Isolation and characterization of the apolipoprotein E receptor from canine and human liver

Previous results have demonstrated that liver membranes possess two distinct lipoprotein receptors: a low density lipoprotein (LDL) receptor that binds lipoproteins containing either apolipoprotein (apo-) B or apo-E, and an apo-E-specific receptor that binds apo-E-containing lipoproteins, but not the apo-B-containing LDL. This study reports the isolation and purification of apo-B,E(LDL) and apo-E receptors from canine and human liver membranes. The receptors were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate and were partially purified by DEAE-cellulose chromatography. The apo-B,E(LDL) receptor was isolated by affinity chromatography on LDL-Sepharose. The apo-E receptor, which did not bind to the LDL-Sepharose column, was then purified by using an HDLc (cholesterol-induced high density lipoprotein)-Sepharose affinity column and an immunoaffinity column. Characterization of the receptors revealed that the hepatic apo-B,E(LDL) receptor is similar to the extrahepatic LDL receptor with an apparent Mr = 130,000 on non-reducing sodium dodecyl sulfate-polyacrylamide gels. The apo-E receptor was found to be distinct from the apo-B,E(LDL) receptor, with an apparent Mr = 56,000. The purified apo-E receptor displayed Ca2+-dependent binding to apo-E-containing lipoproteins and did not bind to LDL or chemically modified apo-E HDLc. Antibodies raised against the apo-B,E(LDL) receptor cross-reacted with the apo-E receptor. However, an antibody prepared against the apo-E receptor did not react with the apo-B,E(LDL) receptor. The apo-E receptor also differed from the apo-B,E(LDL) receptor in amino acid composition, indicating that the apo-E receptor and the apo-B,E(LDL) receptor are two distinct proteins. Immunoblot characterization with anti-apo-E receptor immunoglobulin G indicated that the apo-E receptor is present in the hepatic membranes of man, dogs, rats, and mice and is localized to the rat liver parenchymal cells.     

Uptake of canine beta-very low density lipoproteins by mouse peritoneal macrophages is mediated by a low density lipoprotein receptor

The receptor on mouse peritoneal macrophages that mediates the uptake of canine beta-very low density lipoproteins (beta-VLDL) has been identified in this study as an unusual apolipoprotein (apo-) B,E(LDL) receptor. Ligand blots of Triton X-100 extracts of mouse peritoneal macrophages using 125I-beta-VLDL identified a single protein. This protein cross-reacted with antibodies against bovine apo-B,E(LDL) receptors, but its apparent Mr was approximately 5,000 less than that of the human apo-B,E(LDL) receptor. Binding studies at 4 degrees C demonstrated specific and saturable binding of low density lipoproteins (LDL), beta-VLDL, and cholesterol-induced high density lipoproteins in plasma that contain apo-E as their only protein constituent (apo-E HDLc) to mouse macrophages. Apolipoprotein E-containing lipoproteins (beta-VLDL and apo-E HDLc) bound to mouse macrophages and human fibroblasts with the same high affinity. However, LDL bound to mouse macrophages with an 18-fold lower affinity than to human fibroblasts. Mouse fibroblasts also bound LDL with a similar low affinity. Compared with the apo-B,E(LDL) receptors on human fibroblasts, the apo-B,E(LDL) receptors on mouse macrophages were resistant to down-regulation by incubation of the cells with LDL or beta-VLDL. There are three lines of evidence that an unusual apo-B,E(LDL) receptor on mouse peritoneal macrophages mediates the binding and uptake of beta-VLDL: LDL with residual apo-E removed displaced completely the 125I-beta-VLDL binding to mouse macrophages, preincubation of the mouse macrophages with apo-B,E(LDL) receptor antibody inhibited both the binding of beta-VLDL and LDL to the cells and the formation of beta-VLDL- and LDL-induced cholesteryl esters, and binding of 125I-beta-VLDL to the cells after down-regulation correlated directly with the amount of mouse macrophage apo-B,E(LDL) receptor as determined on immunoblots. This unusual receptor binds LDL poorly, but binds apo-E-containing lipoproteins with normal very high affinity and is resistant to down-regulation by extracellular cholesterol.     

Binding of chylomicron remnants and beta-very low density lipoproteins to hepatic and extrahepatic lipoprotein receptors. A process independent of apolipoprotein B48

The ability of apolipoprotein (apo-) B48 to interact with lipoprotein receptors was investigated using three different types of lipoproteins. First, canine chylomicron remnants, which contained apo-B48 as their primary apoprotein constituent, were generated by the hydrolysis of chylomicrons with milk lipoprotein lipase. These apo-B48-containing chylomicron remnants are deficient in apo-E and reacted very poorly with apo-E receptors on adult dog liver membranes and the low density lipoprotein (apo-B,E) receptors on human fibroblasts. Addition of normal human apo-E3 restored the receptor binding activity of these lipoproteins. Second, beta-very low density lipoproteins (beta-VLDL) from cholesterol-fed dogs were subfractionated into distinct classes containing apo-E along with either apo-B48 or apo-B100. Both classes bound to the apo-B,E and apo-E receptors. Their binding was almost completely mediated by apo-E, as evidenced by the ability of the anti-apo-E to inhibit the receptor interaction. Third, beta-VLDL from type III hyperlipoproteinemic patients were subfractionated by immunoaffinity chromatography into lipoproteins containing apo-E plus either apo-B48 or apo-B100. Both subfractions bound poorly to apo-B,E and apo-E receptors due to the presence of defective apo-E2. However, the residual binding of the apo-B48-containing and apo-B100-containing human beta-VLDL was inhibited by the anti-apo-E. After lipase hydrolysis, apo-B100 became a more prominant determinant responsible for mediating receptor binding to the apo-B,E receptor. By contrast, lipase hydrolysis did not increase the binding activity of the apo-B48-containing beta-VLDL. These results indicate that apo-B48 does not play a direct role in mediating the interaction of lipoproteins with receptors on fibroblasts or liver membranes.     

Defective hepatic lipoprotein receptor binding of beta-very low density lipoproteins from type III hyperlipoproteinemic patients. Importance of apolipoprotein E

Apolipoprotein (apo-) E2 and beta-migrating very low density lipoproteins (beta-VLDL) (which were isolated from type III hyperlipoproteinemic subjects) both demonstrated defective binding to apo-E and apo-B,E receptors on dog liver membranes and to apo-B,E low density lipoproteins (LDL) receptors on fibroblasts. The defective binding activity of the apo-E2 and beta-VLDL varied from very poor to nearly normal. The ability of the beta-VLDL to interact with hepatic apo-E receptors was enhanced by the addition of normal apo-E3 to the beta-VLDL. Furthermore, cysteamine treatment of the apo-E2 in beta-VLDL enhanced binding of the beta-VLDL to both apo-E and apo-B,E receptors. The importance of apo-E in mediating the receptor binding of beta-VLDL to these receptors was confirmed by using monoclonal antibodies. The residual binding activity of beta-VLDL to apo-E and apo-B,E receptors was inhibited by greater than 90% with anti-apo-E, while the addition of anti-apo-B had little effect. The apo-B in the beta-VLDL was capable of binding to apo-B,E receptors after the hydrolysis of the beta-VLDL triglycerides with milk lipoprotein lipase. Lipase treatment yielded, two subfractions of beta-VLDL. One fraction (d = 1.02 to 1.03 g/ml) was enriched with apo-B100; the other fraction (d less than 1.006 g/ml) was enriched with apo-B48 and apo-E2. Significantly increased amounts of the apo-B100-enriched fraction bound to apo-B,E receptors. Inhibition of this binding caused by the addition of anti-apo-B indicated that the binding activity of this subfraction was mediated by apo-B100. The apo-B48-enriched fraction did not show a significant increase in receptor binding, suggesting that apo-B48 does not bind to these receptors. In a control experiment, it was shown that triglyceride-rich VLDL, which contain normal apo-E3 and apo-B100, bind significantly to both liver apo-E receptors and fibroblast apo-B,E receptors. This binding activity was inhibited by greater than 90% with anti-apo-E. Lipase hydrolysis of the VLDL did not further enhance their receptor-binding activity. These results demonstrate that apo-E, and not apo-B, is the major determinant mediating the receptor-binding activity of cholesterol-rich beta-VLDL and triglyceride-rich VLDL.     

A comparison of some immunological characteristics of very low density lipoproteins of normal and hypercholesterolemic rat sera.

The immunological characteristics of a very low density lipoproteins (VLDL) from normal and hypercholesterolemic rat sera were compared using polyspecific antisera to VLDL and high density lipoproteins (HDL) and monospecific antisera to apo-B, apo-C, apo-A-I, and apo-E. Ultracentrifugally isolated VLDL from normal serum were studied by immunodiffusion and found to contain both discrete and associated (with apo-B) apo-C and apo-E, probably in the form of lipid-containing lipoproteins. However, immunoelectrophoresis of whole serum revealed only an associated form of the liporpotein having pre-beta mobility (i.e., VLDL), suggesting that the presence of discrete lipoproteins in isolated VLDL, each containing a single apoprotein family, may represent ultracentrifugal artifacts. Ultracentrifugally isolated VLDL from diet-induced hypercholesterolemic rat serum contained only trace amounts of apo-C and large quantities of apo-E, both of which were totally associated with apo-B. VLDL isolated by ultracentrifugation from perfusate of normal and hypercholesterolemic livers contained only associated lipoprotein complexes made up of apo-B, apo-C, and apo-E in the former but only apo-B and apo-E in the latter. These data suggest that normal VLDL are secreted as lipoprotein complexes containing apo-B, apo-C, and apo-E, which may become destabilized in the circulation. However, VLDL from hypercholesterolemic serum shows a marked diminution in the quantity of apo-C as indicated by the relative incorporation of [3H]leucine in vivo and by polyacrylamide gel electrophoresis of apo-VLDL.     

Identification of homozygosity for a human apolipoprotein A-I variant

An apolipoprotein (apo) A-I variant, previously described in two Norwegian families (Schamaun et al. 1983. Hum. Genet. 64: 380-383), represents a mutation in apoA-I in which a single amino acid substitution of lysine for glutamic acid has taken place at residue 136. An offspring resulting from intermarriage between the two families is genotypically homozygous for this variant. He is the first individual discovered to be homozygous for any of the apoA-I variants. Analysis of lipid data collected from these families indicates one or more lipid abnormalities. The low density lipoproteins (LDL) of subjects having this apoA-I variant demonstrate a compositional abnormality. The plasma cholesterol concentration in the homozygous subject is low because of the extremely reduced levels of LDL and apoB, a property shared by some of his first-degree relatives. However, because of the presence of apoE2 in this family, it is not possible to definitively link these lipid abnormalities to the presence of the A-I variant.     

The effect of khellin and timefurone on secretion and catabolism of lipoproteins by cultured human and rabbit hepatocytes

Using human and rabbit hepatocyte cultures, the effects of khellin and timefurone on lipoprotein metabolism were studied with special reference to the following parameters: i) binding and degradation of 125I-labeled low density lipoproteins (LDL); ii) apoprotein B (apo-B) secretion measured by immunoenzymatic assay, iii) [35S]methionine labeled apo-B and apo-E within the composition of very low density lipoproteins (VLDL); iiii) total cholesterol synthesis and cholesterol secretion within the composition of VLDL. The therapeutic concentrations (0.1-10 micrograms/ml) of the above drugs had no appreciable effect on the binding and degradation of 125I-LDL but inhibited the secretion of apo-B VLDL, leaving the apo-E VLDL unaffected. This was paralleled with inhibition of cholesterol synthesis (by 30-50%) and VLDL secretion. These results suggest that khellin and timefurone mediate the hypolipidemic effect via the reduction of the intracellular synthesis of cholesterol and secretion of apo-B containing VLDL by hepatocytes.     

Lipolysis-induced degradation of apolipoproteins B and E of human very low density lipoproteins

We have found that in vitro lipolysis of human very low density lipoproteins (VLDL) by purified bovine milk lipoprotein lipase (LpL) promotes degradation of the apolipoprotein (apo) B moiety of VLDL. Analysis by sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis showed that lipolysis of VLDL by purified LpL for 1 h at 37 degrees C induced the selective degradation of the high Mr apo-B (apo-B-100) from most hypertriglyceridemic VLDL and from a few normolipidemic VLDL into several small fragments with molecular weights ranging from 90,000-490,000. No detectable degradation of apo-B occurred in control VLDL when incubated without LpL. The apo-E moiety of VLDL from certain individuals was also degraded following lipolysis of VLDL, and the extent of degradation of apo-B and -E in VLDL was varied among the individual VLDL. The major degradation products of apo-E, identified from the gel, were 31,000- and/or 28,000-Da species. In contrast to the apo-E moiety of VLDL, purified apo-E was not degraded when incubated with LpL. Incubation of low density lipoproteins (LDL) with LpL showed only a minimal effect on the apoproteins of LDL. When high density lipoprotein (HDL) was included in the lipolysis mixture as an acceptor of lipolytic surface remnants, the apoproteins of HDL remained unaltered, while the apo-B moiety of VLDL remnants in the mixture was degraded. Inclusion of protease inhibitors in the lipolysis mixture prevented the degradation of apo-B, but the hydrolysis of VLDL-triglyceride was minimally affected. A selective degradation of apo-B in VLDL also occurred during lipolysis of VLDL when VLDL was perfused through rat hearts. These results suggest that conformational changes in apo-B and apo-E caused by VLDL lipolysis may increase the susceptibility of apo-B and apo-E to degradation by the proteases co-isolated with VLDL. The consequences of the lipolysis-induced degradation of apo-B and apo-E on changes in metabolic properties of VLDL remnants remain to be determined.     

The catabolism of human and rat very low density lipoproteins by perfused rat hearts.

The catabolism of human and rat 125I-labelled very low density lipoproteins (VLDL) was compared by perfusing the lipoproteins through beating rat hearts. Triacylglycerol was removed from the VLDL to a greater extent than the protein moiety, leaving remnants containing relatively more apo-B and less apo-C. The change in apo-C content of the remnants correlated with the loss of triacylglycerol. The extent of removal of triacylglycerol from the rat and human VLDL was similar and in most cases appeared to saturate the heart lipoprotein lipase. The remnants were slightly smaller in size than the VLDL, and included particles which appeared to be partially emptied. In addition to remnants of d less than 1.019 g/ml, iodinated lipoproteins derived from rat and human VLDL were recovered at d 1.019-1.063 and 1.063-1.21 g/ml. The former contained largely cholesterol and cholesteryl esters, while phospholipids were the dominant lipid in the latter. An average of 40% of the 125I-labelled apoprotein lost from the VLDL was associated with the perfused hearts. Very little d 1.019-1.063 g/ml lipoprotein was produced from low (physiological) concentrations of rat VLDL, most of the lipoprotein being removed by the heart. However, lipoproteins of density 1.019-1.063 g/ml were formed from human VLDL at all concentrations in the perfusate, as well as from higher concentrations of the rat VLDL. Agarose gel filtration of lipoproteins following heart perfusion with human VLDL revealed large aggregates containing particles which resemble low density lipoproteins (LDL) in electron microscopic appearance and apoprotein composition, since they contain largely apo-B. These data suggest that at normal concentrations rat VLDL are almost completely catabolised and taken up by the heart without the formation of LDL, while LDL is produced from human VLDL at all concentrations.     

VLDL apoprotein secretion and apo-B mRNA level in primary culture of cholesterol-loaded rabbit hepatocytes

Incubation of cultured rabbit hepatocytes with beta very low density lipoproteins (beta-VLDL) induces a dose-dependent increase in cell cholesterol (CH) content and VLDL apoprotein (apo) B and E secretion without change in apo-B mRNA level. These data suggest that beta-VLDL may exert a stimulatory effect on hepatic apo-B production at the co-translational and/or posttranslational level.     

Structure and function of human low density lipoproteins. Studies using proteolytic cleavage by plasma kallikrein

Kallikrein digestion of human low density lipoproteins (LDL) has recently been shown to result in the degradation of apolipoprotein B (apo-B) into four major fragments, two of them being B-26 and B-74, which have been reported to be present in the LDL of some individuals. We studied the binding of kallikrein-treated LDL to human fibroblasts; digestion did not affect binding. Digested LDL was not taken up by macrophages, showing that it behaved like normal LDL. The activation of acyl-CoA cholesterol acyltransferase by LDL in fibroblasts was also not altered by kallikrein digestion. When delipidated LDL was treated with kallikrein, apo-B was digested into very small fragments, indicating that kallikrein can cleave apo-B at sites other than those which result in the formation of B-26 and B-74. The partial delipidation of LDL with heptane also resulted in more extensive digestion of apo-B, although binding to cells was unaffected. These studies suggest that the cholesterol core maintains the proper orientation of apo-B in the LDL particle and that kallikrein may be used as a tool to elucidate the association of apo-B and lipids in the LDL particle.     

Ultrastructural localization of apo-b and apo-c binding to very low density lipoproteins in rat liver.

Hepatic synthesis of apo-B and apo-C and their binding to nascent very low density lipoproteins (VLDL) have been studied in fat-fed rats. Apolipoproteins were located in hepatocyte organelles by light and electron microscopy after immunoenzymatic staining using peroxidase-conjugated antibodies. Our results indicate that apo-B and apo-C are synthesized by membrane-bound ribosomes. Both apoproteins seem to be adsorbed simultaneously to the lipid core of VLDL in the lumen of the endoplasmic reticulum channels, at the junction zone between rough and smooth endoplasmic reticulum. Some additional protein presumably binds nascent VLDL in the Golgi apparatus as judged by the strong positive reaction of lipoprotein particles with peroxidase-labeled antibodies. Finally our data show that significant amounts of apo-B and apo-C are bound to the sinusoidal plasma membrane in fed rat livers which probably represent remnants of lipoprotein of intestinal origin since membrane-bound apolipoproteins virtually disappeared 24 h after lymphatic duct cannulation. It is suggested that nascent VLDL (apo-C poor) could be enriched in apo-C from lipoprotein remnants at the space of Disse.     

Common and rare gene variants affecting plasma LDL cholesterol

The plasma level of LDL cholesterol is clinically important and genetically complex. LDL cholesterol levels are in large part determined by the activity of LDL receptors (LDLR) in the liver. Autosomal dominant familial hypercholesterolaemia (FH) - with its high LDL cholesterol levels, xanthomas, and premature atherosclerosis - is caused by mutations in either the LDLR or in APOB - the protein in LDL recognised by the LDLR. A third, rare form - autosomal recessive hypercholesterolaemia - arises from mutations in the gene encoding an adaptor protein involved in the internalisation of the LDLR. A fourth variant of inherited hypercholesterolaemia was recently found to be associated with missense mutations in PCSK9, which encodes a serine protease that degrades LDLR. Whereas the gain-of-function mutations in PCSK9 are rare, a spectrum of more frequent loss-of-function mutations in PCSK9 associated with low LDL cholesterol levels has been identified in selected populations and could protect against coronary heart disease. Heterozygous familial hypobetalipoproteinaemia (FHBL) - with its low LDL cholesterol levels and resistance to atherosclerosis - is caused by mutations in APOB. In contrast to other inherited forms of severe hypocholesterolaemia such as abetalipoproteinaemia - caused by mutations in MTP - and homozygous FHBL, a deficiency of PCSK9 appears to be benign. Rare variants of NPC1L1, the gene encoding the putative intestinal cholesterol receptor, have shown more modest effects on plasma LDL cholesterol than PCSK9 variants, similar in magnitude to the effect of common APOE variants. Taken together, these findings indicate that heritable variation in plasma LDL cholesterol is conferred by sequence variation in various loci, with a small number of common and multiple rare gene variants contributing to the phenotype.     

Stoichiometric binding of apolipoprotein B-specific monoclonal antibodies to low density lipoproteins

The structure of apolipoprotein B and its stoichiometry on plasma lipoproteins has been a major issue and one refractory to a variety of analyses. Immunochemical analyses represent an independent approach. Examinations of apolipoprotein B (apo-B) epitopes on human plasma low density lipoproteins (LDL) using monoclonal antibodies have consistently revealed the existence of extensive apo-B heterogeneity. In the present study, we have addressed the solution of the stoichiometry problem using quantitative analysis of the maximum number of identical antibodies that can be bound per LDL particle in which we take into account this ligand heterogeneity. We have estimated the molecular weight of apo-B by quantifying the number of times a given apo-B epitope is expressed on the surface of LDL. The quantitative binding of eight previously characterized monoclonal antibodies was measured in a fluid phase radioimmunoassay. The results were analyzed by Scatchard analysis and expressed on the basis of independent measurements of the maximum amount of LDL that could be bound by each antibody. Affinity constants for each of the eight antibodies varied between 8.5 X 10(7) and 80 X 10(7) M-1. For these same antibodies, the concentration of maximally bound antibody at a normalized LDL concentration of 1000 ng/ml was estimated to be 0.9-1.8 nM with a mean of 1.23 nM. Adopting a molecular mass from physicochemical analysis for LDL apo-B of 550,000 daltons, the molar ratio between bound antibody and LDL varied between 0.5 and 1.2 (mean 0.75 +/- 0.15). The results supported the hypothesis that apo-B is present as a single large molecular weight polypeptide in LDL.     

Uptake of irradiated human low density lipoprotein by cultured Chinese hamster V79 cells

Specific binding and degradation of native and gamma-rays irradiated (100-2000 rad; 100 rad/min; 137Cs) human low density lipoprotein by Chinese hamster V79 cells and mouse peritoneal macrophage line, J774G were studied. Low density lipoproteins were labeled with 125I for studying the specific binding and subsequent degradation. The specific binding and degradation of irradiated 125I-low density lipoproteins (mixed with irradiated native lipoprotein) by Chinese hamster V79 cells are considerably reduced. The uptake depends on the concentration of thiobarbutaric acid-reactive products generated in the irradiated lipoproteins which in turn depends on the concentration of carotenoids. In contrast the rate of uptake of oxidized low density lipoproteins is enhanced by Chinese hamster macrophages. The alteration in the surface amino groups of apo-B of low density lipoprotein either due to direct damage of peptide bonds by gamma-rays or via interaction with lipid peroxides (generated in the core upon irradiation) are invoked as possible mechanisms for the reduction in specific binding and subsequent degradation by V79 cells.     

Heterogeneity of human plasma lipoprotein (a). Isolation and characterization of the lipoprotein subspecies and their apoproteins

Lipoprotein (a) (Lp(a] from the plasma of normolipidemic human donors was isolated by rate zonal and isopycnic density gradient ultracentrifugation. The final preparations usually contained varying amounts of isopycnic low-density lipoproteins (LDL), which were totally removed either by heparin-Sepharose column chromatography or by chromatofocusing. The Lp(a) preparations exhibited both inter- and intraindividual density heterogeneity which was accounted for by the differences in their protein and lipid composition. In addition, there was heterogeneity in the size of apoprotein (a) (apo(a] which was found to be linked to apoprotein B (apo-B) through disulfide bonds. Three different apo(a) species were obtained; they had a size either smaller, equal to, or larger than apo-B-100, the protein moiety of LDL. The apo(a) that was smaller than apo-B resided in a low-density Lp(a) particle whose peak was in the 1.019-1.063 g/ml density range. The larger apo(a) was a component of the dense Lp(a) particle and was responsible for the increased density in this Lp(a) species. The third apo(a) which was equivalent in size to apo-B resided in a density range intermediate between the other two Lp(a)s. It is concluded that Lp(a) may differ not only from one individual to another, but also within the same individual who may have more than one Lp(a) species. Part of this heterogeneity may be accounted for by differences in the (a) polypeptide.     

Rabbit liver secretes oxidated lipoproteins in experimental atherosclerosis]

It is shown in rabbits, that alimentary hypercholesterolemia proceeds with increasing lipid peroxidation in liver homogenate, blood serum and apo-B-containing lipoproteins. It is established in the model of liver perfusion in rabbits, that liver cells produce apo-B-containing level of lipid peroxidation. The lipid peroxidation increases in perfusate and in the fraction of lipoproteins (d less than 1,065 g/cm3) from this perfusate. Lipid peroxidation can interfere in the changing of physicochemical characteristics of lipoproteins at the stage of synthesis and secretion of lipoproteins by liver cells.     

Intrahepatic assembly of very low density lipoproteins. Varied synthetic response of individual apolipoproteins to fasting

Hepatocytes obtained from rats fed for 3 days chow (control) or drinking water only (fasted) were used to examine how metabolic state affects lipogenesis, apolipoprotein synthesis, and the capacity to secrete de novo synthesized triacylglycerol. The secretion of triacylglycerol (mass and 3H-labeled via 3H2O incorporation) by both groups of cells was constant for 30 h. Moreover, cells from fasted rats secreted triacylglycerol at rates which were markedly reduced (mass -84%; 3H-labeled -91%). To assess the relative capacities of the two groups of hepatocytes to augment triacylglycerol secretion in response to stimulated lipogenesis, cells were incubated with increasing concentrations of glucose. Control cells responded to glucose by increasing equally the synthesis and secretion of [3H] triacylglycerol. When cells from fasted rats were challenged with glucose, triacylglycerol secretion was not increased. Rather, it accumulated intracellularly. Double-reciprocal plot analysis of the capacity to augment triacylglycerol secretion in response to glucose showed that cells from fasted rats had a greater than 10-fold decrease in V'max. Moreover, fasting changed the synthesis and secretion of apolipoproteins selectively: secretion of low molecular weight apo-B was decreased 50%, large molecular weight apo-B was unchanged, and apo-E was increased 2-4-fold. Analysis of the lipoproteins from both groups of cells on Bio-Gel A-50m showed that the very low density lipoprotein secreted by cells from fasted rats was smaller. In addition, all of the increased de novo synthesized apo-E secreted by cells from fasted rats eluted after the triacylglycerol-rich lipoproteins. The combined data show that: 1) the synthesis of individual very low density lipoprotein apolipoproteins is independently regulated, and 2) the synthesis (availability) of apo-B determines the capacity of the hepatocyte to assemble/secrete triacylglycerol-rich very low density lipoprotein.     

Physico-chemical properties of low density lipoproteins isolated in an equilibrium density gradient

The tryptophanyls of total low density lipoproteins (LDL) (1.006-1.063 g/ml) from coronary heart disease (CHD) patients and subjects without CHD signs had different accessibility to fluorescence quenchers (I-and acrylamide). LDL were separated into subfractions in equilibrium density gradient. The coefficient of extinction , quantum yield and other spectral characteristics of LDL intrinsic fluorescence, rotational mobility of maleimide spin labels and fatty acid spin probe were different in LDL subfractions from healthy subjects. LDL subfractions with hydrated density 1.045-1.05 g/ml bound to B,E-receptors of cultured fibroblasts more effectively than did subfractions with density 1.01-1.03 g/ml. Structural differences of apo-B in the particles with different lipid to protein ratio are supposed.