Oral Delivery of dsRNA Targeting a Female-Biased Flight Muscle Actin Impairs Flight in the Malaria Vector, Anopheles Albimanus

BackgroundDespite the progress to eliminate malaria in Central America, focalized transmission persists, and insecticide resistance is on the rise in the primary vector, Anopheles albimanus. Many of the new control methods being developed depend on the release of a large number of male mosquitoes that must be sorted prior to release. However, An. albimanus manual pupal-sex-sorting is not feasible, and therefore, we explored the use of RNA interference (RNAi) targeting genes with a sex-biased expression for female elimination. Here, we evaluated the effect of feeding larvae with dsRNA for a female-biased orthologue of the flight muscle actin gene.ResultsTwo sex-biased actin forms were identified in An. albimanus. Gene expression analysis showed a >40-fold higher expression of the AALB015469 transcript in female pupae (p = 0.0048) and adults (p = 0.0078) when compared to males. Tissue-specific analysis also suggests this female-biased actin can be an orthologue of the flight muscle actin of Aedes aegypti. At the same time, the AALB015481 transcript showed a >40-fold higher expression in male pupae and adults when compared to females, with no detectable expression in flight muscle. The potential effects of oral-induced RNAi for the female-biased actin were evaluated. Larvae were fed a diet containing either dsRNA for the female-biased actin 3'-UTR alone or for the UTR with an adjoining portion of the C-terminal coding region. A significant number of flightless females resulted from feedings with 3' UTR alone (10.50 ± 5.92 %, p < 0.05) or with the coding region (6.00 ± 2.16 %, p < 0.01). Treatment with the 3' UTR alone resulted in a significant number of flightless males (8.25 ± 3.10 %, p < 0.01). Both diets produced significant mortality in both female and male adults (p < 0.0001). Conclusions Feeding of An. albimanus larvae with dsRNA targeting the female-biased flight muscle actin orthologue impairs flight in both sexes and affects the overall survival of female and male mosquitoes. Providing dsRNA in the larval diet shows promise as a method for screening other differentially expressed genes as potential targets for female elimination in mosquito breeding facilities.