Project description:The extent to which tissue-resident memory T (TRM) cells in transplanted organs possess alloreactivity is uncertain. This study investigates the alloreactive potential of TRM cells in kidney explants from four patients who experienced severe acute rejection leading to graft loss. Alloreactive T-cell receptors (TCRs) clones were identified in pre-transplant blood samples through mixed lymphocyte reactions, followed by single-cell RNA and TCR sequencing of the proliferated recipient T cells. Subsequently, these TCR clones were traced in the TRM cells of kidney explants, which were also subjected to single-cell RNA and TCR sequencing. The proportion of TRM cells expressing an alloreactive TCR in the four kidney explants varied from 0% to 9%. Notably, these alloreactive TCRs were predominantly found among CD4+ and CD8+ TRM cells with an effector phenotype. Intriguingly, alloreactive clones were present not only in recipient-derived TRM cells but also in donor-derived TRM cells, constituting up to 4% of the donor population, suggesting the presence of self-reactive TRM cells. Overall, our study demonstrates that T cells with alloreactive potential present in the peripheral blood prior to transplantation can infiltrate the kidney transplant and adopt a TRM phenotype.

Project description:Tissue-resident memory T (TRM) cells provide key adaptive immune responses in infection, cancer, and autoimmunity. However transcriptional heterogeneity of human intestinal TRM cells remains undefined. Here, we investigated transcriptional and functional heterogeneity of human TRM cells through study of donor-derived intestinal TRM cells from intestinal transplant recipients. Single-cell transcriptional profiling identified two distinct transcriptional states of CD8+ TRM cells, delineated by ITGAE and ITGB2 expression. We defined a transcriptional signature discriminating these two CD8+ populations, including differential expression of cytotoxicity- and residency-associated genes. Flow cytometry of recipient-derived cells infiltrating the graft and lymphocytes from healthy gut confirmed the two CD8+ TRM phenotypes. CD103+ CD8+ TRM cells produced IL-2, and demonstrated greater polyfunctional cytokine production, while β2-integrin+ CD69+ CD103- TRM cells had higher granzyme expression. Phenotypic and functional analysis of intestinal CD4+ T cells identified many parallels, including a distinct β2-integrin+ population. Together, these results describe the transcriptional, phenotypic, and functional heterogeneity of human intestinal CD4+ and CD8+ TRM cells.

Project description:Tissue-resident memory T (TRM) cells provide key adaptive immune responses in infection, cancer, and autoimmunity. However transcriptional heterogeneity of human intestinal TRM cells remains undefined. Here, we investigated transcriptional and functional heterogeneity of human TRM cells through study of donor-derived intestinal TRM cells from intestinal transplant recipients. Single-cell transcriptional profiling identified two distinct transcriptional states of CD8+ TRM cells, delineated by ITGAE and ITGB2 expression. We defined a transcriptional signature discriminating these two CD8+ populations, including differential expression of cytotoxicity- and residency-associated genes. Flow cytometry of recipient-derived cells infiltrating the graft and lymphocytes from healthy gut confirmed the two CD8+ TRM phenotypes. CD103+ CD8+ TRM cells produced IL-2, and demonstrated greater polyfunctional cytokine production, while β2-integrin+ CD69+ CD103- TRM cells had higher granzyme expression. Phenotypic and functional analysis of intestinal CD4+ T cells identified many parallels, including a distinct β2-integrin+ population. Together, these results describe the transcriptional, phenotypic, and functional heterogeneity of human intestinal CD4+ and CD8+ TRM cells.

Project description:Measurement of specific gene expression in clinical samples is a promising approach for monitoring the recipient immune status to the graft in organ transplantation. Identification of biomarker genes closely associated with tolerance or rejection is critical for this monitoring protocol. Unlike previous studies, our microarray analysis focused on donor antigen-reactive T cells, which were prepared by collecting CD69+ T cells from cocultures of recipient peripheral T cells and donor antigen-presenting cells. A comparison of different recipient groups enabled us to identify several tolerance- and rejection-correlated biomarker genes, including previously unknown genes. By measuring biomarker gene expression in the CD69+ T cell fraction using quantitative reverse-transcription polymerase chain reaction, we were able to precisely detect the immune status of recipients relative to their graft. Full-thickness donor (BDF1; C57BL/6 x DBA/2) tail skin was grafted onto recipient (C57BL/6) mice. Tolerance to the graft was induced by donor specific transfusion combined with administration of anti-CD40L Ab (MR-1). Total T lymphocytes were prepared from spleen and lymph nodes of tolerant recipient mice on day 100 after skin transplantation, untreated recipient mice on day 7, and ungrafted, healthy C57BL/6 mice and used as tolerant, rejecting and naïve T lymphocyte samples, respectively. In order to isolate alloantigen-reactive cells, T lymphocytes were cocultured with donor T cell-depleted splenocytes for 20-21 hours and then separated into two subpopulations based on CD69 expression using fluorescence cell sorter. Total RNA was extracted from these CD69+ and CD69- T cells and subjected to microarray using Illunima MouseWG-6 Expression BeadChip. All data analysis and visualization of differentially expressed genes was conducted using Illumina GenomeStudio v2009.2 (Gene Expression Module v1.5.4) and R statistical language v2.6.1. Candidate tolerance genes were defined as the common genes satisfying the following criteria; 1) 1.5 fold or higher expression in CD69+ T cells isolated from tolerant recipients than those from naïve mice, 2) 1.5 fold or higher expression in CD69+ T cells than CD69- T cells from tolerant mice, 3) 500 or higher average signal measured in CD69+ T cells from tolerant mice. The criteria for candidate rejection genes were 1) 1.5 fold or higher expression in CD69+ T cells isolated from rejecting recipients than those from tolerant mice, 2) 1.5 fold or higher expression in CD69+ T cells than CD69- T cells from rejecting mice, 3) 500 or higher average signal measured in CD69+ T cells from rejecting mice.

Project description:Measurement of specific gene expression in clinical samples is a promising approach for monitoring the recipient immune status to the graft in organ transplantation. Identification of biomarker genes closely associated with tolerance or rejection is critical for this monitoring protocol. Unlike previous studies, our microarray analysis focused on donor antigen-reactive T cells, which were prepared by collecting CD69+ T cells from cocultures of recipient peripheral T cells and donor antigen-presenting cells. A comparison of different recipient groups enabled us to identify several tolerance- and rejection-correlated biomarker genes, including previously unknown genes. By measuring biomarker gene expression in the CD69+ T cell fraction using quantitative reverse-transcription polymerase chain reaction, we were able to precisely detect the immune status of recipients relative to their graft. Full-thickness donor (BDF1; C57BL/6 x DBA/2) tail skin was grafted onto recipient (C57BL/6) mice. Tolerance to the graft was induced by donor specific transfusion combined with administration of anti-CD40L Ab (MR-1). Total T lymphocytes were prepared from spleen and lymph nodes of tolerant recipient mice on day 21 and 100 after skin transplantation, untreated recipient mice on day 7, and ungrafted, healthy C57BL/6 mice and used as early tolerant, tolerant, rejecting and naïve T lymphocyte samples, respectively. In order to isolate alloantigen-reactive cells, T lymphocytes were cocultured with donor BM-DCs for 20-21 hours and then separated into two subpopulations based on CD69 expression using fluorescence cell sorter. Total RNA was extracted from these CD69+ and CD69- T cells and subjected to microarray using Illunima MouseRef-8 Expression BeadChip. All data analysis and visualization of differentially expressed genes was conducted using Illumina BeadStudio v3.1.3 (Gene Expression Module v3.3.8), Array Assist 5.5.1 (Stratagene) and R 2.4.1(www.r-project.org). Candidate tolerance genes were defined as the common genes satisfying the following criteria; 1) 1.5 fold or higher expression in CD69+ T cells isolated from tolerant recipients than those from naïve mice, 2) 1.5 fold or higher expression in CD69+ T cells than CD69- T cells from tolerant mice, 3) 500 or higher average signal measured in CD69+ T cells from tolerant mice. The criteria for candidate rejection genes were 1) 1.5 fold or higher expression in CD69+ T cells isolated from rejecting recipients than those from tolerant mice, 2) 1.5 fold or higher expression in CD69+ T cells than CD69- T cells from rejecting mice, 3) 500 or higher average signal measured in CD69+ T cells from rejecting mice.

Project description:Type 1 diabetes (T1D) results from insulin insufficiency due to the loss or dysfunction of pancreatic beta cells following T cell-mediated autoimmune attack. Currently, the only long-term therapy is daily exogenous insulin replacement. The ideal curative approach is the durable restoration of functional islets via transplantation with or without immunosuppression or immune modulation. To date, the limiting factors impeding realization of this goal is the lack of a cost effective and limitless source of high-quality islets suitable for transplantation and the ability to provide long-term islet graft acceptance without prolonged need for deleterious immunosuppression. Ongoing clinical trials are testing the suitability of islets derived from human induced pluripotent stem cells (iPSC); however, long-term acceptance of these or any other islet graft will require a clinically effective therapeutic strategy to prevent engrafted islet destruction by pre-existing islet-antigen specific T cells. While current immunomodulatory strategies focus on autologous T regulatory (Treg) cell expansion or the use of broad immunosuppression, here we demonstrate in the NOD mouse model for T1D that autologous islet graft acceptance can be achieved by the targeted elimination of (re)-activated islet-reactive CD4+ and CD8+ T effector (Teff) cells in the initial post-transplantation period by using a short-acting, combination therapy that results in the elimination of islet-reactive Teff cells by exacerbation of their natural DNA damage response (DDR) to drive apoptosis while at the same time maintaining endogenous Treg cell function and reducing the effector function of residual islet-reactive T cells.

Project description:Immune cells must adapt to different environments during an immune response. We studied the adaptation of CD8+ T cells to the intestinal microenvironment and how this process shapes tissue resident CD8+ T cells (TRM) in the gut. CD8+ T cells progressively remodel their transcriptome and surface phenotype as they acquire gut residency, and downregulate mitochondrial gene expression. Human and mouse gut-resident CD8+ T cells have reduced mitochondrial mass, but maintain a viable energy balance to sustain function. We found that the intestinal microenvironment is rich in prostaglandin E2 (PGE2), which drives mitochondrial depolarization in CD8+ T cells. Consequently, they engage autophagy to clear depolarized mitochondria, and enhance glutathione synthesis to scavenge reactive oxygen species (ROS). Impairing PGE2 sensing promotes TRM accumulation, while tampering with autophagy and glutathione negatively impacts the TRM pool. Thus, a PGE2-autophagy-glutathione axis defines the metabolic adaptation of CD8+ T cells to the intestinal microenvironment, to ultimately influence the TRM pool.

Project description:Immune cells must adapt to different environments during an immune response. We studied the adaptation of CD8+ T cells to the intestinal microenvironment and how this process shapes tissue resident CD8+ T cells (TRM) in the gut. CD8+ T cells progressively remodel their transcriptome and surface phenotype as they acquire gut residency, and downregulate mitochondrial gene expression. Human and mouse gut-resident CD8+ T cells have reduced mitochondrial mass, but maintain a viable energy balance to sustain function. We found that the intestinal microenvironment is rich in prostaglandin E2 (PGE2), which drives mitochondrial depolarization in CD8+ T cells. Consequently, they engage autophagy to clear depolarized mitochondria, and enhance glutathione synthesis to scavenge reactive oxygen species (ROS). Impairing PGE2 sensing promotes TRM accumulation, while tampering with autophagy and glutathione negatively impacts the TRM pool. Thus, a PGE2-autophagy-glutathione axis defines the metabolic adaptation of CD8+ T cells to the intestinal microenvironment, to ultimately influence the TRM pool.

Project description:Resident memory CD8 T cells (Trm) have been shown to provide effective protective responses in the small intestine (SI) in mice. A better understanding of the generation and persistence of SI CD8 Trm cells in humans may have implications for intestinal immune-mediated diseases and vaccine development. Analyzing normal and transplanted human SI we demonstrated that the majority of SI CD8 T cells were bona fide CD8 Trm cells that survived for over 1 year in the graft. Intraepithelial and lamina propria CD8 Trm cells showed a high clonal overlap and a repertoire dominated by expanded clones, conserved both spatially in the intestine and over time. Functionally, lamina propria CD8 Trm cells were potent cytokine-producers, exhibiting a polyfunctional (IFN-γ+ IL-2+ TNF-α+) profile, and efficiently expressed cytotoxic mediators after stimulation. These results suggest that SI CD8 Trm cells could be relevant targets for future oral vaccines and therapeutic strategies for gut disorders.

Project description:Tissue resident memory T cells (TRM) contained at sites of previous infection provide local protection against re-infection. Whether they form and function in organ transplants where cognate antigen persists is unclear. This is a key question in transplantation as T cells are detected long-term in allografts, but it is not known whether they are exhausted or are functional memory T cells. Using a mouse model of kidney transplantation, we showed  that antigen-specific and polyclonal effector T cells differentiated in the graft into TRM and subqeuntly caused allograft rejection. TRM identity was established by surface phenotype, transcriptional profile, and inability to recirculate in parabiosis and re-transplantation experiments. Graft TRM proliferated locally, produced IFNγ upon re-stimulation, and their in vivo depletion attenuated rejection. Importantly, the vast majority of antigen-specific and polyclonal TRM lacked phenotypic and transcriptional exhaustion markers. Single cell analysis of graft T cells early and late after transplantation identified a transcriptional program associated with transition to the tissue resident state that could serve as a platform for the discovery of therapeutic targets. Thus, recipient effector T cells differentiate into functional graft TRM that maintain rejection locally. Targeting these TRM could improve renal transplant outcomes.