Isothermal Titration Calorimetry in Enzymology

<p>PART 1: ITC kinetics measurements<br>1. Enzyme kinetics by ITC<br>2. Measuring binding kinetics by ITC<br>3. Analysing ITC kinetic data with AFFinimeter software<br>4. In vivo enzyme kinetics by ITC<br>5. Characterizing enzyme kinetics by 2D-ITC<br>6. Measuring enzyme stability using ITC<br>7. Kinetics of immobilized enzymes<br>8. Enzyme kinetics in crowded solutions<br>9. Kinetics of nanozymes<br>10. Using ITC to characterize enzyme allostery<br>11. Signal amplification in ITC kinetics experiments<br>12. ITC kinetic studies of 6-phytase<br>13. Catalysis of biological substrates of nuclear metallohydrolases<br>14. Alpha-amylase activity and inhibition<br>15. Enzyme stability and activity of psycrophillic enzymes<br>16. Non-MM kinetics of peroxidases and application to industrial wastes<br>17. Kinetics of diphosphohydrolases<br><br>PART 2: ITC thermodynamic measurements<br>18. Interpretation of ITC binding curves<br>19. Analysis of ITC binding data using SEDPHAT<br>20. ITC in drug discovery<br>21. ITC in the development of cancer therapeutics<br>22. Mechanisms of aminoglycoside resistance enzymes<br>23. Using ITC to characterize the interactions of natural products with biomolecules<br>24. ITC studies of metalloenzymes<br>25. Enzyme interactions with toxic metals<br>26. Thermodynamics of molecular machines<br>27. Thermodynamics of protein chaperones<br>28. Characterizing protein interactions in apoptosis by ITC<br>29. Using ITC to study ubiquitination<br>30. Thermodynamics of transition state analogs<br>31. Thermodynamics of recombinant enzymes in biotechnology<br>32. Ion Binding to Transport Proteins using ITC<br>33. Urease from Helicobacter pylori, lessons from ITC<br>34. Substrate recognition by Chitinases<br>35. ITC studies of glycoside hydrolases</p>