Inhibition of Translational Initiation by Let-7 MicroRNA in Human Cells

Pillai, Ramesh S.; Bhattacharyya, S. N.; Artus, Caroline G.; Zoller, Tabea; Cougot, Nicolas; Basyuk, Eugénia; Bertrand, Édouard; Filipowicz, Witold

doi:10.1126/science.1115079

Cited by 1,253 publications

(1,255 citation statements)

References 24 publications

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“…Plant miRNAs are also methylated on the ribose of the last nucleotide, a modification presumably involved in protecting miRNAs from 3′ end uridylation and degradation, whereas animal miRNAs do not appear to be modified Yu et al 2005). Mechanistically, most animal miRNAs are only partly complementary to their targets and mediate silencing primarily by translational repression, although localization to the processing bodies may also affect RNA stability (Humphreys et al 2005;Liu et al 2005b;Pillai et al 2005;Wienholds and Plasterk 2005;Zamore and Haley 2005). In contrast, most plant miRNAs have near-perfect complementarity to their targets and trigger predominantly mRNA cleavage (Carrington and Ambros 2003;Schwab et al 2005).…”

Section: Additional (Derived?) Functions Of the Rnai Machinerymentioning

confidence: 99%

On the origin and functions of RNA-mediated silencing: from protists to man

2006

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Double-stranded RNA has been shown to induce gene silencing in diverse eukaryotes and by a variety of pathways. We have examined the taxonomic distribution and the phylogenetic relationship of key components of the RNA interference (RNAi) machinery in members of five eukaryotic supergroups. On the basis of the parsimony principle, our analyses suggest that a relatively complex RNAi machinery was already present in the last common ancestor of eukaryotes and consisted, at a minimum, of one Argonautelike polypeptide, one Piwi-like protein, one Dicer, and one RNAdependent RNA polymerase. As proposed before, the ancestral (but non-essential) role of these components may have been in defense responses against genomic parasites such as transposable elements and viruses. From a mechanistic perspective, the RNAi machinery in the eukaryotic ancestor may have been capable of both small-RNA-guided transcript degradation as well as transcriptional repression, most likely through histone modifications. Both roles appear to be widespread among living eukaryotes and this diversification of function could account for the evolutionary conservation of duplicated Argonaute-Piwi proteins. In contrast, additional RNAi-mediated pathways such as RNA-directed DNA methylation, programmed genome rearrangements, meiotic silencing by unpaired DNA, and miRNA-mediated gene regulation may have evolved independently in specific lineages.

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Section: Additional (Derived?) Functions Of the Rnai Machinerymentioning

confidence: 99%

On the origin and functions of RNA-mediated silencing: from protists to man

2006

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“…However, miRNAs also interfere with translation at the initiation step. Analysing of the effects of both exogenously provided miRNA-like siRNAs or endogenous miRNAs on the translation of their reporter and endogenous targets in human cells showed that the 5 0 cap is required for miRNA-mediated translational repression, because IRES initiated translation or tethering eIF4E and eIF4G to the reporter was immune to miRNAs (Humphreys et al, 2005;Pillai et al, 2005). The two reports disagree with the prerequisite of the poly(A) tail for the inhibition, but in cell free translation system both the 5 0 cap and the poly(A) tail has been shown to be required for recapitulating miRNAmediated translational repression .…”

Section: Mechanism(s) Of Mirna-mediated Gene Regulationmentioning

confidence: 99%

Principles and effects of microRNA-mediated post-transcriptional gene regulation

2006

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MicroRNAs (miRNAs) are abundant regulatory RNAs involved in the regulation of many key biological processes. Recent advances in understanding the mechanism of RNA interference and miRNA-mediated mechanisms shed light on major principals of the formation of the regulatory complex and provide models to explain how these small regulatory RNA species interfere with gene expression and how they influence the translational status of the transcriptome.

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“…2); it still remains to be deciphered which of these model mechanisms are cause and consequence of translational repression. miRNAs affecting initiation steps only affect capdependent translation, possibly through m 7 G cap recognition (Refs 46,47,48,49,50). Argonaute proteins contain structural similarities to the cap-binding protein eIF4E, and thus it has been suggested that translational repression may occur due to competition between argonaute and eIF4E for binding to the cap structure (Ref.…”

Section: Mechanism(s) Of Mirna Actionmentioning

confidence: 99%

Molecular medicine of microRNAs: structure, function and implications for diabetes

Hennessy

O’Driscoll²

2008

Expert Rev. Mol. Med.

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MicroRNAs (miRNAs) are a family of endogenous small noncoding RNA molecules, of 19–28 nucleotides in length. In humans, up to 3% of all genes are estimated to encode these evolutionarily conserved sequences. miRNAs are thought to control expression of thousands of target mRNAs. Mammalian miRNAs generally negatively regulate gene expression by repressing translation, possibly through effects on mRNA stability and compartmentalisation, and/or the translation process itself. An extensive range of in silico and experimental techniques have been applied to our understanding of the occurrence and functional relevance of such sequences, and antisense technologies have been successfully used to control miRNA expression in vitro and in vivo. Interestingly, miRNAs have been identified in both normal and pathological conditions, including differentiation and development, metabolism, proliferation, cell death, viral infection and cancer. Of specific relevance and excitement to the area of diabetes research, miRNA regulation has been implicated in insulin secretion from pancreatic β-cells, diabetic heart conditions and nephropathy. Further analyses of miRNAs in vitro and in vivo will, undoubtedly, enable us determine their potential to be exploited as therapeutic targets in diabetes.

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Inhibition of Translational Initiation by Let-7 MicroRNA in Human Cells

Cited by 1,253 publications

References 24 publications

On the origin and functions of RNA-mediated silencing: from protists to man

On the origin and functions of RNA-mediated silencing: from protists to man

Principles and effects of microRNA-mediated post-transcriptional gene regulation

Molecular medicine of microRNAs: structure, function and implications for diabetes

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