Project description:Dysregulated tissue-resident macrophages (TRMs) contribute to pathogenesis of inflammatory bowel disease (IBD) and multiple sclerosis (MS), yet the molecular pathways that regulates TRMs remain unclear. Smurf2 deficiency significantly exacerbates the TRM proliferation in dextran sulfate sodium (DSS)-induced colitis and experimental autoimmune encephalomyelitis (EAE), leading to augmented autoimmune inflammation.

Project description:Although resident memory T cells (TRMs), which are memory T cells that are retained locally within tissues, have recently been described as antigen-specific frontline defenders against pathogens in barrier and non-barrier epithelial tissues, they have also been noted for perpetuating chronic inflammation. Furthermore, the conditions responsible for TRM differentiation are still poorly understood, and their contributions, if any, to sterile models of chronic kidney disease (CKD) remain a mystery. In this study we identify a substantial population of TRMs in the kidneys of mice with aristolochic acid (AA)-induced CKD. Flow cytometry of injured kidneys showed T cells bearing TRM surface markers and single cell RNA sequencing revealed these cells as expressing well-known TRM transcription factors and receptors responsible for TRM differentiation and maintenance. While kidney TRMs expressed Cd44, a marker of antigen experience and T cell activation, their derivation was surprisingly independent of cognate antigen-T cell receptor interactions, as the kidneys of transgenic OT-1 mice still harbored considerable proportions of TRMs after injury. Our results suggest a non-antigen-specific or antigen-independent mechanism capable of generating TRMs in the kidney and highlight the need to better understand TRMs and their involvement in CKD.

Project description:Tissue-resident macrophages (TRMs) are innate immune cells that participate in tissue development, homeostasis, and immune surveillance. Extensive efforts have been made to recapitulate TRM development from pluripotent stem cells (PSCs) in vitro to study molecular and cellular mechanisms of TRM development and to create cellular models of disease. However, available PSC models of mouse TRM development exhibit low overall efficiencies of TRM generation, generate heterogeneous off-target populations, and rely upon undefined media components, thus limiting their reproducibility, scalability, and widespread application as an experimental platform for TRM biology. To address these important limitations, we developed an efficient and reproducible protocol to faithfully recapitulate the stepwise differentiation of mouse PSCs (epiblast stem cells) into unspecialized, proliferative TRMs through the pro-definitive hematopoietic program under defined conditions. These immature TRMs can stably integrate into developing mouse neural organoids in vitro and acquire features of microglia, the TRMs of the brain. In addition, immature TRMs can stably engraft into the lung niche in vivo and adopt alveolar macrophage characteristics. This new platform for modeling mouse TRM development will enable paired in vitro and in vivo studies that leverage the full suite of mouse genetic tools, and thus should be a powerful experimental model system for studying TRM function and dysfunction in development and disease.

Project description:Tissue-resident macrophages (TRMs) are long-lived cells that maintain locally and can be phenotypically distinct from monocyte-derived macrophages. Whether TRMs and monocyte-derived macrophages have district roles under differing pathologies is not understood. Here, we showed that a substantial portion of the macrophages that accumulated during pancreatitis and pancreatic cancer in mice had expanded from TRMs. Pancreas TRMs had an extracellular matrix remodeling phenotype that was important for maintaining tissue homeostasis during inflammation. Loss of TRMs led to exacerbation of severe pancreatitis and death, due to impaired acinar cell survival and recovery. During pancreatitis, TRMs elicited protective effects by triggering the accumulation and activation of fibroblasts, which was necessary for initiating fibrosis as a wound healing response. The same TRM-driven fibrosis, however, drove pancreas cancer pathogenesis and progression. Together, these findings indicate that TRMs play divergent roles in the pathogenesis of pancreatitis and cancer through regulation of stromagenesis.

Project description:Tissue-resident macrophages (TRMs) are long-lived cells that maintain locally and can be phenotypically distinct from monocyte-derived macrophages. Whether TRMs and monocyte-derived macrophages have district roles under differing pathologies is not understood. Here, we showed that a substantial portion of the macrophages that accumulated during pancreatitis and pancreatic cancer in mice had expanded from TRMs. Pancreas TRMs had an extracellular matrix remodeling phenotype that was important for maintaining tissue homeostasis during inflammation. Loss of TRMs led to exacerbation of severe pancreatitis and death, due to impaired acinar cell survival and recovery. During pancreatitis, TRMs elicited protective effects by triggering the accumulation and activation of fibroblasts, which was necessary for initiating fibrosis as a wound healing response. The same TRM-driven fibrosis, however, drove pancreas cancer pathogenesis and progression. Together, these findings indicate that TRMs play divergent roles in the pathogenesis of pancreatitis and cancer through regulation of stromagenesis.

Project description:Tissue-resident macrophages (TRMs) are critical for tissue homeostasis/repair. We previously showed that dermal TRMs produce CCL24 which mediates their interaction with IL-4 producing eosinophils, required to maintain their M2-like properties in the TH1 environment of the Leishmania major infected skin. Here, we unveil another layer of TRM self-maintenance involving production of TSLP, an alarmin typically characterized as epithelial cell-derived. Both TSLP signaling and IL-5+ innate lymphoid cell 2 (ILC2s) were shown to maintain dermal TRM numbers and promote infection. Single cell RNA sequencing identified the dermal TRMs as the sole source of TSLP and CCL24. Generation of Ccl24-cre mice permitted specific labeling of dermal TRMs, as well as interstitial TRMs from other organs. Genetic ablation of TSLP from dermal TRMs reduced the number of dermal TRMs and ameliorated infection. Here, we show that by orchestrating localized type 2 circuitries with ILC2s and eosinophils, dermal TRMs are self-maintained as a replicative niche for L. major.

Project description:Tissue and microbial cues regulate the abundance and function of CD8+ T cells at barrier sites, yet the impact of specific microbes on their long-term durability remains unclear. Here, we show that the commensal protist Tritrichomonas musculus (T. mu) depletes intestinal CD8+ T cells, particularly tissue resident memory (TRM) cells, through activation of localized type 2 immunity. Colonization with T. mu or administration of its major secreted metabolite, succinate, led to the rapid decline of intestinal CD8+ T cells but left systemic memory T cells unaffected. The purinergic receptor, P2RX7, is highly expressed by intestinal TRMs and chemical antagonism of this receptor markedly restored CD8+ T cells during succinate feeding. Using lymphocytic choriomeningitis virus (LCMV) infection to track antigen-specific CD8+ memory T cells, we found viral-specific CD8+ TRMs repopulate the intestine independent of LCMV reinfection after removal of succinate treatment. These findings highlight how commensal protists and their metabolites reset homeostatic CD8+ T cell carrying capacity through damage-independent stimulation of TRM apoptosis and regulate mucosal memory.

Project description:The specifying signals provided by the tissue microenvironment to promote acquisition of Trm features vary across anatomical niches, and those delivered in the large intestine (LI) remain largely uncharacterized. Here we show that following migration of activated T cells from the priming lymph nodes, antigen recognition in the tissue microenvironment is crucial to establish LI CD8 Trm. In the absence of tissue-confined antigen, T cells fail to generate memory precursors and to accumulate in the tissue. Local antigen presentation boosts Trm generation in a dose-dependent manner, and prompts transient acquisition of a distinctive transcriptional program including key signatures of gut Trm. The definitive transcriptional landscape of LI Trm cells comprises both features that are shared with Trm at other locations, as well as unique elements. Our findings identify antigen presentation in the gut microenvironment as a key step in the generation of large LI CD8 Trm, providing key insight for the optimization of mucosal immunization strategies.

Project description:Our previous work showed that vaccine elicited Klebsiella pneumoniae specific CD4+ tissue resident memory (TRM) cells in the lung provide serotype independent immunity against K. pneumoniae for up to 6 months. However, vaccine efficacy wanes in proportion to lung CD4+ TRM cell number. To study what controls TRM maintenance, apart from antigen, we developed an LTA/1Ovalbumin (OVA) model and tetramer pulldown method to enrich OVA+ lung CD4+ TRM cells over time. We applied single-cell RNA-sequencing (scRNA-seq) of these cells, collected on days 30, 90 and 184 after prime immunization with OVA and our prior Th17 adjuvant, E. coli heat labile toxin A1 (LTA1). As control, we used splenic CD4+ T cells from naive mice

Project description:Tissue-resident macrophages (TRMs) play central roles in local tissue development and immunity. However, how to control TRM ontogeny and maintenance remains unclear. We performed transcriptional and histone modification analyses of alveolar macrophages in mice with myeloid-specific (Csf1rCre) deletion of HDAC3 using bulk RNA-seq, single-cell RNA-seq and ChIP-seq. We report that HDAC3 deficiency results in metabolic disorders and increased cell death of the fetal lung TRMs, which is partially regulated through directly targeting PPAR-γ. Although the loss of AMs in the absence of HDAC3 is not AM subset specific, the transcriptome changes in HDAC3 deficient AM subsets are different. We propose that HDAC3 serves a key epigenetic regulator that controls embryonic TRM ontogeny and maintenance.