Role of endothelial cells and their products in the modification of low-density lipoproteins

A majority of the LDL preparations from various donors could be modified by incubation with endothelial cells from human arteries, veins and microvessels. These alterations comprise changes in electrophoretic mobility, buoyant density and lipid composition of LDL, the generation of thiobarbituric acid reactive substances in the medium, and a decrease in primary amino groups of LDL. Furthermore, the association of endothelial cell proteins with LDL was demonstrated by [35S]methionine incorporation and trichloroacetic acid precipitation of reisolated endothelial cell-modified LDL. After SDS-polyacrylamide gel electrophoresis of the reisolated modified LDL particles, radioactivity was mainly found at a molecular mass of 48 kDa and at one or two bands with a molecular mass of more than 100 kDa. The 48 kDa protein was identified as a latent plasminogen activator inhibitor. Cell viability was necessary for the cell-mediated LDL modification, which indicates that endothelial cells are actively involved in this process. The Ca2+ ionophore A23187 and monensin did not influence LDL modification. LDL modification was markedly inhibited by antioxidants. It was not prevented by cyclooxygenase and lipoxygenase inhibitors, which indicates that non-enzymatic lipid peroxidation is involved. Transition metal- (copper-) induced lipid peroxidation results in similar physiochemical alterations of the LDL particle as found with endothelial cells; it is prevented by the presence of superoxide dismutase. In contrast, endothelial cell LDL modification was not influenced by superoxide dismutase. Catalase or singlet oxygen and hydroxyl radical scavengers also did not affect it. We suggest that yet unidentified radicals or lipid peroxides are generated in the cells or on the cell membrane and that these reactive molecule(s) will react with LDL after leaving the cell. HDL and lipoprotein-depleted serum prevented LDL modification markedly, and to a larger extent than that by copper ions. We speculate that LDL modification by endothelial cells will only occur under those conditions in which the balance between the generation of reactive oxygen molecules and the cellular protection against these reactive species is disturbed.     

Role of superoxide in endothelial-cell modification of low-density lipoproteins

Cultured endothelial cells and arterial smooth muscle cells have been shown to modify LDL in a way that leads to rapid uptake by macrophages. Previous studies have demonstrated that this modification involves free radical peroxidation of LDL, and that the role of the cells was to accelerate oxidation under conditions where it otherwise would occur slowly. The objective of the present study was to determine whether the modification was mediated by oxygen-derived free radicals, and whether the ability of a given cell type of line to modify LDL was related to its secretion rate of O2- or H2O2. The results showed that modification required the presence of oxygen, and could be specifically inhibited by superoxide dismutase but not by catalase or by mannitol, a hydroxyl radical scavenger. Rabbit aortic endothelial cells, rabbit arterial smooth muscle cells, monkey arterial smooth muscle cells and human skin fibroblasts were all found to modify LDL, and all of these cell types generated more O2- (superoxide dismutase-inhibitable cytochrome c reduction) than a line of bovine aortic endothelial cells that did not modify LDL. The content of superoxide dismutase and catalase was higher in bovine aortic endothelial cells than in the cell lines that modified LDL, but glutathione peroxidase levels were not different. It was concluded that cells that were capable of modifying LDL produced superoxide or a substance that could be converted to superoxide in the medium, and that superoxide was an important, though possibly indirect, mediator of the modification of LDL by cells.     

Macrophage-derived factors increase low density lipoprotein uptake and receptor number in cultured human liver cells.

Recent evidence suggests the possibility that macrophages can influence lipoprotein metabolism. Therefore we investigated the ability of cultured macrophages to alter low density lipoprotein (LDL) uptake in a human liver cell line (HepG2). Conditioned media from phlogogenic-induced mouse peritoneal macrophages or from a human macrophage cell line stimulated with endotoxin increased HepG2 LDL uptake by as much as 60-70%. The increase was due, in part, to a significant macrophage-induced 40% increase in the number of LDL receptors per cell. Although macrophage conditioned media inhibited HepG2 cholesterol synthesis, the LDL receptor up-regulation did not appear to be due to the effects on cholesterol synthesis. The LDL receptor stimulatory activity was sensitive to proteolysis and heat. Its molecular mass was approximately 20 kDa based on gel filtration. Several macrophage secretory proteins were tested in HepG2 cultures for LDL uptake stimulation. Of these, oncostatin M (approximately 18 kDa by gel filtration) gave the strongest response. The rank order for LDL uptake stimulation was oncostatin M much greater than interleukin 6 = interleukin 1 = transforming growth factor-beta 1. A neutralizing antibody directed against oncostatin M inhibited the ability of conditioned media to up-regulate LDL receptors by 85%. Thus, our results indicate that macrophages can secrete several proteins that up-regulate LDL receptors in HepG2 cells and that most of the up-regulatory activity in macrophage conditioned media appears to be due to oncostatin M.     

Expression of caveolin‐1 in hepatic cells increases oxidized LDL uptake and preserves the expression of lipoprotein receptors

Oxidized LDL (OxLDL) that are positively associated with the risk of developing cardiovascular diseases are ligands of scavenger receptor‐class B type I (SR‐BI) and cluster of differentiation‐36 (CD36) which can be found in caveolae. The contribution of these receptors in human hepatic cell is however unknown. The HepG2 cell, a human hepatic parenchymal cell model, expresses these receptors and is characterized by a very low level of caveolin‐1. Our aim was to define the contribution of human CD36, SR‐BI, and caveolin‐1 in the metabolism of OxLDL in HepG2 cells and conversely the effects of OxLDL on the levels/localization of these receptors. By comparing mildly (M)‐ and heavily (H)‐OxLDL metabolism between control HepG2 cells and HepG2 cells overexpressing CD36, SR‐BI, or caveolin‐1, we found that (1) CD36 increases M‐ and H‐OxLDL‐protein uptake; (2) SR‐BI drives M‐OxLDL through a degradation pathway at the expense of the cholesterol ester (CE) selective uptake pathway; (3) caveolin‐1 increases M‐ and H‐OxLDL‐protein uptake and decreases CE selective uptake from M‐OxLDL. Also, incubation with M‐ or H‐OxLDL decreases the levels of SR‐BI and LDL‐receptor in control HepG2 cells which can be overcome by caveolin‐1 expression. In addition, OxLDL move CD36 from low to high buoyant density membrane fractions, as well as caveolin‐1 in cells overexpressing this protein. Thus, hepatic caveolin‐1 expression has significant effects on OxLDL metabolism and on lipoprotein receptor levels. J. Cell. Biochem. 108: 906–915, 2009. © 2009 Wiley‐Liss, Inc.     

Oncostatin M up-regulates low density lipoprotein receptors in HepG2 cells by a novel mechanism.

Oncostatin M is a growth regulatory protein secreted by macrophages and activated T lymphocytes. In a hepatoma cell line (HepG2) the polypeptide very potently increased low density lipoprotein (LDL) uptake with an EC50 of 0.1-0.2 nM. The stimulation of LDL uptake was detectable by 2 h, was maximal by 8 h, and remained elevated through 20 h of oncostatin M incubation. In a similar fashion, oncostatin M also increased the number of cell surface LDL receptors by a mechanism that was inhibited by cycloheximide or the protein kinase C inhibitor H-7. Oncostatin M stimulation of LDL uptake and receptor protein occurred regardless of the state of cholesterol-dependent regulation of HepG2 LDL receptor (i.e. cells incubated in medium containing lipoproteins responded to the same extent as did cells incubated in the absence of lipoproteins). No significant effects were observed on sterol synthesis over 8 h or on DNA synthesis over 24 h. Oncostatin M induced rapid alterations in HepG2 phospholipid metabolism. Within 5-15 min there was a 20-50% increase in incorporation of 32P into several classes of phospholipids, including the phosphoinositides. Radiolabeled diacylglycerol levels were elevated 20% by 2 min and nearly 50% by 15 min. In addition, the polypeptide induced rapid increased (within 1 min) in phosphorylation of HepG proteins on tyrosine residues. Stimulation of both phosphotyrosine and LDL receptor up-regulation by oncostatin M was decreased by the tyrosine kinase inhibitor genistein. We propose that oncostatin M up-regulates HepG2 LDL receptor expression by a mechanism that includes stimulation of a tyrosine kinase followed by generation of phospholipid-related second messengers.     

Lipoxygenase-mediated transformation of human low density lipoprotein to an oxidized and cytotoxic complex

We have been studying the mechanisms involved in the oxidative modification of low density lipoprotein (LDL) that lead to its transformation to a cytotoxic complex. Here we examine the direct effect-of soybean lipoxygenase (SLO), a 15-lipoxygenase, on normal human LDL. SLO oxidized LDL and rendered it cytotoxic; agents known to interfere with lipoxygenase activity inhibited this reaction. Enhancement of both the SLO-mediated LDL oxidation and the conversion of LDL to a cytotoxin was observed when either superoxide dismutase or copper (II) (3,5,-diisopropylsalicylic acid)2, both of which dismute superoxide anion, were included during the incubation of SLO with LDL. In contrast, catalase inhibited this reaction in the presence or absence of agents that dismute superoxide anion. Thus, purified lipoxygenase can mediate LDL modification and superoxide anion inhibits this reaction, Furthermore, H2O2 is essential for SLO-mediated LDL oxidation and conversion of LDL to a cytotoxin.     

VDAC-dependent permeabilization of the outer mitochondrial membrane by superoxide induces rapid and massive cytochrome c release.

Enhanced formation of reactive oxygen species (ROS), superoxide (O2*-), and hydrogen peroxide (H2O2) may result in either apoptosis or other forms of cell death. Here, we studied the mechanisms underlying activation of the apoptotic machinery by ROS. Exposure of permeabilized HepG2 cells to O2*- elicited rapid and massive cytochrome c release (CCR), whereas H2O2 failed to induce any release. Both O2*- and H2O2 promoted activation of the mitochondrial permeability transition pore by Ca2+, but Ca2+-dependent pore opening was not required for O2*--induced CCR. Furthermore, O2*- alone evoked CCR without damage of the inner mitochondrial membrane barrier, as mitochondrial membrane potential was sustained in the presence of extramitochondrial ATP. Strikingly, pretreatment of the cells with drugs or an antibody, which block the voltage-dependent anion channel (VDAC), prevented O2*--induced CCR. Furthermore, VDAC-reconstituted liposomes permeated cytochrome c after O2*- exposure, and this release was prevented by VDAC blocker. The proapoptotic protein, Bak, was not detected in HepG2 cells and O2*--induced CCR did not depend on Bax translocation to mitochondria. O2*--induced CCR was followed by caspase activation and execution of apoptosis. Thus, O2*- triggers apoptosis via VDAC-dependent permeabilization of the mitochondrial outer membrane without apparent contribution of proapoptotic Bcl-2 family proteins.     

The binding of human lipoprotein lipase treated VLDL by the human hepatoma cell line HepG2.

It has been suggested that besides the LDL-receptor, hepatocytes possess an apo E or remnant receptor. To evaluate which hepatic lipoprotein receptor is involved in VLDL remnant catabolism, we studied the binding of VLDL remnants to HepG2 cells. Native VLDL was obtained from type IIb hyperlipidemic patients and treated with bovine milk lipoprotein lipase (LPL). This LPL-treated VLDL (LPL-VLDL) was used as representative for VLDL remnants. Our results show that LPL-VLDL binds with high affinity to HepG2 cells. Competition experiments showed that the binding of 125I-labelled LPL-VLDL is inhibited to about 30% of the control value by the simultaneous addition of an excess of either unlabelled LDL or LPL-VLDL. Preincubation of HepG2 cells with LDL resulted in a reduction of the binding of LDL and LPL-VLDL to 34 and 55% of the control value, whereas preincubation of the cells with heavy HDL (density between 1.16 and 1.21 g/ml) stimulated the binding of LDL and LPL-VLDL to about 230% of the control value. Preincubation of the cells with insulin (250 nM/l) also stimulated the binding of both LDL and LPL-VLDL (175 and 143% of the control value, respectively). We conclude that LPL-VLDL binds to the LDL-receptor of HepG2 cells and that no evidence has been obtained for the presence on HepG2 cells of an additional receptor that is involved in the binding of VLDL remnants.     

Low density lipoprotein cytotoxicity induced by free radical peroxidation of lipid

Low density lipoprotein (LDL) has been reported to be injurious or toxic to cells in vitro. This injurious effect is, in some instances, due to oxidation of the lipid moiety of the lipoprotein. The objectives of this study were to determine if the oxidation rendering the lipoprotein toxic to human skin fibroblasts occurred by free radical mechanisms, and if so, which of the common free radical oxygen species were involved. The selective free radical blockers or scavengers employed included superoxide dismutase for superoxide, catalase for hydrogen peroxide, dimethylfuran for singlet molecular oxygen, and mannitol for hydroxyl radical. The presence during lipoprotein preparation of general free radical scavengers (vitamin E, butylated hydroxytoluene) or the divalent cation chelator ethylenediamine tetraacetic acid prevented the formation of cytotoxic low density lipoprotein, while the simultaneous presence of superoxide dismutase and catalase partially inhibited its formation. The results indicate that superoxide and/or hydrogen peroxide are involved in the formation of the toxic LDL lipid. The toxic action of oxidized LDL could not be prevented by inclusion of antioxidants in the culture medium, indicating that an oxidized lipid was responsible for cell injury rather than free radicals generated in culture by the action of oxidized LDL. Three separate assays for cell injury (enumeration of attached cells, cell loss of lactate dehydrogenase into the culture medium, and trypan blue uptake) indicated a sequence of events in which the fibroblasts are injured, die, and then detach.     

Superoxide anion participation in human monocyte-mediated oxidation of low-density lipoprotein and conversion of low-density lipoprotein to a cytotoxin

Human monocytes, upon activation with opsonized zymosan, altered low-density lipoprotein (LDL) during a 24-h co-incubation, resulting in its oxidation and acquisition of cytotoxic activity against target fibroblast cell lines. Both the oxidation of LDL and its conversion to a cytotoxin were enhanced with time of incubation, with the most substantial changes occurring after 6 h of culture of LDL with activated monocytes. Unactivated monocytes did not mediate either alteration. Superoxide anion (O2-) participated in both the oxidation of LDL and its conversion to a cytotoxin since addition of superoxide dismutase (SOD) at the beginning of the co-incubation inhibited, in a concentration dependent fashion, both the monocyte-mediated oxidation and the monocyte-mediated conversion of LDL to a cytotoxin. As expected, the rate of superoxide anion release was greatest during the respiratory burst, very early in the 24-h incubation (0 to 2 h); however, exposure of LDL to monocytes during the respiratory burst was not required for LDL oxidation. The lower levels of O2- released by the cells hours after the respiratory burst had subsided were sufficient to lead to the initiation of LDL oxidation. Three results indicated that the oxidative modification of LDL into a cytotoxin required O2(-)-independent free radical propagation after O2(-)-dependent initiation. First, oxidation of LDL exposed to the activated, superoxide anion-releasing monocytes for 6 h could be almost completely blocked by the addition at 6 h of the general free radical scavenger butylated hydroxytoluene, but not by SOD. Second, LDL oxidation proceeded even after removal of LDL from the superoxide anion-producing, activated cells after various durations of exposure. Third, the development of substantial levels of lipid peroxidation products and the development of greater cytotoxicity occurred after 6 h of exposure of LDL to activated cells, long after peak O2- release had subsided. These results lead us to conclude that monocyte-mediated oxidation of LDL, leading to its transformation into a cytotoxin, requires release of O2- occurring as a result of activation but not necessarily during the respiratory burst, and also requires O2(-)-independent free radical propagation. The modification of LDL into a potent toxin by activated monocytes may explain the tissue damage in atherosclerotic lesions and other pathologic sites in which inflammatory cells congregate.     

The role of sulfur-containing amino acids in superoxide production and modification of low density lipoprotein by arterial smooth muscle cells

Extracellular superoxide (O2-.) was detected in cultures of monkey arterial smooth muscle cells as measured by the superoxide dismutase-inhibitable reduction of cytochrome c and acetylated cytochrome c. Reduction of cytochrome c by these cells required L-cystine in the incubation medium. A variety of other sulfur-containing amino acids, including D-cystine, L-cystathionine, L-methionine, and djenkolic acid did not support O2-. generation when present at concentrations equimolar to L-cystine. At millimolar concentrations, the chelators EDTA and diethylene triamine penta-acetic acid inhibited O2-. production by smooth muscle cells. This effect was maximal when the chelator was present at the same concentration as the sum of the Ca2+ and Mg2+ in the medium, suggesting a role for these cations in O2-. generation by cells. Modification of low density lipoprotein (LDL) by arterial smooth muscle cells, as assessed by changes in lipid peroxide content, mobility on agarose gel electrophoresis, and apoprotein B fragmentation, was also L-cystine-dependent. LDL modification also required micromolar concentrations of the transition metal ion Cu(II) or Fe(III) and was inhibited by superoxide dismutase. LDL modified by smooth muscle cells in the presence of L-cystine and Cu(II) was taken up and degraded less well than native LDL by human skin fibroblasts, suggesting that recognition by the LDL receptor was lost. In contrast, LDL modified by smooth muscle cells was taken up and degraded to a greater degree than native LDL by mouse peritoneal macrophages, consistent with recognition by the scavenger receptor. These results indicate that monkey arterial smooth muscle cells produce O2-. and modify LDL by an L-cystine-dependent process. This may involve reduction of cystine to a thiol, possibly cysteine or a cysteine-containing peptide such as glutathione. Sulfur-containing amino acids may play a role in atherogenesis by supporting cell-mediated generation of reactive oxygen species and modification of lipoprotein to a form recognized by the scavenger receptor.     

Glycosaminoglycan-lipoprotein interaction

Glycosaminoglycans (GAGs) bound to various proteoglycans (PGs) present in the cardiovascular system have been proposed to perform a wide range of functions. These include conferring viscoelastic properties; interacting with and modulating growth factors and enzymes; and as receptors and co-receptors in lipoprotein metabolism. Binding of apoB-100 lipoproteins, particularly low density lipoproteins (LDL), to GAGs of extracellular matrix PGs in arteries has been proposed to be an initiating event in development of atherosclerosis. This study was initiated with the aim of getting an overview of the binding patterns of different lipoprotein subclasses with individual GAG categories. We thus evaluated the interaction of lipoproteins with GAGs commonly found in the cardiovascular system using a gel mobility-shift assay developed for this purpose. The same procedure was used to measure lipoproteins binding to metabolically [(35)S]-labeled whole PGs prepared from three cell types, arterial smooth muscle cells, THP-1 macrophages and from HepG2 cells. The effect of GAG composition on PGs on lipoprotein binding was evaluated by enzymatic degradation of the carbohydrate chains. Heparan sulfate was found to bind beta very low density lipoproteins (beta-VLDL) and a chylomicron remnant model (beta-VLDL+apoE), but not LDL. Dermatan sulfate was found to bind LDL, but not beta-VLDL or the chylomicron remnant model. Chondroitin sulfate and heparin were found to bind all lipoproteins tested (LDL, beta-VLDL and beta-VLDL+apoE) although with different affinities. We can conclude that each lipoprotein subclass tested binds a specific assortment of the GAGs tested. The observations made contribute to the understanding of new and complex mechanisms by which carbohydrate and lipid metabolism may be linked.     

Selective uptake of cholesteryl ester from low density lipoprotein is involved in HepG2 cell cholesterol homeostasis.

Low density lipoprotein (LDL) can follow either a holoparticle uptake pathway, initiated by the LDL receptor (LDLr), and be completely degraded, or it can deliver its cholesteryl esters (CE) selectively to HepG2 cells. Although high density lipoprotein-CE selective uptake has been shown to be linked to cell cholesterol homeostasis in nonhepatic cells, there is no available information on the effect of LDL-CE selective uptake on hepatic cell cholesterol homeostasis. In order to define the role of the LDL-CE selective uptake pathway in hepatic cell cholesterol homeostasis, we used a cellular model that expresses constitutively a LDLr antisense mRNA and that shows LDLr activity at 31% the normal level (HepG2-all cells). The addition of a specific antibody anti-LDLr (IgG-C7) reduces LDL protein degradation (LDLr activity) to 7%. This cellular model therefore reflects, above all, LDL-CE selective uptake activity when incubated with LDL. The inactivation of LDLr reduces LDL-protein association by 78% and LDL-CE association by only 43%. The LDL-CE selective uptake was not reduced by the inactivation of LDLr. The activities of the various enzymes involved in cell cholesterol homeostasis were measured in normal and LDLr-deficient cells during incubation in the absence or presence of LDL as a cholesterol source. Essentially, 3-hydroxy-3-methylglutaryl coenzyme A reductase and acyl coenzyme A:cholesterol acyltransferase (ACAT) activities responded to LDL in LDLr-deficient cells as well as in normal HepG2 cells. Inhibition of lysosomal hydrolysis with chloroquine abolished the effect measured on ACAT activity in the presence of LDL, suggesting that CE of LDL, but not free cholesterol, maintains cell cholesterol homeostasis. Thus, in HepG2 cells, when LDLr function is virtually abolished, LDL-CE selective uptake is coupled to cell cholesterol homeostasis.     

Regulation of squalene epoxidase in HepG2 cells

Regulation of squalene epoxidase in the cholesterol biosynthetic pathway was studied in a human hepatoma cell line, HepG2 cells. Since the squalene epoxidase activity in cell homogenates was found to be stimulated by the addition of Triton X-100, enzyme activity was determined in the presence of this detergent. Incubation of HepG2 cells for 18 h with L-654,969, a potent competitive inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, increased squalene epoxidase activity dose-dependently. On the other hand, low density lipoprotein (LDL) and 25-hydroxy-cholesterol decreased the enzyme activity. These results demonstrate that squalene epoxidase is regulated by the concentrations of endogenous and exogenous sterols. The affinity of the enzyme for squalene was not changed by treatment with L-654,969. Cytosolic (S105) fractions, prepared from HepG2 cells treated with or without L-654,969, had no effect on microsomal squalene epoxidase activity of HepG2 cells, in contrast to the stimulating effect of S105 fractions from rat liver homogenate. Mevalonate, LDL, and oxysterol treatment abolished the effect of L-654,969. Simultaneous addition of cycloheximide and actinomycin D also prevented enzyme induction in HepG2 cells. From these results, the change in squalene epoxidase activity is thought to be caused by the change in the amount of enzyme protein. It is further suggested that squalene epoxidase activity is suppressed only by sterols, not by nonsterol derivative(s) of mevalonate, in contrast to the regulation of HMG-CoA reductase.     

Cytochrome c is released in a reactive oxygen species-dependent manner and is degraded via caspase-like proteases in tobacco Bright-Yellow 2 cells en route to heat shock-induced cell death

To gain some insight into the mechanism of plant programmed cell death, certain features of cytochrome c (cyt c) release were investigated in heat-shocked tobacco (Nicotiana tabacum) Bright-Yellow 2 cells in the 2- to 6-h time range. We found that 2 h after heat shock, cyt c is released from intact mitochondria into the cytoplasm as a functionally active protein. Such a release did not occur in the presence of superoxide anion dismutase and catalase, thus showing that it depends on reactive oxygen species (ROS). Interestingly, ROS production due to xanthine plus xanthine oxidase results in cyt c release in sister control cultures. Maximal cyt c release was found 2 h after heat shock; later, activation of caspase-3-like protease was found to increase with time. Activation of this protease did not occur in the presence of ROS scavenger enzymes. The released cyt c was found to be progressively degraded in a manner prevented by either the broad-range caspase inhibitor (zVAD-fmk) or the specific inhibitor of caspase-3 (AC-DEVD-CHO), which have no effect on cyt c release. In the presence of these inhibitors, a significant increase in survival of the cells undergoing programmed cell death was found. We conclude that ROS can trigger release of cyt c, but do not cause cell death, which requires caspase-like activation.     

Regulation of the uptake of high-density lipoprotein-originated cholesteryl ester by HepG2 cells: role of low-density lipoprotein and plasma lipid transfer protein.

Cholesteryl ester uptake by the human hepatoma cell line HepG2 was studied in vitro by using radiolabeled cholesteryl ester as a tracer. After the cells were incubated in a lipoprotein deficient condition, the rate of radio labeled cholesteryl ester uptake from low-density lipoprotein (LDL) was estimated to be some 25-times higher than that from high-density lipoprotein (HDL). LDL-cholesteryl ester uptake was suppressed by preincubation of the cells with LDL, but pretreatment of the cells with HDL did not show significant effect. HDL-cholesteryl ester uptake was only slightly suppressed by pretreatment of the cells with LDL, and there was no effect with HDL pretreatment. HDL-cholesteryl ester uptake was not affected either by the presence of LDL or human plasma lipid transfer protein alone in the medium under our experimental conditions. Lipid transfer protein enhanced the uptake of radiolabeled cholesteryl ester originating from HDL by the cells only in the presence of LDL. Thus, lipid transfer protein catalyzes a bypass to LDL for the uptake by HepG2 cells of cholesteryl ester molecules which originate in HDL, and this pathway is much more efficient than direct uptake of cholesteryl ester originating in HDL by these cells.     

Selective uptake of cholesteryl esters from various classes of lipoproteins by HepG2 cells.

Selective uptake of cholesteryl esters (CE) from lipoproteins by cells has been extensively studied with high density lipoproteins (HDL). It is only recently that such a mechanism has been attributed to intermediate and low density lipoproteins (IDL and LDL). Here, we compare the association of proteins and CE from very low density lipoproteins (VLDL), IDL, LDL and HDL3 to HepG2 cells. These lipoproteins were either labelled in proteins with 125I or in CE with 3H-cholesteryl oleate. We show that, at any lipoprotein concentration, protein association to the cells is significantly smaller for IDL, LDL, and HDL3 than CE association, but not for VLDL. At a concentration of 20 microg lipoprotein/mL, these associations reveal CE-selective uptake in the order of 2-, 4-, and 11-fold for IDL, LDL, and HDL3, respectively. These studies reveal that LDL and HDL3 are good selective donors of CE to HepG2 cells, while IDL is a poor donor and VLDL is not a donor. A significant inverse correlation (r2 = 0.973) was found between the total lipid/protein ratios of the four classes of lipoproteins and the extent of CE-selective uptake by HepG2 cells. The fate of 3H-CE of the two best CE donors (LDL and HDL3) was followed in HepG2 cells after 3 h of incubation. Cells were shown to hydrolyze approximately 25% of the 3H-CE of both lipoproteins. However, when the cells were treated with 100 microM of chloroquine, a lysosomotropic agent, 85 and 40% of 3H-CE hydrolysis was lost for LDL and HDL3, respectively. The fate of LDL and HDL3-CE in HepG2 cells deficient in LDL-receptor was found to be the same, indicating that the portion of CE hydrolysis sensitive to chloroquine is not significantly linked to LDL-receptor activity. Thus, in HepG2 cells, the magnitude of CE-selective uptake is inversely correlated with the total lipid/protein ratios of the lipoproteins and CE-selective uptake from the two best CE donors (LDL and HDL3) appears to follow different pathways.     

HepG2 cell LDL receptor activity and the accumulation of apolipoprotein B and E in response to docosahexaenoic acid and cholesterol.

In the present study, the accumulation of apolipoproteins (apo) A-I, B, and E in culture medium was measured after 0, 3, 6, 12, and 24 h of incubation with 150 microM docosahexaenoic acid complexed to 75 microM bovine serum albumin (BSA-22:6), either in the presence or absence of 50 micrograms/ml cholesterol and 4 micrograms/ml 25-hydroxycholesterol (C/25-OH). HepG2 cells incubated with BSA + C/25-OH for 24 h accumulated approximately 2.0-fold greater apoE and B as compared to BSA-treated cells. Moreover, HepG2 cell apoB accumulation after 24 h of BSA-22:6 treatment was approximately 2.0-fold greater than apoB accumulation from cells treated with BSA alone. When BSA-22:6 and C/25-OH were both included in the incubation, apoB accumulation was approximately 5.0-fold greater than BSA-treated cells. Comparative studies using BSA-18:1 were carried out for 24 h and showed similar levels of apoA-I, B, and E accumulation in culture medium as compared to BSA-22:6-treated cells. In addition, apoA-I, B, and E mRNA abundance were found to be unaffected by type of fatty acid treatment or length of incubation, averaging 48.2 +/- 7.5, 222 +/- 33.6, and 17.1 +/- 0.7 pg mRNA/micrograms RNA (mean +/- SEM), respectively. As the accumulation of apoB and apoE in culture medium may be modified by HepG2 cell LDL receptor expression, LDL receptor mRNA abundance and LDL receptor activity were quantified at various times over the course of the study. By 6 h of BSA + C/25-OH treatment, LDL receptor mRNA was reduced approximately 2.3-fold, while receptor activity was reduced approximately 1.5-fold, as compared to BSA controls. In an experiment designed to determine uptake of HepG2 cell lipoproteins, 3H-labeled apoB-containing lipoproteins derived from HepG2 cells were prepared. The 3H-labeled lipoproteins were 1.25-fold more likely to be removed from the media of HepG2 cells treated with BSA than from cells treated with BSA + C/25-OH. From these results, we postulate that HepG2 cell LDL receptor activity mediates the removal of apoB, E-containing lipoproteins from culture medium and contributes to the lower accumulation of apoB and E observed in culture medium from cells treated with BSA as compared to cells treated with C/25-OH.     

Apolipoprotein B stimulates formation of monocyte-macrophage surface-connected compartments and mediates uptake of low density lipoprotein-derived liposomes into these compartments

Much of the cholesterol that accumulates in atherosclerotic plaques is found within monocyte-macrophages transforming these cells into "foam cells." Native low density lipoprotein (LDL) does not cause foam cell formation. Treatment of LDL with cholesterol esterase converts LDL into cholesterol-rich liposomes having >90% cholesterol in unesterified form. Similar cholesterol-rich liposomes are found in early developing atherosclerotic plaques surrounding foam cells. We now show that cholesterol-rich liposomes produced from cholesterol esterase-treated LDL can cause human monocyte-macrophage foam cell formation inducing a 3-5-fold increase in macrophage cholesterol content of which >60% is esterified. Although cytochalasin D inhibited LDL liposome-induced macrophage cholesteryl ester accumulation, LDL liposomes did not enter macrophages by phagocytosis. Rather, the LDL liposomes induced and entered surface-connected compartments within the macrophages, a unique endocytic pathway in these cells that we call patocytosis. LDL liposome apoB rather than LDL liposome lipid mediated LDL liposome uptake by macrophages. This was shown by the findings that: 1) protease treatment of the LDL liposomes prevented macrophage cholesterol accumulation; 2) liposomes prepared from LDL lipid extracts did not cause macrophage cholesterol accumulation; and 3) purified apoB induced and accumulated within macrophage surface-connected compartments. Although apoB mediated the macrophage uptake of LDL liposomes, this uptake did not occur through LDL, LDL receptor-related protein, or scavenger receptors. Also, LDL liposome uptake was not sensitive to treatment of macrophages with trypsin or heparinase. Cholesterol esterase-mediated transformation of LDL into cholesterol-rich liposomes is an LDL modification that: 1) stimulates uptake of LDL cholesterol by apoB-dependent endocytosis into surface-connected compartments, and 2) causes human monocyte-macrophage foam cell formation.