植物n -丙二酰色氨酸形成对水分亏缺的依赖性

K. Z. Gamburg
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摘要

植物的干旱胁迫伴随着多种代谢变化。其中之一是在许多物种的叶片萎蔫过程中出现了n -丙二酰色氨酸(MT),但也有相当数量的植物物种没有出现MT。有些植物还能合成n -乙酰色氨酸(AT)。切除的番茄叶片与d -氨基酸(包括d -色氨酸)孵育后,即使在没有缺水的情况下,它们也会转化为丙二酰和乙酰基衍生物。然而,在水分亏缺期间出现的MT含有L-Trp。氨基酸-1-氨基-环丙烷-1-羧酸(ACC)在缺水条件下也发生丙二酰化,但其他l -氨基酸没有发生丙二酰化。在一些植物中发现了特异性的Trp和ACC的n -丙二醇转移酶。l -色氨酸特异性的n -丙二醇转移酶存在于植物形成MT的亏水过程中,但尚未得到明确的实验证明。植物可以将外源施用的MT转化为色氨酸,进而转化为吲哚-3-乙酸(IAA)。但到目前为止还没有证据表明内源性MT可能是IAA的来源。目前尚不清楚为什么许多物种的植物在缺水时只需要丙二酸盐。MT是如何在动物体内代谢的,以及它是否会影响它们,这也是未知的。强调了利用分子遗传学方法阐明水分亏缺期间MT形成的生理意义的必要性。
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The Dependence of N-Malonyltryptophan Formation in Plants on Water Deficit (Review)
Drought stress in plants is accompanied by several metabolic changes. One of them is the appearance of N-malonyltryptophan (MT) during leaf wilting of many species, but there is a significant number of plant species in which the appearance of MT did not occur. Plants of some species were able to synthesize also N-acetyltryptophan (AT). Excised tomato leaves incubated with D-amino acids (including D-Trp) transform them into malonyl- and acetyl-derivatives even without water deficit. However, MT which appeared during water deficit has been shown to contain L-Trp. Amino acid—1-amino-cyclopropane-1-carboxylic acid (ACC) is also malonylated during water deficit, but other L-amino acids were not malonylated. N-malonyl transferases specific for Trp and ACC have been found in several plants. The existence of N-malonyltransferase specific to L-Trp and appeared during water deficit in plants forming MT is supposed, but clear experimental proof has not been obtained yet. Plants can transform MT applied exogenously into Trp and further to indole-3-acetic acid (IAA). But no evidence has been appeared up to now that endogenous MT may be a source of IAA. It is unknown till now why it is necessary for plants of many species to malonylate only Trp during water deficit. How MT metabolized in animals and if it affects them is also unknown. The necessity to use molecular-genetic approaches for the elucidation of the physiological significance of MT formation during water deficit is underlined.
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