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Enhanced grand canonical sampling of occluded water sites using nonequilibrium candidate Monte Carlo

Enhanced grand canonical sampling of occluded water sites using nonequilibrium candidate Monte Carlo
Enhanced grand canonical sampling of occluded water sites using nonequilibrium candidate Monte Carlo

Water molecules play a key role in many biomolecular systems, particularly when bound at protein-ligand interfaces. However, molecular simulation studies on such systems are hampered by the relatively long time scales over which water exchange between a protein and solvent takes place. Grand canonical Monte Carlo (GCMC) is a simulation technique that avoids this issue by attempting the insertion and deletion of water molecules within a given structure. The approach is constrained by low acceptance probabilities for insertions in congested systems, however. To address this issue, here, we combine GCMC with nonequilibium candidate Monte Carlo (NCMC) to yield a method that we refer to as grand canonical nonequilibrium candidate Monte Carlo (GCNCMC), in which the water insertions and deletions are carried out in a gradual, nonequilibrium fashion. We validate this new approach by comparing GCNCMC and GCMC simulations of bulk water and three protein binding sites. We find that not only is the efficiency of the water sampling improved by GCNCMC but that it also results in increased sampling of ligand conformations in a protein binding site, revealing new water-mediated ligand-binding geometries that are not observed using alternative enhanced sampling techniques.

1549-9618
1050-1062
Melling, Oliver J.
ba6757bd-a045-4a1d-b554-0388d188d069
Samways, Marley L.
75cda5aa-31ef-4f62-9ea3-8655ea55d3fb
Ge, Yunhui
d764d1fe-12bb-47e0-a705-5094b6654733
Mobley, David L.
bcfb19ab-8b8f-47a4-8e4c-c353dba8b653
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5
Melling, Oliver J.
ba6757bd-a045-4a1d-b554-0388d188d069
Samways, Marley L.
75cda5aa-31ef-4f62-9ea3-8655ea55d3fb
Ge, Yunhui
d764d1fe-12bb-47e0-a705-5094b6654733
Mobley, David L.
bcfb19ab-8b8f-47a4-8e4c-c353dba8b653
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5

Melling, Oliver J., Samways, Marley L., Ge, Yunhui, Mobley, David L. and Essex, Jonathan W. (2023) Enhanced grand canonical sampling of occluded water sites using nonequilibrium candidate Monte Carlo. Journal of Chemical Theory and Computation, 19 (3), 1050-1062. (doi:10.1021/acs.jctc.2c00823).

Record type: Article

Abstract

Water molecules play a key role in many biomolecular systems, particularly when bound at protein-ligand interfaces. However, molecular simulation studies on such systems are hampered by the relatively long time scales over which water exchange between a protein and solvent takes place. Grand canonical Monte Carlo (GCMC) is a simulation technique that avoids this issue by attempting the insertion and deletion of water molecules within a given structure. The approach is constrained by low acceptance probabilities for insertions in congested systems, however. To address this issue, here, we combine GCMC with nonequilibium candidate Monte Carlo (NCMC) to yield a method that we refer to as grand canonical nonequilibrium candidate Monte Carlo (GCNCMC), in which the water insertions and deletions are carried out in a gradual, nonequilibrium fashion. We validate this new approach by comparing GCNCMC and GCMC simulations of bulk water and three protein binding sites. We find that not only is the efficiency of the water sampling improved by GCNCMC but that it also results in increased sampling of ligand conformations in a protein binding site, revealing new water-mediated ligand-binding geometries that are not observed using alternative enhanced sampling techniques.

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Accepted/In Press date: 23 January 2023
e-pub ahead of print date: 24 January 2023
Additional Information: Funding: The authors thank the EPSRC, NIH, CCP5, and the University of Southampton for funding. M.L.S. is supported by the EPSRC�funded CDT in Next Generation Computational Modelling, under Grant EP/L015382/1. Y.G.. and D.L.M. are supported by NIH GM108889s.
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Identifiers

Local EPrints ID: 475560
URI: http://eprints.soton.ac.uk/id/eprint/475560
DOI: doi:10.1021/acs.jctc.2c00823
ISSN: 1549-9618
PURE UUID: bca5816b-fc2c-4260-8332-e3c0d079c94d
ORCID for Marley L. Samways: ORCID iD orcid.org/0000-0001-9431-8789
ORCID for Jonathan W. Essex: ORCID iD orcid.org/0000-0003-2639-2746

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Date deposited: 21 Mar 2023 17:45
Last modified: 18 Mar 2024 02:39

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Contributors

Author: Oliver J. Melling
Author: Marley L. Samways ORCID iD
Author: Yunhui Ge
Author: David L. Mobley
Author: Jonathan W. Essex ORCID iD

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