Project description:Paneth cells, intestine-originated innate immune-like cells, are important for maintenance of the intestinal stem cell niche, gut microbiota, and gastrointestinal barrier. Dysfunctional Paneth cells under pathological conditions are a site of origin for intestinal inflammation. However, mechanisms underlying stress-induced Paneth cell dysregulation remains unclear. We have previously reported that deletion of SIRT1 in the intestinal epithelium (SIRT1 iKO) leads to hyperaction of Paneth cells along with an increased sensitivity to Dextran sodium sulfate (DSS)-induced colitis. We recently generated a Paneth-cell specific SIRT1 KO mouse model (SIRT1 PKO). Similar to mice with SIRT1 iKO mice, SIRT1 PKO mice had increased abundance as well as hyperactivation of Paneth cells in vivo and in cultured intestinal organoids. However, in contrast to the hypersensitivity of SIRT1 iKO mice to chemical- or age-induced inflammation, SIRT1 PKO mice were protected from Dextran sodium sulfate (DSS)-colitis.

Project description:To assess the role of LSD1 in mouse small intestinal epithelium, we grew small intestinal organoids in vitro from mice with an epithelial specific deletion of LSD1 (Villin-Cre+; Lsd1f/f) and from wild type (Villin-Cre-; Lsd1f/f) mice. This experiment uses a new Cre strain with 100% recombination efficiency. Similar to intestinal epithelium from mice with an intestinal epithelium specific LSD1-KO, Paneth cells are not present in LSD1-KO small intestinal organoids. We used these sequencing data to show intrinsic epithelial changes in the intestinal epithelium caused by LSD1 deletion in the absence of microbiota and surrounding in vivo cell types.

Project description:The intestinal epithelium, a self-renewing single-cell layer, acts as a physical barrier isolating gut microbiota from deeper tissues. In human IBD and experimental IBD mouse models, this barrier is compromised, causing microbial infiltration and inflammation. However, the pathogenesis of IBD remains to be fully understood. Our research shows that the absence of TRMT6 in the mouse gut impairs the intestinal mucosal barrier, increasing susceptibility to DSS-induced colitis. Mechanically, loss of TRMT6 in intestinal epithelial cells disrupts m¹A modification-mediated translational control and impairs MYC protein synthesis–a deficiency that inhibits epithelial cell proliferation and differentiation. Further multi-omics analyses suggest that TRMT6 deficiency may be associated with perturbations in intestinal lipid metabolism, nutrient absorption, metabolite homeostasis, and gut microbiota composition–changes that could collectively contribute to the acceleration of colitis progression. In summary, TRMT6 is crucial for maintaining small intestinal mucosal barrier function, offering insights into how its deficiency may drive gastrointestinal inflammation in IBD. Given the critical role of TRMT6 in maintaining intestinal homeostasis, our findings highlight its potential as a therapeutic target for IBD treatment.

Project description:The intestinal epithelium, a self-renewing single-cell layer, acts as a physical barrier isolating gut microbiota from deeper tissues. In human IBD and experimental IBD mouse models, this barrier is compromised, causing microbial infiltration and inflammation. However, the pathogenesis of IBD remains to be fully understood. Our research shows that the absence of TRMT6 in the mouse gut impairs the intestinal mucosal barrier, increasing susceptibility to DSS-induced colitis. Mechanically, loss of TRMT6 in intestinal epithelial cells disrupts m¹A modification-mediated translational control and impairs MYC protein synthesis–a deficiency that inhibits epithelial cell proliferation and differentiation. Further multi-omics analyses suggest that TRMT6 deficiency may be associated with perturbations in intestinal lipid metabolism, nutrient absorption, metabolite homeostasis, and gut microbiota composition–changes that could collectively contribute to the acceleration of colitis progression. In summary, TRMT6 is crucial for maintaining small intestinal mucosal barrier function, offering insights into how its deficiency may drive gastrointestinal inflammation in IBD. Given the critical role of TRMT6 in maintaining intestinal homeostasis, our findings highlight its potential as a therapeutic target for IBD treatment.

Project description:In the DSS-induced colitis model, the epithelial damage and resulting inflammation is restricted to the colon, with a potential influence on the microbial composition in the adjacent cecum. Several studies have reported changes of the gut microbiota in the DSS-induced colitis model and other mouse models of IBD. Furthermore, metaproteomics analysis of the gut microbiome in a mouse model of Crohn’s disease demonstrated that disease severity and location are microbiota-dependent, with clear evidence for the causal role of bacterial dysbiosis in the development of chronic ileal inflammation. We have developed a refined model of chronic DSS-induced colitis that reflects typical symptoms of human IBD without a risky body weight loss usually observed in DSS models [Hoffmann et al., submitted]. In this study, we used metaproteomics to characterize the disease-related changes in bacterial protein abundance and function in the refined model of DSS-induced colitis. To assess the structural and functional changes, we applied 16S rRNA gene sequencing and metaproteomics analysis of the intestinal microbiota in three different entities of the intestinal environment, i.e. colon mucus, colon content and cecum content.

Project description:Epithelial cells in the intestinal mucosa maintain gut homeostasis by interacting with different types of microbiota. Proper appropriate immune responses in the intestinal epithelium are essential for the preservation of the intestinal homeostasis. In the present study, we aimed to identify genotypic and phenotypic changes in mice following oral feeding of various substances which has been shown to differentially affect intestinal homeostasis. We orally fed C57BL/6 mice for either one or seven days with one of the four substances: dextran sulfate sodium (DSS); Typhoid VI Polysaccharide vaccine (Vi vaccine); antibiotic cocktails (AB) of ampicillin, vancomycin, neomycin, and metronidazole; or(probiotics)consisting of Lactobacillus Rhamnosus R0011and L. Acidophilus R0052.While DSS and AB feeding resulted in severe gut pathology characterized by infiltration of inflammatory cells, epithelium shedding, and distortion of paneth cells. Vi vaccine and probiotics feeding resulted in phenotypic improvement of the gut health characterized by epithelial cell proliferation and increased formation of tight junctions between epithelial cells. Interestingly, microarray data showed significant increase in the expression levels of genes regulating cell proliferation and intestinal homeostasis in the gut epithelium of probiotics-and Vi vaccine-fed mice compared to DSS-or AB-fed mice. In addition, expression levels of genes regulating cell death and inflammation were significantly increased in the gut epithelium of DSS- and AB-fed mice. These results suggest that intestinal homeostasis play a pivotal role in maintaining gut health and, subsequently, in protecting host against enteric bacteria and external pathogens infection.

Project description:Autophagy, a cytoprotective mechanism in intestinal epithelial cells, plays a crucial role in maintaining intestinal homeostasis. Beyond its cell-autonomous effects, the significance of autophagy in these cells is increasingly acknowledged in the dynamic interplay between the microbiota and the immune response. In the context of colon cancer, intestinal epithelium disruption of autophagy has been identified as a critical factor influencing tumor development. This disruption modulates the composition of the gut microbiota, eliciting an anti-tumoral immune response. Here, we report that Atg7 deficiency in intestinal epithelial cells shapes the intestinal microbiota leading to an associated limitation of colitis induced by Citrobacter rodentium infection. Mice with an inducible, intestinal epithelial-cell-specific deletion of the autophagy gene, Atg7, exhibited enhanced clearance of C. rodentium, mitigated hyperplasia, and reduced pathogen-induced goblet cell loss. This protective effect is associated with the downregulation of pro-inflammatory pathways and an increase in Th17 and Treg responses—known protective immune responses against C. rodentium infection that are influenced by specific gut microbiota. Fecal microbiota transplantation and antibiotic treatment approaches revealed that the Atg7-deficiency-shapped microbiota, especially Gram-positive bacteria, plays a central role in driving resistance to C. rodentium infection. In summary, our findings highlight that inhibiting autophagy in intestinal epithelial cells contributes to maintaining homeostasis and preventing detrimental intestinal inflammation through microbiota-mediated colonization resistance against C. rodentium. This underscores the central role played by autophagy in shaping the microbiota in promoting immune-mediated resistance against enteropathogens

Project description:The cytokine TNF drives inflammatory diseases, e.g. Crohn disease. In a mouse model of TNF-induced systemic inflammatory response syndrome (SIRS), severe impact on intestinal epithelial cells (IECs) is observed. Zinc confers complete protection in this model. We found that zinc no longer protects in animals which lack glucocorticoids (GCs), or express mutant versions of their receptor GR in IECs, nor in mice which lack gut microbiota. RNA-seq studies in IECs showed that zinc caused reduction of expression of constitutive (STAT1-induced) interferon-stimulated response (ISRE) genes and Interferon Regulatory Factor (IRF) genes. Since some of these genes are involved in TNF-induced cell death in intestinal crypt Paneth cells, and since zinc has direct effects on the composition of the gut microbiota (such as several Staphylococcus species) and on TNF-induced Paneth cell death, we postulate a new zinc-related anti-inflammatory mechanism. Zinc modulates the gut microbiota, causing less induction of ISRE/IRF genes in crypt cells, less TNF-induced necroptosis in Paneth cells and less fatal evasion of gut bacteria into the system.

Project description:The cytokine TNF drives inflammatory diseases, e.g. Crohn disease. In a mouse model of TNF-induced systemic inflammatory response syndrome (SIRS), severe impact on intestinal epithelial cells (IECs) is observed. Zinc confers complete protection in this model. We found that zinc no longer protects in animals which lack glucocorticoids (GCs), or express mutant versions of their receptor GR in IECs, nor in mice which lack gut microbiota. RNA-seq studies in IECs showed that zinc caused reduction of expression of constitutive (STAT1-induced) interferon-stimulated response (ISRE) genes and Interferon Regulatory Factor (IRF) genes. Since some of these genes are involved in TNF-induced cell death in intestinal crypt Paneth cells, and since zinc has direct effects on the composition of the gut microbiota (such as several Staphylococcus species) and on TNF-induced Paneth cell death, we postulate a new zinc-related anti-inflammatory mechanism. Zinc modulates the gut microbiota, causing less induction of ISRE/IRF genes in crypt cells, less TNF-induced necroptosis in Paneth cells and less fatal evasion of gut bacteria into the system.

Project description:The cytokine TNF drives inflammatory diseases, e.g. Crohn disease. In a mouse model of TNF-induced systemic inflammatory response syndrome (SIRS), severe impact on intestinal epithelial cells (IECs) is observed. Zinc confers complete protection in this model. We found that zinc no longer protects in animals which lack glucocorticoids (GCs), or express mutant versions of their receptor GR in IECs, nor in mice which lack gut microbiota. RNA-seq studies in IECs showed that zinc caused reduction of expression of constitutive (STAT1-induced) interferon-stimulated response (ISRE) genes and Interferon Regulatory Factor (IRF) genes. Since some of these genes are involved in TNF-induced cell death in intestinal crypt Paneth cells, and since zinc has direct effects on the composition of the gut microbiota (such as several Staphylococcus species) and on TNF-induced Paneth cell death, we postulate a new zinc-related anti-inflammatory mechanism. Zinc modulates the gut microbiota, causing less induction of ISRE/IRF genes in crypt cells, less TNF-induced necroptosis in Paneth cells and less fatal evasion of gut bacteria into the system.