The basis of ammonium release in nifL mutants of Azotobacter vinelandii.

In Azotobacter vinelandii, nitrogen fixation is regulated at the transcriptional level by an unusual two-component system encoded by nifLA. Certain mutations in nifL result in the bacterium releasing large quantities of ammonium into the medium, and earlier work suggested that this occurs by a mechanism that does not involve NifA, the activator of nif gene transcription. We have investigated a number of possible alternative mechanisms and find no evidence for their involvement in ammonium release. Enhancement of NifA-mediated transcription, on the other hand, by either elimination of nifL or overexpression of nifA, resulted in ammonium release, correlating with enhanced levels of nifH mRNA, raised levels of nitrogenase and acetylene-reducing activity, and increased concentrations of intracellular ammonium. Up to 35 mM ammonium can accumulate in the medium. Where measured, intracellular levels exceeded extracellular levels, indicating that rather than being actively transported, ammonium is lost from the cell passively, possibly by reversal of an NH(4)(+) uptake system. The data also indicate that in the wild type the bulk of NifA is inactivated by NifL during steady-state growth on dinitrogen.

Identification of sequences important for recognition of vnf genes by the VnfA transcriptional activator in Azotobacter vinelandii.

To analyze regulation of the vanadium-dependent nitrogenase of Azotobacter vinelandii, plasmids carrying vnfE-, vnfH-, or vnfD-lacZ fusions were transferred to Escherichia coli. These genes were expressed only if VnfA was present. Deletions of the vnfE upstream region were constructed and comparison of a region necessary for expression with sequences upstream of other vnf genes indicated a substantially conserved motif, GTAC-N6-GTAC, hypothesized to be the binding site for VnfA. This motif was duplicated with 17 or 18 bases lying between each in the vnfH and vnfD promoters. Deletion analysis of the vnfH promoter indicated that both motifs were necessary for full expression. In footprinting experiments, VnfA significantly protected from methylation the guanine residues within or immediately adjacent to the proposed VnfA recognition motifs. The active form of VnfA is probably interacting dimers, a tetramer, or a higher order oligomer since two regions of dyad symmetry are required for its interaction with the DNA.

Redundancy of the conserved His residue in Azotobacter vinelandii NifL, a histidine autokinase homologue which regulates transcription of nitrogen fixation genes.

The NifL protein of Azotobacter vinelandii inhibits NifA, the activator of nif (nitrogen fixation) transcription, in response to oxygen and fixed nitrogen. NifL shows strong homology in its C-terminal domain to the histidine autokinase domains of the canonical two-component sensor proteins, including the region around His-304, which corresponds to the residue known to be phosphorylated in other systems. To examine the mechanism of sensory transduction by NifL, mutations encoding 10 substitutions for His-304 were introduced into the A. vinelandii chromosome. Regulation of nif transcription was measured using acetylene reduction and RNA blots. The substitutions His-304-->Arg and His-304-->Pro impaired regulation by both fixed nitrogen and oxygen, but substitution of Ala, Phe, Ile, Lys, Asn, Ser, Thr, Val had no effect. None of the mutants, including His-304-->Arg and His-304-->Pro, excreted ammonium during diazotrophy, a phenotype of nifL deletion mutants, suggesting that the molecular basis of this effect differs from that responsible for the inhibition of nif transcription. The data show conclusively that phosphorylation of His-304 is not essential for any of the known functions of A. vinelandii NifL. Homology to the family of histidine autokinases is therefore inadequate evidence for a mechanism of sensory transduction involving phosphorylation of the conserved histidine residue.

Sequence and molecular analysis of the nifL gene of Azotobacter vinelandii.

In both Klebsiella pneumoniae and Azotobacter vinelandii the nifL gene, which encodes a negative regulator of nitrogen fixation, lies immediately upstream of nifA. We have sequenced the A. vinelandii nifL gene and found that it is more homologous in its C-terminal domain to the histidine protein kinases (HPKs) than is K. pneumoniae NifL. In particular A. vinelandii NifL contains a conserved histidine at a position shown to be phosphorylated in other systems. Both NifL proteins are homologous in their N-termini to a part of the Halobacterium halobium bat gene product; Bat is involved in regulation of bacterio-opsin, the expression of which is oxygen sensitive. The same region showed homology to the haem-binding N-terminal domain of the Rhizobium meliloti fixL gene product, an oxygen-sensing protein. Like K. pneumoniae NifL, A. vinelandii NifL is shown here to prevent expression of nif genes in the presence of NH+4 or oxygen. The sequences found homologous in the C-terminal regions of NifL, FixL and Bat might therefore be involved in oxygen binding or sensing. An in-frame deletion mutation in the nifL coding region resulted in loss of repression by NH+4 and the mutant excreted high amounts of ammonia during nitrogen fixation, thus confirming a phenotype reported earlier for an insertion mutation. In addition, nifLA are cotranscribed in A. vinelandii as in K. pneumoniae, but expression from the A. vinelandii promoter requires neither RpoN nor NtrC.

The nifH gene encoding the Fe protein component of the molybdenum nitrogenase from Azotobacter chroococcum.

The nucleotide sequence spanning the nifH gene and part of the nifD gene encoding the molybdenum nitrogenase from Azotobacter chroococcum was determined. The transcription start point of the nifH promoter was mapped, and a potential transcriptional attenuator was located between the nifH and nifD genes.

Nucleotide sequence and genetic analysis of the Azotobacter chroococcum nifUSVWZM gene cluster, including a new gene (nifP) which encodes a serine acetyltransferase.

Nucleotide sequence was obtained for a region of 7,099 bp spanning the nifU, nifS, nifV, nifW, nifZ, and nifM genes from Azotobacter chroococcum. Chromosomal mutations constructed at several sites within the locus confirmed a requirement for this region for expression of the molybdenum nitrogenase in this organism. The genes are tightly clustered and ordered as in Klebsiella pneumoniae except for two additional open reading frames (ORFs) between nifV and nifW. The arrangement of genes in A. chroococcum closely matches that described for Azotobacter vinelandii. The polypeptide encoded by ORF4 immediately downstream from nifV is 41% identical over 186 amino acids to the product of the cysE gene from Escherichia coli, which encodes serine acetyltransferase (SAT), a key enzyme in cysteine biosynthesis. Plasmids which potentially express ORF4 complemented E. coli JM39, a cysteine auxotroph which lacks SAT. SAT activity was detected in crude extracts of one such complemented strain. A strain of A. chroococcum carrying a chromosomal disruption of ORF4 grew normally with ammonium as the N source but more slowly than the parental strain when N2 was the sole N source. These data suggest that ORF4 encodes a nif-specific SAT required for optimizing expression of nitrogenase activity. ORF4 was assigned the name nifP. nifP may be required to boost rates of synthesis or intracellular concentrations of cysteine or methionine. Sequence identity between nifV and leuA gene products suggests that nifV may catalyze a condensation reaction analogous to that carried out by isopropylmalate synthase (LEUA) but in which acetyl coenzyme and alpha-ketoglutarate are substrates for the formation of homocitrate, the proposed product of NIFV activity.

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.

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.

Further analysis of nitrogen fixation (nif) genes in Azotobacter chroococcum: identification and expression in Klebsiella pneumoniae of nifS, nifV, nifM, and nifB genes and localization of nifE/N-, nifU-, nifA- and fixABC-like genes.

The results presented extend previous investigations on the genetics of nitrogen fixation in Azotobacter chroococcum and indicate that nif- and fix-like DNA is located in at least five different regions of the genome. Region I contains functional copies of nifS,V and M, as well as nifH, D and K, all of which complemented mutants of Klebsiella pneumoniae. In addition, nifE- and/or nifN-like and nifU-like DNA is located in this region. The organization of the nif cluster in region I closely resembles that of K. pneumoniae. though spread over 22 kb as compared with 14 kb. Region II contains a functional nifB gene, which complemented a K. pneumoniae nifB mutant, and seems to be adjacent to ap nifA-like gene. Region III harbours nifH*, encoding a second nitrogenase Fe-protein. Region IV contains a reiteration of nifE- on and/or nifN-like sequences, and DNA homologous to Rhizobium meliloti fixABC is present in region V. The apparent complexity of nifDNA in A. chroococcum is probably related to the two systems for N2-fixation pr present in this organism.

Second gene (nifH*) 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.

Genome size and complexity in Azotobacter chroococcum.

All of eight strains of Azotobacter chroococcum examined contained between two and six plasmids ranging from 7 to more than 200 MDal in size. Strain MCC-1, a derivative of NCIMB 8003, was cured of various of the four largest of its five plasmids and the phenotypes of the strains compared. all fixed nitrogen and exhibited uptake hydrogenase activity. No differences were observed in carbon source utilization or antibiotic, heavy metal or UV resistance. The genome sizes of two strains of A. chroococcum were determined by two-dimensional electrophoresis. Strain CW8, an isolate from local soil containing two small plasmids of 6 and 6.5 MDAl contained unique DNA sequences equivalent to 1.78 x 10(6) (+/- 20%) bp (1.2 x 10(9) Dal). In strain MDC-1, a derivative of MCC-1, containing a 190 MDal and 7 MDal plasmid, the genome size was 1.94 x 10(6) (+/- 20%) bp. In exponential batch cultures, both contained 20 to 25 genome equivalents per cell. MCD-1 exhibited complex UV kill kinetics with a marked plateau of resistance; CW8 showed a simple response inconsistent with the possibility of organization of its DNA into identical chromosome copies capable of independent segregation.

Cloning and organisation of some genes for nitrogen fixation from Azotobacter chroococcum and their expression in Klebsiella pneumoniae.

By DNA hybridisation, restriction fragments of genomic DNA from Azotobacter chroococcum and A. vinelandii bearing sequences homologous to Klebsiella pneumoniae nitrogenase structural genes were detected. These were different in the two species and inconsistent with the arrangement of the homologous sequences as a contiguous cluster of unique genes. The use of a DNA probe specific for nifH showed that in A. chroococcum two nifH-like sequences were present in the genome. From gene libraries for A. chroococcum, several recombinant cosmid clones bearing nif genes were identified and physically mapped. One copy of the nifH-like sequences was closely linked to nifD and K, the order of genes being as for K. pneumoniae. This cluster was sub-cloned into the broad host-range vector pKT230. The resultant plasmid complemented for C2H2-reduction but not growth in N2 several Nif- mutants of A. vinelandii and K. pneumoniae and also abolished growth in N2 in Nif+ parents. The inhibition was ascribed to a short region adjacent to nifH, which probably corresponds to the promoter as its inhibitory affects were alleviated by provision of K. pneumoniae nifA in multiple copies. 3 sizes of transcripts are produced from the region containing nifH and nifD of A. chroococcum in cultures derepressing for nif. A region bearing homology to a fragment of the K. pneumoniae nif cluster bearing nifV was identified 15 Kb away from nifHDK in A. chroococcum however the order of genes is probably similar to that of K. pneumoniae.