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Mechanistically informed predictions of binding modes for carbocation intermediates of a sesquiterpene synthase reaction.


ABSTRACT: Sesquiterpenoids comprise a class of terpenoid natural products with thousands of compounds that are highly diverse in structure, generally containing a polycyclic carbon backbone that is constructed by a sesquiterpene synthase. Decades of experimental and computational studies have demonstrated that these enzymes generate a carbocation in the active site, which undergoes a series of structural rearrangements until a product is formed via deprotonation or nucleophile attack. However, for the vast majority of these enzymes the productive binding orientation of the intermediate carbocations has remained unclear. In this work, a method that combines quantum mechanics and computational docking is used to generate an all-atom model of every putative intermediate formed in the context of the enzyme active site for tobacco epi-aristolochene synthase (TEAS). This method identifies a single pathway that links the first intermediate to the last, enabling us to propose the first high-resolution model for the reaction intermediates in the active site of TEAS, and providing testable predictions.

SUBMITTER: O'Brien TE 

PROVIDER: S-EPMC6013805 | biostudies-literature | 2016 Jul

REPOSITORIES: biostudies-literature

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Mechanistically informed predictions of binding modes for carbocation intermediates of a sesquiterpene synthase reaction.

O'Brien T E TE   Bertolani S J SJ   Tantillo D J DJ   Siegel J B JB  

Chemical science 20160321 7


Sesquiterpenoids comprise a class of terpenoid natural products with thousands of compounds that are highly diverse in structure, generally containing a polycyclic carbon backbone that is constructed by a sesquiterpene synthase. Decades of experimental and computational studies have demonstrated that these enzymes generate a carbocation in the active site, which undergoes a series of structural rearrangements until a product is formed <i>via</i> deprotonation or nucleophile attack. However, for  ...[more]

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