Soluble LDL-R are formed by cell surface cleavage in response to phorbol esters.

A 140-kDa soluble form of the low density lipoprotein (LDL) receptor has been isolated from the culture medium of HepG2 cells and a number of other cell types. It is produced from the 160-kDa mature LDL receptor by a proteolytic cleavage, which is stimulated in the presence of 4beta-phorbol 12-myristate 13-acetate (PMA), leading to the release of a soluble fragment that constitutes the bulk of the extracellular domain of the LDL receptor. By labeling HepG2 cells with [35S]methionine and chasing in the presence of PMA, we demonstrated that up to 20% of LDL-receptors were released into the medium in a 2-h period. Simultaneously, the level of labeled cellular receptors was reduced by 30% in those cells treated with PMA compared to untreated cells, as was the total number of cell surface LDL-receptors assayed by the binding of 125I-labeled antibody to whole cells. To determine if endocytosis was required for cleavage, internalization-defective LDL-receptors were created by mutagenesis or deletion of the NPXY internalization signal, transfected into Chinese hamster ovary cells, and assayed for cleavage in the presence and absence of PMA. Cleavage was significantly greater in the case of the mutant receptors than for wild-type receptors, both in the absence and presence of PMA. Similar results were seen in human skin fibroblasts homozygous for each of the internalization-defective LDL receptor phenotypes. LDL receptor cleavage was inhibited by the hydoxamate-based inhibitor TAPI, indicating the resemblance of the LDL receptor cleavage mechanism to that of other surface released membrane proteins.     

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.     

Mechanisms by which lipoprotein lipase alters cellular metabolism of lipoprotein(a), low density lipoprotein, and nascent lipoproteins. Roles for low density lipoprotein receptors and heparan sulfate proteoglycans.

We sought to investigate effects of lipoprotein lipase (LpL) on cellular catabolism of lipoproteins rich in apolipoprotein B-100. LpL increased cellular degradation of lipoprotein(a) (Lp(a)) and low density lipoprotein (LDL) by 277% +/- 3.8% and 32.5% +/- 4.1%, respectively, and cell association by 509% +/- 8.7% and 83.9% +/- 4.0%. The enhanced degradation was entirely lysosomal. Enhanced degradation of Lp(a) had at least two components, one LDL receptor-dependent and unaffected by heparitinase digestion of the cells, and the other LDL receptor-independent and heparitinase-sensitive. The effect of LpL on LDL degradation was entirely LDL receptor-independent, heparitinase-sensitive, and essentially absent from mutant Chinese hamster ovary cells that lack cell surface heparan sulfate proteoglycans. Enhanced cell association of Lp(a) and LDL was largely LDL receptor-independent and heparitinase-sensitive. The ability of LpL to reduce net secretion of apolipoprotein B-100 by HepG2 cells by enhancing cellular reuptake of nascent lipoproteins was also LDL receptor-independent and heparitinase-sensitive. None of these effects on Lp(a), LDL, or nascent lipoproteins required LpL enzymatic activity. We conclude that LpL promotes binding of apolipoprotein B-100-rich lipoproteins to cell surface heparan sulfate proteoglycans. LpL also enhanced the otherwise weak binding of Lp(a) to LDL receptors. The heparan sulfate proteoglycan pathway represents a novel catabolic mechanism that may allow substantial cellular and interstitial accumulation of cholesteryl ester-rich lipoproteins, independent of feedback inhibition by cellular sterol content.     

Low density lipoprotein uptake: holoparticle and cholesteryl ester selective uptake.

Low density lipoproteins (LDL) contain apolipoprotein B-100 and are cholesteryl ester-rich, triglyceride-poor macromolecules, arising from the lipolysis of very low density lipoproteins. This review will describe the receptors responsible for uptake of whole LDL particles (holoparticle uptake), and the selective uptake of LDL cholesteryl ester. The LDL-receptor mediates the internalization of whole LDL through an endosomal-lysosomal pathway, leading to complete degradation of LDL. Increasing LDL-receptor expression by pharmacological intervention efficiently reduces blood LDL concentrations. The lipolysis stimulated receptor and LDL-receptor related protein may also lead to complete degradation of LDL in presence of free fatty acids and apolipoprotein E- or lipase-LDL complexes, respectively. Selective uptake of LDL cholesteryl ester has been demonstrated in the liver, especially in rodents and humans. This activity brings five times more LDL cholesteryl ester than the LDL-receptor to human hepatoma cells, suggesting that it is a physiologically significant pathway. The lipoprotein binding site of HepG2 cells mediates this process and recognizes all lipoprotein classes. Scavenger receptor class B type I and CD36, which mediate the selective uptake of high density lipoprotein cholesteryl ester, are potentially involved in LDL cholesteryl ester selective uptake, since they both bind LDL with high affinity. It is not known whether they are identical to the uncloned lipoprotein binding site and if the selective uptake of LDL cholesteryl ester produces a less atherogenic particle. If this is verified, pharmacological up-regulation of LDL cholesteryl ester selective uptake may become another therapeutic approach for reducing blood LDL-cholesterol levels and the risk of atherosclerosis.     

Effects of specific inhibition of sterol biosynthesis on the uptake and utilization of low density lipoprotein cholesterol by HepG2 cells.

Treatment of HepG2 cells in lipoprotein-deficient media with 4,4,10 beta-trimethyl-trans-decal-3 beta-ol (TMD) abolished the incorporation of [3H]acetate into cholesterol with concomitant accumulation of squalene 2,3(S)-oxide and squalene 2,3(S):22(S),23-dioxide, indicating a specific inhibition of oxidosqualene cyclase. The activity of 3-hydroxy-3-methylglutaryl CoA (HMG-CoA) reductase was affected in a biphasic manner, being inhibited by 30% at low concentrations of TMD and stimulated by 30% at concentrations that completely shut down oxidosqualene cyclase. Treatment with TMD (greater than 20 micrograms/ml) doubled the specific binding and internalization of low density lipoproteins (LDL) and also enhanced their degradation to a degree comparable to that produced by lovastatin, a well-known inhibitor of HMG-CoA reductase. The enhanced binding of LDL to HepG2 cells appeared to occur as a result of an increase in the number of binding sites with no change in their binding affinity for the lipoprotein. At concentrations that completely inhibited cholesterol biosynthesis, TMD did not affect the ability of LDL-derived cholesterol to stimulate cholesterol esterification by seven- to tenfold or to stimulate bile acid secretion to a lesser degree. However, TMD treatment inhibited overall bile acid secretion by 75-85%. The compound had no inhibitory effect on the rates of secretion of either apolipoprotein B or of cholesterol by HepG2 cells into the culture medium. These data demonstrate that a specific inhibition of the sterol branch of isoprenoid biosynthetic pathway in hepatic cells by TMD is sufficient to induce the expression of LDL receptors and that the cholesterol delivered by LDL is available for normal metabolic purposes of the cell.     

Cultured human hepatocytes. Evidence for metabolism of low density lipoproteins by a pathway independent of the classical low density lipoprotein receptor

Studies of low density lipoprotein (LDL) metabolism in nonhuman model systems have indicated that the mammalian liver has dual mechanisms for the uptake and regulation of the concentration of plasma LDL. Heretofore, direct evaluation of lipoprotein uptake mechanisms in human hepatocytes has not been possible. In order to compare hepatocyte LDL uptake with fibroblast LDL metabolism, human hepatocytes were isolated and cultured from small biopsy specimens obtained from normolipidemic and homozygous familial hypercholesterolemic patients. Cells cultured in serum-free culture medium retained the morphological and biochemical characteristics of hepatocytes for at least 7 days. The uptake and degradation of LDL by hepatocytes was compared to that of the cultured human fibroblasts. Like fibroblasts, hepatocytes bound, internalized, and degraded LDL. In both cell types, uptake approached saturation at a concentration of 50 micrograms of LDL protein/ml. Competition for LDL binding by LDL, high density lipoprotein, and modified LD revealed that the hepatocyte binding was specific for LDL. Cellular cholesterol loading by incubation in LDL-enriched culture medium resulted in diminished LDL uptake in both cell types. Chemical modification of LDL by acetoacetylation, acetylation, and reductive methylation abolished LDL uptake and degradation by fibroblasts. However, hepatocytes bound and degraded the modified LDL at 30-50% the level of native LDL. Homozygous familial hypercholesterolemic hepatocytes were devoid of the LDL receptor pathway but metabolized native LDL to the extent observed with modified LDL uptake by normal hepatocytes. In contrast to the classic LDL receptor pathway, the second or alternate pathway does not lead to regulation of 3-hydroxy-3-methylglutaryl-CoA reductase activity. These findings indicate the presence of two separate pathways of LDL uptake in human hepatocytes which have different effects on hepatocytic cholesterol metabolism.     

Sphingomyelinase treatment of low density lipoprotein and cultured cells results in enhanced processing of LDL which can be modulated by sphingomyelin.

The addition of neutral sphingomyelinase from S. aureus to the medium of rat intestinal epithelial cell cultures (IEC-6) containing added human low density lipoprotein (LDL) resulted in two- to fivefold increases in LDL uptake and degradation. This overall effect was shown to be the combined result of sphingomyelinase activity on the composition of the LDL particle and a separate action directly on the cells when native LDL was incubated with sphingomyelinase from S. aureus followed by removal of the sphingomyelinase. Analysis of sphingomyelinase-treated LDL showed that > 95% of the sphingomyelin (SM) was hydrolyzed, but no changes were observed in all the other components of the LDL particle. This modified LDL particle (SM(-)LDL) was also bound and degraded at higher rates than control LDL in a variety of cell lines, e.g., HepG2, GM-43, and CHO-K1 cells. No evidence of increased aggregation of SM(-)LDL could be observed. The increased processing of SM(-)LDL was due to enhanced affinity to LDL receptors and not to an increase in LDL receptor number. When sphingomyelinase from S. aureus was added to the medium of IEC-6 or GM-43 cells, which were processing SM(-)LDL, further increases in SM(-)LDL processing were observed, which were primarily due to greatly enhanced cellular degradation of SM(-)LDL, with little change in receptor binding and cell association. Since there was little sphingomyelin remaining in SM(-)LDL, it was assumed that the action of sphingomyelinase on the cells resulted in the enhanced degradation. In support of this concept, previous addition of sphingomyelin to cells growing in lipoprotein-deficient medium followed by addition of SM(-)LDL greatly inhibited the degradation of the apolipoprotein of SM(-)LDL. On the other hand, addition of sphingomyelin concomitantly with SM(-)LDL did not inhibit degradation. These results are interpreted to indicate that there may be two pathways for cellular processing of sphingomyelin, one of which may be a determinant in the lysosomal processing of the apolipoprotein of LDL. In support of this concept, addition of desipramine, an inhibitor of lysosomal sphingomyelinase, to IEC-6 cells in culture greatly inhibited the degradation of 125I-labeled LDL without affecting the receptor binding and cell association. Overall, these results suggest that sphingomyelin may play a modulatory role in cellular cholesterol homeostasis by regulating uptake of LDL as well as LDL processing.     

Analysis of the binding and association of human intermediate density lipoproteins to HepG2 cells.

The binding of human intermediate density lipoproteins (IDL) to HepG2 cells was studied. We found that human 125I-IDL interact with a binding site of high-affinity (Kd 0.74 micrograms/ml, Bmax 0.049 micrograms/mg cell protein) and a binding site of lower affinity (Kd 86.8 micrograms/ml; Bmax 0.53 micrograms/mg cell protein). The high-affinity binding sites show characteristics of LDL-receptors since they interact with IDL and low-density lipoproteins (LDL) and are calcium dependent. The low-affinity binding sites are calcium-independent and interact with IDL, LDL, high density lipoproteins-3 (HDL3), apolipoprotein (apo) E-liposomes, apoCs-liposomes, apoA-I-liposomes but not with liposomes containing albumin or erythrocyte membrane proteins. Therefore, HepG2 cells have on their surface a binding site that resembles or is identical to the lipoprotein binding site (LBS) that we found on rat liver membranes (Brissette and No?l (1986) J. Biol. Chem. 261, 6847-6852). Internalization, degradation and cholesterol ester selective uptake were determined in the presence or in the absence of a sufficient amount of human HDL3 to abolish the interaction of IDL to the LBS in order to obtain information on the function of this site. Our results suggest that the LBS participates in the internalization of IDL but not in their degradation and that it is responsible for the selective uptake of cholesterol esters of IDL.     

Identification and partial characterization of discrete apolipoprotein A-containing lipoprotein particles secreted by human hepatoma cell line HepG2

The purpose of this study was to identify the apolipoprotein A-containing lipoprotein particles produced by HepG2 cells. The apolipoprotein A-containing lipoproteins separated from apolipoprotein B-containing lipoproteins by affinity chromatography of culture medium on concanavalin A were fractionated on an immunosorber with monoclonal antibodies to apolipoprotein A-II. The retained fraction contained apolipoproteins A-I, A-II and E, while the unretained fraction contained apolipoproteins A-I and E. Both fractions were characterized by free cholesterol as the major and triglycerides and cholesterol esters as the minor neutral lipids. Further chromatography of both fractions on an immunosorber with monoclonal antibodies to apolipoprotein A-I showed that 1) apolipoprotein A-II only occurs in association with apolipoprotein A-I, 2) apolipoprotein A-IV is only present as part of a separate lipoprotein family (lipoprotein A-IV), and 3) apolipoprotein E-enriched lipoprotein A-I:A-II and lipoprotein A-I are the main apolipoprotein A-containing lipoproteins secreted by HepG2 cells.     

Induction of low density lipoprotein receptor synthesis by high density lipoprotein in cultures of human skin fibroblasts.

Further studies have been made of the effects of high density lipoprotein (HDL) on the surface binding, internalization and degradation of 125I-labeled low density lipoprotein (125I-labeled LDL) by cultured normal human fibroblasts. In agreement with earlier studies, during short incubations HDL inhibited the surface binding of 125I-labeled LDL. In contrast, following prolonged incubations 125I-labeled LDL binding was consistently greater in the presence of HDL. The increment in 125I-labeled LDL binding induced by HDL was: (a) associated with a decrease in cell cholesterol content; (b) inhibited by the addition of cholesterol or cycloheximide to the incubation medium; and (c) accompanied by similar increments in 125I-labeled LDL internalization and degradation. It is concluded that HDL induces the synthesis of high affinity LDL receptors in human fibroblasts by promoting the efflux of cholesterol from the cells.     

Catabolism of human low density lipoproteins by human hepatoma cell line HepG2

The mechanism of hepatic catabolism of human low density lipoproteins (LDL) by human-derived hepatoma cell line HepG2 was studied. The binding of 125I-labeled LDL to HepG2 cells at 4 degrees C was time dependent and inhibited by excess unlabeled LDL. The specific binding was predominant at low concentrations of 125I-labeled LDL (less than 50 micrograms protein/ml), whereas the nonsaturable binding prevailed at higher concentrations of substrate. The cellular uptake and degradation of 125I-labeled LDL were curvilinear functions of substrate concentration. Preincubation of HepG2 cells with unlabeled LDL caused a 56% inhibition in the degradation of 125I-labeled LDL. Reductive methylation of unlabeled LDL abolished its ability to compete with 125I-labeled LDL for uptake and degradation. Chloroquine (50 microM) and colchicine (1 microM) inhibited the degradation of 125I-labeled LDL by 64% and 30%, respectively. The LDL catabolism by HepG2 cells suppressed de novo synthesis of cholesterol and enhanced cholesterol esterification; this stimulation was abolished by chloroquine. When tested at a similar content of apolipoprotein B, very low density lipoproteins (VLDL), LDL and high density lipoproteins (HDL) inhibited the catabolism of 125I-labeled LDL to the same degree, indicating that in HepG2 cells normal LDL are most probably recognized by the receptor via apolipoprotein B. The current study thus demonstrates that the catabolism of human LDL by HepG2 cells proceeds in part through a receptor-mediated mechanism.     

The effects of low-density lipoprotein and cholesterol on acyl-coenzyme A: cholesterol acyltransferase activity in membranes from cultured human fibroblasts.

Membranes prepared from cultured fibroblasts were assayed for acyl-coenzyme A: cholesterol acyltransferase (ACAT) by a method that relied exclusively on the cholesterol already present on the membranes as the sterol substrate. Changes in membrane ACAT activity during incubation of fibroblasts under a variety of conditions were similar to the changes in the rate of incorporation of oleic acid into cholesteryl esters by the intact cells. The addition of low-density lipoprotein (LDL) to fibroblasts pre-incubated with lipoprotein-deficient serum led to a transient increase in membrane ACAT activity, which reached its peak after 7h and was related to the receptor-mediated uptake and degradation of the lipoprotein by the cells. However, after incubation of the membranes with a cholesterol-rich donor lipoprotein, which resulted in an equilibration of cholesterol between membranes and donor, each preparation exhibited the same activity. In contrast with these effects of LDL, incubation of the cells with non-esterified cholesterol produced a prolonged increase in ACAT activity and an increase in the activity observed after equilibration. Furthermore, ACAT activity in cells grown with linoleic acid was higher, both before and after the addition of LDL, than that of cells grown in normal medium or with palmitate. The increase in activity produced by LDL was also greater, reflecting the greater rate of degradation of LDL by the cells, and was associated with an increase in the activity observed after equilibration with donor. The results suggest that although fibroblasts can increase the amount of active enzyme on their membranes to accommodate an exceptionally high or prolonged supply of cholesterol, under normal circumstances the increase in membrane ACAT activity produced by LDL can be explained entirely by an increase in the amount of cholesterol in the substrate pool.     

Binding, internalization, and degradation of high density lipoprotein by cultured normal human fibroblasts.

Comparative studies were made of the metabolism of plasma high density lipoprotein (HDL) and low density lipoprotein (LDL) by cultured normal human fibroblasts. On a molar basis, the surface binding of (125)I-HDL was only slightly less than that of (125)I-LDL, whereas the rates of internalization and degradation of (125)I-HDL were very low relative to those of (125)I-LDL. The relationships of internalization and degradation to binding suggested the presence of a saturable uptake mechanism for LDL functionally related to high-affinity binding. This was confirmed by the finding that the total uptake of (125)I-LDL (internalized plus degraded) at 5 micro g LDL protein/ml was 100-fold greater than that attributable to fluid or bulk pinocytosis, quantified with [(14)C]sucrose, and 10-fold greater than that attributable to the sum of fluid endocytosis and adsorptive endocytosis. In contrast, (125)I-HDL uptake could be almost completely accounted for by the uptake of medium during pinocytosis and by invagination of surface membrane (bearing bound lipoprotein) during pinocytosis. These findings imply that, at most, only a small fraction of bound HDL binds to the high-affinity LDL receptor and/or that HDL binding there is internalized very slowly. The rate of (125)I-HDL degradation by cultured fibroblasts (per unit cell mass) exceeded an estimate of the turnover rate of HDL in vivo, suggesting that peripheral tissues may contribute to HDL catabolism. In accordance with their differing rates of uptake and cholesterol content, LDL increased the cholesterol content of fibroblasts and selectively inhibited sterol biosynthesis, whereas HDL had neither effect.     

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.     

Release of low density lipoprotein from its cell surface receptor by sulfated glycosaminoglycans.

The sulfated glycosaminoglycan, heparin, was found to release 125I-labeled low density lipoprotein (125I-LDL) from its receptor site on the surface of normal human fibroblasts. Measurement of the amount of 125I-LDL released by heparin permitted the resolution of the total cellular uptake of 125I-LDL at 37 degrees C into two components: first, an initial rapid, high affinity binding of the lipoprotein to the surface receptor, from which the 125I-LDL could be released by heparin, and second, a slower process attributable to an endocytosis of the receptor-bound lipoprotein, which rendered it resistant to heparin release. At 4 degrees C the amount of heparin-releasable 125I-LDL was similar to that at 37 degrees C, but interiorization of the lipoprotein did not occur at the lower temperature. The physiologic importance of the cell surface LDL receptor was emphasized by the finding that mutant fibroblasts from a subject with homozygous Familial Hypercholesterolemia, which lack the ability to take up 125I-LDL at 37 degrees C, did not show cell surface binding of 125I-LDL, as measured by heparin release, at either 4 degrees C or 37 degrees C. Although heparin released 125I-LDL from its binding site, it did not release 3H-concanavalin A from its surface receptor, and conversely, alpha-methyl-D-mannopyranoside, which released 3H-concanavalin A, did not release surface-bound 125I-LDL. When added to the culture medium simultaneously with LDL, heparin prevented the binding of LDL to its receptor and hence prevented the LDL-mediated suppression of 3-hydroxy-3-methylglutaryl coenzyme A reductase activity. The uptake of LDL by fibroblasts is proposed as a model of receptor-mediated adsorptive endocytosis of macromolecules in human cells.     

Low- and high-density lipoprotein metabolism in HepG2 cells expressing various levels of apolipoprotein E

To determine the importance of hepatic apolipoprotein (apo) E in lipoprotein metabolism, HepG2 cells were transfected with a constitutive expression vector (pRc/CMV) containing either the complete or the first 474 base pairs of the human apoE cDNA inserted in an antisense orientation, for apoE gene inactivation, or the full-length human apoE cDNA inserted in a sense orientation for overexpression of apoE. Stable transformants were obtained that expressed 15, 24, 226, and 287% the apoE level of control HepG2 cells. The metabolism of low-density lipoprotein (LDL) and high-density lipoprotein-3 (HDL(3)), two lipoprotein classes following both holoparticle and cholesteryl esters (CE)-selective uptake pathways, was compared between all these cells. LDL-protein degradation, an indicator of the holoparticle uptake, was greater in low apoE expressing cells than in control or high expressing cells, while HDL(3)-protein degradation paralleled the apoE levels of the cells (r(2) = 0.989). LDL- and HDL(3)-protein association was higher in low apoE expressing cells compared to control cells. In opposition, LDL- and HDL(3)-CE association was not different from control cells in low apoE expressing cells but rose in high apoE expressing cells. In consequence, the CE-selective uptake (CE/protein association ratio) was positively correlated with the level of apoE expression in all cells for both LDL (r(2) = 0.977) and HDL(3) (r(2) = 0.998). We also show that, although in normal and low apoE expressor cells, 92% of LDL- and 80% HDL(3)-CE hydrolysis is sensitive to chloroquine suggesting a pathway linked to lysosomes for both lipoproteins, cells overexpressing apoE lost 60% of chloroquine-sensitive HDL(3)-CE hydrolysis without affecting that of LDL-CE. Thus, the level of apoE expression in HepG2 cells determines the fate of LDL and HDL(3).     

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.     

Low-density lipoprotein receptor binding determinants switch from apolipoprotein E to apolipoprotein B during conversion of hypertriglyceridemic very-low-density lipoprotein to low-density lipoproteins

Using thrombin and trypsin as probes, we determined: first, that low-density lipoprotein (LDL) receptor binding determinants switch from apolipoprotein (apo) E to apo-B within the very-low-density lipoprotein (VLDL) Sf 20-60 region of the metabolic cascade from VLDL1 (Sf 100-400) of hypertriglyceridemic (HTG) human subjects to LDL. Second, two different conformations of apo-E exist in HTG-VLDL Sf greater than 60, one accessible (greater than or equal to 1 mol/mol of particle) and one inaccessible (1-2 mol/mol) to both thrombin and the LDL receptor; normal VLDL (Sf greater than 60) have only the inaccessible conformation and therefore do not bind to the LDL receptor. Third, thrombin degrades apo-B into large fragments, three of which have electrophoretic mobilities similar to B-48, B-74, and B-26; this, however, has no effect on apo-B-mediated receptor binding. Fibroblast studies showed that thrombin could abolish receptor uptake of HTG-VLDL1 and HTG-VLDL2 (Sf 60-100), had little or no effect on HTG-VLDL3 (Sf 20-60), and no effect on uptake of intermediate-density lipoprotein (IDL) or LDL. Trypsin abolished the binding of HTG-VLDL1 and HTG-VLDL2, reduced that of HTG-VLDL3, but had little to no effect on IDL or LDL binding. Immunochemical techniques revealed that thrombin cleaved some apo-E into the E-22 and E-12 fragments; after trypsin treatment no apo-E was detected in any HTG-lipoprotein. Normal VLDL subclasses contained less apo-E than the corresponding HTG-VLDL subclasses and it was not cleaved by thrombin. Apo-B immunoreactivities of VLDL subclasses were not significantly changed after treatment with thrombin, although thrombin cleaved some of the B-100 of each VLDL subclass, and all apo-B in IDL and LDL, into 4-6 major large fragments. Trypsin converted all of the apo-B of each lipoprotein into smaller fragments (Mr less than 100,000). We conclude that apo-E of the thrombin-accessible conformation mediates uptake of HTG-VLDL1 and HTG-VLDL2 but that apo-B alone is sufficient to mediate receptor binding of IDL and LDL; the switch from apo-E to apo-B as the primary or sufficient binding determinant occurs within the VLDL3 (Sf 20-60) region of the metabolic cascade, where receptor binding first appears in VLDL subclasses from normal subjects.     

Modification of low density lipoprotein by lipoprotein lipase or hepatic lipase induces enhanced uptake and cholesterol accumulation in cells

Incubation of low density lipoprotein(s) (LDL) with either lipoprotein lipase or hepatic lipase led to modification of the core lipid composition of LDL. Both lipases modified LDL by substantially reducing core triglyceride content without producing marked differences in size, charge, or lipid peroxide content in comparison to native LDL. The triglyceride-depleted forms of LDL that result from treatment with these two enzymes were degraded at approximately twice the rate of native LDL by human monocyte-derived macrophages (HMDM). Lipase-modified LDL degradation was inhibited by chloroquine, suggesting lysosomal involvement in LDL cellular processing. The increased degradation by macrophages of the LDL modified by these lipases was accompanied by enhanced cholesterol esterification rates, as well as by an increase in cellular free and esterified cholesterol content. In a patient with hepatic triglyceride lipase deficiency, degradation of the triglyceride-rich LDL by HMDM was approximately half that of normal LDL. Following in vitro incubation of LDL from this patient with either lipoprotein or hepatic lipase, lipoprotein degradation increased to normal. Several lines of evidence indicate that LDL modified by both lipases were taken up by the LDL receptor and not by the scavenger receptor. 1) The degradation of lipase-modified LDL in nonphagocytic cells (human skin fibroblast and arterial smooth muscle cells) as well as in phagocytic cells (HMDM, J-774, HL-60, and U-937 cell lines) could be dissociated from that of acetylated LDL and was always higher than that of native LDL. A similar pattern was found for cellular cholesterol esterification and cholesterol mass. 2) LDL receptor-negative fibroblasts did not degrade lipase-modified LDL. 3) A monoclonal antibody to the LDL receptor inhibited macrophage degradation of the lipase-modified LDL. 4) Excess amounts of unlabeled LDL competed substantially with 125I-labeled lipase-modified LDL for degradation by both macrophages and fibroblasts. Thus, lipase-modified LDL can cause significant cholesterol accumulation in macrophages even though it is taken up by LDL and not by the scavenger receptor. This effect could possibly be related to the reduced triglyceride content in the core of LDL, which may alter presentation of the LDL receptor-binding domain of apolipoprotein B on the particle surface, thereby leading to increased recognition and cellular uptake via the LDL receptor pathway.     

Apolipoprotein E and lipoprotein lipase secreted from human monocyte-derived macrophages modulate very low density lipoprotein uptake

We investigated the roles of lipoprotein lipase and apolipoprotein E (apoE) secreted from human monocyte-derived macrophages in the uptake of very low density lipoproteins (VLDL). ApoCII-deficient VLDL were isolated from a patient with apoCII deficiency. The lipolytic conversion to higher density and the degradation of the apoCII-deficient VLDL by macrophages were very slight, whereas the addition of apoCII enhanced both their conversion and degradation. This suggests that the lipolysis and subsequent conversion of VLDL to lipoproteins of higher density are essential for the VLDL uptake by macrophages. VLDL incubated with macrophages obtained from subjects with E3/3 phenotype (E3/3-macrophages) showed a 17-fold greater affinity in inhibiting the binding of 2 micrograms/ml 125I-low density lipoprotein (LDL) to fibroblasts than native VLDL, whereas the incubation of VLDL with macrophages obtained from a subject with E2/2 phenotype (E2/2-macrophages) did not cause any increase in their affinity. Furthermore, 3 micrograms/ml 125I-VLDL obtained from a subject with E3/3 phenotype were degraded by E3/3-macrophages to a greater extent than by E2/2-macrophages (2-fold), indicating that VLDL uptake is influenced by the phenotype of apoE secreted by macrophages. From these results, we conclude that both lipolysis by lipoprotein lipase and incorporation of apoE secreted from macrophages alter the affinity of VLDL for the LDL receptors on the cells, resulting in facilitation of their receptor-mediated endocytosis.