The intestinal epithelium serves as a barrier to the intestinal flora. In response to pathogens, intestinal epithelial cells (IEC) secrete proinflammatory cytokines. To aid in defense against bacteria, IEC also secrete antimicrobial peptides, termed defensins. The aim of our studies was to understand the role of TLR signaling in regulation of β-defensin expression by IEC. The effect of LPS and peptidoglycan on β-defensin-2 expression was examined in IEC lines constitutively or transgenically expressing TLRs. Regulation of β-defensin-2 was assessed using promoter-reporter constructs of the human β-defensin-2 gene. LPS and peptidoglycan stimulated β-defensin-2 promoter activation in a TLR4- and TLR2-dependent manner, respectively. A mutation in the NF-κB or AP-1 site within the β-defensin-2 promoter abrogated this response. In addition, inhibition of Jun kinase prevents up-regulation of β-defensin-2 protein expression in response to LPS. IEC respond to pathogen-associated molecular patterns with expression of the antimicrobial peptide β-defensin-2. This mechanism may protect the intestinal epithelium from pathogen invasion and from potential invaders among the commensal flora.
Sustained expression of CagA, the type IV secretion effector of Helicobacter pylori, is closely associated with the development of gastric cancer. However, we observed that after translocation, CagA is degraded by autophagy and therefore short lived. Autophagy and CagA degradation are induced by the H. pylori vacuolating cytotoxin, VacA, which acted via decreasing intracellular glutathione (GSH) levels, causing reactive oxygen species (ROS) accumulation and Akt activation. Investigating this further, we found that CagA specifically accumulated in gastric cells expressing CD44, a cell-surface marker associated with cancer stem cells. The autophagic pathway in CD44-positive gastric cancer stem-like cells is suppressed because of their resistance to ROS, which is supported by increased intracellular GSH levels. These findings provide a molecular link between H. pylori and gastric carcinogenesis through the specific accumulation of CagA in gastric cancer stem-like cells.
The vacuolating cytotoxin VacA produced by Helicobacter pylori causes massive cellular vacuolation in vitro and gastric tissue damage in vivo, leading to gastric ulcers, when administered intragastrically. Here we report that mice deficient in protein tyrosine phosphatase receptor type Z (Ptprz, also called PTP-zeta or RPTP-beta, encoded by Ptprz) do not show mucosal damage by VacA, although VacA is incorporated into the gastric epithelial cells to the same extent as in wild-type mice. Primary cultures of gastric epithelial cells from Ptprz+/+ and Ptprz-/- mice also showed similar incorporation of VacA, cellular vacuolation and reduction in cellular proliferation, but only Ptprz+/+ cells showed marked detachment from a reconstituted basement membrane 24 h after treatment with VacA. VacA bound to Ptprz, and the levels of tyrosine phosphorylation of the G protein-coupled receptor kinase-interactor 1 (Git1), a Ptprz substrate, were higher after treatment with VacA, indicating that VacA behaves as a ligand for Ptprz. Furthermore, pleiotrophin (PTN), an endogenous ligand of Ptprz, also induced gastritis specifically in Ptprz+/+ mice when administered orally. Taken together, these data indicate that erroneous Ptprz signaling induces gastric ulcers.
The study was conducted to determine expression patterns of microRNA (miRNA), a non-coding RNA that controls gene expression mainly through translational repression, in gastric mucosa infected with Helicobacter pylori. Using endoscopic biopsy specimens, miRNA expression patterns in H. pylori-infected gastric mucosa were determined by microarray. The differentially expressed miRNAs were quantitated by real-time reverse-transcriptase polymerase chain reaction (RT-PCR). An in vitro infection model was assessed to monitor the regulation of miRNAs in gastric epithelium in response to H. pylori. The comprehensive method unraveled the expression profiles; among 470 human miRNAs loaded, 55 were differentially expressed between H. pylori-positive and -negative subjects. The expression levels were significantly decreased in 30 miRNAs, whereas hsa-miRNA-223 was the only miRNA to be overexpressed on quantitative RT-PCR. Eight miRNAs enabled discrimination of H. pylori status with acceptable accuracy. Gastritis scores of activity and chronic inflammation according to the updated Sydney system correlated significantly with the expression levels of diverse miRNAs. Cure of the infection with an anti-H. pylori regimen restored decreased expression in 14 of the 30 miRNAs. Expression levels of some miRNAs, including let-7 family members, were significantly altered following infection with a virulent H. pylori strain carrying intact cag pathogenicity island including cagA but not isogenic mutants. These results provide insights into miRNA involvement in the pathogenesis of H. pylori-associated gastritis. cagA may be involved in cellular regulation of certain miRNAs in the gastric epithelium.
Monodispersed dendritic poly(L-lysine)s (DPKs) of several generations were synthesized, and their characteristics as a gene transfection reagent were then investigated. The agarose gel shift and ethidium bromide titration assay proved that the DPKs of the third generation and higher could form a complex with a plasmid DNA, and the degree of compaction of the DNA was increased by the increasing number of the generation. The DPKs of the fifth and sixth generation, which have 64 and 128 amine groups on the surface of the molecule, respectively, showed efficient gene transfection ability into several cultivated cell lines without significant cytotoxity. In addition, the transfection efficiency of the DPK of the sixth generation was not seriously reduced even if serum was added at 50% of the final concentration into the transfection medium. Because we can strictly synthesize various DPK derivatives, which have several types of branch units, terminal cationic groups, and so on, they are expected to be a good object of study regarding the basic information on the detailed mechanism of gene transfection into cells. We also expect to be able to easily construct DPK-based functional gene carriers, e.g., DPKs modified by ligands such as a sugar chain, which can enable advanced gene delivery in vivo.
The NADPH oxidase 1 (Nox1) is a gp91phox homologue preferentially expressed in the colon. We have established primary cultures of guinea pig large intestinal epithelial cells giving 90% purity of surface mucous cells. These cells spontaneously released superoxide anion (O2−) of 160 nmol/mg protein/h and expressed the Nox1, p22phox, p67phox, and Rac1 mRNAs, but not the gp91phox, Nox4, p47phox, p40phox, and Rac2 mRNAs. They also expressed novel homologues of p47phox and p67phox (p41nox and p51nox, respectively). Human colon cancer cell lines (T84 and Caco2 cells) expressed the Nox1, p22phox, p51nox, and Rac1 mRNAs, but not the other NADPH component mRNAs, and secreted only small amounts of O2− (<2 nmol/mg protein/h). Cotransfection of p41nox and p51nox cDNAs in T84 cells enhanced PMA-stimulated O2− release 5-fold. Treatment of the transfected T84 cells with recombinant flagellin (rFliC) from Salmonella enteritidis further augmented the O2− release in association with the induction of Nox1 protein. The enhanced O2− production by cotransfection of p41nox and p51nox vectors further augmented the rFliC-stimulated IL-8 release from T84 cells. T84 cells expressed the Toll-like receptor 5, and rFliC rapidly phosphorylated TGF-β-activated kinase 1 and TGF-β-activated kinase 1-binding protein 1. A potent inhibitor for NF-κB (pyrrolidine dithiocarbamate) significantly blocked the rFliC-primed increase in O2− production and induction of Nox1 protein. These results suggest that p41nox and p51nox are involved in the Nox1 activation in surface mucous cells of the colon, and besides that, epithelial cells discern pathogenicities among bacteria to appropriately operate Nox1 for the host defense.
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