Project description:CD8+ memory T cells are critical components of protective immunity to intracellular pathogens and tumors. While many memory CD8+ T cells recirculate throughout the body, others remain lodged in tissues and guard common sites of pathogen entry. Contributions of the specific tissue environment to tissue-resident memory T cell (Trm) differentiation and homeostasis have been implicated but are not well understood. Here, we define the diversity of gene expression and genome accessibility by mouse CD8+ Trm populations in distinct organs and identify molecules critical for Trm generated in response to acute viral infection. We find that CD8+ TRM across different tissues possess both shared and tissue-specific transcriptional and epigenetic signatures. Notably, Trm in the intestine and salivary gland express TGFb-induced genes and are maintained by ongoing TGFb signaling while those in the fat, kidney, and liver are not. By constructing transcriptional-regulatory networks for each Trm population, we identify the repressor Hic1 as a critical regulator of Trm differentiation, particularly for Trm of the small intestine. This study provides a framework for understanding how Trm adapt to distinct tissue environments and identifies tissue-specific transcriptional regulators that mediate these adaptations, informing strategies to enhance protective memory responses at the sites most vulnerable to infection.

Project description:CD8+ memory T cells are critical components of protective immunity to intracellular pathogens and tumors. While many memory CD8+ T cells recirculate throughout the body, others remain lodged in tissues and guard common sites of pathogen entry. Contributions of the specific tissue environment to tissue-resident memory T cell (Trm) differentiation and homeostasis have been implicated but are not well understood. Here, we define the diversity of gene expression and genome accessibility by mouse CD8+ Trm populations in distinct organs and identify molecules critical for Trm generated in response to acute viral infection. We find that CD8+ TRM across different tissues possess both shared and tissue-specific transcriptional and epigenetic signatures. Notably, Trm in the intestine and salivary gland express TGFb-induced genes and are maintained by ongoing TGFb signaling while those in the fat, kidney, and liver are not. By constructing transcriptional-regulatory networks for each Trm population, we identify the repressor Hic1 as a critical regulator of Trm differentiation, particularly for Trm of the small intestine. This study provides a framework for understanding how Trm adapt to distinct tissue environments and identifies tissue-specific transcriptional regulators that mediate these adaptations, informing strategies to enhance protective memory responses at the sites most vulnerable to infection.

Project description:CD8+ memory T cells are critical components of protective immunity to intracellular pathogens and tumors. While many memory CD8+ T cells recirculate throughout the body, others remain lodged in tissues and guard common sites of pathogen entry. Contributions of the specific tissue environment to tissue-resident memory T cell (Trm) differentiation and homeostasis have been implicated but are not well understood. Here, we define the diversity of gene expression and genome accessibility by mouse CD8+ Trm populations in distinct organs and identify molecules critical for Trm generated in response to acute viral infection. We find that CD8+ TRM across different tissues possess both shared and tissue-specific transcriptional and epigenetic signatures. Notably, Trm in the intestine and salivary gland express TGFb-induced genes and are maintained by ongoing TGFb signaling while those in the fat, kidney, and liver are not. By constructing transcriptional-regulatory networks for each Trm population, we identify the repressor Hic1 as a critical regulator of Trm differentiation, particularly for Trm of the small intestine. This study provides a framework for understanding how Trm adapt to distinct tissue environments and identifies tissue-specific transcriptional regulators that mediate these adaptations, informing strategies to enhance protective memory responses at the sites most vulnerable to infection.

Project description:CD8+ memory T cells are critical components of protective immunity to intracellular pathogens and tumors. While many memory CD8+ T cells recirculate throughout the body, others remain lodged in tissues and guard common sites of pathogen entry. Contributions of the specific tissue environment to tissue-resident memory T cell (Trm) differentiation and homeostasis have been implicated but are not well understood. Here, we define the diversity of gene expression and genome accessibility by mouse CD8+ Trm populations in distinct organs and identify molecules critical for Trm generated in response to acute viral infection. We find that CD8+ TRM across different tissues possess both shared and tissue-specific transcriptional and epigenetic signatures. Notably, Trm in the intestine and salivary gland express TGFb-induced genes and are maintained by ongoing TGFb signaling while those in the fat, kidney, and liver are not. By constructing transcriptional-regulatory networks for each Trm population, we identify the repressor Hic1 as a critical regulator of Trm differentiation, particularly for Trm of the small intestine. This study provides a framework for understanding how Trm adapt to distinct tissue environments and identifies tissue-specific transcriptional regulators that mediate these adaptations, informing strategies to enhance protective memory responses at the sites most vulnerable to infection.

Project description:CD8 tissue-resident memory T cells (TRM) provide frontline immunity in mucosal tissues. The mechanisms regulating CD8 TRM maintenance, heterogeneity, protective and pathological functions are largely elusive. Here we identify an epitope-specific CD8 TRM population that is maintained by in situ MHC-I and B7 signaling following acute influenza infection. These TRM cells co-exhibit exhausted-like phenotypes and memory features, and provide heterologous immunity against secondary infection. PD-L1 blockade at the memory stage promotes exhausted-like TRM rejuvenation and secondary immunity at the cost of developing post-infection fibrotic sequelae. Increased numbers of CD8 TRM cells are observed in the lungs of pulmonary fibrosis patients compared to control patients. Thus, TRM exhaustion results from a tissue-specific cellular adaptation to balance fibrotic sequelae and secondary immunity.

Project description:Immunosurveillance of secondary lymphoid organs (SLO) is performed by central memory T cells that recirculate through blood. Resident memory T cells (TRM) remain parked in nonlymphoid tissues and often stably express CD69. We recently identified TRM within SLO, and this study addresses knowledge gaps in their origin and phenotype. Parabiosis of ‘dirty’ mice revealed that CD69 expression is insufficient to infer stable residence. Using selective depletion strategies, parabiosis, imaging, tissue grafting, and photoactivatable T cells, we report that restimulation of TRM within the skin or mucosa results in a substantial increase in TRM that patrol all regions of draining lymph nodes. SLO TRM were derived from nonlymphoid tissue residents. Transcriptional profiling and flow cytometry revealed a refined phenotype shared between both nonlymphoid and SLO TRM. These data demonstrate the nonlymphoid origin of SLO TRM and suggest vaccination strategies by which memory CD8 T cell immunosurveillance can be regionalized to specific lymph nodes.

Project description:CD8 tissue-resident memory T (TRM) cells provide front-line protection at barrier tissues; however, mechanisms regulating TRM cell development are not completely understood. Priming dictates the migration of effector T cells to the tissue, while factors in the tissue induce in situ TRM cell differentiation. Whether priming also regulates in situ TRM cell differentiation uncoupled from migration is unclear. Here, we demonstrate that T cell priming in the mesenteric lymph nodes (MLN) regulates CD103+ TRM cell differentiation in the intestine. In contrast, T cells primed in the spleen were impaired in the ability to differentiate into CD103+ TRM cells after entry into the intestine. MLN priming initiated a CD103+ TRM cell gene signature and licensed rapid CD103+ TRM cell differentiation in response to factors in the intestine. Licensing was regulated by retinoic acid signaling and primarily driven by factors other than CCR9 expression and CCR9-mediated gut homing. Thus, the MLN is specialized to promote intestinal CD103+ CD8 TRM cell development by licensing in situ differentiation.

Project description:Tissue resident memory (Trm) represent a newly described memory T cell population. We have previously characterized a population of Trm that persists within the brain following acute virus infection. Although capable of providing marked protection against a subsequent local challenge, brain Trm do not undergo recall expansion following dissociation from the tissue. Furthermore, these Trm do not depend on the same survival factors as the circulating memory T cell pool as assessed either in vivo or in vitro. To gain greater insight into this population of cells we compared the gene-expression profiles of Trm isolated from the brain to circulating memory T cells isolated from the spleen following an acute virus infection. Trm displayed altered expression of genes involved in chemotaxis, expressed a distinct set of transcription factors and overexpressed several inhibitory receptors. Cumulatively, these data indicates that Trm are a distinct memory T cell population disconnected from the circulating memory T cell pool and displaying a unique molecular signature which likely results in optimal survival and function within their local environment. 13 samples were analyzed: 5 replicates of memory OT-I CD8+.CD103- T cells isolated from the spleen of mice on day 20 p.i. with VSV-OVA. 5 replicates of memory OT-I CD8+CD103+ T cells isolated from the brain of mice on day 20 p.i. with VSV-OVA; and 3 replicates of memory OT-I.CD8+ CD103- T cells isolated from the brain of mice on day 20 p.i. with VSV-OVA

Project description:Tissue-resident memory T (TRM) cells provide rapid and superior control of localized infections. The transcription factor Runx3 was recently identified as a master regulator of CD8+ T cell tissue residency. However, Runx3 also drives CD8+ T cell lineage commitment and is repressed in CD4+ T cells, raising the possibility that this transcription factor defines a form of tissue residency unique to the CD8+ T cell subset. Here, we show that as a direct consequence of Runx3-deficiency, CD4+ TRM cells in epithelia lack the TGFb-responsive transcriptional network that underpins CD8+ TRM cell residency. Ectopic Runx3 expression in CD4+ T cells rescued this transcriptional program to promote prolonged survival, decreased tissue egress and a microanatomical redistribution towards epithelial layers that combined, resulted in superior local immune protection. Our results thus reveal a mechanistic discordance between CD4+ and CD8+ TRM cell formation in barrier tissues that is controlled by Runx3. Consequently, CD4+ TRM cells are unable to adopt a type of tissue residency that is intrinsically accessible to the CD8+ TRM cell subset.

Project description:Tissue-resident memory CD8+T (TRM) cells are a distinct component of the memory T cell armamentarium found in many tissues. Recent studies have shown disparities among TRM cells across tissues, but it is unknown whether there is heterogeneity among TRM cells from differentanatomic compartments of the small intestine and colon. Herewe show that intestinal TRM cells exhibit distinctive patterns of cytokine and granzyme expression, along with substantial transcriptional, epigenetic, and functional heterogeneity. We elucidate unexpected tissue- and context-specific regulatory roles for the T-box transcription factor Eomesodermin (Eomes), previously described to repressskin, liver, and kidney TRM cell formation, in promoting the maintenance of established TRM cells in the small intestine, but not in the colon. Taken together, these data provide previously unappreciated insights into the heterogeneity and differential requirements for the formation vs. maintenance of TRMcells from the small intestine and colon.