一种测量植物节段水力传导性的新实验装置。

IF 2.6 3区 生物学 Q2 ECOLOGY
AoB Plants Pub Date : 2023-07-01 DOI:10.1093/aobpla/plad024
Louis Krieger, Stanislaus J Schymanski
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引用次数: 0

摘要

植物的水力传导性及其在水分胁迫下的下降是当前植物水力研究的热点。测量水力导电性的常用方法是控制压力梯度,使水通过植物样品,使它们处于与自然界中所经历的条件相去甚远的条件下,在自然界中,水流是由叶片的吸力驱动和水分需求决定的。在本文中,我们提出了两种更接近自然条件下测量水力传导率的方法,一种是人工装置,另一种是水平注射泵装置。这两种方法都使用吸力将水通过植物样本,同时动态监测流量和压力梯度。这里介绍的注射器设置允许控制和快速变化的流量和压力条件,使实验评估植物对水分胁迫的快速水力反应。该装置还允许定量的动态变化,在水储存的植物样品。我们的测试表明,注射泵装置可以再现使用当前标准方法在高于大气压力下推水所测得的水力电导率值。令人惊讶的是,使用传统和我们的新注射泵设置,我们发现流量变化与水力导电性之间呈正相关。此外,当流量或压力条件迅速变化时,我们发现植物样品中水分储存的动态和很大程度上可逆的变化对流量有实质性的贡献。虽然测量可以在亚大气压力下进行,但由于阀门和压力传感器附近存在气泡,因此不可能将样品置于负压下。无论如何,该装置可以前所未有地深入了解工厂各个部门的压力、流量、水力传导性和储水量之间的相互作用。这项工作是使用开放科学方法进行的,原始数据和分析可以在https://doi.org/10.5281/zenodo.7322605上找到。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A new experimental setup to measure hydraulic conductivity of plant segments.

A new experimental setup to measure hydraulic conductivity of plant segments.

A new experimental setup to measure hydraulic conductivity of plant segments.

A new experimental setup to measure hydraulic conductivity of plant segments.

Plant hydraulic conductivity and its decline under water stress are the focal point of current plant hydraulic research. The common methods of measuring hydraulic conductivity control a pressure gradient to push water through plant samples, submitting them to conditions far away from those that are experienced in nature where flow is suction driven and determined by the leaf water demand. In this paper, we present two methods for measuring hydraulic conductivity under closer to natural conditions, an artificial plant setup and a horizontal syringe pump setup. Both approaches use suction to pull water through a plant sample while dynamically monitoring the flow rate and pressure gradients. The syringe setup presented here allows for controlling and rapidly changing flow and pressure conditions, enabling experimental assessment of rapid plant hydraulic responses to water stress. The setup also allows quantification of dynamic changes in water storage of plant samples. Our tests demonstrate that the syringe pump setup can reproduce hydraulic conductivity values measured using the current standard method based on pushing water under above-atmospheric pressure. Surprisingly, using both the traditional and our new syringe pump setup, we found a positive correlation between changes in flow rate and hydraulic conductivity. Moreover, when flow or pressure conditions were changed rapidly, we found substantial contributions to flow by dynamic and largely reversible changes in the water storage of plant samples. Although the measurements can be performed under sub-atmospheric pressures, it is not possible to subject the samples to negative pressures due to the presence of gas bubbles near the valves and pressure sensors. Regardless, this setup allows for unprecedented insights into the interplay between pressure, flow rate, hydraulic conductivity and water storage in plant segments. This work was performed using an Open Science approach with the original data and analysis to be found at https://doi.org/10.5281/zenodo.7322605.

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来源期刊
AoB Plants
AoB Plants PLANT SCIENCES-
CiteScore
4.80
自引率
0.00%
发文量
54
审稿时长
20 weeks
期刊介绍: AoB PLANTS is an open-access, online journal that has been publishing peer-reviewed articles since 2010, with an emphasis on all aspects of environmental and evolutionary plant biology. Published by Oxford University Press, this journal is dedicated to rapid publication of research articles, reviews, commentaries and short communications. The taxonomic scope of the journal spans the full gamut of vascular and non-vascular plants, as well as other taxa that impact these organisms. AoB PLANTS provides a fast-track pathway for publishing high-quality research in an open-access environment, where papers are available online to anyone, anywhere free of charge.
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