Literature DB >> 27655129

MEK and TAK1 Regulate Apoptosis in Colon Cancer Cells with KRAS-Dependent Activation of Proinflammatory Signaling.

Kelsey L McNew1, William J Whipple1, Anita K Mehta1, Trevor J Grant1, Leah Ray1, Connor Kenny1, Anurag Singh2,3.   

Abstract

MEK inhibitors have limited efficacy in treating RAS-RAF-MEK pathway-dependent cancers due to feedback pathway compensation and dose-limiting toxicities. Combining MEK inhibitors with other targeted agents may enhance efficacy. Here, codependencies of MEK, TAK1, and KRAS in colon cancer were investigated. Combined inhibition of MEK and TAK1 potentiates apoptosis in KRAS-dependent cells. Pharmacologic studies and cell-cycle analyses on a large panel of colon cancer cell lines demonstrate that MEK/TAK1 inhibition induces cell death, as assessed by sub-G1 accumulation, in a distinct subset of cell lines. Furthermore, TAK1 inhibition causes G2-M cell-cycle blockade and polyploidy in many of the cell lines. MEK plus TAK1 inhibition causes reduced G2-M/polyploid cell numbers and additive cytotoxic effects in KRAS/TAK1-dependent cell lines as well as a subset of BRAF-mutant cells. Mechanistically, sensitivity to MEK/TAK1 inhibition can be conferred by KRAS and BMP receptor activation, which promote expression of NF-κB-dependent proinflammatory cytokines, driving tumor cell survival and proliferation. MEK/TAK1 inhibition causes reduced mTOR, Wnt, and NF-κB signaling in TAK1/MEK-dependent cell lines concomitant with apoptosis. A Wnt/NF-κB transcriptional signature was derived that stratifies primary tumors into three major subtypes: Wnt-high/NF-κB-low, Wnt-low/NF-κB-high and Wnt-high/NF-κB-high, designated W, N, and WN, respectively. These subtypes have distinct characteristics, including enrichment for BRAF mutations with serrated carcinoma histology in the N subtype. Both N and WN subtypes bear molecular hallmarks of MEK and TAK1 dependency seen in cell lines. Therefore, N and WN subtype signatures could be utilized to identify tumors that are most sensitive to anti-MEK/TAK1 therapeutics. IMPLICATIONS: This study describes a potential therapeutic strategy for a subset of colon cancers that are dependent on oncogenic KRAS signaling pathways, which are currently difficult to block with selective agents. Mol Cancer Res; 14(12); 1204-16. ©2016 AACR. ©2016 American Association for Cancer Research.

Entities:  

Mesh:

Substances:

Year:  2016        PMID: 27655129      PMCID: PMC5136310          DOI: 10.1158/1541-7786.MCR-16-0173

Source DB:  PubMed          Journal:  Mol Cancer Res        ISSN: 1541-7786            Impact factor:   5.852


  43 in total

1.  Identification of predictive markers of response to the MEK1/2 inhibitor selumetinib (AZD6244) in K-ras-mutated colorectal cancer.

Authors:  John J Tentler; Sujatha Nallapareddy; Aik Choon Tan; Anna Spreafico; Todd M Pitts; M Pia Morelli; Heather M Selby; Maria I Kachaeva; Sara A Flanigan; Gillian N Kulikowski; Stephen Leong; John J Arcaroli; Wells A Messersmith; S Gail Eckhardt
Journal:  Mol Cancer Ther       Date:  2010-10-05       Impact factor: 6.261

2.  KrasG12D-induced IKK2/β/NF-κB activation by IL-1α and p62 feedforward loops is required for development of pancreatic ductal adenocarcinoma.

Authors:  Jianhua Ling; Ya'an Kang; Ruiying Zhao; Qianghua Xia; Dung-Fang Lee; Zhe Chang; Jin Li; Bailu Peng; Jason B Fleming; Huamin Wang; Jinsong Liu; Ihor R Lemischka; Mien-Chie Hung; Paul J Chiao
Journal:  Cancer Cell       Date:  2012-01-17       Impact factor: 31.743

3.  EGFR-mediated re-activation of MAPK signaling contributes to insensitivity of BRAF mutant colorectal cancers to RAF inhibition with vemurafenib.

Authors:  Ryan B Corcoran; Hiromichi Ebi; Alexa B Turke; Erin M Coffee; Michiya Nishino; Alexandria P Cogdill; Ronald D Brown; Patricia Della Pelle; Dora Dias-Santagata; Kenneth E Hung; Keith T Flaherty; Adriano Piris; Jennifer A Wargo; Jeffrey Settleman; Mari Mino-Kenudson; Jeffrey A Engelman
Journal:  Cancer Discov       Date:  2012-01-16       Impact factor: 39.397

4.  RNF43 is frequently mutated in colorectal and endometrial cancers.

Authors:  Marios Giannakis; Eran Hodis; Xinmeng Jasmine Mu; Mai Yamauchi; Joseph Rosenbluh; Kristian Cibulskis; Gordon Saksena; Michael S Lawrence; Zhi Rong Qian; Reiko Nishihara; Eliezer M Van Allen; William C Hahn; Stacey B Gabriel; Eric S Lander; Gad Getz; Shuji Ogino; Charles S Fuchs; Levi A Garraway
Journal:  Nat Genet       Date:  2014-10-26       Impact factor: 38.330

5.  The GATA2 transcriptional network is requisite for RAS oncogene-driven non-small cell lung cancer.

Authors:  Madhu S Kumar; David C Hancock; Miriam Molina-Arcas; Michael Steckel; Phillip East; Markus Diefenbacher; Elena Armenteros-Monterroso; François Lassailly; Nik Matthews; Emma Nye; Gordon Stamp; Axel Behrens; Julian Downward
Journal:  Cell       Date:  2012-04-27       Impact factor: 41.582

6.  A colorectal cancer classification system that associates cellular phenotype and responses to therapy.

Authors:  Anguraj Sadanandam; Costas A Lyssiotis; Krisztian Homicsko; Eric A Collisson; William J Gibb; Stephan Wullschleger; Liliane C Gonzalez Ostos; William A Lannon; Carsten Grotzinger; Maguy Del Rio; Benoit Lhermitte; Adam B Olshen; Bertram Wiedenmann; Lewis C Cantley; Joe W Gray; Douglas Hanahan
Journal:  Nat Med       Date:  2013-04-14       Impact factor: 53.440

7.  Combination PI3K/MEK inhibition promotes tumor apoptosis and regression in PIK3CA wild-type, KRAS mutant colorectal cancer.

Authors:  Jatin Roper; Mark J Sinnamon; Erin M Coffee; Peter Belmont; Lily Keung; Larissa Georgeon-Richard; Wei Vivian Wang; Anthony C Faber; Jihye Yun; Ömer H Yilmaz; Roderick T Bronson; Eric S Martin; Philip N Tsichlis; Kenneth E Hung
Journal:  Cancer Lett       Date:  2014-02-24       Impact factor: 8.679

8.  Systematic identification of molecular subtype-selective vulnerabilities in non-small-cell lung cancer.

Authors:  Hyun Seok Kim; Saurabh Mendiratta; Jiyeon Kim; Chad Victor Pecot; Jill E Larsen; Iryna Zubovych; Bo Yeun Seo; Jimi Kim; Banu Eskiocak; Hannah Chung; Elizabeth McMillan; Sherry Wu; Jef De Brabander; Kakajan Komurov; Jason E Toombs; Shuguang Wei; Michael Peyton; Noelle Williams; Adi F Gazdar; Bruce A Posner; Rolf A Brekken; Anil K Sood; Ralph J Deberardinis; Michael G Roth; John D Minna; Michael A White
Journal:  Cell       Date:  2013-10-24       Impact factor: 41.582

9.  TAK1 inhibition promotes apoptosis in KRAS-dependent colon cancers.

Authors:  Anurag Singh; Michael F Sweeney; Min Yu; Alexa Burger; Patricia Greninger; Cyril Benes; Daniel A Haber; Jeff Settleman
Journal:  Cell       Date:  2012-02-17       Impact factor: 41.582

Review 10.  Targeting the cancer kinome through polypharmacology.

Authors:  Zachary A Knight; Henry Lin; Kevan M Shokat
Journal:  Nat Rev Cancer       Date:  2010-02       Impact factor: 60.716
View more
  4 in total

1.  The relationship between members of the canonical NF-kB pathway, tumour microenvironment and cancer specific survival in colorectal cancer patients.

Authors:  Jean A Quinn; Lindsay Bennett; Meera Patel; Mikaela Frixou; James H Park; Antonia Roseweir; Paul G Horgan; Donald C McMillan; Joanne Edwards
Journal:  Histol Histopathol       Date:  2019-10-08       Impact factor: 2.303

2.  Exome sequencing in 51 early onset non-familial CRC cases.

Authors:  Jessada Thutkawkorapin; Annika Lindblom; Emma Tham
Journal:  Mol Genet Genomic Med       Date:  2019-02-27       Impact factor: 2.183

Review 3.  Multifaceted roles of TAK1 signaling in cancer.

Authors:  Himadri Mukhopadhyay; Nam Y Lee
Journal:  Oncogene       Date:  2019-11-06       Impact factor: 9.867

4.  Inactivation of tumor suppressor gene Clusterin leads to hyperactivation of TAK1-NF-κB signaling axis in lung cancer cells and denotes a therapeutic opportunity.

Authors:  Zhipeng Chen; Zhenzhen Fan; Xiaowei Dou; Qian Zhou; Guandi Zeng; Lu Liu; Wensheng Chen; Ruirui Lan; Wanting Liu; Guoqing Ru; Lei Yu; Qing-Yu He; Liang Chen
Journal:  Theranostics       Date:  2020-09-16       Impact factor: 11.556
  4 in total

北京卡尤迪生物科技股份有限公司 © 2022-2023.