19 research outputs found
Population genetic structure of Aedes aegypti, the principal vector of dengue viruses
International audienceKnowledge of vector population genetic structure is critical for vector-borne disease control and prevention strategies. Advances in both molecular genotyping technology and theoretical developments have contributed to the growing impact of such approaches on medical entomology. The pattern of genetic structure may affect the design of control strategies in determining appropriate control limits necessary to disrupt pathogen transmission. In this review, we focus on the mosquito Aedes aegypti, the primary vector of dengue viruses. We describe and discuss numerous population genetic studies illustrating the local genetic variation and gene flow of Ae. aegypti populations
Gene flow, subspecies composition, and dengue virus-2 susceptibility among Aedes aegypti collections in Senegal.
Aedes aegypti, the "yellow fever mosquito", is the primary vector to humans of the four serotypes of dengue viruses (DENV1-4) and yellow fever virus (YFV) and is a known vector of Chikungunya virus. There are two recognized subspecies of Ae. aegypti sensu latu (s.l.): the presumed ancestral form, Ae. aegypti formosus (Aaf), a primarily sylvan mosquito in sub-Saharan Africa, and Ae. aegypti aegypti (Aaa), found globally in tropical and subtropical regions typically in association with humans. The designation of Ae. aegypti s.l. subspecies arose from observations made in East Africa in the late 1950s that the frequency of pale "forms" of Ae. aegypti was higher in populations in and around human dwellings than in those of the nearby bush. But few studies have been made of Ae. aegypti s.l. in West Africa. To address this deficiency we have been studying the population genetics, subspecies composition and vector competence for DENV-2 of Ae. aegypti s.l. in Senegal.A population genetic analysis of gene flow was conducted among 1,040 Aedes aegypti s.l. from 19 collections distributed across the five phytogeographic regions of Senegal. Adults lacking pale scales on their first abdominal tergite were classified as Aedes aegypti formosus (Aaf) following the original description of the subspecies and the remainder were classified as Aedes aegypti aegypti (Aaa). There was a clear northwest-southeast cline in the abundance of Aaa and Aaf. Collections from the northern Sahelian region contained only Aaa while southern Forest gallery collections contained only Aaf. The two subspecies occurred in sympatry in four collections north of the Gambia in the central Savannah region and Aaa was a minor component of two collections from the Forest gallery area. Mosquitoes from 11 collections were orally challenged with DENV-2 virus. In agreement with the early literature, Aaf had significantly lower vector competence than Aaa. Among pure Aaa collections, the disseminated infection rate (DIR) was 73.9% with a midgut infection barrier (MIB) rate of 6.8%, and a midgut escape barrier (MEB) rate of 19.3%, while among pure Aaf collections, DIR = 34.2%, MIB rate = 7.4%, and MEB rate = 58.4%. Allele and genotype frequencies were analyzed at 11 nuclear single nucleotide polymorphism (SNP) loci using allele specific PCR and melting curve analysis. In agreement with a published isozyme gene flow study in Senegal, only a small and statistically insignificant percentage of the variance in allele frequencies was associated with subspecies.These results add to our understanding of the global phylogeny of Aedes aegypti s.l., suggesting that West African Aaa and Aaf are monophyletic and that Aaa evolved in West Africa from an Aaf ancestor
Vector competence of <i>Ae. aegypti s.l.</i> collections in Senegal.
<p>Disseminated infection rate (DIR) appears in black, midgut infection barrier rate (MIB) appears in grey, and midgut escape barrier rate (MEB) appears in white. Pairwise Fisher's Exact Tests were performed on all collections. Strains with equivalent rates have the same labels and these were significantly different from one another. Sample sizes = 50–65 females.</p
UPGMA cluster analysis of pairwise F<sub>ST</sub>/(1−F<sub>ST</sub>) markers among the 25 collections.
<p>UPGMA cluster analysis of pairwise F<sub>ST</sub>/(1−F<sub>ST</sub>) markers among the 25 collections.</p
<i>Aedes aegypti s.l.</i> collection sites and associated sample sites in Senegal.
<p>Predominant vegetation zones are also shown.</p
Geographic origin, sex, and sample sizes of <i>Aedes aegypti s.l.</i> used to screen for SNPs.
<p>Geographic origin, sex, and sample sizes of <i>Aedes aegypti s.l.</i> used to screen for SNPs.</p
Distribution of <i>Aaa</i> or <i>Aaf</i> in Senegal.
<p>Pairwise Fisher's Exact Tests were performed on all collections. Strains with equivalent rates have the same labels and these were significantly different from one another.</p
Addition of Senegal collections to Figure 1.
<p>Addition of Senegal collections to <a href="http://www.plosntds.org/article/info:doi/10.1371/journal.pntd.0000408#pntd-0000408-g001" target="_blank">Figure 1</a>.</p
Regression analysis of pairwise F<sub>ST</sub>/(1−F<sub>ST</sub>) for the SNP markers against geographic distances (km) (upper panel), pairwise F<sub>ST</sub>/(1−F<sub>ST</sub>) for SNP markers against ln(geographic distances (km)) (lower panel).
<p>Regression analysis of pairwise F<sub>ST</sub>/(1−F<sub>ST</sub>) for the SNP markers against geographic distances (km) (upper panel), pairwise F<sub>ST</sub>/(1−F<sub>ST</sub>) for SNP markers against ln(geographic distances (km)) (lower panel).</p
Wright's F-statistics estimated by Weir and Cockerham's method [44] among the 19 Senegal collections.
***<p>P≤0.0001.</p><p>Under F<sub>IS</sub> are indicated the number of tests for goodness-of-fit to Hardy-Weinberg expectation in which F<sub>IS</sub>≠0 over the number of tests. This is followed by the number of tests in which F<sub>IS</sub>>0 and the number in which F<sub>IS</sub><0.</p