Does different orientation of the methoxy groups of ubiquinone-10 in the reaction centre of Rhodobacter sphaeroides cause different binding at QA and QB?

André Remy, Rutger B Boers, Tatiana Egorova-Zachernyuk, Peter Gast, Johan Lugtenburg, Klaus Gerwert
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引用次数: 12

Abstract

The different roles of ubiquinone-10 (UQ10) at the primary and secondary quinone (QA and QB) binding sites of Rhodobacter sphaeroides R26 reaction centres are governed by the protein microenvironment. The 4C=O carbonyl group of QA is unusually strongly hydrogen-bonded, in contrast to QB. This asymmetric binding seems to determine their different functions. The asymmetric hydrogen-bonding at QA can be caused intrinsically by distortion of the methoxy groups or extrinsically by binding to specific amino-acid side groups. Different X-ray-based structural models show contradictory orientations of the methoxy groups and do not provide a clear picture. To elucidate if distortion of the methoxy groups induces this hydrogen-bonding, their (ring-)C-O vibrations were assigned by use of site-specifically labelled [5-13C]UQ10 and [6-13C]UQ10 reconstituted at either the QA or the QB binding site. Two infrared bands at 1288 cm(-1) and 1264 cm(-1) were assigned to the methoxy vibrations. They did not shift in frequency at either the QA or QB binding sites, as compared with unbound UQ10. As the frequencies of these vibrations and their coupling are sensitive to the conformations of the methoxy groups, different conformations of the C(5) and C(6) methoxy groups at the QA and QB binding sites can now be excluded. Both methoxy groups are oriented out of plane at QA and QB. Therefore, hydrogen-bonding to His M219 combined with electrostatic interactions with the Fe2+ ion seems to determine the strong asymmetric binding of QA.

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球形红杆菌反应中心泛素-10甲氧基的不同取向是否导致QA和QB的结合不同?
泛素-10 (UQ10)在球形红杆菌R26反应中心一级和二级醌(QA和QB)结合位点的不同作用受蛋白质微环境的支配。与QB相比,QA的4C=O羰基具有异常强的氢键。这种不对称绑定似乎决定了它们的不同功能。QA上的不对称氢键可以由甲氧基的畸变引起,也可以由与特定氨基酸侧基的结合引起。不同的基于x射线的结构模型显示了甲氧基的相互矛盾的取向,并没有提供一个清晰的图像。为了阐明甲氧基的扭曲是否诱导了这种氢键,他们的(环)C-O振动通过使用位点特异性标记的[5-13C]UQ10和在QA或QB结合位点重组的[6-13C]UQ10来分配。在1288 cm(-1)和1264 cm(-1)的两个红外波段被分配给甲氧基振动。与未结合的UQ10相比,它们在QA或QB结合位点的频率都没有变化。由于这些振动的频率及其耦合对甲氧基的构象很敏感,现在可以排除QA和QB结合位点上C(5)和C(6)甲氧基的不同构象。两个甲氧基在QA和QB处都取向于平面外。因此,与His M219的氢键结合与Fe2+离子的静电相互作用似乎决定了QA的强不对称结合。
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