微处理器活性在体内控制着差异性miRNA生物合成。

Microprocessor activity controls differential miRNA biogenesis In Vivo.

作者信息

Conrad Thomas, Marsico Annalisa, Gehre Maja, Orom Ulf Andersson

机构信息

Otto Warburg Laboratories, Noncoding RNA Research Group, Max Planck Institute for Molecular Genetics, 14195 Berlin, Germany.

Department of Computational Molecular Biology, Max Planck Institute for Molecular Genetics, 14195 Berlin, Germany; Department of Mathematics and Informatics, Free University of Berlin, 14195 Berlin, Germany.

出版信息

Cell Rep. 2014 Oct 23;9(2):542-54. doi: 10.1016/j.celrep.2014.09.007. Epub 2014 Oct 9.

DOI:10.1016/j.celrep.2014.09.007

PMID:25310978

Abstract

In miRNA biogenesis, pri-miRNA transcripts are converted into pre-miRNA hairpins. The in vivo properties of this process remain enigmatic. Here, we determine in vivo transcriptome-wide pri-miRNA processing using next-generation sequencing of chromatin-associated pri-miRNAs. We identify a distinctive Microprocessor signature in the transcriptome profile from which efficiency of the endogenous processing event can be accurately quantified. This analysis reveals differential susceptibility to Microprocessor cleavage as a key regulatory step in miRNA biogenesis. Processing is highly variable among pri-miRNAs and a better predictor of miRNA abundance than primary transcription itself. Processing is also largely stable across three cell lines, suggesting a major contribution of sequence determinants. On the basis of differential processing efficiencies, we define functionality for short sequence features adjacent to the pre-miRNA hairpin. In conclusion, we identify Microprocessor as the main hub for diversified miRNA output and suggest a role for uncoupling miRNA biogenesis from host gene expression.

摘要

在微小RNA（miRNA）生物合成过程中，初级miRNA（pri-miRNA）转录本会转化为前体miRNA发夹结构。这一过程在体内的特性仍然是个谜。在此，我们利用与染色质相关的pri-miRNA的新一代测序技术，在全转录组范围内确定了体内pri-miRNA的加工情况。我们在转录组图谱中识别出一种独特的微处理器特征，据此可以准确量化内源性加工事件的效率。该分析揭示了对微处理器切割的不同敏感性是miRNA生物合成中的关键调控步骤。pri-miRNA之间的加工具有高度变异性，并且比初级转录本身更能预测miRNA丰度。加工在三种细胞系中也基本稳定，这表明序列决定因素起主要作用。基于不同的加工效率，我们定义了前体miRNA发夹结构附近短序列特征的功能。总之，我们确定微处理器是多样化miRNA输出的主要枢纽，并提出了将miRNA生物合成与宿主基因表达解偶联的作用。

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微处理器活性在体内控制着差异性miRNA生物合成。

Microprocessor activity controls differential miRNA biogenesis In Vivo.

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