Anqi Zhang, Tangchao Kong, Baiquan Sun, Shizheng Qiu, Jiahe Guo, Shuyong Ruan, Yu Guo, Jirui Guo, Zhishuai Zhang, Yue Liu, Zheng Hu, Tao Jiang, Yadong Liu, Shuqi Cao, Shi Sun, Tingting Wu, Huilong Hong, Bingjun Jiang, Maoxiang Yang, Xiangyu Yao, Yang Hu, Bo Liu, Tianfu Han, Yadong Wang
{"title":"大豆品种中黄13号的端粒到端粒基因组组装","authors":"Anqi Zhang, Tangchao Kong, Baiquan Sun, Shizheng Qiu, Jiahe Guo, Shuyong Ruan, Yu Guo, Jirui Guo, Zhishuai Zhang, Yue Liu, Zheng Hu, Tao Jiang, Yadong Liu, Shuqi Cao, Shi Sun, Tingting Wu, Huilong Hong, Bingjun Jiang, Maoxiang Yang, Xiangyu Yao, Yang Hu, Bo Liu, Tianfu Han, Yadong Wang","doi":"10.1016/j.cj.2023.10.003","DOIUrl":null,"url":null,"abstract":"Soybean (Glycine max) stands as a globally significant agricultural crop, and the comprehensive assembly of its genome is of paramount importance for unraveling its biological characteristics and evolutionary history. Nevertheless, previous soybean genome assemblies have harbored gaps and incompleteness, which have constrained in-depth investigations into soybean. Here, we present Telomere-to-Telomere (T2T) assembly of the Chinese soybean cultivar Zhonghuang 13 (ZH13) genome, termed ZH13-T2T, utilizing PacBio Hifi and ONT ultralong reads. We employed a multi-assembler approach, integrating Hifiasm, NextDenovo, and Canu, to minimize biases and enhance assembly accuracy. The assembly spans 1,015,024,879 bp, effectively resolving all 393 gaps that previously plagued the reference genome. Our annotation efforts identified 50,564 high-confidence protein-coding genes, 707 of which are novel. ZH13-T2T revealed longer chromosomes, 421 not-aligned regions (NARs), 112 structure variations (SVs), and a substantial expansion of repetitive element compared to earlier assemblies. Specifically, we identified 25.67 Mb of tandem repeats, an enrichment of 5S and 48S rDNAs, and characterized their genotypic diversity. In summary, we deliver the first complete Chinese soybean cultivar T2T genome. The comprehensive annotation, along with precise centromere and telomere characterization, as well as insights into structural variations, further enhance our understanding of soybean genetics and evolution.","PeriodicalId":10790,"journal":{"name":"Crop Journal","volume":"9 6","pages":"0"},"PeriodicalIF":6.0000,"publicationDate":"2023-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A telomere-to-telomere genome assembly of Zhonghuang 13, a widely-grown soybean variety from the original center of Glycine max\",\"authors\":\"Anqi Zhang, Tangchao Kong, Baiquan Sun, Shizheng Qiu, Jiahe Guo, Shuyong Ruan, Yu Guo, Jirui Guo, Zhishuai Zhang, Yue Liu, Zheng Hu, Tao Jiang, Yadong Liu, Shuqi Cao, Shi Sun, Tingting Wu, Huilong Hong, Bingjun Jiang, Maoxiang Yang, Xiangyu Yao, Yang Hu, Bo Liu, Tianfu Han, Yadong Wang\",\"doi\":\"10.1016/j.cj.2023.10.003\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Soybean (Glycine max) stands as a globally significant agricultural crop, and the comprehensive assembly of its genome is of paramount importance for unraveling its biological characteristics and evolutionary history. Nevertheless, previous soybean genome assemblies have harbored gaps and incompleteness, which have constrained in-depth investigations into soybean. Here, we present Telomere-to-Telomere (T2T) assembly of the Chinese soybean cultivar Zhonghuang 13 (ZH13) genome, termed ZH13-T2T, utilizing PacBio Hifi and ONT ultralong reads. We employed a multi-assembler approach, integrating Hifiasm, NextDenovo, and Canu, to minimize biases and enhance assembly accuracy. The assembly spans 1,015,024,879 bp, effectively resolving all 393 gaps that previously plagued the reference genome. Our annotation efforts identified 50,564 high-confidence protein-coding genes, 707 of which are novel. ZH13-T2T revealed longer chromosomes, 421 not-aligned regions (NARs), 112 structure variations (SVs), and a substantial expansion of repetitive element compared to earlier assemblies. 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A telomere-to-telomere genome assembly of Zhonghuang 13, a widely-grown soybean variety from the original center of Glycine max
Soybean (Glycine max) stands as a globally significant agricultural crop, and the comprehensive assembly of its genome is of paramount importance for unraveling its biological characteristics and evolutionary history. Nevertheless, previous soybean genome assemblies have harbored gaps and incompleteness, which have constrained in-depth investigations into soybean. Here, we present Telomere-to-Telomere (T2T) assembly of the Chinese soybean cultivar Zhonghuang 13 (ZH13) genome, termed ZH13-T2T, utilizing PacBio Hifi and ONT ultralong reads. We employed a multi-assembler approach, integrating Hifiasm, NextDenovo, and Canu, to minimize biases and enhance assembly accuracy. The assembly spans 1,015,024,879 bp, effectively resolving all 393 gaps that previously plagued the reference genome. Our annotation efforts identified 50,564 high-confidence protein-coding genes, 707 of which are novel. ZH13-T2T revealed longer chromosomes, 421 not-aligned regions (NARs), 112 structure variations (SVs), and a substantial expansion of repetitive element compared to earlier assemblies. Specifically, we identified 25.67 Mb of tandem repeats, an enrichment of 5S and 48S rDNAs, and characterized their genotypic diversity. In summary, we deliver the first complete Chinese soybean cultivar T2T genome. The comprehensive annotation, along with precise centromere and telomere characterization, as well as insights into structural variations, further enhance our understanding of soybean genetics and evolution.
Crop JournalAgricultural and Biological Sciences-Agronomy and Crop Science
CiteScore
9.90
自引率
3.00%
发文量
638
审稿时长
41 days
期刊介绍:
The major aims of The Crop Journal are to report recent progresses in crop sciences including crop genetics, breeding, agronomy, crop physiology, germplasm resources, grain chemistry, grain storage and processing, crop management practices, crop biotechnology, and biomathematics.
The regular columns of the journal are Original Research Articles, Reviews, and Research Notes. The strict peer-review procedure will guarantee the academic level and raise the reputation of the journal. The readership of the journal is for crop science researchers, students of agricultural colleges and universities, and persons with similar academic levels.