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花生光合作用的温度依赖性反馈抑制。

Temperature-dependent feedback inhibition of photosynthesis in peanut.

机构信息

Division of Plant Industry, CSIRO, G.P.O. Box 1600, 2601, Canberra, A.C.T., Australia.

出版信息

Planta. 1988 Sep;175(3):348-54. doi: 10.1007/BF00396340.

DOI:10.1007/BF00396340
PMID:24221872
Abstract

Arachis hypogaea L. is a tropical crop that is slow-growing at temperatures below 25°C. Unadapted CO2-assimilation rate (A) showed insufficient variation between 15 and 30°C in the short term (hours) to explain this marked reduction in growth. However, at longer periods (12 d), A was depressed as were growth rate and leafproduction rate. To examine the possible relationship between growth, A and sink demand plants were transferred from 30°C, which is near the optimum for growth, to a suboptimal temperature (19°C). In the first 2 d of cooling, A decreased by 50-70%, the stomata stayed open, and the intercellular CO2 concentration (ci) rose, i.e. the decrease in A of the cooled plants was the result of non-stomatal factors. Changes in dark respiration did not account for the decline in A.Clear evidence was obtained of sink control of A by independently manipulating the temperature of different leaves on the plant. Cooling (to 19°C) most of the plant (the sink) led to a 70% decline in A of the remaining leaves at 30°C after 3 d, whereas the converse treatments (30°C sink, 19°C source) resulted in small changes (17%). In plants at 19°C which were exposed to low CO2 concentration to prevent photosynthesis, A was not reduced when measured at normal CO2 concentrations, indicating that carbohydrate accumulation was responsible for the decline in A. Dry-matter build-up at suboptimal temperature was also consistent with end-product inhibition of photosynthesis.

摘要

落花生是一种热带作物,在 25°C 以下生长缓慢。在短期(数小时)内,未经驯化的 CO2 同化率(A)在 15°C 至 30°C 之间变化不大,无法解释这种生长明显下降的原因。然而,在较长时间(12 天)内,A 和生长率、叶片产生率都降低了。为了研究生长、A 和库需求之间的可能关系,将植物从接近生长最适温度(30°C)转移到次适温度(19°C)。在冷却的最初 2 天,A 下降了 50-70%,气孔仍然张开,胞间 CO2 浓度(ci)上升,即冷却植物的 A 下降是由非气孔因素造成的。暗呼吸的变化不能解释 A 的下降。通过独立操纵植物上不同叶片的温度,对 A 进行库控制的证据非常明显。冷却(至 19°C)大部分植物(库)导致 3 天后在 30°C 下剩余叶片的 A 下降了 70%,而相反的处理(30°C 库,19°C 源)导致的变化很小(17%)。在 19°C 下的植物暴露在低 CO2 浓度下以防止光合作用,当在正常 CO2 浓度下测量时,A 没有降低,表明碳水化合物积累是 A 下降的原因。在次适温度下干物质的积累也与光合作用的终产物抑制一致。

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