Resource allocation optimization with multi-trait genomic prediction for bread wheat (Triticum aestivum L.) baking quality

Lado, Bettina; Vázquez, Daniel; Quincke, Martín; Silva, Paula; Aguilar, Ignácio; Gutiérrez, Lucı́a

doi:10.1007/s00122-018-3186-3

Cited by 101 publications

(212 citation statements)

References 56 publications

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“…In transferring GS to plants, however, many applications have failed to consider the inherent structure of plant breeding MET data sets. A recent example demonstrated GS in bread baking quality traits for a large number of varieties and environments (Lado et al., ). They used a stagewise approach where the adjusted means from the first stage were incorporated into a correlation matrix between environments.…”

Section: Discussionmentioning

confidence: 99%

“…The approach also fails to account for non‐genetic sources of variation in the field and laboratory phases nor does it appropriately model the variety (and hence marker) by environment interaction. Similar stagewise methods with deficient models for VEI are prolific in recent literature (see for example, Ben Hassen, Bartholomé, Valè, Cao, & Ahmadi, ; He et al., ; Lado et al., ; Michel et al., ).…”

Section: Discussionmentioning

confidence: 99%

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Genomic selection in multi‐environment plant breeding trials using a factor analytic linear mixed model

Tolhurst

Mathews

Smith

et al. 2019

J Animal Breeding Genetics

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Genomic selection (GS) is a statistical and breeding methodology designed to improve genetic gain. It has proven to be successful in animal breeding; however, key points of difference have not been fully considered in the transfer of GS from animal to plant breeding. In plant breeding, individuals (varieties) are typically evaluated across a number of locations in multiple years (environments) in formally designed comparative experiments, called multi‐environment trials (METs). The design structure of individual trials can be complex and needs to be modelled appropriately. Another key feature of MET data sets is the presence of variety by environment interaction (VEI), that is the differential response of varieties to a change in environment. In this paper, a single‐step factor analytic linear mixed model is developed for plant breeding MET data sets that incorporates molecular marker data, appropriately accommodates non‐genetic sources of variation within trials and models VEI. A recently developed set of selection tools, which are natural derivatives of factor analytic models, are used to facilitate GS for a motivating data set from an Australian plant breeding company. The power and versatility of these tools is demonstrated for the variety by environment and marker by environment effects.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Genomic selection in multi‐environment plant breeding trials using a factor analytic linear mixed model

Tolhurst

Mathews

Smith

et al. 2019

J Animal Breeding Genetics

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“…size, genetic relatedness between individuals in training and testing population, marker density, span 15 of linkage disequilibrium and genetic architecture of traits are some of the factors that can affect the 16 predictive ability of the models [8][9][10]. Genomic prediction models are routinely studied and applied 17 by breeding programs around the world in several crops. Novel statistical methods that are capable 18 of incorporating pedigree, genomic, and environmental covariates into statistical-genetic prediction 19 models have emerged as a result of extensive computational research [11].…”

mentioning

confidence: 99%

“…To address those challenges, 32 expanded genomic prediction models that perform joint analysis of multiple traits have been studied 33 using empirical and simulated data [15,16]. Subsequent improvement in prediction accuracy from 34 multi-trait model over single-trait model depends on trait heritability and correlation between the 35 traits involved [15,17]. 36 Data generated in breeding programs span multiple environment and are recorded for multiple 37 traits for each individual.…”

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confidence: 99%

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Multi-trait regressor stacking increased genomic prediction accuracy of sorghum grain composition

Sapkota

Boatwright

Jordan

et al. 2020

Preprint

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Cereal grains, primarily composed of starch, protein, and fat, are major source of staple for human and animal nutrition. Sorghum, a cereal crop, serves as a dietary staple for over half a billion people in the semi-arid tropics of Africa and South Asia. Genomic prediction has enabled plant breeders to estimate breeding values of unobserved genotypes and environments. Therefore, the use of genomic prediction will be extremely valuable for compositional traits for which phenotyping is labor-intensive and destructive for most accurate results. We studied the potential of Bayesian multi-output regressor stacking (BMORS) model in improving prediction performance over single trait single environment (STSE) models using a grain sorghum diversity panel (GSDP) and a biparental recombinant inbred lines (RILs) population. A total of five highly correlated grain composition traits: amylose, fat, gross energy, protein and starch, with genomic heritability ranging from 0.24 to 0.59 in the GSDP and 0.69 to 0.83 in the RILs were studied. Average prediction accuracies from the STSE model were within a range of 0.4 to 0.6 for all traits across both populations except amylose (0.25) in the GSDP. Prediction accuracy for BMORS increased by 41% and 32% on average over STSE in the GSDP and RILs, respectively. Predicting whole environments by training with remaining environments in BMORS yielded higher average prediction accuracy than from STSE model. Our results show regression stacking methods such as BMORS have potential to accurately predict unobserved individuals and environments, and implementation of such models can accelerate genetic gain.

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Role of the Genomics–Phenomics–Agronomy Paradigm in Plant Breeding

Chen

Rutkoski

Schnable

et al. 2022

Plant Breeding Reviews

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Highlights• Phenomics allows genetic mapping of traits throughout plant growth and a better understanding of both pleiotropy and endophenotypes. • Many GWAS identified loci are not validated and remain unused.• Genomics provides a path to validate phenomics traits, especially the ones without direct links to agronomics traits. • Multiple trait GBLUP remains the most sophisticated method to integrate agronomics and phenomics traits but does not demonstrate consistent advantage across traits and environments. • Bayesian methods have been extended to incorporate multiple traits, multiple environments, and prior biological knowledge. • Prediction using explainable machine learning incorporates domain knowledge with complex modules allowing to learn from data but guided by confirmed domain knowledge rather than less reliable human expert experiences.

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Resource allocation optimization with multi-trait genomic prediction for bread wheat (Triticum aestivum L.) baking quality

Cited by 101 publications

References 56 publications

Genomic selection in multi‐environment plant breeding trials using a factor analytic linear mixed model

Genomic selection in multi‐environment plant breeding trials using a factor analytic linear mixed model

Multi-trait regressor stacking increased genomic prediction accuracy of sorghum grain composition

Role of the Genomics–Phenomics–Agronomy Paradigm in Plant Breeding

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