Peptide-based approach to inhibition of the multidrug resistance efflux pump AcrB
Peptide-based approach to inhibition of the multidrug resistance efflux pump AcrB
Clinically relevant multidrug-resistant bacteria often arise due to overproduction of membrane-embedded efflux proteins that are capable of pumping antibiotics out of the bacterial cell before the drugs can exert their intended toxic effect. The Escherichia coli membrane protein AcrB is the archetypal protein utilized for bacterial efflux study because it can extrude a diverse range of antibiotic substrates and has close homologues in many Gram-negative pathogens. Three AcrB subunits, each of which contains 12 transmembrane (TM) helices, are known to trimerize to form the minimal functional unit, stabilized noncovalently by helix–helix interactions between TM1 and TM8. To inhibit the efflux activity of AcrB, we have rationally designed synthetic peptides aimed at destabilizing the AcrB trimerization interface by outcompeting the subunit interaction sites within the membrane. Here we report that peptides mimicking TM1 or TM8, with flanking N-terminal peptoid tags, and C-terminal lysine tags that aid in directing the peptides to their membrane-embedded target, decrease the AcrB-mediated efflux of the fluorescent substrate Nile red and potentiate the effect of the antimicrobials chloramphenicol and ethidium bromide. To further characterize the motif encompassing the interaction between TM1 and TM8, we used Förster resonance energy transfer to demonstrate dimerization. Using the TM1 and TM8 peptides, in conjunction with several selected mutant peptides, we highlight residues that may increase the potency and specificity of the peptide drug candidates. In targeting membrane-embedded protein–protein interactions, this work represents a novel approach to AcrB inhibition and, more broadly, a potential route to a new category of efflux pump inhibitors.
3973–3981
Jesin, Joshua A.
d77971e7-eaf1-418c-a743-ed1e86153992
Stone, Tracy A.
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Mitchell, Chloe J.
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Reading, Eamonn
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Deber, Charles M.
b1ac288b-2e31-40df-974c-151879e41ec6
20 October 2020
Jesin, Joshua A.
d77971e7-eaf1-418c-a743-ed1e86153992
Stone, Tracy A.
cc26c7e4-676a-4dac-83ad-a7047bee62f3
Mitchell, Chloe J.
7ec1b2ca-3374-47e4-bea6-1e10a4d43583
Reading, Eamonn
62fed933-f867-4c72-89e7-83aea573a836
Deber, Charles M.
b1ac288b-2e31-40df-974c-151879e41ec6
Jesin, Joshua A., Stone, Tracy A., Mitchell, Chloe J., Reading, Eamonn and Deber, Charles M.
(2020)
Peptide-based approach to inhibition of the multidrug resistance efflux pump AcrB.
Biochemistry, 59 (41), .
(doi:10.1021/acs.biochem.0c00417).
Abstract
Clinically relevant multidrug-resistant bacteria often arise due to overproduction of membrane-embedded efflux proteins that are capable of pumping antibiotics out of the bacterial cell before the drugs can exert their intended toxic effect. The Escherichia coli membrane protein AcrB is the archetypal protein utilized for bacterial efflux study because it can extrude a diverse range of antibiotic substrates and has close homologues in many Gram-negative pathogens. Three AcrB subunits, each of which contains 12 transmembrane (TM) helices, are known to trimerize to form the minimal functional unit, stabilized noncovalently by helix–helix interactions between TM1 and TM8. To inhibit the efflux activity of AcrB, we have rationally designed synthetic peptides aimed at destabilizing the AcrB trimerization interface by outcompeting the subunit interaction sites within the membrane. Here we report that peptides mimicking TM1 or TM8, with flanking N-terminal peptoid tags, and C-terminal lysine tags that aid in directing the peptides to their membrane-embedded target, decrease the AcrB-mediated efflux of the fluorescent substrate Nile red and potentiate the effect of the antimicrobials chloramphenicol and ethidium bromide. To further characterize the motif encompassing the interaction between TM1 and TM8, we used Förster resonance energy transfer to demonstrate dimerization. Using the TM1 and TM8 peptides, in conjunction with several selected mutant peptides, we highlight residues that may increase the potency and specificity of the peptide drug candidates. In targeting membrane-embedded protein–protein interactions, this work represents a novel approach to AcrB inhibition and, more broadly, a potential route to a new category of efflux pump inhibitors.
Text
Jesin et al. bi-2020-00417f.R2_pre-print
- Accepted Manuscript
More information
e-pub ahead of print date: 7 October 2020
Published date: 20 October 2020
Identifiers
Local EPrints ID: 478885
URI: http://eprints.soton.ac.uk/id/eprint/478885
ISSN: 0006-2960
PURE UUID: e0a4dd3c-592a-49b6-9250-1cc1acfe8b8e
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Date deposited: 12 Jul 2023 16:38
Last modified: 17 Mar 2024 04:19
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Contributors
Author:
Joshua A. Jesin
Author:
Tracy A. Stone
Author:
Chloe J. Mitchell
Author:
Eamonn Reading
Author:
Charles M. Deber
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