Insights into the genomic divergence of maize heterotic groups in China

doi:10.1111/jipb.13884

Insights into the genomic divergence of maize heterotic groups in China

Yingjie Xue^1†, Yikun Zhao^1†, Yunlong Zhang^1†, Rui Wang^1†, Xiaohui Li², Zhihao Liu¹, Weiwei Wang¹, Shaoxi Zhu¹, Yaming Fan¹, Liwen Xu¹, Wei Zhao¹, Jiuran Zhao^1* and Fengge Wang^1*

1. Maize Research Institute, Beijing Academy of Agriculture & Forestry Sciences (BAAFS), Beijing Key Laboratory of Maize DNA Fingerprinting and Molecular Breeding, Key Laboratory of Crop DNA Fingerprinting Innovation and Utilization (Co‐construction by Ministry and Province), Ministry of Agriculture and Rural Affairs, Shuguang Garden Middle Road No. 9, Beijing 100097, China
2. Maize Research Institute, Jilin Academy of Agricultural Sciences, Gongzhuling 136100, China

^†These authors have contributed equally to this work.
^*Correspondences: Jiuran Zhao (maizezhao@126.com); Fengge Wang (fenggewangmaize@126.com, Dr. Wang is fully responsible for the distribution of all materials associated with this article)

Received:2024-08-26 Accepted:2025-02-13 Online:2025-03-20
Supported by:
This work was funded by the Biological Breeding‐National Science and Technology Major Project (2022ZD04017) and the Construction and Scientific and Technological Innovation Capacity of Beijing Academy of Agriculture and Forestry Sciences (No. KJCX20230301), and National Innovation Center for Digital Seed Industry.

Abstract

Abstract: Diverse heterotic groups have been developed in China over several decades, but their genomic divergences have not been systematically studied after improvement. In this study, we performed Maize6H-60K array of 5,822 maize accessions and whole-genome re-sequencing of 150 inbred lines collected in China. Using multiple population structure analysis methods, we established a genetic boundary used to categorize heterotic groups and germplasm resources. We identified three chloroplast–cytoplasmic types that evolved during adaptation to diverse climatic environments in maize through phylogenetic and haplotype analyses. Comparative analyses revealed obvious genetic differences between heterotic groups and germplasm resources at both the chloroplast and nuclear genome levels, especially in the unique heterotic groups HG1 and HG2, which exhibited distinct regionality and genetic uniqueness. The divergent differentiation of heterotic groups from germplasm resources was driven by differential selection in specific genomic regions. Genome-wide selective sweep analysis identified core selected regions and candidate selected genes associated with traits between heterotic groups, highlighting that stress response- and plant defense-related genes were selected for environmental adaptation across a broad latitudinal range in China. Meanwhile, a genome-wide association study analysis provided evidence that core selected genes served as an important candidate gene pool with a potential role in genetic improvement. Gene exchanges among heterotic groups, which avoided the predominant heterotic patterns as much as possible, occurred to achieve population improvement during modern maize breeding. This study provides insights into the population differentiation and genetic characteristics of heterotic groups, which will facilitate the utilization of germplasm resources, the creation of novel maize germplasm, and the optimization of heterotic patterns during future maize breeding in China.

Key words: genetic difference, germplasm resource, heterotic group, maize, population differentiation

Yingjie Xue, Yikun Zhao, Yunlong Zhang, Rui Wang, Xiaohui Li, Zhihao Liu, Weiwei Wang, Shaoxi Zhu, Yaming Fan, Liwen Xu, Wei Zhao, Jiuran Zhao, Fengge Wang. Insights into the genomic divergence of maize heterotic groups in China[J]. J Integr Plant Biol., DOI: 10.1111/jipb.13884.

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Insights into the genomic divergence of maize heterotic groups in China

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