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乙醇产生介导的低温驯化对于提高水稻根系的抗冷性至关重要。

Low temperature acclimation mediated by ethanol production is essential for chilling tolerance in rice roots.

机构信息

Department of Applied Biological Science; Faculty of Agriculture; Kagawa University; Miki, Kagawa, Japan.

出版信息

Plant Signal Behav. 2008 Mar;3(3):202-3. doi: 10.4161/psb.3.3.5542.

DOI:10.4161/psb.3.3.5542
PMID:19704659
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2634117/
Abstract

Rice seedlings (Oryza sativa L.) were subjected to low temperature pretreatment (LT-PT; 10 degrees C) for various length of time followed by a 48-h chilling temperature stress (2 degrees C). Chilling tolerance of rice roots was improved with increasing duration of LT-PT, but HT-PT longer than 12 h gave no additional improvement. LT-PT did not change in fatty acid composition in rice roots under the present experimental condition. Alcohol dehydrogenase (ADH) activity and ethanol concentration in the roots were increased with increasing duration of LT-PT up to 12 h, which indicates that LT-PT increased ethanol fermentation in the roots. 4-Methylpyrazole, a potent inhibitor of ADH, reduced the ethanol concentration and the chilling tolerance in the roots. This reduction of the chilling tolerance recovered with exogenously applied ethanol. Ethanol also induced 21- and 33-kD protein synthesis in the roots and these proteins may contribute the improvement of the tolerance. The present research suggests that LT-PT may increase chilling tolerance in rice roots owing to ethanol production, and ethanol may trigger a signal transduction cascade, which might lead to a decrease in membrane damage and injury.

摘要

将水稻幼苗(Oryza sativa L.)进行不同时间的低温预处理(LT-PT;10°C),然后进行 48 小时的冷胁迫处理(2°C)。随着 LT-PT 时间的延长,水稻根系的抗冷性得到提高,但 HT-PT 超过 12 小时则没有进一步提高。在目前的实验条件下,LT-PT 不会改变水稻根系中的脂肪酸组成。ADH 活性和乙醇浓度在根系中随 LT-PT 时间的延长而增加,这表明 LT-PT 增加了根系中的乙醇发酵。ADH 的强效抑制剂 4-甲基吡唑降低了根中的乙醇浓度和抗冷性。这种抗冷性的降低可以通过外源乙醇的应用得到恢复。乙醇还诱导了根系中 21kD 和 33kD 蛋白质的合成,这些蛋白质可能有助于提高耐冷性。本研究表明,由于乙醇的产生,LT-PT 可能会增加水稻根系的抗冷性,而乙醇可能会触发信号转导级联反应,从而减少膜损伤和伤害。

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