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Introduction to Enzymes Biological Catalysts Life Process = Chemical Reactions Enzymes A Enzyme 1 B Enzyme 2 C Enzyme 3 D Enzyme 4 E Enzyme 5 F Chemical Reactions Spontaneous and Fast HCl + NaOH Na+ + Cl- + H2 O Spontaneous but Slow 2 H2 + O2 ATP + H 2O 2 H2 O ADP + Pi Types of Reactions • Spontaneous Reactions: thermodynamically or energetically favorable • Kinetically Unfavorable Reactions • Requirement for Catalysts – Protein Catalysts: Enzymes – RNA Catalysts: Ribozymes General Properties of Enzymes • Higher reaction rates (catalytic power) • Milder reaction conditions • Greater reaction specificity • Capacity for regulation Higher Reaction Rates Carbonic Anhydrase CO2 + H2O H2 CO3 105 molecules CO2 per enzyme molecule per second 107 x uncatalyzed reaction Catalytic Power of Some Enzymes Table 11-1 Mild Reaction Condition • Physiological pH = ~7.3 • Temperature = ~37°C Greater Reaction Specificity Hexokinase Glucose + ATP Fructose + ATP Mannose + ATP Glucose-6-P + ADP Fructose-6-P + ADP Mannose-6-P + ADP Glucokinase Glucose + ATP Table 11-1 ONLY Glucose-6-P + ADP Capacity for Regulation • Allosteric (Regulatory) Enzymes • Covalent Modification – Irreversible – Reversible • Non-covalent Modification Enzyme Classes • Oxidoreductases: oxidation-reduction reactions • Transferases: transfer of functional groups • Hydrolases: hydrolysis reactions (cleavage and introduction of water) • Lyases: group elimination to form double bond • Isomerases: isomerization (intramolecular rearrangements • Ligases (synthases): bond formation coupled with ATP hydrolysis Enzyme Nomenclature (Usual usage: often use suffix –ase) • Common Name: – Useful but sometimes ambiguous • Examples: Urease/Arginase • Exceptions to the –ase suffix: – Trypsin/Chymotrypsin • Systematic Name: – Substrate(s) Type of reaction-ase Enzyme Nomenclature (Common Name versus Systematic Name) Aconitase Aconitate Hydratase EC 4.2.1.3 Enzyme Nomenclature (Common Name versus Systematic Name) Aconitase Aconitate Hydratase EC 4.2.1.3 Enzyme Nomenclature (Common Name versus Systematic Name) O OH H3C CH COOH Lactate + NAD+ H3C C COOH + Pyruvate Lactate Dehydrogenase L-Lactate:NAD Oxidoreductase NADH + H+ Enzyme Nomenclature (Common Name versus Systematic Name) O OH H3C CH COOH Lactate + NAD+ H3C C COOH + Pyruvate Lactate Dehydrogenase L-Lactate:NAD Oxidoreductase NADH + H+ Enzyme Catalysis Substrate(s) Product(s) Reaction Pathway (Coordinate) CH3Br H OH - + H + OH - CH3OH H Reactants Br HO Br - H H C + C Br H "Transition State" H HO C H H Products + Br - Transition State Diagram Stabilizing the transition state Catalysts Pathway of Enzyme Catalysis E+S Binding [E–S] Catalysis Enzyme–Substrate Complex Active Site E+P Substrate Specificity • Active Site – Lock and Key Model – Induced Fit Model • Stereospecificity: 3-point attachment • Geometric Specificity: e.g. trypsin and chymotrypsin Principle of Complementarity • Geometric (physical) complementarity • Electronic (chemical) complementarity Enzyme-Substrate Complex Binding Site Models of Complementarity Lock and Key Induced Fit Enzymes are Stereospecific Aconitase Reaction Prochiral Substrate Page 325 Chiral Product Stereospecificity in Substrate Binding Figure 11-2 Enzymes Vary in Geometric Specificity (Alcohol Dehydrogenase) Ethanol ——> Acetaldehyde Methanol ——> Formaldehyde Isopropanol ——> Dimethylketone RATE: Ethanol > Methanol > Isopropanol Trypsin and Chymotrypsin H2O O NH CH C O NH R1 R1 C R2 O NH CH CH C _ O + + H 3N O CH R2 C Trypsin H2O O N NH arginine or lysine CH + C NH C Long "long +positively side chain"charged side chain complementary binding or positioning site _ "SPECIFICITY" Chymotrypsin H2O O N NH phenylalanine tyrosine tryptophan CH C O NH C "aromatic side chain" Aromatic side chain complementary binding or positioning site Hydrophobic Pocket "SPECIFICITY" Some Enzymes Require Cofactors Cofactors • Simple Proteins (no cofactor) • Protein plus Cofactor – Apoenzyme: protein only – Holoenzyme: protein plus cofactor Apoenzyme + cofactor (inactive) Holoenzyme (active) Types of Cofactors Organic Cofactor Transiently Associated Figure 11-3 Permanently Associated Metal Ions Coenzymes: Cosubstrates [NAD(P)+ ——> NAD(P)H + H+] Figure 11-4 NADP+ O C O P O CH2 O– O N OH Nucleotide O OH O P O CH2 O– NH2 OH O A Nucleotide OPO3= NADPH H O C H N R NH2 Coenzymes: Cosubstrates (Alcohol Dehydrogenase) Page 327 Coenzymes: Prosthetic Groups (Cytochromes) Cytochrome•Heme(Fe3+) e– e– Cytochrome•Heme(Fe2+) Coenzymes Must be Regenerated 2H+ + 2e– NAD+ e– NADH + H+ 2H+ + 2e– Alcohol Dehydrogenase Cosubstrate: Different enzyme Heme(Fe3+) Heme(Fe2+) e– Cytochromes Prosthetic group: Same enzyme Control of Enzyme Activity Irreversible Covalent Modification • Zymogen Activation • Proteolysis – Lysosomes – Proteosomes (ubiquitin) Zymogen Activation H2O + "Inactive" "Active" Reversible Covalent Modification (glucose)n Phosphorylase Phosphatase + Phosphorylase Pi (glucose)n-1 P P P P glucose-1-P Phosphorylase a "active" 4 H2 O 4 ADP 4 Pi 4 ATP + + Phosphorylase Kinase Phosphorylase b "inactive" Non-covalent Modification Effectors or Ligands Negative Effectors + Active Site I I Regulatory Site "active" "inactive" or less active Positive Effectors + + + "inactive" or poorly active "active" or more active Allosteric Proteins no effector Vo negative effector positive effector [S] General Properties of Enzymes • Biological Catalysts – Not used up in the reaction (Regenerated) – Higher reaction rates (catalytic power) • Within a biologically relevant time frame – Milder reaction conditions • Biologically appropriate conditions – Greater reaction specificity – Capacity for regulation • Control of substrate and product availability
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