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.     

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.     

Nitrogen fixation mutants of Medicago truncatula fail to support plant and bacterial symbiotic gene expression

The Rhizobium-legume symbiosis culminates in the exchange of nutrients in the root nodule. Bacteria within the nodule reduce molecular nitrogen for plant use and plants provide bacteria with carbon-containing compounds. Following the initial signaling events that lead to plant infection, little is known about the plant requirements for establishment and maintenance of the symbiosis. We screened 44,000 M2 plants from fast neutron-irradiated Medicago truncatula seeds and isolated eight independent mutant lines that are defective in nitrogen fixation. The eight mutants are monogenic and represent seven complementation groups. To monitor bacterial status in mutant nodules, we assayed Sinorhizobium meliloti symbiosis gene promoters (nodF, exoY, bacA, and nifH) in the defective in nitrogen fixation mutants. Additionally, we used an Affymetrix oligonucleotide microarray to monitor gene expression changes in wild-type and three mutant plants during the nodulation process. These analyses suggest the mutants can be separated into three classes: one class that supports little to no nitrogen fixation and minimal bacterial expression of nifH; another class that supports no nitrogen fixation and minimal bacterial expression of nodF, bacA, and nifH; and a final class that supports low levels of both nitrogen fixation and bacterial nifH expression.     

Genetic analysis and cellular localization of the Rhizobium host specificity-determining NodE protein.

The nucleotide sequence of the nodE gene of Rhizobium trifolii strain ANU843 was determined. Like the nodE gene of R. leguminosarum strain 248 it encodes a protein with a predicted mol. wt of 42.0 kd. The predicted NodE proteins of R.trifolii and R.leguminosarum have a homology of 78%. Using antibodies raised against the NodE protein of R.trifolii it was shown that the NodE products of R.leguminosarum and R.trifolii are localized in the cytoplasmic membrane. Furthermore, these NodE proteins are predicted to contain at least two non-polar transbilayer alpha-helices. The nodE genes of R.trifolii and R.leguminosarum were separated from the nodF genes that precede them in the respective nodFE operons. Using the resulting clones, in which NodE was produced under control of the flavonoid-inducible nodABCIJ promoter of R.leguminosarum, it was shown that the NodE product is the main factor that distinguishes the host range of nodulation of R.trifolii and R.leguminosarum. Hybrid nodE genes, which consist of a 5' part of the R.leguminosarum nodE gene and a 3' part of the R.trifolii gene, were constructed. From the properties of these hybrid genes it was concluded that a central region of 185 amino acids at the most, containing only 44 non-identical amino acids, determines the difference in the host-specific characteristics of the two NodE proteins.     

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.     

Functional nodFE genes are present in Sinorhizobium sp. strain MUS10, a symbiont of the tropical legume Sesbania rostrata

We have cloned the nodFE operon from Sinorhizobium sp. strain MUS10. MUS10 NodF shows sequence homology to acyl carrier protein and enables an S. meliloti nodF mutant to effectively nodulate alfalfa. Our results demonstrate the occurrence of nodFE in a symbiont that nodulates a legume host not belonging to the galegoid group.     

Isolation and characterization of the constitutive acyl carrier protein from Rhizobium meliloti.

Rhizobium species produce an inducible acyl carrier protein (ACP), encoded by the nodF gene, that somehow functions in an exchange of cell signals between bacteria and specific plant hosts, leading to nodulation of plant roots and symbiotic nitrogen fixation, as well as a constitutive ACP needed for the synthesis of essential cell lipids. The periplasmic cyclic glucans of Rhizobium spp. are also involved in specific rhizobium-plant interaction. These glucans are strongly similar to the periplasmic membrane-derived oligosaccharides (MDO) of Escherichia coli. E. coli ACP is an essential component of a membrane-bound transglucosylase needed for the biosynthesis of MDO, raising the possibility that either or both of the rhizobial ACPs might have a similar function. We have now isolated the constitutive ACP of R. meliloti and determined its primary structure. We have also examined its function, together with those of ACPs from E. coli, Rhodobacter sphaeroides, and spinach, in the MDO transglucosylase system and as substrate for the E. coli ACP acylase enzyme. All four ACPs act as acceptors of acyl residues, but only the E. coli ACP functions in the transglucosylase system.     

NodD binds to target DNA in isologous octamer

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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.     

Isolation of the Rhizobium leguminosarum NodF nodulation protein: NodF carries a 4''-phosphopantetheine prosthetic group.

Rhizobium species produce a protein product of the nodF gene that has a limited but recognizable homology to the well-characterized acyl carrier protein (ACP) of Escherichia coli. NodF functions together with NodE in generating a host-specific response to the plant host in the interchange of signals leading to the effective nodulation of roots (H.P. Spaink, J. Weinman, M.A. Djordjevic, C.A. Wijffelman, R.J.H. Okker, and B. J.J. Lugtenberg, EMBO J. 8:2811-2818, 1989; B. Scheres, C. van de Wiel, A. Zalensky, B. Horvath, H. Spaink, H. van Eck, F. Zwartkruis, A.M. Wolters, T. Gloudemans, A. van Kammen, and T. Bisseling, Cell 60:281-294, 1990). The nodFE region of Rhizobium leguminosarum has been cloned into a multicopy plasmid and has been shown in R. leguminosarum to code for a flavonoid-inducible protein that is effectively labeled by radioactive beta-alanine added to the growth medium. After purification, the labeled protein migrates as a single band with an apparent molecular weight of 5,000 during sodium dodecyl sulfate-polyacrylamide gel electrophoresis, more rapidly than E. coli ACP. In contrast, in native gels the protein is resolved into two bands, both identified as NodF by analysis of the amino terminus and both migrating more slowly than E. coli ACP. Pulse-chase experiments with labeled beta-alanine suggested that the slower-moving band may be the precursor of the faster band. The NodF protein carries a 4'-phosphopantetheine as a prosthetic group. A NodF fusion protein under the control of the lac promoter is expressed in E. coli and is labeled with beta-alanine, indicating that it is recognized by the ACP synthase of E. coli. The ACP phosphodiesterase of E. coli, which catalyzes the release of phosphopantetheine from E. coli ACP, does not remove phosphopantetheine from NodF.     

Identification and characterization of a nodH ortholog from the alfalfa-nodulating Or191-like rhizobia

Nodulation of Medicago sativa (alfalfa) is known to be restricted to Sinorhizobium meliloti and a few other rhizobia that include the poorly characterized isolates related to Rhizobium sp. strain Or191. Distinctive features of the symbiosis between alfalfa and S. meliloti are the marked specificity from the plant to the bacteria and the strict requirement for the presence of sulfated lipochitooligosaccharides (Nod factors [NFs]) at its reducing end. Here, we present evidence of the presence of a functional nodH-encoded NF sulfotransferase in the Or191-like rhizobia. The nodH gene, present in single copy, maps to a high molecular weight megaplasmid. As in S. meliloti, a nodF homolog was identified immediately upstream of nodH that was transcribed in the opposite direction (local synteny). This novel nodH ortholog was cloned and shown to restore both NF sulfation and the Nif+Fix+ phenotypes when introduced into an S. meliloti nodH mutant. Unexpectedly, however, nodH disruption in the Or191-like bacteria did not abolish their ability to nodulate alfalfa, resulting instead in a severely delayed nodulation. In agreement with evidence from other authors, the nodH sequence analysis strongly supports the idea that the Or191-like rhizobia most likely represent a genetic mosaic resulting from the horizontal transfer of symbiotic genes from a sinorhizobial megaplasmid to a not yet clearly identified ancestor.