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Series GSE50550 Query DataSets for GSE50550
Status Public on Mar 31, 2017
Title Enhancer Remodeling during Adaptive Bypass to MEK Inhibition Is Attenuated by Pharmacologic Targeting of the P-TEFb Complex
Organism Homo sapiens
Experiment type Expression profiling by array
Summary Triple negative breast cancer (TNBC) is heterogeneous with patients exhibiting at least two molecular subtypes, basal-like (BL) and claudin-low (CL). MEK inhibitor (MEKi) treatment of BL and CL cell lines and mouse model tumors induced subtype-specific alterations in overall kinome activity referred to as protein kinase reprogramming. BL- and CL-specific reprogramming involving increases in receptor tyrosine kinases was also seen in TNBC patients comparing tumor samples before and after a one week treatment with the MEKi, trametinib. Combination of kinase inhibitors targeted to the BL and CL reprogrammed signatures would need to be individually selected due to the heterogeneous resiliency of BL and CL kinomes. To overcome this “reprogramming dilemma” we targeted the transcriptional co-activator BRD4 with BET bromodomain inhibitors, JQI and IBET151; both strongly inhibited kinome reprogramming and onset of MEKi resistance in BL and CL cells. Targeting chromatin modifiers may therapeutically block resistance due to kinome reprogramming.BL and CL TNBC are commonly treated as a single disease despite genomic studies showing they represent distinct molecular subtypes1. Recent Cancer Genome Atlas data demonstrated that the 518 protein kinases in the human genome (the kinome) were infrequently mutated in BL breast cancer; however, EGFR, KRAS and BRAF were amplified in 22, 32 and 31% of BL tumors, respectively. These findings are consistent with frequent activation of the BRAF-MEK-ERK pathway in TNBC2,3 and inhibitors targeting kinases in this pathway are currently in clinical trials for TNBC. As single agents, targeted kinase inhibitors generally fail to sustain durable responses when used to treat a range of human cancers including TNBC4-6. Onset of kinase inhibitor resistance can be due to selection of mutations in the targeted kinase7,8, activating mutations or amplification of RAS or downstream kinases9,10 or kinome reprogramming, a process in which there are system-wide changes in kinase networks11-13. Each of these resistance mechanisms allows the cancer cell to circumvent the targeted inhibition of specific kinases14. We previously developed chemical, proteomic methods that assay the activation state of protein kinases en masse15,16. Our methods utilize ¬Multiplexed Inhibitor Beads (MIBs), mixtures of covalently immobilized, linker adapted, kinase inhibitors. The immobilized inhibitors are primarily type I kinase inhibitors that preferentially bind activated (versus inactive) kinase17. Kinase capture is highly reproducible and is a function of kinase affinity for different immobilized inhibitors as well as the kinase activation state. Activated kinases preferentially bind, inactive kinases do not. By coupling MIB capture with mass spectrometry (MIB/MS), the technique allows quantitative interrogation of hundreds of kinases in a single mass spectrometry run. This also interrogates kinases known by sequence but which have been understudied due to lack of reagents such as specific phospho-antibodies. We report here both in preclinical models and patients that BL and CL TNBC have different baseline kinome activation states and both respond differently to MEKi with subtype-specific tyrosine kinase reprogramming. To avoid treatment strategy that uses multiple kinase inhibitors in individual patients, we discovered a novel pharmacologic strategy to block the initial reprogramming response to MEKi involving inhibition of epigenetic processes.
 
Overall design reference x sample
 
Contributor(s) Duncan JS, Perou CM, Johnson GL
Citation(s) 28108460
Submission date Sep 03, 2013
Last update date Jun 30, 2017
Contact name Charles M. Perou
E-mail(s) cperou@med.unc.edu
Organization name University of North Carolina at Chapel Hill
Department Professor of Genetics, and Pathology & Laboratory Medicine; Lineberger Comprehensive Cancer Center
Street address 12-044 Lineberger Comprehensive Cancer Center CB# 7295
City Chapel Hill
State/province NC
ZIP/Postal code 27599-7264
Country USA
 
Platforms (1)
GPL10481 Agilent-scanner-UNC-custom-4X44K-without-Virus
Samples (10)
GSM1221000 MEKi-120161-pretx
GSM1221001 MEKi-120202-posttx
GSM1221002 MEKi-120468-pretx
Relations
BioProject PRJNA218091

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