Project description:Group 3 innate lymphoid cells (ILC3) are composed of NCR- and NCR+ subsets located at mucosal sites exposed to billions of commensal microbes and potentially harmful pathogens. Together with T cells, the various ILC3 subsets maintain the balance between homeostasis and immune activation. Using genetic mapping, we reveal here the existence of a new subset of NCR- ILC3 transiently expressing Ncr1 but strongly related to unlabeled NCR- ILC3, demonstrating previously unsuspected heterogeneity within the NCR- ILC3 population. Notch signaling is required for the differentiation of NCR- ILC3 into NCR+ ILC3. However, we show here that Notch signaling must be sustained for the maintenance of the NCR+ phenotype and that TGF-β impairs the development of NCR+ ILC3. Thus, ILC3 diversity and the plasticity of the NCR- and NCR+ subsets is regulated by the balance between the opposing effects of Notch and TGF-β signaling, maintaining homeostasis in the face of continual challenges. Transcriptional profiling of three ILC subsets (NCR-FM-, NCR-FM- and NCR+FM+) using RNA sequencing

Project description:Group 3 innate lymphoid cells (ILC3) are composed of NCR- and NCR+ subsets located at mucosal sites exposed to billions of commensal microbes and potentially harmful pathogens. Together with T cells, the various ILC3 subsets maintain the balance between homeostasis and immune activation. Using genetic mapping, we reveal here the existence of a new subset of NCR- ILC3 transiently expressing Ncr1 but strongly related to unlabeled NCR- ILC3, demonstrating previously unsuspected heterogeneity within the NCR- ILC3 population. Notch signaling is required for the differentiation of NCR- ILC3 into NCR+ ILC3. However, we show here that Notch signaling must be sustained for the maintenance of the NCR+ phenotype and that TGF-β impairs the development of NCR+ ILC3. Thus, ILC3 diversity and the plasticity of the NCR- and NCR+ subsets is regulated by the balance between the opposing effects of Notch and TGF-β signaling, maintaining homeostasis in the face of continual challenges.

Project description:Group 3 innate lymphoid cells (ILC3) are major regulators of inflammation, infection, microbiota composition and metabolism. ILC3 and neuronal cells were shown to interact at discrete mucosal locations to steer mucosal defence. Nevertheless, whether neuroimmune circuits operate at an organismal level, integrating extrinsic environmental signals to orchestrate ILC3 responses remains elusive. Here we show that light-entrained and brain-tuned circadian circuits regulate enteric ILC3, intestinal homeostasis and the host lipid metabolism. We found that enteric ILC3 display circadian expression of clock genes and ILC3-related transcription factors. ILC3-autonomous ablation of the circadian regulator Arntl led to disrupted gut ILC3 homeostasis, impaired epithelial reactivity, deregulated microbiome, increased susceptibility to bowel infection and disrupted lipid metabolism. Loss of ILC3-intrinsic Arntl shaped the gut postcode receptors of ILC3. Strikingly, light-dark cycles, feeding rhythms and microbial cues differentially regulated ILC3 clocks, with light signals as major entraining cues of ILC3. Accordingly, surgical- and genetically-induced deregulation of brain rhythmicity led to disrupted circadian ILC3 oscillations, deregulated microbiome and altered lipid metabolism. Our work reveals a circadian circuitry that translates environmental light cues into enteric ILC3, shaping intestinal health and organismal homeostasis.

Project description:Inflammatory bowel disease (IBD) results from a dysregulated interaction between the microbiota and a genetically susceptible host. Genetic studies have linked TNFSF15 polymorphisms and its protein TNF-like ligand 1A (TL1A) with IBD, but the functional role of TL1A in linking tissue homeostasis and intestinal inflammation is not known. Here, using cell-specific genetic deletion models, we report an essential role for CX3CR1+ mononuclear phagocyte (MNP)-derived TL1A, which is induced by adherent IBD-associated microbiota, in regulating group 3 innate lymphoid cell (ILC3) production of IL-22 and mucosal healing in acute colitis. However, in contrast to this protective role in acute colitis, TL1A-dependent expression of OX40L in MHCII+ ILC3 during colitis leads to co-stimulation of antigen-specific T cells and is required for chronic T cell colitis. These results identify a new role for ILC3 in regulating intestinal T cells and reveal a central role for TL1A in regulating ILC3 barrier immunity during colitis.

Project description:Group 3 innate lymphoid cells (ILC3s) sense environmental signals that are critical for gut homeostasis and host defense. However, the metabolite-sensing G-protein-coupled receptors that regulate colonic ILC3s remain poorly understood. We found that colonic ILC3s expressed Ffar2, a microbial metabolite-sensing receptor, and that Ffar2 agonism promoted ILC3 expansion and function. Deletion of Ffar2 in ILC3s decreased their in situ proliferation and ILC3-derived IL-22 production. This led to impaired gut epithelial function characterized by altered mucus-associated proteins and antimicrobial peptides and increased susceptibility to colonic injury and bacterial infection. Ffar2 increased IL-22+ CCR6+ ILC3s and influenced ILC3 abundance in colonic lymphoid tissues. Ffar2 agonism differentially activated AKT or ERK signaling and increased ILC3-derived IL-22 via an AKT and STAT3 axis. Our findings demonstrate that Ffar2 regulates colonic ILC3 proliferation and function in a cell-intrinsic manner and identifies an ILC3-receptor signaling pathway regulating gut inflammatory tone and pathogen defense.

Project description:Group 3 innate lymphoid cells (ILC3) are innate immune effectors that contribute to host defense. Whether ILC3 functions are stably modified following pathogen encounter is unknown. Here we assess the impact of a time-restricted enterobacterial challenge to long-term ILC3 activation. We found that intestinal ILC3 persist for months in an activated state following exposure to Citrobacter rodentium. Upon rechallenge, these “trained” ILC3 proliferate, display enhanced interleukin (IL)-22 responses, and have a superior cell-intrinsic capacity to control infection compared to naïve ILC3. Metabolic changes occur in C. rodentium-exposed ILC3 but only trained ILC3 have enhanced proliferative capacity that contributes to elevated IL-22 production. Accordingly, a limited encounter with a pathogen can promote durable phenotypic and functional changes in intestinal ILC3 that contribute to long-term mucosal defense.

Project description:Group 3 innate lymphoid cells (ILC3s) are critical regulators of intestinal homeostasis, yet their role in cancer remains elusive. Here, we identify that the tumor microenvironment of humans and mice with colorectal cancer (CRC) contains altered ILC3 responses that resemble those found during intestinal inflammation and are characterized by reduced frequencies, altered subset distribution, and an imbalance with T cells. We evaluated the consequences of these changes in mice and determined that ILC3-specific major histocompatibility complex class II (MHCII) was required to limit the progression of CRC. Interestingly, ILC3-specific MHCII also prevented resistance to anti-PD-1 immunotherapy by regulating intestinal inflammation and microbiota composition. Finally, humans with intestinal inflammation and dysregulated ILC3s also harbor specific microbiota that are sufficient to promote immunotherapy resistance in mice. Collectively, these data define a protective role for antigen-presenting ILC3s in cancer, and indicate that inherent disruption of this pathway drives CRC progression and immunotherapy resistance.

Project description:Epithelial cells in the intestinal mucosa maintain gut homeostasis by interacting with different types of microbiota. Proper appropriate immune responses in the intestinal epithelium are essential for the preservation of the intestinal homeostasis. In the present study, we aimed to identify genotypic and phenotypic changes in mice following oral feeding of various substances which has been shown to differentially affect intestinal homeostasis. We orally fed C57BL/6 mice for either one or seven days with one of the four substances: dextran sulfate sodium (DSS); Typhoid VI Polysaccharide vaccine (Vi vaccine); antibiotic cocktails (AB) of ampicillin, vancomycin, neomycin, and metronidazole; or(probiotics)consisting of Lactobacillus Rhamnosus R0011and L. Acidophilus R0052.While DSS and AB feeding resulted in severe gut pathology characterized by infiltration of inflammatory cells, epithelium shedding, and distortion of paneth cells. Vi vaccine and probiotics feeding resulted in phenotypic improvement of the gut health characterized by epithelial cell proliferation and increased formation of tight junctions between epithelial cells. Interestingly, microarray data showed significant increase in the expression levels of genes regulating cell proliferation and intestinal homeostasis in the gut epithelium of probiotics-and Vi vaccine-fed mice compared to DSS-or AB-fed mice. In addition, expression levels of genes regulating cell death and inflammation were significantly increased in the gut epithelium of DSS- and AB-fed mice. These results suggest that intestinal homeostasis play a pivotal role in maintaining gut health and, subsequently, in protecting host against enteric bacteria and external pathogens infection.

Project description:How group 3 innate lymphoid cells (ILC3) regulate mucosal protection in the presence of T cells remains poorly understood. Here, we examined ILC3 function in intestinal immunity using ILC3-deficient mice that maintain endogenous T cells, Th17 cells, and secondary lymphoid organs. ILC3 were dispensable for generation of Th17 and Th22 cell responses to commensal and pathogenic bacteria, and absence of ILC3 did not affect IL-22-production by CD4 T cells before or during infection. However, despite presence of IL-22-producing T cells, ILC3 and ILC3-derived IL-22 were required for maintaining homeostatic functions of the intestinal epithelium. T cell-sufficient, ILC3-deficient mice were capable of pathogen clearance and survived infection with low dose Citrobacter rodentium. However, ILC3 increased pathogen tolerance at early timepoints of infection by activating tissue-protective immune pathways. Consequently, ILC3 were indispensable for survival of high dose infection. Our results demonstrate a crucial context-dependent role for ILC3 in immune-sufficient animals and provide a blueprint for uncoupling of ILC3 and Th17 cell functions.

Project description:Innate lymphoid cells (ILC) are tissue-resident effector cells with important roles in tissue homeostasis, protective immunity and inflammatory disease. Current nomenclature divides ILC into subsets based on the expression of master transcription factors and effector cytokine programs. In mucosal barrier tissues, group 3 ILC (ILC3) have been defined by the expression of the master transcription factor RORgt. However, ILC3 can be further subdivided into two major subsets – natural cytotoxicity receptor-expressing (NCR+) ILC3 and lymphoid tissue inducer (LTi)-like ILC3 which share type 3 effector modules but also exhibit significant ontological, transcriptional, phenotypic and functional heterogeneity. In particular, LTi-like ILC3 exhibit effector functions not typically associated with other RORgt-expressing lymphocytes, provoking the hypothesis that other master transcription factors may contribute to LTi-like ILC3 biology. Here we identify Bcl6 as an LTi-like ILC3 associated transcription factor in both mice and humans. Deletion of Bcl6 led to dysregulation of the LTi-like ILC3 transcriptional program and changes to subset-specific phenotypic markers and effector functions. Strikingly, loss of Bcl6 enhanced expression of the type 3 effector cytokines IL-17A and IL-17F in LTi-like ILC3, which was found to be in part dependent upon the commensal microbiota. Together these findings implicate Bcl6 as an ILC3 subset-defining transcription factor and part of a network that confers phenotype and function on LTi-like ILC3. Our study further provides a missing link to redefine analogous immune modules in innate and adaptive lymphocyte responses.