A Intergenic Structural Variation Exacerbates the Fitness Cost of P450-Based Metabolic Resistance in the Major African Malaria Vector

Overview

Journal Genes (Basel)

Publisher MDPI

Date 2022 Apr 23

PMID 35456432

Authors

Magellan Tchouakui

Leon M J Mugenzi

Murielle J Wondji

Micareme Tchoupo

Flobert Njiokou

Charles S Wondji

Affiliations

Soon will be listed here.

Abstract

Metabolic-based resistance to insecticides limit the control of medically important pests, and it is extremely detrimental in the ongoing struggle to control disease vectors. Elucidating the fitness cost of metabolic resistance in major malaria vectors is vital for successful resistance management. We established the fitness cost of the structural variant () between the duplicated P450s using the hybrid strain generated from the crossing between two laboratory strains. Furthermore, we assessed the cumulative impact of this marker with the duplicated P450 genes. We established that individuals that were homozygote for the resistant structural variant (SV) presented reduced fecundity and slow development relative to those that were homozygote for the susceptible SV. Furthermore, we observed that act additively with and to exacerbate the reduced fecundity and the increased development time of resistant mosquitoes since double/triple homozygote susceptible (SS/SS/SS) significantly laid more eggs and developed faster than other genotypes. Moreover, a restoration of susceptibility was noted over 10 generations in the insecticide-free environment with an increased proportion of susceptible individuals. This study highlights the negative impact of multiple P450-based resistance on the key physiological traits of malaria vectors. Such high fitness costs suggest that in the absence of selection pressure, the resistant individuals will be outcompeted in the field. Therefore, this should encourage future strategies based on the rotation of insecticides to reduce selection pressure and to slow the spread of pyrethroid resistance.

Citing Articles

Two highly selected mutations in the tandemly duplicated CYP6P4a and CYP6P4b genes drive pyrethroid resistance in Anopheles funestus in West Africa.

Tatchou-Nebangwa N, Mugenzi L, Muhammad A, Nebangwa D, Kouamo M, Tagne C BMC Biol. 2024; 22(1):286.

PMID: 39696366 PMC: 11657943. DOI: 10.1186/s12915-024-02081-y.

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