Phage resistance in Klebsiella pneumoniae and bidirectional effects impacting antibiotic susceptibility

Bacteriophage (phage) therapy is a promising anti-infective option to combat antimicrobial resistance. However, the clinical utilization of phage therapy has been severely compromised by the potential emergence of phage resistance. Although certain phage resistance mechanisms can restore bacterial s...

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Veröffentlicht in:	Clinical microbiology and infection 2024-06, Vol.30 (6), p.787-794
Hauptverfasser:	Nang, Sue C., Lu, Jing, Yu, Heidi H., Wickremasinghe, Hasini, Azad, Mohammad A.K., Han, Meiling, Zhao, Jinxin, Rao, Gauri, Bergen, Phillip J., Velkov, Tony, Sherry, Norelle, McCarthy, David T., Aslam, Saima, Schooley, Robert T., Howden, Benjamin P., Barr, Jeremy J., Zhu, Yan, Li, Jian
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Sprache:	eng
Schlagworte:	Anti-Bacterial Agents - pharmacology Antibiotic Antimicrobial resistance Bacteriophage therapy Bacteriophages - genetics DNA Transposable Elements Drug Resistance, Bacterial Humans Klebsiella pneumoniae Klebsiella pneumoniae - drug effects Klebsiella pneumoniae - genetics Klebsiella pneumoniae - virology Microbial Sensitivity Tests Mutation Phage resistance Phage steering Phage Therapy
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creator	Nang, Sue C. Lu, Jing Yu, Heidi H. Wickremasinghe, Hasini Azad, Mohammad A.K. Han, Meiling Zhao, Jinxin Rao, Gauri Bergen, Phillip J. Velkov, Tony Sherry, Norelle McCarthy, David T. Aslam, Saima Schooley, Robert T. Howden, Benjamin P. Barr, Jeremy J. Zhu, Yan Li, Jian
description	Bacteriophage (phage) therapy is a promising anti-infective option to combat antimicrobial resistance. However, the clinical utilization of phage therapy has been severely compromised by the potential emergence of phage resistance. Although certain phage resistance mechanisms can restore bacterial susceptibility to certain antibiotics, a lack of knowledge of phage resistance mechanisms hinders optimal use of phages and their combination with antibiotics. Genome-wide transposon screening was performed with a mutant library of Klebsiella pneumoniae MKP103 to identify phage pKMKP103_1-resistant mutants. Phage-resistant phenotypes were evaluated by time-kill kinetics and efficiency of plating assays. Phage resistance mechanisms were investigated with adsorption, one-step growth, and mutation frequency assays. Antibiotic susceptibility was determined with broth microdilution and population analysis profiles. We observed a repertoire of phage resistance mechanisms in K pneumoniae, such as disruption of phage binding (fhuA::Tn and tonB::Tn), extension of the phage latent period (mnmE::Tn and rpoN::Tn), and increased mutation frequency (mutS::Tn and mutL::Tn). Notably, in contrast to the prevailing view that phage resistance re-sensitizes antibiotic-resistant bacteria, we observed a bidirectional steering effect on bacterial antibiotic susceptibility. Specifically, rpoN::Tn increased susceptibility to colistin while mutS::Tn and mutL::Tn increased resistance to rifampicin and colistin. Our findings demonstrate that K pneumoniae employs multiple strategies to overcome phage infection, which may result in enhanced or reduced antibiotic susceptibility. Mechanism-guided phage steering should be incorporated into phage therapy to better inform clinical decisions on phage-antibiotic combinations. [Display omitted]
doi_str_mv	10.1016/j.cmi.2024.03.015
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However, the clinical utilization of phage therapy has been severely compromised by the potential emergence of phage resistance. Although certain phage resistance mechanisms can restore bacterial susceptibility to certain antibiotics, a lack of knowledge of phage resistance mechanisms hinders optimal use of phages and their combination with antibiotics. Genome-wide transposon screening was performed with a mutant library of Klebsiella pneumoniae MKP103 to identify phage pKMKP103_1-resistant mutants. Phage-resistant phenotypes were evaluated by time-kill kinetics and efficiency of plating assays. Phage resistance mechanisms were investigated with adsorption, one-step growth, and mutation frequency assays. Antibiotic susceptibility was determined with broth microdilution and population analysis profiles. We observed a repertoire of phage resistance mechanisms in K pneumoniae, such as disruption of phage binding (fhuA::Tn and tonB::Tn), extension of the phage latent period (mnmE::Tn and rpoN::Tn), and increased mutation frequency (mutS::Tn and mutL::Tn). Notably, in contrast to the prevailing view that phage resistance re-sensitizes antibiotic-resistant bacteria, we observed a bidirectional steering effect on bacterial antibiotic susceptibility. Specifically, rpoN::Tn increased susceptibility to colistin while mutS::Tn and mutL::Tn increased resistance to rifampicin and colistin. Our findings demonstrate that K pneumoniae employs multiple strategies to overcome phage infection, which may result in enhanced or reduced antibiotic susceptibility. Mechanism-guided phage steering should be incorporated into phage therapy to better inform clinical decisions on phage-antibiotic combinations. 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subjects	Anti-Bacterial Agents - pharmacology Antibiotic Antimicrobial resistance Bacteriophage therapy Bacteriophages - genetics DNA Transposable Elements Drug Resistance, Bacterial Humans Klebsiella pneumoniae Klebsiella pneumoniae - drug effects Klebsiella pneumoniae - genetics Klebsiella pneumoniae - virology Microbial Sensitivity Tests Mutation Phage resistance Phage steering Phage Therapy
title	Phage resistance in Klebsiella pneumoniae and bidirectional effects impacting antibiotic susceptibility
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