Literature DB >> 19351816

Oncogenic Kras requires simultaneous PI3K signaling to induce ERK activation and transform thyroid epithelial cells in vivo.

Kelly A Miller1, Nicole Yeager, Kristen Baker, Xiao-Hui Liao, Samuel Refetoff, Antonio Di Cristofano.   

Abstract

Thyroid tumors arising from the follicular cells often harbor mutations leading to the constitutive activation of the PI3K and Ras signaling cascades. However, it is still unclear what their respective contribution to the neoplastic process is, as well as to what extent they interact. We have used mice harboring a Kras oncogenic mutation and a Pten deletion targeted to the thyroid epithelium to address in vivo these questions. Here, we show that although each of these two pathways, alone, is unable to transform thyroid follicular cells, their simultaneous activation is highly oncogenic, leading to invasive and metastatic follicular carcinomas. In particular, phosphatidylinositol-3-kinase (PI3K) activation suppressed Kras-initiated feedback signals that uncouple mitogen-activated protein kinase (MAPK)/extracellular signal-regulated kinase (ERK) kinase (MEK) and ERK activation, thus stunting MAPK activity; in addition, PI3K and Kras cooperated to drastically up-regulate cyclin D1 mRNA levels. Finally, combined pharmacologic inhibition of PI3K and MAPK completely inhibited the growth of double-mutant cancer cell lines, providing a compelling rationale for the dual targeting of these pathways in thyroid cancer.

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Year:  2009        PMID: 19351816      PMCID: PMC2669852          DOI: 10.1158/0008-5472.CAN-09-0024

Source DB:  PubMed          Journal:  Cancer Res        ISSN: 0008-5472            Impact factor:   12.701


  28 in total

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Authors:  David A Tuveson; Alice T Shaw; Nicholas A Willis; Daniel P Silver; Erica L Jackson; Sandy Chang; Kim L Mercer; Rebecca Grochow; Hanno Hock; Denise Crowley; Sunil R Hingorani; Tal Zaks; Catrina King; Michael A Jacobetz; Lifu Wang; Roderick T Bronson; Stuart H Orkin; Ronald A DePinho; Tyler Jacks
Journal:  Cancer Cell       Date:  2004-04       Impact factor: 31.743

2.  Inhibition of the phosphatidylinositol 3'-kinase-AKT pathway induces apoptosis in pancreatic carcinoma cells in vitro and in vivo.

Authors:  Victor M Bondar; Bridget Sweeney-Gotsch; Michael Andreeff; Gordon B Mills; David J McConkey
Journal:  Mol Cancer Ther       Date:  2002-10       Impact factor: 6.261

3.  Improved radioimmunoassay for measurement of mouse thyrotropin in serum: strain differences in thyrotropin concentration and thyrotroph sensitivity to thyroid hormone.

Authors:  J Pohlenz; A Maqueem; K Cua; R E Weiss; J Van Sande; S Refetoff
Journal:  Thyroid       Date:  1999-12       Impact factor: 6.568

4.  An immunohistochemical study of p16(INK4a) expression in multistep thyroid tumourigenesis.

Authors:  Elizabeth Ball; Jane Bond; Brigitte Franc; Catherine Demicco; David Wynford-Thomas
Journal:  Eur J Cancer       Date:  2006-10-13       Impact factor: 9.162

5.  Thyroid targeting of the N-ras(Gln61Lys) oncogene in transgenic mice results in follicular tumors that progress to poorly differentiated carcinomas.

Authors:  D Vitagliano; G Portella; G Troncone; A Francione; C Rossi; A Bruno; A Giorgini; S Coluzzi; T C Nappi; J L Rothstein; R Pasquinelli; G Chiappetta; D Terracciano; V Macchia; R M Melillo; A Fusco; M Santoro
Journal:  Oncogene       Date:  2006-06-19       Impact factor: 9.867

6.  A negative feedback signaling network underlies oncogene-induced senescence.

Authors:  Stéphanie Courtois-Cox; Sybil M Genther Williams; Elizabeth E Reczek; Bryan W Johnson; Lauren T McGillicuddy; Cory M Johannessen; Pablo E Hollstein; Mia MacCollin; Karen Cichowski
Journal:  Cancer Cell       Date:  2006-12       Impact factor: 31.743

7.  Thyrocyte-specific expression of Cre recombinase in transgenic mice.

Authors:  Takashi Kusakabe; Akio Kawaguchi; Rumi Kawaguchi; Lionel Feigenbaum; Shioko Kimura
Journal:  Genesis       Date:  2004-07       Impact factor: 2.487

8.  Preinvasive and invasive ductal pancreatic cancer and its early detection in the mouse.

Authors:  Sunil R Hingorani; Emanuel F Petricoin; Anirban Maitra; Vinodh Rajapakse; Catrina King; Michael A Jacobetz; Sally Ross; Thomas P Conrads; Timothy D Veenstra; Ben A Hitt; Yoshiya Kawaguchi; Don Johann; Lance A Liotta; Howard C Crawford; Mary E Putt; Tyler Jacks; Christopher V E Wright; Ralph H Hruban; Andrew M Lowy; David A Tuveson
Journal:  Cancer Cell       Date:  2003-12       Impact factor: 31.743

9.  The status of CDKN2A alpha (p16INK4A) and beta (p14ARF) transcripts in thyroid tumour progression.

Authors:  A Ferru; G Fromont; H Gibelin; J Guilhot; F Savagner; J M Tourani; J L Kraimps; C J Larsen; L Karayan-Tapon
Journal:  Br J Cancer       Date:  2006-11-21       Impact factor: 7.640

10.  Pten dose dictates cancer progression in the prostate.

Authors:  Lloyd C Trotman; Masaru Niki; Zohar A Dotan; Jason A Koutcher; Antonio Di Cristofano; Andrew Xiao; Alan S Khoo; Pradip Roy-Burman; Norman M Greenberg; Terry Van Dyke; Carlos Cordon-Cardo; Pier Paolo Pandolfi
Journal:  PLoS Biol       Date:  2003-10-27       Impact factor: 8.029
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  67 in total

1.  Mutationally activated BRAF(V600E) elicits papillary thyroid cancer in the adult mouse.

Authors:  Roch-Philippe Charles; Gioia Iezza; Elena Amendola; David Dankort; Martin McMahon
Journal:  Cancer Res       Date:  2011-04-21       Impact factor: 12.701

Review 2.  Thyroid cancer in 2010: a roadmap for targeted therapies.

Authors:  Francesca Carlomagno; Massimo Santoro
Journal:  Nat Rev Endocrinol       Date:  2011-02       Impact factor: 43.330

Review 3.  Coding Molecular Determinants of Thyroid Cancer Development and Progression.

Authors:  Veronica Valvo; Carmelo Nucera
Journal:  Endocrinol Metab Clin North Am       Date:  2018-12-23       Impact factor: 4.741

4.  PTEN inhibits proliferation and functions of hypertrophic scar fibroblasts.

Authors:  Liang Guo; Liang Chen; Sheng Bi; Linlin Chai; Zengxiang Wang; Chuan Cao; Ling Tao; Shirong Li
Journal:  Mol Cell Biochem       Date:  2011-10-12       Impact factor: 3.396

5.  cAMP-dependent activation of mammalian target of rapamycin (mTOR) in thyroid cells. Implication in mitogenesis and activation of CDK4.

Authors:  Sara Blancquaert; Lifu Wang; Sabine Paternot; Katia Coulonval; Jacques E Dumont; Thurl E Harris; Pierre P Roger
Journal:  Mol Endocrinol       Date:  2010-05-19

Review 6.  Lessons from mouse models of thyroid cancer.

Authors:  Caroline S Kim; Xuguang Zhu
Journal:  Thyroid       Date:  2009-12       Impact factor: 6.568

Review 7.  Molecular pathogenesis and mechanisms of thyroid cancer.

Authors:  Mingzhao Xing
Journal:  Nat Rev Cancer       Date:  2013-03       Impact factor: 60.716

8.  Immune Suppression Mediated by Myeloid and Lymphoid Derived Immune Cells in the Tumor Microenvironment Facilitates Progression of Thyroid Cancers Driven by HrasG12V and Pten Loss.

Authors:  Lee Ann Jolly; Nicole Massoll; Aime T Franco
Journal:  J Clin Cell Immunol       Date:  2016-09-16

9.  Cross-talk between PI3K and estrogen in the mouse thyroid predisposes to the development of follicular carcinomas with a higher incidence in females.

Authors:  V G Antico-Arciuch; M Dima; X-H Liao; S Refetoff; A Di Cristofano
Journal:  Oncogene       Date:  2010-08-02       Impact factor: 9.867

Review 10.  Orthotopic mouse models for the preclinical and translational study of targeted therapies against metastatic human thyroid carcinoma with BRAF(V600E) or wild-type BRAF.

Authors:  Z A Antonello; C Nucera
Journal:  Oncogene       Date:  2013-12-23       Impact factor: 9.867
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