The Rhizobium meliloti early nodulation genes (nodABC) are nitrogen-regulated: Isolation of a mutant strain with efficient nodulation capacity on alfalfa in the presence of ammonium

Summary The presence of combined nitrogen in the soil suppresses the formation of nitrogen-fixing root nodules by Rhizobium. We demonstrate that bacterial genes determining early nodulation functions (nodABC) as well as the regulatory gene nodD3 are under nitrogen (NH ₄ ⁺ ) control. Our results suggest that the gene product of nodD3 has a role in mediating the ammonia regulation of early nod genes. The general nitrogen regulatory (ntr) system as well as a chromosomal locus mutated in Rhizobium meliloti were also found to be involved in the regulation of nod gene expression. A R. meliloti mutant with altered sensitivity to ammonia regulation was isolated, capable of more efficient nodulation of alfalfa than the wild-type strain in the presence of 2 mM ammonium sulfate.     

NoIR controls expression of the Rhizobium meliloti nodulation genes involved in the core Nod factor synthesis

The synthesis of Rhizobium meliloti Nod signal molecules, encoded by the nod gene products, is finely regulated. A negative control of plasmid-borne nod gene expression is provided by the NoIR repressor encoded by the chromosomal noIR gene. NoIR was previously shown to downregulate the expression of the activator nodD1 gene and the common nodABC operon by binding to an overlapping region of the two promoters adjacent to the n1 nod-box (Kondorosi et al., 1989). We demonstrate here that NoIR also controls the expression of two additional genes, nodD2 and nodM, but does not directly regulate the expression of the host-specific nod genes located downstream of the n2, n3 and n5 nod-boxes. Thus, the nod genes are differentially regulated by NoIR and only those providing common nodulation functions, by determining the synthesis of the core Nod factor structure, are subjected to this negative regulation. Furthermore, NoIR has a strong negative effect on the production of Nod metabolites, the level of which may serve as a fine-tuning mechanism for optimal nodulation, specific to host-plant genotypes. In addition, it elicits preferential synthesis of Nod factors carrying unsaturated C₁₆ fatty acids. Expression of noIR was high both in the free-living bacterium and in the bacteroid and it was downregulated by its own product and by the nod gene inducer luteolin.     

Chemotaxis of Rhizobium meliloti towards Nodulation Gene-Inducing Compounds from Alfalfa Roots

Luteolin, a flavone present in seed exudates of alfalfa, induces nodulation genes (nod) in Rhizobium meliloti and also serves as a biochemically specific chemoattractant for the bacterium. The present work shows that R. meliloti RCR2011 is capable of very similar chemotactic responses towards 4′,7-dihydroxyflavone, 4′,7-Dihydroxyflavanone, and 4,4′-dihydroxy-2-methoxychalcone, the three principal nod gene inducers secreted by alfalfa roots. Chemotactic responses to the root-secreted nod inducers in capillary assays were usually two- to four-fold above background and, for the flavone and flavonone, occurred at concentrations lower than those required for half-maximal induction of the nodABC genes. Complementation experiments indicated that the lack of chemotactic responsiveness to luteolin seen in nodD1 and nodA mutants of R. meliloti was not due to mutations in the nod genes, as previously thought. Thus, while nod gene induction and flavonoid chemotaxis have the same biochemical specificity, these two functions appear to have independent receptors or transduction pathways. The wild-type strain was found to suffer selective, spontaneous loss of chemotaxis towards flavonoids during laboratory subculture.     

Ammonia regulation of nod genes in Bradyrhizobium japonicum

Summary The expression of the nodD and nodYABC operons of Bradyrhizobium japonicum is repressed by the addition of ammonia. Repression of nodYABC expression is probably due to the effect on nodD since NodD positively regulates itself, as well as other nod operons. The effect of ammonia is independent of the known nitrogen regulatory protein, NtrC, and another regulatory protein for nitrogen fixation, NifA.     

Increase in Alfalfa Nodulation, Nitrogen Fixation, and Plant Growth by Specific DNA Amplification in Sinorhizobium meliloti

To improve symbiotic nitrogen fixation on alfalfa plants, Sinorhizobium meliloti strains containing different average copy numbers of a symbiotic DNA region were constructed by specific DNA amplification (SDA). A DNA fragment containing a regulatory gene (nodD1), the common nodulation genes (nodABC), and an operon essential for nitrogen fixation (nifN) from the nod regulon region of the symbiotic plasmid pSyma of S. meliloti was cloned into a plasmid unable to replicate in this organism. The plasmid then was integrated into the homologous DNA region of S. meliloti strains 41 and 1021, which resulted in a duplication of the symbiotic region. Sinorhizobium derivatives carrying further amplification were selected by growing the bacteria in increased concentrations of an antibiotic marker present in the integrated vector. Derivatives of strain 41 containing averages of 3 and 6 copies and a derivative of strain 1021 containing an average of 2.5 copies of the symbiotic region were obtained. In addition, the same region was introduced into both strains as a multicopy plasmid, yielding derivatives with an average of seven copies per cell. Nodulation, nitrogenase activity, plant nitrogen content, and plant growth were analyzed in alfalfa plants inoculated with the different strains. The copy number of the symbiotic region was critical in determining the plant phenotype. In the case of the strains with a moderate increase in copy number, symbiotic properties were improved significantly. The inoculation of alfalfa with these strains resulted in an enhancement of plant growth.     

Positive and negative control of nod gene expression in Rhizobium meliloti is required for optimal nodulation

We show that expression of common nodulation genes in Rhizobium meliloti is under positive as well as negative control. A repressor protein was found to be involved in the negative control of nod gene expression. Whereas the activator NodD protein binds to the conserved cis-regulatory element (nod-box) required for coordinated regulation of nod genes, the repressor binds to the overlapping nodD1 and nodA promoters, at the RNA polymerase binding site. A model depicting the possible interaction of the plant-derived nod gene inducer (luteolin), the NodD and the repressor with the nod promoter elements is presented. Mutants lacking the repressor exhibited delayed nodulation phenotype, indicating that fine tuning of nod gene expression is required for optimal nodulation of the plant host.     

Host-specificity mutants of Rhizobium meliloti have additive effects in situ on initiation of alfalfa nodules

Pairs of Rhizobium meliloti nod mutants were co-inoculated onto alfalfa (Medicago saliva L.) roots to determine whether one nod mutant could correct, in situ, for defects in nodule initiation of another nod mutant. None of the Tn5 or nod deletion mutants were able to help each other form nodules when co-inoculated together in the absence of the wild-type. However, as previously observed, individual nod mutants significantly increased nodule initiation by low dosages of co-inoculated wild-type cells. Thus, nod mutants do produce certain signal substances or other factors which overcome limits to nodule initiation by the wild-type. When pairs of nod mutants were co-inoculated together with the wild-type, the stimulation of nodulation provided by individual nodABC mutants was not additive. However, clearly additive or synergistic stimulation was observed between pairs of mutants with a defective host-specificity gene (nodE, nodF, or nodH). Each pair of host-specificity mutants stimulated first nodule formation to nearly the maximum levels obtainable with high dosages of the wild-type. Mutant bacteria were recovered from only about 10% of these nodules, whereas the co-inoculated wild-type was present in all these nodules and substantially outnumbered mutant bacteria in nodules occupied by both. Thus, these mutant co-inoculants appeared to help their parent in situ even though they could not help each other. Sterile culture filtrates from wild-type cells stimulated nodule initiation by low dosages of the wild-type, but only when a host-specificity mutant was also present. The results from our studies seem consistent with the possibility that pairs of host-specificity mutants are able to help the wild-type initiate nodule formation by sustained production of complementary signals required for induction of symbiotic host responses.     

Regulation of nod gene expression in Bradyrhizobium japonicum

Summary The best inducers of nod:: lacZ translational fusions in Bradyrhizobium japonicum are isoflavones, primarily genistein and daidzein. Upstream of the nodABC genes in B. japonicum is a novel gene, nodY, which is coregulated with nodABC. Measurements of the activity of lacZ fusions to the nodD gene of B. japonicum show that this gene is inducible by soybean seed extract and selected flavonoid chemicals. The induction of the nodY ABC and nodD operons appears to require a functional nodD gene, indicating that the nodD gene product controls its own synthesis as well as other nod genes.     

Use of a promoter-specific probe to identify two loci from the Rhizobium meliloti nodulation regulon

The nodulation regulon of Rhizobium meliloti AK631 includes several operons (nodABC, hsnABC, hsnD, efn locus) which have in common a consensus promoter sequence called the nod box. A synthetic nod box probe was used to identify two additional nod boxes, n4 and n5, which were subcloned for study. By constructing lac fusions, we show that n4 and n5 sponsor induction of downstream regions as previously shown for n1-nodABC and n2-hsnABC. Using site-directed Tn5 mutagenesis, we find that the n5 locus plays a significant role in nodulation of alfalfa and sweetclover, whereas the n4 locus is important for alfalfa, but not for sweetclover. Hybridization data suggest that the n5 locus is conserved among Rhizobium species. In contrast, the n4 locus seems to be unique to Rhizobium meliloti strains, in agreement with the host-specific phenotype of n4 locus mutants. Thus, the use of a promoter probe allows us to identify nodulation genes which may be overlooked by standard methods such as random Tn5 mutagenesis.     

Common nodABC genes in Nod locus 1 of Azorhizobium caulinodans: Nucleotide sequence and plant-inducible expression

Summary Azorhizobium caulinodans strain ORS571 induces nitrogen-fixing nodules on roots and stem-located root primordia of Sesbania rostrata. Two essential Nod loci have been previously identified in the bacterial genome, one of which (Nod locus 1) shows weak homology with the common nodC gene of Rhizobium mehloti. Here we present the nucleotide sequence of this region and show that it contains three contiguous open reading frames (ORFA, ORFB and ORFC) that are related to the nodABC genes of Rhizobium and Bradyrhizobium species. ORFC is followed by a fourth (ORF4) and probably a fifth (ORF5) open reading frame. ORF4 may be analogous to the nod[ gene of R. leguminosarum, whereas ORF5 could be similar to the rhizobial nodF genes. Coordinated expression of this set of five genes seems likely from the sequence organization. There is no typical nod promoter consensus sequence (nod box) in the region upstream of the first gene (ORFA) and there is no nodD-like gene. LacZ fusions constructed with ORFA, ORFB, ORFC, and ORF4 showed inducible -galactosidase expression in the presence of S. rostrata seedlings as well as around stem-located root primordia. Among a series of phenolic compounds tested, the flavanone naringenin was the most efficient inducer of the expression of this ORS571 nod gene cluster.     

Genomic basis of symbiovar mimosae in Rhizobium etli

Background

Symbiosis genes (nod and nif) involved in nodulation and nitrogen fixation in legumes are plasmid-borne in Rhizobium. Rhizobial symbiotic variants (symbiovars) with distinct host specificity would depend on the type of symbiosis plasmid. In Rhizobium etli or in Rhizobium phaseoli, symbiovar phaseoli strains have the capacity to form nodules in Phaseolus vulgaris while symbiovar mimosae confers a broad host range including different mimosa trees.

Results

We report on the genome of R. etli symbiovar mimosae strain Mim1 and its comparison to that from R. etli symbiovar phaseoli strain CFN42. Differences were found in plasmids especially in the symbiosis plasmid, not only in nod gene sequences but in nod gene content. Differences in Nod factors deduced from the presence of nod genes, in secretion systems or ACC-deaminase could help explain the distinct host specificity. Genes involved in P. vulgaris exudate uptake were not found in symbiovar mimosae but hup genes (involved in hydrogen uptake) were found. Plasmid pRetCFN42a was partially contained in Mim1 and a plasmid (pRetMim1c) was found only in Mim1. Chromids were well conserved.

Conclusions

The genomic differences between the two symbiovars, mimosae and phaseoli may explain different host specificity. With the genomic analysis presented, the term symbiovar is validated. Furthermore, our data support that the generalist symbiovar mimosae may be older than the specialist symbiovar phaseoli.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-575) contains supplementary material, which is available to authorized users.