Electroporation of the E. coli and S. Aureus membranes: molecular dynamics simulations of complex bacterial membranes
Electroporation of the E. coli and S. Aureus membranes: molecular dynamics simulations of complex bacterial membranes
Bacterial membranes are complex organelles composed of a variety of lipid types. The differences in their composition are a key factor in determining their relative permeabilities. The success of antibacterial agents depends upon their interaction with bacterial membranes, yet little is known about the molecular-level interactions within membranes of different bacterial species. To address this, we have performed molecular dynamics simulations of two bacterial membranes: the outer membrane of E. coli and the cell membrane of S. aureus . We have retained the chemical complexity of the membranes by considering the details of their lipidic components. We identify the extended network of lipid-lipid interactions that stabilize the membranes. Our simulations of electroporation show that the S. aureus cell membrane is less resistant to poration than the E. coli outer membrane. The mechanisms of poration for the two membranes have subtle differences; for the E. coli outer membrane, relative differences in mobilities of the lipids of both leaflets are key in the process of poration
13381-13388
Piggot, Thomas J.
75829b71-d73b-43d1-b24f-3e70c2c4d0c8
Holdbrook, Daniel A.
d114c018-fb42-4a49-9b50-f7739feb75f5
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
November 2011
Piggot, Thomas J.
75829b71-d73b-43d1-b24f-3e70c2c4d0c8
Holdbrook, Daniel A.
d114c018-fb42-4a49-9b50-f7739feb75f5
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
Piggot, Thomas J., Holdbrook, Daniel A. and Khalid, Syma
(2011)
Electroporation of the E. coli and S. Aureus membranes: molecular dynamics simulations of complex bacterial membranes.
The Journal of Physical Chemistry B, 115 (45), .
(doi:10.1021/jp207013v).
(PMID:21970408)
Abstract
Bacterial membranes are complex organelles composed of a variety of lipid types. The differences in their composition are a key factor in determining their relative permeabilities. The success of antibacterial agents depends upon their interaction with bacterial membranes, yet little is known about the molecular-level interactions within membranes of different bacterial species. To address this, we have performed molecular dynamics simulations of two bacterial membranes: the outer membrane of E. coli and the cell membrane of S. aureus . We have retained the chemical complexity of the membranes by considering the details of their lipidic components. We identify the extended network of lipid-lipid interactions that stabilize the membranes. Our simulations of electroporation show that the S. aureus cell membrane is less resistant to poration than the E. coli outer membrane. The mechanisms of poration for the two membranes have subtle differences; for the E. coli outer membrane, relative differences in mobilities of the lipids of both leaflets are key in the process of poration
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Published date: November 2011
Organisations:
Computational Systems Chemistry
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Local EPrints ID: 352873
URI: http://eprints.soton.ac.uk/id/eprint/352873
ISSN: 1520-6106
PURE UUID: b8524471-d7df-4098-b3b3-2b60411675ed
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Date deposited: 20 May 2013 10:07
Last modified: 15 Mar 2024 03:29
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Author:
Thomas J. Piggot
Author:
Daniel A. Holdbrook
Author:
Syma Khalid
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