环境条件对水工实验室淡水大型植物健康状况和生物力学的影响

IF 4.6 Q2 ENVIRONMENTAL SCIENCES
D. Vettori, S. Rice
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引用次数: 5

摘要

淹没淡水大型植物经常用于水工实验室研究流-植物相互作用和植物在水生生态系统中的作用,但水槽设施的环境条件往往不适合植物,并可能导致植物应激。植物在逆境下的生理反应会引发植物生物力学的改变,从而影响植物与水的相互作用,影响实验结果。在极端情况下,不能指望死去的植物揭示活的植物如何与流动的水相互作用,但没有明显不健康的受胁迫植物也可能影响实验结果。本研究旨在评估典型水槽设施的环境条件是否以及如何影响植物健康状况并诱导植物生物力学的变化。利用叶绿素荧光分析(一种评估植物健康的标准方法),我们发现淡水大型植物在通常在水力实验室中发现的条件下会受到显著的胁迫。尽管所调查的非生物因素以不同的方式影响不同的物种,但暴露于自来水和低辐照度是淡水大型植物最紧张的条件。在植物与植物的物理相互作用中起主要作用的生物力学特性(如弯曲刚度)由于暴露于压力条件而发生了显著变化。一般来说,植物胁迫与植物茎顶弯曲刚度的降低有关,当考虑到叶片和叶柄时,这表明对植物流体动力学的潜在影响。光系统II的最大量子产率与植物茎秆抗弯刚度呈正相关,可作为植物健康状况的指标。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Implications of environmental conditions for health status and biomechanics of freshwater macrophytes in hydraulic laboratories
Abstract Submerged freshwater macrophytes are frequently used in hydraulic laboratories to study flow–plant interactions and the role of plants in aquatic ecosystems, but environmental conditions in flume facilities are often suboptimal for plants and can cause plant stress. Physiological responses of plants under stress can trigger modifications in plant biomechanics, which may affect plant–flow interactions and compromise experimental results. In the extreme, dead plants cannot be expected to reveal how live plants interact with flowing water, but stressed plants that are not visibly unhealthy may also affect experimental results. The present work aims to assess if and how environmental conditions typical of flume facilities can impact plant health status and induce variations in plant biomechanics. Using chlorophyll fluorescence analysis, a standard method for assessing plant health, we found that freshwater macrophytes can be significantly stressed under conditions typically found in hydraulic laboratories. Even though the abiotic factors investigated affected different species in different ways, exposure to tap water and low irradiance were the most stressful conditions for freshwater macrophytes. Biomechanical properties with a primary role in flow–plant physical interactions (e.g. flexural rigidity) changed significantly as a result of exposure to stressful conditions. In general, plant stress was associated with a reduction in flexural rigidity at the top of plant stems, suggesting a potential effect on plant hydrodynamics when leaves and petioles are considered. The maximum quantum yield of photosystem II, used as proxy of plant health status, was positively correlated with flexural rigidity of plant stems.
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CiteScore
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