The jacktree genome and population genomics provides insights for the mechanisms of the germination obstacle and the conservation of endangered ornamental plants.

IF 7.6 Q1 GENETICS & HEREDITY 园艺研究(英文) Pub Date : 2024-06-18 eCollection Date: 2024-08-01 DOI:10.1093/hr/uhae166
Sheng Zhu, Xue-Fen Wei, Yu-Xin Lu, Dao-Wu Zhang, Ze-Fu Wang, Jing Ge, Sheng-Lian Li, Yan-Feng Song, Yong Yang, Xian-Gui Yi, Min Zhang, Jia-Yu Xue, Yi-Fan Duan
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Abstract

Sinojackia Hu represents the first woody genus described by Chinese botanists, with all species classified as endangered ornamental plants endemic to China. Their characteristic spindle-shaped fruits confer high ornamental value to the plants, making them favored in gardens and parks. Nevertheless, the fruits likely pose a germination obstacle, contributing to the endangered status of this lineage. Here we report the chromosome-scale genome of S. xylocarpa, and explore the mechanisms underlying its endangered status, as well as its population dynamics throughout evolution. Population genomic analysis has indicated that S. xylocarpa experienced a bottleneck effect following the recent glacial period, leading to a continuous population reduction. Examination of the pericarp composition across six stages of fruit development revealed a consistent increase in the accumulation of lignin and fiber content, responsible for the sturdiness of mature fruits' pericarps. At molecular level, enhanced gene expression in the biosynthesis of lignin, cellulose and hemicellulose was detected in pericarps. Therefore, we conclude that the highly lignified and fibrotic pericarps of S. xylocarpa, which inhibit its seed germination, should be its threatening mechanism, thus proposing corresponding strategies for improved conservation and restoration. This study serves as a seminal contribution to conservation biology, offering valuable insights for the study of other endangered ornamental plants.

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千层塔基因组和种群基因组学为濒危观赏植物的发芽障碍机制和保护提供了启示。
胡颓子是中国植物学家描述的第一个木本属,所有物种都被列为中国特有的濒危观赏植物。其特有的纺锤形果实赋予了植物很高的观赏价值,使其在园林和公园中备受青睐。然而,果实很可能会阻碍发芽,从而导致这一品系濒临灭绝。在此,我们报告了 S. xylocarpa 的染色体级基因组,并探讨了其濒危地位的内在机制及其在整个进化过程中的种群动态。种群基因组分析表明,S. xylocarpa 在最近的冰川期后经历了瓶颈效应,导致种群数量持续减少。对果实六个发育阶段的果皮成分进行的研究表明,木质素和纤维含量的积累持续增加,这也是成熟果实果皮坚固的原因。在分子水平上,果皮中木质素、纤维素和半纤维素的生物合成基因表达增强。因此,我们得出结论:木菠萝果皮的高度木质化和纤维化抑制了其种子的萌发,这应该是其威胁机制,从而提出了相应的保护和恢复策略。这项研究是对保护生物学的开创性贡献,为研究其他濒危观赏植物提供了宝贵的启示。
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