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低温对甜菜蔗糖运转抑制作用的时间进程。

Time course of low temperature inhibition of sucrose translocation in sugar beets.

机构信息

Department of Botany and Plant Pathology, Ohio State University, Columbus, Ohio 43210.

出版信息

Plant Physiol. 1967 Jun;42(6):751-6. doi: 10.1104/pp.42.6.751.

DOI:10.1104/pp.42.6.751

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1086616/

Abstract

Further studies are presented characterizing the time-course response of sucrose translocation in sugar beet (Beta vulgaris L. cv Klein Wanzleben) to low temperature inhibition. Only the temperature of a 2 cm zone of the source-leaf petiole was varied (1 degrees vs 25 degrees , approximately). The half-time of inhibition, defined as the time required for 50% inhibition of the control or pre-cooling rate, varied from 4 to 15 minutes, and the half-time of recovery from 30 to 100 minutes. Maximum inhibition varied from 68 to 92%. Possible uncertainties in evaluating these parameters are discussed. When the duration of the low temperature period was sufficient to permit essentially full recovery, subsequent re-warming of the petiole zone to 25 degrees to 30 degrees effected little or no increase in the translocation rate. It is evident that the interposition between source and sink of a 2 cm petiole zone maintained at a temperature generally inhibitory to physiological processes resulted in little or no impairment to the translocation process, after a suitable thermal adaptation period. Thermally adapted petiole systems de-adapted after periods as short as 1 hour at 25 degrees .

摘要

进一步的研究描述了低温抑制对糖甜菜（Beta vulgaris L. cv Klein Wanzleben）蔗糖转运的时间过程响应。仅改变了源叶叶柄 2 厘米区域的温度（1 度对 25 度，大约）。抑制的半衰期，定义为抑制 50%的对照或预冷速率所需的时间，从 4 分钟到 15 分钟不等，从 30 分钟到 100 分钟不等。最大抑制率从 68%到 92%不等。讨论了评估这些参数的可能不确定性。当低温期的持续时间足以允许基本完全恢复时，随后将叶柄区域再升温至 25 度至 30 度对转运率几乎没有或没有影响。显然，在源和汇之间插入一段通常对生理过程具有抑制作用的 2 厘米叶柄区域，在适当的热适应期后，对转运过程几乎没有或没有损害。经过 1 小时 25 度的短暂适应期后，热适应的叶柄系统就会失去适应能力。