Construction of a Female Sterility Maintaining System Based on a Novel Mutation of the MEL2 Gene

IF 4.8 1区 农林科学 Q1 AGRONOMY Rice Pub Date : 2024-02-04 DOI:10.1186/s12284-024-00688-x
Xia Wang, Shuting Yuan, Changjian Wang, Wei Yan, Gang Xie, Cuifang Wang, Shijun Qiu, Jianxin Wu, Xing Wang Deng, Chunjue Xu, Xiaoyan Tang
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Abstract

Background

Hybrid rice has significant yield advantage and stress tolerance compared with inbred rice. However, production of hybrid rice seeds requires extensive manual labors. Currently, hybrid rice seeds are produced by crosspollination of male sterile lines by fertile paternal lines. Because seeds from paternal lines can contaminate the hybrid seeds, mechanized production by mixed-seeding and mixed-harvesting is difficult. This problem can be solved if the paternal line is female sterile.

Results

Here we identified a female infertile mutant named h569 carrying a novel mutation (A1106G) in the MEL2 gene that was previously reported to regulate meiosis entry both in male and female organs. h569 mutant is female infertile but male normal, suggesting that MEL2 regulates meiosis entry in male and female organs through distinct pathways. The MEL2 gene and h569 mutant gave us tools to construct female sterility maintaining systems that can be used for propagation of female sterile lines. We connected the wild-type MEL2 gene with pollen-killer gene ZmAA1 and seed-marker gene DsRed2 in one T-DNA cassette and transformed it into ZZH1607, a widely used restorer line. Transgenic line carrying a single transgene inserted in an intergenic region was selected to cross with h569 mutant. F2 progeny carrying homozygous A1106G mutation and hemizygous transgene displayed 1:1 segregation of fertile and infertile pollen grains and 1:1 segregation of fluorescent and non-fluorescent seeds upon self-fertilization. All of the non-fluorescent seeds generated female infertile plants, while the fluorescent seeds generated fertile plants that reproduced in the way as their previous generation.

Conclusions

These results indicated that the female sterility maintaining system constructed in the study can be used to breed and propagate paternal lines that are female infertile. The application of this system will enable mechanized production of hybrid rice seed by using the mixed-seeding and mixed harvesting approach, which will significantly reduce the cost in hybrid rice seed production.

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基于 MEL2 基因的新型突变构建雌性不育维持系统
背景与近交系水稻相比,杂交水稻具有显著的产量优势和抗逆性。然而,杂交水稻种子的生产需要大量的手工劳动。目前,杂交水稻种子是通过雄性不育系与可育父系杂交授粉生产出来的。由于父本品系的种子会污染杂交种子,因此很难通过混合播种和混合收获进行机械化生产。结果我们发现了一个名为 h569 的雌性不育突变体,其携带的 MEL2 基因有一个新的突变(A1106G),之前有报道称 MEL2 基因可同时调控雌雄器官的减数分裂进入。MEL2基因和h569突变体为我们构建雌性不育维持系统提供了工具,该系统可用于繁殖雌性不育系。我们将野生型 MEL2 基因与花粉杀伤基因 ZmAA1 和种子标记基因 DsRed2 连接在一个 T-DNA 盒中,并将其转化到广泛使用的恢复系 ZZH1607 中。筛选出在基因间区插入单个转基因的转基因品系与 h569 突变体杂交。携带同源突变 A1106G 和半杂合转基因的 F2 后代在自交时,可育和不育花粉粒的分离比例为 1:1,荧光和非荧光种子的分离比例为 1:1。这些结果表明,本研究构建的雌性不育维持系统可用于培育和繁殖雌性不育的父本品系。该系统的应用将使杂交水稻种子的机械化生产成为可能,采用混合播种和混合收获的方法,将大大降低杂交水稻种子生产的成本。
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来源期刊
Rice
Rice AGRONOMY-
CiteScore
10.10
自引率
3.60%
发文量
60
审稿时长
>12 weeks
期刊介绍: Rice aims to fill a glaring void in basic and applied plant science journal publishing. This journal is the world''s only high-quality serial publication for reporting current advances in rice genetics, structural and functional genomics, comparative genomics, molecular biology and physiology, molecular breeding and comparative biology. Rice welcomes review articles and original papers in all of the aforementioned areas and serves as the primary source of newly published information for researchers and students in rice and related research.
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