Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Decreased intra-tumor heterogeneity (ITH) correlates with increased patient survival and immunotherapy response. However, the mechanism underlying this association remains inconclusive since additional factors dictate tumor aggressiveness. Here, we study the mechanisms responsible for the immune escape of tumors bearing low ITH. We compare homogeneous, genetically similar single-cell clones that are rejected vs. non-rejected after transplantation. We followed the growth of these clone-derived tumors over time using single-cell RNA sequencing and immunophenotyping. Non-rejected clones show high infiltration of tumor-associated macrophages (TAM), increased Mif expression, lower T-cell infiltration, and increased T-cell exhaustion. Mif KO led to smaller tumors and reversed these immune phenotypes, validating its role in the growth of low ITH tumors. Mif secretion by these tumor cells causes TAM infiltration, thus contributing to an immunosuppressive environment that supports aggressive growth. We validated this result in melanoma patient data, confirming that high levels of MIF distinguish aggressive from non-aggressive ITHs.

Project description:Decreased intra-tumor heterogeneity (ITH) correlates with increased patient survival and immunotherapy response. However, the mechanism underlying this association remains inconclusive since additional factors dictate tumor aggressiveness. Here, we study the mechanisms responsible for the immune escape of tumors bearing low ITH. We compare homogeneous, genetically similar single-cell clones that are rejected vs. non-rejected after transplantation. We followed the growth of these clone-derived tumors over time using single-cell RNA sequencing and immunophenotyping. Non-rejected clones show high infiltration of tumor-associated macrophages (TAM), increased Mif expression, lower T-cell infiltration, and increased T-cell exhaustion. Mif KO led to smaller tumors and reversed these immune phenotypes, validating its role in the growth of low ITH tumors. Mif secretion by these tumor cells causes TAM infiltration, thus contributing to an immunosuppressive environment that supports aggressive growth. We validated this result in melanoma patient data, confirming that high levels of MIF distinguish aggressive from non-aggressive ITHs.

Project description:Temporal genomic analysis of melanoma rejection identifies regulators of tumor immune evasion

Project description:Temporal genomic analysis of melanoma rejection identifies regulators of tumor immune evasion [scc35]

Project description:Temporal genomic analysis of melanoma rejection identifies regulators of tumor immune evasion [scc]

Project description:The clinical successes of immune checkpoint therapies for cancer make it important to identify mechanisms of resistance to anti-tumor immune responses. Numerous resistance mechanisms have been identified employing studies of single genes or pathways, thereby parsing the tumor microenvironment complexity into tractable pieces. However, this limits the potential for novel gene discovery to in vivo immune attack. To address this challenge, we developed an unbiased in vivo genome-wide RNAi screening platform that leverages host immune selection in strains of immune-competent and immunodeficient mice to select for tumor cell-based genes that regulate in vivo sensitivity to immune attack. Utilizing this approach in a syngeneic triple-negative breast cancer (TNBC) model, we identified 709 genes that selectively regulated adaptive anti-tumor immunity and focused on five genes (CD47, TGFβ1, Sgpl1, Tex9 and Pex14) with the greatest impact. We validated the mechanisms that underlie the immune-related effects of expression of these genes in different TNBC lines, as well as tandem synergistic interactions. Furthermore, we demonstrate the impact of different genes with previously unknown immune functions (Tex9 and Pex14) on anti-tumor immunity. Thus, this innovative approach has utility in identifying unknown tumor-specific regulators of immune recognition in multiple settings to reveal novel targets for future immunotherapies.

Project description:Through an integrative analysis of the lincRNA expression and tumor immune response in 9,626 tumor samples across 32 cancer types, we developed a lincRNA-based immune response (LIMER) score that can predict the immune cells infiltration and patient prognosis in multiple cancer types. Our analysis also identified tumor-specific lincRNAs, including EPIC1, that potentially regulate tumor immune response in multiple cancer types. Immunocompetent mouse models and in vitro co-culture assays demonstrated that EPIC1 induces tumor immune evasion and resistance to immunotherapy by suppressing tumor cell antigen presentation. Mechanistically, lincRNA EPIC1 interacts with the histone methyltransferase EZH2, leading to the epigenetic silencing of IFNGR1, TAP1/2, ERAP1/2, and MHC-I genes. Genetic and pharmacological inhibition of EZH2 abolish EPIC1's immune-related oncogenic effect and its suppression of interferon-γ signaling. The EPIC1-EZH2 axis emerges as a potential mechanism for tumor immune evasion that can serve as therapeutic targets for immunotherapy.

Project description:Several biomarkers such as tumor mutation burden (TMB), neoantigen load (NAL), programmed cell-death receptor 1 ligand (PD-L1) expression, and lactate dehydrogenase (LDH) have been developed for predicting response to immune checkpoint inhibitors (ICIs) in melanoma. However, some limitations including the undefined cut-off value, poor uniformity of test platform, and weak reliability of prediction have restricted the broad application in clinical practice. In order to identify a clinically actionable biomarker and explore an effective strategy for prediction, we developed a genetic mutation model named as immunotherapy score (ITS) for predicting response to ICIs therapy in melanoma, based on whole-exome sequencing data from previous studies. We observed that patients with high ITS had better durable clinical benefit and survival outcomes than patients with low ITS in three independent cohorts, as well as in the meta-cohort. Notably, the prediction capability of ITS was more robust than that of TMB. Remarkably, ITS was not only an independent predictor of ICIs therapy, but also combined with TMB or LDH to better predict response to ICIs than any single biomarker. Moreover, patients with high ITS harbored the immunotherapy-sensitive characteristics including high TMB and NAL, ultraviolet light damage, impaired DNA damage repair pathway, arrested cell cycle signaling, and frequent mutations in NF1 and SERPINB3/4. Overall, these findings deserve prospective investigation in the future and may help guide clinical decisions on ICIs therapy for patients with melanoma.

Project description: Not available