开花植物的雄配子发生

IF 3.7 2区 农林科学 Q2 FOOD SCIENCE & TECHNOLOGY Frontiers in Sustainable Food Systems Pub Date : 2024-01-05 DOI:10.3389/fsufs.2023.1333544
Dan-Lu Cui, Chun-Xia Xu, Ping Wang, Tianjun Gao, Bo Wang, Tian-Ying Yu
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引用次数: 0

摘要

植物生命周期的特点是二倍体孢子体世代和单倍体配子体世代之间的显著交替。减数分裂和受精是实现世代交替的先决条件。二倍体孢子体经过减数分裂产生单倍体配子,雌雄配子融合(双受精)后恢复为二倍体孢子体。雄配子体的形成和发育对高等植物的世代交替至关重要。在植物从水生到陆生的漫长进化过程中,有性生殖方式经历了颠覆性的革新。从精子游动受精,到依靠花粉管精确输送到雌配子,实现雌雄配子的融合,对雄配子体的发育和受精过程提出了更高的要求。为了满足雄配子的输送和运输需要,雄配子体的形成发生了重大变化。随着越来越多证据的出现,人们对雄配子体发育的分子机制,特别是生殖细胞的启动和特化有了更深入的了解。我们以最新研究为重点,回顾并阐明了参与雄配子体形成的关键蛋白和因子,强调了辅助素在原生质细胞特化中的决定性作用以及小孢子成熟在有丝分裂前期的重要性,并分析了雄配子发生的分子机制,以期为今后进一步探索雄配子体的形成提供启示。
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Male gametogenesis in flowering plants
The life cycles of plants are characterized by significant alternations between the diploid sporophytic and the haploid gametophytic generations. Meiosis and fertilization are the prerequisites for achieving the alternation of generations. Diploid sporophytes undergo meiosis to produce haploid gametes, and male–female gametes fuse (double fertilization) to revert to the diploid sporophyte. The formation and development of male gametophytes are crucial for the alternation of generations in higher plants. During the long evolution of plants from aquatic to terrestrial, the way of sexual reproduction has undergone subversive innovations. From sperm swimming for fertilization to relying on the precise delivery of pollen tubes to female gametes for the fusion of the male–female gametes, higher requirements are placed on the male gametophytes’ development and fertilization process. The formation of male gametophytes has undergone significant changes to meet the needs for delivery and transportation of the male gametes. With the emergence of more and more evidence, the molecular mechanism underlying male gametophytes’ development, especially the initiation and specialization of germline cells has been better understood. Focusing on the latest studies, we reviewed and elucidated the critical proteins and factors involved in male gametophyte formation, highlighting the decisive role of auxin in archesporial cell specialization and the importance of microspore maturation in pre-mitosis, and analyzed the molecular mechanisms underlying male gametogenesis, with a view to providing insights for further exploration of male gametophytes formation in the future.
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来源期刊
Frontiers in Sustainable Food Systems
Frontiers in Sustainable Food Systems Agricultural and Biological Sciences-Horticulture
CiteScore
5.60
自引率
6.40%
发文量
575
审稿时长
14 weeks
期刊最新文献
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