Project description:CD8+ T cells are a key weapon in the therapeutic armamentarium against cancer. While CD8+CD103+ T cells with a tissue-resident memory T (TRM) cell phenotype associate with favourable prognoses, the tumour microenvironment also contains dysfunctional exhausted T (TEX) cells that exhibit a myriad of TRM-like features. Here, we deconvolute TRM and TEX cells across human cancers, ascribing markers and gene signatures that distinguish these populations and enable their functional distinction. While TRM cells exhibit superior functionality and are associated with long-term survival post-tumour resection, they are not associated with responsiveness to immune checkpoint blockade. Tumour-associated TEX and TRM cells are clonally distinct, with the latter comprising tumour-independent bystanders and tumour-specific cells segregated from cognate antigen. Intratumoural TRM cells can be forced towards an exhausted fate when chronic antigen stimulation occurs, arguing that the presence or absence of continuous antigen exposure within the microenvironment is the key distinction between tumour-associated TEX and TRM populations. These results suggest unique roles for TRM and TEX cells in tumour control, underscoring the need for distinct strategies to harness these populations in novel cancer therapies.

Project description:CD8+ T cells are a key weapon in the therapeutic armamentarium against cancer. While CD8+CD103+ T cells with a tissue-resident memory T (TRM) cell phenotype associate with favourable prognoses, the tumour microenvironment also contains dysfunctional exhausted T (TEX) cells that exhibit a myriad of TRM-like features. Here, we deconvolute TRM and TEX cells across human cancers, ascribing markers and gene signatures that distinguish these populations and enable their functional distinction. While TRM cells exhibit superior functionality and are associated with long-term survival post-tumour resection, they are not associated with responsiveness to immune checkpoint blockade. Tumour-associated TEX and TRM cells are clonally distinct, with the latter comprising tumour-independent bystanders and tumour-specific cells segregated from cognate antigen. Intratumoural TRM cells can be forced towards an exhausted fate when chronic antigen stimulation occurs, arguing that the presence or absence of continuous antigen exposure within the microenvironment is the key distinction between tumour-associated TEX and TRM populations. These results suggest unique roles for TRM and TEX cells in tumour control, underscoring the need for distinct strategies to harness these populations in novel cancer therapies.

Project description:Current cancer immunotherapies promote recovery of CD103+ tissue-resident memory T cells (Trm) population of the tumor-infiltrating T lymphocytes (TILs). However, not all treated patients exhibit improved anti-tumor immunity and survival, likely due to the immunophenotypical diversity among the CD103+ Trm TILs. Utilising multifaceted proteomics approaches and patients’ clinical analyses, we discovered an unusual subset of CD8+ Trm TILs expressing non-canonical integrin β3 early during T cells activation. The integrin β3 surprisingly heterodimerises with CD103 on T cells, leading to unconventional granulysin-mediated cytotoxicity, elevated alternative bioenergy usage and efficient T cell migration, with minimal overall exhaustion. Importantly, early-stage non-small cell lung carcinoma (NSCLC) patients with enriched presence of integrin β3+CD103+ Trm TILs exhibited better clinical prognosis, with improved T cell immunophenotype, hence confirming the beneficial role of this unusual subset of Trm TILs. These unconventional anti-tumor T cell features provide new avenues and future opportunities for designing better translational immunotherapy strategies.

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:We report the transcriptome analysis of epidermal CD8 tissue resident memory T (TRM) cells from healthy human skin. Specifically, epidermal CD8+CD103+CD49a+ and CD8+CD103+CD49- TRM cells from healthy human skin were sorted by FACS. Differential gene expression analysis revealed functional dichotomy of epidermal CD8+CD103+CD49a+ and CD8+CD103+CD49- TRM cells.

Project description:In cancer models, CD103+CD8 TRM cells are implicated in the response to anti-PD-1 immunotherapy, and a subset of CD4 TRM cells expressing the integrin CD49a is required for response to anti-CTLA-4 immunotherapy. We performed single-cell RNA sequencing on tumour-infiltrating T lymphocytes (TILs) isolated from colon carcinoma et unsupervised analyses reveal several TRM populations.

Project description:<p>Neoantigens, which are derived from tumour-specific protein-coding mutations, are exempt from central tolerance, can generate robust immune responses and can function as bona fide antigens that facilitate tumour rejection. We demonstrated that a strategy that uses multi-epitope, personalized neoantigen vaccination, which has previously been tested in patients with high-risk melanoma, is feasible for tumours such as glioblastoma, which typically have a relatively low mutation load and an immunologically &#8216;cold&#8217; tumour microenvironment. Here we conducted whole-exome sequencing of tumor and normal cells from individual patients with glioblastoma to identify tumor-specific mutations. We assessed the expression of mutated alleles by RNA-sequencing of tumor. We used personalized neoantigen-targeting vaccines to immunize patients newly diagnosed with glioblastoma following surgical resection and conventional radiotherapy in a phase I/Ib study. Patients who did not receive dexamethasone-a highly potent corticosteroid that is frequently prescribed to treat cerebral oedema in patients with glioblastoma-generated circulating polyfunctional neoantigen-specific CD4+ and CD8+ T cell responses that were enriched in a memory phenotype and showed an increase in the number of tumour-infiltrating T cells. Using single-cell T cell receptor analysis, we provide evidence that neoantigen-specific T cells from the peripheral blood can migrate into an intracranial glioblastoma tumour. Neoantigen-targeting vaccines thus have the potential to favourably alter the immune milieu of glioblastoma.</p>

Project description:CD49a marks highly cytotoxic epidermal tissue-resident memory (TRM)-cells, but their molecular circuitry and relationships to circulating populations are poorly defined. We demonstrate enrichment of RUNX family transcription factor binding motifs in human epidermal CD8+CD103+CD49a+ TRM-cells, paralleled by high RUNX2 and RUNX3 protein expression. Clonal overlap between epidermal CD8+CD103+CD49a+ TRM-cells and circulating memory CD8+CD45RA–CD62L+ T-cells identified a reservoir of circulating cells with potential to seed cytotoxic TRM-cells in new sites. Upon IL-15 and TGF-β stimulation, subsets of circulating CD8+CD45RA–CD62L+ T-cells acquired CD49a expression and cytotoxic transcriptional profiles in a RUNX2 and RUNX3 dependent manner. In contrast, knock-out of RUNX3, but not RUNX2, prevented CD103 expression. In melanoma, high RUNX2, but not RUNX3, transcription correlated with a cytotoxic CD8+CD103+CD49a+ TRM cell signature and overall patient survival. Together, our results indicate that combined RUNX2 and RUNX3 activity promotes the differentiation of cytotoxic CD8+CD103+CD49a+ TRM-cells, providing immunosurveillance of infected and malignant cells.

Project description:CD49a marks highly cytotoxic epidermal tissue-resident memory (TRM)-cells, but their molecular circuitry and relationships to circulating populations are poorly defined. We demonstrate enrichment of RUNX family transcription factor binding motifs in human epidermal CD8+CD103+CD49a+ TRM-cells, paralleled by high RUNX2 and RUNX3 protein expression. Clonal overlap between epidermal CD8+CD103+CD49a+ TRM-cells and circulating memory CD8+CD45RA–CD62L+ T-cells identified a reservoir of circulating cells with potential to seed cytotoxic TRM-cells in new sites. Upon IL-15 and TGF-β stimulation, subsets of circulating CD8+CD45RA–CD62L+ T-cells acquired CD49a expression and cytotoxic transcriptional profiles in a RUNX2 and RUNX3 dependent manner. In contrast, knock-out of RUNX3, but not RUNX2, prevented CD103 expression. In melanoma, high RUNX2, but not RUNX3, transcription correlated with a cytotoxic CD8+CD103+CD49a+ TRM cell signature and overall patient survival. Together, our results indicate that combined RUNX2 and RUNX3 activity promotes the differentiation of cytotoxic CD8+CD103+CD49a+ TRM-cells, providing immunosurveillance of infected and malignant cells.

Project description:Using mouse model, we show that CD8 tumor-infiltrating T lymphocytes (TIL) include two major resident T cells subpopulations expressing either CD49a or CD103 integrin, with a subset co-expressing CD103 and Tcf-1 transcription factor. Tumor vaccination induces a decrease in the percentage of Tcf-1+CD103+ TRM-like cells and an expansion of CD49a+ TRM displaying an effector/exhausted profile. Tcf-1+CD103+ TRM-cell density increases in tumors from vaccinated transgenic mice constitutively expressing active TGF-beta-type-2-receptor and wild-type mice challenged with neutralizing anti-IL-12 antibodies. Stimulation of mouse and human CD8 T cells with recombinant (r)TGF-beta combined with anti-CD3 antibodies results in increase in the proportion of CD103+ and Tcf-1+CD103+ CD8 T cells, whereas rIL-12 induces decrease in CD103 expression on CD8 T cells.