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Has breeding altered the light environment, photosynthetic apparatus, and photosynthetic capacity of wheat leaves?

Yuting Li, Ying Li, Jianmin Song, Qian‐Huan Guo, Chengfeng Yang, Wenjing Zhao, Junyan Wang, Jiao Luo, Yanni Xu, Qiang Zhang, Xinyu Ding, Ying Liang, Yue‐Nan Li, Qiu-Ling Feng, Peng Liu, Huiyuan Gao, Geng Li, Shijie Zhao, Zishan Zhang

2021Journal of Experimental Botany17 citationsDOIOpen Access PDF

Abstract

Whether photosynthesis has improved with increasing yield in major crops remains controversial. Research in this area has often neglected to account for differences in light intensity experienced by cultivars released in different years. Light intensity is expected to be positively associated with photosynthetic capacity and the resistance of the photosynthetic apparatus to high light but negatively associated with light-utilization efficiency under low light. Here, we analyzed the light environment, photosynthetic activity, and protein components of leaves of 26 winter wheat cultivars released during the past 60 years in China. Over time, light levels on flag leaves significantly decreased due to architectural changes, but photosynthetic rates under high or low light and the resistance of the photosynthetic apparatus to high light remained steady, contrary to expectations. We propose that the difference between the actual and expected trends is due to breeding. Specifically, breeding has optimized photosynthetic performance under high light rather than low light. Moreover, breeding selectivity altered the stoichiometry of several proteins related to dynamic photosynthesis, canopy light distribution, and photoprotection. These results indicate that breeding has significantly altered the photosynthetic mechanism in wheat and its response to the light environment. These changes likely have helped increase wheat yields.

Topics & Concepts

PhotosynthesisPhotoprotectionLight intensityCanopyBiologyPhotosynthetic efficiencyCultivarPhotosynthetic capacityLight energyNon-photochemical quenchingAgronomyBotanyPhotosystem IIOpticsPhysicsPlant responses to elevated CO2Crop Yield and Soil FertilityPlant Water Relations and Carbon Dynamics