Biosynthesis and degradation of nodule-specific Rhizobium loti compounds in Lotus nodules.

Two nodule-specific Rhizobium loti compounds were identified in Lotus tenuis and Lotus pedunculatus nodules induced by strain NZP2037. One, a silver nitrate-positive cation called rhizolotine, has been characterized as the riboside of a novel alpha-hydroxyimino acid containing a 1,4,5,6-tetrahydropyrimidine ring (G. J. Shaw, R. D. Wilson, G. A. Lane, L. D. Kennedy, D. B. Scott, and G. J. Gainsford, J. Chem. Soc. Chem. Commun., p. 180-181, 1986), and the other, yellow-1, stains yellow with ninhydrin. Both compounds were degraded by R. loti NZP2037 but not by strains of Rhizobium meliloti, Rhizobium trifolii, or Agrobacterium tumefaciens. Under the conditions tested neither compound was able to serve as a sole source of C or N for growth of R. loti NZP2037. Rhizolotine and yellow-1 were found in nodules from a range of different legumes inoculated with NZP2037, suggesting that the Rhizobium and not the host plant determines their synthesis. Neither compound was found in nodulelike structures of L. pedunculatus induced by transposon Tn5-induced noninfectious (Inf-) mutants of NZP2037 or in similar structures induced by a transconjugant of NZP2037 containing the symbiotic (Sym) cointegrate plasmid pPN1 of R. trifolii. Both compounds were also absent in the ineffective nodules induced by the bacterial-release-negative (Bar-) mutant, strain PN239. However, both compounds were present in nodules induced by the fixation-negative (Fix-) mutant PN235 and in Fix+ nodules formed by a plasmid-cured derivative of NZP2037. These results would suggest that infection and bacterial release from the infection thread are necessary for nodule (symbiotic) synthesis of these compounds.     

Isolation and characterization of transposon Tn5-induced symbiotic mutants of Rhizobium loti

Rhizobium loti NZP2037 and NZP2213, each cured of its single large indigenous plasmid, formed effective nodules on Lotus spp., suggesting that the symbiotic genes are carried on the chromosome of these strains. By using pSUP1011 as a vector for introducing transposon Tn5 into R. loti NZP2037, symbiotic mutants blocked in hair curling (Hac), nodule initiation (Noi), bacterial release (Bar), and nitrogen fixation (Nif/Cof) on Lotus pedunculatus were isolated. Cosmids complementing the Hac, Noi, and Bar mutants were isolated from a pLAFR1 gene library of NZP2037 DNA by in planta complementation and found to contain EcoRI fragments of identical sizes to those into which Tn5 had inserted in the mutants. The cosmids that complemented the mutants of these phenotypic classes did not share common fragments, nor did cosmids that complemented four mutants within the Noi class, suggesting that these symbiotically important regions are not tightly linked on the R. loti chromosome.     

Transfer of an indigenous plasmid of Rhizobium loti to other rhizobia and Agrobacterium tumefaciens

Rhizobium loti strains NZP2037 and NZP2213 were each found to contain a single large plasmid: pRlo2037a (240 MDal) and pRlo2213a (120 MDal), respectively. Plasmid DNA present in crude cell lysates of each strain and purified pRlo2037a DNA did not hybridize with pID1, a recombinant plasmid containing part of the nitrogen fixation (nif) region of R. meliloti, indicating that nif genes were not present on these plasmids. The transposon Tn5 was inserted into pRlo2037a and this plasmid was then transferred into R. leguminosarum, R. meliloti and Agrobacterium tumefaciens. All transconjugants failed to nodulate Lotus pedunculatus, suggesting that the ability to nodulate this legume was also not carried on pRlo2037a. Transfer of pRlo2037a to R. loti strain NZP2213 did not alter the Nod+ Fix- phenotype of this strain for L. pedunculatus. Determinants for flavolan resistance, believed to be necessary for effective nodulation of L. pedunculatus, were not carried on pRlo2037a. These data suggest that nodulation, nitrogen fixation and flavolan resistance genes are not present on the large plasmid in R. loti strain NZP2037.     

Symbiotic effectiveness of phage-resistant mutants of two strains of Lotus rhizobia

Summary Phage-resistant mutants were obtained from a fast-growing (NZP2037) and a slow-growing (CC814s) strain of Rhizobium nodulating Lotus. All the mutants were stable and did not differ from the original parent strain in their cultural characteristics. OnLotus pedunculatus the mutants of NZP2037 were as effective in N-fixation as the parent strain but most mutants of CC814s were less effective. These mutants of CC814s were also less effective than the parent strain on several other host plants.     

The requirement for exopolysaccharide precedes the requirement for flavolan-binding polysaccharide in nodulation of Leucaena leucocephala by Rhizobium loti

Rhizobium loti strain PN4115 (NZP2213 str-1) ineffectively nodulates Leucaena leucocephala, i.e., strain PN4115 induces nodulation (Nod⁺) and is able to invade these nodules (Inv⁺), but fails to fix nitrogen (Fix^–). Strain PN4115 does not synthesize a flavolan-binding polysaccharide (FBP), which is synthesized by the fully effective (Nod⁺Inv⁺Fix⁺) R. loti strain PN184 (NZP2037 str-1). The FBP may offer protection from prodelphinidin-rich flavolans synthesized by Lc. leucocephala. In this work, we show that exopolysaccharide (EPS)-negative mutants derived from strain PN4115 have a more severe ineffective phenotype (Nod⁺Inv^–Fix^–) on Lc. leucocephala than strain PN4115. This suggests that EPS from strain PN4115 is functional during invasion of Lc. leucocephala and that the requirement for EPS precedes the requirement for FBP. Received: 8 October 1996 / Accepted: 11 December 1996     

Symbiotic properties of Lotus pedunculitis root nodules induced by Rhizobium loti and Bradyrhizobium sp. (Lotus)

Vance, C. P., Reibach, P. H. and Pankhurst, C. E. 1987. Symbiotic properties of Lotus pedunculatus root nodules induced by Rhizobium loti and Bradyrhizobium sp. ( Lotus ).
Symbiotic properties of root nodules were evaluated in glasshouse-grown Lotus pedunculatus Cav. cv. Maku inoculated with either a fast-growing Rhizobium loti strain NZP2037 or a slow-growing Bradyrhizobium sp. ( Lotus ) strain CC814s. Although the nodule mass of plants inoculated with NZP2037 was twice that of plants inoculated with CC814s, the yield of NZP2037 shoots and roots was 50% that of CC814s shoots and roots. Nodules induced by Bradyrhizobium fixed substantially more N than nodules induced by R. loti. Glucose requirements [mol glucose (mol N₂ fixed)^-1] of nodules induced by CC814s and NZP2037 were 7.1 and 16.6, respectively. Nodule enzymes of carbon and nitrogen assimilation reflected the disparity of the two sym-bioses. Xylem sap of the symbiosis with the higher yield contained a higher concentration of asparagine [9.86 μmol (ml xylem sap)'] than did the lower yielding symbiosis [5.80 umol (ml xylem sap)"']. Nodule CO₂ fixation was directly linked to nodule N assimilation in both symbioses. The results indicate that the difference between the two symbioses extend to nodule N and C assimilation and whole plant N transport. The data support a role for host plant modulation of bacterial efficiency and assimilation of fixed N.     

Mutations conferring azide resistance enhance symbiotic nitrogen fixation in Rhizobium loti

Azide-resistant (AzR) mutants of Rhizobium loti strain NZP2037 were isolated. Mutations conferring azide resistance (azi) appeared at a frequency of 0.5 × 10-7. Nine AzR mutants of R. loti were characterised for their symbiotic behaviour with Lotus pedunculatus plants. In comparison to the wild type parent strain, AzR mutants exhibited either similar or higher symbiotic effectiveness. The azi mutations which enhanced nitrogen fixation as well as improving shoot dry weight of the inoculated plants also increased nodulation. Unlike several azi mutations in Escherichia coli, these azi mutations did not alter sensitivity of R. loti to phenethyl alcohol. One of the AzR mutants exhibited higher micro-aerobic, N, N, N, N-tetramethyl-p-phenylenediamine (TMPD) oxidase activity.     

Isolation and characterization of a Rhizobium loti gene required for effective nodulation of Lotus pedunculatus

A Rhizobium loti gene required for effective invasion of the host Lotus pedunculatus has been identified by transposon Tn5 mutagenesis. Cosmids that complemented a previously isolated mutation (239) at this invasion (inv) locus were identified by in planta complementation and used to construct a physical map of the gene region. The insertion site of Tn5 in PN239 was mapped to a 7.5-kb EcoRI fragment, which complemented the mutation when subcloned into pLAFR1. Further Tn5 mutagenesis of the 7.5-kb fragment was carried out in Escherichia coli using bacteriophage lambda 467, and the mutations homogenotized into R. loti NZP2037. Three additional Fix- mutations were isolated, and these were found to map adjacent to the position of the original mutation in strain PN239. All the other Tn5 insertions isolated in the 7.5-kb fragment gave a Fix+ phenotype on L. pedunculatus. Electron microscopic examination of the L. pedunculatus nodules induced by the isolated Fix- mutants showed that bacteria were either blocked in release from the infection threads or were unable to undergo normal bacteroid development. The inv locus as defined by the Tn5 insertions was sequenced, and a single open-reading frame (ORF) of 576 bp, corresponding to a polypeptide of 21.3 kDa, was identified. The position and orientation of this ORF were consistent with those of the isolated Tn5 Fix- insertions.     

Effect of plant nutrient supply on nodule effectiveness and rhizobium strain competition for nodulation ofLotus pedunculatus

Summary The effect of nutrient supply on nodule formation and competition between Rhizobium strains for nodulation ofLotus pedunculatus was studied. Limiting plant growth by decreasing the supply of nutrients in an otherwise nitrogen-free medium, increased the size but decreased the number and the nitrogenase activity of nodules formed by a fast-growing strain of Lotus Rhizobium (NZP2037). In contrast decreasing nutrient supply caused only a small decline in the size, number and nitrogenase activity of nodules formed by a slow-growing strain (CC814s). Providing small quantities of NH₄NO₃ (50 to 250 g N) to plants grown with a normal supply of other nutrients stimulated nodule development by both Rhizobium strains and increased the nitrogenase activity of the NZP2037 nodules. Differences in the level of effectiveness (nitrogen-fixing ability) of nodules formed by different Rhizobium strains on plants grown with a normal supply of nutrients were less apparent when the plants were grown with decreased nutrient supply or when the plants were supplied with low levels of inorganic N.Inter-strain competition for nodulation ofL. pedunculatus between the highly effective slow-growing strain CC814s and 7 other fast- and slow-growing strains, showed CC814s to form 42 to 100% of the nodules in all associations. The greater nodulating competitiveness of strain CC814s prevailed despite changes in the nutrient supply to the host plant. A tendency was observed for partially effective Lotus Rhizobium strains to become more competitive in nodule formation when plant growth was supplemented with low levels of inorganic nitrogen.     

Grafting between model legumes demonstrates roles for roots and shoots in determining nodule type and host/rhizobia specificity

Previous grafting experiments have demonstrated that legume shoots play a critical role in symbiotic development of nitrogen-fixing root nodules by regulating nodule number. Here, reciprocal grafting experiments between the model legumes Lotus japonicus and Medicago truncatula were carried out to investigate the role of the shoot in the host-specificity of legume-rhizobia symbiosis and nodule type. Lotus japonicus is nodulated by Mesorhizobium loti and makes determinate nodules, whereas M. truncatula is nodulated by Sinorhizobium meliloti and makes indeterminate nodules. When inoculated with M. loti, L. japonicus roots grafted on M. truncatula shoots produced determinate nodules identical in appearance to those produced on L. japonicus self-grafted roots. Moreover, the hypernodulation phenotype of L. japonicus har1-1 roots grafted on wild-type M. truncatula shoots was restored to wild type when nodulated with M. loti. Thus, L. japonicus shoots appeared to be interchangeable with M. truncatula shoots in the L. japonicus root/M. loti symbiosis. However, M. truncatula roots grafted on L. japonicus shoots failed to induce nodules after inoculation with S. meliloti or a mixture of S. meliloti and M. loti. Instead, only early responses to S. meliloti such as root hair tip swelling and deformation, plus induction of the early nodulation reporter gene MtENOD11:GUS were observed. The results indicate that the L. japonicus shoot does not support normal symbiosis between the M. truncatula root and its microsymbiont S. meliloti, suggesting that an unidentified shoot-derived factor may be required for symbiotic progression in indeterminate nodules.     

Exopolysaccharide-deficient mutants of Astragali rhizobia are symbiotically effective on Astragalus sinicus, an indeterminate nodulating host

Five exopolysaccharide-deficient mutants were isolated after rhizobial strain 107 was subjected to transposon Tn5 mutagenesis. The amount of EPS produced by the mutants was dramatically decreased to between 3% and 6% of wild-type level. All mutants carried a singel copy of Tn5. Two mutants (NA3 and NA10) were complemented by the R. meliloti exoA gene and the functionally equivalent exoD gene of Rhizobium sp. strain NGR234. Two other mutants (NA7 and NA8) were complemented by the R. meliloti exoB gene and the functionally equivalent NGR234 exoC gene. The remaining mutant (NA11) was not complemented by any exo genes of R. meliloti or Rhizobium NGR234. All mutants induced normal nitrogen-fixing nodules on Astragalus sinicus, an indeterminate nodulating host.     

Correlation between extracellular polysaccharide composition and nodulating ability inRhizobium trifolii

Summary Two auxotrophic mutants ofRhizobium trifolii which are deficient in nodulating ability have been isolated. Both mutants (strain RS 164 His^– and strain RS213 Leu^–) appear to synthesize abnormal extracellular polysaccharides as compared with the wild type strain RS 55. Simultaneous recovery of nodulating ability and wild type polysaccharide composition has been found in a Leu⁺ revertant of strain RS 213.Abbreviation EPS Extracellular Polysaccharide - NIG N-Methyl-N-Nitro-N-Nitrosoguanidine     

Isolation and characterization ofSporomusa acidovorans sp. nov., a methylotrophic homoacetogenic bacterium

Exopolysaccharides (EPS) of nodulating strains of Rhizobium trifolii and Rhizobium leguminosarum added to red clover seedlings before inoculation reduced the number of nodules. The inhibition of the nodulation was correlated with the amount of EPS. The preparations of EPS from mutants defective in early stages of nodulation (Roa^- or Hac^-) did not affect the nodulation, whereas EPS from mutants deficient in late stages (post Hac^-) exerted an inhibitory effect.Inactive preparation of EPS contained less O-acetyl groups and pyruvic acid residues. Deacetylation and depyruvylation of EPS from R. trifolii Nod⁺ abolished it inhibitory effect. It was concluded that noncarbohydrate substitutions (acetate, pyruvate) are involved in EPS effect.Abbreviations CPS capsular polysaccharide - EPS exopolysaccharide - LPS lipopolysaccharide - Nod nodulation - Fix nitrogen fixation - Hac root hairs curling - Roa root adhesion     

The competitive ability and symbiotic effectiveness of doubly labelled antibiotic resistant mutants of Rhizobium trifolii

Doubly labelled mutants of Rhizobium trifolii , resistant to streptomycin and spectinomycin, were studied in respect of nodulating competitiveness and symbiotic effectiveness relative to the 'wild-type' parent strains using Trifolium repens cv. S184 as the host plant.
A combination of antibiotic resistance, differential absorption of congo-red and the fluorescent antibody technique permitted the rapid differentiation of all Rhizobium strains used, either from mixed inocula or from nodules. The doubly labelled antibiotic resistant mutants were inferior in terms of competitive ability for nodulation with an ineffective strain compared with the 'wild-type' parent strains. A rapid method for evaluating effective antibiotic resistant strains for nodulating competitiveness is suggested. All the mutants examined were also found to be less symbiotically effective than the respective 'wild-type' strains although these differences generally did not reach statistical significance. The reduced symbiotic effectiveness of the antibiotic resistant mutants was associated with an increase in magnitude of the variances for shoot dry weights, relative to that shown by the parent strains. A possible explanation for this phenomenon is presented.     

Four unnamed species of nonsymbiotic rhizobia isolated from the rhizosphere of Lotus corniculatus.

Previously, we found that genetically diverse rhizobia nodulating Lotus corniculatus at a field site devoid of naturalized rhizobia had symbiotic DNA regions identical to those of ICMP3153, the inoculant strain used at the site (J. T. Sullivan, H. N. Patrick, W. L. Lowther, D. B. Scott, and C. W. Ronson, Proc. Natl. Acad. Sci. USA 92:8985-8989, 1995). In this study, we characterized seven nonsymbiotic rhizobial isolates from the rhizosphere of L. corniculatus. These included two from plants at the field site sampled by Sullivan et al. and five from plants at a new field plot adjacent to that site. The isolates did not nodulate Lotus species or hybridize to symbiotic gene probes but did hybridize to genomic DNA probes from Rhizobium loti. Their genetic relationships with symbiotic isolates obtained from the same sites, with inoculant strain ICMP3153, and with R. loti NZP2213T were determined by three methods. Genetic distance estimates based on genomic DNA-DNA hybridization and multilocus enzyme electrophoresis were correlated but were not consistently reflected by 16S rRNA nucleotide sequence divergence. The nonsymbiotic isolates represented four genomic species that were related to R. loti; the diverse symbiotic isolates from the site belonged to one of these species. The inoculant strain ICMP3153 belonged to a fifth genomic species that was more closely related to Rhizobium huakuii. These results support the proposal that nonsymbiotic rhizobia persist in soils in the absence of legumes and acquire symbiotic genes from inoculant strains upon introduction of host legumes.     

Molecular cloning of a nodulation gene from fast- and slow-growing strains of Lotus rhizobia

Summary Cosmids containing a nodulation gene from Rhizobium loti NZP2037 were isolated using a 12.8 kb nod:: Tn5 EcoRI fragment from the Nod^- mutant strain PN233, as a hybridisation probe. A physical map of the nod region was established using the enzymes EcoRI and HindIII and the site of insertion of Tn5 in PN233 determined. Site-specific exchange of the cloned nod:: Tn5 fragment demonstrated that Tn5, and not an indigenous insertion sequence, was responsible for the nod mutation in PN233. The nod cosmids isolated complemented the Nod^- phenotype of strain PN233 but restoration of the Fix phenotype was variable suggesting a need for marker rescue to occur before nitrogen fixation occurred.Corresponding nod cosmids were isolated from a R. loti strain, NZP2213, that forms ineffective tumour-like structures on Lotus pedunculatus and from the slow-growing strain (Bradyrhizobium sp), CC814s, by in planta complementation of PN233. Hybridisation experiments suggested that the nod gene region of R. loti NZP2037 was more homologous to Bradyrhizobium strain CC814s than with a nod gene region of R. trifolii strain PN100. However, transfer of the R. trifolii nod cosmid into the R. loti Nod mutant PN233, restored the ability of this strain to initiate nodules on Lotus pedunculatus.     

Spontaneous root-nodule formation in the model legume Lotus japonicus: a novel class of mutants nodulates in the absence of rhizobia

Root-nodule development in legumes is an inducible developmental process initially triggered by perception of lipochitin-oligosaccharide signals secreted by the bacterial microsymbiont. In nature, rhizobial colonization and invasion of the legume root is therefore a prerequisite for formation of nitrogen-fixing root nodules. Here, we report isolation and characterization of chemically induced spontaneously nodulating mutants in a model legume amenable to molecular genetics. Six mutant lines of Lotus japonicus were identified in a screen for spontaneous nodule development under axenic conditions, i.e., in the absence of rhizobia. Spontaneous nodules do not contain rhizobia, bacteroids, or infection threads. Phenotypically, they resemble ineffective white nodules formed by some bacterial mutants on wild-type plants or certain plant mutants inoculated with wild-type Mesorhizobium loti. Spontaneous nodules formed on mutant lines show the ontogeny and characteristic histological features described for rhizobia-induced nodules on wild-type plants. Physiological responses to nitrate and ethylene are also maintained, as elevated levels inhibit spontaneous nodulation. Activation of the nodule developmental program in spontaneous nodules was shown for the early nodulin genes Enod2 and Nin, which are both upregulated in spontaneous nodules as well as in rhizobial nodules. Both monogenic recessive and dominant spontaneous nodule formation (snf) mutations were isolated in this mutant screen, and map positions were determined for three loci. We suggest that future molecular characterization of these mutants will identify key plant determinants involved in regulating nodulation and provide new insight into plant organ development.     

Formation of Tumor-Like Structures on Legume Roots by Rhizobium

Tumor-like structures appeared on the roots of Medicago sativa, Alysicarpus vaginalis, and Trifolium pratense inoculated with a non-nodulating strain of Rhizobium trifolii or with irradiated cultures of either of two nodulating Rhizobium strains. The structures were composed of disorganized plant tissues which, on the basis of microscopic examination, were devoid of bacterial cells. Rhizobia which could nodulate legumes of one cross-inoculation group and which were able to induce formation of such tumor-like structures on plants of a second cross-inoculation group were isolated from extracts of these root growths. The apparent tumorogenic activity of some of the rhizobia, but not their nodulating capacity, was lost when the bacteria were transferred in laboratory media.     

The diversity of rhizobia nodulating beans in Northwest Argentina as a source of more efficient inoculant strains

The common bean (Phaseolus vulgaris L.) is cultivated widely in Central and South America and particularly in the Northwest of Argentina. In order to describe the diversity of the common bean nodulating rhizobial population from the bean producing area in Northwest Argentina (NWA), a collection of about 400 isolates of common beans recovered from nodules and soil samples from NWA were characterized by using nifH-PCR, analysis of genes coding for 16S rRNA and nodC, and REP-fingerprinting, respectively. It was found that species Rhizobium etli is predominant in common bean nodules although a high degree of diversity was found within the species. Other bean nodulating genotypes recovered from soils by using Leucaena sp. as the trapping host was found to have the 16S rDNA alleles of species such as Sinorhizobium fredii, Sinorhizobium saheli, Sinorhizobium teranga, Mesorhizobium loti, and Rhizobium tropici. Some of the bean genotypes that were found to be more efficient in green house experiments were selected and assayed in two successive bean-cropping seasons in the field environment in NWA, and an increase in yields with inoculation was found. The performance of strains isolated from the region indicates potential for exploiting the diversity.