It controls at least 100 operons that are involved in the TCA cycle and energy metabolism [16, 24–29]. The sensor kinase ArcB undergoes auto-phosphorylation at His292 under anaerobic conditions, and this activation is negatively regulated by the oxidized quinones under aerobic conditions [25]. Activated ArcB undergoes
a phosphorelay of His292 to Asp576 to His717, and subsequently activates its cognate transcriptional regulator ArcA by phosphorylating ArcA at Asp54 to repress genes contributing to aerobic metabolism (e.g. citrate synthase and isocitrate lyase) and activates genes necessary for anaerobic metabolism CBL0137 purchase (e.g. pyruvate formate lyase and hydrogenase) [23, 25, 30–34]. Although the function of the ArcAB system in the anaerobic growth of E. coli has been well characterized, this website its function is unlikely to be limited to those required for the anaerobic growth of bacteria. For example, the ArcAB system has been reported to be involved in chromosomal replication, stress responses and aging of bacteria [35–37]. We have previously reported that ArcA of Salmonella enterica is necessary for its resistance to reactive oxygen and nitrogen species (ROS and RNS) [38]. More
recently, ArcA is implicated in the ROS stress response of Haemophilus influenzae [39]. In this report, we analyzed the role of ArcAB in reactive oxygen resistance of E. coli and investigated the mechanism of ROS resistance mediated by the ArcAB two-component system. Silibinin Results ArcAB system is necessary for E. coli to resist hydrogen peroxide (H2O2) To determine if the ArcAB global regulatory system plays a role in the survival of E. coli under stress by reactive oxygen species (ROS), we generated deletion mutants of ArcA (the global regulator) and
ArcB (the cognate sensor-kinase of ArcA) in E. coli (Table 1). Both ΔarcA and ΔarcB CCI-779 ic50 mutant E. coli formed smaller colonies than their parental E. coli, but otherwise showed similar colony morphology. The ΔarcA and ΔarcB mutant E. coli were tested for their growth properties in complete (Luria Bertani broth) or minimal (M9) medium with glucose as carbon source. Overnight culture of each bacterial strain was diluted 1:100 in LB or M9 medium, and the growth of bacteria was measured by the optical density of the culture at 550 nm (OD550 nm) every 2 hours for 8 hours and then at 24 hours. This incubation period includes both log phase of growth and stationary phase of bacteria. We found that OD550 nm of both ΔarcA and ΔarcB mutants appeared to be lower than that of the wild type E. coli during the log phase of growth. However, both mutants had similar bacterial concentrations and growth curves to those of the wild type E. coli when their growth was quantified by plating (Figure 1B and 1D). Therefore, no gross defect was observed in ΔarcA and ΔarcB mutants in spite of lower OD550 nm of their cultures.