has emerged as one of the leading causative agents of nosocomial infections. Due to its high level of intrinsic and adapted antibiotic resistance, treatment failure rates are high, which allows this opportunistic pathogen to thrive during infection in immune-compromised patients. can cause infections within a broad range of host niches, with pneumonia and bacteraemia being associated with the greatest levels of morbidity and mortality. Although its resistance to antibiotics is widely studied, our understanding of the mechanisms required for dealing with environmental stresses related to virulence and hospital persistence, such as copper toxicity, is limited. Here, we performed an in silico analysis of the copper resistome, examining its regulation under copper stress. Using comparative analyses of bacterial P-type ATPases, we propose that encodes a member of a novel subgroup of P ATPases. Analyses of three putative inner membrane copper efflux systems identified the P ATPase CopA as the primary mediator of cytoplasmic copper resistance in . Using a murine model of pneumonia, we reveal that CopA contributes to the virulence of . Collectively, this study advances our understanding of how deals with environmental copper toxicity, and it provides novel insights into how combats adversities encountered as part of the host immune defence.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6387184 | PMC |
| http://dx.doi.org/10.3390/ijms20030575 | DOI Listing |
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Article Synopsis
- Antibiotic resistance in Acinetobacter baumannii, a common hospital pathogen, is growing, posing serious risks to health care workers and society, driven by both antibiotic overuse and environmental stressors.
- A study found that exposing A. baumannii to copper stress led to significant increases in resistance to key antibiotics: 8-fold for colistin, 44-fold for ciprofloxacin, and 22-fold for levofloxacin, alongside enhanced biofilm formation.
- The bacteria exhibited physiological changes, such as higher efflux pump activity and alterations in membrane permeability, with molecular analysis showing increased gene expression related to antibiotic resistance and oxidative stress, indicating adaptation to stressors.
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