Enzyme Mechanisms C483 Spring 2013.

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Presentation transcript:

Enzyme Mechanisms C483 Spring 2013

Questions 1. Replacement of the amino acid ________ at or near an active site of an enzyme is more likely to change enzyme activity than the replacement of ________ at or near the active site. A) histidine; leucine B) leucine; histidine C) leucine; isoleucine D) histidine; aspartate 2. The following pH dependence was found for the activity of a certain enzyme-catalyzed reaction. If it is known that the only two ionizable residues in the active site are both glutamates, which conclusion can be drawn? A) The glutamates have different microenvironments which cause their pKa's to differ. B) One of the glutamates must be amidated. C) Both glutamates have a pKa equal to 5.0. D) Both glutamates are deprotonated during the reaction.

3. An update of Fischer's lock-and-key theory of enzyme specificity views the ________ as the lock and ________ as the key. A) enzyme; substrate B) substrate; enzyme C) enzyme; transition state D) transition state; enzyme E) substrate; transition state 4. One reason the proximity effect enhances catalysis is because A) the effective molarity of reactive substrate groups increases. B) the enzyme changes conformation to more readily accept the substrate as it approaches the active site. C) the active site becomes smaller. D) the catalytic triad in the active site becomes more flexible.

Mechanisms Four major mechanisms—any or all may be used in a given enzyme Binding Mechanisms Proximity effect Transition State Stabilization Chemical Mechanisms Acid-base catalysis Covalent Catalysis

Binding Energy Binding based on intermolecular forces “Lock and Key” Selectivity Rate Enhancement Effective concentration Entropy trap Productive orientation of two molecules in the active site

Effective Molarity May be higher than actual molarity possibility Entropic help

Induced Fit “Lock and Key” too simplistic Enzymes are actually somewhat flexible Substrate specificity comes at catalytic price kcat = 103 per second, but worth cost

Lowering Activation Energy Transition state stabilization is half the story

Weak Binding of Substrate Substrate binding: too much of a good thing Thermodynamic pit KM ~ 10-4 M Can be 10-6 M for cofactors

Transition State Binding Transition State Analogs Actually, high energy intermediate analog

Designing a Transition State Analog

Binding of Transition State Analog

Binding Catalysis and … Some sidechains occur often in active site From previous slide, polar and charged amino acids make specific contacts Charge/charge, H-bond, etc

…Chemical Catalysis The same sidechains that bind can ofter conduct proton transfers Acid-Base Catalysis

General Acid-Base Catalysis H+ and HO- are “specific acid/base” and depend on pH Amino acid sidechains are general acid-base, and can conduct reactions inside active site pocket that aren‘t possible in solution

Covalent Catalysis Active site nucleophile Group transfer reaction

pH affects Enzyme Catalysis Propose possible explanations of pH profile

Case Study: Diffusion Controlled Enzymes

Triose Phosphate Isomerase

Mechanism Be able to explain catalytic function of AA in each step of a mechanism

Superoxide Dismutase: Better than Diffusion!

Answers A C