| Literature DB >> 34045708 |
Yun Zhou1, Shenglong Bai1, Hao Li1, Guiling Sun1, Dale Zhang1, Feifei Ma1, Xinpeng Zhao1, Fang Nie1, Jingyao Li1, Liyang Chen2, Linlin Lv1, Lele Zhu1, Ruixiao Fan1, Yifan Ge1, Aaqib Shaheen1, Guanghui Guo1, Zhen Zhang1, Jianchao Ma1, Huihui Liang1, Xiaolong Qiu1, Jiamin Hu1, Ting Sun1, Jingyi Hou1, Hongxing Xu1, Shulin Xue1, Wenkai Jiang2, Jinling Huang1,3, Suoping Li1, Changsong Zou4, Chun-Peng Song5.
Abstract
Increasing crop production is necessary to feed the world's expanding population, and crop breeders often utilize genetic variations to improve crop yield and quality. However, the narrow diversity of the wheat D genome seriously restricts its selective breeding. A practical solution is to exploit the genomic variations of Aegilops tauschii via introgression. Here, we established a rapid introgression platform for transferring the overall genetic variations of A. tauschii to elite wheats, thereby enriching the wheat germplasm pool. To accelerate the process, we assembled four new reference genomes, resequenced 278 accessions of A. tauschii and constructed the variation landscape of this wheat progenitor species. Genome comparisons highlighted diverse functional genes or novel haplotypes with potential applications in wheat improvement. We constructed the core germplasm of A. tauschii, including 85 accessions covering more than 99% of the species' overall genetic variations. This was crossed with elite wheat cultivars to generate an A. tauschii-wheat synthetic octoploid wheat (A-WSOW) pool. Laboratory and field analysis with two examples of the introgression lines confirmed its great potential for wheat breeding. Our high-quality reference genomes, genomic variation landscape of A. tauschii and the A-WSOW pool provide valuable resources to facilitate gene discovery and breeding in wheat.Entities:
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Year: 2021 PMID: 34045708 DOI: 10.1038/s41477-021-00934-w
Source DB: PubMed Journal: Nat Plants ISSN: 2055-0278 Impact factor: 15.793