Background

Genomic prediction is based on the accurate estimation of the genomic relationships among and between training animals and selection candidates in order to obtain accurate estimates of the genomic estimated breeding values (GEBV). Various methods have been used to predict GEBV based on population-wide linkage disequilibrium relationships (G _IBS ) or sometimes on linkage analysis relationships (G _LA ). Here, we propose a novel method to predict GEBV based on a genomic relationship matrix using runs of homozygosity (G _ROH ). Runs of homozygosity were used to derive probabilities of multi-locus identity by descent chromosome segments. The accuracy and bias of the prediction of GEBV using G _ROH were compared to those using G _IBS and G _LA . Comparisons were performed using simulated datasets derived from a random pedigree and a real pedigree of Italian Brown Swiss bulls. The comparison of accuracies of GEBV was also performed on data from 1086 Italian Brown Swiss dairy cattle.

Results

Simulations with various thresholds of minor allele frequency for markers and quantitative trait loci showed that G _ROH achieved consistently more accurate GEBV (0 to 4% points higher) than G _IBS and G _LA . The bias of GEBV prediction for simulated data was higher based on the real pedigree than based on a random pedigree. In the analyses with real data, G _ROH and G _LA had similar accuracies. However, G _LA achieved a higher accuracy when the prediction was done on the youngest animals. The G _IBS matrices calculated with and without standardized marker genotypes resulted in similar accuracies.

Conclusions

The present study proposes G _ROH as a novel method to estimate genomic relationship matrices and predict GEBV based on runs of homozygosity and shows that it can result in higher or similar accuracies of GEBV prediction than G _LA , except for the real data analysis with validation of young animals. Compared to G _IBS , G _ROH resulted in more accurate GEBV predictions.