Rhizobium nodM and nodN genes are common nod genes: nodM encodes functions for efficiency of nod signal production and bacteroid maturation.

Earlier, we showed that Rhizobium meliloti nodM codes for glucosamine synthase and that nodM and nodN mutants produce strongly reduced root hair deformation activity and display delayed nodulation of Medicago sativa (Baev et al., Mol. Gen. Genet. 228:113-124, 1991). Here, we demonstrate that nodM and nodN genes from Rhizobium leguminosarum biovar viciae restore the root hair deformation activity of exudates of the corresponding R. meliloti mutant strains. Partial restoration of the nodulation phenotypes of these two strains was also observed. In nodulation assays, galactosamine and N-acetylglucosamine could substitute for glucosamine in the suppression of the R. meliloti nodM mutation, although N-acetylglucosamine was less efficient. We observed that in nodules induced by nodM mutants, the bacteroids did not show complete development or were deteriorated, resulting in decreased nitrogen fixation and, consequently, lower dry weights of the plants. This mutant phenotype could also be suppressed by exogenously supplied glucosamine, N-acetylglucosamine, and galactosamine and to a lesser extent by glucosamine-6-phosphate, indicating that the nodM mutant bacteroids are limited for glucosamine. In addition, by using derivatives of the wild type and a nodM mutant in which the nod genes are expressed at a high constitutive level, it was shown that the nodM mutant produces significantly fewer Nod factors than the wild-type strain but that their chemical structures are unchanged. However, the relative amounts of analogs of the cognate Nod signals were elevated, and this may explain the observed host range effects of the nodM mutation. Our data indicate that both the nodM and nodN genes of the two species have common functions and confirm that NodM is a glucosamine synthase with the biochemical role of providing sufficient amounts of the sugar moiety for the synthesis of the glucosamine oligosaccharide signal molecules.     

In Rhizobium meliloti, the operon associated with the nod box n5 comprises nodL, noeA and noeB, three host-range genes specifically required for the nodulation of particular Medicago species

In Rhizobium meliloti , the genes required for nodulation of legume hosts are under the control of DNA regulatory sequences called nod boxes. In this paper, we have characterized three host-specific nodulation genes, which form a flavonoid-inducible operon down-stream of the nod box n5. The first gene of this operon is identical to the nodL gene identified by Baev and Kondorosi (1992) in R. meliloti strain AK631. The product of the second gene, NoeA, presents some homology with a methyl transferase. nodL mutants synthesize Nod factors lacking the O -acetate substituent. In contrast, in strains carrying a mutation in either noeA or noeB , no modification in Nod-factor structure or production could be detected. On particular hosts, such as Medicago littoralis , mutants of the n5 operon showed a very weak nodule-forming ability, associated with a drastic decrease in the number of infection threads, while nodulation of Medicago truncatula or Melilotus alba was not affected. Thus, nodL , noeA and noeB are host-specific nodulation genes. By using a gain-of-function approach, we showed that the presence of nodL , and hence of O -acetylated Nod factors, is a major prerequisite for confering the ability to nodulate alfalfa upon the heterologous bacterium Rhizobium tropici .     

N-Acetylglutamic acid: an extracellular nod signal of Rhizobium trifolii ANU843 that induces root hair branching and nodule-like primordia in white clover roots

An extracellular metabolite purified from Rhizobium trifolii ANU843 was established as N-acetylglutamic acid (GluNAc) by 1H NMR and Fourier transform IR spectroscopy, gas chromatography/mass spectrometry of its methylated product, and organic synthesis. TLC analyses indicated that extracellular accumulation of GluNAc by R. trifolii ANU843 grown in defined BIII culture medium was dependent on induction of its bacterial nodulation (nod) genes and the positive regulatory gene nodD on its symbiotic plasmid. 1H NMR analyses showed less GluNAc in fractionated culture supernatants of nodL and nodM mutant derivatives of R. trifolii ANU843. GluNAc induced three morphological responses on axenic roots of white clover seedlings: (i) root hair branching; (ii) tip swelling followed by resumed elongation of root hairs; and (iii) a slight increase in foci of cortical cell divisions, which developed into nodule-like primordia. These biological activities of extracellular GluNAc from R. trifolii ANU843 were confirmed with authentic standards of GluNAc. These results indicate that extracellular accumulation of N-acetylglutamic acid is linked to flavone-dependent metabolism involving nodD, nodL, and nodM in R. trifolii ANU843. This constitutes the first report on the structure of a nod-dependent extracellular signal from R. trifolii that can affect root hair and nodule development in white clover and whose biological activity on this host has been confirmed with authentic standards.     

Rhizobium meliloti lipooligosaccharide nodulation factors: different structural requirements for bacterial entry into target root hair cells and induction of plant symbiotic developmental responses.

Rhizobium meliloti produces lipochitooligosaccharide nodulation NodRm factors that are required for nodulation of legume hosts. NodRm factors are O-acetylated and N-acylated by specific C16-unsaturated fatty acids. nodL mutants produce non-O-acetylated factors, and nodFE mutants produce factors with modified acyl substituents. Both mutants exhibited a significantly reduced capacity to elicit infection thread (IT) formation in alfalfa. However, once initiated, ITs developed and allowed the formation of nitrogen-fixing nodules. In contrast, double nodF/nodL mutants were unable to penetrate into legume hosts and to form ITs. Nevertheless, these mutants induced widespread cell wall tip growth in trichoblasts and other epidermal cells and were also able to elicit cortical cell activation at a distance. NodRm factor structural requirements are thus clearly more stringent for bacterial entry than for the elicitation of developmental plant responses.     

Identification of a NodD repressible gene adjacent to nodM in Rhizobium leguminosarum biovar viciae

The nodFEL and nodMNT operons in Rhizobium leguminosarum biovar viciae are transcribed in the same orientation and induced by NodD in response to flavonoids secreted by legumes. In the narrow intergenic region between nodFEL and nodMNT, we identified a small gene divergently transcribed from nodM to the 3' end of nodL. Unlike the promoters upstream of nodF and nodM, the promoter of this gene is constitutively expressed. It appeared that its promoter might partially overlap with that of nodM and its expression was repressed by nodD. A deletion mutation was made and proteins produced by the mutant were compared with those by wild-type using 2D gel electrophoresis. Several protein differences were identified suggesting that this small gene influences the expression or stability of these proteins. However, the mutant nodulated its host plant (pea) normally.     

Rhizobium leguminosarum has two glucosamine syntheses, GImS and NodM, required for nodulation and development of nitrogen-fixing nodules

The Rhizobium leguminosarum nodM gene product shows strong homology to the Escherichia coli glmS gene product that catalyses the formation of glucosamine 6-P from fructose 6-P and glutamine. DNA hybridization with nodM indicated that, in addition to nodM on the symbiotic plasmid, another homologous gene was present elsewhere in the R. leguminosarum genome. A glucosamine-requiring mutant was isolated and its auxotrophy could be corrected by two different genetic loci. It could grow without glucosamine when the nodM gene on the symbiotic plasmid was induced or if the cloned nodM gene was expressed from a vector promoter. Alternatively, it could be complemented by a second fragment of R. leguminosarum DNA that carries a region homologous to E. coli glmS. Biochemical assays of glucosamine 6-P formation confirmed that the two R. leguminosarum genes nodM and glmS have interchangeable functions. No nodulation of peas or vetch was observed with a double nodM glmS mutant, and this block occurred at a very early stage since no root-hair deformation or infection threads were seen. Nodulation and root-hair deformation did occur with either the nodM or the glmS mutant, showing that the gene products of either of these genes can be involved in the formation of the lipo-oligosaccharide nodulation signal. However, the glmS mutant formed nodules that had greatly reduced nitrogen fixation. Constitutive expression of nodM restored nitrogen fixation to the glmS mutant. Therefore the reduced nitrogen fixation probably occurs because glmS is absent and nodM is not normally expressed in nodules and, in the absence of glucosamine precursors, normal bacteroid maturation is blocked.     

Detection and separation of Rhizobium and Bradyrhizobium Nod metabolites using thin-layer chromatography.

Using radioactive acetate as a precursor, it was shown that the common nodABC genes of Rhizobium and Bradyrhizobium strains are involved in the production of one or more metabolites that are excreted into the growth medium. A rapid thin-layer chromatography (TLC) system has been developed to separate these so-called Nod metabolites that can then be visualized by autoradiography. Different patterns of Nod metabolites were observed in the tested strains of the cross-inoculation groups of R. leguminosarum bv. viceae, R. l. bv. trifolii, R. meliloti, and B. japonicum. Only Nod metabolites of R. meliloti became labeled when radioactive sulphate was present in the medium. The role of the other nodulation genes of R. l. bv. viceae in the production of the detected Nod metabolites was tested in further detail. In addition to the common nodABC genes, the nodFE and nodL genes are involved in the production of Nod metabolites. In contrast, the chromosomal background did not influence the number of detected Nod metabolites or their mobilities on TLC plates. Nod metabolites could also be produced and excreted in Escherichia coli cells in which the appropriate nodulation genes were expressed.     

Interference between Rhizobium meliloti and Rhizobium trifolii nodulation genes: genetic basis of R. meliloti dominance.

Transfer of an IncP plasmid carrying the Rhizobium meliloti nodFE, nodG, and nodH genes to Rhizobium trifolii enabled R. trifolii to nodulate alfalfa (Medicago sativa), the normal host of R. meliloti. Using transposon Tn5-linked mutations and in vitro-constructed deletions of the R. meliloti nodFE, nodG, and nodH genes, we showed that R. meliloti nodH was required for R. trifolii to elicit both root hair curling and nodule initiation on alfalfa and that nodH, nodFE, and nodG were required for R. trifolii to elicit infection threads in alfalfa root hairs. Interestingly, the transfer of the R. meliloti nodFE, nodG, and nodH genes to R. trifolii prevented R. trifolii from infecting and nodulating its normal host, white clover (Trifolium repens). Experiments with the mutated R. meliloti nodH, nodF, nodE, and nodG genes demonstrated that nodH, nodF, nodE, and possibly nodG have an additive effect in blocking infection and nodulation of clover.     

Nucleotide sequence of Rhizobium meliloti RCR2011 genes involved in host specificity of nodulation.

A 6 kb DNA segment of the R. meliloti 2011 pSym megaplasmid, which contains genes controlling host specificity of root hair infection and of nodulation, was cloned and sequenced. The DNA sequence analysis, in conjunction with previous genetic data, allowed identification of four nod genes designated as E, F, G and H. nodH is divergently transcribed with respect to nodFE and nodG. A conserved nucleotide sequence was found around 200 bp upstream of the translation start of nodF, nodH and nodA. This sequence is also present upstream of common nodA and species specific nodF genes of other Rhizobium species. The predicted protein products of nodF and nodG show homology with acyl carrier protein and ribitol dehydrogenase, respectively. The nodH product contains a rare sequence of four contiguous proline residues. Comparison with the nod gene products of R. leguminosarum shows that species specific nodFE products are as well conserved as those of common nodABC and nodD genes.     

Molecular characterization of the nodulation gene, nodT, from two biovars of Rhizobium leguminosarum

DNA sequencing of the nodIJ region from Rhizobium leguminosarum biovar trifolii revealed the nodT gene immediately downstream of nodJ. DNA hybridizations using a nodT-specific probe showed that nodT is present in several R. leguminosarum strains. Interestingly, a flavonoid-inducible nodT gene homologue in R. leguminosarum bv. viciae is not in the nodABCIJ operon but is located downstream of nodMN. The sequence of the nodT gene from bv. viciae was determined and a comparison of the predicted amino-acid sequences of the two nodT genes shows them to be conserved; the predicted protein sequences appear to have a potential transit sequence typical of outer-membrane proteins. Mutations affecting nodT in either biovar had no observed effect on nodulation of the legumes tested.     

Cloning and sequence analysis of the arginine deiminase gene from Mycoplasma arginini

Summary A deletion mutant of Rhizobium leguminosarum biovar viciae lacking the host-specific nodulation (nod) gene region (nodFEL nodMNT and nodO) but retaining the other nod genes (nodD nodABCIJ) was unable to nodulate peas or Vicia hirsuta, although it did induce root hair deformation. The mutant appeared to be blocked in its ability to induce infection threads and could be rescued for nodulation of V. hirsuta in mixed inoculation experiments with an exopolysaccharide deficient mutant (which is also Nod^–). The nodulation deficiency of the deletion mutant strain could be partially restored by plasmids carrying the nodFE, nodFEL or nodFELMNT genes but not by nodLMN. Surprisingly, the mutant strain could also be complemented with a plasmid that did not carry any of the nodFELMNT genes but which did carry the nodO gene on a 30 kb cloned region of DNA. Using appropriate mutations it was established that nodO is essential for nodulation in the absence of nodFE. Thus, either of two independent nod gene regions can complement the deletion mutant for nodulation of V. hirsuta. Similar observations were made for pea nodulation except that nodL was required in addition to nodO for nodulation in the absence of the nodFE genes. These observations show that nodulation can occur via either of two pathways encoded by non-homologous genes.Dedicated to the memory of the late Dr. David Goodchild     

Rhizobial NodL O-acetyl transferase and NodS N-methyl transferase functionally interfere in production of modified Nod factors

The products of the rhizobial nodulation genes are involved in the biosynthesis of lipochitin oligosaccharides (LCOs), which are host-specific signal molecules required for nodule formation. The presence of an O-acetyl group on C-6 of the nonreducing N-acetylglucosamine residue of LCOs is due to the enzymatic activity of NodL. Here we show that transfer of the nodL gene into four rhizobial species that all normally produce LCOs that are not modified on C-6 of the nonreducing terminal residue results in production of LCOs, the majority of which have an acetyl residue substituted on C-6. Surprisingly, in transconjugant strains of Mesorhizobium loti, Rhizobium etli, and Rhizobium tropici carrying nodL, such acetylation of LCOs prevents the endogenous nodS-dependent transfer of the N-methyl group that is found as a substituent of the acylated nitrogen atom. To study this interference between nodL and nodS, we have cloned the nodS gene of M. loti and used its product in in vitro experiments in combination with purified NodL protein. It has previously been shown that a chitooligosaccharide N deacetylated on the nonreducing terminus (the so-called NodBC metabolite) is the preferred substrate for NodS as well as for NodL. Here we show that the NodBC metabolite, acetylated by NodL, is not used by the NodS protein as a substrate while the NodL protein can acetylate the NodBC metabolite that has been methylated by NodS.     

A cultivar-specific interaction between Rhizobium leguminosarum bv. trifolii and subterranean clover is controlled by nodM, other bacterial cultivar specificity genes, and a single recessive host gene.

Insertion mutagenesis identified two negatively acting gene loci which restrict the ability of Rhizobium leguminosarum bv. trifolii TA1 to infect the homologous host Trifolium subterraneum cv. Woogenellup. One locus was confirmed by DNA sequence analysis as the nodM gene, while the other locus, designated csn-1 (cultivar-specific nodulation), is not located on the symbiosis plasmid. The presence of these cultivar specificity loci could be suppressed by the introduction of the nodT gene from ANU843, a related R. leguminosarum bv. trifolii strain. Other nod genes, present in R. leguminosarum bv. viciae (including nodX) and R. meliloti, were capable of complementing R. leguminosarum bv. trifolii TA1 for nodulation on cultivar Woogenellup. Nodulation studies conducted with F2 seedlings from a cross between cultivar Geraldton and cultivar Woogenellup indicated that a single recessive gene, designated rwt1, is responsible for the Nod- association between strain TA1 and cultivar Woogenellup. Parallels can be drawn between this association and gene-for-gene systems common in interactions between plants and biotrophic pathogens.