Near isogenic lines of soybeans as tools to identify nodulation specificmutants of Bradyrhizobium elkanii

The dominant allele Rj4 in soybean interdicts or restricts the nodulation of plants by certain strains of bacteria, most of which are classified as Bradyrhizobium elkanii, while the recessive allele permits normal nodulation with the same strains. The near isogenic lines BARC-2 (Rj4) and BARC-3 (rj4) are calculated to be 99.95% identical in their nuclear DNA, but differ specifically in the allele present at the Rj4 locus. These lines were used to identify spontaneous mutants of the Rj4-restricted Bradyrhizobium elkanii strain USDA 61 Nal^r that had the ability to effectively nodulate plants of the Rj4 genotype. Of the eight rare nodules found on roots of soybean plants of the Rj4 genotype inoculated with the genetically marked strain USDA 61 Nal^r, four were identified as containing mutants with the ability to overcome the effects of the Rj4 allele.     

Host genetic control of symbiosis in soybean (Glycine max L.)

Genes controlling nitrogen-fixing symbioses of legumes with specialized bacteria known as rhizobia are presumably the products of many millions of years of evolution. Different adaptative solutions evolved in response to the challenge of survival in highly divergent complexes of symbionts. Whereas efficiency of nitrogen fixation appears to be controlled by quantitative inheritance, genes controlling nodulation are qualitatively inherited. Genes controlling nodulation include those for non-nodulation, those that restrict certain microsymbionts, and those conditioning hypernodulation, or supernodulation. Some genes are naturally occurring polymorphisms, while others were induced or were the result of spontaneous mutations. The geographic patterns of particular alleles indicate the role of coevolution in determining symbiont specificites and compatibilities. For example, the Rj4 allele occurs with higher frequency (over 50%) among the soybean (G. max) from Southeast Asia. DNA homology studies of strains of Bradyrhizobium that nodulate soybean indicated two groups so distinct as to warrant classification as two species. Strains producing rhizobitoxine-induced chlorosis occur only in Group II, now classified as B. elkanii. Unlike B. japonicum, B. elkanii strains are characterized by (1) the ability to nodulate the rj1 genotype, (2) the formation of nodule-like structures on peanut, (3) a relatively high degree of ex planta nitrogenase activity, (4) distinct extracellular polysaccharide composition, (5) distinct fatty acid composition, (6) distinct antibiotic resistance profiles, and (7) low DNA homology with B. japonicum. Analysis with soybean lines near isogenic for the Rj4 versus rj4 alleles indicated that the Rj4 allele excludes a high proportion of B. elkanii strains and certain strains of B. japonicum such as strain USDA62 and three serogroup 123 strains. These groups, relatively inefficient in nitrogen fixation with soybean, tend to predominate in soybean nodules from many US soils. The Rj4 allele, the most common allelic form in the wild species, has a positive value for the host plants in protecting them from nodulation by rhizobia poorly adapted for symbiosis.     

Effect of Rj genotype and cultivation temperature on the community structure of soybean-nodulating bradyrhizobia

The nodulation tendency and community structure of indigenous bradyrhizobia on Rj genotype soybean cultivars at cultivation temperatures of 33/28°C, 28/23°C, and 23/18°C for 16/8 h (day/night degrees, hours) were investigated using 780 bradyrhizobial DNA samples from an Andosol with 13 soybean cultivars of four Rj genotypes (non-Rj, Rj(2)Rj(3), Rj(4), and Rj(2)Rj(3)Rj(4)). A dendrogram was constructed based on restriction fragment length polymorphism of the PCR products (PCR-RFLP) of the 16S-23S rRNA gene internal transcribed spacer region. Eleven Bradyrhizobium U.S. Department of Agriculture strains were used as a reference. The dendrogram indicated seven clusters based on similarities among the reference strains. The occupancy rate of the Bj123 cluster decreased with increasing cultivation temperature, whereas the occupancy rates of the Bj110 cluster, Be76 cluster, and Be94 cluster increased with increasing cultivation temperature. In particular, the Rj(2)Rj(3)Rj(4) genotype soybeans were infected with a number of Bj110 clusters, regardless of the increasing cultivation temperature, compared to other Rj genotype soybean cultivars. The ratio of beta diversity to gamma diversity (H'(β)/H'(γ)), which represents differences in the bradyrhizobial communities by pairwise comparison among cultivation temperature sets within the same soybean cultivar, indicated that the bradyrhizobial communities tended to be different among cultivation temperatures. Multidimensional scaling analysis indicated that the infection of the Bj110 cluster and the Bj123 cluster by host soybean genotype and the cultivation temperature affected the bradyrhizobial communities. These results suggested that the Rj genotypes and cultivation temperatures affected the nodulation tendency and community structures of soybean-nodulating bradyrhizobia.     

Genetic allelism and linkage tests of a soybean gene,Rfg1, controlling nodulation with Rhizobium fredii strain USDA 205

A soybean gene, Rfg1, controlling nodulation with strain USDA 205, the type strain for the fast-growing species Rhizobium fredii, was tested for allelism with the Rj4 gene. The Rj4 gene conditions ineffective nodulation primarily with certain strains of the slow-growing soybean microsymbiont, Bradyrhizobium elkanii. The F2 seeds of the cross of the cultivars Peking, carrying the alleles rfg1, Rj4, i (controlling inhibition of seed coat color) and W1 (controlling flower color), and Kent, carrying the alleles Rfg1, rj4, i-i and w1, were evaluated for nodulation response with strain USDA 205 by planting surface disinfested seeds in sterilized vermiculite in growth trays and inoculating with a stationary phase broth culture of strain USDA 205 at planting. Plants were classified for nodulation response visually after four weeks growth and transplanted to the field for F3 seed production. Flower color, purple (W1) vs white (w1), was determined in the field. The allele present at the i locus was determined by classification of F3 seed coat color. The F3 seeds were planted in growth trays and inoculated with strain USDA 61 of Bradyrhizobium elkanii to determine the genotype for the Rj4 locus. The Rfg1 and Rj4 genes were determined to be located at separate loci. Chi-square analysis for linkage indicated that Rfg1 segregated independently of the Rj4, I and W1 loci.     

The Soybean Rj4 Allele Restricts Nodulation by Bradyrhizobium japonicum Serogroup 123 Strains

Of nine Bradyrhizobium japonicum serogroup 123 strains examined, 44% were found to be restricted for nodulation by cultivar Hill. Nodulation studies with soybean isoline BARC-2 confirmed that the soybean Rj4 allele restricts nodulation by the same serogroup 123 isolates. Immunological analyses indicated that B. japonicum strains in serogroups 123 and 31 share at least one surface somatic antigen.     

Root hairs and phosphorus acquisition of wheat and barley cultivars

Several genes that restrict nodulation with specific Bradyrhizobiumstrains are known in Glycine max (soybean), and a similar system of nodulation restriction has recently been discovered in the related North American legume Amphicarpaea bracteata. We analyzed how nodulation-restrictive genotypes of each plant interacted with Bradyrhizobium strains sampled from the other host species. Ten bacterial isolates from A. bracteata that nodulated differentially with genotypes of their homologous host legume showed uniform responses to two soybean isogenic lines that differed at the Rj4 locus controlling nodulation restriction: all isolates formed nodules of normal size and morphology on both isolines. However, little or no nitrogen fixation occurred in any of these symbioses. A. bracteata genotypes that displayed broad vs. restricted symbiotic phenotypes toward naturally-associated bradyrhizobia were also tested with two bacterial isolates from soybean (USDA 76 and USDA 123). Both isolates formed nodules and fixed nitrogen in association with both A. bracteata genotypes. However, symbiotic effectiveness (as measured by acetylene reduction assays) was normal only for the combination of USDA 76 with the restrictive A. bracteata genotype. Overall, these results indicate that plant genes that restrict nodulation by certain naturally-associated bradyrhizobia do not confer comparable specificity when plants interact with bacteria from another related legume species.     

Rhizobitoxine production and symbiotic compatibility of Bradyrhizobium from Asian and North American lineages of amphicarpaea.

Reciprocal inoculations with Bradyrhizobium sp. isolates from the North American legume Amphicarpaea bracteata (L.) Fern. (Phaseoleae-Glycininae) and from a Japanese population of its close relative Amphicarpaea edgeworthii (Benth.) var. japonica were performed to analyze relative symbiotic compatibility. Amphicarpaea edgeworthii plants formed few or no nodules with any North American bradyrhizobial strains isolated from A. bracteata, but all A. bracteata lineages formed effective nitrogen-fixing nodules with Japanese Bradyrhizobium isolates from A. edgeworthii. However, one group of A. bracteata plants (lineage Ia) when inoculated with Japanese bradyrhizobia developed a striking leaf chlorosis similar to that known to be caused by rhizobitoxine. The beta-cystathionase inhibition assay demonstrated that significant amounts of rhizobitoxine were present in nodules formed by these Japanese bradyrhizobia. No North American bradyrhizobial isolate from A. bracteata induced chlorosis on any plants, and the beta-cystathionase assay failed to detect rhizobitoxine in nodules formed by these isolates. The role of rhizobitoxine in A. edgeworthii nodulation development was tested by inoculating plants with a Bradyrhizobium elkanii rhizobitoxine-producing strain, USDA 61, and two mutant derivatives, RX17E and RX18E, which are unable to synthesize rhizobitoxine. Amphicarpaea edgeworthii inoculated with wild-type USDA 61 developed >150 nodules per plant, while plants inoculated with RX17E and RX18E developed fewer than 10 nodules per plant. Thus, efficient nodule development in A. edgeworthii appears to be highly dependent on rhizobitoxine production by Bradyrhizobium strains.     

Genetic Diversity and Geographical Distribution of Indigenous Soybean-Nodulating Bradyrhizobia in the United States

We investigated the relationship between the genetic diversity of indigenous soybean-nodulating bradyrhizobia and their geographical distribution in the United States using nine soil isolates from eight states. The bradyrhizobia were inoculated on three soybean Rj genotypes (non-Rj, Rj₂Rj₃, and Rj₄). We analyzed their genetic diversity and community structure by means of restriction fragment length polymorphisms of PCR amplicons to target the 16S-23S rRNA gene internal transcribed spacer region, using 11 USDA Bradyrhizobium strains as reference strains. We also performed diversity analysis, multidimensional scaling analysis based on the Bray-Curtis index, and polar ordination analysis to describe the structure and geographical distribution of the soybean-nodulating bradyrhizobial community. The major clusters were Bradyrhizobium japonicum Bj123, in the northern United States, and Bradyrhizobium elkanii, in the middle to southern regions. Dominance of bradyrhizobia in a community was generally larger for the cluster belonging to B. elkanii than for the cluster belonging to B. japonicum. The indigenous American soybean-nodulating bradyrhizobial community structure was strongly correlated with latitude. Our results suggest that this community varies geographically.     

Rhizobitoxine: A phytotoxin of unknown function which is commonly produced by bradyrhizobia

Summary Fifty-six percent of 93 strains ofBradyrhizobium japonicum andBradyrhizobium sp. (various hosts) from diverse geographical areas were found to produce a chlorosis-inducing toxin. Toxin production was common among bradyrhizobia originating from the USA, Africa, Central America, and South America. Toxin produced by West African strains was compared with rhizobitoxine by cation exchange chromatography, paper chromatography, and soybean (Glycine max (L.) Merr.) bioassay. The comparison suggested that the chlorosis-inducing toxin produced by West African bradyrhizobia is rhizobitoxine. Purified toxin from a West AfricanBradyrhizobium sp. (Vigna) strain inhibited the growth ofBacillus subtilis on minimal medium. The growth inhibition was reduced by addition of yeast-extract or casamino acids but not by any of 21 individual amino acids, including methionine. The same toxin did not inhibit the growth of 14 Bradyrhizobium strains, including eight strains that did not produce toxin. Mixed inoculum experiments revealed that a toxin-producing West African strain could not assist toxin non-producingB. japonicum strains in nodulating non-nodulating (rj₁ rj₁) soybeans.     

Exclusion of inefficient Bradyrhizobium japonicum serogroups by soybean genotypes

Soybean [Glycine max (L.) Merr.] forms a symbiosis with serogroups of Bradyrhizobium japonicum that differ in their dinitrogen fixing abilities. The objectives of this study were to identify soybean genotypes that would restrict nodulation by relatively inefficient serogroups indigenous to a large portion of the southeastern USA, and then characterize the nodulation responses of selected genotypes with specific bradyrhizobial strains under controlled conditions. From field screening trials followed by controlled single and competitive inoculations of serogroups USDA 31, 76 and 110, twelve soybean genotypes out of 382 tested were identified with varying levels of exclusion abilities. Soybean nodule occupancies and nodulation characteristics were influenced by plant genotype, environment (i.e. field or greenhouse), bradyrhizobial serogroup, and location of nodules (i.e. tap or lateral root). The cultivar Centennial sustains high seed yields even though it nodulates to a high degree with the inefficient serogroup USDA 31. In contrast, data from the released cultivars Braxton, Centennial and Coker 368 indicate that they may have been selected to exclude the inefficient serogroup USDA 76 from their tap root nodules, possibly contributing to high seed yield.     

Diversity among Field Populations of Bradyrhizobium japonicum in Poland

Genetic structure in field populations of Bradyrhizobium japonicum isolated in Poland was determined by using several complementary techniques. Of the 10 field sites examined, only 4 contained populations of indigenous B. japonicum strains. The Polish bradyrhizobia were divided into at least two major groups on the basis of protein profiles on polyacrylamide gels, serological reaction with polyclonal antisera, repetitive extragenic palindromic PCR fingerprints of genomic DNA, and Southern hybridization analyses with nif and nod gene probes. Serological analyses indicated that 87.5% of the Polish B. japonicum isolates tested were in serogroups 123 and 129, while seven (12.5%) of the isolates tested belonged to their own unique serogroup. These seven strains also could be grouped together on the basis of repetitive extragenic palindromic PCR fingerprints, protein profiles, and Southern hybridization analyses. Cluster analyses indicated that the seven serologically undefined isolates were genetically dissimilar from the majority of the Polish B. japonicum strains. Moreover, immuno-cross-adsorption studies indicated that although the Polish B. japonicum strains reacted with polyclonal antisera prepared against strain USDA123, the majority failed to react with serogroup 123- and 129-specific antisera, suggesting that Polish bradyrhizobia comprise a unique group of root nodule bacteria which have only a few antigens in common with strains USDA123 and USDA129. Nodulation studies indicated that members of the serologically distinct group were very competitive for nodulation of Glycine max cv. Nawiko. None of the Polish serogroup 123 or 129 isolates were restricted for nodulation by USDA123- and USDA129-restricting soybean plant introduction genotypes. Taken together, our results indicate that while genetically diverse B. japonicum strains were isolated from some Polish soils, the majority of field sites contained no soybean-nodulating bacteria. In addition, despite the lack of long-term soybean production in Poland, field populations of unique B. japonicum strains are present in some Polish soils and these strains are very competitive for nodulation of currently used Polish soybean varieties.     

Fine mapping of the Rj4 locus,a gene controlling nodulation specificity in soybean

Leguminous plants have the ability to make their own nitrogen fertilizer by forming a root nodule symbiosis with nitrogen-fixing soil bacteria, collectively called rhizobia. This biological process plays a critical role in sustainable agriculture because it reduces the need for external nitrogen input. One remarkable property of legume–rhizobial symbiosis is its high level of specificity, which occurs at both inter- and intra-species levels and takes place at multiple phases of the interaction, ranging from initial bacterial infection and nodulation to late nodule development associated with nitrogen fixation. Knowledge of the molecular mechanisms controlling symbiotic specificity will facilitate the development of new crop varieties with improved agronomic potential for nitrogen-fixing symbiosis. In this report, we describe fine mapping of the Rj4 locus, a gene controlling nodulation specificity in soybean (Glycine max). The Rj4 allele prevents the host plant from nodulation with many strains of Bradyrhizobium elkanii, which are frequently present in soils of the southeastern USA. Since B. elkanii strains are poor symbiotic partners of soybean, cultivars containing an Rj4 allele are considered favorable. We have delimited the Rj4 locus within a 57-kb genomic region on soybean chromosome 1. The data reported here will facilitate positional cloning of the Rj4 gene and the development of genetic markers for marker-assisted selection in soybean.     

Soybean response to nodulation by bradyrhizobia differing in rhizobitoxine phenotype

Rhizobitoxine-producing (RT⁺) strains of Bradyrhizobium japonicum, differing in their abilities to induce foliar chlorosis with ‘Forrest’ soybean (Glycine max [L.] Merr.), were evaluated for effects on short term shoot productivity, nodulation, N₂ fixation, and nodule protein production under greenhouse conditions. Soybeans were singly inoculated with washed suspensions of (Group II) USDA strains 31, 46, 76, 94, 110, 123 or 130. Strains USDA 110 and USDA 123 (Group I/Ia) were included as RT-controls. The plants were cultured in the absence of combined N in horticultural-grade vermiculite for 49 days. Beginning 21 days after planting, plants were evaluated weekly for chlorophyll, leaf protein and biomass accumulation, nodular contents of leghemoglobin, soluble protein and RT, and total shoot N content. Rhizobitoxine was detected in nodules of all RT⁺ strains with the exception of USDA 31. However, only USDA 76 and USDA 94 produced both quantifiable concentrations of RT and symptoms of RT-induced chlorosis. Coincident with moderate to severe chlorosis were reductions in chlorophyll concentrations, shoot and nodule dry weight, leaf protein and total N₂ fixation. During extended periods of severe chlorosis, reductions in Lb and soluble nodular protein were observed. Based on carbon accumulation, all non-chlorotic treatments were statistically more productive than the chlorotic treatments. Similarly, non-chlorotic Group II treatments tended to fix less carbon relative to the RT-Group I/Ia controls, although these differences were not statistically significant. The results of this study suggest that, in the absence of discernable foliar chlorosis, the effect of RT⁺ (Group II) nodulation on short term soybean productivity is minimal. Published as Miscellaneous Paper No. 1439 of the Delaware Agricultural Experiment Station. Published as Miscellaneous Paper No. 1439 of the Delaware Agricultural Experiment Station.     

Response of introduced Bradyrhizobium strains infectinga promiscuous soybean cultivar

Two field experiments were established to assess the competitiveness of foreign bradyrhizobia in infecting the promiscuous soybean cultivar TGX 536-02D. Seeds were inoculated with antibiotic mutants of the bradyrhizobia strains before planting after land preparation. Soybean plants were harvested at pre-determined days after planting for estimating nodule number, nodule dry weight, nodule occupancy, shoot dry weight and seed yield. Results show that nodule number and dry weight significantly increased and showed great variability at 84 days after planting (DAP), probably due to differences in the ability of inoculant bradyrhizobia to form nodules with the soybean cultivar TGX 536-02D. Increased shoot dry weight, %N, total N and seed yield were a result of increased nodulation by the effective and competitive inoculant Bradyrhizobium strains. Strain USDA 110 occupied the highest percentage of nodule sites because it was more competitive than the other Bradyrhizobium strains. These results show that there was high potential for increasing growth and seed yield of the promiscuous soybean cultivar TGX 536-02D by inoculation with foreign Bradyrhizobium strains.     

Soybean cultivars affect nodulation competition of Bradyrhizobium japonicum strains

The influence of five Thai soybean cultivars on nodulation competitiveness of four Bradyrhizobium japonicum strains was investigated. Cultures of B. japonicum strains THA5, THA6, USDA110 and SEMIA5019 were mixed with each other prior to inoculating germinated soybean seeds growing in Leonard jars with nitrogen-free nutrient solution. At harvest, nodule occupancy by each strain was determined by a fluorescent antibody technique. The term ‘general competitive ability’ was introduced to describe the average competitive nodule occupancy of a strain in paired co-inoculation with a number of strains on soybean. The nodule occupancies by an individual strain were directly correlated with the proportions of that strain in the inoculum mixtures. USDA110 showed higher nodulation competitiveness than the other strains on three of the five cultivars. The Thai strain THA6 appeared to be more competitive than USDA110 on cultivar SJ5. Thus, nodulation competitiveness of the B. japonicum strains was affected by the cultivars of soybean used. This revised version was published online in August 2006 with corrections to the Cover Date.     

Influence of Bradyrhizobium japonicum Location and Movement on Nodulation and Nitrogen Fixation in Soybeans

The influence of seed and soil inoculation on bradyrhizobial migration, nodulation, and N₂ fixation was examined by using two Bradyrhizobium japonicum strains of contrasting effectiveness in N₂ fixation. Seed-inoculated strains formed fewer nodules on soybeans (mostly restricted to the tap and crown roots within 0 to 5 cm from the stem base) than did bradyrhizobia distributed throughout the soil or inoculated at specific depths. Nodulation was greater below the depths at which bradyrhizobial cells were located rather than above, even though watering was done from below to minimize passive bradyrhizobial migration with percolating water. The most profuse nodulation occurred within approximately 5 cm below the point of placement and was generally negligible below 10 cm. These and other results suggest that bradyrhizobial migration from the initial point of placement was very limited. Nevertheless, the more competitive strain, effective strain THA 7, migrated into soil to a greater extent than the ineffective strain THA 1 did. Nitrogen fixation resulting from the dual-strain inoculations differed depending on the method of inoculation. For example, the amount of N₂ fixed when both strains were slurried together onto the seed was about half that obtained from mixing the effective strain into the soil with the ineffective strain on the seed. The results indicate the importance of rhizobial distribution or movement into soil for nodulation, nodule distribution, strain competitiveness, and N₂ fixation in soil-grown legumes.     

Regulation of nodule formation in soybean-Bradyrhizobium symbiosis is controlled by shoot or/and root signals

Two strains of Bradyrhizobium japonicum wereevaluated with five commercial cultivars of soybean(Clark, Crauford, Davis, Centaur, and Nessen) and onehypernodulating mutant NOD1-3. The hypernodulatingNOD1-3 produced 30–50 times more nodules thancommercial cultivars either inoculated with B.japonicum strain USDA 123 or RCR 3409. The currentexperiments were extended to determine if therestricted nodulation of commercial cultivars could be overcome by grafting them to a hypernodulated shoot (NOD1-3). Grafting of NOD1-3 shoots to Clark and Davis roots induced hypernodulation on roots of Clark and Davis but did not enhance nodulation when grafted onto the roots of Crauford, Centaur, and Nessen. The shoots of Clark, Davis, Centaur and Nessen significantlyinhibited nodule formation on the root of NOD1-3,while Crauford shoots did not alter nodule formationon the roots of NOD1-3 as compared with self-grafts ofNOD1-3. It appears that the shoot of NOD1-3 has theability to alter autoregulatory control of nodulationof Clark and Davis cultivars, but did not withCrauford, Centaur and Nessen. The results suggestedthat the regulation of nodulation in soybean cultivarsClark and Davis is controlled by the shoot factors,while the Crauford was root controlled.Reciprocal-grafts between NOD1-3 and Centaur or Nessenindicate that both shoot and root factors involved inregulation of nodulation and the regulation ofnodulation did not depend on bradyrhizobial strains. Isoflavonoid analyses from extracts of grafted plantsshowed that NOD1-3 shoots had markedly higher rootisoflavonoid concentrations in roots of both Clark andNOD1-3. The shoot control of hypernodulation may becausally related to differential root isoflavonoidlevels, which are also controlled by the shoot. Thecurrent work was extended to investigate the effect ofapplication of an isoflavonoid (daidzein) on nodulationand nitrogen fixation of soybean cultivars Clark andCentaur as well as in vitro growth of Bradyrhizobium japonicum. Application of theisoflavonoid (daidzein) significantly enhanced thenodulation and nitrogenase activity of Clark but notof Centaur indicating that this character is notrelated to isoflavonoids. Therefore, autoregulationin Clark and Centaur plants may be separate events inlegume-rhizobia symbiosis and regulated by differentkinds of signals. Addition of daidzein to yeastmannitol broth medium promoted the growth of B.japonicum strain USDA 123 and RCR 3409. It seemsthat this compound is able to help the nodulation ofsoybean cv Clark by a Bradyrhizobium strain. Understanding the signaling pathways between rhizobiaand their host plants may allow modifications of thisinteraction to improve symbiotic performance.     

Short communication: Screening of native and foreign Bradyrhizobium japonicum strains for high N2 fixation in soybean

Four local rhizobia isolates selected after two screening experiments and five USDA Bradyrhizobium japonicum strains were estimated for N₂ fixation in soybean using the ¹⁵N isotope dilution technique. Strain USDA 110 was superior to the local isolates in nodulation and N₂ fixation when inoculated onto soybean cv TGX 1497-ID in a Nigerian soil and could therefore be used as an inoculant for enhanced N₂ fixation in soybean in Nigeria.