J. Chen et al., IRON EXAFS OF AZOTOBACTER-VINELANDII NITROGENASE MO-FE AND V-FE PROTEINS, Journal of the American Chemical Society, 115(13), 1993, pp. 5509-5515
The structure of the iron sites of nitrogenase in dithionite-reduced a
nd thionine-oxidized forms of the Mo-Fe and V-Fe proteins has been inv
estigated using Fe K-edge X-ray absorption spectroscopy. For the dithi
onite-reduced Azotobacter vinelandii Mo-Fe protein, the dominant EXAFS
Fourier transform peaks are assigned to Fe-S and Fe-Fe interactions a
t approximately 2.32 and 2.64 angstrom, as expected for Fe-S clusters.
An additional Fe-Mo component at 2.73 angstrom is required to complet
ely fit the EXAFS in the 1-3-angstrom region. In the 3-5-angstrom regi
on, a 3.8-angstrom Fe-Fe component is identified, with an amplitude co
rresponding to almost one long Fe-Fe interaction, averaged over all of
the iron in the sample. Features that can be explained as Fe-S and Fe
-Fe interactions at 4.3 and 4.7 angstrom are also observed. A similar
pattern of Fe interactions is observed for the reduced A. vinelandii V
-Fe protein, except that the short Fe-Mo interaction is no longer requ
ired. In both Mo-Fe and V-Fe proteins, the first coordination sphere F
e-S distances contract slightly upon thionine oxidation. The long-rang
e Fe-S and Fe-Fe interactions are very close (within 0.1 angstrom) to
corresponding distances in Fe6S6 prismane clusters. If the amplitudes
are adjusted by assuming that only 14 of 30 nitrogenase irons particip
ate in the M center, then they are consistent with recently proposed c
rystallographic models.