Nitrogenase — hydrogenase relationships in Rhizobium japonicum

The conditions necessary for coordinate derepression of nitrogenase and O₂-dependent hydrogenase activities in free-living cultures of Rhizobium japonicum were studied. Carbon sources were screened for their ability to support nitrogenase, and then hydrogenase activities. There was a positive correlation between the level of nitrogenase and corresponding hydrogenase activities among the various carbon substrates. The carbon substrate -ketoglutarate was able to support the highest levels of both nitrogenase and hydrogenase activities. When cells were incubated in -ketoglutarate-containing medium, without added H₂ but in the presence of acetylene (to block H₂ evolution from nitrogenase) significant hydrogenase activity was still observed. Complete inhibition of nitrogenase-dependent H₂ evolution by acetylene was verified by the use of a Hup^- mutant. Hydrogen is therefore not required to induce hydrogenase. The presence of 10% acetylene inhibited derepression of hydrogenase. Constitutive (Hup^c) mutants were isolated which contained up to 9 times the level of hydrogenase acitivity than the wild type in nitrogenase induction medium. These mutants did not have greater nitrogenase activities than the wild type.This is contribution number 1254 from the Department of Biology and the McCollum-Pratt Institute Abbreviations: -Ketoglutarate-containing medium (LOKG) and pre-adaptation medium (SRM) as described in Materials and methods     

Isolation and characterization of heterocysts from Anabaena sp. strain CA

A comparative study has been made on the pigment composition and nitrogenase activity of whole filaments and isolated beterocysts from a mutant strain of Anabaena CA. The whole cell absorption spectra of intact filaments and isolated heterocysts showed close resemblance especially between 550–700 nm region. On a quantitative basis the chlorophyll a content was found almost equal between the vegetative cell and heterocyst but the c-phycocyanin content in the heterocyst was about 1/2 that of the vegetative cell. The purification of the phycobiliprotein on DEAE-cellulose showed the presence of c-phycocyanin (_max 615 nm) and allophycocyanin (_max 645 nm, shoulder 620 nm). Isolated heterocysts under H₂ showed acetylene reduction rates of 57 nmol C₂H₄/mg dry wt·min (342 mol C₂H₄/mg chl a·h), whereas intact filaments reduced at the rate of 18 nmol C₂H₄/mg dry wt·min (108 mol C₂H₄/mg chl a·h). This rate accounts for 30% recovery of nitrogenase activity in isolated heterocysts compared to whole filaments. The activity was strictly light dependent and was linear under H₂ for more than 3 h. Addition of as little as 5% H₂ under argon stimulated the C₂H₂ reductionseveral fold. The acetylene reduction (nitrogenase activity) also showed tolerance to 5% added O₂ either under H₂ or argon. The results suggest that the heterocyst of Anabaena CA-V is different in some characteristics (viz., higher endogenous C₂H₂ reduction rate, prolonged activity and higher levels of phycobiliproteins) than those reported in other Anabaena species.     

Antialgal activity of a hepatotoxin-producing cyanobacterium,Microcystis aeruginosa

Antimicrobial activity of toxin produced by a freshwater bloom-forming cyanobacterium Microcystis aeruginosa has been studied. When tested against certain green algae, cyanobacteria, heterotrophic bacteria and fungi, the toxin inhibited growth of only green algae and cyanobacteria. The toxin has been partially purified employing Thin layer chromatography (TLC) and High-performance liquid chromatography (HPLC) techniques and appears to be microcystin-LR (leucine–arginine). Both crude and purified toxins showed toxicity to mice, the clinical symptoms in test mice being similar to those produced by hepatotoxin. Purified toxin at a concentration of 50 g ml^–1 caused complete inhibition of growth followed by cell lysis in Nostoc muscorum and Anabaena BT1 after 6 days of toxin addition. Addition of toxin (25 g ml^–1) to the culture suspensions of the Nostoc and Anabaena strains caused instant and drastic loss of O₂ evolution. Furthermore a marked reduction (about 87%) in the ¹⁴CO₂ uptake was also observed at a concentration of 50 g ml^–1. Besides its inhibitory effects on photosynthetic processes, M. aeruginosa toxin (50 g ml^–1) also caused 90% loss of nitrogenase activity after 8 h of its addition. Experiments performed with ¹⁴C-labelled toxin indicate that the toxin uptake by cyanobacterial cells occurs both in light and dark. These results demonstrate that the toxin is strongly algicidal and point to the possibility that it may have an important role in establishment and maintenance of toxic blooms of M. aeruginosa in freshwater ecosystems. The relative significance of the hepatotoxic effect and the algicidal effect of the toxin is discussed with reference both to survival and dominance of M. aeruginosa in nature.     

Temporal separation of nitrogen fixation and photosynthesis in the filamentous,non-heterocystous cyanobacterium Oscillatoria sp.

When growing in laternating light-dark cycles, nitrogenase activity (acetylene reduction) in the filamentous, non-heterocystous cyanobacterium Oscillatoria sp. strain 23 (Oldenburg) is predominantly present during the dark period. Dark respiration followed the same pattern as nitrogenase. Maximum activities of nitrogenase and respiration appeared at the same time and were 3.6 mol C₂H₄ and 1.4 mg O₂ mg Chl a ^-1·h^-1, respectively. Cultures, adapted to light-dark cycles, but transferred to continuous light, retained their reciprocal rhythm of oxygenic photosynthesis and nitrogen fixation. Moreover, even in the light, oxygen uptake was observed at the same rate as in the dark. Oxygen uptake and nitrogenase activity coincided. However, nitrogenase activity in the light was 6 times as high (22 mol C₂H₄ mg Chl a ^-1·h^-1) as compared to the dark activity. Although some overlap was observed in which both oxygen evolution and nitrogenase activity occurred simultaneously, it was concluded that in Oscillatoria nitrogen fixation and photosynthesis are separated temporary. If present, light covered the energy demand of nitrogenase and respiration very probably fulfilled a protective function.     

The utilization of molecular hydrogen by the blue-green alga Anabaena cylindrica

The blue-green alga Anabaena cylindrica is found to consume molecular hydrogen in a hydrogenase dependent reaction. This hydrogen uptake proceeds in the dark and is strictly dependent on oxygen, thus representing a Knallgas reactions. Its rate is almost as high as that of the endogenous respiration in Anabaena. Studies with inhibitors reveal that hydrogen is utilized via the complete respiratory chain providing additional energy for the alga. CO plus C₂H₂ completely block the Knallgas reaction which explains the previously reported considerable increase in the total H₂ formation representing the difference between the nitrogenase-dependent H₂-evolution and the reutilization of the gas catalysed by the hydrogenase in intact Anabaena.H₂ is able to support the C₂H₂-reduction in the dark in a reaction again strictly dependent on oxygen. Moreover, H₂ is also consumed in experiments carried out under far red light and in the presence of dichlorophenyl-dimenthyl-urea (DCMU) where the energy for nitrogen fixation is no longer provided by respiration but by cyclic photophosphorylation. Under these conditions, H₂ is found to supply electrons for the formation of C₂H₄ from C₂H₂ in a reaction no longer dependent on the presence of oxygen. Moreover, in these experiments, the presence of H₂ stabilizes the C₂H₂-reduction activity against the deleterious effect of oxygen.Thus, this communication provides evidence for a triplicate function of the H₂-uptake catalysed by hydrogenase in intact Anabaena which is (a) to provide energy by the Knallgas reaction, (b) to supply reducing equivalents for nitrogenase, (c) to protect nitrogenase from damage by oxygen.Abbreviations DCMU N-(3,4-dichlorophenyl)N,N-dimethylurea - DNP 2-4-dinitrophenol - FCCP carbonylcyanid-p-trifluormethoxyphenyl-hydrazone(=p-CF₃-CCP) - Chl chlorophyll     

Autotrophic growth of nitrogen-fixingAzospirillum species and partial characterization of hydrogenase from strain CC

Out of 15 strains ofAzospirillum spp. isolated from the roots of different plants, only 4 (CY, M, CC, and AM) were able to grow autotrophically with H₂ and CO₂. All of them showed H₂ uptake in the presence of oxygen or methylene blue and ribulose-1,5-bisphosphate carboxylase activity. Among the four strains, strain CC isolated from the roots ofCenchrus cilliaris showed maximum H₂+O₂ uptake (32.5 l/min. mg protein) as well as H₂ uptake in the presence of methylene blue (41.4 l/min·mg protein) and also the maximum activity of ribulose-1,5-bisphosphate carboxylase (17 units [U]/g protein). The doubling time of this strain under autotrophic growth conditions and at low oxygen concentration (2.5%, vol/vol) was 10 h. At the same O₂ concentration the maximal rates of H₂+O₂ uptake were reached. The distribution of hydrogenase activity among soluble and particulate protein fractions revealed that the hydrogenase ofAzospirillum strain CC is a membrane-bound enzyme. It showed cross-reaction with antibodies raised against the membrane-bound hydrogenase ofAlcaligenes eutrophus. The hydrogenase in intact cells and crude extracts reacted with methylene blue, phenazine methosulfate, and ferricyanide, but not with NAD or FMN. The specific hydrogenase activity, with methylene blue as an acceptor, was 5.71 U/mg protein in crude extract at 9.38 U/mg protein in the membrane suspension. Hydrogen evolution from reduced viologen dyes could not be demonstrated. The hydrogenase is oxygen sensitive and can be optimally stabilized by addition of dithionite to H₂-gased samples.     

Hydrogen production and uptake by pea nodules as affected by strains of Rhizobium leguminosarum

Hydrogen evolution from root nodules has been reported to make N₂ fixation by some legume-Rhizobium symbiotic systems inefficient. We have surveyed the extent of H₂ evolution and estimated relative efficiencies of nodules of Austrian winter peas formed by 15 strains of R. leguminosarum. Their rates of H₂ evolution in air were about 30% of the rates of H₂ evolution under an atmosphere in which N₂ was replaced by Ar. Relative efficiency values based on C₂H₂ reduction rates ranged from 0.55 to 0.80. With some of the strains, hydrogenase activities were demonstrated in intact nodules and in bacteroids, but the levels of activity were insufficient to recycle all the H₂ evolved by the nitrogenase system. In both intact nodules and bacteroids the hydrogenase is less sensitive to O₂ damage than the nitrogenase system, so H₂ uptake capacity was observed in intact nodules by suppressing the nitrogenase-dependent H₂ evolution with an atmosphere containing a high O₂ concentration, and in bacteroids by using aerobically prepared bacteroid suspensions. The hydrogenase activity of both was dependent on O₂ consumption. A K _mfor H₂ of near 4 M was determined in suspension of bacteroids from nodules formed by strains 128C53 and 128C56.     

Occurrence and localization of an uptake hydrogenase in the filamentous heterocystous cyanobacteriumNostoc PCC 73102

Summary Free-living nitrogen-fixingNostoc PCC 73102, a filamentous heterocystous cyanobacterium originally isolated from coralloid roots of the cycadMacrozamia sp., were examined for the presence of an uptake hydrogenase (H₂ase) enzyme. In vivo and in vitro hydrogen uptake measurements were used to study activities and SDS-PAGE and Western immunoblots to reveal occurrence of the hydrogenase protein. Also, transmission electron microscopy and immunocytological labeling were used to study the cellular and subcellular distribution of H₂ase in theNostoc cells. In vivo measurements demonstrated an active uptake of hydrogen in both light and darkness. Light stimulated in vivo hydrogen uptake with approximately 100%, and this was further doubled by increasing the pH₂, from 56 to 208 M H₂. An in vitro hydrogen uptake of 1.1 mol H₂/ mg (protein)/h was observed when using phenazinemethosulphate as e^–-acceptor. Western immunoblots revealed that a polypeptide with a molecular weight of about 55 kDa was immunologically related to uptake H₂ase holoenzyme purified fromAlcaligenes latus. Immunolocalization demonstrated that the H₂ase protein was located both in heterocysts and vegetative cells. A higher specific labeling was associated with the cytoplasmic membranes where the vegetative cells are in contact with each other and where they actually are dividing into two vegetative cells. Using the particle analysis of an image processor, approximately equal H₂ase-gold labeling per cell area was observed in the nitrogen-fixing heterocysts compared to the photosynthetic vegetative cells. This study also shows that there was no correlation between presence of phycoerythrin and uptake H₂ase activity.Abbreviations H₂ase hydrogenase - IgG immunoglobulin G     

Measurement of diameters of estuarine bacteria and particulates in natural water samples by use of a submicron particle analyzer

Desulfovibrio vulgaris strain Madison outcompetedMethanobacterium strain ivanov for hydrogen when sulfate was in excess because of higher cell yield and growth rate and a greater affinity for hydrogen as a consequence of a lower Km and higher Vmax for in vivo hydrogenase activity.Desulfovibrio vulgaris displayed a growth yield of 1.1 g/mol H₂, a Km for tritium exchange of 4 M, and a specific in vivo hydrogenase activity of 2.17 DPM³H₂O×10³/g cell protein/h; whereasMethanobacterium strain ivanov had a yield of 0.6 g/mol H₂, a Km for tritium exchange of 14 M, and a specific in vivo hydrogenase activity of 0.38 DPM³H₂O×10³/g cell protein/h. Under these physiological conditions, the Gibbs free-energy change associated with methanogenesis and sulfidogenesis from H₂ was calculated to be-47.4 kJ/mol and-62.9 kJ/mol, respectively. When sulfidogenesis was limited by sulfate concentration, the methanogen was able to successfully compete with the sulfidogen for hydrogen. Competition between methanogens and sulfidogens for hydrogen is explained in terms of thermodynamic, kinetic, and other important considerations not discussed in the previous literature.     

Nitrogen fixation and nitrogen metabolism in heliobacteria

Three species of anoxygenic phototrophic heliobacteria, Heliobacterium chlorum, Heliobacterium gestii, and Heliobacillus mobilis, were studied for comparative nitrogen-fixing abilities and regulation of nitrogenase. Significant nitrogenase activity (acetylene reduction) was detected in all species grown photoheterotrophically on N₂, although cells of H. mobilis consistently had higher nitrogenase activity than did cells of either H. chlorum or H. gestii. Nitrogen-fixing cultures of all three species of heliobacteria were subject to switch-off of nitrogenase activity by ammonia; glutamine also served to switch-off nitrogenase activity but only in cells of H. mobilis and H. gestii. Placing photosynthetically grown heliobacterial cultures in darkness also served to switch-off nitrogenase activity. Dark-mediated switch-off was complete in lactate-grown heliobacteria but in pyruvate-grown cells substantial rates of nitrogenase activity continued in darkness. In all heliobacteria examined ammonia was assimilated primarily through the glutamine synthetase/glutamate synthase (GS/GOGAT) pathway although significant levels of alanine dehydrogenase were present in extracts of cells of H. gestii, but not in the other species. The results suggest that heliobacteria, like phototrophic purple bacteria, are active N₂-fixing bacteria and that despite their gram-positive phylogenetic roots, heliobacteria retain the capacity to control nitrogenase activity by a switch-off type of mechanism. Because of their ability to fix N₂ both photosynthetically and in darkness, it is possible that heliobacteria are significant contributors of fixed nitrogen in their paddy soil habitat.     

Nitrite reduction in Bacteroids of Rhizobium “hedysari” strain HCNT 1

Ex planta, bacteroids of the sulla-symbiont Rhizobium hedysari strain HCNT 1 terminated reduction of nitrite at nitrous oxide irrespective of the presence or absence of acetylene. Nitrate was not reduced during the experimental period, but slight nitrate reductase activity occurred if incubation with nitrate was prolonged (up to 15 h). As was observed in free-living cells, exposure of the bacteroids to the metal chelator, diethyldithiocarbamate, prevented reduction of nitrite, indicating the presence of a copper-containing nitrite reductase. Pulses of 10–75 M nitrite transiently impeded O₂ uptake in bacteroids, which resumed consumption of O₂ when the nitrite had been reduced. Exposure to >1.0 mM nitrite for 24h greatly inhibited nitrogenase activity (assayed as acetylene reduction activity) of bacteroids in planta. Exposure to the same concentrations of nitrite after 1h of incubation in the presence of acetylene almost completely stopped ongoing ethylene production in bacteroids of strain HCNT 1 extracted from nodules. Free cells of the non-nitrite-reducing R. hedysari strain CC 1335 were lacking in nitrogenase (acetylene-reduction) activity, whereas identically cultured (low-oxygen) strain HCNT 1 cells reduced both nitrite and acetylene.Abbreviations PMS phenazine methosulfate - DDC diethyldithiocarbamate     

Effect of redox mediators on nitrogenase and hydrogenase activities in Azotobacter vinelandii

In bioelectrochemical studies, redox mediators such as methylene blue, natural red, and thionine are used to studying the redox characteristics of enzymes in the living cell. Here we show that nitrogenase activity in Azotobacter vinelandii is completely inhibited by oxidized methylene blue (MB_o) when the concentration of this mediator in the medium is increased up to 72 M. This activity in A. vinelandii is somewhat inhibited by a coenzyme, ascorbic acid (AA). However, the nitrogenase activity within the A. vinelandii cell is unchanged even for a high concentration of oxidized natural red (NR_o) alone. Interestingly, these mediators and AA do not have the capacity to inhibit the H₂ uptake activity of the hydrogenase in A. vinelandii. Average active rates of 66 nM H₂ evolved/mg cell protein/min from the nitrogenase and 160 nM H₂-uptake/mg cell protein/min from the hydrogenase in A. vinelandii are found in aid of the activities of the enzymes for H₂ evolution and for H₂ uptake are compared. The activities of both enzymes in A. vinelandii are strongly inhibited by thionine having high oxidative potential. Mechanisms of various mediators acting in vivo for both enzymes in A. vinelandii are discussed.     

Characteristics of the H2 oxidizing system in soybean nodule bacteroids

A derivative of Rhizobium japonicum (strain 122 DES) has been isolated which forms nodules on soybeans that evolve little or no H₂ in air and efficiently fixes N₂. Bacteroids isolated from nodules formed by strain 122 DES took up H₂ with O₂ as the physiological acceptor and appeared to be typical of those R. japonicum strains that possess the H₂ uptake system. The hydrogenase system in soybean nodules is located within the bacteroids and activity in macerated bacteroids is concentrated in a particulate fraction. The pH optimum for the reaction is near 8.0 and apparent K _m values for H₂ and O₂ are 2 M and 1 M, respectively. The H₂ oxidizing activity of a suspension of 122 DES bacteroids was stable at 4°C for at least 4 weeks and was not particularly sensitive to O₂. Neither C₂H₂ nor CO inhibited O₂ dependent H₂ uptake activity.Non-physiological electron acceptors of positive oxidation reduction potential also supported H₂ uptake by bacteroids. The rate of H₂ uptake with phenazine methosulfate as the acceptor was greater than that with O₂. When methylene blue, triphenyltetrazolium, potassium ferricyanide or dichlorophenolindophenol were added to bacteriod suspensions, without preincubation, rates of H₂ uptake were supported that were lower than those in the presence of O₂. Preincubation of the bacteroids with acceptors increased the rates of H₂ uptake. No H₂ evolution was observed from reaction mixtures containing bacteroid suspensions and reduced methyl or benzyl viologens. Of a series of carbon substrates added to bacteroid suspensions only acetate, formate or succinate at concentrations of 50 mM resulted in 20% or greater inhibition of H₂ oxidation.The H₂ uptake capacity of isolated 122 DES bacteroids (expressed on a dry bacteroid basis) was at least 10-fold higher than the rate of the nitrogenase reaction in nodules expressed on a comparable basis. Since about 1 mol of H₂ is evolved for every mol of N₂ reduced during the N₂ fixation reaction, these observations explain why soybean nodules formed by strain 122 DES and other strains with high H₂ uptake activities have a capacity for recycling all the H₂ produced from the nitrogenase reaction.Abbreviations PMS PHenazine methosulfate - MB Methylene blue     

The growth of Saccharomyces cerevisiae CBS 426 on mixtures of glucose and ethanol: a model

Saccharomyces cerevisiae CBS 426 was grown in continuous culture in a defined medium with a mixture of glucose and ethanol as carbon source. Growth on ethanol as the sole carbon source was only possible after the addition of a small amount of glutamic acid. The flows of glucose, ethanol, oxygen, carbon dioxide and biomass to and from the system were measured and a model for the growth of the yeast on the carbon sources constructed. The model is shown to allow independent estimation of Y_ATP and P/O. Y_ATP is not independent of the substrate used, but the amount of ATP used in the production of biomass from the monomers is approximately the same for growth on ethanol and on glucose.Nomenclature C chemical state vector - C_i component of the chemical state vector (C-mol) - C_x biomass present in the system (C-mol biomass) - H₂ reduction equivalents (NAD(P)H + H⁺ and FADH₂) - k the amount of ATP required in the production of 1 C-mol of biomass from the monomers (mol ATP/C-mol biomass) - m_ATP maintenance requirement for ATP (mol ATP/C-mol biomass·h) - P/O (=), efficiency of the oxidative phosphorylation (mol ATP/atom O) - r vector of reaction rates - r_i component of the vector of reaction rates (C-mol/h) - r_ATP rate of ATP production (mol ATP/h) - r_x rate of biomass production (C-mol biomass/h) - Y_ATP Y_ATP growth yield on ATP (C-mol biomass/mol ATP) - (Y_ATP)_max maximum growth yield on ATP - stoichiometry matrix - P/O - vector of the flows to the system - _s flow of glucose to the system (C-mol glucose/h) - _o flow of oxygen to the system (mol O₂/h) - _c flow of carbon dioxide to the system (mol CO₂/h) - _x flow of biomass to the system (C-mol biomass/h) - _e flow of ethanol to the system (C-mol ethanol/h) - _w flow of water produced during metabolism (mol H₂O/h)     

Respiration of the hydrogenosome-containing fungus Neocallimastix patriciarum

Mass spectrometric determinations of O₂ affinities by the rumen fungus Neocallimastix patriciarum indicated a stable respiration under liquid phase O₂ concentrations up to 10 M, the apparent K _m for O₂ under these conditions was 4.0 M. Exposure to O₂ concentrations in excess of 10 M resulted in rapid inactivation of the observed respiration. Calculated H₂ evolution rates for the organism are 8.1 nmol min^-1 per mg of protein. Exposure to liquid-phase O₂ concentrations in excess of 1.4 M caused 50% inhibition of H₂ production. That superoxide and peroxide are amongst the products of respiration was shown by the use of ESR spectroscopy with the spin trapping agent 5,5-dimethyl-l-pyrroline-N-oxide. An active superoxide dismutase was present, but catalase could not be detected.Abbreviations ESR electron spin resonance - DMPO 5,5-dimethyl-l-pyrroline-N-oxide - DETAPAC diethylene-triamine pentaacetic acid     

Uptake and evolution of H2 and reduction of C2H2 by root nodules and nodule homogenates ofAlnus glutinosa

Summary In the growing season no net H₂ evolution is detected when root nodules ofAlnus glutinosa are incubated in air or in argon containing 20% O₂. Due to the hydrogenase activity, N₂-fixing root nodules consume added H₂ at a rate of about 1.4 moles H₂.g fresh nodule^–1.h^–1. The uptake of H₂ is only found in summer. At the end of the season, in autumn, nodules evolve significant quantities of H₂ although the nodules still continue to fix nitrogen. In-vitro studies with fractionated homogenates of summer-harvested nodules show that the recovery of the hydrogenase is high when using methylene-blue or phenazine metasulfate as electron acceptors. No hydrogenase activity is detected in homogenates of autumn-harvested nodules.The hydrogenase is localised in the microsymbiont.     

Growth,acetylene reduction activity and localization of nitrogenase in relation to vesicle formation in Frankia strains Cc1.17 and Cp1.2

A comparative study was conducted on the effect of NH₄Cl on growth, vesicle formation and formation of nitrogenase of Frankia strains Cc1.17 and Cp1.2, derived from root nodules of Colletia cruciata and Comptonia peregrina, respectively. On a medium without combined nitrogen (P-N), both strains formed spherical cells, called vesicles, like many other Frankia strains. Data are presented on the number of vesicles per mg protein, after cultivation in media with sodium propionate as C-source without combined nitrogen (P-N) or with 0.2 g NH₄Cl/l (P+N). Strain Cp1.2 as may other Frankia strains, showed on P+N medium a very strong reduction of vesicle formation of 99% relative to the number of vesicles formed on P-N medium, after 11 days growth. However, in strain Cc11.17 this reduction was only 70%. The occurence of relatively large numbers of vesicles in P+N media has not yet been reported for other Frankia strains. No acetylene reduction activity was found in NH ₄ ⁺ -grown cells. The regulation of induction of nitrogenase in Frankia by NH₄Cl was tested by immuno-gelectrophoresis using antisera against nitrogenase of Rhizobium leguminosarum PRE. The component I of the enzyme showed crossreactivity while the component II had only a weak crossreaction. The experiments indicated that no nitrogenase was detectable in the NH ₄ ⁺ -grown cells. For the localization of nitrogenase, relative amounts of the enzyme were compared in whole cells and vesicle-enriched fractions. Western blots showed a significant enrichment of nitrogenase in the vesicle fractions, which indicated that most of the nitrogenase was localized in the vesicle.     

Intramitochondrial pyruvate attenuates hydrogen peroxide-induced apoptosis in bovine pulmonary artery endothelium

In the hydrogen peroxide (H₂O₂) apoptosis model of the murine thymocyte, redox reactant and antioxidant pyruvate prevents programmed cell death. We tested the hypothesis that such protection was mediated, at least in part, via pyruvate handling by mitochondrial metabolism. Cultured bovine pulmonary artery endothelial cells were incubated for 30 min with 0.5 mM H₂O₂ in the absence and presence of 0.5 mM -cyano-3-hydroxycinnamate, as a selective inhibitor of the mitochondrial pyruvate transporter. In controls H₂O₂ decreased cell viability by 30% within 24 h; this was associated with apoptosis-like bodies, nuclear condensation, and biochemical DNA damage consistent with programmed cell death. Pyruvate (0.1–20 mM) enhanced cell viability in a dose-dependent manner, with 85% viable cells at 3 mM and no DNA laddering, no positive nick-end labeling (TUNEL), and no detectable Annexin V or propidium iodide staining. In contrast, using 5 mM L-lactate as a cytosolic reductant or acetate as a redox-neutral substrate, cell death increased to 40%, which was associated with intense DNA laddering, positive TUNEL and Hoechst 33258 assays. -Cyano-3-hydroxycinnamate alone did not significantly decrease endothelial viability but reduced viability from 85 ± 3 to 71 ± 4% (p = 0.023) in presence of 3 mM pyruvate plus H₂O₂; pathological cell morphology and DNA laddering under the same conditions suggested loss of pyruvate protection against apoptosis. Since -cyano-3-hydroxycinnamate re-distributed medium pyruvate and L-lactate consistent with selective blockade of pyruvate uptake into the mitochondria, the findings support the hypothesis that pyruvate protection against H₂O₂ apoptosis is mediated in part via the mitochondrial matrix compartment. Possible mediators include anti-apoptotic bcl-2 and/or products of mitochondrial pyruvate metabolism such as citrate that affect metabolic regulation and anti-oxidant status in the cytoplasm.     

Physiology of nitrogen fixation in Azospirillum lipoferum Br 17 (ATCC 29 709)

Changes of cellular activities during batch cultures with Azospirillum lipoferum strain Br 17 (ATCC 29 709) were observed within the growth cycle, at optimal pO₂ (0.002–0.003 atm). The relative growth rate for cells growing with N₂ as sole nitrogen source during log phase was =0.13 h^-1 and the doubling time was 5.3 h. Nitrogenase activity was not accompanied by hydrogen evolution at any growth stage, and a very active uptake hydrogenase was demonstrated. The hydrogenase activity increased towards the end of the growth period when glucose became limiting and N₂ fixation reached its maximal specific activity. Oxygen consumption and oxygen tolerance at the various growth stages, increased simultaneously with the uptake hydrogenase activity indicating a possible role of this enzyme in an oxygen protection mechanism of A. lipoferum nitrogenase. The efficiency of nitrogen fixation expressed as mg total nitrogen fixed in cells and supernatant per g glucose consumed, was 20 at the early log phase and increased to 48 at the late log phase. About 25% of the total fixed nitrogen was recovered in the culture supernatant.Abbreviations DOT Dissolved oxygen tension - PHB Poly--hydroxybutyric acid - O.D. Optical density (560 nm) - A.T.C.C. American type culture collection - NTA Nitrilotriacetic acid Graduate student of the Universidade Federal Rural do Rio de Janeiro, Brazil     

Carbon cost of nitrogenase activity in Frankia–Alnus incana root nodules

The carbon cost of nitrogenase activity was investigated to determine symbiotic efficiency of the actinorhizal root nodule symbiosis between the woody perennial Alnus incana and the soil bacterium Frankia. Respiration (CO₂ production) and nitrogenase activity (H₂ production) by intact nodulated root systems were continuously recorded in short-term assays in an open-flow gas exchange system. The assays were conducted in N₂:O₂, thus under N₂-fixing conditions, in all experiments except for one. This avoided the declines in nitrogenase activity and respiration due to N₂ deprivation that occur in acetylene reduction assays and during extended Ar:O₂ exposures in H₂ assays. Two approaches were used: (i) direct estimation of root and nodule respiration by removing nodules, and (ii) decreasing the partial pressure of O₂ from 21 to 15% to use the strong relationship between respiration and nitrogenase activity to calculate CO₂/H₂. The electron allocation of nitrogenase was determined to be 0.6 and used to convert the results into moles of CO₂ produced per 2e^– transferred by nitrogenase to reduction of N₂. The results ranged from 2.6 to 3.4mol CO₂ produced per 2e^–. Carbon cost expressed as gC produced per gN reduced ranged from 4.5 to 5.8. The result for this actinorhizal tree symbiosis is in the low range of estimates for N₂-fixing actinorhizal symbioses and crop legumes. Methodology and comparisons of root nodule physiology among actinorhizal and legume plants are discussed.