A reduce and replace strategy for suppressing vector-borne diseases: insights from a stochastic, spatial model

Two basic strategies have been proposed for using transgenic Aedes aegypti mosquitoes to decrease dengue virus transmission: population reduction and population replacement. Here we model releases of a strain of Ae. aegypti carrying both a gene causing conditional adult female mortality and a gene b...

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Bibliographic Details
Published in:PloS one 2013-12, Vol.8 (12), p.e81860-e81860
Main Authors: Okamoto, Kenichi W, Robert, Michael A, Lloyd, Alun L, Gould, Fred
Format: Article
Language:English
Subjects:
Aedes
Aedes - genetics
Aedes - virology
Aedes aegypti
Analysis
Animals
Animals, Genetically Modified
Aquatic insects
Biology
Calibration
Community support
Computer Simulation
Culicidae
Dengue
Dengue fever
Dengue Virus - physiology
Diptera
Disease transmission
Female
Females
Fixation
Genetic drift
Genetic engineering
Genotype
Health aspects
Immigration
Insect Vectors - virology
Male
Medicine
Migrants
Models, Theoretical
Mortality
Mosquitoes
Ovum - metabolism
Pathogens
Population
Population genetics
Reduction
Releasing
Stochastic Processes
Stochasticity
Vector-borne diseases
Vectors
Viral diseases
Viruses
Wolbachia
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Summary:Two basic strategies have been proposed for using transgenic Aedes aegypti mosquitoes to decrease dengue virus transmission: population reduction and population replacement. Here we model releases of a strain of Ae. aegypti carrying both a gene causing conditional adult female mortality and a gene blocking virus transmission into a wild population to assess whether such releases could reduce the number of competent vectors. We find this "reduce and replace" strategy can decrease the frequency of competent vectors below 50% two years after releases end. Therefore, this combined approach appears preferable to releasing a strain carrying only a female-killing gene, which is likely to merely result in temporary population suppression. However, the fixation of anti-pathogen genes in the population is unlikely. Genetic drift at small population sizes and the spatially heterogeneous nature of the population recovery after releases end prevent complete replacement of the competent vector population. Furthermore, releasing more individuals can be counter-productive in the face of immigration by wild-type mosquitoes, as greater population reduction amplifies the impact wild-type migrants have on the long-term frequency of the anti-pathogen gene. We expect the results presented here to give pause to expectations for driving an anti-pathogen construct to fixation by relying on releasing individuals carrying this two-gene construct. Nevertheless, in some dengue-endemic environments, a spatially heterogeneous decrease in competent vectors may still facilitate decreasing disease incidence.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0081860