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Abstract:
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Sparse testing in plant breeding refers to a situation where not all genotypes of interest are grown in each environment. Using genomic prediction and genotype × environment interaction, the non-observed genotype- in-environment combinations can be predicted. Hence, the overall costs can be reduced, and the testing capacities increased. The accuracy of predicting the unobserved data depends on different factors: (1) how many genotypes overlap between environments, (2) in how many environments each genotype is grown, and (3) which prediction method is used. Here, we studied the predictive ability obtained when using a fixed number of plots and different sparse testing designs. The empirical study is built upon two different maize hybrid data sets and each data set was analyzed separately. For each set, phenotypic records on yield from three different environments are available. Three different prediction models were implemented, two main effects models, and a model including the genotype-by-environment interaction (GE) term. The GE model provided higher prediction accuracy than the other two models for the different allocation scenarios.
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