The Impact of Genetic Architecture on Genome-Wide Evaluation Methods

Extensive genetic progress has been achieved in dairy cattle populations on many traits of economic importance because of efficient breeding programmes. Success of these programmes has relied on progeny testing of the best young males to accurately assess their genetic merit and hence their potential for breeding. Over the last few years, the integration of dense genomic information into statistical tools used to make selection decisions, commonly referred to as genomic selection, has enabled gains in predicting accuracy of breeding values for young animals without own performance. The possibility to select animals at an early stage allows defining new breeding strategies aimed at boosting genetic progress while reducing costs. The first objective of this article was to review methods used to model and optimize breeding schemes integrating genomic selection and to discuss their relative advantages and limitations. The second objective was to summarize the main results and perspectives on the use of genomic selection in practical breeding schemes, on the basis of the example of dairy cattle populations. Two main designs of breeding programmes integrating genomic selection were studied in dairy cattle. Genomic selection can be used either for pre-selecting males to be progeny tested or for selecting males to be used as active sires in the population. The first option produces moderate genetic gains without changing the structure of breeding programmes. The second option leads to large genetic gains, up to double those of conventional schemes because of a major reduction in the mean generation interval, but it requires greater changes in breeding programme structure. The literature suggests that genomic selection becomes more attractive when it is coupled with embryo transfer technologies to further increase selection intensity on the dam-to-sire pathway. The use of genomic information also offers new opportunities to improve preservation of genetic variation. However, recent simulation studies have shown that putting constraints on genomic inbreeding rates for defining optimal contributions of breeding animals could significantly reduce achievable genetic gain. Finally, the article summarizes the potential of genomic selection to include new traits in the breeding goal to meet societal demands regarding animal health and environmental efficiency in animal production.Keywords: genomic selection, breeding programme, dairy cattle, genetic gain, inbreeding rates ImplicationsThe practical use of genomic information to select animals, or genomic selection, is currently revolutionizing the organization of dairy cattle breeding schemes. The success of this new technology is because of increased genetic progress on both the bull and cow genetic pathways by reducing costs compared with conventional selection schemes, but also by the potential of using this rich source of information to manage genetic resources. Practical results of the implementation of genomic selection in dairy cattle breeding schemes are of great importa...

mentioning

confidence: 99%

Integrating genomic selection into dairy cattle breeding programmes: a review

Bouquet

Juga

2013

“…However, when referring to other species, for example, dairy cattle, accuracies of GEBVs are substantially higher for production traits compared with fertility, somatic cell score or longevity (VanRaden et al, 2009). Nevertheless, on the basis of results from simulation studies or deterministic predictions (Calus et al, 2008;Daetwyler et al, 2010), a correlation of r mg 5 0.5 should be feasible also for GS for functional traits in horses. Such a crucial value doubles r TI at this very early point of selection (Figure 2) compared with the accuracy of the conventional index.…”

Section: Resultsmentioning

confidence: 99%

Integration of genomic information into sport horse breeding programs for optimization of accuracy of selection

Haberland

Borstel

Simianer

et al. 2012

Reliable selection criteria are required for young riding horses to increase genetic gain by increasing accuracy of selection and decreasing generation intervals. In this study, selection strategies incorporating genomic breeding values (GEBVs) were evaluated. Relevant stages of selection in sport horse breeding programs were analyzed by applying selection index theory. Results in terms of accuracies of indices (r TI ) and relative selection response indicated that information on single nucleotide polymorphism (SNP) genotypes considerably increases the accuracy of breeding values estimated for young horses without own or progeny performance. In a first scenario, the correlation between the breeding value estimated from the SNP genotype and the true breeding value (5 accuracy of GEBV) was fixed to a relatively low value of r mg 5 0.5. For a low heritability trait (h 2 5 0.15), and an index for a young horse based only on information from both parents, additional genomic information doubles r TI from 0.27 to 0.54. Including the conventional information source 'own performance' into the before mentioned index, additional SNP information increases r TI by 40%. Thus, particularly with regard to traits of low heritability, genomic information can provide a tool for well-founded selection decisions early in life. In a further approach, different sources of breeding values (e.g. GEBV and estimated breeding values (EBVs) from different countries) were combined into an overall index when altering accuracies of EBVs and correlations between traits. In summary, we showed that genomic selection strategies have the potential to contribute to a substantial reduction in generation intervals in horse breeding programs.Keywords: accuracy of selection, breeding strategies, generation interval, genomic selection, sport horse ImplicationsThe availability of genomic information demands proper assessment of its impact on practical horse breeding programs. Accuracies of conventional breeding values do not increase significantly until a stallion is aged 8 to 12 years and his progeny enters competition. We showed that additional genomic information considerably increases the accuracy of breeding values estimated for foals, young horses without own performance, and horses without progeny performance. Therefore, genomic selection (GS) enables selection at an earlier stage, shortening generation intervals and opening room for increased genetic progress. Our results indicate that horse breeding organizations could likely benefit from the application of GS.

“…For this study, formulae proposed by Daetwyler et al (2010) with a slight modification proposed by Woolliams et al (2010) to account for incomplete spread of markers across the genome were used to predict the accuracy (r GS ) of direct genomic predictions that do not include additional accuracy provided by parent average information, as follows:…”

Section: Accuracy Of Genomic Predictionsmentioning

confidence: 99%

Turning science on robust cattle into improved genetic selection decisions

Amer¹

2012

More robust cattle have the potential to increase farm profitability, improve animal welfare, reduce the contribution of ruminant livestock to greenhouse gas emissions and decrease the risk of food shortages in the face of increased variability in the farm environment. Breeding is a powerful tool for changing the robustness of cattle; however, insufficient recording of breeding goal traits and selection of animals at younger ages tend to favour genetic change in productivity traits relative to robustness traits. This paper has extended a previously proposed theory of artificial evolution to demonstrate, using deterministic simulation, how choice of breeding scheme design can be used as a tool to manipulate the direction of genetic progress, whereas the breeding goal remains focussed on the factors motivating individual farm decision makers. Particular focus was placed on the transition from progeny testing or mass selection to genomic selection breeding strategies. Transition to genomic selection from a breeding strategy where candidates are selected before records from progeny being available was shown to be highly likely to favour genetic progress in robustness traits relative to productivity traits. This was shown even with modest numbers of animals available for training and when heritability for robustness traits was only slightly lower than that for productivity traits. When transitioning from progeny testing to a genomic selection strategy without progeny testing, it was shown that there is a significant risk that robustness traits could become less influential in selection relative to productivity traits. Augmentations of training populations using genotyped cows and support for industry-wide improvements in phenotypic recording of robustness traits were put forward as investment opportunities for stakeholders wishing to facilitate the application of science on robust cattle into improved genetic selection schemes.