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大肠杆菌 30S 核糖体亚基重建中的动力学协同作用揭示了组装景观中的额外复杂性。

Kinetic cooperativity in Escherichia coli 30S ribosomal subunit reconstitution reveals additional complexity in the assembly landscape.

机构信息

Departments of Molecular Biology and Chemistry, The Scripps Research Institute, La Jolla, CA 92037, USA.

出版信息

Proc Natl Acad Sci U S A. 2010 Mar 23;107(12):5417-22. doi: 10.1073/pnas.0912007107. Epub 2010 Mar 5.

DOI:10.1073/pnas.0912007107
PMID:20207951
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2851750/
Abstract

The Escherichia coli 30S ribosomal subunit self-assembles in vitro in a hierarchical manner, with the RNA binding by proteins enabled by the prior binding of others under equilibrium conditions. Early 16S rRNA binding proteins also bind faster than late-binding proteins, but the specific causes for the slow binding of late proteins remain unclear. Previously, a pulse-chase monitored by quantitative mass spectrometry method was developed for monitoring 30S subunit assembly kinetics, and here a modified experimental scheme was used to probe kinetic cooperativity by including a step where subsets of ribosomal proteins bind and initiate assembly prior to the pulse-chase kinetics. In this work, 30S ribosomal subunit kinetic reconstitution experiments revealed that thermodynamic dependency does not always correlate with kinetic cooperativity. Some folding transitions that cause subsequent protein binding to be more energetically favorable do not result in faster protein binding. Although 3(') domain primary protein S7 is required for RNA binding by both proteins S9 and S19, prior binding of S7 accelerates the binding of S9, but not S19, indicating there is an additional mechanistic step required for S19 to bind. Such data on kinetic cooperativity and the presence of multiphasic assembly kinetics reveal complexity in the assembly landscape that was previously hidden.

摘要

大肠杆菌 30S 核糖体亚基在体外以分级的方式自我组装,在平衡条件下,蛋白质通过先结合其他物质而能够结合 RNA。早期的 16S rRNA 结合蛋白的结合速度也比晚期结合蛋白快,但晚期蛋白结合缓慢的具体原因仍不清楚。先前,已经开发了一种通过定量质谱监测的脉冲追踪方法来监测 30S 亚基组装动力学,这里使用了一种改良的实验方案,通过包括核糖体蛋白亚基结合和在脉冲追踪动力学之前开始组装的步骤来探测动力学协同性。在这项工作中,30S 核糖体亚基的动力学重建实验表明,热力学依赖性并不总是与动力学协同性相关。一些导致随后蛋白质结合更有利的折叠转变并不导致蛋白质结合更快。尽管蛋白质 S7 的 3' 结构域主要负责蛋白质 S9 和 S19 的 RNA 结合,但 S7 的预先结合会加速 S9 的结合,但不会加速 S19 的结合,表明 S19 结合还需要额外的机制步骤。这种关于动力学协同性和多相组装动力学存在的数据揭示了以前隐藏的组装景观的复杂性。

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