Project description:Colonic epithelial repair is a key determinant of health. After injury, repair initiates through phenotypic reprogramming of wounded epithelium to a regenerative state permissive for the activation of alternative stem cell populations and healing. Although cytokine signals such as interferon help induce regenerative reprogramming, the signals that modify this state as the wound resolves remain largely unknown. Here we show that, during healing, the late upregulation of a cytokine receptor, tumor necrosis factor (TNF) receptor 2 (R2, TNFR2, Tnfrsf1b), clears the phenotype of regenerative signaling and restores homeostatic patterns of epithelial differentiation. Mice lacking epithelial-specific expression of TNFR2 also failed to complete colon ulcer healing, suggesting that full repair requires coordination of both regenerative and homeostatic epithelial phenotypes. In single-cell RNA-seq experiments, we find that colonic epithelial organoids grown from Tnfr2-/- mice retain a highly enriched census of progenitor cells and reduced representation of differentiated cells, consistent with TNFR2's role in promoting differentiation. These results demonstrate how epithelial cells adapt to inflammatory cues to choreograph repair.

Project description:Transcriptional profiling of microscopically laser dissected murine colonic tissue from 3 separate normal crypts, wound associated epithelium (WAE), normal epithelium, and regenerating crypts (day 6 only) at days 2,4,and 6 after colonic mucosal injury. Injury model performed as described in: H. Seno et al., Efficient colonic mucosal wound repair requires Trem2 signaling. Proc. Natl. Acad. Sci. USA 106, 256-261 (2009)

Project description:The early phase of colonic epithelial wound healing involves cellular reprogramming to a fetal-like state and reorganization of discrete crypt units into merged wound channels. After re-epithelialization is complete, a latter phase restoring homeostatic signaling and crypt patterning must occur. However, the signals that mediate this regenerative transition are unknown. Here we show that injury-associated upregulation of a cytokine receptor, tumor necrosis factor (TNF) receptor 2 (R2, TNFR2, Tnfrsf1b), suppresses fetal-like signaling and promotes crypt production. We used tissue clearing and whole-mount imaging, RNA-Seq, and organoid cultures to characterize mice with a colonic epithelial-specific deletion of TNFR2. These mice exhibited increased crypt size and reduced fission in adult homeostasis and after colitis, abnormal persistence of fetal-like molecular markers in organoids and after injury, reduced terminal differentiation, and increased proliferative potential. These results demonstrate how epithelial cells can adapt to inflammatory cues to regulate wound healing morphogenesis and signaling.

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:This study identifies a novel mechanism linking IL-17A with colon tissue repair and tumor development. Abrogation of IL-17A signaling mice attenuated tissue repair of DSS-induced damage in colon epithelium and markedly reduced tumor development in AOM/DSS model of colitis-associated cancer. The goal of these studies is to identify genes associated with IL-17RC deficiency during AOM-DSS induced tumorigenesis

Project description:Mucosal healing is associated with better clinical outcomes in patients with inflammatory bowel diseases (IBDs). Unresolved injury and inflammation, on the other hand, increases pathological fibrosis and the predisposition to cancer. Loss of Smad4, a tumor suppressor, is known to increase colitis-associated cancer in mouse models of chronic IBD. Since common biological processes are involved in both injury repair and tumor growth, we sought to investigate the effect of Smad4 loss on the response to epithelial injury. To study the injury response, an IBD mouse model of acute inflammation using dextran sulphate sodium (DSS) was used. Smad4 was knocked out only in the mouse intestinal epithelium, treated with DSS, and the early molecular and morphological response compared to its wildtype counterpart. We find that Smad4 loss alleviates pathological fibrosis and enhances mucosal repair. Transcriptomic changes specific to the epithelium indicate molecular changes that affect peri-crypt epithelial extracellular matrix (ECM), that might contribute to the enhanced mucosal repair, and in preventing the fibrotic response. We find that biological processes that promote tumor progression might facilitate the wound healing response and reduce the pathological fibrotic response to DSS. Therefore, these repair processes could be exploited, if uncoupled from the tumorigenic effect, to develop therapies that promote non-pathological wound healing and to prevent fibrosis.

Project description:Oral administration of dextran sulfate sodium (DSS) to mice induces ulceration and inflammation in the colons of mice. These changes are somewhat similar to those seen in human inflammatory bowel disease. Here we provide a full transcriptome (RNA-Seq) analysis of different gastrointestinal tissues in the regions affected by the DSS chemical, at different timepoints during the injury-inflammation-recovery cycle. The profiled regions include the distal colon (rectum), where the histological changes are most pronounced, the mid-colon, the anus, which is relatively resistant to damage, and the squamous neo-epithelium of the colon, a skin-like tissue that is found in the colon and is believed to be associated with wound healing. We find that administration of DSS is associated with upregulation of cytokines and inflammatory markers. Moreover, stem cell markers of the homeostatic colonic epithelium are depleted, consistent with reprogramming of epithelia to adopt a wound-healing phenotype. Thus, this dataset faithfully recovers broad changes in gene expression in a mouse model of inflammatory bowel disease-like damage.

Project description:Inflammatory bowel disease (IBD) is a condition characterized by severe intestinal inflammation and immune cell activation. The severity of the disease can be mitigated by compounds which activate peroxisome proliferator-activated receptor gamma (PPAR gamma), a receptor present widely in tissues involved in IBD pathogenesis. Our objective was to assess the affect of macrophage-specific deficiency of PPAR gamma on peripheral and colonic immune populations and colonic gene expression in experimental IBD. Macrophage-specific PPAR gamma-deficient mice (PPAR gamma flfl Lysozyme M Cre+) and control (PPAR gamma flfl Lysozyme M Cre-) littermates were treated with 2.5% dextran sodium sulfate (DSS) for 7 days. Disease activity was recorded daily and immune cell populations in the blood, spleen, mesenteric lymph nodes (MLN), and lamina propria were examined by flow cytometry. Colonic gene expression was assessed by real time PCR and microarray analyses. Our findings show that macrophage PPAR r-deficiency significantly exacerbates DSS inflammation. CD4+CD25+FoxP3+ regulatory T cells (T-regs) were significantly reduced in Cre+ mice, and MLN macrophages and CD40 expression were enhanced. There were significant differences in the number colonic macrophages between Cre+ and Cre- mice, but those from Cre+ mice expressed more CD40, Ly6C, and TLR-4. PPAR r-deficiency also increased the percent of CD8+ T cells in the lamina propria and enhanced colonic interferon gamma expression. Our findings indicate that macrophage PPAR gamma deficiency augments the severity of DSS colitis by reducing peripheral T-regs and increasing colonic macrophage activation and T cell inflammation. RNA from 3 PPAR gamma-deficient mice (PPAR gamma flfl; Lysozyme M Cre+) and 3 control (PPAR gamma flfl; Lysozyme M Cre-) littermates was processed and labeled according to the standard target labeling protocols. The samples were hybridized, stained, and scanned per standard Affymetrix protocols at the Virginia Bioinformatics Institute (VBI) core laboratory on Mouse 430 2.0 expression arrays (Affymetrix Inc., Santa Clara, CA).

Project description:Regeneration is the “holy grail” of tissue repair, but skin injury typically yields fibrotic, non-functional scars. Developing pro-regenerative therapies requires rigorous understanding of the molecular progression from injury to fibrosis or regeneration. Here, we report the divergent molecular events driving skin wound cells toward either scarring or regenerative fates. We profile scarring versus YAP inhibition-induced wound regeneration at the transcriptional (single-cell RNA-sequencing), protein (timsTOF proteomics), and tissue (extracellular matrix ultrastructural analysis) levels. Using cell surface barcoding, we integrate these data to reveal fibrotic and regenerative “molecular trajectories” of healing. We show that disrupting YAP mechanical signaling yields regenerative repair orchestrated by fibroblasts with activated Trps1 and Wnt signaling. Finally, by performing in vivo gene knockdown and overexpression in wounds, we identify Trps1 as a key regulatory gene that is necessary and partially sufficient for wound regeneration. Our findings serve as a multimodal map of wound regeneration and could have therapeutic implications for pathologic fibroses.

Project description:Inflammatory bowel disease (IBD) is a condition characterized by severe intestinal inflammation and immune cell activation. The severity of the disease can be mitigated by compounds which activate peroxisome proliferator-activated receptor gamma (PPAR gamma), a receptor present widely in tissues involved in IBD pathogenesis. Our objective was to assess the affect of macrophage-specific deficiency of PPAR gamma on peripheral and colonic immune populations and colonic gene expression in experimental IBD. Macrophage-specific PPAR gamma-deficient mice (PPAR gamma flfl Lysozyme M Cre+) and control (PPAR gamma flfl Lysozyme M Cre-) littermates were treated with 2.5% dextran sodium sulfate (DSS) for 7 days. Disease activity was recorded daily and immune cell populations in the blood, spleen, mesenteric lymph nodes (MLN), and lamina propria were examined by flow cytometry. Colonic gene expression was assessed by real time PCR and microarray analyses. Our findings show that macrophage PPAR r-deficiency significantly exacerbates DSS inflammation. CD4+CD25+FoxP3+ regulatory T cells (T-regs) were significantly reduced in Cre+ mice, and MLN macrophages and CD40 expression were enhanced. There were significant differences in the number colonic macrophages between Cre+ and Cre- mice, but those from Cre+ mice expressed more CD40, Ly6C, and TLR-4. PPAR r-deficiency also increased the percent of CD8+ T cells in the lamina propria and enhanced colonic interferon gamma expression. Our findings indicate that macrophage PPAR gamma deficiency augments the severity of DSS colitis by reducing peripheral T-regs and increasing colonic macrophage activation and T cell inflammation.