RNA修复研究进展

机体DNA损伤修复的机制目前已研究得比较全面,而RNA损伤修复的研究却没有引起广泛的认识.主要由于人们长期以来认为损伤的RNA会被机体特异性降解而不是修复.近年来,随着多个RNA损伤修复系统的相继发现,揭示机体对损伤RNA可能优先选择进行修复.本文从噬菌体型RNA修复系统、细菌型RNA修复系统、酵母型RNA修复系统和人类的RNA损伤修复系统四个方面对目前RNA损伤修复研究的最新进展做一综述.     

Mammalian RNA virus-derived small RNA: biogenesis and functional activity

The role of virus-derived small RNAs (vsRNAs) has been identified as an antiviral mechanism in plants, arthropods, and nematodes. Although mammalian DNA viruses have been observed to encode functional miRNAs, whether RNA virus infection generates functional vsRNAs remains under discussion. This article reviews the most recent reports regarding pathways for generating vsRNAs and the identified vsRNA activity in mammalian cells infected with RNA viruses. We also discuss several hypotheses regarding the roles of mammalian vsRNAs and comment on the potential directions for this research field.     

A DEAD-box RNA helicase promotes thermodynamic equilibration of kinetically trapped RNA structures in vivo

RNAs must assemble into specific structures in order to carry out their biological functions, but in vitro RNA folding reactions produce multiple misfolded structures that fail to exchange with functional structures on biological time scales. We used carefully designed self-cleaving mRNAs that assemble through well-defined folding pathways to identify factors that differentiate intracellular and in vitro folding reactions. Our previous work showed that simple base-paired RNA helices form and dissociate with the same rate and equilibrium constants in vivo and in vitro. However, exchange between adjacent secondary structures occurs much faster in vivo, enabling RNAs to quickly adopt structures with the lowest free energy. We have now used this approach to probe the effects of an extensively characterized DEAD-box RNA helicase, Mss116p, on a series of well-defined RNA folding steps in yeast. Mss116p overexpression had no detectable effect on helix formation or dissociation kinetics or on the stability of interdomain tertiary interactions, consistent with previous evidence that intracellular factors do not affect these folding parameters. However, Mss116p overexpression did accelerate exchange between adjacent helices. The nonprocessive nature of RNA duplex unwinding by DEAD-box RNA helicases is consistent with a branch migration mechanism in which Mss116p lowers barriers to exchange between otherwise stable helices by the melting and annealing of one or two base pairs at interhelical junctions. These results suggest that the helicase activity of DEAD-box proteins like Mss116p distinguish intracellular RNA folding pathways from nonproductive RNA folding reactions in vitro and allow RNA structures to overcome kinetic barriers to thermodynamic equilibration in vivo.     

Evolution and Diversification of RNA Silencing Proteins in Fungi

Comprehensive phylogenetic analyses of fungal Argonaute, Dicer, and RNA-dependent RNA polymerase-like proteins have been performed to gain insights into the diversification of RNA silencing pathways during the evolution of fungi. A wide range of fungi including ascomycetes, basidiomycetyes, and zygomycetes possesses multiple RNA silencing components in the genome, whereas a portion of ascomycete and basidiomycete fungi apparently lacks the whole or most of the components. The number of paralogous silencing proteins in the genome differs considerably among fungal species, suggesting that RNA silencing pathways have diversified significantly during evolution in parallel with developing the complexity of life cycle or in response to environmental conditions. Interestingly, orthologous silencing proteins from different fungal clades are often clustered more closely than paralogous proteins in a fungus, indicating that duplication events occurred before speciation events. Therefore, the origin of multiple RNA silencing pathways seems to be very ancient, likely having occurred prior to the divergence of the major fungal lineages. Electronic Supplementary Material Electronic Supplementary material is available for this article at and accessible for authorised users. [Reviewing Editor: Dr. Rüdiger Cerff]     

小RNA与蛋白质的相互作用

小分子调控RNA,包括siRNA（small interfering RNA）、miRNA（microRNA）和piRNA（piwiinteracting RNA）、hsRNA（heterochromatin associatedsmall RNA）等,是当前生命科学研究的前沿热点。越来越多的证据表明,这些小分子RNA存在于几乎所有较高等的真核生物细胞中,对生物体具有非常重要的调控功能。它们通过各种序列特异性的RNA基因沉默作用,包括RNA干扰（RNAi）、翻译抑制、异染色质形成等,调控诸如生长发育、应激反应、沉默转座子等各种各样的细胞进程。随着对这些小分子调控RNA的发现,一些RNascⅢ酶家族成员、Argonaute蛋白质家族成员及RNA结合蛋白质等先后被鉴定为小RNA的胞内蛋白质合作者,参与小RNA的加工成熟和在细胞内行使功能。本综述简介一些RNA沉默作用途径中重要组分的结构和功能的研究进展。     

The response of mammalian cells to double-stranded RNA

Double-stranded RNA (dsRNA) has long been recognized as a central component of the interferon (IFN) system. It was originally characterized as a key mediator of IFN induction in response to virus infection. Subsequently, it was identified as a prime activator of the antiviral response. In recent years the discovery of the RNA interference (RNAi) pathway in mammals has renewed interest in dsRNA-mediated cellular responses. This has coincided with the identification of key components of the IFN induction pathway. Here, we present an overview of the current knowledge of dsRNA-mediated pathways in mammalian cells and introduce a link between these pathways and application of RNAi.     

Pathways through the small RNA world of plants

RNA silencing pathways in plants have diversified along with key gene families involved in small RNA biogenesis and effector steps. Evidence suggests that these pathways have distinct roles in plant biology.     

RNA silencing in fungi: mechanisms and applications

Two RNA silencing-related phenomena, quelling and meiotic silencing by unpaired DNA (MSUD) have been identified in the fungus Neurospora crassa. Similar to the case with the siRNA and miRNA pathways in Drosophila, different sets of protein components including RNA-dependent RNA polymerase, argonaute and dicer, are used in the quelling and MSUD pathways. Orthologs of the RNA silencing components are found in most, but not all, fungal genomes currently available in the public databases, indicating that the majority of fungi possess the silencing machinery. Advantage and disadvantage of RNA silencing as a tool to explore gene function in fungi are discussed.     

RNA沉默在植物生物逆境反应中的作用

RNA沉默是真核生物共有的基因表达调节机制和防御机制。在植物RNA沉默中, 一些小RNAs, 如微小 RNAs和小干扰RNAs, 在植物防御病毒、细菌或食草动物的反应中具有重要作用。为了抑制宿主的RNA沉默系统, 植物病毒或细菌进化出了在RNA沉默不同阶段起作用的病毒沉默抑制子或细菌沉默抑制子, 来克服寄主的RNA沉默反应。文章就植物RNA沉默、病毒沉默抑制子、细菌沉默抑制子及其相关防御反应的一些新进展做一概述。     

Potential coexistence of both bacterial and eukaryotic small RNA biogenesis and functional related protein homologs in Archaea

RNA silencing plays crucial roles in both bacteria and eukaryotes, yet its machinery appears to differ in these two kingdoms. A couple of Argonaute protein homologs have been reported in some archaeal species in recent years. As Argonaute protein is the key component of eukaryotic RNA silencing pathways, such findings suggested the possibility of existence of eukaryotic RNA silencing like pathways in Archaea, which present the life forms between prokaryotes and eukaryotes. To further explore such hypothesis, we systematically screened 71 fully sequenced archaeal genomes, and identified some proteins containing homologous regions to the functional domains of eukaryotie RNA silencing pathway key proteins. The phylogenetic relationships of these proteins were analyzed. The conserved time-tional amino acids between archaeal and eukaryotic Piwi domains suggested their functional similarity. Our results provide new clues to the evolution of RNA silencing pathways.     

Biphasic folding kinetics of RNA pseudoknots and telomerase RNA activity

Using a combined master equation and kinetic cluster approach, we investigate RNA pseudoknot folding and unfolding kinetics. The energetic parameters are computed from a recently developed Vfold model for RNA secondary structure and pseudoknot folding thermodynamics. The folding kinetics theory is based on the complete conformational ensemble, including all the native-like and non-native states. The predicted folding and unfolding pathways, activation barriers, Arrhenius plots, and rate-limiting steps lead to several findings. First, for the PK5 pseudoknot, a misfolded 5' hairpin emerges as a stable kinetic trap in the folding process, and the detrapping from this misfolded state is the rate-limiting step for the overall folding process. The calculated rate constant and activation barrier agree well with the experimental data. Second, as an application of the model, we investigate the kinetic folding pathways for human telomerase RNA (hTR) pseudoknot. The predicted folding and unfolding pathways not only support the proposed role of conformational switch between hairpin and pseudoknot in hTR activity, but also reveal molecular mechanism for the conformational switch. Furthermore, for an experimentally studied hTR mutation, whose hairpin intermediate is destabilized, the model predicts a long-lived transient hairpin structure, and the switch between the transient hairpin intermediate and the native pseudoknot may be responsible for the observed hTR activity. Such finding would help resolve the apparent contradiction between the observed hTR activity and the absence of a stable hairpin.     

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.     

非编码RNA和RNA沉默

生物体内存在大量的非编码RNA ,它们形态各异 ,功能也千差万别 ,在生物的生长、发育、分化进程中扮演着不同的角色 ,尤其是siRNA ,它是RNA沉默的诱因。RNA沉默是真核生物特有的现象 ,它需要一系列因子的参与 ,其中RNA依赖性的RNA聚合酶是沉默起始的关键 ,Dicer酶是形成siRNA的基础 ,而RNA沉默诱导复合体 (RSIC)等是发生RNA沉默“链式反应”的关键因子