Estimation of lipoprotein and apoprotein distribution in rat plasma by cumulative density ultracentrifugation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis

Lipoprotein distribution in rat plasma determined after sequential ultracentrifugation (requiring 8 days of centrifugation to separate lipoproteins in five density classes), was compared to estimates based upon cumulative density ultracentrifugation (46 hr of ultracentrifugation). In general comparable values were obtained by the two methods with regard to protein, total cholesterol, cholesteryl ester, free cholesterol, and triacylglycerol distribution. However, the HDL3 protein concentration found by sequential ultracentrifugation was only about 50% of that found after the cumulative procedure. Apolipoproteins in lipoproteins isolated by the two methods were well separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Color of the stained bands was extracted and read photometrically. A linear standard curve was obtained with albumin. Absorbance corresponding to 1 microgram/ml was 0.057. Below d = 1.100 g/ml (HDL2b) the two ultracentrifugation methods gave comparable results for all apoproteins. In contrast to this the level of apo A-I, apo E, and apo A-IV in the more dense types of HDL was higher when estimated by cumulative than by sequential ultracentrifugation. In HDL3 isolated by sequential ultracentrifugation the apo A-IV, apo E, and apo A-I concentrations were 51, 31, and 45% respectively, of values found after cumulative ultracentrifugation. The results indicate that cumulative density ultracentrifugation, followed by colorimetric determination of apoproteins separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, is a useful approach when studying lipoprotein distribution in rat plasma.     

Heterogeneity of serum lipoproteins during the fetal and neonatal development of the pig

Serum lipoproteins from fetal, neonatal and adult pigs were characterized with the use of lipid analysis, polyacrylamide gradient gel electrophoresis, two-dimensional immunoelectrophoresis and zonal ultracentrifugation. Almost all serum cholesterol was found in LDL during the early stages of fetal development, while low but increasing levels appeared in the fetal pig HDL by the end of the gestation period. In the fetal pig, most of the serum triglycerides could be found in the HDL fraction. After the start of suckling, the levels of serum triglycerides and cholesterol increased. Most of these exogenous lipids were found in the chylomicrons + VLDL + LDL fraction of the newborn pig serum. The molecular weights of the native serum lipoproteins were calculated as being 2.0-2.4 X 10(5) daltons for newborn pig HDL and 1.4-1.7 X 10(6) daltons for newborn pig LDL. Minor changes in the molecular weight distributions were detected within these ranges for both HDL and LDL during fetal and neonatal development of the pig. Zonal ultracentrifugation of neonatal pig serum partly separated the LDL into three subfractions, whereas neonatal HDL appeared as one broad fraction.     

Effects of serum amyloid A protein (SAA) on composition, size, and density of high density lipoproteins in subjects with myocardial infarction

The acute phase reactant serum amyloid A protein (SAA) circulates in plasma as a constituent of high density lipoproteins (HDL). Advantage has been taken of the induction of SAA in human subjects with myocardial infarction to study the effect of SAA on the physical and chemical properties of HDL. HDL were isolated by sequential ultracentrifugation and assayed for chemical composition. Apolipoprotein composition was assessed by SDS polyacrylamide gel electrophoresis. Size distribution of HDL was determined by gradient gel electrophoresis and density distribution by density gradient ultracentrifugation. In studies of 18 subjects with myocardial infarction, SAA accounted for 8-87% (median 52%) of the HDL apolipoprotein. These SAA-enriched HDL had a density comparable to that of normal HDL subfraction-3 (HDL3). Their chemical composition differed from normal HDL3, however, with a reduced phospholipid (17% vs 24%) and an increased triglyceride (7.7% vs 1.6%) value. When separated by gradient gel electrophoresis, the SAA-enriched HDL were much larger than normal HDL3, having a radius of 4.5-5.3 nm that extended well into the size range of HDL2; particle size correlated with SAA content. This disassociation between particle density and particle size was also observed with the SAA-enriched HDL isolated from a subject with secondary amyloidosis and also with normal HDL that had been enriched with SAA during incubation in vitro. Thus, the presence of high levels of SAA has been found to be associated with phospholipid-depleted particles of a density comparable to HDL3 but a size larger than normal HDL3.     

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.     

Comparison of gradient gel electrophoresis and zonal ultracentrifugation for quantitation of high density lipoproteins

The study was conducted to compare gradient gel electrophoresis (GGE) and zonal ultracentrifugation for quantitation of human plasma high density lipoproteins (HDL). Plasma samples were obtained from seven normal subjects consuming a high fat diet (65% total calories) followed by a high carbohydrate diet (65% total calories). HDL were fractionated into HDL2 and HDL3 by zonal ultracentrifugation and lipid and protein mass were determined. HDL were also fractionated by GGE and the results were compared to the zonal method. Zonally isolated HDL2 represented a homogeneous particle population that was equivalent to HDL2b as determined by GGE. By the zonal method, HDL2 accounted for 27 +/- 4% (mean +/- SEM) of total HDL mass in subjects on the high fat diet as compared to 16 +/- 2% in subjects fed the high carbohydrate diet; by GGE, the HDL2b values were 27 +/- 4% and 14 +/- 1%, respectively. The coefficient of correlation (n = 25) for the two methods was 0.894 (P less than 0.001).     

Particle distribution of human serum high density lipoproteins.

Density gradient ultracentrifugation of human serum high density lipoproteins (HDL) from both normolipemic males and females results in a distribution of HDL concentration versus subfraction hydrated density which has three maxima. Gradient gel electrophoresis of total HDL is characterized by three banding maxima, the positions of which suggest the presence of three particle size ranges: I. 10.8-12.0 nm, II. 9.7-10.7 nm, and III. 8.5-9.6 nm. Gradient gel electrophoresis of density gradient subfractions established an inverse relationship between particle size and particle hydrated density which was corroborated by electron microscopy and analytic ultracentrifugation. Comparison of male HDL from size ranges I, II, and III with female HDL from the same size ranges showed only small differences in the mean value of the peak F degrees 1.20 rate, size, molecular weight, protein weight percent, and weight protein/weight phospholipid. Major differences between males and females were seen in the relative amounts of HDL in density gradient subfractions 1-3 (size range I material) and 11-12 (size range III material); the percent total HDL in the group of subfractions 1-3 was greatly increased in female HDL while that of the group of subfractions 11-12 was increased in the male HDL. These studies indicate the presence of at least three major components in HDL instead of two (HDL2 and HDL3) and that peak F degrees 1.20 rate differences in HDL schlieren patterns between males and females are a function of the relative levels of these three components.     

Isolation of plasma lipoproteins by zonal ultracentrifugation in the B14 and B15 titanium rotors

Lipoproteins were isolated from plasma of man, dog, rabbit, rat, and chicken by ultracentrifugation in continuous density gradients using the B14 titanium and B15 titanium zonal rotors. Both the VLDL and the LDL of human plasma were separated easily from the HDL and from the other more plentiful plasma proteins by centrifugation for only 1 or 2 hr in the B14 or B15 rotor, respectively. Satisfactory separation of the HDL from the more dense plasma proteins was not achieved with these rotors. The human LDL achieved isopycnic equilibrium (d 1.04) on prolonged periods (> 24 hr) of centrifugation in a sucrose-KBr density gradient. The pattern of distribution of cholesterol and phospholipid throughout the density gradient coincided with the pattern of distribution of the lipoprotein-protein measured spectrophotometrically or chemically. The concentration of cholesterol and phospholipid in the lipoproteins isolated by zonal ultracentrifugation agreed with analyses reported for lipoproteins isolated by sequential centrifugation in solutions of increasing density. The lipoproteins isolated by zonal ultracentrifugation were characterized further by their electrophoretic behavior. The fractions which were identified as the LDL (d 1.04-1.05) from all species migrated on paper as a beta-globulin; the LDL from plasma of dogs contained an additional component which has been designated as an alpha(2)-globulin. The fractions which were identified as the HDL from all species migrated as an alpha(1)-globulin. Reaction of human LDL with either rabbit antihuman beta-lipoprotein or rabbit antihuman serum resulted in a single immunodiffusion band. The S(f, 1.063) of the human LDL was calculated to be 6.0. When plasma from humans or rabbits was centrifuged in the B15 rotor, the HDL was not visible as a distinct peak and was not separable from the bulk of the more dense plasma proteins; when plasma from dogs or chickens was centrifuged under identical conditions, the HDL was clearly detectable. Even though the mean density of the HDL from dogs or chickens was not different from that of man or rabbits, the visibility of this lipoprotein in dogs and chickens was probably due to its high concentration in the plasma of these species. When plasma from the rat was centrifuged under similar conditions, the HDL was also clearly in evidence. Although rat plasma contained a relatively small concentration of HDL, the lipoprotein had a lower mean density than did the HDL of the other species and was therefore more easily separable from the dense plasma proteins. The procedure of zonal ultracentrifugation for the isolation of lipoproteins by flotation is simultaneously preparative and analytical and should find useful application in the investigation of the soluble lipoproteins from plasma and tissues.     

Small,dense HDL 3 particles attenuate apoptosis in endothelial cells: pivotal role of apolipoprotein A‐I

Plasma high‐density lipoproteins (HDLs) protect endothelial cells against apoptosis induced by oxidized low‐density lipoprotein (oxLDL). The specific component(s) of HDLs implicated in such cytoprotection remain(s) to be identified. Human microvascular endothelial cells (HMEC‐1) were incubated with mildly oxLDL in the presence or absence of each of five physicochemically distinct HDL subpopulations fractionated from normolipidemic human plasma (n= 7) by isopycnic density gradient ultracentrifugation. All HDL subfractions protected HMEC‐1 against oxLDL‐induced primary apoptosis as revealed by nucleic acid staining, annexin V binding, quantitative DNA fragmentation, inhibition of caspase‐3 activity and reduction of cytoplasmic release of cytochrome c and apoptosis‐inducing factor. Small, dense HDL 3c displayed twofold superior intrinsic cytoprotective activity (as determined by mitochondrial dehydrogenase activity) relative to large, light HDL 2b on a per particle basis (P < 0.05). Equally, all HDL subfractions attenuated intracellular generation of reactive oxygen species (ROS); such anti‐oxidative activity diminished from HDL 3c to HDL 2b. The HDL protein moiety, in which apolipoprotein A‐I (apoA‐I) predominated, accounted for ～70% of HDL anti‐apoptotic activity. Furthermore, HDL reconstituted with apoA‐I, cholesterol and phospholipid potently protected HMEC‐1 from apoptosis. By contrast, modification of the content of sphingosine‐1‐phosphate in HDL did not significantly alter cytoprotection. We conclude that small, dense, lipid‐poor HDL 3 potently protects endothelial cells from primary apoptosis and intracellular ROS generation induced by mildly oxLDL, and that apoA‐I is pivotal to such protection.     

The serum lipoprotein pattern of water buffalo (Bubalus bubalis)

1. The serum lipoprotein pattern of water buffalo was studied by means of electrophoresis and the lipoproteins were isolated by ultracentrifugation on the basis of their hydrated density. 2. High density lipoproteins (HDL) showed a higher level of cholesterol than did the other lipoproteins. Moreover, the level of phospholipids was higher in HDL than in very low density lipoproteins (VLDL). 3. The buffalo B100 apoprotein was similar to that of man and rat. Three apoproteins similar to human apo E, apo AI and AII were found in buffalo HDL, buffalo VLDL contained essentially apo B protein.     

Separation of the principal HDL subclasses by iodixanol ultracentrifugation

HDL subclasses detection, in cardiovascular risk, has been limited due to the time-consuming nature of current techniques. We have developed a time-saving and reliable separation of the principal HDL subclasses employing iodixanol density gradient ultracentrifugation (IxDGUC) combined with digital photography. HDL subclasses were separated in 2.5 h from prestained plasma on a three-step iodixanol gradient. HDL subclass profiles were generated by digital photography and gel scan software. Plasma samples (n = 46) were used to optimize the gradient for the resolution of HDL heterogeneity and to compare profiles generated by IxDGUC with gradient gel electrophoresis (GGE); further characterization from participants (n = 548) with a range of lipid profiles was also performed. HDL subclass profiles generated by IxDGUC were comparable to those separated by GGE as indicated by a significant association between areas under the curve for both HDL₂ and HDL₃ (HDL₂, r = 0.896, P < 0.01; HDL₃, r = 0.894, P < 0.01). The method was highly reproducible, with intra- and interassay coefficient of variation percentage < 5 for percentage area under the curve HDL₂ and HDL₃, and < 1% for peak Rf and peak density. The method provides time-saving and cost-effective detection and preparation of the principal HDL subclasses.     

Rapid method for the isolation of two purified subfractions of high density lipoproteins by differential dextran sulfate-magnesium chloride precipitation

We describe a rapid and reliable three-step precipitation procedure for the isolation of large amounts of the two major components of high density lipoproteins (HDL) in human serum. Precipitation was accomplished by means of dextran sulfate (DS) of mol. wt. 500,000 and MgCl2. First, all apoB-associated lipoproteins of any density were selectively precipitated with critical concentrations of reagents. Secondly, a subfraction of HDL was differentially precipitated from the apoB-depleted serum by increasing the concentration of both reagents. Eventually, the bulk of the remainder of HDL was precipitated by lowering the pH to 5.4. According to the precipitation patterns and the density profiles, the DS-Mg procedure provides a clear differentiation between the two HDL components. According to the compositional criteria and the ultracentrifugal characteristics, the two polyanion-precipitated subclasses are very similar to, if not identical with, the two density subclasses, the lighter HDL2 and the heavier HDL3, isolated by preparative ultracentrifugation after apoB-containing lipoproteins had been removed.     

Isolation of high-density lipoproteins by immunoaffinity column chromatography from hog plasma

High density lipoprotein (HDL) was isolated from hog plasma by a simple immunoaffinity column chromatography procedure using immobilized anti-apolipoprotein AI. The composition of HDL isolated by immunoaffinity chromatography was nearly identical to that of a control sample that was isolated by an alternate method utilizing ultracentrifugation and gel chromatography. The HDL isolated by immunoaffinity chromatography had a larger number of polypeptide components that the control as indicated by acrylamide gel electrophoresis in the presence of urea. When the HDL isolated by immunoaffinity chromatography was applied to a heparin-agarose column the amount of protein retained was approximately twice that of the control. These findings indicate that the ultracentrifugation procedure probably induced the loss of apolipoprotein E containing components from the HDL complex.     

Influence of a plasma fraction of human blood, rich in high density lipoprotein, on in vitro formation of prostaglandin I2 (PGI2) and thromboxane A2 (TXA2)

The influence of a plasma fraction of human blood, rich in high density lipoprotein (HDL), was investigated on the "in vitro" formation of PGI2 and TXA2. The addition of 1 mg HDL-cholesterol per ml incubation fluid stimulated significantly the biotransformation of prostaglandin H2 into PGI2 by the microsomal fraction of pig aorta. The TXB2 formation capacity of whole clotted blood was inhibited by administration of HDL in a dose dependent manner. These results suggest that added HDL is able to enhance the ratio PGI2:TXA2. This did not depend on the preparation of HDL either by ultracentrifugation or by precipitation.     

The isolation of lipoproteins from human plasma by ultracentrifugation in zonal rotors

The major classes of lipoproteins were isolated from human plasma by ultracentrifugation in continuous density gradients using the Ti-14 and Ti-15 zonal rotors. Chylomicrons + VLDL, LDL, and HDL were separated from each other and from the more dense residual proteins (albumin fraction) of plasma by rate-zonal flotation in NaBr gradients in the density range 1.0-1.4. The chylomicron-VLDL fraction was subfractionated into constituent chylomicrons and VLDL by zonal ultracentrifugation in NaBr gradients in the density range 1.0-1.1. Plasma lipoproteins were analyzed for composition of lipids and content of protein, for electrophoretic mobility on paper, and for antigenic determinants by immunoelectrophoresis and immunodiffusion. Flotation constants (S(f)) of the LDL and HDL were calculated from measurements made in the analytical ultracentrifuge. Lipoproteins isolated from plasma by zonal ultracentrifugation were identical by these criteria to lipoproteins isolated by the usual procedure of sequential ultracentrifugation in solvents of increasing density. The procedure of zonal ultracentrifugation is rapid, quantitative, and less laborious than sequential techniques. Lipoproteins isolated by zonal ultracentrifugation are relatively uncontaminated by other proteins and extensive washing is therefore unnecessary. Zonal ultracentrifugation is more than a preparative method for the plasma lipoproteins; it is also an analytical procedure in that a record is obtained of the distribution and quantity of the lipoprotein within the continuous density gradient.     

The molar ratio of the two major polypeptide components of human high density lipoprotein.

Human high density lipoprotein (HDL) and its subfractions (HDL2 and HDL3) were separated by ultracentrifugation and the molar ratio of the two major polypeptide chains apo-Gln-I and apo-Gln-II was determined by fluorescence tagging of sodium dodecyl sulfate-denatured proteins combined with polyacrylamide disc gel electrophoresis. Using purified apo-Gln-I and apo-Gln-II standards, it was found that holo HDL, holo HDL2, and holo HDL3 from all plasma samples contained a molar ratio of apo-Gln-I to the disulfide-bound dimer of apo-Gln-II of 2:1, that is a 1:1 ratio in terms of each species of polypeptide chain. The method described is useful for making repeated and rapid measurements on microgram quantities of intact lipoproteins.     

A simple and precise method for measuring HDL-cholesterol subfractions by a single precipitation followed by homogenous HDL-cholesterol assay

HDL consists of two major subfractions, HDL2 and HDL3. This paper describes a simple method for assaying HDL subspecies by combining a single precipitation with a direct high density lipoprotein-cholesterol (HDL-C) assay. A precipitation reagent (0.06 ml) containing 1,071 U/ml heparin, 500 mmol/l MnCl2) and 12 mg/ml dextran sulfate was added to a serum (0.3 ml). The sample was incubated and centrifuged at 10,000 rpm for 10 min. HDL3-C was measured by a homogenous HDL-C assay in the supernatant, and HDL2-C was estimated by subtracting the HDL3-C from the direct HDL-C. The HDL3-C and HDL2-C values determined by the precipitation method were identical to those determined by ultracentrifugation, and there were excellent correlations between the methods in the measurements of HDL3-C and HDL2-C (r = 0.933 and 0.978, respectively; n = 102). The two methods also proved to be highly correlated in the measurement of apolipoprotein A-I and A-II in HDL subfractions. The HDL-C subfractions determined by ultracentrifugation were more closely associated with the homogenous HDL-C assay than with the total cholesterol assay, especially in the hypertriglyceridemic samples. Our method is far simpler and more precise than the classical dual precipitation method for HDL-C subfractions, and it can be easily performed in a routine chemical laboratory.     

Receptors for homologous plasma lipoproteins on a rat hepatoma cell line

Hepatocytes express on their surfaces more than one class of receptors capable of mediating the internalization of lipoproteins. However, relatively little is known about the binding characteristics of hepatic receptors for various lipoproteins, about the regulation of the receptors, and about the consequences for intracellular lipid metabolism of uptake of lipoproteins via different classes of receptors. The aim of the present studies was to characterize the binding and degradation of various lipoproteins and their mutual competition for cellular processing. Since these kinds of studies may be more easily carried out in continuous established hepatoma cell lines than in nondividing primary hepatocyte cultures, we examined the lipoprotein receptor functions of a well differentiated rat hepatoma (H-35). Cells were grown to confluence in Eagle's minimal essential medium in 15% newborn calf serum. Medium then was changed to 15% lipoprotein-deficient serum for 44 hr before experiments. External binding of 125I-labeled rat plasma and intestinal lymph lipoproteins was assessed at 4 degrees C. Cellular uptake and degradation were assessed at 37 degrees C. Lipoproteins were isolated by fixed angle or zonal ultracentrifugation or by heparin affinity column chromatography and characterized as to their lipid and apoprotein compositions. Labeled low density (LDL), high density (HDL2), non-apoE-HDL, very low density lipoproteins (VLDL), and chylomicron remnants (CM-R) each manifested specific and saturable binding and degradation by the hepatoma cells. Competition experiments indicated that separate receptors were present for LDL, HDL2, and CM-R. Most of HDL2 appeared to be bound to the non-apoE-HDL receptor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Glycosphingolipid-high density lipoprotein-3 interactions. I. Transfer of glycosphingolipid from phosphatidylcholine vesicles to high density lipoprotein-3

Single bilayer vesicles (d less than 1.02 g/ml) of 3H-glycosphingolipids and [14C]phosphatidylcholine in the molar ratio of 1:7 were prepared by ethanolic injection of the lipid mixture into buffer, concentrated, and incubated with human serum high density lipoprotein-3 (HDL3; d = .14 g/ml) at 37 degrees C. Equilibrium ultracentrifugation of the incubation mixtures on a 0-22% NaBr gradient revealed the presence of three discrete lipid-protein complexes of density 1.03, 1.06, and 1.12 g/ml (Peaks I, II, and III, respectively). Each peak was homogeneous upon reultracentrifugation and the protein and radioactivity eluted as a single peak upon Sepharose CL-6B chromatography. Compositional analysis showed peak I to contain 2.6% protein (apo-A-I peptide) and 4.3% cholesterol, peak II to contain 17.6% protein (apo-A-I peptide) and 6.3% cholesterol, and peak III to have a composition similar to HDL3. Electron microscopy of negatively stained samples confirmed the homogeneity of the peaks and the similarity between peak III and HDL3. Peak II particles were larger than HDL3; peak I particles resembled fused or aggregated vesicles which could be removed by ultracentrifugation; disc-shaped particles were not seen in any of the fractions. Direct incubation of HDL3 or human serum with 3H-glycosphingolipid dispersions did not yield a glycolipid . HDL3 complex as judged by density gradient ultracentrifugation and Sepharose CL-6B chromatography. However, incubation of 3H-glycolipid/phosphatidylcholine vesicles with serum did result in transfer of 3H-glycolipid to the HDL fraction. It was concluded that glycolipids incorporated into a lipid membrane structure can interact with, and become incorporated into, high density lipoprotein.     

Alterations of the plasma lipoproteins and apoproteins following cholesterol feeding in the rat.

The feeding of cholesterol to rats resulted in marked alterations in the type and distribution of the plasma lipoproteins and their apoproteins. The hyperlipoproteinemia was characterized by an increase in the d < 1.006 lipoproteins (B-VLDL and VLDL), an increase in the intermediate and low density lipoproteins (LDL), and the appearance of HDL(c). Associated with these lipoproteins was a prominence of the arginine-rich apoprotein. The high density lipoproteins (HDL) were decreased. A two-dimensional immunoelectrophoretic procedure was adapted to quantitate the changes in distribution of the arginine-rich apoprotein in the plasma and various ultracentrifugal fractions obtained from control and cholesterol-fed rats. In rats fed the cholesterol diet, the total plasma arginine-rich apoprotein increased from a control value of approximately 29 mg/dl to 47 mg/dl. The method of ultracentrifugation, however, was found to markedly alter the quantitative results. When the 60 Ti rotor was used at maximum speed to isolate the ultracentrifugal fractions, less than 50% of the total plasma arginine-rich apoprotein was associated with the lipoproteins in the d < 1.006 or the d 1.006-1.02, 1.02-1.063, or 1.063-1.21 ultracentrifugal fractions. By contrast, after limited ultracentrifugation with the 40 rotor, much less arginine-rich apoprotein was lost, with approximately 20% of the arginine-rich apoprotein in control rats and 10% in cholesterol-fed rats found in the d > 1.21 fraction. Significant alterations in the arginine-rich apoprotein quantitation notwithstanding, the observations of increased arginine-rich apoprotein in the B-VLDL, intermediate fraction, and HDL(c) following cholesterol feeding remained valid. However, precise quantitation awaits refinements in lipoprotein isolation techniques.     

Immunoaffinity fractionation of high-density lipoprotein subclasses 2 and 3 using anti-apolipoprotein A-I and A-II immunosorbent gels

High-density lipoprotein (HDL) subclasses 2 and 3 prepared by density gradient ultracentrifugation have been further fractionated by immunoaffinity chromatography using antibody affinity gels targetting the major HDL apolipoproteins, A-I and A-II. Fractions containing A-I without A-II (AI w/o AII) and A-I with A-II (AI w AII) were isolated from both density ranges. Whereas there were similar concentrations of the major subfraction (HDL3(AI w AII] in both males and females, the remaining subfractions were present in higher concentrations in females as compared to males, in the order HDL3 (AI w/o AII) less than HDL2(AI w AII) less than HDL2(AI w/o AII). The difference was most marked for HDL2 (AI w/o AII), where plasma concentrations in females were almost 3-fold greater than in males. Compositional analyses indicated that the plasma concentrations of the fractions, rather than their compositions, were the major determinants of male-female differences in HDL levels. In contrast, fractions defined by similar apolipoprotein criteria and isolated from different density subclasses (i.e., HDL2(AI w/o AII) vs. HDL3(AI w/o AII) and HDL2(AI w AII) vs. HDL3(AI w AII] showed major compositional differences. This is suggestive of distinct lipoprotein particles.