GATOR2-dependent mTORC1 activity is a therapeutic vulnerability in FOXO1 fusion–positive rhabdomyosarcoma
Jacqueline Morales, David V. Allegakoen, José A. Garcia, Kristen Kwong, Pushpendra K. Sahu, Drew A. Fajardo, Yue Pan, Max A. Horlbeck, Jonathan S. Weissman, W. Clay Gustafson, Trever G. Bivona, Amit J. Sabnis
Jacqueline Morales, David V. Allegakoen, José A. Garcia, Kristen Kwong, Pushpendra K. Sahu, Drew A. Fajardo, Yue Pan, Max A. Horlbeck, Jonathan S. Weissman, W. Clay Gustafson, Trever G. Bivona, Amit J. Sabnis
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Research Article Genetics Oncology

GATOR2-dependent mTORC1 activity is a therapeutic vulnerability in FOXO1 fusion–positive rhabdomyosarcoma

Abstract

Oncogenic FOXO1 gene fusions drive a subset of rhabdomyosarcoma (RMS) with poor survival; to date, these cancer drivers are therapeutically intractable. To identify new therapies for this disease, we undertook an isogenic CRISPR-interference screen to define PAX3-FOXO1–specific genetic dependencies and identified genes in the GATOR2 complex. GATOR2 loss in RMS abrogated aa-induced lysosomal localization of mTORC1 and consequent downstream signaling, slowing G1-S cell cycle transition. In vivo suppression of GATOR2 impaired the growth of tumor xenografts and favored the outgrowth of cells lacking PAX3-FOXO1. Loss of a subset of GATOR2 members can be compensated by direct genetic activation of mTORC1. RAS mutations are also sufficient to decouple mTORC1 activation from GATOR2, and indeed, fusion-negative RMS harboring such mutations exhibit aa-independent mTORC1 activity. A bisteric, mTORC1-selective small molecule induced tumor regressions in fusion-positive patient-derived tumor xenografts. These findings highlight a vulnerability in FOXO1 fusion–positive RMS and provide rationale for the clinical evaluation of bisteric mTORC1 inhibitors, currently in phase I testing, to treat this disease. Isogenic genetic screens can, thus, identify potentially exploitable vulnerabilities in fusion-driven pediatric cancers that otherwise remain mostly undruggable.

Authors

Jacqueline Morales, David V. Allegakoen, José A. Garcia, Kristen Kwong, Pushpendra K. Sahu, Drew A. Fajardo, Yue Pan, Max A. Horlbeck, Jonathan S. Weissman, W. Clay Gustafson, Trever G. Bivona, Amit J. Sabnis

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Figure 1

An isogenic screen identifies PAX3-FOXO1 dependencies.

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An isogenic screen identifies PAX3-FOXO1 dependencies. (A) Immunoblot of...
(A) Immunoblot of lysates from P3F+ and P3FKD cells demonstrating decreased abundance of both PAX3-FOXO1 and its target FGFR4. (B) Differential growth of P3F+ and P3FKD cells in 2D (left: CellTiterGlo after 72 hours of tissue culture; n = 10 wells per condition) or 3D (right: crystal violet quantitation of soft agar colony formation in 0.4% agarose over 4 weeks; n = 3 wells per condition) growth. (C) Schematic of CRISPR-interference screen to identify PAX3-FOXO1 genetic dependencies. Each condition was carried out in experimental duplicate. (D) Screen results. Gene-level scores are plotted on the basis of log2 fold-change in P3F+ (x-axis) or P3FKD (y-axis) conditions. Color indicates FDR-adjusted P value by Mann-Whitney test for significance of fold-change in the P3F+ condition. Black asterisks represent negative control sgRNA. The black box indicates genes selected for further study. (E) Results from the box in D arranged by physical interactions identified in the STRING database (20). Outlines correspond to selectivity calls from the DepMap database (19). Coloring indicates the P value, by Mann-Whitney test, for stronger CERES gene effect score in FP (n = 6) rather than FN (n = 5) cell lines in the DepMap. (F) Schematic of the role of the GATOR2 complex, including MIOS and WDR24, in regulation of mTORC1. Positive regulators of mTORC1 are shown in green.