Abstract
We propose a novel Bayesian approach that robustifies genomic modeling by leveraging expert knowledge (EK) through prior distributions. The central component is the hierarchical decomposition of phenotypic variation into additive and nonadditive genetic variation, which leads to an intuitive model parameterization that can be visualized as a tree. The edges of the tree represent ratios of variances, for example broad-sense heritability, which are quantities for which EK is natural to exist. Penalized complexity priors are defined for all edges of the tree in a bottom-up procedure that respects the model structure and incorporates EK through all levels. We investigate models with different sources of variation and compare the performance of different priors implementing varying amounts of EK in the context of plant breeding. A simulation study shows that the proposed priors implementing EK improve the robustness of genomic modeling and the selection of the genetically best individuals in a breeding program. We observe this improvement in both variety selection on genetic values and parent selection on additive values; the variety selection benefited the most. In a real case study, EK increases phenotype prediction accuracy for cases in which the standard maximum likelihood approach did not find optimal estimates for the variance components. Finally, we discuss the importance of EK priors for genomic modeling and breeding, and point to future research areas of easy-to-use and parsimonious priors in genomic modeling.
Highlights
Plant breeding programs are improving productivity of a range of crops and with this addressing the global and rising hunger problem that impacts 820 million people across the world (FAO et al 2019)
The central component is the hierarchical decomposition of phenotypic variation into additive and nonadditive genetic variation, which leads to an intuitive model parameterization that can be visualized as a tree
We propose an easy-to-use, intuitive, and robust Bayesian approach that builds on two recent innovations in Bayesian statistics: (1) the hierarchical decomposition (HD) prior framework (Fuglstad et al 2020) to provide a hierarchical description of the decomposition of phenotypic variation into different types of variation, and (2) the penalized complexity (PC) prior framework (Simpson et al 2017) to facilitate robust genomic modeling
Summary
Plant breeding programs are improving productivity of a range of crops and with this addressing the global and rising hunger problem that impacts 820 million people across the world (FAO et al 2019). One of the most important food sources in the world is wheat (Shewry and Hey 2015), recent improvements in wheat yield are smaller than the projected requirements (Ray et al 2013) and might become more variable or even decrease due to climate change (Asseng et al 2015) This trend is in stark contrast to the United Nation’s Sustainable Development Goals that aim to end hunger and malnutrition by 2030 (UN General Assembly 2015). A key component in breeding is genomic modeling, where we aim to reduce environmental noise in phenotypic observations and associate the remaining variation with variation in individual genomes We use these associations to estimate genetic values for phenotyped or even nonphenotyped individuals and with this identify the genetically best individuals (Meuwissen et al 2001). Improving this process involves improving the methods for disentangling genetic variation from environmental variation
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