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    Expression of insect α6-like nicotinic acetylcholine receptors in Drosophila melanogaster highlights a high level of conservation of the receptor:spinosyn interaction
    Perry, T ; Somers, J ; Yang, YT ; Batterham, P (PERGAMON-ELSEVIER SCIENCE LTD, 2015-09)
    Insecticide research has often relied on model species for elucidating the resistance mechanisms present in the targeted pests. The accuracy and applicability of extrapolations of these laboratory findings to field conditions varies but, for target site resistance, conserved mechanisms are generally the rule rather than the exception (Perry et al., 2011). The spinosyn class of insecticides appear to fit this paradigm and are a pest control option with many uses in both crop and animal protection. Resistance to spinosyns has been identified in both laboratory-selected and field-collected pest insects. Studies using the model insect, Drosophila melanogaster, have identified the nicotinic acetylcholine receptor subunit, Dα6 as an important target of the insecticide spinosad (Perry et al., 2007; Watson et al., 2010). Field-isolated resistant strains of several agricultural pest insects provide evidence that resistance cases are often associated with mutations in orthologues to Dα6 (Baxter et al., 2010; Puinean et al., 2013). The expression of these receptors is difficult in heterologous systems. In order to examine the biology of the Dα6 receptor subunit further, we used Drosophila as a model and developed an in vivo rescue system. This allowed us to express four different isoforms of Dα6 and show that each is able to rescue the response to spinosad. Regulatory sequences upstream of the Dα6 gene able to rescue the resistance phenotype were identified. Expression of other D. melanogaster subunits revealed that the rescue phenotype appears to be Dα6 specific. We also demonstrate that expression of pest insect orthologues of Dα6 from a variety of species are capable of rescuing the spinosad response phenotype, verifying the relevance of this receptor to resistance monitoring in the field. In the absence of a robust heterologous expression system, this study presents an in vivo model that will be useful in analysing many other aspects of these receptors and their biology.
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    The Wiggle Index: An Open Source Bioassay to Assess Sub-Lethal Insecticide Response in Drosophila melanogaster
    Denecke, S ; Nowell, CJ ; Fournier-Level, A ; Perry, T ; Batterham, P ; Guedes, RNC (PUBLIC LIBRARY SCIENCE, 2015-12-18)
    Toxicological assays measuring mortality are routinely used to describe insecticide response, but sub-lethal exposures to insecticides can select for resistance and yield additional biological information describing the ways in which an insecticide impacts the insect. Here we present the Wiggle Index (WI), a high-throughput method to quantify insecticide response by measuring the reduction in motility during sub-lethal exposures in larvae of the vinegar fly Drosophila melanogaster. A susceptible wild type strain was exposed to the insecticides chlorantraniliprole, imidacloprid, spinosad, and ivermectin. Each insecticide reduced larval motility, but response times and profiles differed among insecticides. Two sets of target site mutants previously identified in mortality studies on the basis of imidacloprid or spinosad resistance phenotypes were tested. In each case the resistant mutant responded significantly less than the control. The WI was also able to detect a spinosad response in the absence of the primary spinosad target site. This response was not detected in mortality assays suggesting that spinosad, like many other insecticides, may have secondary targets affecting behaviour. The ability of the WI to detect changes in insecticide metabolism was confirmed by overexpressing the imidacloprid metabolizing Cyp6g1 gene in digestive tissues or the central nervous system. The data presented here validate the WI as an inexpensive, generic, sub-lethal assay that can complement information gained from mortality assays, extending our understanding of the genetic basis of insecticide response in D. melanogaster.