Crop adaptation to climate change as a consequence of long-term breeding

Major global crops in high-yielding, temperate cropping regions are facing increasing threats from the impact of climate change, particularly from drought and heat at critical developmental timepoints during the crop lifecycle. Research to address this concern is frequently focused on attempts to id...

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Bibliographic Details
Published in:Theoretical and applied genetics 2021-06, Vol.134 (6), p.1613-1623
Main Authors: Snowdon, Rod J., Wittkop, Benjamin, Chen, Tsu-Wei, Stahl, Andreas
Format: Article
Language:English
Subjects:
Adaptation, Physiological
Agriculture
Biochemistry
Biomedical and Life Sciences
Biotechnology
Breeding crops for climate resilience
Climate adaptation
Climate Change
Crops
Crops, Agricultural - genetics
Crops, Agricultural - physiology
Drought
Droughts
Environmental aspects
Genes
Genes, Plant
Genetic diversity
Genetic factors
Genetic Variation
Genetically modified organisms
Germany
Global temperature changes
Life Sciences
Multigene Family
Plant Biochemistry
Plant Breeding
Plant Breeding/Biotechnology
Plant genetics
Plant Genetics and Genomics
Review
Stress, Physiological
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Summary:Major global crops in high-yielding, temperate cropping regions are facing increasing threats from the impact of climate change, particularly from drought and heat at critical developmental timepoints during the crop lifecycle. Research to address this concern is frequently focused on attempts to identify exotic genetic diversity showing pronounced stress tolerance or avoidance, to elucidate and introgress the responsible genetic factors or to discover underlying genes as a basis for targeted genetic modification. Although such approaches are occasionally successful in imparting a positive effect on performance in specific stress environments, for example through modulation of root depth, major-gene modifications of plant architecture or function tend to be highly context-dependent. In contrast, long-term genetic gain through conventional breeding has incrementally increased yields of modern crops through accumulation of beneficial, small-effect variants which also confer yield stability via stress adaptation. Here we reflect on retrospective breeding progress in major crops and the impact of long-term, conventional breeding on climate adaptation and yield stability under abiotic stress constraints. Looking forward, we outline how new approaches might complement conventional breeding to maintain and accelerate breeding progress, despite the challenges of climate change, as a prerequisite to sustainable future crop productivity.
ISSN:0040-5752
1432-2242
DOI:10.1007/s00122-020-03729-3