RNA干扰研究进展

RNA干扰(RNA interference,RNAi)是指由双链RNA(double-strandedRNA,dsRNA)启动的序列特异的转录后基因沉默现象,广泛存在于真菌、植物和动物中。它是细胞内由双链RNA诱导降解与其配对的特定mRNA的过程。细胞内双链RNA在酶的作用下,形成20-25碱基大小的小干扰RNA(siRNAs),由siRNAs进一步掺入多组分核酸酶并使其激活,从而精确降解与siRNAs序列相同的mRNA,抑制该基因在细胞内的翻译表达。RNAi技术是近年来迅速发展起来的高效、特异、易操作的基因沉默技术。与反义寡核苷酸等传统方法相比,RNAi技术有着无可比拟的优势。本文就其近年的研究进展作一综述。     

基于BP神经网络的siRNA活性预测

RNA干扰(RNAinterference,RNAi)是由双链RNA(dsRNA)引起的基因沉默现象,它通过降解具有同源序列的mRNA来起作用,特殊设计的siRNA能使靶基因发生特异性沉默,起到确定基因功能或沉默致病基因从而治疗疾病的目的。在RNAi技术的应用中,通常采用的是长度为19bp,正、反义链3'端各有2个不配对碱基的双链RNA(siRNA)。但针对靶基因不同位点设计的siRNA作用效果差别很大。影响siRNA效果的因素是多方面的,这些因素的作用又是非线性的。本文在研究影响siRNA作用效果的各种因素的基础上,对已经公开发表的实验数据进行特征提取,作为BP神经网络的训练数据,并将训练好的BP神经网络用于siRNA活性预测。     

可用于研究RNA干扰的试剂盒简介

RNA干扰 (RNAi)指双链RNA (dsRNA)通过刺激目标RNA降解而特异性抑制目标蛋白质合成的现象 ,这些目标RNA具有与双链RNA相同的序列。人们假设RNA干扰的机理为两步反应 :起始阶段和效应器阶段。在起始阶段 ,被导入非哺乳动物细胞系统 ,例如果蝇的长双链RNA(2 0 0～ 10 0 0bp) ,被RNaseⅢ家族的一个成员 (例如果蝇中的Dicer酶 )处理成 2 1～ 2 3nt的双链RNA (短干扰RNA ,siRNA)。再进一步切割生成 3′端有两个核苷酸突出的许多双链RNA。在效应器阶段 ,双链siRNA诱发RNA诱导的沉默复合体 (RISC)的形成 ,这是一个由若干蛋白…     

番茄丛矮病毒p19蛋白抑制转录后基因沉默作用机制

RNA干扰（RNA interference,RNAi）是真核生物体内由双链RNA（double—stranded RNA）介导的同源RNA降解现象。在细胞内,长的dsRNA被Dicer酶切割成21～26核苷酸（nucleotide,nt）的小干扰RNA（small interfering RNA或short interfering RNA,siRNA）;siRNA与多种蛋白结合后形成RNA诱导沉默复合物（RNA—induced silencing complex,RISC）,同时解链;有活性的RISC可在siRNA的指引下与互补的转录物结合,并导致RNA的降解,     

RNA诱导沉默复合体中的生物大分子及其装配

在RNA干扰机制中,双链RNA诱导同源RNA降解的过程依赖于RNA诱导沉默复合体（RISC）的活性。RISC由Dicer酶,Argonaute蛋白,siRNA等多种生物大分子装配而成,对这些大分子的结构和功能进行深入细致的研究,有助于进一步了解RISC的形成过程、作用方式,以及阐明整个RNAi过程的作用机制。研究表明,RISC中的Dicer具有RNaseIII结构域,在RNAi的起始阶段负责催化siRNA的产生,在RISC装配过程中起稳定RISC中间体结构和功能的作用;Argonaute蛋白是RISC中的核心蛋白,有PAZ和PIWI两个主要的结构域,前者为siRNA的传递提供结合位点,后者是RISC中的酶切割活性中心;siRNA是RISC完成特异性切割作用的向导,在成熟的RISC中虽然只包含siRNA的一条链,但siRNA在RISC形成过程中的双链结构是保证RNAi效应的决定因素。尽管RISC中还存在其他一些功能未知的蛋白质,但在RISC组分结构及功能研究方面取得的进展为建立一个可能的RISC装配模型提供了理论基础。     

高效siRNA设计的研究进展

RNA干扰(RNA interference, RNAi) 是生物界普遍存在的一种抵御外来基因和病毒感染的保守进化机制, 其本质是siRNA与靶向mRNA特异结合、并由RISC介导其降解, 从而阻止mRNA的翻译, 导致基因沉默。因此, RNAi可以作为基因功能研究、基因治疗等的新工具。但是, 随机设计的siRNA之间沉默效应差别很大。如何针对靶基因设计特异、高效的siRNA就成了一个关键的问题。文章对siRNA设计原则的研究进展进行了总结论述。     

可用于研究RNA干扰的试剂盒简介

RNA干扰 (RNAi)指双链RNA (dsRNA)通过刺激目标RNA降解而特异性抑制目标蛋白质合成的现象 ,这些目标RNA具有与双链RNA相同的序列 .人们假设RNA干扰的机理为两步反应 :起始阶段和效应器阶段 .在起始阶段 ,被导入非哺乳动物细胞系统 ,例如果蝇的长双链RNA(2 0 0～ 10 0 0bp)被RNaseⅢ家族的一个成员 (例如果蝇中的Dicer酶 )处理成 2 1～ 2 3nt的双链RNA(短干扰RNA ,siRNA) .再经进一步切割生成 3′端有两个核苷酸突出的许多双链RNA .在效应器阶段 ,双链siRNA诱发RNA诱导的沉默复合体 (RISC)的形成 ,这是一个由若干蛋白质…     

小干扰RNA的研究进展

RNA干扰(RNA interference,RNAi)是近年发展起来的一种新技术。RNAi是指通过外源性或内源性的双链RNA在体内诱导靶基因mRNA产生特异性降解,进而引起不同水平的基因沉默,其效应分子主要是小干扰RNA(siRNA)。siRNA是生物界普遍存在的一种抵御外来基因和病毒感染的基因调控方式,也是一种重要的研究工具。大量的研究工作致力于设计合理的siRNA片段用于基因功能研究,并将其作为一种治疗方法用于肿瘤、病毒性疾病等基因治疗以及药物靶向研究。因此本文对siRNA的作用机制、设计原则及其在临床应用中的缺点和解决方法进行综述。     

Initiation by a Eukaryotic RNA-dependent RNA Polymerase Requires Looping of the Template End and Is Influenced by the Template-tailing Activity of an Associated Uridyltransferase

A conserved family of eukaryotic RNA-dependent RNA polymerases (RDRs) initiates or amplifies the production of small RNAs to provide sequence specificity for gene regulation by Argonaute/Piwi proteins. RDR-dependent silencing processes affect the genotype-phenotype relationship in many eukaryotes, but the principles that underlie the specificity of RDR template selection and product synthesis are largely unknown. Here, we characterize the initiation specificity of the Tetrahymena RDR, Rdr1, as a heterologously expressed single subunit and in the context of its biologically assembled multisubunit complexes (RDRCs). Truncation analysis of recombinant Rdr1 revealed domain requirements different from those of the only other similarly characterized RDR, suggesting that there are subfamilies of the RDR enzyme with distinct structural requirements for activity. We demonstrate an apparently obligate Rdr1 mechanism of initiation in which the template end is looped to provide the hydroxyl group priming the synthesis of dsRNA. RDRC subunits with poly(U) polymerase activity can act on the template end prior to looping to increase the duplex length of product, thus impacting the small RNA sequences generated by the RDRC-coupled Dicer. Overall, our findings give new perspective on mechanisms of RDR initiation and demonstrate that non-RDR subunits of an RDRC can affect the specificity of product synthesis.     

Small RNAs from cereal powdery mildew pathogens may target host plant genes

Small RNAs (sRNAs) play a key role in eukaryotic gene regulation, for example by gene silencing via RNA interference (RNAi). The biogenesis of sRNAs depends on proteins that are generally conserved in all eukaryotic lineages, yet some species that lack part or all the components of the mechanism exist. Here we explored the presence of the RNAi machinery and its expression as well as the occurrence of sRNA candidates and their putative endogenous as well as host targets in phytopathogenic powdery mildew fungi. We focused on the species Blumeria graminis, which occurs in various specialized forms (formae speciales) that each have a strictly limited host range. B. graminis f. sp. hordei and B. graminis f. sp. tritici, colonizing barley and wheat, respectively, have genomes that are characterized by extensive gene loss. Nonetheless, we find that the RNAi machinery appears to be largely complete and expressed during infection. sRNA sequencing data enabled the identification of putative sRNAs in both pathogens. While a considerable part of the sRNA candidates have predicted target sites in endogenous genes and transposable elements, a small proportion appears to have targets in planta, suggesting potential cross-kingdom RNA transfer between powdery mildew fungi and their respective plant hosts.     

Omnipotent RNA

The capability of polyribonucleotide chains to form unique, compactly folded structures is considered the basis for diverse non-genetic functions of RNA, including the function of recognition of various ligands and the catalytic function. Together with well-known genetic functions of RNA – coding and complementary replication – this has led to the concept of the functional omnipotence of RNA and the hypothesis that an ancient RNA world supposedly preceded the contemporary DNA–RNA–protein life. It is proposed that the Woese universal precursor in the ancient RNA world could be a cell-free community of mixed RNA colonies growing and multiplying on solid surfaces.     

The promise of cryo-EM to explore RNA structural dynamics

Conformational dynamics are essential to macromolecular function. This is certainly true of RNA, whose ability to undergo programmed conformational dynamics is essential to create and regulate complex biological processes. However, methods to easily and simultaneously interrogate both the structure and conformational dynamics of fully functional RNAs in isolation and in complex with proteins have not historically been available. Due to its ability to image and classify single particles, cryogenic electron microscopy (cryo-EM) has the potential to address this gap and may be particularly amenable to exploring structural dynamics within the three-dimensional folds of biologically active RNAs. We discuss the possibilities and current limitations of applying cryo-EM to simultaneously study RNA structure and conformational dynamics, and present one example that illustrates this (as of yet) not fully realized potential.     

RNA空间编码探析

RNA空间结构同线性结构一样包含着重要的生物信息。RNA空间编码蕴含了RNA功能信息。RNA空间编码具有简并性、通用性、动态性、重叠性、间隔性和方向性等性质。本文对RNA空间编码的概念和性质进行了初步探讨。     

RNA polymerase II acts as an RNA‐dependent RNA polymerase to extend and destabilize a non‐coding RNA

RNA polymerase II (Pol II) is a well‐characterized DNA‐dependent RNA polymerase, which has also been reported to have RNA‐dependent RNA polymerase (RdRP) activity. Natural cellular RNA substrates of mammalian Pol II, however, have not been identified and the cellular function of the Pol II RdRP activity is unknown. We found that Pol II can use a non‐coding RNA, B2 RNA, as both a substrate and a template for its RdRP activity. Pol II extends B2 RNA by 18 nt on its 3′‐end in an internally templated reaction. The RNA product resulting from extension of B2 RNA by the Pol II RdRP can be removed from Pol II by a factor present in nuclear extracts. Treatment of cells with α‐amanitin or actinomycin D revealed that extension of B2 RNA by Pol II destabilizes the RNA. Our studies provide compelling evidence that mammalian Pol II acts as an RdRP to control the stability of a cellular RNA by extending its 3′‐end.     

Functional roles of non-coding Y RNAs

Non-coding RNAs are involved in a multitude of cellular processes but the biochemical function of many small non-coding RNAs remains unclear. The family of small non-coding Y RNAs is conserved in vertebrates and related RNAs are present in some prokaryotic species. Y RNAs are also homologous to the newly identified family of non-coding stem-bulge RNAs (sbRNAs) in nematodes, for which potential physiological functions are only now emerging. Y RNAs are essential for the initiation of chromosomal DNA replication in vertebrates and, when bound to the Ro60 protein, they are involved in RNA stability and cellular responses to stress in several eukaryotic and prokaryotic species. Additionally, short fragments of Y RNAs have recently been identified as abundant components in the blood and tissues of humans and other mammals, with potential diagnostic value. While the number of functional roles of Y RNAs is growing, it is becoming increasingly clear that the conserved structural domains of Y RNAs are essential for distinct cellular functions. Here, we review the biochemical functions associated with these structural RNA domains, as well as the functional conservation of Y RNAs in different species. The existing biochemical and structural evidence supports a domain model for these small non-coding RNAs that has direct implications for the modular evolution of functional non-coding RNAs.