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Understanding and Circumventing the Requirement for Native Thioester Substrates for α-Oxoamine Synthase Reactions

Sarah E. Ackenhusen, Ye Wang, Stephanie W. Chun, Alison R. H. Narayan

2022ACS Chemical Biology11 citationsDOIOpen Access PDF

Abstract

Many enzyme classes require thioester electrophiles such as acyl-carrier proteins and acyl-coenzyme A substrates. For in vitro applications, these substrates can render these chemical transformations impractical. To address this challenge, we have investigated the mechanism of coenzyme A in gating catalysis of one α-oxoamine synthase, SxtA AOS. Through investigating the reactivity of SxtA AOS and corresponding enzyme variants against a panel of substrates and coenzyme A mimics, we determined that activity is gated through the binding of the pantetheine arm and a phosphate group that hydrogen bonds to residue Lys154 that is predicted by an AlphaFold2 model to be located in a tunnel leading to the active site. To provide an economical solution for preparative-scale reactions, in situ transthioesterification was used with pantetheine and simple thioester substrate precursors, resulting in productive reactions. These findings outline a strategy for employing ACP- and CoA-dependent enzymes that are inaccessible through other means without the need for cost-prohibitive coenzyme A or carrier protein-activated substrates.

Topics & Concepts

ThioesterCoenzyme AElectrophileEnzymeChemistryCombinatorial chemistryBiochemistryResidue (chemistry)Enzyme catalysisSubstrate (aquarium)StereochemistryCofactorATP synthaseActive siteCatalysisBiologyReductaseEcologyNeurological diseases and metabolismBiochemical and Molecular ResearchBiochemical Acid Research Studies