Studies on the mechanism of uptake of low density lipoprotein-proteoglycan complex in macrophages

Earlier, we (Vijayagopal, P. et al. (1988) Biochim. Biophys. Acta 960, 210) showed that mouse peritoneal macrophages metabolize low density lipoprotein (LDL)-proteoglycan complex by a receptor pathway distinct from the acetyl-LDL receptor. Further studies were conducted to probe further into the mechanism of LDL-proteoglycan complex uptake by macrophages. Both 125I-methyl-LDL-proteoglycan complex and 125I-LDL-proteoglycan complex were taken up and degraded by the cells to the same extent. Similarly, the ability of these ligands to stimulate cholesteryl ester synthesis was also indistinguishable. These results rule out the possibility of apoB,E receptor involvement in the uptake of LDL-proteoglycan complex in macrophages. Sodium fluoride, cytochalasin D and aggregated LDL inhibited degradation of the complex by 24%, 26% and 28%, respectively, indicating that phagocytosis is only a minor pathway for the uptake. Both binding and degradation of the complex were not inhibited by excess hyaluronic acid suggesting that ligand recognition was not through hyaluronic acid binding sites. As compared to acetyl-LDL, the cellular degradation of LDL-proteoglycan complex was retarded. Macrophages exhibited a rapid stimulation of [3H]inositol trisphosphate (IP3) release and diacylglycerol production when incubated with LDL-proteoglycan complex. Furthermore, pertussis toxin produced a 62% inhibition of LDL-proteoglycan complex mediated IP3 release, suggesting that LDL-proteoglycan complex metabolism in macrophages is dependent upon the G-protein coupled signal transduction mechanism. These results show that receptor mediated endocytosis plays a major role in the metabolism of LDL-proteoglycan complex in macrophages.     

Metabolism of low-density lipoprotein-proteoglycan complex by macrophages: further evidence for a receptor pathway

Earlier, we (Vijayagopal, P., et al. (1985) Biochim. Biophys. Acta 837-251) have shown that complexes of plasma low-density lipoproteins (LDL) and arterial chondroitin sulfate-dermatan sulfate proteoglycan aggregate promote LDL degradation and cholesteryl ester accumulation in mouse peritoneal macrophages. Further studies were conducted to determine whether LDL-proteoglycan complex is metabolized by a receptor-mediated process. Native proteoglycan aggregate was isolated from bovine aorta by associative CsCl isopycnic centrifugation. Complex of 125I-labeled LDL and proteoglycan aggregate formed in the presence of 30 mM Ca2+ was incubated with macrophages, and the binding at 4 degrees C and degradation at 37 degrees C of 125I-labeled LDL in the complex was monitored. Both binding and degradation of the complex were specific and saturable, suggesting that the processes are receptor mediated. The Kd for binding was 23 micrograms LDL protein per ml in the complex. Degradation of 125I-labeled LDL-proteoglycan complex was not suppressed by preincubation of macrophages with excess unlabeled complex, suggesting that the receptor for the complex is not subject to down regulation. Both binding and degradation of the complex and the resultant stimulation of cholesteryl ester synthesis were inhibited by limited treatment of cells with low doses of trypsin and pronase, indicating that the binding sites are protein or glycoprotein in nature. Binding was not inhibited by an excess of native LDL and beta-VLDL and exhibited only partial competition by excess unlabeled acetyl-LDL; however, polyinosinic acid, fucoidin and dextran sulfate, known inhibitors of acetyl-LDL binding and degradation in macrophages, did not affect LDL-proteoglycan complex binding and degradation. Similarly, excess unlabeled LDL-proteoglycan complex produced only partial inhibition of the binding and degradation of 125I-labeled acetyl-LDL by macrophages, suggesting that the binding sites for acetyl-LDL and LDL-proteoglycan complex are probably not identical. These studies provide evidence for a receptor-mediated pathway for the metabolism of LDL-proteoglycan complex in macrophages.     

Complexes of low-density lipoproteins and arterial proteoglycan aggregates promote cholesteryl ester accumulation in mouse macrophages

We studied the effect of complexes of low-density lipoproteins (LDL) and different proteoglycan preparations from bovine aorta on LDL degradation and cholesteryl ester accumulation in mouse peritoneal macrophages. Native proteoglycan aggregate containing proteoglycan monomers, hyaluronic acid and link protein was isolated by associative extraction of aortic tissue, while proteoglycan monomer was obtained by dissociative isopycnic centrifugation of the native proteoglycan aggregate. In vitro proteoglycan aggregates were prepared by reaction of the proteoglycan monomer with exogenous hyaluronic acid. 125I-labeled LDL-proteoglycan complexes were formed in the presence of 30 mM Ca2+ and incubated with macrophages. At equivalent uronic acid levels in the proteoglycans the degradation of 125I-labeled LDL contained in the native proteoglycan aggregate complex was 3.7-7.5-fold greater than the degradation of the lipoprotein in the proteoglycan monomer complex. Degradation of 125I-LDL in the in vitro aggregate complex, while higher than that in the monomer complex, was markedly less than that in the native aggregate complex. The larger size and the greater complex-forming ability of the native proteoglycan aggregate might account for the greater capacity of the aggregate to promote LDL degradation in macrophages. The proteoglycan-stimulated degradation of LDL produced a marked increase in cholesteryl ester synthesis and content in macrophages. The LDL-proteoglycan complex was degraded with saturation kinetics, suggesting that these complexes are internalized through high-affinity receptors. Degradation was inhibited by the lysosomotropic agent, chloroquine. Acetyl-LDL, but not native LDL, competitively inhibited the degradation of the 125I-LDL component of the complex. Polyanionic compounds such as polyinosinic acid and fucoidin, while completely blocking the acetyl-LDL-stimulated cholesteryl ester formation, had no effect on the proteoglycan aggregate-stimulated cholesterol esterification. This suggests that LDL-proteoglycan complex and acetyl-LDL are not entering the cells through the same receptor pathway. These results demonstrate that the interaction of LDL with arterial wall proteoglycan aggregates results in marked cholesteryl ester accumulation in macrophages, a process likely to favor foam cell formation. A role for arterial proteoglycans in atherosclerosis is obvious.     

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.     

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.     

Modification of LDL by platelet secretory products induces enhanced uptake and cholesterol accumulation in macrophages

LDL modified by incubation with platelet secretory products caused cholesterol accumulation and stimulation of cholesterol esterification in mouse peritoneal macrophages. Its uptake by the macrophages was a receptor-mediated process, not susceptible to competition by acetyl-LDL or polyanions suggesting independence of the scavenger receptor. Stimulation of the esterification process in macrophages by this modified LDL was inhibited by the lysosomal inhibitor chloroquine, indicating requirement for cellular uptake and lysosomal hydrolysis of the lipoprotein. Within the cell, the modified LDL inhibited cellular biosynthesis of triglycerides in a manner similar to the action of acetyl-LDL but different to the effect of native LDL. In the presence of HDL, acting in the medium as an acceptor for cholesterol, a low rate of cholesterol efflux from cells incubated with this modified LDL as well as with acetyl-LDL was demonstrated. A small reduction in cholesteryl ester synthesis was found in these cells, compared to a 60% reduction in cells incubated with native LDL. Thus it was demonstrated that LDL modified by platelet secretory products could induce macrophage cholesterol accumulation even though it was recognized and taken up via the regulatory LDL receptor.     

Inhibition of mouse macrophage degradation of acetyl-low density lipoprotein by interferon-gamma

In vitro, metabolism of modified forms of low density lipoprotein (LDL) by macrophages via the acetyl-LDL receptor pathway promotes the massive cellular accumulation of lipid. It has been postulated that in vivo this contributes to foam cell formation in the atherosclerotic lesion. Recent studies have shown that arterial wall cells in vitro can secrete a number of cytokines, several of which have been reported to modulate macrophage cell function. Thus, cytokines have the potential to modulate the acetyl-LDL receptor pathway and to influence the rate of foam cell generation. To study the regulation of this pathway by cytokines, the effect of cytokines on the degradation of acetyl-LDL protein by mouse peritoneal macrophages was examined. Initially, supernatant from stimulated lymphocytes was used as a source of cytokines. Macrophages preincubated with supernatants obtained after the stimulation of T-cell helper type 1 (Th1) clone HDK-1 or BALB/c spleen cells degraded acetyl-LDL at a slower rate, whereas supernatant from stimulated T-cell helper type 2 (Th2) clone D-10 had no effect. Comparison of the lymphokine profiles showed that spleen and HDK-1 cells secreted several lymphokines in common including significant levels of interferon-gamma. Interferon-gamma was then directly shown to be inhibitory; an anti-interferon-gamma monoclonal antibody blocked the HDK-1-mediated inhibition by 70% and the addition of recombinant interferon-gamma (IFN-gamma) to macrophages inhibited the specific degradation of acetyl-LDL in a dose- and time-dependent manner with a maximum suppression to approximately 40% of control. The inhibition was not accompanied by an increase in the amount of cell-associated acetyl-LDL and was not due to cell death nor could it be accounted for by the presence of endotoxin. To study the mechanism of the inhibition, the effects of IFN-gamma on the itinerary of acetyl-LDL and its receptor were examined. IFN-gamma decreased specific acetyl-LDL binding only to a small degree, and the rate of lysosome-mediated degradation was not affected. The principal alteration was in the rate of transport to the lysosome which was markedly slowed. Since the receptors eventually returned to the surface to maintain a steady state, and there was not an increase in cell-associated lipoprotein, there must be other changes in the itinerary that were not identified with the techniques used. Thus, the receptor cycle is being regulated at a discrete point. IFN-gamma also suppressed the LDL receptor pathway in macrophages, but this pathway was not affected by IFN-gamma in mouse fibroblasts.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of 3-hydroxy-3-methylglutaryl-coenzyme A reductase activity in mouse peritoneal macrophages.

The lipoprotein-mediated regulation of 3-hydroxy-3-methylglutaryl-(HMG-) CoA reductase in cultured mouse peritoneal macrophages has been investigated. In contrast to what has been reported for other cells, HMG-CoA reductase activity is not suppressed by normal serum or by normal low density lipoproteins (LDL) from humans or dogs. Suppression of reductase activity occurred when cells were cultured in the presence of beta-migrating very low density lipoproteins (beta-VLDL) or LDL from hypercholesterolaemic dogs, or LDL modified by acetoacetylation. Human beta-VLDL from an atypical type III hyperlipoproteinaemic patient was also effective, as was apolipoprotein (apo) E-containing high density lipoproteins (HDL) from cholesterol-fed dogs (apo-E HDLc). The results indicate that cholesterol biosynthesis in mouse peritoneal macrophages is regulated by lipoprotein cholesterol entering via receptor-mediated endocytosis. Normal LDL were not effective because of the poor binding and uptake of these lipoproteins by the apo-B, E (LDL) receptor. Only beta-VLDL, apo-E HDLc, and hypercholesterolaemic LDL were avidly taken up by this receptor and were able to suppress HMG-CoA reductase. Acetoacetylated LDL were internalized via the acetyl-LDL (scavenger) receptor. Thus, mouse macrophages differ from human fibroblasts and smooth muscle cells in their physiological regulation of cholesterogenesis.     

Acyl coenzyme A:cholesterol acyl transferase in macrophages utilizes a cellular pool of cholesterol oxidase-accessible cholesterol as substrate

Cholesterol esterification by acyl CoA:cholesterol acyl transferase (ACAT) in macrophages is a key process in atheroma foam cell formation. However, the process of cholesterol substrate delivery to ACAT is not well defined. In this study, J774 macrophages, which form foam cells with native low density lipoprotein (LDL), were labeled with [3H]cholesterol-containing liposomes. Most (80-90%) of the cholesterol label could be converted by cholesterol oxidase to cholestenone, suggesting plasma membrane localization; only 0.6% of the label was in cholesteryl ester (CE). In cells chased for 6 h in medium lacking LDL, the distribution of label was essentially unchanged, whereas in cells chased with LDL, 28% of the label was incorporated into CE concomitant with a decrease in cholestenone label to 50%. [3H]Cholesterol-labeled mouse peritoneal macrophages incubated with acetyl-LDL, and both J774 and mouse peritoneal macrophages incubated with 25-hydroxy-cholesterol, also showed a shift of label from cholestenone to CE. Similar results were found when cellular cholesterol was biosynthetically labeled with [3H]mevalonate. The percentage of cholesterol substrate for ACAT in LDL-treated J774 macrophages which originates from endogenous cellular pools (versus that originating from LDL itself) is approximately 50%. We conclude that upon activation of ACAT in macrophages, there is a novel process whereby a cholesterol oxidase-accessible pool of cellular cholesterol, presumably plasma membrane cholesterol, is translocated to ACAT in the endoplasmic reticulum.     

Monocyte colony-stimulating factor enhances uptake and degradation of acetylated low density lipoproteins and cholesterol esterification in human monocyte-derived macrophages

We have investigated effects of monocyte colony-stimulating factor (M-CSF) on the uptake of acetylated low density lipoproteins (acetyl-LDL) and the activity of cholesterol esterification in human monocyte-derived macrophage. The cells were cultured with M-CSF for 10 days and then incubated with acetyl-LDL for 24 h. M-CSF (128 ng/ml) enhanced the uptake and degradation of 10 micrograms/ml of 125I-acetyl LDL 7.5-fold (n = 6) and the effect of M-CSF was dose-dependent at the concentrations of 0.5-32 ng/ml. The binding experiments at 4 degrees C demonstrated that the number of acetyl-LDL receptor was increased by the addition of M-CSF. Supporting this, ligand blotting analysis revealed a significant increase in a receptor protein for acetyl-LDL (240 kDa). Binding of LDL was also enhanced by M-CSF but less significantly than that of acetyl-LDL. Cellular cholesterol esterification in the presence of 10 micrograms/ml acetyl-LDL was enhanced 24.1-fold (n = 13) by 128 ng/ml M-CSF. It was evident that M-CSF enhanced cholesterol esterification to a greater extent than the cellular uptake of acetyl-LDL (24.1- versus 7.5-fold). Cholesterol esterification was also enhanced by the addition of granulocyte-macrophage colony-stimulating factor and interleukin 1. We conclude that M-CSF enhances the uptake of both acetyl-LDL and LDL by increasing their receptor number, and further enhances the process of cholesterol esterification, resulting in a remarkable increase in cholesterol esterification in macrophages. These findings strongly suggest the significant involvement of cytokines such as M-CSF in cholesterol metabolism of macrophages.     

A low density lipoprotein-sized particle isolated from human atherosclerotic lesions is internalized by macrophages via a non-scavenger-receptor mechanism

A lipoprotein particle designated A-LDL, which contains apolipoprotein B (apoB) and which is the size of plasma low density lipoproteins (LDL), was isolated from homogenates of human aortic athersclerotic plaques by a combination of affinity chromatography and gel-filtration. Compared to plasma LDL, A-LDL was more electronegative, its hydrated density was lower and more heterogeneous, and its protein-to-lipid ratio was lower. In addition, apoB in A-LDL was highly degraded, and A-LDL was recognized by mouse peritoneal macrophages (MPM) as indicated by its ability to stimulate cholesterol esterification. Cholesterol esterification was saturable with an apparent Km of 100 micrograms of A-LDL cholesterol/ml. Stimulation of cholesterol esterification was linear with time, leading to extensive accumulation of cholesteryl ester in MPM over a 48-hr time interval. The uptake or degradation of acetyl-LDL (radiolabeled either in the protein with 125I or hydrophobic core with [3H]cholesteryl ether) was markedly decreased by excess unlabeled acetyl-LDL but not by A-LDL, and excess acetyl-LDL did not inhibit the uptake or degradation of labeled A-LDL. However, a 10-fold excess of A-LDL also failed to inhibit the uptake of labeled A-LDL. This finding was consistent with the observation that, unlike the saturable stimulation of cholesterol esterification in MPM induced by A-LDL, the uptake of cholesteryl ether-labeled A-LDL was almost linear over a 0-400 micrograms cholesterol/ml range. This discrepancy between dose response curves for A-LDL, which did not occur for acetyl-LDL, could be eliminated by a 24-hr postincubation period in the absence of lipoprotein, suggesting that A-LDL is catabolized less efficiently than acetyl-LDL following internalization. In summary, we conclude that A-LDL uptake by MPM occurs via a low affinity-high capacity process. Although the uptake of A-LDL is not readily saturated, it is of sufficient affinity to lead to lipid loading of macrophages even when A-LDL is present at relatively low concentrations. If these mechanisms are operative in vivo, they could explain how foam cells in human fatty streak lesions develop.     

Topography and dynamics of receptors for acetylated and malondialdehyde-modified low-density lipoprotein in the plasma membrane of mouse peritoneal macrophages as visualized by colloidal gold in conjunction with surface replicas

The topography and dynamics of receptors for acetylated (acetyl) and malondialdehyde-modified (MDA) low-density lipoprotein (LDL) in the plasma membrane of cultured mouse peritoneal macrophages were investigated using a new technique. Modified LDL labeled with gold particles was used to visualize LDL receptors in the plane of the plasma membrane in platinum-carbon surface replicas of critical point-dried cells. It was found that the native distribution of unoccupied acetyl-LDL receptors is diffuse, whereas unoccupied MDA-LDL receptors are preclustered in the plasma membrane. Competition and double labeling experiments suggest the existence of two distinct classes of receptor sites for acetyl-LDL and MDA-LDL.     

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.     

The interaction of human apoB-containing lipoproteins with mouse peritoneal macrophages: a comparison of Lp(a) with LDL

Cholesteryl ester accumulation in macrophages and foam cell formation is believed to play an important role in atherogenesis. The effect of Lp(a) on the incorporation of [14C]oleate into cholesteryl esters was studied in mouse peritoneal macrophages. In view of the physico-chemical similarities between Lp(a) and LDL, the results were compared with those obtained with LDL. Native Lp(a) and LDL did not stimulate cholesteryl ester formation. Incubation of macrophages with Lp(a)- or LDL-dextran sulfate complexes caused a significant increase in cholesteryl ester formation. A similar effect was observed when Lp(a) or LDL were incubated with macrophages in the presence of antibodies directed against the specific Lp(a) apoprotein or against LpB. Treatment of Lp(a) with acetic anhydride or malondialdehyde (MDA) was followed by precipitation of most of the lipoprotein. Therefore, these modifications were not suitable to study the uptake of modified Lp(a) by macrophages. Studies with acetyl-LDL or MDA-treated LDL caused the well-known stimulation of [14C]oleate incorporation into cholesteryl esters. Thus, the modification of Lp(a) by sulfated polysaccharides or by treatment with antibodies yields similar cholesteryl ester deposition in mouse peritoneal macrophages as observed with modified LDL. This might be one mechanism by which Lp(a) exerts its atherogenicity.     

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.     

Essential fatty acid deficiency lowers the activity of the acetylated low density lipoprotein receptor of rat peritoneal macrophages.

We compared phospholipid fatty acid composition, cholesterol ester accumulation, and receptor-mediated binding, internalization, and degradation of acetylated low-density lipoprotein (acetyl-LDL) in cultured peritoneal macrophages from rats fed an essential fatty acid deficient or control diet. The deficient diet increased the 5,8,11-eicosatrienoic acid and decreased the omega 6 fatty acid content of macrophage phospholipid relative to control. The deficient diet did not affect macrophage uptake of [1-14C]oleate; however, it lowered the accumulation of intracellular labelled cholesteroyl oleate to 66% of the control. This effect was attributed to a diminution of the specific binding of acetyl-LDL, and not to acetyl-LDL internalization nor to degradation. The results demonstrate the sensitivity of the acetyl-LDL receptor to changes in its membrane environment, brought about through dietary means.     

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.     

Mouse macrophage elastase. Purification and characterization as a metalloproteinase.

Macrophage elastase was purified from tissue-culture medium conditioned by inflammatory mouse peritoneal macrophages. Characterized as a secreted neutral metalloproteinase, this enzyme was shown to be catalytically and immunochemically distinct from the mouse pancreatic and mouse granulocyte elastases, both of which are serine proteinases. Inhibition profiles, production of nascent N-terminal leucine residues and sodium dodecyl sulphate/polyacrylamide-gel electrophoresis of degraded elastin indicated that macrophage elastase is an endopeptidase, with properties of a metalloproteinase, rather than a serine proteinase. Macrophage elastase was inhibited by alpha 2-macroglobulin, but not by alpha 1-proteinase inhibitor. Macrophage elastase was resolved into three chromatographically distinct forms. The predominant form had mol.wt. 22 000 and was purified 4100-fold. Purification of biosynthetically radiolabelled elastase indicated that this form represented less than 0.5% of the secreted protein of macrophages. Approx. 800% of the starting activity was recovered after purification. Evidence was obtained for an excess of an endogenous inhibitor masking more than 80% of the secreted activity.     

Effect of the proteolysis of low-density serum lipoproteins on their interaction with macrophages

125I-labelled human serum low density lipoproteins (LDL) were incubated with cultured mouse peritoneal macrophages at 37 degrees C, with the following study of cellular uptake and 125I-LDL degradation by measuring the content of TCA-soluble products of LDL hydrolysis in the cultural medium. It was shown that limited pepsin proteolysis of LDL (10%) led to a more effective LDL uptake and degradation by macrophages. The data suggest that enzyme-induced modification of LDL may increase their atherogenicity.     

The interaction of Naegleria fowleri amoebae with murine macrophage cell lines

The present study was undertaken to determine whether murine macrophage cell lines exhibited in vitro amoebicidal activity comparable to that elicited by activated murine peritoneal macrophages. Peritoneal macrophages activated in vivo by bacillus Calmette-Guérin or Propionibacterium acnes demonstrated significant cytolysis of Naegleria fowleri amoebae. The macrophage cell line RAW264.7 also effected cytolysis of amoebae, but to a lesser extent than that elicited by activated peritoneal macrophages. However, the macrophage cell lines, J774A.1 and P388D1, did not exhibit amoebicidal activity. Macrophage conditioned medium prepared from RAW264.7 macrophages mediated cytolysis of L929 tumor cells but had no effect on N. fowleri amoebae. In addition, neither recombinant tumor necrosis factor nor recombinant interleukin-1 exhibited amoebicidal activity. Scanning electron microscopy of co-cultures revealed that N. fowleri bound to activated peritoneal macrophages and RAW264.7 macrophages. These results suggest that RAW264.7 macrophages treated in vitro with lipopolysaccharide are similar to macrophages activated in vivo in that they effect contact-dependent cytolysis of Naegleria fowleri amoebae. The RAW264.7 macrophages are unlike primary macrophage cultures in that they either do not release soluble amoebicidal factors into the conditioned medium or they release insufficient quantities.