Helicobacter pylori, an oxygen-sensitive microaerophilic bacterium, contains many antioxidant proteins, among which alkylhydroperoxide reductase (AhpC) is the most abundant. The function of AhpC is to protect H. pylori from a hyperoxidative environment by reduction of toxic organic hydroperoxides. We have found that the sequence of AhpC from H. pylori is more homologous to mammalian peroxiredoxins than to eubacterial AhpC. We have also found that the protein structure of AhpC could shift from lowmolecular-weight oligomers with peroxide-reductase activity to high-molecular-weight complexes with molecular-chaperone function under oxidative stresses. Time-course study by following the quaternary structural change of AhpC in vivo revealed that this enzyme changes from low-molecular-weight oligomers under normal microaerobic conditions or short-term oxidative shock to high-molecular-weight complexes after severe long-term oxidative stress. This study revealed that AhpC of H. pylori acts as a peroxide reductase in reducing organic hydroperoxides and as a molecular chaperone for prevention of protein misfolding under oxidative stress.peroxiredoxin ͉ oxidative stress ͉ phylogenetic comparison ͉ dual functionality ͉ quaternary structural change
Helicobacter pylori is a spiral, slow growing gram‐negative microaerophilic bacterium. It has been shown to be the etiological agent of gastroduodenal diseases, such as chronic gastritis, gastric and duodenal ulcers, and gastric cancer. To address the influence of oxidative stress and its underlying mechanisms, we have compared proliferation, urease activity and protein expression profile of H. pylori incubated under normal microaerophilic (5% O2) and aerobic stress (20% O2) conditions. Oxidative‐stress cells displayed coccoid morphology and time‐dependent decrease in proliferation. The urease activity was completely abrogated after 32 h. We have further compared the protein expression profiles of H. pylori under normal growing and oxidative‐stress conditions by a global proteomic analysis, which includes high‐resolution 2‐DE followed by MALDI‐TOF‐MS and bioinformatic databases search/peptide‐mass comparison. The results revealed that more than ten proteins were differentially expressed under oxidative stress. Most notably, the protein expression levels of urease accessory protein E (UreE, an essential metallochaperone for urease activity) and alkylhydroperoxide reductase (AhpC) with antioxidant potential are greatly decreased under stress conditions. Measurements of messenger RNA transcription level by performing RT‐PCR on total mRNA also confirmed that gene expressions for these two proteins are consistently repressed under oxygen tension. These changes form a firm basis to account for the loss of urease activity and anti‐oxidative ability of H. pylori after long‐term exposure to reactive oxygen. Conceivably, UreE and AhpC may thus be listed as potential targets for the development of therapeutic drugs against H. pylori.
Alkylhydroperoxide reductase (AhpC) is an abundant and important antioxidant protein present in Helicobacter pylori (HP), a spiral Gram-negative microaerophilic bacterium. By sequence alignment and structure comparison, HP-AhpC was found to be more homologous to human peroxiredoxins (hPrx) than to other eubacterial AhpC proteins. Similar to hPrxI, native HP-AhpC existed as a dimer of single subunit, comprising alpha-helix and beta-sheet domains with low surface hydrophobicity. AhpC can form high-molecular-weight (HMW) aggregates ranging from 700 to higher than 2,000 kDa under oxidative stress, possessing chaperone activity in the presence of thioredoxin (Trx). Further analysis of peroxide-reductase activities showed that HP-AhpC was more resistant to H(2)O(2) than hPrxI. However, the mechanism of enzyme inactivation to H(2)O(2) appeared to be similar for both HP-AhpC and hPrxI as revealed by native gel electrophoresis followed by proteomic identification using two-dimensional gel electrophoresis (2-DE) and LC-MS/MS. In contrast to T90D-hPrxI mutant with chaperone activity, site-specific mutant T87D-HP-AhpC did not form HMW chaperone complexes. The comparison of these two evolutionarily distant and yet functionally related enzymes may shed some light on the mechanism(s) underlying the evolution and development of the dual functionality in HP-AhpC and hPrxI with similar protein structure.
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