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

The gene encoding dinitrogenase reductase 2 is required for expression of the second alternative nitrogenase from Azotobacter vinelandii

Under diazotrophic conditions in the absence of molybdenum (Mo) and vanadium (V), Azotobacter vinelandii reduces N2 to NH4+ by using nitrogenase 3 (encoded by anfHDGK). However, dinitrogenase reductase 2 (encoded by vnfH) is also expressed under these conditions even though this protein is a component of the V-containing alternative nitrogenase. Mutant strains that lack dinitrogenase reductase 2 (VnfH-) grow slower than the wild-type strain in N-free, Mo-, and V-deficient medium. In this medium, these strains synthesize dinitrogenase reductase 1 (a component of the Mo-containing nitrogenase encoded by nifH), even though this component is not normally synthesized in the absence of Mo. Strains that lack both dinitrogenase reductases 1 and 2 (NifH-VnfH-) are unable to grow diazotrophically in Mo- and V-deficient medium. In this medium, NifH- VnfH- strains containing an anfH-lacZ transcriptional fusion exhibited less than 3% of the beta-galactosidase activity observed in the wild type with the same fusion. Beta-Galactosidase activity expressed by VnfH- mutants containing the anfH-lacZ fusion ranged between 57 and 78% of that expressed by the wild type containing the same fusion. Thus, expression of dinitrogenase reductase 2 seems to be required for transcription of the anfHDGK operon, although, in VnfH-mutants, dinitrogenase reductase 1 appears to serve this function. Active dinitrogenase reductase 1 or 2 is probably required for this function since a nifM deletion mutant containing the anfH-lacZ fusion was unable to synthesize beta-galactosidase above background levels. An anfA deletion strain containing the anfH-lacZ fusion exhibited beta-galactosidase activity at 16% of that of the wild type containing the same fusion. However, in the presence of NH4+, the beta-galactosidase activity expressed by this strain more than doubled. This indicates that AnfA is required not only for normal levels of anfHDGK transcription but also for NH4+ -and, to a lesser extent, Mo-mediated repression of this transcription.

Tn5 mutagenesis and insertion replacement in Azotobacter vinelandii

Tn5 insertion mutants of Azotobacter vinelandii were isolated using vectors pJB4JI (IncP) and pGS9 (IncN). A procedure to replace Tn5 (Kmr) by its nontransposing derivative Tn5-131 (Tcr) was developed. For the replacement, a ColEl derivative harboring Tn5-131 (pRZ131) was conjugally mobilized by the IncN plasmid pCU101 into A. vinelandii strains containing Tn5. Both plasmids are unable to be maintained in A. vinelandii, but the transient presence of pRZ131 allows recombination between the incoming and the resident Tn5 elements. Genetic and physical analysis showed that insertion replacements result in lower frequencies of Tn5-associated genomic rearrangements, thereby increasing the stability of Tn5-containing strains.

Characterization of the pyoverdines of Azotobacter vinelandii ATCC 12837 with regard to heterogeneity

Azotobacter vinelandii strain ATCC 12837 produces peptide siderophores of the general class known as pyoverdines. In the past, it was assumed that a single well-defined pyoverdine was produced by each parent microorganism. However, there are a number of reports of incompletely characterized pyoverdines that demonstrate heterogeneity in pyoverdine preparations obtained from a single organism, but the nature of this phenomena has not been explained. This study shows that A. vinelandii does indeed produce more than one pyoverdine and that these compounds differ in their peptide components. The metabolism of these siderophores suggests that only one of them is a true siderophore while the others are metabolic byproducts. It was demonstrated that this phenomenon is likely due to intrinsic limitations of the synthetase complex involved in the biosynthesis of these compounds. Characterization of two of the major pyoverdines produced demonstrated that they are novel compounds, although they belonged to the Azotobacter-type family of pyoverdines.

Characterization of three different nitrogen-regulated promoter regions for the expression of glnB and glnA in Azospirillum brasilense

The complete nucleotide sequence of the open reading frame (ORF) located upstream of the glnA structural gene for glutamine synthetase (GS) in Azospirillum brasilense Sp7 was determined. This ORF, which codes for a 12 kDa protein, was identified as glnB, the structural gene for the PII protein, a component of the adenylylation cascade involved in the regulation of GS activity in some gram-negative bacteria. Transcription analysis and mRNA mapping of glnB and glnA of A. brasilense was performed with bacteria grown under different physiological conditions. The glnA gene can be transcribed either as a glnB-A mRNA of 2.4 kb or as a glnA mRNA of 1.5 kb. Differential expression of the two mRNAs was found to depend on the nitrogen source. The glnB-A mRNA was the major transcript under nitrogen fixation conditions, while the synthesis of the glnA mRNA was almost completely abolished. The glnA mRNA was predominantly produced in NH4(+)-containing medium. Transcription start site analysis revealed the presence of three different types of nitrogen-regulated promoters. GlnB-A mRNA was transcribed selectively from tandem promoters. One of them is similar to the NtrA-dependent promoter and the other to the Escherichia coli sigma 70 promoter. The synthesis of glnA mRNA was regulated by a promoter, which was repressed (or non-activated) only under conditions of nitrogen fixation, when moleuclar nitrogen was the sole nitrogen source. The transcriptional initiation site in front of glnA is not preceded by a canonical E. coli sigma 70 promoter. A sequence reminiscent of the NtrA-dependent promoter consensus, except for a fundamental mismatch, was found at positions -33 to -21. This sequence overlapped a putative "weak" NtrC-binding site, similar to those identified in enteric bacteria. From these results, it is postulated that glnA mRNA is controlled by a novel type of nitrogen-regulated promoter.

Molecular analysis of the Azotobacter vinelandii glnA gene encoding glutamine synthetase

The gene encoding glutamine synthetase (GS), glnA, was cloned from Azotobacter vinelandii on a 6-kb EcoRI fragment that also carries the ntrBC genes. The DNA sequence of 1,952 bp including the GS-coding region was determined. An open reading frame of 467 amino acids indicated a gene product of Mr 51,747. Transcription of glnA occurred from a C residue located 32 bases upstream of an ATG considered to be the initiator codon because (i) it had a nearby potential ribosome-binding site and (ii) an open reading frame translated from this site indicated good N-terminal homology to 10 other procaryotic GSs. Sequences similar to the consensus RNA polymerase recognition sites at -10 and -35 were present at the appropriate distance upstream of the transcription initiation site. As expected from earlier genetic studies indicating that expression of A. vinelandii glnA did not depend on the rpoN (ntrA; sigma 54) gene product, no sigma 54 recognition sequences were present, nor was there significant regulation of glnA expression by fixed nitrogen. Repeated attempts to construct glutamine auxotrophs by recombination of glnA insertion mutations were unsuccessful, Although the mutated DNA could be found by hybridization experiments in drug-resistant A. vinelandii transformants, the wild-type glnA region was always present. These results suggest that glnA mutations are lethal in A. vinelandii. In [14C]glutamine uptake experiments, very little glutamine was incorporated into cells, suggesting that glutamine auxotrophs are nonviable because they cannot be supplied with sufficient glutamine to support growth.

Sequence and analysis of the rpoN sigma factor gene of rhizobium sp. strain NGR234, a primary coregulator of symbiosis

We report the nucleotide sequence of the rpoN gene from broad-host-range Rhizobium sp. strain NGR234 and analyze the encoded RPON protein, a sigma factor. Comparative analysis of the deduced amino acid sequence of RPON from NGR234 with sequences from other gram-negative bacteria identified a perfectly conserved RPON box unique to RPON sigma factors. Symbiotic regulatory phenotypes were defined for a site-directed internal deletion within the coding sequence of the rpoN gene of Rhizobium strain NGR234: they included quantitative nodulation kinetics on Vigna unguiculata and microscopic analysis of the Fix- determinate nodules of V. unguiculata and Macroptilium atropurpureum. RPON was a primary coregulator of nodulation and was implicated in establishment or maintenance of the plant-synthesized peribacteroid membrane. Phenotypes of rpoN in Rhizobium strain NGR234 could be grouped as symbiosis related, rather than simply pleiotropically physiological as in free-living bacteria such as Klebsiella pneumoniae and Pseudomonas putida.

Complementation of Escherichia coli sigma 54 (NtrA)-dependent formate hydrogenlyase activity by a cloned Thiobacillus ferrooxidans ntrA gene

The ntrA gene of Thiobacillus ferrooxidans was cloned by complementation of an Escherichia coli ntrA mutant that was unable to produce gas via the sigma 54 (NtrA)-dependent formate hydrogenlyase pathway. Analysis of the DNA sequence showed that the T. ferrooxidans ntrA gene coded for a protein of 475 amino acids (calculated Mr, 52,972). The T. ferrooxidans NtrA protein had 49, 44, 33, and 18% amino acid similarity with the NtrA proteins of Klebsiella pneumoniae, Azotobacter vinelandii, Rhizobium meliloti, and Rhodobacter capsulatus, respectively. The ability of the T. ferrooxidans NtrA protein to direct transcription from sigma 54-dependent promoters was demonstrated in E. coli by using fdhF-lacZ and nifH-lacZ fusions. An open reading frame coding for a protein of 241 amino acids (calculated Mr, 27,023) was situated 12 base pairs upstream of the T. ferrooxidans ntrA gene. Comparison of this protein with the product of the open reading frame ORF1, located upstream of the R. meliloti ntrA gene, showed that the two proteins had 55% amino acid similarity. The cloned T. ferrooxidans ntrA gene was expressed in E. coli from a promoter located within the ORF1 coding region.

Involvement of Pseudomonas putida RpoN sigma factor in regulation of various metabolic functions

The RpoN protein was originally identified in Escherichia coli as a sigma (sigma) factor essential for the expression of nitrogen regulons. In the present study we cloned the Pseudomonas putida rpoN gene and identified its gene product as a protein with an apparent molecular weight of 78,000. A mutant rpoN gene was constructed by in vitro insertion mutagenesis with a kanamycin cassette. A P. putida rpoN mutant was then isolated by replacement of the intact chromosomal rpoN gene by the mutant rpoN gene through homologous recombination. Examination of the phenotypes of the P. putida rpoN mutant thus obtained allowed the identification of a series of metabolic functions whose expression depends upon the RpoN sigma factor. The rpoN mutation in P. putida affected the utilization by this organism of nitrate, urea, and uncharged amino acids, namely, alanine, glycine, isoleucine, leucine, and serine, as nitrogen sources. The mutation also affected the utilization of the above-mentioned amino acids, as well as lysine, C4-dicarboxylates (succinate, fumarate), and alpha-ketoglutarate, as carbon sources. In contrast to the P. putida wild-type strain, the rpoN mutant was nonmotile. The colony morphology of the mutant strain was different from that of the wild-type strain. Studies on the expression of the TOL plasmid catabolic operons in the mutant strain demonstrated that transcription from the upper-operon promoter and from the xylS gene promoter requires the RpoN sigma factor.

Two nifA-like genes required for expression of alternative nitrogenases by Azotobacter vinelandii

Two nifA-like genes, designated anfA and vnfA, have been identified in Azotobacter vinelandii. The anfA gene is located upstream from the nitrogenase-3 structural gene cluster (anfHDGK) and is preceded by a sequence that is potentially part of a ntrA-dependent promoter. The product of anfA appears to be required for expression of nitrogenase-3, since cells of the anfA deletion strain CA66 were unable to synthesize this nitrogenase when derepressed in N-free, Mo- and V-deficient medium. The vnfA gene was identified after determination of the nucleotide sequence of DNA flanking the Tn5 insertion in mutant strain CA46. Two open reading frames (ORF1 and ORF2) were found located upstream from the vnfA gene, and a nifE-like ORF, preceded by a possible ntrA-dependent promoter, was found downstream from this gene. It is not known whether vnfA is expressed only under N2-fixing conditions. However, potential ntrA-dependent promoters were found immediately upstream from vnfA (within the 3' end of ORF2) and immediately downstream from ORF1. The region spanning ORF1 and ORF2 contained an A + T-rich sequence that was also found immediately upstream from the potential ntrA-dependent promoter of anfA. The product of vnfA appears to be required for the synthesis of nitrogenase-2, since cells of strain CA46 synthesized only nitrogenase-1 and -3 but not nitrogenase-2 when grown in the presence of vanadium. The product of nifA, which is required for synthesis of nitrogenase-1, is not required for synthesis of either nitrogenase-2 or nitrogenase-3. However, growth data indicate that nifA is required for a factor (or factors) necessary for maximal diazotrophic growth under Mo- and V-deficient conditions.

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.

Role of the Bradyrhizobium japonicum ntrC gene product in differential regulation of the glutamine synthetase II gene (glnII)

We isolated the ntrC gene from Bradyrhizobium japonicum, the endosymbiont of soybean (Glycine max), and examined its role in regulating nitrogen assimilation. Two independent ntrC mutants were constructed by gene replacement techniques. One mutant was unable to produce NtrC protein, while the other constitutively produced a stable, truncated NtrC protein. Both ntrC mutants were unable to utilize potassium nitrate as a sole nitrogen source. In contrast to wild-type B. japonicum, the NtrC null mutant lacked glnII transcripts in aerobic, nitrogen-starved cultures. However, the truncated-NtrC mutant expressed glnII in both nitrogen-starved and nitrogen-excess cultures. Both mutants expressed glnII under oxygen-limited culture conditions and in symbiotic cells. These results suggest that nitrogen assimilation in B. japonicum is regulated in response to both nitrogen limitation and oxygen limitation and that separate regulatory networks exist in free-living and symbiotic cells.

Identification and characterization of two nitrogen fixation regulatory regions, nifA and nfrX, in Azotobacter vinelandii and Azotobacter chroococcum

Five Tn5-induced Nif- mutants of Azotobacter vinelandii were characterized as regulatory mutants because they were restored to Nif+ by the introduction of constitutively expressed nifA from Klebsiella pneumoniae. The mutants fell into two different classes on the basis of hybridization to a Rhizobium leguminosarum nifA gene probe and by complementation with cosmids isolated from pLAFRI gene banks of A. vinelandii and Azotobacter chroococcum. One mutant, MV3, was located in or near a nifA gene. The others, MV12, MV16, MV18 and MV26, defined a new regulatory gene, which has been called nfrX. The lack of expression of different nif-lacZ fusions confirmed the regulatory phenotype of all five mutant strains. The ability of both nifA and nfrX mutants to grow on nitrogen-free medium with vanadium, but not on medium with molybdenum, suggests that neither gene is required for expression of the alternative V-containing nitrogenase of A. vinelandii. A fragment carrying Tn5 and flanking DNA from MV3 was used as a probe to isolate the nifA region of A. chroococcum. Ligation of two adjacent EcoRI fragments of A. chroococcum yielded an intact nifA gene that activated expression of nifH-lac fusions and also restored MV3 to Nif+. The four nfrX mutants were complemented by pLAFR1 cosmids pLV163 and pLC121. The nfrX gene was subcloned from pLV163 and located within a 3.2 kb fragment. To determine whether nfrX might be found in other nitrogen-fixing organisms, DNA from 13 different species was hybridized to an nfrX probe. The failure to observe hybridization suggests that nfrX may be specific to nif regulation in Azotobacter.

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.

Bacterial alternative nitrogen fixation systems

The introduction briefly reviews some of the salient features of the well-characterized conventional molybdo-enzyme system for N2 fixation. This is followed by a brief account of the discovery of an alternative N2 fixation system that does not require molybdenum in the N2-fixing bacterum Azotobacter vinelandii. The next section cites observations from the early literature on N2 fixation suggesting may not always require molybdenum. Next, recent evidence for an alternative N2 fixation system in A. vinelandii is discussed. A brief description of our discovery of an alternative nitrogenase which is not a molybdenum or vanadium enzyme is presented, followed by a summary of recent papers describing an alternative vanadium-containing nitrogenase. Available information on the genetics and regulation of alternative N2 fixation systems is discussed. Finally, the possible/probable presence of alternative N2 fixation systems in bacteria other than Azotobacter species is covered.

The nucleotide sequence of the sigma factor gene ntrA (rpoN) of Azotobacter vinelandii: analysis of conserved sequences in NtrA proteins

The nucleotide sequence of the Azotobacter vinelandii ntrA gene has been determined. It encodes a 56916 Dalton acidic polypeptide (AvNtrA) with substantial homology to NtrA from Klebsiella pneumoniae (KpNtrA) and Rhizobium meliloti (RmNtrA). NtrA has been shown to act as a novel RNA polymerase sigma factor but the predicted sequence of AvNtrA substantiates our previous analysis of KpNtrA in showing no substantial homology to other known sigma factors. Alignment of the predicted amino acid sequences of AvNtrA, KpNtrA and RmNtrA identified three regions; two showing greater than 50% homology and an intervening sequence of less than 10% homology. The predicted protein contains a short sequence near the centre with homology to a conserved region in other sigma factors. The C-terminal region contains a region of homology to the beta' subunit of RNA polymerase (RpoC) and two highly conserved regions one of which is significantly homologous to known DNA-binding motifs. In A. vinelandii, ntrA is followed by another open reading frame (ORF) which is highly homologous to a comparable ORF downstream of ntrA in K. pneumoniae and R. meliloti.

Identification and characterization of the Rhizobium meliloti ntrC gene: R. meliloti has separate regulatory pathways for activation of nitrogen fixation genes in free-living and symbiotic cells

We show here that Rhizobium meliloti, the nitrogen-fixing endosymbiont of alfalfa (Medicago sativa), has a regulatory gene that is structurally homologous to previously characterized ntrC genes in enteric bacteria. DNA sequence analysis showed that R. meliloti ntrC is homologous to previously sequenced ntrC genes from Klebsiella pneumoniae and Bradyrhizobium sp. (Parasponia) and that an ntrB-like gene is situated directly upstream from R. meliloti ntrC. Similar to its counterparts in K. pneumoniae and Escherichia coli, R. meliloti ntrC is expressed when the cells are grown in nitrogen-limiting media. In addition, R. meliloti ntrC is required for growth on media containing nitrate as the sole nitrogen source and for the ex planta transcription of several R. meliloti nif genes. On the other hand, root nodules elicited by R. meliloti ntrC mutants fix nitrogen as well as nodules elicited by wild-type R. meliloti. These latter results indicate that R. meliloti has separate regulatory pathways for activating nif gene expression ex planta and during symbiotic nitrogen fixation.

Complementation of nitrogen-regulatory (ntr-like) mutations in Rhodobacter capsulatus by an Escherichia coli gene: cloning and sequencing of the gene and characterization of the gene product

In vivo genetic engineering by R' plasmid formation was used to isolate an Escherichia coli gene that restored the Ntr+ phenotype to Ntr- mutants of the photosynthetic bacterium Rhodobacter capsulatus (formerly Rhodopseudomonas capsulata; J. F. Imhoff, H. G. Trüper, and N. Pfenning, Int. J. Syst. Bacteriol. 34:340-343, 1984). Nucleotide sequencing of the gene revealed no homology to the ntr genes of Klebsiella pneumoniae. Furthermore, hybridization experiments between the cloned gene and different F' plasmids indicated that the gene is located between 34 and 39 min on the E. coli genetic map and is therefore unlinked to the known ntr genes. The molecular weight of the gene product, deduced from the nucleotide sequence, was 30,563. After the gene was cloned in an expression vector, the gene product was purified. It was shown to have a pI of 5.8 and to behave as a dimer during gel filtration and on sucrose density gradients. Antibodies raised against the purified protein revealed the presence of this protein in R. capsulatus strains containing the E. coli gene, but not in other strains. Moreover, elimination of the plasmid carrying the E. coli gene from complemented strains resulted in the loss of the Ntr+ phenotype. Complementation of the R. capsulatus mutations by the E. coli gene therefore occurs in trans and results from the synthesis of a functional gene product.

Nucleotide sequence of the Azospirillum brasilense Sp7 glutamine synthetase structural gene

The complete nucleotide sequence of the glnA gene, encoding the glutamine synthetase subunit of Azospirillum brasilense Sp7, was established. This is the first Azospirillum gene sequenced. The gene encodes a 468 residue polypeptide of MW 51,917. The similarity coefficient (SAB) between the polypeptidic sequence of Azospirillum and Anabaena 7120, which is the only other glnA sequence available, is 58%. No significant homology with E. coli canonical and ntr promoters, or with the promoter region of the Anabaena glnA gene was found. When fused to an E. coli promoter, the gene could be translated in E. coli, despite a very biased codon usage and an atypical Shine-Dalgarno sequence.