Project description:Inflammatory bowel diseases (IBD) in humans are characterized by chronic inflammation and gastrointestinal tissue damage, caused by a combination of genetic and environmental factors. It has been largely documented that IBD frequently lead to colorectal cancers (CRC). The identification of causative factors of IBD is thus essential to understand CRC progression and develop therapeutical approaches. Models have been described in which molecular alterations are combined with inflammatory treatments in order to recapitulate IBD-associated CRC. Here, we describe a mouse line, α6fl/fl Villin-Cre, in which inactivation of the gene encoding the integrin alpha-6 subunit (ITGA6) specifically in the intestinal mucosa results into chronic inflammation and intestinal carcinogenesis. In these mice, the loss of integrin alpha-6 beta-4, a receptor mediating the attachment of epithelial cells to laminins, leads to epithelial detachment, hyperplasia, chronic inflammation, rectal prolapses, and ultimately adenocarcinomas. Alterations of differentiation affecting mucus secreting (goblet) cells as well as changes in expression of essential intestinal transcription factors were detected. Thus alpha-6 beta-4 integrin is a key factor for the maintenance of intestinal integrity and its loss may represent a risk factor for tumor progression associated with IBD. Transcriptome analysis of RNA from normal versus inflamed and carcinomatous rectal mucosa of α6 integrin deficient intestinal epithelium mice was performed. RNAs were prepared from 5 adenocarcinomas, which were macrodissected from the rectal prolapses and 4 flanking inflamed rectal mucosa of 53-80 week-old α6fl/fl Villin-Cre mice. RNAs from normal rectal mucosa were obtained by rectum scraping from 4 matched control animals. The transcriptome analysis was performed using the Affymetrix Mouse Gene 1.0 ST arrays. Images were processed using affymetrix GeneChip® Command Console® Software (AGCC) (version 2.0) and numerical value were generated using Affymetrix Expression Console™ Software (version 1.1).

Project description:Inflammatory bowel disease (IBD) is a complex autoimmune disorder and recently shown to be associated with SUMOylation, a post-translational modification mechanism. Here we have identified a link between De-SUMOylases and tissue inflammation in IBD. SENP7, a deSUMOylase was seen to be explicitly upregulatedupregulated specifically in intestinal epithelial cells of animal model and human IBD patient samples. SENP7 expression was negatively regulated by a direct interaction and ubiquitination by SIAH2. This control was lost in inflamed cells, leading to SENP7 upregulation allowing access to a distinct SENP7 interactome revealed by complex mass-spectrometry. Furthermore, in vivo Knock-Down of SENP7 or pharmacological induction of SIAH2 abrogated DSS-induced gut inflammation. Explicitly, SENP7 upregulation led to an expansion of localized γδT cells triggering a proinflammatory environment. Strong statistical correlation between upregulated SENP7 and high clinical disease indices were observed in IBD patients. Overall our data reveal that epithelial SENP7 is necessary and sufficient in controlling gut inflammation, thus highlighting its importance as a potential drug target.

Project description:Inflammatory bowel disease (IBD) is a complex autoimmune disorder and recently shown to be associated with SUMOylation, a post-translational modification mechanism. Here we have identified a link between De-SUMOylases and tissue inflammation in IBD. SENP7, a deSUMOylase was seen to be explicitly upregulatedupregulated specifically in intestinal epithelial cells of animal model and human IBD patient samples. SENP7 expression was negatively regulated by a direct interaction and ubiquitination by SIAH2. This control was lost in inflamed cells, leading to SENP7 upregulation allowing access to a distinct SENP7 interactome revealed by complex mass-spectrometry. Furthermore, in vivo Knock-Down of SENP7 or pharmacological induction of SIAH2 abrogated DSS-induced gut inflammation. Explicitly, SENP7 upregulation led to an expansion of localized γδT cells triggering a proinflammatory environment. Strong statistical correlation between upregulated SENP7 and high clinical disease indices were observed in IBD patients. Overall our data reveal that epithelial SENP7 is necessary and sufficient in controlling gut inflammation, thus highlighting its importance as a potential drug target.

Project description:Patient-derived intestinal organoids provide an excellent tool to unravel mechanisms underlying ulcerative colitis (UC). Fresh biopsies, to isolate crypts and culture organoids, were obtained from both inflamed and non-inflamed regions from eight patients with active UC (Mayo endoscopic subscore ≥2), and from eight non-IBD controls.To address the inflammatory character of ex vivo organoids, we compared the transcriptome of biopsies, crypts and organoids derived from inflamed, and non-inflamed regions and aimed to (re-)induce inflammation ex vivo.

Project description:Inflammatory bowel diseases (IBD) in humans are characterized by chronic inflammation and gastrointestinal tissue damage, caused by a combination of genetic and environmental factors. It has been largely documented that IBD frequently lead to colorectal cancers (CRC). The identification of causative factors of IBD is thus essential to understand CRC progression and develop therapeutical approaches. Models have been described in which molecular alterations are combined with inflammatory treatments in order to recapitulate IBD-associated CRC. Here, we describe a mouse line, α6fl/fl Villin-Cre, in which inactivation of the gene encoding the integrin alpha-6 subunit (ITGA6) specifically in the intestinal mucosa results into chronic inflammation and intestinal carcinogenesis. In these mice, the loss of integrin alpha-6 beta-4, a receptor mediating the attachment of epithelial cells to laminins, leads to epithelial detachment, hyperplasia, chronic inflammation, rectal prolapses, and ultimately adenocarcinomas. Alterations of differentiation affecting mucus secreting (goblet) cells as well as changes in expression of essential intestinal transcription factors were detected. Thus alpha-6 beta-4 integrin is a key factor for the maintenance of intestinal integrity and its loss may represent a risk factor for tumor progression associated with IBD.

Project description:Epigenetic modifications play a crucial role in the pathogenesis of inflammatory bowel disease (IBD) by mediating gene–environment interactions. We previously showed that UHRF1, a central regulator of DNA methylation, contributes to cancer progression; however, its function in IBD remains poorly understood. Here, we revealed that UHRF1 is frequently reduced in inflamed tissues of IBD patients and that its deficiency exacerbates intestinal epithelial cell (IEC) damage. Through a multi-level approach incorporating human cell models and an intestinal epithelial-specific Uhrf1 knockout mouse model, we established UHRF1 as a key mitigator of IBD progression. Mechanistically, UHRF1 bound to the NPY1R promoter, promoting its methylation and leading to transcriptional suppression. The NPY1R upregulation resulting from UHRF1 deficiency attenuated cAMP–PKA–CREB signaling in IECs, thereby enhancing NF-κB activation and subsequent pro-inflammatory responses, which compromised intestinal epithelial barrier integrity. Furthermore, we identified miR-141 as a negative regulator of NPY1R, highlighting its potential as a therapeutic agent. Collectively, our results identified the UHRF1–NPY1R regulatory axis as a critical epigenetic mechanism in intestinal inflammation and underscored its dual promise for IBD diagnostics and therapy.

Project description:Epigenetic modifications play a crucial role in the pathogenesis of inflammatory bowel disease (IBD) by mediating gene–environment interactions. We previously showed that UHRF1, a central regulator of DNA methylation, contributes to cancer progression; however, its function in IBD remains poorly understood. Here, we revealed that UHRF1 is frequently reduced in inflamed tissues of IBD patients and that its deficiency exacerbates intestinal epithelial cell (IEC) damage. Through a multi-level approach incorporating human cell models and an intestinal epithelial-specific Uhrf1 knockout mouse model, we established UHRF1 as a key mitigator of IBD progression. Mechanistically, UHRF1 bound to the NPY1R promoter, promoting its methylation and leading to transcriptional suppression. The NPY1R upregulation resulting from UHRF1 deficiency attenuated cAMP–PKA–CREB signaling in IECs, thereby enhancing NF-κB activation and subsequent pro-inflammatory responses, which compromised intestinal epithelial barrier integrity. Furthermore, we identified miR-141 as a negative regulator of NPY1R, highlighting its potential as a therapeutic agent. Collectively, our results identified the UHRF1–NPY1R regulatory axis as a critical epigenetic mechanism in intestinal inflammation and underscored its dual promise for IBD diagnostics and therapy.

Project description:Objective The imbalance between Th17 cells and regulatory T cells in the gut of inflammatory bowel disease (IBD) patients promotes intestinal epithelial cell damage. In this scenario, T helper cell lineage commitment is accompanied by dynamic changes to the chromatin that facilitate, enforce or repress gene expression patterns and ultimately promote the induction and maintenance of dysregulated intestinal CD4 T cells. Design Here, we characterized the chromatin landscape and the heterogeneity of CD4 T cells from blood samples and biopsies of IBD patients using in house generated ATAC-Seq and single cell RNA-Seq libraries as well as publicly available datasets. Results We found that chromatin accessibility profiles specific to CD4 T cells from inflamed intestinal biopsies associate to inflammatory genes capable of promoting γδT, NK, T and B cell activation and proliferation. Our data show that the chromatin accessibility changes of CD4 T cells are associated with a higher predominance of pathogenic Th17 cells (pTh17 cells) in inflamed biopsies of IBD patients. In addition, we found that IBD risk loci in CD4 T cells are colocalized with accessible chromatin changes near pTh17-related genes. For instance, the IBD risk locus rs12942547 lies within an intronic STAT3 region enriched in areas of active intestinal inflammation from IBD patients. A similar profile was observed in a region near IL23R. Moreover, single cell RNA-Seq analysis of CD4 T cells from patient biopsies shows a population of CD4 T cells that resembles pTh17 cells with co-expression of Th1 and Th17 transcriptional programs, including a cytotoxic gene signature. Conclusion Altogether, our data suggest that cytotoxic pTh17 cells are associated with intestinal inflammation of IBD patients and specifically associate some IBD genetic variants with this CD4 T cell subset.

Project description:Overproduction of reactive oxygen species and antioxidant superoxide dismutases (SOD1, SOD2) dysregulation contribute to chronic inflammatory bowel disease (IBD) pathogenesis. A kinetic redox proteomic strategy (OcSILAC) was used to explore the lipopolysaccharide (LPS) effect, together with the role of the Mn1 SOD-mimic, in the intestinal HT29-MD2 cellular model. Cysteine oxidation was the main early event of LPS treatment, attenuated over 6 h, as counteracted by rapid response systems on both protein levels (SOD1, NQO1, ALDH1) and post-translational levels (oxidized peroxiredoxins), and a late preponderant increased SOD2 level. Mn1 exerted a potent antioxidant effect, limiting the LPS-induced oxidation and increasing antioxidant enzyme levels, and a variable anti-inflammatory effect attenuating the level of most of the LPS-regulated proteins. Our results reveal the multifaceted LPS effect in intestinal epithelial cells (IECs) and highlight Mn1 as a potential effective anti-oxidant and anti-inflammatory agent for IBD treatment, and a useful tool to explore the oxidation and inflammation interconnection.

Project description:Inflammatory bowel disease (IBD) is a chronic, relapsing, and remitting disease characterized by chronic inflammation in the gastrointestinal tract. The exact etiology and pathogenesis of IBD remain elusive. Although ELF-1 has been known to be highly expressed in epithelial cells for past twenty years, little is known about its function in epithelial cells and epithelial-related IBD. Here, we demonstrated that ELF-1 deficiency in mouse lead to exacerbated DSS-induced colitis, marked by inflammation dominated by neutrophil infiltration and activation of IL-17 signaling pathways in various immune cells, including Th17, ILC3, γδT and NKT cells. Bone marrow transfer experiments confirmed ELF-1 deficiency in non-hematopoietic cells intrinsically worsened DSS-induced colitis. On one hand, ELF-1 deficiency enhanced the production of pro-inflammatory chemokines in colonic epithelial cells, leading to extensive infiltration of neutrophils and other immune cells into the colonic mucosal tissue. On the other hand, ELF-1 directly regulated the expression of the Rack1 gene in colonic epithelial tissue, which has been proved to play critical roles in maintaining intestinal homeostasis. Altogether, ELF-1 plays a protective role in colitis by maintaining intestinal epithelium homeostasis.