Binding of rat chylomicrons and their remnants to the hepatic low-density-lipoprotein receptor and its role in remnant removal.

Binding and uptake of rat chylomicrons of different metabolic stages by the hepatic low-density-lipoprotein (LDL) receptor were studied. Pure chylomicrons, characterized by apolipoprotein B-48 devoid of contaminating B-100, were labelled in their cholesteryl esters. Lymph chylomicrons and serum chylomicrons, enriched in apolipoprotein E and the C-apolipoproteins, bound poorly to rat hepatic membranes. In contrast, chylomicron remnants, containing the apolipoproteins B-48 and E, bound with high affinity. Specific binding of remnants was virtually completely competed for by LDL free of apolipoprotein E. In addition, in ligand blots both remnants and LDL associated with the same protein with an Mr characteristic of the LDL receptor. Uptake of remnants during a single pass through isolated perfused rat livers was decreased to about 50% by an excess of LDL. It is concluded that rat chylomicron remnants are a ligand of the hepatic LDL receptor. The much higher affinity as compared with LDL is mediated by apolipoprotein E but not B-48, and is inhibited by the C-apolipoproteins. This explains why serum chylomicrons are not taken up by the liver, whereas remnants are rapidly removed from the circulation. Results from experiments in vivo suggest that the LDL receptor makes an important contribution to the hepatic uptake of remnants and may be the principal binding site of the liver responsible for remnant removal.     

The uptake of chylomicron remnants and very low density lipoprotein remnants by the perfused rat liver

The regulation of the hepatic uptake of chylomicron remnants and very-low-density lipoprotein (VLDL) remnants was studied in the rat using a nonrecirculating liver perfusion system. The hepatic removal of remnant lipoproteins was shown to be by receptor-mediated processes since the concentration-dependent uptake was saturable and reductive methylation of the particles reduced the uptake of each lipoprotein by two-thirds. Treatment of liver donor rats with 17 alpha-ethinyl estradiol resulted in a 2-fold increase in the hepatic uptake of VLDL remnants, while cholesterol feeding of liver donor rats caused complete suppression of the receptor-mediated uptake of VLDL remnants. Chylomicron remnant removal was unaffected by estradiol administration and only slightly diminished by cholesterol feeding. The results of competition studies also indicated that a specific chylomicron remnant receptor exists in the liver. Apoprotein E was shown to be required for the receptor-mediated uptake of both remnant lipoproteins. Chylomicron remnants which contained no apoprotein E and VLDL remnants which contained reductively methylated apoprotein E were removed by the liver to about one-third of the extent of native particles. Thus the hepatic uptake of remnant lipoproteins occurs by receptor-mediated processes and the specific removal of both particles is mediated by apoprotein E. In addition, the uptake of VLDL remnants is regulated by the same factors that control hepatic low-density lipoprotein removal, while chylomicron remnant removal is unaffected by these factors.     

Effects of cholesterol content on the metabolism of protein-free emulsion models of lipoproteins

After intravenous injection, emulsions with compositions similar to chylomicrons behaved metabolically as described for chylomicrons, with faster removals of triacylglycerols than cholesteryl esters from the blood after injection into rats, and with greater uptakes of cholesteryl esters than triacylglycerols by the liver. In contrast, emulsions with a high content of free cholesterol showed equal removal rates from the blood of triacylglycerols and cholesteryl esters; and similar uptakes by the liver. This pattern of metabolism was that expected for a chylomicron core remnant particle. Emulsions poor in cholesteryl ester but rich in free cholesterol showed remnant-like behavior, whereas emulsions rich in cholesteryl ester but poor in free cholesterol were metabolized like nascent chylomicron particles. The amount of free cholesterol appeared to regulate metabolism by affecting the binding of apolipoproteins to the particle surface. Emulsions with a high content of free cholesterol bound less A-I, A-IV and C apolipoproteins, and the relative amount of apolipoprotein E was increased. All of these effects are consistent with the metabolic differences between chylomicrons and remnant particles, suggesting that the amount of free cholesterol plays a regulatory role in chylomicron metabolism.     

Composition, removal and metabolic fate of chylomicrons derived from diabetic rats

Tri[14C]acylglycerol-labelled chylomicrons, obtained from cannulated mesenteric lymph of streptozotocin-diabetic donor rats, when intravenously injected into non-diabetic recipient rats, disappeared from the circulation at a significantly slower rate than similarly prepared tri[14C]acylglycerol chylomicrons from non-diabetic donor rats (t1/2, 5.6 +/- 0.7 vs. 3.2 +/- 0.5 min-1, P less than 0.02). The appearance of labelled lipolysis products among plasma lipids (free fatty acid, cholesterol ester and phospholipid fractions) was delayed, indicating decreased availability for lipolysis of the chylomicron-borne triacylglycerol of diabetic origin. Tissue distribution of triacylglycerol, 15 min after the injection of chylomicrons to recipient rats, disclosed a 4-5-fold increase in uptake by muscles (heart and diaphragm) in relation to adipose tissues (epididymal and perirenal sites), in the case of chylomicrons of diabetic derivation. Since a large share of the chylomicron triacylglycerol was taken up by the liver, this tissue was perfused with chylomicron 'remnants' prepared by partial in vitro lipolysis with purified lipoprotein lipase. The 'remnants' of diabetic derivation were taken up by the liver at a 2-3-fold slower rate than those of non-diabetic origin. Chylomicrons derived from diabetic rats were found to be similar in size but markedly depleted of E apolipoproteins as determined by SDS-polyacrylamide gel electrophoresis, isoelectric focussing and a specific immunoassay. Decreases were also seen in A-I apolipoproteins by immunoassay and isoelectric focussing. Chylomicron 'remnants' were also markedly apolipoprotein E-deficient. In vitro incubation of the 'diabetic remnants' with high-density lipoproteins raised their apolipoprotein E content approx. 3-fold and considerably increased their hepatic uptake. Injection of intact chylomicrons preincubated with high-density lipoproteins likewise increased their in vivo removal rate toward the range of that of 'non-diabetic' chylomicrons. We conclude that diabetes-induced changes in the apolipoprotein composition of the chylomicrons and chylomicron remnants play an important role in their removal from the circulation. It appears that their recognition pattern is altered, reducing their ability to interact with receptor sites in the peripheral tissues and the liver, respectively.     

The kinetic parameters of the uptake of very-low-density lipoprotein remnant cholesteryl esters by perfused rat livers

The aim of this study was to determine the kinetic parameters of the hepatic uptake of VLDL remnant cholesteryl esters. Rat livers were perfused in situ with a broad range of remnant [3H]cholesteryl ester concentrations of known specific radioactivity. Following exactly 3 min of perfusion, hepatic lipids were extracted and labelled cholesteryl esters were separated by thin-layer chromatography and counted. The rate of cholesteryl ester uptake was a saturable process and the apparent kinetic parameters were determined from the Lineweaver-Burk plot of the data. Km and Vmax were calculated to be 72 microM and 35 nmol cholesteryl ester/min per g liver, respectively. For the purpose of comparison, we have expressed our kinetic parameters in terms of number of particles (Vmax = 0.022 nmol particles/min per g liver and Km = 45 nM) and compared our values with those obtained with chylomicron remnants by another group of investigators (Sherrill, B.C., Innerarity, T.L. and Mahley, R.W. (1980) J. Biol. Chem. 255, 1804-1807). We found that the maximal capacity for the removal of VLDL particles was similar to what was observed with rat chylomicron remnants. In contrast, the Km for the uptake process of VLDL remnant particles was approximately four times higher than that of rat chylomicron remnant particles. Our results are consistent with the hypothesis that hepatic removal of both chylomicron and VLDL remnants is mediated by the same receptor, but suggest that the affinity of VLDL remnants for the hepatic removal process is substantially lower, possibly due to structural differences between the two remnant particles.     

Distribution of C apolipoproteins between the vascular and lymph compartments of the rat

This study has investigated the kinetics of transfer of C apolipoproteins between the vascular and lymph compartments of the rat. Very-low-density lipoprotein, labeled with [125I]apolipoprotein C, was injected intravenously into lymph duct-cannulated rats and the redistribution of radioactivity between lymph and plasma followed at frequent intervals for 3 h. Equilibration between the two compartments was rapid (10-15 min), and thereafter removal from both compartments continued at similar rates. Specific radioactivity determinations showed that lymph C-III-0, C-III-3, and C-III-2,1 apolipoproteins rapidly reached values identical to those of corresponding plasma C apolipoproteins and the interrelationship between the curves were consistent with precursor-product relationships in which all, or most, of the product (lymph apolipoprotein C-III) was derived from the precursor (plasma). However, the specific radioactivity curves for C-II peptide did not cross; the lower value for lymph C-II apolipoprotein suggests that, unlike C-III apolipoproteins, a substantial proportion (approx. 40%) of lymph C-II peptide is not derived from the plasma compartment. The most likely source of the unlabeled lymph apolipoprotein C-II is synthesis and secretion from the intestine.     

Post-secretory acquisition of apolipoprotein E by nascent rat hepatic very-low-density lipoproteins in the absence of cholesteryl ester transfer

Previous work has shown that nascent hepatic very-low-density lipoproteins (VLDL) in the rat are biosynthesized without the obligatory co-factor (apolipoprotein C-II) for lipoprotein lipase-mediated hydrolysis of their core triacylglycerols. Upon secretion, apolipoproteins C-II and C-III are rapidly transferred to the particles from high-density lipoprotein (HDL) within the space of Disse and upon the entry into the plasma. Here we extend those studies to include observations on the apolipoprotein E content and lipid composition of nascent hepatic VLDL before and after exposure to plasma components. We have elected to use hepatic secretory vesicle VLDL rather than liver perfusate VLDL as truly representative of the nascent lipoproteins. Nascent VLDL from fed rats has an apolipoprotein B/E ratio of 6.6 ± 0.5, whereas that from fasted animals is 13.9 ± 2.3. Incubation of nascent VLDL from fed and fasted rats with d > 1.063 g/ml rat serum, HDL or the d > 1.21 g/ml fraction resulted in a mass transfer of apoliproprotein E to the VLDL such that the apolipoprotein B/E ratio decreased to at least that of serum VLDL (3.4 ± 0.3). The d > 1.21 g/ml fraction appeared to contain a species of apolipoprotein E which most actively transferred to VLDL. The acquisition of apolipoprotein E by nascent secretory vesicle VLDL was attended by a loss of phospholipids, particularly the C₄₀ (stearoylarachidonyl) molecular species, and an increase in the cholesterol-to-phospholipid ratio from 0.11 ± 0.01 to 0.18 ± 0.03. No evidence was obtained to suggest a simultaneous acquisition of cholesteryl esters upon incubation of nascent VLDL with VLDL-free serum. We conclude that nascent hepatic VLDL is modified after secretion by acquisition of apolipoproteins C-II, C-III and E with a concomitant loss of phospholipids.     

Hepatic uptake of chylomicrons and triglyceride emulsions in rats fed diets of differing fat content

The hepatic removal of plasma chylomicrons was determined for rats fed the following diets: a) containing no triglyceride, b) regular chow diet with 4.5% of its mass as lipid and, c) a corn oil-supplemented chow with triglyceride accounting for 20% of the mass. The fractional hepatic uptake of either radiolabeled chylomicrons or a triglyceride emulsion was reciprocally related to the amount of lipid in the diet. The animals receiving only carbohydrate and protein calories had the most active hepatic uptake of particulate triglyceride and were observed to have a significant decrease in the plasma concentration of the C apolipoproteins. The addition of either C-I, C-II, or C-III apoproteins to the triglyceride emulsion prior to intravenous injection produced a significantly lower hepatic triglyceride recovery of emulsions containing apoC-III. When the plasma of animals fed a fat-free diet was supplemented with human C-III-1 apolipoprotein, the distribution into the liver of either enterally administered fatty acid or parenteral triglyceride was diminished. The triglyceride content in the liver of the rats fed fat-free or corn oil-supplemented diets was significantly greater than that of the control rats and composition was somewhat similar to that of lymph triglyceride. The studies indicate an important influence of dietary lipid on both the partition of plasma triglyceride into the liver and the steady state hepatic triglyceride content.     

Chylomicron-chylomicron remnant clearance by liver and bone marrow in rabbits. Factors that modify tissue-specific uptake

The metabolism of [14C]cholesterol- and [3H]retinol-labeled chylomicrons obtained from canine thoracic duct or rabbit mesenteric lymph was investigated in normal fasted rabbits. Typically, 70-80% of the chylomicrons injected into the rabbits were cleared from the plasma in 20 min, and their uptake was accounted for principally by the liver and the bone marrow. Surprisingly, the bone marrow was a major site of uptake; the uptake ranged from about half that of the liver to a nearly equal amount. The importance and specificity of chylomicron-chylomicron remnant uptake by the bone marrow were established by demonstrating that (a) bone marrow throughout the body accumulated these lipoproteins, (b) the level of uptake was consistent regardless of how the values were calculated or how the chylomicrons were prepared, (c) the uptake represented specific binding, and (d) radiolabeled intestinal lipoproteins induced in vivo delivered cholesterol and retinol to the marrow. Electron microscopic examination of the rabbit bone marrow established that perisinusoidal macrophages uniquely accounted for the uptake of the chylomicrons. Whereas liver cleared a variety of both triglyceride-rich lipoproteins (chylomicrons, chylomicron remnants, and very low density lipoproteins) and cholesterol-rich lipoproteins (beta-very low density lipoproteins and high density lipoproteins containing apolipoprotein E), bone marrow uptake appeared to be restricted to the triglyceride-rich lipoproteins. More chylomicron remnants (generated in a hepatectomized rabbit) were cleared by the liver than by the bone marrow, and the addition of excess apolipoprotein E to chylomicrons resulted in their preferential uptake by the liver. The role of chylomicron-chylomicron remnant delivery of lipids or lipid-soluble vitamins to rabbit bone marrow is open to speculation, and whether triglyceride-rich lipoprotein uptake occurs to a significant extent in the bone marrow of humans remains to be determined.     

Human chylomicron apolipoprotein metabolism.

Chylomicron apolipoprotein metabolism was studied utilizing chylomicrons isolated from the pleural fluid of a patient with a recurrent chylous pleural effusion. Chylomicrons contained apolipoproteins A-I, A-II, B, C-I, C-II, C-III, D, E, and albumin. Following intravenous injection of [¹²⁵I] chylomicrons, almost all of the A apolipoprotein radioactivity was recovered in high density lipoproteins, while only a small amount of the B apolipoprotein radioactivity was recovered in low density lipoproteins. These observations indicate that intestinal chylomicron A apolipoproteins serve as precursors for plasma high density lipoprotein A apolipoproteins and only a small fraction of chylomicron apolipoprotein B is metabolized to form low density lipoprotein apolipoprotein B.     

Uptake and degradation of human very-low-density lipoproteins by rat liver endothelial cells in culture

Rat liver endothelial cells in primary cultures take up and degrade 125I-labelled human very-low-density lipoproteins (VLDL) in a saturable fashion at physiological triacylglycerol concentrations. The iodinated VLDL are readily taken up by the freshly isolated endothelial cells and degradation products appear in the medium about 30 min after the addition of VLDL to the cultures. Uptake and degradation at 37 degrees C are effectively inhibited by unlabelled human VLDL, low-density lipoproteins (LDL), high-density lipoproteins and lymph chylomicrons, but only modestly by acetylated LDL. Purified apolipoproteins E and C-III:1 also compete with the uptake of iodinated VLDL, but when degradation was studied for longer periods of time, such a competition could not be demonstrated. This may be due to the fact that the added apolipoproteins become associated with the lipoproteins. In binding experiments at 7 degrees C, iodinated apolipoprotein C III:1 bound to the liver endothelial cells in a manner characteristic of receptor binding with a dissociation constant of 0.5 microM. This binding could not only be inhibited by unlabelled apolipoprotein C-III:1 but also by unlabelled apolipoprotein E. The results indicate that rat liver endothelial cells carry receptors for VLDL and that these recognize the apolipoproteins E, C-III and B on the lipoprotein surface. Considering the large endothelial surface and high blood flow through the liver, significant quantities of lipoproteins can be taken up and degraded, thus influencing the levels of circulating lipoproteins in the in vivo situation.     

Metabolism of chylomicrons by the isolated rat liver

Isolated livers perfused with washed corn oil chylomicrons labeled in vivo with palmitic acid-1-(14)C removed a large proportion of the chylomicrons. Slices from these livers oxidized chylomicron fatty acid esters to both carbon dioxide and acetoacetate. The liver slices also generated free fatty acids from chylomicron lipids and converted chylomicron triglycerides to phospholipids. Similar activities were observed in rat liver slices prepared shortly after the intravenous administration of chylomicrons to intact rats. The observed chylomicron uptake and lipid conversions were similar in livers from both fed and fasted rats. Fasting increased the oxidation of chylomicron fatty acid esters by livers labeled in vivo and by perfusion. In livers removed from intact rats given labeled chylomicrons, the triglyceride-(14)C to phospholipid-(14)C ratio was high, a finding unexpected if the liver had acquired this (14)C by removal of circulating fatty acids formed by extrahepatic lipolysis. These results demonstrate the ability of the liver to remove and utilize chylomicrons directly and suggest that direct removal accounts for a significant portion of the chylomicron fatty acids utilized by the liver of intact rats.     

Plasma clearance and liver uptake of chylomicron remnants generated by hepatic lipase lipolysis: evidence for a lactoferrin-sensitive and apolipoprotein E-independent pathway

Chylomicrons labeled with [3H]cholesterol and [14C]triglyceride fatty acids were lipolyzed by hepatic lipase (HL) in vitro and then injected intravenously into normal mice fed low- or high-fat diets, and into apolipoprotein (apo) E-deficient mice. In normal mice fed the high-fat diet and injected with non-lipolyzed chylomicrons, the plasma clearance and hepatic uptake of the resulting [3H]cholesterol-labeled remnants was markedly inhibited. In contrast, chylomicrons lipolyzed by HL were taken up equally rapidly by the livers of mice fed the low- and high-fat diets. The removal of non-lipolyzed chylomicrons lacking apoE from the plasma of apoE-deficient mice was inhibited, but not the removal of chylomicrons lipolyzed by HL. Pre-injection of lactoferrin into normal mice inhibited the plasma clearance of both non-lipolyzed chylomicrons and chylomicrons lipolyzed by HL. The removal of HL from the surface of the lipolyzed particles by proteolytic digestion did not affect their rapid uptake, indicating that the hepatic recognition of the lipoproteins was not mediated by HL. These observations support previous findings that phospholipolysis of chylomicrons by hepatic lipase generates remnant particles that are rapidly cleared from circulation by the liver. They also support the concept that chylomicron remnants can be taken up by the liver by an apolipoprotein E-independent mechanism. We hypothesize that this mechanism is modulated by the remnant phospholipids and that it may involve their interaction with a phospholipid-binding receptor on the surface of hepatocytes such as the class B scavenger receptor BI.     

The estradiol-stimulated lipoprotein receptor of rat liver. A binding site that membrane mediates the uptake of rat lipoproteins containing apoproteins B and E

Hepatic catabolism of lipoproteins containing apolipoproteins B or E is enhanced in rats treated with pharmacologic doses of 17 alpha-ethinyl estradiol. Liver membranes prepared from these rats exhibit an increased number of receptor sites that bind 125I-labeled human low density lipoproteins (LDL) in vitro. In the present studies, this estradiol-stimulated hepatic receptor was shown to recognize the following rat lipoproteins: LDL, very low density lipoproteins obtained from liver perfusates (hepatic VLDL), and VLDL-remnants prepared by intravenous injection of hepatic VLDL into functionally eviscerated rats. The receptor also recognized synthetic lamellar complexes of lecithin and rat apoprotein E as well as canine high density lipoproteins containing apoprotein E (apo E-HDLc). It did not recognize human HDL or rat HDL deficient in apoprotein E. Much smaller amounts of this high affinity binding site were also found on liver membranes from untreated rats, the number of such sites increasing more than 10-fold after the animals were treated with estradiol. Each of the rat lipoproteins recognized by this receptor was taken up more rapidly by perfused livers from estrogen-treated rats. In addition, enrichment of hepatic VLDL with C-apoproteins lowered the ability of these lipoproteins to bind to the estradiol-stimulated receptor and diminished their rate of uptake by the perfused liver of estrogen-treated rats, just as it did in normal rats. The current data indicate that under the influence of pharmacologic doses of estradiol the liver of the rat contains increased amounts of a functional lipoprotein receptor that binds lipoproteins containing apoproteins B and E. This hepatic lipoprotein receptor appears to mediate the uptake and degradation of lipoproteins by the normal liver as well as the liver of estradiol-treated rats. The hepatic receptor bears a close functional resemblance to the LDL receptor previously characterized on extrahepatic cells.     

Hydrolysis of chylomicron triacylglycerol by endothelium-bound lipoprotein lipase. Effect of decreased apoprotein C-II/C-III ratio.

Chylomicrons with a decreased ratio of C-II/C-III apoproteins on their surface produced by the addition of apoproteins C-III-0 or C-III-3 to intact rat lymph chylomicrons. These chylomicrons inhibited the activity of soluble lipoprotein lipase in vitro, but had no effect on the activity of the endothelium-bound enzyme in the perfused heart.     

Effect of the apolipoprotein A-IV Q360H polymorphism on postprandial plasma triglyceride clearance

Apolipoprotein (apo)A-IV is synthesized in the small intestine during fat absorption and is incorporated onto the surface of nascent chylomicrons. In circulation, apoA-IV is displaced from the chylomicron surface by high density lipoprotein-associated C and E apolipoproteins; this exchange is critical for activation of lipoprotein lipase and chylomicron remnant clearance. The variant allele A-IV-2 encodes a Q360H polymorphism that increases the lipid affinity of the apoA-IV-2 isoprotein. We hypothesized that this would impede the transfer of C and E apolipoproteins to chylomicrons, and thereby delay the clearance of postprandial triglyceride-rich lipoproteins. We therefore measured triglycerides in plasma, S(f) > 400 chylomicrons, and very low density lipoproteins (VLDL) in 14 subjects heterozygous for the A-IV-2 allele (1/2) and 14 subjects homozygous for the common allele (1/1) who were fed a standard meal containing 50 gm fat per m(2) body surface area. All subjects had the apoE-3/3 genotype. Postprandial triglyceride concentrations in the 1/2 subjects were significantly higher between 2;-5 h in plasma, chylomicrons, and VLDL, and peaked at 3 h versus 2 h for the 1/1 subjects. The area under the triglyceride time curves was greater in the 1/2 subjects (plasma, P = 0.045; chylomicrons, P = 0.027; VLDL, P = 0.063). A post-hoc analysis of the frequency of the apoA-IV T347S polymorphism suggested that it had an effect on triglyceride clearance antagonistic to that of the A-IV-2 allele. We conclude that individuals heterozygous for the A-IV-2 allele display delayed postprandial clearance of triglyceride-rich lipoproteins.     

Effects of oleic acid on the biosynthesis of lipoprotein apoproteins and distribution into the very-low-density lipoprotein by the isolated perfused rat liver.

The effects of oleic acid on the biosynthesis and secretion of VLDL (very-low-density-lipoprotein) apoproteins and lipids were investigated in isolated perfused rat liver. Protein synthesis was measured by the incorporation of L-[4,5-3H]leucine into the VLDL apoproteins (d less than 1.006) and into apolipoproteins of the whole perfusate (d less than 1.21). Oleate did not affect incorporation of [3H]leucine into total-perfusate or hepatic protein. The infusion of oleate, however, increased the mass and radioactivity of the VLDL apoprotein in proportion to the concentration of oleate infused. Uptake of oleate was similar with livers from fed or fasted animals. Fasting itself (24 h) decreased the net secretion and incorporation of [3H]leucine into total VLDL apoprotein and decreased the output of VLDL protein by the liver. A linear relationship existed between the output of VLDL triacylglycerol (mumol/h per g of liver) and secretion and/or synthesis of VLDL protein. Net output of VLDL cholesterol and phospholipid also increased linearly with VLDL-triacylglycerol output. Oleate stimulated incorporation of [3H]leucine into VLDL apo (apolipoprotein) E and apo C by livers from fed animals, and into VLDL apo Bh, B1, E and C by livers from fasted rats. The incorporation of [3H]leucine into individual apolipoproteins of the total perfusate lipoprotein (d less than 1.210 ultracentrifugal fraction) was not changed significantly by oleate during perfusion of livers from fed rats, suggesting that the synthesis de novo of each apolipoprotein was not stimulated by oleate. This is in contrast with that observed with livers from fasted rats, in which the synthesis of the total-perfusate lipoprotein (d less than 1.210 fraction) apo B, E and C was apparently stimulated by oleate. The observations with livers from fed rats suggest redistribution of radioactive apolipoproteins to the VLDL during or after the process of secretion, rather than an increase of apoprotein synthesis de novo. It appears, however, that the biosynthesis of apo B1, Bh, E and C was stimulated by oleic acid in livers from fasted rats. Since the incorporations of [3H]leucine into the VLDL and total-perfusate apolipoproteins were increased in fasted-rat liver when the fatty acid was infused, part of the apparent stimulated synthesis of the VLDL apoprotein may be in response to the increased formation and secretion of VLDL lipid.     

Uptake of chylomicron remnants by the liver: further evidence for the modulating role of phospholipids

Rat lymph chylomicrons were treated with rat heparin-releasable hepatic lipase (HL) or with bovine milk lipoprotein lipase (LPL). The ability of the resulting particles to be taken up by the liver in vivo was assessed following their infusion into the portal vein of partially hepatectomized animals. The following observations were made: a) the rate of phospholipid depletion, relative to the rate of triglyceride hydrolysis, induced by HL was two- to threefold higher than that observed for LPL; b) the depletion of at least 57% of phospholipids from the surface of HL-treated chylomicrons caused no major alterations in the apoprotein profile of the particles; c) for the same extent of triglyceride hydrolysis, HL-treated chylomicrons were taken up by liver at a rate significantly higher (P less than 0.005) than LPL-treated particles; d) the liver uptake of HL-treated chylomicrons was competitively inhibited by endogenously generated chylomicron remnants, indicating that these two types of lipoproteins share the same process of recognition and uptake by liver cells. It is concluded that the in vivo changes in phospholipid content, or composition, on the surface of chylomicrons during their transformation into remnants, modulate the differentiation of these two particles by the hepatic remnant receptor.     

Effects of C apoproteins on the activity of endothelium-bound lipoprotein lipase.

Rat apoprotein C-II activated the hydrolysis of triacylglycerol in apoprotein-depleted chylomicrons by lipoprotein lipase in vitro and in the perfused rat heart. Apoproteins C-I and C-III-3 inhibited the hydrolysis of the triacylglycerol moiety in intact and apoprotein C-II-re-activated chylomicrons in vitro, but had no effect on the hydrolysis in situ.     

Retention of apolipoprotein B and cholesterol by perfused heart during lipolysis of very-low-density lipoprotein

The fate and mechanism of removal of apolipoproteins and lipids of human very-low-density lipoproteins were determined in the perfused rat heart. Approx. 50% of the VLDL triacylglycerol was hydrolyzed during a 2 h perfusion. Phospholipid phosphorus, apolipoproteins C-II, C-III and E were quantitatively recovered in the medium. However, there was a loss of unesterified (17 +/- 6%) and esterified (19 +/- 8%) cholesterol from the perfusion medium. Apolipoprotein B was retained by the heart, as determined by the loss of immunoassayable apolipoprotein B (30 +/- 5%) or the uptake of 125I-labelled apolipoprotein of VLDL (9 +/- 2%) from the perfusion medium. The discrepancy in the two methods for estimating apolipoprotein removal was shown to be due to the modification of apolipoprotein B-containing lipoproteins, which was such that they were no longer precipitated with antibodies to apolipoprotein B. The labelled apolipoprotein B, retained by the heart, could be partially released by perfusion of the heart with buffer containing heparin (14 +/- 2%) or trypsin (50 +/- 2%). Labelled apolipoprotein uptake by the heart was reduced by 90% when lipoprotein lipase was first released by heparin or when VLDL was treated with 1,2-cyclohexanedione to modify arginine residues of apolipoproteins. Very little extensive degradation of the apoprotein to low molecular weight material occurred during the 2 h perfusion, since 95% of the tissue label was precipitated by trichloroacetic acid. It is concluded that there is retention of apolipoprotein B, cholesteryl ester and cholesterol by the perfused heart during catabolism of VLDL. The data are consistent with the concept that the retention of apolipoprotein B requires membrane-bound lipoprotein lipase or an interaction with the cell surfaces that is modified by heparin. The overall process also involves arginine residues of apolipoproteins. At least 50% of the labelled apolipoprotein retained in the tissue is associated with lipoprotein lipase and other cell surface sites, while the remainder may be taken up by the cells.