Crystal structure of the double azurin mutant Cys3Ser/Ser100Pro from Pseudomonas aeruginosa at 1.8 Å resolution: its folding–unfolding energy and unfolding kinetics

Mats Ökvist , Nicklas Bonander , Anders Sandberg , B.Göran Karlsson , Ute Krengel , Yafeng Xue , Lennart Sjölin
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引用次数: 4

Abstract

Azurin is a cupredoxin, which functions as an electron carrier. Its fold is dominated by a β-sheet structure. In the present study, azurin serves as a model system to investigate the importance of a conserved disulphide bond for protein stability and folding/unfolding. For this purpose, we have examined two azurin mutants, the single mutant Cys3Ser, which disrupts azurin’s conserved disulphide bond, and the double mutant Cys3Ser/Ser100Pro, which contains an additional mutation at a site distant from the conserved disulphide. The crystal structure of the azurin double mutant has been determined to 1.8 Å resolution2, with a crystallographic R-factor of 17.5% (Rfree=20.8%). A comparison with the wild-type structure reveals that structural differences are limited to the sites of the mutations. Also, the rates of folding and unfolding as determined by CD and fluorescence spectroscopy are almost unchanged. The main difference to wild-type azurin is a destabilisation by ∼20 kJ mol−1, constituting half the total folding energy of the wild-type protein. Thus, the disulphide bond constitutes a vital component in giving azurin its stable fold.

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铜绿假单胞菌双azurin突变体Cys3Ser/Ser100Pro在1.8 Å分辨率下的晶体结构:折叠展开能和展开动力学
Azurin是一种铜氧还蛋白,其功能是电子载体。褶皱以β片状结构为主。在本研究中,azurin作为一个模型系统来研究保守的二硫键对蛋白质稳定性和折叠/展开的重要性。为此,我们研究了两个azurin突变体,一个是单突变体Cys3Ser,它破坏了azurin的保守的二硫化物键,另一个是双突变体Cys3Ser/Ser100Pro,它在远离保守的二硫化物的位点上包含一个额外的突变。azurin双突变体的晶体结构已测定为1.8 Å分辨率2,晶体学r因子为17.5% (Rfree=20.8%)。与野生型结构的比较表明,结构差异仅限于突变位点。此外,由CD和荧光光谱测定的折叠和展开速率几乎没有变化。与野生型azurin的主要区别是失稳约20 kJ mol−1,占野生型蛋白总折叠能量的一半。因此,二硫键构成了保证蓝蛋白稳定折叠的重要组成部分。
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