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Background: Mosquitoes are major vectors of arboviruses and other vector-borne diseases, making them a significant public health concern worldwide. Mitigation of arboviral outbreaks relies largely on the use of insecticides, but the effectiveness of such responses is threatened by the evolution of insecticide resistance. Monitoring mosquito susceptibility to different insecticides is therefore vital for informed decisions regarding outbreak responses. In this study, we elucidate the patterns of resistance to two insecticide classes within the primary vectors of West Nile virus in the northeast and midwestern regions of the continental United States, Culex pipiens and Culex restuans. Methodology/Principal Findings: Egg collections were performed throughout Illinois from 2018-2020, and adults were tested for insecticide resistance to permethrin and malathion. Individuals from each sampling location were sequenced to determine the presence of kdr target-site mutations, and biochemical assays were performed to determine increases in detoxification enzymes and insensitive acetylcholinesterase. Results from the bottle assays indicate variable resistance rates in Illinois, however lowered mortality was found in most of the regions that were tested. The kdr mutation (L1014F) was present in 50% of Culex pipiens sequenced, and more prevalent in southern Illinois compared with northern and central (p < 0.001). Different mechanisms were predictive of resistance by species and insecticide, with permethrin resistance being affected by kdr-allele frequency and oxidase levels and malathion resistance by α- and β-esterases in Culex pipiens. For Culex restuans α-esterase and oxidase levels were predictive of permethrin resistance while β-esterase and insensitive acetylcholinesterase levels were predictive of malathion resistance. Conclusions/Significance: We documented variation in insecticide resistance levels that appear to be driven by population differences in kdr mutation rates and metabolic resistance mechanisms. The presence of different mechanisms in species and regions has implications for approaches to resistance management and highlights the need to implement and maintain insecticide resistance monitoring practices.
Noel et al. (Sat,) studied this question.