Identification and DNA sequence of fixZ, a nifB-like gene from Rhizobium leguminosarum.

Previously, several mutants which nodulated peas but which failed to fix nitrogen were isolated following Tn5 mutagenesis of pRL 1JI, a symbiotic plasmid of Rhizobium leguminosarum. Two of these alleles, fix52::Tn5 and fix137::Tn5 were in a region of pRL 1JI which hybridized to a probe that contained the nifA gene and the amino-terminal region of the nifB gene of Klebsiella pneumoniae. The nitrogen fixation defect of the fix52::Tn5 mutant strain was corrected by a 2.0kb fragment of the corresponding wild-type DNA cloned in a wide host-range plasmid. The DNA sequence of this region revealed an open reading frame corresponding to the gene within which the fix52::Tn5 allele was located. The polypeptide corresponding to this open reading frame had a deduced molecular weight of 39,936 and the gene was termed fixZ. The deduced amino acid sequence of the fixZ gene product contained two clusters of cysteine residues, suggesting that the protein may contain an iron-sulphur cluster. The sequence of the fixZ polypeptide was very similar to the sequence of the K. pneumoniae nifB gene (provided by W. Arnold and A. Pühler) which is required for the synthesis of the FeMo-cofactor of nitrogenase. It was shown that the previously observed hybridization was due to homology between the amino terminal regions of fixZ and nifB. Upstream from fixZ was found another open reading frame whose 5' terminus was not established, but within which was located the fix137::Tn5 allele. This gene was termed fixY. The deduced amino acid sequence of the sequenced part of fixY showed similarity to that of the regulatory nifA gene of K. pneumoniae (provided by W. J. Buikema and F. M. Ausubel). Thus in R. leguminoarum the fix genes that correspond to the nifA and nifB genes are in the same relative orientation as in K. pneumoniae.     

Organization and partial sequence of a DNA region of the Rhizobium leguminosarum symbiotic plasmid pRL6JI containing the genes fixABC, nifA, nifB and a novel open reading frame.

By hybridization and heteroduplex studies the fixABC and nifA genes of the Rhizobium leguminosarum symbiotic plasmid pRL6JI have been identified. DNA sequencing of the region containing nifA showed an open reading frame of 1557 bp encoding a protein of 56, 178 D. Based on sequence homology, this ORF was confirmed to correspond to the nifA gene. Comparison of three nifA proteins (Klebsiella pneumoniae, Rhizobium meliloti, Rhizobium leguminosarum) revealed only a weak relationship in their N-terminal regions, whereas the C-terminal parts exhibited strong homology. Sequence analysis also showed that the R. leguminosarum nifA gene is followed by nifB and preceded by fixC with an open reading frame inserted in between. This novel ORF of 294 bp was found to be highly conserved also in R. meliloti. No known promoter and termination signals could be defined on the sequenced R. leguminosarum fragment.     

Functional difference between Sinorhizobium meliloti NifA and Enterobacter cloacae NifA

The nifA gene is an important regulatory gene and its product, NifA protein, regulates the expression of many nif genes involved in the nitrogen fixation process. We introduced multiple copies of the constitutively expressed Sinorhizobium meliloti (Sm) or Enterobacter cloacae (Ec) nifA gene into both the nifA mutant strain SmY and the wild-type strain Sm1021. Root nodules produced by SmY containing a constitutively expressed Sm nifA gene were capable of fixing nitrogen, while nodules produced by SmY containing the EC nifA gene remained unable to fix nitrogen, as is the case for SmY itself. However, transfer of an additional Sm nifA gene into Sm1021 improved the nitrogen-fixing efficiency of root nodules to a greater extent than that observed upon transfer of the EC nifA gene into Sm1021. Comparative analysis of amino acid sequences between Sm NifA and EC NifA showed that the N-terminal domain was the least similar, but this domain is indispensable for complementation of the Fix-phenotype of SmY by Sm Ni     

The nifA gene of Rhizobium meliloti is oxygen regulated.

Experiments using plasmid-borne gene fusions and direct RNA measurements have revealed that expression from the nifA gene is induced in Rhizobium meliloti when the external oxygen concentration is reduced to microaerobic levels. Induction occurs in the absence of alfalfa and in the presence of fixed nitrogen and does not require ntrC. The production of functional nifA gene product (NifA) can be demonstrated by its ability to activate the nitrogenase promoter P1. Aerobic induction of nifA can also occur during nitrogen starvation at low pH, but in this case induction is dependent on ntrC and does not lead to P1 activation. The data indicate that reduced oxygen tension is potentially a major trigger for symbiotic activation of nitrogen fixation in Rhizobium species.     

The Azorhizobium caulinodans nitrogen-fixation regulatory gene, nifA, is controlled by the cellular nitrogen and oxygen status

The nucleotide sequence of the Azorhizobium caulinodans ORS571 nifA locus was determined and the deduced NifA amino acid sequence compared with that of NifA from other nitrogen-fixing species. Highly conserved domains, including helix-turn-helix and ATP-binding motifs, and specific conserved residues, such as a cluster of cysteines, were identified. The nifA 5' upstream region was found to contain DNA sequence motifs highly homologous to promoter elements involved in nifA/ntr-mediated control and a consensus element found in the 5' upstream region of the Bradyrhizobium japonicum 5-aminolevulinic acid synthase (hemA) gene and of Escherichia coli genes activated during anaerobiosis via the fnr (fumarate nitrate reduction) control system. A nifA-lac fusion was constructed using miniMu-lac and its activity measured in different genetic backgrounds and under various physiological conditions (in culture and in planta). NifA expression was found to be negatively autoregulated, repressed by rich nitrogen sources and high oxygen concentrations, and controlled (partially) by the ntrC gene, both in culture and in planta. DNA supercoiling was also implicated in nifA regulation, since DNA gyrase inhibitors severely repressed nifA-lac expression.     

Excretion of ammonium by a nifL mutant of Azotobacter vinelandii fixing nitrogen.

A mutation in the gene upstream of nifA in Azotobacter vinelandii was introduced into the chromosome to replace the corresponding wild-type region. The resulting mutant, MV376, produced nitrogenase constitutively in the presence of 15 mM ammonium. When introduced into a nifH-lacZ fusion strain, the mutation permitted beta-galactosidase production in the presence of ammonium. The gene upstream of nifA is therefore designated nifL because of its similarity to the Klebsiella pneumoniae nifL gene in proximity to nifA, in mutant phenotype, and in amino acid sequence of the gene product. The A. vinelandii nifL mutant MV376 excreted significant quantities of ammonium (approximately 10 mM) during diazotrophic growth. In contrast, ammonium excretion during diazotrophy was much lower in a K. pneumoniae nifL deletion mutant (maximum, 0.15 mM) but significantly higher than in NifL+ K. pneumoniae. The expression of the A. vinelandii nifA gene, unlike that of K. pneumoniae, was not repressed by ammonium.     

Excretion of ammonium by a nifL mutant of Azotobacter vinelandii fixing nitrogen.

A mutation in the gene upstream of nifA in Azotobacter vinelandii was introduced into the chromosome to replace the corresponding wild-type region. The resulting mutant, MV376, produced nitrogenase constitutively in the presence of 15 mM ammonium. When introduced into a nifH-lacZ fusion strain, the mutation permitted beta-galactosidase production in the presence of ammonium. The gene upstream of nifA is therefore designated nifL because of its similarity to the Klebsiella pneumoniae nifL gene in proximity to nifA, in mutant phenotype, and in amino acid sequence of the gene product. The A. vinelandii nifL mutant MV376 excreted significant quantities of ammonium (approximately 10 mM) during diazotrophic growth. In contrast, ammonium excretion during diazotrophy was much lower in a K. pneumoniae nifL deletion mutant (maximum, 0.15 mM) but significantly higher than in NifL+ K. pneumoniae. The expression of the A. vinelandii nifA gene, unlike that of K. pneumoniae, was not repressed by ammonium.     

fixK, a gene homologous with fnr and crp from Escherichia coli, regulates nitrogen fixation genes both positively and negatively in Rhizobium meliloti.

Nitrogen fixation genes are shown to undergo a complex positive and negative regulation in Rhizobium meliloti. Activation of fixN by fixLJ is shown to require a third regulatory gene, fixK. As fixK is activated by fixLJ, we propose a cascade model for fixN regulation such that fixLJ activates fixN via fixK. In addition fixK negatively regulates expression of the nif-specific activator nifA as well as its own expression by autoregulation. Thus nifA and fixK are subject to a mixed regulation, positive (by fixLJ) and negative (by fixK). The sequence of fixK shows homology with the Escherichia coli regulators fnr and crp, which makes fixK the third characterized member of this family of prokaryotic regulators.     

A new symbiotic cluster on the pSym megaplasmid of Rhizobium meliloti 2011 carries a functional fix gene repeat and a nod locus.

A 290-kilobase (kb) region of the Rhizobium meliloti 2011 pSym megaplasmid, which contains nodulation genes (nod) as well as genes involved in nitrogen fixation (nif and fix), was shown to carry at least six sequences repeated elsewhere in the genome. One of these reiterated sequences, about 5 kb in size, had previously been identified as part of a cluster of fix genes located 220 kb downstream of the nifHDK promoter. Deletion of the reiterated part of this fix cluster does not alter the symbiotic phenotype. Deletion of the second copy of this reiterated sequence, which maps on pSym 40 kb upstream of the nifHDK promoter, also has no effect. Deletion of both of these copies however leads to a Fix- phenotype, indicating that both sequences carry functionally reiterated fix gene(s). The fix copy 40 kb upstream of nifHDK is part of a symbiotic cluster which also carries a nod locus, the deletion of which produces a marked delay in nodulation.