Phylogenetic relationships among Frankia genomic species determined by use of amplified 16S rDNA sequences

MAGs-centric crack: how long will, spore-positive Frankia and most Protofrankia, microsymbionts remain recalcitrant to axenic growth?

Nearly 50 years after the ground-breaking isolation of the primary Comptonia peregrina microsymbiont under axenic conditions, efforts to isolate a substantial number of Protofrankia and Frankia strains continue with enduring challenges and complexities. This study aimed to streamline genomic insights through comparative and predictive tools to extract traits crucial for isolating specific Frankia in axenic conditions. Pangenome analysis unveiled significant genetic diversity, suggesting untapped potential for cultivation strategies. Shared metabolic strategies in cellular components, central metabolic pathways, and resource acquisition traits offered promising avenues for cultivation. Ecological trait extraction indicated that most uncultured strains exhibit no apparent barriers to axenic growth. Despite ongoing challenges, potential caveats, and errors that could bias predictive analyses, this study provides a nuanced perspective. It highlights potential breakthroughs and guides refined cultivation strategies for these yet-uncultured strains. We advocate for tailored media formulations enriched with simple carbon sources in aerobic environments, with atmospheric nitrogen optionally sufficient to minimize contamination risks. Temperature adjustments should align with strain preferences-28-29°C for Frankia and 32-35°C for Protofrankia-while maintaining an alkaline pH. Given potential extended incubation periods (predicted doubling times ranging from 3.26 to 9.60 days, possibly up to 21.98 days), patience and rigorous contamination monitoring are crucial for optimizing cultivation conditions.

Taxonomic assignment of uncultured prokaryotes with long range PCR targeting the spectinomycin operon

The taxonomic assignment of uncultured prokaryotes to known taxa is a major challenge in microbial systematics. This relies usually on the phylogenetic analysis of the ribosomal small subunit RNA or a few housekeeping genes. Recent works have disclosed ribosomal proteins as valuable markers for systematics and, due to the boom in complete genome sequencing, their use has become widespread. Yet, in the case of uncultured strains, for which complete genome sequences cannot be easily obtained, sequencing many markers is complicated and time consuming. Taking the advantage of the organization of ribosomal protein coding genes in large gene clusters, we amplified a 32 kb conserved region encompassing the spectinomycin (spc) operon using long range PCR from isolated and from uncultured nodular endophytic Frankia strains. The phylogenetic analysis of the 27 ribosomal protein genes contained in this region provided a robust phylogenetic tree consistent with phylogenies based on larger set of markers, indicating that this subset of ribosomal proteins contains enough phylogenetic signal to address systematic issues. This work shows that using long range PCR could break down the barrier preventing the use of ribosomal proteins as phylogenetic markers when complete genome sequences cannot be easily obtained.

In-planta sporulation phenotype: a major life history trait to understand the evolution of Alnus-infective Frankia strains

Two major types of Frankia strains are usually recognized, based on the ability to sporulate in-planta: spore-positive (Sp+) and spore-negative (Sp-). We carried out a study of Sp+ and Sp- Frankia strains based on nodules collected on Alnus glutinosa, Alnus incana and Alnus viridis. The nodules were phenotyped using improved histology methods, and endophytic Frankia strain genotype was determined using a multilocus sequence analysis approach. An additional sampling was done to assess the relation between Sp+ phenotype frequency and genetic diversity of Frankia strains at the alder stand scale. Our results revealed that (i) Sp+ and Sp- Alnus-infective Frankia strains are genetically different even when sampled from the same alder stand and the same host-plant species; (ii) there are at least two distinct phylogenetic lineages of Sp+ Frankia that cluster according to the host-plant species and without regard of geographic distance and (iii) genetic diversity of Sp+ strains is very low at the alder stand scale compared with Sp- strains. Difference in evolutionary history and genetic diversity between Sp+ and Sp- Frankia allows us to discuss the possible ecological role of in-planta sporulation.

Whole-Cell Hybridization of Frankia Strains with Fluorescence- or Digoxigenin-Labeled, 16S rRNA-Targeted Oligonucleotide Probes

Whole-cell hybridization with non-radioactively labeled oligonucleotide probes was used to detect and identify Frankia strains in pure cultures and in nodules. Digoxigenin-labeled probes, which were detected with antibody-alkaline phosphatase conjugates, were more suitable for in situ detection of Frankia strains than fluorescent probes since the sensitivity of the former was higher and problems arising from the autofluorescence of cells and plant material were avoided. Successful detection of Frankia strains in paraformaldehyde-fixed cell material with digoxigenin-labeled oligonucleotide probes depended on pretreatments to permeabilize the cells. Specific hybridization signals on vesicles were obtained after lysozyme pretreatment (1 mg ml for 30 min at 20 degrees C). Reliable penetration of the antibody-enzyme conjugate into hyphae required additional washing with the detergent Nonidet P-40 (0.1%) and toluene (1% in ethanol) after lysozyme treatment. Identification of Frankia vesicles in nodule homogenates was possible only after the removal of the polysaccharide capsule surrounding the vesicles. Incubation with H(2)O(2) (15% in water for 1 h at room temperature) before lysozyme and detergent treatments was found to facilitate specific hybridization. No filaments or spores could be detected in nodule homogenates. This technique should be a powerful tool in the identification of Frankia isolates, in the characterization of as-yet-uncultured nodule populations, and in the confirmation of the origin of unusual Frankia isolates.

Assessing the phylogeny of Frankia-actinorhizal plant nitrogen-fixing root nodule symbioses with Frankia 16S rRNA and glutamine synthetase gene sequences

Actinomycetes from the genus Frankia induce nitrogen-fixing root nodules on actinorhizal plants in the "core rosid" clade of eudicots. Reported here are nine partial Frankia 16S rRNA gene sequences including the first from host plants of the rosaceous genera Cercocarpus and Chamaebatia, 24 partial glutamine synthetase (GSI; glnA) sequences from Frankia in nodules of 17 of the 23 actinorhizal genera, and the partial glnA sequence of Acidothermus cellulolyticus. Phylogenetic analyses of combined Frankia 16S rDNA and glnA sequences indicate that infective strains belong to three major clades (I-III) and that Clade I strains consisting of unisolated symbionts from the Coriariaceae, Datiscaceae, Rosaceae, and Ceanothus of the Rhamnaceae are basal to the other clades. Clock-like mutation rates in glnA sequence alignments indicate that all three major Frankia clades diverged early during the emergence of eudicots in the Cretaceous period, and suggest that present-day symbioses are the result of an ancestral symbiosis that emerged before the divergence of extant actinorhizal plants.

Hypervariable spacer regions are good sites for developing specific PCR-RFLP markers and PCR primers for screening actinorhizal symbionts

While the ribosomal RNA like highly conserved genes are good molecular chronometers for establishing phylogenetic relationships, they can also be useful in securing the amplification of adjoining hyper-variable regions. These regions can then be used for developing specific PCR primers or PCR-RFL profiles to be used as molecular markers. We report here the use of ITS region of rrn operon of Frankia for developing PCR-RFL profiles capable of discriminating between closely related frankiae. We have also made use of the ITS1 region of the nuclear rrn operon of Alnus nepalensis (D Don) for designing a PCR primer for specific amplification of nuclear DNA of this tree.

Analysis of pFQ12, a 22.4-kb Frankia plasmid

Frankia are gram-positive, filamentous bacteria capable of fixing atmospheric dinitrogen in symbiosis with a wide variety of woody plants and shrubs. Some isolates of Frankia harbor plasmids of 8.5 (pFQ11) and 22.4 kb (pFQ12) that have no known function but are transmitted through many generations in culture. We have sequenced the 22,437-bp pFQ12 plasmid that is present in isolates CpI1 and ArI3. This sequence, with 76% G+C, is almost totally unrelated to that of pFQ11 found in the same cells. However, four regions of identity, 40-90 bp each, are dispersed around the plasmids. The 22.4-kb plasmid has >50 open reading frames (ORFs) that encode putative proteins of more than 100 amino acids, with the largest being 2226 amino acids. Twenty of these ORFs are likely to encode proteins based on their codon bias as determined by two different algorithms. Transcripts from nine of these regions have been identified by reverse transcriptase-polymerase chain reaction (RT-PCR) or filter hybridization. The two Frankia plasmids each encode a protein similar to the korSA protein that regulates transmission of pSAM2 in Streptomyces. The origin of replication (ORI) region of pFQ12 was localized by intrastrand AT and GC equivalence switch. It includes a 40-bp, intergenic, A+T-rich region that has a strong identity in pFQ11.

Frankia sequences exhibiting RNA polymerase promoter activity

Frankia are Gram-positive, filamentous bacteria capable of fixing atmospheric dinitrogen either in the free-living state or in symbiosis with a variety of woody plants. Only a few Frankia genes have been sequenced and gene expression is not well characterized. To isolate a segment of Frankia DNA that functions as an RNA polymerase promoter, fragments of Frankia strain ArI5 genomic DNA were cloned upstream of a promoterless, Vibrio harveyi luxAB cassette. Constructs were screened for luminescence in E. coli and positive clones assayed for in vitro transcription activity with a partially purified Frankia RNA polymerase extract. Primer extension analysis of in vitro transcripts produced from one clone, GLO7, identified two major transcription start sites, TSP-1 and TSP-2, 52 bp apart. Deletion analysis then localized sequences essential for promoter activity. The upstream promoter region, GLO7p1, contains sequences resembling the -35 element of a Streptomyces promoter and the -35 and -10 elements of the canonical E. coli promoter. Also within this region are two pentamers identical to sequences near the 5' end of the Frankia strain CpI1 glutamine synthetase gene. The second promoter, GLO7p2, contains a putative NtrC binding site at -145 and a possible sigma(N)-RNA polymerase recognition sequence at -14 suggesting that GLO7p2 may be a nitrogen-regulated promoter. An in vivo transcript representing an ORF of 498 aa starting 64 bp downstream of the distal transcription start, TSP-1, was detected by RT-PCR. This supports the conclusion that this DNA fragment has promoter activity in vivo as well as in vitro.

Polymerase chain reaction - restriction fragment length polymorphisms for assessing and increasing biodiversity ofFrankiaculture collections

During the last few years, some Frankia culture collections that maintained a large number of unidentified and uncharacterized Frankia strains were closed because of funding shortages. To reduce the costs of maintenance, we evaluated the biodiversity of half of the Frankia strains from our collection, by polymerase chain reaction - restriction fragment length polymorphisms (PCR-RFLPs) of nifD-nifK intergenic spacer and 16S-23S rDNA intergenic spacer regions. In this way we were able to reduce the number of strains without reducing the biodiversity of the whole collection. In general the nifD-nifK target proved to be more polymorphic than the rrn target. From 51 isolates of Elaeagnus frankiae, PCR-RFLP results allowed us to detect 13 identical strains, and to predict that the genomic species P8 of Akimov and Dobritsa (1992) very likely agrees with genomic species 5 of Fernandez et al. (1989). Moreover, we revealed genomic groups not yet described, as well as intraspecific variability. For Alnus frankiae, the polymorphisms shown by both the nif and the rrn PCR-RFLPs revealed three host plant species-specific subgroups inside Frankia alni. An expandable data base was created to serve as reference for future biodiversity evaluations on both culture collections and unisolated Frankia populations. It will be accessible by Internet at the International Frankia Website (http://www.unifi.it/unifi/distam/frankia/international.html).Key words: Frankia, PCR-RFLP, nifD-nifK intergenic spacer, rrn 16S-23S intergenic spacer, biodiversity, culture collections.

Genomic fingerprinting ofFrankiamicrosymbionts fromCeanothuscopopulations using repetitive sequences and polymerase chain reactions

Specificity between Ceanothus species and their microsymbionts, Frankia, were investigated with nodules collected from three geographically separated copopulations of Ceanothus species. Nodules were analyzed using DNA sequencing and repetitive sequence polymerase chain reaction (rep-PCR) techniques. DNA sequencing of the intergenic spacer region between 16S and 23S rRNA genes suggested that Ceanothus-microsymbiotic Frankia are closely related at the intraspecific level. Diversity of the microsymbionts was further analyzed by genomic fingerprinting using repetitive sequences and PCR. A newly designed direct repeat (DR) sequence and a BOX sequence were used as PCR primers after justification that these primers can generate Frankia-specific fingerprints from nodule DNA. Analysis of the nodules using BOX- and DR-PCR showed that Ceanothus-microsymbiotic Frankia exhibited less diversity within each copopulation than among copopulations. These data suggested that geographic separation plays a more important role for divergence of Ceanothus-microsymbiotic Frankia than host plant.Key words: Frankia, Ceanothus, rep-PCR, diversity.

Phylogenetic placement of unculturedCeanothusmicrosymbionts using 16S rRNA gene sequences

Full-length 16S rDNA sequences were amplified directly from the nodules of Ceanothus americanus L. and Ceanothus thyrsiflorus Eschsch. using the polymerase chain reaction. Sequences were determined using an automated sequencer, compared against those in GenBank, and assembled into consensus sequences. The sequences were aligned with other full-length Frankia 16S rDNA sequences available from the data base. Phylogenetic trees were obtained using three different algorithms: neighbor joining, parsimony, and the maximum-likelihood method. All three methods showed that these Ceanothus L. microsymbionts were most closely related to the microsymbiont associated with Dryas drummondii Richardson ex Hook. Lvs. rather than Frankia isolated from the Elaeagnaceae.Key words: Frankia, Ceanothus, 16S rDNA.

Co-evolution between Frankia populations and host plants in the family Casuarinaceae and consequent patterns of global dispersal

Symbioses between the root nodule-forming, nitrogen-fixing actinomycete Frankia and its angiospermous host plants are important in the nitrogen economies of numerous terrestrial ecosystems. Molecular characterization of Frankia strains using polymerase chain reaction/restriction fragment length polymorphism (PCR/RFLP) analyses of the 16S rRNA-ITS gene and of the nifD-nifK spacer was conducted directly on root nodules collected worldwide from Casuarina and Allocasuarina trees. In their native habitats in Australia, host species contained seven distinctive sets of Frankia in seven different molecular phylogenetic groups. Where Casuarina and Allocasuarina trees are newly planted outside Australia, they do not normally nodulate unless Frankia is introduced with the host seedling. Nodules from Casuarina trees introduced outside Australia over the last two centuries were found to contain Frankia from only one of the seven phylogenetic groups associated with the host genus Casuarina in Australia. The phylogenetic group of Frankia found in Casuarina and Allocasuarina trees introduced outside Australia is the only group that has yielded isolates in pure culture, suggesting a greater ability to survive independently of a host. Furthermore, the Frankia species in this group are able to nodulate a wider range of host species than those in the other six groups. In baiting studies, Casuarina spp. are compatible with more Frankia microsymbiont groups than Allocasuarina host spp. adapted to drier soil conditions, and C. equisetifolia has broader microsymbiont compatibility than other Casuarina spp. Some Frankia associated with the nodular rhizosphere and rhizoplan, but not with the nodular tissue, of Australian hosts were able to nodulate cosmopolitan Myrica plants that have broad microsymbiont compatibility and, hence, are a potential host of Casuarinaceae-infective Frankia outside the hosts' native range. The results are consistent with the idea that Frankia symbiotic promiscuity and ease of isolation on organic substrates, suggesting saprophytic potential, are associated with increased microsymbiont ability to disperse and adapt to diverse new environments, and that both genetics and environment determine a host's nodular microsymbiont.

Emergence of a laccase-positive variant of Azospirillum lipoferum occurs via a two-step phenotypic switching process

Two variants have been isolated from the wild-type Azospirillum lipoferum strain 4B. The first variant, 4V(I), spontaneously emerged from the wild-type at frequencies in the order of 10(-4) to 10(-3) per cell generation. Compared to the wild-type, the 4V(I) variant gained (production of a carotenoid-like pigment, assimilation of certain carbohydrates) and lost (swimming motility, reduction of triphenyl tetrazolium chloride, acid production from certain sugars) apparently unrelated phenotypic characteristics. Only from the 4V(I) variant, a second atypical stable form, variant 4V(II), which acquired laccase activity and ability to produce melanin, appeared under very specific conditions, namely growth at extremely low oxygen concentrations. Neither of the variants was able to revert to the parental phenotype. The results suggest that atypical non-motile laccase-positive isolates of A. lipoferum that are found in the rice rhizosphere originate from wild-type (motile, laccase-negative) cells via a two-step phenotypic switching event, a non-motile laccase-negative variant being an intermediate phase.

Analysis of LMW RNA profiles of Frankia strains by staircase electrophoresis

An optimized technique of polyacrylamide gel electrophoresis, Staircase Electrophoresis (SCE), was applied to determine the stable Low Molecular Weight RNA (LMW RNA) profiles of 25 Frankia strains from diverse geographic origins and host specificity groups as well as species from other actinomycete genera. Application of the technique permits the rapid identification of Frankia strains and their differentiation from other actinomycetes. The isolates used in this study were grouped in eight clusters, each comprising strains with identical LMW RNA profiles. Comparison of these results with others obtained from DNA sequences or DNA hybridization methods suggest a high degree of complexity in the genus Frankia. Application of SCE to profile LMW RNA should in the future facilitate biodiversity studies of Frankia and discrimination of new species.

Diversity of frankia strains in root nodules of plants from the families elaeagnaceae and rhamnaceae

Partial 16S ribosomal DNAs (rDNAs) were PCR amplified and sequenced from Frankia strains living in root nodules of plants belonging to the families Elaeagnaceae and Rhamnaceae, including Colletia hystrix, Elaeagnus angustifolia, an unidentified Elaeagnus sp., Talguenea quinquenervia, and Trevoa trinervis. Nearly full-length 16S rDNAs were sequenced from strains of Frankia living in nodules of Ceanothus americanus, C. hystrix, Coriaria arborea, and Trevoa trinervis. Partial sequences also were obtained from Frankia strains isolated and cultured from the nodules of C. hystrix, Discaria serratifolia, D. trinervis, Retanilla ephedra, T. quinquenervia, and T. trinervis (Rhamnaceae). Comparison of these sequences and other published sequences of Frankia 16S rDNA reveals that the microsymbionts and isolated strains from the two plant families form a distinct phylogenetic clade, except for those from C. americanus. All sequences in the clade have a common 2-base deletion compared with other Frankia strains. Sequences from C. americanus nodules lack the deletion and cluster with Frankia strains infecting plants of the family Rosaceae. Published plant phylogenies (based on chloroplast rbcL sequences) group the members of the families Elaeagnaceae and Rhamnaceae together in the same clade. Thus, with the exception of C. americanus, actinorhizal plants of these families and their Frankia microsymbionts share a common symbiotic origin.

The nodular microsymbionts of Gymnostoma spp. are Elaeagnus-infective Frankia strains

The phylogenetic relationships of Frankia strains infective on Gymnostoma with other Frankia strains was analyzed. Partial sequencing of the 16S rDNA and use of specific primers showed that the Frankia strains present in Gymnostoma are phylogenetically close to Elaeagnus-infective strains. This finding was confirmed by using the sequences of the hypervariable nifDK intergenic spacer. The strains present in Gymnostoma nodules were close to one another. Clustered with Elaeagnus-infective strains, and distantly related to Casuarina and Alnus-infective strains. Morphological observations of strains and cross-inoculation trials showed that Gymnostoma-infective strains are indistinguishable from Elaeagnus-infective strains. Results of both phenotypic and genotypic approaches indicate that Gymnostoma-infective strains are Elaeagnus infective and not Casuarina infective.

Analysis of partial sequences of genes coding for 16S rRNA of actinomycetes isolated from Casuarina equisetifolia nodules in Mexico

Filamentous bacteria isolated from surface-sterilized nodules of Casuarina equisetifolia trees in México were capable of reducing acetylene, a diagnostic test for nitrogenase, but were unable to nodulate their host. Analysis of partial 16S rRNA gene sequences suggests that the Mexican isolates are not Frankia strains but members of a novel clade.

PCR-restriction fragment length polymorphism identification and host range of single-spore isolates of the flexible Frankia sp. strain UFI 132715

Twelve single-spore isolates of the flexible Elaeagnus-Frankia strain UFI 132715 fulfilled the third and the fourth of Koch's postulates on both Alnus and Elaeagnus axenic plants. Seminested nifD-nifK PCR-restriction fragment length polymorphisms provided evidence for the genetic uniformity of the single-spore frankiae with the mother strain and its plant reisolates and allowed their molecular identification directly inside Alnus and Elaeagnus nodules. The clonal nature of these single-spore-purified frankiae should allow safe mutagenesis programs, while their flexible phenotype makes them a powerful tool for understanding the molecular interactions between Frankia strains and actinorhizal plants and for identifying Frankia nodulation genes.

Genetic diversity among Frankia strains nodulating members of the family Casuarinaceae in Australia revealed by PCR and restriction fragment length polymorphism analysis with crushed root nodules

DNA extracted directly from nodules was used to assess the genetic diversity of Frankia strains symbiotically associated with two species of the genus Casuarina and two of the genus Allocasuarina naturally occurring in northeastern Australia. DNA from field-collected nodules or extracted from reference cultures of Casuarina-infective Frankia strains was used as the template in PCRs with primers targeting two DNA regions, one in the ribosomal operon and the other in the nif operon. PCR products were then analyzed by using a set of restriction endonucleases. Five distinct genetic groups were recognized on the basis of these restriction patterns. These groups were consistently associated with the host species from which the nodules originated. All isolated reference strains had similar patterns and were assigned to group 1 along with six of the eight unisolated Frankia strains from Casuarina equisetifolia in Australia. Group 2 consisted of two unisolated Frankia strains from C. equisetifolia, whereas groups 3 to 5 comprised all unisolated strains from Casuarina cunninghamiana, Allocasuarina torulosa, and Allocasuarina littoralis, respectively. These results demonstrate that, contrary to the results of previous molecular studies of isolated strains, there is genetic diversity among Frankia strains that infect members of the family Casuarinacaeae. The apparent high homogeneity of Frankia strains in these previous studies probably relates to the single host species from which the strains were obtained and the origin of these strains from areas outside the natural geographic range of members of the family Casuarinaceae, where genetic diversity could be lower than in Australia.

Molecular structure of the Frankia spp. nifD-K intergenic spacer and design of Frankia genus compatible primer

The nifD-K intergenic spacer (IGS) of ArI3 and ACoN24d were found to have a length 265 and 199 nucleotides, respectively. They are markedly less conserved than the two neighbouring genes and have, in some instances, a repeated structure reminiscent of an insertion event. The repeated sequence and the IGSs have no detectable homology with sequences in DNA databanks. The IGS has a stem-loop structure with a low folding energy, lower than that between nifH and nifD. No convincing alignment of IGS sequences could be obtained among Frankia strains. Only between ACoN24d and ArI3, which belong to the same genomic species, was the alignment good enough to permit detection of a doubly repeated structure. No promoter could be detected in the IGSs. The putative nifK open reading frame (ORF) in Frankia strain ArI3 has a length of 1587 nucleotides, starting with a GTG codon, preceded by a ribosome binding site of a structure similar to that of nifH (GGAGGN7). The codon usage was similar to that of previously sequenced Frankia genes with a strong bias toward G- and C-ending codons except in the case of glycine where GGT is frequent. Alignment of the three Frankia nifK sequences (EUN1f; ArI3 and ACoN24d) with those of other nitrogen-fixing bacteria permitted detection of a sequence conserved among the three Frankia strains but absent in the other sequences. A primer targeted to that region in combination with FGPD807-85 amplified the nifD-KIGS sequences of all Frankia strains (except the non-nitrogen-fixing Frankia strains CN3 and AgB1-9) and yet failed to amplify DNA of all other nitrogen-fixing bacteria.(ABSTRACT TRUNCATED AT 250 WORDS)

Cloning of Frankia species putative tRNA(Pro) genes and their efficacy for pSAM2 site-specific integration in Streptomyces lividans

pSAM2 is a conjugative Streptomyces ambofaciens mobile genetic element that can transfer and integrate site specifically in the genome. The chromosomal attachment site (attB) for pSAM2 site-specific recombination for two Frankia species was analyzed. It overlaps putative proline tRNA genes having a 3'-terminal CCA sequence, an uncommon feature among actinomycetes. pSAM2 is able to integrate into a cloned Frankia attB site harbored in Streptomyces lividans. The integration event removes the 3'-terminal CCA sequence and introduces a single nucleotide difference in the T psi C loop of the putative Frankia tRNA(Pro) gene. Major differences between the attP sequence from pSAM2 and the Frankia attB sequence restrict the identity segment to a 43-bp-long region. Only one mismatch is found between these well-conserved att segments. This nucleotide substitution makes a BstBI recognition site in Frankia attB and was used to localize the recombination site in a 25-bp region going from the anticodon to the T psi C loop of the tRNA(Pro) sequence. Integration of pSAM2 into the Frankia attB site is the first step toward introduction of pSAM2 derivatives into Frankia spp.

Molecular relationship of an atypical Azospirillum strain 4T to other Azospirillum species

DNA/DNA hybridization, plasmid content and partial 16S rDNA sequence were determined to confirm the relationship between two Azospirillum strains, 4B and 4T, isolated from the same rice rhizosphere. The partial 16S rDNA sequence was determined for 9 strains belonging to 5 Azospirillum species which included Azospirillum lipoferum strains 4B and 4T, and was compared to a set of ribosomal sequences from other bacteria of the alpha subdivision of the Proteobacteria. Four Azospirillum species sequences were found to form a coherent group, whereas A. halopraeferens was found to be more divergent. The five Azospirillum species were closely related to Magnetospirillum and to a lesser extent to Rhodospirillum, with which they share some morphological features. The partial 16S rDNA sequences of the two strains 4B and 4T were identical and confirmed the closeness of these two strains. Plasmid content and DNA/DNA hybridization data (S1 nuclease and delta Tm) grouped Azospirillum strains 4B and 4T with the other strains of species Azospirillum lipoferum (USA5a, 59b, BR17). Other biochemical and genetic characters confirmed the grouping of Azospirillum strains 4B and 4T together with A. lipoferum.

Genetic diversity of Datisca cannabina-compatible Frankia strains as determined by sequence analysis of the PCR-amplified 16S rRNA gene

The presence of Frankia strains in soil samples collected from northern areas of Pakistan was detected by inoculating Coriaria nepalensis and Datisca cannabina plants. The abundance of compatible Frankia strains in some areas was indicated by profuse nodulation of the host plants, whereas soil samples from other localities failed to result in nodulation. An oligonucleotide probe (COR/DAT) directed against the 16S rRNA gene of the endophytes of Coriaria and Datisca spp. that did not cross-react with the RNA gene of Frankia strains isolated from other hosts was developed. Genetic diversity among Frankia strains nodulating D. cannabina was determined by sequence analysis of the partial 16S rRNA gene amplified from nodules induced by soil samples from different localities by PCR. Four types of Frankia sequences and one non-Frankia sequence were detected by hybridization with a Frankia genus probe and the COR/DAT probe as well as by sequence analysis of the cloned PCR products.

The nodular endophytes of Coriaria spp. form a distinct lineage within the genus Frankia

Repeated attempts at isolating the Frankia endophyte of Coriaria spp. have not yielded infective microbial cultures that could fulfil Koch's postulates. In order to circumvent the critical isolation step, nodule endophytes of Coriaria were characterized directly by means of specific amplification of nodule DNA (PCR) followed by sequencing of part of the 16S rDNA gene. Three closely related sequences were obtained from nodules originating from France, Mexico and New Zealand, containing unique sequences different from all other Frankia strains characterized so far. The sequences obtained were closest (with 5 or 6 substitutions) to those of Frankia alni and those of Casuarina-infective Frankia strains, respectively. Two nucleotides unique to the Coriaria endophyte sequences were used to define specific primers, resulting in a hybridization test that could discriminate between Frankia DNAs originating from Coriaria nodules and those recovered from all cultured Frankia strains tested. The endophytes of Coriaria thus appear to form a distinct Frankia lineage.

Identification of Agrobacterium strains by PCR-RFLP analysis of pTi and chromosomal regions

Chromosomes and Ti plasmids of 41 Agrobacterium strains, belonging to biovars 1, 2, 3, and Agrobacterium rubi species were characterized by the restriction fragment length polymorphism of PCR-amplified DNAs. Profiles that were obtained by the analysis of the amplified 16S rDNA confirmed the grouping of the strains according to their species. Higher polymorphism was detected in the intergenic spacer between the 16S rDNA and 23S rDNA genes, allowing efficient discrimination of strains. Identification of most strains was possible, and the genetic relatednesses of Agrobacterium strains could be estimated. The analysis of the plasmid Ti encoded regions between the tmr and nos genes, and the virA and virB2 genes, allowed fingerprinting of Ti plasmids. Genomic typing by the rapid PCR-RFLP method is thus shown to be useful for an independent identification of strains and of the conjugative Ti plasmids.

Molecular characterization of Frankia microsymbionts from spore-positive and spore-negative nodules in a natural alder stand

Among the Frankia strains capable of establishing a nitrogen-fixing symbiosis with actinorrhizal plants, in planta sporangial formation is not universal and has led to the distinction between spore-positive (Sp+) and spore-negative (Sp-) nodules. Numerous Frankia strains have been isolated in pure culture from Sp+ nodules of different host plants, but, although they were able to reinfect their respective host plant, none of them was able to differentiate endophytic sporangia under laboratory conditions. The first step of this study was to demonstrate, at the molecular level, the existence of specific Sp+ strain genotypes differing from Sp- strain genotypes in a single alder stand. In a second step, by way of PCR amplification and sequencing of the PCR products, we have characterized oligonucleotide primers specific for the genus Frankia and for each of the two types of Frankia microsymbionts able, or not, to differentiate sporangia inside natural green alder nodules. These primers applied in PCRs with DNA extracted from nodules confirmed the morphological identification and revealed the presence of nodules colonized by both types of actinomycetes. Finally, a preliminary PCR study was conducted with DNA extracted directly from soil samples which permitted checking the rhizosphere of Sp+ and Sp- nodules for the presence of the corresponding strains.

Morphological and molecular characterization of Frankia sp. isolates from nodules of Alnus nepalensis Don

Nodules collected from Alnus nepalensis growing in mixed forest stands at three different sites around Shillong, were crushed in various culture media to obtain isolates of Frankia. The isolates were found to have typical Frankia morphology as revealed by the scanning electron microscope. Seedlings inoculated with isolates or crushed nodules formed nitrogen fixing nodules. Frankia specific DNA probes amplified the DNA of the tested isolate AnpUS4. Partial nucleotide sequence of the 16S rRNA gene indicated that AnpUS4 was phylogenetically distinct from all other Frankia strains characterized so far.

Physiology of some actinomycete genera

Actinomycetes are widespread in the environment and are mainly organotrophic. Studies of their ecology have been primarily focussed on their detection and isolation, with comparatively little attention to the control mechanisms that determine their occurrence and behaviour in their natural environments. This session provided some diverse examples of approaches to this problem. Several actinomycete genera produce motile spores. The significance of flagella proteins and factors influencing spore motility and germination are considered. The genus Frankia forms nitrogen-fixing associations with non-leguminous plants. Molecular techniques have been used to clarify the endophyte-host relationships. Micromonospora species are common in the environment. The growth and physiology of a gentamicin-producing strain are described. Thermophilic actinomycetes in the genus Thermoactinomyces are common in composts and other self-heating environments. Novel isolates from acid soil, which grow and produce enzymes active at high temperatures and in acidic conditions, are discussed.

Biology of Frankia strains, actinomycete symbionts of actinorhizal plants

Frankia strains are N2-fixing actinomycetes whose isolation and cultivation were first reported in 1978. They induce N2-fixing root nodules on diverse nonleguminous (actinorhizal) plants that are important in ecological successions and in land reclamation and remediation. The genus Frankia encompasses a diverse group of soil actinomycetes that have in common the formation of multilocular sporangia, filamentous growth, and nitrogenase-containing vesicles enveloped in multilaminated lipid envelopes. The relatively constant morphology of vesicles in culture is modified by plant interactions in symbiosis to give a diverse array of vesicles shapes. Recent studies of the genetics and molecular genetics of these organisms have begun to provide new insights into higher-plant-bacterium interactions that lead to productive N2-fixing symbioses. Sufficient information about the relationship of Frankia strains to other bacteria, and to each other, is now available to warrant the creation of some species based on phenotypic and genetic criteria.

Typing method for N2-fixing bacteria based on PCR-RFLP--application to the characterization of Frankia strains

DNA sequences of an intergenic spacer (IGS) and parts of genes in the nif cluster were amplified by the polymerase chain reaction (PCR) using two primers derived from nifD- and nifK-conserved sequences. The PCR products were cleaved by ten 4-base cutting restriction enzymes and the restriction patterns were used as fingerprints to type Frankia strains. The feasability of this PCR-RFLP method for typing Frankia strains was investigated on Frankia reference strains belonging mainly to the Elaeagnaceae infectivity group but also on new Frankia isolates and on other N2-fixing microorganisms. By modulating the stringency of the amplifications, we showed the method allowed to target either Frankia strains or the whole N2-fixing microbial community. DNA digestion patterns were used to estimate the sequence divergence between the Frankia nifD-K fragment. The estimated relationships deduced from these genotypic data correlated well with established Frankia taxonomic schemes.

Balneatrix alpica gen. nov., sp. nov., a bacterium associated with pneumonia and meningitis in a spa therapy center

In 1987, an outbreak of pneumonia and meningitis caused by an unknown bacterium occurred in a spa therapy centre. Nine isolates of this pathogen constituted a tight DNA hybridization group. rRNA-DNA hybridization and 16S rRNA sequencing showed that the studied bacteria represented a new branch in superfamily II (= gamma subclass) of the Proteobacteria, close to the genus Oceanospirillum. The new bacterium was highly polymorphic and, in young cultures, had curved Gram-negative cells, motile by polar single flagella. The new bacterium differed from the genus Oceanospirillum by its lacking the NaCl requirement and by reducing nitrate into nitrite, producing indole from tryptophan and producing acid from carbohydrates. The name Balneatrix alpica gen. nov., sp. nov. is proposed for the studied organism. The type strain is strain 4-87 (= CIP 103589).

Evidence that some Frankia sp. strains are able to cross boundaries between Alnus and Elaeagnus host specificity groups

Phenotypic and genotypic methods were used to prove the existence of Frankia strains isolated from an Elaeagnus sp. that are able to cross the inoculation barriers and infect Alnus spp. also. Repeated cycles of inoculation, nodulation, and reisolation were performed under axenic conditions. Frankia wild-type strain UFI 13270257 and three of its coisolates did exhibit complete infectivity and effectiveness on Elaeagnus spp. and Hippophaë rhamnoides and variable infectivity on Alnus spp. Microscopical observation of host plant roots showed that these strains are able to infect Alnus spp. by penetrating deformed root hairs. Reisolates obtained from nodules induced on monoxenic Alnus glutinosa, Alnus incana, and Elaeagnus angustifolia resembled the parent strains in host infectivity range, in planta and in vitro morphophysiology, isoenzymes, and nif and rrn restriction fragment length polymorphisms, thus fulfilling Koch's postulates on both host plant genera. Alnus and Elaeagnus group-specific polymerase chain reaction DNA amplifications, DNA-DNA hybridizations, and partial gene sequences coding for 16S rRNA provided evidence for the genetic uniformity of wild-type strains and their inclusion into one and the same genomic species, clearly belonging to the Elaeagnus group of Frankia species.

Analysis of a ribosomal RNA operon in the actinomycete Frankia

The organisation of ribosomal RNA-encoding (rrn) genes has been studied in Frankia sp. strain ORS020606. The two rrn clusters present in Frankia strain ORS020606 were isolated from genomic banks in phage lambda EMBL3 by hybridization with oligodeoxyribonucleotide probes. The 5'-3' gene order is the usual one for bacteria: 16S-23S-5S. The two clusters are not distinguishable by restriction enzyme mapping inside the coding section, but vary considerably outside it. Sequencing showed that the 16S-rRNA-encoding gene of ORS020606 is very closely related to that of another Alnus-infective Frankia strain (Ag45/Mut15) and highly homologous to corresponding genes of Streptomyces spp. Two possible promoter sequences were detected upstream from the 16S gene, while no tRNA-encoding gene was detected in the whole operon. Regions with a high proportion of divergence for the study of phylogenetic relationships within the genus were looked for and found in the first intergenic spacer, in the 23S and in the 16S gene.