Radiolabeled sucrose covalently linked to protein. A device for quantifying degradation of plasma proteins catabolized by lysosomal mechanisms

A conjugate of doxorubicin with lactosaminated albumin enhances the drug concentrations in all the forms of rat hepatocellular carcinomas independently of their differentiation grade

BACKGROUND/AIMS

Doxorubicin (DOXO) was coupled to lactosaminated human serum albumin (L-HSA) in order to enhance the drug concentration in the well differentiated hepatocellular carcinomas (HCCs), which can accumulate L-HSA through the asialoglycoprotein receptor. In the present experiments we compared the DOXO concentrations produced by this conjugate (L-HSA-DOXO) and by the uncoupled drug in the well, moderately, and poorly differentiated rat HCCs.

METHODS

The same dose (1 microg/g) of free or L-HSA coupled-DOXO was injected in rats with HCCs induced by diethylnitrosamine. At different times, the animals were killed and the neoplastic nodules of liver were isolated. Their differentiation grade was determined histologically and their DOXO content was measured.

RESULTS

Unexpectedly, we found that also in the poorly differentiated forms of HCCs, which display no or only a poor capacity of accumulating L-HSA, the conjugate raised DOXO levels that were approximately twofold higher than those produced by the free drug.

CONCLUSIONS

The conjugate L-HSA-DOXO could improve the potential of DOXO in the treatment of all HCCs, including the poorly differentiated tumors that are the common forms in the advanced disease for which an effective chemotherapy is particularly needed.

Regulation of the selective uptake of cholesteryl esters from high density lipoproteins by sphingomyelin

Although sphingomyelin (SM) is a major phospholipid in lipoproteins as well as in the membrane rafts where the scavenger receptor class B type I (SR-BI) is localized, its possible role in the selective uptake of cholesteryl ester (CE) by the SR-BI-mediated pathway is unknown. We investigated the effect of SM in lipoproteins and cell membranes on the selective uptake in three different cell lines: SR-BI-transfected CHO cells, hepatocytes (HepG2), and adrenocortical cells (Y1BS1). Incorporation of SM into recombinant high density lipoprotein (rHDL) containing labeled CE resulted in up to 50% inhibition of the selective uptake of CE in all three cell lines. This inhibition was completely reversed by treatment of rHDL with sphingomyelinase (SMase). Selective uptake from plasma HDL was activated by 22-72% after treatment of HDL with SMase. In addition, pretreatment of the cells with SMase resulted in stimulation of CE uptake from rHDL by CHO and Y1BS1, although not by HepG2. Incorporation of ceramide into rHDL resulted in up to 2-fold stimulation of CE uptake, although pretreatment of cells with egg ceramide had no significant effect. These results show that SM and ceramide in the lipoproteins and the cell membranes regulate the SR-BI-mediated selective uptake of CE, possibly by interacting with the sterol ring or with SR-BI itself.

Enhanced uptake of lactosaminated human albumin by rat hepatocarcinomas: implications for an improved chemotherapy of primary liver tumors

BACKGROUND/AIMS

The hepatocyte receptor for asialoglycoproteins (ASGP-R) internalizes macromolecules exposing galactosyl residues (MEGRs) which can be used as liver-addressed drug carriers. This receptor was also found on the cells of the large majority of well differentiated hepatocarcinomas (HCCs). The aim of the present experiments was to ascertain whether ASGP-R of HCCs is functionally active and these tumors can internalize higher quantities of MEGRs than extra-hepatic tissues.

METHODS

We injected radioactive lactosaminated human albumin (L-HSA) in rats with HCCs produced by nitroso-diethylamine and measured the radioactivity of tumors, surrounding liver, heart, intestine and kidney. L-HSA is a MEGR successfully used in humans as a hepatotropic drug carrier.

RESULTS

The levels of radioactivity of HCCs were two to three times lower than those of surrounding liver, but several times higher than those of extra-hepatic tissues. L-HSA accumulation in the tumors mainly occurred via the ASGP-R, as indicated by the 20 times lower penetration of non-lactosaminated HSA. L-HSA uptake by the well-differentiated tumors were four times higher compared with that by the poorly differentiated forms.

CONCLUSIONS

The present results suggest that in the chemotherapy of HCCs expressing the ASGP-R the extra-hepatic toxicity of anticancer agents can be reduced by conjugation to L-HSA.

Synthesis and evaluation of a monoreactive DOTA derivative for indium-111-based residualizing label to estimate protein pharmacokinetics

The purpose of this study was to develop an indium-111 (111In)-based residualizing label for estimating the pharmacokinetics of proteins. 1,4,7,10-Tetraazacyclododecane-N,N',N'',N'''-tetraacetic acid (DOTA), which produced a highly stable and hydrophilic 111In chelate, was selected as the chelating site, and the monoreactive DOTA derivative with a tetrafluorophenyl group as the protein binding site (mDOTA) was designed to avoid cross-linkings of proteins. mDOTA was synthesized with an overall yield of 11%. The stability in murine plasma, the radioactivity retention in the catabolic sites of proteins and the radiochemical yields of 111In-labelled proteins via mDOTA were investigated using human serum albumin (HSA), galactosyl-neoglycoalbumin (NGA) and cytochrome c (cyt c) as model proteins. 111In-labelled HSA via mDOTA was highly stable for 5 days after incubation in murine plasma. Long retention of radioactivity in the catabolic sites was observed after injection of 111In-DOTA-NGA in mice, due to the slow elimination of the radiometabolite from the lysosome. At a chelator concentration of 42.2 microM, 111In-DOTA-cyt c was produced with over 91% radiochemical yield. On the other hand, 111In-DOTA-lysine and 111In-DOTA were obtained with high radiochemical yields at lower chelator concentrations. These findings indicated that mDOTA would be an appropriate 111In-labelling agent for estimating protein pharmacokinetics. These findings also suggested that the introduction of a protein binding site at a position distal from the unmodified DOTA structure would be preferable to preparing 111In-DOTA-labelled proteins with higher specific activity.

Inhibition of mast cell-dependent conversion of cultured macrophages into foam cells with antiallergic drugs

Degranulation of isolated, rat peritoneal mast cells in the presence of low density lipoprotein (LDL) induces cholesteryl ester accumulation in cocultured macrophages with ensuing foam cell formation. This event occurs when the macrophages phagocytose LDL particles that have been bound to the heparin proteoglycans of exocytosed granules. In an attempt to inhibit such foam cell formation pharmacologically, rat peritoneal mast cells that had been passively sensitized with anti-ovalbumin-IgE were treated with 2 mast cell-stabilizing antianaphylactic drugs, MY-1250 or disodium cromoglycate (DSCG). Both drugs were found to inhibit antigen (ovalbumin)-triggered release of histamine from the mast cells, revealing mast cell stabilization. In cocultures of rat peritoneal macrophages and passively sensitized mast cells, addition of MY-1250 before addition of the antigen resulted in parallel reductions in histamine release from mast cells, uptake of [(14)C]sucrose-LDL, and accumulation of LDL-derived cholesteryl esters in the cocultured macrophages. Similarly, when passively sensitized mast cells were stimulated with antigen in the presence of DSCG and the preconditioned media containing all substances released from the drug-treated mast cells were collected and added to macrophages cultured in LDL-containing medium, uptake and esterification of LDL cholesterol by the macrophages were inhibited. The inhibitory effects of both drugs were mast cell-specific because neither drug inhibited the ability of macrophages to take up and esterify LDL cholesterol. Analysis of heparin proteoglycan contents of the incubation media revealed that both drugs had inhibited mast cells from expelling their granule remnants. Thus, both MY-1250 and DSCG prevent mast cells from releasing the heparin proteoglycan-containing vehicles that bind LDL and carry it into macrophages. This study suggests that antiallergic pharmacological agents could be used in animal models to prevent mast cell-dependent formation of foam cells in vivo.

Cholesterol-loading of peripheral tissues alters the interconversion of high density lipoprotein subfractions in rabbits

High density lipoprotein (HDL) has been implicated in the process of reverse cholesterol transport,by which surplus cholesterol is removed from peripheral tissues and transported to the liver for excretion. It has been suggested that some subfractions of HDL may have a particular role in this process, though the underlying mechanism remains unclear. The present study was aimed at investigating the role of specific subfractions of HDL in reverse cholesterol transport. The interconversion of HDL subfractions in normal and cholesterol-loaded rabbits was studied in vivo. Rabbit HDL was separated by heparin-Sepharose affinity chromatography into six subfractions (HDL(I)-HDL(VI)), which were progressively enriched with apolipoprotein E (apo E), and varied in diameter and composition. Total HDL and its subfractions were individually labelled with 14C sucrose and injected in the rabbits. When rabbits which were not acutely loaded with [3H]cholesterol were injected with 14C-HDL(I), 70% of the label remained in this fraction while less than 5% was recovered in HDL(VI), containing the largest particles and those most enriched in apo E. No label was detectable in the liver of these animals. In rabbits which had received a prior loading of cholesterol, an average of only 18.3% of the 14C label was present in HDL(I) while approx. 40% of the label was recovered in HDL(VI). On average, 5.1% of the total 14C injected in these rabbits was recovered in the liver. It is concluded that two alternative routes for reverse cholesterol transport may be operative. While a continuous cholesterol-clearance route may be provided by particles of HDL of intermediate size, another route may be operative for clearance of excess cholesterol loaded into peripheral endothelial cells.

Inhibition of the oxidative modification of LDL by nitecapone

We studied in vitro the ability of nitecapone, 3-[(3,4-dihydroxy-5-nitrophenyl)methylene]-2,4-pentanedione, a novel water-soluble compound with antioxidative properties, to inhibit the LDL oxidation promoted by copper ions, the aqueous free radical generator 2,2'-azobis(2-amidinopropane) hydrochloride (AAPH), and mouse peritoneal macrophages. In these three oxidation systems, the extent of LDL oxidation was determined by measuring the formation of conjugated dienes, the formation of thiobarbituric acid-reactive substances, the change in the electrophoretic mobility of LDL, and the uptake of LDL by macrophages. When LDL oxidation was promoted by copper ions, the reaction was found to be inhibited by nitecapone added in a three- to five-molar excess of the concentration of copper ions. The mechanism by which nitecapone exerted its antioxidative effect in copper-mediated LDL oxidation depended on binding and redox inactivation of the copper ions. Moreover, nitecapone released LDL-bound copper ions and so rendered the LDL particles more resistant to oxidation. In contrast to a water-soluble alpha-tocopherol analogue that was rapidly consumed during the oxidative process, nitecapone retained its inhibitory effect for at least 2 days. Using immobilized metal ion affinity chromatography, we showed that nitecapone binds both copper and iron ions, whereas its affinity for zinc ions is low. Nitecapone also inhibited LDL oxidation in the free radical-mediated oxidation system (AAPH). In this system, nitecapone showed synergistic antioxidative action with ascorbic acid. Finally, nitecapone inhibited macrophage-mediated LDL oxidation. Accordingly, nitecapone appears to have a unique antioxidative profile in that it both selectively chelates pro-oxidative transition metals and scavenges free radicals.(ABSTRACT TRUNCATED AT 250 WORDS)

IgE-dependent generation of foam cells: an immune mechanism involving degranulation of sensitized mast cells with resultant uptake of LDL by macrophages

Because a role has been suggested for IgE in cardiovascular diseases and for mast cells in cholesterol accumulation within the macrophages of atherosclerotic lesions, we examined mast cell-macrophage interactions in vitro by using rats with high serum levels of IgE antibodies. The rats were immunized with an antigen (ovalbumin) and adjuvant (Bordetella pertussis vaccine) to provoke synthesis of IgE and to sensitize their mast cells, ie, to allow the IgE to bind to the high-affinity IgE receptors on the mast cell surfaces. On addition of the ovalbumin to suspensions of mast cells isolated from the peritoneal cavity of the immunized rats, the mast cells responded by exocytosing their heparin-proteoglycan--containing granules. When IgE-bearing peritoneal mast cells were cocultured with peritoneal macrophages (also from the immunized rats) in a medium enriched in LDL, addition of ovalbumin to the incubation medium triggered a dose-dependent release of granules and a dose-dependent increase in the rate of LDL uptake by the macrophages. In contrast, ovalbumin had no effect on LDL uptake if the cultures contained only macrophages or if the mast cells and macrophages were from nonimmunized rats. Thus, the sequence of events leading to enhanced uptake of LDL by macrophages depended wholly on IgE-dependent degranulation of the sensitized mast cells. With the aid of gold-labeled LDL we demonstrated that the exocytosed mast cell granules had bound LDL particles and carried them into the macrophages, with subsequent formation of foam cells. The current series of experiments delineates a novel immunologic mechanism for the formation of macrophage foam cells and assigns a potentially atherogenic role to mast cell-bound IgE antibodies.

Total parenteral nutrition and plasma lipoproteins in the rat: evidence for accelerated clearance of apo-A-I-rich HDL

The effect of total parenteral nutrition (TPN) containing fat on plasma lipoproteins and apo-A-I-rich HDL catabolism was studied in the rat. TPN rats were intravenously infused for 5 days with a nutritive mixture containing amino acids, lipids (Intralipid 20%) and glucose. In spite of similar plasma levels of total cholesterol in TPN and control orally fed rats, density gradient ultracentrifugation of plasma samples gave evidence of marked differences in the lipoprotein profiles. In the density range 1.010-1.040, were found elevated amounts of apo-B-100 and apo-B-48 containing lipoproteins, as well as an increase in free cholesterol and phospholipids, the latter indicating that the plasma of TPN rats contained abnormal lipoprotein-X-like particles. The level of apo-E-rich HDL (density: 1.040-1.063) was not markedly changed, whereas that of typical HDL (d > 1.063) was lowered, with less apo-A-I and apo-A-IV, and low amounts of cholesterol and phospholipids were found in the most dense HDL3 fractions (d > 1.090) containing the bulk of apo-A-I-rich particles. After intravenous infusion of homologous [14C]sucrose-labelled HDL3, the clearance of these particles was 2-fold faster in TPN than in control rats, with a tissue uptake increased in the liver (+40%) and decreased in the small and large intestines (-60%). Because the pool of apo-A-I-rich HDL was dramatically reduced after 5 days of artificial feeding, the absolute catabolic rate of these lipoproteins was similar in the two groups. These data suggest that, in TPN rats lacking of chylomicron coat components as a source for HDL material, the fall in plasma levels of apo-A-I-rich HDL resulted mainly from accelerated turnover of these particles, mediated by increased uptake by the liver. Conversely, mucosa atrophy was probably involved in the reduced uptake of apo-A-I-rich HDL by the gastrointestinal tract.

Metabolism of LDL in mast cells recovering from degranulation. Description of a novel intracellular pathway leading to proteolytic modification of the lipoprotein

Rat serosal mast cells contain cytoplasmic secretory granules composed of a proteoglycan matrix in which histamine and neutral proteases are embedded. On stimulation, these granules are exocytosed, but some of them remain in the degranulation channels where on exposure to the extracellular fluid, they lose their histamine and a fraction of their proteoglycans. In vitro, such granule remnants efficiently bind low density lipoprotein (LDL) present in the incubation medium. After a lag period of about 10 minutes, the granule remnants, still within the channels and coated with LDL particles, are internalized by the parent mast cells. During subsequent recovery from degranulation, the apolipoprotein B of the intracellularly located remnant-bound LDL becomes efficiently (up to 70%) degraded by the proteolytic enzymes of the granule remnants. Since the granule remnants lack cholesteryl esterase activity, no LDL cholesterol is made available for cellular nutrition. Instead, selective proteolytic degradation of the bound LDL leads to formation of LDL particles enlarged by fusion on the granule remnant surface. In response to restimulation of the mast cells, about 50% of the fused LDL particles are exocytosed with the granule remnants. Of these, about one in five are expelled into the incubation medium. The granule remnants that again remain in the degranulation channels bind and internalize more LDL. This "round trip" of LDL in mast cells exposed to repeated stimulation constitutes a hitherto-unknown intracellular pathway for modification of LDL.

Inhibition of copper-mediated oxidation of LDL by rat serosal mast cells. A novel cellular protective mechanism involving proteolysis of the substrate under oxidative stress

Rat serosal mast cells, when stimulated to exocytose their cytoplasmic granules, effectively blocked the copper-mediated oxidation of low density lipoproteins (LDLs) in vitro. This effect depended on the proteolytic activity of the formed extracellular granule remnants, since specific inhibition of chymase, the neutral protease that they contain, blocked the protective effect of the mast cells. The mechanism of this chymase-mediated inhibition of LDL oxidation was found to be binding of the copper ions present in the incubation medium by peptides released from LDL on proteolytic degradation of their apolipoprotein B (apoB) component. This was verified by demonstrating that addition of such peptides to LDL--copper ion mixtures completely prevented oxidation of LDL and that this protective effect could be overcome by adding copper ions in excess. Furthermore, proteolytic degradation of the apoB of LDL, with concomitant release of copper-containing peptides, left the partially degraded apoB without the copper ions necessary for propagation of LDL oxidation. These observations provide the first evidence for cell-mediated inhibition of LDL oxidation.

Lipoprotein-mediated distribution of N-aspartyl chlorin-E6 in the mouse

The localization of many photosensitizing agents has been attributed to distribution of low density lipoprotein (LDL)-bound drug as a function of the relative numbers of LDL receptors in different tissues. While the chlorin derivative NPe6 is a potent photosensitizing agent in the mouse, it binds mainly to mouse plasma high density lipoproteins (HDL) and albumin, with only 1% bound to LDL. This pattern suggests only a minor role for the LDL-receptor pathway with regard to N-aspartyl chlorin e6 (NPe6) biodistribution. Moreover, patterns of accumulation of radioactive NPe6, LDL and HDL in murine tissues are consistent with the suggestion that distribution of NPe6 to different tissues cannot be explained on the basis of an LDL-mediated mechanism.

Identification of tissue sites for increased albumin degradation in sarcoma-bearing mice

Plasma albumin concentration declines in both experimental and clinical cancer. Previous investigations have demonstrated that this is partly explained by increased breakdown of albumin. The present study has identified the tissue sites for increased albumin degradation in a nonmetastasizing sarcoma mouse (C57/BL6J) model. Results have been compared to nontumor-bearing animals either freely fed or food restricted (pair-weighed) so that their body composition was similar to tumor-bearing animals. Tumor-bearing mice had increased albumin degradation (0.13 +/- 0.02 mg/hr/g bw) compared to both freely fed (0.09 +/- 0.007) and pair-weighed control animals (0.05 +/- 0.008). Radioactivity from circulating [3H]raffine aldehyde labeled albumin appeared with maximum peak values in lysosomes isolated from both tumor and nontumor tissues at 48 hr following iv injection. The intralysosomal accumulation of radioactivity was two- to threefold higher in tumor tissue compared to liver tissue, although the specific activity of protease(s) for albumin degradation measured in vitro was not higher in tumor tissue (30.4 +/- 3.6 mg/hr/g tissue) compared to normal liver tissue (36.9 +/- 1.7). Accounting for the entire tumor the proteolytic capacity for albumin breakdown was however much larger in the tumor (161.6 +/- 32.6 mg/organ) compared to both normal liver (37.5 +/- 2.3) and tumor-host liver (56.4 +/- 2.8). Pepstatin inhibited 78 +/- 6% of the proteolytic activity in the tumor measured by 125I-labeled undenatured mouse albumin as the substrate. Leupeptin inhibited 49 +/- 6%. There was a significantly decreased breakdown of albumin in both skeletal muscles and the gastrointestinal tract from tumor-bearing animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Cerebral low-density lipoprotein (LDL) uptake is stimulated by acute bile drainage

Although the cholesterol pool in the central nervous system is considered to be relatively stable, few studies have tested this assumption. The aim of the study was to gain further information on the communication between the extracerebral organs and the brain as far as cholesterol and lipoprotein transport are concerned. Receptor-dependent as well as receptor-independent LDL uptake in the brain were measured, by established methods, after constant 1-h intravenous infusions of [14C]sucrose-labelled hamster LDL and methylated human LDL, both in hamsters with an acute bile fistula and in control animals with an intact enterohepatic circulation. The receptor-dependent LDL uptake in the brain promptly showed a significant increase after the construction of the bile fistula. However, there was no difference in the receptor-independent LDL uptake between the bile fistula and control animals. The studies indicate the presence of close communications between extracerebral and brain cholesterol. Changes in the extracerebral compartments of cholesterol are, apparently, readily sensed by the LDL receptor in the brain and promptly evoke appropriate modifications in its activity.

Uptake and metabolism of high-density lipoproteins by cultured rabbit hepatocytes

The selective uptake and internalization of core components of high-density lipoproteins (HDL) were examined in primary monolayer cultures of rabbit hepatocytes. Using [14C]sucrose as a surface marker covalently attached to apolipoprotein and [3H]cholesteryl linoleyl ether as a core marker, there was a 5-6-fold greater internalization of cholesteryl ether than sucrose-labeled apolipoprotein during 48 h of culture. The rate of uptake of [3H]cholesteryl linoleyl ether was 263 +/- 29 ng apo HDL/mg cell protein per h during the initial 8 h of culture, but averaged 101 +/- 32 ng apo HDL/mg cell protein per h over the 48 h culture period. Concomitant with this apparent selective uptake of cholesteryl ester core, there was a change in the HDL size distribution, with the appearance of a distinct population of smaller 4.3 nm radius particles in addition to the originally predominant particles of 4.9 nm radius. This was associated with a significant reduction of cholesteryl ester as a percentage of lipoprotein mass from 15.5 +/- 1.2 to 11.0 +/- 1.2 (P less than 0.001) and a reduction in cholesteryl ester:protein mass ratio from 0.30 +/- 0.01 to 0.19 +/- 0.01 (P less than 0.001). There was no change in the mass ratio of HDL triacylglycerol to protein. Thus rabbit hepatocytes in culture exhibit the capacity to selectively extract cholesteryl ester from HDL and produce smaller HDL particles.

Increase in selective hepatic uptake of high-density lipoprotein cholesteryl esters in the fasted rabbit

The selective hepatic uptake of high-density lipoprotein cholesteryl esters was determined in primary hepatocyte cultures of cells from normal, cholestyramine-fed and 48-h-fasted rabbits. The HDL was labeled in the apoprotein moiety with [14C]sucrose and in the core component with [3H]cholesteryl linoleyl ether. The uptake of the apoprotein label did not differ between groups (indicating no change in holoparticle HDL uptake), but in contrast, the uptake of the cholesteryl ether label was significantly increased in hepatocytes from cholestyramine-fed and fasted animals. After 40 h of culture, the ratio of 3H to 14C uptake was 4.96 in controls cells, 7.15 in cholestyramine-treated cells and 10.24 in fasted hepatocytes from short-term fasted animals. Thus short-term fasting was associated with a 2-fold increase in the selective hepatic uptake of HDL core components, indicating that selective hepatic uptake of HDL cholesteryl esters is a physiologically responsive process.

Metabolism of apolipoprotein A-IV in rat

The metabolism of apolipoprotein A-IV (apo-IV) has been investigated in the rat. In this animal species, apoA-IV is a major protein constituent of plasma HDL and lymph chylomicron. The apolipoprotein is also present in the lipoprotein-deficient fraction (LDF) of plasma and lymph. In vivo studies with the radioiodinated protein showed the apoA-IV does not exchange freely between HDL and LDF and that LDF apoA-IV had a faster catabolism than HDL apoA-IV. ApoA-IV in chylomicrons is a direct precursor of apoA-IV in plasma HDL but not of that in LDF. On the other hand lymph LDF apoA-IV is an important precursor of plasma LDF apoA-IV. Transfer of apoA-IV from plasma to lymph is negligible, and since most of apoA-IV in lymph is present in LDF, we speculate that LDF apoA-IV is the major apoA-IV secretory product of the intestine. Studies aimed at identifying the site of catabolism of apoA-IV utilizing either radioiodinated or [14C]sucrose labelled apoA-IV, gave results consistent with the view that the liver plays a major role. When tested, human apoA-IV behaved in vivo in rat as the autologous protein. These findings, together with others previously published (Ghiselli, G. et al. (1987) J. Lipid Res. 27, 813-827), support the conclusion that the plasma metabolism of apoA-IV is remarkably similar in rat and human. We speculate that in mammals the rapid plasma catabolism of apoA-IV is mediated by an efficient uptake by the liver.

Effects of dietary beef and soy protein on tissue composition and low density lipoprotein uptake in young pigs

To study effects of dietary protein source on plasma cholesterol homeostasis, six littermate pairs of 8-wk-old, castrated male pigs were assigned randomly to high fat diets containing either lean beef or soy protein isolate, with beef tallow as the major fat source in both diets. Diets were fed for 6 wk, with blood samples taken weekly and analyzed for lipid composition. At 6 wk, each pig was injected with [3H]cholesterol- and [14C]sucrose-labeled low density lipoproteins, and serial blood samples were taken. Pigs were then killed, and several tissues were sampled. Results show that dietary beef or soy protein, when fed with beef tallow as a fat source, has differential effects on rates of uptake of intact LDL by heart, M. sartorius muscle and subcutaneous adipose tissue, and on rates of uptake of LDL cholesterol by net free cholesterol exchange in subcutaneous and perirenal adipose tissues. Dietary protein source affected the composition of only two tissues analyzed. Pigs fed the beef-based diet had greater lipid concentrations in M. sartorius muscle, whereas pigs fed the soy protein-based diet had greater lipid concentrations in heart. Source of dietary protein did not influence in vivo kinetics of LDL cholesterol removal from blood plasma.

Bile salt hydrophobicity influences cholesterol recruitment from rat liver in vivo when cholesterol synthesis and lipoprotein uptake are constant

These studies were undertaken to characterize the role of bile salt hydrophobicity in determining the rate of cholesterol recruitment from the liver. Using an in vivo rat model in which the acquisition of hepatic cholesterol from chylomicron remnants, low-density lipoproteins, and de novo synthesis was measured and kept constant, it was found that the amount of sterol recruited from the liver cell increased progressively as the liver was probed with a constant infusion of progressively more hydrophobic bile salts. The absolute secretion rate of both cholesterol and phospholipid increased nearly 50% as the hydrophobic index of the bile salts traversing the liver increased from 1.7 to 4.5, but the ratio of cholesterol to phospholipid secreted in bile remained nearly constant. Thus, when cholesterol entry into the hepatocyte via lipoproteins and de novo cholesterol synthesis is constant, the mass of cellular cholesterol recruited into the bile is directly proportional to the hydrophobic-hydrophilic balance of the secreted bile salts.

Effect of monensin on fluid phase and receptor mediated endocytosis by rat hepatocyte monolayers

We have investigated the effect of monensin on the uptake of sucrose and sucrose-asialofetuin by rat hepatocyte monolayers and on the intracellular traffic of these molecules. Endocytosis of sucrose is not affected by monensin while that of sucrose-asialofetuin is markedly inhibited. Monensin causes a decrease of galactosyltransferase, a Golgi membrane enzyme without affecting dipeptidylpeptidase IV a plasma membrane enzyme and three lysosomal hydrolases. The inhibition of sucrose-asialofetuin uptake is proportional to the reduction of galactosyltransferase activity. Differential and isopycnic centrifugation results indicate that monensin at a concentration (10 mumol/l) that markedly decreases sucrose-asialofetuin uptake does not prevent the transfer of sucrose and sucrose-asialofetuin from endosomes to lysosomes.

Some metabolic characteristics of low-density lipoprotein subfractions, LDL-1 and LDL-2: in vitro and in vivo studies

Two low-density lipoprotein subfractions, LDL-1 and LDL-2, with density ranges of respectively 1.023-1.034 and 1.036-1.041 g/ml, were isolated by aspiration after density gradient ultracentrifugation of human pooled serum. In vitro interactions of both LDL subfractions with the LDL receptor of human cultured fibroblasts, human hepatoma cell line Hep G2 and human hepatocytes were compared. No difference in association (binding and internalization) nor in degradation between LDL-1 and LDL-2 by these cells was found. However, kinetic studies in guinea pigs showed that LDL-2 disappeared faster from the circulation and accumulated to a greater extent in the liver, compared to LDL-1. Thus, we were unable to show a difference in the LDL receptor-mediated uptake of both LDL subfractions by various cells in vitro. The results obtained in vivo suggest that LDL-1 is more atherogenic than LDL-2, because its longer half-life renders the particle more susceptible to uptake by the scavenger LDL receptor on macrophages.

Evidence for surface entrapment of cholesterol-rich lipoproteins in luteinized ovary

Previous studies showed that perfused 125I-labeled low and high density lipoproteins (LDL, HDL) have affinity for specialized microvillar regions of luteal cells in hormone-primed, luteinized rat ovaries. In the current report, we re-examined the interaction of cholesterol-rich lipoproteins with these specialized plasma membrane regions using native lipoproteins visualized as discrete particles by standard electron microscopic techniques. In ovaries perfused with the various lipoproteins, spherical particles (varying in size from 12 to 28 nm depending on the particle used) were found over the surfaces of all luteal cells and filling up extensive "channel" space formed by the apposed plasma membranes of adjacent microvilli or cytoplasmic surfaces. Only 30% of these tissue-associated particles were removable after prolonged washing with perfused media or heparin. Few intact particles were found inside the cells, despite the fact that the lipoproteins induced a substantial hormone response by the ovary. To determine the total protein internalized by cells during the course of the experiments, parallel biochemical experiments were carried out with nonreleasable (14C-sucrose-coupled) human LDL. Of the total bound 14C-sucrose LDL, only 8.5% was degraded (trichloroacetic acid-soluble) and presumed internalized by the cells. Thus, while large numbers of cholesterol-rich lipoprotein particles interact with the luteal cell surface in specialized microvillar channels and elicit a progesterone response, relatively few intact lipoprotein particles appear to enter the cells to be degraded. We speculate that in the luteinized ovary, a large majority of the lipoprotein-cholesterol transfer occurs at the surface of the luteal cells, and that the membranes of the microvillar channels are involved in this process.

Modulation of bile secretion by hepatic low-density lipoprotein uptake and by chenodeoxycholic acid and ursodeoxycholic acid treatment in the hamster

The effects of both apolipoprotein B,E receptor-dependent and receptor-independent uptake of low-density lipoprotein (LDL) in the liver on bile secretion were studied in bile fistula hamsters. Three groups of animals were studied after 4 wk of feeding either a control, chenodeoxycholic acid-, or ursodeoxycholic acid-containing diet. The hepatic receptor-dependent and receptor-independent uptake of LDL was related to both bile flow and biliary lipid secretion. The correlation with bile flow and biliary lipid secretion was positive for the receptor-dependent, but negative for the receptor-independent uptake of LDL. Although the receptor-mediated LDL uptake appeared to exert a strong influence on bile acid-independent bile flow, the receptor-independent uptake showed a significant relation with biliary bile acid excretion. Differences between the two mechanisms of LDL uptake were also evident in the biliary bile acid-cholesterol coupling, which was significantly stronger during receptor-independent than during receptor-dependent uptake of LDL. The effects of LDL uptake on bile secretion were modulated by the experimentally induced changes in both the content and composition of bile acids in the enterohepatic circulation.

Uptake, intracellular transport and release of 125I-poly(vinylpyrrolidone) and [14C]-sucrose-asialofetuin in rat liver parenchymal cells. Effects of ammonia on the intracellular transport

We have studied the intracellular transport of 125I-labeled poly(vinylpyrrolidone) (125I-PVP) and [14C]sucrose-asialofetuin (14C-SAF) in isolated rat hepatocytes. 125I-PVP and 14C-SAF are taken up in the cells by fluid phase and receptor-mediated endocytosis, respectively. The labeled degradation products formed from 14C-SAF are trapped in the lysosomes. They can therefore serve as markers for lysosomes in subcellular fractionation studies. The accumulation of 125I-PVP in the cells was rapid initially and then decreased to a constant value. The diminished rate of accumulation was due to release (exocytosis) of previously endocytosed 125I-PVP. The release of 125I-PVP was studied in cells that had accumulated 125I-PVP for various times and then after washing incubated in new medium at 37 degrees. About 25% of the radioactivity associated with the cells after 1 hr was released to the medium subsequently. No such release was observed in cells that had taken up 14C-SAF. Subcellular distribution of 125I-PVP and 14C-SAF was studied by isopycnic centrifugation in sucrose gradients. Both compounds were sequentially associated with light (1.13 g/ml) and dense (1.19 g/ml) vesicles. Exocytosed 125I-PVP was derived from the light vesicles. The denser organelles were probably lysosomes as their distribution coincided with that of lysosomal enzymes. By measuring radioactivity soluble and precipitable in trichloroacetic acid it could be shown that only degraded 14C-SAF was associated with lysosomes. Undegraded 14C-SAF was associated with vesicles banding at 1.13 g/ml. Degraded 14C-SAF was, however, also seen first in this region of the gradient, suggesting that degradation started in a light lysosome. Both uptake and release of 125I-PVP were temperature dependent; both processes ceased at 10 degrees. Ammonium ions had negligible effects on uptake and release of 125I-PVP. The amine inhibited, however, the transfer of both 125I-PVP and 14C-SAF to the lysosomes.

Degradation of exogenous membrane proteins implanted into the plasma membrane of cultured hepatoma cells

The degradation of radiolabeled red cell band 3 and Sendai envelope proteins was studied after band 3 virosomes were fused with hepatoma cells as previously described (Hare, J E & Huston, M, Exp cell res 161 (1986) 317) [26]. 125I-band 3 (T1/2 = 13-14 h), Sendai HN (T1/2 = 37-40 h), and F (T1/2 = 21-23 h) envelope proteins were degraded by an apparent first-order process that was greater than 90% sensitive to 20 mM NH4Cl. 125I-Sendai envelope proteins were degraded at approximately similar rates when hepatoma cells were fused with intact virus, isolated viral membrane, or band 3 virosomes. There thus appears to be distinct heterogeneity among the degradation rates of implanted polypeptides dependent on structural aspects of each. To identify the subcellular site of membrane protein degradation, band 3 was labeled with membrane impermeant [14C]sucrose and implanted into hepatoma plasma membranes. After replating, trichloroacetic acid (TCA)-soluble label was found to accumulate in the lysosomal compartment of fractionated cells. The results identify the lysosome as the ultimate site of plasma membrane protein degradation, but suggest that plasma membrane proteins are selectively rather than non-selectively delivered to this compartment.

Cholesterol transport and uptake in miniature swine fed vegetable and animal fats and proteins. 1. Plasma lipoproteins and LDL clearance

In a 2 X 2 factorial arrangement, miniature pigs were fed four diets containing vegetable protein/fat (soybean) and animal protein (egg white)/fat (beef tallow) to demonstrate the effects of protein and fat source on total plasma cholesterol, lipoprotein distribution, low density lipoprotein (LDL) composition, and plasma clearance of LDL-cholesterol and protein. Beef tallow consumption resulted in greater plasma cholesterol concentration, decreased LDL-cholesterol concentration, and a lower LDL-cholesterol to LDL-protein ratio than did consumption of soybean oil. High density lipoprotein (HDL)-cholesterol concentration was increased by beef tallow consumption. Cholesterol percentage by weight in LDL was significantly greater in pigs consuming soybean oil than those consuming beef tallow. Percentages by weight of protein, triglyceride and phospholipid in LDL were not significantly different in any group. Dietary protein source had no significant effect on total plasma cholesterol concentration, lipoprotein concentration or LDL composition. Egg white consumption decreased fractional catabolic rate and irreversible loss of LDL-cholesterol and LDL-protein when compared with consumption of soy protein. Dietary fat source had no consistent effect on LDL clearance from plasma. Dietary fat and protein seemed to influence lipoprotein metabolism by different mechanisms. Fat source altered lipoprotein concentration and LDL composition, whereas protein source affected the removal rate of LDL from plasma.

Cholesterol transport and uptake in miniature swine fed vegetable and animal fats and proteins. 2. LDL uptake and cholesterol distribution in tissues

In a 2 X 2 factorial arrangement, miniature pigs were fed four diets containing vegetable protein/fat (soybean) and animal protein (egg white)/fat (beef tallow) to demonstrate the effects of protein and fat source on tissue cholesterol concentrations, uptake of intact low density lipoproteins (LDL) and free cholesterol exchange from LDL to tissues. Soybean oil feeding, compared with beef tallow feeding, resulted in greater concentrations of cholesterol in aorta, heart, and large and small intestines. Similar trends were seen in liver, adipose tissue and skeletal muscle. Dietary protein source had little or no effect on tissue cholesterol concentrations. Uptake of intact LDL, as measured by using [14C]sucrose-LDL, tended to be greater in pigs fed soybean oil or soy protein. Net exchange of free cholesterol from LDL, as measured with [3H]cholesterol, tended to be greater when vegetable products were fed. Relative contributions of whole tissues to total uptake by either mechanism were not influenced by diet. Mechanisms in addition to uptake of cholesterol from LDL seem to be involved in the greater accumulation of tissue cholesterol resulting from polyunsaturated fat feeding.

Uptake and degradation of bovine testes beta-galactosidase by parenchymal and nonparenchymal rat liver cells

The plasma half-life of beta-galactosidase in rat was about 1.5 min. Ten minutes after in vivo injection, 45% of the enzyme was recovered in liver, with hepatocytes and endothelial cells as the predominant cell types responsible for uptake. In vitro uptake of beta-galactosidase in hepatocytes and nonparenchymal liver cells was saturable, Ca2+-dependent and it could be partly inhibited by mannose or alpha-methyl-mannoside.