Resident Memory Research Articles

Epstein-Barr virus infection induces tissue-resident memory T cells in mucosal lymphoid tissues.

EBV contributes to around 2% of all tumors worldwide. Simultaneously, more than 90% of healthy human adults persistently carry EBV without clinical symptoms. In most EBV carriers, it is thought that virus-induced tumorigenesis is prevented by cell-mediated immunity. Specifically, memory CD8+ T cells recognize EBV-infected cells during latent and lytic infection. Using a symptomatic primary infection model, similar to infectious mononucleosis (IM), we found EBV-induced CD8+ tissue resident memory T cells (TRMs) in mice with a humanized immune system. These human TRMs were preferentially established after intranasal EBV infection in nasal-associated lymphoid tissues (NALT), equivalent to tonsils, the primary site of EBV infection in humans. They expressed canonical TRM markers, including CD69, CD103, and BLIMP-1, as well as granzyme B, CD107a, and CCL5. Despite cytotoxic activity and cytokine production ex vivo, these TRMs demonstrated reduced CD27 expression and proliferation and failed to control EBV viral loads in the NALT during infection, although effector memory T cells (TEMs) controlled viral titers in spleen and blood. Overall, TRMs are established in mucosal lymphoid tissues by EBV infection, but primarily, systemic CD8+ T cell expansion seems to control viral loads in the context of IM-like infection.

Role of resident memory T cells in neuroinflammatory and neurodegenerative diseases in the central nervous system

Role of resident memory T cells in neuroinflammatory and neurodegenerative diseases in the central nervous system

Abstract A006: Tissue resident memory (TRM) T cells and dendritic cells form an in situ archetype for improved response to immune checkpoint therapy in metastatic melanoma

Abstract A006: Tissue resident memory (TRM) T cells and dendritic cells form an in situ archetype for improved response to immune checkpoint therapy in metastatic melanoma

Alarm Functions of PD-1+ Brain-Resident Memory T Cells.

Resident memory T cells (TRM cells) have been described in barrier tissues as having a "sensing and alarm" function where, upon sensing cognate Ag, they alarm the surrounding tissue and orchestrate local recruitment and activation of immune cells. In the immunologically unique and tightly restricted CNS, it remains unclear whether and how brain TRM cells, which express the inhibitory receptor programmed cell death protein 1 (PD-1), alarm the surrounding tissue during Ag re-encounter. Using mouse models, we reveal that TRM cells are sufficient to drive the rapid remodeling of the brain immune landscape through activation of microglia, dendritic cells, NK cells, and B cells, expansion of regulatory T cells, and recruitment of macrophages and monocytic dendritic cells. Moreover, we report that although PD-1 restrained granzyme B upregulation in brain TRM cells reactivated via viral peptide, we observed no apparent effect on cytotoxicity invivo, or downstream alarm responses within 48 h of TRM reactivation. We conclude that TRM cells are sufficient to trigger rapid immune activation and recruitment in the CNS and may have an unappreciated role in driving neuroinflammation.

Tissue resident memory T cells contribute to protectionagainst heterologousSARS-CoV-2 challenge.

Widespread vaccination and natural infection have resulted in greatly decreased rates of severe disease, hospitalization and death after subsequent infection or reinfection with SARS-CoV-2. New vaccine formulations are based on circulating strains of virus, which have tended to evolve to more readily transmit human to human and to evade the neutralizing antibody response. An assumption of this approach is that ancestral strains of virus will not recur. Recurrence of these strains could be a problem for individuals not previously exposed to ancestral spike protein by vaccination or infection. Here, we addressed this question by infecting mice with recent SARS-CoV-2 variants and then challenging them with a highly pathogenic mouse-adapted virus closely related to the ancestral Wuhan-1 strain (SARS2-N501YMA30). We found that challenged mice were protected from death and substantial weight loss, even though they generally had low or no neutralizing antibody response to SARS2-N501YMA30 at the time of reinfection. T cell depletion from the previously infected mice did not diminish infection against clinical disease, although it did result in delayed kinetics of virus clearance in the nasal turbinate and in some cases, in the lungs. Levels of tissue resident memory T cells were significantly elevated in the nasal turbinate of previously infected mice compared to mice that had no previous exposure to SARS-CoV-2. However, this phenotype was not seen in lung tissues. Together, these results indicate that the immune response to newly circulating variants afforded protection against re-infection with the ancestral virus that was at least in part T cell based.

Resident memory B cells are enriched in chronic rhinosinusitis with nasal polyps

BackgroundChronic rhinosinusitis with nasal polyps (CRSwNPs) is a chronic nasal and sinonasal inflammatory disease. Recently, resident memory B cells (BRMs) have been identified in the lungs, although not in the sinonasal mucosa. ObjectiveTo characterize memory B cell phenotypes with regards to patients with CRSwNPs and to identify BRMs in both normal sinonosal mucosa and CRSwNPs. MethodsCD19+ B cells were isolated from patients with CRSwNPs and analyzed using flow cytometry and immunohistochemistry. ResultsAlthough BRMs were found in the normal sinonasal mucosa, their numbers and frequencies tended to be limited. These findings were confirmed based on immunohistochemical analyses indicating an upregulation of CD69/CD45RB in tissue sections from CRSwNPs, although not in normal sinonasal mucosa. Accordingly, BRMs were established to be enriched in the nasal polyps isolated from patients with CRSwNPs. ConclusionOur findings in this study reveal that BRMs can be detected in normal sinonasal mucosa, although are significantly enriched in nasal polyps derived from patients with CRSwNP. These findings can contribute to gaining a more comprehensive understanding of the immune reactions associated with CRSwNP and facilitate the identification of potential therapeutic targets, such as anti-B cell therapy.

Cluster of differentiation-44 as a novel biomarker of lupus nephritis and its role in kidney inflammation and fibrosis.

CD44 is a transmembrane glycoprotein implicated in tissue inflammation and fibrosis. We investigated its role in kidney inflammation and fibrosis in a murine model of lupus nephritis (LN), and the clinico-pathological association of serum CD44 level in patients with biopsy-proven Class III/IV ± V LN. NZB/W F1 mice were treated with control IgG or anti-CD44 monoclonal antibody for 4 weeks and disease parameters assessed. Serum CD44 level in LN patients was determined by ELISA. Control groups included healthy subjects and patients with non-renal SLE or non-lupus renal disease. CD44 expression was absent in the normal kidney, but it was expressed in proximal and distal tubular epithelial cells and infiltrating cells in renal biopsies from patients with active proliferative LN. ScRNA-Seq datasets confirmed that CD44 was predominantly expressed in tubular cells and all immune cells identified in LN patients including tissue resident, inflammatory and phagocytic macrophages, Treg cells, effector and central memory CD4+ T cells, resident memory CD8+ T cells and naïve and activated B cells. Treatment of NZB/W F1 mice with anti-CD44 antibody preserved kidney histology and reduced proteinuria, tubulo-interstitial infiltration of CD3+, CD4+ and CD19+ immune cells, and mediators of kidney fibrosis compared to Control mice. Longitudinal studies showed that serum CD44 level increased prior to clinical renal flare by 4.5 months and the level decreased after treatment. ROC curve analysis showed that CD44 level distinguished patients with active LN from healthy subjects and patients with quiescent LN, active non-renal lupus, and non-lupus CKD (ROC AUC of 0.99, 0.96, 0.99 and 0.99 respectively). CD44 level correlated with leukocyte infiltration and interstitial inflammation scores in active LN kidney biopsies. Our findings suggest that CD44 plays a pathogenic role in renal parenchymal inflammation and fibrosis in active LN and monitoring CD44 may facilitate early diagnosis of flare.

A Prime-Boost Vaccination Approach Induces Lung Resident Memory CD8+ T Cells Derived from Central Memory T Cells That Prevent Tumor Lung Metastasis.

Memory T cells play a key role in immune protection against cancer. Vaccine-induced tissue-resident memory T (TRM) cells in the lung have been shown to protect against lung metastasis. Identifying the source of lung TRM cells can help to improve strategies, preventing tumor metastasis. Here, we found that a prime-boost vaccination approach using intramuscular DNA vaccine priming, followed by intranasal live-attenuated influenza-vectored vaccine (LAIV) boosting induced higher frequencies of lung CD8+ TRM cells compared with other vaccination regimens. Vaccine-induced lung CD8+ TRM cells, but not circulating memory T cells, conferred significant protection against metastatic melanoma and mesothelioma. Central memory T (TCM) cells induced by the DNA vaccination were major precursors of lung TRM cells established after the intranasal LAIV boost. Single-cell RNA sequencing analysis indicated that transcriptional reprogramming of TCM cells for differentiation into TRM cells in the lungs started as early as day 2 post the LAIV boost. Intranasal LAIV altered the mucosal microenvironment to recruit TCM cells via CXCR3-dependent chemotaxis and induced CD8+ TRM-associated transcriptional programs. These results identified TCM cells as the source of vaccine-induced CD8+ TRM cells that protect against lung metastasis. Significance: Prime-boost vaccination shapes the mucosal microenvironment and reprograms central memory T cells to generate lung resident memory T cells that protect against lung metastasis, providing insights for the optimization of vaccine strategies.

Sublingual immune cell clusters and dendritic cell distribution in the oral cavity.

The oral mucosa is the first line of defense against pathogenic bacteria and plays a vital role in maintaining tolerance to food antigens and commensal bacteria. We used CD11c reporter mice to visualize dendritic cells (DCs), a key immune cell population, in the oral cavity. We identified differences in DC density in each oral tissue region. Sublingual immune cell clusters (SLICs) extended from the lamina propria to the epithelium, where DCs and T cells resided in close contact with each other and innate lymphoid cells (ILCs). Targeted in situ photolabeling revealed that the SLICs comprised mostly of CD11c+CD11b+ DCs and were enriched for cDC1s and Langerhans cells. Although the frequency of T cell subsets was similar within and outside the SLICs, tissue resident memory T cells were significantly enriched within the clusters and cluster size increased in response to inflammation. Collectively, we found that SLICs form a unique microenvironment that facilitates T cell-DC interactions in the steady state and during inflammation. Since the oral mucosa is an important target for needle-free vaccination and sublingual immunotherapy to induce tolerogenic responses, the novel insight into the localized immunoregulation provided in this study may accelerate the development of these approaches.

Tissue resident memory CD4 + T cells are sustained by site-specific levels of self-renewal and replacement from precursors.

Tissue-resident memory T cells (T RM ) protect from repeated infections within organs and barrier sites. The breadth and duration of such protection is defined at minimum by three quantities; the rate at which new T RM are generated from precursors, their rate of self-renewal, and their loss rate through death, egress, or differentiation. Quantifying these processes in isolation is challenging. Here we combine genetic fate mapping tools and mathematical models to untangle these basic homeostatic properties of CD4 + T RM in skin and lamina propria (LP) of healthy adult mice. We show that CD69 + CD4 + T RM in skin reside for ∼ 24 days and self-renew more slowly, such that clones halve in size approximately every 5 weeks; and approximately 2% of cells are replaced daily from precursors. CD69 + CD4 + T RM in LP have shorter residencies ( ∼ 14 days) and are maintained largely by immigration (4-6% per day). We also find evidence that the constitutive replacement of CD69 + CD4 + T RM at both sites derives from circulating effectormemory CD4 + T cells, in skin possibly via a CD69 - intermediate. Our integrated approach maps the ontogeny of CD4 + T RM in skin and LP and exposes their dynamic and distinct behaviours, with continual seeding and erosion potentially impacting the duration of immunity at these sites.

Differential expression of HIV target cells CCR5 and α4β7 in tissue resident memory CD4 T cells in endocervix during the menstrual cycle of HIV seronegative women.

Ovarian hormones are known to modulate the immune system in the female genital tract (FGT). We sought to define the impact of the menstrual cycle on the mucosal HIV target cell levels, and tissue-resident CD4 T cells. Here, we characterized the distribution, phenotype, and function of CD4 T cells with special emphasis on HIV target cells (CCR5+ and α4β7+) as well as tissue-resident memory (TRM; CD69+ and CD103+) CD4 T cells in FGT of cycling women. Peripheral blood and Endocervical cells (EC-collected from cytobrush) were collected from 105 healthy women and performed multicolor flow cytometry to characterize the various subsets of CD4 T cells. Cervicovaginal lavage (CVL) were collected for cytokine analysis and plasma were collected for hormonal analysis. All parameters were compared between follicular and luteal phase of menstrual cycle. Our findings revealed no significant difference in the blood CD4 T cell subsets between the follicular and luteal phase. However, in EC, the proportion of several cell types was higher in the follicular phase compared to the luteal phase of menstrual cycle, including CCR5+α4β7-cells (p=0.01), CD69+CD103+ TRM (p=0.02), CCR5+CD69+CD103+ TRM (p=0.001) and FoxP3+ CD4 T cells (p=0.0005). In contrast, α4β7+ CCR5- cells were higher in the luteal phase (p=0.0004) compared to the follicular phase. In addition, we also found that hormonal levels (P4/E2 ratio) and cytokines (IL-5 and IL-6) were correlated with CCR5+ CD4 T cells subsets during the follicular phase of the menstrual cycle. Overall, these findings suggest the difference in the expression of CCR5 and α4β7 in TRM CD4 T cell subsets in endocervix of HIV seronegative women between the follicular and luteal phase. Increase in the CCR5+ expression on TRM subsets could increase susceptibility to HIV infection during follicular phase of the menstrual cycle.

Higher frequency of peripheral blood CD103+CD8+ T cells with lower levels of PD-1 and TIGIT expression related to favorable outcomes in leukemia patients.

Leukemia is a prevalent pediatric life-threatening hematologic malignancy with a poor prognosis. Targeting immune checkpoints (ICs) to reverse T cell exhaustion is a potentially effective treatment for leukemia. Tissue resident memory T (TRM) cells have been found to predict the efficacy of programmed death receptor-1 inhibitor (anti-PD-1) therapy in solid tumors. However, the IC characteristics of TRM cells in leukemia and their relationship with prognosis remain unclear. We employed multi-color flow cytometry to evaluate the frequencies of CD103+CD4+ and CD103+CD8+ T cells in the peripheral blood (PB) of patients with acute myeloid leukemia and B-cell acute lymphoblastic leukemia compared to healthy individuals. We examined the expression patterns of PD-1 and T cell immunoreceptor with immunoglobulin and ITIM domain (TIGIT) within the circulating CD103+ T cell subsets affected by leukemia. To further elucidate the immunological landscape, we assessed the differentiation status of CD103+ T cells across various disease states in patients with leukemia. Our findings showed a significant increase in the frequency of CD103+CD8+ T cells in the PB of patients with leukemia who had achieved complete remission (CR) compared to those in the de novo (DN) and relapsed/refractory (RR) stages. This increase was accompanied by a notable decrease in the expression levels of PD-1 and TIGIT in CD103+CD8+ T cells in the CR stage. Additionally, our analysis revealed a higher proportion of CD103+CD8+ T cells in the central memory (TCM) and effector memory (TEM) subsets of the immune profile. Notably, the proportions of CD103+ naïve T cells, CD103+ TEM, and CD103+ terminally differentiated T cells within the CD8+ T cell population were significantly elevated in patients with CR compared to those in the DN/RR stages. The data indicate that circulating higher frequency of CD103+CD8+ T cells with lower expression of PD-1 and TIGIT are associated with favorable outcomes in patients with leukemia. This suggests a potential role of TRM cells in leukemia prognosis and provides a foundation for developing targeted immunotherapies.

A lymphocyte chemoaffinity axis for lung, non-intestinal mucosae and CNS.

Tissue-selective chemoattractants direct lymphocytes to epithelial surfaces to establish local immune environments, regulate immune responses to food antigens and commensal organisms, and protect from pathogens. Homeostatic chemoattractants for small intestines, colon, and skin are known1 2, but chemotropic mechanisms selective for respiratory tract and other non-intestinal mucosal tissues (NIMT) remain poorly understood. Here we leveraged diverse omics datasets to identify GPR25 as a lymphocyte receptor for CXCL17, a chemoattractant cytokine whose expression by epithelial cells of airways, upper gastrointestinal and squamous mucosae unifies the NIMT and distinguishes them from intestinal mucosae. Single-cell transcriptomic analyses show that GPR25 is induced on innate lymphocytes prior to emigration to the periphery, and is imprinted in secondary lymphoid tissues on activated B and T cells responding to immune challenge. GPR25 characterizes B and T tissue resident memory and regulatory T lymphocytes in NIMT and lungs in humans and mediates lymphocyte homing to barrier epithelia of the airways, oral cavity, stomach, biliary and genitourinary tracts in mouse models. GPR25 is also expressed by T cells in cerebrospinal fluid and CXCL17 by neurons, suggesting a role in CNS immune regulation. We reveal widespread imprinting of GPR25 on regulatory T cells, suggesting a mechanistic link to population genetic evidence that GPR25 is protective in autoimmunity3,4. Our results define a GPR25-CXCL17 chemoaffinity axis with the potential to integrate immunity and tolerance at non-intestinal mucosae and the CNS.

High proportion of PD-1 and CD39 positive CD8+ tissue resident T lymphocytes correlates with better clinical outcome in resected human oesophageal adenocarcinoma

ObjectiveTo understand the CD8+ tumour infiltrating lymphocyte (TIL) compartment of oesophageal adenocarcinoma (OAC) with regards to markers of lymphocyte exhaustion, tissue residency and to identify possible reasons behind differential responses to therapy.DesignTumour samples from 44 patients undergoing curative resection for OAC were assessed by flow cytometry for presence of antigen-experienced TILs and markers of activation and exhaustion. Populations of PD-1 and CD39 positive OAC TILs were sorted, and bulk RNA sequencing undertaken using a modified SmartSeq2 protocol. Flow cytometric assessment of functionality was completed.ResultsA higher proportion of antigen experienced CD8+ OAC TILs was associated with improved survival following surgery; while, high double positivity (DP) for PD-1 and CD39 among these TILs also correlated significantly with outcome. These DP TILs possess a minority population which is positive for the markers of exhaustion TIM3 and LAG3. Transcriptomic assessment of the PD-1 and CD39 DP TILs demonstrated enrichment for a tissue resident memory T lymphocyte (TRM) phenotype associated with improved survival in other cancers, reinforced by positivity for the canonical TRM marker CD103 by flow cytometry. This population demonstrated maintained functional capacity both in their transcriptomic profile, and on flow cytometric assessment, as well as preserved proliferative capacity.ConclusionResected OAC are variably infiltrated by PD-1 and CD39 DP TILs, an abundance of which among lymphocytes is associated with improved survival. This DP population has an increased, but still modest, frequency of TIM3 and LAG3 positivity compared to DN, and is in keeping with a functionally competent TRM phenotype.

Abstract P200: Immune memory contributes to chronic hypertension recurrence

Keeping blood pressure under control is a challenge in hypertension treatment because high blood pressure quickly returns with a momentary lapse in treatment or a high-salt diet. We have previously reported the CD8+ T cells (CD8Ts) in the kidney can drive aberrant sodium handling to aggravate blood pressure. Recently, our new findings suggest that these CD8Ts remain long-term within the kidney. Here, we propose these CD8Ts have developed into a resident memory (Trm) population with the aid of TGFβ signaling, and this residency continually aggravates and leads to the recurrence of hypertension . To explore this hypothesis, we utilized two mouse models of hypertension, including a classic DOCA-salt model and a novel Angiotensin II (Ang II) induced salt memory model, with continuous blood pressure monitored by radiotelemetry. In the Ang II-induced salt memory model, the mice were administered Ang II and high salt for a week before a resting period to restore normal blood pressure. Thereafter, the mice were given a second high salt challenge to model the high salt-driven recurrence of hypertension. Mouse strains include both wild-type (WT) and a T-cell specific TGFβRII KO (Tsp-TGFβR KO), which has T cells unable to develop into Trm due to the reliance of Trm on TGFβ signaling. T cells were analyzed with flow cytometry. In the DOCA-salt model, WT mice developed a significant CD8Trm population within the kidney. In contrast, TSP-TGFβR KO mice, which lack the ability to develop Trm, had an attenuated development of hypertension with DOCA-salt treatment. Testing the capability for hypertension to recur, both WT and Tsp-TGFβR KO mice experienced a similar degree of hypertension with Ang II-salt treatment. However, only the WT had a significant expansion of Trm and demonstrated the clinical manifestation of recurring hypertension with the rapid increase of blood pressure with a high salt challenge. Isolating the T cells from the kidneys confirmed that the significant CD8Trm population development in the WT was not present in the Tsp-TGFβR KO. In summary, our findings suggest that the memory T cell population developed in the kidney during hypertension instills a perpetual memory for salt sensitivity in hypertension. Without the ability to develop this memory population, mice are protected against this recurrence of high-salt-induced hypertension.

540. INFILTRATION OF RESECTED OESOPHAGEAL ADENOCARCINOMA WITH ANTIGEN-EXPERIENCED PD-1 AND CD39 POSITIVE CD8+ TISSUE RESIDENT MEMORY CELLS CORRELATE WITH IMPROVED SURVIVAL

Abstract Background The development of novel treatments for oesophageal adenocarcinoma (OAC) represents an area of significant unmet need. Despite the application of immune checkpoint blockade alongside chemotherapy as standard of care for some patients with metastatic OAC, responses to immunotherapies are modest and 5-year survival is 17%. The reasons for this remains unclear and while tumour infiltration with CD8+ T lymphocytes (TILs) at the time of resection is associated with improved outcomes, this heterogeneous population remains incompletely characterised in OAC. Tissue resident memory cells (TRM) are increasingly understood as key mediators of immunotherapy response but their role in OAC is poorly understood. Methods Tumour samples were accessed by punch biopsy from the central portion of cancers resected from 44 patients undergoing curative surgery for OAC. Samples were assessed by multi-parametric flow cytometry for the presence of antigen-experienced TILs and markers of activation and exhaustion. Populations of antigen-experienced PD-1 and CD39 positive CD8+ OAC TILs were sorted, and bulk RNA sequencing (RNAseq) undertaken using a modified SmartSeq2 protocol allowing differential gene expression analysis and gene set enrichment analysis. Flow cytometric assessment of functionality was completed. Results Resected OAC are often highly infiltrated with antigen experienced CD8+ TILs expressing high levels of PD-1 and CD39 and an abundance of this population correlates with improved survival (%PD-1/CD39+ >Median, OS HR 0.12). RNAseq of sorted TILs identified this PD-1+ and CD39+ lymphocyte population as enriched for precursor exhausted-like CD8+ TRM (NES 2.01 p=0.00). This is correlated by their CD103+ and TIM3- predominance on flow cytometry in keeping with TRMsassociated with immunotherapy response in other cancers. This population demonstrated a maintained proliferative potential, an ability to degranulate and produce the key effector molecules IFN-γ, TNF-α and Granzyme B. Conclusions An abundance of a PD-1 and CD39 positive CD8+ TIL population, consistent with a precursor exhausted-like TRM population with maintained proliferative and functional capacity, is observed to correlate with improved outcomes following curative surgery for OAC. This TRM population is consistent with analogous populations observed to be responsible for immunotherapy response in other cancers and their identification may predict benefit from such approaches in OAC and allow better patient selection for treatment with immune checkpoint inhibitors.

450. TISSUE RESIDENT MEMORY CELLS: CORRELATING THE PHENOTYPIC AND FUNCTIONAL CAPABILITIES OF A POTENTIAL TUMOUR REACTIVE CELL POPULATION IN OESOPHAGEAL ADENOCARCINOMA

Abstract Background Oesophageal adenocarcinoma (OAC) is a disease with a high mortality and morbidity rate. Immunotherapy has recently demonstrated progress in the treatment of OAC but its impact on long term survival is currently uncertain. Tissue resident memory (TRM) T cells are a subset of lymphocytes within the tumour/tissue infiltrating lymphocyte (TIL) milieu that has attracted considerable interest within cancer immunology. Although TRM cells have been associated with better outcomes in multiple cancer types there is a lack of knowledge of their role in OAC. This study aims to critically correlate the phenotype of TRM with their functional capacity in this disease. Methods 33 patients undergoing surgical resection for OAC were recruited and consented for collection of fresh tumour (T), adjacent normal tissue (AN), and peripheral blood. Peripheral blood mononuclear cell (PBMC) from blood and infiltrating lymphocytes from T and AN were isolated using standard density gradient and enzymatic digestion protocols. Multiparametric flow cytometry was performed on 12 patients using matched PBMC, T and AN infiltrating lymphocytes for phenotypic analysis and 21 patients for functional analysis following cell stimulation assay. BD FACSymphony was used for data acquisition and data analysed on FlowJo version 10.10. Statistical analysis was carried out using GraphPad Prism. Results TRM (CD103+CD69+) dominated the CD8+ T cell population of T and AN TIL. Expression of checkpoint proteins PD1+ and CD39+, a marker of tumour reactivity, was identified on CD8+ TRM and CD8+ non TRM in TIL. The differentiation status of TRM within memory lineages demonstrated that TRM express a higher proportion of effector memory cells (CCR7-CD45RA) compared to those in blood. TRM cells also showed lower expression of the transcription factors EOMES, TBET and TCF compared to CD8+ cells within PBMC. Moreover, tumour CD8+ TRM populations had reduced ability to produce IL-2 following stimulation compared to adjacent normal TRM populations. Conclusion TRM make up a large proportion of CD8+ T cell within the tumour microenvironment (TME) of OAC. TRM generation is associated with the downregulation of T-Box transcription factors EOMES and TBET and expression of an effector memory phenotype with reduction of the stem-like transcription factor, TCF. High levels of CD39+ indicate a strong level of activation but the increased PD1 expression and reduced capability to produce IL2 indicate functional impairment suppressed within the TME. An opportunity may exist to reverse this with novel immunotherapeutic agents.

322.7: Single cell RNA-sequencing delineates CD8+ tissue resident memory T cells maintaining rejection in liver transplantation.

322.7: Single cell RNA-sequencing delineates CD8+ tissue resident memory T cells maintaining rejection in liver transplantation.

Epicardial adipose tissue resident memory T cells in atrial fibrillation.

Epicardial adipose tissue resident memory T cells in atrial fibrillation.

O14 KIDNEY RESIDENT MEMORY T CELLS MEDIATE THE CHRONIC PROGRESSION OF HYPERTENSION

A significant challenge in treating hypertension is insufficient blood pressure (BP) control and its recurrence. Previously, we described the contribution of CD8 T cells (CD8Ts) to the pathogenesis of salt-sensitive hypertension. Notably, despite antihypertensive therapy temporarily lowering BP in hypertensive mice, the T cell residency was not disrupted within the kidneys, and hypertension recurred when treatment was ceased. We hypothesize that the CD8Ts established a long-living resident memory (Trm) population in the kidney that instigates the recurrence of hypertension. To examine this, we utilized both wild-type (WT) and T-cell-specific KO of TGFβRII (Tsp-TGFβRKO) mice, which prevents the formation of Trms. Blood pressure was recorded continuously with radiotelemetry. Hypertension was induced with the classic DOCA-salt model and an Angiotensin II (Ang II)-induced salt memory model to mimic the clinical recurrence of hypertension with high salt intake. In this salt-memory model, a one-week infusion of Ang II paired with high salt-induced hypertension before being allowed to return to normal blood pressure. A chronic high salt intake challenge then tested the recurrence of hypertension. Both splenic and renal T cell populations were characterized using flow cytometry. As expected, DOCA-salt treatment led to salt-sensitive hypertension in WT mice along with the development of a significant CD8Trm population within their kidneys. These CD8Trms were notably diminished in the kidneys of DOCA-treated Tsp-TGFβRKO mice who also had attenuated blood pressure elevation. While testing the recurrence of hypertension during the Ang II-induced salt-memory model both WT and Tsp-TGFβKO reached the same degree of hypertension during Ang II-salt and baseline blood pressure before and after Ang II-salt. However, only the WT developed Trm and had the recurrence of hypertension with high salt challenge whereas both were lost in the Tsp-TGFβKO mice. In summary, our study unveils the critical role of kidney CD8Trms in contributing to salt-sensitive hypertension and its recurrence. This leads to targeting key molecules that initiate the development of Trms to mitigate the persistency of hypertension.