RNAi shows potential as an agricultural technology for insect control, yet, a relatively low number of robust lethal RNAi targets have been demonstrated to control insects of agricultural interest. In the current study, a selection of lethal RNAi target genes from the iBeetle (Tribolium castaneum) screen were used to demonstrate efficacy of orthologous targets in the economically important coleopteran pests Diabrotica virgifera virgifera and Meligethes aeneus. Transcript orthologs of 50 selected genes were analyzed in D. v. virgifera diet-based RNAi bioassays; 21 of these RNAi targets showed mortality and 36 showed growth inhibition. Low dose injection- and diet-based dsRNA assays in T. castaneum and D. v. virgifera, respectively, enabled the identification of the four highly potent RNAi target genes: Rop, dre4, ncm, and RpII140. Maize was genetically engineered to express dsRNA directed against these prioritized candidate target genes. T0 plants expressing Rop, dre4, or RpII140 RNA hairpins showed protection from D. v. virgifera larval feeding damage. dsRNA targeting Rop, dre4, ncm, and RpII140 in M. aeneus also caused high levels of mortality both by injection and feeding. In summary, high throughput systems for model organisms can be successfully used to identify potent RNA targets for difficult-to-work with agricultural insect pests.
Transgenic maize plants expressing dsRNA targeting western corn rootworm (WCR, Diabrotica virgifera virgifera LeConte) v‐ATPase subunit C mRNA for RNAi provided significant root protection from WCR larval feeding damage in greenhouse assays compared to negative controls. Transcribed hairpin dsRNA in WCR‐resistant maize plants was present as both intact hairpin‐derived dsRNA and plant‐processed siRNA. Therefore, the ability of dsRNA and siRNA targeting Dv v‐ATPase CmRNA to cause an RNAi response was studied in both WCR larvae and adults. In 9‐day diet‐based feeding assays, dsRNA of at least 60 bp in length resulted in high levels of larval mortality. In contrast, 15‐, 25‐ or 27‐bp dsRNAs or pooled 21‐bp siRNAs did not cause mortality of exposed larvae. When larvae were fed with diet overlaid with siRNAs, Dv v‐ATPase C transcript levels did not change. Conversely, when WCR larvae were fed with diet overlaid with 184‐bp dsRNA, the mRNA level was reduced by >20‐fold relative to yfp dsRNA negative control. Similarly, 184‐bp dsRNA caused 100% mortality of WCR adults, whereas the mortality of adults fed on diet treated with siRNAs was similar to the negative control. Feeding adults with siRNAs on diet did not affect the level of Dv v‐ATPase CmRNA transcripts, whereas adults fed with the 184‐bp dsRNA showed approximately 35‐fold reduction in the target mRNA level. Similar results were obtained with the WCR adults injected with 184‐bp dsRNA or 21‐bp siRNA. These results suggest that only long dsRNA or hairpin‐derived dsRNA is effective in causing lethal knock‐down of Dv v‐ATPase CmRNA. These results have implications for efficacious plant‐delivered dsRNA for the protection of transgenic maize from WCR feeding damage and for the risk assessment of transgenic maize expressing insecticidal dsRNA.
"Parental RNA interference of genes involved in embryonic development of the western corn rootworm, Diabrotica virgifera virgifera LeConte" (2015). Faculty Publications: Department of Entomology. 420.
Western corn rootworm (WCR, Diabrotica virgifera virgifera LeConte) is highly sensitive to orally delivered double-stranded RNA (dsRNA). RNAi in WCR is systemic and spreads throughout the insect body. This raises the question whether transitive RNAi is a mechanism that functions in WCR to amplify the RNAi response via production of secondary siRNA. Secondary siRNA production is achieved through RNA-dependent RNA polymerase (RdRP) activity in other eukaryotic organisms, but RdRP has not been identified in WCR and any other insects. This study visualized the spread of the RNAi-mediated knockdown of Dv v-ATPase C mRNA throughout the WCR gut and other tissues using high-sensitivity branched DNA in situ hybridization. Furthermore, we did not detect either secondary siRNA production or transitive RNAi in WCR through siRNA sequence profile analysis. Nucleotide mismatched sequences introduced into either the sense or antisense strand of v-ATPase C dsRNAs were maintained in siRNAs derived from WCR fed with the mismatched dsRNAs in a strand specific manner. The distribution of all siRNAs was restricted to within the original target sequence regions, which may indicate the lack of new dsRNA synthesis leading to production of secondary siRNA. Thus, the systemic spread of RNAi in WCR may be derived from the original dsRNA molecules taken up from the gut lumen. These results indicate that the initial dsRNA dose is important for a lethal systemic RNAi response in WCR and have implications in developing effective dsRNA traits to control WCR and in resistance management to prolong the durability of RNAi trait technology.
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