The dual resistance mechanism of CYP325G4 and CYP6AA9 in Culex pipiens pallens legs according to transcriptome and proteome analysis

Mosquitoes within the Culex pipiens complex play a crucial role in human disease transmission. Insecticides, especially pyrethroids, are used to control these vectors. Mosquito legs are the main entry point and barrier for insecticides to gain their neuronal targets. However, the resistance mechanism in mosquito legs is unclear. Herein, we employed transcriptomic analyses and isobaric tags for relative and absolute quantitation techniques to investigate the resistance mechanism, focusing on Cx. pipiens legs. We discovered 2346 differentially expressed genes (DEGs) between deltamethrin-resistant (DR) and deltamethrin-sensitive (DS) mosquito legs, including 41 cytochrome P450 genes. In the same comparison, we identified 228 differentially expressed proteins (DEPs), including six cytochrome P450 proteins). Combined transcriptome and proteome analysis revealed only two upregulated P450 genes, CYP325G4 and CYP6AA9. The main clusters of DEGs and DEPs were associated with metabolic processes, such as cytochrome P450-mediated metabolism of drugs and xenobiotics. Transcription analysis revealed high CYP325G4 and CYP6AA9 expression in the DR strain at 72 hours post-eclosion compared with that in the DS strain, particularly in the legs. Mosquitoes knocked down for CYP325G4 were more sensitive to deltamethrin than the controls. CYP325G4 knockdown reduced the expression of several chlorinated hydrocarbon (CHC)-related genes, which altered the cuticle thickness and structure. Conversely, CYP6AA9 knockdown increased CHC gene expression without altering cuticle thickness and structure. P450 activity analysis demonstrated that CYP325G4 and CYP6AA9 contributed to metabolic resistance in the midgut and legs. This study identified CYP325G4 as a novel mosquito deltamethrin resistance factor, being involved in both metabolic and cuticular resistance mechanisms. The previously identified CYP6AA9 was investigated for its involvement in metabolic resistance and potential cuticular resistance in mosquito legs. These findings enhance our comprehension of resistance mechanisms, identifying P450s as promising targets for the future management of mosquito vector resistance, and laying a theoretical groundwork for mosquito resistance management. Author SummaryCulex pipiens mosquitoes are the primary vector of the filamentous nematode, Wuchereria bancrofti and also involved in the transmission of other pathogens, such as West Nile virus (WNV), avian malarias, and avian pox virus. Insecticides, particularly pyrethroids, continue to be the primary method to control these significant vectors. Worryingly, resistance to insecticides has become widespread and is rapidly intensifying in Culex mosquitoes throughout China, posing a threat to the efficacy of insecticides. Legs are the main sites of contact with ITNs and sprayed insecticides, and the insecticides have to penetrate the leg cuticle to reach their targets.Therefore, the resistance mechanisms in mosquito legs deserve further investigation. Several reports have found a certain amount of P450 in insect legs. Unfortunately, none of the above reports have conducted further functional studies on P450s in the legs. Here, we have identified two P450 enzymes, CYP325G4 and CYP6AA9, through the integrated analysis of transcriptomics and proteomics. CYP325G4 enriched in the cuticle of resistant mosquitoes might possess a dual resistance mechanism involving metabolic resistance and cuticle resistance. CYP6AA9 was slightly different, possibly exerting metabolic resistance as its main function and also being involved in cuticle synthesis. Understanding the dual resistance mechanism of P450s in the metabolism of pyrethroid insecticides will have an important role in optimizing vector control strategies.