生长温度对滨藜光合作用器官热稳定性的影响。
Effects of Growth Temperature on the Thermal Stability of the Photosynthetic Apparatus of Atriplex lentiformis (Torr.) Wats.
机构信息
Department of Biological Sciences, State University of New York at Albany, Albany, New York 12222.
出版信息
Plant Physiol. 1977 May;59(5):873-8. doi: 10.1104/pp.59.5.873.
Abstract
High growth temperatures induced a substantial increase in the thermal stability of the photosynthetic apparatus of Atriplex lentiformis. This was manifested as a much reduced inhibition of light-saturated photosynthesis and the initial slope of the light-dependence curves by exposure to high temperatures in high as compared to moderate temperature-grown plants. Heat treatment at 46 C of leaves from moderate temperature-grown plants resulted in a marked reduction in photosystem II activities of chloroplasts isolated from them. In contrast, heat treatment of leaves from high temperature-grown plants resulted in no reduction of photosystem II activities. In vivo estimates of photosystem II functioning, the 515 nm light-induced absorbance change, and the ratio initial to maximum fluorescence (F(0)/F(max)) indicated a similar increase in the thermal stability of photosystem II in high temperature-grown plants.
摘要
高温显著提高了滨藜光合作用装置的热稳定性。具体表现在,与中温生长植株相比,高温生长植株的光合作用在高温下受到的抑制较小,光依赖曲线的初始斜率也较小。将中温生长植株的叶片在 46°C 下热处理,会导致从叶片中分离出的叶绿体的光合系统 II 活性显著降低。相比之下,对高温生长植株的叶片进行热处理不会降低光合系统 II 的活性。体内估计光合系统 II 功能的 515nm 光诱导吸收变化和初始荧光与最大荧光的比值(F(0)/F(max))表明,高温生长植株的光合系统 II 的热稳定性也有类似的提高。
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