CSIG-04. UNCOUPLING OF ETS1 FROM MAPK PATHWAY SIGNALS AS RESISTANCE MECHANISM TOWARDS BRAF INHIBITORS IN BRAF-MUTATED CHILDHOOD GLIOMA

High-grade gliomas are among the most aggressive brain tumors across all age groups. BRAF is within the most frequently altered genes in pediatric glioma, sometimes connected with telomerase reverse transcriptase (TERT) promoter mutations, predicting a particularly aggressive course of disease. Precision medicine approaches targeting the MAPK pathway have shown promising results in patients with BRAF-mutated glioma. Although acquired insensitivity to BRAF inhibitors appears as major issue for therapy failure, underlying molecular mechanisms are still poorly understood.

Cell models from an anaplastic pleomorphic xanthoastrocytoma with BRAF^V600E and TERT promoter mutations and the recurrent tumor, operated following MAPK pathway-targeting therapy, were established. Furthermore, a dabrafenib-resistant subline of the recurrent tumor was generated. The patient-derived cell models were genetically characterized using array-based genomic hybridization (aCGH). Sensitivity of the cells towards different MAPK pathway inhibitors was tested. Basal expression and activation of MAPK pathway and downstream signals were analyzed by qRT-PCR and Western blots.

Screening a panel of both primary and immortalized glioma cell models with different BRAF and TERT promoter status revealed significantly induced MAPK pathway activation and enhanced TERT levels in BRAF^V600E and TERT promoter double-mutant gliomas. Furthermore, cells with both mutations were hyper-sensitive towards BRAF-targeting agents and BRAF inhibition resulted in reduced TERT levels. ETS1 expression was strongly increased in the recurrent tumor and identified as important player in telomerase re-activation. aCGH revealed gains of chromosomal regions encoding for different ETS-factors in the dabrafenib-resistant subline. Western blot analyses suggested a BRAF/ERK-independent survival mechanism in the dabrafenib-resistant subline. Accordingly, dabrafenib insensitivity triggered cross-resistance towards the MEK inhibitor trametinib. Uncoupled from the MAPK pathway, ETS1 expression was further upregulated in the dabrafenib-resistant subline. CONSLUSION: Taken together, our data demonstrate that MAPK-independent ETS transcription factor upregulation is a central mechanism of BRAF inhibitor therapy failure in BRAF-mutated pediatric glioma patients.