植物和真菌漆酶中T1铜位点的还原热力学

Reduction thermodynamics of the T1 Cu site in plant and fungal laccases.

作者信息

Battistuzzi Gianantonio, Bellei Marzia, Leonardi Alan, Pierattelli Roberta, De Candia Ariel, Vila Alejandro J, Sola Marco

机构信息

Department of Chemistry-Centro SCS, University of Modena and Reggio Emilia, Via Campi 183, 41100, Modena, Italy.

出版信息

J Biol Inorg Chem. 2005 Dec;10(8):867-73. doi: 10.1007/s00775-005-0035-z. Epub 2005 Oct 18.

DOI:10.1007/s00775-005-0035-z

PMID:16231129

Abstract

The thermodynamic parameters for reduction of the type-1 (T1) copper site in Rhus vernicifera and Trametes versicolor laccases and for the derivative of the former protein from which the type-2 copper has been selectively removed (T2D) have been determined with UV-vis spectroelectrochemistry. In all cases, the enthalpic term turns out to be the main determinant of the Eo' of the T1 site. Also the difference between the reduction potentials of the two laccases is enthalpy-based and reflects differences in the coordination features of the T1 sites and their protein environment. The T1 sites in native R. vernicifera laccase and its T2D derivative show the same Eo', as a result of compensatory differences in the reduction thermodynamics. This suggests that removal of the type-2 (T2) copper results in modification of the reduction-induced solvent reorganization effects, with no influence in the structure of the multicopper protein site. This conclusion is supported by NMR data recorded on the native, the T2D, and Hg-substituted T1 derivatives of R. vernicifera laccase, which show that the T1 and T2/T3 sites are largely noninteracting.

摘要

利用紫外可见光谱电化学法测定了漆树漆酶和云芝漆酶中1型（T1）铜位点的还原热力学参数，以及选择性去除2型铜后的前一种蛋白质衍生物（T2D）的还原热力学参数。在所有情况下，焓项都是T1位点Eo'的主要决定因素。两种漆酶还原电位的差异也是基于焓的，反映了T1位点及其蛋白质环境配位特征的差异。由于还原热力学的补偿差异，天然漆树漆酶及其T2D衍生物中的T1位点显示出相同的Eo'。这表明去除2型（T2）铜会导致还原诱导的溶剂重组效应发生改变，而对多铜蛋白位点的结构没有影响。漆树漆酶的天然、T2D和汞取代T1衍生物的核磁共振数据支持了这一结论，这些数据表明T1和T2/T3位点在很大程度上是不相互作用的。

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植物和真菌漆酶中T1铜位点的还原热力学

Reduction thermodynamics of the T1 Cu site in plant and fungal laccases.

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