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心脏 microRNAs 对心脏 microRNAs 的调控。

Regulation of cardiac microRNAs by cardiac microRNAs.

机构信息

Department of Internal Medicine, Center for Pharmacogenomics, Washington University School of Medicine, St. Louis, MO 63110, USA.

出版信息

Circ Res. 2013 Jun 21;113(1):62-71. doi: 10.1161/CIRCRESAHA.113.300975. Epub 2013 Apr 26.

DOI:10.1161/CIRCRESAHA.113.300975
PMID:23625950
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3769967/
Abstract

RATIONALE

MicroRNAs modestly suppress their direct mRNA targets, and these direct effects are amplified by modulation of gene transcription pathways. Consequently, indirect mRNA modulatory effects of microRNAs to increase or decrease mRNAs greatly outnumber direct target suppressions. Because microRNAs are products of transcription, the potential exists for microRNAs that regulate transcription to regulate other microRNAs.

OBJECTIVE

Determine whether cardiac-expressed microRNAs regulate expression of other cardiac microRNAs, and measure the impact of microRNA-mediated microRNA regulation on indirect regulation of nontarget mRNAs.

METHODS AND RESULTS

Transgenic expression of pre-microRNAs was used to generate mouse hearts expressing 6- to 16-fold normal levels of microRNA (miR)-143, miR-378, and miR-499. Genome-wide mRNA and microRNA signatures were established using deep sequencing; expression profiles provoked by each microRNA were defined. miR-143 suppressed its direct cardiac mRNA target hexokinase 2, but exhibited little indirect target regulation and did not regulate other cardiac microRNAs. Both miR-378 and miR-499 indirectly regulated hundreds of cardiac mRNAs and 15 to 30 cardiac microRNAs. MicroRNA overexpression did not alter normal processing of either transgenic or endogenous cardiac microRNAs, and microRNA-mediated regulation of other microRNAs encoded within parent genes occurred in tandem with parent mRNAs. MicroRNA regulation by miR-378 and miR-499 was stimulus specific, and contributed to observed mRNA downregulation.

CONCLUSIONS

MicroRNAs that modulate cardiac transcription can indirectly regulate other microRNAs. Transcriptional modulation by microRNAs, and microRNA-mediated microRNA regulation, help explain how small direct effects of microRNAs are amplified to generate striking phenotypes.

摘要

背景

微小 RNA 可适度抑制其直接的 mRNA 靶标,这些直接作用通过基因转录途径的调节得到放大。因此,微小 RNA 增加或减少 mRNAs 的间接 mRNA 调节作用远远超过直接靶标抑制作用。由于微小 RNA 是转录的产物,因此调节转录的微小 RNA 有可能调节其他微小 RNA。

目的

确定心脏表达的微小 RNA 是否调节其他心脏微小 RNA 的表达,并测量微小 RNA 介导的微小 RNA 调节对非靶标 mRNAs 的间接调节的影响。

方法和结果

使用前微小 RNA 的转基因表达来产生心脏中表达正常水平 6 到 16 倍的微小 RNA(miR)-143、miR-378 和 miR-499 的小鼠。使用深度测序建立了全基因组 mRNA 和微小 RNA 特征;定义了每个微小 RNA 引起的表达谱。miR-143 抑制其直接的心脏 mRNA 靶标己糖激酶 2,但表现出很少的间接靶标调节作用,并且不调节其他心脏微小 RNA。miR-378 和 miR-499 都间接调节数百个心脏 mRNAs 和 15 到 30 个心脏微小 RNA。微小 RNA 的过表达并未改变转基因或内源性心脏微小 RNA 的正常加工,并且微小 RNA 对母基因内编码的其他微小 RNA 的调节与母 mRNA 同时发生。miR-378 和 miR-499 的微小 RNA 调节具有刺激特异性,并有助于观察到的 mRNA 下调。

结论

调节心脏转录的微小 RNA 可以间接调节其他微小 RNA。微小 RNA 的转录调节以及微小 RNA 介导的微小 RNA 调节有助于解释微小 RNA 的微小直接作用如何被放大以产生显著的表型。

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