大肠杆菌中的核糖体生物合成与翻译过程。
Ribosome biogenesis and the translation process in Escherichia coli.
作者信息
Kaczanowska Magdalena, Rydén-Aulin Monica
机构信息
Department of Genetics, Microbiology, and Toxicology, Stockholm University, S-10691 Stockholm, Sweden.
出版信息
Microbiol Mol Biol Rev. 2007 Sep;71(3):477-94. doi: 10.1128/MMBR.00013-07.
Abstract
Translation, the decoding of mRNA into protein, is the third and final element of the central dogma. The ribosome, a nucleoprotein particle, is responsible and essential for this process. The bacterial ribosome consists of three rRNA molecules and approximately 55 proteins, components that are put together in an intricate and tightly regulated way. When finally matured, the quality of the particle, as well as the amount of active ribosomes, must be checked. The focus of this review is ribosome biogenesis in Escherichia coli and its cross-talk with the ongoing protein synthesis. We discuss how the ribosomal components are produced and how their synthesis is regulated according to growth rate and the nutritional contents of the medium. We also present the many accessory factors important for the correct assembly process, the list of which has grown substantially during the last few years, even though the precise mechanisms and roles of most of the proteins are not understood.
摘要
翻译,即将信使核糖核酸(mRNA)解码为蛋白质,是中心法则的第三个也是最后一个环节。核糖体是一种核蛋白颗粒,对这一过程负责且至关重要。细菌核糖体由三个核糖体RNA(rRNA)分子和大约55种蛋白质组成,这些组分以一种复杂且严格调控的方式组装在一起。最终成熟时,必须检查核糖体颗粒的质量以及活性核糖体的数量。本综述的重点是大肠杆菌中的核糖体生物合成及其与正在进行的蛋白质合成之间的相互作用。我们讨论核糖体组分是如何产生的,以及它们的合成如何根据生长速率和培养基的营养成分进行调控。我们还介绍了许多对正确组装过程很重要的辅助因子,尽管大多数蛋白质的确切机制和作用尚不清楚,但在过去几年中,这一名单已大幅增加。
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