Project description:Tissue-resident memory T cells (Trm) are central to maintaining autoimmune and inflammatory disease. Modulation of their continued replenishment in tissues has significant implications for clinical treatment. In a murine model of lung inflammation, scRNA-seq revealed the complexity of antigen-responding CD4+ Trm, encompassing many pathogenic subpopulations including Th2, Th17, Th1 and CTL, but suggested several targets for therapeutic intervention, with significant co-expression of the costimulatory molecules OX40, ICOS, CD30, and CD30L throughout these T cells. Inhibiting ICOSL alone, or co-blocking OX40L and CD30L, with neutralizing antibodies, only partially suppressed the response of Trm to recall antigen, whereas inhibiting all three molecules strongly reduced the accumulation of Trm-derived effector memory T cells, and ablated all aspects of lung inflammation. Most importantly, transient therapeutic inhibition of these molecules together prevented the continued accumulation and long-term persistence of induced Trm, leading to a state of tolerance such that subsequent exposure to antigen failed to re-establish a pathogenic inflammatory response. These data show that costimulatory molecules are critical for reactivation and persistence of pathogenic CD4+ Trm, and reveal several therapeutic combinations that are applicable for treatment of lung inflammatory disease and potentially multiple autoimmune diseases.

Project description:Tissue-resident memory T (TRM) cells are crucial mediators of adaptive immunity in non-lymphoid tissues. However, the functional heterogeneity and pathogenic roles of CD4+ TRM cells that reside within chronic inflammatory lesions remain unknown. We found that CD69hiCD103low CD4+ TRM cells produced effector cytokines and promoted the inflammation and fibrotic responses induced by chronic exposure to Aspergillus fumigatus. Simultaneously, immunosuppressive CD69hiCD103hiFoxp3+ CD4+ regulatory T (Treg) cells were induced and constrained the ability of pathogenic CD103low TRM cells to cause fibrosis. Thus, lung tissue-resident CD4+ T cells play crucial roles in the pathology of chronic lung inflammation, and CD103 expression defines pathogenic effector and immunosuppressive tissue-resident cell subpopulations in the inflamed lung.

Project description:CD8+ tissue resident memory T cells (TRM) develop from effectors that are recruited into peripheral tissues by infection or inflammation where they persist and provide defense against subsequent challenges. Long-term persistence of epidermal TRM requires autocrine TGFβ that is transactivated by integrins expressed on keratinocytes. In response to inflammation, the availability of TGFβ transactivation is limited. Antigen-experienced TRM that encountered antigen in the epidermis during their development are more fit and outcompete bystander TRM for TGFβ transactivation resulting in their enrichment in the epidermis. Transcriptomic analysis of endogenous epidermal TRM revealed that antigen-experienced TRM were enriched for TRM signature genes while bystander TRM retained the transcriptome of an earlier developmental state. Following antigen recall, antigen-experienced TRM displayed accelerated proliferation kinetics compared with bystanders that was determined by the TCR signal-strength during their differentiation the skin. Finally, antigen experienced TRM expressed TGFβRIII, which increases avidity of the TGFβRI/II receptor complex. Selective ablation of Tgfbr3 from antigen experienced TRM reduced their capacity to persist when TGFβ activation was limited thus rendering them phenotypically like bystander TRM. In sum, antigen-driven TCR signaling in the epidermis during TRM differentiation represents a required final step in ontogeny resulting in a lowered requirement on TGFβ transactivation for persistence and increased proliferation during recall responses that together result in the enhanced fitness of antigen-experience epidermal TRM.

Project description:Lung tissue-resident memory CD8+ T-cells (Trm) are critical for heterosubtypic immunity against influenza virus-(IAV)-reinfection. How these cells surveil the lung, respond to infection and interact with other cells remains unresolved. Here, we used mouse models to identify and enrich lung Trm in combination with intravital and static imaging to assess spatiotemporal dynamics of IAV-induced lung TRM before and after recall-infection. CD69+CD103+ Trm localize to sites of prior influenza infection where they exhibit substantially slower movement properties than non-Trm that also surveil the lung. After rechallenge, lung Trm form tight clusters in an antigen-dependent manner. IAV-specific Trm express several factors that regulate myeloid cell biology and their protective immune responses are accompanied by activation and migration of dendritic cells to draining lymph nodes and recruitment of inflammatory monocytes. Overall, these data reveal the dynamic landscapes of lung Trm cells associated with early protective immunity against IAV infection.

Project description:Rheumatoid arthritis is a systemic autoimmune disease, but disease flares typically affect only a subset of joints, distributed in a pattern that is distinctive for each patient. Pursuing this intriguing pattern, we show that arthritis recurrence is mediated by long-lived synovial resident memory T cells (TRM). In three murine models, CD8+ cells bearing TRM markers remain in previously inflamed joints during remission. These cells are bona fide TRM, exhibiting failure to migrate from joint to joint, preferential uptake of fatty acids, and long-term residency. Disease flares result from TRM activation by antigen, leading to CCL5-mediated recruitment of circulating effector cells. Correspondingly, TRM depletion ameliorates recurrence in a site-specific manner. Human rheumatoid arthritis joint tissues contain a comparable CD8+-predominant TRM population, most evident in late-stage leukocyte-poor synovium, exhibiting limited T cell receptor diversity and a pro-inflammatory transcriptomic signature. Together, these findings establish synovial TRM cells as a targetable mediator of disease chronicity in autoimmune arthritis.

Project description:CD8+ TRM are described in autoimmune and chronic inflammatory diseases. However, we still lack knowledge about mechanisms regulating TRM reactivation, in particular in autoimmune diseases. Here, we investigated in a model of TRM-driven central nervous system autoimmunity the transcriptional landscape of self-reactive brain TRM and the requirement of these cells for CD4+ T cell help.

Project description:Transcriptome profiling of lung tissues and lung CD8+ TRM during early phase of infection to investigate the mechanism of lung TRM cells during antigen re-exposure within 48hours. After P14 T cell transfer, PR8 infection would not induce P14 TRM cells, while PR8-gp33 would. Comparing the gene expression of lung tissues after LCMV Armstrong challenge at day 30 after PR8 or PR8-gp33 infection would help us understand the function of lung CD8+ TRM cells. Sorted TRM cells from mice challenged with LCMV Armstrong at day 30 after PR8-gp33 infection would reveal the activation mechanism of TRM cells.

Project description:Primary biliary cholangitis (PBC) is a cholestatic autoimmune liver disease secondary to an autoreactive T cell response against intrahepatic small bile ducts. Multiple murine models have demonstrated the critical role of effector CD8+T cells in this response and our work has used IL-12p40-/-IL-2Rα-/- mice (DKO mice) to study this issue. Herein we first demonstrated that use of either a CD8a knock-out or an anti-CD8a antibody prevents/reduces biliary immunopathology. Bulk and single-cell RNA sequencing analysis identifies CD8+ tissue resident memory T cells (Trm) in the liver of DKO mice, which highly express activation and cytotoxicity associated markers and have the ability to induce apoptosis of bile duct epithelial cells. Liver CD8+Trm cells also upregulate expression of several immune checkpoint molecules and in particular we identified PD-1 as a specific liver CD8+Trm cell marker in this model. Based on these data we constructed a novel chimeric antigen receptor containing a PD-L1 extracellular domain to target PD-1-expressing CD8+Trm cells. Importantly, treatment of DKO mice with PD-1 targeting CAR-T cells selectively depleted liver CD8+Trm cells in vivo and alleviated autoimmune cholangitis.

Project description:Tissue resident memory T cells (TRM) maintain immunity in diverse sites as determined in mouse models, while their establishment and role in human tissues has been difficult to assess. Here, we investigated human lung TRM generation, maintenance and function in airway samples obtained longitudinally from HLA-disparate lung transplant recipients, where donor and recipient T cells could be localized and tracked over time. Donor T cells persist specifically in the lungs (and not blood) of transplant recipients and express high levels of TRM signature markers including CD69, CD103, and CD49a, while lung-infiltrating recipient T cells gradually acquire TRM phenotypes over months in vivo. Single cell transcriptome profiling of airway T cells reveals that donor T cells comprise two TRM-like subsets with varying levels of expression of TRM-associated genes while recipient T cells comprised non-TRM and similar TRM-like subpopulations, suggesting de novo TRM generation. Transplant recipients exhibiting higher frequencies of persisting donor TRM experienced fewer adverse clinical events such as primary graft dysfunction and acute cellular rejection compared to recipients with low donor TRM persistence, suggesting that monitoring TRM dynamics could be clinically informative. Together, our results provide novel spatial and temporal insights into how human TRM develop, function, persist, and impact tissue integrity within the complexities of lung transplantation.

Project description:Gene expression profiling of repeatedly activated compared to recently activated Th1 cells to identify genes that play a role in chronic inflammatory disorders and may qualify as diagnostic or therapeutic targets; Upon activation under appropriate costimulatory conditions, naive T helper (Th) cells differentiate into Th2 or Th17 cells, each characterized by the expression of specific effector cytokines. In response to a repeated stimulation with antigen, Th cells develop a stable memory for the expression of those cytokines as well as for other secreted or membrane-associated factors. The stable memory for the expression of proinflammatory effector functions may explain the resistance of Th effector cells to conventional immunosuppressive therapy, and the inability of immunosuppression to cure chronic inflammation. The imprinting of the functional memory is based on epigenetic modifications and expression of distinct transcription factors. In this project, we compare the transcriptomes of once and repeatedly activated murine Th1 cells, to identify genes that induce and maintain the functional memory and control the persistence of pathogenic memory Th1 cells. This in turn might help to discriminate pathogenic versus protective cells in immunopathology and present novel targets for the diagnosis and therapy of chronic inflammatory disease.