Abstract. Twenty 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.
The dengue type 4 virus (DEN4) RNA genome contains a 101-nt 5' noncoding (NC) sequence which is predicted to form a stable secondary structure. DEN4 cDNA from which infectious RNA can be transcribed was used to engineer deletions in the 5' NC region for functional analysis of RNA structure and for isolation of DEN4 mutants that could be evaluated as candidates for use in a live attenuated vaccine. Eleven distinct deletions in the region of the DEN4 genome between nts 18 and 98 were constructed; each mutation was predicted to alter or disrupt the local base-parings in the 5' NC RNA structure. An infectious virus was not recovered from the RNA transcripts of five of these deletion mutants. Significantly, four of the five apparently lethal deletions were located in a 5- to 6-nt base-paired region of a predicted long stem or adjacent to it. In contrast, with one exception, mutants which yielded infectious virus had deletions which were located in a loop or short stem region. The effect of the deletions on the efficiency of translation of viral RNA transcripts was examined in vitro. The RNA transcripts of deletion constructs which did not yield viable virus were translated at an efficiency ranging from 40 to 160% that of wild-type virus transcripts. The translation efficiency of infectious RNA transcripts also varied. Deletion mutants recovered from RNA transcripts that exhibited low to moderate efficiency of translation had a small plaque morphology and exhibited reduced growth in simian LLC-MK2 and mosquito C6/36 cells compared to the wild-type virus. Among the 11 mutant constructs, deletion of nts 82-87 caused the greatest reduction in translation efficiency. Nevertheless, an infectious virus was recovered from LLC-MK2 cells transfected with the RNA transcripts of mutant d(82-87). The progeny of this mutant produced small plaques on LLC-MK2 cells and grew to low titer in these cells. Unlike wild-type DEN4 or other DEN4 deletion mutants tested, mutant d(82-87) failed to produce plaques on C6/36 cells and was also replication-defective in Aedes aegypti and Aedes albopictus following intrathoracic inoculation.
Abstract. Genetic 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 Ͼ10 Ϫ4 ) 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.
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