The application of three approximate free energy calculations methods to structure based ligand design: Trypsin and its complex with inhibitors |
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Authors: | Randall J. Radmer Peter A. Kollman |
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Affiliation: | (1) Department of Pharmaceutical Chemistry, University of California, San Francisco, CA, 94143-0446, U.S.A |
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Abstract: | Three approximate free energy calculation methods are examined and applied to an example ligand design problem. The first of the methods uses a single simulation to estimate the relative binding free energies for related ligands that are not simulated. The second method is similar, except that it uses only first derivatives of free energy with respect to atomic parameters (most often charge, van der Waals equilibrium distance, and van der Waals well depth) to calculate free energy differences. The last method PROFEC (Pictorial Representation of Free Energy Components), generates contour maps that show how binding free energy changes when additional particles are added near the ligand. These three methods are applied to a benzamidine/trypsin complex. They each reproduce the general trends in the binding free energies, indicating that they might be useful for suggesting how ligands could be modified to improve binding and, consequently, useful in structure-based drug design. |
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Keywords: | free energy calculations ligand design molecular dynamics Pictorial Representation of Free Energy Changes (PROFEC) |
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