Glomeromycota communities survive extreme levels of metal toxicity in an orphan mining site.

Abandoned tailing basins and waste heaps of orphan mining sites are of great concern since extreme metal contamination makes soil improper for any human activity and is a permanent threat for nearby surroundings. Although spontaneous revegetation can occur, the process is slow or unsuccessful and rhizostabilisation strategies to reduce dispersal of contaminated dust represent an option to rehabilitate such sites. This requires selection of plants tolerant to such conditions, and optimization of their fitness and growth. Arbuscular mycorrhizal fungi (AMF) can enhance metal tolerance in moderately polluted soils, but their ability to survive extreme levels of metal contamination has not been reported. This question was addressed in the tailing basin and nearby waste heaps of an orphan mining site in southern France, reaching in the tailing basin exceptionally high contents of zinc (ppm: 97,333 total) and lead (ppm: 31,333 total). In order to contribute to a better understanding of AMF ecology under severe abiotic stress and to identify AMF associated with plants growing under such conditions, that may be considered in future revegetation and rhizostabilisation of highly polluted areas, nine plant species were sampled at different growing seasons and AMF root colonization was determined. Glomeromycota diversity was monitored in mycorrhizal roots by sequencing of the ribosomal LSU. This first survey of AMF in such highly contaminated soils revealed the presence of several AMF ribotypes, belonging mainly to the Glomerales, with some examples from the Paraglomerales and Diversisporales. AMF diversity and root colonization in the tailing basin were lower than in the less-contaminated waste heaps. A Paraglomus species previously identified in a polish mining site was common in roots of different plants. Presence of active AMF in such an environment is an outstanding finding, which should be clearly considered for the design of efficient rhizostabilisation processes.

Early modifications of Brassica napus root system architecture induced by a plant growth-promoting Phyllobacterium strain.

• Plant growth-promoting bacteria (PGPB) have been reported to stimulate root morphogenesis. To improve our knowledge of the PGPB effect, the early modifications of Brassica napus root system architecture induced by the PGPB Phyllobacterium sp. (29-15) were analysed. • Plants were grown in Petri dishes on a vertical medium supplemented with variable doses of Phyllobacterium sp. in gnotobiotic conditions. Root system elementary variables were measured in a nondestructive manner and the distribution of the bacteria throughout the primary root was quantified. • Phyllobacterium sp. in doses from 3 × 107 to 3 × 108 colony-forming units ml-1 significantly promoted B. napus total root length up to 50% by increasing both lateral root density throughout the primary root and growth rate of mature lateral roots. The primary root was progressively colonized by the bacteria from the tip to the base and the number of colonizing cells was positively correlated with the inoculum density. • Relationships between inoculum density, root colonization and root system architecture emphasized the relevance of this approach to specify PGPB effects on plants.

Stimulation of the ionic transport system in Brassica napus by a plant growth-promoting rhizobacterium (Achromobacter sp.).

A plant growth-promoting rhizobacterium belonging to the genus Achromobacter was isolated from the oil-seed-rape (Brassica napus) root. Growth promotion bioassays were performed with oilseed rape seedlings in a growth chamber in test tubes containing attapulgite and mineral nutrient solution, containing NO3- as N source. The presence of this Achromobacter strain increased shoot and root dry weight by 22-33% and 6-21%, respectively. Inoculation of young seedlings with the Achromobacter bacteria induced a 100% improvement in NO3- uptake by the whole root system. Observations on the seminal root of seedlings 20 h after inoculation showed that there was an enhancement of both the number and the length of root hairs, compared to non-inoculated seedlings. Electrophysiological measurements of NO3- net flux with ion-selective microelectrodes showed that inoculation resulted in a specific increase of net nitrate flux in a root zone morphologically similar in inoculated and non-inoculated plants. The root area increased due to root hair stimulation by the Achromobacter bacteria, which might have contributed to the improvement of NO3- uptake by the whole root system, together with the enhancement of specific NO3- uptake rate. Moreover, inoculated plants showed increased potassium net influx and proton net efflux. Overall, the data presented suggest that the inoculation of oilseed-rape with the bacteria Achromobacter affects the mineral uptake.

Rapid identification of Medicago nodulating strains by using two oligonucleotide probes complementary to 16S rDNA sequences.

Symbiotic bacteria associated with the Medicago genus are separated into two closely related species named Sinorhizobium meliloti and Sinorhizobium medicae. To discriminate rapidly between these two bacterial species, two 15-base DNA probes, 16Smfs and 16Smed, were designed from the alignment of 16S rDNA sequences to differentiate S. meliloti from S. medicae. Their specificities were evaluated by dot-blot hybridization experiments on 25 reference strains representing 13 species of Rhizobium and Sinorhizobium, and by comparison with all 16S rDNA sequences available in the GenBank data base. No cross-reaction was found with 16Smed, which was thus considered species specific for S. medicae. By contrast, as expected according to the 16S rDNA sequence alignment, the labeled 16Smfs probe cross-hybridized with the DNAs of S. meliloti, Sinorhizobium fredii, and Sinorhizobium saheli but not with the DNA of S. medicae. Since S. saheli and S. fredii do not nodulate Medicago, 16Smed and 16Smfs can be routinely used to characterize the two Sinorhizobium species nodulating Medicago from pure cultures or from Medicago root nodules. Fifty strains isolated from eight annual Medicago species were then characterized by using colony hybridizations. Sinorhizobium meliloti was more frequently obtained (> 80% isolates) than was S. medicae. Both Sinorhizobium species seemed to be trapped by annual Medicago and no plant-host specificity was detected.

Sinorhizobium medicae sp. nov., isolated from annual Medicago spp.

The taxonomic position of isolates of a new genomic species (designated genomic species 2) obtained from several annual Medicago species and originating from different geographical locations was established through the results of phenotypic tests (including the results of auxanographic and biochemical tests and symbiotic properties) and 16S rRNA phylogenetic inferences. A comparison of the complete 16S rRNA sequence of a representative of genomic species 2 (strain A 321T [T = type strain]) with the 16S rRNA sequences of other members of the Rhizobiaceae and closely related taxa showed that genomic species 2 was phylogenetically related to Sinorhizobium meliloti, Sinorhizobium fredii, Sinorhizobium saheli, and Sinorhizobium teranga. The levels of sequence similarity and observed numbers of nucleotide substitutions in Sinorhizobium strains indicated that A 321T and S. meliloti exhibited the highest level of sequence similarity (99.7%), with four nucleotide substitutions and one deletion. The results of a numerical analysis based on data from 63 auxanographic and biochemical tests clearly separated genomic species 2 isolates from S. meliloti. Genomic species 2 isolates nodulated and fixed nitrogen with Medicago polymorpha, whereas S. meliloti isolates were ineffective and formed rudimentary nodules on this host plant. On the basis of phenotypic and 16S sequence analysis data, genomic species 2 isolates cannot be assigned to a previously described species. We propose that these isolates belong to a new species, Sinorhizobium medicae.

Evidence that two genomic species of Rhizobium are associated with Medicago truncatula.

Seventy-three isolates of rhizobia sampled from root nodules of Medicago truncatula were analyzed by restriction fragment length polymorphism (RFLP) of DNA regions amplified by the polymerase chain reaction (PCR) targeting the symbiotic plasmid (nifD-K, nodD1, and nodD2 genes) and the chromosome (16S rDNA plus intergenic spacer). Two genotypic groups were found, regardless of the DNA region targeted. These two groups were given the status of genomic species based on results of DNA/DNA hybridization.

Genomic heterogeneity of strains nodulating chickpeas (Cicer arietinum L.) and description of Rhizobium mediterraneum sp. nov.

The genetic diversity of chickpea strains was studied by using 30 isolates obtained from nodules on chickpeas growing in uninoculated fields over a wide geographic range. The following taxonomic approaches were used: DNA-DNA relatedness analysis, restriction fragment length polymorphism analysis of the amplified 16S ribosomal DNA (rDNA) intergenic spacer (IGS), and total 16S rRNA sequence analysis. The division of chickpea-infective strains into two major phylogenetic groups (groups A and B) that has been described previously was confirmed by the polymorphism of the 16S IGS rDNA. We identified a total of five genomic species, including the previously described species Rhizobium ciceri. All of the group B strains except one were homogeneous and belonged to a single genomic species corresponding to R. ciceri. Group A was heterogeneous, containing three genomic species and five strains that remained unclassified, and its members had very different PCR restriction fragment length polymorphism profiles. The complete 16S rRNA sequences of strains representing the two major groups, R. ciceri UPM-Ca7T (T = type strain) and genomic species 2 strain UPM-Ca36T, exhibited 19 mismatches. Both of these strains belonged to the Rhizobium loti-Rhizobium huakuii branch; R. ciceri UPM-Ca7T was closely related to R. loti, and strain UPM-Ca36T was clearly separated from R. ciceri and closely related to R. huakuii. Thus, genomic species 2 could be distinguished from R. ciceri by its 16S rRNA sequence, by DNA relatedness data, by the polymorphism of the 16S IGS rDNAs, and by previously described multilocus enzyme electrophoresis results and phenotypic characteristics. Therefore, we propose that strains belonging to genomic species 2 should be classified in a new species, Rhizobium mediterraneum, and that strain UPM-Ca36 should be the type strain.

Degradation of iprodione by a soil Arthrobacter-like strain.

A bacterial strain able to transform iprodione was isolated from a fast iprodione-degrading soil by enrichment procedures. Transformation was detected through 3,5-dichloroaniline production as measured by a rapid colorimetric method. The strain, MA6, was tentatively identified as an Arthrobacter sp. When it was incubated with MA6 in a minimum mineral medium (pH 6.5), iprodione (8.8 mumol/liter) was transformed into two major metabolites that were identified by high-performance liquid chromatography analysis: 3,5-dichlorophenylcarboximide (metabolite 1) and (3,5-dichlorophenylurea) acetic acid (metabolite 2), which was produced after ring cleavage of the former product. These products were synthesized in the laboratory and compared with metabolites 1 and 2 which were formed during iprodione degradation. Small quantities of 3,5-dichloroaniline also appeared in the bacterial culture but did not substantially increase between the first and second days of incubation. In contrast, in the sterile control medium, iprodione was spontaneously transformed into hydantoic acid and an iprodione isomer. Chemical and biological transformations of iprodione seem to occur through two different pathways. One biological degradation pathway is proposed.

Rhizobium ciceri sp. nov., consisting of strains that nodulate chickpeas (Cicer arietinum L.).

The taxonomic status of 16 collection strains of chickpea (Cicer arietinum L.) rhizobia which were previously determined to belong to two groups (groups A and B) were compared with reference strains belonging to different genera and species of the family Rhizobiaceae. We used the following taxonomic, phylogenetic, and phenotypic characteristics and approaches to study these organisms: DNA homology, guanine-plus-cytosine content, restriction fragment length polymorphism of the amplified 16S-intergenic spacer rRNA gene, partial 16S rRNA sequencing, and auxanographic tests performed with 147 carbon sources. Similar groups of chickpea strains were identified by the different approaches. The chickpea strains were found to belong to the genus Rhizobium regardless of the phylogenetic group to which they belonged (group A or B). All strains fell into a tight cluster which included Rhizobium loti and Rhizobium galegae, and the group B strains were closely related to R. loti. An analysis of partial 16S ribosomal DNA sequences revealed identical nucleotide sequences for the slowly growing strains and fast-growing strains that were used as representatives of groups A and B, respectively, and these organisms fell into the Rhizobium-Agrobacterium lineage. When the sequences of these organisms were compared with the partial sequences of Rhizobium huakuii and R. loti, one- and two-nucleotide mismatches were observed, respectively, indicating that the chickpea rhizobia are closely related to these two species. The DNA-DNA hybridization data revealed that the chickpea rhizobia exhibited low levels of homology (less than 17%) to previously described Rhizobium and Bradyrhizobium species. Moreover, when we compared chickpea strains to R. loti and R. huakuii, the most closely related species as determined by the partial 16S rRNA sequence analysis, the homology values ranged from 21 to 52% and the delta Tm values were greater than 5 degrees C (delta Tm is the difference between the denaturation temperatures of the heterologous and homologous duplexes). These results confirmed that the rhizobia that nodulate chickpeas cannot be assigned to a previously described species. Within the chickpea rhizobia, the DNA homology values obtained when members of groups A and B were compared were less than 38%, indicating that the group A and group B organisms belong to different species. Furthermore, these organisms can be distinguished from each other by the results of phenotypic tests. We propose that the group B chickpea rhizobia should be assigned to a new species, Rhizobium ciceri; UPM-Ca7 is the type strain of R. ciceri.

Genotypic and phenotypic diversity of Rhizobium isolated from chickpea (Cicer arietinum L.).

The diversity of 16 strains of chickpea-infective rhizobia from various geographical origins was analysed using genotypic and phenotypic approaches. Multilocus enzyme electrophoresis was performed, and restriction fragment length polymorphisms of the amplified 16S + IGS (intergenic spacer) rRNA gene, assimilation of 147 carbon sources, antibiotic resistance, and tolerance to NaCl and extreme pH values and temperatures were tested. These approaches had different discriminating powers. Esterase polymorphisms gave a unique pattern for each strain, allowing this method to be used for strain fingerprinting. Genetic distances between strains were estimated. The three approaches used in this study yielded consistent results. They evidenced high heterogeneity among the strains, and made it possible to classify the strains into two clusters. Isozyme patterns for superoxide dismutase were particularly interesting, since they delineated the same two groups. The phenotypic tests clearly confirmed the existence of two genetic groups on the basis of 11 phenotypic characters. Owing to the large phylogenetic distance between the two groups of strains, the taxonomic status of chickpea-infective strains is discussed.

Purification, properties and partial amino-acid sequence of 1-aminocyclopropane-1-carboxylic acid oxidase from apple fruits.

The enzyme which converts 1-aminocyclopropane-1-carboxylic acid (ACC) into ethylene, ACC oxidase, has been isolated from apple fruits (Malus x domestica Borkh. cv. Golden Delicious), and for the first time stabilized in vitro by 1,10-phenanthroline and purified 170-fold to homogeneity in a five-step procedure. The sodium dodecyl sulfate-denatured and native proteins have similar molecular weights (approx. 40 kDa) indicating that the enzyme is active in its monomeric form. Antibodies raised against a recombinant ACC oxidase over-produced in Escherichia coli from a tomato cDNA recognise the apple-fruit enzyme with high specificity in both crude extracts and purified form. Glycosylation appears to be absent because of (i) the lack of reactivity towards a mixture of seven different biotinylated lectins and (ii) the absence of N-linked substitution at a potential glycosylation site, in a sequenced peptide. Phenylhydrazine and 2-methyl-1-2-dipyridyl propane do not inhibit activity, indicating that ACC oxidase is not a prosthetic-heme iron protein. The partial amino-acid sequence of the native protein has strong homology to the predicted protein of a tomato fruit cDNA demonstrated to encode ACC oxidase.

Electrophoretic and immunological studies on acid phosphatase from a mycorrhizal fungus of Erica hispidula L.

Wall-bound acid phosphatases of an endomycorrhizal fungus of Erica hispidula L. were separated by PAGE, electrotransferred to nitrocellulose membranes and glycoprotein characteristics studied using Concanavalin A. An antiserum was raised against the major high-molecular-weight acid phosphatase and its specificity demonstrated by immunoblotting and ELISA. The antiserum reacted very little with protein extracts of other cellular fractions and was unable to bind to wall-bound protein antigens of a mycorrhizal isolate from K. mauritanica. Ultrastructural localization of acid phosphatase by cytoenzymology and indirect immunogold labelling showed it to be almost exclusively associated with the fungal wall and septa of living hyphae, whilst in senescent hyphae it was also present within the disorganized cytoplasm.

Preparation by two-dimensional electrophoresis of proteins for antibody production: antibodies against proteins whose synthesis is reduced by auxin in tobacco mesophyll protoplasts.

Using phenol extraction from tobacco callus, we have prepared extracts with a high protein content. These proteins were separated in cylindrical non-equilibrium pH gradient gels and visualized by dipping in sodium dodecyl sulfate (SDS)-containing solution. Three gel sections, each containing proteins previously detected as abundantly synthesized in tobacco mesophyll protoplasts and whose synthesis is reduced by auxin application, were excised from each gel and collected. These proteins were further separated on slab SDS gels and protein bands were excised after Coomassie Brilliant Blue R-250 staining and used to inject three rabbits. After one booster, highly specific antibodies were detected in their sera by ELISA and immunoblotting. Using these sera we have confirmed that the corresponding proteins are identical in callus and mesophyll protoplast and demonstrated that they are abundantly accumulated in tobacco roots but are undetectable in aerial organs and seeds.

Stability of Bradyrhizobium japonicum Inoculants after Introduction into Soil.

Bradyrhizobium japonicum USDA 125-Sp, USDA 138, and USDA 138-Sm had been used as inoculants for soybean (Glycine max (L.) Merr.) in soils previously free of B. japonicum. At 8 to 13 years after their release, these strains were reisolated from soil samples. A total of 115 isolates were obtained through nodules, and seven colonies were obtained directly by a serological method. The stability of the inoculants was confirmed by comparing the reisolated cultures with their respective parental strains which had been preserved by being lyophilized or stored on a yeast extract-mannitol agar slant at 4 degrees C. Comparisons were made on morphological and serological characters, carbon compound utilization (8 tested), intrinsic antibiotic resistance (9 tested), and enzymatic activity (19 tested). Mucous and nonmucous isolates of serogroup 125 were analyzed for symbiotic effectiveness and restriction fragment hybridization with a DNA probe. Our data suggest that the B. japonicum inoculants have survived for up to 13 years in the soils without significant mutation except for two reisolates with a slightly increased kanamycin resistance level.

Isolation from soils ofNitrobacter and evidence for novel serotypes using immunofluorescence.

To study the ecology of chemoautotrophic nitrifying bacteria (Nitrobacter), the immunofluorescence technique has been used. Fluorescent antibodies againstNitrobacter winogradskyi andNitrobacter agilis, the two known serotypes, have not labeled strains isolated from soils of the Lyon region (pH 8.1 and pH 4.7). The pure-culture isolates appeared to belong to the same genus, but to be serologically different from the reference strains. These results led us to question the diversity of strains ofNitrobacter in soils.