Top7-CFr的模拟:短暂的螺旋延伸引导折叠。
Simulation of Top7-CFr: a transient helix extension guides folding.
作者信息
Mohanty Sandipan, Meinke Jan H, Zimmermann Olav, Hansmann Ulrich H E
机构信息
John von Neumann Institute for Computing, Research Centre Jülich, 52425 Jülich, Germany.
出版信息
Proc Natl Acad Sci U S A. 2008 Jun 10;105(23):8004-7. doi: 10.1073/pnas.0708411105. Epub 2008 Apr 11.
Abstract
Protein structures often feature beta-sheets in which adjacent beta-strands have large sequence separation. How the folding process orchestrates the formation and correct arrangement of these strands is not comprehensively understood. Particularly challenging are proteins in which beta-strands at the N and C termini are neighbors in a beta-sheet. The N-terminal beta-strand is synthesized early on, but it can not bind to the C terminus before the chain is fully synthesized. During this time, there is a danger that the beta-strand at the N terminus interacts with nearby molecules, leading to potentially harmful aggregates of incompletely folded proteins. Simulations of the C-terminal fragment of Top7 show that this risk of misfolding and aggregation can be avoided by a "caching" mechanism that relies on the "chameleon" behavior of certain segments.
摘要
蛋白质结构通常具有β折叠片层,其中相邻的β链在序列上有较大间隔。折叠过程如何精心安排这些链的形成和正确排列,目前尚未完全理解。特别具有挑战性的是那些N端和C端的β链在β折叠片中相邻的蛋白质。N端的β链在早期合成,但在链完全合成之前它无法与C端结合。在此期间,存在N端的β链与附近分子相互作用的风险,从而导致未完全折叠的蛋白质形成潜在有害的聚集体。对Top7 C端片段的模拟表明,通过一种依赖于某些片段“变色龙”行为的“缓存”机制,可以避免这种错误折叠和聚集的风险。
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