Growth behaviour and bioproduction of indole acetic acid by a Rhizobium sp. isolated from root nodules of a leguminous tree Dalbergia lanceolaria

The Rhizobium sp. isolated from healthy and mature root nodules of a leguminous tree, Dalbergia lanceolaria Linn. f., preferred mannitol and KNO3 for growth as carbon and nitrogen sources, respectively. The bacterium produced a high amount (22.3 microg/ml) of indole acetic acid (IAA) from L-tryptophan supplemented basal medium. Growth and IAA production started simultaneously. IAA production was maximum at 20 hr when the bacteria reached the stationary phase of growth. Cultural requirements were optimized for maximum growth and IAA production. The IAA production by the Rhizobium sp. was increased by 270.8% over control when the medium was supplemented with mannitol (1%,w/v), SDS (1 microg/ml), L-asparagine (0.02%,w/v) and biotin (1 microg/ml) in addition to L-tryptophan (2.5 mg/ml). The possible role of IAA production in the symbiosis is discussed.     

Production of indole acetic acid in root nodules and culture by a Rhizobium species from root nodules of the fodder legume Melilotus alba DESR.

The root nodules of Melilotus alba DESR ., a fodder legume, contained high amounts of IAA. A tryptophan pool present in the nodule might serve as a source of IAA production. Presence of IAA oxidase and peroxidase in the nodules indicated the metabolism of IAA, at least in part, in the nodules. The Rhizobium species isolated from the root nodules produced a high amount of IAA (190 μg/ml) from L-tryptophan supplemented basal medium. IAA production and microbial growth were coincident. The production of IAA by the Rhizobium sp. was increased by 315% when the medium was supplemented with lactose (1%), NiCl₂ (10 μg/ml), cetyl pyridinium chloride (0.5 μg/ml) and glutamic acid (0.4%), in addition to L-tryptophan (3 mg/ml). The possible role of the rhizobial production of IAA on the rhizobia-legume symbiosis is discussed.     

Indole acetic acid production by a Rhizobium species from root nodules of a leguminous shrub, Cajanus cajan

A Rhizobium sp. isolated from the root nodules of a leguminous pulse-yielding shrub, Cajanus cajan, was found to produce high amounts (99.7 microg/ml) of indole acetic acid (IAA) during growth in basal medium supplemented with L-tryptophan. The Rhizobium sp. was a fast growing species which reached its stationary phase at 28 h. The IAA production could be increased upto 653.3% over control by supplementing the carbon-free incubation medium with glucose (5 g/l), NiCl2 (10 microg/ml) and glutamic acid (0.5 g/l). The possible role of rhizobial IAA on the rhizobia-legume symbiosis is discussed.     

Studies on root nodules of leguminous plants bioproduction of indole acetic acid by a Rhizobium sp. from a twiner Clitoria ternatea L.

The Rhizobium sp. isolated from the root nodules of Clitoria ternatea L., a leguminous twiner, produced a high amount of IAA (16.4 μg/ml) from tryptophan in an unsupplemented basal medium. The production of IAA started simultaneously with the growth and had no different growth and production phase. The growth and production were parallel and increased up to 45–50 h. The IAA production by the Rhizobium sp. was increased by 520% when the medium was supplemented with fructose (1.5%), MnSO₄ (1.0 μg/ml), riboflavin (0.10 μg/ml) and Triton X-100 (0.01%). The possible role of the rhizobial production of IAA on the rhizobia-legume symbiosis is discussed.     

Studies on the root nodules of leguminous plants: The production of indole acetic acid in culture by a Rhizobium sp. from a leguminous climbing shrub Derris scandens benth

The Rhizobium sp. When isolated form the root nodules of a leguminous climbing shrub Derris scandens produced a high amount of indole acetic acid (IAA) (135.2 μg/ml) from the tryptophan-supple-mented basal medium. Growth and IAA production started simultaneously, and the maximum amount of IAA was produced as a secondary metabolite in the stationary phase of growth. The IAA production by the Rhizobium sp. was increased by 503% when the medium was supplemented with mannitol (2%), KNO₃ (0.2%), nicotinic acid (0.1 μg/ml) and MnSO₄ (1 μg/ml) in addition to tryptophan (4 mg/ml)/ The possible role of the rhizobial production of IAA on the rhizobia-legume symbiosis is also discussed.     

Production and metabolism of indole acetic acid in roots and root nodules of Phaseolus mungo

The mature root nodules of Phaseolus mungo (L.), a leguminous pulse, contain higher amount of indole acetic acid (IAA) than non-nodulated roots. The tryptophan pool present in the mature nodule and young roots might serve as a precursor for the IAA production. Presence of IAA metabolising enzymes – IAA oxidase and peroxidase – indicate the metabolism of IAA in the nodules and roots. In culture, the symbiont, isolated from the nodules, produced a high amount of IAA, when tryptophan was supplied in the medium as a precursor. The symbiont preferred l-isomer over the dl- or d-isomer of tryptophan for IAA production.The important physiological implication of the IAA production in the legume-Rhizobium symbiosis is discussed.     

Indole-3-acetic acid (IAA) production by Arthrobacter species isolated from Azolla.

Arthrobacter species, isolated from the leaf cavities and the microsporocarps of the aquatic fern species Azolla pinnata and Azolla filiculoides, produced indole-3-acetic acid (IAA) in culture when the precursor tryptophan was added to the medium. No IAA production was detected in the absence of tryptophan. Maximum IAA formation was obtained in the first 2 d of incubation. Part of the tryptophan was transformed to N alpha-acetyl-L-tryptophan.     

Studies of the root nodules of leguminous plants IV: Production of indole acetic acid by a bradyrhizobium sp. from the root nodules of a leguminous shrub,crotalaria retusa L

Bradyrhizobium sp. isolated from the root nodules of a leguminous shrub, Crotalaria retusa L., produced a high amount of indole acetic acid (IAA) from tryptophan in the culture. The bacteria preferred D-isomer to the DL- or L-isomer of tryptophan for the IAA production. The IAA production could be increased up to 153.6% over control by supplementing the medium with arabinose (0.5%), ZnSO₄(0.01 μg/ml), KNO₃ (0.1%), thiamine-HCl (0.01 μg/ml) and EDTA (5 μg/ml). The possible role of the rhizobial production of IAA with the rhizobia-legume symbiosis is discussed.     

Growth inhibitory indole acetic acid polyacetylenic ester from Japanese ivy (Hedera rhombea Bean)

Polyacetylenes 1 and 2 were isolated from extracts of Japanese ivy (Hedera rhombea Bean) flower buds, with their chemical structures established on the basis of extensive 1D and 2D NMR and MS analyses. The absolute configurations of compounds 1 and 2 were determined by both chemical means, and by using the modified Mosher's method. Compound 1 is the first polyacetylene having an ester linkage between falcarindiol (3) and indole-3-acetic acid (IAA) moieties and 2 also had an unique substructure containing a conjugated diene adjacent to a hydroxy group. Polyacetylenes 1, 2, and 3 were also subjected to assessment of growth inhibition against the shoot and root growth of the monocotyledon plants, rice and perennial ryegrass, as well as the dicotyledons, cockscomb, lettuce, cress, and fenugreek. The most bioactive compound appeared to be compound 1, while 2 showed no activity. Compound 1 selectively showed growth inhibitory activity against dicotyledons.     

Optimization of indole acetic acid production by isolated bacteria from Stevia rebaudiana rhizosphere and its effects on plant growth

The ability to synthesize Indole-3-acetic acid (IAA) is widely associated with the plant growth promoting rhizobacteria (PGPR). The present work deals with isolation and characterization of such bacteria from the rhizosphere of medicinal plant Stevia rebaudiana and optimization of IAA production from its isolates. The optimization of IAA production was carried out at different pH and temperature with varied carbon and nitrogen sources of culture media. Out of different isolates obtained, three of them were screened as efficient PGPRs on the basis of different plant growth promoting attributes. Isolates CA1001 and CA2004 showed better production of IAA at pH 9 (91.7?µg?ml^?1) and at temperature 37?°C (81.7?µg?ml^?1). Dextrose (1%) was found to be the best carbon source for isolate CA1001 with 104?µg?ml^?1 IAA production. Isolate CA 2004 showed best production of IAA 36?µg?ml^?1 and 34?µg?ml^?1 at 1.5% and 1% Beef extract as nitrogen source respectively. Isolate CA 1001 showed 32?µg?ml^?1 IAA production at 0.5% nicotinic acid concentration. From the current study, CA1001 and CA2004 emerged as noble alternatives for IAA production further which also resulted in root and shoot biomass generation in crop plants, hence can be further used as bio-inoculants for plant growth promotion.     

Agrobacterium strains isolated from root nodules of common bean specifically reduce nodulation by Rhizobium gallicum

In a previous work, we showed that non-nodulating agrobacteria strains were able to colonize root nodules of common bean. Both rhizobia and agrobacteria co-existed in the infected nodules. No impact on symbiosis was found in laboratory conditions when using sterile gravel as a support for growth. In this study, soil samples originating from different geographic and agronomic regions in Tunisia were inoculated with a mixture of agrobacteria strains isolated previously from root nodules of common bean. A significant effect on nodulation and vegetal growth of common bean was observed. Characterization of nodulating rhizobia and comparison with non-inoculated controls showed a biased genetic structure. It seemed that Rhizobium gallicum was highly inhibited, whereas nodulation by Sinorhizobium medicae was favored. Co-inoculation of non-sterile soils with R. gallicum and agrobacteria confirmed these findings. In vitro antibiosis assays indicated that agrobacteria exercised a significant antagonism against R. gallicum.     

Redifferentiation of bacteria isolated from Lotus japonicus root nodules colonized by Rhizobium sp. NGR234

In most studies concerning legume root nodules, the question to what extent the nodule-borne bacteroids survive nodule senescence has not been properly addressed. At present, there is no "model system" to study these aspects in detail. Such a system with Lotus japonicus and the broad host range Rhizobium sp. NGR234 has been developed. L. japonicus L. cv. Gifu was inoculated with Rhizobium sp. NGR234 and grown over a 12 week time period. The first nodules could be harvested after 3 weeks. Nodulation reached a plateau after 11 weeks with a mean of 64 nodules having a biomass of nearly 100 mg FW per plant. Nodules were harvested and homogenized at different stages of plant development. Microscopic inspection of the extracts revealed that, typically, nodules contained c. 15x10(9) bacteroids g(-1) FW, and that about 60% of the bacteroids were viable as judged by vital staining. When aliquots of the extracts were plated on selective media, a substantial number of "colony-forming units" was observed in all cases, indicating that a considerable fraction of the bacteroids had the potential to redifferentiate into growing bacteria. In nodules from the early developmental stages, the fraction of total bacteroids yielding CFUs amounted to about 20%, or one-third of the bacteroids judged to be viable after extraction, and it increased slightly when the plants started to flower. In order to see how nodule senescence affected the survival and redifferentiation potential of bacteroids, some plants were placed in the dark for 1 week. This led to typical symptoms of senescence in the nodules such as an almost complete loss of nitrogenase activity and a considerable decrease in soluble proteins. However, surprisingly, the number of total and viable bacteroids g(-1) nodule FW remained virtually constant, and the fraction of total bacteroids yielding CFUs did not decrease but significantly increased up to 75% of the bacteroids judged to be viable after extraction. This result indicates that during nodule senescence bacteroids might be induced to redifferentiate into the state of free-living, growing bacteria.     

Indole-3-acetic acid production by bacteroids from soybean root nodules

Purine nucleotide and RNA synthesis have been investigated at the different growth stages of carrot ( Daucus carota L.) cells grown in suspension cultures. At the early growth stages an increase in the content of RNA was observed, although at later stages RNA was degraded. The highest rates of incorporation of [¹⁴C]-labelled adenosine into ATP and GTP were observed at the late growth sttages. This indicated that purine slavage was more importnt at the late growth stages, while de novo synthesis was dominant during the initial growth stages. This pattern was also reflected by increased levels, in the cell dividison phase, of theenzymes glycinamide ribonucleotide synthetase (EC 6.3.1.3.) and phosphoribosylpyrophosphate amido-transferase (EC 2.4.2.14) involved in de novo purine synthesis. The activities of the purine salvage enzymes varied little during growth. Cells in the stationary phase, that were starved for sucrose and phosphate, showed a dramatic increase in cellular metabolism, as judged from a rapid uptake and incorporation of [³²P]-labelled phosphate into nucleotides and RNA, when incubated in fresh medium.     

Comparison of geographically distant populations of Rhizobium isolated from root nodules of Phaseolus vulgaris

Seventy-two rhizobial strains were isolated from the root nodules of french beans ( Phaseolus vulgaris ). They were sampled from two geographically distant field populations and 18 additional different sites in France. They were characterized by a) plasmid profiles, (b) RFLP analysis of total cellular DNA using various chromosomal and symbiotic gene probes (including nif H from Rhizobium etli bv. phaseoli ) and c) their ability to nodulate a potential alternative host, L. leucocephala. Over half of the isolates were ascribed to Rhizobium leguminosarum bv. phaseoli on the basis of the hybridization analysis, the possession of multiple copies of nif H and their inability to nodulate L. leucocephala. The remaining isolates belonged to 2 groups which were shown to be genomically distinct from R. leguminosarum bv. phaseoli, R. etli bv. phaseoli and R. tropici. Most members of these two groups shared with R. tropici the ability to nodulate L. leucocephala and, for isolates of only one of these groups, the presence of one copy of nif H. Members of each of the 3 taxa were widely distributed in France and circumstantial evidence of pSym transfer between them was shown. R. leguminosarum bv. phaseoli and one of the two novel groups co-occurred within the two geographically distant populations. Individual genotypes were conserved between them. The finding of a third taxon at various other locations indicated additional diversity among rhizobia nodulating beans.     

Phage sensitivity and host range of Rhizobium strains isolated from root nodules of temperate legumes

Twenty-five Rhizobium strains were isolated from root nodules of Astragalus spp. (10), Hedysarum alpinum (7), Glycyrrhiza pallidiflora (3) and Ononis arvensis (5). The sensitivity of these strains to bacteriophages of Rhizobium loti, R. meliloti, R. galegae and R. leguminosarum was studied. Phages specific to R. loti strains were shown to induce the phage lysis of several Astragalus, Hedysarum and Ononis rhizobia. Ten R. loti strains tested for nodulation abilities on the plant hosts under investigation were able to develop nitrogen-fixing nodules on the Ononis arvensis roots. On the other hand, rhizobia from Ononis and Glycyrrhiza could form an effective symbiosis with Lotus corniculatus plants, so these bacteria are considered to belong to the Rhizobium loti taxon. Bacterial strains isolated from Astragalus and Hedysarum were observed to cross-nodulate their plant hosts as well as Oxytropis campestris, Glycyrrhiza uralensis and Ononis arvensis plants, whereas they could not nodulate Lotus plants. It is concluded that these Rhizobium strains comprise a cross-inoculation group related to Rhizobium loti. ei]{gnR O D}{fnDixon}     

Production of extracellular polysaccharides by a Rhizobium species from root nodules of Cajanus cajan

The ability of the Rhizobium sp., isolated from the root nodules of the leguminous pulse yielding shrub Cajanus cajan, to produce extracellular polysaccharides (EPS) was checked. A large amount of EPS (1, 128 μg/ml) was produced by the bacteria in yeast extract mannitol medium. Growth and EPS production started simultaneously, but the production reached its maximum level in the stationary phase of growth at 28 h. The EPS production by this Rhizobium sp. was much higher than by many other strains from nodules of Cajanus cajan which took a much longer time to reach maximum EPS production than this strain. The maximum EPS production (2,561 μg/ml) was obtained when the medium was supplemented with mannitol (1%), cetyl pyridinium chloride (2 μg/ml) and KNO₃ (0.2%), in which the production was increased by 276% compared to the control. The EPS production rose in the period up to 65 h with increased mannitol concentration. The EPS contained arabinose, xylose and rhamnose monomers. The possible role of rhizobial EPS production in root nodule symbiosis is discussed.     

Rhizobium indicum sp. nov., isolated from root nodules of pea (Pisum sativum) cultivated in the Indian trans-Himalayas

Three strains of rhizobia isolated from effective root nodules of pea (Pisum sativum L.) collected from the Indian trans-Himalayas were characterized using 16S rRNA, atpD and recA genes. Phylogeny of the 16S rRNA genes revealed that the newly isolated strains were members of the genus Rhizobium with ≥99.9% sequence similarity to the members within the “Rhizobium leguminosarum” group. Phylogenetic analyses based on the concatenated sequences of atpD and recA gene, and 92 core genes extracted from the genome sequences indicated that strains JKLM 12A2^T and JKLM 13E are grouped as a separate clade closely related to R. laguerreae FB206^T. In contrast, the strain JKLM 19E was placed with “R. hidalgonense” FH14^T. Whole-genome average nucleotide identity (ANI) values were 97.6% within strains JKLM 12A2^T and JKLM 13E, and less than 94% with closely related species. The digital DNA-DNA hybridization (dDDH) values were 81.45 within the two strains and less than 54.8% to closely related species. The major cellular fatty acids were C_18:1w7c in summed feature 8, C_{14:0 3OH}/C_{16:1 iso I} in summed feature 2, and C_18:0. The DNA G + C content of JKLM 12A2^T and JKLM 13E was 60.8 mol%. The data on genomic, chemotaxonomic, and phenotypic characteristics indicates that the strains JKLM 12A2^T and JKLM 13E represent a novel species, Rhizobium indicum sp. nov. The type strain is JKLM 12A2^T (= MCC 3961^T = KACC 21380^T = JCM 33658^T). However, the strain JKLM 19E represents a member of “R. hidalgonense” and the symbiovar viciae.     

Genome sequence of Rhizobium etli CNPAF512, a nitrogen-fixing symbiont isolated from bean root nodules in Brazil

Rhizobium etli is a Gram-negative soil-dwelling alphaproteobacterium that carries out symbiotic biological nitrogen fixation in close association with legume hosts. R. etli strains exhibit high sequence divergence and are geographically structured, with a potentially dramatic influence on the outcome of symbiosis. Here, we present the genome sequence of R. etli CNPAF512, a Brazilian isolate from bean nodules. We anticipate that the availability of genome sequences of R. etli strains from distinctly different areas will provide valuable new insights into the geographic mosaic of the R. etli pangenome and the evolutionary dynamics that shape it.     

Production of extracellular polysaccharides by a Rhizobium species from the root nodules of Melilotus alba

The Rhizobium sp., isolated from the root nodules of the leguminous fodder herb Melilotus alba, produced large amounts of extracellular polysaccharides (EPS) (963.5 μg/ml) in a yeast extract mannitol medium. Growth and EPS production started simultaneously, but EPS production reached its maximum during the stationary phase of growth of the bacteria, at 20 hours. EPS production was increased with all of the thirteen sugars tested. Different nitrogen sources, such as nitrates, glutamic acid, casamino acid and L-asparagine, increased the EPS production although it was inhibited by glycine, nitrite and ammonium salts. Among the vitamins and metal ions, only pyridoxal phosphate and ZnSO₄ promoted EPS production. Attempts were made to optimize the cultural requirements for growth and maximum EPS production. Maximum EPS production (1457.0 μg/ml) was obtained when the medium was supplemented with glucose (1%), pyridoxal phosphate (2 μ g/ml), ZnSO₄ × 7 H₂O (10 μg/ml) and glutamic acid (0.1%). Under these conditions, the production was increased by 254.3% compared to the control. The EPS contained arabinose, xylose and rhamnose monomers. The presence of arabinose and xylose in the EPS produced by a Rhizobium sp. was uncommon.