SRP RNA 与翻译核糖体之间的协同作用可在共翻译蛋白靶向过程中有效递呈正确的货物。
Synergistic actions between the SRP RNA and translating ribosome allow efficient delivery of the correct cargos during cotranslational protein targeting.
机构信息
Division of Chemistry and Chemical Engineering, California Institute of Technology, Pasadena, California 91125, USA.
出版信息
RNA. 2011 May;17(5):892-902. doi: 10.1261/rna.2610411. Epub 2011 Apr 1.
Abstract
During cotranslational protein targeting by the Signal Recognition Particle (SRP), the correct cargo accelerates stable complex assembly between the SRP and SRP receptor (FtsY) by several orders of magnitude, thus enabling rapid and faithful cargo delivery to the target membrane. The molecular mechanism underlying this cargo-induced rate acceleration has been unclear. Here we show that the SRP RNA allows assembly of the SRP-FtsY complex to be specifically stimulated by a correct cargo, and, reciprocally, a correct cargo enables the SRP RNA to optimize its electrostatic interactions with FtsY. These results combined with recent structural work led us to suggest a "conformational selection" model that explains the synergistic action of the SRP RNA with the cargo in accelerating complex assembly. In addition to its previously proposed role in preventing the premature dissociation of SRP and FtsY, we found that the SRP RNA also plays an active role in ensuring the formation of productive assembly intermediates, thus guiding the SRP and FtsY through the most efficient pathway of assembly.
摘要
在信号识别颗粒 (SRP) 介导的共翻译蛋白靶向过程中,正确的货物通过几个数量级加速了 SRP 和 SRP 受体 (FtsY) 之间的稳定复合物组装,从而能够快速而准确地将货物递送到靶膜。然而,这种货物诱导的速率加速的分子机制尚不清楚。在这里,我们表明 SRP RNA 允许 SRP-FtsY 复合物的组装被正确的货物特异性地刺激,并且,反过来,正确的货物使 SRP RNA 能够优化其与 FtsY 的静电相互作用。这些结果结合最近的结构研究,使我们提出了一个“构象选择”模型,解释了 SRP RNA 与货物在加速复合物组装中的协同作用。除了其在防止 SRP 和 FtsY 过早解离方面的先前提出的作用外,我们还发现 SRP RNA 还在确保形成有生产力的组装中间体方面发挥着积极作用,从而引导 SRP 和 FtsY 通过最有效的组装途径。
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