Evidence for the lack of oxygen repression of Fe−Mo protein in mutants ofAnabaena variabilis

Mutants ofAnabaena variabilis, unable to fix nitrogen under aerobic conditions, were used to determine whether nitrogenase synthesis is subject to O₂ repression, as is the case in some heterotrophic bacteria. Nitrogenase activity in the mutants was induced as heterocysts matured under microaerophilic conditions. However, addition of 5% O₂ to the assay system inhibited activity by 95%. Under aerobic conditions, nitrogenase activity in the mutants could not be detected, but an activity-independent, immunological assay showed that the Fe-Mo protein was present at levels similar to those found in wild-type and mutant strains induced microaerophilically. Reducing the O₂ tension of an aerobically induced mutant resulted in a rate of nitrogenase activity induction twice the rate under continuous microaerophilic conditions. These results indicate that O₂ does not repress Fe-Mo protein synthesis in these mutants.     

N2-fixation in Erwinia herbicola

Four from 18 strains of Erwinia herbicola tested had nitrogenase activity and grew with N₂ as sole source of nitrogen under strict anaerobic conditions with a doubling time of 20–24 h. Nitrogenase activity started only 96–120 h after transfer to a special medium maintained under anaerobic conditions. A ten fold increase in protein per culture found after the maximum nitrogenase activity of 80–130 nmol C₂H₄. mg protein^-1·min^-1 was accompanied by a fall in pH of the medium (20 mM phosphate buffer and in 125 mM Tris-buffer) from pH 7.2 to 5.4 or less, but only to 6.8 in 100 mM phosphate buffer. In all cases we found a sharp curtailing of nitrogenase activity 48 h after the maximum. The bacteria utilized only 35–50% of the nitrogen fixed for growth. Erwinia herbicola strains differed from two strains of Enterobacter agglomerans in being unable to fix nitrogen on agar surfaces exposed to air. Specific nitrogenase activity in Erwinia herbicola is compared with data reported for other Enterobacteriaceae and is found to be higher than that reported for Klebsiella pneumoniae, Enterobacter cloacae or Citrobacter freundii.     

木麻黄和桤木离体根瘤和立地土壤的固氮酶与N2O还原酶活性的研究

为了解非豆科固氮树种的固氮酶和N_2O还原酶(Nos)活性,采用乙炔还原法和乙炔抑制技术对细枝木麻黄(Casuarina cunninghamiana)和江南桤木(Alnus trabeculosa)离体根瘤及立地土壤的两种酶活性进行了研究。结果表明,离体根瘤只在厌氧条件下有固氮酶活性,在好氧条件下有Nos活性。根瘤区根际土和非根瘤区根际土的固氮酶活性在好氧条件大于厌氧条件,Nos活性只表现在厌氧条件下。在好氧条件下,根瘤区根际土和非根瘤区根际土的固氮酶活性无显著差异;根瘤区根际土的Nos活性显著大于非根瘤区根际土。除离体根瘤在好氧条件下不表现固氮酶活性外,细枝木麻黄和桤木的离体根瘤、根瘤区根际土和非根瘤区根际土的固氮酶活性均都大于Nos活性。好氧条件下根瘤区根际土的固氮酶活性与非根瘤区根际土的呈极显著正相关,而厌氧条件下根瘤的固氮酶活性与好氧条件下根瘤区根际土和非根瘤区根际土固氮酶活性、好氧条件下根瘤的Nos活性与厌氧条件下根瘤区根际土和非根瘤区根际土Nos活性均呈极显著负相关。这为研究弗兰克氏菌结瘤植物共生固氮体系对N2O汇强度的影响和调控奠定基础。     

H2 production of Rhodospirillum rubrum during adaptation to anaerobic dark conditions

Rhodospirillum rubrum is able to produce H₂ during fermentation anaerobically in the dark in two ways, namely through formate hydrogen lyase and through the nitrogenase. After chemotrophic preculture aerobically in the dark formate hydrogen lyase was synthesized after a lag phase, whilst after phototrophic preculture a slight activity was present from the beginning of the anaerobic dark culture. During fermentation metabolism its activity increased noticeably. Hydrogen production through the nitrogenase occurred if the nitrogenase had been activated during phototrophic preculture. It ceased during fermentation metabolism after about 3 1/2 h anaerobic dark culture. The CO insensitive H₂ production by the nitrogenase could be partially inhibited by N₂. Potential activity of this system, however, remained and could be increased under conditions of nitrogenase induction. It seems therefore possible that synthesis of nitrogenase under N-deficiency can occur during fermentation metabolism in the same way as the formation of the photosynthetic apparatus in order to prepare for subsequent phototrophic metabolism.Abbreviations CAP chloramphenicol - DSM Deutsche Sammlung von Mikroorganismen, Göttingen - FHL formate hydrogen lyase - O.D optical density - PFL pyruvate formate lyase     

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.     

Nitrogen fixation by a marine non‐heterocystous cyanobacterium requires a heterotrophic bacterial consort

Cultures of the non‐heterocystous cyanobacterium, Leptolyngbya nodulosa, could be grown indefinitely in media devoid of combined nitrogen. Acetylene reduction assays showed that these cultures fixed nitrogen in the dark period of a diurnal cycle under micro‐oxygenic or anaerobic conditions. Addition of DCMU to cultures induced much higher rates of nitrogenase activity, most of which occurred in the light. Measurements of activity in the presence of chloramphenicol indicated that nitrogenase is synthesized in darkness and probably destroyed in the subsequent light period. Neither the dark‐mediated nitrogenase in the absence of DCMU nor light‐mediated activity in the presence of DCMU could be sustained for more than 3 days without a photoperiodic light/dark cycle. Axenic cultures could not be grown in the absence of combined nitrogen and did not demonstrate any acetylene reduction activity. An identical nifH gene sequence was found in axenic and non‐axenic cultures of L. nodulosa. RT‐PCR demonstrated that this gene was expressed only in non‐axenic cultures. Western blotting showed that the Fe‐protein of nitrogenase is absent in cultures that are incapable of acetylene reduction, indicating that the lack of nitrogenase activity is likely due to the absence of the enzyme. These observations strongly indicate that L. nodulosa contains a functional nitrogenase which is not expressed in the absence of heterotrophic bacteria.     

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.     

Freeze-Recovery Physiology of Nitrogenase Activity in Terrestrial Nostoc sp. Colonies

Nostoc sp. colonies from field collections were cultured and propagated on silica sand with aqueous N-free BG-11 medium. Laboratory experiments were conducted to characterize the in vivo freeze-recovery physiology of nitrogenase activity. Nitrogenase activity was monitored by the acetylene reduction technique. Frozen Nostoc sp. colonies were thawed and warmed to 10, 15, 20, 25, or 30°C. At 25 and 30°C, nitrogenase activity was detected within 6 h after thawing. At 20°C or lower, nitrogenase activity was not detected until 12 h after thawing. Optimum thawing temperature with respect to the recovery of nitrogenase activity was 25°C. In subsequent experiments, laboratory-grown Nostoc colonies were used along with the following conditions: prefreezing treatment of 3 days of exposure to light or darkness, freezing, and then thawing to 25°C in light or darkness with or without metabolic inhibitors [3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU), monofluoroacetate, or chloramphenicol]. Approximately 30% of the energy in the initial recovery of nitrogenase activity (to 12 h after thawing) appeared to be supplied via the utilization of carbon compounds stored before freezing. Photosynthetic conditions (i.e., light and without DCMU) were necessary for maximum recovery of nitrogenase activity. In the presence of the protein synthesis inhibitor chloramphenicol, nitrogenase activity was still detected at 12 to 48 h after thawing. Although damage may occur to nitrogenase, some of the enzyme was capable of surviving the freeze-thaw period in vivo. However, complete recovery of nitrogenase activity (equal to prefreezing activity) may entail some de novo synthesis of nitrogenase.     

Stimulation of nitrogenase activity and photosynthesis in some cyanobacteria by glyoxylate

Abstract The effect og glyoxylate on nitrogenase activity (C₂H₂ reduction) and photosynthesis (H¹⁴CO₃ fixation and O₂ evolution) was in vestigated in the three heterocystous cyanobacteria Anabaena cylindrica, A. variabiltis and N. muscorum. Glyoxylate had virtually no effect on the rate of dark respiration and was unable to sustain photoheterotrophic growth, though some slight stimulation (= 30%) of photorophic growth was noted. A considerable stimulation of both nitrogenase and photosynthetic activities was observed in presence of glyoxylate. In the light the stimulation increased with time up to about 15-25 h after adding optimal concentrations of 4–6 mM glyoxylate. Placing glyoxylate treated samples in the dark or adding DCMU (30 μM) in the light, showed that glyoxylate initially supported significantly higher nitrogenase activity than did samples in absence of glyoxylate. However, after a prolonged incubation in the dark or in presence of DCMU glyoxylate is unable to relieve the adverse effects of such conditions. The stimulation of the nitrogenase activity was even more pronounced when the glyoxylate was added to cells preincubated in the dark (“carbon starved”) than for cells kept constantly in light. The results suggest that glyoxylate, or a metabolite, may act as an inhibitor of cyanobacterial photorespiration and this hypothesis is discussed.     

Glycogen content and nitrogenase activity in Anabaena variabilis

Nitrogenase (=acetylene-reducing activity) was followed during photoautotrophic growth of Anabaena variabilis (ATCC 29413). When cell density increased during growth, (1) inhibition of light-dependent activity by DCMU, an inhibitor of photosynthesis, increased, and (2) nitrogenase activity in the dark decreased. Addition of fructose stabilized dark activity and alleviated the DCMU effect in cultures of high cell density.The resistance of nitrogenase towards oxygen inactivation decreased after transfer of autotrophically grown cells into the dark at subsequent stages of increasing culture density. The inactivation was prevented by addition of fructose. Recovery of acetylene-reducing activity in the light, and in the dark with fructose present, was suppressed by ammonia or chloramphenicol. In the light, also DCMU abolished recovery.To prove whether the observed effects were related to a lack of photosynthetic storage products, glycogen of filaments was extracted and assayed enzymatically. The glycogen content of cells was highest 10 h after inoculation, while light-dependent nitrogenase activity was at its maximum about 24 h after inoculation. Glycogen decreased markedly as growth proceeded and dropped sharply when the cells were transferred to darkness. Thus, when C-supply (by photosynthesis or added fructose) was not effective, the glycogen content of filaments determined the activity of nitrogenase and its stability against oxygen. In cells lacking glycogen, nitrogenase activity recovered only when carbohydrates were supplied by exogenously added fructose or by photosynthesis.Abbreviations Chl chlorophyll a - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

Molybdenum independence of nitrogenase component synthesis in the non-heterocystous cyanobacterium Plectonema.

The cyanobacterium Plectonema boryanum (IU 594-UTEX 594) fixes N2 only in the absence of combined N and of O2. We induced nitrogenase by transfer to anaerobic N-free medium and studied the effect of Mo starvation on nitrogenase activity and synthesis. Activity was first detected within 3 h after transfer by the acetylene reduction assay in controls, increasing for at least 25 h. Cells grown on nitrate and Mo and then transferred to N-free, Mo-free medium produced 8% of the control nitrogenase activity. Addition of W to the Mo-free medium reduced the activity to 0.5%. Under both Mo starvation conditions, nitrogenase protein components were synthesized. Component II of the cyanobacterial enzyme was detected by in vitro complementation with Mo-containing component I from Klebsiella pneumoniae or Azotobacter vinelandii but not Clostridium pasteurianum. Component I activity was restored by addition of Mo to cultures in which new enzyme synthesis was blocked by chloramphenicol. Acidified extracts of Plectonema induced in Mo-containing medium contained the Fe-Mo cofactor required to activate extracts of the Azotobacter mutant UW45 in vitro, but they did not activate extracts of Mo-starved Plectonema. Analysis of 35SO4(2-)-labeled proteins by polyacrylamide gel electrophoresis suggested that Mo is required for the conversion of a high-molecular-weight precursor to component I in Plectonema.     

Increase of Nitrogenase Activity in the Blue-Green Alga Nostoc muscorum (Cyanobacterium)

Preincubation of the blue-green alga (cyanobacterium) Nostoc muscorum under hydrogen or argon (nongrowing conditions, neither CO₂ nor N₂ or bound nitrogen present) in the light resulted in a two- to fourfold increase of light-induced hydrogen evolution and a 30% increase of acetylene reduction. Preincubation under the same gases in the dark led to a decrease of both activities. Cultivation of algae under a hydrogen-containing atmosphere (N₂, H₂, CO₂) increased neither hydrogen nor ethylene evolution by the cells. Formation of both ethylene and hydrogen is due to nitrogenase activity, which apparently was induced by the absence of N₂ or bound nitrogen and not by the presence of hydrogen. Inhibitors of protein biosynthesis prevented the increase of nitrogenase activity. Hydrogen uptake by the cells was almost unaffected under all of these conditions. With either ammonia or chloramphenicol present, nitrogenase activity decreased under growing conditions (i.e., an atmosphere of N₂ and CO₂). The kinetics of decrease were the same with ammonia or chloramphenicol, which was interpreted as being due to rapid protein breakdown with a half-life of approximately 4 h. The decay of nitrogenase activity caused by chloramphenicol could be counteracted by nitrogenase-inducing conditions, i.e., by the absence of N₂ or bound nitrogen. A cell-free system from preconditioned algae with an adenosine 5′-triphosphate-generating system exhibited the same increase or decrease of nitrogenase activity as the intact cell filaments, indicating that this effect resided in the nitrogenase complex only. We tentatively assume that not the whole nitrogenase complex, but merely a subunit or a special protein with regulatory function, is susceptible to fast turnover.     

On the origin of the yolk protein ferritin in snails

Summary The iron storage protein, ferritin, is the major yolk protein in freshwater snails. In this report we show by in vitro labelling experiments that yolk ferritin of the snails Lymnaea stagnalis L. and Planorbarius corneus L. is an exogenous protein synthesized in the midgut gland and secreted into the hemolymph. Gonad and mantle tissue are inactive in the synthesis of yolk ferritin, but, together with the midgut gland, they synthesize another ferritin type (soma ferritin) which is not released into the hemolymph and which may be a housekeeping ferritin. Soma ferritin and yolk ferritin are not in a precursor/product relationship since subunits of both ferritins are synthesized as primary translation products in rabbit reticulocyte lysate programmed with poly (A)⁺ RNA from midgut gland and gonad. Results suggest that both ferritins are synthesized on different mRNAs (and possibly on different genes) so they may be regulated in a different way.     

Effects of photoperiodicity and light irradiance on phosphate-limited Oscillatoria agardhii in chemostat cultures

Oscillatoria sp. strain 23 is a filamentous, non-heterocystous cyanobacterium that fixes nitrogen aerobically. Although, in this organism nitrogenase is inactivated by oxygen a high tolerance is observed. Up to a pO₂ of 0.15 atm, oxygen does not have any measurable effects on acetylene reduction. Higher concentrations of oxygen inhibited the activity to a relatively high degree. Evidence for two mechanisms of oxygen protection of nitrogenase in this cyanobacterium was obtained. A high rate of synthesis of nitrogenase may allow the organism to maintain a certain amount of active enzyme under aerobic conditions. Secondly, a switch off/on mechanism may reversibly convert the active enzyme into a non-active form which is insensitive to oxygen inactivation after a sudden and short-term exposure to high oxygen concentrations. It is conceived that these mechanisms in addition to a temporal separation of nitrogen fixation from oxygenic photosynthesis sufficiently explain the regulation process of aerobic nitrogen fixation in this organism.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - CAP chloramphenicol     

Regulation of nitrogen-fixation by different nitrogen sources in the marine non-heterocystous cyanobacterium Trichodesmium sp. NIBB1067

The effect of various nitrogen sources on the synthesis and activity of nitrogenase was studied in the marine, non-heterocystous cyanobacterium Trichodesmium sp. NIBB1067 grown under defined culture conditions. Cells grown with N₂ as the sole inorganic nitrogen source showed light-dependent nitrogenase activity (acetylene reduction). Nitrogenase activity in cells grown on N₂ was not suppressed after 7 h incubation with 2 mM NaNO₃ or 0.02 mM NH₄Cl. However, after 3 h of exposure to 0.5 mM of urea, nitrogenase was inactivated. Cells grown in medium containing 2 mM NaNO₃, 0.5 mM urea or 0.02 mM NH₄Cl completely lacked the ability to reduce acetylene. Western immunoblots tested with polyclonal antisera against the Fe-protein and the Mo–Fe protein, revealed the following: (1) both the Fe-protein and the Mo–Fe protein were synthesized in cells grown with N₂ as well as in cells grown with NaNO₃ or low concentration of NH₄Cl; (2) two bands (apparent molecular mass of 38 000 and 40 000) which cross-reacted with the antiserum to the Fe-protein, were found in nitrogen-fixing cells; (3) only one protein band, corresponding to the high molecular mass form of the Fe-protein, was found in cells grown with NaNO₃ or low concentration of NH₄Cl; (4) neither the Fe-protein nor the Mo–Fe protein was found in cells grown with urea; (5) the apparent molecular mass of the Fe-protein of Trichodesmium sp. NIBB1067 was about 5000 dalton higher than that of the heterocystous cyanobacterium, Anabaena cylindrica IAM-M1.     

Interaction of respiratory and photosynthetic electron transport in Anabaena variabilis Kütz.

Prelabeled Anabaena variabilis Kütz. evolves ¹⁴CO₂ in the light with KCN and DCMU (2,4-dichlorophenyl-1,1-dimethylurea) present, comparable to the dark control without inhibitors added. Double-reciprocal plots of CO₂ release vs. light intensity with either KCN or KCN+DCMU present result in two straight lines intersecting at the ordinate. Apparently, reducing equivalents originating from carbohydrate catabolism are channeled into the photosynthetic electron-transport chain, competing for electrons from photosystem II. Under these conditions, the CO₂ release is accompanied by a light-dependent oxygen uptake, presumably due to oxygen-reducing photosystem-I activity while ribulose-bisphosphate carboxylase is inhibited by KCN.Comparing nine blue-green algae it was shown that only nitrogen-fixing species release substantial amounts of CO₂ in the light with KCN or KCN+DCMU present. This release is particularly obvious with Anabaena variabilis Kütz. under nitrogen-fixing conditions, but small when the alga is grown with combined nitrogen.We conclude that nitrogen-fixing species share a common link between respiratory and photosynthetic electron transport. The physiological role may be electron supply of nitrogenase by photosystem I.     

Nitrogenase Inhibition in Nodules from Pea Plants Grown Under Salt Stress Occurs at the Physiological Level and can be Alleviated by B and Ca

In order to shed new light on the mechanisms of salt-mediated symbiotic N₂-fixation inhibition, the effect of salt stress (75 mM) on N₂-fixation in pea root nodules induced by R. leguminosarum was studied at the gene expression, protein production and enzymatic activity levels. Acetylene reduction assays for nitrogenase activity showed no activity in salt-stressed plants. To know whether salt inhibits N₂-fixing activity at a molecular or at a physiological level, expression of the nifH gene, encoding the nitrogenase reductase component of the nitrogenase enzyme was analyzed by RT-PCR analysis of total RNA extracted from nodulated roots. The nifH messenger RNA was present both in plants grown in the presence and absence of salt, although a reduction was observed in salt-stressed plants. Similar results were obtained for the immunodetection of the nitrogenase reductase protein in Western-blot assays, indicating that nitrogen fixation failed mainly at physiological level. Given that nutrient imbalance is a typical effect of salt stress in plants and that Fe is a prosthetic component of nitrogenase reductase and other proteins required by symbiotic N₂-fixation, as leghemoglobin, plants were analyzed for Fe contents by atomic absorption and the results confirmed that Fe levels were severely reduced in nodules developed in salt-stressed plants. In a previous papers (El-Hamdaoui et al., 2003b), we have shown that supplementing inoculated legumes with boron (B) and calcium (Ca) prevents nitrogen fixation decline under saline conditions stress. Analysis of salt-stressed nodules fed with extra B and Ca indicated that Fe content and nitrogenase activity was similar to that of non-stressed plants. These results indicate a linkage between Fe deprivation and salt-mediated failure of nitrogen fixation, which is prevented by B and Ca leading to increase of salt tolerance.     

Immunological evidence for the capability of free-living Rhizobium japonicum to synthesize a portion of a nitrogenase component

Immunodiffusion tests conducted under aerobic conditions demonstrated that cross-reactive material to antiserum prepared against the MoFe protein component of nitrogenase from soybean nodule bacteroids was detectable in extracts of free-living Rhizobium japonicum cells cultured in a standard medium under: aerobic conditions; aerobic conditions with nitrate; aerobic conditions with ammonia; anaerobic conditions with nitrate; and anaerobic conditions with nitrate and ammonia. The most intense precipitin bands resulted from cross-section of the antiserum with extracts of cells cultured anaerobically with nitrate or anaerobically with ammonia and nitrate. Immunodiffusion experiments with crude bacteroid extract and purified MoFe protein revealed a greater number of precipitin bands in tests conducted under aerobic conditions than those conducted under anaerobic conditions. These results indicate that some of the cross-reactive material observed under aerobic conditions resulted from breakdown of the MoFe protein. Bacteroid extracts of nodules from plants supplied with ammonia exhibited only a trace of nitrogenase activity. The addition of an excess of the Fe protein component of nitrogenase, however, resulted in a 270-fold enhancement of activity indicating the presence of active MoFe protein in these extracts.Our experiments together with results published elsewhere provide evidence that the genetic information for synthesis of a part of the MoFe component of nitrogenase is carried by Rhizobium.     

Growth characteristics of non-heterocystous cyanobacterium Plectonema boryanum with N2 as nitrogen source

Strains of filamentous, non-heterocystous cyanobacteria from the Pasteur Culture Collection (PCC), able to synthesize nitrogenase under anaerobic test conditions, were tested for growth with N₂ as sole nitrogen source at low O₂ partial pressure (less than 0.05%). Plectonema boryanum (PCC 73110) exhibited exponential growth under these conditions. This capacity was restricted to light intensities not exceeding 500 lux. Growth rates were 0.014/h at 200 and 0.023 at 500 lux and similar to those of anaerobic and aerobic control cultures with nitrate as N-source. For N₂-fixing cultures incubated at 200 and 500 lux, acetylene reduction rates were 4–8 and 5–14 nmol C₂H₄ per mg protein per min, respectively. The ratio of phycocyanine to chlorophyll was higher (200 lux) or slightly reduced (500 lux) in N₂-fixing cultures as compared to control cultures with nitrate as N-source. On the basis of epifluorescence microscopy and microfluorimetry, no differences in pigment contents were found between individual cells or filaments of N₂-fixing cultures. Also no noteworthy differences were observed between the pycobiliprotein composition of individual cells in N₂ fixing cultures as compared to nitrate-grown controls. Thus the observed exponential growth of P. boryanum at low light intensities implies simultaneous nitrogen fixation and oxygenic photosynthesis. Additional continuous culture experiments showed that N₂-fixing exponential growth was dependent on O₂ partial pressures lower than 0.2–0.4%.The other strains tested (PCC 6412, 6602, 7403, 7104) did not grow under such conditions.Abbreviations Chl chlorophyll - PBP phycobiliproteins - PC phycocyanin - PCC Pasteur Culture Collection - OD optical density     

Effect of oxygen on the cyanobacterium Oscillatoria limnetica

Oscillatoria limnetica grown photoautotrophically under aerobic or anaerobic conditions contained a single superoxide dismutase (SOD) of identical electrophoretic mobility in both cases. Its activity was cyanide resistant and H₂O₂ sensitive, implicating Fe-SOD. The enzyme level was high in aerobically and low in anaerobically growing cells. Anaerobically grown cells were more sensitive than aerobic to photooxidation, as expressed by bleaching of phycocyanin and disintegration of the trichomes.Abbreviations DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - SOD superoxide dismutase