植物脱水与蛋白质合成:利用内源和合成信使核糖核酸,建立来自干燥和水合苔藓的体外系统
Plant desiccation and protein synthesis: an in vitro system from dry and hydrated mosses using endogenous and synthetic messenger ribonucleic Acid.
作者信息
Gwóźdź E A, Bewley J D
机构信息
Department of Biology, University of Calgary, Calgary, Alberta, T2N 1N4, Canada.
出版信息
Plant Physiol. 1975 Feb;55(2):340-5. doi: 10.1104/pp.55.2.340.
Abstract
The conditions and requirements for an in vitro protein synthesizing system from the moss Tortula ruralis are outlined. Using this system the effects of desiccation, achieved quickly or slowly, were studied. Slowly dried moss retained fewer polyribosomes on desiccation but more active ribosomes than rapidly dried moss. Even in the completely desiccated moss the polyribosomes and/or free ribosomes present have retained their synthetic capacities. On rehydration, the slowly dried moss resumed protein synthesis more quickly than moss previously desiccated rapidly. Moss ribosomes are cycloheximide sensitive and chloramphenicol insensitive and thus the major protein synthesis occurs within the cytoplasm on rehydration. Extracted polyribosomes per se can withstand desiccation to a significant extent, suggesting that protection by the cytoplasm might not be necessary. The aquatic moss Hygrohypnum luridum can retain polyribosomal and ribosomal activity during desiccation, but this decreases greatly on rehydration.
摘要
概述了来自真藓的体外蛋白质合成系统的条件和要求。利用该系统研究了快速或缓慢干燥所产生的干燥效应。缓慢干燥的苔藓在干燥时保留的多核糖体较少,但比快速干燥的苔藓保留更多活性核糖体。即使在完全干燥的苔藓中,存在的多核糖体和/或游离核糖体也保留了它们的合成能力。复水后,缓慢干燥的苔藓比先前快速干燥的苔藓更快恢复蛋白质合成。苔藓核糖体对放线菌酮敏感,对氯霉素不敏感,因此复水时主要的蛋白质合成发生在细胞质内。提取的多核糖体本身在很大程度上可以耐受干燥,这表明细胞质的保护可能不是必需的。水生苔藓水灰藓在干燥过程中可以保留多核糖体和核糖体活性,但复水时这种活性会大大降低。
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Plant desiccation and protein synthesis: an in vitro system from dry and hydrated mosses using endogenous and synthetic messenger ribonucleic Acid.植物脱水与蛋白质合成:利用内源和合成信使核糖核酸,建立来自干燥和水合苔藓的体外系统
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Plant Desiccation and Protein Synthesis: II. On the Relationship between Endogenous Adenosine Triphosphate Levels and Protein-synthesizing Capacity.植物脱水与蛋白质合成:II. 关于内源性三磷酸腺苷水平与蛋白质合成能力之间的关系
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Desiccation-tolerant flowering plants in southern Africa.南非耐旱开花植物。
Science. 1971 Dec 3;174(4013):1033-4. doi: 10.1126/science.174.4013.1033.
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Polyribosome formation and protein synthesis in imbibed but dormant lettuce seeds.吸胀但休眠的生菜种子中的多核糖体形成与蛋白质合成
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Polyribosomes Conserved during Desiccation of the Moss Tortula ruralis Are Active.干旱胁迫下苔藓拟南芥多聚核糖体保持稳定并具有活性。
Plant Physiol. 1973 Feb;51(2):285-8. doi: 10.1104/pp.51.2.285.
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"Free" and membrane-bound ribosomes, and nature of products formed by isolated tobacco chloroplasts incubated for protein synthesis.“游离”核糖体和膜结合核糖体,以及分离的烟草叶绿体用于蛋白质合成培养时所形成产物的性质。
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The site of protein synthesis in the moss Tortula ruralis on recovery from desiccation.脱水复苏后,藓类植物粗糙真藓中蛋白质合成的位点。
Can J Biochem. 1974 Apr;52(4):345-8. doi: 10.1139/o74-052.
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