花粉二型性研究进展

doi:10.17520/biods.2025031

摘要/Abstract

摘要： 花粉二型性(pollen dimorphism), 即同一物种内存在两种不同类型的花粉, 是一种花粉形态变异现象。本文基于形态和生理两个维度, 将花粉二型性分为花粉大小二型性、花粉形态二型性、花粉颜色二型性和花粉活性二型性等4种类型。少数物种存在两种或两种以上的花粉二型性类型。在现有文献基础上, 我们对51科116属被子植物中已确认存在花粉二型性的类群构建了系统发育树。结果表明花粉二型性往往出现在具有特殊繁育系统的植物中, 如异型雄蕊、隐雌雄异株、镜像花等, 这可能与特化的传粉机制和交配系统有关。目前, 花粉二型性遗传基础、发育机制、生态适应与进化等方面的研究仍显不足, 因此, 采用多手段、多途径对其进行深入研究十分必要。花粉二型性的研究不仅有助于揭示花粉形态的进化, 还能为理解植物多样性形成机制以及植物与传粉者的协同进化提供新视角。

关键词: 花粉二型性, 繁育系统, 花粉形态变异, 繁殖特征, 适应性进化

Abstract

Background & Aims: Pollen grains in natural plant populations exhibit remarkable diversity in morphological features including size, shape, surface ornamentation, aperture number, and coloration. Despite this interspecific variability, pollen morphology typically remains relatively conserved within a single species, a characteristic of significant value for both taxonomic classification and studies of reproductive success. Intriguingly, pollen dimorphism—the production of two or more distinct pollen types within an individual plant—has been documented in certain taxa, challenging the traditional assumption of pollen uniformity. While preliminary investigations have explored the phylogenetic implications and adaptive advantages of this phenomenon, systematic syntheses addressing its evolutionary drivers and ecological functions remain limited. A comprehensive analysis of pollen dimorphism is thus critical to unraveling its role in shaping floral diversity, optimizing pollination efficiency, and mediating coevolutionary dynamics between angiosperms and their pollinators.

Progress: This study proposes a comprehensive classification system for pollen dimorphism, categorizing the phenomenon into four distinct types based on morphological and physiological characteristics: size dimorphism, shape dimorphism, color dimorphism, and vitality dimorphism. Notably, certain plant species demonstrate concurrent expression of two or more dimorphic pollen types. Through extensive literature analysis, we have reconstructed a phylogenetic framework encompassing 116 genera across 51 angiosperm families that exhibit pollen dimorphism. The evolutionary emergence of this trait shows significant correlation with specialized breeding system, including but not limited to heteranthery, cryptic dioecy, and enantiostyly (mirror-image flowers). These floral adaptations, frequently associated with pollen dimorphism, appear to have co-evolved with specific pollination syndromes and mating system optimizations, suggesting an adaptive mechanism for reproductive assurance and resource allocation efficiency in flowering plants.

Prospects: Current research on pollen dimorphism remains in its nascent stages, with critical knowledge gaps persisting in understanding its genetic architecture, ontogenetic regulation, ecological significance, and evolutionary trajectories. Addressing these fundamental questions requires multidisciplinary approaches integrating molecular genetics, developmental biology, and ecological genomics. This line of investigation holds significant implications for elucidating the evolutionary innovation of pollen morphology, identifying the evolutionary drivers of floral diversification, and deciphering the intricate plant-pollinator coevolutionary dynamics. Systematic exploration of pollen dimorphism may ultimately provide novel insights into the evolutionary optimization of plant reproductive strategies under selective pressures.

Key words: pollen dimorphism, breeding system, pollen morphological variation, reproductive characteristics, adaptive evolution

孙婷婷, 张彦文 (2025) 花粉二型性研究进展. 生物多样性, 33, 25031. DOI: 10.17520/biods.2025031.

Tingting Sun, Yanwen Zhang (2025) Research progress on pollen dimorphism. Biodiversity Science, 33, 25031. DOI: 10.17520/biods.2025031.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2025031

https://www.biodiversity-science.net/CN/Y2025/V33/I7/25031

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