Evidence for adenylate nucleotide transport (ATP-ADP translocation) in vesicles of Frankia sp. strain EAN1pec.

Atractyloside and carboxyatractyloside partially inhibited nitrogenase activity (acetylene reduction) by isolated vesicles of Frankia strain EAN1pec. Extracts of disrupted vesicles showed nitrogenase activity that was not affected by the inhibitors. The vesicles accumulated ATP by an atractyloside-sensitive mechanism. This inhibition of ATP uptake was reversed when vesicles were permeabilized by detergent. Uptake of ATP was inhibited by excess ATP and ADP, but not AMP or adenosine, and by a calcium-dependent ATPase inhibitor. Uptake was stimulated by calcium ions. Accumulation of ATP was accompanied by release of ADP and AMP from the vesicles. The ATP taken up by vesicles and cells grown with N2 as the nitrogen source was found in the corresponding cell pools only as ATP. The data indicate activity of an ATP-ADP translocase system in vesicles of this organism. The role of ATP translocation in the symbiosis between Frankia strain EAN1pec and plant root nodules is discussed.     

The nitrogen fixation system of photosynthetic bacteria. I. Preparation and properties of a cell-free extract from Chromatium

The preparation and properties of cell-free extracts of the photosynthetic bacterium Chromatium which give consistent and appreciable nitrogen fixation are described. Nitrogen fixation required ATP and reducing power. Reducing power was supplied by reduced ferredoxin or, in its absence, by sodium dithionite or H₂, in the presence of catalytic amounts of a viologen dye. ATP was supplied by phosphocreatine and creatine phosphokinase, with a catalytic amount of free ATP.

The Chromatium nitrogenase complex was found to have the typical properties of other nitrogenases, i.e., reduction of N₂ to ammonia, and of acetylene to ethylene, ATP-dependent H₂ evolution and reductant-dependent ATP hydrolysis.     

Modes of reduction of nitrogen 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.     

Respiration supported nitrogenase activity of isolated Rhizobium meliloti bacteroids

Bacteroids having a high level of respiration-supported nitrogenase activity were isolated from nitrogen-fixing alfalfa root nodules. Gentle maceration under anaerobic conditions in the presence of sodium succinate and a fatty acid scavenging agent were employed in this method. A large proportion of isolated bacteroids retained a triple membrane structure as shown by transmission electron microscopy. Dicarboxylic acids of the TCA cycle (malate, fumarate, succinate), but not glutamate or aspartate, supported sufficient respiratory activity to supply the nitrogenase system with ATP and reducing equivalents and to protect the nitrogenase system from inactivation by 4% oxygen over a period of 20-30 min. Sugars did not support nitrogenase activity in intact bacteroids. The properties of the isolated bacteroids were ascribed to minimal damage to the cytoplasmic membrane and peribacteroidal membrane during isolation. With succinate as substrate and oxygen as terminal electron acceptor, initial nitrogenase activity was determined at 4% oxygen in the gas phase of the assay system employed. At this oxygen concentration, the sustained rate of acetylene reduction by respiring bacteroids was linear up to 30 min. Bacteroid activity declined rapidly with time of exposure to oxygen above 4% in the gas phase. The optimum temperature range for this activity was 10-20 degrees C. Nitrogenase activity was measurable at incubation temperatures below 10 degrees C under 4% oxygen. Functionally intact bacteroids had little nitrogenase activity under anaerobic conditions in the presence of an external source of ATP and reductant. Treatment of the bacteroids with chlorpromazine eliminated respiration-supported activity and rendered the bacteroid cell membrane permeable to external ATP. Bacteroids treated with chlorpromazine had high acetylene reducing activity with external ATP and dithionite in the absence of oxygen.     

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.     

呼吸活性的下降可解释水分亏缺对银合欢根瘤固氮酶活性的抑制(英)

在温室条件下研究了水分亏缺对银合欢根瘤的水分关系、固氮酶活性（乙炔还原活性）、呼吸活性以及蔗糖代谢有关酶活性的影响。随着土壤含水量的下降,根瘤水势也相继下降。土壤干旱不但显著地抑制了根瘤乙炔还原的活性,而且对根瘤的呼吸活性、ATP的产生以及催化蔗糖降解的碱性转化酶和蔗糖合成酶的活性也具强烈的抑制作用。然而,根瘤可溶性总糖含量则不受土壤干旱的影响。用呼吸抑制剂DNP处理根瘤后,其固氮酶活性、呼吸活性及ATPI含量都受到极显著的抑制。这都表明,水分胁迫对根瘤呼吸活性及ATP产生的抑制可解释干旱条件下固氮酶活性的下降。     

Permeabilization of isolated heterocysts of Anabaena sp. strain 7120 with detergent.

Heterocysts isolated from Anabaena sp. strain 7120 with lysozyme plus sonication were permeabilized with the cationic detergent cetyltrimethylammonium bromide, and they then exhibited comparable acetylene reduction activity in the light and dark with an ATP-regenerating system plus dithionite. The detergent diminished the effect of H2 in enhancing acetylene reduction.     

Calcium and magnesium effects on symbiotic nitrogen fixation in the alfalfa (M. sativa) –Rhizobium meliloti system

An investigation of the roles of calcium and magnesium ions in symbiotic nitrogen fixation by legumes has shown that alfalfa plants ( Medicago sativa L. cv. Saranac and Apollo) deficient in either cation were poorly nodulated and retarded in growth on nitrogen-free media. This effect was reversed by supplementation with normal levels of these cations. After recovery, the calcium deficient seedlings showed continuing effects of early mineral deficiencies but recovered to 75% of the nitrogenase activity and had nearly the same yield as control plants. Magnesium deficient plants recovered nitrogenase activity to the same degree but grew to only about 50% of the weight of controls. Supplementation of non-deficient seedlings grown on N-free media with varying amounts of Ca²⁺ and Mg²⁺ resulted in the identification of an optimal ratio of calcium and magnesium near 2 when neither cation was growth limiting. A highly significant positive correlation was obtained between yield of dry matter and the fraction of total expressed nitrogenase activity that was actually available for dinitrogen reduction (nitrogen reducing equivalent). Bacteroids isolated from root nodules and freed of plant cytoplasmic components required high magnesium levels for maximal utilization of externally supplied ATP and dithionite. Ca⁺ was antagonistic to this activity but complemented Mg²⁺ in stimulating the respiration-supported nitrogenase activity of intact bacteroids which had been treated with a chelating agent. The effects of calcium and magnesium on the nitrogenase system of intact bacteroids may be due to binding of the Ca²⁺ ions to the bacteroid membrane.     

Isolation and nitrogen-fixing activity of Frankia sp. strain CpI1 vesicles.

Under N2-fixing conditions in aerobic culture and in symbiosis, frankiae produce spherical, multicellular structures that have been called vesicles. The vesicles have been proposed as the site of nitrogen fixation. We isolated vesicles by using density centrifugation in a single-step sucrose gradient. Vesicles migrated out of 50% (wt/vol) sucrose and banded at the 40 to 50% sucrose interface; they were intact, as assessed by transmission electron microscopy, and were free of hyphal contamination. Specific activities of nitrogenase in vesicles prepared anaerobically were up to 100-fold greater than the specific activity of the largely hyphal pellet, depending on the recovery of vesicles. All of the activity in the pellet could be accounted for by the number of vesicles present in the pellet. Glutamine synthetase activity in crude extracts of vesicles was extremely low.     

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.     

Bacteroids Isolated from Ineffective Nodules of Pisum sativum Mutant E135 (syml3) Lack Nitrogenase Activity but Contain the Two Protein Components of Nitrogenase

Pea mutant E135 (sym15) forms ineffective (Fix^–) nodulesthat lack nitrogen fixing activity. To determine the developmentalstep blocked in E135 nodules we studied the nitrogenase activitiesin isolated bacteroids and in cell-free extracts of bacteroids,and measured the two components of nitrogenase protein in bacteroids.Bacteroids prepared anaerobically from E135 nodules showed noacetylene reduction activity in the presence and absence ofmyoglobin. Furthermore, no acetylene reduction activity by cell-freeextracts of E135 bacteroids was detected in the presence ofATP-generating system and dithionite. However, immuno-blottinganalyses revealed the presence of nitrogenase components I andII in E135 nodule bacteroids. These results suggest that a hostplant gene is involved in the expression of nitrogenase activityin symbiotic bacteria. (Received May 11, 1998; Accepted August 7, 1998)     

Interaction between hydrogenase, nitrogenase, and respiratory activities in a Frankia isolate from Alnus rubra

H2 uptake and H2-supported O2 uptake were measured in N2-fixing cultures of Frankia strain ArI3 isolated from root nodules of Alnus rubra. H2 uptake by intact cells was O2 dependent and maximum rates were observed at ambient O2 concentrations. No hydrogenase activity could be detected in NH4+-grown, undifferentiated filaments cultured aerobically indicating that uptake hydrogenase activity was associated with the vesicles, the cellular site of nitrogen fixation in Frankia. Hydrogenase activity was inhibited by acetylene but inhibition could be alleviated by pretreatment with H2. H2 stimulated acetylene reduction at supraoptimal but not suboptimal O2 concentrations. These results suggest that uptake hydrogenase activity in ArI3 may play a role in O2 protection of nitrogenase, especially under conditions of carbon limitation.     

Effects of water stress on nitrogenase activity in Abuts incana

Tolerance to water stress was studied in plants of grey alder, Alnus incana (L.) Moench, grown in a climate chamber in pots of sand supplied with a nitrogen-free nutrient solution. The plants were subjected to a single drying and recovery cycle, during which acetylene reduction, transpiration and stomatal resistance were measured. At different stress levels the plants were placed in a closed system to equilibrate the water potential in the plant-soil system. The water potential of the plants was determined, after which they were watered and their recovery studied. Nitrogenase activity showed low tolerance to water deficit. At moderate stress (−0.6 to −0.8 MPa) acetylene reduction was reduced by half, and at more severe stress, (< −1 MPa) activity was near zero. There was a rapid decrease in nitrogenase activity coincident with stomatal closure, which indicates a continuous need for photoassimilates for nitrogenase activity. Nodules or nitrogenase activity seemed to be weak sinks for assimilates compared with root pressure bleeding. Measurements of nitrogenase activity in root nodule homogenates supplied with ATP and reductant suggested a loss of active nitrogenase in the nodules in response to water stress. The recovery from moderate stress or long dark treatment took several days, and recovery from severe stress took still longer. Shortage of assimilates and disturbances in oxygen and nitrogen balances in the nodules are discussed as reasons for the reduced nitrogenase activity in response to water stress.     

Nitrogenase. VII. Effect of component ratio, ATP and H2 on the distribution of electrons to alternative substrates.

Some kinetic properties of purified component I (Mo-Fe protein) and component II (Fe protein) of nitrogenase (EC 1.7.99.2) from Azotobacter vinelandii have been examined. The apparent Km values for reducible substrates (0.1 atm for N2, 0.01 atm for acetylene) and dithionite (0.5 mM) are similar for osmotically shocked cell lysates and purified components. However, the ATP dependence of acetylene and N2 reduction varies sigmoidally with ATP concentration and as a function of the relative and absolute concentration of components I and II in the assay. Acetylene is reduced in preference to N2 in competitive assays when component I is in relative excess. Acetylene reduction is not as dependent upon ATP concentration as is N2 reduction, so that acetylene is also a preferred substrate at lower ATP levels. Hydrogen specifically inhibits N2 reduction, diverting electrons to acetylene when both substrates are present in the assay. We propose a model of the enzyme activity, in which the substrates for reduction are bound to component I with electrons being activated by component II. ATP may be involved in activating electrons and in maintaining the appropriate conformation or reduction state of components to allow effective reduction of substrates. The relative rate of reduction of alternative substrates is dependent on the concentration of the particular state(s) capable of reacting with each substrate. The concentration of a particular state of component I is a function of components I, II and ATPL     

Nif- Hup- mutants of Rhizobium japonicum.

Two H2 uptake-negative (Hup-) Rhizobium japonicum mutants were obtained that also lacked symbiotic N2 fixation (acetylene reduction) activity. One of the mutants formed green nodules and was deficient in heme. Hydrogen oxidation activity in this mutant could be restored by the addition of heme plus ATP to crude extracts. Bacteroid extracts from the other mutant strain lacked hydrogenase activity and activity for both of the nitrogenase component proteins. Hup+ revertants of the mutant strains regained both H2 uptake ability and nitrogenase activity.     

Factors influencing dark nitrogen fixation in a blue-green alga.

Nitrogen-fixing activity declines first rapidly and then more gradually when Anabaenopsis circularis is transferred from light into dark conditions. The rate and duration of dark acetylene reduction (nitrogen fixation) depend upon conditions prevailing during the preceding light period. Factors (such as light intensity, CO2 concentration, and supply of glucose), which in the light affect photosynthesis and the accumulation of reserve carbon, have a profound effect on dark nitrogen fixation. Glucose greatly promotes nitrogen fixation in the light and supports prolonged nitrogenase activity in the dark. The results suggest that heterotrophic nitrogen fixation by blue-green algae in the field may be important both under light and dark conditions.     

Isolation and structure of the lipid envelopes from the nitrogen-fixing vesicles of Frankia sp. strain CpI1.

Frankia vesicles are differentiated during nitrogen starvation; they contain nitrogenase whether produced by free-living frankiae or by frankiae in actinorhizal root nodules. Vesicles are surrounded by envelopes of several monolayers of uncharacterized lipid. It has been suggested that the envelope limits diffusion of O2 into the vesicle cytoplasm, thereby preventing inactivation of nitrogenase. Whole vesicles were prepared on sucrose gradients and sonicated, and vesicle envelopes were isolated on top of a cushion of 40% sucrose. Transmission electron microscopy of potassium permanganate-fixed envelopes confirmed the purity of these preparations. Only the outer and inner envelope layers were visible in permanganate-fixed intact vesicles; the laminae were not visible in aldehyde-osmium-fixed, lead citrate-uranyl acetate-stained whole vesicles. However, the laminated nature of the envelope was clearly evident in sonicated vesicles and in envelope fragments fixed with KMnO4. The observations indicate that partial disruption of the vesicle envelope enables its visualization with permanganate fixation, and these observations open the way for further studies on the relationship of the vesicle surface to environmental conditions.     

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.     

Development of the nitrogen fixing apparatus in the legumes,Centrosema pubescens Benth., and Vigna unguiculata L. Walp.

The sequence of events leading up to the establishment of symbiotic nitrogen-fixation were studied in two tropical legumes, Centrosema pubescens Benth, and Vigna unguiculata L. Walp. Parameters measured included fresh and dry weights, chlorophyll and leghaemoglobin contents, as well as the activities of NADH-nitrate reductase (EC 1.6.6.1), and nitrogenase (nitric-oxide reductase-EC 1.7.99.2) in plants that were inoculated with suitable rhizobia or which were watered with potassium nitrate. Dry weight and photosynthetic activity of both species followed the sigmoidal pattern which is characteristic of most plants. Growth was little different in either a qualitative or quantitative sense whether nitrogen was supplied as nitrate or through dinitrogen fixation. Although the biochemical sequence of events was dependent on the limiting sensitivities of the individual assays used, the data suggest that nitrate reductase is the first measurable enzymatic activity in the nodules (and roots), followed by acetylene reduction and leghaemoglobin in that order. It is possible therefore, that low levels of symbiotic nitrogen fixation occur in the nodules in the absence of leghaemoglobin. Nitrate reductase activity in C. pubescens nodules was negatively exponentially correlated with nitrogenase activity of the same nodules, suggesting a changing metabolism in old nodules. These data are discussed in terms of environmental and physical factors known to control nitrogen fixation.     

Consequences of Sporangial Development for Nodule Function in Root Nodules of Comptonia peregrina and Myrica gale

Frankia sp., the actinomycetous endophyte in nitrogen-fixing actinorhizal nodules, may differentiate two forms from its hyphae: vesicles and sporangia. In root nodules of Comptonia peregrina (L.) Coult. and Myrica gale L., sporangia may be either absent or present. Nitrogenase activity and symbiotic efficiency were contrasted in spore(+) and spore(−) nodules of these two host genera. Seedlings of C. peregrina nodulated with the spore(+) inoculum showed only 60% of the nitrogenase activity and 50% of the net size of their spore(−) counterparts after 12 weeks of culture. Measurements of acetylene reduction (i.e., nitrogenase activity) were coordinated with samplings of nodules for structural studies. Significant differences in acetylene reduction rates were discernible between spore(+) and spore(−) nodules commencing 4 weeks after nodulation, concomitant with the maturation of sporangia in the nodule. Spore(+) nodules ultimately reached less than half of the rate of nitrogenase activity of spore(−) nodules. Both types of nodules evolved only small amounts of molecular hydrogen, suggesting that both were equally efficient in recycling electrons lost to the reduction of hydrogen ions by nitrogenase. Respiratory cost of nitrogen fixation, expressed as the quotient of micromole CO₂ to micromole ethylene evolved by excised nodules, was significantly greater in spore(+) than in spore(−) nodules. M. gale spore(−) nodules showed variable effectivity, though all had low CO₂ to ethylene evolution ratios. M. gale spore(+) nodules resembled C. peregrina spore(+), with low effectivity and high respiratory cost for nitrogen fixation.