Enhancing sampling of water rehydration on ligand binding: a comparison of techniques
Enhancing sampling of water rehydration on ligand binding: a comparison of techniques
Water often plays a key role in protein structure, molecular recognition, and mediating protein–ligand interactions. Thus, free energy calculations must adequately sample water motions, which often proves challenging in typical MD simulation time scales. Thus, the accuracy of methods relying on MD simulations ends up limited by slow water sampling. Particularly, as a ligand is removed or modified, bulk water may not have time to fill or rearrange in the binding site. In this work, we focus on several molecular dynamics (MD) simulation-based methods attempting to help rehydrate buried water sites: BLUES, using nonequilibrium candidate Monte Carlo (NCMC); grand, using grand canonical Monte Carlo (GCMC); and normal MD. We assess the accuracy and efficiency of these methods in rehydrating target water sites. We selected a range of systems with varying numbers of waters in the binding site, as well as those where water occupancy is coupled to the identity or binding mode of the ligand. We analyzed the rehydration of buried water sites in binding pockets using both clustering of trajectories and direct analysis of electron density maps. Our results suggest both BLUES and grand enhance water sampling relative to normal MD and grand is more robust than BLUES, but also that water sampling remains a major challenge for all of the methods tested. The lessons we learned for these methods and systems are discussed.
1359–1381
Ge, Yunhui
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Wych, David C.
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Samways, Marley, Luke
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Wall, Michael E.
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Essex, Jonathan W.
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Mobley, David L.
bcfb19ab-8b8f-47a4-8e4c-c353dba8b653
8 March 2022
Ge, Yunhui
d764d1fe-12bb-47e0-a705-5094b6654733
Wych, David C.
3e33681f-5051-4d23-869f-14910cc360a2
Samways, Marley, Luke
75cda5aa-31ef-4f62-9ea3-8655ea55d3fb
Wall, Michael E.
139244bf-612e-4bfd-a622-7e883e1624a4
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5
Mobley, David L.
bcfb19ab-8b8f-47a4-8e4c-c353dba8b653
Ge, Yunhui, Wych, David C., Samways, Marley, Luke, Wall, Michael E., Essex, Jonathan W. and Mobley, David L.
(2022)
Enhancing sampling of water rehydration on ligand binding: a comparison of techniques.
Journal of Chemical Theory and Computation, 18 (3), .
(doi:10.1021/acs.jctc.1c00590).
Abstract
Water often plays a key role in protein structure, molecular recognition, and mediating protein–ligand interactions. Thus, free energy calculations must adequately sample water motions, which often proves challenging in typical MD simulation time scales. Thus, the accuracy of methods relying on MD simulations ends up limited by slow water sampling. Particularly, as a ligand is removed or modified, bulk water may not have time to fill or rearrange in the binding site. In this work, we focus on several molecular dynamics (MD) simulation-based methods attempting to help rehydrate buried water sites: BLUES, using nonequilibrium candidate Monte Carlo (NCMC); grand, using grand canonical Monte Carlo (GCMC); and normal MD. We assess the accuracy and efficiency of these methods in rehydrating target water sites. We selected a range of systems with varying numbers of waters in the binding site, as well as those where water occupancy is coupled to the identity or binding mode of the ligand. We analyzed the rehydration of buried water sites in binding pockets using both clustering of trajectories and direct analysis of electron density maps. Our results suggest both BLUES and grand enhance water sampling relative to normal MD and grand is more robust than BLUES, but also that water sampling remains a major challenge for all of the methods tested. The lessons we learned for these methods and systems are discussed.
Text
water_benchmark
- Accepted Manuscript
More information
Accepted/In Press date: 11 February 2022
e-pub ahead of print date: 11 February 2022
Published date: 8 March 2022
Identifiers
Local EPrints ID: 456313
URI: http://eprints.soton.ac.uk/id/eprint/456313
ISSN: 1549-9618
PURE UUID: f394b9a4-7fa8-4e91-9057-38c5135a9350
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Date deposited: 27 Apr 2022 02:18
Last modified: 17 Mar 2024 07:13
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Contributors
Author:
Yunhui Ge
Author:
David C. Wych
Author:
Marley, Luke Samways
Author:
Michael E. Wall
Author:
David L. Mobley
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