Sequence and analysis of the rpoN sigma factor gene of rhizobium sp. strain NGR234, a primary coregulator of symbiosis.

We report the nucleotide sequence of the rpoN gene from broad-host-range Rhizobium sp. strain NGR234 and analyze the encoded RPON protein, a sigma factor. Comparative analysis of the deduced amino acid sequence of RPON from NGR234 with sequences from other gram-negative bacteria identified a perfectly conserved RPON box unique to RPON sigma factors. Symbiotic regulatory phenotypes were defined for a site-directed internal deletion within the coding sequence of the rpoN gene of Rhizobium strain NGR234: they included quantitative nodulation kinetics on Vigna unguiculata and microscopic analysis of the Fix- determinate nodules of V. unguiculata and Macroptilium atropurpureum. RPON was a primary coregulator of nodulation and was implicated in establishment or maintenance of the plant-synthesized peribacteroid membrane. Phenotypes of rpoN in Rhizobium strain NGR234 could be grouped as symbiosis related, rather than simply pleiotropically physiological as in free-living bacteria such as Klebsiella pneumoniae and Pseudomonas putida.     

Identification of Rhizobium-specific intergenic mosaic elements within an essential two-component regulatory system of Rhizobium species.

Analysis of the DNA regions upstream of the phosphoenolpyruvate carboxykinase gene (pckA) in Rhizobium meliloti and Rhizobium sp. strain NGR234 identified an open reading frame which was highly homologous to the Agrobacterium tumefaciens chromosomal virulence gene product ChvI. A second gene product, 500 bp downstream of the chvI-like gene in R. meliloti, was homologous to the A. tumefaciens ChvG protein. The homology between the R. meliloti and A. tumefaciens genes was confirmed, because the R. meliloti chvI and chvG genes complemented A. tumefaciens chvI and chvG mutants for growth on complex media. We were unable to construct chvI or chvG insertion mutants of R. meliloti, whereas mutants carrying insertions outside of these genes were readily obtained. A 108-bp repeat element characterized by two large palindromes was identified in the chvI and chvG intergenic regions of both Rhizobium species. This element was duplicated in Rhizobium sp. strain NGR234. Another structurally similar element with a size of 109 bp was present in R. meliloti but not in Rhizobium sp. strain NGR234. These elements were named rhizobium-specific intergenic mosaic elements (RIMEs), because their distribution seems to be limited to members of the family Rhizobiaceae. A homology search in GenBank detected six more copies of the first element (RIME1), all in Rhizobium species, and three extra copies of the second element (RIME2), only in R. meliloti. Southern blot analysis with a probe specific to RIME1 showed the presence of several copies of the element in the genome of R. meliloti, Rhizobium sp. strain NGR234, Rhizobium leguminosarum, and Agrobacterium rhizogenes, but none was present in A. tumefaciens and Bradyrhizobium japonicum.     

Molecular cloning of thentrA gene of the broad host-rangeRhizobium sp. NGR234, and phenotypes of a site-directed mutant

Summary The clonedntrA (rpoN) gene andntrA mutants ofRhizobium meliloti were used to isolate the homologous gene from the broad-host rangeRhizobium sp. NGR234 by hybridization and interspecies complementation. The NGR234 locus was analyzed by deletion and insertional mutagenesis. A site-directedntrA mutant, NGR234rn1, was made with an interposon, GmI, and its phenotype was examined ex planta and in symbiosis. NGR234rn1 formed Fix⁻ nodules on six genera tested from among its legume hosts, including both indeterminate and determinate nodule-type plants. Formation of nodules onMacroptilium was delayed, and expression of anR. meliloti nodABC-lacZ fusion was reduced by the mutant allele.     

Two C4-dicarboxylate transport systems in Rhizobium sp. NGR234: rhizobial dicarboxylate transport is essential for nitrogen fixation in tropical legume symbioses.

To investigate the role of dicarboxylate transport in nitrogen-fixing symbioses between Rhizobium and tropical legumes, we made a molecular genetic analysis of the bacterial transport system in Rhizobium sp. NGR234. This braod host range strain fixes nitrogen in association with evolutionarily divergent legumes. Two dicarboxylate transport systems were cloned from Rhizobium NGR234. One locus was chromosomally located, whereas the other was carried on the symbiotic plasmid (pSym) and contained a dctA carrier protein gene, which was analyzed in detail. Although the DNA and derived amino acid sequences of the structural gene were substantially homologous to that of R. meliloti, its promoter sequences was quite distinct, and the upstream sequence also exhibited no homology to dctB, which is found at this position in R. meliloti. A site-directed internal deletion mutant in dctA of NGR234 exhibited a (unique) exclusively symbiotic phenotype that could grow on dicarboxylates ex planta, but could not fix nitrogen in planta. This phenotype was found for tested host plants of NGR234 with either determinate- or indeterminate-type nodules, confirming for the first time that symbiosis-specific uptake of dicarboxylates is a prerequisite for nitrogen fixation in tropical legume symbioses.     

Rhizobium sp. strain NGR234 NodZ protein is a fucosyltransferase.

Rhizobium sp. strain NGR234 produces a large family of lipochitooligosaccharide Nod factors carrying specific substituents. Among them are 3-O- (or 4-O-) and 6-O-carbamoyl groups, an N-methyl group, and a 2-O-methylfucose residue which may bear either 3-O-sulfate or 4-O-acetyl substitutions. Investigations on the genetic control of host specificity revealed a number of loci which directly affect Nod factor structure. Here we show that insertion and frameshift mutations in the nodZ gene abolish fucosylation of Nod factors. In vitro assays using GDP-L-fucose as the fucose donor show that fucosyltransferase activity is associated with the nodZ gene product (NodZ). NodZ is located in the soluble protein fraction of NGR234 cells. Together with extra copies of the nodD1 gene, the nodZ gene and its associated nod box were introduced into ANU265, which is NGR234 cured of the symbiotic plasmid. Crude extracts of this transconjugant possess fucosyltransferase activity. Fusion of a His6 tag to the NodZ protein expressed in Escherichia coli yielded a protein able to fucosylate both nonfucosylated NodNGR factors and oligomers of chitin. NodZ is inactive on monomeric N-acetyl-D-glucosamine and on desulfated Rhizobium meliloti Nod factors. Kinetic analyses showed that the NodZ protein is more active on oligomers of chitin than on nonfucosylated NodNGR factors. Pentameric chitin is the preferred substrate. These data suggest that fucosylation occurs before acylation of the Nod factors.     

Isolation of unique nucleic acid sequences from rhizobia by genomic subtraction: Applications in microbial ecology and symbiotic gene analysis

A subtraction hybridization and PCR amplification procedure was used to isolate two Rhizobium DNA probes which exhibited high degrees of specificity at different levels of taxonomic organization and which could be used as tools for detection of rhizobia in ecological studies. First, a probe was isolated from Rhizobium leguminosarum bv. trifolii strain P3 by removing those Sau3A restriction fragments from a P3 DNA digest which cross hybridized with pooled DNA from seven other strains of the same biovar. The remaining restriction fragments hybridized to DNA from strain P3 but not to DNA from any of the seven other strains. In a similar experiment another DNA probe, specific for the Rhizobium leguminosarum bv. phaseoli and Rhizobium tropici group, was generated by removing sequences from R. leguminosarum bv phaseoli strain Kim 5s with pooled subtracter DNA from eight other Rhizobium, Bradyrhizobium and Agrobacterium species. The same subtraction hybridization technique was also used to isolate symbiotic genes from a Rhizobium species. Results from a 1:1 subtractive DNA hybridization of the broad host range Rhizobium sp NGR234 against highly homologous S. fredii USDA257, combined with those from competitive RNA hybridizations to cosmid digests of the NGR234 symbiotic plasmid, allowed the identification of several NGR234 loci which were flavonoid-inducible and not present in S. fredii USDA257. One of these, ORF-1, was highly homologous to the leucine responsive regulatory protein of E. coli.     

Functional and evolutionary relatedness of genes for exopolysaccharide synthesis in Rhizobium meliloti and Rhizobium sp. strain NGR234.

Rhizobium meliloti SU47 and Rhizobium sp. strain NGR234 produce distinct exopolysaccharides that have some similarities in structure. R. meliloti has a narrow host range, whereas Rhizobium strain NGR234 has a very broad host range. In cross-species complementation and hybridization experiments, we found that several of the genes required for the production of the two polysaccharides were functionally interchangeable and similar in evolutionary origin. NGR234 exoC and exoY corresponded to R. meliloti exoB and exoF, respectively. NGR234 exoD was found to be an operon that included genes equivalent to exoM, exoA, and exoL in R. meliloti. Complementation of R. meliloti exoP, -N, and -G by NGR234 R'3222 indicated that additional equivalent genes remain to be found on the R-prime. We were not able to complement NGR234 exoB with R. meliloti DNA. In addition to functional and evolutionary equivalence of individual genes, the general organization of the exo regions was similar between the two species. It is likely that the same ancestral genes were used in the evolution of both exopolysaccharide biosynthetic pathways and probably of pathways in other species as well.     

Identification of a nodD-dependent locus in the Rhizobium strain NGR234 activated by phenolic factors secreted by soybeans and other legumes

Transfer of the strain NGR234nodD 1 gene into the narrow host range R. trifolii strain ANU843 on either a 6.7-kb HindIII or 17-kb XhoI fragment broadens the host range of this bacterium to include the tropical legumes Vigna unguiculata, Glycine ussuriensis, Leucaena leucocephala, and siratro (Macroptilium atropurpureum). Contrary to previous data (Bassam et al. 1986), mutagenesis of the 17-kb XhoI fragment with a mini-Mu lac transposon (Mu dII1734) showed that a functional nodD 1 gene was essential for extended host range. Gene expression studies using both Mu dII1734 fusions and a promoter-cloning vector indicated that several loci, including the nodD 1 gene, are constitutively expressed. No evidence was found for regulation of the strain NGR234 nodD 1 gene by its product. Another locus nod-81, was induced only in the presence of exudates from various plant species, including soybean (Glycine max). Whereas the expression of nod-81 was dependent on the presence of a functional nodD 1 gene product, a regulatory nod-box DNA sequence was not detected 5' to this gene by using available oligonucleotide hybridization probes. The nod-81 locus was induced by genistein, daidzein, naringenin, and coumestrol from both cotyledon and root tissue of freshly germinated soybean seedlings. A broad spectrum of commercially available phenolic compounds stimulated induction of the nod-81 locus, including some that antagonize nod gene induction in other Rhizobium species. The nodD 1 gene product from strain NGR234 was shown to determine the spectrum of compounds that induce nod-81 expression.     

Characterization of NopP, a type III secreted effector of Rhizobium sp. strain NGR234

The type three secretion system (TTSS) encoded by pNGR234a, the symbiotic plasmid of Rhizobium sp. strain NGR234, is responsible for the flavonoid- and NodD1-dependent secretion of nodulation outer proteins (Nops). Abolition of secretion of all or specific Nops significantly alters the nodulation ability of NGR234 on many of its hosts. In the closely related strain Rhizobium fredii USDA257, inactivation of the TTSS modifies the host range of the mutant so that it includes the improved Glycine max variety McCall. To assess the impact of individual TTSS-secreted proteins on symbioses with legumes, various attempts were made to identify nop genes. Amino-terminal sequencing of peptides purified from gels was used to characterize NopA, NopL, and NopX, but it failed to identify SR3, a TTSS-dependent product of USDA257. By using phage display and antibodies that recognize SR3, the corresponding protein of NGR234 was identified as NopP. NopP, like NopL, is an effector secreted by the TTSS of NGR234, and depending on the legume host, it may have a deleterious or beneficial effect on nodulation or it may have little effect.     

Heterologous exopolysaccharide production in Rhizobium sp. strain NGR234 and consequences for nodule development.

Rhizobium sp. strain NGR234 produces large amounts of acidic exopolysaccharide. Mutants that fail to synthesize this exopolysaccharide are also unable to nodulate the host plant Leucaena leucocephala. A hybrid strain of Rhizobium sp. strain NGR234 containing exo genes from Rhizobium meliloti was constructed. The background genetics and nod genes of Rhizobium sp. strain NGR234 are retained, but the cluster of genes involved in exopolysaccharide biosynthesis was deleted. These exo genes were replaced with genes required for the synthesis of succinoglycan exopolysaccharide from R. meliloti. As a result of the genetic manipulation, the ability of these hybrids to synthesize exopolysaccharide was restored, but the structure was that of succinoglycan and not that of Rhizobium sp. strain NGR234. The replacement genes were contained on a cosmid which encoded the entire known R. meliloti exo gene cluster, with the exception of exoB. Cosmids containing smaller portions of this exo gene cluster did not restore exopolysaccharide production. The presence of succinoglycan was indicated by staining with the fluorescent dye Calcofluor, proton nuclear magnetic resonance spectroscopy, and monosaccharide analysis. Although an NGR234 exoY mutant containing the R. meliloti exo genes produced multimers of the succinoglycan repeat unit, as does the wild-type R. meliloti, the deletion mutant of Rhizobium sp. strain NGR234 containing the R. meliloti exo genes produced only the monomer. The deletion mutant therefore appeared to lack a function that affects the multiplicity of succinoglycan produced in the Rhizobium sp. strain NGR234 background. Although these hybrid strains produced succinoglycan, they were still able to induce the development of an organized nodule structure on L. leucocephala. The resulting nodules did not fix nitrogen, but they did contain infection threads and bacteroids within plant cells. This clearly demonstrated that a heterologous acidic exopolysaccharide structure was sufficient to enable nodule development to proceed beyond the developmental barrier imposed on mutants of Rhizobium sp. strain NGR234 that are unable to synthesize any acidic exopolysaccharide.     

Rhizobia catabolize nod gene-inducing flavonoids via C-ring fission mechanisms.

Gas chromatographic and mass spectrometric analyses of derivatized culture medium extracts were used to identify the products of flavonoid metabolism by rhizobia. A number of Rhizobium species and biovars degraded their nod gene-inducing flavonoids by mechanisms which originated in a cleavage of the C-ring of the molecule and which yielded conserved A- and B-ring products among the metabolites. In contrast, Pseudomonas putida degraded quercetin via an initial fission in its A-ring, and Agrobacterium tumefaciens displayed a nonspecific mode of flavonoid degradation which yielded no conserved A- or B-ring products. When incubated with rhizobia, flavonoids with OH substitutions at the 5 and 7 positions yielded phloroglucinol as the conserved A-ring product, and those with a single OH substitution at the 7 position yielded resorcinol. A wider range of structures was found among the B-ring derivatives, including p-coumaric, p-hydroxybenzoic, protocatechuic, phenylacetic, and caffeic acids. The isoflavonoids genistein and daidzein were also degraded via C-ring fission by Rhizobium fredii and Rhizobium sp. strain NGR234, respectively. Partially characterized aromatic metabolites with potential nod gene-inducing activity were detected among the products of naringenin degradation by Rhizobium leguminosarum bv. viciae. The initial structural modification of nod gene-inducing flavonoids by rhizobia can generate chalcones, whose open C-ring system may have implications for the binding of inducers to the nodD gene product.     

Degradation of trehalose by rhizobia and characteristics of a trehalose-degrading enzyme isolated from Rhizobium species NGR234

AIMS: This study was designed to examine the breakdown of trehalose by rhizobia and to characterize the trehalose-degrading enzyme isolated from Rhizobium sp. NGR234. METHODS AND RESULTS: Rhizobium sp. NGR234, Rhizobium fredii USDA257, R. phaseoli RCR3622, R. tropici CIAT899 and R. etli CE3 showed good growth in the presence of carbohydrate. Validamycin A did not prevent the growth of NGR234 on trehalose. The expression of a trehalose-degrading enzyme by NGR234 was intracellular and inducible by trehalose. The isolated enzyme digested other disaccharides, p-nitrophenyl-alpha-d-glucopyranoside and the substrate. The enzyme showed optimum activities at pH 7.0 and 30 degrees C. Its pI was 4.75 and the V(max) of the enzyme occurred at 35.7 micromol s(-1) mg(-1) protein with the K(m) of 23 mmol when trehalose was hydrolysed. CONCLUSIONS: An enzyme capable of breaking down trehalose was produced. Some of the properties of the trehalose-degrading enzyme are similar to those isolated from other organisms but, this enzyme was validamycin resistant. These rhizobia like other trehalose-degrading microbes use trehalose by enzymatic catabolic action. SIGNIFICANCE AND IMPACT OF THE STUDY: Trehalose which accumulates during legume-rhizobia symbiosis is toxic to plants. Detoxification by trehalose-degrading enzymes is important for the progress of symbiosis.     

Cyclic-β-glucans of Rhizobium (Sinorhizobium) sp. strain NGR234 are required for hypo-osmotic adaptation, motility, and efficient symbiosis with host plants

Cyclic-β-glucans (CβG) consist of cyclic homo-polymers of glucose that are present in the periplasmic space of many Gram-negative bacteria. A number of studies have demonstrated their importance for bacterial infection of plant and animal cells. In this study, a mutant of Rhizobium (Sinorhizobium) sp. strain NGR234 (NGR234) was generated in the cyclic glucan synthase (ndvB)-encoding gene. The great majority of CβG produced by wild-type NGR234 are negatively charged and substituted. The ndvB mutation abolished CβG biosynthesis. We found that, in NGR234, a functional ndvB gene is essential for hypo-osmotic adaptation and swimming, attachment to the roots, and efficient infection of Vigna unguiculata and Leucaena leucocephala.     

Role of BacA in lipopolysaccharide synthesis, peptide transport, and nodulation by Rhizobium sp. strain NGR234

BacA of Sinorhizobium meliloti plays an essential role in the establishment of nitrogen-fixing symbioses with Medicago plants, where it is involved in peptide import and in the addition of very-long-chain fatty acids (VLCFA) to lipid A of lipopolysaccharide (LPS). We investigated the role of BacA in Rhizobium species strain NGR234 by mutating the bacA gene. In the NGR234 bacA mutant, peptide import was impaired, but no effect on VLCFA addition was observed. More importantly, the symbiotic ability of the mutant was comparable to that of the wild type for a variety of legume species. Concurrently, an acpXL mutant of NGR234 was created and assayed. In rhizobia, AcpXL is a dedicated acyl carrier protein necessary for the addition of VLCFA to lipid A. LPS extracted from the NGR234 mutant lacked VLCFA, and this mutant was severely impaired in the ability to form functional nodules with the majority of legumes tested. Our work demonstrates the importance of VLCFA in the NGR234-legume symbiosis and also shows that the necessity of BacA for bacteroid differentiation is restricted to specific legume-Rhizobium interactions.