Mechanistically distinct cancer-associated mTOR activation clusters predict sensitivity to rapamycin
Jianing Xu, … , Emily H. Cheng, James J. Hsieh
Jianing Xu, … , Emily H. Cheng, James J. Hsieh
Published August 2, 2016
Citation Information: J Clin Invest. 2016;126(9):3526-3540. https://doi.org/10.1172/JCI86120.
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Mechanistically distinct cancer-associated mTOR activation clusters predict sensitivity to rapamycin

Abstract

Genomic studies have linked mTORC1 pathway–activating mutations with exceptional response to treatment with allosteric inhibitors of mTORC1 called rapalogs. Rapalogs are approved for selected cancer types, including kidney and breast cancers. Here, we used sequencing data from 22 human kidney cancer cases to identify the activating mechanisms conferred by mTOR mutations observed in human cancers and advance precision therapeutics. mTOR mutations that clustered in focal adhesion kinase targeting domain (FAT) and kinase domains enhanced mTORC1 kinase activity, decreased nutrient reliance, and increased cell size. We identified 3 distinct mechanisms of hyperactivation, including reduced binding to DEP domain–containing MTOR-interacting protein (DEPTOR), resistance to regulatory associated protein of mTOR–mediated (RAPTOR-mediated) suppression, and altered kinase kinetics. Of the 28 mTOR double mutants, activating mutations could be divided into 6 complementation groups, resulting in synergistic Rag- and Ras homolog enriched in brain–independent (RHEB-independent) mTORC1 activation. mTOR mutants were resistant to DNA damage–inducible transcript 1–mediated (REDD1-mediated) inhibition, confirming that activating mutations can bypass the negative feedback pathway formed between HIF1 and mTORC1 in the absence of von Hippel–Lindau (VHL) tumor suppressor expression. Moreover, VHL-deficient cells that expressed activating mTOR mutants grew tumors that were sensitive to rapamycin treatment. These data may explain the high incidence of mTOR mutations observed in clear cell kidney cancer, where VHL loss and HIF activation is pathognomonic. Our study provides mechanistic and therapeutic insights concerning mTOR mutations in human diseases.

Authors

Jianing Xu, Can G. Pham, Steven K. Albanese, Yiyu Dong, Toshinao Oyama, Chung-Han Lee, Vanessa Rodrik-Outmezguine, Zhan Yao, Song Han, David Chen, Daniel L. Parton, John D. Chodera, Neal Rosen, Emily H. Cheng, James J. Hsieh

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Figure 5

Characterization of the response of mTOR-activating mutants to RAPTOR-mediated inhibition; mTOR kinase domain mutants exhibit increased kinase activity and display structural reorganization.

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Characterization of the response of mTOR-activating mutants to RAPTOR-me...
(A) 293T cells, transfected with vectors expressing HA-S6K, indicated Flag-mTOR mutants, and either GFP or RAPTOR was subjected to immunoblot analysis using the indicated antibodies. Hatched bars indicate the mutants not inhibited by overexpressed RAPTOR. Densitometry of phosphorylated S6K versus HA-S6K from 3 independent experiments is shown (mean ± SEM, n = 3 independent experiments). **P < 0.01; ***P < 0.001 (t test). (B) In vitro kinase assays were carried out with the indicated Flag-tagged recombinant mTOR proteins in the presence of the indicated amount of recombinant HA-S6K. The recombinant Flag-mTOR and HA-S6K proteins were produced in 293T cells by transient transfection of respective expression constructs followed by anti-Flag and anti-HA affinity purification, respectively. The reactions were analyzed by the indicated immunoblots. (C) Graph shows the quantitation of the phosphorylated S6K(T389) determined by densitometry versus S6K at different concentrations. (D) A contact map where each point (x, y) gives the net change in probability of forming a contact between residue x and residue y between the mutant and WT, as estimated from simulations. The net contact change (blue indicating gain, red indicating loss) observed in the S2215F mutant is shown in the upper-left triangle, with WT shown in the bottom right to indicate the secondary structure present at corresponding locations. Disrupted contacts between residues 2214 and 2217 (green circle 1), residues 2218 and 2389, and residues 2214 and 2402 (green circle 2) are highlighted. (E) Superposition of WT (gray) and S2215F (wheat) mTOR kinase domain structures at 501 ns of simulation, with the S2215F mutation shown in red sticks. Of note, kα3b is unwound and has moved further away from kα8 in S2215F simulation.