Maura Fabbrini

Comparing the catalytic efficiency of some mediators of laccase

The mechanism of oxidation of non-phenolic substrates by laccase/mediators systems has been investigated. Oxidation of 4-methoxybenzyl alcohol (1), taken as a benchmark reaction, enabled us to compare and to rank the relative ability of twelve mediators: TEMPO proved most effective, and a ionic mechanism is suggested for its action. Data on intermolecular selectivity of substrate oxidation are in favour of an electron transfer (ET) mechanism in the case of ABTS-mediated oxidations, and of a radical mechanism in HBT- and HPI-mediated reactions. Investigation by cyclic voltammetry (CV) of some of the mediators revealed that an important role in determining the mechanism of substrate oxidation may be played by the stability of the oxidised form of the mediator, as well as by its redox potential.

Promoting laccase activity towards non-phenolic substrates: a mechanistic investigation with some laccase–mediator systems

The oxidation of benzyl alcohols with the enzyme laccase, under mediation by appropriate mediator compounds, yields carbonylic products, whereas laccase can not oxidise these non-phenolic substrates directly. The oxidation step is performed by the oxidised form of the mediator (Med(ox)), generated on its interaction with laccase. The Med(ox) can follow either an electron transfer (ET) or a radical hydrogen atom transfer (HAT) route of oxidation of the substrates. Experimental evidence is reported that enables unambiguous assessment of the occurrence of either one the oxidation routes with each of the investigated mediators, namely, ABTS, HBT, HPI and VLA. Support to the conclusions is provided by (i) investigating the intermolecular selectivity of oxidation with appropriate substrates, (ii) attempting Hammett correlations for the oxidation of a series of 4-X-substituted benzyl alcohols, (iii) measuring the kinetic isotope effect, (iv) investigating the product pattern with suitable probe precursors. Based on these points, a HAT mechanism results to be followed by the laccase-HBT, laccase-HPI and laccase-VLA systems, whereas an ET route appears feasible in the case of the laccase-ABTS system.

An oxidation of alcohols by oxygen with the enzyme laccase and mediation by TEMPO

Abstract A simple and efficient oxidation of alcohols to carbonyl compounds by oxygen at room temperature is described; it requires the laccase/TEMPO mediator system as the catalyst. A possible mechanistic explanation is provided.

A Mechanistic Survey of the Oxidation of Alcohols and Ethers with the Enzyme Laccase and Its Mediation by TEMPO

The oxidation of alcohols and ethers by O2 with the enzyme laccase, mediated by the stable N-oxyl radical TEMPO, affords carbonylic products. An ionic mechanism is proposed, where a nucleophilic attack of the oxygen lone-pair of the alcohol (or ether) onto the oxoammonium form of TEMPO (generated by laccase on oxidation) takes place leading to a transient adduct. Subsequent deprotonation of this adduct α

The radical rate-determining step in the oxidation of benzyl alcohols by two N–OH-type mediators of laccase: the polar N-oxyl radical intermediate

Determination of the effect of substituents in the aerobic oxidation of X-substituted benzyl alcohols by laccase, with mediation by HPI or HBT, confirms the H-atom abstraction from the benzylic C–H bond as the rate-determining step (HAT route), and supports a polar nature for the N-oxyl radical intermediate originating from the two N–OH mediators.

Catalytic Efficiency of some Mediators in Laccase-Catalyzed Alcohol Oxidation

The enzyme laccase oxidises phenolic groups of lignin but not the non-phenolic ones. Redox mediators activate laccase towards the non-phenolic groups, particularly the benzyl alcohols. The oxidation step is performed by the oxidised form of the mediator, generated on its interaction with laccase. The oxidised mediator can follow an electron transfer, a radical hydrogen atom transfer or an ionic mechanism in the oxidation of the non-phenolic subunits. Support for these conclusions is provided by (i) investigating the product pattern with suitable probe substrates, (ii) measuring the intramolecular kinetic isotope effect. Determination of electrochemical properties and bond dissociation energies via semiempirical calculations enabled us to rationalise the origin of the different mechanistic behaviour of the mediators. Finally, a comparison of different laccase-mediator-systems (LMS), when applied to the delignification of wood pulp, indicates violuric acid as the most efficient mediator, in an oxidation that is selectively directed towards lignin only.