Institute of Agricultural and Environmental Sciences, Estonian University of Life Sciences, Kreutzwaldi 1, Tartu, 51014, Estonia.
Estonian Academy of Sciences, Kohtu 6, Tallinn, 10130, Estonia.
New Phytol. 2020 Jan;225(1):183-195. doi: 10.1111/nph.16159. Epub 2019 Oct 17.
Fast stomatal reactions enable plants to successfully cope with a constantly changing environment yet there is an ongoing debate on the stomatal regulation mechanisms in basal plant groups. We measured stomatal morphological parameters in 29 fern and allied species from temperate to tropical biomes and two outgroup angiosperm species. Stomatal dynamic responses to environmental drivers were measured in 16 ferns and the two angiosperms using a gas-exchange system. Principal components analyses were used to further reveal the structure-function relationships in stomata. We show a > 10-fold variation for stomatal opening delays and 20-fold variation for stomatal closing delays in ferns. Across species, stomatal responses to vapor pressure deficit (VPD) were the fastest, while light and [CO ] responses were slower. In most cases the outgroup species' reaction speeds to changes in environmental variables were similar to those of ferns. Correlations between stomatal response rate and size were apparent for stomatal opening in light and low [CO ] while not evident for closing reactions and changes in VPD. No correlations between stomatal density and response speed were observed. Together, this study demonstrates different mechanisms controlling stomatal reactions in ferns at different environmental stimuli, which should be considered in future studies relating stomatal morphology and function.
快速的气孔反应使植物能够成功应对不断变化的环境,但关于基础植物群的气孔调节机制仍存在争议。我们测量了来自温带到热带生物群落的 29 种蕨类植物和相关物种以及两个外群被子植物物种的气孔形态参数。我们使用气体交换系统测量了 16 种蕨类植物和两种被子植物对环境驱动因素的气孔动态响应。主成分分析进一步揭示了气孔的结构-功能关系。我们表明,蕨类植物的气孔张开延迟变化超过 10 倍,气孔关闭延迟变化超过 20 倍。在物种间,气孔对水汽压亏缺(VPD)的响应最快,而对光和[CO ]的响应较慢。在大多数情况下,外群物种对环境变量变化的反应速度与蕨类植物相似。在光和低[CO ]下,气孔开放的反应速度与大小之间存在明显的相关性,而在关闭反应和 VPD 变化中则不明显。未观察到气孔密度与响应速度之间存在相关性。综上所述,本研究表明,不同环境刺激下,蕨类植物控制气孔反应的机制不同,这在未来与气孔形态和功能相关的研究中应加以考虑。
