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月桂樱叶片中的木质部空穴化及其对叶片水力的影响。

Xylem cavitation in the leaf of Prunus laurocerasus and its impact on leaf hydraulics.

作者信息

Nardini A, Tyree M T, Salleo S

机构信息

Dipartimento di Biologia, Università degli Studi di Trieste, Via L. Giorgieri 10, 34127 Trieste, Italy.

出版信息

Plant Physiol. 2001 Apr;125(4):1700-9. doi: 10.1104/pp.125.4.1700.

DOI:10.1104/pp.125.4.1700
PMID:11299351
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC88827/
Abstract

This paper reports how water stress correlates with changes in hydraulic conductivity of stems, leaf midrib, and whole leaves of Prunus laurocerasus. Water stress caused cavitation-induced dysfunction in vessels of P. laurocerasus. Cavitation was detected acoustically by counts of ultrasonic acoustic emissions and by the loss of hydraulic conductivity measured by a vacuum chamber method. Stems and midribs were approximately equally vulnerable to cavitations. Although midribs suffered a 70% loss of hydraulic conductance at leaf water potentials of -1.5 MPa, there was less than a 10% loss of hydraulic conductance in whole leaves. Cutting and sealing the midrib 20 mm from the leaf base caused only a 30% loss of conduction of the whole leaf. A high-pressure flow meter was used to measure conductance of whole leaves and as the leaf was progressively cut back from tip to base. These data were fitted to a model of hydraulic conductance of leaves that explained the above results, i.e. redundancy in hydraulic pathways whereby water can flow around embolized regions in the leaf, makes whole leaves relatively insensitive to significant changes in conductance of the midrib. The onset of cavitation events in P. laurocerasus leaves correlated with the onset of stomatal closure as found recently in studies of other species in our laboratory.

摘要

本文报道了水分胁迫与月桂樱茎、叶中脉及全叶导水率变化之间的关系。水分胁迫导致月桂樱导管发生空化诱导的功能障碍。通过超声声发射计数和声测法检测空化现象,并用真空室法测量导水率的损失。茎和中脉对空化的敏感度大致相同。尽管在叶片水势为-1.5 MPa时,中脉的导水率损失了70%,但全叶的导水率损失不到10%。从叶基部20毫米处切断并密封中脉,全叶的导水率仅损失30%。使用高压流量计测量全叶的导水率,并随着叶片从叶尖向基部逐渐切割。这些数据拟合到一个叶片导水率模型中,该模型解释了上述结果,即水分传导途径的冗余使得水分能够绕过叶片中栓塞区域流动,从而使全叶对中脉导水率的显著变化相对不敏感。月桂樱叶片中空化事件的发生与气孔关闭的开始相关,这与我们实验室最近对其他物种的研究结果一致。

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