A hybrid biofuel cell has been constructed based on the Zn anode and O-2 biocathode, exploiting fungal Cerrena maxima and Choriolus hirsutus laccases cross-linked onto graphite and microstructured graphitized carbon cloth (GCC) electrodes. Immobilized at the graphite electrodes, laccases exhibited a high similarity in the reaction of direct (in the absence of any mediators) bioelectrocatalytic reduction of O-2 starting from 0.7 V vs. Ag/AgCl, pH 5, which was consistent with a 94% structural homology of the laccases. The efficiency of the bioelectrocatalytic reaction was enhanced by immobilizing laccases on the high-surface area GCC, due to the increased surface concentration of the laccase molecules properly orientated for the direct electron transfer reaction within the micro-structured electrode. The hybrid biofuel cell, based on the battery-type Zn anode and oxygen laccase/GCC biocathode yielded the open-circuit voltage V-oc of 1.76 V and the short-circuit current density j(sc) of 4 mA cm(-2) in quiescent aerated solutions. A maximum power density of the cell was 0.44 mW cm(-2) at the cell voltage of 0.5V, pH 5. The hybrid biofuel cell exploiting cross-linked stabilized laccases at GCC was able to power a 1.5 V domestic device for 38 days. (C) 2011 Elsevier Ltd. All rights reserved.