• Introduction to Protein Structure and Function
• 40 min
  1. Nature’s strategies in the regulation of enzyme activity by modifiers

  • Prof. Antonio Baici
• Creation of Protein Variability by Manipulation of Genes
• 28 min
  2. Understanding protein variability through functional analysis of random mutagenesis

  • Prof. Andrew Kaplan
• 48 min
  3. Perspectives on biological catalysis

  • Prof. Stephen Benkovic
• 45 min
  4. Fundamentals and principles for engineering proteolytic activity

  • Prof. Charles Craik
• Metabolic Diseases Caused by Genetic Mutation
• 36 min
  5. Modifications of pyruvate handling in health and disease

  • Prof. Mary Sugden
• 29 min
  6. Mitochondrial fatty acid oxidation deficiencies

  • Prof. Niels Gregersen
• 33 min
  7. Inborn errors of ketone body metabolism

  • Prof. Toshiyuki Fukao
• 34 min
  8. Cathepsin K in bone and joint diseases

  • Prof. Dieter Bromme
• 22 min
  9. Fabry disease: alfa-galactosidase A deficiency and enzyme replacement therapy

  • Prof. David Warnock
• 47 min
  10. Acid beta-glucosidase/glucocerebrosidase (GCase)

  • Prof. Gregory Grabowski
• 23 min
  11. GM2 gangliosidosis future treatments 1

  • Prof. Brian Mark
• 19 min
  12. GM2 gangliosidosis future treatments 2

  • Prof. Brian Mark
• 29 min
  13. The neuronal ceroid lipofuscinoses

  • Prof. Sandra Hofmann
• Disorders of Blood Coagulation
• 24 min
  14. Advances in fibrinolysis

  • Dr. Paul Kim
• 26 min
  15. Tissue factor and factor VII: initiation of blood coagulation

  • Dr. John McVey
• 36 min
  16. Structure of thrombin, a Janus-headed proteinase

  • Prof. Wolfram Bode
• 45 min
  17. The protein c-thrombomodulin mechanism: regulating multiple biological systems

  • Prof. Edward Conway
• 40 min
  18. Fibrinogen and factor XIII

  • Prof. John Weisel
• 31 min
  19. Factor VIII and haemophilia A

  • Dr. Geoffrey Kemball-Cook
• 34 min
  20. Factor IX

  • Prof. Bruce Furie
• 42 min
  21. The biology and pathobiology of von Willebrand factor

  • Prof. David Lillicrap
• 40 min
  22. Thrombotic thrombocytopenic purpura

  • Prof. J. Evan Sadler
• 26 min
  23. Fibrinolysis

  • Prof. Edward Tuddenham
• Other Molecular and Metabolic Disorders
• 45 min
  24. Glucose-6-phosphate dehydrogenase deficiency

  • Dr. Jane Leopold
• 26 min
  25. Cytochrome b5 reductase deficiency and hereditary methemoglobinemia

  • Dr. Scott Reading
• 50 min
  26. Sickle cell disease

  • Prof. Martin H. Steinberg
• 40 min
  27. Pyruvate kinase deficiency

  • Prof. Alberto Zanella
• 47 min
  28. Heritable disorders of collagen

  • Dr. Heather Yeowell
• 40 min
  29. Duchenne muscular dystrophy

  • Prof. Jeff Chamberlain
• Archived Lectures *These may not cover the latest advances in the field
• 33 min
  30. Protein crystallography

  • Prof. Michael James
• 48 min
  31. Regulation of blood coagulation by the serpin, antithrombin

  • Prof. Steve Olson
• 37 min
  32. Rhodopsin and retinitis pigmentosa

  • Dr. Shalesh Kaushal
• 40 min
  33. The physiology and pathology of coagulation factor XI

  • Dr. David Gailani
• 24 min
  34. Cytochrome b5 reductase deficiency and hereditary methemoglobinemia

  • Prof. Josef Prchal
• 49 min
  35. Metachromatic leukodystrophy

  • Prof. Volkmar Gieselmann
• 21 min
  36. Serpins and serpinopathies

  • Dr. James Whisstock
• 27 min
  37. Multiple acyl-CoA dehydrogenation deficiency: defects of electron transfer flavoproteins

  • Dr. Rikke Olsen
• 39 min
  38. Pleiotropic and epistatic genes in sickle cell anaemia

  • Prof. Ronald Nagel
• 44 min
  39. Genetic disorders of carbonic anhydrases II and IV

  • Prof. William Sly
• 39 min
  40. GM2 gangliosidoses

  • Prof. Don Mahuran
• 48 min
  41. Kinetic analysis of protein activity

  • Prof. Antonio Baici

Printable Handouts

PDF

Navigable Slide Index

1. Introduction
2. Why kinetics with proteins?
3. Content of presentation
4. Nomenclature, symbols, terms
5. Thermodynamics in biochemistry
6. Binding of ligands to proteins
7. Thermodynamics versus kinetics
8. Kinetics of protein action
9. Transition state diagram
10. Energy and the rate of reactions
11. Energetics of enzyme catalysis
12. Energy and rate constants
13. A typical case
14. The Michaelis-Menten mechanism
15. Planning ahead
16. Conventional data acquisition
17. Possible loss of information
18. Stopped-flow
19. Stopped-flow continued
20. Fast reaction
21. Principle of relaxation kinetics
22. Methods in relaxation kinetics
23. The relaxation process
24. Relaxation time and mechanisms
25. Interactions without catalysis
26. Rapid equlibrium assumption
27. Steady-state approach
28. Equilibrium vs. steady state
29. Reaction progress: S and P
30. Reaction progress: ES and E
31. The very beginning: E and ES
32. The very beginning: S and P
33. The true steady state velocity
34. Validity of steady state
35. From data to mechanisms
36. Graphical and regression analysis
37. Enzyme inhibition
38. The general modifier mechanism
39. The specific velocity equation
40. The specific velocity plot
41. Primary specific velocity plot
42. Secondary specific velocity plot
43. Example of kinetic analysis
44. Specific velocity plot - primary
45. Specific velocity plot - secondary
46. Inhibition profile and the final polish
47. The most likely mechanism
48. Not just an academic exercise
49. Slow and fast-binding inhibition, slow isomerization
50. Rare inhibitor species
51. Progress curve for slow inhibition
52. Equation fitted to data
53. The delay time for inhibition
54. Fast enough?
55. Thanks
56. References

Topics Covered

• Thermodynamics vs. kinetics
• Enzyme catalysis
• Conventional and rapid kinetic methods
• Equilibrium and steady-state approaches
• The phases of an enzymatic reaction
• Graphical and statistical analysis
• Enzyme inhibition
• The importance of kinetics for protein activity

Links

Series:

• Protein Epidemiology

Categories:

• Biochemistry
• Cell Biology
• Methods

Talk Citation

Publication History

• Published on October 1, 2007
• Reviewed on September 6, 2015
• Archived on March 30, 2023

Financial Disclosures

• There are no commercial/financial matters to disclose.