Characterization of the oxidative stress response regulatory network in Bacteroides fragilis: An interaction between BmoR and OxyR regulons promotes abscess formation in a model of intra-abdominal infection.

OBJECTIVES: Bacteroides fragilis is an anaerobic bacterium that is commonly found in the human gut microbiota and an opportunistic pathogen in extra-intestinal infections. B. fragilis displays a robust response to oxidative stress which allows for survival in oxygenated tissues such as the peritoneal cavity and lead to the formation of abscesses. In this study, we investigated the synergy of the oxidative stress response regulators OxyR and BmoR in the ability of B. fragilis to resist oxidative damage and to survive in extra-intestinal infection. METHODS: A ΔbmoR ΔoxyR double mutant B. fragilis strain was constructed, and its oxidative stress response was compared to parental and single mutant strains in phenotypical assays and gene expression analysis. The pathogenic potential in an in vivo mouse model of abscess formation was also evaluated. RESULTS: Expression analysis showed a coordinated control of thioredoxin C (trxC) gene expression by BmoR and OxyR during oxygen exposure, with upregulation of trxC in the bmoR mutant strain (4.9-fold increase), downregulation in the oxyR mutant (2.5-fold decrease), and an intermediate level of deregulation (2-fold increase) in the double mutant strain compared to the parent strain. Expression analysis during oxidative stress conditions also showed that BmoR is a major repressor of the CoA-disulfide reductase gene (upregulated 47-fold in the bmoR mutant) while OxyR plays a minor repression role in this gene (upregulated 2.5-fold in the oxyR mutant). Exposure to atmospheric oxygen for up to 72 h revealed that the deletion of bmoR alone had no significant effect in in vitro survival phenotype assays, though it partially abolishes the OxyR sensitivity phenotype in the bmoR/oxyR double mutant strain compared to oxyR mutant. In vivo assays showed that bmoR and oxyR mutants were significantly impaired in the formation and development of abscesses compared to the parent strain in an experimental intra-abdominal infection mouse model. CONCLUSION: Although the full extent of genes whose expression are modulated by BmoR and OxyR is yet to be defined, we present evidence that these regulators have overlapping functions in B. fragilis response to oxidative stress and ability to form abscess in extra-intestinal tissues.

Deletion of BmoR affects the expression of genes related to thiol/disulfide balance in Bacteroides fragilis.

Bacteroides fragilis, an opportunistic pathogen and commensal bacterium in the gut, is one the most aerotolerant species among strict anaerobes. However, the mechanisms that control gene regulation in response to oxidative stress are not completely understood. In this study, we show that the MarR type regulator, BmoR, regulates the expression of genes involved in the homeostasis of intracellular redox state. Transcriptome analysis showed that absence of BmoR leads to altered expression in total of 167 genes. Sixteen of these genes had a 2-fold or greater change in their expression. Most of these genes are related to LPS biosynthesis and carbohydrates metabolism, but there was a significant increase in the expression of genes related to the redox balance inside the cell. A pyridine nucleotide-disulfide oxidoreductase located directly upstream of bmoR was shown to be repressed by direct binding of BmoR to the promoter region. The expression of two other genes, coding for a thiosulphate:quinone-oxidoreductase and a thioredoxin, are indirectly affected by bmoR mutation during oxygen exposure. Phenotypic assays showed that BmoR is important to maintain the thiol/disulfide balance in the cell, confirming its relevance to B. fragilis response to oxidative stress.