The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis
Genotype-by-environment interaction (GEI) is an important phenomenon in plant breeding. This paper presents a series of models for describing, exploring, understanding, and predicting GEI. All models depart from a two-way table of genotype by environment means. First, a series of descriptive and explorative models/approaches are presented: Finlay Wilkinson model, AMMI model, GGE biplot. All of these approaches have in common that they merely try to group genotypes and environments and do not use other information than the two-way table of means. Next, factorial regression is introduced as an approach to explicitly introduce genotypic and environmental covariates for describing and explaining GEL Finally, OIL modeling is presented as a natural extension of factorial regression, where marker information is translated into genetic predictors. Tests for regression coefficients corresponding to these genetic predictors are tests for main effect OIL expression and OIL by environment interaction (QED. OIL models for which QEI depends on environmental covariables form an interesting model class for predicting GEI for new genotypes and new environments. For realistic modeling of genotypic differences across multiple environments, sophisticated mixed models are necessary to allow for heterogeneity of genetic variances and correlations across environments. The use and interpretation of all models is illustrated by an example data set from the CIMMYT maize breeding program, containing environments differing in drought and nitrogen stress. To help readers to carry out the statistical analyses, GenStat (R) programs, 15th Edition and Discovery (R) version, are presented as "Appendix"
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| Format: | Article/Letter to editor biblioteca |
| Language: | English |
| Subjects: | drought conditions, ecophysiological analyses, evaluation trials, flanking markers, mixed models, qtl analysis, quantitative trait loci, tropical maize, variance, wheat-variety database, |
| Online Access: | https://research.wur.nl/en/publications/the-statistical-analysis-of-multi-environment-data-modeling-genot |
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dig-wur-nl-wurpubs-4457362025-01-10 Malosetti, M. Ribaut, J.M. van Eeuwijk, F.A. Article/Letter to editor Frontiers in Physiology 4 (2013) ISSN: 1664-042X The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis 2013 Genotype-by-environment interaction (GEI) is an important phenomenon in plant breeding. This paper presents a series of models for describing, exploring, understanding, and predicting GEI. All models depart from a two-way table of genotype by environment means. First, a series of descriptive and explorative models/approaches are presented: Finlay Wilkinson model, AMMI model, GGE biplot. All of these approaches have in common that they merely try to group genotypes and environments and do not use other information than the two-way table of means. Next, factorial regression is introduced as an approach to explicitly introduce genotypic and environmental covariates for describing and explaining GEL Finally, OIL modeling is presented as a natural extension of factorial regression, where marker information is translated into genetic predictors. Tests for regression coefficients corresponding to these genetic predictors are tests for main effect OIL expression and OIL by environment interaction (QED. OIL models for which QEI depends on environmental covariables form an interesting model class for predicting GEI for new genotypes and new environments. For realistic modeling of genotypic differences across multiple environments, sophisticated mixed models are necessary to allow for heterogeneity of genetic variances and correlations across environments. The use and interpretation of all models is illustrated by an example data set from the CIMMYT maize breeding program, containing environments differing in drought and nitrogen stress. To help readers to carry out the statistical analyses, GenStat (R) programs, 15th Edition and Discovery (R) version, are presented as "Appendix" en application/pdf https://research.wur.nl/en/publications/the-statistical-analysis-of-multi-environment-data-modeling-genot 10.3389/fphys.2013.00044 https://edepot.wur.nl/286157 drought conditions ecophysiological analyses evaluation trials flanking markers mixed models qtl analysis quantitative trait loci tropical maize variance wheat-variety database Wageningen University & Research |
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drought conditions ecophysiological analyses evaluation trials flanking markers mixed models qtl analysis quantitative trait loci tropical maize variance wheat-variety database drought conditions ecophysiological analyses evaluation trials flanking markers mixed models qtl analysis quantitative trait loci tropical maize variance wheat-variety database |
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drought conditions ecophysiological analyses evaluation trials flanking markers mixed models qtl analysis quantitative trait loci tropical maize variance wheat-variety database drought conditions ecophysiological analyses evaluation trials flanking markers mixed models qtl analysis quantitative trait loci tropical maize variance wheat-variety database Malosetti, M. Ribaut, J.M. van Eeuwijk, F.A. The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis |
| description |
Genotype-by-environment interaction (GEI) is an important phenomenon in plant breeding. This paper presents a series of models for describing, exploring, understanding, and predicting GEI. All models depart from a two-way table of genotype by environment means. First, a series of descriptive and explorative models/approaches are presented: Finlay Wilkinson model, AMMI model, GGE biplot. All of these approaches have in common that they merely try to group genotypes and environments and do not use other information than the two-way table of means. Next, factorial regression is introduced as an approach to explicitly introduce genotypic and environmental covariates for describing and explaining GEL Finally, OIL modeling is presented as a natural extension of factorial regression, where marker information is translated into genetic predictors. Tests for regression coefficients corresponding to these genetic predictors are tests for main effect OIL expression and OIL by environment interaction (QED. OIL models for which QEI depends on environmental covariables form an interesting model class for predicting GEI for new genotypes and new environments. For realistic modeling of genotypic differences across multiple environments, sophisticated mixed models are necessary to allow for heterogeneity of genetic variances and correlations across environments. The use and interpretation of all models is illustrated by an example data set from the CIMMYT maize breeding program, containing environments differing in drought and nitrogen stress. To help readers to carry out the statistical analyses, GenStat (R) programs, 15th Edition and Discovery (R) version, are presented as "Appendix" |
| format |
Article/Letter to editor |
| topic_facet |
drought conditions ecophysiological analyses evaluation trials flanking markers mixed models qtl analysis quantitative trait loci tropical maize variance wheat-variety database |
| author |
Malosetti, M. Ribaut, J.M. van Eeuwijk, F.A. |
| author_facet |
Malosetti, M. Ribaut, J.M. van Eeuwijk, F.A. |
| author_sort |
Malosetti, M. |
| title |
The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis |
| title_short |
The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis |
| title_full |
The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis |
| title_fullStr |
The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis |
| title_full_unstemmed |
The statistical analysis of multi-environment data: Modeling genotype-by-environment interaction and its genetic basis |
| title_sort |
statistical analysis of multi-environment data: modeling genotype-by-environment interaction and its genetic basis |
| url |
https://research.wur.nl/en/publications/the-statistical-analysis-of-multi-environment-data-modeling-genot |
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