病毒诱导的基因沉默及其在植物基因功能研究中的应用

RNA介导的基因沉默是近年来在生物体中发现的一种基于核酸水平高度保守的特异性降解机制.病毒诱导的基因沉默（virus induced gene silencing, VIGS）是指携带植物功能基因cDNA的病毒在侵染植物体后,可诱导植物发生基因沉默而出现表型突变,进而可以研究该目的基因功能.至今,已经建立了以RNA病毒、DNA病毒、卫星病毒和DNA卫星分子为载体的VIGS体系,这些病毒载体能在多种寄主植物（包括拟南芥、番茄和大麦）上有效抑制功能基因的表达.VIGS已开始应用于N基因和Pto基因介导的抗性信号途径中关键基因的功能研究、抗病毒相关的寄主因子研究以及植物代谢和发育调控研究.在当前植物基因组或EST序列大量测定的情况下,VIGS为植物基因功能鉴定提供了有效的技术平台.     

植物基因功能鉴定新工具--病毒诱导基因沉默技术的研究进展

病毒诱导基因沉默（Virus—induced gene silencing,VIGS）技术是指带一段靶基因序列的VIGS重组病毒侵染植物、引起植物同源基因沉默与表型变异,进而通过表型变异进行基因功能分析的方法,是近年发展起来的从反向遗传学方向快速鉴定植物基因功能的技术,是转录后基因沉默机制的一种表现。①VIGS的分子机制,涉厦基因沉默的起始、维持和信号放大、传播共3个阶段;②VIGS技术、栽体与方法学的发展;③VIGS作为基因功能研究的优越性,如不必进行转基因、操作方法简便、获得结果快速等;④应用VIGS对植物抗病途径、代谢与发育调控中参与基因功能进行研究的概况。同时。展望了VIGS技术作为植物功能基因组学功能分析的高通量技术平台的美好前景。     

病毒诱导的基因沉默技术及其在植物中的研究进展

病毒诱导的基因沉默(virus-induced gene silencing,VIGS)是近年来发现的一种转录后基因沉默现象,是植物抵抗病毒侵染的一种自然机制。现已被开发为快速鉴定植物基因功能的一种反向遗传学新技术。与传统的植物转基因技术相比,VIGS无需构建转基因植株,而且具有操作简便、获得表型快速等优点,目前已广泛应用于与植物抗病、逆境胁迫、细胞信号转导以及生长发育等相关基因功能的研究。该文就VIGS技术的作用机理、主要操作规程、在植物基因功能研究方面的应用以及存在的问题进行综述。     

植物生理与分子生物学

主要从病毒诱导的基因沉默体系中植物与病毒的相互作用、VIGS涉及的信号分子和移动方式以及靶基因的沉默和病毒载体的复制关系介绍和分析植物病毒诱导的基因沉默效应的分子机制,并进一步分析此种体系在植物基因功能研究中应用的研究进展。     

植物中病毒诱导基因沉默的研究进展

研究表明TGS往往与目的基因启动子的甲基化密切相关,RNA沉默则由目的基因的mRNA特异,挫降解引起。植物体中诱导RNA沉默的外部因素有转基因和病毒。与传统的转基因技术相比,病毒诱导的基因沉默（Virus-induced gene silencing VIGS）是一种瞬时表达体系,能在较短的时间里取得良好的效果,目前被广泛地用来研究植物基因的功能。就VIGS的研究进展做一个比较全面的综述。阐述了DNA和RNA病毒诱导植物基因沉默的机理,同时讨论了利用病毒诱导的基因沉默（VIGS）鉴定植物基因功能的优缺点和将来的发展趋势。     

植物病毒诱导的基因沉默效应的分子机制

主要从病毒诱导的基因沉默体系中植物与病毒的相互作用、VIGS涉及的信号分子和移动方式以及靶基因的沉默和病毒载体的复制关系介绍和分析植物病毒诱导的基因沉默效应的分子机制,并进一步分析此种体系在植物基因功能研究中应用的研究进展。     

病毒诱导的基因沉默及其在植物功能基因组研究中的应用

病毒诱导的基因沉默已成为研究植物功能基因组的重要工具. VIGS 体系因其方法简便、周期性短以及避免植物转化等诸多优点, 已在利用正向遗传学和反向遗传学寻找和鉴定基因功能方面发挥了日益重要的作用. 越来越多的植物病毒被改造成为VIGS 载体, 并已在植物发育、生物逆境、非生物逆境、细胞代谢、信号传导等基因功能研究方面得到了应用. 本文围绕VIGS的发展以及在植物功能基因鉴定中的应用及前景提出了展望.     

植物RNA沉默抗病机制与应用研究进展

RNA沉默是真核生物基因表达调控的保守机制,在植物生长发育以及响应生物和非生物胁迫过程中发挥着非常重要的作用。跨界RNA沉默与种间RNA沉默为开发基于RNA沉默的作物病害防控体系提供了理论基础。本文概括了植物RNA沉默保守途径,归纳了RNA沉默在植物-病原互作研究中的代表性研究,阐述了基于RNA沉默开发的宿主诱导基因沉默、喷施诱导基因沉默和微生物诱导基因沉默技术的原理,以及应用研究现状,以期为开发基于RNA沉默的新型作物病害防控技术提供参考。     

植物病毒诱导的基因沉默在基因功能研究中的应用

传统的植物遗传转化方法周期长、工作量大、过程繁琐,不利于基因功能的快速高通量鉴定．近年来随着基因沉默机制研究的深入和不断发展,利用病毒诱导的基因沉默(Virus induced gene silencing,VIGS)进行植物功能基因组研究作为一种快速、高通量的反向遗传学工具已被广泛应用在烟草、马铃薯、番茄等植物中, 在大规模的植物基因组功能鉴定中展示了广阔的应用前景．综述了 VIGS 的作用机制、植物病毒栽体、转化方法以及在植物基因功能研究等方面的应用及前景．     

用卫星DNA沉默载体研究植物矿质营养相关的基因：以沉默番茄的高铁还原酶基因FR01为例

病毒诱导的基因沉默（VIGS）是近年来发展的一种研究植物基因功能的新技术．至今尚不明确这种新技术是否能够有效地沉默植物根系中与矿质营养相关的基因．本研究中,以根系高铁还原酶基因FR01为例,探讨了一种改进的卫星DNA沉默载体（DNAmβ）在研究与根系矿质营养相关的基因功能中的适用性．将番茄的铁还原酶基因FRO1的cDNA片段插入到DNAmβ载体中,构建了FRO1基因的沉默载体,并利用农杆菌介导法和辅助病毒中国番茄黄化曲叶病毒一起接种番茄．结果表明,缺铁番茄根系的FROImRNA水平显著降低,同时,铁还原酶活性也明显降低,上述结果证明了VIGS技术可以用来研究植物根系中与矿质营养相关的基因功能。     

Agrodrench: a novel and effective agroinoculation method for virus-induced gene silencing in roots and diverse Solanaceous species

Summary Virus-induced gene silencing (VIGS) is an extremely powerful tool for plant functional genomics. We used Tobacco rattle virus (TRV)-derived VIGS vectors expressed from binary vectors within Agrobacterium to induce RNA silencing in plants. Leaf infiltration is the most common method of agroinoculation used for VIGS but this method has limitations as it is laborious for large-scale screening and some plants are difficult to infiltrate. Here we have developed a novel and simple method of agroinoculation, called 'agrodrench', where soil adjacent to the plant root is drenched with an Agrobacterium suspension carrying the TRV-derived VIGS vectors. By agrodrench we successfully silenced the expression of phytoene desaturase (PDS), a 20S proteasome subunit (PB7) or Mg-protoporphyrin chelatase (Chl H) encoding genes in Nicotiana benthamiana and in economically important crops such as tomato, pepper, tobacco, potato, and Petunia, all belonging to the Solanaceae family. An important aspect of agrodrench is that it can be used for VIGS in very young seedlings, something not possible by the leaf infiltration method, which usually requires multiple fully expanded leaves for infiltration. We also demonstrated that VIGS functioned to silence target genes in plant roots. The agrodrench method of agroinoculation was more efficient than the leaf infiltration method for VIGS in roots. Agrodrench will facilitate rapid large-scale functional analysis of cDNA libraries and can also be applied to plants that are not currently amenable to VIGS technology by conventional inoculation methods.     

Virus-induced gene silencing is an effective tool for assaying gene function in the basal eudicot species Papaver somniferum (opium poppy)

Virus-induced gene silencing (VIGS) is an attractive method for assaying gene function in species that are resistant to conventional genetic approaches. However, VIGS has been shown to be effective in only a few, closely related plant species. Tobacco rattle virus (TRV), a bipartite RNA virus, has a wide host range and so in principle could serve as an efficient vector for VIGS in a diverse array of plant species. Here we show that a vector based on TRV sequences is effective at silencing the endogenous phytoene desaturase (PapsPDS) gene in Papaver somniferum (opium poppy). We show that this vector does not compromise the growth or reproduction of poppy and the plants did not display viral symptoms. The silencing of PapsPDS resulted in a significant reduction in PapsPDS mRNA and a concomitant photobleached phenotype. The ability to rapidly assay gene function in P. somniferum will be valuable in manipulation of the opiate pathway in this pharmaceutically important species. We suggest that our vacuum infiltration method used to deliver TRV-based vectors into poppy is a promising approach for expanding VIGS to diverse angiosperm species in which traditional delivery methods fail to induce VIGS. Furthermore, these studies demonstrate the utility of TRV-VIGS for probing gene function in a basal eudicot species that is phylogenetically distant from model plant species.     

Rapid analysis of Jatropha curcas gene functions by virus-induced gene silencing

Jatropha curcas L. is a small, woody tree of the Euphorbiaceae family. This plant can grow on marginal land in the tropical and subtropical regions and produces seeds containing up to 30% oil. Several Asian countries have selected Jatropha for large scale planting as a biodiesel feedstock. Nevertheless, Jatropha also possesses several undesirable traits that may limit its wide adoption. An improved understanding of plant development and the regulation of fatty acid (FA) and triacylglyceride biosynthesis in Jatropha is particularly facilitative for the development of elite crops. Here, we show that a tobacco rattle virus (TRV) vector can trigger virus-induced gene silencing (VIGS) in Jatropha. Our optimized method produced robust and reliable gene silencing in plants agroinoculated with recombinant TRV harbouring Jatropha gene sequences. We used VIGS to investigate possible functions of 13 Jatropha genes of several functional categories, including FA biosynthesis, developmental regulation and toxin biosynthesis, etc. Based on the effects of VIGS on the FA composition of newly emerged leaves, we determined the function of several genes implicated in FA biosynthesis. Moreover, VIGS was able to discriminate independent functions of related gene family members. Our results show that VIGS can be used for high-throughput screening of Jatropha genes whose functions can be assayed in leaves.     

Virus-induced gene silencing in Solanum species

Virus-induced gene silencing (VIGS) has been used routinely in Nicotiana benthamiana to assess functions of candidate genes and as a way to discover new genes required for diverse pathways, especially disease resistance signalling. VIGS has recently been shown to work in Arabidopsis thaliana and in tomato. Here, we report that VIGS using the tobacco rattle virus (TRV) viral vector can be used in several Solanum species, although the choice of vector and experimental conditions vary depending on the species under study. We have successfully silenced the phytoene desaturase (PDS) gene in the diploid wild species Solanum bulbocastanum and S. okadae, in the cultivated tetraploid S. tuberosum and in the distant hexaploid relative S. nigrum (commonly known as deadly nightshade). To test whether the system could be utilised as a rapid way to assess gene function of candidate resistance (R) genes in potato and its wild relatives, we silenced R1 and Rx in S. tuberosum and RB in S. bulbocastanum. Silencing of R1, Rx and RB successfully attenuated R-gene-mediated disease resistance and resulted in susceptible phenotypes in detached leaf assays. Thus, the VIGS system is an effective method of rapidly assessing gene function in potato.     

A systematic study to determine the extent of gene silencing in Nicotiana benthamiana and other Solanaceae species when heterologous gene sequences are used for virus-induced gene silencing

Virus-induced gene silencing (VIGS) is a rapid and robust method for determining and studying the function of plant genes or expressed sequence tags (ESTs). However, only a few plant species are amenable to VIGS. There is a need for a systematic study to identify VIGS-efficient plant species and to determine the extent of homology required between the heterologous genes and their endogenous orthologs for silencing. Two approaches were used. First, the extent of phytoene desaturase (PDS) gene silencing was studied in various Solanaceous plant species using Nicotiana benthamiana NbPDS sequences. In the second approach, PDS sequences from a wide range of plant species were used to silence the PDS gene in N. benthamiana. The results showed that tobacco rattle virus (TRV)-mediated VIGS can be performed in a wide range of Solanaceous plant species and that heterologous gene sequences from far-related plant species can be used to silence their respective orthologs in the VIGS-efficient plant N. benthamiana. A correlation was not always found between gene silencing efficiency and percentage homology of the heterologous gene sequence with the endogenous gene sequence. It was concluded that a 21-nucleotide stretch of 100% identity between the heterologous and endogenous gene sequences is not absolutely required for gene silencing.