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对掺入双分子层中的跨膜肽进行时间分辨电子顺磁共振浸入深度研究。

Time-resolved EPR immersion depth studies of a transmembrane peptide incorporated into bicelles.

作者信息

Nusair Nisreen A, Mayo Daniel J, Dorozenski Tia D, Cardon Thomas B, Inbaraj Johnson J, Karp Ethan S, Newstadt Justin P, Grosser Stuart M, Lorigan Gary A

机构信息

Walsh University, North Canton, OH 44720, USA.

出版信息

Biochim Biophys Acta. 2012 Mar;1818(3):821-8. doi: 10.1016/j.bbamem.2011.11.009. Epub 2011 Nov 11.

DOI:10.1016/j.bbamem.2011.11.009
PMID:22100865
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3273666/
Abstract

The reduction in EPR signal intensity of nitroxide spin-labels by ascorbic acid has been measured as a function of time to investigate the immersion depth of the spin-labeled M2δ AChR peptide incorporated into a bicelle system utilizing EPR spectroscopy. The corresponding decay curves of n-DSA (n=5, 7, 12, and 16) EPR signals have been used to (1) calibrate the depth of the bicelle membrane and (2) establish a calibration curve for measuring the depth of spin-labeled transmembrane peptides. The kinetic EPR data of CLS, n-DSA (n=5, 7, 12, and 16), and M2δ AChR peptide spin-labeled at Glu-1 and Ala-12 revealed excellent exponential and linear fits. For a model M2δ AChR peptide, the depth of immersion was calculated to be 5.8Å and 3Å for Glu-1, and 21.7Å and 19Å for Ala-12 in the gel-phase (298K) and L(α)-phases (318K), respectively. The immersion depth values are consistent with the pitch of an α-helix and the structural model of M2δ AChR incorporated into the bicelle system is in a good agreement with previous studies. Therefore, this EPR time-resolved kinetic technique provides a new reliable method to determine the immersion depth of membrane-bound peptides, as well as, explore the structural characteristics of the M2δ AChR peptide.

摘要

通过测量抗坏血酸对氮氧自旋标记物EPR信号强度的降低随时间的变化,利用电子顺磁共振波谱法研究了掺入双分子层系统中的自旋标记M2δ AChR肽的浸入深度。已使用n-DSA(n = 5、7、12和16)EPR信号的相应衰减曲线来(1)校准双分子层膜的深度,以及(2)建立用于测量自旋标记跨膜肽深度的校准曲线。在Glu-1和Ala-12处自旋标记的CLS、n-DSA(n = 5、7、12和16)以及M2δ AChR肽的动力学EPR数据显示出出色的指数和线性拟合。对于模型M2δ AChR肽,在凝胶相(298K)和L(α)相(318K)中,Glu-1的浸入深度经计算分别为5.8Å和3Å,Ala-12的浸入深度分别为21.7Å和19Å。浸入深度值与α-螺旋的螺距一致,并且掺入双分子层系统中的M2δ AChR的结构模型与先前的研究非常吻合。因此,这种EPR时间分辨动力学技术提供了一种新的可靠方法来确定膜结合肽的浸入深度,以及探索M2δ AChR肽的结构特征。

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