Mechanisms of inhibition by apolipoprotein C of apolipoprotein E-dependent cellular metabolism of human triglyceride-rich lipoproteins through the low density lipoprotein receptor pathway

The mechanism of inhibition by apolipoprotein C of the uptake and degradation of triglyceride-rich lipoproteins from human plasma via the low density lipoprotein (LDL) receptor pathway was investigated in cultured human skin fibroblasts. Very low density lipoprotein (VLDL) density subfractions and intermediate density lipoprotein (IDL) with or without added exogenous recombinant apolipoprotein E-3 were used. Total and individual (C-I, C-II, C-III-1, and C-III-2) apoC molecules effectively inhibited apoE-3-mediated cell metabolism of the lipoproteins through the LDL receptor, with apoC-I being most effective. When the incubation was carried out with different amounts of exogenous apoE-3 and exogenous apoC, it was shown that the ratio of apoE-3 to apoC determined the uptake and degradation of VLDL. Excess apoE-3 overcame, at least in part, the inhibition by apoC. ApoC, in contrast, did not affect LDL metabolism. Neither apoA-I nor apoA-II, two apoproteins that do not readily associate with VLDL, had any effect on VLDL cell metabolism. The inhibition of VLDL and IDL metabolism cannot be fully explained by interference of association of exogenous apoE-3 with or displacement of endogenous apoE from the lipoproteins. IDL is a lipoprotein that contains both apoB-100 and apoE. By using monoclonal antibodies 4G3 and 1D7, which specifically block cell interaction by apoB-100 and apoE, respectively, it was possible to assess the effects of apoC on either apoprotein. ApoC dramatically depressed the interaction of IDL with the fibroblast receptor through apoE, but had only a moderate effect on apoB-100. The study thus demonstrates that apoC inhibits predominantly the apoE-3-dependent interaction of triglyceride-rich lipoproteins with the LDL receptor in cultured fibroblasts and that the mechanism of inhibition reflects association of apoC with the lipoproteins and specific concentration-dependent effects on apoE-3 at the lipoprotein surface.     

Uptake of type IV hypertriglyceridemic VLDL by cultured macrophages is enhanced by interferon-gamma.

Hypertriglyceridemic (HTG) very low density lipoproteins (VLDL) from subjects with type IV hyperlipoproteinemia induce both cholesteryl ester (CE) and triglyceride (TG) accumulation in cultured J774 macrophages. We examined whether the cytokine interferon-gamma (IFN-gamma), which is expressed by lymphocytes in atherosclerotic lesions, would modulate macrophage uptake of HTG -VLDL. Incubation of cells with HTG -VLDL alone significantly increased cellular CE and TG mass 17- and 4.3-fold, respectively, while cellular free cholesterol (FC) was unaffected. Pre-incubation of cells with IFN-gamma (50 U/ml) prior to incubation with HTG -VLDL caused a marked enhancement in cellular CE and TG 27- and 6-fold over no additions (controls), respectively, and a 1.5-fold increase in FC. IFN-gamma increased low density lipoprotein (LDL)-induced cellular CE 2-fold compared to LDL alone. IFN-gamma did not enhance the uptake of type III (apoE2/E2) HTG -VLDL or VLDL from apoE knock-out mice. Incubations in the presence of a lipoprotein lipase (LPL) inhibitor or an acylCoA:cholesterol acyltransferase (ACAT) inhibitor demonstrated that the IFN-gamma-enhanced HTG -VLDL uptake was dependent on LPL and ACAT activities. IFN-gamma significantly increased the binding and degradation of 125I-labeled LDL. Binding studies with 125I-labeled alpha2-macroglobulin, a known LDL receptor-related protein (LRP) ligand, and experiments with copper-oxidized LDL indicated that the IFN-gamma-enhanced uptake was not due to increased expression of the LRP or scavenger receptors. Thus, IFN-gamma may promote foam cell formation by accelerating macrophage uptake of native lipoproteins. IFN-gamma-stimulated CE accumulation in the presence of HTG -VLDL occurs via a process that requires receptor binding-competent apoE and active LPL. IFN-gamma-enhanced uptake of both HTG -VLDL and LDL is mediated by the LDL-receptor and requires ACAT-mediated cholesterol esterification.     

The intracellular distribution of labelled lipoproteins in the tissues of rats under physical loading]

A study was made of the influence of a 3 hour physical loading on the intracellular distribution of 125I-labeled very low density lipoprotein (VLDL), low density lipoprotein (LDL), high density lipoprotein (HDL) in the rat tissues after intravenous injection. The uptake of VLDL by liver was decreased, that of LDL was not altered and that uptake of HDL was increased, Redistribution of labeled lipoproteins between the subcellular structures was found. Accumulation of labeled VLDL in cytosol, microsome and large membranes was observed in muscles. The radioactivity level of VLDL was decreased in lysosomes, whereas the level of HDL was increased, Physical loading increased the uptake of HDL in adrenal glands. Accumulation of radioactivity was found in cytosol and small membranes. The data confirm the important role of lipoproteins of cellular metabolism regulation.     

Disparities in the interaction of rat and human lipoproteins with cultured rat fibroblasts and smooth muscle cells. Requirements for homology for receptor binding activity

This study characterizes the interactions of various rat and human lipoproteins with the lipoprotein cell surface receptors of rat and human cells. Iodinated rat very low density lipoproteins (VLDL), rat chylomicron remnants, rat low density lipoproteins (LDL), and rat high density lipoproteins containing predominantly apoprotein E (HDL1) bound to high affinity cell surface receptors of cultured rat fibroblasts and smooth muscle cells. Rat VLDL and chylomicron remnants were most avidly bound; the B-containing LDL and the E-containing HDL1 displayed lesser but similar binding. Rat HDL (d = 1.125 to 1.21) exhibited weak receptor binding; however, after recentrifugation to remove apoprotein E, they were devoid of binding activity. Competitive binding studies at 4 degrees C confirmed these results for normal lipoproteins and indicated that VLDL (B-VLDL), LDL, and HDLc (cholesterol-rich HDL1) isolated from hypercholesterolemic rats had increased affinity for the rat receptors compared with their normal counterparts, the most pronounced change being in the LDL. The cell surface receptor pathway in rat fibroblasts and smooth muscle cells resembled the system described for human fibroblasts as follows: 1) lipoproteins containing either the B or E apoproteins interacted with the receptors; 2) receptor binding activity was abolished by acetoacetylation or reductive methylation of a limited number of lysine residues of the lipoproteins; 3) receptor binding initiated the process of internalization and degradation of the apo-B- and apo-E-containing lipoproteins; 4) the lipoprotein cholesterol was re-esterified as determined by [14C]oleate incorporation into the cellular cholesteryl esters; and 5) receptor-mediated uptake (receptor number) was lipoprotein cholesterol. An important difference between rat and human fibroblasts was the inability of human LDL to interact with the cell surface receptors of rat fibroblasts. Rat lipoproteins did, however, react with human fibroblasts. Furthermore, the rat VLDL were the most avidly bound of the rat lipoproteins to rat fibroblasts. When the direct binding of 125I-VLDL was subjected to Scatchard analysis, the very high affinity of rat VLDL was apparent (Kd = 1 X 10(-11) M). Moreover, compared with data for rat LDL, the data suggested each VLDL particle bound to four to nine lipoprotein receptors. This multiple receptor binding could explain the enhanced binding affinity of the rat VLDL. The Scatchard plot of rat 125I-VLDL revealed a biphasic binding curve in rat and human fibroblast cells and in rat smooth muscle cells, suggesting two populations of rat VLDL. These results indicate that rat cells have a receptor pathway similar to, but not identical with, the LDL pathway of human cells. Since human LDL bind poorly to rat cell receptors on cultured rat fibroblasts and smooth muscle cells, metabolic studies using human lipoproteins in rats must be interpreted cautiously.     

Macrophage colony-stimulating factor rapidly enhances beta-migrating very low density lipoprotein metabolism in macrophages through activation of a Gi/o protein signaling pathway

Previous studies have examined lipoprotein metabolism by macrophages following prolonged exposure (>24 h) to macrophage colony-stimulating factor (M-CSF). Because M-CSF activates several signaling pathways that could rapidly affect lipoprotein metabolism, we examined whether acute exposure of macrophages to M-CSF alters the metabolism of either native or modified lipoproteins. Acute incubation of cultured J774 macrophages and resident mouse peritoneal macrophages with M-CSF markedly enhanced low density lipoproteins (LDL) and beta-migrating very low density lipoproteins (beta-VLDL) stimulated cholesteryl [(3)H]oleate deposition. In parallel, M-CSF treatment increased the association and degradation of (125)I-labeled LDL or beta-VLDL without altering the amount of lipoprotein bound to the cell surface. The increase in LDL and beta-VLDL metabolism did not reflect a generalized effect on lipoprotein endocytosis and metabolism because M-CSF did not alter cholesterol deposition during incubation with acetylated LDL. Moreover, M-CSF did not augment beta-VLDL cholesterol deposition in macrophages from LDL receptor (-/-) mice, indicating that the effect of M-CSF was mediated by the LDL receptor. Incubation of macrophages with pertussis toxin, a specific inhibitor of G(i/o) protein signaling, had no effect on cholesterol deposition during incubation with beta-VLDL alone, but completely blocked the augmented response promoted by M-CSF. In addition, incubation of macrophages with the direct G(i/o) protein activator, mastoparan, mimicked the effect of M-CSF by enhancing cholesterol deposition in cells incubated with beta-VLDL, but not acetylated LDL. In summary, M-CSF rapidly enhances LDL receptor-mediated metabolism of native lipoproteins by macrophages through activation of a G(i/o) protein signaling pathway. Together, these findings describe a novel pathway for regulating lipoprotein metabolism.     

Metabolism of very low density lipoproteins in the pig. An in vivo study.

1. The metabolism of apolipoprotein B (apoB) was investigated in pigs injected with [125I]very low density lipoproteins (VLDL) to determine to which extent the two distinct low density lipoprotein subclasses (LDL1 and LDL2) derive from VLDL. 2. The lipoproteins were isolated by density gradient ultracentrifugation and the transfer of radioactivity from VLDL into LDL1 and LDL2 apoB was measured. 3. Only a minor portion of VLDL apoB was converted to LDL1 (7.7 +/- 3.2%) and LDL2 (3.6 +/- 1.5%), respectively. Thus, we conclude that the major portion of LDL, especially LDL2, is synthesized independently from VLDL catabolism.     

Lipoproteins activate acyl-coenzyme A:cholesterol acyltransferase in macrophages only after cellular cholesterol pools are expanded to a critical threshold level

Activation of acyl-CoA:cholesterol actyltransferase (ACAT) in macrophages by lipoproteins is a key event in atheroma foam cell formation. To help elucidate the mechanisms whereby lipoproteins stimulate ACAT, the early cellular events of lipoprotein-induced ACAT stimulation were studied in mouse peritoneal macrophages. As a function of increasing lipoprotein-cholesterol influx to the cell during the first few hours of incubation, ACAT activity was markedly stimulated by beta-very low density lipoprotein (beta-VLDL) and acetyl-low density lipoprotein (acetyl-LDL) only after lipoprotein-cholesterol influx reached a threshold level of approximately 25% above the basal cell cholesterol content. In contrast, LDL stimulated ACAT only minimally at this level of lipoprotein-cholesterol influx. In further experiments, the source of ACAT cholesterol substrate during the initial stimulation of ACAT was shown to be a mixture of cellular (approximately 75%) and lipoprotein-cholesterol (approximately 25%) in proportions that approximated the proportions of originally cellular and lipoprotein-cholesterol in the cell. Thus, lipoprotein-cholesterol rapidly mixed with most or all of cellular cholesterol before ACAT esterification. Additional studies showed that LDL caused significant efflux of cellular cholesterol, thus providing at least a partial explanation for the relatively weak ACAT stimulatory potential of LDL. To support this idea, LDL that was modified to decrease its ability to induce net cellular cholesterol efflux stimulated ACAT 2-fold greater than control LDL when matched for lysosomal LDL-cholesterol influx. Moreover, when the effective efflux potentials of beta-VLDL and acetyl-LDL were increased, ACAT stimulation was markedly decreased despite unchanged lipoprotein-cholesterol influx. Thus, macrophage ACAT is stimulated not directly by the influx of newly hydrolyzed lipoprotein-cholesterol but rather by net expansion of cellular cholesterol pools to a particular threshold level. This scheme has potentially important implications regarding the cellular and molecular mechanisms of foam cell formation.     

Metabolic pathways of apolipoprotein B in heterozygous familial hypercholesterolemia: studies with a [3H]leucine tracer.

The kinetics of apolipoprotein B (apoB) were measured in seven studies in heterozygous, familial hypercholesterolemic subjects (FH) and in five studies in normal subjects, using in vivo tracer kinetic methodology with a [3H]leucine tracer. Very low density (VLDL) and low density lipoproteins (LDL) were isolated ultracentrifugally and LDL was fractionated into high and low molecular weight subspecies. ApoB was isolated, its specific radioactivity was measured, and the kinetic data were analyzed by compartmental modeling using the SAAM computer program. The pathways of apoB metabolism differ in FH and normal subjects in two major respects. Normals secrete greater than 90% of apoB as VLDL, while one-third of apoB is secreted as intermediate density lipoprotein IDL/LDL in FH. Normals lose 40-50% of apoB from plasma as VLDL/IDL, while FH subjects lose none, metabolizing all of apoB to LDL. In FH, there is also the known prolongation of LDL residence time. The leucine tracer, biosynthetically incorporated into plasma apoB, permits distinguishing the separate pathways by which the metabolism of apoB is channeled. ApoB synthesis and secretion require 1.3 h. ApoB is secreted by three routes: 1) as large VLDL where it is metabolized by a delipidation chain; 2) as a rapidly metabolized VLDL fraction converted to LDL; and 3) as IDL or LDL. ApoB is metabolized along two pathways. The delipidation chain processes large VLDL to small VLDL, IDL, and LDL. The IDL pathway channels nascent, rapidly metabolized VLDL and IDL particles into LDL. It thus provides a fast pathway for the entrance of apoB tracer into LDL, while the delipidation pathway is a slower route for channeling apoB through VLDL into LDL. LDL apoB is derived in almost equal amounts from both pathways, which feed predominantly into large LDL. Small LDL is a product of large LDL, and the major loss of LDL-apoB is from small LDL. Two features of apoB metabolism in FH, the major secretory pathway through IDL and the absence of a catabolic loss of apoB from VLDL/IDL, greatly facilitate measuring the metabolic channeling of apoB into LDL.     

Metabolism of apoB-100 in lipoproteins separated by density gradient ultracentrifugation in normal and Watanabe heritable hyperlipidemic rabbits

We have examined the capability of a previously developed compartmental model to explain the kinetics of radioiodinated apolipoprotein (apo) B-100 in very low density lipoproteins (VLDL), intermediate density lipoproteins (IDL), and low density lipoproteins (LDL) separated by density gradient ultracentrifugation after intravenous injection of radioiodinated VLDL into New Zealand white (NZW) and Watanabe heritable hyperlipidemic (WHHL) rabbits. Our model was developed primarily from kinetics in whole blood plasma of apoB-100 in particles with and without apoE after intravenous injection of large VLDL, total VLDL, IDL, and LDL. When the initial conditions for this model were assumed to be an intravenous injection of radiolabeled VLDL, the plasma VLDL and LDL simulations for NZW rabbits and the VLDL, IDL, and LDL simulations for WHHL rabbits were found to be inconsistent with the observed density gradient data. By adding a new pathway in the VLDL portion of the model for NZW rabbits and a new compartment in VLDL for WHHL rabbits, and by assuming some cross-contamination in the density gradient ultracentrifugal separations, it was possible to bring our model, which was based upon measurements of 125I-labeled apoB-100 in whole plasma, into conformity with the data obtained by density gradient ultracentrifugation. The relatively modest changes required in the model to fit the gradient ultracentrifugation data support the suitability of our approach to the kinetic analysis of the metabolism of apoB-100 in VLDL and its conversion to IDL and LDL based upon measurements of 125I-labeled apoB-100 in whole plasma after injection of radiolabeled VLDL, IDL, and LDL. Furthermore, the differences in kinetics observed by us between data from whole plasma and data from plasma submitted to ultracentrifugal separation from the same or similar animals highlight the fact that small variations that can occur in the separation of lipoprotein classes by buoyant density can lead to confusing results.     

The very low density lipoprotein (VLDL) receptor – a peripheral lipoprotein receptor for remnant lipoproteins into fatty acid active tissues

The VLDL (very low density lipoprotein) receptor is a member of the LDL (low density lipoprotein) receptor family. The VLDL receptor binds apolipoprotein (apo) E but not apo B, and is expressed in fatty acid active tissues (heart, muscle, adipose) and macrophages abundantly. Lipoprotein lipase (LPL) modulates the binding of triglyceride (TG)-rich lipoprotein particles to the VLDL receptor. By the unique ligand specificity, VLDL receptor practically appeared to function as IDL (intermediate density lipoprotein) and chylomicron remnant receptor in peripheral tissues in concert with LPL. In contrast to LDL receptor, the VLDL receptor expression is not down regulated by lipoproteins. Recently several possible functions of the VLDL receptor have been reported in lipoprotein metabolism, atherosclerosis, obesity/insulin resistance, cardiac fatty acid metabolism and neuronal migration. The gene therapy of VLDL receptor into the LDL receptor knockout mice liver showed a benefit effect for lipoprotein metabolism and atherosclerosis. Further researches about the VLDL receptor function will be needed in the future.     

The uptake and degradation of matrix-bound lipoproteins by macrophages require an intact actin Cytoskeleton, Rho family GTPases, and myosin ATPase activity

A key cellular event in atherogenesis is the interaction of macrophages with lipoproteins in the subendothelium. In vivo, these lipoproteins are bound to matrix and often aggregated, yet most cell-culture experiments explore these events using soluble monomeric lipoproteins. We hypothesized that the internalization and degradation of matrix-retained and aggregated low density lipoprotein (LDL) by macrophages may involve the actin-myosin cytoskeleton in a manner that distinguishes this process from the endocytosis of soluble LDL. To explore these ideas, we plated macrophages on sphingomyelinase-aggregated LDL bound to smooth muscle cell-derived matrix in the presence of lipoprotein lipase. The macrophages internalized and degraded the LDL, which was mediated partially by the LDL receptor-related protein. Cytochalasin D and latrunculin A, which block actin polymerization, markedly inhibited the uptake and degradation of matrix-retained LDL but not soluble LDL. Inhibition of Rho family GTPases by Clostridium difficile toxin B blocked the degradation of matrix-retained and aggregated LDL by >90% without any inhibition of soluble LDL degradation. However, specific inhibition of Rho had no effect, suggesting the importance of Rac1 and Cdc42. Degradation of matrix-retained, but not soluble, LDL was also blocked by inhibitors of tyrosine kinase, phosphatidylinositol 3-kinase, and myosin ATPase. These findings define fundamental cytoskeletal pathways that may be involved in macrophage foam cell formation in vivo but have been missed by the use of previous cell culture models.     

Suppression of 3-hydroxy-3-methylglutaryl-CoA reductase by low density lipoproteins produced in vitro by lipoprotein lipase action on nonsuppressive very low density lipoproteins.

Very low density lipoproteins (VLDL), Sf60 to 400, from normolipemic individuals do not suppress 3-hydroxy-3-methylglutaryl-CoA reductase activity in cultured normal human fibroblasts at concentrations 20-fold higher than those of low density lipoproteins (LDL) that give total suppression. To determine if these VLDL contain all of the structural elements necessary for receptor-mediated suppression, they were converted in vitro with bovine milk lipoprotein lipase to low density lipoproteins. These LDL-like lipoproteins were as effective in suppression as LDL isolated directly from plasma, with half-maximal and complete suppression at 1 and 4 microgram of cholesterol ml-1. Neither native LDL nor LDL produced in vitro suppressed receptor-negative fibroblasts. We conclude that action of lipoprotein lipase on VLDL leads to a rearrangement of lipoprotein components that permits interaction of LDL produced in vitro with the LDL-specific cell surface receptor of fibroblasts and subsequent suppression of 3-hydroxy-3-methylglutaryl-CoA reductase.     

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.     

Transport of beta-very low density lipoproteins and chylomicron remnants by macrophages is mediated by the low density lipoprotein receptor pathway

The receptor-mediated uptake of rat hypercholesterolemic very low density lipoproteins (beta VLDL) and rat chylomicron remnants was studied in monolayer cultures of the J774 and P388D1 macrophage cell lines and in primary cultures of mouse peritoneal macrophages. Uptake of 125I-beta VLDL and 125I-chylomicron remnants was reduced 80-90% in the presence of high concentrations of unlabeled human low density lipoproteins (LDL). Human acetyl-LDL did not significantly compete at any concentration tested. Uptake of 125I-beta VLDL and 125I-chylomicron remnants was also competitively inhibited by specific polyclonal antibodies directed against the estrogen-induced LDL receptor of rat liver. Incubation in the presence of anti-LDL receptor IgG, but not nonimmune IgG, reduced specific uptake greater than 80%. Anti-LDL receptor IgG, 125I-beta VLDL, and 125I-chylomicron remnants bound to two protein components of apparent molecular weights 125,000 and 111,000 on nitrocellulose blots of detergent-solubilized macrophage membranes. Between 70-90% of 125I-lipoprotein binding was confined to the 125,000-Da peptide. Binding of 125I-beta VLDL and 125I-chylomicron remnants to these proteins was competitively inhibited by anti-LDL receptor antibodies. Comparison of anti-LDL receptor IgG immunoblot profiles of detergent-solubilized membranes from mouse macrophages, fibroblasts, and liver, and normal and estrogen-induced rat liver demonstrated that the immunoreactive LDL receptor of mouse cells is of a lower molecular weight than that of rat liver. Incubation of J774 cells with 1.0 micrograms of 25-hydroxycholesterol/ml plus 20 micrograms of cholesterol/ml for 48 h decreased 125I-beta VLDL uptake and immuno- and ligand blotting to the 125,000- and 111,000-Da peptides by only 25%. Taken together, these data demonstrate that uptake of beta VLDL and chylomicron remnants by macrophages is mediated by an LDL receptor that is immunologically related to the LDL receptor of rat liver.     

Conversion of plasma VLDL and IDL precursors into various LDL subpopulations using density gradient ultracentrifugation

The contribution of very low density lipoproteins (VLDL) and intermediate density lipoproteins (IDL) to various low density lipoprotein (LDL) subfractions was examined in three normal subjects and two with familial combined hyperlipidemia. Autologous VLDL + IDL (d less than 1.019 g/ml) or VLDL only (d less than 1.006 g/ml; one subject only) were isolated by sequential ultracentrifugation, iodinated, and injected into each subject. The appearance, distribution, and subsequent disappearance of radioactivity into LDL density subpopulations was characterized using density gradient ultracentrifugation. These techniques help determine the contribution of precursors to various LDL subpopulations defined uniquely for each subject. The results from these studies have suggested: 1) it took up to several days of intravascular processing of precursor-derived LDL before it resembled the distribution of the 'steady-state' plasma LDL protein; 2) plasma VLDL and IDL precursors contributed rapidly to a broad density range of LDL; 3) the radiolabeled plasma precursors did not always contribute to all LDL density subfractions within an individual in proportion to their relative LDL protein mass as determined by density gradient ultracentrifugation; 4) with time, the distribution of the precursor-derived LDL became more buoyant or more dense than distribution of the LDL protein mass; and 5) the kinetic characteristics of precursor-derived particles within LDL changed within a relatively narrow density range and were not always related to the LDL density heterogeneity of each subject. These studies emphasize the complexities of apoB metabolism and the need to design studies to carefully examine the production of various LDL subpopulations, the kinetic fate and interconversions among the subpopulations, and ultimately, their relationship to the development of atherosclerosis.     

Low density lipoprotein stimulation of human macrophage proteoglycan secretion

Lipoprotein trapping in arterial intima increases the risk for lipoprotein oxidation, foam cell formation, and inflammatory response in surrounding cells. Modified lipoproteins increase smooth muscle cell production of proteoglycans likely to retain lipoproteins in intimal extracellular matrix. We hypothesized that macrophage proteoglycan production is regulated in a similar manner, and characterized glycosaminoglycan side chains of secreted proteoglycans. Incubation with native low density lipoproteins (LDL) strongly stimulates total proteoglycan secretion in a time and concentration dependent manner. The main secretion product is small-sized (120 kDa) with unusually long galactosaminoglycan chains, predominantly chondroitin-6-O-sulfated. The effect appears specific for native LDL; oxidized LDL, very low density lipoproteins or phospholipid liposomes have only minor effects compared to control. These observations suggest that native LDL stimulate macrophages to secrete a chondroitin sulfate-rich proteoglycan moiety likely to have high capacity for vascular extracellular trapping of apolipoprotein B-containing lipoproteins.     

Metabolism of modified LDL and foam cell formation in murine macrophage-like RAW 264 cells.

The uptake of modified low density lipoprotein (LDL) by arterial macrophages is a key event in the atherogenesis. We studied 1) the uptake and degradation of modified LDL, 2) LDL recognition by specific receptors, and 3) the foam cell formation with murine macrophage-like RAW 264 cells in vitro. The cells took up and degraded effectively 125I-labeled acetylated LDL (Ac-LDL) and aggregated LDL (Aggr-LDL). Also oxidized LDL (Ox-LDL) was taken up but it was degraded poorly. The degradation of 125I-Ac-LDL was efficiently competed by both unlabeled Ac-LDL and Ox-LDL, whereas the degradation of 125I-Ox-LDL was partially competed by unlabeled Ox-LDL and Aggr-LDL but not at all by unlabeled Ac-LDL. The incubation with increasing concentrations of Ac-LDL, Aggr-LDL or Ox-LDL resulted in marked foam cell formation in the RAW 264 cells. Ox-LDL was cytotoxic at 500 to 1000 microg/ml concentrations. The results show that RAW 264 cells have at least two classes of receptors for modified lipoproteins: one that recognizes both Ox-LDL and Ac-LDL, and is similar to the scavenger receptors, and another that recognizes Ox-LDL but not Ac-LDL. RAW 264 cells are a convenient model cell line for examining the metabolism of modified lipoproteins, not only that of Ac-LDL but also that of Ox-LDL and Aggr-LDL, and cellular accumulation of lipids derived from modified LDL.     

Imipramine associations with plasma components and its uptake by cultured human cells

It has been proposed that in vivo variability in response to certain hydrophobic chemicals or drugs, such as imipramine, may be due in part to the varying plasma lipid levels in patients. The distribution of [3H]imipramine into the lipoproteins of human plasma was therefore studied. Differential density centrifugation of plasma containing [3H]imipramine resulted in flotation of very low density, low density and high density lipoproteins (VLDL, LDL, HDL) and approximately one-third of the total 3H radioactivity. Twelve percent of the radioactivity was present in the sedimented fraction which included most of the plasma proteins. There appeared to be little specific binding of [3H]imipramine to VLDL or LDL, as shown by ultracentrifugation, dialysis and column chromatography. [3H]Imipramine was readily incorporated into cultured human fibroblasts;o no differences were observed in cellular uptake whether it was added to the medium in plasma, LDL or HDL. Also, no differences in uptake of [3H]imipramine by LDL-receptor positive and receptor negative cells were noted. These experiments indicate that LDL is not a major vehicle for the transport of this drug and that both the bound and free fractions are available for cellular uptake.     

Effects of 1,2-cyclohexanedione modification on the metabolism of very low density lipoprotein apolipoprotein B: potential role of receptors in intermediate density lipoprotein catabolism

The conversion of very low density (VLDL) to low density lipoproteins (LDL) is a two-step process. The first step is mediated by lipoprotein lipase, but the mechanism responsible for the second is obscure. In this study we examined the possible involvement of receptors at this stage. Apolipoprotein B (apoB)-containing lipoproteins were separated into three fractions, VLDL (Sf 100-400), an intermediate fraction IDL (Sf 12-100), and LDL (Sf 0-12). Autologous 125I-labeled VLDL and 131I-labeled 1,2-cyclohexanedione-modified VLDL were injected into the plasma of four normal subjects and the rate of transfer of apoB radioactivity was followed through IDL to LDL. Modification did not affect VLDL to IDL conversion. Thereafter, however, the catabolism of modified apoB in IDL was retarded and its appearance in LDL was delayed. Hence, functional arginine residues (and by implication, receptors) are required in this process. Confirmation of this was obtained by injecting 125I-labeled IDL and 131I-labeled cyclohexanedione-treated IDL into two additional subjects. Again, IDL metabolism was delayed by approximately 50% as a result of the modification. These data are consistent with the view that receptors are involved in the metabolism of intermediate density lipoprotein.     

Secretion of lipids, apolipoproteins, and lipoproteins by human hepatoma cell line, HepG2: effects of oleic acid and insulin

The aim of this study was to determine the effect of oleic acid and insulin on the secretion of lipoproteins by HepG2 cells grown in minimum essential medium. Triglycerides were the major neutral lipid (57% of total) and apoB was the predominant apolipoprotein (56% of total) secreted by these cells. The addition of oleate resulted in a two-fold increase in the concentration of neutral lipids but only a slight to moderate increase in the apolipoprotein (A-I, A-II, B, and E) levels. The secretion of very low density lipoproteins (VLDL) was stimulated by 425%, low density lipoproteins (LDL) by 77%, and high density lipoproteins (HDL) by 68%. Whereas neutral lipid composition of LDL was unchanged, the VLDL particles contained a significantly higher percentage of triglyceride and lower percentages of cholesterol and cholesteryl esters compared with VLDL secreted in the absence of oleate. Oleate had no significant effect on the composition of apolipoproteins in VLDL, LDL and HDL. In basal medium, insulin caused a significant decrease in the secretion of neutral lipids and apolipoproteins, particularly triglycerides and apoB. In addition to a 60-68% reduction in the total concentration of VLDL and LDL, insulin altered their composition by producing particles that had a significantly lower content of triglycerides, contained less apoB, and were deficient in apoE. There were no major changes in the concentration or composition of HDL particles. Insulin had a similar but less pronounced effect on the concentration and composition of lipoproteins secreted in the presence of oleate. The increased accumulation of triglycerides in the HepG2 cells concomitant with their reduced levels in the medium suggests that insulin may affect the secretion rather than synthesis of triglyceride-rich lipoproteins.