Genomic prediction in pigs using data from a commercial crossbred population: insights from the Duroc x (Landrace x Yorkshire) three-way crossbreeding system

Liu, Siyi; Yao, T. S.; Chen, Dong; Xiao, Shijun; Chen, Liqing; Zhang, Zhiyan

doi:10.1186/s12711-023-00794-2

Cited by 3 publications

(1 citation statement)

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“…Commercial data are also recorded in the target environment for production, so that the genotype-by-environment interaction between stud and commercial environments is no longer an issue (e.g. [ 36 ]). However in tropical beef populations, often little is known about breed composition or the heterosis of these animals, and limited or no pedigree is available, so that models such as ssBLUP and metafounders cannot be readily applied.…”

Section: Introductionmentioning

confidence: 99%

Multi-breed genomic evaluation for tropical beef cattle when no pedigree information is available

Hayes,

Copley,

Dodd

et al. 2023

Genet Sel Evol

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Background It has been challenging to implement genomic selection in multi-breed tropical beef cattle populations. If commercial (often crossbred) animals could be used in the reference population for these genomic evaluations, this could allow for very large reference populations. In tropical beef systems, such animals often have no pedigree information. Here we investigate potential models for such data, using marker heterozygosity (to model heterosis) and breed composition derived from genetic markers, as covariates in the model. Models treated breed effects as either fixed or random, and included genomic best linear unbiased prediction (GBLUP) and BayesR. A tropically-adapted beef cattle dataset of 29,391 purebred, crossbred and composite commercial animals was used to evaluate the models. Results Treating breed effects as random, in an approach analogous to genetic groups allowed partitioning of the genetic variance into within-breed and across breed-components (even with a large number of breeds), and estimation of within-breed and across-breed genomic estimated breeding values (GEBV). We demonstrate that moderately-accurate (0.30–0.43) GEBV can be calculated using these models. Treating breed effects as random gave more accurate GEBV than treating breed as fixed. A simple GBLUP model where no breed effects were fitted gave the same accuracy (and correlations of GEBV very close to 1) as a model where GEBV for within-breed and the GEBV for (random) across-breed effects were included. When GEBV were predicted for herds with no data in the reference population, BayesR resulted in the highest accuracy, with 3% accuracy improvement averaged across traits, especially when the validation population was less related to the reference population. Estimates of heterosis from our models were in line with previous estimates from beef cattle. A method for estimating the number of effective breed comparisons for each breed combination accumulated across contemporary groups is presented. Conclusions When no pedigree is available, breed composition and heterosis for inclusion in multi-breed genomic evaluation can be estimated from genotypes. When GEBV were predicted for herds with no data in the reference population, BayesR resulted in the highest accuracy.

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Section: Introductionmentioning

confidence: 99%