Models for genome-wide prediction and association studies usually target a
single phenotypic trait. However, in animal and plant genetics it is common to
record information on multiple phenotypes for each individual that will be
genotyped. Modeling traits individually disregards the fact that they are most
likely associated due to pleiotropy and shared biological basis, thus providing
only a partial, confounded view of genetic effects and phenotypic interactions.
In this paper we use data from a Multiparent Advanced Generation Inter-Cross
(MAGIC) winter wheat population to explore Bayesian networks as a convenient
and interpretable framework for the simultaneous modeling of multiple
quantitative traits. We show that they are equivalent to multivariate genetic
best linear unbiased prediction (GBLUP), and that they are competitive with
single-trait elastic net and single-trait GBLUP in predictive performance.
Finally, we discuss their relationship with other additive-effects models and
their advantages in inference and interpretation. MAGIC populations provide an
ideal setting for this kind of investigation because the very low population
structure and large sample size result in predictive models with good power and
limited confounding due to relatedness.Comment: 28 pages, 1 figure, code at
http://www.bnlearn.com/research/genetics1