Bud shapes dictate tiller-rhizome transition in African perennial rice (Oryza longistaminata).

IF 4.4 1区 农林科学 Q1 AGRONOMY Theoretical and Applied Genetics Pub Date : 2024-07-30 DOI:10.1007/s00122-024-04699-6
Kai Wang, Yufei Lu, Suwen Jing, Ru Yang, Xianjie Xu, Yourong Fan, Jiangyi Yang
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Abstract

Key message: Rhizome formation of Oryza longistaminata was dependent on the bud shape. The loci qBS3.1, qBS3.2 and qBS3.3 for controlling rhizome formation were functional redundant under Oryza longistaminata background. The rhizome, a root-like underground stem, is the key organ for grasses to achieve perennial growth. Oryza longistaminata, the only rhizomatous wild Oryza species with the same AA genome as cultivated rice, is an important germplasm for developing perennial rice. Our study found that the rhizome formation of O. longistaminata was dependent on the bud shape: the dome-like axillary bud (dome bud) usually penetrated through the leaf sheaths, developing into rhizome (extravaginal branching), but the flat axillary bud (flat bud) wrapped by the leaf sheaths only developed into tiller (intravaginal branching). The genetic loci (QTL) controlling the bud shape (BS) were mapped by entire population genotyping method (F2 population from crossing O. longistaminata with Balilla (Oryza sativa) and selective genotyping mapping method (BC1F2 population from backcrossing F1 with Balilla). A total of twelve loci were identified, including four major-effect QTL: qBS2, qBS3.1, qBS3.2 and qBS3.3, and the genetic network of these twelve loci was established. The dome bud lost the potential to develop into rhizome with the increase in backcross generations under Balilla background. Considering the rapid loss of rhizome under Balilla background, the near-isogenic lines under O. longistaminata background were used to identify the effect of major-effect loci. According to the BC3F2, BC4F2 and BC5F2 under O. longistaminata background, there was some functional redundancy among qBS3.1, qBS3.2 and qBS3.3. Our results provided a new perspective for analyzing the genetic basis of perenniality and laid the foundation for fine mapping and verification of related genes.

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芽的形状决定了非洲多年生水稻(Oryza longistaminata)的分蘖-根茎过渡。
关键信息:Oryza longistaminata根茎的形成取决于芽的形状。控制根状茎形成的位点qBS3.1、qBS3.2和qBS3.3在Oryza longistaminata背景下存在功能冗余。根状茎是一种根状地下茎,是禾本科植物实现多年生生长的关键器官。Oryza longistaminata是唯一与栽培稻具有相同AA基因组的根瘤野生稻种,是开发多年生水稻的重要种质。我们的研究发现,O. longistaminata的根状茎形成与芽的形状有关:圆顶状的腋芽(圆顶芽)通常穿透叶鞘,发育成根状茎(叶外分枝),而被叶鞘包裹的扁平腋芽(扁芽)只发育成分蘖(叶内分枝)。通过全群体基因分型法(O. longistaminata与Balilla(Oryza sativa)杂交的F2群体)和选择性基因分型法(F1与Balilla回交的BC1F2群体)绘制了控制芽形(BS)的遗传位点(QTL)。共鉴定出 12 个位点,包括 4 个主要效应 QTL:qBS2、qBS3.1、qBS3.2 和 qBS3.3,并建立了这 12 个位点的遗传网络。在巴利拉背景下,随着回交代数的增加,圆顶芽失去了发育成根茎的潜力。考虑到在巴利拉背景下根茎的迅速丧失,研究人员利用O. longistaminata背景下的近等基因系来鉴定主要效应位点的影响。结果表明,O.longistaminata背景下的BC3F2、BC4F2和BC5F2中,qBS3.1、qBS3.2和qBS3.3之间存在一定的功能冗余。我们的研究结果为分析多年生植物的遗传基础提供了一个新的视角,并为相关基因的精细图谱绘制和验证奠定了基础。
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来源期刊
CiteScore
9.60
自引率
7.40%
发文量
241
审稿时长
2.3 months
期刊介绍: Theoretical and Applied Genetics publishes original research and review articles in all key areas of modern plant genetics, plant genomics and plant biotechnology. All work needs to have a clear genetic component and significant impact on plant breeding. Theoretical considerations are only accepted in combination with new experimental data and/or if they indicate a relevant application in plant genetics or breeding. Emphasizing the practical, the journal focuses on research into leading crop plants and articles presenting innovative approaches.
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