Cigarette smoke alters plasma membrane fluidity of rat alveolar macrophages.

This study examined the effect of cigarette smoking on the fluidity of the rat alveolar macrophage plasma membrane. Rats were subjected to 8 wk of an in vivo smoke exposure protocol, after which their alveolar macrophages were harvested. Fluidity was assessed by measuring steady-state anisotropy of isolated plasma membranes as well as of lipid vesicles made from total lipid extracts of these plasma membranes. The smoke-exposed animals showed a significant decrease in fluidity in both intact plasma membranes (p less than 0.0001) and in their lipid vesicle preparations (p less than 0.0001). To assess the time course of these changes, lipid vesicles were prepared from total cellular lipid extracts of macrophages from paired rats, control and smoke-exposed, at 1 through 4 wk after initiation of exposure. Significant decreases in fluidity were observed as early as 2 wk after smoking was begun (p less than 0.001). To assess the reversibility of these changes, paired rats were exposed for 8 wk, then withdrawn for 8, 12, and 18 wk, after which fluidity was evaluated in lipid vesicles prepared from total cellular lipids. Even after 18 wk of smoking cessation, significant decreases in fluidity persisted (p less than 0.01). We conclude that cigarette smoking causes a decrease in plasma membrane fluidity of rat alveolar macrophages. This is due at least in part to a change in the lipid portion of the membrane. These alterations occur after a very brief period of smoke exposure and persist long after cessation of smoking.

Serotonin transport and fluidity in plasma membrane vesicles: effect of hyperoxia.

Plasma membrane vesicles were prepared from porcine pulmonary artery endothelial cells by a dextran-polyethylene glycol two-phase system. Specific carrier-mediated transport of 5-hydroxytryptamine (5-HT) into the vesicles was examined. Transport required a Na+ gradient (out greater than in) across the membrane, and accumulated 5-HT rapidly effluxed out of the vesicles when the ionophore gramicidin was added. Transport was inhibited by the antidepressant imipramine. 5-HT transport into plasma membrane vesicles appeared saturable and exhibited Michaelis-Menten kinetics (Km 7.4 microM, maximal velocity 217 pmol.min-1.mg membrane protein-1). A 24-h exposure to 95% O2 at 1 atmosphere absolute resulted in a 21% decrease (P less than 0.05) in specific 5-HT transport by plasma membrane vesicles. Hyperoxia also caused a significant (P less than 0.01) decrease in plasma membrane fluidity, as measured with the fluorescence probe 1,6-diphenyl-1,3,5-hexatriene. These results indicate that pulmonary artery endothelial cell plasma membrane vesicles provide a good model for studying 5-HT transport activity in vitro. Hyperoxia affects plasma membrane fluidity and 5-HT transport in pulmonary artery endothelial cells, suggesting a possible cause-and-effect relationship between the two.

Plasma membrane fluidity measurements in intact endothelial cells: effect of hyperoxia on fluorescence anisotropies of 1-[4-(trimethylamino)phenyl]-6-phenyl hexa-1,3,5-triene.

Fluorescence anisotropy measurements are widely used as sensitive indicators of cell membrane fluidity. 1-[4-(trimethylamino)phenyl]-6-phenyl hexa-1,3,5-triene (TMA-DPH) is a cationic fluorescent aromatic hydrocarbon that anchors at the lipid-water interface of membrane lipid bilayers. Its uptake into porcine pulmonary artery and aortic endothelial cells was monitored and the probe remained specifically localized on the cell surface for at least 4 h. It can therefore be recommended for use for specific plasma membrane lipid fluidity measurements in these cells. The effect of hyperoxia on plasma membrane fluidity was measured by using TMA-DPH. In both cell types, hyperoxic damage resulted in decreases in plasma membrane fluidity. Recovery was achieved 48 h after a 42-h hyperoxic exposure. These results indicate that TMA-DPH is a sensitive probe of plasma membrane lipid domains of pulmonary artery and aortic endothelial cells and that hyperoxia causes reversible changes in the physical state of superficial lipid domains of the plasma membrane of these cells.

Hyperoxia reduces plasma membrane fluidity: a mechanism for endothelial cell dysfunction.

To evaluate the relative contributions of three possible mechanisms that can be advanced to explain the observation that hyperoxia decreases serotonin uptake by endothelial cells, we examined the effect of high O2 tensions on Na+-K+-ATPase activity, ATP content, and plasma membrane fluidity in cultured endothelial cells. Confluent monolayers of pulmonary artery and aortic endothelial cells were exposed to 95% O2 (hyperoxia) or 20% O2 (controls) in 5% CO2 at 1 ATA for 4-42 h. Exposure to high O2 tensions had no effect on Na+-K+-ATPase activity or ATP content in pulmonary artery or aortic endothelial cells in culture. However, hyperoxia decreased the fluidity of the plasma membrane of pulmonary artery and aortic endothelial cells in culture, and the time course for the decrease in fluidity parallels that of the hyperoxic inhibition of serotonin transport. These results indicate that hyperoxia decreases fluidity in the hydrophobic core of the plasma membranes of cultured endothelial cells. Such decreases in plasma membrane fluidity may be responsible for hyperoxia-induced alterations in membrane function including decreases in transmembrane transport of amines.

Endotoxin protects against hyperoxic decrease in membrane fluidity in endothelial cells but not in fibroblasts.

We evaluated the ability of endotoxin to protect against hyperoxic depression of plasma membrane fluidity in endothelial cells and fibroblasts in culture. Second- to-fifth passage porcine aortic endothelial cells and human newborn foreskin fibroblasts with 20 ng/ml of endotoxin or diluent in the culture medium were exposed to 20% O2 (control) or 95% O2 (hyperoxic) in 5% CO2 for 4 hours. After exposure, cells were labeled with 1,6-diphenyl-1,3,5-hexatriene (DPH), an aromatic hydrocarbon that partitions into the hydrophobic core of lipid bilayer membranes, or transparinaric acid (TPA), a natural, conjugated fatty acid that orients parallel to fatty acyl chains of membrane phospholipids. Membrane fluidity was monitored by measuring changes in the steady state fluorescence anisotropies (rs) for DPH and for TPA by using fluorescence spectroscopy. Reductions in membrane fluidity increase the value of rs. Addition of endotoxin to the culture medium of control endothelial cells and fibroblasts had no effect on rs for DPH or TPA. In hyperoxic endothelial cells, rs for DPH and rs for TPA were increased (p less than 0.001). Addition of endotoxin to the medium of hyperoxic endothelial cells prevented the increases in rs for DPH and TPA. Hyperoxia increased rs for DPH (p less than 0.003) but not rs to TPA in fibroblasts, and endotoxin failed to prevent this increase. These results indicate that hyperoxia decreases plasma membrane fluidity in endothelial cells and fibroblasts and demonstrate that endotoxin prevents the decrease in plasma membrane fluidity in endothelial cells, but not in fibroblasts. These membrane-protective effects may represent an alternative mechanism by which endotoxin protects against hyperoxic cellular injury, and this mechanism may be specific for hyperoxic injury to endothelial cells.

Effect of oxygen and endotoxin on lactate dehydrogenase release, 5-hydroxytryptamine uptake, and antioxidant enzyme activities in endothelial cells.

We compared the effects of 95% O2 (hyperoxia) alone, endotoxin (20 ng/ml) alone, and 95% O2 plus endotoxin on the release of lactate dehydrogenase (LDH), uptake of 5-hydroxytryptamine (5-HT), and antioxidant enzyme activities in porcine pulmonary arterial and aortic endothelial cells in monolayer culture. Hyperoxia increased LDH release and decreased 5-HT in both endothelial cell types. Hyperoxia also caused a decrease in catalase (CAT) activity and an increase in total superoxide dismutase (SOD) and glutathione reductase (GSH-Red) activities in both cell types. Endotoxin alone had no effect on LDH release, 5-HT uptake, or antioxidant enzyme activities. However, endotoxin prevented the hyperoxic increase in LDH release and the hyperoxic decrease in 5-HT uptake. Endotoxin plus 95% O2 had no consistent effect on the antioxidant enzyme profile in pulmonary artery or aortic endothelial cells. These results indicate that (1) hyperoxia injures both pulmonary artery and aortic endothelial cells in culture and causes changes in the antioxidant enzyme profile that are similar in the two cell types; (2) hyperoxia-induced decreases in CAT activity and increases in SOD activity may be responsible for increased sensitivity of endothelial cells to O2 toxicity; and (3) endotoxin protects against hyperoxic injury to endothelial cells in vitro, but increases in antioxidant enzyme activities are not the mechanism for this protection.