The alkenyl-acyl subclass of phosphatidylethanolamine (PtdEtn) and phosphatidylcholine (plasmalogens) are minor components of alveolar surfactant. Plasmalogens promote and stabilize hexagonal structures of phospholipids. In another study (W. R. Perkins, R. B. Dause, R. A. Parente, S. R. Michey, K. C. Neuman, S. M. Gruner, T. F. Taraschi, and A. S. Janoff. Science 273: 330–332, 1996), it was shown that polymorphic phase behavior may have an important role in the effective functioning of pulmonary surfactant. Therefore, we hypothesized that surface properties of phospholipid mixtures that contain plasmalogens are superior to plasmalogen-free mixtures. The effect of plasmalogens on surface tension of surfactant-like phospholipid mixtures (70 mol% dipalmitoyl phosphatidylcholine, 10 mol% phosphatidylglycerol, and 20 mol% PtdEtn) was measured. Using the pulsating bubble surfactometer, we show that an increasing amount of ethanolamine plasmalogens [plasmenylethanolamine (PlsEtn)] results in reduction of surface tension (0 mol% PlsEtn 44.7 ± 1.7, 2 mol% 33.5 ± 1.7, 4 mol% 36 ± 3.1, 6 mol% 26.2 ± 2.9, and 8 mol% 22.2 ± 0.3 mN/m). By means of the captive bubble surfactometer, minimal surface tension reached with 8 mol% PlsEtn was even lower (3.8 ± 0.7 mN/m). With regard to morphological studies (B. Fringes, K. Gorgas, and A. Reith. Eur. J. Cell Biol. 46: 136–143, 1988), clofibrate treatment of rats might increase the plasmalogen content of alveolar surfactant. However, in the present study, we could not show that synthesis and secretion of plasmalogens are affected by clofibrate treatment.
Alveolar type II cells accumulate vitamin E preferentially from high-density lipoproteins (HDL) and express at least three receptors that are specific for HDL. The expression of these receptors increases in response to vitamin E deficiency. Beside receptors for specific lipid transfer from HDL, cubilin and megalin, several other receptors that mediate HDL-particle uptake were found in the lung. We hypothesize that alveolar type II cells also exhibit the HDL-particle uptake and that this process can be regulated by the vitamin E status. By confocal laser microscopy and flow cytometry we showed that type II cells accumulate protein-labeled HDL-particle. Vitamin E depletion in rats increased HDL-particle uptake in alveolar type II cells and the expression of megalin. The expression of cubilin did not change. Refeeding with vitamin E reversed HDL-particle uptake and megalin expression. Long-time incubation of type II cells with phorbol myristyl acetate (PMA) reduced HDL-holoparticle uptake and megalin expression. We assume that alveolar type II cells exhibit HDL-holoparticle uptake mediated by megalin and cubilin. Megalin represents the regulated element of the megalin/cubilin receptor-cooperation and can be modulated by protein kinase C.
Glycoprotein IV (FAT/CD36) has been shown to be phosphorylated by a cAMP-dependent, platelet membrane-bound ectokinase. In this study, we demonstrate that ectophosphorylation of FAT/CD36 regulates initial palmitate uptake. This is the first time that short-term regulation of the activity of a long-chain fatty acid carrier could be shown. Phosphorylation of FAT/CD36 was paralleled by a significant decrease in initial palmitate uptake by morphologically and functionally intact platelets. Maximum inhibition of palmitate uptake was achieved at 0.5 nM extracellular ATP, being significantly decreased to 72% compared to the control. Inhibition of palmitate uptake was abolished by co-incubation with the specific protein kinase A inhibitor peptide PKI or with beta,gamma-methylene-ATP, and was reversible upon addition of alkaline phosphatase. An extracellular ATP concentration above 5 microM completely prevented the ectophosphorylation-mediated inhibition of palmitate uptake. We conclude that FAT/CD36-mediated palmitate uptake by human platelets is short-term regulated via cAMP-dependent ectophosphorylation of FAT/CD36.
Cholesterol is an abundant lipid of lung surfactant, where its concentration changes relative to phospholipids in response to certain physiological conditions. We investigated the effect of the cellular cholesterol content on uptake and esterification of palmitic acid, and on cellular distribution of fatty acid translocase (FAT/CD36) in alveolar type II cells. Incubation of type II cells with methyl-beta-cyclodextrin-cholesterol complexes increased the cholesterol content of lamellar bodies. The palmitate uptake of type II cells increased in parallel with the cellular cholesterol content. The content of FAT/CD36 increased in membranes and decreased in cytosol in type II cells. The detergent-insoluble fraction (DIGs), isolated from type II cells, was enriched in FAT/CD36 and caveolin-1 after increasing the cellular cholesterol. The total incorporation of labeled palmitic acid into glycerolipids and cholesterol ester (CE) increased by a factor of about 10 when the amount of unbound (14)C-palmitic acid added to type II cells was increased by a factor of about 1000. Under these conditions, a small but significant increase of the palmitate incorporation into PL occurred. Independent from the amount of added palmitate, palmitate incorporation into triacylglycerol decreased and palmitate incorporation into cholesterol ester increased about 40-65-fold. The beta-oxidation of palmitate significantly decreased. We conclude that alveolar type II cells respond to an increase of the cholesterol level with (i) cellular redistribution of FAT/CD36 into DIGs causing enhanced palmitate uptake and increased cholesterol ester-formation, (ii) storage of cholesterol in lamellar bodies, and (iii) induction of the formation of caveolae-like microdomains in the surface membrane, a structure possibly involved in a lamellar body-independent efflux of free cholesterol via the high-density lipoprotein-specific pathway.
Oxidants play an important role in the development of acute and chronic lung injuries. Alveolar surfactant is the first target of air-borne oxidants. Surfactant contains, besides dipalmitoyl phosphatidylcholine, cholesterol and polyunsaturated phospholipids that play an important functional role. Therefore, vitamin E could be important for protecting surfactant lipids against oxidation and subsequent lung injury. Alveolar type II cells play a central role in synthesis and secretion of surfactant lipids and also supplement the surfactant with vitamin E during intracellular assembly. High density lipoprotein (HDL) is the primary source of vitamin E for type II cells. The uptake of vitamin E by specific lipid transfer is mediated by at least three HDL-specific receptors (scavenger receptor BI, membrane dipeptidase, and HDL-binding protein-2). In addition, cubilin and megalin mediate in a cooperative manner HDL-holoparticle uptake by alveolar type II cells. A temporary vitamin E deficiency induces a reversible change of the expression of pro- and antiinflammatory markers and of markers defining apoptosis, and reduces surfactant lipid synthesis in alveolar type II cells. These metabolic changes of type II cells may prime the lung to develop clinically manifest injury in response to an additional insult, e.g., hyperoxia.
Alveolar surfactant (exposed to air and therefore a prime target of air oxidants) is supplied with antioxidants during its intracellular formation on type-II pneumocytes [Rüstow, Haupt, Stevens and Kunze (1993) Am. J. Physiol. 265, L133-L139]. Plasmalogens can protect animal cells against lipid peroxidation caused by u.v. radiation. It has been suggested that plasmalogens play a direct role in protecting animal cell membranes against oxidative stress [Zoeller, Morand and Raetz (1988) J. Biol. Chem. 263, 11590-11596]. We investigated biosynthesis and secretion of plasmalogens and phospholipids by type-II cells of adult rat lungs. The plasmalogens of type-II cells consist of 93% ethanolamine plasmalogens (EthPlas) and 7% choline plasmalogens (ChoPlas). Plasmalogens isolated from alveolar surfactant, however, consist of 36.5% ChoPlas and 63.5% EthPlas. The different incorporation rates of [14C]hexadecanol into both types of plasmalogen by type-II pneumocytes are reflected in the relative proportions of their total cellular plasmalogen content. Type-II cells cultured in the presence of labelled hexadecanol or labelled hexadecylglycerol and of labelled palmitate secrete labelled ChoPlas and labelled phospholipids, both spontaneously and in response to isoprenaline. The spontaneous and stimulated secretion rates of labelled ChoPlas are 3-6 times higher than those of labelled EthPlas. This higher relative secretion rate of ChoPlas corresponds to its higher proportion in the total plasmalogen content of alveolar surfactant compared with type-II cells. Added extracellular surfactant-specific protein A inhibits the secretion of plasmalogens as well as that of phospholipids by type-II cells. The molecular species of EthPlas and ChoPlas isolated from type-II cells or lung lavage do not differ significantly and consist mainly of molecular species containing poly-unsaturated fatty acids. We conclude that ChoPlas are secreted partly as integral constituents of the alveolar surfactant. Type-II cells select between both types of plasmalogens for secretion as a constituent of surfactant. The intramolecular sorting signal presumably is the choline moiety.
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