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Atomistic level characterisation of ssDNA translocation through the E. coli proteins CsgG and CsgF for nanopore sequencing

Atomistic level characterisation of ssDNA translocation through the E. coli proteins CsgG and CsgF for nanopore sequencing
Atomistic level characterisation of ssDNA translocation through the E. coli proteins CsgG and CsgF for nanopore sequencing
Two proteins of the Escherichia coli membrane protein complex, CsgG and CsgF, are studied as proteinaceous nanopores for DNA sequencing. It is highly desirable to control the DNA as it moves through the pores, this requires characterisation of DNA translocation and subsequent optimization of the pores. In order to inform protein engineering to improve the pores, we have conducted a series of molecular dynamics simulations to characterise the mechanical strength and conformational dynamics of CsgG and the CsgG-CsgF complex and how these impact ssDNA, water and ion movement. We find that the barrel of CsgG is more susceptible to damage from external electric fields compared to the protein vestibule. Furthermore, the presence of CsgF within the CsgG-CsgF complex enables the complex to withstand higher electric fields. We find that the eyelet loops of CsgG play a key role in both slowing the translocation rate of DNA and modulating the conductance of the pore. CsgF also impacts the DNA translocation rate, but to a lesser degree than CsgG.
2001-0370
6417-6430
Rattu, Punam
70569439-229e-4c6e-b313-f908d259777d
Glencross, Flo
4da401b5-e169-46dd-80ed-cf9fa16b95ba
Mader, Sophie L.
ccec2852-edba-41e9-aa86-99fdb858df97
Skylaris, Chris-Kriton
8f593d13-3ace-4558-ba08-04e48211af61
Matthews, Stephen J.
ca0ec2f9-69b0-4266-b53a-937941e64560
Rouse, Sarah L.
67f40d9d-a7ba-49ee-a6a3-2e325ff3ad10
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394
Rattu, Punam
70569439-229e-4c6e-b313-f908d259777d
Glencross, Flo
4da401b5-e169-46dd-80ed-cf9fa16b95ba
Mader, Sophie L.
ccec2852-edba-41e9-aa86-99fdb858df97
Skylaris, Chris-Kriton
8f593d13-3ace-4558-ba08-04e48211af61
Matthews, Stephen J.
ca0ec2f9-69b0-4266-b53a-937941e64560
Rouse, Sarah L.
67f40d9d-a7ba-49ee-a6a3-2e325ff3ad10
Khalid, Syma
90fbd954-7248-4f47-9525-4d6af9636394

Rattu, Punam, Glencross, Flo, Mader, Sophie L., Skylaris, Chris-Kriton, Matthews, Stephen J., Rouse, Sarah L. and Khalid, Syma (2021) Atomistic level characterisation of ssDNA translocation through the E. coli proteins CsgG and CsgF for nanopore sequencing. Computational and Structural Biotechnology Journal, 19, 6417-6430. (doi:10.1016/j.csbj.2021.11.014).

Record type: Article

Abstract

Two proteins of the Escherichia coli membrane protein complex, CsgG and CsgF, are studied as proteinaceous nanopores for DNA sequencing. It is highly desirable to control the DNA as it moves through the pores, this requires characterisation of DNA translocation and subsequent optimization of the pores. In order to inform protein engineering to improve the pores, we have conducted a series of molecular dynamics simulations to characterise the mechanical strength and conformational dynamics of CsgG and the CsgG-CsgF complex and how these impact ssDNA, water and ion movement. We find that the barrel of CsgG is more susceptible to damage from external electric fields compared to the protein vestibule. Furthermore, the presence of CsgF within the CsgG-CsgF complex enables the complex to withstand higher electric fields. We find that the eyelet loops of CsgG play a key role in both slowing the translocation rate of DNA and modulating the conductance of the pore. CsgF also impacts the DNA translocation rate, but to a lesser degree than CsgG.

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More information

Accepted/In Press date: 12 November 2021
e-pub ahead of print date: 18 November 2021
Additional Information: This work was supported by the Medical Research Council grant number MR/T017961/1 to SL. Access to ARCHER and ARCHER2 was provided by HECBiosim through EPSRC grant EP/R029407/1.

Identifiers

Local EPrints ID: 454525
URI: http://eprints.soton.ac.uk/id/eprint/454525
ISSN: 2001-0370
PURE UUID: 281e0e42-84b6-4997-90b4-b088a991f084
ORCID for Chris-Kriton Skylaris: ORCID iD orcid.org/0000-0003-0258-3433
ORCID for Syma Khalid: ORCID iD orcid.org/0000-0002-3694-5044

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Date deposited: 15 Feb 2022 17:37
Last modified: 17 Mar 2024 03:11

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Contributors

Author: Punam Rattu
Author: Flo Glencross
Author: Sophie L. Mader
Author: Stephen J. Matthews
Author: Sarah L. Rouse
Author: Syma Khalid ORCID iD

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