Long-Term Resistance of Drosophila melanogaster to the Mushroom Toxin Alpha-Amanitin

Insect resistance to toxins exerts not only a great impact on our economy, but also on the ecology of many species. Resistance to one toxin is often associated with cross-resistance to other, sometimes unrelated, chemicals. In this study, we investigated mushroom toxin resistance in the fruit fly Dr...

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Bibliographic Details
Published in:PloS one 2015-05, Vol.10 (5), p.e0127569
Main Authors: Mitchell, Chelsea L, Yeager, Roger D, Johnson, Zachary J, D'Annunzio, Stephanie E, Vogel, Kara R, Werner, Thomas
Format: Article
Language:English
Subjects:
Agaricales
Agrochemicals
Alpha-Amanitin - toxicity
Amanitin
Animals
Basidiocarps
Body size
Costs
Cross-resistance
Culex pipiens
Culicidae
Cytochrome
Drosophila
Drosophila melanogaster
Drosophila melanogaster - drug effects
Drosophila melanogaster - genetics
Drosophila tripunctata
Ecology
Ecosystem
Ecosystem assessment
Ecosystems
Enzyme inhibitors
Evolution
Fecundity
Female
Fitness
Food
Fruit flies (Tephritidae)
Fruits
Genes
Genetic aspects
Impact analysis
India
Insecticide resistance
Insecticides
Insects
Kinases
Larva - drug effects
Larva - physiology
Larvae
Malaysia
Male
Mushroom Poisoning - genetics
Mushrooms
Mycotoxins - toxicity
Nematodes
Parasites
Pesticides
Phenotype
Physiological aspects
Taiwan
Toxins
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Summary:Insect resistance to toxins exerts not only a great impact on our economy, but also on the ecology of many species. Resistance to one toxin is often associated with cross-resistance to other, sometimes unrelated, chemicals. In this study, we investigated mushroom toxin resistance in the fruit fly Drosophila melanogaster (Meigen). This fruit fly species does not feed on mushrooms in nature and may thus have evolved cross-resistance to α-amanitin, the principal toxin of deadly poisonous mushrooms, due to previous pesticide exposure. The three Asian D. melanogaster stocks used in this study, Ama-KTT, Ama-MI, and Ama-KLM, acquired α-amanitin resistance at least five decades ago in their natural habitats in Taiwan, India, and Malaysia, respectively. Here we show that all three stocks have not lost the resistance phenotype despite the absence of selective pressure over the past half century. In response to α-amanitin in the larval food, several signs of developmental retardation become apparent in a concentration-dependent manner: higher pre-adult mortality, prolonged larva-to-adult developmental time, decreased adult body size, and reduced adult longevity. In contrast, female fecundity nearly doubles in response to higher α-amanitin concentrations. Our results suggest that α-amanitin resistance has no fitness cost, which could explain why the resistance has persisted in all three stocks over the past five decades. If pesticides caused α-amanitin resistance in D. melanogaster, their use may go far beyond their intended effects and have long-lasting effects on ecosystems.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0127569