Siderophore production byBradyrhizobium spp. strains nodulating groundnut

EighteenBradyrhizobium spp. strains, fourRhizobium spp. strains and oneAzorhizobium caulinodans strain were grown under Fe limitation and assayed for siderophore production. It was further assessed if Fe accumulation in two groundnut cultivars was influenced by inoculant strain or nitrate fertilisation. Growth ofBradyrhizobium spp. strains nodulating groundnut was slow with mean generation times from 11–24 h. All strains, except MAR 967, showed a reduced growth rate when deprived of Fe; none of the strains showed starvation at 1 M Fe. In the CAS (chrome azurol S)-agar assay, all strains, which formed colonies, produced siderophores as visualised by orange halos around the colonies on blue plates.Bradyrhizobium strains produced much smaller halos than the referenceRhizobium meliloti strain. In the CAS-supernatant assay, all strains, except MAR 967, gave positive responses (measured as absorbance at 630 nm) when supernatants of Fe-depleted cultures were assayed with CAS-indicator complex in comparison with Fe-supplemented cultures. Responses of all fourRhizobium spp. strains were large, while responses of allBradyrhizobium strains, exceptB. japonicum MAR 1491 (USDA 110), were small and mostly insignificant. A small response, i.e. a low Fe-scavenging ability, implies either the production of small quantities of siderophores or the production of low affinity siderophores. Among theBradyrhizobium strains, MAR 1574 and MAR 1587 gave the largest responses taken over the two assays. Fe accumulation in groundnut cultivar Falcon was seven times larger than in cultivar Natal Common. No correlation was found between the quantity of nodule tissue and Fe accumulation, making it unlikely that bacteroids are involved in Fe acquisition by groundnuts. Nitrate-fertilised plants accumulated significantly more Fe, suggesting involvement of nitrate reductase in Fe assimilation in groundnut. The two most successful Fe-scavengingBradyrhizobium spp. strains were also the most effective in nodulating groundnut, the reverse also being true. Strain MAR 967, with the lowest Fe requirement, produced the largest nodule dry weight. These data indicate that improved Fe scavenging properties and/or reduced Fe requirement improve rhizospheric growth and with that nodulation effectiveness.     

Effects of a vesicular-arbuscular mycorrhizal fungus and other soil microorganisms on growth,mineral nutrient acquisition and root exudation of soil-grown maize plants

Maize (Zea mays L. cv. Alize) plants were grown in a calcareous soil in pots divided by 30-m nylon nets into three compartments, the central one for root growth and the outer ones for hyphal growth. Sterle soil was inoculated with either (1) rhizosphere microorganisms other than vesicular-arbuscular mycorrhizal (VAM) fungi, (2) rhizosphere microorganisms together with a VAM fungus [Glomus mosseae (Nicol. and Gerd.) Gerdemann and Trappel], or (3) with a gamma-irradiated inoculum as control. Plants were grown under controlled-climate conditions and harvested after 3 or 6 weeks. VAM plants had higher shootroot ratios than non-VAM plants. After 6 weeks, the concentrations of P, Zn and Cu in roots and shoots had significantly increased with VAM colonization, whereas Mn concentrations had significantly decreased. Root exudates were collected on agar sheets placed on the interface between root and hyphal compartments. Six-week-old VAM and non-VAM plants had similar root exudate compositions of 72–73% reducing sugars, 17–18% phenolics, 7% organic acids and 3% amino acids. In another experiment in which root exudates were collected on agar sheets with or without antibiotics, the amounts of amino acids and carbohydrates recovered were similar in VAM and non-VAM plants. However, threeto sixfold higher amounts of carbohydrates, amino acids and phenolics were recovered when antibiotics were added to the agar sheets. Thus, the high microbial activity in the rhizosphere and on the rhizoplane limits the exudates recovered from roots.     

Signal molecules in the peanut–bradyrhizobia interaction

Main nodulation signal molecules in the peanut–bradyrhizobia interaction were examined. Flavonoids exuded by Arachis hypogaea L. cultivar Tegua were genistein, daidzein and chrysin, the latest being released in lower quantities. Thin layer chromatography analysis from genistein-induced bacterial cultures of three peanut bradyrhizobia resulted in an identical Nod factor pattern, suggesting low variability in genes involved in the synthesis of these molecules. Structural study of Nod factor by mass spectrometry and NMR analysis revealed that it shares a variety of substituents with the broad-host-range Rhizobium sp. NGR234 and Bradyrhizobium spp. Nodulation assays in legumes nodulated by these rhizobia demonstrated differences between them and the three peanut bradyrhizobia. The three isolates were classified as Bradyrhizobium sp. Their fixation gene nifD and the common nodulation genes nodD and nodA were also analyzed. Accession numbers: AY427207, EF202193, EF158295 (16S rRNA gene of strains NLH25, NOD31 and NDEHE, respectively); DQ295199, DQ295200, DQ295201 (Partial nifD gene sequences of strains NLH25, NOD31 and NDEHE, respectively).     

The role of Rhizobium conserved and host specific nodulation genes in the infection of the non-legume Parasponia andersonii

Summary Rhizobium and Bradyrhizobium bacteria gain intercellular entry into roots of the non-legume Parasponia andersonii by stimulating localized sites of cell division which disrupt the epidermis. Infection threads are then initiated from intercellular colonies within the cortex. Infection via the information of infection threads within curled root hairs, which commonly occurs in legumes, was not observed in Parasponia. The conserved nodulation genes nodABC, necded for the curling of legume root hairs, were not essential for the initiation of infection, however, these genes were required for Parasponia prenodule development. In contrast, the nodD gene of Rhizobium strain NGR234 was essential for the initiation of infection. In addition, successful infection required not only nodD but a region of the NGR234 symbiotic plasmid which is not needed for the nodulation of legumes. Agrobacterium tumefaciens carrying this Parasponia specific region, as well as legume nod genes, was able to form nodules on Parasponia which reached an advanced stage of development.     

The potential of <Emphasis Type="Italic">Rhizobium</Emphasis> strains for biological control of <Emphasis Type="Italic">Orobanche crenata</Emphasis>

Orobanche crenata Forsk is a chlorophyll lacking holoparasite that subsists on the roots of plants and causes significant damage to the culture of leguminous plants and, in particular, to peas (Pisum sativum L.). Here, we investigated the potential of Rhizobium strains for biological control of Orobanche crenata using a commercial pea cultivar (Douce de province) and different Rhizobium strains. Firstly, benefit of bacterial inoculation on plant growth and efficiency in N-incorporation were demonstrated with four isolates, P.SOM, P.1001, P.Mat.95 and P.1236. After five Rhizobium strains (three efficient: P.SOM, P.1236, P.Mat.95 and two not efficient: P.OM1.92, P.MleTem.92) were investigated for their ability to control Orobanche crenata using pot and Petri dish experiments. Inoculation of peas with two (P.SOM and P.1236) of the five strains induced a significant decrease in O. crenata seed germination and in the number of tubercles on pea roots. Furthermore, other symptoms, including the non-penetration of the germinated seeds into pea roots followed by radicle browning and death of the parasites, were observed in the presence of these inoculated pea plants. The hypothesis that roots secrete toxic compounds related to Rhizobium inoculation is discussed.     

Nitrogen-fixing potential of micropropagated clones of Acacia mangium inoculated with different Bradyrhizobium spp. strains

Five A. mangium seedlings of different shoot lengths were selected from a 600-seed screening experiment and micropropagated. Two-week-old rooted microcuttings of the 5 micropropagated clones were inoculated with 3 specific Bradyrhizobium spp. strains in 15 combinations. After 5 months of growth, nodule dry weight and shoot dry weight data showed significant effects of clone and Bradyrhizobium spp. strain. Clones RR-G₁ and IR-M₂ and Bradyrhizobium sp. Aust13c resulted in the highest dry-matter production and most efficient nodulation. No interaction was observed between clone and Bradyrhizobium spp. strain, which indicates that the Bradyrhizobium spp. strain and the host plant can be selected separately.     

Inoculum Density and Population Dynamics of Suppressive and PathogenicStreptomycesStrains and Their Relationship to Biological Control of Potato Scab

SeveralStreptomycesstrains are capable of suppressing potato scab caused byStreptomyces scabies.Although these strains have been successful in the biocontrol of potato scab in the field, little is known about how populations of pathogenicStreptomycesin the potato rhizosphere are influenced by inoculation of the suppressive strains. The effects of inoculum densities of pathogenic and suppressiveStreptomycesstrains on their respective populations on roots and in rhizosphere soil were examined during the growing season. The relationships between inoculum density or rhizosphere population densities and disease severity were also investigated. Populations of suppressiveStreptomycesstrain 93 increased significantly on roots with increasing inoculum dose. At its highest inoculum dose, the suppressive strain reached a population density greater than 10⁶CFU/g root 14 weeks after planting. The ability of the suppressive strain to increase its populations with increasing inoculum density was hindered at high inoculum doses of the pathogen, suggesting that density-dependent competitive interactions may be occurring between the two antagonists. Strain 93 was most effective at preventing scab early in the growing season (8 weeks after planting), when tubers were most susceptible to the scab disease. Population densities of the suppressive strain in soil were more highly negatively correlated with scab severity than were populations on roots, suggesting that rhizosphere soil rather than potato roots may be the primary source of inoculum of the suppressive strain for tubers.     

Effect of Rhizobium inoculation methodologies on nodulation and growth of Leucaena leucocephala

The aim of this study was to evaluate the effect of five methods of Rhizobium inoculum application on nodulation and nitrogen fixation in Leucaena leucocephala seedlings cultivated for 6 months in the greenhouse. Plants inoculated with alginate beads were significantly more developed and more nodulated than plants inoculated with the other methodologies used.     

Attachment,colonization and proliferation ofAzospirillum brasilense andEnterobacter spp. on root surface of grasses

Root colonization studies, employing immunofluorescence and using locally isolated strains, showed thatEnterbacter sp. QH7 andEnterobacter agglomerans AX12 attached more readily to the roots of most plants compared withAzospirillum brasilense JM82. Heat treatment of either root or inoculum significantly decreased the adsorption of bacteria to the root surface. Kallar grass and rice root exudates sustained the growth ofA. brasilense JM82,Enterobacter sp. QH7 andE. agglomerans AX12 in Hoagland and Fahraeus medium. All the strains colonized kallar grass and rice roots in an axenic culture system. However, in studies involving mixed cultures,A. brasilense JM82 was inhibited byEnterobacter sp. QH7 in kallar grass rhizosphere and the simultaneous presence ofEnterobacter sp. QH7 andE. agglomerans AX12 suppressed the growth ofA. brasilense JM82 in rice rhizosphere. The bacterial colonization pattern changed from dispersed to aggregated within 3 days of inoculation. The colonization sites corresponded mainly to the areas where root mucigel was present. The area around the point of emergence of lateral roots usually showed maximum colonization.     

Host range,RFLP, and antigenic relationships betweenRhizobium fredii strains andRhizobium sp. NGR234

Rhizobium fredii is a nitrogen-fixing symbiont from China that combines broad host range for nodulation of legume species with cultivar specificity for nodulation of soybean. We have compared 10R. fredii strains withRhizobium sp. NGR234, a well known broad host range strain from Papua New Guinea. NGR234 nodulated 16 of 18 tested lugume species, and nodules on 14 of the 16 fixed nitrogen. TheR. fredii strains were not distinguishable from one another. They nodulated 13 of the legumes, and in only nine cases were nodules effective. All legumes nodulated byR. fredii were included within the host range of NGR234. Restriction fragment length polymorphisms (RFLPs) were detected with four DNA hybridization probes: the regulatory and commonnod genes,nodDABC; the soybean cultivar specificity gene,nolC; the nitrogenase structural genes, nifKDH; and RFRS1, a repetitive sequence fromR. fredii USDA257. A fifth locus, corresponding to a second set of soybean cultivar specificity genes,nolBTUVWX, was monomorphic. Using antisera against whole cells of threeR. fredii strains and NGR234, we separated the 11 strains into four serogroups. The anti-NGR234 sera reacted with a singleR. fredii strain, USDA191. Only one serogroup, which included USDA192, USDA201, USDA217, and USDA257, lacked cross reactivity with any of the others. Although genetic and phenotypic differences amongR. fredii strains were as great as those between NGR234 andR. fredii, our results confirm that NGR234 has a distinctly wider host range thanR. fredii.     

Coculture of Pachyrhizus erosus (L.) hairy roots with Rhizobium spp.

Summary We have established an in vitro system for the induction and study of nodulation in Pachyrhizus erosus (jicama) via a hairy root-Rhizobium coculture. In vitro-grown P. erosus plantlets were infected with Agrobacterium rhizogenes (ATCC No. 15834) and two hairy root lines were established. Hairy roots were grown in a split-plate system in which compartment I (CI) contained MS medium with nitrogen and different sucrose levels (0–6%), while CII held MS medium without nitrogen and sucrose. Nodule-like structures developed in transformed roots grown in CI with 2–3% surcose, inoculated with Rhizobium sp. and transferred to CII. Nodule-like structures that developed from hairy roots lacked the rigid protective cover observed in nodules from plants grown in soil. Western blot analysis of nodules from hairy roots and untransformed roots (of greenhouse-grown jicama) showed expression of glutamine synthetase leghemoglobin and nodulins. Leghemoglobin was expressed at low levels in hairy root nodules.     

Quantitative assessments of the host range and strain specificity of endophytic colonization by Klebsiella pneumoniae 342

Enteric bacteria, particularly Klebsiella, are common endophytes of plants. Endophytic colonization is important as these bacteria may be beneficial, either by providing fixed N or growth hormones to the host plant. In this work, we assessed the host range and strain specificity for endophytic colonization with Klebsiella pneumoniae 342 (Kp342) on five host plants. This strain was inoculated onto seedlings of Medicago sativa, Medicago truncatula, Arabidopsis thaliana, Triticum aestivum, and Oryza sativa. The type strain of K. pneumoniae, ATCC13883, was also inoculated on all of these hosts except M. truncatula. Both strains were labeled with GFP. Eight inoculum levels were used from 1 CFU to 10⁷ CFU per plant plus uninoculated controls. Six days after inoculation, the number of cells colonizing the rhizosphere and interior were determined. Inoculation with about one CFU of Kp342 was adequate to obtain high colonization levels on the rhizosphere and roots of all host plants. The type strain could colonize the interior of the host plant but the highest colonization levels were generally 100-fold lower than those obtained from Kp342 and those levels required at least 1000 cells in the inoculum. Thus, Kp342 was a more efficient colonizer of the plant apoplast. In addition, the monocots inoculated in this work were colonized endophytically in much higher numbers than were the dicots. Cells of Kp342 congregate at lateral root junctions suggesting the cells enter the plant through cracks created by lateral root extensions. The strain and host effects observed here suggest that endophytic colonization is an active process controlled by genetic determinants from both partners.     

A chromosomal genetic map of Rhizobium sp. NGR234 generated with Tn5-Mob

Summary Rhizobium sp. NGR234 in a fast-growing Rhizobium strain with a broad host range. The location and role of chromosomal genes involved in cellular metabolism or in the legume symbioses is unknown. We isolated a series of auxotrophic and antibiotic resistant mutants of NGR234 and utilized a chromosome mobilization system based on Tn5-Mob and pJB3JI; Tn5-Mob donor strains behaved like Hfr strains, transferring the chromosome polarly at high frequency from a fixed point of insertion. The use of four different strains with Tn5-Mob located at different nutritional loci in crosses with double auxotrophic recipients, allowed us to build up a circular linkage map of NGR234 based on relative recombination frequencies. Also, symbiotically important genes identified by site-directed mutagenesis, such as hemA and ntrA, could be located and mapped on the chromosome.Abbreviations Tc tetracycline - Sp spectinomycin - Rif rifampicin - Km kanamycin     

Molecular cloning of thentrA gene of the broad host-rangeRhizobium sp. NGR234, and phenotypes of a site-directed mutant

Summary The clonedntrA (rpoN) gene andntrA mutants ofRhizobium meliloti were used to isolate the homologous gene from the broad-host rangeRhizobium sp. NGR234 by hybridization and interspecies complementation. The NGR234 locus was analyzed by deletion and insertional mutagenesis. A site-directedntrA mutant, NGR234rn1, was made with an interposon, GmI, and its phenotype was examined ex planta and in symbiosis. NGR234rn1 formed Fix⁻ nodules on six genera tested from among its legume hosts, including both indeterminate and determinate nodule-type plants. Formation of nodules onMacroptilium was delayed, and expression of anR. meliloti nodABC-lacZ fusion was reduced by the mutant allele.     

Soil acidity in relation to groundnut-Bradyrhizobium symbiotic performance

Effects of soil acidity on groundnut-Bradyrhizobium symbiotic performance were studied in a potted, sandy soil in a glasshouse in Zimbabwe. The soil was limed to soil-pH levels of 5.0 and 6.5. Soil acidity negatively affected plant development, measured as leaf area and plant dry weight, while nodulation was enhanced. This acidity-enhanced nodulation was most evident when nodulation was caused by the indigenousBradyrhizobium population. Effects of soil acidity differed between groundnut cultivars andBradyrhizobium spp. strains, the former having greater importance. TwoArachis hypogaea L. Spanish-type cultivars, Falcon and Plover, performed equally well at neutral soil pH, but Falcon was more acid tolerant. Comparison of the symbiotic performance in neutral versus acid soil of twoBradyrhizobium spp. strains, MAR 411 (3G4b20) and MAR 1510 (CB 756), showed that MAR 411 performed superiorly in neutral soil, but MAR 1510 in acid soil. The indigenousBradyrhizobium population was more effective than was inoculation with strains MAR 411 or MAR 1510. Comparison of twelveBradyrhizobium spp. strains for their symbiotic performance in acid soil showed that some strains were totally ineffective under acidity stress (MAR 253, MAR 967 and MAR 1506), while others performed well.Bradyrhizobium spp. strain MAR 1576 (32 H1) ranked highest for nitrogen accumulation, plant dry weight and leaf area, with strains MAR 1555 (TAL 11) and MAR 1510 following closely. Nitrate fertilisation of groundnut plants led to soil alkalinisation, while nitrogen fixation resulted in soil acidification. Soil acidity in combination with soil sterilisation gave rise to symptoms associated with Al and Mn toxicity.     

Frankia in the rhizosphere of nonhost plants: A comparison with root-associated N2-fixing Enterobacter,Klebsiella and Pseudomonas

Bacterial growth in the rhizosphere and resulting changes in plant growth parameters were studied in small aseptic seedlings of birch (Betula pendula and B. pubescens) and grasses (Poa pratensis and Festuca rubra). The seedlings were inoculated with three Frankia strains (Ai1a and Ag5b isolated from native Alnus root nodules and Ai17 from a root nodule induced by soil originating from a Betula pendula stand), and three associative N₂-fixing bacteria (Enterobacter agglomerans, Klebsiella pneumoniae and Pseudomonas sp., isolated from grass roots). Microscopic observations showed that all the Frankia strains were able to colonize and grow on the root surface of the plants tested without addition of an exogenous carbon source. No net growth of the associative N₂-fixers was observed in the rhizosphere, although inoculum viable counts were maintained over the experimental period. Changes in both the biomass and morphology of plant seedlings in response to bacterial inoculation were recorded, which were more dependent on the plant species than on the bacterial strain.     

Genetic diversity and distribution of Bradyrhizobium and Azorhizobium strains associated with the herb legume Zornia glochidiata sampled from across Senegal

Herb legumes have great potential for rehabilitation of semi-arid degraded soils in Sahelian ecosystems as they establish mutualistic symbiosis with N₂-fixing rhizobia. A phylogenetic analysis was performed for 78 root nodule bacteria associated with the common Sahelian herb legume Zornia glochidiata Reichb ex DC in Senegal. Based on ITS (rDNA16S-23S) and recA sequences, these strains were shown to belong to the two genera Bradyrhizobium and Azorhizobium. Strains of this latter, although frequent, formed small and ineffective nodules and suggested a parasitism rather than a symbiotic association. A potential negative effect of Azorhizobium on Zornia growth was tested for when inoculated alone or in association with a Bradyrhizobium strain. Bradyrhizobium isolates were distributed in four groups. Groups A and B were two sister clades in a larger monophyletic group also including Bradyrhizobium liaoningense, Bradyrhizobium yuanmingense, and Bradyrhizobium japonicum. Strains of cluster D fell in a sister clade of the photosynthetic Bradyrhizobium sp. group, including ORS278, whereas group C appeared to be divergent from all known Bradyrhizobium clusters. Amplified fragment length polymorphism (AFLP) clustering was congruent with ITS and recA phylogenies, but displayed much more variability. However, within the main Bradyrhizobium clades, no obvious relationship could be detected between clustering and geographical origin of the strains. Each sub-cluster included strains sampled from different locations. Conversely, Azorhizobium strains showed a tendency in the phylogeny to group together according to the site of sampling. The predominance of ineffective Azorhizobium strains in the nodules of Zornia roots, the large Bradyrhizobium genetic diversity and the geographical genetic diversity pattern are explored.     

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}     

Biology of theParasponia-Bradyrhizobium symbiosis

Parasponia remains the only non-legume known to nodulate withRhizobium/Bradyrhizobium. It is a pioneer plant that is capable of rapid growth and fixing large quantities of nitrogen. In addition to its high agronomic potential, the symbiosis offers the scientist the unique opportunity of studying differences at the molecular level of both partners, and to investigate any possible extension of the symbiosis to other non-legumes of importance. Haemoglobin has been found in the nodule tissue ofParasponia and other nodulated non-legumes and the gene for it has been found and expressed in non-nodulating plants such asTrema tomentosa andCeltis australis. Bradyrhizobium strains isolated from species ofParasponia growing in Papua New Guinea form a group that are more specific in their host requirements thanBradyrhizobium strains from tropical legumes from the same area. They do not effectively nodulate (except CP283) tropical legumes, andParasponia is not readily nodulated withRhizobium andBradyrhizobium strains from legumes. The effectiveness of the symbiosis is influenced by host species, theBradyrhizobium strain and the environment.Parasponia andersonii forms a more effective symbiosis than the other species tested. In competition studies with strains from legumes, isolates fromParasponia always dominate in nodules onParasponia.     

Macroptilium atropurpureum (siratro) host specificity genes are linked to a nodD-like gene in the broad host range Rhizobium strain NGR234

Summary A 6.7 kb HindIII fragment from the Sym-plasmid of strain NGR234 was found to code a nodD-like gene flanked by two loci which were required for siratro host range. Transfer of the 6.7 kb fragment from NGR234 to R. trifolii strain ANU843 conferred extended host range ability to this strain on siratro plants but not to other plants normally nodulated by strain NGR234. Tn5 mutagenesis of the 6.7 kb fragment showed that insertions located into loci flanking the nodD-like gene abolished the extended host range phenotype. A hybridization probe spanning one of the host specificity loci was shown to hybridize to three specific bands in the NGR234 genome. Complementation and DNA hybridization data showed that the nodD-like gene of strain NGR234 was functionally similar to that in R. trifolii. The introduction to R. trifolii of the 6.7 kb HindIII fragment containing Tn5 insertions located in the nodD-like gene did not abolish the ability to extend the host range of R. trifolii to siratro plants. However, transfer of the 6.7 kb HindIII to R. trifolii derivatives containing Tn5 insertions into either nodA, B or C or other R. trifolii nod genes failed to confer siratro nodulation to these recipients. Reconstruction experiments showed that the 6.7 kb fragment from strain NGR234 and the 14 kb nodulation region of R. trifolii could induce the nodulation of siratro plants when introduced together into Sym-plasmid-cured Rhizobium strains.