Polarized protein-specific charges from atoms-in-molecule electron density partitioning
Polarized protein-specific charges from atoms-in-molecule electron density partitioning
Atomic partial charges for use in traditional force fields for biomolecular simulation are often fit to the electrostatic potentials of small molecules and, hence, neglect large-scale electronic polarization. On the other hand, recent advances in atoms-in-molecule charge derivation schemes show promise for use in flexible force fields but are limited in size by the underlying quantum mechanical calculation of the electron density. Here, we implement the density derived electrostatic and chemical charges method in the linear-scaling density functional theory code ONETEP. Our implementation allows the straightforward derivation of partial atomic charges for systems comprising thousands of atoms, including entire proteins. We demonstrate that the derived charges are chemically intuitive, reproduce ab initio electrostatic potentials of proteins and are transferable between closely related systems. Simulated NMR data derived from molecular dynamics of three proteins using force fields based on the ONETEP charges are in good agreement with experiment.
2981-2991
Lee, Louis P.
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Cole, Daniel J.
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Skylaris, Chris-Kriton
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Jorgensen, William L.
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Payne, Mike C.
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9 July 2013
Lee, Louis P.
7e11b32f-b117-4ad0-a6f1-18109b47b89f
Cole, Daniel J.
cb208a53-13ef-4871-b59b-6373abaadc39
Skylaris, Chris-Kriton
8f593d13-3ace-4558-ba08-04e48211af61
Jorgensen, William L.
ff29f903-0a44-485b-8f36-6350cf3291f0
Payne, Mike C.
abb730ea-f683-4bec-a7e0-766f0a180a05
Lee, Louis P., Cole, Daniel J., Skylaris, Chris-Kriton, Jorgensen, William L. and Payne, Mike C.
(2013)
Polarized protein-specific charges from atoms-in-molecule electron density partitioning.
Journal of Chemical Theory and Computation, 9 (7), .
(doi:10.1021/ct400279d).
(PMID:23894231)
Abstract
Atomic partial charges for use in traditional force fields for biomolecular simulation are often fit to the electrostatic potentials of small molecules and, hence, neglect large-scale electronic polarization. On the other hand, recent advances in atoms-in-molecule charge derivation schemes show promise for use in flexible force fields but are limited in size by the underlying quantum mechanical calculation of the electron density. Here, we implement the density derived electrostatic and chemical charges method in the linear-scaling density functional theory code ONETEP. Our implementation allows the straightforward derivation of partial atomic charges for systems comprising thousands of atoms, including entire proteins. We demonstrate that the derived charges are chemically intuitive, reproduce ab initio electrostatic potentials of proteins and are transferable between closely related systems. Simulated NMR data derived from molecular dynamics of three proteins using force fields based on the ONETEP charges are in good agreement with experiment.
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e-pub ahead of print date: 11 June 2013
Published date: 9 July 2013
Organisations:
Computational Systems Chemistry
Identifiers
Local EPrints ID: 356356
URI: http://eprints.soton.ac.uk/id/eprint/356356
ISSN: 1549-9618
PURE UUID: cac404b7-50b5-4dd8-bc4f-aaeaed3faf41
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Date deposited: 25 Sep 2013 10:07
Last modified: 15 Mar 2024 03:26
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Author:
Louis P. Lee
Author:
Daniel J. Cole
Author:
William L. Jorgensen
Author:
Mike C. Payne
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