Project description:Novel approaches are needed to boost the efficacy of immune checkpoint blockade (ICB) therapy. Ataxia Telangiectasia Mutated (ATM) protein plays a central role in sensing DNA double strand breaks and coordinating their repair. Recent data indicated that ATM might be a promising target to enhance immune checkpoint blockade (ICB) therapy. However, the molecular mechanism involved is not clearly elucidated. Here we show that ATM inhibition could potentiate ICB therapy by promoting cytoplasmic leakage of mitochondrial DNA and activation of the cGAS/STING pathway. Genetic depletion of ATM in murine cancer cells significantly delayed tumor growth in syngeneic mouse hosts in a T-cell dependent manner. Furthermore, chemical inhibition of ATM significantly potentiated anti-PD1 therapy of mouse tumors. ATM inhibition potently activated the cGAS/STING pathway and enhanced lymphocyte infiltration into the tumor microenvironment by downregulating TFAM, which led to mitochondrial DNA leakage into the cytoplasm. Moreover, our analysis of data from a large patient cohort indicated that ATM mutations, especially nonsense mutations, predicted for clinical benefits for ICB therapy. Our study therefore provides strong evidence that ATM may serve both as a therapeutic target and a biomarker to enable ICB therapy.

Project description:BRCA1 loss leads to tumor cell transcriptional reprogramming, resulting in a DNA damage-driven, mandatory cell-autonomous type I IFN inflammatory activation mediated by STING and TREX1/2. PARP inhibition augmented this immunoreactivity, creating contextual lethality to dual immune checkpoint blockade (ICB) in vivo. BRCA1-deficient tumor can escape T-cell inflammation through targeted deletion or methylation of the DNA sensing/IFN pathway genes, such as STING, IFNB1 or the chemokine CCL5. Alternatively, BRCA-mutated carcinomas retaining immunoreactivity upregulate their VEGF-A expression driven by STING, which mediates immune resistance and tumor progression. STING elimination attenuated tumor growth and abrogated therapeutic resistance to dual ICB. VEGF-A blockade synergized with immune checkpoint blockade and/or PARP inhibition to control outgrowth of Brca1-/- ovarian tumors, offering opportunities for rational combination therapy of cancers with homologous recombination repair deficiency (HRD).

Project description:Immune checkpoint blockade (ICB) demonstrates durable clinical benefit only in a minority of renal cell carcinoma (RCC) patients. Identifying molecular features that determine response and developing approaches to enhance the response remain an urgent clinical need. Here we found that, in multiple RCC cell lines, targeting the ATR-CHK1 axis with pharmacological inhibitors increased cytosolic DNA accumulation, activated the cGAS-IRF3-dependent cytosolic DNA sensing pathway, and resulted in the inflammatory cytokine expression. SETD2 mutated RCC cell lines or tumor samples were associated with preferential ATR-CHK1 activation over ATM-CHK2 activation. SETD2 knockdown promoted the cytosolic DNA sensing pathway and conferred greater sensitivity in response to ATR-CHK1 inhibition. In murine Renca tumors, Setd2 knockdown and ATR inhibitor VE822 synergistically promoted cytosolic DNA sensing pathway, immune cell infiltration, and immune checkpoint protein expression. Setd2 deficient Renca tumors demonstrated greater vulnerability to ICB monotherapy or in combination with VE822 than Setd2 proficient tumors. SETD2 mutations were associated with a higher response rate and prolonged overall survival in ICB-treated RCC patients, but not in non-ICB-treated RCC patients. This study provides a mechanism-based guidance to develop more personalized combination therapy regimens for RCC patients with SETD2 mutations.

Project description:Epigenetic mechanism contributes to immune landscapes in cancer. Here we identify the SETDB1-TRIM28 complex as a critical suppressor of antitumor immunity. An epigenetic CRISPR-Cas9 screen of 1,218 chromatin regulators identified TRIM28 as a novel suppressor of PD-L1 expression. We revealed that expression of the SETDB1-TRIM28 complex negatively correlates with infiltration of effector CD8+ T cells. Inhibition of SETDB1-TRIM28 simultaneously upregulates PD-L1 and activates the cGAS-STING innate immune response to increase infiltration of CD8+ T cells. Mechanistically, SETDB1-TRIM28 inhibition leads to micronuclei formation in cytoplasm, a known activator of the cGAS-STING pathway. Thus, SETDB1-TRIM28 inhibition bridges the innate and adaptive immunity. Indeed, SETDB1 knockout enhances the antitumor effects of immune checkpoint blockade anti-PD-L1 in an ovarian cancer mouse model in a cGAS dependent manner. Our findings establish SETDB1-TRIM28 complex as a regulator of antitumor immunity and its loss activates cGAS-STING innate immunity to boost antitumor effects of immune checkpoint blockades.

Project description:Epigenetic mechanism contributes to immune landscapes in cancer. Here we identify the SETDB1-TRIM28 complex as a critical suppressor of antitumor immunity. An epigenetic CRISPR-Cas9 screen of 1,218 chromatin regulators identified TRIM28 as a novel suppressor of PD-L1 expression. We revealed that expression of the SETDB1-TRIM28 complex negatively correlates with infiltration of effector CD8+ T cells. Inhibition of SETDB1-TRIM28 simultaneously upregulates PD-L1 and activates the cGAS-STING innate immune response to increase infiltration of CD8+ T cells. Mechanistically, SETDB1-TRIM28 inhibition leads to micronuclei formation in cytoplasm, a known activator of the cGAS-STING pathway. Thus, SETDB1-TRIM28 inhibition bridges the innate and adaptive immunity. Indeed, SETDB1 knockout enhances the antitumor effects of immune checkpoint blockade anti-PD-L1 in an ovarian cancer mouse model in a cGAS dependent manner. Our findings establish SETDB1-TRIM28 complex as a regulator of antitumor immunity and its loss activates cGAS-STING innate immunity to boost antitumor effects of immune checkpoint blockades.

Project description:Non-inflamed (cold) tumors such as leiomyosarcoma (LMS) do not benefit from immune checkpoint blockade (ICB) monotherapy. Combining ICB with angiogenesis-, or poly-ADP ribose polymerase (PARP) inhibitors may increase tumor immunogenicity by altering the immune cell composition of the tumor microenvironment (TME). The DAPPER phase II study evaluated the safety, immunologic, and clinical activity of ICB-based combinations in pre-treated LMS patients.

Project description:Immune checkpoint blockades (ICBs) have been approved for treating multiple cancer types, but the response rate is limited for many solid tumors. Much efforts have been devoted to understand the mechanisms governing ICB therapy efficacy and the abundance of tumor-infiltrating lymphocytes is among the factors that influence on ICB responsiveness. The deubiquitinase TRABID was identified in our previous study as a positive regulator of autophagy by stabilizing VPS34, the class III PI3K critical for autophagosome formation. In this study, we identify an upregulation of TRABID in mitosis and its critical role in mitotic progression through deubiquitination and stabilization of AURKB and BIRC5, two subunits of the chromosome passenger complex governing multiple mitotic steps. Furthermore, TRABID depletion induces micronuclei phenotype, which is likely mediated by the combinatory defects in mitosis and autophagy. Consequently, TRABID depletion or inhibition activates cGAS/STING pathway to induce type I interferon production and inflammatory responses. TRABID depletion in tumors cells reduces tumor burden and promotes anti-tumor immune surveillance by increasing tumor infiltration of CD4+ and CD8+ T cells and NK cells and reducing Treg cells. Clinically, TRABID expression in multiple cancer types correlates negatively with the infiltration of anti-tumor immune cells and positively with that of pro-tumor immune cells. Our study supports a suppressive role of tumor-intrinsic TRABID in anti-tumor immunity and suggests TRABID inhibitor as a promising agent for enhancing the sensitivity of solid tumors to ICB therapy.

Project description:One of the most common metabolic defects of cancer cells is the deficiency in arginine synthesis due to suppressed expression of argininosuccinate synthetase 1 (ASS1) which renders cancer cells auxotrophic to external arginine supply. Arginine deprivation has been effectively used as a treatment for leukemias, with several clinical trials on solid tumors underway. We previously showed that in prostate cancer arginine depletion induced mitochondrial dysfunction and excessive ROS production resulting in chromatin autophagy, nuclear DNA leakage, and cellular death, but the detailed mechanism of arginine starvation-induced cell death remains unclear. In this study, we demonstrated that arginine deprivation coordinately suppressed metabolic genes, including those responsible for mitochondrial oxidative phosphorylation (OXPHOS), nucleotide metabolism, and DNA repair. The consequent ROS production and impaired DNA damage response resulted in nuclear DNA leakage and cGAS-STING activation which is accompanied by upregulation of type I interferon response. We also showed that coordinated silencing of OXPHOS and DNA repair genes is caused in part by the depletion of α-ketoglutarate (αKG) and inactivation of histone demethylases. Supplementing cell-permeable dimethyl α-ketoglutarate (DMKG) both reduced repressive histone methylations and partially restored OXPHOS gene expressions, mitochondrial functions, and mitigated nuclear DNA leakage. Using our dietary arginine-restriction model, we demonstrate that arginine starvation slows prostate cancer growth with evidence of enhanced interferon responses and recruitment of immune cells. Our data suggests arginine starvation induces cell killing of ASS1-low cancer cells by metabolic depletion and epigenetic silencing of metabolic genes, leading to DNA damage and leakage. Resulting cGAS-STING activation may further enhance these killing effects.

Project description:Checkpoint blockade immunotherapy is a promising strategy in cancer treatment, depending on a favorable preexisting tumor immune microenvironment. However, prostate cancer is usually considered as an immune “cold” tumor with the poor immunogenic response and low density of tumor-infiltrating immune cells. This research uses samples from prostate cancer patients showing that docetaxel-based chemohormonal therapy reprograms the immune microenvironment and increases tumor-infiltrating T cells. Mechanistically, docetaxel treatment activates the cGAS/STING pathway and induces the type I interferon signaling, which may boost T cell-mediated immune response. In a murine prostate cancer model, chemohormonal therapy sensitizes tumor-bearing mice to PD1-blockade therapy. These findings demonstrate that docetaxel-based chemohormonal therapy activates prostate cancer immunogenicity and acts cooperatively with anti-PD-1 checkpoint blockade, providing a combination immunotherapy strategy that would lead to better therapeutic benefit for prostate cancer.

Project description:The induction of proinflammatory T cells by dendritic cell (DC) subtypes is critical for anti-tumor responses and effective immune checkpoint blockade (ICB) therapy. Here we show that human CD1c+CD5+ dendritic cells are reduced in melanoma-affected lymph nodes, with CD5 expression on DCs correlating with patient survival. Activating CD5 on DCs enhanced T-cell priming and improved survival after immune checkpoint blockade therapy. CD5+ DC numbers increased during ICB treatment, and low IL-6 levels promoted their de novo differentiation. Mechanistically, CD5 expression by DCs was required to generate optimally protective CD5hi T helper and CD8+ T cells; further, deletion of CD5 from T cells dampened tumor elimination in response to ICB therapy in vivo. Thus, CD5+ dendritic cells are an essential component of optimal immune checkpoint blockade therapy.