Issue 19, 2012

Hydroxylation mechanism of methane and its derivatives over designed methane monooxygenase model with peroxo dizinc core

Abstract

The peroxo dizinc Zn2O2 complex Q coordinated by imidazole and carboxylate groups for each Zn center has been designed to model the hydroxylase component of methane monooxygenase (MMO) enzyme, on the basis of the experimentally available structure information of enzyme with divalent zinc ion and the MMO with Fe2O2 core. The reaction mechanism for the hydroxylation of methane and its derivatives catalyzed by Q has been investigated at the B3LYP*/cc-pVTZ, Lanl2tz level in protein solution environment. These hydroxylation reactions proceed via a radical-rebound mechanism, with the rate-determining step of the C–H bond cleavage. This radical-rebound reaction mechanism is analogous to the experimentally available MMOs with diamond Fe2O2 core accompanied by a coordinate number of six for the hydroxylation of methane. The rate constants for the hydroxylation of substrates catalyzed by Q increase along CH4 < CH3F < CH3CN ≈ CH3NO2 < CH3CH3. Both the activation strain ΔEstrain and the stabilizing interaction ΔEint jointly affect the activation energy ΔE. For the C–H cleavage of substrate CH3X, with the decrease of steric shielding for the substituted CH3X (X = F > H > CH3 > NO2 > CN) attacking the O center in Q, the activation strain ΔEstrain decreases, whereas the stabilizing interaction ΔEint increases. It is predicted that the MMO with peroxo dizinc Zn2O2 core should be a promising catalyst for the hydroxylation of methane and its derivatives.

Graphical abstract: Hydroxylation mechanism of methane and its derivatives over designed methane monooxygenase model with peroxo dizinc core

Supplementary files

Article information

Article type
Paper
Submitted
20 Jan 2012
Accepted
13 Mar 2012
First published
15 Mar 2012

Org. Biomol. Chem., 2012,10, 3924-3931

Hydroxylation mechanism of methane and its derivatives over designed methane monooxygenase model with peroxo dizinc core

C. Li, H. Yang, J. Xu and C. Hu, Org. Biomol. Chem., 2012, 10, 3924 DOI: 10.1039/C2OB25163A

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