Allelic variation and multigenic metabolic activity of cytochrome P450s confer insecticide resistance in field populations of anopheles funestus s.s., a major malaria vector in Africa

Ibrahim, Sulaiman Sadi
Allelic variation and multigenic metabolic activity of cytochrome P450s confer insecticide resistance in field populations of anopheles funestus s.s., a major malaria vector in Africa. PhD thesis, University of Liverpool.

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Malaria control relies heavily on the use of insecticides, especially the pyrethroids, for control interventions such as Long Lasting Insecticide Nets (LLINs) and Indoor Residual Spraying (ITNs). However, widespread resistance to insecticides in major malaria vectors, such as An. funestus is threatening to derail these control tools. To design and implement suitable resistance management strategies which will ensure the continued effectiveness of these control tools it is necessary to elucidate the molecular basis of the resistance. In An. funestus, resistance is mainly metabolic with the duplicated P450s CYP6P9a and CYP6P9b implicated as the major pyrethroid resistance genes. Despite the detection of these key resistance genes the detailed molecular mechanisms through which they confer pyrethroid resistance remain uncharacterised. Because CYP6P9a and CYP6P9b were shown to exhibit significant allelic variation between resistant and susceptible mosquitoes, we hypothesised that this allelic variation is potentially a key mechanism conferring pyrethroid resistance. Here, I characterised the role of these genes in the resistance to pyrethroids and identified other candidate genes which confer cross-resistance to non-pyrethroid insecticides. The role of allelic variation in pyrethroid resistance was investigated using polymorphism survery and in silico prediction of activity. Metabolic activities and efficiencies of allelic variants of CYP6P9a and CYP6P9b were investigated using fluorescent probes, metabolism assays and transgenic expression in D. melanogaster system. Pyrethroid resistance causative mutations were detected using the site-directed mutagenesis. Other candidate P450s that confer cross-resistance to pyrethroids carbamates and organochlorines were identified and characterised. This study revealed that CYP6P9a and CYP6P9b from resistant populations of An. funestus are undergoing directional selection with reduced genetic diversity and beneficial mutations selected, compared to the alleles from susceptible strain (FANG), which exhibited high genetic variation. Modelling and docking simulations predicted the alleles of CYP6P9a and CYP6P9b from the resistant strains all across Africa to metabolise pyrethroids with high efficiency while the susceptible alleles FANGCYP6P9a and FANGCYP6P9b were predicted to have low activity toward pyrethroids. Validation of the docking predictions with probes and metabolism assays established that the resistant alleles of CYP6P9a and CYP6P9b possess high activities toward pyrethroids with kinetic profiles significantly different (high affinity and catalytic efficiency) from those obtained from the FANG, indicating that allelic variation is playing a major role in pyrethroid resistance. These findings were further strengthened by results from transgenic expression with GAL4/UAS technology showing that flies expressing the resistant alleles of both genes were significantly more resistant to pyrethroids than those expressing the susceptible alleles. Using mutagenesis, three key residues (Val109, Asp335 and Asn384) from the resistant allele of CYP6P9b were established as the important amino acid changes responsible for resistance with impact on substrate channelling, possible enhancement of interaction with redox partners and inter-molecular hydrogen bonding interactions, respectively conferring high metabolic efficiency. The finding of these resistance markers make it possible to design a diagnostic tool that can allow detection and tracking of the resistant alleles in the field population of An. funestus across Africa. Other up-regulated P450s in multiple resistant populations from southern Africa were also characterised, revealing that pyrethroid resistance is mediated by other P450s as well: CYP6M7, CYP6Z1, CYP9J11 and CYP6AA4 all of which metabolise pyrethroids. CYP6Z1 and CYP9J11 are cross-resistance genes which metabolise bendiocarb, while CYP6Z1 metabolise DDT in addition. In conclusion, allelic variation is a key mechanism conferring pyrethroid resistance in An. funestus s.s. from sub-Saharan Africa. Key amino acid changes control pyrethroid resistance factors and these molecular markers can be used to design DNA-based diagnostic tests which will allow tracking of the resistance alleles in the field. Pyrethroid resistance is multi-genic in the field populations of An. funestus with other P450s involved apart from CYP6P9a and CYP6P9b. The finding of cross-resistance P450s is of concern to resistance management and should be taken into account when designing resistance management strategies.

Item Type: Thesis (PhD)
Additional Information: Date: 2015-01-22 (completed)
Subjects: ?? RZ ??
Depositing User: Symplectic Admin
Date Deposited: 01 Sep 2015 08:50
Last Modified: 17 Dec 2022 01:38
DOI: 10.17638/02008567