TAMI-56. HYPOXIA-DRIVEN NECROSIS DRIVES DYNAMIC TUMOR PROGRESSION IN GLIOBLASTOMA

Abstract

Abstract The onset of necrosis correlates with aggressive malignant progression in solid tumors. Whether necrosis arises from or promotes accelerated tumor proliferation and progression remains unknown, primarily due to inadequate models systems that fail to induce or capture these dynamic changes as they develop. In glioblastoma (GBM; WHO grade IV), the most malignant primary brain tumor, vascular pathology and central necrosis precedes rapid, radial expansion resulting in patient mortality. While genetic alterations in GBM have been highly characterized, biological adaptations arising from sustained hypoxia/anoxia require further mechanistic investigation. This sustained nutrient deprivation leads to necrosis which dramatically changes the tumor microenvironment (TME). To reveal the dynamic temporal and spatial changes promoting expansive progression, we are generating mouse models that more appropriately capture events found in human gliomas, accounting for unique microenvironmental stressors often lacking in GBM animal models, specifically central necrosis. Combining hypoxia-induced focal necrosis within high grade gliomas with intravital microscopy captures TME restructuring to understand its impact on glioma progression. Our studies use both genetically characterized patient-derived orthotopic GBM xenografts, alongside an immunocompetent RCAS/tv-a model, to determine how antagonizing these processes impacts disease progression and outcomes across multiple GBM subtypes. Complementary to this, we are investigating how increasing hypoxia and necrosis-driven signaling events promotes tumor-associated macrophages (TAMs) influx and reprogramming during glioma progression. Our preliminary data indicate substantial differences pre- and post-necrosis regarding TAM enrichment, immunosuppressive phenotypic conversion and their biological impact, however these mechanisms have not yet been elucidated. Our models capture glioma growth dynamics, reactive neuroinflammation and therapeutic resistance, facilitating innovative pre-clinical interventions to improve patient outcome.