Role of the kdr and super-kdr sodium channel mutations in pyrethroid resistance: correlation of allelic frequency to resistance level in wild and laboratory populations of horn flies (Haematobia irritans).

We report the isolation of cDNA clones containing the full 6.3-kb coding sequence of the para-type sodium channel gene of the housefly, Musca domestica. This gene has been implicated as the site of knockdown resistance (kdr), an important resistance mechanism that confers nerve insensitivity to DDT and pyrethroid insecticides. The cDNAs predict a polypeptide of 2108 amino acids with close sequence homology (92% identity) to the Drosophila para sodium channel, and around 50% homology to vertebrate sodium channels, Only one major splice form of the housefly sodium channel was detected, in contrast to the Drosophila para transcript which has been reported to undergo extensive alternative splicing. Comparative sequence analysis of housefly strains carrying kdr or the more potent super-kdr factor revealed two amino acid mutations that correlate with these resistance phenotypes. Both mutations are located in domain II of the sodium channel. A leucine to phenylalanine replacement in the hydro-phobic IIS6 transmembrane segment was found in two independent kdr strains and six super-kdr strains of diverse geographic origin, while an additional methionine to threonine replacement within the intracellular IIS4-S5 loop was found only in the super-kdr strains. Neither mutation was present in five pyrethroid-sensitive strains. The mutations suggest a binding site for pyrethroids at the intracellular mouth of the channel pore in a region known to be important for channel inactivation.

Pyrethroid insecticides interact with a variety of neurochemical processes, but not all of these actions are likely to be involved in the disruption of nerve function. Several lines of evidence suggest that the voltage-sensitive sodium channel is the single principal molecular target site for all pyrethroids and DDT analogs in both insects and mammals. The alterations of sodium channel functions identified in both biophysical and biochemical studies are directly related to the effects of these compounds on intact nerves. The pyrethroid recognition site of the sodium channel exhibits the stringent stereospecificity predicted by in vivo estimates of intrinsic neurotoxicity in both insects and mammals. Type I and Type II compounds produce qualitatively different effects on sodium channel tail currents, divergent actions on intact nerves, and different effects on the excitability of vertebrate skeletal muscle. Moreover, compounds that are defined as intermediate in the Type I/Type II classification scheme are also intermediate in their effects on sodium channel kinetics. The range of different actions on sensory and motor nerve pathways arising from these qualitatively different effects at the level of the sodium channel appear to be sufficient to explain the distinct poisoning syndromes that have been identified in both insects and mammals. Thus, it does not appear necessary to invoke different primary target sites for Type I and Type II compounds to explain their actions in whole animals. Although the voltage-sensitive sodium channel is likely to be the principal site of pyrethroid action, it is probably not the only site involved in intoxication. Insect neurosecretory neurons are sensitive to very low concentrations of pyrethroids, and disruption of the neuroendocrine system has been implicated as a factor contributing to the irreversible effects of pyrethroid intoxication in insects. Since action potentials in these nerves are carried by calcium ions through TTX-insensitive voltage-gated cation channels, these findings provide evidence that pyrethroids can alter neuronal excitability through an action on voltage-sensitive channels other than the sodium channel. Actions on voltage-sensitive calcium channels may also be involved in the effects of pyrethroids on neurotransmitter release in mammals. The proconvulsant actions of pyrethroids mediated through the peripheral-type benzodiazepine receptor may also contribute to pyrethroid intoxication. Both Type I and Type II compounds are potent proconvulsants in vivo at doses well below those required to produce pyrethroid-dependent intoxication.(ABSTRACT TRUNCATED AT 400 WORDS)

Previous behavioral, electrophysiological, pharmacological, and genetic studies of mutations of the para locus in Drosophila melanogaster suggested that these mutations alter the structure or function of sodium channels. To identify the protein encoded by this gene and to elucidate the molecular basis of the mutant phenotypes, genomic DNA from the para locus was cloned. Mutational lesions in nine different para alleles were mapped and found to be distributed over a region of 45 kb. Analysis of cDNAs revealed that the para locus comprises a minimum of 26 exons distributed over more than 60 kb of genomic DNA. The nucleotide sequence of the complementary DNA predicts a protein whose structure and amino acid sequence are extremely similar to those of vertebrate sodium channels. The results support the conclusion that para encodes a functionally predominant class of sodium channels in Drosophila neurons. Furthermore, the para transcript appears to undergo alternative splicing to produce several distinct subtypes of this channel.