Fundamentals Of Plant Biochemistry And Biotechnology PDF

Summary

This document provides information regarding fundamental plant biochemistry and biotechnology. It covers key topics such as the importance of biochemistry, properties of water, carbohydrates, lipids, proteins, and enzymes. Additional topics include nucleic acids, metabolism, plant biotechnology techniques, and applications in agriculture.

Full Transcript

Fundamental of Plant Biochemistry and Biotechnology

Course Name : FUNDAMENTAL OF PLANT BIOCHEMISTRY
AND BIOTECHNOLOGY

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 Fundamental of Plant Biochemistry and Biotechnology AME 111

- 111 Fundamentals of Plant Biochemistry and Biotechnology
A-Theory
S.No Topics No. of Lec.
1 Importance of Biochemistry; Properties of Water, pH and 1
Buffer
2 Carbohydrate: Importance and classification; Structures of 3
Monosaccharides, Reducing and oxidizing properties of
Monosaccharides, Mutarotation
3 Structure of Disaccharides and Polysaccharides 1
4 Lipid: Importance and classification; Structures and 2
properties of fatty acids
5 Proteins: Importance of proteins and classification; 2
Structures, titration and zwitterions nature of amino acids
6 Structural organization of proteins 1
7 Enzymes: General properties; Classification; Mechanism of 2
action
8 Michaelis & Menten and Line Weaver Burk equation & plots 1
9 Nucleic acids: Importance and classification 1
10 Structure of Nucleotides, A, B & Z DNA 2
11 RNA: Types and Secondary & Tertiary structure 2
12 Metabolism of carbohydrates: Glycolysis, TCA cycle, 3
Glyoxylate cycle, Electron transport chain
13 Metabolism of lipids: Beta oxidation, Biosynthesis of fatty 2
acids
14 Concepts and applications of plant biotechnology 1
15 Nutritional Requirement in Tissue Culture 1
15 Techniques in in vitro culture: Callus culture, Organ culture, 2
cell suspension culture, embryo culture, anther and pollen
culture, ovule culture and their applications
16 Micro-propagation methods 1
17 Organogenesis and somatic embryogenesis 1
18 Synthetic seeds and their significance 1
19 Somatic hybridization and cybrids 1
20 Application in crop improvement of somatic hybrids and 1
cybrids
21 Somaclonal variation and its use in crop improvement; Cryo- 1
preservation
22 Introduction to recombinant DNA methods 1
23 Physical (Gene gun method), chemical (PEG mediated) and 2
Agrobacterium mediated gene transfer methods
24 Transgenics and its importance in crop improvement 2
25 PCR techniques and its applications 1
26 RFLP, RAPD, SSR 2
27 Marker Assisted Breeding in crop improvement 2
28 Biotechnology regulations 1
Total lectures of theory 44

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Introduction of Biochemistry
Biochemistry comprises study of chemical nature of living organisms and their
relationship with their environment. It tries to explain life processes at molecular level; the
processes by which an exchange of chemical substances takes place between the living
organisms and the environment the processes by which the absorbed materials are utilized
for synthetic reactions leading to growth and replenishment of tissues and multiplication
of the cell and the species the metabolic breakdown of the materials to supply energy for
all the above and the mechanisms which regulate with precision all these processes. All
these studies come under the purview of biochemistry. Correlation of biological functions
and molecular structures is the central theme of biochemistry.
Biochemistry includes various aspects of organic chemistry, physical chemistry,
physics, biology and other basic disciplines. It is also interrelated with physiology,
microbiology, medicine and agriculture.
Importance of biochemistry
During the early part of the twentieth century, the central theme of biochemistry was the
development of the field of intermediary metabolism that is the elucidation of the
pathways for the synthesis and degradation of the constituents of living organisms.
Although studies concerned with intermediary metabolism continue to be important, at
present, biochemical research may be classified into the following major areas:
1. Composition and characteristics of chemical compounds of living organisms.
2. Cell ultra structure.
3. Cellular control mechanisms.
4. Physical chemistry of bio macromolecules.
5. Structure-function, kinetics, regulation and mode of action of enzymes.
6. Intermediary metabolism.
7. Bioenergetics particularly the mechanisms of formation of adenosine triphosphate
(ATP) in the process of oxidative phosphorylation.
8. The molecular basis for genetic and developmental phenomena.
9. The molecular basis for physiological phenomena including nerve conduction, muscle
contraction, vision and transport across membrane
10. Role, transformation and requirement of nutrients in plants, animals and other
organisms.
11. Chemistry of inheritance: structure-function and regulation of gene expression.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Contribution of biochemistry in various field of Biology
Several research done in field of biochemistry, microbiology, molecular genetics, cell
biology and recombinant DNA has led to the development of 'biotechnology'. In 1981, the
European Federation of Biochemistry defined this branch of science as "the integrated use
of biochemistry, microbiology and chemical engineering in order to achieve the
technological application of the capacities of microbes and culture cells". A recent off-
shoot of biotechnology research is genetic engineering, which involves gene splicing and
recombinant DNA cloning.
Some of the applications of genetic engineering and biotechnology in various fields are
listed below:
1. Agriculture Improvement of crop plants for higher photosynthetic
efficiency, nutrient and water uptake, biological nitrogen
fixation, nutritional quality of cereals, resistance to pests and
diseases, plant cell and tissue culture and improvement of
animal stock for desirable characteristics
2. Chemical industry Transformation of substances by biocatalysts to products
such as biopolymers, antibiotics, alternative structural
materials to plastics
3. Energy industry Production of new fuel sources and improved efficiency of
energy recovery from existing ones.
4. Food industry Production of colourants, sweeteners, preservatives, etc

5. Fermentation Production of beer, wine, alcohols, amino acids, vitamins,
industry etc.,
6. Public health Production of vaccines, drugs, growth hormones, interferons
monoclonal antibodies, etc., use of bacteria in waste water
treatment and recycling and pollution control

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Properties of Water, pH and Buffer
Water is the most abundant substance in living systems, making up 70% or more of the
weight of most organisms. The attractive forces between water molecules and the slight
tendency of water to ionize are of crucial importance to the structure and function of
biomolecules. The water molecule and its ionization products, H+ and OH-, profoundly
influence the structure, self-assembly and properties of all cellular components, including
proteins, nucleic acids and lipids. The noncovalent interactions responsible for the strength
and specificity of “recognition” among biomolecules are decisively influenced by the
solvent properties of water, including its ability to form hydrogen bonds with itself and
with solutes.
Properties of water
Water is a polar molecule.
It has hydrogen bonding potential
It has Specific heat, heat of vaporization
Nucleophilic
Ionization
Water is an ideal biological solvent
Water is a polar molecule
It is a polar molecule: Atoms are held together by polar covalent bonds. This gives the
oxygen as light negative charge (δ-) and each hydrogen as
light positive charge (δ+). Hydrogen atoms are attached to the
oxygen at an angle of 104.5o.

Hydrogen bonding gives water its unusual properties
Each water molecule can form up to four hydrogen bonds (with the oxygen
accepting two hydrogen bonds, and with each hydrogen acting as an hydrogen bond
donor). The arrangement is roughly tetrahedral. The H–O–H bond angle does not allow
the formation of a perfect tetrahedron. (Note that in actual water, the average number
of hydrogen bonds per water molecule is less than four, probably due to geometry
constraints and entropic effects.)
The ability of the water molecule to participate in extensive hydrogen bonding
networks is responsible for most of the unusual bulk properties of water, including its high

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Fundamental of Plant Biochemistry and Biotechnology AME 111

melting and boiling points, ∆H of vaporization, and
surface tension.
A look at the electron structure of the H2O molecule
reveals the cause of these intermolecular attractions.
Each hydrogen atom of a water molecule shares an
electron pair with the central oxygen atom. The geometry
of the molecule is dictated by the shapes of the outer
electron orbitals of the oxygen atom, which are similar
to the sp3 bonding orbitals of carbon. These orbitals
describe a rou gh tetrahedron, with a hydrogen atom at
each of two corners and unshared electron pairs at the
other two corners. The H-OH bond angle is 104.5o,
slightly less than the 109.5o of a perfect tetrahedron
because of crowding by the nonbonding orbitals of the
oxygen atom.
The oxygen nucleus attracts electrons more strongly than does the hydrogen nucleus (a
proton); that is, oxygen is more electronegative. The sharing of electrons between H and O
is therefore unequal; the electrons are more often in the vicinity of the oxygen atom than
of the hydrogen. The result of this unequal electron sharing is two electric dipoles in the
water molecule, one along each of the H-O bonds; each hydrogen bears a partial positive
charge and the oxygen atom bears a partial negative charge equal to the sum of the two
partial positives. As a result, there is an electrostatic attraction between the oxygen atom
of one water molecule and the hydrogen of another (Fig. 2–1c), called a hydrogen bond.
Hydrogen bonds are relatively weak. Those in liquid water have a bond dissociation
energy (the energy required to break a bond) of about 23 kJ/mol, compared with 470
kJ/mol for the covalent O-H bond in water or 348 kJ/mol for a covalent C-C bond. The
hydrogen bond is about 10% covalent, due to overlaps in the bonding orbitals, and about
90% electrostatic.
Water as solvent
Hydrogen bonds between water molecules provide the cohesive forces that make water a
liquid at room temperature and that favor the extreme ordering of molecules that is typical
of crystalline water (ice). Polar biomolecules dissolve readily in water because they can
replace water-water interactions with more energetically favorable water-solute
interactions. In contrast, nonpolar biomolecules interfere with water-water interactions but

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Fundamental of Plant Biochemistry and Biotechnology AME 111

are unable to form water-solute interactions consequently, nonpolar molecules are poorly
soluble in water. In aqueous solutions, nonpolar molecules tend to cluster together.
Hydrogen bonds and ionic, hydrophobic (Greek, “water-fearing”), and van der Waals
interactions are individually weak, but collectively they have a very significant influence
on the three-dimensional structures of proteins, nucleic acids, polysaccharides, and
membrane lipids.
Ionization of water
Water spontaneously ionizes to release free protons and free hydroxyl ions. In aqueous
media, free H+ doesn’t typically exist. Instead, the dissociated proton is shared
between many other water molecules to form transient H3O+ and related species.
H2O H+ + OH–
For simplicity, in the following discussion the symbol H+ will be used to reflect the shared
ion. Aqueous solutions do contain free hydroxyl ions, although these ions, as with all
ions in aqueous solution, have a hydration shell
K= [H+] [OH–]
[H2O]
However, in aqueous solution, the concentration of H2O is so high that it is
not
significantly altered by the extremely small amount of dissociation that occurs. The
effectively constant water concentration is generally included in the equilibrium K term to
simplify the calculations.
Kw = [H+][OH–] = 10 -14M2
In pure water, therefore, [H+] = [OH–] = 10 -7M
To simplify discussion another term was introduced to describe small
concentrations of hydrogen ions: pH, which is defined as the negative log of the
hydrogen ion concentration. Neutral is defined as pH 7.0, because this is the pH for water
with no additional ions present. Because pH is a log function, a change of one pH unit
(e.g., from pH 7 to pH 6) corresponds to a 10-fold change in hydrogen ion concentration.
Weak acids
Unlike strong acids, some compounds capable of releasing protons do not completely
ionize in aqueous solution. For example, acetic acid also dissociates to yield a free proton
and acetate ion (the conjugate base of acetic acid):

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Again, this process reaches equilibrium, with the dissociation constant given by:

For acetic acid, Ka = 1.75 x 10 -5M; this indicates that only a small proportion of the acetic
acid will dissociate. As with hydrogen ion concentrations, this dissociation constant value
is somewhat clumsy to deal with, and therefore, as with pH, it is frequently worth
using the negative log of the Ka: pKa = 4.75. By contrast, HCl has a pKa of -7. This
illustrates a general principle: a higher pKa corresponds to a higher affinity for protons. To
determine the pH, the equilibrium equation can be rearranged to solve for hydrogen
ion concentration:

Taking the negative log of both sides gives:

This is the same as:

which is the classic Henderson-Hasselbalch equation. For acetic acid (and for all weak
acids), when [Ac–] = [HAc] the solution pH is equal to the pKa. The Henderson-
Hasselbalch equation can be used to solve for the relative amounts of acid and
conjugate base present at any pH.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Buffers
Solutions containing mixtures of weak acids and their conjugate bases resist changes
in pH due to the addition of either
hydrogen ions or hydroxide ions. These
solutions are buffers. Buffers are
critical for maintenance of pH control
both in experiments in vitro and in
physiological systems (although
physiological systems also use active
mechanisms to control pH).
Weak acids have the ability to act as
buffers. Because the conjugate base of a
weak acid has a relatively high affinity
for hydrogen ions, it will absorb any hydrogen ions added to a solution;
alternatively, if the pH increases, the weak acid can release hydrogen ions. Adding
HCl to water causes a rapid drop in pH to a final pH of 1. On the other hand, in the
presence of Tris base (a commonly used buffer compound), the decrease in pH is
markedly attenuated, with the final pH being 2 pH units higher. In the titration shown
below for 0.1 M Tris, the solution pH changes from a high value to a low value upon
addition of the strong acid HCl. The inflection point at 0.5 equivalents of strong acid
corresponds to the pKa of the protonated form of Tris. As is apparent in the plot,
between about 0.05 and 0.95 equivalents (corresponding to ±1 pH around the pKa),
the system resists change in pH. (Note that, to a very good approximation, all of the
added protons can be assumed to become bound by the conjugate base; the pH change
then results from the altered ratio of conjugate base to weak acid.)
In principle, the Henderson-Hasselbalch equation can be used to calculate the pH of a
buffer given the ratio of weak acid and conjugate base, or to calculate the amount of weak
acid and conjugate base that must be added to a solution to obtain a desired pH. Because,
in most cases, real solutions deviate from ideal behavior, most biochemists obtain the
desired pH by titrating a solution while directly measuring pH using a pH meter. The
Henderson-Hasselbalch allows an estimate of the amount of strong acid or strong base
that must be added to obtain the correct pH, which tends to make buffer preparation less
tedious.
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Carbohydrates
Based on chemical constitution, the carbohydrates or saccharides are most simply defined
as polyhydroxy aldehydes or ketones and their derivatives. But this definition is not
entirely satisfactory. Because, presence of free carbonyl group (>C=O) in the simple
carbohydrate molecule is not true. Because carbonyl compound reacts with an alcohol to
form a hemiacetal. In carbohydrate,we have an aldehyde group which combine with an
alcoholic –OH of the same molecule to form an interal hemiacetal and by elimination of
H2O between the hemiacetal –OH group of two sugar molecules are formed. So that the
definition of carbohydrate may be improved by a polyhydroxy compound that has an
aldehyde or a ketone function present, either free or as hemiacetal or acetal. Carbohydrates
are composed of carbon, hydrogen and oxygen possessing a common empirical formula
Cn(H2O)n.
Occurrence
Carbohydrates are the most abundant of all biochemical compounds and constitute more
than 50 percent of the total biochemical matter. They are widely distributed in plants,
animals and microbes. They are synthesized in green plants and algae from water and CO2
using solar energy in a process called photosynthesis.
Physiological role and biological importance
The carbohydrates serve many functions in the living organisms. Some of their vital
functions are:
1. Chief source of energy (4 kcal/g).
2. Reserve or storage forms of energy in plants (starch, inulin) and animals (glycogen).
3. Structural elements in plant cell wall (cellulose), exoskeleton of some insects and
crustacea (chitin), cell walls of certain microorganisms (peptidoglycans) and skin and
connective tissues of animals (mucopolysaccharides).
4. Important components of nucleic acids, co-enzymes and flavoproteins (for example,
ribose).
5. They are involved in cell recognition, contact inhibition and also have antigenic

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properties of blood group substances.

Classification
The carbohydrates can be classified into three main groups as: a) monosaccharides, b)
oligosaccharides and c) polysaccharides, based on number of monomeric sugar units
present. Monosaccharides are the simplest sugars consisting of single polyhydroxy
aldehyde or ketone group that cannot be hydrolyzed into smaller units under reasonable
mild conditions. They serve as the building-blocks for the more complex sugars.
Oligosaccharides (Greek Oligo 'few') contain from two to ten monosaccharide units joined
through glycosidic linkage or bond. They are hydrolysable into constituent
monosaccharide units.
Polysaccharides are polymers of monosaccharide units joined in long linear or
branched chains through glycosidic bonds. Hydrolysis of polysaccharides yields many
units of constituent monosaccharides. Polysaccharides have two major biological
functions: a) as a storage form of fuels and b) as structural elements in living organisms.
1. Monosaccharides (simple sugars)
Monosaccharides, also called as simple sugars have the empirical formula (CH2O)n,
where n=3 or larger number. They contain a short chain of carbon atoms with one
carbonyl group, each of the remaining carbon atoms bearing a hydroxyl group. If the
carbonyl group is an aldehyde (-CHO) the sugar is called as an aldose (name ends in 'ose')
and if a ketone (C=O) it is a ketose (usually ends in 'ulose'). The simplest monosaccharides
are the 3-carbon trioses glyceraldehyde and dihydroxyacetone.

Glyceraldehyde is an aldotriose; dihydroxyacetone is a ketotriose. Other
monosaccharides are tetroses (four carbons), pentoses (five carbons), hexoses (six
carbons), heptoses (seven carbons) and octoses (eight carbons). Each exists in two series,

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ie., aldotetroses and ketotetroses; aldopentoses and ketopentoses; aldohexoses and
ketohexoses, etc. Hexoses (both aldoses and ketoses) are the most abundant among
monosaccharides. Glucose (aldohexose) is the most abundant monosaccharide; serves as
the major fuel for most organisms and the- basic building-block of the many oligo- and
polysaccharides. However, aldopentoses are important components of nucleic acids (for
example, ribose) and various polysaccharides (for example, xylose and arabinose).
Trioses, tetroses and heptoses are important intermediates in carbohydrate metabolism.
Table: Some important monosaccharides.
Name Major source Function Type No. of
carbons
Xylose Hydrol,ysis of wood, Constituent of Aldopentose 5
(wood straw, seed hulls straw, seed hulls
sugar) wood,
Arabinose Hydrolysis of gum Constituent of Aldopentose 5
arabic, cherry tree gum arabic
gum, pectin
Ribose Hydrolysis of nucleic Constituent of Aldopentose 5
acids nucleic acids
Glucose Ripe fruits, sweet Energy source Aldohexose 6
(dextrose) corn,
honey, blood, egg
yolk
Mannose Hydrolysis of Constituent of Aldohexose 6
mannans mannans
Galactose Hydrolysis of lactose Constituent of Aldohexose 6
milk sugar
Fructose Honey, sweet fruits Energy source Ketohexose 6
(levulose)

General properties
Some of the general properties of monosaccharides are summarized below:
b) Monosaccharides are polyhydroxy aldehydes or ketones and their derivatives having
either a potentially free aldehyde or a ketone group.
c) Simplest form of carbohydrates which cannot be hydrolyzed to other sugar units
under reasonably mild chemical conditions.
d) Generally monosaccharides are white crystalline solids, insoluble in ether, sparingly
soluble in alcohol but readily soluble in water.
e) Most of them have a sweet taste and char when heated.
f) Those with potentially a free aldehydic or a ketonic group are able to reduce metal
ions under alkaline conditions. Hence, they are excellent reducing agents.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

g) Amphoteric nature i.e., they are capable of reacting as weak acids or weak bases with
strong acids or alkalies to form salts.
Stereochemistry
All the monosaccharides except dihydroxyacetone contain one or more asymmetric
carbon atom(s) i.e., a single carbon atom having four different substituents and thus are
chiral molecules. Subcompounds are capable of existing in two or more isomeric forms
that are non-superimposable mirror images of each other. Such com· pounds exist in right-
handed forms and are called chiral (hand) compounds. This phenomenon is called chirality
(handedness).
Glyceraldehyde contains only one asymmetric carbon atom (carbon atom, 2) and
therefore can exist as two different stereoisomers, i.e., as D- and L- glyceraldehyde. The
symbols D- and L- designate the absolute configuration of an isomer and not the sign of
rotation of plane-polarized light. The structure with -OH group on the right and –CHO
group on the top of the asymmetric carbon atom is designated as D-glyceraldehyde. The
structure in which the -OH group is to the left and -CHO group on the top is designated as
L-glyceraldehyde.
The D- and L-glyceraldehydes are used as reference or parent compounds for
designating the absolute configuration of all stereoisomeric compounds. The term
configuration refers to the special arrangement of the atoms in a molecule resulting from
the double bonds and/or chiral centers. Configurational isomers cannot be interconverted
without breaking one or- more covalent bonds.
Enantiomers
Aldoses and ketoses of the L-series are mirror-images of their D-counterparts as
shown in Fig. 2.5. These two D- and L- forms of a sugar are known as enantiomers. L-
sugars are found in nature, but they are not so abundant as D-sugars.
Diastereoisomers
Two sugars having the same molecular formulae but not the mirror images of each
other are known as diastereoisomers. e.g. D-glucose and D-mannose. All these sugars are
not mirror images of each other.
Epimers
Two sugars differing only in the configuration around one specific carbon atom are
called epimers of each other. Thus, D-glucose and D-mannose are epimers with respect to
carbon atom 2, and D-glucose and D-galactose are epimers with respect to carbon atom 4.
Optical activity
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Fundamental of Plant Biochemistry and Biotechnology AME 111

All the monosaccharides except dihydroxyacetone contain one are more asymmetric
carbon atom(s) and thus are optically active. Optical activity refers to the ability of a
compound in solution to rotate the plane of polarization of plane-polarized light when
observed in a polarimeter. Optical activity is shown by all compounds capable of existing
in two forms that are non-superimposable mirror images of each other.
The optical activity is expressed quantitatively as the specific rotation:

Where, α = specific rotation in degrees at temperature usually 25 oC and the wavelength of
the light employed (usually the D line of sodium) is 589.3nm.
If the rotation of the beam of plane-polarized light is clockwise (to the
right or rectus as the observer looks towards the light source), the enantiomer is designated
as dextrarotatory (dextro, 'd' or '+' symbols) and if it is anticlockwise (to the left or
sinister), the enantiomer is designated as levorotatory (levo, '1' or '-' symbols). For
example, the specific rotation of a-D-glucose is + 112.2o (dextrarotatory) and that of D-
fructose is -930 (levorotatory). Thus, the symbol '+' and '-' refer to the direction of rotation
of the beam of plane-polarized light but not the absolute configuration.
The D-and L-stereoisomers of any given compound have identical physical properties and
identical chemical reactivities, with two exceptions: (a) they rotate the plane of plane-
polarized light equally but in opposite directions and (b) they react at different rates with
reagents that are themselves asymmetric. The equimolar mixture of the D- and L-
stereoisomers, known as racemic mixture or racemate (designated as D L-) is optically
inactive as the asymmetric carbon atom passes through a symmetrical intermediate during
chemical reaction.
Structural aspects
Ring structure and mutarotation
In aqueous solution, many monosaccharides act as if they have one more asymmetric
center than is given by the open chain structural formulae. D-glucose may exist in two
different isomeric forms differing in specific rotation, α-D-glucose (Crystallizes from a
concentrated aqueous solution at 30°C , melting point 146°C), for which [α]D20 = + 112°,
and β-D-glucose (Crystallizes from hot glacial acetic acid solution, melting point 148-
150°C), for which [α]D20 = +19°. These two sugars do not differ in elementary
composition but differ in physical and chemical properties. When the α- and β-isomers of
D-glucose are dissolved in water, the optical rotation of each gradually changes with time

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and approaches a final equilibrium value of [α]D20 = +53°. This change, called
mutarotation is due to the formation of an equilibrium mixture consisting of about one-
third α-D-glucose and two thirds β-D-glucose at 20°C.
Although carbohydrates are formally aldehydes or ketones, a sugar like glucose does not
readily answer the normal reactions of aldehydes as would be expected; this is because of
their existence as cyclic hemiacetals or hemiketals. Aldehydes can react with an alcohol to
form a hemiacetal; similarly ketones can react with an alcohol to form a hemiketal.
Anomers
From various chemical considerations it has been deduced that the α- and β-isomers
of D-glucose are not open-chain structures in aqueous solution but six-membered ring
structures formed by the reaction of the alcoholic hydroxyl group at carbon atom 5 with
the aldehydic carbon atom 1 to form a hemiacetal which renders an other chiral center at
carbon atom 1, also known as carbonyl carbon atom or anomeric carbon atom. Isomeric
forms of monosaccharides that differ from each other only in configuration about the
carbonyl carbon atom are known as anomers. Thus, D-glucose will have two anomers
designated as α-D-glucose and β-D-glucose.
As hemiacetal or hemiketal formation is
reversible, if one of the anomers is dissolved
in water, an equilibrium mixture of the two
anomers results. This interconversion
between the two anomers is due to
mutarotation. The cyclic hemiacetal
formation in the case of glucose by the
reaction of the alcoholic hydroxyl group at
carbon 5 with the aldehydic carbon atom 1
results in formation of six-membered ring.
The six-membered ring forms of sugars are
called pyranoses because they are derivatives
of the heterocyclic compound pyran. Thus, the systematic name for the ring form of α-D-
glucose is α-D-glucopyranose.
In the case of fructose, the hemiketal is formed by reaction of the hydroxyl group on
carbon atom 5 with the carbonyl group at carbon atom 2 to yield a five-membered ring.
The five-membered ring forms of sugars are called furanoses as they are derivatives of
heterocyclic compound, furan (Fig. 2.8) as suggested by Haworth. The systematic name

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for the ring form of α-D-fructose is α-D-fructofuranose.

2. Oligosaccharides
These sugars consist of a short chain of 2 to 10 monosaccharide units linked by the
glycosidic bond (s) with the elimination of water molecule (s). The glycosidic bond is
formed most frequently between the anomeric carbon of one sugar residue and a hydroxyl
group of the other sugar residue. Depending on the number of monosaccharide units that
are linked, the oligosaccharides are further classified as disaccharides (two sugar units),
trisaccharides (three sugar units), tetrasaccharides (four sugar units), etc. Amongst these,
disaccharides are the most important class because of their biological role and relative
abundance in natural products.
2.1.Disaccharides (C12H22O11).
These are a group of compound sugars composed of two monosaccharides linked by the
glycosidic bond with the elimination of one molecule of water.
General properties
1. Those with potentially a free aldehyde or a ketone group can reduce Fehling's
solution, hence are called reducing disaccharides.
2. The reducing disaccharides have most of the properties of monosaccharides i.e., they
can form osazones and show mutarotation, etc.
3. Disaccharides can be hydrolyzed into their constituent monosaccharide units unlike
monosaccharides.
4. Some disaccharides may exist in white crystalline solids and are soluble in water and
sweet in taste.
5. Disaccharides are not fermented by yeast directly but they are first hydrolyzed to
constituent monosaccharides which in turn are fermented.
The most abundant disaccharides in nature are maltose, sucrose and lactose.
2.1.1 Maltose
It is a disaccharide formed by linking
two units of α-D-glucose through α-1,4
glycosidic bond with the elimination of
one molecule of water '(Fig. 2.20). It is
a reducing sugar since the -OH group
bound to carbon 1 of the glucose residue

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is free and can exist in the aldehyde form. It exhibits mutarotation since it exists in both α-
and β-forms. Malt prepared from sprouting barely, is an excellent, source of maltose.
2.1.2 Sucrose (α-D-glucopyranosyl-β-D-fructofuranoside)
Sucrose or cane sugar or beet sugar or
saccharose or invert sugar is a disaccharide
made up of one molecule each of α-D-
glucose and β-D-fructose, the linkage
involving the potential aldehyde group of
carbon atom 1 of glucose and the ketonic
group of the carbon atom 2 of fructose (β,2-
>1) linkage. It is a non-reducing.sugar
because of the absence of a potentially free aldehyde or ketonic group and forms no
osazone. As it does not exist in α- and β-forms, it fails to exhibit mutarotation.
It is hydrolyzed by acid or enzyme sucrase (invertase) into glucose and fructose. The
specific rotation of sucrose is +66.5° and after hydrolysis, the specific rotation of the
mixture is -19.84°. Such a change in specific rotation. from dextro- to levorotatory nature
is called 'inversion' and hence the name 'invert sugar'. The reason for the inversion is that
fructose is more strongly levorotatory (-93° than glucose which is dextrarotatory (+52.5°).
It is the most abundant oligosaccharide and is ubiquitous in plants. It is generally
manufactured from sugarcane and sugar beet.
2.1.3 Lactose (4-O-β-D-galactopyranosyl-D-glucopyranose)
Lactose or milk sugar is made up of β-D-
galactose and α-(in α-form) or β-(in β-form)
D-glucose through β-1, 4 glycosidic bond
(Fig. 2.20). It is a reducing sugar, exhibits
mutarotation and forms osazone. It reduces
Fehling's solution but not Barfoed's reagent
and thus can be distinguished from other
reducing disaccharides. It is hydrolyzed by the enzyme lactase into its constituent hexoses.
It does not ferment as easily as glucose and hence makes an ideal constituent of milk of
mammals (about 5 g/100 ml milk). It is not produced in plants.
2.1.4 Cellobiose (4-O-β-D-glucopyranosyl-D-glucopyranose)
It is a partial hydrolytic product of cellulose, made up of two glucose units joined through
β-1, 4 linkage (Fig. 2.20). It is a reducing sugar. It is probably present in only trace

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Fundamental of Plant Biochemistry and Biotechnology AME 111

amounts in nature and formed during the digestion of cellulose by the cellulases of
microorganisms.
2.1.5 Trehalose (1-O-α-D-glucopyranosyl-1-α-D-glucopyranoside)
It is made up of two glucose units linked through two anomeric carbon atoms. It is a non-
reducing sugar. It is the major carbohydrate present in insects and fungi where it serves as
a storage carbohydrate from which glucose may be obtained as required.
2.2 Trisaccharides (C18H34O17)
A naturally occurring trisaccharide is raffinose [α-D-galactopyranosyl-O-( 1,6-α-D-
glucopyranosyl-O-(1,2) –β-D-fructofuranoside] found in sugar beet, coffee and other plant
materials. It is a non-reducing sugar.
Melezitose[O-α-ODglucopyranosyl(1->3)-O-β-D-fructofuranosyl(2,1)-α-D
glucopyranoside] is found in the sap of some coniferous trees.
2.3 Tetrasaccharides
The important one among tetrasaccharides is the stachyose derived from raffinose.
Stachyose consists of galactose-galactose-glucose-fructose monosaccharide sugars linked
through α-1, 6, α-l, 6 and α-1, 2 glycosidic bonds, respectively. It occurs during
germination of seeds.
3. Polysaccharides or glycans (C5H10O5)n
These are complex carbohydrates which are polymerized anhydrides of a large but
undetermined number of the simple sugars which are joined by glycosidic bonds. Those
found in nature contain either five or six carbon monosaccharide units. The bulk of carbon
found in nature exists in the form of polysaccharides. These are involved in the majority of
biological processes although free monosaccharides and disaccharides occur in many
biological fluids and plants.
General properties
Some of the important properties of polysaccharides are as follows:
1. Complex sugars of high molecular weight; polymers of several units of
monosaccharides or either derivatives with linear or branched chains.
2. Upon hydrolysis by acids or enzymes, they are broken down into various intermediate
products and finally into their consituent monosaccharides or their derivatives.
3. They are tasteless, apparently amorphous, some are crystalline
4. Mostly insoluble in cold water but form a sticky or gelatinous solutions
5. They differ in the nature of their recurring monosaccharides units, in the length of
their chains and in the degree of branching

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Biological role
Polysaccharides serve two main functions in the living organisms as:
1. Storage form of cellular fuel and
2. Structural elements in animal, plant and microbial systems
Classification
Polysaccharides can be classified in many ways
A. Based on function
1. Structural polysaccharides: These polysaccharides serve as structural components of
living organisms. e.g. cellulose (plant cell wall), chitin (exoskeleton of some insects), etc.
2. Storage/reserve/nutrient polysaccharides: These polysaccharides function as
reserve or storage form of fuel in living organisms e.g. starch (plants), glycogen (animal
cells) etc.
B. Based on composition:
1. Homopolysaccharides: These are made up of single kind of monosaccharide
residues or their derivatives. e.g. Starch, glycogen, cellulose, chitin, inulin, etc.
2. Heteropolysaccharides: These are made up of two or more different kinds of
monosaccharide units or their derivatives. e.g. Hyaluronic acid, heparin, pectins,
gums, mucilages, chondroitins, etc.
Polysaccharides are often called as glycans. Those containing glucose are called as
glycans (starch and glycogen); those containing mannose are called mannans and those
containing galactose units are called galactans.
Structural polysaccharides
Cellulose
It is the most abundant organic compound of our planet accounting for about 50 per
cent of all carbon. It is the principal constituent of cell walls in higher plants forming the
main structural element. It is a linear homopolymer of glucose units linked by β-1,4
glycosidic bonds. It is insoluble in water and all organic solvents. It dissolves in conc.
H2SO4, on diluting the solution and boiling, glucose is formed as final product. Partial
hydrolysis of cellulose yields cellobiose, a disaccharide. Cellulase, a β-glucosidase
produced by many bacteria and fungi, hydrolyzes cellulose. The large amount of glucose
present in cellulose is not available as a source of energy for humans due to the lack of
enzymes capable of cleaving the β-1,4 bonds. However, ruminants can effectively use
cellulose as they contain a large bacterial population in their rumen capable of hydrolyzing
it.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

In plant cell walls, cellulose microfibrils are cemented together by other substances
important among them being pectin and hemicellulsoe. Pectins contain arabinose,
galactose and glacturonic acid while hemicelluloses are homopolymers of D-xylose linked
by β- 1,4 bonds. The important sources of cellulose are cotton fibers (98%), jute (50-70%),
wood (40-50%), algae and bacteria. Cellulose and its derivatives are widely used in
textiles, films and plastics.
Chitin
It is a structural homopolysaccharide made up of N-acetyl glucosamine residues in β-
1,4 linkage. It is the principal structural polysaccharide present in the exoskeleton of
crustaceous insects, earthworms and mollusks. It is the second most abundant organic
substance on earth.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Table: Structure and functions of some polysaccharides
No. of
Polymer Type Repeating unit monosaccharide Role
unit
Starch
A linear polymer of D-glucose
Amylose Homo 50-50000
residues in (α1→4) linkage.
Glucose residues in amylopectin Energy storage: in plants
chains are (α1→4); the branch
Amylopectin Homo Up to 106
points (Occurring every 24 to 30
residues) are (α1→6) linkages.
polymer of (α 1→4)-linked
Glycogen Homo subunits of glucose, with (α 1→6)- Up to 50000 Energy storage: in bacteria and animal cells
linked branches,
D-glucose residues are in Structural: in plants, gives rigidity and
Cellulose Homo Up to 15000
(β1→4)linkage strength to cell walls
A homopolymer of N-acetyl-D-
Structural: in insects, spiders, crustaceans,
Chitin Homo glucosamine units in (β1→4) Very large
gives rigidity and strength to exoskeletons
linkage.
(α1→6)-linked poly-D-glucose Structural: in bacteria, extracellular
Dextran Homo Wide range
with (α1→3) branches adhesive
Hetero-; (β1→4)-linked N-
Structural: in bacteria, gives rigidity and
Peptidoglycane peptides acetylglucosamine and N- Very large
strength to cell envelope
attached acetylmuramic acid residues
D-galactose (β1→4)-linked to 3,6-
anhydro-L-galactose that are
Agarose Hetero- 1000 Structural: in algae, cell wall material
joined by (α1→3) glycosidic links
to form polymer
Hyaluronate Structural: in vertebrates, extracellular
Hetero-; D-glucuronic acid(β1→3) and N-
(a glycosamine Up to 100000 matrix of skin and connective tissue;
acidic acetylglucosamine (β1)
-glycan) viscosity and lubrication in joints

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Fundamental of Plant Biochemistry and Biotechnology AME 111.
Peptidoglycan (murein)
It is a structural heteropolysaccharide present in bacterial cell walls. The repeating unit of
peptidoglycan is the muropeptide which is a disaccharide composed of N-acetyl-D-
glucosamine (NAG) and N-acetyl muramic acid (NAMA) joined by a, β-1,4 glycosidic bond.
NAMA consists of a NAG unit which has its C-3 hydroxyl group joined to the hydroxyl group
of lactic acid by an ether linkage.. In the peptidoglycan the carboxyl group of each lactic acid
moiety is in turn linked to a tetrapeptide consisting of L-alanine, D-isoglutamine, L-lysine and
D-alanine (Fig. 2.21). The terminal D-alanine residue of the side chain of one polysaccharide
chain is joined covalently with the peptide side chain of an adjacent polysaccharide chain,
either directly as in E.coli or through a short conneting peptide, e.g. The pentaglycine in
Staphylococcus aureus.
The peptidoglycan structure of the bacterial cell wall is resistant to the action of peptide-
hydrolyzing enzymes, which do not attack peptides containing D-amino acids. However, the
enzyme lysozyme, found in tears and in egg white, hydrolyzes the β(1 4) glycosidic bonds of
the polysaccharide backbone of the peptidoglycan structure.
Reserve or storage polysaccharides
Starch
It is a principal storage homopolysaccharide of the plant kingdom, made up of D-glucose
as repeating units. It is a mixture of two components amylose (about 20%) and amylopectin
(about 80%) Amylose consists of long unbranched chains of D-glucose units which are linked
by α-1, 4 glycosidic bonds. Its molecular wieght ranges from a few thousands of about
500,000. It gives blue colour with iodine due to the iodine-amylose complex in which iodine
molecule is occupying a position in the interior of the helical coil. Amylopectin also has a
backbone of α-1, 4 linked glucose units but in addition, branched through α-1, 6 linkages. The
average length of branching is from 24 to 30 glucose residues. It gives a purple colour with
iodine. Its molecular weight may range from 50,000 to 1,000,000.
Both amylose and amylopectin can be hydrolyzed by the enzymes α- and β-amylases. α-
amylases cleave α-1,4 linkages at random to give the mixture of maltose and glucose units
while the β-amylases, present in plants remove maltose units succcesively from the non
reducing end. The intermediate product left after the cleavage of starch by α and β amylases is

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Fundamental of Plant Biochemistry and Biotechnology AME 111

called limit dextrins. Neither of these enzymes can hydrolyze α-1,6 linkages. Microbial
glucomylase can act on both α-1, 4 and α-1, 6 likages of starch to yield glucose.
Starch forms the major source of carbohydrates in the human diet and is of great economic
importance. The important source of starch are seeds, fruits, tubers, bulbs and cereal grains
varying from a few per cent of over 75 per cent. It is also found in some protozoa, bacteria
and algae.
Glycogen
It is the storage homopolysaccharide in animals and is often called ‘animal starch’. It is
present mainly in liver, skeletal muscle and in smaller amounts in all other tissues. It is stored
in liver and muscles of animals and split to glucose in the liver to maintain proper
concentration of glucose in the blood to furnish energy. The amount of glycogen present in
the animal varies widely among the different tissues with diet and physiological state of the
body. It is also aabundant in the mollusks while glycogens like polysaccharides are found in
some bacteria.
Glycogen is a branched chain of D-glucose units resembling amylopectin of starch.
However, the branching through α-1, 6 linkages is more extensive than amylopectin, with 8-
10 glucose units between branching points. A glycogen molecule may contain as many as
30,000 glucose units. It is readily dispersed in water to form an opalescent solution which
gives a reddish brown colour with iodine. It does not reduce Fehling’s solution.
Insulin
It is a storage polysaccharide in the Compositae family (artichokes, dahlias, dandelions,
etc). It is a homopolymer made of D-Fructose units linked by β(2→1) bonds.
Dextrans
These are storage polysaccharides of some yeasts and bacteria. They consist of D-glucose
units joined by α-1, 6 glycosidic bonds primarily with cross linkages through α-1,2 and and α-
1, 3 linkages.
Glycoproteins
Glycoproteins are molecules composed of covalently joined protein and carbohydrates.
The carbohydrate is attached to the polypeptide chains of the protein in a series of reactions
that are enzymatically catalyzed after the protein component is synthesized.
Glycoproteins in cell membranes apparently have an important role in the group behavior of

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cells and other biological functions of the membrane. They form a major part of the mucus
that is secreted by epithelial cells, where they perform an important role in lubrication and in
the protection of tissues lining the body's ducts. Many other proteins secreted from cells into
extracellular fluids are glycoproteins. These proteins include hormone proteins found in
blood, such as follicle stimulating hormone (FSH), lutenizing hormone (LH), chorianic
gonadotropin; and plasma proteins such as immunoglobulins etc. Glycoproteins are also one
of the major components of the cell coats of higher organisms.
The carbohydrate percent within glycoproteins is highly variable. Some glycoproteins such as
IgG contain low amounts of carbohydrate (4 %). Human ovarian cyst glycoprotein is
composed of 70 per cent carbohydrate and human gastricglycoprotein is 82 per cent
carbohydrate. Glycoproteins having a very high content of carbohydrate are called
proteoglycans.

*****

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Amino acid and Protein
All proteins are formed from 20 different amino acids. All the amino acids have trivial or
common names based on the source from which they were first isolated or based on their
properties. e.g. Asparagine was named so, as it was isolated from asparagus and glycine was
so named because of its sweet taste (Greek:'glykos' meaning sweet).
All the 20 amino acids, except proline, found in proteins have an amino group and a
carboxyl group attached to the same carbon atom, namely the α-carbon. They differ only in
the side chains (R groups). The 20 amino acids found in proteins are referred as the standard
or normal or protein amino acids.
There are many other amino acids found in nature but do not occur in proteins. They are
referred as non-protein amino acids.
Classification of protein amino acids
The protein amino acids are classified according to the chemical nature of their R groups as
aliphatic, aromatic, heterocyclic and sulphur containing amino acids. More meaningful
classification of amino acids is based on the polarity of the R groups. The polarity of the R
groups varies widely from totally non-polar to highly polar. The 20 amino acids are classified
into four main classes whose structures, three-letter and one-letter symbols are given below
a) Amino acids with non-polar or hydrophobic, aliphatic R groups
This group of amino acids includes glycine, alanine, valine, leucine, isoleucine and
proline. The hydrocarbon R groups are non-polar and hydrophobic. The side chains of
alanine, valine, leucine and isoleucine are important in promoting hydrophobic interactions
within protein structures. The minimal steric hindrance of the glycine side chain (hydrogen)
allows more flexibility than other amino acids. On the other hand, the imino group of proline
is held in a rigid conformation and reduces the structural flexibility of the protein.
b) Amino acids with non-polar aromatic R groups
This group includes phenylalanine, tyrosine and tryptophan. All these amino acids
participate in hydrophobic interactions, which is stronger than aliphatic R groups because of
stacking one another. Tyrosine and tryptophan are more polar than phenylalanine due to the
presence of hydroxyl group in tyrosine and nitrogen in the indole ring of tryptophan. The
absorption of ultraviolet (UV) light at 280 nm by tyrosine, tryptophan and to a lesser extent by

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Fundamental of Plant Biochemistry and Biotechnology AME 111

phenylalanine is responsible for the characteristic strong absorbance of light by proteins. This
property is exploited in the characterization and quantification of proteins.
b) Amino acids with polar, uncharged R groups
This group of amino acids includes serine, threonine, cysteine, methionine, asparagine and
glutamine. The hydroxyl group of serine and threonine, the sulphur atom of cysteine and
methionine and the amide group of asparagine and glutamine, contribute to the polarity.
The R groups of these amino acids are more hydrophilic than the non-polar amino acids.
c) Amino acids with charged R groups
Acidic: The two amino acids with acidic R groups are aspartic and glutamic acids. These
amino acids have a net negative charge at pH 7.0.
Basic: This group includes lysine, arginine and histidine. The R groups have a net positive
charge at pH 7.0. The lysine has a second -amino group; arginine has a positively charged
guanidino group; and histidine has an imidazole group.
Physical Properties of amino acids
Amino acids are white crystalline substances. Most of them are soluble in water and
insoluble in non-polar organic solvents (e.g., chloroform and ether). Aliphatic and aromatic
amino acids particularly those having several carbon atoms have limited solubility in water
but readily soluble in polar organic solvents. They have high melting points varying from
200-300oC or even more. They are tasteless, sweet or bitter. Some are having good flavour.
Sodium glutamate is a valuable flavouring agent and is used in the preparation of certain
dishes and sauces.
Amphoteric nature of amino acids
Ø Amino acids are amphoteric compounds, as they contain both acidic (COOH) and basic
(NH2) groups.
Ø They can react with both alkalis and acids to form salts.
Ø In acid solution amino acids carry positive charges and hence they move towards
cathode in an electric field.
Ø In alkaline solution, the amino acids carry negative charges and therefore move towards
anode.
Ø When an amino acid is dissolved in water, it exists as inner salt carrying both positive
and negative charges.This occurs as a result of dissociation of carboxyl group to release the

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Fundamental of Plant Biochemistry and Biotechnology AME 111

H+ ion, which passes from the carboxyl to the amino group. The amino acids possessing both
positive and negative charges are called

Zwitterions.
The zwitterion reacts as an acid with a base by liberating a proton (H+) from the NH3+
group and as a result possesses a net negative charge. On the other hand, zwitterions reacts
with an acid as base, combining with the proton (H+) of the acid resulting in the formation
of a compound having a net positive charge. These reactions are reversible. The pH at which
the amino acid has no tendency to move either towards positive or negative electrode is called
isoelectric pH or isoelectric point. At isoelectric pH, the amino acid molecule bears a net
charge of zero.

Isomerism
Ø All amino acids except proline, found in protein are -amino acids because NH2 group is
attached to the -carbon atom, which is next to the COOH group.
Ø Examination of the structure of amino acids reveals that except glycine, all other amino
acids possess asymmetric carbon atom at the alpha position.
Ø Because of the presence of asymmetric carbon atom, amino acids exist in optically active
forms.
Ø For example, in the steric configuration for serine, the carboxyl group is written on the
top, while the amino group is written to the left in the case of L-serine and to the right in the
case of D-serine This distinction will hold good for all the amino acids having asymmetric
carbon atoms.

Ø 'D' and 'L' do not refer to the optical rotation, but to the steric configuration of amino
group to the right and left side of the carboxyl group.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Ø The direction of optical rotation of amino acid is indicated by the symbol + or -, which
follows the designation 'D' or 'L'.
Ø The steric configuration and optical rotation of an amino acid may be simultaneously
expressed as D (+) or D (-) and L (+) or L (-).
Ø L-forms are more common than D-forms and most of the naturally occurring amino
acids are L-amino acids.

Chemical properties
a) Reactions due to amino group
Reaction with formaldehyde (Formal titration)
Ø Amino acid exists as zwitterion in aqueous medium. If an amino acid solution is treated
with excess of neutralized formaldehyde solution, the amino group combines with
formaldehyde forming dimethylol amino acid which is an amino acid formaldehyde
complex.
Ø Hence the amino group is protected and the proton released is titrated against alkali.
Ø This method is used to find out the amount of total free amino acids in plant samples.

Reaction with nitrous acid
Nitrous acid reacts with the amino group of amino acids to form the corresponding
hydroxyacids and liberate nitrogen gas.

Reaction with ninhydrin
Ninhydrin is a strong oxidizing agent. When a solution of amino acid is boiled with
ninhydrin, the amino acid is oxidatively deaminated to produce ammonia and a ketoacid.
The keto acid is decarboxylated to produce an aldehyde with one carbon atom less than the
parent amino acid. The net reaction is that ninhydrin oxidatively deaminates and
decarboxylates - amino acids to CO2, NH3 and an aldehyde. The reduced ninhydrin then
reacts with the liberated ammonia and another molecule of intact ninhydrin to produce a
purple coloured compound known as Ruhemann's purple. This ninhydrin reaction is
employed in the quantitative determination of amino acids. Proteins and peptides that have
free amino group(s) (in the side chain) will also react and give colour with ninhydrin.

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Reactions due to carboxyl group
Decarboxylation
Ø The carboxyl group of amino acids is decarboxylated to yield the corresponding amines.
Thus, the vasoconstrictor agent, histamine is produced from histidine.
Ø Histamine stimulates the flow of gastric juice into the stomach and the dilation and
constriction of specific blood vessels.
Ø Excess reaction to histamine causes the symptoms of asthma and various allergic
reactions.
Essential amino acids
Ø Most of the prokaryotic and many eukaryotic organisms (plants) are capable of
synthesizing all the amino acids present in the protein. But higher animals including man
possess this ability only for certain amino acids.
Ø The amino acids, which are needed for normal functioning of the body but cannot be
synthesized from metabolic intermediates, are called essential amino acids.
Ø These must be obtained from the diet and a deficiency in any one of the amino acids
prevents growth and may even cause death.
Ø Methionine, Arginine, Threonine, Tryptophan, Valine, Isoleucine, Leucine,
Phenylalanine, Histidine, and Lysine are the essential amino acids
Ø (Remember MATTVILPHLy).

Peptide
Ø Amino acids are linked together by formation of covalent bonds.
Ø The covalent bond is formed between the -carboxyl group of one amino acid and the
amino group of the next amino acid.
Ø The bond so formed between the carboxyl and the amino groups, after elimination of a
water molecule is called as a peptide bond and the compound formed is a peptide.
Ø The peptide formed between two amino acids is a dipeptide; three amino acids is a
tripeptide; few amino acids are an oligopeptide and many amino acids is a polypeptide.
Ø In writing the peptide structure, the amino terminal (N-terminal) amino acid is written
first and carboxyl terminal (C-terminal) amino acid written last.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Ø

Peptides of physiological interest
Glutathione is a commonly occurring tripeptide (glutamyl cysteinyl glycine) in many living
organisms.

Ø It has a role in detoxification of toxic compounds in physiological system.
Ø The nonapeptides (nine amino acids), oxytocin and vasopressin are important animal
peptide hormones.
Ø Oxytocin induces labor in pregnant women and controls contraction of uterine muscle.
Ø Vasopressin plays a role in control of blood pressure by regulating the contraction of
smooth muscles.
Ø A dipeptide L-aspartyl-L-phenylalanine, is of commercial importance. This dipeptide is
about 200 times sweeter than cane sugar. The methyl ester of this dipeptide is called as
aspartame and marketed as an artificial sweetener for diabetics.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Protein structure
Protein are polymer of Amino acid , the structure of Protein is rather complex which can be
divided into 4 levels of organization
1. Primary Structure
2. Secondary structure
3. Tertiary Structure
4. Quaternary Structure

The structure of Protein is comparable with the structure of a building. The amino acids
may be considered as the bricks, the wall as the Primary structure, the twists in a wall as the
secondary structure, a full fledged self contained room as the tertiary structure. A building
with similar and dissimilar rooms will be the quaternary structures.
Primary Structure
The primary structure of a protein refers to the linear sequence of amino acids in the
polypeptide chain. The primary structure is held together by covalent bonds such as peptide
bonds, which are made during the process of protein biosynthesis or translation. The two ends
of the polypeptide chain are referred to as the carboxyl terminus (C-terminus) and the amino
terminus (N-terminus) based on the nature of the free group on each extremity. Counting of
residues always starts at the N-terminal end (NH2 -group), which is the end where the amino
group is not involved in a peptide bond.
Secondary Structure
The conformation of polypeptide chain by twisting or folding is referred to as secondary
structure.
The amino acid are located close to each other in their sequence. The most common type of
secondary structure are the
a) Alpha helix.
b) Beta pleated sheet.
Both Alpha helix and beta pleated sheet patterns are stabilized by hydrogen bonds between
the carbonyl and N-H groups in the polypeptide’s backbone.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Alpha Helix
1. The Alpha Helical structure was proposed by Pauling and Corey (1951)
2. The Alpha Helix is the most common spiral, rigid, rod like structure that forms when a
polypeptide chain twists into a helical conformation. The screw sense of Alpha Helix can be
right handed (right handed) or left handed (anticlockwise), however right handed helices are
energetically more favorable. There are 3.6 amino acid residues per turn of the helix and the
distance it rises per turn is 0.54 nm each residue is related to the next one by rise of 1.5 A.
3. The Alpha Helix is stabilize by extensive hydrogen bonds in between the N-H group of
each amino acid and the carbonyl group of the amino acid four residue away, side chain of
amino acids extended outward from the central helix. The hydrogen bond are individually
weak but collectively they are strong enough to stabilize the Helix.
4. All the peptide bonds, except the first and the last in polypeptide chain participate in the
H-bonding.

Beta Pleated sheets
This is the second type of structure, proposed by Pauling and Corey.
1. Beta pleated sheets form when two or more polypeptide chain segment line up side by
side. Each individual segment is referred to as a beta-strand. Rather than being coiled, each
Beta strand is fully extended. The distance between adjacent amino acids along a beta strand
is approximately 3.5 A.
2. Beta pleated sheets are stabilized by hydrogen bonds that form between the polypeptide
backbone N-H and carbonyl groups of adjacent strand, adjacent strand can be either parallel
or antiparallel.
3. In parallel Beta pleated sheet structures, the polypeptide chains are arranged in the same
direction. However in, antiparallel Beta pleated sheet chain run in opposite directions.
Antiparallel beta pleated sheet are more stable than parallel beta pleated sheet because fully
collinear hydrogen bonds form.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Tertiary structure
1. The three dimensional arrangement of protein structure referred to a tertiary structure.
2. It is a compact structure with hydrophobic side chain held interior while the hydrophilic
groups are on the surface of the protein molecule, this type of arrangement ensures stability of
the molecule.
3. The following types of covalent and non-covalent interaction stabilize tertiary structure.
i. Hydrophobic interaction
ii. Electrostatic interaction
iii. Hydrogen bond
iv. Vander waal forces
v. Covalent bonds.
Quaternary structure
1. Some of the Proteins are composed of two or more polypeptide chains referred t o as
subunits. The spatial arrangement of these subunits is known as Quaternary Structure. Subunit
in multisubunit protein may be identical or quite different. Multisubunit Proteins in which
some or all subunits are identical are referred to as Oligomer and identical units are referred to
as protomers.
2. Polypeptide subunits assemble and are held together by the noncovalent interactions such
as hydrophobic interactions, ionic bond and hydrogen bonds.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Denaturation and Renaturation of protein
· Renaturation refers to the attainment of an original, regular three-dimensional
functional protein after its denaturation.
· When active pancreatic ribonuclease A is treated with 8M urea or mercaptoethanol, it is
converted to an inactive, denatured molecule.
· When urea or mercaptoethanol is removed, it attains its native (active) conformation.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

ENZYMES
Enzyme are biocatalysts – the catalysts of life, a catalysts is defined as a substance that
increases the velocity or rate of a chemical reaction without itself undergoing any change in
the overall process. It is well known that highly complex synthetic and breakdown reactions
take place much more rapidly and easily by the living organism. In the absence of the cell
these chemical reactions would proceed too slowly. In the laboratory, hydrolysis of protein by
a strong acid at 100 C takes at least a couple of days. The same protein is fully digested by the
enzyme in gastrointestinal tract by the enzyme in gastrointestinal tract at body temperature
(37 C) with in a couple of hours
An enzyme is a protein that is synthesized in a living cell and catalyzes or speeds up a
thermodynamically possible chemical reaction. The enzymes in on way modify the
equilibrium constant (Keq) or the free energy change (G) of a reaction.

Terminology
Some of the terms used in enzymology are defined below:
Substrate: The substrate acted upon by the enzyme.
Product: The substrate formed as a result of the enzymatic action
Active site or catalytic site: the site on the enzyme wherein the substrate is bound and is
converted into products
Regulatory site: The site other than the active site on the enzyme wherein the effector or
modulator is bound and controls the rate of enzyme catalyzed reaction.
Effector or modulator: The substance which binds at an allosteric site (the site other than the
catalytic site) of the regulatory enzyme and may stimulate or inhibit the rate of enzyme
catalyzed reaction
Holoenzyme: A completely catalytically active enzyme.
Holoenzyme = Apoenzyme + Cofactor
(active) (inactive) (inactive)

Cofactor: The non-protein component of the enzyme molecule required for complete activity.
Cofactors can be classified into three groups; coenzymes, prosthetic groups and metal ions.

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Fundamental of Plant Biochemistry and Biotechnology AME 111

Enzymes and their Cofactors
Sl.no Co -factors Enzymes
1 Fe2+ or Fe3+ Cytochrome oxidase
Catalase.
Peroxidase.
iv. Xanthine Oxidase.

2 Cu2+ Cytochrome oxidase
Lysyl oxidase
Superoxide Dismutase
3 Zn2+ Carbonic anhydrase
Alcohal dehydrogenase
Carboxy peptidase
4 Mg2+ Hexokinase
Enolase
Glucose 6 Phosphatase
5 Mn2+ Arginase
Enolase
Pyruvate carboxylase
6 K+ Pyruvate Kinase
7 Ni2+ Urease
8 Mo Dinitrogenase
Xanthine oxidase
9 Se Glutathione peroxidase

Apoenzyme: The protein component of the enzyme.
Coenzyme: The non-protein organic molecule that is not covalently bound and can be readily
dissociated from the protein component of the enzyme by dialysis.
Prosthetic group: The non-protein component that is covalently bound and not readily
dissociated from the protein component of the enzyme by dialysis.

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Zymogen or proenzyme : The precursor form of the enzyme in an inactive form. Activator:
Any substance that increases the rate of an enzyme-catalyzed reaction.
Inhibitor: Any substance that reduces or inhibits the rate of an enzyme- catalyzed reaction.
Turnover number (molar activity): The number of molecules transformed into product
(s) per minute by one molecule of the enzyme.
Specific activity: The amount of enzyme units present per milligram of protein.
Enzyme unit: The amount of enzyme which transforms one micromole of substrate per
minute under defined assay conditions.
Michaelis-Menten constants (Km): The substrate concentration at half the maximal velocity
of the enzyme-catalyzed reaction.

General characteristics
The general characteristics of enzymes are as follows:
Specialized proteins
All the enzymes as far as known are specialized proteins that catalyze biochemical reactions.
Enzymes show all the properties of protein, i.e., like proteins, enzymes are chemically made
up of amino acids as building-blocks linked by peptide bonds; can be hydrolyzed to yield a
mixture of constituent amino acids; lose catalytic activity if subjected to extreme pH,
temperature, strong acids or bases, organic solvents or other conditions which denature
protein and give typical color tests like biuret and FCR (Folin-Ciocalteu reagent) reactions.
Biological organic catalysis
Enzymes are also referred to as biological organic catalysis as:
· Thy enhance the rate of specific chemical reactions.
· They do not shift the eqauilibria of the reactions they catalyze.
· They are regenerated during the course the reaction and
· They are effective in concentrations that are minute as compared with the concentrations
of substrates undergoing reaction.

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Fig: Activation energy

How an enzyme enhances the rate of chemical reactions?
For a chemical reaction A + B → C + D to occur, three criteria must be met:
1. The reactants, called substrates (A, B) must collide
2. The molecular collision must occur with the correct orientation, and
3. The reactants must have sufficient energy. This energy is called the activation energy
which is the amount of energy required to bring all the molecules at a given temperature to the
transition sate. More specifically, it is the difference in energy between the ground state of
reactants and the transition state.
Enzymes enhance the rate of chemical reaction by decreasing the activation energy of the
reaction and with a high probability of correct orientation of reactants. The transition state
refers to the state at which all molecules at any given instant possess
enough energy to attain an activated condition before the reactants can be converted to

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products (C, D). This state is at the top of the energy barrier separating the reactants and
products.
In the normal course, not all molecules acquire sufficient energy to attain the transition state
by collision. There are two ways of increasing the reaction rate by:
a) Increasing the temperature which increases thermal motion and energy of molecules
capable of entering the transition state, and
b) Lowering the energy of the transition state by the addition of catalysts.
In the enzyme-catalyzed reaction, the lowering of activation energy is achieved by the
formation of activated ES (enzyme-substrate) complex by the combination of the enzyme
with the substrate. This is clearly represented in Fig(6.1) where, (1) is the energy of
activation, the difference in the energy level of reactants, A and B and the transition state for
uncatalyzed reaction, (2) it is energy of activation for the formation of ES complex and is
much less than (1) and (3), is the difference in energy levels between the reactant and product,
i.e., overall free energy change of the reaction which remains the same in both catalyzed and
uncatalyzed reactions.
Specificity
Unlike inorganic catalysts enzymes, the biological organic catalysts are more specific toward
their substrates and for the type of reactions that catalyze. The term specificity refers to the
affinity of the enzyme towards its substrate.
Types of specificity
Enzymes exhibit different types of specificity

· Absolute specificity: Some enzymes act on only one substrate. Such enzymes are said to
exhibit absolute specificity. For example, succinic dehydrogenase, a key enzyme of TCA
cycle catalyzes only the oxidation of succinate to fumarate.

· Absolute group specificity: Some other enzymes act on a very small group of substrates
having the same functional group but at different rates. Such enzymes are said to exhibit
absolute group specificity. For example, alcohol dehydrogenase oxidizes both ethanol
and methanol which have common hydroxyl group. Similarly, hexokinase not only
phosphorylats glucose but also fructose and mannose.

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· Relative group specificity: Some other enzymes exhibit relative group specificity. A
given enzyme can act upon more than one group of substrates. For example, trypsin
catalyzes the hydrolysis of both ester and amide bonds.

· Stereospecificity: Many other enzymes show stereospecificity i.e., a given enzyme can
act upon only particular stereoisomer. For example, L-amino acid oxidase acts only on L-
amino acid but not on its D-form of amino acid. D-amino oxidase acts only on D-amino
acid but not on its L-form.

The enzymes are so specific since the active site of each enzyme has the proper shape, size
and charge to bind certain substructure only and to catalyze the conversion of these substrates
to specific products.

Active site
Enzyme –catalyzed reactions occur at an asymmetric pocket of the enzyme called the active
site. The conformation and chemical composition of the active site determines the specificity
of enzymatic catalysis. Theoretically, the active site can be subdivided

a) A binding site, which includes the amino acid residues come into contact with the substrate,
and (b) a catalytic site, which includes residues directly responsible for catalysis. However,
the binding and bond-breaking processes are important in catalysis by enzymes.
In all cases where conformations of enzymes have been determined by X-ray crystallography,
the active site has been found to a relatively small area of the enzyme surface. Furthermore,
the active site is a specific three – dimensional region having a unique arrangement of amino
acid side chains, which are often contributed by amino acids situated quite far apart on the
linear sequence of polypeptide chain. For example, the groups on the active site of enzyme
lysozyme are contributed by the side chains of glutamate 35, aspartate – 52, tryptophan – 62
and 63 and aspartate – 101 (number after each amino acid refers to its location along the
polypeptide chain). The rest of the polypeptide chain may be extremely important in
maintaining the correct three – dimensional conformation of the active site.

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Theories for enzyme – substrate binding
Two theories have been proposed to explain interaction of substrate and enzyme.
1. Lock and key model
According to the lock and key model proposed by Emil Fisher in 1894, the substrate and
enzyme have structural complementarily and fit together like lock and key i.e., the active site
of the enzyme has a complementary shape of the substrate to form enzyme- substrate
complex. This model has proved to be essentially correct in the case of enzymes known to
exhibit absolute specificity.
2. Induced-fit theory
This theory proposed by D.E.Koshland in 1968 suggests that the substrate binds at the active
site of the enzyme and then modifies the shape of the active site so that it becomes
complementary for the substrate binding. For example, binding of substrate to lysozyme takes
place in this way.

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Nomenclature
Naming of enzymes
In the past enzymes were named in a haphazard manner as an when they were discovered.
The ways in which enzymes are or have been named are listed below:

1. The first enzymes studied have been named for their colour their localization within the
body or after the person who discovered them. However, this nomenclature had not been
agreeable to many.

2. Later, many enzymes have been named by adding the suffix “ase” to the name of the
substrate, for example, urease catalyzes the hydrolysis of arginine to ornithine and urea and so
on. However, this nomenclature has not been always practicable.

3. Further, a systematic classification of enzymes has been adopted on the recommendation
of an International Enzyme Commission as listed in the 1973 edition of Enzyme
Nomenclature with a few exceptions. According to this, enzymes have been classified into six
major classes and sets of classes based on the nature and type of reactions catalyzed.
According to this, each enzyme is assigned:

A recommended name: It is usually short and appropriate everyday use. A systematic
name: It identifies the reaction the enzymes catalyzes and

A classification number: It is used where accurate and unambiguous identification of an
enzyme is required, as in research journals, abstracts and indexes.

An example is given by the enzyme catalyzing the reaction: ATP + creatine → ADP +
phosphocreatine
The recommended name: creatine kinase
The systematic name: ATP: creatine phosphotransferase
Classification number : EC 2.7.3.2, where EC stands for Enzyme Commission, the first digit
(2) for the major class name (transferases), the second digit (7) for the subclass

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(phosphotransferases), the third digit (3) for the sub-subclass (phosphotransferases with a
nitrogenous group as acceptor) and the fourth digit (2) designates creatine kinase.

Enzyme classification
Enzymes can be classified into six major classes based on the nature and type of reactions
catalyzed as given below:

1. Oxidoreductases: These enzymes catalyze oxidation or reduction reactions by transfer of
hydrogen or electrons, e.g., succinic dehydrogenase.

2. Transferases: These enzymes are involved in transferring functional groups between
donors and acceptors. The amino, acyl, phosphate, one-carbon and glycosyl groups are the
major moieties that are transferred e.g., glutamic pyruvic transminase.

3. Hydrolases: This group of enzymes can be considered as special class of transferases in
which the donor group is transferred to water. The generalized reaction involves the
hydrolytic cleavage of C-O, C-N, O-P and C-S bonds. The cleavage of the peptide bond by
peptidases is good example of this reaction. The proteolytic enzymes are a special class of
hydrolases called peptidases.
4. Layses: These enzymes remove the groups of water, ammonia or CO2 from the substrate
to cleave double bond or conversely, add these groups to double bonds e.g., furmarase.
5. Isomerases: These are a very heterogeneous group of enzymes that catalyze
isomerizations (i.e., structural rearrangements within a molecule) of several types. These
include cis-trans, keto-enol, and adose-ketose interconversion. Isomerases that catalyze
inversion at asymmetric carbons are either epimerases or racemases. Mutases involve the
intramulecular transfer of a group such as phosphoryl group.
6. Liagases (synthetases): These enzymes are involved in synthetic reactions where two
molecules are joined together at the expense of breakdown of nucleoside-triphosphates. The
formation of aminoacyl tRNAs, acetyl coenzyme A, glutamine, and the addition of CO2 to
pyruvate are reactions catalyzed by ligases, e.g. pyruvic carboxylase.

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The six major classes of enzymes and the type of reactions catalyzed are summarized in Table
below.

Table: Classification of enzymes and types of reactions catalyzed
S.N. Enzyme class Reactions catalyzed
1. Oxidoreductases Oxidation and reduction of substrates (usually involve
hydrogen transfer)
Dehydrogenases Transfer of hydrogen atoms from substrate to NAD*
Oxidases Transfer of hydrogen atoms from substrate to oxygen
Oxygenases Partial incorporation of oxygen to substrate
Peroxidases Transfer of electrons from substrate to hydrogen
peroxide
2. Transferases Transfer of a chemical group (such as a methyl group,
amino group, phosphate group from one molecule to
another
Phosphorylases Addition of orthophosphate to substrate
Transaminases Transfer of amino group from one substrate to another
Kinases Transfer of phosphate from ATP to substrate
3. Hydrolases Cleavage of bonds by the addition of water
Phosphatases Removal of phosphate from substrate
Peptidases Cleavage of peptide bonds
4. Lyases Addition of groups to double bond
(-C=C-, C=O, -C=N-)
Decarboxylases Removal of carbon dioxide from substrate
5. Isomerases Rearrangement of atoms of a molecule
6. Liagases Formation of new bonds using energy from
(simultaneous) breakdown of ATP
Synthetases Joining two molecules together

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Factors affecting the rate of enzyme-catalyzed reactions

Several factors are known to influence the rate of enzyme-catalyzed reaction, chief of them
being :
1. Enzyme concentration
2. Substrate concentration
3. Temperature
4. pH and
5. Activators and inhibitor

Effect of enzyme concentration
With few exceptions, the initial velocity (V0 ) of enzymatic reactions bears a linear
relationship with the concentration of the enzyme [E], provided other conditions do not act as
limiting factors. If an excess substrate is present, doubling the enzyme concentration usually
doubles the rate of formation of end products. This usually applies only at the start of the
reaction, for the end-products of the reaction often have an inhibitory effect on the enzyme,
and decrease its efficiency. Fig 6.5 is a graph which relates enzyme concentration to enzyme
activity, all other factors being held constant. The dotted part is hypothetical, and almost
impossible to attain in vitro; it may occur to a limited extent in the living cell.

Effect of substrate concentration

The concentration of substrate [S] affects the rate of the enzyme-catalyzed reaction. When the
enzyme concentration is kept constant and the substrate concentration varied, the rate of
enzyme-catalyzed reaction increases linearly upto a certain concentration of substrate after
which a point is finally reached, where the enzyme is saturated with substrate. When this
saturation point is reached, further increases in substrate concentration have no influence on
rate of the enzyme-catalyzed reaction which is due to saturation of all the active sites of the
enzyme by the substrate and partly due to more rapid accumulation of end-products causing
inhibition of enzyme. The typical shape of curve obtained in this case is a nonlinear
hyperbolic relationship between V0 and substrate concentration.

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Pioneering work on the kinetic studies of enzyme-catalyzed actions was made by A. Brown
(1902) and V. Henri (1903). This was further developed by L. Michaelis and M.L. Menten in
1903 and by G.E. Briggs and J.B.S.Haldane in 1926.
To account for hyperbolic relationship. Brown put forward hypothesis that the enzyme (E)
reversibly combines with the substrate (S) to form an enzyme-substrate (ES) complex which is
decomposed to yield product (P) and the free enzyme in its original from.

Based on the work of Briggs and Henri, Michaelis and Menten derived a mathematical equation
which is consistent with the empirical data represented They assumed that a rapid equilibrium
exists between E, S and ES and that ES-complex breakdown of ES to E and S. This plot is based
on the following equation for the behavior of a simple enzyme-catalyzed reaction in which one
substrate is converted to one product.

Where k+1, k-1 , k+2 and k-2 are the velocity constants for the above four steps. By rate
measuring the of reaction, the rate constant k-2 may be ignored because not be
initial present to make the reverse reaction proceed at significant rate.
enough products
will

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The equation they obtained is called Michaelis-Menten equation which is,

Where Vo = Initial velocity of the enzymatic reaction

Vmax = Maximal velocity at infinite substrate concentration, [S] = Substrate
concentrtion and
Km = Michaelis – Menten constant

In Michaelis – Menten equation, when [S] = Km, then

Or Vo = Vmax
2

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Hence, Km can be defined as the concentration of the substrate at which the reaction rate is half
the maximal velocity. Usually, Km has dimension moles per liter and its independent of enzyme
concentration.
Determination of Km and Vmax
The hyperbolic curve of the Vo verses [S] plot does not permit the determination of exact values
of Km and Vmax. This limitation can be overcome by plotting the same kinetic data in different
ways. The most popular approach is simple by taking reciprocal of both sides of Michaelis-
Menten equation to yield a straight-line rate equation, called a Lineweaver-Burk equation which
is,

Fig. Lineweaver–Burk plot

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By plotting l/Vo versus l/[S], a straight line is obtained having a slope of Km/Vmax, an intercept
of l/Vmax on l/vo axis and an intercept of –l/Km and l/[S] axis. Such a plot is called a
Lineweaver- Burk plot or double reciprocal plot (Fig. 6.7 ). By determining the value of
l/Vmax, Km can be determined. Km can also be directly determined by extrapolation of the line
to meet the l/(S) axis where the intercept is –l/Km.

The double-reciprocal plot has the advantage that measurement of the velocity of the reaction
can be made at a number of substrate concentrations and then extrapolated back to infinite
substrate concentrations at the intercept, which gives a straight-line so that accurate values of
Vmax and Km can be determined. This also gives variable information on enzyme inhibition.

Significance of Km and Vmax
The Km value which is expressed in molar concentration is characteristic of each individual
enzyme. Km is not a fixed value may vary with structure of substrate, pH and temperature. For
enzyme having more than one substrate, each substrate has a characteristic Km value. Km
helps to evaluate the specificity of action of given enzyme towards similar substrates. The
substrate with the lowest Km value has highest apparent affinity for the enzyme. It also
establishes an approximate value for the intercellular level of substrate as the enzymes are not
necessarily saturated with their substrates. Knowledge of the Km of an enzyme can be of
consideration value in investigations of metabolic control.

Vmax represents the efficiency of enzyme action and can be used to compare the catalytic
efficiency of different enzymes.

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Effect of temperature
As with most chemical reactions, the rate of an enzyme-catalyzed reaction increases
with temperature, however, in the case enzymes there is a temperature at which thermal
denaturation of protein causes a loss of activity and the rate begins to slow down. For each
enzyme there is an optimum temperature at which it is more active and its activity slows
down when the temperature is changed in either direction away from this optimum. This is
because, temperature changes cause slight changes in the three-dimensional shape of protein,
increases in temperature may cause the protein to loosen up and become less compact. Even
small changes in the dimensions of its active site can make an enzyme a less efficient catalyst.

The velocity of a chemical reaction is related to temperature according to Vant Hoff’s law
which states that a rise of 10ºC will double the speed of a chemical reaction.
Velocity at (T+10º)
------------------------
Velocity at Tº

The temperature coefficient is usually expressed by the symbol, Q10 which is also applicable
to enzyme-catalyzed reactions. For most enzyme-catalyzed reactions. Q10 is approximately 2
at lower temperatures, but gradually drops off until the rate is 1 (or lower) at higher
temperatures. Fig.6.8 shows the general effect of temperatures (bell shaped curve) on most
enzyme-catalyzed reactions. Most enzymes show a temperature optimum between 25 and
37ºC but are inactivated at temperatures above 55ºC although enzymes in thermophilic
bacteria are active even at temperature exceeding 55ºC.

Effect of pH

The activity of the enzyme is markedly influenced by the pH of the medium in which the
reaction occurs. It is usually found that activity is shown over a limited range of pH and
within this range, a bell-shaped activity curve (Fig ) is often observed when enzyme activity is
plotted against pH. Every enzyme has a characteristic pH optimum wherein the activity is at
maximum and the activity decreases on either side of this value. Most enzymes have pH

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optimum in the region 6-8, which, however, varies with the source of the enzyme, the kind of
substrate, the kind of buffer and the temperature. For example, pepsin has a pH optimum
around 2, for enzymes of plants and fungi it is 4.0-6.5 and for most enzymes of higher
animals it is 6.5-8.0.
At extreme pH values protein denaturation will occur with concomitant loss
of enzyme activity. Slight changes in pH which do not denature the protein, may alter the
state or degree of ion