Project description:Desmosomes play an underexplored role in intestinal homeostasis and are linked to the pathogenesis of inflammatory bowel diseases. We found a novel function of the desmosomal plaque protein Plakoglobin (JUP) in initiating the innate immune response to facilitate intestinal inflammation. Tissue samples from Crohn’s disease (CD) patients revealed a loss of JUP, which was mirrored in a mouse model of dextran sodium sulfate-induced (DSS) colitis. Inducible intestinal epithelial-specific knock-out of Jup (iVilCreERT2Jupfl/fl) in mice resulted in increased submucosal infiltration of macrophages and neutrophils, along with activation of the inflammasome. This was paralleled by p38MAPK phosphorylation, while loss of intestinal epithelial barrier function was absent. In DSS-colitis, epithelial Jup-deficiency impaired recovery and enhanced IL23/IL17-signaling. Intestinal organoids lacking Jup demonstrated NLRP1 inflammasome activation, indicated by increased IL1β and IL18 levels, which was attenuated by p38MAPK inhibition. In silico analysis and co-immunoprecipitation confirmed a direct interaction between JUP and p38MAPK, revealing a regulatory mechanism where JUP limits inflammasome signaling in intestinal epithelial cells. These effects were blunted by NLRP1/3 inhibitor ADS032. These findings identify JUP as a critical modulator of epithelial innate immunity in the gut. The loss of JUP in tissues from CD patients underscores its potential relevance in disease pathology.

Project description:Investigation of microbial community composition in mouse models using an intestinal epithial-specific and inducible VilCreERT2-mediated conditional knockout of Jup under basal conditions and in acute dextran-sodium sulfate (DSS)-induced colitis We investigated the gut microbiome composition in a dextran sulfate sodium (DSS) colitis model using Jupfl/fl and iVilCreERT2Jupfl/fl mice. Fecal samples were collected after DSS treatment, and 16S rRNA sequencing was employed to analyze microbial communities. Our findings revealed no significant differences in microbial profiles between Jupfl/fl and iVilCreERT2Jupfl/fl under DSS treatment.

Project description:Purpose: PKM2-mediated metabolic switch to aerobic glycolysis plays a critical role in promoting cell survival and proliferation. However, little is known about the function of intestinal epithelial PKM2 in intestinal homeostasis. Here we investigated whether and how intestinal epithelial PKM2 modulates the morphology and function of the adult intestine in experimental murine colitis. Methods: Colonoscopic biopsies from the Crohn’s disease (CD) and ulcerative colitis (UC) patients (10 each) were analyzed for PKM2 expression. We also generated intestinal epithelial-specific Pkm2 knockout mice and employed them to examine PKM2 function. Mouse intestinal inflammation was induced with dextran sulfate sodium (DSS) in drinking water. Disease phenotypes were investigated by mouse survival, body weight, colon length and analysis of immune cell infiltration in colon, intestinal epithelial cell gene profiling and signal pathway. Results: Intestinal epithelial PKM2 level in UC and CD patients was significantly decreased compared to that from non-inflamed intestinal epithelium. Similar reduction of intestinal epithelial PKM2 was observed in mice with experimental colitis. Supporting the notion that PKM2 serves as a safeguard against colitis, intestinal epithelial-specific Pkm2-deficient (Pkm2-/-) mice displayed a severer intestinal inflammation, companying with shortened colon, disruption of epithelial tight junction, higher permeability, elevation of inflammatory cytokines and immune cell infiltration, compared with wild-type mice. Gene profiling and western blot analysis indicated that cell survival signaling, particularly the Akt/β-catenin pathways, were downregulated in Pkm2-/- mice. Functional assay using mouse primary colonic epithelial cells confirmed that Pkm2 reduction decreased proliferation and migration of epithelial cells, while enhanced expression of Pkm2 was associated with increased transcriptional activity of β-catenin. Moreover, increasing mouse intestinal epithelial Pkm2 expression via delivery of Pkm2-expressing plasmid attenuated DSS-induced experimental colitis. Conclusions: Intestinal epithelial PKM2, through activating Wnt/β-catenin signaling, induces a strong proliferative and migratory response that increases cell survival and wound healing under colitic condition.

Project description:Inflammatory caspases are essential effectors of inflammation and cell death. Here, we investigated their roles in colitis and colorectal cancer and report a bimodal regulation of intestinal homeostasis, inflammation and tumorigenesis by caspases-1 and -12. Casp1-/- mice exhibited defects in mucosal tissue repair and succumbed rapidly after dextran sulfate sodium (DSS) administration. This phenotype was rescued by administration of exogenous interleukin-18 and was partially reproduced in mice deficient in the inflammasome adaptor ASC. Casp12-/- mice, in which the inflammasome is derepressed, were resistant to acute colitis and showed signs of enhanced repair. Together with their increased inflammatory response, the enhanced repair response of Casp12-/- mice rendered them more susceptible to colorectal cancer induced by azoxymethane (AOM)+DSS. Taken together, our results indicate that the inflammatory caspases are critical in the induction of inflammation in the gut following injury, which is necessary for tissue repair and maintenance of immune tolerance. Total RNA obtained from isolated tumors or normal colon tissue from wild type and caspase-12 deficient mice were compared.

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:To determine how deficiency of Efhd2 in intestinal epithelial cells aggravates DSS-induced colitis in mice, we performed a transcriptional analysis.

Project description:STAT3 is a pleiotropic transcription factor with important functions in cytokine signalling in a variety of tissues. However, the role of STAT3 in the intestinal epithelium is not well understood. Here we demonstrate that development of colonic inflammation is associated with the induction of STAT3 activity in intestinal epithelial cells (IEC). Studies in genetically engineered mice showed that epithelial STAT3 activation in DSS colitis is dependent on IL-22 rather than IL-6. IL-22 was secreted by colonic CD11c+ cells in response to Toll-like receptor stimulation. Conditional knockout mice with an IEC specific deletion of STAT3 activity were highly susceptible to experimental colitis, indicating that epithelial STAT3 regulates gut homeostasis. STAT3IEC-KO mice, upon induction of colitis, showed a striking defect of epithelial restitution. Gene chip analysis indicated that STAT3 regulates the cellular stress response, apoptosis and pathways associated with wound healing in IEC. Consistently, both IL-22 and epithelial STAT3 were found to be important in wound-healing experiments in vivo. In summary, our data suggest that intestinal epithelial STAT3 activation regulates immune homeostasis in the gut by promoting IL-22-dependent mucosal wound healing. 4 samples of colon epithelium were analyzed from 4 mice (2 per group Stat3flfl VillinCre- and Stat3flfl VillinCre+, respectively) after they had been treated with DSS (2.5%) for 5 days

Project description:The danger signals that activate the NLRP1 inflammasome have yet to be firmly established. NLRP1 undergoes autoproteolysis to generate N-terminal (NT) and C-terminal (CT) fragment, which importantly, is a necessary step for its check-point regulation by the DPP9 ternary complex and the mechanistic activation of NLRP1 through functional degradation. Here, we report an added layer of regulatory complexity to NLRP1 activity, in the form of a repressive interaction that NLRP1 forms with the oxidized, but not reduced, form of thioredoxin-1 (TRX1). Loss of TRX1 destabilizes the NT fragment of NLRP1 and promotes enhanced inflammasome activation. The TRX1 interaction occurs through the NACHT-LRR of NLRP1 and requires nucleotide binding in its ATPase domain. In addition, we found that several patient-derived and ATPase-inactivating mutations in the NACHT-LRR region hyperactive the inflammasome by destabilize protein folding and are also shown to abrogate TRX1 binding. Thus, NLRP1 appears to detect intracellular reductive stress through a decrease in the fraction of intracellular oxidized TRX1, which enhances protein disorder, leading to inflammasome signaling. These findings link the cellular redox environment to NLRP1-mediated innate immunity.

Project description:The danger signals that activate the NLRP1 inflammasome have yet to be firmly established. NLRP1 undergoes autoproteolysis to generate N-terminal (NT) and C-terminal (CT) fragment, which importantly, is a necessary step for its check-point regulation by the DPP9 ternary complex and the mechanistic activation of NLRP1 through functional degradation. Here, we report an added layer of regulatory complexity to NLRP1 activity, in the form of a repressive interaction that NLRP1 forms with the oxidized, but not reduced, form of thioredoxin-1 (TRX1). Loss of TRX1 destabilizes the NT fragment of NLRP1 and promotes enhanced inflammasome activation. The TRX1 interaction occurs through the NACHT-LRR of NLRP1 and requires nucleotide binding in its ATPase domain. In addition, we found that several patient-derived and ATPase-inactivating mutations in the NACHT-LRR region hyperactive the inflammasome by destabilize protein folding and are also shown to abrogate TRX1 binding. Thus, NLRP1 appears to detect intracellular reductive stress through a decrease in the fraction of intracellular oxidized TRX1, which enhances protein disorder, leading to inflammasome signaling. These findings link the cellular redox environment to NLRP1-mediated innate immunity.

Project description:The goal of this project is to investigate the mechanisms through which high fat diet (HFD) exacerbates colitis via the liver-gut axis, particularly focusing on liver dysregulated lipid metabolism and intestinal autophagy. We examined liver transcriptomes of C57BL6/J mice fed a control diet (CD) or HFD with or without dextran sulfate sodium (DSS) by RNA seq analysis.