STEM-03. TARGETING ANDROGEN SIGNALING IN GLIOBLASTOMA

Abstract

Abstract BACKGROUND Glioblastoma is a lethal brain cancer. Androgen receptor (AR) transcript levels and protein expression are upregulated in glioblastoma compared to normal brain. AR signaling has a role in cancer stem cell function in various cancers. Stem cell activity and cancer cell plasticity represent a key resistance mechanism in glioblastoma. Thus, potent brain-penetrant anti-androgen therapies have the potential to improve treatment outcomes in glioblastoma. METHODS Clinical samples and patient derived xenografts were assessed for AR expression by immunohistochemistry. Cytoplasmic AR+ and AR- glioblastoma patient-derived xenografts maintained under stem cell conditions were tested in vitro for their response to anti-androgen therapies (abiraterone, enzalutamide and seviteronel). Stem cell function was assessed using a tumoursphere assay. Changes in plasticity markers, including ZEB1, were measured with immunofluorescence. RESULTS ~55% of people with glioblastoma have detectable cytoplasmic AR based on immunohistochemistry. AR-positive patient-derived glioma stem cell line RN1 was inhibited by low concentrations of anti-androgen agents, with seviteronel having the lowest half maximal inhibitory concentration (IC50) (at 96 hours: enzalutamide 52µM, abiraterone 12µM, seviteronel 7µM). AR-negative line WK1 was also inhibited though with higher IC50s (at 96 hours: enzalutamide 63µM, seviteronel 21µM). Conventional cell lines U87 and U251 were also inhibited by anti-androgen monotherapy. Tumoursphere assays demonstrated that anti-androgen agents inhibit the tumour-forming ability of cells, with seviteronel and abiraterone showing more inhibition than enzalutamide. Immunofluorescence analysis showed downregulation of plasticity marker ZEB1 with anti-androgen treatment (normalised mean fluorescent intensity: abiraterone 0.84, enzalutamide 0.91, seviteronel 0.74). CONCLUSIONS Glioblastoma is a devastating disease, lacking effective or targeted treatments. Targeting AR with repurposed anti-androgen drugs may be a promising therapeutic strategy, with the potential to abrogate treatment resistance. We are now evaluating these anti-androgen regimens in animal experiments, which will provide a more replicative microenvironment and confirm blood-brain barrier penetrance.