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Ligand configurational entropy and protein binding Chia-en A. Chang, Wei Chen, and Michael K. Gilson – PNAS(2007) Presented by Christopher Williams.

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Presentation on theme: "Ligand configurational entropy and protein binding Chia-en A. Chang, Wei Chen, and Michael K. Gilson – PNAS(2007) Presented by Christopher Williams."— Presentation transcript:

1 Ligand configurational entropy and protein binding Chia-en A. Chang, Wei Chen, and Michael K. Gilson – PNAS(2007) Presented by Christopher Williams

2 Remember K*? Uses conformational entropy of side chains to better predict redesign mutations

3 What about ligands? Entropy is lost on binding How much? What kind? Do we care?

4 Configurational Entropy

5 Conformational EntropyVibrational Entropy

6 Configurational Entropy Conformational EntropyVibrational Entropy

7 Configurational Entropy Conformational EntropyVibrational Entropy Rotation/ Translation Torsion Angle Bending Bond Stretching

8 Energy Well More Wells Wider Well Higher Conformational Entropy Higher Vibrational Entropy

9 How to measure entropy S = k ln(W)  k = Boltzman constant  W = Multiplicity j

10 The test case Amprenavir, an HIV protease inhibitor

11 Results Configurational entropy loss on binding: 26.4 kcal/mol # of accessible conformations in solution: 960 # of accessible conformations bound: 1  ΔS = RT ln(960) Conformational entropy contribution: 4.1 kcal/mol

12 Results Configuational entropy loss on binding: 26.4 kcal/mol Entropy loss: torsion only: 12.2 kcal/mol Entropy loss: rotation/translation only: 15.7 kcal/mol 12.2 + 15.7 = 27.9 != 26.7 kcal/mol

13

14 Configurational Entropy Conformational EntropyVibrational Entropy Rotation/ Translation Torsion Angle Bending Bond Stretching There is correlation among the “separate” components of configurational entropy

15 Proof? Similar results were returned by a separate analysis  “Quasiharmonic analysis” – essentially an MD approach  Compare 11.6 kcal/ mol to 12.3 kcal/mol Cannot test in wetleb  Cannot yet measure separate components of entropy

16 Predictions and Observations Configurational entropy has a similar magnitude effect to electrostatics or hydrophobics ~25 kcal/mol  Does not include protein  Varies by ligand  Varies by tightness of binding

17 Predictions and Observations Vibrational entropy loss dominates  Not conformational/rotamer loss  This challenges conventional thinking Certain atom centers are more prone to vibrational entropy  sp3 versus ring structures

18 Applications to design Optimizing drugs  Entropy loss inhibits binding  Rigid ligands have less entropy to lose

19 Applications to design Improving Scoring Functions  Current functions overweight conformational entropy, underweight vibrational  Varies by ligand

20 Applications to design Computational savings  Vibrational entropy dominates  May not have to enumerate every minumum

21 Chia-en A. Chang, Wei Chen, & Michael K. Gilson. Ligand configurational entropy and protein binding. 2007 PNAS 104(5):1534-1539

22 Questions

23 Mining Minima Margin of Error: ± 0.8 kcal/mol

24 q.e.d

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