Structure of high density lipoprotein. The immunologic reactivities of the COOH- and NH2-terminal regions of apolipoprotein A-I.

Only 5 to 10% of the apolipoprotein A-I (ApoA-I) of intact high density lipoprotein (HDL) is detectable by radioimmunoassay. In addition, when isolated ApoA-I is recombined with lipids in vitro, its immunologic reactivity is decreased by 30 to 95%. Thus, ApoA-I is less reactive immunologically in the presence of lipids. Our aim was to ascertain whether the COOH- or NH2-terminal regions of ApoA-I were equally reactive in intact HDL2. CNBr fragments of ApoA-I were produced by the method of Baker et al. (Baker, H.N., Jackson, R.L., and Gotto, A.M. (1973) Biochemistry 12, 3866-3871) and iodinated with lactoperoxidase. Double-antibody radioimmunoassays were set up using anti ApoA-I antisera and 125I-CNBr I (COOH-terminal region) or 125I-CNBr II (NH2-terminal). Both labels were bound by the antisera. Affinity columns were prepared by binding CNBr I or CNBr II to Sepharose 4B. Antibodies specific against CNBr I or CNBr II were isolated by means of these columns, suggesting that ApoA-I had at least two antigenic sites. In other assays using labeled fragments and anti ApoA-I antisera, 125I-CNBr I was displaced by CNBr I, ApoA-I , and HDL2 but not CNBr II. Conversely, 125I-CNBr II was displaced by CNBr II, ApoA-I, and HDL2 but not by CNBr I. Thus the assays were region-specific. The reactivities of isolated ApoA-I and the ApoA-I in intact HDL2-ApoA-I) were compared in these assays. On a molar basis, HDL2-ApoA-I was consistently more reactive (2- to 5-fold) in the 125I-CNBr I than in the 125I-CNBr II assays. The findings suggest (a) that the two terminal regions of ApoA-I are immunologically distinct, (b) that the two regions can be assayed independently of each other in intact HDL2, and (c) that the COOH-terminal region is more reactive immunologically than is the NH2-terminal. The results are compatible with a more "exposed" position for the COOH-terminal region on the surface of HDL2.     

Evidence for non-equilibrating pools of apolipoprotein C-III in plasma lipoproteins

Using immunoaffinity chromatography to isolate apoC-III from radiolabeled lipoproteins for direct determination of specific radioactivity, we have studied the metabolism of human apoC-III in VLDL and in HDL following the bolus injection of 125I-labeled VLDL. Transfer of apoC-III radioactivity from VLDL to HDL was detected in the plasma sample drawn 5 min after injection of the tracer. However, the specific radioactivity of apoC-III in VLDL was found to be higher than that in HDL, with this difference being maintained throughout the sampling period (48-72 hr). The ratios of the respective specific activities ranged from 1.2 to 1.9 in six subjects studied (two normolipidemics and four hypertriglyceridemics). When 125I-labeled HDL was injected as the tracer, however, the higher apoC-III specific radioactivity was associated with the HDL fraction. This lack of complete equilibration of apoC-III between VLDL and HDL in vivo was further characterized by in vitro studies using either 125I-labeled VLDL or 125I-labeled HDL. All incubations were carried out for 3 hr at 37 degrees C followed by 16 hr at 4 degrees C and the apoC-III specific activity in each lipoprotein fraction was directly determined after immunoaffinity chromatography. In a study of plasma from a mildly hypertriglyceridemic subject in which 125I-labeled VLDL was incubated with unlabeled HDL, apoC-III specific activities in VLDL remained 30% greater than that in HDL. When 125I-labeled HDL (from the same subject) was incubated with unlabeled VLDL of apoC-III, final specific activity in VLDL was less than 10% of that of HDL apoC-III. Differences in specific activities were also demonstrated when radiolabeled purified apoC-III was exchanged onto VLDL prior to its incubation with HDL. A consistent difference in apoC-III specific activities in VLDL and HDL was observed after isolation of the particles either by molecular sieve chromatography or by ultracentrifugation. These studies demonstrated that, while the exchange of apoC-III between VLDL and HDL may be very rapid, this equilibration is not complete. Pools of apoC-III that do not participate in the equilibration process are present in both the VLDL and HDL fractions and could account for 30-60% of the total apoC-III mass in each lipoprotein fraction.     

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.     

Apolipoprotein A-IV. A determinant for binding and uptake of high density lipoproteins by rat hepatocytes

To identify the role of a specific apoprotein other than apoE which might be responsible for the receptor-mediated uptake of high density lipoprotein (HDL) by rat hepatocytes, 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC) was combined with rat apoE, apoA-I, or apoA-IV to form apoprotein-phospholipid complexes and the complexes were tested for their binding and uptake by primary rat hepatocytes. Apoprotein-POPC complexes were labeled with the specific fluorescent probe, 1,1-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine to monitor their uptake by cultured rat hepatocytes at 37 degrees C using digital fluorescence imaging microscopy or were labeled with 125I to study their binding to hepatocytes at 4 degrees C. POPC, either alone or with apoA-I, was not internalized by rat hepatocytes while complexes containing apoE or apoA-IV were taken up by the cells. Specific binding at 4 degrees C was demonstrated for apoE-free HDL, apoA-IV X POPC, and apoE X POPC but not for apoA-I X POPC. The binding of apoE-free HDL was inhibited by apoA-IV X POPC, apoE-free HDL, and apoA-IV + apoA-I X POPC but not by apoA-I X POPC. Binding of apoA-IV X POPC was inhibited by apoE-free HDL, apoA-IV X POPC, and apoA-IV + apoA-I X POPC, but not by apoE X POPC or apoE-enriched HDL. These data indicate that apoA-IV is a ligand responsible for the rat HDL binding to primary rat hepatocytes and that apoA-IV binds to a receptor site distinct from apoE-dependent receptors such as the apoB,E or chylomicron-remnant receptor.     

High-density lipoprotein particle uptake and selective uptake of high-density lipoprotein-associated cholesteryl esters by J774 macrophages

High-density lipoprotein (HDL) cholesteryl esters are taken up by fibroblasts via HDL particle uptake and via selective uptake, i.e., cholesteryl ester uptake independent of HDL particle uptake. In the present study we investigated HDL selective uptake and HDL particle uptake by J774 macrophages. HDL3 (d = 1.125-1.21 g/ml) was labeled with intracellularly trapped tracers: 125I-labeled N-methyltyramine-cellobiose-apo A-I (125I-NMTC-apo A-I) to trace apolipoprotein A-I (apo A-I) and [3H]cholesteryl oleyl ether to trace cholesteryl esters. J774 macrophages, incubated at 37 degrees C in medium containing doubly labeled HDL3, took up 125I-NMTC-apo A-I, indicating HDL3 particle uptake (102.7 ng HDL3 protein/mg cell protein per 4 h at 20 micrograms/ml HDL3 protein). Apparent HDL3 uptake according to the uptake of [3H]cholesteryl oleyl ether (470.4 ng HDL3 protein/mg cell protein per 4 h at 20 micrograms/ml HDL3 protein) was in significant excess on 125I-NMTC-apo A-I uptake, i.e., J774 macrophages demonstrated selective uptake of HDL3 cholesteryl esters. To investigate regulation of HDL3 uptake, cell cholesterol was modified by preincubation with low-density lipoprotein (LDL) or acetylated LDL (acetyl-LDL). Afterwards, uptake of doubly labeled HDL3, LDL (apo B,E) receptor activity or cholesterol mass were determined. Preincubation with LDL or acetyl-LDL increased cell cholesterol up to approx. 3.5-fold over basal levels. Increased cell cholesterol had no effect on HDL3 particle uptake. In contrast, LDL- and acetyl-LDL-loading decreased selective uptake (apparent uptake 606 vs. 366 ng HDL3 protein/mg cell protein per 4 h in unloaded versus acetyl-LDL-loaded cells at 20 micrograms HDL3 protein/ml). In parallel with decreased selective uptake, specific 125I-LDL degradation was down-regulated. Using heparin as well as excess unlabeled LDL, it was shown that HDL3 uptake is independent of LDL (apo B,E) receptors. In summary, J774 macrophages take up HDL3 particles. In addition, J774 cells also selectively take up HDL3-associated cholesteryl esters. HDL3 selective uptake, but not HDL3 particle uptake, can be regulated.     

Enhanced binding of low and high density lipoproteins to human adipocyte plasma membranes: effects of temperature and proteases

The specific binding of 125I-labelled low density lipoprotein ([125I]LDL to human adipocyte plasma membranes was higher at 37 than at 0 degree C. Prior treatment of membranes with pronase had no effect on LDL binding measured at 0 degree C but consistently stimulated binding at 37 degrees C. Plasmin was similar to pronase in enhancing LDL-specific binding, but thrombin was not as effective. 125I-labelled high density lipoprotein ([125I]HDL2) specific binding to human adipocyte plasma membranes was similarly sensitive to temperature and pronase treatment. Addition of the protease inhibitor aprotinin in the adipocyte membrane binding assay significantly reduced [125I]LDL binding at 37 degrees C (p less than 0.05), suggesting the involvement of a protease activity intrinsic to the lipoproteins and (or) membranes. These data demonstrate that both LDL and HDL binding in human adipocyte plasma membranes can be "up-regulated" by specific proteolytic perturbations in a temperature-dependent manner.     

Protein transfer between A-I-containing lipoprotein subpopulations: evidence of non-transferable A-I in particles with A-II.

Transfer of apolipoproteins (apo) between the two subpopulations of apo A-I-containing lipoproteins in human plasma: those with A-II [Lp(AI w AII)] and those without [Lp(AI w/o AII)], were studied by observing the transfer of 125I-apo from a radiolabeled subpopulation to an unlabeled subpopulation in vitro. When Lp(AI w AII) was directly radioiodinated, 50.3 +/- 7.4 and 19.5 +/- 7.7% (n = 6) of the total radioactivity was associated with A-I and A-II, respectively. In radioiodinated Lp(AI w/o AII), 71.5 +/- 6.8% (n = 6) of the total radioactivity was A-I-associated. Time-course studies showed that, while some radiolabeled proteins transferred from one population of HDL particles to another within minutes, at least several hours were necessary for transfer to approach equilibrium. Incubation of the subpopulations at equal A-I mass resulted in the transfer of 51.8 +/- 5.0% (n = 4) of total radioactivity from [125I]Lp(AI w/o AII) to Lp(AI w AII) at 37 degrees C in 24 h. The specific activity (S.A.) of A-I in the two subpopulations after incubation was nearly identical. Under similar incubation conditions, only 13.4 +/- 4.6% (n = 4) of total radioactivity was transferred from [125I]Lp(AI w AII) to Lp(AI w/o AII). The S.A. of A-I after incubation was 2-fold higher in particles with A-II than in particles without A-II. These phenomena were also observed with iodinated high-density lipoproteins (HDL) isolated by ultracentrifugation and subsequently subfractionated by immunoaffinity chromatography. However, when Lp(AI w AII) radiolabeled by in vitro exchange with free [125I]A-I was incubated with unlabeled Lp(AI w/o AII), the S.A. of A-I in particles with and without A-II differed by only 18% after incubation. These data are consistent with the following: (1) in both populations of HDL particles, some radiolabeled proteins transferred rapidly (minutes or less), while others transferred slowly (hours); (2) when Lp(AI w AII) and Lp(AI w/o AII) were directly iodinated, all labeled A-I in particles without A-II were transferable, but some labeled AI in particles with A-II were not; (3) when Lp(AI w AII) were labeled by in vitro exchange with [125I]A-I, considerably more labeled A-I were transferable. These observations suggest the presence of non-transferable A-I in Lp(AI w AII).     

Selective radiolabeling of cell surface proteins to a high specific activity

A procedure was developed for selective radiolabeling of membrane proteins on cells to higher specific activities than possible with available techniques. Cell surface amino groups were derivatized with 125I-(hydroxyphenyl)propionyl groups via 125I-sulfosuccinimidyl (hydroxyphenyl)propionate (125I-sulfo-SHPP). This reagent preferentially labeled membrane proteins exposed at the cell surface of erythrocytes as assessed by the degree of radiolabel incorporation into erythrocyte ghost proteins and hemoglobin. Comparison with the lactoperoxidase-[125I]iodide labeling technique revealed that 125I-sulfo-SHPP labeled cell surface proteins to a much higher specific activity and hemoglobin to a much lower specific activity. Additionally, this reagent was used for selective radiolabeling of membrane proteins on the cytoplasmic face of the plasma membrane by blocking exofacial amino groups with uniodinated sulfo-SHPP, lysing the cells, and then incubating them with 125I-sulfo-SHPP. Exclusive labeling of either side of the plasma membrane was demonstrated by the labeling of some marker proteins with well-defined spatial orientations on erythrocytes. Transmembrane proteins such as the epidermal growth factor receptor on cultured cells could also be labeled differentially from either side of the plasma membrane.     

Metabolism of HDL-cholesteryl ester in the rat, studied with a nonhydrolyzable analog, cholesteryl linoleyl ether

Intralipid was sonicated with [3H]cholesteryl linoleyl ether (a nonhydrolyzable analog of cholesteryl linoleate) and incubated with rat HDL and d greater than 1.21 fraction of rabbit serum at a ratio of 0.012 mg triacylglycerol to 1 mg HDL protein. 25% of [3H]cholesteryl linoleyl ether was transferred to HDL. The labeled HDL was injected into donor rats and was screened for 4 h. [125I]HDL was subjected to the same protocol as the 3H-labeled HDL, including screening. The screened, labeled sera were injected into acceptor rats and the disappearance of radioactivity from the circulation was compared. The t1/2 in the circulation of [125I]HDL was about 10.5 h, while that of [3H]cholesteryl linoleyl ether-HDL was about 8 h. The liver and carcass were the major sites of uptake of [3H]cholesteryl linoleyl ether-HDL and accounted for 29-41% (liver) and 30% (carcass) of the injected label. Maximal recovery of [3H]cholesteryl linoleyl ether in the liver was seen 48 h after injection, and thereafter there was a progressive decline of radioactivity, which reached 7.8% after 28 days. The maximal recovery of [125I]HDL in the liver was about 9%. Pretreatment of the acceptor rats with estradiol for 5 days resulted in a 20% increase in the hepatic uptake of [3H]cholesteryl linoleyl ether-HDL and a 5-fold increase in adrenal uptake. The present findings indicate that in the rat the liver is the major site of uptake of HDL cholesteryl ester and that part of the HDL cholesteryl ester may be cleared from the circulation separately from the protein moiety. On the basis of our previous findings (Stein, Y., Kleinman Y, Halperin, G., and Stein, O. (1983) Biochim. Biophys. Acta 750, 300-305) the loss of the [3H]cholesteryl linoleyl ether from the liver after 14-28 days was interpreted to indicate that the labeled [3H]cholesteryl linoleyl ether had been taken up by hepatocytes.     

Transfer of functional immunoglobulin G (IgG) antibody into the gastrointestinal tract accounts for IgG clearance in calves.

The transfer of circulating immunoglobulin G1 (IgG1) antibody to the gastrointestinal tract in young calves was quantified by using bovine anti-dinitrophenol IgG1 antibody labeled with 125I. The antibody was administered to newborn calves by intravenous injection, and transfer of the labeled IgG1 to the gastrointestinal tract occurred as demonstrated by excretion of protein-bound label in the feces and by the presence of the labeled IgG1 antibody in the gastrointestinal tract lumen at necropsy. Sixty-eight percent of the [125I]IgG1 clearance occurred by transfer to the gastrointestinal tract. Protein-bound 125I in the gastrointestinal tract lumen retained 65% of the specific dinitrophenol-binding ability of the labeled antibody originally administered. These results show that (i) transfer to the intestinal lumen is the major means of IgG1 clearance in calves, and (ii) this transfer results in antigen-binding antibody in the intestinal tract lumen. The potential contribution to enteric immunity of IgG1 reaching the intestinal lumen from circulation remains to be determined.     

Characterization of high-density lipoprotein binding and cholesterol efflux in cultured mouse adipose cells

Binding of high-density lipoproteins to cultured mouse Ob1771 adipose cells was studied, using labeled human HDL3, mouse HDL and apolipoprotein AI- or AII-containing liposomes. In each case, saturation curves were obtained, yielding linear Scatchard plots. The Kd values were found to be respectively 18, 42, 30 and 3.4 micrograms/ml, whereas the maximal binding capacities were found to be 160, 100, 90 and 21 ng/mg of cell protein. Apoprotein AI not inserted into liposomes did not bind. The binding of 125I-HDL3 was competitively inhibited by apolipoprotein AI-containing liposomes greater than mouse HDL greater than HDL3. The binding of 125I-labeled apolipoprotein AI- and 125I-labeled apolipoprotein AII-containing liposomes was competitively inhibited by HDL3, apolipoprotein AI- and apolipoprotein AII-containing liposomes. Dimyristoylphosphatidylcholine liposomes containing or not cholesterol did not interfere with the binding of labeled HDL3 or apolipoprotein-containing liposomes. Binding studies on crude membranes of Ob1771 adipose cells revealed the presence of intracellular binding sites for LDL and HDL3. Thus, adipose cells have specific binding sites for apolipoprotein E-free HDL and apolipoprotein AI (or AII) is the ligand for these binding sites. Long-term exposure of adipose cells to LDL cholesterol as a function of LDL concentration led to an accumulation of cellular unesterified cholesterol. This process was saturable and reversible as a function of time and concentration by exposure to HDL3 or apolipoprotein AI-containing liposomes, whereas apolipoprotein AII-containing liposomes did not promote any cholesterol efflux. Since long-term exposure of adipose cells to LDL and HDL3 did not affect the number of apolipoprotein B,E receptors and apolipoprotein E-free binding sites, respectively, it appears that adipose cells do not show efficient cholesterol homeostasis and thus could accumulate or mobilize unesterified cholesterol.     

Regulation of high density lipoprotein receptors in cultured macrophages: role of acyl-CoA:cholesterol acyltransferase

The interaction of human serum high density lipoproteins (HDL) with mouse peritoneal macrophages and human blood monocytes was studied. Saturation curves for binding of apolipoprotein E-free [125I]HDL3 showed at least two components: non-specific binding and specific binding that saturated at approximately 40 micrograms HDL protein/ml. Scatchard analysis of specific binding of apo E-free [125I]-HDL3 to cultured macrophages yielded linear plots indicative of a single class of specific binding sites. Pretreatment of [125I]HDL3 with various apolipoprotein antibodies (anti apo A-I, anti apo A-II, anti apo C-II, anti apo C-III and anti apo E) and preincubation of the cells with anti-idiotype antibodies against apo A-I and apo A-II prior to the HDL binding studies revealed apolipoprotein A-I as the ligand involved in specific binding of HDL. Cellular cholesterol accumulation via incubation with acetylated LDL led to an increase in HDL binding sites as well as an increase in the activity of the cytoplasmic cholesterol esterifying enzyme acyl-CoA:cholesterol acyltransferase (ACAT). Incubation of the cholesterol-loaded cells in the presence of various ACAT inhibitors (Sandoz 58.035, Octimibate-Nattermann, progesterone) revealed a time- and dose-dependent amplification in HDL binding and HDL-mediated cholesterol efflux. It is concluded that the homeostasis of cellular cholesterol in macrophages is regulated in part by the number of HDL binding sites and that ACAT inhibitors enhance HDL-mediated cholesterol efflux from peripheral cells.     

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.     

Stability of 125I-Labeled Staphylococcal Enterotoxins in Solid-Phase Radioimmunoassay

Staphylococcal enterotoxins, Types A, B, and C, were labeled with 1252 by the chloramine-T method at approximately two levels of specific activity, 40 and 4 muCi/mug of protein. Toxins labeled with high specific activity showed extensive dissociation of 125I when stored at different temperatures, including -23 C. In contrast, toxins labeled with low specific activity did not show any significant loss of 125I when stored at -23 C for as long as 2 months. Enterotoxins, whether labeled with high or low activities, formed aggregates immediately upon labeling. Aggregate formation increased in high-activity-labeled toxins on storage at -23 C, and low-activity-labeled toxins showed no significant increase in aggregate formation, even after 2 months at -23 C. The aggregated forms of the enterotoxins were either devoid of antigenic activity in solid-phase radioimmunoassay or they possessed significantly reduced antigenic activity. Thus, a decrease in binding of 1252-labeled enterotoxin to specific antibody in solid-phase radioimmunoassay results mainly from (i) loss of 125I on storage, and (ii) formation of aggregates with reduced antigenic activity.     

Metabolism of high-density lipoproteins in cultured rat luteal cells

The uptake of cholesterol from high-density lipoproteins (HDL) labeled with 125I and [3H]cholesterol was examined in cultured rat luteal cells. Luteal cells were incubated with labeled HDL, following which the metabolic fate of the apolipoproteins and cholesterol moieties of the receptor-bound HDL were examined. About 50% of the originally bound HDL apolipoproteins were released into the medium in 24 h by a temperature-dependent process while only 5% of the HDL cholesterol was released unmetabolized. Inclusion of unlabeled HDL in the chase incubation resulted in increased release of apolipoprotein-derived radioactive products without significant change in the release of unmetabolized cholesterol. 60% of the apolipoprotein-derived radioactivity could be precipitated with trichloroacetic acid; the remaining trichloroacetic acid-soluble radioactive fraction was identified as [125I]iodotyrosine. Gel filtration chromatography of the chase-released material showed that the trichloroacetic acid-precipitable products, which contained no detectable amounts of cholesterol, eluted over a range of molecular sizes (9-80 kDa). No intact HDL was retroendocytosed. About 80% of trichloroacetic acid-precipitable products could be immunoadsorbed on anti-apolipoprotein A-I antibody immobilized on CNBr-activated Sepharose, suggesting the presence of fragments containing apolipoprotein A-I. This material was also capable of reassociating with native HDL. Lysosomal inhibitors were partially effective in inhibiting the amount of trichloroacetic acid-soluble products formed. The lysosomal degradation appeared to have no role in the uptake of HDL-derived cholesterol. These studies demonstrate preferential and total uptake of HDL cholesterol by luteal cells, with concomitant degradation of the lipoprotein.     

Proteolytic degradation of HDL1 on the fat cell surface is nutritionally regulated

The importance of plasma HDL apolipoprotein concentration as a predictor of atherosclerotic risk is well recognized, yet the processes of HDL modification and degradation in various cells are not clearly understood. We examined the characteristics of HDL1 apolipoprotein degradation and cellular uptake by rat adipocytes and determined the effects of fasting on these processes. Epididymal and perirenal adipocytes were isolated from male Wistar rats (310 +/- 4 g) fed ad libidum and incubated with 5 micrograms of rat 125I-labeled HDL1 (d: 1.07-1.10 g/mL) mL-1 for 2 h at 37 degrees C. Cellular uptake of HDL1 was calculated as the trichloroacetic acid precipitable radioactivity associated with adipocytes following incubation. Intracellular and medium degradation of HDL1 were determined as trichloroacetic acid soluble 125I counts associated with cells and measured in the postincubation medium, respectively. Fifty to sixty percent of cellular uptake and degradation of HDL1 was inhibited by the addition of 25-fold excess unlabeled HDL. HDL1 degradation measured in the medium was 10- to 12-fold greater than cellular uptake of HDL1 apolipoproteins. Intracellular degradation of HDL1 was negligible. The presence of EDTA in the incubation medium reduced HDL1 degradation measured in the medium, but enhanced HDL1 cellular uptake. Conditioned medium separated from cells after 2 h of incubation at 37 degrees C in the absence of HDL and subsequently incubated with 125I-labeled HDL1 for an additional 2 h at 37 degrees C, degraded less than 5% of HDL compared with degradation in the presence of cells. These results suggest that rat adipocytes degrade, or modify, HDL1 particles, possibly by interactions with cell surface proteases.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Apolipoprotein A-I assayed in human serum by isotope dilution as a potential standard for immunoassay

We measured the amount of apoA-I in serum by isotope dilution, finding 1.33 mg/ml (standard deviation 0.177) in six normolipidemic, healthy subjects. We developed this method by adapting published techniques to purify apoA-I from 3 ml of serum in two steps: density gradient ultracentrifugation and high performance liquid chromatography gel filtration. The 125I-labeled apoA-I tracer was first screened, by incubation with serum, to select labeled apoA-I which retained the ability to exchange with native apoA-I and bind to HDL. A known amount of 125I-labeled apoA-I-labeled HDL was added to unknown serum samples; apoA-I was reisolated from the serum and its specific radioactivity was used to calculate the dilution of the added, labeled apoA-I by the unlabeled apoA-I in the unknown serum. By not relying on immunochemical techniques, the isotope dilution assay provided results that are independent of the expression of individual apoA-I antigenic sites. Therefore, sera that have been assayed by isotope dilution can serve as standards to evaluate the accuracy of immunoassays for serum apoA-I and provide primary standards for such immunoassays.     

Plasma factors controlling atrial natriuretic peptide (ANP) aggregation: role of lipoproteins

We have previously shown that human plasma atrial alpha-natriuretic peptide (alpha-hANP) sequestering is a protective phenomenon against amyloid aggregation. In the present work, the possible role of lipoproteins as alpha-hANP binding factors has been investigated in vitro using an experimental model, developed in our laboratory, that allows to work at physiological concentrations. This approach consists of gel filtration on Sephacryl S-300 HR of big alpha-[(125)I]hANP generated in phosphate buffered saline or in human normal plasma supplemented or not with lipoproteins. The results of these experiments indicate that high density lipoproteins (HDL) are responsible for the ANP binding phenomenon observed in vitro, while low density lipoproteins and very low density lipoproteins do not directly interact with ANP. Moreover, the HDL remodeling process occurring in vitro has been analyzed during plasma incubation by monitoring the redistribution of lipids and apolipoproteins among the HDL subclasses. The changes in HDL size and composition observed in incubated plasma were compared with the redistribution of endogenous and labeled big ANP. The obtained results revealed that both tend to follow the molecular rearrangement in plasma of apolipoprotein A-I containing particles and suggested that, among HDL species, the small particles are mainly involved in the ANP binding phenomenon. This hypothesis was further demonstrated by ligand blotting experiments that confirmed the existence of differences in the ability of HDL particles to bind alpha-[(125)I]hANP.     

Scavenger receptor class B type I is solely responsible for the selective uptake of cholesteryl esters from HDL by the liver and the adrenals in mice

Scavenger receptor class B type I (SR-BI) has been identified as a functional HDL binding protein that can mediate the selective uptake of cholesteryl ester (CE) from HDL. To quantify the in vivo role of SR-BI in the process of selective uptake, HDL was labeled with cholesteryl ether ([(3)H] CEt-HDL) and (125)I-tyramine cellobiose ([(125)I]TC-HDL) and injected into SR-BI knockout (KO) and wild-type (WT) mice. In SR-BI KO mice, the clearance of HDL-CE from the blood circulation was greatly diminished (0.043 +/- 0.004 pools/h for SR-BI KO mice vs. 0.106 +/- 0.004 pools/h for WT mice), while liver and adrenal uptake were greatly reduced. Utilization of double-labeled HDL ([(3)H]CEt and [(125)I]TC) indicated the total absence in vivo of the selective decay and liver uptake of CE from HDL in SR-BI KO mice. Parenchymal cells isolated from SR-BI KO mice showed similar association values for [(3)H]CEt and [(125)I]TC in contrast to WT cells, indicating that in parenchymal liver cells SR-BI is the only molecule exerting selective CE uptake from HDL. Thus, in vivo and in vitro, SR-BI is the sole molecule mediating the selective uptake of CE from HDL by the liver and the adrenals, making it the unique target to modulate reverse cholesterol transport.