Frankia-Alnus incana symbiosis: Effect of endophyte on nitrogen fixation and biomass production

The efficiency of different FinnishFrankia strains as symbionts onAlnus incana (L.) Moench was evaluated in inoculation experiments by measuring nitrogen fixation and biomass production. Since all available pure cultures ofFrankia are of the Sp⁻ type (sporangia not formed in nodules), but the dominant nodule endophyte ofA. incana in Finland is of the Sp⁺ type (sporangia formed in nodules), crushed nodules of thisFrankia type were included. The Sp⁻ pure cultures, whether originating fromA. incana orA. glutinosa, produced with one exception, similar biomass withA. incana. The highest biomass was produced with an American reference strain fromA. viridis crispa. Using Sp⁺ nodule homogenates fromA. incana as inoculum, the biomass production was only one third of that produced by Sp⁻ pure cultures from the same host. Hence, through selection of the endophyte it is possible to exert a considerable influence on the productivity ofAlnus incana.     

Study of the contribution of the shoot and/or root ofAlnus sp. in the compatibility between the host and a Sp+ Frankia strain using a grafting technique

Two alder species,Alnus glutinosa (L.) Gaertn. andAlnus incana (L) Moench, were inoculated with a Sp⁺ Frankia homogenate obtained fromA. incana root nodules. This inoculum formed effective nodules on the original host plant and ineffective nodules onA. glutinosa. Grafts between the two alder species were made to determine which part of the plant is involved in this phenomenon. The results obtained indicate that the compatibility between Alnus andFrankia is restricted to the root system.     

Frankia Populations in Soil and Root Nodules of Sympatrically Grown Alnus Taxa

The genetic diversity of Frankia populations in soil and in root nodules of sympatrically grown Alnus taxa was evaluated by rep-polymerase chain reaction (PCR) and nifH gene sequence analyses. Rep-PCR analyses of uncultured Frankia populations in root nodules of 12 Alnus taxa (n?=?10 nodules each) growing sympatrically in the Morton Arboretum near Chicago revealed identical patterns for nodules from each Alnus taxon, including replicate trees of the same host taxon, and low diversity overall with only three profiles retrieved. One profile was retrieved from all nodules of nine taxa (Alnus incana subsp. incana, Alnus japonica, Alnus glutinosa, Alnus incana subsp. tenuifolia, Alnus incana subsp. rugosa, Alnus rhombifolia, Alnus mandshurica, Alnus maritima, and Alnus serrulata), the second was found in all nodules of two plant taxa (A. incana subsp. hirsuta and A. glutinosa var. pyramidalis), and the third was unique for all Frankia populations in nodules of A. incana subsp. rugosa var. americana. Comparative sequence analyses of nifH gene fragments in nodules representing these three profiles assigned these frankiae to different subgroups within the Alnus host infection group. None of these sequences, however, represented frankiae detectable in soil as determined by sequence analysis of 73 clones from a Frankia-specific nifH gene clone library. Additional analyses of nodule populations from selected alders growing on different soils demonstrated the presence of different Frankia populations in nodules for each soil, with populations showing identical sequences in nodules from the same soil, but differences between plant taxa. These results suggest that soil environmental conditions and host plant genotype both have a role in the selection of Frankia strains by a host plant for root nodule formation, and that this selection is not merely a function of the abundance of a Frankia strain in soil.     

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.     

The improvement and utilization in forestry of nitrogen fixation by actinorhizal plants with special reference toAlnus in Scotland

Summary Alnus species are used widely in Britain for land reclamation, forestry and other purposes. Rapid juvenile growth of the AmericanAlnus rubra makes it an attractive species for planting on N-deficient soils, particularly those of low organic content. In small plot trials, this species is nodulated by indigenous soil frankiae as effectively asAlnus glutinosa. Over a three year period both species return similar amounts of N to the ecosystem, estimated at up to 10–12 kg N ha^–1. Several strains ofFrankia have been isolated from local (Lennox Forest)A. rubra nodules. These differ morphologically and in their growth on different culture media, both from each other and fromA. glutinosa nodule isolates. AllAlnus isolates, however, have a total cellular fatty acid composition qualitatively similar to some other Group B frankiae. Glasshouse tests in N free culture suggest thatA. rubra nodules formed after inoculation of seedlings with American spore (–) isolates are three times more effective in N fixation than those inoculated with LennoxA. rubra spore (+) nodule homogenates. By contrast, the early growth of seedlings inoculated with spore (–)Frankia strains suggests at best a 35% improvement in N fixing activity over seedlings inoculated with LennoxA. rubra nodule isolates. Nevertheless, this improvement in activity, together with the better performance of seedlings inoculated with isolates compared with those treated with crushed nodule preparations, suggest that it would be worthwhile commercially to inoculate nursery stock with a spore (–)Frankia strain.     

Distribution of spore-positive and spore-negative nodules in stands ofAlnus glutinosa andAlnus incana in Finland

Summary The distribution of spore positive (Sp⁺) and spore negative (Sp⁻) nodules on the two native alder species (A. incana andA. glutinosa) in Finland was investigated. Nodules were collected throughout the country from different ecosystems (forests, swamps, lake- sea- and riversides, old pastures and fields as well as from alder plantations). OnA. incana Sp⁺ nodules predominated, whereas onA. glutinosa the vast majority of the nodules were of the Sp⁻ type. Sp⁺ nodules onA. glutinosa were found only at sites where the two alder species grew close together. This distribution pattern indicates an association of nodule type with alder species, the reasons for which are discussed. Indications of saprophytic growth in the Sp⁻ strain were also found.     

Effective nodulation ofCoriaria myrtifolia L. induced byFrankia strains fromAlnus glutinosa L. (Gaertn.)

The present contribution covers the cross-inoculation between two actinorhizae belonging to different genera and families, mainlyAlnus glutinosa andCoriaria myrtifolia. Frankia strains isolated fromA. glutinosa received from the Netherlands (LDAgp₁r₁, LDAgn₁) and from Scotland (UGL010708), induced a fully effective nodulation onC. myrtifolia. The same effect was caused by a nodule extract fromA. glutinosa. The reverse, a crushed-nodule inoculum fromC. myrtifolia nodulated all theA. glutinosa seedlings, though nodules formed were less effective than those induced by the other inocula. Re-isolation of thoseFrankia strains from the nodules formed onA. glutinosa was readily obtained, whereas attempts to re-isolate them from the nodules formed onC. myrtifolia failed, suggesting that isolation procedures different to those employed should be tried.     

Biomass production and nitrogen utilization by Alnus incana when grown on N2 or NH 4 + made available at the same rate

A single clone of Alnus incana (L.) Moench was grown in a controlled-environment chamber. The plants were either inoculated with Frankia and fixed atmospheric nitrogen or were left uninoculated but received ammonium at the same rate as the first group fixed their nitrogen. Nitrogen fixation was calculated from frequenct measurements of acetylene reduction and hydrogen evolution. The diurnal variation of acetylene reduction was also taken into account. The relative efficiency of nitrogenase could be used in the calculations of fixed nitrogen since the Frankia used did not show any detectable hydrogenase activity. Alders fixing nitrogen developed more biomass, longer shoots, larger leaf areas and contained more nitrogen than alders receiving ammonium. In one experiment, almost all ammonium given to the non-nodulated alders was taken up and 15% of the nitrogen taken up was excreted. In the other experiment, 34% of the ammonium was left in the nutrient solution and 8% of the nitrogen taken up was excreted. Alders inoculated with Frankia did not excrete any detectable amount of nitrogen. It seems that the energy demand for nitrogen fixation is not so high that biomass production in alders is retarded. The symbiotic system of A. incana and Frankia seems to be more efficient in utilizing its nitrogen than non-symbiotic A. incana receiving ammonium.     

Selection and micropropagation of nodulating and non-nodulating clones ofAlnus crispa (Ait.) Pursh

Summary 600,000 seedlings ofAlnus crispa were inoculated with a 111 mixture of theFrankia strains ACN1 ^AG , AGN1 _exo ^AG and MGP10i. After 3 successive inoculations and screenings, one individual, AC-4, was selected as non-nodulating (Nod^–) with Frankiae. This selected individual AC-4 (Nod^–) and two other clones ofA. crispa, AC-2 and AC-5, known for their ability to nodulate (Nod⁺) and two other clones ofA. crispa, AC-2 and AC-5, known for their ability to nodulate (Nod⁺) withFrankia werein vitro propagated. The different clones ofA. crispa in culture required different kinds and concentrations of sugar during the in vitro multiplication and rooting stages. Nodulation tests using 7Frankia strains indicated that the clone AC-4 (Nod^–) was non-nodulating with 6 of the 7Frankia strains tested. One strain,Frankia ANNI, isolated from one unique nodule produced on the mother-plant AC-4, induced 38% of the AC-4 plantlets to nodulate but with a number of nodules 10 to 20 times less than the clones AC-2 (Nod⁺) and AC-5 (Nod⁺). Morphological observations of the roots of AC-4 (Nod^–) indicated that this clone had few and abnormally short root hairs.     

Growth responses and N and P use efficiency of three Alnus species as affected by arbuscular-mycorrhizal colonisation

In this study it was determined how different species ofAlnus (A. cordata, A. incana and A. glutinosa) responded tocolonisation by arbuscular mycorrhizal (AM) fungi (Glomusmosseae or Glomus intraradices) with regard togrowth and their ability to acquire and utilise nitrogen and phosphorus.Non-mycorrhizal plants but with phosphorus added, were used as control. InA. glutinosa the application of 75 ppm P hadsimilar effect on growth and P acquisition as did AM. Nevertheless,A.cordata and A. incana grew poorly when suppliedwith 75 ppm of P and required AM symbiosis for optimum growth andNand P uptake. The percentage increases in shoot dry biomass in AM colonised ascompared with P-fertilised plants were 441 (A. cordata)and644 (A. incana) whilst AM-colonised A.glutinosa matched P-fertilised plants. Plant shoot N/P ratioincreased in response to AM-colonisation indicating that mycorrhizal effects onN uptake are greater than on P uptake. Information concerning the directinfluence of AM on N acquisition and nutrient use efficiency byAlnus species is important. AM-colonisation provides anexcellent biological mechanism by which Alnus plantsbecamemore efficient P-users. That Alnus sp. are highlymycorrhizal-dependent plants was apparent because AM-colonisation was criticalfor growth of A. incana and A.cordata. In this respect, for maximizing the efficient uptake anduseof N and P, under the growth conditions provided, Alnusplants need to be mycorrhizal. AM symbiosis seems decisive for the successfulestablishment of Alnus sp. in revegetation strategies. Thelow N and P availability in soils where Alnus species areuseful candidates in any recolonisation and reclamation process emphasises theneed to investigate systems by which N and P uptake byAlnus plants can be enhanced.     

Detection of pectolytic activity andpel homologous sequences inFrankia

Using a cup-plate pectin agar assay, pectolytic activity was detected in nodule filtrates obtained fromAlnus rugosa (DuRoi) Spreng,A. glutinosa (L.) Gaertn andA. crispa (Ait.) Pursh seedlings after infection with twoFrankia strains (ACN1 ^AG , CpI1). Pectolytic activity was also detected in cultures filtrates of the same twoFrankia isolates afterin vitro-cultivation on Qmod pectin liquid medium. When Southern blots of Frankia total DNAs from 3 isolates ofF. alni subsp.Pommerii (ACN1 ^AG , ArI3, and CPX32b) and 3 isolates ofF. elaeagni (EUN1 pec, SCN 10a and TX31e ^HR ) were hybridized withPelBDA probes fromErwinia chrysanthemi, positive signals were found in all 7 Frankiae tested.     

Growth promoting effect of Azospirillum brasilense on Casuarina cunninghamiana Miq. seedlings

The growth of Casuarina cunninghamiana seedlings was stimulated when inoculated with Azospirillum brasilense. This resulted in a higher biomass production than in uninoculated controls in the presence or absence of a non-nodulating strain of Frankia.Increase in whole plant dry weight was due to a significant increase in both shoot and root biomass, which corresponded with a higher total N content of the plants inoculated with Azospirillum. No such effects were observed under inoculation with a non-nodulating Frankia strain. These results suggest that the growth-promoting substances provided by A. brasilense may have enhanced the growth of Casuarina seedlings.     

Identification of Frankia strains in nodules by hybridization of polymerase chain reaction products with strain-specific oligonucleotide probes

A set of oligonucleotides has been developed to study the competitivity of two Frankia strains in the nodulation of the roots of two host plant species: Alnus glutinosa and Alnus incana. Two 20 mer-oligonucleotides, complementary to highly conserved sequences inside the nifH gene, were used as primers for the polymerase chain reaction (PCR) system in order to amplify microsymbiont DNA extracted from actinorhizae. PCR products were analyzed using two strain-specific 15-mer oligonucleotides identified in the amplified region. Hybridization data indicate that strain ACoN24d is more competitive than train ArI3 in the nodulation of both hosts.     

Studies in tetrapartite symbioses

Alnus incana seedlings were successfully inoculated with an endomycorrhizal fungus (Glomus fasciculatus), an ectomycorrhizal fungus (Paxillus involutus) and an isolate ofFrankia (ACN1) simultaneously. The effects of the inoculation treatments on the growth performance of the seedlings were evaluated under controlled conditions.The overall growth performance of the seedlings inoculated with the three organisms was better than those inoculated withFrankia, G. fasciculatus andP. involutus individually or withFrankia+G. fasciculatus andFrankia+P. involutus combinations. The highest growth performance and mycorrhizal infection occurred when the seedlings were inoculated simultaneously withFrankia+G. fasciculatus+P. involutus.     

Growth increment ofAlnus glutinosa upon dual inoculation with effective and ineffectiveFrankia strains

Investigations on the ecological function of ineffectiveFrankia strains and their behaviour in competition with effectiveFrankia strains indicated an enhanced plant growth upon dual inoculation with increasing amounts of effective (i.e. N₂-fixing)Frankia strains and simultaneous inoculation with a constant amount of an ineffectiveFrankia strain. Enhanced plant growth was measured as increase in plant height and total dry weight at constant shoot/root ratio. The stimulating effect of the ineffective strain was independent of the plant clone and was obtained with bothAlnus glutinosa clones W I and B II, which were resistant and susceptable, respectively, to the ineffective strain. Stimulation was also independent of the nodulation conditions. Short-term studies (7 weeks) under axenic conditions and greenhouse experiments during 3 months showed comparable results, not only in plant growth but also in nodule formation. Increment in plant growth was not necessarily correlated to higher nodule formation with the effectiveFrankia strains.     

Effects of some pure and mixedFrankia strains on seedling growth in differentAlnus species

In greenhouse experiments plants of eightAlnus species, from various parts of the world, and from different taxonomic sections, were inoculated with threeFrankia strains in order to show any possible interaction. Mixtures in equal parts of theseFrankia strains were also tried. The growth of inoculated plants was significantly higher than of the controls, with one of the three strains being superior. Mixtures of strains generally provided higher growth than the best individual strain. No interaction betweenFrankia strains andAlnus species was detected in the young plants 60 days after inoculation. Three clones ofAlnus glutinosa were inoculated with the same pure cultures ofFrankia, without producing any interaction. Inoculation time was studied in one clone and one progeny ofAlnus glutinosa. The best results were obtained with the earlier inoculation (at sowing for the progeny and at transfer to soil for thein vitro-propagated clone). The results are discussed in terms of nursery practice and field experiments for selection in breeding programmes.     

Heterogeneity withinFrankia sp. LDAgpl studied among clones and reisolates

Summary Frankia sp. LDAgpl, an isolate from spore positive nodules ofAlnus glutinosa, only slowly infects its host plant. Reisolates obtained from occasional nodules caused by infection with LDAgpl, are capable of infecting the alder much more rapidly. A variability analysis of LDAgpl has been performed to obtain more insight into the question whether these reisolates constitute a different genotype within LDAgpl and if the plant is exerting an influence during plant passage. High dilutions of mildly sonicatedFrankia suspensions were plated to obtain genetically homogeneous colonies. Clones thus generated showed differences in growth pattern, sporulation and C₂H₂-reduction on media containing propionic acid as sole C-source (P-medium). Differences in sporulation on P-medium indicate that LDAgpl was a highly heterogeneous strain. Comparisons of sporulation on several different media gave evidence that the differences in sporulation between LDAgpl clones are the result of differences in efficiency of propionic acid utilization.The differences observed between the reisolates and LDAgpl clones indicate that the reisolates constitute a different genotype, which could be selected for by the plant during the infection process. Comparison with similar changes in phenotype occuring in a spore negative type strain fromA. glutinosa is discussed.     

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.     

Evolutionary implications of nucleotide sequence relatedness between Alnus nepalensis and Alnus glutinosa and also between corresponding Frankia microsymbionts

Frankia DNAs were isolated directly from root nodules of Alnus nepalensis and Alnus nitida collected from various natural sites in India. For comparison, a nodule sample from Alnus glutinosa was also collected from Tuebingen, Germany. Nucleotide sequence analyses of amplified 16S–23S ITS region revealed that one of the microsymbionts from Alnus nepalensis was closely related to the microsymbiont from Alnus glutinosa. A similar exercise on the host was also carried out. It was found that one sample of Alnus nepalensis was closely related to Alnus glutinosa sequence from Europe. Since both Frankia and the host sequences studied revealed proximity between Alnus glutinosa and Alnus nepalensis, it is hypothesised that the common progenitor of all the alders first entered into an association with Frankia, and the symbiotic association has evolved since.     

Variable compatibility of clonedAlnus glutinosa ecotypes against ineffectiveFrankia strains

Nodulation tests onin-vitro propagated clones ofAlnus glutinosa ecotypes (forest ecotype, pioneer ecotype) withFrankia strains originating from both ecotypes indicated differences in host-plant compatibility. Inoculated plants of the pioneer ecotype clone were not infected by strains, that were unable to fix nitrogen in pure culture. Nodulation could only be induced on the clone of the forest ecotype, but no nitrogen-fixing activity could be detected. Ultra-structural observations of the nodules by SEM and TEM indicated that ineffectivity of these strains was correlated with the lack of vesicles in the infected cells. Cells were only filled with hyphae: neither sporangia nor vesicles could be detected. In contrast, effective nodules could be obtained on both alder clones after inoculation with an effective strain, showing normal development of vesicle clusters in infected cells. In pure culture the ineffective strains produced no vesicles; sporangia were found only during early stage of growth. The results demonstrate the existence ofFrankia strains which were either non-infective or ineffective on different clones ofAlnus glutinosa.