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Accounting for Genetic Architecture Improves Sequence Based Genomic Prediction for a Drosophila Fitness Trait

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  • Ulrike Ober
  • Wen Huang
  • Michael Magwire
  • Martin Schlather
  • Henner Simianer
  • Trudy F C Mackay

Abstract

The ability to predict quantitative trait phenotypes from molecular polymorphism data will revolutionize evolutionary biology, medicine and human biology, and animal and plant breeding. Efforts to map quantitative trait loci have yielded novel insights into the biology of quantitative traits, but the combination of individually significant quantitative trait loci typically has low predictive ability. Utilizing all segregating variants can give good predictive ability in plant and animal breeding populations, but gives little insight into trait biology. Here, we used the Drosophila Genetic Reference Panel to perform both a genome wide association analysis and genomic prediction for the fitness-related trait chill coma recovery time. We found substantial total genetic variation for chill coma recovery time, with a genetic architecture that differs between males and females, a small number of molecular variants with large main effects, and evidence for epistasis. Although the top additive variants explained 36% (17%) of the genetic variance among lines in females (males), the predictive ability using genomic best linear unbiased prediction and a relationship matrix using all common segregating variants was very low for females and zero for males. We hypothesized that the low predictive ability was due to the mismatch between the infinitesimal genetic architecture assumed by the genomic best linear unbiased prediction model and the true genetic architecture of chill coma recovery time. Indeed, we found that the predictive ability of the genomic best linear unbiased prediction model is markedly improved when we combine quantitative trait locus mapping with genomic prediction by only including the top variants associated with main and epistatic effects in the relationship matrix. This trait-associated prediction approach has the advantage that it yields biologically interpretable prediction models.

Suggested Citation

  • Ulrike Ober & Wen Huang & Michael Magwire & Martin Schlather & Henner Simianer & Trudy F C Mackay, 2015. "Accounting for Genetic Architecture Improves Sequence Based Genomic Prediction for a Drosophila Fitness Trait," PLOS ONE, Public Library of Science, vol. 10(5), pages 1-17, May.
    • Handle: RePEc:plo:pone00:0126880
    DOI: 10.1371/journal.pone.0126880
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    References listed on IDEAS

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    1. Lars M. Steinmetz & Himanshu Sinha & Dan R. Richards & Jamie I. Spiegelman & Peter J. Oefner & John H. McCusker & Ronald W. Davis, 2002. "Dissecting the architecture of a quantitative trait locus in yeast," Nature, Nature, vol. 416(6878), pages 326-330, March.
    2. Robert Makowsky & Nicholas M Pajewski & Yann C Klimentidis & Ana I Vazquez & Christine W Duarte & David B Allison & Gustavo de los Campos, 2011. "Beyond Missing Heritability: Prediction of Complex Traits," PLOS Genetics, Public Library of Science, vol. 7(4), pages 1-9, April.
    3. Juergen Kroymann & Thomas Mitchell-Olds, 2005. "Epistasis and balanced polymorphism influencing complex trait variation," Nature, Nature, vol. 435(7038), pages 95-98, May.
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    Cited by:

    1. Martini, Johannes W.R. & Toledo, Fernando H. & Crossa, José, 2020. "On the approximation of interaction effect models by Hadamard powers of the additive genomic relationship," Theoretical Population Biology, Elsevier, vol. 132(C), pages 16-23.

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