Effect of cholesterol on the uptake and intracellular degradation of liposomes by liver and spleen; a combined biochemical and gamma-ray perturbed angular correlation study

We investigated the effect of cholesterol on the uptake and intracellular degradation of liposomes by rat liver and spleen macrophages. Multilamellar vesicles (MLV) consisting of distearoylphosphatidylcholine/phosphatidylserine (molar ratio 9:1) or distearoylphosphatidylcholine/cholesterol/phosphatidylserine (molar ratio 4:5:1) were labeled with [3H]cholesteryl hexadecyl ether and/or cholesteryl [14C]oleate. After i.v. injection the cholesterol-containing liposomes were eliminated less rapidly from the bloodstream and taken up to a lesser extent by the liver (macrophages) than the cholesterol-free liposomes. Assessment of the 3H/14C ratios in liver and spleen cells revealed that the cholesterol-containing liposomes are substantially more resistant towards intracellular degradation than the cholesterol-free liposomes. These results could be confirmed by measuring the release of 111In from liposomes after uptake by liver and spleen by means of gamma-ray perturbed angular correlation spectroscopy. Experiments with cultured Kupffer cells in monolayer also revealed that incorporation of cholesterol results in a decrease of the uptake and an increase of the intracellular stability of cholesteryl [14C]oleate-labeled liposomes. Finally, incubation of both types of liposomes with lysosomal fractions prepared from rat liver demonstrated a difference in susceptibility to lysosomal degradation: the cholesterol-free vesicles were much more sensitive to lysosomal esterase than the cholesterol-containing liposomes. These results may be relevant to the application of liposomes as a drug carrier system to liver and spleen (macrophages).     

Processing of different liposome markers after in vitro uptake of immunoglobulin-coated liposomes by rat liver macrophages

We compared the metabolic fate of [³H]cholesteryl[¹⁴C]oleate, [³H]cholesteryl hexadecylether, ¹²⁵I-labeled bovine serum albumin and [³H]inulin as constituents of large immunoglobulin-coupled unilamellar lipid vesicles following their internalization by rat liver macrophages (Kupffer cells) in monolayer culture. Under serum-free conditions, the cholesteryl oleate that is taken up is hydrolyzed, for the greater part, within 2 h. This occurs in the lysosomal compartment as judged by the inhibitory effect of the lysosomotropic agents monensin and chloroquin. After hydrolysis, the cholesterol moiety is accommodated in the cellular pool of free cholesterol and the oleate is reutilized for the synthesis mainly of phospholipids and, to a lesser extent of triacylglycerols. During incubation in plasma, however, substantial proportions of both the cholesterol and the oleate are shed from the cells, predominantly in the unesterified form. When the liposomes are labeled with the cholesteryl ester analog [³H]cholesteryl hexadecylether only a very small fraction of the label is released from the cells, even in the presence of plasma. Similar to the label remaining associated with the cells, the released label is identified in that case as unchanged cholesteryl ether. The liposomal aqueous phase marker ¹²⁵I-labeled bovine serum albumin is also readily degraded intralysosomally and the radioactive label is rapidly released from the cells in a trichloroacetic acid-soluble form. Also, as much as 20% of the aqueous phase marker [³H]inulin that becomes cell-associated during a 2-h incubation with inulin-containing liposomes, is released from the cells during a subsequent 4-h incubation period in medium or rat plasma. The usefulness of the various liposomal labels as parameters of liposome uptake and intracellular processing is discussed.     

Interaction of immunoglobulin-coupled liposomes with rat liver macrophages in vitro

The interaction between liposomes coated with covalently linked rabbit immunoglobulin (RbIg-liposomes), and rat liver macrophages (Kupffer cells) in monolayer culture was studied biochemically with radioactive tracers and morphologically by electron microscopy. The attachment of immunoglobulin (Ig) to liposomes caused a five-fold increase in liposome uptake by the Kupffer cells at 37 degrees C, in comparison with uncoated liposomes. The uptake was linear with time for at least 4 h and linear with liposome concentration up to a lipid concentration of 0.2 mM. At 4 degrees C uptake, probably representing cell surface-bound liposomes, was reduced to a level of approx. 20% of the 37 degrees C values. Involvement of the Fc receptor in the uptake process was indicated by the reduction of RbIg-liposome uptake by more than 75% as a result of preincubating the cells with heat-aggregated human or rabbit Ig at concentrations (less than 2 mg/ml) at which bovine serum albumin (BSA) had virtually no effect on uptake. At high concentrations (10-35 mg/ml), however, albumin also reduced liposome uptake significantly (20-30%), which suggests an interaction of the RbIg-liposomes with the Kupffer cells that is partially non-specific. RbIg-liposome uptake was dependent on the amount of RbIg coupled to the liposomes. Maximal uptake values were reached at about 200 micrograms RbIg/mumol liposomal lipid. Electron microscopic observations on cells incubated with horseradish peroxidase-containing RbIg-liposomes demonstrated massive accumulation of peroxidase reaction product in intracellular vacuoles, showing that the uptake observed by label association represents true internalization.     

The uptake and metabolism of chylomicron-remnant lipids by rat liver parenchymal and non-parenchymal cells in vitro.

The uptake and metabolism of chylomicron-remnant lipids by individual liver cell types was examined by incubating remnants with monolayer cultures of hepatocytes, Kupffer cells, and endothelial cells from rat liver. Remnants were prepared in vitro from radiolabelled mesenteric-lymph chylomicra, utilizing either purified lipoprotein lipase from bovine milk, or plasma isolated from heparinized rats. The resulting particles contained [3H]phosphatidylcholine and cholesterol, and [14C]oleate in the acylglycerol, phospholipid, fatty-acid and cholesterol-ester fractions. The capacities of the three cell types for uptake of both [3H]lipids and [14C]lipids were determined to be, on a per-cell basis, in the order: Kupffer greater than hepatocytes greater than endothelial. The relative proportions of [3H]phospholipid and total [3H]cholesterol taken up by hepatocytes and non-parenchymal cells remained constant with time. The uptake of [14C]oleoyl lipids by all three cell types was slightly greater than that of the total [3H]cholesterol and [3H]phospholipid components. There was evidence of cholesterol-ester hydrolysis and turnover of [14C]oleate in the phospholipid fraction in hepatocytes and Kupffer cells, but not endothelial cells, over the first 2 h. With both remnant preparations, these observations indicate that significant differences exist between the three major liver cell types with respect to the uptake and metabolism of remnant lipid components.     

Uptake of phosphatidylserine-containing liposomes by liver sinusoidal endothelial cells in the serum-free perfused rat liver

We studied the kinetics of hepatic uptake of liposomes during serum-free recirculating perfusion of rat livers. Liposomes consisted of phosphatidylcholine, cholesterol and phosphatidylserine in a 6:4:0 or a 3:4:3 molar ratio and were radiolabelled with [3H]cholesteryl oleyl ether. The negatively charged liposomes were taken up to a 10-fold higher extent than the neutral ones. Hepatic uptake of fluorescently labelled liposomes was examined by fluorescence microscopy. The neutral liposomes displayed a typical Kupffer cell distribution pattern, in addition to weak diffuse staining of the parenchyma, while the negatively charged liposomes showed a characteristic sinusoidal lining pattern, consistent with an endothelial localization. In addition, scattered Kupffer cell staining was distinguished as well as diffuse parenchymal fluorescence. The mainly endothelial localisation of the negatively charged liposomes was confirmed by determining radioactivity in endothelial and Kupffer cells isolated following a 1-h perfusion. Perfusion in the presence of polyinosinic acid, an inhibitor of scavenger receptor activity, reduced the rate of uptake of the negatively charged liposomes twofold, indicating the involvement of this receptor in the elimination mechanism. These results are compatible with earlier in vitro studies on liposome uptake by isolated endothelial cells and Kupffer cells, which showed that in the absence of serum also endothelial cells in situ are able to take up massive amounts of negatively charged liposomes. The present results emphasize that the high in vitro endothelial cell uptake in the absence of serum from earlier observations was not an artifact induced by the cell isolation procedure.     

High-density lipoprotein subpopulations as substrates for the transfer of cholesteryl esters to very-low-density lipoproteins.

1. Human total HDL (high-density lipoprotein), HDL2 and HDL3 were labelled in vitro by incubation with lipoprotein-deficient serum (LPDS) which contained either [3H]cholesteryl oleate or [14C]cholesterol under different conditions. The lipoproteins were then subfractionated by heparin-Sepharose column chromatography, and three subfractions (A, B and C) were successively eluted from each preparation of HDL, HDL2 and HDL3. When the labelling was done at 37 degrees C for 17 h, the subfractions were homogeneously labelled with [3H]cholesteryl oleate. However, when it was performed for only 30 min at 4 degrees C, the subfractions showed marked differences in the 3H specific radioactivity, which was much higher in the C fractions than in the others. 2. 3H-labelled HDL2 and HDL3 subfractions behaved differently under the precipitant action of heparin-Mn2+; fraction C (the richest in apolipoprotein E) produced the largest amount of radioactive and chemical precipitate. More 3H radioactivity, but not the cholesterol, was precipitated from HDL2 or HDL3 by the reagent, demonstrating that 3H-labelled HDL2 and HDL3 behave like their fraction C, which becomes labelled to the highest specific radioactivity despite having the smallest mass. 3. The incubation of 3H-labelled HDL subfractions with human LPDS and very-low-density lipoprotein (VLDL) at 37 degrees C increased the quantity of 3H radioactivity that was precipitated, in proportion to the amount of VLDL present in the media. These changes were attributable to the action of cholesterol ester transfer protein, since they did not occur at 4 degrees C or when human LPDS was replaced with rat LPDS. 4. Kinetics of the transfer of HDL [3H]cholesteryl oleate to VLDL showed a greater apparent Vmax for fractions A than for fractions B from either HDL2 or HDL3, whereas the apparent Km values were very similar, which suggest that this transfer process is influenced by the apoprotein composition of the donor lipoprotein.     

Uptake of phosphatidylserine-containing liposomes by liver sinusoidal endothelial cells in the serum-free perfused rat liver

We studied the kinetics of hepatic uptake of liposomes during serum-free recirculating perfusion of rat livers. Liposomes consisted of phosphatidylcholine, cholesterol and phosphatidylserine in a 6:4:0 or a 3:4:3 molar ratio and were radiolabelled with [³H]cholesteryl oleyl ether. The negatively charged liposomes were taken up to a 10-fold higher extent than the neutral ones. Hepatic uptake of fluorescently labelled liposomes was examined by fluorescence microscopy. The neutral liposomes displayed a typical Kupffer cell distribution pattern, in addition to weak diffuse staining of the parenchyma, while the negatively charged liposomes showed a characteristic sinusoidal lining pattern, consistent with an endothelial localization. In addition, scattered Kupffer cell staining was distinguished as well as diffuse parenchymal fluorescence. The mainly endothelial localisation of the negatively charged liposomes was confirmed by determining radioactivity in endothelial and Kupffer cells isolated following a 1-h perfusion. Perfusion in the presence of polyinosinic acid, an inhibitor of scavenger receptor activity, reduced the rate of uptake of the negatively charged liposomes twofold, indicating the involvement of this receptor in the elimination mechanism. These results are compatible with earlier in vitro studies on liposome uptake by isolated endothelial cells and Kupffer cells, which showed that in the absence of serum also endothelial cells in situ are able to take up massive amounts of negatively charged liposomes. The present results emphasize that the high in vitro endothelial cell uptake in the absence of serum from earlier observations was not an artifact induced by the cell isolation procedure.     

Behaviour of phospholipase-modified HDL towards cultured hepatocytes. I. Enhanced transfers of HDL sterols and apoproteins

Human HDL subfractions (HDL2, HDL3, or HDL separated by heparin affinity chromatography) were labelled either on their apolipoprotein moiety with 125I or on their sterols: unesterified [14C]cholesterol and [3H]cholesteryl linoleyl ether, a non-hydrolysable analog of esterified cholesterol. HDL subfractions were then treated with or without phospholipase A2 from Crotalus adamanteus in presence of albumin leading to a 72-82% phosphatidylcholine degradation. Control and treated HDL were reisolated and then addressed to cultured rat hepatocytes. (A) During incubations, unesterified [14C]cholesterol from HDL3 readily appeared in hepatocytes. The specific uptake of HDL esterified cholesterol calculated from [3H]cholesteryl ether was 2-4-times less important. Uptake of HDL cholesterol tended to saturate at 150-200 micrograms/ml HDL protein. A prior phospholipase treatment of HDL3 stimulated by 2-5-fold the uptake of [3H]cholesteryl ether, whereas the transfer of free [14C]cholesterol was minimally increased. The uptake of 3H/14C-labelled sterols from HDL2 was 2-3-times higher than from HDL3. (B) Parallel experiments were conducted with 125I-labelled HDL subfractions. At 37 degrees C, the specific uptake and degradation of HDL3 125I-apolipoprotein were about 2-fold enhanced following treatment of HDL3 with phospholipase A2. Uptakes of apolipoprotein and of esterified cholesterol were compared, indicating a preferential delivery of the sterol over apoprotein (X5). The dissociation was still more pronounced with phospholipase-treated HDL3. Competition experiments showed that 12-times more unlabelled HDL3 were required to half reduce the uptake of HDL3 [3H]cholesteryl ether than to impede similarly the HDL 125I-apolipoprotein recovered in cells. Uptake of 125I-labelled apolipoprotein from HDL2 was quantitatively comparable to that from HDL3. (C) Binding of 125I-HDL subfractions was followed at 4 degrees C. A specific binding was observed for HDL2 and HDL3, although kinetic parameters were quite different (KD of 9 and 25 micrograms/ml, respectively). Following phospholipolysis, both the specific and non-specific contributions to total binding were increased. Hence, hepatocytes take up more 125I-labelled apolipoprotein and 3H/14C-labelled sterols from lipolysed HDL than from unmodified particles. This is associated to changes in the binding characteristics.     

The role of apolipoproteins of HDL in the selective uptake of cholesteryl linoleyl ether by cultured rat and bovine adrenal cells

Rat adrenal cells in culture were used to study the uptake of cholesteryl linoleyl ether [( 3H]cholesteryl linoleyl ether), a nonhydrolyzable analog of cholesteryl ester. When [3H]cholesteryl linoleyl ether was added in the form of liposomes, its uptake was enhanced by adrenocorticotropin (ACTH) and by addition of milk lipoprotein lipase and interfered by heparin. When the adrenal cells were incubated with homologous [3H]cholesteryl linoleyl ether-HDL, ACTH treatment also resulted in an increase in [3H]cholesteryl linoleyl ether uptake. The uptake of [3H]cholesteryl linoleyl ether was in excess of the uptake and metabolism of 125I-labeled HDL protein and was not sensitive to heparin. Unlabeled HDL or delipidated HDL reduced very markedly the uptake of [3H]cholesteryl linoleyl ether, while addition of phosphatidylcholine liposomes had little effect. Attempts were made to deplete and enrich the adrenal cells in cholesterol and, while depletion resulted in a decrease in [3H]cholesteryl linoleyl ether-HDL uptake, enrichment of cells with cholesterol had no effect. Among the individual apolipoproteins tested, apolipoprotein A-I and the C apolipoproteins reduced [3H]cholesteryl linoleyl ether uptake, while apolipoprotein E was not effective. Since the labeled ligand studied was a lipid, these effects could not be due to an exchange of apolipoproteins, but indicated competition for binding sites. Preferential uptake of human [3H]cholesteryl linoleyl ether-HDL3 by bovine adrenal cells was found when compared to the uptake and metabolism of 125I-labeled HDL. The present results suggest that the preferential uptake of HDL cholesteryl ester (as studied with [3H]cholesteryl linoleyl ether) requires an interaction between the apolipoproteins of HDL and cell surface components.     

Sphingomyelin liposomes with defined fatty acids: metabolism and effects on reverse cholesterol transport

Small unilamellar liposomes prepared from sphingomyelins with defined 14C-labeled fatty acids were studied after injection into rats. The liposomes contained trace amounts of [3H]cholesteryl linoleyl ether (CLE), which served as a nonexchangeable and nonhydrolyzable marker. The liposomes were cleared from the circulation with an initial t1/2 of about 90 min. [14C]18:0- and [14C]18:1-containing sphingomyelins were cleared at a similar rate, but [14C]18:2-sphingomyelin disappeared much faster. The liver accounted for up to 70% of [3H]cholesteryl ether injected with 18:0-sphingomyelin liposomes, and for up to 50% with liposomes prepared from 18:1 or 18:2-sphingomyelin. The initial uptake of the liver appeared to be of the entire particle, and the loss of 14C label with time indicated metabolism of the sphingomyelins. With [14C]18:0-sphingomyelin liposomes, up to 8% of liver radioactivity was recovered in neutral lipids 6 h after injection, and this value was 17 and 22% with [14C]18:2- and [14C]18:1-sphingomyelins, respectively. The recovery in 'carcass' of [3H]cholesteryl ether 3 h after injection of [14C]18:2-sphingomyelin liposomes was 33% and of 14C label, 21%. Injection of 18:1- or 18:2-sphingomyelin liposomes (5.4 mumol/100 g body weight) resulted in a 2-fold increase of plasma unesterified cholesterol; a 30% increase was seen with 18:0 liposomes (2.63 mumol/100 g body weight). In experiments with cultured cells, the unsaturated sphingomyelin liposomes alone enhanced cholesterol efflux more extensively than the saturated ones, but their efficacies became similar when mixed with apoprotein (apo) A-I. At equimolar concentration, apo C-III1 or C-III2 had a smaller effect than apo A-I. It is concluded that 18:1- or 18:2-sphingomyelin tends to form small unilamellar liposomes which may reach also extrahepatic tissues. The liposomes able to enhance cholesterol release in vitro and in vivo. Since they are not a substrate for lecithin-cholesterol acyltransferase, they should be able to deliver the free cholesterol to the liver, where they are also rapidly metabolized.     

Hepatic processing of the cholesteryl ester from low density lipoprotein in the rat

Human low density lipoprotein (LDL), radiolabeled in the cholesteryl ester moiety, was injected into estrogen-treated and -untreated rats. The hepatic and extrahepatic distribution and biliary secretion of [3H]cholesteryl esters were determined at various times after injection. In order to follow the intrahepatic metabolism of the cholesteryl esters of LDL in vivo, the liver was subfractioned into parenchymal and Kupffer cells by a low temperature cell isolation procedure. In control rats, the LDL cholesteryl esters were mainly taken up by the Kupffer cells. After uptake, the [3H]cholesteryl esters are rapidly hydrolyzed, followed by release of [3H]cholesterol from the cells to other sites in the body. Up to 24 h after injection of LDL, only 9% of the radioactivity appeared in the bile, whereas after 72 h, this value was 30%. Hepatic and especially the parenchymal cell uptake of [3H]cholesteryl esters from LDL was strongly increased upon 17 alpha-ethinylestradiol treatment (3 days, 5 mg/kg). After rapid hydrolysis of the esters, [3H]cholesterol was both secreted into bile (28% of the injected dose in the first 24 h) as well as stored inside the cells as re-esterified cholesterol ester. It is concluded that uptake of human LDL by the liver in untreated rats is not efficiently coupled to biliary secretion of cholesterol (derivatives), which might be due to the anatomical localization of the principal uptake site, the Kupffer cells. In contrast, uptake of LDL cholesterol ester by liver hepatocytes is tightly coupled to bile excretion. The Kupffer cell uptake of LDL might be necessary in order to convert LDL cholesterol (esters) into a less toxic form. This activity can be functional in animals with low receptor activity on hepatocytes, as observed in untreated rats, or after diet-induced down-regulation of hepatocyte LDL receptors in other animals.     

Metabolism of cholesteryl ester lipid droplets in a J774 macrophage foam cell model

J774 macrophages rapidly incorporated [3H]cholesteryl oleate droplets by a non-saturable phagocytic process. In less than 2 h, foam cell morphology was acquired. The extent of loading obtained after 2 h was a linear function of the mass of cholesteryl oleate provided to the cells. The cholesteryl oleate incorporated was hydrolyzed in the cells at a linear rate over 24 h and the fractional hydrolysis was constant over a wide range of cellular esterified cholesterol contents. The rate of hydrolysis was influenced by the physical state of the cholesteryl ester; cholesteryl oleate in isotropic droplets was hydrolyzed 2-3-fold more rapidly than cholesteryl oleate in anisotropic droplets. The hydrolysis of both types of droplets was inhibited by lysosomotropic agents, indicating that hydrolysis occurred in the lysosomes. Only a small fraction (less than 10% after 24 h) of the free [3H]cholesterol generated in the lysosomes was esterified by ACAT resulting in a doubling of the cell free cholesterol content. Electron microscopy of cells treated with digitonin revealed the accumulation of free cholesterol in lipid-laden lysosomes. ACAT was active as endogenous free [14C]cholesterol was esterified in a linear manner over 24 h and was responsive to the presence of lysosomally-derived cholesterol, as the extent of esterification of the endogenous pool was directly proportional to the mass of [3H]cholesterol generated in the lysosomes.     

Evaluation of cholesteryl ester transfer in the seminiferous tubule cells of immature rats in vivo and in vitro

Sertoli cells and germ cells are separated from the interstitial blood capillaries by an extracellular matrix and the peritubular cells, which constitute a barrier to the movement of plasma lipoproteins. The present study was undertaken to evaluate in vivo and in vitro the high density lipoprotein (HDL) cholesteryl ester transfer from plasma to seminiferous tubule cells in the testis of 30-day-old rats. Firstly, the transfer of HDL cholesteryl oleate from plasma to testicular compartments was evaluated and, secondly, the role of apolipoproteins A-I and E in the uptake of cholesteryl ester by Sertoli cells was investigated. At 2 h after the administration of HDL reconstituted with [3H]cholesteryl ester, dimyristoyl phosphatidylcholine and apolipoproteins, the tissue space in the interstitial cells (740 +/- 60 microliters g-1 cell protein) was fourfold higher than that in the seminiferous tubule cells (170 +/- 10 microliters g-1). Sertoli cells were isolated and incubated with [3H]cholesteryl ester HDL reconstituted with apolipoprotein A-I or E to evaluate the mechanisms of cholesteryl ester influx. At the same apolipoprotein concentration (50 micrograms apolipoprotein ml-1 medium), the uptake of [3H]cholesteryl oleate from phospholipid-apolipoprotein E vesicles was twofold higher than that with phospholipid-apolipoprotein A-I vesicles. The presence of heparin reduced the uptake of cholesteryl ester from apolipoprotein E vesicles but not with apolipoprotein A-I vesicles, indicating that uptake of apolipoprotein A-I vesicles via a secretion of apolipoprotein E by the cells themselves was not involved. These results demonstrate that plasma lipoprotein cholesterol is able to cross the testis lamina propria and that Sertoli cells take up cholesteryl ester for seminiferous tubule cell metabolism mainly via an apolipoprotein E pathway.     

Intravascular metabolism of lipoprotein cholesteryl esters in African green monkeys: differential fate of doubly labeled cholesteryl oleate

High density lipoproteins (HDL), doubly labeled with [3H]cholesteryl oleate and cholesteryl [14C]oleate, were reinjected to study HDL cholesteryl ester metabolism in African green monkeys. The transfer of labeled HDL cholesteryl ester to low density lipoprotein (LDL) was rapid and equilibration of the [3H]cholesteryl oleate and cholesteryl [14C]oleate specific activities in LDL and HDL occurred within 90 min after reinjection. The apparent rates of disappearance from the circulation of the two moieties of the cholesteryl ester were different. In the same four animals, the residence time for the turnover of plasma [3H]cholesterol averaged 6.1 days while the residence time for the removal of cholesteryl [14C]oleate from plasma was approximately 2.1 days. These results suggest that for some lipoprotein cholesteryl esters removed from plasma, the cholesterol moiety subsequently reappeared in plasma. The difference between the rate of decay of the 14C-labeled fatty acid moiety, which represents all of the cholesteryl ester removed from plasma (0.48 pools/day) and the decay of the 3H-labeled cholesterol moiety, which represents the sum of cholesteryl ester removal and cholesterol reappearance (0.16 pools/day), is the fraction of the cholesteryl ester pool recycled per day (0.32 pools/day or 22.5 mg/kg per day). In other words, approximately 68% of the cholesterol moiety that was removed from plasma as cholesteryl oleate reappeared in the plasma cholesterol pool. These studies support the concept that an efficient reutilization cycle for plasma cholesterol occurs, i.e., the cholesteryl ester molecule can exit and the cholesterol moiety can re-enter plasma without effective equilibration of the cholesterol moiety with extravascular cholesterol pools.     

Reversible accumulation of cholesteryl esters in macrophages incubated with acetylated lipoproteins

Mouse peritoneal macrophages accumulate large amounts of cholesteryl ester when incubated with human low-density lipoprotein that has been modified by chemical acetylation (acetyl-LDL). This accumulation is related to a high-affinity cell surface binding site that mediates the uptake of acetyl-LDL by adsorptive endocytosis and its delivery to lysosomes. The current studies demonstrate that the cholesteryl ester accumulation can be considered in terms of a two-compartment model: (a) the incoming cholesteryl esters of acetyl-LDL are hydrolyzed in lysosomes, and (b) the resultant free cholesterol is re-esterified in the cytosol where the newly formed esters are stored as lipid droplets. The following biochemical and morphologic evidence supports the hydrolysis-re-esterification mechanism: (a) Incubation of macrophages with acetyl-LDL markedly increased the rate of cholesteryl ester synthesis from [14C]oleate, and this was accompanied by an increase in the acyl-CoA:cholesteryl acyltransferase activity of cell-free extracts. (b) When macrophages were incubated with reconstituted acetyl-LDL in which the endogenous cholesterol was replaced with [3H]-cholesteryl linoleate, the [3H]cholesteryl linoleate was hydrolyzed, and at least one-half of the resultant [3H]cholesterol was re-esterified to form [3H]cholesteryl oleate, which accumulated within the cell. The lysosomal enzyme inhibitor chloroquine inhibited the hydrolysis of the [3H]cholesteryl linoleate, thus preventing the formation of [3H]cholesteryl oleate and leading to the accumulation of unhydrolyzed [3H]cholesteryl linoleate within the cells. (c) In the electron microscope, macrophages incubated with acetyl-LDL had numerous cytoplasmic lipid droplets that were not surrounded by a limiting membrane. The time course of droplet accumulation was similar to the time course of cholesteryl ester accumulation as measured biochemically. (d) When acetyl-LDL was removed from the incubation medium, biochemical and morphological studies showed that cytoplasmic cholesteryl esters were rapidly hydrolyzed and that the resultant free cholesterol was excreted from the cell.     

The transfer of lipids from protein-free lipoprotein models to human fibroblasts in culture

Lipid microemulsions were prepared by sonication of mixtures of cholesteryl ester, triacylglycerol, phosphatidylcholine and cholesterol in aqueous dispersions and were purified by gel filtration. The resulting emulsion particles were characterized by differential scanning calorimetry, electron microscopy and analytical gel filtration and were shown to have the size and general organization of low-density lipoprotein. The lipid microemulsions were used as protein-free plasma lipoprotein models for studies of the receptor-independent transfer of lipids to human fibroblasts in culture. The transfer rate of [3H]cholesterol increased with the donor concentration and with the molar ratio between cholesterol and phosphatidylcholine in the donor particles. A maximal transfer value of 1 nmol per mg protein per h was obtained for cholesterol/phosphatidylcholine 1:1 particles. There was a profound temperature effect on the cholesterol transfer. The effect of altering the core lipid of the emulsion particles on the [3H]cholesterol transfer rate was small giving a somewhat higher rate with cholesteryl oleate and cholesteryl stearate than with cholesteryl linoleate. Addition of trioleoylglycerol to the cholesteryl ester core had no effect on the transfer rate. The transfer rate of palmitoyl[14C]oleoylphosphatidylcholine was found to be about 1/5 of that obtained for [3H]cholesterol. About 50% of the cell-associated [14C]cholesteryl oleate was found in the trypsin-releasable pool, while 25% was internalized by the cells at a rate of 0.06 nmol X mg-1 X h-1. Trioleoylglycerol was internalized at the same rate as the cholesteryl ester. Our data suggest that the lipoprotein lipid composition may play a role in the receptor-independent cellular uptake of cholesterol.     

Clearance of acetyl low density lipoprotein by rat liver endothelial cells. Implications for hepatic cholesterol metabolism

We have studied the hepatic uptake of human [14C] cholesteryl oleate labeled acetyl low density lipoprotein (LDL). Acetyl-LDL injected intravenously into rats was cleared from the blood with a half-life of about 10 min. About 80% of the injected acetyl-LDL was recovered in the liver after 1 h. Initially, most of the [14C]cholesterol was recovered in liver endothelial cells (about 60%). Some radioactivity (about 15%) was also recovered in the hepatocytes, while the Kupffer cells and stellate cells contained only small amounts of the label (less than 5%). About 1 h after injection, radioactivity started to disappear from endothelial cells and appeared instead in hepatocytes. Radioactivity subsequently declined in hepatocytes as well. After a lag phase of 4 h, significant amounts of radioactivity were recovered in bile. The in vitro uptake and hydrolysis of [14C]cholesteryl oleate-labeled acetyl-LDL were saturable in isolated rat liver endothelial cells. Native LDL does neither affect the uptake nor the hydrolysis of acetyl-LDL. Ammonia and monensin reduced the hydrolysis of acetyl-LDL in isolated liver endothelial cells. Furthermore, monensin at concentrations above 10 microM completely blocked the binding of acetyl-LDL to the liver endothelial cells, suggesting that the receptor for acetyl-LDL is trapped inside the cells. The liver endothelial cells may be involved in the protection against atherogenic lipoproteins, e.g. liver endothelial cells may mediate uptake of cholesterol from plasma and transfer of cholesterol to the hepatocytes for further secretion into the bile.     

Comparative acyl specificities for transfer and selective uptake of high density lipoprotein cholesteryl esters

This study compares the specificities of selective uptake and transfer mediated by plasma cholesteryl ester transfer protein (CETP) for various species of cholesteryl esters in high density lipoproteins (HDL). [3H]Cholesterol was esterified with a series of variable chain length saturated acids and a series of variably unsaturated 18-carbon acids. These were incorporated into synthetic HDL particles along with 125I-labeled apoA-I as a tracer of HDL particles and [14C]cholesteryl oleate as an internal standard for normalization between preparations. Selective uptake by Y1-BS1 mouse adrenal cortical tumor cells was most extensively studied, but uptake by human HepG2 hepatoma cells and fibroblasts of human, rat, and rabbit origin were also examined. Acyl chain specificities for selective uptake and for CETP-mediated transfer were conversely related; selective uptake by all cell types decreased with increasing acyl chain length and increased with the extent of unsaturation of C18 chains. In contrast, CETP-mediated transfer increased with acyl chain length, and decreased with unsaturation of C18 chains. The specificities of human and rabbit CETP were also compared, and were found to differ little. Associated experiments showed that HDL-associated triglycerides, traced by [3H]glyceryl trioleyl ether, were selectively taken up but at a lesser rate than cholesteryl esters. The mechanism of this uptake appears to be the same as for selective uptake of cholesteryl esters.     

Rapid transport of fatty acids from rat liver endothelial to parenchymal cells after uptake of cholesteryl ester-labeled acetylated LDL

Acetylated low-density lipoprotein (acetyl-LDL) radiolabeled in the oleate moiety of cholesteryloleate was injected into rats. Isolation of the various liver cell types at different times after acetyl-LDL injection by a low-temperature procedure allowed the intrahepatic metabolism of the oleate moiety to be followed in vivo. The cholesteryloleate radioactivity is rapidly cleared from the circulation and at 5 min after injection recovered into parenchymal and endothelial liver cells, mainly as cholesteryloleate ester. At longer time intervals after injection, the amount of cholesteryl esters associated with the endothelial cells was sharply decreased and the [14C]oleate was redistributed within the liver and mainly recovered in the parenchymal cells. The cholesteryl ester initially directly taken up by the parenchymal cells was also rapidly hydrolysed but, in contrast to the endothelial cells, the [14C]oleate remained inside the cells and was incorporated into triacylglycerols and phospholipids. The 14C radioactivity in parenchymal cells taken up between 5 and 30 min after injection of the cholesteryl [14C]oleate-labeled acetyl-LDL (transported as oleate from endothelial cells), followed a similar metabolic route as the amount which was directly associated to parenchymal cells. The data indicate that the liver and, in particular, the liver endothelial cell has the full capacity to rapidly catabolize modified lipoproteins. In this catabolism, the liver functions as an integrated organ in which fatty acids, formed from cholesteryl esters in endothelial cells, are rapidly transported to parenchymal cells, indicating the concept of metabolic cooperation between the various liver cell types.     

Metabolism of high density lipoprotein lipids by the rat liver: evidence for participation of hepatic lipase in the uptake of cholesteryl ester.

In order to determine the role of hepatic lipase in the hepatic uptake and metabolism of high density lipoprotein (HDL) triglycerides, cholesteryl esters, and phospholipids, isolated rat livers were perfused with a reconstituted HDL (rHDL) radiolabeled with [3H]triolein and [14C]cholesteryl oleate or palmitoyl-[14C]linoleoyl phosphatidylcholine. A bolus of radiolabeled rHDL was injected into the portal vein and livers were perfused for 5 min using a nonrecirculating perfusion system. Recovery of rHDL triolein in the liver as intact triolein was used to determine the amount of unmetabolized rHDL remaining in the liver. After correcting for the amount of unmetabolized rHDL remaining in the liver, about 30% of the rHDL triolein was hydrolyzed of which 19% was recovered in the liver and 11% in the perfusate. Moreover, about 7% of the rHDL phosphatidylcholine was hydrolyzed to lysophosphatidylcholine, all of which was recovered in the perfusate. Although there was no hydrolysis of rHDL cholesteryl oleate, about 30% of the cholesteryl oleate was taken up by the liver. Preperfusion of the liver with heparin to deplete the liver of hepatic lipase resulted in about a 70% reduction in rHDL triolein hydrolysis and about a 75% reduction in rHDL cholesteryl oleate uptake. Although hepatic lipase hydrolyzes both triglycerides and phosphatidylcholines, elimination of the triolein from rHDL had no effect on the uptake of rHDL cholesteryl oleate, but replacement of the rHDL phosphatidylcholine with a nonhydrolyzable phosphatidylcholine diether resulted in an 87% reduction in cholesteryl oleate uptake. These results indicate that hepatic lipase is necessary for the hepatic uptake of both HDL triglycerides and cholesteryl esters and that the uptake of cholesteryl esters is not dependent on the hydrolysis of HDL triglycerides but is dependent on the hydrolysis of HDL phospholipids.