Literature DB >> 34464356

Targeting enhancer reprogramming to mitigate MEK inhibitor resistance in preclinical models of advanced ovarian cancer.

Shini Liu1, Qiong Zou1, Jie-Ping Chen1, Xiaosai Yao2, Peiyong Guan3, Weiting Liang1, Peng Deng1, Xiaowei Lai1, Jiaxin Yin1, Jinghong Chen1, Rui Chen1, Zhaoliang Yu4, Rong Xiao1, Yichen Sun1, Jing Han Hong3, Hui Liu1, Huaiwu Lu5, Jianfeng Chen1, Jin-Xin Bei1, Joanna Koh6, Jason Yongsheng Chan6, Baohua Wang7, Tiebang Kang1, Qiang Yu3,8, Bin-Tean Teh2,3,6,9,10, Jihong Liu1, Ying Xiong1, Jing Tan1,6,11.   

Abstract

Ovarian cancer is characterized by aberrant activation of the mitogen-activated protein kinase (MAPK), highlighting the importance of targeting the MAPK pathway as an attractive therapeutic strategy. However, the clinical efficacy of MEK inhibitors is limited by intrinsic or acquired drug resistance. Here, we established patient-derived ovarian cancer models resistant to MEK inhibitors and demonstrated that resistance to the clinically approved MEK inhibitor trametinib was associated with enhancer reprogramming. We also showed that enhancer decommissioning induced the downregulation of negative regulators of the MAPK pathway, leading to constitutive ERK activation and acquired resistance to trametinib. Epigenetic compound screening uncovered that HDAC inhibitors could alter the enhancer reprogramming and upregulate the expression of MAPK negative regulators, resulting in sustained MAPK inhibition and reversal of trametinib resistance. Consequently, a combination of HDAC inhibitor and trametinib demonstrated a synergistic antitumor effect in vitro and in vivo, including patient-derived xenograft mouse models. These findings demonstrated that enhancer reprogramming of the MAPK regulatory pathway might serve as a potential mechanism underlying MAPK inhibitor resistance and concurrent targeting of epigenetic pathways and MAPK signaling might provide an effective treatment strategy for advanced ovarian cancer.

Entities:  

Keywords:  Cancer; Drug screens; Molecular biology; Oncology

Mesh:

Substances:

Year:  2021        PMID: 34464356      PMCID: PMC8516457          DOI: 10.1172/JCI145035

Source DB:  PubMed          Journal:  J Clin Invest        ISSN: 0021-9738            Impact factor:   14.808


  78 in total

1.  Comprehensive predictive biomarker analysis for MEK inhibitor GSK1120212.

Authors:  Junping Jing; Joel Greshock; Joanna Dawn Holbrook; Aidan Gilmartin; Xiping Zhang; Elizabeth McNeil; Theresa Conway; Christopher Moy; Sylvie Laquerre; Kurt Bachman; Richard Wooster; Yan Degenhardt
Journal:  Mol Cancer Ther       Date:  2011-12-14       Impact factor: 6.261

2.  HDAC Inhibition Enhances the In Vivo Efficacy of MEK Inhibitor Therapy in Uveal Melanoma.

Authors:  Fernanda Faião-Flores; Michael F Emmons; Michael A Durante; Fumi Kinose; Biswarup Saha; Bin Fang; John M Koomen; Srikumar P Chellappan; Silvya Stuchi Maria-Engler; Uwe Rix; Jonathan D Licht; J William Harbour; Keiran S M Smalley
Journal:  Clin Cancer Res       Date:  2019-06-21       Impact factor: 12.531

3.  V211D Mutation in MEK1 Causes Resistance to MEK Inhibitors in Colon Cancer.

Authors:  Yijun Gao; Ann Maria; Na Na; Arnaud da Cruz Paula; Alexander N Gorelick; Jaclyn F Hechtman; Julianne Carson; Robert A Lefkowitz; Britta Weigelt; Barry S Taylor; HuiYong Zhao; Jorge S Reis-Filho; Elisa de Stanchina; Neal Rosen; Zhan Yao; Rona Yaeger
Journal:  Cancer Discov       Date:  2019-06-21       Impact factor: 39.397

4.  Synergistic effect of MEK inhibitor and metformin combination in low grade serous ovarian cancer.

Authors:  Ismail Mert; Jasdeep Chhina; Ghassan Allo; Jing Dai; Shelly Seward; Mark S Carey; Marta Llaurado; Shailendra Giri; Ramandeep Rattan; Adnan R Munkarah
Journal:  Gynecol Oncol       Date:  2017-05-22       Impact factor: 5.482

5.  BRAF V600E disrupts AZD6244-induced abrogation of negative feedback pathways between extracellular signal-regulated kinase and Raf proteins.

Authors:  Bret B Friday; Chunrong Yu; Grace K Dy; Paul D Smith; Liang Wang; Stephen N Thibodeau; Alex A Adjei
Journal:  Cancer Res       Date:  2008-08-01       Impact factor: 12.701

6.  Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2.

Authors:  Michael I Love; Wolfgang Huber; Simon Anders
Journal:  Genome Biol       Date:  2014       Impact factor: 13.583

7.  HTSeq--a Python framework to work with high-throughput sequencing data.

Authors:  Simon Anders; Paul Theodor Pyl; Wolfgang Huber
Journal:  Bioinformatics       Date:  2014-09-25       Impact factor: 6.937

Review 8.  Targeted therapy of ovarian cancer including immune check point inhibitor.

Authors:  Jin Young Kim; Chi Heum Cho; Hong Suk Song
Journal:  Korean J Intern Med       Date:  2017-08-22       Impact factor: 2.884

9.  Trametinib response in heavily pretreated high-grade ovarian cancer: One step towards precision medicine.

Authors:  Serena Cappuccio; Maria Grazia Distefano; Viola Ghizzoni; Anna Fagotti; Giovanni Scambia
Journal:  Gynecol Oncol Rep       Date:  2020-02-13

10.  Fast and accurate short read alignment with Burrows-Wheeler transform.

Authors:  Heng Li; Richard Durbin
Journal:  Bioinformatics       Date:  2009-05-18       Impact factor: 6.937
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  2 in total

1.  Preclinical Assessment of MEK Inhibitors for Malignant Peripheral Nerve Sheath Tumors Reveals Differences in Efficacy and Adaptive Response.

Authors:  Yihui Gu; Wei Wang; Yuehua Li; Haibo Li; Zizhen Guo; Chengjiang Wei; Manmei Long; Manhon Chung; Rehanguli Aimaier; Qingfeng Li; Zhichao Wang
Journal:  Front Oncol       Date:  2022-07-07       Impact factor: 5.738

2.  Concurrent inhibition of FAK/SRC and MEK overcomes MEK inhibitor resistance in Neurofibromatosis Type I related malignant peripheral nerve sheath tumors.

Authors:  Yihui Gu; Chengjiang Wei; Manhon Chung; Haibo Li; Zizhen Guo; Manmei Long; Yuehua Li; Wei Wang; Rehanguli Aimaier; Qingfeng Li; Zhichao Wang
Journal:  Front Oncol       Date:  2022-07-29       Impact factor: 5.738
  2 in total

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