Tumor heterogeneity underlies clinical outcome and MEK inhibitor response in somatic NF1-mutant glioblastoma
Sixuan Pan, Kanish Mirchia, Emily Payne, S. John Liu, Nadeem Al-Adli, Zain Peeran, Poojan Shukla, Jacob S. Young, Rohit Gupta, Jasper Wu, Joanna Pak, Tomoko Ozawa, Brian Na, Alyssa T. Reddy, Steve E. Braunstein, Joanna J. Phillips, Susan Chang, David A. Solomon, Arie Perry, David R. Raleigh, Mitchel S. Berger, Adam R. Abate, Harish N. Vasudevan
Sixuan Pan, Kanish Mirchia, Emily Payne, S. John Liu, Nadeem Al-Adli, Zain Peeran, Poojan Shukla, Jacob S. Young, Rohit Gupta, Jasper Wu, Joanna Pak, Tomoko Ozawa, Brian Na, Alyssa T. Reddy, Steve E. Braunstein, Joanna J. Phillips, Susan Chang, David A. Solomon, Arie Perry, David R. Raleigh, Mitchel S. Berger, Adam R. Abate, Harish N. Vasudevan
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Research Article Genetics Oncology

Tumor heterogeneity underlies clinical outcome and MEK inhibitor response in somatic NF1-mutant glioblastoma

Abstract

Tumor suppressor NF1 is recurrently mutated in glioblastoma, leading to aberrant activation of Ras/rapidly accelerated fibrosarcoma (RAF)/MEK signaling. However, how tumor heterogeneity shapes the molecular landscape and efficacy of targeted therapies remains unclear. Here, we combined bulk and single-cell genomics of human somatic NF1-mutant, isocitrate dehydrogenase (IDH) wild-type glioblastomas with functional studies in cell lines and mouse intracranial tumor models to identify mechanisms of tumor heterogeneity underlying clinical outcome and MEK inhibitor response. Targeted DNA sequencing identified CDKN2A/B homozygous deletion as a poor prognostic marker in somatic NF1-mutant, but not NF1 wild-type, glioblastoma. Single-nucleus RNA sequencing of human patient NF1-mutant glioblastomas demonstrated that mesenchymal-like (MES-like) tumor cells were enriched for MEK activation signatures. Single-cell RNA-sequencing of mouse intracranial glioblastomas treated with the MEK inhibitor selumetinib identified distinct responses among tumor subpopulations. MEK inhibition selectively depleted MES-like cells, and selumetinib-resistant MES-like cells upregulated Ras signaling while resistant non-MES cells expressed markers of glial differentiation. Finally, genome-wide CRISPR interference screens validated Ras/RAF/MEK signaling as a key mediator of selumetinib response. Repression of the RAF regulator SHOC2 sensitized glioblastomas to selumetinib in vitro and in vivo, suggesting a synergistic treatment strategy. Taken together, these results highlighted the heterogeneity of NF1-mutant glioblastomas and informed future combination therapies.

Authors

Sixuan Pan, Kanish Mirchia, Emily Payne, S. John Liu, Nadeem Al-Adli, Zain Peeran, Poojan Shukla, Jacob S. Young, Rohit Gupta, Jasper Wu, Joanna Pak, Tomoko Ozawa, Brian Na, Alyssa T. Reddy, Steve E. Braunstein, Joanna J. Phillips, Susan Chang, David A. Solomon, Arie Perry, David R. Raleigh, Mitchel S. Berger, Adam R. Abate, Harish N. Vasudevan

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Figure 1

Targeted DNA sequencing of somatic NF1-mutant, IDH wild-type glioblastoma (n = 186) reveals CDKN2A/B codeletion is associated with significantly worse overall survival.

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Targeted DNA sequencing of somatic NF1-mutant, IDH wild-type glioblastom...
(A) DNA mutational analysis of NF1-mutant, IDH wild-type glioblastoma (n = 186) identifies recurrent co-alterations (>10% of tumors) in the TERT promoter, TP53, cell cycle regulators (CDKN2A/B, RB1), PI3K signaling (PTEN, PIK3CA, PIK3R1), and Ras signaling (PTPN11). (B) Analysis of recurrently comutated genes in NF1-mutant and propensity score–matched NF1 wild-type glioblastoma cohort reveals NF1-mutant tumors exhibit significantly increased co-alteration with PTPN11 mutation and are mutually coexclusive with EGFR, CDK4, MDM2, and MDM4 alterations. (C) NF1-mutant glioblastomas do not demonstrate significantly different outcomes compared with NF1 wild-type glioblastomas in a propensity score–matched cohort of IDH wild-type glioblastomas. (D) CDKN2A/B homozygous loss is associated with significantly worse OS compared with CDKN2A/B-intact tumors across NF1-mutant (log-rank test, P = 0.03) but not (E) NF1 wild-type glioblastomas (log-rank test, P = 0.34). (F) Multivariable CPH analysis of recurrent genetic alterations shows CDKN2A/B loss is the only independent genetic factor significantly associated with worse OS in NF1-mutant glioblastoma. Factors in red are significantly associated with OS.