Study of theRhizobium japonicum-soybean symbiosis

Summary Capsular polysaccharides were isolated fromRhizobium japonicum (61A76NS) and conjugated to a fluorescent dye to determine if the specificity in theRhizobium japonicum-soybean symbiosis is expressed by a component (lectin) located on soybean roots which binds to the sugars of the bacterial capsules.The conjugated Fraction A capsular polysaccharides ofR. japonicum bound only to the root hair tips of soybean seedlings. The polysaccharide would not bind specifically to the roots of clover or alfalfa seedlings. Rhodamine conjugated polysaccharides ofR. japonicum could be inhibited from binding to soybean root hairs by the addition of N-acetylgalactosamine or galactose, effective hapten inhibitors of this type of binding. This is the first report of hapten-reversible binding of an isolated rhizobial component to soybean root hairs, the differentiated epidermal cells which are subsequently infected by this nitrogen-fixing symbiont.Paper number6046 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, North Carolina.     

Binding and penetration ofRhizobium japonicum to cultured soybean cells

A cultured soybean cell line, SB-1 was used to evaluate the initial interaction between the soybean cells andRhizobium japonicum. Co-culturing ofR. japonicum with SB-1 cells in suspension resulted in strain-specific polar attachment. This attachment can be inhibited by galactose and antibodies raised against seed soybean agglutinin (SBA). A lectin was purified from SB-1 cells which shares properties with SBA in terms of immunological reactivity, sugar binding activity, polypeptide molecular weight and peptide maps. When the SB-1 cells were co-cultured withR. japonicum for three weeks in solid agar medium, histological staining revealed bacterial penetration into certain SB-1 cells. Furthermore, there were focal regions of cells with prominent nuclei representing actively proliferating regions. These observations are analogous to that ofin vivo nodule initiation in soybean roots.     

Nodulation and nitrogen fixation by fast- and slow-growing rhizobia strains of soybean on several temperate and tropical legumes

Three slow-growingBradyrhizobium japonicum (G₃, USDA-110 and KUL-150) of diverse origins and two fast-growing strains ofRhizobium fredii (USDA-192 and USDA-193) were tested with a cropped soybean (Glycine max L. Merrill) cultivar, two cowpeas (Vigna unguiculata), one mung-bean (Phaseolus radiata), one winged-bean (Psophocarpus tetragonolobus) and one field bean (Phaseolus vulgaris) varieties.TheR. fredii strains nodulated and fixed Nitrogen as effectively as the strains ofB. japonicum in a modern european soybean cultivar, namely Fiskeby V. The other western bred soybeans tested were not nodulated by theseR. fredii strains. All of the soybean rhizobia produced nodules in both cowpeas and in mung-bean; theR. fredii strains showed effective N₂-fixation in the cowpeas, particularly USDA-193, yielding shoot dry weights greater than those from theB. japonicum. The symbiotic performance of theR. fredii strains with soybean and other legumes indicated that they should be placed in an intermediate group between the slow-growingB. japonicum and cowpearhizobium sp.The hydrogen uptake activites suggested a possible host effect on the expression of such genes in one out of theB. japonicum strains tested. Furthermore, the slow-growing rhizobia showed significantly higher nitrate-reduction than theR. fredii in the nodules.     

Response of soybean-Rhizobium symbioses to mineral nitrogen

Summary The effect of mineral nitrogen on establishment and activity of symbioses between soybean and several strains ofRhizobium japonicum and on the establishment of nodules ofR. japonicum isolated from nodules of field crops is studied. All strains were highly susceptible to the effects of 200 ppm NO₃–N on the establishment of symbiosis; 50 ppm NO₃–N had little effect. Response of symbioses establishhed in the absence of mineral N to short term exposure to nitrate or ammonium varied significantly between strains. Nodule isolates from soybean crops growing in nitrifying soil were no less susceptible to the inhibitory effects of mineral N on nodule formation than a laboratory culture of the commercial inoculant strain.     

Competitive growth of slow growingRhizobium japonicum against fast growingEnterobacter andPseudomonas species at low concentrations of succinate and other substrates in dialysis culture

A cultivation system with simultaneous growth of six bacterial cultures in separate bags in dialysis culture was developed. In a medium with no added carbon source (one half concentrated Hoagland solution, water deionized and distilled), cell number ofRhizobium japonicum increased during a 7 day period by a factor of 35, whereas the number ofEnterobacter aerogenes cells decreased to one half. With a concentration of 100 nM succinate as an additional carbon source in the inflow,Rhizobium japonicum 61-A-101 cell number increased by a factor of 50 during an 8 day period, whereas cell number ofEnterobacter cloacae NCTC 10005 only doubled and ofEnterobacter aerogenes NCTC 10006 decreased. At 10 mM concentration of succinate in the inflow, doubling time the twoEnterobacter strains was about 12 h, compared to about 24 h for theRhizobium japonicum strain. Varying the succinate concentration from 10 mM to 100 nM in the inflow,Rhizobium japonicum 61-A-101 surpassed theEnterobacter aerogenes strains in the growth rate between 1 mM and 100 M succinate in the inflowing medium. Three otherRhizobium japonicum strains (fix⁺ and fix^-) did grow with a similar rate as strain 61-A-101 at very low concentrations of substrate. Growth rates for the strains were confirmed by protein data per culture. Growing in competition with twoPseudomonas strains,Rhizobium japonicum RH 31 Marburg (fix^-) did overgrow alsoPseudomonas fluorescens, was however outgrown byPseudomonas putida. In utilizing low concentrations of a¹⁴C labelled organic acid (malonate), three strains ofRhizobium japonicum left 2–4 times smaller amounts of¹⁴C in the medium than two species ofPseudomonas and two species ofArthrobacter.On sabbatical leave at ANU     

Characterization ofR. fredii QB1130, a strain effective on commercial soybean cultivars

Summary Two rhizobial strains (QB1130 and C3A) from northeast China were identified asRhizobium fredii on the basis of growth rate, media acidification and growth on a wide range of carbon substrates. The strains were shown to be distinct from USDA 191 on the basis of plasmid number and size. Bothnif and commonnod genes were located on the 295 kb plasmid of strains QB1130 and USDA 191, while onlynif genes were identified on this plasmid in C3A. When used to inoculate four commercial soybean (Glycine max) cultivars, one of the strains (C3A) was found to be ineffective, while the other (QB1130) was at least as effective as USDA 191, a strain ofR. fredii reported to be widely effective on North American cultivars of soybean. Further, QB1130 was capable of more effective nodulation of cowpea or the uncultivated soybean line, Peking, than either USDA 191 or the slow-growingBradyrhizobium japonicum USDA 16. Strain QB1130 should be useful for studies directed at improving symbiotic performance in soybean, or for studies of the comparative physiology and genetics of FG and SG strains on a single host.     

Agglutination ofRhizobium japonicum 3I1b110 by soybean lectin

Summary Conditions leading to agglutination ofRhizobium japonicum 3I1b110 with soybean seed lectin were examined. Ability of cells to be agglutinated was transient and was optimal for cultures grown for 4–5 days on yeast extract mannitol plates. Similar lectin-binding results were obtained with cells from the same cultures using fluorescence microscopy with fluorescein isothiocyanate-labelled lectin. These results revise the previous model for soybean lectin-R. japonicum interactions, since it was based on the inability of soybean lectin to agglutinate these bacteria.     

Enhanced nodulation of soybean by Bradyrhizobium in the presence ofPseudomonas fluorescens

Experiments were undertaken to determine the effect ofPseudomonas fluorescens on nodulation of soybean by two strains ofBradyrhizobium japonicum, USDA I-110 and 61A76.Pseudomonas fluorescens can enhance the nodulation ability ofB. japonicum. Preincubation ofB. japonicum withP. fluorescens before inoculation further increased the level of nodulation.     

Associative effect ofAzospirilium brasilense withRhizobium japonicum on nodulation and yield of soybean (Glycine max)

Summary Azospirillum was associated with nodules of soybean. In general, seed inoculation with a broth culture ofAzospirillum brasilense alone significantly increased nodulation and grain yield of soybean grown in pots in unsterilized soil with different levels of urea ranging from 0 to 80 kg N/ha. This trend was significantly reproducible in a second experiment when a carrier based inoculant of the bacterium was used for seed inoculation.Inoculation withRhizobium japonicum andA. brasilense in combination generally increased grain yield in both the experiments, although the data were not significant.     

Survival and multiplication ofRhizobium japonicum strains in silt loam

Summary Antibiotic resistant mutants 8-0 Str^R, 110 Tet^R and 138 Kan^R derived from wild typeRhizobium japonicum strains were inoculated into silt loam soil to cell concentrations greater than 2×10⁸/g of soil. Population changes were monitored using antibiotic media and strain identification was done using immunodiffusion assay on microcores of soil. Immunodiffusion bands formed by the mutant strains with homologous antisera essentially duplicated bands formed by the parent strain. Strains 110 Tet^R and 8-0 Str^R had cross reacting antigens whereas antigens of strain 138 Kan^R reacted only with the homologous antiserum. Populations ofR. japonicum strains introduced into sterile soil increased over a period of four weeks under both single and mixed culture inoculations. All populations decreased by the end of six weeks and thereafter remained constant. When theseR. japonicum strains were introduced into non-sterile soil, the population did not increase over the initial population added. Population decreased gradually for two weeks and then maintained thereafter. It was possible to recover very low populations of antibiotic resistantR. japonicum strains from both sterile and unsterile soils using media containing specific antibiotics. Detection ofR. japonicum strains by immunodiffusion was accomplished only when the population was 10⁹ cells/g of soil. The method using antibiotic resistant mutants permitted an evaluation of the interactions of variousR. japonicum strains in soil with respect to their survival and multiplication.     

Some USDA studies on the soybean-Rhizobium symbiosis

Summary The ecology, strain evaluation, genetics of host strain interactions and physiology of nitrogen fixation ofRhizobium japonicum in association with the soybean,Glycine max, were studied. Results of inoculation experiments with selected strains ofRhizobium japonicum indicated that indigenous strains occupied most of the nodules of soybeans grown in highRhizobium japonicum populated soils. Nodule sampling indicated that inoculation did not result in quicker nodulation or a higher incidence of root nodules (primary or secondary) than uninoculated checks. Rhizosphere studies indicated that colonization by introduced strains did occur but did not compete successfully with field strains for nodule sites. Recovery of specific serological types from nodules was influenced by planting intervals. The distribution of the serotypes varied with the time of planting and the age of the plant. Temperature studies indicated that the distribution of serotypes recovered from the nodules was influenced by temperature. Field studies showed the selectivity of soybean genotypes on strains ofRhizobium japonicum. Some strains were more common in the nodules of some varieties than in others. Closely related varieties had similar populations in their nodules. Three genes which control nodule response in soybeans are reported. Nitrogen fixation profiles were determined for some variety-strain interactions. Combinations previously classified as inefficient showed some nitrogenase activity as measured by the acetylene reduction technique. Research Microbiologist; Research Agronomist; Research Plant Physiologist, Soybean Investigations, Crops Research Division, Beltsville, Md. (USDA, ARS); and Plant Pathologist currently located at Michigan State University, East Lansing, Michigan.     

A new perfusion system for the measurement and characterization of potential rates of soil nitrification

The effect of two isoflavonoids, coumestrol and daidzein which are present in aseptically grown roots and root exudates of soybean, was tested on some rhizospheric microorganisms. It was found that coumestrol promotes the growth ofR. japonicum USDA 138 (about 30%) andR. leguminosarum (about 15%) whereas it inhibits the growth ofAgrobacterium tumefaciens (about 50%) andPseudomonas sp. (about 20%). The following microorganisms were unaffected by this molecule:R. japonicum W505,Agrobacterium radiobacter, Micrococcus luteus andCryptococcus laurentii. It was found that daidzein promotesR. japonicum USDA 138 growth (about 20%) and inhibitsPseudomonas sp. growth (about 20%); other microorganisms were unaffected. In addition, coumestrol favoured the formation of ‘coccoids’ cells byRhizobium japonicum USDA 138 which could be the infective state of this strain. It seems that this compound is able to help nodulation of soybean by aRhizobium strain. This result supports the work of Peterset al. (1986) and Redmondet al. (1986) who show that flavones present in plant exudates induces expression of nodulation genes in Rhizobium.     

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.     

Identification of enzymes involved in indole-3-acetic acid degradation

Strains of Bradyrhizobium japonicum with the ability to catabolize indole-3-acetic acid (IAA) and strains of B. japonicum, Rhizobium loti, and Rhizobium galegae, unable to catabolize IAA, were analyzed for enzymes involved in the pathway for IAA degradation. Two enzymes having isatin as substrate were detected. An isatin amidohydrolase catalyzing the hydrolysis of isatin into isatinic acid was found in some B. japonicum strains and in two Rhizobium species, R loti and R. galegae. The enzyme was inducible (4–5-fold) by its substrate, isatin, and the partially purified enzyme from R. loti showed an apparent K_M of 11 M for isatin. A NADPH-dependent isatin reductase was measured in extracts from a strain of B. japonicum lacking the isatin amidohydrolase. The structure of the reaction product, dioxindole was verified by NMR spectroscopy. Isatin reductase activity was also detected in extracts of dry pea seeds, and present in at least two isoforms. A low K_M of 10 M for isatin was found with a partially purified preparation of the pea enzyme. The presence of such an enzyme activity in pea indicates dioxindole and isatin as possible intermediates in IAA degradation in pea.     

Comparison of the host range of fast-growingR. japonicum strains with a fast-growing isolate from Lablab

Summary Fast-growingRhizobium japnicum strains derived from the People's Republic of China were compared with a fast-growingRhizobium isolate from Lablab for their ability to nodulate tropical legumes grown in Leonard-jars and test tube culture. Fast-growingR. japonicum strains were all effective to varying degrees in their symbiosis withVigna unguiculata. Two strains USDA 192 and USDA 201, effectively nodulatedGlycine whightii and one strain, USDA 193, effectively nodulatedMacroptilium atropurpureum. Other nodulation responses in tropical legumes were ineffective. The fast-growing isolate from Lablab was more promiscuous, effectively nodulating with a larger host range. The fast-growing Lablab strain was considered more akin, on a symbiotic basis, to the slow-growing cowpea type rhizobia than the fast-growing China strains ofR. japonicum whilst maintaining physiological characteristics of other fast-growing rhizobia.     

The effect of growth medium on lectin binding byRhizobium japonicum

Summary A comparative study of soybean lectin binding byRhizobium japonicum 61A76 grown in yeast extract mannitol medium supplemented with soil extract showed that it produced cells with greater lectin binding capacity, larger cell size and a higher percentage of coccoid forms than those produced in yeast extract mannitol medium alone.     

In Bradyrhizobium japonicum the common nodulation genes, nodABC, are linked to nifA and fixA

Summary Using cloned Rhizobium phaseoli nodulation (nod) genes as hybridization probes homologous restriction fragments were detected in the genome of the slow-growing soybean symbiont, Bradyrhizobium japonicum strain 110. These fragments were isolated from a cosmid library, and were shown to lie 10 kilobasepairs (kb) upstream from the nifA and fixA genes. Specific nod probes from Rhizobium leguminosarum were used to identify nodA-, nodB-, and nodC-like sequences clustered within a 4.5 kb PstI fragment. A mutant was constructed in which the kanamycin resistance gene from Tn5 was inserted into the nodA homologous B. japonicum region. This insertion was precisely located, by DNA sequencing, to near the middle of the nodA gene. B. japonicum mutants carrying this insertion were completely nodulation deficient (Nod^-).     

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.     

Field evaluation of symbiotic nitrogen fixation by rhizobial strains using15N methodology

Summary Small differences in N₂ fixation by nodulated soybeans (Glycine max. (L.) Merr.), inoculated with various strains ofRhizobium japonicum, were assessed in field experiments using¹⁵N methodology, and compared with yields of plant dry matter and total N. Percentage of plant-N derived from atmospheric N₂ and from fertilizer, and values of %¹⁵N atom excess had lower coefficients of variation than did total N and dry matter yield. Nevertheless the precision of estimates of kg N/ha fixed were sufficient to differentiate only the extremes of the range of strains tested, and there were discrepancies between ranking of strains based on % N derived from fertilizer and on total N yield.     

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.