Genetic diversity and phylogeny of indigenous rhizobia from cowpea [<Emphasis Type="Italic">Vigna unguiculata</Emphasis> (L.) Walp.]

16S rRNA RFLP, 16S rRNA sequencing, 16S-23S rRNA Intergenetic Spacer (IGS) RFLP and G-C rich random amplified polymorphic DNA (RAPD) assays were conducted to genetically characterise indigenous cowpea [Vigna unguiculata (L.) Walp.] rhizobia from different geographic regions of China. Isolated cowpea rhizobia comprised six 16S rRNA genospecies. Genotype I was composed of 14 isolated strains and the reference strains of B. japonicum and B. liaoningense. This group was divided into two sub-groups respectively related to B. japonicum and B. liaoningense by 16S rRNA sequencing, IGS restriction fragment length polymorphism and RAPD assays. Genotype II composed of 27 isolates from a variety of geographic regions. Four different assays confirmed this group was genetically distinct from B. japonicum and B. liaoningense and probably represent an uncharacterised species. Strains isolated from Hongan, Central China and B. elkanii were grouped to genotype III. Strain DdE4 was solely clustered into genotype IV and related to Rhizobium leguminosarum. Genotypes V and VI consisted of six fast-growing isolates and clustered with reference strain of Sinorhizobium fredii. Comparing with the miscellaneous slow-growing isolates, fast-growing isolates mainly isolated from cowpea cultivar Egang I exhibited strict microbe–host specificity except SjzZ4. Nucleotide sequences reported were deposited in the GenBank with the accession numbers DQ786795–DQ786804.     

Diversity,phylogeny and host specificity of soybean and peanut bradyrhizobia

A study on the diversity, phylogeny, and host specificity of soybean (Glycine max L.) and peanut (Arachis hypogaea L.) bradyrhizobia was conducted based on the 16S ribosomal RNA (rRNA) restriction fragment length polymorphisms (RFLPs), 16S rRNA sequencing, and 16S–23S rRNA intergenetic spacer (IGS) RFLP assays. Based on 16S rRNA RFLP assay, tested bradyrhizobia were divided into five genotypes, which could be further clustered into five groups by IGS RFLP assays. According to the 16S rRNA sequencing, strains of IGS-II, IV, and V were phylogenetically related to Bradyrhizobium liaoningense, Bradyrhizobium japonicum, and Bradyrhizobium elkanii, while strains of IGS-Ic and IGS-III related to Bradyrhizobium yuanmingense and Bradyrhizobium canariense, respectively. All isolates could crossly nodulate Phaseolus vulgaris, forming small white nodules. Strains of IGS-II originally isolated from peanut could efficiently nodulate Glycine soja, and two strains isolated from soybean could also nodulate peanut.     

Polyphasic characteristics of bradyrhizobia isolated from nodules of peanut (Arachis hypogaea) in China

Peanuts (Arachis hypogaea L.) were introduced to China about 500 years ago. However, the diversity of Rhizobial strains in China that can nodulate peanut was poorly understand. Diversity and phylogeny of 50 slow-growing strains, isolated from root nodules of peanut in different geographical regions of China, were studied using polyphasic techniques. All stains were clustered by phenotypic tests into two distinct groups: Group I: 16S rRNA RFLP genotype 3, and Group II, which divided into 16S rRNA RFLP genotypes 1 and 2. Genotype 1 shares the same genotype with USDA110, USDA122 and USDA127 of Bradyrhizobium japonicum, and genotype 2 solely consisted of extra-slow growing bradyrhizobia isolated from Hongan, China. Results of 16S rRNA sequencing revealed that peanut bradyrhizobia were phylogenetically related to B. japonicum and their sequence divergence was less than 1.1%. Based upon the size of the internally transcribed spacer (ITS) between the16S and 23S RNA genes, strains were classified into ITS-I, ITS-II and ITS-III genotypes. Strains could be further divided into sub-clusters IA, IB, IIa, IIb and IIc five sub-clusters through ITS PCR-RFLP and repetitive extragenic palindromic PCR (REP-PCR) analysis. Host specificity test revealed that all peanut bradyrhizobia tested nodulated Phaseolus vulgaris and strains of clusters IIb and IIc nodulated Glycine soja efficiently. Bradyrhizobia isolated from peanut were related, but still exhibited phylogenetical divergence with B. japonicum.     

A significant proportion of indigenous rhizobia from India associated with soybean (<Emphasis Type="Italic">Glycine max</Emphasis> L.) distinctly belong to <Emphasis Type="Italic">Bradyrhizobium</Emphasis> and <Emphasis Type="Italic">Ensifer</Emphasis> genera

The diversity among 269 rhizobia isolated from naturally occurring root nodules of soybean collected from two different agro-ecological regions of India, based on RFLP and sequences of the intergenic spacer (IGS) between the 16S and 23S rRNA genes, growth rate, and indole acetic acid production, revealed their significant, site-dependent genomic diversity. Among these bacteria, nine IGS genotypes were identified with two endonucleases. They were distributed into five divergent lineages by sequence analysis of each IGS representative strain, i.e., (1) comprising IGS genotypes I, II, III, and reference Bradyrhizobium yuanmingense; (2) with genotype IV and strains of unclassified bradyrhizobia genomic species; (3) including genotypes V, VI, and Bradyrhizobium liaoningense; (4) with IGS genotype VII and Bradyrhizobium elkanii strains; and (5) comprising IGS genotypes VIII, IX, and different Ensifer genus bacteria. Host-specificity test revealed that all rhizobia-nodulated soybean and cowpea and only part of them formed nodules on Arachis hypogeae and Cajanus cajan. The great diversity of soybean nodulators observed in this study emphasises that Indian soil is an important reservoir of nitrogen-fixing rhizobia.     

Characterization of local rhizobia in Thailand and distribution of malic enzymes

TWenty-six isolates were obtained from nodules of various legume plants (Glycine max, Vigna sinensis, Arachis hypogaea, Desmanthus virgatus, Acacia mangium, Centrosema pascuorum, Pterocarpus indicus, Xylia xylocarpa, and Sesbania rostrata) in Thailand. After confirming their nodulation and nitrogen-fixing abilities, they were identified by 16S rRNA gene analysis as Bradyrhizobium japonicum, Bradyrhizobium elkanii, Rhizobium leguminosarum, Rhizobium gallicum, and Rhizobium galegae. Using these local isolates, the distribution of the activities of both NAD⁺-dependent (DME: EC 1.1.1.39) and NADP⁺-dependent (TME: EC 1.1.1.40) malic enzymes was surveyed. The malic enzyme activities were present in all the isolated rhizobia and in other 17 local Bradyrhizobium strains in Thailand. In almost all the rhizobia, the DME activity predominated whereas the TME activity predominated only in the Rhizobium gallicum strains that were major symbionts of Sesbania rostrata. Southern hybridization analysis was performed to survey the distribution of the malic enzyme genes among the local rhizobia, which are similar to those of B. japonicum. DNA probes (ME1 for DME and ME2 for TME) were prepared by polymerase chain reaction (PCR) using degenerated primers from conserved regions of the protein sequences of bacterial malic enzymes. Southern blot analysis with ME1 as a probe showed a single band in about half of the isolates, especially in B. japonicum and R. leguminosarum strains, suggesting the wide distribution of such DME genes among local rhizobia. In contrast, Southern blot analysis with ME2 as a probe detected a single band only in five B. japonicum strains, suggesting that the TME genes, which are similar to those of B. japonicum, would be unique in a group of B. japonicum.     

Diversity and phylogeny of rhizobial strains isolated from Lotus uliginosus grown in Uruguayan soils

Lotus uliginosus is generally nodulated by rhizobia of the genus Bradyrhizobium when used for improvement of Uruguayan pastures. The genetic diversity and phylogenetic relationships of 111 isolates from nodules of L. uliginosus collected from four fields with or without prior inoculation history were analyzed in this study. Genetic diversity estimated by ERIC-PCR revealed 75 different genomic fingerprints, and showed a relatively greater value compared with other methods and varied by soil type. 16S ribosomal RNA gene RFLP analysis revealed three different ribogroups, A, B and C, with 71 isolates in ribogroup A, three isolates in ribogroup B and only one in ribogroup C. Phylogenetic analyses based on 16S RNA gene sequences, ITS, as well as atpD, recA and glnII gene sequences indicated that ribogroup A strains were affiliated with B. japonicum bv. genistearum strains. The three isolates in ribogroup B did not clearly associate with any Bradyrhizobium species described previously and could represent a novel species within this genus. Unlike B. japonicum strains these isolates were able to nodulate and fix nitrogen with other Lotus species as well as with Spartium, a leguminous shrub. The unique isolate in ribogroup C clustered with Mesorhizobium and appeared genetically and phenotypically related to broad host-range Mesorhizobium sp. NZP2037. Our data suggest that Uruguayan soils contain native or naturalized bradyrhizobia that are able to nodulate L. uliginosus as efficiently as the commercial strain NZP2309 but could have adaptive advantages making them more suitable for inoculant purposes.     

Co-introduction of exotic rhizobia to the rhizosphere of the invasive legume Acacia saligna,an intercontinental study

Invasive woody legumes have profound impacts in the nitrogen content and cycling of invaded ecosystems due to the ability to enter into symbiosis with nitrogen-fixing bacteria. In spite of the relevance of this symbiosis, the identity and origin of the symbionts involved in invasion are not well understood. We conducted a study to assess the diversity of symbiotic root-nodulating bacteria associated with the invasive Acacia saligna, in newly colonized areas in Portugal and Australia. BOX-PCR was used to discriminate the isolated bacteria and 16S rRNA and nifD genes were sequenced to identify the different isolates and their geographic origin. Bradyrhizobium and Mesorhizobium nodulated A. saligna in Australia while only Bradyrhizobium spp. were found in Portugal. The dominant strains nodulating A. saligna were related to Bradyrhizobium liaoningense and Bradyrhizobium canariense. Co-occurring Acacia longifolia and A. saligna in Australia harbor different rhizobial communities. As an example, we found Mesorhizobium sp. and Phyllobacterium trifolii in A. saligna and A. longifolia respectively, being this the first report for this association. The analysis of the phylogeographic marker nifD clustered most of the sequences obtained in this study with sequences of Australian origin, indicating that exotic bradyrhizobia might have been co-introduced with A. saligna in Portugal. This result highlights the risks of introducing exotic inoculants that might facilitate the invasion of new areas and alter native soil bacterial communities, hindering the recovery of ecosystems.     

Diversity of rhizobia nodulating Lotus corniculatus grown in northern and southern regions of Uruguay

Diversity of rhizobia nodulating Lotus corniculatus grown in geographical regions with different rainfall regimes in northern and southern Uruguay, was estimated using 168 root nodule isolates. ERIC-PCR analysis revealed no correlation between observed fingerprints and the geographical origin of isolates. Despite the commercial strain U510 has been used for decades to inoculate L. corniculatus, none of the isolates corresponded to this strain. Phylogenetic analyses using 16S rRNA and atpD genes, and ITS sequences clustered all the isolates within genus Mesorhizobium. A great majority of the isolates likely belong to the species M. huakuii, as does the commercial strain U510. The remaining isolates were closely related to either M. septentrionale or M. caraganae. Although no M. loti-like bacteria were identified, all isolates carried symbiotic genes closely related to M. loti and other narrow host range Lotus rhizobia. A significant portion of the Uruguayan isolates were as efficient as the reference strain U510 in symbiosis with L. corniculatus. A few of the isolates were also capable of nitrogen fixation in symbiosis with L. uliginosus, albeit with lower efficiency than reference strains. Our results indicate that rhizobia nodulating L. corniculatus in Uruguay are genetically and phenotypically diverse, and that the commercial strain U510 is probably not adapted to survive the Uruguayan edaphoclimatic conditions.     

Distribution and genetic diversity of rhizobia nodulating natural populations of Medicago truncatula in tunisian soils

A collection of 299 isolates of rhizobia nodulating Medicago truncatula was isolated from 10 Tunisian soils and was characterized by restriction fragment length polymorphism analysis of polymerase chain reaction (PCR/RFLP) of 16S rRNA gene. Results showed that 227 and 72 isolates were assigned, respectively, to Sinorhizobium meliloti and Sinorhizobium medicae. In 9 out of 10 soils S. meliloti was detected, whereas S. medicae was recovered from only 5 out of 10 soils. The cross-nodulation of three populations of M. truncatula grown on Bulla Regia soil, which contained naturally the two Sinorhizobium species, showed that M. truncatula population collected from Amra site was selective to S. meliloti at least in soil conditions. Forty-eight isolates of each Sinorhizobium species trapped by M. truncatula populations collected from Bulla Regia, Soliman and Rhayet sites on Bulla Regia soil were characterized by repetitive extragenic palindromic-PCR (REP-PCR) and showed a clear distinction between the two Sinorhizobium species and a higher diversity for S. meliloti.     

Genetic diversity of indigenous common bean (Phaseolus vulgaris) rhizobia in two Brazilian ecosystems

Although rhizobia for common bean (Phaseolus vulgaris L.) are established in most Brazilian soils, understanding of their genetic diversity is very poor. This study characterized bean strains from two contrasting ecosystems in Brazil, the Northeast Region, with a semi-arid climate and neutral soils and the South Region, with a humid subtropical climate and acid soils. Seedlings of the cultivars Negro Argel and Aporé were used to trap 243 rhizobial isolates from 12 out of 14 sites. An analysis of ERIC-PCR products revealed enormous variability, with 81% of the isolates representing unique strains considering a level of 70% of similarity. In general, there was no effect of either the bean cultivar, or the ecosystem on rhizobial diversity. One-hundred and one strains showing genetic relatedness (ERIC-PCR) less than 70% were further analyzed using restriction fragment length polymorphism (RFLP) of the 16 S rDNA cleaved with five restriction enzymes. Twenty-five different profile combinations were obtained. Rhizobium etli was the predominant species, with 73 strains showing similar RFLP profiles, while 12 other strains differed only by the profile with one restriction enzyme. Fifty strains were submitted to sequencing of a 16 S rDNA fragment, and 34 clustered with R. etli, including strains with RFLP-PCR profiles similar to those species or differing by one restriction enzyme. However, other strains differing by one or two enzymes were genetically distant from R. etli and two strains with identical profiles showed higher similarity to Sinorhizobium fredii. Other strains showed higher similarity of bases with R. tropici, R. leguminosarum and Mesorhizobium plurifarium, but some strains were quite dissimilar and may represent new species. Great variability was also verified among the sequenced strains in relation to the ability to grow in YMA at 40 °C, in LB, to synthesize melanin in vitro, as well as in symbiotic performance, including differences in relation to the described species, e.g. many R. etli strains were able to grow in LB and in YMA at 40 °C, and not all R. tropici were able to nodulate Leucaena.     

Genotypic diversity and symbiotic effectiveness of rhizobia isolated from root nodules of Phaseolus vulgaris L. grown in Tunisian soils

 One hundred and sixty isolates of rhizobia were sampled from the root nodules of common bean (Phaseolus vulgaris L.) cultivated in Tunisian soil samples originating from three geographically distinct fields. Plasmid profiling was used as a primary method to rapidly screen the isolates, and then 38 plasmid types were recorded among the 160 isolates. A sample representing the majority of plasmid types was chosen for further characterization by restriction fragment length polymorphism (RFLP) analysis of genomic DNA using chromosomal and symbiotic gene probes, and by their ability to nodulate a potential alternative host, Leucaena leucocephala. One third of the isolates showed a high similarity to Rhizobium gallicum isolated from common bean in France, another third showed the same characteristics as the R. etli-R. leguminosarum group, while the remaining isolates could not be related to any of the five species nodulating bean. When reexamined for nodulation, some of these isolates, showing similarities to R. tropici and Agrobacterium with respect to colony morphology and growth in different media, failed to nodulate their original host. The R. gallicum-like isolates, R. etli-like isolates, and R. leguminosarum-like isolates were recovered from regions where bean is frequently grown, while in fields which had not been cultivated with beans for at least the 10 previous years, solely unrecognized taxa of ineffective isolates were recovered. We detected variations in the symbiotic regions, but certain pSym RFLP patterns for nifH were conserved between Tunisian, French, and Austrian populations of bean rhizobia. Evaluation of symbiotic effectiveness showed that R. gallicum-like isolates and R. etli-like isolates were effective, whereas some R. leguminosarum-like isolates were ineffective. Furthermore, effective isolates were also found among the unrecognized taxa. Received: 10 March 1998     

Improvement of simazine degradation by inoculation of corn and soybean plants with rhizobacteria

We isolated the strains of aerobic bacteria, that were able to use the simazine (2-chloro4,6-bis(ethylamino)-s-triazine) herbicide as a sole source of nitrogen, from the roots of corn plants and the nodules of soybean plants. Partial base sequences of 16S rRNA genes and physiological characteristics of the representative isolates revealed that they belonged to Agrobacterium radiobacter and Bradyrhizobium japonicum, respectively. Inoculation of corn plants with the isolates of A. radiobacter resulted in a faster decrease in the amount of simazine in vermiculite soil. Neither bacteria nor corn plants alone were able to promote the decrease in the amount of simazine. Soybean plants modulated by the isolates of B. japonicum were more sensitive to simazine in a hydroponic medium compared to non-nodulated soybeans, though a significant decrease in the amount of simazine in the media was observed. The results obtained in the present study indicate that the rhizosphere of corn and soybean plants containing root nodules is an appropriate habitat for simazine-degrading bacteria to degrade the herbicide.     

Inoculation with Native Bradyrhizobia Strains Improved Growth of Cowpea Plants Cultivated on a Saline Soil

Selection of osmotolerant rhizobia gained importance because of increasing soil salinity in many regions. A field experiment in the Cauto Valley was conducted to determine the effect of seed inoculation with two native strains of Bradyrhizobium sp. on biological nitrogen (N)-fixation of cowpea (Vigna unguiculata) on a salt affected soil. Inoculation with both strains resulted in higher numbers of nodules, specific N-fixation, and yields of cowpeas than the control without inoculation. The strain VIBA-1 (Bradyrhizobium liaoningense) was partly superior to VIBA-2 (Bradyrhizobium yuanmingense). This study indicates that the strains inoculated are competitive against other natural strains and able to nodulate cowpea.     

Diversity and geographical distribution of indigenous soybean-nodulating bradyrhizobia in Japan

Abstract

Genetic diversity and distribution of indigenous soybean-nodulating bradyrhizobia in Japan were investigated based on restriction fragment length polymorphism analysis of PCR product (PCR-RFLP) analysis of the 16S?23S rDNA internal transcribed spacer (ITS) region using Bradyrhizobium USDA strains as reference strains. Soil samples were collected from five field sites in Hokkaido, Fukushima, Kyoto, Miyazaki and Okinawa in Japan. A total of 300 isolates were derived from three Rj-genotype soybean cultivars, Akishirome (non-Rj), CNS (Rj ₂ Rj ₃) and Fukuyutaka (Rj ₄), and five field site combinations. The PCR products of the ITS region were digested with HaeIII, HhaI, MspI and XspI. Electrophoresed patterns were analyzed for phylogenetic relationship using Bradyrhizobium reference strains. Results revealed 22 RFLP patterns and 11 clusters. The RFLP patterns of the seven clusters were similar or identical to Bradyrhizobium japonicum USDA 6, 38, 110, 115, 123 and Bradyrhizobium elkanii USDA 76 and 94. Four minor clusters were independent from the clusters of the reference strains. The isolation ratio revealed the major clusters at each field site. These results suggested that major clusters of indigenous bradyrhizobia might be in the order Bj123, Bj38, Bj110, Bj6 and Be76 from the northern to southern regions in Japan.     

Phylogeny and nodulation signal molecule of rhizobial populations able to nodulate common beans—other than the predominant species Rhizobium etli—present in soils from the northwest of Argentina

We examined the bean rhizobia community other than the predominant species Rhizobium etli present in soils of a region that is part of the range occupied by the host in Northwest Argentina, which showed Rep and 16S rDNA RFLP polymorphism. Two populations represented by isolates T29N3L and T44N22P were found to be distinct chromosomal genotypes and closely related to species Rhizobium tropici and Agrobacterium rhizogenes. Their symbiotic genes were analyzed and found to cluster with those from R. tropici as well as with rhizobia isolated from leguminous trees. Three nodulation metabolites produced by T44N22P were detected which are tetra- and pentameric chitocompounds, N-methylated, O-carbamoylated, and N-substituted either by a C_18:0 or C_18:1 acyl chain at their non-reducing end, and all them sulphated at the reducing end. Isolates T29N3L and T44N22P exhibited broad host range but unlike T29N3L, only T44N22P was able to efficiently nodulate Medicago truncatula.     

Abundance and characterization of cowpea miscellany Rhizobium from sudanese soils

Sudan is the fourth largest exporter of groundnuts in the world, yet little is known concerning the plant-rhizobial symbiosis. A study was made on the abundance of groundnut-nodulating rhizobia in the soils of Sudan as related to soil properties and the duration since groundnuts were last planted. Also, physiological, serological and nitrogen-fixing characteristics of Sudanese rhizobia are reported. All but one of 32 sites contained more than 300 rhizobia g^?1 soil capable of forming nodules on siratro (Macroptilium atropurpureum). Several of these soils had never been planted to groundnut. A correlation matrix indicated no relationship was present between soil rhizobial populations and any of the measured soil properties, or between soil rhizobial populations and the time since groundnuts were last planted in the rotation. Individual isolates of Rhizobium from six legumes: groundnut (Arachis hypogaea), mung bean (Vigna radiata), lubia (Dolichos lablab), cowpea (Vigna unguiculata), pigeonpea (Cajanus cajan) and bambara groundnut (Voandzeia subterranea) were obtained from four locations in Sudan. All isolates were able to nodulate each of the six legumes when grown in sterile vermiculite. The isolates grew in 0.1% NaCl-amended media, but growth was variable in 2.0% amended media. Most isolates grew after exposure to moist heat for 15 min at 50°C. Optimum pH for growth was, in general, between pH 6 and 8. Agglutination reactions indicated isolates from groundnuts, as well as isolates from other legumes, belonged to several serological groupings. Some isolates formed a large number of nodules on a Sudanese groundnut cultivar, whereas other isolates formed only few nodules.     

Cloning and characterization of a NADP+-malic enzyme gene from Bradyrhizobium japonicum USDA110

Malic enzymes have been considered to play a key role in energy metabolism for nitrogenase reaction in bacteroids. To elucidate the physiological role of the malic enzymes in Bradyrhizobium japonicum bacteroids, a putative malic enzyme gene Bjtme1 was cloned by polymerase chain reaction (PCR) using degenerated primers from conserved regions of the protein sequences of bacterial malic enzymes and draft sequence data of the Bradyrhizobium japonicum USDA110 genome sequence project. To confirm the characteristics of the Bjtme1 gene, the protein encoded by this gene was over-expressed using a pET32a(+) system and it exhibited a NADP⁺-malic enzyme (EC 1.1.1.40) activity, indicating that Bjtme1 was the gene of the NADP⁺-malic enzyme. This is the first report on the cloning and characterization of the NADP⁺-malic enzyme gene from B. japonicum, and the gene structure was compared with that of NADP⁺-malic enzyme genes of other rhizobia.     

Root-nodule bacteria from indigenous legumes in the north-west of Western Australia and their interaction with exotic legumes

Bacteria were isolated from root-nodules collected from indigenous legumes at 38 separate locations in the Gascoyne and Pilbara regions of Western Australia. Authentication of cultures resulted in 31 being ascribed status as root-nodule bacteria based upon their nodulation of at least one of eight indigenous legume species. The authenticated isolates originated from eight legume genera from 19 sites. Isolates were characterised on the basis of their growth and physiology; 20 isolates were fast-growing and 11 were slow-growing (visible growth within 3 and 7 d, respectively). Fast-growers were isolated from Acacia, Isotropis, Lotus and Swainsona, whilst slow-growers were from Muelleranthus, Rhynchosia and Tephrosia. Indigofera produced one fast-growing isolate and seven slow-growing isolates. Three indigenous legumes (Swainsona formosa, Swainsona maccullochiana and Swainsona pterostylis) nodulated with fast-growing isolates and four species (Acacia saligna, Indigofera brevidens, Kennedia coccinea and Kennedia prorepens) nodulated with both fast- and slow-growing isolates. Swainsona kingii did not form nodules with any isolates. Fast-growing isolates were predominantly acid-sensitive, alkaline- and salt-tolerant. All slow-growing isolates grew well at pH 9.0 whilst more than half grew at pH 5.0, but all were salt-sensitive. All isolates were able to grow at 37 °C. The fast-growing isolates utilised disaccharides, whereas the slow-growing isolates did not. Symbiotic interactions of the isolates were assessed on three annual, one biennial and nine perennial exotic legume species that have agricultural use, or potential use, in southern Australia. Argyrolobium uniflorum, Chamaecytisus proliferus, Macroptilium atropurpureum, Ononis natrix, Phaseolus vulgaris and Sutherlandia microphylla nodulated with one or more of the authenticated isolates. Hedysarum coronarium, Medicago sativa, Ornithopus sativus, Ornithopus compressus, Trifolium burchellianum, Trifolium polymorphum and Trifolium uniflorum did not form nodules. Investigation of the 31 authenticated isolates by polymerase chain reaction with three primers resulted in the RPO1 primer distinguishing 20 separate banding patterns, while ERIC and PucFor primers distinguished 26 separate banding patterns. Sequencing the 16S rRNA gene for four fast- and two slow-growing isolates produced the following phylogenetic associations; WSM1701 and WSM1715 (isolated from Lotus cruentus and S. pterostylis, respectively) displayed 99% homology with Sinorhizobium meliloti, WSM1707 and WSM1721 (isolated from Sinorhizobium leeana and Indigofera sp., respectively) displayed 99% homology with Sinorhizobium terangae, WSM1704 (isolated from Tephrosia gardneri) shared 99% sequence homology with Bradyrhizobium elkanii, and WSM1743 (isolated from Indigofera sp.) displayed 99% homology with Bradyrhizobium japonicum.     

Symbiotic effectiveness of Bradyrhizobium japonicum in acid soils can be predicted from their sensitivity to acid soil stress factors in acidic agar media

In acid soil, low pH, reduced availability of nutrients, and toxicity of Al and Mn limit plant growth and the survival and effectiveness of rhizobia. The symbiosis between legumes and rhizobia is particularly sensitive to acid soil stress. A pot experiment evaluated whether Bradyrhizobium japonicum strain growth on acidic agar media would predict ability to colonize the rhizosphere and form effective nodules in acidic soils. Three Indonesian strains of B. japonicum with similar effectiveness at neutral pH in sand culture but with different tolerance of acid soil stress factors in agar media, and an acid-tolerant commercial strain (CB1809) of comparable effectiveness, were tested in three acid soils using the Al tolerant soybean (Glycine max cv PI 416937). At 7 days after inoculation all strains had achieved large rhizosphere populations, but by day 14 the rhizosphere population of the acid-sensitive strain had decreased, while the more acid-tolerant strains increased. The acid-tolerant strains had significantly greater nodulation and symbiotic effectiveness than plants inoculated with the acid-sensitive strain. Laboratory prescreening of B. japonicum for acid, Al and Mn tolerance in acid media successfully identified strains which were symbiotically competent in low pH soils.     

Population size,distribution, and symbiotic characteristics of indigenous Bradyrhizobium spp. that nodulate TGx soybean genotypes in Africa

Soils of many potential soybean fields in Africa are characterized by low levels of biological nitrogen fixation (BNF) activities and often cannot support high soybean yields without addition of inorganic N fertilizers or external application of soybean rhizobia. The most probable number (MPN) technique was used to determine the bradyrhizobial populations that nodulate TGx soybean genotypes (a cross between nonpromiscuous North American soybean genotypes and promiscuous Asian soybean genotypes), cowpea or North American soybean cv. Clark IV, in soils from 65 sites in 9 African countries. The symbiotic effectiveness of isolates from these soils was compared to that of Bradyrhizobium japonicum strain USDA110. The bradyrhizobial population sizes ranged from 0 to 10⁴ cells g⁻¹ soil. Bradyrhizobium sp. (TGx) populations were detected in 72% and B. japonicum (Clark) in 37% of the soil samples. Bradyrhizobium sp. (TGx) populations were generally low, and significantly less than that of the cowpea bradyrhizobial populations in 57% of the samples. Population sizes of less than 10 cells g⁻¹ soil were common as these were detected in at least 43% of the soil samples. B. japonicum (Clark) occurred in higher population densities in research sites compared to farmers’ fields. Bradyrhizobium sp. (TGx) populations were highly correlated with biotic but not abiotic factors. The frequent incidence of low Bradyrhizobium sp. (TGx) populations is unlikely to support optimum BNF enough for high soybean yields while the presence of B. japonicum (Clark) in research fields has the potential to compromise the selection pressure anticipated from the indigenous Bradyrhizobium spp. (Vigna) populations. Bradyrhizobium isolates could be placed in four symbiotic phenotype groups based on their effectiveness on a TGx soybean genotype and the North American cultivar Clark IV. Symbiotic phenotype group II isolates were as effective as B. japonicum strain USDA110 on both soybean genotypes while isolates of group IV were effective on the TGx soybean genotype but not on the Clark IV. The group IV isolates represent a unique subgroup of indigenous bradyrhizobia that can sustain high soybean yields when available in sufficient population densities.