coli and Saccharomyces cerevisiae showed that this compound cannot diffuse freely [9, 10]. For HOCl, diffusion through the OM is reported to be limited [11]. One possibility for H2O2 and HOCl influx through the OM is diffusion through porins. In this context, we recently reported that OmpD, S.
Typhimurium most abundant OM porin, allows H2O2 diffusion [12]. OM porins are organized as homo-trimers (classic porins) or monomers (small porins) forming aqueous channels that allow the influx of hydrophilic solutes with a molecular weight ≤ 600 find more Da [13]. Classic porins, including OmpC and OmpF, form β-barrels with 12–22 transmembrane segments while small porins (OmpW) are composed of 8–10 [14, 15]. The crystal structure of OmpW from E. coli revealed that it forms an 8-stranded β-barrel and functions as an ion channel in lipid bilayers [16, 17]. In Vibrio cholerae, OmpW was described as an immunogenic 22 KDa protein [18] and its expression is altered by factors such as temperature, salinity, nutrient availability and oxygen levels [19]. Additionally, several studies show that porins are regulated by ROS. Due its oxidant nature and diffusion through the OM, regulation of porin expression must be tightly regulated
VEGFR inhibitor as a mechanism of controlling OM permeability. Accordingly, S. Typhimurium ompD and ompW expression is regulated in response to H2O2 and paraquat [12, 20], respectively, and S. Enteritidis and Typhimurium exposure to HOCl results in lower levels of ompD ompC and ompF transcripts [21]. The cellular response to oxidative stress is regulated at the transcriptional
level by activating the SoxRS and OxyR regulons in response to O2 − and H2O2, respectively [22, 23], however, several studies have provided evidence for a role of the ArcAB two selleck compound component system in the resistance to ROS induced damage [12, 24–26]. ArcA is essential for S. Enteritidis, Typhimurium and E. coli resistance to ROS [24, 26, 27]. ArcB is a sensor member of the histidine kinase family that is anchored to the inner membrane [28]. In response to oxygen availability, ArcB autophosphorylates VDA chemical in an ATP dependant intramolecular reaction at position His-292 [29, 30] and transfers the phosphate group to the cytoplasmic response regulator ArcA [31–33], which binds to promoter regions regulating gene expression [34, 35]. ArcB activity is regulated in response to oxygen conditions by the redox state of both the ubiquinone and menaquinone pools [29, 36–38]. However, recent studies in E. coli show that the system is regulated by the degree of aerobiosis but not by the redox state of the ubiquinone pool, challenging the idea that the system is inhibited by oxidized quinones [39]. In this work we provide further evidence of the role of the ArcAB two component system in the response to ROS under aerobic conditions and show that this system mediates regulation of ompW expression in response to a novel signal, HOCl.