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. 2012;7(8):e42771.
doi: 10.1371/journal.pone.0042771. Epub 2012 Aug 27.

Open field release of genetically engineered sterile male Aedes aegypti in Malaysia

Renaud Lacroix  1 Andrew R McKemeyNorzahira RaduanLim Kwee WeeWong Hong MingTeoh Guat NeySiti Rahidah A ASawaluddin SalmanSelvi SubramaniamOreenaiza NordinNorhaida Hanum A TChandru AngamuthuSuria Marlina MansorRosemary S LeesNeil NaishSarah ScaifePam GrayGeneviève LabbéCamilla BeechDerric NimmoLuke AlpheySeshadri S VasanLee Han LimNazni Wasi AShahnaz Murad
Affiliations

Open field release of genetically engineered sterile male Aedes aegypti in Malaysia

Renaud Lacroix et al. PLoS One. 2012.

Abstract

Background: Dengue is the most important mosquito-borne viral disease. In the absence of specific drugs or vaccines, control focuses on suppressing the principal mosquito vector, Aedes aegypti, yet current methods have not proven adequate to control the disease. New methods are therefore urgently needed, for example genetics-based sterile-male-release methods. However, this requires that lab-reared, modified mosquitoes be able to survive and disperse adequately in the field.

Methodology/principal findings: Adult male mosquitoes were released into an uninhabited forested area of Pahang, Malaysia. Their survival and dispersal was assessed by use of a network of traps. Two strains were used, an engineered 'genetically sterile' (OX513A) and a wild-type laboratory strain, to give both absolute and relative data about the performance of the modified mosquitoes. The two strains had similar maximum dispersal distances (220 m), but mean distance travelled of the OX513A strain was lower (52 vs. 100 m). Life expectancy was similar (2.0 vs. 2.2 days). Recapture rates were high for both strains, possibly because of the uninhabited nature of the site.

Conclusions/significance: After extensive contained studies and regulatory scrutiny, a field release of engineered mosquitoes was safely and successfully conducted in Malaysia. The engineered strain showed similar field longevity to an unmodified counterpart, though in this setting dispersal was reduced relative to the unmodified strain. These data are encouraging for the future testing and implementation of genetic control strategies and will help guide future field use of this and other engineered strains.

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Conflict of interest statement

Competing Interests: Authors affiliated to Oxitec Ltd. or Oxitec Sdn Bhd are past or present staff or students of Oxitec Ltd. or Oxitec Sdn Bhd. These authors also have, or had, shares or share options in Oxitec Ltd. The genetically modified line of Aedes aegypti OX513A used in the study is a product of Oxitec Ltd. and contains patented technology owned by Oxitec Ltd. and Oxford University. Specific details will be made available upon request. This does not alter the authors' adherence to all the PLoS ONE policies on sharing data and materials, as detailed online in the guide for authors. All other authors declare no conflicting interests.

Figures

Figure 1
Figure 1. Study and monitored areas in Bentong, Pahang, Malaysia.
(a) The release was conducted in an uninhabited area comprising a jungle area (government land), a cleared area and a young rubber plantation where a network of 45 adult traps (BG-Sentinel) and 44 ovitraps were set. The closest inhabited areas were monitored with 35 ovitraps only, (release point: red star; uninhabited study area: green area; inhabited monitored area: blue area) (Credits for small scale map: © 2012 Google; © 2012 Tele Atlas; © 2012 TerraMetrics; Credits for large scale map: © 2012 Google; © 2012 GeoEye; © 2012 Cnes/Spot Image; © 2012 Mapit). (b) The BG-Sentinel traps were principally set in the cleared area on the small terraces surrounding the release point and uphill on a small path through the forest until around 100 m from the release point. Further traps were placed downhill in the rubber plantation along the road leading to the closest inhabited area. (Release point: red star; BG-Sentinel™ traps: circles; Altitude: contour lines (separated by 10 m)).
Figure 2
Figure 2. Recapture rate over time of OX513A-My1 and My1 males.
Adult traps (BG-Sentinel) were serviced daily; the recapture rate of each released male type caught each day following release on Day 0 is plotted (OX513A-My1: blue; My1: red). Similar recapture rates over time were observed for each strain.
Figure 3
Figure 3. Ovitrap index of Ae. aegypti and Ae. albopictus in uninhabited and inhabited sites.
The larval monitoring confirmed the predominance of Ae. albopictus in the uninhabited area as well as in the inhabited areas surrounding the study area. (Ae. aegypti uninhabited area: blue solid line; Ae. aegypti inhabited area: blue dotted line; Ae. albopictus uninhabited area: green solid line; Ae albopictus inhabited area: green dotted line).
Figure 4
Figure 4. Difference in dispersal of My1 and OX513A-My1 males.
Proportion of the total trap density corrected recaptures calculated according to the distance from the release point by concentric annuli of 25 m. Most of the OX513A-My1 males (68%) were caught in the first two annuli surrounding the release point, i.e. <50 m, while the My1 males are more evenly distributed among the annuli (from 3% to 22%). This accounts for the latter higher Mean Distance Travelled (MDT), Flight Range 50 (FR50) and Flight Range 90 (FR90). (My1 males: red; OX513A-My1 males: blue).
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Publication types

Grants and funding

This study was supported by a grant from the National Institutes of Health from the Ministry of Health, Malaysia (code: JPP-IMR 06-053). Oxitec Ltd. provided salary and other support for the research program of those authors employed by the company (as noted in the author list). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.