Activated ALK Signals Through the ERK-ETV5-RET Pathway to Drive Neuroblastoma Oncogenesis

Overview

Journal Oncogene

Specialties Molecular Biology
Oncology

Date 2018 Jan 12

PMID 29321660

Citations 27

Authors

Lucille Lopez-Delisle

Cecile Pierre-Eugene

Caroline Louis-Brennetot

Didier Surdez

Virginie Raynal

Sylvain Baulande

Valentina Boeva

Sandrine Grossetete-Lalami

Valerie Combaret

Michel Peuchmaur

Olivier Delattre

Isabelle Janoueix-Lerosey

Affiliations

Soon will be listed here.

Abstract

Activating mutations of the ALK receptor occur in a subset of neuroblastoma tumors. We previously demonstrated that Alk mutations cooperate with MYCN overexpression to induce neuroblastoma in mice and identified Ret as being strongly upregulated in MYCN/Alk tumors. By a genetic approach in vivo, we now document an oncogenic cooperation between activated Ret and MYCN overexpression in neuroblastoma formation. We show that MYCN/Ret tumors exhibit histological features and expression profiles close to MYCN/Alk tumors. We show that RET transcript levels decrease precedes RET protein levels decrease upon ALK inhibition in neuroblastoma cell lines. Etv5 was identified as a candidate transcription factor regulating Ret expression from murine MYCN/Alk tumor transcriptomic data. We demonstrate that ETV5 is regulated both at the protein and mRNA levels upon ALK activation or inhibition in neuroblastoma cell lines and that this regulation precedes RET modulation. We document that ALK activation induces ETV5 protein upregulation through stabilization in a MEK/ERK-dependent manner. We show that RNAi-mediated inhibition of ETV5 decreases RET expression. Reporter assays indicate that ETV5 is able to drive RET gene transcription. ChIP-seq analysis confirmed ETV5 binding on the RET promoter and identified an enhancer upstream of the promoter. Finally, we demonstrate that combining RET and ALK inhibitors reduces tumor growth more efficiently than each single agent in MYCN and Alk-driven murine neuroblastoma. Altogether, these results define the ERK-ETV5-RET pathway as a critical axis driving neuroblastoma oncogenesis downstream of activated ALK.

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