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.     

Uptake of rat plasma HDL subfractions labeled with [3H]cholesteryl linoleyl ether or with 125I by cultured rat hepatocytes and adrenal cells

Rat plasma low- and high-density lipoproteins were labeled with [3H]cholesteryl linoleyl ether and isolated by rate-zonal ultracentrifugation into apolipoprotein B-containing LDL, apolipoprotein E-containing HDL1 and apolipoprotein E-poor HDL2. These fractions were incubated with cultured rat hepatocytes and comparable amounts of all lipoproteins were taken up by the cells. Rat HDL was isolated at d 1.085-1.21 g/ml and apolipoprotein E-free HDL was prepared by heparin Sepharose chromatography. The original HDL and the apolipoprotein E-free HDL were labeled with 125I or with [3H]cholesteryl linoleyl ether and incubated with rat hepatocytes or adrenal cells in culture. The uptake of apolipoprotein E-free [3H]cholesterol linoleyl ether HDL by the cultured hepatocytes was 20-40% more than that of the original HDL. Comparison of uptake of cholesteryl ester moiety (represented by uptake of [3H]cholesteryl linoleyl ether) and of protein moiety (represented by metabolism of 125I-labeled protein) was carried out using both original and apolipoprotein E-free HDL. In experiments in which low concentrations of HDL were used, the ratio of 3H/125I exceeded 1.0. In cultured adrenal cells, the uptake of [3H]cholesteryl linoleyl ether-labeled HDL was stimulated 3-6-fold by 1 X 10(-7) M ACTH, while the uptake of 125I-labeled HDL increased about 2-fold. The ratio of 3H/125I representing cellular uptake was 2-3 and increased to 5 in ACTH-treated cells. The present results indicate that in cultured rat hepatocytes the uptake of homologous HDL does not depend on the presence of apolipoprotein E. Evidence was also presented for an uptake of cholesteryl ester independent of protein uptake in cultured rat adrenal cells and to a lesser extent in rat hepatocytes.     

Putative role of cholesteryl ester transfer protein in removal of cholesteryl ester from vascular interstitium, studied in a model system in cell culture

A model system to study the putative role of cholesteryl ester transfer protein in the egress of interstitial cholesteryl ester is described. Confluent cultures of bovine aortic smooth muscle cells were labeled for 24 h with [3H]cholesteryl linoleyl ether and [14C]cholesteryl linoleate by incubation with bovine milk lipoprotein lipase. This method of labeling results in the transfer of cholesteryl linoleyl ether and cholesteryl ester to three compartments: a trypsin-releasable, trypsin-resistant and catabolic compartment (Stein, O., Halperin, G., Leitersdorf, E., Olivecrona, T. and Stein, Y. (1984) Biochim. Biophys. Acta 795, 47-59). The efflux of labeled cholesteryl linoleyl ether and cholesteryl ester from the extracellular and cell-surface related compartments into a serum-free culture medium containing 1% bovine serum albumin was studied during 24 h of postincubation. The efflux was expressed as a percentage of pulse value, i.e., radioactivity retained by the cell culture at the end of the labeling period. The efflux of [3H]cholesteryl linoleyl ether, [14C]cholesteryl ester and 14C-labeled free cholesterol (formed by cellular hydrolysis of cholesterol ester) into the culture medium with 1% bovine serum albumin was about 5% of the pulse value. Addition of human lipoprotein-deficient serum resulted in a 3-10-fold increase in the efflux of [3H]cholesteryl linoleyl ether and [14C]cholesteryl ester, but did not change markedly the efflux of 14C-labeled free cholesterol. Rat lipoprotein-deficient serum which does not contain cholesteryl ester transfer protein did not increase the efflux of [3H]cholesteryl linoleyl ether or [14C]cholesteryl ester. The rate of cholesteryl ester efflux in the presence of human lipoprotein-deficient serum was linear for about 6 h and increased further up to 24 h. Addition of Intralipid to medium containing human lipoprotein-deficient serum further enhanced the efflux of [3H]cholesteryl linoleyl ether and, to a lesser extent, that of cholesteryl ester. A similar effect was observed also by addition of rat VLDL to medium containing human lipoprotein-deficient serum. Inhibition of cholesteryl linoleyl ether and cholesteryl ester efflux and marked enhancement of free cholesterol efflux occurred when rat HDL was added to medium containing human lipoprotein-deficient serum, while human HDL was only slightly inhibitory. The results obtained with human lipoprotein-deficient serum were reproduced with partially purified cholesteryl ester transfer protein. Using the partially purified cholesteryl ester transfer protein, the efflux of cholesteryl linoleate was compared to that of cholesteryl oleate and was found to be the same.     

Effect of lipid transfer protein on plasma lipids, apolipoproteins and metabolism of high-density lipoprotein cholesteryl ester in the rat

The role of human plasma lipid transfer protein (LTP) in lipoprotein metabolism was studied in the rat, a species without endogenous cholesteryl ester and triacylglycerol transfer activity. Partially purified human LTP was injected intravenously into rats. The plasma activity was between 1.5- and 4-fold that of human plasma during the experiments. 6 h after the injection of LTP, a significant increase in serum apoB, and no significant changes in serum total cholesterol, free cholesterol, triacylglycerols, apoA-I, apoE, or apoA-IV were noted. Cholesterol was increased in very-low density and low-density lipoproteins (VLDL and LDL) and decreased in large-sized apoE-rich HDL. ApoA-I-containing particles with a size smaller than in normal rats were present in serum of LTP-treated rats. The mean diameter of HDL particles decreased and apoE, normally present on large-sized HDL, was present on smaller sized particles. The metabolic fate of cholesteryl ester, originally associated with HDL, was studied by injection of [3H]cholesteryl linoleyl ether-labelled apoA-I-rich HDL in the absence and in the presence of LTP. The disappearance of [3H]cholesteryl linoleyl ether, injected as part of apoA-I-rich HDL, from serum was increased in the LTP-treated rats; the t1/2 changed from 3.9 to 2.2 h, resulting in an increased accumulation of [3H]cholesteryl linoleyl ether in the liver. This can be explained by the redistribution of HDL [3H]cholesteryl linoleyl ether to VLDL and LDL in the presence of LTP, leading to the combined contribution of VLDL, LDL and HDL to the hepatic uptake. The present findings show profound effects of LTP on the chemical composition of HDL subspecies, the size of HDL and on the plasma turnover and hepatic uptake of cholesteryl esters originally present in apo A-I-rich HDL.     

Uptake of high-density lipoprotein-associated apoprotein A-I and cholesterol esters by 16 tissues of the rat in vivo and by adrenal cells and hepatocytes in vitro

The uptake of high-density lipoprotein (HDL)-associated apolipoprotein A-I and cholesterol esters was estimated in 16 tissues of the rat using rat HDL doubly labeled with nondegradable tracers; covalently attached 125I-tyramine-cellobiose traced apo-A-I, and [3H]cholesteryl linoleyl ether traced cholesterol esters. Both labels remained associated with the HDL fraction in the plasma, adequately traced their unlabeled counterparts, and were well trapped at their sites of uptake. Cholesteryl ether was taken up at a greater fractional rate than apo-A-I by adrenal, ovary, and liver: 7-fold, 4-fold, and 2-fold greater, respectively. The rates of uptake of cholesteryl ether and apo-A-I were about equal in the other tissues (except kidney). The disproportionate uptake of HDL cholesteryl ether relative to HDL apo-A-I was also observed in primary cultures of rat adrenal cells and hepatocytes. Uptake of both moieties in both cell types showed saturability. Both the absolute rate of uptake of [3H]cholesteryl ether and the ratio of ether uptake to apo-A-I uptake were greater in adrenal cells than in hepatocytes, consonant with the in vivo observations. Very similar results were obtained using HDL biologically labeled with [3H]cholesterol esters. The disproportionate uptake of [3H]cholesteryl ether was not significantly decreased by depletion of apo-E from the HDL nor by reductive methylation of the apo-E to block its recognition by receptors. However, apo-A-I uptake was decreased, suggesting that apo-E mediates the uptake of particles containing apo-A-I but does not contribute to the disproportionate uptake of [3H]cholesteryl ether.     

Preferential binding of [3H]cholesteryl linoleyl ether-HDL3 by bovine adrenal membranes

Membranes isolated from bovine adrenal cortex, incubated with human high-density lipoproteins (HDL3), labeled with 125I and [3H]cholesteryl linoleyl ether, showed preferential binding of [3H]cholesteryl linoleyl ether. The preferential binding was Ca2+ independent, temperature sensitive and was slightly increased after phospholipase C or pronase treatment. Reduction of membrane phosphatidylcholine by phospholipase A2 resulted in a marked increase in the binding of the entire HDL3 particle and a relative decrease in preferential binding of [3H]cholesteryl linoleyl ether. These findings suggest that the presence of intact phospholipid in the membrane plays an important role in the magnitude of the preferential binding.     

Scavenger receptor class B type I is solely responsible for the selective uptake of cholesteryl esters from HDL by the liver and the adrenals in mice

Scavenger receptor class B type I (SR-BI) has been identified as a functional HDL binding protein that can mediate the selective uptake of cholesteryl ester (CE) from HDL. To quantify the in vivo role of SR-BI in the process of selective uptake, HDL was labeled with cholesteryl ether ([(3)H] CEt-HDL) and (125)I-tyramine cellobiose ([(125)I]TC-HDL) and injected into SR-BI knockout (KO) and wild-type (WT) mice. In SR-BI KO mice, the clearance of HDL-CE from the blood circulation was greatly diminished (0.043 +/- 0.004 pools/h for SR-BI KO mice vs. 0.106 +/- 0.004 pools/h for WT mice), while liver and adrenal uptake were greatly reduced. Utilization of double-labeled HDL ([(3)H]CEt and [(125)I]TC) indicated the total absence in vivo of the selective decay and liver uptake of CE from HDL in SR-BI KO mice. Parenchymal cells isolated from SR-BI KO mice showed similar association values for [(3)H]CEt and [(125)I]TC in contrast to WT cells, indicating that in parenchymal liver cells SR-BI is the only molecule exerting selective CE uptake from HDL. Thus, in vivo and in vitro, SR-BI is the sole molecule mediating the selective uptake of CE from HDL by the liver and the adrenals, making it the unique target to modulate reverse cholesterol transport.     

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.     

High-density lipoprotein particle uptake and selective uptake of high-density lipoprotein-associated cholesteryl esters by J774 macrophages

High-density lipoprotein (HDL) cholesteryl esters are taken up by fibroblasts via HDL particle uptake and via selective uptake, i.e., cholesteryl ester uptake independent of HDL particle uptake. In the present study we investigated HDL selective uptake and HDL particle uptake by J774 macrophages. HDL3 (d = 1.125-1.21 g/ml) was labeled with intracellularly trapped tracers: 125I-labeled N-methyltyramine-cellobiose-apo A-I (125I-NMTC-apo A-I) to trace apolipoprotein A-I (apo A-I) and [3H]cholesteryl oleyl ether to trace cholesteryl esters. J774 macrophages, incubated at 37 degrees C in medium containing doubly labeled HDL3, took up 125I-NMTC-apo A-I, indicating HDL3 particle uptake (102.7 ng HDL3 protein/mg cell protein per 4 h at 20 micrograms/ml HDL3 protein). Apparent HDL3 uptake according to the uptake of [3H]cholesteryl oleyl ether (470.4 ng HDL3 protein/mg cell protein per 4 h at 20 micrograms/ml HDL3 protein) was in significant excess on 125I-NMTC-apo A-I uptake, i.e., J774 macrophages demonstrated selective uptake of HDL3 cholesteryl esters. To investigate regulation of HDL3 uptake, cell cholesterol was modified by preincubation with low-density lipoprotein (LDL) or acetylated LDL (acetyl-LDL). Afterwards, uptake of doubly labeled HDL3, LDL (apo B,E) receptor activity or cholesterol mass were determined. Preincubation with LDL or acetyl-LDL increased cell cholesterol up to approx. 3.5-fold over basal levels. Increased cell cholesterol had no effect on HDL3 particle uptake. In contrast, LDL- and acetyl-LDL-loading decreased selective uptake (apparent uptake 606 vs. 366 ng HDL3 protein/mg cell protein per 4 h in unloaded versus acetyl-LDL-loaded cells at 20 micrograms HDL3 protein/ml). In parallel with decreased selective uptake, specific 125I-LDL degradation was down-regulated. Using heparin as well as excess unlabeled LDL, it was shown that HDL3 uptake is independent of LDL (apo B,E) receptors. In summary, J774 macrophages take up HDL3 particles. In addition, J774 cells also selectively take up HDL3-associated cholesteryl esters. HDL3 selective uptake, but not HDL3 particle uptake, can be regulated.     

Tissue distribution of [3H]cholesteryl linoleyl ether-labeled human Lp(a) in different rat organs

The sites of tissue uptake of human lipoprotein(a) (Lp(a] were studied in rats using [3H]cholesteryl linoleyl ether [( 3H]CLE) as a marker. Since rat plasma has no cholesteryl ester transfer activity, the amount of label in various tissues should reflect the quantitative uptake of Lp(a). Isolated Lp(a) was labeled with [3H]CLE by incubation overnight of Lp(a), a source of cholesteryl ester transfer activity (1.23 g/ml infranate of human plasma), and [3H]CLE-labeled Intralipid. Following labeling, the homogeneity and integrity of Lp(a) was shown by agarose electrophoresis and immunoblotting. Intact Lp(a) was injected via the tail vein of rats (120-170 g, n = 4 at each time point), and tissues were collected at various times thereafter (4-48 h). The disappearance curve of [3H]CLE-labeled Lp(a) from rat plasma was bimodal and had an initial rapid t1/2 of 1.8 h followed by a slower component, t1/2 = 13.3 h. Tissue uptake at all sampling times was greatest in liver (28.5% at 48 h of total dpm injected), followed by the intestine (9-12%), with less than 3% uptake by spleen. The small intestine was divided into four segments, and while the 3H radioactivity was similar in the proximal segments, a time-related increase in [3H]CLE was seen in its most distal portion. These studies indicate that the tissue sites of degradation in the rat of human Lp(a) are similar to human low-density lipoproteins (LDL); the increase in label in the distal portion of the small intestine with time may represent [3H]CLE excreted through the bile and absorbed by the mucosal cells.     

Removal of cholesteryl ester from hepatic reticuloendothelial cells in vivo is not enhanced by plasma cholesteryl ester transfer protein

The putative role of cholesteryl ester transfer protein (CETP) in the removal of cholesteryl ester from hepatic reticuloendothelial cells in vivo was studied in hamsters. The parameter tested was retention of [3H]cholesteryl linoleyl ether ([3H]CLE), a nonhydrolysable analog of cholesteryl ester, in the liver after injection of [3H]CLE labeled acetylated LDL, which is targetted to nonparenchymatous littoral cells. In hamsters fed laboratory chow, plasma cholesteryl ester transfer activity (CETA) was 10.6 +/- 0.9 units and the retention of [3H]CLE in the liver 28 days after injection was 86% of the 4 h value. It was about 55% in rats fed the same diet, in which CETA was not detectable. When the diet was supplemented with 2% cholesterol and 15% margarine, CETA activity in hamsters increased 2-fold, yet no change in retention of [3H]CLE in liver was seen after 28 days. In rats, the retention of [3H]CLE in the liver was also not changed by the dietary fat supplementation. These results do not support the role of CETP in vivo in removal of cholesteryl ester from intact reticuloendothelial cells.     

Caveolin-1 negatively regulates SR-BI mediated selective uptake of high-density lipoprotein-derived cholesteryl ester.

The class B, type I scavenger receptor (SR-BI) mediates the selective uptake of high density lipoprotein (HDL) cholesteryl esters and the efflux of free cholesterol. SR-BI is predominantly associated with caveolae in Chinese hamster ovary cells. The caveola protein, caveolin-1, binds to cholesterol and is involved in intracellular cholesterol trafficking. We previously demonstrated a correlative increase in caveolin-1 expression and the selective uptake of HDL cholesteryl esters in phorbol ester-induced differentiated THP-1 cells. The goal of the present study was to determine if the expression of caveolin-1 is the causative factor in increasing selective cholesteryl ester uptake in macrophages. To test this, we established RAW and J-774 cell lines that stably expressed caveolin-1. Transfection with caveolin-1 cDNA did not alter the amount of 125I-labeled HDL that associated with the cells, although selective uptake of HDL [3H]cholesteryl ether was decreased by approximately 50%. The amount of [3H]cholesterol effluxed to HDL was not affected by caveolin-1. To directly address whether caveolin-1 inhibits SR-BI-dependent selective cholesteryl ester uptake, we overexpressed caveolin-1 by adenoviral vector gene transfer in Chinese hamster ovary cells stably transfected with SR-BI. Caveolin-1 inhibited the selective uptake of HDL [3H]cholesteryl ether by 50-60% of control values without altering the extent of cell associated HDL. We next used blocking antibodies to CD36 and SR-BI to demonstrate that the increase in selective [3H]cholesteryl ether uptake previously seen in differentiated THP-1 cells was independent of SR-BI. Finally, we used beta-cyclodextrin and caveolin overexpression to demonstrate that caveolae depleted of cholesterol facilitate SR-BI-dependent selective cholesteryl ester uptake and caveolae containing excess cholesterol inhibit uptake. We conclude that caveolin-1 is a novel negative regulator of SR-BI-dependent selective cholesteryl ester uptake.     

Angiotensin II stimulates receptor-mediated uptake of LDL by bovine adrenal cortical cells in primary culture

Bovine adrenal cells were isolated from the subcapsular region of the gland to obtain cultures enriched in cells of the zona glomerulosa. The cells kept in primary cultures were shown to respond to angiotensin II and adrenocorticorticotropin (ACTH) by a significant increase in aldosterone production. These primary adrenal cultures were used to study the effect of angiotensin II on LDL metabolism. Addition of angiotensin II for 48 h to the culture medium resulted in a 200-300% increase in LDL metabolism, and the lowest effective concentration was 10(-8) -10(-9) M. The angiotensin II effect became evident after 12-16 h of incubation. To compare the metabolism of the 125I-labeled protein moiety to that of cholesteryl ester of LDL, the lipoprotein was labeled also with cholesteryl linoleyl ether, a nonhydrolyzable analog of cholesteryl ester. Under basal conditions and in the presence of angiotensin II or ACTH the ratio of [3H]cholesteryl linoleyl ether to 125I indicate some preferential uptake of the cholesteryl ester moiety. Stimulation of specific LDL binding at 4 degrees C and LDL metabolism at 37 degrees C by 10(-7) M angiotensin II occurred at all concentrations of LDL studied. Linearization of the kinetic data showed that angiotensin II increased the LDL receptor number significantly but not the affinity of the LDL receptor for its ligand. The present findings indicate that in analogy to ACTH, angiotensin II can influence receptor-mediated uptake of LDL by adrenal cortical cells. It remains to be shown whether the angiotensin II effect on LDL metabolism is limited to adrenal cells or will affect other cells which express the angiotensin II receptor.     

Lipoprotein lipase mediates an increase in selective uptake of HDL-associated cholesteryl esters by cells in culture independent of scavenger receptor BI.

Scavenger receptor class B type I (SR-BI) mediates the selective uptake of HDL cholesteryl esters (CEs) by the liver. LPL promotes this selective lipid uptake independent of lipolysis. In this study, the role of SR-BI in the mechanism of this LPL-mediated increase in selective CE uptake was explored. Baby hamster kidney (BHK) cells were transfected with the SR-BI cDNA, and significant SR-BI expression could be detected in immunoblots, whereas no SR-BI was visualized in control cells. Y1-BS1 murine adrenocortical cells were cultured without or with adrenocorticotropic hormone, and cells with no detectable or with SR-BI were obtained. These cells incubated without or with LPL in medium containing 125I/[3H]cholesteryl oleyl ether- labeled HDL3; tetrahydrolipstatin inhibited the catalytic activity of LPL. In BHK and in Y1-BS1 cells without or with SR-BI expression, apparent HDL3 selective CE uptake ([3H]CEt - 125I) was detectable. Cellular SR-BI expression promoted HDL3 selective CE uptake by approximately 250-1,900%. In BHK or Y1-BS1 cells, LPL mediated an increase in apparent selective CE uptake. Quantitatively, this stimulating LPL effect was very similar in control cells and in cells with SR-BI expression. The uptake of radiolabeled HDL3 was also investigated in human embryonal kidney 293 (HEK 293) cells that are an established SR-BI-deficient cell model. LPL stimulated [3H]cholesteryl oleyl ether uptake from labeled HDL3 by HEK 293 cells substantially, showing that LPL can induce selective CE uptake from HDL3 independent of SR-BI. To explore the role of cell surface proteoglycans on lipoprotein uptake, we induced proteoglycan deficiency by heparinase treatment. Proteoglycan deficiency decreased the LPL-mediated promotion of HDL3 selective CE uptake. In summary, evidence is presented that the stimulating effect of LPL on HDL3 selective CE uptake is independent of SR-BI and lipolysis. However, cell surface proteoglycans are required for the LPL action on selective CE uptake. It is suggested that pathways distinct from SR-BI mediate selective CE uptake from HDL.     

Intravascular metabolism of the cholesteryl ester moiety of rat plasma lipoproteins

The intravascular metabolism of the cholesteryl ester moiety of rat plasma LDL, HDL1, and HDL2 was determined in intact male rats. Biosynthetically labeled lipoproteins were prepared by zonal ultracentrifugation from the plasma of rats injected with [3H]cholesterol. The lipoproteins were concentrated by vacuum ultrafiltration as other procedures were found to alter the biological properties of the lipoproteins. After injection of labeled LDL, [3H]cholesteryl esters remained with the injected lipoprotein and decayed from plasma with a t1/2 of 7-8 hours. [3H]Cholesteryl esters in HDL1 behaved similarly and decayed with a t1/2 of 10.5 hours. With HDL2, however, a different metabolic pattern was observed with intraplasma conversion of some [3H]cholesteryl ester HDL2 particles to HDL1. Since such conversion of HDL2 to HDL1 was not observed after in vitro incubations of rat plasma, this process seems to depend on metabolic events that occur in vivo. [3H]Cholesteryl esters disappeared from HDL2 with a t1/2 of 6-7 hours, while the esters that were transferred to HDL1 decayed with a t1/2 of 10-11 hours, similar to labeled cholesteryl esters injected with HDL1. The study demonstrated that the high apoE content of rat plasma HDL1 is not associated with rapid catabolism of the lipoprotein and that a major source of HDL1 in the rat is the intraplasma conversion of HDL2 particles to HDL1.     

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.     

Cholesterol removal by peritoneal lavage with phospholipid-HDL apoprotein mixtures in hypercholesterolemic hamsters

Syrian hamsters were rendered hypercholesterolemic by supplementation of their diet with 1% cholesterol and 15% butter. The hamsters were injected intraperitoneally (i.p.) with about 20 mg of phospholipid liposomes containing trace amounts of [3H]cholesteryl linoleyl ether ([ 3H]CLE) alone or combined with 10 mg delipidated high-density lipoprotein (apoHDL). After 2 h the peritoneal cavity was washed repeatedly with up to 15 ml phosphate-buffered saline. 60%-70% of [3H]CLE were retained after i.p. injection without apoHDL, 30-50% in the presence of apoHDL. The amount of free cholesterol recovered in the peritoneal lavage was significantly higher when apoHDL was combined with 18:2 sphingomyelin or dilinoleyl phosphatidylcholine liposomes, when compared to either liposomes or apoHDL alone. It is suggested that supplementation of dialysate with HDL apolipoproteins and phospholipids in patients undergoing continuous peritoneal dialysis could be of use in a cholesterol depletion regimen.     

Regulation of the selective uptake of high density lipoprotein-associated cholesteryl esters by human fibroblasts and Hep G2 hepatoma cells

We have previously shown that the liver and steroidogenic tissues of rats in vivo and a wider range of cells in vitro, including human cells, selectively take up high density lipoprotein (HDL) cholesteryl esters without parallel uptake of HDL particles. This process is regulated in tissues of rats and in cultured rat cells according to their cholesterol status. In the present study, we examined regulation of HDL selective uptake in cultured human fibroblasts and Hep G2 hepatoma cells. The cholesterol content of these cells was modified by a 20-hr incubation with either low density lipoprotein (LDL) or free cholesterol. Uptake of HDL components was examined in a subsequent 4-6-hr assay using intracellularly trapped tracers: 125I-labeled N-methyl-tyramine-cellobiose-apoA-I (125I-NMTC-apoA-I) to trace apoA-I, and [3H]cholesteryl oleyl ether to trace cholesteryl esters. In the case of fibroblasts, pretreatment with either LDL or free cholesterol resulted in decreased selective uptake (total [3H]cholesteryl ether uptake minus that due to particle uptake as measured by 125I-NMTC-apoA-I). In contrast, HDL particle uptake increased with either form of cholesterol loading. The amount of HDL that was reversibly cell-associated (bound) was increased by prior exposure to free cholesterol, but was decreased by prior exposure to LDL. In the case of Hep G2 cells, exposure to free cholesterol only slightly increased HDL particle uptake; selective uptake decreased after both forms of cholesterol loading, and reversibly bound HDL increased after exposure to free cholesterol, but either did not change or decreased after exposure to LDL. It was excluded that either LDL carried over into the HDL uptake assay or that products secreted by the cultured cells influenced these results. Thus, selective uptake by cells of both hepatic and extrahepatic origin was down-regulated by cholesterol loading, under which conditions HDL particle uptake increased. Total HDL binding was not directly correlated with either the rate of selective uptake or the rate of HDL particle uptake or the cholesterol status of the cells, suggesting more than one type of HDL binding site.     

Tissue sites of degradation of apoprotein A-I in the rat

The tissue sites of degradation of apoprotein A-I were determined in the rat in vivo using a newly developed tracer of protein catabolism, an adduct of 125I-tyramine and cellobiose. This methodology takes advantage of the fact that when a protein labeled with 125I-tyramine-cellobiose is taken up and degraded, the radiolabeled ligand remains trapped intracellularly. Thus, radio-iodine accumulation in a tissue acts as a cumulative measure of protein degradation in that tissue. In the present studies, apoprotein AI (apo-A-I) was labeled with tyramine-cellobiose (TC). The TC-labeled apo-A-I was then reassociated with high density lipoprotein (HDL) in vivo by injection into donor animals. After 30 min, serum from donor animals was recovered and then injected into recipient rats. TC-labeled apo-A-I in the donor serum was shown to be exclusively associated with HDL. The fractional catabolic rate of 125I-TC-apo-A-I was not significantly different from that of conventionally labeled apo-A-I. The kidney was the major site of degradation, accounting for 39% of the total. The liver was responsible for 26% of apo-A-I catabolism, 96% of which occurred in hepatocytes. The kidney was also the most active organ of catabolism/g of wet weight. The tissues next most active/g of wet weight were ovary and adrenal, a finding that is compatible with a special role of HDL in the rat for delivery of cholesterol for steroidogenesis. Immunofluorescence studies of frozen sections of rat kidney demonstrated the presence of apo-A-I on the brush-border and in apical granules of proximal tubule epithelial cells. Preliminary studies using HDL labeled both with 125I-TC-apo-A-I and [3H]cholesteryl ethers again demonstrated high rates of renal uptake of apo-A-I but less than 1% of total ether uptake. It is postulated that the high activity of kidney was not due to uptake of intact HDL particles, but rather, due to glomerular filtration and tubular reabsorption of free apo-A-I.     

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.