TMIC-33. UNDERSTAND AND TARGET ASTROCYTE REACTIVITY IN BRAIN TUMORS TO PREVENT RADIORESISTANCE

Abstract

Abstract Glioblastoma multiforme (GBM) is the most aggressive type of glioma and deadliest brain tumor. Despite aggressive treatments including surgery, chemo-, and radiotherapy, tumors invariably recur as incurable lesions, and the median survival is approximately 15 months after diagnosis. Recurrence is tightly linked to tumor cell resistance to ionizing radiation (IR), a feature that in turn is linked to stem cell characteristics of tumor cells. Previous results from our lab indicate that stromal astrocytes respond to IR with a reactive phenotype that in turn promotes therapeutic resistance of neighboring tumor cells. Our objectives were to i) identify pathways involved in IR-induced astrocyte reactivity; ii) identify compounds able to inhibit IR-induced astrocyte reactivity. We used two complementary approaches to meet our objectives. Using an antibody array we found that JNK and ABL pathways were activated following IR in primary human astrocytes. To validate their involvement in the induction of astrocyte reactive phenotype we used an image-based readout combining the changes in the expression of reactivity markers and in the morphology of astrocytes. For the second approach, we used a similar readout to perform an image-based drug screen which aimed to identify compounds able to inhibit IR-induced astrocyte reactivity. The drug libraries used consisted of approved drugs to get candidates with potential for drug repurposing. We identified 20 compounds inhibiting IR-induced astrocyte reactivity and amongst them, 10 are brain-penetrant compounds that could make them good candidates for repurposing in GBM. An in vivo test is now ongoing with 2 of these compounds in a PDGFA/PDGFB-driven mouse model of GBM to validate their efficiency to increase radiosensitivity of the tumor cell by inhibiting astrocyte reactivity