Abstract
Understanding past dispersal and breeding events can provide insight into ecology and evolution and can help inform strategies for conservation and the control of pest species. However, parent–offspring dispersal can be difficult to investigate in rare species and in small pest species such as mosquitoes. Here, we develop a methodology for estimating parent–offspring dispersal from the spatial distribution of close kin, using pairwise kinship estimates derived from genome‐wide single nucleotide polymorphisms (SNPs). SNPs were scored in 162 Aedes aegypti (yellow fever mosquito) collected from eight close‐set, high‐rise apartment buildings in an area of Malaysia with high dengue incidence. We used the SNPs to reconstruct kinship groups across three orders of kinship. We transformed the geographical distances between all kin pairs within each kinship category into axial standard deviations of these distances, then decomposed these into components representing past dispersal events. From these components, we isolated the axial standard deviation of parent–offspring dispersal and estimated neighbourhood area (129 m), median parent–offspring dispersal distance (75 m) and oviposition dispersal radius within a gonotrophic cycle (36 m). We also analysed genetic structure using distance‐based redundancy analysis and linear regression, finding isolation by distance both within and between buildings and estimating neighbourhood size at 268 individuals. These findings indicate the scale required to suppress local outbreaks of arboviral disease and to target releases of modified mosquitoes for mosquito and disease control. Our methodology is readily implementable for studies of other species, including pests and species of conservation significance.
Highlights
Dispersal is a key trait in ecology and evolution, allowing species to evade stressful areas and locate favourable new areas and determining levels of gene flow that influence the adaptability of species (Clobert, Baguette, Benton, & Bullock, 2012)
We focus on dispersal across a residential site in Kuala Lumpur, Malaysia, as part of preparation for active interventions involving releases of Ae. aegypti transinfected with the bacterium Wolbachia
The dbRDA evaluating the effects of geographical distance on genetic structure (“dist”) indicated that 3 of 8 principal components (PCs) were within the significance threshold (Bonferroni‐corrected critical value: p < 0.006)
Summary
Dispersal is a key trait in ecology and evolution, allowing species to evade stressful areas and locate favourable new areas and determining levels of gene flow that influence the adaptability of species (Clobert, Baguette, Benton, & Bullock, 2012). We use the above methodology to investigate dispersal in Ae. ae‐ gypti, the primary vector of arboviral diseases such as dengue, chikungunya and Zika (Morrison, Zielinski‐Gutierrez, Scott, & Rosenberg, 2008) This highly anthropophilic mosquito is generally considered a weak disperser by flight (Harrington et al, 2005), though some MRR studies have reported flights over long distances (Honorio et al, 2003; Reiter et al, 1995). Understanding intergenerational movement will help inform strategies for responding to newly detected Ae. aegypti incursions globally or to localized dengue outbreaks by chemical suppression of populations Applications of this methodology extend well beyond Ae. aegypti and other pest vectors. Our approach to estimating dispersal and neighbourhood size has numerous applications for both threatened and threatening species
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