Common genetic basis for canopy temperature depression under heat and drought stress associated with optimized root distribution in bread wheat

Key message QTL related to cooler canopy temperatures are associated with optimal root distribution whereby roots proliferate at depth under drought or near to surface under hot, irrigated conditions. Previous research using a bread wheat RIL population of the Seri/Babax cross showed that common QTL...

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Bibliographic Details
Published in:Theoretical and applied genetics 2015-04, Vol.128 (4), p.575-585
Main Authors: Pinto, R. Suzuky, Reynolds, Matthew P.
Format: Article
Language:English
Subjects:
Acclimatization - genetics
Adaptation
Agricultural production
Agriculture
Biochemistry
Biomedical and Life Sciences
Biotechnology
Climate change
Drought
Droughts
Gene expression
Genetic aspects
Genotype
Health aspects
Heat
Hot Temperature
Identification and classification
Life Sciences
Original Paper
Plant Biochemistry
Plant Breeding/Biotechnology
Plant Genetics and Genomics
Plant Roots - growth & development
Quantitative Trait Loci
Rice
Stress, Physiological
Temperature
Temperature effects
Triticum - genetics
Triticum - physiology
Triticum aestivum
Wheat
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Summary:Key message QTL related to cooler canopy temperatures are associated with optimal root distribution whereby roots proliferate at depth under drought or near to surface under hot, irrigated conditions. Previous research using a bread wheat RIL population of the Seri/Babax cross showed that common QTL were associated with cooler canopies under both drought and heat-stressed conditions. A subset of RIL was grown under water-limited and hot-irrigated field environments to test how cooler canopies are related to root development. Eight sisters and the two parents were used in the study with genotypes grouped as COOL or HOT according to their respective QTL for canopy temperature and previous phenotypic data. Root mass production and residual available soil moisture were measured around anthesis at four depth profiles (from 0 to 120 cm depth). When considering different root profiles, there was a clear interaction of QTL with environment. Under water stress, the COOL genotypes showed a deeper root system allowing the extraction of 35 % more water from the 30–90 cm soil profile. The strategy under heat was to concentrate more roots at the surface, in the 0–60 cm soil layer where water was more available from surface irrigation. Since COOL genotypes showed better agronomic performance, it can be concluded that their QTL are associated with more optimal root distribution in accordance with water availability under the respective stresses. The study demonstrates the importance of root development under both water-limited and hot-irrigated environments, and shows a common genetic basis for adaptation to both stresses that appears to be associated with sensitivity of roots to proliferate where water is available in the soil profile.
ISSN:0040-5752
1432-2242
DOI:10.1007/s00122-015-2453-9