Investigating Metalloenzyme Reactions Using Electrochemical Sweeps and Steps:  Fine Control and Measurements with Reactants Ranging from Ions to Gases

Abstract: Protein film voltammetry is a powerful method for probing the chemistry of redox-active sites in metalloproteins. The technique affords precise potential control over a tiny quantity of material that is manipulated on an electrode surface, providing information on ligand- or metal-exchange reactions coupled to electron transfer. This is illustrated by examples of transformations of the iron-sulfur clusters in ferredoxins. Protein film voltammetry is particularly advantageous in studies of metalloenzymes for wh… Show more

“…A higher anode potential might induce damage of the enzymes that are used for electron transfer, as enzymes have a maximum activity at a particular potential [22]. After operation at 100 , however, the polarization curves did show a limiting current, but no maximum (Fig.…”

Performance of non-porous graphite and titanium-based anodes in microbial fuel cells

“…A higher anode potential might induce damage of the enzymes that are used for electron transfer, as enzymes have a maximum activity at a particular potential [22]. After operation at 100 , however, the polarization curves did show a limiting current, but no maximum (Fig.…”

Performance of non-porous graphite and titanium-based anodes in microbial fuel cells

“…In some favorable cases, the electrochemical surface may actually mimic the charged membranes where many biological processes occur; in this case, observing a discrepancy between the two techniques does not necessarily mean that the reduction potential measured in the potentiometric titration is more relevant. 52 Flavocytochrome c 3 (fcc3) is a soluble fumarate reductase that houses a flavin active site and four c-type hemes in a single subunit (63.8kDa, pdb 1QJD). 312,313 The UV-vis spectrum of the FAD is masked by the intense bands from the four hemes; with the enzyme adsorbed at a PGE electrode, the FAD noncatalytic signal is easily distinguished as a sharp peak (small δ in eq 3 or n app > 1 in eq 5) above the four broader n ) 1 signals which span 300 mV.…”

Direct Electrochemistry of Redox Enzymes as a Tool for Mechanistic Studies

“…24 The rates and strengths of binding of an inhibitor are thus addressable as a precise function of potential during steady-state catalysis, and this allows the particular redox level of the enzyme that is being targeted to be identified. Importantly, information on enzyme activity is easily obtained at potentials well below those commonly accessed by chemical mediators and titrants, which is essential when studying an enzyme able to catalyze CO 2 reduction, which requires potentials more negative than −0.5 V. The fact that the enzyme is immobilized also allows inhibitors to be added and then removed, a procedure that is impractical in solution kinetics.…”

A Unified Electrocatalytic Description of the Action of Inhibitors of Nickel Carbon Monoxide Dehydrogenase