Two of the three groEL homologues in Rhizobium leguminosarum are dispensable for normal growth.

Although many bacteria contain only a single groE operon encoding the essential chaperones GroES and GroEL, examples of bacteria containing more than one groE operon are common. The root-nodulating bacterium Rhizobium leguminosarum contains at least three operons encoding homologues to Escherichia coli GroEL, referred to as Cpn60.1, Cpn60.2 and Cpn60.3, respectively. We report here a detailed analysis of the requirement for and relative levels of these three proteins. Cpn60.1 is present at higher levels than Cpn60.2, and Cpn60.3 protein could not be detected under any conditions although the cpn60.3 gene is transcribed under anaerobic conditions. Insertion mutations could not be constructed in cpn60.1 unless a complementing copy was present, showing that this gene is essential for growth under the conditions used here. Both cpn60.2 and cpn60.3 could be inactivated with no loss of viability, and a double cpn60.2 cpn60.3 mutant was also constructed which was fully viable. Thus only Cpn60.1 is required for growth of this organism.

Identification of gene products from the Azotobacter vinelandii nifBfdxNnifOQ operon.

The Azotobacter vinelandii nifBfdxNnifOQ operon is required for synthesis of the nitrogenase iron-molybdenum cofactor. To further characterize the roles of its gene products, specific antibodies against NifB and NifO were generated, and the NifB, NifO and NifQ gene products were visualized and identified in nitrogen-fixing A. vinelandii cell extracts by a combination of two-dimensional gel electrophoresis of radiolabelled extracts and immunological detection methods. The three proteins showed apparent pI and M(r) values similar to those expected from sequence data, except for NifO, which showed an apparent M(r) of ca. 23 kDa (vs. 16 kDa expected).

A novel plasmid series for in vitro production of phoA translational fusions and its use in the construction of Escherichia coli PhoE::PhoA hybrid proteins.

We have developed a series of vectors for easy construction of translational fusions with the phoA gene (encoding the periplasmic alkaline phosphatase, PhoA) in the three reading frames. One plasmid series carries a multiple cloning site (MCS) followed by a promoterless and leaderless 5'-truncated phoA ('phoA), which in turn is followed by a kanamycin-resistance-encoding gene (kan). Another plasmid series contains two identical inverted MCS flanking the phoA-kan cluster. These latter vectors are devised as phoA-kan cassette delivery vectors. In-frame cloning results in the production of hybrid PhoA proteins which display PhoA activity if successfully exported beyond the cytoplasmic membrane. In order to test these vectors, we have constructed hybrid PhoE::PhoA proteins, which were used to analyze the activity of the phoE promoter and identify the hybrid gene products.

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.

Hyperreiterated DNA regions are conserved among Bradyrhizobium japonicum serocluster 123 strains.

We have identified and cloned two DNA regions which are highly reiterated in Bradyrhizobium japonicum serocluster 123 strains. While one of the reiterated DNA regions, pFR2503, is closely linked to the B. japonicum common and genotype-specific nodulation genes in strain USDA 424, the other, pMAP9, is located next to a Tn5 insertion site in a host-range extension mutant of B. japonicum USDA 438. The DNA cloned in pFR2503 and pMAP9 are reiterated 18 to 21 times, respectively, in the genomes of B. japonicum serocluster 123 strains. Gene probes from the reiterated regions share sequence homology, failed to hybridize (or hybridized poorly) to genomic DNA from other B. japonicum and Bradyrhizobium spp. strains, and did not hybridize to DNA from Rhizobium meliloti, Rhizobium fredii, Rhizobium leguminosarum biovars trifolii, phaseoli, and viceae, or Agrobacterium tumefacians. The restriction fragment length polymorphism hybridization profiles obtained by using these gene probes are useful for discriminating among serologically related B. japonicum serocluster 123 strains.

The Bradyrhizobium japonicum nolA gene and its involvement in the genotype-specific nodulation of soybeans.

Several soybean genotypes have been identified which specifically exclude nodulation by members of Bradyrhizobium japonicum serocluster 123. We have identified and sequenced a DNA region from B. japonicum strain USDA 110 which is involved in genotype-specific nodulation of soybeans. This 2.3-kilobase region, cloned in pMJS12, allows B. japonicum serocluster 123 isolates to form nodules on plants of serogroup 123-restricting genotypes. The nodules, however, were ineffective for symbiotic nitrogen fixation. The nodulation-complementing region is located approximately 590 base pairs transcriptionally downstream from nodD2. The 5' end of pMJS12 contains a putative open reading frame (ORF) of 710 base pairs, termed nolA. Transposon Tn3-HoHo mutations only within the ORF abolished nodulation complementation. The N terminus of the predicted nolA gene product has strong similarity with the N terminus of MerR, the regulator of mercury resistance genes. Translational lacZ fusion experiments indicated that nolA was moderately induced by soybean seed extract and the isoflavone genistein. Restriction fragments that hybridize to pMJS12 were detected in genomic DNAs from both nodulation-restricted and -unrestricted strains.

Interspecies homology of nodulation genes in Rhizobium.

The internal structural portion of genes nodC and nodD (representatives of the two transcription units coding for common nodulation functions) and of hsnB and hsnD (genes from the two transcription units determining host-specificity of nodulation) have been cloned from Rhizobium meliloti into M13 vectors and used as probes against genomic DNAs from different Rhizobium strains and species. nodC and nodD were found in all species with one exception, indicating that they are common and widely spread genes, though the nodD gene hybridized only very weakly with slow-growing rhizobia. Interestingly, reiteration of nodD sequences was observed in almost all fast-growing strains (with the exception of R. leguminosarum). hsnB and, more so, hsnD are present only in a few species tested, supporting their specific involvement in R. meliloti-Medicago sativa symbiosis. In several cases the hybridizing bands from total Rhizobium DNA were compared to those found in recombinant plasmids carrying functional nodulation regions, and these analyses supported the notion that the bands indicate the presence of functional genes.

At least two nodD genes are necessary for efficient nodulation of alfalfa by Rhizobium meliloti.

A Rhizobium meliloti DNA region (nodD1) involved in the regulation of other early nodulation genes has been delimited by directed Tn5 mutagenesis and its nucleotide sequence has been determined. The sequence data indicate a large open reading frame with opposite polarity to nodA, -B and -C, coding for a protein of 308 (or 311) amino acid residues. Tn5 insertion within the gene caused a delay in nodulation of Medicago sativa from four to seven days. Hybridization of nodD1 to total DNA of Rhizobium meliloti revealed two additional nodD sequences (nodD2 and nodD3) and both were localized on the megaplasmid pRme41b in the vicinity of the other nod genes. Genetic and DNA hybridization data, combined with nucleotide sequencing showed that nodD2 is a functional gene, while requirement of nodD3 for efficient nodulation of M. sativa could not be detected under our experimental conditions. The nodD2 gene product consists of 310 amino acid residues and shares 86.4% homology with the nodD1 protein. Single nodD2 mutants had the same nodulation phenotype as the nodD1 mutants, while a double nodD1-nodD2 mutant exhibited a more severe delay in nodulation. These results indicate that at least two functional copies of the regulatory gene nodD are necessary for the optimal expression of nodulation genes in R. meliloti.