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核RNA干扰有助于秀丽隐杆线虫中脱靶基因和重复序列的沉默。

Nuclear RNAi contributes to the silencing of off-target genes and repetitive sequences in Caenorhabditis elegans.

作者信息

Zhou Xufei, Xu Fei, Mao Hui, Ji Jiaojiao, Yin Meng, Feng Xuezhu, Guang Shouhong

机构信息

School of Life Sciences, University of Science and Technology of China, Hefei, Anhui 230027, People's Republic of China.

出版信息

Genetics. 2014 May;197(1):121-32. doi: 10.1534/genetics.113.159780. Epub 2014 Feb 14.

DOI:10.1534/genetics.113.159780
PMID:24532782
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4012473/
Abstract

Small RNAs recognize, bind, and regulate other complementary cellular RNAs. The introduction of small RNAs to eukaryotic cells frequently results in unintended silencing of related, but not identical, RNAs: a process termed off-target gene silencing. Off-target gene silencing is one of the major concerns during the application of small RNA-based technologies for gene discovery and the treatment of human disease. Off-target gene silencing is commonly thought to be due to inherent biochemical limitations of the RNAi machinery. Here we show that following the introduction of exogenous sources of double-stranded RNA, the nuclear RNAi pathway, but not its cytoplasmic counterparts, is the primary source of off-target silencing in Caenorhabditis elegans. In addition, we show that during the normal course of growth and development the nuclear RNAi pathway regulates repetitive gene families. Therefore, we speculate that RNAi off-target effects might not be "mistakes" but rather an intentional and genetically programmed aspect of small RNA-mediated gene silencing, which might allow small RNAs to silence rapidly evolving parasitic nucleic acids. Finally, reducing off-target effects by manipulating the nuclear RNAi pathway in vivo might improve the efficacy of small RNA-based technologies.

摘要

小RNA识别、结合并调控其他互补的细胞RNA。将小RNA导入真核细胞常常会导致相关但不完全相同的RNA意外沉默:这一过程被称为脱靶基因沉默。脱靶基因沉默是基于小RNA的技术应用于基因发现和人类疾病治疗过程中的主要问题之一。脱靶基因沉默通常被认为是由于RNA干扰机制固有的生化局限性所致。在此我们表明,在引入外源双链RNA后,核RNA干扰途径而非其细胞质对应途径是秀丽隐杆线虫中脱靶沉默的主要来源。此外,我们表明在正常的生长和发育过程中,核RNA干扰途径调控重复基因家族。因此,我们推测RNA干扰的脱靶效应可能并非“错误”,而是小RNA介导的基因沉默中有意且由基因编程的一个方面,这可能使小RNA能够沉默快速进化的寄生核酸。最后,通过在体内操纵核RNA干扰途径来减少脱靶效应可能会提高基于小RNA的技术的功效。

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