Cumulative exposure assessment for trace-level polycyclic aromatic hydrocarbons (PAHs) using human blood and plasma analysis.

Humans experience chronic cumulative trace-level exposure to mixtures of volatile, semi-volatile, and non-volatile polycyclic aromatic hydrocarbons (PAHs) present in the environment as by-products of combustion processes. Certain PAHs are known or suspected human carcinogens and so we have developed methodology for measuring their circulating (blood borne) concentrations as a tool to assess internal dose and health risk. We use liquid/liquid extraction and gas chromatography-mass spectrometry and present analytical parameters including dynamic range (0-250 ng/ml), linearity (>0.99 for all compounds), and instrument sensitivity (range 2-22 pg/ml) for a series of 22 PAHs representing 2-6-rings. The method is shown to be sufficiently sensitive for estimating PAHs baseline levels (typical median range from 1 to 1000 pg/ml) in groups of normal control subjects using 1-ml aliquots of human plasma but we note that some individuals have very low background concentrations for 5- and 6-ring compounds that fall below robust quantitation levels.

The effects of ambient particulate matter on human alveolar macrophage oxidative and inflammatory responses.

Epidemiologic and occupational studies demonstrated that ambient particulate matter (PM) and diesel exhaust particles (DEP) exert deleterious effects on human cardiopulmonary health, including exacerbation of pre-existing lung disease and development of respiratory infections. The effects of ambient PM on lung cell responsiveness are poorly defined. Human alveolar macrophages (AM) were exposed to SRM 1649 (Washington, DC, urban dust; UD), SRM 2975 (forklift diesel exhaust particles; DEP), and fine or coarse ambient PM collected in Chapel Hill, NC, during the late fall (November) and early summer (June) of 2001-2002. AM were subsequently incubated with lipopolysaccharide (LPS), phorbol myristate acetate (PMA), or calcium ionophore A23817 for 6 or 24 h after PM exposure. UD and DEP markedly suppressed O2- release 24 h post-PM exposure. UD exposure significantly inhibited tumor necrosis factor (TNF)-alpha, interleukin (IL)-6, and IL-8 release after exposure to 10 nanog/ml LPS. DEP significantly suppressed only TNF-alpha and IL-6 release. Suppressed cytokine release may also be produced by reduced cellular cytokine production. Data suggested that decreased cytokine release is not produced by the presence of benzo[a]pyrene (BaP), a polycyclic aromatic hydrocarbon. Comparison of TNF-alpha release after LPS, PMA, or A23817 revealed that suppressive effects of UD are LPS dependent, whereas inhibitory effects of DEP may work across multiple mechanistic pathways. November and June Chapel Hill PM exposure stimulated TNF-alpha and IL-8 release before LPS exposure. Fine and coarse November PM exposure markedly suppressed TNF-alpha release 6 h after LPS stimulation, but appeared to exert a stimulatory effect on IL-8 release 24 h after LPS exposure. June fine and coarse PM suppressed IL-8 release after LPS exposure. Data suggest that seasonal influences on PM composition affect AM inflammatory response before and after bacterial exposure. Overall, delayed or inhibited AM immune responses to LPS after PM exposure suggest human exposure to ambient PM may enhance pulmonary susceptibility to respiratory infections.

Application of novel method to measure endogenous VOCs in exhaled breath condensate before and after exposure to diesel exhaust.

Polar volatile organic compounds (PVOCs) such as aldehydes and alcohols are byproducts of normal human metabolism and thus are found in blood and exhaled breath. Perturbation of the normal patterns of such metabolites may reflect exposures to environmental stressors, disease state, and human activity. Presented herein is a specific methodology for assaying PVOC biomarkers in exhaled breath condensate (EBC) samples with application to a series of samples from a controlled chamber exposure to dilute diesel exhaust (DE) or to purified air. The collection/analysis method is based on condensation of normal (at rest) exhaled breaths for 10 min (resulting in 1-2 ml of liquid) with subsequent analyte adsorption onto Tenax cartridges followed by thermal desorption and analysis by gas chromatography/mass spectrometry (GC/MS). Analytical data have linearity of response (R(2)>0.98) across a range of 0-160 ng/ml with a detection limit ranging from 0.2 to 7 ng/ml depending on the compound. Statistical analyses of the results of the controlled exposure study indicate that metabolism, as reflected in simple breath-borne oxygenated species, is not affected by exposure to ambient airborne levels of DE. Linear mixed-effects models showed that PVOC biomarker levels are affected by gender and vary significantly among nominally healthy subjects. Differences among PVOCs analyzed in clinic air, purified chamber air, and chamber air containing dilute DE confirm that most of the compounds are likely of endogenous origin as the exogenous exposure levels did not perturb the EBC measurements.

Responses measured in the exhaled breath of human volunteers acutely exposed to ozone and diesel exhaust.

Exhaled breath collection is used to identify and monitor inflammatory or oxidative components in breath. Exhaled breath sample collection is noninvasive and would greatly benefit human pollutant exposure research. We demonstrate the efficacy of exhaled breath collection and analysis in two human exposure studies to ozone (O(3)) and diesel exhaust, respectively. O(3) study: we collected exhaled breath (gas phase) from healthy human volunteers (age 18-35 years, 12 subjects) immediately before and after exposure to filtered air or 0.4 ppm O(3) for 2 h with and without intermittent exercise. Six subjects received antioxidant supplementation for 2 weeks before their O(3) exposure, while the remaining six subjects received placebo treatments. We demonstrate increased amounts of non-polar carbonyls exhaled immediately post O(3) exposure. The O(3)-induced increase in exhaled carbonyl concentrations was attenuated in the group receiving antioxidants. Our data demonstrate that exhaled exposure biomarkers can be measured in the breath gas phase in humans exposed to O(3). Diesel study: we collected exhaled breath condensate (EBC; liquid phase) from healthy human volunteers (age 18-40 years; 10 subjects) immediately before, immediately after and 20 h post filtered air or diesel exhaust (106 ± 9 µg m(-3)) exposure. Clean air and diesel exposures were separated by 3 weeks to 6 months. We obtained reproducible intra-subject EBC volumes and total protein concentrations across our six collection time points. Diesel exposure did not affect either EBC volume or total protein concentrations. Our data demonstrated EBC volume and total protein reproducibility over several months. Volume and total protein concentration may serve as normalizing factors for other EBC constituents.

Metabolic capacity regulates iron homeostasis in endothelial cells.

The sensitivity of endothelial cells to oxidative stress and the high concentrations of iron in mitochondria led us to test the hypotheses that (1) changes in respiratory capacity alter iron homeostasis, and (2) lack of aerobic metabolism decreases labile iron stores and attenuates oxidative stress. Two respiration-deficient (rho(o)) endothelial cell lines with selective deletion of mitochondrial DNA (mtDNA) were created by exposing a parent endothelial cell line (EA) to ethidium bromide. Surviving cells were cloned and mtDNA-deficient cell lines were demonstrated to have diminished oxygen consumption. Total cellular and mitochondrial iron levels were measured, and iron uptake and compartmentalization were measured by inductively coupled plasma atomic emission spectroscopy. Iron transport and storage protein expression were analyzed by real-time polymerase chain reaction and Western blot or ELISA, and total and mitochondrial reactive oxygen species (ROS) generation was measured. Mitochondrial iron content was the same in all three cell lines, but both rho(o) lines had lower iron uptake and total cellular iron. Protein and mRNA expressions of major cytosolic iron transport constituents were down-regulated in rho(o) cells, including transferrin receptor, divalent metal transporter-1 (-IRE isoform), and ferritin. The mitochondrial iron-handling protein, frataxin, was also decreased in respiration-deficient cells. The rho(o) cell lines generated less mitochondrial ROS but released more extracellular H(2)O(2), and demonstrated significantly lower levels of lipid aldehyde formation than control cells. In summary, rho(o) cells with a minimal aerobic capacity had decreased iron uptake and storage. This work demonstrates that mitochondria regulate iron homeostasis in endothelial cells.

Air pollution particles mediated oxidative DNA base damage in a cell free system and in human airway epithelial cells in relation to particulate metal content and bioreactivity.

Epidemiological studies demonstrate an association between increased human morbidity and mortality with exposure to air pollution particulate matter. We hypothesized that such effects may be associated with the ability of the particles to mediate generation of reactive oxygen species (ROS), either directly, via interaction with ambient oxygen or indirectly through initiation of an oxidative burst in phagocytes. To test this hypothesis, we determined 8-oxo-dG formation as a measure of direct generation of ROS, in response to particulate exposures to 2'-deoxyguanosine (dG), free and in calf thymus DNA in aerated solutions as the target molecule and cell culture, to assess the relationship between induction of oxidative damage, particulate metal content and metal bioreactivity. The HPLC-ECD technique was employed for separation and quantification of 8-oxo-dG, the most widely recognized marker of DNA oxidation. Particles used in this study include: Arizona desert dust (AZDD), coal fly ash (CFA and ECFA), oil fly ash (OFA and ROFA), and ambient air [SRM 1649 and Dusseldorf (DUSS), Germany]. The major difference between these particles is the concentration of water-soluble metals. The fly ash particulates OFA and ROFA showed a significant dose-dependent increase in dG hydroxylation to 8-oxo-dG formation over the control dG (p < 0.05), with yields 0.03 and 1.25% at the highest particulate concentration (1 mg/mL). Metal ion chelators and DMSO, a hydroxyl radical scavenger, inhibited this hydroxylation. In contrast, desert dust, coal fly ash and urban air particles induced 8-oxo-dG with yields ranging from 0.003 to 0.006%, respectively, with levels unaffected by pretreatment of the particles with metal ion chelators or addition of DMSO to the incubation mixture. When calf thymus DNA was used as a substrate, all the particles induced 8-oxo-dG in a pattern similar to that observed for dG hydroxylation, but with relatively less yield. Treatment of the particles with metal ion chelator before reacting with DNA or addition of catalase in the incubation mixture, suppressed 8-oxo-dG formation significantly (p < 0.05) in oil-derived fly ash particles only. To determine whether the oxidative responses of these particulates as shown in cell-free systems were consistent with responses using a more biologically relevant environment, human airway epithelial cells were treated with the particulates and induction of 8-oxo-dG was determined. All particles induced 8-oxo-dG in the DNA of cells above culture control, except CFA. Cells exposed to 10-400 mg/mL of ROFA for 2 h induced a dose-dependent increase in 8-oxo-dG formation. Treatment of ROFA with metal ion chelator attenuated these effects. Overall, damage enhancement by particulates in dG, calf thymus, and cellular DNA as determined by 8-oxo-dG formation under aerobic conditions is consistent with the concentration of water-soluble, not the total metal content of the particle.

Effect of ozone on diesel exhaust particle toxicity in rat lung.

Ambient particulate matter (PM) concentrations have been associated with mortality and morbidity. Diesel exhaust particles (DEP) are present in ambient urban air PM. Coexisting with DEP (and PM) is ozone (O(3)), which has the potential to react with some components of DEP. Some reports have shown increased lung injury in rats coexposed to PM and O(3), but it is unclear whether this increased injury was due to direct interaction between the pollutants or via other mechanisms. To examine whether O(3) can directly react with and affect PM bioactivity, we exposed DEP to O(3) in a cell-free in vitro system and then examined the bioactivity of the resultant DEP in a rat model of lung injury. Standard Reference Material 2975 (diesel exhaust PM) was initially exposed to 0.1 ppm O(3) for 48 h and then instilled intratracheally in Sprague-Dawley rats. Rat lung inflammation and injury was examined 24 h after instillation by lung lavage. The DEP exposed to 0.1 ppm O(3) was more potent in increasing neutrophilia, lavage total protein, and LDH activity compared to unexposed DEP. The increased DEP activity induced by the O(3) exposure was not attributable to alteration by air that was also present during the O(3) exposure. Exposure of DEP to a higher O(3) concentration (1.0 ppm) led to a decreased bioactivity of the particles. In contrast, carbon black particles, low in organic content relative to DEP, did not exhibit an increase in any of the bioactivities examined after exposure to 0.1 ppm O(3). DEP incorporated O(3) (labeled with (18)O) in a linear fashion. These data suggest that ambient concentrations of O(3) can increase the biological potency of DEP. The ozonized DEP may play a role in the induction of lung responses by ambient PM.

Accumulation of iron in the rat lung after tracheal instillation of diesel particles.

Oxidant generation catalyzed by metals has been postulated to account for a lung injury following exposure to air pollution particles. In particles that are predominantly carbonaceous, it is difficult to implicate such an oxidative stress as the responsible mechanism, since concentrations of metals can be extremely low. Comparable to these air pollution particles, mineral oxide particles can include only minute amounts of metal, but lung injury following their exposure can be associated with an accumulation of endogenous iron from the host and an oxidative stress. We tested the hypothesis that diesel exhaust particulate (DEP) effects an accumulation of biologically active iron in the rat lung, with both oxidative stress and a lung injury resulting. Characterization of the DEP confirmed a high concentration of carbon, whereas metals were low in quantity. The concentration of total lavage iron in animals instilled with saline was low, but this concentration increased with exposure to DEP. Non-heme iron in lung tissue was similarly elevated after instillation of the diesel product. Particle instillation was associated with a decrease in lavage ascorbate concentration supporting an oxidative stress. Relative to saline exposure, DEP resulted in elevated lavage concentrations of the inflammatory mediators macrophage inflammatory protein-2 and tumor necrosis factor. Finally, an injury after particle instillation was evident with increased neutrophils and an elevation of lavage protein and lactic dehydrogenase. We conclude that DEP exposure effected an accumulation of iron in the rat lung. This accrual of iron was associated with an oxidative stress, release of oxidant-sensitive mediators, and a neutrophilic lung injury.

Increased expression of cyclooxygenase 2 mediates oil fly ash-induced lung injury.

We have previously shown that in vitro exposure to the combustion-derived ambient air pollutant residual oil fly ash (ROFA) induces the expression of prostaglandin H synthase 2 (COX2) in human airway epithelial cells. To determine the role of prostaglandins and COX2 expression in ROFA-induced lung injury in vivo, we have examined the effect of intratracheal ROFA instillation on COX2 expression, prostaglandin synthesis, and indices of pulmonary injury and inflammation in adult Sprague-Dawley rats. ROFA treatment induced a marked increase in the level of prostagladin E2 (PGE2) recovered in the bronchoalveolar lavage fluid (BALF), which was effectively decreased by pretreating the animals with the specific COX2 inhibitor NS398. Immunohistochemical analyses of rat airways showed concomitant expression of COX2 in the proximal airway epithelium of rats treated with ROFA. Increases in BALF protein, but not interleukin 6 (IL-6) increases or ROFA-induced polymorphonuclear neutrophils (PMN) influx into the airway, were blunted by administration of NS398 prior to ROFA instillation. These data demonstrate that prostaglandins mediate lung injury induced by exposure to ROFA and implicate increased expression of COX2 as a mechanism that contributes to the toxicity of metal-laden ambient particulate matter.

Ozone effects on airway responsiveness, lung injury, and inflammation. Comparative rat strain and in vivo/in vitro investigations.

Asthmatic individuals appear to be particularly sensitive to the effects of certain air pollutants-including ozone (O(3)), an oxidant ambient air pollutant-for reasons that are poorly understood. The general purpose of these studies, therefore, was to expand and improve upon toxicologic methods for assessing ozone-induced effects on the airways of the rat by (1) developing an in vivo testing procedure that allows detection of airway responsiveness changes in rats exposed to ozone; (2) identifying a strain of rat that may be inherently more sensitive to the effects of ozone; and (3) validation of an in vitro epithelial culture system to more directly assess airway cellular/subcellular effects of ozone. Using methacholine inhalation challenges, we detected increased airway responsiveness in senescent F344 rats acutely after ozone exposure (2 ppm x 2 h). We also determined that acutely after ozone exposure (0.5 ppm x 8 h), Wistar rats developed significantly greater lung injury, neutrophilic inflammation, and bronchoalveolar lavage (BAL) fluid concentrations of IL-6 than either Sprague-Dawley (SD) or F344 rats. SD rats had greater BAL fluid concentrations of prostaglandin E(2) (PGE(2)), while F344 rats consistently exhibited the least effect. Wistar rat-derived tracheal epithelial (RTE) cultures were exposed in vitro to air or ozone (0.1-1.0 ppm x 1 h), and examined for analogous effects. In a concentration-dependent manner, ozone exposure resulted in acute but minor cytotoxicity. RT polymerase chain reaction (PCR) analysis of RNA isolated from ozone-exposed cells demonstrated variable increases in steady-state gene expression of IL-6 at 4 h postexposure, while at 24 h cellular fibronectin expression (EIIIA domain) was decreased. Exposure was without effect on macrophage inflammatory protein 2 (MIP-2) or gamma-glutamyl cysteine synthetase expression. At 6 h postexposure, IL-6 synthesis and apical release appeared increased in ozone-exposed cells (1 ppm x 1 h). MIP-2 release was not significantly increased in ozone-exposed cells. At 2 h postexposure, ozone exposure resulted in minor increases in apical fibronectin, but exposure was without effect on basolateral accumulation of fibronectin. Exposure to 1.0, but not 0.1 ppm (x 1 h), increased production of cyclooxygenase (i.e., PGE(2)) and noncyclooxygenase products of arachidonic acid. Results demonstrate that multiple inflammatory mediator pathways are affected by ozone exposure. Such effects could exacerbate morbidity in individuals with preexisting airway inflammation such as asthmatics.

Acetaldehyde (CH3CHO) production in rodent lung after exposure to metal-rich particles.

Epidemiological reports demonstrate an association between increased human morbidity and mortality with exposure to air pollution particulate matter (PM). Metal-catalyzed oxidative stress has been postulated to contribute to lung injury in response to PM exposure. We studied the effects of residual oil fly ash (ROFA), a component of ambient air PM, on the formation of lung carbonyls that are indicators of lipid peroxidation. Rats were instilled intratracheally with ROFA (62.5-1000 micrograms) and underwent lung lavage. Lavage fluid carbonyls were derivatized with 2,4-dinitrophenylhydrazine, and measured by high performance liquid chromatography with UV detection. Dose-dependent increases in a peak that eluted with the same retention time as the acetaldehyde (CH3CHO) derivative was observed in rats treated with ROFA 15 min after instillation (up to 25-fold greater than saline treated controls). The identification of CH3CHO was confirmed using gas chromatography-mass spectroscopy. ROFA-induced increases in other lavage fluid carbonyls were not seen. Increased CH3CHO in lavage fluid was observed as late as 8 h later. No increase in CH3CHO was observed in plasma from ROFA-treated rats. An increased formation of CH3CHO was observed in a human airway epithelial cell line incubated with ROFA suggesting a pulmonary source of CH3CHO production. Instillation of solutions of metals (iron, vanadium, nickel) contained in ROFA, or instillation of another ROFA-type particle containing primarily iron, also induced a specific increase in CH3CHO. These data support the hypothesis that metals were involved in the increased CH3CHO formation. Thus metals on PM may mediate lung responses through induction of lipid peroxidation and carbonyl formation.

Inflammatory response in humans exposed to 2.0 ppm nitrogen dioxide.

Nitrogen dioxide (NO2) is a common indoor air pollutant, especially in homes with unvented combustion appliances. Epidemiological studies suggest that children living in homes with unvented heating sources are more prone to respiratory infections than children living in homes with lower levels of NO2. However, experimental studies in which human volunteers were exposed acutely to moderate levels of NO2 (0.5-2.0 ppm) have shown little evidence of lung inflammation or decreased host resistance capacity. In the study reported here, 8 healthy volunteers were exposed to 2.0 ppm NO2 and to filtered air for 4 h while undergoing intermittent moderate exercise. Bronchoalveolar lavage was performed the following morning. The lavage was divided into a predominantly bronchial washing (first 20 ml of lavage; BL) and a predominantly alveolar washing (BAL). In the BL, NO2 exposure caused increases in polymorphonuclear neutrophils (PMNs), interleukin 6 (IL-6), IL-8, alpha1-antitrypsin, and tissue plasminogen activator, and decreases in epithelial cells. In the BAL, there were no NO2-induced changes in either cell numbers or soluble mediators. On the other hand, alveolar macrophages from BAL showed a decrease in the ability to phagocytose unopsonized Candida albicans and a decrease in superoxide production. No difference in susceptibility to virus infection was found between the NO2- and air-exposed macrophages. No changes in lung function were observed, but the aerosol bolus recovery technique revealed a statistically significant (p <.05) decrease in the fraction of aerosol recovered following nitrogen dioxide exposure, which is suggestive of small obstructive changes induced by NO2.

Cell proliferation in nasal respiratory epithelium of people exposed to urban pollution.

The nasal passages are a common portal of entry and are a prime site for toxicant-induced pathology. Sustained increases in regenerative cell proliferation can be a significant driving force in chemical carcinogenesis. The atmosphere in Mexico City contains a complex mixture of air pollutants and its residents are exposed chronically and sequentially to numerous toxicants and potential carcinogens. We were concerned that exposure to Mexico City's atmosphere might induce cytotoxicity and increase nasal respiratory epithelial cell proliferation. Nasal biopsies were obtained for DNA cell cycle analysis from 195 volunteers. The control population consisted of 16 adults and 27 children that were residents in a Caribbean island with low pollution. The exposed Mexico City population consisted of 109 adults and 43 children. Sixty-one of the adult subjects were newly arrived in Mexico City and were followed for 25 days from their arrival. Control children, control adult and exposed Mexico City children all had similar percentages of cells in the replicative DNA synthesis phase (S phase) of the cell cycle (%S). A significant increase in %S in nasal epithelial cells was seen in exposed adult residents in Mexico City biopsied at three different dates compared with control adults. Newly arrived adults exhibited a control level of cell turnover at day 2 after coming to the city. However, at days 7, 14 and 25 they exhibited significant increases in %S. These data demonstrate an increased and sustained nasal cell turnover rate in the adult population observable in as little as 1 week of residence in Mexico City. This increase in cell proliferation is in agreement with other reports of induced pathological changes in the nasal passages of Mexico City dwellers. These observations suggest an increased potential risk factor of developing nasal neoplasms for residents of large cities with heavy pollution.

Model systems for modulating the free energy of ATP hydrolysis in normoxically perfused rat hearts.

This study has two objectives; first, to develop perfusion conditions that decrease the free energy of ATP hydrolysis, Delta GATP, in isolated hearts; and, second, to modulate the Delta GATP in these perfused hear models. To accomplish the first goal, a series of inhibitors was employed to restrict acetyl-CoA oxidation. The second goal was accomplished by increasing work demand. Rat hearts were perfused with Krebs-Henseleit solution containing glucose and either; (i) no inhibitors (G group hearts); (ii) 0.3 mm bromo-octanoate (BrO), an inhibitor of beta-oxidation (GB group); (iii) 0.4 mm amino-oxyacetate (AOA), an inhibitor of the malate-aspartate shuttle (GA group); (iv) BrO and AOA (GBA group hearts); or (v) BrO, AOA, and 4 mm butyrate, an alternate substrate (GBA-Bu). Pacing hearts at 300 beats per min (beats/min), at 450 beats/min, and at 450 beats/min in the presence of 80 microgram/l dobutamine allowed three increasing levels of work demand to be attained. The Delta GATP values of the five groups of hearts were calculated for each workstate using the concentrations of high energy phosphate metabolites measured by 31P NMR spectroscopy. At the highest levels of workload demand, the G, GB, and GBA-Bu group hearts had Delta GATP values >/=-53 kJ/mol ATP. At the highest levels of workload demand, the GA and GBA hearts had Delta GATP values 20 min. The G, GB, and GBA-Bu hearts attained RPPs of >/=54x10(3) mmHg/min at the highest levels of workload demand. The GA and GBA hearts attained RPPs of

Induction of prostaglandin H synthase 2 in human airway epithelial cells exposed to residual oil fly ash.

Exposure to ambient air containing respirable particulate matter at concentrations below the current National Ambient Air Quality Standard has been associated with increased rates of pulmonary-related morbidity and mortality. To identify mechanisms involved in pulmonary responses to such exposure, we studied the effects of the emission source particulate air pollutant residual oil fly ash (ROFA) on prostaglandin metabolism in cultured human airway epithelial cells. Epithelial cells exposed to ROFA for 24 hr secreted substantially increased amounts of the prostaglandin H synthase (PHS) products prostaglandins E2 and F2 alpha. The ROFA-induced increase in prostaglandin synthesis was correlated with a marked increase in PHS activity. Western blots showed that ROFA exposure induced dose-dependent increases in PHS2 protein levels. Reverse transcriptase-PCR analyses demonstrated accompanying increases in PHS2 mRNA which were evident by 2 hr of continuous exposure. In contrast, expression of PHS1 was not affected by ROFA treatment of airway epithelial cells. There were no alterations in arachidonic acid release, incorporation, or availability in ROFA-exposed cells. These data show that exposure to ROFA induces PHS2 expression, leading to increased prostaglandin synthesis in cultured airway epithelial cells. These findings suggest that prostaglandins may play a role in the toxicology of air pollution particle inhalation.

The use of the single cell gel electrophoresis assay in detecting DNA single strand breaks in lung cells in vitro.

DNA single strand breaks (SSB) can be used as a biomarker of oxidant exposure, and also as an indicator of the carcinogenicity/ mutagenicity of a substance. The single cell gel electrophoresis (SCGE) assay is more sensitive and requires fewer cells compared to other techniques used for detecting SSB. We examined the utility of using the SCGE assay for human lung cells exposed to endogenous and exogenous oxidants. A human bronchial cell line (BEAS) was used as a model of airway epithelial cells in this study. BEAS cells exposed to 0-50 microM hydrogen peroxide (H2O2) for 60 min at 4 degrees C exhibited a concentration-dependent increase in SSB as determined by an increased DNA migration area in a gel undergoing electrophoresis. H2O2-induced increases in DNA SSB were also demonstrated using cultured normal human tracheobronchial epithelial (NHBE) cells and human alveolar macrophages in a concentration response manner. BEAS cells were also exposed to air or ozone (O3) on a Transwell filter without medium present apically. Cells exposed to O3 at 0.1 or 0.4 ppm at 37 degrees C for up 120 min had a time- and concentration-dependent increase in SSB compared to air-exposed cells. NHBE cells exposed to 0.4 ppm O3 (60 min) also had increased DNA SSB. Cells with H2O2-induced DNA SSB can be frozen and stored up to 4 weeks without altering the original DNA SSB. These findings indicate that SCGE can be used to detect SSB in cultured lung cells, and has applicability for detecting SSB in lung cells recovered from in vivo and in vitro exposures to oxidants.

Characterization of a secretory phospholipase A2 in human bronchoalveolar lavage fluid.

Phospholipase A2 (PLA2) is a pivotal enzyme involved in the synthesis of the potent lipid inflammatory mediators platelet activating factor (PAF) and the eicosanoids. This study characterizes a PLA2 recovered in the bronchoalveolar lavage fluid (BALF) of healthy adult human subjects. Human BALF PLA2 exhibited characteristics of secretory PLA2s that include an activity that is acid stable, sensitive to reducing agents, and optimally requires millimolar calcium. BALF PLA2 showed marked selectivity for phosphatidylcholine containing arachidonic acid (AA) over linoleic or palmitic acids. Size exclusion chromatography showed the BALF PLA2 protein to be approximately 14 kDa in mass, consistent with it being a secretory form of PLA2. The biological significance of BALF PLA2 was tested by applying BALF concentrates to cultures of the human bronchial epithelial cell line BEAS 2B. Cultures of BEAS 2B cells treated with BALF concentrates released increased amounts of AA and produced higher levels of PAF. These data show that the lining fluid of the human respiratory tract normally contains a secretory PLA2, which may be involved in the formation of lipid inflammatory mediators in normal and pathophysiologic states in the lung.

Time-dependent changes of inflammatory mediators in the lungs of humans exposed to 0.4 ppm ozone for 2 hr: a comparison of mediators found in bronchoalveolar lavage fluid 1 and 18 hr after exposure.

Acute exposure of humans to ozone results in reversible respiratory function decrements and cellular and biochemical changes leading to the production of substances which can mediate inflammation and acute lung injury. While pulmonary function decrements occur almost immediately after ozone exposure, it is not known how quickly the cellular and biochemical changes indicative of inflammation occur in humans. Increased bronchoalveolar lavage (BAL) fluid levels of neutrophils (PMNs) and prostaglandins (PGE2) have been reported in humans as early as 3 hr and as late as 18 hr after exposure. The purpose of this study was to determine whether a broad range of inflammatory mediators are elevated in BAl fluid within 1 hr of exposure. We exposed eight healthy volunteers twice: once to 0.4 ppm ozone and once to filtered air. Each exposure lasted for 2 hr during which the subjects underwent intermittent heavy exercise (66 liters/min). BAL was performed 1 hr after the exposure. Ozone induced rapid increases in PMNs, total protein, LDH, alpha-1 antitrypsin, fibronectin, PGE2, thromboxane B2, C3a, tissue factor, and clotting factor VII. In addition, there was a decrease in the recovery of total cells and alveolar macrophages, and decreased ability of alveolar macrophages to phagocytize Candida albicans. A comparison of these changes with changes observed in an earlier study in which subjects underwent BAL 18 hr after an identical exposure regimen indicates that IL-6 and PGE2 levels were higher 1 hr after exposure than 18 hr after exposure, fibronectin and tissue-plasminogen activator levels were higher 18 hr after exposure, and that PMNs, protein, and C3a were present at essentially the same levels at both times. These results indicate that (i) several inflammatory mediators are already elevated 1 hr after exposure; (ii) some mediators achieve their maximal levels in BAL fluid at different times following exposure. These data suggest that the inflammatory response is complex, depending on a cascade of timed events, and that depending on the mediator of interest one must choose an appropriate sampling time.

Products of ozonized arachidonic acid potentiate the formation of DNA single strand breaks in cultured human lung cells.

In this study we examined the potential for environmental levels of ozone (03) to degrade arachidonic acid (AA), a polyunsaturated fatty acid abundantly present in the lung, into products that can produce DNA single strand breaks (ssb) in cultured human lung cells. Human lung fibroblasts were incubated with 60 microM AA that had been previously exposed to and degraded by 0.4 ppm 03 (1 hr.) Incubation of the cells with 03-exposed AA (but not with vehicle alone) for 1 hr at 4 degrees C and 37 degrees C produced 555 and 245 rad-equivalents of DNA ssb, respectively, as determined by the DNA alkaline elution technique. These breaks were completely eliminated when the ozonized AA solution was incubated with catalase prior to cell treatment, indicating that h202 was solely responsible for damaging DNA. Superoxide dismutase bovine serum albumin, or heat-inactivated catalase showed little, if any, inhibitory activity. The H202 content of the ozonized AA (31 +/- 4 microM) could account for only about 40% of the observed breaks. Potentiation of the H202-induced DNA ssb persisted after removal of the carbonyl substances by chromatographic procedures, suggesting that the non-carbonyl component of ozonized AA was the responsible component for inducing augmentation of the observed increases in DNA ssb. Ozonized AA also induced DNA ssb in cultures of the human bronchial epithelial cell line BEAS-2B. Again, these breaks were shown to exceed levels that could be attributed to the presence of H202 alone. These results indicate that products of ozonized AA can interact to potentiate DNA ssb in human lung cells.

Acylcarnitine accumulation does not correlate with reperfusion recovery in palmitate-perfused rat hearts.

Carnitine palmitoyltransferase-I (CPT-I) inhibitors improve postischemic myocardial function either by decreasing muscle long-chain acylcarnitines (LCAC) during ischemia or by increasing oxidation of alternate substrates such as glucose during reperfusion. These possibilities were evaluated using oxfenicine, a CPT-I inhibitor, and alternate substrates that bypass carnitine-dependent metabolism. Isolated rat hearts subjected to 20 min of ischemia followed by 40 min of reperfusion with 1.8 mM palmitate as exogenous substrate recovered little function during reperfusion. Hearts made ischemic and reperfused with palmitate and 2.4 mM hexanoate as exogenous substrates had significantly improved reperfusion function compared to palmitate-perfused hearts. Addition of 2 mM oxfenicine to palmitate-hexanoate-perfused hearts gave an additional small improvement in reperfusion function. At the end of ischemia, the LCAC content of hearts perfused with palmitate or hexanoate and palmitate was identical. Palmitate-, hexanoate, and oxfenicine-perfused hearts had significantly decreased LCAC content at the end of ischemia compared with hexanoate-palmitate-perfused hearts. Therefore, depressed reperfusion function in long-chain fatty acid-perfused hearts can be ameliorated by alternate substrates, including medium-chain fatty acids. LCAC accumulation during ischemia apparently plays only a minor role in the postischemic dysfunction of long-chain fatty acid-perfused hearts.