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Catalytic Strategies

Catalytic Strategies. Basic Catalytic Principles. What is meant by the binding energy as it relates to enzyme substrate interactions? free energy released by formation of weak interactions between enzyme and substrate How is binding energy used in catalysis? establishes substrate specificity

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Catalytic Strategies

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  1. Catalytic Strategies

  2. Basic Catalytic Principles • What is meant by the binding energy as it relates to enzyme substrate interactions? • free energy released by formation of weak interactions between enzyme and substrate • How is binding energy used in catalysis? • establishes substrate specificity • increases catalytic efficiency • promotes structural changes in enzyme and substrate

  3. Basic Catalytic Principles • What are the four strategies used by enzymes to carry out catalysis? • covalent catalysis • functional groups in enzyme act as nucleophile • OH groups of serine • SH groups of cysteine • Imidazole group of histidine • example - chymotrypsin

  4. Basic Catalytic Principles • general acid-base catalysis • enzymes provide functional groups that act as proton donors or acceptors • amino groups • carboxyl groups • sulfhydryl groups • Example – lysozyme (donates proton)

  5. Basic Catalytic Principles • metal ion catalysis • metal ion acts as electrophilic catalyst • stabilizes negative charge on intermediate • metal ion may generate a nucleophile by increasing acidity of nearby molecule • example – carbonic anhydrase • metal ion may bind to substrate and increase binding energy • example – NMP kinases

  6. Basic Catalytic Principles • catalysis by approximation • binding to enzyme brings two substrates together • example – NMP kinases • binding to enzyme orients substrate • susceptible bond is close to catalytic groups of active site • orbital steering (Koshland and Storm)

  7. Proteases • What are proteases? • protein degrading enzymes • Why are proteases important in biological systems? • recycling of amino acids • digestion of proteins in diet • Enzyme regulation

  8. Proteases • Describe the reaction catalyzed by proteases. • Why is it so difficult to break a peptide bond?

  9. Chymotrypsin • What is the nature of the reaction is catalyzed by chymotrypsin?

  10. Chymotrypsin • What catalytic strategy does chymotrypsin use? • covalent catalysis • nucleophilic group in enzyme attacks unreactive carbonyl group of substrate forming covalent bond • Which group of enzyme acts as the nucleophile? • serine 195

  11. Chymotrypsin • How was it possible to identify the specific functional group involved in catalysis?

  12. Chymotrypsin • What are the two steps involved in the action of chymotrypsin?

  13. Chymostrypsin • Can see two stages of chymotrypsin catalysis

  14. Chymotrypsin • Three-dimensional structure of enzyme has helped to reveal its catalytic mechanism

  15. Chymotrypsin • Three amino acid residues are involved in catalysis: serine 195, histidine 57, aspartate 102

  16. Chymotrypsinmechanism of action

  17. Chymotrypsinmechanism of action

  18. Chymotrypsinmechanism of action

  19. Chymotrypsinmechanism of action

  20. Chymotrypsinmechanism of action

  21. Chymotrypsinmechanism of action

  22. Chymotrypsinmechanism of action

  23. Chymotrypsinmechanism of action

  24. Chymotrypsinmechanism of action • Unstable tetrahydral intermediate is stabilized by interactions with NH groups from protein at oxyanion hole

  25. Chymotrypsin • What accounts for the preference of this enzyme cleaving peptide bonds adjacent to residues with large hydrophobic side chains?

  26. Serine Proteases • Other proteases use same catalytic triad • trypsin • cleaves at peptide bond after residue with long, positively charged side chain • elastase • cleaves at peptide bond after residue with small side chains • Specificity depends upon residues in pocket

  27. Serine Proteases • Subtilisin from Bacillus amyloliquefaciens also uses catalytic triad and oxyanion hole

  28. Serine Proteases • Carboxypeptidase II which has a very different structure also uses catalytic triad and oxyanion hole

  29. Serine Proteases • Presence of similar active sites in different protein families is a result of convergent evolution. • What does this tell us about this mechanism for the hydrolysis of peptides? • What is site-directed mutagenesis and how is it used?

  30. Other Proteases • What are cysteine, aspartyl and metalloproteases? • Cysteine proteases – cysteine residue acts as nucleophile • Papain • Aspartyl proteases – pair of aspartate residues act to enable water molecule to attack peptide bond • renin

  31. Other Proteases • Metalloproteases – active site contains a metal ion that activates water to act as a nucleophile • metal is usually zinc • Carboxypeptidase A

  32. Protease Inhibitors • Several useful drugs • Catopril – ACE inhibitor • regulator of blood pressure • Crixivan – HIV protease • AIDS treatment

  33. Carbonic Anhydrases • What is the reaction catalyzed by these enzymes? • CO2 + H2O  H2CO3  HCO3- + H+ • Where does this reaction take place?

  34. Carbonic Anhydrases • What metal ion is associated with these enzymes and where is it bound to the enzyme?

  35. Carbonic Anhydrases • How does the zinc complex facilitate the hydration of carbon dioxide? • Binding of water to zinc reduces pKa of water from 15.7 to 7 and creates a hydroxide ion that can act as a nucleophile

  36. Carbonic Anhydrases • Mechanism of action

  37. Carbonic Anhydrases • What enables these enzymes to be extremely effective catalysts? • Proton shuttle mechanism

  38. Restriction Enzymes • What are restriction endonucleases and how have they been used by bacterial cells? • Enzymes that cleave DNA • Protection against invading viruses • What is cognate DNA? • DNA containing recognition sites

  39. Restriction Enzymes • How do bacteria protect their own DNA from cleavage?

  40. Restriction Enzymes • What bond is cleaved by these enzymes? • Bond between 3! oxygen atom an phosphorous atom

  41. Restriction Enzymes • What is the mechanism of this reaction? • direct attack of water as a nucleophile on phosphorous • Why is Mg+2 needed for activity? • Mg+2 helps position water molecule to attack phosphate • Mg+2 along with aspartate residue helps to deprotinate water molecule

  42. Restriction Enzymes

  43. Restriction Enzymes • What ensures specificity of the EcoRV reaction? • Inverted repeats of recognition site creates a twofold rotational symmetry

  44. Restriction Enzymes • G and A bases at 5! End form hydrogen bonds with residues from two loops of enzyme causing distortion of DNA and bonding with Mg+2

  45. Restriction Enzymes • How does methylation protect host DNA from restriction enzymes?

  46. Restriction Enzymes • What is horizontal gene transfer and how do this relate to the presence of restriction enzymes in bacteria?

  47. Restriction Enzymes • Different bacteria share common gene sequences and a similar active site conformation

  48. NMP Kinases • What reaction do nucleoside monophosphate kinases catalyze? • transfer of phosphate group from a nucleoside triphosphate to a nucleoside monophosphate • Example of NMP kinase? • adenylate kinase

  49. NMP Kinases

  50. NMP Kinases • What structural features does this family of enzymes have in common?

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