通过转录后修饰扩展核糖体的核苷酸组成。
Expanding the nucleotide repertoire of the ribosome with post-transcriptional modifications.
作者信息
Chow Christine S, Lamichhane Tek N, Mahto Santosh K
机构信息
Department of Chemistry, Wayne State University, Detroit, Michigan 48202, USA.
出版信息
ACS Chem Biol. 2007 Sep 21;2(9):610-9. doi: 10.1021/cb7001494.
Abstract
In all kingdoms of life, RNAs undergo specific post-transcriptional modifications. More than 100 different analogues of the four standard RNA nucleosides have been identified. Modifications in ribosomal RNAs (rRNAs) are highly prevalent and cluster in regions of the ribosome that have functional importance, have a high level of nucleotide conservation, and typically lack proteins. Modifications also play roles in determining antibiotic resistance or sensitivity. A wide spectrum of chemical diversity from the modifications provides the ribosome with a broader range of possible interactions between rRNA regions, transfer RNA, messenger RNA, proteins, or ligands by influencing local rRNA folds and fine-tuning the translation process. The collective importance of the modified nucleosides in ribosome function has been demonstrated for a number of organisms, and further studies may reveal how the individual players regulate these functions through synergistic or cooperative effects.
摘要
在所有生命王国中,RNA都会经历特定的转录后修饰。现已鉴定出四种标准RNA核苷的100多种不同类似物。核糖体RNA(rRNA)中的修饰非常普遍,集中在核糖体中具有功能重要性、核苷酸保守程度高且通常缺乏蛋白质的区域。修饰在决定抗生素抗性或敏感性方面也发挥作用。修饰带来的广泛化学多样性通过影响局部rRNA折叠并微调翻译过程,为核糖体提供了rRNA区域、转运RNA、信使RNA、蛋白质或配体之间更广泛的可能相互作用。已在许多生物体中证明了修饰核苷在核糖体功能中的总体重要性,进一步的研究可能会揭示各个成分如何通过协同或合作效应来调节这些功能。
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