拟南芥的根和地上部分对缺氧胁迫具有不同的耐受机制。
Arabidopsis roots and shoots have different mechanisms for hypoxic stress tolerance.
作者信息
Ellis M H, Dennis E S, Peacock W J
机构信息
Commonwealth Scientific and Industrial Research Organization, Division of Plant Industry, G.P.O. Box 1600, Canberra ACT 2601, Australia.
出版信息
Plant Physiol. 1999 Jan;119(1):57-64. doi: 10.1104/pp.119.1.57.
Abstract
Arabidopsis has inducible responses for tolerance of O2 deficiency. Plants previously exposed to 5% O2 were more tolerant than the controls to hypoxic stress (0.1% O2 for 48 h) in both roots and shoots, but hypoxic acclimation did not improve tolerance to anoxia (0% O2). The acclimation of shoots was not dependent on the roots: increased shoot tolerance was observed when the roots of the plants were removed. An adh (alcohol dehydrogenase) null mutant did not show acclimation of the roots but retained the shoot survival response. Abscisic acid treatment also differentiated the root and shoot responses; pretreatment induced root survival in hypoxic stress conditions (0.1% O2) but did not induce any increase in the survival of shoots. Cycloheximide blocked both root and shoot acclimation, indicating that both acclimation mechanisms are dependent on protein synthesis.
摘要
拟南芥对缺氧具有诱导性耐受反应。之前暴露于5%氧气环境的植株,其根和地上部分对低氧胁迫(0.1%氧气,持续48小时)的耐受性均强于对照植株,但低氧驯化并未提高对无氧(0%氧气)的耐受性。地上部分的驯化不依赖于根:去除植株根部后,地上部分的耐受性仍会增加。一个乙醇脱氢酶(adh)缺失突变体未表现出根部的驯化,但保留了地上部分的存活反应。脱落酸处理也使根和地上部分的反应有所不同;预处理可诱导根在低氧胁迫条件(0.1%氧气)下存活,但未诱导地上部分存活率增加。放线菌酮阻断了根和地上部分的驯化,表明这两种驯化机制均依赖于蛋白质合成。
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