Simultaneous analysis of surface marker expression and cell cycle progression in human peripheral blood mononuclear cells.

One method for examining cell cycle kinetics by flow cytometry uses continuous DNA labeling with bromodeoxyuridine (BrdU), a thymidine analogue. Upon incorporation into DNA, BrdU causes stoichiometric quenching of the DNA fluorochrome Hoechst 33258. After counterstaining with a secondary DNA fluorochrome (e.g., ethidium bromide), the analyst can distinguish cells in different phases of the cell cycle over a number of mitotic cycles with flow cytometry. In this report, we describe a modification of the flow cytometric BrdU-Hoechst assay that allows combined analysis of cell proliferation and immunophenotyping at the single cell level. To demonstrate an application of this method, human peripheral blood mononuclear cells were stimulated with tetanus toxoid or interleukin-2 for up to 6 days in the presence of BrdU, harvested, and immunostained for the cell surface markers CD3, CD4, CD8, CD14, CD19, and the cytokine receptor, CCR5. We used four-color flow cytometry analyses to simultaneously measure cell proliferation and surface marker expression, for the purpose of immunophenotyping and identifying specific cell subsets responding to antigen stimulation. Our successful application of this method suggests that it may be used to study immune responses at the molecular and cellular level and to identify mechanisms of immune system modulation.

Ozone alters the distribution of beta1 integrins in cultured primate bronchial epithelial cells.

The effects of 0.5 ppm ozone exposure for 6 h on the synthesis and distribution of beta1 integrins were examined in bronchial epithelial cells cultured at an air-cell interface. Ozone exposure damaged cilia and caused significant cell loss. Immunocytochemical localization and quantification of the beta1 subunit in the remaining attached cells using scanning laser cytometry demonstrated time-dependent changes in beta1 distribution in response to ozone. Although no changes were detected immediately after exposure, beta1 immunoreactivity increased 23 +/- 5% and 66 +/- 6% at 6 and 24 h, respectively. The increased immunostaining was localized at the apical surfaces and, to a lesser extent, at cell-cell contacts of cultured cells. Furthermore, integrin redistribution was not due to increased messenger RNA (mRNA) levels and protein synthesis because levels of beta1 mRNA and newly synthesized beta1 protein did not change after ozone exposure. However, immunoprecipitation analysis of beta1 integrins in lysates from equal numbers of cells showed that ozone-exposed cells contained 90 +/- 15% more total beta1 subunit at 24 h after exposure. In addition, our results demonstrated the presence of the alpha5beta1 integrin complex in bronchial epithelial cells and that the detergent-soluble amount of its associated beta1 subunit increased 60 +/- 10% in lysates of ozone-exposed cells. In conclusion, ozone altered cellular distribution of beta1 integrins in the remaining attached cells subsequent to cell injury and loss. The changes in beta1 distribution might be due to increased detergent extractibility of beta1 integrins rather than a real increase in the synthesis of beta1 integrins.

Release of RANTES from nasal and bronchial epithelial cells.

RANTES is a chemokine with eosinophil attractant and activating activities. This study was undertaken to determine whether primary cultures of human nasal and primate bronchial epithelial cells produce RANTES and the effect of various cytokines and dexamethasone on the release of this chemokine. Nasal epithelial cells from 32 patients (HNE) and bronchial epithelial cells from 17 Macaca nemestrina monkeys (PBE) were cultured in vitro for 24 to 72 h with LPS, TNF-alpha, IL-1 beta, IFN-gamma and TNF-alpha combined with IFN-gamma and/or dexamethasone at 10 to 1000 micrograms/ml. Culture supernatants were assayed for RANTES by ELISA. RANTES synthesis was measured by immunoprecipitation. HNE and PBE released modest constitutive amounts of RANTES (350 to 1000 pg/ml) which did not increase with time in culture. Release of RANTES was stimulated by all activators except LPS in a time-dependent manner, with the greatest synthesis induced by the combined addition of TNF-alpha and IFN-gamma. The combination of these activators also increased RANTES synthesis as determined by immunoprecipitation. Dexamethasone at 100 and 1000 micrograms/ml produced significant inhibition of stimulated RANTES release. These data indicate that normal nasal and bronchial epithelial cells release RANTES which is upregulated by various cytokines and inhibited by dexamethasone. The enhanced release is due to stimulation of both synthesis and secretion. Production of RANTES by epithelial cells could contribute to the inflammation that characterizes the respiratory tract in asthma and rhinitis and downregulation of RANTES by glucocorticoids may be one mechanism of the therapeutic effect of these agents.

Lung lining fluid modification of asbestos bioactivity for the alveolar macrophage.

It is likely that chrysotile fibers deposited in the lower respiratory tract become rapidly coated by components of lung lining fluid. Therefore, we have used lung lining fluid and its components as part of an in vitro model to study chrysotile stimulation of superoxide anion production by the alveolar macrophage. In terms of superoxide anion production, lung lining fluid-treated chrysotile was 50% as effective as the untreated fibers. Fractionated lung lining fluid components and pure phospholipids were tested individually for their effects on chrysotile bioactivity. Pretreatment of chrysotile with lung surfactant isolated from a 30,000g pellet of lung lining fluid decreased chrysotile-stimulated superoxide anion production by 90%. The inhibitory activity of lung surfactant was found to reside in a chloroform extract containing hydrophobic proteins and lipids. Total proteolysis of the proteins did not affect the inhibitory activity of the chloroform extract, but treatment with phospholipase C significantly decreased its inhibitory activity. The inhibitory effects of lung surfactant could be simulated with phosphatidylinositol, phosphatidylserine, and phosphatidylglycerol at concentrations equivalent to those found in lung lining fluid. These results strongly suggest that phosphatidylinositol, phosphatidylserine, and phosphatidylglycerol in lung lining fluid can modify chrysotile bioactivity for the alveolar macrophage. Together with previous results indicating that IgG enhances asbestos bioactivity, it would appear that lung lining fluid contains components that can either inhibit or enhance the bioactivity of asbestos and that it is the relative amounts of these components that determines the overall bioactivity of the fiber.