Cotargeting MNK and MEK kinases induces the regression of NF1-mutant cancers
Rebecca Lock, … , Jeremy R. Graff, Karen Cichowski
Rebecca Lock, … , Jeremy R. Graff, Karen Cichowski
Published May 9, 2016
Citation Information: J Clin Invest. 2016;126(6):2181-2190. https://doi.org/10.1172/JCI85183.
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Research Article Oncology

Cotargeting MNK and MEK kinases induces the regression of NF1-mutant cancers

Abstract

Neurofibromin 1–mutant (NF1-mutant) cancers are driven by excessive Ras signaling; however, there are currently no effective therapies for these or other Ras-dependent tumors. While combined MEK and mTORC1 suppression causes regression of NF1-deficient malignancies in animal models, the potential toxicity of cotargeting these 2 major signaling pathways in humans may necessitate the identification of more refined, cancer-specific signaling nodes. Here, we have provided evidence that MAPK-interacting kinases (MNKs), which converge on the mTORC1 effector eIF4E, are therapeutic targets in NF1-deficient malignancies. Specifically, we evaluated primary human NF1-deficient peripheral nervous system tumors and found that MNKs are activated in the majority of tumors tested. Genetic and chemical suppression of MNKs in NF1-deficient murine tumor models and human cell lines potently cooperated with MEK inhibitors to kill these cancers through effects on eIF4E. We also demonstrated that MNK kinases are important and direct targets of cabozantinib. Accordingly, coadministration of cabozantinib and MEK inhibitors triggered dramatic regression in an aggressive genetically engineered tumor model. The cytotoxicity of this combination required the suppression of MNK-induced eIF4E phosphorylation and was not recapitulated by suppressing other cabozantinib targets. Collectively, these studies demonstrate that combined MNK and MEK suppression represents a promising therapeutic strategy for these incurable Ras-driven tumors and highlight the utility of developing selective MNK inhibitors for these and possibly other malignancies.

Authors

Rebecca Lock, Rachel Ingraham, Ophélia Maertens, Abigail L. Miller, Nelly Weledji, Eric Legius, Bruce M. Konicek, Sau-Chi B. Yan, Jeremy R. Graff, Karen Cichowski

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Figure 4

Cabozantinib cooperates with PD901 by suppressing MNK and eIF4E phosphorylation.

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Cabozantinib cooperates with PD901 by suppressing MNK and eIF4E phosphor...
(A) p-MET, p-eIF4E, and p-ERK1/2 levels in S462 cells 24 hours after treatment with 1 μM PF04217903 and 750 nM PD901. (B) Change in cell number after treatment with 1 μM PF04217903 (PF903) and/or 750 nM PD901. Graph represents the average log2 of fold change in cell number 72 hours after treatment relative to time 0 (mean ± SD, n = 3). (C) Axl, VEGFR-2, p-eIF4E, and p-ERK1/2 levels in S462s following transfection with siAXL, siKDR, or control siRNA (siCNT). (D) Change in cell number following transfection with siAXL, siKDR, or siCNT and treatment with 750 nM PD901. Graph represents the average log2 of fold change in cell number 72 hours after treatment relative to time 0 (mean ± SD, n = 3). (E) eIF4E levels in parental S462 cells or cells expressing exogenous Flag-HA–tagged (FHA) eIF4E WT or eIF4ES209D coexpressing shEIF4E_1 against endogenous eIF4E. (F) (Left) Change in cell number of FHA-WT eIF4E– and FHA-eIF4ES209D–expressing cells coexpressing shEIF4E_1 treated with 750 nM PD901 alone or in combination with 0.5 μM cabozantinib. Graph represents the average log2 of fold change in cell number 72 hours after treatment relative to time 0 (mean ± SD, n = 3, t test). (Right) p-eIF4E and p-ERK1/2 levels in cells described above 24 hours after treatment. (G) (Left) Levels of p-eIF4E in 90-8TL human MPNST cells relative to S462 cells. (Right) p-MET, p-eIF4E, and p-ERK1/2 levels in 90-8TL cells treated with 0.5 μM or 1 μM cabozantinib alone or combined with 1 μM PD901. (H) Change in cell number of 90-8TL cells treated with the indicated concentrations of cabozantinib or 1 μM PD901 alone or in combination. Graph represents the average log2 of fold change in cell number 72 hours after treatment relative to time 0 (mean ± SD, n = 3). Experiments repeated at least 3 times for validation.