The differential action of metronidazole on nitrogen fixation,hydrogen metabolism,photosynthesis and respiration in Anabaena and Scenedesmus

Metronidazole (2-methyl-5-nitroimidazole-1-ethanol) at 1–2 mM levels has been shown to be a selective inhibitor of nitrogenase activity in Anabaena. Two constitutive hydrogenases and photosynthesis are insensitive to metronidazole at these same concentrations. At higher concentrations metronidazole inhibits photosynthesis in Anabaena while photoreduction and to a lesser extent photohydrogen production are retarded in Scenedesmus. Respiration is slightly stimulated at high metronidazole levels in both algae. The reductant source for nitrogenase in Anabaena and photohydrogen production and photoreduction electron transport in Scenedesmus are discussed. Due to the activity of metronidazole as a selective inhibitor of ferredoxin-associated processes, it should prove to be useful in N₂ fixation studies and in distinguishing between ferredoxin-linked reactions of different sensitivities and other activities not associated with low reduction potential components.     

Lack of site-specificity of spinach chloroplast coupling factor 1

The irreversible inhibition of chloroplast phosphorylation by either sulfate anions, or N-ethylmaleimide, is energy dependent. Chloroplasts must first be illuminated in the presence of the inhibitors and a mediator of electron flow, for the subsequent phosphorylation to show any inhibition. Both inhibitors affect the chloroplast coupling factor 1.Electron transport only through Photosystem I can be used to activate either of these inhibitions. The subsequent inhibition in a second light reaction is the same whether ATP synthesis is supported by Photosystem I, or by Photosystem II electron transport. The reverse experiment, activating inhibition by electron transport only through Photosystem II, is possible in the case of sulfate. Again, the inhibition is expressed whether Photosystem II or Photosystem I electron flow supports ATP synthesis. We conclude that the two electron transport regions probably generate the same high energy state which is able to activate all members of a functionally uniform coupling factor population. These enzyme molecules must catalyze phosphorylation coupled to electron transport through either region of the chain. The results tend to discredit models requiring a separate group of coupling factor molecules unique to each part of the chain.     

Electron transport to nitrogenase in Rhodospirillum rubrum: Role of energization of the chromatophore membrane

Nitrogen fixation is dependent on a source of ATP and the generation of a reductant at low enough red-ox potential to transfer electrons to nitrogenase. In Rhodospirillum rubrum, grown photoheterotrophically, ATP is produced by photophosphorylation, a process studied in great detail, but the source of reductant for nitrogenase is as yet unidentified. In this report we have studied the effect on nitrogen fixation when the energization of the chromatophore membranes was changed, by decreasing the light intensity or by addition of uncouplers. When the light intensity was lowered a pronounced decrease in nitrogenase activity was observed although there was no decrease in the ATP/ADP ratio. The inhibition observed was not due to ADP-ribosylation, as the same effect was observed in a mutant devoid of the enzymes in the metabolic regulatory cascade operating in R. rubrum and some other diazotrophs. Even at low concentrations of the uncouplers used, a drastic decrease in the ATP/ADP ratio was observed. However, this decrease in the ATP/ADP ratio did not cause a decrease in nitrogenase activity. At higher concentrations of uncouplers, nitrogenase activity decreased but the ATP/ADP ratio remained essentially at a constant low level. These results support a model in which reduction of the electron donor(s) to nitrogenase in R. rubrum is coupled to the energization of the chromatophore membranes.     

Role of uptake hydrogenase in providing reductant for nitrogenase in Rhizobium leguminosarum bacteroids

The role of uptake hydrogenase in providing reducing power to nitrogenase was investigated in Rhizobium leguminosarum bacteroids from nodules of Pisum sativum L. (cv. Homesteader). H₂ increased the rate of C₂H₂ reduction in the absence of added substrates. Malate also increased nitrogenase (C₂H₂) activity while decreasing the effect of H₂. At exogenous malate concentrations above 0.05 mM no effect of H₂ was seen. Malate appeared to be more important as a source of reductant than of ATP. When iodoacetate was used to minimize the contribution of endogenous substrates to nitrogenase activity in an isolate in which H₂ uptake was not coupled to ATP formation, H₂ increased the rate of C₂H₂ reduction by 77%. In the presence of iodoacetate, an ATP-generating system did not enhance C₂H₂ reduction, but when H₂ was also included, the rate of C₂H₂ reduction was increased by 280% over that with the ATP-generating system alone. The data suggest that, under conditions of substrate starvation, the uptake hydrogenase in R. leguminosarum could provide reductant as well as ATP in an isolate in which the H₂ uptake is coupled to ATP formation, to the nitrogenase complex.     

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.     

The stoichiometry (ATP/2e− ratio) of non-cyclic photophosphorylation in isolated spinach chloroplasts

1. The stoichiometry of non-cyclic photophosphorylation and electron transport in isolated chloroplasts has been re-investigated. Variations in the isolation and assay techniques were studied in detail in order to obtain optimum conditions necessary for reproducibly higher ADP/O (equivalent to ATP/2e^?) and photosynthetic control ratios.2. Studies which we carried out on the possible contribution of cyclic phosphorylation to non-cyclic phosphorylation suggested that not more than 10% of the total phosphorylation found could be due to cyclic phosphorylation.3. Photosynthetic control, and the uncoupling of electron transport in the presence of NH₄Cl, were demonstrated using oxidised diaminodurene as the electron acceptor. A halving of the ADP/O ratio was found, suggesting that electrons were being accepted between two sites of energy conservation, one of which is associated with Photosystem I and the other associated with Photosystem II.4. ATP was shown to inhibit State 2 and State 3 of electron transport, but not State 4 electron transport or the overall ADP/O ratio, thus confirming its activity as an energy transfer inhibitor. It is suggested that part of the non-phosphorylating electron transport rate (State 2) which is not inhibited by ATP is incapable of being coupled to subsequent phosphorylation triggered by the addition of ADP (State 3). If the ATP-insensitive State 2 electron transport is deducted from the State 3 electron transport when calculating the ADP/O ratio, a value of 2.0 is obtained.5. The experiments reported demonstrate that there are two sites of energy conservation in the non-cyclic electron transfer pathway: one associated with Photosystem II and the other with Photosystem I. Thus, non-cyclic photophosphorylation can probably produce sufficient ATP and NADPH “in vivo” to allow CO₂ fixation to proceed.     

The differential action of metronidazole on nitrogen fixation, hydrogen metabolism, photosynthesis and respiration in Anabaena and Scenedesmus.

Metronidazole (2-methyl-5-nitroimidazole-1-ethanol) at 1--2 mM levels has been shown to be a selective inhibitor of nitrogenase activity in Anabanena. Two constitutive hydrogenases and photosynthesis are insensitive to metronidazole at these same concentrations. At higher concentrations metronidazole inhibits photosynthesis in Anabaena while photoreduction and to a lesser extent photohydrogen production are retarded in Scenedesmus. Respiration is slightly stimulated at high metronidazole levels in both algae. The reductant source for nitrogenase in Anabaena and photohydrogen production and photoreduction electron transport in Scenedesmus are discussed. Due to the activity to metronidazole as a selective inhibitor of ferredoxin-associated processes, it should prove to be useful in N2 fixation studies and in distinguishing between ferredoxin-linked reactions of different sensitivities and other activities not associated with low reduction potential components.     

Respiratory control determines respiration and nitrogenase activity of Rhizobium leguminosarum bacteroids.

The relationship between the O2 input rate into a suspension of Rhizobium leguminosarum bacteroids, the cellular ATP and ADP pools, and the whole-cell nitrogenase activity during L-malate oxidation has been studied. It was observed that inhibition of nitrogenase by excess O2 coincided with an increase of the cellular ATP/ADP ratio. When under this condition the protonophore carbonyl cyanide m-chlorophenylhydrazone (CCCP) was added, the cellular ATP/ADP ratio was lowered while nitrogenase regained activity. To explain these observations, the effects of nitrogenase activity and CCCP on the O2 consumption rate of R. leguminosarum bacteroids were determined. From 100 to 5 microM O2, a decline in the O2 consumption rate was observed to 50 to 70% of the maximal O2 consumption rate. A determination of the redox state of the cytochromes during an O2 consumption experiment indicated that at O2 concentrations above 5 microM, electron transport to the cytochromes was rate-limiting oxidation and not the reaction of reduced cytochromes with oxygen. The kinetic properties of the respiratory chain were determined from the deoxygenation of oxyglobins. In intact cells the maximal deoxygenation activity was stimulated by nitrogenase activity or CCCP. In isolated cytoplasmic membranes NADH oxidation was inhibited by respiratory control. The dehydrogenase activities of the respiratory chain were rate-limiting oxidation at O2 concentrations (if >300 nM. Below 300 nM the terminal oxidase system followed Michaelis-Menten kinetics (Km of 45 +/- 8 nM). We conclude that (i) respiration in R. leguminosarum bacteroids takes place via a respiratory chain terminating at a high-affinity oxidase system, (ii) the activity of the respiratory chain is inhibited by the proton motive force, and (iii) ATP hydrolysis by nitrogenase can partly relieve the inhibition of respiration by the proton motive force and thus stimulate respiration at nanomolar concentrations of O2.     

Electron transport to nitrogenase in Rhodospirillum rubrum: the role of NAD(P)H as electron donor and the effect of fluoroacetate on nitrogenase activity

The role of the reactions of the TCA cycle in the generation of reductant for nitrogenase in Rhodospirillum rubrum has been investigated. Addition of fluoroacetate inhibited nitrogenase activity almost completely when pyruvate or endogenous sources were used as electron donors, whereas the inhibition was incomplete when malate, succinate or fumarate were used. Addition of NAD(P)H to cells supported nitrogenase activity, both with and without prior addition of fluoroacetate. We suggest that the role of the TCA cycle in nitrogen fixation in R. rubrum is to generate reduced pyridine nucleotides which are oxidized by the components of the electron transport pathway to nitrogenase.     

Cellular ATP levels and nitrogenase switchoff upon oxygen stress in chemostat cultures of Azotobacter vinelandii.

When Azotobacter vinelandii, growing diazotrophically in chemostat culture, was subjected to sudden increases in the ambient oxygen concentration (oxygen stress), nitrogenase activity was switched off and cellular ATP pools decreased at rates depending on the stress level. Following a fast decrease, the ATP pool approached a lower level. When the stress was released, these effects were reversed. The reversible decrease of the ATP pool upon oxygen stress could also be observed with cultures assimilating ammonium and, at the same time, fixing dinitrogen because of growth at a high C/N ratio but not with cultures growing only at the expense of ammonium. When strains OP and UW136 of A. vinelandii were subjected to long-term increases in ambient oxygen, the sizes of cellular ATP pools eventually started to increase to the level before stress and diazotrophic growth resumed. The cytochrome d-deficient mutant MK5 of A. vinelandii, however, impaired in aerotolerant diazotrophic growth, was unable to recover from stress on the basis of its ATP pool. The results suggest that adaptation to higher ambient oxygen depends on increased ATP synthesis requiring increased electron flow through the entire respiratory chain, which is possible only in combination with the more active, yet possibly uncoupled, branch terminated by cytochrome d. It is proposed that the decrease of the cellular ATP level under oxygen stress resulted from the increased energy and electron donor requirement of nitrogenase in reacting with oxygen.     

Electron paramagnetic resonance studies on nitrogenase. III. Function of magnesium adenosine 5′-triphosphate and adenosine 5′-diphosphate in catalysis by nitrogenase

The electron paramagnetic resonance spectra of azoferredoxin and molybdoferredoxin, components of the nitrogenase of Clostridium pasteurianum, disappear when the proteins are oxidized by certain dyes. When molybdoferredoxin and azoferredoxin were mixed in a 1 to 2 molar ratio, the electron paramagnetic resonance spectrum of the mixture was the sum of the two spectra with the exception of a slight change in the azoferredoxin signal. Addition of magnesium ATP and dithionite to this reconstituted nitrogenase resulted in a rapid change in the spectrum of both nitrogenase components; the molybdoferredoxin spectrum at all g-values decreased with a half-life less than 70 ms to 40% of its original size whereas the azoferredoxin signal changed in shape and size with a half-life of less than 40 ms. If an ATP-generating system was added instead of MgATP so that no ADP accumulated, then the molybdoferredoxin signal almost completely disappeared and the azoferredoxin signal changed in shape and slightly in size. These changes occurred at molar ratios of molybdoferredoxin to azoferredoxin from 1:14 to 1:0.2. If the reaction was allowed to consume the reductant, then the molybdoferredoxin signal(s) was restored but the azoferredoxin signal disappeared. The signal of azoferredoxin was restored and the signal of molybdoferredoxin again disappeared on addition of more reductant. The data suggest that for nitrogenase to catalyze the reduction of substrates, the magnesium ATP-reduced azoferredoxin complex is formed first and this complex then reacts with molybdoferredoxin to allow electron flow. In addition the data suggests that the rate-limiting reaction is an ATP-mediated electron flow from azoferredoxin to molybdoferredoxin. Finally the results show that no flow of electrons from azoferredoxin or molybdoferredoxin occurs when a mixture of ADP and ATP in a molar ratio of 2:1 is added initially or is reached by conversion of ATP to ADP and inorganic phosphate during reduction of protons. A mechanism consistent with these findings is proposed.     

The flexibility of metabolic interactions between chloroplasts and mitochondria in Nicotiana tabacum leaf

To examine the effect of mitochondrial function on photosynthesis, wild-type and transgenic Nicotiana tabacum with varying amounts of alternative oxidase (AOX) were treated with different respiratory inhibitors. Initially, each inhibitor increased the reduction state of the chloroplast electron transport chain, most severely in AOX knockdowns and least severely in AOX overexpressors. This indicated that the mitochondrion was a necessary sink for photo-generated reductant, contributing to the ‘P700 oxidation capacity’ of photosystem I. Initially, the Complex III inhibitor myxothiazol and the mitochondrial ATP synthase inhibitor oligomycin caused an increase in photosystem II regulated non-photochemical quenching not evident with the Complex III inhibitor antimycin A (AA). This indicated that the increased quenching depended upon AA-sensitive cyclic electron transport (CET). Following 12 h with oligomycin, the reduction state of the chloroplast electron transport chain recovered in all plant lines. Recovery was associated with large increases in the protein amount of chloroplast ATP synthase and mitochondrial uncoupling protein. This increased the capacity for photophosphorylation in the absence of oxidative phosphorylation and enabled the mitochondrion to act again as a sink for photo-generated reductant. Comparing the AA and myxothiazol treatments at 12 h showed that CET optimized photosystem I quantum yield, depending upon the P700 oxidation capacity. When this capacity was too high, CET drew electrons away from other sinks, moderating the P700⁺ amount. When P700 oxidation capacity was too low, CET acted as an electron overflow, moderating the amount of reduced P700. This study reveals flexible chloroplast–mitochondrion interactions able to overcome lesions in energy metabolism.     

Inorganic Phosphate (Pi) Enhancement of Dark Respiration in the Pi-Limited Green Alga Selenastrum minutum (Interactions between H+/Pi Cotransport,the Plasmalemma H+-ATPase,and Dark Respiratory Carbon Flow)

Inorganic phosphate (Pi) enrichment of the Pi-limited green alga Selenastrum minutum in the dark caused a 2.5-fold increase in the rate of O2 consumption. Alkalization of the media during Pi assimilation was consistent with a H+/Pi cotransport mechanism with a stoichiometry of at least 2 H+ cotransported per Pi. Dark O2 consumption remained enhanced beyond the period of Pi assimilation and did not recover until the medium was reacidified. This result, coupled with an immediate decrease in adenylate energy charge following Pi enrichment, suggested that respiration is regulated by the ATP requirements of a plasmalemma H+-ATPase that is activated to maintain intracellular pH and provide proton motive force to power Pi uptake. Concentrations of tricarboxylic acid cycle intermediates decreased following Pi enrichment and respiratory CO2 efflux increased, indicating that the tricarboxylic acid cycle was activated to supply reductant to the mitochondrial electron transport chain. These results are consistent with direct inhibition of electron transport by ADP limitation. Enhanced rates of starch breakdown and increases in glycolytic metabolites indicated that respiratory carbon flow was activated to supply reductant to the electron transport chain and to rapidly assimilate Pi into metabolic intermediates. The mechanism that initiates glycolytic carbon flow could not be clearly identified by product:substrate ratios due to the complex nature of Pi assimilation. High levels of triose-P and low levels of phosphoenolpyruvate were the primary regulators of pyruvate kinase and phosphofructokinase, respectively.     

Photosynthetic electron transport,ATP synthesis and nitrogenase activity in isolated heterocysts of Anabaena cylindrica

Isolated heterocysts of the N₂-fixing blue-green alga Anabaena cylindrica contain the Photosystem I components P-700, bound and soluble ferredoxins and ferredoxin-NADP reductase. They also show Photosystem I activity being able to photoreduce both methylviologen and NADP when ascorbate+dichlorophenol-indophenol acts as reductant. They photophosphorylate (64 μmol ATP produced/mg chlorophyll $\text{a}\text{h}$) and carry out oxidative phosphorylation (8.7 μmol ATP produced/mg chlorophyll $\text{a}\text{h}$). Ninety per cent of the total cell-free extract nitrogenase activity is located in the heterocyst fraction of aerobic cultures.     

The Relationships between Nitrogen Fixation and Several Kinds of Energy Metabolism by Gloeocapsa sp

Gloeocapsa sp., a species of anicellular blue-green alga, fixes dinitrogen mostly under light. The energy (ATP and reductant) needed for nitrogen fixation may be provided by photoreaction and aerobic catabolism. The nitrogenase activity (acetylene reduction) in vivo was decreased under the conditions of dark and inhibition of photo-phosphorylation or oxidative phosphorylation in the light. When photosystem Ⅱ was inhibited by the presence of DCMU, nitrogenase activities in both reactions of acetylene reduction and hydrogen evolution may be muchenhanced probably due to eliminating of the damage caused by the oxygen produced in the photolysis of water. The effects of the oxygen present in the atmosphere of the reaction systemand produced by the cells are different. It is shown that some trace oxygen seems to be required for nitrogen fixation by the energy supply of aerobic actabolism and oxidative phosphorylation. While the fixation of dinitrogen was inhibited by CO or no any reducible substrate was present, 70-100% of the energy accepted by nitrogenase was evolved as hydrogen. The algal cells also showed hydrogen uptake reaction, but no enhancement of nitrogen fixation by the hydrogen uptake was found.     

Effect of Oxygen and Malate on NO(3) Inhibition of Nitrogenase in Soybean Nodules

Soybean (Glycine max cv Hodgson) nitrogenase activity (C₂H₂ reduction) in the presence or absence of nitrate was studied at various external O₂ tensions. Nitrogenase activity increased with oxygen partial pressure up to 30 kilopascals, which appeared to be the optimum. A parallel increase in ATP/ADP ratios indicated a limitation of respiration rate by low O₂ tensions in the nodule, and the values found for adenine nucleotide ratios suggested that the nitrogenase activity was limited by the rate of ATP regeneration. In the presence of nitrate, the nitrogenase activity was low and less stimulated by increased pO₂, although the nitrite content per gram of nodules decreased from 0.05 to 0.02 micromole when pO₂ increased from 10 to 30 kilopascals. Therefore, the accumulation of nitrite inside the nodule was probably not the major cause of the inhibition. Instead, inhibition by nitrate could be due to competition for reducing power between nitrate reduction and bacteroid or mitochondrial respiration inside the nodule. This is supported by the observation of decrease in ATP/ADP ratios from 1.65, in absence of nitrate, to 0.93 in the presence of this anion at 30 kilopascals O₂. Furthermore, the inhibition was suppressed by the addition, to the plant nutrient solution, of 15 millimolar l-malate, a carbon substrate that is considered to be the major source of reductant for the bacteroids in the symbiosis.     

Bcl-2 inhibits apoptosis induced by mitochondrial uncoupling but does not prevent mitochondrial transmembrane depolarization

Bcl-2 overexpression protects cells from apoptosis induced by many cytotoxic agents. In this study, we investigated the effects of uncoupling mitochondrial electron transport in both HL60 wild-type and Bcl-2-overexpressing cells using the protonophore carbonyl cyanide m-chlorophenylhydrazone. We found that uncoupling mitochondrial electron transport induced apoptosis in wild-type, but not in Bcl-2-overexpressing cells. To investigate the mechanism of action of Bcl-2-mediated inhibition of cyanide m-chlorophenylhydrazone-induced apoptosis, we measured the mitochondrial transmembrane potential (DeltaPsi(m)) after uncoupling mitochondrial electron transport and found that both HL-60 wild-type and Bcl-2-overexpressing cells similarly depolarize following cyanide m-chlorophenylhydrazone exposure. Western blot analysis demonstrated that Bcl-2 overexpression did not completely block cytochrome c release from mitochondria after uncoupling mitochondrial electron transport. Since Bcl-2 may act as an antioxidant, we studied the effect of altering the cellular redox state prior to uncoupling mitochondrial electron transport in Bcl-2-overexpressing cells. Depletion of mitochondrial (but not cytosolic) glutathione induced apoptosis in Bcl-2-overexpressing cells and negated the protective effect of Bcl-2. Furthermore, following glutathione depletion, Bcl-2-overexpressing cells were sensitized to undergo cyanide m-chlorophenylhydrazone-induced apoptosis. These data suggest that the action of Bcl-2 is dependent, in part, on the cellular and mitochondrial redox state.     

Nitrogenase activity and regeneration of the cellular ATP pool in Azotobacter vinelandii adapted to different oxygen concentrations.

The in vivo activity of nitrogenase under aerobiosis was studied with diazotrophic chemostat cultures of Azotobacter vinelandii grown under glucose- or phosphate-limited conditions at different dilution rates (Ds, representing the growth rate mu) and different dissolved oxygen concentrations. Under steady-state conditions, the concentration as well as the cellular level of ATP increased in glucose-limited cultures when D was increased. Irrespective of the type of growth limitation or the dissolved oxygen concentration, the steady-state concentrations of ATP and of dinitrogen fixed by nitrogenase increased in direct proportion to each other. Specific rates of dinitrogen fixation as well as of the regeneration of the cellular ATP pool were compared with specific rates of cellular respiration. With glucose-limited cultures, the rate of regeneration of the ATP pool and the rate of respiration varied in direct proportion to each other. This relationship, however, was dependent on the dissolved oxygen concentration. As compared to the phosphate-sufficient control, phosphate-limited cultures exhibited the same nitrogenase activity but significantly increased respiratory activities. Rates of ATP regeneration and of cellular respiration of phosphate-limited cultures did not fit into the relationship characteristic of glucose-limited cultures. However, a linear relationship between the rates of dinitrogen fixation and ATP regeneration was identified irrespective of the type of growth limitation and the dissolved oxygen concentration. The results suggest that the ATP supply rather than cellular oxygen consumption is of primary importance in keeping nitrogenase activity in aerobic cultures of A. vinelandii.     

Effects of Water Stress on Energy Transduction in Chloroplasts

Water stress inhibited the photosynthetic O2 evolution rate of wheat leaves. It was shown that water stress decreased the electron transport rate, the activities of photophosphorylation and, coupling factor, and, the synthesis of ATP in chloroplasts. PS Ⅱ electron transport was more senstitive to water stress than PS Ⅰ. The reduction in photophosphorylation activity might be the results of reduction in electron transport rate and coupling factor activity, as well as the uncoupling effect of water stress on chloroplasts. The uncoupling effect could be due to the inhibition of light induced proton translocation in chloroplasts.     

Interactions of H2 and carbon metabolism in moderating nitrogenase activity of the Gunnera/Nostoc symbiosis

Nitrogenase activity in the Gunnera Nostoc symbiosis is shown to respond dramatically to the addition of glucose. H₂ can replace glucose in stimulating nitrogenase activity, but there is no H₂ stimulation in the presence of excess glucose. Net hydrogen evolution is strongly stimulated by addition of glucose. We postulate that carbohydrate supply and uptake hydrogenase can moderate the apparent activity of nitrogenase by supplying reductant and/or ATP. The recycling of a large proportion of the electron flux in nitrogenase through uptake hydrogenase maintains a high level of potential nitrogenase ready to take advantage of an influx of carbohydrate.