We investigate two approaches to increase the efficiency of phenotypic
prediction from genome-wide markers, which is a key step for genomic selection
(GS) in plant and animal breeding. The first approach is feature selection
based on Markov blankets, which provide a theoretically-sound framework for
identifying non-informative markers. Fitting GS models using only the
informative markers results in simpler models, which may allow cost savings
from reduced genotyping. We show that this is accompanied by no loss, and
possibly a small gain, in predictive power for four GS models: partial least
squares (PLS), ridge regression, LASSO and elastic net. The second approach is
the choice of kinship coefficients for genomic best linear unbiased prediction
(GBLUP). We compare kinships based on different combinations of centring and
scaling of marker genotypes, and a newly proposed kinship measure that adjusts
for linkage disequilibrium (LD).
We illustrate the use of both approaches and examine their performances using
three real-world data sets from plant and animal genetics. We find that elastic
net with feature selection and GBLUP using LD-adjusted kinships performed
similarly well, and were the best-performing methods in our study.Comment: 17 pages, 5 figure