真菌黄素依赖卤化酶对异喹啉的特异性氯化。
Specific chlorination of isoquinolines by a fungal flavin-dependent halogenase.
机构信息
Department of Biological Engineering, Utah State University, 4105 Old Main Hill, Logan, UT 84322, USA.
出版信息
Bioorg Med Chem Lett. 2013 Feb 15;23(4):1001-3. doi: 10.1016/j.bmcl.2012.12.038. Epub 2012 Dec 21.
Abstract
Rdc2 is the first flavin-dependent halogenase identified from fungi. Based on the reported structure of the bacterial halogenase CmlS, we have built a homology model for Rdc2. The model suggests an open substrate binding site that is capable of binding the natural substrate, monocillin II, and possibly other molecules such as 4-hydroxyisoquinoline (1) and 6-hydroxyisoquinoline (2). In vitro and in vivo halogenation experiments confirmed that 1 and 2 can be halogenated at the position ortho to the hydroxyl group, leading to the synthesis of the chlorinated isoquinolines 1a and 2a, respectively, which further expands the spectrum of identified substrates of Rdc2. This work revealed that Rdc2 is a useful biocatalyst for the synthesis of various halogenated compounds.
摘要
Rdc2 是首个从真菌中鉴定出的黄素依赖型卤化酶。根据已报道的细菌卤化酶 CmlS 的结构,我们构建了 Rdc2 的同源模型。该模型显示了一个开放的底物结合位点,能够结合天然底物单胞菌素 II,并且可能还能够结合其他分子,如 4-羟基异喹啉(1)和 6-羟基异喹啉(2)。体外和体内卤化实验证实,1 和 2 可以在羟基的邻位被卤化,分别生成氯化异喹啉 1a 和 2a,这进一步扩展了 Rdc2 鉴定出的底物范围。这项工作表明,Rdc2 是合成各种卤化化合物的有用生物催化剂。
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