Genomic prediction based on selected variants from imputed whole-genome sequence data in Australian sheep populations

Moghaddar, Nasir; Khansefid, Majid; van der Werf, Julius H J; Bolormaa, Sunduimijid; Duijvesteijn, Naomi; Clark, Samuel A; Swan, Andrew A; Daetwyler, Hans D; MacLeod, Iona M

doi:10.1186/s12711-019-0514-2

Author(s)

Moghaddar, Nasir

Khansefid, Majid

van der Werf, Julius H J

Bolormaa, Sunduimijid

Duijvesteijn, Naomi

Clark, Samuel A

Swan, Andrew A

Daetwyler, Hans D

MacLeod, Iona M

Publication Date

2019-12-05

Abstract

Supplementary information accompanies this paper at https://doi.org/10.1186/s12711-019-0514-2

Abstract

Background: Whole-genome sequence (WGS) data could contain information on genetic variants at or in high linkage disequilibrium with causative mutations that underlie the genetic variation of polygenic traits. Thus far, genomic prediction accuracy has shown limited increase when using such information in dairy cattle studies, in which one or few breeds with limited diversity predominate. The objective of our study was to evaluate the accuracy of genomic prediction in a multi-breed Australian sheep population of relatively less related target individuals, when using information on imputed WGS genotypes. <br/> Methods: Between 9626 and 26,657 animals with phenotypes were available for nine economically important sheep production traits and all had WGS imputed genotypes. About 30% of the data were used to discover predictive single nucleotide polymorphism (SNPs) based on a genome-wide association study (GWAS) and the remaining data were used for training and validation of genomic prediction. Prediction accuracy using selected variants from imputed sequence data was compared to that using a standard array of 50k SNP genotypes, thereby comparing genomic best linear prediction (GBLUP) and Bayesian methods (BayesR/BayesRC). Accuracy of genomic prediction was evaluated in two independent populations that were each lowly related to the training set, one being purebred Merino and the other crossbred Border Leicester x Merino sheep. <br/> Results: A substantial improvement in prediction accuracy was observed when selected sequence variants were fitted alongside 50k genotypes as a separate variance component in GBLUP (2GBLUP) or in Bayesian analysis as a separate category of SNPs (BayesRC). From an average accuracy of 0.27 in both validation sets for the 50k array, the average absolute increase in accuracy across traits with 2GBLUP was 0.083 and 0.073 for purebred and crossbred animals, respectively, whereas with BayesRC it was 0.102 and 0.087. The average gain in accuracy was smaller when selected sequence variants were treated in the same category as 50k SNPs. Very little improvement over 50k prediction was observed when using all WGS variants. <br/> Conclusions: Accuracy of genomic prediction in diverse sheep populations increased substantially by using variants selected from whole-genome sequence data based on an independent multi-breed GWAS, when compared to genomic prediction using standard 50K genotypes.

Citation

Genetics Selection Evolution, 51(1), p. 1-14

ISSN

1297-9686

0999-193X

Pubmed ID

31805849

Link

https://hdl.handle.net/1959.11/28980

Language

en

Publisher

BioMed Central Ltd

Rights

Attribution 4.0 International

Title

Genomic prediction based on selected variants from imputed whole-genome sequence data in Australian sheep populations

Type of document

Journal Article

Entity Type

Publication

Author(s)	Moghaddar, Nasir Khansefid, Majid van der Werf, Julius H J Bolormaa, Sunduimijid Duijvesteijn, Naomi Clark, Samuel A Swan, Andrew A Daetwyler, Hans D MacLeod, Iona M
Publication Date	2019-12-05
Abstract	Supplementary information accompanies this paper at https://doi.org/10.1186/s12711-019-0514-2
Abstract	Background: Whole-genome sequence (WGS) data could contain information on genetic variants at or in high linkage disequilibrium with causative mutations that underlie the genetic variation of polygenic traits. Thus far, genomic prediction accuracy has shown limited increase when using such information in dairy cattle studies, in which one or few breeds with limited diversity predominate. The objective of our study was to evaluate the accuracy of genomic prediction in a multi-breed Australian sheep population of relatively less related target individuals, when using information on imputed WGS genotypes. <br/> Methods: Between 9626 and 26,657 animals with phenotypes were available for nine economically important sheep production traits and all had WGS imputed genotypes. About 30% of the data were used to discover predictive single nucleotide polymorphism (SNPs) based on a genome-wide association study (GWAS) and the remaining data were used for training and validation of genomic prediction. Prediction accuracy using selected variants from imputed sequence data was compared to that using a standard array of 50k SNP genotypes, thereby comparing genomic best linear prediction (GBLUP) and Bayesian methods (BayesR/BayesRC). Accuracy of genomic prediction was evaluated in two independent populations that were each lowly related to the training set, one being purebred Merino and the other crossbred Border Leicester x Merino sheep. <br/> Results: A substantial improvement in prediction accuracy was observed when selected sequence variants were fitted alongside 50k genotypes as a separate variance component in GBLUP (2GBLUP) or in Bayesian analysis as a separate category of SNPs (BayesRC). From an average accuracy of 0.27 in both validation sets for the 50k array, the average absolute increase in accuracy across traits with 2GBLUP was 0.083 and 0.073 for purebred and crossbred animals, respectively, whereas with BayesRC it was 0.102 and 0.087. The average gain in accuracy was smaller when selected sequence variants were treated in the same category as 50k SNPs. Very little improvement over 50k prediction was observed when using all WGS variants. <br/> Conclusions: Accuracy of genomic prediction in diverse sheep populations increased substantially by using variants selected from whole-genome sequence data based on an independent multi-breed GWAS, when compared to genomic prediction using standard 50K genotypes.
Citation	Genetics Selection Evolution, 51(1), p. 1-14
ISSN	1297-9686 0999-193X
Pubmed ID	31805849
Link	https://hdl.handle.net/1959.11/28980
Language	en
Publisher	BioMed Central Ltd
Rights	Attribution 4.0 International
Title	Genomic prediction based on selected variants from imputed whole-genome sequence data in Australian sheep populations
Type of document	Journal Article
Entity Type	Publication

Genomic prediction based on selected variants from imputed whole-genome sequence data in Australian sheep populations

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