Insecticide resistance in mosquitoes represents a notable challenge to public health efforts aimed at controlling vector-borne diseases. Among mosquito species, Aedes aegypti is particularly significant due to its extensive geographic spread and its ability to transmit arboviruses causing diseases such as dengue, yellow fever, Zika, and chikungunya (Brown et al., 2014). Insecticide resistance typically develops through two main mechanisms: target-site mutations, which affect the insecticide's interaction with its target, and metabolic resistance, in which insecticide detoxification is enhanced in mosquitoes. While target-site mutations are well characterized, the mechanisms underlying metabolic resistance are understudied. 

The study by Bacot and colleagues (2024) contributes to our understanding of the genetic and evolutionary mechanisms driving insecticide resistance, focusing on a case of metabolic resistance in Aedes aegypti from French Guiana. Following the recent identification of a copy number variant region on chromosome 1, potentially linked to overexpression of detoxification enzymes (Cattel et al., 2020), this study explores the region’s genomic architecture, its likely origin and provides compelling evidence for its role in insecticide resistance.

Through RNA sequencing and whole-genome pool sequencing, the authors reveal that this 220 kilobase duplication increases the expression level of several clustered P450 genes. Cytochrome P450s are known to play a role in breaking down pyrethroids like deltamethrin, a commonly used insecticide. The role of P450 enzymes in detoxification was demonstrated by treating mosquitoes with piperonyl butoxide, a P450 enzyme inhibitor, and observing reduction in deltamethrin resistance, further confirmed by RNA interference experiments. Despite the clear advantages of this genomic duplication in conferring resistance, the study also uncovers a fitness cost associated with carrying the duplication. Through experimental evolution, the authors find that mosquitoes with the duplication experience reduced fitness in the absence of insecticide pressure. Given the regions structural complexity, the authors could not completely disassociate the effect of the duplicated region and that of a target-site mutation. However, they developed an assay that can accurately track the presence of this resistance allele in mosquito populations. 

Altogether, the study by Bacot et al. (2024) highlights the challenges of characterizing the phenotypic effect of copy number variant regions in complex genomes, such as that of Aedes aegypti. It emphasizes the need for further studies on the origin and spread of this duplication to better understand how similar resistance mechanisms might evolve and disseminate. Overall, the completeness and coherence of the narrative, the detailed and thorough analysis, and the insightful discussion, make this work not only a significant contribution to the field of insecticide resistance but an interesting read for the general evolutionary biology community.   

References

Brown, J. E., Evans, B. R., Zheng, W., Obas, V., Barrera-Martinez, L., Egizi, A., Zhao, H., Caccone, A., & Powell, J. R. (2014). Human impacts have shaped historical and recent evolution in Aedes aegypti, the dengue and yellow fever mosquito. Evolution, 68(2), 514–525. https://doi.org/10.1111/evo.12281

Cattel, J., Faucon, F., Le Péron, B., Sherpa, S., Monchal, M., Grillet, L., Gaude, T., Laporte, F., Dusfour, I., Reynaud, S., & David, J. P. (2019). Combining genetic crosses and pool targeted DNA-seq for untangling genomic variations associated with resistance to multiple insecticides in the mosquito Aedes aegypti. Evolutionary applications, 13(2), 303–317. https://doi.org/10.1111/eva.12867

Tiphaine Bacot, Chloe Haberkorn, Joseph Guilliet, Julien Cattel, Mary Kefi, Louis Nadalin, Jonathan Filee, Frederic Boyer, Thierry Gaude, Frederic Laporte, Jordan Tutagata, John Vontas, Isabelle Dusfour, Jean-Marc Bonneville, Jean-Philippe David (2024) A genomic duplication spanning multiple P450s contributes to insecticide resistance in the dengue mosquito Aedes aegypti. bioRxiv, ver.5 peer-reviewed and recommended by PCI Evol Biol https://doi.org/10.1101/2024.04.03.587871