Genomic analysis of Zhou8425B, a key founder parent, reveals its genetic contributions to elite agronomic traits in wheat breeding

High-quality genome information is essential for efficiently deciphering and improving crop traits. Here, we report a highly contiguous and accurate hexaploid genome assembly for the key wheat breeding parent Zhou8425B, an elite 1BL/1RS translocation line with durable adult plant resistance (APR) ag...

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Published in:Plant communications 2024-12, p.101222, Article 101222
Main Authors: Li, Guangwei, Ren, Yan, Yang, Yuxin, Chen, Shulin, Zheng, Jizhou, Zhang, Xiaoqing, Li, Junlong, Chen, Mengen, Sun, Xiaonan, Lv, Chunlei, Li, Xiaode, Zhang, Bingbing, Sun, Xiao, Li, Yujia, Zhao, Mingtian, Dong, Chunhao, Tang, Jianwei, Huang, Zhenpu, Peng, Yanyan, Gu, Dengbin, Wang, Zhiyong, Zheng, Hongyuan, Shi, Cuilan, Kang, Guozhang, Zheng, Tiancun, Chen, Feng, Wang, Daowen, Zhang, Kunpu, Yin, Guihong
Format: Article
Language:English
Subjects:
1RS translocation
adult plant resistance
common wheat
founder genotype effects
genome assembly
yellow rust disease
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Summary:High-quality genome information is essential for efficiently deciphering and improving crop traits. Here, we report a highly contiguous and accurate hexaploid genome assembly for the key wheat breeding parent Zhou8425B, an elite 1BL/1RS translocation line with durable adult plant resistance (APR) against yellow rust (YR) disease. By integrating HiFi and Hi-C sequencing reads, we generated a 14.75-Gb genome assembly for Zhou8425B with a contig N50 of 70.94 and a scaffold N50 of 735.11 Mb. Comparisons with previously sequenced common wheat cultivars shed light on structural changes in the 1RS chromosome arm, which has been extensively used in wheat improvement. Interestingly, Zhou8425B 1RS carries more genes encoding AP2/ERF-ERF or B3 transcription factors than its counterparts in four previously sequenced wheat and rye genotypes. The Zhou8425B genome assembly aided in the fine mapping of a new APR locus (YrZH3BS) that confers resistance to YR disease and promotes grain yield under field conditions. Notably, pyramiding YrZH3BS with two previously characterized APR loci (YrZH22 and YrZH84) can further reduce YR severity and enhance grain yield, with the triple combination (YrZH3B + YrZH22 + YrZH84) having the greatest effect. Finally, the founder genotype effects of Zhou8425B were explored using publicly available genome resequencing data, which revealed the presence of important Zhou8425B genomic blocks in its derivative cultivars. Our data demonstrate the value of the Zhou8425B genome assembly for further study of the structural and functional characteristics of 1RS, the genetic basis of durable YR resistance, and founder genotype effects in wheat breeding. Our resources will facilitate the development of elite wheat cultivars through genomics-assisted breeding. This study reports a highly contiguous and accurate genome assembly for Zhou8425B, a key wheat founder parent with many hundreds of derivative cultivars, and provides insights into the genetic contributions of Zhou8425B to elite agronomic traits, e.g., yield-related traits and durable yellow rust resistance, in wheat breeding. These results will aid genomics-assisted wheat improvement in the future.
ISSN:2590-3462
2590-3462
DOI:10.1016/j.xplc.2024.101222