Copper inactivates DcsB by oxidizing the metal ligand Cys86 to sulfinic acid.

Kosuke Oda, Kenji Komaguchi, Yasuyuki Matoba
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Abstract

Nω-hydroxy-l-arginine amidinohydrolase (EC:3.5.3.25), an enzyme in the d-cycloserine (d-CS) biosynthetic pathway of Streptomyces lavendulae, catalyzes the hydrolysis of an arginase inhibitor, Nω-hydroxy-l-arginine, to produce l-ornithine and hydroxyurea, despite being homologous to arginase. Like arginase, the enzyme (DcsB) possesses two manganese ions (MnA and MnB) essential for the enzymatic reaction at the bottom of the cavity formed within the molecule. However, one of the MnA ligands in DcsB is Cys86, whereas the corresponding residues in arginase are histidine. In this study, we determined the crystal structure of Mn-free DcsB to elucidate the installation mechanism of the manganese ions. The flipping of the His111 residue after the formation of the coordination bond to the second manganese ion may facilitate the installation of MnB and the closing of the cavity entrance to retain MnA and MnB at the active site. Copper ions, which are known to be a positive regulator of many secondary metabolites in Streptomyces species, were found to irreversibly inactivate the catalytic activity of DcsB. Mass spectrometric and crystallographic analyses of the Cu(II)-treated DcsB indicated that Cys86 is oxidized to sulfinic acid. The d-CS biosynthesis in the producing microorganism may be negatively regulated by the concentration of intracellular copper ions, which mediates the oxidative stress.

铜通过将金属配体 Cys86 氧化为亚硫酸,使 DcsB 失活。
Nω-hydroxy-l-arginine amidohydrolase(EC:3.5.3.25)是链霉菌(Streptomyces lavendulae)d-环丝氨酸(d-CS)生物合成途径中的一种酶,它催化精氨酸酶抑制剂 Nω-hydroxy-l-arginine 的水解,生成 l-ornithine 和羟基脲,尽管它与精氨酸酶同源。与精氨酸酶一样,这种酶(DcsB)在分子内形成的空腔底部也具有酶促反应所必需的两个锰离子(MnA 和 MnB)。不过,DcsB 中的 MnA 配体之一是 Cys86,而精氨酸酶中的相应残基是组氨酸。在这项研究中,我们测定了无锰 DcsB 的晶体结构,以阐明锰离子的安装机制。在与第二个锰离子形成配位键后,His111残基的翻转可能促进了MnB的安装和空腔入口的关闭,从而将MnA和MnB保留在活性位点。众所周知,铜离子是链霉菌中许多次级代谢产物的正向调节剂,研究发现铜离子会不可逆地使 DcsB 的催化活性失活。经 Cu(II)处理的 DcsB 的质谱和晶体学分析表明,Cys86 被氧化为亚硫酸。生产微生物的 d-CS 生物合成可能受到细胞内铜离子浓度的负向调节,铜离子浓度介导了氧化应激。
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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