COP1/DET1/ETS axis regulates ERK transcriptome and sensitivity to MAPK inhibitors
Yuanyuan Xie, … , Ping Chi, Yu Chen
Yuanyuan Xie, … , Ping Chi, Yu Chen
Published January 23, 2018
Citation Information: J Clin Invest. 2018;128(4):1442-1457. https://doi.org/10.1172/JCI94840.
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Research Article Oncology

COP1/DET1/ETS axis regulates ERK transcriptome and sensitivity to MAPK inhibitors

Abstract

Aberrant activation of MAPK signaling leads to the activation of oncogenic transcriptomes. How MAPK signaling is coupled with the transcriptional response in cancer is not fully understood. In 2 MAPK-activated tumor types, gastrointestinal stromal tumor and melanoma, we found that ETV1 and other Pea3-ETS transcription factors are critical nuclear effectors of MAPK signaling that are regulated through protein stability. Expression of stabilized Pea3-ETS factors can partially rescue the MAPK transcriptome and cell viability after MAPK inhibition. To identify the players involved in this process, we performed a pooled genome-wide RNAi screen using a fluorescence-based ETV1 protein stability sensor and identified COP1, DET1, DDB1, UBE3C, PSMD4, and COP9 signalosome members. COP1 or DET1 loss led to decoupling between MAPK signaling and the downstream transcriptional response, where MAPK inhibition failed to destabilize Pea3 factors and fully inhibit the MAPK transcriptome, thus resulting in decreased sensitivity to MAPK pathway inhibitors. We identified multiple COP1 and DET1 mutations in human tumors that were defective in the degradation of Pea3-ETS factors. Two melanoma patients had de novo DET1 mutations arising after vemurafenib treatment. These observations indicate that MAPK signaling–dependent regulation of Pea3-ETS protein stability is a key signaling node in oncogenesis and therapeutic resistance to MAPK pathway inhibition.

Authors

Yuanyuan Xie, Zhen Cao, Elissa W.P. Wong, Youxin Guan, Wenfu Ma, Jenny Q. Zhang, Edward G. Walczak, Devan Murphy, Leili Ran, Inna Sirota, Shangqian Wang, Shipra Shukla, Dong Gao, Simon R.V. Knott, Kenneth Chang, Justin Leu, John Wongvipat, Cristina R. Antonescu, Gregory Hannon, Ping Chi, Yu Chen

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Figure 5

COP1 couples MAPK downstream transcriptional output through MAPK-dependent regulation of ETV1 protein stability.

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COP1 couples MAPK downstream transcriptional output through MAPK-depende...
(A) GIST882 MAPK median Z score (defined as the normalized median of genes downregulated by more than 2-fold, 8 hours after PD325901 [PD901] treatment in GIST882 cells) in GIST882 cells transfected with siSCR or 2 siRNAs against COP1 and then treated with vehicle or PD901 (100 nM) for 8 hours. n = 2. Error bars indicate the mean ± SD. (B) Heatmap of GIST882 MAPK gene(change >2-fold, P < 0.05 by PD901) expression changes in GIST882 cells under the indicated conditions (from left to right): PD325901 versus vehicle treatment (PD901Δ); ETV1sh2 versus shSCR (shETV1Δ); COP1si1 versus siSCR and with PD325901 treatment (COP1si1Δ in PD901); and COP1si2 versus siSCR and with PD325901 treatment (COP1si2Δ in PD901). (C) GSEA enrichment plot of a gene set defined by genes upregulated by COP1 knockdown in PD325901-treated GIST882 cells (G882_siCOP1_UP_in_PD901), demonstrating that this gene set was highly negatively enriched among genes downregulated by PD901 compared with vehicle. (D) A375 MAPK median Z score in siSCR- and siCOP1-transfected A375 cells after treatment with vehicle, vemurafenib (1 μM), or trametinib (100 nM) for 8 hours. (E) Heatmap of gene expression changes in A375 cells (from left to right): vemurafenib versus vehicle treatment in siSCR-transfected cells (VemuΔ); shETV1 versus shSCR (shETV1Δ); vemurafenib-treated siCOP1 versus siSCR-transfected cells (siCOP1Δ in Vemu); and trametinib-treated siCOP1 versus siSCR-transfected cells (siCOP1Δ in Tram). (F) GSEA showing that a gene set defined by genes upregulated by siCOP1 in vemurafenib-treated A375 cells was highly negatively enriched among genes downregulated by vemurafenib in A375 cells. UP, upregulated.