Water sites, networks, and free energies with grand canonical Monte Carlo
Water sites, networks, and free energies with grand canonical Monte Carlo
Water molecules play integral roles in the formation of many protein–ligand complexes, and recent computational efforts have been focused on predicting the thermodynamic properties of individual waters and how they may be exploited in rational drug design. However, when water molecules form highly coupled hydrogen-bonding networks, there is, as yet, no method that can rigorously calculate the free energy to bind the entire network or assess the degree of cooperativity between waters. In this work, we report theoretical and methodological developments to the grand canonical Monte Carlo simulation technique. Central to our results is a rigorous equation that can be used to calculate efficiently the binding free energies of water networks of arbitrary size and complexity. Using a single set of simulations, our methods can locate waters, estimate their binding affinities, capture the cooperativity of the water network, and evaluate the hydration free energy of entire protein binding sites. Our techniques have been applied to multiple test systems and compare favorably to thermodynamic integration simulations and experimental data. The implications of these methods in drug design are discussed.
14930-14943
Ross, Gregory A.
113a6add-41b2-4ccc-9ab9-73fb52d728c5
Bodnarchuk, Michael S.
cb7c3390-a1e3-4e13-916c-200706d11f34
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5
2 December 2015
Ross, Gregory A.
113a6add-41b2-4ccc-9ab9-73fb52d728c5
Bodnarchuk, Michael S.
cb7c3390-a1e3-4e13-916c-200706d11f34
Essex, Jonathan W.
1f409cfe-6ba4-42e2-a0ab-a931826314b5
Ross, Gregory A., Bodnarchuk, Michael S. and Essex, Jonathan W.
(2015)
Water sites, networks, and free energies with grand canonical Monte Carlo.
Journal of the American Chemical Society, 137 (47), .
(doi:10.1021/jacs.5b07940).
Abstract
Water molecules play integral roles in the formation of many protein–ligand complexes, and recent computational efforts have been focused on predicting the thermodynamic properties of individual waters and how they may be exploited in rational drug design. However, when water molecules form highly coupled hydrogen-bonding networks, there is, as yet, no method that can rigorously calculate the free energy to bind the entire network or assess the degree of cooperativity between waters. In this work, we report theoretical and methodological developments to the grand canonical Monte Carlo simulation technique. Central to our results is a rigorous equation that can be used to calculate efficiently the binding free energies of water networks of arbitrary size and complexity. Using a single set of simulations, our methods can locate waters, estimate their binding affinities, capture the cooperativity of the water network, and evaluate the hydration free energy of entire protein binding sites. Our techniques have been applied to multiple test systems and compare favorably to thermodynamic integration simulations and experimental data. The implications of these methods in drug design are discussed.
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e-pub ahead of print date: 28 October 2015
Published date: 2 December 2015
Organisations:
Computational Systems Chemistry
Identifiers
Local EPrints ID: 390560
URI: http://eprints.soton.ac.uk/id/eprint/390560
ISSN: 0002-7863
PURE UUID: d7cd88a4-b67e-4b4f-a50c-2ceb0905c2d4
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Date deposited: 04 Apr 2016 14:21
Last modified: 15 Mar 2024 05:27
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Author:
Gregory A. Ross
Author:
Michael S. Bodnarchuk
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