Abstract

Knockdown resistance (<i>kdr</i>) and detoxification enzymes are major resistance mechanisms in insecticide-resistant <i>Aedes aegypti</i> throughout the world. Persistence of the resistance phenotype is associated with high fitness of resistance alleles in the absence of insecticide pressure. This study determined the relative fitness cost of three insecticide-resistant strains of <i>Aedes aegypti</i>-PMD, PMD-R, and UPK-R-and a hybrid under similar laboratory conditions in the absence of insecticide. The PMD strain is resistant to DDT with no <i>kdr</i> alleles; the PMD-R is resistant to DDT and permethrin with 1534C homozygous <i>kdr</i> alleles; and UPK-R is resistant to DDT, permethrin, and deltamethrin with 989P + 1016G homozygous alleles. The DDT-resistant PMD strain had the highest fitness compared with the two DDT/pyrethroid-resistant strains (PMD-R and UPK-R) and hybrid. Consistent fitness costs were observed in the DDT/pyrethroid-resistant strains and hybrid, including shorter wing length, reduced egg hatchability, shorter female lifespan, and shorter viability of eggs after storage, whereas no effect was observed on blood feeding rate. In addition, reduced egg production was observed in the PMD-R strain and prolonged developmental time was seen in the UPK-R strain. The corresponding hybrid that is heterozygous for <i>kdr</i> alleles was fitter than either of the homozygous mutant genotypes. This is in accordance with the high frequency of heterozygous genotypes observed in natural populations of <i>Ae. aegypti</i> in Chiang Mai city.