Across-country test-day model evaluations for Holstein, Nordic Red Cattle, and Jersey

J Dairy Sci. 2015 Feb;98(2):1296-309. doi: 10.3168/jds.2014-8307. Epub 2014 Nov 28.

Abstract

Three random regression models were developed for routine genetic evaluation of Danish, Finnish, and Swedish dairy cattle. Data included over 169 million test-day records with milk, protein, and fat yield observations from over 8.7 million dairy cows of all breeds. Variance component analyses showed significant differences in estimates between Holstein, Nordic Red Cattle, and Jersey, but only small to moderate differences within a breed across countries. The obtained variance component estimates were used to build, for each breed, their own set of covariance functions. The covariance functions describe the animal effects on milk, protein, and fat yields of the first 3 lactations as 9 different traits, assuming the same heritabilities and a genetic correlation of unity across countries. Only 15, 27, and 7 eigenfunctions with the largest eigenvalues were used to describe additive genetic animal effects and nonhereditary animal effects across lactations and within later lactations, respectively. These reduced-rank covariance functions explained 99.0 to 99.9% of the original variances but reduced the number of animal equations to be solved by 44%. Moderate rank reduction for nonhereditary animal effects and use of one-third-smaller measurement error correlations than obtained from variance component estimation made the models more robust against extreme observations. Estimation of the genetic levels of the countries' subpopulations within a breed was found sensitive to the way the breed effects were modeled, especially for the genetically heterogeneous Nordic Red Cattle. Means to ensure that only additive genetic effects entered the estimated breeding values were to describe the crossbreeding effects by fixed and random cofactors and the calving age effect by an age × breed proportion interaction, and to model phantom parent groups as random effects. To ensure that genetic variances were the same across the 3 countries in breeding value estimation, as suggested by the variance component estimates, the applied multiplicative heterogeneous variance adjustment method had to be tailored using country-specific reference measurement error variances. Results showed the feasibility of across-country genetic evaluation of cows and sires based on original test-day phenotypes. Nevertheless, applying a thorough model validation procedure is essential throughout the model building process to obtain reliable breeding values.

Keywords: across-country genetic evaluation; covariance function; crossbreeding effect; heterogeneous variance.

Publication types

  • Comparative Study

MeSH terms

  • Algorithms
  • Analysis of Variance
  • Animals
  • Breeding
  • Cattle / genetics*
  • Fats / analysis
  • Female
  • Genetic Heterogeneity
  • Genetic Variation
  • Hybrid Vigor
  • Hybridization, Genetic
  • Lactation / genetics*
  • Milk / chemistry*
  • Milk Proteins / analysis
  • Milk Proteins / genetics
  • Models, Statistical*
  • Phenotype
  • Regression Analysis
  • Research
  • Species Specificity

Substances

  • Fats
  • Milk Proteins