Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Specific microbial signals induce the differentiation of a distinct pool of RORγ+ regulatory T cells (Tregs) crucial for intestinal homeostasis. We discovered highly analogous populations of microbiota-dependent Tregs that promote tissue regeneration at extra-gut sites, notably acutely injured skeletal muscle and fatty liver. Tissue damage elicited the emigration of RORγ+ Tregs from the gut to compromised tissues, wherein they regulated the dynamics and tenor of early inflammation and helped balance the proliferation versus differentiation of local stem cells. Reining in IL-17A-producing T cells was a major mechanism underlying these rheostatic functions. Our findings highlight the importance of gut-trained Treg emissaries in controlling the response to sterile injury of non-mucosal tissues.

Project description:Specific microbial signals induce the differentiation of a distinct pool of RORγ+ regulatory T cells (Tregs) crucial for intestinal homeostasis. We discovered highly analogous populations of microbiota-dependent Tregs that promote tissue regeneration at extra-gut sites, notably acutely injured skeletal muscle and fatty liver. Tissue damage elicited the emigration of RORγ+ Tregs from the gut to compromised tissues, wherein they regulated the dynamics and tenor of early inflammation and helped balance the proliferation versus differentiation of local stem cells. Reining in IL-17A-producing T cells was a major mechanism underlying these rheostatic functions. Our findings highlight the importance of gut-trained Treg emissaries in controlling the response to sterile injury of non-mucosal tissues.

Project description:The gut microbiota promotes distal tissue regeneration via RORγ+ regulatory T cell emissaries

Project description:The gut microbiota promotes distal tissue regeneration via RORγ+ regulatory T cell emissaries [scRNA-seq]

Project description:The gut microbiota promotes distal tissue regeneration via RORγ+ regulatory T cell emissaries [bulk RNA-seq]

Project description:The metabolic pathways encoded by the human gut microbiome constantly interact with host gene products through numerous bioactive molecules1. Primary bile acids (BAs) are synthesized within hepatocytes and released into the duodenum to facilitate absorption of lipids or fat-soluble vitamins2. Some BAs (approximately 5%) escape into the colon, where gut commensal bacteria convert them into various intestinal BAs2 that are important hormones that regulate host cholesterol metabolism and energy balance via several nuclear receptors and/or G-protein-coupled receptors3,4. These receptors have pivotal roles in shaping host innate immune responses1,5. However, the effect of this host-microorganism biliary network on the adaptive immune system remains poorly characterized. Here we report that both dietary and microbial factors influence the composition of the gut BA pool and modulate an important population of colonic FOXP3+ regulatory T (Treg) cells expressing the transcription factor RORγ. Genetic abolition of BA metabolic pathways in individual gut symbionts significantly decreases this Treg cell population. Restoration of the intestinal BA pool increases colonic RORγ+ Treg cell counts and ameliorates host susceptibility to inflammatory colitis via BA nuclear receptors. Thus, a pan-genomic biliary network interaction between hosts and their bacterial symbionts can control host immunological homeostasis via the resulting metabolites.

Project description:Exposure to environmental pollutants and human microbiome composition are important predisposition factors for tumour development1,2. Similar to drug molecules, pollutants are typically metabolized in the body, which can change their carcinogenic potential and affect tissue distribution through altered toxicokinetics3. Although recent studies demonstrated that human-associated microorganisms can chemically convert a wide range of xenobiotics and influence the profile and tissue exposure of resulting metabolites4,5, the effect of microbial biotransformation on chemical-induced tumour development remains unclear. Here we show that the depletion of the gut microbiota affects the toxicokinetics of nitrosamines, which markedly reduces the development and severity of nitrosamine-induced urinary bladder cancer in mice6,7. We causally linked this carcinogen biotransformation to specific gut bacterial isolates in vitro and in vivo using individualized bacterial culture collections and gnotobiotic mouse models, respectively. We tested gut communities from different human donors to demonstrate that microbial carcinogen metabolism varies between individuals and we showed that this metabolic activity applies to structurally related nitrosamine carcinogens. Altogether, these results indicate that gut microbiota carcinogen metabolism may be a contributing factor for chemical-induced carcinogenesis, which could open avenues to target the microbiome for improved predisposition risk assessment and prevention of cancer.

Project description:Skin allo- and xenotransplantation are the standard treatment for major burns when donor sites for autografts are not available. The relationship between the immune response to foreign grafts and their impact on wound healing has not been fully elucidated. Here, we investigated changes in collagen architecture after xenogeneic implantation of human biologic scaffolds. We show that collagen deposition in response to the implantation of human split-thickness skin grafts (hSTSGs) containing live cells recapitulates normal skin architecture, whereas human acellular dermal matrix (ADM) grafts led to a fibrotic collagen deposition. We show that macrophage differentiation in response to hSTSG implantation is driven toward regenerative Trem2+ subpopulations and found that hydrogel delivery of these cells significantly accelerated wound closure. Our study identifies the preclinical therapeutic potential of Trem2+ macrophages to mitigate fibrosis and promote wound healing, providing a novel effective strategy to develop advanced cell therapies for complex wounds.

Project description:Arrhythmias and sudden cardiac death (SCD) impose a significant burden. Their prevalence rises with age and is linked to gut dysbiosis. Our study aimed to determine whether aged gut microbiota affects arrhythmogenesis. Here, we demonstrated that arrhythmia susceptibility in aged mice could be transmitted to young mice using fecal microbiota transplantation (FMT). Mechanistically, increased intestinal reactive oxygen species (ROS) in aged mice reduced ion channel protein expression and promoted arrhythmias. Gut microbiota depletion by an antibiotic cocktail reduced ROS and arrhythmia in aged mice. Interestingly, oxidative stress in heart induced by hydrogen peroxide (H2O2) increased arrhythmia. Moreover, aged gut microbiota could induce oxidative stress in young mice colon by gut microbiota metabolites transplantation. Vitexin could reduce aging and arrhythmia through OLA1-Nrf2 signaling pathway. Overall, our study demonstrated that the gut microbiota of aged mice reduced cardiac ion channel protein expression through systemic oxidative stress, thereby increased the risk of arrhythmias.