Single-stranded DNA within nanopores: conformational dynamics and implications for sequencing; a molecular dynamics simulation study
Single-stranded DNA within nanopores: conformational dynamics and implications for sequencing; a molecular dynamics simulation study
Engineered protein nanopores, such as those based on ?-hemolysin from Staphylococcus aureus have shown great promise as components of next-generation DNA sequencing devices. However, before such protein nanopores can be used to their full potential, the conformational dynamics and translocation pathway of the DNA within them must be characterized at the individual molecule level. Here, we employ atomistic molecular dynamics simulations of single-stranded DNA movement through a model ?-hemolysin pore under an applied electric field. The simulations enable characterization of the conformations adopted by single-stranded DNA, and allow exploration of how the conformations may impact on translocation within the wild-type model pore and a number of mutants. Our results show that specific interactions between the protein nanopore and the DNA can have a significant impact on the DNA conformation often leading to localized coiling, which in turn, can alter the order in which the DNA bases exit the nanopore. Thus, our simulations show that strategies to control the conformation of DNA within a protein nanopore would be a distinct advantage for the purposes of DNA sequencing.
1028-1036
Guy, Andrew T.
611827bb-86cc-4ff6-a33a-8daefe2e47c3
Piggot, Thomas J.
75829b71-d73b-43d1-b24f-3e70c2c4d0c8
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
5 September 2012
Guy, Andrew T.
611827bb-86cc-4ff6-a33a-8daefe2e47c3
Piggot, Thomas J.
75829b71-d73b-43d1-b24f-3e70c2c4d0c8
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
Guy, Andrew T., Piggot, Thomas J. and Khalid, Syma
(2012)
Single-stranded DNA within nanopores: conformational dynamics and implications for sequencing; a molecular dynamics simulation study.
Biophysical Journal, 103 (5), .
(doi:10.1016/j.bpj.2012.08.012).
(PMID:23009852)
Abstract
Engineered protein nanopores, such as those based on ?-hemolysin from Staphylococcus aureus have shown great promise as components of next-generation DNA sequencing devices. However, before such protein nanopores can be used to their full potential, the conformational dynamics and translocation pathway of the DNA within them must be characterized at the individual molecule level. Here, we employ atomistic molecular dynamics simulations of single-stranded DNA movement through a model ?-hemolysin pore under an applied electric field. The simulations enable characterization of the conformations adopted by single-stranded DNA, and allow exploration of how the conformations may impact on translocation within the wild-type model pore and a number of mutants. Our results show that specific interactions between the protein nanopore and the DNA can have a significant impact on the DNA conformation often leading to localized coiling, which in turn, can alter the order in which the DNA bases exit the nanopore. Thus, our simulations show that strategies to control the conformation of DNA within a protein nanopore would be a distinct advantage for the purposes of DNA sequencing.
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Published date: 5 September 2012
Organisations:
Computational Systems Chemistry
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Local EPrints ID: 352906
URI: http://eprints.soton.ac.uk/id/eprint/352906
ISSN: 0006-3495
PURE UUID: c8ce2b11-fd66-44bb-a299-ea1bac14551b
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Date deposited: 22 May 2013 15:10
Last modified: 15 Mar 2024 03:29
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Author:
Andrew T. Guy
Author:
Thomas J. Piggot
Author:
Syma Khalid
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