High-throughput phenotyping of physiological traits for wheat resilience to high temperature and drought stress

0561388 - ÚVGZ 2023 RIV GB eng J - Journal Article
Correia, P. M. P. - Westergaard, J. C. - da Silva, A. B. - Roitsch, Thomas - Carmo-Silva, E. - da Silva, J. M.
High-throughput phenotyping of physiological traits for wheat resilience to high temperature and drought stress.
Journal of Experimental Botany. Roč. 73, č. 15 (2022), s. 5235-5251. ISSN 0022-0957. E-ISSN 1460-2431
R&D Projects: GA MŠMT(CZ) LO1415
Research Infrastructure: CzeCOS III - 90123
Institutional support: RVO:86652079
Keywords : Carbohydrate metabolism * climate change * drought resilience * food security * high temperature * high-throughput plant phenotyping * multispectral imaging * Triticum aestivum * water deficit * wheat
OECD category: Plant sciences, botany
Impact factor: 6.9, year: 2022
Method of publishing: Open access
https://academic.oup.com/jxb/article/73/15/5235/6572012?login=true

Interannual and local fluctuations in wheat crop yield are mostly explained by abiotic constraints. Heatwaves and drought, which are among the top stressors, commonly co-occur, and their frequency is increasing with global climate change. High-throughput methods were optimized to phenotype wheat plants under controlled water deficit and high temperature, with the aim to identify phenotypic traits conferring adaptative stress responses. Wheat plants of 10 genotypes were grown in a fully automated plant facility under 25/18 degrees C day/night for 30 d, and then the temperature was increased for 7 d (38/31 degrees C day/night) while maintaining half of the plants well irrigated and half at 30% field capacity. Thermal and multispectral images and pot weights were registered twice daily. At the end of the experiment, key metabolites and enzyme activities from carbohydrate and antioxidant metabolism were quantified. Regression machine learning models were successfully established to predict plant biomass using image-extracted parameters. Evapotranspiration traits expressed significant genotype-environment interactions (GxE) when acclimatization to stress was continuously monitored. Consequently, transpiration efficiency was essential to maintain the balance between water-saving strategies and biomass production in wheat under water deficit and high temperature. Stress tolerance included changes in carbohydrate metabolism, particularly in the sucrolytic and glycolytic pathways, and in antioxidant metabolism. The observed genetic differences in sensitivity to high temperature and water deficit can be exploited in breeding programmes to improve wheat resilience to climate change.
Permanent Link: https://hdl.handle.net/11104/0334198