Literature DB >> 25624498

BRAF inhibitor resistance mediated by the AKT pathway in an oncogenic BRAF mouse melanoma model.

Daniele Perna1, Florian A Karreth2, Alistair G Rust3, Pedro A Perez-Mancera2, Mamunur Rashid3, Francesco Iorio4, Constantine Alifrangis5, Mark J Arends6, Marcus W Bosenberg7, Gideon Bollag8, David A Tuveson9, David J Adams10.   

Abstract

BRAF (v-raf murine sarcoma viral oncogene homolog B) inhibitors elicit a transient anti-tumor response in ∼ 80% of BRAF(V600)-mutant melanoma patients that almost uniformly precedes the emergence of resistance. Here we used a mouse model of melanoma in which melanocyte-specific expression of Braf(V618E) (analogous to the human BRAF(V600E) mutation) led to the development of skin hyperpigmentation and nevi, as well as melanoma formation with incomplete penetrance. Sleeping Beauty insertional mutagenesis in this model led to accelerated and fully penetrant melanomagenesis and synchronous tumor formation. Treatment of Braf(V618E) transposon mice with the BRAF inhibitor PLX4720 resulted in tumor regression followed by relapse. Analysis of transposon insertions identified eight genes including Braf, Mitf, and ERas (ES-cell expressed Ras) as candidate resistance genes. Expression of ERAS in human melanoma cell lines conferred resistance to PLX4720 and induced hyperphosphorylation of AKT (v-akt murine thymoma viral oncogene homolog 1), a phenotype reverted by combinatorial treatment with PLX4720 and the AKT inhibitor MK2206. We show that ERAS expression elicits a prosurvival signal associated with phosphorylation/inactivation of BAD, and that the resistance of hepatocyte growth factor-treated human melanoma cells to PLX4720 can be reverted by treatment with the BAD-like BH3 mimetic ABT-737. Thus, we define a role for the AKT/BAD pathway in resistance to BRAF inhibition and illustrate an in vivo approach for finding drug resistance genes.

Entities:  

Keywords:  BRAF inhibitors; drug resistance; melanoma; mouse models

Mesh:

Substances:

Year:  2015        PMID: 25624498      PMCID: PMC4330752          DOI: 10.1073/pnas.1418163112

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  66 in total

1.  Regulation of BAD phosphorylation at serine 112 by the Ras-mitogen-activated protein kinase pathway.

Authors:  X Fang; S Yu; A Eder; M Mao; R C Bast; D Boyd; G B Mills
Journal:  Oncogene       Date:  1999-11-18       Impact factor: 9.867

2.  Cancer gene discovery in solid tumours using transposon-based somatic mutagenesis in the mouse.

Authors:  Lara S Collier; Corey M Carlson; Shruthi Ravimohan; Adam J Dupuy; David A Largaespada
Journal:  Nature       Date:  2005-07-14       Impact factor: 49.962

Review 3.  Genetics and epigenetics of cutaneous malignant melanoma: a concert out of tune.

Authors:  Karin van den Hurk; Hanneke E C Niessen; Jürgen Veeck; Joost J van den Oord; Maurice A M van Steensel; Axel Zur Hausen; Manon van Engeland; Véronique J L Winnepenninckx
Journal:  Biochim Biophys Acta       Date:  2012-03-31

4.  Characterization of melanocyte-specific inducible Cre recombinase transgenic mice.

Authors:  Marcus Bosenberg; Viswanathan Muthusamy; David P Curley; Zhenxiong Wang; Cara Hobbs; Betsy Nelson; Cristina Nogueira; James W Horner; Ronald Depinho; Lynda Chin
Journal:  Genesis       Date:  2006-05       Impact factor: 2.487

5.  The BAD protein integrates survival signaling by EGFR/MAPK and PI3K/Akt kinase pathways in PTEN-deficient tumor cells.

Authors:  Qing-Bai She; David B Solit; Qing Ye; Kathryn E O'Reilly; Jose Lobo; Neal Rosen
Journal:  Cancer Cell       Date:  2005-10       Impact factor: 31.743

6.  Survival in BRAF V600-mutant advanced melanoma treated with vemurafenib.

Authors:  Jeffrey A Sosman; Kevin B Kim; Lynn Schuchter; Rene Gonzalez; Anna C Pavlick; Jeffrey S Weber; Grant A McArthur; Thomas E Hutson; Stergios J Moschos; Keith T Flaherty; Peter Hersey; Richard Kefford; Donald Lawrence; Igor Puzanov; Karl D Lewis; Ravi K Amaravadi; Bartosz Chmielowski; H Jeffrey Lawrence; Yu Shyr; Fei Ye; Jiang Li; Keith B Nolop; Richard J Lee; Andrew K Joe; Antoni Ribas
Journal:  N Engl J Med       Date:  2012-02-23       Impact factor: 91.245

7.  Hepatocyte growth factor promotes renal epithelial cell survival by dual mechanisms.

Authors:  Y Liu
Journal:  Am J Physiol       Date:  1999-10

8.  Role of ERas in promoting tumour-like properties in mouse embryonic stem cells.

Authors:  Kazutoshi Takahashi; Kaoru Mitsui; Shinya Yamanaka
Journal:  Nature       Date:  2003-05-29       Impact factor: 49.962

9.  Insertional mutagenesis identifies multiple networks of cooperating genes driving intestinal tumorigenesis.

Authors:  H Nikki March; Alistair G Rust; Nicholas A Wright; Jelle ten Hoeve; Jeroen de Ridder; Matthew Eldridge; Louise van der Weyden; Anton Berns; Jules Gadiot; Anthony Uren; Richard Kemp; Mark J Arends; Lodewyk F A Wessels; Douglas J Winton; David J Adams
Journal:  Nat Genet       Date:  2011-11-06       Impact factor: 38.330

10.  The deubiquitinase USP9X suppresses pancreatic ductal adenocarcinoma.

Authors:  Pedro A Pérez-Mancera; Alistair G Rust; Louise van der Weyden; Glen Kristiansen; Allen Li; Aaron L Sarver; Kevin A T Silverstein; Robert Grützmann; Daniela Aust; Petra Rümmele; Thomas Knösel; Colin Herd; Derek L Stemple; Ross Kettleborough; Jacqueline A Brosnan; Ang Li; Richard Morgan; Spencer Knight; Jun Yu; Shane Stegeman; Lara S Collier; Jelle J ten Hoeve; Jeroen de Ridder; Alison P Klein; Michael Goggins; Ralph H Hruban; David K Chang; Andrew V Biankin; Sean M Grimmond; Lodewyk F A Wessels; Stephen A Wood; Christine A Iacobuzio-Donahue; Christian Pilarsky; David A Largaespada; David J Adams; David A Tuveson
Journal:  Nature       Date:  2012-04-29       Impact factor: 49.962
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  63 in total

1.  Lysyl Oxidase Is a Key Player in BRAF/MAPK Pathway-Driven Thyroid Cancer Aggressiveness.

Authors:  Myriem Boufraqech; Dhaval Patel; Naris Nilubol; Astin Powers; Timothy King; Jasmine Shell; Justin Lack; Lisa Zhang; Sudheer Kumar Gara; Viswanath Gunda; Joanna Klubo-Gwiezdzinska; Suresh Kumar; James Fagin; Jeffrey Knauf; Sareh Parangi; David Venzon; Martha Quezado; Electron Kebebew
Journal:  Thyroid       Date:  2018-12-28       Impact factor: 6.568

2.  Resistance mechanisms to TP53-MDM2 inhibition identified by in vivo piggyBac transposon mutagenesis screen in an Arf-/- mouse model.

Authors:  Emilie A Chapeau; Agnieszka Gembarska; Eric Y Durand; Emeline Mandon; Claire Estadieu; Vincent Romanet; Marion Wiesmann; Ralph Tiedt; Joseph Lehar; Antoine de Weck; Roland Rad; Louise Barys; Sebastien Jeay; Stephane Ferretti; Audrey Kauffmann; Esther Sutter; Armelle Grevot; Pierre Moulin; Masato Murakami; William R Sellers; Francesco Hofmann; Michael Rugaard Jensen
Journal:  Proc Natl Acad Sci U S A       Date:  2017-03-06       Impact factor: 11.205

3.  P21-activated kinase 1 regulates resistance to BRAF inhibition in human cancer cells.

Authors:  Mahamat Babagana; Sydney Johnson; Hannah Slabodkin; Wiam Bshara; Carl Morrison; Eugene S Kandel
Journal:  Mol Carcinog       Date:  2017-02-23       Impact factor: 4.784

Review 4.  In vivo functional screening for systems-level integrative cancer genomics.

Authors:  Julia Weber; Christian J Braun; Dieter Saur; Roland Rad
Journal:  Nat Rev Cancer       Date:  2020-07-07       Impact factor: 60.716

5.  Identification of NRAS isoform 2 overexpression as a mechanism facilitating BRAF inhibitor resistance in malignant melanoma.

Authors:  Megan C Duggan; Andrew R Stiff; Maryam Bainazar; Kelly Regan; Gonzalo N Olaverria Salavaggione; Sophia Maharry; James S Blachly; Madison Krischak; Christopher J Walker; Nicholas Latchana; Susheela Tridandapani; Albert de la Chapelle; Ann-Kathrin Eisfeld; William E Carson
Journal:  Proc Natl Acad Sci U S A       Date:  2017-08-21       Impact factor: 11.205

6.  Targeting Extracellular Matrix Remodeling Restores BRAF Inhibitor Sensitivity in BRAFi-resistant Melanoma.

Authors:  Charles Marusak; Varsha Thakur; Yuan Li; Juliano T Freitas; Patrick M Zmina; Vijay S Thakur; Mayland Chang; Ming Gao; Jiufeng Tan; Min Xiao; Yiling Lu; Gordon B Mills; Keith Flaherty; Dennie T Frederick; Benchun Miao; Ryan J Sullivan; Tabea Moll; Genevieve M Boland; Meenhard Herlyn; Gao Zhang; Barbara Bedogni
Journal:  Clin Cancer Res       Date:  2020-08-20       Impact factor: 12.531

7.  Identification of WEE1 as a target to make AKT inhibition more effective in melanoma.

Authors:  Omer F Kuzu; Raghavendra Gowda; Arati Sharma; Mohammad A Noory; Gregory Kardos; SubbaRao V Madhunapantula; Joseph J Drabick; Gavin P Robertson
Journal:  Cancer Biol Ther       Date:  2017-11-30       Impact factor: 4.742

8.  Autocrine IGF1 Signaling Mediates Pancreatic Tumor Cell Dormancy in the Absence of Oncogenic Drivers.

Authors:  Nirakar Rajbhandari; Wan-Chi Lin; Barbara L Wehde; Aleata A Triplett; Kay-Uwe Wagner
Journal:  Cell Rep       Date:  2017-02-28       Impact factor: 9.423

9.  The Dietary Supplement Chondroitin-4-Sulfate Exhibits Oncogene-Specific Pro-tumor Effects on BRAF V600E Melanoma Cells.

Authors:  Ruiting Lin; Siyuan Xia; Changliang Shan; Dong Chen; Yijie Liu; Xue Gao; Mei Wang; Hee-Bum Kang; Yaozhu Pan; Shuangping Liu; Young Rock Chung; Omar Abdel-Wahab; Taha Merghoub; Michael Rossi; Ragini R Kudchadkar; David H Lawson; Fadlo R Khuri; Sagar Lonial; Jing Chen
Journal:  Mol Cell       Date:  2018-03-15       Impact factor: 17.970

10.  The lncRNA RMEL3 protects immortalized cells from serum withdrawal-induced growth arrest and promotes melanoma cell proliferation and tumor growth.

Authors:  Cibele Cardoso; Rodolfo B Serafim; Akinori Kawakami; Cristiano Gonçalves Pereira; Jason Roszik; Valeria Valente; Vinicius L Vazquez; David E Fisher; Enilza M Espreafico
Journal:  Pigment Cell Melanoma Res       Date:  2018-12-16       Impact factor: 4.693
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