Efficiency of genomic prediction for boar taint reduction in Danish Landrace pigs
- PMID: 26449733
- PMCID: PMC4949655
- DOI: 10.1111/age.12369
Efficiency of genomic prediction for boar taint reduction in Danish Landrace pigs
Abstract
Genetic selection against boar taint, which is caused by high skatole and androstenone concentrations in fat, is a more acceptable alternative than is the current practice of castration. Genomic predictors offer an opportunity to overcome the limitations of such selection caused by the phenotype being expressed only in males at slaughter, and this study evaluated different approaches to obtain such predictors. Samples from 1000 pigs were included in a design which was dominated by 421 sib pairs, each pair having one animal with high and one with low skatole concentration (≥0.3 μg/g). All samples were measured for both skatole and androstenone and genotyped using the Illumina SNP60 porcine BeadChip for 62 153 single nucleotide polymorphisms. The accuracy of predicting phenotypes was assessed by cross-validation using six different genomic evaluation methods: genomic best linear unbiased prediction (GBLUP) and five Bayesian regression methods. In addition, this was compared to the accuracy of predictions using only QTL that showed genome-wide significance. The range of accuracies obtained by different prediction methods was narrow for androstenone, between 0.29 (Bayes Lasso) and 0.31 (Bayes B), and wider for skatole, between 0.21 (GBLUP) and 0.26 (Bayes SSVS). Relative accuracies, corrected for h(2) , were 0.54-0.56 and 0.75-0.94 for androstenone and skatole respectively. The whole-genome evaluation methods gave greater accuracy than using only the QTL detected in the data. The results demonstrate that GBLUP for androstenone is the simplest genomic technology to implement and was also close to the most accurate method. More specialised models may be preferable for skatole.
Keywords: Bayes; androstenone; genomic best linear unbiased prediction; genomic selection; skatole.
© 2015 The Authors. Animal Genetics published by John Wiley & Sons Ltd on behalf of Stichting International Foundation for Animal Genetics.
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References
-
- Andresen O. (1974) Development of a radioimmunoassay for 5‐andro‐16‐en‐one in pig peripheral plasma. Acta Endocrinologica 76, 377–87. - PubMed
-
- Babol J., Squires E. J. & Lundstrom K. (1999) Relationship between metabolism of androstenone and skatole in intact male pigs. Journal of Animal Science 77, 84–92. - PubMed
-
- Bonneau M. & Squires J. (2004) Boar taint: causes and measurement In: Encyclopedia of Meat Sciences (I–S). (Ed. by Jensen W.K., Devine C. & Dikemann M.), pp. 91–6. Elsevier, Oxford;
-
- Bonneau M., Dufour R., Chouvet C., Roulet C., Meadus W. & Squires E.J. (1994) The effects of immunization against luteinizing hormone‐releasing hormone on performance, sexual development, and levels of boar taint‐related compounds in intact male pigs. Journal of Animal Science 72, 14–20. - PubMed
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