Electrochemical Characterization of Isolated Nitrogenase Cofactors from Azotobacter vinelandii.

The nitrogenase cofactors are structurally and functionally unique in biological chemistry. Despite a substantial amount of spectroscopic characterization of protein-bound and isolated nitrogenase cofactors, electrochemical characterization of these cofactors and their related species is far from complete. Herein we present voltammetric studies of three isolated nitrogenase cofactor species: the iron-molybdenum cofactor (M-cluster), iron-vanadium cofactor (V-cluster), and a homologue to the iron-iron cofactor (L-cluster). We observe two reductive events in the redox profiles of all three cofactors. Of the three, the V-cluster is the most reducing. The reduction potentials of the isolated cofactors are significantly more negative than previously measured values within the molybdenum-iron and vanadium-iron proteins. The outcome of this study provides insight into the importance of the heterometal identity, the overall ligation of the cluster, and the impact of the protein scaffolds on the overall electronic structures of the cofactors.

A V-Nitrogenase Variant Containing a Citrate-Substituted Cofactor.

Nitrogenases catalyze the ambient reduction of N2 and CO at its cofactor site. Herein we present a biochemical and spectroscopic characterization of an Azotobacter vinelandii V nitrogenase variant expressing a citrate-substituted cofactor. Designated VnfDGKCit , the catalytic component of this V nitrogenase variant has an αß2 (δ) subunit composition and carries an 8Fe P* cluster and a citrate-substituted V cluster analogue in the αß dimer, as well as a 4Fe cluster in the "orphaned" ß-subunit. Interestingly, when normalized based on the amount of cofactor, VnfDGKCit shows a shift of N2 reduction from H2 evolution toward NH3 formation and an opposite shift of CO reduction from hydrocarbon formation toward H2 evolution. These observations point to a role of the organic ligand in proton delivery during catalysis and imply the use of different reaction sites/mechanisms by nitrogenase for different substrate reductions. Moreover, the increased NH3 /H2 ratio upon citrate substitution suggests the possibility to modify the organic ligand for improved ammonia synthesis in the future.