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Catalytic mechanism and pH dependence of a methyltransferase ribozyme (MTR1) from computational enzymology

Erika McCarthy, Şölen Ekesan, Timothy J. Giese, Timothy J. Wilson, Jie Deng, Lin Huang, David M.J. Lilley, Darrin M. York

2023Nucleic Acids Research17 citationsDOIOpen Access PDF

Abstract

A methyltransferase ribozyme (MTR1) was selected in vitro to catalyze alkyl transfer from exogenous O6-methylguanine (O6mG) to a target adenine N1, and recently, high-resolution crystal structures have become available. We use a combination of classical molecular dynamics, ab initio quantum mechanical/molecular mechanical (QM/MM) and alchemical free energy (AFE) simulations to elucidate the atomic-level solution mechanism of MTR1. Simulations identify an active reactant state involving protonation of C10 that hydrogen bonds with O6mG:N1. The deduced mechanism involves a stepwise mechanism with two transition states corresponding to proton transfer from C10:N3 to O6mG:N1 and rate-controlling methyl transfer (19.4 kcal·mol-1 barrier). AFE simulations predict the pKa for C10 to be 6.3, close to the experimental apparent pKa of 6.2, further implicating it as a critical general acid. The intrinsic rate derived from QM/MM simulations, together with pKa calculations, enables us to predict an activity-pH profile that agrees well with experiment. The insights gained provide further support for a putative RNA world and establish new design principles for RNA-based biochemical tools.

Topics & Concepts

ProtonationRibozymeMolecular dynamicsTransfer RNAHydrogen bondMethyltransferaseBiologyComputational chemistryChemical physicsStereochemistryRNAChemistryMoleculeBiochemistryIonDNAMethylationOrganic chemistryGeneDNA and Nucleic Acid ChemistryRNA and protein synthesis mechanismsRNA modifications and cancer