Extension of host range of Rhizobium leguminosarum bv. trifolii caused by point mutations in nodD that result in alterations in regulatory function and recognition of inducer molecules

The positive activation of several nodulation genes in strain ANU843 of Rhizobium leguminosarum biovar trifolii is mediated by the product of the nodD gene and by the interaction of NodD with plant-secreted inducer and anti-inducer compounds. We have mutagenized the nodD gene of strain ANU843 with nitrosoguanidine and have found that the ability of the mutated nodD products to interact with inducer and anti-inducer compounds is affected by the amino acid sequence in at least two key regions, including a novel area between amino acids 77 and 123. Several novel classes of mutants were recognized by phenotypic and molecular analysis of the mutant nodD genes. Classes 1 and 4 mutants were able to induce nodA expression independently of the addition of inducer and anti-inducer compounds and were unable to mediate autoregulation of the nodD gene. Classes 2 and 3 mutants retained several properties of the wild-type nodD, including the ability to interact with inducer and anti-inducer compounds and the capacity to autoregulate nodD expression. In addition, class 2 mutants showed an inducer-independent ability to mediate nodA expression to 10-fold higher levels over control strains. The class 3 mutant showed reactivity to compounds that had little or no inducing ability with the wild-type nodD. An alteration in NodD function was demonstrated with classes 2 and 3 mutants, which showed greatly enhanced ability to complement a Tn5-induced mutation in the nodD1 gene of strain NGR234 and to restore nodulation ability on the tropical legume siratro. Mutants of nodD possessing inducer-independent ability to activate nod gene expression (classes 1, 2, and 4) were capable of extending the host range of R. l. bv. trifolii to the nonlegume Parasponia. DNA sequence analysis showed that single base changes were responsible for the altered phenotypic properties of five of six mutants examined. Four of the six mutations affected amino acid residues in a putative receiver domain in the N-terminal end of the nodD protein.     

Nucleotide sequence of Rhizobium meliloti nodulation genes

A Rhizobium meliloti DNA region, determining nodulation functions common in different Rhizobium species, has been delimited by directed Tn5 mutagenesis and its nucleotide sequence has been determined. The sequence data indicates three large open reading frames with the same polarity coding for three proteins of 196, 217 and 402 (or 426) amino acid residues, respectively. We suggest the existence of three nod genes on this region, which were designated as nodA, B and C, respectively. Comparison of the R. meliloti nodA, B, C nucleotide and amino acid sequences with those from R. leguminosarum, as reported in the accompanying paper, shows 69-72% homology, clearly demonstrating the high degree of conservation of common nod genes in these Rhizobium species.     

Identification and cloning of the bacterial nodulation specificity gene in the Sinorhizobium meliloti--Medicago laciniata symbiosis

Medicago laciniata (cut-leaf medic) is an annual medic that is highly nodulation specific, nodulating only with a restricted range of Sinorhizobium meliloti. e.g., strain 102L4, but not with most strains that nodulate Medicago sativa (alfalfa), e.g., strains RCR2011 and Rm41. Our aim was to identify and clone the S. meliloti 102L4 gene implicated in the specific nodulation of M. laciniata and to characterize the adjacent nodulation (nod) region. An 11-kb EcoRI DNA fragment from S. meliloti 102L4 was shown to complement strain RCR2011 for nodulation of M. laciniata. Nucleotide sequencing revealed that this fragment contained nodABCIJ genes whose overall arrangement was similar to those found in strains RCR2011 and Rm41, which do not nodulate M. laciniata. Data for Tn5 mutagenesis of the nodABCIJ region of strain 102L4 suggested that the nodC gene was involved in the specific nodulation of M. laciniata. Tn5 insertions in the nodIJ genes gave mutants with nodulation delay phenotypes on both M. laciniata and M. sativa. Only subclones of the 11-kb DNA fragment containing a functional nodC gene from strain 102L4 were able to complement strain RCR2011 for nodulation of M. laciniata. The practical implications of these findings are discussed in the context of the development of a specific M. sativa - S. meliloti combination that excludes competition for nodulation by bacterial competitors resident in soil.     

A locus encoding host range is linked to the common nodulation genes of Bradyrhizobium japonicum.

By using cloned Rhizobium meliloti, Rhizobium leguminosarum, and Rhizobium sp. strain MPIK3030 nodulation (nod) genes as hybridization probes, homologous regions were detected in the slow-growing soybean symbiont Bradyrhizobium japonicum USDA 110. These regions were found to cluster within a 25-kilobase (kb) region. Specific nod probes from R. meliloti were used to identify nodA-, nodB-, nodC-, and nodD-like sequences clustered on two adjacent HindIII restriction fragments of 3.9 and 5.6 kb. A 785-base-pair sequence was identified between nodD and nodABC. This sequence contained an open reading frame of 420 base pairs and was oriented in the same direction as nodABC. A specific nod probe from R. leguminosarum was used to identify nodIJ-like sequences which were also contained within the 5.6-kb HindIII fragment. A nod probe from Rhizobium sp. strain MPIK3030 was used to identify hsn (host specificity)-like sequences essential for the nodulation of siratro (Macroptilium atropurpureum) on a 3.3-kb HindIII fragment downstream of nodIJ. A transposon Tn5 insertion within this region prevented the nodulation of siratro, but caused little or no delay in the nodulation of soybean (Glycine max).     

Rhizobium meliloti nodD genes mediate host-specific activation of nodABC.

To differentiate among the roles of the three nodD genes of Rhizobium meliloti 1021, we studied the activation of a nodC-lacZ fusion by each of the three nodD genes in response to root exudates from several R. meliloti host plants and in response to the flavone luteolin. We found (i) that the nodD1 and nodD2 products (NodD1 and NodD2) responded differently to root exudates from a variety of hosts, (ii) that NodD1 but not NodD2 responded to luteolin, (iii) that NodD2 functioned synergistically with NodD1 or NodD3, (iv) that NodD2 interfered with NodD1-mediated activation of nodC-lacZ in response to luteolin, and (v) that a region adjacent to and upstream of nodD2 was required for NodD2-mediated activation of nodC-lacZ. We also studied the ability of each of the three R. meliloti nodD genes to complement nodD mutations in R. trifolii and Rhizobium sp. strain NGR234. We found (i) that nodD1 complemented an R. trifolii nodD mutation but not a Rhizobium sp. strain NGR234 nodD1 mutation and (ii) that R. meliloti nodD2 or nodD3 plus R. meliloti syrM complemented the nodD mutations in both R. trifolii and Rhizobium sp. strain NGR234. Finally, we determined the nucleotide sequence of the R. meliloti nodD2 gene and found that R. meliloti NodD1 and NodD2 are highly homologous except in the C-terminal region. Our results support the hypothesis that R. meliloti utilizes the three copies of nodD to optimize the interaction with each of its legume hosts.     

Structural and functional analysis of two different nodD genes in Bradyrhizobium japonicum USDA110.

Bradyrhizobium japonicum has two closely linked homologs of the nodulation regulatory gene, nodD; these homologs are located upstream of and in divergent orientation to the nodYABCSUIJ gene cluster. We report here the nucleotide sequence and mutational analyses of both nodD copies. The predicted NodD1 and NodD2 proteins shared 62% identical amino acid residues at corresponding positions and exhibited different degrees of homology with NodD proteins of other Bradyrhizobium, Azorhizobium, and Rhizobium strains. Induction of the nodYABCSUIJ operon, as measured by expression of a translational nodC'-'lacZ fusion, required the nodD1 gene, but not nodD2. A B. japonicum mutant deleted for both nodD copies (strain delta 1267) still showed residual nodulation activity; however, nodulation of soybean was significantly delayed, and nodulation of mung bean and siratro resulted in strongly reduced nodule numbers. Fully efficient nodulation of mung bean and siratro by strain delta 1267 was restored by genetic complementation with the nodD1 gene, but not with nodD2. We conclude from these data that nodD1 is the critical gene that contributes to maximal nodulation efficiency, whereas the nodD2 gene does not play any obvious role in nodulation of the host plants tested.     

Identification of NolR, a negative transacting factor controlling the nod regulon in Rhizobium meliloti.

In Rhizobium meliloti, expression of the nodulation genes (nod and nol genes) is under both positive and negative controls. These genes are activated by the products of the three related nodD genes, in conjunction with signal molecules from the host plants. We showed that negative regulation is mediated by a repressor protein, binding to the overlapping nodD1 and nodA as well as to the nodD2 promoters. The encoding gene, termed nolR, was identified and cloned from strain 41. By subcloning, deletion and Tn5 mutagenesis, a region of 594 base-pairs was found to be necessary and sufficient for repressor production in strains of R. meliloti lacking the repressor or in Escherichia coli. Sequence analysis revealed that nolR encodes a 13,349 Da protein, which is in agreement with the molecular weight of the NolR protein, determined after purification by affinity chromatography, utilizing long synthetic DNA multimers of the 21 base-pair conserved repressor-binding sequence. Our data suggest that the native NolR binds to the operator site in dimeric form. The NolR contains a helix-turn-helix motif, which shows homology to the DNA-binding sequences of numerous prokaryotic regulatory proteins such as the repressor XylR or the activator NodD and other members of the LysR family. Comparison of the putative DNA-binding helix-turn-helix motifs of a large number of regulatory proteins pointed to a number of novel regularities in this sequence. Hybridizations with an internal nolR fragment showed that sequences homologous to the nolR gene are present in all R. meliloti isolates tested, even in those that do not produce the repressor. In another species, such as Rhizobium leguminosarum, where NodD is autoregulated, however, such sequences were not detected.     

Implication of nifA in regulation of genes located on a Rhizobium meliloti cryptic plasmid that affect nodulation efficiency.

We examined the contribution of a cryptic plasmid, pRmeGR4b, to the nodulation of Medicago sativa by strain GR4 of Rhizobium meliloti. A 905-base-pair PstI DNA fragment in pRmeGR4b was found to hybridize DNA of the R. meliloti fixA promoter region as a probe. Sequence analysis of the PstI fragment showed a 206-base-pair region displaying high homology with the DNA upstream of the RNA start points of the P1 and P2 symbiotic promoters. Putative nif promoter consensus sequences were conserved in this DNA segment. Expression of DNA downstream of the nif promoterlike sequence, monitored by beta-galactosidase activity of different lacZ fusions, was demonstrated to depend on a functional nifA gene, both in microaerobically free-living cells and in nodules. Individual transposon Tn3-HoHo1 insertions in this DNA region caused a reduced nodulation competitiveness. This new symbiotic region, occupying approximately 5 kilobases of pRmeGR4b DNA, was called nfe (nodule formation efficiency).     

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.     

Rhizobium meliloti nifN (fixF) gene is part of an operon regulated by a nifA-dependent promoter and codes for a polypeptide homologous to the nifK gene product.

An essential gene for symbiotic nitrogen fixation (fixF) is located near the common nodulation region of Rhizobium meliloti. A DNA fragment carrying fixF was characterized by hybridization with Klebsiella pneumoniae nif DNA and by nucleotide sequence analysis. The fixF gene was found to be related to K. pneumoniae nifN and was therefore renamed as the R. meliloti nifN gene. Upstream of the nifN coding region a second open reading frame was identified coding for a putative polypeptide of 110 amino acids (ORF110). By fragment-specific Tn5 mutagenesis it was shown that the nifN gene and ORF110 form an operon. The control region of this operon contains a nif promoter and also the putative nifA-binding sequence. For the deduced amino acid sequence of the nifN gene product a striking homology to the R. meliloti nifK protein was found. One cysteine residue and its adjacent amino acid sequence, which are highly conserved in the R. meliloti nifK, R. meliloti nifN, and K. pneumoniae nifN proteins, may play a role in binding the FeMo cofactor.     

Rhizobium meliloti nodulation genes: identification of nodDABC gene products, purification of nodA protein, and expression of nodA in Rhizobium meliloti.

A set of conserved, or common, bacterial nodulation (nod) loci is required for host plant infection by Rhizobium meliloti and other Rhizobium species. Four such genes, nodDABC, have been indicated in R. meliloti 1021 by genetic analysis and DNA sequencing. An essential step toward understanding the function of these genes is to characterize their protein products. We used in vitro and maxicell Escherichia coli expression systems, together with gel electrophoresis and autoradiography, to detect proteins encoded by nodDABC. We facilitated expression of genes on these DNA fragments by inserting them downstream of the Salmonella typhimurium trp promoter, both in colE1 and incP plasmid-based vectors. Use of the incP trp promoter plasmid allowed overexpression of a nodABC gene fragment in R. meliloti. We found that nodA encodes a protein of 21 kilodaltons (kDa), and nodB encodes one of 28 kDa; the nodC product appears as two polypeptide bands at 44 and 45 kDa. Expression of the divergently read nodD yields a single polypeptide of 33 kDa. Whether these represent true Rhizobium gene products must be demonstrated by correlating these proteins with genetically defined Rhizobium loci. We purified the 21-kDa putative nodA protein product by gel electrophoresis, selective precipitation, and ion-exchange chromatography and generated antiserum to the purified gene product. This permitted the immunological demonstration that the 21-kDa protein is present in wild-type cells and in nodB- or nodC-defective strains, but is absent from nodA::Tn5 mutants, which confirms that the product expressed in E. coli is identical to that produced by R. meliloti nodA. Using antisera detection, we found that the level of nodA protein is increased by exposure of R. meliloti cells to plant exudate, indicating regulation of the bacterial nod genes by the plant host.     

Physical and genetic map of a Rhizobium meliloti nodulation gene region and nucleotide sequence of nodC.

Infection of alfalfa by the soil bacterium Rhizobium meliloti proceeds by deformation of root hairs and bacterial invasion of host tissue by way of an infection thread. We studied an 8.7-kilobase (kb) segment of the R. meliloti megaplasmid, which contains genes required for infection. Site-directed Tn5 mutagenesis was used to examine this fragment for nodulation genes. A total of 81 R. meliloti strains with mapped Tn5 insertions in the 8.7-kb fragment were evaluated for nodulation phenotype on alfalfa plants; 39 of the insertions defined a 3.5-kb segment containing nodulation functions. Of these 39 mutants, 37 were completely nodulation deficient (Nod-), and 2 at the extreme nif-distal end were leaky Nod-. Complementation analysis was performed by inoculating plants with strains carrying a genomic Tn5 at one location and a plasmid-borne Tn5 at another location in the 3.5-kb nodulation segment. Mutations near the right border of the fragment behaved as two distinct complementation groups. The segment in which these mutations are located was analyzed by DNA sequencing. Several open reading frames were found in this region, but the one most likely to function is 1,206 bases long, reading from left to right (nif distal to proximal) and spanning both mutation groups. The genetic behavior of this segment may be due either to the gene product having two functional domains or to a recombinational hot spot between the apparent complementation groups.     

The product of the Rhizobium meliloti ilvC gene is required for isoleucine and valine synthesis and nodulation of alfalfa.

Tn5-induced mutants of Rhizobium meliloti that require the amino acids isoleucine and valine for growth on minimal medium were studied. In one mutant, 1028, the defect is associated with an inability to induce nodules on alfalfa. The Tn5 mutation in 1028 is located in a chromosomal 5.5-kb EcoRI fragment. Complementation analysis with cloned DNA indicated that 2.0 kb of DNA from the 5.5-kb EcoRI fragment restored the wild-type phenotype in the Ilv- Nod- mutant. This region was further characterized by DNA sequence analysis and was shown to contain a coding sequence homologous to those for Escherichia coli IlvC and Saccharomyces cerevisiae Ilv5. Genes ilvC and ilv5 code for the enzyme acetohydroxy acid isomeroreductase (isomeroreductase), the second enzyme in the parallel pathways for the biosynthesis of isoleucine and valine. Enzymatic assays confirmed that strain 1028 was a mutant defective in isomeroreductase activity. In addition, it was shown that the ilvC genes of Rhizobium meliloti and E. coli are functionally equivalent. We demonstrated that in ilvC mutant 1028 the common nodulation genes nodABC are not activated by the inducer luteolin. E. coli ilvC complemented both defective properties (Ilv- and Nod-) found in mutant 1028. These findings demonstrate that R. meliloti requires an active isomeroreductase enzyme for successful nodulation of alfalfa.     

Bradyrhizobium (Arachis) sp. strain NC92 contains two nodD genes involved in the repression of nodA and a nolA gene required for the efficient nodulation of host plants.

The common nodulation locus and closely linked nodulation genes of Bradyrhizobium (Arachis) sp. strain NC92 have been isolated on an 11.0-kb EcoRI restriction fragment. The nucleotide sequence of a 7.0-kb EcoRV-EcoRI subclone was determined and found to contain open reading frames (ORFs) homologous to the nodA, nodB, nodD1, nodD2, and nolA genes of Bradyrhizobium japonicum and Bradyrhizobium elkanii. Nodulation assays of nodD1, nodD2, or nolA deletion mutants on the host plants Macroptilium atropurpureum (siratro) and Vigna unguiculata (cowpea) indicate that nolA is required for efficient nodulation, as nolA mutants exhibit a 6-day nodulation delay and reduced nodule numbers. The nolA phenotype was complemented by providing the nolA ORF in trans, indicating that the phenotype is due to the lack of the nolA ORF. nodD1 mutants displayed a 2-day nodulation delay, whereas nodD2 strains were indistinguishable from the wild type. Translational nodA-lacZ, nodD1-lacZ, nodD2-lacZ, and nolA-lacZ fusions were created. Expression of the nodA-lacZ fusion was induced by the addition of peanut, cowpea, and siratro seed exudates and by the addition of the isoflavonoids genistein and daidzein. In a nodD1 or nodD2 background, basal expression of the nodA-lacZ fusion increased two- to threefold. The level of expression of the nodD2-lacZ and nolA-lacZ fusions was low in the wild type but increased in nodD1, nodD2, and nodD1 nodD2 backgrounds independently of the addition of the inducer genistein. nolA was required for increased expression of the nodD2-lacZ fusion. These data suggest that a common factor is involved in the regulation of nodD2 and nolA, and they are also consistent with a model of nod gene expression in Bradyrhizobium (Arachis) sp. strain NC92 in which negative regulation is mediated by the products of the nodD1 and nodD2 genes.     

Localization and symbiotic function of a region on the Rhizobium leguminosarum Sym plasmid pRL1JI responsible for a secreted, flavonoid-inducible 50-kilodalton protein.

A previously described (R. A. de Maagd, C. A. Wijffelman, E. Pees, and B. J. J. Lugtenberg, J. Bacteriol. 170:4424-4427, 1988) Sym plasmid-dependent, naringenin-inducible 50-kilodalton protein of Rhizobium leguminosarum biovar viciae is further characterized in this paper. The protein was overproduced by constructing a strain containing multiple copies of the R. meliloti nodD gene, which facilitated its purification. An antiserum was used to screen Tn5 insertion mutants located in the pRL1JI region found to be responsible for the production of the 50-kilodalton protein. These inserts define a new nod locus left of the nod genes identified previously. Mutations in this region affect the nodulation ability in a way which is dependent on the bacterial background as well as on the host plant. The mutants nodulate normally in a strain RBL1532 (R. leguminosarum biovar viciae strain 248, cured of its Sym plasmid) background on all three tested host plant species. In contrast, in a strain RBL5045 (R. leguminosarum biovar trifolii strain RCR5, cured of its Sym plasmid) background, nodulation on Vicia sativa is severely impaired, whereas nodulation on Vicia hirsuta and Trifolium subterraneum is apparently unaltered.