EPEN-04. OVERWHELMING ZFTA-RELA NUCLEAR LOCALIZATION AS A THERAPEUTIC STRATEGY AGAINST EPENDYMOMA

Abstract

Abstract BACKGROUND Pediatric ependymoma is a malignant brain tumor without targeted therapies. The 10-year survival is close to 50%, as this relentless tumor often relapses years following initial diagnosis. Over two thirds of supratentorial ependymomas harbor a gene fusion between ZFTA and RELA (ZFTA-RELA). Despite evidence that ZFTA-RELA drives tumorigenicity, mechanistic details remain elusive, hindering efforts to uncover therapeutic vulnerabilities. Since direct targeting of ZFTA-RELA is not currently possible, we hypothesized that ZFTA-RELA fusion binding partners would represent vulnerabilities amenable to therapeutic targeting. METHODS We investigated the biochemical basis of ZFTA-RELA, with the goal of identifying key members of the protein interaction landscape. This was performed in our in utero electroporation mouse model of ZFTA-RELA ependymoma. A series of sucrose gradient and immuno-precipitation experiments were performed, coupled with mass spectrometry. ZFTA-RELA interaction proteins were functionalized using focused CRIPSR-Cas9 library screens in cell cultures. Critically, these revealed novel dependencies and druggable targets, with XPO1 emerging as a lead candidate. In vitro and in vivo studies were conducted to evaluate targeting XPO1 in ZFTA-RELA ependymoma. RESULTS ZFTA-RELA regulates XPO1 gene transcription, and elevated gene expression is associated with poor survival in these patients. While expression of ZFTA-RELA is necessary for oncogenic transcription, extremely elevated nuclear localization is associated with reduced growth. This suggests a ‘goldilocks’ model in which XPO1 titrates precise levels of nuclear ZFTA-RELA protein. We reveal that a potential therapeutic vulnerability emerges through modulation of ZFTA-RELA nuclear localization. Supporting this, chemical inhibition of XPO1 using Selinexor, has a direct effect on ZFTA-RELA cellular localization patterns. Critically, in patient derived orthotopic xenograft models, XPO1 inhibition exerts anti-tumor effects both in vitro and in vivo. CONCLUSION Our findings reveal a novel therapeutic strategy in ependymoma, and provide the mechanistic and pre-clinical data needed to develop a clinical trial for patients with ZFTA-RELA ependymoma.