通过过渡态路径采样阐明多肽在生长淀粉样纤维上的锁定机制。
Elucidating the locking mechanism of peptides onto growing amyloid fibrils through transition path sampling.
机构信息
Van 't Hoff Institute for Molecular Sciences, University of Amsterdam, Amsterdam, The Netherlands.
出版信息
Biophys J. 2012 Sep 19;103(6):1296-304. doi: 10.1016/j.bpj.2012.07.056.
Abstract
We investigate the molecular mechanism of monomer addition to a growing amyloid fibril composed of the main amyloidogenic region from the insulin peptide hormone, the LVEALYL heptapeptide. Applying transition path sampling in combination with reaction coordinate analysis reveals that the transition from a docked peptide to a locked, fully incorporated peptide can occur in two ways. Both routes involve the formation of backbone hydrogen bonds between the three central amino acids of the attaching peptide and the fibril, as well as a reorientation of the central Glu side chain of the locking peptide toward the interface between two β-sheets forming the fibril. The mechanisms differ in the sequence of events. We also conclude that proper docking is important for correct alignment of the peptide with the fibril, as alternative pathways result in misfolding.
摘要
我们研究了单体添加到由胰岛素肽激素的主要淀粉样纤维形成区域组成的生长淀粉样纤维的分子机制,该纤维由 LVEALYL 七肽组成。应用过渡路径采样结合反应坐标分析表明,从对接肽到锁定的、完全整合的肽的转变可以通过两种方式发生。这两种途径都涉及到附着肽的三个中心氨基酸与纤维之间的骨架氢键的形成,以及锁定肽的中心 Glu 侧链朝向形成纤维的两个β-片层之间的界面的重定向。机制在事件的顺序上有所不同。我们还得出结论,正确的对接对于肽与纤维的正确对齐很重要,因为替代途径会导致错误折叠。
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