Chemoenzymatic Formation of Oxa-Terpenoids by Sesqui- and Diterpene Synthase-Mediated Biotransformations with 9-Oxy-FPP Ether Derivatives

Overview

Journal Biochemistry

Specialty Biochemistry

Date 2024 Dec 28

PMID 39731539

Authors

Henry Struwe

Trang Nguyen

Svenja Schworer

Jorn Droste

Hanke Spinck

Andreas Kirschning

Affiliations

Soon will be listed here.

Abstract

Farnesyl pyrophosphate derivatives bearing an additional oxygen atom at position 5 proved to be very suitable for expanding the substrate promiscuity of sesquiterpene synthases (STSs) and the formation of new oxygenated terpenoids. Insertion of an oxygen atom in position 9, however, caused larger restraints that led to restricted acceptance by STSs. In order to reduce some of the proposed restrictions, two FPP-ether derivatives with altered substitution pattern around the terminal olefinic double bond were designed. These showed improved promiscuity toward different STSs. Four new cyclized terpenoids with an embedded ether group were isolated and characterized. In the case of two cyclic enol ethers, also the corresponding "hydrolysis" products, linear hydroxyaldehydes, were isolated. Interestingly, all cyclization products originate from an initial 1 → 12 cyclization unprecedented when native farnesyl pyrophosphate serves as a substrate. We found that the most suitable FPP derivative with an additional oxygen at position 9 does not carry any methyl group on the terminal alkene, which likely reduces steric congestion when the preferred conformation for cyclization is adopted in the active site.

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