Hansen J E, Longworth J W, Fleming G R
Department of Chemistry, University of Chicago, Illinois 60637.
Biochemistry. 1990 Aug 7;29(31):7329-38. doi: 10.1021/bi00483a024.
The fluorescence lifetimes of Cu(II), Cu(I), Ag(I), Hg(II), Co(II), and Ni(II) azurin Pae from Pseudomonas aeruginosa and Cu(II), Cu(I), and Hg(II) azurin Afe from Alcaligenes faecalis were measured at 295 K by time-correlated single-photon counting. In addition, fluorescence lifetimes of Cu(II) azurin Pae were measured between 30 and 160 K and showed little change in value. Ultraviolet absorption difference spectra between metalloazurin Pae and apoazurin Pae were measured, as were the fluorescence spectra of metalloazurins. These spectra were used to determine the spectral overlap integral required for dipole-dipole resonance calculations. All metalloazurins exhibit a reduced fluorescence lifetime compared to their respective apoazurins. Forster electronic energy transfer rates were calculated for both metalloazurin Pae and metalloazurin Afe derivatives; both enzymes contain a single tryptophyl residue which is located in a different position in the two azurins. These azurins have markedly different fluorescence spectra, and electronic energy transfers occur from these two tryptophyl sites with different distances and orientations and spectral overlap integral values. Intramolecular distances and orientations were derived from an X-ray crystallographic structure and a molecular dynamic simulation of the homologous azurin Ade from Alcaligenes denitrificans, which contains both tryptophyl sites. Assignments were made of metal-ligand-field electronic transitions and of transition dipole moments and directions for tryptophyl residues, which accounted for the observed fluorescence quenching of Hg(II), Co(II), and Ni(II) azurin Pae and Cu(II) and Hg(II) azurin Afe. The fluorescence of azurin Pae is assigned as a 1Lb electronic transition, while that of azurin Afe is 1La. The marked fluorescence quenching of Cu(II) azurin Pae and Cu(I) azurin Pae and Afe is less well reproduced by our calculations, and long-range oxidative and reductive electron transfer, respectively, are proposed as additional quenching mechanisms. This study illustrates the application of Forster electronic energy transfer calculations to intramolecular transfers in structurally well characterized molecular systems and demonstrates its ability to predict observed fluorescence quenching rates when the necessary extensive structural, electronic transition assignment, and spectroscopic data are available. The agreement between Forster calculations and quenching rates derived from fluorescence lifetime measurements suggests there are limited changes in conformation between crystal structure and solution structures, with the exception of the tryptophyl residue of azurin Afe, where a conformation derived from a molecular simulation in water was necessary rather than that found in the crystal structure.
通过时间相关单光子计数法,在295 K下测量了来自铜绿假单胞菌的铜(II)、铜(I)、银(I)、汞(II)、钴(II)和镍(II)型绿脓杆菌蓝蛋白Pae,以及来自粪产碱菌的铜(II)、铜(I)和汞(II)型粪产碱菌蓝蛋白Afe的荧光寿命。此外,还测量了铜(II)型绿脓杆菌蓝蛋白Pae在30至160 K之间的荧光寿命,其值变化不大。测量了金属化绿脓杆菌蓝蛋白Pae和脱辅基绿脓杆菌蓝蛋白Pae之间的紫外吸收差光谱以及金属化绿脓杆菌蓝蛋白的荧光光谱。这些光谱用于确定偶极 - 偶极共振计算所需的光谱重叠积分。与各自的脱辅基绿脓杆菌蓝蛋白相比,所有金属化绿脓杆菌蓝蛋白的荧光寿命均缩短。计算了金属化绿脓杆菌蓝蛋白Pae和金属化粪产碱菌蓝蛋白Afe衍生物的福斯特电子能量转移速率;这两种酶都含有一个色氨酸残基,位于两种蓝蛋白的不同位置。这些蓝蛋白具有明显不同的荧光光谱,并且电子能量从这两个色氨酸位点以不同的距离、取向和光谱重叠积分值发生转移。分子内距离和取向源自反硝化产碱菌同源蓝蛋白Ade的X射线晶体结构和分子动力学模拟,该蓝蛋白包含两个色氨酸位点。对金属 - 配体场电子跃迁以及色氨酸残基的跃迁偶极矩和方向进行了赋值,这解释了观察到的汞(II)、钴(II)和镍(II)型绿脓杆菌蓝蛋白Pae以及铜(II)和汞(II)型粪产碱菌蓝蛋白Afe的荧光猝灭现象。绿脓杆菌蓝蛋白Pae的荧光被指定为1Lb电子跃迁,而粪产碱菌蓝蛋白Afe的荧光为1La。我们的计算对铜(II)型绿脓杆菌蓝蛋白Pae、铜(I)型绿脓杆菌蓝蛋白Pae和粪产碱菌蓝蛋白Afe明显的荧光猝灭现象的重现性较差,分别提出远程氧化和还原电子转移作为额外的猝灭机制。本研究说明了福斯特电子能量转移计算在结构特征明确的分子系统中分子内转移的应用,并证明了当有必要的广泛结构、电子跃迁赋值和光谱数据时,它能够预测观察到的荧光猝灭速率。福斯特计算与从荧光寿命测量得出的猝灭速率之间的一致性表明,除了粪产碱菌蓝蛋白Afe的色氨酸残基外,晶体结构和溶液结构之间的构象变化有限,对于粪产碱菌蓝蛋白Afe的色氨酸残基,需要水中分子模拟得出的构象而非晶体结构中的构象。
