Evidence for the selective population of FeMo cofactor sites in MoFe protein and its molecular recognition by the Fe protein in transition state complex analogues of nitrogenase.

We have collected synchrotron x-ray solution scattering data for the MoFe protein of Klebsiella pneumoniae nitrogenase and show that the molecular conformation of the protein that contains only one molybdenum per alpha(2)beta(2) tetramer is different from that of the protein that has full occupancy i.e. two molybdenums per molecule. This structural finding is consistent with the existence of MoFe protein molecules that contain only one FeMo cofactor site occupied and provides a rationale for the 50% loss of the specific activity of such preparations. A stable inactive transition state complex has been shown to form in the presence of MgADP and AlF(4)(-). Gel filtration chromatography data show that the MoFe protein lacking a full complement of the cofactor forms initially a 1:1 complex before forming a low affinity 1:2 complex. A similar behavior is found for the MoFe protein with both cofactors occupied, but the high affinity 1:2 complex is formed at a lower ratio of Fe protein/MoFe protein. The 1:1 complex, MoFe protein-Fe protein x (ADP x AlF(4)(-))(2), formed with MoFe protein that lacks one of the cofactors, is stable. X-ray scattering studies of this complex have enabled us to obtain its low resolution structure at approximately 20-A resolution, which confirms the gel filtration finding that only one molecule of the Fe protein binds the MoFe protein. By comparison with the low resolution structure of purified MoFe protein that contains only one molybdenum per tetramer, we deduce that the Fe protein interacts with the FeMo cofactor-binding alpha-subunit of the MoFe protein. This observation demonstrates that the conformation of the alpha-subunit or the alpha beta subunit pair that lacks the FeMo cofactor is altered and that the change is recognized by the Fe protein. The structure of the 1:1 complex reveals a similar change in the conformation of the Fe protein as has been observed in the low resolution scattering mask and the high resolution crystallographic study of the 1:2 complex where both cofactors are occupied and with the Fe protein bound to both subunits. This extensive conformational change observed for the Fe protein in the complexes is, however, not observed when MgATP or MgADP binds to the isolated Fe protein. Thus, the large scale conformational change of the Fe protein is associated with the complex formation of the two proteins.

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.

MgATP-independent hydrogen evolution catalysed by nitrogenase: an explanation for the missing electron(s) in the MgADP-AlF4 transition-state complex.

When the MoFe (Kp1) and Fe (Kp2) component proteins of Klebsiella pneumoniae nitrogenase are incubated with MgADP and AlF4(-) in the presence of dithionite as a reducing agent, a stable putative transition-state complex is produced [Yousafzai and Eady (1997) Biochem. J. 326, 637-640]. Surprisingly, the EPR signal associated with reduced Kp2 is not detectable, but Kp1 retains the S=3/2 EPR signal arising from the dithionite reduced state of the MoFe cofactor centre of the protein. This is consistent with the [Fe4S4] centre of the Fe protein in the complex being oxidized, and similar observations have been made with the complex of Azotobacter vinelandii [Spee, Arendsen, Wassink, Marritt, Hagen and Haaker (1998) FEBS Lett. 432, 55-58]. No satisfactory explanation for the fate of the electrons lost by Kp2 has been forthcoming. However, we report here that during the preparation of the MgADP-AlF4 K. pneumoniae complex under argon, H2 was evolved in amounts corresponding to one half of the FeMoco content of the Kp1 (FeMoco is the likely catalytic site of nitrogenase with a composition Mo:Fe7:S9:homocitrate). This is surprising, since activity is observed during incubation in the absence of MgATP, normally regarded as being essential for nitrogenase function, and in the presence of MgADP, a strong competitive inhibitor of nitrogenase. The formation of H2 by nitrogenase in the absence of AlF4(-) was also observed in reaction mixtures containing MgADP but not MgATP. The reaction showed saturation kinetics when Kp1 was titrated with increasing amounts of Kp2 and, at saturation, the amount of H2 formed was stoichiometric with the FeMoco content of Kp1. The dependence of the rate of formation of H2 on [MgADP] was inconsistent with the activity arising from MgATP contamination. We conclude that MgATP is not obligatory for H+ reduction by nitrogenase since MgADP supports a very low rate of hydrogen evolution.

Nitrogenase of Klebsiella pneumoniae: kinetics of formation of the transition-state complex and evidence for an altered conformation of MoFe protein lacking a FeMoco centre.

We have investigated the kinetics of inactivation of Mo-nitrogenase isolated from Klebsiella pneumoniae when it forms an inhibited putative transition-state complex on incubation with ADP and AlF4-. In the presence of excess Kp2 (Fe protein of the Mo-nitrogenase of K. pneumoniae), the kinetics were found to depend on the Mo content of Kp1 (the MoFe protein of Mo-nitrogenase of K. pneumoniae). The residual nitrogenase activity versus time of incubation using Kp1 preparations containing integral, i.e. one or two Mo atoms per molecule of Kp1, were essentially monophasic, but significantly different rates of inactivation were observed. In contrast, the progress curves for preparations of Kp1 with non-integral Mo content were biphasic, suggesting the presence of two discrete catalytically active species of Kp1. The best fit to the observed data was obtained with a two-exponential expression, the amplitude of which was consistent with the Mo content, provided that the fast phase of the reaction was assigned to a Kp1 species containing one, and the slow phase to a species containing two Mo atoms per alpha2beta2 tetramer. This analysis provides the first evidence for the existence of a catalytically active Kp1 species containing a single Mo atom. These data also indicate that MoFe protein which does not have all FeMoco binding sites occupied has an altered conformation compared with a fully loaded protein, and that the Fe protein reacts with these conformations at different rates to form the stable, but inhibited transition-state complex.

The first glimpse of a complex of nitrogenase component proteins by solution X-ray scattering: conformation of the electron transfer transition state complex of Klebsiella pneumoniae nitrogenase.

An essential feature of the mechanism of nitrogenase, the enzyme responsible for biological nitrogen fixation, is the formation of a transient electron transfer complex between the MoFe protein containing the active site at which N2 is reduced, and the Fe protein, which functions as a specific electron donor to the MoFe protein. We have obtained high quality solution X-ray scattering data using synchrotron X-rays of a stable putative electron transfer complex, (MoFe-protein)(Fe-protein.ADP.AIF4)2, of Klebsiella pneumoniae and used the model-independent approach based on the multipole expansion method to provide a stable and unique shape restoration at approximately 15 A resolution. The biological significance of this first molecular structure of a nitrogenase complex is discussed.

Isolation and characterization of nitrogenase MoFe protein from the mutant strain pHK17 of Klebsiella pneumoniae in which the two bridging cysteine residues of the P-clusters are replaced by the non-coordinating amino acid alanine.

Nitrogenase MoFe protein (Kp1) from the mutant strain pHK17 or Klebsiella pneumoniae has been purified to give three catalytically active fractions. In this mutant, each of the two bridging cysteine ligands to the P-clusters, alpha-Cys-89 and beta-Cys-94, has been replaced by a non-coordinating residue, alanine. SDS/PAGE and earlier native gels showed that the three fractions retained the normal alpha 2 beta 2 tetrameric form of wild-type Kp1; therefore we conclude that in each of the fractions the subunits are folded differently, thus resulting in different surface charges and allowing separation of the fractions on ion-exchange chronatography. Earlier EPR and magnetic CD data had shown that the mutant fractions contain P-clusters, and thus the mutated residues are not as essential for maintaining the integrity of the P-clusters as they appear from the X-ray structure. The specific activity of each of the three fractions was less than that of wild-type Kp1, the most active fraction having only 50% of wild-type activity. No change in substrate specificity or in the relative distribution of electrons to various substrates was found. The relationship between ATP hydrolysis and substrate-reducing activity, the EPR spectra of the S = 3/2 spin state of the iron-molybdenum cofactor (FeMoco) and the pH profile of acetylene-reduction activities of the three fractions did not differ significantly from those exhibited by wild-type Kp1. The specific activities of the three mutant fractions and of wild-type Kp1 were linearly proportional to the intensity of the S = 3/2 EPR signal from the FeMoco centres. This implies that those molecules of the three mutant fractions and the wild-type protein that contain EPR-active FeMoco are fully active, i.e. that the Cys to Ala substitution of the P-cluster ligands does not affect the specific activity of the protein. This in turn implies that the P-clusters are not directly associated with the rate-limiting step in enzyme turnover. We conclude that the lower specific activities of the mutant fractions are observed because the fractions are mixtures of species containing a full complement of FeMoco and P-clusters and species lacking some or all of these clusters. On the basis of the Mo contents and EPR spectroscopy of the mutant fractions, we propose that the loss of the P-clusters causes (i) the physical loss or inhibition of binding of some FeMoco; (ii) the EPR and catalytic inactivation of some FeMoco; and/or (iii) the incorporation of a FeMoco-like species into the FeMoco site of the mutant molecules.