Pfeiffer M, Rink T, Gerwert K, Oesterhelt D, Steinhoff H J
Lehrstuhl für Biophysik, Ruhr-Universität Bochum, Bochum, 44780, Germany.
J Mol Biol. 1999 Mar 19;287(1):163-71. doi: 10.1006/jmbi.1998.2593.
Due to high temperature factors and the lack of considerable electron density, electron microscopy and X-ray experiments on the cytoplasmic E-F loop of bacteriorhodopsin result in a variety of structural models. As the experimental conditions regarding ionic strength, temperature and the presence of detergents may affect the structure of the E-F loop, we employ electron paramagnetic resonance and site-directed spin-labeling to study the structure of this loop under physiological conditions. The amino acid residues at positions 154 to 171 were replaced by cysteine residues and derivatized with a sulfhydryl-specific nitroxide spin label one by one. The conventional and power saturation electron paramagnetic spectroscopy provide the mobility of the nitroxide and its accessibility to dissolved molecular oxygen and membrane-impermeable chromium oxalate in the respective site. The results show that K159 and A168 are located at the water-lipid interface of helices E and F, respectively. The orientation of the amino acid side-chains in the helical regions from positions 154 to 159 and 166 to 171 were found to agree with published structural data for bacteriorhodopsin. In the residue sequence from positions 160 to 165 the EPR data yield evidence for a turned loop structure with the side-chains of M163 and S162 oriented towards the proton channel and the water phase, respectively.
由于高温因素以及缺乏可观的电子密度,对细菌视紫红质细胞质E-F环进行的电子显微镜和X射线实验产生了多种结构模型。鉴于离子强度、温度和去污剂的存在等实验条件可能会影响E-F环的结构,我们采用电子顺磁共振和定点自旋标记技术来研究该环在生理条件下的结构。将第154至171位的氨基酸残基替换为半胱氨酸残基,并逐一用巯基特异性氮氧化物自旋标记进行衍生化。传统的和功率饱和电子顺磁共振光谱分别提供了氮氧化物的流动性及其在各个位点对溶解分子氧和膜不可渗透的草酸铬的可及性。结果表明,K159和A168分别位于螺旋E和F的水-脂界面。发现第154至159位和166至171位螺旋区域中氨基酸侧链的取向与已发表的细菌视紫红质结构数据一致。在第160至165位的残基序列中,电子顺磁共振数据提供了一个转折环结构的证据,其中M163和S162的侧链分别朝向质子通道和水相。