AI Article Synopsis
- * The bacterial protein OhrR regulates the response to these toxic hydroperoxides, promoting the production of the enzyme that converts them into less harmful alcohols, but its expression is complex, influenced by different oxidants.
- * Finally, the study reveals that alterations in the levels of OhrR can affect bacterial survival and virulence, indicating that both OhrR and organic hydroperoxides are important factors in the pathogenicity of bacteria.
Article Abstract
Fatty acid hydroperoxides are involved in host-pathogen interactions. In both plants and mammals, polyunsaturated fatty acids are liberated during infection and enzymatically oxidized to the corresponding toxic hydroperoxides during the defensive oxidative burst that is designed to thwart the infection. The bacterial transcription factor OhrR (organic hydroperoxide reductase regulator) is oxidized by organic hydroperoxides, as a result of which the gene encoding organic hydroperoxide reductase is induced. This enzyme converts the hydroperoxides to less toxic alcohols. We show here that OhrR from represses expression of Gene expression is induced by cumene hydroperoxide and to a lesser extent by inorganic oxidants; however, Ohr contributes to degradation only of the organic hydroperoxide. OhrR, which binds specific sites in both and promoters, as evidenced by DNase I footprinting, belongs to the 2-Cys subfamily of OhrR proteins, and its oxidation leads to reversible disulfide bond formation between conserved N- and C-terminal cysteines in separate monomers. Oxidation of the N-terminal Cys is sufficient for attenuation of DNA binding , with complete restoration of DNA binding occurring on addition of a reducing agent. Surprisingly, both overexpression of and deletion of results in enhanced survival on exposure to organic hydroperoxide While Δ cells are more virulent in a model of infection, Δ cells are less so. Taken together, our data suggest that OhrR has several unconventional features and that both OhrR and organic hydroperoxides may contribute to virulence.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6105889 | PMC |
| http://dx.doi.org/10.1128/IAI.00322-18 | DOI Listing |
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