Purification of an apolipoprotein A binding protein from mouse adipose cells

Apolipoprotein A-II, HDL metabolism and atherosclerosis

Apolipoprotein (Apo) A-I and apo A-II are the major apolipoproteins of HDL. It is clearly demonstrated that there are inverse relationships between HDL-cholesterol and apo A-I plasma levels and the risk of coronary heart disease (CHD) in the general population. On the other hand, it is still not clearly demonstrated whether apo A-II plasma levels are associated with CHD risk. A recent prospective epidemiological (PRIME) study suggests that Lp A-I (HDL containing apo A-I but not apo A-II) and Lp A-I:A-II (HDL containing apo A-I and apo A-II) were both reduced in survivors of myocardial infarction, suggesting that both particles are risk markers of CHD. Apo A-II and Lp A-I:A-II plasma levels should be rather related to apo A-II production rate than to apo A-II catabolism. Mice transgenic for both human apo A-I and apo A-II are less protected against atherosclerosis development than mice transgenic for human apo A-I only, but the results of the effects of trangenesis of human apo A-II (in the absence of a co-transgenesis of human apo A-I) are controversial. It is highly suggested that HDL reduce CHD risk by promoting the transfer of peripherical free cholesterol to the liver through the so-called 'reverse cholesterol transfer'. Apo A-II modulates different steps of HDL metabolism and therefore probably alters reverse cholesterol transport. Nevertheless, some effects of apo A-II on intermediate HDL metabolism might improve reverse cholesterol transport and might reduce atherosclerosis development while some other effects might be deleterious. In different in vitro models of cell cultures, Lp A-I:A-II induce either a lower or a similar cellular cholesterol efflux (the first step of reverse cholesterol transport) than Lp A-I. Results depend on numerous factors such as cultured cell types and experimental conditions. Furthermore, the effects of apo A-II on HDL metabolism, beyond cellular cholesterol efflux, are also complex and controversial: apo A-II may inhibit lecithin-cholesterol acyltransferase (LCAT) (potential deleterious effect) and cholesteryl-ester-transfer protein (CETP) (potential beneficial effect) activities, but may increase the hepatic lipase (HL) activity (potential beneficial effect). Apo A-II may also inhibit the hepatic cholesteryl uptake from HDL (potential deleterious effect) probably through the SR-BI depending pathway. Therefore, in terms of atherogenesis, apo A-II alters the intermediate HDL metabolism in opposing ways by increasing (LCAT, SR-BI) or decreasing (HL, CETP) the atherogenicity of lipid metabolism. Effects of apo A-II on atherogenesis are controversial in humans and in transgenic animals and probably depend on the complex effects of apo A-II on these different intermediate metabolic steps which are in weak equilibrium with each other and which can be modified by both endogenous and environmental factors. It can be suggested that apo A-II is not a strong determinant of lipid metabolism, but is rather a modulator of reverse cholesterol transport.

Identification of a GPI-anchored type HDL-binding protein on human macrophages

To identify the HDL3-binding proteins on human macrophages, we examined the involvement of GPI-anchored protein in the binding of HDL3, and tried to purify HDL3-binding protein. From membrane fractions of macrophages, we obtained 80- and 130-kDa HDL3-binding proteins by ligand blotting. Treatment of macrophages with phosphatidylinositol-specific phospholipase C (PI-PLC) significantly decreased the specific HDL3-binding in a dose-dependent manner. Furthermore, treatment with mannosamine, which blocks GPI-anchor formation, decreased specific HDL3-binding in a dose-dependent manner. PI-PLC treatment released from the cells the proteins with an M(r) of 80 kDa, which could also bind HDL3. PI-PLC as well as mannosamine treatment markedly reduced cholesterol efflux from macrophages in association with the decreased HDL-binding. Using HDL3-affinity chromatography, we purified 80-kDa GPI-anchored type HDL3-binding protein. In summary, we demonstrate the implication of 80-kDa GPI-anchored protein in the binding of HDL3 to human macrophages, which might have some role in reverse cholesterol transport.

High-density lipoprotein subclasses and apolipoprotein A-I

Epidemiological and clinical studies showing an association between decreased concentrations of high-density lipoprotein (HDL) cholesterol and increased risk of premature coronary artery disease have generated interest in the mechanism through which HDL prevents atherosclerosis. Recognition of the importance of apolipoproteins (apo(s)) has led to the separation of HDL into subpopulations according to their apolipoprotein composition. It is now recognised that HDL comprises at least two types of apo A-I-containing lipoproteins: LpA-I:A-II containing both apo A-I and apo A-II and LpA-I containing apo A-I but not apo A-II. A majority of studies support the fact that LpA-I is more effective than LpA-I:A-II in promoting cellular cholesterol efflux, the first step in reverse cholesterol transport. Studies in transgenic animals have revealed that the gene transfer of human apo A-I in mice and rabbits increases plasma apo A-I and HDL cholesterol levels and particularly apo A-I-rich HDL particle concentrations, leading to inhibition of the development of dietary or genetically induced atherosclerosis. On the other hand, gene transfer of apo A-II in mice gives conflicting results. The conclusions of some experiments indicate either an atherogenic, or a poorly anti-atherogenic, or even a strongly anti-atherogenic role for apo A-II and for apo A-II-rich HDL lipoproteins. Although these experimental results have been obtained in animals, they confirm previous studies obtained in human clinical studies, indicating that apo A-I-rich HDL (tested as LpA-I in clinical studies) are generally strong plasma markers of atherosclerosis protection while the clinical significance of apo A-I + apo A-II HDL (tested as LpA-I:A-II in clinical studies) is more controversial. The introduction of immunological methods to measure LpA-I and LpA-I:A-II levels in blood make large-scale studies feasible to confirm the clinical significance of these HDL particles.

Elevation of cyclic AMP by iloprost and prostaglandin E1 increases cholesterol efflux and the binding capacity for high-density lipoproteins in human fibroblasts

Elevation of cAMP concurrently enhances cholesterol efflux and binding of HDL3 in human skin fibroblasts. These effects were observed regardless of the route by which cAMP levels were increased. Cholesterol efflux and HDL3 binding were stimulated by the cAMP analogue CPT-cAMP, the adenylate cyclase activator forskolin, and by iloprost and prostaglandin E1 (PGE1) (which elevate cAMP via receptor-mediated processes). Dideoxyforskolin and PGF2alpha, which do not elevate cAMP, altered neither cholesterol efflux nor binding of HDL3. Inhibition of protein kinase A with H89 abolished the stimulatory effects of CPT-cAMP and iloprost, suggesting protein kinase A involvement in enhancing cholesterol efflux and HDL3 binding. Enhancement of HDL3 binding by iloprost was due to increased maximal capacity of the cells to bind HDL3, i.e., a greater number of HDL3 binding sites. A positive correlation was demonstrated between changes in HDL3 binding and changes in [3H]cholesterol efflux. The data are compatible with a model in which cholesterol efflux is partially dependent upon HDL binding to the cells. A short exposure to iloprost was sufficient to stimulate cAMP synthesis, triggering a chain of events leading to increased HDL3 binding and [3H]cholesterol efflux 20-24 h later. We conclude that both cholesterol efflux and the maximal capacity for HDL3 binding are enhanced by elevation of cellular cAMP. Cyclic AMP-elevating prostanoids could initiate these responses in vivo.

Conformation of apolipoprotein AI in reconstituted lipoprotein particles and particle-membrane interaction: effect of cholesterol

Discoidal recombinant high density lipoproteins (rHDL) of apolipoprotein AI (apoAI) and palmitoyloleoylphosphatidylcholine (POPC), with or without cholesterol, were prepared by cholate dialysis. By gel filtration, rHDL containing 2-4 (Lp2, Lp3 and Lp4) apoAI molecules/particle were obtained. The ApoAI conformation in these rHDL was investigated by tryptophan fluorescence, denaturation with guanidine HCl, and immunoreactivity with two monoclonal antibodies recognizing epitopes in the N-terminal and central domains. Data show that apoAI conformation is highly dependent on particle size as well as on cholesterol. The ability of rHDL to interact with lipid bilayer was studied by measuring leakage induction on POPC and POPC/cholesterol vesicles loaded with terbium/dipicolinic acid. Among the cholesterol-free rHDL, the most efficient ones were the smallest Lp2. Leakage induction on POPC vesicles is dramatically decreased by the presence of cholesterol in Lp2 and Lp3. All the rHDL, but specially those containing cholesterol, induced more leakage on the POPC/cholesterol than on the POPC vesicles. These results suggest that in small cholesterol-poor particles, apoAI could have a conformation determining a high affinity for membranes, which could facilitate cholesterol efflux. After cholesterol enrichment, a conformational change in apoAI could decrease the affinity for membranes allowing the lipoprotein release.

High-density-lipoprotein subfraction 3 interaction with glycosylphosphatidylinositol-anchored proteins

To elucidate further the binding of high-density-lipoprotein subfraction 3 (HDL3) to cells, the involvement of glycosylphosphatidylinositol-anchored proteins (GPI-proteins) was studied. Treatment of cultured cells, such as fibroblasts or SK-MES-1 cells, with a phosphatidylinositol-specific phospholipase C (PI-PLC) significantly decreases specific HDL3 binding. Moreover, PI-PLC treatment of cultured cells or cellular plasma membrane fractions results in releasing proteins. These proteins have a soluble form and can also bind HDL3, as revealed by ligand blotting experiments with HDL3. In order to obtain enriched GPI-proteins, we used a detergent-free purification method to prepare a caveolar membrane fraction. In the caveolar fraction, we obtained, by ligand blotting experiments, the enrichment of two HDL3-binding proteins with molecular masses of 120 and 80 kDa. These proteins were also revealed in a plasma membrane preparation with two other proteins, with molecular masses of 150 and 104 kDa, and were sensitive to PI-PLC treatment. Electron microscopy also showed the binding of Au-labelled HDL3 inside the caveolar membrane invaginations. In SK-MES-1 cells, HDL3 are internalized into a particular structure, resulting in the accumulation and concentration of such specific membrane domains. To sum up, a demonstration has been made of the implication of GPI-proteins as well as caveolae in the binding of HDL3 to cells.

Phosphoproteins regulated by the interaction of high-density lipoprotein with human skin fibroblasts

Interaction of HDL with cells activates protein kinase C (PKC), a process that may be important in stimulating efflux of excess cellular cholesterol. Here we report that HDL treatment of cholesterol-loaded fibroblasts increases 32P labeling of three acidic phosphoproteins. These phosphoproteins, called pp80, pp27, and pp18 based on apparent M(r) in kD, were also phosphorylated by acute treatment of cells with phorbol myristate acetate, suggesting that they are regulated in response to PKC activation. The HDL-stimulated phosphorylation of pp80 and pp18 was significant after only 30 seconds and was sustained for at least 30 and 120 minutes, respectively, while increased phosphorylation of pp27 was transient, reaching a maximum at 10 minutes. Both pp27 and pp18 were phosphorylated on serine/threonine residues, whereas pp80 was phosphorylated on serine/threonine and tyrosine residues. Immunoprecipitation studies suggested that pp80 is the myristoylated alanine-rich C kinase substrate protein, but the identities of pp27 and pp18 are unknown. HDL and trypsin-digested HDL stimulated phosphorylation of pp80 and pp27, while purified apoA-I, apoA-II, or apoE had no stimulatory effects, indicating that the active component in HDL was trypsin resistant and unlikely to be an apolipoprotein. Conversely, HDL, apoA-I, apoA-II, and apoE all stimulated pp18 phosphorylation, while trypsin-digested HDL had less effect, consistent with pp18's being responsive to HDL apolipoproteins. Treatment of cholesterol-depleted cells with apoA-I also stimulated phosphorylation of pp18, but only transiently. These results suggest that HDL interaction with cells activates diverse PKC-mediated pathways that target different phosphoproteins. Of these three phosphoproteins, only pp18 has a phosphorylation response consistent with its being involved in apolipoprotein-mediated lipid transport.

Reverse cholesterol transport--a review of the process and its clinical implications

OBJECTIVES

This review article will summarize the current knowledge surrounding the reverse cholesterol transport system; the process, the effect of mutations in genes coding for proteins which function in the system, and the possible clinical implications of these alterations.

RESULTS

High-density lipoprotein-cholesterol (HDL-C) concentration is a marker for the reverse cholesterol transport (RCT) system, whereby cholesterol is returned from peripheral cells to the liver for reuse or excretion in the bile. Increased HDL-C concentrations are generally accepted to be protective against the future development of atherosclerosis and coronary artery disease (CAD), but recent evidence has indicated that the underlying cause of the increased HDL-C may affect whether it is protective or detrimental. The major steps in the RCT pathway are the efflux of free cholesterol from cells and binding by pre-beta HDL, esterification of HDL-bound cholesterol by lecithin cholesterol acyl transferase (LCAT), cholesteryl ester transfer protein (CETP) mediated exchange of cholesteryl ester and triglycerides between HDL and apo B-containing particles, and hepatic lipase (HL) mediated uptake of cholesterol and triglycerides by the liver. Mutations in proteins active in the RCT pathway can shed light on the functions and control of the various steps in the system. LCAT deficiency, leading to greatly reduced HDL and fish eye disease, is not usually associated with increased risk of CAD. Several new mutations in LCAT have recently been reported, however, which do result in CAD. Mutations leading to reduced CETP activity result in less CE being directed into apo-B containing particles and more remaining in the HDL. This has been associated with increased HDL-C concentrations. The generally accepted hypothesis that reduced CETP activity leads to reduced CAD risk has been challenged by a number of recent publications, and has become an area of active investigation. Mutations leading to reduced HL activity are rare occurrences. To date, all have been associated with increased HDL-C concentrations and CAD.

CONCLUSION

The development of techniques to identify and characterize the functional significance of mutations in proteins involved in RCT will aid in the understanding of the mechanisms and control of this pathway.

Apolipoprotein AIV of human interstitial fluid is associated with apolipoprotein AI-containing but not with AII-containing particles

Apolipoproteins and lipoprotein particles from human interstitial fluid and plasma were analyzed. The interstitial fluid was enriched in apolipoproteins AI, AII, and AIV compared with apo B, apo CIII, and apo E, LpAI was found to contain apo AIV which was absent from LpAI: AII. Moreover, the bulk of lecithin-cholesterol acyl-transferase was present in LpAI. The concentration range of these particles was in agreement with those required in vitro for cholesterol efflux. Thus the interstitial fluid contains particles in which two agonists but no antagonists of cholesterol efflux are associated with lecithin-cholesterol acyltransferase activity. This supports apolipoprotein AI- and/or AIV-containing particles playing a critical role in the first step of reverse cholesterol transport.

Elevation of cyclic AMP in human skin fibroblasts results in increased capacity for HDL binding

Pre-incubation of cultured human skin fibroblasts, lung fibroblasts and vascular smooth muscle cells, for 24 h with cAMP-elevating agents resulted in a significant increase (40-60%) of the cells' capacity to bind HDL. The increase was due to enhancement of the maximal binding capacity of a high affinity saturable site which binds HDL in preference to LDL. The effect was dependent upon the concentration of the cAMP-elevating agents and required more than 4 h to become evident. Cyclic AMP-mediated elevation of HDL binding occurred in cells with access to an exogenous source of cholesterol, which could be the physiological donor LDL or non-lipoprotein in origin. The observed effects were not subsequent to changes in cellular balance of cholesterol to cholesterol ester and were not due to inhibition of cellular proliferation.

Identification of four ovarian receptor proteins that bind vitellogenin but not other homologous plasma lipoproteins in the rainbow trout, Oncorhynchus mykiss

Membrane proteins from ovarian follicles, testis and somatic tissues of rainbow trout, Oncorhynchus mykiss, were extracted by ultracentrifugation, separated on sodium dodecyl sulphate gels and isolated on polyvinyl difluoride membranes. Vitellogenin receptor proteins were visualized using protein staining and hybridisation with 125I-vitellogenin. Four follicle-membrane proteins, with molecular masses of 220, 210, 110 and 100 kDa, showed a strong affinity for vitellogenin and were specific to the ovary. Other homologous lipoproteins (very low density lipoprotein, low density lipoprotein and high density lipoprotein) had a very limited ability to displace 125I-vitellogenin from its receptor, indicating that the ovarian receptor proteins were fairly specific for vitellogenin. Proteins with an affinity for very low density lipoprotein and low density lipoprotein were visualised in liver, spleen and muscle, eluting on sodium dodecyl sulphate gels with molecular masses of about 150 kDa. Peptides generated from trypsin digests of the receptor proteins with a high affinity for vitellogenin showed sequence homology with receptors in the lipoprotein family, including a sequence that is believed to act as the internalisation signal [Phe-Asp-Phe-Tyr-] and a sequence identity with the recently characterised chicken vitellogenin/very low density lipoprotein receptor [Ser-Glu-Leu-Tyr-Glu-Pro-Ala-]. Together, the ligand blotting and peptide sequence data support the contention that the four ovarian membrane proteins isolated are receptor proteins specific for vitellogenin and they do not bind other plasma lipoproteins to any significant degree.

Identification of a sequence of apolipoprotein A-I associated with the efflux of intracellular cholesterol to human serum and apolipoprotein A-I containing particles

The effect of monoclonal antibodies against apolipoprotein A-I (apoA-I) on the efflux of intracellular and plasma membrane cholesterol from HepG2 cells to human serum, high-density lipoprotein (HDL), apoA-I, and apoA-I/phosphatidylcholine complex (apoA-I/PC) was studied. Fab fragments of two monoclonal antibodies, AI-3 (residues 140-147) and Al-4.2 (residues 149-150), inhibited the efflux of intracellular cholesterol to serum in a dose-dependent manner. In combination, these antibodies were twice as effective than when used alone. None of the antibodies tested inhibited efflux of the plasma membrane cholesterol. When different types of acceptors were compared for their ability to promote intracellular cholesterol efflux, they were effective in the following order: serum > HDL > apoA-I/PC > pure apoA-I. Antibody AI-3 inhibited efflux of intracellular cholesterol to serum, HDL, and pure apoA-I, but not to apoA-I/PC. Antibody AI-4.2 inhibited efflux to serum, apoA-I/PC, and pure apoA-I, but not to HDL. An explanation for this is that antibody AI-4.2 reacts poorly with isolated alpha-HDL in an immunoprecipitation assay and has higher affinity for pre beta 2-HDL and pre beta 3-HDL particles than antibody AI-3 in nondenaturing two-dimensional electrophoresis. In conclusion, we have demonstrated that a region of apoA-I within or adjacent to residues 140-150 determines the ability of apoA-I to promote intracellular cholesterol efflux.

Glucocorticoids upregulate high-affinity, high-density lipoprotein binding sites in rat hepatocytes

Glucocorticoid hormones (GL) regulate high-density lipoprotein (HDL) plasma concentrations by increasing synthesis and secretion of HDL by the liver. However, little is known about the effect of GL on the uptake and processing of HDL by hepatocytes (HEP). To investigate this question, we studied the effects of dexamethasone (DEX) on the expression of high-affinity HDL-binding sites via the specific binding and internalization of iodine-labeled apolipoprotein E (apo E)-free HDL3 in a culture of rat HEP. Specific binding and internalization of HDL3 decreased by 60% in cells cultured in the absence of DEX for 48 hours. At concentrations of 10(-7) and 10(-5) mol/L, DEX prevented the decrease, maintaining specific binding and internalization versus the control level (at 24 hours). HDL-binding sites with a Kd of 20 micrograms/mL were revealed on the surface of cultured HEP. HEP demonstrated a greater binding capacity in the presence of DEX at concentrations of 10(-7) and 10(-5) mol/L (125 v 45 ng/mg cell protein). The effect of the hormone has demonstrated to be dose-dependent at concentrations between 10(-9) and 10(-7) mol/L, leveling off at 10(-7). Higher concentrations did not induce a further increase in specific binding and internalization. Withdrawal of the hormone from culture medium was associated with a decrease in specific binding of the ligand by 60% in the following 24 hours. To investigate the effect of glucocorticoid deficiency on liver uptake of HDL in vivo, specific binding and internalization were studied in a culture of HEP isolated from adrenalectomized rats (AER) at 2 hours after seeding.(ABSTRACT TRUNCATED AT 250 WORDS)

Limited discriminant value of lipoprotein AI, lipoprotein Lp(a) and other lipoprotein particles in patients with and without early onset ischaemic heart disease

AIMS

To assess whether the ability of lipoprotein related variables to discriminate between individuals with or without premature clinical ischaemic heart disease (IHD) was improved using data on high density lipoprotein-lipoprotein AI (HDL-LpAI) fractions, alone or in combination with data on Lp(a).

METHODS

Lipid and apolipoprotein concentrations were measured in 26 middle-aged men (mean age 50.3 years) with early onset IHD and coronary artery bypass grafting prior to sampling, and in 26 matched lipaemic and 26 normolipaemic asymptomatic controls.

RESULTS

Triglyceride and Lp(a) concentrations were higher, while HDL cholesterol and apolipoprotein A-I (apoA-I) concentrations were lower in patients than in controls. LpAI concentrations were also lower in IHD patients and were correlated with HDL and apoA-I in both IHD and control groups. Lp(a) was not correlated with any other lipid or apolipoprotein measured in either patients or controls. Univariate discriminant function analysis showed that the proportion correctly classified as patients or controls was marginally greater using LpAI concentrations as the discriminator, which was not increased in combination with Lp(a). Serum triglycerides, HDL cholesterol, apoA-I and Lp(a) alone all had similar, but weaker, discriminant power, which increased in various combinations with LpAI.

CONCLUSIONS

LpAI particle measurement may be useful in research to define mechanisms of cardiovascular protection by HDL but the discriminating power for IHD was only marginally superior to measuring total apoA-I or Lp(a) concentrations. Little further advantage arose through combining LpAI data with other variables.

Structural domain of apolipoprotein A-I involved in its interaction with cells

Apolipoprotein A-I (apo A-I) is the major protein constituent of high-density lipoprotein (HDL), the lipoprotein fraction which mediates the reverse cholesterol transport. This apolipoprotein plays an important role in the binding of HDL to cells and participates in the efflux of cellular cholesterol. We have recently compared six different genetic variants of apo A-I and found that the apo A-I (Pro 165-->Arg) mutant is defective in promoting cellular cholesterol efflux from murine adipocytes and peritoneal macrophages and we have proposed that this region of apo A-I may be involved in their interaction with cells. To confirm this hypothesis, four monoclonal antibodies (mAbs) specific for apo A-I were used to study the inhibition of the interaction of palmitoyloleoylphosphatidylcholine (POPC): apoA-I complexes with HeLa cells and adipocytes. Among these antibodies, the apo A-I epitope recognized by the A44 mAb lies in the COOH terminal region (amino acid residues 149-186) including the proposed region. The antibodies A05, and A03 react with residues 25-82, 135-140, respectively and the A11 mAb corresponds to a discontinuous epitope at residues 99-105 and 126-132. Our results show clearly that the A44 and A05 mAbs reduce both the binding to HeLa cells and the cholesterol efflux from adipocytes. The inhibition of POPC: apoA-I complexes binding to both cell types is more strictly observed with the Fab fragments of monoclonal antibodies A44 and A05. Partial cotitration curves of these mAbs in a solid phase assay (RIA), indicated partial competition between these two antibodies. We propose a structural model for the POPC: apoA-I complexes where the N-terminal domain of one apo A-I molecule is in close spatial relationship with the C-terminal domain of the adjacent apo A-I molecule. We therefore suggest that the domain around amino acid 165 of apo A-I and which is recognized by mAb A44 (149-186) forms or contains some specific regions which mediate selectively the interaction with the binding site of cells and is involved in the efflux of cellular cholesterol.

Binding of HDL to basolateral membranes of the renal cortex. Evidence for two components in the HDL-membrane association

The binding of porcine 125I-HDL to purified basolateral membrane fractions isolated from pig kidney cortex displays two categories of sites, one with high affinity ((Kd = (3.0 +/- 0.7) x 10(-9) M) and low capacity (Bmax = 52 +/- 32 ng/mg proteins) another with low affinity (Kd = (5.3 +/- 0.7) x 10(-8) M) but a higher capacity (Bmax = 795 +/- 115 ng/mg proteins). Binding was competitively inhibited to the same extent by unlabeled HDL from swine, human or rat, demonstrating an absence of species specificity. Porcine LDL partially competed for binding even in the presence of 30 mM EDTA which prevents apo B/E specific binding. Membrane proteins solubilized with CHAPS were analyzed by electrophoresis followed by ligand blotting using porcine 125I-HDL and 125I-apoAI-HDL to show that HDL bound to two proteins of respective molecular masses 120 +/- 2 and 95 +/- 9 kDa. 125I-apoAI associated mostly with the 95 kDa protein. A 100-fold excess of unlabeled HDL greatly decreased binding to the 95 kDa protein but less to the 120 kDa protein. We conclude that part of HDL binding occurs through the lipid moiety, while another is the result of a specific interaction between apoAI and a membrane protein of 95 kDa.

Net transport of cholesterol from cells of the human EA.hy 926 endothelial cell line to high density lipoproteins

EA.hy 926 cells, a human endothelial cell line, show characteristics of differentiated endothelial cells. The cells express saturable binding of apo E-free 125I-high density lipoprotein3 (HDL3). Bmax increased from 71 to 226 ng HDL3 bound/mg cell protein after cholesterol loading of the confluent endothelial cells with cationized low density lipoprotein (LDL). The affinity did not change after cholesterol enrichment (Kd was 37 micrograms HDL3 protein/ml for control cells and 31 micrograms/ml for loaded cells). Incubation of cholesterol-loaded EA.hy 926 cells with native HDL and LDL had different effects on cellular cholesterol levels. Incubation with HDL decreased both esterified and unesterified cellular cholesterol, but LDL did not change total cellular cholesterol. However, LDL tended to increase cellular cholesteryl esters, with a concomitant decrease of unesterified cellular cholesterol. Incubation of endothelial cells with both HDL and LDL also resulted in decreased total cellular cholesterol levels. These data show that cationized LDL-loaded human endothelial EA.hy 926 cells can be used to study the net transport of cellular cholesterol to HDL, the first step in reverse cholesterol transport.

Cross-linking of apolipoproteins is involved in a loss of the ligand activity of high density lipoprotein upon Cu(2+)-mediated oxidation

A recent study demonstrated that Cu(2+)-mediated oxidation of high density lipoprotein (HDL) resulted in a loss of the capacity to reduce cholesterol from macrophage foam cells [(1991) Proc. Natl. Acad. Sci. USA 88, 6457-6461]. In the present study we characterized the physicochemical properties of oxidized HDL and correlated them with the ligand activity toward the HDL receptor. Among them, the cross-linking of apolipoproteins and an increase in lipid peroxides were characteristic and closely similar to those of tetranitromethane-treated HDL, an abortive ligand for the HDL receptor. Cellular experiments with murine peritoneal macrophages revealed that both the cellular binding activity of HDL and its capacity to enhance cholesterol efflux from macrophage foam cells were markedly reduced upon oxidation. These results suggest that cross-linking of HDL apolipoproteins is involved in the loss of the ligand activity of oxidized HDL.

Binding of modified high density lipoproteins to endothelial cells: relation with cellular cholesterol efflux?

Human endothelial cells (EA.hy 926 line) were enriched with cholesterol using cationized low density lipoprotein (LDL). Cholesterol-loaded cells interacted with native apolipoprotein (apo) E-free high density lipoprotein3 (HDL)3 as well as with dimethyl suberimidate-modified HDL3 (DMS-HDL3). At 4 degrees C both HDL preparations showed a saturable high affinity binding with a KD of 31 and 50 micrograms of protein/ml and a Bmax of 226 and 436 ng/mg cell protein for native HDL3 and DMS-HDL3 particles, respectively. Competition of binding of 5 micrograms apo E-free 125I-labelled HDL3/ml by unlabelled DMS-HDL3 and tetranitromethane-treated HDL3 (TNM-HDL3) was very poor, whereas unlabelled native HDL3 competed very effectively with 125I-labelled HDL3 binding. Thus, both types of modified HDL did not compete for the high affinity binding sites for native HDL. Unlabelled native HDL3 and unlabelled DMS-HDL3 both competed for the binding of 125I-labelled DMS-HDL3 very effectively. These experiments indicate that there are two distinct high affinity binding sites for HDL on cationized LDL-loaded EA.hy 926 cells: one specific HDL binding site, which only binds native HDL, and a second binding site for both native HDL and DMS-HDL. The modified HDL fractions were used to study the relation between HDL binding and HDL-mediated efflux. Efflux of cell cholesterol was measured as the increase of cholesterol mass in the medium after 24 h of incubation with 0.2 mg native HDL3/ml, or the same amount of modified HDL3. DMS-HDL3-mediated efflux was identical to efflux mediated by native HDL3. TNM-HDL3 also induced efflux of cell cholesterol; however, efflux induced by TNM-HDL3 was only 45-50% of the amount obtained with native HDL3. So both DMS- and TNM-modified HDL3 induced efflux of cholesterol, although these particles do not bind to the specific high affinity sites for native HDL. These results do not indicate a link between binding of HDL to specific receptors for native HDL and HDL-mediated efflux of cholesterol from loaded endothelial cells.

Characterization and isolation of a high-density-lipoprotein-binding protein from bovine corpus luteum plasma membrane

The ovary uses the cholesterol from high-density lipoproteins (HDL) as a substrate source for steroid hormone production. It is not clear, however, how ovarian cells acquire the lipoprotein cholesterol. This study describes the characterization and isolation of a high-affinity-binding protein for apolipoprotein E-free HDL from the plasma-membrane fraction of bovine corpora lutea. Plasma membranes were prepared by differential centrifugation with 5-6-fold enrichment of 5'-nucleotidase activity. The binding of 125I-HDL to the plasma membranes was time-dependent, and there appeared to be a single high-affinity site with a Kd of 6.7 micrograms of HDL/ml of assay buffer. The binding was not affected by high concentrations of low-density lipoproteins or the Ca2+ chelator EDTA, nor by changes in pH in the range 6.5-9.0. The binding was affected by the salt concentration in the buffer, with a dose-dependent increase that reached a maximum at 150-250 mM-NaCl. Binding was increased in the presence of high concentrations of KCl and KBr, and most significantly increased by high concentrations of bivalent metal ions. Ligand-blot analysis under reducing conditions revealed that the binding protein was a single polypeptide of about 108 kDa that was associated with the plasma-membrane fraction. This HDL-binding protein was purified to homogeneity by solubilization with Triton X-100, poly(ethylene glycol) precipitation, DEAE-Sephadex chromatography, and preparative SDS/PAGE. The purified binding protein is a single polypeptide of 108 kDa that retains high affinity and specificity for HDL as assayed by ligand blotting.

High density lipoprotein mediates selective reduction in cholesteryl esters from macrophage foam cells

To elucidate an anti-atherogenic nature of high density lipoprotein (HDL) at cellular level, its in vitro effect on macrophage foam cells was examined. Rat peritoneal macrophages were converted to foam cells by incubation with [3H]cholesterol-labeled acetylated LDL. HDL addition to these foam cells resulted in a reduction in cellular radioactive cholesteryl esters (CE) as well as its CE mass. The radioactive free cholesterol (FC) was similarly reduced with time, whereas its FC mass level was unaltered. Other lipoproteins such as very low density lipoprotein and low density lipoprotein also reduced the radioactive FC. However, their CE-reducing capacity was negligibly weak. These results suggest that (i) CE reduction is selective to HDL, (ii) FC transfer from plasma membrane to lipoprotein (cholesterol efflux) expressed by reduction in radioactive FC is not selective to HDL but occurs to other lipoproteins, (iii) the CE-reducing capacity of HDL became weaker when cellular binding of HDL was reduced by chemical modification with tetranitromethane or a chemical cross-linker, dithiobis-succinimidylpropionate, suggesting an importance of the specific binding in the HDL-mediated CE reduction. These in vitro results gave an experimental support to a definite role of HDL as an anti-atherogenic lipoprotein in vivo.

High density lipoprotein-binding proteins in porcine liver. Isolation and histological localization

The antiatherogenic properties of high density lipoproteins (HDLs) are thought to reside in their involvement in the reverse cholesterol transport pathway. Specific HDL-binding proteins could play a key role in this process. Two HDL-binding proteins of approximately 90 and 180 kd were identified in porcine liver by ligand blotting and were purified to apparent homogeneity by a combination of protein extraction, DEAE-cellulose chromatography, Con A-Sepharose chromatography, and preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Binding of 125I-HDL by these proteins could be actively competed for by unlabeled HDL but not by low density lipoprotein. Polyclonal antisera have been raised against these two proteins. Each antiserum recognized only one of the HDL-binding proteins, indicating that they are not immunologically related. Moreover, striking differences in localization were observed in immunohistochemical studies. The 90-kd protein is located within the hepatocellular plates, while the 180-kd protein is present along the lining of the sinusoids. These results suggest functional differences between the two HDL-binding proteins described.

Cholesterol efflux from macrophages mediated by high-density lipoprotein subfractions, which differ principally in apolipoprotein A-I and apolipoprotein A-II ratios

High-density lipoprotein (HDL) was fractionated by preparative isoelectric focussing into six distinct subpopulations. The major difference between the subfractions was in the molar ratio of apolipoprotein A-I to apolipoprotein A-II, ranging from 2.1 to 0.5. The least acidic particles had little apolipoprotein A-II, were larger and contained the most lipid. The efflux capacity of the HDL subfractions was tested with mouse peritoneal macrophages and a mouse macrophage cell line (P388D1), either fed with acetylated low-density lipoprotein or free cholesterol. All the HDL subfractions were equally able to efflux cholesterol. The efflux was concentration dependant and linear for the first 6 h. The HDL subfractions bound with high affinity (Kd = 6.7-7.9 micrograms/ml) at 4 degrees C to the cell surface of P388D1 cells (211,000-359,000 sites/cell). Ligand blotting showed that all the HDL subfractions bound to membrane polypeptides at 60, 100, and 210 kDa. These HDL binding proteins may represent HDL receptors. In summary HDL particles, which differed principally in ratio of apolipoprotein A-I to apolipoprotein A-II behaved in a similar manner for both cholesterol efflux and cell surface binding.

Characterization and purification of proteins which bind high-density lipoprotein. A putative cell-surface receptor

High-density lipoprotein (HDL) is shown by ligand blotting to bind membrane-associated polypeptides with sizes of 60, 100 and 210 kDa. Binding was concentration-dependent and competed by excess unlabelled HDL. All the major apolipoproteins of HDL, apoA-I, apoA-II and apoA-IV, bound independently. The 100 kDa and 210 kDa HDL-binding activities were purified from membranes of Hep3B tumour cells by ion-exchange chromatography and gel filtration. The binding activities at 100 kDa and 210 kDa co-purified. After treatment with disulphide-reducing reagent, the 210 kDa band was no longer present and an increase was observed in the amount and binding ability of the 100 kDa polypeptide. The 100 kDa binding protein labelled at the cell surface with 125I could be immunoprecipitated after cross-linking to cell-surface-bound HDL. It is proposed that this HDL-binding activity, a putative cell-surface receptor for HDL, exists totally or in part as a high-molecular-mass complex composed of 100 kDa subunits.

Cholesterol transport between cells and high-density lipoproteins

Various types of studies in humans and animals suggest strongly that HDL is anti-atherogenic. The anti-atherogenic potential of HDL is thought to be due to its participation in reverse cholesterol transport, the process by which cholesterol is removed from non-hepatic cells and transported to the liver for elimination from the body. Extensive studies in cell culture systems have demonstrated that HDL is an important mediator of sterol transport between cells and the plasma compartment. The topic of this review is the mechanisms that account for sterol movement between HDL and cells. The most prominent and easily measured aspect of sterol movement between HDL and cells is the rapid bidirectional transfer of cholesterol between the lipoprotein and the plasma membrane. This movement occurs by unmediated diffusion, and in most situations its rate in each direction is limited by the rate of desorption of sterol molecules from the donor surface into the adjacent water phase. The net transfer of sterol mass out of cells occurs when there is either a relative enrichment of sterol within the plasma membrane or a depletion of sterol in HDL. Recent studies suggest that certain minor subfractions of HDL (with pre-beta mobility on agarose gel electrophoresis and containing apoprotein A-I but no apo A-II) are unusually efficient at promoting efflux of cell sterol. To what extent efflux to these HDL fractions is balanced by influx from the lipoprotein has not yet been established clearly. The prevention and reversal of atherosclerosis require the mobilization of cholesterol from internal (non-plasma membrane) cellular locations. To some extent, this may involve the retroendocytosis of HDL. However, most mobilization probably involves the transport of internal sterol to the plasma membrane, followed by desorption to extracellular HDL. Several laboratories are investigating the transport of sterol from intracellular locations to the plasma membrane. Studies on biosynthetic sterol (probably originating mostly in the smooth endoplasmic reticulum) suggest that there is rapid transport to the plasma membrane in lipid-rich vesicles. Important features of this transport are that it bypasses the Golgi apparatus and may be positively regulated by the specific binding of HDL to the plasma membrane.(ABSTRACT TRUNCATED AT 400 WORDS)

Apoprotein A-1 is a cofactor independent substrate of protein kinase C

Apoprotein A-1 (apo A-1), the predominant protein constituent of high density lipoproteins (HDL), was phosphorylated by protein kinase C (PKC). Optimal phosphorylation of lipid-free apo A-1 occurs in the absence of calcium, phosphatidyl serine (PS), and diolein (DO). However, HDL-bound apo A-1 was not phosphorylated by PKC. Furthermore, addition of either native or reconstituted HDL particles to lipid-free apo A-1 resulted in a concentration-dependent inhibition of phosphorylation. It appears that the phosphorylatable sites on apo A-1 are involved in hydrophobic interaction with the lipids of HDL. Apo A-1 is a novel substrate of PKC because it does not require calcium and lipid cofactors for optimal phosphorylation.

High density lipoprotein loses its effect to stimulate efflux of cholesterol from foam cells after oxidative modification

In this study, we performed oxidative modification of high density lipoprotein (HDL) in vitro. The amount of lipid peroxide increased when either HDL2 or HDL3 was incubated with phosphate-buffered saline containing 5 microM CuSO4 for 24 h at 37 degrees C, indicating that both fractions of HDL were oxidatively modified. This modification resulted in denaturation of apolipoprotein AI on SDS/PAGE and increased the negative charge on agarose gel electrophoresis. When incubated with macrophage-derived foam cells, native HDL caused a marked efflux of cholesterol from them, leading to a decrease in the amount of cholesteryl ester in the cells. However, oxidized HDL showed a lessened effect on the decrease of cholesteryl ester in foam cells. These data suggest that oxidative modification of HDL may stimulate development of atherosclerosis by limiting efflux of cholesterol from foam cells.

Differential role of apolipoprotein AI-containing particles in cholesterol efflux from adipose cells

Cholesterol efflux was studied in cultured Ob1771 adipose cells after preloading with LDL cholesterol. Exposure to particles containing apo AII (LpAI) and particles containing apo AI and apo AII (LpAI:AII) isolated from native human plasma, and from HDL2 or HDL3, showed that only LpAI were able to promote cholesterol efflux, despite the fact that both kinds of particles were able to bind to receptor sites within the same range of concentrations (apparent Kd values between 10 and 25 micrograms/ml). During this long-term exposure, LpAI:AII demonstrated a concentration-dependent inhibition (10-60 micrograms/ml) of LpAI-mediated cholesterol efflux from adipose cells under conditions where LpAI:AII did not deliver cholesterol to the cells and where no net change in the distribution of apo AI between LpAI and LpAI:AII was observed. The antagonizing and modulating role of LpAI:AII in preventing cholesterol efflux mediated by LpAI appears not to be related to the lipid composition and cholesterol content of the particles but, rather, appears dependent upon the presence of apo AI in LpAI particles and apo AII in LpAI:AII particles. The actual concentrations of these particles in the interstitial fluid bathing peripheral cells might be critical for the in vivo occurrence of cholesterol efflux.

Cholesterol efflux from adipose cells is coupled to diacylglycerol production and protein kinase C activation

Apolipoprotein A-I (apo A-I)*/DMPC complexes have been previously shown to promote cholesterol efflux from cholesterol-preloaded adipose cells whereas apo A-II/DMPC complexes, which bind to the same cell surface binding sites, were ineffective. Addition of apo A-I/DMPC complexes led to a rapid and transient formation of diacylglycerol. However, in contrast to PGF2 alpha (Doglio et al., Proc. Natl. Acad. Sci. USA, 1989, 86, 1148), no accumulation of inositol phosphates was observed. Apo A-II/DMPC complexes had no effect on diacylglycerol formation. Stimulation by apo A-I/DMPC complexes or native HDL3 of cells prelabelled with (2-palmitoyl 9,10[3H])phosphatidylcholine induced also the formation of labelled diacylglycerol whereas apo A-II/DMPC complexes and HDL3 treated with tetranitromethane showed no effect. Direct activation of protein kinase C(s) by PMA promoted cholesterol efflux providing that DMPC liposomes were present as cholesterol acceptor. It is proposed that lipoprotein particles have two separate effects, i.e. a ligand-induced effect leading to cholesterol translocation from intracellular stores to the cell surface and a bilayer-induced effect allowing cholesterol efflux from the cell surface to the acceptor.