Tritiated thymidine incorporation and the development of an interstitial lesion in the bronchiolar-alveolar regions of the lungs of normal and complement deficient mice after inhalation of chrysotile asbestos.

Inhaled asbestos causes the proliferation of bronchiolar-alveolar epithelial and interstitial cells in rats and mice 19 to 72 hours after a single 5-hour exposure. This condition is associated with rapid macrophage accumulation and development of an interstitial fibrotic lesion at alveolar duct bifurcations. In an attempt to define the mechanisms mediating asbestos-induced cell proliferation and fibrogenesis, we studied mice exposed to chrysotile asbestos for five hours. The mice were normal (strain B10.D2/nSn)(C5+) and a congenic strain (B10.D2/oSn), deficient in the fifth component of complement (C5-). We knew that the latter exhibit a depressed asbestos-induced macrophage response and wanted to learn whether the depressed response correlated with measurements of cell proliferation and progression of an interstitial lesion. Sections of first alveolar duct bifurcations were prepared for light microscopic autoradiography and ultrastructural morphometry at varying times after animal exposure to asbestos. In sham-exposed C5+ and C5- animals, less than 1% of epithelial and interstitial cells of the terminal bronchioles and alveolar ducts incorporated tritiated thymidine (3H-TdR) at any time after exposure to asbestos. Between 19 and 72 hours after exposure, epithelial and interstitial cells in both strains of mice exhibited significantly increased levels of 3H-TdR incorporation. The response decreased by eight days postexposure, and 3H-TdR incorporation was normal one month after exposure. Similarly, morphometry showed that both the C5+ and C5- asbestos-exposed mice exhibited significant increases in the volume density of epithelial and interstitial cells 48 hours after exposure. However, one month after exposure, the normal C5+ asbestos-exposed mice developed a fibrotic lesion, whereas the C5- asbestos-exposed animals were no different from sham-exposed C5- controls. The depressed macrophage response in the C5- animals does not appear to change the early mitogenic response to asbestos but may be central to the apparent attenuation of fibrogenesis.

The differentiation capacity of Clara cells isolated from the lungs of rabbits.

The purpose of our studies was to determine the growth and differentiation potential of Clara cells isolated from rabbit lungs. The Clara cell preparations were enriched (80 to 85%) by density gradient-elutriation procedures and then were inoculated into rat tracheas denuded of their own epithelium. These tracheas then were transplanted subcutaneously on the backs of nude mice. For purposes of comparison, other denuded tracheas were inoculated with mixed epithelial cells obtained from rabbit tracheas by enzymatic procedures. Control tracheas were inoculated with cell-free media. At 2, 4, and 14 weeks after transplantation, the tracheal grafts were removed from the recipient nude mice and examined by light and electron microscopy. Tracheal grafts not receiving cell inocula contained no epithelial lining, and the tracheal lumens were filled with loose connective tissue. Tracheas inoculated with 2 X 10(4) mixed tracheal cells showed a columnar, pseudostratified epithelium composed of five cell types: (a) poorly-differentiated cells, (b) ciliated cells, (c) mucous cells, (d) Clara-like cells, and (e) typical basal cells. A very different epithelium was established in tracheas repopulated with Clara cell isolates. This epithelium, at all time points examined, was cuboidal, single layered (never pseudostratified), and lacked basal cells. The tracheal lumens were lined with ciliated and nonciliated cells. The latter showed typical features of mature Clara cells (i.e., electron dense granules and smooth endoplasmic reticulum). At 14 weeks, the same two cell types were present, and often they were located on ridges and furrows of the tracheal walls. Mixed tracheal cells inoculated into denuded tracheas gave rise to a normal-appearing pseudostratified mucociliary epithelium, whereas the Clara cells inoculated under identical conditions gave rise to a low cuboidal epithelium resembling that seen in normal bronchioles. Establishment of these two types of epithelial linings occurred in the presence of the same mesenchymal components. Thus, we conclude that Clara cells have considerable self-renewal capacity, and their differentiation potential appears to be quite narrow.

Role of phagocytosis in Syrian hamster cell transformation and cytogenetic effects induced by asbestos and short and long glass fibers.

We have shown previously that asbestos and other mineral dusts, including glass fibers, induce cell transformation and chromosomal mutations in Syrian hamster embryo cells in culture. In the present study, we observed that both asbestos and glass fibers were phagocytized by these cells and accumulated in the perinuclear region of the cytoplasm. In order to understand the mechanism of fiber length-dependent cellular effects, we examined the phagocytosis and intracellular distribution of glass fibers of differing lengths in cells at various times after treatment. Glass fiber length was decreased by milling with a mortar and pestle. Cells treated with an equal dose of milled glass fibers (on a weight per surface area basis) were exposed to 7-fold more fibers since milling of glass fibers resulted in a 7-fold decrease in length with little change in diameter. However, cells exposed to milled glass fibers phagocytized a similar number of fibers as cells exposed to an equal mass of unmilled glass fibers, indicating that milled fibers were less readily phagocytized. In cells treated with either unmilled or milled glass fibers, the length of the intracellular fibers was more than 2-fold greater than the length of the fibers on the surface, suggesting that cells selectively internalized longer fibers. Fiber length, however, did not appear to affect the migration of intracellular fibers to the perinuclear region of the cytoplasm. Even though cells treated with milled glass fibers contained a similar number of fibers as those treated with unmilled glass fibers, the resulting cytotoxicity, transformation frequency, and frequency of micronuclei were greatly reduced in the cultures treated with milled glass fibers. Thus, fiber length appears to affect the phagocytosis of fibers as well as the ability of intracellular fibers to induce cytogenetic damage and the resultant transformation.

Vitamin E--a selective inhibitor of the NADPH oxidoreductase enzyme system in human granulocytes.

The cellular sites of H2O2 formation in phagocytizing granulocytes have been identified with cerium chloride. A precipitate was visible in phagosomes and on plasma membranes from intact normal cells in the presence of either 0.71 mM NADH or NADPH. X-ray microanalysis permitted identification of cerium deposition within the phagosomes even in the absence of reduced pyridine nucleotides. Catalase ablated the formation of the reaction product. Intact granulocytes obtained from subjects receiving 1600 units of vitamin E daily for 2 weeks exhibited reaction product in the presence of NADH but not NADPH. Intact cells from subjects treated with vitamin E demonstrated diminished numbers of phagocytic vesicles containing reaction product. During phagocytosis the granulocytes treated with vitamin E consumed oxygen but exhibited significantly reduced rates of hydrogen-peroxide-dependent glucose-1-14C oxidation to 14CO2. Isolated phagocytic vesicles obtained from granulocytes after ingestion of opsonized lipopolysaccharide-paraffin oil droplets contained reaction product when exposed to 0.71 mM NADPH. No reaction product was evident at 0.71 mM NADH but was evident at 2.0 mM NADH. Isolated phagocytic vesicles from the granulocytes of subjects receiving vitamin E exhibited reaction product only in the presence of NADH. These observations suggest that vitamin E interferes with the electron transport chain apparently required for the oxidation of NADPH to form H2O2 in the phagocytizing granulocyte.

Comparative studies of functional characteristics of mononuclear cell subsets and granulocytes.

Two human peripheral blood monocyte subsets and lymphocytes were isolated by counterflow centrifugal elutriation (CCE). The cell volumes of 303 mu3 and 380 mu3 were measured for the smaller and larger monocyte populations, respectively. Superoxide release by large monocytes exposed to opsonized zymosan was five times more active than that of the small monocytes. The production of colony stimulating activity was two-fold greater and the myeloperoxidase activity was 1.4-fold greater by the larger monocytes. Enriched fractions of cytotoxic cells responsible for natural killer (NK) activity against neuroblastoma cells were also obtained by counterflow centrifugal elutriation. Natural killer cells were obtained in larger lymphocyte fractions and had a mean cell volume of 180 mu3. Compared with the NK activity against the neuroblastoma cells, both the small and large monocytes displayed greater antibody-dependent cellular cytotoxicity (ADCC) activity against human erythrocytes. The larger peripheral blood monocytes aggregated in response to FMLP (N-formyl-methionyl-leucyl-phenyl alanine peptide) and PAF (platelet activating factor). Unlike the granulocyte, monocyte aggregation in response to FMLP was not accompanied by degranulation nor was it potentiated by cytochalasin B. In addition, monocyte aggregation could be blocked by benoxaprofen, unlike the granulocyte. Thus, CCE provides a means of isolating subsets of monocytes and lymphocytes and obtaining large numbers of peripheral blood monocytes for functional studies.

The effect of vitamin E on rabbit neutrophil activation.

Chemoattractants such as N-formylmethionyl leucyl phenylalanine (FMLP) cause neutropenia in vivo. The sequestered neutrophils may block the microvasculature and contribute to respiratory distress. Neutrophils from humans receiving 1600 units vitamin E per day have reduced oxidative activity. To test whether vitamin E attenuates the responses of neutrophils to FMLP in vivo we gave rabbits four daily intramuscular injections of 100 mg vitamin E. Serum levels of the vitamin were 2.34 +/- 0.15 mg% compared to 0.19 +/- 0.04 mg% in control rabbits receiving placebo injections. On the fifth day testing was done before and after injecting FMLP. Variables monitored were the absolute granulocyte count (AGC), systolic, diastolic and mean blood pressures (MBP), heart rate, PO2, PCO2, pH and respiratory rate. When 0.5 microgram FMLP was injected intravenously the AGC decreased (at 2.5 min the percentage change was -89.7 +/- 8.0 with vitamin E and -97.0 +/- 2.7 without vitamin E; P = 0.2). MBP decreased also (% change, -29.0 +/- 13.0 with vitamin E and -36.3 +/- 16.0, without vitamin E). By 15 min recovery was seen (AGC % change, -26.0 +/- 17 with vitamin E and -78.7 +/- 10.5, without vitamin E; P = 0.01; MBP % change, -9.3 +/- 3.8 with vitamin E and -52.3 +/- 10.1 without vitamin E). Chromatographic analysis of serum extracts revealed increases in 6-keto-PGF1 alpha after stimulation. Studies with [3h]thymidine-labelled neutrophils showed that the sequestered cells return to the circulation. Vitamin E might facilitate this return by altering the adherence of neutrophils to endothelium. This possibility was tested by measuring the adherence to cultivated rabbit aorta endothelial monolayers of FMLP-stimulated neutrophils from vitamin E-treated rabbits. The percentage of neutrophils adhering was 32.5 +/- 3.5 with vitamin E and 60.0 +/- 7.1, without vitamin E. Thus vitamin E promotes the return of neutrophils to the circulation after chemotactic challenge and may do so by reducing their adherence to endothelium.

Membrane-bound lactoferrin alters the surface properties of polymorphonuclear leukocytes.

Polymorphonuclear leukocytes (PMN) aggregate and avidly attach to endothelium in response to chemotactic agents. This response may be related in part to the release of the specific granule constituent lactoferrin (LF). We found by using immunohistology and biochemical and biophysical techniques that LF binds to the membrane and alters the surface properties of the PMN. Upon exposure of PMN treated with 5 micrograms/ml cytochalasin B to 2 x 10(-7) M formyl-methionine-leucine-phenylalanine for 5 min, the PMN mobilized LF to their surface as observed by immunoperoxidase staining for LF. At added LF levels ranging from 4 to 15 micrograms/10(7) PMN there was a dose-dependent reduction in PMN surface charge reaching 4 mV, when the partitioning into the membrane of a charged amphipathic nitroxide spin label was measured by electron spin resonance spectroscopy, whereas transferrin was without effect. When 125I-FeLF was added to human PMN in increasing amounts and the results corrected for the residual amount of free LF contaminating the cells, the PMN were saturated with LF at concentrations between 100 and 200 nM in the medium. Human PMN bound 1.35 x 10(6) molecules per cell and the calculated value for the association constant for these receptors was 5.2 x 10(6) M-1. Additionally, 6 micrograms/ml LF served as an opsonin for rabbit MN to promote PMN uptake by rabbit macrophages, when assessed by electron microscopy, but lysozyme did not. These studies indicate that LF can bind to the surface of the PMN and reduce its surface charge. This correlates with enhanced "stickiness" leading to a variety of cell-cell interactions.

Changes in energy metabolism, structure and function in alveolar macrophages under anaerobic conditions.

To determine whether the change in energy metabolism of guinea-pig alveolar macrophages (AM) would alter their function to resemble peritoneal macrophages (PM), AM were exposed to strict anaerobic environments for 96 h. Exposure of cultivated AM to hypoxic conditions resulted in a decreased activity of cytochrome oxidase, a key enzyme in oxidative phosphorylation, whereas pyruvate kinase activity, a key enzyme in glycolysis, increased to levels observed in PM. Under hypoxic conditions the total mitochondrial structure available for respiratory activity also decreased in the glycolytic energy-dependent AM. Accompanying the shift in energy metabolism, adaptive changes in the functional responses of lectin-receptor activity occurred in the AM exposed to hypoxic conditions. Culture of AM in an anaerobic environment led to a loss in their ability to mobilize their lectin receptors in response to cytochalasin B, whereas AM maintained in an aerobic environment could mobilize their receptors in response to either cytochalasin B and D. Alterations in O2 tension affect AM metabolism, morphology and function and indicate that the AM is able to change its energy metabolism according to environmental circumstances.