Salt tolerance of Rhizobium species in broth cultures

Salt tolerance of five rhizobia strains was examined in broth cultures. Five levels of NaCl concentration were used and the optical density was taken as a measure for the vigour of bacterial growth. Rhizobium leguminosarum and R. meliloti were tolerant to high levels of salinity and growth curves in saline broth showed a similar pattern to the control level. Rhizobium japonicum, cowpea Rhizobium, and R. trifolii were intolerant to salt and showed a strong growth retardation with increasing salt concentration. Growth was inhibited at high levels of salinity. It is suggested that rhizobia sensitivity to salts may be partly responsible to the inhibition of nitrogen fixation by legumes growing under salt stress.     

Genetic diversity of rhizobia nodulating lentil (Lens culinaris) in Bangladesh

In order to determine the bacterial diversity and the identity of rhizobia nodulating lentil in Bangladesh, we performed a phylogenetic analysis of housekeeping genes (16S rRNA, recA, atpD and glnII) and nodulation genes (nodC, nodD and nodA) of 36 bacterial isolates from 25 localities across the country. Maximum likelihood (ML) and Bayesian analyses based on 16S rRNA sequences showed that most of the isolates (30 out of 36) were related to Rhizobium etli and Rhizobium leguminosarum. Only these thirty isolates were able to re-nodulate lentil under laboratory conditions. The protein-coding housekeeping genes of the lentil nodulating isolates showed 89.1-94.8% genetic similarity to the corresponding genes of R. etli and R. leguminosarum. The same analyses showed that they split into three distinct phylogenetic clades. The distinctness of these clades from closely related species was also supported by high resolution ERIC-PCR fingerprinting and phenotypic characteristics such as temperature tolerance, growth on acid-alkaline media (pH 5.5-10.0) and antibiotic sensitivity. Our phylogenetic analyses based on three nodulation genes (nodA, nodC and nodD) and cross-inoculation assays confirmed that the nodulation genes are related to those of R. leguminosarum biovar viciae, but clustered in a distinct group supported by high bootstrap values. Thus, our multi-locus phylogenetic analysis, DNA fingerprinting and phenotypic characterizations suggest that at least three different clades are responsible for lentil nodulation in Bangladesh. These clades differ from the R. etli-R. leguminosarum group and may correspond to novel species in the genus Rhizobium.     

Characterization of high temperature-tolerant rhizobia isolated from Prosopis juliflora grown in alkaline soil

A method was developed for the fast screening and selection of high-temperature tolerant rhizobial strains from root nodules of Prosopis juliflora growing in alkaline soils. The high-temperature tolerant rhizobia were selected from 2,500 Rhizobium isolates with similar growth patterns on yeast mannitol agar plates after 72 h incubation at 30 and 45 degrees C, followed by a second screening at 47.5 degrees C. Seventeen high-temperature tolerant rhizobial strains having distinguishable protein band patterns were finally selected for further screening by subjecting them to temperature stress up to 60 degrees C in yeast mannitol broth for 6 h. The high-temperature tolerant strains were NBRI12, NBRI329, NBRI330, NBRI332, and NBRI133. Using this procedure, a large number of rhizobia from root nodules of P. juliflora were screened for high-temperature tolerance. The assimilation of several carbon sources, tolerance to high pH and salt stress, and ability to nodulate P. juliflora growing in a glasshouse and nursery of the strains were studied. All five isolates had higher plant dry weight in the range of 29.9 to 88.6% in comparison with uninoculated nursery-grown plants. It was demonstrated that it is possible to screen in nature for superior rhizobia exemplified by the isolation of temperature-tolerant strains, which established effective symbiosis with nursery-grown P. juliflora. These findings indicate a correlation between strain performance under in vitro stress in pure culture and strain behavior under symbiotic conditions. Pure culture evaluation may be a useful tool in search for Rhizobium strains better suited for soil environments where high temperature, pH, and salt stress constitutes a limitation for symbiotic biological nitrogen fixation.     

Characterization of marine bacteria highly resistant to mercury exhibiting multiple resistances to toxic chemicals

Several strains of bacteria unusually highly resistant to mercury were isolated from seawater and marine sediment samples and identified by 16S rDNA sequencing and were also characterized by a battery of biochemical and morphological tests. The bacterial isolates were identified to belong to the genera Pseudomonas, Alcaligenes, Brevibacterium and Bacillus. Many of the chosen isolates were tested for growth in the presence of different heavy metals and a variety of xenobiotics. Growth curves of all six bacteria highly resistant to mercury examined for growth at different concentrations of Hg exhibited prolonged lag phase, during which time necessary physiological adaptations to toxic milieu were undergone. All the strains tested for antibiotic resistance showed little to no effect of antibiotics on their normal growth. Results of this study demonstrate the occurrence of diverse groups of marine prokaryotes capable of high tolerance to mercury with a potential to degrade a variety of toxic heavy metals and xenobiotics.     

Phenotypic characteristics and composition of rhizobia associated with woody legumes growing in diverse Kenyan conditions

Over 480 rhizobia were isolated from root nodules of woody legume and herbaceous trap host species grown in soils collected from 12 different Kenyan sites. The isolates were differentiated by growth and morphological characteristics, intrinsic antibiotic resistance (IAR) and salt (NaCl) tolerance levels (STL) when grown on yeast mannitol mineral salts agar and broth media.The bulk of the isolates (91%) were watery, milky-translucent and curdled milk types with moderate to copious extracellular polysaccharide (EPS). The rest were creamy or white opaque with little to moderate EPS production. Overall, they showed a wide range of growth rates: very fast-growing (mean generation time 1.6–2.5 h), fast-growing (2.8–4.8 h), intermediate between fast- and slow-growing (5.6–5.7 h) and slow- and very slow-growing (6.4–8.8 h). The isolates were tentatively grouped into Rhizobium spp., to include very fast, fast and intermediate (acid-producing) types; and Bradyrhizobium spp., to include very slow, slow and intermediate (alkali-producing) types.Bradyrhizobium spp. were more sensitive to antibiotics (40 g mL^-1) than Rhizobium spp., contrary to the general opinion which indicates that they are normally resistant. Cluster analysis based on sensitivity responses of IAR and STL could not distinguish Rhizobium spp. from Bradyrhizobium spp., neither was there any association by site nor host of isolation except for those isolates trapped with Phaseolus vulgaris at Kibwezi.Our data demonstrated a high diversity of tropical rhizobia associated with trees.     

Use of nodulation pattern, stress tolerance, nodC gene amplification, RAPD-PCR and RFLP-16S rDNA analysis to discriminate genotypes of Rhizobium leguminosarum biovar viciae

Twenty-seven new Rhizobium isolates were obtained from root nodules of wild and crop legumes belonging to the genera Vicia, Lathyrus and Pisum from different agroecological areas in central and southern Italy. A polyphasic approach including phenotypic and genotypic techniques was used to study their diversity and their relationships with other biovars and species of rhizobia. Analysis of symbiotic properties and stress tolerance tests revealed that wild isolates showed a wide spectrum of nodulation and a marked variation in stress tolerance compared with reference strains tested in this study. All rhizobial isolates (except for the isolate CG4 from Galega officinalis) were presumptively identified as Rhizobium leguminosarum biovar viciae both by their symbiotic properties and the specific amplification of the nodC gene. In particular, we found that the nodC gene could be used as a diagnostic molecular marker for strains belonging to the bv. viciae. RFLP-PCR 16S rDNA analysis confirms these results, with the exception of two strains that showed different RFLP-genotypes from those of the reference strains of R. leguminosarum bv. viciae. Analysis of intraspecies relationship among strains by using the RAPD-PCR technique showed a high level of genetic polymorphism, grouping our isolates and reference strains into six different major clusters with a similarity level of 20%. Data from seven parameters of phenotypic and genotypic analyses were evaluated by using principal component analysis which indicated the differences among strains and allowed them to be divided into seven different groups.     

Growth Tolerance of Rhizobia Isolated from Sand Dune Legumes of the Southwest Coast of India

This paper describes the properties of rhizobia from extreme soil environments which are characterized by high temperatures, salt concentrations and also rather extreme pH values due to the contamination by spray water from the sea. Coastal sand dunes are such extreme habitats which support a variety of microorganisms. To explore stress‐tolerant rhizobia, ten rhizobial strains were isolated from five wild legumes from two dune systems of the southwest coast of India. They were tested for growth performance or tolerance at a wide range of temperatures (30–55 °C), salinity (0.1–4.5 % w/v) and initial pH values (3.5–11). Growth of five isolates was highest between 30–40 °C, while four isolates showed considerable growth up to 2.5 % salinity (at 35 °C). All isolates demonstrated elevated growth at an initial pH of between 5–6 (at 35 °C and 2 % salinity), while five isolates had additional growth peaks at an initial pH of between pH 7.5–9 indicating alkaline tolerance and were suitable for efficient phosphate solubilization. The stress tolerance traits of these rhizobia are of potential value for strain improvement in agriculture or the bioremediation of soils at elevated temperatures, salinity and extreme pH values, and thus are of high biotechnological importance.     

Characterisation and differentiation of indigenous rhizobia isolated from Canarian shrub legumes of agricultural and ecological interest

In the course of a study on rhizobia nodulating six indigenous legume shrubs from the Canary Islands, one Rhizobium and 27 Bradyrhizobium Canarian isolates were characterised. It was found that those ascribed to Bradyrhizobium were promiscuous and formed effective nodules not only in their original host but on Chamecytisus proliferus subsp. proliferus (Tagasaste) as well. However, Rhizobium isolate RES-1 was more specific and only nodulated on its host (Teline canariensis). The serotyping of these isolates required a broad antisera panel due to the great antigenic diversity of these rhizobia, that appeared to be due to differences in their lipopolysaccharides, the main antigenic determinants, that showed great structural diversity. The 28 isolates studied produced 22 easily distinguishable electrophoretic profiles of lipopolysaccharides. Protein or plasmid electrophoretic profiles were equally or less discriminating than the lipopolysaccharides profiles and were more difficult to compare. The comparison of the lipopolysaccharide electrophoretic patterns is a more reliable and discriminating method than serotyping or electrophoretic protein and plasmid profile analysis for the identification of Bradyrhizobium strains. No correlation between the lipopolysaccharide profiles of the isolates and the plant from which they were obtained or their geographical origin was observed.     

Characterization of rhizobia isolated from Carob tree (Ceratonia siliqua)

Bacteria were isolated from root nodules of Carob tree (Ceratonia siliqua). We studied their cultural, physiological and biochemical characteristics. Strains showed some variability concerning tolerance to NaCl and KCl, and none grew at pHs below 7. The mean temperature for growth was 30°C and some strains could grow at 45°C. These isolates could use a great variety of carbohydrates as a sole carbon source (hexoses, pentos, disaccharides, trisaccharides, polysaccharides and organic acids). According to their cultural and physiological features and their in vitro infectivity on their original host, we suggest that these isolates may belong to the genus Rhizobium. Moreover, with regard to their average generation time, carbohydrate utilization, antibiotic resistance and other biochemical properties, they may be related to fast-growing rhizobia until further characterization.     

Genetic diversity and symbiotic compatibility among rhizobial strains and Desmodium incanum and Lotus spp. plants

This work aimed to evaluate the symbiotic compatibility and nodulation efficiency of rhizobia isolated from Desmodium incanum, Lotus corniculatus, L. subbiflorus, L. uliginosus and L. glaber plants by cross-inoculation. Twelve reference strains and 21 native isolates of rhizobia were genetically analyzed by the BOX-PCR technique, which showed a high genetic diversity among the rhizobia studied. The isolates were also characterized based on their production of indolic compounds and siderophores, as well as on their tolerance to salinity. Fifteen of the 33 rhizobia analyzed were able to produce indolic compounds, whereas 13 produced siderophores. All the tested rhizobia were sensitive to high salinity, although some were able to grow in solutions of up to 2% NaCl. Most of the native rhizobia isolated from L. uliginosus were able to induce nodulation in all plant species studied. In a greenhouse experiment using both D. incanum and L. corniculatus plants, the rhizobia isolate UFRGS Lu2 promoted the greatest plant growth. The results demonstrate that there are native rhizobia in the soils of southern Brazil that have low host specificity and are able to induce nodulation and form active nodules in several plant species.     

Relationships Amongst the Fast-growing Rhizobia of Lablab purpureus, Leucaena leucocephala, Mimosa spp., Acacia farnesiana and Sesbania grandiflora and their Affinities with Other Rhizobial Groups

Colony characteristics, growth in litmus milk, precipitation in calcium glycerophosphate medium and utilization of carbon sources of the root-nodule bacteria isolated from the tropical legumes Leucaena, Mimosa, Acacia, Sesbania and Lablab were similar to fast-growing rhizobia of temperate legumes, particularly Rhizobium meliloti. In agglutination tests, isolates from each host shared antigens with one or more of five Rhizobium strains from Leucaena. Infective characteristics of the fast-growing rhizobia were studied in modified Leonard jars and in agar culture. Cross-infections by rhizobia between these plants were common and the association often effective. Lablab was effectively nodulated by its own fast-growing isolate but only formed root swellings, possibly ineffective pseudonodules, with the other isolates. Slow-growing rhizobia which were able to nodulate Macroptilium atropurpureus were unable to form nodules on these legumes except Lablab which was considered more akin to the cowpea group. All fast-growing isolates nodulated, often effectively, Vigna unguiculata and V. unguiculata ssp. sesquipedalis. The isolate from Lablab also effectively nodulated a number of other tropical legumes which have previously only been reported to nodulate with slow-growing nodule bacteria and it also produced ineffective nodulation on Medicago sativa. This is the first record of an effective fast-growing isolate from Lablab.     

Selection for acid tolerance inRhizobium meliloti

In the selection of acid-tolerantRhizobium meliloti, procedures for the collection and isolation of rhizobia, and the assessment of acid tolerance, have not been critically evaluated. Such procedures form the basis of this study. Root nodules were collected fromMedicago spp. found growing on acid soil in Sardinia. Their encumbent bacteria were isolated directly onto media adjusted over a range of pH values, and then assessed for acid tolerance in both the laboratory and field. Strains ofRhizobium meliloti isolated onto low pH media were, in general, more acid-tolerant than sister isolates from high pH media, when tested in both the laboratory and field. Dilution (10 or 100 fold) of the inocula used in the laboratory assessment did not greatly influence the rating derived, although there was some effect of bacterial colony type on growth rating. The link between polysaccharide production and acid tolerance was not strong. There was a poor correlation between the growth ratings derived from the laboratory screening and acid tolerance as expressed in the field.     

Metabolic properties, maximum growth temperature and phage sensitivity of Rhizobium sp. (Galega) compared with other fast-growing rhizobia

Abstract Rhizobium strains nodulating Galega species were characterized by metabolic tests, maximum growth temperature determinations in a temperature gradient incubator and phage typing, and compared with other fast-growing rhizobia. By numerical taxonomy it was shown that the Galega Rhizobium strains are closely related to each other and unrelated to the recognized species of Rhizobium . The maximum growth temperature of rhizobia nodulating G. orientalis was 33.0–34.0°C and of rhizobia nodulating G. officinalis 35.0–37.0°C. The Galega rhizobia were only lysed by their own phages, and not by typing phages for other Rhizobium species. The G + C% of Rhizobium sp. ( Galega ) strainswas 63%.44 previously unclassified fast-growing rhizobia from tropical plants, which were included in the experiments, were shown to form a heterogenous group with diverse properties. The results confirm and extend previous findings, and suggest that Rhizobum sp. ( Galega ) should be considered a new species of Rhizobium .     

Growth of Indigenous Rhizobium leguminosarum and Rhizobium meliloti in Soils Amended with Organic Nutrients

The ability of indigenous Rhizobium leguminosarum and Rhizobium meliloti to use organic nutrients as growth substrates in soil was assessed by indirect bacteriophage analysis. A total of 17 organic compounds, including 9 carbohydrates, 3 organic acids, and 5 amino acids, were tested (1,000 μg g⁻¹) in three soils with different cropping histories. Four additional soils were screened with a glucose amendment. Nutrient amendments stimulated growth of indigenous rhizobia, allowing subsequent replication of indigenous bacteriophages. Phage populations were enumerated by plating soil extracts on 19 R. leguminosarum and 9 R. meliloti indicator strains, including root nodule isolates from the soils assayed. On the basis of indirect phage analysis, all soils contained native rhizobia similar to one or more of the indicator strains, although not all indicator strains were detected in soil. All organic compounds stimulated growth of indigenous rhizobia, but the growth response varied for each rhizobial strain depending on the nutrient, the nutrient concentration, and the soil. Indigenous rhizobia readily utilized most organic compounds except phenylalanine, glycine, and aspartic acid. The ability of indigenous rhizobia to utilize a wide range of organic compounds as growth substrates in situ indicates their ability to successfully compete with other soil bacteria for nutrients in these soils.     

Diversity among Rhizobia Effective with Robinia pseudoacacia L

The diversity of rhizobia that form symbioses with roots of black locust (Robinia pseudoacacia L.), an economically important leguminous tree species, was examined by inoculating seedling root zones with samples of soil collected from the United States, Canada, and China. Bacteria were isolated from nodules, subcultured, and verified to be rhizobia. The 186 isolates varied significantly in their resistance to antibiotics and NaCl, their growth on different carbohydrates, and their effect on the pH of culture media. Most isolates showed intermediate antibiotic resistance, the capacity to use numerous carbohydrates, and a neutral to acid pH response. Isolates had greater similarity within sampling locations than among sampling locations. The isolates were grouped by using numerical taxonomy techniques, and representative strains of 37 groups were selected. The mean generation times of these isolates ranged from 3 to 9 h, and the protein profile of each of the 37 isolates was unique. Nitrogen fixation, total nitrogen accumulation, and plant growth varied significantly among black locust seedlings inoculated with the representative isolates. We conclude that great variation exists among Rhizobium spp. that nodulate black locust, and selection of strains for efficiency of the symbiotic association appears possible.     

Diverse genomic species and evidences of symbiotic gene lateral transfer detected among the rhizobia associated with Astragalus species grown in the temperate regions of China

Based on the analyses of ribosomal DNA and housekeeping genes, a total of 118 bacterial isolates obtained from 13 Astragalus species grown in the temperate region of China were identified as 19 genomic species of Mesorhizobium, Rhizobium, Sinorhizobium and Bradyrhizobium, two of them being putatively new species. Phylogenetic comparison of symbiotic genes (nodC and nifH) and housekeeping genes showed that the symbiotic genes of the Astragalus rhizobia were maintained by both vertical and horizontal transfer. The results demonstrated that the Astragalus species were very promiscuous hosts for rhizobia and that their rhizobia had very diverse genomic and symbiotic gene backgrounds.     

Multiple antibiotic resistances in metal tolerant E. coli from hospital waste water

Study of antibiotic resistance was done among the metal tolerant E. coli isolates from hospital wastewater at Lucknow city. Metal tolerance was determined in terms of visible growth on metal amended plates at their varying concentrations. MICs were also determined among all metal tolerant E. coli isolates. All the isolates showed their MIC in between 100-2000 µg/ml while maximum isolates demonstrated their MICs at 400, 800 and 1600 µg/ml against all the metal tested. 23.07% of the isolates showed their MIC at 2000 µg/ml against Ni³⁺. Multiple antibiotic resistances were recorded among all the metal resistant E.coli isolates. A high level of resistance was observed against Methicillin (86.53%) followed by penicillin (73.07%), Cephradin (57.69%), Rifampicin (34.61%), Erythromycin (26.92%), Nalidixic acids (25%), Chloramphenicol (3.84%) and least to Gentamycine (1.92%). Streptomycin was recorded most effective against E.coli isolates among the entire antibiotic tested. Antimicrobial resistance observed among the bacteria from the aquatic system contaminated with hospital wastes may be threatful for the environment and public health both.     

Genetic diversity of rhizobia isolated from Caragana intermedia in Maowusu sandland,north of China

AIMS: Thirty-three rhizobial strains isolated from nodules of Caragana intermedia in Maowusu sandland were examined for their genetic diversity and putative phylogenetic position. METHODS AND RESULTS: Isolates from Caragana intermedia were classified into 12 genotypes by 16S rDNA polymerase chain reaction-restriction fragment length polymorphism (RFLP), which showed no distinct relationships with those of the reference strains. The genotypes of rhizobia were not related to geographical location. Thr 16S rDNA sequence of representative strain GH2001 from dominant genotype 2 shared high homologuey with some Rhizobium species: Rh. giardinii (96.4%), Rh. huautlense (95.3%), Rh. galegae (95.7%), Rh. yanglingense (95.2%), Rh. mongolense (95.6%), Rh. radiobacter (99%) and Rh. rubi (98.3%). CONCLUSIONS: A high degree of genetic diversity existed among rhizobia nodulating Caragana intermedia in Maowusu sandland. Most of the new isolates might belong to Rhizobium. SIGNIFICANCE AND IMPACT OF THE STUDY: The results suggest that the rich diversity of rhizobia might have contributed to the adaptation of the arid region. These strains could be valuable at the economic and ecosystem level.     

Effect of Aldrin on Growth and Oxidative Metabolism of Rhizobia

At 500 μg ml⁻¹ of aldrin, Rhizobium sp. Bengal gram ( Cicer arietinum ) and Rhizobium sp. Green gram (Vigna radiata ) showed a lag of about 12 h after which the growth returned to normal. The lag period was extended at concentrations above 500 μg ml⁻¹ of aldrin and it was more in the case of Rhizobium sp. Green gram than Rhizobium sp. Bengal gram. However, at high concentrations of aldrin, after the lag, the growth rate was very slow. On the seventh day, Rhizobium sp. Bengal gram showed 72, 81 and 84° inhibition while Rhizobium sp. Green gram exhibited 74, 85 and 88° inhibition of growth at 1000, 1500 and 2000 μg ml⁻¹ of aldrin, respectively. In general, oxidative activity of both of the Rhizobium spp. on pentoses, hexoses and TCA cycle intermediates was more strongly inhibited in aldrin grown cells than normal cells. The inhibitory effect of aldrin on the oxidative activity of rhizobia was partially released with a high concentration of glucose.