Lung effects of inhaled corticosteroids in a rhesus monkey model of childhood asthma.

BACKGROUND: The risks for infants and young children receiving inhaled corticosteroid (ICS) therapy are largely unknown. Recent clinical studies indicate that ICS therapy in pre-school children with symptoms of asthma result in decreased symptoms without influencing the clinical disease course, but potentially affect postnatal growth and development. The current study employs a primate experimental model to identify the risks posed by ICS therapy. OBJECTIVE: To (1) establish whether ICS therapy in developing primate lungs reverses pulmonary pathobiology associated with allergic airway disease (AAD) and (2) define the impact of ICS on postnatal lung growth and development in primates. METHODS: Infant rhesus monkeys were exposed, from 1 through 6 months, to filtered air (FA) with house dust mite allergen and ozone using a protocol that produces AAD (AAD monkeys), or to FA alone (Control monkeys). From three through 6 months, the monkeys were treated daily with ICS (budesonide) or saline. RESULTS: Several AAD manifestations (airflow restrictions, lavage eosinophilia, basement membrane zone thickening, epithelial mucin composition) were reduced with ICS treatment, without adverse effects on body growth or adrenal function; however, airway branching abnormalities and intraepithelial innervation were not reduced. In addition, several indicators of postnatal lung growth and differentiation: vital capacity, inspiratory capacity, compliance, non-parenchymal lung volume and alveolarization, were increased in both AAD and Control monkeys that received ICS treatment. CONCLUSIONS AND CLINICAL RELEVANCE: Incomplete prevention of pathobiological changes in the airways and disruption of postnatal growth and differentiation of airways and lung parenchyma in response to ICS pose risks for developing primate lungs. These responses also represent two mechanisms that could compromise ICS therapy's ability to alter clinical disease course in young children.

Elevation of susceptibility to ozone-induced acute tracheobronchial injury in transgenic mice deficient in Clara cell secretory protein.

Increases in Clara cell abundance or cellular expression of Clara cell secretory protein (CCSP) may cause increased tolerance of the lung to acute oxidant injury by repeated exposure to ozone (O3). This study defines how disruption of the gene for CCSP synthesis affects the susceptibility of tracheobronchial epithelium to acute oxidant injury. Mice homozygous for a null allele of the CCSP gene (CCSP-/-) and wild type (CCSP+/+) littermates were exposed to ozone (0.2 ppm, 8 h; 1 ppm, 8 h) or filtered air. Injury was evaluated by light and scanning electron microscopy, and the abundance of necrotic, ciliated, and nonciliated cells was estimated by morphometry. Proximal and midlevel intrapulmonary airways and terminal bronchioles were evaluated. There was no difference in airway epithelial composition between CCSP+/+ and CCSP-/- mice exposed to filtered air, and exposure to 0.2 ppm ozone caused little injury to the epithelium of both CCSP+/+ and CCSP-/- mice. After exposure to 1.0 ppm ozone, CCSP-/- mice suffered from a greater degree of epithelial injury throughout the airways compared to CCSP+/+ mice. CCSP-/- mice had both ciliated and nonciliated cell injury. Furthermore, lack of CCSP was associated with a shift in airway injury to include proximal airway generations. Therefore, we conclude that CCSP modulates the susceptibility of the epithelium to oxidant-induced injury. Whether this is due to the presence of CCSP on the acellular lining layer surface and/or its intracellular distribution in the secretory cell population needs to be defined.

Allergic asthma induced in rhesus monkeys by house dust mite (Dermatophagoides farinae).

To establish whether allergic asthma could be induced experimentally in a nonhuman primate using a common human allergen, three female rhesus monkeys (Macaca mulatta) were sensitized with house dust mite (Dermatophagoides farinae) allergen (HDMA) by subcutaneous injection, followed by four intranasal sensitizations, and exposure to allergen aerosol 3 hours per day, 3 days per week for up to 13 weeks. Before aerosol challenge, all three monkeys skin-tested positive for HDMA. During aerosol challenge with HDMA, sensitized monkeys exhibited cough and rapid shallow breathing and increased airway resistance, which was reversed by albuterol aerosol treatment. Compared to nonsensitized monkeys, there was a fourfold reduction in the dose of histamine aerosol necessary to produce a 150% increase in airway resistance in sensitized monkeys. After aerosol challenge, serum levels of histamine were elevated in sensitized monkeys. Sensitized monkeys exhibited increased levels of HDMA-specific IgE in serum, numbers of eosinophils and exfoliated cells within lavage, and elevated CD25 expression on circulating CD4(+) lymphocytes. Intrapulmonary bronchi of sensitized monkeys had focal mucus cell hyperplasia, interstitial infiltrates of eosinophils, and thickening of the basement membrane zone. We conclude that a model of allergic asthma can be induced in rhesus monkeys using a protocol consisting of subcutaneous injection, intranasal instillation, and aerosol challenge with HDMA.

Differential expression of stress proteins in nonhuman primate lung and conducting airway after ozone exposure.

The presence of seven stress proteins including various heat shock proteins [27-kDa (HSP27), 60-kDa (HSP60), 70-kDa (HSP70) and its constitutive form HSC70, and 90-kDa (HSP90) HSPs] and two glucose-regulated proteins [75-kDa (GRP75) and 78-kDa (GRP78) GRPs] in ozone-exposed lungs of nonhuman primates and in cultured tracheobronchial epithelial cells was examined immunohistochemically by various monoclonal antibodies. Heat treatment (42 degrees C) resulted in increased HSP70, HSP60, and HSP27 and slightly increased HSC70 and GRP75 but no increase in GRP78 in primary cultures of monkey tracheobronchial epithelial cells. Ozone exposure did not elevate the expression of these HSPs and GRPs. All of these HSPs including HSP90, which was undetectable in vitro, were suppressed in vivo in monkey respiratory epithelial cells after ozone exposure. Both GRP75 and GRP78 were very low in control cells, and ozone exposure in vivo significantly elevated these proteins. These results suggest that the stress mechanism exerted on pulmonary epithelial cells by ozone is quite different from that induced by heat. Furthermore, differences between in vitro and in vivo with regard to activation of HSPs and GRPs suggest a secondary mechanism in vivo, perhaps related to inflammatory response after ozone exposure.

Relationship of inhaled ozone concentration to acute tracheobronchial epithelial injury, site-specific ozone dose, and glutathione depletion in rhesus monkeys.

Acute pulmonary epithelial injury produced by short-term exposure to ozone varies by site within the tracheobronchial tree. To test whether this variability is related to the local dose of ozone at the tissue site or to local concentrations of glutathione, we exposed adult male rhesus monkeys for 2 h to filtered air or to 0.4 or 1.0 ppm ozone generated from 18O2. Following exposure, lungs were split into lobes and specimens were selected by microdissection so that measurements could be made on airway tissue of similar branching history, including trachea, proximal (generation one or two) and distal (generation six or seven) intrapulmonary bronchi, and proximal respiratory bronchioles. One half of the lung was lavaged for analysis of extracellular components. In monkeys exposed to filtered air, the concentration of reduced glutathione (GSH) varied throughout the airway tree, with the proximal intrapulmonary bronchus having the lowest concentration and the parenchyma having the highest concentration. Exposure to 1.0 ppm ozone significantly reduced GSH only in the respiratory bronchiole, whereas exposure to 0.4 ppm increased GSH only in the proximal intrapulmonary bronchus. Local ozone dose (measured as excess 18O) varied by as much as a factor of three in different airways of monkeys exposed to 1.0 ppm, with respiratory bronchioles having the highest concentration and the parenchyma the lowest concentration. In monkeys exposed to 0.4 ppm, the ozone dose was 60% to 70% less than in the same site in monkeys exposed to 1.0 ppm. Epithelial disruption was present to some degree in all airway sites, but not in the parenchyma, in animals exposed to 1.0 ppm ozone. The mass of mucous and ciliated cells decreased in all airways, and necrotic and inflammatory cells increased. At 0.4 ppm, epithelial injury was minimal, except in the respiratory bronchiole, where cell loss and necrosis occurred, and was 50% that found in monkeys exposed to 1.0 ppm ozone. We conclude that there is a close association between site-specific O3 dose, the degree of epithelial injury, and glutathione depletion at local sites in the tracheobronchial tree.

Cytochrome P450 2E1 in rat tracheobronchial airways: response to ozone exposure.

The distal trachea and centriacinus of the lung are primary sites of acute injury during short-term ozone exposure; long-term exposure yields cells in these areas that are resistant to high doses of oxidant gases. Epithelial cells located in primary sites for ozone injury are also targets for chemicals that undergo cytochrome P450 (CYP)-dependent activation. These studies were designed to compare the effects of ozone exposure on pulmonary CYP2E1 in susceptible and nonsusceptible sites within the airway tree of lung. CYP2E1 activity was measured in well-defined regions of airways using p-nitrophenol, a CYP2E1-selective substrate, with HPLC/ electrochemical detection of the p-nitrocatechol. Alterations in distribution of CYP2E1 were evaluated by immunohistochemistry. CYP2E1 activities were highest in the distal bronchioles and minor daughter airways but were much lower in the lobar bronchi/ major daughter airways and trachea. Immediately after short-term ozone exposures (8 h, 1 ppm), CYP2E1 activities were elevated only in the lobar bronchi/major daughter airways. These activities remained above the filtered air control at 1 day but returned to control levels by 2 days. Immunohistochemical assessment of CYP2E1 protein in ozone and filtered air-exposed animals was consistent with the activity measurements. After long-term ozone exposures (90 days, 1 ppm), CYP2E1 activities were decreased in the major and minor daughter airways. These studies indicate that CYP2E1 activities vary substantially by airway level. However, ozone exposure only results in minimal alterations in activity with varying concentration of ozone, length of exposure, and time after exposure in any of the lung subcompartments examined.

Neutrophils enhance removal of ozone-injured alveolar epithelial cells in vitro.

After acute exposure to oxidant gases in vivo, migration and accumulation of inflammatory cells in pulmonary epithelium coincides with epithelial cell necrosis. The present study was designed to test quantitatively the hypothesis that quiescent neutrophils enhance the removal of oxidant-injured pulmonary epithelial cells after exposure to ozone in vitro. Primary isolated rat alveolar type II cells were cultured as monolayers, using serum-free medium. After exposure to 0.1-0.5 ppm ozone for 0.5 h, apical sides of monolayers were administered either fresh nutrient medium only or medium containing quiescent human neutrophils. Monolayer bioelectric properties and cellular uptake of vital dye were recorded from 5 to 48 h after ozone exposure. Ozone dose-dependent increases in monolayer permeability were associated with proportionally higher numbers of injured epithelial cells. However, the direction and magnitude of neutrophil effects on monolayer permeability after ozone exposure were dependent on ozone concentration. Furthermore, neutrophil-treated monolayers exposed to 0.1 ppm ozone had significantly fewer attached cells positive for uptake of vital dye relative to monolayers exposed to the low level of ozone only; this effect was ablated with increasing ozone concentration. These data suggest that at high levels of ozone neutrophils may exacerbate injury to oxidant-impaired epithelial cells, whereas the presence of neutrophils after exposure to ambient concentrations of ozone may expedite the restoration of epithelial barrier function. We conclude that, by enhancing the removal of injured cells, neutrophils may facilitate the repair of centriacinar epithelium after ozone exposure in vivo.

In vitro exposure of tracheobronchial epithelial cells and of tracheal explants to ozone.

An in vitro system for exposing respiratory epithelial cells or explant tissues to ozone has been developed and characterized. This system is designed to generate and monitor consistent, reproducible levels of ozone, over a range of concentrations, in a humidified atmosphere, and to allow an exposure time of 24 h or longer. Based on chemical analysis, highly reproducible concentrations of ozone are delivered throughout the chamber, with a coefficient of variation of < 5% between five replicate vials exposed to 0.5 ppm of ozone for 50 min. The viability of cultured human tracheobronchial epithelial cells, as measured by the ability to oxidize a vital dye, and of rat tracheal epithelium, as measured by total numbers of necrotic cells in tracheal explants, after ozone exposure was examined in this system. Responses of cultured cells to ozone exposure as measured by bioassay were consistent with the observed low level of variability of ozone concentration between replicate incubation dishes or vials. Responses of cultured cells to ozone were proportional to duration of exposure and inversely proportional to the volume of medium covering the cells. We conclude that this newly developed in vitro exposure system will allow relatively simple and convenient exposure of cultured cells or organs to ozone or other gaseous agents under highly controlled and reproducible conditions.

Ozone injury to alveolar epithelium in vitro does not reflect loss of antioxidant defenses.

The objective of this study was to characterize an in vitro model of oxidant gas toxicity, using primary cultures of alveolar type II cells maintained in serum-free medium, by evaluating (1) epithelial barrier function, (2) the stability of cellular antioxidant defenses, and (3) the response of alveolar epithelial barrier properties to ozone exposure. Antioxidant enzyme activities and glutathione levels were measured in rat type II cells that were freshly isolated, cultured for 1 day in serum-supplemented medium, and subsequently grown in serum-free nutrient medium. After measurement of peak bioelectric properties on Day 4 in primary culture, alveolar epithelial monolayers were exposed to ozone at various concentrations and lengths of exposure. Ozone-induced alterations in monolayer bioelectric properties and impairment of cellular organization were used to evaluate oxidant injury. The primary effect of ozone exposure was a dose-dependent increase in monolayer permeability, which resulted from damage to intercellular junctions and/or loss of epithelial integrity. Extensive and persistent permeability increases correlated with focal areas of epithelial degradation. The focal nature of ozone injury to alveolar epithelium in vitro suggests that individual cell susceptibility to oxidant stress may account for the overall decrement in barrier function. However, this sensitivity does not result from overall loss of antioxidant defenses associated with cell culture, as these monolayers (when cultured in serum-free medium) maintained their antioxidant enzyme activities and glutathione content at levels found in freshly isolated cells. We conclude that the sensitivity of these monolayers to ozone injury in vitro reflects a disproportionate degree of oxidant stress on cell membranes relative to intracellular antioxidant defenses, i.e., cellular susceptibility to oxidant injury may depend on the ratio of the surface area of the cell to its cytoplasmic volume.

Aerosolized fluorescent microspheres detected in the lung using confocal scanning laser microscopy.

Aerosolized fluorescent microspheres were used to study particle deposition in site-specific regions of the lung with confocal laser scanning microscopy. A nebulizer was used to aerosolize microspheres followed by passage through a heated discharging column to reduce static charge and to remove water surrounding each microsphere. Precoating of microspheres with albumin helped to minimize displacement during vascular fixation of the lungs. Confocal laser microscopy facilitated visualization of microspheres throughout the bronchial tree, ducts, and alveoli of the lungs. The use of fluorescent microspheres and confocal laser imaging provided distinct advantages compared with other methods to study lung particle deposition due to (1) the generation of single microspheres of uniform size by nebulization, (2) easy detection of microspheres in large slabs of microdissected lung tissues, (3) excellent resolution of tissue surfaces and microspheres for an infinite number of orientations and planes of section, and (4) the ability to visualize microspheres below fluid lining layers and on surfaces that could not easily be done by other methods of microscopy.

Interaction of nitrogen dioxide with human plasma. Antioxidant depletion and oxidative damage.

Nitrogen dioxide (NO2.) is often present in inhaled air and may be generated in vivo from nitric oxide. Exposure of human blood plasma to NO2. caused rapid losses of ascorbic acid, uric acid and protein thiol groups, as well as lipid peroxidation and depletions of alpha-tocopherol, bilirubin and ubiquinol-10. No increase in protein carbonyls was detected. Supplementation of plasma with ascorbate decreased the rates of lipid peroxidation, alpha-tocopherol depletion and loss of uric acid. Uric acid supplementation decreased rates of lipid peroxidation but not the loss of alpha-tocopherol. We conclude that ascorbic acid, protein -SH groups, uric acid and alpha-tocopherol may be important agents protecting against NO2. in vivo. If these antioxidants are depleted, peroxidation of lipids occurs and might contribute to the toxicity of NO2..

Functional and morphologic changes caused by acute ozone exposure in the isolated and perfused rat lung.

Ozone has been shown to increase airway resistance and/or airway reactivity in vivo in animals and humans. Because of the complexities inherent in studying this phenomenon in whole animals, we developed a model of ozone-induced effects on airway physiology using the isolated perfused rat lung. Rat lungs were suspended in an airtight chamber and perfused via the pulmonary circulation with a modified Krebs-Henseleit buffer containing 4.5% bovine albumin. Ventilation of the lungs was achieved by generating a fluctuating negative pressure within the chamber (-2 to -7 cm H2O) at a rate of 60 breaths/min. The lungs were ventilated with humidified 95% air and 5% CO2 alone (control condition) or mixed with ozone at 1.0 or 2.0 ppm. Transpulmonary pressure, flow rate, and tidal volume were recorded at 0, 1, 2, and 3 hours, and pulmonary resistance (RL) and dynamic compliance (Cdyn) were calculated. There was no significant difference in lung weight/total body weight ratios between the three groups at the end of the 3-h period. RL increased and Cdyn decreased in a time- and dose-dependent manner with ozone exposure. The percent increase above baseline in RL +/- SEM at 3 h was 9.4 +/- 4.1% for control lungs, 21.0 +/- 3.2% for 1.0 ppm ozone-exposed lungs, and 63.6 +/- 13.5% for 2.0 ppm ozone-exposed lungs. The percent decrease below baseline in Cdyn +/- SEM at 3 h was 27.4 +/- 2.1% for control lungs, 37.1 +/- 2.7% for 1.0 ppm ozone-exposed lungs, and 55.2 +/- 7.3% for 2.0 ppm ozone-exposed lungs.(ABSTRACT TRUNCATED AT 250 WORDS)

Increased carbon monoxide excretion in Bolivian squirrel monkeys with fasting hyperbilirubinemia.

Pulmonary carbon monoxide (CO) excretion rates (VeCO) were 50% greater, on average, in Bolivian squirrel monkeys (BoSMs) which exhibit a unique fasting hyperbilirubinemia (FH), than in fasted control Brazilian squirrel monkeys (BrSMs). Since the catabolism of heme produces equimolar amounts of CO and bilirubin, the increased VeCOs are consistent with concurrent increases in endogenous bilirubin production rates. Tin-protoporphyrin, a competitive inhibitor of heme oxygenase, significantly decreased both the VeCO and serum bilirubin level in fasted BoSMs. Overproduction of bilirubin may be responsible in part for the marked FH in BoSMs.

Effect of ferrous sulfate aerosols and nitrogen dioxide on murine pulmonary defense.

A murine infectivity model was used to test the effect of exposure to atmospheres containing 290 +/- 50 microgram/m3 of respirable sized ferrous sulfate (FeSO4) particles (0.4 micron mass median aerodynamic diameter) and 1.0 ppm nitrogen dioxide (NO2) prior to infection with aerosols of Staphylococcus aureus or group C streptococci. Exposure to these combined pollutants for 24 or 48 hr did not impair pulmonary inactivation of S. aureus. Exposure to FeSO4 or NO2 for 48 hr, or to both pollutants for 24 or 48 hr, resulted in significant decreases in inactivation of inhaled group C streptococci. Mortality studies following pollutant exposure demonstrated earlier, but not an increased number of deaths. These studies demonstrate the importance of the test organism in assessing air quality standards with the infectivity model and enhanced toxicity and prolongation of exposure to relatively low levels of submicron-size particles of FeSO4 and NO2.

Generatation and characterization of sodium sulfite aerosols for applications in inhalation toxicologic research.

A method has been developed for generation of submicrometer aerosols of sodium sulfite suitable for use in inhalation toxicologic research. Concentrations ranging up to about 30 mg/m3 Na2SO3 were achieved in a 0.44 m3 exposure chamber with an air flow rate of 0.20 m3/min for periods up to 16 days. The coefficient of variation of the sulfite aerosol mass concentration was about 4% during a typical exposure period. The measured mass median aerodynamic diameters (MMADar) of the generated aerosols were 1.2 (+/- 0.2SD) microns with a geometric standard deviation (sigma g) of 1.9 (+/- 0.3SD). The chamber was sampled for gas phase SO2 concentration, and aerosol samples were analyzed for particulate sulfite and sulfate. The fraction of sulfur qas sulfite in the aerosol was usually 95% and was always greater than 90%. Gas phase SO2 amounted to less than 2% of the total S(IV) present in the chamber.

Effect of near ambient exposures to sulfur dioxide and ferrous sulfate particles on murine pulmonary defense mechanisms.

An infectivity model was used to test the safety margins for presently established air quality standards for sulfur dioxide and sulfate particles. Mice and rats were exposed to atmospheres of sulfur dioxide and mono-disperse ferrous sulfate particles from 3 to 6 times the standard for 17 hr prior to, or 4 hr after infection with aerosols of Staphylococcus aureus or Group C Streptococci. Exposure to these concentrations of pollutants did not impair the rodents' ability to ingest and inactivate the minimally virulent Straphylococcus or enhance the virulence of the Group C Streptococci. Insofar as these results can be extrapolated to man, the present air quality standards for sulfur dioxide and sulfate particles are protective in regard to respiratory bacterial infection.