A Bayesian Decision Theory Approach for Genomic Selection

Villar-Hernández, Bartolo de Jesús; Pérez-Elizalde, Sergio; Crossa, J.; Pérez‐Rodríguez, Paulino; Toledo, Fernando H.; Burgueño, Juan

doi:10.1534/g3.118.200430

Cited by 4 publications

(12 citation statements)

References 26 publications

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“…maintaining grain yield or protein content but favoured one trait at cost of the other. Accordingly, it can be recommended to focus on genomic selection indices that correspond to deviations from regression line when conducting a simultaneous selection for grain yield and protein content and for finding the desirable outliers from the common trend, although it should be noticed that other methods such as using the multi-optimization framework by setting optimal compromise solutions or from the Bayesian decision theory have also shown great promise (Akdemir et al 2018 ; de Villar-Hernández et al 2018 ).…”

Section: Discussionmentioning

confidence: 99%

Simultaneous selection for grain yield and protein content in genomics-assisted wheat breeding

Michel

Löschenberger²,

Ametz³

et al. 2019

Theor Appl Genet

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Key message Large genetic improvement can be achieved by simultaneous genomic selection for grain yield and protein content when combining different breeding strategies in the form of selection indices. Abstract Genomic selection has been implemented in many national and international breeding programmes in recent years. Numerous studies have shown the potential of this new breeding tool; few have, however, taken the simultaneous selection for multiple traits into account that is though common practice in breeding programmes. The simultaneous improvement in grain yield and protein content is thereby a major challenge in wheat breeding due to a severe negative trade-off. Accordingly, the potential and limits of multi-trait selection for this particular trait complex utilizing the vast phenotypic and genomic data collected in an applied wheat breeding programme were investigated in this study. Two breeding strategies based on various genomic-selection indices were compared, which (1) aimed to select high-protein genotypes with acceptable yield potential and (2) develop high-yielding varieties, while maintaining protein content. The prediction accuracy of preliminary yield trials could be strongly improved when combining phenotypic and genomic information in a genomics-assisted selection approach, which surpassed both genomics-based and classical phenotypic selection methods both for single trait predictions and in genomic index selection across years. The employed genomic selection indices mitigated furthermore the negative trade-off between grain yield and protein content leading to a substantial selection response for protein yield, i.e. total seed nitrogen content, which suggested that it is feasible to develop varieties that combine a superior yield potential with comparably high protein content, thus utilizing available nitrogen resources more efficiently. Electronic supplementary material The online version of this article (10.1007/s00122-019-03312-5) contains supplementary material, which is available to authorized users.

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Section: Discussionmentioning

confidence: 99%

Simultaneous selection for grain yield and protein content in genomics-assisted wheat breeding

Michel

Löschenberger²,

Ametz³

et al. 2019

Theor Appl Genet

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“…Genomic approaches (1) estimate the GEBV through a statistical model and information about the unobserved (genotyped) individuals (candidate population) using the phenotypic and genotypic data of their parents, (2) rank the lines based on GEBV, and (3) select the top-ranking lines. Recently, Villar-Hernández et al (2018) proposed a method based on Bayesian decision theory (BDT) for selecting the best candidates (in a single trait or in multi-trait) that maximize R ; results were obtained by simulating a breeding program. For a single trait, and assuming the candidates have the same amount of information and are identically distributed, R could be expressed in terms of the selection differential

, the difference between the mean of the selected individuals,

, and the mean of the original population,

) multiplied by the heritability

.…”

Section: Introductionmentioning

confidence: 99%

“…Thus, R=

S , and when

1

S (maximum expected response to selection, minimum expected loss in the decision of which candidates to select based on our breeding goals), whereas when

0

, R ≪ S (minimum expected response to selection, maximum expected loss) . The BDT methodology proposed by Villar-Hernández et al (2018) considers the variance-covariance matrix between traits and the trait mean while minimizing the posterior expected distance between the distribution of the offspring of the selected individuals (distribution of the candidates) and the distribution of the selected individuals (distribution of the selected parents), and therefore maximizing the expected response to selection ( R ) given the phenotypic, genotypic and genomic information at hand. Minimizing the distance between the distribution of the parental candidates and the progeny distribution increases the accuracy of selection (assuming equal selection intensity).…”

Section: Introductionmentioning

confidence: 99%

“…The selection of multi-traits can be facilitated by ranking lines based on a single number; for example, genomic selection indices (SI) score lines based on a weighted average of GEBV, and then select those lines with high scores ( Cerón-Rojas and Crossa 2020 ). The approach of Villar-Hernández et al (2018) ranks the lines based on the posterior expected loss (PEL, a single number) given our breeding goals, in terms of the mean and the genetic variance-covariance matrix. Thus, those candidates whose distributions are closer to the theoretical parental distribution will have the lowest expected loss value (high R ), and the decision should be to advance those lines given that they reach the desired mean and keep the genetic variance as much as possible (high

).…”

Section: Introductionmentioning

confidence: 99%

“…As described in Villar-Hernández et al (2018) , the LF is the vehicle to go from the action space (candidate lines) to the resulting space (selected lines) given a Bayesian action (an action that guarantees a minimum PEL given our preferences). Of the three multivariate LFs used by Villar-Hernández et al (2018) , the Kullback–Leibler (KL) LF is easier to understand.…”

Section: Introductionmentioning

confidence: 99%

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Application of multi-trait Bayesian decision theory for parental genomic selection

Villar-Hernández

Pérez-Elizalde

Martini

et al. 2021

G3 Genes|Genomes|Genetics

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In all breeding programs, the decision about which individuals to select and intermate to form the next selection cycle is crucial. The improvement of genetic stocks requires considering multiple traits simultaneously, given that economic value and net genetic merits depend on many traits; therefore, with the advance of computational and statistical tools and genomic selection (GS), researchers are focusing on multi-trait selection. Selection of the best individuals is difficult, especially in traits that are antagonistically correlated, where improvement in one trait might imply a reduction in other(s). There are approaches that facilitate multi-trait selection, and recently a Bayesian decision theory (BDT) has been proposed. Parental selection using BDT has the potential to be effective in multi-trait selection given that it summarizes all relevant quantitative genetic concepts such as heritability, response to selection and the structure of dependence between traits (correlation). In this study, we applied BDT to provide a treatment for the complexity of multi-trait parental selection using three multivariate loss functions (LF), Kullback-Leibler (KL), Energy Score, and Multivariate Asymmetric Loss (MALF), to select the best performing parents for the next breeding cycle in two extensive real wheat data sets. Results show that the high ranking lines in genomic estimated breeding value (GEBV) for certain traits did not always have low values for PEL. For both data sets, the KL loss function gave similar importance to all traits including grain yield. In contrast, the Energy Score and MALF gave better performance in 3 of 4 traits that were different than grain yield. The BDT approach should help breeders to decide based not only on the GEBV per se of the parent to be selected, but also on the level of uncertainty according to the Bayesian paradigm.

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A Bayesian optimization R package for multitrait parental selection

Villar‐Hernández,

Dreisigacker,

Crespo

et al. 2024

The Plant Genome

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Selecting and mating parents in conventional phenotypic and genomic selection are crucial. Plant breeding programs aim to improve the economic value of crops, considering multiple traits simultaneously. When traits are negatively correlated and/or when there are missing records in some traits, selection becomes more complex. To address this problem, we propose a multitrait selection approach using the Multitrait Parental Selection (MPS) R package—an efficient tool for genetic improvement, precision breeding, and conservation genetics. The package employs Bayesian optimization algorithms and three loss functions (Kullback–Leibler, Energy Score, and Multivariate Asymmetric Loss) to identify parental candidates with desirable traits. The software's functionality includes three main functions—EvalMPS, FastMPS, and ApproxMPS—catering to different data availability scenarios. Through the presented application examples, the MPS R package proves effective in multitrait genomic selection, enabling breeders to make informed decisions and achieve strong performance across multiple traits.

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A Bayesian Decision Theory Approach for Genomic Selection

Cited by 4 publications

References 26 publications

Simultaneous selection for grain yield and protein content in genomics-assisted wheat breeding

Simultaneous selection for grain yield and protein content in genomics-assisted wheat breeding

Application of multi-trait Bayesian decision theory for parental genomic selection

A Bayesian optimization R package for multitrait parental selection

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