Physical and genetic map of the major nif gene cluster from Azotobacter vinelandii

Determination of a 28,793-base-pair DNA sequence of a region from the Azotobacter vinelandii genome that includes and flanks the nitrogenase structural gene region was completed. This information was used to revise the previously proposed organization of the major nif cluster. The major nif cluster from A. vinelandii encodes 15 nif-specific genes whose products bear significant structural identity to the corresponding nif-specific gene products from Klebsiella pneumoniae. These genes include nifH, nifD, nifK, nifT, nifY, nifE, nifN, nifX, nifU, nifS, nifV, nifW, nifZ, nifM, and nifF. Although there are significant spatial differences, the identified A. vinelandii nif-specific genes have the same sequential arrangement as the corresponding nif-specific genes from K. pneumoniae. Twelve other potential genes whose expression could be subject to nif-specific regulation were also found interspersed among the identified nif-specific genes. These potential genes do not encode products that are structurally related to the identified nif-specific gene products. Eleven potential nif-specific promoters were identified within the major nif cluster, and nine of these are preceded by an appropriate upstream activator sequence. A + T-rich regions were identified between 8 of the 11 proposed nif promoter sequences and their upstream activator sequences. Site-directed deletion-and-insertion mutagenesis was used to establish a genetic map of the major nif cluster.

Biochemical and genetic analysis of the nifUSVWZM cluster from Azotobacter vinelandii

Azotobacter vinelandii genes contained within the major nif-cluster and designated orf6, nifU, nifS, nifV, orf7, orf8, nifW, nifZ, nifM, and orf9 are organized into at least two overlapping transcriptional units. Nitrogenase derepressed crude extracts of Azotobacter vinelandii mutant strains having individual deletions located within nifU, nifS, nifV, nifW, nifZ, or nifM were examined for nitrogenase component protein activities. The results of these experiments indicated that, in A. vinelandii, the nifU, nifS and nifM gene products are required for the full activation or the catalytic stability of the nitrogenase Fe protein. Deletion of the nifV gene resulted in lower MoFe protein activity, probably resulting from the accumulation of an altered FeMo-cofactor. The nifW and nifZ gene products were required for the full activation or catalytic stability of the MoFe protein. Deletion of nifZ alone or nifM alone did not appear to affect FeMo-cofactor biosynthesis. However, deletion of both nifZ and nifM eleminated either FeMo-cofactor biosynthesis or the insertion of FeMo-cofactor into the apo-MoFe protein. Other genes contained within the nifUSVWZM gene cluster (orf6, orf7, orf8, and orf9) were not required for Mo-dependent diazotrophic growth.

Evidence for an alternative nitrogen fixation system in Azotobacter vinelandii

Two Azotobacter vinelandii strains capable of growing on N2(Nif+) were isolated from two different mutant strains that lacked dinitrogenase activity (Nif-). Extracts of N2-grown cells of the two Nif+ strains lacked significant amounts of the "conventional" dinitrogenase protein subunits, as determined by two-dimensional gel electrophoresis. Instead, the extracts contained at least four new proteins that appeared to be ammonia-repressible (i.e., they were not detected in extracts of ammonia-grown cells). Based on the results of genetic backcrosses, the two Nif+ strains were shown to be pseudorevertants. Both Nif+ pseudorevertant strains were able to grow in N-free media lacking molybdenum but containing tungsten (conditions that prevented growth of the wild-type strain). The four new proteins were observed in extracts of N2-fixing cells of the Nif+ pseudorevertants regardless of whether the cells were grown in the presence of molybdenum-starved wild-type A. vinelandii cells grown under N2-fixing conditions. Under conditions of molybdenum deprivation, Nif- mutant strains of several different phenotypic classes underwent phenotypic reversal to Nif+, as shown by their ability to incorporate 15N2 and to grow in N-free media. These results provide evidence that A. vinelandii possesses an alternative N2-fixation system that is expressed during conditions of molybdenum deficiency.

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.

Nucleotide sequence and genetic analysis of the nifB-nifQ region from Azotobacter vinelandii

A 3.8-kilobase-pair EcoRI fragment which corrects the mutations carried by the NifB- Azotobacter vinelandii strains CA30 and UW45 was cloned, and its nucleotide sequence was determined. Four complete open reading frames (ORFs) and two partial ORFs were found. The translation product of the first partial ORF is the carboxy-terminal end of a protein homologous to the nifA gene product from Klebsiella pneumoniae. A 285-base-pair sequence containing a potential nif promoter and nif regulatory sites separates this nifA gene from the first complete ORF which encodes a protein homologous to nifB gene products from K. pneumoniae and Rhizobium species. The Tn5 insertion in strain CA30 and the nif-45 mutation of strain UW45 are located within this nifB gene. The ORF downstream from nifB predicts an amino acid sequence with a cysteine residue pattern that is characteristic of ferredoxins. No similarities were found between the translation product of the third complete ORF and those of nif genes from other organisms. At the carboxy-terminal end of the predicted translation product of the fourth complete ORF, 30 of 60 amino acid residues were identical with the sequence of the nifQ gene product from K. pneumoniae. The partial ORF located at the end of the fragment encodes the N-terminal part of a potential protein with an unknown function. Northern (RNA) blot analysis indicated that transcripts from the region containing the four complete ORFs were NH4+ repressible and that the transcription products were identical in cells derepressed under conditions of Mo sufficiency or Mo deficiency or in the presence of vanadium. In contrast to the NifB- strain CA30, which is Nif- under all conditions, mutants that carry mutations affecting the C-terminal end of nifB or genes located immediately downstream from nifB, grew under all N2-fixing conditions. However, in the presence of Mo, most of the strains required 1,000 times the amount of molybdate that is sufficient for maximal growth of the wild-type strain CA under N2-fixing conditions. Growth data from strain CA37, which carries a Kanr insertion in nifQ, indicate that nifQ in A. vinelandii is not required for N2 fixation in the presence of V2O5 or under Mo-deficient conditions. Growth studies and acetylene reduction assays performed on two nifEN deletion strains showed that nifE and nifN are required for N2 fixation under Mo sufficiency, as previously observed (K. E. Brigle, M. C. Weiss, W. E. Newton, and D. R. Dean, J. Bacteriol. 169:1547-1553, 1987), but not under conditions of Mo deficiency or in the presence of 50 nM V2O5.

Products of the iron-molybdenum cofactor-specific biosynthetic genes, nifE and nifN, are structurally homologous to the products of the nitrogenase molybdenum-iron protein genes, nifD and nifK

The genes from Azotobacter vinelandii, which are homologous to the iron-molybdenum cofactor biosynthetic genes, nifE and nifN, from Klebsiella pneumoniae, have been cloned and sequenced. These genes comprise a single transcription unit and are located immediately downstream from the nitrogenase structural gene cluster (nifHDK). DNA sequence analysis has revealed that the products of the nifE and nifN genes contain considerable homology when compared with the nifD (MoFe protein alpha subunit) and the nifK (MoFe protein beta subunit) gene products, respectively. These striking sequence homologies indicate a structural and functional relationship between a proposed nifEN product complex and the nitrogenase MoFe protein as well as imply an ancestral relationship between these gene clusters. The isolation and characterization of strains which contain deletions within the nifEN gene cluster demonstrate a role for these products in iron-molybdenum cofactor biosynthesis in A. vinelandii.

Cloning and mutagenesis of genes encoding the cytochrome bd terminal oxidase complex in Azotobacter vinelandii: mutants deficient in the cytochrome d complex are unable to fix nitrogen in air

The genome of Azotobacter vinelandii contains DNA sequences homologous to the structural genes for the Escherichia coli cytochrome bd terminal oxidase complex. Two recombinant clones bearing cydA- and cydB-like sequence were isolated from an A. vinelandii gene library and subcloned into the plasmid vector pACYC184. Physical mapping demonstrated that the cydA- and cydB-like regions in A. vinelandii are contiguous. The cydAB and flanking DNA was mutagenized by the insertion of Tn5-B20. Mutations in the cydB-hybridizing region resulted in the loss of spectral features associated with cytochromes b595 and d. A new locus, cydB, encoding cytochromes b595 and d in A. vinelandii is proposed. A second region adjacent to cydB was also involved in expression of the cytochrome bd complex in A. vinelandii, since mutations in this region resulted in an increase in the levels of both cytochrome b595 and cytochrome d. The regions involved in expression of the cytochrome bd complex and cydB are transcribed in the same direction. Mutants deficient in cytochromes b595 and d were unable to grow on N-deficient medium when incubated in air but could fix nitrogen when the environmental O2 concentration was reduced to 1.5% (vol/vol). It is proposed that the branch of the respiratory chain terminated by the cytochrome bd complex supports the high respiration rates required for the respiratory protection of nitrogenase.

Bacterial alginate biosynthesis--recent progress and future prospects

The extracellular polysaccharide alginate has been widely associated with chronic Pseudomonas aeruginosa infections in the cystic fibrosis lung. However, it is clear that alginate biosynthesis is a more widespread phenomenon. Alginate plays a key role as a virulence factor of plant-pathogenic pseudomonads, in the formation of biofilms and with the encystment process of Azotobacter spp.

Optimal conditions for transformation of Azotobacter vinelandii

Optimal transformation of Azotobacter vinelandii OP required a 20-min incubation of the competent cells with deoxyribonucleic acid at 30 degrees C in buffer (pH 6.0 to 8.0) containing 8 mM magnesium sulfate. Nitrogen-fixing transformants of nitrogen fixation-deficient recipients could be plated immediately on selective medium, but transformants acquiring rifampin and streptomycin resistance required preincubation in nonselective medium. The three phenotypes achieved an approximately equal and stable frequency after 17 h (six generations) of growth in nonselective medium.

Genetic characterization of the stabilizing functions of a region of broad-host-range plasmid RK2

One of the regions responsible for the stable inheritance of the broad-host-range plasmid RK2 is contained within the PstI C fragment, located from coordinates 30.8 to 37.0 kb (P.N. Saurugger, O. Hrabak, H. Schwab, and R.M. Lafferty, J. Biotechnol. 4:333-343, 1986). Genetic analysis of this 6.2-kb region demonstrated that no function was present that stabilized by selectively killing plasmid-free segregants. The sequence from 36.0 to 37.0 kb mediated a twofold increase in plasmid copy number, but this region was not required for stabilization activity. The PstI C fragment was shown to encode a multimer resolution system from 33.1 to 35.3 kb. The resolution cis-acting site was mapped to 140 bp, sequenced, and observed to contain two directly repeated sequences of 6 and 7 bases and two perfect inverted repeats of 6 and 8 bases. The trans-acting factor(s) was mapped and functionally determined to encode a resolvase capable of catalyzing recombination at high frequency between cis-acting sites in either direct or inverted orientation. Multimer resolution alone did not account for complete plasmid stabilization by the PstI C fragment, since removal of regions adjacent to the 35.3-kb border of the minimal mrs locus dramatically reduced stabilization. The minimal region required for complete stabilization, from 32.8 to 35.9 kb, was capable of fully stabilizing plasmids independently of the replicon or the recA proficiency of the host. Stabilization activity was also fully expressed in several diverse gram-negative bacteria, whereas the F plasmid par locus functioned only in Escherichia coli. On the basis of these observations, we conclude that under the growth conditions used, the minimal stabilization locus encodes both an mrs activity and a stabilization activity that has the properties of a par locus.

Nucleotide sequence and mutational analysis of the structural genes (anfHDGK) for the second alternative nitrogenase from Azotobacter vinelandii

The nucleotide sequence of a region of the Azotobacter vinelandii genome exhibiting sequence similarity to nifH has been determined. The order of open reading frames within this 6.1-kilobase-pair region was found to be anfH (alternative nitrogen fixation, nifH-like gene), anfD (nifD-like gene), anfG (potentially encoding a protein similar to the product of vnfG from Azotobacter chroococcum), anfK (nifK-like gene), followed by two additional open reading frames. The 5'-flanking region of anfH contains a nif promoter similar to that found in the A. vinelandii nifHDK gene cluster. The presumed products of anfH, anfD, and anfK are similar in predicted Mr and pI to the previously described subunits of nitrogenase 3. Deletion plus insertion mutations introduced into the anfHDGK region of wild-type strain A. vinelandii CA resulted in mutant strains that were unable to grow in Mo-deficient, N-free medium but grew in the presence of 1 microM Na2MoO4 or V2O5. Introduction of the same mutations into the nifHDK deletion strain CA11 resulted in strains that grew under diazotrophic conditions only in the presence of vanadium. The lack of nitrogenase 3 subunits in these mutant strains was demonstrated through two-dimensional gel analysis of protein extracts from cells derepressed for nitrogenase under Mo and V deficiency. These results indicate that anfH, anfD, and anfK encode structural proteins for nitrogenase 3.

Lipoamide dehydrogenase from Azotobacter vinelandii. Molecular cloning, organization and sequence analysis of the gene

The gene encoding lipoamide dehydrogenase from Azotobacter vinelandii has been cloned in Escherichia coli. Fragments of 9-23 kb from Azotobacter vinelandii chromosomal DNA obtained by partial digestion with Sau3A were ligated into the BamHI site of plasmid pUC9. E. coli TG2 cells were transformed with the resulting recombinant plasmids. Screening for clones which produced A. vinelandii lipoamide dehydrogenase was performed with antibodies raised against the purified enzyme. A positive colony was found which produced complete chains of lipoamide dehydrogenase as concluded form SDS gel electrophoresis of the cell-free extract, stained for protein or used for Western blotting. After subcloning of the 14.7-kb insert of this plasmid the structural gene could be located on a 3.2-kb DNA fragment. The nucleotide sequence of this subcloned fragment (3134 bp) has been determined. The protein-coding sequence of the gene consists of 1434 bp (478 codons, including the AUG start codon and the UAA stop codon). It is preceded by an intracistronic region of 85 bp and the structural gene for succinyltransferase. A putative ribosome-binding site and promoter sequence are given. The derived amino acid composition is in excellent agreement with that previously published for the isolated enzyme. The predicted relative molecular mass is 50223, including the FAD. The overall homology with the E. coli enzyme is high with 40% conserved amino acid residues. From a comparison with the three-dimensional structure of the related enzyme glutathione reductase [Rice, D. W., Schultz, G. E. & Guest, J. R. (1984) J. Mol. Biol. 174, 483-496], it appears that essential residues in all four domains have been conserved. The enzyme is strongly expressed, although expression does not depend on the vector-encoded lacZ promoter. The cloned enzyme is, in all the respects tested, identical with the native enzyme.

Effects of model root exudates on structure and activity of a soil diazotroph community

Nitrogen fixation is often enhanced in the rhizosphere as compared with bulk soil, due to asymbiotic microorganisms utilizing root exudates as an energy source. We have studied the activity and composition of asymbiotic soil diazotrophs following pulse additions of artificial root exudates and single carbon sources, simulating the situation of bulk soil coming into contact with exudates from growing roots. Artificial root exudates and single sugars rapidly induced nitrogen fixation. The population of potential diazotrophs was studied using universal and group-specific nifH polymerase chain reaction (PCR) and denaturing gradient gel electrophoresis (DGGE) analysis. Reverse transcription PCR of nifH mRNA confirmed that phylotypes with an apparently increasing population size also expressed the nitrogenase system. According to our results, the actively nitrogen-fixing population represents only a fraction of the total diazotroph diversity, and the results of group-specific nifH PCR and phylogenetic analysis of cloned nifH and 16S rRNA gene fragments identified active species that belonged to the genus Azotobacter. Rapid changes of transcriptional activity over time were observed, indicating different growth and activation strategies in different Azotobacter strains. Only sugar-containing substrates were able to induce nitrogen fixation, but substrate concentration and the presence of organic acids may have additional selective effects on the active diazotroph population.

Role for the nitrogenase MoFe protein alpha-subunit in FeMo-cofactor binding and catalysis

Two components constitute Mo-dependent nitrogenase (EC 1.18.6.1)--the Fe protein (a homodimer encoded by nifH) and the MoFe protein (an alpha 2 beta 2 tetramer encoded by nifDK). The MoFe protein provides the substrate-binding site and probably contains six prosthetic groups of two types--four Fe-S centres and two Fe- and Mo-containing cofactors. To determine the distribution and catalytic function of these metalloclusters, we and others are attempting to change the catalytic and spectroscopic features of nitrogenase by substituting specific amino acids targeted as potential metallocluster ligands, particularly those to the FeMo-cofactor, which is responsible for the biologically unique electron paramagnetic resonance signal (S = 3/2) of nitrogenase, and is believed to be the N2-reducing site. Here we describe mutant strains of Azotobacter vinelandii that have single amino-acid substitutions within the MoFe protein alpha-subunit. These substitutions alter both substrate-reduction properties and the unique electron paramagnetic resonance signal, indicating that the FeMo-cofactor is associated with both the alpha-subunit and the substrate-reducing site.

Nucleotide sequences and mutational analysis of the structural genes for nitrogenase 2 of Azotobacter vinelandii

The nucleotide sequence (6,559 base pairs) of the genomic region containing the structural genes for nitrogenase 2 (V nitrogenase) from Azotobacter vinelandii was determined. The open reading frames present in this region are organized into two transcriptional units. One contains vnfH (encoding dinitrogenase reductase 2) and a ferredoxinlike open reading frame (Fd). The second one includes vnfD (encoding the alpha subunit of dinitrogenase 2), vnfG (encoding a product similar to the delta subunit of dinitrogenase 2 from A. chroococcum), and vnfK (encoding the beta subunit of dinitrogenase 2). The 5'-flanking regions of vnfH and vnfD contain sequences similar to ntrA-dependent promoters. This gene arrangement allows independent expression of vnfH-Fd and vnfDGK. Mutant strains (CA80 and CA11.80) carrying an insertion in vnfH are still able to synthesize the alpha and beta subunits of dinitrogenase 2 when grown in N-free, Mo-deficient, V-containing medium. A strain (RP1.11) carrying a deletion-plus-insertion mutation in the vnfDGK region produced only dinitrogenase reductase 2.

Regulation of nitrogen metabolism in Azotobacter vinelandii: isolation of ntr and glnA genes and construction of ntr mutants

The ntrA, ntrB and ntrC products are responsible for regulating the transcription of many genes involved in the assimilation of poor nitrogen sources in enteric bacteria. The presence of a similar system in the non-enteric bacterium Azotobacter vinelandii is reported here. Genes analogous to ntrA and ntrC were isolated from an A. vinelandii gene library by complementation of Escherichia coli mutants. The gene encoding glutamine synthetase, glnA, was also isolated and found to be adjacent to ntrC but distant from ntrA, as it is in enteric organisms. The cloned Azotobacter genes also complemented Klebsiella pneumoniae mutants and hybridized to K. pneumoniae ntrA, ntrC and glnA gene probes. The role of ntrA and ntrC in A. vinelandii was established by using Tn5 insertions in the cloned genes to construct mutants by marker exchange. These mutants show that both ntrA and ntrC are required for the utilization of nitrate as a nitrogen source. However, ntrC is not required for nitrogen fixation by A. vinelandii, in contrast with K. pneumoniae where both ntrA and ntrC are essential.

Structural genes for the vanadium nitrogenase from Azotobacter chroococcum

Structural genes for the VFe-protein (Ac1V) of the vanadium nitrogenase from Azotobacter chroococcum were cloned and sequenced. The VFe-protein contains three subunit types with Mr of 53,793 (alpha), 52,724 (beta) and 13,274 (delta). alpha and beta subunits show 18 and 15% sequence identity respectively, with alpha and beta subunits of the MoFe-protein of A.chroococcum molybdenum nitrogenase. The genes for the three subunits vnfD (alpha), vnfG (delta) and vnfK (beta) are contiguous and form an operon whose transcription is repressed in response to ammonia. The Fe-protein component of the V-nitrogenase (Ac2V) is the product of nifH* that we have previously cloned and sequenced. This gene was located 2.5 kb upstream of vnfD. A deletion in the vnfD, G and K gene cluster prevents V-dependent nitrogen fixation. A strain defective in both V-nitrogenase and Mo-nitrogenase structural genes showed no residual nitrogen fixing capacity arguing against the presence of a third nitrogen fixation system in this organism.

Transcriptional regulation of nitrogen fixation by molybdenum in Azotobacter vinelandii

Multiple genomic regions homologous to nifH were found in the diazotroph Azotobacter vinelandii. The nifHDK gene cluster, located on a 12.8-kilobase (kb) XhoI fragment and two additional XhoI fragments (7.4 and 8.4 kb) hybridized to a nifH-specific DNA template but the 7.4- and 8.4-kb fragments did not hybridize to nifD- or nifK-specific DNA probes. In vivo transcription of the nifHDK gene cluster was ammonia-repressible and required the presence of at least 50 nM molybdenum in the derepression medium. Three mRNA species were transcribed from the nifHDK gene cluster, a 4.2-kb transcript homologous to nifH-, nifD-, and nifK-specific DNA templates, a 2.6-kb transcript homologous to nifH- and nifD-specific DNA templates, and a 1.2-kb transcript homologous only to the nifH-specific DNA template. In strain CA11, a nifHDK deletion mutant, the nifHDK-specific transcripts were not produced and the strain was unable to grow in N-free medium in the presence of Na2MoO4 at concentrations of 50 nM or higher. However, at concentrations of 25 nM Mo or less, growth occurred in N-free medium. Under these conditions two nifH-homologous (but not nifD- or nifK-homologous) transcripts were observed (1.2 and 1.8 kb). Presumably these were transcribed from the additional nifH-homologous sequences present in the genome. These results are consistent with the existence of two N2 fixation systems in A. vinelandii which are regulated by molybdenum at the level of transcription.

Genetic evidence for an Azotobacter vinelandii nitrogenase lacking molybdenum and vanadium

We have constructed a strain of Azotobacter vinelandii which has deletions in the genes for both the molybdenum (Mo) and vanadium (V) nitrogenases. This strain fixed nitrogen in medium that did not contain Mo or V. Growth and nitrogenase activity were inhibited by Mo and V. In highly purified medium, growth was limited by iron. Addition of other metals (Co, Cr, Cu, Mn, Ni, Re, Ti, W, and Zn) did not stimulate growth. Like the V-nitrogenase, the nitrogenase synthesized by the double deletion strain reduced acetylene to both ethylene and ethane (C2H6/C2H4 ratio, 0.046). There was an approximately 10-fold increase in ethane production when Mo was added to the deletion strain grown in medium lacking Mo and V. This change in reactivity may be due to the incorporation of an Mo-containing cofactor into the nitrogenase synthesized by the double-deletion strain. A strain synthesizing the V-nitrogenase did not show a similar increase in ethane production. The growth characteristics of the double-deletion strain, together with the metal composition reported for a nitrogenase isolated from a tungstate-tolerant strain lacking genes for the molydenum enzyme grown in the absence of Mo and V (J. R. Chisnell, R. Premakumar, and P. E. Bishop, J. Bacteriol. 170:27-33, 1988) show that A. vinelandii can synthesize a nitrogenase which lacks both Mo and V. Reduction of dinitrogen by nitrogenase can therefore occur at a center lacking both these metals.

In vitro synthesis of the iron-molybdenum cofactor of nitrogenase

Molybdate- and ATP-dependent in vitro synthesis of the iron-molybdenum cofactor (FeMo-co) of nitrogenase requires the protein products of at least the nifB, nifN, and nifE genes. Extracts of FeMo-co-negative mutants of Klebsiella pneumoniae and Azotobacter vinelandii with lesions in different genes can be complemented for FeMo-co synthesis. Both K. pneumoniae and A. vinelandii dinitrogenase (component I) deficient in FeMo-co can be activated by FeMo-co synthesized in vitro. Properties of the partially purified dinitrogenase activated by FeMo-co synthesized in vitro were comparable to those of dinitrogenase from the wild-type organism; e.g., ratios of acetylene- to nitrogen-reduction activities, as well as those of acetylene reduction activities to EPR spectrum peak height at g = 3.65, were very similar. A. vinelandii mutants UW45 and CA30 have mutations in a gene functionally equivalent to nifB of K. pneumoniae.

Biosynthesis of iron-molybdenum cofactor in the absence of nitrogenase

Klebsiella pneumoniae accumulates molybdenum during nitrogenase derepression. The molybdenum is primarily in nitrogenase component I in the form of iron-molybdenum cofactor (FeMo-co). Mutations in any of three genes (nifB, nifN, and nifE) involved in the biosynthesis of FeMo-co resulted in very low molybdenum accumulation and in a molybdenum-free nitrogenase component I. A mutant lacking both subunits of nitrogenase component I accumulated 60% of the amount of molybdenum present in the wild type. The molybdenum was in protein-bound form and behaved differently than that in the wild type with respect to electrophoretic mobility, size, and extractability by organic solvents. Two forms of molybdenum could be extracted from the protein fraction of the mutant; one of them was not detected in the wild type, and the other behaved like FeMo-co in nonaqueous gel filtration chromatography. Crude extracts of this mutant were able to complement in vitro K. pneumoniae or Azotobacter vinelandii mutants unable to produce FeMo-co. These data show that biosynthesis of FeMo-co does not require the presence of nitrogenase component I. In its absence, FeMo-co is accumulated on a different protein, presumably an intermediate in the normal FeMo-co biosynthetic pathway.

D-(-)-poly-beta-hydroxybutyrate in membranes of genetically competent bacteria

D-(-)-Poly-beta-hydroxybutyrate is a constituent of the membranes and the cytoplasms of genetically competent Azotobacter vinelandii, Bacillus subtilis, and Haemophilus influenzae cells. Within each species the concentration of D-(-)-poly-beta-hydroxybutyrate in the membranes and cytoplasm correlates with transformability. Fluorescence analysis of the thermotropic lipid phase transitions in A. vinelandii and B. subtilis cells indicates that D-(-)-poly-beta-hydroxybutyrate forms an organized gel structure in the membranes which is very labile. The concentration of organized D-(-)-poly-beta-hydroxybutyrate in the membranes, which can be estimated from the intensity of its phase transition, can be used to assess the competence of a culture.

Site-directed mutagenesis of Azotobacter vinelandii ferredoxin I: [Fe-S] cluster-driven protein rearrangement

Azotobacter vinelandii ferredoxin I is a small protein that contains one [4Fe-4S] cluster and one [3Fe-4S] cluster. Recently the x-ray crystal structure has been redetermined and the fdxA gene, which encodes the protein, has been cloned and sequenced. Here we report the site-directed mutation of Cys-20, which is a ligand of the [4Fe-4S] cluster in the native protein, to alanine and the characterization of the protein product by x-ray crystallographic and spectroscopic methods. The data show that the mutant protein again contains one [4Fe-4S] cluster and one [3Fe-4S] cluster. The new [4Fe-4S] cluster obtains its fourth ligand from Cys-24, a free cysteine in the native structure. The formation of this [4Fe-4S] cluster drives rearrangement of the protein structure.

Second gene (nif H* ) coding for a nitrogenase iron protein in Azotobacter chroococcum is adjacent to a gene coding for a ferredoxin-like protein

Azotobacter chroococcum MCD1 contains a cluster of nitrogen fixation (nif) genes coding for the structural polypeptides for nitrogenase (nifH for the Fe-protein and nifD and nifK for the MoFe protein) and a second sequence in the genome homologous to nifH. DNA fragments bearing this second nifH-like sequence were cloned and the DNA sequence around the homologous region determined. Two open reading frames were identified in this region. One codes for a protein of 289 amino acid residues and is highly homologous to other Fe-proteins but is different from the gene adjacent to the nifDK genes in A. chroococcum. This putative gene we call nifH*. The following open reading frame codes for a protein of 63 amino acids, nine of which are cysteine residues. The protein is homologous to the small low-potential ferredoxins found in anaerobic bacteria, and in particular those from Chlorobium limicola. Linkage between a structural gene for nitrogenase and a small ferredoxin has not previously been observed. Sequence analysis suggests that the two genes form an operon. Transcription of the ferredoxin gene on a 1320-bp transcript was only detectable under conditions in which A. chroococcum MCD1155, which carries a chromosomal deletion of 6.3 kb removing the entire nifHDK cluster, is capable of fixing N2, i.e. in media containing no added molybdenum or high levels of NH3. The size of the observed transcript agrees well with the predicted size for a transcript encoding nifH* and the ferredoxin genes. Expression of the nifH* promoter was not significantly activated in Escherichia coli even when nifA, the positive activator of nif genes in Klebsiella pneumoniae, was supplied in multiple copies. The results are discussed in relation to an alternative pathway for N2 fixation in A. chroococcum.