Project description:Coeliac disease (CeD) is a complex, polygenic inflammatory enteropathy with autoimmune features caused by exposure to dietary gluten that occurs in a subset of genetically susceptible HLA-DQ8 and HLA-DQ2 individuals. Attempts to develop a pathophysiologically relevant animal model that develops villous atrophy (VA) have failed. The need to develop non-dietary treatments for this common disorder is now widely recognized, but it is hampered by the lack of a preclinical model. Furthermore, while human studies have led to major advances in our understanding of CeD pathogenesis, direct demonstration of the respective roles of disease-predisposing HLA molecules, and adaptive and innate immunity in the development of tissue damage is missing. To address these unmet needs, we engineered a mouse model that reproduces the dual overexpression of IL-15 in the gut epithelium and the lamina propria (Lp) characteristic of active CeD, expresses the predisposing HLA-DQ8 molecule, and develops VA upon gluten ingestion. We show that overexpression of IL-15 in both the epithelium and Lp is required for development of VA, demonstrating the location-dependent central role of IL-15 in CeD pathogenesis. Furthermore, our study reveals the critical role played by both CD4+ and cytotoxic CD8+ T cells in VA development. Finally, it establishes that HLA-DQ8 is central for tissue destruction, but dispensable for loss of oral tolerance to gluten. This mouse model, by reflecting the complex interplay between gluten, genetics and the IL-15-driven tissue inflammation found in CeD, represents a powerful preclinical model to test new therapeutics and study disease pathogenesis.

Project description:In vitro models of autoimmunity are constrained by an inability to culture affected epithelium alongside the complex tissue-resident immune microenvironment. Celiac disease (CeD) is an autoimmune disease where dietary gluten-derived peptides bind the MHC- II molecules HLA-DQ2 or -DQ8 to initiate immune-mediated duodenal mucosal injury. Here, we generated air-liquid interface (ALI) duodenal organoids from endoscopic biopsies that preserve epithelium alongside native mesenchyme and tissue-resident immune cells as a unit without requiring reconstitution. The ALI organoid immune diversity spanned T, B, plasma, NK and myeloid cells with extensive T and B cell receptor repertoires. HLA-DQ2.5-restricted gluten peptides selectively instigated epithelial destruction in HLA-DQ2.5-expressing CeD patient organoids, which was antagonized by MHC-II or NKG2C/D blockade. Gluten epitopes stimulated a CeD organoid network response in lymphoid and myeloid subsets alongside anti-TG2 autoantibody production. Functional studies in CeD organoids revealed IL-7 as a novel gluten-inducible pathogenic modulator which regulated CD8+ T cell-NKG2C/D expression and was necessary and sufficient for epithelial destruction. Further, endogenous IL-7 was markedly induced in patient biopsies from active CeD versus remission disease, predominantly in lamina propria mesenchyme. By preserving epithelium alongside diverse immune populations, this human in vitro CeD model recapitulates gluten-dependent pathology, facilitates mechanistic investigation, and establishes proof-of-principle for organoid modeling of autoimmunity.

Project description:Background Celiac disease (CeD) is an autoimmune disorder triggered by gluten, with gliadin as the primary antigen. Therapies targeting gliadin to induce antigen-specific immune tolerance are of significant interest. This study investigates the therapeutic potential of a novel rapamycin-gliadin composite nanoparticle (PLN-GR) in enhancing Kupffer cell-mediated hepato-splenic dialogue to promote gluten tolerance in CeD. Methods Rapamycin-gliadin composite nanoparticles were synthesized using a precipitation self-assembly method and characterized for size, zeta potential, and cellular uptake. A CeD delayed-type hypersensitivity (DTH) mouse model was employed to evaluate the immunomodulatory effects of PLN-GR. Cellular biodistribution, immune phenotyping, and metabolic assessments were conducted to elucidate the nanoparticles' mechanism of action. Results Rapamycin-gliadin composite nanoparticles effectively targeted the liver and were internalized by Kupffer cells, inducing a tolerogenic phenotype. In vivo treatment with PLN-GR ameliorated systemic and intestinal inflammation in the CeD DTH mouse model, evidenced by reduced paw swelling and intestinal histopathology. The nanoparticles induced a metabolic shift from glycolysis to oxidative phosphorylation in macrophages, associated with increased itaconate production. This metabolic reprogramming was linked to an increase in PD-L1+ tolerogenic dendritic cells and a decrease in Th1 cell counts in the spleen. Conclusion The study demonstrates that rapamycin-gliadin nanoparticles can induce antigen-specific tolerance in CeD by modulating hepatic and splenic immune responses. The findings suggest a potential therapeutic strategy for CeD by enhancing immunometabolic reprogramming and inter-organ communication.

Project description:Celiac disease (CeD) is an immune-mediated chronic enteropathy caused by gluten exposure in HLA-DQ2 and/or -DQ8 positive individuals. The hallmarks of CeD include increased intraepithelial lymphocytes and villous atrophy. Clinically, a small subset of individuals with elevated serum tissue transglutaminase antibody (TTG) concentrations but unremarkable duodenal mucosa at initial endoscopy may progress to CeD over time. We hypothesize that these rare CeD precursor cases can allow us to interrogate histologic and molecular signatures to predict those who subsequently develop CeD, and to study the final cascade into overt lesions in CeD.

Project description:Celiac disease (CeD) is a food sensitivity characterized by a breakdown of oral tolerance to gluten proteins in genetically predisposed individuals, although the underlying mechanisms are incompletely understood. To evaluate a functional role of bacterial proteases in CeD, we colonized germ-free or clean SPF mice with P.aeruginosa PA14 or P.aeruginosa PA14 disrupted in lasB gene (elastase). We show gluten-independent, PAR-2 mediated upregulation of inflammatory pathways by LasB in C57BL/6 mice without villus blunting. In mice expressing CeD risk genes, P. aeruginosa elastase synergized with gluten to induce more severe inflammation that was associated with moderate villus blunting.

Project description:Objective Development of novel treatments for coeliac disease (CeD) is dependent on precise tools to monitor changes in gluten-induced mucosal damage. Current histology measures are subjective and difficult to standardise. Biopsy proteome scoring is an objective alternative to histology which is based on robust changes in biological pathways that directly reflect gluten-induced mucosal damage. In this study we aimed to evaluate biopsy proteome scoring as effect measure in a clinical trial setting by measuring intestinal remodeling in response to oral gluten challenge. Design We analyzed biopsies from a gluten challenge trial of treated CeD patients that consumed 3 g (n=6) or 10 g (n=7) gluten per day for 14 days. Sections from individually embedded biopsies collected before and after challenge were processed for proteome scoring (n = 109) and measurement of Vh:Cd ratio (n = 58). Proteome scores were compared to histology, intraepithelial lymphocyte (IEL) frequency and plasma interleukin-2 (IL-2). Results Change in proteome scores were significant for the group of patients who consumed 10 g gluten, but not for the group who consumed 3 g gluten. Altogether, 8 of 13 patients had changes in delta proteome scores above cut-off. Proteome scores correlated with Vh:Cd ratios both at run-in and at day 15. Proteome scores at day 15 correlated with IEL frequency and with serum IL-2 levels measured 4 hours post gluten intake. Conclusion Biopsy proteome scoring is a simple and reliable measure of gluten-induced mucosal remodeling in response to 14-day oral gluten challenge.

Project description:Coeliac Disease (CeD) is a chronic autoimmune disorder affecting 0.5-1% of the general population with a wide geographical distribution. Despite recent efforts to deeply phenotype gluten-specific immune activation at the single cell level, recent clinical studies targeting gluten degradation and other immune tolerance mechanisms have been unsuccessful. To this end, a deeper understanding of immune and non-immune cellular dynamics and interactions are required to characterize tissue-specific mechanisms responsible for CeD pathogenesis, repair, and resolution. Here, we assembled the most comprehensive scRNAseq dataset in Coeliac Disease to date, including 203,555 cells across 21 active CeD and 11 control duodenal samples. Compared to control duodenum, CeD was characterized by single cell differential changes in abundance, gene expression and cell-cell interactions across cellular compartments. In the immune compartments, CeD samples showed expected increases in plasma cell abundance and shifts toward type 1 effector biology (e.g., increase in cycling CD8pos, γδ T cells and IFNG transcriptional shifts) and Tfh-related biology (e.g., increases in IL21 signaling to effector T cells). In addition, activated myeloid subsets, including DC2 and monocytes, were increased in disease and were characterized by increased pro-inflammatory pathway expression, including IL-1β. Non-immune compartments showed increased stem/crypt and secretory enterocytes in CeD samples with a decrease in absorptive enterocytes, reflecting the villus atrophy and crypt hyperplasia hallmarks of CeD epithelial dysfunction. Accompanying the epithelial changes, distinct changes in stromal populations were identified, particularly with increases in abundance and transcriptional activity of NRG1 and SMOC2 fibroblasts. Cell-cell interaction analysis across multiple cellular compartments proposed a distinct increased role of fibroblasts to support the epithelial reprogramming of the increased stem/crypt epithelial fraction in CeD, mediated by myeloid derived IL-1β signal and lymphoid-derived IFN-γ. This dataset reveals a previously unknown role for T-myeloid-stromal-epithelial cell communication in CeD, highlighting key mechanisms of the tissue-level cellular dynamics in response to gluten ingestion.

Project description:Study of the effects of re-exposure to gliadin of intestinal biopsies from normalized celiac patients (>2 years on gluten free diet). Comparison of the expresson profile in biopsy portions incubated with 10ug/ml gliadin versus without gliadin for 4 hours.

Project description:The common gamma chain (γc) is required for productive signaling by interleukin (IL)-15, IL-21 and IL-2, which are critically involved in immune activation and regulation. IL-21 and IL-15 are implicated in the pathogenesis of type-1 diabetes, graft-versus-host disease, and celiac disease (CeD), a gluten-mediated autoimmune-like enteropathy. Attempts to treat type-1 diabetes and graft-versus-host disease with biologics targeting one particular cytokine have failed. Both IL-15 and IL-21 have been suggested to drive activation of cytotoxic T cells (CTL) that are the effectors mediating tissue destruction in CeD and organ-specific autoimmune disorders. We show that the concomitant upregulation of IL-15 and IL-21 occurs only in full-blown CeD with villous atrophy. BNZ-2, a peptide that targets the γc, was able to block the cooperative IL-15/IL-21 mediated transcriptional activation of human tissue-resident intraepithelial CTL. Importantly, this inhibition was specific and did not interfere with IL-2 signaling, a cytokine with known immunoregulatory functions. Moreover, BNZ-2 blocked gluten-induced IFN-γ production in small intestinal organ cultures from CeD patients. These observations identify BNZ-2 as a therapeutic candidate for immune disorders in which IL-15 and IL-21 cooperate to induce CTL-mediated tissue damage.

Project description:Dietary gluten proteins (prolamins) from wheat, rye, and barley are the driving forces behind celiac disease, an organ-specific autoimmune disorder that targets both the small intestine and organs outside the gut. In the small intestine, gluten induces inflammation and a typical morphological change of villous atrophy and crypt hyperplasia. Gut lesions improve and heal when gluten is excluded from the diet and the disease relapses when patients consume gluten. Oral immune tolerance towards gluten may be kept for years or decades before breaking tolerance in genetically susceptible individuals. Celiac disease provides a unique opportunity to study autoimmunity and the transition in immune cells as gluten breaks oral tolerance. Seventy-three celiac disease patients on a long-term gluten-free diet ingested a known amount of gluten daily for six weeks. A peripheral blood sample and intestinal biopsies were taken before and six weeks after initiating the gluten challenge. Biopsy results were reported on a continuous numeric scale that measured the villus height to crypt depth ratio to quantify gluten-induced gut mucosal injury. Pooled B and T cells were isolated from whole blood, and RNA was analyzed by DNA microarray looking for changes in peripheral B- and T-cell gene expression that correlated with changes in villus height to crypt depth, as patients maintained or broke oral tolerance in the face of a gluten challenge.