相邻螺旋的取向偏好可以驱动一个边缘疏水性跨膜螺旋的内质网插入。
Orientational preferences of neighboring helices can drive ER insertion of a marginally hydrophobic transmembrane helix.
机构信息
Department of Biochemistry and Biophysics, Center for Biomembrane Research, Stockholm University, Sweden.
出版信息
Mol Cell. 2012 Feb 24;45(4):529-40. doi: 10.1016/j.molcel.2011.12.024. Epub 2012 Jan 25.
Abstract
α-helical integral membrane proteins critically depend on the correct insertion of their transmembrane α helices into the lipid bilayer for proper folding, yet a surprisingly large fraction of the transmembrane α helices in multispanning integral membrane proteins are not sufficiently hydrophobic to insert into the target membrane by themselves. How can such marginally hydrophobic segments nevertheless form transmembrane helices in the folded structure? Here, we show that a transmembrane helix with a strong orientational preference (N(cyt)-C(lum) or N(lum)-C(cyt)) can both increase and decrease the hydrophobicity threshold for membrane insertion of a neighboring, marginally hydrophobic helix. This effect helps explain the "missing hydrophobicity" in polytopic membrane proteins.
摘要
α-螺旋跨膜整合膜蛋白对于其跨膜α螺旋正确插入脂质双层对于正确折叠至关重要,然而多跨整合膜蛋白中的很大一部分跨膜α螺旋本身并没有足够的疏水性插入到靶膜中。这些疏水性较弱的片段如何在折叠结构中形成跨膜螺旋?在这里,我们表明具有强烈定向偏好的跨膜螺旋(N(胞质)-C(胞腔)或 N(胞腔)-C(胞质))都可以增加和降低相邻疏水性较弱的螺旋插入膜的疏水性阈值。这种效应有助于解释多跨膜蛋白中的“缺失疏水性”。
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