A voltammetric study of nitrogenase MoFe-protein using low-potential electron transfer mediators

The molybdenum-iron protein (MoFeP), a component of the enzyme nitrogenase, catalyzes the reduction of an array of small molecules, including N2 to NH3. In microorganisms, during the catalytic cycle, MoFeP receives electrons from the obligate biological redox partner iron protein (FeP) in a process coupled to the hydrolysis of two MgATP per one electron transferred. Despite the favorable redox properties of the cofactors, the requirement of the MgATP hydrolysis significantly decreases the energy efficiency of MoFeP. Therefore, remarkable efforts have been devoted to electrochemically activating MoFeP without FeP and MgATP. Previously, MoFeP was adsorbed on an electrode surface and revealed a slow catalysis with and without electron transfer mediators. However, enzyme adsorption can cause conformational and structural changes in a fragile protein molecule and alter its catalytic activity. In this work, MoFeP was electrochemically studied in solution. Various electron transfer mediators with potentials ranging from -0.3 V to -1 V (vs. NHE) were examined with MoFeP using cyclic voltammetry. No significant catalytic activity of the MoFeP was observed with any of the tested mediators. This indicates that efficient electrochemical activation of MoFeP cannot be achieved exclusively by increasing the driving force between the MoFeP redox cofactors and an electron donor.

Automated summary

The molybdenum-iron protein (MoFeP) is a component of the enzyme nitrogenase and can catalyze the reduction of various small molecules. However, it has been found that increasing the driving force alone cannot achieve efficient electrochemical activation of MoFeP.