Animals can be genotyped for thousands of single nucleotide polymorphisms (SNPs) at one time, where the SNPs are located at roughly 1-cM intervals throughout the genome. For each contiguous pair of SNPs there are four possible haplotypes that could be inherited from the sire. The effects of each interval on a trait can be estimated for all intervals simultaneously in a model where interval effects are random factors. Given the estimated effects of each haplotype for every interval in the genome, and given an animal's genotype, a 'genomic' estimated breeding value is obtained by summing the estimated effects for that genotype. The accuracy of that estimator of breeding values is around 80%. Because the genomic estimated breeding values can be calculated at birth, and because it has a high accuracy, a strategy that utilizes these advantages was compared with a traditional progeny testing strategy under a typical Canadian-like dairy cattle situation. Costs of proving bulls were reduced by 92% and genetic change was increased by a factor of 2. Genome-wide selection may become a popular tool for genetic improvement in livestock.
[1]
L. Schaeffer,et al.
Estimation of genome-wide haplotype effects in half-sib designs.
,
2007,
Journal of animal breeding and genetics = Zeitschrift fur Tierzuchtung und Zuchtungsbiologie.
[2]
G. Kistemaker,et al.
Dairy genetic improvement through artificial insemination, performance recording and genetic evaluation
,
2003
.
[3]
M. Goddard,et al.
Prediction of total genetic value using genome-wide dense marker maps.
,
2001,
Genetics.
[4]
R. Bourdon.
Understanding Animal Breeding
,
1999
.
[5]
G. H. Schmidt,et al.
Principles of Dairy Science
,
1974
.