Decrease in plant hydraulic conductance due to soil waterlogging suppresses the transpiration rate of Glycine max even during post-waterlogging reoxygenation

IF 3.9 2区 农林科学 Q1 AGRONOMY
Shigehiro Kubota, Kazuhiro Nishida, Shuichiro Yoshida
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Abstract

Background and aims

In humid regions, the transpiration rate is determined by transpiration demand because of the sufficiently moist soil. However, inhibition of plant water uptake capacity due to soil waterlogging can significantly constrain the transpiration rate even after drainage. This study aimed to evaluate plant hydraulic conductance during soil waterlogging and subsequent reoxygenation and its impact on whole plant transpiration.

Methods

Two experiments were conducted to assess the ecophysiological responses of soybeans during waterlogging (Experiment 1) and reoxygenation (Experiment 2). Transpiration rate, stomatal conductance, leaf water potential, and leaf area were measured. In addition, plant hydraulic conductance was calculated using the root water uptake equation. A simple transpiration model incorporating the response of plant hydraulic conductance to waterlogging was used to evaluate the impact of waterlogging on transpiration estimation.

Results

Waterlogging for more than 3 days reduced plant hydraulic conductance, which persisted even during the post-waterlogging reoxygenation period. Furthermore, leaf water potential, stomatal conductance, and transpiration rate in waterlogging treatment exhibited a lower value than those in control during both waterlogging and reoxygenation. The constructed model effectively reproduced the responses of plant hydraulic conductance and transpiration rate, especially during reoxygenation.

Conclusion

Soil waterlogging significantly reduce the hydraulic conductance of soybean plants, resulting in leaf water stress and depression of transpiration, even during reoxygenation. Our results highlight the importance of integrating plant hydraulic responses with water dynamics models in the soil-plant-atmosphere system.

Abstract Image

土壤涝害导致植物水力传导下降,即使在涝害后的复氧过程中也会抑制最大甘蓝的蒸腾速率
背景和目的在湿润地区,由于土壤足够湿润,蒸腾速率由蒸腾需求决定。然而,土壤渍水会抑制植物的吸水能力,即使在排水后也会严重制约蒸腾速率。本研究旨在评估土壤涝害和随后复氧过程中的植物水力传导及其对整个植物蒸腾作用的影响。方法进行了两次实验,评估大豆在涝害(实验 1)和复氧(实验 2)过程中的生态生理反应。测量了蒸腾速率、气孔导度、叶片水势和叶面积。此外,还利用根部吸水方程计算了植物的水力传导。使用一个包含植物水力传导对水涝反应的简单蒸腾模型来评估水涝对蒸腾估算的影响。此外,在涝害和复氧期间,涝害处理的叶片水势、气孔导度和蒸腾速率均低于对照组。所构建的模型有效地再现了植物水力传导和蒸腾速率的响应,尤其是在复氧期间。我们的研究结果凸显了将植物水力反应与土壤-植物-大气系统中的水动力学模型相结合的重要性。
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来源期刊
Plant and Soil
Plant and Soil 农林科学-农艺学
CiteScore
8.20
自引率
8.20%
发文量
543
审稿时长
2.5 months
期刊介绍: Plant and Soil publishes original papers and review articles exploring the interface of plant biology and soil sciences, and that enhance our mechanistic understanding of plant-soil interactions. We focus on the interface of plant biology and soil sciences, and seek those manuscripts with a strong mechanistic component which develop and test hypotheses aimed at understanding underlying mechanisms of plant-soil interactions. Manuscripts can include both fundamental and applied aspects of mineral nutrition, plant water relations, symbiotic and pathogenic plant-microbe interactions, root anatomy and morphology, soil biology, ecology, agrochemistry and agrophysics, as long as they are hypothesis-driven and enhance our mechanistic understanding. Articles including a major molecular or modelling component also fall within the scope of the journal. All contributions appear in the English language, with consistent spelling, using either American or British English.
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