Probing the influence of non-covalent contact networks identified by charge density analysis on the oxidoreductase BacC

Protein Engineering, Design and Selection Pub Date : 2017-03-01 DOI:10.1093/protein/gzx006

K. Perinbam, H. Balaram, T. N. Guru Row, B. Gopal

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引用次数: 4

Abstract

Bacillus subtilis BacC is an oxidoreductase involved in the biosynthesis of the potent antibiotic bacilysin. The crystal structure of BacC was determined at 1.19 Å resolution. An experimental charge density approach was used to calculate non-covalent interactions within the monomer and across the dimeric interface of BacC. This interaction network, in turn, enabled an analysis of non-covalently connected paths that span the protein structure. One of the pathways of non-covalent interactions was examined by mutational analysis. Biochemical analysis of BacC mutants with potential disruptions in non-covalent interactions along this path revealed that residues that form nodes in pathways of non-covalent interactions influence catalytic activity more than others in a similar chemical environment. Furthermore, we note that nodes in the non-covalent interaction networks are co-localized with compensatory mutation sites identified by multiple sequence alignment of proteins with low sequence similarity to BacC. Put together, this analysis supports the hypothesis that non-covalent nodes represent conserved structural features that can impact the catalytic activity of an enzyme.

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探讨电荷密度分析鉴定的非共价接触网络对氧化还原酶BacC的影响

枯草芽孢杆菌BacC是一种氧化还原酶，参与强效抗生素杆菌素的生物合成。在1.19 Å分辨率下测定BacC的晶体结构。采用实验电荷密度方法计算了单体内和二聚体界面间的非共价相互作用。这种相互作用网络反过来又使跨蛋白质结构的非共价连接路径的分析成为可能。通过突变分析研究了非共价相互作用的途径之一。对沿该路径的非共价相互作用潜在中断的BacC突变体的生化分析表明，在非共价相互作用途径中形成节点的残基比类似化学环境中的其他残基更能影响催化活性。此外，我们注意到，非共价相互作用网络中的节点与与BacC序列相似性低的蛋白质的多序列比对鉴定的补偿性突变位点共定位。综上所述，这一分析支持了非共价节点代表可以影响酶催化活性的保守结构特征的假设。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Protein Engineering, Design and Selection

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