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Dissection of genomic drivers of spike morphology changes in wheat by high-throughput phenotyping

Kuocheng Shen, Botao Ye, Xuchang Yu, Peng Shen, Rui Yu, Changbin Yin, Xiaowan Xu, Jing Dong, Ziying Wang, He Wu, Yi-Ming Zang, Jiaxin Li, Yanchun Peng, Dejun Han, Zhonghu He, Xueyong Zhang, Junming Li, Chenyang Hao, Zhiliang Zhang, Lipeng Kang, Song Xu, Fei Lü, Yuanfeng Hao, Tingting Wu, Jianhui Wu, Zifeng Guo

2025Cell Reports7 citationsDOIOpen Access PDF

Abstract

Spike morphology is crucial for wheat (Triticum aestivum L.) yield and environmental adaptation. We developed a high-throughput phenotyping platform to dissect spike morphology traits based on 54 traits in 1,359 wheat accessions. These 54 spike morphology traits exhibited clear geographical differences among 306 worldwide accessions and breeding selection trend across different time windows for 1,053 accessions released from 1900 to 2020 in China. Based on geographical distribution and breeding selection of haplotypes, we attribute the differences in spike morphology to variable haplotype combinations. Wheat breeding breaks the trade-off between spike length and width/thickness, resulting in increased spike volume. A large proportion of genomic regions has been identified across wheat varieties and utilized as a fixed group to facilitate the targeted improvement and selection of desirable traits during wheat breeding programs. Overall, we provide a resource for the molecular design of spike morphology to facilitate future wheat breeding.

Topics & Concepts

Morphology (biology)Spike (software development)BiologyThroughputDissection (medical)Computational biologyEvolutionary biologyGeneticsAnatomyComputer scienceSoftware engineeringTelecommunicationsWirelessWheat and Barley Genetics and PathologyGenetic Mapping and Diversity in Plants and AnimalsGenetic diversity and population structure