Effects of different diets on Aedes aegypti adults: improving rearing techniques for sterile insect technique.

The aim was to evaluate the effect of different energy diets available in adulthood on the longevity, dispersal capacity and sexual performance of Aedes aegypti produced under a mass-rearing system. To evaluate the effects of diets in relation to the survival of the adult male insects of Ae. aegypti, six treatments were used: sucrose at a concentration of 10%, as a positive control (sack10); starvation, as a negative control (starvation); sucrose at a concentration of 20% associated with 1 g/l of ascorbic acid (sac20vitC); wild honey in a concentration of 10% (honey10); demerara sugar in a 10% concentration (demerara10); and sucrose at a concentration of 20% associated with 1 g/l of ascorbic acid and 0.5 g/l of amino acid proline (sac20vitCPr). Each treatment had 16 cages containing 50 adult males. For the tests of flight ability and propensity to copulation, five treatments were used (saca10; sac20vitC; mel10; demerara10; and sac20vitCPr), with males each for flight ability and females copulated by a single male for copulation propensity. The diet composed of sucrose at a concentration of 20% associated with ascorbic acid, as an antioxidant, improved the survival, flight ability and propensity to copulate in Ae. aegypti males under mass-rearing conditions, and may be useful to enhance the performance of sterile males, thus improving the success of sterile insect technique programmes.

A chalcone identified by in silico and in vitro assays possesses high larvicidal activity against Aedes aegypti.

The Aedes aegypti mosquito is a vector of important viral diseases in tropical countries, as Zika, Chikungunya and Dengue fever. The use of the chemical control of the insect life cycle is one of the most popular strategies used as prophylactic for the human population exposed. However, potential environmental and human toxicity, as well as the resistance phenomena acquired by the insects, are the main limitations for the available options. This scenario encourages the continuous search for more potent and less inconvenient chemical alternatives. In this paper, we report a potent in vitro larvicidal activity in Aedes aegypti found to a chalcone compound, previously mined by an exhaustive virtual screening by molecular docking calculations in an important protein for the larvae growth. The protein 3-hydroxykynurenine transaminase enzyme (PDB ID: 6MFB) was then combined with potential ligands provided by a homemade databank, containing secondary metabolites found in plants of the brazilian Caatinga biome. Structural rationalization of the compounds with high affinity pointed the chalcone class as most promising. Subsequent in vitro tests allowed the identification of a specific molecule with very high larvicidal potency (100% of lethality at 2.5 ppm). These results can be used in future and more refined studies, to propose a larvicidal formulation for direct application and the exploration of new compounds of this chemical class.

A perspective on the need and current status of efficient sex separation methods for mosquito genetic control.

Major efforts are currently underway to develop novel, complementary methods to combat mosquito-borne diseases. Mosquito genetic control strategies (GCSs) have become an increasingly important area of research on account of their species-specificity, track record in targeting agricultural insect pests, and their environmentally non-polluting nature. A number of programs targeting Aedes and Anopheles mosquitoes, vectors of human arboviruses and malaria respectively, are currently being developed or deployed in many parts of the world. Operationally implementing these technologies on a large scale however, beyond proof-of-concept pilot programs, is hampered by the absence of adequate sex separation methods. Sex separation eliminates females in the laboratory from male mosquitoes prior to release. Despite the need for sex separation for the control of mosquitoes, there have been limited efforts in recent years in developing systems that are fit-for-purpose. In this special issue of Parasites and Vectors we report on the progress of the global Coordinated Research Program on "Exploring genetic, molecular, mechanical and behavioural methods for sex separation in mosquitoes" that is led by the Insect Pest Control Subprogramme of the Joint FAO/IAEA Division of Nuclear Techniques in Food and Agriculture with the specific aim of building efficient sex separation systems for mosquito species. In an effort to overcome current barriers we briefly highlight what we believe are the three main reasons why progress has been so slow in developing appropriate sex separation systems: the availability of methods that are not scalable, the difficulty of building the ideal genetic systems and, finally, the lack of research efforts in this area.