细菌肽脱甲酰基酶的催化机制和金属特异性：密度泛函理论QM/MM研究

Catalytic mechanism and metal specificity of bacterial peptide deformylase: a density functional theory QM/MM study.

作者信息

Xiao Chuanyun, Zhang Yingkai

机构信息

Department of Chemistry, New York University, New York, New York 10003, USA.

出版信息

J Phys Chem B. 2007 Jun 7;111(22):6229-35. doi: 10.1021/jp068657f. Epub 2007 May 16.

DOI:10.1021/jp068657f

PMID:17503802

Abstract

Bacterial peptide deformylase (PDF) represents a novel class of mononuclear iron peptidase, and has an intriguing metal preference different from most other metalloproteases. Using a hybrid density functional theory (B3LYP) QM/MM method, we have theoretically investigated its catalytic mechanism and metal specificity by studying both Fe2+-PDF and Zn2+-PDF. In both forms of PDF, the conserved Glu133 residue is protonated in the reactant complex, and acts as a general acid during the reaction. The initial reaction step is the nucleophilic attack of the metal-bound hydroxide on the carbonyl carbon of the substrate. Our calculations indicate that the metal ion in Fe2+-PDF is always pentacoordinated during the reaction process, while that in Zn2+-PDF is only tetrahedrally coordinated and not bound to the substrate in the reactant complex. This difference in their metal coordination is suggested to account for the lower activity of Zn2+-PDF in comparison with Fe2+-PDF.

摘要

细菌肽脱甲酰基酶（PDF）是一类新型的单核铁肽酶，具有与大多数其他金属蛋白酶不同的有趣金属偏好。我们使用混合密度泛函理论（B3LYP）量子力学/分子力学（QM/MM）方法，通过研究Fe2+-PDF和Zn2+-PDF，从理论上探究了其催化机制和金属特异性。在两种形式的PDF中，保守的Glu133残基在反应物复合物中被质子化，并在反应过程中作为广义酸。初始反应步骤是金属结合的氢氧根对底物羰基碳的亲核攻击。我们的计算表明，Fe2+-PDF中的金属离子在反应过程中始终是五配位的，而Zn2+-PDF中的金属离子仅为四面体配位，且在反应物复合物中不与底物结合。它们金属配位的这种差异被认为是Zn2+-PDF比Fe2+-PDF活性低的原因。

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细菌肽脱甲酰基酶的催化机制和金属特异性：密度泛函理论QM/MM研究

Catalytic mechanism and metal specificity of bacterial peptide deformylase: a density functional theory QM/MM study.

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