Serine residue 45 of nodulation protein NodF from Rhizobium leguminosarum bv. viciae is essential for its biological function.

A system for testing the role of the Rhizobium nodF gene in the production of host-specific lipochitin oligosaccharides and in nodulation was developed. We show that a mutant nodF gene, in which the codon for serine residue 45 was changed to that for threonine, still expresses NodF, which, however, is no longer functional.     

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.     

Cloning of Rhizobium leguminosarum genes for competitive nodulation blocking on peas.

One type of competitive interaction among rhizobia is that between nonnodulating and nodulating strains of Rhizobium leguminosarum on primitive pea genotypes. Pisum sativum cv. Afghanistan nodulates effectively with R. leguminosarum TOM, and this can be blocked in mixed inoculations by R. leguminosarum PF2, which does not nodulate this cultivar. We termed this PF2 phenotype Cnb+, for competitive nodulation blocking. Strain PF2 contains three large plasmids including a 250-kilobase-pair symbiotic (Sym) plasmid. Transfer of this plasmid, pSymPF2, to nonblocking rhizobia conferred the Cnb+ phenotype on recipients in mixed inoculations on cultivar Afghanistan with TOM. A library of the PF2 genome constructed in the vector pMMB33 was used to isolate two cosmid clones which hybridize to pSymPF2. These cosmids, pDD50 and pDD58, overlapped to the extent of 23 kilobase pairs and conferred a Cnb+ phenotype on recipient Cnb- rhizobia, as did pSD1, a subclone from the common region.     

Competition among Rhizobium leguminosarum bv. phaseoli strains for nodulation of common bean.

Six effective Rhizobium leguminosarum bv. phaseoli strains were examined for nodulation competitiveness on common bean (Phaseolus vulgaris L.), using all possible two-strain combinations of inoculum. Nodule occupancy was determined with strain-specific fluorescent antibodies. The strains were divided into three groups according to their overall competitive abilities on pole bean cv. Kentucky Wonder and bush bean cv. Bountiful. Strains TAL 182 and TAL 1472 were highly competitive (greater than 70% nodule occupancy); strains KIM-5, Viking 1, and CIAT 899 were moderately competitive (approximately 50% nodule occupancy); and strain CIAT 632 was poorly competitive (less than 5% nodule occupancy). The competitiveness of the six strains was similar on the two host cultivars. The proportion of competing strains in the inoculum influenced the nodule occupancy of the highly competitive and moderately competitive strains, but not that of the poorly competitive strain. Two outstanding strains (TAL 182 and TAL 1472) were identified as ideal model strains for molecular and genetic studies on nodulation competitiveness.     

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.     

Rhizobium leguminosarum genes required for expression and transfer of host specific nodulation

The contributions of various nod genes from Rhizobium leguminosarum biovar viceae to host-specific nodulation have been assessed by transferring specific genes and groups of genes to R. leguminosarum bv. trifolii and testing the levels of nodulation on Pisum sativum (peas) and Vicia hirsuta. Many of the nod genes are important in determination of host-specificity; the nodE gene plays a key (but not essential) role and the efficiency of transfer of host specific nodulation increased with additional genes such that nodFE < nodFEL < nodFELMN. In addition the nodD gene was shown to play an important role in host-specific nodulation of peas and Vicia whilst other genes in the nodABCIJ gene region also appeared to be important. In a reciprocal series of experiments involving nod genes cloned from R. leguminosarum bv. trifolii it was found that the nodD gene enabled bv. viciae to nodulate Trifolium pratense (red clover) but the nodFEL gene region did not. The bv. trifolii nodD or nodFEL genes did significantly increase nodulation of Trifolium subterraneum (sub-clover) by R. leguminosarum bv. viciae. It is concluded that host specificity determinants are encoded by several different nod genes.     

Adenine requirement for nodulation of pea by an auxotrophic mutant of Rhizobium leguminosarum

A non-nodulating auxotroph (L4-73) derived from an effective strain (L4) of Rhizobium leguminosarum has a growth requirement for adenine and thiamine. The auxotroph was able to infect the roots of the host plant Pisum sativum L. but formed root nodules (ineffective in nitrogen fixation) only when adenine and, to a lesser extent, thiamine were added to the plant substrate. Nodules formed in the presence of adenine were structurally abnormal, containing small cells in which infection threads appeared to have aborted. In the presence of thiamine the auxotroph produced a smaller number of nodules which were slightly more developed and were able to reduce trace amounts of acetylene to ethylene. The adenine effect predominated when both growth factors were added together or separately in different sequences. Adenine amendment was required during the first 6 days following inoculation to achieve the maximum number of nodules. The block in symbiosis could not be fully overcome by sequential addition or removal from the root medium of either compound or by addition of some other adeninecontaining compounds. Partial prototroph revertants requiring adenine but not thiamine induced a nodulation response similar to that of the original auxotroph in the presence of thiamine; partial prototrophs requiring thiamine only were almost fully effective. Bioassay of pea root tissue indicated the presence of significant amounts of both adenine and thiamine or related substances in the roots. The auxotroph was able to compete with the parent strain L4 in nodulation on roots of pea only in the presence of exogenous adenine.     

Speed of nodulation and competitive ability among strains of Rhizobium leguminosarum bv phaseoli

This study examines the speed of nodulation of 20 strains of Rhizobium leguminosarum bv phaseoli, and relates this trait to the competitive performance of these strains with Phaseolus vulgaris L. At 25/20°C day/night temperature, and with 10⁷ cells applied per growth pouch, there was a strong positive correlation between the speed of nodulation and the competitiveness of strains with the nod ⁺ fix^– reference strain UMR 1116. Strains UMR 1084, 1125, 1165, 1173 and 1384 combined good competitive performance with extensive nodulation in the uppermost root regions. When inoculant levels in the RTM studies were reduced to 10³ cells per pouch no correlation between the apparent competitiveness of strains and their speed in nodulation was evident, presumably because cells had to undergo multiplication before infection. Nodulation was also delayed when growth temperatures were raised to 31/26°C, but a correlation was still evident between competitive performance and nodulation in the region 0.1 to 5.0 mm below the RTM at the time of inoculation. From these results speed of nodulation can be used to estimate the competitive potential of Rhizobium strains, but only under carefully regulated conditions. The effects of inoculation level and temperature on the relationship between speed of nodulation and strain competitiveness could explain the inconsistent results obtained in earlier studies on this topic.Journal paper No. 16962, Agricultural Experiment Station, University of Minnesota, St. Paul, MN 55108, USA     

Involvement of Rhizobium leguminosarum nodulation genes in gene expression in pea root hairs

The mRNA population in pea root hairs was characterized by means of in vitro translation of total root hair RNA followed by 2-dimensional gel electrophoresis of the translation products. Root hairs contain several mRNAs not detectable in total RNA preparations from roots. Most of these root hair-specific mRNAs occur in elongating root hairs at higher levels than in mature root hairs. The expression of some genes in pea root hairs is typically affected by inoculation with Rhizobium leguminosarum. One gene, encoding RH-42, is specifically induced while the expression of another gene, encoding RH-44, is markedly enhanced. Using R. leguminosarum mutants it was shown that the nodC gene is required for the induction and enhancement of expression of the RH-42 and RH-44 genes, respectively, while the Rhizobium chromosomal gene pss1, involved in exopolysaccharide synthesis, is not essential. After induction of the nod genes with apigenin the bacteria excrete into the culture medium a factor that causes root hair deformation. This deformation factor stimulates the expression of the RH-44 gene but does not induce the expression of the gene encoding RH-42.     

Identification of a rhizosphere protein encoded by the symbiotic plasmid of Rhizobium leguminosarum.

A protein was identified which was made by wild-type strains of Rhizobium leguminosarum but not by nodulation-deficient derivatives which had deletions of their symbiotic plasmids. The protein, which had a subunit molecular weight of ca. 24,000 ( 24K ), was found to be present in large amounts within bacteria that had been reisolated from the surface of inoculated pea roots but was not detected in bacteroids isolated from nodules. The protein could also be induced during growth of R. leguminosarum on nutrient medium and was purified from the cytoplasmic fraction of broken cells. Antiserum raised against the purified protein was used to screen transposon-induced mutants of R. leguminosarum, and four independent mutants were isolated which lacked the protein. The sites of the Tn5 insertions were found to map between the nitrogenase and nodulation genes on symbiotic plasmid pRL1JI , ca. 5 kilobases from the nitrogenase genes and 13 kilobases from the nodulation genes. Genetic determinants for the 24K protein were found to be closely linked to plasmid-borne nodulation genes for all strains of R. leguminosarum tested. However, the mutants which lacked the 24K protein still formed normal nitrogen-fixing nodules on peas, and the function of the protein is unknown.     

Characterization of the anomalous infection and nodulation of subterranean clover roots by Rhizobium leguminosarum 1020

Anomalous nodulation of Trifolium subterraneum (subterranean clover) roots by Rhizobium leguminosarum 1020 was examined as a model of modified host-specificity in a Rhizobium-legume symbiosis. Consistent with previous reports, these nodules (i) appeared most often at sites of secondary root emergence, (ii) were ineffective in nitrogen fixation and (iii) were as numerous as nodules formed by an effective Rhizobium trifolii strain. R. leguminosarum 1020, grown on agar plates or in the clover root environment, did not bind the white clover lectin, trifoliin A. This strain did not attach in high numbers, and did not induce shepherd's crooks or infection threads, in subterranean clover root hairs. However, R. leguminosarum 1020 did cause branching, moderate curling and other deformations of root hairs. The bacteria probably entered the clover root through breaks in the epidermis at sites of lateral root emergence. The anomalous nodulation was inhibited by nitrate. Only trace amounts of leghaemoglobin were detected in the nodules by Western blot analysis. The nodules were of the meristematic type and initially contained well-developed infection, bacteroid and senescent zones. Infection threads were readily found in the infection zone of the nodule. However, the bacteroid-containing tissue senesced more rapidly than in the effective symbiosis between subterranean clover and R. trifolii 0403. This anomalous nodulation of subterranean clover by R. leguminosarum 1020 suggests a naturally-occurring alternative route of infection that allows Rhizobium to enlarge its host range.