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Dryad

Novel insight into the effects of CPXR on Salmonella enteritidis cells during the chlorhexidine treatment and non-stressful growing conditions

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Aug 31, 2021 version files 488.03 KB

Abstract

The emergence and spread of antimicrobial resistance is a significant global challenge. To solve this emerging problem, the discovery of novel bacterial cellular targets and the critical pathways associated with antimicrobial resistance is urgently needed. In this study, we investigated the role of the two most critical extracytoplasmic stress response regulators, RpoE and CpxR, on the physiology and susceptibility of growing Salmonella enterica serovar Enteritidis cells using the polycationic antimicrobial agent, chlorhexidine (CHX). We showed that deletion of the cpxR gene significantly increased the susceptibility of this organism, whereas deletion of the rpoE gene had no effect on the pathogen’s susceptibility to the drug. It has been shown that a lack of the CpxR regulator induces multifaceted stress responses not only in the envelope but also in the cytosol, further affecting the key biomolecules, including DNA, RNA, and proteins. We showed that alterations in cellular trafficking and most of the stress responses are associated with a dysfunctional CpxR regulator during non-stressful (exponential growth phase) conditions, indicating that these physiological changes are intrinsically associated with the lack of the CpxR regulator. In contrast, induction of type II toxin-antitoxin systems and decrease of abundances of enzymes and proteins associated with the recycling of muropeptides and resistance to polymixin and cationic antimicrobial peptides were specific responses of the ∆cpxR mutant to the CHX treatment. Overall, our study provides insight into the effects of CpxR on the physiology of S. Enteritidis cells during the exponential growth phase and drug treatment, which may point to potential cellular targets for the development of an effective antimicrobial agent.