Literature DB >> 25263593

mRNA destabilization is the dominant effect of mammalian microRNAs by the time substantial repression ensues.

Stephen W Eichhorn1, Huili Guo2, Sean E McGeary1, Ricard A Rodriguez-Mias3, Chanseok Shin4, Daehyun Baek5, Shu-Hao Hsu6, Kalpana Ghoshal6, Judit Villén3, David P Bartel7.   

Abstract

MicroRNAs (miRNAs) regulate target mRNAs through a combination of translational repression and mRNA destabilization, with mRNA destabilization dominating at steady state in the few contexts examined globally. Here, we extend the global steady-state measurements to additional mammalian contexts and find that regardless of the miRNA, cell type, growth condition, or translational state, mRNA destabilization explains most (66%->90%) miRNA-mediated repression. We also determine the relative dynamics of translational repression and mRNA destabilization for endogenous mRNAs as a miRNA is induced. Although translational repression occurs rapidly, its effect is relatively weak, such that by the time consequential repression ensues, the effect of mRNA destabilization dominates. These results imply that consequential miRNA-mediated repression is largely irreversible and provide other insights into the nature of miRNA-mediated regulation. They also simplify future studies, dramatically extending the known contexts and time points for which monitoring mRNA changes captures most of the direct miRNA effects.
Copyright © 2014 Elsevier Inc. All rights reserved.

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Year:  2014        PMID: 25263593      PMCID: PMC4292926          DOI: 10.1016/j.molcel.2014.08.028

Source DB:  PubMed          Journal:  Mol Cell        ISSN: 1097-2765            Impact factor:   17.970


  58 in total

1.  Differential regulation of germline mRNAs in soma and germ cells by zebrafish miR-430.

Authors:  Yuichiro Mishima; Antonio J Giraldez; Yasuaki Takeda; Toshinobu Fujiwara; Hiroshi Sakamoto; Alexander F Schier; Kunio Inoue
Journal:  Curr Biol       Date:  2006-11-07       Impact factor: 10.834

2.  Uncoupling of lin-14 mRNA and protein repression by nutrient deprivation in Caenorhabditis elegans.

Authors:  Janette Holtz; Amy E Pasquinelli
Journal:  RNA       Date:  2009-01-20       Impact factor: 4.942

3.  Most mammalian mRNAs are conserved targets of microRNAs.

Authors:  Robin C Friedman; Kyle Kai-How Farh; Christopher B Burge; David P Bartel
Journal:  Genome Res       Date:  2008-10-27       Impact factor: 9.043

4.  Mammalian microRNAs predominantly act to decrease target mRNA levels.

Authors:  Huili Guo; Nicholas T Ingolia; Jonathan S Weissman; David P Bartel
Journal:  Nature       Date:  2010-08-12       Impact factor: 49.962

5.  Mammalian miRNA RISC recruits CAF1 and PABP to affect PABP-dependent deadenylation.

Authors:  Marc R Fabian; Géraldine Mathonnet; Thomas Sundermeier; Hansruedi Mathys; Jakob T Zipprich; Yuri V Svitkin; Fabiola Rivas; Martin Jinek; James Wohlschlegel; Jennifer A Doudna; Chyi-Ying A Chen; Ann-Bin Shyu; John R Yates; Gregory J Hannon; Witold Filipowicz; Thomas F Duchaine; Nahum Sonenberg
Journal:  Mol Cell       Date:  2009-08-27       Impact factor: 17.970

6.  Posttranscriptional regulation of the heterochronic gene lin-14 by lin-4 mediates temporal pattern formation in C. elegans.

Authors:  B Wightman; I Ha; G Ruvkun
Journal:  Cell       Date:  1993-12-03       Impact factor: 41.582

Review 7.  MicroRNAs: target recognition and regulatory functions.

Authors:  David P Bartel
Journal:  Cell       Date:  2009-01-23       Impact factor: 41.582

8.  Genome-wide analysis in vivo of translation with nucleotide resolution using ribosome profiling.

Authors:  Nicholas T Ingolia; Sina Ghaemmaghami; John R S Newman; Jonathan S Weissman
Journal:  Science       Date:  2009-02-12       Impact factor: 47.728

9.  Concordant regulation of translation and mRNA abundance for hundreds of targets of a human microRNA.

Authors:  David G Hendrickson; Daniel J Hogan; Heather L McCullough; Jason W Myers; Daniel Herschlag; James E Ferrell; Patrick O Brown
Journal:  PLoS Biol       Date:  2009-11-10       Impact factor: 8.029

10.  Ago-TNRC6 triggers microRNA-mediated decay by promoting two deadenylation steps.

Authors:  Chyi-Ying A Chen; Dinghai Zheng; Zhenfang Xia; Ann-Bin Shyu
Journal:  Nat Struct Mol Biol       Date:  2009-10-18       Impact factor: 15.369
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  210 in total

Review 1.  Strategies to Modulate MicroRNA Functions for the Treatment of Cancer or Organ Injury.

Authors:  Tae Jin Lee; Xiaoyi Yuan; Keith Kerr; Ji Young Yoo; Dong H Kim; Balveen Kaur; Holger K Eltzschig
Journal:  Pharmacol Rev       Date:  2020-07       Impact factor: 25.468

2.  Tissue- and development-stage-specific mRNA and heterogeneous CNV signatures of human ribosomal proteins in normal and cancer samples.

Authors:  Anshuman Panda; Anupama Yadav; Huwate Yeerna; Amartya Singh; Michael Biehl; Markus Lux; Alexander Schulz; Tyler Klecha; Sebastian Doniach; Hossein Khiabanian; Shridar Ganesan; Pablo Tamayo; Gyan Bhanot
Journal:  Nucleic Acids Res       Date:  2020-07-27       Impact factor: 16.971

3.  A Network of Noncoding Regulatory RNAs Acts in the Mammalian Brain.

Authors:  Benjamin Kleaveland; Charlie Y Shi; Joanna Stefano; David P Bartel
Journal:  Cell       Date:  2018-06-07       Impact factor: 41.582

Review 4.  Towards a molecular understanding of microRNA-mediated gene silencing.

Authors:  Stefanie Jonas; Elisa Izaurralde
Journal:  Nat Rev Genet       Date:  2015-06-16       Impact factor: 53.242

5.  In vivo, Argonaute-bound microRNAs exist predominantly in a reservoir of low molecular weight complexes not associated with mRNA.

Authors:  Gaspare La Rocca; Scott H Olejniczak; Alvaro J González; Daniel Briskin; Joana A Vidigal; Lee Spraggon; Raymond G DeMatteo; Megan R Radler; Tullia Lindsten; Andrea Ventura; Thomas Tuschl; Christina S Leslie; Craig B Thompson
Journal:  Proc Natl Acad Sci U S A       Date:  2015-01-07       Impact factor: 11.205

6.  AGO CLIP Reveals an Activated Network for Acute Regulation of Brain Glutamate Homeostasis in Ischemic Stroke.

Authors:  Mariko Kobayashi; Corinne Benakis; Corey Anderson; Michael J Moore; Carrie Poon; Ken Uekawa; Jonathan P Dyke; John J Fak; Aldo Mele; Christopher Y Park; Ping Zhou; Josef Anrather; Costantino Iadecola; Robert B Darnell
Journal:  Cell Rep       Date:  2019-07-23       Impact factor: 9.423

Review 7.  A network-biology perspective of microRNA function and dysfunction in cancer.

Authors:  Cameron P Bracken; Hamish S Scott; Gregory J Goodall
Journal:  Nat Rev Genet       Date:  2016-10-31       Impact factor: 53.242

8.  General rules for functional microRNA targeting.

Authors:  Doyeon Kim; You Me Sung; Jinman Park; Sukjun Kim; Jongkyu Kim; Junhee Park; Haeok Ha; Jung Yoon Bae; SoHui Kim; Daehyun Baek
Journal:  Nat Genet       Date:  2016-10-24       Impact factor: 38.330

9.  miRNA target identification and prediction as a function of time in gene expression data.

Authors:  Pranas Grigaitis; Vytaute Starkuviene; Ursula Rost; Andrius Serva; Pascal Pucholt; Ursula Kummer
Journal:  RNA Biol       Date:  2020-04-22       Impact factor: 4.652

10.  miRISC Composition Determines Target Fates in Time and Space.

Authors:  Himani Galagali; John K Kim
Journal:  Dev Cell       Date:  2018-10-22       Impact factor: 12.270
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