Literature DB >> 25043018

Activation and repression by oncogenic MYC shape tumour-specific gene expression profiles.

Susanne Walz1, Francesca Lorenzin1, Jennifer Morton2, Katrin E Wiese3, Björn von Eyss3, Steffi Herold3, Lukas Rycak4, Hélène Dumay-Odelot5, Saadia Karim2, Marek Bartkuhn6, Frederik Roels7, Torsten Wüstefeld8, Matthias Fischer7, Martin Teichmann5, Lars Zender9, Chia-Lin Wei10, Owen Sansom2, Elmar Wolf11, Martin Eilers12.   

Abstract

In mammalian cells, the MYC oncoprotein binds to thousands of promoters. During mitogenic stimulation of primary lymphocytes, MYC promotes an increase in the expression of virtually all genes. In contrast, MYC-driven tumour cells differ from normal cells in the expression of specific sets of up- and downregulated genes that have considerable prognostic value. To understand this discrepancy, we studied the consequences of inducible expression and depletion of MYC in human cells and murine tumour models. Changes in MYC levels activate and repress specific sets of direct target genes that are characteristic of MYC-transformed tumour cells. Three factors account for this specificity. First, the magnitude of response parallels the change in occupancy by MYC at each promoter. Functionally distinct classes of target genes differ in the E-box sequence bound by MYC, suggesting that different cellular responses to physiological and oncogenic MYC levels are controlled by promoter affinity. Second, MYC both positively and negatively affects transcription initiation independent of its effect on transcriptional elongation. Third, complex formation with MIZ1 (also known as ZBTB17) mediates repression of multiple target genes by MYC and the ratio of MYC and MIZ1 bound to each promoter correlates with the direction of response.

Entities:  

Mesh:

Substances:

Year:  2014        PMID: 25043018      PMCID: PMC6879323          DOI: 10.1038/nature13473

Source DB:  PubMed          Journal:  Nature        ISSN: 0028-0836            Impact factor:   49.962


  38 in total

1.  Myc-induced proliferation and transformation require Akt-mediated phosphorylation of FoxO proteins.

Authors:  Caroline Bouchard; Judith Marquardt; Alexandra Brás; René H Medema; Martin Eilers
Journal:  EMBO J       Date:  2004-07-08       Impact factor: 11.598

Review 2.  The role of MIZ-1 in MYC-dependent tumorigenesis.

Authors:  Katrin E Wiese; Susanne Walz; Björn von Eyss; Elmar Wolf; Dimitris Athineos; Owen Sansom; Martin Eilers
Journal:  Cold Spring Harb Perspect Med       Date:  2013-12-01       Impact factor: 6.915

3.  c-Myc regulates transcriptional pause release.

Authors:  Peter B Rahl; Charles Y Lin; Amy C Seila; Ryan A Flynn; Scott McCuine; Christopher B Burge; Phillip A Sharp; Richard A Young
Journal:  Cell       Date:  2010-04-30       Impact factor: 41.582

Review 4.  The RNA polymerase II CTD coordinates transcription and RNA processing.

Authors:  Jing-Ping Hsin; James L Manley
Journal:  Genes Dev       Date:  2012-10-01       Impact factor: 11.361

5.  Transcriptional amplification in tumor cells with elevated c-Myc.

Authors:  Charles Y Lin; Jakob Lovén; Peter B Rahl; Ronald M Paranal; Christopher B Burge; James E Bradner; Tong Ihn Lee; Richard A Young
Journal:  Cell       Date:  2012-09-28       Impact factor: 41.582

6.  Trp53R172H and KrasG12D cooperate to promote chromosomal instability and widely metastatic pancreatic ductal adenocarcinoma in mice.

Authors:  Sunil R Hingorani; Lifu Wang; Asha S Multani; Chelsea Combs; Therese B Deramaudt; Ralph H Hruban; Anil K Rustgi; Sandy Chang; David A Tuveson
Journal:  Cancer Cell       Date:  2005-05       Impact factor: 31.743

7.  Repression of p15INK4b expression by Myc through association with Miz-1.

Authors:  P Staller; K Peukert; A Kiermaier; J Seoane; J Lukas; H Karsunky; T Möröy; J Bartek; J Massagué; F Hänel; M Eilers
Journal:  Nat Cell Biol       Date:  2001-04       Impact factor: 28.824

8.  BEDTools: a flexible suite of utilities for comparing genomic features.

Authors:  Aaron R Quinlan; Ira M Hall
Journal:  Bioinformatics       Date:  2010-01-28       Impact factor: 6.937

9.  Pol II and its associated epigenetic marks are present at Pol III-transcribed noncoding RNA genes.

Authors:  Artem Barski; Iouri Chepelev; Dritan Liko; Suresh Cuddapah; Alastair B Fleming; Joanna Birch; Kairong Cui; Robert J White; Keji Zhao
Journal:  Nat Struct Mol Biol       Date:  2010-04-25       Impact factor: 15.369

10.  seqMINER: an integrated ChIP-seq data interpretation platform.

Authors:  Tao Ye; Arnaud R Krebs; Mohamed-Amin Choukrallah; Celine Keime; Frederic Plewniak; Irwin Davidson; Laszlo Tora
Journal:  Nucleic Acids Res       Date:  2010-12-21       Impact factor: 16.971
View more
  229 in total

1.  Low expression of miR-let-7a promotes cell growth and invasion through the regulation of c-Myc in oral squamous cell carcinoma.

Authors:  Chunyang Luo; Jiyong Zhang; Yi Zhang; Xiao Zhang; Yinan Chen; Weimin Fan
Journal:  Cell Cycle       Date:  2020-06-28       Impact factor: 4.534

Review 2.  Patterns of Chromosomal Aberrations in Solid Tumors.

Authors:  Marian Grade; Michael J Difilippantonio; Jordi Camps
Journal:  Recent Results Cancer Res       Date:  2015

Review 3.  MYC: connecting selective transcriptional control to global RNA production.

Authors:  Theresia R Kress; Arianna Sabò; Bruno Amati
Journal:  Nat Rev Cancer       Date:  2015-09-18       Impact factor: 60.716

4.  Deubiquitinating c-Myc: USP36 steps up in the nucleolus.

Authors:  Xiao-Xin Sun; Rosalie C Sears; Mu-Shui Dai
Journal:  Cell Cycle       Date:  2015       Impact factor: 4.534

5.  MYC-induced apoptosis in mammary epithelial cells is associated with repression of lineage-specific gene signatures.

Authors:  Heidi M Haikala; Juha Klefström; Martin Eilers; Katrin E Wiese
Journal:  Cell Cycle       Date:  2016       Impact factor: 4.534

6.  TEAD activity is restrained by MYC and stratifies human breast cancer subtypes.

Authors:  Dana Elster; Laura A Jaenicke; Martin Eilers; Björn von Eyss
Journal:  Cell Cycle       Date:  2016-07-19       Impact factor: 4.534

7.  MYC Disrupts the Circadian Clock and Metabolism in Cancer Cells.

Authors:  Brian J Altman; Annie L Hsieh; Arjun Sengupta; Saikumari Y Krishnanaiah; Zachary E Stine; Zandra E Walton; Arvin M Gouw; Anand Venkataraman; Bo Li; Pankuri Goraksha-Hicks; Sharon J Diskin; David I Bellovin; M Celeste Simon; Jeffrey C Rathmell; Mitchell A Lazar; John M Maris; Dean W Felsher; John B Hogenesch; Aalim M Weljie; Chi V Dang
Journal:  Cell Metab       Date:  2015-09-17       Impact factor: 27.287

Review 8.  MYC, Metabolism, and Cancer.

Authors:  Zachary E Stine; Zandra E Walton; Brian J Altman; Annie L Hsieh; Chi V Dang
Journal:  Cancer Discov       Date:  2015-09-17       Impact factor: 39.397

9.  mTORC2 Signaling Drives the Development and Progression of Pancreatic Cancer.

Authors:  David R Driscoll; Saadia A Karim; Makoto Sano; David M Gay; Wright Jacob; Jun Yu; Yusuke Mizukami; Aarthi Gopinathan; Duncan I Jodrell; T R Jeffry Evans; Nabeel Bardeesy; Michael N Hall; Brian J Quattrochi; David S Klimstra; Simon T Barry; Owen J Sansom; Brian C Lewis; Jennifer P Morton
Journal:  Cancer Res       Date:  2016-10-06       Impact factor: 12.701

10.  MYCN Silencing by RNAi Induces Neurogenesis and Suppresses Proliferation in Models of Neuroblastoma with Resistance to Retinoic Acid.

Authors:  Ruhina Maeshima; Dale Moulding; Andrew W Stoker; Stephen L Hart
Journal:  Nucleic Acid Ther       Date:  2020-04-02       Impact factor: 5.486
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.