On the formation of an oxygen-tolerant three-component nitrogenase complex from Azotobacter vinelandii

Conditions are defined in which the oxygen-labile nitrogenase components from Azotobacter vinelandii can be protected against oxygen inactivation by the so-called Fe/S protein II. It is demonstrated that oxygen protection can be achieved by complex formation of the three proteins. Complex formation was studied by gel chromatography. Only when the three proteins are in the oxidized state and MgCl2 is present, can an oxygen-tolerant complex be isolated. Quantitative SDS/polyacrylamide gel electrophoresis of such complexes, yielded an average ratio of nitrogenase component 2/nitrogenase component 1 (Av2/Av1) of 2.4 +/- 0.5. Protection by Fe/S protein II was correlated with the amount of [2 Fe-2S] clusters present in the protein and not by the amount of protein. Measurements of the amount of iron and sulfide of Fe/S protein II showed that the iron and sulfide content of the protein was variable. The maximum values found indicate that Fe/S protein II contains two [2Fe-2S] clusters per dimer of 26 kDa. Full protection by Fe/S protein II was obtained with a ratio of Fe/S protein II/Av1 of 1.1 +/- 0.2; the Fe/S protein II containing two [2Fe-2S] clusters per dimer of 26 kDa. When Fe/S protein II contains less [2Fe-2S] clusters, more protein is necessary to obtain full protection. The three-component nitrogenase complex is also oxygen stable in the presence of MgATP or MgADP. Analysis in the ultracentrifuge showed that the major fraction of the reconstituted complex has a sedimentation coefficient centered around 34S. A small fraction (less than 30%) sediments with values centered around 111 S. This suggests an average mass for the oxygen-stable nitrogenase complex of 1.5 MDa. Taking into account the determined stoichiometry of the individual proteins, the molecular composition of the oxygen-stable nitrogenase complex is presumably 4 molecules of AV1,8--12 molecules of aAV2 and 4--6 molecules of Fe/S protein II containing two [2Fe-2S] clusters per dimer of 26 kDa.     

Nitrogenase of Klebsiella pneumoniae: evidence for an adenosine triphosphate-induced association of the iron–sulphur protein (Short Communication)

The effect of various nucleotides on the Fe-containing component of nitrogenase of Klebsiella pneumoniae was investigated by ultracentrifugation and thiol-group reactivity towards 5,5'-dithiobis-(2-nitrobenzoate). In the absence of Na(2)S(2)O(4), ATP and ADP produced changes in sedimentation behaviour and thiol-group reactivity consistent with association of the protein.     

Nitrogenase of Klebsiella pneumoniae. A stopped-flow study of magnesium-adenosine triphosphate-induce electron transfer between the compeonent proteins.

Stopped-flow kinetic data have been obtained for a rapid electron-transfer reaction between the component proteins of nitrogenase from Klebsiella pneumoniae, which was induced by MgATP. Up to three equivalents of the Fe-containing protein were rapidly oxidized by one equivalent of the Fe-Mo-containing protein in a unimolecular reaction, k2 = 2 x 10(2)S-1. Evidence for a tight complex between the component proteins, KD(complex) less than 0.5 muM, which was formed with a rate k1 greater than 1 x 10(7)M-1-S-1, has been obtained. MgATP bound to either the Fe-containing protein or to the two-protein complex with a rate k3 greater than 2.5 x 10(6)M-1-S-1 and with KD(MgATP) = 0.4mM, before the electron-transfer reaction.     

Characterization of an oxygen-stable nitrogenase complex isolated from Azotobacter chroococcum.

In crude cell-free extracts of Azotobacter chroococcum, nitrogenase was much less sensitive to irreversible inactivation by O2 than was the purified enzyme. When nitrogenase was partially purified by anaerobic discontinuous sucrose-density-gradient centrifugation, O2-tolerance was retained. This preparation was considerably enriched in four polypeptides, three of which were derived from the Mo-Fe(molybdenum-iron) protein and Fe (iron) protein of nitrogenase. The fourth was purified to homogeneity and shown to be an iron-sulphur protein (mol.wt. 14000) probably containing a 2Fe--2S centre. When this protein was added to purified nitrogenase, the enzyme was rendered O2-tolerant, through stabilization was Mg2+-dependent. The isolated O2-tolerant nitrogenase was an equimolar stoicheiometric complex between the MO--Fe, Fe and protective proteins. It is likely that the formation of this complex in vivo is the mechanism of 'conformational protection' in this organism.     

Klebsiella pneumoniae nitrogenase: formation and stability of putative beryllium fluoride-ADP transition state complexes.

Incubation of the MoFe protein (Kp1) and Fe protein (Kp2), the component proteins of Klebsiella pneumoniae nitrogenase, with BeF(3)(-) and MgADP resulted in a progressive inhibition of nitrogenase activity. We have shown that at high Kp2 to Kp1 molar ratios this inhibition is due to the formation of an inactive complex with a stoichiometry corresponding to Kp1.{Kp2.(MgADP.BeFx)2}2. At lower Kp2:Kp1 ratios, an equilibrium between this 2:1 complex, the partially active 1:1 Kp1.Kp2.(MgADP. BeFx)2 complex, and active nitrogenase components was demonstrated. The inhibition was reversible since incubation of the 1:1 complex in the absence of MgADP and beryllium resulted in complete restoration of activity over 30 h. Under pseudo-first-order conditions with regard to nitrogenase components and MgADP, the kinetics of the rate of inhibition with increasing concentrations of BeF(3)(-) showed a square dependence on [BeF(3)(-)], consistent with the binding of two Be atoms by Kp2 in the complex. Analytical fplc gel filtration profiles of Kp1.Kp2 incubation mixtures at equilibrium resolved the 2:1 complex and the 1:1 complex from free Kp1. Deconvolution of the equilibrium profiles gave concentrations of the components allowing constants for their formation of 2.1 x 10(6) and 5.6 x 10(5) M(-1) to be calculated for the 1:1 and 2:1 complexes, respectively. When the active site concentration of the different species was taken into account, values for the two constants were the same, indicating the two binding sites for Kp2 are the same for Kp1 with one or both sites unoccupied. The value for K(1) we obtain from this study is comparable with the value derived from pre-steady-state studies of nitrogenase. Analysis of the elution profile obtained on gel filtration of a 1:1 ratio incubation mixture containing 20 microM nitrogenase components showed 97% of the Kp2 present initially to be complexed. These data provide the first unequivocal demonstration that Fe protein preparations which may contain up to 50% of a species of Fe protein defective in electron transfer is nevertheless fully competent in complex formation with MoFe protein.     

Vanadium nitrogenase of Azotobacter chroococcum. MgATP-dependent electron transfer within the protein complex.

The kinetics of MgATP-induced electron transfer from the Fe protein (Ac2V) to the VFe protein (AclV) of the vanadium-containing nitrogenase from Azotobacter chroococcum were studied by stopped-flow spectrophotometry at 23 degrees C at pH 7.2. They are very similar to those of the molybdenum nitrogenase of Klebsiella pneumoniae [Thorneley (1975) Biochem. J. 145, 391-396]. Extrapolation of the dependence of kobs. on [MgATP] to infinite MgATP concentration gave k = 46 s-1 for the first-order electron-transfer reaction that occurs with the Ac2V MgATPAclV complex. MgATP binds with an apparent KD = 230 +/- 10 microM and MgADP acts as a competitive inhibitor with Ki = 30 +/- 5 microM. The Fe protein and VFe protein associate with k greater than or equal to 3 x 10(7) M-1.s-1. A comparison of the dependences of kobs. for electron transfer on protein concentrations for the vanadium nitrogenase from A. chroococcum with those for the molybdenum nitrogenase from K. pneumoniae [Lowe & Thorneley (1984) Biochem. J. 224, 895-901] indicates that the proteins of the vanadium nitrogenase system form a weaker electron-transfer complex.     

Nucleotide sequence of the gene coding for the nitrogenase iron protein from Klebsiella pneumoniae

We report the complete DNA sequence of the Klebsiella pneumoniae nifH gene, the gene which codes for component 2 (Fe protein or nitrogenase reductase) of the nitrogenase enzyme complex. The amino acid sequence of the K. pneumoniae nitrogenase Fe protein is deduced from the DNA sequence. The K. pneumoniae Fe protein contains 292 amino acids, has a Mr = 31,753, and contains 9 cysteine residues. We compare the amino acid sequence of the K. pneumoniae protein with available amino acid sequence data on nitrogenase Fe proteins from two other species, Clostridium pasteurianum and Azotobacter vinelandii. The C. pasteurianum Fe protein, for which the complete sequence is known, shows 67% homology with the K. pneumoniae Fe protein. Extensive regions of strong conservation (90-95%) are found, while other regions show relatively poor conservation (30-35%). It is suggested that these strongly conserved regions are of special importance to the function of this enzyme, and the findings are discussed in the light of evolutionary theories on the origin of nif genes.     

Interaction with magnesium and ADP stabilizes both components of nitrogenase from Klebsiella pneumoniae against urea denaturation

The nitrogenase enzyme of Klebsiella pneumoniae consists of two separable proteins, each with multiple subunits and one or more oxygen sensitive metallocenters. The wild-type nitrogenase proteins are stable to electrophoresis in high concentrations of urea under anaerobic conditions. Addition of Mg+2 and ADP greatly increases the stability of the smaller Fe protein (from <4 to >6 M for full unfolding), an effect directly analogous to stabilization in p21ras induced by Mg+2 and GDP. Stabilization by Mg+2 is slight for the holo MoFe protein (from approximately 1.5 to approximately 2.4 M) but more dramatic for the apo protein form of the MoFe protein accumulated by certain Fe protein (nifH gene) mutants. The potent product inhibitor of nitrogenase function, MgADP, increases stability of the MoFe protein more than Mg+2 alone, to approximately 3.6 M, showing that nucleotides interact with the MoFe protein. Mutations of the nifM gene result in slower accumulation of less stable Fe protein, indicating that NifM is involved in correct folding of the Fe protein. Mutationally altered proteins are often difficult to purify for study because of their inherent instability, low expression level, or oxygen lability. Crude extracts of 11 different mutants of Fe protein (nifH gene) were examined by transverse urea gradient gels to rapidly screen for stabilizing interactions in the presence or absence of substrate or inhibitor analogs. Amino acid alterations D44N and R188C, at the interface of the dimer, in the vicinity of the nucleotide binding site(s), have significantly lower stability than the wild-type enzyme in the absence of Mg+2 but comparable stability in its presence, showing the importance of Mg+2 in the subunit interactions. Mutations N163S and E266K, in which residues normally involved in hydrogen bonding far from the active site were altered, are more labile than the wild-type even with Mg+2 added. Seven other mutants, though nonfunctional, did not appear altered in stability compared to the wild-type.     

Formation of a tight 1:1 complex of Clostridium pasteurianum Fe protein-Azotobacter vinelandii MoFe protein: evidence for long-range interactions between the Fe protein binding sites during catalytic hydrogen evolution

It has been well documented that the combination of the MoFe protein of Azotobacter vinelandii nitrogenase (Av1) with the Fe protein (Cp2) from Clostridium pasteurianum nitrogenase produces an inactive, stable complex. However, we report that this heterologous nitrogenase has a low level of activity for H(2) evolution, with a specific activity of 12 nmol min(-)(1) mg(-)(1) of Av1. This activity does not arise from contaminating hydrogenase since it required the presence of both Cp2 and Av1 and showed saturation kinetics when increasing amounts of Cp2 were added to the assay. Incubation of the two proteins at a 4:1 Cp2:Av1 ratio in the absence of MgATP followed by analytical gel filtration showed, surprisingly, that the stoichiometry of the isolated complex was Av1.Cp2 instead of Av1.(Cp2)(2) as determined previously. The presence of MgATP in the elution buffer did not change the elution profile of the complex. The hydrodynamic radius of the isolated complex determined by dynamic light scattering was 5.93 +/- 0.14 nm, intermediate between Av1 and a stable 2:1 nitrogenase complex, consistent with a 1:1 assignment for the Av1.Cp2 complex. When assayed with Av2, the isolated Av1.Cp2 complex showed full half-site reactivity with a specific activity of 750 nmol of C(2)H(2) reduced min(-)(1) mg(-)(1) of Av1. The EPR spectrum of the isolated complex showed the Cp2 to be oxidized and the Av1 to retain the S = (3)/(2) signal characteristic of FeMoco. In the presence of MgATP, under turnover conditions at a 2:1 ratio of Cp2:Av1, the [4Fe-4S] center of Cp2 was protected from the chelator 2,2'-bipyridyl. This is consistent with the formation of a tight 2:1 complex of Av1.(Cp2)(2) which is more stable than the homologous Cp nitrogenase. Assuming that the Lowe-Thorneley model for nitrogenase applies and that a rate-limiting dissociation of the complex is required for H(2) evolution, then with a rate of 0.032 s(-)(1) the 1:1 complex is too stable to be involved in catalysis. The differences in the stability of the 2:1 and 1:1 complexes indicate cooperativity between the Fe protein binding sites of Av1, which structural data show to be separated by 105 A. On the basis of these observations, we propose a model for nitrogenase catalysis in which the stable 1:1 complex formed between oxidized Fe protein and the one-electron-reduced MoFe protein plays an essential role. In this scheme, the two Fe protein binding sites of the MoFe protein alternately bind and release Fe protein in a shuttle mechanism associated with long-range conformational changes in the MoFe protein.     

Evidence for a junctional feet-ryanodine receptor complex from sarcoplasmic reticulum

Heavy sarcoplasmic reticulum vesicles, labelled with the Ca2+ release channel probe [3H]ryanodine, were solubilized in detergent, then centrifuged through sucrose gradients. A single peak of ryanodine binding activity was observed with an apparent sedimentation coefficient of 30S. Electron microscopy of the peak fraction showed disk structures of 25-28 nm diameter and 10 nm thickness. Proteins specifically enriched in the peak fraction were the Mr 160,000 and 260,000 and junctional feet proteins (Mr 320,000 and 300,000). This suggests that the feet proteins and ryanodine receptor may be specifically associated into a large oligomeric complex comprising subunits of Mr 160,000-320,000.     

Nitrogenase synthesis in Klebsiella pneumoniae: comparison of ammonium and oxygen regulation.

Rates of nitrogenase synthesis by Klebsiella pneumoniae were measured by pulse-labelling organisms with a mixture of 14C-labelled amino acids followed by sodium dodecyl sulphate gel electrophoresis and autoradiography. Populations from an NH4+-repressed, SO42--limited chemostat (0.46 mg dry wt ml-1), when released from NH4+ repression, simultaneously synthesized detectable quantities of the three nitrogenase polypeptides 45 min before acetylene-reducing activity was observed. Exposure of populations synthesizing nitrogenase to air or NH4+ (200 microgram N ml-1) repressed synthesis of both component proteins simultaneously, the rate initially decreasing by half in 11 to 12 min; in the presence of NH4+ a second slower phase with an approximate half-life of 30 min was observed. With 5% O2 in N2 the half-lives for the decreases in the rates of synthesis were 30 min for the Fe protein and 33 min for the Mo-Fe protein. Oxygen also repressed nitrogenase in a glutamine synthetase constitutive derivative of K. pneumoniae (strain SK24) which escapes NH4+ repression. Regulation of nitrogenase by O2 may therefore be independent of glutamine synthetase.     

The mechanism of Klebsiella pneumoniae nitrogenase action. Simulation of the dependences of H2-evolution rate on component-protein concentration and ratio and sodium dithionite concentration.

The rate constants from Table 1 and Scheme 2 of Lowe & Thorneley [(1984) Biochem. J. 224, 877-886] were used to simulate the rate of H2 evolution, under various conditions, from nitrogenase isolated from Klebsiella pneumoniae. These rates depend on both the ratio and concentrations of the MoFe protein and Fe protein that comprise nitrogenase. The simulations explain the shapes of 'protein titration' and 'dilution effect' curves. The concept of an apparent Km for the reductant Na2S2O4 is shown to be invalid, since the dependence of H2-evolution rate on the square root of S2O4(2-) concentration is not hyperbolic and depends on the ratio and absolute concentrations of the MoFe protein and Fe protein.     

Purification of a second alternative nitrogenase from a nifHDK deletion strain of Azotobacter vinelandii.

A second alternative nitrogenase complex (nitrogenase 3) was purified from a nifHDK deletion strain of Azotobacter vinelandii. The active complex is made up of two components, dinitrogenase 3 and dinitrogenase reductase 3. Dinitrogenase 3 contains two protein subunits (alpha, Mr 58,000, and beta, Mr 50,000) which assemble into at least two active configurations: alpha 2 beta 2 (dinitrogenase 3s) and alpha 1 beta 2 (dinitrogenase 3F). Dinitrogenase 3s contains 24 Fe and 18 acid-labile S2-ions per Mr 216,000, and dinitrogenase 3F contains 11 Fe and 9 acid-labile S2-ions per Mr 158,000. Dinitrogenase reductase 3 is composed of two protein subunits of identical Mr (32,500) and contains four Fe and four acid-labile S2- ions per Mr 65,000. On two-dimensional gels, the protein subunits of the nitrogenase 3 complex comigrated with the four Mo-, V-, and NH4+-repressible proteins originally designated as N2ase B: the nitrogenase hypothesized to exist in the alternative N2 fixation system first described in 1980 (P.E. Bishop, D. M. L. Jarlenski, and D. R. Hetherington, Proc. Natl. Acad. Sci. USA 77:7342-7346, 1980). Neutron activation analysis indicated that the nitrogenase 3 complex lacked significant amounts of Mo, V, Cr, Re, and W. Some Zn, however, was found in the dinitrogenase 3S and dinitrogenase 3F preparations. The pattern of substrate reduction efficiency was H+ greater than N2 greater than C2H2. The maximum specific activity found for N2 reduction was 38 nmol of NH3 per min per mg of protein (dinitrogenase 3S). Nitrogenase 3 was found to be extremely sensitive to O2, and activities could not be reproducibly maintained during freezing and thawing.     

Cyanamide: a new substrate for nitrogenase

(1) Cyanamide (N identical to C-NH2) has been shown to be a substrate for purified Mo-nitrogenases of Klebsiella pneumoniae and Azotobacter chroococcum, with apparent Km values near 0.8 mM. (2) Reduction products were CH4, CH3NH2 and NH3 formed by pathways requiring 6 or 8 electrons: N identical to CNH2 + 6e + 6H+----CH3NH2 + NH3; N identical to CNH2 + 8e + 8H+----CH4 + 2NH3 (3) Acetylene reduction and hydrogen evolution were inhibited more than 75% by cyanamide (10 mM). Cyanamide also inhibited total electron flux at nitrogenase protein component ratios (Fe/MoFe) near 10. (4) Cyanamide was also a substrate for the recently isolated Va-nitrogenase of A. chroococcum, but with an apparent Km of 2.6 mM showed weaker binding and an 8-fold lower Vmax than did either Mo-nitrogenase. (5) The component ratios of nitrogenase proteins favouring CH4 formation was 3.5 Fe/MoFe protein and 1 Fe/VaFe protein.     

Nitrogenases from Klebsiella pneumoniae and Clostridium pasteurianum. Kinetic investigations of cross-reactions as a probe of the enzyme mechanism.

In combination with the Mo-Fe protein of nitrogenase from Klebsiella pneumoniae, the Fe protein of nitrogenase from Clostridium pasteurianum forms an active enzyme with novel properties different from those of either of the homologous nitrogenases. The steady-state rates of reduction of acetylene and H+ are 12% of those of the homologous system from C.pasteurianim. Acetylene reductase activity exhibited an approx. 10min lag at 30 degrees C before the rate of reduction became linear, consistent with a once-only activation step being necessary for acetylene reduction to occur. No such lag was observed for H2 evolution. The activity with N2 as a reducible substrate was very low, implying that acetylene reductase activity is not necessarily an accurate indication of nitrogen-fixing ability. This is of particular relevance to studies on mutant and agronomically important organisms. Stopped-flow spectrophotometric studies showed unimolecular electron transfer from the Fe protein to the Mo-Fe protein to occur at the same rate (k2 = 2.5 X 10(2)s-1) and with the same dependence on ATP concentration (apparent KD = 400 muM) as with the homologous Klebsiella nitrogenase. However, an ATP/2e ratio of 50 was obtained for H2 evolution, indicating that ATP hydrolysis had been uncoupled from electron transfer to substrate. These data indicate that ATP has at least two roles in the mechanism of nitrogenase action. The combination of the Mo-Fe protein of nitrogenase of C.pasteurianim and the Fe protein of K.pneumoniae were inactive in all the above reactions, except for a weak adenosine triphosphatase activity, 0.5% of that of the homologous K.pneumoniae system.     

The mechanism of Klebsiella pneumoniae nitrogenase action. The determination of rate constants required for the simulation of the kinetics of N2 reduction and H2 evolution.

Kinetic data for Klebsiella pneumoniae nitrogenase were used to determine the values of nine of the 17 rate constants that define the scheme for nitrogenase action described by Lowe & Thorneley [(1984) Biochem. J. 224, 877-886]. Stopped-flow spectrophotometric monitoring of the MgATP-induced oxidation of the Fe protein (Kp2) by the MoFe protein (Kp1) was used to determine the rates of association (k+1) and dissociation (k-1) of reduced Kp2(MgATP)2 with Kp1. The dependences of the apparent KNm2 on Fe protein/MoFe protein ratio and H2 partial pressure were used to determine the mutual displacement rates of N2 and H2 (k+10, k-10, k+11 and k-11). These data also allowed the rate constants for H2 evolution from progressively more reduced forms of Kp1 to be determined (k+7, k+8 and k+9). A mechanism for N2-dependent catalysis of 1H2H formation from 2H2 that requires H2 to be a competitive inhibitor of N2 reduction is also presented.     

The roles of the nifW, nifZ and nifM genes of Klebsiella pneumoniae in nitrogenase biosynthesis

Active Fe protein of nitrogenase was synthesised in a non-nitrogen fixing organism when Escherichia coli was transformed with a plasmid encoding only two nif-specific genes, nifH and nifM of Klebsiella pneumoniae. Hence proteins NifH and NifM are sufficient to produce active Fe protein in E. coli. K. pneumoniae strains carrying chromosomal nifW- and nifZ- mutations were constructed and shown to be significant C2H2-reducing activity and to grow on N-free plates. Nevertheless, derepressing cultures of the mutant strains had reduced levels of MoFe protein activity, and consequently significantly lower levels of nitrogenase activity, than the nif+ parent strain. NifW and NifZ therefore appear to be involved in the formation or accumulation of active MoFe protein, but are not essential for nitrogen fixation in K. pneumoniae under the conditions tested.     

The vanadium nitrogenase of Azotobacter chroococcum. Purification and properties of the VFe protein.

1. Nitrogenase activity of a strain of Azotobacter chroococcum lacking the structural genes for conventional nitrogenase (nifHDK) was separated into two components: an Fe-containing protein and a vanadoprotein. 2. The larger protein was purified to homogeneity by the criterion of electrophoresis of 10% (w/v) acrylamide gels in the presence of SDS. Two types of subunit, of Mr 50,000 and 55,000, were present in equal amounts. 3. The protein had an Mr of 210,000 and contained 2 V atoms, 23 Fe atoms and 20 acid-labile sulphide groups per molecule. The Mo content was less than 0.06 g-atom/mol. All the common amino acids were present, with a predominance of acidic residues. Ultracentrifugal analysis gave a maximum sedimentation coefficient of 9.7 S and a symmetrical boundary at 5 mg of protein X ml-1; dissociation occurred at lower concentrations. The specific activities (nmol of product/min per mg of protein), when assayed under optimum conditions with the complementary Fe protein from this strain, were 1348 for H2 evolution, 350 for NH3 formation and 608 for acetylene reduction. Activity was O2-labile, with a t1/2 of 40 s in air. At low temperatures the dithionite-reduced protein showed e.p.r. signals at g = 5.6, 4.35, 3.77 and 1.93, consistent with an S = 3/2 ground state with an additional S = 1/2 centre giving rise to the feature at g = 1.93. The u.v. spectra of dithionite-reduced and thionine-oxidized protein were very similar. Oxidation resulted in a general increase in absorbance in the visible region. The shoulder at 380 nm in the spectrum of reduced protein was replaced with shoulders near 330 nm and 420 nm on oxidation.     

Molybdenum independence of nitrogenase component synthesis in the non-heterocystous cyanobacterium Plectonema.

The cyanobacterium Plectonema boryanum (IU 594-UTEX 594) fixes N2 only in the absence of combined N and of O2. We induced nitrogenase by transfer to anaerobic N-free medium and studied the effect of Mo starvation on nitrogenase activity and synthesis. Activity was first detected within 3 h after transfer by the acetylene reduction assay in controls, increasing for at least 25 h. Cells grown on nitrate and Mo and then transferred to N-free, Mo-free medium produced 8% of the control nitrogenase activity. Addition of W to the Mo-free medium reduced the activity to 0.5%. Under both Mo starvation conditions, nitrogenase protein components were synthesized. Component II of the cyanobacterial enzyme was detected by in vitro complementation with Mo-containing component I from Klebsiella pneumoniae or Azotobacter vinelandii but not Clostridium pasteurianum. Component I activity was restored by addition of Mo to cultures in which new enzyme synthesis was blocked by chloramphenicol. Acidified extracts of Plectonema induced in Mo-containing medium contained the Fe-Mo cofactor required to activate extracts of the Azotobacter mutant UW45 in vitro, but they did not activate extracts of Mo-starved Plectonema. Analysis of 35SO4(2-)-labeled proteins by polyacrylamide gel electrophoresis suggested that Mo is required for the conversion of a high-molecular-weight precursor to component I in Plectonema.     

Klebsiella pneumoniae nitrogenase. Inhibition of hydrogen evolution by ethylene and the reduction of ethylene to ethane.

Ethylene (C2H4) inhibited H2 evolution by the Mo-containing nitrogenase of Klebsiella pneumoniae. The extent of inhibition depended on the electron flux determined by the ratio of Fe protein (Kp2) to MoFe protein (Kp1) with KiC2H4 = 409 kPa ([Kp2]/[Kp1] = 22:1) and KC2H4i = 88 kPa ([Kp1]/[Kp2] = 21:1) at 23 degrees C at pH 7.4. At [Kp2]/[Kp1] = 1:1, inhibition was minimal with C2H4 (101 kPa). Extrapolation of data obtained when C2H4 was varied from 60 to 290 kPa indicates that at infinite pressure of C2H4 total inhibition of H2 evolution should occur. C2H4 inhibited concomitant S2O4(2-) oxidation to the same extent that it inhibited H2 evolution. Although other inhibitors of total electron flux such as CN- and CH3NC uncouple MgATP hydrolysis from electron transfer, C2H4 did not affect the ATP/2e ratio. Inhibition of H2 evolution by C2H4 was not relieved by CO. C2H4 was reduced to C2H6 at [Kp2]/[Kp1] ratios greater than or equal to 5:1 in a reaction that accounted for no more than 1% of the total electron flux. These data are discussed in terms of the chemistry of alkyne and alkene reduction on transition-metal centres.