Co-inoculation with antibiotic-producing bacteria to increase colonization and nodulation by rhizobia

A study was conducted to determine whether colonization of legume roots and nodulation byRhizobium meliloti andBradyrhizobium japonicum could be enhanced by using inocula containing microorganisms that produce antibiotics suppressing soil or rhizosphere inhabitants but not the root-nodule bacteria. An antibiotic-producing strain of Pseudomonas and one of Bacillus were isolated, and mutants ofR. meliloti andB. japonicum sp. resistant to the antibiotics were used. The colonization of the alfalfa rhizosphere and nodulation byR. meliloti were enhanced by inoculation of soil withPseudomonas sp. in soil initially containing 2.7×10⁵ R. meliloti per g. The colonization of soybean roots byB. japonicum was enhanced by inoculating soil with three cell densities ofBacillus sp., and nodulation was stimulated byBacillus sp. added at two cell densities. In some tests, the dry weights of soybeans and seed yield increased as a result of these treatments, and co-inoculation with Bacillus also increased pod formation. Inoculation of seeds withBacillus sp. and the root-nodule bacterium enhanced nodulation of soybeans and alfalfa, but colonization byB. japonicum andR. meliloti was stimulated only during the early period of plant growth. Studies were also conducted withStreptomyces griseus and isolates ofR. meliloti andB. japonicum resistant to products of the actinomycete. Nodulation of alfalfa byR. meliloti was little or not affected by the actinomycete alone; however, both nodulation and colonization were enhanced if the soil was initially amended with chitin andS. griseus was also added. Chitin itself did not affectR. meliloti. Treatments of seeds with chitin orS. griseus alone did not enhance colonization of alfalfa roots byR. meliloti or soybean roots byB. japonicum, but the early colonization of the roots by both bacterial species was promoted if the seeds received both chitin andS. griseus; this treatment also increased nodulation and dry weights of alfalfa and soybeans and the N content of alfalfa. It is suggested that co-inoculation of legumes with antibiotic-producing microorganisms and root-nodule bacteria resistant to those antibiotics is a promising means of promoting nodulation and possibly nitrogen fixation.     

Bacterial Growth Rates and Competition Affect Nodulation and Root Colonization by Rhizobium meliloti

The addition of streptomycin to nonsterile soil suppressed the numbers of bacterial cells in the rhizosphere of alfalfa (Medicago sativa L.) for several days, resulted in the enhanced growth of a streptomycin-resistant strain of Rhizobium meliloti, and increased the numbers of nodules on the alfalfa roots. A bacterial mixture inoculated into sterile soil inhibited the colonization of alfalfa roots by R. meliloti, caused a diminution in the number of nodules, and reduced plant growth. Enterobacter aerogenes, Pseudomonas marginalis, Acinetobacter sp., and Klebsiella pneumoniae suppressed the colonization by R. meliloti of roots grown on agar and reduced nodulation by R. meliloti, the suppression of nodulation being statistically significant for the first three species. Bradyrhizobium sp. and “Sarcina lutea” did not suppress root colonization nor nodulation by R. meliloti. The doubling times in the rhizosphere for E. aerogenes, P. marginalis, Acinetobacter sp., and K. pneumoniae were less and the doubling times for Bradyrhizobium sp. and “S. lutea” were greater than the doubling time of R. meliloti. Under the same conditions, Arthrobacter citreus injured alfalfa roots. We suggest that competition by soil bacteria reduces nodulation by rhizobia in soil and that the extent of inhibition is related to the growth rates of the rhizosphere bacteria.     

Enhancing Soybean Rhizosphere Colonization by Rhizobium japonicum

A study was conducted to seek means to increase the colonization of the rhizosphere of soybeans (Glycine max L. Merrill) by Rhizobium japonicum. For this purpose, a strain of R. japonicum that was resistant to benomyl, streptomycin, and erythromycin was used. The numbers of R. japonicum rose quickly in the first 2 days after soybean seeds were planted in soil and then rapidly fell. The decline was slower if the seeds were coated with benomyl. This fungicide reduced the numbers of bacteria and protozoa in the rhizosphere, but the effect became less or disappeared as the plants grew. In sterile soil inoculated with R. japonicum and a mixture of microorganisms, the numbers of R. japonicum were usually lower if protozoa were present than if they were absent. Nodulation and plant yield were increased by the addition of benomyl to soybean seeds sown in sterile soil inoculated with R. japonicum and a mixture of microorganisms. The addition of streptomycin and erythromycin to soil stimulated the growth of R. japonicum but inhibited other bacteria in the presence or absence of soybeans. The data indicate that colonization can be increased by the use of antimicrobial agents and R. japonicum strains resistant to those inhibitors.     

Colonization behaviour of Pseudomonas fluorescens and Sinorhizobium meliloti in the alfalfa (Medicago sativa) rhizosphere

The colonization ability of Pseudomonas fluorescens F113rif in alfalfa rhizosphere and its interactions with the alfalfa microsymbiont Sinorhizobium meliloti EFB1 has been analyzed. Both strains efficiently colonize the alfalfa rhizosphere in gnotobiotic systems and soil microcosms. Colonization dynamics of F113rif on alfalfa were similar to other plant systems previously studied but it is displaced by S. meliloti EFB1, lowering its population by one order of magnitude in co-inoculation experiments. GFP tagged strains used to study the colonization patterns by both strains indicated that P. fluorescens F113rif did not colonize root hairs while S. meliloti EFB1 extensively colonized this niche. Inoculation of F113rif had a deleterious effect on plants grown in gnotobiotic systems, possibly because of the production of HCN and the high populations reached in these systems. This effect was reversed by co-inoculation. Pseudomonas fluorescens F113 derivatives with biocontrol and bioremediation abilities have been developed in recent years. The results obtained support the possibility of using this bacterium in conjunction with alfalfa for biocontrol or rhizoremediation technologies.     

Positive role of nodulation on the establishment ofRhizobium japonicum in subsequent crops of soybean

The influence of soybean nodulation on the establishment ofRhizobium japonicum inRhizobium-free soil was examined. Seeds of nodulating (Rj ₁) and nonnodulating (rj ₁) isolines of soybeans and four other crop species (cowpeas, mungbeans, corn, and alfalfa) were grown in field plots that were inoculated with a genetically marked strain ofRhizobium (strain I-110 ARS) and the following year nodulating soybeans were grown in these plots and were inoculated with a different genetically marked subline of the same strain (strain I-110 FN). The proportion of nodules containing strain I-110 ARS relative to strain I-110 FN was determined and interpreted as reflecting the relative numbers of the two genetically marked sublines in the soil. The results clearly demonstrate that nodulation with the specific host plant (soybeans) has a significant positive role in the establishment ofRhizobium inRhizobium-free soil and suggests that alfalfa plants diminish the establishment of soybean rhizobia in soil.     

Saprophytic Actinomycetes Promote Nodulation in <Emphasis Type="Italic">Medicago sativa</Emphasis>-<Emphasis Type="Italic">Sinorhizobium meliloti</Emphasis> Symbiosis in the Presence of High N

Saprophytic rhizoactinomycetes isolated from the root nodule surface of the nitrogen-fixing actinorhizal plant Discaria trinervis, Streptomyces MM40, Actinoplanes ME3, and Micromonospora MM18, previously shown to stimulate nodulation in Frankia-Discaria trinervis symbiosis, were assayed as co-inoculants with Sinorhizobium meliloti 2011 on Medicago sativa. When plants were fertilized with a low level of N (0.07 mM), the inoculation of the actinomycetes alone did not show any effect on plant growth. Meanwhile, when actinomycetes were co-inoculated with S. meliloti, nodulation and plant growth were significantly stimulated compared to plants inoculated with only S. meliloti. The analysis of nodulation kinetics of simultaneously or delayed co-inoculations suggests that the effect of the actinomycetes operates in early infection and nodule development counteracting the autoregulation of nodulation by the plant. Because the actinomycete effect was found in the symbiotic nitrogen-fixing state of the plant, we investigated the effects of the actinomycetes, in single inoculation or co-inoculation with S. meliloti, on plants grown under a high level of N (7 mM) that was inhibitory for nodulation by S. meliloti. The inoculation of the actinomycetes alone did not show any effect on plant growth although high N was available. Unexpectedly, the co-inoculation of actinomycetes with S. meliloti on plants grown with high N (7 mM) significantly stimulates nodulation, clearly counteracting the inhibition of nodulation by high N. These results corroborate that the interaction of rhizoactinomycetes would interfere with the autoregulation of nodulation in alfalfa mediated by high N, opening new research lines of potential agronomical applications.     

Relative genetic structure of a population of Rhizobium meliloti isolated directly from soil and from nodules of alfalfa (Medicago sativa) and sweet clover (Melilotus alba)

Insertion sequence (IS) hybridization was used to define the structure of a population of Rhizobium meliloti isolated directly from soil and from nodules of Medicago sativa (alfalfa) and Melilotus alba (sweet clover) grown under controlled conditions and inoculated with a suspension of the same soil. The detection of R. meliloti isolated from soil on agar plates was facilitated by use of a highly species specific DNA probe derived from ISRm5. All R. meliloti obtained directly from soil proved to be symbiotic (i.e. nodulated and fixed nitrogen with alfalfa). Analysis of 293 R. meliloti isolates revealed a total of 17 distinct IS genotypes of which 9, 9 and 15 were from soil, M. alba and M. sativa, respectively; 8 genotypes were common to soil and both plant species. The frequency of R. meliloti genotypes from soil differed markedly from that sampled from nodules of both legume species: 5 genotypes represented about 90% of the isolates from soil whereas a single genotype predominated among isolates from nodules accounting for more than 55% of the total. The distribution of genotypes differed between M. sativa and M. alba indicating species variation in nodulation preferences for indigenous R. meliloti. The data are discussed in the context of competition for nodulation of the host plant and the selection of Rhizobium strains for use in legume inoculants. This study has ecological implications and suggests that the composition of R. meliloti populations sampled by the traditionally used host legume may not be representative of that actually present in soil.     

Rhizobium meliloti inoculation of alfalfa selected for tolerance to acid,aluminum-rich soils

Alfalfa (Medicago sativa L.) growth and nodulation in acid soil is reduced because the plant and its bacterial symbiontRhizobium meliloti cannot tolerate acid, aluminum-rich soil. A study was conducted to determine if a relatively acid-tolerant alfalfa germplasm combined with a relatively acid-tolerantR. meliloti strain could overcome these limitations. In a light room study, an acid-tolerant alfalfa germplasm inoculated with a more acid-tolerantR. meliloti strain produced greater top growth, nodule number and weight, and acetylene reduction values in an unlimed soil (pH 4.6) than the same germplasm inoculated with a relatively acid-sensitiveR. meliloti strain or an acid-sensitive germplasm inoculated with either a relatively acid-tolerant or acid-sensitiveR. meliloti strain.     

Biological Control of Phytophthora Root Rots on Alfalfa and Soybean with Streptomyces

A collection of 53 antibiotic-producing Streptomyces isolated from soils from Minnesota, Nebraska, and Washington were evaluated for their ability to inhibit plant pathogenic Phytophthora medicaginis and Phytophthora sojae in vitro. Eight isolates having the greatest pathogen-inhibitory capabilities were subsequently tested for their ability to control Phytophthora root rots on alfalfa and soybean in sterilized vermiculite and naturally infested field soil. The Streptomyces isolates tested significantly reduced root rot severity in alfalfa and soybean caused by P. medicaginis and P. sojae, respectively (P < 0.05). On alfalfa, isolates varied in their effect on plant disease severity, percentage dead plants, and plant biomass in the presence of the pathogen. The same eight isolates of Streptomyces were also tested for inhibitory activities against each other and against three strains of Bradyrhizobium japonicum and two strains of Sinorhizobium meliloti isolated from soybean and alfalfa, respectively. Streptomyces isolates clustered into two major compatibility groups: isolates within the same group were noninhibitory toward one another in vitro. The compatibility groups corresponded with groupings obtained based upon inhibition of B. japonicum and S. meliloti strains.     

Symbiotic performance of common bean and soybean co-inoculated with rhizobia and <Emphasis Type="Italic">Chryseobacterium balustinum</Emphasis> Aur9 under moderate saline conditions

The effect of co-inoculating beans and soybeans with rhizobia and Chryseobacterium, a plant growth promoting bacteria (PGPR), was studied under conditions of mild saline stress. Chryseobacterium balustinum Aur9 was used with Rhizobium tropici CIAT899 or R. etli ISP42 to inoculate common bean (Phaseolus vulgaris L.), or jointly with Ensifer (Sinorhizobium) fredii SMH12 and HH103 to inoculate soybean (Glycine max (L.) Merrill). The effect of co-inoculation was studied by following nodule primordia initiation, nodulation kinetics and symbiotic performance in plants grown under moderate saline conditions (25 mM NaCl). In common bean, co-inoculation improved nodule primordia formation when compared with single inoculation (R. tropici CIAT899). However, co-inoculation did not provide benefits in the development of nodule primordia in soybean with E. fredii SMH12. The kinetic of nodulation in bean was also favored by double inocula resulting in a higher number of nodules. Long-term effects of co-inoculation on beans and soybeans depended on the rhizobial species used. In both, control and saline conditions, co-inoculation of R. tropici CIAT899 and C. balustinum Aur9 improved bean growth when compared with the single inoculation (CIAT899). However, the positive effect of double inocula on plant growth did not occur when using R. etli ISP42. Soybean plants receiving double inoculation (E. fredii SMH12 and C. balustinum Aur9) showed better symbiotic performance, mostly under saline stress, than with a single inoculation. The results indicate that co-inoculation with C. balustinum and rhizobia under mild saline conditions partially relieves the salt-stress effects, although do not always result advantageous for symbiotic N₂ fixation in legume plants.     

Influence of the herbicide phosphinothricin on growth and nodulation capacity of Rhizobium meliloti

  Rhizobium meliloti proved to be sensitive to low concentrations of the herbicide phosphinothricintripeptide (PTT) and its active ingredient phosphinothricin (PT), which was formerly assumed to be non-toxic for most of the bacteria analysed. Growth was more strongly reduced in sterile synthetic media and less reduced in sterile soil; in unsterile soil only a transient growth reduction was detectable. Sensitivity was also observed in five out of eight other species analysed. In all sensitive species tested, spontaneous resistances to PT occurred. Under sterile conditions, PTT and PT reduced rhizobial nodulation rates of PT-resistant alfalfa plants drastically; however, nitrogen fixation in the few nodules that arose was unaffected. Because of the small number of nodules, the overall fixation rate was strongly diminished. In unsterile soil, nodulation and nitrogen fixation rates were not changed, possibly because of the rapid degradation of PTT and PT in the soil. Using a herbicide as model substance it could be demonstrated that the sensitivity of R. meliloti to chemical additives in the soil can be detected by analysing its growth rate, and that even a weak impact can influence its nodulation capacity. R. meliloti has proven to be a fast, easy and sensitive detection system for bacteriostatic components present in the soil. Received: 12 April 1996 / Received revision: 15 July 1996 / Accepted: 18 July 1996     

Production of Exo-polysaccharide by <Emphasis Type="Italic">Rhizobium</Emphasis> sp.

Two fold increase in the yield of glucose and maltose containing exo-polysaccharide (EPS) by Rhizobium sp. was observed during its growth in modified YEMB. EPS production, plant growth promotion activity and root colonization of Rhizobium sp. studies showed enhanced EPS synthesis, more seed germination and over all improvement in plant growth over control and R. meliloti treatment. Groundnut seeds bacterized with Rhizobium sp. resulted in 69.75% more root length, 49.51% more shoot height, 13.75% more number of branches and 13.60% more number of pods over the control and R. meliloti treatment. Bacterization of wheat seeds increased the dry matter yield of roots (1.7-fold), and roots adhering soil (RAS) (1.5) and shoot mass (1.9-fold). Rhizobium sp. inoculation also increased the population density of EPS-producing bacteria on the rhizoplane. Roots of plants inoculated with Rhizobium sp. maintained a higher K⁺/Na⁺ ratio and K⁺–Na⁺ selectivity.     

Characterization of extrachromosomal replicons present in the extended host range Rhizobium sp. LPU83

In several rhizobia, bacteria that inhabit the soil in free-living conditions and associate in symbiosis with the root of legumes as nitrogen-fixing organisms, plasmid DNA can constitute a high percentage of the genome. We have characterized acid-tolerant isolates of rhizobia-here represented by the strain Rhizobium sp. LPU83-that have an extended nodulation-host range including alfalfa, the common bean, and Leucena leucocephala. In this study we analyzed the plasmids of R. sp. LPU83 in order to characterize their role in the evolution of Medicago symbionts and their involvement in symbiotic behavior. The pLPU83a plasmid was found to be transmissible with no associated phenotypic traits. The symbiotic plasmid pLPU83b could be transferred at very low frequencies under laboratory conditions only when pLPU83a was present; could restore nodulation to a strain cured of its symbiotic plasmid, S. meliloti A818; but could not restore the full nitrogen fixation associated with alfalfa.     

Variation in Preference for Rhizobium meliloti Within and Between Medicago sativa Cultivars Grown in Soil

Variation in nodulation preferences for Rhizobium strains within and between Medicago sativa cultivars was assessed in the greenhouse with plants grown in Leonard jars and two soils of diverse origin (Lanark and Ottawa), using inocula consisting of effective individual or paired strains of R. meliloti which could be recognized by high-concentration antibiotic resistance. The results indicated considerable variability in host preferences for R. meliloti among plants within cultivars but not between cultivars. The implications of this variation are discussed from the point of view of possible improvement of symbiotic nitrogen fixation. With one exception, the differences in nodulation success between inoculant R. meliloti strains were consistent in Leonard jars and both soils. All introduced strains formed significantly more nodules in Renfrew soil containing few native rhizobia than in Ottawa soil with a large resident R. meliloti population. Plants grown in Lanark soil without inoculation were ineffectively nodulated by native rhizobia and yielded significantly less growth than those receiving inoculation. In contrast, the yield of inoculated plants in Ottawa soil did not significantly differ from those without inoculation due to effective nodulation by native R. meliloti. The data indicated synergistic effects on yield by certain paired strain inocula relative to the same strains inoculated individually in Lanark but not in Ottawa soil or Leonard jars.     

Alfalfa Root Exudates and Compounds which Promote or Inhibit Induction of Rhizobium meliloti Nodulation Genes

Using a plate induction assay, we demonstrate that alfalfa exudes inducer of Rhizobium meliloti nodulation genes. The inducer is exuded from the infectible zone of the root, accumulates to at least 1 micromolar, and is not affected by 10 millimolar nitrate. No zones of inhibition are observed. A nodulation minus mutant line of alfalfa, MN-1008, exudes normal levels of inducer. R. meliloti grown in rich medium requires ten-fold higher concentrations of luteolin to achieve half-maximal induction as compared to cells grown in a minimal medium. Flavonoids other than luteolin are found to have activity in R. meliloti nodulation gene induction assays. The compounds apigenin and eriodictyol have activities two-fifths and one-seventh that of luteolin, respectively. Several of the flavonoids tested (morin = naringenin > kaempferol = chrysin > quercetin = fisetin = hesperitin) demonstrate antagonistic activity toward induction by luteolin. The most effective antagonist is the coumarin, umbelliferone.     

Rhizosphere Response as a Factor in Competition Among Three Serogroups of Indigenous Rhizobium japonicum for Nodulation of Field-Grown Soybeans

Rhizosphere response was studied as a factor in competition among indigenous Rhizobium japonicum serogroups for the nodulation of soybeans under field conditions. R. japonicum serogroups 110, 123, and 138 were found to coexist in a Waukegan field soil where they were determined to be the major nodulating rhizobia in soybean nodules. Competitive relationships among the three serogroups in that soil and in rhizospheres were examined during two growing seasons with several host cultivars with and without inoculation and with a nonlegume. Enumeration of each of the three competitors was carried out on inner rhizosphere and nonrhizosphere soil by immunofluorescence with serogroup-specific fluorescent antibodies. Rhizobia present in early- and late-season nodules were identified by fluorescent antibody analysis. Populations of each serogroup increased gradually in host rhizospheres, not exceeding 10⁶/g of rhizosphere soil during the first few weeks after planting, whereas numbers in fallow soil remained at initial levels (10⁴ to 10⁵/g). The rhizosphere effects were minor in host plants during this period of nodule initiation and were about the same for all three serogroups. Although serogroup 123 gave no evidence of dominance in early host rhizospheres, it clearly dominated in nodule composition, occupying 60 to 100% of the nodules. High densities of all three serogroups were observed in host rhizospheres during flowering. Rhizosphere populations, especially of serogroup 123, were still high during pod fill and seed maturation. The rhizosphere responses of the R. japonicum serogroups were much greater with the soybean cultivars than with oats, but even in host rhizospheres the R. japonicum populations were greatly outnumbered by other bacteria. The success of serogroup 123 in achieving nodulation does not appear to be due to superior colonization of the host rhizosphere.     

Mineral Soils as Carriers for Rhizobium Inoculants

Mineral soil-based inoculants of Rhizobium meliloti and Rhizobium phaseoli survived better at 4°C than at higher temperatures, but ca. 15% of the cells were viable at 37°C after 27 days. Soil-based inoculants of R. meliloti, R. phaseoli, Rhizobium japonicum, and a cowpea Rhizobium sp. applied to seeds of their host legumes also survived better at low temperatures, but the percent survival of such inoculants was higher than peat-based inoculants at 35°C. Survival of R. phaseoli, R. japonicum, and cowpea rhizobia was not markedly improved when the cells were suspended in sugar solutions before drying them in soil. Nodulation was abundant on Phaseolus vulgaris derived from seeds that had been coated with a soil-based inoculant and stored for 165 days at 25°C. The increase in yield and nitrogen content of Phaseolus angularis grown in the greenhouse was the same with soil-and peat-based inoculants. We suggest that certain mineral soils can be useful and readily available carriers for legume inoculants containing desiccation-resistant Rhizobium strains.     

Molecular evidence of genetic modification of Sinorhizobium meliloti: enhanced PCB bioremediation

The genome of the nitrogen-fixing soil bacterium Sinorhizobium meliloti does not possess genes for bioremediation of aromatic pollutants. It has the well-known ability to interact specifically with the leguminous alfalfa plant, Medicago sativa. Our previous work has shown enhanced degradation of the nitroaromatic compound 2,4-dinitrotoluene (DNT) when a plasmid containing degradative genes was introduced in it. In this study we report molecular evidence of the transfer of a polychlorinated biphenyl (PCB)-biodegradative plasmid pE43 to S. meliloti strain USDA 1936. Several standard analytical tests and plant growth chamber studies were conducted to test the ability of S. meliloti to degrade 2′,3,4-PCB congener. Alfalfa plant alone was able to degrade 30% of PCBs compared with control. No enhanced dechlorination was noted when alfalfa plant was grown with wild-type S. meliloti, and when alfalfa plant was grown with the S. meliloti electrotransformants (genetically modified) dechlorination of PCBs was more than twice that when alfalfa plant was grown with wild-type S. meliloti. When alfalfa plant was grown with uncharacterized mixed culture (containing nodule formers), almost equally significant PCB degradation was observed. The significance of this work is that the naturally occurring nitrogen-fixing soil bacterium S. meliloti (genetically modified) has the ability to enhance fertility of soil in association with the leguminous alfalfa plant while simultaneously enhancing bioremediation of PCB-contaminated soils. Enhanced bioremediation of PCB and robust alfalfa plant growth was also noted when uncharacterized mixed cultures containing alfalfa plant nodule formers were used.

     

Field experiments on nitrogen fixation by nodulated legumes

Summary Phosphate increased nitrogen uptake by lucerne appreciably on a saline soil. Nitrogenous fertiliser or inoculation with an effective strain ofRhizobium meliloti did not increase the yield significantly. In soils where indigenousRhizobium japonicum was absent inoculation increased soybean yields and the additional fixed nitrogen removed by soybeans amounted to 40 to 120 kg ha⁻¹. Gram and groundnut also responded to Rhizobium inoculation in field trials.     

Establishment of Bradyrhizobium japonicum for soybean by inoculation of a preceding wheat crop

On fields with no history of soybean (Glycine max (L.) Merr.) production, inoculation alone is often inadequate to provide for adequate nodulation the first time this crop is grown. The objective of this study was to determine if inoculation of spring wheat (Triticum aestivum L.) seed with Bradyrhizobium japonicum would lead to an increase of B. japonicum numbers in the soil, and improve nodulation of a subsequent soybean crop. In the greenhouse, wheat seed inoculation increased B. japonicum numbers from undetectable numbers to >9000 g^–1 of soil, whereas the numbers of introduced B. japonicum declined in unseeded pots. In the field, inoculation of wheat seed increased B. japonicum numbers in the soil from undetectable levels to >4000 g^–1 the following year. When soybean seed was inoculated, but grown in soil devoid of B. japonicum, nodules formed only near the point of seed placement. The heaviest nodulation, and widest distribution of nodules in the topsoil were found whenB. japonicum was established the year before by wheat seed inoculation, plus soybean seed inoculation. Wheat seed inoculation the year before growing soybean, combined with proper soybean seed inoculation, should provide for abundant nodulation the first time soybean is grown on a field.