Project description:T cell exhaustion is a major impediment to anti-tumor immunity. However, it remains elusive how other immune cells in the tumor microenvironment (TME) contribute to this dysfunctional state. Here we show that the biology of tumor-associated macrophages (TAM) and exhausted T cells (Tex) in the TME is extensively linked. We demonstrate that in vivo depletion of TAM reduces exhaustion programs in tumor-infiltrating CD8+ T cells and reinvigorates their effector potential. Reciprocally, transcriptional and epigenetic profiling reveals that Tex express factors that actively recruit monocytes to the TME and shape their differentiation. Using lattice light sheet microscopy, we show that TAM and CD8+ T cells engage in unique long-lasting antigen-specific synaptic interactions that fail to activate T cells, but prime them for exhaustion, which is then accelerated in hypoxic conditions. Spatially resolved sequencing supports a spatiotemporal self-enforcing positive feedback circuit that is aligned to protect rather than destroy a tumor.

Project description:T cell exhaustion is a major impediment to anti-tumor immunity. However, it remains elusive how other immune cells in the tumor microenvironment (TME) contribute to this dysfunctional state. Here we show that the biology of tumor-associated macrophages (TAM) and exhausted T cells (Tex) in the TME is extensively linked. We demonstrate that in vivo depletion of TAM reduces exhaustion programs in tumor-infiltrating CD8+ T cells and reinvigorates their effector potential. Reciprocally, transcriptional and epigenetic profiling reveals that Tex express factors that actively recruit monocytes to the TME and shape their differentiation. Using lattice light sheet microscopy, we show that TAM and CD8+ T cells engage in unique long-lasting antigen-specific synaptic interactions that fail to activate T cells, but prime them for exhaustion, which is then accelerated in hypoxic conditions. Spatially resolved sequencing supports a spatiotemporal self-enforcing positive feedback circuit that is aligned to protect rather than destroy a tumor.

Project description:T cell exhaustion is a major impediment to anti-tumor immunity. However, it remains elusive how other immune cells in the tumor microenvironment (TME) contribute to this dysfunctional state. Here we show that the biology of tumor-associated macrophages (TAM) and exhausted T cells (Tex) in the TME is extensively linked. We demonstrate that in vivo depletion of TAM reduces exhaustion programs in tumor-infiltrating CD8+ T cells and reinvigorates their effector potential. Reciprocally, transcriptional and epigenetic profiling reveals that Tex express factors that actively recruit monocytes to the TME and shape their differentiation. Using lattice light sheet microscopy, we show that TAM and CD8+ T cells engage in unique long-lasting antigen-specific synaptic interactions that fail to activate T cells, but prime them for exhaustion, which is then accelerated in hypoxic conditions. Spatially resolved sequencing supports a spatiotemporal self-enforcing positive feedback circuit that is aligned to protect rather than destroy a tumor.

Project description:T cell exhaustion is a state of functional decline in T cells, driven by chronic antigen exposure and inhibitory signals within the tumor microenvironment. Exhausted CD8+ T cells (Tex) derive from precursor exhausted T cells (Tpex), a self-renewing population responsible for the proliferative burst observed in anti-PD-1 therapies. Exhausted cells are exposed to adenosine in the tumor, yet the role of the CD73/adenosine axis and Tpex/Tex differentiation remains unclear. Using an in vitro model for CD8+ T cell exhaustion, we found that CD73 expression increased during Tpex formation and that its expression is negatively correlated with Tex generation. CD73-deficient (CD73KO) CD8⁺ T cells showed impaired activation and reduced progression to Tex. Moreover, we demonstrated that CD73 promotes transcriptional expression of the adenosine receptor A2A (A2AR) and the differentiation into IFNγ/TNFα-producing Tex cells. RNAseq analysis of exhausted CD73KO CD8+ T cells showed a more stem-like transcriptomic profile and enrichment in genes associated with the immune response than their WT counterpart. In vivo, co-transfer of naïve CD73 KO and WT tumor antigen-specific CD8⁺ T cells into tumor-bearing mice showed increased Tpex frequency and numbers among CD73KO cells in tumors. Conversely, in vitro exhaustion in the presence of A2AR agonists decreased Tex frequency and activation/exhaustion markers, while increasing CD73 and CD62L, markers associated with stemness. Supporting this, A2AR blockade with SYN115 in tumor-bearing mice reduced Tpex markers and increased Tex differentiation. Altogether, our data suggest CD73 promotes Tpex-to-Tex differentiation, whereas adenosine-A2AR signaling supports Tpex maintenance in the tumor microenvironment.

Project description:Identifying signals that govern the differentiation of tumor-infiltrating CD8 + T cells (CD8 + TILs) towards exhaustion can improve current therapeutic approaches for cancer. Here, we show that type I interferons (IFN-Is) act as environmental cues enhancing terminal CD8 + T cell exhaustion in tumors. We found enrichment of IFNIs-stimulated genes (ISGs) within exhausted CD8 + T cells (Tex cells) in patients across various cancer types, with heightened ISG levels correlating with poor response to immune checkpoint blockade (ICB) therapy. In preclinical models, CD8 + TILs devoid of IFN-Is signaling developed less exhaustion features, provided better tumor control and showed greater response to ICB-mediated rejuvenation. Mechanistically, chronic IFN-Is stimulation perturbed lipid metabolism and redox balance in Tex cells, leading to aberrant lipid accumulation and elevated oxidative stress. Collectively, these defects promoted lipid peroxidation, which potentiated metabolic and functional exhaustion of Tex cells. Thus, cell intrinsic IFN-Is signaling regulates the extent of CD8+ TIL exhaustion, and has important implications for immunotherapy.

Project description:Identifying signals that govern the differentiation of tumor-infiltrating CD8 + T cells (CD8 + TILs) towards exhaustion can improve current therapeutic approaches for cancer. Here, we show that type I interferons (IFN-Is) act as environmental cues enhancing terminal CD8 + T cell exhaustion in tumors. We found enrichment of IFNIs-stimulated genes (ISGs) within exhausted CD8 + T cells (Tex cells) in patients across various cancer types, with heightened ISG levels correlating with poor response to immune checkpoint blockade (ICB) therapy. In preclinical models, CD8 + TILs devoid of IFN-Is signaling developed less exhaustion features, provided better tumor control and showed greater response to ICB-mediated rejuvenation. Mechanistically, chronic IFN-Is stimulation perturbed lipid metabolism and redox balance in Tex cells, leading to aberrant lipid accumulation and elevated oxidative stress. Collectively, these defects promoted lipid peroxidation, which potentiated metabolic and functional exhaustion of Tex cells. Thus, cell intrinsic IFN-Is signaling regulates the extent of CD8+ TIL exhaustion, and has important implications for immunotherapy.

Project description:Identifying signals that govern the differentiation of tumor-infiltrating CD8 + T cells (CD8 + TILs) towards exhaustion can improve current therapeutic approaches for cancer. Here, we show that type I interferons (IFN-Is) act as environmental cues enhancing terminal CD8 + T cell exhaustion in tumors. We found enrichment of IFNIs-stimulated genes (ISGs) within exhausted CD8 + T cells (Tex cells) in patients across various cancer types, with heightened ISG levels correlating with poor response to immune checkpoint blockade (ICB) therapy. In preclinical models, CD8 + TILs devoid of IFN-Is signaling developed less exhaustion features, provided better tumor control and showed greater response to ICB-mediated rejuvenation. Mechanistically, chronic IFN-Is stimulation perturbed lipid metabolism and redox balance in Tex cells, leading to aberrant lipid accumulation and elevated oxidative stress. Collectively, these defects promoted lipid peroxidation, which potentiated metabolic and functional exhaustion of Tex cells. Thus, cell intrinsic IFN-Is signaling regulates the extent of CD8+ TIL exhaustion, and has important implications for immunotherapy.

Project description:Chronic infections and cancer cause T cell dysfunction known as exhaustion due to persistent antigen exposure, suboptimal co-stimulation and a plethora of hostile factors, which dampens protective immunity and limits the efficacy of immunotherapies1-4. The mechanisms behind T cell exhaustion remain poorly understood. Herein, we dissected the proteome of CD8+ exhausted T cells (Tex) across multiple states of exhaustion in the context of both chronic viral infections and cancer. We found that there was a non-stochastic pathway-specific discordance between mRNA and protein dynamics in T effector (Teff) versus Tex cells. We identified a unique proteostatic stress response (PSR) in Tex cells which we termed TexPSR. Contrary to canonical stress responses with reduced protein synthesis5,6, the TexPSR involves increased global translation activity and an upregulation of specialized chaperones, characterized further by the accumulation of protein aggregates, stress granules and autophagy-dominant protein catabolism. We established that disruption of proteostasis alone can convert Teff to Tex cells, and linked TexPSR mechanistically to persistent Akt signaling. Finally, we found that disruption of TexPSR-associated chaperones in CD8+ T cells improved cancer immunotherapy preclinically and demonstrated that high TexPSR feature in T cells in cancer patients confers poor response to immunotherapy clinically. Our findings collectively highlight TexPSR as a hallmark and a mechanistic driver of T cell exhaustion, raising the possibility of targeting proteostasis as a potential novel approach for cancer immunotherapy.

Project description:Tumor-specific CD8+ T lymphocytes are crucial for anti-cancer immunity but can lose cytotoxic function in the immunosuppressive tumor microenvironment. Immune checkpoint blockade (ICB), like anti-PD-1 therapy, enhance and prolong anti-tumor T cell responses. Despite its widespread clinical use, resistance to ICB develops in some patients, characterized by the proliferation of exhausted T cell (Tex). Here, we establish two single-cell murine hepatocellular carcinoma (HCC) models to explore regulatory network in Tex with ICB resistance. We uncover distinct T cell compositions, including both early and terminal Tex subsets, following prolonged ICB treatment, and reveal the differentiation trajectory of Tex subsets. Finally, we not only identify transcription factor Runx2 and its downstream targets as contributors to T cell exhaustion in both models, but discover ICB response correlates to Runx2 level in human tumor-infiltrating lymphocytes. These findings elucidate Runx2 regulates T cell exhaustion in response to prolonged ICB treatment, influencing ICB effICBency, and suggest potential targets for combination therapy alongside ICB in HCC.

Project description:Tumor-specific CD8+ T lymphocytes are crucial for anti-cancer immunity but can lose cytotoxic function in the immunosuppressive tumor microenvironment. Immune checkpoint blockades (ICB), like anti-PD-1 therapy, enhance and prolong anti-tumor T cell responses. Despite its widespread clinical use, resistance to ICB develops in some patients, characterized by the proliferation of exhausted T cell (Tex). Here, we establish two single-cell murine hepatocellular carcinoma (HCC) models to explore regulatory network in Tex with ICB resistance. We uncover distinct T cell compositions, including both early and terminal Tex subsets, following prolonged ICB treatment, and reveal the differentiation trajectory of Tex subsets. Finally, we not only identify transcription factor Runx2 and its downstream targets as contributors to T cell exhaustion in both models, but discover ICB response correlates to Runx2 level in human tumor-infiltrating lymphocytes. These findings elucidate Runx2 regulates T cell exhaustion in response to prolonged ICB treatment, influencing ICB effICBency, and suggest potential targets for combination therapy alongside ICB in HCC.