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Section II Molecules of Life Universities Press
/1/A & /1, Himayatnagar Hyderabad (A.P.), India Phone: /5447
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Enzymes
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ENZYMES Enzymes are highly specialised proteins that act as catalysts in biological systems (biocatalysts). Enzymes are highly specific for their substrates
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NOMENCLATURE AND CLASSIFICATION OF ENZYMES
International Union of Biochemistry (IUB) devised a new system of nomenclature in 1964. A four-digit Enzyme Commission (E.C.) number is assigned to each enzyme. The first digit represents the class, the second digit indicates the subclass, the third digit represents the sub-subclass and the fourth digit specifies the individual enzyme. Enzymes are classified into six major classes as per the IUB system of enzyme classification.
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CLASIFICATION OF ENZYMES
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CLASIFICATION OF ENZYMES
…Continues) (Continued…
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CLASIFICATION OF ENZYMES
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…Continues)
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ENZYME STRUCTURE Enzymes are proteins Apoenzyme Coenzyme Holoenzyme
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ACTIVE SITE The small cleft-like portion of an enzyme where the substrate(s) binds and catalysis occurs is known as the active site or active centre. Substrate binding site Catalytic site A diagrammatic representation of an enzyme and its active site
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COENZYMES Coenzymes of B-complex vitamins
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Coenzymes which are not related to vitamins
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ENZYME SPECIFICITY The active site in a specified conformation on an intact enzyme molecule is largely responsible for the enzyme specificity. There are three types of specificity: 1. Stereo specificity 2. Substrate specificity 3. Reaction specificity
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HOW DO ENZYMES WORK? Transition state Ground state Activation energy
Enzymes act by reducing the activation energies Binding energy
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Effect of enzyme on activation energy in a reaction (S =substrate; P = product).
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To summarise, the energy required to surmount the activation barrier is the activation energy. Enzymes catalyse the reactions by lowering the activation barrier. The binding energy resulting from weak non-covalent interactions between the substrate and the enzyme reduces the activation energy. Enzymes do not alter the reaction equilibria, they only enhance the reaction rates by lowering activation energies.
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MECHANISM OF ENZYME ACTION
1. Lock and key model 2. Induced fit theory 3. Substrate strain theory
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Different models explaining enzyme–substrate (ES) complex formation (A) Lock and key model, (B) Induced fit theory, (C) Substrate strain theory.
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MECHANISM OF CATALYSIS
Acid-base catalysis Covalent catalysis Metal ion catalysis
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FACTORS AFFECTING ENZYME ACTIVITY
The various factors that influence enzyme activity are concentration of enzyme concentration of substrate concentration of product Temperature pH.
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EFFECT OF CONCENTRATION OF SUBSTRATE ON ENZYME VELOCITY
The rate of an enzyme catalysed reaction increases as the substrate concentration increases until it reaches a maximal rate, which remains constant despite further increases in substrate concentration. The substrate concentration (expressed in moles/L) required to produce half-maximum velocity (1/2 Vmax) is known as Km or Michaelis–Menten constant.
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Effect of substrate concentration on enzyme velocity.
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Km or Michaelis–Menten constant can be derived as follows:
The relationship between substrate concentration (S) and enzyme velocity (V) can be shown as follows: (Continued…
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When the measured velocity (V) is exactly one-half Vmax
…Continues) When the measured velocity (V) is exactly one-half Vmax In Km, K stands for a constant and m stands for Michaelis and Menten.
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EFFECT OF TEMPERATURE ON ENZYME VELOCITY
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EFFECT OF pH ON ENZYME VELOCITY
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ENZYME INHIBITION Enzyme inhibition can be broadly classified into three categories. 1. Competitive inhibition 2. Non-competitive inhibition 3. Allosteric inhibition
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COMPETITIVE INHIBITION
The inhibitor binds with the enzyme through non-covalent interactions and hence the pro cess is readily reversible. In competitive inhibition, the Km value increases whereas Vmax is unchanged.
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Velocity versus substrate plot in competitive inhibition
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DRUGS ACTING AS COMPETITIVE INHIBITORS
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NON-COMPETITIVE INHIBITION
The inhibitor binds to the enzyme covalently and inactivates it making the process essentially irreversible. In non-competitive inhibition, the Km value is unchanged while Vmax is lowered.
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Velocity versus substrate plot in non-competitive inhibition
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REGULATION OF ENZYME ACTIVITY
1. Allosteric regulation 2. Covalent modulation 3. Proteolytic trimming 4. Compartmentation 5. Control of enzyme synthesis and degradation
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ALLOSTERIC REGULATION
Allosteric enzymes Allosteric modulators Cooperativity of allosteric enzymes Classification of allosteric enzymes K class allosteric enzymes V class allosteric enzymes Feedback regulation
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Effect of substrate concentration on allosteric enzymes.
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Examples of allosteric enzymes
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COVALENT MODULATION Regulatory enzymes or rate-limiting enzymes
Reversible protein phosphorylation Protein kinases Protein phosphatases
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Regulatory enzymes (rate-limiting enzymes) controlled by covalent modulation
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ISOENZYMES The multiple molecular forms of an enzyme catalysing the same reaction are called isoenzymes. They differ in their physical and chemical properties such as structure, Km, Vmax, pH, electrophoretic mobility and their susceptibility to inhibitors. Isoenzyme variants are coded by different genes. Allelozymes Hybrid isoenzymes Isoforms
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CREATINE KINASE (CK) Normal serum levels of CK are 15–100 U/L in males and 10–80 U/L in females. Lohmann’s reaction In myocardial infarction, CK levels (CK–MB isoenzyme) start to rise within 3–6 hours of infarction. Isoenzymes of CK
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LACTATE DEHYDROGENASE (LDH)
Normal levels of LDH in serum are 100–200 U/L Isoenzymes of LDH
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ALKALINE PHOSPHATASE (ALP)
The normal serum levels of ALP range between 40 and 125 U/L. Increased ALP levels are most commonly associated with bone disease and hepatobiliary disease (Continued…
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…Continues) Isoenzymes of ALP
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Plasma specific enzymes
Plasma non-specific enzymes Units of enzyme activity
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DIAGNOSTIC MARKERS OF MYOCARDIAL
INFARCTION (MI)
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ENZYMES USED AS THERAPEUTIC AGENTS
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ENZYMES USED IN LABORATORY MEASUREMENTS AND GENE TRANSFER
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