与香叶醇复合的霍霍巴醇合酶揭示了萜烯环化酶的作用机制。

Hedycaryol synthase in complex with nerolidol reveals terpene cyclase mechanism.

机构信息

Center for Integrated Protein Science at the Department of Chemistry, Lehrstuhl für Biochemie, Technische Universität München, Lichtenbergstrasse 4, 85747 Garching (Germany).

出版信息

Chembiochem. 2014 Jan 24;15(2):213-6. doi: 10.1002/cbic.201300708. Epub 2014 Jan 7.

DOI:10.1002/cbic.201300708

PMID:24399794

Abstract

The biosynthesis of terpenes is catalysed by class I and II terpene cyclases. Here we present structural data from a class I hedycaryol synthase in complex with nerolidol, serving as a surrogate for the reaction intermediate nerolidyl diphosphate. This prefolded ligand allows mapping of the active site and hence the identification of a key carbonyl oxygen of Val179, a highly conserved helix break (G1/2) and its corresponding helix dipole. Stabilising the carbocation at the substrate's C1 position, these elements act in concert to catalyse the 1,10 ring closure, thereby exclusively generating the anti-Markovnikov product. The delineation of a general mechanistic scaffold was confirmed by site-specific mutations. This work serves as a basis for understanding carbocation chemistry in enzymatic reactions and should contribute to future application of these enzymes in organic synthesis.

摘要

萜类化合物的生物合成由 I 类和 II 类萜烯合酶催化。在这里，我们展示了与橙花叔醇复合的 I 类愈创木醇合酶的结构数据，橙花叔醇作为反应中间体橙花基二磷酸的替代物。这种预折叠配体允许对活性位点进行映射，从而确定关键的羰基氧 Val179、高度保守的螺旋断裂（G1/2）及其相应的螺旋偶极子。这些元素稳定了底物 C1 位的碳正离子，协同作用催化 1,10 环闭合，从而专一地生成反 Markovnikov 产物。通过定点突变证实了通用机制支架的描述。这项工作为理解酶促反应中的碳正离子化学提供了基础，并应有助于这些酶在有机合成中的未来应用。

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与香叶醇复合的霍霍巴醇合酶揭示了萜烯环化酶的作用机制。

Hedycaryol synthase in complex with nerolidol reveals terpene cyclase mechanism.

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