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Integrating Crop Growth Models with Whole Genome Prediction through Approximate Bayesian Computation

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  • Frank Technow
  • Carlos D Messina
  • L Radu Totir
  • Mark Cooper

Abstract

Genomic selection, enabled by whole genome prediction (WGP) methods, is revolutionizing plant breeding. Existing WGP methods have been shown to deliver accurate predictions in the most common settings, such as prediction of across environment performance for traits with additive gene effects. However, prediction of traits with non-additive gene effects and prediction of genotype by environment interaction (G×E), continues to be challenging. Previous attempts to increase prediction accuracy for these particularly difficult tasks employed prediction methods that are purely statistical in nature. Augmenting the statistical methods with biological knowledge has been largely overlooked thus far. Crop growth models (CGMs) attempt to represent the impact of functional relationships between plant physiology and the environment in the formation of yield and similar output traits of interest. Thus, they can explain the impact of G×E and certain types of non-additive gene effects on the expressed phenotype. Approximate Bayesian computation (ABC), a novel and powerful computational procedure, allows the incorporation of CGMs directly into the estimation of whole genome marker effects in WGP. Here we provide a proof of concept study for this novel approach and demonstrate its use with synthetic data sets. We show that this novel approach can be considerably more accurate than the benchmark WGP method GBLUP in predicting performance in environments represented in the estimation set as well as in previously unobserved environments for traits determined by non-additive gene effects. We conclude that this proof of concept demonstrates that using ABC for incorporating biological knowledge in the form of CGMs into WGP is a very promising and novel approach to improving prediction accuracy for some of the most challenging scenarios in plant breeding and applied genetics.

Suggested Citation

  • Frank Technow & Carlos D Messina & L Radu Totir & Mark Cooper, 2015. "Integrating Crop Growth Models with Whole Genome Prediction through Approximate Bayesian Computation," PLOS ONE, Public Library of Science, vol. 10(6), pages 1-20, June.
  • Handle: RePEc:plo:pone00:0130855
    DOI: 10.1371/journal.pone.0130855
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    References listed on IDEAS

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    1. Marco Lopez-Cruz & Fernando M. Aguate & Jacob D. Washburn & Natalia Leon & Shawn M. Kaeppler & Dayane Cristina Lima & Ruijuan Tan & Addie Thompson & Laurence Willard Bretonne & Gustavo los Campos, 2023. "Leveraging data from the Genomes-to-Fields Initiative to investigate genotype-by-environment interactions in maize in North America," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    2. Yusuke Toda & Hitomi Wakatsuki & Toru Aoike & Hiromi Kajiya-Kanegae & Masanori Yamasaki & Takuma Yoshioka & Kaworu Ebana & Takeshi Hayashi & Hiroshi Nakagawa & Toshihiro Hasegawa & Hiroyoshi Iwata, 2020. "Predicting biomass of rice with intermediate traits: Modeling method combining crop growth models and genomic prediction models," PLOS ONE, Public Library of Science, vol. 15(6), pages 1-21, June.
    3. Guadagno, C.R. & Millar, D. & Lai, R. & Mackay, D.S. & Pleban, J.R. & McClung, C.R. & Weinig, C. & Wang, D.R. & Ewers, B.E., 2020. "Use of transcriptomic data to inform biophysical models via Bayesian networks," Ecological Modelling, Elsevier, vol. 429(C).
    4. Lamsal, Abhishes & Welch, S.M. & Jones, J.W. & Boote, K.J. & Asebedo, Antonio & Crain, Jared & Wang, Xu & Boyer, Will & Giri, Anju & Frink, Elizabeth & Xu, Xuan & Gundy, Garrison & Ou, Junjun & Arachc, 2017. "Efficient crop model parameter estimation and site characterization using large breeding trial data sets," Agricultural Systems, Elsevier, vol. 157(C), pages 170-184.

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