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

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

A change in apolipoprotein B expression is required for the binding of apolipoprotein E to very low density lipoprotein

Factors affecting the association of apolipoprotein E (apoE) with human plasma very low density lipoprotein (VLDL) were investigated in experiments in which the lipid content of the lipoprotein was modified either by lipid transfer in the absence of lipolysis or through the action of lipoprotein lipase. In both cases, lipoprotein particles initially containing no apoE (VLDL-E), isolated by heparin affinity chromatography, were modified until they had the same lipid composition as native apoE-containing VLDL (VLDL+E) from the same plasma. Transfer-modified lipoproteins, unlike native VLDL+E, did not bind apoE or interact with heparin. In contrast, VLDL-E, whose lipid composition was modified to the same extent by lipase, bound apoE and bound to heparin under the same conditions as native VLDL+E. A structural protein (apolipoprotein B) epitope characteristic of VLDL+E was expressed during lipolysis prior to ApoE or heparin binding. The data suggest that the reaction of apoE with VLDL-E is a two-step reaction. The appearance of apoB is modified during lipolysis, with expression of a major heparin-binding site. The modified VLDL then becomes competent to bind apoE. The lipid composition of VLDL appears not to be a major factor in the ability of VLDL to bind apoE or to bind to heparin.     

Regional specificities of monoclonal anti-human apolipoprotein B antibodies

The usefulness of monoclonal antibodies as probes of protein structure is directly related to knowledge of the structures and locations of the epitopes with which they interact. In this report we provide a detailed map of 13 epitopes on apoB-100 defined by our anti-apoB monoclonal antibodies based on current information on the amino acid sequence of apoB-100. To localize antibody specificities to smaller regions along the linear sequence of the apoB-100 molecule we used a) thrombin- and kallikrein-generated fragments of apoB-100; b) beta-galactosidase- apoB fusion proteins; c) heparin; and d) antibody versus antibody competition experiments. Most of the monoclonal antibodies elicited by immunization with LDL were directed towards epitopes within the first 1279 amino terminal (T4/K2 fragments) or last 1292 carboxyl terminal amino acid residues (T2/K4 fragments) of apoB-100. One epitope localized to the mid-portion of apoB-100 was elicited by immunization with VLDL (D7.2). Saturating amounts of heparin bound to LDL did not inhibit the binding of any of the monoclonal antibodies to their respective epitopes on apoB-100, indicating that none of the antibody determinants is situated close to any of the reported heparin binding sites on LDL apoB. We examined the expression of apoB epitopes on VLDL subfractions and LDL isolated from a normolipidemic donor. The apparent affinities with which the antibodies interacted with their respective epitopes on the VLDL subfractions and LDL uniformly increased as follows: LDL greater than VLDL3 greater than VLDL2 greater than VLDL1, suggesting that each of the major regions of apoB-100 is progressively more exposed as normal VLDL particles become smaller in size and epitopes are most exposed in LDL. Previous experiments utilizing hypertriglyceridemic VLDL subfractions yielded similar results, but the rank order of VLDL subfractions and LDL was not the same for all antibodies tested. Thus, differences in apoB epitope expression on VLDL particles of differing sizes is a general phenomenon, but the expression of apoB epitopes in hypertriglyceridemic VLDL appears to be more heterogeneous than is the case for VLDL from normolipidemic donors.(ABSTRACT TRUNCATED AT 400 WORDS)     

Immunoaffinity isolation of apolipoprotein E-containing lipoproteins

Discrete apolipoprotein E-containing lipoproteins can be identified when EDTA plasma is fractionated on columns of 4% agarose. The present study has demonstrated, by physical and metabolic criteria, that these apolipoprotein E-containing lipoprotein subclasses may be further isolated by immunoaffinity chromatography. Whole plasma was first bound to an anti-apolipoprotein E immunoadsorbent prior to gel filtration on 4% agarose. After elution from the affinity column and dialysis, the bound fraction was chromatographed on 4% agarose. Discrete subfractions of apolipoprotein E could be demonstrated within elution volumes similar to those observed in the original plasma. When whole plasma was first submitted to gel filtration and the apolipoprotein E-containing lipoproteins of either intermediate- or of high-density lipoprotein (HDL) size were subsequently bound to anti-apolipoprotein E columns, the bound eluted fractions maintained their size and physical properties as shown by electron microscopy and by rechromatography on columns of 4% agarose. The metabolic integrity of apolipoprotein E-containing very-low-density lipoproteins (VLDL) was examined by coinjection into a cynomolgus monkey of 125I-labeled apolipoprotein E-rich and 131I-labeled apolipoprotein E-deficient human VLDL which had been separated by immunoaffinity chromatography. The plasma specific activity time curves of the apolipoprotein B in VLDL, intermediate-density (IDL) and low-density (LDL) lipoproteins demonstrated rates of decay and precursor-product relationships similar to those obtained after injection of whole labeled VLDL, supporting the metabolic integrity of VLDL isolated by immunoaffinity chromatography.     

Immunological heterogeneity of rat apolipoprotein B epitope expression. A study using monoclonal antibodies to rat apolipoprotein B

Epitope expression of rat apolipoprotein B on lipoproteins was investigated with the help of six monoclonal antibodies produced from mice. Through a variety of techniques, which include cotitrations, ELISAs and quantitative immunoadsorption precipitation, we concluded that the six monoclonal antibodies recognize five different epitopes. LRB 110 and LRB 260 recognize epitopes that may be overlapping. LRB 240 and LRB 250 recognize epitopes that are preferentially expressed in triacylglycerol-rich particles. LRB 220 recognizes an epitope that is expressed by all apolipoprotein-B-containing lipoproteins. We have also determined that apolipoprotein B epitope expression in rat lipoproteins is very similar to its human counterpart. Both rat and human apolipoprotein B epitope expression on lipoproteins showed heterogeneities even in homologous lipoprotein preparations. We concluded that a variety of techniques are necessary to fully characterize monoclonal antibodies to apolipoproteins. The possible implications of epitope expression in pathophysiology are also discussed.     

Golgi-associated maturation of very low density lipoproteins involves conformational changes in apolipoprotein B, but is not dependent on apolipoprotein E

The major protein component in secreted very low density lipoproteins (VLDL) is apoB, and it is established that these particles can reach sizes approaching 100 nm. We previously employed a cell-free system to investigate the nature of the vesicles in which this large cargo exits the endoplasmic reticulum (ER) (Gusarova, V., Brodsky, J. L., and Fisher, E. A. (2003) J. Biol. Chem. 278, 48051-48058). We found that apoB-containing lipoproteins exit the ER as dense lipid-protein complexes regardless of the final sizes of the particles and that further expansion occurs via post-ER lipidation. Here, we focused on maturation in the Golgi apparatus. In three separate approaches, we found that VLDL maturation (as assessed by changes in buoyant density) was associated with conformational changes in apoB. In addition, as the size of VLDL expanded, apoE concentrated in a subclass of Golgi microsomes or Golgi-derived vesicles that co-migrated with apoB-containing microsomes or vesicles, respectively. A relationship between apoB and apoE was further confirmed in co-localization studies by immunoelectron microscopy. These combined results are consistent with previous suggestions that apoE is required for VLDL maturation. To our surprise, however, we observed robust secretion of mature VLDL when apoE synthesis was inhibited in either rat hepatoma cells or apoE(-/-) mouse primary hepatocytes. We conclude that VLDL maturation in the Golgi involves apoB conformational changes and that the expansion of the lipoprotein does not require apoE; rather, the increase in VLDL surface area favors apoE binding.     

Capillary isotachophoresis study of lipoprotein network sensitive to apolipoprotein E phenotype. 1. ApoE distribution between lipoproteins

Sixteen patients differing widely in plasma triglyceride content were divided into three groups by their apolipoprotein E (apoE) phenotype—E33 homozygotes, E23, and E34 heterozygotes. The plasma lipid and apoE distribution between individual lipoproteins was followed by capillary isotachophoresis (CITP) of plasma samples pre-stained with lipid fluorescent probe NBD-C6-ceramide and by fluorescein-labeled apoE, respectively. Among 12 peaks visualized by ceramide staining, an individual peak with very low density lipoproteins (VLDL) was identified. The VLDL cholesterol and apoE content determined by CITP directly in whole plasma were significantly related to their content as determined by conventional analysis with isolated VLDL. The ceramide distribution among lipoprotein pools was insensitive to apoE phenotype (49–53 : 7–11 : 39–43% for HDL, VLDL, and IDL/LDL, respectively) while the preferential binding of apoE to VLDL was observed in E34 patients compared to E33 (62 : 19 : 20 vs. 70 : 9 : 22%). In a study of apoE/F displacement from lipoproteins at plasma titration by apoC-III in vitro, apoE was found to bind more tightly to VLDL from E34 compared to E33 patients as evidenced by both the increased non-displaceable apoE pool, the increased VLDL sorbtion capacity for apoE, and the decreased displacement parameter in a “container” model of lipoprotein binding. Two different types of apoE package in a whole lipoprotein profile were observed. ApoE structure in a particular lipoprotein may underlie the phenotype-sensitive apoE distribution and apoC-III interference in hypertriglyceridemia.     

Rapid turnover of apolipoprotein C-III-containing triglyceride-rich lipoproteins contributing to the formation of LDL subfractions

The atherogenicity theory for triglyceride-rich lipoproteins (TRLs; VLDL + intermediate density lipoprotein) generally cites the action of apolipoprotein C-III (apoC-III), a component of some TRLs, to retard their metabolism in plasma. We studied the kinetics of multiple TRL and LDL subfractions according to the content of apoC-III and apoE in 11 hypertriglyceridemic and normolipidemic persons. The liver secretes mainly two types of apoB lipoproteins: TRL with apoC-III and LDL without apoC-III. Approximately 45% of TRLs with apoC-III are secreted together with apoE. Contrary to expectation, TRLs with apoC-III but not apoE have fast catabolism, losing some or all of their apoC-III and becoming LDL. In contrast, apoE directs TRL flux toward rapid clearance, limiting LDL formation. Direct clearance of TRL with apoC-III is suppressed among particles also containing apoE. TRLs without apoC-III or apoE are a minor, slow-metabolizing precursor of LDL with little direct removal. Increased VLDL apoC-III levels are correlated with increased VLDL production rather than with slow particle turnover. Finally, hypertriglyceridemic subjects have significantly greater production of apoC-III-containing VLDL and global prolongation in residence time of all particle types. ApoE may be the key determinant of the metabolic fate of atherogenic apoC-III-containing TRLs in plasma, channeling them toward removal from the circulation and reducing the formation of LDLs, both those with apoC-III and the main type without apoC-III.     

Preparative free-solution isotachophoresis for separation of human plasma lipoproteins: apolipoprotein and lipid composition of HDL subfractions

We have previously shown that plasma lipoproteins can be separated by analytical capillary isotachophoresis (ITP) according to their electrophoretic mobility in a defined buffer system. As in lipoprotein electrophoresis, HDL show the highest mobility followed by VLDL, IDL, and LDL. Chylomicrons migrate according to their net-charge between HDL and VLDL, because ITP has negligible molecular sieve effects. Three HDL subfractions were obtained which were designated fast-, intermediate-, and slow-migrating HDL. To further characterize these HDL subfractions, a newly developed free-solution ITP (FS-ITP)-system was used, that allows micro-preparative separation of human lipoproteins directly from whole plasma (B?ttcher, A. et al. 1998. Electrophoresis. 19: 1110-1116). The fractions obtained by FS-ITP were analyzed for their lipid and apolipoprotein composition and by two-dimensional nondenaturing polyacrylamide gradient gel electrophoresis (2D-GGE) with subsequent immunoblotting. fHDL are characterized by the highest proportion of esterified cholesterol of all three subfractions and are relatively enriched in LpA-I. Together with iHDL they contain the majority of plasma apoA-I, while sHDL contain the majority of plasma apoA-IV, apoD, apoE, and apoJ. Pre-beta-HDL were found in separate fractions together with triglyceride-rich fractions between sHDL and LDL. In summary, ITP can separate the bulk of HDL into lipoprotein subfractions, which differ in apolipoprotein composition and electrophoretic mobility. While analytical ITP permits rapid separation and quantitation for diagnostic purposes, FS-ITP can be used to obtain these lipoprotein subfractions on a preparative scale for functional analysis. As FS-ITP is much better suited for preparative purposes than gel electrophoresis, it represents an important novel tool for the functional analysis of lipoprotein subclasses.     

Lipolysis is a prerequisite for lipid accumulation in HepG2 cells induced by large hypertriglyceridemic very low density lipoproteins.

Lipoprotein kinetic studies have demonstrated that a large proportion of Sf 60-400 very low density lipoprotein (VLDL) is cleared directly from the circulation in Type IV hypertriglyceridemic subjects, at an unknown tissue site. The present studies were designed to investigate the role of hepatocytes in this process and to define the conditions, whereby Type IV Sf 60-400 VLDL would induce lipid accumulation in HepG2 cells. Type IV VLDL (Sf 60-400) failed to augment the total cholesterol, esterified cholesterol, or triglyceride content of HepG2 cells following 24-h incubations. Coincubation of bovine milk lipoprotein lipase (LPL) and Type IV VLDL with HepG2 cells induced a 3-fold increment in cellular esterified cholesterol mass (p less than 0.005) and a 7-fold increase in cellular triglyceride mass (p less than 0.005), compared to VLDL alone. The increased cellular lipid mass was associated with increased oleate incorporation into cellular cholesterol esters and triglycerides. Exogenous LPL hydrolyzed 76% of the VLDL triglyceride over 24 h. LPL action on Type IV VLDL was sufficient to promote cellular uptake of these lipoproteins, while elevated media-free fatty acid levels were not. Although HepG2 cells secrete apolipoprotein (apo) E, we assessed the role of VLDL-associated apoE in the lipid accumulation induced by VLDL plus LPL. ApoE-rich and apoE-poor Type IV VLDL subfractions induced similar increments in cellular esterified cholesterol in the presence of LPL, despite a 4-fold difference in apoE content. Sf 60-400 VLDL, from subjects homozygous for the defective apoE2, plus LPL, behaved identically to Type IV VLDL plus LPL. Type IV VLDL plus LPL, preincubated with anti-apoE (1D7) and apoB (5E11) monoclonal antibodies, known to block the binding of apoE and -B, respectively, to the LDL receptor failed to block lipid accumulation. In contrast, apoE-poor Type IV VLDL, apoE2 VLDL, and VLDL plus 1D7 were taken up poorly by J774 cells, cells that secrete LPL, but not apoE. These studies suggest that lipolytic remodeling of large Type IV VLDL by LPL is a prerequisite for their uptake by HepG2 cells and that HepG2 cell-secreted apoE rather than VLDL-associated apoE is the ligand involved in uptake.     

Effects of polymorphism on the lipid interaction of human apolipoprotein E

ApoE exists as three common isoforms, apoE2, apoE3, and apoE4; apoE2 and apoE3 preferentially bind to high density lipoproteins, whereas apoE4 prefers very low density lipoproteins (VLDL). To understand the molecular basis for the different lipoprotein distributions of these isoforms in human plasma, we examined the lipid-binding properties of the apoE isoforms and some mutants using lipid emulsions. With both large (120 nm) and small (35 nm) emulsion particles, the binding affinity of apoE4 was much higher than that of apoE2 and apoE3, whereas the maximal binding capacities were similar among the three isoforms. The 22-kDa N-terminal fragment of apoE4 displayed a much higher binding capacity than did apoE2 and apoE3. The apoE4(E255A) mutant, which has no electrostatic interaction between Arg61 and Glu255, showed binding behavior similar to that of apoE3, indicating that N- and C-terminal domain interaction in apoE4 is responsible for its high affinity for lipid. In addition, the apoE3(P267A) mutant, which is postulated to contain a long alpha-helix in the C-terminal domain, had significantly decreased binding capacities for both sizes of emulsion particle, suggesting that the apoE4 preference for VLDL is not due to a stabilized long alpha-helical structure. Isothermal titration calorimetry measurements showed that there is no significant difference in thermodynamic parameters for emulsion binding among the apoE isoforms. However, fluorescence measurements of 8-anilino-1-naphthalenesulfonic acid binding to apoE indicated that apoE4 has more exposed hydrophobic surface compared with apoE3 mainly due to the different tertiary organization of the C-terminal domain. The less organized structure in the C-terminal domain of apoE4 leads to the higher affinity for lipid, contributing to its preferential association with VLDL. In fact, we found that apoE4 binds to VLDL with higher affinity compared with apoE3.     

Characterization and quantification of serum lipoprotein subfractions by capillary isotachophoresis: relationships with lipid, apolipoprotein, and lipoprotein levels.

Human serum lipoproteins are currently defined according to their density as well as according to their electrophoretic mobility. They can be fractionated into discrete subspecies which exhibit variations in their structure and function. Capillary electrophoresis has been suggested to be a potential analytical strategy in understanding metabolic lipoprotein heterogeneity. In a sample of 35 normolipidemic subjects, we analyzed ceramide-labeled serum lipoproteins by capillary isotachophoresis linked to laser-induced fluorescent detection. Capillary isotachophoresis showed advantage to be an automated, rapid (6 min) and reproducible (CV < 7%) separation mode, on-line monitoring lipoprotein subfractions according to net charge. HDL were separated into three subfractions: i) the fast migrating HDL correlated positively with serum apoA-I (P < 0.05) and negatively with triglyceride (P < 0.01) concentrations, ii) the intermediate migrating HDL involved in HDL-cholesterol delivery and inversely related to LDL particles concentration (P < 0.001), and iii) the slow migrating prebeta(1)HDL. Triglyceride level was significantly associated with two fractions: i) the VLDL fraction correlated positively with apoE serum concentration (P < 0.01), and ii) the IDL fraction closely and positively associated with apoC-III-containing lipoprotein level (P < 0.001). Two LDL subfractions were positively related to LDL-cholesterol (0.05 相似文献   

Distinct patterns of lipoproteins with apoB defined by presence of apoE or apoC-III in hypercholesterolemia and hypertriglyceridemia

Apolipoprotein (apo) E and apoC-III concentrations in VLDL and LDL are associated with coronary heart disease. We studied the relationship between apoE and apoC-III and the abnormal concentrations and distribution of apoB lipoproteins in 10 hypercholesterolemic and 13 hypertriglyceridemic patients compared with 12 normolipidemic subjects (mean age, 45 years). Sixteen distinct types of apoB lipoprotein particles were separated by first using anti-apoE and anti-apoC-III immunoaffinity chromatography in sequence and then ultracentrifugation [light VLDL, dense VLDL, IDL, and LDL, with apoE with or without apoC-III (E(+)C-III(+), E(+)C-III(-)) or without apoE with or without apoC-III (E(-)C-III(+), E(-)C-III(-))]. The concentrations of VLDL particles with apoC-III (E(+)C-III(+), E(-)C-III(+)) were increased in the hypertriglyceridemic group compared with the hypercholesterolemic and normolipidemic groups. These particles were the most triglyceride rich of the particle types, and their triglyceride content was twice as high in hypertriglyceridemics compared with the other two groups. Hypertriglyceridemics had a similar concentration of total E(-)C-III(-) particles compared with normolipidemics, but the E(-)C-III(-) particles were distributed more to VLDL and IDL than to LDL. Hypercholesterolemics, in contrast, were distinguished from the normolipidemic group by 2-fold higher concentrations of apoB lipoproteins without apoE or apoC-III (E(-)C-III(-)), mainly LDL, which had high cholesterol content. Nonetheless, both normolipidemics and hypercholesterolemics had apoC-III-containing VLDL, which comprised 68% and 43% of their total VLDL particles. E(+)C-III(-) particles were a minor type, comprising <10% of particles in all lipoproteins and patient groups. Therefore, VLDL particles with apoC-III may play a central role in identifying the high risk of coronary heart disease in hypertriglyceridemia, but their substantial prevalence in normolipidemics may be of clinical significance as well.     

Apolipoprotein E metabolism in normolipoproteinemic human subjects

Human apolipoprotein E (apoE) is a constituent of plasma very low density and high density lipoproteins and is important in modulating the catabolism of remnants of triglyceride-rich lipoproteins. There are three common isoforms of apoE, designated apoE-2, E-3, and E-4, which are coded by three separate alleles (epsilon 2, epsilon 3, and epsilon 4) at a single genetic locus and inherited in the population in a co-dominant fashion. ApoE-3 is the predominant apoE isoform in the normolipidemic population, and epsilon 3 has been proposed to be the normal allele. ApoE-3 metabolism was studied in nine normolipidemic subjects homozygous for the epsilon 3 allele. In these subjects, the plasma apoE-3 concentration was 4.8 +/- 1.2 mg/dl (mean +/- SD), the plasma apoE-3 residence time was 0.73 +/- 0.18 days, and the plasma apoE-3 production rate was 3.4 +/- 1.5 mg/kg-day. The apoE in males, when compared to females, tended to have a shorter residence time (0.63 +/- 0.15 days versus 0.83 +/- 0.16), a higher production rate (4.20 +/- 1.73 mg/kg-days versus 2.60 +/- 0.78), but a similar plasma concentration (5.1 +/- 1.5 mg/dl versus 4.5 +/- 0.8). ApoE-3 had a more rapid catabolism from plasma than other apolipoproteins previously studied (apolipoproteins A-I, A-II, A-IV, B-100, C-II, and C-III) except for apolipoprotein B-48. The catabolism of apoE-3 in the individual lipoprotein subfractions was also examined and apoE was shown to be catabolized most rapidly from the VLDL and slowest from the HDL. The results of the kinetic analysis of apoE metabolism are consistent with apoE being important in the catabolism of triglyceride-rich lipoproteins and with HDL serving as a reservoir for apoE to reassociate with newly secreted triglyceride-rich lipoproteins.     

Recognition of vesicular lipoproteins by the apolipoprotein B,E receptor of cultured fibroblasts

Vesicular lipoproteins (e.g., lipoprotein-X) are found in plasma in cholestasis or following infusion of Intralipid or phospholipid. To investigate the metabolism of vesicular lipoproteins, we isolated them from the plasma of subjects with cholestasis or following chronic or single Intralipid infusion. Cholestasis and chronic Intralipid therapy were found to be associated with elevated plasma concentrations of apoE, as determined by radioimmunoassay. Vesicular lipoproteins purified from each of the three types of plasma contained apoE, as well as other proteins. In cholestasis, in which levels of apoE were up to five times normal, a major portion of the plasma apoE was on vesicular lipoproteins. Normalized for apoE content, all preparations of vesicular lipoproteins displaced 125I-labeled LDL from apoB,E receptors of cultured fibroblasts identically. This displacement was inhibited by monoclonal antibodies that block receptor binding of apoE. Vesicular lipoproteins containing 125I-labeled apoE were internalized and degraded by fibroblasts. Different preparations caused small losses or gains of cellular cholesterol, with appropriate stimulation or suppression of apoB,E receptors. Thus, vesicular lipoproteins contain apoE, and apoE mediates their interaction with the apoB,E receptor. Our results suggest that the catabolism of cholesterol-rich vesicular lipoproteins, formed during cholestasis or following infusions of Intralipid or phospholipid, may be receptor-mediated.     

Apolipoprotein C-III displacement of apolipoprotein E from VLDL: effect of particle size.

ApoC-III and apoE are important determinants of intravascular lipolysis and clearance of triglyceride-rich chylomicrons and VLDL from the blood plasma. Interactions of these two apolipoproteins were studied by adding purified human apoC-III to human plasma at levels observed in hypertriglyceridemic subjects and incubating under specific conditions (2 h, 37 degrees C). As plasma concentrations of apoC-III protein were increased, the contents in both VLDL and HDL were also increased. Addition of apoC-III at concentrations up to four times the intrinsic concentration resulted in the decreasing incremental binding of apoC-III to VLDL while HDL bound increasing amounts without evidence of saturation. No changes were found in lipid content or in particle size of any lipoprotein in these experiments. However, distribution of the intrinsic apoE in different lipoprotein particles changed markedly with displacement of apoE from VLDL to HDL. The fraction of VLDL apoE that was displaced from VLDL to HDL at these high apoC-III concentrations varied among individuals from 20% to 100% its intrinsic level. The proportion of VLDL apoE that was tightly bound (0% to 80%) was found to be reproducible and to correlate with several indices of VLDL particle size. In the group of subjects studied, strongly adherent apoE was essentially absent from VLDL particles having an average content of less than 50,000 molecules of triglyceride.Addition of apoC-III to plasma almost completely displaces apoE from small VLDL particles. Larger VLDL contain tightly bound apoE which are not displaced by increasing concentration of apoC-III.     

Lipoprotein lipase- and hepatic triglyceride lipase- promoted very low density lipoprotein degradation proceeds via an apolipoprotein E-dependent mechanism

Apolipoprotein E (apoE) is the primary recognition signal on triglyceride-rich lipoproteins responsible for interacting with low density lipoprotein (LDL) receptors and LDL receptor-related protein (LRP). It has been shown that lipoprotein lipase (LPL) and hepatic triglyceride lipase (HTGL) promote receptor-mediated uptake and degradation of very low density lipoproteins (VLDL) and remnant particles, possibly by directly binding to lipoprotein receptors. In this study we have investigated the requirement for apoE in lipase-stimulated VLDL degradation. We compared binding and degradation of normal and apoE-depleted human VLDL and apoE knockout mouse VLDL in human foreskin fibroblasts. Surface binding at 37 degrees C of apoE knockout VLDL was greater than that of normal VLDL by 3- and 40-fold, respectively, in the presence of LPL and HTGL. In spite of the greater stimulation of surface binding, lipase-stimulated degradation of apoE knockout mouse VLDL was significantly lower than that of normal VLDL (30, 30, and 80%, respectively, for control, LPL, and HTGL treatments). In the presence of LPL and HTGL, surface binding of apoE-depleted human VLDL was, respectively, 40 and 200% of normal VLDL whereas degradation was, respectively, 25 and 50% of normal VLDL. LPL and HTGL stimulated degradation of normal VLDL in a dose-dependent manner and by a LDL receptor-mediated pathway. Maximum stimulation (4-fold) was seen in the presence LPL (1 microgram/ml) or HTGL (3 microgram/ml) in lovastatin-treated cells. On the other hand, degradation of apoE-depleted VLDL was not significantly increased by the presence of lipases even in lovastatin-treated cells. Surface binding of apoE-depleted VLDL to metabolically inactive cells at 4 degrees C was higher in control and HTGL-treated cells, but unchanged in the presence of LPL. Degradation of prebound apoE-depleted VLDL was only 35% as efficient as that of normal VLDL. Surface binding of apoE knockout or apoE-depleted VLDL was to heparin sulfate proteoglycans because it was completely abolished by heparinase treatment. However, apoE appears to be a primary determinant for receptor-mediated VLDL degradation.Our studies suggest that overexpression of LPL or HTGL may not protect against lipoprotein accumulation seen in apoE deficiency.     

Hepatic apolipoprotein E expression promotes very low density lipoprotein-apolipoprotein B production in vivo in mice

In addition to its role in the uptake of apolipoprotein B (apoB)-containing lipoproteins, apoE promotes hepatic very low density lipoprotein-triglyceride (VLDL-TG) production in animal models. However, it is not known if apoE increases the amount of TG per VLDL particle or the number of VLDL particles secreted. VLDL-apoB production is a measure of the rate of VLDL particle secretion. We determined the effects of apoE deficiency and apoE overexpression on VLDL-apoB production in mice. [(35)S]methionine was injected into endogenously label VLDL-apoB and Triton WR-1339 was simultaneously injected to block the catabolism of VLDL. Compared with wild-type mice, the VLDL-apoB production rate was decreased by 33% in apoE-deficient mice. Conversely, VLDL-apoB production was increased by 48% in mice overexpressing apoE compared with controls. Nascent VLDL, obtained from post-Triton plasma, had a decreased, not increased, content of TG per apoB in the apoE-overexpressing group compared with the control group. This study demonstrates that hepatic apoE expression increases the output of VLDL triglyceride by increasing the production rate of VLDL-apoB, suggesting that hepatic apoE influences the number of VLDL particles secreted by the liver.     

Phenotyping of human apolipoprotein E from whole blood plasma by immunoblotting

Human apolipoprotein E (apoE) exists in the population in three common genetically determined isoforms, apoE-2, E-3, and E-4, that are coded for by three alleles epsilon-2, epsilon-3 and epsilon-4 at the apoE structural gene locus resulting in six phenotypes, three homozygotes (E 2/2, E 3/3, and E 4/4) and three heterozygotes (E 2/3, E 2/4, and E 3/4). A new procedure is described that allows identification of apoE isoforms and phenotypes from whole plasma or serum without the need for isolating apoE-containing lipoproteins or two-dimensional gel electrophoresis of serum. This rapid method combines cysteamine treatment of apoE in plasma, separation in parallel of cysteamine-treated and untreated hydrophobic serum proteins by charge-shift electrophoresis, and isoelectric focusing of apolipoproteins with immunoblotting. Compared to phenotyping of apoE after isolation of VLDL, the new procedure agreed in most cases and may be of special value in detecting apoE mutants that differ in their cysteine residues or either are spun off during isolation of lipoproteins or cofocus with other apoproteins and thus escape detection by conventional one-dimensional techniques. The method provides a simple tool to screen apoE isoforms that are known to have a major impact on individual plasma cholesterol levels.     

Regulation of apoprotein synthesis and secretion in the human hepatoma Hep G2. The effect of exogenous lipoprotein

The regulation of lipoprotein assembly and secretion at a molecular level is incompletely understood. To begin to identify the determinants of apoprotein synthesis and distribution among lipoprotein classes, we have examined the effects of chylomicron remnants which deliver triglyceride and cholesterol, and beta very low density lipoprotein (beta VLDL), which deliver primarily cholesterol, on apolipoprotein synthesis and secretion by the human hepatoma Hep G2. Hep G2 cells were incubated with remnants or beta VLDL for 24 h, the medium was changed and the cells then incubated with [35S]methionine. The secreted lipoproteins were separated by gradient ultracentrifugation and the radiolabeled apoproteins were isolated by immunoprecipitation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis and counted. Remnants caused a 14-fold, and beta VLDL a 7-fold, increase in VLDL apoprotein (apo) secretion; the apoB/apoE ratio in this class was unchanged. Preincubation with either of the lipoproteins also stimulated low density lipoprotein apoB secretion. Preincubation with beta VLDL, but not with remnants, significantly increased apoE and apoA-I secreted in high density lipoprotein (HDL). In addition, the apoE/apoA-I ratio precipitated from the HDL of beta VLDL-treated cells by anti-apoE was 2.2-fold higher than that precipitated by anti-apoA-I. There was no difference in the ratios precipitated from control HDL. This was due to the secretion of a lipoprotein, subsequently isolated by immunoaffinity chromatography, that contained predominantly apoE. When Hep G2 cells were preincubated with oleic acid alone, total apoprotein secretion was not altered. However, cholesterol-rich liposomes stimulated secretion of newly synthesized apoE, but not apoB, while apoA-I secretion was variably affected. Cholesterol-poor liposomes had no effect. Thus, lipid supply is a determinant of apoprotein synthesis and secretion, and cholesterol may be of particular importance in initiating apoprotein synthesis.