Casey Lee McNeil scite author profile

Genetic dissection of complex, polygenic trait variation is a key goal of medical and evolutionary genetics. Attempts to identify genetic variants underlying complex traits have been plagued by low mapping resolution in traditional linkage studies, and an inability to identify variants that cumulatively explain the bulk of standing genetic variation in genome-wide association studies (GWAS). Thus, much of the heritability remains unexplained for most complex traits. Here we describe a novel, freely available resource for the Drosophila community consisting of two sets of recombinant inbred lines (RILs), each derived from an advanced generation cross between a different set of eight highly inbred, completely resequenced founders. The Drosophila Synthetic Population Resource (DSPR) has been designed to combine the high mapping resolution offered by multiple generations of recombination, with the high statistical power afforded by a linkage-based design. Here, we detail the properties of the mapping panel of >1600 genotyped RILs, and provide an empirical demonstration of the utility of the approach by genetically dissecting alcohol dehydrogenase (ADH) enzyme activity. We confirm that a large fraction of the variation in this classic quantitative trait is due to allelic variation at the Adh locus, and additionally identify several previously unknown modest-effect trans-acting QTL (quantitative trait loci). Using a unique property of multiparental linkage mapping designs, for each QTL we highlight a relatively small set of candidate causative variants for follow-up work. The DSPR represents an important step toward the ultimate goal of a complete understanding of the genetics of complex traits in the Drosophila model system.

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Genetic Dissection of the Drosophila melanogaster Female Head Transcriptome Reveals Widespread Allelic Heterogeneity

King

et al. 2014

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Modern genetic mapping is plagued by the “missing heritability” problem, which refers to the discordance between the estimated heritabilities of quantitative traits and the variance accounted for by mapped causative variants. One major potential explanation for the missing heritability is allelic heterogeneity, in which there are multiple causative variants at each causative gene with only a fraction having been identified. The majority of genome-wide association studies (GWAS) implicitly assume that a single SNP can explain all the variance for a causative locus. However, if allelic heterogeneity is prevalent, a substantial amount of genetic variance will remain unexplained. In this paper, we take a haplotype-based mapping approach and quantify the number of alleles segregating at each locus using a large set of 7922 eQTL contributing to regulatory variation in the Drosophila melanogaster female head. Not only does this study provide a comprehensive eQTL map for a major community genetic resource, the Drosophila Synthetic Population Resource, but it also provides a direct test of the allelic heterogeneity hypothesis. We find that 95% of cis-eQTLs and 78% of trans-eQTLs are due to multiple alleles, demonstrating that allelic heterogeneity is widespread in Drosophila eQTL. Allelic heterogeneity likely contributes significantly to the missing heritability problem common in GWAS studies.

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Multiple Quantitative Trait Loci Influence the Shape of a Male-Specific Genital Structure inDrosophila melanogaster

McNeil

Bain

Macdonald

2011

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The observation that male genitalia diverge more rapidly than other morphological traits during evolution is taxonomically widespread and likely due to some form of sexual selection. One way to elucidate the evolutionary forces acting on these traits is to detail the genetic architecture of variation both within and between species, a program of research that is considerably more tractable in a model system. Drosophila melanogaster and its sibling species, D. simulans, D. mauritiana, and D. sechellia, are morphologically distinguishable only by the shape of the posterior lobe, a male-specific elaboration of the genital arch. We extend earlier studies identifying quantitative trait loci (QTL) responsible for lobe divergence across species and report the first genetic dissection of lobe shape variation within a species. Using an advanced intercross mapping design, we identify three autosomal QTL contributing to the difference in lobe shape between a pair of D. melanogaster inbred lines. The QTL each contribute 4.6–10.7% to shape variation, and two show a significant epistatic interaction. Interestingly, these intraspecific QTL map to the same locations as interspecific lobe QTL, implying some shared genetic control of the trait within and between species. As a first step toward a mechanistic understanding of natural lobe shape variation, we find an association between our QTL data and a set of genes that show sex-biased expression in the developing genital imaginal disc (the precursor of the adult genitalia). These genes are good candidates to harbor naturally segregating polymorphisms contributing to posterior lobe shape.

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Dissection of Complex, Fitness-Related Traits in MultipleDrosophilaMapping Populations Offers Insight into the Genetic Control of Stress Resistance

Everman

McNeil

Hackett

et al. 2019

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Dissection of complex, fitness-related traits in multiple Drosophila mapping populations offers insight into the genetic control of stress resistance

Everman

McNeil

Hackett

et al. 2018

Preprint

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44We leverage two complementary Drosophila melanogaster mapping panels to genetically dissect 45 starvation resistance, an important fitness trait. Using >1600 genotypes from the multiparental 46Drosophila Synthetic Population Resource (DSPR) we map numerous starvation stress QTL that 47 the DGRP. We found strong phenotypic correlations among studies, but extremely low overlap 59 in the sets of genomewide significant sites. Despite this, our analyses revealed that the most 60 highly-associated variants from each study typically showed the same additive effect sign in 61 independent studies, in contrast to otherwise equivalent sets of random variants. This 62 consistency provides evidence for reproducible trait-associated sites in a widely-used mapping 63 panel, and highlights the polygenic nature of starvation resistance. 64 65 Periods of food scarcity and suboptimal nutrient resources present an important 66 challenge for nearly all species (McCue 2010), and this form of environmental stress can limit the 67 survival of individuals with poor nutritional status and reduced stress resistance (Harshman et al. 68 1999;Lee and Jang 2014). As a result, starvation stress resistance has direct implications for the 69 fitness of individuals as they experience resource variability in natural populations. Starvation 70 resistance is a classic quantitative, fitness-related trait that is associated with several other 71 phenotypes that influence survival, lifespan, and reproduction (Service and Rose 1985; Da Lage 72 et al

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Casey Lee McNeil

Genetic dissection of a model complex trait using the Drosophila Synthetic Population Resource

Genetic Dissection of the Drosophila melanogaster Female Head Transcriptome Reveals Widespread Allelic Heterogeneity

Multiple Quantitative Trait Loci Influence the Shape of a Male-Specific Genital Structure inDrosophila melanogaster

Dissection of Complex, Fitness-Related Traits in MultipleDrosophilaMapping Populations Offers Insight into the Genetic Control of Stress Resistance

Dissection of complex, fitness-related traits in multiple Drosophila mapping populations offers insight into the genetic control of stress resistance

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