Your search keyword '"Norris, Rachel"' showing total 4 results

1. Isolation and characterization of the decreased cuticular penetration mechanism of fluralaner resistance in the house fly, Musca domestica.

Author

Scott JG, Baker OS, Dressel AE, Norris RH, and Burgess ER 4th

Subjects

Animals, Houseflies drug effects, Insecticides pharmacology, Insecticide Resistance, Isoxazoles pharmacology

Abstract

Decreased cuticular penetration has been documented as a mechanism of resistance in several insects, yet this mechanism remains poorly understood. Levels of resistance conferred, effects of the physicochemical properties on the manifestation of resistance and the effects of different routes of exposure are largely unknown. We recently selected a strain (FlurR) of house fly that was >11,000-fold resistance to fluralaner, and decreased cuticular penetration was one of the mechanisms of resistance (Norris et al., 2023). We sought to isolate the decreased penetration mechanism from FlurR into the background of the susceptible aabys strain, and to characterize the protection it conferred to fluralaner and other insecticides. We successfully isolated the decreased penetration mechanism and found that it conferred 7.1-fold resistance to fluralaner, and 1.4- to 4.9-fold cross-resistance to five other insecticides by topical application. Neither mass, metabolic lability, vapor pressure, nor logP explained the differences in the resistance ratios. The mechanism also conferred cross resistance by residual and feeding exposure, although at reduced levels compared to topical application. Remaining data gaps in our understanding of this mechanism are discussed., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

2. Selection and characterization of spinetoram resistance in field collected Drosophila melanogaster.

Author

Scott JG, Norris RH, Mertz RW, Dressel AE, and Loeb G

Subjects

Animals, Macrolides, Insecticides toxicity, Drosophila melanogaster, Insecticide Resistance genetics

Abstract

Insecticides are commonly employed in vineyards to control vinegar flies and limit sour rot disease. Widespread resistance to available insecticides is having a negative impact on managing Drosophila melanogaster populations, rendering control of sour rot more difficult. An insecticide registered for use in vineyards to which resistance is not yet widespread (at least in New York and Missouri) is spinetoram. Spinetoram targets the nicotinic acetylcholine receptor α6, and mutations in α6 have been associated with resistance in some insects. Our goals were to select for a spinetoram resistant strain of D. melanogaster (starting with field collected populations), characterize the resistance, and identify the mutation responsible. After five selections a strain (SpinR) with >190-fold resistance was obtained. Resistance could not be overcome by insecticide synergists, suggesting an altered target site was involved. We cloned and sequenced the α6 allele from the spinetoram resistant strain and identified a mutation causing a glycine to alanine change at amino acid 301 (equivalent position to the G275E mutation found in some spinosad/spinetoram resistant insects). This mutation was found at low levels in field populations, but increased with each selection until it became homozygous in SpinR. We discuss how the identification of the spinetoram resistance mutation can be used for resistance management., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

3. Selection for, and characterization of, fluralaner resistance in the house fly, Musca domestica.

Author

Norris RH, Baker OS, Burgess ER 4th, Tarone A, Gerry A, Trout Fryxell RT, Hinkle NC, Olds C, Boxler D, Wise KL, Machtinger ET, and Scott JG

Subjects

Animals, Humans, Insecticide Resistance genetics, Insecticides toxicity, Houseflies, Pyrethrins, Diptera

Abstract

House flies, Musca domestica (L), are the mechanical vector of >100 human and animal pathogens, including those that are antibiotic-resistant. Given that house flies are associated closely with human and livestock activity, they present medical and veterinary health concerns. Although there are numerous strategies for control of house fly populations, chemical control has been favored in many facilities. Products with pyrethroid active ingredients have been used predominantly for >35 years in space sprays. As a result, strong selection for pyrethroid resistance has led to reduced control of many populations. Reliance on a limited number of insecticides for decades has created fly control problems necessitating the discovery and formulation of new control chemistries. Fluralaner is a relatively new insecticide and acaricide (first reported in 2010), belonging to the isoxazoline class. These insecticides target the glutamate- and gamma-aminobutyric acid-gated (GABA) chloride channels, which is a different mode of action from other insecticides used against house flies. Although is it not currently registered for house fly control in the United States, previous work has shown that fluralaner is highly toxic to house flies and that there was limited cross-resistance found in laboratory strains having high levels of resistance to other insecticides. Herein, we characterized the time and age dependency of fluralaner toxicity, detected cross-resistance in populations from across the United States, and selected a highly resistant (>11,000-fold) house fly strain. We found that the fluralaner LD 50 of 18-24 h old flies was 2-fold higher than for 5-6 d old flies. This appears to be due to more rapid penetration of fluralaner into the 5-6 d old flies. Fluralaner resistance was inherited as an intermediate to incompletely dominant trait and was mapped to chromosomes 5 and 3. Resistance could be suppressed to 7-fold with piperonyl butoxide, suggesting that cytochrome P450 (CYP)-mediated detoxification was a major mechanism of resistance. Decreased penetration was also demonstrated as a mechanism of resistance. The utility of fluralaner for house fly control is discussed., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

4. Insecticide resistance in Drosophila melanogaster in vineyards and evaluation of alternative insecticides.

Author

Mertz RW, Hesler S, Pfannenstiel LJ, Norris RH, Loeb G, and Scott JG

Subjects

Animals, Drosophila melanogaster, Farms, Horses, Insecticide Resistance, Malathion, Insecticides pharmacology, Pyrethrins pharmacology

Abstract

Background: Cultivation of grapes is a major crop globally, particularly in support of the wine production industry which has significant economic impact in numerous countries. Sour rot is an economically important disease of grapes. It is caused by an interaction of yeast + acetic acid bacteria, and vectored by Drosophila spp. Substantial control of sour rot in wine grape vineyards has been achieved by control of Drosophila using insecticides such as zeta-cypermethrin. An outbreak of sour rot and high populations of Drosophila melanogaster were observed in 2018 in a vineyard in New York (Finger Lakes region), USA. Flies from this population were found to be resistant to zeta-cypermethrin (the active ingredient in Mustang Maxx®), but whether or not this was a widespread problem was not known. To determine if resistance was geographically limited, we surveyed populations of D. melanogaster collected from 11 vineyards across New York State and one in Missouri (USA). We also evaluated 19 alternative insecticides for their potential use for control of D. melanogaster, by determining their toxicity to a susceptible strain and by examining cross-resistance using a field-collected population., Results: There were high levels of resistance to zeta-cypermethrin, malathion, and acetamiprid found in all populations sampled. Resistance to zeta-cypermethrin and malathion was stable over 33 months. Results from two vineyards also suggested that resistance to spinetoram was starting to evolve. The alternative insecticides we evaluated had LC 50 values to the susceptible strain ranging from 0.65 to 15 000 ng·cm -2 ., Conclusion: Resistance to zeta-cypermethrin, malathion, and acetamiprid is geographically widespread and the levels of resistance are similar between early season and late season collections. Cross-resistance was detected against all the insecticides tested, with the lowest levels seen for broflanilide, fipronil, and flumethrin. These patterns of resistance/cross-resistance/multiple resistance are discussed in terms of selection within and outside of vineyards. The implications of these results to insecticide resistance monitoring and management are discussed., (© 2021 Society of Chemical Industry.)

Published

2022