ABSTRACT
Extended x-ray absorption fine structures, small-angle x-ray scattering, and atomistic model calculations have been employed to probe the homogeneity of the fcc solution created in Ag-Cu, a classical system demonstrating the extension of solubility across the entire miscibility gap through rapid quenching. Our results reveal that in many cases the supersaturated solutions formed have decomposition features on the scale of 1 nm. Conventional diffraction methods are inadequate in determining the level of supersaturation or the uniformity of such solid solution alloys.
ABSTRACT
The nitrogenase VFe protein of Azotobacter vinelandii (Av1') has been shown to exist in two forms called Av1'A, which has a primary alpha beta 2 trimeric structure, and Av1'B, which has an alpha 2 beta 2 tetrameric structure [Blanchard, C. Z., & Hales, B. J. (1996) Biochemistry 35, 472-478]. Both forms exhibit S = 5/2 EPR signals in the as-isolated state that may be assigned to 1-equiv-oxidized P clusters (P+). These signals are abolished by enzymatic reduction with the component 2 protein (Av2'). Stepwise oxidative titrations of enzymatically reduced Av1'B result in the restoration of the S = 5/2 P+ signals and the concurrent decrease of the S = 3/2 vanadium cofactor signal. Further oxidation results in the appearance of an integer spin signal assigned to the 2-equiv-oxidized P cluster (P2+). Unlike the analogous signal previously observed in Mo nitrogenase component 1 (Av1), which arises from an excited state, the integer spin P2+ signal in Av1'B originates from a ground-state doublet. Similar oxidative titrations of enzymatically reduced Av1'A show redox behavior dramatically different from that of Av1'B, as monitored by EPR spectroscopy. We observed spectral evidence for a redox-induced intramolecular electron transfer between the reduced P cluster and the oxidized FeV cofactor cluster during the titrations.
