Inhibitor of apoptosis is an effective target gene for RNAi-mediated control of Colorado potato beetle,Leptinotarsa decemlineata

The Colorado potato beetle (CPB; Leptinotarsa decemlineata) is one of the most notorious and difficult to control pests of potato and other solanaceous crops in North America. This insect has evolved a remarkable ability to detoxify both plant and synthetic toxins, allowing it to feed on solanaceous plants containing toxic alkaloids and to develop resistance to synthetic chemicals used for its control. RNA interference (RNAi) is a natural mechanism that evolved as an immune response to double-stranded RNA (dsRNA) viruses where dsRNA triggers silencing of target gene expression. RNAi is being developed as a method to control CPB. Here, we evaluated four CPB-specific genes to identify targets for RNAi-mediated control of this insect. Out of the four dsRNAs evaluated in CPB larvae and adults, dsIAP (dsRNA targeting inhibitor of apoptosis, iap gene) performed better than dsActin, dsHSP70, and dsDynamin in inducing larval mortality. However, in adults, the mortality induced by dsActin is significantly higher than the mortality induced by dsIAP, dsHSP70, and dsDynamin. Interestingly, a combination of dsIAP and dsActin performed better than either dsIAP or dsActin alone by inducing feeding inhibition in 24 hr and mortality in 48 hr in larvae. When the dsIAP and dsActin were expressed in the Escherichia coli HT115 strain and applied as a heat-killed bacterial spray on potato plants, it protected the plants from CPB damage. These studies show that the combination of dsIAP and dsActin shows promise as an insecticide to control CPB.     

Feasibility,limitation and possible solutions of RNAi‐based technology for insect pest control

Abstract Numerous studies indicate that target gene silencing by RNA interference (RNAi) could lead to insect death. This phenomenon has been considered as a potential strategy for insect pest control, and it is termed RNAi‐mediated crop protection. However, there are many limitations using RNAi‐based technology for pest control, with the effectiveness target gene selection and reliable double‐strand RNA (dsRNA) delivery being two of the major challenges. With respect to target gene selection, at present, the use of homologous genes and genome‐scale high‐throughput screening are the main strategies adopted by researchers. Once the target gene is identified, dsRNA can be delivered by micro‐injection or by feeding as a dietary component. However, micro‐injection, which is the most common method, can only be used in laboratory experiments. Expression of dsRNAs directed against insect genes in transgenic plants and spraying dsRNA reagents have been shown to induce RNAi effects on target insects. Hence, RNAi‐mediated crop protection has been considered as a potential new‐generation technology for pest control, or as a complementary method of existing pest control strategies; however, further development to improve the efficacy of protection and range of species affected is necessary. In this review, we have summarized current research on RNAi‐based technology for pest insect management. Current progress has proven that RNAi technology has the potential to be a tool for designing a new generation of insect control measures. To accelerate its practical application in crop protection, further study on dsRNA uptake mechanisms based on the knowledge of insect physiology and biochemistry is needed.     

植物介导的害虫RNA干扰

摘要: 应用植物介导的昆虫RNAi进行害虫防治近10年来受到了广泛的关注,其作用机理包括两个阶段,首先是害虫靶标基因dsRNA在植物体内的表达、运输和贮存,然后是害虫取食该植物后,dsRNA特异性抑制害虫体内靶标基因的表达。目前,植物介导的昆虫RNAi主要针对鳞翅目、鞘翅目和同翅目害虫,可以引起害虫生长发育的异常,导致死亡/繁殖力下降,甚至影响到其子代的生长。影响植物介导昆虫RNAi效率的因素主要包括害虫靶标基因的选择、dsRNA靶定位点及长度、植物表达dsRNA载体的结构和转基因植物的遗传转化方式等。植物介导昆虫RNAi防治害虫的策略也面临着潜在的安全性问题,如转基因植物安全性和RNAi潜在脱靶性等。随着植物介导昆虫RNAi技术的成熟,该方法有望成为害虫防治的新策略。     

Evidence that processed small dsRNAs may mediate sequence-specific mRNA degradation during RNAi in Drosophila embryos

BACKGROUND: RNA interference (RNAi) is a phenomenon in which introduced double-stranded RNAs (dsRNAs) silence gene expression through specific degradation of their cognate mRNAs. Recent analyses in vitro suggest that dsRNAs may be copied, or converted, into 21-23 nucleotide (nt) guide RNAs that direct the nucleases responsible for RNAi to their homologous mRNA targets. Such small RNAs are also associated with gene silencing in plants. RESULTS: We developed a quantitative single-embryo assay to examine the mechanism of RNAi in vivo. We found that dsRNA rapidly induced mRNA degradation. A fraction of dsRNAs were converted into 21-23 nt RNAs, and their time of appearance and persistence correlated precisely with inhibition of expression. The strength of RNAi increased disproportionately with increasing dsRNA length, but an 80bp dsRNA was capable of effective gene silencing. RNAi was saturated at low dsRNA concentration and inhibited by excess unrelated dsRNA. The antisense strand of the dsRNA determined target specificity, and excess complementary sense or antisense single-stranded RNAs (ssRNAs) competed with the RNAi reaction. CONCLUSIONS: Processed dsRNAs can act directly to mediate RNAi, with the antisense strand determining mRNA target specificity. The involvement of 21-23 nt RNAs is supported by the kinetics of the processing reaction and the observed size dependence. RNAi depends on a limiting factor, possibly the nuclease that generates the 21-23 mer species. The active moiety appears to contain both sense and antisense RNA strands.     

Enzymatic production and expression of shRNAmir30 from cDNAs

RNA interference (RNAi) is an important tool for studying gene function and genetic networks. Double-stranded RNA (dsRNA) triggers RNAi that selectively silences gene expression mainly by degrading target mRNA sequences. Short interfering RNA, short hairpin RNA (shRNA), long dsRNA, and microRNA-based shRNA (shRNAmir) are four different types of dsRNA that have been widely used to silence gene expression in cultured cells, tissues, organs, and organisms. Long dsRNAs are usually 200–500 nucleotides in length and can selectively suppress expression of target genes in Caenorhabditis elegans and Drosophila but not in mammals due to unwanted non-specific knockdown. Thus, multiple attempts have been made to synthesize, express, and deliver short dsRNAs that specifically silence target genes in mammals. We describe a method for constructing an RNAi library by converting cDNAs into shRNAmir30 sequences by sequential treatment with different enzymes and affinity purification of biotin- or digoxygenin-labeled DNA fragments. We also developed a system to generate stable cell lines that uniformly express shRNAmir30s and fluorescence reporters by Cre recombinase-dependent site-specific recombination. Thus, combined with the RNAi library, this system facilitates screening for potent RNAi sequences that strongly suppress expression of target genes.     

Specific and nontoxic silencing in mammalian cells with expressed long dsRNAs

A number of groups have developed libraries of siRNAs to identify genes through functional genomics. While these studies have validated the approach of making functional RNAi libraries to understand fundamental cellular mechanisms, they require information and knowledge of existing sequences since the RNAi sequences are generated synthetically. An alternative strategy would be to create an RNAi library from cDNA. Unfortunately, the complexity of such a library of siRNAs would make screening difficult. To reduce the complexity, longer dsRNAs could be used; however, concerns of induction of the interferon response and off-target effects of long dsRNAs have prevented their use. As a first step in creating such libraries, long dsRNA was expressed in mammalian cells. The 250 nt dsRNAs were capable of efficiently silencing a luciferase reporter gene that was stably transfected in MDA-MB-231 cells without inducing the interferon response or off-target effects any more than reported for siRNAs. In addition, a long dsRNA expressed in the same cell line was capable of silencing endogenous c-met expression and inhibited cell migration, whereas the dsRNA against luciferase had no effect on c-met or cell migration. The studies suggest that large dsRNA libraries are feasible and that functional selection of genes will be possible.     

小菜蛾抑制性谷氨酸受体的RNA干扰

谷氨酸门控的氯离子通道（glutamate-gated chloride channels, GluCls）或抑制性谷氨酸受体（inhibitory glutamate receptor, IGluR）是阿维菌素类药剂（avermectins）主要的作用靶标, 目前人们对于昆虫的IGluR知之甚少。本实验采用RNA干扰（RNAi）技术对小菜蛾Plutella xylostella IGluR的功能进行了初步研究。结果表明： 小菜蛾2龄和3龄幼虫中双链RNA（dsRNA）的最佳注射量分别为50.6 nL和71.3 nL。实时荧光定量（quantitative real-time PCR, qRT-PCR）检测结果表明, 2龄和3龄幼虫在注射dsRNA 36 h和24 h后IGluR基因的转录后水平分别下降了32.67%和49.30%。幼虫发生RNA干扰后对阿维菌素的敏感性结果显示, 注射了IGluR dsRNA的幼虫死亡率显著低于对照。结果说明, 小菜蛾IGluR是阿维菌素的潜在靶标之一, 为进一步阐明小菜蛾对阿维菌素靶标抗性机理奠定了基础。     

Characterizing the Mechanism of Action of Double-Stranded RNA Activity against Western Corn Rootworm (Diabrotica virgifera virgifera LeConte)

RNA interference (RNAi) has previously been shown to be effective in western corn rootworm (WCR, Diabrotica virgifera virgifera LeConte) larvae via oral delivery of synthetic double-stranded RNA (dsRNA) in an artificial diet bioassay, as well as by ingestion of transgenic corn plant tissues engineered to express dsRNA. Although the RNAi machinery components appear to be conserved in Coleopteran insects, the key steps in this process have not been reported for WCR. Here we characterized the sequence of events that result in mortality after ingestion of a dsRNA designed against WCR larvae. We selected the Snf7 ortholog (DvSnf7) as the target mRNA, which encodes an essential protein involved in intracellular trafficking. Our results showed that dsRNAs greater than or equal to approximately 60 base-pairs (bp) are required for biological activity in artificial diet bioassays. Additionally, 240 bp dsRNAs containing a single 21 bp match to the target sequence were also efficacious, whereas 21 bp short interfering (si) RNAs matching the target sequence were not. This result was further investigated in WCR midgut tissues: uptake of 240 bp dsRNA was evident in WCR midgut cells while a 21 bp siRNA was not, supporting the size-activity relationship established in diet bioassays. DvSnf7 suppression was observed in a time-dependent manner with suppression at the mRNA level preceding suppression at the protein level when a 240 bp dsRNA was fed to WCR larvae. DvSnf7 suppression was shown to spread to tissues beyond the midgut within 24 h after dsRNA ingestion. These events (dsRNA uptake, target mRNA and protein suppression, systemic spreading, growth inhibition and eventual mortality) comprise the overall mechanism of action by which DvSnf7 dsRNA affects WCR via oral delivery and provides insights as to how targeted dsRNAs in general are active against insects.     

四种鳞翅目害虫精氨酸激酶基因的表达谱及基于RNAi的功能分析

【目的】精氨酸激酶(arginine kinase, AK)(EC 2.7.3.3)是昆虫体内重要的磷酸原激酶(能量代谢调节因子),也是唯一能够形成有效ATP的磷酰基供体,起着与脊椎动物中肌酸激酶相同的作用。本研究旨在了解鳞翅目害虫AK基因的表达和功能。【方法】利用qRT-PCR方法测定AK基因在大螟Sesamia inferens、二化螟Chilo suppressalis、甜菜夜蛾Spodoptera exigua和斜纹夜蛾Spodoptera litura 这4种鳞翅目害虫不同发育阶段和3龄幼虫不同组织中的表达谱;通过终点法检测了这4种害虫不同发育阶段和幼虫不同组织中的AK酶活性;采用RNAi技术抑制该基因的表达并分析其功能。【结果】AK基因在大螟、二化螟、甜菜夜蛾和斜纹夜蛾这4种鳞翅目昆虫的不同发育阶段和3龄幼虫不同组织中均有表达,说明该基因的表达不具有发育时期和组织特异性。不同发育时期和3龄幼虫不同组织中AK酶活性与基因表达量变化趋势大体一致。注射以AK基因为靶标的dsRNA 6 d后,4种害虫体内AK基因的mRNA表达下降30%~50%,AK酶活性降低30%左右;14 d后幼虫的死亡率达50%左右,显著高于对照组幼虫的死亡率。【结论】AK基因在上述4种鳞翅目害虫中为组成型表达,RNAi抑制AK基因的表达可导致4种害虫的幼虫死亡,研究结果为开发以AK基因为靶标的鳞翅目害虫防治新技术提供了理论依据。     

Double-stranded RNAs targeting inhibitor of apoptosis gene show no significant cross-species activity

RNA interference (RNAi) has become an integral part of mainstream research due to its versatility and ease of use. However, the potential nontarget effects associated with double-stranded RNAs (dsRNA) are poorly understood. To explore this, we used dsRNAs targeting the inhibitor of apoptosis (iap) gene from nine insect species and assayed their possible nontarget effects. For each assay, we used a control (dsRNA targeting the gene coding for green fluorescent protein, GFP) and a species-specific dsRNA targeting nine iap genes in insect species to evaluate target gene knockdown efficiency, apoptosis phenotype in cells and mortality in insects. Our results revealed that dsIAP efficiently knocks down iap gene expression and induces apoptosis phenotype and mortality in target insect species. In contrast, no significant knockdown of the iap gene expression, apoptosis phenotypes, or mortality were detected in cell lines developed from nontarget insects or nontarget insects treated with dsIAPs. Interestingly, even among closely related insects such as stink bugs, Nezara viridula, Halyomorpha halys, and Murgantia histrionica, with substantial sequence similarity among iap genes from these insects, no significant nontarget effects of dsIAP were observed under the conditions tested. These data demonstrate no significant nontarget effects for dsIAPs and suggest that the threat of nontarget effects of RNAi technology may not be substantial.