Project description:Oral eubiosis is of utmost importance for local and systemic health. Consolidated habits, as excessive alcohol consumption, smoke, inappropriate oral hygiene, and western diet, exert detrimental effects on oral microbiota composition and function. This leads to caries, gingivitis, and periodontitis, also increasing the risk of preterm births, inflammation, and cancer. Thus, effective tools to contain pathobiont overgrowth and virulence and restore oral eubiosis are needed. Therefore, the effects of Limosilactobacillus reuteri LRE11, Lacticaseibacillus rhamnosus LR04, Lacticaseibacillus casei LC04, and their co-culture cell-free supernatants (CFSs), produced in both conventional MRS medium and a novel animal derivative-free medium named TIL, along with vitamin D, were assessed on the viability and interleukin (IL)-6 production of oral epithelial FaDu cells infected with Aggregatibacter actinomycetemcomitans, Fusobacterium nucleatum, and Porphyromonas gingivalis. The CFS proteomic, short chain fatty acid, and lactic acid contents were also investigated. Interestingly, probiotic CFSs and vitamin D differentially reduced the infected cell IL-6 production and counteracted the infection-induced cytotoxicity. Taken together, these results suggest that probiotics and vitamin D can reverse pathogen-induced cell damage. Since probiotic CFS effect is both strain and growth medium composition dependent, further experiments are required to deepen the probiotic and vitamin D synergic activity in this context.

Project description:The gut microbiota and its metabolites critically regulate immune cell phenotype, function, and energy metabolism. We screened a collection of gut microbiota-related metabolites to identify modulators of mitochondrial metabolism in T cells. Here, we show that indole-3-propionic acid (IPA) stimulates mitochondrial respiration of CD4+ T cells by increasing the oxidation of fatty acids and amino acids (FAO and AAO), while inhibiting glycolytic capacity. IPA also impacts CD4+ T cell behavior by inhibiting their differentiation to TH1 and TH17 phenotypes. Mechanistically, the metabolic and immune effects of IPA are mediated by Peroxisome Proliferator-Activated Receptor-beta/delta. The administration of IPA rescues mitochondria respiration in mice with gut bacteria depletion or colitis by enhancing FAO and AAO in colonic CD4+ T cells. Adoptive transfer experiments show that IPA acts on CD4+T cells to exert its protective effect against inflammation. Collectively, our study reveals that the anti-inflammatory effects of IPA are mediated by metabolic reprogramming of CD4+ T cells toward the enhancement of mitochondrial respiration.

Project description:While fermentable oligo- and di-, mono-saccharides and polyols (FODMAPs) have been implicated in exacerbating inflammatory bowel disease (IBD) symptoms, the exact influence of FODMAPs on gut microbiota and inflammation is unclear. Here, we show that sorbitol, a polyol, exacerbates colitis in mice induced by dextran sodium sulfate (DSS). Sorbitol increases the expression of inflammatory genes including Il1b in the colon, associated with M1 macrophage-related genes elevated in IBD patients. Indeed, sorbitol treatment leads to a higher proportion of M1 macrophages in the colon, worsening colitis, which is reversed in IL-1β-deficient mice and mitigated with antibiotic treatment. Sorbitol alters the composition of gut microbiota and metabolites, with Prevotellaceae and tryptamine positively correlated with colonic M1 macrophages. Tryptamine stimulation enhances M1 macrophage polarization. Taken together, polyol consumption activates intestinal macrophages by altering the gut microbiome, which in turn promotes intestinal inflammation.

Project description:Approximately 80% of patients with Primary Sclerosing Cholangitis (PSC) also have an underlying Inflammatory Bowel Disease (IBD). Notably, PSC-IBD presents a unique phenotype compared to Ulcerative Colitis or Crohn’s Disease alone , which may increase the risk of colitis-associated neoplasia. This case-control study comprises a cohort of 15 patients in the PSC-IBD group, 30 patients in the IBD-alone group, and 19 patients in the control group. Through the analysis of patient serum and colon tissue proteomics, colon gene expression, fecal gut microbiota, and in vitro data with human monocytes, we identified a specific interplay between systemic circulation and gut microbiota dysbiosis that may predispose PSC-IBD patients to neoplasia development. Our study revealed that PSC-IBD patients show a shift in gut microbiota towards an increase in Intestinibacter, a bacterium known to exacerbate IBD conditions.Interestingly, when comparing the PSC-IBD group to the IBD-alone group, we observed elevated miR-21 expression levels in fasting serum and stool samples. Finally, we partially reproduce the inflammatory PSC-IBD profile using miR-21 and bile acid GCDCA stimulus in human-derived monocytes. Our findings suggest that circulating miR-21, along with bile acid GCDCA, tissue macrophage recruitment, and distinct microbiota profiles, may contribute to the unique phenotype of IBD in PSC patients.

Project description:Microbial dysbiosis has been identified in adult inflammatory bowel disease (IBD) patients. However, microbial composition and functional interplay between host genetics and microorganisms in early IBD onset remain poorly defined. Here, we identified and demonstrated the causal effect of Atopobium parvulum and the gut microbiota in pediatric IBD. Microbiota and proteomic profiling revealed that the abundance of A. parvulum, a potent H2S producer, was associated with increased disease severity and a concurrent reduction in the expression of the host H2S detoxification pathway. In the Il10-/- mouse model of inflammation, A. parvulum induced severe pancolitis that was dependent on the presence of the gut microbiota. In addition, we demonstrated that administration of bismuth, an H2S scavenger, prevented A. parvulum-induced colitis. Our findings identified Atopobium parvulum as a major mediator of inflammation severity, and revealed an alteration of the balance between the production and detoxification of H2S in the gastrointestinal tract.

Project description:Hyperactive TLR7 signaling has long been appreciated as a driver of autoimmune disease in mouse models by breaking tolerance to self-nucleic acids1-5. Recently, the first monogenic mutations within TLR7 or its associated regulator Unc93b16,7 have been identified as causative agents of human lupus. The unifying feature of these mutations is TLR7 gain-of-function resulting from increased ligand binding. TLR7 is an intracellular transmembrane receptor, localized to late endosomes, that senses RNA breakdown products within these hydrolytic compartments8,9. Hence, its function depends on a complex interplay between specialized organelles, transport mechanisms and membrane interactions. Whether perturbations of any of these endosome-related processes can give rise to TLR7 gain-of-function and facilitate self-reactivity has not been investigated. Here we show that a dysregulated endosomal compartment can result in TLR7 gain-of-function and lupus disease in humans. Mechanistically, the late endosomal protein complex BORC-Arl8b controls TLR7 protein levels by mediating the receptor's final sorting step towards lysosomal degradation. A direct interaction between Arl8b and Unc93b1 is required to regulate the turnover of TLR7. We identified an amino acid insertion in Unc93b1 in a patient with childhood-onset lupus, which results in loss of interaction with the BORC-Arl8b complex and an accumulation of functional TLR7. Our results highlight the importance of an intact endomembrane system to prevent autoimmune disease. Disrupting the proper progression of TLR7 through its endocytic life cycle is sufficient to break immunological tolerance to nucleic acids. Our work expands the repertoire of cellular mechanisms important to restrict pathological TLR7 activity. Identifying and stratifying lupus patients based on a TLR7-driven pathology opens the way for precision medicine specifically targeting TLR7.

Project description:Colitis-associated colorectal cancer (CAC) is a serious complication of inflammatory bowel disease (IBD) with complex etiology involving chronic inflammation, immune dysregulation, and gut microbiota dysbiosis. Creatine, a natural nitrogenous com-pound, possesses anti-inflammatory and immunomodulatory properties, but its role in CAC remains unclear.We established an AOM/DSS-induced mouse model of CAC and supplemented mice with creatine. We assessed the effects of creatine on colitis severity, tumor burden, and histopathology. Additionally, we investigated the impact of crea-tine on gut barrier function, macrophage polarization, and gut microbiota composi-tion.Creatine supplementation significantly alleviated DSS-induced colitis, reduced tumor burden, and delayed CAC progression in mice. Mechanistically, creatine im-proved gut barrier function by protecting tight junction proteins from degradation in-duced by the modeling stimulus，influenced macrophage polarization, and main-tained gut microbiota diversity, promoting the abundance of beneficial bacteria while reducing harmful ones.Our findings suggest that creatine supplementation may rep-resent a promising supportive therapy for IBD and CAC by modulating the gut micro-biota and immune microenvironment. Further investigation is warranted to explore the clinical potential of creatine in the management of CAC.

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:Studying host-microbiota interactions is fundamental to understand mechanisms involved in intestinal inflammation and inflammatory bowel diseases. In this work, we studied these interactions in mice mono-associated with 4 bacteria and 2 yeasts, all representative of intestinal microbiota and/or associated with IBD pathogenesis: Bacteroides thetaiotaomicron, adhesive-invasive Escherichia coli (AIEC), Ruminococcus gnavus, Roseburia intestinalis, Saccharomyces boulardii and Candida albicans. Transcriptomics analyses showed that B. thetaiotaomicron had the highest immunological effect, being able to almost recapitulate the effects of a whole microbiota, and particularly induced Treg pathways. Furthermore, this analysis also pointed out the effects of E. coli AIEC LF82 on IDO activation and of S. boulardii on angiogenesis, as well as major effects of R. gnavus on metabolism. This work therefore reveals information on the role of each micro-organism and proposes several tracks to follow to better understand IBD pathogenesis and identify therapeutic targets  6 mono-associations + 2 controls (germ-free and conventionalized mice), with 5 to 7 mice per group.

Project description:To elucidate the mechanism by which USP26 dictates HCC tumorigenesis, we attempted to identify the protein associated with USP26 using a triple-epitope (S-protein, FLAG tag and streptavidin binding peptide)-tagged version of USP26 (SFB-USP26). Tandem affinity purification followed by mass spectrometric analysis identified several strong interactors of USP26.