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:Inflammatory bowel disease (IBD) relates to gut microbiota dysbiosis, bile acid (BA) disturbance and intestinal barrier impairment. We purified a fructose-dominant (Fru 93.63%) low-molecular-weight Polygonatum sibiricum polysaccharide (PSP). In 3% DSS-induced colitis in C57BL/6 mice, PSP (400 mg/kg/day) alleviated symptoms. Multi-omics showed PSP reversed DSS-induced disorders, regulated BA biosynthesis, restored barrier function and mitigated colitis, supporting its IBD intervention potential.

Project description:Inflammatory bowel disease (IBD) results from a dysregulated interaction between the microbiota and a genetically susceptible host. Genetic studies have linked TNFSF15 polymorphisms and its protein TNF-like ligand 1A (TL1A) with IBD, but the functional role of TL1A in linking tissue homeostasis and intestinal inflammation is not known. Here, using cell-specific genetic deletion models, we report an essential role for CX3CR1+ mononuclear phagocyte (MNP)-derived TL1A, which is induced by adherent IBD-associated microbiota, in regulating group 3 innate lymphoid cell (ILC3) production of IL-22 and mucosal healing in acute colitis. However, in contrast to this protective role in acute colitis, TL1A-dependent expression of OX40L in MHCII+ ILC3 during colitis leads to co-stimulation of antigen-specific T cells and is required for chronic T cell colitis. These results identify a new role for ILC3 in regulating intestinal T cells and reveal a central role for TL1A in regulating ILC3 barrier immunity during colitis.

Project description:Inflammatory bowel disease (IBD) encompasses a spectrum of complex intestinal disorders characterized by dysregulated host innate and adaptive immune responses to gut microbiota in genetically susceptible hosts. We generated an integrated single-cell (scRNA-seq, scTCR-seq, and scBCR-seq) resource dataset that revealed key cellular components and cell states of the gastrointestinal mucosal and peripheral immune systems in health and ulcerative colitis (UC).

Project description:Background & Aims: The complex interactions between diet and the microbiota that influence mucosal inflammation and inflammatory bowel disease are poorly understood. Experimental colitis models provide the opportunity to control and systematically perturb diet and the microbiota in parallel to quantify the contributions between multiple dietary ingredients and the microbiota on host physiology and colitis. Methods: To examine the interplay of diet and the gut microbiota on host health and colitis, we fed over 40 different diets with varied macronutrient sources and concentrations to specific pathogen free or germ free mice either in the context of healthy, unchallenged animals or dextran sodium sulfate colitis model. Results: Diet influenced physiology in both health and colitis across all models, with the concentration of protein and psyllium fiber having the most profound effects. Increasing dietary protein elevated gut microbial density and worsened DSS colitis severity. Depleting gut microbial density by using germ-free animals or antibiotics negated the effect of a high protein diet. Psyllium fiber influenced host physiology and attenuated colitis severity through microbiota-dependent and microbiota-independent mechanisms. Combinatorial perturbations to dietary protein and psyllium fiber in parallel explain most variation in gut microbial density, intestinal permeability, and DSS colitis severity, and changes in one ingredient can be offset by changes in the other. Conclusions: Our results demonstrate the importance of examining complex mixtures of nutrients to understand the role of diet in intestinal inflammation. Keywords: IBD; Diet; Microbiota; Mouse Models; Systems Biology

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:The postnatal period is one of the important windows for developing the gastrointestinal tract's structure-function and associated mucosal immunity. Recent studies suggest a promising contribution of gut microbiota in maintaining host health, immunity, and gut development. However, the function of postnatal gut microbiota dynamics concerning intestinal mucosal development needs to be better understood. To decipher the causal role of gut microbiota on barrier integrity and intestinal epithelium development, we executed an antibiotic-mediated perturbation and tracked the kinetics in postnatal mice. We observed a postnatal age-related impact of antibiotic-mediated gut microbiota perturbation with a substantial decrease in total bacterial load on P14D and also in the barrier integrity and IECs marker. To enhance our knowledge of the mechanisms behind this, we employed a global transcriptomics approach to see the alterations in the mucosal innate immunity and other relevant pathways.

Project description:Gut dysbiosis is closely involved in the pathogenesis of inflammatory bowel disease (IBD). However, it remains unclear whether IBD-associated gut dysbiosis plays a primary role in disease manifestation or is merely secondary to intestinal inflammation. Here, we established a humanized gnotobiotic (hGB) mouse system to assess the functional role of gut dysbiosis associated with two types of IBD - Crohn's disease (CD) and ulcerative colitis (UC). In order to explore the functional impact of dysbiotic microbiota in IBD patients on host immune responses, we analyzed gene expression profiles in colonic mucosa of hGB mice colonized with healty (HC), CD, and UC microbiota.

Project description:The intestinal epithelial barrier plays a critical role in the mucosal immunity. However, it remains largely unknown how the epithelial barrier is maintained after damage. Here we show that FGF2 synergizes with IL-17A to induce genes for repairing of damaged epithelium. Deficiency of FGF2 or IL-17A resulted in impaired epithelial proliferation, increased pro-inflammatory microbiota outgrowth, and consequently worse pathology in a DSS-induced colitis model.

Project description:Background and Aims: We have shown in several controlled rat and human infection studies that dietary calcium improves intestinal resistance and strengthens the mucosal barrier. Reinforcement of gut barrier function is also relevant for inflammatory bowel disease (IBD). Therefore, we investigated the effect of supplemental calcium on spontaneous colitis development in HLA-B27 transgenic rats, an experimental animal model of IBD. Methods: HLA-B27 transgenic rats were fed a purified high-fat diet containing either a low or high calcium content (30 and 120 mmol CaHPO4/kg diet, respectively) for almost 7 weeks. Inert chromium ethylenediamine-tetraacetic acid (CrEDTA) was added to the diets to quantify intestinal permeability by measuring urinary CrEDTA excretion. Relative fecal dry-weight was determined to quantify diarrhea. Colonic inflammation was determined histologically, and by measuring mucosal interleukin-1β. In addition, colonic mucosal gene expression of individual rats was analyzed, using whole genome microarrays. Interesting results were verified by Q-PCR. Results: The high-calcium diet significantly prevented the increase in intestinal permeability and diarrhea with time in HLA-B27 rats developing colitis as compared to the low-calcium group. The histological colitis score and mucosal interleukin-1β levels were lower in high-calcium fed rats. Supplemental calcium prevented the colitis-induced increase in the expression of extracellular matrix remodeling genes (e.g. matrix metalloproteinases, procollagens and fibronectin), which was confirmed by Q-PCR. Conclusions: Dietary calcium inhibits colitis development in HLA-B27 transgenic rats. Calcium prevents the colitis-related increase in intestinal permeability, diminishes diarrhea, and lowers the inflammatory response in the mucosa, resulting in less extracellular matrix breakdown. Keywords: nutritional intervention