ABSTRACT Gliomas, including oligodendroglioma and astrocytoma subtypes, are a diverse group of malignant primary brain tumors that respond to radiation, surgery and chemotherapy; however, relapse remains a major barrier affecting overall patient survival. Immunotherapy targeting the adaptive immune system such as checkpoint inhibitors has shown limited efficacy in gliomas. Thus, understanding the immunobiology of gliomas and mechanisms of resistance to immune therapies is crucial to therapeutically leverage the immune system for treating patients. Our long-term goal is to dissect the innate immune system in gliomas and identify vulnerabilities that can be exploited for designing therapies. Recent studies have implicated a link between mutations in ATRX, a SWI-SNF chromatin remodeler and immune cell infiltration in the tumor microenvironment of ATRX-mutant astrocytomas. Our preliminary data suggest that ATRX inactivation in gliomas leads to enriched inflammatory signatures and potentiation of type I interferon/pro-inflammatory signaling, and selective sensitization of tumors to double-stranded (dsRNA)-based immune agonists. Based on these preliminary findings, we hypothesize that ATRX inactivation induces innate inflammation and sensitizes tumors to immune surveillance and dsRNA agonist therapy; concurrent IDH mutations suppress innate inflammation to enable tumor immune evasion. We will test our hypothesis in the following specific aims. Aim 1: Define the role of ATRX inactivation in modulating glioma cell-intrinsic innate signaling; Aim 2: Elucidate the role of ATRX deficiency and concurrent IDH1R132H mutation in modulating anti- tumor immunity and the response to dsRNA agonist therapy in pre-clinical murine glioma models; Aim 3: Determine the extent to which dsRNA-based therapies induce inflammatory activation of lower-grade gliomas. Our proposal will: 1) delineate the novel role of ATRX loss in regulating innate immune signaling responses and their downstream effects in glioma, 2) examine the immunological interplay between ATRX mutations and its partner mutation, IDH1R132H and 3) lay preclinical groundwork for exploiting a potential therapeutic vulnerability in gliomas carrying ATRX mutations.