Enzymes

• Enzymes may be defined as biocatalysts synthesized
by living cells. They are protein in nature, colloidal
and thermolabile in character, and specific in action.
• A catalyst is defined as a substance that increases the
velocity or rate of a chemical reaction without itself
undergoing any change in the overall process.
• Friedrich Wilhelm Kuhne (1878) – given the name
ENZYME (En = in ; Zyme = yeast)
• James B. Sumner (1926) - first isolated & crystallized
urease from jack bean and identified protein.

NOMENCLATURE AND CLASSIFICATION
1. Substrate acted upon by the enzyme:
• named the enzymes by adding the “ase” in the name
of the substrate catalyzed
Eg., carbohydrates – carbohydrases
proteins - proteinases,
lipids – lipases
nucleic acids - nucleases
A few of the names were even more specific like
Eg., maltase - acting upon maltose
sucrase - upon sucrose
urease - upon urea etc.

2. Type of reaction catalyzed:
• The enzymes are named by adding the “ase” in the
name of the reaction
Eg., Hydrolases - catalyzing hydrolysis
Isomerases – isomerization
Oxidases – catalyzing oxidation
Dehydrogenases – catalyzing dehydrogenation
Transaminases – catalyzing transamination
Phosphorylases - catalyzing phosphorylation etc.

3. Substrate acted upon and type of reaction catalyzed:
• The names of some enzymes give clue of both the
substrate utilized and the type of reaction catalyzed.
Eg., succinic dehydrogenase – catalyzes dehydrogenation of
the substrate succinic acid.
L-glutamic dehydrogenase – catalyzes
dehydrogenation reaction involving L-glutamic acid.

4. Substance that is synthesized:
• A few enzymes have been named by adding the
“ase” to the name of the substance synthesized
Eg., rhodonase - forms rhodonate from hydrocyanic
acid and sodium thiosulphate
fumarase - forms fumarate from L-malate.

5. Endoenyzmes and exoenyzmes:
• enzymes that act within the cells in which they are
produced - intracellular enzymes or endoenzymes
Eg., plant enzymes and metabolic enzymes
• Enzymes which are liberated by living cells, catalyze
useful reactions outside the cell in its environment -
extracellular enzymes or exoenzymes
Eg., bacterial enzymes, fungal enzymes, digestive tract
enzymes

INTERNATIONAL UNION OF BIOCHEMISTRY (IUB)
NOMENCLAURE AND CLASSIFICATION
• The chemical reaction catalyzed is the specific
property which distinguishes one enzyme from
another.
• In 1961, IUB used this criterion as a basis for the
classification and naming of enzymes.
• According to IUB, the reactions and the enzymes
catalyzing them are divided into 6 major classes, each
with 4 to 13 subclasses.

1. Oxidoreductases
2. Transferases
3. Hydrolases
4. Lyases or Desmolases
5. Isomerases
6. Ligases or Synthetases

1. Oxidoreductases:
• Enzymes which bring about oxidation-reduction
reactions between two substrates.
• Groups to be present in the substrate: CH—OH, C=O,
CH—CH, CH—NH2 and CH=NH groups
• Eg., Alcohol dehydrogenase, Acyl-CoA dehydrogenase,
Cytochrome oxidase etc.,

2. Transferases:
• Enzymes which catalyze the transfer of a group, G
(other than hydrogen) between a pair of substrates, S
and S′ are called transferases
S—G + S′ -----------→ S + S′—G
• These enzymes catalyze the transfer of one-carbon
groups, aldehydic or ketonic residues and acyl,
glycosyl, alkyl, phosphorus or sulfur-containing groups
• Eg., Acyltransferases, Glycosyltransferases, Hexokinase

3. Hydrolases:
• These catalyze the hydrolysis of their substrates by
adding constituents of water across the bond they
split.
• The substrates include ester, glycosyl, ether, peptide,
acid-anhydride, C—C, halide and P—N bonds.
• e.g., glucose-6-phosphatase, pepsin, trypsin,
esterases, glycoside hydrolases

4. Lyases (Desmolases):
• These are those enzymes which catalyze the
removal of groups from substrates by mechanisms
other than hydrolysis, leaving double bonds.
• These include enzymes acting on C—C, C—O, C—N,
C—S and C—halide bonds.
• Eg., Aldolase, Fumarase, Histidase etc.,

5. Isomerases:
1. These catalyze interconversion of optical, geometric
or positional isomers by intramolecular
rearrangement of atoms or groups.
2. Eg., Alanine racemase, Retinene isomerase,
Glucosephosphate isomerase etc.,

6. Ligases:
• These are the enzymes catalyzing the linking together
of two compounds utilizing the energy made available
due to simultaneous breaking of a pyrophosphate
bond in ATP or a similar compound.
• This category includes enzymes catalyzing reactions
forming C—O, C—S, C—N and C—C bonds.
• Eg., Acetyl-CoA synthetase, Glutamine synthetase etc.,

CHEMICAL NATURE OF ENZYMES
1. Simple-protein enzymes.
• These contain simple proteins only e.g., urease,
amylase, papain etc.
2. Complex-protein enzymes.
• These contain conjugated proteins i.e., they have a
protein part called apoenzyme and a nonprotein part
called prosthetic group associated with the protein
unit. The two parts constitute what is called a
holoenzyme

• The activity of an enzyme depends on the prosthetic
group that is tightly associated with the apoenzyme.
• But sometimes the prosthetic group is loosely bound
to the protein unit and can be separated by dialysis
and yet indispensable for the enzyme activity.
• In that case, this dialyzable prosthetic group is called
as a coenzyme (organic nature) or cofactor (inorganic
nature).

COENZYMES
• The non-protein, organic, Iow molecular weight
and dialysable substance associated with
enzyme function is known as coenzyme.
• Coenzymes are often regarded as the second
substrates or co-substrates, since they have
affinity with the enzyme comparable with that
of the substrate
• Types of coenzymes: B-complex vitamin
coenzymes and non B-complex vitamin
coenzymes

COFACTORS
• The non-protein, inorganic, Iow molecular weight
and dialysable substance associated with enzyme
function is known as cofactors.
• Most of the cofactors are metal ions
• Metal activated enzymes: In these enzymes, the
metals form a loose and easily dissociable
complex.
• Eg., ATPase (Mg2+ and Ca2+, Enolase (Mg2+)

• Metalloenzymes: In this case metal ion is bound
tightly to the enzyme and is not dissociated
Eg., alcohol dehydrogenase, carbonic anhydrase,
alkaline phosphatase, carboxypeptidase and aldolase
contain zinc.
Phenol oxidase (copper)
Pyruvate oxidase (manganese)
Xanthine oxidase (molybdenum)
Cytochrome oxidase (iron and copper).

ACTIVE SITE
The active site (or active center) of an
enzyme represents as the small region
at which the substrate binds and
participates in the catalysis
Salient features:
• The existence of active site is due
to the tertiary structure of protein.
• Made up of amino acids which are
far from each other in the linear
sequence of amino acids.

• Active sites are regarded as clefts or crevices or
pockets occupying a small region in a big enzyme
molecule.
• The active site is not rigid, it is flexible to promote the
specific substrate binding
• Enzymes are specific in their function due to the
existence of active sites.

• Active site possesses a substrate binding site and a
catalytic site.
• The coenzymes or cofactors on which some
enzymes depend are present as a part of the
catalytic site.
• The substrate binds at the active site by weak
noncovalent bonds.

• The commonly found amino acids at the active
sites are serine(mostly found), aspartate, histidine,
cysteine, lysine, arginine, glutamate, tyrosine .
• The substrate binds the enzyme (E) at the active
site to form enzyme-substrate complex (ES). The
product (P) is released after the catalysis and the
enzyme is available for reuse.

MODE OF ENZYME ACTION
• Two theories have been put forth to explain
mechanism of enzyme-substrate complex formation
1. Lock and key model/ Fischer’s template Theory
2. Induced fit theory/Koshland’s model

Lock and key model/ Fischer’s template Theory:
• Proposed by a Emil Fischer.
• Very first model proposed to explain an enzyme
catalyzed reaction
• According to this model, the structure or conformation
of the enzyme is rigid.
• The substrate fits to the binding site just as a key fits
into the proper lock or a hand into the proper glove.
• Thus the active site of an enzyme is a rigid and pre-
shaped template where only a Specific substrate can
bind.

• This model was not accepted because
1. Does not give any scope for the flexible nature of
enzymes
2. Totally fails to explain many facts of enzymatic
reactions
3. Does not explain the effect of allosteric modulator

2. Induced fit theory/Koshland’s model:
• Koshland proposed this model
• The active site is not rigid and pre-shaped
• The interaction of the substrate with the enzyme
induces a fit or a conformation changei n the enzyme,
resulting in the formation of a strong substrate
binding site.
• Further more the appropriate amino acids of the
enzyme are repositioned to form the active site and
bring about the catalysis

• This model was accepted because:
1. Has sufficient experimental evidence from the X-ray
diffraction studies.
2. This model also explains the action of allosteric
modulators and competitive inhibition on enzymes

FACTORS AFFECTING ENZYME ACTION
Concentration of the enzyme:
• As the concentration of the enzyme is increased, the
velocity of the reaction proportionately increases.
• This property of enzyme is made use in determining
the serum enzymes for the diagnosis of diseases.

Concentration of the Substrate:
• Increase in the substrate concentration gradually
increases the velocity of enzyme reaction within the
limited range of substrate levels.
• A rectangular hyperbola is obtained when velocity is
plotted against the substrate concentration.
• Three distinct phases of the reaction are observed in
the graph (A-linear; B-curve; C-almost unchanged).

Order of reaction :
• When the velocity of the reaction is almost
proportional to the substrate concentration, the rate
of the reaction is said to be first order with respect
to substrate.
• When the substrate concentration is much greater
than Concentration of enzyme, the rate of reaction is
independent of substrate concentration, and the
reaction is said to be zero order.

Effect of temperature:
• Velocity of an enzyme reaction increases with
increase in temperature up to a maximum and then
declines. A bell-shaped curve is usually observed.

• Temperature coefficient or Q10 is defined as increase
in enzyme velocity when the temperature is increased
by 10oC.
• For a majority of enzymes, Q10 is 2 between 0"C and
40oC.
• optimum temperature - 40oC-45oC. (However, a few
enzymes e.g. venom phosphokinases, muscle
adenylatek inase are active even at 100oC. Some plant
enzymes like urease have optimum activity around
60oC.)

1. when the enzymes are exposed to a temperature
above 50oC, denaturation leading to derangement
in the native (tertiary) structure of the protein and
active site are seen.
2. Majority of the enzymes become inactive at
higher temperature (above 70oC).

Effect of pH:
• Each enzyme has an optimum pH at which the
velocity is maximum. Below and above this pH, the
enzyme activity is much lower and at extreme pH,
the enzyme becomes totally inactive

• Most of the enzymes of higher organisms show
optimum activity around neutral pH (6-8).
• There are, however, many exceptions like pepsin (1-2),
acid phosphatase (4-5) and alkaline phosphatase(10-
11).
• Enzymes from fungi and plants are most active in
acidic pH (4-6).
• Hydrogen ions influence the enzyme activity by
altering the ionic charges on the amino acids
(particularly at the active site) and substrate.

Effect of product concentration
ln the living system, this type of inhibition is generally
prevented by a quick removal of products formed

Effect of time:
• Under ideal and optimal conditions (like pH,
temperature etc.), the time required for an enzyme
reaction is less.
• Variations in the time of the reaction are generally
related to the alterations in pH and temperature.
Effect of light and radiation:
• Exposure of enzymes to ultraviolet, beta, gamma and
X-rays inactivates certain enzymes.
• The inactivation is due to the formation of peroxides.
• e.g. UV rays inhibit salivary amylase activity.

ENZYME KINETICS/MICHAELIS-MENTEN HYPOTHESIS
• Leonor Michaelis and Maud L. Menten (1913), while
studying the hydrolysis of sucrose catalyzed by the
enzyme invertase, proposed this theory.
• According to this theory
• From the above equation theoretically one can explain
the kinetics of the enzyme reaction, but practically not
• For this reason Micheali and Menten proposed an
equation.

• From that equation, these immeasurable quantities
were replaced by those which could be easily measured
experimentally.
• Following symbols may be used for deriving Michaelis-
Menten equation :
(Et) = total concentration of enzyme
(S) = total concentration of substrate
(ES) = concentration of enzyme-substrate
complex
(Et) − (ES) = concentration of free enzyme

Derivation of the equation:
• The rate of appearance of products (i.e., velocity, V)
is proportional to the concentration of the enzyme-
substrate complex.
V α ES
V = k (ES) -------------------- (1)
• The maximum reaction rate, Vm will occur at a point
where the total enzyme Et is bound to the substrate.
Vm α Et
Vm = k (Et) ----------------------(2)

• Dividing equation (1) by (2,) we get :
V = k (ES)
---------------
Vm = k (Et)
• ------------ (3)
Now coming back to the reversible reaction,
E + S ES,
one can write the equilibrium constant for dissociation of
ES as Km which is equal to :

Michaelis-Menten plot
This plot is used to determine the Vm and Km value of
the enzyme

Determination of Vm and Km value
When V = ½Vm
Km = S

Significance of Vm and Km value
• Km or Michaelis-Menten constant is defined as the
substrate concentration (expressed in moles/l) to
produce half-maximum velocity in an enzyme catalyzed
reaction
• The Km values of the enzymes differ greatly from one
to other, but it is a characteristic feature of a particular
enzyme.
• for most of the enzymes, the general range is between
10−1 and 10−6 M

• The Km value depends on the particular substrate and
on the environmental conditions such as temperature
and ionic concentration.
• But it is not dependent on the concentration of enzyme
• Km is a measure of the strength of ES complex. The high
Km value indicates weak binding whereas the low Km
value signifies strong binding.
• The maximal rate (Vm) represents the turnover number
of an enzyme, if the concentration of the active sites
(Et) is known.

ENZYME INHIBITION
• Enzyme inhibitor is defined as a substance which binds
with the enzyme and brings about a decrease in
catalytic activity of that enzyme.
• Inhibitor may be organic or inorganic in nature.
• There are three broad categories of enzyme inhibition
1. Reversible inhibition.
2. Irreversible inhibition.

1. Reversible inhibition:
• The inhibitor binds non-covalently with enzyme
• Enzyme inhibition can be reversed if the inhibitor is
removed.
• The reversible inhibition is further sub-divided into
l. Competitive inhibition
ll. Non-competitive inhibition

l. Competitive inhibition
• The rate of inhibition depends on:
1. Concentration of substrate and inhibitor
2. Affinity of inhibitor towards the enzyme
• The inhibition can be reversed by increasing the
concentration of substrate

• Km value increases whereas Vmax remains
unchanged
• Eg., succinate dehydrogenase
Original substrate - succinic acid
Inhibitor – malonic acid, glutaric acid, oxalic acid
• Competitive inhibitors have clinical significance

ll. Non-competitive inhibition
• The rate of inhibition depends on the concentration
of the inhibitor
• Km remains constant whereas Vmax value
decreases

• Eg., Various heavy metals ions (Ag+, Hg2+, Pb2+) inhibit
the activity of a variety of enzymes.
• Urease, for example, is highly sensitive to any of these
ions in traces.
• Heavy metals form mercaptides with sulfhydryl (-SH)
groups of enzymes:
• cyanide and hydrogen sulfide strongly inhibit the action
of iron-containing enzymes like catalase and
peroxidase.

2. Irreversible inhibition:
• The inhibitors bind covalently with the enzymes and
inactivate them irreversibly
• These inhibitors are usually toxic poisonous
substances
• Irreversible inhibitors combine with or destroy a
functional group on the enzyme that is essential for
its activity

• Eg., lodoacetate – irreversible inhibitor of papain and
glyceraldehyde 3-phosphate dehydrogenase .
Iodoacetate combines with sulfhydryl (-SH) groups at
the active site of these enzvmes and makes them
inactive
• Eg., Diisopropyl fluorophosphate (DFP) is a nerve gas
developed by the Germans during Second World War.
DFP irreversibly binds with enzymes containing serine
at the active site, e.g. serine proteases, acetylcholine
esterase

• Eg., Organophosphorus insecticides like melathion
are toxic to animals (including man) as they block the
activity of acetylcholine esterase (essential for nerve
conduction), resulting in paralysis of vital body
functions
• Eg., Penicillin antibiotics act as irreversible inhibitors
of serine – containing enzymes, and block the
bacterial cell wall synthesis

ENZYME REGULATION
Covalent modification:
• Certain enzymes exist in the active and inactive forms
which are interconvertible, depending on the needs of
the body.
• The interconversion is brought about by the reversible
covalent modifications, namely
1. phosphorylation and dephosphorylation
2. oxidation and reduction of disulfide bonds.

Covalent modification by phosphorylation-
dephosphorylation of a seryl residue
For some enzymes phosphorylation increases its
activity whereas for some other enzymes it decreases
the activity

Covalent modification by oxidation and reduction of
disulfide bonds
• A few enzymes are active only with sulfhydryl (-SH)
groups, Eg., succinate dehydrogenase, urease.
• Substances like glutathione bring about the stability
of these enzymes.

Allosteric regulation:
• They possess sites called allosteric site (other than that
of active site)
• Certain substances referred to as allosteric modulators
(effectors or modifiers) bind at the allosteric site and
regulate the enzyme activity.
• positive (+) allosteric effector – the binding of which
increases the activity of the enzyme – so called as
allosteric activator
• negative (-) allosteric effector – the binding of which
decreases the activity of the enzyme – so called as
allosteric inhibitor

Homotropic effect: modulator and substrate are same –
mostly positive
Heterotropic effect: modulator and substrate are
different – may be positive or negative

Allosteric regulation mechanism

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