Project description:Innate lymphoid cells (ILCs) have emerged as essential players in the skin-associated immune system in health and inflammatory skin diseases. Their low numbers and lack of specific markers hampered extensive characterization and consequently resulted in limited knowledge of their protein expression. Here, we combined flow cytometry and state-of-the-art proteomics to comprehensively describe the proteins constitutively expressed by ILC2 and ILC3 subsets derived from healthy human skin and peripheral blood. We quantified 6666 proteins from skin ILC and identified 608 differentially expressed proteins in the investigated subsets. In addition to the current analyses, highlighting new functions of ILC, the ILC proteomic libraries and the proteomes of the ILC2 and ILC3 subsets will serve as valuable resources for future analyses of ILC function and are available at http://skin.science.

Project description:We find that the expression of GATA3 in skin ILCs is significantly lower than in conventional ILC2s of other tissues, indicating that the regulatory role of GATA3 may be different. Indeed, skin ILCs are still maintained after inducing Gata3 depletion in Gata3fl/flCreERT2 mice, when all ILC2s were gone. In addition, about 70% skin ILCs are found to experience RORγt expression as reflected by RORγt fate-mapping. And, conditional Gata3 depletion in the RORγt fate-mapped skin ILCs does not affect their number as well. Therefore, in contrast to conventional ILC2s, GATA3 is not required for skin ILCs for their maintenance. The RORγt fate-mapped skin ILCs have exhibited ILC3-like features. Single-cell transcriptome analysis further reveals that skin ILCs converge on a Ccr6+ ILC3-like state and an Il1rl1+ ILC2-like state. The regulatory role of GATA3 is crucial in the ILC3-like skin ILCs. It promotes the expression of their featured genes, while suppresses the expression of ILC2-like skin ILC featured genes. These ILC3-like skin ILCs locate in close proximity to hair follicles. During hair follicle recycling they migrate from isthmus to suprabulbar to promote the hair follicle growth. Whereas in absence of Gata3, the ILC3-like skin ILCs exhibit defective migration to the suprabulbar and reduced expression of the featured genes in this process. Together, our study evidence that skin ILCs are alternative to conventional ILC2s. In particular, we shed light on the function of GATA3 in promoting the specific gene expression in ILC3-like skin ILCs and regulating their crucial roles in hair follicle recycling, which will improve our knowledge about the involvement of ILCs in maintaining homeostasis of skin.

Project description:Innate lymphoid cells (ILCs) are able to directly respond to alarmin signals and produce an array of effector molecules for immune protection and tissue homeostasis. However, how posttranscriptional machinery in ILCs execute extracellular stimuli towards robust gene expression is yet to understand. Here, we reported a cell type-specific role of N6-methyladenosine (m6A) RNA methylation in ILCs. Inducible deletion of m6A methyltransferase METTL3 had little impact on ILC maintenance in the steady state or cytokine-induced ILC1 or ILC3 activation, but dramatically diminished IL-25-triggered ILC2 response. Specific deletion of Mettl3 in ILC2 significantly attenuated cell expansion, cytokine production, inter-organ migration, and anti-helminth immunity. To investigate the molecular mechanism by which m6A modification regulates ILC response, we subjected IL-1 plus IL-23-activated ILC3 to a m6A-tagged mRNA immunoprecipitation sequencing (meRIP-seq) to identify the m6A modified mRNA.

Project description:Innate lymphoid cells (ILCs) are highly plastic and predominantly mucosal tissue-resident cells that contribute to both homeostasis and inflammation depending on the microenvironment. The recent discovery of naïve-like tissue-resident ILCs suggests an ILC differentiation process that is akin to naïve T cell differentiation. Delineating the naïve-like ILC heterogeneity and the transcriptional, epigenetic and functional mechanisms that underlie ILC differentiation in tissues is crucial for understanding ILC biology in health and disease. Here we show that CD62L distinguishes two subsets of naïve-like CD45RA+ ILCs in tonsil tissue. While both subsets contain uni- and multipotent precursors of ILC1/NK cells and ILC3, CD62L+ ILCs resemble bona fide naïve ILCs with metabolism reminiscent of naïve T cells, lacking transcriptional and epigenetic signatures of mature ILCs. CD62L- ILCs are epigenetically similar to, but transcriptionally distinct from CD62L+ naïve-like ILCs including transcripts of cytokine signaling and metabolic pathways related to mature ILCs. A similar population of CD62L- quiescent ILCs with preferential differentiation capacity towards IL-22-producing ILC3 accumulate in the inflamed mucosa of patients with inflammatory bowel disease (IBD). These data suggest that naïve-like and quiescent ILCs are imprinted by their tissue microenvironment that poises their differentiation potential. Our findings identify restoration of homeostatic IL-22-producing ILC3 from CD62L- quiescent ILCs as a potential approach to improve tissue healing in IBD.

Project description:Innate lymphoid cells (ILCs) play a critical role in maintaining intestinal health in homeostatic and diseased conditions. During C. difficile infection (CDI), IL-33 activates ILC2 to protect from colonic damage and mortality. The function of IL-33 and ILC is tightly regulated by the intestinal microbiota. We set out to determine the impact of antibiotic-induced disruption of the microbiome on ILC function. Our goal was to understand antibiotic-induced changes in ILC function on susceptibility to C. difficile colitis in a mouse model. We utilized high-throughput single-cell RNAseq to investigate the phenotypic features of colonic ILC at baseline, after antibiotic administration with or without IL-33 treatment. We identified a heterogeneous landscape of colonic ILCs with gene signatures of inflammatory, anti-inflammatory, migratory, progenitor, plastic, and antigen-presenting ILC. Antibiotic treatment decreased ILC2 while coordinately increasing ILC1 and ILC3 phenotypes. Notably, Ifng+, Ccl5+, and Il23r+ ILC increased after antibiotics. IL-33 treatment counteracted the antibiotic effect by downregulating ILC1 and ILC3 and activating ILC2. In addition, IL-33 treatment markedly induced the expression of type 2 genes, including Areg and Il5. Finally, we identified amphiregulin, produced by ILC2, as protective duringC. difficileinfection. Together, our data expand our understanding of how antibiotics induce susceptibility to C. difficile colitis through their impact on ILC subsets and function.

Project description:Innate lymphoid cells (ILCs) are important for mucosal immunity. The intestine harbors all ILC subsets; however, how these cells orchestrate each other to achieve immune homeostasis and mount appropriate immunity during infection remains elusive. Here, we show that the adaptation of the aryl hydrocarbon receptor (Ahr) expression in the gut is a key regulatory mode for the host to keep the ILC balance. Among ILCs, Ahr is most highly expressed by gut ILC2, and controls in a positive feedback manner, chromatin accessibility at the Ahr gene locus. Ahr suppresses Gfi1-mediated ST2 expression in ILC2 and expression of ILC2 effector molecules IL-5, IL-13 and amphiregulin in a cell-intrinsic manner. Ablation of Ahr enhances anti-helminth immunity in the gut, while genetic or pharmacological activation of Ahr suppresses ILC2 but enhances ILC3 to protect the host from Citrobacter rodentium infection. Thus, the host regulates the gut ILC2-ILC3 balance by engaging the Ahr pathway to mount appropriate immunity against various pathogens.

Project description:Innate lymphoid cells (ILCs) are able to directly respond to alarmin signals and produce an array of effector molecules for immune protection and tissue homeostasis. However, how posttranscriptional machinery in ILCs execute extracellular stimuli towards robust gene expression is yet to understand. Here, we reported a cell type-specific role of N6-methyladenosine (m6A) RNA methylation in ILCs. Inducible deletion of m6A methyltransferase METTL3 had little impact on ILC maintenance in the steady state or cytokine-induced ILC1 or ILC3 activation, but dramatically diminished IL-25-triggered ILC2 response. Specific deletion of Mettl3 in ILC2 significantly attenuated cell expansion, cytokine production, inter-organ migration, and anti-helminth immunity. To investigate the molecular mechanism by which m6A modification regulates ILC response, we subjected IL-12 plus IL-18-activated ILC1 to a m6A-tagged mRNA immunoprecipitation sequencing (meRIP-seq) to identify the m6A modified mRNA.

Project description:Type-2 innate lymphoid cells (ILC2s) promote anti-helminth responses and contribute to allergies. Though Bcl11b has been previously considered a T-lineage identity transcription factor (TF) that restrains the innate-cell genetic programs, we report here that Bcl11b is highly expressed in mature ILC2s and acts upstream of the key ILC2 TFs Gfi1, Gata-3, and of IL-33 receptor IL1rl1 (T1ST2). Additionally, Bcl11b-/- ILC2s de-repressed Rorγt, Ahr and IL-23 receptor, normally expressed in type-3 ILCs (ILC3s). Consequently, Bcl11b-/- ILC2s lost ILC2 functions and gained ILC3 functions, expanding in response to the protease allergen papain, however producing IL-17 and IL-22, and not IL-5 and IL-13, causing lung neutrophilia rather than eosinophilia, and diminished mucus production. Our results broaden Bcl11b's role from a T-cell only TF, and establishes that Bcl11b sustains mature ILC2 genetic and functional programs and lineage fidelity through positive regulation of essential ILC2 TFs and negative regulation of pivotal ILC3 TFs. RNA-seq analysis on sorted ILC2s from the mLNs of Bcl11bF/F Cre-ERT2 and wildtype mice at steady state following tamoxifen mediated deletion of Bcl11b

Project description:Innate lymphoid cells (ILCs) are able to directly respond to alarmin signals and produce an array of effector molecules for immune protection and tissue homeostasis. However, how posttranscriptional machinery in ILCs execute extracellular stimuli towards robust gene expression is yet to understand. Here, we reported a cell type-specific role of N6-methyladenosine (m6A) RNA methylation in ILCs. Inducible deletion of m6A methyltransferase METTL3 had little impact on ILC maintenance in the steady state or cytokine-induced ILC1 or ILC3 activation, but dramatically diminished IL-25-triggered ILC2 response. Specific deletion of Mettl3 in ILC2 significantly attenuated cell expansion, cytokine production, inter-organ migration, and anti-helminth immunity. To investigate the molecular mechanism by which m6A modification regulates ILC2 response, we subjected IL-25-activated iILC2 to a m6A-tagged mRNA immunoprecipitation sequencing (meRIP-seq) to identify the m6A modified mRNA.

Project description:Innate lymphoid cells (ILCs) are able to directly respond to alarmin signals and produce an array of effector molecules for immune protection and tissue homeostasis. However, how posttranscriptional machinery in ILCs execute extracellular stimuli towards robust gene expression is yet to understand. Here, we reported a cell type-specific role of N6-methyladenosine (m6A) RNA methylation in ILCs. Inducible deletion of m6A methyltransferase METTL3 had little impact on ILC maintenance in the steady state or cytokine-induced ILC1 or ILC3 activation, but dramatically diminished IL-25-triggered ILC2 response. Specific deletion of Mettl3 in ILC2 significantly attenuated cell expansion, cytokine production, inter-organ migration, and anti-helminth immunity. To investigate the molecular mechanism by which m6A modification regulates ILC2 response, we subjected ILC2 of WT and Mettl3 Klrg1Cre mice to a m6A-tagged mRNA immunoprecipitation sequencing (meRIP-seq) to identify the m6A modified mRNA.