Biochemical profiling of functionally expressed CYP6P9 variants of the malaria vector Anopheles funestus with special reference to cytochrome b5 and its role in pyrethroid and coumarin substrate metabolism

Transcription factor B-H2 regulates CYP9J34 expression conveying deltamethrin resistance in Culex pipiens pallens

BACKGROUND

Mosquitoes are vectors of various diseases, posing significant health threats worldwide. Chemical pesticides, particularly pyrethroids like deltamethrin, are commonly used for mosquito control, but the emergence of resistant mosquito populations has become a concern. In the deltamethrin-resistant (DR) strain of Culex pipiens pallens, the highly expressed cytochrome P450 9 J34 (CYP9J34) gene is believed to play a role in resistance, yet the underlying mechanism remains unclear.

RESULTS

Quantitative polymerase chain reaction with reverse transcription (qRT-PCR) analysis revealed that the expression of CYP9J34 was 14.6-fold higher in DR strains than in deltamethrin-susceptible (DS) strains. The recombinant production of CYP9J34 protein of Cx. pipiens pallens showed that the protein could directly metabolize deltamethrin, yielding the major metabolite 4'-OH deltamethrin. Through dual luciferase reporter assays and RNA interference, the transcription factor homeobox protein B-H2-like (B-H2) was identified to modulate the expression of the CYP9J34 gene, contributing to mosquito resistance to deltamethrin.

CONCLUSIONS

Our findings demonstrate that the CYP9J34 protein could directly degrade deltamethrin, and the transcription factor B-H2 could regulate CYP9J34 expression, influencing the resistance of mosquitoes to deltamethrin. © 2023 Society of Chemical Industry.

Resilience of transfluthrin to oxidative attack by duplicated CYP6P9 variants known to confer pyrethroid resistance in the major malaria mosquito Anopheles funestus

Resistance to common pyrethroids, such as deltamethrin and permethrin is widespread in the malaria mosquito Anopheles funestus and mainly conferred by upregulated cytochrome P450 monooxygenases (P450s). In the pyrethroid resistant laboratory strain An. funestus FUMOZ-R the duplicated genes CYP6P9a and CYP6P9b are highly upregulated and have been shown to metabolize various pyrethroids, including deltamethrin and permethrin. Here, we recombinantly expressed CYP6P9a and CYP6P9b from An. funestus using a baculovirus expression system and evaluated the interaction of the multifluorinated benzyl pyrethroid transfluthrin with these enzymes by different approaches. First, by Michaelis-Menten kinetics in a fluorescent probe assay with the model substrate 7-benzyloxymethoxy-4-trifluoromethylcoumarin (BOMFC), we showed the inhibition of BOMFC metabolism by increasing concentrations of transfluthrin. Second, we tested the metabolic capacity of recombinantly expressed CYP6P9 variants to degrade transfluthrin utilizing UPLC-MS/MS analysis and detected low depletion rates, explaining the virtual lack of resistance of strain FUMOZ-R to transfluthrin observed in previous studies. However, as both approaches suggested an interaction of CYP6P9 variants with transfluthrin, we analyzed the oxidative metabolic fate and failed to detect hydroxylated transfluthrin, but low amounts of an M-2 transfluthrin metabolite. Based on the detected metabolite we hypothesize oxidative attack of the gem-dimethyl substituted cyclopropyl moiety, resulting in the formation of an allyl cation upon ring opening. In conclusion, these findings support the resilience of transfluthrin to P450-mediated pyrethroid resistance, and thus, reinforces its employment as an important resistance-breaking pyrethroid in resistance management strategies to control the major malaria vector An. funestus.

Sequential phase I metabolism of pyrethroids by duplicated CYP6P9 variants results in the loss of the terminal benzene moiety and determines resistance in the malaria mosquito Anopheles funestus

Pyrethroid resistance in Anopheles funestus is threatening the eradication of malaria. One of the major drivers of pyrethroid resistance in An. funestus are cytochrome P450 monooxygenases CYP6P9a and CYP6P9b, which are found upregulated in resistant An. funestus populations from Sub-Saharan Africa and are known to metabolise pyrethroids. Here, we have functionally expressed CYP6P9a and CYP6P9b variants and investigated their interactions with azole-fungicides and pyrethroids. Some azole fungicides such as prochloraz inhibited CYP6P9a and CYP6P9b at nanomolar concentrations, whereas pyrethroids were weak inhibitors (>100 μM). Amino acid sequence comparisons suggested that a valine to isoleucine substitution at position 310 in the active site cavity of CYP6P9a and CYP6P9b, respectively, might affect substrate binding and metabolism. We therefore swapped the residues by site directed mutagenesis to produce CYP6P9a^I310V and CYP6P9b^V310I. CYP6P9b^V310I produced stronger metabolic activity towards coumarin substrates and pyrethroids, particularly permethrin. The V310I mutation was previously also detected in a pyrethroid resistant field population of An. funestus in Benin. Additionally, we found the first metabolite of permethrin and deltamethrin after hydroxylation, 4'OH permethrin and 4'OH deltamethrin, were also suitable substrates for CYP6P9-variants, and were depleted by both enzymes to a higher extent than as their respective parent compounds (approximately 20% more active). Further, we found that both metabolites were toxic against An. funestus FANG (pyrethroid susceptible) but not towards FUMOZ-R (pyrethroid resistant) mosquitoes, the latter suggesting detoxification by overexpressed CYP6P9a and CYP6P9b. We confirmed by mass-spectrometric analysis that CYP6P9a and CYP6P9b are capable of cleaving phenoxybenzyl-ethers in type I pyrethroid permethrin and type II pyrethroid deltamethrin and that both enzymes preferentially metabolise trans-permethrin. This provides new insight into the metabolism of pyrethroids and a greater understanding of the molecular mechanisms of pyrethroid resistance in An. funestus.