Schwannoma development is mediated by Hippo pathway dysregulation and modified by RAS/MAPK signaling
Zhiguo Chen, Stephen Li, Juan Mo, Eric Hawley, Yong Wang, Yongzheng He, Jean-Philippe Brosseau, Tracey Shipman, D. Wade Clapp, Thomas J. Carroll, Lu Q. Le
Zhiguo Chen, Stephen Li, Juan Mo, Eric Hawley, Yong Wang, Yongzheng He, Jean-Philippe Brosseau, Tracey Shipman, D. Wade Clapp, Thomas J. Carroll, Lu Q. Le
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Research Article Genetics Oncology

Schwannoma development is mediated by Hippo pathway dysregulation and modified by RAS/MAPK signaling

Abstract

Schwannomas are tumors of the Schwann cells that cause chronic pain, numbness, and potentially life-threatening impairment of vital organs. Despite the identification of causative genes, including NF2 (Merlin), INI1/SMARCB1, and LZTR1, the exact molecular mechanism of schwannoma development is still poorly understood. Several studies have identified Merlin as a key regulator of the Hippo, MAPK, and PI3K signaling pathways; however, definitive evidence demonstrating the importance of these pathways in schwannoma pathogenesis is absent. Here, we provide direct genetic evidence that dysregulation of the Hippo pathway in the Schwann cell lineage causes development of multiple schwannomas in mice. We found that canonical Hippo signaling through the effectors YAP/TAZ is required for schwannomagenesis and that MAPK signaling modifies schwannoma formation. Furthermore, cotargeting YAP/TAZ transcriptional activity and MAPK signaling demonstrated a synergistic therapeutic effect on schwannomas. Our new model provides a tractable platform to dissect the molecular mechanisms underpinning schwannoma formation and the role of combinatorial targeted therapy in schwannoma treatment.

Authors

Zhiguo Chen, Stephen Li, Juan Mo, Eric Hawley, Yong Wang, Yongzheng He, Jean-Philippe Brosseau, Tracey Shipman, D. Wade Clapp, Thomas J. Carroll, Lu Q. Le

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Figure 4

YAP/TAZ gene dosage determines the tumor burden and survival.

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YAP/TAZ gene dosage determines the tumor burden and survival. (A and B) ...
(A and B) Representative pictures of tumor-burdened mice (left panel). Scatter plot of the total number of palpable tumors in each mouse (middle panel). Kaplan-Meier plot illustrating the survival curve among the groups with corresponding genotypes (right panel) for Hoxb7-Cre;Lats1fl/+;Lats2fl/fl (A) and Hoxb7-Cre;Lats1fl/fl;Lats2fl/+ (B) mice. H7;Lats1fl/+;Lats2fl/fl;YAP/TAZmut4, n = 12. H7;Lats1fl/+;Lats2fl/fl;YAP/TAZmut3, n = 44. H7;Lats1fl/+;Lats2fl/fl;YAP/TAZmut2, n = 60. H7;Lats1fl/+;Lats2fl/fl;YAP/TAZWT, n = 24. H7;Lats1fl/fl;Lats2fl/+;YAP/TAZmut4, n = 15. H7;Lats1fl/fl;Lats2fl/+;YAP/TAZmut3, n = 29. H7;Lats1fl/fl;Lats2fl/+;YAP/TAZmut2, n = 39. H7;Lats1fl/fl;Lats2fl/+;YAP/TAZWT, n = 25. (C) IHC of YAP and TAZ on tumor sections. (D) Quantification of IHC in C (n = 3/group). (E) Genotyping of tumor tissues (upper panel) and tumor-derived cell lines (lower panel). Red star, intact floxed allele. Green dot, nonspecific amplification. Scale bars: 50 μm. One-way ANOVA with Tukey’s test for multiple comparisons were applied to evaluate statistical significance in A, B, and D. Log-rank statistical test was employed in A and B. Statistics are represented as the mean ± SEM. *P < 0.05, **P < 0.01, ***P < 0.001.