Bacterial motility is also necessary for successful colonization

Bacterial motility is also necessary for successful colonization of the gastric epithelium. Motility of H. pylori depends on the presence of up to 6 functional unipolar flagella. Recent studies indicate that proper assembly of flagella requires peptidoglycan-degrading enzymes that promote the correct localization and function of the flagella motor [2]. H. pylori regulates cell motility 5-Fluoracil by responding to chemotactic cues, which then alter flagellar activity. Indeed, chemotactic (Che-) mutants have altered colonization patterns. H. pylori senses environmental chemical cues via four chemoreceptors: Tlp A, B, C, and D. Using isogenic chemoreceptor

mutants, Rolig et al. demonstrate that TlpD is necessary for H. pylori to survive and grow in the infected and inflamed antrum but not elsewhere in the murine stomach [3]. After colonization, adherence to gastric epithelial cells is required to avoid shedding and increase availability of nutrients. However, adherence may also be detrimental due to more intimate interactions with the host immune response. H. pylori employs genetic diversification to adapt to the selleck chemical changing environment to promote colonization and persistent infection. H. pylori has a variety of outer membrane proteins (OMPs), several

of which can serve as adhesins including BabA and SabA. The 5′ and 3′ end regions of the omp genes (encoding OMPs) are highly conserved, which could allow for recombination, thereby switching loci and bacterial phenotype [4]. Clinical isolates

obtained from pediatric see more subjects showed variability in the copy number and locus of the omp genes sabA and sabB implicating intragenomic recombination among strains [4]. In vitro studies demonstrated that sabA gene duplication increases SabA protein production and adherence. Using binding assays to a panel of glycosphingolipids, the structural requirements for binding of BabA to the host cell adhesin receptor were further assessed. BabA was found to bind blood group determinants on both the type 1 and type 4 core chains in these in vitro assays [5]. Recent studies continue to expand our understanding of the potential mechanisms by which the major virulence factors cagA and vacA influence disease. Of interest, a novel model for investigating CagA pathogenesis was recently described in zebra fish [6]. This model recapitulated CagA-mediated changes previously identified in tissue culture and in animal models supporting its use to investigate pathogenic mechanisms involved in disease. Two complementary studies provided insight into the structure and function of CagA [7, 8]. Upon contact with epithelial cells, CagA is injected into the host cell via the cag pathogenicity island (cagPAI)-encoded type IV secretion system (T4SS).

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