Genomic prediction in hybrid breeding: I. Optimizing the training set design

Abstract

Abstract Key message Training sets produced by maximizing the number of parent lines, each involved in one cross, had the highest prediction accuracy for H0 hybrids, but lowest for H1 and H2 hybrids. Abstract Genomic prediction holds great promise for hybrid breeding but optimum composition of the training set (TS) as determined by the number of parents (nTS) and crosses per parent (c) has received little attention. Our objective was to examine prediction accuracy ($$r_{a}$$ r a ) of GCA for lines used as parents of the TS (I1 lines) or not (I0 lines), and H0, H1 and H2 hybrids, comprising crosses of type I0 × I0, I1 × I0 and I1 × I1, respectively, as function of nTS and c. In the theory, we developed estimates for $$r_{a}$$ r a of GBLUPs for hybrids: (i)$$\hat{r}_{a}$$ r ^ a based on the expected prediction accuracy, and (ii) $$\tilde{r}_{a}$$ r ~ a based on $$r_{a}$$ r a of GBLUPs of GCA and SCA effects. In the simulation part, hybrid populations were generated using molecular data from two experimental maize data sets. Additive and dominance effects of QTL borrowed from literature were used to simulate six scenarios of traits differing in the proportion (τSCA = 1%, 6%, 22%) of SCA variance in σG2 and heritability (h2 = 0.4, 0.8). Values of $$\tilde{r}_{a}$$ r ~ a and $$\hat{r}_{a}$$ r ^ a closely agreed with $$r_{a}$$ r a for hybrids. For given size NTS = nTS × c of TS, $$r_{a}$$ r a of H0 hybrids and GCA of I0 lines was highest for c = 1. Conversely, for GCA of I1 lines and H1 and H2 hybrids, c = 1 yielded lowest $$r_{a}$$ r a with concordant results across all scenarios for both data sets. In view of these opposite trends, the optimum choice of c for maximizing selection response across all types of hybrids depends on the size and resources of the breeding program.