Evidence for Multiple Substrate-Reduction Sites and Distinct Inhibitor-Binding Sites from an Altered Azotobacter vinelandii Nitrogenase MoFe Protein

Abstract

The arginine-277 residue of the α-subunit of the nitrogenase MoFe protein was targeted for substitution because it is (i) a close neighbor of α-cysteine-275, which is one of only two residues anchoring the FeMo cofactor to the polypeptide, and (ii) a component of a potential channel for entry/exit of substrates/products and for accepting FeMo cofactor during MoFe-protein maturation. Several of the eight mutant strains constructed were capable of good diazotrophic growth and also contained FeMo cofactor as indicated by its biologically unique S = 3/2 EPR spectrum. These observations indicate that the positively charged α-arginine-277 residue is not required for acceptance of the negatively charged FeMo cofactor by the separately synthesized, cofactor-deficient, apo-MoFe protein. The wide range of nitrogen-fixation phenotypes shown by these mutant strains generally correlated well with their C₂H₂- and proton-reduction activities, which range from 5 to 65% of wild-type activity. One notable exception is the histidine-substituted strain, DJ788 (α-277^His). This strain, although unable to fix N₂ and grow diazotrophically, elaborates an altered α-277^His MoFe protein that catalyzes the reduction of the alternative substrates, C₂H₂, HCN, HN₃, and protons. These observations are best explained if multiple redox levels are available to the MoFe protein but the α-277^His MoFe protein is incapable of reaching the more-reduced redox levels required for nitrogen fixation. Under nonsaturating CO concentrations, the α-277^His MoFe-protein-catalyzed reduction of C₂H₂ showed sigmoidal kinetics, which is consistent with inhibitor-induced cooperativity among two C₂H₄-evolving sites and indicates the presence of three sites, which can be simultaneously occupied, on the MoFe protein. Similar kinetics were not observed for α-277^His MoFe-protein-catalyzed reduction of either HCN or HN₃ with nonsaturating CO levels, indicating that these substrates are unlikely to share common binding sites with C₂H₂. Further, CN^- did not induce cooperativity in C₂H₂ reduction and, therefore, CO and CN^- are unlikely to share a common binding site. These changed substrate specificities, reinforced by changes in the FeMo-cofactor-derived S = 3/2 EPR spectrum, clearly indicate the importance of the α-277 residue in catalysis and the delicate control exerted on the properties of bound FeMo cofactor by its polypeptide environment.