Mutants of Rhizobium japonicum defective in nodulation

Several mutants defective in nodulation were isolated from Rhizobium japonicum strains 3I1b110 and 61A 76. Mutants of class I do not form nodules after incubation with soybean [Glycine max (L.) Merrill] for 17 days, but will do so by 28 days. When host plants other than G. max are infected with several of these strains, there is no detectable difference in the time of nodulation or size of nodules as compared to the wild type. Two mutants of class I (i. e., SM1 and SM2) have been shown previously to be altered in the lipopolysaccharide portion of their cell wall. Mutants of class II are not slow to nodulate but form fewer nodules than the wild type on all the host plants tested. Mutants of class III are unable to form nodules. Some bacteriophage-resistant mutants, altered in cell surface structure, fall into this class. Two mutants of class III do not bind to soybean roots.     

Plasmid-mediated control of nodulation in Rhizobium trifolii

The nodulation ability was effectively eliminated from different Rhizobium trifolii strains incubated at elevated temperature (urkowski and Lorkiewicz, 1978). Non-nodulating (Nod^-) mutants were stable and no reversion of Nod^- to Nod⁺ phenotype was observed. Strains R. trifolii 24 and T12 which showed a high percentage of elimination of nodulation ability were examined in detail. Two plasmids were detected in strain 24 using neutral and alkaline sucrose gradient centrifugation of plasmid preparations. Molecular weights of the plasmids pWZ1 and pWZ2 were 460 Mdal and 190 Mdal, respectively. Rhizobium lysates labeled with ³H-thymidine and ultracentrifuged in caesium chloride — ethidium bromide gradients demonstrated a 40% reduction of the plasmid DNA content in R. trifolii 24 Nod^- mutants in comparison with the nodulating wild type strain 24. It was found further that non-nodulation of mutants 24 Nod^- was due to the absence of plasmid pWZ2. Sucrose gradient data also demonstrated that strain T12 contained two plasmids with molecular weights corresponding to those of pWZ1 and pWZ2, respectively. In Nod^- mutant clones derived from strain T12, pWZ2 plasmid was missing.Non Standard Abbreviations CCC covalently closed circular - OC open cirucular - Sarkosyl sodium N-lauroylsarcosinate     

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.     

Growth regulators,Rhizobium and nodulation in peas

The cytokinin content of roots and nodules of pea and the culture supernatants from two strains of Rhizobium leguminosarum has been examined. Roots, nodules and wild-type Rhizobium culture medium contained very little cytokinin as indicated by bioassay. Chemical ionisation gas chromatography-mass spectrometric analysis of the isopentenyladenine content of the culture medium from the Rhizobium strains confirmed that the content of the wild-type was low (approx. 1 ng dm^-3) but that it was increased by the introduction of the Agrobacterium Ti plasmid into the Rhizobium strain.Abbreviations CI chemical ionisation - GCMS gas chromatography-mass spectrometry - HPLC high performance liquid chromatography - iPAde isopentenyladenine - MIM multiple ion monitoring     

Localization of nodulation gene on the chromosome of Rhizobium meliloti

Using N-methyl-N'-nitro-N-nitrosoguanidine mutant RM54 of Rhizobium meliloti L5-30 defective in the nodulation process (Nod-) and in the biosynthesis of adenine was obtained. Nod- phenotype of this mutant was not caused by the auxotrophic mutation. The nod gene is located on the chromosome. The wild type strain of R. meliloti and Nod- mutant RM54 harbour two indigenous plasmids having a molecular weight of 90 Mdal and about 300 Mdal.     

Involvement of Rhizobium japonicum O antigen in soybean nodulation.

Non-nodulating mutant strains of Rhizobium japonicum lacked a surface antigen that was present on the wild type. This surface antigen is associated with the O antigen portion of the lipopolysaccharide. Paper chromatography of hydrolyzed lipopolysaccharide and O antigen revealed three major component differences between the non-nodulating strains and the wild type.     

Interaction of nod and exo Rhizobium meliloti in alfalfa nodulation

Among the genes of Rhizobium meliloti SU47 that affect nitrogen-fixing symbiosis with alfalfa are nod genes, in which mutations block nodule induction, and exo genes, in which mutations allow nodule formation but block rhizobial exopolysaccharide production as well as nodule invasion and nitrogen fixation. To investigate whether an exo+ bacterium can "help" (that is, reverse the symbiotic defect of) an exo mutant in trans, we have coinoculated alfalfa with pairs of rhizobia of different genotypes. Coinoculant genotypes were chosen so that the exo+ helper strain was nif while the exo "indicator" strain was nif+, and thus any fixation observed was carried out by the exo coinoculant. We find that a nod exo+ coinoculant can help an exo mutant both to invade nodules and to fix nitrogen. However, a nod+ exo+ coinoculant cannot help an exo mutant: Few exo bacteria are recovered from nodules, some bacteroids differentiate into bizarre aberrant forms, and the nodules fail to fix nitrogen. In a triple coinoculation, the effect of nod+ helper supersedes that of nod helper. Implications of these results for interaction of nod and exo gene products are discussed.     

The role of motility in the efficiency of nodulation by Rhizobium meliloti

Tn5 mutants of Rhizobium meliloti L5.30 defective in motility (Mot^-) were isolated and compared to the parent with respect to the nodulation activity. Each of the mutants was able to generate normal nodules on the alfalfa (Medicago sativa) but had slightly delayed nodule formation. Coinoculation of lucerne with wild type Mot⁺ and Mot^- cells in the wide range of ratios resulted in nodules occupied in the majority by a motile strain suggesting that motility is a factor involved in the competition for nodule formation.     

Characterization of the Rhizobium leguminosarum genes nodLMN involved in efficient host-specific nodulation

Three nodulation genes, nodL, nodM and nodN, were isolated from Rhizobium leguminosarum and their DNA sequences were determined. The three genes are in the same orientation as the previously described nodFE genes and the predicted molecular weights of their products are 20,105 (nodL), 65,795 (nodM) and 18,031 (nodN). Analysis of gene regulation using operon fusions showed that nodL, nodM and nodN are induced in response to flavanone molecules and that this induction is nodD-dependent. In addition, it was shown that the nodM and nodN genes are in one operon which is preceded by a conserved 'nod-box' sequence, whereas the nodL gene is in the same operon as the nodFE genes. DNA hybridizations using specific gene probes showed that strongly homologous genes are present in Rhizobium trifolii but not Rhizobium meliloti or Bradyrhizobium japonicum. A mutation within nodL strongly reduced nodulation of peas, Lens and Lathyrus but had little effect on nodulation of Vicia species. A slight reduction in nodulation of Vicia hirsuta was observed with strains carrying mutations in nodM or nodN.     

Structural determination of bacterial nodulation factors involved in the Rhizobium meliloti-alfalfa symbiosis

Extracellular signals produced by Rhizobium meliloti are able to induce root hair deformations and nodule organogenesis on alfalfa. The production of these signals is controlled by bacterial nod genes. To enable their isolation in significant amounts, an overproducting strain was constructed. These Nod factors were first extracted by butanol from the culture medium and further purified by reverse-phase high performance liquid chromatography, ion-exchange, and Sephadex LH-20 chromatographies. The structure of the major signal, called NodRm-1, was determined by mass spectrometry, nuclear magnetic resonance, 35S labeling, chemical analysis, and enzymatic degradation, and was shown to be a sulfated and acylated tetramer of glucosamine namely, beta-D-GlcpN(2,9-hexadecadie-noyl) - (1----4) - beta - D - Glc p Nac - (1----4) - beta - D - Glc p NAc - (1----4) - D - GlcpNAc-6-SO3H. Another Nod factor (called Ac-NodRm-1) was co-purified and identified as NodRm-1 acetylated on the C-6 of the nonreducing end sugar. NodRm-1 elicits root hair deformation specifically on alfalfa at a concentration less than 10(-10) M but has no effect on vetch (a heterologous host plant).     

Structural identification of the iipo-chitin oligosaccharide nodulation signals of Rhizobium loti

Rhizobium loti is a fast-growing Rhizobium species that has been described as a microsymbiont of plants of the genus Lotus. Nodulation studies show that Lotus plants are nodulated by R loti, but not by most other Rhizobium strains, indicating that R. loti produces specific lipo-chitin oligosaccharides (LCOs) which are necessary for the nodulation of Lotus plants. The LCOs produced by five different Rhizobium ioti strains have been purified and were shown to be N-acetylglucosamine pentasaccharides of which the non-reducing residue is N-methylated and N-acylated with c/s-vaccenic acid (C18:1) or stearic acid (C18:O) and carries a carbamoyl group. In one R. loti strain, NZP2037, an additional carbamoyl group is present on the non-reducing terminal residue. The major class of LCO molecules is substituted on the reducing terminal residue with 4-O-acetylfucose. Addition of LCOs to the roots of Lotus plants results in abundant distortion, swelling and branching of the root hairs, whereas spot inoculation leads to the formation of nodule primordia.     

Secretion of the Rhizobium leguminosarum nodulation protein NodO by haemolysin-type systems

The Rhizobium leguminosarum biovar viciae nodulation protein NodO is partially homologous to haemolysin of Escherichia coli and, like haemolysin, is secreted into the growth medium. The NodO protein can be secreted by a strain of E. coli carrying the cloned nodO gene plus the haemolysin secretion genes hlyBD, in a process that also requires the outer membrane protein encoded by tolC. The related protease secretion genes, prtDEF, from Erwinia chrysanthemi also enable E. coli to secrete NodO. The Rhizobium genes encoding the proteins required for NodO secretion are unlinked to nodO and are unlike other nod genes, since they do not require flavonoids or NodO for their expression. Although proteins similar to NodO were not found in rhizobia other than R. leguminosarum bv. viciae, several rhizobia and an Agrobacterium strain containing the cloned nodO gene were found to have the ability to secrete NodO. These observations indicate that a wide range of the Rhizobiaceae have a protein secretion mechanism analogous to that which secretes haemolysin and related toxins and proteases in the ENterobacteriaceae.     

Polysaccharide synthesis in relation to nodulation behavior of Rhizobium leguminosarum.

In this study, we characterized four Tn5 mutants derived from Rhizobium leguminosarum RBL5515 with respect to synthesis and secretion of cellulose fibrils, extracellular polysaccharides (EPS), capsular polysaccharides, and cyclic beta-(1,2)-glucans. One mutant, strain RBL5515 exo-344::Tn5, synthesizes residual amounts of EPS, the repeating unit of which lacks the terminal galactose molecule and the substituents attached to it. On basis of the polysaccharide production pattern of strain RBL5515 exo-344::Tn5, the structural features of the polysaccharides synthesized, and the results of an analysis of the enzyme activities involved, we hypothesize that this strain is affected in a galactose transferase involved in the synthesis of EPS only. All four mutants failed to nodulate plants belonging to the pea cross-inoculation group; on Vicia sativa they induced root hair deformation and rare abortive infection threads. All of the mutants appeared to be pleiotropic, since in addition to defects in the synthesis of EPS, lipopolysaccharide, and/or capsular polysaccharides significant increases in the synthesis and secretion of cyclic beta-(1,2)-glucans were observed. We concluded that it is impossible to correlate a defect in the synthesis of a particular polysaccharide with nodulation characteristics.     

Isolation of adenylate cyclase mutants from Rhizobium meliloti deficient in nodulation

Six Rhizobium meliloti mutants were isolated after Tn5-mediated mutagenesis as resistant to inhibition by a mixture of amino acids (serine, methionine, glycine and leucine). All were defective in adenylate cyclase activity and failed to form nodules in infected roots of Medicago sativa. Furthermore, like other nodulation mutants, they showed altered motility and increased secretion of exopolysaccharides; addition of cAMP to the growth medium abolished some of these phenotypic defects. The possibility that adenylate cyclase participates in the transduction of signals inducing nodulation is discussed.     

The nolL gene from Rhizobium etli determines nodulation efficiency by mediating the acetylation of the fucosyl residue in the nodulation factor

The nodulation factors (Nod factors) of Rhizobium etli and R. loti carry a 4-O-acetyl-L-fucosyl group at the reducing end. It has been claimed, based on sequence analysis, that NolL from R. loti participates in the 4-O-acetylation of the fucosyl residue of the Nod factors, as an acetyl-transferase (D. B. Scott, C. A. Young, J. M. Collins-Emerson, E. A. Terzaghi, E. S. Rockman, P. A. Lewis, and C. E. Pankhurst. Mol. Plant-Microbe Interact. 9:187-197, 1996). Further support for this hypothesis was obtained by studying the production of Nod factors in an R. etli nolL::Km mutant. Chromatographic and mass spectrometry analysis of the Nod factors produced by this strain showed that they lack the acetyl-fucosyl substituent, having a fucosyl group instead. Acetyl-fucosylation was restored upon complementation with a wild-type nolL gene. These results indicate that the nolL gene determines 4-O-acetylation of the fucosyl residue in Nod factors. Analysis of the predicted NolL polypeptide suggests a transmembranal location and that it belongs to the family of integral membrane transacylases (J. M. Slauch, A. A. Lee, M. J. Mahan, and J. J. Mekalanos. J. Bacteriol. 178:5904-5909, 1996). NolL from R. loti was also proposed to function as a transporter; our results show that NolL does not determine a differential secretion of Nod factors from the cell. We also performed plant assays that indicate that acetylation of the fucose conditions efficient nodulation by R. etli of some Phaseolus vulgaris cultivars, as well as of an alternate host (Vigna umbellata).