The occurrence of coryneform bacteria in the leaf cavity of Azolla

Coryneform bacteria were found associated with the nitrogen fixing blue-green alga, Anabaena azollae in the leaf cavity of Azolla caroliniana. Plate counts indicated ca. 7,400±1,900 bacterial cells per mature leaf cavity or approximately 1 bacterial cell for every algal cell. No other type of bacterium was found in these cavities.     

Endophyte transmission and activity in the Anabaena-Azolla association

Summary The survival of Azolla was studied in an artificial system which simulated the soil/water interface and the desiccation of soil during a fallow period in lowland rice culture. Tests with non-sporulating and sporulating Azolla fronds showed that Azolla only survives with sporulated fronds. At their reappearance the Azolla fronds already harboured the Anabaena endophyte. A detailed light microscopic and transmission electron microscopic study of macro- and micros-porocarp formation and development revealed that the endophyte is transmitted by the macrosporocarps and not by the microsporocarps. The Anabaena cells within the macrosporocarps are found just below the indusium cap. These cells are not nitrogen-fixing akinetes. The free-living Anabaena cells at the stem apex and below the overarching developing leaves do not bear heterocysts and accordingly are non nitrogen-fixing. During the development of the leaf the Anabaena enters the leaf cavity, but later the pore of this, cavity closes and the imprisoned cyanobacteria are lysed before the leaf decays. As the Azolla leaves age a nitrogen-fixing capability is successively built up concomittantly with the production of heterocysts. Heterocyst frequencies of 40–50% can be found inAnabaena azollae. Usually a gradient of nitrogen-fixing capacity occurs along the Azolla rhizome with two distinct peaks at leaf number 7/8 and at leaf number 13/14 from the apex.     

Fingerprinting cyanobionts and hosts of theAzolla symbiosis by DNA amplification

Cyanobionts of six species of the aquatic fernAzolla were evaluated by specific and random DNA profiles amplified by the DNA polymerase chain reaction. Simultaneous examination of the prokaryoticAnabaena azollae and the host was achieved using primers for the chloroplast-encoded intron of the tRNA-Leucine (UAA) gene. These amplifiedtrnL intron sizes, restriction fragment length polymorphisms of the amplified 16s rRNA gene, and random amplified polymorphic DNAs demonstrated the capacity of this method for the rapid assessment of similarities amongAnabaena azollae and minorAnabaena isolates fromAzolla.     

Sub-cellular distribution of nitrogen compounds inAzolla andAnabaena by ESI and EELS analysis

Summary The sub-cellular localization of some nitrogen compounds within the leaf cavities ofAzolla filiculoides Lam. was obtained by means of electron spectroscopic imaging (ESI) and electron energy loss spectroscopy (EELS). The analyses were performed on ultrathin unstained sections of differentAzolla leaf cavities which contain epidermal hairs,Anabaena azollae Strasb. and bacteria. Net nitrogen distributions were visualized by image analysis, and nitrogen peaks were evidenced in spectra recorded in the same areas. Different distributions of nitrogen compounds were observed within the leaf cavities along the stem, in particular inside the epidermal hairs ofAzolla and the vegetative cells and heterocysts ofA. azollae.     

Antigenic differences between Anabaena azollae fresh from the Azolla fern leaf cavity and free-living cyanobacteria

Fluorescent antibody staining indicated differences in surface antigenicity in Anabaena azollae cells fresh from the leaf cavities of the fern, Azolla caroliniana, and algae which were isolated and subcultured from this fern. Such results suggest that either changes in antigenicity occur in this phycobiont during culturing or that isolation selects for an antigenically different mutant strain capable of in vitro growth.Non-Standard Abbreviations FA fluorescent antibody staining - PBS phosphate buffered saline - W microwatt - Anti-F antiserum prepared against fresh cells - Anti-N antiserum prepared against Newton's culture - FTTC fluorescein isothiocyanate To whom offprint requests should be sent     

The effects of immobilization on the biochemical,physiological and morphological features of Anabaena azollae

Anabaena azollae, a presumptive isolate from Azolla filiculoides, was immobilized in polyurethane foam, hydrophilic polyvinyl foam and alginate. When viewed by low-temperature scanning electron microscopy a thick mucilage layer covered the surface of both cells and matrix; this closely resembles the mode of attachment of the symbiont Anabaena in the Azolla leaf cavity. The heterocyst frequency of the immobilized A. azollae doubled relative to free-living cells and reached a level of 14–17%. Immobilization induced increases in both hydrogen production via nitrogenase or hydrogenase and in the rates and stabilization of acetylene reduction (N₂-fixation). Ammonia production by immobilized cells with L-methionine-D,L-sulfoximine (MSX) is greater than that of freeliving cells. Immobilized cells without MSX were, however, able to excrete ammonium at lower rates thus emulating the characteristic of the symbiotic cyanobacteria (A. azollae) in the leaf cavity of Azolla.Abbreviations Chl chlorophyll - GS glutamine synthetase - MSX L-methionine-D,L-sulfoximine - SEM scanning electron microscopy - PU polyurethane - PV polyvinyl     

Spheroplast induction inAnabaena variabilis Kütz andA. azollae stras

Summary Spheroplasts were obtained by lysozyme treatment of 48 hour (4– 8cells) akinete germlings of the cultured cyanobacteriaAnabaena variabilis andA. azollae originally isolated from the leaf cavity of the fernAzolla pinnata. The osmotic stabilizer was 0.5 M sucrose. At least 50% of the cells in a short filament became spheroplasts after 1–4 hours in lysozyme (1 mg/ml) in incubation medium at 34 °C, with greater than 75% viability after 2 hours. The spheroplasts were osmotically fragile and showed intense chlorophyll autofluorescence in UV light. In phase microscopy, treated cells appeared larger, became spherical and lost some of their optical refraction. Transmission electron microscopy confirmed the loss of the peptidoglycan layer and the partial remains of the outer membrane after lysozyme exposure. We previously obtained protoplasts ofAzolla fern leaf cells so that we now can study the recognition sites in both members of theAzolla/Anabaena nitrogen fixing symbiosis during cell wall degradation and regeneration.     

Pigment distribution and nitrogen fixation inAnabaena azollae

Summary The symbiotic heterocystous cyanobacteriumAnabaena azollae present in the leaf cavities of the water fernAzolla spp. was studied. The cyanobacteria extracted from the leaf cavities showed differences in pigment composition in three species ofAzolla, i.e A.pinnata var.pinnata, A.caroliniana and A.filiculoides, as observed by pigment absorption and epifluorescence tests. These differences suggest that of these species the cyanobiont ofA. pinnata is the most actively nitrogenfixing form. This has been confirmed by nitrogen fixation (acetylene reduction) tests. Heterocysts of the symbiont ofA. pinnata were characterized by high chlorophylla and low phycocyanin content, a low fluorescence yield of chlorophyll in the heterocysts compared to vegetative cells and a gradient of phycocyanin concentration in the vegetative cells adjacent to heterocysts. This indicates that only photosystem I is present in the heterocyst. In the two otherAzolla species quantitative shifts in the pigment composition occurred suggesting a lower nitrogen fixation activity.In the cyanobiontAnabaena azollae the heterocyst frequency could reach a value of 44–45%. It is argued that there are two generations of heterocysts in a matureAzolla plant, which are concomitant with two peaks of nitrogen fixation activity correlated with leaf age,i.e. leaf number along the main axis of the plant. At both peaks of maximal N₂-ase activity, only 20–25% of the heterocysts present are metabolically active as demonstrated by the reduction of Neotetrazolium chloride (NTC) in the heterocysts and darkening of nuclear emulsions by silver salt reduction. Vegetative cells of the cyanobiont reduce Neotetrazolium chloride (NTC) to formazan more rapidly than has been observed in the free-living heterocystous cyanobacteriumAnabaena cylindrica tested in parallel experiments. This feature may be due to a more permeable cell wall of the vegetative cells of the cyanobiont compared to the free-living form, since the vegetative cells of the symbiont play a role in cross-feeding of the host (Azolla).Evidence is obtained that only the heterocysts of the cyanobiont ofAzolla are involved in the nitrogen fixation process as in free-living heterocystous cyanobacterium species. This situation is different from other cyanobacterial symbioses such as inGunnera, Blasia andAnthoceros, where physiological modifications are reported in the symbiosis with another photosynthetic partner such as the absence of O₂ evolution and the absence of photo-fixation of CO₂ in the cyanobionts.Pigment composition and N₂-ase activity in the symbiotic cyanobacteria of three Azolla species have indicated the superiority of theA. pinnata symbiont.A. pinnata var.pinnata is a semidomesticated form used in S.E. Asia for agricultural purposes (irrigated rice culture) to increase soil fertility.It is suggested that by selection (domestication) more efficient strains (clones) can be obtained, and further that with more advanced techniques such as gene mutation and genetic manipulation even more efficient and for agriculture more beneficial clones can be obtained.     

DNA Probes Show Genetic Variation in Cyanobacterial Symbionts of the Azolla Fern and a Closer Relationship to Free-Living Nostoc Strains than to Free-Living Anabaena Strains

Twenty-two isolates of Anabaena azollae derived from seven Azolla species from various geographic and ecological sources were characterized by DNA-DNA hybridization. Cloned DNA fragments derived from the genomic sequences of three different A. azollae isolates were used to detect restriction fragment length polymorphism among all symbiotic anabaenas. DNA clones were radiolabeled and hybridized against southern blot transfers of genomic DNAs of different isolates of A. azollae digested with restriction endonucleases. Eight DNA probes were selected to identify the Anabaena strains tested. Two were strain specific and hybridized only to A. azollae strains isolated from Azolla microphylla or Azolla caroliniana. One DNA probe was section specific (hybridized only to anabaenas isolated from Azolla ferns representing the section Euazolla), and five other probes gave finer discrimination among anabaenas representing various ecotypes of Azolla species. These cloned genomic DNA probes identified 11 different genotypes of A. azollae isolates. These included three endosymbiotic genotypes within Azolla filiculoides species and two genotypes within both A. caroliniana and Azolla pinnata endosymbionts. Although we were not able to discriminate among anabaenas extracted from different ecotypes of Azolla nilotica, Azolla mexicina, Azolla rubra and Azolla microphylla species, each of the endosymbionts was easily identified as a unique genotype. When total DNA isolated from free-living Anabaena sp. strain PCC7120 was screened, none of the genomic DNA probes gave detectable positive hybridization. Total DNA of Nostoc cycas PCC7422 hybridized with six of eight genomic DNA fragments. These data imply that the dominant symbiotic organism in association with Azolla spp. is more closely related to Nostoc spp. than to free-living Anabaena spp.     

Are bacteria the third partner of theAzolla-Anabaena symbiosis?

The development of the prokaryotic colony inAzolla filiculoides indicates thatAnabaena azollae is maintained through the life cycle of the fern and present in the leaves and megasporocarps. The same biological pattern is applied to the bacteria that are also present in these structures and seems to follow a development pattern identical to the cyanobacteria and probably can be considered the third partner of this symbiotic association.     

Surface lectin binding toAnabaena variabilis and to cultured and freshly isolatedAnabaena azollae

Five fluorescein isothiocyanate (FITC)-labeled lectins and Calcofluor white ST were tested for their binding abilities to vegetative cells and heterocysts of culturedAnabaena variabilis (AVA) and toA. azollae from four species ofAzolla; toAnabaena azollae freshly isolated fromAzolla pinnata (AP),A. caroliniana (AC),A. mexicana (AX), andA. filiculoides (AF); and to cultured akinetes ofAnabaena variabilis and four isolates ofA. azollae. Heterocysts of cultured cells of threeAnabaena isolates (APC, ACC, AXC) were most intensively surface-stained with soybean agglutinin fromGlycine max (SBA)-FITC; those of AX and AC were dimly stained with wheat germ agglutinin fromTriticum vulgaris (WGA); and only heterocysts of AX were dimly stained withDolichos biflorus agglutinin (DBA). Akinetes of cultured cells stained only with ConA. Vegetative cells and heterocysts of all four fresh isolates stained with Jack Beam aglutinin fromCanavalia ensiformis (ConA). None of the cell types were stained with either peanut agglutinin fromArachis hypogea (PNA) or Calcofluor.     

Immobilization of Anabaena azollae from Azolla filiculoides in polyvinyl foam for ammonia production in a photobioreactor system

Anabaena azollae (AS-DS), isolated from Azolla filiculoides and grown in nitrogen-free medium, was immobilized in 5-mm-cube polyvinyl foam pieces and incorporated into a photobioreactor system for the production of NH₃. NH₃ was produced continuously and in significant amounts. Benlate (methyl-1-butyl-carbamoyl)-2-benzimidazole carbamate at 5 ppm and l-methionine-d,l-sulphoximine at 50 m stimulated NH₃ production continuously for a period of 1 week.S. Kannaiyan is with the Biotechnology Unit, Department of Agricultural Microbiology, Tamilnadu Agricultural University, Coimbatore-641003, Tamilnadu, India; K.K. Rao and D.O. Hall are with the Division of Life Sciences, King's College London, Campden Hill Road, London W8 7AH, UK.     

Genetic diversity and phylogeny analysis of Anabaena azollae based on RFLPs detected in Azolla-Anabaena azollae DNA complexes using nif gene probes

The cyanobacterium Anabaena has both symbiotic and free-living forms. The genetic diversity of Anabaena strains symbiotically associated with the aquatic fern Azolla and the evolutionary relationships among these symbionts were evaluated by means of RFLP (restriction fragment length polymorphism) experiments. Three DNA fragments corresponding to nif genes were cloned from the free-living cyanobacterium Anabaena PCC 7120 and used as probes. A mixture of Azolla, Anabaena and bacterial DNA was extracted from Azolla fronds and digested with two restriction enzymes. Single-copy RFLP signals were detected with two of the probes in all Azolla Anabaena examined. Multiple-copy RFLP signals were obtained from the third probe which corresponded to a part of the nif N gene. A total of 46 probe/enzyme combinations were scored as present or absent and used to calculate pairwise Nei's genetic distances among symbiotic Anaebaena strains. Phylogenetic trees summarizing phenetic and cladistic relationships among strains were generated according to three different evolutionary scenarios: parsimony, UPGMA and neighbour joining. All trees revealed identical phylogenetic relationships. Principal component analysis was also used to evaluate genetic similarities and revealed three groups: group one contains the cyanobacteria associated with plants from the Azolla section, group two contains those associated with plants from the pinnata species and group three contains those associated with plants from the nilotica species. The same groups had already been identified earlier in a random amplified polymorphic DNA (RAPD) analysis of Azolla-Anbaena DNA complexes, suggesting that the present Azolla taxonomy should be revised. We now suggest a taxonomy of Anabaena azollae that is parallel to such a revised Azolla taxonomy. An Azolla chloroplast DNA sequence derived from Oryza sativa was also used as an RFLP probe on Azolla DNA to confirm the presence of plant DNA in the total genomic DNA extracted from ferns with or without the symbiont. Our results also suggest that total DNA extracted from the Azolla-Anabaena complexes includes both plant and symbiont DNA and can be used equally well for RFLP analysis of host plant or symbiotic cyanobacteria.     

Fructose supports glycogen accumulation,heterocysts differentiation,N2 fixation and growth of the isolated cyanobiont Anabaena azollae

Cells of the cyanobiont Anabaena azollae isolated from the water fern Azolla filiculoides were found to take up and utilize fructose in the light for mixotrophic growth. Fructose was favored by the cyanobiont as a substrate over sucrose and glucose. Cell growth in the presence of 8 mM fructose led to glycogen accumulation in the cells which approached 20% of the cell dry weight within 2 to 3 days, followed by reduction of glycogen content during the fourth day. Glucose-6-phosphate dehydrogenase activity was increased 5–6-fold in the fructose grown cells from the third day of growth onwards. The frequency of heterocysts in fructose-grown cells increased from 6 to 18%, and acetylene reduction by nitrogenase was increased 3-fold in the presence of fructose as compared with control cells, with maximum values observed between the third and fifth day of mixotrophic growth. Fructose-supported growth yielded a 2–4-fold increase in cell dry weight over controls.It is suggested that fructose-supported development and growth of the cyanobiont in batch cultures may resemble its mixotrophic growth and development in situ in the leaf cavity of the host fern Azolla.Abbreviation G6PDH glucose-6-phosphate dehydrogenase     

Symbiotic algal nitrogenase activity and heterocyst frequency in sevenAzolla species after phosphorus fertilization

Seven species ofAzolla (A. caroliniana, A. microphylla, A. nilotica, A. filiculoides, A. mexicana, A. rubra, A. pinnata the last from both Malaysia and India) grown in pots of flooded soil were subjected to three different treatments with respect to P: none, single application, split application. The experiments were carried out under greenhouse conditions. Heterocyst frequency inAnabaena azollae and acetylene reducing activity (ARA) were studied in successiveAzolla leaves. Both variables increased from the first leaf (shoot apex) to the last one (before branch) in all species in the presence or absence of P. However, heterocyst frequency, ARA andAzolla biomass were all less in the treatment lacking P. Heterocyst frequency inA. azollae, ARA and biomass ofAzolla were higher when P was applied in split doses than in the other treatments.Azolla plants exhibited more ARA than the isolated leaves.     

The Azolla, Anabaena azollae Relationship: I. Initial Characterization of the Association

Cultures of Azolla caroliniana Willd. free of the symbiotic blue-green alga, Anabaena azollae, were obtained by treatment of Azolla fronds with a regimen of antibiotics. These symbiontfree plants can be maintained only on medium containing a combined nitrogen source.     

Ultrastructural ontogeny of leaf cavity trichomes inAzolla implies a functional role in metabolite exchange

Summary Anabaena azollae is associated with two types of multicellular epidermal trichomes inAzolla leaf cavities, the simple and branched hairs. The observation of transfer cell ultrastructure in some hair cells led to speculation that the cavity hairs might participate in metabolite exchange between the symbionts. The developmental ontogeny of cavity trichomes is described here, using transmission electron microscopy, with a goal of improving our understanding of possible functions of these structures in the symbiosis. The observations have established that all cells of simple and branched hairs develop the structural characteristics of transfer cells, but not simultaneously. Rather, there is an acropetal succession of transfer cell ultrastructure beginning in terminal cells, moving to body cells where present, and ending in stalk cells. The transfer cell stage is followed immediately by senescence in all hair cells. The timing of transfer cell differentiation, considered together with information from other studies, suggests that branched hairs may be involved in exchange of fixed nitrogen between the symbionts, while simple hairs may participate in exchange of fixed carbon fromAzolla toAnabaena. Contribution no. 869 from the Battelle-C. F. Kettering Research Laboratory.     

Fate of nitrogen applied as Azolla and blue-green algae (Cyanobacteria) in waterlogged rice soils—a15N tracer study

Summary ¹⁵N tracer was used to detect the extent to which nitrogen of appliedAzolla caroliniana, Anabaena variabilis andNostoc muscorum was available for assimilation by the growing rice plants in pots under 4 cm flood water for 60 days. The rate of release of nitrogen from the above biofertilizers, the amount of nitrogen remaining in the soils and the amount that was lost from the soils during this period were also examined. Previously¹⁵N-labelled biomass of Azolla, Anabaena and Nostoc to provide 40 mg N was mixed thoroughly with 0.5 kg silt loam Bangladesh soil (Sonatola series) in each of three pots used for a single treatment. Each pot received four 16 days old IR8 rice seedlings. A parallet set of experiments was conducted without rice plants.It was found that nitrogen uptake in the rice plants was increased by 91, 176 and 215% on using Azolla, Anabaena and Nostoc which resulted in increased total dry matter yields (shoot plus root) of 74, 105 and 125%, respectively. Of the total¹⁵N applied at the start, 26, 49 and 53% was released from Azolla, Anabaena and Nostoc; about 7, 14 and 13% was lost by denitrification and 74, 51 and 47% remained in the soils as the undecomposed part of the biofertilizers, respeciively, after 60 days. Of 15.76, 22.72 and 25.92 mg N assimilated by the rice plants, 48, 61 and 62% was supplied by Azolla, Anabaena and Nostoc, respectively. The rest was obtained from the soil used.In the absence of the rice plants 30, 43 and 45% of applied¹⁵N of Azolla, Anabaena and Nostoc was released, respectively, in 60 days of which 93–96% was lost as N₂ through denitrification.     

Organization of the nif genes in cyanobacteria in symbiotic association with Azolla and Anthoceros

The sizes of endonuclease digestion fragments of DNA from cyanobacteria in symbiotic association with Azolla caroliniana or Anthoceros punctatus, or in free-living culture, were compared by Southern hybridization using cloned nitrogenase (nif) genes from Anabaena sp. PCC 7120 as probes. The restriction fragment pattern produced by cyanobacteria isolated from A. caroliniana by culture through symbiotic association with Anthoceros differed from that of the major symbiotic cyanobacterium freshly separated from A. caroliniana. The results indicate that minor cyanobacterial symbionts occur in association with Azolla and that the dominant symbiont was not cultured in the free-living state. Both the absence of hybridization to an xisA gene probe and the mapping of restriction fragments indicated a contiguous nifHDK organization in all cells of the symbiont in association with Azolla. On the other hand, in the cultured isolate from Azolla and in Nostoc sp. 7801, the nifD and nifK genes are nominally separated by an interval of unknown length, compatible with the interruption of the nifHDK operon by a DNA element as observed in Anabaena sp. PCC 7120. In the above cultured strains, restriction fragments consistent with a contiguous nifHDK operon were also present at varying hybridization intensities, especially in Nostoc sp. 7801 grown in association with Anthoceros, presumably due to gene rearrangement in a fraction of the cells.Non-standard abbreviations bp base pairs - kb kilobase pairs - kd kilodaltons