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Designing future barley ideotypes using a crop model ensemble

Tao, Fulu, Rötter, Reimund P., Palosuo, Taru, Díaz-Ambrona, C.G.H., Mínguez, M. Inés, Semenov, Mikhail A., Kersebaum, Kurt Christian, Nendel, Claas, Cammarano, Davide, Hoffmann, Holger, Ewert, Frank, Dambreville, Anaelle, Martre, Pierre, Rodríguez, Lucía, Ruiz-Ramos, Margarita, Gaiser, Thomas, Höhn, Jukka G., Salo, Tapio, Ferrise, Roberto, Bindi, Marco, Schulman, Alan H.
European journal of agronomy 2017 v.82 pp. 144-162
Hordeum vulgare, abiotic stress, barley, climate change, climatic factors, climatic zones, crop models, cultivars, drought tolerance, ecophysiology, genes, genetic traits, genotype, ideotypes, information exchange, leaves, phenology, photoperiod, photosynthesis, plant breeders, quantitative trait loci, radiation use efficiency, simulation models, stress tolerance, vernalization, weather, Europe
Climate change and its associated higher frequency and severity of adverse weather events require genotypic adaptation. Process-based ecophysiological modelling offers a powerful means to better target and accelerate development of new crop cultivars. Barley (Hordeum vulgare L.) is an important crop throughout the world, and a good model for study of the genetics of stress adaptation because many quantitative trait loci and candidate genes for biotic and abiotic stress tolerance have been identified in it. Here, we developed a new approach to design future crop ideotypes using an ensemble of eight barley simulation models (i.e. APSIM, CropSyst, HERMES, MCWLA, MONICA, SIMPLACE, SiriusQuality, and WOFOST), and applied it to design climate-resilient barley ideotypes for Boreal and Mediterranean climatic zones in Europe. The results showed that specific barley genotypes, represented by sets of cultivar parameters in the crop models, could be promising under future climate change conditions, resulting in increased yields and low inter-annual yield variability. In contrast, other genotypes could result in substantial yield declines. The most favorable climate-zone-specific barley ideotypes were further proposed, having combinations of several key genetic traits in terms of phenology, leaf growth, photosynthesis, drought tolerance, and grain formation. For both Boreal and Mediterranean climatic zones, barley ideotypes under future climatic conditions should have a longer reproductive growing period, lower leaf senescence rate, larger radiation use efficiency or maximum assimilation rate, and higher drought tolerance. Such characteristics can produce substantial positive impacts on yields under contrasting conditions. Moreover, barley ideotypes should have a low photoperiod and high vernalization sensitivity for the Boreal climatic zone; for the Mediterranean, in contrast, it should have a low photoperiod and low vernalization sensitivity. The drought-tolerance trait is more beneficial for the Mediterranean than for the Boreal climatic zone. Our study demonstrates a sound approach to design future barley ideotypes based on an ensemble of well-tested, diverse crop models and on integration of knowledge from multiple disciplines. The robustness of model-aided ideotypes design can be further enhanced by continuously improving crop models and enhancing information exchange between modellers, agro-meteorologists, geneticists, physiologists, and plant breeders.