70S 核糖体上翻译终止的构象控制。

Conformational Control of Translation Termination on the 70S Ribosome.

机构信息

RNA Therapeutics Institute, University of Massachusetts Medical School, 368 Plantation St., Worcester, MA 01605, USA.

出版信息

Structure. 2018 Jun 5;26(6):821-828.e3. doi: 10.1016/j.str.2018.04.001. Epub 2018 May 3.

DOI:10.1016/j.str.2018.04.001

PMID:29731232

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5990466/

Abstract

Translation termination ensures proper lengths of cellular proteins. During termination, release factor (RF) recognizes a stop codon and catalyzes peptide release. Conformational changes in RF are thought to underlie accurate translation termination. However, structural studies of ribosome termination complexes have only captured RFs in a conformation that is consistent with the catalytically active state. Here, we employ a hyper-accurate RF1 variant to obtain crystal structures of 70S termination complexes that suggest a structural pathway for RF1 activation. We trapped RF1 conformations with the catalytic domain outside of the peptidyl-transferase center, while the codon-recognition domain binds the stop codon. Stop-codon recognition induces 30S decoding-center rearrangements that precede accommodation of the catalytic domain. The separation of codon recognition from the opening of the catalytic domain suggests how rearrangements in RF1 and in the ribosomal decoding center coordinate stop-codon recognition with peptide release, ensuring accurate translation termination.

摘要

翻译终止确保了细胞蛋白质的适当长度。在终止过程中，释放因子（RF）识别终止密码子并催化肽的释放。RF 的构象变化被认为是准确翻译终止的基础。然而，核糖体终止复合物的结构研究仅捕获了与催化活性状态一致的 RF 构象。在这里，我们使用超精确的 RF1 变体获得了终止复合物的 70S 晶体结构，这些结构提示了 RF1 激活的结构途径。我们使用催化结构域在肽转移酶中心之外捕获 RF1 构象，而密码子识别结构域结合终止密码子。终止密码子的识别诱导 30S 解码中心的重排，然后再容纳催化结构域。密码子识别与催化结构域的打开分离表明，RF1 和核糖体解码中心的重排如何协调终止密码子的识别与肽的释放，从而确保准确的翻译终止。

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本文引用的文献

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