Formation of cholesterol- and apoprotein E-enriched high density lipoproteins in vitro

The delivery of cholesterol to canine serum or plasma altered the distribution of cholesterol and apoproteins in subclasses of high density lipoproteins (HDL). In these experiments, two in vitro systems were employed. The first system used cholesterol-celite particles to deliver cholesterol to canine plasma during 4-h incubations. When the cholesterol distribution in the lipoproteins was analyzed by Geon-Pevikon electrophoresis, an increase in cholesterol content was found in the slower migrating subclasses of HDL (HDL1 and HDLc). A large increase in apoprotein E (apo-E) was also observed in the lipoproteins. Densitometric analysis of lipid-stained, 4 to 30% gradient acrylamide gels of canine plasma after incubation with cholesterol-celite revealed that the concentration of the major high density lipoproteins (HDL3) decreased, and the concentration of subclasses of HDL-with apo-E (HDL1 and HDLc) increased 2- to 5-fold. In the second system, cholesterol-loaded mouse peritoneal macrophages released cholesterol to HDL in an incubation medium containing 10 to 20% canine serum. The HDL1 and HDLc, which demonstrated slower electrophoretic mobility as determined by Geon-Pevikon block electrophoresis, became enriched in cholesterol and cholesteryl esters. Gradient gel electrophoresis showed substantial increases in these subclasses of HDL-with apo-E. The cholesterol-loaded mouse peritoneal macrophages synthesized and secreted apo-E into the medium. When L-[35S]methionine was used as a precursor, 65 to 90% of the 35S-labeled protein associated with the lipoproteins in the 1.02 to 1.09 density range was immunoprecipitated with antibody directed against rat apo-E. Gradient gel electrophoresis of density fractions demonstrated the presence of HDL1 and HDLc as the major lipoproteins. In addition, when canine 125I-HDL3 (primarily apo-A-I-containing HDL) were added to canine serum and incubated with cholesterol-loaded macrophages, the appearance of HDL1 and HDLc was associated with a marked increase in the 125I label in these newly formed, cholesteryl ester-rich lipoproteins. There was a corresponding marked reduction in the 125I-HDL3 in the serum. Similar results were observed using human HDL3 and human serum.     

Spurious elevation of serum high-density lipoprotein cholesterol in patients with cholestatic liver diseases.

Strikingly discrepant values were obtained by two commercial precipitating reagents for serum HDL cholesterol determination in three patients with cholestatic liver diseases (two patients with primary biliary cirrhosis and one patient with chronic hepatitis). An abnormal alpha 2-migrating lipoprotein (slow alpha-lipoprotein) was observed in agarose gel electrophoresis for each serum. The slow alpha-lipoprotein was partly recovered in the supernatant by precipitation with polyethylene glycol, and was completely precipitated with a polyanion-containing reagent, which well explains the discrepancy. The slow alpha-lipoprotein isolated from one of the cases is notable for (1) having an intermediate particle size between normal LDL and normal HDL, (2) containing apo E as the major apolipoprotein, and (3) being enriched with cholesterol (esterified and free) and phospholipid. Cholesterol accumulation was also found in another HDL subclass, alpha 1-migrating HDL. A severe impediment in the clearance of cholesterol-loaded HDL particles from plasma was implied. Electrophoresis of serum lipoproteins and/or the measurement of serum apo E concentrations are necessary to avoid an erroneous estimation of HDL cholesterol in patients with hepatobiliary diseases.     

Rapid method for the isolation of lipoproteins from human serum by precipitation with polyanions

Procedures are described for the isolation of lipoproteins from human serum by precipitation with polyanions and divalent cations. A mixture of low and very low density lipoproteins can be prepared without ultracentrifugation by precipitation with heparin and either MnCl(2) alone or MgCl(2) plus sucrose. In both cases the precipitation is reversible, selective, and complete. The highly concentrated isolated lipoproteins are free of other plasma proteins as judged by immunological and electrophoretic methods. The low density and very low density lipoproteins can then be separated from each other by ultracentrifugation. The advantage of the method is that large amounts of lipoproteins can be prepared with only a single preparative ultracentrifugation. Polyanions other than heparin may also be used; when the precipitation of the low and very low density lipoproteins is achieved with dextran sulfate and MnCl(2), or sodium phosphotungstate and MgCl(2), the high density lipoproteins can subsequently be precipitated by increasing the concentrations of the reagents. These lipoproteins, containing small amounts of protein contaminants, are further purified by ultracentrifugation at d 1.22. With a single preparative ultracentrifugation, immunologically pure high density lipoproteins can be isolated from large volumes of serum.     

Separation of the main lipoprotein density classes from human plasma by rate-zonal ultracentrifugation

The major lipoprotein density classes (chylomicrons-VLDL, LDL, HDL(2) and HDL(3)) were isolated from human plasma in a two-step ultracentrifugal procedure using the Ti-14 zonal rotor. The isolation of the two major high density lipoprotein subclasses (HDL(2) and HDL(3)) was achieved in a 24-hr run using a nonlinear NaBr gradient in the density range of 1.00-1.40. The lipoproteins with a density < 1.063 found in the rotor's center were isolated in a second run of 140 min duration using a continuous linear NaBr gradient in the density range of 1.00-1.30. The isolated lipoproteins were analyzed for chemical composition and for electrophoretic mobility; purity of isolated fractions was checked by immunochemistry. The lipoproteins exhibited flotation rates, chemical compositions, and molecular weights similar to those found with the common sequential procedures in angle-head rotors. The amount of lipoprotein lipids in the bottom fraction of the zonal rotor was comparable to that of the angle-head rotor. The described method yields the main lipoprotein density classes free from albumin in a very short running time; compared with the rate-zonal techniques already in use, this method allows the quantitative separation of an additional lipoprotein density class (HDL(2)) without increasing the running time. Furthermore, this procedure proved to be suitable for isolation of plasma lipoproteins from subjects with various types and varying degrees of hyperlipoproteinemia.     

Evaluation of the polyethylene glycol precipitation method for the estimation of chicken high density lipoprotein cholesterol

A neutral polymer precipitation procedure using polyethylene glycol 6000 (PEG) for fractionation of chicken plasma lipoproteins was optimized. Lipoprotein precipitation was dependent on PEG concentration and pH but was independent of PEG exposure time. A PEG concentration of 100 g/l (pH 8) precipitated chicken plasma very low density (VLDL) and low density (LDL) lipoproteins. Disc electrophoresis of supernates demonstrated that high density lipoprotein (HDL) was retained and LDL eliminated by PEG treatment of plasma. Gel filtration chromatography of whole plasma and PEG-treated supernatants on Bio-Gel A-5m demonstrated that HDL-cholesterol content of supernates was unchanged by PEG exposure, while VLDL-cholesterol was selectively removed.     

Changes in HDL subfractions in patients with type I diabetes mellitus before and after metabolic control

In order to further investigate the behaviour of high density lipoproteins in diabetes mellitus, we studied HDL subclasses, HDL2 and HDL3, in 10 patients with newly detected, untreated insulin-deficient diabetes before starting insulin treatment and after getting a good metabolic control. We used the extractive method of Abell to determine HDL-cholesterol after LDL and VLDL precipitation with polyanions and HDL3-cholesterol after HDL2 precipitation with dextransulphate 15,000 m.w. After insulin therapy, we observed a significant increase in HDL-cholesterol and a decrease in serum triglycerides. Only HDL2-cholesterol, but not HDL3-cholesterol, raised; moreover, we found a significant inverse relationship between HDL-cholesterol (and also HDL2-cholesterol) and triglycerides. So, we think that an increase of lipoprotein lipase activity, owing to insulin treatment, could account for our results.     

A comprehensive evaluation of the heparin-manganese precipitation procedure for estimating high density lipoprotein cholesterol.

The accurate quantitation of high density lipoproteins has recently assumed greater importance in view of studies suggesting their negative correlation with coronary heart disease. High density lipoproteins may be estimated by measuring cholesterol in the plasma fraction of d > 1.063 g/ml. A more practical approach is the specific precipitation of apolipoprotein B (apoB)-containing lipoproteins by sulfated polysaccharides and divalent cations, heparin-Mn(2+) being the most commonly used combination. The present heparin-Mn(2+) procedure was found to be reasonably specific and not often subject to large errors; however, 9% (primarily hypertriglyceridemic samples) of the 966 plasma samples treated with heparin-Mn(2+) had obvious supernatant turbidity, indicating incomplete sedimentation of apoB-associated lipoproteins. Furthermore, 48% of the nonturbid supernates contained more than 1 mg/dl (mean 2.5 mg/dl) of apoB-associated cholesterol when measured by a radial immunodiffusion procedure, indicating slight overestimation of HDL cholesterol. Determination of the extent of the unprecipitated apoB-associated lipoproteins by sensitive radioimmunoassay and of the amount of precipitated high density lipoprotein by radial immunodiffusion assay of apolipoproteins A-I and A-II at various heparin and Mn(2+) concentrations indicated that the usual heparin level (approximately 1.3 mg/ml) was adequate. However, a twofold increase in Mn(2+) concentration to 0.092 M improved precipitation of the apoB-associated lipoproteins without excessive precipitation of high density lipoprotein from plasma. This increased Mn(2+) level also provided improved sedimentation of the apoB-associated lipoproteins from hypertriglyceridemic plasma. Additional observations suggested that, for convenience, the heparin and Mn(2+) can be added simultaneously as a combined reagent, that samples can be incubated for 10 minutes at room temperature before centrifugation, and that turbid supernates from hypertriglyceridemic samples can usually be made free of apoB-associated lipoproteins by centrifugation at 12,000 g for 10 minutes.     

Lipid composition and cholesterol esterification in serum lipoprotein fraction of the horse, Equus caballus.

1. Changes in lipid components of lipoproteins during incubation of horse serum at 37 degrees C were investigated. In non-incubated serum, cholesterol and lecithin existed predominantly in alpha-lipoprotein or in high-density lipoprotein (HDL). Lysolecithin was mainly associated with the fraction with density above 1.21. 2. When serum was separated into alpha- and beta-lipoproteins by the heparin precipitation method after 1 hr incubation, the decrease in alpha-lipoprotein free cholesterol and lecithin was about four times that in beta-lipoprotein counterparts. 3. When serum lipoproteins were separated by ultracentrifugation, the decrease in each lipoprotein free cholesterol was closely paralleled with that in lecithin. 4. HDL appeared to be a preferential substrate for the lecithin: cholesterol acyltransferase reaction. 5. Disc electrophoretic patterns indicated significant differences in the composition of horse serum lipoproteins from those of human and rat.     

Interchange of apoprotein components between the human plasma high density lipoprotein subclasses HDL2 and HDL3 in vitro.

The major apoproteins of human high density lipoproteins (HDL) labeled with 125I have been shown to exchange between the two major HDL subclasses HDL2 and HDL3 in vitro. This bidirectional exchange process is inhibited by cross-linking with bifunctional reagents and is apparently dependent upon the formation of collision complexes. This exchange has been demonstrated both when the subclasses of HDL are free in solution and also when one of them is covalently bound to Sepharose. Using system involving Sepharose-bound HDL, it could be shown that not only free apoprotein molecules but subunits consisting of lipid-apoprotein combinations were exchanged between HDL2 and HDL3. The rate of exchange in these processes is significant in the lifetime of the protein particles in vivo equalling approximately 2.5% per h for apoprotein exchange. These experiments suggest that there is a dynamic relationship between HDL2 and HDL3 even though each of them exists alone in vitro as stable separate entities; when they are placed together in solution significant interaction occurs between the particles. Apoprotein exchange occurs between HDL2:HDL2 and HDL3:HDL3 as well as between HDL2 and HDL3 molecules. These data also suggest that the interconversion of HDL2 and HDL3 may be affected by the availability of lipids.     

Direct determination of human and rabbit apolipoprotein B selectively precipitated with butanol-isopropyl ether

A method is described for the rapid, selective, and quantitative precipitation of apolipoprotein B from isolated hypercholesterolemic rabbit and human very low density lipoproteins (VLDL), intermediate density lipoproteins (IDL), and low density lipoproteins (LDL). Lipoprotein samples are heat-treated at 100 degrees C in 1% SDS. The denatured apoprotein solutions are then mixed briefly with two volumes of butanol-isopropyl ether 45:55 (v/v) to precipitate the apoB. The supernatant solutions, containing the non-apoB proteins and lipids, are removed and the apoB pellet is washed once with water. To determine apoB specific activity, the apoB pellet is resolubilized in 0.5 M NaOH by heating for 30 min at 120 degrees C. The hydrolyzed apoB protein is quantitated by fluorescence of a fluorescamine derivative. The precipitation of apoB is quantitative and selective: 99.5% of rabbit 125I-labeled LDL-apoB and 97.5% of human 125I-labeled LDL-apoB is precipitated and less than 5% of 125I-labeled HDL added to unlabeled VLDL, IDL, or LDL is precipitated. Triglyceride and cholesteryl ester contamination of the apoB pellet is less than 2% of their original radioactivities.     

Interaction of canine and swine lipoproteins with the low density lipoprotein receptor of fibroblasts as correlated with heparin/manganese precipitability.

Canine HDL1 and canine and swine HDLc were fractionated into several lipoprotein subpopulations by heparin/manganese precipitation. The ability of the various subfractions of HDL1 or HDLc to compete with 125I-labeled low density lipoproteins (LDL) for binding and degradation by human fibroblasts was compared. The HDL1 or HDLc which precipitated at the lowest concentration of heparin (a concentration which precipitates LDL) were the most effective in competing with 125I-LDL for binding, internalization, and degradation. A striking characteristic of these lipoproteins was the occurrence of a prominence of the arginine-rich apoprotein. The HDL1 or HDLc subfractions which were not precipitated by heparin/managanese lacked detectable arginine-rich apoprotein and did not compete significantly with the 125I-LDL for binding and degradation. Furthermore, the lipid to protein ratio differed in the precipitable and nonprecipitable lipoproteins, with those which were most efficiently bound and degraded containing more cholesterol. Specific lipoprotein interaction with heparin and with the cell surface receptors may occur by a common mechanism; namely, through a positively charged region on the lipoprotein surface which may reside with the B and arginine-rich apoproteins.     

Comparative study of the lipid dynamics in the surface layer of porcine and human high density lipoprotein subclasses by spin labeling

In order to obtain information on the determinants of the lipid dynamics in the high density lipoproteins (HDL), we have compared the structural properties of human HDL subclasses with porcine HDL artificially subdivided into density subfractions corresponding to those of human HDL. Four different positional isomers of spin labeled fatty acids and spin labeled androstanol experienced more restricted motion in porcine HDL than in the human HDL2 and HDL3 subclasses. The differences in the spin label motion could not be accounted for on the basis of the differences in the chemical composition of the lipoproteins examined. They are, however, most probably due to the specific properties of the interactions between lipids and proteins that differ among the lipoproteins.     

A Novel Chromatographic Method for the Preparation of High Density Lipoproteins

High density lipoproteins (HDL) were isolated by a procedure employing polyanion precipitation and column chromatography. The product was free of low density lipoproteins (LDL) but serum albumin (HSA) was still present. The remaining HSA was removed by an immuno-adsorbent column. The HDL isolated by our method was compared to another HDL preparation isolated from the same plasma sample by the combination of ultra centrifugation and gel chromatography.¹ It was found to have approximately the same lipid and protein composition as the HDL isolated by conventional techniques.¹ Minor differences included a higher phospholipid and apoprotein E content and lower triglyceride and ApoC II content of the HDL isolated by column chromatography. The method described here is considerably less tedious than earlier techniques, can be scaled up without substantial increase in labor and results in an approximately 30% higher yield than the method described by Rudel et al.¹     

Electrophoretic separation of high density lipoprotein subclasses in the presence of sodium tetraphenylborate]

It has been shown that the synthetic lipophilic anion, sodium tetraphenylboron, used at concentrations up to 15 mM causes modification of high density lipoproteins (HDL) by changing the electrophoretic properties of individual lipoprotein subclasses. The densitograms obtained after separation of sodium tetraphenylborate-modified HDL under non-denaturing conditions have a better resolution with respect to subclasses 2a and 2b, which markedly facilitates the analysis of the subfractional composition of lipoproteins.     

The analysis of subclasses of high-density lipoprotein by equilibrium centrifugation

A procedure is described in which the subclasses of human serum high-density lipoproteins are separated by equilibrium centrifugation, permitting an estimation of the relative amounts of each on the basis of their ultraviolet absorption. The cesium sulfate gradients used are sufficiently steep at 60.000 rpm in the analytical ultracentrifuge to cover a density range from 1.05 to 1.22 g/ml in a single experiment. Two major components are apparent in this density range, the total and relative amounts of which vary widely among sera from different individuals. In these high-density lipoprotein patterns for the sera from females, a component of banding density of 1.07 g/ml is predominant. In the sera from males, this component is usually small, while the major component has a density of 1.10 g/ml. These two components appear to correspond to high-density lipoproteins 2 and 3 but with different densities due to the use of cesium sulfate.     

Method for quantitating cholesterol in subfractions of serum lipoproteins separated by gradient gel electrophoresis

Extensive heterogeneity in particle size distribution of serum lipoproteins of baboons was resolved by a procedure that combined Sudan black B prestaining, polyacrylamide gradient gel electrophoresis (GGE), and quantitative densitometry. Each densitometric scan represented a continuous distribution of the relative amount of cholesterol in a serum sample, as a function of the lipoprotein particle size. For analytical purposes, each scan was divided into 12 fractions, representing 12 particle size ranges. The relationship between the estimated cholesterol concentrations in the summed GGE/densitometric fractions corresponding to very low-density lipoproteins (VLDL) + low-density lipoproteins (LDL) and those corresponding to high-density lipoproteins (HDL) and concentrations measured by the heparin-Mn2+ precipitation/enzymatic procedure was linear over a broad range. However, a systematic overestimation of HDL cholesterol concentration and an underestimation of VLDL + LDL cholesterol concentration was apparent. Therefore, correction factors were developed for adjusting the estimates of VLDL + LDL and HDL cholesterol concentrations obtained by the GGE/densitometric method. This analytical method is rapid, repeatable, economical, and useful for genetic and dietary research in which cholesterol concentrations in multiple particle size ranges of lipoproteins must be measured in large numbers of samples. It also is adaptable to immunoblotting procedures for detecting the distribution of specific apolipoproteins among the size-resolved lipoproteins.     

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.     

Dynamics of the lipoprotein distribution in early hypercholesterolemia characterizes the activation of cholesterol transport]

Using gradient gel electrophoresis, the levels of major classes of rabbit blood sera lipoproteins were studied over a period of 28 days. Hypercholesterolemia persisted up to the 4th day with a subsequent decrease. This was paralleled with an increase in the levels of triglyceride-rich and apoB-containing particles. The decrease of the electrophoretic mobility of low density lipoproteins correlated with an increased content of the intermediate fraction. On the 28th day after the beginning of experiment the concentration of total high density lipoproteins showed an increase. The subfractional redistribution of HDL3 and HDL2 subclasses pointed to the stimulation of the accepting process and the overall reverse cholesterol transport system. A comparison of experimental results with literary data allowed to conclude that the relative decrease of the serum cholesterol level typical of hypercholesterolemia of one month duration is due to the activation of specific and nonspecific preventive mechanisms.     

In vitro incorporation of radiolabeled cholesteryl esters into high and low density lipoproteins

We have developed and validated a method for in vitro incorporation of radiolabeled cholesteryl esters into low density (LDL) and high density lipoproteins (HDL). Radiolabeled cholesteryl esters dissolved in absolute ethanol were mixed with LDL or HDL in the presence of lipoprotein-deficient serum (LPDS) as a source of core lipid transfer activity. The efficiency of incorporation was dependent on: a) the core lipid transfer activity and quantity of LPDS, b) the mass of added radiolabeled cholesteryl esters, c) the length of incubation, and d) the amount of acceptor lipoprotein cholesterol. The tracer incorporation was documented by repeat density gradient ultracentrifugation, agarose gel electrophoresis, and precipitation with heparin-MnCl2. The radiolabeling conditions did not affect the following properties of the lipoproteins: 1) chemical composition, 2) electrophoretic mobility on agarose gels, 3) hydrated density, 4) distribution of apoproteins on SDS gels, 5) plasma clearance rates, and 6) immunoprecipitability of HDL apoproteins A-I and A-II. Rat HDL containing radiolabeled cholesteryl esters incorporated in vitro had plasma disappearance rates identical to HDL radiolabeled in vivo.     

Expression of human apolipoprotein A-I epitopes in high density lipoproteins and in serum

The expression and immunoreactivity of apolipoprotein (apo) A-I epitopes in high density lipoproteins (HDL) and serum has been investigated using two series of monoclonal antibodies (Mabs) which have been described elsewhere. Series 1 Mabs, identified as 3D4, 6B8, and 5G6, were obtained by immunization and screening with apoA-I, and series 2 Mabs, identified as 2F1, 4H1, 3G10, 4F7, and 5F6, were obtained by immunization and screening with HDL. These Mabs were characterized with respect to their binding to HDL particles in solution. In series 2 Mabs, 2F1, 3G10, and 4F7, which react with apoA-I CNBr-fragments 1 and 2, could precipitate 100% of 125I-labeled HDL, while 4H1 and 5F6, which react with CNBr fragments 1 and 3, precipitated 90 and 60% of 125I-labeled HDL, respectively. Therefore, three distinct epitopes mapped to CNBr fragments 1 and 2 have been identified which are expressed on all HDL particles, indicating that several antigenic do mains exist on apoA-I which have the same conformation on all apoA-I-containing lipoproteins. The Mabs reacting at these sites have significantly higher affinity constants for 125I-labeled HDL than those that failed to precipitate 100% of HDL. This suggests that the high affinity Mabs react with apoA-I epitopes that are both expressed on all lipoproteins and located in thermo-dynamically stable regions of the molecules. All Mabs from series 1 precipitated 35% or less of 125I-labeled HDL prepared from freshly collected serum, but the proportion of HDL particles expressing the epitopes for these Mabs doubled or more upon serum storage at 4 degrees C. The time course of the alteration of apoA-I antigen in vitro was measured in three normolipemic donors. Upon storage of serum at 4 degrees C, the immunoreactivity of series 2 Mabs (4H1, 3G10) remained unchanged. However, the immunoreactivity of series 1 Mab 3D4 increased linearly at 38%/day for 4 weeks and by 12 weeks had plateaued at about 280-fold compared to day 1. The immunoreactivity of other series 1 Mabs also increased significantly with time in vitro. This process was partially inhibited in the presence of EDTA and by addition of antioxidants, however, the exact molecular nature of this in vitro alteration of apoA-I antigen was not identified.