Fine-mapping nicotine resistance loci in Drosophila using a multiparent advanced generation inter-cross population

Fine-mapping nicotine resistance loci in Drosophila using a multiparent advanced generation inter-cross population

Animals in nature are frequently challenged by toxic compounds, from those that occur naturally in plants as a defense against herbivory, to pesticides used to protect crops. On exposure to such xenobiotic substances, animals mount a transcriptional response, generating detoxification enzymes and tr...

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Published in:Genetics (Austin) Vol. 198; no. 1; pp. 45 - 57
Main Authors: Marriage, Tara N, King, Elizabeth G, Long, Anthony D, Macdonald, Stuart J
Format: Journal Article
Language:English
Published: United States Genetics Society of America 01-09-2014
Subjects:
Animal behavior
Animals
Chromosome Mapping
Cytochrome P-450 Enzyme System - genetics
Drosophila melanogaster
Drosophila melanogaster - drug effects
Drosophila melanogaster - genetics
Drug Resistance - genetics
Gene loci
Genes
Glycosyltransferases - genetics
Inbreeding
Insects
Multiparental Populations
Nicotine
Nicotine - pharmacology
Polymorphism
Quantitative Trait Loci
Multiparent Advanced Generation Inter-Cross (MAGIC)
DSPR
quantitative genetics
nicotine
RIL
Multiparental populations
complex traits
MPP
Drosophila melanogaster
RNAseq
QTL mapping
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Summary:Animals in nature are frequently challenged by toxic compounds, from those that occur naturally in plants as a defense against herbivory, to pesticides used to protect crops. On exposure to such xenobiotic substances, animals mount a transcriptional response, generating detoxification enzymes and transporters that metabolize and remove the toxin. Genetic variation in this response can lead to variation in the susceptibility of different genotypes to the toxic effects of a given xenobiotic. Here we use Drosophila melanogaster to dissect the genetic basis of larval resistance to nicotine, a common plant defense chemical and widely used addictive drug in humans. We identified quantitative trait loci (QTL) for the trait using the DSPR (Drosophila Synthetic Population Resource), a panel of multiparental advanced intercross lines. Mapped QTL collectively explain 68.4% of the broad-sense heritability for nicotine resistance. The two largest-effect loci-contributing 50.3 and 8.5% to the genetic variation-map to short regions encompassing members of classic detoxification gene families. The largest QTL resides over a cluster of ten UDP-glucuronosyltransferase (UGT) genes, while the next largest QTL harbors a pair of cytochrome P450 genes. Using RNAseq we measured gene expression in a pair of DSPR founders predicted to harbor different alleles at both QTL and showed that Ugt86Dd, Cyp28d1, and Cyp28d2 had significantly higher expression in the founder carrying the allele conferring greater resistance. These genes are very strong candidates to harbor causative, regulatory polymorphisms that explain a large fraction of the genetic variation in larval nicotine resistance in the DSPR.
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ISSN:1943-2631
0016-6731
1943-2631
DOI:10.1534/genetics.114.162107