Ozone does not react with human erythrocyte membrane lipids.

Ozone was applied to sealed red cell ghost membranes at the rate of 95 nmol/min for periods up to 20 min. Acetylcholine esterase, on the outer face of the membrane, was inhibited up to 20%. Glyceraldehyde-3-phosphate dehydrogenase, on the inner surface of the membrane, was inhibited up to 87%. These differences reflected the inherent susceptibilities of the two enzymes and the presence or absence of the membrane barrier. Analysis of the total lipids of the ozone-treated ghosts showed no significant change in the distribution of lipid classes and no significant change in the fatty acid composition. There was no significant change in the fatty acid composition of the phosphatidylcholine fraction. There was a slight increase in 18:0 and 20:2 + 20:3 in the phosphatidylethanolamine fraction. There was no change in the molecular species distribution of the phosphatidylcholine or the phosphatidylethanolamine fraction. There was no evidence for the formation of the phospholipid ozonolysis product, 1-acyl-2-(9-oxo-nonanyl) derivatives of glyceryl-phosphoryl choline. There was no decline in the amount of cholesterol in the lipids derived from ozone-treated red cell membranes. Treatment of red cell ghost membranes and, by implication, the plasma membrane of cells by ozone therefore oxidizes peripheral proteins before it oxidizes lipids.

Reaction of ozone with enzymes of erythrocyte membranes.

Ozone is a widespread component of polluted air. It is the cause of many adverse effects on the lung such as decreased athletic performance and exacerbation of asthma. Ozone inactivated acetylcholine esterase (AChE) both in intact washed human erythrocytes and in ghosts prepared from the erythrocytes. This is consistent (a) with the location of AChE on the outer face of the membrane and (b) with the change in structure of AChE when amino acids were oxidized. The glyceraldehyde-3-phosphate dehydrogenase (G3PDH) of intact washed erythrocytes was unaffected by ozone. However, ozone severely inactivated G3PDH of ghosts, much more severely than AChE in ghosts. This result raised questions about the relative permeability of intact erythrocytes and ghosts and also about the inherent susceptibility of the two enzymes. Inhibition of the ozone-treated erythrocyte AChE with the competitive inhibitor trimethyl-(p-aminophenyl) ammonium chloride was measured. The inhibited enzyme had a higher K(M) and slightly lower Vmax than the control. Ozone did not affect the K(M) of the uninhibited enzyme but decreased the K(M) of the inhibited enzyme. Ozone decreased the Vmax of both the inhibited and the uninhibited enzyme. The K(I) was unchanged by the treatment with ozone. This suggested that the active site of the enzyme was not affected by ozone, but other features of the protein were changed by ozone. The effects of products of lipid ozonolysis [hydrogen peroxide, nonanal, and 1-palmitoyl-2-(9-oxononanyl)-sn-3-glycerophosphorylcholine (PN1PC)] were tested on the ghost preparations. The ozonolysis products were tested at concentrations equivalent to calculated amounts that could have been produced by ozone. Hydrogen peroxide had no effect on the G3PDH and AChE. Nonanal slightly increased the permeability of the ghost membrane, as judged by the increase in rate of G3PDH in the absence of Triton X-100, but did not inhibit enzyme activity. PN1PC increased the permeability of the ghosts, as judged by the increase in rate of G3PDH in the absence of Triton X-100. There was also an increase in the activity of G3PDH in the presence of Triton X-100. AChE was not inhibited by ozone in the presence or absence of Triton X-100.

Activation of eicosanoid metabolism in human airway epithelial cells by ozonolysis products of membrane fatty acids.

Inhaled ozone can react with a variety of cellular macromolecules within the lung. Recent analyses of the chemistry of ozone reactions with unsaturated fatty acids, which are present in all membranes and in mucus in the airways, indicate that ozonolysis yields one aldehyde and one hydroxyhydroperoxide molecule for each molecule of ozone. The hydroxyhydroperoxide molecule is unstable in aqueous environments, and subsequently yields a second aldehyde and hydrogen peroxide. The structure of common unsaturated fatty acids is such that attack by ozone at the carbon-carbon double bonds will yield 3-, 6-, and 9-carbon saturated and unsaturated aldehydes and hydroxyhydroperoxide. This study examines the effects of ozonolysis products on eicosanoid metabolism in human airway epithelial cells. Eicosanoid biosynthesis is important in a wide array of pathophysiological responses in the airway, and the release of eicosanoids by the epithelial barrier is likely to be significant in diseases induced by environmental factors. Previously, we demonstrated that ozone can increase eicosanoid synthesis from airway epithelial cells exposed in vitro. Human exposures to concentrations of ozone below the current National Ambient Air Quality Standard (0.12 ppm, not to be exceeded for more than one hour once per year) also resulted in increased eicosanoids in bronchoalveolar lavage fluid. To determine whether ozonolysis products could activate eicosanoid release, we exposed human airway epithelial cells to 3-, 6-, and 9-carbon aldehydes, hydroxyhydroperoxides, and hydrogen peroxide. We measured (1) eicosanoid metabolism using high-performance liquid chromatography and radioimmunoassays, and (2) the effects of the aldehydes, hydroxyhydroperoxides, and hydrogen peroxide on cell lysis. Eicosanoid release increased after exposure to aldehyde; release induced by 9-carbon (nonanal) aldehyde was greater than that induced by the 6-carbon (hexanal) or 3-carbon (propanal) aldehydes. Hydroxyhydroperoxides induced greater eicosanoid release than the corresponding aldehydes of equivalent chain length. Again, the longer the aliphatic chain length of the hydroxyhydroperoxide the greater the effect. These effects were noted at concentrations of hydroxyhydroperoxide below those that produce cell lysis, and the time course of the two responses was dissimilar. Because hydroxyhydroperoxides can degrade into an aldehyde and hydrogen peroxide, it is conceivable that the effects observed were attributable to the formation of either hydrogen peroxide or hydrogen peroxide and aldehyde. This mechanism is unlikely, however, because the effects of hydroxyhydroperoxides on eicosanoid release were dependent on chain length, whereas each hydroxyhydroperoxide can produce only one hydrogen peroxide molecule. Although hydrogen peroxide alone also stimulated eicosanoid metabolism, this effect was not augmented when aldehyde and hydrogen peroxide were added together. In addition, the dose of hydroxyhydroperoxide needed to produce an effect (10 to 100 microM) was lower than that of hydrogen peroxide (300 microM). We could not fully evaluate the effects of the unsaturated aldehydes and hydroxyhydroperoxides. Although the 6-carbon and 9-carbon cis-3-aldehydes could be synthesized from the cis-3-alcohols, the resulting aldehydes were not chemically stable. The cis-3-aldehydes were useful for producing the corresponding 1-hydroxy-alkenyl-hydroperoxides of high purity. These results support the method selected for chemical synthesis, but further studies are required to establish proper storage and handling methods before these compounds can be tested in assays of eicosanoid metabolism.

Physical and chemical characterization of airbag effluents.

OBJECTIVE: This paper describes a study aimed at characterizing the exposure to physical and chemical by-products from the deployment of airbag restraint systems. DESIGN, MATERIALS AND METHODS: Specifically, the levels of particulates and the composition of gases and bag fabric speed were measured in the passenger compartment following deployment of either a driver's side or driver's side/passenger's side airbag system. MEASUREMENTS: A Fourier transform infrared analyzer (FTIR) and chemiluminescence analyzers were used for gas analysis, a cascade impactor and gravimetric filter measurements for aerosol determination and high-speed films to determine fabric speed. MAIN RESULTS AND CONCLUSIONS: The measured gases were found to be within the recommended guidelines for human exposures, but no guidelines exist for particle exposures of this magnitude (150-220 mg/m3) but short duration. High-speed films were also taken of the deployments to obtain an estimate of the fabric speed as it leaves the module. The maximum average speed for both types of airbag was approximately 100 mph and in both cases average speeds ranged from lows near 50 mph to highs of over 200 mph.

Airway epithelial cell responses to ozone injury.

The airway epithelial cells is an important target in ozone injury. Once activated, the airway epithelium responds in three phases. The initial, or immediate phase, involves activation of constitutive cells, often through direct covalent interactions including the formation of secondary ozonolysis products--hydroxyhydroperoxides, aldehydes, and hydrogen peroxide. Recently, we found hydroxyhydroperoxides to be potent agonists of bioactive eicosanoid formation by human airway epithelial cells in culture. Other probable immediate events include activation and inactivation of enzymes present on the epithelial surface (e.g., neutral endopeptidase). During the next 2 to 24 hr, or early phase, epithelial cells respond by synthesis and release of chemotactic factors, including chemokines--macrophage inflammatory protein-2, RANTES, and interleukin-8. Infiltrating leukocytes during this period also release elastase, an important agonist of epithelial cell mucus secretion and additional chemokine formation. The third (late) phase of ozone injury is characterized by eosinophil or monocyte infiltration. Cytokine expression leads to alteration of structural protein synthesis, with increases in fibronectin evident by in situ hybridization. Synthesis of epithelial antiproteases, e.g., secretory leukocyte protease inhibitor, may also increase locally 24 to 48 hr after elastase concentrations become excessive. Thus, the epithelium is not merely a passive barrier to ozone injury but has a dynamic role in directing the migration, activating, and then counteracting inflammatory cells. Through these complex interactions, epithelial cells can be viewed as the initiators (alpha) and the receptors (omega) of ozone-induced airway disease.

Ozonolysis products of membrane fatty acids activate eicosanoid metabolism in human airway epithelial cells.

When inhaled, ozone reacts at the airway luminal surface with unsaturated fatty acids contained in the extracellular fluid and plasma membrane to form an aldehyde and hydroxyhydroperoxide. The resulting hydroxyhydroperoxide degrades in aqueous systems to yield a second aldehyde and hydrogen peroxide (H2O2). Previously, we demonstrated that ozone can augment eicosanoid metabolism in bovine airway epithelial cells. To examine structure-activity relationships of ozone-fatty acid degradation products on eicosanoid metabolism in human airway epithelial cells, 3-, 6-, and 9-carbon saturated aldehydes and hydroxyhydroperoxides were synthesized and purified. Eicosanoid metabolism was evaluated by determination of total 3H-activity release from confluent cells previously incubated with [3H]arachidonic acid and by identification of specific metabolites with high performance liquid chromatography and radioimmunoassay. The major metabolites detected were prostaglandin E2, prostaglandin F2 alpha, and 15-hydroxyeicosatetraenoic acid. The 9-carbon aldehyde, nonanal, in contrast to 3- or 6-carbon aldehydes, stimulated release at concentrations > or = 100 microM, suggesting that the stimulatory effect increases with increasing chain length. When tested under identical conditions, the 3-, 6-, and 9-carbon hydroxyhydroperoxides were more potent than the corresponding aldehydes. Again, a greater effect was noted when the chain length was increased. One possible explanation for the increased potency of the hydroxyhydroperoxides over the aldehydes could be due to degradation of the hydroxyhydroperoxide into H2O2 and aldehyde. We consider this an unlikely explanation because responses varied with chain length (although each hydroxyhydroperoxide would produce an equivalent amount of H2O2) and because exposure to H2O2 alone or H2O2 plus hexanal produced a response dissimilar to 1-hydroxy-1-hexanehydroperoxide.(ABSTRACT TRUNCATED AT 250 WORDS)

Products and mechanism of the reaction of ozone with phospholipids in unilamellar phospholipid vesicles.

While considerable effort has been expended on determining the health effects of exposure to typical urban concentrations of O3, little is known about the chemical events responsible for toxicity. Phospholipids containing unsaturated fatty acids in the cell membranes of lung cells are likely reaction sites for inhaled ozone (O3). In this study, we examined the reaction of O3 with 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) in unilamellar phospholipid vesicles. Reaction of ozone with the carbon-carbon double bond of POPC yielded an aldehyde and a hydroxy hydroperoxide. The hydroxy hydroperoxide eliminated H2O2 to yield a second aldehyde. Upon further ozonolysis, the aldehydes were oxidized to the corresponding carboxylic acids. A material balance showed that no other reaction consumed POPC and O3 or produced these products. As a mechanistic probe, we measured incorporation of oxygen-18 from 18O3 into aldehyde, carboxylic acid, and H2O2. Approximately 50% of the aldehyde oxygen atoms were derived from O3. Oxygen in H2O2 was derived solely from O3, where both oxygen atoms in a molecule of H2O2 were from the same molecule of O3. One of the carboxylic acid oxygen atoms was derived from the precursor aldehyde, while the other was derived from O3. These results support the following mechanism. Cleavage of the carbon-carbon double bond of POPC by O3 yields a carbonyl oxide and an aldehyde. Reaction of H2O with the carbonyl oxide yields a hydroxy hydroperoxide, preventing formation ozonide by reaction of the carbonyl oxide and aldehyde. Elimination of H2O2 from the hydroxy hydroperoxide yields a second aldehyde. Oxidation of the aldehydes by O3 yields carboxylic acids.

Incorporation and disappearance of oxygen-18 in lung from mice exposed to 1 ppm 18O3.

In this study, 18O3 was used as a tracer for inhaled ozone in mice. The amount of ozone-derived oxygen (ODO) in the lungs was determined by measuring the amount of oxygen-18 in excess of the natural abundance level which remained covalently bound to organic constituents of lung following exposure to 1 ppm 18O3 for less than or equal to 60 min. The rate of disappearance of ODO from the lungs was determined by quantifying the rate of decrease of oxygen-18 in excess of the natural abundance level in lung from mice exposed to 1 ppm 18O3 for 45 min. With exposure to 1 ppm 18O3. ODO accumulated in lung at a rate of 4.38 pmol/mg dry weight/min. Ozone-derived oxygen had a half-life in lung of approximately 6 hr. We estimate that a minimum of 44 pmol of O3 reacted with lung every minute of exposure to 1 ppm O3.

Detection of CCl4-induced oxidation of hepatic tissue in vivo by oxygen-18 tracing.

Oxidation of rat hepatic tissue was measured as incorporation of oxygen-18 (18O) from 18O2 following exposure to carbon tetrachloride (CCl4). Anesthetized rats were injected with CCl4 and allowed to breathe 18O2 for 1 hr, and then livers were homogenized, fractionated, and dried. The dried fractions were pyrolyzed to CO by an oxygen elemental analyzer, the CO was oxidized to CO2, and isotope ratio mass spectrometry was used to determine the abundance of 18O in the CO2. Rats that breathed 18O2 (21% in N2) for 1 hr had significant incorporation of 18O into lipids, solutes, and macromolecules of the liver. Injection with CCl4 increased incorporation of 18O into all liver fractions, although this increase was significant only in the lipid fraction. Rats pretreated with phenobarbital and then given CCl4 had significantly increased 18O in all liver fractions although it was greatest in the lipid fraction. About 5 mumol of 18O per gram of dry liver was incorporated in phenobarbital/CCl4-treated rats, of which 60% was in the water-soluble fraction, 17% in the lipids, and 16% in the macromolecules. Piperonyl butoxide administration abolished the CCl4-induced 18O incorporation. Thus, 18O incorporation appeared to provide a measure of oxidation in all tissue fractions following in vivo CCl4-induced liver injury.

Isotopic analyses based on the mass spectrum of carbon dioxide.

Measurements of carbon and oxygen isotopic abundances are commonly based on the mass spectrum of carbon dioxide, but analysis of that spectrum is not trivial because three isotope ratios (17O/16O, 18O/16O, and 13C/12C) must be determined from only two readily observable ion-current ratios (45/44 and 46/44). Here, approaches to the problem are reassessed in the light of new information regarding the distribution of oxygen isotopes in natural samples. It is shown that methods of calculation conventionally employed can lead to systematic errors in the computed abundance of 13C and that these errors may be related to incorrect assessment of the absolute abundance of 17O. Further, problems arising during the analysis of samples enriched by admixture of 18O-labeled materials are discussed, and it is shown (i) that serious inaccuracies arise in the computed abundance of 17O and 13C if methods of calculation conventionally employed in the analysis of natural materials are applied to material labeled with 18O but (ii) that computed fractional abundances of 18O are always within 0.4% of the correct result. Methods for exact calculation of two isotope ratios when the third is known are presented and discussed, and a more exact approach to the computation of all three isotope ratios in natural materials is given.

Effects of social comparison on aggression and regression in groups of young children.

The influence of negative, equal, and positive social comparison and of nonsocial comparison upon 4- and 5-year-old black children's subsequent aggressive and regressive behavior in 3-member groups was investigated. The group behavior of boys included more physical agression following negative social comparison than the other treatments, and their group behavior also consisted of more nonverbal teasing behavior following the negative comparison treatment than that of the equal and nonsocial comparison groups. When the behavior of the nontarget partners was controlled, children initiated more physical aggression, nonverbal teasing, and regression after experiencing negative social comparison with the partners than after following the other treatments. There was some evidence to support the reciprocal influence of children's aggressive behavior on each other, particularly for boys following imbalanced social comparison treatments.

Father absence, perceived, maternal behavior, and moral development in boys.

The rated and observed moral behavior, judgment, and affect of 120 preadolescent, predominantly lower-class boys from early-divorced (before the boys were 6), late-divorced (between 6 and 10), and parentally intact homes were investigated. In addition, the mothers' discipline (power assertive, inductive, and love withdrawal) and affection were examined by asking subjects about their mothers' methods of dealing with their transgressions. Moral behavior was assessed with resistance-to-temptation, self-criticism, altruism, reparation, and teacher-rating measures, while moral judgment was evaluated with 3 Kohlberg items and moral affect was investigated with 2 story-completion items maximizing guilt. The major findings were: (1) when relevant variables (IQ, SES, age, sibling status) were controlled, few differences were found between father-absent and father-present boys; (2) however, father-absent boys were reported by their teachers as less advanced in moral development than father-present boys; (3) the sons of the divorced women showed more "social deviation", according to their teachers, but were more advanced in level of moral judgment than were the sons of widows; (4) divorced women disciplined with more power assertion than widows, according to their sons' reports.