Developing African arbovirus networks and capacity strengthening in arbovirus surveillance and response: findings from a virtual workshop

This meeting report presents the key findings and discussion points of a 3-h virtual workshop, held on 21 September 2022, and organized by the "Resilience Against Future Threats through Vector Control (RAFT)" research consortium. The workshop aimed to identify priorities for advancing arbovirus research, network and capacity strengthening in Africa. Due to increasing human population growth, urbanization and global movement (trade, tourism, travel), mosquito-borne arboviral diseases, such as dengue, Chikungunya and Zika, are increasing globally in their distribution and prevalence. This report summarizes the presentations that reviewed the current status of arboviruses in Africa, including: (i) key findings from the recent WHO/Special Programme for Research & Training in Tropical Diseases (WHO/TDR) survey in 47 African countries that revealed deep and widespread shortfalls in the capacity to cope with arbovirus outbreak preparedness, surveillance and control; (ii) the value of networking in this context, with examples of African countries regarding arbovirus surveillance; and (iii) the main priorities identified by the breakout groups on "research gaps", "networks" and "capacity strengthening"

Study of cuticular resistance in Anopheles gambiae

La gestion de la résistance aux insecticides et plus particulièrement aux pyréthrinoïdes chez les vecteurs du paludisme est un enjeu majeur pour conserver les acquis de la lutte antivectorielle contre le paludisme. Parmi les mécanismes de résistance, de nombreux travaux ont porté sur les mutations de la cible insecticides (kdr) ou encore les enzymes qui métabolisent les molécules insecticides. La résistance cuticulaire chez Anopheles gambiae a jusqu'à ce jour au mieux été suspectée mais pas démontrée. Dans ce cadre, le but de ce travail était donc de déterminer i) s’il y a une implication de la cuticule dans le phénotype résistant d’Anopheles gambiae aux pyréthrinoïdes ; ii) de déterminer les principaux acteurs de cette résistance. Nous avons construit une souche d’Anopheles gambiae présentant un phénotype résistant (MRS) mais ne portant pas la mutation kdr. Notre approche a été d’étudier l’expression des gènes, mais aussi celle des protéines de la cuticule et celles intervenant dans la détoxication. L’ultrastructure de la cuticule, sa composition en chaines hydrocarbonées ainsi que sa perméabilité à la deltaméthrine ont aussi été testés. Nous avons montré que la cuticule est impliquée dans le phénotype résistant plus particulièrement en réduisant significativement la pénétration de la deltaméthrine dans le corps de l’insecte. La structure même de la cuticule est profondément modifiée chez MRS. Nos résultats indiquent l’implication des membres de la famille CPAP3 dans la résistance cuticulaire et probablement des chaines hydrocarbonées. Des enzymes métaboliques sont également impliqués. Au cours de ce travail, nous avons démontré l’existence de la résistance cuticulaire chez An.gambiae, ce mécanisme agit de concert avec les mécanismes de détoxication. La caractérisation des différents acteurs nous permettra surement de trouver de nouvelles cibles pour la lutte anti-vectorielle.Mots clés : Résistance, cuticule, An.gambiae, deltaméthrine, ultrastructure, perméabilité, protéinesThe management of Anopheles insecticide resistance, especially to pyrethroids, is a key challenge to preserve success of vector control against malaria. Among resistance mechanisms target site mutation (kdr) and metabolic resistance are well known. Cuticular resistance in malaria vectors has been overlooked, just suggested but not established so far. The aim of this PhD work was to demonstrate i) the involvement of cuticle in pyrethroid resistance in An. gambiae; ii) to determine which components act on this mechanism. To achieve this, we built An.gambiae strain resistant to pyrethroids and free of kdr mutation (MRS). We studied both cuticular and metabolic genes and proteins expressions by transcriptomic and proteomic approaches. Cuticle ultrastructure and biochemical composition were also investigated. At least, cuticle permeability to deltamethrin was also assessed. Our results showed that cuticle is involved in resistant phenotype in An.gambiae. MRS cuticle reduces insecticide uptake in the mosquito’s body linked to an increasing cuticle thickness in MRS. Expression and chemical studies revealed that CPAP3 family and epicuticular hydrocarbons takes part in this process. This work also suggested that metabolic enzymes act together with cuticular mechanism to resistant phenotype. How the different components interacts could improve our knowledge of resistance and bring new target for vector control.Keywords: Resistance, cuticle, An.gambiae, deltamethrin, ultrastructure, permeability, protein

Susceptibility profile and metabolic mechanisms involved in Aedes aegypti and Aedes albopictus resistant to DDT and deltamethrin in the Central African Republic

Abstract Background Aedes aegypti and Ae. albopictus are the main epidemic vectors of dengue, chikungunya and Zika viruses worldwide. Their control during epidemics relies mainly on control of larvae and adults with insecticides. Unfortunately, loss of susceptibility of both species to several insecticide classes limits the efficacy of interventions. In Africa, where Aedes-borne viruses are of growing concern, few data are available on resistance to insecticides. To fill this gap, we assessed the susceptibility to insecticides of Ae. aegypti and Ae. albopictus populations in the Central African Republic (CAR) and studied the mechanisms of resistance. Methods Immature stages were sampled between June and September 2014 in six locations in Bangui (the capital of CAR) for larval and adult bioassays according to WHO standard procedures. We also characterized DDT- and pyrethroid-resistant mosquitoes molecularly and biochemically, including tests for the activities of nonspecific esterases (α and β), mixed-function oxidases, insensitive acetylcholinesterase and glutathione S-transferases. Results Larval bioassays, carried out to determine the lethal concentrations (LC50 and LC95) and resistance ratios (RR50 and RR95), suggested that both vector species were susceptible to Bacillus thuringiensis var. israeliensis and to temephos. Bioassays of adults showed susceptibility to propoxur and fenitrothion, except for one Ae. albopictus population that was suspected to be resistant to fenithrothion. None of the Ae. aegypti populations was fully susceptible to DDT. Ae. albopictus presented a similar profile to Ae. aegypti but with a lower mortality rate (41%). Possible resistance to deltamethrin was observed among Ae. aegypti and Ae. albopictus, although some were susceptible. No kdr mutations were detected in either species; however, the activity of detoxifying enzymes was higher in most populations than in the susceptible Ae. aegypti strain, confirming decreased susceptibility to DDT and deltamethrin. Conclusion These findings suggested that regular, continuous monitoring of resistance is necessary in order to select the most effective adulticides for arbovirus control in Bangui

Additional file 1: Table S1. of Susceptibility profile and metabolic mechanisms involved in Aedes aegypti and Aedes albopictus resistant to DDT and deltamethrin in the Central African Republic

Assessing association between resistance status and enzyme activities in Ae. aegypti. Table S2. Assessing association between resistance status and enzyme activities in Ae. abopictus. (DOC 135 kb