Role of oxidatively modified LDL in atherosclerosis

Oxidative modification of LDL is accompanied by a number of compositional and structural changes, including increased electrophoretic mobility, increased density, fragmentation of apolipoprotein B, hydrolysis of phosphatidylcholine, derivatization of lysine amino groups, and generation of fluorescent adducts due to covalent binding of lipid oxidation products to apo B. In addition, oxidation of LDL has been shown to result in numerous changes in its biologic properties that could have pathogenetic importance, including accelerated uptake in macrophages, cytotoxicity, and chemotactic activity for monocytes. The present article summarizes very recent developments related to the mechanism of oxidation of LDL by cells, receptor-mediated uptake of oxidized LDL in macrophages, the mechanism of phosphatidylcholine hydrolysis during LDL oxidation, and other biologic actions of oxidized LDL including cytotoxicity, altered eicosanoid metabolism, and effects on the secretion of growth factors and chemotactic factors. In addition, this review will examine the evidence for the presence of oxidized LDL in vivo and the evidence that oxidized LDL plays a pathogenetic role in atherosclerosis.     

Fluorescent adducts formed by reaction of oxidized unsaturated fatty acids with amines increase macrophage viability

Macrophages are prominent components of human atherosclerotic lesions and they are believed to accelerate the progression and/or complications of both early and advanced atherosclerotic lesions. We and others have shown that oxidized low-density lipoprotein (oxLDL) induces growth and inhibits apoptosis in murine bone marrow-derived macrophages. In this study, we sought to characterize the oxidative modification of LDL that is responsible for this prosurvival effect. We found that both the modified lipid and the modified protein components of oxLDL can increase the viability of macrophages. The key modification appeared to involve derivatization of amino groups in apoB or in phosphatidylethanolamine by lipid peroxidation products. These reactive oxidation products were primarily unfragmented hydroperoxide- or endoperoxide-containing oxidation products of linoleic acid or arachidonic acid. LC-MS/MS studies showed that some of the arachidonic acid-derived lysine adducts were isolevuglandins that contain lactam and hydroxylactam rings. MS/MS analysis of linoleic acid autoxidation adducts was consistent with 5- or 6-membered nitrogen-containing heterocycles derived from unfragmented oxidation products. The amine modification by oxidation products generated a fluorescence pattern with an excitation maximum at 350nm and emission maximum at 430nm. This is very similar to the fluorescence spectrum of copper-oxidized LDL.     

Recognition of oxidized low density lipoprotein by the scavenger receptor of macrophages results from derivatization of apolipoprotein B by products of fatty acid peroxidation

Uptake of cholesterol-containing lipoproteins by macrophages in the arterial intima is believed to be an important step in the pathogenesis of atherosclerosis. There are a number of possible mechanisms by which macrophages might accumulate cholesterol, and one that has attracted much interest recently involves the uptake of oxidatively modified low density lipoprotein (LDL) via a specific cell surface receptor, termed the scavenger or acetyl-LDL receptor. Previous studies have shown that chemical derivatization of LDL with reagents that result in neutralization of the charge of lysine amino groups also allows recognition by this receptor. As well, it has been shown that oxidation of LDL is accompanied by a decrease in free lysine groups and binding of lipid products to apolipoprotein B. The present studies were done to further characterize the receptor-binding domain on oxidized LDL. It was found that LDL could be modified by incubation with water-soluble products derived from autoxidized unsaturated fatty acids under conditions that inhibited oxidation of the LDL itself. The LDL modified in this way had increased electrophoretic mobility but showed no evidence of the oxidative damage that typifies LDL oxidized by exposure to metal ions. Furthermore, the oxidation product-modified LDL was rapidly degraded by cultured macrophages through the scavenger receptor pathway. Bovine albumin modified by oxidation products also showed greatly accelerated degradation by macrophages. When analyzed by reverse-phase high pressure liquid chromatography, the reactive oxidation products appeared less polar than fatty acids or simple medium-chain aldehydes. When treated with the carbonyl reagent 2,4-dinitrophenylhydrazine, the reactive fractions yielded derivatives, some of which were identified by mass spectrometry as hydrazones of nonenal, heptenal, pentenal, and crotonaldehyde. A series of 2-unsaturated aldehydes (acrolein to 2-nonenal) were all found to modify LDL, but none of these aldehyde-modified LDLs were recognized by the scavenger receptor of macrophages and all were degraded much more slowly by these cells than LDL modified with oxidation products. Furthermore, copper-oxidized LDL had only very slight immunoreactivity toward a panel of antibodies specific for adducts of simple 2-unsaturated aldehydes. Analysis of underivatized autoxidized fatty acids by coupled liquid chromatography/thermospray mass spectrometry revealed compounds with m/z corresponding to M+17, M+31, and 2M+31 in fractions that were capable of modifying LDL. The unoxidized fatty acids showed a dominant peak at M-1. These results indicate that the scavenger receptor of macrophages can recogn     

A modification of apolipoprotein B accounts for most of the induction of macrophage growth by oxidized low density lipoprotein

It has recently been shown that macrophage proliferation occurs during the progression of atherosclerotic lesions and that oxidized low density lipoprotein (LDL) stimulates macrophage growth. Possible mechanisms for this include the interaction of oxidized LDL with integral plasma membrane proteins coupled to signaling pathways, the release of growth factors and autocrine activation of growth factor receptors, or the potentiation of mitogenic signal transduction by a component of oxidized LDL after internalization. The present study was undertaken to further elucidate the mechanisms involved in the growth-stimulating effect of oxidized LDL in macrophages. Only extensively oxidized LDL caused significant growth stimulation, whereas mildly oxidized LDL, native LDL, and acetyl LDL were ineffective. LDL that had been methylated before oxidation (to block lysine derivatization by oxidation products and thereby prevent the formation of a scavenger receptor ligand) did not promote growth, even though extensive lipid peroxidation had occurred. The growth stimulation could not be attributed to lysophosphatidylcholine (lyso-PC) because incubation of oxidized LDL with fatty acid-free bovine serum albumin resulted in a 97% decrease in lyso-PC content but only a 20% decrease in mitogenic activity. Similarly, treatment of acetyl LDL with phospholipase A2 converted more than 90% of the initial content of phosphatidylcholine (PC) to lyso-PC, but the phospholipase A2-treated acetyl LDL was nearly 10-fold less potent than oxidized LDL at stimulating growth. Platelet-activating factor receptor antagonists partly inhibited growth stimulation by oxidized LDL, but platelet-activating factor itself did not induce growth. Digestion of oxidized LDL with phospholipase A2 resulted in the hydrolysis of PC and oxidized PC but did not attenuate growth induction. Native LDL, treated with autoxidized arachidonic acid under conditions that caused extensive modification of lysine residues by lipid peroxidation products but did not result in oxidation of LDL lipids, was equal to oxidized LDL in potency at stimulating macrophage growth. Albumin modified by arachidonic acid peroxidation products also stimulated growth, demonstrating that LDL lipids are not essential for this effect. These findings suggest that oxidatively modified apolipoprotein B is the main growth-stimulating component of oxidized LDL, but that oxidized phospholipids may play a secondary role.     

Macrophage receptors responsible for distinct recognition of low density lipoprotein containing pyrrole or pyridinium adducts: models of oxidized low density lipoprotein

Oxidation of low density lipoproteins (LDL) induced by incubation with Cu(2+) ions results in the formation of a heterogeneous group of aldehydic adducts on lysyl residues (Lys) of apolipoprotein B (apoB) that are thought to be responsible for the uptake of oxidized LDL (oxLDL) by macrophages. To define the structural and chemical criteria governing such cell recognition, we induced two modifications of lysines in LDL that mimic prototypic adducts present in oxLDL; namely, epsilon-amino charge-neutralizing pyrrolation by treatment with 2,5-hexanedione (hdLDL), and epsilon-amino charge-retaining pyridinium formation via treatment with 2,4,6-trimethylpyrylium (tmpLDL). Both modifications led to recognition by receptors on mouse peritoneal macrophages (MPM). To assess whether the murine scavenger receptor class A-I (mSR-A) was responsible for recognition of hdLDL or tmpLDL in MPM, we measured binding at 4 degrees C and degradation at 37 degrees C of these modified forms of (125)I-labeled LDL by mSR-A-transfected CHO cells. Although uptake and degradation of hdLDL by mSR-A-transfected CHO cells was quantitatively similar to that of the positive control, acLDL, tmpLDL was not recognized by these cells. However, both tmpLDL and hdLDL were recognized by 293 cells that had been transfected with CD36. In the human monocytic cell line THP-1 that had been activated with PMA, uptake of tmpLDL was significantly inhibited by blocking monoclonal antibodies to CD36, further suggesting recognition of tmpLDL by this receptor. Macrophage uptake and degradation of LDL oxidized by brief exposure to Cu(2+) was inhibited more effectively by excess tmpLDL and hdLDL than was more extensively oxidized LDL, consistent with the recognition of the former by CD36 and the latter primarily by SR-A.Collectively, these studies suggest that formation of specific pyrrole adducts on LDL leads to recognition by both the mSR-A and mouse homolog of CD36 expressed on MPM, while formation of specific pyridinium adducts on LDL leads to recognition by the mouse homolog of CD 36 but not by mSR-A. As such, these two modifications of LDL may represent useful models for dissecting the relative contributions of specific modifications on LDL produced during oxidation, to the cellular uptake of this heterogeneous ligand.     

Scavenger receptor-mediated uptake and metabolism of lipid vesicles containing acidic phospholipids by mouse peritoneal macrophages

We studied the mechanism of uptake and metabolism of exogenous phospholipids in mouse peritoneal macrophages using vesicles composed of various phospholipids and cholesterol. Macrophages in culture were found to actively incorporate and metabolize phosphatidylcholine/cholesterol vesicles containing small amounts of acidic phospholipids such as phosphatidylserine, phosphatidylinositol, or phosphatidic acid and to store the fatty acyl chains and cholesterol in triacylglycerol and cholesteryl ester form in their cytosol. These cells exhibited massive amounts of oil red O-positive lipid droplets, a typical feature of foam cells. The metabolism of exogenous phospholipid vesicles was completely inhibited by chloroquine and cytochalasin B, suggesting that vesicle uptake occurs by endocytosis. A similar type of metabolism was observed in guinea pig peritoneal macrophages, macrophage cell line J774.1, but not in Swiss 3T3 fibroblasts. Competition studies using various ligands for the scavenger receptor showed that acetylated low density lipoprotein (acetyl-LDL), dextran sulfate, or fucoidan was able to compete for up to 60% of the binding of phosphatidylserine-containing vesicles, and that copper-oxidized LDL (oxidized LDL) competed for more than 90% of the vesicle binding. On the other hand, phosphatidylserine-containing vesicles was able to compete for more than 90% of the binding of acetyl-LDL. These results indicate that acidic phospholipids are recognized by the scavenger receptors on the surface of macrophages and that more than one scavenger receptor exists on mouse peritoneal macrophages, i.e. one capable of recognizing acetyl-LDL, oxidized LDL, and an array of acidic phospholipids on membranes, and the other recognizing both acidic phospholipids and oxidized LDL but not acetyl-LDL.     

Phospholipids in oxidized LDL not adducted to apoB are recognized by the CD36 scavenger receptor

Previous studies have shown that oxidation of low-density lipoprotein (oxLDL) results in its recognition by scavenger receptors on macrophages. Whereas blockage of lysyl residues on apoB-100 of oxLDL by lipid peroxidation products appears to be critical for recognition by the scavenger receptor class A (SR-A), modification of the lipid moiety has been suggested to be responsible for recognition by the scavenger class B receptor, CD36. We studied the recognition by scavenger receptors of oxidized LDL in which lysyl residues are blocked prior to oxidation through methylation [ox(m)LDL]. This permits us to minimize any contribution of modified apoB-100 to the recognition of oxLDL, but does not disrupt the native configuration of lipids in the particle. We found that ox(m)LDL was recognized by receptors on mouse peritoneal macrophages (MPM) almost as well as oxLDL. Ox(m)LDL was recognized by CD36-transfected cells but not by SR-A-transfected cells. Oxidized phospholipids (oxPC) transferred from oxLDL or directly from oxPC to LDL, conveyed recognition by CD36-transfected cells, confirming that CD36 recognized unbound oxidized phospholipids in ox(m)LDL. Collectively, these results suggest that oxPC not adducted to apoB within the intact oxLDL particle are recognized by the macrophage scavenger receptor CD36, that these lipids are not recognized by SR-A, and that they can transfer from oxidized to unoxidized LDL and induce CD36 recognition.     

Multiple receptors for modified low density lipoproteins in mouse peritoneal macrophages: different uptake mechanisms for acetylated and oxidized low density lipoproteins

Receptor-mediated incorporations of two modified low density lipoproteins (LDL), acetylated LDL (acetyl-LDL) and oxidized LDL were compared in vitro in mouse peritoneal macrophages by cross-competition experiments. Excess amount of oxidized LDL inhibits the binding of [125I]acetyl-LDL only partially, and excess amount of acetyl-LDL inhibits that of [125I]oxidized LDL also only partially, suggesting that the uptake of the two LDL by macrophages is mediated by partially overlapped yet different mechanisms. Scatchard analysis of [125I]acetyl-LDL binding showed a linear plot and addition of excess amount of oxidized LDL partially displaced the binding sites without changing the affinity, suggesting that there are two classes of receptors with similar affinity; one is specific for acetyl-LDL and the other is common. And the plot of [125I]oxidized LDL binding showed a curvilinear plot and excess amount of acetyl-LDL partially displaced the binding sites of the low affinity, suggesting that there are two classes of binding sites with different affinities and the low affinity one is shared with acetyl-LDL. These results indicate that macrophage receptors for modified LDL consist of at least three receptors, two of which are specific for each LDL and the rest is a common receptor.     

Role of lysine residues of plasma lipoproteins in high affinity binding to cell surface receptors on human fibroblasts.

The low density lipoprotein (LDL) cell surface receptors on human fibroblasts grown in culture bind specific plasma lipoproteins, initiating a series of events which regulate intracellular cholesterol metabolism. Specificity for the interaction with the receptors resides with the protein moieties of the lipoproteins, specifically with the B and E apoproteins of LDL and certain high density lipoproteins (HDLc HDLl), respectively. It was previously established that the amino acid arginine is a functionally significant residue in or near the recognition sites on the B and E apoproteins and that modification of this residue abolishes the ability of these apolipoproteins to bind to the receptor. The present study indicates that lysine residues are also involved in the lipoprotein-receptor interaction. Chemical modification of 15% of the lysine residues of LDL by carbamylation with cyanate or 20% by acetoacetylation with diketene prevents the LDL from competitively displacing unmodified 125I-LDL from the high affinity receptor sites or from binding directly to the receptor. Moreover, quantitative reversal of the aceto-acetylation of the lysine residues of LDL by hydroxylamine treatment regenerates the lysyl residues and reestablishes greater than 90% of the original binding activity of the LDL. The reversibility of this reaction establishes that the loss of binding activity which follows lysine modification is not due to an irreversible alteration of the LDL or HDLc but is probably due to an alteration of a property of the recognition site associated with specific lysine residues. While acetoacetylation and carbamylation neutralize the positive charge on the epsilon-amino group of lysine, reductive methylation selectively modifies lysine residues of LDL and HDLc without altering the positive charge, yet abolishes their ability to bind to the receptor. Preservation of the charge but loss of binding activity following reductive methylation of the lipoproteins suggests that the specificity of the recognition site does not reside simply with the presence of positive charges but depends on other more specific properties of the site determined by the presence of a limited number of the lysine (and arginine) residues. The precise role of lysine remains to be defined, but its function may be to establish and maintain the conformation of the recognition site or the alignment of reactive residues, or both, or to chemically react, through its epsilon-amino group, with the receptor (hydrogen bond formation would be such a possibility).     

Oxidized phospholipids, linked to apolipoprotein B of oxidized LDL, are ligands for macrophage scavenger receptors

Previous studies have shown that macrophage receptors for oxidized LDL (OxLDL) recognize both the lipid and protein moieties, and that a monoclonal antibody against OxLDL, EO6, also recognizes both species. The present studies show directly that during LDL oxidation phospholipids become covalently attached to apolipoprotein B (apoB). After exhaustive extraction of lipids, apoB of native LDL contained 4 +/- 3 moles of phosphorus/mole protein. In contrast, apoB of OxLDL contained approximately 75 moles of phosphorus/mole protein. Saponification of this apoB released phosphorus, choline, and saturated fatty acids in a molar ratio of 1.0:0.98:0.84. When LDL was reductively methylated prior to oxidation, the amount of phospholipid covalently bound was reduced by about 80%, indicating that the phospholipids attach at lysine epsilon amino groups. Progressive decreases in the phospholipid associated with apoB of OxLDL decreased the ability of the protein to compete for binding to macrophage scavenger receptors and decreased its reactivity with antibody EO6.We postulate that some oxidized phospholipids containing fatty acid aldehydes at the sn-2 position bind to lysine residues of apoB while others remain unreacted within the lipid phase. This would account for the interchangeability of lipid and apolipoprotein of OxLDL with respect to receptor binding and antibody recognition.     

The binding of acetic anhydride- and citraconic anhydride-modified human low-density lipoprotein to mouse peritoneal macrophages. The evidence for separate binding sites

Human plasma low-density lipoprotein (LDL) was modified chemically with either the monocarboxylic acid derivative, acetic anhydride, or the dicarboxylic acid derivative, citraconic anhydride, reagents which react principally with the lysine residues of protein. The modifications increased the net negative charge on the LDL particles, with citraconyl-LDL displaying a greater negative charge than acetylated LDL. Neither the antigenic reactivity nor the overall gross protein/lipid composition of the LDL were affected by the modification procedures, although a small reduction in the total cholesterol content was observed. The altered LDL species lost the ability to bind to the high-affinity cell surface B/E receptor but both bound to mouse peritoneal macrophages with saturable high-affinity kinetics. At 4 degrees C, the macrophages bound 125I-labelled citraconyl-LDL more avidly (K = 21 X 10(-3) ml/ng) than they bound labelled acetyl-LDL (K = 2 X 10(-3) ml/ng). Competitive inhibition studies indicated that acetyl-LDL and citraconyl-LDL were bound to non-identical sites on the macrophage monolayer surface and that the binding site for citraconyl-LDL was also different from that recognized by hypercholesterolaemic rabbit plasma VLDL (beta VLDL).     

Oxidation of low density lipoprotein leads to particle aggregation and altered macrophage recognition.

Oxidized (ox-) low density lipoproteins (LDL) is characterized by the formation of lipid peroxides and their decomposition to reactive aldehydes which covalently link to apoB in LDL. These chemical changes are believed to be responsible for the enhanced recognition of ox-LDL by receptors on macrophages in culture. When oxidation is extensive, particle aggregation also occurs. The aim of this study was to characterize aggregation formation and how this influences the interaction of ox-LDL with macrophages in culture. When LDL was oxidized by incubating at 500 micrograms of protein/ml with 10 microM Cu2+ at 20 degrees C for up to 25 h, time-dependent increases in thiobarbituric acid reactive substances, conjugated diene content, electrophoretic mobility, and fluorescence at 360 excitation/430 emission were found. Particle aggregation increased in parallel with several parameters of oxidation and increased with increasing incubation temperatures and LDL concentrations used. When evaluated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, apoB fragments of reproducible sizes and higher molecular weight species appeared after mild oxidation of LDL. The percent of total apoB remaining aggregated in sodium dodecyl sulfate was 50-80% at high degrees of oxidation, whereas it was far less in LDL that had been aggregated without chemical modification. This suggested that intermolecular cross-linking of apoB had occurred during oxidation of LDL at high concentrations. Degradation of ox-LDL in mouse peritoneal macrophages (MPM) increased in parallel with the degree of oxidation and with particle aggregation but reached a plateau after 12 h. Results from cross-competition studies in MPM with soluble and insoluble portions of extensively ox-LDL and with acetyl-LDL were consistent with uptake of soluble ox-LDL via both the scavenger receptor and another receptor on MPM, and uptake of the insoluble ox-LDL by an alternative mechanism.     

Macrophage recognition of LDL modified by levuglandin E2, an oxidation product of arachidonic acid

Levuglandin (LG) E₂, a secoprostanoic acid levulinaldehyde derivative, is a product of free radical oxidation that forms covalent adducts with lysyl residues on proteins. Treatment of LDL with LGE₂ leads to uptake and degradation by mouse peritoneal macrophages. Oxidized LDL, but not acetyl LDL efficiently competed for binding and uptake of LGE₂-modified ¹²⁵I-LDL. This result suggests that LGE₂-modified LDL was recognized by a class of scavenger receptor that demonstrated ligand specificity for oxidized LDL but not for acetyl LDL.     

Mechanisms of oxidative modification of low density lipoproteins under conditions of oxidative and carbonyl stress

Low-molecular-weight aldehydes (glyoxal, methylglyoxal, 3-deoxyglucosone) generated on autooxidation of glucose under conditions of carbonyl stress react much more actively with amino groups of L-lysine and epsilon-amino groups of lysine residues of apoprotein B-100 in human blood plasma low density lipoproteins (LDL) than their structural analogs (malonic dialdehyde (MDA), 4-hydroxynonenal) resulting on free radical oxidation of lipids under conditions of oxidative stress. Glyoxal-modified LDL aggregate in the incubation medium with a significantly higher rate than LDL modified by MDA, and MDA-modified LDL are markedly more poorly absorbed by cultured human macrophages and significantly more slowly eliminated from the rat bloodstream upon intravenous injection. Studies on kinetics of free radical oxidation of rat liver membrane phospholipids have shown that ubiquinol Q(10) is the most active lipid-soluble natural antioxidant, and suppression of ubiquinol Q(10) biosynthesis by beta-hydroxy-beta-methylglutaryl coenzyme A reductase inhibitors (statins) is accompanied by intensification of lipid peroxidation in rat liver biomembranes and in LDL of human blood plasma. Injection of ubiquinone Q(10) protects the human blood plasma LDL against oxidation and prevents oxidative stress-induced damages to rat myocardium. A unified molecular mechanism of atherogenic action of carbonyl-modified LDL in disorders of lipid and carbohydrate metabolism is discussed.     

Role of lysines in mediating interaction of modified low density lipoproteins with the scavenger receptor of human monocyte macrophages

The ability of the scavenger receptor of human monocyte macrophages to recognize human low density lipoproteins (LDL) progressively modified by three lysine-specific reagents, malondialdehyde, acetic anhydride, or succinic anhydride, has been investigated. Regardless of the reagent utilized, receptor-mediated uptake was dependent upon modification of greater than 16% of the peptidyl lysines rather than upon the net negative charge of derivatized LDL. Rates of lysosomal hydrolysis of acetyl-LDL and succinyl-LDL increased as a function of progressive modification and reflected the amount of derivatized LDL binding to the receptor. Succinylation or acetylation of greater than 60% of the lysines was necessary to attain maximal ligand binding, internalization, and degradation. In contrast, modification of only 16% of the peptidyl lysines by malondialdehyde resulted in maximal levels of binding, uptake, and hydrolysis. The expression of receptor recognition site(s) appears to depend upon the charge modification of critical lysine residues of the LDL protein rather than the net negative charge of the lipoprotein complex. Malondialdehyde, a bifunctional reactant, may modify surface and sequestered lysines concomitantly and thus promote efficient formation of the recognition site(s).     

Stimulation of smooth muscle cell proliferation by ox-LDL- and acetyl LDL-induced macrophage-derived foam cells.

To test the hypothesis that LDL lacking of initial oxidation may also anticipate an essential role in the progression for atherosclerotic lesions, we studied the in vitro effect of foam cells induced by low density lipoprotein (LDL), oxidized (ox)-LDL or acetyl-LDL on smooth muscle cell (SMC) proliferation. Intraperitoneal macrophages collected from ICR mice were incubated with buffered saline LDL, ox-LDL or acetyl-LDL to induce foam cell formation. Porcine aortas with atherosclerotic lesions were collected from 5 pigs fed high cholesterol diets. The results indicate that foam cells induced by ox-LDL and acetyl-LDL, but not by LDL, promoted SMC proliferation. SMC proliferation was also increased by ruptured, ox-LDL- and acetyl-LDL- induced foam cells. Immunohistochemically, epitopes of the LDL, ox-LDL, and malondialdelyde (MDA)-LDL were present in atherosclerotic lesions, but the acetyl epitope was not. We suggest that foam cells, whether induced by the oxidized or acetyl or acetyl (unoxidized) form, play an essential role in the pathogenesis of atherosclerosis by stimulating SMC proliferation.     

Interaction of a high-affinity heparin subfraction with low-density lipoprotein stimulates cholesteryl ester accumulation in mouse macrophages

A high-affinity heparin subfraction accounting for 8% of whole heparin from bovine lung was isolated by low-density lipoprotein (LDL)-affinity chromatography. When compared to whole heparin, the high-affinity subfraction was relatively higher in molecular weight (11,000 vs. 17,000) and contained more iduronyl sulfate as hexuronic acid (76% vs. 86%), N-sulfate ester (0.75 vs. 0.96 mol/mol hexosamine), and O-sulfate ester (1.51 vs. 1.68 mol/mol hexosamine). Although both heparin preparations formed insoluble complexes with LDL quantitatively in the presence of 30 mM Ca2+, the concentrations of NaCl required for 50% reduction in maximal insoluble complex formation was markedly higher with high-affinity subfraction (0.55 M vs. 0.04 M). When compared to complex of 125I-LDL and whole heparin (H-125I-LDL), complex of 125I-LDL and high-affinity heparin subfraction (HAH-125I-LDL) produced marked increase in the degradation of lipoproteins by macrophages (7-fold vs. 1.4-fold over native LDL, after 5 h incubation) as well as cellular cholesteryl ester synthesis (16.7-fold vs. 2.2-fold over native LDL, after 18 h incubation) and content (36-fold vs. 2.7-fold over native LDL, after 48 h incubation). After a 5 h incubation, macrophages accumulated 2.3-fold more cell-associated radioactivity from HAH-125I-LDL complex than from [125I]acetyl-LDL. While unlabeled HAH-LDL complex produced a dose-dependent inhibition of the degradation of labeled complex, native unlabeled LDL did not elicit any effect even at a 20-fold excess concentration. Unlabeled particulate LDL aggregate competed for 33% of degradation of labeled complex; however, cytochalasin D, known inhibitor of phagocytosis, did not effectively inhibit the degradation of labeled complex. Unlabeled acetyl-LDL produced a partial (33%) inhibition of the degradation of labeled complex. These results indicate that (1) the interaction of high-affinity heparin subfraction with LDL leads to scavenger receptor mediated endocytosis of the lipoprotein, and stimulation of cholesteryl ester synthesis and accumulation in the macrophages; and (2) with respect to macrophage recognition and uptake, HAH-LDL complex was similar but not identical to acetyl-LDL. These observations may have implications for atherogenesis, because both mast cells and endothelial cells can synthesize heparin in the arterial wall.     

Modification of human serum low density lipoprotein by oxidation--characterization and pathophysiological implications

Plasma low density lipoprotein (LDL) can undergo free radical oxidation either catalyzed by divalent cations, such as Cu2+ or Fe2+ or promoted by incubation with cultured cells such as endothelial cells, smooth muscle cells and monocytes. The content of vitamin E, beta-carotene and unsaturated fatty acids is decreased in oxidized LDL. A breakdown of apolipoprotein-B (apoB), hydrolysis of the phospholipids, an increase of thiobarbituric acid reactive substances and the generation of aldehydes also occur. Changes in the ratio of lipid to protein, the electrophoretic mobility and the fluorescent properties have also been reported to accompany oxidation of this lipoprotein. The functional changes of oxidized LDL include its recognition by the scavenger receptor on macrophages, its cytotoxicity especially to proliferating cells, its chemotactic properties with respect to monocyte-macrophages and its regulation of platelet-derived growth factor-like protein (PDGFc) production by endothelial cells. In this article we summarize some of the contributions to this topic and present speculations relating oxidized LDL to pathological conditions such as atherosclerosis.     

The oxidative modification of low-density lipoproteins by macrophages.

1. Mouse resident peritoneal macrophages in culture modified human 125I-labelled low-density lipoprotein (LDL) to a form that other macrophages took up about 10 times as fast as unmodified LDL. The modified LDL was toxic to macrophages in the absence of serum. 2. There was a lag phase of about 4-6 h before the LDL was modified so that macrophages took it up faster. A similar time lag was observed when LDL was oxidized by 5 microM-CuSO4 in the absence of cells. 3. LDL modification was maximal when about 1.5 x 10(6) peritoneal cells were plated per 22.6 mm-diam. well. 4. Re-isolated macrophage-modified LDL was also taken up much faster by macrophages, indicating that the increased uptake was due to a change in the LDL particle itself. 5. Micromolar concentrations of iron were required for the modification of LDL by macrophages to take place. The nature of the other components in the culture medium was also important. Macrophages would modify LDL in Ham's F-10 medium but not in Dulbecco's modified Eagle's medium, even when iron was added to it. 6. The macrophage-modified LDL appeared to be taken up almost entirely via the acetyl-LDL receptor. 7. LDL modification by macrophages was inhibited partially by EDTA and desferrioxamine and completely by the general free radical scavengers butylated hydroxytoluene, vitamin E and nordihydroguaiaretic acid. It was also inhibited completely by low concentrations of foetal calf serum and by the anti-atherosclerotic drug probucol. It was not inhibited by the cyclo-oxygenase inhibitors acetylsalicylic acid and indomethacin. 8. Macrophages are a major cellular component of atherosclerotic lesions and the local oxidation of LDL by these cells may contribute to their conversion into cholesterol-laden foam cells in the arterial wall.