Abstract
Infections, microbe sampling and occasional leakage of commensal microbiota and their products across the intestinal epithelial cell layer represent a permanent challenge to the intestinal immune system. The production of reactive oxygen species by NADPH oxidase is thought to be a key element of defense. Patients suffering from chronic granulomatous disease are deficient in one of the subunits of NADPH oxidase. They display a high incidence of Crohn’s disease-like intestinal inflammation and are hyper-susceptible to infection with fungi and bacteria, including a 10-fold increased risk of Salmonellosis. It is not completely understood which steps of the infection process are affected by the NADPH oxidase deficiency. We employed a mouse model for Salmonella diarrhea to study how NADPH oxidase deficiency (Cybb −/−) affects microbe handling by the large intestinal mucosa. In this animal model, wild type S. Typhimurium causes pronounced enteropathy in wild type mice. In contrast, an avirulent S. Typhimurium mutant (S.Tmavir; invGsseD), which lacks virulence factors boosting trans-epithelial penetration and growth in the lamina propria, cannot cause enteropathy in wild type mice. We found that Cybb −/− mice are efficiently infected by S.Tmavir and develop enteropathy by day 4 post infection. Cell depletion experiments and infections in Cybb −/− Myd88 −/− mice indicated that the S.Tmavir-inflicted disease in Cybb −/− mice hinges on CD11c+CX3CR1+ monocytic phagocytes mediating colonization of the cecal lamina propria and on Myd88-dependent proinflammatory immune responses. Interestingly, in mixed bone marrow chimeras a partial reconstitution of Cybb-proficiency in the bone marrow derived compartment was sufficient to ameliorate disease severity. Our data indicate that NADPH oxidase expression is of key importance for restricting the growth of S.Tmavir in the mucosal lamina propria. This provides important insights into microbe handling by the large intestinal mucosa and the role of NADPH oxidase in maintaining microbe-host mutualism at this exposed body surface.
Highlights
The intestinal immune system is capable of handling occasional breaches by the microbiota and by mucosal-invading pathogens
Typhimurium Mutant To analyze the role of NADPH oxidase in mucosal defense, we have worked in the genetic background of S
We established that NADPH oxidase deficient mice were not able to limit gut mucosa colonization and enteropathy by a normally avirulent S
Summary
The intestinal immune system is capable of handling occasional breaches by the microbiota and by mucosal-invading pathogens This is facilitated by efficient secondary barriers, such as the large number of specialized lymphoid and myeloid cells of the gutassociated immune system (e.g. Peyer’s patches and isolated lymphoid follicles) and the lamina propria (LP) of the absorptive mucosa. Commensals and pathogens which breach the epithelial layer are taken up, killed, processed and presented by diverse phagocytes, in particular by diverse mononuclear phagocyte populations and polymorphonuclear leukocytes/granulocytes (PMN). These populations are thought to play an important role in limiting bacterial loads in the LP and preventing disease. This includes the PMN and at least three different monocytic phagocyte populations, i.e. dendritic cells performing functions in antigen transport and presentation (e.g. CD11b+CD11c+CD103+CX3CR12 cells), macrophages contributing to microbe phagocytosis and elimination (e.g. CD11b+CD11c2CD1032CX3CR12 cells) and CX3CR1+ mononuclear phagocytes (e.g. CD11b+CD11c+/2CD1032CX3CR1+ cells) which are thought to facilitate luminal antigen sampling, eliciting TH1 and TH17 differentiation, and to control pro- and anti-inflammatory responses [1]
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