生物多样性 ›› 2022, Vol. 30 ›› Issue (7): 22065. DOI: 10.17520/biods.2022065
所属专题: 物种形成与系统进化
收稿日期:
2022-02-08
接受日期:
2022-04-19
出版日期:
2022-07-20
发布日期:
2022-06-06
通讯作者:
王芸芸
作者简介:
*E-mail: yyzhsh3210@163.com基金资助:
Yunyun Wang1,*(), Zhanqing Hao2
Received:
2022-02-08
Accepted:
2022-04-19
Online:
2022-07-20
Published:
2022-06-06
Contact:
Yunyun Wang
摘要:
性系统是被子植物繁育系统的核心, 决定着植物种群的遗传特征、进化方向与速度, 在种群动态、群落结构及生态系统的构建与维持中具有重要意义。本文回顾了被子植物性系统的发展历程及研究方向, 总结了近30年基于性系统研究的前沿科学问题, 包括性系统的多样性和进化、与其他功能性状的生态关联、沿环境梯度的分布格局及变化规律、与群落物种共存机制和群落动态的关系及其对干扰的响应。尽管有关植物性系统的研究已经延伸到生态学领域的诸多方面, 有力地推动了各方面的发展, 但仍有很多值得关注和需要着重研究的方向和问题。本文对未来基于植物性系统的研究方向等提出了展望, 并指出, 在当前全球气候变化背景下, 性系统可作为重要的功能性状应用于指导生物多样性保护和生态系统管理政策的制定。
王芸芸, 郝占庆 (2022) 被子植物性系统的多样性、生态功能及分布规律. 生物多样性, 30, 22065. DOI: 10.17520/biods.2022065.
Yunyun Wang, Zhanqing Hao (2022) Angiosperm sexual systems-Concepts, evolution, ecology, and future directions. Biodiversity Science, 30, 22065. DOI: 10.17520/biods.2022065.
图1 性系统状态及各状态之间的进化转变(改编自Goldberg et al, 2017), H指向雌雄异株D的更大箭头表征演化的主要趋势。
Fig. 1 Sexual system states and transitions between them. Transitions are often expected to be toward greater sexual differentiation (larger arrow).
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