不同双层厚度的快速翻滚双分子层中的脂质动力学：模型跨膜肽的影响

Lipid dynamics in fast-tumbling bicelles with varying bilayer thickness: effect of model transmembrane peptides.

作者信息

Lind Jesper, Nordin Jon, Mäler Lena

机构信息

Center for Biomembrane Research, Department of Biochemistry and Biophysics, The Arrhenius Laboratory, Stockholm University, 10691 Stockholm, Sweden.

出版信息

Biochim Biophys Acta. 2008 Nov;1778(11):2526-34. doi: 10.1016/j.bbamem.2008.07.010. Epub 2008 Jul 22.

DOI:10.1016/j.bbamem.2008.07.010

PMID:18692021

Abstract

The morphology of q=0.5 fast-tumbling bicelles prepared with three different acyl chain lengths has been investigated by NMR. It is shown that bicelles prepared with DLPC (12 C) and DHPC are on average larger than those containing DMPC or DPPC (14 and 16 C) and DHPC, which may be due to a higher degree of mixing between DLPC and DHPC. The fast internal mobility of the lipids was determined from natural abundance carbon-13 relaxation. A similar dynamical behaviour of the phospholipids in the three different bicelles was observed, although the DPPC lipid acyl chain displayed a somewhat lower degree of mobility, as evidenced by higher generalized order parameters throughout the acyl chain. Carbon-13 relaxation was also used to determine the effect of different model transmembrane peptides, with flanking Lys residues, on the lipid dynamics in the three different bicelles. All peptides had the effect of increasing the order parameters for the DLPC lipid, while no effect was observed on the longer lipid chains. This effect may be explained by a mismatch between the hydrophobic length of the peptides and the DLPC lipid acyl chain.

摘要

通过核磁共振（NMR）研究了用三种不同酰基链长度制备的q = 0.5快速翻滚双分子层的形态。结果表明，用DLPC（12个碳）和DHPC制备的双分子层平均比含有DMPC或DPPC（14和16个碳）与DHPC的双分子层更大，这可能是由于DLPC和DHPC之间的混合程度更高。脂质的快速内部流动性由天然丰度碳-13弛豫确定。在三种不同的双分子层中观察到磷脂具有相似的动力学行为，尽管DPPC脂质酰基链的流动性程度略低，这通过整个酰基链上较高的广义序参数得以证明。碳-13弛豫也用于确定具有侧翼赖氨酸残基的不同模型跨膜肽对三种不同双分子层中脂质动力学的影响。所有肽都有增加DLPC脂质序参数的作用，而对较长的脂质链没有观察到影响。这种效应可能是由于肽的疏水长度与DLPC脂质酰基链不匹配所致。

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不同双层厚度的快速翻滚双分子层中的脂质动力学：模型跨膜肽的影响

Lipid dynamics in fast-tumbling bicelles with varying bilayer thickness: effect of model transmembrane peptides.

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