Comparative organization of nitrogen fixation-specific genes from Azotobacter vinelandii and Klebsiella pneumoniae: DNA sequence of the nifUSV genes.

In the facultative anaerobe Klebsiella pneumoniae 17 nitrogen fixation-specific genes (nif genes) have been identified. Homologs to 12 of these genes have now been isolated from the aerobic diazotroph Azotobacter vinelandii. Comparative studies have indicated that these diverse microorganisms share striking similarities in the genetic organization of their nif genes and in the primary structure of their individual nif gene products. In this study the complete nucleotide sequence of the nifUSV gene clusters from both K. pneumoniae and A. vinelandii were determined. These genes are identically organized on their respective genomes, and the individual genes and their products exhibit a high degree of interspecies sequence homology.     

The N-terminal and C-terminal portions of NifV are encoded by two different genes in Clostridium pasteurianum.

The nifV gene products from Azotobacter vinelandii and Klebsiella pneumoniae share a high level of primary sequence identity and are proposed to catalyze the synthesis of homocitrate. While searching for potential nif (nitrogen fixation) genes within the genomic region located downstream from the nifN-B gene of Clostridium pasteurianum, we observed two open reading frames (ORFs) whose deduced amino acid sequences exhibit nonoverlapping sequence identity to different portions of the nifV gene products from A. vinelandii and K. pneumoniae. Conserved regions were located between the C-terminal 195 amino acid residues of the first ORF and the C-terminal portion of the nifV gene product and between the entire sequence of the second ORF (269 amino acid residues) and the N-terminal portion of the nifV gene product. We therefore designated the first ORF nifV omega and the second ORF nifV alpha. The deduced amino acid sequences of nifV omega and nifV alpha were also found to have sequence similarity when compared with the primary sequence of the leuA gene product from Salmonella typhimurium, which encodes alpha-isopropylmalate synthase. Marker rescue experiments were performed by recombining nifV omega and nifV alpha from C. pasteurianum, singly and in combination, into the genome of an A. vinelandii mutant strain which has an insertion and a deletion mutation located within its nifV gene. A NifV+ phenotype was obtained only when both the C. pasteurianum nifV omega and nifV alpha genes were introduced into the chromosome of this mutant strain. These results suggest that the nifV omega and nifV alpha genes encode separate domains, both of which are required for homocitrate synthesis in C. pasteurianum.     

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.     

Nucleotide sequence of the gene encoding the nitrogenase iron protein of Thiobacillus ferrooxidans.

The DNA sequence was determined for the cloned Thiobacillus ferrooxidans nifH and part of the nifD genes. A putative T. ferrooxidans nifH promoter was identified whose sequences showed perfect consensus with those of the Klebsiella pneumoniae nif promoter. Two putative consensus upstream activator sequences were also identified. The amino acid sequence was deduced from the DNA sequence. In a comparison of nifH DNA sequences from T. ferrooxidans and eight other nitrogen-fixing microbes, a Rhizobium sp. isolated from Parasponia andersonii showed the greatest homology (74%) and Clostridium pasteurianum (nifH 1) showed the least homology (54%). In a comparison of the amino acid sequences of the Fe proteins, the Rhizobium sp. and Rhizobium japonicum showed the greatest homology (both 86%) and C. pasteurianum (nifH 1 gene product) demonstrated the least homology (56%) to the T. ferrooxidans Fe protein.     

The product of the nitrogen fixation regulatory gene nfrX of Azotobacter vinelandii is functionally and structurally homologous to the uridylyltransferase encoded by glnD in enteric bacteria.

We sequenced the nitrogen fixation regulatory gene nfrX from Azotobacter vinelandii, mutations in which cause a Nif- phenotype, and found that it encodes a 105-kDa protein (NfrX), the N terminus of which is highly homologous to that of the uridylyltransferase-uridylyl-removing enzyme encoded by glnD in Escherichia coli. In vivo complementation experiments demonstrate that the glnD and nfrX products are functionally interchangeable. A vinelandii nfrX thus appears to encode a uridylyltransferase-uridylyl-removing enzyme, and in this paper we report the first sequence of such a protein. The Nif- phenotype of nfrX mutants can be suppressed by a second mutation in a recently identified nifL-like gene immediately upstream of nifA in A. vinelandii. NifL mediates nif regulation in response to the N status in A. vinelandii, presumably by inhibiting NifA activator function as occurs in Klebsiella pneumoniae; thus, one role of NfrX is to modify, either directly or indirectly, the activity of the nifL product.     

Genetic and structural analysis of the Rhizobium meliloti fixA, fixB, fixC, and fixX genes.

The fixA, fixB, fixC, and fixX genes of Rhizobium meliloti 1021 constitute an operon and are required for nitrogen fixation in alfalfa nodules. DNA homologous to the R. meliloti fixABC genes is present in all other Rhizobium and Bradyrhizobium species examined, but fixABC-homologous sequences were found in only one free-living diazotroph, Azotobacter vinelandii. To determine whether the fixABCX genes share sequence homology with any of the 17 Klebsiella pneumoniae nif genes, we determined the entire nucleotide sequence of the fixA, fixB, fixC, and fixX genes and defined four open reading frames that code for polypeptides of molecular weights 31,146, 37,786, 47,288, and 10,937, respectively. Neither DNA nor amino acid sequence homology to the R. meliloti fixA, -B, -C, and -X genes was found in the K. pneumoniae nif operon. The fixX gene contains a cluster of cysteine residues characteristic of ferredoxins and is highly homologous to an Azotobacter ferredoxin which has been shown to donate electrons to nitrogenase. The fixABC operon contains a promoter region that is highly homologous to other nifA-activated promoters. We also found a duplication of the 5' end of the fixABCX operon; a 250-bp region located 520 bp upstream of the fixABCX promoter bears more than 65% homology to the 5' end of the transcribed region, including the first 32 codons of fixA.     

nifV is contiguous to nifHDK in Frankia strain FaC1

The organization of genes with the capacity to code for four proteins involved in nitrogen fixation in Frankia strain FaC1 was determined by restriction fragment mapping and nucleotide sequence analysis. Analysis of the 44-kb genomic cosmid clone pFAH 1. isolated from a cosmid library made from Frankia strain FaCl, resulted in the identification of a 7.2-kb Pst I fragment to which Klebsiella nif H, nif D and nif K probes hybridized. This nif -hybridizing fragment was subcloned and analyzed by restriction fragment mapping. Further subcloning of the 7.2-kb fragment and subsequent sequence analysis of approximately 6.8 kb revealed the presence of six open reading frames (ORFs). Four of these ORFs have the potential to code for nif V-, nif H-, nif D- and nif K-like gene products and the two others are unidentified ORFs. The organization of the structural genes for nitrogenase is the same in this Frankia strain as it is in most other nitrogen-fixing prokaryotes, but the positioning of the nif V-like gene relative to the nif HDK cluster differs, A consensus nif -promoter-like sequence, found 5'to nif H. was not detected upstream of the nif V-like gene. Nine copies of a 7-bp direct repeat were found 5'to ORFA.     

Nitrogen fixation specific regulatory genes of Klebsiella pneumoniae and Rhizobium meliloti share homology with the general nitrogen regulatory gene ntrC of K. pneumoniae.

We have determined the complete nucleotide sequences of three functionally related nitrogen assimilation regulatory genes from Klebsiella pneumoniae and Rhizobium meliloti. These genes are: 1) The K. pneumoniae general nitrogen assimilation regulatory gene ntrC (formerly called glnG), 2) the K. pneumoniae nif-specific regulatory gene nifA, and 3) an R. meliloti nif-specific regulatory gene that appears to be functionally analogous to the K. pneumoniae nifA gene. In addition to the DNA sequence data, gel-purified K. pneumoniae nifA protein was used to determine the amino acid composition of the nifA protein. The K. pneumoniae ntrC and nifA genes code for proteins of 52,259 and 53,319 d respectively. The R. meliloti nifA gene codes for a 59,968 d protein. A central region within each polypeptide, consisting of approximately 200 amino acids, is between 52% and 58% conserved among the three proteins. Neither the amino termini nor the carboxy termini show any conserved sequences. Together with data that shows that the three regulatory proteins activate promoters that share a common consensus sequence in the -10 (5'-TTGCA-3') and -23 (5'-CTGG-3') regions, the sequence data presented here suggest a common evolutionary origin for the three regulatory genes.     

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.     

Isolation, sequencing, and mutagenesis of the nifF gene encoding flavodoxin from Azotobacter vinelandii

The nifF gene encoding flavodoxin from Azotobacter vinelandii OP was cloned and its DNA sequence determined. It is located adjacent to, or possibly within, the major nif cluster and it is preceded by nif-specific regulatory elements. Southern hybridization analysis revealed that there is only a single copy of the nifF gene on the A. vinelandii OP genome. Mutant strains were constructed which have an insertion mutation or an insertion and a deletion mutation within the nifF gene coding sequence. These mutant strains are capable of diazotrophic growth, indicating that flavodoxin is not the unique physiological electron donor to nitrogenase. The results of nifF-lacZYA gene fusion experiments and Northern hybridization analyses indicated that the nifF gene is both transcribed and translated under nitrogen fixing and non-nitrogen fixing conditions. However, under nitrogen fixing conditions a substantial increase in both nifF synthesis and in accumulation of an approximately 800-base pair nifF-encoding mRNA species was observed. Furthermore, strains mutated within the nifF gene have only 70% of the wild type in vivo nitrogenase activity as determined by whole cell acetylene reduction assays. These data demonstrate that the nifF-encoded flavodoxin of A. vinelandii OP, although not essential for nitrogen fixation, is required for maximum in vivo nitrogenase activity.