Uptake and degradation of 125I-labelled high density lipoproteins in rat liver cells in vivo and in vitro.

1. The uptake of 125I-labelled high density lipoproteins (HDL) in various organs of the rat was determined after an intravenous injection. The uptake of 125I-labelled polyvinylpyrrolidone in the same organs was determined in order to assess uptake by fluid endocytosis. The uptake/organ was highest for the liver. The adrenals showed the highest uptake/unit weight of the organs studied. The liver, the kidneys and the spleen showed comparable values for uptake/g of tissue. The uptake of 125I-labelled HDL exceeded by far that of 125I-labelled polyvinylpyrrolidone in the liver, the kidneys, the spleen and the adrenals, indicating that the uptake of 125I-labelled HDL was mediated by adsorptive endocytosis. 2. The in vivo uptake of 125I-labelled HDL was determined in purified hepatocytes and non-parenchymal cells prepared by collagenase perfusion of livers from animals after intravenous injections of 125I-labelled HDL. When expressed per cell, the hepatocytes and the non-parenchymal liver cells took up about the same amount of 125I-labelled HDL. 3. The in vitro uptake and degradation of 125I-labelled HDL in isolated rat hepatocytes was studied. The uptake at increasing concentrations of 125I-labelled HDL was saturable indicating uptake mediated through binding sites. 125I-labelled HDL were easily degraded by contaminating proteases from the perfusate. 4. Subcellular fractionation by isopycnic centrifugation indicated that the accumulation of 125I-labelled HDL did not take place in the lysosomes, but rather on the plasma membrane and possibly in the endosomes (phagosomes). 5. 125I-labelled HDL were internalized into the cells and degraded in the lysosomes. Leupetin and chloroquine, inhibitors of the lysosomal function effectively inhibited the formation of 125I-labelled acid-soluble radioactivity by the cells. Chloroquine, but not the protease inhibitor leupeptin, reduced the hydrolysis of the cholesteryl ester moiety of HDL.     

Mitochondrial matrix granules in soft tissues. II. Isolation and initial characterization of a calcium-precipitable, soluble lipoprotein subfraction from brown fat and liver mitochondria

Degradation of ¹²⁵I-labelled HDL ([¹²⁵I]HDL) was measured in isolated rat hepatocytes that had been preincubated with [¹²⁵I]HDL and then reincubated in fresh medium without [¹²⁵I]HDL. About 5 % of the [¹²⁵I]HDL associated with the cells in advance were degraded per hour at 37 °C. This in vitro degradation was inhibited about 50% by lysosomal inhibitors such as chloroquine, ammonia and leupeptin. Depolymerization of microtubuli by colchicine inhibited the degradation of [¹²⁵I]HDL to about 65–75 % of the control cells. Cytochalasin B (CB), a destabilizer of microfilaments, had a less marked effect on the degradation in vitro. Degradation of [¹²⁵I]HDL associated with cells in vivo after intravenous injection was also studied in isolated cells. About 8.5% of the [¹²⁵I]HDL associated with the cells in vivo were degraded per hour in the isolated cells. The effects of ammonia, chloroquine, leupeptin and colchicine on HDL degradation were similar for [¹²⁵I]HDL taken up in vivo and in vitro. Subcellular fractionation by centrifugation in sucrose gradients indicated that [¹²⁵I]HDL associated with hepatocytes in vivo are primarily accumulated in lysosomes. [¹²⁵I]HDL associated with the cells in vitro are located in organelles whose distribution coincides with that of 5′-nucleotidase. These organelles may be endocytic vesicles. It is concluded that the internalization of [¹²⁵I]HDL in rat hepatocytes is relatively slow. The intracellular degradation of the apoproteins of HDL is at least partly lysosomal.     

Specific saturable binding of rat high-density lipoproteins to rat kidney membranes

The binding of rat 125I-labelled high-density lipoprotein (HDL) to rat kidney membranes was studied using HDL fractions varying in their apolipoprotein E content. The apolipoprotein E/apolipoprotein A-I ratio (g/g) in the HDL fractions ranged from essentially 0 to 1.5. All these HDL preparations showed the same binding characteristics. The saturation curves, measured at 0 degrees C in the presence of 2% bovine serum albumin, consisted of two components: low-affinity non-saturable binding and high-affinity binding (Kd about 40 micrograms of HDL protein/ml). Scatchard analyses of the high-affinity binding suggest a single class of non-interacting binding sites. These sites could be purified together with the plasma membrane marker enzyme 5'-nucleotidase. The binding of rat HDL to rat kidney membranes was not sensitive to high concentrations of EDTA, relatively insensitive to pronase treatment and influenced by temperature. The specific binding of rat HDL was highest at acid pH and showed an additional optimum at pH 7.5. On a total protein basis unlabelled rat VLDL competed as effectively as unlabelled rat HDL for binding of 125I-labelled rat HDL to partially purified kidney membranes. Rat LDL, purified by chromatography on concanavalin A columns and human LDL did not compete. Unlabelled human HDL was a much weaker competitor than unlabelled rat HDL and the maximal specific binding of 125I-labelled human HDL was only 10% of the value for 125I-labelled rat HDL.     

Low density lipoprotein receptors and catabolism in primary cultures of rabbit hepatocytes.

Rabbit 125I-labelled low density lipoproteins (LDL) were incubated with primary monolayer cultures of rabbit hepatocytes in studies designed to assess the role of liver in LDL catabolism at the cellular level. After hepatocytes were preincubated for 20 h in lipoprotein-free medium, they exhibited time- and concentration-dependent interaction with 125I-labelled DLD at concentrations to 1 mg LDL protein/ml and times to 24 h. After a 3 h (37 degrees C) incubation with 50 microgram LDL protein/ml, hepatocytes bound 400 ng (LDL protein)/mg (cell protein), internalized 280 ng/mg, and degraded 660 ng/mg. Internalization and degradation may be greater than indicated by these values since pulse studies suggested the presence of a deiodinase which attacks cell associated 125I-labelled LDL. The amounts of LDL bound to hepatocytes after 3 h (37 degrees C) were similar to amounts for fibroblasts, but DLD internalization and degradation were considerably less. Rabbit hyperlipidemic 125I-labelled DLD showed the same amount of binding but 1.39 times more internalization and degradation than normolipidemic 125I-labelled LDL. Binding of both control and hyperlipidemic LDL was 3-fold greater at 24 and 42 h than at O or 3 h but addition of a 50-fold molar excess of high density lipoproteins (HDL) prevented increased LDL binding with time. Induction of specific high affinity receptors for binding LDL was shown to occur by preincubation of hepatocytes for increasing periods in lipoprotein-free medium and then measuring 125I-labelled LDL binding at 4 degrees C in the presence and absence of excess unlabelled LDL. Finally, hepatocytes took up 40 times more LDL than sucrose or dextran over a 24-h period, an indication that the uptake of LDL occurs via some mechanism other than simple bulk fluid endocytosis.     

Uptake and degradation of formaldehyde-treated 125I-labelled human serum albumin in rat liver cells in vivo and in vitro

The uptake of formaldehyde-treated 125I-labelled human serum albumin in rat hepatocytes and nonparenchymal liver cells was measured in vivo and in vitro. Isolated liver cells were prepared by treating the perfused liver with collagenase. Purified hepatocytes and nonparenchymal cells were obtained by differential centrifugation. Human serum albumin was found to be taken up exclusively or almost exclusively by nonparenchymal cells in vitro and in vivo (after intravenous injection). The maximal rate of human serum albumin-uptake in vitro was comparable to that in vivo. Nonparenchymal cells degraded human serum albumin in vitro as indicated by release of trichloroacetic acid-soluble radioactivity. Degradation started about 20-30 min after addition of human serum albumin to cells and rate of degradation was proportional to rate of uptake. Human serum albumin-degradation could be studied without interference of concurrent uptake by separating cells that had been preincubated with human serum albumin from the medium and then reincubating them with human serum albumin-free medium. The lag phase before human serum albumin-degradation starts and the inhibitory effect of chloroquine on degradation indicate that human serum albumin is degraded in lysosomes. The data obtained show that enzymatically prepared nonparenchymal liver cells retain their endocytic activity in vitro. Denatured human serum albumin should be useful both as a marker for rat liver macrophages and for the study of intracellular proteolysis in these cells.     

Uptake and degdradation of formaldehyde-treated 125I-labeled human serum albumin in rat liver cells in vivo and in vitro

The uptake of formaldehyde-treated ¹²⁵I-labelled human serum albumin in rat hepatocytes and nonparenchymal liver cells was measured in vivo and in vitro. Isolated liver cells were prepared by treating the perfused liver with collagenase. Purified hepatocytes and nonparenchymal cells were obtained by differential centrifugation. Human serum albumin was found to be taken up exclusively or almost exclusively by nonparenchymal cells in vitro and in vivo (after intravenous injection). The maximal rate of human serum albumin-uptake in vitro was comparable to that in vivo. Nonparenchymal cells degraded human serum albumin in vitro as indicated by release of trichloroacetic acid-soluble radioactivity. Degradation started about 20–30 min after addition of human serum albumin to cells and rate of degradation was proportional to rate of uptake. Human serum albumin-degradation could be studied without interference of concurrent uptake by separating cells that had been preincubated with human serum albumin from the medium and then reincubating them with human serum albumin-free medium. The lag phase before human serum albumin-degradation starts and the inhibitory effect of chloroquine on degradation indicate that human serum albumin is degraded in lysosomes. The data obtained show that enzymatically prepared nonparenchymal liver cells retain their endocytic activity in vitro. Denatured human serum albumin should be useful both as a marker for rat liver macrophages and for the study of intracellular proteolysis in these cells.     

Induction of high-density-lipoprotein receptors in rat corpus luteum by human choriogonadotropin. Evidence of protein synthesis de novo.

The present studies investigated the specific binding of 125I-labelled high-density lipoprotein (125I-HDL) to plasma membranes. Golgi, rough endoplasmic reticulum and mitochondria/lysosomes, prepared from ovaries of rats injected with human choriogonadotropin (hCG) or 0.9% NaCl. Treatment in vivo with hCG resulted in 2-3-fold induction of 125I-HDL binding activity in all the subcellular organelles. The specific binding of HDL to various subcellular organelles was dependent on the amount of protein, lipoprotein concentration and incubation time. Equilibrium-binding studies revealed comparable Kd values (13-22 micrograms of HDL protein/ml) for HDL binding in all the subcellular organelles tested. Treatment with cycloheximide (2.0 mg/kg body wt.) before hCG administration abolished the induction of HDL receptors, suggesting the involvement of a protein-synthesis-dependent process in receptor induction. Analysis of equilibrium dissociation constants (Kd) for 125I-HDL binding in membranes from hCG-, cycloheximide-and saline-treated animals suggests that the increase in binding was due to an increase in the number of binding sites rather than a change in the affinity. Additionally, pretreatment with tunicamycin, an inhibitor of N-linked glycosylation, had no effect on hCG-mediated receptor induction, suggesting that glycosylation of the receptor may not be necessary for the interaction of HDL with its receptors.     

Behaviour of phospholipase-modified HDL towards cultured hepatocytes. I. Enhanced transfers of HDL sterols and apoproteins

Human HDL subfractions (HDL2, HDL3, or HDL separated by heparin affinity chromatography) were labelled either on their apolipoprotein moiety with 125I or on their sterols: unesterified [14C]cholesterol and [3H]cholesteryl linoleyl ether, a non-hydrolysable analog of esterified cholesterol. HDL subfractions were then treated with or without phospholipase A2 from Crotalus adamanteus in presence of albumin leading to a 72-82% phosphatidylcholine degradation. Control and treated HDL were reisolated and then addressed to cultured rat hepatocytes. (A) During incubations, unesterified [14C]cholesterol from HDL3 readily appeared in hepatocytes. The specific uptake of HDL esterified cholesterol calculated from [3H]cholesteryl ether was 2-4-times less important. Uptake of HDL cholesterol tended to saturate at 150-200 micrograms/ml HDL protein. A prior phospholipase treatment of HDL3 stimulated by 2-5-fold the uptake of [3H]cholesteryl ether, whereas the transfer of free [14C]cholesterol was minimally increased. The uptake of 3H/14C-labelled sterols from HDL2 was 2-3-times higher than from HDL3. (B) Parallel experiments were conducted with 125I-labelled HDL subfractions. At 37 degrees C, the specific uptake and degradation of HDL3 125I-apolipoprotein were about 2-fold enhanced following treatment of HDL3 with phospholipase A2. Uptakes of apolipoprotein and of esterified cholesterol were compared, indicating a preferential delivery of the sterol over apoprotein (X5). The dissociation was still more pronounced with phospholipase-treated HDL3. Competition experiments showed that 12-times more unlabelled HDL3 were required to half reduce the uptake of HDL3 [3H]cholesteryl ether than to impede similarly the HDL 125I-apolipoprotein recovered in cells. Uptake of 125I-labelled apolipoprotein from HDL2 was quantitatively comparable to that from HDL3. (C) Binding of 125I-HDL subfractions was followed at 4 degrees C. A specific binding was observed for HDL2 and HDL3, although kinetic parameters were quite different (KD of 9 and 25 micrograms/ml, respectively). Following phospholipolysis, both the specific and non-specific contributions to total binding were increased. Hence, hepatocytes take up more 125I-labelled apolipoprotein and 3H/14C-labelled sterols from lipolysed HDL than from unmodified particles. This is associated to changes in the binding characteristics.     

Low density lipoprotein binding, internalization, and degradation in human adipose cells.

Human adipose tissue derives its cholesterol primarily from circulating lipoproteins. To study fat cell-lipoprotein interactions, low density lipoprotein (LDL) uptake and metabolism were examined using isolated human adipocytes. The 125I-labelled LDL (d = 1.025-1.045) was bound and incorporated by human fat cells in a dose-dependent manner with an apparent Km of 6.9 + 0.9 microgram LDL protein/mL and a Vmax of 15-80 microgram LDL protein/mg lipid per 2 h. In time-course studies, LDL uptake was characterized by rapid initial binding followed by a linear accumulation for at least 4 h. The 125I-labelled LDL degradation products (trichloroacetic acid soluble iodopeptides) accumulated in the incubation medium in a progressive manner with time. Azide and F- inhibited LDL internalization and degradation, suggesting that these processes are energy dependent. Binding and cellular internalization of 125I-labelled LDL lacked lipoprotein class specificity in that excess (25-fold) unlabelled very low density lipoprotein (VLDL) (d less than 1.006) and high density lipoprotein (HDL) (d = 1.075-1.21) inhibited binding and internalization of 125I-labelled LDL. On an equivalent protein basis HDL was the most potent. The 125I-labelled LDL binding to an adipocyte plasma membrane preparation was a saturable process and almost completely abolished by a three- to four-fold greater concentration of HDL. The binding, internalization, and degradation of LDL by human adipocytes resembled that reported by other mesenchymal cells and could account for a significant proportion of in vivo LDL catabolism. It is further suggested that adipose tissue is an important site of LDL and HDL interactions.     

Uptake of rat plasma HDL subfractions labeled with [3H]cholesteryl linoleyl ether or with 125I by cultured rat hepatocytes and adrenal cells

Rat plasma low- and high-density lipoproteins were labeled with [3H]cholesteryl linoleyl ether and isolated by rate-zonal ultracentrifugation into apolipoprotein B-containing LDL, apolipoprotein E-containing HDL1 and apolipoprotein E-poor HDL2. These fractions were incubated with cultured rat hepatocytes and comparable amounts of all lipoproteins were taken up by the cells. Rat HDL was isolated at d 1.085-1.21 g/ml and apolipoprotein E-free HDL was prepared by heparin Sepharose chromatography. The original HDL and the apolipoprotein E-free HDL were labeled with 125I or with [3H]cholesteryl linoleyl ether and incubated with rat hepatocytes or adrenal cells in culture. The uptake of apolipoprotein E-free [3H]cholesterol linoleyl ether HDL by the cultured hepatocytes was 20-40% more than that of the original HDL. Comparison of uptake of cholesteryl ester moiety (represented by uptake of [3H]cholesteryl linoleyl ether) and of protein moiety (represented by metabolism of 125I-labeled protein) was carried out using both original and apolipoprotein E-free HDL. In experiments in which low concentrations of HDL were used, the ratio of 3H/125I exceeded 1.0. In cultured adrenal cells, the uptake of [3H]cholesteryl linoleyl ether-labeled HDL was stimulated 3-6-fold by 1 X 10(-7) M ACTH, while the uptake of 125I-labeled HDL increased about 2-fold. The ratio of 3H/125I representing cellular uptake was 2-3 and increased to 5 in ACTH-treated cells. The present results indicate that in cultured rat hepatocytes the uptake of homologous HDL does not depend on the presence of apolipoprotein E. Evidence was also presented for an uptake of cholesteryl ester independent of protein uptake in cultured rat adrenal cells and to a lesser extent in rat hepatocytes.     

Uptake and degradation of 125I-labelled asialo-fetuin by isolated rat hepatocytes.

125I-Labelled asialo-fetuin was taken up by isolated rat hepatocytes by a saturable process. Half maximum uptake was seen at about 3 - 10(-8) M asialo-fetuin. Non-parenchymal liver cells did not take up asialo-fetuin in vitro. Rate of uptake of asialo-fetuin exceeded rate of degradation at all concentrations of asialo-fetuin tested. Asialo-fetuin consequently accumulated in the cells until the extracellular supply was exhausted. Asialo-fetuin degradation could be studied without concurrent uptake by incubating cells, previously exposed to asialo-fetuin, in asialo-fetuin-free medium. Degradation, as evidenced by increase in acid-soluble radioactivity, was inhibited by NH4Cl and chloroquine. The change with time in the intracellular distribution pattern of radioactivity in cells that had been exposed to 125I-labelled asialo-fetuin for 10 min was examined by means of differential centrifugation. Initially, the radioactivity was found mostly in the microsomal fraction. 60 min after the exposure to labelled protein, the distribution pattern of radioactivity resembled that of the lysosomal enzyme beta-acetylglucosaminidase. The possibility that asialo-fetuin digestion takes place in lysosomes is discussed.     

Intracellular transport and degradation of 125I-labelled denatured serum albumin in isolated nonparenchymal rat liver cells

The intracellular movement, following uptake of ¹²⁵I-labelled denatured serum albumin into nonparenchymal liver cells, was followed by means of subcellular fractionation. Isolated nonparenchymal rat liver cells were prepared by means of differential centrifugation. The cells were homogenized in a sonifier and the cytoplasmic extract subjected to isopycnic centrifugation in a sucrose gradient. The intracellular movement of the labelled albumin was followed by comparing the distribution profile of radioactivity in the sucrose gradient with those of marker enzymes for plasma membrane and lysosomes. The distribution profiles for radioactivity after the cells had been exposed to the labelled denatured albumin for different time periods indicated that the radioactivity was first associated with subcellular fractions of lower modal densities than the lysosomes. With time of incubation the radioactivity moved towards higher densities. After prolonged incubations in the absence of extracellular labelled denatured albumin the radioactivity peak coincided with that of the lysosomal marker β-acetylglucosaminidase. When the cells were treated with the lysosomal inhibitor leupeptin, degradation of the labelled albumin was decreased, resulting in a massive intracellular accumulation of radioactivity. The radioactivity peak coincided with the peak of activity for the lysosomal marker β-acetylglucosaminidase, suggesting lysosomal degradation.     

Isolation of a porcine liver plasma membrane fraction that binds low density lipoproteins.

Large amounts of injected radiolabeled low density lipoproteins have been found by others to accumulate primarily in the liver and studies in various types of isolated cells, including hepatocytes, have indicated the presence of specific cell membrane recognition sites for lipoproteins. In the present studies, the high affinity binding of radiolabeled low density lipoproteins ([125I]LDL, d 1.020--1.063 g/mL) was measured in the major subcellular fractions of porcine liver homogenates. The nuclear and mitochondrial fractions were 1.9- and 1.4-fold enriched in binding activity with respect to unfractionated homogenates and contained 15% and 12% of the total binding activity, respectively. The microsomes, which contained most of the plasma membranes and endoplasmic reticulum, were approximately 4-fold enriched in binding and contained 73% of the binding activity. Microsomal subfractions obtained by differential homogenization and centrifugation procedures were 5.6--7.0-fold enriched in LDL binding and contained 54--58% of the homogenate binding activity. They were separated by discontinuous sucrose density gradient centrifugation into fractions which contained "light" and "heavy" plasma membranes and endoplasmic reticulum. The heavy membrane fraction was 2--4 fold in binding with respect to the parent microsomes (16--22 fold with respect to the homogenate). There was no enrichment of binding activity in the other two fractions. Two plasma membrane "marker" enzymes, nucleotide pyrophosphatase and 5'-nucleotidase, were also followed. Of the two, binding in the sucrose density gradient subfractions most closely followed nucleotide pyrophosphatase, which was also most highly enriched (3.2--3.3-fold) in the heavy membrane fraction, but did not follow it exactly. The enzyme was 2-fold richer in the light membranes than in the parent microsomes, though the light membrane binding activity was only 0.4--1.4 times that of the parent microsomes. High affinity binding was time and temperature dependent, saturable, and inhibited by unlabeled low density lipoproteins but not by unrelated proteins. Binding was stimulated 2--3 fold Ca2+, was not affected by treatment with Pronase or trypsin and was inhibited by low concentrations of phospholipids and high density lipoproteins (HDL). Heparin-Mn2+ treatment of HDL did not affect its ability to inhibit [125I] LDL binding. The LDL recognition site was distinct from the liver membrane asialoglycoprotein receptor; LDL binding was not inhibited by desialidated fetuin. We conclude that porcine liver contains a high affinity binding site that recognizes features common to both pig low density and high density lipoproteins. Further studies may elucidate the significance of this binding site in lipoprotein metabolism.     

Intracellular transport and degradation of I-labelled denatured serum albumin in isolated nonparenchymal rat liver cells

The intracellular movement, following uptake of ¹²⁵I-labelled denatured serum albumin into nonparenchymal liver cells, was followed by means of subcellular fractionation. Isolated nonparenchymal rat liver cells were prepared by means of differential centrifugation. The cells were homogenized in a sonifier and the cytoplasmic extract subjected to isopycnic centrifugation in a sucrose gradient. The intracellular movement of the labelled albumin was followed by comparing the distribution profile of radioactivity in the sucrose gradient with those of marker enzymes for plasma membrane and lysosomes. The distribution profiles for radioactivity after the cells had been exposed to the labelled denatured albumin for different time periods indicated that the radioactivity was first associated with subcellular fractions of lower modal densities than the lysosomes. With time of incubation the radioactivity moved towards higher densities. After prolonged incubations in the absence of extracellular labelled denatured albumin the radioactivity peak coincided with that of the lysosomal marker β-acetylglucosaminidase. When the cells were treated with the lysosomal inhibitor leupeptin, degradation of the labelled albumin was decreased, resulting in a massive intracellular accumulation of radioactivity. The radioactivity peak coincided with the peak of activity for the lysosomal marker β-acetylglucosaminidase, suggesting lysosomal degradation.     

The localization in rat liver of alkaline phosphodiesterase to a discrete organelle implicated in ligand internalization

The subcellular distribution of alkaline phosphodiesterase and NADH pyrophosphatase, two activities thought to be expressed by the same enzyme, was investigated. Although the two activities share a localization to a low-density vesicular membrane (equilibrium density = 1.12 g.cm-3), little NADH pyrophosphatase activity, in contrast to alkaline phosphodiesterase, was found in plasma membrane (equilibrium density = 1.18 g.cm-3), as reflected by the distribution of 5'nucleotidase. The binding and uptake of 125I-labelled insulin in perfused rat liver was also investigated. This ligand was found to bind to sinusoidal plasma membrane at 4 degrees C, but was rapidly internalized at 37 degrees C to the low-density membrane, which is rich in alkaline phosphodiesterase and NADH pyrophosphatase. These vesicular membranes were shown to belong to none of the enzymatically characterized subcellular bodies, and it is proposed that they represent discrete organelles participating in the subcellular processing of receptor-ligand complexes.     

Intracellular pathway followed by invertase endocytosed by rat liver

Yeast invertase, when injected into rats, is endocytosed by the liver, mainly by sinusoidal cells. The work reported here aims at investigating the organelles involved in the intracellular journey of this protein. Experiments were performed on rats injected with 125I-invertase (25 micrograms/100 g body wt) and killed at various times after injection. Homogenates were fractioned by differential centrifugation, according to de Duve, Pressman, Gianetto, Wattiaux and Appelmans [(1955) Biochem. J. 63, 604-617]. Early after injection the radioactivity was recovered mainly in the microsomal fraction P; later it was found in the mitochondrial fractions (ML). At all times a peak of relative specific activity was observed in the light mitochondrial fraction L. After isopycnic centrifugation in a sucrose gradient, structures bearing 125I-invertase, present in P, exhibited a relatively flattened distribution with a density of around 1.17 g/ml, relatively similar to that of alkaline phosphodiesterase a plasma membrane marker. The organelles located in ML were endowed with a more homogeneous distribution, their median equilibrium density increasing up to 30 min after injection (1.20 g/ml----1.23 g/ml); with time the radioactivity distribution became more closely related to the distribution of arylsulfatase, a lysosomal enzyme. ML fractions, isolated 10 min and 180 min after 125I-invertase injection, were subjected to isopycnic centrifugation in Percoll gradient with, as solvent, 0.25 M, 0.5 M and 0.75 M sucrose. The change of density of the particles bearing 125I-invertase, as a function of the sucrose concentration, paralleled the change of density of the lysosomes as ascertained by the behaviour of arylsulfatase. The distribution of radioactivity and arylsulfatase in a sucrose gradient was established after isopycnic centrifugation of the ML fraction of rats injected with 125I-invertase, the animals having received or not an injection of 900 micrograms/100 g body weight of unlabelled invertase 15 h before killing. In agreement with our previous results, a shift towards higher densities of about 25% or arylsulfatase takes place in rats pretreated with unlabelled invertase. At 10 min, invertase preinjection did not change the radioactivity distribution curve. Later, it caused a progressive shift of the distribution towards higher-density regions of the gradient where the arylsulfatase, which had been shifted, was located.(ABSTRACT TRUNCATED AT 400 WORDS)     

High-density lipoprotein binding to bovine adrenal cortex membranes

Binding studies were performed with bovine adrenal cortex membranes, human 125I-labelled high-density lipoprotein (HDL) and modified photoactivable derivatives of 125I-labelled HDL, namely 125I-labelled HDL-amidinophenylazide and 125I-labelled HDL-amidopropionyldithiophenylazide. The purity of the apolipoprotein composition of the 125I-labelled HDL and photoactivable 125I-labelled HDL used in the binding studies was determined by Coomassie blue and silver staining, and by measuring 125I-labelled cpm after SDS-polyacrylamide gel electrophoresis. About 45% of the 125I-labelled HDL binding to the membranes occurred in the presence of excess EDTA and only unlabelled HDL competed for the binding site. The 125I-labelled interaction with this binding site on the membranes did not require calcium. In addition, 40% of the 125I-labelled HDL binding was to an EDTA-sensitive site, and unlabelled HDL and low-density lipoprotein (LDL) competed for the binding site. Consequently, adrenal cortex membranes have binding sites which show cross reactivity for both HDL and LDL. Modification of 58% of the apolipoprotein lysine residues of 125I-labelled HDL with methylazidophenylimidate, a reagent which maintains the positive charge at lysine residues, had little affect on binding to EDTA-sensitive and insensitive sites. In contrast, modification of 35% of apolipoprotein lysine residues of 125I-labelled HDL with N-succinimidyl(4-azidophenyldithio)propionate, a reagent which converts charged amino lysines to amide bonds, showed binding properties which were almost totally inhibited by EDTA.     

Intracellular localization and degradation of asialofetuin in isolated rat hepatocytes.

Analysis by isopycnic and differential centrifuging of the intracellular distribution of radioactivity following uptake of 125I-labelled asialofetuin by isolated rat hepatocytes showed that during incubations up to 1 h, most of the radioactivity was associated with structures which had a subcellular distribution pattern different from both the lysosomes and the plasma membrane. The latter two organelles were followed by means of enzyme markers. Ca2+ is necessary for the binding of asialofetuin to the plasma membrane, and it was also possible to differentiate between asialofetuin bound to the plasma membrane and that contained in intracellular structures by removing Ca2+ from the medium (by EGTA). Such experiments showed that asialofetuin became rapidly internalized. Practically all the labelled protein was located intracellularly in cells that had been incubated with asialofetuin for more than 30 min. When incubations were carried out for more than 1 h a peak appeared in the radioactivity distribution in the same place as the peak of activity of lysosomal marker enzymes. However, degradation of asialofetuin takes place in the lysosomes and this starts before the labelled protein can be found in the lysosomal fractions. Our data suggest that the rate-determining step in the cellular handling of asialofetuin is the transport of endocytized protein from the endocytic vesicles to the lysosomes.     

Heterogeneity of lysosomes originating from rat liver parenchymal cells. Metabolic relationship of subpopulations separated by density-gradient centrifugation.

1. A crude lysosomal fraction obtained by differential centrifugation of a rat liver homogenate was subjected to zonal centrifugation in iso-osmotic self-generating gradients composed of modified colloidal silica (Percoll). Analysis of relevant marker-enzyme activities shows a continuous band of considerably purified lysosomal particles in the density range 1.04--1.11 g/ml. 2. A relationship between age and buoyant density of the parenchymal lysosomal subpopulations is indicated by the distribution of 125I-labelled asialoglycoproteins in the heterogeneous lysosomes during the catabolism of the glycoprotein. The labelled asialoglycoprotein first appeared in lysosomal particles of low density, which with time progressively acquired a higher density. Furthermore, 30 min after administration the 125I-labelled asialocaeruloplasmin recovered in the light lysosomes was less degraded than the material recovered in the heavy lysosomes. 3. A lysosomal enzyme (arylsulphatase) was found to possess considerably higher isoelectric points in the heavy lysosomes than in the light lysosomes, which is consistent with a relationship between age and density of the lysosomes.     

A 70-kDa apolipoprotein designated ApoJ is a marker for subclasses of human plasma high density lipoproteins

A new apolipoprotein, termed apolipoprotein J (apoJ), was purified from human plasma by immunoaffinity chromatography. ApoJ is a glycoprotein consisting of disulfide-linked subunits of 34-36 and 36-39 kDa. Each subunit is glycosylated and has a pI range of 4.9-5.4. ApoJ exists in the plasma associated with high density lipoproteins (HDL) and specifically with subclasses of HDL which also contain apoAI and cholesteryl ester transfer protein activity. Immunoaffinity purified apoJ-HDL subclasses have apparent molecular masses of 80, 160, 240, 340, and 520 kDa, as determined by gradient gel electrophoresis. By negative staining electron microscopy, apoJ-HDL range in diameter from 5 to 16 nm. Fractionation of plasma by vertical gradient density centrifugation revealed apoJ-HDL in HDL2 (d 1.063-1.125 g/ml) with the majority overlapping HDL3 (d 1.125-1.21 g/ml) and very high density lipoprotein (d 1.21-1.25 g/ml). The bimodal density distribution of apoJ-HDL suggests that these subclasses have a unique metabolic relationship and may play a role in the transport of cholesterol from peripheral tissues to the liver.