Literature DB >> 34168367

Selective inhibitors of mTORC1 activate 4EBP1 and suppress tumor growth.

Bianca J Lee1, Jacob A Boyer2,3, G Leslie Burnett4, Arun P Thottumkara4, Nidhi Tibrewal5, Stacy L Wilson1, Tientien Hsieh5, Abby Marquez5, Edward G Lorenzana1, James W Evans1, Laura Hulea6,7,8, Gert Kiss5, Hui Liu9, Dong Lee10, Ola Larsson9, Shannon McLaughlan6, Ivan Topisirovic6, Zhengping Wang10, Zhican Wang10, Yongyuan Zhao10, David Wildes1, James B Aggen4, Mallika Singh1, Adrian L Gill4, Jacqueline A M Smith11, Neal Rosen12.   

Abstract

The clinical benefits of pan-mTOR active-site inhibitors are limited by toxicity and relief of feedback inhibition of receptor expression. To address these limitations, we designed a series of compounds that selectively inhibit mTORC1 and not mTORC2. These 'bi-steric inhibitors' comprise a rapamycin-like core moiety covalently linked to an mTOR active-site inhibitor. Structural modification of these components modulated their affinities for their binding sites on mTOR and the selectivity of the bi-steric compound. mTORC1-selective compounds potently inhibited 4EBP1 phosphorylation and caused regressions of breast cancer xenografts. Inhibition of 4EBP1 phosphorylation was sufficient to block cancer cell growth and was necessary for maximal antitumor activity. At mTORC1-selective doses, these compounds do not alter glucose tolerance, nor do they relieve AKT-dependent feedback inhibition of HER3. Thus, in preclinical models, selective inhibitors of mTORC1 potently inhibit tumor growth while causing less toxicity and receptor reactivation as compared to pan-mTOR inhibitors.
© 2021. The Author(s), under exclusive licence to Springer Nature America, Inc.

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Year:  2021        PMID: 34168367      PMCID: PMC9249104          DOI: 10.1038/s41589-021-00813-7

Source DB:  PubMed          Journal:  Nat Chem Biol        ISSN: 1552-4450            Impact factor:   16.174


  56 in total

Review 1.  The phosphatidylinositol 3-Kinase AKT pathway in human cancer.

Authors:  Igor Vivanco; Charles L Sawyers
Journal:  Nat Rev Cancer       Date:  2002-07       Impact factor: 60.716

2.  Rapamycin differentially inhibits S6Ks and 4E-BP1 to mediate cell-type-specific repression of mRNA translation.

Authors:  Andrew Y Choo; Sang-Oh Yoon; Sang Gyun Kim; Philippe P Roux; John Blenis
Journal:  Proc Natl Acad Sci U S A       Date:  2008-10-27       Impact factor: 11.205

3.  Structure-activity studies of rapamycin analogs: evidence that the C-7 methoxy group is part of the effector domain and positioned at the FKBP12-FRAP interface.

Authors:  J I Luengo; D S Yamashita; D Dunnington; A K Beck; L W Rozamus; H K Yen; M J Bossard; M A Levy; A Hand; T Newman-Tarr
Journal:  Chem Biol       Date:  1995-07

4.  Mammalian target of rapamycin inhibitors activate the AKT kinase in multiple myeloma cells by up-regulating the insulin-like growth factor receptor/insulin receptor substrate-1/phosphatidylinositol 3-kinase cascade.

Authors:  Yijiang Shi; Huajun Yan; Patrick Frost; Joseph Gera; Alan Lichtenstein
Journal:  Mol Cancer Ther       Date:  2005-10       Impact factor: 6.261

5.  Structure of the FKBP12-rapamycin complex interacting with the binding domain of human FRAP.

Authors:  J Choi; J Chen; S L Schreiber; J Clardy
Journal:  Science       Date:  1996-07-12       Impact factor: 47.728

6.  A novel multivalent ligand that bridges the allosteric and orthosteric binding sites of the M2 muscarinic receptor.

Authors:  Tod Steinfeld; Mathai Mammen; Jacqueline A M Smith; Richard D Wilson; Jeffrey R Jasper
Journal:  Mol Pharmacol       Date:  2007-05-03       Impact factor: 4.436

7.  A scaling normalization method for differential expression analysis of RNA-seq data.

Authors:  Mark D Robinson; Alicia Oshlack
Journal:  Genome Biol       Date:  2010-03-02       Impact factor: 13.583

8.  nanoCAGE reveals 5' UTR features that define specific modes of translation of functionally related MTOR-sensitive mRNAs.

Authors:  Valentina Gandin; Laia Masvidal; Laura Hulea; Simon-Pierre Gravel; Marie Cargnello; Shannon McLaughlan; Yutian Cai; Preetika Balanathan; Masahiro Morita; Arjuna Rajakumar; Luc Furic; Michael Pollak; John A Porco; Julie St-Pierre; Jerry Pelletier; Ola Larsson; Ivan Topisirovic
Journal:  Genome Res       Date:  2016-03-16       Impact factor: 9.043

Review 9.  mTOR-sensitive translation: Cleared fog reveals more trees.

Authors:  Laia Masvidal; Laura Hulea; Luc Furic; Ivan Topisirovic; Ola Larsson
Journal:  RNA Biol       Date:  2017-02-10       Impact factor: 4.652

10.  Polysome fractionation and analysis of mammalian translatomes on a genome-wide scale.

Authors:  Valentina Gandin; Kristina Sikström; Tommy Alain; Masahiro Morita; Shannon McLaughlan; Ola Larsson; Ivan Topisirovic
Journal:  J Vis Exp       Date:  2014-05-17       Impact factor: 1.355
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  4 in total

Review 1.  Chloride intracellular channel 1 promotes esophageal squamous cell carcinoma proliferation via mTOR signalling.

Authors:  Huiwu Geng; Cheng Feng; Zhangran Sun; Xu Fan; Yiqing Xie; Jinghua Gu; Libin Fan; Gang Liu; Chao Li; Rick F Thorne; Xu Dong Zhang; Xinying Li; Xiaoying Liu
Journal:  Transl Oncol       Date:  2022-10-14       Impact factor: 4.803

Review 2.  At a crossroads: how to translate the roles of PI3K in oncogenic and metabolic signalling into improvements in cancer therapy.

Authors:  Neil Vasan; Lewis C Cantley
Journal:  Nat Rev Clin Oncol       Date:  2022-04-28       Impact factor: 65.011

Review 3.  PI3K/Akt/mTOR Pathway and Its Role in Cancer Therapeutics: Are We Making Headway?

Authors:  Yan Peng; Yuanyuan Wang; Cheng Zhou; Wuxuan Mei; Changchun Zeng
Journal:  Front Oncol       Date:  2022-03-24       Impact factor: 6.244

4.  Induced Cell Cycle Arrest in Triple-Negative Breast Cancer by Combined Treatment of Itraconazole and Rapamycin.

Authors:  Hua-Tao Wu; Chun-Lan Li; Ze-Xuan Fang; Wen-Jia Chen; Wen-Ting Lin; Jing Liu
Journal:  Front Pharmacol       Date:  2022-04-19       Impact factor: 5.988
  4 in total

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