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Unravelling the myths and mysteries of the antimicrobial agent, silver
Author(s) -
Lemire Joe,
ChatfieldReed Kate,
Kalan Lindsay,
Gugala Natalie,
Westersund Connor,
Almblad Henrik,
Chua Gordon,
Turner Raymond J
Publication year - 2017
Publication title -
the faseb journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.709
H-Index - 277
eISSN - 1530-6860
pISSN - 0892-6638
DOI - 10.1096/fasebj.31.1_supplement.939.2
Subject(s) - biofilm , antimicrobial , microbiology and biotechnology , bacteria , crystal violet , silver stain , silver nanoparticle , biology , chemistry , nanotechnology , materials science , genetics , nanoparticle
Background Silver is being widely‐deployed in the clinic – in wound dressing, catheters, and endotracheal tubes ‐ to combat and control infectious disease. Despite this widespread use, we still don't know the precise way that silver kills the bacterial cell. Recently, our research group demonstrated that silver formulations with novel chemistries – silver oxysalts – have an enhanced antibacterial activity. Yet, we still don't know why different silver formulations show variable antimicrobial efficacy. Methods To test the efficacy of various silver compounds, numerous strains of E.coli , P.aeruginosa , and S.aureus were grown as single and multispecies biofilms in the Calgary Biofilm Device. The capacity of different silver compounds to prevent the formation of and eradicate planktonic and biofilm populations of bacteria was performed using the minimal biofilm eradication concentration assay, confocal microscopy and crystal violet staining. To enhance our understanding of how silver poisons bacteria, we undertook a robotic chemical genetic screen of an ordered mutant library of E.coli bacteria – the Keio collection. To confirm the genetic linkage of our silver responsive genes identified in our chemical genetic screen, we used Scarless Cas‐9 Assisted Recombineering to generate unmarked mutants. Our genes of interest were then linked to silver sensitivity or resistance phenotypes using minimal inhibition concentration assays and transmission electron microscopy (TEM). Results We observed that higher oxidation states of silver have enhanced activity for preventing the formation of, and eradicating single and multispecies, planktonic and biofilm, populations of bacteria – suggesting that the chemistry of silver formulations dictates its antimicrobial efficacy. Our chemical genetic screen suggests that silver poisoning has previously unanticipated effects on the bacterial cell including disrupting the bacterial cell envelope, altering indole metabolism, and controlling bacterial cell population. Moreover, using a Recombineering workflow and TEM we confirmed the involvement of a gene involved in the production of a cell wall protein, and a monovalent cation transporter, in silver sensitivity and resistance, respectively. The latter finding is relevant because the protein responsible for the entrance of silver into the bacterial cell has yet to be identified. Conclusions Altogether, our findings established novel mechanisms regarding the mode‐of‐action of silver in the bacterial cell. We've established that the specific chemistries of silver compounds determine antimicrobial capacity. Additionally, we've identified genes that may lead to silver resistance. These findings are ever‐important as we aim to maintain the utility of this valuable antimicrobial agent. Support or Funding Information We graciously acknowledge funding from the Natural Science and Engineering Research Council of Canada and the Canadian Institutes of Health Research. JL was funded by a Banting Postdoctoral Fellowship and an Alberta Innovates Health Solutions Postdoctoral award. We would also like to thank the University of Calgary for providing an Eyes High Graduate/Postgraduate Fellowship to NG and HA, respectively and research funding for JL.