Oxidized low density lipoprotein is resistant to cathepsins and accumulates within macrophages

The rate of uptake of oxidized low density lipoprotein (LDL) by mouse peritoneal macrophages is similar to that of acetyl LDL; but only approximately 50% of the internalized oxidized LDL is ultimately degraded, in contrast to the near-complete degradation seen with acetyl LDL. The objectives of this study were to determine if this was due to increased surface binding of oxidized LDL, different uptake pathways for oxidized LDL and acetyl LDL, lysosomal dysfunction caused by oxidized LDL, or resistance of oxidized LDL to hydrolysis by lysosomal proteinases. LDL binding studies at 4 degrees C showed that the increased cell association with oxidized LDL could not be explained by differences in cell-surface binding. Immunofluorescence microscopy confirmed intracellular accumulation of apoB-immunoreactive material in macrophages incubated with oxidized LDL, but not with acetyl LDL. The scavenger receptor ligand polyinosinic acid inhibited both the cell association and degradation of oxidized LDL in macrophages by greater than 75%, suggesting a common uptake pathway for degraded LDL and nondegraded LDL. Studies in THP-1 cells also did not reveal more than one specific uptake pathway for oxidized LDL. LDL derivatized by incubation with oxidized arachidonic acid (under conditions that prevented oxidation of the LDL itself) showed inefficient degradation, similar to oxidized LDL. When macrophages were incubated with oxidized LDL together with acetyl 125I-LDL, the acetyl LDL was degraded normally, excluding lysosomal dysfunction as the explanation for the accumulation of oxidized LDL. Generation of trichloroacetic acid-soluble products from oxidized 125I-LDL by exposure to cathepsins B and D was less than that observed with native 125I-LDL. LDL modified by exposure to reactive products derived from oxidized arachidonic acid was also degraded more slowly than native 125I-LDL by cathepsins. In contrast, acetyl 125I-LDL was degraded more rapidly by cathepsins than native 125I-LDL, and aggregated LDL and malondialdehyde-modified LDL were degraded at the same rate as native 125I-LDL. It is concluded that the intracellular accumulation of oxidized LDL in macrophages can be explained at least in part by the resistance of oxidatively modified apolipoprotein B to cathepsins. This resistance to cathepsins does not appear to be due to aggregation of oxidized LDL, but may be a consequence of modification of apolipoprotein B by lipid peroxidation products.     

Low-density-lipoprotein binding by mast-cell granules. Demonstration of binding of apolipoprotein B to heparin proteoglycan of exocytosed granules.

To study the interaction between low-density lipoprotein (LDL) and granules from rat serosal mast cells in vitro, mast cells were stimulated with the degranulating agent 48/80 to induce exocytosis of the secretory granules. Subsequent incubation of the exocytosed granules with 125I-LDL resulted in binding of the labelled LDL to the granules. When increasing amounts of agent 48/80 were added to mast-cell suspensions, a dose-dependent release of granules was observed and a parallel increase in the amount of 125I-LDL bound to granules resulted. 125I-LDL bound to a single class of high-affinity binding sites on the granules. At saturation, 105 ng of LDL were bound per microgram of granule protein. The lipoprotein binding to mast-cell granules was apolipoprotein(apo)-B + E-specific. Thus 125I-LDL binding to the granules was effectively compared for by LDL (apo-B) or by dimyristoyl phosphatidylcholine vesicles containing apo-E, but not by high-density lipoprotein (HDL3) containing apo-AI as their major protein component. Neutralization by acetylation of the positively charged amino groups of apo-B of LDL or presence of a high ionic strength in the incubation medium prevented LDL from binding to the granules, indicating the presence of ionic interactions between the positively charged amino acids of LDL and negatively charged groups of the granules. It could be demonstrated that LDL bound to the negatively charged heparin proteoglycan of the granules. Thus treatment of granules with heparinase resulted in loss of their ability to bind LDL, and substances known to bind to heparin, such as Toluidine Blue, avidin, lipoprotein lipase, fibronectin and protamine, all effectively competed with LDL for binding to the granules. The results show that LDL is efficiently bound to the heparin proteoglycan component of mast-cell granules once the mast cells are stimulated to release their granules into the extracellular space.     

Modification of low density lipoproteins by secretory granules of rat serosal mast cells

When low density lipoprotein (LDL) is incubated with granules isolated from rat serosal mast cells, a fraction of LDL is bound to the granule heparin proteoglycan. If incubation is continued at 37 degrees C, the bound LDL, but not the unbound LDL, is degraded by granule neutral proteases. In the early stage of incubation, all the granule-bound LDL can be released by 0.3 M NaCl (the "salt-sensitive" fraction of LDL). With time, an increasing proportion of the granule-bound LDL requires 0.5 M NaCl for release (the "salt-resistant" fraction of LDL). Chemical analysis showed that, on average, 20% of the apolipoprotein B LDL was lost from the salt-sensitive fraction and 60% from the salt-resistant fraction, without any change in the composition of the lipid portion. Electron microscopic analysis disclosed large fused particles of LDL (diameters up to 100 nm) in the highly proteolyzed salt-resistant fraction, but no fused particles could be found in the less proteolyzed salt-sensitive fraction. We conclude that both binding and extensive degradation of LDL by mast cell granules is required for fusion of LDL particles on the granule surface. As compared with native LDL, the mast cell granule-modified LDL particles exhibit (i) increased particle size, (ii) selective loss of protein (apoB), (iii) a decrease in hydrated density, and (iv) stronger ionic interaction between apoB and heparin proteoglycan. The particles resemble the extracellular lipid droplets found in atherosclerotic lesions of both man and animals. Modification of LDL by mast cells may therefore provide a model of how these lipid structures are formed.     

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

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

Proteolytic enzymes of mast cell granules degrade low density lipoproteins and promote their granule-mediated uptake by macrophages in vitro

Secretory granules exocytosed from rat serosal mast cells bind low density lipoprotein (LDL), and on being phagocytosed by macrophages, carry the bound LDL into these cells (Kokkonen, J. O., and Kovanen, P. T. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 2287-2291). The binding of LDL to the granules is mediated through interactions between the apolipoprotein B (apoB) component of LDL and the heparin proteoglycan component of the granules. Here we report how degradation of apoB by the neutral proteases of the granules affects the granule-mediated uptake of LDL by cultured mouse macrophages. During incubation of LDL with proteolytically inactive granules, the rate of uptake of LDL by macrophages increased by 10-fold; whereas during incubation with proteolytically active granules, it increased by 50-fold, the increase in the rate of uptake during proteolysis correlating with the degree of apoB degradation. The 5-fold greater capacity of the proteolytically active granules to enhance the uptake of LDL resulted from their greater capacity to bind LDL, and consequently, to carry it into the macrophages. Electron microscopic analysis of LDL bound to the proteolytically active granules disclosed large spherical particles of fused LDL. The diameters of the granule-bound particles ranged up to 90 nm compared with an average diameter of 22 nm for both native LDL and the LDL bound to proteolytically inactive granules. The results show that granule proteases, by inducing fusion of granule-bound LDL, increase the amount of LDL bound per unit weight of granule heparin proteoglycan. Hence, the two components of mast cell granules, the proteases and the heparin proteoglycan, act in concert to promote the uptake of LDL by macrophages in vitro.     

Degradation of the heparin matrix of mast cell granules by cultured fibroblasts

The ability of cultured rat fibroblasts to phagocytose rat peritoneal mast cell granules has been previously demonstrated by light and electron microscopy. To determine if the heparin matrix of ingested granules could be degraded by fibroblasts after phagocytosis, the heparin within peritoneal mast cells was labeled with [35S]sulfate in vivo. The 35S-labeled rat peritoneal mast cells were purified and their granules were isolated and shown to contain [35S]heparin proteoglycan. Incubation of [35S]heparin proteoglycan-containing granules with cultured rat fibroblasts revealed internalization of radioactivity by the fibroblasts over the first 24 hr consistent with phagocytosis of the granules by these fibroblasts. The [35S]heparin proteoglycan internalized by the fibroblasts was shown to decrease in size over 72 hr indicating that the fibroblasts were capable of degrading the heparin within the ingested granules. Degradation of [35S]heparin proteoglycan within the fibroblast was accompanied by the appearance of free [35S]sulfate in the extracellular compartment. Similar findings were obtained using cultured human fibroblasts. These data demonstrate for the first time that both rat and human fibroblasts are not only capable of ingesting mast cell granules but also of degrading mast cell granule heparin proteoglycan. This ingestion and degradation of mast cell granules by fibroblasts may represent an important mechanism in the regulation of the biologic expression of heparin and other granule-associated mediators in immediate hypersensitivity reactions.     

Free fatty acids activate a high-affinity saturable pathway for degradation of low-density lipoproteins in fibroblasts from a subject homozygous for familial hypercholesterolemia.

This paper describes a mechanism for degradation of low-density lipoprotein (LDL) in fibroblasts unable to synthesize the LDL receptor. In this cell line, long-chain free fatty acids (FFA) activated 125I-LDL uptake; unsaturated FFA were the most efficient. The first step of this pathway was the binding of LDL apoB to a single class of sites on the plasma membrane and was reversible in the presence of greater than or equal to 10 mM suramin. Binding equilibrium was achieved after a 60-90-min incubation at 37 degrees C with 1 mM oleate; under these conditions, the apparent Kd for 125I-LDL binding was 12.3 micrograms/mL. Both cholesterol-rich (LDL and beta-VLDL) and triglyceride-rich (VLDL) lipoproteins, but not apoE-free HDL, efficiently competed with 125I-LDL for this FFA-induced binding site. After LDL bound to the cell surface, they were internalized and delivered to lysosomes; chloroquine inhibited subsequent proteolysis of LDL and thereby increased the cellular content of the particles. A physiological oleate to albumin molar ratio, i.e., 1:1 (25 microM oleate and 2 mg/mL albumin), was sufficient to significantly (p less than 0.01) activate all three steps of this alternate pathway: for example, 644 +/- 217 (25 microM oleate) versus 33 +/- 57 (no oleate) ng of LDL/mg of cell protein was degraded after incubation (2 h, 37 degrees C) with 50 micrograms/mL 125I-LDL. We speculate that this pathway could contribute to the clearance of both chylomicron remnants and LDL.     

Low density lipoprotein degradation by secretory granules of rat mast cells. Sequential degradation of apolipoprotein B by granule chymase and carboxypeptidase A

The secretory granules of rat serosal mast cells are able efficiently to degrade the apolipoprotein B component of low density lipoproteins (LDL) Kokkonen, J. O., and Kovanen, P. T. (1985) J. Biol. Chem. 260, 14756-14763). The granules are known to contain two neutral proteases with complementary specificities: a chymotrypsin-like endopeptidase called chymase, and an exopeptidase, the granule carboxypeptidase A. The role of this enzyme pair in the proteolytic degradation of LDL was studied with the aid of specific enzyme inhibitors. Incubation of LDL with intact granules (both enzymes active) led to the formation of numerous low molecular weight peptides and the liberation of free amino acids, most of which (95%) were aromatic (Phe, Tyr, Trp) or branched-chain aliphatic (Leu, Ile, Val). Selective inhibition of granule carboxypeptidase A (leaving chymase active) blocked the liberation of free amino acids, but left the formation of peptides uninhibited. On the other hand, selective inhibition of granule chymase (leaving carboxypeptidase A active) totally abolished the proteolytic degradation of LDL. The results are consistent with a model according to which the proteolytic degradation of LDL by mast cell granules results from coordinated action of the two granule-bound enzymes, whereby the chymase first cleaves peptides from the apolipoprotein B of LDL, and thereafter the carboxypeptidase A cleaves amino acids from the peptides formed.     

Low density lipoprotein receptor activity in homozygous familial hypercholesterolemia fibroblasts

We have identified specific low affinity low density lipoprotein (LDL) receptors in skin fibroblasts from two patients previously classified as having LDL receptor-negative homozygous familial hypercholesterolemia (FHC). Km and maximum capacity for cell-associated and degraded 125I-LDL were determined by two independent methods, a traditional technique in which increasing amounts of 125I-LDL were added until receptor saturation was achieved and a new technique in which the displacement of a small amount of 125I-LDL tracer was observed during the addition of variable amounts of unlabeled LDL. The Km for specific cell-associated 125I-LDL in FHC cells was 3.5-7.3 times that of normal cells and the maximum specific capacity was reduced to 11% of normal. Thus, some FHC cells have reduced affinity as well as reduced capacity for LDL. The FHC cell receptors share many but not all properties of the normal skin fibroblast LDL receptor. Specific degradation of bound 125I-LDL occurred concomitantly with LDL binding and was greatly reduced by the addition of chloroquine, an inhibitor of lysosomal function. Preincubation of FHC cells with cholesterol or LDL resulted in significant suppression of receptor function. Modification of lysine residues of LDL abolished receptor activity in both normal and FHC cells. Treatment of FHC cells with compactin, a cholesterol synthesis inhibitor, resulted in significant increases in specific 125I-LDL binding and degradation compared to FHC cells without compactin treatment. Normal cells also showed increases in 125I-LDL binding and degradation with compactin treatment, but the mean percentage increase in specific 125I-LDL degradation was significantly greater in FHC cells (strain GM 2000, 160 +/- 18%) than in normal cells (29 +/- 8%).     

Accumulation of low density lipoproteins in stimulated rat serosal mast cells during recovery from degranulation

Stimulation of rat serosal mast cells in vitro with compound 48/80, a degranulating agent, resulted in an immediate increase in binding of low density lipoproteins (LDL) to the stimulated mast cells. The increase in binding was dose-dependent and closely followed the increase in histamine release, i.e., the exocytosis of mast cell granules. It could be demonstrated that the LDL were bound to exocytosed secretory granules which remained cell-associated. During the recovery period the granule-bound LDL were internalized by the mast cells along with the granules. A single stimulation of mast cells rendered their cytoplasm to be filled with granular material showing positive staining for both apoB and neutral lipid. This change was accompanied by a 30-fold increase in the cellular content of cholesteryl esters. Thus, rat serosal mast cells possess a specific mechanism for uptake of LDL that is activated by stimuli that lead to degranulation, the result being massive uptake of LDL by stimulated mast cells during recovery from degranulation.     

Stimulation of LDL receptor activity in Hep-G2 cells by a serum factor(s)

The regulation of low-density lipoprotein (LDL) receptor activity in the human hepatoma cell line Hep-G2 by serum components was examined. Incubation of dense monolayers of Hep-G2 cells with fresh medium containing 10% fetal calf serum (FM) produced a time-dependent increase in LDL receptor activity. Uptake and degradation of 125I-LDL was stimulated two- to four-fold, as compared with that of Hep-G2 cells cultured in the same media in which they had been grown to confluence (CM); the maximal 125I-LDL uptake plus degradation increased from 0.2 microgram/mg cell protein/4 h to 0.8 microgram/mg cell protein/4 h. In addition, a two-fold increase in cell surface binding of 125I-LDL to Hep-G2 cells was observed when binding was measured at 4 degrees C. There was no change in the "apparent" Kd. The stimulation of LDL receptor activity was suppressed in a concentration-dependent manner by the addition of cholesterol, as LDL, to the cell medium. In contrast to the stimulation of LDL receptor activity, FM did not affect the uptake or degradation of 125I-asialoorosomucoid. Addition of FM increased the protein content per dish, and DNA synthesis was stimulated approximately five-fold, as measured by [3H]thymidine incorporation into DNA; however, the cell number did not change. Cellular cholesterol biosynthesis was also stimulated by FM; [14C]acetate incorporation into unesterified and esterified cholesterol was increased approximately five-fold. Incubation of Hep-G2 cells with high-density lipoproteins (200 micrograms protein/ml) or albumin (8.0 mg/ml) in the absence of the serum factor did not significantly increase the total processed 125I-LDL. Stimulation of LDL receptor activity was dependent on a heat-stable, nondialyzable serum component that eluted in the inclusion volume of a Sephadex G-75 column. Uptake of 125I-LDL by confluent monolayers of human skin fibroblasts was not changed by incubation with FM or by incubation with Hep-G2 conditioned medium. Taken together, these data demonstrate that LDL receptor activity in Hep-G2 cells is stimulated by a serum component. Furthermore, this serum factor shows some specificity for the LDL receptor pathway in liver-derived Hep-G2 cells.     

Oleic,linoleic and linolenic acids enhance receptor-mediated uptake of low density lipoproteins in Hep-G2 cells

In the present study, the binding, internalization and degradation of low-density lipoprotein (LDL) was investigated in Hep-G2 cells treated with 18:0, 18:1, 18:2 and 18:3. In non-treated control cells, the surface binding (heparin-releasable) of 125I-LDL progressed in a saturable manner reaching equilibrium within 2 h, amounting 24.0 +/- 1.1, 29.5 +/- 1.3 and 31.4 +/- 2.8 (ng/mg cell protein) at 1, 2 and 4 h, respectively. The cells rapidly internalized 125I-LDL reaching a plateau at 2 h (72.4 +/- 6.3/1 h, 96.7 +/- 4.3/2 h and 100.8 +/- 4.6 ng/mg protein/4 h, respectively). The degradation of internalized LDL progressed slowly during the first hour of incubation reflecting the time required to an uptake and delivery of LDL to the cellular lysosomes. The levels of degraded LDL discharged into the medium then increased rapidly in a linear manner after the initial lag period, amounting 16.8 +/- 1.2, 51.8 +/- 7.0 and 118.2 +/- 5.7 ng/mg protein at 1, 2 and 4 h, respectively. The treatment of cells with of 1.0 mM of fatty acids for 4 h resulted in a significant increase in the surface binding of 125I-LDL compared to the control (34.9 +/- 3.0), but it was significantly lower in cells exposed to 18:0 (48.2 +/- 2.0) than to 18:1 (56.8 +/- 5.1), 18:2 (56.0 +/- 3.5) and 18:3 (57.8 +/- 6.0 ng/mg protein/4 h) (P < 0.05). The levels of degraded LDL in cells remained nearly the same regardless of fatty acid treatments, but degraded LDL levels in the medium were much higher in cells exposed to 18:1 (167.6 +/- 10.1), 18:2 (159.8 +/- 7.7) and 18:3 (165.1 +/- 14.7) than to 18:0 (142.1 +/- 8.4) and the control (121.2 +/- 3.4 ng/mg protein/4 h) (P < 0.05). The present finding that 18:1 is equally effective in enhancing the receptor-mediated LDL uptake and its degradation as those of 18:2 and 18:3 suggests that the major action of 18:1 in lowering LDL-cholesterol levels also involves an increased clearance of LDL via hepatic LDL-receptors.     

Effect of insulin on low-density-lipoprotein metabolism in human lymphocytes in vitro.

The metabolism of low-density lipoproteins (LDL) in vitro in the presence of insulin was studied in freshly isolated human peripheral-blood lymphocytes. Insulin appeared to decrease the binding affinity of 125I-LDL to its cell-surface receptor, without any change in apparent Vmax or in the number of LDL receptors. As a consequence, the absolute amounts of 125I-LDL internalized and degraded were lower in the presence of insulin than in its abscence, although the fraction of internalized 125I-LDL degraded in either instance was quite similar. 3-Hydroxy-3-methylglutaryl-CoA reductase activity, and hence cholesterol synthesis, were stimulated by insulin. This effect of insulin was independent of the inhibitory effect of LDL on cholesterol synthesis. At the same time, acid cholesterol esterase and acyl-CoA: cholesterol O-acetyltransferase activities were lower in cells incubated with insulin than in controls. The net effect of these metabolic alterations seems to be that cells accumulate greater quantities of free and esterified cholesterol when treated with insulin.     

Effects of hypoxia on cholesterol metabolism in human monocyte-derived macrophages

We assessed the metabolism of low density lipoprotein (LDL) of human monocyte-derived macrophages under hypoxia. The specific binding and association of 125I-labeled LDL (125I-LDL) were not changed under hypoxia compared to normoxia. However, the degradation of 125I-LDL under hypoxia decreased to 60%. The rate of cholesterol esterification under hypoxia was 2-fold greater on incubation with LDL or 25-hydroxycholesterol. The cellular cholesteryl ester content was also greater under hypoxia on incubation with LDL. Secretion of apolipoprotein E into the medium was not altered under hypoxia, suggesting that apolipoprotein E independent cholesterol efflux may be reduced under hypoxia. Thus, hypoxia affects the intracellular metabolism of LDL, stimulates cholesterol esterification, and enhances cholesteryl ester accumulation in macrophages. Hypoxia is one of the important factors modifying the cellular lipid metabolism in arterial wall.     

Phorbol esters inhibit the binding of low-density lipoproteins (LDL) to U-937 monocytelike cells

The present study demonstrates that U-937 monocytelike human cells possess specific LDL receptors. 125I-LDL binds at 4 degrees C on the cell surface. The bound molecules are releasable by heparin. The reaction requires Ca2+ and the binding sites are sensitive to proteolysis. Unlabeled LDL compete with 125I-LDL, whereas HDL are ineffective. At 37 degrees C, LDL are internalized and degraded by a chloroquine-sensitive pathway. Tumor-promoting phorbol esters inhibit the binding of 125I-LDL to its receptor on U-937 cells. This inhibition exhibits temperature, time, and concentration dependence. At 37 degrees C, inhibition is 50% at 5 X 10(-9) M of TPA. After removal of phorbol esters, treated cells recover their 125I-LDL-binding activity in 60 min. The inhibitory activities of various phorbol esters are proportional to their tumor-promoting activities. Inhibition appears to be due to a reduction in the number of available LDL receptors rather than a decrease in receptor affinity.     

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.     

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

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

Defective receptor binding of low density lipoprotein from pigs possessing mutant apolipoprotein B alleles

We previously identified a defect in the in vivo catabolism of low density lipoprotein (LDL) from hypercholesterolemic pigs carrying a mutant apolipoprotein B allele. In the present studies, we examined the in vitro metabolism of mutant LDL in cultured pig fibroblasts. A 3-fold higher concentration of mutant LDL (compared to control) was needed to displace 50% of control 125I-LDL binding. Mutant LDL had a 6-fold higher dissociation constant than control LDL. Scatchard plots of the binding data were concave upward, suggesting multiple classes of binding sites or negative cooperativity. The mutant LDL degradation rate was reduced by 40%; this decrease could be attributed to a dense LDL subspecies. Mutant and control buoyant LDL subspecies were degraded more slowly than the corresponding dense LDL subspecies. Together, these studies show that diminished LDL receptor binding can result from mutations in apolipoprotein B and from changes in the lipid composition of LDL particles.     

A simple binding assay for the determination of low-density lipoprotein receptors in cell homogenates

A convenient binding assay has been developed for the determination of low-density lipoprotein (LDL) receptors in homogenates of cultured and freshly-isolated normal and malignant human cells. Cell homogenates were incubated with 125I-labeled LDL and the ligand bound to the homogenate particulates was separated from the unbound ligand by filtration. When the particulates of the homogenates were subsequently incubated with heparin, a fraction of the bound 125I-LDL was released. Previous studies on intact cells have shown that heparin exclusively releases LDL bound to its cell surface receptor. The heparin-sensitive binding of 125I-LDL to cell homogenate particulates represents LDL bound to its cell surface receptor as judged from the following criteria: (a) it was quantitatively similar to the heparin-sensitive binding of 125I-LDL to intact cells, (b) it showed a direct correlation to the receptor-mediated degradation of 125I-LDL by intact cells, (c) no heparin-sensitive binding could be detected in homogenates prepared from normal erythrocytes or from cultured fibroblasts from a patient with homozygous familial hypercholesterolemia (two types of cell lacking LDL receptors), (d) it was dependent on calcium and inhibited by EDTA, (e) it was susceptible to treatment with pronase, and (f) it was heat-labile. The assay developed should be of value in determining the number of LDL receptors in tissues, since it is far less time-consuming and requires less material than currently available methods.     

The presence of ANP in rat peritoneal mast cells

Atrial natriuretic peptide （ANP） is an important component of the natriuretic peptide system. A great role in many regulatory systems is played by mast cells. Meanwhile involvement of these cells in ANP activity is poorly studied. In this work, we have shown the presence of ANP in rat peritoneal mast cells. Pure fraction of mast cells was obtained by separation of rat peritoneal cells on a Percoll density gradient. By Westem blotting, two ANP-immunoreactive proteins of molecular masses of 2.5 kDa and 16.9 kDa were detected in lysates from these mast cells. Electron microscope immunogold labeling has revealed the presence of ANP-immunoreactive material in storage, secreting and released granules of mast cells. Our findings indicate the rat peritoneal mast cells to contain both ANP prohormone and ANP. These both peptides are located in mast cell secretory granules and released by mechanism of degranulation. It is discussed that many mast cell functions might be due to production of natriuretic peptides by these cells.