Mechanisms of acquired resistance to ERK1/2 pathway inhibitors

被引:90
作者
Little, A. S. [1 ]
Smith, P. D. [2 ]
Cook, S. J. [1 ]
机构
[1] Babraham Inst, Signalling Lab, Cambridge CB22 3AT, Cambs, England
[2] AstraZeneca, Oncol iMed, Macclesfield, Cheshire, England
来源
ONCOGENE | 2013年 / 32卷 / 10期
基金
英国生物技术与生命科学研究理事会;
关键词
acquired resistance; BRAF; ERK1/2; MEK1/2; RAS; TYROSINE KINASE INHIBITORS; SIGNAL-REGULATED KINASE; POTENTIAL MECHANISM; AZD6244; ARRY-142886; MEK1/2; INHIBITORS; TUMOR PROGRESSION; DOWN-REGULATION; BRAF GENE; RAF; MUTATIONS;
D O I
10.1038/onc.2012.160
中图分类号
Q5 [生物化学]; Q7 [分子生物学];
学科分类号
071010 ; 081704 ;
摘要
The ERK1/2 (extracellular signal-regulated kinase 1 and 2) pathway, comprising the protein kinases RAF (v-raf-1 murine leukemia viral oncogene homolog 1), MEK1/2 (mitogen-activated protein kinase or ERK kinase 1 and 2) and ERK1/2 is frequently de-regulated in human cancers, due to mutations in RAS or BRAF (v-raf-1 murine leukemia viral oncogene homolog B1). New, highly selective inhibitors of BRAF and MEK1/2 have shown promise in clinical trials, including in previously intractable diseases such as melanoma. However, drug-resistant tumour cells invariably emerge leading to disease progression. It is important to understand the mechanisms underlying such acquired resistance since this may lead to the development of rational strategies either to delay its onset or to overcome it once established. It also offers unique insights into the plasticity of signalling pathways, which may in turn inform our understanding of the basic biology of these pathways and lead to the validation of new drug targets. Several recent reports have identified diverse mechanisms of acquired resistance to MEK1/2 or BRAF inhibitors. In this article, we review these studies, discuss the different mechanisms, identify common themes and consider their therapeutic implications. Oncogene (2013) 32, 1207-1215; doi:10.1038/onc.2012.160; published online 7 May 2012
引用
收藏
页码:1207 / 1215
页数:9
相关论文
共 75 条
[1]   Tumour cell survival signalling by the ERK1/2 pathway [J].
Balmanno, K. ;
Cook, S. J. .
CELL DEATH AND DIFFERENTIATION, 2009, 16 (03) :368-377
[2]   Intrinsic resistance to the MEK1/2 inhibitor AZD6244 (ARRY-142886) is associated with weak ERKI/2 signalling and/or strong P13K signalling in colorectal cancer cell lines [J].
Balmanno, Kathryn ;
Chell, Simon D. ;
Gillings, Annette S. ;
Hayat, Shaista ;
Cook, Simon J. .
INTERNATIONAL JOURNAL OF CANCER, 2009, 125 (10) :2332-2341
[3]   Biology using engineering tools The negative feedback amplifier [J].
Birtwistle, Marc R. ;
Kolch, Walter .
CELL CYCLE, 2011, 10 (13) :2069-2076
[4]   Clinical efficacy of a RAF inhibitor needs broad target blockade in BRAF-mutant melanoma [J].
Bollag, Gideon ;
Hirth, Peter ;
Tsai, James ;
Zhang, Jiazhong ;
Ibrahim, Prabha N. ;
Cho, Hanna ;
Spevak, Wayne ;
Zhang, Chao ;
Zhang, Ying ;
Habets, Gaston ;
Burton, ElizabethA. ;
Wong, Bernice ;
Tsang, Garson ;
West, Brian L. ;
Powell, Ben ;
Shellooe, Rafe ;
Marimuthu, Adhirai ;
Nguyen, Hoa ;
Zhang, Kam Y. J. ;
Artis, Dean R. ;
Schlessinger, Joseph ;
Su, Fei ;
Higgins, Brian ;
Iyer, Raman ;
D'Andrea, Kurt ;
Koehler, Astrid ;
Stumm, Michael ;
Lin, Paul S. ;
Lee, Richard J. ;
Grippo, Joseph ;
Puzanov, Igor ;
Kim, Kevin B. ;
Ribas, Antoni ;
McArthur, Grant A. ;
Sosman, Jeffrey A. ;
Chapman, Paul B. ;
Flaherty, Keith T. ;
Xu, Xiaowei ;
Nathanson, Katherine L. ;
Nolop, Keith .
NATURE, 2010, 467 (7315) :596-599
[5]  
BUDAY L, 1995, ONCOGENE, V11, P1327
[6]   V600EBraf induces gastrointestinal crypt senescence and promotes tumour progression through enhanced CpG methylation of p16INK4a [J].
Carragher, Linda A. S. ;
Snell, Kimberley R. ;
Giblett, Susan M. ;
Aldridge, Victoria S. S. ;
Patel, Bipin ;
Cook, Simon J. ;
Winton, Doug J. ;
Marais, Richard ;
Pritchard, Catrin A. .
EMBO MOLECULAR MEDICINE, 2010, 2 (11) :458-471
[7]   Improved Survival with Vemurafenib in Melanoma with BRAF V600E Mutation [J].
Chapman, Paul B. ;
Hauschild, Axel ;
Robert, Caroline ;
Haanen, John B. ;
Ascierto, Paolo ;
Larkin, James ;
Dummer, Reinhard ;
Garbe, Claus ;
Testori, Alessandro ;
Maio, Michele ;
Hogg, David ;
Lorigan, Paul ;
Lebbe, Celeste ;
Jouary, Thomas ;
Schadendorf, Dirk ;
Ribas, Antoni ;
O'Day, Steven J. ;
Sosman, Jeffrey A. ;
Kirkwood, John M. ;
Eggermont, Alexander M. M. ;
Dreno, Brigitte ;
Nolop, Keith ;
Li, Jiang ;
Nelson, Betty ;
Hou, Jeannie ;
Lee, Richard J. ;
Flaherty, Keith T. ;
McArthur, Grant A. .
NEW ENGLAND JOURNAL OF MEDICINE, 2011, 364 (26) :2507-2516
[8]   BRAF Gene Amplification Can Promote Acquired Resistance to MEK Inhibitors in Cancer Cells Harboring the BRAF V600E Mutation [J].
Corcoran, Ryan B. ;
Dias-Santagata, Dora ;
Bergethon, Kristin ;
Iafrate, A. John ;
Settleman, Jeffrey ;
Engelman, Jeffrey A. .
SCIENCE SIGNALING, 2010, 3 (149)
[9]   AZD6244 (ARRY-142886), a potent inhibitor of mitogen-activated protein kinase/extracellular signal-regulated kinase kinase 1/2 kinases:: mechanism of action in vivo, pharmacokinetic/pharmacodynamic relationship, and potential for combination in preclinical models [J].
Davies, Barry R. ;
Logie, Armelle ;
McKay, Jennifer S. ;
Martin, Paul ;
Steele, Samantha ;
Jenkins, Richard ;
Cockerill, Mark ;
Cartlidge, Sue ;
Smith, Paul D. .
MOLECULAR CANCER THERAPEUTICS, 2007, 6 (08) :2209-2219
[10]   Mutations of the BRAF gene in human cancer [J].
Davies, H ;
Bignell, GR ;
Cox, C ;
Stephens, P ;
Edkins, S ;
Clegg, S ;
Teague, J ;
Woffendin, H ;
Garnett, MJ ;
Bottomley, W ;
Davis, N ;
Dicks, N ;
Ewing, R ;
Floyd, Y ;
Gray, K ;
Hall, S ;
Hawes, R ;
Hughes, J ;
Kosmidou, V ;
Menzies, A ;
Mould, C ;
Parker, A ;
Stevens, C ;
Watt, S ;
Hooper, S ;
Wilson, R ;
Jayatilake, H ;
Gusterson, BA ;
Cooper, C ;
Shipley, J ;
Hargrave, D ;
Pritchard-Jones, K ;
Maitland, N ;
Chenevix-Trench, G ;
Riggins, GJ ;
Bigner, DD ;
Palmieri, G ;
Cossu, A ;
Flanagan, A ;
Nicholson, A ;
Ho, JWC ;
Leung, SY ;
Yuen, ST ;
Weber, BL ;
Siegler, HF ;
Darrow, TL ;
Paterson, H ;
Marais, R ;
Marshall, CJ ;
Wooster, R .
NATURE, 2002, 417 (6892) :949-954
12345678