Impaired innate immune function associated with fecal supernatant from Crohn's disease patients: insights into potential pathogenic role of the microbiome.

BACKGROUND: Although a dysbiosis of the intestinal microbiome plays a role in the pathogenesis of Crohn's disease (CD), the functional implication is unclear. We sought to determine the influence of fecal supernatant from patients with CD on innate immune function in neutrophil, macrophage, and epithelial cells. Metabolomic analysis was subsequently performed in an attempt to identify potential compounds responsible for the effects identified. METHODS: In the fecal samples from 11 pediatric patients with CD and 10 healthy controls, 16S ribosomal and metabolomic analyses were performed. We evaluated the effect of preincubation with fecal supernatant on neutrophil, macrophage, epithelial cell survival, superoxide production, bacterial invasion, and/or bactericidal function using gentamicin protection assay. Ten substances identified as most elevated in CD compared with control samples by metabolomic analysis were similarly tested for effect on bactericidal function. RESULTS: There were no statistically significant differences in microbial membership in fecal samples from patients with CD compared with healthy controls. However, bactericidal function was impaired in neutrophils and monocytes preincubated with supernatant from fecal samples from patients with CD. Although levels of many metabolites were noted to be altered in samples from patients with CD, the combination of the 10 most elevated compounds failed to demonstrate any effect on neutrophil bactericidal capacity. CONCLUSIONS: Fecal supernatant from patients with CD impairs intracellular bactericidal activity in neutrophils and macrophages. The functional consequences of the intestinal microbiome and its associated secreted products on innate immune function may be more critical than microbial membership in understanding the pathophysiology of CD.

Colitis and colon cancer in WASP-deficient mice require helicobacter species.

BACKGROUND: Wiskott-Aldrich syndrome protein-deficient patients and mice are immunodeficient and can develop inflammatory bowel disease. The intestinal microbiome is critical to the development of colitis in most animal models, in which Helicobacter spp. have been implicated in disease pathogenesis. We sought to determine the role of Helicobacter spp. in colitis development in Wiskott-Aldrich syndrome protein-deficient (WKO) mice. METHODS: Feces from WKO mice raised under specific pathogen-free conditions were evaluated for the presence of Helicobacter spp., after which a subset of mice were rederived in Helicobacter spp.-free conditions. Helicobacter spp.-free WKO animals were subsequently infected with Helicobacter bilis. RESULTS: Helicobacter spp. were detected in feces from WKO mice. After rederivation in Helicobacter spp.-free conditions, WKO mice did not develop spontaneous colitis but were susceptible to radiation-induced colitis. Moreover, a T-cell transfer model of colitis dependent on Wiskott-Aldrich syndrome protein-deficient innate immune cells also required Helicobacter spp. colonization. Helicobacter bilis infection of rederived WKO mice led to typhlitis and colitis. Most notably, several H. bilis-infected animals developed dysplasia with 10% demonstrating colon carcinoma, which was not observed in uninfected controls. CONCLUSIONS: Spontaneous and T-cell transfer, but not radiation-induced, colitis in WKO mice is dependent on the presence of Helicobacter spp. Furthermore, H. bilis infection is sufficient to induce typhlocolitis and colon cancer in Helicobacter spp.-free WKO mice. This animal model of a human immunodeficiency with chronic colitis and increased risk of colon cancer parallels what is seen in human colitis and implicates specific microbial constituents in promoting immune dysregulation in the intestinal mucosa.

Wiskott-Aldrich syndrome protein deficiency in innate immune cells leads to mucosal immune dysregulation and colitis in mice.

BACKGROUND & AIMS: Immunodeficiency and autoimmune sequelae, including colitis, develop in patients and mice deficient in Wiskott-Aldrich syndrome protein (WASP), a hematopoietic cell-specific intracellular signaling molecule that regulates the actin cytoskeleton. Development of colitis in WASP-deficient mice requires lymphocytes; transfer of T cells is sufficient to induce colitis in immunodeficient mice. We investigated the interactions between innate and adaptive immune cells in mucosal regulation during development of T cell-mediated colitis in mice with WASP-deficient cells of the innate immune system. METHODS: Naïve and/or regulatory CD4(+) T cells were transferred from 129 SvEv mice into RAG-2-deficient (RAG-2 KO) mice or mice lacking WASP and RAG-2 (WRDKO). Animals were observed for the development of colitis; effector and regulatory functions of innate immune and T cells were analyzed with in vivo and in vitro assays. RESULTS: Transfer of unfractionated CD4(+) T cells induced severe colitis in WRDKO, but not RAG-2 KO, mice. Naïve wild-type T cells had higher levels of effector activity and regulatory T cells had reduced suppressive function when transferred into WRDKO mice compared with RAG-2 KO mice. Regulatory T-cell proliferation, generation, and maintenance of FoxP3 expression were reduced in WRDKO recipients and associated with reduced numbers of CD103(+) tolerogenic dendritic cells and levels of interleukin-10. Administration of interleukin-10 prevented induction of colitis following transfer of T cells into WRDKO mice. CONCLUSIONS: Defective interactions between WASP-deficient innate immune cells and normal T cells disrupt mucosal regulation, potentially by altering the functions of tolerogenic dendritic cells, production of interleukin-10, and homeostasis of regulatory T cells.