Mary Kefi scite author profile

Malaria incidence has halved since the year 2000, with 80% of the reduction attributable to the use of insecticides. However, insecticide resistance is now widespread, is rapidly increasing in spectrum and intensity across Africa, and may be contributing to the increase of malaria incidence in 2018. The role of detoxification enzymes and target site mutations has been documented in the major malaria vector Anopheles gambiae ; however, the emergence of striking resistant phenotypes suggests the occurrence of additional mechanisms. By comparing legs, the most relevant insect tissue for insecticide uptake, we show that resistant mosquitoes largely remodel their leg cuticles via enhanced deposition of cuticular proteins and chitin, corroborating a leg-thickening phenotype. Moreover, we show that resistant female mosquitoes seal their leg cuticles with higher total and different relative amounts of cuticular hydrocarbons, compared with susceptible ones. The structural and functional alterations in Anopheles female mosquito legs are associated with a reduced uptake of insecticides, substantially contributing to the resistance phenotype.

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Transcriptomic analysis of resistance and short-term induction response to pyrethroids, in Anopheles coluzzii legs

Kefi

Charamis

Balabanidou

et al. 2021

BMC Genomics

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Background Insecticide-treated bed nets and indoor residual spraying comprise the major control measures against Anopheles gambiae sl, the dominant vector in sub-Saharan Africa. The primary site of contact with insecticide is through the mosquitoes’ legs, which represents the first barrier insecticides have to bypass to reach their neuronal targets. Proteomic changes and leg cuticle modifications have been associated with insecticide resistance that may reduce the rate of penetration of insecticides. Here, we performed a multiple transcriptomic analyses focusing on An. coluzzii legs. Results Firstly, leg-specific enrichment analysis identified 359 genes including the pyrethroid-binder SAP2 and 2 other chemosensory proteins, along with 4 ABCG transporters previously shown to be leg enriched. Enrichment of gene families included those involved in detecting chemical stimuli, including gustatory and ionotropic receptors and genes implicated in hydrocarbon-synthesis. Subsequently, we compared transcript expression in the legs of a highly resistant strain (VK7-HR) to both a strain with very similar genetic background which has reverted to susceptibility after several generations without insecticide pressure (VK7-LR) and a lab susceptible population (NG). Two hundred thirty-two differentially expressed genes (73 up-regulated and 159 down-regulated) were identified in the resistant strain when compared to the two susceptible counterparts, indicating an over-expression of phase I detoxification enzymes and cuticular proteins, with decrease in hormone-related metabolic processes in legs from the insecticide resistant population. Finally, we analysed the short-term effect of pyrethroid exposure on An. coluzzii legs, comparing legs of 1 h-deltamethrin-exposed An. coluzzii (VK7-IN) to those of unexposed mosquitoes (VK7-HR) and identified 348 up-regulated genes including those encoding for GPCRs, ABC transporters, odorant-binding proteins and members of the divergent salivary gland protein family. Conclusions The data on An. coluzzii leg-specific transcriptome provides valuable insights into the first line of defense in pyrethroid resistant and short-term deltamethrin-exposed mosquitoes. Our results suggest that xenobiotic detoxification is likely occurring in legs, while the enrichment of sensory proteins, ABCG transporters and cuticular genes is also evident. Constitutive resistance is primarily associated with elevated levels of detoxification and cuticular genes, while short-term insecticide-induced tolerance is linked with overexpression of transporters, GPCRs and GPCR-related genes, sensory/binding and salivary gland proteins.

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Two functionally distinct CYP4G genes of Anopheles gambiae contribute to cuticular hydrocarbon biosynthesis

Kefi

Balabanidou

Douris

et al. 2019

Insect Biochemistry and Molecular Biology

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Cuticular hydrocarbon (CHC) biosynthesis is a major pathway of insect physiology.In Drosophila melanogaster the cytochrome P450 CYP4G1 catalyses the insectspecific oxidative decarbonylation step, while in the malaria vector Anopheles gambiae, two CYP4Gs paralogues, CYP4G16 and CYP4G17 are present. Analysis of the subcellular localization of CYP4G17 and CYP4G16 in larval and pupal stages revealed that CYP4G16 preserves its PM localization across developmental stages analyzed; however CYPG17 is differentially localized in two distinct types of pupal oenocytes, presumably oenocytes of larval and adult developmental specificity.Western blot analysis showed the presence of two CYP4G17 forms, potentially associated with each oenocyte type. Both An. gambiae CYP4Gs were expressed in D. melanogaster flies in a Cyp4g1 silenced background in order to functionally characterize them in vivo. CYP4G16, CYP4G17 or their combination rescued the lethal phenotype of Cyp4g1-knock down flies, demonstrating that CYP4G17 is also a functional decarbonylase, albeit of somewhat lower efficiency than CYP4G16 in Drosophila. Flies expressing mosquito CYP4G16 and/or CYP4G17 produced similar CHC profiles to 'wild-type' flies expressing the endogenous CYP4G1, but they also produce very long-chain dimethyl-branched CHCs not detectable in wild type flies, suggesting that the specificity of the CYP4G enzymes contributes to determine the complexity of the CHC blend. In conclusion, both An. gambiae CYP4G enzymes contribute to the unique Anopheles CHC profile, which has been associated to defense, adult desiccation tolerance, insecticide penetration rate and chemical communication.

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Mary Kefi

Mosquitoes cloak their legs to resist insecticides

Transcriptomic analysis of resistance and short-term induction response to pyrethroids, in Anopheles coluzzii legs

Two functionally distinct CYP4G genes of Anopheles gambiae contribute to cuticular hydrocarbon biosynthesis

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