Effects of free fatty acids on the organization of cytoskeletal elements in lymphocytes.

Treatment of mouse lymphocytes with cis-unsaturated free fatty acids produced alterations in the immunofluorescence patterns of the cytoskeleton and contractile proteins. Saturated free fatty acids and trans-unsaturated free fatty acids had no effect. In untreated cells, the microtubular pattern exhibited radiation from an organizing center, resembling the spokes of an umbrella. The addition of linoleic acid produced a polarized submembranous aggregate. Under control conditions, staining for actin revealed a diffuse pattern over the entire cell, but the addition of linoleic acid caused the formation of a single large patch, or polarized submembranous aggregate. The pattern for alpha-actinin normally revealed intense perinuclear staining on a diffuse background. Linoleic acid caused the loss of this pattern and the formation of a polarized submembranous aggregate. Linoleic acid treatment also caused the pattern for myosin to change from diffuse to uniform submembranous patching around the periphery of the cell. For all of these proteins, calcium (8 mM), but not magnesium, partially reversed the effects of linoleic acid. Sodium azide had little effect on the normal distribution of actin, tubulin, and alpha-actinin; however, myosin staining revealed prominent patch formation. Colchicine treatment caused diffuse staining, some polarized submembranous aggregate formation of tubulin, and some patching of myosin, but not as extensively as did treatment with linoleic acid. Actin and alpha-actinin were unaffected. These results, in view of the previously shown facts that pretreatment of cells with linoleic acid followed by anti-immunoglobulin inhibits capping of surface immunoglobulin (Klausner, et al., Proc. Natl. Acad. Sci. U.S.A. 77:437-441, 1980) and that free fatty acids partition into the surface membrane (Klausner et al., J. Biol. Chem. 255:1286-1295, 1980), suggest that the perturbation of the plasma membrane with unsaturated free fatty acids alters the interaction of surface receptors with the cytoskeleton, which in turn affects cytoplasmic distribution of the proteins.

Relative mobility of con A and anionic receptor sites on the cell surface of lymphocytes. A quantitative-cytochemical study.

Events following the binding of Concanavalin A and cationized ferritin to the surface of normal human peripheral blood lymphocytes were followed using ultracytochemical methods. In this paper, we described a technique involving microdensitometry, which was employed in order to make a comparative cytochemical quantitation of the dense horseradish peroxidase-diaminobenzidine reaction products representing the states of Concanavalin A receptors under various conditions of distribution and redistribution. The technique presents a direct approach to the analysis of various probes that are currently being employed for studying the nature and distribution of various cell surface components. An attempt was also made to analyze the distribution of anionic sites, and their lateral redistribution is compared with the mobility of Concanavalin A receptors. The data presented suggests an independent mobility of receptors for Concanavalin A and cationized ferritin.

Modification of macrophage adhesion by ozone: role of cytokines and cell adhesion molecules.

The inflammatory response in the lungs following an inhalation exposure of animals and humans to ozone (O3) is associated with macrophage stimulation, release of chemotactic agents, and neutrophilia. This study investigated the adhesive behavior of the alveolar macrophages and its relevance to the inflammatory processes in the lung. Macrophages recovered by BAL from rats exposed to purified air or 0.8 ppm O3 were studied in vitro for their adhesion to epithelial cells derived from ARL-14. The macrophages from O3-exposed animals displayed greater adhesion to the epithelial cells than the macrophages from control rats exposed to purified air. The O3-induced adhesion was attenuated in the macrophages treated with a combination of interleukin-1 alpha and tumor necrosis factor-alpha antibodies (anti-IL-1+anti-TNF). The cell adhesion stimulated by O3 exposure was also attenuated when the macrophages were incubated in the presence of antibodies to leukocyte adhesion molecules, CD11b, or epithelial cell adhesion molecules, ICAM-1. A marginal increase in the surface expression of CD11b was noticed in macrophages from the rats exposed to O3. A similar change in the ICAM-1 expression was, however, not observed. The results suggest that the O3-induced modifications of macrophages are mediated by IL-1 and TNF, and that these modifications are accompanied by a minimal change in the expression of the cell-adhesion molecules.

Surfactant dysfunction after inhalation of nitric oxide.

To study whether nitric oxide (NO) affects surfactant function, 36 young rats inhaled one of the following humidified environments for 24 h: 1) air; 2) 95% O2; 3) air and 100 parts/million (ppm) NO; and 4) 95% O2 and 100 ppm NO. The treatments did not change the recovery of phospholipid from bronchoalveolar lavage (BAL). Exposure to NO of animals that breathed either air or 95% O2 increased the minimum surface tension of surfactant from BAL at low (1.5 mumol/ml), but not at high (4 mumol/ml), phosphatidylcholine concentration. After inhaled NO, the nonsedimentable protein of BAL decreased the surface activity of surfactant (1 mumol phosphatidylcholine/ml) more than the protein from the controls. NO treatment of animals that breathed either air or 95% O2 affected neither the quantity nor the molecular weight distribution of nonsedimentable protein. Hyperoxia increased the amount of the nonsedimentable protein, whereas NO increased the iron saturation of transferrin. The surfactant fraction and the nonsedimentable protein from BAL were separately exposed to 80 ppm NO in vitro. NO exposure had no effect on the surface activity of surfactant fraction. NO exposure of nonsedimentable protein from the control animals (no NO) increased the inhibition of the surface activity and changed the adsorption spectrum of the protein, suggesting conversion of hemoglobin to methemoglobin. Nonsedimentable protein from NO-exposed animals contained methemoglobin. We propose that surfactant dysfunction caused by inhaled NO is in part due to alteration of protein(s) in epithelial lining fluid that in turn inactivates surfactant.

Respiratory tract responses to repeated inhalation of an oxidant and acid gas-particle air pollutant mixture.

The purpose of this study was to examine a broad range of toxicologic responses in rats exposed to a multi-component pollutant atmosphere. Cumulative and adaptive respiratory tract responses to 3 concentrations of an inhaled particle-oxidant mixture were examined in Fisher 344 N rats exposed 4 h/day, 3 days/week for 4 weeks. The mixtures contained O3, NO2, NH4HSO4, carbon particles, and HNO3 vapor. Irritant-induced, rapid-shallow breathing responses were present during the first 4-h exposure to medium and high concentrations. Successive exposures showed diminished responses in medium concentrations and exacerbated responses in high concentrations. At the end of 4 weeks, rats exposed to high concentrations exhibited lung lesions. Lavaged pulmonary macrophages showed dose-dependent depressions of Fc-receptor binding and phagocytosis. Lung tissue macrophages showed dose-dependent increases in acid phosphatase staining density and carbon particles. Respiratory tract clearance of tracer particles was not significantly affected by the exposures. Broncho-alveolar epithelial permeability was increased by the high concentration. Epithelial cell-proliferation labeling showed a dose-dependent increase at all levels of the respiratory tract. Progressively exacerbated breathing-pattern responses at high concentrations were associated with lung lesions and high cell-proliferation labeling in the nose transitional epithelium and terminal bronchioles. Attenuating or adaptive breathing-pattern responses occurred in the presence of smaller, but in many cases still significant, compromise of respiratory functions. Either attenuating or exacerbated breathing-pattern responses can occur in the presence of a significant dose-dependent compromise of other respiratory functions and lung tissue injury.

The influence of polymorphonuclear leukocytes on altered pulmonary epithelial permeability during ozone exposure.

Ozone (O3), a pulmonary irritant, and a major toxic component of photochemical smog, is capable of inducing pulmonary inflammation characterized by recruitment of polymorphonuclear leukocytes (PMNs) into the lung. The recruited PMNs, in turn, can release toxic mediators and produce lung injury. The mechanism of ozone-induced changes in lung permeability remains unknown. It is our hypothesis that PMNs migrating into the lung play a significant role in the pathophysiology following O3 exposure and that increasing the number of PMNs coming into the lung will exaggerate the changes in lung permeability. To test this hypothesis, we induced an influx of PMNs into the lungs of Sprague-Dawley rats by intratracheal instillation of 1% rabbit serum and then exposed the animals to either 0.8 ppm O3 or filtered air for 3 h. Control animals were intratracheally instilled with phosphate-buffered saline (PBS) and simultaneously exposed to O3 or filtered air in the same manner as the serum-treated animals. The animals were sacrificed and the lungs lavaged 10-12 h after exposure. The bronchoalveolar lavage fluid (BALF) was analyzed for albumin and protein, as indicators of permeability. In addition, BALF from the various groups was tested for its ability to alter epithelial resistance of pulmonary type II cells in culture. O3 exposure resulted in a significant increase in albumin and protein levels in the BALF as compared to air-exposed controls. The instillation of serum resulted in a significant increase in airway PMNs, but no significant elevations in albumin levels in both the O3 and air-exposed groups, as compared to PBS instillation. In vitro studies did not reveal a differential BALF effect on epithelial resistance. The data demonstrate that an excessive neutrophilia in the lung is not matched by a comparable amplification of epithelial injury. It is therefore suggested that a simple elevation in PMN number in the air spaces, as that induced by serum instillation, does not necessarily augment the lung pathophysiology, but that a more complex interaction with O3 may be required for cellular activation and release of toxic products.

Alteration of ozone-induced airway permeability by oxygen metabolites and antioxidants.

This study determined the interactive effects of O3 and enzymatically-generated oxidants and antioxidants in the lung. Rats treated with dimethylthiourea (DMTU) or H2O2, generated by glucose/glucose oxidase, were exposed for 2 h to 0.6 or 0.8 ppm O3. A significant increase in the flux of total albumin in the bronchoalveolar lavage (BAL) and a concomitant elevation in the transport of 99mTc-diethylenetriaminepentaacetate (99mTc-DTPA) from trachea to blood occurred after O3 exposure. Pretreatment of rats with DMTU prevented the albumin flux in the BAL. Intratracheal instillation of glucose/glucose oxidase produced a localized response in trachea, but it did not affect the broncho-alveolar permeability. The results demonstrate an additive effect of O3 and an enzymatically-generated oxidant, and an antagonistic effect of an antioxidant in rats exposed to O3. The observations support the suggestion that a balance of oxidant-antioxidant system may be critical in maintaining respiratory integrity following O3 exposure.

Attenuation of ozone-induced lung injury by interleukin-10.

Ozone (O3), an oxidant air pollutant, is capable of producing pulmonary inflammation and injury. Exposure to O3 results in the release of inflammatory cytokines including tumor necrosis factor-alpha (TNF-alpha) and interleukin-1 (IL-1) by alveolar macrophages. In addition, O3 exposure results in an increased expression of the inducible isoform of nitric oxide synthetase (iNOS). Interleukin-10 (IL-10) is an anti-inflammatory cytokine which inhibits the synthesis of TNF-alpha and IL-1 by macrophages and decreases the expression of iNOS. To test the protective properties of IL-10 in vivo, on the pulmonary injury induced by O3 exposure, we intratracheally instilled rat recombinant IL-10 1 h prior to O3 exposure (0.8 ppm x 3 h). Approximately 10-12 h following exposure, the animals were sacrificed and the bronchoalveolar lavage fluid (BALF) collected. The quantification of albumin, protein and fibronectin in the BALF provided a means of assessing pulmonary injury while the analysis of the BALF cells reflected the inflammatory response. Ozone exposure resulted in a significant (P<0.05) increase in BALF albumin, protein and fibronectin content as compared to air-exposed controls. In addition, significant increases in the percentage of BALF polymorphonuclear leukocytes (PMNs) and tissue expression of fibronectin mRNA were observed. The intratracheal instillation of IL-10 prior to O3 exposure resulted in a significant reduction in BALF albumin, protein and fibronectin content, and lung fibronectin mRNA as compared to O3 exposure alone. The data shows that IL-10, when given intratracheally, significantly reduces the pulmonary injury following O3 exposure in the rat. However, since the PMNs and the levels of albumin, protein and fibronectin in the IL-10 treated group did not reach baseline values, we conclude that other mediators of inflammation and injury not regulated by IL-10 also contribute to the pathophysiology of O3-induced lung injury.

Inhalation of resuspended road dust, but not ammonium nitrate, decreases the expression of the pulmonary macrophage Fc receptor.

Pulmonary macrophages (PM) play a key role in the immune defenses of the lung. When stimulated, PM express Fc receptors (FcR) that regulate the immune response. PM were assayed for FcR expression following subchronic inhalation exposure of adult Fischer 344 rats to either 90 micrograms/m3 nitrate (NH4NO3), 300 micrograms/m3 road dust, or clean air, for 4 h/day, 4 days/week, for 8 weeks. PM were lavaged from the lungs and attached to glass coverslips for 18 h. PM FcR were labelled with rat IgG conjugated with cyanine-3. For each exposure, FcR were determined with a Meridian ACAS 570 confocal cytometer by imaging the fluorescence of 50 cells. We found that the IgG binding to FcR (in arbitrary fluorescence units, FU, per cell) for PM from road dust exposed rats was less (835 +/- 39.3 FU/cell) than that for PM from both ammonium nitrate or clean air-exposed rats (1115 +/- 58.0 FU/cell and 1123 +/- 46.6 FU/cell, respectively). While acid incubation conditions in vitro (pH 5.5 for 30 min to simulate the acid environment of ammonium nitrate inhalation) resulted in a 16% decrease in IgG binding (P < 0.05), IgG binding to PM from acid aerosol exposed rats was no different than the IgG bound to PM from clean air-exposed rats. PM exposed to road dust in vivo expressed 25% fewer FcR (P < 0.05). Three-dimensional images of PM failed to show any major alterations in FcR distribution. These preliminary results indicate cellular recognition of antibody-immune complexes may be impaired by subchronic exposure to road dust, which could decrease the immune response of road dust exposed animals.

Lung injury, inflammation, and inflammatory stimuli in rats exposed to ozone.

The effects of ozone (O3) on airway epithelia, inflammation, and expression of inflammatory stimuli were investigated to delineate the mechanisms of inflammatory reactions relevant to lung injury. Because the airway responses to O3 develop gradually, this investigation included a time-sequence analysis. Rats exposed for 3 h to 1 ppm O3 were studied at 4-h intervals up to 20 h postexposure. Bronchoalveolar lavage fluid (BAL) was analyzed for albumin as an indicator of increased permeability, polymorphonuclear leukocytes (PMNs) to assess the inflammatory status, macrophage inflammatory protein-2 (MIP-2, an inflammatory chemokine), and cell adhesion molecules for their role in inflammation and PMN functions. The time-related increase in albumin was matched by a similar significant increase for PMNs, MIP-2, and intercellular adhesion molecule-1 (ICAM-1). However, no marked change occurred for beta-2 integrin (CD-18) and leukotriene B4 (LTB4). The results establish a temporal correlation of epithelial permeability with changes in inflammatory activity and stimuli responsible for PMN recruitment in the lung. The observations of elevated MIP-2 and ICAM-1 levels are consistent with their role in injury and inflammation. An early expression of MIP-2 mRNA in BAL cells, that is, immediately post O3 exposure, and the peak increase in BAL MIP-2 levels 4 h later support the chemotactic role of MIP-2 in PMN recruitment at 4- and 12-h time points. The rapid drop in MIP-2 and ICAM-1 levels appears to signal the termination of inflammatory cell recruitment, which is accompanied by an onset of recovery.

Alteration of epithelial integrity, alkaline phosphatase activity, and fibronectin expression in lungs of rats exposed to ozone.

The deleterious effects of ozone (O3), an oxidant air pollutant, in the lung are dependent on dose and exposure duration and generally evolve with time postexposure. This study characterized the time sequence of epithelial injury and fibronectin expression in the lungs of rats exposed to O3. Bronchoalveolar lavage (BAL) fluid was analyzed for alkaline phosphatase and total protein as markers of epithelial injury and increased permeability, and fibronectin for its role in inflammation and lung injury. The results revealed a time-related increase in total protein in the BAL fluid following a 3-h exposure of rats to 1 ppm O3. The increased protein concentrations peaked at 12 h and then declined, but remained significantly higher than control at 24 h postexposure. A similar time-related significant increase also occurred for BAL fibronectin and alkaline phosphatase activity. However, the return of alkaline phosphatase levels to baseline prior to a comparable reduction in protein levels suggests repair of injured cells, but a delay in the formation of epithelial junctions that limit the transfer of serum proteins to air spaces. By cytochemistry, alkaline phosphatase activity was detected in association with lung type II epithelial cells and in BAL polymorphonuclear leukocytes (PMNs), but not in macrophages. While a significant increase in cytochemically detectable alkaline phosphatase resulted from the increase in PMN number following O3 exposure, mononuclear cells constituted the primary cell type responsible for fibronectin mRNA upregulation. While the cytochemical observations support the role of inflammatory cells in the injury process, the comparability of temporal changes in BAL protein, fibronectin, and alkaline phosphatase suggests a mechanistic role for fibronectin in lung injury.

Transport of macromolecules and particles at target sites for deposition of air pollutants.

This study analyzed rats' nasal, tracheal and bronchoalveolar epithelial permeability to macromolecules after they were exposed, in 2- or 4-hour periods of rest or exercise, to ozone (O3) (0.6, 0.8 or 2 ppm), nitrogen dioxide (NO2) (2.5, 6 or 12 ppm) or formaldehyde (10 ppm). Exercise was performed on a treadmill operated at a speed that led to a 2-fold increase in oxygen consumption. Histopathologic and electron microscopic cytochemical and autoradiographic studies were performed to identify the structural aspects of mucosal response. In rats not exposed to pollutants, the quantity of macromolecular tracers (99mTc-DTPA, 125I-BSA) in blood sampled 6, 7, 8, 9 and 10 minutes after a slow 5-minute instillation of comparable quantities of tracer molecules in the lumen of each zone, was lowest in nasal, highest in tracheal, and intermediate in the bronchoalveolar region. Exposure of resting rats to O3 did not affect nasal permeability, but tracheal and bronchoalveolar permeabilities increased by 2-fold 1 hour after the exposure. In rats exposed at rest to O3, tracheal permeability was no longer elevated 24 hours after exposure, but bronchoalveolar permeability remained elevated at 24 hours after exposure and was normal at 48 hours. Exposure during exercise increased the effect of O3 in the trachea and in the bronchoalveolar zone. However, exercise also prolonged the duration of the O3 effect on the tracheal zone from 1 hour to 24 hours and, in the bronchoalveolar zone, from 24 hours to 48 hours. Histologically, focal inflammatory lesions in the alveolar zone were maximal at 48 hours after a 4-hour resting exposure to O3. After exposure during exercise, the area of lung involved by lesions increased 4- to 7-fold above the lesion-bearing area in rats exposed while resting. By electron microscopy, horseradish peroxidase (HRP) was localized in epithelial intercellular spaces, but not in the apical tight junctions, of tracheal epithelial cells from O3-exposed rats; no HRP was found in intercellular spaces in controls. The number of HRP-containing endocytic vesicles in tracheal epithelial cells was 2-fold greater in rats exposed to O3 than in control rats. This 2-fold increase in vesicles presumed to be transporting HRP matches the 2-fold increase in transfer of DTPA from the tracheal lumen to the blood. Electron microscopic autoradiography revealed 125I-BSA accumulation in subepithelial connective tissue, and electron microscopic cytochemistry identified accumulation of HRP not only between cells but also at the basal lamina.(ABSTRACT TRUNCATED AT 400 WORDS)

Alteration of alveolar macrophage chemotaxis, cell adhesion, and cell adhesion molecules following ozone exposure of rats.

Ozone (O3) exposure of humans and animals induces an inflammatory response in the lung, which is associated with macrophage stimulation, release of chemotactic agents, and recruitment of polymorphonuclear leukocytes (PMNs). This study was designed to investigate the functional aspects of the macrophages that impact inflammatory processes in the lung. Macrophages recovered by bronchoalveolar lavage (BAL) from rats exposed to purified air or 0.8 ppm O3 were studied for their chemotactic activity, adhesive interactions with alveolar epithelial cells in culture, surface morphology, and surface expression of cell adhesion molecules. The macrophages isolated from O3-exposed rats exhibited a greater motility in response to a chemotactic stimulus than the macrophages isolated from rats exposed to purified air. The macrophages from O3-exposed animals also displayed greater adhesion when placed in culture with epithelial cells isolated from adult rat lung (ARL-14) than the macrophages from control rats. Both chemotactic motility and cell adhesion stimulated by O3 exposure were attenuated when the macrophages were incubated in the presence of monoclonal antibodies to leukocyte adhesion molecules, CD11b, or epithelial cell adhesion molecules, ICAM-1. Flow cytometry revealed a modest increase in the surface expression of CD11b but no change in ICAM-1 expression in macrophages from O3-exposed rats when compared to those from the air-exposed controls. The results demonstrate an alteration of macrophage functions following O3 exposure and suggest the dependence of these functions on the biologic characteristics, rather than the absolute expression, of the cell adhesion molecules.

Ozone-induced lung inflammation and mucosal barrier disruption: toxicology, mechanisms, and implications.

The airway epithelial lining serves as an efficient barrier against penetration of exogenous particles and macromolecules. Disruption of this barrier following O3 exposure represents a state of compromised epithelial defenses leading to increased transmucosal permeability. Although the barrier disruption following an acute exposure is transient in nature, the brief period of disruption caused by O3, an oxidant air pollutant, provides an opportunity for facilitated entry of a potentially toxic particulate copollutant(s) across the airway epithelia. The subsequent deposition and retention of the copollutant(s) in the subepithelial compartment for prolonged periods adds the risk of injury due to chronic exposure following an acute episode. Toxicological studies from several laboratories have demonstrated alterations in epithelial permeability, suggestive of barrier disruption, in animals and humans exposed to O3. Inflammatory cells represent another important component of pulmonary defenses, but upon activation these cells can both induce and sustain injury. The recruitment of these cells into the lung following O3 exposure presents a risk of tissue damage through the release of toxic mediators by activated inflammatory cells. Several studies have reported concomitant changes in permeability and recruitment of the inflammatory cells in the lung following O3 exposure. In these studies, an inflammatory response, as detected by an increase in the number of polymorphonuclear leukocytes in the bronchoalveolar lavage (BAL) or in lung parenchyma, was accompanied by either an increased tracer transport across the airway mucosa or an elevation in the levels of total protein and/or albumin in the BAL. The magnitude of response and the time at which the permeability changes and inflammatory response peaked varied with O3 concentration, exposure duration, and the mode of analysis. The responsiveness to O3 also appeared to vary with the animal species, and increased under certain conditions such as physical activity and pregnancy. Some of the effects seen after an acute exposure to O3 were modified upon repeated exposures. The responses following repeated exposures included attenuation, persistence, or elevation of permeability and inflammation. Mechanistic studies implicate chemotactic factors, cellular mediators, and cell-surface-associated molecules in the induction of inflammation and lung injury. In discussing these studies, this review serves to introduce the mucosal barrier functions in the lung, evaluates inflammatory and permeability consequences of O3, addresses mechanisms of inflammatory reactions, and offers alternate viewpoints.

Pulmonary epithelial permeability in rats exposed to O3.

Measurements of pulmonary epithelial permeability were made in rats exposed for 2 h to either purified air or ozone (O3) at concentrations of 0.8 or 2 ppm. [99mTc]Diethylenetriaminepentaacetate ([99mTc]DTPA) (492 daltons) and 125I-labeled bovine serum albumin ([125I]BSA) (69,000 daltons) were injected intravenously, and the lungs were lavaged 6 min later. In rats exposed to air, transfer of the larger tracer molecule (BSA) from blood to the lavage fluid was less than that of the smaller molecule (DTPA) when the amount of tracer in the lavage fluid was calculated as percent of the counts in femoral artery blood 5 min after injection, i.e., 1 min prior to lavage. In rats exposed to O3, alveolar permeability increased in a dose-related fashion, the increase under all exposure conditions was greater for the smaller molecule than for the larger one, and the permeability was reversible with time. The increase in permeability from blood to air was comparable to the increase from air to blood reported earlier (Bhalla et al., 1986). The increased permeability provided an early and reliable indicator of short-term O3 exposure effect in rats. Autoradiography by electron microscopy identified multiple pathways for BSA transfer from blood to the alveolar space. Grains produced by [125I]BSA were localized over endothelial and epithelial cell surfaces, were associated with cytoplasmic vesicles, were over cell surface invaginations, and were found in the cytoplasm of apparently degenerating cells. Although defects in tight junctions of alveolar type I cells were observed in lungs of rats exposed to O3, autoradiographic grains also appeared in intercellular spaces, with the intercellular junctions remaining intact.

Tracheal permeability in rats exposed to ozone. An electron microscopic and autoradiographic analysis of the transport pathway.

Exposure of rats to ozone (O3), 0.8 ppm increases the tracheal permeability to 99mTc-diethylenetriaminepentaacetate (99mTc-DTPA) about twofold but to 125I-bovine serum albumin (125I-BSA) to a lesser extent. It is generally believed that exposure to air pollutants causes perturbation of tight junctions and formation of intercellular channels for the passage of molecules from airway lumen to blood. We now report that a second mechanism, vesicular transport, is operative in the transepithelial movement of molecules, that this mechanism is speeded in tracheas of O3-exposed rats, and that there is a concurrent delay in movement of BSA from connective tissue to capillaries after O3 exposure. Horseradish peroxidase (HRP) instilled in trachea was taken up by endocytic vesicles, which could be localized in apical as well as basal regions of ciliated and nonciliated cells. A count of HRP-positive vesicles and measurement of their surface area revealed an approximate twofold increase in O3-exposed rats over that in control animals breathing clean air; this paralleled a twofold increase in transport of 99mTc-DTPA from tracheal lumen to blood. An autophagocytic process induced in tracheal epithelial cells by O3 is proposed. Despite the difference in the size of HRP and BSA, the 2 molecules migrated through common pathways and were colocalized in the luminal membranes as well as in endocytic vesicles and intercellular spaces in double labeling experiments involving simultaneous detection of HRP by cytochemistry and 125I-BSA by autoradiography. This procedure proved particularly useful in detecting a dramatic accumulation of 125I-BSA autoradiographic grains in subepithelial connective tissue and HRP accumulation in intercellular spaces and at the basal membrane-connective tissue junction in O3-exposed rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Time course of permeability changes and PMN flux in rat trachea following O3 exposure.

Changes in rat tracheal epithelial permeability and polymorphonuclear leukocyte (PMN) populations during a 24-hr time period following a 3-hr exposure to 0.8 ppm ozone (O3) were investigated. An increase in permeability to 99mTc-diethylene-triaminepentaacetate (DTPA) occurred immediately after the exposure, peaked at the 8-hr time point and decreased to control level by 24 hr. For correlation with tracheal permeability, tracheal cross sections were stained with naphthol AS-D chloroacetate and PMNs were scored by their location as well as staining characteristics (positive or negative). The total PMN population remained at the control value at the 0-, 4-, and 8-hr time points, and increased at 12 hr, followed by a rapid decline to below the control value for the remaining time points. There was a shift at the 8-hr time point in the population location, from the vasculature to the interstitium, which returned to control values at 12 hr. The percentage stained PMNs increased significantly at 16 hr while remaining at control values for all other time points. The data reveal that there is a significant increase in tracheal epithelial permeability immediately after the exposure, but the overall increase in the PMN population is preceded by a lag phase. A decrease in the vascular pool of PMNs concomitant with an increase in the interstitial pool of PMNs suggests their migration from blood to the interstitium after ozone exposure. These data indicate that while PMNs may play a role in permeability changes of tracheal epithelium, the initiation is most likely due to other factors.

Transport across rat trachea in vitro after exposure to cytoskeleton-active drugs in vitro or to ozone in vivo.

Full-length tracheas from Sprague-Dawley rats were exposed to cytoskeleton-active drugs in short-term organ culture, and the permeability of the tracheal epithelium was measured by instilling radiotracers into the lumen and assay of the radioactivity appearing in the external bathing medium. In vitro treatment with cytochalasin D (cyto D, 2-10 x 10(-6) M) increased the rate of movement of [14C]mannitol across the epithelium. Exposure to vinblastine (VB, 10(-4) M) alone had no significant effect. However, VB in combination with cyto D increased the permeability in a dose-dependent manner. In vivo exposure to ozone (O3, 0.8 or 2.0 ppm, 2 h) had only a slight effect on the rate of movement of the tracer as measured in vitro immediately after exposure. At 24 h postexposure there was no significant difference in permeability between ozone- and air-exposed tracheas. Prior in vivo O3 exposure sensitized the tracheas to the in vitro effects of cyto D; treatment of O3-exposed tracheas with cyto D immediately after O3 exposure produced a greater than additive effect on permeability measured in vitro. VB at concentrations up to 10(-4) M had no enhancing effect on permeability in O3-exposed tracheas. Sham exposure to clean air did not affect permeability compared to untreated (shelf) controls. Electron microscopic studies demonstrated penetration of horseradish peroxidase into intercellular spaces in the tracheas treated in vitro with cyto D or cyto D plus VB. Cyto D is known to affect intracellular microfilaments that have attachments at or near the cell surface, while VB affects microtubules associated with internal cellular structures. Therefore, the synergistic effect on tracheal permeability observed with O3 and cyto D, but not with O3 and VB, suggests that O3 may change cell surface structures associated with the microfilamentous cytoskeleton.

Migration of B and T lymphocytes to M cells in Peyer's patch follicle epithelium: an autoradiographic and immunocytochemical study in mice.

Intimate interaction occurs between M cells which take up antigens in Peyer's patch epithelium and underlying lymphocytes but the migratory pathway and subtypes of these lymphocytes have remained uncertain. Lymphocyte homing to Peyer's patches was investigated by separating mouse splenic B and T lymphocytes, labeling with [3H]adenosine, reinjecting into syngeneic mice, and localizing them by autoradiography after 17, 40, and 68 hr. Both B and T lymphocytes migrated across postcapillary venules through intercellular spaces. Most labeled cells of both types localized around postcapillary venules in the initial time period, then migrated through the lymphoid mass to follicle epithelium. T-cell number in follicle epithelium peaked at 17 hr but B cells peaked at 40 hr. At each time point more labeled B than T lymphocytes were found below M cells and in follicle epithelium but the differences were only significant (P less than 0.01) at 40 hr. Endogenous B lymphocytes, identified by antibody staining, were also associated with M cells, possibly reflecting a role for secretory antibody in modulating antigen uptake.