Nucleotide-iron-sulfur cluster signal transduction in the nitrogenase iron-protein: the role of Asp125.

Electron transfer in nitrogenase involves a gating process initiated by MgATP (magnesium adenosine triphosphate) binding to Fe-protein. The redox site, an 4Fe:4S cluster, is structurally separated from the MgATP binding site. For MgATP hydrolysis to be coupled to electron transfer, a signal transduction mechanism is proposed that is similar to that in guanosine triphosphatase proteins. Based on the three-dimensional structure of Fe-protein, Asp125 is likely to be part of a putative transduction path. Altered Fe-protein with Glu replacing Asp has been prepared and retains the ability for the initial nucleotide-dependent conformational change. However, either MgADP or MgATP can induce the shift and Mg binding to the nucleotide is no longer essential.

Nitrogen Fixation by Azotobacter vinelandii Strains Having Deletions in Structural Genes for Nitrogenase.

Phenotypic reversal of Nif(-) mutant strains to Nif(+) under molybdenum-deficient conditions has been cited as evidence that Azotobacter vinelandii possesses two nitrogen fixation systems: the conventional molybdenum-enzyme system and an alternative nitrogen-fixation system. Since explanations other than the existence of an alternative system were possible, deletion strains of A. vinelandii lacking the structural genes for conventional nitrogenase (nifHDK) were constructed. These strains were found to grow in molybdenum-deficient nitrogen-free media, reduce acetylene (at low rates), and incorporate molecular nitrogen labeled with nitrogen-15. Thus it can be concluded that the phenotypic reversal phenomenon cannot be due to altered phenotypic expression of nif mutations under molybdenum-deficient conditions, but is due to the existence of an alternative nitrogen-fixation system in A. vinelandii as originally proposed.

Infrared spectroscopy of the nitrogenase MoFe protein under electrochemical control: potential-triggered CO binding.

We demonstrate electrochemical control of the nitrogenase MoFe protein, in the absence of Fe protein or ATP, using europium(iii/ii) polyaminocarboxylate complexes as electron transfer mediators. This allows the potential dependence of proton reduction and inhibitor (CO) binding to the active site FeMo-cofactor to be established. Reduction of protons to H2 is catalyzed by the wild type MoFe protein and ß-98Tyr→His and ß-99Phe→His variants of the MoFe protein at potentials more negative than -800 mV (vs. SHE), with greater electrocatalytic proton reduction rates observed for the variants compared to the wild type protein. Electrocatalytic proton reduction is strongly attenuated by carbon monoxide (CO), and the potential-dependence of CO binding to the FeMo-cofactor is determined by in situ infrared (IR) spectroelectrochemistry. The vibrational wavenumbers for CO coordinated to the FeMo-cofactor are consistent with earlier IR studies on the MoFe protein with Fe protein/ATP as reductant showing that electrochemically generated states of the protein are closely related to states generated with the native Fe protein as electron donor.

Evidence that conserved residues Cys-62 and Cys-154 within the Azotobacter vinelandii nitrogenase MoFe protein α-subunit are essential for nitrogenase activity but conserved residues His-83 and Cys-88 are not.

Metallocluster extrusion requirements, interspecies MoFe-protein primary sequence comparisons and comparison of the primary sequences of the MoFe-protein subunits with each other have been used to assign potential P-cluster (Fe-S cluster) domains within the MoFe protein. In each ß unit of the MoFe protein, subunit domains, which include potential Fe-S cluster ligands Cys-62, His-83, Cys-88 and Cys-154, and ß-subunit domains, which include potential Fe-S cluster ligands Cys-70, His-90, Cys-95 and Cys-153, are proposed to comprise nearly equivalent P-cluster environments located adjacent to each other in the native protein. As an approach to test this model and to probe the functional properties of the P clusters, amino acid residue substitutions were placed at the α- subunit Cys-62, His-83, Cys-88 and Cys-154 positions by site-directed mutagenesis of the Azotobacter vinelandii nifD gene. The diazotrophic growth rates. MoFe-protein acetylene-reduction activities, and whole-cell S 3/2 electron paramagnetic resonance spectra of these mutants were examined. Results of these experiments show that MoFe-protein α-submit residues, Cys-62 and Cys-154, are probably essential for MoFe-protein activity but that His-83 and Cys-88 residues are not. These results indicate either that His-83 and Cys-88 do not provide essential P-cluster ligand or that a new cluster-ligand arrangement is formed in their absence.

Gene dosage analysis in Azotobacter vinelandii.

For more than a decade, Azotobacter vinelandii has been considered a polyploid bacterium on the basis of physical studies of chromosome size and DNA content per cell. However, as described in the present work, many genetic operations can be performed in A. vinelandii without the constraints expected in a polyploid bacterium: (i) reversion of transposon-induced mutations is usually associated with loss of the transposable element; (ii) revertants retaining the transposon always carry secondary transpositions; (iii) heterozygotic transconjugants and transformants are unstable and segregate homozygotic colonies even in the absence of selection. Physical monitoring of segregation, achieved by colony hybridization, indicates that phenotypic expression of an allele is always correlated with its physical presence, thus ruling out the existence of either threshold dosage requirements or transcriptionally inactive DNA. Chromosomal lac fusions constructed by double crossover with a linearized plasmid show a segregation pattern consistent with the inheritance of one or several chromosomes per daughter cell. Analysis of the delay required for the expression of recessive chromosomal mutations such as rif, nal and str provides further evidence that A. vinelandii is not a polyploid bacterium.

Complete nucleotide sequence of the Azotobacter vinelandii nitrogenase structural gene cluster.

DNA fragments coding for the structural genes for Azotobacter vinelandii nitrogenase have been isolated and sequenced. These genes, nifH, nifD and nifK, code for the iron (Fe) protein and the alpha and beta subunits of the molybdenum-iron (MoFe) protein, respectively. They are arranged in the order: promoter:nifH:nifD:nifK. There are 129 nucleotides separating nifH and nifD and 101 nucleotides separating nifD and nifK. The amino acid (aa) sequences deduced from the nucleotide sequences are discussed in relation to the prosthetic group-binding regions of the nifHDK-encoded polypeptides.

The role of the MoFe protein alpha-125Phe and beta-125Phe residues in Azotobacter vinelandii MoFe protein-Fe protein interaction.

Site-directed mutagenesis and gene-replacement techniques were used to substitute alanine for the MoFe protein alpha- and beta-subunit phenylalanine-125 residues both separately and in combination. These residues are located on the surface of the MoFe protein near the pseudosymmetric axis of symmetry between the alpha- and beta-subunits. Altered MoFe proteins that contain an alanine substitution at only one of the respective positions exhibit proton reduction activities of about 25-50% when compared to that of the wild-type protein. The lower level of proton reduction also corresponds with decreases in the rates of MgATP hydrolysis. The MoFe protein which contains alanine substitutions in both the alpha- and beta- subunits did not exhibit any proton reduction activity or MgATP hydrolysis. Stopped flow spectrophotometry of the singly substituted MoFe proteins indicate primary electron transfer rate constants approximately an order of magnitude slower than what is observed for wild-type MoFe protein, while no primary electron transfer is observed for the doubly substituted MoFe protein. The doubly substituted MoFe protein is able to interact with the Fe protein as shown by chemical crosslinking experiments. However, this protein does not form a tight complex with the Fe protein when treated with MgADP-AlF4- or when using the altered 127delta Fe protein. Stopped flow spectrophotometry was also used to quantitate the first-order dissociation rate constants for the two component proteins. These results suggest that the 125Phe residues are involved in an early event(s) that occurs upon component protein docking and could be involved in eliciting MgATP hydrolysis.

NifU and NifS are required for the maturation of nitrogenase and cannot replace the function of isc-gene products in Azotobacter vinelandii.

In recent years, it has become evident that [Fe-S] proteins, such as hydrogenase, nitrogenase and aconitase, require a complex machinery to assemble and insert their associated [Fe-S] clusters. So far, three different types of [Fe-S] cluster biosynthetic systems have been identified and these have been designated nif, isc and suf. In the present work, we show that the nif-specific [Fe-S] cluster biosynthetic system from Azotobacter vinelandii, which is required for nitrogenase maturation, cannot functionally replace the isc [Fe-S] cluster system used for the maturation of other [Fe-S] proteins, such as aconitase. The results indicate that, in certain cases, [Fe-S] cluster biosynthetic machineries have evolved to perform only specialized functions.

Azotobacter vinelandii nifD- and nifE-encoded polypeptides share structural homology.

The Azotobacter vinelandii nifE gene was isolated and its complete nucleotide sequence was determined. The amino acid sequences deduced from the A. vinelandii nifE and nifD gene sequences were compared and found to share striking primary sequence homology. This homology implies a functional and possibly an evolutionary relationship between these two gene products. The structural homology is discussed with regard to the potential FeMo cofactor binding properties of these polypeptides and the possible role of a nifEN product complex as a surrogate MoFe protein.

Catalytic formation of a nitrogenase iron-sulfur cluster.

Biological nitrogen fixation is catalyzed by nitrogenase, an enzyme comprised of two component proteins called the Fe protein and the MoFe protein. Both nitrogenase component proteins contain metalloclusters. The Azotobacter vinelandii nifS gene product (NifS), which is required for full activation of the nitrogenase component proteins, is a pyridoxal phosphate enzyme and is able to catalyze the desulfurization of L-cysteine to yield sulfur and L-alanine (Zheng, L., White, R. H., Cash, V.L., Jack, R.F., and Dean, D.R. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 2754-2758). An enzyme-bound persulfide that was identified as an intermediate in the cysteine desulfurization reaction catalyzed by NifS has been suggested as a possible S-donor in formation of the iron-sulfide cores of the nitrogenase metalloclusters. In the present work it is shown that NifS is able to effectively catalyze activation of an apo-form of the Fe protein that was prepared by removal of its Fe4S4 cluster using the chelator, alpha,alpha'-dipyridyl. The reconstitution reaction includes apo-Fe protein, NifS, L-cysteine, ferrous ion, dithiothreitol, and MgATP. Reconstitution of the inactive apo-Fe protein catalyzed by NifS results in 80-95% recovery of the original activity and yields an Fe protein having the normal electron paramagnetic resonance spectra properties associated with the Fe protein's Fe4S4 cluster. An altered NifS protein, NifS-Ala325, which lacks the desulfurase activity and is unable to from the NifS-bound persulfide, is not able to catalyze reactivation of the apo-Fe protein. These in vitro results support the proposal that NifS activity provides the inorganic sulfide necessary for in vivo formation of the nitrogenase metalloclusters. Moreover, because NifS has recently been shown to be a member of a highly homologous gene family, it appears that pyridoxal phosphate chemistry might play a general role in iron-sulfur cluster assembly.

Selection of Bacillus subtilis mutants impaired in ammonia assimilation.

The selection of Bacillus subtilis mutants capable of using D-histidine to fulfill a requirement for L-histidine resulted in mutants with either no glutamate synthase activity or increased amounts of an altered glutamine synthetase.

Activity, reconstitution, and accumulation of nitrogenase components in Azotobacter vinelandii mutant strains containing defined deletions within the nitrogenase structural gene cluster.

The Azotobacter vinelandii genes encoding the nitrogenase structural components are clustered and ordered: nifH (Fe protein)-nifD (MoFe protein alpha subunit)-nifK (MoFe protein beta subunit). In this study various A. vinelandii mutant strains which contain defined deletions within the nitrogenase structural genes were isolated and studied. Mutants deleted for the nifD or nifK genes were still able to accumulate significant amounts of the unaltered MoFe protein subunit as well as active Fe protein. Extracts of such nifD or nifK deletion strains had no MoFe protein activity. However, active MoFe protein could be reconstituted by mixing extracts of the mutant strains. These results establish an approach for the purification of the individual MoFe protein subunits. Mutants lacking either or both of the MoFe protein subunits were still able to synthesize the iron-molybdenum cofactor (FeMo-cofactor), indicating that in A. vinelandii the FeMo-cofactor is preassembled and inserted into the MoFe protein. In contrast, a mutant strain lacking both the Fe protein and the MoFe protein failed to accumulate any detectable FeMo-cofactor. The further utility of specifically altered A. vinelandii strains for the study of the assembly, structure, and reactivity of nitrogenase is discussed.

Nucleotide sequence and mutagenesis of the nifA gene from Azotobacter vinelandii.

The nucleotide sequence of the nifA gene from Azotobacter vinelandii was determined. This gene encodes an Mr = 58,100 polypeptide that shares significant sequence identity when compared to nifA-encoded products from other organisms. Interspecies comparisons of nifA-encoded products reveal that they all have a consensus ATP binding site and a consensus DNA binding site in highly conserved regions of the respective polypeptides. The nifA gene immediately precedes the nifB-nifQ gene region but is unlinked to the major nif gene cluster from A. vinelandii. A potential regulatory gene precedes and is apparently cotranscribed with nifA. Mutant strains that have a deletion or a deletion plus an insertion within nifA are incapable of diazotrophic growth and they fail to accumulate nitrogenase structural gene products.

Nitrogenase-catalyzed ethane production and CO-sensitive hydrogen evolution from MoFe proteins having amino acid substitutions in an alpha-subunit FeMo cofactor-binding domain.

Unlike wild type, certain Mo-dependent nitrogenases, which are expressed in non-N2-fixing mutant strains of Azotobacter vinelandii and have single amino acid substitutions within a region of the MoFe protein alpha-subunit proposed to encompass an FeMo cofactor-binding domain, are able to catalyze the reduction of acetylene by both two and four electrons to yield ethylene and ethane, respectively (Scott, D. J., May, H. D., Newton, W. E., Brigle, K. E., and Dean, D. R. (1990) Nature 343, 188-190). Although the V-dependent nitrogenase is also able to catalyze the reduction of acetylene to the same two- and four-electron products (Dilworth, M. J., Eady, R. R., Robson, R. L., and Miller, R. W. (1987) Nature 327, 167-168), we find that ethane formation from acetylene catalyzed by the altered Mo-dependent nitrogenases occurs by a different mechanism, which is distinguished by: (i) an increased sensitivity to CO; (ii) the absence of a lag; and (iii) no temperature dependence of product distribution among ethylene and ethane during acetylene reduction. An altered MoFe protein, which was purified from one such mutant strain having the alpha-subunit glutaminyl 191 residue substituted by lysyl, exhibited both a changed S = 3/2 EPR spectrum and changes in the distribution of electrons to various products when compared to wild type. Also, unlike wild type, this altered MoFe protein catalyzed proton reduction that is inhibited by carbon monoxide (CO). Because proton reduction catalyzed by a nitrogenase that has a FeMo cofactor with citrate rather than homocitrate as its organic constituent (Liang, J., Madden, M., Shah, V. K., and Burris, R. H. (1990) Biochemistry 29, 8577-8581) is also inhibited by CO, the possibility arose that changes in the polypeptide environment of FeMo cofactor might have caused a rearrangement in its molecular structure or composition. However, this possibility was ruled out by biochemical reconstitution studies (using FeMo cofactor isolated from both the wild-type and altered MoFe proteins), which were monitored by EPR spectroscopy and resulting catalytic activity.

Biosynthesis of iron-sulphur clusters is a complex and highly conserved process.

Iron-sulphur ([Fe-S]) clusters are simple inorganic prosthetic groups that are contained in a variety of proteins having functions related to electron transfer, gene regulation, environmental sensing and substrate activation. In spite of their simple structures, biological [Fe-S] clusters are not formed spontaneously. Rather, a consortium of highly conserved proteins is required for both the formation of [Fe-S] clusters and their insertion into various protein partners. Among the [Fe-S] cluster biosynthetic proteins are included a pyridoxal phosphate-dependent enzyme (NifS) that is involved in the activation of sulphur from l-cysteine, and a molecular scaffold protein (NifU) upon which [Fe-S] cluster precursors are formed. The formation or transfer of [Fe-S] clusters appears to require an electron-transfer step. Another complexity is that molecular chaperones homologous to DnaJ and DnaK are involved in some aspect of the maturation of [Fe-S]-cluster-containing proteins. It appears that the basic biochemical features of [Fe-S] cluster formation are strongly conserved in Nature, since organisms from all three life Kingdoms contain the same consortium of homologous proteins required for [Fe-S] cluster formation that were discovered in the eubacteria.

Altered nitrogenase MoFe proteins from Azotobacter vinelandii. Analysis of MoFe proteins having amino acid substitutions for the conserved cysteine residues within the beta-subunit.

The regions surrounding the three strictly conserved cysteine residues (positions 70, 95 and 153) in the beta-subunit of the Azotobacter vinelandii nitrogenase MoFe protein have been proposed to provide P-cluster environments [Dean, Setterquist, Brigle, Scott, Laird & Newton (1990) Mol. Microbiol. 4, 1505-1512]. In the present study, each of these cysteine residues was individually substituted by either serine or alanine by site-directed mutagenesis of the nifK gene, which encodes the MoFe protein beta-subunit. A mutant strain for which the codon for Cys-153 is removed was also isolated. Significant structural or functional roles are indicated for the cysteine residues at positions 70 and 95, where substitution by either serine or alanine eliminates diazotrophic growth of the resulting strains and abolishes or markedly decreases both MoFe-protein acetylene-reduction activity and the intensity of the whole-cell S = 3/2 e.p.r. signal. Changes introduced at position 153 have various effects on the functional properties of the enzyme. The strains produced either by deletion of the Cys-153 residue or its substitution by serine exhibit only a moderate decrease in diazotrophic growth and MoFe-protein activity and no loss of the whole-cell e.p.r.-signal intensity. In contrast, substitution by alanine eliminates diazotrophic growth and very markedly decreases both MoFe-protein activity and e.p.r.-signal intensity. These results are interpreted in terms of a metallocluster-driven protein rearrangement. After purification of the altered MoFe protein, in which serine replaces Cys-153, an investigation of its catalytic and spectroscopic properties confirms that neither the FeMo cofactor, i.e. the substrate-reduction site, nor the component-protein interaction site has been affected. Instead, these data indicate a disruption in electron transfer within the MoFe protein, which is consistent with a role for this residue (and region) at the P clusters.

Nitrogenase structure and function: a biochemical-genetic perspective.

Biological nitrogen fixation is catalyzed by nitrogenase, an enzyme composed of two component proteins called the Fe protein and the MoFe protein. During catalysis, electrons are delivered one at a time from the Fe protein to the MoFe protein in a process involving component-protein association and dissociation and hydrolysis of at least two MgATP for each electron transfer. The Fe protein contains the sites for MgATP binding and hydrolysis, whereas the site for substrate binding and reduction is located on the MoFe protein. Among the important aspects of nitrogenase enzymology discussed here are (a) the structures of the metal centers that participate in electron transfer, (b) the organization of the metalloclusters within the polypeptides and their contributions to substrate binding and electron transfer, (c) the nature of the dynamic interactions between the two component proteins that lead to nucleotide hydrolysis and intermolecular electron transfer, (d) the mechanism by which the multiple electrons necessary for substrate reduction are distributed within the MoFe protein, (e) the nature of the intramolecular electron path within the MoFe protein, and (f) where and how substrate and various inhibitors become bound to the substrate-reduction site. This chapter summarizes biochemical-genetic strategies used to address these questions and discussed them in the context of the recently proposed three-dimensional models for both the Fe protein and MoFe protein from Azotobacter vinelandii.

Characterization of the gamma protein and its involvement in the metallocluster assembly and maturation of dinitrogenase from Azotobacter vinelandii.

Dinitrogenase, the enzyme capable of catalyzing the reduction of N2, is a heterotetramer (alpha 2 beta 2) and contains the iron-molybdenum cofactor (FeMo-co) at the active site of the enzyme. Mutant strains unable to synthesize FeMo-co accumulate an apo form of dinitrogenase, which is enzymatically inactive but can be activated in vitro by the addition of purified FeMo-co. Apodinitrogenase from certain mutant strains of Azotobacter vinelandii has a subunit composition of alpha 2 beta 2 gamma 2. The gamma subunit has been implicated as necessary for the efficient activation of apodinitrogenase in vitro. Characterization of gamma protein in crude extracts and partially pure fractions has suggested that it is a chaperone-insertase required by apodinitrogenase for the insertion of FeMo-co. These are three major forms of gamma protein detectable by Western analysis of native gels. An apodinitrogenase-associated form is found in extracts of nifB or nifNE strains and dissociates from the apocomplex upon addition of purified FeMo-co. A second form of gamma protein is unassociated with other proteins and exists as a homodimer. Both of these forms of gamma protein can be converted to a third form by the addition of purified FeMo-co. This conversion requires the addition of active FeMo-co and correlates with the incorporation of iron into gamma protein. Crude extracts that contain this form of gamma protein are capable of donating FeMo-co to apodinitrogenase, thereby activating the apodinitrogenase. These data support a model in which gamma protein is able to interact with both FeMo-co and apodinitrogenase, facilitate FeMo-co insertion into apodinitrogenase, and then dissociate from the activated dinitrogenase complex.

Role of the MoFe protein alpha-subunit histidine-195 residue in FeMo-cofactor binding and nitrogenase catalysis.

Site-directed mutagenesis and gene-replacement procedures were used to isolate mutant strains of Azotobacter vinelandii that produce altered MoFe proteins in which the alpha-subunit residue-195 position, normally occupied by a histidine residue, was individually substituted by a variety of other amino acids. Structural studies have revealed that this histidine residue is associated with the FeMo-cofactor binding domain and probably provides an NH-->S hydrogen bond to a central bridging sulfide located within FeMo-cofactor. Substitution by a glutamine residue results in an altered MoFe protein that binds but does not reduce N2, the physiological substrate. Although N2 is not a substrate for the altered MoFe protein, it is a potent inhibitor of both acetylene and proton reduction, both of which are otherwise effectively reduced by the altered MoFe protein. This result provides evidence that N2 inhibits proton and acetylene reduction by simple occupancy of a common active site. N2 also uncouples MgATP from proton reduction catalyzed by the altered MoFe protein but does so without lowering the overall rate of MgATP hydrolysis. Thus, the quasi-unidirectional flow of electrons from the Fe protein to the MoFe protein that occurs during nitrogenase turnover is controlled, in part, by the substrate serving as an effective electron sink. Substitution of the alpha-histidine-195 residue by glutamine also imparts to the altered MoFe protein hypersensitivity of both its acetylene reduction and N2 binding to inhibition by CO, indicating that the imidazole group of the alpha-histidine-195 residue might protect an Fe contained within the FeMo-cofactor from attack by CO. Finally, comparisons of the catalytic and spectroscopic properties of altered MoFe proteins produced by various mutant strains suggest that the alpha-histidine-195 residue has a structural role, which serves to keep FeMo-cofactor attached to the MoFe protein and to correctly position FeMo-cofactor within the polypeptide matrix, such that N2 binding is accommodated.

Role of NifS in maturation of glutamine phosphoribosylpyrophosphate amidotransferase.

Glutamine phosphoribosylpyrophosphate amidotransferase from Bacillus subtilis is synthesized as an inactive precursor that requires two maturation steps: incorporation of a [4Fe-4S] center and cleavage of an 11-residue NH2-terminal propeptide. Overproduction from a multicopy plasmid in Escherichia coli leads to the formation of soluble proenzyme and mature enzyme forms as well as a small fraction of insoluble proenzyme. Heterologous expression of Azotobacter vinelandii nifS from a compatible plasmid increased the maturation of the soluble proenzyme three- to fourfold without influencing the content of the insoluble fraction. These results support a role for NifS in heterologous Fe-S cluster assembly and enzyme maturation.