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由稀有密码子和tRNA短缺导致的SsrA介导的肽标签化。

SsrA-mediated peptide tagging caused by rare codons and tRNA scarcity.

作者信息

Roche E D, Sauer R T

机构信息

Department of Biology, Massachusetts Institute of Technology, Cambridge, MA 02139, USA.

出版信息

EMBO J. 1999 Aug 16;18(16):4579-89. doi: 10.1093/emboj/18.16.4579.

DOI:10.1093/emboj/18.16.4579

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1171532/

Abstract

SsrA RNA mediates the addition of a C-terminal peptide tag (AANDENYALAA) to bacterial proteins translated from mRNAs without in-frame stop codons. This process involves both tRNA- and mRNA-like functions of SsrA and targets the tagged proteins for degradation. By designing an SsrA variant that adds a peptide tag (AANDENYALDD) that does not result in rapid degradation, we show that tagging of a model protein synthesized from an mRNA without stop codons can be detected both in vivo and in vitro. We also use this assay to demonstrate that ribosome stalling at clusters of rare arginine codons in mRNA is sufficient to recruit and activate the SsrA peptide tagging system. An essential requirement for tagging at rare AGA codons is a scarcity of the cognate tRNA; supplemental tRNA(AGA) suppresses tagging, and depleting the available pool of tRNA(AGA) enhances tagging and reveals tagging caused by single rare AGA codons. Protein tagging at sites corresponding to rare codons appears to involve SsrA action at an internal mRNA site rather than at the 3' end of a cleaved mRNA.

摘要

SsrA RNA介导在没有框内终止密码子的mRNA所翻译的细菌蛋白质上添加一个C端肽标签（AANDENYALAA）。这个过程涉及SsrA的tRNA样和mRNA样功能，并将带标签的蛋白质作为降解目标。通过设计一种添加不会导致快速降解的肽标签（AANDENYALDD）的SsrA变体，我们表明在体内和体外都能检测到从无终止密码子的mRNA合成的模型蛋白的标签化。我们还利用这个检测方法证明，mRNA中稀有精氨酸密码子簇处的核糖体停滞足以招募并激活SsrA肽标签系统。在稀有AGA密码子处进行标签化的一个基本要求是同源tRNA的稀缺；补充tRNA(AGA)会抑制标签化，而耗尽可用的tRNA(AGA)库则会增强标签化，并揭示由单个稀有AGA密码子引起的标签化。在与稀有密码子对应的位点进行蛋白质标签化似乎涉及SsrA在mRNA内部位点而非切割后mRNA的3'端的作用。