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.     

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.     

Modes of reduction of nitrogenase in heterocysts isolated from Anabaena species

N₂ fixation (acetylene reduction) has been studied with heterocysts isolated from Anabaena cylindrica and Anabaena 7120. In the presence of ATP and at very low concentrations of sodium dithionite, reducing equivalents for activity of nitrogenase in these cells can be derived from several compounds. In the dark, d-glucose 6-phosphate, 6-phosphogluconate and dl-isocitrate support acetylene reduction via NADPH. In the light, reductant can be generated by Photosystem I.     

Role of ammona in regulation of nitrogenase synthesis and activity in Anabaena cylindrica

The regulation of nitrogenase biosynthesis and activity by ammonia was studied in the heterocystous cyanobacterium Anabaena cylindrica. Nitrogenase synthesis was measured by in vivo acetylene reduction assays and in vitro by an activity-independent, immunoelectrophoretic measurement of the Fe-Mo protein (Component I). When ammonia was added to differentiating cultures after a point when heterocyst differentiation became irreversible, FeMo protein synthesis was also insensitive to ammonia. Treating log-phase batch cultures with 100% O₂ for 30 min resulted in a loss of 90% of nitrogenase activity and a 50% loss of the FeMo protein. Recovery was inhibited by chloramphenicol but not by ammonia or urea. The addition of ammonia to log-phase cultures resulted in a decrease in specific levels of nitrogenase activity and FeMo protein that occurred at the same rate as algal growth and was independent of O₂ tension of the culture media. However, in light-limited linear-phase cultures, ammonia effected a dramatic inhibition of nitrogenase activity. These results indicate that nitrogenase biosynthesis becomes insensitive to repression by ammonia as heterocysts mature and that ammonia or its metabolites act to regulate nitrogen fixation by inhibiting heterocyst differentiation and by inhibiting nitrogenase activity through competition with nitrogenase for reductant and/or ATP, but not by directly regulating nitrogenase biosynthesis in heterocysts.     

Electron donation to nitrogenase in heterocysts of cyanobacteria

Various electron donors were found to stimulate C₂H₂ reduction (N₂ fixation) by isolated heterocysts from Anabaena variabilis and Anabaena cylindrica. Intermediates of glycolysis and the tricarboxylic acid cycle as well as unphosphorylated sugars like glucose, fructose and erythrose were among these electron donors. The transfer of electrons from donors like H₂, NADH, glyoxylate and glycollate was strictly light-dependent, whereas others like NADPH or pyruvate plus coenzyme A supported C₂H₂ reduction also in the dark. In all cases, the overall activity was enhanced by light. The stimulation by light was more distinct with heterocysts from A. variabilis than with heterocysts from A. cylindrica.The present communication establishes that pyruvate supports C₂H₂ reduction by heterocysts from either A. variabilis or A. cylindrica with rates comparable to those with other electron donors. Pyruvate could, however, support C₂H₂ reduction only in the presence of coenzyme A, and the concentrations of both coenzyme A and pyruvate were crucial. A pyruvate-dependent reduction of ferredoxin by extracts from heterocysts was recorded spectrophotometrically. Glyoxylate, which is an inhibitor of thiamine pyrophosphate-dependent decarboxylations, inhibited pyruvate-dependent C₂H₂ reduction. This result supports the conclusion that pyruvate is metabolised by pyruvate: ferredoxin oxidoreductase in heterocysts. High concentrations of pyruvate and other electron donors inhibited C₂H₂ reduction which suggests that nitrogenase activity in heterocysts may be controlled by the availability of electron donors.Dedicated to Professor Norbert Pfennig, Konstanz, on the occasion of his 60th birthday     

Site of Nitrogenase Activity in the Blue-Green Alga <Emphasis Type="Italic">Anabaena</Emphasis> sp. L-31

MANY blue-green algae fix nitrogen, assimilate carbon dioxide and evolve oxygen and as algal nitrogenase is inhibited^1–3 by high oxygen pressure, enhanced nitrogen fixation accompanying photosynthesis is surprising. Heterocysts do not contain⁴ or have comparatively less amounts^4–7 of photosystem II (PS II) pigments, which are responsible for the evolution of oxygen. This tends to favour the suggestion of Fay et al.⁸ that these cells are the sites of nitrogenase activity. Until now, however, attempts at obtaining unequivocal evidence for heterocysts as principal loci for nitrogenase activity have yielded conflicting results. Stewart et al.⁷ first demonstrated nitrogenase activity in heterocysts incubated aerobically, a finding confirmed by Wolk and Wojciuch⁹ and Van Gorkom and Donze¹⁰. By contrast, Smith and Evans^3,11 and Kurz and La Rue¹² reported results favouring vegetative cells as the major site of nitrogenase activity. Other evidence^2,13 showed high nitrogenase activity in cell-free preparations of Anabaena cylindrica and the non-heterocystous alga Plectonema boryanum strain 594.     

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     

Nitrogen fixation by Anabaena cylindrica

Summary The effects of oxygen, light and photosynthesis inhibitors on nitrogenase activities in Anabaena cylindrica batch cultures were followed as a function of time after inoculation. During the early rapid growth period the nitrogenase activities of cultures grown under air/CO₂ or N₂/CO₂ were relatively resistant to oxygen and DCMU inhibition. These cultures also exhibited oxygen-dependent nitrogenase activity in the dark of up to 50% of that measured in the light. After active growth ceased the cultures continued to slowly grow for a prolonged period of time. The nitrogenase activities of these old cultures were very sensitive to oxygen and DCMU inhibition. These cultures also had little or no dark nitrogenase activities. The photosynthesis inhibitor DBMIB was not a specific inhibitor of light-driven electron transport since it inhibited both light and dark nitrogenase activities. Nitrogenase activities induced under oxygen-free/CO₂ gas mixtures initially were significantly more sensitive to oxygen inhibition than those induced under air/CO₂. We discuss these results in relation to heterocyst function.     

Morphological and isotopic changes of heterocystous cyanobacteria in response to N2 partial pressure

Earth's atmospheric composition has changed significantly over geologic time. Many redox active atmospheric constituents have left evidence of their presence, while inert constituents such as dinitrogen gas (N₂) are more elusive. In this study, we examine two potential biological indicators of atmospheric N₂: the morphological and isotopic signatures of heterocystous cyanobacteria. Biological nitrogen fixation constitutes the primary source of fixed nitrogen to the global biosphere and is catalyzed by the oxygen‐sensitive enzyme nitrogenase. To protect this enzyme, some filamentous cyanobacteria restrict nitrogen fixation to microoxic cells (heterocysts) while carrying out oxygenic photosynthesis in vegetative cells. Heterocysts terminally differentiate in a pattern that is maintained as the filaments grow, and nitrogen fixation imparts a measurable isotope effect, creating two biosignatures that have previously been interrogated under modern N₂ partial pressure (pN₂) conditions. Here, we examine the effect of variable pN₂ on these biosignatures for two species of the filamentous cyanobacterium Anabaena. We provide the first in vivo estimate of the intrinsic isotope fractionation factor of Mo‐nitrogenase (ε_fix = ?2.71 ± 0.09‰) and show that, with decreasing pN₂, the net nitrogen isotope fractionation decreases for both species, while the heterocyst spacing decreases for Anabaena cylindrica and remains unchanged for Anabaena variabilis. These results are consistent with the nitrogen fixation mechanisms available in the two species. Application of these quantifiable effects to the geologic record may lead to new paleobarometric measurements for pN₂, ultimately contributing to a better understanding of Earth's atmospheric evolution.     

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.     

Regulation of nitrogenase gene expression in anaerobic cultures of Anabaena variabilis.

Derepression of nitrogenase gene expression was studied at the mRNA and enzyme activity levels in anaerobic cultures of Anabaena variabilis 29413. Cells, previously grown with ammonium chloride, were incubated in the absence of fixed nitrogen compounds under an Ar atmosphere with dichlorophenyldimethyl-urea present to inhibit oxygen evolution. The appearance of nitrogenase mRNA (measured by dot blot hybridization analysis) and nitrogenase activity (measured as acetylene-reducing activity) was followed, and the cells were also observed by phase-contrast microscopy. Nitrogenase mRNA could be detected after 1.5 to 2.0 h of nitrogen starvation; enzyme activity appeared about 1 h later. Although enzyme activity increased for many hours, mRNA levels reached a steady state rapidly. Neither heterocysts nor proheterocysts formed under these conditions; however, the cells were observed to shrink and become chlorotic. When anaerobic, derepressed cultures were exposed to oxygen, nitrogenase mRNA levels decreased very rapidly.     

Glyoxylate decreases the oxygen sensitivity of nitrogenase activity and photosynthesis in the cyanobacterium Anabaena cylindrica

Raising the pO₂ reduced nitrogenase activity (C₂H₂ reduction) of Anabaena cylindrica for both glyoxylate-treated (5 mM) and untreated cells. The stimulation caused by glyoxylate, however, increased with increases of pO₂ from 2 to 99 kPa. As the pO₂ increased the net CO₂ fixation was lowered (Warburg effect) while the CO₂ compensation point increased. Glyoxylate partly relieved this sensitivity of net photosynthesis to oxygen and reduced the compensation point considerably. The cells used were preincubated in the dark to exhaust photosynthetic pools. A more pronounced reduction in sensitivity of nitrogenase to oxygen for glyoxylate-treated cells was evident when a preincubation in air with reduced pCO₂ (13 l l^-1) was used. This was, however, not evident until after a 10-h incubation in air. Before this point 2 kPa O₂ sustained the highest nitrogenase activity. Addition of 0.5 and 5 mM of HCO ₃ ^- to Anabaena cultures preincubated at low CO₂ levels (29 l l^-1) abolished the stimulatory effect of glyoxylate on the nitrogenase. Thus, the results sustain the suggestion that glyoxylate may act as an inhibitor of photorespiratory activities in cyanobacteria and can be used as a means of increasing their nitrogen and CO₂ fixation capacities.Abbreviation RuBP ribulose 1,5-bisphosphate     

Effect of canavanine and other amino acid analogues on akinete formation in the cyanobacterium Anabaena cylindrica

Addition of the arginine analogue, canavanine, to cultures of nitrogen-fixing Anabaena cylindrica at the onset of akinete formation, resulted in the development of akinetes randomly distributed within the filament, in addition to those adjacent to heterocysts. The total frequency of akinetes increased up to five-fold. A feature of akinetes is their increased content of cyanophycin granules (an arginine-aspartic acid polymer) and addition of canavanine to cultures at an earlier stage resulted in entire filaments becoming agranular and containing agranular akinetes. The effects on akinete pattern appeared to be specific for canavanine since other amino acid analogues, although increasing the frequency of akinetes (approximately two-fold), had no effect on their position relative to heterocysts. In ammonia-grown, stationary phase cultures of A. cylindrica, akinetes were observed adjacent to proheterocysts and in positions more than 20 cells from any heterocyst. These observations indicate that nitrogen fixation and heterocysts are not essential for akinete formation in A. cylindrica, although the availability of a source of fixed nitrogen does appear to be a requirement.These results suggest that during exponential growth some aspect of the physiology of vegetative cells suppresses their development into akinetes and that the role of the heterocyst may not be one of direct stimulation of adjacent vegetative cells to form akinetes, but the removal or negation of the inhibition within them. A model for akinete formation and the involvement of canavanine is given.     

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.     

The occurrence of the hydrogenase in some blue-green algae

Several blue-green algae were surveyed for the occurrence of the hydrogenase which was assayed by the oxyhydrogen or Knallgas reaction in the intact organisms. In aerobically grown cultures, the reaction was detectable in Anabaena cylindrica, Nostoc muscorum and in two Anabaena variabilis species, whereas virtually no activity was observed in Anacystis nidulans and Cyanophora paradoxa. In these latter two algae, the reaction was, however, found after growth under molecular hydrogen for several days, which drastically increased the activity levels with all the algae tested. In the nitrogen fixing species, the activity of the Knallgas reaction was enhanced when all combined nitrogen was omitted from the media. H₂ and hydrogenase could not significantly support the CO₂-fixation in photoreduction experiments with all blue-green algae investigated here. Hydrogenase was assayed by the dithionite and methyl viologen dependent evolution of hydrogen and was found to be present with essentially the same specific activity levels in preparations of both heterocysts and vegetative cells from Anabaena cylindrica. Na₂S₂O₄ as well as H₂ supported the C₂H₂-reduction of the isolated heterocysts. The H₂-dependent C₂H₂-reduction did not require the presence of oxygen but was strictly light-dependent where H₂ served as an electron donor to photosystem I of these cells. It is concluded that hydrogen can be utilized by two different pathways in blue-green algae.Abbreviations Chl chlrophyll - CP creatine phosphate - CP kinase creatine phosphokinase - DCMU N-(3,4-dichlorophenyl)N,N-dimethylurea     

Localization of iron-superoxide dismutase in the cyanobiont ofAzolla filiculoides Lam

Summary Immunogold labeling and transmission electron microscopy were used to localize iron-superoxide dismutase (Fe-SOD) in the different cells of nitrogen-fixing cyanobacterial symbiont present within different leaf cavity groups ofAzolla filiculoides Lam. As evidenced by Western blotting and immunoprecipitation, Fe-SOD antibody fromAnabaena cylindrica recognized Fe-SOD in extracts of the cyanobiont and showed the same electrophoretic mobility and pattern as purifiedA. cylindrica Fe-SOD. In vegetative cells of the cyanobiont, Fe-SOD was mainly localized in the thylakoidal membranes and in the outer membrane. The labeling pattern was similar in vegetative cells of the various groups of leaf cavities examined except at the apex where a lower gold particle density was seen. In heterocysts of the leaf cavity groups containing high nitrogenase activity, Fe-SOD labeling was most pronounced and more intense than in vegetative cells. The Fe-SOD label was preferentially located throughout the heterocyst cytoplasm and in the honeycomb regions. In accordance with the decline in nitrogenase activity, the Fe-SOD gold particle density decreased significantly in heterocysts of basal leaf cavity group. The presence of Fe-SOD in regions of high nitrogenase protein levels, and the fact that the pattern of Fe-SOD label parallels that of nitrogenase activity support a role of Fe-SOD in the protection of nitrogenase against superoxide radicals.     

Immunochemical evidence that nitrogenase is restricted to the heterocysts in Anabaena cylindrica

The question of whether the vegetative cells of Anabaena cylindrica synthesize nitrogenase under anaerobic conditions was studied by immunoferritin labelling of the Fe-Mo protein (Component I). Differentiating cultures, incubated under an argon atmosphere, were treated with DCMU 12 h following initiation of induction. DCMU inhibited photosynthetic O₂ production, thus insuring strict anaerobic conditions, but had no effect on nitrogenase induction. Fe-Mo protein levels, as determined by rocket immunoelectrophoresis, increased 5-fold within 24h of DCMU treatment. Immunoferritin labelling of aldehyde fixed, ultrathin cryosections of anaerobically induced filaments showed that the Fe-Mo protein was restricted to the heterocyst. Ferritin labelling was shown to be specific by the following criteria: (a) substituting preimmune goat serum for the anti-Fe-Mo protein IgG prevented ferritin labelling; (b) ferritin-conjugated, non-homologous rabbit anti-goat IgG did not bind; (c) incubation of anti-Fe-Mo protein IgG treated sections with rabbit anti-goat IgG prior to the treatment with the ferritin label also prevented labelling. The results provide direct immunochemical evidence that nitrogenase is restricted to the heterocysts even under strictly anaerobic conditions.     

Oxidation of diaminobenzidine in the heterocysts ofAnabaena cylindrica

Hemoproteins were localized in the cyanobacteriumAnabaena cylindrica with diaminobenzidine (DAB). Incubation of whole cells in the light with DAB resulted in deposition of oxidized DAB on the lamellae of the vegetative cells and central heterocyst region. This reaction was greatest at pH 7.5, light-dependent, insensitive to 3-(3,4-dichlorophenyl)-1, 1-dimethyl urea, and abolished by glutaraldehyde fixation. A light-independent oxidation of DAB was also observed with light and electron microscopy in the honeycomb region and periphery of heterocysts. This reaction was greatest at pH 7.5, enhanced by H₂O₂, and active in glutaraldehyde-fixed frozen sections. Inhibitors such as sodium cyanide, sulfide, and hydroxylamine severely reduced DAB oxidation and nitrogenase activity under aerobic but not anaerobic conditions. These results indicate that the heme proteins, localized in heterocysts by light-independent DAB oxidation, are involved in the oxygen-protection mechanism of the O₂-labile nitrogenase.     

Light‐dependent oxygen consumption in nitrogen‐fixing cyanobacteria plays a key role in nitrogenase protection1

All colonial diazotrophic cyanobacteria are capable of simultaneously evolving O₂ through oxygenic photosynthesis and fixing nitrogen via nitrogenase. Since nitrogenase is irreversibly inactivated by O₂, accommodation of the two metabolic pathways has led to biochemical and/or structural adaptations that protect the enzyme from O₂. In some species, differentiated cells (heterocysts) are produced within the filaments. PSII is absent in the heterocysts, while PSI activity is maintained. In other, nonheterocystous species, however, a “division of labor” occurs whereby individual cells within a colony appear to ephemerally fix nitrogen while others evolve oxygen. Using membrane inlet mass spectrometry (MIMS) in conjunction with tracer ¹⁸O₂ and inhibitors of photosynthetic and respiratory electron transport, we examined the light dependence of O₂ consumption in Trichodesmium sp. IMS 101, a nonheterocystous, colonial cyanobacterium, and Anabaena flos‐aquae (Lyngb.) Bréb. ex Bornet et Flahault, a heterocystous species. Our results indicate that in both species, intracellular O₂ concentrations are maintained at low levels by the light‐dependent reduction of oxygen via the Mehler reaction. In N₂‐fixing Trichodesmium colonies, Mehler activity can consume ～75% of gross O₂ production, while in Trichodesmium utilizing nitrate, Mehler activity declines and consumes ～10% of gross O₂ production. Moreover, evidence for the coupling between N₂ fixation and Mehler activity was observed in purified heterocysts of Anabaena, where light accelerated O₂ consumption by 3‐fold. Our results suggest that a major role for PSI in N₂‐fixing cyanobacteria is to effectively act as a photon‐catalyzed oxidase, consuming O₂ through pseudocyclic electron transport while simultaneously supplying ATP in both heterocystous and nonheterocystous taxa.