QM/MM study of the reaction mechanism of sulfite oxidase

Octav Caldararu,Milica Feldt,Marie-Céline Van Severen,Daniela Cioloboc,Ulf Ryde,Ebbe Nordlander,Kerstin Starke,Ricardo A Mata

doi:10.1038/s41598-018-22751-6

Octav Caldararu, Milica Feldt + Show 6 more

Open Access

https://doi.org/10.1038/s41598-018-22751-6

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Abstract

Sulfite oxidase is a mononuclear molybdenum enzyme that oxidises sulfite to sulfate in many organisms, including man. Three different reaction mechanisms have been suggested, based on experimental and computational studies. Here, we study all three with combined quantum mechanical (QM) and molecular mechanical (QM/MM) methods, including calculations with large basis sets, very large QM regions (803 atoms) and QM/MM free-energy perturbations. Our results show that the enzyme is set up to follow a mechanism in which the sulfur atom of the sulfite substrate reacts directly with the equatorial oxo ligand of the Mo ion, forming a Mo-bound sulfate product, which dissociates in the second step. The first step is rate limiting, with a barrier of 39–49 kJ/mol. The low barrier is obtained by an intricate hydrogen-bond network around the substrate, which is preserved during the reaction. This network favours the deprotonated substrate and disfavours the other two reaction mechanisms. We have studied the reaction with both an oxidised and a reduced form of the molybdopterin ligand and quantum-refinement calculations indicate that it is in the normal reduced tetrahydro form in this protein.

Highlights

Molybdenum (Mo) is the only second-row transition metal that is used in biological systems[1]
Sarkar and coworkers have suggested that sulfite first coordinates to the Mo ion with one of the oxygen atoms, before it reacts with the oxo group (O → Mo mechanism)[14,15]
We have studied the reaction mechanism of sulfite oxidase with quantum mechanical (QM)/MM methods

Summary

Introduction

Molybdenum (Mo) is the only second-row transition metal that is used in biological systems[1]. Sarkar and coworkers have suggested that sulfite first coordinates to the Mo ion with one of the oxygen atoms, before it reacts with the oxo group (O → Mo mechanism)[14,15]. They showed that a functional inorganic model of SO showed saturation kinetics (in contrast to other oxygen acceptors, e.g. phosphines and phosphites16), indicating that an enzyme–substrate complex is formed before the new S–O bond is formed. It has been suggested that sulfite may instead coordinate to Mo by the sulfur atom, before it reacts (S → Mo mechanism)[20]

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