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细菌视紫红质的高分辨率13C固态核磁共振:特定天冬氨酸的归属及单点突变的结构意义

High resolution 13C-solid state NMR of bacteriorhodopsin: assignment of specific aspartic acids and structural implications of single site mutations.

作者信息

Engelhard M, Hess B, Metz G, Kreutz W, Siebert F, Soppa J, Oesterhelt D

机构信息

Max-Planck-Institut für Ernährungsphysiologie, Rheinlanddamm, Dortmund, Federal Republic of Germany.

出版信息

Eur Biophys J. 1990;18(1):17-24. doi: 10.1007/BF00185416.

DOI:10.1007/BF00185416
PMID:1968385
Abstract

Three mutant strains of Halobacterium sp. GRB with the site of mutation in the bacterioopsin gene (PM 326: Asp96----Asn; PM 374: Asp96----Gly; PM 384: Asp85----Glu) were grown in a synthetic medium containing (4-13C)-Asp. The mutant bacteriorhodopsins labeled with (4-13C)-Asp (37%-45%), and owing to the metabolism of Halobacteria also with (11-13C)-Trp (50%-100%), were isolated as purple membranes and 13C Solid State Magic Angle Sample Spinning (MASS) Nuclear Magnetic Resonance (NMR) spectra of the samples were taken. The Asp96 mutants lacked the signal at 171.3 ppm which was previously assigned to a protonated internal Asp (Engelhard et al. 1989a). This observation supports the conclusion that Asp96 is protonated in the ground state. PM 384 (Asp85----Glu) has an absorption maximum at 610 nm. It can be converted into a purple form (lambda max = 540 nm) by treatment with a detergent (CHAPSO). The NMR-spectra of these two species differ from each other and from the wild type. The intensity of the resonance at 173 ppm in the wild type spectrum is reduced in both forms of the mutant protein. It is probable that this signal is caused by Asp85. The amino acid changes result not only in a perturbation of their direct environment but also effects on Trp residues and the chromophore protein interaction can be observed.

摘要

三株嗜盐菌属GRB的突变菌株,其细菌视紫红质基因发生了位点突变(PM 326:天冬氨酸96位突变为天冬酰胺;PM 374:天冬氨酸96位突变为甘氨酸;PM 384:天冬氨酸85位突变为谷氨酸),在含有(4-¹³C)-天冬氨酸的合成培养基中培养。用(4-¹³C)-天冬氨酸标记的突变型细菌视紫红质(37%-45%),由于嗜盐菌的代谢作用,还含有(11-¹³C)-色氨酸(50%-100%),作为紫膜被分离出来,并对样品进行了¹³C固态魔角样品旋转(MASS)核磁共振(NMR)光谱测定。天冬氨酸96位突变体在171.3 ppm处没有信号,该信号先前被指定为质子化的内部天冬氨酸(恩格尔哈德等人,1989a)。这一观察结果支持了天冬氨酸96位在基态下被质子化的结论。PM 384(天冬氨酸85位突变为谷氨酸)在610 nm处有最大吸收峰。用去污剂(CHAPSO)处理后可转化为紫色形式(最大吸收波长=540 nm)。这两种形式的核磁共振光谱彼此不同,也与野生型不同。野生型光谱中173 ppm处的共振强度在突变蛋白的两种形式中均降低。这个信号可能是由天冬氨酸85位引起的。氨基酸的变化不仅导致其直接环境的扰动,还可以观察到对色氨酸残基的影响以及发色团与蛋白质相互作用的影响。

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本文引用的文献

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Conformational changes of bacteriorhodopsin detected by Fourier transform infrared difference spectroscopy.傅里叶变换红外差示光谱法检测细菌视紫红质的构象变化。
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