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.     

Relationships among pure cultured strains of Frankia based on host specificity

Fifty strains of Frankia were tested for their ability to nodulate six species of actinorhizal plants. Pure cultured strains were used to inoculate seedlings of Alnus glutinosa (L.) Gaertn., Alnus rubra Bong., Casuarina equisetifolia L., Elaeagnus angustifolia L., Hippophaë rhamnoides L. and Myrica cerifera L. in nutrient solution culture. From the results of this study, host inoculation groups among the actinorhizal plants were defined. Although overlap between host inoculation groups appears to be common, the results from this study did not support the view that Frankia strains are promiscuous. All Frankia strains tested in this study could easily be classified into four major host-specificity groups.     

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.     

Distribution of gymnostoma spp. microsymbiotic frankia strains in new caledonia is related to soil type and to host-plant species

The diversity of the Frankia strains that are naturally in symbiosis with plants belonging to the Gymnostoma genus in New Caledonia was investigated. A direct molecular characterization of DNA extracted from nodules was performed, followed by characterization by restriction fragment length polymorphism (RFLP) of the ribosomal rrs-rrl (16S-23S) intergenic spacer (IGS) polymerase chain reaction (PCR)-amplified region. Seventeen different patterns were identified among the 358 microsymbiotic strains studied in the eight species of host plant present in New Caledonia. This genotypical approach permitted us to show that a large diversity existed among the patterns and that these did not exhibit a strict specificity to any host-plant species comparable with that previously found in the Casuarina and Allocasuarina symbioses in Australia. Despite this lack of specificity, a correspondence analysis nevertheless showed that the distribution of these patterns was related to soil type and to host-plant species. Furthermore, several Frankia strains were exclusively associated with the ultramafic soils.     

The abilities of three Frankia isolates to nodulate and fix nitrogen with four species of Casuarina

Three isolates of Frankia from nodules of Casuarina sens, strict. (JCT287. JCT295 and 20607) were compared in their abilities to nodulate and fix N, when associated with four species of Casuarina ( C. cunninghamiana Miq., C. equisetifolia Forst., C obesa Miq. and C. glauca Sieb. ex Spreng) growing in a N-deficient soil.
All three Frankia isolates nodulated each of the four species of Casuarina . At 27 weeks after inoculation, growth (dry weight) of inoculated plants was 3.6 to 5.0 times greater than that of uninoculated plants. There were no significant differences in plant dry weight, the N concentration of shoots or roots, or the amount of N, fixed per plant among the Frankia isolates for each of the species of Casuarina studied. The infectivity and effectiveness in N, fixation of Frankia strain JCT287 with C. cunninghamiana was similar when two different defined media were used for culture of the inoculum.     

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.     

Sensitivity of selected Frankia isolates from Casuarina, Allocasuarina and North American host plants to sodium chloride

Three experiments examined the effects of NaCl concentrations 0 to 500 mM on the growth of isolates of Frankia from Casuarinaceae and selected North American host plants. Four Casuarina isolates grew well in defined medium (pyruvate-BAP) but not in a yeast extract medium. Conversely the non-Casuarina isolates preferred the yeast-extract medium, although two of them grew in the defined medium. When grown in their preferred medium, the Casuarina isolates were little affected by NaCl concentrations up to 200 m M but did not grow at 500 m M . The non-Casuarina isolates, with the exception of an isolate from Purshia tridentata . were severely affected above 50 m M NaCl.
Nitrogenase activity (C₂H₂ reduction) by the non-Casuarina isolates could not be detected in low-N medium although protein determinations indicated that a low level of nitrogen fixation had occurred. All four Casuarina isolates showed nitrogenase activity in culture, up to 200 m M NaCl, although at that concentration of NaCl, growth was affected more than that of cultures in N-supplemented medium. All four strains showed a marked increase in nitrogenase activity up to 72 h after the addition of C₂H₂, with the magnitude of the effect and their subsequent behaviour being strain dependent.
The results indicate that the isolates of Frankia from Casuarina and Allocasuarina , and that from Purshia tridentata , are more tolerant of NaCl than isolates from species not normally growing under sodic conditions. They provide optimism that these strains could successfully establish in saline soils if introduced with species of host plants tolerant to these soils.     

Protective effect of Brucella outer membrane complex-bearing liposomes against experimental murine brucellosis

Abstract Nodulation ability was tested for Frankia strains HFPCcI3 and ELI, and Frankia sources A.t. and G.a. from Allocasuarina torulosa and Gymnostoma australianum , respectively, on A. torulosa Miq., Casuarina cunninghamiana Miq., G. australianum L. Johnson and Elaeagnus triflora Roxb. It was shown that A. torulosa and C. cunninghamiana formed nodules only with the Frankia sources obtained from their own host plant, while E. triflora formed nodules with three of the four Frankia sources tested. All nodules formed were effectively fixing nitrogen. Specific nitrogenase activity was highest in E. triflora inoculated with the Frankia strain isolated from nodules of the same species. Identification of Frankia sources in the nodules was performed by use of PCR amplification of DNA with a random primer. PCR amplification of DNA isolated from nodules of G. australianum and E. triflora inoculated with Frankia strain EL1 revealed, when compared with DNA amplified from free living Frankia strain EL1, that there was only one Frankia strain causing the observed nodules.     

Host-Frankia specificity within the Casuarinaceae

Summary Fifteen species from three genera of the Casuarinaceae were inoculated with suspensions ofFrankia prepared from single nodule-lobes collected from different species and genera within the Casuarinaceae. Host-endophyte specificity was expressed mainly at the generic level. There was marked cross-inoculation within Casuarina and little nodulation ofCasuarina species from Allocasuarina sources with the exception of 3 sources ofFrankia fromA. torulosa which showed a high tendency to nodulateCasuarina species. Few sources from Casuarina nodulated species of Allocasuarina and while cross-inoculation within Allocasuarina was frequent it was less marked than within Casuarina. SomeFrankia inocula had wider host ranges than others, nodulating outside the genus or series of origin. It was not possible to determine if these apparent wider ranges in host spectra reflected genotypic differences betweenFrankia or were associated with the presence of more than oneFrankia strain in some inocula.     

Geographic distribution and genetic diversity of Ceanothus-infective Frankia strains

Little is known about Ceanothus-infective Frankia strains because no Frankia strains that can reinfect the host plants have been isolated from Ceonothus spp. Therefore, we studied the diversity of the Ceonothus-infective Frankia strains by using molecular techniques. Frankia strains inhabiting root nodules of nine Ceanothus species were characterized. The Ceanothus species used represent the taxonomic diversity and geographic range of the genus; therefore, the breadth of the diversity of Frankia strains that infect Ceanothus spp. was studied. DNA was amplified directly from nodular material by using the PCR. The amplified region included the 3' end of the 16S rRNA gene, the intergenic spacer, and a large portion of the 23S rRNA gene. A series of restriction enzyme digestions of the PCR product allowed us to identify PCR-restriction fragment length polymorphism (RFLP) groups among the Ceanothus-infective Frankia strains tested. Twelve different enzymes were used, which resulted in four different PCR-RFLP groups. The groups did not follow the taxonomic lines of the Ceanothus host species. Instead, the Frankia strains present were related to the sample collection locales.     

不同科属来源的六株Frankia代表菌株碳源利用谱的研究

对来自赤杨属、木麻黄属、异木麻黄属、沙棘属和杨梅属的六株Frankia代表菌株进行了二十四种碳源利用谱的比较研究(包括简单有机酸、单糖、双糖、三糖和糖醇在内)。结果表明,各菌株在碳源利用种类和程度上有明显差异;简单有机酸盐特别是丙酸钠是所有菌株的良好碳源;菌株Cc01、A11I1和Hr16还能很好地利用丙酮酸钠;除了菌株Hr16能很好地利用纤维二糖,菌株A11I1利用葡萄糖外;糖醇类很少被利用。如果以丙酮酸钠、丙酸钠和乙酸为“诊断性”碳源,则可以将供试菌株分为三个类群,即赤杨——杨梅类群、沙棘类群和木麻黄类群;这与交叉接种和血清学方法得出的结论相吻合。     

PCR-RFLP and total DNA homology revealed three related genomic species among broad-host-range Frankia strains

Abstract: Restriction fragment length polymorphism (RFLP) analysis of the PCR amplified nif D-K intergenic spacer (IGS) region was used to cluster 22 Frankia strains of the Elaeagnus host specificity group into seven genomic groups and to measure the degree of genetic similarity among them. This PCR-RFLP analysis could assign freshly isolated strains to described genomic species and revealed genomic groups not yet described among Frankia strains of the Elaeagnus specificity group. Six broad-host-range Frankia strains, infective on both Alnus and Elaeagnus , fell into three closely related PCR-RFLP clusters. DNA-DNA hybridization was then used to establish the correlations between PCR-RFLP clusters and total DNA relatedness groups. The three PCR-RFLP clusters agreed with two new and one reference genomic species, indicating that Frankia ability to nodulate with Alnus and Elaeagnus is a monophyletic trait shared by three genomic species.     

Recent advances in the biogeography and genecology of symbiotic Frankia and its host plants

Molecular phylogenetic approaches have begun to outline the origin, distribution and diversity of actinorhizal partners. Geographic isolation of Frankia and its host plants resulting from shifting continents and dispersal patterns have apparently led to the development of Frankia genotypes with differing affinities for host genera, even within the same plant family. Actinorhizal plant genera of widespread global distribution tend to nodulate readily even outside their native ranges. These taxa may maintain infective Frankia populations of considerable diversity on a broad scale. Arid environments seem to have distinctive actinorhizal partnerships, with smaller and more specific sets of Frankia symbionts. This has led to the hypothesis that some host families have taxa that are evolving towards narrow strain specificity, perhaps because of drier habitats where fewer Frankia strains would be able to survive. Harsh conditions such as water-saturated soils near lakes, swamps or bogs that are typically acidic and low in oxygen may similarly lessen the diversity of Frankia strains present in the soil, perhaps limiting the pool of frankiae available for infection locally and, at a larger scale, for natural selection of symbiotic partnerships with host plants. Recent molecular ecological studies have also provided examples of Frankia strain sorting by soil environment within higher order cluster groupings of Frankia host specificity. Future frontiers for ecological research on Frankia and actinorhizal plants include the soil ecosystem and the genome of Frankia and its hosts.     

Hopanoid lipids in Frankia: identification of squalene-hopene cyclase gene sequences

In Frankia, the microsymbiont in actinorhizal root nodules, nitrogen fixation takes place in specialized structures called vesicles. The lipidic vesicle envelope forms a barrier to oxygen diffusion, an essential part of the nitrogenase oxygen protection system. We have shown previously that the vesicle envelope is composed primarily of two species of hopanoid lipids, sterol-like molecules that are synthesized in a wide range of bacteria, including Frankia, several cyanobacteria, and rhizobia. The levels of hopanoid found in Frankia are among the highest of any organism known to date. Here we report that short (328-bp) DNA sequences from several strains of Frankia spp. have been identified that are homologous to a portion of the coding region of squalene-hopene cyclase (shc) genes. The fragments and corresponding polymerase chain reaction (PCR) primers can be used in phylogenetic comparisons of Frankia, both within Frankiaceae and among bacteria that synthesize hopanoids.     

Diversity and distribution of Frankia strains symbiotic with Ceanothus in California

Frankia strains symbiotic with Ceanothus present an interesting opportunity to study the patterns and causes of Frankia diversity and distribution within a particular host infectivity group. We intensively sampled Frankia from nodules on Ceanothus plants along an elevational gradient in the southern Sierra Nevada of California, and we also collected nodules from a wider host taxonomic and geographic range throughout California. The two sampling scales comprised 36 samples from eight species of Ceanothus representing six of the seven major biogeographic regions in and around California. The primary objective of this study was to use a quantitative model to test the relative importance of geographic separation, host specificity, and environment in influencing the identity of Ceanothus Frankia symbionts as determined by ribosomal DNA sequence data. At both sampling scales, Frankia strains symbiotic with Ceanothus exhibited a high degree of genetic similarity. Frankia strains symbiotic with Chamaebatia (Rosaceae) were within the same clade as several Ceanothus symbionts. Results from a classification and regression tree model used to quantitatively explain Frankia phylogenetic groupings demonstrated that the only significant variable in distinguishing between phylogenetic groups at the more local sampling scale was host species. At the regional scale, Frankia phylogenetic groupings were explained by host species and the biogeographic province of sample collection. We did not find any significant correspondence between Frankia and Ceanothus phylogenies indicative of coevolution, but we concluded that the identity of Frankia strains inhabiting Ceanothus nodules may involve interactions between host species specificity and geographic isolation.     

Nickel is essential for active hydrogenase in free-living Frankia isolated from Casuarina

Five free-living Frankia strains isolated from Casuarina were investigated for occurrence of hydrogenase activity. Nitrogenase activity (acetylene reduction) and hydrogen evolution were also evaluated. Acetylene reduction was recorded in all Frankia strains. None of the Frankia strains had any hydrogenase activity when grown on nickel-depleted medium and they released hydrogen in atmospheric air. After addition of nickel to the medium, the Frankia strains were shown to possess an active hydrogenase, which resulted in hydrogen uptake but no hydrogen evolution. The hydrogenase activity in Frankia strain KB5 increased from zero to 3.86 μ mol H₂ (mg protein)⁻¹ h⁻¹ after addition of up to 1.0 μ M Ni. It is likely that the hydrogenase activity could be enhanced even more as a response on further addition of Ni. It is indicated in this study that absence of hydrogenase activity in free-living Frankia isolated from Casuarina spp. is due to nickel deficiency. Frankia living in symbiosis with Casuarina spp. show hydrogenase activity. Therefore, the results also indicate that the hydrogenase to some extent is regulated by the host plant and/or that the host plant supplies the symbiotic microorganism with nickel. Moreover, the result shows that this Frankia is somewhat different from Frankia isolated from Alnus incana and Comptonia peregrina ., i.e., Frankia isolated from A. incana and C. peregrina showed a small hydrogen uptake activity even without addition of nickel.     

Homogeneity of superoxide dismutase patterns in Frankia strains from Casuarinaceae

Abstract Seven Frankia strains from Casuarina and Allocasuarina were analyzed by polyacrylamide gel electrophoresis to determine the patterns of several enzymes. No relatedness could be established between the strains as far as polyphenol oxidase, esterase and diaphorase were concerned. A first attempt at grouping the Frankia isolates could be achieved with catalase. It was confirmed by the study of superoxide dismutase: only one activity band, with the same mobility, was found in all cases. We propose to use this enzyme as a marker for identification of Frankia strains issued from Casuarinaceae.     

The isolation,culture and infectivity of aFrankia strain fromGymnostoma papuanum (Casuarinaceae)

A strain ofFrankia was isolated fromGymnostoma papuanum(Casuarinaceae) nodules harvested from rooted cuttings which had been inoculated with a suspension of crushedCasuarina equisetifolia nodules. Designated HFPGpI1 (catalogue #HFP021801), this strain is pigmented and similar to other pigmentedFrankia strains in cultural characteristics. A previously unknown spiraled hyphal morphology was observed at very low frequency in some cultures of this strain. HFPGpI1 is infective and effective onG. papuanum but not on anyCasuarina species tested. It also infects members of the family Elaeagnaceae andMyrica gale. The host plantG. papuanum can be infected with a wide range ofFrankia isolates and thus can be considered a promiscuous host, unlike its close relatives in the genera Casuarina and Allocasuarina which are very restrictive as to which strains may nodulate them.     

Host range ofFrankia endophytes

Summary Cross-inoculation experiments with 10 pure cultured strains and 17 host species were carried out. The 10 strains were isolated from the root nodules on actinorhizal trees ranging in 9 species, 5 genera and 4 families. The host species belong to 5 genera. The pure cultured strains fromAlnus are of strong ability to infect different species of the same genus. The seedlings inoculated with these strains are able to nodulate normally. These strains can also infect and nodulate the seedlings ofMyrica californica, but not the seedlings of Elaeagnus, Casuarina andMyrica rubra. The pure cultured strains from Elaeagnus can infect and nodulate the host species in the same genus and family with an exception ofE. viridis vardelavayi, which can be only poorly nodulated by a few strains from Elaeagnus. The strains from Elaeagnus cannot infect the seedlings of Alnus andMyrica rubra. The results presented here suggest thatFrankia endophytes can be divided into two groups: Alnus group and Elaeagnus group.     

Native agarose-polyacrylamide gel electrophoresis allowing the detection of aminopeptidase, dehydrogenase, and esterase activities at the nanogram level: enzymatic patterns in some Frankia strains

Nanogram amounts of soluble aminopeptidases, dehydrogenases, and esterases were detected by nondenaturing ultralow gelling point agarose-polyacrylamide gel electrophoresis (ULGA-PAGE). Cytosolic fractions from Frankia sp. were electrophoresed at 4 degrees C in the presence of Co2+, Zn2+, or Mg2+ ions. Then, aminopeptidases and esterases were revealed by simultaneous capture staining by using fast garnet GBC diazonium salt as the chromogenic coupling compound. Dehydrogenases were revealed by using nitro blue tetrazolium salt as electron acceptor. A variety of aminopeptidases, dehydrogenases, and esterases could be identified by their migration in ULGA-PAGE and by their sensitivities to NaCl, CoSO4, ZnSO4, and MgCl2 when assayed "ingel." The presence of agarose was essential for the detection of the complex enzyme patterns. The patterns were remarkably similar for the five Frankia strains isolated from Allocasuarina and Casuarina host plants and differed from those of Frankia strains isolated from Comptonia and Hippopha? host plants. A nomenclature is proposed for aminopeptidases and other Frankia enzymes. The richness of the Frankia amino-peptidases and esterases zymograms makes them adequate marker enzymes for taxonomical, genetic, or biochemical studies. Dehydrogenases might also be useful, although a more restricted number of bands were found with L-lactic and L-malic acid as substrates.