Are Northwestern Patagonian “mallín” wetland meadows reservoirs of <Emphasis Type="BoldItalic">Ochetophila trinervis</Emphasis> infective <Emphasis Type="BoldItalic">Frankia?</Emphasis>

“Mallín” (plural mallines) is a particular kind of wetland occurring in Patagonian steppe and forests. In Northwest Patagonia, mallines are humid meadows with high net primary production. It was previously found that a mallín soil in the steppe devoid of actinorhizal plants had a higher Frankia nodulation capacity in Ochetophila trinervis (sin. Discaria trinervis) than other soils in the region. Under the hypothesis that mallín wetland meadows are reservoir of infective Frankia, we studied the Frankia nodulation capacity in O. trinervis of 12 mallín and their neighbouring steppe soils, by using plant bioassays. A qualitative plant bioassay showed that infective Frankia was present in most soils. The number of nodules per plant in seedlings inoculated with mallín soils was negatively correlated with soil water content while the opposite was true for plants inoculated with soils from neighbouring steppe. A quantitative bioassay was performed with eight representative soils, selected according to the number of nodules per plant produced in the qualitative assay and to the presence or not of different actinorhizal plants at the sites. Frankia nodulation units per cm³ of soil (NU) in mallín soils were higher than those in steppe. Water and organic matter content of soils were correlated with the higher nodulation capacity of mallines, which may account for the saprotrophic growth of Frankia in soils. The symbiosis was effective in plants inoculated with all soil samples. These results suggest that Northwestern Patagonian mallín wetland meadows are reservoirs of infective and effective Frankia propagules in O. trinervis.     

Host range differentiation of spore-positive and spore-negative strain types of Frankia in stands of Alnus glutinosa and Alnus incana in Finland

Host compatibility of different spore-positive (Sp⁺)and spore-negative (Sp^?) strain types of Frankia from alder stands in Finland was studied in Modulation tests with hydrocultures of Alnus glutinosa (L.) Gaertner, A. incana (L.) Moench and A. nitida Endl. Root nodules and soil samples from stands of A. incana (Lammi forest and Hämeenlinna forest) were dominated by Sp ⁺ types of Frankia (coded AiSp⁺ and AiSp⁺ H. respectively), which caused effective root nodules in test plants of A. incana, but failed to induce nodules in A. nitida. In A. glutinosa Frankia strain types AiSp ⁺ and AiSp ⁺ H caused small, ineffective root nodules with sporangia (coded Ineff ^?), which were recognized by the absence or near absence of vesicles in the nodule tissue. Ineffective nodules without sporangia (coded Ineff ^?) were induced on A. glutinosa with soil samples collected at Lammi swamp. The spore-negative strain type of Frankia was common in root nodules of A. glutinosa in Finland (Lammi swamp) and caused effective Sp^? type root nodules (coded AgSp ^?) in hydrocultures of A. incana, A. glutinosa and A. nitida. A different Sp ⁺ strain type of Frankia. coded AgSp⁺ Finland, was occasionally found in stands of A. glutinosa. It was clearly distinguished from strain type AiSp ⁺ by the ability to produce effective nodules on both A. glutinosa and A. incana. The nodulation capacities of soil and nodule samples were calculated from the nodulation response in hydrocutlure and served as a measure for the population density of infective Frankia particles. Sp ⁺ nodules from both strain types had equal and high nodulation capacities with compatible host species. The nodulation capacities of Sp type root nodules from A. glutinosa were consistently low. High frequencies of Frankia AiSp⁺ and AiSp⁺ H were found in the soil environment of dominant AiSp ⁺ nodule populations on A. incana. The numbers of infective particles of this strain type were insignificant in the soil environment of nearby Sp ^? nodule populations on A. glutinosa and in the former field at Hämeen-linna near the Sp⁺ nodule area in Hämeenlinna forest. Strain type AgSp^? had low undulation capacity in the soil environment of both A. incana and A. glutinosa stands, Explanations for the strong associations between Frankia strain types AiSp⁺ and AiSp ^? H and A. incana and between strain type AgSp^? and A. glutinosa are discussed in the light of host specificity and of some characteristics of population dynamics of both strain types. The possible need to adapt the concept of Frankia strain types Sp ⁺ and Sp ^? to strains with some variation in spore development was stressed by the low potentials of strain type AiSp ⁺ H to develop spores in symbioses with hydrocultures of A. incnna.     

Nodulation potential of soils from red alder stands covering a wide age range

Red alder (Alnus rubra Bong.) stands in the Pacific Northwest are the common first stage in succession following disturbance. These stands are highly productive and contribute a large amount of N to the soils as a result of their N₂-fixing symbiosis with Frankia. As these alder stands age, the soils not only increase in total N, but concentrations of NO^– ₃ increase and pH decreases as a result of nitrification. The objective of this study was to determine how the nodulation capacity of Frankia varies as red alder stands age and if differences in nodulation capacity are related to changes in soil properties. Nodulation capacity was determined by a red alder seedling bioassay for soils from red alder stands in the Oregon coast range covering a wide range of ages. Six chronosequences were sampled, each containing a young, an intermediate, and an older alder stand. Soil total N, total C, NO^– ₃, NH⁺ ₄, and pH were measured on the same soil samples. These factors as well as alder stand characteristics were compared with nodulation capacity in an attempt to identify soil characteristics typical in developing alder stands that most strongly affect nodulation capacity. Soil pH and NO^– ₃ concentration were highly correlated with nodulation capacity and with each other. Cluster analysis of the sites using these two variables identified two groups with distinctly different nodulation capacities. The cluster with the higher nodulation capacity was lower in NO^– ₃ and higher in pH than the other cluster, which included the majority of sites. There was substantial overlap in the age ranges for the two clusters and there was no significant correlation between age and nodulation capacity. Thus nodulation capacity appears to be most closely related to soil properties than to stand age.     

Natural rhizobial populations and nodulation status of woody legumes growing in diverse Kenyan conditions

The rhizobial populations and nodulation status of both indigenous (mainly Acacia species) and some introduced woody legume species were assessed under glasshouse conditions in soils collected from 12 sites located in different ecological zones of Kenya. The populations among the sites, as estimated by the MPN technique, varied from <3.6 to>2.3×10⁵ cells g^-1 of soil. There were some intrasite variations in population estimates depending on the trap host species, date of soil collection and the method used in sampling the soils. Nodulation in whole soil also varied across the sites with test species frequently showing higher nodulation ability in native soils. Sesbania sesban (L.) Merr. was the most prolific nodulating species while Acacia tortilis (Forsskal) Hayne was very erratic in nodulation. Nodulation of most species showed interplant and intraspecific variability within a single soil source.     

Nodulation of actinorhizal plants byFrankia strains capable of both root hair infection and intercellular penetration

Summary A morphological analysis of the initiation and development of root nodules ofElaeagnus angustifolia andMyrica cerifera inoculated with pure-culturedFrankia strains DDB 011610 or DDB 020110 was undertaken. From ultrastructural observations it was determined that both of theseFrankia strains can infectElaeagnus by an intercellular penetration mechanism andMyrica by the root hair infection mechanism. This indicates that both of these strains have the ability to infect host plant roots by either of two mechanisms. The reverse, thatElaeagnus orMyrica could be infected by both mechanisms, was not observed. The infection and nodule development processes of these two plants in combination with these strains were similar to observations made in previous studies (Miller andBaker 1985,Torrey andCallaham 1979). However, one exception was identified in the development of the prenodule ofMyrica when infected with strain 011610, in that endophytic hyphae developed vesicles within the cells of the prenodule. This event has not been described before for any of the actinorhizal genera and may be an indication of less than optimal compatibility between the host plant and the symbiont.Contribution no. 876 of the Battelle-Kettering Laboratory.     

Alnus rubra nodulation capacity of soil under five species from harvested forest sites in coastal British Columbia

Nodulation of Alnus rubra seedlings after inoculation with soil from under A. rubra, Betula papyrifera. Rubus lacianutus, R. spectabilis, and R.ursinus on 2 recently harvested sites was compared. Nodulation capacity was low compared to other published reports, ranging from 0 to 18.9 infective units cm^-3 of soil and was significantly affected by the site and plant species. Nodulation capacity of soil under alder was significantly higher than under all other species except R. spectabilis, regardless of site. The lowest nodulation capacity was found in soil under B. papyrifera.Joint appointment with Dept. of Soil Science, Faculty of Agricultural Sciences     

Frankia inoculation,soil biota,and host tissue amendment influence Casuarina nodulation capacity of a tropical soil

The effects of soil biota, Frankia inoculation and tissue amendment on nodulation capacity of a soil was investigated in a factorial study using bulked soil from beneath a Casuarina cunninghamiana tree and bioassays with C. cunninghamiana seedlings as capture plants. Nodulation capacities were determined from soils incubated in sterile jars at 21 °C for 1, 7, and 28 days, after receiving all combinations of the following treatments: ± steam pasteurization, ± inoculation with Frankia isolate CjI82001, and ± amendment with different concentrations of Casuarina cladode extracts. Soil respiration within sealed containers was determined periodically during the incubation period as a measure of overall microbial activity. Soil respiration, and thus overall microbial activity, was positively correlated with increasing concentrations of Casuarina cladode extracts. The nodulation capacity of soils inoculated with Frankia strain Cj82001 decreased over time, while those of unpasteurized soils without inoculation either increased or remained unaffected. The mean nodulation capacity of unpasteurized soil inoculated with Frankia CjI82001 was two to three times greater than the sum of values for unpasteurized and inoculated pasteurized soils. Our results suggest a positive synergism between soil biota as a whole and Frankia inoculum with respect to host infection.     

The production and utilisation of monoclonal antibodies for identification of a Frankia strain utilised as inoculum for Casuarina equisetifolia

Monoclonal antibodies were raised against Frankia 0RS020607, a strain isolated originally by H.G. Diem from nodules of Casuarina equisetifolia from Senegal. One of these antibodies, mAb8C5, was shown by ELISA to have high, but not absolute specificity for 0RS020607. This antibody was employed to investigate the mobility and persistence of 0RS020607 in plantations of C. equisetifolia. Seedlings were inoculated in pots of sand in a forest nursery with 0RS020607, with local crushed nodule suspensions or were left uninoculated. They were planted out after 5 months in experimental plots on a moderately fertile black soil site and on a low organic, oxidised red soil site. Compared with crushed nodule inoculated seedlings or uninoculated controls, growth of seedlings at transplant was improved by inoculation with Frankia 0RS020607. However, 4 years after transplant to experimental plots, the growth of trees receiving different treatments was similar. The possibility that movement of ORS 020607 between treatment plots contributed to new nodulation and enhanced growth of uninoculated trees was tested using mAb8C5 in ELISA of Frankia mycelium, extracted from the nodules of trees of the three treatments. No significant differences in reactivity were detected between nodules from uninoculated and 0RS020607 inoculated trees at either the black or the red soil sites, showing that 0RS020607 moved between treatment plots at both sites. However, at both sites, nodules from plots of trees that were inoculated originally with local crushed nodules gave reactions in ELISA that were significantly lower than values for 0RS020607 inoculated trees, possibly due to the competitive effects for new nodulation of enhancement of the indigenous population of Frankia. Serological techniques using antibodies of high specificity against Frankia strains have value for rapid screening of field samples as a preliminary for further analysis by more discriminatory techniques based on assays of genetic polymorphisms.     

Life in soil by the actinorhizal root nodule endophyte <Emphasis Type="BoldItalic">Frankia</Emphasis>. A review

Frankia is a genus of soil actinomycetes famous for its ability to form N₂-fixing root nodule symbioses with actinorhizal plants. Although Frankia strains display a high diversity in terms of ecological niches in soil, current knowledge about Frankia is dominated by its life as an endophyte in root nodules. Increased use of molecular methods has refined and expanded insights into endophyte-host specificities and Frankia phylogeny. This review has focus on Frankia as a soil organism, including its part of microbial consortia, and how to study Frankia in soil. We highlight the use of nodulation tests and molecular methods to reveal population size and genetic diversity of Frankia in soil and discuss how autoregulation of nodulation and interactions with other soil microorganisms may influence the results. A comprehensive record of published interactions between Frankia and other soil microbes is summarized.     

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.     

Occurrence of Myrica-nodulating Frankia in Hawaiian volcanic soils

The ability of Hawaiian volcanic soils to nodulate actinorhizal Myrica cerifera, Casuarina equisetifolia, and Alnus glutinosa was determined using a host-plant bioassay. Myrica-nodulating Frankia occurred in five volcanic deposits with depositional ages ranging from 20 to 162 years before present. The oldest deposit had a mean estimated nodulation capacity from 450 to 1200 times greater than those of the younger deposits. Only the oldest deposit had high moisture content, high organic matter content, and increased vegetative cover, including an abundance of actinorhizal M. faya. Casuarina- and Alnus-nodulating Frankia were not detected in any of these volcanic deposits.     

Effect of juglone on growthin vitro ofFrankia isolates and nodulation ofAlnus glutinosa in soil

Summary In vitro growth (total protein content) of 5Frankia isolates was significantly inhibited at 10^–4 M juglone (5-hydroxy-1, 4-napthoquinone) concentration, but the degree of inhibition varied with theFrankia isolate. Isolates fromAlnus crispa [Alnus viridis ssp.crispa (Ait.) Turril] were most tolerant of 10^–4 M juglone relative to controls, while an isolate fromPurshia tridentata (Pursh.) D.C. was most inhibited, displaying a dramatic decrease in growth and greatly altered morphology.Nodulation of black alder [Alnus glutinosa L. (Gaertn.)] in an amended prairie soil inoculated with aFrankia isolate from red alder (Alnus rubra Bong.) was significantly decreased by the addition of aqueous suspensions of 10^–3 M and 10^–4 M juglone. This decrease was partially independent of decreased plant growth. The addition of an equal volume of sand to the soil mixture further decreased nodulation of black alder.Frankia inoculation of the soil mixtures significantly increased the total number of nodules formed per seedling, and the degree of differences in seedling nodulation owing to juglone and soil treatments.     

Effects of Zn<Superscript>2+</Superscript> on nodulation and growth of a South American actinorhizal plant, <Emphasis Type="Italic">Discaria americana</Emphasis> (Rhamnaceae)

Discaria americana is a xerophytic shrub which lives in symbiosis with an actinomycete of the genus Frankia. The objective of this paper was to investigate the effects of high soil Zn²⁺ concentrations on growth and nodulation on the association Discaria americana–Frankia with the aim of determining if this association is suitable for improving contaminated soils. Two experiments were performed in 1 dm³ pots containing soil and different Zn additions, from 0 to 2,000 mg Zn²⁺ kg⁻¹ dry soil, with or without N fertilization. Zn additions strongly delayed shoot and root growth, but once growth was initiated, the biomass production of the plants supplied with moderate Zn amounts did not differ from the control plants. Zn reduced the final nodule number, but not the total nodule biomass. At the end of the experiment only the highest Zn treatments showed a lower nodule weight than the control plants, while N addition completely inhibited nodulation. It is concluded than Zn reduces the number of Frankia infections, but once the actinomycete is inside the roots, nodules can continue growing according to plant demand for N, compensating the reduced nodule number with more biomass. On the other hand, there is a toxic effect of Zn itself on plants when present in very high concentrations.     

Genetic Diversity of Frankia Microsymbionts from the Relict Species Myrica faya (Ait.) and Myrica rivas-martinezii (S.) in Canary Islands and Hawaii

In the Western Canary Islands, Myrica faya and Myrica rivas-martinezii (Myricaceae) are phylogenetically close, endemic, actinorhizal species presumed to be remnants either of the European or the African Tertiary floras. Unisolated Frankia strains from field-collected nodules on Tenerife, Gomera, and La Palma Islands were compared by their rrs gene and 16S–23S intergenic spacer (IGS) restriction patterns. To compare the genetic diversity of Frankia strains from within and outside the host’s native range, nodules of M. faya field plants were collected both in Canary Islands and in Hawaii, where this species is an exotic invasive. Myrica rivas-martinezii, endemic to the Canary Islands, was sparsely nodulated in the field. Frankia strains harbored in field-collected nodules of M. faya and M. rivas-martinezii belonged to the Elaeagnaceae strains’ genetic cluster and exhibited a high degree of diversity. Frankia genotypes were specific to each host species. In the Canary archipelago, we found no relationship between site of collection and Frankia genotype for M. faya. The only exceptions were strains from site 2 in Tenerife, a location with a geological history different from the other sites sampled. Hawaiian and Canarian M. faya strains had no genotypes in common, raising questions concerning the origin of M. faya-infective Frankia in Hawaii. Nodular strains of M. rivas-martinezii from nursery plants were genetically characterized and shown to be divergent from the strains of field-collected nodules and belong to the Alnus-Casuarina strains cluster. This suggests Myrica may have the potential to nodulate with a broader range of Frankia genotypes under artificial conditions than has been detected in field-collected nodules.     

Nodulation patterns of actinorhizal plants in the family rosaceae

Patterns of nodulation, growth, andFrankia — host specificity have not been well characterized for the actinorhizal genera in the family Rosaceae because of the scarcity ofFrankia isolates from these taxa. Furthermore, the few isolates available from actinorhizal Rosaceae have consistently failed to nodulate plants from the host genus. In a series of experiments, species of rosaceousDryas, Cowania, Cercocarpus, Fallugia, andPurshia were inoculated withFrankia isolates, crushedDryas actinorhizae, and neoglacial soils to ascertain whether any of these inocula would effectively induce nodulation. Neoglacial soils from Alaska and Canada nodulated not only the localDryas drummondii, but alsoCercocarpus betuloides, Cowania mexicana andPurshia tridentata from distant and ecologically diverse locales as well as nonrosaceous, actinorhizal species ofAlnus, Elaeagnus, Myrica, andShepherdia. But of eightFrankia isolates, including two fromPurshia tridentata and one fromCowania mexicana, none were able to induce nodulation onPurshia orCowania species. Globular, actinorhizae-like nodules incapable of acetylene reduction were produced onC. betuloides inoculated withFrankia isolates. Crushed nodule suspensions fromDryas drummondii nodulated rosaceousCowania, Dryas andPurshia, as well as non-rosaceousElaeagnus, Myrica, andShepherdia species. Nodules produced by inoculation ofCowania mexicana andPurshia tridentata with crushed, dried nodule suspensions fromDryas drummondii reduced acetylene to ethylene, indicating nitrogenase activity for these nodulated plants. These data suggest that a similar microsymbiont infects the actinorhizal genera in the family Rosaceae.     

Distribution ofFrankia in soils from forest and afforestation sites in northern Sweden

Summary The presence in soil ofFrankia, capable of forming nitrogen-fixing root nodules onAlnus incana (L.) Moench, was investigated. Intact soil cores from forested as well as disturbed sites were sampled and both alder-rich and alder-free sites were included in the study. Surface-sterilized alder seeds were sown in the soil cores which were kept in sterile culture tubes in a growth chamber. Root nodules with nitrogenase activity developed in soil cores from all sites studied. Thus, infective and effectiveFrankia was present in all of the soils sampled, even from sites free from actinorhizal plants and irrespective of pH and nitrogen content of the soils.     

Survival ofFrankia strains introduced into soil

Factors affecting the establishment of Alnus/Frankia symbioses were studied partly by following the survival ofFrankia strains exposed to different soil conditions, and partly by investigating the effect of pH on nodulation. TwoFrankia strains were used, both of the Sp⁻ type (sporangia not formed in nodules). One of the strains sporulated heavily, while the other formed mainly hyphae. The strains originated fromAlnus incana root nodules growing in soils of pH 3.5 and 5.0. The optimum pH for their growth in pure culture was found to be 6.7 and 6.2, respectively. The strains were introduced into twoFrankia-free soils, peat and fine sand. Their survival, measured as the persistance of nodulation capacity using the plant infection technique, was followed for 14 months. The survival curves of the strains were similar despite the morphological differences between the strains in pure culture. The nodulation capacities declined over time both at 14 and 22°C. Survival was better in soils limed to a pH above 6 than in soils at their original pH (peat 2.9, fine sand 4.2). The effect of pH on nodule formation in Alnus seedlings by theFrankia strains was studied in liquid culture. The number of nodules increased linearly within the pH range studied (3.5–5.8). No nodules were formed at pH 3.5.     

Effects of soil acidity on nodulation ofAlnus glutinosa and viability ofFrankia

Summary Black alder seedlings were grown from seed for 7 weeks in six soils limed to various pH levels and inoculated withFrankia in two inoculation-seeding time combinations (inoculated and seeded concurrently; inoculated then seeded 5 weeks after inoculation). Three mine soils and three non-mine soils were used. Soil pHs in the study ranged from 3.6 to 7.6. In the second inoculation-seeding time combination, a series of soil samples at each of the pH levels below 7.0 were relimed to pH 7.0 immediately prior to seeding. The purpose of the study was to examine the effects of soil acidity on the nodulation of black alder byFrankia and the viability ofFrankia in acid soils. Based on the average number of nodules established per seedling, soil pH was determined to be a significant factor affecting nodulation in the mine soils. The highest levels of nodulation occurred between soil pH 5.5 and 7.2. Below pH 5.5, nodulation was reduced. There was also evidence of decreased viability of the endophyte below pH 4.5.     

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.     

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.