Denitrification ability of rhizobial strains isolated from Lotus sp.

Ten rhizobial strains isolated from Lotus sp. have been characterized by their ability to denitrify. Out of the 10 strains, the five slow-growing isolates grew well under oxygen-limiting conditions with nitrate as a sole nitrogen source, and accumulated nitrous oxide in the growth medium when acetylene was used to inhibit nitrous oxide reductase activity. All five strains contained DNA homologous to the Bradyrhizobium japonicum nirK, norBDQ and nosZ genes. In contrast, fast-growing lotus rhizobia were incapable of growing under nitrate-respiring conditions, and did not accumulate nitrous oxide in the growth medium. DNA from each of the five fast-growing strains showed a hybridization band with the B. japonicum nirK gene but not with norBDQ and nosZ genes. Partial 16S rDNA gene sequencing revealed that fast-growing strains could be identified as Mesorhizobium loti species and the slow-growers as Bradyrhizobium sp.     

Diversity in symbiotic specificity of cowpea rhizobia indigenous to Zimbabwean soils

Tropical cowpea rhizobia are often presumed to be generally promiscuous but poor N fixers. This study was conducted to evaluate symbiotic interactions of 59 indigenous rhizobia isolates (49 of them from cowpea (Vigna unguiculata)), with up to 13 other (mostly tropical) legume species. Host ranges averaged 2.4 and 2.3 legume species each for fast- and slow-growing isolates respectively compared to 4.3 for slow-growing reference cowpea strains. An average of 22% and 19% of fast- and slow-growing cowpea isolates respectively were effective on each of 12 legume species tested. We conclude that the indigenous cowpea rhizobia studied have relatively narrow host ranges. The ready nodulation of different legumes in tropical soils appears due to the diversity of indigenous symbiotic genotypes, each consisting of subgroups compatible with a limited number of legume species.     

Invalidity of the Concept of Slow Growth and Alkali Production in Cowpea Rhizobia

A total of 103 rhizobial strains representing the cowpea miscellany and Rhizobium japonicum were studied with regard to growth rate, glucose metabolic pathways, and pH change in culture medium. Doubling times ranged from 1.4 ± 0.04 to 44.1 ± 5.2 h; although two populations of “fast-growing” and “slow-growing” rhizobia were noted, they overlapped and were not distinctly separated. Twenty-four strains which had doubling times of less than 8 h all showed NADP-linked 6-phosphogluconate dehydrogenase (6-PGD) activity, whereas only one slow-growing strain (doubling time, 10.8 ± 0.9 h) of all those tested showed 6-PGD activity. Doubling times among fast growers could not be explained solely by the presence or absence of 6-PGD activity (r² = 0.14) because the tricarboxylic acid cycle and the Emden-Meyerhoff-Parnas pathway were operative in both 6-PGD-positive and 6-PGD-negative strains. Growth rate and pH change were unrelated to each other. Fast- or slow-growing strains were not associated with any particular legume species or group of species from which they were originally isolated, with the exception of Stylosanthes spp., all nine isolates of which were slow growers. We conclude that 6-PGD activity is a more distinctive characteristic among physiologically different groups of rhizobia than doubling times and that characterization of the cowpea rhizobia as slow-growing alkali producers is an invalid concept.     

Growth of Fast- and Slow-Growing Rhizobia on Ethanol

Free-living soybean rhizobia and Bradyrhizobium spp. (lupine) have the ability to catabolize ethanol. Of the 30 strains of rhizobia examined, only the fast- and slow-growing soybean rhizobia and the slow-growing Bradyrhizobium sp. (lupine) were capable of using ethanol as a sole source of carbon and energy for growth. Two strains from each of the other Rhizobium species examined (R. meliloti, R. loti, and R. leguminosarum biovars phaseoli, trifolii, and viceae) failed to grow on ethanol. One Rhizobium fredii (fast-growing) strain, USDA 191, and one (slow-growing) Bradyrhizobium japonicum strain, USDA 110, grew in ethanol up to concentrations of 3.0 and 1.0%, respectively. While three of the R. fredii strains examined (USDA 192, USDA 194, and USDA 205) utilized 0.2% acetate, only USDA 192 utilized 0.1% n-propanol. None of the three strains utilized 0.1% methanol, formate, or n-butanol as the sole carbon source.     

Metabolic versatility of haloalkaliphilic bacteria from soda lakes belonging to the Alkalispirillum–Alkalilimnicola group

Four new isolates were obtained from denitrifying enrichments with various electron donors using sediment samples from hypersaline soda lakes. Based on 16S rRNA gene analysis and DNA-DNA hybridization results, they were all identified as members of the Gammaproteobacteria closely associated with the Alkalispirillum–Alkalilimnicola group. Two isolates were obtained from samples enriched with nitrate as electron acceptor and H₂ or polysulfide as electron donors, and another two strains were obtained with N₂O as the electron acceptor and sulfide or acetate as electron donors. All four new isolates, together with the type strains of the genera Alkalispirillum and Alkalilimnicola originally described as obligate aerobes, were capable of anaerobic growth with acetate using either nitrate or N₂O as electron acceptors. Their denitrification pathway, however, was disrupted at the level of nitrite. RuBisCO form I gene was detected and sequenced in the new isolates and in Alkalilimnicola halodurans but not in Alkalispirillum mobile. These data, together with the evidence of Oremland et al. (Appl Environ Microbiol 68:4795–4802, 2002) on the potential of Alkalilimnicola sp. MLHE-1 for autotrophic growth with arsenite as electron donor and nitrate as electron acceptor, demonstrate much higher metabolic diversity of this specific group of haloalkaliphilic Gammaproteobacteria than was originally anticipated.     

Characteristics of Woodland Rhizobial Populations from Surface- and Deep-Soil Environments of the Sonoran Desert

A collection of 74 rhizobial isolates recovered from nodules of the desert woody legumes Prosopis glandulosa, Psorothamnus spinosus, and Acacia constricta were characterized by using 61 nutritional and biochemical tests. We compared isolates from A. constricta and Prosopis glandulosa and tested the hypothesis that the rhizobia from a deep-phreatic rooting zone of a Prosopis woodland in the Sonoran Desert of southern California were phenetically distinct from rhizobia from surface soils. Cluster analysis identified four major homogeneous groups. The first phenon contained slow-growing (SG) Prosopis rhizobia from surface and deep-phreatic-soil environments. These isolates grew poorly on most of the media used in the study, probably because of their requirement for a high medium pH. The second group of isolates primarily contained SG Prosopis rhizobia from the deep-phreatic rooting environment and included two fast-growing (FG) Psorothamnus rhizobia. These isolates were nutritionally versatile and grew over a broad pH range. The third major phenon was composed mainly of FG Prosopis rhizobia from surface and dry subsurface soils. While these isolates used a restricted range of carbohydrates (including sucrose) as sole carbon sources, they showed better growth on a range of organic acids as sole carbon sources and amino acids as sole carbon and nitrogen sources than did other isolates in the study. They grew better at 36°C than at 26°C. The FG Acacia rhizobia from surface-soil environments formed a final major phenon that was distinct from the Prosopis isolates. They produced very high absorbance readings on all of the carbohydrates tested except sucrose, grew poorly on many of the other substrates tested, and preferred a 36 to a 26°C incubation temperature. The surface populations of Prosopis rhizobia required a higher pH for growth and, under the conditions used in this study, were less tolerant of low solute potential and high growth temperature than were phreatic-soil isolates. SG Prosopis rhizobia from phreatic and surface soils were physiologically distinct, suggesting adaptation to their respective soil environments.     

Indigenous plasmids and cultural characteristics of rhizobia nodulating chickpeas (Cicer arietinum L.)

We examined 27 strains of chickpea rhizobia from different geographic origins for indigenous plasmids, location and organization of nitrogen fixation (nif) genes, and cultural properties currently used to separate fast- and slow-growing groups of rhizobia. By using an in-well lysis and electrophoresis procedure one to three plasmids of molecular weights ranging from 35 to higher than 380 Mdal were demonstrated in each of 19 strains, whereas no plasmids were detected in the eight remaining strains. Nitrogenase structural genes homologous to Rhizobium meliloti nifHD, were not detected in plasmids of 26 out of the 27 strains tested. Hybridization of EcoRI digested total DNA from these 26 strains to the nif probe from R. meliloti indicated that the organization of nifHD genes was highly conserved in chickpea rhizobia. The only exception was strain IC-72 M which harboured a plasmid of 140 Mdal with homology to the R. meliloti nif DNA and exhibited also a unique organization of nifHD genes. The chickpea rhizobia strains showed a wide variation of growth rates (generation times ranged from 4.0 to 14.5 h) in yeast extract-mannitol medium but appear to be relatively homogeneous in terms of acid production in this medium and acid reaction in litmus milk. Although strains with fast and slow growth rates were identified, DNA/DNA hybridization experiments using a nifHD-specific probe, and the cultural properties examined so far do not support the separation of chickpea rhizobia into two distinct groups of the classical fast- and slow-growing types of rhizobia.     

Utilization of carbon and nitrogen sources and acid/alkali production by cowpea rhizobia

Summary Sixteen slow-growing strains of rhizobia (15 cowpea rhizobia and oneR. japonicum) were examined to determine the effects of carbon and nitrogen sources on acid/alkali production in culture media. We found that the pH changes of the medium were more influenced by nitrogen sources than carbon sources (with the exception of ribose). When ammonium sulphate was used as a nitrogen source, all the cowpea rhizobia strains produced acid. When yeast-extract was used as a nitrogen source, however, a heterogenous pattern for acid/alkali production was found. The majority of the strains produced alkali from nitrate, glutamate and urea irrespective of carbon sources and acid from ribose irrespective of nitrogen sources.     

Nitrate effects on the nodulation of legumes inoculated with nitrate-reductase-deficient mutants of Rhizobium

The effect of nitrate on the symbiotic properties of nitrate-reductase-deficient mutants of a strain of cowpea rhizobia (32H1), and of a strain of Rhizobium trifolii (TA1), were examined; the host species were Macroptilium atropurpureum (DC.) Urb. and Trifolium subterraneum L. Nitrate retarded initial nodulation by the mutant strains to an extent similar to that found with the parent strains. It is therefore unlikely that nitrite produced from nitrate by the rhizobia, plays a significant role in the inhibition of nodulation by nitrate. Nitrite is an inhibitor of nitrogenase, and its possible production in the nodule tissue by the action of nitrate reductase could be responsible for the observed inhibition of nitrogen fixation when nodulated plants are exposed to nitrate. However, the results of this investigation show that nitrogen fixation by the plants nodulated by parent or mutant strains was depressed by similar amounts in the presence of nitrate. No nitrite was detected in the nodules. Nodule growth, and to a lesser extent, the nitrogenase specific activity of the nodules (mol C₂H₄g^–1 nodule fr. wt. h^–1), were both affected by the added nitrate.     

Phenotypic characteristics of root-nodulating bacteria isolated from Acacia spp. grown in Libya

Thirty isolates of root-nodulating bacteria obtained from Acacia cyanophylla, A. karroo, A. cyclops, A. tortilis (subsp.raddiana), Faidherbia albida and Acacia sp., grown in different regions of Libya, were studied by performing numerical analysis of 104 characteristics. Three fast- and one slow-growing reference strains from herbaceous and woody legumes were included. Five distinct clusters were formed. The fast-growing reference strains were separated from the isolates whereas the slow-growing was included in cluster 4. With the exception of one cluster, the majority of clusters were formed regardless of the host plant or site of origin. Based on plant tests, generation times, acid production and carbon utilization the isolates were diverse (fast and slow-growing isolates). Like slow-growing isolates, most of the fast-growing isolates appeared to be non-specific, nodulated many species from the same genus notably F. albida, known to nodulate only with slow-growing strains. Most clusters grew at temperatures 35 °C and 37 °C; some grew at temperatures above 40 °C. The majority of isolates grew at acid and alkaline pH and only one isolate grew below pH 4. Most isolates were able to utilize many amino acids as nitrogen sources and to reduce nitrate. Urea was hydrolysed by all clusters. Monosaccharides and polyols were used by slow and fast-growing isolates as the only carbon sources whereas assimilation of disaccharides varied: Some isolates, like slow-growing isolates, failed to utilize these carbon sources. Most isolates were unable to utilize polysaccharides. Regarding tolerance to NaCl on agar medium, the majority of isolates were unable to grow at a concentration of 2% NaCl, but some were highly resistant and there was one isolate which grew at 8% NaCl. Most isolates were resistant to heavy metals and to antibiotics.     

Relationships Among Rhizobia from Native Australian Legumes

Isolates from 12 legumes at three sites in Victoria showed a wide range of morphological, cultural, symbiotic, and serological properties. Isolates from Acacia longifolia var. sophorae and Kennedia prostrata were fast growing but nodulated ineffectively Macroptilium atropurpureum and all native legumes except Swainsonia lessertiifolia. Isolates from S. lessertiifolia showed anomalous properties intermediate between fast- and slow-growing rhizobia. All isolates from the other two sites were slow-growing “cowpea” rhizobia. Symbiotic effectiveness was usually poor, and there was no relationship between effectiveness and host taxonomy or serological affinities of the isolates. This is the first report of fast-growing rhizobia from temperate Australian woody legumes and the first report of the symbiotic effectiveness of native Australian legumes with indigenous rhizobia.     

Group antigens in slow-growing rhizobia

Summary Internal group antigens of several slow-growing and fast-growing Rhizobium strains were tested by gel-diffusion against antisera to three strains of Rhizobium japonicum. At least one, generally two common antigens were found in 13 strains of R. japonicum, 4 strains of R. lupini, 4 strains isolated from cowpea and two slow-growing strains isolated from Lotus. Forty-six fast-growing rhizobia (including two from Lotus and 4 from Leucaena leucocephala) were clearly distinguished from the slow-growing strains in tests with the same antisera. They were wholly negative (9) or gave a much weaker non-identical line with one antiserum (24 strains), two antisera (8) or three antisera (5). The 5 strains of agrobacteria grouped with the fast-growing rhizobia.     

Characterization of rhizobia fromLeucaena

Seventy-six rhizobia were isolated from the nodules ofLeucaena plants of various genotypes growing in a wide range of soil types and climatic regions. The isolates were fast-growing and acid-producing. In establishing a serological grouping for the isolates, the intrinsic antibiotic resistance (IAR) patterns to low concentrations of eight antibiotics was helpful for selecting the strains for immunization purposes. Eight distinct somatic serogroups ofLeucaena rhizobia were identified by using strain-specific fluorescent antibodies. The results indicated that use of serological markers is a more specific technique than IAR pattern for strain identification. Strains from some different serogroups had the same IAR patterns. The immunofluorescence cross-reactions ofLeucaena rhizobia serogroups among themselves and with other species of fast- and slow-growing rhizobia were very low. Sero-grouping is ideal for use in further ecological studies in field inoculation trials.     

Response of Lotus rhizobia to acidity and aluminium in liquid culture and in soil

Measurements of multiplication in liquid culture indicated that fast-growing Lotus rhizobia (Rhizobium loti) were tolerant of acidity and aluminium (at least 50 μM A1 at pH 4.5). Slow-growing Lotus rhizobia (Bradyrhizobium sp. (Lotus)) were less tolerant of acidity but equally tolerant of A1. Both genera were able to nodulateLotus pedunculatus in an acid soil (pH 4.1 in 0.01M CaCl₂) and the slow-growing strains were more effective than the fast-growing strains in this soil over 30 days.     

Symbiotic effectiveness and plant growh promoting traits in some Rhizobium strains isolated from Phaseolus vulgaris L.

The ability of Rhizobia to colonize roots of certain legumes and promote their growth has been proven previously. In this study the symbiotic efficiency of 47 Rhizobium strains with 6 common bean cultivars was evaluated under greenhouse condition. Fourteen strains showed the best symbiotic efficiency, whereas some isolates could not induce nodules on host plants. The ability of fourteen superior strains to solubilize phosphorus and zinc and to produce auxin, HCN and siderohores was evaluated in the laboratory assays. Rhizobium strain Rb102 produced the highest amount of auxin (14.2?mg?l^?1) in the medium containing l-tryptophan. None of the isolates were able to solubilize ZnO and ZnCO₃ on solid medium but in liquid medium some of them had negligible solubilization. The highest P solubility in liquid and solid medium was observed in strains Rb113 and Rb130, respectively. Strain Rb102 produced the highest amount of siderophores. None of the isolates were able to produce HCN. This study showed that there was a great diversity between the strains of Rhizobium in terms of their plant growth promoting traits symbiotic efficiency which supports the importance of screening rhizobia for selecting the most efficient strains. The genetic diversity of the isolates was analyzed by PCR–RFLP of the 16S rDNA. Our rhizobia were clustered into 10 groups showing high levels of diversity.     

Positive selection of antibiotic-producing soil isolates.

Stepwise discriminant analysis was used to identify the most powerful selective substrates which could be used to formulate media capable of enriching for antibiotic-producing soil isolates. This was achieved by characterizing a collection of 74 soil bacteria, including eubacteria and actinomycetes, according to their ability to produce antibacterial antibiotics and their growth responses to 43 physiological and nutritional tests. The characters which were selective for actinomycetes relative to eubacteria included growth on proline (1%, w/v) and humic acid (0.1%) as sole sources of both carbon and nitrogen, growth on nitrate as a nitrogen source, and growth at pH 7.7-8.0. Growth on proline (1%) and humic acid (0.1%) as sole carbon/nitrogen sources, growth on asparagine as a nitrogen source, and growth in the presence of vitamins were among the characteristics which allowed antibiotic-producing actinomycetes to be differentiated from non-antibiotic-producing strains. Several simple isolation media which incorporated the selective substrates identified by discriminant analysis succeeded in increasing the proportion of actinomycetes isolated from soil samples. Furthermore, the percentage of isolates capable of antibiotic production was considerably increased.     

Nitrogenase activity in pure cultures of spectinomycin-resistant fast and slow-growing Rhizobium.

Several strains of Rhizobium resistant to spectinomycin also had nitrogenase activity (C₂H₂ reduction and H₂ production) in static culture under 95% Ar/1%O₂/4%C₂H₂. This relationship between nitrogenase activity and spectinomycin resistance was observed in both fast-growing (R. trifolii and R. leguminosarum) and slow-growing (R. japonicum) rhizobia. The effect of different media and various carbon sources on nitrogenase activity was investigated in more detail in R. trifolii strain TlSp. This communication demonstrates that fast-growing rhizobia can have nitrogenase activity in the absence of any plant component.     

Effect of soil salinity level and zinc application on growth,yield, and nutrient composition of rice

Summary Physiological and symbiotic characteristics were identified in fast-growing (FG)Rhizobium japonicum. Carbon nutritional patterns linked these rhizobia to other FG rhizobia. They were able to use hexoses, pentoses, disaccharides, trioses, and organic acids for growth, but they were unable to use dulcitol or citrate. These rhizobia produced acid with all carbon sources except intermediates of the Krebs cycle. FGR. japonicum showed no vitamin requirements and were tolerant to 1% NaCl but not to 2%. They nodulated cowpea, pigeon pea, and mung bean but not peanut. Effective, nitrogen-fixing symbioses were observed only with cowpea and pigeon pea. In addition, FGR. japonicum formed effective symbioses with Asian-type soybeans. We concluded that although the physiological characteristics of FGR. japonicum were similar to other FG rhizobia, their symbiotic properties were similar to slow-growing rhizobia of the cowpea miscellany.     

Nodulation Efficiency of Legume Inoculation as Determined by Intrinsic Antibiotic Resistance

Patterns of intrinsic resistance and susceptibility to different levels of antibiotics were determined for strains of both fast- and slow-growing rhizobia. These patterns were stable to plant passage when they were used to identify Rhizobium strains in nodule suspensions or nodule isolates. The method of identification by intrinsic resistance and susceptibility patterns was reliable for identifying strains in field nodules when strains were first isolated from the nodules to provide a standard inoculum size and then typed on antibiotic-containing media. Other patterns of resistance were encountered during identification of field isolates; these patterns may have resulted from acquired resistance to certain antibiotics or from mixed infections of the nodules. The occurrence of resistance patterns identical to those of inoculant strains among native strains was directly related to the size of the soil population. High strain recovery was associated directly with high rates of inoculation.     

Medium for Enhanced Growth of Bacteria from a Swine Manure Digester

Most bacterial strains isolated from a swine manure digester grew sufficiently to permit transfer of cultures, but not characterization. Substrates, crude extracts, growth factors, and electron acceptors were evaluated for growth promotion. The growth of all but one group of the isolates was substantially increased with a medium containing glucose, cellobiose, soluble starch, pyruvate, peptone, yeast extract, minerals, volatile acids, vitamins, hemin plus vitamins K₁ and K₃, sodium bicarbonate, cysteine, and digester fluid. The strains require both known and unknown factors (in crude extracts) for maximal growth.