Project description:Persistent NF-κB activation is a hallmark of the malignant Hodgkin/Reed-Sternberg (HRS) cells in classical Hodgkin lymphoma (cHL). Analysis of the cHL cell-secreted key factors for NF-κB activation by chromatography and subsequent mass spectrometry revealed lymphotoxin-α (LTA) as the causative factor for autocrine and paracrine activation of canonical and noncanonical NF-κB in cHL cell lines. Upon CRISPR/Cas9-mediated gene knockout of LTA in the cell line L-1236, we performed expression analysis of LTA knockout versus control cells by using the Affymetrix array, Clariom S human, profiling tool.

Project description:Persistent activation of canonical and non-canonical NF-κB pathways is a hallmark of the malignant Hodgkin and Reed-Sternberg cells in classical Hodgkin lymphoma (cHL). We identified lymphotoxin alpha (LTA), which is secreted by the cHL cell line L-1236 in high concentrations. This cytokine contributes to the constitutive activation of the canonical and non-canonical NF-κB pathways. L-1236 cells were purchased from the DSMZ (Braunschweig, Germany) and cultured in RPMI (Gibco) with 10% heat-inactivated fetal calf serum (FCS; Gibco). Cells were transducted with the lentiCRIPSPR v2 vector containing gRNAs which target the second (g2) and the fourth exon (g3) of LTA. Following single cell clonal selection, L-1236 control cells (v2) and two LTA knockout (KO) clones g2_1 and g3_4 were cultured in normal culture medium for 72 h. The RNA was extracted using the RNeasy kit (Qiagen) according to manufacturer’s instructions. Preparation of cDNA, fragmentation and labeling was performed with the GeneChIPTM WT PLUS reagent kit (ThermoFisher Scientific). Samples were hybridized to the human Clariom™ S Assay (ThermoFisher Scientific).

Project description:The active form of vitamin D (1,25(OH)2D) suppresses experimental models of inflammatory bowel disease in part by regulating the microbiota. In this study, the role of vitamin D in the regulation of microbe induced RORgt/FoxP3+ T regulatory (reg) cells in the colon was determined. Vitamin D sufficient (D+) mice had significantly higher frequencies of FoxP3+ and RORgt/FoxP3+ T reg cells in the colon compared to vitamin D deficient (D-) mice. The higher frequency of RORgt/FoxP3+ T reg cells in D+ colon correlated with higher numbers of bacteria from the Clostridium XIVa and Bacteroides in D+ compared to D- cecum. D- mice with fewer RORgt/FoxP3+ T reg cells were significantly more susceptible to colitis than D+ mice. Transfer of the cecal bacteria from D+ or D- mice to germfree recipients phenocopied the higher numbers of RORgt/FoxP3+ cells and reduced susceptibility to colitis in D+ versus D- recipient mice. 1,25(OH)2D treatment of the D- mice beginning at 3 weeks of age did not completely recover RORgt/FoxP3+ T reg cells or the Bacteriodes, Bacteriodes thetaiotaomicron, and Clostridium XIVa numbers to D+ values. Early vitamin D status shapes the microbiota to optimize the population of colonic RORgt/FoxP3+ T reg cells important for resistance to colitis.

Project description:Foxp3+ regulatory T (Treg) cells are essential for immunological tolerance and homeostasis. In peripheral tissues, Treg cells acquire enhanced suppressive functions and co-opt distinct transcriptional modules, allowing context and tissue-dependent immune regulation. Here we show that the transcription factor c-Maf was highly expressed by effector Treg cells and controlled their IL-10 production. In the intestine, c-Maf was required for the differentiation of RORgt+ microbiota-dependent Treg cells, and restricted their production of inflammatory cytokines. Consequently, Treg cell-specific loss of c-Maf resulted in perturbed intestinal homeostasis, microbial dysbiosis and a selective failure to control Th17 responses during homeostasis and upon chemically induced epithelial damage. Molecular profiling revealed that c-Maf regulated expression of key genes of the transcriptional signature of intestinal Treg cells, including Rorc and Il10. Thus, our study identifies a key role of c-Maf in preserving the identity and function of intestinal Treg cells, essential for the control of intestinal immune homeostasis.

Project description:The aim of this study was to analyze the global transcriptional profiles of small intestine (SI) Innate Lymphoid Cells (ILCs) expressing the NK cell marker NKp46. Based on differential expression of the RORgt transcription factor SI NKp46+ ILCs can be divided in NKp46+RORgt- and NKp46+RORgt+ cells. While NKp46+RORgt- cells produce IFN-g, like conventional Natural Killer (NK) cells, NKp46+RORgt+ cells secrete IL-22, like Lymphoid Tissue inducer (LTi) cells. We compared the global transcriptional profiles of both NKp46+RORgt- and NKp46+RORgt+ cells to conventional splenic NK cells and to SI NKp46-RORgt+ cells, which contain adult LTi cells. By following this approach, we showed that SI NKp46+RORγt- ILCs correspond to SI NK cells. We also identified a transcriptional program conserved in adult SI NKp46+RORγt+, NKp46-RORγt+ ILCs and fetal LTi. The various ILC cell populations analyzed in this study were isolated from C57BL/6 RORc(gt)+/GFP reporter mice. SI NKp46+RORγt- (NKp46+GFP-) cells, SI NKp46+RORγt+ cells (NKp46+GFPlow and NKp46+GFPhigh cells) and NKp46-RORγt+ ILCs, including adult LTi cells , were sorted by flow cytometry from CD3- lamina propria cells of small intestine (SI) of RORc(γt)+/GFP reporter mice . Splenic NKp46+RORγt- (NKp46+GFP-) cells were also sorted as the reference for conventional NK cells. Two replicates of each populations were produced and analyzed.

Project description:We profiled transcriptome and chromatin landscapes in jejunal mouse intestinal epithelial cells (IECs) from mice reared in the absence (Germ Free or GF) or presence (Conventionalized or CV) of microbiota. We show that microbiota colonization results in changes in histone modifications at hundreds of enhancers that are associated with microbiota-regulated genes. Furthermore, we show that microbiota colonization is associated with a drastic genome-wide reduction in Hnf4a and Hnf4g binding.

Project description:The mutualistic relationship of gut-resident microbiota and cells of the host immune system promotes homeostasis that ensures maintenance of the microbial community and of a poised, but largely non-aggressive, immune cell compartment1. Consequences of disturbing this balance, by environmental or genetic factors, include proximal inflammatory conditions, like Crohn’s disease, and systemic illnesses, both metabolic and autoimmune. One of the means by which this equilibrium is achieved is through induction of both effector and suppressor or regulatory arms of the adaptive immune system. In mice, Helicobacter species induce regulatory (iTreg) and follicular helper (Tfh) T cells in the colon-draining mesenteric lymph nodes under homeostatic conditions, but can instead induce inflammatory Th17 cells when iTreg cells are compromised3,4. How Helicobacter hepaticus and other gut bacteria direct T cells to adopt distinct functions remains poorly understood. Here, we investigated which cells and molecular components are required to convey the microbial instruction for the iTreg differentiation program. We found that antigen presentation by cells expressing RORgt, rather than by classical dendritic cells, was both required and sufficient for iTreg induction. These RORgt+ cells, likely to be type 3 innate lymphoid cells (ILC3) or a recently-described population of Aire+ cells termed Janus cells5, require the MHC class II antigen presentation machinery, the chemokine receptor CCR7, and av integrin, which activates TGF-β, for iTreg cell differentiation. In the absence of any of these, instead of iTreg cells there was expansion of microbiota-specific pathogenic Th17 cells, which were induced by other antigen presenting cells (APCs) that did not require CCR7. Thus, intestinal commensal microbes and their products target multiple APCs with pre-determined features suited to directing appropriate T cell differentiation programs, rather than a common APC that they endow with appropriate functions.

Project description:The gut microbiota is a key environmental determinant of mammalian metabolism. Regulation of white adipose tissue (WAT) by the gut microbiota is a critical process that maintains metabolic fitness, while dysbiosis contributes to the development of obesity and insulin resistance (IR). However, how the gut microbiota controls WAT functions remain largely unknown. Herein, we show that tryptophan-derived metabolites produced by the microbiota control the expression of the miR-181 family in white adipocytes to regulate energy expenditure and insulin sensitivity. Moreover, we show that dysregulation of the microbiota-miR-181 axis is required for the development of obesity, IR, and WAT inflammation. Thus, our results indicate that regulation of miRNA levels in WAT by microbiota-derived cues is a central mechanism by which host metabolism is tuned in response to dietary and environmental changes. As MIR-181 is dysregulated in WAT from obese human individuals, the MIR-181 family may represent a potential therapeutic target to modulate WAT function in the context of obesity.

Project description:The mutualistic relationship of gut-resident microbiota and cells of the host immune system promotes homeostasis that ensures maintenance of the microbial community and of a poised, but largely non-aggressive, immune cell compartment1,2. Consequences of disturbing this balance, by environmental or genetic factors, include proximal inflammatory conditions, like Crohn’s disease, and systemic illnesses, both metabolic and autoimmune.  One of the means by which this equilibrium is achieved is through induction of both effector and suppressor or regulatory arms of the adaptive immune system. In mice, Helicobacter species induce regulatory (iTreg) and follicular helper (Tfh) T cells in the colon-draining mesenteric lymph nodes under homeostatic conditions, but can instead induce inflammatory Th17 cells and colitis when iTreg cells are compromised3,4. How Helicobacter hepaticus and other gut bacteria direct T cells to adopt distinct functions remains poorly understood. It could involve targeting a common antigen presenting cell (APC) by distinct microbial products, endowing it with specialized functions, or targeting APCs with pre-determined features suited to directing appropriate T cell differentiation programs. Here, we investigated which cells and molecular components are required to convey the microbial instruction for the iTreg differentiation program. We found that antigen presentation by cells expressing RORgt, rather than by classical dendritic cells, was both required and sufficient for iTreg induction. The MHC class II antigen presentation machinery, chemokine receptor CCR7, and av integrin, which activates TGF-β, were necessary in RORgt+ cells, likely type 3 innate lymphoid cells (ILC3), for iTreg cell differentiation. In the absence of any of these, instead of iTreg cells there was expansion of H. hepaticus-specific pathogenic Th17 cells, which were induced by other APCs that did not require CCR7. Our results illustrate the ability of microbiota to exploit specialized functions of distinct innate immune system cells, targeting them to achieve the desired composition of equipoised T cells, thus maintaining tolerance.

Project description:Tissue physiology and responses to injury can be controlled by the cross-talk between all physiological systems including the nervous and immune system. How the microbiota influences this dialogue remains unclear. Here, we show that adaptive responses to the microbiota directly promote sensory neuron regeneration. At homeostasis, commensal-specific Th17 co-localize with sensory neurons within the dermis and display a transcriptional profile associated with tissue and nerve repair. Following injury, commensal-specific Th17 cells promote axon growth and local nerve regeneration. Mechanistically, our data support the idea that IL17-A produced by commensal-specific T cells directly signal sensory neurons via IL17RA, the transcription of which is specifically upregulated in injured neurons. Collectively our work reveals that microbiota-specific T cells can bridge biological systems by directly promoting neuronal repair and identify IL17-A as a major determinant of this fundamental process.