Contiguous organization of nitrogenase genes in a heterocystous cyanobacterium

The organization of the three structural nitrogen fixation (nif) genes that encode nitrogenase (nif K and nif D) and nitrogenase reductase (nif H) have been examined in a number of cyanobacteria. Hybridization of Anabaena 7120 nif gene probes to restriction endonuclease-digested genomic DNA has shown (a) that cyanobacteria incapable of N₂ fixation have no regions of DNA with significant homology to the three nif probes, (b) that Pseudanabaena sp., a nonheterocystous cyanobacterium, has a contiguous nif KDH gene cluster, and (c) that in contrast with other heterocystous cyanobacteria, Fischerella sp. has a contiguous nif KDH gene cluster.     

Nitrogen fixation genes (nif K,D,H) in the filamentous nonheterocystous cyanobacteriumPlectonema boryanum do not rearrange

The organisation of the structural genes for nitrogen fixation (nif K,D and H) in a nonheterocystous, filamentous cyanobacteriumPlectonema boryanum has been examined in comparison with a heterocystous cyanobacterium,Anabaena torulosa. DNA from repressed (fix-) cultures ofA. torulosa showed a discontinuousnif region spread over approximately 18 kb, an arrangement typical of the vegetative cells of heterocystous cyanobacteria. The region contained a contiguousnif DH separated fromnif K. by nearly 11 kb DNA. The intervening 11 kb DNA harboured the genexis A involved in the rearrangement ofnif K,D,H to form a cluster during differentiation of heterocysts. DNA fromPlectonema boryanum had a small, contiguousnif KDH cluster spanning a region of approximately 4 kb. DNA homologous to the 11 kb excison with its residentxis A was not present.Nif hybridisation patterns of restriction digests of the DNA isolated from repressed (fix^-) or induced (fix^--) cultures ofP. boryanum were completely identical. These results unequivocally demonstrate that in the nonheterocystous cyanobacterium, unlike in the heterocystous strains, no gene rearrangement, either within thenif KDII cluster or in its vicinity, accompanies the expression of nitrogenase activity.     

Genetic analysis of the het and nif genes in the blue-green alga Nostoc muscorum

Summary Two multiply marked complementary strains namely Het ⁺ Nif⁺ Str-R and Het ^- Nif^- Ery-R MSO-R were constructed and crossed under conditions counterselective for the Het ⁺ Nif⁺ Str-R parent and selective only for recombinants of Str-R and Ery-R or Str-R and MSO-R constitution. The results of the recombinant analysis with regard to the selected and unselected markers suggested that the Het ^- Nif^- Ery-R MSO-R parent acted as a recipient and the Het ⁺ Nif⁺ Str-R parent as donor of the genetic markers in the cross. The joint inheritance of Het ⁺ and Nif ⁺ unselected markers among the recombinants was found to occur more frequently than the inheritance of the Het ⁺ or Nif ⁺ markers alone. The observed joint inheritance of Het ⁺ and Nif ⁺ markers among the recombinants probably results from the inheritance of the regulatory gene(s) required for the activation of latent het and nif genes. This interpretation is fully supported by (a) the frequency distribution of unselected Het ⁺ and Nif ⁺ markers and (b) the reversion frequency of Het ^- Nif ^- strains to Het ⁺ Nif⁺ prototrophy. Accordingly the apparent close genetic linkage of het and nif genes is not due to their organization in a single operon but to their common regulation by regulatory gene(s) of a positive control nature. The Het ⁺ Nif⁺ wild type, mutant, revertant, and recombinant strains all appear similar in their NO ₃ ^- repression of both heterocyst and nitrogenase. The Het ⁺ Nif^- and Het ^- Nif⁺ recominants also show similar NO ₃ ^- repression of their heterocyst and nitrogenase respectively. The presence of only microaerobic acetylene reducing activity in Het ^- Nif⁺ recombinants clearly indicates the heterocyst to be an organ for protection of nitrogenase against oxygen toxicity.Abbreviations CFU Colony forming units - Ery erythromycin - Ery-R erythromycin resistance - het genotypic designation of genes required for heterocyst differentiation - Het phenotype designation of genes required for heterocyst differentiation - MSO l-Methionine-dl-sulfoximine - MSO-R MSO-resistance - N₂ medium Chu 10 medium without combined nitrogen - NH ₄ ⁺ medium basic mineral medium with ammonium nitrogen - nif genotype designation of genes required for N₂ fixation - Nif phenotype designation of genes required for N₂ fixation - NO ₃ ^- medium Chu 10 medium supplemented with KNO₃ - NTG N-methyl-N-nitro-N-nitrosoguanidine - r gene(s) regulatory gene(s) - Str streptomycin - Str-R streptomycin resistance - Str-S streptomycin sensitive     

Genetic control of heterocyst formation in the blue-Green algae Nostoc muscorum and nostoc linckia

Non-heterocystous, non-nitrogenfixing (het ^- nif^-), heterocystous, non-nitrogenfixing (het ⁺ nif^-) and multiple heterocystous, nitrogen-fixing (M-het ⁺ nif⁺) mutants of heterocystous, nitrogen-fixing (het ⁺ nif⁺) wild-type Nostoc muscorum and Nostoc linckia were isolated and characterized with respect to (a) nitrogenfixing activity, (b) reversion frequency, (c) ammonium repressibility of heterocyst formation, (d) heterocyst spacing pattern, and (e) action of L-methionine-DL-sulphoximine (MSO), an inhibitor of glutamine synthetase (GS), on heterocyst regulation. The mutant and revertant results suggest: (i) either involvement of a common genetic determinant in the formation of heterocyst and nitrogenase or the organization of het genes and nif genes in a single operon prone to complete inactivation by a single polar mutation, (ii) non-participation of active nitrogenase in regulation of heterocyst spacing; (iii) involvement of genetic factor(s) in the control of heterocyst spacing pattern in N. linckia, and (iv) apparently different nature of the mechanism of heterocyst inhibition by proheterocyst from that of heterocyst inhibition by NO ₃ ^- or NH ₄ ⁺ . L-Methionine-DL-sulphoximine inhibits growth and causes heterocyst formation in chains in N. linckia growing in nitrogen-free, NO ₃ ^- , NO ₂ ^- or NH ₄ ⁺ medium, thus indicating a close physiological linkage between heterocyst and inorganic nitrogen metabolism regulation.     

Organization of the nif genes in cyanobacteria in symbiotic association with Azolla and Anthoceros

The sizes of endonuclease digestion fragments of DNA from cyanobacteria in symbiotic association with Azolla caroliniana or Anthoceros punctatus, or in free-living culture, were compared by Southern hybridization using cloned nitrogenase (nif) genes from Anabaena sp. PCC 7120 as probes. The restriction fragment pattern produced by cyanobacteria isolated from A. caroliniana by culture through symbiotic association with Anthoceros differed from that of the major symbiotic cyanobacterium freshly separated from A. caroliniana. The results indicate that minor cyanobacterial symbionts occur in association with Azolla and that the dominant symbiont was not cultured in the free-living state. Both the absence of hybridization to an xisA gene probe and the mapping of restriction fragments indicated a contiguous nifHDK organization in all cells of the symbiont in association with Azolla. On the other hand, in the cultured isolate from Azolla and in Nostoc sp. 7801, the nifD and nifK genes are nominally separated by an interval of unknown length, compatible with the interruption of the nifHDK operon by a DNA element as observed in Anabaena sp. PCC 7120. In the above cultured strains, restriction fragments consistent with a contiguous nifHDK operon were also present at varying hybridization intensities, especially in Nostoc sp. 7801 grown in association with Anthoceros, presumably due to gene rearrangement in a fraction of the cells.Non-standard abbreviations bp base pairs - kb kilobase pairs - kd kilodaltons     

Isolation and Characterization of Frankia sp. Strain FaC1 Genes Involved in Nitrogen Fixation

Genomic DNA was isolated from Frankia sp. strain FaC1, an Alnus root nodule endophyte, and used to construct a genomic library in the cosmid vector pHC79. The genomic library was screened by in situ colony hybridization to identify clones of Frankia nitrogenase (nif) genes based on DNA sequence homology to structural nitrogenase genes from Klebsiella pneumoniae. Several Frankia nif clones were isolated, and hybridization with individual structural nitrogenase gene fragments (nifH, nifD, and nifK) from K. pneumoniae revealed that they all contain the nifD and nifK genes, but lack the nifH gene. Restriction endonuclease mapping of the nifD and nifK hybridizing region from one clone revealed that the nifD and nifK genes in Frankia sp. are contiguous, while the nifH gene is absent from a large region of DNA on either side of the nifDK gene cluster. Additional hybridizations with gene fragments derived from K. pneumoniae as probes and containing other genes involved in nitrogen fixation demonstrated that the Frankia nifE and nifN genes, which play a role in the biosynthesis of the iron-molybdenum cofactor, are located adjacent to the nifDK gene cluster.     

Nitrogen fixation in strains ofAzotobacter chroococcum bearing deletions of a cluster of genes coding for nitrogenase

Strains of the obligately aerobic nitrogen fixing organismAzotobacter chroococcum were constructed which contained defined chromosomal deletions in which the nitrogenase structural genenifHDK cluster (nifH for the polypeptide of the Fe-protein component of nitrogenase andnifD andnifK for the alpha and beta subunits respectively of the MoFe-protein component of the enzyme) was replaced by a kanamycin resistance gene. N₂ fixation was nevertheless observed in deletion strains though only in a molybdenum-deficient medium or in spontaneously arising tungstate-resistant derivatives. In comparison with the parent strain growing in molybdenum-sufficient medium, diazotrophic growth was slow and the nitrogenase activity in vivo was characterised by disproportionately low rates of C₂H₂-reduction compared to H₂-evolution and relative insensitivity of H₂-evolution to inhibition by C₂H₂. The findings show reiteration of functional structural genes for nitrogenase inA. chroococcum consistent with our previous observation of twonifH genes in this organism and detection in this work of a secondnifK-like sequence in the genomes of both parent and deletion strains whenA. chroococcum nifK DNA was used as a probe.     

Rearrangements of nitrogen fixation (nif) genes in the heterocystous cyanobacteria

In the vegetative cells of heterocystous cyanobacteria, such asAnabaena, two Operons harbouring the nitrogen fixaton (nif) genes contain two separate intervening DNA elements resulting in the dispersion of genes and impaired gene expression. A 11 kb element disrupts thenifD gene in thenifH, D-K operon. It contains a 11 bp sequence (GGATTACTCCG) directly repeated at its ends and harbours a gene,xisA, which encodes a site-specific recombinase. A large 55 kb element interrupts thefdxN gene in thenifB fdxN-nifS-nifU operon. It contains two 5 bp direct repeats (TATTC) at its ends and accommodates at least one gene,xisF, which encodes another site-specific recombinase. During heterocyst differentiation both the discontinuities are precisely excised by two distinct site-specific recombination events. One of them is brought about by the XisA protein between the 11 bp direct repeats. The second one is caused by the XisF protein and occurs between the 5 bp direct repeats. As a consequence the 11kb and 55 kb elements are removed from the chromosome as circles and functionalnif Operons are created. Nitrogenase proteins are then expressed from the rearranged genes in heterocysts and aerobic nitrogen fixation ensues. How these elements intruded thenif genes and how and why are they maintained in heterocystous cyanobacteria are exciting puzzles engaging considerable research effort currently. The unique developmental regulation of these gene rearrangements in heterocystous cyanobacteria is discussed.     

携带Paenibacillus polymyxa WLY78固氮基因簇(nif)的重组大肠杆菌Escherichia coli78-7转录组分析

[目的]来自Paenibacillus polymyxa WLY78的固氮基因簇（nifBHDKEfNXhesAnifV）可以转化入Escherichia coli中表达并使重组大肠杆菌合成有固氮活性的固氮酶。本文拟通过对重组大肠杆菌E.coli 78-7的转录组分析以提高其固氮能力。[方法]对固氮条件（无氧无NH₄⁺）和非固氮条件（空气和100 mmol/L NH₄⁺）培养的重组大肠杆菌E.coli 78-7进行转录组分析。[结果]nif基因在两种培养条件下显著表达,说明在重组大肠杆菌中可规避原菌中氧气和NH₄⁺对nif基因的负调控。对于固氮过程必需的非nif基因,如参与钼、硫、铁元素转运的mod、cys和feoAB,这些基因在两种培养条件下表达水平有差异。而参与铁硫簇合成的suf和isc基因簇在两条件下表达水平差异巨大。此外,参与氮代谢的基因在固氮条件下显著上调。[结论]重组大肠杆菌中与固氮相关的非nif基因在该菌的固氮过程中具有较大影响,本文对在异源宿主中调高固氮酶活性研究具有重要意义。     

Epilithic Cyanobacterial Communities of a Marine Tropical Beach Rock (Heron Island, Great Barrier Reef): Diversity and Diazotrophy

The diversity and nitrogenase activity of epilithic marine microbes in a Holocene beach rock (Heron Island, Great Barrier Reef, Australia) with a proposed biological calcification “microbialite” origin were examined. Partial 16S rRNA gene sequences from the dominant mat (a coherent and layered pink-pigmented community spread over the beach rock) and biofilms (nonstratified, differently pigmented microbial communities of small shallow depressions) were retrieved using denaturing gradient gel electrophoresis (DGGE), and a clone library was retrieved from the dominant mat. The 16S rRNA gene sequences and morphological analyses revealed heterogeneity in the cyanobacterial distribution patterns. The nonheterocystous filamentous genus Blennothrix sp., phylogenetically related to Lyngbya, dominated the mat together with unidentified nonheterocystous filaments of members of the Pseudanabaenaceae and the unicellular genus Chroococcidiopsis. The dominance and three-dimensional intertwined distribution of these organisms were confirmed by nonintrusive scanning microscopy. In contrast, the less pronounced biofilms were dominated by the heterocystous cyanobacterial genus Calothrix, two unicellular Entophysalis morphotypes, Lyngbya spp., and members of the Pseudanabaenaceae family. Cytophaga-Flavobacterium-Bacteroides and Alphaproteobacteria phylotypes were also retrieved from the beach rock. The microbial diversity of the dominant mat was accompanied by high nocturnal nitrogenase activities (as determined by in situ acetylene reduction assays). A new DGGE nifH gene optimization approach for cyanobacterial nitrogen fixers showed that the sequences retrieved from the dominant mat were related to nonheterocystous uncultured cyanobacterial phylotypes, only distantly related to sequences of nitrogen-fixing cultured cyanobacteria. These data stress the occurrence and importance of nonheterocystous epilithic cyanobacteria, and it is hypothesized that such epilithic cyanobacteria are the principal nitrogen fixers of the Heron Island beach rock.     

Light‐dependent oxygen consumption in nitrogen‐fixing cyanobacteria plays a key role in nitrogenase protection1

All colonial diazotrophic cyanobacteria are capable of simultaneously evolving O₂ through oxygenic photosynthesis and fixing nitrogen via nitrogenase. Since nitrogenase is irreversibly inactivated by O₂, accommodation of the two metabolic pathways has led to biochemical and/or structural adaptations that protect the enzyme from O₂. In some species, differentiated cells (heterocysts) are produced within the filaments. PSII is absent in the heterocysts, while PSI activity is maintained. In other, nonheterocystous species, however, a “division of labor” occurs whereby individual cells within a colony appear to ephemerally fix nitrogen while others evolve oxygen. Using membrane inlet mass spectrometry (MIMS) in conjunction with tracer ¹⁸O₂ and inhibitors of photosynthetic and respiratory electron transport, we examined the light dependence of O₂ consumption in Trichodesmium sp. IMS 101, a nonheterocystous, colonial cyanobacterium, and Anabaena flos‐aquae (Lyngb.) Bréb. ex Bornet et Flahault, a heterocystous species. Our results indicate that in both species, intracellular O₂ concentrations are maintained at low levels by the light‐dependent reduction of oxygen via the Mehler reaction. In N₂‐fixing Trichodesmium colonies, Mehler activity can consume ～75% of gross O₂ production, while in Trichodesmium utilizing nitrate, Mehler activity declines and consumes ～10% of gross O₂ production. Moreover, evidence for the coupling between N₂ fixation and Mehler activity was observed in purified heterocysts of Anabaena, where light accelerated O₂ consumption by 3‐fold. Our results suggest that a major role for PSI in N₂‐fixing cyanobacteria is to effectively act as a photon‐catalyzed oxidase, consuming O₂ through pseudocyclic electron transport while simultaneously supplying ATP in both heterocystous and nonheterocystous taxa.     

Nitrogen fixation andnif gene organization in branched heterocystous cyanobacteria: Variation in the presence ofxisA

Five branched heterocystous cyanobacteria (Scytonematopsis sp.,Scytonema sp.,Tolypothrix ceylonica, Mastigocladus sp. andFischerella sp.) were examined for their pattern of induction of nitrogenase activity andnif gene organization. All the forms showed the onset of nitrogenase activity after 12 h which could be correlated with the appearance of proheterocysts. The highest activity was exhibited byT. ceylonica. Hybridization studies revealed the presence of thenifD gene but the absence of thexisA gene inMastigocladus sp. andScytonematopsis sp. Interestingly,Tolypothrix sp. andScytonema sp. DNA samples hybridized withxisA. Hence no uniformity seems to exist regarding the presence ofxisA and the relatednif gene organization in branched heterocystous cyanobacteria. This investigation throws light on the primitive character and phylogenetic relatedness of branched forms to the coccoid/colonial forms. It also provides evidence for the proposition that stigonematacean cyanobacteria may not represent the most advanced cyanobacterial forms; rather they may link the coccoid and filamentous forms.     

Isolation and preliminary characterization of mutants of the cyanobacterium Nostoc muscorum resistant to growth inhibition by methylamine

Summary The wild-type heterocystous and nitrogen-fixing (Het ⁺ Nif ⁺) N. muscorum and its non-heterocystous non-nitrogen-fixing (Het ^- Nif ^-) mutant strain both fail to grow in different inorganic nitrogen media containing 1 mM methylamine hydrochloride (MA). Mutants of the Het ⁺ Nif ⁺ and Het ^- Nif ^- parents resistant to growth inhibition by 5 mM MA and thus designated as MA ^R strains were isolated with a frequency of 2.5(±2.4)×10⁶. A MA ^R strains of the Het ⁺ Nif ⁺ and a MA ^R strain of the Het ^- Nif ^- parent were characterized for growth, heterocyst formation and acetylene reducing activity in the presence and absence of methylamine in N₂ medium. The Het ⁺ Nif ⁺ MA ^R strain grows better in MA containing than in MA-free N₂ medium, and all cultures grown with MA are found to lack both acetylene reducing activity and heterocyst. The Het ^- Nif ^- MA ^R strain shows good growth in MA-containing N₂ medium but no growth in MA-free N₂ medium. Furthermore, both the Het ⁺ Nif ⁺ MA ^R and Het ^- Nif ^- MA ^R strains show better growth in the presence than in the absence of MA in NO ₃ ^- and NH ₄ ⁺ media. These results appear to suggest that the MA ^R phenotype in N. muscorum is due to the metabolic utilization of the ammonium analog as a nitrogen source.     

Inferring the Evolutionary History of Mo-Dependent Nitrogen Fixation from Phylogenetic Studies of nifK and nifDK

The ability to fix nitrogen is widely, but sporadically distributed among the Bacteria and Archaea suggesting either a vertically inherited, ancient function with widespread loss across genera or an adaptive feature transferred laterally between co-inhabitants of nitrogen-poor environments. As previous phylogenetic studies of nifH and nifD have not completely resolved the evolutionary history of nitrogenase, sixty nifD, nifK, and combined nifDK genes were analyzed using Bayesian, maximum likelihood, and parsimony algorithms to determine whether the individual and combined datasets could provide additional information. The results show congruence between the 16S and nifDK phylogenies at the phyla level and generally support vertical descent with loss. However, statistically significant differences between tree topographies suggest a complex evolutionary history with the underlying pattern of vertical descent obscured by recurring lateral transfer events and different patterns of evolution between the genes. Results support inheritance from the Last Common ancestor or an ancient lateral transfer of the nif genes between Bacteria and Archaea, ongoing gene transfer between cohabitants of similar biogeographic regions, acquisition of nitrogen-fixing capability via symbiosis islands, possible xenologous displacement of one gene in the operon, and possible retention of ancestral genes in heterocystous cyanobacteria. Analyses support the monophyly of the Cyanobacteria, αβγ-Proteobacteria, and Actinobacteria (Frankia) and provide strong support for the placement of Frankia nif genes at the base of combined the Cyanobacteria/Proteobacteria clades.     

Identification and cloning of nodulation genes from the stem-nodulating bacterium ORS571

Summary After random Tn5 mutagenesis of the stem-nodulating Sesbania rostrata symbiont strain ORS571, Nif^-, Fix^- and Nod^- mutants were isolated. The Nif^- mutants had lost both free-living and symbiotic N₂ fixation capacity. The Fix^- mutants normally fixed N₂ in the free-living state but induced ineffective nodules on S. rostrata. They were defective in functions exclusively required for symbiotic N₂ fixation. A further analysis of the Nod^- mutants allowed the identification of two nod loci. A Tn5 insertion in nod locus 1 completely abolished both root and stem nodulation capacity. Root hair curling, which is an initial event in S. rostrata root nodulation, was no longer observed. A 400 bp region showing weak homology to the nodC gene of Rhizobium meliloti was located 1.5 kb away from this nod Tn5 insertion. A Tn5 insertion in nod locus 2 caused the loss of stem and root nodulation capacity but root hair curling still occurred. The physical maps of a 20.5 kb DNA region of nod locus 1 and of a 40 kb DNA region of nod locus 2 showed no overlaps. The two nod loci are not closely linked to nif locus 1, containing the structural genes for the nitrogenase complex (Elmerich et al. 1982).     

Dinitrogen-Fixing Cyanobacteria in Microbial Mats of Two Shallow Coral Reef Ecosystems

Dinitrogen-fixing organisms in cyanobacterial mats were studied in two shallow coral reef ecosystems: La Reunion Island, southwestern Indian Ocean, Sesoko (Okinawa) Island, and northwestern Pacific Ocean. Rapidly expanding benthic miniblooms, frequently dominated by a single cyanobacterial taxon, were identified by microscopy and molecular tools. In addition, nitrogenase activity by these blooms was measured in situ. Dinitrogen fixation and its contribution to mat primary production were calculated using ¹⁵N₂ and ¹³C methods. Dinitrogen-fixing cyanobacteria from mats in La Reunion and Sesoko showed few differences in taxonomic composition. Anabaena sp. among heterocystous and Hydrocoleum majus and Symploca hydnoides among nonheterocystous cyanobacteria occurred in microbial mats of both sites. Oscillatoria bonnemaisonii and Leptolyngbya spp. occurred only in La Reunion, whereas Hydrocoleum coccineum dominated in Sesoko. Other mats dominated by Hydrocoleum lyngbyaceum, Phormidium laysanense, and Trichocoleus tenerrimus occurred at lower frequencies. The 24-h nitrogenase activity, as measured by acetylene reduction, varied between 11 and 324 nmoles C₂H₂ reduced μg⁻¹ Chl a. The highest values were achieved by heterocystous Anabaena sp. performed mostly during the day. Highest values for nonheterocystous cyanobacteria were achieved by H. coccineum mostly during the night. Daily nitrogen fixation varied from nine (Leptolyngbya) to 238 nmoles N₂ μg⁻¹ Chl day⁻¹ (H. coccineum). Primary production rates ranged from 1,321 (S. hydnoides) to 9,933 nmoles C μg⁻¹ Chl day⁻¹ (H. coccineum). Dinitrogen fixation satisfied between 5% and 21% of the nitrogen required for primary production.     

Insertion and deletion mutations within the nif region of Rhizobium japonicum

Insertion and deletion mutants were used to characterize a genomic region of Rhizobium japonicum where the nitrogenase structural genes are located on two separate operons nifDK and nifH. In addition to previously described nifD:: Tn5 and nifK:: Tn5 mutations we have now generated, by localized mutagenesis, further Tn5 insertion mutations in the vicinity of nifDK as well as within and adjacent to nifH. The nifD:: Tn5, nifK:: Tn5, and nifH:: Tn5 mutant strains were of the Nod⁺ Fix^- phenotype whereas all other mutants were symbiotically fully effective (Nod⁺ Fix⁺). The nifH:: Tn5 mutation was helpful in the identification of the nifH gene product (the dinitrogenase reductase) by two-dimensional gel electrophoresis: due to its polar effect this insertion specifically abolished the synthesis of that protein under microaerobic culture conditions. The ultrastructure of soybean root nodules infected with either the nif ⁺ wild-type or with the nif ^- (but otherwise isogenic) mutant strains was analyzed by electron microscopy. All contained fully developed bacteroids, but the nitrogen non-fixing mutants showed massive accumulation of PHB.Of Tn5-containing strains, kanamycin sensitive derivatives were obtained which contained deletions. Several classes of deletion mutants were found which, as judged by their physical DNA structure and their phenotypes, allowed the following most important conclusions: (i) deletions lacking both the nifDK and nifH regions indicate linkage between the two operons whereby at least 15 kb of DNA separate them; (ii) one deletion ending upstream from nifH, and lacking only nifDK, indicates that the nifDK operon is located on the 5-flanking side of the nifH operon; (iii) all deletion mutants are Nod⁺ indicating that there are no essential nodulation gnes located between and adjacent to nifDK and nifH.