EPEN-32. Leveraging cell surface targets as therapeutic vulnerabilities for pediatric ependymoma

Abstract

Brain tumors are the leading cause of cancer-associated death in children. Ependymoma, an aggressive type of childhood brain tumor, is currently treated with surgery and radiotherapy. Ependymomas are a molecularly heterogeneous group of tumors driven by distinct genetic and epigenetic alterations. In children, 90% of ependymomas arise intracranially, with two thirds occurring in the posterior fossa (PF) and one third in the supratentorial brain (ST). PF ependymomas are divided into at least two groups termed, PFA and PFB, with PFA tumors associated with poor clinical outcomes. Over 70% of ST ependymoma are characterized by an oncogenic fusion between ZFTA and RELA and shown in some cohorts to have poor clinical outcome, particularly in the context of CDKN2A tumor suppressor gene loss. A major challenge in identifying therapies against ependymoma, has been the paucity of genetic abnormalities available for targeting. PFA ependymomas harbor largely balanced genomes with no recurrent CNVs, fusions, or somatic mutations that are amenable to pharmacologic inhibition. ZFTA-RELA ependymoma while representing a clear disease driver, functions as a transcription factor and lacks clear binding surfaces available for direct inhibition using small molecules. Therefore, alternative approaches are needed to identify new targets and effective therapies in ependymoma to be evaluated in pre-clinical models. In both human ependymoma cell culture lines and PDX models, we demonstrate that a multi-omic approach is promising for cell surface target discovery, and further, focused cell surface profiling can identify lead targets that can be rapidly translated for CAR T-cell therapy.