Structural insights into the arms race between host and virus along RNA silencing pathways in Arabidopsis thaliana

RNA silencing refers to a conserved sequence‐specific gene‐regulation mechanism mediated by small RNA molecules. In plants, microRNA (miRNA) and small interfering RNA (siRNA) represent two major types of small RNA molecules which play pivotal roles in plant developmental control and antiviral defences. To escape these plant defences, plant viruses have encoded a vast array of viral suppressors of RNA silencing (VSRs) to attack the host antiviral silencing pathway by interfering with small RNA processing, RNA‐induced silencing complex (RISC) assembly, viral mRNA cleavage etc. Transgenic plants expressing distinct VSRs often show developmental aberrations that resemble the phenotype of miRNA‐deficient mutants, implying a potential intrinsic link between VSRs and the miRNA pathway (at least in Arabidopsis thaliana) even though their pathogenic mechanisms remain largely unknown. In this review, we summarise our current structural understandings of the arms race between the host and virus along the RNA silencing pathway in A. thaliana by focusing on several important ribonucleoprotein (RNP) structures involved in RNA silencing and unique structural features adopted by VSRs.     

Virus‐induced gene silencing in transgenic plants: transgene silencing and reactivation associate with two patterns of transgene body methylation

We used bisulfite sequencing to study the methylation of a viral transgene whose expression was silenced upon plum pox virus infection of the transgenic plant and its subsequent recovery as a consequence of so‐called virus‐induced gene silencing (VIGS). VIGS was associated with a general increase in the accumulation of small RNAs corresponding to the coding region of the viral transgene. After VIGS, the transgene promoter was not methylated and the coding region showed uneven methylation, with the 5′ end being mostly unmethylated in the recovered tissue or mainly methylated at CG sites in regenerated silenced plants. The methylation increased towards the 3′ end, which showed dense methylation in all three contexts (CG, CHG and CHH). This methylation pattern and the corresponding silenced status were maintained after plant regeneration from recovered silenced tissue and did not spread into the promoter region, but were not inherited in the sexual offspring. Instead, a new pattern of methylation was observed in the progeny plants consisting of disappearance of the CHH methylation, similar CHG methylation at the 3′ end, and an overall increase in CG methylation in the 5′ end. The latter epigenetic state was inherited over several generations and did not correlate with transgene silencing and hence virus resistance. These results suggest that the widespread CG methylation pattern found in body gene bodies located in euchromatic regions of plant genomes may reflect an older silencing event, and most likely these genes are no longer silenced.     

RNA silencing movement in plants

Multicellular organisms, like higher plants, need to coordinate their growth and development and to cope with environmental cues. To achieve this, various signal molecules are transported between neighboring cells and distant organs to control the fate of the recipient cells and organs. RNA silencing produces cell non-autonomous signal molecules that can move over short or long distances leading to the sequence specific silencing of a target gene in a well defined area of cells or throughout the entire plant,respectively. The nature of these signal molecules, the route of silencing spread, and the genes involved in their production, movement and reception are discussed in this review. Additionally, a short section on features of silencing spread in animal models is presented at the end of this review.     

RNA-dependent RNA polymerase 6 is required for efficient hpRNA-induced gene silencing in plants

In plants, transgenes with inverted repeats are used to induce efficient RNA silencing, which is also frequently induced by highly transcribed sense transgenes. RNA silencing induced by sense transgenes is dependent on RNA-dependent RNA polymerase 6 (RDR6), which converts single-stranded (ss) RNA into double-stranded (ds) RNA. By contrast, it has been proposed that RNA silencing induced by self-complementary hairpin RNA (hpRNA) does not require RDR6, because the hpRNA can directly fold back on itself to form dsRNA. However, it is unclear whether RDR6 plays a role in hpRNA-induced RNA silencing by amplifying dsRNA to spread RNA silencing within the plant. To address the efficiency of hpRNA-induced RNA silencing in the presence or absence of RDR6, Wild type (WT, Col-0) and rdr6-11 Arabidopsis thaliana lines expressing green fluorescent protein (GFP) were generated and transformed with a GFP-RNA interference (RNAi) construct. Whereas most GFP-RNAi-transformed WT lines exhibited almost complete silencing of GFP expression in the T1 generation, various levels of GFP expression remained among the GFP-RNAi-transformed rdr6-11 lines. Homozygous expression of GFP-RNAi in the T3 generation was not sufficient to induce complete GFP silencing in several rdr6-11 lines. Our results indicate that RDR6 is required for efficient hpRNA-induced RNA silencing in plants.     

Spontaneous short-range silencing of a GFP transgene in Nicotiana benthamiana is possibly mediated by small quantities of siRNA that do not trigger systemic silencing

A green fluorescent protein (GFP) transgene under the control of the 35S cauliflower mosaic virus (CaMV) promoter was introduced by Agrobacterium-mediated transformation into Nicotiana benthamiana to generate fourteen transgenic lines. Homozygous lines that contained one or two copies of the transgene showed great variation of GFP expression under ultraviolet (UV) light, which allowed classification into three types of transgenic plants. Plants from more than half of the transgenic lines underwent systemic RNA silencing and produced short interfering RNA (siRNA) as young seedlings, while plants of the remaining lines developed, in a spontaneous manner, defined GFP-silenced zones on their leaves, mostly in the form of circular spots that expanded to about 4-7 mm in size. In some of the latter lines, the GFP-silenced spots remained stable, but no systemic silencing occurred. Here we characterize this phenomenon, which we term spontaneous short-range silencing (SSRS). Biochemical analysis of silenced spot tissue did not reveal detectable levels of siRNA. However, agro-infiltration with the suppressor proteins P19 of cymbidium ring spot virus (CymRSV), HC-Pro of tobacco etch virus (TEV), and crosses to a P19 transgenic line, nevertheless suggests that low concentrations of siRNA may have a functional role in the locally silenced zone. We propose that small alterations in the steady-state concentration of siRNAs and their cognate mRNA are decisive with regard to whether silencing remains local or spreads in a systemic manner.     

RNA干扰机制的研究进展

RNA干扰(RNAi)广泛存在于各种生物体中,是参与细胞防御与分化调控的重要机制之一。RNAi的作用由双链RNA启动,通过在转录、转录后和翻译等多个水平上对同源基因表达的特异阻断和抑制来实现,清晰地阐明其作用机制将为功能基因组学、发育生物学,以及抗肿瘤、抗病毒的新策略研究提供重要的理论依据。本文综述了近年来有关RNAi机制的研究进展。     

RNA沉默与植物病毒

植物中RNA沉默（RNAsilencing)亦称为转录后基因沉默（PTGS）或共抑制,是植物抵抗外来核酸（转座子、转基因或病毒）入侵,并保护自身基因组完整性的一种防御机制。RNA沉默是近十年来发现的植物界中普遍存在的现象,已成为植物分子生物学领域的一个新的研究方向。对RNA沉默特点和机制的研究表明,植物病毒与（转基因）植物内发生的RNA沉默有着密切的联系,作者从病毒对RNA沉默的诱导、抑制、防御等方面,简述了RNA沉默与病毒的关系。并对病毒载体所诱导的RNA沉默在植物发育和基因组功能分析等方面的应用价值进行了讨论。     

RNA干扰与基因敲除

RNAi是指通过双链RNA介导特异性降解靶mRNA,导致转录后水平基因沉默的现象。其作用途径有RdRP依赖的RNAi的途径与非RdRP依赖的RNAi途径2种。利用RNAi的基因敲除技术在dsRNA序列选择、质粒或病毒为载体的dsRNA体内合成、发夹样siRNA的转录、dsRNA的导入方法等方面取得了很大进展,在研究人类或其他生物基因组中未知基因及蛋白质的功能等领域具有诱人的应用前景。     

RNA沉默在分析植物基因功能方面的研究

RNA沉默是真核生物的一种高度保守的和序列特异的RNA降解系统,它不但是基础生物学领域的研究热点,同时在调节基因表达或研究基因功能方面也是非常有前景的。植物中的转录后基因沉默（PTGS）是RNA沉默的一种形式,通过PTGS能对目标RNA进行特异性降解。对双链RNA（dsRNA）在RNA沉默启动中所起中心作用的认知,形成了几种RNA沉默载体的构建方法,这些方法与基因组资源相结合,通过转基因或非转基因的方法能够快速和高效研究植物的基因功能。     

RNA interference: the story of gene silencing in plants and humans

RNA interference is an exciting field of functional genomics that can silence viral genes. This property of interfering RNA can be used to combat viral diseases of plants as well as animals and humans. It is a short sequence of nucleic acid that can bind to the mRNA of the gene and interferes the process of its expression. It is diverse in occurrence as well as in applications. It occurs from nematodes to fungi and can cause gene silencing in plants, animals and human beings. Small interfering RNAs are used to silence plant viral genes and in production of therapeutic drugs against Hepatitis or Immuno-deficiency viruses in human. In this review, we will discuss the history, mechanism and applications of RNA interference in plant, animal and human research.     

植物RNA沉默的分子机制研究进展

RNA沉默（RNA silencing）是真核生物中的一种抵抗外源遗传因子（病毒、转座子或转基因）及调控基凶表达的防御机制。参与植物RNA沉默的酶及蛋白质主要包括6种RNA依赖的RNA聚合酶、4种Dicer-like（DCL）核酸内切酶和10种Argonautes蛋白。植物中4条RNA沉默途径分别由微小RNA（miRNAs）和3种小干扰RNA（siRNAs）介导,包括反式作用siRNAs（ta－siRNAs）、天然反义siRNAs（natsiRNAs）和异染色质siRNAs（hc-siRNAs）。在植物RNA沉默的系统性传播中,由DCL4或DCL2将dsRNAs裁剪为次级SiRNAS,以放大RNA沉默信号和增强沉默效应。     

Virus-induced gene silencing in plants

Virus-induced gene silencing (VIGS) is a technology that exploits an RNA-mediated antiviral defense mechanism. In plants infected with unmodified viruses the mechanism is specifically targeted against the viral genome. However, with virus vectors carrying inserts derived from host genes the process can be additionally targeted against the corresponding mRNAs. VIGS has been used widely in plants for analysis of gene function and has been adapted for high-throughput functional genomics. Until now most applications of VIGS have been in Nicotiana benthamiana. However, new vector systems and methods are being developed that could be used in other plants, including Arabidopsis. Here we discuss practical and theoretical issues that are specific to VIGS rather than other gene "knock down" or "knockout" approaches to gene function. We also describe currently used protocols that have allowed us to apply VIGS to the identification of genes required for disease resistance in plants. These methods and the underlying general principles also apply when VIGS is used in the analysis of other aspects of plant biology.