Genome Biology (Jul 2020)

PiggyBac mutagenesis and exome sequencing identify genetic driver landscapes and potential therapeutic targets of EGFR-mutant gliomas

  • Imran Noorani,
  • Jorge de la Rosa,
  • Yoonha Choi,
  • Alexander Strong,
  • Hannes Ponstingl,
  • M. S. Vijayabaskar,
  • Jusung Lee,
  • Eunmin Lee,
  • Angela Richard-Londt,
  • Mathias Friedrich,
  • Federica Furlanetto,
  • Rocio Fuente,
  • Ruby Banerjee,
  • Fengtang Yang,
  • Frances Law,
  • Colin Watts,
  • Roland Rad,
  • George Vassiliou,
  • Jong Kyoung Kim,
  • Thomas Santarius,
  • Sebastian Brandner,
  • Allan Bradley

DOI
https://doi.org/10.1186/s13059-020-02092-2
Journal volume & issue
Vol. 21, no. 1
pp. 1 – 36

Abstract

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Abstract Background Glioma is the most common intrinsic brain tumor and also occurs in the spinal cord. Activating EGFR mutations are common in IDH1 wild-type gliomas. However, the cooperative partners of EGFR driving gliomagenesis remain poorly understood. Results We explore EGFR-mutant glioma evolution in conditional mutant mice by whole-exome sequencing, transposon mutagenesis forward genetic screening, and transcriptomics. We show mutant EGFR is sufficient to initiate gliomagenesis in vivo, both in the brain and spinal cord. We identify significantly recurrent somatic alterations in these gliomas including mutant EGFR amplifications and Sub1, Trp53, and Tead2 loss-of-function mutations. Comprehensive functional characterization of 96 gliomas by genome-wide piggyBac insertional mutagenesis in vivo identifies 281 known and novel EGFR-cooperating driver genes, including Cdkn2a, Nf1, Spred1, and Nav3. Transcriptomics confirms transposon-mediated effects on expression of these genes. We validate the clinical relevance of new putative tumor suppressors by showing these are frequently altered in patients’ gliomas, with prognostic implications. We discover shared and distinct driver mutations in brain and spinal gliomas and confirm in vivo differential tumor suppressive effects of Pten between these tumors. Functional validation with CRISPR-Cas9-induced mutations in novel genes Tead2, Spred1, and Nav3 demonstrates heightened EGFRvIII-glioma cell proliferation. Chemogenomic analysis of mutated glioma genes reveals potential drug targets, with several investigational drugs showing efficacy in vitro. Conclusion Our work elucidates functional driver landscapes of EGFR-mutant gliomas, uncovering potential therapeutic strategies, and provides new tools for functional interrogation of gliomagenesis.