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The Role of Entropy in Biomolecular Modelling Three Examples 1.Force Field Development How to parametrise non-bonded interaction terms? Include Entropy.

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Presentation on theme: "The Role of Entropy in Biomolecular Modelling Three Examples 1.Force Field Development How to parametrise non-bonded interaction terms? Include Entropy."— Presentation transcript:

1 The Role of Entropy in Biomolecular Modelling Three Examples 1.Force Field Development How to parametrise non-bonded interaction terms? Include Entropy of variety of solutes Simulation at finite T

2 The Role of Entropy in Biomolecular Modelling 3. Protein-Ligand Complexation: Ligand binding to the Estrogen Receptor: A variety of configurations (ensemble) contributes to binding, both in the protein and in water Continuum representation of the solvent is unable to mimic binding subtleties of individual solvent or co-solvent molecules 2. Partitioning of Solutes between various Solvent Mixtures Solvation of small molecules: H S Enthalpy co-act or may depending on mixture and solute S S Entropycounteract Continium methods will not catch these entropic effects

3 Four Ways to Compute Entropy Differences Coupling Parameters approach Hamiltonian is made function of : Free energy depends on : 1.Entropy Difference via Thermodynamic Intergration (TI) Free Energy Difference and End States Energy Difference accurate not so acc u rate

4 Four Ways to Compute Entropy Differences using and 2. Entropy Difference directly via TI correlation betweenandnot so accurate only -dependent terms all terms 3. Entropy Difference via finite Temperature Difference using difference between almost equal accurate values

5 Four Ways to Compute Entropy Differences 4. Solvation Entropy Difference via Solute-Solvent Entropy Difference (using TI) and End States Solvent-Solvent Energy Difference accurate only solute-solvent terms not so accurate all solvent terms solvent: v solute: u

6 Comparison of 1. Excess Free Energy, Entropy of Water 2. Hydration Free Energy, Entropy of Water Using four different Methods Three Models or Hamiltonians: 1.SPC Model: Coulomb plus van der Waals interaction 2.SPC nc Model: no Coulomb interaction 3.SPC nn Model: no (non-bonded) interaction Christine Peter Thermodynamic CycleSystem 1000 H 2 O molecules periodic boundary conditions T = 280K, 300K, 320K simulations = 100-600ps NVT NPT Change: 1 H 2 O  hydration all H 2 O  excessmore accurate SPC (liquid) SPC nc (liquid, no Coulomb) SPC nn (ideal gas) G, S, H = 0

7 Free Energy and Entropy of Water Reference: J.Chem.Phys. (2004) method 2144

8 Free Energy and Entropy of Water Reference: J. Chem. Phys. (2004) method 3 63 close

9 All 1000 H 2 O Molecules Changed TI

10 A Single H 2 O Molecule Changed  A via TI S via TI S uv via TI NVT NPT same pattern as for 1000 H 2 O changed erratic not converged same pattern as for 1000 H 2 O changed

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