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Browsing by Subject "Darmepithel"

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    Molekulare Interaktionen von Milchsäurebakterien mit enterohämorrhagischen Escherichia coli und humanen Darmepithelzellen
    (2011) Stöber, Helen; Schmidt, Herbert
    The interactions of 19 benign strains of lactic acid bacteria, bifidobacteria and staphylococci with five enterohemorrhagic Escherichia coli (EHEC) strains of different serotypes and virulence gene spectrum were investigated using a HT29 cell culture infection model. As a parameter for the infection the secretion of Interleukin 8 (IL-8) of the infected cells was analyzed by ELISA. None of the used benign strains induced an IL-8 secretion, whereas the infection with the EHEC strains leads ? independent of their virulence profile - to high amounts of IL-8. In coinfection assays with the pathogen EDL933 (O157:H7) and different test strains the secretion of IL-8 of the cultured cells was decreased by a few strains. With 12 of 19 tested strains, a weak reduction < 30 % of IL-8 secretion of HT29 cells after coinfection with EHEC O157:H7 strain EDL933 was observed. Six strains reduced the IL-8 secretion up to 60 % and the strain B. breve DSMZ 20083 decreased the IL-8 production about 73 %. Coinfection assays with different strains of one species (B. adolescentis DSMZ 20083 and DSMZ 20086 as well as L. johnsonii BFE 633 and DSMZ 10533) showed the strain specificity of the observed anti-inflammatory effect, due to different capabilities of IL-8 reduction. In further coinfection assays with different EHEC strains of the serotypes O103:H2, O26:H-, 0157:H- and O113:H21 different abilities of the benign strains to influence the infection with the different pathogen strains were noted. Therefore the protective anti-inflammatory effect is strain specific for the tested benign bacteria and also depends on the application of EHEC strains with different sero- and virulence types. Further investigations indicated the imperative of living bacteria for the observed protective effect; neither culture supernatant nor inactivated bacteria showed an effect on the IL-8 secretion of the EDL933 infected HT29 cells. The analysis of the cell culture supernatants 6 h after infection with different bacteria detected the production of lactic and acetic acid. The application of these acids in infection assays with EDL933 did not lead to an reduced IL-8 secretion of the infected cells. Therefore the production of organic acids did not explain the protective effect. The induction of IL-8 could not be traced back to the influence of a single virulence factor. Four PMK5 strains with deletions in different virulence genes induced similar IL-8 secretions in comparison to cells infected with the wild-type strain. Coinfection assays with the mutants and S. pasteuri LTH 5211 showed also similar IL-8 reductions than coinfection assays with the wild-type strain. It is to suppose that the anti-inflammatory effects of the benign bacteria do not influence a single virulence factor of the tested EHEC strains. As a second parameter the activation of the transcription factor ?Nuclear Factor kappa B? (NF-κB) of coinfected HT29 cells was monitored using a reporter-genassay. In comparison to the single EHEC-infection, the NF-κB activation was reduced by all tested lactic acid bacteria, bifidobacteria and S. pasteuri LTH 5211 in coinfection trials significantly. No strain-specificity and no pathogen-specificity could be observed. Interestingly, stimulation of the HT29 cells with benign bacteria led to inhibition of NF-κB activity, the measured values were less than the values of the negative control PBS. A gene expression analysis of toll-like receptors (TLRs), recognizing bacteria on cell surfaces and initiating the immune response, showed no regulation for TLR2. Infection with EDL933 led to down regulation of TLR4 and to up regulation of TLR9. Stimulation with L. rhamnosus GG, L. johnsonii DSMZ 10533 or L. fermentum DSMZ 20052 led neither to regulation of TLR4 nor TLR9. The benign bacteria did not influence the EHEC-induced TLR4 regulation in coinfection trials; in contrast the regulation of TLR9 was reduced significantly. The model described here is useful for screening basic effects of protective bacteria that are able to counteract EHEC-mediated effects on human cells and to study the molecular interaction between bacteria as well as between bacteria and human cultured cells.
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    Probiotic bacteria enhance the antibacterial barrier of enterocytes: insights into their mechanism of action
    (2007) Schlee, Miriam; Bode, Christiane
    In the healthy intestine there is a stable balance of luminal bacteria and host factors to prevent infections or inflammatory bowel diseases (IBD). A complex network of environmental, genetic, and immunoregulatory factors may precipitate the onset of ulcerative colitis (UC) and Crohn's disease (CD), the primary manifestations of inflammatory bowel disease (IBD). It is currently believed that IBD results from an aberrant immune response of the intestinal mucosa towards the normal commensal bacterial flora. Alternatively, a primary defect in the mucosal barrier might permit bacterial invasion and trigger inflammation. In our research group the hypothesis was proposed that the defective barrier in Crohn´s disease may be due to a lack of defensins which form a chemical barrier against luminal bacteria. A major gut defensin is the human beta defensin-2 (hBD-2) which is an inducible antimicrobial peptide synthesized and secreted by the epithelium to counteract bacterial adherence and invasion. Proinflammatory cytokines, as well as certain bacterial strains, have been identified as potent endogenous inducers. In recent studies, Fellermann et al demonstrated that the defective expression of hBD-2 which was measured in the gut mucosa of patients with Crohn´s disease was due to a reduced copy number of the hBD-2 gene. In patients with ulcerative colitis beta-defensin expression is low in the colon during remission, but readily inducible during inflammation. Probiotic bacteria might act beneficially in the human gut by inducing the expression of defensins and thereby reinforcing the mucosal barrier. Recently, our group has been the first to describe hBD-2 induction by the probiotic strain E. coli Nissle (Mutaflor®) which is an effective treatment for ulcerative colitis during remission. The aim of the present work was to determine the underlying molecular mechanisms. We determined a time- and dose-dependent expression pattern of hBD-2 in Caco-2 cells upon stimulation with IL-1 beta;, E. coli Nissle culture supernatant and diverse other probiotic strains. We further investigated the transcriptional regulation of hBD-2 expression mediated by probiotics. The hBD-2 promoter contains several elements known to be involved in transcriptional upregulation such as the NF-kappa B element, which is believed to be one of the main regulators of the hBD-2 gene expression. However, for certain signals, the expression of the hBD-2 gene has been reported to depend on the activation of a second transcription factor, such as AP-1. Most importantly, E. coli Nissle was shown to shed or secrete factors, contained in the bacterial supernatant, which were sufficient to trigger activation of NF-kappa B and AP-1 and to induce hBD-2. Our results indicated further that the supernatant-induced activation of the MAP kinase pathways ERK½, JNK, and p38 may be directly responsible for the probiotic supernatant-induced activation of the transcription factors AP-1 and NF-kappa B and subsequent synthesis of hBD-2. A further aim of the present study was to identify and isolate the bacterial components which are responsible for E. coli Nissle mediated hBD-2 induction. As E. coli Nissle culture supernatant was found to be a more potent stimulant than the bacterial pellet, we investigated the characteristics of the unknown soluble or shed molecules in the bacterial culture media. The first analysis revealed the factor as a heat resistant and proteinase sensitive molecule. Both, E. coli Nissle specific lipopolysaccharide (LPS) and bacterial DNA, which might contain immunostimulatory DNA motifs, failed to trigger hBD-2 expression. Based on the knowledge of the surface composition several E. coli Nissle deletion mutants were constructed and tested for their ability to induce hBD-2 expression in Caco-2 cells. Deletion mutants for flagellin, the flagella filament protein, specifically exhibited an impaired immunostimulatory capacity. Reinsertion of the flagellin gene restored the induction capacity to normal levels. Next, we isolated flagellins from different bacteria strains (Salmonella enterica serovar Enteritidis, E. coli ATCC 25922, E. coli Nissle and the uropathogenic E. coli strain CFT073 Delta hly, whose genome structure resembles closely that of E. coli Nissle). In the Western blot anti-H1 flagellin displayed immunoreactivity against the different types of flagellins, due to the highly conserved central region of the flagellin filament structure. Incubation of Caco-2 cells with isolated E. coli Nissle flagellin (molecular size 60.81 kDa) induced hBD-2 promoter activation in a dose-dependent manner. The induction of hBD-2 expression by flagellin was confirmed with a positive control (Salmonella flagellin). Interestingly, the serotype-identical CFT073 Delta hly flagellin expressed only moderate hBD-2 inducing ability compared to E. coli Nissle flagellin. Thus, differences in extracellular matrix e.g. the glycosilation degree might underlie the differentially modulated hBD-2 response of Caco-2 cells by the two flagellins. H1 flagellin antiserum abrogated hBD-2 expression induced by flagellin as well as E. coli Nissle supernatant, confirming that flagellin is the major stimulatory factor of E. coli Nissle. In conclusion, flagellin of E. coli Nissle provides reinforcement of mucosal antimicrobial function, apparently without inducing inflammation. This might explain the beneficial effects of E. coli Nissle on remission maintenance in ulcerative colitis. In patients with Crohn´s disease there is evidence against a therapeutic effect of probiotics and this may be explained by a defective defensin system. Future investigations about strain-specific beneficial functions might contribute to the therapeutic application of science-based probiotic products.