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Chemistry 501 Handout 6 Enzymes Chapter 6

Dep. of Chemistry & Biochemistry Prof. Indig. Chemistry 501 Handout 6 Enzymes Chapter 6. Lehninger. Principles of Biochemistry. by Nelson and Cox, 5 th Edition; W.H. Freeman and Company. With exception of a small group of catalytic RNA molecules, all enzymes are proteins

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Chemistry 501 Handout 6 Enzymes Chapter 6

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  1. Dep. of Chemistry & Biochemistry Prof. Indig Chemistry 501 Handout 6EnzymesChapter 6 Lehninger. Principles of Biochemistry. by Nelson and Cox, 5th Edition; W.H. Freeman and Company

  2. With exception of a small group of catalytic RNA molecules, all enzymes are proteins Largest class of proteins. More than 3000 enzymes known. Enzymes are biological catalysts that accelerate reactions. Enzymes are generally highly specific and react with only one substrate to form one product and can enhance reaction rates by as much as 1017. Some enzymes requirecofactors/ coenzymesfor activity Coenzymes act as transient carriers of specific functional groups A cofactor or coenzymes that is very tightly or even covalently bound to the enzyme protein is called aprosthetic group. Complete, catalytically active enzyme:holoenzyme Only protein part (withoutcofactorand/orcoenzyme): apoenzyme or apoprotein

  3. Enzymes are classified by the reactions they catalyze International Classification System (nomenclature): (Four-part classification number and asystematic name) Systematic name: ATP:glucose phosphotransferase Classification number: 2.7.1.1. 2. --> Transferase (class) 7. --> phosphotransferase (subclass) 1. --> phosphotransferase with a hydroxyl group as acceptor 1. --> D-glucose as the phosphoryl group acceptor ATP + D-glucose --> ADP + D-glucose-6-phospate Hexokinase

  4. Binding of a substrate to an enzyme at the active site Representation of a simple enzymatic reaction Enzymes affect reaction rates, not equilibria E + SESEPE + P Reaction coordinate diagram for a chemical reaction Reaction coordinate diagram comparing enzyme-catalyzed and uncatalyzed reactions

  5. Equilibrium SP Reaction S→P Reaction rate = V = k [S] If the rate depends only on the concentration of S (first-order) From the Transition-State Theory:

  6. Weak interactions between enzyme and substrate are optimized in the transition state The energy derived from enzyme-substrate interaction is called binding energy, DGB Enzyme active sites are complementary not to the substrate per se, but to the transition state through which substrates pass as they are converted into products during an enzymatic reaction Complementary shapes of a substrate and its binding site on the enzyme Role of binding energy in catalysis An imaginary enzyme (sticase) designed to catalyze breakage of a metal stick

  7. How a catalyst circumvents unfavorable charge development during cleavage of a amide Rate enhancements by entropy reduction Specific acid-base catalysis General acid-base catalysis Hydrolysis of an amide bond - same reaction as that catalyzed by chymotrypsin and other proteases

  8. Amino acids in general acid-base catalysis Covalent and general acid-base catalysis First step of the reaction His57 His57 Amino acid side chains and the functional groups of some cofactors can serve as nucleophiles in the formation of covalent bonds with substrates

  9. Enzyme Kinetics Effect of substrate concentration on the initial velocity of an enzyme-catalyzed reaction Michaelis-Menten kinetics initial rate measurements [S] >> [E] [ES] ~ constant V0 = K2[ES] Michaelis constant

  10. Dependence of initial velocity on substrate concentration When km > > [S] When [S] > > km

  11. A double-reciprocal or Lineweaver-Burk plot Lineweaver-Burk equation

  12. Kcat describes the limiting rate of any enzyme-catalyzed reaction at saturation

  13. Many enzymes catalyze reactions with two or more substrates Common mechanisms for enzyme-catalyzed bisubstrate reactions

  14. Pre-steady state kinetics can provide evidence for specific reaction steps Ternary complex is formed in the reaction (as indicated by the intersecting lines) Ping-Pong (double displacement) reaction

  15. Enzymes are subject to reversible and irreversible inhibition

  16. Enzymes are subject to reversible and irreversible inhibition

  17. Irreversible inhibition Reaction of chymotrypsin with diisopropylfluorophosphate irreversibly inhibits the enzyme Suicide inactivators or mechanism-based inactivators

  18. Examples of Enzymatic Reactions Chymotrypsin is a protease specific for peptide bonds adjacent to aromatic amino acids (Trp, Tyr, Phe) Key active-site amino acid residues Ser195, His57, and Asp102 Aromatic amino acid side chain Pocket in which the amino acid side chain of the substrate is bound Three polypeptide chains linked by disulfide bonds

  19. The chymotrypsin mechanism involves acylation and deacylation of a Ser residue

  20. Regulatory Enzymes Allosteric enzymes undergo conformational changes in response to modulator binding Conformational change Subunit interactions in an allosteric enzyme, and interactions with inhibitors and activators

  21. Two views of the regulatory enzyme aspartate transcarbamoylase This allosteric regulatory enzyme has two stackedcatalytic clusters, each with three catalytic polypeptide chains (in shades of blueand purple) and three regulatoryclusters, each with two regulatory peptide chains (in redand yellow). Modulator binding produces large changes in enzyme conformation and activity

  22. Feedback inhibition Buildup of the end product ultimately slows the entire pathway In many pathways a regulatory step is catalyzed by an allosteric enzyme Example of heterotropic allosteric inhibition

  23. Phosphoryl groups affect the structure and catalytic activity of enzymes Regulation of muscle glycogen phosphorylase activity by multiple mechanisms

  24. Some enzymes and other proteins are regulated by proteolytic cleavage of a precursor Activation of zymogens by proteolytic cleavage

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