Abstract
Most Gram-negative bacteria respond to excessive levels of H2O2 using the peroxide-sensing transcriptional regulator OxyR, which can induce the expression of antioxidant genes to restore normality. Vibrio vulnificus has two distinct OxyRs (OxyR1 and OxyR2), which are sensitive to different levels of H2O2 and induce expression of two different peroxidases, Prx1 and Prx2. Although OxyR1 has both high sequence similarity and H2O2 sensitivity comparable with that of other OxyR proteins, OxyR2 exhibits limited sequence similarity and is more sensitive to H2O2 To investigate the basis for this difference, we determined crystal structures and carried out biochemical analyses of OxyR2. The determined structure of OxyR2 revealed a flipped conformation of the peptide bond before Glu-204, a position occupied by glycine in other OxyR proteins. Activity assays showed that the sensitivity to H2O2 was reduced to the level of other OxyR proteins by the E204G mutation. We solved the structure of the OxyR2-E204G mutant with the same packing environment. The structure of the mutant revealed a dual conformation of the peptide bond before Gly-204, indicating the structural flexibility of the region. This structural duality extended to the backbone atoms of Gly-204 and the imidazole ring of His-205, which interact with H2O2 and invariant water molecules near the peroxidatic cysteine, respectively. Structural comparison suggests that Glu-204 in OxyR2 provides rigidity to the region that is important in H2O2 sensing, compared with the E204G structure or other OxyR proteins. Our findings provide a structural basis for the higher sensitivity of OxyR2 to H2O2 and also suggest a molecular mechanism for bacterial regulation of expression of antioxidant genes at divergent concentrations of cellular H2O2.
Highlights
Most Gram-negative bacteria respond to excessive levels of H2O2 using the peroxide-sensing transcriptional regulator OxyR, which can induce the expression of antioxidant genes to restore normality
Structural comparison suggests that Glu-204 in OxyR2 provides rigidity to the region that is important in H2O2 sensing, compared with the E204G structure or other OxyR proteins
Our findings provide a structural basis for the higher sensitivity of OxyR2 to H2O2 and suggest a molecular mechanism for bacterial regulation of expression of antioxidant genes at divergent concentrations of cellular H2O2
Summary
5X0V a Values in parentheses are for the highest-resolution shell. of H2O2, resulting in formation of the oxidized (or disulfidized) form of OxyR that activates the induction of target genes [11, 12]. VvOxyR1 has high sequence and functional similarities to typical types of OxyR proteins and induces VvPrx expression at a certain H2O2 concentration (ϳ5 M) [16]. A three-state activation mechanism for VvOxyR2 was proposed [11] In this mechanism, above the working concentration of H2O2 for VvPrx, VvOxyR2 undergoes a new conformational change to prevent non-functional gene expression. Above the working concentration of H2O2 for VvPrx, VvOxyR2 undergoes a new conformational change to prevent non-functional gene expression In this third state, the peroxidatic cysteine residue of VvOxyR2 is further oxidized to cysteine-sulfinic acid (Cys-SO2H) or cysteine-sulfonic acid (Cys-SO3H), yielding the overoxidized form of OxyR that lacks transcriptional activity [11]. To understand how OxyR proteins with similar structures have differing sensitivities to different levels of H2O2, we determined the crystal structures of OxyR2 RD from V. vulnificus and performed biochemical analyses
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