Studies on biochemical effects of nitrogen dioxide. II. Changes of the protective systems in rat lungs and of lipid peroxidation by acute exposure

Serum Clara-Cell Protein and β2-Microglobulin as Early Markers of Occupational Exposure to Nitric Oxides

Biochemical effects of NOx on 60 workers (both genders) of nitric acid production were studied. The control group consisted of 61 nonexposed people employed elsewhere in the plant. Although the actual threshold limit valuetime weighted averages (TLV-TWA) were not exceeded in the specific conditions of our study, the subjects were exposed to NO2 and NO during several exposure episodes with peak maximal concentrations of 140 ppm and 515 ppm, respectively. Additional cross-week evaluation of several biochemical biomarkers in 15 NOx-exposed workers from one shift was performed. The objective of the study was to evaluate the value of serum Clara-cell protein (CC16) as a marker of bronchoalveolar epithelium activity. Antioxidant status was assessed by measuring activity of enzymes: glutathione peroxidase (GSH-Px), ceruloplasmin (Cp) in plasma, or superoxide dismutase (SOD), gluthatione S-transferase (GST), and nonenzymatic alpha-tocopherol in erythrocytes and thiobarbituric acid-reactive substances (TBARS) in plasma. Serum hyaluronic acid (HA) determining the connective tissue matrix status of airways, and beta2-microglobulin in serum (beta2M-S) and urine (beta2M-U) as a marker of renal function in occupational exposure to NOx were also employed. Exposure to NOx initiates peroxidative chain depleting of lipoprotein pool (alpha-tocopherol) in blood. Serum CC16 levels in NOx-exposed workers were found to be closely connected with alpha-tocopherol content. In NOx-exposed workers, the beta2M-S level was significantly higher than in the nonexposed ones, with the exception of smokers. Results of the cross-week study confirm cumulative systemic effects of NOx on several examined biomarkers. SOD and GST were found to be depleted. A transient higher level of HA after a 5-d shift significantly inversely correlated with CC16 level. The data imply that NOx-depleted levels of CC16 are detectable already after an 8-h shift. Our results demonstrate that even low NOx human exposure can cause characteristic changes in bronchiolar epithelium cells and renal effects. Serum CC16 level, although a nonspecific marker, was lowest in NOx-exposed subjects. The most sensitive parameters in exposed workers were beta2M-S and a-tocopherol. Spirometric assessment was not useful to describe low occupational exposure to NOx. In studying the effects of NOx on biomarkers, it is essential to carefully select suitable time of sampling. Screening of CC16, beta2M-S, and a-tocopherol can be successfully employed for biological monitoring of exposure to NOx.

Antioxidant mobilization in response to oxidative stress: a dynamic environmental-nutritional interaction

In today's society, human activities and lifestyles generate numerous forms of environmental oxidative stress. Oxidative stress is defined as a process in which the balance between oxidants and antioxidants is shifted toward the oxidant side. This shift can lead to antioxidant depletion and potentially to biological damage if the body has an insufficient reserve to compensate for consumed antioxidants. This report focuses on the observation that oxidative stress resulting from inhalation of oxidant air pollutants mobilized vitamin E to the lung. A review of the literature showed that this mobilization is not limited to the lung; rather, a variety of situations in which oxidative stress occur can mobilize antioxidants. This antioxidant mobilization shows that a high antioxidant capacity in the body must be maintained for it to cope efficiently with environmental oxidative stress. Maintaining a high-antioxidant capacity in the body with the use of dietary supplementation was a convenient and acceptable method by test subjects, human or non-human. One mechanism that might explain the antioxidant mobilization is a dynamic interaction between environment and nutrition. In that mechanism, oxidative stress would alter certain bioactive molecules, followed by activation of signal transduction pathways that in turn would mobilize antioxidants to the target organ of the oxidant attack.

Biochemical and morphological changes in lung tissue and isolated lung cells of rats induced by short-term nitrogen dioxide exposure

To investigate the effects of repeated exposure to nitrogen dioxide (NO2) on antioxidant enzymes in lung tissue and isolated lung cells, rats were continuously exposed to 20 mg/m3 NO2 (10.6 ppm) for 4 days. The activities of glucose-6-phosphate dehydrogenase (G6PDH), glutathione reductase (GR), and glutathione peroxidase (GSHPx) were measured in the cytosolic fraction of lung tissue of both control and NO2-exposed rats as well as in isolated alveolar macrophages (AMs) and type II cells. Qualitative and quantitative changes in AM and type II cells were studied by electron microscopy and by morphometric analyses using enzyme and immunohistochemistry. NO2 exposure resulted in significantly increased pulmonary activities of G6PDH, GR, and GSHPx, both expressed per lung and per gram of lung weight. Morphometric data show that NO2 exposure significantly increased the number of type II cells, predominantly in the centriacinar region, indicating proliferation of epithelium following cellular injury. Type II cells in lungs of NO2-exposed rats had a squamous, less cuboidal appearance with more lamellar bodies compared to type II cells in lungs of control rats. Compared to control lungs, a higher number of macrophages could be isolated from NO2-exposed lungs, while numbers of type II cells isolated from lungs of control and NO2-exposed rats were the same. Isolated type II cells from control and NO2-exposed rats were polymorphic, with a small number of lamellar bodies and without polarity. Isolated macrophages were rounded and contained many filopodia. NO2 exposure caused increases in the activities of G6PDH and GSHPx in isolated type II cells and of GSHPx in isolated macrophages, when expressed per number of cells. Macrophages and type II cells isolated from control and NO2-exposed rats and re-exposed in vitro to NO2, showed no differences in phagocytosis and viability features. Our results indicate that NO2-induced increases in pulmonary antioxidant enzymes are also reflected in isolated AM and type II cells. Since these lung cells do not display a decreased sensitivities toward an in vitro NO2 exposure, overall increase in antioxidant enzyme activities do not seem to play the most pivotal role in controlling cellular NO2 sensitivity and oxidant defence. Combined data from biochemical, morphological, and morphometric analyses of lungs and lung cells suggest that lung cell and tissue oxidant sensitivity and defence largely depends on the cell and tissue organisation, i.e., cell numbers and morphology as well as the ratio of surface area to cytoplasmic volume.

Adaptation of rat type II pneumocytes to NO2: effects of NO2 application mode on phosphatidylcholine metabolism

Previous studies have shown that nitrogen dioxide (NO2) inhalation affects the extracellular surfactant as well as the structure and function of type II pneumocytes. Since in these studies there were great variabilities in oxidant concentration, duration of exposure, and mode of NO2 application, we evaluated the influence of the NO2 application mode on the phospholipid metabolism of type II pneumocytes. Rats were exposed to identical NO2 body doses (720 ppm x h), which were applied continuously (10 ppm for 3 d), intermittently (10 ppm for 8 h per day, for 9 d), and repeatedly (10 ppm for 3 d, 28 d rest, and then 10 ppm for 3 d). Immediately after exposure, type II cells were isolated and evaluated for cell yield, vitality, phosphatidylcholine (PC) synthesis, and secretion. Type II pneumocyte cell yield from animals that had been continuously exposed to NO2 was significantly increased, whereas intermittently and repeatedly treated rats exhibited cell yields that were nonsignificantly enhanced. Vitality of the isolated type II pneumocytes was not affected by the NO2 exposure modes. Continuous application of 720 ppm x h NO2 resulted in increased activity of the cytidine-5-diphosphate (CDP)-choline pathway. After continuous NO2 application, specific activity of choline kinase, cytidine triphosphate (CTP):cholinephosphate cytidylyltransferase, uptake of choline, and pool sizes of CDP-choline and PC were significantly increased over those of controls. Intermittent application of this NO2 body dose also provoked an increase in PC synthesis, but this increase was less prominent than after continuous exposure. After repeated exposure, the synthesis parameters were comparable to those for cells from control animals. Whereas PC synthesis in type II cells was obviously stimulated by NO2, the secretory activity of the cells was reduced. Continuous exposure reduced this activity most, whereas intermittent exposure nonsignificantly reduced this activity as compared with that of controls. The repeated application of NO2 produced no differences. We conclude that type II pneumocytes adapt to NO2 atmospheres depending on the mode of its application, at least for the metabolism of PC and its secretion from isolated type II pneumocytes. Further studies are necessary to determine whether additional metabolic activities will also adapt to NO2 atmospheres, and if these observations are specific for NO2 or represent effects generally due to oxidants.

Effect of zinc on lipid peroxidation and antioxidant enzymes in hepatic and brain tissues of chick embryos

Chick embryos were treated with different concentrations (25 and 75 mumoles/kg egg wt.) of zinc on the 14th day of embryonic development. The levels of thiobarbuturic acid reacting substances (TBARS), glutathione (GSH) and activity levels of antioxidant enzymes such as glutathione peroxidase (GPx), glutathione reductase (GR), glutathione-S-transferase (GST), superoxide dismutase (SOD) and catalase were measured in both hepatic and brain tissues after different time intervals (24 h, 72 h and 120 h) of zinc exposure. Increased levels of TBARS were observed after 24 h of zinc treatment and thereafter (72 h and 120 h) the levels were decreased in both the tissues. Significant induction was observed in antioxidant enzyme activities in both the tissues after 24 h and 72 h when compared to 120 h. However, the GSH levels were increased at 24 h and 72 h and thereafter decreased in both the tissues at 120 h. The elevated levels of antioxidant enzymes at 24 h and 72 h may be responsible for the reduction of TBARS at 72 h and 120 h in developing chick embryos.

Nitrogen dioxide exposure activates gamma-glutamyl transferase gene expression in rat lung

Exposure to nitrogen dioxide (NO2) has been shown to activate glutathione metabolism in lung and lung lavage. Since GGT is a key enzyme in glutathione metabolism and we have previously characterized GGT expression in distal lung epithelium and in lung surfactant, we examined the NO2 exposed lung for induction of gamma-glutamyl transferase (GGT) mRNA, protein, and enzyme activity. We found that the GGT gene product is induced in lung by NO2. The GGT mRNA level in lung increases 2-fold within 6 hr and 3-fold after 24 hr of exposure to this oxidant gas, and this 3-fold elevation persists even after 14 days of exposure. The pattern of GGT mRNA expression switches from the single GGT mRNA III transcript in the normal lung to the dual expression of GGT mRNA I and mRNA III. Enzyme activity in whole lung increases 1.6- to 2.5-fold while extracellular surfactant-associated GGT activity accumulates 5.5-fold and GGT protein accumulates in lung surfactant. Induction of GGT mRNA and protein is evident in cells of the bronchioles by in situ hybridization and immunolocalization, respectively. In contrast, alveolar type 2 cells lack an in situ hybridization signal and exhibit a reduction in the intensity of immunostaining with prolonged exposure. Our studies show that NO2 induces GGT mRNA expression, including GGT mRNA1, in lung and GGT protein and enzyme activity in lung and lung lavage in response to the oxidative stress of NO2 inhalation.

Effect of subchronic in vivo exposure to nitrogen dioxide on lung tissue inflammation, airway microvascular leakage, and in vitro bronchial muscle responsiveness in rats

OBJECTIVES

In a previous study on bronchoalveolar lavage fluid from rats exposed in vivo for seven days to 10 ppm nitrogen dioxide (NO2), it has been shown that there is an influx of macrophages into the airways. The present study investigated the effect of seven day exposure to 10 ppm NO2, on: (a) lung tissue inflammation and morphology; (b) airway microvascular leakage; (c) in vitro contractile response of main bronchi.

METHODS

Lung tissue was studied by light microscopy, after fixing the lungs by inflation with 4% formalin at a pressure of 20 cm H2O. Microvascular leakage was measured by extravasation of Evans blue dye in the larynx, trachea, main bronchi, and intrapulmonary airways. Smooth muscle responsiveness was evaluated by concentration-responses curves to acetylcholine (10(-9)-10(-3) M), serotonin (10(-9)-10(-4) M), and voltage-response curves (12-28 V) to electrical field stimulation.

RESULTS

Histology showed an increased total inflammation at the level of respiratory bronchioles and alveoli. No influx of inflammatory cells was found in the main bronchi. A loss of cilia in the epithelium of small airways and ectasia of alveolar capillaries was also found. By contrast, no alterations to microvascular permeability or modification of bronchial smooth muscle responsiveness was found.

CONCLUSIONS

Subchronic exposure to 10 ppm NO2 causes airway inflammation and structural damage, but does not cause any persistent alteration to microvascular permeability or bronchial smooth muscle responsiveness in rats.

Suppression of the hydrazine-induced formation of megamitochondria in the rat liver by coenzyme Q10

The effects of coenzyme Q10 (CoQ10) on the hydrazine-induced changes in the structure of mitochondria and those in antioxidant systems of the liver were investigated using rats as experimental animals. Animals were placed on a powdered diet containing 1.0% hydrazine for 7-8 days in the presence or absence of the combined treatment with CoQ10. Results obtained were as follows: (a) treatment of animals with CoQ10 prevented the hydrazine-induced formation of megamitochondria in the liver; (b) changes observed in the liver of the hydrazine-treated animals in comparison to the control were increases in the contents of alpha-tocopherol and CoQ analogs, increases in the levels of lipid peroxidation, decreases in the level of reduced glutathione with increases in that of oxidized glutathione, and increases in the ratio of unsaturated to saturated fatty acids in phospholipid domains of mitochondrial membranes; and (c) administration of CoQ10 to hydrazine-treated animals suppressed enhanced lipid peroxidation and improved lowered adenosine diphosphate/O ratios of mitochondria. The present data suggest that CoQ10 suppresses the hydrazine-induced formation of megamitochondria by scavenging free radicals generated from hydrazine and its metabolites.

The role of free radicals and antioxidants: how do we know that they are working?

This review briefly discusses how free radicals are formed and the possible participation of free radicals in disease. The review describes the basic radical reactions and the types of products that are formed from the free-radical reactions of cellular constituents. In many cases, in vivo free-radical oxidation can be detected by measuring products that were derived from radical reactions. Since aerobic organisms generate oxygen-containing free radicals during oxygen metabolism, they carry chemicals and enzymes that reduce the threat posed by these radicals. The more common sources of in vivo free radicals are described in the article as well as the methods used by cells to protect themselves from free-radical damage. Generation of free radicals in vivo also may be the result of exposure to certain chemical agents present in the environment. Many of these agents cause pathologic changes to the exposed tissues and organs by initiating free-radical reactions.

Diffuse alveolar damage in the rat lung after short and long term exposure to nitrogen dioxide

In order to quantify parenchymal, vascular and epithelial changes occurring in the exudative and organizing phase of diffuse alveolar damage (DAD) induced by inhaled NO2 groups of 7 rats were continuously exposed to 5, 10 or 20 ppm NO2 for 3 and 25 days alternatively. AgNOR analysis revealed the highest proliferative activity in the epithelium of the respiratory bronchioles. In this region already after 3d exposure to 5 ppm the maximum AgNOR number was reached. In contrast to long-term exposure after 3d exposure to 5 and 10 ppm NO2 the AgNOR number in the respiratory bronchioles was significantly higher than in central airway epithelia. After long-term exposure to 5 and 10 ppm AgNOR number decreased to normal values or showed no further significant increase, long-term exposure to 20 ppm resulted in a further increase of the AgNOR number. A significant increase of the alveolar circumference and decrease of alveolar surface density was found after an exposure to 20 ppm for 3d and long-term exposure to 10 and 20 ppm NO2, whereas the 5 ppm exposure groups disclosed no significant change of these values. Medial hypertrophy was detected after exposure to 10 and 20 ppm NO2 for 25 days, after the exposure to 5 ppm for 3d and 25d medial thickness was significantly decreased due to vasodilation induced by NO, one of the major reaction products of NO2.

Biochemical and histological alterations in rats after acute nitrogen dioxide intoxication

1. In previous studies a rat inhalation model was developed to investigate the treatment of acute nitrogen dioxide (NO2) intoxication. 2. Biochemical parameters, which may be important for the evaluation of lung injury and repair, were reviewed and compared with the histology. 3. After exposure to high NO2 concentrations (75 ppm, 125 ppm or 175 for 10 min) the lung injury observed by light microscope was most pronounced after 24 h and became worse with increasing concentration. 4. The most sensitive indicators for lung injury in the broncho-alveolar lavage fluid (BAL) were protein and albumin concentrations, angiotensin converting enzyme activity, beta-glucuronidase activity and the presence of neutrophil leucocytes. The changes observed in these variables were dose-dependent. Following exposure to 175 ppm the protein and albumin concentrations and the angiotensin converting enzyme activity showed a 100-fold increase, while the beta-glucuronidase activity showed a 10-fold increase. 5. Glucose-6-phosphate dehydrogenase and glutathione peroxidase in the supernatant of lung homogenate and gamma-glutamyl transferase activity in BAL are likely to be the most practical parameters for monitoring the phase of repair because their activities were maximal at the moment histological changes were reduced in intensity. 6. Repair was almost complete 7 d following exposure.

"Activation" of alveolar leukocytes isolated from cats fed taurine-free diets

Taurine is a ubiquitous amino sulfonic acid in mammals, present in high concentrations in tissues, including those exposed to elevated levels of oxidants. Experiments were designed to examine the consequences of taurine deficiency on production of ROI in leukocytes isolated from the lungs and blood of cats fed taurine-deficient diets. Cats were maintained on taurine-free or taurine-supplemented diets for at least 12 months at which time taurine deficiency was evident. To analyze alveolar cells, lungs were lavaged to recover lung macrophages and PMNs. Lung lavage fluid from cats contained macrophages and PMNs, although taurine deficiency was associated with a decrease in the percentage of PMNs in the lungs. This is similar to our findings in blood that taurine deficiency reduced the proportion of PMNs. Taurine measurements revealed 2.1 +/- 1.6 mumol/g wet wt of taurine in the lungs from cats fed a taurine-deficient diet versus 8.3 +/- 2.6 in lungs from cats fed a diet supplemented with taurine (n = 16). The effects of taurine deficiency on the functional activity of lung macrophages and PMNs were analyzed including the production of ROI. Alveolar leukocytes from cats fed taurine-deficient diets produced more superoxide anion in response to phorbol myristate acetate than cats fed taurine supplemented diets. Similar results were obtained using a chemiluminescence assay. Using the highly specific H2O2 indicator dye, dichlorofluorescin, and flow cytometry we found that alveolar leukocytes made more H2O2 than cells from cats fed taurine-supplemented diets. Forty-two percent of the cells from cats fed a taurine-supplemented diet expressed class II antigens. In contrast, 72% of cells from the taurine-deficient cats expressed this antigen. We hypothesize that taurine functions to prevent terminal activation and release of cytotoxic mediators by lung macrophages. Thus, a deficiency of taurine will indeed cause an activation of leukocytes, as evidenced by our data which show an increase in ROI, as well as an increase in class II antigen.

Experimental studies on tumor promotion by nitrogen dioxide

The effects of nitrogen dioxide (NO2) on promotion of lung tumorigenesis induced by N-bis(2-hydroxypropyl) nitrosamine (BHPN) were investigated in male Wistar rats. In a preliminary study, the highest non-effective dose of BHPN was found to be 0.5 g per kg body weight. Rats were given a single intraperitoneal injection of BHPN at a dose of 0.5 g per kg body weight or saline at 6 weeks of age, and then exposed to clean air, 0.04 ppm, 0.4 ppm or 4 ppm of NO2 for 17 months, respectively. The incidence of pulmonary tumors in rats exposed to BHPN plus 4 ppm of NO2 was 12.5%; the tumors were adenomas and adenocarcinomas. Adenomas were found in 4 out of 40 rats (10%) and adenocarcinomas were found in 1 out of 40 rats (2.5%). The tumor incidence in the lungs of rats kept in BHPN plus clean air and BHPN plus 0.04 ppm of NO2 was 2.5% (1/40). In both groups adenomas were found. There was no significant difference in tumor incidence between animals exposed to BHPN plus clean air and to BHPN plus 4 ppm of NO2. No lung tumors were found in the group of BHPN plus 0.4 ppm NO2 and in animals exposed to NO2 without BHPN treatment. A high incidence of alveolar cell hyperplasia was observed in the lungs of rats injected with BHPN, and the effect of NO2 on development of alveolar cell hyperplasia was slight. On the other hand, marked bronchiolar mucosal hyperplasia was found in 17 out of 40 rats (42.5%) in the group of BHPN plus 4 ppm of NO2, and in 1 out of 40 rats (2.5%) in each of the group exposed to clean air, 0.04 ppm or 0.4 ppm of NO2 with BHPN treatment, respectively. The hyperplasia in lungs of rats exposed to 4 ppm of NO2 without BHPN treatment was slighter than that in lung of rat exposed to 4 ppm of NO2 with BHPN treatment. On the other hand, tumor incidence in the nasal cavity of rats in each of group exposed to clean air and NO2 with BHPN treatment was 97-100%. Incidence of tumors in other organs in the groups exposed to clean air and NO2 with and without BHPN treatment was very low, and NO2 had no effect on tumor development in the nasal cavity and other organs whether animals were treated with BHPN or not.(ABSTRACT TRUNCATED AT 400 WORDS)

Biochemical effects of combined gases of nitrogen dioxide and ozone. IV. Changes of lipid peroxidation and antioxidative protective systems in rat lungs upon life span exposure

Lipid peroxide production, antioxidant contents and activities of antioxidative protective enzymes were examined in lungs of rats exposed to clean air (control group), 0.05 ppm O3, 0.05 ppm O3 + 0.04 ppm NO2 and 0.05 ppm O3 + 0.4 ppm NO2 for 22 months. The results were compared with our previous data in rats exposed to 0.04 ppm NO2, 0.4 ppm NO2 and 4 ppm NO2 for their life span (Sagai et al., Toxicol. Appl. Pharmacol., 73, (1984) 444-456). TBA values used as an index of lipid peroxidation in the lungs were increased maximally at 9 months, but were decreased below control values in animals exposed for 18 and 22 months. Nonprotein sulfhydryl (NPSH) contents were increased maximally at 9 months, and after 18 and 22 months were decreased significantly below control values. Vitamin E (VE) contents showed a similar trend. On the other hand, enzyme activities of glucose-6-phosphate dehydrogenase (G6PD), 6-phosphogluconate dehydrogenase (6PGD), glutathione reductase (GR), glutathione peroxidase measured by using cumene hydroperoxide (cum.OOH) substrate (GPx-cum.OOH), glutathione peroxidase measured by using H2O2 as a substrate (GPx-H2O2), glutathione S-transferase (GSH-Tase) and superoxide dismutase (SOD) did not show any significant changes during this experiment. The results show that lipid peroxidation in lungs was increased synergistically by a combination of NO2 and O3 at ambient levels, and that the time of maximum lipid peroxide production was shorter than with NO2 alone. The protective ability against lipid peroxides was higher with increased lipid peroxide levels, but the inducibility was not maintained through a life span exposure to the combined gases. Additionally, two small adenomas were observed in 2 out of 18 rats in the 0.05 ppm O3 + 0.04 ppm NO2 group and a large adenoma was observed in 1 out of 18 animals in the 0.05 ppm + 0.4 ppm NO2 group exposed for 22 months.

Increased vitamin E content in the lung after ozone exposure: a possible mobilization in response to oxidative stress

Vitamin E (vE) is a biological free radical scavenger capable of providing antioxidant protection depending upon its tissue content. In previous studies, we observed that vE increased significantly in rat lungs after oxidant exposure, and we postulated that vE may be mobilized to the lung from other body sites under oxidative stress. To test this hypothesis, we fed Long-Evans rats either a vE-supplemented or a vE-deficient diet, injected them intraperitoneally with 14C-labeled vE, and then exposed half of each group to 0.5 ppm ozone (O3) for 5 days. After exposure, we determined vE content and label retention in lungs, liver, kidney, heart, brain, plasma, and white adipose tissue. Tissue vE content of all tissues generally reflected the dietary level, but labeled vE retention in all tissues was inversely related to tissue content, possibly reflecting a saturation of existing vE receptor sites in supplemented rats. Following O3 exposure, lung vE content increased significantly in supplemented rats and decreased in deficient rats, but the decrease was not statistically significant, and vE content remained unchanged in all other tissues of both dietary groups. Retention of 14C-labeled vE increased in all tissues of O3-exposed rats of both dietary groups, except in vE-deficient adipose tissue and vE-supplemented brain, where it decreased, and plasma, where it did not change. The marked increases in lung vE content and labeled vE retention of O3-exposed vE-supplemented rats support our hypothesis that vE may be mobilized to the lung in response to oxidative stress, providing that the vitamin is sufficiently available in other body sites.

Effects of in vitro ozone exposure on peroxidative damage, membrane leakage, and taurine content of rat alveolar macrophages

Rat alveolar macrophages (AM) were isolated by pulmonary lavage, allowed to adhere to a tissue culture flask, and then exposed to 0.45 +/- 0.05 ppm ozone. After exposures ranging from 0 to 60 min, the medium was decanted and cells were harvested. Cells were assayed for oxidant damage and media analyzed for leakage of intracellular components. Increasing length of exposure to ozone resulted in a decreased number of adherent AM and decreased cell viability. Resting and zymosan-stimulated chemiluminescence increased immediately after ozone exposure and reached a maximum at 15-30 min, then declined to initial levels after 60 min of ozone exposure. Lipid peroxidation and leakage of protein and K+ ions increased with increasing length of exposure to ozone, while leakage of reduced and oxidized glutathione increased through 30 min, then declined (reduced) or leveled off (oxidized). Activity of the Na+/K+ ATPase decreased with time while intracellular taurine concentration exhibited an initial rise, peaked at 30 min, and then returned to the untreated level. Leakage of taurine into the medium increased with time of exposure, suggesting that exposure of AM to ozone results in a shift from bound to free intracellular taurine. These data indicate that in vitro exposure of AM to ozone results in a time-dependent alteration of cell function, membrane integrity, and viability.

Biochemical changes in the rat lung and liver following intratracheal instillation of cadmium oxide

Acute biochemical changes in the rat lung and liver following intratracheal instillation of cadmium oxide (CdO) were observed at a dose of 5 micrograms Cd/rat to investigate the defense mechanism to Cd intoxication via airway. In the lung metallothionein (MT) was induced, reaching a maximum at 2 days. A slight increase in reduced glutathione (GSH) concentration was observed at 4 days. The activity of glucose-6-phosphate dehydrogenase (G6PDH) was increased and superoxide dismutase (SOD) activity was slightly decreased, but glutathione peroxidase (GPx) and glutathione reductase (GR) activities were not changed. These observations suggested that MT played a key role in detoxification of instilled CdO, but that the antioxidant enzymes had a minimal role. In the liver MT and GSH concentrations were diminished 7 h after instillation and returned to their control levels. Hepatic GPx activity was increased 1 day after instillation and the significantly elevated level lasted up to 7 days, while hepatic GR activity was decreased. These hepatic biochemical changes are suggested to be due to the secondary effects of the lung injury.

Biochemical effects of combined gases of nitrogen dioxide and ozone. III. Synergistic effects on lipid peroxidation and antioxidative protective systems in the lungs of rats and guinea pigs

Rats and guinea pigs were exposed continuously to 0.4 ppm NO2, 0.4 ppm O3 or a combination of the two gases for 2 weeks. The concentration of lipid peroxides in lungs of rats and guinea pigs exposed to NO2 alone or O3 alone did not change. The lipid peroxide level of rats inhaling the combined gases also did not change. However, the level of lipid peroxides in guinea pigs exposed to a combination of the two gases was increased to 2.2 times of the control level, showing a synergistic interaction. No increases of antioxidative protective enzyme activities and of antioxidants (such as NPSH, VE, VC) in guinea pigs exposed to NO2, O3 or the combined gases were found. In rats, no changes in enzyme activities and of the antioxidant contents were observed after NO2 alone, but O3 exposure produced slight increases of NPSH, VC, and GPx-H2O2. On the other hand, in rats exposed to the combined gases, marked synergistic increased of many antioxidative factors such as NPSH, VC, G6PD, GPx-cum.OOH and GPx-H2O2 were found. The results show that those animals which are able to increase antioxidative protective factors in the lung following exposure to the combined gases do not respond with a significant increase in lipid peroxides. On the other hand, in animals with poor induction-ability of these factors lipid peroxides are formed. This might explain why guinea pigs were the most sensitive to the effects of the combined gases. Furthermore, it was shown that in guinea pigs the increased level of lipid peroxides and that in rats the increased activities of antioxidative enzymes and the increased contents of the antioxidants were synergistic following exposure to the combined gases.

Effects of nitrogen dioxide and ozone in combination on xenobiotic metabolizing activities of rat lungs

Male Jcl:Wistar rats were exposed continuously to 0.2 ppm ozone (O3) and 4 ppm nitrogen dioxide (NO2), alone and in combination, for 1 and 2 months to examine the effects of combined gas on the xenobiotic metabolizing systems of lung microsomes. The cytochrome P-450 content increased to 200% and 253% of the control values during 2-month exposures to O3, while it was not increased by NO2 exposures. Addition of NO2 to O3 reduced the increased level of cytochrome P-450 to 179% and 178% of the control values. The activities of cytochrome P-450-dependent monooxygenase, benzo[a]pyrene hydroxylase and 7-ethoxycoumarin O-deethylase were changed in the same fashion by exposures to NO2 and O3. The 7-ethoxycoumarin O-deethylase activity was increased to 147% and 142% of the control values by O3 exposure, whereas it was decreased to 71% and 75% of the control values by NO2 exposures. This activity was decreased to 124% and 97% of the control values by combination of O3 with NO2 after 1 and 2 months, respectively. Similarly, the benzo[a]pyrene hydroxylase activity was increased to 157% and 153% of the control values during O3 exposures, while it was not changed by NO2 exposures. Addition of NO2 to O3 reduced the activity to 140% and 115% of the control values after 1 and 2 months, respectively. The alteration of coumarin hydroxylase activity was different from those of others. This activity decreased to 44% and 29% of the control values after 1- and 2-month exposures to NO2, respectively, and was also decreased by O3 exposures. However, the magnitude of decrease was not reinforced by combination of NO2 with O3. These results indicate that an increased level of xenobiotic metabolizing activity produced by O3 exposures is lowered by combination with NO2. These phenomena may be antagonistic effects of these gases on the xenobiotic metabolizing systems of lung microsomes.

A selective decrease in the xenobiotic metabolizing activity of rat lungs by nitrogen dioxide exposures

Groups of male Wistar rats were continuously exposed to nitrogen dioxide (NO2) ranging from 1.2 to 15 ppm for 1 or 2 weeks to examine the dose-effect relationship between NO2 and the xenobiotic metabolizing activity of lung microsomes. The lung cytochrome P-450 decreased significantly after 1-week exposures to 10 and 15 ppm NO2 and showed a decreasing tendency after 2-week exposures to 6-10 ppm NO2. On the other hand, the cytochrome b5, NADPH-cytochrome P-450 reductase and NADH-cytochrome b5 reductase of lung microsomes were increased concomitant with increase in microsomal proteins during 2-week exposures to 6-10 ppm NO2. These results show that the lung cytochrome P-450 decreases preferentially upon exposure to NO2 at higher concentrations. The coumarin hydroxylase activity was the most sensitive to NO2 exposures among activities metabolizing 4 kinds of xenobiotics examined. The coumarin hydroxylase activity was decreased in a dose-dependent fashion to 67-10% of the control level by 2-week exposures to 1.2-6 ppm NO2 and became negligible at 10 ppm NO2. The 7-ethoxycoumarin O-deethylase activity was also decreased to 82-56% of the control level by 2-week exposures to 1.2-6 ppm NO2 and became a constantly reduced level at 10 ppm NO2. The benzo[a]pyrene hydroxylase activity was decreased by exposures to NO2 above 10 ppm, and the benzphetamine N-demethylase activity also decreased during 2-week exposures to 6-10 ppm NO2. These results indicate that exposures to NO2 above 1.2 ppm cause a consistent and preferential reduction in the activities of coumarin hydroxylase and 7-ethoxycoumarin O-deethylase of lung microsomes in a dose-dependent manner.

Protective effect of beta-naphthoflavone against NO2 toxicity in mice with genetically inducible lung cytochrome P450

The effects of the cytochrome P450 inducer beta-naphthoflavone (BNF) on NO2 toxicity were studied in two strains of mice. In one strain (C57B1/6J), cytochrome P450 could be induced by the aromatic hydrocarbon, while in the other strain (DBA/2J) cytochrome P450 was not inducible by this compound. Mice were treated with BNF before and during 4 days of exposure to 20 ppm NO2. The body growth of NO2-exposed mice improved only in BNF-treated C57B1/6J mice. In this strain, BNF reduced both pulmonary edema (as measured by wet and dry lung weights or as assessed by histological studies) and lung peroxidation (as measured by malondialdehyde). This protective effect of BNF on NO2 toxicity in C57B1/6J mice was associated with an increase in the components of the cytochrome P450 system (cytochrome P450 and cytochrome b5), whereas the activities of pulmonary antioxidant enzymes (superoxide dismutase, glutathione peroxidase, and glutathione reductase) were not significantly increased. These data suggest that the induction of the cytochrome P450 system may be important in promoting NO2 tolerance in those strains of mice in which the cytochrome P450 system is genetically inducible.

Biochemical effects on combined gases of nitrogen dioxide and ozone. I. Species differences of lipid peroxides and phospholipids in lungs

In the present study, changes of lipid peroxides, phospholipids and antioxidant levels in lungs of 4 animal species exposed to the combined gases of NO2 and O3 were compared. Male mice, hamsters, rats and guinea pigs were used. Lipid peroxides were increased significantly in the lungs of mice and guinea pigs exposed to the combined gases, but not in hamsters and rats. Changes of alpha-tocopherol (VE) contents were slight. On the other hand, non-protein sulfhydryl (NPSH) contents were increased strikingly, especially in hamsters, but were not increased in guinea pigs. Phosphatidylcholine (PC) contents were increased and phosphatidylethanolamine (PE) contents were decreased by the exposure to the combined gases, with the order guinea pig greater than mouse greater than rat. In hamsters no changes were seen. The changes of fatty acid composition in guinea pigs and mice were marked, the increases of palmitate and palmitolate and the decreases of polyunsaturated fatty acid were especially characteristic. These changes in phospholipid class and fatty acid composition may be a "a kind of adaptation phenomenon" to avoid further lipid peroxidation. On the other hand, the changes in hamsters and rats were small. The results show the existence of species differences in lipid peroxide formation by exposure to the combined gases of NO2 and O3. They were found to be related to the contents of antioxidants and the compositions of phospholipids and their fatty acids.

Influence of polyunsaturated fatty acid supplementation and membrane fluidity on ozone and nitrogen dioxide sensitivity of rat alveolar macrophages

The phospholipid polyunsaturated fatty acid (PUFA) content and the membrane fluidity of rat alveolar macrophages were modified dose-dependently and in different ways. This was done to study the importance of both membrane characteristics for the cellular sensitivity toward ozone and nitrogen dioxide. Cells preincubated with arachidonic acid (20:4) complexed to bovine serum albumin (BSA) demonstrated an increased in vitro sensitivity versus ozone and nitrogen dioxide. The phenomenon was only observed at the highest 20:4 concentrations tested, whereas the membrane fluidity of the 20:4-treated cells already showed a maximum increase at lower preincubation concentrations. Hence it could be concluded that the increased ozone and nitrogen dioxide sensitivity of PUFA-enriched cells is not caused by their increased membrane fluidity, resulting in an increased accessibility of sensitive cellular fatty acid moieties or amino acid residues. This conclusion receives further support from other observations. These results strongly support the involvement of lipid oxidation in the mechanism(s) of toxic action of both ozone and nitrogen dioxide in an intact cell system.

Toxicity of ozone and nitrogen dioxide to alveolar macrophages: comparative study revealing differences in their mechanism of toxic action

The toxicity of ozone and nitrogen dioxide is generally ascribed to their oxidative potential. In this study their toxic mechanism of action was compared using an intact cell model. Rat alveolar macrophages were exposed by means of gas diffusion through a Teflon film. In this in vitro system, ozone appeared to be 10 times more toxic than nitrogen dioxide. alpha-Tocopherol protected equally well against ozone and nitrogen dioxide. It was demonstrated that alpha-tocopherol provided its protection by its action as a radical scavenger and not by its stabilizing structural membrane effect, as (1) concentrations of alpha-tocopherol that already provided optimal protection against ozone and nitrogen dioxide did not influence the membrane fluidity of alveolar macrophages and (2) neither one of the structural alpha-tocopherol analogs tested (phytol and the methyl ether of alpha-tocopherol) could provide a protection against ozone or nitrogen dioxide comparable to the one provided by alpha-tocopherol. It was concluded that reactive intermediates scavenged by alpha-tocopherol are important in the toxic mechanism of both ozone and nitrogen dioxide induced cell damage. However, further results presented strongly confirmed that the kind of radicals and/or reactive intermediates, and thus the toxic reaction mechanism involved, must be different in ozone- and nitrogen dioxide-induced cell damage. This was concluded from the observations that showed that (1) vitamin C provided significantly better protection against nitrogen dioxide than against an equally toxic dose of ozone, (2) glutathione depletion affected the cellular sensitivity toward ozone to a significantly greater extent than the sensitivity towards nitrogen dioxide, and (3) the scavenging action of alpha-tocopherol was accompanied by a significantly greater reduction in its cellular level during nitrogen dioxide exposure than during exposure to ozone. One of the possibilities compatible with the results presented in this study might be that lipid (peroxyl) free radicals formed in a radical-mediated peroxidative pathway, resulting in a substantial breakdown of cellular alpha-tocopherol, are involved in nitrogen dioxide-induced cell damage, and that lipid ozonides, scavenged by alpha-tocopherol as well, are involved in ozone-induced cell damage.

Sex-related differences in NADPH-dependent lipid peroxidation induced by cadmium

Male and female rats were dosed once a day for 2 days with injections of 1.5 mg Cd/kg. Formation of thiobarbituric acid reactive substances (TBA-RS) was significantly increased in male rat liver but not in the females. NADPH-dependent lipid peroxidation in vitro in microsomes derived from untreated rat liver was greater in males than in females. Furthermore, addition of cadmium (Cd) to microsomes isolated from male rat liver produced a dose-dependent potentiation of NADPH-dependent lipid peroxidation from low concentrations of Cd. In microsomes derived from females a significant increase in lipid peroxidation was observed only at high Cd concentrations. NADPH-dependent lipid peroxidation enhanced by Cd was greater in the males than in the females. These data suggest that a sex-related difference in the ability of Cd to induce lipid peroxidation in vivo in rat liver appears to be mediated partly through differences in hepatic microsomal NADPH-dependent lipid peroxidation.

Effects of 50 ppm NO2 gas exposure on physiological functions of rats

When rats were exposed to 50 ppm NO2 gas for 36 h, remarkable changes in some biochemical levels compared with those of control rats were observed. Namely, levels of total cholesterol, ester cholesterol, total lipids, triglycerides, nitrogen of urea, uric acid, glutamic-oxaloacetic transaminase (GOT), glutamic-pyruvic transaminase (GPT), lactate dehydrogenase (LDH), alkaline phosphatase (ALP) and cytochrome P-450 of the exposed rats were decidedly different from those of the control rats. Thus, it was suggested that functions of liver are acutely injured upon exposure to 50 ppm NO2 gas, although extensive pulmonary injury resulting from such an exposure may also be responsible for some of the abnormal serum values.

The effect of lung alpha-tocopherol content on the acute toxicity of nitrogen dioxide

The effect of lung vitamin E content on early direct damage to lung by NO2 was studied by exposing three groups of rats differing in lung vitamin E content to 0, 10, 20, 30, and 40 ppm NO2 for 4 hr. Lung vitamin E contents of 3.24, 17.4, and 87.7 micrograms/lung were obtained by maintaining animals on semipurified diets containing 0, 10, or 1000 mg/kg of d-alpha-tocopherol acetate. Animals were sacrificed immediately after the 4-hr exposure and lung damage was assessed by assaying the lung lavage content of protein, sialic acid, lactate dehydrogenase (LDH), malate dehydrogenase (MDH), glucose-6-phosphate dehydrogenase (GDH), acid phosphatase (AP), and aryl sulfatase (AS), all of which increase in lavage fluid in a concentration-dependent manner over the range of NO2 concentrations used. Increases in lavagable protein, sialic acid, AP, and AS were not affected by the different vitamin E contents, while the increases in LDH, MDH, and GDH were significantly attenuated in the 1000-mg/kg diet group relative to the 0- and 10-mg/kg diet groups. Lipid peroxidation was not detectable in NO2-exposed lungs by either conjugated diene measurement or thiobarbituric-acid-reactive materials, with the exception of a slight increase in thiobarbituric-acid-reactive material in free cells. These results suggest two mechanisms of NO2 damage to lung. The attenuation of the appearance of some lavage parameters by high vitamin E is consistent with lipid peroxidation as a necessary event in the damage responsible for their appearance, although the lack of change in indicators of lipid peroxidation in the whole lung suggests that peroxidation occurs to only a very limited extent. The lavage parameters which are unaffected by lung vitamin E content apparently appear in airways as a result of events not involving lipid peroxidation.

Detection of in vivo lipid peroxidation using the thiobarbituric acid assay for lipid hydroperoxides

Thiobarbituric acid (TBA) assays which have been modified for detection of lipid hydroperoxides appear to be useful for demonstration of in vivo lipid peroxidation. Since these methods require heating tissue membranes with the buffered TBA, there is a possibility of interference from the detection of autoxidation that occurs during heating. These studies were undertaken to investigate conditions which favor TBA color production from hydroperoxide while limiting autoxidation during the assay. An acetic acid-sodium acetate buffered (pH 3.6) TBA assay was used. Heating linoleic acid hydroperoxide with 50 microM ferric iron or under nitrogen nearly doubled color production compared to heating it with no added iron or under air. The lipid antioxidant butylated hydroxytoluene inhibited color production from fatty acid hydroperoxides. When tissue fractions, including liver and lung microsomes and lung whole membranes, were heated in the assay, color production was greater under air than under nitrogen and was much greater under oxygen. When liver microsomes from carbon tetrachloride-exposed rats were used, color was increased only when oxygen was present in the heating atmosphere. The results with tissue fractions appear to demonstrate autoxidation during color development rather than the presence of preformed hydroperoxides. Finally, it was found that color production from membrane fractions was dependent on the vitamin E content of the membranes. It appears that autoxidation during heating should be limited by heating under nitrogen and not by adding antioxidants, which inhibit color production from hydroperoxides. As the vitamin E effect demonstrates, antioxidant status must be considered, since a change in color production could result from a change in antioxidant content without the accumulation of lipid hydroperoxides.

Activation and increment of alveolar macrophages induced by nitrogen dioxide

Male Wistar rats were exposed to 4 ppm nitrogen dioxide (NO2) for 10 d, and at intervals alveolar macrophages were collected by pulmonary lavage. A metabolic enhancement of alveolar macrophages was observed on d 4 of exposure. The specific activities of glucose-6-phosphate dehydrogenase and glutathione peroxidase of the peroxidative metabolic pathway increased to 1.29-fold (p less than 0.001) and 1.17-fold (p less than 0.05) those of the control values, respectively. The specific activities of succinate-cytochrome c reductase of the mitochondrial respiratory system and pyruvate kinase of the glycolytic pathway also increased to 1.17-fold (p less than 0.01) and 1.20-fold (p less than 0.01) those of the control values, respectively. In addition, the incorporation of [3H]leucine and [14C]thymidine into alveolar macrophages were elevated to 1.77-fold (p less than 0.001) and 1.84-fold (p less than 0.01) those of the control values, respectively. The activities of all enzymes tested decreased to control levels by d 10. The number of alveolar macrophages collected from exposed animals increased to 1.24-fold (p less than 0.01) that of the control value on d 7 and was maintained at a significantly higher level until d 10. Alveolar macrophages were heterogeneous in size (7-21 micron in diameter), and most of them were distributed between 11 and 17 micron in diameter. Exposures to 4 ppm NO2 increased significantly the cells of 9-13 micron in diameter on the seventh day. These results show that exposures to 4 ppm NO2 cause a metabolic enhancement and subsequent increase in alveolar macrophages.

In vivo effects of nitrogen dioxide and ozone on xenobiotic metabolizing systems of rat lungs

Male Jcl:Wistar rats were exposed continuously to either ozone (O3) or nitrogen dioxide (NO2) for 7 and 14 days to examine the effects of these gases on the xenobiotic metabolizing systems of lung microsomes. Exposure to 0.2 and 0.4 ppm O3 increased NADPH-cytochrome P-450 reductase activity and cytochrome P-450 as well as microsomal protein by the 14th day, whereas NADH-cytochrome b5 reductase was not affected. The most marked increase was observed in cytochrome P-450. In parallel to this increment, the activities of benzo(a)pyrene hydroxylase and 7-ethoxycoumarin O-deethylase of exposed animals increased significantly on the 7th and 14th days of exposure to 0.2 and 0.4 ppm 03. In contrast, exposure to 1.2 and 4 ppm NO2 decreased cytochrome P-450 on the 7th day. Moreover, the 7-ethoxycoumarin O-deethylase activity in exposed animals decreased to 61% (P less than 0.05) and 74% (P less than 0.001) of control on the 7th and 14th days of exposure to 4 ppm NO2, respectively. This decrease occurred in a dose-dependent manner with exposure to 0.4-4.0 ppm NO2, whilst benzo(a)pyrene hydroxylase activity was not affected. These results show that O3 at low doses induces xenobiotic metabolizing activities in the lung, whereas NO2 reduces this.

An increase in the activities of glycolytic enzymes in rat lungs produced by nitrogen dioxide

Male Jcl: Wistar rats were exposed to 2, 4, and 10 ppm NO2 for 14, 10, and 7 d, respectively, to examine the effect of NO2 on the lung glycolytic pathway, a major energy-generating system in the lung. A highly significant increase in the activities of hexokinase, phosphofructokinase, 3-phosphoglycerate kinase, pyruvate kinase (PK), and lactate dehydrogenase was observed after 5 d exposure to 10 ppm NO2, and a significantly higher value was maintained until d 7. Similarly, the activities of all enzymes examined increased significantly by exposure to 4 ppm NO2, reaching the maximum between 4 and 7 d of exposure, and then approached to near the control levels. The most remarkable increase was found in the PK activity, which reached 1.82- (p less than 0.001) and 1.53-fold (p less than 0.001) that of the control at d 5 (10 ppm) and d 7 (4 ppm) of exposure, respectively. Upon exposure to 2 ppm NO2, the PK activity of exposed animals was also increased to 1.23-fold (p less than 0.05) that of the control at d 7, and a higher activity was maintained until d 14. The glucose-6-phosphate dehydrogenase activity of exposed animals increased significantly at d 3, 4, and 14 of exposures to 10, 4, and 2 ppm NO2, respectively, and a significantly higher value was maintained in the following period of exposure. These results show that short-term exposure of rats to 2-10 ppm NO2 induces the pulmonary systems concerning glycolysis and NADPH-generation. The generation of energy and NADPH in the lung may be enhanced by NO2 inhalation.

Studies on the biochemical effects of nitrogen dioxide. IV. Relation between the change of lipid peroxidation and the antioxidative protective system in rat lungs upon life span exposure to low levels of NO2

This study examined the relation between lipid peroxidation and the antioxidative protective system in lungs of rats exposed to low levels of nitrogen dioxide (NO2). JCL:male Wistar rats were exposed to 0, 0.04, 0.4, and 4 ppm NO2 for 9, 18, and 27 months. Lipid peroxidation measured by TBA method, increased significantly in the 4 ppm NO2 group of the 9-month exposure and in the 0.4 and 4 ppm NO2 groups of the 18-month exposure. The activity of glutathione peroxidase measured with hydrogen peroxide as substrate decreased significantly in the 4 ppm NO2 group of the 9-month exposure and in the 0.4 and 4 ppm NO2 groups of the 18-month exposure. Furthermore, the activities of two glutathione S-transferases, aryl and aralkyl S-transferase, also decreased in the 0.4 and 4 ppm NO2 groups of the 18-month exposure, but not in any groups of the 9-month exposure. The activity of glutathione peroxidase measured with cumene hydroperoxide as substrate did not show any significant changes in any NO2 group. The activities of glucose-6-phosphate dehydrogenase and glutathione reductase were significantly higher than those in the control group for the 9-month exposure. In the 18-month exposure, however, they showed a tendency to return to control level. The activities of superoxide dismutase and disulfide reductase upon NO2 exposure for 9 and 18 months were not different from control values. To confirm that lipid peroxidation was increased with greater NO2 concentrations and exposure times, ethane and pentane exhalation in breath as an index of lipid peroxidation was examined. Ethane exhalation increased significantly following 0.04, 0.4, and 4 ppm NO2 exposure for 9 and 18 months. Furthermore, ethane formation of rats exposed to 0.04 and 0.4 ppm NO2 for 27 months also increased to twice the control level. On the other hand, after exposure to 4 ppm NO2 for 27 months, ethane levels returned to control level. Pentane formation increased significantly only in the 0.04 and 0.4 ppm groups in the 18-month exposure. Ethane exhalation in rats exposed to 0.04, 0.12, and 0.4 ppm NO2 for 9 and 18 months was similar. These results suggested that the antioxidative protective ability was decreased with prolonged exposure, while formation of cytotoxic lipid peroxides was increased.(ABSTRACT TRUNCATED AT 400 WORDS)

Toxicological data on NOx: an overview

This overview is based on experimental and epidemiological studies of NOx toxicity during the past decade. Approximately 130 published studies are cited and about one-fourth of these are discussed briefly under one of the following headings: acute and subacute studies, chronic low-level studies, human studies, and special studies. The latter section examines a selection of comparatively unique investigations, including several devoted to the pulmonary uptake and retention of NO2, and several examining the potential tumorigenicity of NO2. For each major section of the overview, a critical evaluation is attempted in terms of the impact of the appropriate studies on the extant NOx toxicological data base and on the current and planned air quality standards for NOx.

Effects of nitrogen dioxide exposure on prostacyclin synthesis in lung and thromboxane A2 synthesis in platelets in rats

Effects of nitrogen dioxide (NO2) exposure on prostacyclin (PGI2) synthesis in the rat lung and thromboxane A2 (TXA2) synthesis in the platelets were studied. Male Wistar rats were exposed to 10 ppm NO2 for 1, 3, 5, 7 and 14 days. PGI2 synthesizing activity of homogenized lung decreased. The damage of PGI2 synthesizing activity reaches its maximum at 3 days. At 14 days, PGI2 synthesizing activity returned to the normal level. The activity of PGI2 synthetase decreased significantly. The formation of lipid peroxides due to NO2 exposure may cause the depression of PGI2 synthesizing activity of lung. On the other hand, platelet TXA2 synthesizing activity increased. This increased TXA2 synthesizing activity lasted at least till 3 days. Then, it returned to the normal level. The counts of platelet were decreased significantly by 1, 3, 5 and 7 days NO2 exposure. Then the decreased counts of platelet returned to the normal level at 14 days NO2 exposure. These results indicate that the depression of PGI2 synthesizing activity of lung by NO2 exposure cause an increase in TXA2 synthesizing activity of platelets. It may contribute to induce platelet aggregation and to the observed decrease in the number of platelets during NO2 exposure.

Biochemical studies on strain differences of mice in the susceptibility to nitrogen dioxide

Strain differences of mice in their susceptibility to nitrogen dioxide (NO2) were examined by measuring the activities of antioxidative protective enzymes, and the amounts of antioxidants and lipid peroxides in lungs. Four strains of mice: ICR, BALB/c, ddy and C57BL/6 were used in this study and their LC50 values after exposure to NO2 for 16 hr were: 38, 49, 51 and 64 ppm, respectively (1). Genetic strain differences were observed in the enzyme activities, the antioxidant contents and lipid peroxide contents among these four different strains. The activities of glutathione peroxidase (GPX), glutathione S-transferase, and superoxide dismutase (SOD), and the contents of non-protein sulfhydryls (NPSH), alpha-tocopherol (alpha-Toc) and total lipids in lungs of the four strains were related to their LC50, while TBA reactants in lungs of the four strains were inversely related to their LC50. After exposure to 20 ppm NO2 for 16 hr, the activities of the protective enzymes and the contents of NPSH decreased, while the level of alpha-Toc increased markedly. The activities of GPX, 6-phosphogluconate dehydrogenase, SOD and disulfide reductase, and the contents of NPSH, alpha-Toc and total lipids were also related to their LC50. On the other hand, TBA reactants increased higher than those of the control groups and were inversely related to their LC50. These results suggest that the protective enzymes and the antioxidants are important factors at defence mechanism in lungs to NO2 and that the intensity of the protective systems in pigmented strains is generally greater than that in albino strains.