Manchester Institute of Biotechnology, The University of Manchester, 131 Princess Street, Manchester, M1 7DN, United Kingdom.
Department of Chemistry, The University of Manchester, Oxford Road, Manchester, M13 9PL, United Kingdom.
Chemistry. 2024 Nov 26;30(66):e202402604. doi: 10.1002/chem.202402604. Epub 2024 Oct 16.
The nonheme iron dioxygenase capreomycin C (CmnC) hydroxylates a free L-arginine amino acid regio- and stereospecifically at the C-position as part of the capreomycin antibiotics biosynthesis. Little is known on its structure, catalytic cycle and substrate specificity and, therefore, a comprehensive computational study was performed. A large QM cluster model of CmnC was created of 297 atoms and the mechanisms for C-H, C-H and C-H hydroxylation and C-C desaturation were investigated. All low-energy pathways correspond to radical reaction mechanisms with an initial hydrogen atom abstraction followed by OH rebound to form alcohol product complexes. The work is compared to alternative L-Arg hydroxylating nonheme iron dioxygenases and the differences in active site polarity are compared. We show that a tight hydrogen bonding network in the substrate binding pocket positions the substrate in an ideal orientation for C-H activation, whereby the polar groups in the substrate binding pocket induce an electric field effect that guides the selectivity.
非血红素铁双加氧酶卷曲霉素 C(CmnC)作为卷曲霉素抗生素生物合成的一部分,将游离的 L-精氨酸的 C 位上的氨基酸区域和立体特异性羟基化。目前对于其结构、催化循环和底物特异性知之甚少,因此进行了全面的计算研究。创建了一个由 297 个原子组成的 CmnC 大型 QM 簇模型,并研究了 C-H、C-H 和 C-H 羟化和 C-C 去饱和的机制。所有低能量途径都对应于自由基反应机制,其中首先进行氢原子的提取,然后 OH 反弹形成醇产物配合物。这项工作与替代的 L-Arg 羟基化非血红素铁双加氧酶进行了比较,并比较了活性位点极性的差异。我们表明,在底物结合口袋中形成的紧密氢键网络将底物定位在 C-H 活化的理想取向,其中底物结合口袋中的极性基团诱导电场效应,从而引导选择性。
