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代谢相关氨基酸对多细胞植物生长的协同效应。II. 14C-氨基酸掺入的研究。

Synergistic effects of metabolically related amino acids on the growth of a multicellular plant. II. Studies of 14C-amino acid incorporation.

作者信息

Dunham V L, Bryan J K

出版信息

Plant Physiol. 1971 Jan;47(1):91-7. doi: 10.1104/pp.47.1.91.

DOI:10.1104/pp.47.1.91

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC365818/

Abstract

The synergistic inhibition of the growth of Marchantia polymorpha gemmalings by lysine and threonine and its prevention by methionine has been investigated utilizing (14)C-labeled amino acids. Experiments involving the uptake of (14)C-lysine or (14)C-threonine in the presence or absence of methionine indicated that the synergistic growth effects were not a result of altered amino acid uptake. These data, as well as direct chemical analysis, indicated that growth inhibition was correlated with an inhibition of protein synthesis. Experiments utilizing (14)C-aspartic acid revealed that the presence of lysine and threonine resulted in increased (14)CO(2) production and an accumulation of soluble (14)C-aspartic acid and labeled ninhydrin-positive compounds. These metabolic alterations were prevented when methionine was also included in the growth media. A model depicting a sequence of events which involve the interaction of regulatory mechanisms is suggested to account for the effects of specific amino acids on plant growth.

摘要

利用¹⁴C标记的氨基酸，研究了赖氨酸和苏氨酸对多形苔鲜芽体生长的协同抑制作用以及蛋氨酸对其的预防作用。涉及在有无蛋氨酸存在的情况下摄取¹⁴C-赖氨酸或¹⁴C-苏氨酸的实验表明，协同生长效应并非氨基酸摄取改变的结果。这些数据以及直接化学分析表明，生长抑制与蛋白质合成的抑制相关。利用¹⁴C-天冬氨酸进行的实验表明，赖氨酸和苏氨酸的存在导致¹⁴CO₂产生增加以及可溶性¹⁴C-天冬氨酸和茚三酮阳性标记化合物的积累。当生长培养基中也包含蛋氨酸时，这些代谢变化得以预防。提出了一个描述涉及调节机制相互作用的一系列事件的模型，以解释特定氨基酸对植物生长的影响。