Studies on the mechanism of NADPH oxidation by the granule fraction isolated from human resting polymorphonuclear blood cells.

Various factor affecting NADPH-oxidation by resting human leucocyte granules (LG) at acid pH, have been investigated. It was found that: 1) oxidation of NADPH by LG was increasingly inhibited by increased cyanide concentrations in the medium and was abolished by 4 mM cyanide. 2) with or without cyanide in the incubation medium, LG omitted, Mn++ in the presence of NADPH induced superoxide anion (O- WITH 2) production, as evidenced by oxygen consumption and H2O2 production, which were abolished (in the absence of cyanide) by cytochrome C (a potent O- with 2 scavenger). 3) Both NADPH oxidation in the presence of 2 mM cyanide (cyanide-resistant) and in its absence (cyanide-sensitive) by LG occurred only in the presence of Mn++, and both were inhibited by superoxide dismutase. 4) Cyanide-resistant NADPH oxidation by LG generated H2O2, was inhibited by H2O2 and was not modified by "active" catalase. The ratio of cyanide-resistant NADPH oxidation/O2 uptake was 1 up to 1.25 mM NADPH, and increased above this concentration. 5) Cyanide-sensitive NADPH oxidation was inhibited by catalase and increased upon addition of H2O2. The ratio of cyanide-sensitive NADPH oxidation/O2 uptake was 2. It was concluded that after initiation by O - with 2, produced independently of LG, two sequential types of LG dependent NADPH oxidations occur. First, an O - with 2-dependent protein mediated NADPH oxidation (cyanide-resistant) which generates H2O2 and O - with 2 occurs. Second, NADPH peroxidation (cyanide-sensitive) which utilizes H2O2 takes place.     

NADPH Oxidase System as a Superoxide-generating Cyanide-Resistant Pathway in the Respiratory Chain of Corynebacterium glutamicum

The respiratory chain of Corynebacterium glutamicum was investigated, especially with respect to a cyanide-resistant respiratory chain bypass oxidase. The membranes of C. glutamicum had NADH, succinate, lactate, and NADPH oxidase activities, and menaquinone, and cytochromes a ₅₉₈, b _562(558), and c ₅₅₀ as respiratory components. The NADH, succinate, lactate, and NADPH oxidase systems, all of which were more cyanide-resistant than N,N,N′,N′-tetramethyl-p-phenylene diamine oxidase activity (cytochrome aa ₃ terminal oxidase), had different sensitivities to cyanide; the cyanide sensitivity of these oxidase systems increased in the order, NADPH, lactate, NADH, and succinate. Taken together with the analysis of redox kinetics in the cytochromes and the effects of respiratory inhibitors, the results suggested that there is a cyanide-resistant bypass oxidase branching at the menaquinone site, besides cyanide-sensitive cytochrome oxidase in the respiratory chain. H⁺/O measurements with resting cells suggested that the cyanide-sensitive respiratory chain has two or three coupling sites, of which one is in NADH dehydrogenase and the others between menaquinone and cytochrome oxidase, but the cyanide-resistant bypass oxidase may not have any proton coupling site. NADPH and lactate oxidase systems were more resistant to UV irradiation than other systems and the UV insensitivity was highest in the NADPH oxidase system, suggesting that a specific quinone resistant to UV or no such a quinone works in at least NADPH oxidase system while the UV-sensitive menaquinone pool does in other oxidase systems. Furthermore, superoxide was generated in well-washed membranes, most strongly in the NADPH oxidase system. Thus, it was suggested that the cyanide-resistant bypass oxidase system of C. glutamicum is related to the NADPH oxidase system, which may be involved in generation of superoxide anions and probably functions together with superoxide dismutase and catalase.     

Studies on the NADPH oxidation by subcellular particles from phagocytosing polymorphonuclear leucocytes. Evidence for the involvement of three mechanisms

1. The NADPH-oxidizing activity of a 100 000 × g particulate fraction of the postnuclear supernatant obtained from guinea-pig phagocytosing polymorphonuclear leucocytes has been assayed by simultaneous determination of oxygen consumption, NADPH oxidation and O^?₂ generation at pH 5.5 and 7.0 and with 0.15 mM and 1 mM NADPH.2. The measurements of oxygen consumption and NADPH oxidation gave comparable results. The stoichiometry between the oxygen consumed and the NADPH oxidized was 1 : 1.3. A markedly lower enzymatic activity was observed, under all the experimental conditions used, when the O^?₂ generation assay was employed as compared to the assays of oxygen uptake and NADPH oxidation.4. The explanation of this difference came from the analysis of the effect of superoxide dismutase and of cytochrome c which removes O^?₂ formed during the oxidation of NADPH.5. Both superoxide dismutase and cytochrome c inhibited the NADPH-oxidizing reaction at pH 5.5. The inhibition was higher with 1 mM NADPH than with 0.15 mM NADPH.6. Both superoxide dismutase and cytochrome c inhibited the NADPH-oxidizing reaction at pH 7.0 with 1 mM NADPH but less than at pH 5.5 with 1 mM NADPH.7. The effect of superoxide dismutase at pH 7.0 with 0.15 mM NADPH was negligible.8. In all instances the inhibitory effect of cytochrome c was greater than that of superoxide dismutase.9. It was concluded that the NADPH-oxidizing reaction studied here is made up of three components: an enzymatic univalent reduction of O₂; an enzymatic, apparently non-univalent, O₂ reduction and a non-enzymatic chain reaction.10. These three components are variably and independently affected by the experimental conditions used. For example, the chain reaction is freely operative at pH 5.5 with 1 mM NADPH but is almost absent at pH 7.0 with 0.15 mM NADPH, whereas the univalent reduction of O₂ is optimal at pH 7.0 with 1 mM NADPH.     

Respiratory Activity and Naphthoquinone Synthesis in the Fungus Fusarium decemcellulare Exposed to Oxidative Stress

The effect of oxidants (hydrogen peroxide and juglone) on the growth, respiration, and naphthoquinone synthesis in the fungus Fusarium decemcellulare was studied. The addition of the oxidants to the exponential-phase fungus inhibited cell respiration (either partially or completely, depending on the oxidant concentration), culture growth, and naphthoquinone synthesis. The treatment of fungal cells with nonlethal concentrations of H₂O₂ (below 0.25 mM) and juglone (below 0.1 mM) induced the resistance of cell respiration to cyanide. The residual respiration in the presence of cyanide could be inhibited by benzohydroxamic acid, indicating the occurrence of alternative oxidase. Increased concentrations of oxidants (0.25 mM juglone and 0.5 mM H₂O₂) rapidly and irreversibly inhibited cell respiration. These observations suggest that the mitochondrial respiratory chain of fungal cells exposed to oxidative stress is subject to the action of active oxygen species. The treatment of fungal cells with nonlethal concentrations of H₂O₂ and juglone activated cellular glutathione reductase and glucose-6-phosphate dehydrogenase, which are protective enzymes against oxidative stress.     

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.     

Peroxidase mediated hydrogen peroxide production in barley roots grown under stress conditions

All applied metals (Co, Al, Cu, Cd) and NaCl inhibited barley root growth. No root growth inhibition was caused by drought exposure, in contrast to cold treatment. 0.01 mM H₂O₂ stimulated root growth and GA application did not affect root growth at all. Other activators and inhibitors of H₂O₂ production (SHAM, DTT, 10 mM H₂O₂, 2,4-D) inhibited root growth. Loss of cell viability was most significant after Al treatment, followed by Cd and Cu, but no cell death was induced by Co. Drought led to slight increase in Evans blue uptake, whereas neither NaCl nor cold influenced this parameter. DTT treatment caused slight increase in Evans blue uptake and significant increases were detected after 2,4-D and 10 mM H₂O₂ treatment, but were not induced by others stressors. Metal exposure increased guaiacol-POD activity, which was correlated with oxidation of NADH and production of H₂O₂. Exposure to drought caused a minor change in NADH oxidation, but neither H₂O₂ production nor guaiacol-POD activity was increased. Cold and NaCl application decreased all monitored activities. Increase in NADH oxidation and guaiacol-POD activity was caused by 10 mM H₂O₂ and 0.01 mM 2,4-D treatment, which also caused enhancement of H₂O₂ production. Slight inhibition of all activities was caused by 0.01 mM H₂O₂, GA, DTT; more pronounced inhibition was detected after SHAM treatment. The role of H₂O₂ production mediated by POD activity in relation to root growth and cell viability under exposure to some abiotic stress factors is discussed.     

Salicylic Acid induces cyanide-resistant respiration in tobacco cell-suspension cultures

Cyanide-resistant, alternative respiration in Nicotiana tabacum L. cv Xanthi-nc was analyzed in liquid suspension cultures using O₂ uptake and calorimetric measurements. In young cultures (4-8 d after transfer), cyanide inhibited O₂ uptake by up to 40% as compared to controls. Application of 20 μm salicylic acid (SA) to young cells increased cyanide-resistant O₂ uptake within 2 h. Development of KCN resistance did not affect total O₂ uptake, but was accompanied by a 60% increase in the rate of heat evolution from cells as measured by calorimetry. This stimulation of heat evolution by SA was not significantly affected by 1 mm cyanide, but was reduced by 10 mm salicylhydroxamic acid (SHAM), an inhibitor of cyanide-resistant respiration. Treatment of SA-induced or uninduced cells with a combination of cyanide and SHAM blocked most of the O₂ consumption and heat evolution. Fifty percent of the applied SA was taken up within 10 min, with most of the intracellular SA metabolized in 2 h. 2,6-Dihydroxybenzoic and 4-hydroxybenzoic acids also induced cyanide-resistant respiration. These data indicate that in tobacco cell-suspension culture, SA induces the activity and the capacity of cyanide-resistant respiration without affecting the capacity of the cytochrome c respiration pathway.     

An extracellular NADH-oxidizing peroxidase produced by a lignin-degrading basidiomycete,Phanerochaete chrysosporium

A lignin-degrading basidiomycete, Phanerochaete chrysosporium, produces an extracellular peroxidase which in turn produces H₂O₂ by catalyzing the oxidation of NADH and NADPH. The high enzyme activity was observed in the culture grown under nutrient nitrogen limitation (low-N) and high oxygen tension (high-O₂). The enzyme activity was absent in non-ligninolytic agitated culture and in the cultures of non-ligninolytic mutant strains of this organism. The culture method using polyurethane foam cubes as a support for the growing mycelia showed the beneficial effect of producing a large amount of the enzyme. The enzyme is capable of catalyzing the oxidation of NADH and NADPH in the absence of added H₂O₂, and its activity was inhibited strongly by catalase and superoxide dismutase. It is suggested that this peroxidase participates in the ligninolytic system of Phanerochaete chrysosporium as a donor of H₂O₂, which is required for the lignin-peroxidase reaction, by oxidizing extracellular NADH and NADPH.     

Roles of superoxide and myeloperoxidase in ascorbate oxidation in stimulated neutrophils and H2O2-treated HL60 cells

Ascorbate is present at high concentrations in neutrophils and becomes oxidized when the cells are stimulated. We have investigated the mechanism of oxidation by studying cultured HL60 cells and isolated neutrophils. Addition of H₂O₂ to ascorbate-loaded HL60 cells resulted in substantial oxidation of intracellular ascorbate. Oxidation was myeloperoxidase-dependent, but not attributable to hypochlorous acid, and can be explained by myeloperoxidase (MPO) exhibiting direct ascorbate peroxidase activity. When neutrophils were stimulated with phorbol myristate acetate, about 40% of their intracellular ascorbate was oxidized over 20 min. Ascorbate loss required NADPH oxidase activity but in contrast to the HL60 cells did not involve myeloperoxidase. It did not occur when exogenous H₂O₂ was added, was not inhibited by myeloperoxidase inhibitors, and was the same for normal and myeloperoxidase-deficient cells. Neutrophil ascorbate loss was enhanced when endogenous superoxide dismutase was inhibited by cyanide or diethyldithiocarbamate and appears to be due to oxidation by superoxide. We propose that in HL60 cells, MPO-dependent ascorbate oxidation occurs because cellular ascorbate can access newly synthesized MPO before it becomes packaged in granules: a mechanism not possible in neutrophils. In neutrophils, we estimate that ascorbate is capable of competing with superoxide dismutase for a small fraction of the superoxide they generate and propose that the superoxide responsible is likely to come from previously identified sites of intracellular NADPH oxidase activity. We speculate that ascorbate might protect the neutrophil against intracellular effects of superoxide generated at these sites.     

Reduced nicotinamide adenine dinucleotide phosphate (NADPH)-dependent formation and breakdown of hydrogen peroxide during mixed function oxidation reactions in liver microsomes.

Conditions for the recovery of H₂O₂ from microsomes and for determination of the rate and extent of H₂O₂ formation during oxidation of NADPH by liver microsomes have been investigated. H₂O₂ was determined by two methods that are applicable to conditions existing during microsomal mixed function oxidation reactions, provided that contaminating catalase activity is inhibited by azide and that interference by other mixed function oxidation reactions can be excluded. To estimate the formation of H₂O₂ in absence of azide, H₂O₂ was determined indirectly by the production of HCHO during oxidation of cold and ¹⁴C-labeled methanol and an excess of exogenous catalase. As additional catalase-independent decomposition of H₂O₂ also occurs during oxidation of NADPH, the kinetics of H₂O₂ formation in microsomes is influenced by two independent processes. H₂O₂ will be produced under optimal conditions i.e., at V when O₂ and NADPH are in excess. Addition or formation of increasing amounts of H₂O₂ raises the substrate (H₂O₂) concentration and will enhance the rate of breakdown of H₂O₂.     

Reduced nicotinamide adenine dinucleotide phosphate oxidase in adipocyte plasma membrane and its activation by insulin. Possible role in the hormone's effects on adenylate cyclase and the hexose monophosphate shunt.

An oxidase activity utilizing reduced nicotinamide adenine dinucleotide phosphate (NADPH) and producing H₂O₂ was observed in intact adipocytes of rat, as well as in the isolated plasma membranes of these cells. A stoichiometry of 1 mol of H₂O₂ production per mole of NADPH disappearance was found with isolated plasma membranes. Activation of this enzyme (R) was produced by pretreatment of cells with insulin, dithiothreitol, or sulfhydryl inhibitors, e.g., p-chloromercuribenzoate or tosyl-l-lysine chloromethyl ketone. All of these agents also stimulated glucose oxidation via the hexose monophosphate shunt. Activation of R was also observed with biologically active derivatives of insulin, e.g., proinsulin or desalanine insulin, but not with an inactive derivative, desoctapeptide insulin. The enzyme could not be activated by exposing the cells to membrane perturbants, e.g., hypotonic conditions or Triton X-100 (0.01–0.1%). The enzyme activity in the plasma membrane had a pH optimum at 6.0 and, from the Lineweaver-Burke plot, V was determined at 230 nmol and K_m for NADPH was at 5.8 × 10^?5, m. The activity remained unaltered in the presence of sodium azide or cyanide. Preincubation of adipocytes with insulin or SH reagents or direct addition of oxidants, e.g., H₂O₂, potassium ferricyanide, or phenazine methosulfate, to the membranes also caused inhibition of adenylate cyclase (AC). This enzyme activity could be restored in these preparations by adding thiols. It is suggested that inhibition of AC in whole cells in response to insulin may be caused by oxidation of its SH groups by the H₂O₂ generated from the activated NADPH oxidase. Reversal of this inhibition may involve cellular reducing equivalents. The evidence suggests that the plasma membrane enzymes, i.e., NADPH oxidase and adenylate cyclase, are controlled, in part, by the intracellular redox potential.     

Electron transport reactions in respiratory particles of hydrogenase-induced Anacystis nidulans

Respiratory particles from hydrogen-grown Anacystis nidulans were found to oxidize H₂, NADPH, NADH, succinate and ascorbate plus N,N,N,N-tetramethyl-p-phenylenediamine at rates corresponding to 28, 15, 6, 2.5, and 70 nmol O₂ taken up x mg protein^–1xmin^–1, respectively. The particles were isolated by brief sonication of lysozyme-pretreated cells. Respiratory activities were studied in terms of both substrate oxidation and O₂ uptake. The stoichiometry between oxidation of H₂, NADPH, NADH or succinate, and consumption of O₂ was calculated to be 1.95+-0.1 with each substrate.Inhibitors of flavoproteins did not affect the oxyhydrogen reaction while 2-n-heptyl-8-hydroxyquinoline-N-oxide as well as compounds known to block the terminal oxidase impaired the oxidation of both H₂ and of NAD(P)H or succinate in a parallel fashion. No additivity of O₂ uptake was observed when NADPH, NADH or succinate was present in addition to H₂. Instead, H₂ uptake was depressed under such conditions, and also the oxidation of NAD(P)H or succinate was increasingly lowered by increasing H₂ tensions.The results suggest that in Anacystis molecular hydrogen is oxidized through the same type of respiratory chain as are NAD(P)H and succinate. Moreover, the cyanide-resistant branch of respiratory O₂ uptake will be discussed, and a few results obtained with particles prepared from thylakoid-free Anacystis will also be presented.Abbreviations BAL 2,3-dimercaptopropanol-(1) - DCPIP 2,6-dichlorophenolindophenol - HOQNO 2-n-heptyl-8-hydroxyquinoline-N-oxide - TMPD N,N,N,N-tetramethyl-p-phenylenediamine - tricine N-tris-(hydroxymethyl)-methylglycine - Tris tris-(hydroxymethyl)-aminomethane - TTFA thenoyltrifluoroacetone NAD(P)H indicates NADPH and/or NADH     

Oxidation of ethanol by hepatic microsomes of acatalasemic mice

Hepatic microsomes of acatalasemic Cs^b mice subjected to heat inactivation displayed decreased catalatic activity but NADPH dependent microsomal ethanol oxidation (MEOS) remained active and unaffected. Even without heat inactivation, in the Cs^b strain, the NADPH dependent metabolism of ethanol was much more active than the H₂O₂ mediated one whereas microsomes of Cs^a control mice displayed equal rates of H₂O₂ and NADPH dependent ethanol oxidation. Addition of catalase to liver microsomes in vitro abolished this difference whereas the catalase inhibitor azide established in the Cs^a mice a pattern similar to that of the Cs^b, namely a much more active NADPH dependent than a H₂O₂ mediated ethanol oxidation. The selective persistence in the Cs^b mice of NADPH dependent ethanol oxidation contrasting with the reduction in the H₂O₂ mediated metabolism of ethanol supports the existence of a microsomal ethanol oxidizing system independent of catalase.     

The respiratory system of the marine bacterium Beneckea natriegens. II. Terminal branching of respiration to oxygen and resistance to inhibition by cyanide

1. Cell-free extracts of the marine bacterium Beneckea natriegens, derived by sonication, were separated into particulate and supernatant fractions by centrifugation at 150 000 × g.2. NADH, succinate, d(?)- and l(+)-lactate oxidase and dehydrogenase activities were located in the particles, with 2- to 3-fold increases in specific activity over the cell free extract. The d(?)- and l(+)-lactate dehydrogenases were NAD⁺ and NADP⁺ independent. Ascorbate-N,N,N′,N′-tetramethylphenylenediamine (TMPD) oxidase was also present in the particulate fraction; it was 7–12 times more active than the physiological substrate oxidases.3. Ascorbate-TMPD oxidase was completely inhibited by 10 μM cyanide. Succinate, NADH, d(?)-lactate and l(+)-lactate oxidases were inhibited in a biphasic manner, with 10 μM cyanide causing only 10–50 % inhibition; further inhibition required more than 0.5 mM cyanide, and 10 mM cyanide caused over 90 % inhibition. Low sulphide (5 μM) and azide (2 mM) concentrations also totally inhibited ascorbate-TMPD oxidase, but only partially inhibited the other oxidases. High concentrations of sulphide but not azide caused a second phase inhibition of NADH, succinate, d(?)-lactate and l(+)-lactate oxidases.4. Low oxidase activities of the physiological substrates, obtained by using non-saturating substrate concentrations, were more inhibited by 10 μM cyanide and 2 mM azide than high oxidase rates, yet ascorbate-TMPD oxidase was completely inhibited by 10 μM cyanide over a wide range of rates of oxidation.5. These results indicate terminal branching of the respiratory system. Ascorbate-TMPD is oxidised by one pathway only, whilst NADH, succinate, d(?)-lactate and l(+)-lactate are oxidised via both pathways. Respiration of the latter substrates occurs preferentially by the pathway associated with ascorbate-TMPD oxidase and which is sensitive to low concentrations of cyanide, azide and sulphide.6. The apparent K_m for O₂ for each of the two pathways was detected using ascorbate-TMPD and NADH or succinate plus 10 μM cyanide respectively. The former pathway had an apparent K_m of 8–17 (average 10.6) μM and the latter 2.2–4.0 (average 3.0) μM O₂.     

Appearance of an Alternate Pathway Cyanide-resistant during Germination of Seeds of Cicer arietinum

The combined action of the inhibitors antimycin A and cyanide with benzohydroxamic acid indicates the presence of a cyanide-resistant pathway of respiration in chick pea (Cicer arietinum L.) seeds. The appearance of this pathway takes place during germination. During the first 12 hours of germination, the respiration is predominantly cyanide-sensitive, showing after this time a shift to an “alternate” respiration which is sensitive to benzohydroxamic acid, reaching the maximal cyanide resistance between 72 and 96 hours of germination. The appearance of the alternate pathway is initiated by high O₂ concentrations and depends on cytoplasmic protein synthesis, since its appearance is inhibited by cycloheximide but not by chloramphenicol. Actinomycin D has no effect on the appearance of the alternate pathway. Our results indicate, in agreement with other authors, that the branching point is located between the flavoproteins and cytochromes b, probably at the level of ubiquinone, but the possibility of more than one branching point of the electron flow is also considered.     

Mechanisms of H2O2 formation by leukocytes. Properties of the NAD(P)H oxidase activity of intact leukocytes.

It is postulated that the burst of oxygen consumption and H₂O₂ formation following phagocytosis by polymorphonuclear leukocytes is due to the action of an oxidase located in the plasma membrane. The cyanide-resistant oxygen consumption of resting polymorphonuclear leukocytes was also found to be stimulated by 2,4-dichlorophenol with H₂O₂ being the sole product formed. NADH and NADPH added to the leukocytes greatly enhanced the oxygen consumption and were oxidized in the process without penetrating the leukocytes. Mn²⁺ stimulated this oxidase activity. The apparent K_m values for added NADH and NADPH were 50 and 40 μm, respectively, with a V of 300 nmol/mg protein/min. A stoichiometry of 1 mol H₂O₂ formed per mol of NAD(P)H was found. Whilst the oxidase is similar to the oxidase properties of a peroxidase, myeloperoxidase is not responsible for the activity.     

Investigation of the H(2) Oxidation System in Rhizobium japonicum 122 DES Nodule Bacteroids

The H₂-oxidizing complex in Rhizobium japonicum 122 DES bacteroids failed to catalyze, at a measurable rate, ²H¹H exchange from a mixture of ²H₂ and ¹H₂ in presence of ²H₂O and ¹H₂O, providing no evidence for reversibility of the hydrogenase reaction in vivo. In the H₂ oxidation reaction, there was no significant discrimination between ²H₂ and ¹H₂, indicating that the initial H₂-activation step in the over-all H₂ oxidation reaction is not rate-limiting. By use of improved methods, an apparent K_m for H₂ of 0.05 micromolar was determined. The H₂ oxidation reaction in bacteroids was strongly inhibited by cyanide (88% at 0.05 millimolar), theonyltrifluoroacetone, and other metal-complexing agents. Carbonyl cyanide m-chlorophenylhydrazone at 0.005 millimolar and 2,4-dinitrophenol at 0.5 millimolar inhibited H₂ oxidation and stimulated O₂ uptake. This and other evidence suggest the involvement of cytochromes and nonheme iron proteins in the pathway of electron transport from H₂ to O₂. Partial pressures of H₂ at 0.03 atmosphere and below had a pronounced inhibitory effect on endogenous respiration by bacteroid suspensions. The inhibition of CO₂ evolution by low partial pressures of H₂ suggests that H₂ utilization may result in conservation of oxidizable substrates and benefits the symbiosis under physiological conditions. Succinate, acetate, and formate at concentrations of 50 millimolar inhibited rates of H₂ uptake by 8, 29, and 25%, respectively. The inhibition by succinate was noncompetitive and that by acetate and formate was uncompetitive. A concentration of 11.6 millimolar CO₂ (initial concentration) in solution inhibited H₂ uptake by bacteroid suspensions by 18%. Further research is necessary to establish the significance of the inhibition of H₂ uptake by succinate, acetate, formate, and CO₂ in the metabolism of the H₂-uptake-positive strains of Rhizobium.     

Light and dark reactions of the uptake hydrogenase in anabaena 7120

Reactions of the uptake hydrogenase from Anabaena 7120 (A.T.C.C. 27893, Nostoc muscorum) were examined in whole filaments, isolated heterocysts, and membrane particles. Whole filaments or isolated heterocysts that contained nitrogenase consumed H₂ in the presence of C₂H₂ or N₂ in a light-dependent reaction. If nitrogenase was inactivated by O₂ shock, filaments catalyzed H₂ uptake to an unidentified endogenous acceptor in the light. Addition of NO₃⁻ or NO₂⁻ enhanced these rates. Isolated heterocysts consumed H₂ in the dark in the presence of electron acceptors with positive midpoint potentials, and these reactions were not enhanced by light. With acceptors of negative midpoint potential, significant light enhancement of H₂ uptake occurred. Maximum rates of light-dependent uptake were approximately 25% of the maximum dark rates observed. Membrane particles prepared from isolated heterocysts showed similar specificity for electron acceptors. These particles catalyzed a cyanide-sensitive oxyhydrogen reaction that was inactivated by O₂ at O₂ concentrations above 2%. Light-dependent H₂ uptake to low potential acceptors by these particles was inhibited by dibromothymoquinone but was insensitive to cyanide. In the presence of O₂, light-dependent H₂ uptake occurred simultaneously with the oxyhydrogen reaction. The pH optima for both types of H₂ uptake were near 7.0. These results further clarify the role of uptake hydrogenase in donating electrons to both the photosynthetic and respiratory electron transport chains of Anabaena.     

Chitosan-induced programmed cell death in plants

Chitosan, CN⁻, or H₂O₂ caused the death of epidermal cells (EC) in the epidermis of pea leaves that was detected by monitoring the destruction of cell nuclei; chitosan induced chromatin condensation and marginalization followed by the destruction of EC nuclei and subsequent internucleosomal DNA fragmentation. Chitosan did not affect stoma guard cells (GC). Anaerobic conditions prevented the chitosan-induced destruction of EC nuclei. The antioxidants nitroblue tetrazolium or mannitol suppressed the effects of chitosan, H₂O₂, or chitosan + H₂O₂ on EC. H₂O₂ formation in EC and GC mitochondria that was determined from 2′,7′-dichlorofluorescein fluorescence was inhibited by CN⁻ and the protonophoric uncoupler carbonyl cyanide m-chlorophenylhydrazone but was stimulated by these agents in GC chloroplasts. The alternative oxidase inhibitors propyl gallate and salicylhydroxamate prevented chitosan- but not CN⁻-induced destruction of EC nuclei; the plasma membrane NADPH oxidase inhibitors diphenylene iodonium and quinacrine abolished chitosan- but not CN⁻-induced destruction of EC nuclei. The mitochondrial protein synthesis inhibitor lincomycin removed the destructive effect of chitosan or H₂O₂ on EC nuclei. The effect of cycloheximide, an inhibitor of protein synthesis in the cytoplasm, was insignificant; however, it was enhanced if cycloheximide was added in combination with lincomycin. The autophagy inhibitor 3-methyladenine removed the chitosan effect but exerted no influence on the effect of H₂O₂ as an inducer of EC death. The internucleosome DNA fragmentation in conjunction with the data on the 3-methyladenine effect provides evidence that chitosan induces programmed cell death that follows a combined scenario including apoptosis and autophagy. Based on the results of an inhibitor assay, chitosan-induced EC death involves reactive oxygen species generated by the NADPH oxidase of the plasma membrane.