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Lehninger Principles of Biochemistry
David L. Nelson and Michael M. Cox Lehninger Principles of Biochemistry Fourth Edition Chapter 6: Enzymes (Part II) Copyright © 2004 by W. H. Freeman & Company
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[6] Enzyme Inhibition Inhibitor: Any molecule that acts directly on an enzyme to lower its catalytic rate. These can be cellular metabolites, or foreign substances such as drugs or toxins that have either a therapeutic or toxic (can be lethal) effect. There are two major types of inhibition: (1) Irreversible inhibition (2) Reversible inhibition a) Competitive b) Un-competitive c) Mixed
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(1) Irreversible Inhibition: inhibitor binds tightly, often covalently, to the enzyme, permanently inactivating it. DIPF = DIFP = diisopropylfluorophosphate
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(2) Reversible Inhibition
Competitive inhibition: Inhibitor has close structural similarities to the normal substrate and therefore competes with the substrate for the active site.
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In the presence of a competitive inhibitor, I,
Vmax [S] v0 = Km(1 + [I]/Ki) + [S] [E][I] where Ki (inhibition constant) = [EI] Then, Km+ [S] where = (1 + [I]/Ki) The type of inhibition can be determined using the double reciprocal plot.
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In competitive inhibition, inhibition can be overcome by high [S].
Vmax does not change, but Km increases (Km,app = Km).
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An uncompetitive inhibitor binds at a site other than the active site and, binds only to the ES complex.
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v0 = Vmax [S] Km + [S] where = (1 + [I]/Ki) and Ki = [ES][I]/[ESI]. Since I does not share the binding site with S, uncompetitive inhibition cannot be overcome by high [S]. Vmax,app – decrease (by a factor of -1) Km,app – decrease
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Rare in single-substrate reaction.
More common in multisubstrate reaction Ex) Compulsory ordered Bi-Bi reaction. B ─BX E + AX ⇄ EAX ⇄ EAXB ⇄ EABX ⇄ EA ⇄ E + A EAXBI No reaction Compound, BI is an uncompetitive inhibitor of AX.
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Inhibitor binds at a site other than the active site (E or ES) and causes changes in the overall 3-D shape of the enzyme that leads to a decrease in activity:
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I binds to E and ES with the same affinity (Ki = Ki)
Vmax[S] v0 = –––––––––– Km + [S] where = (1 + [I]/Ki) and = (1 + [I]/Ki) Ki = [E][I]/[EI], Ki = [ES][I]/[ESI]. When, = , that is, I binds to E and ES with the same affinity (Ki = Ki) ⇒ Noncompetitive inhibition. Mixed inhibition cannot be overcome by high [S]. Vmax,app – decrease (by a factor of (1 + [I]/Ki)) Km,app – unchanged
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Ex) Compulsory ordered Bi-Bi reaction.
B ─BX E + AX ⇄ EAX ⇄ EAXB ⇄ EABX ⇄ EA ⇄ E + A B EAXI ⇄ EAXIB Compound, AXI is a noncompetitive inhibitor of B.
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[7] Enzyme Mechanism - Chymotryipsin
Hydrophobic pocket Active site residues
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Lehninger p.216
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Hexokinase and Induced Fit
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[7] Enzyme regulation The rates of enzyme-catalyzed reactions are altered by activators and inhibitors (a.k.a. effector molecules). (1) Allosteric enzymes: have more than one site, where effector binding at one site induces a conformational change in the enzyme, altering its affinity for a substrate. An allosteric activator increases enzyme rate of activity, an allosteric inhibitor decreases its activity. Regulation mechanism: Reversible, noncovalent binding of allosteric effectors. Covalent modification (phosphorylation, adenylation, etc.). Binding by separate regulatory proteins. Proteolytic activation (irreversible).
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In most cases, the first enzyme of the multireaction pathway (catabolism, anabolism) is a regulatory enzyme to avoid unneeded accumulation of the intermediates.
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(2) Feedback inhibition: An enzyme,
early in the metabolic pathway, is inhibited by an end-product. Often takes place at the committed step of the pathway, the step which commits a metabolite to a pathway.
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(3) Regulatory enzymes are generally more complex than other enzymes,
i.e. Aspartate transcarbamoylase – first step in CTP synthesis, converts Asp to N-carbamoyl Asp CO2 + Gln + ATP H2N-(C=O)-OPO32- (carbamoyl phosphate) Asp transcarbamoylase catalyzes the following reaction: Carbamoyl phosphate + Asp N-carbamoylAspartate CTP (building block of DNA) CTP, the end product of the reaction, decreases the rate of enzyme activity – allosteric inhibitor. ATP increases the rate of enzyme activity – allosteric activator. Many effectors work in concert to regulate the pathway.
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Catalytic domains Catalytic domains Catalytic domains
Catalytic domains Catalytic domains Catalytic domains Regulatory domains
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(4) Kinetic properties of regulatory enzymes
The relationship between enzyme velocity and substrate concentration is often a sigmoidal saturation curve for an allosteric enzyme rather than hyperbolic (Michaelis), and we no longer refer to substrate concentration at half maximal velocity as Km, we use [S]0.5 or K0.5.
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(a) Homotropic allosteric enzymes (substrate = effector):
- Multisubunit enzymes. - The same binding site on each subunit functions as both active site and regulatory site. - Substrate acts as an activator as well. (O2 and Hb). - Binding of one substrate alters the enzyme’s conformation and enhances the binding of subsequent substrates. ⇒ Sigmoidal kinetics. ⇒ sensitive to a small change in [S]. (b) Heterotropic allosteric enzymes (substrate = effector)
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(5) Reversible Covalent Modification: is the making and breaking of a covalent bond between a non-protein group and an enzyme that affects its activity. Examples of some transfer groups: ① Phosphate groups: cause a change in the 3D structure enhancing or inhibiting enzyme activity. Enzymes are phosphorylated by a protein kinase or dephosphorylated by a phosphatase.
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Glycogen phosphorylase (Glucose)n + Pi (glucose)n-1 + glucose 1-Ⓟ Glycogen Shortened glycogen
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② Adenylation: the transfer of adenylate from ATP
③ ADP-ribosylation: the transfer of an adenosine diphosphate-ribosyl moiety from NAD+ ④ Uridylation ⑤ Methylation
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(6) Proteolytic activation:
Some enzymes are synthesized as larger inactive precursor forms called proenzymes or zymogens. Activation involves the irreversible hydrolysis of one or more peptide bonds, resulting in an active form.
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