Abstract 1153: Hypoxic microenvironments promote stemness and enhance the directed migration of glioma stem cells

Abstract

Abstract Glioblastoma (GBM) is a highly malignant primary brain tumor and has a poor prognosis and is resistant to the most advanced therapies. The development of highly hypoxic centrally located necrotic regions is strongly associated with accelerated GBM progression, yet mechanistic explanations are not complete. Hypoxic regions within GBM are highly enriched for glioma stem cells (GSC), which are critical for tumor initiation, recurrence and therapeutic resistance due to their self-renewing capabilites. While most GBM cells migrate outward, away from hypoxia, GSCs accumulate there, forming a hypercellular border called pseudopalisades that promote their survival. Mechanisms that mediate GSC accumulation within pseudopalisades are unknown. We hypothesize that GSCs are enriched in the pseudopalisades due to the homing of a subpopulation towards the supportive hypoxic microenvironment. This in turn activates critical hypoxia-induced drivers to promote stemness, survival and migratory behavior encouraging the recruitment of more GSCs. Using two genetically distinct patient-derived GBM cell lines, we found that exposure to hypoxia in vitro led to enrichment of GSCs among a heterogeneous population of GSCs and non-GSCs. We found that hypoxia enhanced the expression of stem cell, pro-survival and pro-migratory factors in GSCs, such as the pro-migratory chemokine SDF-1α, and its cognate receptor CXCR4. Importantly, we found hypoxia also induced upregulation of OLIG2, one of four core transcription factors necessary and sufficient to induce stemness, in GSCs and non-GSCs exposed to hypoxia. We determined that OLIG2 was necessary for the expression of stem cell markers, and that its knockdown reduced cellular migration in hypoxia vs normoxia in GSCs. This suggests a critical role for OLIG2 in both hypoxia-induced stemness and homing behavior. We also generated a unique model of localized hypoxia in one brain hemisphere through vaso-cclusion and observed the homing of xenografted GBM cells towards hypoxia, regulated by OLIG2 in vivo. These data shed light on how hypoxic tumor microenvironments facilitate mechanisms vital to GBM progression and therapeutic resistance. Citation Format: Nitya V. Sharma, Monica Chau, Subhas Mukherjee, James Ross, Brandon Miller, Changming Zhang, Jun Kong, Carol Tucker-Burden, Emily Kaissi, John W. Reitnauer, Bilge Dundar, Cheryl L. Olson, Gregory Bix, Daniel J. Brat. Hypoxic microenvironments promote stemness and enhance the directed migration of glioma stem cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 1153.