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Enhancing Water Sampling in Free Energy Calculations with Grand Canonical Monte Carlo

Gregory A. Ross, Ellery Russell, Yuqing Deng, Chao Lü, Edward Harder, Robert Abel, Lingle Wang

2020Journal of Chemical Theory and Computation107 citationsDOI

Abstract

The prediction of protein-ligand binding affinities using free energy perturbation (FEP) is becoming increasingly routine in structure-based drug discovery. Most FEP packages use molecular dynamics (MD) to sample the configurations of proteins and ligands, as MD is well-suited to capturing coupled motion. However, MD can be prohibitively inefficient at sampling water molecules that are buried within binding sites, which has severely limited the domain of applicability of FEP and its prospective usage in drug discovery. In this paper, we present an advancement of FEP that augments MD with grand canonical Monte Carlo (GCMC), an enhanced sampling method, to overcome the problem of sampling water. We accomplished this without degrading computational performance. On both old and newly assembled data sets of protein-ligand complexes, we show that the use of GCMC in FEP is essential for accurate and robust predictions for ligand perturbations that disrupt buried water.

Topics & Concepts

Free energy perturbationMolecular dynamicsMonte Carlo methodSampling (signal processing)Umbrella samplingDrug discoveryStatistical physicsComputer scienceThermodynamic integrationGrand canonical ensembleBinding affinitiesWater modelComputational chemistryChemistryPhysicsMathematicsStatisticsFilter (signal processing)ReceptorComputer visionBiochemistryProtein Structure and DynamicsMass Spectrometry Techniques and ApplicationsRNA and protein synthesis mechanisms
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