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Literature DB >> 20364142

Mitotic cell-cycle progression is regulated by CPEB1 and CPEB4-dependent translational control.

Isabel Novoa¹, Javier Gallego, Pedro G Ferreira, Raul Mendez.

Abstract

Meiotic and early-embryonic cell divisions in vertebrates take place in the absence of transcription and rely on the translational regulation of stored maternal messenger RNAs. Most of these mRNAs are regulated by the cytoplasmic-polyadenylation-element-binding protein (CPEB), which mediates translational activation and repression through cytoplasmic changes in their poly(A) tail length. It was unknown whether translational regulation by cytoplasmic polyadenylation and CPEB can also regulate mRNAs at specific points of mitotic cell-cycle divisions. Here we show that CPEB-mediated post-transcriptional regulation by phase-specific changes in poly(A) tail length is required for cell proliferation and specifically for entry into M phase in mitotically dividing cells. This translational control is mediated by two members of the CPEB family of proteins, CPEB1 and CPEB4. We conclude that regulation of poly(A) tail length is not only required to compensate for the lack of transcription in specialized cell divisions but also acts as a general mechanism to control mitosis.

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Year: 2010 PMID： 20364142 DOI： 10.1038/ncb2046

Source DB: PubMed Journal: Nat Cell Biol ISSN： 1465-7392 Impact factor: 28.824

44 in total

1. Cytoplasmic polyadenylation elements mediate masking and unmasking of cyclin B1 mRNA.

Authors: C H de Moor; J D Richter
Journal: EMBO J Date: 1999-04-15 Impact factor: 11.598

2. Phosphorylation of CPEB by Eg2 mediates the recruitment of CPSF into an active cytoplasmic polyadenylation complex.

Authors: R Mendez; K G Murthy; K Ryan; J L Manley; J D Richter
Journal: Mol Cell Date: 2000-11 Impact factor: 17.970

3. A deadenylation negative feedback mechanism governs meiotic metaphase arrest.

Authors: Eulàlia Belloc; Raúl Méndez
Journal: Nature Date: 2008-04-02 Impact factor: 49.962

4. Selective small-molecule inhibitor reveals critical mitotic functions of human CDK1.

Authors: Lyubomir T Vassilev; Christian Tovar; Shaoqing Chen; Dejan Knezevic; Xiaolan Zhao; Hongmao Sun; David C Heimbrook; Li Chen
Journal: Proc Natl Acad Sci U S A Date: 2006-07-03 Impact factor: 11.205

Review 5. Gel retardation and UV-crosslinking assays to detect specific RNA-protein interactions in the 5' or 3' UTRs of translationally regulated mRNAs.

Authors: J Walker; O de Melo Neto; N Standart
Journal: Methods Mol Biol Date: 1998

6. Opposing polymerase-deadenylase activities regulate cytoplasmic polyadenylation.

Authors: Jong Heon Kim; Joel D Richter
Journal: Mol Cell Date: 2006-10-20 Impact factor: 17.970

7. Control of cellular senescence by CPEB.

Authors: Irina Groisman; Maria Ivshina; Veronica Marin; Norman J Kennedy; Roger J Davis; Joel D Richter
Journal: Genes Dev Date: 2006-10-01 Impact factor: 11.361

8. Two previously undescribed members of the mouse CPEB family of genes and their inducible expression in the principal cell layers of the hippocampus.

Authors: Martin Theis; Kausik Si; Eric R Kandel
Journal: Proc Natl Acad Sci U S A Date: 2003-07-18 Impact factor: 11.205

Review 9. Cdc20: a WD40 activator for a cell cycle degradation machine.

Authors: Hongtao Yu
Journal: Mol Cell Date: 2007-07-06 Impact factor: 17.970

10. Widespread use of poly(A) tail length control to accentuate expression of the yeast transcriptome.

Authors: Traude H Beilharz; Thomas Preiss
Journal: RNA Date: 2007-07 Impact factor: 4.942

83 in total

1. Meiosis requires a translational positive loop where CPEB1 ensues its replacement by CPEB4.

Authors: Ana Igea; Raúl Méndez
Journal: EMBO J Date: 2010-06-08 Impact factor: 11.598

Review 2. Translational control by changes in poly(A) tail length: recycling mRNAs.

Authors: Laure Weill; Eulàlia Belloc; Felice-Alessio Bava; Raúl Méndez
Journal: Nat Struct Mol Biol Date: 2012-06-05 Impact factor: 15.369

3. Time of day regulates subcellular trafficking, tripartite synaptic localization, and polyadenylation of the astrocytic Fabp7 mRNA.

Authors: Jason R Gerstner; William M Vanderheyden; Timothy LaVaute; Cara J Westmark; Labib Rouhana; Allan I Pack; Marv Wickens; Charles F Landry
Journal: J Neurosci Date: 2012-01-25 Impact factor: 6.167

4. Zar1 represses translation in Xenopus oocytes and binds to the TCS in maternal mRNAs with different characteristics than Zar2.

Authors: Tomomi M Yamamoto; Jonathan M Cook; Cassandra V Kotter; Terry Khat; Kevin D Silva; Michael Ferreyros; Justin W Holt; Jefferson D Knight; Amanda Charlesworth
Journal: Biochim Biophys Acta Date: 2013-07-01

5. RNA-binding profiles of Drosophila CPEB proteins Orb and Orb2.

Authors: Barbara Krystyna Stepien; Cornelia Oppitz; Daniel Gerlach; Ugur Dag; Maria Novatchkova; Sebastian Krüttner; Alexander Stark; Krystyna Keleman
Journal: Proc Natl Acad Sci U S A Date: 2016-10-24 Impact factor: 11.205

6. Rapid growth of a hepatocellular carcinoma and the driving mutations revealed by cell-population genetic analysis of whole-genome data.

Authors: Yong Tao; Jue Ruan; Shiou-Hwei Yeh; Xuemei Lu; Yu Wang; Weiwei Zhai; Jun Cai; Shaoping Ling; Qiang Gong; Zecheng Chong; Zhengzhong Qu; Qianqian Li; Jiang Liu; Jin Yang; Caihong Zheng; Changqing Zeng; Hurng-Yi Wang; Jing Zhang; Sheng-Han Wang; Lingtong Hao; Lili Dong; Wenjie Li; Min Sun; Wei Zou; Caixia Yu; Chaohua Li; Guojing Liu; Lan Jiang; Jin Xu; Huanwei Huang; Chunyan Li; Shuangli Mi; Bing Zhang; Baoxian Chen; Wenming Zhao; Songnian Hu; Shi-Mei Zhuang; Yang Shen; Suhua Shi; Christopher Brown; Kevin P White; Ding-Shinn Chen; Pei-Jer Chen; Chung-I Wu
Journal: Proc Natl Acad Sci U S A Date: 2011-07-05 Impact factor: 11.205