Phenotypic and genetic diversity among rhizobia isolated from three Hedysarum species: H. spinosissimum,H. coronarium and H. flexuosum

Cultural, physiological and biochemical properties of 18 strains of rhizobia isolated from root nodules of the forage legume H. spinosissimum were compared with those of rhizobia from the related species H. coronarium (15 strains) and H. flexuosum (four strains). On the basis of 43 characteristics the 37 strains of Hedysarum rhizobia could be divided into two groups by numerical analysis. The H. spinosissimum rhizobia formed the first group and the second group comprised the strains from H. coronarium and H. flexuosum. The reference Rhizobium leguminosarum bv. viceae strain 250A was clustered with the rhizobia from H. coronarium and H. flexuosum. By contrast Bradyrhizobium sp. (Arachis) reference strain 280A was not clustered with any of the strains tested, indicating that the H. spinosissimum rhizobia differ from both Rhizobium and Bradyrhizobium. Serological data also discriminate between H. spinosissimum and H. coronariumrhizobia but not between the latter and H. flexuosum strains. The strains tested exhibit a high degree of specificity for nodulation and nitrogen fixation. We also determined the16SrRNA gene sequence of H. spinosissimum rhizobia (four strains), H. coronarium (two strains) and H. flexuosum (two strains) and found that the four H. spinosissimum isolates share a 98% identity among each other in this region but they showed less than 92% identity to the H. coronarium and H. flexuosum isolates. The H. spinosissimum isolates were closely related to both Mesorhizobium loti and M. ciceri, sharing 97% identity with each species.     

Phage sensitivity and host range of Rhizobium strains isolated from root nodules of temperate legumes

Twenty-five Rhizobium strains were isolated from root nodules of Astragalus spp. (10), Hedysarum alpinum (7), Glycyrrhiza pallidiflora (3) and Ononis arvensis (5). The sensitivity of these strains to bacteriophages of Rhizobium loti, R. meliloti, R. galegae and R. leguminosarum was studied. Phages specific to R. loti strains were shown to induce the phage lysis of several Astragalus, Hedysarum and Ononis rhizobia. Ten R. loti strains tested for nodulation abilities on the plant hosts under investigation were able to develop nitrogen-fixing nodules on the Ononis arvensis roots. On the other hand, rhizobia from Ononis and Glycyrrhiza could form an effective symbiosis with Lotus corniculatus plants, so these bacteria are considered to belong to the Rhizobium loti taxon. Bacterial strains isolated from Astragalus and Hedysarum were observed to cross-nodulate their plant hosts as well as Oxytropis campestris, Glycyrrhiza uralensis and Ononis arvensis plants, whereas they could not nodulate Lotus plants. It is concluded that these Rhizobium strains comprise a cross-inoculation group related to Rhizobium loti. ei]{gnR O D}{fnDixon}     

Variation of plastid and mitochondrial DNAs in the genus Hedysarum

Summary Plastid and mitochondrial DNAs from Hedysarum species of the western Mediterranean basin, H. spinosissimum ssp eu-spinosissimum, H. spinosissimum ssp capitatum, H. carnosum, H. coronarium and H. flexuosum, were compared by restriction endonuclease fragment analysis. ctDNA fragment patterns for ssp eu-spinosissimum and ssp capitatum were indistinguishable in different enzyme digests. An identical ctDNA variation was found in Hpa II digests with two Sardinian populations of ssp capitatum. Each of the two subspecies was characterized by specific mt DNA patterns with Pst I, Bam HI, Sma I and EcoRI. No variation was detected in populations of different geographical origins for a given subspecies. H. carnosum, H. coronarium and H. flexuosum generated specific ct and mt DNA patterns. Comparison of mitochondrial fragments indicated: — a strong homology between the two subspecies, — a closer homology among the three other diploids, each being closer to the other two than to H. spinosissimum subspecies — as was also the case for the plastid genomes.     

Infection by the VA-mycorrhizal fungusGlomus caledonium inHedysarum coronarium as influenced by host plant and P content of soil

The low degree of infection ofHedysarum coronarium L. (sulla) exposed to inoculum of the VAM endophyteGlomus caledonium was investigated. Infection began after a prolonged lag phase and remained at very low levels even after three months’ growth. Neither very high rates of inoculum, nor very low P content of the soil raised the low infection level of the sulla plants. There appeared to be some differences in rate of infection among ten different ecotypes of sulla but the level of infection remained low in all cases. In all tested populations some plants remained uninfected. The low infection rate of sulla may therefore have a genetic basis. It was shown that the growth ofH. coronarium is hardly improved by phosphate fertilization. This may explain the poor response of this plant species, adapted to grow in nutrient-deficient soil, to VAM. Programmes aimed at increasing the productivity in marginal soils through the introduction of efficient VAM endophytes should take into account the fact that certain plant species growing in marginal soils may not always benefit from mycorrhizal inoculation, due to their inherently low mycorrhizal dependency.     

INTERACTIONS FOR POLLINATION BETWEEN TWO SYNCHRONOUSLY BLOOMING HEDYSARUM SPECIES (FABACEAE) IN ALASKA

In interior and arctic Alaska, Hedysarum boreale and H. alpinum (Fabaceae) occur sympatrically, bloom nearly synchronously, have similar floral morphology and color, and require pollination by insects to set seed. I studied the pollination ecology of these species at a site where they occur sympatrically near Fairbanks, Alaska, to determine if pollination interactions play a role in maintaining overlapping blooming times. Seed set in each species was apparently neither enhanced nor reduced by the presence of the other species. Seed set of H. boreale was positively related to visitation rates by female Megachile giliae, the most abundant visitor to H. boreale. This bee showed no preference between the two Hedysarum species. However, worker Bombus flavifrons, the most abundant visitor to H. alpinum, preferred to forage on H. alpinum. The exhibition of strong floral constancy by visitors to the two Hedysarum species suggests that interspecific pollination may not be strong enough to cause divergence in blooming times. I found no evidence that the presence of one Hedysarum species enhances visitation to the other species. Instead, because visitation by worker B. flavifrons to H. alpinum was reduced on sympatric plots, H. alpinum may have to tolerate overlap with H. boreale to take advantage of worker B. flavifrons activity. The results of this study suggest that the two Hedysarum species may simply bloom when their best pollinators are most active.     

Molecular methods of analysing bacterial diversity: the case of Rhizobia

The distribution of rhizobia, bacteria which nodulate the roots of leguminous plants, was surveyed for 91 species of the familyLeguminosae. A total of 117 strains of rhizobia were isolated, and 28 strains were obtained from culture collections. The sample total of 145 strains was discriminated by rapid ribosomal RNA (rRNA) sequencing. The partial sequences (157 bases from position (inEscherichia coli) 1220 to 1377 from 5 end) of 16S rRNA revealed the presence of 16 groups in these rhizobia. Further, DNA-DNA homology studies suggested that the differences of the 16 groups were enough to justify establishing at least 16 species.     

Phage specificity and lipopolysaccarides of stem- and root-nodulating bacteria (Azorhizobium caulinodans, Sinorhizobium spp., and Rhizobium spp.) of Sesbania spp

Phage susceptibility pattern and its correlation with lipopolysaccharide (LPS) and plasmid profiles may help in understanding the phenotypic and genotypic diversity among highly promiscuous group of rhizobia nodulating Sesbania spp.; 43 phages were from two stem-nodulating bacteria of S. rostrata and 16 phages were from root-nodulating bacteria of S. sesban, S. aegyptica and S. rostrata. Phage susceptibility pattern of 38 Sesbania nodulating bacteria was correlated with their LPS rather than plasmid profiles. Different species of bacteria (A. caulinodans- ORS571, SRS1-3 and Sinorhizobium saheli- SRR907, SRR912) showing distinct LPS subtypes were susceptible to different group of phages. Phages could also discriminate the strains of Si. saheli (SSR312, SAR610) possessing distinct LPS subtypes. Phages of Si. meliloti (SSR302) were strain-specific. All the strains of R. huautlense having incomplete LPS (insignificant O-chain) were phage-resistant. In in vitro assay, 100% of the phages were adsorbed to LPS of indicator bacterium or its closely related strain(s) only. These observations suggest the significance of LPS in phage specificity of Sesbania nodulating rhizobia. Highly specific phages may serve as biological marker for monitoring the susceptible bacterial strains in culture collections and environment.     

Indigenous plasmids and cultural characteristics of rhizobia nodulating chickpeas (Cicer arietinum L.)

We examined 27 strains of chickpea rhizobia from different geographic origins for indigenous plasmids, location and organization of nitrogen fixation (nif) genes, and cultural properties currently used to separate fast- and slow-growing groups of rhizobia. By using an in-well lysis and electrophoresis procedure one to three plasmids of molecular weights ranging from 35 to higher than 380 Mdal were demonstrated in each of 19 strains, whereas no plasmids were detected in the eight remaining strains. Nitrogenase structural genes homologous to Rhizobium meliloti nifHD, were not detected in plasmids of 26 out of the 27 strains tested. Hybridization of EcoRI digested total DNA from these 26 strains to the nif probe from R. meliloti indicated that the organization of nifHD genes was highly conserved in chickpea rhizobia. The only exception was strain IC-72 M which harboured a plasmid of 140 Mdal with homology to the R. meliloti nif DNA and exhibited also a unique organization of nifHD genes. The chickpea rhizobia strains showed a wide variation of growth rates (generation times ranged from 4.0 to 14.5 h) in yeast extract-mannitol medium but appear to be relatively homogeneous in terms of acid production in this medium and acid reaction in litmus milk. Although strains with fast and slow growth rates were identified, DNA/DNA hybridization experiments using a nifHD-specific probe, and the cultural properties examined so far do not support the separation of chickpea rhizobia into two distinct groups of the classical fast- and slow-growing types of rhizobia.     

Characterization of rhizobia fromLeucaena

Seventy-six rhizobia were isolated from the nodules ofLeucaena plants of various genotypes growing in a wide range of soil types and climatic regions. The isolates were fast-growing and acid-producing. In establishing a serological grouping for the isolates, the intrinsic antibiotic resistance (IAR) patterns to low concentrations of eight antibiotics was helpful for selecting the strains for immunization purposes. Eight distinct somatic serogroups ofLeucaena rhizobia were identified by using strain-specific fluorescent antibodies. The results indicated that use of serological markers is a more specific technique than IAR pattern for strain identification. Strains from some different serogroups had the same IAR patterns. The immunofluorescence cross-reactions ofLeucaena rhizobia serogroups among themselves and with other species of fast- and slow-growing rhizobia were very low. Sero-grouping is ideal for use in further ecological studies in field inoculation trials.     

Diversity of Plasmid Profiles and Conservation of Symbiotic Nitrogen Fixation Genes in Newly Isolated Rhizobium Strains Nodulating Sulla (Hedysarum coronarium L.)

Forty-five Rhizobium strains nodulating sulla (Hedysarum coronarium L.), isolated from plants grown in different sites in Menorca Island and southern Spain, were examined for plasmid content and the location and organization of nif (nitrogen fixation) and nod (nodulation) sequences. A great diversity in both number and size of the plasmids was observed in this native population of strains, which could be distributed among 19 different groups according to their plasmid profiles. No correlation was found between plasmid profile and geographical origin of the strains. In each strain a single plasmid ranging from 187 to 349 megadaltons hybridized to Rhizobium meliloti nifHD and nodD DNA, and in three strains the spontaneous loss of this plasmid resulted in the loss of the nodulation capacity. In addition to the symbiotic plasmid, 18 different cryptic plasmids were identified. A characteristic cryptic plasmid of >1,000 megadaltons was present in all strains. Total DNA hybridization experiments, with nifHD and portions of nodC and nodD genes (coding for common nodulation functions) from R. meliloti as probes, demonstrated that both the sequence and organization of nif and common nod genes were highly conserved within rhizobia nodulating sulla. Evidence for reiteration of nodD sequences and for linkage of nodC to at least one copy of nodD was obtained for all the strains examined. From these results we conclude that Rhizobium strains nodulating sulla are a homogeneous group of symbiotic bacteria that are closely related to the classical fast-growing group of rhizobia.     

Genetic diversity of fast-growing rhizobia that nodulate soybean ( Glycine max L. Merr)

The fast-growing Rhizobium sp. strain NGR234, isolated from Papua New Guinea, and 13 strains of Sinorhizobium fredii, isolated from China and Vietnam, were fingerprinted by means of RAPD, REP, ERIC and ARDRA. ERIC, REP and RAPD markers revealed a considerable genetic diversity among fast-growing rhizobia. Chinese isolates showed higher levels of diversity than those strains isolated from Vietnam. ARDRA analysis revealed three different genotypes among fast-growing rhizobia that nodulate soybean, even though all belonged to a subcluster that included Sinorhizobium saheli and Sinorhizobium meliloti. Among S. fredii rhizobia, two strains, SMH13 and HH303, might be representatives of other species of nitrogen-fixing organisms. Although restriction analysis of the nifD–nifK intergenic DNA fragment confirmed the unique nature of Rhizobium sp. strain NGR234, several similarities between Rhizobium sp. strain NGR234 and S. fredii USDA257, the ARDRA analysis and the full sequence of the 16S rDNA confirmed that NGR234 is a S. fredii strain. In addition, ARDRA analysis and the full sequence of the 16S rDNA suggested that two strains of rhizobia might be representatives of other species of rhizobia.     

Diverse<Emphasis Type="Italic"> Mesorhizobium plurifarium</Emphasis> populations native to Mexican soils

Forty-six Mesorhizobium strains associated with the leguminous plants Leucaena leucocephala and Sesbania herbacea in an uncultivated Mexican field were characterized using a polyphasic approach. The strains were identified as Mesorhizobium plurifarium based upon the close relationships with the reference strains for this species in PCR-based restriction fragment length polymorphism analyses, sequencing of 16S rRNA genes, multilocus enzyme electrophoresis, and DNA-DNA hybridization. Although the strains isolated from both plants formed the same group in multilocus enzyme electrophoresis and cross-nodulations were observed in the laboratory, different electrophoretic types were obtained from the two plants grown in natural soils, indicating the existence of a preferable association between the plants and the rhizobia. The M. plurifarium strains from Mexico and the reference strains from Africa and Brazil formed different phenotypic clusters in a numerical taxonomy. The Mexican strains did not grow at 37 °C and were sensitive to salty-alkaline conditions, while the reference strains from Africa and Brazil grew at 42 °C and were more resistant to salty-alkaline conditions. These results demonstrate that both the plants and environmental factors affected the evolution of rhizobia and that the Mexican strains had adapted to the neutral soils and the cool climate where they were isolated.     

Root nodulation studies inAeschynomene aspera

Summary Fifteen isolates of nodule bacteria were isolated from root and stem nodules ofAeschynomene aspera and they were characterized as Rhizobium by well known laboratory tests. All these isolates together with other efficient strains of known rhizobia belonging to different cross-inoculation groups were evaluated for their nodulation abilities onAeschynomene aspera, Cajanus cajan (pigeon pea),Cicer arietinum (chickpea),Pisum sativum (pea),Trifolium repens (clover),Medicago sativa (lucerne),Lens culinaris (lentil),Glycine max (soybean),Vigna sinensis (cowpea),Vigna radiata (mung bean),Vigna mungo (urd bean) andArachis hypogea (peanut). The results demonstrated that Rhizobium fromAeschynomene could form nodules only on its homologous host (Aeschynomene) but not on other legumes tested. Secondly, none of the rhizobia of other cross-inoculation groups could nodulateA. aspera.     

Presence of unique repeated insertion sequences in nodulation genes of Rhizobium ‘hedysari’

Cloning and sequencing of DNA from a symbiotic large plasmid in Rhizobium hedysari strain IS 123 required for its nodulation of the mediterranean legume crop Hedysarum coronarium (sulla) and complementation studies of nod^- mutant derivatives led to the characterization of a 30-kb region containing common and host-specific nod genes. This DNA region also contained at least six copies of a novel insertion sequence-like structure, some of which appeared to have suffered deletions. This 0.8 kb novel element carries two 17-bp flanking inverted repeats and an open reading frame showing homology with a transposase from Staphylococcus aureus. Hybridization studies revealed that several strains of Rhizobium hedysari carry this element in various copy number. The six copies in strain IS 123 appear clustered specifically within the pSym nod region.The significance of this IS element in rhizobia and its possible use as a probe for taxonomic and phylogenetic studies of Rhizobiaceae is addressed.     

Genetic diversity of indigenous tropical fast-growing rhizobia isolated from soybean nodules

This study characterized genetically 30 fast-growing rhizobial strains isolated from nodules of Asian and modern soybean genotypes that had been inoculated with soils from disparate regions of Brazil. Analyses by rep-PCR (ERIC and REP) and RAPD indicated a high level of genetic diversity among the strains. The RFLP-PCR and sequencing analysis of the 16S rRNA genes indicated that none of the strains was related to Sinorhizobium (Ensifer) fredii, whereas most were related to Rhizobium tropici (although they were unable to nodulate Phaseolus vulgaris) and to Rhizobium genomic species Q. One strain was related to Rhizobium sp. OR 191, while two others were closely related to Agrobacterium (Rhizobium) spp.; furthermore, symbiotic effectiveness with soybean was maintained in those strains. Five strains were related to Bradyrhizobium japonicum and B. elkanii, with four of them being similar to strains carried in Brazilian inoculants, therefore modifications in physiological properties, as a shorter doubling time might have resulted from adaptation to local conditions. Phospholipid fatty acid analysis (PFLA) was less precise in delineating taxonomic relationships. The strains fit into eight Nod-factor profiles that were related to rhizobial species, but not to N₂-fixation capacity or competitiveness. The data obtained highlight the diversity and promiscuity of rhizobia in the tropics, being capable of nodulating exotic legumes and might reflect ecological strategies to survive in N-poor soils; in addition, the diversity could also represent an important source of efficient and competitive rhizobial strains for the tropics. Putative new rhizobial species were detected only in undisturbed soils. Three species (R. tropici, B. japonicum and B. elkanii) were found under the more sustainable management system known as no-till, while the only species isolated from soils under conventional till was R. tropici. Those results emphasize that from the moment that agriculture was introduced into undisturbed soils rhizobial diversity has changed, being drastically reduced when a less sustainable soil management system was adopted.     

Genetic diversity of <Emphasis Type="Italic">Sinorhizobium meliloti</Emphasis> associated with alfalfa in Chilean volcanic soils and their symbiotic effectiveness under acidic conditions

A study was conducted with the aim of evaluating the genetic diversity of alfalfa rhizobia isolated from volcanic soils in southern Chile and their ability to establish an effective symbiosis with alfalfa. Rhizobial strains isolated from nodules were identified and selected based on PCR analyses and acid tolerance. Symbiotic effectiveness (nodulation and shoot dry weight) of acid-tolerant rhizobia was evaluated in glasshouse experiments under acidic conditions. The results revealed that Sinorhizobium meliloti is the dominant species in alfalfa nodules with a high genetic diversity at strain level grouped in three major clusters. There was a close relationship (r ² = 0.895, P ≤ 0.001, n = 40) between soil pH and the size of rhizobial populations. Representative isolates from major cluster groups showed wide variation in acid tolerance expressed on buffered agar plates (pH 4.5–7.0) and symbiotic effectiveness with alfalfa. One isolate (NS11) appears to be suitable as an inoculant for alfalfa according to its acid tolerance and symbiotic effectiveness at low pH (5.5). The isolation and selection of naturalized S. meliloti strains with high symbiotic effectiveness under acidic conditions is an alternative approach to improving the productivity of alfalfa and for reducing the application of synthetic fertilizers in Chile.     

Isolation of the replication DNA region from a Rhizobium plasmid and examination of its potential as a replicon for Rhizobiaceae cloning vectors

The DNA region essential for replication and stability of a native plasmid (pTM5) from Rhizobium sp. (Hedysarum) has been identified and isolated within a 5.4-kb PstI restriction fragment. The isolation of this region was accomplished by cloning endonuclease-restricted pTM5 DNA into a ColE1-type replicon and selecting the recombinant plasmids containing the pTM5 replicator (pTM5 derivative plasmids) by their ability to replicate in Rhizobium. DNA homology studies revealed that pTM5-like replicons are present in cryptic plasmids from some Rhizobium sp. (Hedysarum) strains but not in plasmids from strains of other Rhizobium species or Agrobacterium tumefaciens. The pTM5 derivative plasmids were able to replicate in Escherichia coli and A. tumefaciens and in a wide range of Rhizobium species. On the basis of stability assays in the absence of antibiotic selective pressure, the pTM5 derivative plasmids were shown to be highly stable in both free-living and symbiotic cells of Rhizobium sp. (Hedysarum). The stability of these plasmids in other species of Rhizobium and in A. tumefaciens varied depending on the host and on the plasmid. Most pTM5 derivative plasmids tested showed significantly higher symbiotic stability than RK2 derivative plasmids pRK290 and pAL618 in Rhizobium sp. (Hedysarum), R. meliloti, and R. leguminosarum bv. phaseoli. Consequently, we consider that the constructed pTM5 derivative plasmids are potentially useful as cloning vectors for Rhizobiaceae.     

Conserved plasmid/chromosome sequences in fast- and slow-growing rhizobia that nodulate the same plant

Apart from the ability to nodulate legumes, fast-and slow-growing rhizobia have few bacteriological traits in common. Given that there is only one pathway to nodulation, DNA sequences conserved in fast- and slow-growing organisms that nodulate the same host should be strongly enriched in infectivity genes. We tested this hypothesis with seven fast-growing and five slow-growing strains that produced responses varying from fully effective nodulation through various ineffective associations to non-nodulation on four different hosts (Lotus pedunculatus, Lupinus nanus, Macroptilium atropurpureum, and Vigna unguiculata). When restriction enzyme digested total DNA from 10 of the strains was separately hybridized with nick-translated plasmid DNA isolated from 4 fast-growing strains, variable but significant homologies were found with all 10 strains. Part of this homology was shown to be associated with the nifKDH genes for nitrogenase and part with putative nodulation genes carried on pC2, a cosmid clone containing a 37 kbp region of the large sym plasmid present in the fast-growing broad-host range Rhizobium sp. strain NGR234. Analysis of the extent of homology between the plasmids of 3 fastgrowing strains (NGR234, TAL 996 and UMKL 19) able to effectively nodulate Vigna unguiculata showed them to have homologous DNA fragments totalling 47 kbp. This core homology represents less than 12% of the total coding capacity of the sym plasmid present in each of these strains.Abbreviations Sym symbiotic sequences/plasmids - nod genes required for nodulation - nod putative nod genes - nif genes required for the synthesis of the enzyme nitrogenase     

Diversity of nif gene location and nitrogen fixation among root-associated Enterobacter and Klebsiella strains

Our previous work showed that strains of dinitrogen fixing enterobacter and Klebsiella were found associated with the roots of uncultivated grasses in Finland more commonly than other species of diazotrophic bacteria. In this paper we compare E. agglomerans strains to K. pneumoniae and K. terrigena strains, and show that the E. agglomerans strains fall into two biogroups. The groups differ not only in the utilization of different carbon sources and other physiological characteristics such as the production of indole, but also in the physiology and genetics of nitrogenase activity. Biotype 1 (isolated from Achillea millefolium, Calamagrostis arundinacea, and Phleum pratense) showed active nitrogenase in atmospheric oxygen, whereas biotype 2 (from Phalaris arundinacea) resembled K. pneumoniae in that it was active at reduced oxygen pressure (pO₂<-0.002) only. DNA of all strains showed positive hybridization with K. pneumoniae nifHDK genes (pSA30) but differed in the location of the genes. Biotype 1 strains of E. agglomerans carried nifHDK genes on large (105–125 Mdal) plasmids, whereas no plasmid was detected in biotype 2 or in the K. pneumoniae strains isolated from Agrostis stolonifera and Poa pratensis and K. terrigena strain isolated from Carex pallescens. The one K. terrigena strain (isolated from Ph. arundinacea) that was found to contain an indigenous plasmid (80 Mdal) did not carry nifHDK genes on this plasmid.