Hydrogen peroxide mediated killing of bacteria

Summary Polymorphonuclear leukocytes (PMN) or neutrophils have multiple systems available for killing ingested bacteria. Nearly each of these incorporates H₂O₂ indicating the essential nature of this reactive oxygen intermediate for microbicidal activity. Following ingestion of bacteria by PMN, H₂O₂ is formed by the respiratory burst which consumes O₂ and generates H₂O₂ from O_2–. H₂O₂ is deposited intracellularly near bacteria within phagocytic vacuoles where it can react with the MPO-H₂O₂-halide system to form toxic hyperchlorous acid (HOCl) and/or possibly singlet oxygen (¹O₂). H₂O₂ can also react with O_2– and/or iron (Fe⁺⁺) from lactoferrin or bacteria to form the highly toxic hydroxyl radical (¹OH). These mechanisms appear important since deficiencies of H₂O₂ production, myeloperoxidase or lactoferrin frequently increases their owner's susceptibility to infection. In particular, examination of PMN from infection prone patients with chronic granulomatous disease (CGD) most clearly demonstrates the importance of H₂O₂ in killing of bacteria. CGD PMN lack the capacity to effectively generate H₂O₂ and subsequently have impaired ability to kill catalase positive (H₂O₂ producing) but not catalase negative (not H₂O₂ producing) bacteria. PMN also have catalase and glutathione peroxidase systems in their cytoplasms to protect themselves from the toxicity of H₂O₂. Finally, while H₂O₂ is critical for host defense, it can also be released extracellularly and thereby play a significant role in PMN mediated tissue injury.     

Kinetic Characterization of Extracellular Catalases fromPenicillium piceum F-648 and Its Hydrogen Peroxide-Adapted Variants

A comparative kinetic study of extracellular catalases produced by Penicillium piceum F-648 and their variants adapted to H₂O₂ was performed in culture liquid filtrates. The specific activity of catalase, the maximum rate of catalase-induced H₂O₂ degradation (V _max), V _max/K _M ratio, and the catalase inactivation rate constant in the enzymatic reaction (k _in, s^–1) were estimated in phosphate buffer (pH 7.4) at 30°C. The effective constant representing the rate of catalase thermal inactivation (k _in ^*, s^–1) was determined at 45°C. In all samples, the specific activity and K _M for catalase were maximum at a protein concentration in culture liquid filtrates of (2.5–3.5) × 10^–4 mg/ml. The effective constants describing the rate of H₂O₂ degradation (k, s^–1) were similar to that observed in the initial culture. These values reflected a twofold decrease in catalase activity in culture liquid filtrates. We hypothesized that culture liquid filtrates contain two isoforms of extracellular catalase characterized by different activities and affinities for H₂O₂. Catalases from variants 5 and 3 with high and low affinities for H₂O₂, respectively, had a greater operational stability than the enzyme from the initial culture. The method of adaptive selection for H₂O₂ can be used to obtain fungal variants producing extracellular catalases with improved properties.     

Encapsulation of catalase into nanochannels of an inorganic composite membrane

Enzymes, especially those known as membrane proteins existing in plasma membranes, direct important and complicated reactions in living bodies. Thus, attempts have been made to extract such enzymes from living bodies, and immobilize and accumulate them on supports to effectively use their functions for catalysis [M. Hartmann, Chem. Mater. 17 (2005) 4577–4593]. However, enzymes extracted from living bodies tend to aggregate in the absence of detergents or at high concentrations, resulting in a loss of their activities [Y. Urabe, T. Shiomi, T. Itoh, A. Kawai, T. Tsunoda, F. Mizukami, K. Sakaguchi, ChemBioChem 8 (2007) 668–674]. We have, however, succeeded in assembling a highly durable membrane capable of high-density accumulation and providing a regular array of catalase by encapsulating it in mesoporous silica synthesized in the pores of an alumina membrane. The artificial biomembrane showed not only activity similar to that of the native catalase for the decomposition of H₂O₂ but also much higher stability; the catalase immobilized in the membrane still retained its original activity even after being employed 160 times in decomposing H₂O₂, whereas the native lost its activity after 40 cycles.     

Parallel Changes in H2O2 and Catalase during Thermotolerance Induced by Salicylic Acid or Heat Acclimation in Mustard Seedlings

Spraying mustard (Sinapis alba L.) seedlings with salicylic acid (SA) solutions between 10 and 500 μm significantly improved their tolerance to a subsequent heat shock at 55°C for 1.5 h. The effects of SA were concentration dependent, with higher concentrations failing to induce thermotolerance. The time course of thermotolerance induced by 100 μm SA was similar to that obtained with seedlings acclimated at 45°C for 1 h. We examined the hypothesis that induced thermotolerance involved H₂O₂. Heat shock at 55°C caused a significant increase in endogenous H₂O₂ and reduced catalase activity. A peak in H₂O₂ content was observed within 5 min of either SA treatment or transfer to the 45°C acclimation temperature. Between 2 and 3 h after SA treatment or heat acclimation, both H₂O₂ and catalase activity significantly decreased below control levels. The lowered H₂O₂ content and catalase activity occurred in the period of maximum thermoprotection. It is suggested that thermoprotection obtained either by spraying SA or by heat acclimation may be achieved by a common signal transduction pathway involving an early increase in H₂O₂.     

Multiple reactions in vanadyl-V(IV) oxidation by H2O2

Oxidation of vanadyl sulfate by H₂O₂ involves multiple reactions at neutral pH conditions. The primary reaction was found to be oxidation of V(IV) to V(V) using 0.5 equivalent of H₂O₂, based on the loss of blue color and the visible spectrum. The loss of V(IV) and formation V(V) compounds were confirmed by ESR and⁵¹V-NMR spectra, respectively. In the presence of excess H₂O₂ (more than two equivalents), the V(V) was converted into diperoxovanadate, the major end-product of these reactions, identified by changes in absorbance in ultraviolet region and by the specific chemical shift in NMR spectrum. The stoichiometric studies on the H₂O₂ consumed in this reaction support the occurrence of reactions of two-electron oxidation followed by complexing two molecules of H₂O₂. Addition of a variety of compounds—Tris, ethanol, mannitol, benzoate, formate (hydroxyl radical quenching), histidine, imidazole (singlet oxygen quenching), and citrate—stimulated a secondary reaction of oxygen-consumption that also used V(IV) as the reducing source. This reaction requires concomitant oxidation of vanadyl by H₂O₂, favoured at low H₂O₂:V(IV) ratio. Another secondary reaction of oxygen release was found to occur during vanadyl oxidation by H₂O₂ in acidic medium in which the end-product was not diperoxovanadate but appears to be a mixture of VO ₃ ⁺ (–546 ppm), VO³⁺ (–531 ppm) and VO ₂ ⁺ (–512 ppm), as shown by the⁵¹V-NMR spectrum. This reaction also occurred in phosphate-buffered medium but only on second addition of vanadyl. The compounds that stimulated the oxygen-consumption reaction were found to inhibit the oxygen-release reaction. A combination of these reactions occur depending on the proportion of the reactants (vanadyl and H₂O₂), the pH of the medium and the presence of some compounds that affect the secondary reactions.     

Chemolithoautotrophy in the marine,magnetotactic bacterial strains MV-1 and MV-2

Magnetite-producing magnetotactic bacteria collected from the oxic–anoxic transition zone of chemically stratified marine environments characterized by O₂/H₂S inverse double gradients, contained internal S-rich inclusions resembling elemental S globules, suggesting they oxidize reduced S compounds that could support autotrophy. Two strains of marine magnetotactic bacteria, MV-1 and MV-2, isolated from such sites grew in O₂-gradient media with H₂S or thiosulfate (S₂O₃^2–) as electron sources and O₂ as electron acceptor or anaerobically with S₂O₃^2– and N₂O as electron acceptor, with bicarbonate (HCO₃^–)/CO₂ as sole C source. Cells grown with H₂S contained S-rich inclusions. Cells oxidized S₂O₃^2– to sulfate (SO₄^2–). Both strains grew microaerobically with formate. Neither grew microaerobically with tetrathionate (S₄O₆^2–), methanol, or Fe²⁺ as FeS, or siderite (FeCO₃). Growth with S₂O₃^2– and radiolabeled ¹⁴C-HCO₃^– showed that cell C was derived from HCO₃^–/CO₂. Cell-free extracts showed ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) activity. Southern blot analyses indicated the presence of a form II RubisCO (cbbM) but no form I (cbbL) in both strains. cbbM and cbbQ, a putative post-translational activator of RubisCO, were identified in MV-1. MV-1 and MV-2 are thus chemolithoautotrophs that use the Calvin–Benson–Bassham pathway. cbbM was also identified in Magnetospirillum magnetotacticum. Thus, magnetotactic bacteria at the oxic–anoxic transition zone of chemically stratified aquatic environments are important in C cycling and primary productivity.     

Involvement of the oxidative burst in phytoalexin accumulation and the hypersensitive reaction

The role of the oxidative burst, transient production of activated oxygen species such as H₂O₂ and superoxide (O₂⁻) in elicitation of phytoalexins and the hypersensitive reaction (HR) was investigated in white clover (Trifolium repens L.) and tobacco (Nicotiana tabacum L.). H₂O₂ and O₂⁻ production was measured as chemiluminescence (CL) mediated by luminol, which was added to suspension-cultured white clover just before measurement in an out-of-coincidence mode scintillation counter. Maximum CL occurred between 10 and 20 min after addition of 0.4 × 10⁸ colony-forming units/mL of incompatible Pseudomonas corrugata or 158 μm HgCl₂. Autoclaved P. corrugata produced a slightly higher response. Elicitation of cells with 25 μm HgCl₂ did not produce CL. Preincubation of plant cells in superoxide dismutase, which converts O₂⁻ to H₂O₂, for 2 min before addition of bacteria did not significantly increase maximum CL levels (P ≥ 0.05). Preincubation of plant cells with catalase for 2 min before addition of bacteria prevented the increase in CL, confirming that H₂O₂ is the substrate for the luminol reaction. Addition of live bacteria or HgCl₂ (25 and 158 μm) to white clover increased levels of the phytoalexin medicarpin during a 24-h period, but addition of autoclaved bacteria did not elicit formation of medicarpin. Preincubation of plant cells with catalase, which quenched the bacteria-induced oxidative burst, did not decrease phytoalexin accumulation. Live bacteria infiltrated into Havana 44 tobacco leaf panels induced development of the HR, but autoclaved bacteria did not. Incubation of live bacteria with superoxide dismutase and catalase before infiltration into tobacco leaves did not interfere with development of the HR. Tobacco leaf panels infiltrated with up to 158 μm HgCl₂ did not develop an HR. These results suggest that an oxidative burst consisting of H₂O₂ and O₂⁻ does occur during these two plant defense responses, but it may not be a necessary element of the signaling system for HR and phytoalexin formation.     

Improved assay for catalase based upon steady-state substrate concentration

A modification of the polarographic assay for catalase is described that is based upon automatic titration of a buffered H₂O₂-catalase reaction mixture with a more concentrated H₂O₂ solution such that there is no significant change in the volume of the reaction mixture. The recorded rate of addition of the titrant required to maintain a steady-state substrate concentration yields enzyme activity measurements in terms of actual reaction rate instead of the less satisfactory rate constant for H₂O₂ decomposition, as is the case for most extant assays for catalase. An additional advantage of the new method is that the reaction can be easily carried out at considerably lower temperature and substrate concentrations than can be employed practicably in other types of assays for this enzyme. Both of these features are desirable to minimize the formation of inactive catalase-H₂O₂ complexes. The improved assay works satisfactorily for measuring catalase activity in rat tissue homogenates.     

Fast and sensitive chemiluminescence determination of H2O2 concentration in stimulated human neutrophils

A fast and sensitive chemiluminescence assay for the determination of H₂O₂ in stimulated neutrophils without the use of enzymes was developed. The method is based on the oxidation of luminol by hypochlorous acid. The chemiluminescence of this reaction is highly dependent on the concentration of hydrogen peroxide. Changes in H₂O₂ concentration in PMA-stimulated neutrophils were followed by injection of NaOCI to cell suspension at different times after cell stimulation. The short integration time of 2 s permits calculation of actual concentrations of H₂O₂ without influence of H₂O₂ decomposition by cellular enzymes or newly produced H₂O₂ due to dismutation of superoxide anion radicals. Concentrations of H₂O₂ were diminished by catalase and enhanced by sodium azide owing to inhibition of cellular catalase and myeloperoxidase. Changes in H₂O₂ concentration upon stimulation could be observed at 3000 cell/mL.     

Changes in hydrogen peroxide homeostasis and cytokinin levels contribute to the regulation of shade-induced senescence in wheat leaves

In a previous work we demonstrated that the suppression of blue light in shaded leaves of wheat increases their senescence rate and the development of oxidative stress symptoms. In order to better understand the interaction between the oxidative metabolism and light spectral quality in the regulation of leaf senescence, we studied the evolution of H₂O₂ concentration, protein oxidation, proteolytic activity and cytokinin content in excised leaves, either illuminated (control, “C”) or shaded under blue (“B”, high blue light transmission) or green (“G”, very low blue light transmission) light filters. H₂O₂ concentration significantly increased during the first 9 h after treatment initiation, an effect that was consistently higher in treatments B and C. Leaves from these treatments showed lower chlorophyll and protein degradation rates, lower concentration of oxidized proteins, and maintained higher levels of the cytokinin isopentenyl-adenosine than those from treatment G. When moderate H₂O₂ concentrations were supplied during 6–9 h after the onset of the shade treatments, senescence rate in treatment G was delayed, while the opposite effect was observed in the presence of the H₂O₂ scavengers catalase and, to a lesser extent, dimethylthiourea. These effects were accompanied by an increment or a decrement, respectively, of catalase activity, suggesting that the early changes in H₂O₂ homeostasis in leaves from treatments B and C may contribute to the prevention rather than to the induction of further oxidative damage. Altogether our results show that the suppression of blue light transmission in shaded leaves act as a stress signal that increases their sensitivity to oxidative stress and accelerates cell death.     

Production of gluconic acid by immobilized in pumice stones mycelium of Aspergillus niger using unconventional oxygenation of culture

Gluconic acid was produced in repeated batch processes with Aspergillus niger AM-11, immobilized in pumice stone particles using an unconventional oxygenation of culture media based on the addition of H₂O₂, decomposed by catalase to O₂ and water. The highest gluconic acid productivity of 8.2 g l^–1 h^–1 was reached with 30 g immobilized mycelium per 150 ml, 10% (w/v) glucose, at 24 °C and pH 6.5, with O₂ at 100% saturation. The immobilized mycelium was successfully reused up to 8 times in 1-h batches with only a slight loss (11%) of gluconic acid productivity.     

A Mechanism of Resistance to Hydrogen Peroxide in Vibrio rumoiensis S-1

A possible mechanism of resistance to hydrogen peroxide (H₂O₂) in Vibrio rumoiensis, isolated from the H₂O₂-rich drain pool of a fish processing plant, was examined. When V. rumoiensis cells were inoculated into medium containing either 5 mM or no H₂O₂, they grew in similar manners. A spontaneous mutant strain, S-4, derived from V. rumoiensis and lacking catalase activity did not grow at all in the presence of 5 mM H₂O₂. These results suggest that catalase is inevitably involved in the resistance and survival of V. rumoiensis in the presence of H₂O₂. Catalase activity was constitutively present in V. rumoiensis cells grown in the absence of H₂O₂, and its occurrence was dependent on the age of the cells, a characteristic which is observed for the HP II-type catalase of Escherichia coli. The presence of the HP II-type catalase in V. rumoiensis cells was evidenced by partial sequencing of the gene encoding the HP II-type catalase from this organism. A notable difference between V. rumoiensis and E. coli is that catalase is accumulated at very high levels (~2% of the total soluble proteins) in V. rumoiensis, in contrast to the case for E. coli. When V. rumoiensis cells which had been exposed to 5 mM H₂O₂ were centrifuged, most intracellular proteins, including catalase, were recovered in the medium. On the other hand, when V. rumoiensis cells were grown on plates containing various concentrations of H₂O₂, individual cells had a colony-forming ability inferior to those of E. coli, Bacillus subtilis, and Vibrio parahaemolyticus. Thus, it is suggested that when V. rumoiensis cells are exposed to high concentrations of H₂O₂, most cells will immediately be broken by H₂O₂. In addition, the cells which have had little or no damage will start to grow in a medium where almost all H₂O₂ has been decomposed by the catalase released from broken cells.     

Mitochondrial transmembrane potential is diminished in phorbol myristate acetate-stimulated peritoneal resident macrophages isolated from wild-type mice,but not in those from gp91-phox-deficient mice

Macrophages produce superoxide (O₂^–) during phagocytosis or upon stimulation with a variety of agents including phorbol myristate acetate (PMA) through the activation of NADPH oxidase, and the formed O₂^– is converted to other reactive oxygen species (ROS) such as hydrogen peroxide (H₂O₂). The aim of the present study was to elucidate the effect of the intracellularly produced ROS on mitochondrial transmembrane potential (MTP) in mouse (C57BL/6) peritoneal resident macrophages stimulated with PMA. Using a fluorescent dye, succinimidyl ester of dichlorodihydrofluorescein (H₂DCFDA), O₂^– was visualized in intracellular compartments in a certain subpopulation of macrophages isolated from wild-type mice. Cells deficient in gp91-phox, one of the membrane components of NADPH oxidase, were negative for the fluorescence. When cells were loaded with both H₂DCFDA and MitoCapture, a fluorescent dye for mitochondria, mitochondrial fluorescence was diminished in O₂^–-producing cells, but not in O₂^–-deficient cells. Flow cytometry also revealed the decrease of mitochondrial fluorescence in wild-type cells, but not in gp91-phox-deficient cells. The loss of mitochondrial fluorescence was prevented by microinjection of catalase into cells. The present findings demonstrate that MTP is diminished by ROS, including the H₂O₂ dismutated from O₂^–, produced intracellularly by activation of the NADPH oxidase in mouse peritoneal resident macrophages stimulated with PMA.     

Hydrogen Peroxide Metabolism in Yeasts

A catalase-negative mutant of the yeast Hansenula polymorpha consumed methanol in the presence of glucose when the organism was grown in carbon-limited chemostat cultures. The organism was apparently able to decompose the H₂O₂ generated in the oxidation of methanol by alcohol oxidase. Not only H₂O₂ generated intracellularly but also H₂O₂ added extracellularly was effectively destroyed by the catalase-negative mutant. From the rate of H₂O₂ consumption during growth in chemostat cultures on mixtures of glucose and H₂O₂, it appeared that the mutant was capable of decomposing H₂O₂ at a rate as high as 8 mmol · g of cells⁻¹ · h⁻¹. Glutathione peroxidase (EC 1.11.1.9) was absent under all growth conditions. However, cytochrome c peroxidase (CCP; EC 1.11.1.5) increased to very high levels in cells which decomposed H₂O₂. When wild-type H. polymorpha was grown on mixtures of glucose and methanol, the CCP level was independent of the rate of methanol utilization, whereas the level of catalase increased with increasing amounts of methanol in the substrate feed. Also, the wild type decomposed H₂O₂ at a high rate when cells were grown on mixtures of glucose and H₂O₂. In this case, an increase of both CCP and catalase was observed. When Saccharomyces cerevisiae was grown on mixtures of glucose and H₂O₂, the level of catalase remained low, but CCP increased with increasing rates of H₂O₂ utilization. From these observations and an analysis of cell yields under the various conditions, two conclusions can be drawn. (i) CCP is a key enzyme of H₂O₂ detoxification in yeasts. (ii) Catalase can effectively compete with mitochondrial CCP for hydrogen peroxide only if hydrogen peroxide is generated at the site where catalase is located, namely in the peroxisomes.     

The stimulatory effect of negative air ions and hydrogen peroxide on the activity of superoxide dismutase

The activity of erythrocyte cytosolic superoxide dismutase from rat, bovine, man and duck was considerably increased when measured after preparation or incubation in media pretreated with negative air ions (mostly superoxide) from electroeffluvial ion generator. 0.5–1.0 μM H₂O₂ was found in incubation medium after treatment with air ions. The stimulatory effect of air ions on superoxide dismutase activity was mimicked by addition of 0.5–6 μM H₂O₂. The primary physicochemical mechanism of beneficial biological action of negative air ions is suggested to be related to the stimulation of superoxide dismutase activity by micromolar concentrations of H₂O₂.     

Overexpression of catalase delays G0/G1- to S-phase transition during cell cycle progression in mouse aortic endothelial cells

Although it is understood that hydrogen peroxide (H₂O₂) promotes cellular proliferation, little is known about its role in endothelial cell cycle progression. To assess the regulatory role of endogenously produced H₂O₂ in cell cycle progression, we studied the cell cycle progression in mouse aortic endothelial cells (MAECs) obtained from mice overexpressing a human catalase transgene (hCatTg), which destroys H₂O₂. The hCatTg MAECs displayed a prolonged doubling time compared to wild-type controls (44.0  ±  4.7 h versus 28.6  ±  0.8 h, p < 0.05), consistent with a diminished growth rate and H₂O₂ release. Incubation with aminotriazole, a catalase inhibitor, prevented the observed diminished growth rate in hCatTg MAECs. Inhibition of catalase activity with aminotriazole abrogated catalase overexpression-induced antiproliferative action. Flow cytometry analysis indicated that the prolonged doubling time was principally due to an extended G₀/G₁ phase in hCatTg MAECs compared to the wild-type cells (25.0  ±  0.9 h versus 15.9  ±  1.4 h, p  <  0.05). The hCatTg MAECs also exhibited decreased activities of the cyclin-dependent kinase (Cdk) complexes responsible for G₀/G₁- to S-phase transition in the cell cycle, including the cyclin D–Cdk4 and cyclin E–Cdk2 complexes. Moreover, the reduction in cyclin–Cdk activities in hCatTg MAECs was accompanied by increased protein levels of two Cdk inhibitors, p21 and p27, which inhibit the Cdk activity required for the G₀/G₁- to S-phase transition. Knockdown of p21 and/or p27 attenuated the antiproliferative effect of catalase overexpression in MAECs. These results, together with the fact that catalase is an H₂O₂ scavenger, suggest that endogenously produced H₂O₂ mediates MAEC proliferation by fostering the transition from G₀/G₁ to S phase.     

Effects of supraoptimal temperatures on the myxomycetePhysarum polycephalum

Vibrio parahaemolyticus, the flagellated nonswarming marine bacteria were induced to swarm on solid media under three different conditions: growth at 20–26°C on medium containing 1% NaCl, growth on a medium in a sealed Petridish and growth on H₂O₂-treated medium. The morphological transformations observed in cells during swarming of V. parahaemolyticus are similar to those found jor the naturally swarming Vibrio alginolyticus. The mechanism of swarming in both species involves massive formation of peritrichous flagella and a negative chemotactive response to metabolic byproducts.     

H2 oxidation,O2 uptake and CO2 fixation in hydrogen treated soils

In many legume nodules, the H₂ produced as a byproduct of N₂ fixation diffuses out of the nodule and is consumed by the soil. To study the fate of this H₂ in soil, a H₂ treatment system was developed that provided a 300 cm³ sample of a soil:silica sand (2:1) mixture with a H₂ exposure rate (147 nmol H₂ cm^–3hr^–1) similar to that calculated exist in soils located within 1–4 cm of nodules (30–254 nmol H₂ cm^–3hr^–1). After 3 weeks of H₂ pretreatment, the treated soils had a K_m and V_max for H₂ uptake (1028 ppm and 836 nmol cm^–3 hr^–1, respectively) much greater than that of control, air-treated soil (40.2 ppm and 4.35 nmol cm^–3 hr^–1, respectively). In the H₂ treated soils, O₂, CO₂ and H₂ exchange rates were measured simultaneously in the presence of various pH₂. With increasing pH₂, a 5-fold increase was observed in O₂ uptake, and CO₂ evolution declined such that net CO₂ fixation was observed in treatments of 680 ppm H₂ or more. At the H₂ exposure rate used to pretreat the soil, 60% of the electrons from H₂ were passed to O₂, and 40% were used to support CO₂ fixation. The effect of H₂ on the energy and C metabolism of soil may account for the well-known effect of legumes in promoting soil C deposition.     

The effect of reactive oxygen species on ethylene production induced by osmotic stress in etiolated mungbean seedling

After 10 h osmotic stress in 25% polyethylene glycol (PEG6000) solution (–1.8 MPa) at 25 °C in darkness, the etiolated mungbean seedlings were transferred to pure water for recovery. The ethylene release rate and the level of reactive oxygen species (ROS), including superoxide radical (O₂^–) and hydrogen peroxide (H₂O₂), were investigated during the recovery process. The results showed that ethylene production rate and amount of ROS increased dramatically after osmotic stress, and a close correlation was observed between ethylene release rate and concentrations of ROS. Inhibitors of ethylene biosynthesis, aminoethoxyvinylglycine (AVG) or aminooxyacetic acid (AOA), could reduce the ethylene release rate, but had no significant influence to the content of O₂^– and H₂O₂. As well as, silver thiosulfate (STS), an inhibitor of ethylene action, exhibited no obvious effect to the concentration of ROS, showing stress-inducible ethylene was not the cause for the increase of stress-inducible ROS. On the other hand, exogenous generator of superoxide radical (methylviologen, MV, or sodium dithionite, Na₂S₂O₄) could enhance the ethylene production evidently, which could be inhibited by exogenous scavenger of superoxide radical (superoxide dismutase, SOD, or 1, 4-diazabicyclo (2,2,2) octane, DABCO). However, either exogenous H₂O₂ or catalase (CAT) had no significant influence on ethylene production. The results suggested that it was superoxide radical but not H₂O₂which was involved directly in osmotic stress-inducible ethylene biosynthesis. The dual-role of superoxide radical on stress ethylene biosynthesis was also discussed.     

Treatment of H2S using a horizontal biotrickling filter based on biological activated carbon: reactor setup and performance evaluation

Biological treatment is an emerging and prevalent technology for treating off-gases from wastewater treatment plants. The most commonly reported odorous compound in off-gases is hydrogen sulfide (H₂S), which has a very low odor threshold. A self-designed, bench-scale, cross-flow horizontal biotrickling filter (HBF) operated with bacteria immobilized activated carbon (termed biological activated carbon—BAC), was applied for the treatment of H₂S. A mixed culture of sulfide-oxidizing bacteria dominated by Acidithiobacillus thiooxidans acclimated from activated sludge was used as bacterial seed and the biofilm was developed by culturing the bacteria in the presence of carbon pellets in mineral medium. HBF performance was evaluated systematically over 120 days, depending on a series of changing factors including inlet H₂S concentration, gas retention time (GRT), pH of recirculation solution, upset and recovery, sulfate accumulation, pressure drop, gas-liquid ratio, and shock loading. The biotrickling filter system can operate at high efficiency from the first day of operation. At a volumetric loading of 900 m³ m^–3 h^–1 (at 92 ppmv H₂S inlet concentration), the BAC exhibited maximum elimination capacity (113 g H₂S/m^–3 h^–1) and a removal efficiency of 96% was observed. If the inlet concentration was kept at around 20 ppmv, high H₂S removal (over 98%) was achieved at a GRT of 4 s, a value comparable with those currently reported for biotrickling filters. The bacterial population in the acidic biofilter demonstrated capacity for removal of H₂S over a broad pH range (pH 1–7). A preliminary investigation into the different effects of bacterial biodegradation and carbon adsorption on system performance was also conducted. This study shows the HBF to be a feasible and economic alternative to physical and chemical treatments for the removal of H₂S.