Identifying and annotating human bifunctional RNAs reveals their versatile functions 被引量：1

Identifying and annotating human bifunctional RNAs reveals their versatile functions

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摘要 Bifunctional RNAs that possess both protein-coding and noncoding functional properties were less explored and poorly understood. Here we systematically explored the characteristics and functions of such human bifunctional RNAs by integrating tandem mass spectrometry and RNA-seq data. We first constructed a pipeline to identify and annotate bifunctional RNAs,leading to the characterization of 132 high-confidence bifunctional RNAs. Our analyses indicate that bifunctional RNAs may be involved in human embryonic development and can be functional in diverse tissues. Moreover, bifunctional RNAs could interact with multiple miRNAs and RNA-binding proteins to exert their corresponding roles. Bifunctional RNAs may also function as competing endogenous RNAs to regulate the expression of many genes by competing for common targeting miRNAs. Finally,somatic mutations of diverse carcinomas may generate harmful effect on corresponding bifunctional RNAs. Collectively,our study not only provides the pipeline for identifying and annotating bifunctional RNAs but also reveals their important gene-regulatory functions. Bifunctional RNAs that possess both protein-coding and noncoding functional properties were less explored and poorly understood. Here we systematically explored the characteristics and functions of such human bifunctional RNAs by integrating tandem mass spectrometry and RNA-seq data. We first constructed a pipeline to identify and annotate bifunctional RNAs, leading to the characterization of 132 high-confidence bifunctional RNAs. Our analyses indicate that bifunctional RNAs may be involved in human embryonic development and can be functional in diverse tissues. Moreover, bifunctional RNAs could interact with multiple miRNAs and RNA-binding proteins to exert their corresponding roles. Bifunctional RNAs may also function as competing endogenous RNAs to regulate the expression of many genes by competing for common targeting miRNAs. Finally, somatic mutations of diverse carcinomas may generate harmful effect on corresponding bifunctional RNAs. Collectively, our study not only provides the pipeline for identifying and annotating bifunctional RNAs but also reveals their important gene-regulatory functions.

作者 Geng Chen Juan Yang Jiwei Chen Yunjie Song Ruifang Cao Tieliu Shi Leming Shi

机构地区 Center for Pharmacogenomics The Center for Bioinformatics and Computational Biology State Key Laboratory of Genetic Engineering and MOE Key Laboratory of Contemporary Anthropology Fudan-Zhangjiang Center for Clinical Genomics Zhanjiang Center for Translational Medicine

出处《Science China(Life Sciences)》 SCIE CAS CSCD 2016年第10期981-992,共12页 中国科学（生命科学英文版）

基金 supported in part by the National High Technology Research and Development Program of China(2015AA020104,2015AA020108) the China Human Proteomics Project(2014DF30030) the National Science Foundation of China(31471239)

关键词 bifunctional RNA noncoding RNA RNA-SEQ tandem mass spectrometry miRNAs 人类胚胎识别注释多功能蛋白相互作用调控功能蛋白质编码

分类号 Q752 [生物学—分子生物学]

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Identifying and annotating human bifunctional RNAs reveals their versatile functions 被引量：1

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