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蒸腾作用引起叶片光合能力的变化。

Transpiration-induced changes in the photosynthetic capacity of leaves.

机构信息

Biological Sciences Center, Desert Research Institute, University of Nevada System, P.O.B. 60220, 89506, Reno, NV, USA.

出版信息

Planta. 1984 Feb;160(2):143-50. doi: 10.1007/BF00392862.

DOI:10.1007/BF00392862
PMID:24258416
Abstract

High transpiration rates were found to affect the photosynthetic capacity of Xanthium strumarium L. leaves in a manner analagous to that of low soil water potential. The effect was also looked for and found in Gossypium hirsutum L., Agathis robusta (C. Moore ex Muell.) Bailey, Eucalyptus microcarpa Maiden, Larrea divaricata Cav., the wilty flacca tomato mutant (Lycopersicon esculentum (L.) Mill.) and Scrophularia desertorum (Munz) Shaw. Two methods were used to distinguish between effects on stomatal conductance, which can lower assimilation by reducing CO2 availability, and effects on the photosynthetic capacity of the mesophyll. First, the response of assimilation to intercellular CO2 pressure (C i) was compared under conditions of high and low transpiration. Second, in addition to estimating C i using the usual Ohm's law analogy, C i was measured directly using the closed-loop technique of T.D. Sharkey, K. Imai, G.D. Farquhar and I.R. Cowan (1982, Plant Physiol, 60, 657-659). Transpiration stress responses of Xanthium strumarium were compared with soil drought effects. Both stresses reduced photosynthesis at high C i but not at low C i; transpiration stress increased the quantum requirement of photosynthesis. Transpiration stress could be induced in small sections of leaves. Total transpiration from the plant did not influence the photosynthetic capacity of a leaf kept under constant conditions, indicating that water deficits develop over small areas within the leaf. The effect of high transpiration on photosynthesis was reversed approximately half-way by returning the plants to low-transpiration conditions. This reversal occurred as fast as measurements could be made (5 min), but little further recovery was observed in subsequent hours.

摘要

高蒸腾率被发现以类似于低土壤水势的方式影响苍耳叶片的光合能力。这种影响也在棉花(Gossypium hirsutum L.)、南洋杉(Agathis robusta (C. Moore ex Muell.) Bailey)、细叶桉(Eucalyptus microcarpa Maiden)、龙舌兰(Larrea divaricata Cav.)、萎蔫 flacca 番茄突变体(Lycopersicon esculentum (L.) Mill.)和沙漠玄参(Scrophularia desertorum (Munz) Shaw)中进行了研究和发现。使用两种方法来区分对气孔导度的影响,气孔导度可以通过降低 CO2 可用性来降低同化作用,以及对叶肉光合能力的影响。首先,比较了在高蒸腾和低蒸腾条件下同化作用对细胞间 CO2 压力(C i)的响应。其次,除了使用通常的欧姆定律类比来估计 C i 之外,还使用 T.D. Sharkey、K. Imai、G.D. Farquhar 和 I.R. Cowan(1982,植物生理学,60,657-659)的闭环技术直接测量 C i。与土壤干旱效应相比,苍耳的蒸腾胁迫反应。两种胁迫都在高 C i 下降低了光合作用,但在低 C i 下没有;蒸腾胁迫增加了光合作用的量子需求。可以在叶片的小部分诱导蒸腾胁迫。在保持恒定条件下的叶片中,植物的总蒸腾作用不会影响叶片的光合能力,这表明水亏缺在叶片内的小区域内发展。将植物恢复到低蒸腾条件约一半时,高蒸腾对光合作用的影响就会逆转。这种逆转与测量一样快(5 分钟),但在随后的几个小时内观察到的恢复很少。

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