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Discovering a uniform functional trade-off of the CBC-type 2,3-oxidosqualene cyclases and deciphering its chemical logic

Fan Zhang, Yunpeng Wang, Jingyang Yue, Rong-Rong Zhang, Yonger Hu, Ruoshi Huang, Ai-jia Ji, B. Andes Hess, Zhongqiu Liu, Lixin Duan, Ruibo Wu

2023Science Advances14 citationsDOIOpen Access PDF

Abstract

Many functionally promiscuous plant 2,3-oxidosqualene cyclases (OSCs) have been found, but complete functional reshaping is rarely reported. In this study, we have identified two new plant OSCs: a unique protostadienol synthase ( Ao PDS) and a common cycloartenol synthase ( Ao CAS) from Alisma orientale (Sam.) Juzep. Multiscale simulations and mutagenesis experiments revealed that threonine-727 is an essential residue responsible for protosta-13 (17),24-dienol biosynthesis in Ao PDS and that the F726T mutant completely reshapes the native function of Ao CAS into a PDS function to yield almost exclusively protosta-13 (17),24-dienol. Unexpectedly, various native functions were uniformly reshaped into a PDS function by introducing the phenylalanine → threonine substitution at this conserved position in other plant and non-plant chair-boat-chair–type OSCs. Further computational modeling elaborated the trade-off mechanisms of the phenylalanine → threonine substitution that leads to the PDS activity. This study demonstrates a general strategy for functional reshaping by using a plastic residue based on the decipherment of the catalytic mechanism.

Topics & Concepts

ThreonineATP synthaseResidue (chemistry)PhenylalanineFunction (biology)BiochemistryBiologyMutantComputational biologyAmino acidPhosphorylationSerineCell biologyEnzymeGenePlant biochemistry and biosynthesisPlant Gene Expression AnalysisMicrobial Natural Products and Biosynthesis
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