The Accumulation and Degradation Dynamics of Cyanophycin in Cyanobacterial Cells Grown in Symbiotic Associations with Plant Tissues and Cells

Five different artificial associations of cyanobacterial cells with the cells or tissues of nightshade and rauwolfia were studied. The associations grown on nitrogen-containing media produced heterocysts. Cyanobacterial cells in the associations retained their ability to take up combined nitrogen from the medium, to store it in the form of cyanophycin granules, and to use them in the process of symbiotic growth. The synthesis and degradation of cyanophycin granules in cyanobacterial cells were more active in the associations than in monocultures. In the symbiotic associations of Chlorogloeopsis fritschii ATCC 27193 with Solanum laciniatum cells and of Nostoc muscorum CALU 304 with the Rauwolfia serpentina callus, heterocysts were produced with a 3- to 30-fold higher cyanophycin content than in pure cyanobacterial cultures. In contrast, in the association of N. muscorum CALU 304 with the Solanum dulcamara callus, heterocysts were produced with a lower cyanophycin content than in the N. muscorum CALU 304 pure culture. The degradation of cyanophycin granules in N. muscorum CALU 304 cells grown in associations with plant tissues or cells was subjected to mathematical analysis. The activation of cyanophycin degradation and heterocyst differentiation in the associations N. muscorum CALU 304–R. serpentinaand C.fritschii–S. laciniatum was accompanied by an enhanced synthesis of the nitrogen-containing alkaloids in plant cells. The data obtained suggest that an integrated system of nitrogen homeostasis can be formed in symbiotic associations. Depending on the growth stage of an association, its plant member can either stimulate the accumulation of combined nitrogen in vegetative cyanobacterial cells in the form of cyanophycin granules, activate their degradation, or initiate the formation of heterocysts independently of the cyanobacterial combined nitrogen deprivation sensing-signaling pathway.     

Spatial integration of partners and heteromorphism of cyanobacterium Nostoc muscoum CALU 304 in mixed culture with Rauwolfia

A comparative morphological study was conducted of Nostoc muscorum CALU 304 grown either as a pure culture on standard media or as a mixed culture with Rauwolfia callus tissue on a medium for plant tissue cultivation. The interaction of the cyanobacterial and plant partners results in their spatial integration into aggregates of specific anatomy, which arise periodically during the mixed culture growth. The morphology of the cyanobacterial cells varies depending on their localization in the combined aggregate. The degree of cyanobacterial heteromorphism increases with time of growth of the association. Evidence of the plant origin of the factors inducing heteromorphic changes in N. muscorum was obtained, as well as evidence indicating that these factors can rapidly diffuse in agarized medium. A conclusion is inferred that the heteromorphic cells correspond to bacterial forms that appear during unbalanced growth as an adaptation to altered environmental conditions.     

Ultrastructure of the cell surface of heteromorphic Nostoc muscorum CALU 304 cocultured with Rauwolfia tissue]

The ultrastructure of the heteromorphic cells (HMCs) of the cyanobacterium Nostoc muscorum CALU 304 grown in pure culture, monoculture, and a mixed culture with the Rauwolfia callus tissue was studied. The comparative analysis of the cell surface of HMCs, the frequency of the generation of cell forms with defective cell walls (DCWFs), including protoplasts and spheroplasts, and the peculiarities of the cell surface ultrastructure under different growth conditions showed that, in the early terms of mixed incubation, the callus tissue acts to preserve the existing cyanobacterial DCWFs, but begins to promote their formation in the later incubation terms. DCWFs exhibited an integrity of their protoplasm and were metabolically active. It is suggested that structural alterations in the rigid layer of the cell wall may be due to the activation of the murolytic enzymes of cyanobacteria and the profound rearrangement of their peptidoglycan metabolism caused by the Rauwolfia metabolites diffused through the medium. These metabolites may also interfere with the functioning of the universal cell division protein of bacteria, FtsZ. In general, the Rauwolfia callus tissue promoted the unbalanced growth of the cyanobacterium N. muscorum CALU 304 and favored its viability in the mixed culture. The long-term incubation of the Rauwolfia tissue with the N. muscorum CALU 304 cells led to their transformation to L-forms.     

Formation of giant and ultramicroscopic forms of Nostoc muscorum CALU 304 during cocultivation with Rauwolfia tissues

The study of heteromorphic Nostoc muscorum CALU 304 cells, whose formation was induced by 6- to 7-week cocultivation with the Rauwolfia callus tissues under unfavorable conditions, revealed the occurrence of giant cell forms (GCFs) with a volume which was 35-210 times greater than that of standard cyanobacterial cells. Some GCFs had an impaired structure of the murein layer of the cell wall, which resulted in the degree of impairment of the cell wall ranging from the mere loss of its rigidity to its profound degeneration with the retention of only small peptidoglycan fragments. An analysis of thin sections showed that all GCFs had enlarged nucleoids. The photosynthetic membranes of spheroplast-like GCFs formed vesicles with the contents analogous to that of nucleoids (DNA strands and ribosomes). About 60% of the vesicles had a size exceeding 300 nm. With the degradation of GCFs, the vesicles appeared in the intercellular slimy matrix. It is suggested that the vesicles are analogous to elementary bodies, which are the minimal and likely primary reproductive elements of L-forms. The data obtained in this study indicate that such L-forms may be produced in the populations of the cyanobionts of natural and model syncyanoses. Along with the other known cyanobacterial forms induced by macrosymbionts, L-forms may represent specific adaptive cell forms generated in response to the action of plant symbionts.     

Developmental patterns related to nitrogen fixation in theNostoc-Gunnera magellanica Lam. symbiosis

Developmental patterns related to nitrogen fixation in the heterocystous cyanobacteriumNostoc harboured in distinct colonies along the stem ofGunnera magellanica Lam. plantlets were examined using successive plant sections. Pronounced morphological, physiological and biochemical alterations in the cyanobacterium were demonstrated. Close to the growing apex the cyanobacterial biomass, contained in smallGunnera cells, was low and consisted mostly of vegetative cells showing a high density of different storage structures except for cyanophycin granules. In contrast, both the total and specific nitrogenase activity and the relative nitrogenase protein level were at maximum within this part; while the frequency of heterocysts increased from zero to 30% within the same area. The nitrogenase protein was localized only in the heterocysts throughout the plant. Further down theGunnera stem there was a progressive increase in both the cyanobacterial biomass and the heterocyst frequency, which finally constituted about 60% of the cyanobacterial cell population. Throughout this part of the stem, cyanophycin granules were frequent in the vegetativeNostoc cells. At the base of the stem, degeneratedNostoc cells dominated and the nitrogenase activity was close to zero, although the nitrogenase protein remained. Degeneration of theNostoc cells and leaf shedding coincided. Both intact plants (approx. 20 mm in height) and plant stem sections (2 mm in length) showed substantial nitrogenase activity, although sectioning caused a 30% reduction in total nitrogenase activity.     

Spatial integration of the partners and heteromorphism of the cyanobacteriumNostoc muscorum CALU 304 in a mixed culture with theRauwolfia tissue

A comparative morphological study was conducted ofNostoc muscorum CALU 304 grown either as a pure culture on standard media or as a mixed culture withRauwolfia callus tissue on a medium for plant tissue cultivation. The interaction of the cyanobacterial and plant partners results in their spatial integration into aggregates of specific anatomy, which arise periodically during the mixed culture growth. The morphology of the cyanobacterial cells varies depending on their localization in the mixed aggregate. The degree of cyanobacterial heteromorphism increases with the time of growth of the association. Evidence of the plant origin of the factors inducing heteromorphic changes inN. muscorum was obtained, as well as evidence indicating that these factors can rapidly diffuse in agarized medium. A conclusion is inferred that the heteromorphic cells correspond to bacterial forms that appear during unbalanced growth as an adaptation to altered environmental conditions.     

A mutant of the cyanobacterium Anabaena variabilis ATCC 29413 lacking cyanophycin synthetase: growth properties and ultrastructural aspects

The gene cphA encoding cyanophycin synthetase was interrupted in Anabaena variabilis ATCC 29413 by insertional mutagenesis. The mutant lacked cyanophycin granules and the polar nodules of heterocysts. The mutant grew as fast as the wild-type irrespective of the nitrogen source at low light intensity whereas growth on N(2) was somewhat reduced in high light. It is concluded that cyanophycin metabolism and polar nodules are not essential for aerobic N(2) fixation.     

Surface Ultrastructure of the Heteromorphic Cells of Nostoc muscorumCALU 304 in a Mixed Culture with the RauwolfiaCallus Tissue

The ultrastructure of the heteromorphic cells (HMCs) of the cyanobacterium Nostoc muscorumCALU 304 grown in pure culture, monoculture, and a mixed culture with the Rauwolfiacallus tissue was studied. The comparative analysis of the cell surface of HMCs, the frequency of the generation of cell forms with defective cell walls (DCWFs), including protoplasts and spheroplasts, and the peculiarities of their ultrastructure under different growth conditions showed that, in the early terms of mixed incubation, the callus tissue acts to preserve the existing cyanobacterial DCWFs, but begins to promote their formation in the later incubation terms. DCWFs exhibited an integrity of their protoplasm and were metabolically active. It is suggested that structural alterations in the rigid layer of the cell wall may be due to the activation of the murolytic enzymes of cyanobacteria and the profound rearrangement of their peptidoglycan metabolism caused by the Rauwolfiametabolites diffused through the medium. These metabolites may also interfere with the functioning of the universal cell division protein of bacteria, FtsZ. In general, the Rauwolfiacallus tissue promoted the unbalanced growth of the cyanobacterium N. muscorumCALU 304 and favored its viability in the mixed culture. The long-term mixed cultivation substantially augmented the probability of the formation of L-forms of N. muscorumCALU 304.     

Cellular differentiation in the cyanobacterium Nostoc punctiforme

Nostoc punctiforme is a phenotypically complex, filamentous, nitrogen-fixing cyanobacterium, whose vegetative cells can mature in four developmental directions. The particular developmental direction is determined by environmental signals. The vegetative cell cycle is maintained when nutrients are sufficient. Limitation for combined nitrogen induces the terminal differentiation of heterocysts, cells specialized for nitrogen fixation in an oxic environment. A number of unique regulatory events and genes have been identified and integrated into a working model of heterocyst differentiation. Phosphate limitation induces the transient differentiation of akinetes, spore-like cells resistant to cold and desiccation. A variety of environmental changes, both positive and negative for growth, induce the transient differentiation of hormogonia, motile filaments that function in dispersal. Initiation of the differentiation of heterocysts, akinetes and hormogonia are hypothesized to depart from the vegetative cell cycle, following separate and distinct events. N. punctiforme also forms nitrogen-fixing symbiotic associations; its plant partners influence the differentiation and behavior of hormogonia and heterocysts. N. punctiforme is genetically tractable and its genome sequence is nearly complete. Thus, the regulatory circuits of three cellular differentiation events and symbiotic interactions of N. punctiforme can be experimentally analyzed by functional genomics.     

Formation of Giant and Ultramicroscopic Forms of Nostoc muscorum CALU 304 during Cocultivation with Rauwolfia Tissues

The study of heteromorphic Nostoc muscorum CALU 304 cells, whose formation was induced by 6- to 7-week cocultivation with the Rauwolfia callus tissues under unfavorable conditions, revealed the occurrence of giant cell forms (GCFs) with a volume which was 35–210 times greater than that of standard cyanobacterial cells. Some GCFs had an impaired structure of the murein layer of the cell wall, which resulted in a degree of impairment of the cell wall ranging from the mere loss of its rigidity to its profound degeneration with the retention of only small peptidoglycan fragments. An analysis of thin sections showed that all GCFs had enlarged nucleoids. The photosynthetic membranes of spheroplast-like GCFs formed vesicles with contents analogous to that of nucleoids (DNA strands and ribosomes). About 60% of the vesicles had a size exceeding 300 nm. With the degradation of GCFs, the vesicles appeared in the intercellular slimy matrix. It is suggested that the vesicles are analogous to elementary bodies, which are the minimal and likely primary reproductive elements of L-forms. The data obtained in this study indicate that such L-forms may be produced in the populations of the cyanobionts of natural and model syncyanoses. Along with the other known cyanobacterial forms induced by macrosymbionts, L-forms may represent specific adaptive cell forms generated in response to the action of plant symbionts.     

A cyanobacterial recombination study, involving an efficient N2-fixing non-heterocystous partner

Many filamentous cyanobacteria fix atmospheric nitrogen under natural conditions in specialized anaerobic compartments, heterocysts, interspersed between vegetative cells, which provide protection to the O2-sensitive nitrogenase. A few unicellular cyanobacterial strains are also known to fix nitrogen aerobically at a slower rate. Filamentous cyanobacteria lacking heterocysts are not known so far to fix nitrogen. We describe the isolation and purification of a non-heterocystous filamentous cyanobacterium from the fronds of the water-fern Azolla, fixing nitrogen at 18.7+/-0.2 n moles ethylene microg Chl. a(-1) h(-1) when grown in nitrogen-free medium at a low level of oxygen between two layers of agar. This strain of Anabaena azollae has been designated as het- nif+ (non-heterocystous and nitrogen-fixing), and is found to be easily and effectively preserved in nitrogen-free medium in standard synthetic cyanobacterial nutrient medium (pH 8.5) at a continuous light intensity of 2800 lx at 25+/-1 degrees C. This het- nif+ strain is an effective donor of the nif+ marker to a het+ nif- strain of another cyanobacterium, Nostoc muscorum, when both are grown together in a recombination study.     

Nitrogen metabolism and ultrastructure inAnabaena cylindrica

Nitrogen starvation, effected by incubating a culture ofAnabaena cylindrica in a medium free from combined nitrogen and under an atmosphere of 1% CO₂ in argon, leads to rapid and characteristic changes in the appearance, structure and function of the alga. Change of colour, due apparently to a decrease in the amounts of nitrogenous pigments, is accompanied by a structural transformation of vegetative cells: cyanophycin granules and polyhedral bodies disintegrate, lipid and glycogen accumulate, and large membrane-bound spaces form by means of thylakoid swelling and vesiculation. The rate of heterocyst differentiation and nitrogenase activity is increased. These changes are fully reversed on addition of ammonia to the culture. It appears that thylakoids reform by coalescence of small vesicles assembled in the intrathylakoidal space. Rapid ammonia assimilation is indicated by ample formation of cyanophycin granules in vegetative cells and of “plugs” in the heterocysts.     

Sub-cellular Localization of Calcium in Azolla-Anabaena Symbiosis by Chlortetracycline,ESI and EELS

The subcellular localization of calcium in cells of symbiotic partners located within leaf cavities of Azolla was investigated by using chlorotetracycline, ESI and EELS analysis. Loosely membrane-bound calcium was evidenced by using CTC or EGTA and CTC, in cytoplasmic regions of Azolla hair cells and in cytoplasm of the cyanobiont. Tightly membrane-bound calcium revealed by CTC, and ESI and EELS analysis, was observed in cyanophycin granules and carboxysomes of the cyanobiont. A third calcium type, revealed by ESI and EELS analysis, was localized at the level of cell walls of simple and branched Azolla hairs, in the envelope of heterocysts, and in the cell walls of the cyanobiont.     

Ultrastructural characterisation of cells specialised for nitrogen fixation in a non-heterocystous cyanobacterium,Trichodesmium spp.

Summary Trichodesmium is the first described example of a filamentous cyanobacterium without heterocysts that contains cells specialised for nitrogen fixation. The ultrastructure of cells with and without nitrogenase were compared using primarilyTrichodesmium tenue Wille, but alsoT. thiebautii Gomont andT. erythraeum Ehrenberg et Gomont. Immunohistochemistry demonstrated that the cytoplasm of certain cells was densely labelled with antibodies against Fe-protein (dinitrogenase reductase). Comparative TEM-image analysis revealed that these cells were also distinguished by a denser thylakoid network, dividing the vacuole-like space into smaller units. The nitrogenase-containing cells also exhibited less extensive gas vacuoles as well as fewer and smaller cyanophycin granules compared to cells which lacked nitrogenase. Carboxysomes were present in both cell types in equal proportion. Longitudinal sections showed that cells with nitrogenase were arranged adjacent to each other, and that groups of cells with and without nitrogenase may coexist in the same trichome. The correlation between modifications in ultrastructure and the presence of nitrogenase suggests a new type of cyanobacterial cell specialisation related to nitrogen fixation. The results obtained also question the systematic affiliation of the genusTrichodesmium.     

Nitrogen limitation and recovery in the cyanobacterium Aphanocapsa 6308

The effects of nitrogen limitation and recovery on nitrogen-containing macromolecules were followed in the cyanobacterium Aphanocapsa 6308. Removal of nitrogen from growth media triggers the degradation of the endogenous nitrogen reserves phycocyanin and cyanophycin granule polypeptide in the cyanobacterium Aphanocapsa 6308. Nitrogen recovery involves immediate synthesis of cyanophycin granule polypeptide with peak levels of 5–12% of cell dry weight found 8–12 h after a utilizable nitrogen source is added. A rapid decrease in cyanophycin granule polypeptide level then occurs and the level remains low even in light-limited stationary growth with all nitrogen sources tested except nitrate and ammonia. Protein and phycocyanin recoveries began 3 h after a utilizable nitrogen source was added. Data suggest continuous activity of the enzyme system synthesizing cyanophycin granule polypeptide in nitrogen-limited cells, but synthesis of a degrading system only after nitrogen recovery begins.Nonstandard Abbreviations CGP Cyanophycin granule polypeptide - CAP chloramphenicol - PC phycocyanin To whom offprint requests should be sent     

Immuno-gold localization of glutamine synthetase in a nitrogen-fixing cyanobacterium (Anabaena cylindrica)

Localization of glutamine synthetase in thin sections of nitrogen-fixing Anabaena cylindrica was performed using immuno-gold/transmission electronmicroscopy. The enzyme was present in all of the three cell types possible; vegetative cells, heterocysts and akinetes. The specific gold label was always more pronounced in heterocysts compared with vegetative cells, and showed a uniform distribution in all three types. No specific label was associated with subcellular inclusions such as carboxysomes, cyanophycin granules and polyphosphate granules. When anti-glutamine synthetase antiserum was omitted, no label was observed.Abbreviation GS glutamine synthetase     

The isocitrate dehydrogenase from cyanobacteria

The present communication describes the properties of isocitrate dehydrogenase in crude extracts from the unicellular Anacystis nidulans and from heterocysts and vegetative cells of Nostoc muscorum and Anabaena cylindrica. The activity levels of this enzyme are much higher in heterocysts than in vegetative cells of N. muscorum and A. cylindrica. Isocitrate dehydrogenase is virtually inactive in vegetative cells of A. cylindrica. The enzyme is negatively regulated by the reduction charge and scarcely affected by oxoglutarate in the three cyanobacteria. The inhibition by ATP and ADP is competitive with respect to isocitrate and NADP+ in A. cylindrica and N. muscorum and noncompetitive in A. nidulans. Isocitrate dehydrogenase from the three cyanobacteria seems to be a hysteretic enzyme. All the experimental data suggest that the major physiological role of isocitrate and the isocitrate dehydrogenase in heterocysts is not to generate reducing equivalents for N2-fixation. Oxoglutarate formed by the enzyme reaction is likely required for the biosynthesis of glutamate inside the heterocysts. Thioredoxin preparations from spinach chloroplasts or from A. cylindrica activate isocitrate dehydrogenase from either heterocysts or vegetative cells of A. cylindrica. Activation is completed within seconds and requires dithiothreitol besides thioredoxin. The thioredoxin preparation which activates isocitrate dehydrogenase also activates NADP+-dependent malate dehydrogenase from spinach chloroplasts or heterocysts of A. cylindrica. Isocitrate dehydrogenase from A. cylindrica is deactivated by oxidized glutathione. It is speculated that isocitrate dehydrogenase and thioredoxin play a role in the differentiation of vegetative cells to heterocysts.     

Regulation of cellular differentiation in filamentous cyanobacteria in free-living and plant-associated symbiotic growth states.

Certain filamentous nitrogen-fixing cyanobacteria generate signals that direct their own multicellular development. They also respond to signals from plants that initiate or modulate differentiation, leading to the establishment of a symbiotic association. An objective of this review is to describe the mechanisms by which free-living cyanobacteria regulate their development and then to consider how plants may exploit cyanobacterial physiology to achieve stable symbioses. Cyanobacteria that are capable of forming plant symbioses can differentiate into motile filaments called hormogonia and into specialized nitrogen-fixing cells called heterocysts. Plant signals exert both positive and negative regulatory control on hormogonium differentiation. Heterocyst differentiation is a highly regulated process, resulting in a regularly spaced pattern of heterocysts in the filament. The evidence is most consistent with the pattern arising in two stages. First, nitrogen limitation triggers a nonrandomly spaced cluster of cells (perhaps at a critical stage of their cell cycle) to initiate differentiation. Interactions between an inhibitory peptide exported by the differentiating cells and an activator protein within them causes one cell within each cluster to fully differentiate, yielding a single mature heterocyst. In symbiosis with plants, heterocyst frequencies are increased 3- to 10-fold because, we propose, either differentiation is initiated at an increased number of sites or resolution of differentiating clusters is incomplete. The physiology of symbiotically associated cyanobacteria raises the prospect that heterocyst differentiation proceeds independently of the nitrogen status of a cell and depends instead on signals produced by the plant partner.     

Isolation and characterization of chlorate-resistant mutants of the blue-green alga Nosoc muscorum.

Spontaneous chlorate-resistant (Clr) mutants of three classes were isolated from Nostoc muscorum under three different selective conditions. A Clr-N2 class of mutants lacked nitrate reductase and showed nitrate inhibition of nitrogen fixation. A Clr-NO3 group of het+ nif- mutants formed heterocysts, but lacked nitrogen fixation and active nitrogenase enzyme. The Clr-NO2 class included those mutants deficient in both active nitrogenase and nitrate reductase, as they were unable to grow at the expense of molecular nitrogen or with nitrate nitrogen. The results suggest a common genetic determinant of active nitrogenase and nitrate reductase in the blue-green alga N. muscorum.