Genetic control of vectorial competence in Aedes mosquitoes

International audienceThe transmission of pathogens by arthropods is dependent on the relationships that exist between the pathogen, the invertebrate host (the vector) and the vertebrate host, each of which is influenced by environmental variations. Particular attention is given to the knowledge of intrinsic factors and the mechanisms controlling the ability of vectors to transmit pathogens (viruses or parasites). Polymorphism in the expression of susceptibility to oral infection has been shown to occur among geographical samples of mosquitoes. It has been proven that intraspecific variations in vector competence are controlled by one or more genes and expressed in variable proportions within a mosquito population. Recent advances in molecular biology have facilitated accessibility of nucleic acid sequence data. These new techniques allow one to analyse the genotype distribution within and among populations. Population genetic studies are currently used to understand the evolution of species differentiation and provide indications on genetic relationship among field vector populations. Estimations of gene flow with respect to vector capacity have provided rich insight into vector species complexes. Knowledge of intraspecies variation is important for the understanding of vector transmission, disease epidemiology and disease control. In this article, two examples are presented to illustrate the contribution of population genetic studies to the understanding of epidemiology of arthropod-borne diseases: Aedes polyneniensis, a vector of human lymphatic filariasis and Aedes aegypti, the vector of dengue viruses

Réceptivité orale d'Aedes aegypti formosus de Franceville (Gabon, Afrique centrale) pour le virus de la dengue type 2

International audienceDengue is widely distributed in the tropics but epidemic activity was rarely reported in Africa before the 1980's. In the past 15 years, increased epidemic dengue fever has been reported both in East and West Africa, raising concern about the ability of local populations of Aedes aegypti to transmit dengue viruses. Ae. aegypti is present in two forms in Africa: Ae. aegypti aegypti and Ae. aegypti formosus. This latter form, much darker, was not originally a local species but is now colonizing artificial breeding sites within cities. We have been able to demonstrate the oral susceptibility for dengue type 2 virus of Ae. aegypti formosus collected in Franceville, Gabon (Central Africa). However, these mosquitoes sampled exhibited lower infection rates than those of a control colony of Ae. aegypti aegypti originating from French Polynesia.La dengue sévit dans toute la zone intertropicale mais le continent africain semblait relativement épargné jusqu’au début des années 80. Au cours des 15 dernières années la situation a évolué avec l’apparition d’épisodes épidémiques aussi bien en Afrique de l’Est qu’en Afrique de l’Ouest, soulevant de ce fait le problème de la réceptivité orale pour les virus de la dengue des populations locales d’Ae. aegypti. Ce moustique est présent sous deux formes en Afrique : Ae. aegypti aegypti et Ae. aegypti formosus. Cette dernière forme, non domestique à l’origine, colonise maintenant des gîtes de pontes artificiels dans les villes. Nous avons montré la réceptivité orale pour le virus de la dengue type 2 d’un échantillon d’Ae. aegypti formosus provenant de Franceville (Afrique centrale). Cependant, la réceptivité de cet échantillon était significativement plus faible, à l’issue d’un repas artificiel, que celle d’une souche témoin d’Ae. aegypti aegypti, originaire de Polynésie française

Aedes aegypti in Tahiti and Moorea (French Polynesia): isoenzyme differentiation in the mosquito population according to human population density

International audienceGenetic differences at five polymorphic isoenzyme loci were analyzed by starch gel electrophoresis for 28 Aedes aegypti samples. Considerable (i.e., high F st values) and significant (i.e., P values 10 4) geographic differences were found. Differences in Ae. aegypti genetic structure were related to human population densities and to particularities in mosquito ecotopes in both Tahiti and Moorea islands. In highly urbanized areas (i.e., the Papeete agglomeration), mosquitoes were highly structured. Recurrent extinction events consecutive to insecticidal treatments during dengue outbreaks tend to differentiate mosquito populations. In less populated zones (i.e., the east coast of Moorea and Tahiti), differences in ecotope characteristics could explain the lack of differentiation among mosquitoes from rural environments such as the east coast of Tahiti where natural breeding sites predominate. When the lowest populated zones such as Tahiti Iti and the west coast of Moorea are compared, mosquito are less differentiated in Moorea. These results will be discussed in relation to the recent findings of variation in mosquito infection rates for dengue-2 virus

Variation in oral susceptibility to dengue type 2 virus of populations of Aedes aegypti from the islands of Tahiti and Moorea, French Polynesia.

International audienceTwenty three samples of Aedes aegypti populations from the islands of Tahiti and Moorea (French Polynesia) were tested for their oral susceptibility to dengue type 2 virus. The high infection rates obtained suggest that the artificial feeding protocol used was more efficient than those previously described. Statistical analysis of the results allowed us to define two distinct geographic areas on Tahiti with respect to the susceptibility of Ae. aegypti: the east coast, with homogeneous infection rates, and the west coast, with heterogeneous infection rates. No geographic differences could be demonstrated on Moorea. The possible mechanisms of this phenomenon are discussed in connection with recent findings on the variability of susceptibility of Ae. aegypti to insecticides

Aedes aegypti in Ho Chi Minh City (Viet Nam): susceptibility to dengue 2 virus and genetic differentiation

International audienceAedes aegypti is the principal vector of dengue viruses, responsible for a viral infection that has become a major public health concern in Asia. In Viet Nam, dengue haemorrhagic fever was first detected in the 1960s and is now a leading cause of death in childhood. We studied the variability in competence of Ae. aegypti as a vector for dengue 2 virus and genetic differentiation in this mosquito species. Twenty mosquito samples collected in 1998 in Ho Chi Minh City were subjected to oral infection and isoenzyme polymorphism analysis by starch gel electrophoresis. Ae. aegypti populations from the centre of Ho Chi Minh City were genetically differentiated and their infection rates differed from those of populations from the commuter belt. These results have implications for insecticidal control during dengue outbreaks

Aedes aegypti in French Guiana: susceptibility to a dengue virus

International audienceTwenty-seven samples of Aedes aegypti (F1 generation) from French Guiana were tested for their susceptibility to dengue serotype 2 virus. Very high infection rates were observed by indirect fluorescent antibody (IFA) test. Ae. aegypti samples were pooled according to two groups: the first group (N=10) represented mosquitoes from the urbanized area of Cayenne and surroundings, and the second group (N=17) corresponded to mosquitoes collected in the countryside. Infection rates were found to be similar in these two cases. These findings are discussed in relation with the history of Ae. aegypti in this part of the world

Potential vectors of rift valley Fever virus in the Mediterranean region

We evaluated the ability of three mosquito species (Aedes caspius, Aedes detritus, Culex pipiens), collected in southern France and Tunisia, and of different laboratory-established colonies (Aedes aegypti, Aedes albopictus, Aedes vexans, Anopheles gambiae, Culex pipiens, Culex quinquefasciatus) to disseminate two strains of Rift Valley fever virus (RVFV), the virulent ZH548 and the avirulent Clone 13. After feeding on an infectious blood meal at 10(8.5) plaque-forming units/mL, females were maintained at 30 degrees C for 14 days. Surviving females were tested for the presence of virus on head squashes. Disseminated infection rate corresponds to the number of females with disseminated infection among surviving females. Among field-collected mosquitoes, Cx. pipiens was the most susceptible species with disseminated infection rates ranging from 3.9% to 9.1% for French strains and up to 14.7% for Tunisian strains. Among laboratory-established colonies, Ae. aegypti from Tahiti exhibited the highest disseminated infection rates: 90% when infected with ZH548 and 72.6% with Clone 13. The presence of competent Cx. pipiens in southern France and Tunisia indicates the potential for RVFV epizootics to occur if the virus was introduced into countries of the Mediterranean basin