Samples of the dithionite-reduced FeFe protein (the dinitrogenase component of the Fe-only nitrogenase) from Rhodobacter capsulatus have been investigated by 57Fe Mössbauer spectroscopy and by Fe and Zn EXAFS as well as XANES spectroscopy. The analyses were performed on the basis of data known for the FeMo cofactor and the P cluster of Mo nitrogenases. The prominent Fourier transform peaks of the Fe K-edge spectrum are assigned to Fe-S and Fe-Fe interactions at distances of 2.29 A and 2.63 A, respectively. A significant contribution to the Fe EXAFS must be assigned to an Fe backscatterer shell at 3.68 A, which is an unprecedented feature of the trigonal prismatic arrangement of iron atoms found in the FeMo cofactor of nitrogenase MoFe protein crystal structures. Additional Fe...Fe interactions at 2.92 A and 4.05 A clearly indicate that the principal geometry of the P cluster is also conserved. Mössbauer spectra of 57Fe-enriched FeFe protein preparations were recorded at 77 K (20 mT) and 4.2 K (20 mT, 6.2 T), whereby the 4.2 K high-field spectrum clearly demonstrates that the cofactor of the Fe-only nitrogenase (FeFe cofactor) is diamagnetic in the dithionite-reduced ("as isolated") state. The evaluation of the 77 K spectrum is in agreement with the assumption that this cofactor contains eight Fe atoms. In the literature, several genetic and biochemical lines of evidence are presented pointing to a significant structural similarity of the FeFe, the FeMo and and the FeV cofactors. The data reported here provide the first spectroscopic evidence for a structural homology of the FeFe cofactor to the heterometal-containing cofactors, thus substantiating that the FeFe cofactor is the largest iron-sulfur cluster so far found in nature.
The component proteins of the iron-only nitrogenase were isolated from Rhodobacter capsulatus (AnifhTDK, AmodABCD strain) and purified in a one-day procedure that included only one columnchromatography step (DEAE-Sephacel). This procedure yielded component 1 (FeFe protein, RclFe), which was more than 95% pure, and an approximately 80% pure component 2 (Fe protein, R c~~' ) . The highest specific activities, which were achieved at an R c~~V R C~~~ molar ratio of 40: 1, were 260 (C,H, from C,H,), 350 (NH, formation), and 2400 (H, evolution) nmol product formed . min-' . mg protein-'.The purified FeFe protein contained 26 -t 4 Fe atoms ; it did not contain Mo, V, or any other heterometal atom.The most significant catalytic property of the iron-only nitrogenase is its high H,-producing activity, which is much less inhibited by competitive substrates than the activity of the conventional molybdenum nitrogenase. Under optimal conditions for N, reduction, the activity ratios (mol N, reduced/mol H, produced) obtained were 1 : 1 (molybdenum nitrogenase) and 1 :7.5 (iron nitrogenase). The Rcl" protein has only a very low affinity for C,H,. The K,, value determined (12.5 kPa), was about ninefold higher than the K,, for RclM" (1.4 kPa). The proportion of ethane produced from acetylene (catalyzed by the iron nitrogenase), was strictly pH dependent. It corresponded to 5.5% of the amount of ethylene at pH 6.5 and was almost zero at pH values greater than 8.5.In complementation experiments, component 1 proteins coupled very poorly with the 'wrong' component 2. RclF', if complemented with R c~~" , showed only 10-15% of the maximally possible activity. Cross-reaction experiments with isolated polyclonal antibodies revealed that Rcl'" and Rc lM" are immunologically not related.The most active RclFe samples appeared to be EPR-silent in the Na,S,O,-reduced state. However, on partial oxidation with K,[Fe(CN),] or thionine several signals occurred. The most significant signal appears to be the one at g = 2.27 and 2.06 which deviates from all signals so far described for P clusters. It is a transient signal that appears and disappears reversibly in a redox potential region between -100 mV and + 150 mV. Another novel EPR signal (g = 1.96, 1.92, 1.77) occurred on further reduction of RclF" by using turnover conditions in the presence of a substrate (N,, C,H,, H+).Keywords: nitrogenase ; iron protein ; cofactor; EPR; Rhodobacter capsulatus.Three genetically distinct types of nitrogenase systems (ng vnJ unf, have so far been proved to exist in nature. The most widespread and intensively characterized system is the classical Mo-containing nitrogenase (nif system) found in all diazotrophs [l, 21. During the last few years, two types of alternative, Moindependent nitrogenases have been discovered and described. One is a vanadium-containing nitrogenase (vnf system) (for review see [3]) and the other enzyme lacks both Mo and V (anf system) and has been tentatively designated as Fe nitrogenase [4][5][6]. Although there is much circumstantial and...
In Rhodobacter capsulatus there exists, in addition to a conventional Mo-containing nitrogenase, a second, Mo-indendent nitrogenase which was demonstrated in wild-type cells as well as in cells of a nifHDK- mutant. To construct this R. capsulatus mutant, a 4-kb BglII-HindIII fragment encompassing nifK, nifD and most of the nifH coding region was substituted by an interposon coding for kanamycin resistance. The alternative nitrogenase is repressed by molybdenum. Mo concentration greater than 1 ppb in the growth medium prevented diazotrophic growth of nifHDK- cells and the expression of nitrogenase activity. The Mo-independent nitrogenase was maximally derepressed in activated carbon-treated media which contained less than 0.05 ppb Mo, high concentrations of iron (1 mM ferric citrate) and serine as N source. Under N2-fixing and optimal Mo-deficient conditions, nifHDK- cells grew with a doubling time of 9 h. The highest activity achieved with whole cells was 1.2 nmol ethylene.min-1.mg protein-1. Vanadium neither stimulated nor inhibited growth and activity. The alternative nitrogenase reduced acetylene to both ethylene and ethane. With whole cells (nifHDK-) the proportion of ethane varied over 2-5% depending on the amount of residual traces of Mo in the medium. The addition of Mo to a growing, nitrogenase-active culture resulted in a slow decrease of total activity but also in a simultaneous increase of ethane production up to 40%. In contrast, cell-free extracts and the purified enzyme did not show any or only very little ethane formation (0-0.4%). Both enzyme components appeared to be very labile proteins. Component 2 lost almost all its activity during cell breakage. With component 1 in crude extracts, if complemented with the stable component 2 of the Mo-nitrogenase from Xanthobacter autotrophicus, a recovery of 50% of the original whole cell activity could be achieved. During purification, component 1 (from the nifHDK- mutant) remained remarkably stable. The partially purified component 1 had a pH optimum (acetylene reduction) of 7.8-8.0, relatively high affinity to acetylene (Km = 0.055 mM) and was analyzed to contain 20 mol Fe atoms/mol protein, 0.2 mol Mo atoms and negligible amounts of V, W and Re. The dithionite-reduced dinitrogenase appeared to be ESR-silent. The results indicate that the alternative nitrogenase of R. capsulatus is not a vanadium enzyme but rather a heterometal-free Fe-nitrogenase or a nitrogenase with an as-yet-unidentified heterometal atom.
The soluble hydrogenase (hydrogen-NAD+ oxidoreductase, EC 1.12.1.2) of Alcaligenes eutrophus H16 was shown to be stabilized by oxidation with oxygen and ferricyanide as long as electron donors and reducing compounds were absent. The simultaneous presence of H2, NADH and O2 in the enzyme solution, however, caused an irreversible inactivation of hydrogenase that was dependent on the O2 concentration. The half-life periods of 4 degrees C under partial pressures of 0.1, 5, 20 and 50% O2 were 11, 5, 2.5 and 1.5 h respectively. Evidence has been obtained that hydrogenase produces superoxide free radical anions (O2-.), which were detected by their ability to oxidize hydroxylamine to nitrite. The correlation between O2 concentration, nitrite formation and inactivation rates and the stabilization of hydrogenase by addition of superoxide dismutase indicated that superoxide radicals are responsible for enzyme inactivation. During short-term activity measurements (NAD+ reduction, H2 evolution from NADH), hydrogenase activity was inhibited by O2 only very slightly. In the presence of 0.7 mM-O2 an inhibition of about 20% was observed.
By preparative polyacrylamide gel electrophoresis at pH 8.5, and in the absence of nickel ions, two types of subunit dimers of the NAD-linked hydrogenase from Nocardia opaca I b were separated and isolated, and their properties were compared with each other as well as with the properties of the native enzyme.The intact hydrogenase contained 14.3+0.4 labile sulphur, 13.6*1.1 iron and 3.8A0.1 nickel atoms and approximately 1 FMN molecule per enzyme molecule. The oxidized hydrogenase showed an absorption spectrum with maxima (shoulders) at 380nm and 420 nm and an electron spin resonance (ESR) spectrum with a signal at g = 2.01. The midpoint redox potential of the Fe-S cluster giving rise to this signal was + 25 mV. In the reduced state, hydrogenase gave characteristic low-temperature (10 -20 K) and high-temperature ( > 40 K) ESR spectra which were interpreted as due to [4Fe -4S] and [2Fe -2S] clusters, respectively. The midpoint redox potentials of these clusters were determined to be -420 mV and -285 mV, respectively.The large hydrogenase dimer, consisting of subunits with relative molecular masses M,, of 64000 and 31 000, contained 9.9 0.5 iron atoms per protein molecule. This dimer contained the FMN molecule, but no nickel. The absorption and ESR spectra of the large dimer were qualitatively similar to the spectra of the whole enzyme. This dimer did not show any hydrogenase activity, but reduced several electron acceptors with NADH as electron donor (diaphorase activity).The small hydrogenase dimer, consisting of subunits with M , of 56000 and 27000, was demonstrated to have substantially different properties. For iron and labile sulphur average values of 3.9 and 4.3 atoms/dimer molecule have been determined, respectively. The dimer contained, in addition, about 2 atoms of nickel and was free of flavins. In the oxidized state this dimer showed an absorption spectrum with a broad band in the 400-nm region and a characteristic ESR signal at g= 2.01. The reduced form of the dimer was ESR-silent. The small dimer alone was diaphorase-inactive and did not reduce NAD with H,, but it displayed high H,-uptake activities with viologen dyes, methylene blue and FMN, and H,-evolving activity with reduced methyl viologen. Hydrogen-dependent NAD reduction was fully restored by recombining both subunit dimers, although the reconstituted enzyme differed from the original in its activity towards artificial acceptors and the ESR spectrum in the oxidized state.0.4 S2 -and 9.3Besides the soluble hydrogenases of Alcaligenes eutrophus [I -31 and Alcaligenes ruhlandii [4], the hydrogenase isolated from Nocardia opaca 1 b has been described as being NADlinked [5,6]. With respect to many catalytic and molecular properties (electron acceptor specificity, pH optima, affinity for NAD and H2, molecular mass, subunit structure), this enzyme closely resembles the soluble hydrogenase of A . eutrophus HI6 [6]. The most extraordinary property of both enzymes is that they are tetramers each composed of four nonidentical subunits. The subunits of t...
Azotobacter vinelandii is a diazotrophic bacterium characterized by the outstanding capability of storing Mo in a special storage protein, which guarantees Mo-dependent nitrogen fixation even under growth conditions of extreme Mo starvation. The Mo storage protein is constitutively synthesized with respect to the nitrogen source and is regulated by molybdenum at an extremely low concentration level (0-50 nM). This protein was isolated as an alpha4beta4 octamer with a total molecular mass of about 240 kg mol(-1) and its shape was determined by small-angle X-ray scattering. The genes of the alpha and beta subunits were unequivocally identified; the amino acid sequences thereby determined reveal that the Mo storage protein is not related to any other known molybdoprotein. Each protein molecule can store at least 90 Mo atoms. Extended X-ray absorption fine-structure spectroscopy identified a metal-oxygen cluster bound to the Mo storage protein. The binding of Mo (biosynthesis and incorporation of the cluster) is dependent on adenosine triphosphate (ATP); Mo release is ATP-independent but pH-regulated, occurring only above pH 7.1. This Mo storage protein is the only known noniron metal storage system in the biosphere containing a metal-oxygen cluster.
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