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 acetylene-induced decline in nitrogenase activity in root nodules of Elaeagnus angustifolia

The rate of C₂H₂ reduction by nodulated seedlings of Elaeagnus angustifolia (Russian olive) was followed as a function of time. Our goals were to: 1) determine whether there is an C₂H₂-induced decline in nitrogenase activity; and 2) investigate the mechanism of any decline. We found a peak rate of C₂H₂ reduction at 1.5 min after the introduction of C₂H₂ that was followed by a rapid decline in activity to 56% of the peak value. After the decline there was a partial recovery to 67% of the peak value at 60 min. When the pO₂ was decreased during the decline there was no significant effect (p0.05) on nitrogenase activity. When the C₂H₂ reduction assay was preceded by an incubation in a gas mixture (20 kPa O₂) with Ar substituted for N₂, there was little decline in nitrogenase activity as a function of time, but the rate of C₂H₂ reduction per gram nodule was reduced by approximately 50%. From these results we conclude that t Elaeagnus angustifolia exhibits a pronounced C₂H₂-induced decline and consequently the initial peak rate C₂H₂ reduction must be determined to obtain a valid measure of nitrogenase activity. We further suggest that cessation of NH₃ formation initiates the decline and that the decline is not caused by a change in nodule permeability to gases.     

Liberation of ammonia during nitrogen fixation by a facultatively heterotrophic cyanobacterium

Nitrogen fixation (acetylene reduction) and ammonia liberation were studied in a facultatively heterotrophic cyanobacterium. Autotrophically grown cells lost acetylene reduction activity when incubated under anaerobic conditions; the activity was maintained in the presence of methionine sulfoximine; or by pretreatment of the cells with a carbon supply. Heterotrophically grown cells maintained acetylene reduction activity anaerobically in the absence of methionine sulfoximine. Both cell types required light for maintenance of activity. The data indicate that methionine sulfoximine preserves the intracellular pool of reductant needed for nitrogenase. Autotrophs and heterotrophs both liberated ammonia when treated with methionine sulfoximine under nitrogen-fixing conditions. However, on treatment with methionine sulfoximine under anaerobiosis, heterotrophs also accumulated large amounts of intracellular ammonia in a pool which was diminished by the Photosystem II inhibitor, 3(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU). DCMU enhanced ammonia liberation without affecting acetylene reduction activity, and hence changed the ratio of acetylene reduced to ammonia formed by the heterotrophs. These data suggest a role for Photosystem II in ammonia liberation by the cyanobacteria.     

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.     

Hydrogen (h(2)) evolution by rhizobia after synergetic culture with soybean cell suspensions

Rhizobium japonicum cells were grown in liquid suspension cultures and separated from soybean plant cells by two to three bacterial membrane filters. Under these conditions, the plant cells elaborated materials into the medium which aided in the expression of a major rhizobial phenotype, namely, nitrogenase activity (acetylene reduction). The evolution of H₂ was also measured and this activity relative to acetylene reduction, was influenced by: (a) O₂; (b) the quantity of conditioned plant medium; and (c) ammonia. It is concluded that plant substances are of major importance in the H₂ evolution and nitrogenase activities of free-living rhizobia in suspension cultures.     

Physiology of Root-Associated Nitrogenase Activity in Oryza sativa

An intact method for measuring immediately linear rates of acetylene reduction was used to investigate the relationship between temperature, pH, O₂ concentration, and light intensity with the rate of root-associated nitrogenase activity in rice (Oryza sativa L.). Nitrogenase activity varied over a temperature range of 10 to 50°C and optimal rates of acetylene reduction were recorded at 35°C. Nitrogenase activity was also influenced by the pH of the liquid surrounding the roots prior to assay. Maximal rates of acetylene reduction were recorded over a pH range from 5.8 to 7.5. Nitrogenase activity was significantly reduced by concentrations of O₂ 0.5% (v/v) or more when the intact plant assay method was used, and no optimum was detected. However, when the plant tops were removed and the cut ends sealed from the atmosphere for 4 hours, acetylene reduction rates were maximal at 0.25% O₂ (v/v). When plants were moved from sunlight (1,400 microeinsteins per square meter per second) to shade (9.6) root-associated nitrogenase activity at 35° C significantly decreased 15 min later to one-fourth the rate and recovered upon return to sunlight. When the light intensity reaching the leaf canopy was progressively reduced from 1,050 to 54 microeinsteins per square meter per second the rate of root-associated nitrogenase activity decreased from 550 ± 135 to 192 ± 55 nanomoles ethylene per gram dry root per hour. The study suggests that the rate of root-associated nitrogenase activity in rice at constant temperature may well be mediated by variations in the concentration of O₂ resulting from changes in the rate of photosynthesis as well as variations in the rate of transport of photosynthate.     

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.     

Diffusion of Gases through Plant Tissues : Entry of Acetylene into Legume Nodules

I have measured acetylene diffusion through plant tissues including nodules from several species of legume—vetch, peas, soybeans, and Sesbania rostrata. The observed half-time for reequilibration of internal and external concentration is less than 1 minute for typical nodules. Inward diffusion of acetylene in air is rapid relative to the use of acetylene by nitrogenase so that diffusion of acetylene would not be a significant limiting factor for nitrogenase activity in air. However, under an atmosphere of Ar:O₂ where there is no N₂ reduction, the inward diffusion rate of acetylene into larger nodules could produce a measurable limitation of observed nitrogenase activity at low acetylene concentrations.     

Effect of ammonia on nitrogen fixation by the blue-green alga Anabaena cylindrica

Ammonia at a concentration of 1 ? 10^–3M completely inhibitednitrogenase activity, as measured by acetylene reduction, inthe blue-green alga Anabaena cylindrica. Free ammonia was undetectablein cells grown either on N₂ or ammonia within the limits ofprecision of the method used. Glutamic acid formed a major aminoacid pool in N₂-grown cells, and basic amino acids, i.e. lysine,histidine and arginine were abundant in ammonia-grown cells.A 10-fold increase in the amounts of labile amino compound(s)was observed when N₂-grown cells were exposed to ammonia. When cells were incubated under anaerobic conditions, the acetylene-reducingactivity increased 2-fold or more; ammonia had no effect. Oxygenwas required for ammonia to inhibit acetylene reduction. Modes of inhibition by ammonia on acetylene reduction were comparedwith those by chloramphenicol, puromycin, cycloheximide, DCMUand CCCP. On the basis of these comparisons we concluded thatammonia not only acts as a suppressor of nitrogenase synthesisbut also inhibits acetylene-reducing activity by lowering thesupply of reductant and/or of energy for the nitrogenase system. ¹This work was supported by grant No. 38814 from the Ministryof Education. (Received July 30, 1973; )     

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.     

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.     

C2H2 and Ar induce rapid declines in nitrogenase activity and CO2 evolution in nodules of Datisca glomerata

Preliminary studies have indicated that after addition of C₂H₂ there is a rapid decline in nitrogenase activity in the nodules of Datisca glomerata . The present work was undertaken to determine whether (1) there is also a decline in respiration and (2) the decline is associated with the cessation of ammonia production. The rates of C₂H₄ and CO₂ evolution by nodulated root systems of Datisca were measured as a function of time after exposure to C₂H₂. The peak rate of C₂H₄ evolution occurred at 30 s after C₂H₂ exposure, while the rate of CO₂ evolution started to decline at 60 s after exposure to C₂H₂. Incubation of nodules in a gas mixture containing Ar also caused a decline in CO₂ evolution. Further, pretreatment with Ar eliminated most of the C₂H₂-induced decline in nitrogenase activity and CO₂ evolution. These C₂H₂- and Ar-induced declines in Datisca nodules are more rapid than those reported in any other nodules. They are evidence that continued ammonia formation is essential for maintenance of normal nitrogenase activity in Datisca nodules.     

Nitrogenase activity and root nodule metabolism in response to O2 and short-term N2 deprivation in dark-treated Frankia-Alnus incana plants

Inhibition of nitrogenase (EC 1.18.6.1) activity by O₂ has been suggested to be an early response to disturbance in carbon supply to root nodules in the Frankia‐Alnus incana symbiosis. Intact nodulated root systems of plants kept in prolonged darkness of 22 h were used to test responses to O₂ and short‐term N₂ deprivation (1 h in Ar:O₂). By using a Frankia lacking uptake hydrogenase it was possible to follow nitrogenase activity over time as H₂ evolution in a gas exchange system. Respiration was simultaneously recorded as CO₂ evolution. Dark‐treated plants had lower initial nitrogenase activity in N₂:O₂ (68% of controls), which declined further during a 1‐h period in the assay system in N₂:O₂ at 21 and 17% O₂, but not at 13% O₂. When dark‐treated plants were deprived of N₂ at 21 and 17% O₂ nitrogenase activity declined rapidly to 61 and 74%, respectively, after 20 min, compared with control plants continuously kept in their normal light regime. In contrast, there was no decline in dark‐treated plants at 13% O₂, and only a smaller and temporary decline in control plants at 21% O₂. When dark‐treated plants were kept at 21% O₂ during 45 min prior to N₂ deprivation at 17% O₂ the decline was abolished. This supports the idea that the decline in nitrogenase activity observed in N₂:O₂ at 21% O₂ and during N₂ deprivation was caused by O₂, which affected a sensitive nodule fraction. Nodule contents of the amino acids Gln and Cit decreased during N₂ deprivation, suggesting decreased assimilation of NH₄⁺. Contents of ATP and ADP in nodules were not affected by short‐term N₂ deprivation. ATP/ADP ratios were about 5 indicating a highly aerobic metabolism in the root nodule. We conclude that nitrogenase activity of Alnus plants exposed to prolonged darkness becomes more sensitive to inactivation by O₂. It seemed that dark‐treated plants could not adjust their nodule metabolism at higher perceived pO₂ and during cessation of NH₄⁺ production.     

Ontogenetic Variation of Nitrogenase, Nitrate Reductase, and Glutamine Synthetase Activities in Oryza sativa

The relationship between the rates of nitrogenase, nitrate reductase, and glutamine synthetase activities, and plant ontogeny in rice (Oryza sativa L.), cultivar `M9', grown in salt marsh sediment with and without nitrate treatment was studied. In both treatments, nitrogenase activity measured as the immediate linear rate of acetylene reduction by bacteria associated with the roots varied with plant age. In control plants, the nitrogenase activity developed during the vegetative stage, peaked during early reproductive growth and then declined. The application of 10 kilograms N per hectare as KNO₃ once every 2 weeks delayed the development of and decreased the nitrogenase activity. The nitrogenase activity in both treatments developed as leaf nitrate reductase activity declined. The per cent nitrogen of roots was negatively correlated with the rates of acetylene reduction during the life cycles of control and nitrate-treated plants. This suggests that the concentration of combined nitrogen in the plants controlled the development and rate of root-associated nitrogenase activity. During reproductive growth, no nitrate reductase activity was detected in the roots from either treatment. In control plants, the patterns of nitrogenase activity and glutamine synthetase activity in the roots were similar. Thus, rice roots have the potential to assimilate ammonia while fixing N₂. During the vegetative and early reproductive stages of growth, the development of maximal rates of nitrogenase activity coincided with an increase of total nitrogen of the plants in both treatments.     

Effect of temperature on h(2) evolution and acetylene reduction in pea nodules and in isolated bacteroids

Nitrogenase (EC 1.7.99.2) activity in pea (Pisum savitum) nodules formed after infection with Rhizobium leguminosarum (lacking uptake hydrogenase) was measured as acetylene reduction, H₂ evolution in air and H₂ evolution in Ar:O₂. With detached roots the relative efficiency, calculated from acetylene reduction, showed a decrease (from 55 to below 0%) with increasing temperature. With excised nodules and isolated bacteroids similar results were obtained. However, the relative efficiency calculated from H₂ evolution in Ar:O₂ was unaffected by temperature. Measurements on both excised nodules and isolated bacteroids showed a marked difference between acetylene reduction and H₂ evolution in Ar:O₂ with increased temperature, indicating that either acetylene reduction or H₂ evolution in Ar:O₂ are inadequate measures of nitrogenase activity at higher temperature.     

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.     

Physiological sources of reductant for nitrogen fixation activity in Nostoc sp. strain UCD 7801 in symbiotic association with Anthoceros punctatus.

Pure cultures of the symbiotic cyanobacterium-bryophyte association with Anthoceros punctatus were reconstituted by using Nostoc sp. strain UCD 7801 or its 3-(3,4-dichlorophenol)-1,1-dimethylurea (DCMU)-resistant mutant strain, UCD 218. The cultures were grown under high light intensity with CO2 as the sole carbon source and then incubated in the dark to deplete endogenous reductant pools before measurements of nitrogenase activities (acetylene reduction). High rates of light-dependent acetylene reduction were obtained both before starvation in the dark and after recovery from starvation, regardless of which of the two Nostoc strains was reconstituted in the association. Rates of acetylene reduction by symbiotic tissue with the wild-type Nostoc strain decreased 99 and 96% after 28 h of incubation in the dark and after reexposure to light in the presence of 5 microM DCMU, respectively. Supplementation of the medium with glucose restored nitrogenase activity in the dark to a rate that was 64% of the illuminated rate. In the light and in the presence of 5 microM DCMU, acetylene reduction could be restored to 91% of the uninhibited rate by the exogenous presence of various carbohydrates. The rate of acetylene reduction in the presence of DCMU was 34% of the uninhibited rate of tissue in association with the DCMU-resistant strain UCD 218. This result implies that photosynthates produced immediately by the cyanobacterium can supply at least one-third of the reductant required for nitrogenase activity on a short-term basis in the symbiotic association. However, high steady-state rates of nitrogenase activity by symbiotic Nostoc strains appear to depend on endogenous carbohydrate reserves, which are presumably supplied as photosynthate from both A. punctatus tissue and the Nostoc strain.     

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.     

Effect of supra-ambient oxygen on nitrogenase activity (c(2)h(2)) and root respiration of soybeans and isolated soybean bacteroids

Isolated soybean (Glycine max [L.] Merr. cv Wilkin) bacteroids have O₂-dependent nitrogenase activity which is strongly inhibited by supraoptimal O₂ concentrations. Oxygen-inhibited nitrogenase activity is recovered by addition of 10 millimolar sodium succinate or by lowering the O₂ concentration.

Brief treatment of roots of intact soybean plants with 1.0 atmosphere O₂ reduces nitrogenase activity (C₂H₂). There is a rapid partial recovery of activity within 2 to 3 hours, and a slower return to near normal levels by 36 hours. The drop and recovery of nitrogenase activity is accompanied by a parallel drop and increase in root respiration. There is a direct relationship between the change in respiration and the change in acetylene reduction following O₂ treatment. The O₂-mediated changes in nitrogenase activity and root respiration are not affected by the planting medium. The ratio of the change in respiration to the change in nitrogenase activity was the same in 13 soybean cultivars.

     

A Major Error in the Acetylene Reduction Assay: Decreases in Nodular Nitrogenase Activity Under Assay Conditions

Observations on both attached nodulated roots and detached noduleshave revealed that nitrogenase activity in many legume speciesdeclined rapidly in the presence of acetylene, with a concurrentreduction in respiration. The reduction began within a few minutesof exposure to acetylene and continued for 30–60 min beforea new steady-state was attained. A similar decline in H₂ evolutionand respiration was observed when N₂ was replaced with argonor helium. This suggests that the decrease is linked to thecessation of ammonia production. Measurements of ¹⁵N₂ uptakedemonstrated that it is the pre-decline rather than final rateof ethylene production which represents the real rate of nitrogenaseactivity. The implications of these findings for the interpretationof acetylene reduction and hydrogen evolution data are considered. Key words: Roots, Acetylene, Nitrogenase activity