Local Adaptation of Frankia to Different Discaria (Rhamnaceae) Host Species Growing in Patagonia

Frankia BCU110601 (Da) and Frankia BCU110345 (Dc) were isolated from root nodules of Discaria articulata and Discaria chacaye, respectively; Frankia BCU110501 (Dt) was previously isolated from Discaria trinervis. The strains were identical at the 16S sequence and after analysis of RFLP of 16S and 23S rDNA intergenic region. Diversity was revealed at the molecular level after fingerprint analysis by BOX–polymerase chain reaction. The strains were infective and effective on the original host plants. A cross-inoculation assay intra Discaria genus, including D. trinervis, D. articulata, and D. chacaye, with each of these isolated Frankia strains caused effective symbioses with a similar dry weight in each plant species regardless of the inoculated strain. Nevertheless, a differential degree of recognition was revealed: Homologous symbiotic pairs in the case of D. chacaye–Frankia BCU110345 (Dc), D. articulata–Frankia BCU110601 (Da), and D. trinervis–Frankia BCU110501 (Dt) had faster nodulation rates than heterologous pairs. The differences in nodulation rate would suggest the existence of a subspecific level of recognition within a certain cross-inoculation group, pointing to subspecific adaptation occurring in this actinorhizal symbiosis.     

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.     

Extraction of ribosomal RNA from soil for detection of Frankia with oligonucleotide probes

Sequences of 16S rRNA of the nitrogen-fixing Frankia strain Ag45/Mut15 and the ineffective Frankia strain AgB1.9 were used to design a genus-specific oligonucleotide probe. Hybridization experiments of this Frankia probe and a second probe, specific for Nif⁺-Frankia strains only, were used to detect Frankia specific target sequences in RNA isolations from soil. A method is described for direct isolation of RNA from a loamy soil and a peat. Yields of about 10 ng RNA/g wet soil are obtained without detectable contamination with humic acids. Isolation of RNA after initial extraction of bacteria from soil resulted in significantly lower RNA yields, compared to the direct isolation procedure. Hybridization with both probes against rRNA isolations from Frankia-containing soil could detect target sequences within RNA isolations from 1 g wet soil with an estimated detection limit of 10⁴ cells.     

Molecular ecology ofFrankia: Advantages and disadvantages of the use of DNA probes

Ecological studies on the actinomyceteFrankia are often influenced by the difficulty to isolate and identify this microorganism. The application of molecular biological techniques offers possibilities to detect microbes without isolation and cultivation.Nif genes or whole plasmids can serve as targets for the design of specific probes. Alternatively, ribosomal RNA (rRNA), commonly used in modern phylogenetic studies, can be used as a target molecule in ecological studies. This paper gives an overview of new developments on the use of 16S rRNA as a target molecule for oligonucleotide probes. Group-specific sequences in the 16S rRNA ofFrankia can be used as targets for oligonucleotide probes that a) recognize ineffectiveFrankia strains onAlnus, b) recognize effective strains onAlnus, c) recognize allFrankia strains tested so far. The present paper summarizes the essential steps needed for the use of these probes for the detection ofFrankia strains in soil without isolation and cultivation.     

16S–23S rRNA Intergenic Spacer Region Variability in the Genus Frankia

16S–23S rRNA internally transcribed spacer (ITS) sequences from 53 Frankia strains were sequenced and sized from polymerase chain reaction amplification products and compiled with 14 selected 16S–23S ITS sequences from public database. Frankia genomes included two to three ITS copies lacking length polymorphism except for nine strains. No tRNA gene was encountered in this region. Frankia strains exhibited various lengths (369 to 452 nt) and a wide range of sequence similarity (35–100%) in the ITS region. The average pairwise distance varied from 0.368 (clusters 1 and 2) to 0.964 (clusters 3 and 4) and was 0.397, 0.138, 0.129, and 0.016, respectively, for cluster 4 (saprophytic non-infective/non-effective), clusters 1 and 3 (facultative symbiotic), and cluster 2 (obligate symbiotic). This suggests a gradual erosion of Frankia diversity concomitantly with a shift from saprophytic non-infective/non-effective to facultative and symbiotic lifestyle. Comparative sequence analyses of the 16S–23S rRNA intergenic spacer region of Frankia strains are not useful to assign them to their respective cluster or host infection group. Accurate assignment required the inclusion of the adjacent 16S and 23S rRNA gene fragments.     

Molecular analysis of actinorhizal symbiotic systems: Progress to date

The application of molecular tools to questions related to the genetics, ecology and evolution of actinorhizal symbiotic systems has been especially fruitful during the past two years. Host plant phylogenies based on molecular data have revealed markedly different relationships among host plants than have previously been suspected and have contributed to the development of new hypotheses on the origin and evolution of actinorhizal symbiotic systems. Molecular analyses of host plant gene expression in developing nodules have confirmed the occurrence of nodulin proteins and in situ hybridization techniques have been successfully adapted to permit the study of the spatial and temporal patterns of gene expression within actinorhizal nodules. The use of heterologous probes in combination with nucleotide sequence analysis have allowed a number of nif genes to be mapped on the Frankia chromosome which will ultimately contribute to the development of hypotheses related to nif gene regulation in Frankia. The use of both 16S and 23S rDNA nucleotide sequences has allowed the construction of phylogenetic trees that can be tested for congruence with symbiotic characters. In addition the development of Frankia-specific gene probes and amplification primers have contributed to studies on the genetic diversity and distribution of Frankia in the soil.     

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.     

Homology between the ribosomal DNA of Escherichia coli and mitochondrial DNA preparations of maize is principally to sequences other than mitochondrial rRNA genes

E. coli ribosomal DNA has been used to probe maize mitochondrial DNA. It hybridizes primarily with chloroplast ribosomal DNA sequences and with fungal and bacterial sequences which may contaminate the mtDNA preparations. It also hybridizes to the chloroplast 16S ribosomal RNA gene sequence present in the mitochondrial genome (1) as well as to the mitochondrial 18S ribosomal RNA gene sequence. Weak sequence homology was detected between E. coli rDNA and the mitochondrial 26S ribosomal RNA gene.     

Phylogenetic Positions and Assignment of Swine and Ovine Corynebacterial Isolates Based on the 16S rDNA Sequence

The nucleotide sequences of the 16S ribosomal RNA gene (rDNA) of swine and ovine corynebacterial strains were determined. The sequences of the strains that identified as Corynebacterium pseudotuberculosis by their biochemical characteristics were homologous with each other. The phylogenetic position of C. pseudotuberculosis strains was closest to C. ulcerans and next closest to C. diphtheriae. The nucleotide sequence of another swine isolate, SC8, was similar to that of a recently proposed species, C. seminale, and a non-validated species, “C. glucuronolyticum,” with about 0.01 to 0.02 evolutionary distances. Analysis of the predicted secondary structure of the 16S rRNA molecule agreed with the close phylogenetic relationships between C. pseudotuberculosis and C. ulcerans and between C. seminale and strain SC8.     

Isolate B12, which harbours a virus-like element,represents a new species of the archaebacterial genus Sulfolobus,Sulfolobus shibatae,sp. nov.

The Sulfolobus isolate B12 and its endogenous virus-like element SSV1 have provided a fruitful system for detailed analysis of certain aspects of archaebacterial molecular biology, especially those concerning gene expression. In the course of clarifying this isolate's taxonomic position, we determined DNA base composition, ability to grow autotrophically, nucleotide sequence of 16S ribosomal RNA, and level of total genomic homology to other Sulfolobus strains. Although the results generally demonstrate a similarity to S. solfataricus, DNA-DNA hybridisation and 16S rRNA sequence data indicate that isolate B12 in fact represents a distinct species.Abbreviations DSM Deutsche Sammlung von Mikroorganismen, Mascheroder Weg 1 B, D-3300 Braunschweig, FRG - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis     

Natural Diversity of Nodular Microsymbionts of Alnus glutinosa in the Tormes River Basin

The genetic diversity of Frankia strains nodulating Alnus glutinosa along the basin of the Tormes River was studied on DNA extracted directly from nodules. Frankia strains inhabiting root nodules at 12 different locations, ranging in altitude from 409 to 1181 m, were characterized. For that, we amplified the whole IGS region between 16S–23S rDNA and performed a restriction fragment length polymorphism (RFLP) analysis with four restriction enzymes. Two different RFLP patterns (termed A and B) were obtained with HaeIII, indicating the existence of two different groups of Frankia strains. Three different nodule extracts from each of the two RFLP groups were selected for further analyses. Sequencing of the 16S–23S rDNA IGS showed a 100% of intragroup homology and also confirmed the difference (98.4% level of similarity) between the Frankia strains in the two nodule extract groups. The phylogenetic analyses based on the two 16S–23S rDNA IGS sequences obtained in this study and other previously published sequences indicated that Frankia strains TFAg5 and TFAg23 (chosen as representative of HaeIII–RFLP group A and B, respectively) are quite similar to other strains nodulating plants of A. rhombifolia and A. viridis in California (pairwise levels of similarity including gaps ranged from 97.8% to 98.6%), together with which they form a single group. To put the Frankia strains representative of each HaeIII–RFLP group in the context of overall Frankia diversity we amplified and sequenced the 16S rDNA and glnII gene from nodular DNA. An also remarkable fact found in this study was that Frankia strains belonging to the HaeIII–RFLP group A were distributed all along the river course, from the lowest site sampled to the highest, while Frankia strains placed into RFLP group B were restricted to the upper Tormes River, being exclusively found at altitudes of 946 m or higher.     

Bioconversion of Ferulic Acid to 4-Vinylguaiacol and 4-Ethylguaiacol and of 4-Vinylguaiacol to 4-Ethylguaiacol by Halotolerant Yeasts Belonging to the Genus Candida

In order to examine the genesis of the characteristic flavors of soy sauce and miso, seven novel halotolerant yeast strains of two types, which showed convertibility of ferulic acid (FA) to 4-vinylguaiacol (4-VG) and to 4-ethylguaiacol (4-EG), were isolated from miso-koji and miso pastes. Two of these strains were identified as Candida guilliermondii (anamorph of Pichia guilliermondii), and Candida fermentati (anamorph of Pichia caribbica), based on sequence analyses of a partial 26S ribosomal RNA gene and the region of internal transcribed spacers 1 and 2, and the 5.8S ribosomal RNA gene. Moreover, we also found three Candida etchellsii strains which showed convertibility of FA to 4-VG, but not to 4-EG, and two atypical strains of Candida versatilis which showed no convertibility of FA to 4-VG, but did show convertibility of 4-VG to 4-EG from soy sauce mashes. The bioconversion pathway from FA to 4-EG via 4-VG in halotolerant yeasts and bacteria is discussed.     

Functional interdependence among ribosomal elements as revealed by genetic analysis

Summary Escherichia coli strains with preexisting ribosomal mutations were used in order to isolate further ribosomal mutations. The ribosomal mutations used were resistance to erythromycin, spectinomycin, streptomycin or kasugamycin. These mutations cause alteration of specific ribosomal elements, L4, S5, S12 proteins and 16S rRNA respectively. Mutations have been introduced into strains carrying one, two or three of these mutations. Strains with all possible combinations of these four mutations were constructed. The phenotypes of all isolated mutants were tested, and frequently the strains lost one or more of their pre-existing resistances.Thus, functional interactions were revealed among proteins, as well as RNA and proteins within the 30 S ribosomal subunit and as well as between the 30 S and the 50 S ribosomal subunits.     

Molecular diversity of <Emphasis Type="Italic">Frankia</Emphasis> from root nodules of <Emphasis Type="Italic">Hippophae salicifolia</Emphasis> D.Don found in Sikkim

Molecular diversity of Frankia was assessed directly from the root nodules of Hippophae salicifolia naturally occurring in North Sikkim. Amplicon restriction patterns (ARPs) were developed by digesting 16S-ITS-23S amplicons with RsaI. Three ARPs were detected, showing diversity among strains of Frankia that nodulate Hippophae. This was confirmed by sequencing one amplicon each for the three ARPs. Therefore, ARP can be used as a tool for screening amplicons for nucleotide sequencing.     

Phylogeny of nitrogenase sequences inFrankia and other nitrogen-fixing microorganisms

Summary The complete nucleotide sequence of a nitrogenase (nifH) gene was determined from a second strain (HRN18a) ofFrankia, an aerobic soil bacterium. The open reading frame is 870 bp long and encodes a polypeptide of 290 amino acids. The amino acid and nucleotide sequences were compared with 21 other published sequences. The twoFrankia strains were 96% similar at the amino acid level and 93% similar at the nucleotide level. A number of methods were used to infer phylogenies of these nitrogen fixers, based onnifH amino acid and nucleotide sequences. The results obtained do not agree completely with other phylogenies for these bacteria and thus make probable occurrences of lateral transfer of thenif genes. The time of divergence of the twoFrankia strains could be estimated at about 100 million years. The vanadium-dependent (Type 2) nitrogenase present inAzotobacter spp. appears to be a recent derivation from the conventional molybdenum-dependent (Type 1) enzyme, whereas the iron-dependent (Type 3) alternative nitrogenase would have a much older origin.     

Diversity and Specificity of Frankia Strains in Nodules of Sympatric Myrica gale, Alnus incana, and Shepherdia canadensis Determined by rrs Gene Polymorphism

The identity of Frankia strains from nodules of Myrica gale, Alnus incana subsp. rugosa, and Shepherdia canadensis was determined for a natural stand on a lake shore sand dune in Wisconsin, where the three actinorhizal plant species were growing in close proximity, and from two additional stands with M. gale as the sole actinorhizal component. Unisolated strains were compared by their 16S ribosomal DNA (rDNA) restriction patterns using a direct PCR amplification protocol on nodules. Phylogenetic relationships among nodular Frankia strains were analyzed by comparing complete 16S rDNA sequences of study and reference strains. Where the three actinorhizal species occurred together, each host species was nodulated by a different phylogenetic group of Frankia strains. M. gale strains from all three sites belonged to an Alnus-Casuarina group, closely related to Frankia alni representative strains, and were low in diversity for a host genus considered promiscuous with respect to Frankia microsymbiont genotype. Frankia strains from A. incana nodules were also within the Alnus-Casuarina cluster, distinct from Frankia strains of M. gale nodules at the mixed actinorhizal site but not from Frankia strains from two M. gale nodules at a second site in Wisconsin. Frankia strains from nodules of S. canadensis belonged to a divergent subset of a cluster of Elaeagnaceae-infective strains and exhibited a high degree of diversity. The three closely related local Frankia populations in Myrica nodules could be distinguished from one another using our approach. In addition to geographic separation and host selectivity for Frankia microsymbionts, edaphic factors such as soil moisture and organic matter content, which varied among locales, may account for differences in Frankia populations found in Myrica nodules.     

Molecular and phenotypic characterization of Leptospira johnsonii sp. nov., Leptospira ellinghausenii sp. nov. and Leptospira ryugenii sp. nov. isolated from soil and water in Japan

In a previous study, 50 of 132 soil samples collected throughout Japan were found to be Leptospira‐positive. In the present study, three strains identified in the collected specimens, three, E8, E18 and YH101, were found to be divergent from previously described Leptospira species according to 16S ribosomal RNA gene sequence analysis. These three strains have a helical shape similar to that of typical Leptospira and were not re‐isolated from experimental mice inoculated with the cultured strains. Upon 16S ribosomal RNA gene sequence analysis, E8 was found to belong to the intermediate Leptospira species clade and E18 and YH101 to belong to the saprophytic Leptospira species clade. Based on analyses of genome‐to‐genome distances and average nucleotide identity in silico using whole genome sequences and DNA–DNA hybridization in vitro, these isolates were found to be distinct from previously described Leptospira species. Therefore, these three isolates represent novel species of the genus Leptospira for which the names Leptospira johnsonii sp. nov., (type strain E8 ^T, = JCM 32515 ^T = CIP111620 ^T), Leptospira ellinghausenii sp. nov., (type strain E18 ^T, = JCM 32516 ^T = CIP111618 ^T) and Leptospira ryugenii sp. nov., (type strain YH101 ^T, = JCM 32518 ^T = CIP111617 ^T) are proposed.     

Genotyping of a Miso and Soy Sauce Fermentation Yeast,Zygosaccharomyces rouxii,Based on Sequence Analysis of the Partial 26S Ribosomal RNA Gene and Two Internal Transcribed Spacers

We analyzed sequences of the D1D2 domain of the 26S ribosomal RNA gene (26S rDNA sequence), the internal transcribed spacer 1, the 5.8S ribosomal RNA gene, and the internal transcribed spacer 2 (the ITS sequence) from 46 strains of miso and soy sauce fermentation yeast, Zygosaccharomyces rouxii and a closely related species, Z. mellis, for typing. Based on the 26S rDNA sequence analysis, the Z. rouxii strains were of two types, and the extent of sequence divergence between them was 2.6%. Based on the ITS sequence analysis, they were divided into seven types (I–VII). Between the type strain (type I) and type VI, in particular, a 12% difference was detected. The occurrence of these nine genotypes with a divergence of more than 1% in these two sequences suggests that Z. rouxii is a species complex including novel species and hybrids. Z. mellis strains were of two types (type α and type β) based on the ITS sequence. Z. rouxii could clearly be distinguished from Z. mellis by 26S rDNA and ITS sequence analyses, but not by the 16% NaCl tolerance, when used as the sole key characteristic for differentiation between the two species.     

Conservation of nif sequences in Frankia

Summary Southern blots of Frankia total DNAs were hybridized with nifHDK probes from Rhizobium meliloti, Klebsiella pneumoniae and Frankia strain Arl3. Differences between strains were noted in the size of the hybridizing restriction fragments. These differences were more pronounced among Elaeagnus-compatible strains than among Alnus- or Casuarina-compatible strains. Gene banks constructed for Frankia strains EUN1f, HRN18a, CeD and ACoN24d were used to isolate nif-hybridizing restriction fragments for subsequent mapping and comparisons. The nifH zone had the highest sequence conservation and the nifH and nifD genes were found to be contiguous. The complete nucleotide sequence of the nifH open reading frame (ORF) from Frankia strain Arl3 is 861 bp in length and encodes a polypeptide of 287 amino acids. Comparisons of these nucleic acid and amino acid sequences with other published nifH sequences suggest that Frankia is most similar to Anabaena and Azotobacter spp. and K. pneunoniae and least similar to the Gram-positive Clostridium pasteurianum and to the archaebacterium Methanococcus voltae.