原子诱变揭示 23S 核糖体 RNA 的 A2660 是 EF-G GTP 酶激活的关键。

Atomic mutagenesis reveals A2660 of 23S ribosomal RNA as key to EF-G GTPase activation.

机构信息

Innsbruck Biocenter, Medical University Innsbruck, Division of Genomics and RNomics, Innsbruck, Austria.

出版信息

Nat Chem Biol. 2010 May;6(5):344-51. doi: 10.1038/nchembio.341. Epub 2010 Mar 28.

PMID:20348921

Abstract

Following ribosomal peptide bond formation, the reaction products, peptidyl-tRNA and deacylated tRNA, need to be translocated from the A- and P-sites to the P- and E-sites, respectively. This process is facilitated by the GTPase elongation factor G (EF-G). The mechanism describing how the ribosome activates GTP hydrolysis is poorly understood in molecular terms. By using an 'atomic mutagenesis' approach, which allows the manipulation of specific functional groups on 23S rRNA nucleotides in the context of the entire ribosome, we disclose the adenine exocyclic N6 amino group at A2660 of the sarcin-ricin loop as a key determinant for triggering GTP hydrolysis on EF-G. We show that the purine pi system-expanding characteristics of the exocyclic functional group at the C6 position of A2660 are essential. We propose that stacking interactions of A2660 with EF-G may act as a molecular trigger to induce repositioning of suspected functional amino acids in EF-G that in turn promote GTP hydrolysis.

摘要

核糖体肽键形成后，反应产物肽酰-tRNA 和去酰化 tRNA 需要分别从 A 位和 P 位转移到 P 位和 E 位。这一过程由 GTP 酶延伸因子 G（EF-G）促进。核糖体如何激活 GTP 水解的机制在分子水平上理解得很差。通过使用“原子诱变”方法，我们可以在整个核糖体的背景下操纵 23S rRNA 核苷酸上的特定功能基团，揭示了位于 Sarcin-Ricin 环中的 A2660 的腺嘌呤外环 N6 氨基基团是触发 EF-G 上 GTP 水解的关键决定因素。我们表明，A2660 的 C6 位置上的外环功能基团的嘌呤π系统扩展特性是必不可少的。我们提出，A2660 与 EF-G 的堆积相互作用可以作为分子触发因素，诱导 EF-G 中疑似功能氨基酸的重新定位，从而促进 GTP 水解。

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原子诱变揭示 23S 核糖体 RNA 的 A2660 是 EF-G GTP 酶激活的关键。

Atomic mutagenesis reveals A2660 of 23S ribosomal RNA as key to EF-G GTPase activation.

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