FREQUENT HETEROCYST GERMINATION IN THE BLUE-GREEN ALGA GLOEOTRICHIA GHOSEI SINGH1

A unique feature, frequent heterocyst germination, has been observed in a nonsporulating mutant clone (of spontaneous origin) of the blue-green alga Gloeotrichia ghosei Singh. The controlling factor seems to be the presence of ammoniacal nitrogen in the medium. In addition, such a medium supports differentiation of successive crops of new heterocysts and their germination in the name medium and in the same algal culture. Contrary to previous observations with oilier blue-green algae, ammoniacal nitrogen does not seem to inhibit heterocyst differentiation in this alga. Both the parent alga and its mutant clone grow poorly in a nitrogen-free medium, which, although they are not completely free from bacteria, may indicate that they tire poor fixers or nonfixers. However, they form a large number of heterocysts under these conditions. The general conclusion is that the heterocysts of blue-green algae show a multiplicity of structure and function. In the present case they have reproductive function leading to direct propagation of the alga. The bearing of these findings on the interrelationships of the genera Gloeotrichia and Rivularia has been discussed. It has been concluded that the distinction between them is purely artificial.     

Action of 2,4-Dichlorophenoxyacetic Acid onNostoc linckia: Impact of Glucose and Tryptophan

2,4-Dichlorophenoxyacetic acid (2,4-D) stimulated growth and heterocyst differen- tiation ofNostoc linckia in nitrogen-free medium at lower concentrations (100 μ.g/mL) while its higher concentrations inhibited both processes and 1500 μg/mL proved to be lethal. Dry mass and specific growth rate of the alga declined with increasing concentration of 2,4-D in the range of 100–1500 μg/mL. Glucose slightly increased the heterocyst frequency without any lag in their differentiation. Tryptophan promoted growth of the alga, and formation of heterocysts (nearly three-fold). Tryptophan (50 μg/mL) complex medium with 1 mg 2,4-D per mL did not produce mature heterocysts. The filaments were fragmented at the point of hererocyst development and detached heterocysts germinatedin situ. Glucose and tryptophan protected the alga, its growth and heterocyst differentiation even at the lethal concentration of the herbicide. We are grateful to the Head, Department of Botany,Banaras Hindu University, Varanasi, for providing the necessary facilities. The first author is also grateful to the Principal,K.D. College, Kutir-Chakkey, Jaunpur, for his interest in this study.     

Regulation of CO on heterocyst differentiation and nitrate uptake in the cyanobacterium Anabaena sp. PCC 7120

AIMS: The aim of the present investigation was to study the effects of different inorganic carbon and nitrogen sources on nitrate uptake and heterocyst differentiation in the culture of cyanobacterium Anabaena sp. PCC 7120. METHODS AND RESULTS: Anabaena was cultivated in media BG11 containing combined nitrogen and supplementary NaHCO3 or CO2. Cell growth, heterocyst differentiation, nitrate reductase (NR, EC 1.7.7.2), glucose-6-phosphate dehydrogenase (G6PDH, EC 1.1.1.49) and NO uptake were analysed. The cells cultivated in BG11(0) medium with aeration were taken as reference. Experimental results showed that the differentiation frequency of heterocysts when the cells were cultivated with elevated CO2 was higher than that of the cells grown with air or bicarbonate. Heterocysts appeared unexpectedly when CO2 was introduced into the medium containing nitrate. However, no heterocysts emerged when CO2 was added to medium containing NH or urea, or when NaHCO3 was supplied to the medium with nitrate. Both nitrate uptake rate and nitrate reduction enzyme activity were depressed by the supplement of CO2 to the culture. The activity of G6PDH was enhanced with the increase in heterocyst differentiation frequency. CONCLUSION: CO2 might compete with NO for energy and electrons in the uptake process and CO2 appears favoured. This led to a high intracellular C/N ratio and a relative N limitation. So the process of heterocyst differentiation was activated to supplement nitrogen uptake. SIGNIFICANCE AND IMPACT OF THE STUDY: This study provided an attractive possibility to form more heterocysts by rapid growth of Anabaena cells cultivated in the medium containing nitrate in order to increase nitrogen fixation and hydrogen production.     

Action of 2,4-dichlorophenoxyacetic acid and rifampicin on heterocyst differentiation in the blue-green alga,Nostoc linckia

2,4-Dichlorophenoxyacetic acid, a commonly used herbicide, increased the growth of the filamentous blue-green alga,Nostoc linckia at doses upto 100 μg /ml. The herbicidetreated N₂-cultures showed enhanced heterocyst frequency and N₂-growth. Thus, the herbicide stimulated algal growth at the expense of molecular nitrogen under aerobic growth conditions. Rifampicin caused chain formation of heterocysts. This was effectively counteracted by 2,4-dichlorophenoxyacetic acid, suggesting a biological interaction between them at the level of the heterocyst spacing control mechanism.     

Effect of ammonia and sulfide on rifampicin-induced heterocyst formation inNostoc linckia

The effect of ammonia and sulfide on rifampicin-induced heterocyst differentiation was studied in the nitrogen-fixing cyanobacteriumNostoc linckia. Aerobic growth with nitrogen gas of the cyanobacterium was greatly affected by rifampicin with formation of multiple heterocysts in chains in the filaments whereas ammonia in the medium reversed the rifampicin inhibition of growth and prevented the induction of heterocysts. In a sulfide medium the suppression exerted by rifampicin on aerobic growth with nitrogen gas and heterocyst induction was found to be considerably reduced. The results suggest two interesting points,viz. that (i) rifampicin interferes with the nitrogen-fixing function of heterocysts, and (ii) it checks the synthesis of an unknown heterocyst, inhibitor and thus permits the adjacent vegetative cells to differentiate into heterocysts in chains.     

Heterocyst differentiation and tryptophan metabolism in the cyanobacterium Anabaena sp. CA

Anabaena sp. CA does not synthesize heterocysts or express nitrogenase activity when grown with nitrate as the nitrogen source. Heterocysts and nitrogenase are induced in such cultures by various tryptophan analogs. The effect does not require inhibition of de novo protein synthesis in the culture. It is restricted to tryptophan analogs only, and, more specifically, to those which can be incorporated into proteins. dl-7-Azatryptophan was effective at triggering both heterocysts and nitrogenase when incubated in the culture for only 1–2 h, even though 6–7 h was required for heterocysts to fully mature and nitrogenase activity to be expressed. Chloramphenicol completely negated this effect, supporting the idea that the analogs are either incorporated into protein themselves or trigger the synthesis of proteins which initiate complete development of mature heterocysts. Using toluene-permeabilized cells, we have shown that anthranilate synthetase, the first key enzyme in tryptophan biosynthesis, has glutamine-dependent activity. This activity can be effectively feedback inhibited by the various tryptophan analogs at concentrations which are also effective in triggering heterocyst differentiation. These data provide firm evidence for a link between tryptophan biosynthesis, nitrogenase synthesis, heterocyst differentiation, and primary ammonia assimilation.     

Nitrogen fixation and heterocysts in the blue-green alga Anabaena cylindrica

The site of nitrogen fixation in the blue-green alga Anabaenacylindrica Lemra (Fogg strain) was investigated. Less than 4%of the total nitrogen fixed during a relatively short period(5-15 min) was recovered in heterocysts. When estimated on thecellular nitrogen basis, vegetative cells can fix molecularnitrogen at the same rate as do heterocysts. There was no positivecorrelation between nitrogen fixation and heterocyst formation.Results do not support the hypothesis that the heterocyst isthe main site for nitrogen fixation in blue-green algae. ¹ This work was supported by grant (No. 38814) from the Ministryof Education. (Received July 23, 1971; )     

Anaerobic and aerobic hydrogen gas formation by the blue-green alga Anabaena cylindrica.

An investigation was made of certain factors involved in the formation of hydrogen gas, both in an anaerobic environment (argon) and in air, by the blue-green alga Anabaena cylindrica. The alga had not been previously adapted under hydrogen gas and hence the hydrogen evolution occurred entirely within the nitrogen-fixing heterocyst cells; organisms grown in a fixed nitrogen source, and which were therefore devoid of heterocysts, did not produce hydrogen under these conditions. Use of the inhibitor dichlorophenyl-dimethyl urea showed that hydrogen formation was directly dependent on photosystem I and only indirectly dependent on photosystem II, consistent with heterocysts being the site of hydrogen formation. The uncouplers carbonyl cyanide chlorophenyl hydrazone and dinitrophenol almost completely inhibited hydrogen formation, indicating that the process occurs almost entirely via the adenosine 5'-triphosphate-dependent nitrogenase. Salicylaldoxime also inhibited hydrogen formation, again illustrating the necessity of photophosphorylation. Whereas hydrogen formation could usually only be observed in anaerobic, dinitrogen-free environments, incubation in the presence of the dinitrogen-fixing inhibitor carbon monoxide plus the hydrogenase inhibitor acetylene resulted in significant formation of hydrogen even in air. Hydrogen formation was studied in batch cultures as a function of age of the cultures and also as a function of culture concentration, in both cases the cultures being harvested in logarithmic growth. Hydrogen evolution (and acetylene-reducing activity) exhibited a distinct maximum with respect to the age of the cultures. Finally, the levels of the protective enzyme, superoxide dismutase, were measured in heterocyst and vegetative cell fractions of the organism; the level was twice as high in heterocyst cells (2.3 units/mg of protein) as in vegetative cells (1.1 units/mg of protein). A simple procedure for isolating heterocyst cells is described.     

Anaerobic and Aerobic Hydrogen Gas Formation by the Blue-Green Alga Anabaena cylindrica

An investigation was made of certain factors involved in the formation of hydrogen gas, both in an anaerobic environment (argon) and in air, by the blue-green alga Anabaena cylindrica. The alga had not been previously adapted under hydrogen gas and hence the hydrogen evolution occurred entirely within the nitrogen-fixing heterocyst cells; organisms grown in a fixed nitrogen source, and which were therefore devoid of heterocysts, did not produce hydrogen under these conditions. Use of the inhibitor dichlorophenyl-dimethyl urea showed that hydrogen formation was directly dependent on photosystem I and only indirectly dependent on photosystem II, consistent with heterocysts being the site of hydrogen formation. The uncouplers carbonyl cyanide chlorophenyl hydrazone and dinitrophenol almost completely inhibited hydrogen formation, indicating that the process occurs almost entirely via the adenosine 5′-triphosphate-dependent nitrogenase. Salicylaldoxime also inhibited hydrogen formation, again illustrating the necessity of photophosphorylation. Whereas hydrogen formation could usually only be observed in anaerobic, dinitrogen-free environments, incubation in the presence of the dinitrogen-fixing inhibitor carbon monoxide plus the hydrogenase inhibitor acetylene resulted in significant formation of hydrogen even in air. Hydrogen formation was studied in batch cultures as a function of age of the cultures and also as a function of culture concentration, in both cases the cultures being harvested in logarithmic growth. Hydrogen evolution (and acetylene-reducing activity) exhibited a distinct maximum with respect to the age of the cultures. Finally, the levels of the protective enzyme, superoxide dismutase, were measured in heterocyst and vegetative cell fractions of the organism; the level was twice as high in heterocyst cells (2.3 units/mg of protein) as in vegetative cells (1.1 units/mg of protein). A simple procedure for isolating heterocyst cells is described.     

Induction of increase in the heterocyst frequency of Anabaena sp. strain ATCC33047. Effect on ammonium photoproduction

Abstract Several approaches have been followed to increase the nitrogenase level in filaments of Anabaena ATCC33047. In a nitrogen-free medium lacking added molybdate and supplemented with 10 mM tungstate, growth was impaired as a result of decreased nitrogenase activity level. Under these conditions, the filaments exhibited nitrogen starvation symptoms and a high heterocyst frequency, with heterocysts being up to 28% of the total number of cells in the filaments, while a regular pattern of heterocyst distribution was maintained. Normal nitrogenase level and nitrogen status were recovered upon molybdate addition, with resumption of growth and decrease of the heterocyst frequency with time until reaching a value of about 10%. The yield of ammonium photoproduction from N₂ by filaments displaying different heterocyst frequencies and treated with l -methionine- d,l -sulfoximine (MSX) was determined. Maximal rates were obtained with filaments containing 16% of the cells differentiated as heterocysts. Results indicate that appropriate manipulation of the heterocyst frequency leads to an improvement in the efficiency of conversion of light energy into chemical energy through photoreduction of N₂ to ammonium.     

THE HETEROCYSTS OF BLUE-GREEN ALGAE (MYXOPHYCEAE)

1. Heterocysts are found in many species of filamentous blue-green algae. They are cells of slightly larger size and with a more thickened wall than the vegetative cells. 2. Structural details of the heterocyst are: the presence of three additional wall layers, the absence of granules, sparse thylakoid network throughout, except at the poles where a dense coiling of membranes occurs. Other characters include the two pores at opposite poles ‘plugged’ with refractive material called the polar granule. 3. Peculiarities in the pigment composition of the heterocyst include an abundance of carotenoids and absence of phycobilins, and a short-wave form of chlorophyll a. 4. Unique glycolipids and an acyl lipid, not found in the vegetative cells of the algae or in other plant cells, are associated with the heterocyst. The glycolipids constitute the laminated layer of the wall and probably regulate diffusion of substances through it, whereas the acyl lipids are supposed to function as carriers and intermediates in the biosynthesis of the wall. 5. The heterocysts develop from vegetative cells, and the visible changes during differentiation include cell enlargement, synthesis of additional wall layers, disappearance of granules and reorientation and synthesis of the thylakoids. 6. Heterocysts are formed sequentially with characteristic cellular spacing during the growth of cultures in medium free from combined nitrogen. 7. Various sources of combined nitrogen inhibit heterocyst formation when supplied in the culture medium. Ammonium salts are among the most powerful inhibitors. Heterocysts are formed simultaneously and within a short period after transference of ammonia-grown non-heterocystous filaments to ammonia-free medium. 8. Incompletely differentiated heterocysts or proheterocysts are found in cultures grown in the presence of combined nitrogen. If two or more proheterocysts are close together generally a single one develops to maturity after a competitive interaction in medium free from combined nitrogen. This indicates that heterocyst formation is completed in two phases: phase I, synthesis and conservation of macromolecules, which takes place during growth in ammonia-containing medium: and phase 11, morphological differentiation of the heterocyst which is unaccompanied by growth in cell number. In the ammonia-free medium phase 11 quickly succeeds phase 1 and the whole process appears as a continuum. 9. Heterocyst formation shows a definite requirement for light. Red light favours heterocyst formation, whereas green and blue light do not. The effects of light seem to be mainly due to photosynthesis, although some effects may be morphogenetic. 10. Studies with metabolic inhibitors have revealed the involvement of photosynthesis, respiration and protein synthesis in heterocyst formation. Photosynthesis provides carbon skeletons, whereas ATP is most probably supplied by oxidative metabolism. 11. Various functions have been assigned to the heterocyst from time to time. Their role in akinete formation is suggested by (i) the formation of akinetes adjacent to the heterocysts and (ii) prevention of sporulation by detachment of the heterocysts from the vegetative cells (potential akinetes). Despite substantial evidence for such a role, it is not applicable to all akinete-forming genera. 12. Heterocysts are now widely believed to be the site of nitrogen fixation in blue-green algae. The main facts in favour of such a role are: (i) fixation of nitrogen by all heterocystous algae, (ii) inhibition of heterocyst formation by combined nitrogen and (iii) direct observations on acetylene reduction by isolated heterocysts. 13. Some non-heterocystous and unicellular algae, and vegetative cells of heterocystous algae fix nitrogen under microaerophilic conditions suggesting that absence of oxygen favours nitrogenase activity. Heterocysts lack the oxygen-evolving photo-system 11, possess oxidative enzymes, and reduce externally supplied tetrazolium salts - all indicating that they are the most suitable sites for harbouring nitrogenase in aerobic conditions. 14. Heterocysts probably originated in the Precambrian in response to the earth's changing environment and seem to be the first example of morphological differentiation in the plant kingdom.     

The Anabaena sp. strain PCC 7120 asr1734 gene encodes a negative regulator of heterocyst development

The novel asr1734 gene of Anabaena (Nostoc) sp. strain PCC 7120 inhibited heterocyst development when present in extra copies. Overexpression of asr1734 inhibited heterocyst development in several strains including the wild type and two strains that form multiple contiguous heterocysts (Mch phenotype): a PatS null mutant and a hetR(R223W) mutant. Overexpression of asr1734 also caused increased nblA messenger RNA levels, and increased loss of autofluorescence in vegetative cells throughout filaments after nitrogen or sulphur depletion. Unlike the wild type, an asr1734 knockout mutant formed 5% heterocysts after a nitrogen shift from ammonium to nitrate, and formed 15% heterocysts and a weak Mch phenotype after step-down to medium lacking combined nitrogen. After nitrogen step-down, the asr1734 mutant had elevated levels of ntcA messenger RNA. A green fluorescent protein reporter driven by the asr1734 promoter, P(asr1734)-gfp, was expressed specifically in differentiating proheterocysts and heterocysts after nitrogen step-down. Strains overexpressing asr1734 and containing P(hetR)-gfp or P(patS)-gfp reporters failed to show normal patterned upregulation 24 h after nitrogen step-down even though hetR expression was upregulated at 6 h. Apparent orthologues of asr1734 are found only in two other filamentous nitrogen-fixing cyanobacteria, Anabaena variabilis and Nostoc punctiforme.     

Evidence for a role of glutamine synthetase in assimilation of amino acids as nitrogen source in the cyanobacterium Nostoc muscorum.

Methylammonium/ammonium ion, glutamine, glutamate, arginine and proline uptake, and their assimilation as nitrogen sources, was studied in Nostoc muscorum and its glutamine synthetase-deficient mutant. Glutamine served as nitrogen source independent of glutamine synthetase activity. Glutamate was not metabolised as a nitrogen source but still inhibited nitrogenase activity and diazotrophic growth. Glutamine synthetase activity was essential for the assimilation of N2, ammonia, arginine and proline as nitrogen sources but not for the control of their transport, heterocyst formation, and production of ammonia or aminoacid dependent repressor signal for N2-fixing heterocysts. These results also suggest that glutamine synthetase serves as the sole route of ammonia assimilation and glutamine synthesis, and ammonia per se as the repressor signal for N2-fixing heterocysts and methylammonium (ammonium) transport.     

Eucaryote thermophily: role of lipids in the growth of Talaromyces thermophilus

Metabolically active heterocysts were isolated from a mutant of Anabaena sp. strain CA with fragile vegetative cells. Heterocysts isolated from cultures grown in 1% CO2 in air reduced C2H2 at 57 and 10 nmol of C2H2 per mg (dry weight) per min under H2 and Ar, respectively. However, if whole filaments were sparged with 1% CO2 in 99% Ar for 12 h before heterocyst isolation, these heterocysts showed C2H2 reduction rates of 83 nmol of C2H4 per mg (dry weight) per min under either H2 or Ar, or 40% the activity of whole filaments grown in 1% CO2 in air. Heterocysts isolated from cultures sparged with 100% Ar or 1% CO2 in 99% N2 had the same C2H2 reduction pattern as heterocysts from cultures grown in 1% CO2 in air, i.e., low activity under Ar and high activity under H2. Labeling of whole filaments incubated with NaH14CO3 for 12 h under 1% CO2 in air or 1% CO2 in 99% Ar resulted in a twofold higher accumulation of 14C-labeled compounds in vegetative cells and heterocysts of Ar-incubated cells. Our results suggest that during incubation under 1% CO2 in 99% Ar, presumably a nitrogen starvation condition, continuing photosynthetic fixation of CO2 leads to accumulation of material(s) in the heterocysts that supports a high, persistent endogenous rate of C2H2 reduction. This material appears to be, in part, glycogen.     

Synthesis of nitrogenase and heterocysts by Anabaena sp. CA in the presence of high levels of ammonia.

Anabaena sp. CA fails to synthesize heterocysts and nitrogenase when grown with KNO3 as the nitrogen source. By contrast, both heterocysts and proheterocysts are synthesized in NH4Cl-containing media to a level nearly commensurate with cells grown in the absence of combined nitrogen. The growth rate of the organism in NH4Cl-containing media was similar to that obtained with KNO3 as the nitrogen source and was independent of the presence of N2 in the atmosphere. Thus, our results indicate that the organism assimilated nitrate and ammonium nitrogen equally well to meet the nitrogen requirements for growth. Moreover, in contrast to previous studies with other cyanobacteria, the repressor singal for heterocyst differentiation in Anabaena sp. CA is not derived from the metabolism of ammonia but appears to be involved with nitrate metabolism. Nitrogenase activity was partially expressed in NH4Cl-grown cultures. Increasing the level of nitrogenase activity to a value representative of a N2-grown culture required both the inhibition of ammonia assimilation and de novo protein synthesis. An increase in the number of mature heterocysts was not required. The fact that high levels of exogenous ammonia only partially repress the synthesis of proteins required for the maximum expression of nitrogenase activity in Anabaena sp. CA has important implications.     

Some Observations on the Pattern of Sporulation in a Blue-green Alga, Anabaena doliolum

Sporulation in Anabaena doliolum begins in the middle of thetwo heterocysts and proceeds towards the heterocystous ends.Two inorganic nitrogen sources—potassium nitrate and ammoniumchloride inhibit sporulation, whereas glucose promotes it. Duringsporulation, the reductive ability of the heterocyst graduallydiminishes. It is concluded that spore differentiation in this alga is controlledby critical levels of nitrogen and of sugar in the cell. Thecritical levels are probably regulated by the heterocyst.     

Correlation between nitrogenase and glutamine synthetase expression in the cyanobacterium Anabaena cylindrical

Distribution pattern and levels of nitrogenase (EC 1.7.99.2) and glutamine synthetase (GS, EC 6.3.1.2) were studied in N₂-, NO₃^? and NH₄⁺ grown Anabaena cylindrica (CCAP 1403/2a) using immunogold electron microscopy. In N₂- and NO₃^? grown cultures, heterocysts were formed and nitrogenase activity was present. The nitrogenase antigen appeared within the heterocysts only and showed an even distribution. The level of nitrogenase protein in the heterocysts was identical with both nitrogen sources. In NO₃^? grown cells the 30% reduction in the nitrogenase activity was due to a corresponding decrease in the heterocyst frequency and not to a repressed nitrogenase synthesis. In NH₄^? grown cells, the nitrogenase activity was almost zero and new heterocysts were formed to a very low extent. The heterocysts found showed practically no nitrogenase protein throughout the cytoplasm, although some label occurred at the periphery of the heterocyst. This demonstrates that heterocyst differentiation and nitrogenase expression are not necessarily correlated and that while NH₄⁺ caused repression of both heterocyst and nitrogenase synthesis, NO₃^? caused inhibition of heterocyst differentiation only. The glutamine synthetase protein label was found throughout the vegetative cells and the heterocysts of all three cultures. The relative level of the GS antigen varied in the heterocysts depending on the nitrogen source, whereas the GS level was similar in all vegetative cells. In N₂- and NO₃⁺ grown cells, where nitrogenase was expressed, the GS level was ca 100% higher in the heterocysts compared to vegetative cells. In NH₄⁺ grown cells, where nitrogenase was repressed, the GS level was similar in the two cell types. The enhanced level of GS expressed in heterocysts of N₂ and NO₃^? grown cultures apparently is related to nitrogenase expression and has a role in assimilation of N₂derived ammonia.     

Heterocyst and akinete induction with altered pattern in Anabaena cylindrica,caused by neo-peptone

Neo-peptone B119 (Difco) was found to have a significant effect on differentiation of heterocysts and akinetes in Anabaena cylindrica. On adding neopeptone (0.4 g/l) to exponential phase culture of A. cylindrica, the following effects were observed (i) increased heterocyst frequency with altered heterocyst spacing and presence of double and multiple heterocysts after 24 h in cultures grown on N-free medium, (ii) induction of regular pattern of heterocysts after 48 h, in culture grown on medium supplemented with NH₄Cl, (iii) induction of pro-akinetes after 48 h in both N-free and ammonium-grown cultures. The higher concentrations of neo-peptone were lytic to A. cylindrica, and, its lytic and inductive effects could be decreased by acid hydrolysis or supplementation of NH₄Cl. Gel-filtration of neo-peptone showed that the inductive as well as the lytic effect was associated with some active factor(s) with molecular weight between 10,000–20,000. The retention of the inductive effect on autoclavation but its loss on trypsin digestion suggested that active factor(s) may be heat stable polypeptide(s). The heterocyst induction by active factor(s) decreased and akinete induction increased with increasing culture age. The pro-akinetes induced during exponential phase divided before maturation, while those induced during late exponential phase, could achieve full maturity. Growth and nitrogenase activity was unaffected while there was an increase in mean cell length on treatment of A. cylindrica with active factor(s) from neo-peptone, indicating that the effect may be mediated through cell division process(es).Abbreviations used N Nitrogen - chl chlorophyll