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. 2006 Feb;188(4):1389-95.
doi: 10.1128/JB.188.4.1389-1395.2006.

Novel organic hydroperoxide-sensing and responding mechanisms for OhrR, a major bacterial sensor and regulator of organic hydroperoxide stress

Warunya Panmanee  1 Paiboon VattanaviboonLeslie B PooleSkorn Mongkolsuk
Affiliations

Novel organic hydroperoxide-sensing and responding mechanisms for OhrR, a major bacterial sensor and regulator of organic hydroperoxide stress

Warunya Panmanee et al. J Bacteriol. 2006 Feb.

Abstract

Xanthomonas campestris pv. phaseoli OhrR belongs to a major family of multiple-cysteine-containing bacterial organic hydroperoxide sensors and transcription repressors. Site-directed mutagenesis and subsequent in vivo functional analyses revealed that changing any cysteine residue to serine did not alter the ability of OhrR to bind to the P1 ohrR-ohr promoter but drastically affected the organic hydroperoxide-sensing and response mechanisms of the protein. Xanthomonas OhrR requires two cysteine residues, C22 and C127, to sense and respond to organic hydroperoxides. Analysis of the free thiol groups in wild-type and mutant OhrRs under reducing and oxidizing conditions indicates that C22 is the organic hydroperoxide-sensing residue. Exposure to organic hydroperoxides led to the formation of an unstable OhrR-C22 sulfenic acid intermediate that could be trapped by 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole and detected by UV-visible spectral analysis in an oxidized C127S-C131S mutant OhrR. In wild-type OhrR, the cysteine sulfenic acid intermediate rapidly reacts with the thiol group of C127, forming a disulfide bond. The high-performance liquid chromatography-mass spectrometry analysis of tryptic fragments of alkylated, oxidized OhrR and nonreducing polyacrylamide gel electrophoresis analyses confirmed the formation of reversible intersubunit disulfide bonds between C22 and C127. Oxidation of OhrR led to cross-linking of two OhrR monomers, resulting in the inactivation of its repressor function. Evidence presented here provides insight into a new organic hydroperoxide-sensing and response mechanism for OhrRs of the multiple-cysteine family, the primary bacterial transcription regulator of the organic hydroperoxide stress response.

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Figures

FIG. 1.
FIG. 1.
Alignment of the deduced amino acid sequences of OhrRs from various bacteria. Xanthomonas, X. campestris (EMBL accession no. AAK62673); Caulobacter, C. crescentus (accession no. AAK22899); Brucella, B. melitensis (accession no. ALL53650), Vibrio, V. cholerae (accession no. AAF96901); Burkholderia, B. mallei (accession no. AAU46183); Erwinia, E. carotovora subsp. atroseptica (accession no. CAG76066); Acinetobacter, A. calcoaceticus (accession no. GAG69726); Sinorhizobium, S. meliloti (accession no. CAC45533); Agrobacterium, A. tumefaciens (accession no. AAL41860); Ralstonia, R. solanacearum (accession no. CAD18257); Pseudomonas, P. aeruginosa (accession no. AAG06237); Clostridium, C. acetobutylicum (accession no. AAK79536); Azotobacter, A. vinelandii (accession no. EAM06258); Bacillus, B. subtilis (accession no. CAA05594); Oceanobacillus, O. iheyensis (accession no. BAC15414); Streptomyces, S. coelicolor (accession no. CAB87337). Numbers indicate the positions of amino acid residues corresponding to X. campestris pv. phaseoli OhrR. Cysteine residues are shaded.
FIG. 2.
FIG. 2.
Organic hydroperoxide-dependent regulation of the X. campestris ohrR P1 promoter by wild-type and mutant OhrRs. β-Galactosidase activities of exponential-phase cultures of various XpP1lacZ transcriptional fusion strains (15, 17) expressing wild-type and C22S, C127S, and C131S mutant OhrRs were either induced with 100 μM CHP for 30 min (gray bars) or untreated (black bars). The values presented are the means and standard deviations of three independent experiments.
FIG. 3.
FIG. 3.
Spectra of NBD chloride-treated OhrR mutant proteins. Reduced C127S-C131S OhrR was treated with (solid line) or without (dotted line) an equivalent amount of CHP prior to incubation with 20 molar equivalents of NBD chloride. Shown are the UV-visible absorbance spectra of the NBD-labeled proteins with absorbance maxima at 347 and 420 nm, respectively.
FIG. 4.
FIG. 4.
Disulfide bond formation between OhrR monomers. Purified OhrR samples prepared under various conditions were separated in nonreducing SDS-PAGE. R, reduced OhrR; O, oxidized OhrR; NEM, oxidized OhrR treated with N-ethylmaleimide; DTT, oxidized OhrR treated with DTT. Arrows indicate the positions of monomers (18 kDa) and dimers (37 kDa). Protein bands were stained with Coomassie blue. M represents protein molecular mass markers.
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