Effect of Acidity on the Composition of an Indigenous Soil Population of Rhizobium trifolii Found in Nodules of Trifolium subterraneum L.

Acidity affected which members of an indigenous soil population of Rhizobium trifolii nodulated Trifolium subterraneum L. cv. Mt. Barker. In three experiments involving plants grown either in mineral salts agar adjusted to pH 4.8 or 6.8 and inoculated with a soil suspension or grown directly in samples of unamended soil (pH 4.8) or soil amended with CaCO₃ (pH 6.4), 121 of 151 isolates of R. trifolii were placed into four serogroups. Seventy-nine of these isolates were placed into two serogroups (6 and 36) whose nodulating ability was affected by the pH of the plant root environment. Representatives of serogroup 6 occupied the greatest percentage of the nodules at the low pH in both mineral salts agar (77%) and in unlimed soil (47 and 57%). The same serogroup was a minor nodule occupant at the higher pH in mineral salts agar (0%) and in limed soil (0 and 10%). In contrast, serogroup 36 was virtually absent in nodules formed at the low pH, whereas it was the dominant serogroup at the higher pH in both mineral salts agar (32%) and in limed soil (35 and 49%). Despite the isolates from within each serogroup being antigenically identical, separation of cellular proteins by sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis revealed four and six different gel types within serogroups 6 and 36, respectively. Isolates represented by one or two gel types dominated the contribution of each serogroup to the nodule population. Further evidence for differences between isolates within each gel type were revealed from measurements of symbiotic effectiveness.     

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.     

Alfalfa,Medicago sativa L., in highly weathered,acid soils

Summary Seedlings of a broad based population of alfalfa, (Medicago sativa L.), were visually selected for 2 generations (cycles) in an acid Cecil soil (pH=4.8). Simultaneously, 2 generations of selections were made in a limed Cecil soil (pH=6.2) amended with phosphorus. When tested in acid soil (pH=4.8) with added P, the cycle 2 acid selections yielded significantly more top yield than either the limed selections or the original seed. When grown in the limed soil (pH=6.2) without added P, the acid selections yielded significantly less. There were no significant differences among selections in other soil conditions (pH=4.8, no P added and pH=6.2, P added). Root weight and length and nodule fresh weight correlated well with top yield in all treatments. The yield of the 10 parent varieties and polycrossed seed of their cycle 1 acid and cycle 1 limed selections were compared under two soil conditions (acid and limed). The results of this test indicate that some varieties were more responsive to acid soil selection than other. Overall, none of the 10 varieties showed any decreases in total top yield due to one cycle of selection in either the acid or limed soil conditions.     

Influence of Lime and Phosphate on Nodulation of Soil-Grown Trifolium subterraneum L. by Indigenous Rhizobium trifolii

Previous research had identified four serogroups of Rhizobium trifolii indigenous to the acidic Abiqua soil (fine, mixed, mesic Cumulic Ultic Haploxeroll). Nodulation of subterranean clover (Trifolium subterraneum L.) by two of the serogroups, 6 and 36, was differentially influenced by an application of CaCO₃ which raised the pH of the soil from 5.0 to 6.5. These studies were designed to characterize this phenomenon more comprehensively. Liming the soil with either CaCO₃, Ca(OH)₂, MgO, or K₂CO₃ significantly (P = 0.05) increased the percent nodule occupancy by serogroup 36, whereas the percent nodule occupancy by serogroup 6 was decreased, but the decrease was significant (P = 0.05) only after application of either CaCO₃ or Ca(OH)₂. Application of KH₂PO₄ (25 mg of P kg of soil⁻¹), which did not change soil pH, also significantly (P = 0.05) increased the percent nodule occupancy by serogroup 36. Application of KH₂PO₄ in combination with Ca(OH)₂ produced the same increase in nodule occupancy by serogroup 36 as did individual application of the two materials. Soil populations of serogroup 36 consistently, and in the majority of cases significantly (P = 0.05), outnumbered those of serogroup 6 before planting and after harvest regardless of soil treatment or the outcome of nodulation. Soil chemical and plant analyses provided no evidence that liming was simulating phosphate addition by increasing the availability and subsequent uptake of soil P_i by the subclover plants. Liming did, however, result in a significant transformation (30 to 50 mg of P kg of soil⁻¹) of P_i from the residual soil P_i fraction into an NaOH-extractable organic P fraction during the preplant equilibration period.     

Effect of pH on competition for nodule occupancy by type I and type II strains ofRhizobium leguminosarum bv.phaseoli

The effect of soil pH on the competitive abilities of twoRhizobium leuminosarum bv.phaseoli type I and one type II strains was examined in a nonsterile soil system.Phaseolus vulgaris seedlings, grown in unlimed (pH 5.2) or limed (pH 7.6) soil, were inoculated with a single-strain inoculum containing 1 × 10⁶ cells mL^–1 of one of the three test strains or with a mixed inoculum (1:1, type I vs. type II) containing the type II strain CIAT 899 plus one type I strain (TAL 182 or CIAT 895). At harvest, nodule occupants were determined. In a separate experiment, a mixed suspension (1:1, type I vs. type II) of CIAT 899 paired with either TAL 182 or CIAT 895 was used to inoculateP. vulgaris seedlings grown in sterile, limed or unlimed soil. The numbers of each strain in the rhizosphere were monitored for 10 days following inoculation. The majority of nodules (> 60%) formed on plants grown in acidic soil were occupied by CIAT 899, the type II strain. This pattern of nodule occupancy changed in limed soil. When CIAT 899 was paired with TAL 182, the type I strain formed 78% of the nodules. The number of nodules formed by CIAT 899 and CIAT 895 (56% and 44%, respectively) were not significantly different. The observed patterns of nodule occupancy were not related to the relative numbers or specific growth rates of competing strains in the host rhizosphere prior to nodulation. The results indicate that soil pH can influence which symbiotype ofR. leguminosarum bv.phaseoli will competitively nodulateP. vulgaris.     

Diversity within Serogroups of Rhizobium leguminosarum biovar viceae in the Palouse Region of Eastern Washington as Indicated by Plasmid Profiles, Intrinsic Antibiotic Resistance, and Topography

Serology, plasmid profiles, and intrinsic antibiotic resistance (IAR) were determined for 192 isolates of Rhizobium leguminosarum biovar viceae from nodules of peas (Pisum sativum L.) grown on the south slope and bottomland topographic positions in eastern Washington State. A total of 3 serogroups and 18 plasmid profile groups were identified. Nearly all isolates within each plasmid profile group were specific for one of the three serogroups. Cluster analysis of IAR data showed that individual clusters were dominated by one serogroup and by one or two plasmid profile groups. Plasmid profile analysis and IAR analysis grouped 72% of the isolates similarly. Most plasmid profile groups and several IAR clusters favored either the south slope or the bottomland topographic position. These findings show that certain intraserogroup strains possess a greater competitiveness for nodulation and/or possess a greater ability to survive in adjacent soil environments.     

Determination of prevalence and economic impact of ovine footrot in central Kashmir India with isolation and molecular characterization of Dichelobacter nodosus

The present study determines the prevalence, economic impact of virulent footrot in central Kashmir, India, along with isolation and molecular characterization of Dichelobacter nodosus (D. nodosus) where so far no such work has been carried out. Over all 12.54% prevalence of footrot was recorded in central Kashmir with highest (15.84%) in district Srinagar, and least (10.89%) in district Budgam, while it was 13.28% in district Ganderbal. Overall economic impact of footrot was estimated to the tune of Rs 15.82 million annually to the sheep farming in central Kashmir. Out of 370 samples collected from footrot lesions of naturally infected sheep, 200 (54.05%) detected D. nodosus positive by polymerase chain reaction (PCR). Out of these, 132 (66.00%) samples carried serogroup B of D. nodosus, five (2.50%) serogroup E, one (0.50%) serogroup I, while, 53 (26.50%) had mixed infection of serogroups B and E, four (2.00%) of serogroups B and I, two (1.00%) of serogroups B and G and the remaining three (1.50%) samples harboured the mixed infection of serogroups B, E and I. Serogroup G was detected for the first time in India. Over all serogroup B was most frequent (97.0%) followed by E (30.5%), while serogoups I (4.0%) and G (1.0%) were least prevalent. A total of 265 D.nodosus strains were isolated out of which 194 (73.20%) were typed as serogroup B, 61 (23.01%) as serogroup E, eight (3.01%) as serogroup I and remaining two (0.75%) belonged to serogroup G. Out of 265 D. nodosus isolates, 164 (61.88%) possessed intA (integrase) gene, thus were considered as virulent strains. Serogroup wise intA gene was found in 121(62.37%) isolates of serogroup B, 36 (59.01%) of E, two (100%) of G and five (62.50%) of I. Out of 20 randomly selected isolates subjected to gelatin gel test, 16 isolates with intA gene produced thermostable protease while four isolates without intA gene revealed the production of thermolabile protease. This indicated a good co-relation between presence of intA gene and gelatin gel test in determination of the D. nodosus virulence. Thus the present investigation suggests the incorporation of serogroups B and E, based on their predominant prevalence, in the formulation of an effective bivalent vaccine to combat footrot in central Kashmir.     

Early Infection and Competition for Nodulation of Soybean by Bradyrhizobium japonicum 123 and 138

Interactions of soybean with Bradyrhizobium japonicum 123 (serogroup 123) and 138 (serogroup c1) were used to examine the relationship between early infection rates, competition for nodulation, and patterns of nodule occupancy. Both strains formed more infections in autoclaved soil (sterile soil) than in untreated soil (unsterile soil). Inoculation did not increase numbers of infection threads in unsterile soil-grown plants, where infection of proximal portions of primary roots was complete by 5 days after planting. Both strains infected and nodulated at similar rates in sterile soil. Nodules were always clustered on the upper root system, regardless of inoculation and soil treatment. Sixty-seven percent of the nodules of uninoculated plants grown in unsterile soil were occupied by rhizobia belonging to serogroups other than 123 or c1. Inoculation with strain 123 or 138 increased occupancy by that strain at the expense of residency by other rhizobia. Eighty-three percent of all nodules on plants dually inoculated with both strains in sterile soil contained strain 138. The corresponding value for plants inoculated in unsterile soil was 31%. Neither inoculum strain dominated occupancy of first-formed nodules in unsterile soil. It appears that north central Missouri soil may not have populations of highly competitive serogroup 123 and that early infection and nodulation rates do not contribute to the competitive success of strain 138.     

Direct amplification of nodD from community DNA reveals the genetic diversity of Rhizobium leguminosarum in soil

Sequences of nodD , a gene found only in rhizobia, were amplified from total community DNA isolated from a pasture soil. The polymerase chain reaction (PCR) primers used, Y5 and Y6, match nodD from Rhizobium leguminosarum biovar trifolii , R. leguminosarum biovar viciae and Sinorhizobium meliloti . The PCR product was cloned and yielded 68 clones that were identified by restriction pattern as derived from biovar trifolii [11 restriction fragment length polymorphism (RFLP) types] and 15 clones identified as viciae (seven RFLP types). These identifications were confirmed by sequencing. There were no clones related to S. meliloti nodD . For comparison, 122 strains were isolated from nodules of white clover ( Trifolium repens ) growing at the field site, and 134 from nodules on trap plants of T. repens inoculated with the soil. The nodule isolates were of four nodD RFLP types, with 77% being of a single type. All four of these patterns were also found among the clones from soil DNA, and the same type was the most abundant, although it made up only 34% of the trifolii -like clones. We conclude that clover selects specific genotypes from the available soil population, and that R. leguminosarum biovar trifolii was approximately five times more abundant than biovar viciae in this pasture soil, whereas S. meliloti was rare.     

A Survey of Rhizobia in Farm Soils at Wye College, Kent

S ummary : Numbers of Rhizobium meliloti, R. trifolii, R. leguminosarum and R. lupini in different fields near Wye, Kent, were determined by the 'plant dilution'method. R. trifolii was most abundant, followed by R. leguminosarum , with R. meliloti and R. lupini less abundant and more restricted in their distribution. Isolates were made from nodules taken from the highest dilutions of soil that produced nodules and were tested for effectiveness in fixing nitrogen in agar tube culture. In general, isolates were effective or fairly effective. Highly effective isolates of R. trifolii were found in a very calcareous soil which had grown barley for 9 years. A permanent pasture which received higher doses of N fertilizer than other fields, contained strains of R. trifolii with a wider range of effectiveness, some giving only 50% of the dry matter production of the standard strain. The survival of R. meliloti 2001 in fields in which lucerne had not been grown for 9—14 years was studied, using a serological technique. No isolate was identified with certainty as strain 2001, but 55 of the 110 isolates tested showed some common features with this strain.     

Comparative strain typing of Rhizobium leguminosarum bv. viciae natural populations

372 natural isolates of Rhizobium leguminosarum bv. viciae, rescued from nodules of pea plants grown in an agricultural field in northern Italy, were analyzed by different methods. Three DNA-based fingerprinting techniques were lined up to compare their relative degree of resolution and possible advantages of each approach. The methods included (i) Eckhardt gel plasmid profiles, (ii) pulsed-field gel electrophoresis (PFGE) of genomic large fragment digests, and (iii) random amplified polymorphic DNA (RAPD) profiles, generated with arbitrary primers. The scheme also involved the isolation of a number of different isolates per nodule to estimate the level of intra-nodular variability. It was therefore possible to evaluate the frequency of double and multiple occupancies, and the proportion of the alternative profiles sharing the same nodule, generally resulting in a numerically dominant, main representative accompanied by a secondary one with a slightly different fingerprint. This finding revealed that the different profiles within a nodule are normally due to bacteria derived from the same single invader following genetic alterations possibly occurred during infection, e.g., by plasmid loss. The analysis of 31 nodules revealed 16 different patterns, representing the most frequently occurring nodulation-proficient isolates of the natural soil examined, five of which were found with frequencies around 15%. The sensitivity of the methods in differentiating isolates was compared. The relatedness of the different natural rhizobial isolates was investigated by densitometrical gel analysis of the fingerprints, allowing a comparison of the results. One of the most interesting conclusions was that the degree of information yielded by the plasmid gel profiling alone, carried out by simple visual inspection without software-aided analyses, was surprisingly high, as it enabled a placement of the isolates, whose accuracy, in terms of relatedness, was subsequently confirmed by each of the two genomic methods.     

Diversity and Dynamics of Indigenous Rhizobium japonicum Populations

A simple method, based upon the separation of cellular proteins by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, has been devised for distinguishing between isolates of Rhizobium japonicum. Eleven laboratory strains, previously classified into five serogroups, were analyzed by gel electrophoresis. Groups determined subjectively according to protein patterns matched the serogroups, with one exception. Most strains within serogroups could be distinguished from one another. For studying the ecology of Rhizobium, an important advantage of this technique compared with serology or phage typing is that it discriminates among previously unencountered indigenous bacterial isolates as well as among known laboratory strains. SDS-gels were used to analyze the Rhizobium population of 500 nodules, sampled throughout the growing season, from soybeans at two different Wisconsin localities. Although the soybeans had been inoculated with laboratory strains of R. japonicum, indigenous R. japonicum predominated. At one location, 19 indigenous gel types were distinguished and classified mainly into four groups. At the other location, 18 gel types, falling mainly into three groups, were detected. The predominance of a particular group varied, in some cases dramatically, depending upon the time and depth of nodule formation.     

Acetohydroxy acid synthase I, a required enzyme for isoleucine and valine biosynthesis in Escherichia coli K-12 during growth on acetate as the sole carbon source.

The fimbriae of Bacteroides nodosus play a major role in protective immunity against ovine footrot and are an important determinant in the serological classification system that divides field isolates into at least eight serogroups and 16 serotypes. Purified fimbriae contain two polypeptide antigens, the structural subunit of the fimbrial strand (molecular weight about 17,000) and a basal protein (molecular weight about 80,000), both of which exhibit structural variation. Fimbriae were prepared from all prototype strains, as well as from a number of other isolates representative of each of the B. nodosus serotypes, and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Substantial variation was observed in the electrophoretic mobility of the fimbrial subunits from the prototypes of each of the eight serogroups. With the exception of serogroup H, which is an unusual case, the apparent molecular weights of the fimbrial subunits ranged from about 16,500 in serogroup D to 19,000 in serogroup F (serotype 1); in serogroup A, B, C and E, the apparent molecular weights were clustered in the range of 17,000 to 17,500, whereas serogroup G was about 18,500. Serogroup H fimbriae appeared to consist of two smaller polypeptides, which in the prototype (H1) had apparent molecular weights of about 6,000 and 10,000 and which seem to have arisen as a consequence of an internal proteolytic nick in the original subunit. Electrophoretic variation in the fimbrial subunit was also observed between different serotypes, although with the exceptions of serogroups F and H, this was not as pronounced as between the serogroups. Examination of a number of isolates classified within the same serotypes showed that some variation, although minor, also occurred at this level. The basal antigen exhibited significant variation at all levels of the serotypic hierarchy in a manner apparently unrelated to the classification system. Among the range of isolates examined, the apparent molecular weight of this antigen varied from about 77,000 to 88,000.     

Diversity within two serogroups of Rhizobium leguminosamm native to soils in the Palouse of eastern Washington*

The effect of plant genotype, soil temperature, and moisture on recovery of Rhizobium leguminosamm serogroups WA01 and WA02 from soil, was evaluated in the greenhouse using three plant genotypes (Pisum sativum cv. Alaska, Pisum sativum cv. Paloma and Lens culinaris cv. Rechief), three temperatures (12, 20 and 24°C) and soil from two different slope positions. The impact of moisture was followed by assessing pea nodulation after incubation of soil at different preplanting moisture levels. Isolates were also evaluated for serogroup, response to low levels of antibiotics and efficacy of symbiotic characters. Of the 33 antibiotic-strain combinations showing growth, 10 permitted 50% or more of the isolates to grow. Of the 24 clusters obtained, all except one were dominated by isolates in either serogroup. WA01 or WA02. There was no relation between either serogroup or cluster groupings and N₂ fixation. Serogroup recovery was influenced by plant genotype and temperature. At root temperatures of 12 and 24°C, serogroup WA02 occurred in a significantly lower fraction of the lentil nodules as compared to the pea species. At 12°C, recovery of WA02 was higher for the Paloma than Alaska pea. Recovery of WA02 in pea nodules generally increased as the soil moisture was preconditioned to drier levels of -0.5 and -1.5 MPa water potential.     

An Ecological Study of Marked Rhizobium trifolii Strains on the Host Plant Trifolium repens var. Huai in an Acidic Peat and a Neutral Mineral Soil

An ecological study of the nodulation of Trifolium repens var. grassland Huai by genetically marked Rhizobium trifolii was carried out in two Irish soils, a neutral mineral and an acidic peat. An indigenous population of 2 x 10⁴ R. trifolii /g was found in the mineral soil. In the peat soil, 4 x 10¹ R. trifolii /g was found in the uninoculated peat. This number increased to 4.5 x 10⁵ R. trifolii /g, however, eight weeks after the peat soil was neutralized, supplemented with nutrients and sown with uninoculated clover seed. Indigenous R. trifolii strains from the mineral soil were effective whereas strains from the peat soil were ineffective on the host plant T. repens under plant room conditions. The introduced strains were inoculated on to clover seed at the rate of 1 x 10⁵ R. trifolii /seed. In the mineral soil, the introduced inoculum failed to establish at any period during the growing season. In the peat soil, the percentage establishment of the introduced inoculum varied from 40-50% of nodules selected eight weeks after sowing to 70-90% of nodules selected at the end of the growing season.     

Symbiotic Characteristics of Rhizobium leguminosarum bv. trifolii Isolates Which Represent Major and Minor Nodule-Occupying Chromosomal Types of Field-Grown Subclover (Trifolium subterraneum L.)

The symbiotic effectiveness and nodulation competitiveness of Rhizobium leguminosarum bv. trifolii soil isolates were evaluated under nonsoil greenhouse conditions. The isolates which we used represented both major and minor nodule-occupying chromosomal types (electrophoretic types [ETs]) recovered from field-grown subclover (Trifolium subterraneum L.). Isolates representing four ETs (ETs 2, 3, 7, and 8) that were highly successful field nodule occupants fixed between 2- and 10-fold less nitrogen and produced lower herbage dry weights and first-harvest herbage protein concentrations than isolates that were minor nodule occupants of field-grown plants. Despite their equivalent levels of abundance in nodules on field-grown subclover plants, ET 2 and 3 isolates exhibited different competitive nodulation potentials under nonsoil greenhouse conditions. ET 3 isolates generally occupied more subclover nodules than isolates belonging to other ETs when the isolates were mixed in 1:1 inoculant ratios and inoculated onto seedlings. In contrast, ET 2 isolates were less successful at nodulating under these conditions. In many cases, ET 2 isolates required a numerical advantage of at least 6:1 to 11:1 to occupy significantly more nodules than their competitors. We identified highly effective isolates that were as competitive as the ET 3 isolates despite representing serotypes that were rarely recovered from nodules of field-grown plants. When one of the suboptimally effective isolates (ET2-1) competed with an effective and competitive isolate (ET31-5) at several different inoculant ratios, the percentages of nodules occupied by the former increased as its numerical advantage increased. Although subclover yields declined as nodule occupancy by ET2-1 increased, surprisingly, this occurred at inoculant ratios at which large percentages of nodules were still occupied by ET31-5.     

Population Size and Distribution of Rhizobium leguminosarum bv. trifolii in Relation to Total Soil Bacteria and Soil Depth

Bacterial cells small enough to pass through 0.4-μm-pore-size filters made up 5 to 9% of the indigenous bacterial population in 0- to 20-cm-depth samples of Abiqua silty clay loam. Within the same soil samples, cells of a similar dimension were stained with fluorescent antibodies specific to each of four antigenically distinct indigenous serogroups of Rhizobium leguminosarum bv. trifolii and made up 22 to 34% of the soil population of the four serogroups. Despite the extensive contribution of small cells to these soil populations, no evidence of their being capable of either growth or nodulation was obtained. The density of soil bacteria which could be cultured ranged between 0.5 and 8.5% of the >0.4-μm direct count regardless of media, season of sampling, or soil depth. In the same soil samples, the viable nodulating populations of biovar trifolii determined by the plant infection soil dilution technique ranged between 1 and 10% of the >0.4-μm direct-immunofluorescence count of biovar trifolii. The <0.4-μm cell populations of both total soil bacteria and biovar trifolii changed abruptly between the 10- to 15-cm and 15- to 20-cm soil depth increments, increasing from 5 to 20% and from 20 to 50%, respectively, of their direct-count totals. The increase in density of the small-cell population corresponded to a significant increase in soil bulk density (1.07 to 1.21 g cm⁻³). The percent contribution of the <0.4-μm direct count to individual serogroup totals increased with soil depth by approximately 2-fold (39 to 87%) for serogroups 17 and 21 and by 12-fold (6 to 75%) for serogroups 6 and 36.     

Yersinia enterocolitica and related species isolated from wildlife in New York State.

Fecal specimens for Yersinia screening were obtained from a variety of wild mammals, birds, reptiles, fish, and invertebrates throughout New York State. One specimen from each of 1,426 animals was examined. A total of 148 isolates of Yersinia enterocolitica and related species were obtained from 133 (9.3%) of the animals. Y. enterocolitica was isolated from 100 (7%) of the animals tested, including 81 (10%) of 812 mammals and 19 (3.3%) of 573 birds. Y. intermedia, Y. frederiksenii, and Y. kristensenii were isolated from 39 (2.7%), 5 (0.35%), and 4 (0.28%) animals, respectively. The 81 Y. enterocolitica isolates from mammals belonged to 15 serogroups and included three pathogens: two isolates of typical serogroup 0:8, the "American strain," one from a gray fox (Urocyon cinereoargenteus) and one from a porcupine (Erethizon dorsatum); and one isolate of serogroup 0:3, bacteriophage type IXb, the "Canadian strain," from a gray fox. The most prevalent serogroups recovered from mammals were 0:6,31 (16 isolates) and 0:5,27 (6 isolates). The 19 isolates of Y. enterocolitica from birds belonged to nine serogroups and included one serogroup 0:6,31 isolate from a common grackle (Quiscalus quiscula) and two serogroup 0:5,27 isolates from great horned owls (Bubo virginianus).     

Yersinia enterocolitica and related species isolated from wildlife in New York State

Fecal specimens for Yersinia screening were obtained from a variety of wild mammals, birds, reptiles, fish, and invertebrates throughout New York State. One specimen from each of 1,426 animals was examined. A total of 148 isolates of Yersinia enterocolitica and related species were obtained from 133 (9.3%) of the animals. Y. enterocolitica was isolated from 100 (7%) of the animals tested, including 81 (10%) of 812 mammals and 19 (3.3%) of 573 birds. Y. intermedia, Y. frederiksenii, and Y. kristensenii were isolated from 39 (2.7%), 5 (0.35%), and 4 (0.28%) animals, respectively. The 81 Y. enterocolitica isolates from mammals belonged to 15 serogroups and included three pathogens: two isolates of typical serogroup 0:8, the "American strain," one from a gray fox (Urocyon cinereoargenteus) and one from a porcupine (Erethizon dorsatum); and one isolate of serogroup 0:3, bacteriophage type IXb, the "Canadian strain," from a gray fox. The most prevalent serogroups recovered from mammals were 0:6,31 (16 isolates) and 0:5,27 (6 isolates). The 19 isolates of Y. enterocolitica from birds belonged to nine serogroups and included one serogroup 0:6,31 isolate from a common grackle (Quiscalus quiscula) and two serogroup 0:5,27 isolates from great horned owls (Bubo virginianus).     

Effect of soil bradyrhizobia on the success of soybean inoculant strain CB 1809

Four decades of soybean [Glycine max (L.) Merr.] cultivation in South Africa has resulted in the establishment of populations of bradyrhizobia against which the recently introduced inoculant strain CB 1809 must compete. Serological and DNA fingerprinting methods were used to study the diversity of nodule isolates from soils at Bergville, Koedoeskop and Morgenzon. Dominant serogroups included Bradyrhizobium elkanii serotype 76 at Bergville (67%), Bradyrhizobium japonicum serotype 123 at Morgenzon (81%) and B. japonicum serotype 135 at Koedoeskop (100%). Their origin is unknown as they do not correspond in serotype to strains used in previous inoculants. A small percentage of isolates from Bergville (13%) and Morgenzon (16%) were serologically homologous to strain WB 1 (serotype 31/76), applied for two decades before CB 1809 (serotype 122). Nitrogen-fixing effectiveness of CB 1809 was superior to 60% of the isolates tested from Bergville and Morgenzon, but similar to 73% of the Koedoeskop isolates. Seed and liquid-in-furrow application methods increased CB 1809 nodule occupancy at least three-fold above background levels at Bergville (pH 5.16) and Morgenzon (pH 6.33). Inoculation did not, however, increase CB 1809 nodule occupancy at Koedoeskop (pH 7.76), possibly because alkaline soil conditions favoured the serotype 135 population predominant at this site.