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利用一氧化碳的振动斯塔克效应探测蛋白质空腔中的电场。

Probing electric fields in protein cavities by using the vibrational stark effect of carbon monoxide.

作者信息

Lehle Hartwig, Kriegl Jan M, Nienhaus Karin, Deng Pengchi, Fengler Stephanus, Nienhaus G Ulrich

机构信息

Department of Biophysics, University of Ulm, D-89081 Ulm, Germany.

出版信息

Biophys J. 2005 Mar;88(3):1978-90. doi: 10.1529/biophysj.104.048140. Epub 2004 Dec 13.

DOI:10.1529/biophysj.104.048140
PMID:15596507
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1305250/
Abstract

To determine the magnitude and direction of the internal electric field in the Xe4 cavity of myoglobin mutant L29W-S108L, we have studied the vibrational Stark effect of carbon monoxide (CO) using infrared spectroscopy at cryogenic temperatures. CO was photodissociated from the heme iron and deposited selectively in Xe4. Its infrared spectrum exhibits Stark splitting into two bands associated with CO in opposite orientations. Two different photoproduct states can be distinguished, C' and C'', with markedly different properties. For C', characteristic temperature-dependent changes of the area, shift, and width were analyzed, based on a dynamic model in which the CO performs fast librations within a double-well model potential. For the barrier between the wells, a height of approximately 1.8 kJ/mol was obtained, in which the CO performs oscillations at an angular frequency of approximately 25 cm(-1). The magnitude of the electric field in the C' conformation was determined as 11.1 MV/cm; it is tilted by an angle of 29 degrees to the symmetry axis of the potential. Above 140 K, a protein relaxation leads to a significantly altered photoproduct, C'', with a smaller Stark splitting and a more confining potential (barrier >4 kJ/mol) governing the CO librations.

摘要

为了确定肌红蛋白突变体L29W - S108L的Xe4腔体内内部电场的大小和方向,我们在低温下利用红外光谱研究了一氧化碳(CO)的振动斯塔克效应。CO从血红素铁上光解离并选择性地沉积在Xe4中。其红外光谱显示斯塔克分裂为与相反取向的CO相关的两个谱带。可以区分出两种不同的光产物状态,C'和C'',它们具有明显不同的性质。对于C',基于一个动态模型对面积、位移和宽度随温度的特征变化进行了分析,在该模型中CO在双阱模型势内进行快速摆动。对于阱之间的势垒,得到的高度约为1.8 kJ/mol,其中CO以约25 cm⁻¹的角频率进行振荡。C'构象中电场的大小确定为11.1 MV/cm;它相对于势的对称轴倾斜29度角。在140 K以上,蛋白质弛豫导致光产物显著改变,变为C'',其斯塔克分裂较小,并且有一个更强约束性的势(势垒>4 kJ/mol)控制着CO的摆动。

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