Regulation of Metabolism

1. Regulation of Metabolism

2. Rationale for Regulation

3. Biological Efficiency • Flexibility: adaptaton to dietary changes • Need for biosynthetic products • Control of pre-existing enzymes • Modulation: biosynthesis only as fast as needs for macromolecular syntesis

4. Competing Reactions: Regulation

5. Kinetic Controls

6. Control Mechanisms • Control of Enzyme Amount • Induction and Repression • Catabolite Repression • Attenuaton • Control of Enzyme Activity • Modulation of k or Vmax (rare) • Control of Km’s • Control of Substrate Availability

7. Review of Genetic Regulation General Principles

8. Types of Enzymes • Constitutive Enzymes: e.g. glycolytic enzymes and gluconeogenic enzymes • Inducible Enzymes: e.g. b-galactosidase • Repressible Enzymes: e.g. ten enzymes of histidine biosynthesis

9. Sites of Regulation Prokaryotes: usually at transcription initiation. Eukaryotes: can be anywhere!

10. Types of Regulation • Specific: one pathway’s substrate or product • General: needs for C or N sources or growth rates (e.g. energy charge)

11. Signals Mediating Regulation Availability of Substrates or Products (Ligands) Regulatory Proteins

12. Gene Organization and Control

13. Gene Expression in Bacteria(Operon Model)

14. Upstream Regulatory Sequences • Promoter (general term) • UAS (Upstream Activation Sequence) • Enhancers • URS (Upstream Repression Sequence) • Operator

15. Binding of RNA Polymerase to Promoter • Affected by regulators • Affected by “strength” of promoter: provides appropriate variation in enzyme levels

16. Gene Expression in Eukaryotes Dispersed Genes

17. Mechanisms of Gene Regulation

18. Negative Regulators[Bind to operators or upstream repression sequences (URS)]

19. Positive Regulators[Bind to promoters, enhancers or upstream activation sequences (UAS)]

20. Attenuation in Bacteria(Coupled Transcription and Translation)

21. Mechanism of Attenuation NOTE: Negative Regulatory System

22. Discovery of Attenuation Charles Yanofsky

23. Control of Enzyme Activity

24. Irreversible Covalent Modification • Zymogen Activation • Proteolysis • Lysosomes • Proteosomes (ubiquitin)

25. Reversible Covalent Modification

26. Non-covalent Modification Effectors or Ligands

27. Negative Effectors

28. Positive Effectors

29. Allosteric Proteins

30. Energy Charge(Daniel Atkinson) Steady-State E.C. = 0.93 ATP, ADP and AMP = Regulatory Ligands

31. Regulation of Degradative Pathways

32. Degradative Pathways

33. Enzyme Amount Induction (Inducer = Substrate) Catabolite Repression

34. Negative Regulators

35. Positive Regulators

36. Enzyme Activity Regulation Unnecessary No Substrate = No Flux

37. Lactose Utilization NOTE: function is to provide carbon and energy when substrate is available and when products are needed.

38. Regulation of Enzyme Amount

39. Regulation • Specific Regulation: mediated by availability of substrate called effector (or inducer) – e.g. lactose (allolactose) through its interaction with a regulatory protein. • General Regulation: e.g. catabolite repression – analogous to repression in that endproduct effector (catabolite co-repressor) prevents gene expression, often by interacting with a regulatory protein, but may use second messenger system – e.g. cAMP.

40. Physiological Manifestations of Catabolite Repression

41. Structure of Lac Operon

42. Regulation of the Lac Operon

43. Requirements for Gene Expression • Availability of Substrate: Lactose (or allolactose) and • Need for Product: low [glucose) —> cAMP

44. Mechanism of Catabolite Repression

45. Inducible Operon(Positive Regulator)

46. Hut Operon of Klebsiella aerogenes

47. Pathway

48. Regulation hisR+ Enzyme Levels hisRC Enzyme Levels

49. Mechanism of Regulation Carbon Catabolite Repression Nitrogen Metabolite Repression

50. Regulation of Biosynthetic Pathways