Project description:PD-1+TCF-1+ stem-like CD8 T cells, also referred to as progenitors of exhausted T cells (TPEX), are a crucial resource pool for maintaining CD8 T cell during chronic viral infections and cancer. These stem-like CD8 T cells are a key therapeutic target in antiviral and anticancer immunotherapy as they provide a proliferative burst of effector CD8 T cells upon PD-1 blockade therapy. In our study we show that IL-7 therapy preferentially expands these stem-like CD8 T cells, using NT-I7, a long-acting hybrid Fc-fused recombinant human IL-7 (rhIL-7-hyFc, efineptakin alfa). Single-cell gene profile analysis revealed a proliferating cluster induced by NT-I7, distinct from previously described stem-like, transitory effector, or terminally exhausted subset cluster. This cluster exhibited an enriched stem-like signature, including transcription factors and costimulatory molecules associated with stem-like CD8 T cells. Notably, the cluster was enriched with genes related to lymphocyte migration. Consistent with this gene profile, there was a significant increase in stem-like CD8 T cells in circulation and peripheral tissues after NT-I7 treatment, contrasting with their resident property in lymphoid organs. Our data suggest the potential of NT-I7 therapy to enhance antiviral and anticancer immunotherapies by amplifying the stem-like CD8 T cell pool and mobilizing them to the peripheral target sites.

Project description:TGFb signaling is a major pathway associated with poor clinical outcome in patients with advanced metastatic cancers and non-response to immune checkpoint blockade, particularly in the immune-excluded tumor phenotype. While previous pre-clinical studies demonstrated that converting tumors from an excluded to an inflamed phenotype and curative anti-tumor immunity require attenuation of both PD-L1 and TGFb signaling, the underlying cellular mechanisms remain unclear. Recent studies suggest that stem cell-like CD8 T cells (TSCL) can differentiate into non-exhausted CD8 T effector cells that drive durable anti-tumor immunity. Here, we show that TGFb and PD-L1 restrain TSCL expansion as well as replacement of progenitor exhausted and dysfunctional CD8 T cells with non-exhausted IFNghi CD8 T effector cells in the tumor microenvironment (TME). Blockade of TGFb and PD-L1 generated IFNghi CD8 T effector cells with enhanced motility, enabling both their accumulation in the TME and increased interaction with other cell types. Ensuing IFNg signaling markedly transformed myeloid, stromal, and tumor niches to yield a broadly immune-supportive ecosystem. Blocking IFNg completely abolished the effect of anti-PD-L1/ TGFb combination therapy. Our data suggest that TGFb works in concert with PD-L1 to prevent TSCL expansion and replacement of exhausted CD8 T cells with fresh CD8 T effector cells, thereby maintaining the CD8 T cell compartment in a dysfunctional state.

Project description:Chronic hepatitis C virus (HCV) infection is associated with CD8+ T-cell exhaustion characterized by limited effector functions and thus compromised anti-viral activity. Exhausted HCV-specific CD8+ T cells are comprised of memory-like and terminally exhausted CD8+ T-cell subsets. So far, little is not known about the molecular profile and fate of these cells after elimination of chronic antigen stimulation by direct acting antiviral therapy (DAA). Here, we report an antigen-driven molecular core signature underlying exhausted CD8+ T-cell subset heterogeneity in chronic viral infection with a progenitor/progeny relationship of memory-like and terminally exhausted HCV-specific CD8+ T cells via an intermediate stage. Furthermore, transcriptional profiling reveals that the memory-like cells remain after DAA-mediated cure while terminally exhausted HCV-specific CD8+ T-cell subsets are lost. Thus, the memory polarization of the overall HCV-specific CD8+ T-cell response after cure does not result from re-differentiation of exhausted T cells. Consequently, antigen elimination has little impact on the exhausted core signature of memory-like CD8+ T cells that remains clearly different from bona fide T-cell memory. These results identify a molecular signature of T-cell exhaustion that is imprinted like a chronic scar in HCV-specific CD8+ T cells even after HCV cure, highlighting the requirement of re-programming to elicit full effector potential of exhausted T cells.

Project description:Chronic hepatitis C virus (HCV) infection is associated with CD8+ T-cell exhaustion characterized by limited effector functions and thus compromised anti-viral activity. Exhausted HCV-specific CD8+ T cells are comprised of memory-like and terminally exhausted CD8+ T-cell subsets. So far, little is not known about the molecular profile and fate of these cells after elimination of chronic antigen stimulation by direct acting antiviral therapy (DAA). Here, we report an antigen-driven molecular core signature underlying exhausted CD8+ T-cell subset heterogeneity in chronic viral infection with a progenitor/progeny relationship of memory-like and terminally exhausted HCV-specific CD8+ T cells via an intermediate stage. Furthermore, transcriptional profiling reveals that the memory-like cells remain after DAA-mediated cure while terminally exhausted HCV-specific CD8+ T-cell subsets are lost. Thus, the memory polarization of the overall HCV-specific CD8+ T-cell response after cure does not result from re-differentiation of exhausted T cells. Consequently, antigen elimination has little impact on the exhausted core signature of memory-like CD8+ T cells that remains clearly different from bona fide T-cell memory. These results identify a molecular signature of T-cell exhaustion that is imprinted like a chronic scar in HCV-specific CD8+ T cells even after HCV cure, highlighting the requirement of re-programming to elicit full effector potential of exhausted T cells.

Project description:Persistent antigen stimulation exposes CD8+ T cells to various metabolic stresses and induces a dysfunctional state termed T-cell exhaustion. Exhausted CD8+ T cells are continuously replenished by a recently discovered self-renewing stem-like CD8+ T-cell subset, which maintains long-term immunity and provides proliferative burst in response to immunotherapies. Although the redox system plays an important role in regulating T-cell activation, how cellular redox affects the differentiation of stem-like and exhausted CD8+ T cells is incompletely understood. Here, we showed that both antigen stimulation and terminal differentiation reduced mitochondrial oxidation and reactive oxygen species (ROS) in exhausted CD8+ T cells, which displayed a chromatin state primed for regulation by the redox sensing KEAP1-NRF2 pathway. During chronic viral infection, KEAP1 promoted expansion of antiviral CD8+ T cells and facilitated their differentiation into the stem-like subset in a cell autonomous manner. In addition, KEAP1 was required for establishing proper transcriptional programs of stem-like and exhausted CD8+ T cells. Mechanistically, KEAP1 maintained oxidation by upregulating genes involved in mitochondrial oxidation and repressing NRF2-driven transcription of antioxidant pathways. Deleting KEAP1 binding domain in NRF2 released NRF2 from regulation by KEAP1, impaired expansion and stemness of CD8+ T cells, and dysregulated multiple metabolic pathways including redox pathways. Thus, our study revealed a novel role of the redox pathway in regulating the molecular program and differentiation of stem-like and exhausted CD8+ T cells during chronic antigen stimulation.

Project description:CD8 T cells normally differentiate from resting naïve T cells into function effector and then memory CD8 T cells following acute infections. During chronic viral infections, however, virus-specific CD8 T cells often become exhausted. We used microarrays to examine the gene expression differences between naive, effector, memory and exhausted virus-specific CD8 T cells following lymphocytic choriomeningitis virus infection. Experiment Overall Design: Three or four independent samples were sorted by flow cytometry for each cell type (naive, effector, memory and exhausted) virus-specific CD8 T cells. RNA was extracted and hybridized to Affymetrix microarrays.

Project description:In most cancers, T lymphocytes comprise an essential cellular component of the non-neoplastic microenvironment, where they have the capacity to both suppress and support tumor growth. One specialized T lymphocyte population is the CD8+ exhausted T cell, which has been intensely studied as an actionable therapeutic target. Unfortunately, there is currently no uniformly accepted classification scheme for these specialized T cells. To provide a potential model for classifying CD8+ exhausted T cells, we leveraged single cell transcriptomic analysis of a diverse collection of both human (n = 8) and mouse (n = 4) cancers to identify unique subpopulations shared across tumor types and species. By integrating data from both human and mouse cancer studies, as well as previously described CD8+ exhausted T cell subsets, we provide an integrated framework to characterize the heterogeneity of exhausted CD8+ T cells. As such, one of these subpopulations (cluster C1) increases following immune checkpoint inhibitor treatment in the setting of cancer in mice and patients. Taken together, this proposed classification scheme may be useful for the design and interpretation of current and future immune-based therapy studies.

Project description:<p>Checkpoint blockade therapy using antibodies targeting CTLA4, PD1 or PDL1 have changed the way cancer patients with advanced disease are being treated, as evident by their FDA approval in a wide variety of malignancies, and their ability to induce high response rates when compared to conventional therapies (e.g. chemotherapy). However, even in melanoma, despite the high response rate, most patients are refractory to therapy or acquire resistance in 10-12 months. To identify key immunological elements coupled with response or resistance to checkpoint immunotherapy, we performed an unbiased analysis on 16,291 CD45&#43; immune cells from 32 patients (48 samples) treated with checkpoint therapy (anti-PD1&#61;37; anti-PD1/CTLA4&#61;11), using single cell transcriptomics. Initial unsupervised clustering of all CD45&#43; cells identified 11 clusters. When examining the association of these clusters with clinical outcome, we found that two clusters (B-cells, p&#61;0.005; memory T-cells, p&#61;0.03) were significantly enriched in responder lesions while 4 clusters (monocytes/macrophages, p&#61;0.003; dendritic cells, p&#61;0.015; exhausted CD8&#43; T-cells, p&#61;0.005; and exhausted/cell-cycle lymphocytes, 1.3x10^-5) are enriched in non-responder lesions. Next, by leveraging our unbiased single cell approach, we identified not only clusters but also specific markers associated with either responder lesions (PLAC8, LTB, LY9, SELL, TCF7, IGKC and CCR7) or non-responder ones (CCL3, CD38, HAVCR2, ENTPD1 and WARS), many of which were not previously reported to be associated with clinical outcome to checkpoint therapy. Due to the importance of CD8&#43; T-cells in controlling tumors, the significant association of T-cell states with clinical outcome, and their high abundance in melanoma tumors, we next focused our analysis on CD8&#43; T-cells and identified 2 main clusters CD8_G (with increased expression of genes linked to memory) and CD8_B (enriched for genes linked to cell dysfunction), that were significantly enriched in responder (CD8_G, p&#61;1.4x10^-6) and non-responder (CD8_B, p&#61;0.005) lesions, respectively. Since cells with both states coexist in each of the responder and non-responder lesions, we decided to calculate the ratio between the number of cells in these 2 clusters and observed a significant separation between responders (CD8_G/CD8_B&#62;1) and non-responders (CD8_G/CD8_B&#60;1) when looking at all samples, baseline or post samples separately. Similar results were detected when looking at the expression of a single transcription factor, TCF7, in CD8 T-cells in an independent cohort (n&#61;43) using a simple immunofluorescence assay. Additionally, we validated the identity and function of some of the newly identified cell states as well as their epigenetic landscape, and found that cells expressing the inhibitory molecules CD39 and TIM3, on top of being enriched in non-responder lesions, are likely to play a crucial role in T-cell exhaustion in melanoma. Collectively, our study provides extensive unbiased data in human tumors for discovery of predictors and therapeutic targets to checkpoint immunotherapy.</p>

Project description:Chronic viral infections are characterized by a state of CD8 T cell dysfunction termed exhaustion. A better understanding of the mechanisms that regulate CD8 T cell responses during chronic infection is required to improve immunotherapies that restore function in exhausted CD8 T cells. Here we identify a novel population of virus-specific CD8 T cells with a T follicular helper (Tfh)-like signature in mice chronically infected with lymphocytic choriomeningitis virus (LCMV). These Tfh-like CD8 T cells expressed the programmed cell death-1 (PD-1) inhibitory receptor but at the same time also expressed co-stimulatory molecules and had a gene signature that was related to CD8 T cell memory precursor cells and hematopoietic stem cells (HSC). These Tfh-like CD8 T cells acted as stem cells during chronic infection undergoing self-renewal and also differentiating into the terminally exhausted CD8 T cells that were present in both lymphoid and non-lymphoid tissues. The Tfh-like CD8 T cells were found only in lymphoid tissues and resided predominantly in the T cell zones along with naïve CD8 T cells. Interestingly, the proliferative burst after PD-1 blockade came almost exclusively from this Tfh-like CD8 T cell subset. Importantly, the transcription factor TCF1 played a cell intrinsic and essential role in the generation of Tfh-like CD8 T cells. Taken together, our study identifies Tfh-like CD8 T cells as the critical subset for maintaining the pool of virus-specific CD8 T cells during chronic infection and as the cells that proliferate after PD-1 blockade. These findings provide a better understanding of T cell exhaustion and have implications towards optimizing PD-1 directed immunotherapy. 8 samples isolated from CD8 T-cells in LCMV clone 13 GK1.5 infected mice (2 naïve, 3 CXCR5+Tim3-, 3 CXCR5-Tim3+) cells were analyzed

Project description:Background: People with cancer, and especially older people, have a weakened immune system (the defense system of the body). This is often caused by the treatments for cancer. Older cancer survivors are therefore more prone to getting infections, some of which are preventable through vaccines. But because their immune systems are weakened, their response to vaccines is poor. Researchers want to see if a new drug, NT-I7, can help. Objective: To see if NT-I7 can boost the immune system. Eligibility: Adults 60 and older who have recently finished chemotherapy for breast, colorectal, or bladder cancer. Design: Participants will be screened with a physical exam, medical history, and blood and urine samples. Their heart s electrical activity will be checked. They will have an ultrasound of their spleen. They may give a tissue sample from a previous biopsy. Participants in phase 1a of the study will get 1 dose of NT-I7. It will be given by injection with a needle into the muscle of the upper arm, thigh, or buttocks. Participants in phase 1b will get 5 vaccines over a few months. They may get an optional booster and/or 6th vaccine. They will also get NT-I7. Participants will repeat the screening tests during the study. They may get a peripheral intravenous catheter in a vein in their hand or arm for blood draws. Participants may have apheresis. For this, blood is taken from an arm vein. The white blood cells are separated from the blood. The rest of the blood, minus the white blood cells, is returned into a vein in the other arm. A catheter may be used. Participants will have follow-up visits for 1 year.