Characterization of a broad-based mosquito yeast interfering RNA larvicide with a conserved target site in mosquito semaphorin-1a genes

BACKGROUND: RNA interference (RNAi), which has facilitated functional characterization of mosquito neural development genes such as the axon guidance regulator semaphorin-1a (sema1a), could one day be applied as a new means of vector control. Saccharomyces cerevisiae (baker's yeast) may represent an effective interfering RNA expression system that could be used directly for delivery of RNA pesticides to mosquito larvae. Here we describe characterization of a yeast larvicide developed through bioengineering of S. cerevisiae to express a short hairpin RNA (shRNA) targeting a conserved site in mosquito sema1a genes. RESULTS: Experiments conducted on Aedes aegypti larvae demonstrated that the yeast larvicide effectively silences sema1a expression, generates severe neural defects, and induces high levels of larval mortality in laboratory, simulated-field, and semi-field experiments. The larvicide was also found to induce high levels of Aedes albopictus, Anopheles gambiae and Culex quinquefasciatus mortality. CONCLUSIONS: The results of these studies indicate that use of yeast interfering RNA larvicides targeting mosquito sema1a genes may represent a new biorational tool for mosquito control

A functional requirement for sex-determination M/m locus region lncRNA genes in Aedes aegypti female larvae

Although many putative long non-coding RNA (lncRNA) genes have been identified in insect genomes, few of these genes have been functionally validated. A screen for female-specific larvicides that facilitate Aedes aegypti male sex separation uncovered multiple interfering RNAs with target sites in lncRNA genes located in the M/m locus region, including loci within or tightly linked to the sex determination locus. Larval consumption of a Saccharomyces cerevisiae (yeast) strain engineered to express interfering RNA corresponding to lncRNA transcripts resulted in significant female death, yet had no impact on male survival or fitness. Incorporation of the yeast larvicides into mass culturing protocols facilitated scaled production and separation of fit adult males, indicating that yeast larvicides could benefit mosquito population control strategies that rely on mass releases of male mosquitoes. These studies functionally verified a female-specific developmental requirement for M/m locus region lncRNA genes, suggesting that sexually antagonistic lncRNA genes found within this highly repetitive pericentromeric DNA sequence may be contributing to the evolution of A. aegypti sex chromosomes

Assessment of Trinidad community stakeholder perspectives on the use of yeast interfering RNA-baited ovitraps for biorational control of Aedes mosquitoes

Dengue, Zika, chikungunya and yellow fever viruses continue to be a major public health burden. Aedes mosquitoes, the primary vectors responsible for transmitting these viral pathogens, continue to flourish due to local challenges in vector control management. Yeast interfering RNA-baited larval lethal ovitraps are being developed as a novel biorational control tool for Aedes mosquitoes. This intervention circumvents increasing issues with insecticide resistance and poses no known threat to non-target organisms. In an effort to create public awareness of this alternative vector control strategy, gain stakeholder feedback regarding product design and acceptance of the new intervention, and build capacity for its potential integration into existing mosquito control programs, this investigation pursued community stakeholder engagement activities, which were undertaken in Trinidad and Tobago. Three forms of assessment, including paper surveys, community forums, and household interviews, were used with the goal of evaluating local community stakeholders' knowledge of mosquitoes, vector control practices, and perceptions of the new technology. These activities facilitated evaluation of the hypothesis that the ovitraps would be broadly accepted by community stakeholders as a means of biorational control for Aedes mosquitoes. A comparison of the types of stakeholder input communicated through use of the three assessment tools highlighted the utility and merit of using each tool for assessing new global health interventions. Most study participants reported a general willingness to purchase an ovitrap on condition that it would be affordable and safe for human health and the environment. Stakeholders provided valuable input on product design, distribution, and operation. A need for educational campaigns that provide a mechanism for educating stakeholders about vector ecology and management was highlighted. The results of the investigation, which are likely applicable to many other Caribbean nations and other countries with heavy arboviral disease burdens, were supportive of supplementation of existing vector control strategies through the use of the yeast RNAi-based ovitraps

Community acceptance of yeast interfering RNA larvicide technology for control of Aedes mosquitoes in Trinidad

RNA interference (RNAi), a technique used to investigate gene function in insects and other organisms, is attracting attention as a potential new technology for mosquito control. Saccharomyces cerevisiae (baker’s yeast) was recently engineered to produce interfering RNA molecules that silence genes required for mosquito survival, but which do not correspond to genes in humans or other non-target organisms. The resulting yeast pesticides, which facilitate cost-effective production and delivery of interfering RNA to mosquito larvae that eat the yeast, effectively kill mosquitoes in laboratory and semi-field trials. In preparation for field evaluation of larvicides in Trinidad, a Caribbean island with endemic diseases resulting from pathogens transmitted by Aedes mosquitoes, adult residents living in the prospective trial site communities of Curepe, St. Augustine, and Tamana were engaged. Open community forums and paper surveys were used to assess the potential acceptability, societal desirability, and sustainability of yeast interfering RNA larvicides. These assessments revealed that Trinidadians have good working knowledge of mosquitoes and mosquito-borne illnesses. A majority of the respondents practiced some method of larval mosquito control and agreed that they would use a new larvicide if it were proven to be safe and effective. During the community engagement forums, participants were educated about mosquito biology, mosquito-borne diseases, and the new yeast larvicides. When invited to provide feedback, engagement forum attendees were strongly supportive of the new technology, raised few concerns, and provided helpful advice regarding optimal larvicide formulations, insecticide application, operational approaches for using the larvicides, and pricing. The results of these studies suggest that the participants are supportive of the potential use of yeast interfering RNA larvicides in Trinidad and that the communities assessed in this investigation represent viable field sites

Evaluation of large volume yeast interfering RNA lure-and-kill ovitraps for attraction and control of Aedes mosquitoes

Aedes mosquitoes (Diptera: Culicidae), principle vectors of several arboviruses, typically lay eggs in man-made water-filled containers located near human dwellings. Given the widespread emergence of insecticide resistance, stable and biofriendly alternatives for mosquito larviciding are needed. Laboratory studies have demonstrated that inactivated yeast interfering RNA tablets targeting key larval developmental genes can be used to facilitate effective larvicidal activity while also promoting selective gravid female oviposition behaviour. Here we examined the efficacy of transferring this technology toward development of lure-and-kill ovitraps targeting Aedes aegypti (L.) and Aedes albopictus (Skuse) female mosquitoes. Insectary, simulated field and semi-field experiments demonstrated that two mosquito-specific yeast interfering RNA pesticides induce high levels of mortality among larvae of both species in treated large volume containers. Small-scale field trials conducted in Trinidad, West Indies demonstrated that large volume ovitrap containers baited with inactivated yeast tablets lure significantly more gravid females than traps containing only water and were highly attractive to both A. aegypti and A. albopictus females. These studies indicate that development of biorational yeast interfering RNA-baited ovitraps may represent a new tool for control of Aedes mosquitoes, including deployment in existing lure-and-kill ovitrap technologies or traditional container larviciding programs

Studies on Aedes polynesiensis introgression and ecology to facilitate lymphatic filariasis control

The mosquito Aedes polynesiensis, a member of the Aedes scutellaris complex, is the main vector in the South Pacific region of the Wuchereria bancrofti parasite, the causative agent of lymphatic filariasis (LF), and is also a major nuisance biter. Decades of Mass Drug treatment (MDA) have not been successful in elimination LF. Two non-vector species in the Ae. scutellaris complex were introgressed with Ae. polynesiensis to attempt to obtain lines that would produce cytoplasmic incompatibility (CI) with wild populations and / or LF-refractoriness. Despite selection of progeny from Brugia-challenged, non-infective females at each backcross, no refractory line was acquired. However, three lines from crosses between aposymbiotic Ae. polynesiensis and Ae. riversi displayed CI and male mating competiveness suitable for the purpose of population suppression using the incompatible insect technique (IIT). A population study was conducted of potential release sites and the evaluation of monitoring tools for Ae. polynesiensis on Moorea and Tetiaroa, French Polynesia. There was no evidence of active migration between selected islets on the atoll of Tetiaroa, suggesting it is a suitable site for field releases of CI males. The BioGents Sentinel trap was shown to be an efficient and convenient trap suitable for Ae. polynesiensis monitoring. The effects of temperature and larval density on life-table parameters relevant to IIT were examined, including: larval survivorship, developmental time to pupation, male to female ratio, male pupae yield, male size and adult male survival. These findings were used to design and conduct a 14-week field experiment testing CI male strain against an isolated population, using optimized rearing conditions. Approximately 8000 males were released weekly on motu Onetahi, Tetiaroa atoll. Significant sterility was induced by Wolbachia in the targeted female population, supporting the development and scale-up of this approach toward Ae. polynesiensis nuisance and LF transmission reduction.</p

Studies on Aedes polynesiensis introgression and ecology to facilitate lymphatic filariasis control

The mosquito Aedes polynesiensis, a member of the Aedes scutellaris complex, is the main vector in the South Pacific region of the Wuchereria bancrofti parasite, the causative agent of lymphatic filariasis (LF), and is also a major nuisance biter. Decades of Mass Drug treatment (MDA) have not been successful in elimination LF. Two non-vector species in the Ae. scutellaris complex were introgressed with Ae. polynesiensis to attempt to obtain lines that would produce cytoplasmic incompatibility (CI) with wild populations and / or LF-refractoriness. Despite selection of progeny from Brugia-challenged, non-infective females at each backcross, no refractory line was acquired. However, three lines from crosses between aposymbiotic Ae. polynesiensis and Ae. riversi displayed CI and male mating competiveness suitable for the purpose of population suppression using the incompatible insect technique (IIT). A population study was conducted of potential release sites and the evaluation of monitoring tools for Ae. polynesiensis on Moorea and Tetiaroa, French Polynesia. There was no evidence of active migration between selected islets on the atoll of Tetiaroa, suggesting it is a suitable site for field releases of CI males. The BioGents Sentinel trap was shown to be an efficient and convenient trap suitable for Ae. polynesiensis monitoring. The effects of temperature and larval density on life-table parameters relevant to IIT were examined, including: larval survivorship, developmental time to pupation, male to female ratio, male pupae yield, male size and adult male survival. These findings were used to design and conduct a 14-week field experiment testing CI male strain against an isolated population, using optimized rearing conditions. Approximately 8000 males were released weekly on motu Onetahi, Tetiaroa atoll. Significant sterility was induced by Wolbachia in the targeted female population, supporting the development and scale-up of this approach toward Ae. polynesiensis nuisance and LF transmission reduction

Studies on Aedes polynesiensis introgression and ecology to facilitate lymphatic filariasis control

The mosquito Aedes polynesiensis, a member of the Aedes scutellaris complex, is the main vector in the South Pacific region of the Wuchereria bancrofti parasite, the causative agent of lymphatic filariasis (LF), and is also a major nuisance biter. Decades of Mass Drug treatment (MDA) have not been successful in elimination LF. Two non-vector species in the Ae. scutellaris complex were introgressed with Ae. polynesiensis to attempt to obtain lines that would produce cytoplasmic incompatibility (CI) with wild populations and / or LF-refractoriness. Despite selection of progeny from Brugia-challenged, non-infective females at each backcross, no refractory line was acquired. However, three lines from crosses between aposymbiotic Ae. polynesiensis and Ae. riversi displayed CI and male mating competiveness suitable for the purpose of population suppression using the incompatible insect technique (IIT). A population study was conducted of potential release sites and the evaluation of monitoring tools for Ae. polynesiensis on Moorea and Tetiaroa, French Polynesia. There was no evidence of active migration between selected islets on the atoll of Tetiaroa, suggesting it is a suitable site for field releases of CI males. The BioGents Sentinel trap was shown to be an efficient and convenient trap suitable for Ae. polynesiensis monitoring. The effects of temperature and larval density on life-table parameters relevant to IIT were examined, including: larval survivorship, developmental time to pupation, male to female ratio, male pupae yield, male size and adult male survival. These findings were used to design and conduct a 14-week field experiment testing CI male strain against an isolated population, using optimized rearing conditions. Approximately 8000 males were released weekly on motu Onetahi, Tetiaroa atoll. Significant sterility was induced by Wolbachia in the targeted female population, supporting the development and scale-up of this approach toward Ae. polynesiensis nuisance and LF transmission reduction.This thesis is not currently available in ORA

Effect of temperature and larval density on Aedes polynesiensis (Diptera: Culicidae) laboratory rearing productivity and male characteristics

Aedes polynesiensis Marks (Diptera: Culicidae) larvae were reared to adulthood in the laboratory under a range of temperatures and larval densities. We studied the effect of these variables on several life table parameters of relevance to male-release-based vector control strategies including: larval survivorship, developmental time to pupation, male to female ratio, male pupae yield, adult male size and survival. The range of tested rearing temperatures (20, 25, 27, and 30 °C) and larval densities (50, 100, 200, and 400 larvae/L) was selected within the conditions allowing larval growth and survival. Larval survivorship was the highest when larvae were reared at 200 larvae/L for all temperatures except 20 °C. Male to female ratio was male biased at all temperatures and densities. Time to pupation decreased with increasing temperatures. Larval density and temperature influenced the proportion of males pupating on first day of pupation with 43-47% of total male pupae produced at 25 °C. No significant differences in mean wing length were observed between male mosquitoes reared in the laboratory (except at 20 and 30 °C for some densities) and field collected males. Altogether, the study allowed the identification of rearing conditions delivering high male yield with essentially no female contamination, adequate adult male size and survival. Ae. polynesiensis thus appears particularly amenable to biological and mechanical sex separation offering good prospects for Ae. polynesiensis population suppression trials that rely on the production and release of large numbers of incompatible or sterile males