HIV drugs inhibit transfer of plasmids carrying extended-spectrum β-lactamase and carbapenemase genes
HIV drugs inhibit transfer of plasmids carrying extended-spectrum β-lactamase and carbapenemase genes
Antimicrobial-resistant (AMR) infections pose a serious risk to human and animal health. A major factor contributing to this global crisis is the sharing of resistance genes between different bacteria via plasmids. The WHO lists Enterobacteriaceae, such as Escherichia coli and Klebsiella pneumoniae, producing extended-spectrum β-lactamases (ESBL) and carbapenemases as "critical" priorities for new drug development. These resistance genes are most often shared via plasmid transfer. However, finding methods to prevent resistance gene sharing has been hampered by the lack of screening systems for medium-/high-throughput approaches. Here, we have used an ESBL-producing plasmid, pCT, and a carbapenemase-producing plasmid, pKpQIL, in two different Gram-negative bacteria, E. coli and K. pneumoniae Using these critical resistance-pathogen combinations, we developed an assay using fluorescent proteins, flow cytometry, and confocal microscopy to assess plasmid transmission inhibition within bacterial populations in a medium-throughput manner. Three compounds with some reports of antiplasmid properties were tested; chlorpromazine reduced transmission of both plasmids and linoleic acid reduced transmission of pCT. We screened the Prestwick library of over 1,200 FDA-approved drugs/compounds. From this, we found two nucleoside analogue drugs used to treat HIV, abacavir and azidothymidine (AZT), which reduced plasmid transmission (AZT, e.g., at 0.25 μg/ml reduced pCT transmission in E. coli by 83.3% and pKpQIL transmission in K. pneumoniae by 80.8% compared to untreated controls). Plasmid transmission was reduced by concentrations of the drugs which are below peak serum concentrations and are achievable in the gastrointestinal tract. These drugs could be used to decolonize humans, animals, or the environment from AMR plasmids.IMPORTANCE More and more bacterial infections are becoming resistant to antibiotics. This has made treatment of many infections very difficult. One of the reasons this is such a large problem is that bacteria are able to share their genetic material with other bacteria, and these shared genes often include resistance to a variety of antibiotics, including some of our drugs of last resort. We are addressing this problem by using a fluorescence-based system to search for drugs that will stop bacteria from sharing resistance genes. We uncovered a new role for two drugs used to treat HIV and show that they are able to prevent the sharing of two different types of resistance genes in two unique bacterial strains. This work lays the foundation for future work to reduce the prevalence of resistant infections.
Buckner, Michelle M.C.
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Ciusa, M. Laura
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Meek, Richard W.
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Moorey, Alice R.
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McCallum, Gregory E.
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Prentice, Emma L.
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Reid, Jeremy P.
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Alderwick, Luke J.
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Di Maio, Alessandro
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Piddock, Laura J.V.
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25 February 2020
Buckner, Michelle M.C.
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Ciusa, M. Laura
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Meek, Richard W.
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Moorey, Alice R.
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McCallum, Gregory E.
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Prentice, Emma L.
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Reid, Jeremy P.
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Alderwick, Luke J.
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Di Maio, Alessandro
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Piddock, Laura J.V.
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Buckner, Michelle M.C., Ciusa, M. Laura, Meek, Richard W., Moorey, Alice R., McCallum, Gregory E., Prentice, Emma L., Reid, Jeremy P., Alderwick, Luke J., Di Maio, Alessandro and Piddock, Laura J.V.
(2020)
HIV drugs inhibit transfer of plasmids carrying extended-spectrum β-lactamase and carbapenemase genes.
mBio, 11 (1).
(doi:10.1128/mbio.03355-19).
Abstract
Antimicrobial-resistant (AMR) infections pose a serious risk to human and animal health. A major factor contributing to this global crisis is the sharing of resistance genes between different bacteria via plasmids. The WHO lists Enterobacteriaceae, such as Escherichia coli and Klebsiella pneumoniae, producing extended-spectrum β-lactamases (ESBL) and carbapenemases as "critical" priorities for new drug development. These resistance genes are most often shared via plasmid transfer. However, finding methods to prevent resistance gene sharing has been hampered by the lack of screening systems for medium-/high-throughput approaches. Here, we have used an ESBL-producing plasmid, pCT, and a carbapenemase-producing plasmid, pKpQIL, in two different Gram-negative bacteria, E. coli and K. pneumoniae Using these critical resistance-pathogen combinations, we developed an assay using fluorescent proteins, flow cytometry, and confocal microscopy to assess plasmid transmission inhibition within bacterial populations in a medium-throughput manner. Three compounds with some reports of antiplasmid properties were tested; chlorpromazine reduced transmission of both plasmids and linoleic acid reduced transmission of pCT. We screened the Prestwick library of over 1,200 FDA-approved drugs/compounds. From this, we found two nucleoside analogue drugs used to treat HIV, abacavir and azidothymidine (AZT), which reduced plasmid transmission (AZT, e.g., at 0.25 μg/ml reduced pCT transmission in E. coli by 83.3% and pKpQIL transmission in K. pneumoniae by 80.8% compared to untreated controls). Plasmid transmission was reduced by concentrations of the drugs which are below peak serum concentrations and are achievable in the gastrointestinal tract. These drugs could be used to decolonize humans, animals, or the environment from AMR plasmids.IMPORTANCE More and more bacterial infections are becoming resistant to antibiotics. This has made treatment of many infections very difficult. One of the reasons this is such a large problem is that bacteria are able to share their genetic material with other bacteria, and these shared genes often include resistance to a variety of antibiotics, including some of our drugs of last resort. We are addressing this problem by using a fluorescence-based system to search for drugs that will stop bacteria from sharing resistance genes. We uncovered a new role for two drugs used to treat HIV and show that they are able to prevent the sharing of two different types of resistance genes in two unique bacterial strains. This work lays the foundation for future work to reduce the prevalence of resistant infections.
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mBio.03355-19
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Accepted/In Press date: 10 February 2020
Published date: 25 February 2020
Identifiers
Local EPrints ID: 476622
URI: http://eprints.soton.ac.uk/id/eprint/476622
ISSN: 2150-7511
PURE UUID: 7b63f6b1-8827-4bd0-80f0-e2cf5b2ad94f
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Date deposited: 10 May 2023 16:36
Last modified: 17 Mar 2024 04:19
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Contributors
Author:
Michelle M.C. Buckner
Author:
M. Laura Ciusa
Author:
Richard W. Meek
Author:
Alice R. Moorey
Author:
Gregory E. McCallum
Author:
Emma L. Prentice
Author:
Jeremy P. Reid
Author:
Luke J. Alderwick
Author:
Alessandro Di Maio
Author:
Laura J.V. Piddock
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