Magnetic studies of the trinuclear center in laccase and ascorbate oxidase approached by EPR spectroscopy and magnetic susceptibility measurements.

The trinuclear centers in Rhus vernicifera laccase and Cucumis sativus ascorbate oxidase have been studied by EPR spectroscopy and magnetic susceptibility measurements over the wide range of 5 K to 300 K. The EPR spectra showed that type II copper receives increasing tetrahedral distortion with raising temperature. Magnetic susceptibilities of laccase showed that both of type I and type II coppers are almost fully paramagnetic since the antiferromagnetic interaction between type III coppers is extremely strong from 5 K to 300 K. On the other hand, the effective magnetic moment of ascorbate oxidase is contributed by ca. 1.7 Cu2+ even below ca. 100 K, since type II Cu is partly in the reduced form. The effective magnetic moment continuously increased with raising temperature because the antiferromagnetic interaction between type III coppers is not as strong as in the case of laccase. The simulation of the SQUID measurement results suggested that the conformational change of the ascorbate oxidase molecule caused the temperature dependence of the antiferromagnetic interaction. The type II Cu EPR signals in laccase and ascorbate oxidase were conspicuously broadened with raising temperature because of the increasing contribution of the triplet state by type III Cu's and/or of the rapid relaxation which finally led to only ca. 30% detection of the type II Cu signals at room temperature. The stepwise binding of azide to the trinuclear center made one of type III Cu's to be EPR detectable. SQUID measurements indicated that only one Cu in the trinuclear center is paramagnetic and other two Cu's are antiferromagnetically coupled for both of the one- and two-azide bound forms. The binding mode of azide to the trinuclear center was discussed based on some models.