Modifiers of heterocyst repression and spacing and formation of heterocysts without nitrogenase in the cyanobacterium Anabaena variabilis.

Twelve amino acid analogs and related compounds were screened for their ability to induce heterocysts in ammonia-repressed, undifferential filaments of Anabaena variabilis. As has been previously described, 1-methionine-dl-sulfoximine induces both heterocysts and nitrogenase. In contrast, dl-7-azatryptophan and beta-2-thienyl-dl-alanine were found to induce heterocysts but not nitrogenase activity (measured as acetylene reduction) even under microaerobic conditions. When the initial ammonium concentration was reduced, dl-7-azatryptophan-treated cultures sequentially produced heterocysts and then nitrogenase activity, but nitrogenase was detected only when a parallel culture without analog also became capable of acetylene reduction. Neither of the two latter analogs affected gamma-glutamyl transferase activity in crude extracts. All three analogs significantly reduced the mean interheterocyst distance in nitrogen-fixing cultures.     

Adenine nucleotide levels in and nitrogen fixation by the cyanobacterium Anabaena sp. strain 7120.

Adenine nucleotide levels were determined in whole filaments of Anabaena sp. 7120 grown under different N2-fixing or non-N2-fixing conditions. These were compared with levels in isolated heterocysts, Rhodospirillum rubrum, and Azotobacter vinelandii. Adenine nucleotides in whole filaments of Anabaena sp. do not reflect the energetic expense of N2 fixation as they do in R. rubrum and A. vinelandii. However, adenine nucleotide levels in heterocysts were similar to the levels found in N2-fixing R. rubrum, i.e., an ATP:ADP ratio near 1 and an energy charge between 0.5 and 0.7. Nitrogenase activity was only 50% of optimal in permeabilized heterocysts at an exogenous ATP:ADP ratio of 3.33. Hydrogen, which increases acetylene reduction activity, also causes a transient increase (2 to 5 min) in the ATP:ADP ratio. Hydrogen has little effect on energy charge.     

D-erythrose supports nitrogenase activity in isolated Anabaena sp. strain 7120 heterocysts.

Among organic compounds tested for their ability to support nitrogenase activity in isolated heterocysts of Anabaena sp. strain 7120 under argon, D-erythrose (5 mM) was unique in supporting acetylene reduction at 10 times the control rates. Higher concentrations of D-erythrose exhibited substrate inhibition. At 50 kPa of H2, all concentrations of D-erythrose inhibited H2-supported acetylene reduction. The effects of D-erythrose on nitrogenase activity were explored. Erythrose enhanced 15N2 incorporation by heterocysts, but NADP+ did not enhance erythrose-supported acetylene reduction. H2 protected nitrogenase from O2 inactivation, but erythrose did not; erythrose did not counter protection by H2. Tests with inhibitors of electron transport showed that erythrose-supported acetylene reduction requires electron flow through ferredoxin, a b-type cytochrome, and a 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone-sensitive transfer agent whose electron flow is not mediated through the plastoquinone and Rieske iron protein.     

H2, N2, and O2 metabolism by isolated heterocysts from Anabaena sp. strain CA.

Metabolically active heterocysts isolated from wild-type Anabaena sp. strain CA showed high rates of light-dependent acetylene reduction and hydrogen evolution. These rates were similar to those previously reported in heterocysts isolated from the mutant Anabaena sp. strain CA-V possessing fragile vegetative cell walls. Hydrogen production was observed with isolated heterocysts. The ratio of C2H4 to H2 produced ranged from 0.9 to 1.2, and H2 production exhibited unique biphasic kinetics consisting of a 1 to 2-min burst of hydrogen evolution followed by a lower, steady-state rate of hydrogen production. This burst was found to be dependent upon the length of the dark period immediately preceding illumination and may be related to dark-to-light ATP transients. The presence of 100 nM NiCl2 in the growth medium exerted an effect on both acetylene reduction and hydrogen evolution in the isolated heterocysts from strain CA. H2-stimulated acetylene reduction was increased from 2.0 to 3.2 mumol of C2H4 per mg (dry weight) per h, and net hydrogen production was abolished. A phenotypic Hup- mutant (N9AR) of Anabaena sp. strain CA was isolated which did not respond to nickel. In isolated heterocysts from N9AR, ethylene production rates were the same under both 10% C2H2-90% Ar and 10% C2H2-90% H2 with or without added nickel, and net hydrogen evolution was not affected by the presence of 100 nM Ni2+. Isolated heterocysts from strain CA were shown to have a persistent oxygen uptake of 0.7 mumol of O2 per mg (dry weight) per h, 35% of the rate of whole filaments, at air saturating O2 levels, indicating that O2 impermeability is not a requirement for active heterocysts.     

Inhibition of nitrogen fixation by nitrite inAnabaena variabilis

Addition of nitrite to rapidly growing, nitrogen-fixing filaments ofAnabaena variabilis caused an immediate drop in nitrogenase activity. This was followed by a transient induction of nitrite reductase, recovery of nitrogen fixation and cyanobacterial growth. The experiments with isolated heterocysts and a partially purified nitrogenase preparation from heterocysts showed that nitrite primarily exerted its inhibitory effect by inactivating nitrogenase irreversibly, rather than interfering with photosynthetic energy conservation.Abbreviations ATCC American type culture collection - Chl chlorophyll - FCCP carbonyl cyanide p-trifluoromethoxy phenylhydrazone - Tes 2-{[2 hydroxy-1,1-bis(hydroxymethyl)ethyl] amino} ethane sulfonic acid     

Mechanism of nitrogenase switch-off by oxygen.

Oxygen caused a reversible inhibition (switch-off) of nitrogenase activity in whole cells of four strains of diazotrophs, the facultative anaerobe Klebsiella pneumoniae and three strains of photosynthetic bacteria (Rhodopseudomonas sphaeroides f. sp. denitrificans and Rhodopseudomonas capsulata strains AD2 and BK5). In K. pneumoniae 50% inhibition of acetylene reduction was attained at an O2 concentration of 0.37 microM. Cyanide (90 microM), which did not affect acetylene reduction but inhibited whole-cell respiration by 60 to 70%, shifted the O2 concentration that caused 50% inhibition of nitrogenase activity to 2.9 microM. A mutant strain of K. pneumoniae, strain AH11, has a respiration rate that is 65 to 75% higher than that of the wild type, but its nitrogenase activity is similar to wild-type activity. Acetylene reduction by whole cells of this mutant was inhibited 50% by 0.20 microM O2. Inhibition by CN- of 40 to 50% of the O2 uptake in the mutant shifted the O2 concentration that caused 50% inhibition of nitrogenase to 1.58 microM. Thus, when the respiration rates were lower, higher oxygen concentrations were required to inhibit nitrogenase. Reversible inhibition of nitrogenase activity in vivo was caused under anaerobic conditions by other electron acceptors. Addition of 2 mM sulfite to cell suspensions of R. capsulata B10 and R. sphaeroides inhibited nitrogenase activity. Nitrite also inhibited acetylene reduction in whole cells of the photodenitrifier R. sphaeroides but not in R. capsulata B10, which is not capable of enzymatic reduction of NO2-. Lower concentrations of NO2- were required to inhibit the activity in NO3- -grown cells, which have higher activities of nitrite reductase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation and characterization of heterocysts from Anabaena sp. strain CA

A comparative study has been made on the pigment composition and nitrogenase activity of whole filaments and isolated beterocysts from a mutant strain of Anabaena CA. The whole cell absorption spectra of intact filaments and isolated heterocysts showed close resemblance especially between 550–700 nm region. On a quantitative basis the chlorophyll a content was found almost equal between the vegetative cell and heterocyst but the c-phycocyanin content in the heterocyst was about 1/2 that of the vegetative cell. The purification of the phycobiliprotein on DEAE-cellulose showed the presence of c-phycocyanin (_max 615 nm) and allophycocyanin (_max 645 nm, shoulder 620 nm). Isolated heterocysts under H₂ showed acetylene reduction rates of 57 nmol C₂H₄/mg dry wt·min (342 mol C₂H₄/mg chl a·h), whereas intact filaments reduced at the rate of 18 nmol C₂H₄/mg dry wt·min (108 mol C₂H₄/mg chl a·h). This rate accounts for 30% recovery of nitrogenase activity in isolated heterocysts compared to whole filaments. The activity was strictly light dependent and was linear under H₂ for more than 3 h. Addition of as little as 5% H₂ under argon stimulated the C₂H₂ reductionseveral fold. The acetylene reduction (nitrogenase activity) also showed tolerance to 5% added O₂ either under H₂ or argon. The results suggest that the heterocyst of Anabaena CA-V is different in some characteristics (viz., higher endogenous C₂H₂ reduction rate, prolonged activity and higher levels of phycobiliproteins) than those reported in other Anabaena species.     

Isolation of cyanobacterial heterocysts with high and sustained dinitrogen-fixation capacity supported by endogenous reductants

A method is described for the preparation of cyanobacterial heterocysts with high nitrogen-fixation (acetylene-reduction) activity supported by endogenous reductants. The starting material was Anabaena variabilis ATCC 29413 grown in the light in the presence of fructose. Heterocysts produced from such cyanobacteria were more active than those from photoautotrophically-grown A. variabilis, presumably because higher reserves of carbohydrate were stored within the heterocysts. It proved important to avoid subjecting the cyanobacteria to low temperatures under aerobic conditions, as inhibition of respiration appeared to lead to inactivation of nitrogenase. Low temperatures were not harmful in the absence of O₂. A number of potential osmoregulators at various concentrations were tested for use in heterocyst isolation. The optimal concentration (0.2M sucrose) proved to be a compromise between adequate osmotic protection for isolated heterocysts and avoidance of inhibition of nitrogenase by high osmotic strength. Isolated heterocysts without added reductants such as H₂ had about half the nitrogen-fixation activity expected on the basis of intact filaments. H₂ did not increase the rate of acetylene reduction, suggesting that the supply of reductant from heterocyst metabolism did not limit nitrogen fixation under these conditions. Such heterocysts had linear rates of acetylene reduction for at least 2 h, and retained their full potential for at least 12 h when stored at 0°C under N₂.     

Pyridine nucleotides and H2 as electron donors to the respiratory and photosynthetic electron-transfer chains and to nitrogenase in Anabaena heterocysts

The pathways through which NADPH, NADH and H₂ provide electrons to nitrogenase were examined in anaerobically isolated heterocysts. Electron donation in freeze-thawed heterocysts and in heterocyst fractions was studied by measuring O₂ uptake, acetylene reduction and reduction of horse heart cytochrome c. In freeze-thawed heterocysts and membrane fractions, NADH and H₂ supported cyanide-sensitive, respiratory O₂ uptake and light-enhanced, cyanide-insensitive uptake of O₂ resulting from electron donation to O₂ at the reducing side of Photosystem I. Membrane fractions also catalyzed NADH-dependent reduction of cytochrome c. In freeze-thawed heterocysts and soluble fractions from heterocysts, NADPH donated electrons in dark reactions to O₂ or cytochrome c through a pathway involving ferredoxin:NADP reductase; these reactions were only slightly influenced by cyanide or illumination. In freeze-thawed heterocysts provided with an ATP-generating system, NADH or H₂ supported slow acetylene reduction in the dark through uncoupler-sensitive reverse electron flow. Upon illumination, enhanced rates of acetylene reduction requiring the participation of Photosystem I were observed with NADH and H₂ as electron donors. Rapid NADPH-dependent acetylene reduction occurred in the dark and this activity was not influenced by illumination or uncoupler. A scheme summarizing electron-transfer pathways between soluble and membrane components is presented.     

Oxygen Sensitive Nitrogen-Fixing Mutants of Anabaena

Two Anabaena mutants having heterocysts but incapable of fixing molecular nitrogen in air have been isolated by using ultraviolet radiation or NTG mutagenesis. Their vegetative cells differentiated into heterocysts at a higher frequency than that of the wild type. The phenotype of the mutants is stable and a low frequence of spontaneous reversion was observed. Under microaerobic condition the mutants cells can express the genetic information which encodes nitrogenase synthesis and were capable of utilizing nitrogen for growth with a low acetylene reductiop activity. The level of nitrogenase activity was correlated reciprocally with the content of cell phycocyanin and the light intensity. Both synthesis and activity of the mutant nitrogenase were very sensitive than wild type to the oxygen in vive. Introduction of 1% O2 (v/v) into the gas phase inhibited evidently acetylene reduction. Exposure of the mutant suspension to 20% O2 (v/v) resulted in total and irreversible denaturation of nitrogenase. Withdrawing of O2 in gas phase, the nitrogenase was synthesized de nero; The synthesis process was repressed by chloramphenical or ammonia. The nitrogenase activity of mutant cells increased significantly either by nitrogen- starvating to decrease the phycocyanin content or by lowering the light intensity. Specifically, during the anaerobic induction by treating the mutants filaments with diehloromethylurea which prevents photosynthetic oxygen production, the specific activity of mutant nitrogcnase was equivalent nearly to that of wild type. The ability to reduce 2, 3, 5-triphenyltetrazolium was lower in heterocysts and vegetative cells of mutants than in that of wild type. The results suggest that the oxygen sensitivity of nitrogen fixation by heterocystous bluegreen algal mutants may be duc to the defect of some enzymic systems which might play a role in scavenging oxygen toxity, so that the process of nitrogen fixation is inhibited by the active oxygen produced by vegetative cells. The mechanism of protecting nitrogenase from oxygen damage in blue-green algae is discussed.     

Cyanobacterial N2 fixation in presence of nitrogen fertilizers

Anabaena oryzae ARM 570 was examined for its growth (chlorophyll and protein), heterocyst frequency, nitrogenase (acetylene reduction) activity, ammonia excretion, and glutamine synthetase and nitrate reductase in response to two levels of urea-N vis-à-vis N2-N. Growth of cyanobacterium increased with duration of incubation. Reduction in heterocyst frequency (40%) was observed at 30 ppm of urea-N, whereas at 60 ppm of urea-N, filaments were completely devoid of heterocysts and no nitrogenase activity was observed. Maximum excretion of ammonia occurred at 30 ppm of urea-N, which was concomitant with minimum glutamine synthetase activity. These results suggested that A. oryzae could be effectively utilized in cyanobacterial biofertilizer programme even in the presence of combined nitrogen, for improving N-budget in rice cultivation.     

Cellular differentiation and nitrogenase activity in the cyanobacteriumAnabaena

Nitrogenase activity at periods of differentiation of heterocysts and akinetes was assayed by the acetylene reduction technique. There was no nitrogenase activity in ammoniumgrown, non-heterocystousAnabaena sp.; the activity appeared only after a lag-phase of about 17 – 21 h after the ammonium-grown culture had been transferred to medium free of combined nitrogen. This activity started appearing as the proheterocysts were developing to mature heterocysts. Maximum nitrogenase activity was attained with exponential phase of culture and mature heterocysts. This activity gradually decreased with the differentiation of akinetes. Only insignificant nitrogenase activity was observed in old cultures in which most cells had matured into akinetes.     

Physiological Studies of Oxygen Protection Mechanisms in the Heterocysts of Anabaena cylindrica

The mechanism of O₂ protection of nitrogenase in the heterocysts of Anabaena cylindrica was studied in vivo. Resistance to O₂ inhibition of nitrogenase activity correlated with the O₂ tension of the medium in which heterocyst formation was induced. O₂ resistance also correlated with the apparent K_m for acetylene, indicating that O₂ tension may influence the development of a gas diffusion barrier in the heterocysts. The role of respiratory activity in protecting nitrogenase from O₂ that diffuses into the heterocyst was studied using inhibitors of carbon metabolism. Reductant limitation induced by 3-(3,4-dichlorophenyl)-1, 1-dimethylurea increased the O₂ sensitivity of in vivo acetylene reduction. Azide, at concentrations (30 mM) sufficient to completely inhibit dark nitrogenase activity (a process dependent on oxidative phosphorylation for its ATP supply), severely inhibited short-term light-dependent acetylene reduction in the presence of O₂ but not in its absence. After 3 h of aerobic incubation in the presence of 20 mM azide, 75% of cross-reactive component I (Fe-Mo protein) in nitrogenase was lost; less than 35% was lost under microaerophilic conditions. Sodium malonate and monofluoroacetate, inhibitors of Krebs cycle activity, had only small inhibitory effects on nitrogenase activity in the light and on cross-reactive material. The results suggest that oxygen protection is dependent on both an O₂ diffusion barrier and active respiration by the heterocyst.     

Phosphorylation and nitrogenase activity in isolated heterocysts from Anabaena variabilis (ATCC 29413)

Adenylate-pool composition, energy charge, and nitrogenase activity were examined in isolated heterocysts from Anabaena variabilis (ATCC 29413). ATP formation was detected as a light- or oxygen-induced increase in ATP concentration. No cofactors or substrates had to be added for photophosphorylation to occur, whereas oxidative phosphorylation was dependent on hydrogen and oxygen (Knallgas reaction). The increase in ATP concentration was reflected by a decrease in AMP concentration, accompanied by small changes in ADP levels. Thus, a regulation of the adenylate pool by a myokinase (adenylate kinase) has to be assumed. Upon dark-light transitions, the energy charge in heterocysts increased from values below 0.4 to values approaching 0.8. High energy-charge values, reached in the light only, allowed for high rates of acetylene reduction in the presence of hydrogen. The increase in the energy charge in the dark to approx. 0.64 by addition of oxygen (5% ($\text{v}\text{v}$) in the presence of hydrogen) resulted in low nitrogenase activities, generally not exceeding 1–3% of the light-induced rates. In the dark, oxygen concentrations above 10% were inhibitory to both ATP formation and acetylene reduction. Increasing light intensities led to a steep increase in energy charge followed by an increase in nitrogenase activity. Plotting enzyme activity versus energy charge, a nonlinear, asymptotic relationship was observed.     

Short-term nitrate (nitrite) inhibition of nitrogen fixation in Azotobacter chroococcum.

Nitrate-grown Azotobacter chroococcum ATCC 4412 cells lack the ability to fix N2. Nitrogenase activity developed after the cells were suspended in a combined nitrogen-free medium and was paralleled by a concomitant decrease in nitrate assimilation capacity. In such treated cells exhibiting transitory nitrate assimilation and N2-fixation capacity, nitrate or nitrite caused a short-term inhibitory effect on nitrogenase activity which ceased once the anion was exhausted from the medium. The analog L-methionine-DL-sulfoximine, an inhibitor of glutamine synthetase, prevented inhibition of nitrogenase activity by nitrate or nitrite without affecting the uptake of these antions, which were reduced and stoichiometrically released into the external medium as ammonium. Inhibition of nitrogenase by nitrate (nitrite) did not take place in A. chroococcum MCD1, which is unable to assimilate either. We conclude that the short-term inhibitory effect of nitrate (nitrite) on nitrogenase activity is due to some organic product(s) formed during the assimilation of the ammonium resulting from nitrate (nitrite) reduction.     

Effect of carbamoyl phosphate on nitrogenase in Anabaena cylindrica Lemm.

Carbamoyl phosphate inhibited acetylene reduction by whole cells and cell-free extracts of Anabaena cylindrica. Higher levels of both endogenous carbamoyl phosphate and carbamoyl phosphate synthase activity were present in NH4+-grown cells (in which acetylene reduction was absent) than in N2-grown cells (in which acetylene reduction was present). However, inhibition of acetylene reduction was observed also with cyanate, the main initial decomposition product under the conditions used. It is concluded that carbamoyl phosphate or one of its metabolites may act as a physiological regulator of both nitrogenase activity and synthesis, but caution must be used in interpreting effects observed several hours after the addition of carbamoyl phosphate, because the effects may be due to cyanate.     

Energy transfer from phycobiliproteins to photosystem I in vegetative cells and heterocysts of Anabaena variabilis

The presence of phycobilins in heterocysts of Anabaena variabilis is established on the basis of absorption and fluorescence spectroscopy. At 77 K heterocysts exhibit fluorescence emission bands at 645 and 661 nm indicative of phycocyanin and allophycocyanin, respectively. Both allophycocyanin levels and fluorescence emission at 695 nm were low in heterocysts relative to whole filaments. In situ fluorescence microscopy confirmed the presence of phycobilins in individual heterocysts, but the pigment levels varied considerably among cells. Heterocysts exhibited Photosystem I activity, as evidenced by photooxidation of P-700, but no Photosystem II activity. The quantum efficiency of phycobilins in sensitizing P-700 photooxidation was 50-70% that of chlorophyll a. Phycoibins were also effective in promoting light-dependent reduction of acetylene to ethylene. The results are discussed in terms of the role of the heterocyst in nitrogen fixation and of the significance of energy transfer from phycobilins to Photosystem I in heterocysts.     

Nitrogen fixation by Anabaena cylindrica

Hydrogen-supported nitrogenase activity was demonstrated in Anabaena cylindrica cultures limited for reductant. Nitrogen-fixing Anabaena cylindrica cultures sparged in the light with anaerobic gases in the presence of the photosynthesis inhibitor DCMU slowly lost their ability to reduce acetylene in the light under argon but exhibited near normal activities in the presence of 11% H₂ (balance argon). The hydrogen-supported nitrogenase activity was half-saturated between 2 and 3% H₂ and was strongly inhibited by oxygen (50% inhibition at about 5–6% O₂). Batch cultures of Anabaena cylindrica approaching stationary growth phase (“old” cultures) lost nitrogenase-dependent hydrogen evolution almost completely. In these old cultures hydrogen relieved the inhibitory effects of DCMU and O₂ on acetylene reduction. Our results suggest that heterocysts contain an uptake hydrogenase which supplies an electron transport chain to nitrogenase but which couples only poorly with the respiratory chain in heterocysts and does not function in CO₂ fixation by vegetative cells.     

Properties of in vivo nitrogenase activity in Beggiatoa alba

A procedure was devised for analyzing in vivo nitrogenase activity in Beggiatoa alba B18LD which involves: (1) the induction of nitrogenase in cells pre-grown on NH₄Cl, by washing the cells free of NH₄Cl and lowering their exposure to oxygen, and (2) measuring acetylene reduction by these cells. Using this induction methodology we examined the effects of pH, temperature, and nitrogenous compounds on in vivo nitrogenase induction and activity in Beggiatoa alba B18LD. Nitrate and nitrite repressed the induction of nitrogenase activity, but glutamine did not. Induction and activity had a combined pH optimum of 6.5 to 8.0, and activity had a temperature optimum of 29°C. Ammonium and urea caused immediate inhibition of nitrogenase activity, but nitrate, nitrite, glutamine, asparagine, and other amino acids did not. Ammonium-induced inhibition was transient and incomplete, and the duration of inhibition increased in direct proportion to the amount of ammonium added. Methionine sulfoximine, a glutamine synthetase inhibitor, at a final concentration of 50 μM blocked ammonium uptake by cells, but did not prevent nitrogenase inhibition if added before ammonium. Our results imply that B. alba nitrogenase inhibition by ammonium: (1) is not directly caused by ammonium assimilation products, (2) is probably not due to an enzymatic inactivation, and (3) may be related to ammonium transport.     

Formation of glutamine from [13n]ammonia, [13n]dinitrogen, and [14C]glutamate by heterocysts isolated from Anabaena cylindrica.

A method is described for the isolation of metabolically active heterocysts from Anabaena cylindrica. These isolated heterocysts accounted for up to 34% of the acetylene-reducing activity of whole filaments and had a specific activity of up to 1,560 nmol of C2H4 formed per mg of heterocyst chlorphyll per min. Activity of glutamine synthetase was coupled to activity of nitrogenase in isolated heterocysts as shown by acetylene-inhibitable formation of [13N]NH3 and of amidelabeled [13N]glutamine form [13N]N2. A method is also described for the production of 6-mCi amounts of [13N]NH3. Isolated heterocysts formed [13N]glutamine from [13N]NH3 and glutamate, and [14C]glutamine from NH3 and [14C]glutamate, in the presence of magnesium adenosine 5'-triphosphate. Methionine sulfoximine strongly inhibited these syntheses. Glutamate synthase is, after nitrogenase and glutamine synthetase, the third sequential enzyme involved in the assimilation of N2 by intact filaments. However, the kinetics of solubilization of the activity of glutamate synthase during cavitation of suspensions of A. cylindrica indicated that very little, if any, of the activity of that enzyme was located in heterocysts. Concordantly, isolated heterocysts failed to form substantial amounts of radioactive glutamate from either [13N]glutamine or alph-[14C]ketoglutarate in the presence of other substrates and cofactors of the glutamate synthase reaction. However, they formed [14C]glutamate rapidly from alpha-[14C]ketoglutarate by aminotransferase reactions, with various amino acids as the nitrogen donor. The implication of these findings with regard to the identities of the substances moving between heterocysts and vegetative cells are discussed.