Gunne Matthias, Höppner Astrid, Hagedoorn Peter-Leon, Urlacher Vlada B
Institute of Biochemistry, Heinrich-Heine-Universität Düsseldorf, Germany.
FEBS J. 2014 Sep;281(18):4307-18. doi: 10.1111/febs.12755. Epub 2014 Mar 10.
Laccases (EC 1.10.3.2) are members of the multicopper oxidase family. They oxidize diverse electron-rich substrates through electron abstraction by the type 1 copper ion in the enzyme active site. Abstracted electrons are transferred to the trinuclear copper cluster, where molecular oxygen serves as final acceptor and is reduced to water. Laccase activity is assumed to depend on the redox potential of its type 1 copper ion. Whereas numerous studies have been undertaken to elucidate the determinants of the redox potential of type 1 copper ions in one-domain cupredoxins and in three-domain laccases, such experimental investigations are lacking for recently described, small, two-domain laccases. In this work, the crystal structure of the small laccase Ssl1 from Streptomyces sviceus was solved, and the positions that might influence the redox potential of Ssl1 were depicted. On the basis of this knowledge, several Ssl1 variants were constructed with an increase in redox potential of 16-81 mV, from 375 mV to 391-456 mV. Mutation of residues in close proximity to the type 1 copper center resulted in a predicted increase in the redox potential of the copper center; however, there was a reduced specific activity for the oxidation of 2,6-dimethoxyphenol, which has a relatively low redox potential. Mutations more distant to the type 1 copper also led to an increased redox potential of the copper center, and resulted in variants able to oxidize the high redox potential substrates 1,2-dihydroxyanthraquinone-3-sulfonic acid (Alizarin Red S) and indigo carmine more efficiently than wild-type Ssl1.
The atomic coordinates of the structure of Ssl1 laccase from Streptomyces sviceus and structure factors have been deposited in the RCSB Protein Data Bank (4M3H) STRUCTURED DIGITAL ABSTRACT: •Ssl1 and Ssl1 bind by x-ray crystallography (View interaction).
漆酶(EC 1.10.3.2)是多铜氧化酶家族的成员。它们通过酶活性位点中的1型铜离子夺取电子来氧化各种富电子底物。夺取的电子被转移到三核铜簇,在那里分子氧作为最终受体并被还原为水。漆酶活性被认为取决于其1型铜离子的氧化还原电位。尽管已经进行了大量研究来阐明单结构域铜氧化还原蛋白和三结构域漆酶中1型铜离子氧化还原电位的决定因素,但对于最近描述的小型双结构域漆酶,此类实验研究尚缺。在这项工作中,解析了来自浅青紫链霉菌的小型漆酶Ssl1的晶体结构,并描绘了可能影响Ssl1氧化还原电位的位置。基于这些知识,构建了几个Ssl1变体,其氧化还原电位从375 mV增加到391 - 456 mV,增加了16 - 81 mV。靠近1型铜中心的残基突变导致铜中心氧化还原电位的预测增加;然而,对于氧化还原电位相对较低的2,6 - 二甲氧基苯酚,其比活性降低。与1型铜距离更远的突变也导致铜中心氧化还原电位增加,并产生了比野生型Ssl1更能有效氧化高氧化还原电位底物1,2 - 二羟基蒽醌 - 3 - 磺酸(茜素红S)和靛蓝胭脂红的变体。
来自浅青紫链霉菌的Ssl1漆酶结构的原子坐标和结构因子已存入RCSB蛋白质数据库(4M3H) 结构化数字摘要:•通过X射线晶体学解析Ssl1和Ssl1的结合(查看相互作用)。
