Prediction of genetic values of quantitative traits with epistatic effects in plant breeding populations

Wang, D; Elbasyoni, Ibrahim S.; Baenziger, P. Stephen; Crossa, J.; Eskridge, Kent M.; Dweikat, İsmail

doi:10.1038/hdy.2012.44

Cited by 62 publications

(51 citation statements)

References 46 publications

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“…However, with progeny models, the prediction accuracy regarding the breeding value increased from G_A H to G_A H +D H . Our study generated new findings to supplement previously published results based on experimental data that had diverse conclusions, for example, in plants, Dudley andJohnson (2009), Hu et al (2011) and Wang et al (2012) found that including marker interactions substantially increased the prediction accuracy, but Lorenzana and Bernardo (2009) and Muñoz et al (2014) came to opposite conclusions. With animals, Su et al (2012) and Sun et al (2014) showed that including non-additive effects improved the prediction.…”

Section: Impact Of Modeling On the Prediction Accuracysupporting

confidence: 79%

Modeling additive and non-additive effects in a hybrid population using genome-wide genotyping: prediction accuracy implications

Bouvet

Makouanzi²,

Cros

et al. 2015

Heredity

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Hybrids are broadly used in plant breeding and accurate estimation of variance components is crucial for optimizing genetic gain. Genome-wide information may be used to explore models designed to assess the extent of additive and non-additive variance and test their prediction accuracy for the genomic selection. Ten linear mixed models, involving pedigree-and markerbased relationship matrices among parents, were developed to estimate additive (A), dominance (D) and epistatic (AA, AD and DD) effects. Five complementary models, involving the gametic phase to estimate marker-based relationships among hybrid progenies, were developed to assess the same effects. The models were compared using tree height and 3303 single-nucleotide polymorphism markers from 1130 cloned individuals obtained via controlled crosses of 13 Eucalyptus urophylla females with 9 Eucalyptus grandis males. Akaike information criterion (AIC), variance ratios, asymptotic correlation matrices of estimates, goodness-of-fit, prediction accuracy and mean square error (MSE) were used for the comparisons. The variance components and variance ratios differed according to the model. Models with a parent marker-based relationship matrix performed better than those that were pedigree-based, that is, an absence of singularities, lower AIC, higher goodness-of-fit and accuracy and smaller MSE. However, AD and DD variances were estimated with high s.es. Using the same criteria, progeny gametic phase-based models performed better in fitting the observations and predicting genetic values. However, DD variance could not be separated from the dominance variance and null estimates were obtained for AA and AD effects. This study highlighted the advantages of progeny models using genome-wide information.

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Section: Impact Of Modeling On the Prediction Accuracysupporting

confidence: 79%

Modeling additive and non-additive effects in a hybrid population using genome-wide genotyping: prediction accuracy implications

Bouvet

Makouanzi²,

Cros

et al. 2015

Heredity

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“…Modelling of epistatic effects should provide more accurate results and the estimation of non-additive effects in genetic predictions is needed (Wang et al, 2012). Implementation of GS in commercial wheat breeding programmes needs further investigation before it can be fully employed Crossa, Beyene et al, 2013;Heffner, Jannink, Iwata et al, 2011;Rutkoski et al, 2012).…”

Section: Implementation In Wheatmentioning

confidence: 99%

Goals and hurdles for a successful implementation of genomic selection in breeding programme for selected annual and perennial crops

Jonas

Koning

2016

Biotechnology and Genetic Engineering Reviews

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Genomic Selection is an important topic in quantitative genetics and breeding. Not only does it allow the full use of current molecular genetic technologies, it stimulates also the development of new methods and models. Genomic selection, if fully implemented in commercial farming, should have a major impact on the productivity of various agricultural systems. But suggested approaches need to be applicable in commercial breeding populations. Many of the published research studies focus on methodologies. We conclude from the reviewed publications, that a stronger focus on strategies for the implementation of genomic selection in advanced breeding lines, introduction of new varieties, hybrids or multi-line crosses is needed. Efforts to find solutions for a better prediction and integration of environmental influences need to continue within applied breeding schemes. Goals of the implementation of genomic selection into crop breeding should be carefully defined and crop breeders in the private sector will play a substantial part in the decision-making process. However, the lack of published results from studies within, or in collaboration with, private companies diminishes the knowledge on the status of genomic selection within applied breeding programmes. Studies on the implementation of genomic selection in plant breeding need to evaluate models and methods with an enhanced emphasis on population-specific requirements and production environments. Adaptation of methods to breeding schemes or changes to breeding programmes for a better integration of genomic selection strategies are needed across species. More openness with a continuous exchange will contribute to successes.

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“…Genomic selection approaches based on additive and dominance effects have been successfully applied to predict complex traits in human (Yang et al 2010), animal (Hayes et al 2009, and plant populations (Jannink et al 2010;Zhao et al 2015). Moreover, several genomic selection approaches have been developed to model both main and epistatic effects (Xu 2007;Cai et al 2011;Wittenburg et al 2011;Wang et al 2012). While in some studies prediction accuracies increased (Hu et al 2011), in others modeling epistasis adversely affected prediction accuracies (Lorenzana and Bernardo 2009).…”

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confidence: 99%

Modeling Epistasis in Genomic Selection

Jiang¹,

2015

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Modeling epistasis in genomic selection is impeded by a high computational load. The extended genomic best linear unbiased prediction (EG-BLUP) with an epistatic relationship matrix and the reproducing kernel Hilbert space regression (RKHS) are two attractive approaches that reduce the computational load. In this study, we proved the equivalence of EG-BLUP and genomic selection approaches, explicitly modeling epistatic effects. Moreover, we have shown why the RKHS model based on a Gaussian kernel captures epistatic effects among markers. Using experimental data sets in wheat and maize, we compared different genomic selection approaches and concluded that prediction accuracy can be improved by modeling epistasis for selfing species but may not for outcrossing species.KEYWORDS epistasis; genomic selection; genomic best linear unbiased prediction (G-BLUP); extended G-BLUP (EG-BLUP); reproducing kernel Hilbert space regression (RKHS); GenPred; shared data resource E PISTASIS has long been recognized as an important component in dissecting genetic pathways and understanding the evolution of complex genetic systems (Phillips 2008). It is hence a biologically influential component contributing to the genetic architecture of quantitative traits (Mackay 2014). The influence of epistasis on genome-wide QTL mapping ranges from limited (e.g., Buckler et al. 2009;Tian et al. 2011) to high (e.g., Carlborg et al. 2006;Würschum et al. 2011;Huang et al. 2014). These discrepancies can be explained by the complexities of the examined traits, which are controlled by many loci exhibiting small effects entailing a low QTL detection power. In addition, the estimation of QTL main and interaction effects is very likely biased (Beavis 1994), which makes it challenging to reliably elucidate the role of epistasis through genome-wide QTL mapping studies.Genomic selection has been suggested as an alternative to tackle complex traits that are regulated by many genes, each exhibiting a small effect (Meuwissen et al. 2001). Genomic selection approaches based on additive and dominance effects have been successfully applied to predict complex traits in human (Yang et al. 2010), animal (Hayes et al. 2009, and plant populations (Jannink et al. 2010;Zhao et al. 2015). Moreover, several genomic selection approaches have been developed to model both main and epistatic effects (Xu 2007;Cai et al. 2011;Wittenburg et al. 2011;Wang et al. 2012). While in some studies prediction accuracies increased (Hu et al. 2011), in others modeling epistasis adversely affected prediction accuracies (Lorenzana and Bernardo 2009).Despite these first attempts, epistasis is often ignored in genomic selection approaches using parametric models mainly because of the high associated computational load, especially if a large number of markers are available. An attractive solution to reduce the computational load is to extend genomic best linear unbiased prediction (G-BLUP) models (VanRaden 2008) by adding marker-based epistatic relationship matrices [extended genomic...

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Prediction of genetic values of quantitative traits with epistatic effects in plant breeding populations

Cited by 62 publications

References 46 publications

Modeling additive and non-additive effects in a hybrid population using genome-wide genotyping: prediction accuracy implications

Modeling additive and non-additive effects in a hybrid population using genome-wide genotyping: prediction accuracy implications

Goals and hurdles for a successful implementation of genomic selection in breeding programme for selected annual and perennial crops

Modeling Epistasis in Genomic Selection

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