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J. D. Honeycutt and D. Thirumalai, “The nature of folded states of globular proteins,” Biopolymers 32 (1992) 695. T. Veitshans, D. Klimov, and D. Thirumalai,

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Presentation on theme: "J. D. Honeycutt and D. Thirumalai, “The nature of folded states of globular proteins,” Biopolymers 32 (1992) 695. T. Veitshans, D. Klimov, and D. Thirumalai,"— Presentation transcript:

1 J. D. Honeycutt and D. Thirumalai, “The nature of folded states of globular proteins,” Biopolymers 32 (1992) 695. T. Veitshans, D. Klimov, and D. Thirumalai, “Protein folding kinetics: timescales, pathways and energy landscapes in terms of sequence-dependent properties,” Folding & Design 2 (1996)1. Coarse-grained (continuum, implicit solvent, C  ) models for proteins 1

2 3-letter C  model: B 9 N 3 (LB) 4 N 3 B 9 N 3 (LB) 5 L B=hydrophobic N=neutral L=hydrophilic N sequences = 3 ~ 10 22 N p ~ exp(aN m )~10 19 Number of structures per sequence Number of sequences for N m =46 2

3 different mapping? and dynamics 3

4 Molecular Dynamics: Equations of Motion for i=1,…N atoms Coupled 2nd order Diff. Eq. How are they coupled? 4

5 (iv) Bond length potential 5

6 Pair Forces: Lennard-Jones Interactions i j Parallelogram rule -dV/dr ij > 0; repulsive -dV/dr ij < 0; attractive force on i due to j 6

7 ‘Long-range interactions’ BB V(r) r/  NB, NL, NN LL, LB r*=2 1/6  hard-core attractions -dV/dr < 0 7

8 Bond Angle Potential  0 =105  ij k  ijk  ijk =[0,  ] 8

9 Dihedral Angle Potential V d (  ijkl )  ijkl Successive N’s 9

10 Bond Stretch Potential ij for i, j=i+1, i-1 10

11 Equations of Motion velocity verlet algorithm Constant Energy vs. Constant Temperature (velocity rescaling, Langevin/Nosé-Hoover thermostats) 11

12 Collapsed Structure T 0 =5  h ; fast quench; (R g /  ) 2 = 5.48 12

13 Native State T 0 =  h ; slow quench; (R g /  ) 2 = 7.78 13

14

15

16 startend 16

17 native states Total Potential Energy 17

18 slow quench unfolded native state Radius of Gyration TfTf 18

19 Reliable Folding at Low Rate 19

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