Novel structure and redox chemistry of the prosthetic groups of the iron-sulfur flavoprotein sulfide dehydrogenase from Pyrococcus furiosus; evidence for a [2Fe-2S] cluster with Asp(Cys)3 ligands.

The consecutive structural genes for the iron-sulfur flavoenzyme sulfide dehydrogenase, sudB and sudA, have been identified in the genome of Pyrococcus furiosus. The translated sequences encode a heterodimeric protein with an alpha-subunit, SudA, of 52598 Da and a beta-subunit, SudB, of 30686 Da. The alpha-subunit carries a FAD, a putative nucleotide binding site for NADPH, and a [2Fe-2S]2+,+ prosthetic group. The latter exhibit EPR g-values, 2.035, 1.908, 1.786, and reduction potential, Em,8 = +80 mV, reminiscent of Rieske-type clusters; however, comparative sequence analysis indicates that this cluster is coordinated by a novel motif of one Asp and three Cys ligands. The motif is not only found in the genome of hyperthermophilic archaea and hyperthermophilic bacteria, but also in that of mesophilic Treponema pallidum. The beta-subunit of sulfide dehydrogenase contains another FAD, another putative binding site for NADPH, a [3Fe-4S]+,0 cluster, and a [4Fe-4S]2+,+ cluster. The 3Fe cluster has an unusually high reduction potential, Em,8 = +230 mV. The reduced 4Fe cluster exhibits a complex EPR signal, presumably resulting from magnetic interaction of its S = 1/2 spin with the S=2 spin of the reduced 3Fe cluster. The 4Fe cluster can be reduced with deazaflavin/EDTA/light but not with sodium dithionite; however, it is readily reduced with NADPH. SudA is highly homologous to KOD1-GO-GAT (or KOD1-GltA), a single-gene encoded protein in Pyrococcus kodakaraensis, which has been putatively identified as hyperthermophilic glutamate synthase. However, P. furiosus sulfide dehydrogenase does not have glutamate synthase activity. SudB is highly homologous to HydG, the gamma-subunit of P. furiosus NiFe hydrogenase. The latter enzyme also has sulfide dehydrogenase activity. The P. furiosus genome contains a second set of consecutive genes, sudY and sudX, with very high homology to the sudB and sudA genes, and possibly encoding a sulfide dehydrogenase isoenzyme. Each subunit of sulfide dehydrogenase is a primary structural paradigm for a different class of iron-sulfur flavoproteins.

Nitrogenase of Azotobacter vinelandii: kinetic analysis of the Fe protein redox cycle.

Nitrogenase consists of two metalloproteins (Fe protein and MoFe protein) which are assumed to associate and dissociate to transfer a single electron to the substrates. This cycle, called the Fe protein cycle, is driven by MgATP hydrolysis and is repeated until the substrates are completely reduced. The rate-limiting step of the cycle, and substrate reduction, is suggested to be the dissociation of the Fe protein-MoFe protein complex which is obligatory for the reduction of the Fe protein [Thorneley, R. N. F., and Lowe, D. J. (1983) Biochem. J. 215, 393-403]. This hypothesis is based on experiments with dithionite as the reductant. We also tested besides dithionite flavodoxin hydroquinone, a physiological reductant. Two models could describe the experimental data of the reduction by dithionite. The first model, with no reduction of Fe protein bound to MoFe protein, predicts a rate of dissociation of the protein complex of 8.1 s-1. This rate is too high to be the rate-limiting step of the Fe protein cycle (kobs = 3.0 s-1). The second model, with reduction of the Fe protein in the nitrogenase complex, predicts a rate of dissociation of the protein complex of 2.3 s-1, which in combination with reduction of the nitrogenase complex can account for the observed turnover rate of the Fe protein cycle. When flavodoxin hydroquinone (155 microM) was the reductant, the rate of reduction of oxidized Fe protein in the nitrogenase complex (kobs approximately 400 s-1) was 100 times faster than the turnover rate of the cycle with flavodoxin as the reductant (4 s-1). Pre-steady-state electron uptake experiments from flavodoxin hydroquinone indicate that before and after reduction of the nitrogenase complex relative slow reactions take place, which limits the rate of the Fe protein cycle. These results are discussed in the context of the kinetic models of the Fe protein cycle of nitrogenase.

Redox properties and electron paramagnetic resonance spectroscopy of the transition state complex of Azotobacter vinelandii nitrogenase.

Nitrogenase is a two-component metalloenzyme that catalyzes a MgATP hydrolysis driven reduction of substrates. Aluminum fluoride plus MgADP inhibits nitrogenase by stabilizing an intermediate of the on-enzyme MgATP hydrolysis reaction. We report here the redox properties and electron paramagnetic resonance (EPR) signals of the aluminum fluoride-MgADP stabilized nitrogenase complex of Azotobacter vinelandii. Complex formation lowers the midpoint potential of the [4Fe-4S] cluster in the Fe protein. Also, the two-electron reaction of the unique [8Fe-7S] cluster in the MoFe protein is split in two one-electron reactions both with lower midpoint potentials. Furthermore, a change in spin-state of the two-electron oxidized [8Fe-7S] cluster is observed. The implications of these findings for the mechanism of MgATP hydrolysis driven electron transport within the nitrogenase protein complex are discussed.

Pre-steady-state kinetics of nitrogenase from Azotobacter vinelandii. Evidence for an ATP-induced conformational change of the nitrogenase complex as part of the reaction mechanism.

The pre-steady-state electron transfer reactions of nitrogenase from Azotobacter vinelandii have been studied by stopped-flow spectrophotometry. With reduced nitrogenase proteins after the initial absorbance increase at 430 nm (which is associated with electron transfer from the Fe protein to the MoFe protein and is complete in 50 ms) the absorbance decreases, which, dependent on the ratio [Av2]/[Av1], is followed by an increase of the absorbance. The mixing of reductant-free nitrogenase proteins with MgATP leads after 20 ms to a decrease of the absorbance, which could be fitted (from 0. 05 to 1 s) with a single exponential decay with a rate constant kobs = 6.6 +/- 0.8 s-1. This reaction of nitrogenase was measured at different wavelengths. The data indicate the formation of a species with a blue shift of the absorbance of metal-sulfur clusters of nitrogenase from 430 to 360 nm. The absorbance decrease at 430 nm observed (after 50 ms) in the case of the reduced nitrogenase proteins could only be simulated well if, after the initial electron transfer from the Fe protein to the MoFe protein and before dissociation of the nitrogenase complex, an additional reaction was assumed. The rate constant of this reaction was of the same order as the rate constant of the MgATP-dependent pre-steady-state proton production by nitrogenase from A. vinelandii: kobs = 14 +/- 4 s-1 with reduced nitrogenase proteins and kobs = 6 +/- 2 s-1 with dithionite-free nitrogenase proteins (Duyvis, M. G., Wassink, H., and Haaker, H. (1994) Eur. J. Biochem. 225, 881-890). It is proposed that in the presence and absence of reductant, the observed absorbance decrease at 430 nm of nitrogenase is caused by a change of the conformation of the nitrogenase complex, as a consequence of hydrolysis of MgATP.

Respiratory control determines respiration and nitrogenase activity of Rhizobium leguminosarum bacteroids.

The relationship between the O2 input rate into a suspension of Rhizobium leguminosarum bacteroids, the cellular ATP and ADP pools, and the whole-cell nitrogenase activity during L-malate oxidation has been studied. It was observed that inhibition of nitrogenase by excess O2 coincided with an increase of the cellular ATP/ADP ratio. When under this condition the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) was added, the cellular ATP/ADP ratio was lowered while nitrogenase regained activity. To explain these observations, the effects of nitrogenase activity and CCCP on the O2 consumption rate of R. leguminosarum bacteroids were determined. From 100 to 5 microM O2, a decline in the O2 consumption rate was observed to 50 to 70% of the maximal O2 consumption rate. A determination of the redox state of the cytochromes during an O2 consumption experiment indicated that at O2 concentrations above 5 microM, electron transport to the cytochromes was rate-limiting oxidation and not the reaction of reduced cytochromes with oxygen. The kinetic properties of the respiratory chain were determined from the deoxygenation of oxyglobins. In intact cells the maximal deoxygenation activity was stimulated by nitrogenase activity or CCCP. In isolated cytoplasmic membranes NADH oxidation was inhibited by respiratory control. The dehydrogenase activities of the respiratory chain were rate-limiting oxidation at O2 concentrations (if >300 nM. Below 300 nM the terminal oxidase system followed Michaelis-Menten kinetics (Km of 45 +/- 8 nM). We conclude that (i) respiration in R. leguminosarum bacteroids takes place via a respiratory chain terminating at a high-affinity oxidase system, (ii) the activity of the respiratory chain is inhibited by the proton motive force, and (iii) ATP hydrolysis by nitrogenase can partly relieve the inhibition of respiration by the proton motive force and thus stimulate respiration at nanomolar concentrations of O2.

Formation and characterization of a transition state complex of Azotobacter vinelandii nitrogenase.

A stable complex is formed between the nitrogenase proteins of Azotobacter vinelandii, aluminium fluoride and MgADP. All nitrogenase activities are inhibited. The complex formation was found to be reversible. An incubation at 50 degrees C recovers nitrogenase activity. The complex has been characterized with respect to protein and nucleotide composition and redox state of the metal-sulfur clusters. Based on the inhibition by aluminium fluoride together with MgADP, it is proposed that a stable transition state complex with nitrogenase is isolated.

The molybdenum nitrogenase from wild-type Xanthobacter autotrophicus exhibits properties reminiscent of alternative nitrogenases.

In the presence of molybdate (1 microM) 2-3.5% oxygen and with sucrose as carbon source, Xanthobacter autotrophicus GZ29, a microaerophilic nitrogen-fixing hydrogen-oxidizing bacterium, grew diazotrophically with a minimal doubling time of 2.5 h and a calculated absorbance of up to 52 (546 nm). The maximal specific activity obtained was 145 nmol ethylene reduced . min-1 . mg protein-1 (crude extract). The Mo nitrogenase was derepressed to a comparable level with methionine as nitrogen source. Vanadium compounds stimulated neither growth nor nitrogenase activity. Without added molybdate, diazotrophic growth and nitrogenase activity decreased to an extremely low level. The nitrogenase, responsible for the residual activity in molybdate-starved cells, contained molybdate but no other heterometal atom. These results indicate that, in X. autotrophicus, a Mo-independent nitrogenase does not exist. However, the molybdate-containing nitrogenase exhibited some properties which are reminiscent of alternative nitrogenases. The MoFe protein (component 1, Xa1) copurified with two molecules of a small, not previously detected polypeptide (molar mass 13.6 kDa) and was able to reduce acetylene not only to ethylene but also partly to ethane. Under certain conditions, i.e. in Tris/HCl buffer at alkaline pH values, with titanium (III) citrate as electron donor, at high component 1/component 2 ratios, and at low, non-saturating acetylene concentrations, up to 5.5% ethane was measured. Parallel to the pH-dependent increase of the relative yield of ethane, the total activity (both acetylene and nitrogen reduction rates) decreased and the S = 3/2 FeMo cofactor ESR signal was split into three signals with different rhombicities [E/D values of 0.036 (signal I), 0.072 (signal II) and 0.11 (signal III)]. The intensities of the two new FeMo cofactor signals were more pronounced the more alkaline the pH. They could be further enhanced using titanium (III) citrate instead of Na2S2O4 as reductant.

Pre-steady-state MgATP-dependent proton production and electron transfer by nitrogenase from Azotobacter vinelandii.

MgATP-dependent pre-steady-state proton production by nitrogenase from Azotobacter vinelandii was studied by monitoring the absorbance changes at 572 nm of the pH indicator o-cresolsulphonphtalein in a weakly buffered solution. The absorbance changes are characterized by a constant phase, a single exponential decrease and a linear decrease. The observed rate constant for the single exponential MgATP-dependent proton production by reduced nitrogenase proteins at 20.0 degrees C is 14 +/- 4 s-1. No proton production with a rate constant comparable to the observed rate constant of electron transfer (kobs approximately 100 s-1) was detected. The extent of the observed MgATP-dependent proton production is determined by the redox state of the nitrogenase proteins before mixing with MgATP; less protons are produced when more electrons are transferred from the Fe protein to the MoFe protein. Values of 2.7 +/- 0.3 mol H+produced/mol MoFe protein with oxidized Fe protein, and 1.1 +/- 0.1 mol H+produced/mol MoFe protein with reduced Fe protein, were found. The data are interpreted to mean that protons are taken up after electron transfer from the Fe protein to the MoFe protein; the ratio electrons(transferred)/H-uptake was calculated to be 1.2 +/- 0.2. After mixing the nitrogenase proteins with MgADP, proton production takes place as well. The proton-production curve did not have a constant phase and the observed rate constant of the single exponential reaction is higher, compared to MgATP-dependent proton production (kobs approximately 35 s-1). The amount of protons produced depends also on the redox state of the Fe protein; no proton production was observed with the oxidized Fe protein; with dithionite-reduced Fe protein a value of 3.1 +/- 0.4 mol H+produced/mol MoFe protein was found (or 0.5 +/- 0.1 mol H+/mol Fe protein). Similar results were obtained when only the Fe protein was mixed with MgADP, but the observed absorbance changes were smaller; mixing of dithionite-reduced Fe protein with MgADP resulted in the production of 0.17 +/- 0.05 mol H+/mol Fe protein. All reported absorbance changes were absent when the experiments were performed in a buffered solution. The series of events that occur after mixing of the nitrogenase proteins with MgATP will be presented and discussed. In the case of the reduced Fe protein, electron transfer takes place at a rate of 100 s-1, which is followed by H+ production (kobs approximately 14 s-1). When there is no electron transfer (oxidized Fe protein) the rate constant of the MgATP-induced proton production decreases.(ABSTRACT TRUNCATED AT 400 WORDS)

A reinvestigation of the pre-steady-state ATPase activity of the nitrogenase from Azotobacter vinelandii.

The pre-steady-state ATPase activity of nitrogenase has been reinvestigated. The exceptionally high burst in the hydrolysis of MgATP by the nitrogenase from Azotobacter vinelandii communicated by Cordewener et al. (1987) [Cordewener J., ten Asbroek A., Wassink H., Eady R. R., Haaker H. & Veeger C. (1987) Eur. J. Biochem. 162, 265-270] was found to be caused by an apparatus artefact. A second possible artefact in the determination of the stoichiometry of the pre-steady-state ATPase activity of nitrogenase was observed. Acid-quenched mixtures of dithionite-reduced MoFe or Fe protein of Azotobacter vinelandii nitrogenase and MgATP contained phosphate above the background level. It is proposed that due to this reaction, quenched reaction mixtures of nitrogenase and MgATP may contain phosphate in addition to the phosphate released by the ATPase activity of the nitrogenase complex. It was feasible to monitor MgATP-dependent pre-steady-state proton production by the absorbance change at 572 nm of the pH indicator o-cresolsulfonaphthalein in a weakly buffered solution. At 5.6 degrees C, a pre-steady-state phase of H+ production was observed, with a first-order rate constant of 2.2 s-1, whereas electron transfer occurred with a first-order rate constant of 4.9 s-1. At 20.0 degrees C, MgATP-dependent H+ production and electron transfer in the pre-steady-state phase were characterized by observed rate constants of 9.4 s-1 and 104 s-1, respectively. The stopped-flow technique failed to detect a burst in the release of protons by the dye-oxidized nitrogenase complex. It is concluded that the hydrolysis rate of MgATP, as judged by proton release, is lower than the rate of electron transfer from the Fe protein to the MoFe protein.

The role of MgATP hydrolysis in nitrogenase catalysis.

Kinetic studies on MgATP hydrolysis by nitrogenase of Azotobacter vinelandii were performed in the presence and in the absence of reducing equivalents. By measuring the ATPase activity of dye-oxidized nitrogenase proteins it can be excluded that reductant-independent ATPase activity is the result of futile cycling of electrons. The turnover rates of MoFe protein during reductant-dependent and reductant-independent ATPase activity, when measured with excess Fe protein, have approximately the same value, i.e. 5 s-1 at pH 7.4 and 22 degrees C, assuming the hydrolysis of four molecules of MgATP per turnover of MoFe protein. For Fe protein on the other hand, the maximum turnover rate during reductant-independent ATPase activity is only about 6% of that of reductant-dependent ATPase activity. While the reductant-dependent ATPase activity shows a sigmoidal dependence on the concentration of MgATP, the reductant-independent ATPase activity yields hyperbolic saturation curves. To account for these results it is proposed that the rate-limiting step during MgATP hydrolysis by oxidized nitrogenase is the rate of regeneration of active Fe protein. In the presence of reductant, the regeneration of active Fe protein is stimulated, explaining the higher ATPase activity of nitrogenase during substrate reduction.

Binding of ADP and orthophosphate during the ATPase reaction of nitrogenase.

The pre-steady-state ATPase activity of nitrogenase from Azotobacter vinelandii was investigated. By using a rapid-quench technique, it has been demonstrated that with the oxidized nitrogenase complex the same burst reaction of MgATP hydrolysis occurs as observed with the reduced complex, namely 6-8 mol orthophosphate released/mol MoFe protein. It is concluded that the pre-steady-state ATPase activity is independent of electron transfer from Fe protein to MoFe protein. Results obtained from gel centrifugation experiments showed that during the steady state of reductant-independent ATP hydrolysis there is a slow dissociation of one molecule of MgADP from the nitrogenase proteins (koff less than or equal to 0.2 s-1); the second MgADP molecule dissociates much faster (koff greater than or equal to 0.6 s-1). Under the same conditions orthophosphate was found to be associated with the nitrogenase proteins. The rate of dissociation of orthophosphate from the nitrogenase complex, as estimated from the gel centrifugation experiments, is in the same order of magnitude as the steady-state turnover rate of the reductant-independent ATPase activity (0.6 mol Pi formed X s-1 X mol Av2(-1) at 22 degrees C). These data are consistent with dissociation of orthophosphate or MgADP being rate-limiting during nitrogenase-catalyzed reductant-independent ATP hydrolysis.

Electron allocation to H+ and N2 by nitrogenase in Rhizobium leguminosarum bacteroids.

Electron allocation to H+ and N2 by nitrogenase in intact Rhizobium leguminosarum bacteroids has been studied. Nitrogenase activity was measured in intact cells with succinate and oxygen substrates. When whole cell nitrogenase activity was inhibited by oxygen-limitation or by the addition of the H+-conducting ionophore carbonylcyanide m-chlorophenylhydrazone, both inducing a low intracellular ATP/ADP ratio, the electron allocation to H+ was favoured over that to N2. When whole cell nitrogenase activity was inhibited by excess oxygen or by the addition of the K+-conducting ionophore valinomycin, both inhibiting electron transport to nitrogenase without affecting the intracellular ATP/ADP ratio, no effect upon the electron allocation to H+ and N2 was observed. The whole cell experiments could be confirmed by experiments with bacteroids treated with hexadecyltrimethylammonium bromide. Nitrogenase is highly active in these preparations with Na2S2O4 and MgATP as substrates. No effect was observed upon electron allocation to H+ and N2 when nitrogenase was inhibited by limitation of reductant (Na2S2O4) or MgATP. Only when nitrogenase was inhibited by MgADP, electron allocation to H+ was favoured. The amount of nitrogenase component 1 and 2 in bacteroids was estimated with protein blotting, followed by an immunological detection. It was found that 17% +/- 3% of total bacteroid protein is component 1 and 12% +/- 2% is component 2. The specific nitrogenase activity of bacteroids treated with hexadecyltrimethylammonium bromide is 178 +/- 62 nmol C2H4 formed X min-1 X mg total protein-1. Despite the high protein concentrations, nitrogenase is not inhibited. With cell-free extracts or with purified nitrogenase components isolated from R. leguminosarum bacteroids, electron allocation to H+ was favoured over that to N2, independently of the mechanism of inhibition. The discrepancies between the whole cell studies and those with isolated enzyme will be discussed with respect to the present mechanism of action of nitrogenase.