Direct electron transfer from graphite and functionalized gold electrodes to T1 and T2/T3 copper centers of bilirubin oxidase

Abstract: Direct electron transfer (DET) from bare spectrographic graphite (SPGE) or 3-mercaptopropionic acid-modified gold (MPA-gold) electrodes to Trachyderma tsunodae bilirubin oxidase (BOD) was studied under anaerobic and aerobic conditions by cyclic voltammetry and chronoamperometry. On cyclic voltammograms nonturnover Faradaic signals with midpoint potentials of about 700 mV and 400 mV were clearly observed corresponding to redox transformations of the T1 site and the T2/T3 cluster of the enzyme, respectively. The… Show more

“…[48] This suggests that the electrode can be recognized as the primary electron donor to the MCOs, and can provide direct access to the potential values for the T1 Cu centers (Table 1). [41,47,[49][50][51][52][53] The Cu II /Cu I transition of the T1 center for plant and fungal LACs are determined to be between + 0.22 and + 0.58 V vs. Ag/AgCl. [45] According to this potential, LACs are classified in low, middle, or high redox potential enzymes, the latter being the most interesting for applications in EBFCs.…”

“…[42][43] Noncatalytic voltametric signatures of MCOs in the absence of O 2 were difficult to assign, especially on gold electrodes, because of some discrepancy between the cyclic voltammetry (CV) potentials and the potential at which O 2 reduction occurred. [44][45][46][47] A mutant of Myrothecium verrucaria (Mv) BOD, displaying a lower Cu T1 redox potential, was however shown to catalyze O 2 reduction at a lower poten- CHEMELECTROCHEM REVIEWS www.chemelectrochem.org tial than the wild type. [48] This suggests that the electrode can be recognized as the primary electron donor to the MCOs, and can provide direct access to the potential values for the T1 Cu centers (Table 1).…”

“…Potential values for T2 and T3 centers are more difficult to evaluate because of the many intermediates with different geometries and oxidation states that are generated in the course of O 2 reduction. [47,52,[58][59][60] Some works however reported multiple noncatalytic redox waves for MCOs in the range + 0.2 to + 0.4 V vs. Ag/AgCl, most probably because of a different enzyme orientation depending on the electrode material. [47,[61][62] At least one of these processes might be attributed to a trinuclear cluster intermediate.…”

“…[47,52,[58][59][60] Some works however reported multiple noncatalytic redox waves for MCOs in the range + 0.2 to + 0.4 V vs. Ag/AgCl, most probably because of a different enzyme orientation depending on the electrode material. [47,[61][62] At least one of these processes might be attributed to a trinuclear cluster intermediate. [41,47,[63][64] An uphill intramolecular electron transfer was thus proposed, which was confirmed both by electrochemistry and quantum and molecular mechanical calculations.…”

Biohydrogen for a New Generation of H₂/O₂ Biofuel Cells: A Sustainable Energy Perspective

“…[48] This suggests that the electrode can be recognized as the primary electron donor to the MCOs, and can provide direct access to the potential values for the T1 Cu centers (Table 1). [41,47,[49][50][51][52][53] The Cu II /Cu I transition of the T1 center for plant and fungal LACs are determined to be between + 0.22 and + 0.58 V vs. Ag/AgCl. [45] According to this potential, LACs are classified in low, middle, or high redox potential enzymes, the latter being the most interesting for applications in EBFCs.…”

“…[42][43] Noncatalytic voltametric signatures of MCOs in the absence of O 2 were difficult to assign, especially on gold electrodes, because of some discrepancy between the cyclic voltammetry (CV) potentials and the potential at which O 2 reduction occurred. [44][45][46][47] A mutant of Myrothecium verrucaria (Mv) BOD, displaying a lower Cu T1 redox potential, was however shown to catalyze O 2 reduction at a lower poten- CHEMELECTROCHEM REVIEWS www.chemelectrochem.org tial than the wild type. [48] This suggests that the electrode can be recognized as the primary electron donor to the MCOs, and can provide direct access to the potential values for the T1 Cu centers (Table 1).…”

“…Potential values for T2 and T3 centers are more difficult to evaluate because of the many intermediates with different geometries and oxidation states that are generated in the course of O 2 reduction. [47,52,[58][59][60] Some works however reported multiple noncatalytic redox waves for MCOs in the range + 0.2 to + 0.4 V vs. Ag/AgCl, most probably because of a different enzyme orientation depending on the electrode material. [47,[61][62] At least one of these processes might be attributed to a trinuclear cluster intermediate.…”

“…[47,52,[58][59][60] Some works however reported multiple noncatalytic redox waves for MCOs in the range + 0.2 to + 0.4 V vs. Ag/AgCl, most probably because of a different enzyme orientation depending on the electrode material. [47,[61][62] At least one of these processes might be attributed to a trinuclear cluster intermediate. [41,47,[63][64] An uphill intramolecular electron transfer was thus proposed, which was confirmed both by electrochemistry and quantum and molecular mechanical calculations.…”

Biohydrogen for a New Generation of H₂/O₂ Biofuel Cells: A Sustainable Energy Perspective

“…Detailed fundamental bioelectrochemical investigations of BMCO were performed using various planar electrodes [14]. It was discovered that carbon was superior, providing efficient O 2 bioelectroreduction at high potentials, whereas DET-based bioelectrocatalysis at metal electrodes seems to be much more complicated [20][21][22]. Thus, regarding the very efficient and stable BMCO-based biocathodes assembled and characterised so far, carbonaceous electrodes are preferred (e.g.…”

Stable ‘Floating' Air Diffusion Biocathode Based on Direct Electron Transfer Reactions Between Carbon Particles and High Redox Potential Laccase

Molecular Properties and Reaction Mechanism of Multicopper Oxidases Related to Their Use in Biofuel Cells