Pulmonary oxygen toxicity: Lack of tolerance of mice of various ages

Prolonged continuous exposure of adult (3–4 months) and old (21 months) mice to hyperoxia did not lead to significant changes in the activities of superoxide dismutase and catalase in liver or blood. Lung superoxide dismutase activity increased by 25% during initial exposure to 100% O₂, but then fell progressively to below control level. Exposure of mice to 60% or 80% O₂ increased their susceptibility to further exposure to 100% O₂. The results clearly show that both adult and old mice are incapable of coping with the high oxygen environment and that antioxidant enzyme induction and the associated partial protection from pulmonary O₂ toxicity are not the general rule in mammalian lung exposed to subtoxic oxygen levels.     

Superoxide dismutase-rich bacteria. Paradoxical increase in oxidant toxicity

Superoxide dismutase is considered important in protection of aerobes against oxidant damage, and increased tolerance to oxidant stress is associated with induction of this enzyme. However, the importance of superoxide dismutase in this tolerance is not clear because conditions which promote the synthesis of superoxide dismutase likewise affect other antioxidant enzymes and substances. To clarify the role of superoxide dismutase per se in organismal defense against oxidant-generating drugs, we employed Escherichia coli transformed with multiple copies of the gene for bacterial iron superoxide dismutase. These bacteria have greater than ten times the superoxide dismutase activity of wild-type E. coli but, importantly, are normal in other oxidant defense parameters including catalase, peroxidases, glutathione, and glutathione reductase. High superoxide dismutase and control bacteria were exposed to the O2- -generating drug paraquat and to elevated pO2. We find; high superoxide dismutase E. coli are more readily killed by paraquat under aerobic, but not anaerobic, conditions. During exposure to paraquat, high superoxide dismutase E. coli accumulate more H2O2. Coincidentally, the reduced glutathione content of high superoxide dismutase E. coli declines more than in control E. coli. E. coli with high superoxide dismutase activity are also more readily killed by hyperoxia. Interestingly, the susceptibility of the parental and high superoxide dismutase E. coli to killing by exogenous H2O2 is not significantly different. Thus, under these experimental conditions, greatly enhanced superoxide dismutase activity accelerates H2O2 formation. The increased H2O2 probably accounts for the exaggerated sensitivity of high superoxide dismutase bacteria to oxidant-generating drugs. These results support the concept that the product of superoxide dismutase, H2O2, is at least as hazardous as the substrate, O2-. We conclude that effective organismal defense against reactive oxygen species may require balanced increments in antioxidant enzymes and cannot necessarily be improved by increases in the activity of single enzymes.     

Rat superoxide dismutases. Purification, labeling, immunoassay, and tissue concentration

This study determines the validity of utilizing radioimmunoassay of CuZn and Mn superoxide dismutase in the rat for defining mechanism of control over mammalian tissue superoxide dismutase concentrations. To accomplish this, rat Mn and CuZn superoxide dismutase were purified. The CuZn superoxide dismutase dimer had a specific activity of 3600 units/mg of protein and a subunit Mr of 17,000. The Mn superoxide dismutase tetramer had a specific activity of 3700 units/mg of protein and a subunit Mr of 22,000. Both enzymes provided a single discrete protein band on disc gel electrophoresis. The purified enzymes were utilized to develop sensitive (less than 2.5 ng/ml Mn superoxide dismutase and less than 3.12 ng/ml CuZn superoxide dismutase) reproducible immunoassays the specificity of which was confirmed by tissue homogenate dilution and column chromatography. Immunoassay of these enzymes in rat tissues permitted clarification of existing data based on activity assays and demonstrated a trend for higher Mn superoxide dismutase concentrations in tissues of high mitochondrial content (with relative tissue concentrations comparable to man) and low superoxide dismutase concentrations in islets (providing an explanation for their sensitivity to free radical damage). This represents the first report of a radioimmunoassay for rat Mn superoxide dismutase, and the second report of successful purification of rat Mn superoxide dismutase (with higher specific activity and apparent purity and stability). The data support the proposition that these radioimmunoassays in rats will provide a useful system for investigation of mechanisms of control over tissue superoxide dismutase concentrations in mammalian tissues.     

Proposed mechanism for neonatal rat tolerance to normobaric hyperoxia

Induction of two forms of superoxide dismutase, catalase and glutathione peroxidase, occurs very rapidly in neonatal rat lung tissue upon exposure of these animals to 94 + % normobaric oxygen. No such oxygen-mediated enzyme induction occurs in the lungs of adult rats. The aged-dependent pattern of enzyme induction correlates with the well-established age-dependent tolerance of neonatal rats to hyperoxia. Enzyme induction occurs in the lungs of neonates in only those species known to be resistant to oxygen-provoked lung damage. Compromise of oxygen-mediated enzyme induction predisposed the neonatal rats to pulmonary oxygen toxicity. These data have formed the basis of the proposal that oxygen induction of the superoxide dismutases catalase and glutathione peroxidase provides a vital part of the defense mechanism against oxygen toxicity. A biochemical mechanism of oxygen-provoked pulmonary damage has been elaborated to explain the role of each enzyme in the protection against oxygen and free radical toxicity.     

Inhalation of ozone induces DNA strand breaks and inflammation in mice

Ozone (O3) is a well-known oxidant pollutant present in photochemical smog. Although ozone is suspected to be a respiratory carcinogen it is not regulated as a carcinogen in most countries.The genotoxic and inflammatory effects of ozone were investigated in female mice exposed to ozone for 90 min. The tail moment in bronchoalveolar lavage (BAL) cells from BALB/c mice was determined by the comet assay as a measure of DNA strand breaks. Within the first 200 min after exposure, the BAL cells from the mice exposed to 1 or 2 ppm ozone had 1.6- and 2.6-fold greater tail moments than unexposed mice. After 200 min there was no effect. It could be ruled out that the effect during the first 200 min was due to major infiltration of lymphocytes or neutrophils. Unexpectedly, ozone had no effect on the content of 8-oxo-deoxyguanosine (8-oxo-dG) in nuclear DNA or on oxidised amino acids in the lung tissue. The mRNA level of the repair enzyme ERCC1 was not increased in the lung tissue. Inflammation was measured by the cytokine mRNA level in lung homogenates. An up to 150-fold induction of interleukin-6 (IL-6) mRNA was detected in the animals exposed to 2 ppm ozone compared to the air-exposed control mice. Also at 1 ppm ozone, the IL-6 mRNA was induced. The large induction of IL-6 mRNA in the lung took place after DNA strand breaks were induced in BAL. This does not support the notion that inflammatory reactions are the cause of DNA damage. To determine whether these exposures were mutagenic, Muta Mice were exposed to 2 ppm ozone, 90 min per day for 5 days. No treatment-related mutations could be detected in the cII transgene.These results indicate that a short episode of ozone exposure at five times the threshold limit value (TLV) in US induces lung inflammatory mediators and DNA damage in the cells in the lumen of the lung. This was not reflected by an induction of mutations in the lung of Muta Mice.     

Apoplastic antioxidative system responses to ozone stress in strawberry leaves

Cell wall polysaccharides, pectin composition, as well as apoplastic superoxide dismutase and peroxidase activities were investigated in strawberry (Fragaria × ananassa) cultivars (cvs) Korona and Elsanta differing in their ozone sensitivity. Plants were exposed to 140–170 μg m⁻³ ozone either short-term for 7 days or long-term for 2 months in order to investigate whether differences in ozone sensitivity were due to differences in the apoplastic antioxidative systems. Cell wall polysaccharides were increased after 7 days and 2 months of ozone stress. While water-soluble pectins, low methoxy pectinates and NaOH-soluble pectinates were elevated after 7 days, their contents were unaffected (water-soluble pectins) or lower (low methoxy pectinates, NaOH-soluble pectinates) after 2 months. In cv. Elsanta, ozone treatment resulted in a significant reduction of superoxide dismutase activity after 7 days and 2 months, while it remained similar in cv. Korona. After 7 days, peroxidase activity was significantly higher in ozone-exposed leaves of cv. Korona, whereas after 2 months it was similar to or higher than in controls. Superoxide dismutase in cv. Korona detoxified ozone and its products in the apoplast, and the resulting elevated levels of H₂O₂ were balanced within 7 days by an increase in peroxidase activity. Long-term peroxidase activity may not play a comparably significant role in ozone defence, but the increase in cell wall polysaccharides and cell wall thickness measured after 2 months, resulting in a decrease in specific leaf area, reflected structural modifications that limited activities of reactive oxygen species efficiently. In contrast, the reduction of superoxide dismutase activity in cv. Elsanta indicated a less efficient apoplastic radical scavenging system, at least during the first 7 days of ozone stress, which was accompanied by membrane leakage and contributed to accelerated leaf senescence. Long-term, the reduction of intercellular air space volume in leaves contributed to ozone tolerance of cv. Elsanta as in cv. Korona.     

Superoxide dismutase and catalase in Azotobacter vinelandii grown in continuous culture at different dissolved oxygen concentrations

Superoxide dismutase and catalase activities were studied in Azotobacter vinelandii grown diazotrophically at different ambient oxygen concentrations in continuous culture. Activities were expressed either as specific activity or activity per cell. Specific superoxide dismutase activity increased by a factor of 1.6 with increasing oxygen concentration from about 1% to 90% air saturation of the growth medium whereas specific catalase activity increased only slightly, if at all. Since cell volumes increased in parallel to increases in the oxygen concentration cellular superoxide dismutase activities increased by a factor of 4.3 while cellular catalase activities increased by a factor of 3.3. Under all conditions only the Fe-containing form of superoxide dismutase was detected. The possible function of these enzymes in the protection nitrogenase from oxygen damage is discussed.Abbreviation SOD superoxide dismutase     

Inhalation of ozone induces DNA strand breaks and inflammation in mice

Ozone (O₃) is a well-known oxidant pollutant present in photochemical smog. Although ozone is suspected to be a respiratory carcinogen it is not regulated as a carcinogen in most countries.The genotoxic and inflammatory effects of ozone were investigated in female mice exposed to ozone for 90 min. The tail moment in bronchoalveolar lavage (BAL) cells from BALB/c mice was determined by the comet assay as a measure of DNA strand breaks. Within the first 200 min after exposure, the BAL cells from the mice exposed to 1 or 2 ppm ozone had 1.6- and 2.6-fold greater tail moments than unexposed mice. After 200 min there was no effect. It could be ruled out that the effect during the first 200 min was due to major infiltration of lymphocytes or neutrophils. Unexpectedly, ozone had no effect on the content of 8-oxo-deoxyguanosine (8-oxo-dG) in nuclear DNA or on oxidised amino acids in the lung tissue. The mRNA level of the repair enzyme ERCC1 was not increased in the lung tissue. Inflammation was measured by the cytokine mRNA level in lung homogenates. An up to 150-fold induction of interleukin-6 (IL-6) mRNA was detected in the animals exposed to 2 ppm ozone compared to the air-exposed control mice. Also at 1 ppm ozone, the IL-6 mRNA was induced. The large induction of IL-6 mRNA in the lung took place after DNA strand breaks were induced in BAL. This does not support the notion that inflammatory reactions are the cause of DNA damage. To determine whether these exposures were mutagenic, Muta™Mice were exposed to 2 ppm ozone, 90 min per day for 5 days. No treatment-related mutations could be detected in the cII transgene.These results indicate that a short episode of ozone exposure at five times the threshold limit value (TLV) in US induces lung inflammatory mediators and DNA damage in the cells in the lumen of the lung. This was not reflected by an induction of mutations in the lung of Muta™Mice.     

Expression of manganese superoxide dismutase is not altered in transgenic mice with elevated level of copper-zinc superoxide dismutase

In evaluating the relative expression of copper-zinc and manganese superoxide dismutase (CuZnSOD and MnSOD) in vivo in states like Down syndrome in which one dismutase is present at increased levels, we measured activities of both enzymes, in tissues of control and transgenic mice constitutively expressing increased levels of CuZnSOD, during exposure to normal and elevated oxygen tensions. Using SOD gel electrophoresis assay, CuZnSOD and MnSOD activities of brain, lung, heart, kidney, and liver from mice exposed to either normal (21%) or elevated (>99% oxygen, 630 torr) oxygen tensions for 120 h were compared. Whereas CuZnSOD activity was elevated in tissues of transgenic relative to control mice under both normoxic or hyperoxic conditions, MnSOD activities in organs of transgenic mice were remarkably similar to those of controls under both conditions. To confirm the accuracy of this method in quantitating MnSOD relative to CuZnSOD expression, two other methods were utilized. In lung, which is the organ exposed to the highest oxygen tension during ambient hyperoxia, a sensitive, specific ELISA for MnSOD was used. Again, MnSOD protein was not different in transgenic relative to control mice during exposure to air or hyperoxia. In addition, lung MnSOD protein was not changed significantly by exposure to hyperoxia in either group. In kidney, a mitochondrion-rich organ, SOD assay, before and after inactivation of CuZnSOD with diethyldithiocarbamate, was used. MnSOD activity was not different in organs from air-exposed transgenic relative to control mice. The data indicated that expression of MnSOD in vivo was not affected by overexpression of the CuZnSOD and, therefore, the two enzymes are probably regulated independently.     

Effects of culture conditions an hyperoxia on antioxidant enzymes in pig pulmonary artery and aortic endothelium

Because hyperoxia induces early injury to lung endothelial cells and since tolerance to hyperoxia is correlated with increased lung antioxidant enzyme activity, we measured superoxide dismutase, catalase and glutathione peroxidase in both fresh isolates and primary cultures of endothelial cells from pig pulmonary artery and aorta. Cultured endothelial cells were studied at confluency and up to 5 days thereafter under control or hyperoxic conditions. In both types of confluent cell, total and cyanide-insensitive superoxide dismutase increased when compared to fresh cells. The most conspicuous postconfluency change in both types of endothelial cell was a marked decrease in gluthathione peroxidase, which could be prevented by the addition of selenomethionine to culture media. A 5-day exposure to hyperoxia resulted in a 2-fold increase in cyanide-insensitive superoxide dismutase in both aortic and pulmonary artery endothelial cells. In view of a similar decrease in DNA in both types of cells despite some differences in enzyme levels, oxygen cytotoxicity could not be related to a particular antioxidant enzyme profile.     

Specific induction of indoleamine 2,3-dioxygenase by bacterial lipopolysaccharide in the mouse lung

Indoleamine 2,3-dioxygenase activity in the supernatant fractions (30,000g, 30 min) from various tissues of mice increased almost linearly after a single intraperitoneal administration of bacterial lipopolysaccharide (5 to 20 μg/mouse). The most prominent effect was observed in the lung, where both specific and total enzyme activities increased 40 to 80-fold during the first 24 h. Significant (10- to 20-fold) stimulation was also observed in the seminal vesicle, coagulating gland, colon, and caecum, and severalfold in the trachea, stomach, heart, small intestine, and spleen. Lipid A fraction, the biologically active unit in the lipopolysaccharide complex, was as active as the lipopolysaccharide preparations from either Escherichia coli or Salmonella S and R mutant strains, whereas the polysaccharide fraction was inactive under identical experimental conditions. When mice were pretreated with a series of daily injections of bacterial lipopolysaccharide, enzyme induction was no longer evident, indicating that tolerance to this agent had developed and that enzyme induction was caused by lipopolysaccharide but not by possible contaminants in the preparations. The enzyme activities from normal and lipopolysaccharide-treated mice were exclusively found in the soluble fractions of mouse lung homogenates. Other enzyme activities in the lung such as lysosomal (acid phosphatase), microsomal (prostaglandin cyclooxygenase), mitochondrial (monoamine oxidase and superoxide dismutase), and soluble enzyme activities (lipooxygenase and superoxide dismutase) were not significantly altered by this treatment. This increase in the enzyme activity with the lipopolysaccharide treatment was abolished with a simultaneous administration of cycloheximide or actinomycin D, and an immunological analysis with antibody for mouse enzyme (rabbit IgG) demonstrated that the observed increment of the enzyme activity was essentially due to an increase in the enzyme protein.     

Time course and quantitative analysis of the adaptive responses to 85% oxygen in the rat lung and heart

The phenomenon of oxygen tolerance (resistance to 100% O(2) in rats previously exposed to 85% O(2)) constitutes one of the few models of adaptive responses to oxidative stress in mammals. In vitro studies suggest that reactive oxygen species mediate this response. To test this hypothesis in vivo, we followed the time course of oxidative stress, enzyme induction, and edema in the lung, heart and liver of rats exposed to 85% O(2) for 1 to 5 days. Interestingly, not only the lung, but also the heart of rats exposed to 85% O(2) showed increases in the production of O(*-)(2) (aconitase inactivation) early during the exposure. Increases in O(*-)(2) were associated to oxidative stress (increased in situ chemiluminescence) and transient edema in both tissues. Both the lung and heart displayed induction of superoxide dismutase and reversion of the oxidative stress and damage. The adaptive response in the heart was faster and more efficient, suggesting that this tissue is at a more critical risk when exposed to elevated O(2) concentrations.     

AMP-activated protein kinase deficiency reduces ozone-induced lung injury and oxidative stress in mice

Background

Acute ozone exposure causes lung oxidative stress and inflammation leading to lung injury. At least one mechanism underlying the lung toxicity of ozone involves excessive production of reactive oxygen and nitrogen intermediates such as peroxynitrite. In addition and beyond its major prooxidant properties, peroxynitrite may nitrate tyrosine residues altering phosphorylation of many protein kinases involved in cell signalling. It was recently proposed that peroxynitrite activates 5''-AMP-activated kinase (AMPK), which regulates metabolic pathways and the response to cell stress. AMPK activation as a consequence of ozone exposure has not been previously evaluated. First, we tested whether acute ozone exposure in mice would impair alveolar fluid clearance, increase lung tissue peroxynitrite production and activate AMPK. Second, we tested whether loss of AMP-activated protein kinase alpha1 subunit in mouse would prevent enhanced oxidative stress and lung injury induced by ozone exposure.

Methods

Control and AMPKα1 deficient mice were exposed to ozone at a concentration of 2.0 ppm for 3 h in glass cages. Evaluation was performed 24 h after ozone exposure. Alveolar fluid clearance (AFC) was evaluated using fluorescein isothiocyanate tagged albumin. Differential cell counts, total protein levels, cytokine concentrations, myeloperoxidase activity and markers of oxidative stress, i.e. malondialdehyde and peroxynitrite, were determined in bronchoalveolar lavage (BAL) and lung homogenates (LH). Levels of AMPK-Thr¹⁷² phosphorylation and basolateral membrane Na(+)-K(+)-ATPase abundance were determined by Western blot.

Results

In control mice, ozone exposure induced lung inflammation as evidence by increased leukocyte count, protein concentration in BAL and myeloperoxidase activity, pro-inflammatory cytokine levels in LH. Increases in peroxynitrite levels (3 vs 4.4 nM, p = 0.02) and malondialdehyde concentrations (110 vs 230 μmole/g wet tissue) were detected in LH obtained from ozone-exposed control mice. Ozone exposure consistently increased phosphorylated AMPK-Thr¹⁷² to total AMPK ratio by 80% in control mice. Ozone exposure causes increases in AFC and basolateral membrane Na(+)-K(+)-ATPase abundance in control mice which did not occur in AMPKα1 deficient mice.

Conclusions

Our results collectively suggest that AMPK activation participates in ozone-induced increases in AFC, inflammation and oxidative stress. Further studies are needed to understand how the AMPK pathway may provide a novel approach for the prevention of ozone-induced lung injury.     

EC-SOD and the response to inflammatory reactions and aging in mouse lung

The lung is exposed to high oxygen tension and oxygen free radicals have been implicated in many pathologies of the organ. Extracellular superoxide dismutase occurs in high concentration in the lung and protects against hyperoxia-induced inflammation. We hypothesized that the enzyme might ameliorate other types of inflammation as well as aging-related changes of the organ. Tracheal instillation of endotoxin plus zymosan into extracellular superoxide dismutase knockout and wild-type mice resulted in a marked neutrophilic inflammation and increases in inflammatory cytokines, protein, and lactate dehydrogenase activity in the bronchoalveolar lavage fluid. There were no significant differences between the genotypes. Repeated challenges with ovalbumin caused an allergic inflammation with increases in eosinophils, interleukin-5, protein, and lactate dehydrogenase activity in the bronchoalveolar lavage fluid. Only minimal differences between the genotypes were found. In lungs from 2-year-old mice, marginal increases in inflammatory variables and fibrosis were found in the knockout mice. In conclusion, extracellular superoxide dismutase had a negligible role in the present inflammation and allergy models and for the long-term integrity of the organ.     

Factors Related to the Oxygen Tolerance of Anaerobic Bacteria

The effect of atmospheric oxygen on the viability of 13 strains of anaerobic bacteria, two strains of facultative bacteria, and one aerobic organism was examined. There were great variations in oxygen tolerance among the bacteria. All facultative bacteria survived more than 72 h of exposure to atmospheric oxygen. The survival time for anaerobes ranged from less than 45 min for Peptostreptococcus anaerobius to more than 72 h for two Clostridium perfringens strains. An effort was made to relate the degree of oxygen tolerance to the activities of superoxide dismutase, catalase, and peroxidases in cell-free extracts of the bacteria. All facultative bacteria and a number of anaerobic bacteria possessed superoxide dismutase. There was a correlation between superoxide dismutase activity and oxygen tolerance, but there were notable exceptions. Polyacrylamide gel electropherograms stained for superoxide dismutase indicated that many of the anaerobic bacteria contained at least two electrophoretically distinct enzymes with superoxide dismutase activity. All facultative bacteria contained peroxidase, whereas none of the anaerobic bacteria possessed measurable amounts of this enzyme. Catalase activity was variable among the bacteria and showed no relationship to oxygen tolerance. The ability of the bacteria to reduce oxygen was also examined and related to enzyme content and oxygen tolerance. In general, organisms that survived for relatively long periods of time in the presence of oxygen but demonstrated little superoxide dismutase activity reduced little oxygen. The effects of medium composition and conditions of growth were examined for their influence on the level of the three enzymes. Bacteria grown on the surface of an enriched blood agar medium generally had more enzyme activity than bacteria grown in a liquid medium. The data indicate that superoxide dismutase activity and oxygen reduction rates are important determinants related to the tolerance of anaerobic bacteria to oxygen.     

Environmental agents altering lung biochemistry.

Environmental agents may enter the lung via the tracheobronchial tree or via the bloodstream. They can interact with lung cell metabolism and set in motion a sequence of events that leads to damage, adaptation, and repair. Biochemical signs of lung damage described include lipid peroxidation, decreased biosynthesis of macromolecules, depressed enzyme activities, and the binding of metabolites of the offending agent to tissue macromolecules. As a response to acute damage, lung can activate several biochemical pathways. The selenium-glutathione peroxidase system affords protection against lipid peroxidation and increased activity of superoxide dismutase provides oxygen tolerance. Biochemical adaptation occasionally occurs very quickly: the herbicides paraquat and diquat produce an acute loss of cellular NADPH in lung. This is accompanied by a sudden increase in pentose phosphate pathway activity. Biochemical events accompanying tissue repair following lung injury are increased synthesis of nucleic acids and of protein and enhanced enzymatic activity. The repair following lung damage caused by drugs may be inhibited by oxygen.     

Pre-exposure of calli to ozone promotes tolerance of regenerated Lycopersicon esculentum cv. PKM1 plantlets against acute ozone stress

Studies were performed to evaluate the effects of pre-exposure of calli to ozone in promoting tolerance of the regenerated Lycopersicon esculentum cv. PKM1 (tomato) plantlets against acute ozone stress (AOS). Calli induced from tomato leaf explants were subjected to pre-treatment with ozone: T(1)=100ppb, T(2)=200ppb and T(3)=300ppb. For the control (C) calli, charcoal-filtered air was supplied to test differential sensitivity of regenerated plantlets to acute ozone stress. All treated calli were subsequently transferred to shooting, rooting medium and acclimatized. The plantlets regenerated from the respective ozone (T(1), T(2), T(3))-treated calli are referred to here as T(1), T(2), T(3) plantlets and the plantlets regenerated from control calli are referred to as control plantlets. The frequencies of regeneration of tomato plantlets from the calli were T(1)=86%, T(2)=82% and T(3)=67%, and 92% regeneration was obtained from control calli. In order to evaluate the ozone tolerance, all the regenerated plantlets were exposed to the acute ozone exposure (AOE). After AOE, the T(2) plantlets endured remarkably well by experiencing reduced ozone stress, which was evident from the lower level of hydrogen peroxide and oxidative stress-related enzymes such as ascorbate peroxidase (EC 1.11.1.11) and superoxide dismutase (EC 1.15.1.1) activities relative to T(3), T(1) and C plantlets. All T(2) plantlets showed enhanced tolerance against AOE by upholding enhanced soluble phenol content, a higher level of foliar and apoplastic ascorbic acid, elevated dehydroascorbate reductase (EC 1.8.5.1) and glutathione content. The present study reveals that the calli pre-exposed to T(2) ozone treatment resulted in an increase in the level of antioxidants and provided the plants greater protection against acute ozone stress.     

The effect of carnosine and trolox on cellular chemiluminescence of leukocytes]

The effects of hydrophilic antioxidant carnosine, trolox (6-hydroxy-2.5.7.8-tetramethylchroman-2-carboxylic acid), and superoxide dismutase on the myeloperoxidase activity of leukocytes, superoxide anion and active oxygen species generation have been studied. Physiological concentrations of carnosine have been shown to decrease the ability of human leukocytes to produce chemiluminescence as a result of myeloperoxidase activation. However, the chemiluminescence induced by the generation of the superoxide or its derivatives is unaffected by this process. Trolox does not inhibit the induction of superoxide-dependent chemiluminescence of leukocytes either.     

Regulation of the synthesis of superoxide dismutases in rat lungs during oxidant and hyperthermic stresses

Heat shock proteins are induced at normal temperatures by oxidants and during reoxygenation following hypoxia. We now report cyanide-resistant O2 consumption increased 30-50% in rat lungs exposed to heat shock or reoxygenation following hypoxia. The synthesis of Cu,Zn superoxide dismutase, but not Mn superoxide dismutase, was increased in rat lung slices by in vivo hyperthermia (39 degrees C), by in vitro heat shock (41 degrees C), and during incubation of lung slices with the Cu chelator diethyldithiocarbamate, which decreased the activity of Cu,Zn superoxide dismutase. The heat shock-induced increase in Cu,Zn superoxide dismutase developed 2 h later than the induction of heat shock proteins and was not blocked by actinomycin D. The rates of synthesis of both superoxide dismutases were decreased 50% by hypoxia and failed to increase during reoxygenation. During hypoxia the activity of Cu,Zn superoxide dismutase decreased about 50%, but the activity of Mn superoxide dismutase remained unchanged. We conclude that hyperthermia increases the synthesis of Cu,Zn superoxide dismutase, the synthesis of Cu,Zn superoxide dismutase and Mn superoxide dismutase are not coordinately regulated by hyperthermia or by the oxidant stress produced by lowering the activity of Cu,Zn superoxide dismutase, and the synthesis of heat shock proteins and Cu,Zn superoxide dismutase are regulated at different levels of gene expression.