A NUMERICAL TAXONOMIC STUDY OF NOSTOC AND ANABAENA1

Thirty characteristics of 14 Nostoc and 10 Anabaena species were analyzed from previously published data. Using standard numerical taxonomic methods, simple matching coefficients were calculated and a phenogram drawn. The analysis revealed that some of the central characteristics of Nostoc are: a punctiforme stage; motile reproductive stage; plant mass with a dull to shiny luster, non-veined surface, and nonfimbriate margin; some spherical vegetative cells; no cylindrical heterocysts; and some spherical, but no cylindrical akinetes. Some of the central characteristics of Anabaena that were revealed are: no punctiforme stage; a motile vegetative stage; plant mass with a shiny luster, veined surface, and fimbriate margin; no spherical vegetative cells; some cylindrical heterocysts; and some cylindrical, but no spherical, akinetes. In general, Anabaena has larger akinetes and vegetative cells than Nostoc. Based on 30 morphological characteristics and the clustering data of the phenogram, keys were constructed for the Nostoc and Anabaena species studied. The data clearly support two separate and distinct, though similar genera and, less sharply, the separation of the 24 species. The more useful characteristics for separation of the species are size and shape of akinetes, vegetative cells, and heterocysts; color and luster of plant mass; veined plant mass surface; margin fimbriate; and shape of plant mass in nature.     

Tetrazolium reduction and nitrogenase activity in heterocystous blue-green algae

Summary Heterocysts reduce triphenyl tetrazolium chloride (TTC) faster than vegetative cells apparently because the absence of the O₂-evolving photosystem II and the high electron transport activity in these cells. Although the rate of TTC reduction in vegetative cells is increased by the continuous removal of O₂ evolved in photosynthesis, it has not been possible to obtain rates of TTC reduction comparable with those in heterocysts probably because of the continued competition for electrons between TTC and O₂. The use of nitro-blue tetrazolium chloride (NBT) as a redox indicator has revealed the presence in filaments under aerobic conditions of a gradient of electron transport activity with strongest reducing power in the heterocysts, proheterocysts and vegetative cells next to heterocysts, and with gradually diminishing activity midway between two heterocysts. This pattern is indistinct in filaments grown under micro-aerophilic conditions. The strong electron transport activity in vegetative cells adjacent to heterocysts appears to promote reducing conditions in the heterocysts. Both, red-formazan formation in the heterocysts and blue-formazan deposition in vegetative cells greatly inhibit nitrogenase activity, and this was adversely affected also by the detachment of heterocysts from vegetative cells. The findings are consistent with the idea that the association of heterocysts with vegetative cells in essential for nitrogen fixation to occur in heterocystous blue-green algae.     

14C-labeled metabolites in heterocysts and vegetative cells of Anabaena cylindrica filaments and their presumptive function as transport vehicles of organic carbon and nitrogen

To investigate the transport of primary metabolites in Anabaena cylindrica from vegetative cells into heterocysts, intact filaments were labeled with the heterocysts were separated from the vegetative cells after different time intervals, and the labeling patterns were determined. After a 20-s fixation time, a high percentage of labeling of alanine, glutamate and glutamine, and, to a lesser extent, glucose 6-phosphate was found in heterocysts as compared with whole filaments. The results can be explained if transport of alanine, glutamate, and sugars from vegetative cells into heterocysts is assumed. Alanine can serve as a precursor for reducing equivalents if it is oxidized to glutamine which flows back to the vegetative cells. This idea is supported by an experiment in which exogenous alanine is readily converted by isolated heterocysts to glutamate and glutamine under a N2-H2 atmosphere. The incorporation of [14C]carbonate in isolated heterocysts demonstrated the absence of the reductive pentose phosphate pathway; however, it revealed marked activity of an acid fixation reaction.     

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.     

Movement of Carbon from Vegetative Cells to Heterocysts in Anabaena cylindrica

Radioactive carbon assimilated by vegetative cells of Anabaena cylindrica in the light passed via an intrafilamentous route into heterocysts in the dark. After several hours, label per heterocyst approximated label per vegetative cell. Much of the label entering heterocysts was not available for diffusional exchange back into vegetative cells.     

Components and activity of the photosynthetic electron transport system of intact heterocysts isolated from the blue-green alga Nostoc muscorum

Heterocysts of the blue-green alga Nostoc muscorum have been isolated by prolonged treatment with lysozyme. Quantitative data are presented which show the occurrence of cytochromes c-553, f-557 and b-563 in heterocysts in amounts comparable to vegetative cells. Particularly the content of the water-soluble cytochrome c-553 can be used to evaluate the intactness of a heterocyst preparation. Cytochrome f-557 has been partially purified and found to be a c-type cytochrome corresponding to cytochrome f of higher plants and other algae. Cytochrome b-559 is present in vegetative cells but not in heterocysts. The content of plastoquinone in heterocysts is reduced to 42% of the amount present in vegetative cells. These data suggest a degradation of Photosystem II during heterocyst differentiation. Measurements of photosynthetic electron transport in heterocysts proved the inability of the photosynthetic apparatus to carry out electron transport with electrons donated by water or diphenylcarbazide. In Tris-washed thylakoids from vegetative cells, however, diphenylcarbazide can act as an electron donor to Photosystem II.     

Superoxide dismutase in vegetative cells, heterocysts and akinetes of Anabaena cylindrica Lemm

Abstract: Superoxide dismutase (SOD) activity was assayed in vegetative cells, heterocysts and akinetes of Anabaena cylindrica Lemm. The iron-containing isoenzyme (Fe-SOD) was in all cases predominant over the manganese-containing isoenzyme (Mn-SOD). Differentiated cells maintained the same relative content of the two enzymes as in vegetative cells. However, heterocysts and akinetes contained only 20 and 35%, respectively, of the total SOD activity present in vegetative cells.
Both Mn-SOD and Fe-SOD activities increased in all types of cells isolated from A. cylindrica grown at high light intensity. The increase of SOD in heterocysts paralleled that of nitrogenase, suggesting a role of SOD in the protection mechanism of nitrogenase.     

Continuous periplasm in a filamentous, heterocyst-forming cyanobacterium

The cyanobacteria bear a Gram-negative type of cell wall that includes a peptidoglycan layer and an outer membrane outside of the cytoplasmic membrane. In filamentous cyanobacteria, the outer membrane appears to be continuous along the filament of cells. In the heterocyst-forming cyanobacteria, two cell types contribute specialized functions for growth: vegetative cells provide reduced carbon to heterocysts, which provide N2-derived fixed nitrogen to vegetative cells. The promoter of the patS gene, which is active specifically in developing proheterocysts and heterocysts of Anabaena sp. PCC 7120, was used to direct the expression of altered versions of the gfp gene. An engineered green fluorescent protein (GFP) that was exported to the periplasm of the proheterocysts through the twin-arginine translocation system was observed also in the periphery of neighbouring vegetative cells. However, if the GFP was anchored to the cytoplasmic membrane, it was observed in the periphery of the producing proheterocysts or heterocysts but not in adjacent vegetative cells. These results show that there is no cytoplasmic membrane continuity between heterocysts and vegetative cells and that the GFP protein can move along the filament in the periplasm, which is functionally continuous and so provides a conduit that can be used for chemical communication between cells.     

四唑(Tetrazolium)对固氮鱼腥藻固氮和氢代谢的影响

固氮鱼腥藻(Anabaena azotica Ley)细胞能还原无色的TTC和NBT分别成为红色或蓝色的甲(月朁)(formazan)沉淀。异形胞还原TTC的速率高于营养细胞。前异形胞及异形胞附近的营养细胞对NBT的还原作用最强。而异形胞对NBT不起还原作用。无论在异形胞形成红色甲(月朁)或在营养细胞形成蓝色甲(月朁)后都抑制固氮酶活性。NBT甲(月朁)对固氮酶活性的抑制作用大于TTC甲(月朁),因为NBT氧化还原电位低于TTC。 TTC和NBT两者都明显地抑制固氮鱼腥藻完整细胞的放氢。因鱼腥藻的放氢是由固氮酶催化的结果。四唑抑制放氢推想是由于它截取了固氮酶催化系统中的电子的缘故。固氮微生物(包括蓝色细菌和根瘤菌)对四唑还原与吸氢酶之间有无相关是一个争论的问题。一些学者认为分离豆科植物体的一些根瘤菌株培养于含有TTC的琼脂培养基,如还原,便可证明这些根瘤菌株能氧化氢;换言之,应用TTC的还原可作为一些根瘤菌的菌落具有吸氢酶的验证。相反,我们发现固氮鱼腥藻还原TTC和NBT之后,都没有影响吸氢的能力。因此,我们推想固氮鱼腥藻对四唑之还原与吸氢酶是没有直接的关系。     

KINETICS OF CELL DEATH IN THE CYANOBACTERIUM ANABAENA FLOS-AQUAE AND THE PRODUCTION OF DISSOLVED ORGANIC CARBON1

Kinetics of cell death and the production of dissolved organic carbon (DOC) were investigated in Anabaena flos-aquae (Lyngb.) Bréb grown on three different N sources (N₂nitrate, and ammonium) in a phosphorus (P)-limited chemostat. The fraction of live cells in the total population increased as growth rate increased with decreasing P limitation. Cell death was less in nitrate and ammonium media than in N₂. The specific death rate (γ), when calculated as the slope ofv^?1_x vs. D^?1, where v_xand D are live cell fraction (or cell viability) and dilution rate, respectively, was 0. 0082 day^?1 in N₂and 0.0042 day^?1 in nitrate. The slope of the plot in ammonium culture was not significant; however, the value of the live cell fraction was within the range for the NO^?₃culture. The fraction of live vegetative cells in N₂ culture was constant at all growth rates and the increase in the overall live cell fraction with growth rate was due entirely to an increase in live heterocysts. Live heterocysts comprised 3.5% of the total cells at a growth rate of 0.25 day^?1 and increased to 6.3% at 0.75 day^?1 with the ratio of live heterocysts to live vegetative cells linearly increasing with growth rate. The fraction of live vegetative cells was invariant in nitrate cultures us in N₂cultures. The live heterocysts fraction also increased with growth rate in nitrate cultures, along with the live heterocysts : live vegetative cells ratio, but the level was lower than in N₂cultures. DOC released from dead cells increased inversely with growth rate in N₂from 36.4% of the total DOC at a growth rate of 0.75 day^?1 to 54.15% at 0.25 day^?1. The contribution of cell death to the total DOC production in nitrate and ammonium media was significantly less than that under N₂DOC from dead cells consisted mainly of high-molecular-weight compounds, whereas DOC excreted from live cells was largely of low molecular weight.     

The metabolism of glucose by heterocysts and vegetative cells of Anabaena cylindrica

Whole filaments of autotrophically grown Anabaena cylindrica and heterocysts isolated from them will assimilate and metabolise exogenous glucose. Radiorespirometric experiments suggest the operation of the pentose phosphate pathway. Glucose-6-phosphate and 6-phosphogluconate dehydrogenase are present in heterocysts at 6–8 times the levels found in vegetative cells whereas enzymes of the reductive pentose phosphate and glycolytic pathways are barely or not detectable. Glucose-6-phosphate dehydrogenase in vegetative cells, but not in heterocysts is subject to inhibition by ribulose diphosphate.     

A new method for identification of heterocysts and proheterocysts in morphologically complex cyanobacteria

A new light microscopic method for identifying heterocysts and proheterocysts in morphologically complex cyanobacteria was evaluated for reliability and usefulness. Mature heterocysts and proheterocysts could be distinguished readily from vegetative cells in 0.25 micron sections of fixed and embedded material after staining with toluidine blue. Examination by light and electron microscopy of the same specimens indicated that the staining reactions which served to differentiate these cell types were both reproducible and accurate. Light microscopic analysis of serial sections stained with toluidine blue greatly facilitated localization of heterocysts and proheterocysts in the complex, branching cyanobacterium, Mastigocladus laminosus, even when its filaments of cells were intertwined in thick mats.     

Inactivation of patS and hetN causes lethal levels of heterocyst differentiation in the filamentous cyanobacterium Anabaena sp. PCC 7120

Summary In the filamentous cyanobacterium Anabaena sp. PCC 7120 patS and hetN suppress the differentiation of vegetative cells into nitrogen-fixing heterocysts to establish and maintain a pattern of single heterocysts separated by approximately 10 undifferentiated vegetative cells. Here we show that the patS- and hetN-dependent suppression pathways are the only major factors that prevent vegetative cells from differentiating into heterocysts when a source of ammonia is not present. The patS and hetN pathways are independent of each other, and inactivation of both patS and hetN leads to differentiation of almost all cells of a filament in the absence of a source of fixed nitrogen, compared with approximately 9% in the wild type. Complete differentiation of filaments also occurs when nitrate is supplied as a source of fixed nitrogen, conditions that do not induce differentiation of wild-type filaments. However, ammonia is still capable of suppressing differentiation. The percentage of cells that differentiate into heterocysts appears to be a function of time when a source of fixed nitrogen is absent or a function of growth phase when nitrate is supplied. Although differentiation proceeds unchecked in the absence of patS and hetN expression, differentiation is asynchronous and non-random.     

A model for cell type-specific differential gene expression during heterocyst development and the constitution of aerobic nitrogen fixation ability inAnabaena sp. strain PCC 7120

When deprived of combined nitrogen, aerobically-grown filaments ofAnabaena sp. strain PCC7120 differentiate specialized cells called the heterocysts. The differentiation process is an elaborate and well orchestrated programme involving sensing of environmental and developmental signals, commitment of cells to development, gene rearrangements, intricate DNA-protein interactions, and differential expression of several genes. It culminates in a physiological division of labour between heterocysts, which become the sole sites of aerobic nitrogen fixation, and vegetative cells, that provide photosynthate to the heterocysts in return for nitrogen supplies. We propose a model, to describe the chronology of the important events and to explain how cell type-specific differential gene expression is facilitated by DNA-protein interactions leading to the development of heterocysts and constitution of nitrogen-fixing apparatus inAnabaena.     

Heterocyst differentiation in the cyanobacterium Mastigocladus laminosus.

The morphological and ultrastructural aspects of heterocyst differentiation in the branching, filamentous cyanobacterium Mastigocladus laminosus were examined with light and electron microscopy. The earliest differentiation stages involved cytoplasmic changes, including (i) rapid degradation of carboxysomes, (ii) degradation of polysaccharide granules, and (iii) accumulation of electron-dense ribosomal or protein material (or both). Intermediate differentiation stages involved synthesis of a homogeneous extra wall layer, development of necks leading to adjacent cells, and elaboration of a complex system of intracytoplasmic membranes. Late differentiation stages included further development of necks and continued elaboration of membranes. Mature heterocysts possessed a uniformly electron-dense cytoplasm that contained large numbers of closely packed membranes, some of which were arranged in lamellar stacks. Mature heterocysts lacked all of the inclusion bodies present in undifferentiated vegetative cells, but contained a number of unusual spherical inclusions of variable electron density. Cells in both narrow and wide filaments were capable of differentiating. No regular heterocyst spacing pattern was observed in the narrow filaments; the number of vegetative cells between consecutive heterocysts of any given filament varied by a factor of 10. Heterocysts developed at a variety of locations in the wide, branching filaments, although the majority of them were situated adjacent to branch points. M. laminosus displayed a marked tendency to produce sets of adjacent heterocysts or proheterocysts (or both) that were not separated from each other by vegetative cells. Groups of four or more adjacent heterocysts or proheterocysts occurred frequently in wide filaments, and in some of these filaments virtually all of the cells appeared to be capable of differentiating into heterocysts.     

Changes in thylakoid structure associated with the differentiation of heterocysts in the cyanobacterium, Anabaena cylindrica.

The thylakoids of vegetative cells of the filamentous cyanobacterium, Anabaena cylindrica, are capable of oxygen-evolving photosynthesis and contain both Photosystems I and II (PSI and PSII). The heterocysts, cells specialized for nitrogen fixation, do not produce oxygen and lack Photosystem II activity, the major accessory pigments, and perhaps the chlorophyll a associated with PSII. Freeze-fracture replicas of vegetative cells and of heterocysts reveal differences in the structure of the thylakoids. A histogram of particle sizes on the exoplasmic fracture face (E-face, EF) of vegetative cell thylakoids has two major peaks, at 75 and 100 A. The corresponding histogram for heterocyst thylakoids lacks the 100 A size class, but has a very large peak at about 55 A with a shoulder at 75 A. Histograms of protoplasmic fracture face (P-face, PF) particle diameters show single broad peaks, the mean diameter being 71 A for vegetative cells and 64 A for heterocysts. The thylakoids of both cell types have about 5600 particles/micrometers2 on the P-face. On the E-face, the density drops from 939 particles/micrometers2 on vegetative cell thylakoids to 715 particles/micrometers2 on heterocyst thylakoids. The data suggest that the 100 A E-face particle of vegetative cell thylakoids is a PSII complex. The 55 A EF particle of heterocysts may be part of the nitrogenase complex or a remnant of the PSII complex. The role of the 75 A EF particle is unknown. Other functions localized on cyanobacterial thylakoids, such as respiration and hydrogenase activity, must be considered when interpreting the structure of these complex thylakoids.     

The 2A resolution crystal structure of HetL, a pentapeptide repeat protein involved in regulation of heterocyst differentiation in the cyanobacterium Nostoc sp. strain PCC 7120

The hetL gene from the cyanobacterium Nostoc sp. PCC 7120 encodes a 237 amino acid protein (25.6kDa) containing 40 predicted tandem pentapeptide repeats. Nostoc sp. PCC 7120 is a filamentous cyanobacterium that forms heterocysts, specialized cells capable of fixing atmospheric N(2) during nitrogen starvation in its aqueous environment. Under these conditions, heterocysts occur in a regular pattern of approximately one out of every 10-15 vegetative cells. Heterocyst differentiation is highly regulated involving hundreds of genes, one of which encodes PatS, thought to be an intercellular peptide signal made by developing heterocysts to inhibit heterocyst differentiation in neighboring vegetative cells, thus contributing to pattern formation and spacing of heterocysts along the filament. While overexpression of PatS suppresses heterocyst differentiation in Nostoc sp. PCC 7120, overexpression of HetL produces a multiple contiguous heterocyst phenotype with loss of the wild type heterocyst pattern, and strains containing extra copies of hetL allow heterocyst formation even in cells overexpressing PatS. Thus, HetL appears to interfere with heterocyst differentiation inhibition by PatS, however, the mechanism for HetL function remains unknown. As a first step towards exploring the mechanism for its biochemical function, the crystal structure of HetL has been solved at 2.0A resolution using sulfur anomalous scattering.     

Quantitative and qualitative DNA variations in Anabaena azollae Strasb. living in Azolla filiculoides lam.

Heterocysts and vegetative cells of the filamentous nitrogen-fixing Anabaena azollae isolated from the apex to the basal leaf cavities of Azolla filiculoides were examined by epifluorescent microscope after fluorochrome staining. Acridine orange (AO), DAPI, and chromomycin fluorochromes were used in order to evidence total DNA content and respectively, A + T and G + C bases. Measurements of fluorescence intensities were made on photographic prints by the automatic image analysis system Quantimet 970. Heterocysts contained higher amounts of DNA than did vegetative cells, and their content strongly increased in the basal leaf cavities. The heterocyst DAPI brightness was quite uniform, whereas in vegetative cells DAPI brightness increased from the apex to the basal groups. In vegetative cells from the apex to the median group, the percentage of DAPI brightness was 60-85% with respect to AO brightness, whereas in heterocysts of the same groups DAPI brightness was 40-50% with respect to AO brightness. In the basal group, brightness due to DAPI staining was comparable with those of previous group both in heterocysts and in vegetative cells, whereas chromomycin brightness increased strongly in heterocysts. These data show that heterocyst changes its DNA content and composition in the basal leaf cavities, suggesting that its lifetime is not completely over.     

Developmental regulation of the cell division protein FtsZ in Anabaena sp. strain PCC 7120, a cyanobacterium capable of terminal differentiation

Heterocysts are terminally differentiated cells devoted to nitrogen fixation in the filamentous cyanobacterium Anabaena sp. strain PCC 7120. We show here that the cell division protein FtsZ is present in vegetative cells but undetectable in heterocysts. These results provide a first rational explanation for the inability of mature heterocysts to undergo cell division.