Relationships of Bradyrhizobium strains nodulating three Algerian Genista species.

The Mediterranean world is the cradle for the diversification of a large number of plant species, including legumes belonging to the Tribe Genisteae. Nodule bacteria from three species of Genista legumes indigenous to northwestern Africa (G. ferox, G. numidica, G. tricuspidata) were sampled across a 150km region of Algeria in order to investigate symbiotic relationships. Partial 23S rRNA sequences from 107 isolates indicated that Bradyrhizobium was the predominant symbiont genus (96% of isolates), with the remainder belonging to Rhizobium or Mesorhizobium. A multilocus sequence analysis on 46 Bradyrhizobium strains using seven housekeeping (HK) genes showed that strains were differentiated into multiple clades with affinities to seven species: B. canariense (17 isolates), B. japonicum (2), B. ottawaense (2), B. cytisi/B. rifense (9), 'B. valentinum' (5), and B. algeriense (11). Extensive discordance between the HK gene phylogeny and a tree for four loci in the symbiosis island (SI) region implied that horizontal transfer of SI loci has been common. Cases of close symbiont relationship across pairs of legumes hosts were evident, with 33% of isolates having as their closest relative a strain sampled from a different Genista species. Nevertheless, tree permutation tests also showed that there was substantial host-related phylogenetic clustering. Thus, each of the three Genista hosts utilized a measurably different array of bacterial lineages.

Root nodules of Genista germanica harbor Bradyrhizobium and Rhizobium bacteria exchanging nodC and nodZ genes.

A collection of 18 previously unstudied strains isolated from root nodules of Genista germanica (German greenweed) grown in southeast Poland was evaluated for the level of genetic diversity using the BOX-PCR technique and the phylogenetic relationship based on both core (16S rRNA, dnaK, ftsA, glnII, gyrB, recA, rpoB) and nodulation (nodC and nodZ) gene sequences. Each of the 18 G. germanica root nodule isolates displayed unique BOX-PCR patterns, indicating their high level of genomic heterogeneity. Based on the comparative 16S rDNA sequence analysis, 12 isolates were affiliated to the Bradyrhizobium genus and the other strains were most similar to Rhizobium species. Phylogenetic analysis of the core gene sequences indicated that the studied Bradyrhizobium bacteria were most closely related to Bradyrhizobium japonicum, whereas Rhizobium isolates were most closely related to Rhizobium lusitanum and R. leguminosarum. The phylogenies of nodC and nodZ for the Rhizobium strains were incongruent with each other and with the phylogenies inferred from the core gene sequences. All Rhizobium nodZ gene sequences acquired in this study were grouped with the sequences of Bradyrhizobium strains. Some of the studied Rhizobium isolates were placed in the nodC phylogenetic tree together with reference Rhizobium species, while the others were closely related to Bradyrhizobium bacteria. The results provided evidence for horizontal transfer of nodulation genes between Bradyrhizobium and Rhizobium. However, the horizontal transfer of nod genes was not sufficient for Rhizobium strains to form nodules on G. germanica roots, suggesting that symbiotic genes have to be adapted to the bacterial genome.

Molecular phylogeny of Bradyrhizobium bacteria isolated from root nodules of tribe Genisteae plants growing in southeast Poland.

The phylogeny of 16 isolates from root nodules of Genista germanica, Genista tinctoria, Cytisus ratisbonensis, and Cytisus scoparius growing in southeast Poland was estimated by comparative sequence analysis of core (16S rDNA, atpD, glnII, recA) and symbiosis-related (nodC, nodZ, nifH) genes. All the sequences analyzed placed the studied rhizobia in the genus Bradyrhizobium. Phylogenetic analysis of individual and concatenated housekeeping genes showed that the Genisteae microsymbionts form a homogeneous group with Bradyrhizobium japonicum strains. The phylogeny of nodulation and nitrogen fixation genes indicated a close relationship of the examined rhizobia with B. japonicum, Bradyrhizobium canariense, Bradyrhizobium cytisi, Bradyrhizobium rifense and Bradyrhizobium lupini strains infecting other plants of the tribe Genisteae. For the first time, the taxonomic position of G. germanica and C. ratisbonensis rhizobia, inferred from multigenic analysis, is described. The results of the phylogenetic analysis based on the protein-coding gene sequences presented in this study also indicate potential pitfalls concerning the choice of marker and reference strains, which may lead to conflicting conclusions in species delineation.

Phenotypic and genomic characteristics of rhizobia isolated from Genista tinctoria root nodules.

Forty three rhizobial strains isolated from root nodules of Genista tinctoria growing in England, Ukraine, and Poland were compared with 21 representatives of the recognized rhizobial species and two unclassified Bradyrhizobium sp. (Lupinus) strains by performing a numerical analysis of 102 phenotypic features and with the reference bradyrhizobia by simplified AFLP analysis with one restriction enzyme PstI and one selective primer PstI-A. All Genista tinctoria microsymbionts were slow-growing bradyrhizobia with generation time of 10-14 h, acid tolerant, salt sensitive, and antibiotic resistant. Cluster analysis based on the phenotypic properties of all bacteria included, grouped dyer's broom rhizobia together with Bradyrhizobium strains, and classified them into three major phena according to their geographic origin. Genista tinctoria nodule isolates were separated into three clusters with the strain composition as in a phenogrouping by AFLP patterns. The presented results, suggest the relationship of G. tincoria microsymbionts to Bradyrhizobium species and show the usefulness of AFLP analysis for differentiation and classification of the studied rhizobia.

The endemic Genista versicolor from Sierra Nevada National Park in Spain is nodulated by putative new Bradyrhizobium species and a novel symbiovar (sierranevadense).

Genista versicolor is an endemic legume from Sierra Nevada National Park which constitutes one of the UNESCO-recognized Biosphere Reserves. In the present study, a collection of strains nodulating this legume was analysed in characteristic soils of this ecosystem. Most strains nodulating G. versicolor belonged to rrs group I within the genus Bradyrhizobium and only one strain, named GV137, belonged to rrs group II from which only a single species, B. retamae, has been described in Europe to date. Strain GV137, and some strains from rrs group I, belonged to putative new species of Bradyrhizobium, although most strains from group I belonged to B. canariense, according to the ITS fragment and atpD gene analysis. This result contrasted with those obtained in Genista tinctoria in Northeast Europe whose endosymbionts were identified as B. japonicum. The analysis of the symbiotic nodC and nifH genes carried by G. versicolor-nodulating strains showed that most of them belonged to symbiovar genistearum, as did those isolated from G. tinctoria. Nevertheless, strain GV137, belonging to rrs group II, formed a divergent lineage that constituted a novel symbiovar within the genus Bradyrhizobium for which the name sierranevadense is proposed. This finding showed that the Genisteae are not restrictive legumes only nodulated by symbiovar genistearum, since Genista is a promiscuous legume nodulated by at least two symbiovars of Bradyrhizobium, as occurs in Retama species.

Genista tinctoria microsymbionts from Poland are new members of Bradyrhizobium japonicum bv. genistearum.

The phylogeny and taxonomic position of slow-growing Genista tinctoria rhizobia from Poland, Ukraine and England were estimated by comparative 16S rDNA, atpD, and dnaK sequence analyses, PCR-RFLP of 16S rDNA, DNA G+C content, and DNA-DNA hybridization. Each core gene studied placed the G. tinctoria rhizobia in the genus Bradyrhizobium cluster with unequivocal bootstrap support. G. tinctoria symbionts and bradyrhizobial strains shared 96-99% similarity in 16S rDNA sequences. Their similarity for atpD and dnaK sequences was 93-99% and 89-99%, respectively. These data clearly showed that G. tinctoria rhizobia belonged to the genus Bradyrhizobium. 16S rDNA sequence analysis was in good agreement with the results of the PCR-RFLP of the 16S rRNA gene. Although the tested strains formed separate lineages to the reference bradyrhizobia their RFLP 16S rDNA patterns were quite similar. The genomic DNA G+C content of three G. tinctoria rhizobia was in the range from 60.64 to 62.83 mol%. Data for species identification were obtained from DNA-DNA hybridization experiments. G. tinctoria microsymbionts from Poland were classified within Bradyrhizobium japonicum genomospecies based on 56-82% DNA-DNA similarity.

Phenotypic and genotypic diversity of Genista saharae microsymbionts from the infra-arid region of Tunisia.

AIMS: Genista saharae, indigenous of Sahara, is a spontaneous shrub that plays an important ecological role for the preservation and fertility of poor and eroded soils. This legume has not been examined for its root nodule bacteria. The taxonomic diversity of bacteria from root nodules of G. saharae growing in the infra-arid region of Tunisia was investigated. METHODS AND RESULTS: A total of 28 bacterial strains isolated from root nodules of G. saharae grown in Tunisian soil were characterized using a polyphasic approach including phenotypic characteristics, PCR-RFLP of 16S rDNA and 16S rRNA gene sequencing. It was found that new isolates are diverse and affiliated to Ensifer (75%), Rhizobium (10%) and Phyllobacterium (15%). The Phyllobacterium isolates lacked the capacity for nodule formation on this plant. CONCLUSIONS: Genista saharae formed nodules with diverse rhizobia in Tunisian soils. Furthermore, our results support the presence of non-nodulating commensal strains (Phyllobacterium) in legumes nodule. SIGNIFICANCE AND IMPACT OF THE STUDY: This study is the first report on the characterization of G. saharae microsymbionts in Tunisia.

Phylogeny of nodulation genes and symbiotic properties of Genista tinctoria bradyrhizobia.

Pairwise comparisons of Genista tinctoria (dyer's weed) rhizobium nodA, nodC, and nodZ gene sequences to those available in databanks revealed their highest sequence identities to nodulation loci of Bradyrhizobium sp. (Lupinus) strains and rhizobia from other genistoid legumes. On phylogenetic trees, genistoid microsymbionts were grouped together in monophyletic clusters, which suggested that their nodulation genes evolved from a common ancestor. G. tinctoria nodulators formed symbioses not only with the native host, but also with other plants of Genisteae tribe such as: Lupinus luteus, Sarothamnus scoparius, and Chamaecytisus ratisbonensis, and they were classified as the genistoid cross-inoculation group. The dyer's weed root nodules were designated as indeterminate with apical meristem consisting of infected and uninfected cells.