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Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems

Identifying opportunities and limitations for closing yield gaps is essential for setting right the efforts dedicated to improve germplasm and agronomic practices. This study analyses genotypes × environments interaction (G × E), genetic progress, and grain yield stability under contrasting producti...

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Autores principales: Herrera, Juan M., Levy Häner, Lilia, Mascher, Fabio, Hiltbrunner, Jürg, Fossati, Dario, Brabant, Cécile, Charles, Raphaël, Pellet, Didier
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6997878/
https://www.ncbi.nlm.nih.gov/pubmed/32063910
http://dx.doi.org/10.3389/fpls.2019.01745
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author Herrera, Juan M.
Levy Häner, Lilia
Mascher, Fabio
Hiltbrunner, Jürg
Fossati, Dario
Brabant, Cécile
Charles, Raphaël
Pellet, Didier
author_facet Herrera, Juan M.
Levy Häner, Lilia
Mascher, Fabio
Hiltbrunner, Jürg
Fossati, Dario
Brabant, Cécile
Charles, Raphaël
Pellet, Didier
author_sort Herrera, Juan M.
collection PubMed
description Identifying opportunities and limitations for closing yield gaps is essential for setting right the efforts dedicated to improve germplasm and agronomic practices. This study analyses genotypes × environments interaction (G × E), genetic progress, and grain yield stability under contrasting production systems. For this, we analyzed datasets obtained from three Swiss trial-networks of winter wheat that were designed to evaluate genotypes under organic farming conditions, conventional management with low-inputs (150 kg nitrogen (N) ha(−1) with no fungicide application) and conventional management with high-inputs (170 kg N ha(−1) with fungicide application). The datasets covered the periods from 1998 to 2018 for organic and conventional management with low-inputs and from 2008 to 2018 for conventional management with high-inputs. The trial-networks evaluated each year an average of 36 winter wheat genotypes that included released varieties, advanced breeding lines, and lines for registration and post-registration in Switzerland. We investigated within each trial-network the influence of years, genotypes, environments and their interactions on the total variance in grain yield and grain N concentration using variance components analyses. We further applied mixed models with regression features to dissect genetic components due to breeding efforts from non-genetic components. The genotype as a single factor or as a factor interacting with the environment or the year (G × E, G × year, and G × E × year) explained 13% (organic), 20% (conventional low-inputs), and 24% (conventional high-inputs) of the variance in grain yield, while the corresponding values for grain N concentration were 29%, 25%, and 32%. Grain yield has stagnated since 1990 for conventional systems while the trend under organic management was slightly negative. The dissection of a genetic component from the grain yield trends under conventional management showed that genetic improvements contributed with 0.58 and 0.68 t ha(−1) y(−1) with low- and high- inputs, respectively. In contrast, a significant genetic source in the grain yield trend under organic management was not detected. Therefore, breeding efforts have been less effective on the wheat productivity for organic farming conditions than for conventional ones.
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spelling pubmed-69978782020-02-14 Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems Herrera, Juan M. Levy Häner, Lilia Mascher, Fabio Hiltbrunner, Jürg Fossati, Dario Brabant, Cécile Charles, Raphaël Pellet, Didier Front Plant Sci Plant Science Identifying opportunities and limitations for closing yield gaps is essential for setting right the efforts dedicated to improve germplasm and agronomic practices. This study analyses genotypes × environments interaction (G × E), genetic progress, and grain yield stability under contrasting production systems. For this, we analyzed datasets obtained from three Swiss trial-networks of winter wheat that were designed to evaluate genotypes under organic farming conditions, conventional management with low-inputs (150 kg nitrogen (N) ha(−1) with no fungicide application) and conventional management with high-inputs (170 kg N ha(−1) with fungicide application). The datasets covered the periods from 1998 to 2018 for organic and conventional management with low-inputs and from 2008 to 2018 for conventional management with high-inputs. The trial-networks evaluated each year an average of 36 winter wheat genotypes that included released varieties, advanced breeding lines, and lines for registration and post-registration in Switzerland. We investigated within each trial-network the influence of years, genotypes, environments and their interactions on the total variance in grain yield and grain N concentration using variance components analyses. We further applied mixed models with regression features to dissect genetic components due to breeding efforts from non-genetic components. The genotype as a single factor or as a factor interacting with the environment or the year (G × E, G × year, and G × E × year) explained 13% (organic), 20% (conventional low-inputs), and 24% (conventional high-inputs) of the variance in grain yield, while the corresponding values for grain N concentration were 29%, 25%, and 32%. Grain yield has stagnated since 1990 for conventional systems while the trend under organic management was slightly negative. The dissection of a genetic component from the grain yield trends under conventional management showed that genetic improvements contributed with 0.58 and 0.68 t ha(−1) y(−1) with low- and high- inputs, respectively. In contrast, a significant genetic source in the grain yield trend under organic management was not detected. Therefore, breeding efforts have been less effective on the wheat productivity for organic farming conditions than for conventional ones. Frontiers Media S.A. 2020-01-28 /pmc/articles/PMC6997878/ /pubmed/32063910 http://dx.doi.org/10.3389/fpls.2019.01745 Text en Copyright © 2020 Herrera, Levy Häner, Mascher, Hiltbrunner, Fossati, Brabant, Charles and Pellet http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Plant Science
Herrera, Juan M.
Levy Häner, Lilia
Mascher, Fabio
Hiltbrunner, Jürg
Fossati, Dario
Brabant, Cécile
Charles, Raphaël
Pellet, Didier
Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems
title Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems
title_full Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems
title_fullStr Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems
title_full_unstemmed Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems
title_short Lessons From 20 Years of Studies of Wheat Genotypes in Multiple Environments and Under Contrasting Production Systems
title_sort lessons from 20 years of studies of wheat genotypes in multiple environments and under contrasting production systems
topic Plant Science
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6997878/
https://www.ncbi.nlm.nih.gov/pubmed/32063910
http://dx.doi.org/10.3389/fpls.2019.01745
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