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

Phenotypic characterization of a tungsten-tolerant mutant of Azotobacter vinelandii

A tungsten-tolerant mutant strain (CA6) of Azotobacter vinelandii first described in 1980 (P. E. Bishop, D. M. L. Jarlenski, and D. R. Hetherington, Proc. Natl. Acad. Sci. USA 77:7342-7346, 1980) has been further characterized. Results from growth experiments suggest that both nitrogenases 1 and 3 are utilized when CA6 grows in N-free medium containing Na2MoO4. Strain CA6.1.71, which lacks both nitrogenases 2 and 3, grew as well as strain CA in N-free medium containing Na2MoO4 after an initial lag. This indicates that nitrogenase 1 is fully functional in strain CA6. nifH-lacZ and anfH-lacZ transcriptional fusions were expressed in CA6 in the presence of Na2MoO4. Thus, in contrast to wild-type strain CA, transcription of the anfHDGK gene cluster in strain CA6 is not repressed by Mo. Expression of the vnfD-lacZ fusion was the same in both strains CA and CA6. In agreement with the results obtained with lac fusions, subunits of both nitrogenases 1 and 3 were found in protein extracts of CA6 cells grown in N-free medium containing Na2MoO4. However, CA6 cells, cultured in the presence of Na2WO4, accumulated nitrogenase 3 proteins without detectable amounts of nitrogenase 1 proteins. This indicates that expression of Mo-independent nitrogenase 3 is the basis for the tungsten tolerance phenotype of strain CA6. A measure of Mo accumulation as a function of time showed that accumulation by strain CA6 was slower than that for strain CA. When Mo accumulation was studied as a function of Na2MoO4 concentration, the two strains accumulated similar amounts of Mo in the concentration range of 0 to 1 microM Na2MoO4 during a 2-h period. Within the range of 1 to 5 microM Na2MoO4, Mo accumulation by strain CA increased linearly with increasing concentration whereas no further increases were observed for strain CA6. These results are consistent with the possibility that the tungsten tolerance mutation carried by CA6 is in a Mo transport system.

Isolation of two forms of the nitrogenase VFe protein from Azotobacter vinelandii

When Q-Sepharose was used in the purification of the V nitrogenase proteins from Azotobacter vinelandii, an increase in resolution was observed that resulted in a separation of the nitrogenase component 1 protein (Av1') into two forms, labeled Av1'A and Av1'B. Even though both forms possessed the same enzymatic behavior, Av1'A exhibited a lower specific activity and migrated during gel filtration with an apparent lower molecular weight than Av1'B. Furthermore, SDS-polyacrylamide gel electrophoresis showed different relative compositions of the two major subunits of both forms, with Av1'A possessing a trimer (alpha beta 2) pattern compared to the more typical tetramer (alpha 2 beta 2) pattern found for Av1'B. Metal analysis indicated a V-to-Fe ratio of 1:19 for Av1'A and 1:15 (or 2:30) for Av1'B, while acid-labile sulfide analysis showed that Av1'A possessed about half as much sulfide as Av1'B. EPR spectroscopy revealed that both proteins retained the S = 3/2 and S = 1/2 signals observed in earlier isolations, with an additional S = 1/2 signal present in the spectrum of protein A. These results suggest that Av1'A is an incomplete form of the VFe protein, containing only one cofactor and one P cluster with an additional [Fe4-S4]-like cluster. The presence of a V storage protein in A. vinelandii was also investigated. Although no V storage protein was found, two V-binding proteins were observed.

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.

Characteristics of orf1 and orf2 in the anfHDGK genomic region encoding nitrogenase 3 of Azotobacter vinelandii

In Azotobacter vinelandii, the anfHDGK operon encodes the subunits for the third nitrogenase complex. Two open reading frames (orf1 and orf2) located immediately downstream of anfK were shown to be required for diazotrophic growth under Mo- and V-deficient conditions. We have designated orf1 and orf2 anfO and anfR, respectively. Strains (CA115 and CA116) carrying in-frame deletions in anfO and anfR accumulate the subunits for nitrogenase 3 under Mo-deficient diazotrophic conditions. AnfO and AnfR are required for nitrogenase 3-dependent diazotrophic growth and 15N2 incorporation but not for acetylene reduction. AnfO contains a putative heme-binding domain that exhibits similarity to presumed heme-binding domains of P-450 cytochromes. Amino acid substitutions of Cys-158 show that this residue is required for fully functional AnfO as measured by diazotrophic growth under Mo- and V-deficient conditions. The nucleotide sequence of the region located immediately downstream of anfR has been determined. A putative rho-independent transcription termination site has been identified 250 bp from the 3' end of anfR. A third open reading frame (orf3), located downstream of anfR, does not appear to be required for diazotrophic growth under Mo- and V-deficient conditions.

The genes encoding the delta subunits of dinitrogenases 2 and 3 are required for mo-independent diazotrophic growth by Azotobacter vinelandii

vnfG and anfG encode the delta subunits of alternative nitrogenases 2 and 3 in Azotobacter vinelandii, respectively. As a first step towards elucidating the role of these subunits, diazotrophic growth and acetylene reduction studies were conducted on mutants containing alterations in the genes encoding these subunits. Mutants containing a stop codon (C36stop) or an in-frame deletion in anfG were unable to grow in N-free, Mo-deficient medium (Anf-). Mutants in which cysteine 36 of AnfG (a residue conserved between VnfG and AnfG) was changed to Ala or Ser were Anf+. Thus, this conserved cysteine is not essential for the function of AnfG in dinitrogenase 3. A mutant with a stop codon in vnfG (C17stop) grew after a lag of 25 h in N-free, Mo-deficient medium containing V2O5. However, a Nif- Anf- strain with this mutation was unable to grow under these conditions. This shows that the vnfG gene product is required for nitrogenase 2-dependent growth. Strains with mutations in vnfG and anfG reduced acetylene to different degrees. This indicates that the delta subunits are not required for acetylene reduction by nitrogenases 2 and 3.

The role of regulatory genes nifA, vnfA, anfA, nfrX, ntrC, and rpoN in expression of genes encoding the three nitrogenases of Azotobacter vinelandii

Several regulatory gene mutants of Azotobacter vinelandii were tested for ability to synthesize functional nitrogenase-1 (Nif phenotype), nitrogenase-2 (Vnf), or nitrogenase-3 (Anf). While nifA mutants were Nif-, Vnf+, and Anf+/-, and ntrC mutants were Nif+, Vnf+, and Anf+, nifA ntrC double mutants were Nif-, Vnf-, and Anf-. A vnfA mutant was Nif+, Vnf+/-, and Anf+/-, and an anfA strain was Nif+, Vnf+, and Anf-. lacZ fusions in the nifH, vnfH, vnfD, anfH, and nifM genes of Azotobacter vinelandii were constructed and introduced into wild-type and regulatory mutants of A. vinelandii. Expression of these operons correlated with the growth phenotype of the regulatory mutants. Apparently either NifA or NtrC can activate expression of nifM. Also, expression of the anf operon required the NifA transcriptional activator, although there are no NifA binding sites at appropriate locations upstream of anfH (or anfA). The results confirm previous reports that VnfA and AnfA are required for expression of vnf and anf genes, respectively, and that VnfA is involved in repression of the nifHDK operon in the absence of molybdenum and of the anfHDGK operon in the presence of vanadium.

Effect of amino acid substitutions in a potential metal-binding site of AnfA on expression from the anfH promoter in Azotobacter vinelandii

AnfA, an activator required for transcription of the structural genes encoding nitrogenase 3 (anfHDGK) in Azotobacter vinelandii, has a potential metal-binding site [(S19)H(C21)FTGE(C26)R] in its N terminus. Growth studies and expression of an anfH-lacZ fusion in mutants containing amino acid substitutions in this site indicate that Ser-19 is not required for AnfA activity whereas Cys-21 and Cys-26 are required. Residual expression of the anfH-lacZ fusion in AnfA- mutants was found to be due to activation by VnfA, the activator required for expression of genes encoding nitrogenase 2.

Changes of ploidy during the Azotobacter vinelandii growth cycle

The size of the Azotobacter vinelandii chromosome is approximately 4,700 kb, as calculated by pulsed-field electrophoretic separation of fragments digested with the rarely cutting endonucleases SpeI and SwaI. Surveys of DNA content per cell by flow cytometry indicated the existence of ploidy changes during the A. vinelandii growth cycle in rich medium. Early-exponential-phase cells have a ploidy level similar to that of Escherichia coli or Salmonella typhimurium (probably ca. four chromosomes per cell), but a continuous increase of DNA content per cell is observed during growth. Late-exponential-phase cells may contain > 40 chromosomes per cell, while cells in the early stationary stage may contain > 80 chromosomes per cell. In late-stationary-phase cultures, the DNA content per cell is even higher, probably over 100 chromosome equivalents per cell. A dramatic change is observed in old stationary-phase cultures, when the population of highly polyploid bacteria segregates cells with low ploidy. The DNA content of the latter cells resembles that of cysts, suggesting that the process may reflect the onset of cyst differentiation. Cells with low ploidy are also formed when old stationary-phase cultures are diluted into fresh medium. Addition of rifampin to exponential-phase cultures causes a rapid increase in DNA content, indicating that A. vinelandii initiates multiple rounds of chromosome replication per cell division. Growth in minimal medium does not result in the spectacular changes of ploidy observed during rapid growth; this observation suggests that the polyploidy of A. vinelandii may not exist outside the laboratory.

Characterization of nitrogen-fixing bacteria from a temperate saltmarsh lagoon, including isolates that produce ethane from acetylene

Nitrogen-fixing bacteria were isolated from sediments and water of a saltmarsh lagoon on the west coast of South Africa, and characterized according to factors that regulate nitrogen fixation in the marine environment. The majority of isolates were assigned to the Photobacterium or Vibrio genera on the basis of physiological and biochemical characteristics. One isolate was further assigned to the species Vibrio diazotrophicus. Carbohydrate utilization by each diazotrophic isolate was examined. Abilities of the isolates to utilize a range of mono-, di-, and polysaccharides largely reflected the predicted availability of organic carbon and energy in the lagoon, except that chitin was not utilized. Biochemical tests on the utilization of combined nitrogen showed that one isolate could utilize nitrate, and that this strain was susceptible to full repression of nitrogenase activity by 10mM nitrate. Urease activity was not detected in any of the isolates. In the absence of molybdenum two of the isolates, a Photobacterium spp. and V. diazotrophicus, reduced acetylene to ethylene and ethane, a property frequently associated with the activity of alternative nitrogenases. Addition of 25µM molybdenum inhibited ethane production by V. diazotrophicus, but stimulated ethylene and ethane production by the Photobacterium isolate. Addition of 28µM vanadium did not appear to regulate ethane production by either strain. Assays of nitrogenase activity in sediments from which some isolates were obtained indicated that molybdenum was not limiting nitrogenase activity at naturally-occurring concentrations. Southern hybridizations of the chromosomes of these strains with the anfH and vnfH genes of Azotobacter vinelandii and the nifH gene of Klebsiella pneumoniae indicated the presence of only one nitrogenase in these isolates.

Construction of chimeric proteins from the sigma N-associated transcriptional activators VnfA and AnfA of Azotobacter vinelandii shows that the determinants of promoter specificity lie outside the 'recognition' helix of the HTH motif in the C-terminal domain

Functional chimeras have been generated from the transcriptional activators VnfA and AnfA, which control expression of the alternative nitrogenases in Azotobacter vinelandii. The activation profiles of the native and chimeric proteins have been determined using lacZ fusions to A. vinelandii anf and vnf promoters in Klebsiella pneumoniae. Replacing the C-terminal domain of AnfA with that of VnfA gives a protein with the promoter specificity of VnfA, confirming that the C-terminal domain contains the determinants of promoter specificity. However, substituting the VnfA sequence from the turn in the helix-turn-helix motif to the C-terminus does not alter the promoter specificity of AnfA. These changes in promoter specificity were reflected in changes in affinity for a VnfA-binding site, as measured by an in vivo repression assay using a lacZ fusion to a synthetic promoter. This supports the assumption that promoter recognition is determined by activator binding to enhancer--like sequences, and shows that the principal determinants of specific DNA-binding lie outside the 'recognition' helix. This may be a general feature of transcriptional activators dependent on sigma N (sigma 54). The chimera with the promoter specificity of VnfA retained the dependence on nitrogenase Fe protein characteristic of AnfA, indicating that this property is not related to particular promoter sequences, but is a function of the central or N-terminal domains of AnfA.

Characterization of genes for an alternative nitrogenase in the cyanobacterium Anabaena variabilis

Anabaena variabilis ATCC 29413 is a heterotrophic, nitrogen-fixing cyanobacterium that has been reported to fix nitrogen and reduce acetylene to ethane in the absence of molybdenum. DNA from this strain hybridized well at low stringency to the nitrogenase 2 (vnfDGK) genes of Azotobacter vinelandii. The hybridizing region was cloned from a lambda EMBL3 genomic library of A. variabilis, mapped, and sequenced. The deduced amino acid sequences of the vnfD and vnfK genes of A. variabilis showed only about 56% similarity to the nifDK genes of Anabaena sp. strain PCC 7120 but were 76 to 86% similar to the anfDK or vnfDK genes of A. vinelandii. The organization of the vnf gene cluster in A. variabilis was similar to that of A. vinelandii. However, in A. variabilis, the vnfG gene was fused to vnfD; hence, this gene is designated vnfDG. A vnfH gene was not contiguous with the vnfDG gene and has not yet been identified. A mutant strain, in which a neomycin resistance cassette was inserted into the vnf cluster, grew well in a medium lacking a source of fixed nitrogen in the presence of molybdenum but grew poorly when vanadium replaced molybdenum. In contrast, the parent strain grew equally well in media containing either molybdenum or vanadium. The vnf genes were transcribed in the absence of molybdenum, with or without vanadium. The vnf gene cluster did not hybridize to chromosomal DNA from Anabaena sp. strain PCC 7120 or from the heterotrophic strains, Nostoc sp. strain Mac and Nostoc sp. strain ATCC 29150. A hybridizing ClaI fragment very similar in size to the A. variabilis ClaI fragment was present in DNA isolated from several independent, cultured isolates of Anabaena sp. from the Azolla symbiosis.

Organization of potential alternative nitrogenase genes from Clostridium pasteurianum

A 3.3 kb HindIII genomic DNA fragment from Clostridium pasteurianum ATCC 6013 which hybridized to the anfDGK genes for the Fe-only 'alternative' nitrogenase from Azotobacter vinelandii was cloned. Open reading frames (ORFs D, G, and K) with high sequence identity to anfD, anfG, and part of anfK were located in the nucleotide sequence obtained for 2494 bp of this fragment. In C. pasteurianum, ORFD maps approximately 1.8 kb downstream of nifH3 and is transcribed in the same direction. There was no evidence for additional copies of ORFDGK-like sequences in the genome of C. pasteurianum, other than those encoding the Mo-nitrogenase. Physiological and biochemical studies suggest that a nitrogenase not requiring molybdenum may occur in C. pasteurianum. This enzyme is probably encoded by nifH3 and ORFs D, G, and K identified here.

Molybdenum-independent nitrogenases of Azotobacter vinelandii: a functional species of alternative nitrogenase-3 isolated from a molybdenum-tolerant strain contains an iron-molybdenum cofactor

Nitrogenase-3 of Azotobacter vinelandii is synthesized under conditions of molybdenum and vanadium deficiency. The minimal metal requirement for its synthesis, and its metal content, indicated that the only transition metal in nitrogenase-3 was iron [Chisnell, Premakumar and Bishop (1988) J. Bacteriol. 170, 27-33; Pau, Mitchenall and Robson (1989) J. Bacteriol. 171, 124-129]. A new species of nitrogenase-3 has been purified from a strain of A. vinelandii (RP306) lacking structural genes for the Mo- and V-nitrogenases and containing a mutation which enables nitrogenase-3 to be synthesized in the presence of molybdenum. SDS/PAGE showed that component 1 contained a 15 kDa polypeptide which N-terminal amino acid sequence determination showed to be encoded by anfG. This confirms that nitrogenase-3, like V-nitrogenase, comprises three subunits. Preparations of the nitrogenase-3 from strain RP306 contained 24 Fe atoms and 1 Mo atom per molecule. Characterization of the cofactor centre of the enzyme by e.p.r. spectroscopy and an enzymic cofactor assay, together with stimulation of the growth of strain RP306 by Mo, showed that nitrogenase-3 can incorporate the Mo-nitrogenase cofactor (FeMoco) to form a functional enzyme. The specific activities (nmol of product produced/min per mg of protein) determined from activity titration curves were: under N2, NH3 formation 110, with concomitant H2 evolution of 220; under argon, H2 evolution 350; under 10% acetylene (C2H2) in argon, ethylene (C2H4) 58, ethane (C2H6) 26, and concomitant H2 evolution 226. The rate of formation of C2H6 was non-linear, and the C2H6/C2H4 ratio strongly dependent on the ratio of nitrogenase components.

Characterization of anf genes specific for the alternative nitrogenase and identification of nif genes required for both nitrogenases in Rhodobacter capsulatus

To identify Rhodobacter capsulatus nif genes necessary for the alternative nitrogenase, strains carrying defined mutations in 32 genes and open reading frames of nif region A, B or C were constructed. The ability of these mutants to grow on nitrogen-free medium with molybdenum (Nif phenotype) or in a nifHDK deletion background on medium without molybdenum (Anf phenotype) was tested. Nine nif genes and nif-associated coding regions are absolutely essential for the alternative nitrogenase. These genes comprise nifV and nifB, the nif-specific ntr system (nifR1, R2, R4) and four open reading frames, which exhibit no homology to known genes. In addition, a significantly reduced activity of both the alternative nitrogenase and the molybdenum-dependent nitrogenase was found for fdxN mutants. By random Tn5 mutagenesis of a nifHDK deletion strain 42 Anf- mutants were isolated. Southern hybridization experiments demonstrated that 17 of these Tn5 mutants were localized in at least 13 different restriction fragments outside of known nif regions. Ten different Anf- Tn5 mutations are clustered on a 6 kb DNA fragment of the chromosome designated anf region A. DNA sequence analysis revealed that this region contained the structural genes of the alternative nitrogenase (anfHDGK). The identification of several Tn5 insertions mapping outside of anf region A indicated that at least 10 genes specific for the alternative nitrogenase are present in R. capsulatus.

Expression of the nifBfdxNnifOQ region of Azotobacter vinelandii and its role in nitrogenase activity

The nifBQ transcriptional unit of Azotobacter vinelandii has been previously shown to be required for activity of the three nitrogenase systems, Mo nitrogenase, V nitrogenase, and Fe nitrogenase, present in this organism. We studied regulation of expression and the role of the nifBQ region by means of translational beta-galactosidase fusions to each of the five open reading frames: nifB, orf2 (fdxN), orf3 (nifO), nifQ, and orf5. Expression of the first three open reading frames was observed under all three diazotrophic conditions; expression of orf5 was never observed. Genes nifB and fdxN were expressed at similar levels. With Mo, expression of nifO and nifQ was approximately 20- and approximately 400-fold lower than that of fdxN, respectively. Without Mo, expression of nifB dropped three- to fourfold and that of nifQ dropped to the detection limit. However, expression of nifO increased threefold. The products of nifB, fdxN, nifO, and nifQ have been visualized in A. vinelandii as beta-galactosidase fusion proteins with the expected molecular masses. The NifB- fusion lacked activity for any of the three nitrogenase systems and showed an iron-molybdenum cofactor-deficient phenotype in the presence of Mo. The FdxN- mutation resulted in reduced nitrogenase activities, especially when V was present. Dinitrogenase activity in extracts was similarly affected, suggesting a role of FdxN in iron-molybdenum cofactor synthesis. The NifO(-)-producing mutation did not affect any of the nitrogenases under standard diazotrophic conditions. The NifQ(-)-producing mutation resulted in an increased (approximately 1,000-fold) Mo requirement for Mo nitrogenase activity, a phenotype already observed with Klebsiella pneumoniae. No effect of the NifQ(-)-producing mutation on V or Fe nitrogenase was found; this is consistent with its very low expression under those conditions. Mutations in orf5 had no effect on nitrogenase activity.

The ORF encoding a putative ferredoxin-like protein downstream of the vnfH gene in Azotobacter vinelandii is involved in the vanadium-dependent alternative pathway of nitrogen fixation

An open reading frame (ORF) in the same operon as, but downstream of, vnfH in Azotobacter vinelandii can code for a ferredoxin-like protein. The role this ORF may play in the vnf (vanadium-dependent alternative) pathway of nitrogen fixation was investigated. Site-directed mutagenesis was used to alter one base in each of the codons specifying amino acids 18 and 19 generating a unique Bg/II site. A kanamycin resistance cartridge was cloned into the Bg/II site. This construct was mobilized into A. vinelandii CA12 (delta nifHDK) strain by conjugation and the mutation was introduced into the genome by marker exchange. The resulting mutant was unable to fix nitrogen under conditions in which the vnf pathway of nitrogen fixation operates. This suggests that this ORF is functional and is essential for the vanadium-dependent alternative pathway of nitrogen fixation in A. vinelandii.

Regulation of nitrogenase-2 in Azotobacter vinelandii by ammonium, molybdenum, and vanadium

Under diazotrophic conditions in the absence of molybdenum and in the presence of vanadium, Azotobacter vinelandii reduces N2 to NH4+ by using nitrogenase-2, a V-containing enzyme complex encoded by vnfH (the gene for dinitrogenase reductase-2), and vnfDGK (the genes for dinitrogenase-2 subunits). Accumulation of the vnfHorfFd and vnfDGK transcripts occurred under Mo-deficient conditions in the presence and absence of V; however, in the case of vnfDGK, the protein products only accumulated in the presence of V. This suggests that V is required for translation of the vnfDGK transcripts. In addition, expression of vnfH-lacZ and vnfD-lacZ transcriptional fusions was only partially repressed in the presence of NH4+. Transcripts hybridizing with vnfH (1.4 and 1.0 kb), vnfDG (3.4 and 1.8 kb), and vnfK (3.4 kb) were detected in RNA extracted from wild-type cells cultured with NH4+ in the presence or absence of V. However, nitrogenase-2 subunits were not detected in extracts of cells derepressed for nitrogenase-2 in the presence of NH4+. These results indicate that this nitrogen source acts at the posttranscriptional level as well as at the transcriptional level. vnf transcripts were not detected in the presence of Mo (with or without NH4+).

The nifU, nifS and nifV gene products are required for activity of all three nitrogenases of Azotobacter vinelandii

Strains with mutations in 23 of the 30 genes and open reading frames in the major nif gene cluster of A. vinelandii were tested for ability to grow on N-free medium with molybdenum (Nif phenotype), with vanadium (Vnf phenotype), or with neither metal present (Anf phenotype). As reported previously, nifE, nifN, nifU, nifS and nifV mutants were Nif- (failed to grow on molybdenum) while nifM mutants were Nif-, Vnf- and Anf-. nifV, nifS, and nifU mutants were found to be unable to grow on medium with or without vanadium, i.e. were Vnf- Anf-. Therefore neither vnf nor anf analogoues of nifU, nifS, nifV or nifM are expected to be present in A. vinelandii.

Nucleotide sequence and mutational analysis of the vnfENX region of Azotobacter vinelandii

The nucleotide sequence (3,600 bp) of a second copy of nifENX-like genes in Azotobacter vinelandii has been determined. These genes are located immediately downstream from vnfA and have been designated vnfENX. The vnfENX genes appear to be organized as a single transcriptional unit that is preceded by a potential RpoN-dependent promoter. While the nifEN genes are thought to be evolutionarily related to nifDK, the vnfEN genes appear to be more closely related to nifEN than to either nifDK, vnfDK, or anfDK. Mutant strains (CA47 and CA48) carrying insertions in vnfE and vnfN, respectively, are able to grow diazotrophically in molybdenum (Mo)-deficient medium containing vanadium (V) (Vnf+) and in medium lacking both Mo and V (Anf+). However, a double mutant (strain DJ42.48) which contains a nifEN deletion and an insertion in vnfE is unable to grow diazotrophically in Mo-sufficient medium or in Mo-deficient medium with or without V. This suggests that NifE and NifN substitute for VnfE and VnfN when the vnfEN genes are mutationally inactivated. AnfA is not required for the expression of a vnfN-lacZ transcriptional fusion, even though this fusion is expressed under Mo- and V-deficient diazotrophic growth conditions.

Identification of an alternative nitrogenase system in Rhodospirillum rubrum

A second nitrogenase activity has been demonstrated in Rhodospirillum rubrum. This nitrogenase is expressed whenever a strain lacks an active Mo nitrogenase because of physiological or genetic inactivation. The alternative nitrogenase is able to support growth on N2 in the absence of fixed N. V does not stimulate, nor does Mo or W inhibit, growth or activity under the conditions tested. The proteins responsible for this activity were identified by electrophoretic and immunological properties. The synthesis of these proteins was repressed by NH4+. The alternative nitrogenase reductase is ADP ribosylated in response to darkness by the system that regulates the activity of the Mo nitrogenase. The genes for the alternative nitrogenase have been cloned, and the alternative nitrogenase reductase has been expressed in an in vitro transcription-translation system.

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.

Transcriptional regulation by metals of structural genes for Azotobacter vinelandii nitrogenases

Azotobacter vinelandii has three nitrogenases: a molybdenum (Mo) nitrogenase, a vanadium (V) nitrogenase, and a third nitrogenase (nitrogenase-3), which apparently lacks Mo and V. Mo represses synthesis of both V nitrogenase and nitrogenase-3, and in the absence of Mo, V represses synthesis of nitrogenase-3. We have investigated transcriptional regulation of the three nitrogenases by metals using Northern analysis and probes specific for transcripts of each of the three nitrogenases. Our results confirm that Mo is required for expression of the Mo nitrogenase structural genes (nifHDK), and substantiate the notion that Mo represses transcription of the structural genes for both V nitrogenase and nitrogenase-3. We show that repression by V of nitrogenase-3 is also effected at the level of transcription. Unexpectedly, V only represses transcription of the nitrogenase-3 structural genes (anfHDGK) if the V nitrogenase structural gene cluster vnfDGK is present. Further, deletion of nifHDK allows low expression of anfHDGK in the presence of Mo. Repression by Mo or V is independent of cofactor synthesis and therefore of enzyme activity.

Temperature-Dependent Regulation by Molybdenum and Vanadium of Expression of the Structural Genes Encoding Three Nitrogenases in Azotobacter vinelandii

Temperature affects the expression of the three different nitrogenases in Azotobacter vinelandii. Molybdenum repressed the vnfH and anfH operons relatively more at 30°C than at 20°C; at 14°C molybdenum did not repress these genes at all. Similarly, V repressed the anf operon at 30°C but not at 20 or 14°C. Mo was poorly transported into cells grown at the lower temperatures. A. vinelandii thus has the potential to synthesize any of the three nitrogenases at 14 to 20°C regardless of the presence of Mo or V.

Detection of alternative nitrogenases in aerobic gram-negative nitrogen-fixing bacteria

Strains of aerobic, microaerobic, nonsymbiotic, and symbiotic dinitrogen-fixing bacteria were screened for the presence of alternative nitrogenase (N2ase) genes by DNA hybridization between genomic DNA and DNA encoding structural genes for components 1 of three different enzymes. A nifDK gene probe was used as a control to test for the presence of the commonly occurring Mo-Fe N2ase, a vnfDGK gene probe was used to show the presence of V-Fe N2ase, and an anfDGK probe was used to detect Fe N2ase. Hitherto, all three enzymes have been identified in Azotobacter vinelandii OP, and all but the Fe N2ase are present in Azotobacter chroococcum ATCC 4412 (MCD1). Mo-Fe N2ase and V-Fe N2ase structural genes only were confirmed in this strain and in two other strains of A. chroococcum (ATCC 480 and ATCC 9043). A similar pattern was observed with Azotobacter beijerinckii ATCC 19360 and Azotobacter nigricans ATCC 35009. Genes for all three systems are apparently present in two strains of Azotobacter paspali (ATCC 23367 and ATCC 23833) and also in Azomonas agilis ATCC 7494. There was no good evidence for the existence of any genes other than Mo-Fe N2ase structural genes in several Rhizobium meliloti strains, cowpea Rhizobium strain 32H1, or Bradyrhizobium japonicum. Nitrogenase and nitrogenase genes in Azorhizobium caulinodans behaved in an intermediate fashion, showing (i) the formation of ethane from acetylene under Mo starvation, a characteristic of alternative nitrogenases, and (ii) a surprising degree of cross-hybridization to the vnfDGK, but not the anfDGK, probe. vnfDGK- and anfDGK-like sequences were not detected in two saccharolytic Pseudomonas species or Azospirillum brasilense Sp7. The occurrence of alternative N2ases seems restricted to members of the family Azotobacteraceae among the aerobic and microaerobic diazotrophs tested, suggesting that an ability to cope with O2 when fixing N2 may be an important factor influencing the distribution of alternative nitrogenases.