Another type of RNA, called transfer RNA or tRNA collects the amino acids in the cytoplasm and brings them to the mRNA in the ribosome. There js at least one tRNAmolecule for each kind of amino acid. The specific tRNA and the correct amino acid are brought together with the help of the energy molecule, the ATP'and an enzyme designed for the job.
Chemicals of Life
30
e···· .... ··
Ribosome Translation starts
:>~ ::.:;:.
'.,
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\ NHZ
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Making of a protein from mRNA
The ribosome moves slowly over the mRNA template step by step with the help of tRNA. The finished polypeptide chain is then released and the protein is now complete. Life isn't easy on the inside, it is nluch n10re complicated than you can imagine. How can just four bases. determine the order of 20 amino acids in a protein
Nucleic Acids -
the Threads of Life
31
chain? The answer lies in the triplet code. In other words, a group of three bases in a certain order forms the coding segment known as the codon, for a specific amino acid. Each codon is given a three-letter name that corresponds to the abbreviation of the names of its bases. It is surprising that the genetic code is universal - from bacteria to human beings. And the order of bases - the genetic code in the DNA molecule is passed on from one generation to the next. It makes an elephant give birth to an elephant and not a tiger. It makes a human being give birth to another human being and not a monkey. It is this order that determines the colour of your eyes, the shape of your ears and thousands of other traits. Sometimes things go wrong. And this is what precisely happens when changes occur in the sequences of bases in genes. These are what we callmutations. Mutations can occur through rare accidents during the duplication of DNA ]be wrong base may mistakenly become attached to a DNA half-ladder. Mutations can also occur in DNA that has been damaged by X-raysor certain chemicals. A mutation that occurs in a body cell affects only the person who carries it. However, a mutation in a sex cell can be transmitted from one generation to the next. A mutation may result in the formation of a faulty protein. For example, a mutation for the gene for haemoglobin in the blood can produce haemoglobin with a reduced abilityto transport oxygen causing sickle cell anaemia. Many such genetic disorders are known today which are caused due to defective proteins.
tlte Energ!/ Molecules
enruolt!/drntes -
In
drates is another important group of macromoleaddition to proteins and nucleic cules, present in living cells. acids, Most carbohyof the carbohydrates found in nature occur as polysaccharides with high molecular weight. Polysaccharides such as starch have molecular weights running in millions. Because polysaccharides are built from only a single kind of unit or from two different alternating units, they cannot carry encoded genetic information as nucleic acids. Carbohydrates in the form of sugar and starch represent a major part of the total caloric intake; almost 55 per cent or more for humans as well as for animals and even for many microorganisms. Green plants and other photosynthetic organisms utilize solar energy to synthesize carbohydrates from carbondioxide and water. Starch and other carbo- hydrates made by photosynthesis become the ultimate energy and carbon sources for non-photosyntheticcells of animals and microbes. Carbohydrates are polyhydroxy aldehydes or ketones or substances that yield
Carbohydrates - the Energy Molecules
33
such compounds on hydrolysis. In these carbon 'hydrates', the ratio of carbon to hydrogen to oxygen is 1:2:1. Although many carbohydrates conform to this ratio, others do not show this ratio and some also contain nitrogen, phosphorous or sulphur. There are three major classes of carbohydrates: monosaccharides, oligosaccharides and polysaccharides. Monosaccharides are simple sugars consisting of single polyhydroxy aldehyde or ketone unit. The most abundant monosaccharide in nature is the 6-carbon sugar glucose. Monosaccharides are colourless, cry.stalline solids that are freely soluble in water but insoluble in oils or non-polar solvents. Most have a sweet taste. The backbone of monosaccharides is an unbranched single bonded carbon chain. Both mono and disa~charides have names ending with the suffix-ose. Monosaccharides having 4, 5, 6 and 7 carbon atoms in their backbones are called tetroses, pentoses, hexoses and heptoses. The principal monosaccharides include glucose, fructose and galactose. Glucose, a mildly sweet sugar is the most important carbohydrate in the blood. It is also called blood sugar.Fructose, an extremely sweet sugar comes from fruits and vegetables. Large amounts of glucose and fructose are found in honey. Galactose occurs in food only as a part of a disaccharide called lactose found in\milk. Oligosaccharides consist of short chains of J)1onosaccharide units joined together by covalent bonds. Most oligosaccharides having three or more
Chemicals of life
34
(a)
Glycogen
(c)
Structure of a monosaccharide (a), disaccharide (b) and a polysacccharide (c)
units do not occur free but are je>inedas side chains to polypeptides in glycoproteins and proteoglycans. The most abundant oligosaccharides, however, are the diasaccharides, which have two monosaccharide units as in cane sugar which consists of 6-carbon sugars, glu-
Carbohydrates - the Energy Molecules
35
cose and fructose joined in covalent bonds. Among the most important disaccharides are sucrose, lactose and maltose. Sucrose is table or household sugar which comes from sugarcane and juices of the sugar beet plant. A molecule of sucrose consists of a molecule of glucose linked to a molecule of fructose. Lactose also called as milk sugar, makes up about 5 per cent of cow's milk. A molecule of lactose consists of a molecule of glucose and a molecule of galactose. Maltose or malt sugar remains after the brewing process. It is used to flavour some sweets. A molecule of n1altose consists of two molecules of glucose. Polysaccharides consist of long chains having hundreds or thousands of monosaccharide units. Some polysaccharides such as cellulose have single chains whereas others such as glycogen have branched chains. The most abundant polysaccharides are starch, glycogen and cellulose of the plant world. A molecule of starch consists of hundreds or even thousands of glucose molecules joined end to end. It is the chief form of carbohydrate stored by plants. Starch occurs in food such as beans, maize, potatoes and wheat. Cellulose and glycogen also consist of many glucose molecules. Cellulose makes up much of the cell walls of plants. Cellulose is the only carbohydrate that cannot be digested by the human body and has no food value. However, it helps maintain the health and tone of the intestines and thus aids digestion. Cattle, goats and many other animals that eat plants, have bacteria in their digestive systems that can breakdown cellulose. The bodies of such animals use the digested cellulose
Chemicals of llie
36
as fuel. Glycogen, sometimes called animal starch, is the chief form of stored carbohydrates in animals. Glycoproteins are hybrid molecules. They are proteins that are linked to carbohydrates, elther single monosaccharides or relatively short oligosaccharides. Glycolipids is another class of hybrid molecules which contain carbo.hydrate groups. The most remarkable glycoprotein is the anti-freeze protein present in the blood of some Arctic and Antarctic fish and in winter flounder and codfish of the eastern coast of North America. These proteins depress the freezing point of water, allowing the fish to tolerate the low temperatures of polar seawater. Animal cell surface too contains glycoproteins: in the. cells lining the intestine there lies a very thick carbohydrate-rich coat called the glycocalyx or "fuzzy coat". One of the best known membrane glycoproteins is the glycophorin of the red blood cell membrane which contains almost 50 per cent carbohydrate molecules attached to a polypeptide chain. How does our body use carbohydrates? Only monosaccharides can enter the bloodstream directly from the digestive system. The rest of the carbohydrates have to be br.oken down into simple sugars. Digestion of carbohydrates begins in the mouth. Chewing breaks down the cellulose envelope and makes starch and sugar readily available for subsequent digestion. Saliva contains a starch-~plitting enzyme ptyalin or salivary amylase which converts starch into simple sugars and maltose. The digestive action of ptyalin is \
Carbohydrates -
Glucose
Sucrose
37
the Energy Molecules
Starch
Lipids
Proteins
I
Mineral salts & Vitamins Water Cellulose
Saliva
Gastric juice
Pancreatic juice
Intestinal juice
CD
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a
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Various enzymes secreted by different glands aid in digestion of food
38
Chemicals of life
continued in the stomach until acidity of the gastric juice rises and stops the action. Carbohydrates are mainly digested in the small intestine. The enzyme, amylase of the pancreatic juice rapidly converts starch into maltose. Sucrase or invertase, maltase and lactase, enzymes present in the intestinal cells convert disaccharides into monosaccharides. The breaking down process occurs in the small intestine after which the blood transports the simple sugars to the liver. The liver changes fructose and galactose into glucose, which is then carried by the blood to all the cells of the body. The cells use glucose as fuel for the muscles and nerves to build and repair body tissues. The liver changes excess glucose into glycogen and stores it. Only when the level of sugar in the blood is low, the liver changes glycogen back into glucose and releases it into the, blood. Glycogen is also stored in the muscles as an emergency reserve of energy. Some of the glycogen is changed back into glucose when the body needs energy quickly. Carbohydrates are sometimes mistakenly termed as "junk" foods without recognising their nutritive value as suppliers of energy. Apart from supplYing ready fuel, carbohydrates also playa role in the proper functioning of the liver, the central nervous system and heart and muscle contraction. The mechanism of the control of blood sugar levels is associated with the hormone insulin secreted by the pancreas.
Carbohydrates - the Energy Molecules
39
Carbohydrates form our staple food; rice, wheat, bajra, jowar, pulses - moong dal, tuvar dal etc. Foods high in carbohydrate content include bananas, bread, macaroni, potatoes, sweet potatoes, sugar, honey and jaggery. Some sources of carbohydrates such as fruits, vegetables and whole cereal grains also contain important vitamins and minerals. Most sweets and soft drinks have a high sugar content, however, they serve only as a source of energy for the body and so do not provide the health benefits of the other carbohydrate foods.
£ipids -
tlte £arpe
Oil!! Molecules
'ne
the lipids. They play an important role in cell other important groupLipids of macromolecules are structure and function. are concentrated source of food energy and yield about twice as many calories as an equal weight of protein or carbohydrate. Many kinds of organisms store food in lipid form. For example, the seeds of many plants store lipids as food reserves for their embryos. The bone marrow, the tissues beneath the skin and those surrounding the body organs consist mostly of stored lipids. Lipids dislike water. Hence they are, water-insoluble. They are oily or greasy organic substances that can be extracted from the cells and tissues by non-polar solvents such as chloroform and ether. The most abundantly found lipids are the fats or triacylglycerols which are the major fuels for most organisms. Indeed, they are the most important storage form of chemical energy. The other class of lipids includes the polar lipids that are the major components of cell membranes. Membranes are simply not inert "skins" surrounding
Lipids - the Large Oily Molecules
41
the cells. They contain many important enzymes and transport systems. Moreover, on the outer surface of cell membrane are located many different recognition or receptor sites that can recognize other cells. These can bind hormones, and sense other types of signals from the external environment. Most of the properties of cell membranes are reflections of their polar lipid content. There are several classes of lipids and each has a specific/biological function. Fatty acids are the characteristic building- block components of most lipids. Fatty acids are long-chain organic acids having from 4 to 24
Fatty acids . ....
Hydrophobic tail
Hydrophilic head, Water .....
.:
Lipids are oily and water insoluble
42
Chemicals of life
carbon atoms. They have a singly carboxyl or acid group and a long non-polar hydrocarbon 'tail' which gives these lipids their water-insoluble and oily nature. Nearly all fatty acids in nature have an even number of carbon atoms. Amongst these, those with 16 and 18 carbons are the most abundant. Lipids are classified into two classes, according to their structure. Simple lipids contain only carbon, hydrogen and oxygen. They consist of an alcohol in combination with certain organic acids containing a variable number of carbon atoms. The most common type of simple lipid, the triacylglycerols or triglycerides (fat) contain one molecule of an alcohol called glycerol and three molecules of fatty acid. These fats include butter, lard or pig fat, tallow or beef and mutton fat, blubber or whale fat, castor oil, coconut oil and olive oil.Waxes are another group of simple lipids containing an alcohol moleculeJhat is larger than the glycerol molecule. Triacylglycerols are the major components of storage or depot fat in plant and animal cells but are not comD;lonly found in membranes. Simple triacylglycerols are tristearoyglycerol (tristearin); tripalmitoyglycerol (tripalmitin) and trioleyglycerol (triolein), which contain stearic acid, palmitic acid and oleic acid respectively. Triglycerols containing two or more different fatty acids are called mixed triacylglycerols. Triacylglycerols undergo hydrolysis when boiled with acids or bases or when acted upon by the enzyme lipase. The primary chemical reaction that is involved in making household soap from triacylglycerols is hy-
lipids - the Large Oily Molecules
43
drolysis of triacylglycerols with sodium hydroxide or potassium hydroxide called saponification or soap formation. In most animal and plant cells, triacylglycerols occur as microscopic oily droplets, finely dispersed and emulsified. Large amounts oftriacylglycerols are stored in the adipocytes or fat cells; the Adipose tissue constitutes specialised cells of the confat storage cells nective tissue of animals, in the form of fat droplets which fill almost the entire cell volume. Fat cells are found under the skin, in the abdominal cavity and in the mammary glands. In fat people, many kilograms of triacylglycerols are deposited in fat cells of the body, sufficient to supply basal energy needs of the body for several months. In contrast, our body can store less than a day's energy supply in the form of glycogen. Triacylglycerols yield over twice as much energy gram for gram, as carbohydrates. In some animals, triacylp-Iycerolsstored under the skin serve a double purpose, .both as important energy storage depots and an insulation against very low temperatures. Seals, walruses, penguins and other Arctic and Antarctic aninlals are amply padded with triacylglycerols. Waxes are included in the simple lipid class of mole-
cules. In vertebrates, waxes are secreted by skin glands
44
Chemicals of life
as a protective coating to keep the skin pliable, lubricated and waterproof. Hair, wool and fur are also coated with waxy secretions. Birds, particularly waterfowl, secrete waxes in their preen glands to·make their feathers water-repellent. The leaves of many plants are coated with a protective layer of waxes. Waxes are formed as well as used in very large amounts in marine life, especially in plankton organisms. Here, wax serves as the chief storage form of caloric fuel. Since some whales, herring, salmon and many other marine species consume planktons in large amounts, waxes are major food and storage lipids in oceanic food chains. Complex lipids have a more complicated structure than simple lipids. They include phospholipids that contain phosphorous, steroids that are made up of four rings of carbon atoms joined together, and other compounds such as glycolipids which contain lipids with one or more sugar molecules. Other complex lipids include fat-soluble vitamins such as vitamins A,D,E and K and terpenes, and yellow pigments like carotene. Phospholipids are found in all bacteria and in the cells of plants and animals. They are most plentiful in sperm, eggs, embryos and brain cells. A phospholipid molecule contains a molecule of glycerol, a phosphate ion and two molecules of fatty acid. Most phospholipids also contain a compound with nitrogen in it. Some contain inositol, a substance found in vitamin B complex. Phospholipids are often called as polar or charged lipids as their structures have polar heads and nonit
lipids - the Large Oily Molecules
45
Cytoplasm
Cell membranes mainly constitute a double layer of phospholipid molecules
The second largest group of membrane lipids are the sphingolipids which do not contain glycerol. They are composed of one molecule of the long chain amino alcohol, 'sphingosine' or one of its derivatives and an alcohol. Sphingosine is the parent compound of a number of long chain amino alcohols found in different sphingolipids. Cells also contain lipids which contain no fatty acids and thus cannot form soaps. There are two major classes of such lipids-the steroids and terpenes. These are included in the complex lipid group. Steroids make up an important part ofliving things. Many animal hormones, including the sex hormones and those produced by the cortex or the outer part of the adrenal
Chemicals of life
46
glands, are steroids. Yeasts, other fungi and the seeds of higher plants also contain steroids. Steroids are complex fat soluble molecules with four fused rings. The most abundant steroids are the sterols, which are steroid alcohols. Cholesterol is the major sterol in animal tissues. Cholesterol and its derivatives with long chain fatty acids are important components of plasma lipoproteins and of the outer cellular membrane. Lipoproteins are specific proteins associated with some lipids. In blood, there are plasma lipoproteins which may contain from 50 to 90 per cent of lipids. These inclu-de both polar lipids and triacylglycerols, cholesterol and its derivatives, the esters. The blood lipoproteins are classified on the basis of their density, which in turn is a reflection of their lipid content. The greater their lipid content the lower their density and the greater theIr tendency to move upward or "float". Evidence today suggests that the combination of a high plasma level of very-low density lipoproteins (VLDL) with a low level of high-density lipoproteins (HDL) is an important factor in causing atherosclerosis, the formation of thick deposits of cholesterol and its esters on the inner surface of blood vessels. It causes restriction of the blood flow through the clogged blood vessels of the brain and heart leading to heart attacks anclstroke. I
•
Fat literally floats in the stomach. In an erect posture, fat emptying is considerably delayed. The entry of fat in the duodenum releases certain enzymes which then stimulate the flow of bile and pancreatic juice. The digestion of triacylglycerols begins in the small intes-
Lipids - the Large Oily Mol~~ules
47
A blood vessel clogged by the deposition of cholesterol
tine. These are hydrolysed in the presence of bile salts, the enzyme lipase and colipase to yield a mixture offree fatty acids which are then further emulsified into fine droplets by peristalsis - the churning action of the small intestine. The dIgested lipids in the droplet form are absorbed by mtestinal cells, where they are reassembled into triacylglycerols. The triacylglycerols do not pass into the blood.capillaries but into the lacteals, small lymph vessels in the intestinal villi. The lymph draining the small intestine, is called chyle, which has a milky appearance- after a fat-rich meal due to suspended chylomicrons, droplets of highly emulsified triacylglycerols. The chylomicron core contains triglycerides and cholesterol, while the membrane con-
48
Chemicals of life
sists of phospholipid and some lipoprotein. In fact, after a meal rich in lipids, the blood plasma itself becomes opalescent because of the high concentration of chylomicrons. After absorption, fats may be oxidised to carbon dioxide and water or stored in the fat depots. Insulin, the hormone secreted by the pancreas aides fat storage. After the energy requirement of the body have been met, excess fat is stored away under the skin, the peritoneal cavity, between the muscles and around the kidneys and ovaries. Women have a higher proportion of fatty tissue than men. In both sexes, proportion of fat rises with age. Fats are thus ideally constituted as the reserve fuel of the body. Dietary fats can be divided into two general groups, the visible fats and the invisible fats. Most of us are aware of the visible fats that we eat, such as the fat in meat, butter, salad oils and cooking oils, ghee etc. But foods such as milk, eggs, fish and nuts contain invisible fats. Invisible fats are spread finely throughout certain animals and plants. Many such fats are especially rich in fatty acids. Certain kinds of fats; the saturated fats, seem to increase the amount ofcholesterol in the blood. Therefore, it is advisable to consume diets high in unsaturated fats and polyunsaturated fats.
VitaJHins~Minerals ~ J!OfJHOneS
termed as macro nutrients as they are required Carbohydrates, proteins lipids are together in bulk amounts by the a?d body. Vitamins are required in small amounts by our body as well as animals for proper growth and function. We require vitamins in only milligram or microgram quantities per day. Therefore, they are called micronutrients. Vitamins are catalYtic in action, and they make possible the numerous chemical transformations of the macronutrients that is together called metabolism. Nearly all known vitamins are present in the cells of all animals, most plants and micro organisms and perform the same important biochemical functions there. However, not all known vitamins are necessarily required in the diet of every animal species. For example, although vitamin C is required as well as in the diet of monkeys, guinea pigs and the Indian fruit bat, most other animals do not require vitamin C because they
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Chemicals of life
have enzymes to manufacture it from its simple precursor glucose. Vitamins can be grouped into two classes, the watersoluble and fat-soluble vitamins. The water-soluble vitamins include Vitamin C or ascorbic acid and vitamin B-complex. Vitamin B Complex is actually a group of eight vitamins; thiamine or vitamin B1, riboflavin or vitamin B2, nicotinic acid, pantothenic acid, pyridoxine or vitamin B6, biotin, folic acid, and vitamin B12.The fat soluble vitamins are oily substances that are not readily soluble in water. They include vitamins A, D, E and K Vitamins are 13 in all and .each one has specific use and the lack of one vitamin can interfere with the function of another. Five of these are produced within our body; biotin, niacin, pantothenic acid, vitamin D and vitamin K. Only biotin, pantothenic acid and vitamin K which are made by bacteria in the human intestine are possibly produced in sufficient quantities to meet the body's needs. Therefore, vitamins must be supplied in a person's daily diet. A significant characteristic of the fat-soluble vitamins is that they can be stored in the body in large amounts, so that the effects of their complete deficiency in the diet may not be manifested physiologically for many months. Vitamin A is a fat-soluble vitamin. There are two natural forms, vitamin Al or retinol, obtained from marine fish livers and vitamin A2, from livers of fresh-water fish. Both are 20-carbon alcohols formed of isoprene units which are also the building blocks of many naturally occurring oily, rubbery substances of plant origin. Vitamin A itself does
Vitamins, Minerals & Hormones
51
VITAMINS K Fat Soluble A D (Calciferol) (retinol) E (tocopherol) (menadione) Niacin Folic acid acid Biotin Pantothenic acid Ascorbic Pyridoxine (86) Riboflavin (B1) (82) Water Soluble Thiamine Cobalamin (812)
not occur in plants but many plants contain isoprenoid compounds known as carotenoids, which can be enzymatically converted into vitamin A by most animals. ~-carotene is the one that gives carrots, sweet potatoes and other yellow vegetables their characteristic colour. Vitamin A is present in egg yolk, liver, milk, fruits like mangoes and papayas, green and yellow vegetables etc.
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Chemicals of life
Vitamin A is absorbed along with fat from the small intestine. It is stored in the liver and unlike water-soluble vitamins, it is not excreted through the urine. It is needed for the growth of bones and teeth. It keeps the skin healthy and helps produce mucous secretions that build resistance to infection. Moreover, it is good for the eyes. People who do not get enough of vitamin A can suffer from night-blindness. Vitamin D is from the group of fat-soluble vitamins. There are several forms of vitamin D. One form, calciferol, or vitamin D2, is produced in plants. It is produced from a sterol, a type of chemical compound, when a plant is exposed to ultraviolet light. Another form, cholecalciferol} or vitamin D3, occurs in the tissues of animals, including human beings. Vitamin D has been called the "sunshine vitamin" because it forms in the skin when the body is exposed to sunlight. Liver and fish oils contain much vitamin D2. The natural sources of vitamin D are egg yolk, milk and butter. Dietary vitamin D is absorbed together with fat from the intestine while vitamin D absorbed from the skin slowly diffuses in the blood. It is stored mainly in the liver. Vitamin D helps prevent rickets, a bone disease. Deficiency of vitamin D leads to abnormal calcium and phosphorous metabolism. Born into the vitamin family, and yet had a long struggle to attain the present status and dignity is the vitamin E. Vitamin E consists of four molecular species, the a, P, rand btocopherols, ofwhich a-tocopherol is most important. The name tocopherol is derived from
Vitamins, Minerals & Hormones
53
Greek tokos - childbirth. a-tocopherol is the most potent. Vitamin E or tocopherols help prevent polyunsaturated fatty acids from oxidising, or combining with oxygen. Vitamin E thus plays an important role in maintaining cell membranes which contain substantial amounts of polyunsaturated fatty acids. The best sources of vitamin E are lettuce and wheatgerm oil. Meat, milk, eggs liver, whole-grain cereals and most vegetables also contain this vitamin. Tocopherols are readily absorbed along with fats, however, bile juice secreted by the gall bladder, is necessary for its absorption: The storage sites for vitamin E are the liver and the fatty tissues. Tocopherol deficiency causes SYmPtoms including degeneration of liver and altered membrane function. Vitamin K, the last one in the fat-soluble group, has two major forms; vitamin K and vitamin K2 that are abundant in most higher plants. They are organic compounds with isoprenoid side chains of differing lengths. Vitamin K has a major role to play in the blood-clotting mechanism. It is necessary for the proper formation of the blood plasma protein prothrombin, the inactive precursor of thrombin, an enzyme that converts the protein fibrinogen of blood into fibrin. Fibrin is an insoluble fibrous protein that holds blood clots together. Green leafy vegetables, such as cabbage, cauliflower and spinach are rich in vitamin K Pork liver is also an excellent source. Intestinal bacteria manufac1:urevitamin K in the body. Vitamin K is absorbed from the small intestine with the help of bile salts and it is not stored in the body. Deficiency of vitamin K in chicks
54
Chemicals of life
and other animals results in faulty clotting of blood. However, deficiency of this vitamin rarely results from a poor diet. . Amongst the water soluble group of vitamins is vitamin B complex which was first believed to be only one vitamin. It was later discovered that it consists of eight vitamins. The first one is vitamin B 1 or thiamine which is necessary in the nutrition of most vertebrates and of some microbial species. Thiamine contains two ring systems, a pyrimidine that contains nitrogen atoms and a thiazole ring that contains a sulphur atom. Sources of thiamine include green vegetables, meat, especially pork, nuts, soybeans, yeast and whole-grain and enriched bread and cereals. Thiamine is readily absorbed from the small intestine and is stored in the skeletal muscle, heart, liver, kidney and brain. This vitamin, like vitamin A is needed for growth. Our body also needs it to change carbohydrates into energy. Its deficiency in our diet causes beriberi, a disease characterised by neurological disorders, paralysis and loss of weight. In Asia, in the 1800s and early 1900s, beriberi caused the death of perhaps hundreds of thousands of people subsisting on diets in which polished, refined rice was the major staple food. The husks which are removed in the refining process, contain nearly all the thiamine of rice. Vitamin B2 or riboflavin was first isolated from milk. Its intense yellow colour is due to its complex isoal-
Vitamins, Minerals & Hormones
55
loxazine ring system. Riboflavin is a component of two closely related coenzymes, flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD). They function as tightly bound prosthetic groups of a class of molecules dehydrogenases known as the flavoproteins. Riboflavin is most abundant in foods such as eggs, fish, liver, milk, poultry, yeast and green and leafy vegetables. It is absorbed from the intestine. Direct sunlight destroys riboflavin in milk. This vitamin is needed for growth and for healthy skin and eyes. It promotes the body's use of oxygen in converting food into energy. If you do not get enough riboflavin, cracks may develop in the skin at the corners of the mouth. You may also get inflamed lips and a sore tongue and scaly skin around the nose and ears. The eyes too may become extremely sensitive to light. Niacin or nicotinic acid and its amide, nicotinamide are names that might mislead some of us into thinking that tobacco is nutritious. Nicotinic acid is pyrimidine beta carboxylic acid. Nicotinamide is a component of two related coenzymes nicotinamide adenine dinucleotide (NAD) and nicotinamide adenine dinucleotide phosphate (NADP). NADP consists of NAD with an extra phosphate group. These coenzymes occur in oxidised and reduced forms. The best sources of niacin are fish, green vegetables, lean meat, poultry, wholegrain, enriched bread and cereal. Nicotinic acid or nicotinamide is rapidly absorbed from the stomach, the small intestine and the large intestine. Nicotinamide is distributed in cells throughout the body, being essential in the tissue metabolism. Niacin helps prevent pel-
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Chemicals of Life
lagra which is a disease that occurs in many regions of the world where the diet is poor in meat, milk and eggs and heavily dependent on com as a staple diet. Pellagra is characterised by the three D's - dermatitis; a skin ailment, diarrhoea, and dementia; a form of depression. Although milk and eggs have little niacin, they are good pellagra preventive foods because they contain tryptophan, an amino acid. The body converts some tryptophan into niacin. Niacin is essential for growth, for healthy tissues and for the conversion of carbohydrates into energy. It also helps produce fats in the body. Without niacin, thiamine and riboflavin cannot function properly. Lack of niacin may cause ailments of the skin and of the digestive and nervous systems. Pantothenic acid is found in all plant and animal tissues and also in micro-organisms. Pantothenic acid is a peptide derivative. It is converted by the body into coenzyme A, a vital substance that helps the body produce energy from food. The coenzyme is distributed throughout all animal tissues, especially in the liver, kidneys, spleen, heart and adrenal glands. Pantothenic acid is absorbed from the alimentary canal. Deficiency of pantothenic acid may cause burning feet syndrome which includes a sensation of pins and needles pricking in the feet, tingling and numbness and burning of feet especially in the night. The vitamin B6 group consists of three closely related compounds, pyridoxine, pyridoxal and pYridoxamine which are readily interconvertible biologically. Pyridoxine helps the body use amino acids, which are
Vitamins, Minerals & Hormones
57
the building blocks of proteins. The foods richest in vitamin B6 are egg yolk, meat, fish milk, whole grain, cabbage and other green vegetables. Vitamin B6 is probably also synthesised by the intestinal bacteria. It is rapidly absorbed from the intestine and also from the skin. Human red cells rapidly take up vitamin B6 and convert into pyridoxal phosphate. Much of the newly synthesised pyridoxal phosphate is bound to haemoglobin. Our body can store vitamin B6 for about eight weeks. Lack of vitamin B6 damages the skin and nervous system. Biotin was originally called vitamin H, from the German word Haut which means skin, because it protected rats from dermatitis. Biotin is a component of human tissues. Although eggs are otherwise nutritious and do contain biotin, consumption of large amounts of uncooked egg whites can cause biotin deficiency in animals. This is because, the egg white contains a protein, avidin, which binds biotin very tightly and does not allow the vitamin to be absorbed from the intestine. Folic acid, the word is derived from Latin, folium meaning "leaf". It has three major components: glutamic acid, p-amino benzoic acid and a derivative of the heterocyclic fused-ring compound pteridine. It is also known as pteroylglutamic acid. Almost all uncooked food contains folic acid but cooking destroys varying amounts of it. It is derived from vegetables, cereals, meat and liver. Folic acid is absorbed from the intestine. Our body stores folic acid in the liver. Deficiency of folic
58
Chemicals of Life
acid causes a type of anaemia in which the red blood cells do not mature properly. Vitamin B 12 is the most complex of all vitamins. It is unique in that it contains not only a complex orgarrlt: molecule but also an essential trace element, cobalt. Vitamin B12 is called cyanocobalamine because it contains a cyano group attached to cobalt. Vitamin B12 is not made by either plants or animals. It is synthesised by only a few species of microorganisms. It is required in only minute amounts, about three microgram per day, by otherwise healthy people. Vitamin B12 is essential for the normal functioning of folic acid. Eggs, liver, milk and other animal sources of proteins as well as some microbes supply vitamin B12. Active absorption of vitamin B 12 from food occurs from the ileum. The bulk of body stores of vitamin B 12 is in the form of coenzyme B12. The main storage occurs in the liver. People who eat only vegetables may lack this vitamin. Lack of vitamin B 12 can damage the nervous system and can cause anaemia. Vitamin C or ascorbic acid is present in all animals and higher plant tissues. It is required in the diet of human beings and only a few other vertebrates as most animals and probably all plants can synthesise ascorbic acid from glucose. Ascorbic acid is not present in or even required by microorganisms. The body stores little vitamin C and so this vitamin must be supplied daily in the diet. Good sources of it include citrus fruits, raw cabbage, strawberries and tomatoes, germinated cereals and pulses. 'Peru' or 'Jamrookh' has a high
Vitamins, Minerals
& Hormones
59
A balanced diet is the key to good health
content of vitamin C. Vitamin C is absorbed from the intestine. This vitamin prevents and cures scurvy, a disease that is caused by a lack of vitamin C resulting in defective formation of collagen. This is because one of the functions of this vitamin is that it helps form collagen, a protein that holds tissues together. Scurvy manifests changes in the skin, blood vessels, bones,
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ChemicalsofLife
teeth and gums. PeoZinc Iron Iodine Trace elements Copper Molybdenum Other Vital Dietary ple who lack vitamin C, Elements Fluorine Chromium Minerals Chlorine Selenium Potassium Calcium Sodium Sulphur Manganese Cobalt have sore Phosphorus gums and Magnesium suffer bleeding under the skin. In the absence of this vitamin, wound healing too becomes defective and formation of scar tissue is delayed. Vitamin C has gained a reputation for being useful in reducing the severity or preventing common cold. In addition to vitamins in diet, animals and people require a number of chemical elements in inorganic form for proper growth and biological function. These elements can be grouped into two classes: bulk elements and trace elements. The bulk elements include calcium, magnesium, sodium, potassium, phosphorous, sulphur and chlorine. These are required in large amounts, say about a few grams per day. Often, they have more than one function, for example, calcium is a structural component of bone mineral. Free calcium ions also serve as a very important regulatory agent in the cell. The essential trace elements are required only in milligram or microgram amounts per day. Some 15
Vitamins, Minerals & Hormones
61
trace elements are known to be required in animal nutrition. Most of the essential trace elements function as' enZyme cofactors or prosthetic groups. Iron is among the best known of the trace elements with regard to biological function as it is a conlponent of heme groups ofthe oxygen-carrying proteins haemoglobin and myoglobin and of the electron-carrying mitachondrial protein cytochrome c. Several ilnportant enzymes also ~ontain heme prosthetic groups. Gopper plays an important role in the cataly1ic activity of cytochrome oxidase; an electron-transferring enzyme, which contains both iron and copper. Copper is also present in the active group of lysyl oxidase, an enzyme that makes linkages between polypeptide chains in collagen and elastin. Zinc is an essential component of nearly a hundred different enzymes. It is present in enzymes that promote the transfer of hydride ions from substrate molecules to the coenzymes. Zinc is also an essential component of DNA and RNA polymerases and thus participates in important enzymatic reactions involved in the replication and transcription of genetic information. The hormone insulin is stored as a zinc complex. Among the most interesting roles of zinc, is the proper functioning of the taste and smell receptors of the tongue and nasal passages .. Other trace elements such as manganese, cabalt, selenium, molybdenum, vanadium, silicon, nickel~ chromium, tin, boron and aluminium are also known to
62
Chemicals of Life
I',
I
,
,
,, ,
I
! I
Testis
The location of major endocrine glands in the body
Vitamins, Minerals & Hormones
63
be required by some enzymes. All these are essential in the diet. The list of chemicals of life remains incomplete without the mention of hormones. Hormones are chemical substances produced within a human being, an animal, or a plant. In animals, hormones control body activities such as growth, development and reproduction. In plants, hormones regulate many aspects of growth. In human beings, hormones control not only different aspects of metabolism but also many other functions like cell and tissue growth, heart rate, blood pressure, kidney function, motility of the gastrointestinal tract,_secretion of digestive enzymes, lactation or milk secretion and the reproductive system. The word hormone is derived from a Greek verb meaning "to stir up or to set in motion". A hormone is secreted in small amounts by one type of tissue and carried by the blood to a target tissue elsewhere in the body where it stimulates a specific biochemical or physiological activity. Thus, hormones serve as a means of communication among various parts of an organism. They act as "chemical messengers" that help these parts function in a co-ordinated way. If an organism fails to produce the proper kind or amount of hormones, serious disturbances or even death may result. Hormones are produced by organs called endocrine or ductless glands. The word endocrine means "to secrete within". The secretions of such glands are internal, that is, into the blood. The major endocrine glands include the two adrenal glands, the pituitary
64
Chemicals of life
gland, the four parathyroid glands, the sex glands and the thyroid gland. A few hormones are secreted by endocrine tissue present in the organs that are not primary endocrine glands. Such organs include the stomach and pancreas. The hypothalamus, a special ised portion of the brain, is the co- ordination centre of the endocrine system. It receives and integrates messages from the central nervous systenl. In response to these messages the hypothalamus produces a number of hypothalamic regulatory hormones which are sent to the pituitary gland located just below the hypothalamus. Each hypothalamic hormone regulates the secretion of a specific hormone by the pituitary gland. Once the pituitary is stimulated, it secretes hormones into the blood to be carried to the next rank of endocrine glands such as the pancreas, the thyroid gland and the ovary and testis. These glands, in turn, are stimulated to secrete their specific hormones, which are caJTied by the blood to hormone receptors on or in the cells of the ultimate target tissues to which the hormone binds firmly. The whole system works like a 'relay race. In the cells of the target tissue, yet another molecular signalling agent, an intracellular messenger, carries the message from the hormone receptor to the specific cell structure or enzyme that is the ultimate target. Thus, each endocrine system resembles a set of relays, designed to carry messages from the nervous system to a specific molecule in its target cells. The endocrine system is also modulated by interconnecting feedback controls. For example, the' thyrotropin-releasing hormone (fRH) is sent out by the
Vitamins, Minerals & Hormones
65
hypothalamus to the anterior lobe or the front part of th~ pituitary gland, causing it to release more thyrotropin. This in turn, stimulates the thyroid gland to release the thyroid hormones thyroxine and triiodothyronine which are sent to their target tissues. However, the circulating thyroid hormones in the blood act as feedback inhibitors; they deplete the secretion of TRH by the hypothalamus and of thyrotropin by the pituitary. Thus, the activities of the endocrine system consist of a very complex regulatory network. There are three classes of hormones: the peptides, amines and steroids. The peptide hormones have from three to over 200 amino acid residues. These include all the hormones of the hypothalamus and pituitary, as well as insulin and glucagon ofthe pancreas. The amine hormones are small water-soluble compounds containing amino groups. These include adrenaline of the adrenal gland and the thyroid hormones. The steroid hormones are fat-soluble,
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ChemicalsofLife
additional sugar into the blood. Thyroxine and triiodothyronine are both produced by the thyroid gland. They control the rate at which the cells use food to release energy. Overproduction of these hormones can cause physical and emotional disturbances including excitability, muscular weakness, rapid pulse and respiration and weight loss. Underproduction causes low body temperature, mental and physical sluggishness and weight gain. The glucocorticoids function primarily in regulating the metabolism of carbohydrates, fats and proteins. They control the processes by which the body converts digested proteins into carbohydrates and fats. This group of hormones include corticosterone, cortisol and cortisone. The glucocorticoids are secreted by the cortex, the outer part of the adrenal gland. Insulin and growth hormone (GH), a hormone secreted by the anterior pituitary gland, also regulate the creation of new tissues. GH also stimulates cells to use fat, rather than sugar, as an energy source and so helps maintain a fairly high level of sugar in the blood for the brain to function properly. GH controls the overall growth during childhood. Faulty 13roduction of this hormone can cause a person to either become a giant or a dwarf. In adults, GH enables certain tissues to maintain their proper size and structure. Insulin, glucocorticoids and thyroxine, all play major role in tissue and growth maintenance. Between the ages of 11 to 15, youngsters undergo a rapid spurt of growth and physical changes. 111ere are
Vitamins, Minerals & Hormones
67
hormones that control this phase of development commonly known as puberty. At the start of puberty, the hypothalamus increases its secretion of gonadotropinreleasing hormone, stimulating in turn the secretion of gonadotropic hormones - follicle stimulating hormone (FSH) and luteinising hormone (LH) from the anterior pituitary gland. These hormones act on the gonads or sex glands - the testes in males and the ovaries in females. Under the influence of FSH and LH, the gonads grow and begin to secrete large amounts of sex hormones; androgens which are testosterone and androsterone in males and estrogens and progesterone in females. The cortex of the adrenal glands too secrete some sex hormones, both in men and women, especially androgens. The sex hormones regulate the remarkable changes that occur during puberty, in both boys and girls. Androgens cause the male sex organs to mature and they stimulate the development of secondary sexual characteristics, such as the growth of beard, moustache or deep voice in men. Estrogens cause the female sex organs to develop fully and also stimulate the secondary sexual characteristics such as breast development and wide hips. FSH, LH, estrogens and progesterone work together to control the menstrual cycle. Progesterone also regulates processes necessary for pregnancy. Healthy blood contains fairly exact levels of several ~hemical substances. And any alteration in the levels of these can prove harmful to our body. A nurnber of hormones work together to ensure that the composition of the blood remains within normal ranges. Para-
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Chemicals of Life
thormone, secreted by the parathyroid gland and calcitonin, from the thyroid gland, both regulate the levels of calcium in the blood. The former also controls the amount of phosphate in the blood. The mineralocorticoids secreted by the adrenal cortex, control the balance of salts and water in the blood. Vasopressin, the anti-diuretic hormone, secreted from the posterior lobe of the pituitary gland, regulates the water level of the blood. When you are angry, scared or injured, the medulla, the inner portion of the adrenal glands secretes adrenaline and noradrenaline. Adrenaline, in particular prepares your body for stress. Other hormones in human beings include oxytocin and relaxin, both of which affect the process of birth. Oxytocin like vasopressin is stored and secreted by the posterior pituitary gland. The ovaries produce relaxin. It widens the birth canal, the passageway through which a baby leaves its mother's body. Oxytocin causes the rnuscles of the womb, the uterus to contract during the birth pangs known as labour. It also stimulates the release of milk from the mother's breasts, when the infant nurses. Melanocyte-stimulating hormone (MSH) is another hormone secreted by the anterior pituitary gland. It is supposed to regulate the amount of pigment, Inelanin present in the skin. Plant hormones are produced mainly in actively growing parts, in the tips of roots and stems. These hormones influence growth and are often called the growth regulators. There are mainly three types of plant hormones, the auxins, cytokinins and gibberellins. Auxins cause various effects on different parts of a
Vitamins, Minerals & Hormones
69
plant, such as, elongation and lengthening of cells in stems and roots, stimulation of the growth of fruits and preventing fruits and leaves from falling apart. Cytokinins control cell division in plants. They help determining which cells of a young plant will become root cells and which cells will become leaf cells and so on. Gibberellins stimulate many plants to grow taller. They also help in blossoming of certain plants. Other growth regulators include abscissic acid and ethylene. The former blocks plant growth, thus stimulating dormancy while the latter regulates the ripening of fruit. This is how the chemicals of life control the working of a living organism. Any living organism, is a self-assuring, self-adjusting, self-perpetuating systern of organic molecules which extract free energy and raw materials from its environment. It maintains itself in a dynatnic steady state and most importantly, its nearly precise self-replication through many generations is ensured by self-replicating system. The organic machinery of living cells functions within the same set of l~ws that governs the operation ofman-made machines, but the chemical reactions and regulatory processes have been refined far beyond the present capabilities of the chemical engineer. The study of biomolecules, therefore, provides us with new and important insights into the human physiology, nutrition, medicine, plant biology and agriculture besides evolution and ecology.
Collections of various lifeless biomolecules
con-
stitute the living organisms. Called the chemicals of life, these biomolecules comprise proteins, nucleic acids, carbohydrates and lipids all of which have specific shapes and functions. This lucidly written and profusely illustrated book, targeted at school children, elaborates· the role played by the various chemicals of life in running the cellular machinery.
ABOUT THE AUTHOR Dr. Paul R. Sheth is a freelance science writer. After completing her M.Sc. in organic
chemistry
from St. Xavier's
Mumbai, she acquired Ph.D. in biochemistry
College,
from Seth G.S.
Medical College, Mumbai. She was a research officer at the Institute for Research in Reproduction (ICMR), Mumbai, before joining the editorial board of Science Today, a Times of India publication.
She had her postdoctoral tr:.aining in Andrology at
the University
of Rome,
Italy. She has over 25 research
publications and over 200 popular science articles to her credit published in various newspapers, magazines and journals. She conducts medical interviews, gives popular science talks and also writes features for the All India Radio, Mumbai. Besides Chemicals
of life, she has also authored two other popular
science books entitled, Gene Play and Strange Plants.