Abstract
BackgroundBreed-specific effects are observed when the same allele of a given genetic marker has a different effect depending on its breed origin, which results in different allele substitution effects across breeds. In such a case, single-breed breeding values may not be the most accurate predictors of crossbred performance. Our aim was to estimate the contribution of alleles from each parental breed to the genetic variance of traits that are measured in crossbred offspring, and to compare the prediction accuracies of estimated direct genomic values (DGV) from a traditional genomic selection model (GS) that are trained on purebred or crossbred data, with accuracies of DGV from a model that accounts for breed-specific effects (BS), trained on purebred or crossbred data. The final dataset was composed of 924 Large White, 924 Landrace and 924 two-way cross (F1) genotyped and phenotyped animals. The traits evaluated were litter size (LS) and gestation length (GL) in pigs.ResultsThe genetic correlation between purebred and crossbred performance was higher than 0.88 for both LS and GL. For both traits, the additive genetic variance was larger for alleles inherited from the Large White breed compared to alleles inherited from the Landrace breed (0.74 and 0.56 for LS, and 0.42 and 0.40 for GL, respectively). The highest prediction accuracies of crossbred performance were obtained when training was done on crossbred data. For LS, prediction accuracies were the same for GS and BS DGV (0.23), while for GL, prediction accuracy for BS DGV was similar to the accuracy of GS DGV (0.53 and 0.52, respectively).ConclusionsIn this study, training on crossbred data resulted in higher prediction accuracy than training on purebred data and evidence of breed-specific effects for LS and GL was demonstrated. However, when training was done on crossbred data, both GS and BS models resulted in similar prediction accuracies. In future studies, traits with a lower genetic correlation between purebred and crossbred performance should be included to further assess the value of the BS model in genomic predictions.
Highlights
Breed-specific effects are observed when the same allele of a given genetic marker has a different effect depending on its breed origin, which results in different allele substitution effects across breeds
The estimate of the breed-specific additive genetic variance was slightly larger for alleles that were inherited from the Large White (LW) population compared to alleles that were inherited from the LR population, the standard errors were high (0.74 ± 0.23 and 0.56 ± 0.24 for litter size (LS), and 0.42 ± 0.08 and 0.40 ± 0.08 for gestation length (GL), respectively)
The highest accuracy for predicting the performance of crossbred sows was observed when training was done on crossbred data (Table 4), for which the genomic selection model (GS) and breed-specific effects (BS) models resulted in similar prediction accuracies
Summary
Breed-specific effects are observed when the same allele of a given genetic marker has a different effect depending on its breed origin, which results in different allele substitution effects across breeds In such a case, single-breed breeding values may not be the most accurate predictors of crossbred performance. Selection takes place in purebred lines and genetic evaluations are performed mainly with information that is collected on purebreds, in high-health environments, the final product of the pig industry is a crossbred animal. This strategy may not be optimal when the objective is to improve crossbred. When breed-specific effects are present, allele substitution effects will differ between breeds, and the breeding values that are estimated by using only data from one of the purebred parental line may not accurately predict crossbred performance
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