Further resolution of the low density lipoprotein spectrum in normal human plasma: physicochemical characteristics of discrete subspecies separated by density gradient ultracentrifugation

The molecular basis of the heterogeneity of plasma low density lipoproteins (LDL, d 1.024-1.050 g/ml) was evaluated in 40 normolipidemic male subjects following fractionation by isopycnic density gradient ultracentrifugation into eight major subspecies. The mass profile of our subjects' LDL uniformly displayed single symmetric or asymmetric peaks as a function of density; the peak occurred most frequently (20 subjects) in subfraction 7 (d 1.0297-1.0327 g/ml). Several physicochemical properties (hydrodynamic behavior, electrophoretic mobility, chemical composition, size and particle heterogeneity, and apolipoprotein heterogeneity) of the LDL subfractions were examined. Hydrodynamic analyses revealed unimodal distributions and distinct peak Sf degree rates in individual subfractions. Such behavior correlated well with particle size and heterogeneity data, in which LDL subspecies were typically resolved as unique narrow bands by gradient gel electrophoresis. Subspecies with average densities of 1.024 to 1.0409 g/ml ranged from 229 to 214 A in particle diameter. LDL protein content increased in parallel with density while the proportion of triglyceride diminished; cholesteryl esters predominated, accounting for approximately 40% or more by weight. Distinct differences in net electric charge were demonstrated by electrophoresis in agarose gel, the subspecies with average density of 1.0314 g/ml displaying the lowest net negative charge. ApoB-100 was the major apoprotein in all subspecies, and constituted the unique protein component over the density interval 1.0271-1.0393 g/ml. ApoE and apo[a] were detected at densities less than 1.0271 and greater than 1.0393 g/ml. While apoE was evenly distributed within these two regions, representing up to 2% of apoLDL, the distribution of apo[a] was skewed towards the denser region, in which it amounted to 3-7% of apoLDL. ApoC-III was detectable as a trace component at densities greater than 1.0358 g/ml. Calculation of the number of molecules of each chemical component per LDL subspecies showed the presence of one copy of apoB-100 per particle, in association with decreasing amounts of cholesteryl ester, free cholesterol, and phospholipid. These data indicate that a similar overall molecular organization and structure is maintained in a unimodal distribution of LDL particle subspecies over the density range approximately 1.02 to 1.05 g/ml. In sum, our data may be interpreted to suggest that microheterogeneity in the physicochemical properties of human LDL subspecies reflects dissimilarities in their origins, intravascular metabolism, tissular fate, and possibly in their atherogenicity.     

Alteration of high density lipoprotein subfraction distribution with induction of serum amyloid A protein (SAA) in the nonhuman primate

Overnight chair restraint results in a dramatic increase in serum amyloid A protein (apoSAA) of nonhuman primate high density lipoprotein (HDL). To determine whether apoSAA induction resulted in a displacement of indigenous HDL protein or a change in the subfraction distribution of HDL, we analyzed the characteristics of HDL subfractions in eight vervet monkeys before and 24 hr after apoSAA induction. Blood was taken from each animal before and after chair restraint to induce apoSAA. HDL was isolated from the plasma by ultracentrifugation and agarose column chromatography. The isolated HDL was subfractionated by density gradient centrifugation and five resulting subfractions were analyzed for protein and lipid content. With apoSAA induction there was a significant increase in d less than 1.09 g/ml protein, phospholipid, and free and esterified cholesterol which resulted in a 44% increase in the total mass of this subfraction. Concomitantly, there was a significant decrease in d 1.10-1.11 g/ml protein, total cholesterol, and cholesteryl ester, which resulted in a 16% decrease in the total mass of the subfraction. The response of the d 1.10-1.11 and d greater than 1.12 g/ml subfraction protein, cholesterol, and phospholipid concentrations to chair restraint for individual animals was directly proportional to their plasma HDL concentrations. Although there was a change in the HDL subfraction concentrations after chair restraint, there was no change in the lipid composition of the HDL subfractions nor in the total amount of HDL protein. However, the apoSAA/A-I ratio was significantly increased with induction while the apoA-II + C's/A-I ratio remained unchanged. The apoSAA/A-I ratio progressively increased with the density of the HDL subfraction. The protein composition of the d greater than 1.12 g/ml subfraction was changed from an average of three apoA-I and two apoA-II (or C's) molecules per particle to an average of two apoA-I, one apoA-II (or C's), and three or four apoSAA molecules per particle after chair restraint. Thus, apoSAA was predominantly associated with the denser HDL subfractions even though the lighter HDL subfractions were the most responsive in terms of changes in concentration. These data suggest that chair restraint of nonhuman primates induces apoSAA which displaces apoA-I and apoA-II or C's from HDL without altering the overall lipid and protein composition of the particle. In addition, chair restraint alters the concentration of HDL subfractions in ways that may be independent of apoSAA induction.     

Separation of swine plasma LDL from Lpb2/3 heterozygotes into two apoB allelic haplotypes, Lpb2 and Lpb3, with apoB epitope specific antibodies

Studies were performed to investigate the separation of Lpb (lipoprotein B) species present in plasma of heterozygous swine bearing the Lpb2 and Lpb3 apoB mutant genes. Low density lipoprotein (LDL) fractions from Lpb2/2 and Lpb3/3 homozygotes were coupled to a matrix and used to isolate affinity-purified antibodies anti-Lpb2 and anti-Lpb3 from swine alloimmune sera, one with specificity for the Lpb2 epitope(s) and the other for Lpb3. These antibodies in turn were used to construct two immunosorbers, anti-Lpb2 and anti-Lpb3 Sepharose columns. To separate the two Lpb haplotype populations present in LDL, a density gradient ultracentrifuge subfraction (d 1.032-1.043 g/ml) obtained from Lpb2/3 heterozygous pigs was applied to the specific immunosorbers. The retained fraction from the anti-Lpb2 column reacted in the double immunodiffusion test with anti-Lpb2 and anti-Lpb13 immune sera but not with either anti-Lpb3 or anti-Lpb12, while the unretained fractions reacted with anti-Lpb3 and anti-Lpb12 but not with either anti-Lpb2 or anti-Lpb13. The reaction patterns obtained with the two sets of alloimmune sera indicate the existence of two separate lipoprotein populations in LDL: one lipoprotein carrying the Lpb2 and Lpb13 epitopes corresponding to the Lpb2 apoB allele, and the other carrying the Lpb3 and Lpb12 allotypes specified by the Lpb2 gene. Immunoblotting with anti-Lpb2 and anti-Lpb3 and silver staining showed that the epitopes of both isolated LDL subpopulations are associated with apoB-100. Neutral lipid analyses showed no differences between the isolated Lpb2 and Lpb3 lipoprotein species from the Lpb2/3 heterozygotes. These studies demonstrate that plasma LDL subfractions from Lpb heterozygous swine can be separated into two haplotype populations, each corresponding to the product of one apoB gene, and reveal a new insight into the phenotypic expression of plasma LDL, and the LDL phenotype-genotype relationship. Furthermore, this approach will facilitate studies on metabolic differences of two structurally distinct LDL, unaffected by in vitro manipulation, exposed to the metabolic milieu of one individual.     

Density distribution and physicochemical properties of plasma lipoproteins and apolipoproteins in the goose, Anser anser, a potential model of liver steatosis

The fractionation and physicochemical characterization of the complex molecular components composing the plasma lipoprotein spectrum in the goose, a potential model of liver steatosis, are described. Twenty lipoprotein subfractions (d less than 1.222 g/ml) were separated by isopycnic density gradient ultracentrifugation, and characterized according to their chemical composition, particle size and particle heterogeneity, electrophoretic mobility, and apolipoprotein content. Analytical ultracentrifugal analyses showed high density lipoproteins (HDL) to predominate (approximately 450 mg/dl plasma), the peak of its distribution occurring at d approximately 1.090 g/ml (F1.21 approximately 2.5). The HDL class displayed marked density heterogeneity, HDL1-like particles being detected up to a lower density limit of approximately 1.020 g/ml, particle size decreasing progressively from 17-19 nm at d 1.024-1.028 g/ml to 10.5-12 nm (d 1.055-1.065 g/ml), and then remaining constant (approximately 9 nm) at densities greater than 1.065 g/ml. HDL subfractions displayed multiple size species; five subspecies were present over the range d 1.103-1.183 g/ml with diameters of 10.5, 9.9, 9.0, 8.2, and 7.5 nm, four in the range d 1.090-1.103 g/ml (diameters 10.5, 9.9, 9.0, and 8.2 nm) and three over the range d 1.076-1.090 g/ml (diameters 10.5, 9.9, and 9.0 nm). ApoA-I (Mr 25,000-27,000) was the major apolipoprotein in all goose HDL subfractions, while the minor components (apparent Mr 100,000, 91,000, 64,000, 58,000, approximately 42,000, 18,000 and apoC-like proteins) showed marked quantitative and qualitative variation across this density range (i.e., 1.055-1.165 g/ml). The d 1.063 g/ml boundary for separation of goose low density lipoproteins (LDL) from HDL was inappropriate, since HDL-like particles were present in the density interval 1.024-1.063 g/ml, while particles enriched in apoB (Mr approximately 540,000) and resembling LDL in size (approximately 20.5 nm) were detected up to a density of approximately 1.076 g/ml. Goose LDL itself was a major component of the profile (90-172 mg/dl) with a single peak of high flotation rate (Sf approximately 10.5). The physicochemical properties and apolipoprotein content of intermediate density lipoproteins (IDL) and LDL varied but little over the range d 1.013-1.040 g/ml, presenting as two particle species (diameters 20.5 and 21 nm) of essentially constant chemical composition; LDL (d 1.019-1.040 g/ml) were separated from HDL1 by gel filtration chromatography and appeared to contain primarily apoB with lesser amounts of apoA-I.(ABSTRACT TRUNCATED AT 400 WORDS)     

Single spin density gradient ultracentrifugation method for the detection and isolation of light and heavy low density lipoprotein subfractions

A single spin density gradient ultracentrifugation method in a swinging bucket rotor has been applied for the detection and isolation of low density lipoprotein (LDL) subfractions. The visualization of the LDL heterogeneity was facilitated by prestaining the serum with Coomassie Brilliant Blue R prior to density gradient ultracentrifugation for 19.5 hr. A total of 13 human serum pools was analyzed. In each pool, two LDL subfractions, a lighter LDL1 subfraction, occasionally showing a subdivision into two bands, LDL1A and LDL1B, and a heavier LDL2 could be clearly distinguished by the banding pattern in the density gradient. Physicochemical characteristics of the isolated LDL subfractions were determined. The simple method for detection and isolation of these subfractions presented here may facilitate future studies on LDL heterogeneity.     

Role of LDL subfraction heterogeneity in the reduced binding of low density lipoproteins to arterial proteoglycans in cynomolgus monkeys fed a fish oil diet.

Previous studies using cynomolgus monkeys have shown that isocaloric substitution of dietary fish oil for lard reduced the in vitro binding of plasma low density lipoproteins (LDL) to arterial proteoglycans (PG) (Edwards, I.J., A.K. Gebre, W. D. Wagner, and J. S. Parks. 1991. Arterioscler. Thromb., 11: 1778-1785). The purpose of the present study was to determine whether all LDL subfractions were equally affected by the type of dietary fat with regard to PG binding and to identify compositional changes in LDL subfractions that might relate to the differential in PG binding. Two groups of cynomolgus monkeys (n = 5 each) were fed atherogenic diets (40% calories as fat; 0.26 mg cholesterol/kcal) containing 20% of calories as egg yolk and 20% as either lard or menhaden fish oil. LDL were isolated from plasma by ultracentrifugation and size exclusion chromatography and subfractionated by density gradient centrifugation. Three density ranges of LDL subfractions were collected from the gradients for determination of chemical composition, apoE and apoB content by ELISA, and binding to arterial PG in vitro. The d 1.015-1.025 g/ml subfraction contained 39 +/- 8% of the LDL cholesterol in the lard group but only 7 +/- 3% for the fish oil group. Values for cholesterol distribution were opposite for the d 1.035-1.045 g/ml subfraction, 8 +/- 1% versus 41 +/- 8%, respectively. Similar trends were noted for the distribution of apoB. For the lard group, LDL binding to arterial PG increased with decreasing density (i.e., increasing size) of the subfractions.(ABSTRACT TRUNCATED AT 250 WORDS)     

Distribution and characterization of the serum lipoproteins and apoproteins in the mouse, Mus musculus

Murine lipoproteins were separated into nine subfractions by a density gradient ultracentrifugal procedure. They were characterized by electrophoretic, immunological, chemical, and morphological analyses, and their protein moieties were defined according to charge, molecular weight, and isoelectric point. HDL predominated (approximately 500 mg/dl serum), the mode of its distribution being situated in the d 1.09-1.10 g/ml (F 1.21 approximately 4) region. Chemical analysis showed subfractions of d 1.085-1.136 g/ml to resemble human HDL3 closely, including the presence of apoA-I (Mr 25,000-27,000) as their major apolipoprotein. An apoA-II-like protein, of Mr 8400 (in monomeric form), was also tentatively identified. In electrophoretic mobility and chemical composition, the d 1.060-1.085 g/ml subfraction (approximately 10% of total HDL) was distinct and akin to human HDL2. ApoA-I represented approximately 60% of its complement of low molecular weight apoproteins. The density range used for separation of human HDL2 (d 1.066-1.100 g/ml) by gradient ultracentrifugation is inadequate in the mouse, and the d 1.060-1.085 g/ml interval is more appropriate. The 1.063 g/ml boundary for separation of mouse LDL from HDL was unsuitable. Immunological and electrophoretic studies revealed that alpha-migrating lipoproteins were present in the d 1.046-1.060 g/ml range, a finding consistent with their enrichment in apoA-I; apoE-, apoA-II-, and apoC-like proteins were also detected. These findings indicate the presence of HDL1 particles. Murine apoA-I and apoB-like proteins of higher (apoBH) and lower (apoBL) molecular weight were constituents of the d 1.033-1.046 g/ml fraction. Alternative techniques, such as electrophoresis in starch block, are therefore a prequisite for separation of apoB from alpha-migrating, apoA-I-containing lipoproteins in the low density range in mouse serum. The LDL class (d 1.023-1.060 g/ml) amounted to only approximately 20% of the total murine lipoproteins of d less than 1.188 g/ml (65-70 mg/dl serum). Particles were richer In triglyceride, larger in diameter (mean 244 A), and more heterogeneous than typical of man. VLDL (40-80 mg/dl serum) was triglyceride-rich (66% by weight) and similarly heterogeneous in size (mean diameter 494 A; range 270-750 A). ApoBH and apoBL were prominent in murine VLDL, and cross-reacted with an antiserum to human apoB. ApoE- and apoA-I-like proteins were also detectable in apoVLDL, as was a protein of 70,000-75,000 mol wt. The presence of murine apolipoproteins analogous to human apoB and apoE was confirmed by the immunological cross-reactivities of VLDL and LDL with monospecific antisera to the human proteins. The marked similarity of lipoprotein and apolipoprotein profile in the mouse and rat is notable. Since murine VLDL contains apoE and apoBL, this resemblance may extend to the metabolism of chylomicron remnants and hepatic VLDL in the two species.     

Native low-density lipoproteins stimulate leukotriene B4 production by human monocyte-derived macrophages.

We have evaluated the effect of native low-density lipoproteins (LDL) on the production of leukotriene B4 (LTB4), a potent inflammatory and chemotactic factor, by human monocyte-derived macrophages. The capacity of LDL (d, 1.024-1.050 g/ml) to increase LTB4 secretion was dose-dependent with an optimal response at 100 micrograms LDL protein/ml, representing an approx. 7.5-fold stimulation over basal levels at 10 days of culture; the half-maximal response occurred at 20 micrograms/ml. The effect of LDL on LTB4 production was rapid (within 15 min) and was maintained for at least 21 h. The generation of LTB4 in response to LDL was partially inhibited (approx. 70% inhibition) by EDTA (5 mM) and by a monoclonal antibody (IgG-C7; 160 micrograms/ml) directed against the binding site of the cellular LDL receptor. In addition, the effects of native LDL and acetylated LDL were additive. These findings suggest that the specific interaction of LDL with its high affinity receptor represents a major component in the stimulation of the production of LTB4 by human monocyte-derived macrophages.     

Characterization of two lipoproteins containing apolipoproteins B and E from lesion-free human aortic intima

Lesion-free areas of aortic intimas from seven men, 30 to 49 years old, were extracted with aqueous buffer within a few hours after an accidental or sudden death. Two lipoprotein fractions could be isolated by density gradient ultracentrifugation from all cases. The mean composition of fraction I (d less than 1.012 g/ml) resembled that reported for the cholesteryl ester-rich, beta-migrating very low density lipoprotein (beta-VLDL); the composition of fraction II (d 1.021-1.046 g/ml) resembled that of plasma low density lipoprotein (LDL). Mean diameter of the particles was 35 +/- 8 nm in fraction I and 25 +/- 5 nm in fraction II (22 +/- 2 nm in plasma LDL). Both fractions contained apolipoproteins B (apoB) and E (apoE), and had increased electrophoretic mobilities and reduced contents of linoleic acid. The immunoreactivity of apoB to a polyclonal and two monoclonal antibodies in both fractions was not different from that of plasma lipoproteins. The apoE isoform patterns in both fractions were similar to those obtained from the respective postmortem plasmas. When incubated with mouse peritoneal macrophages, fractions I and II enhanced the incorporation of radioactive oleate into cholesteryl esters by 10- to 20-fold and 3- to 4-fold, respectively, in comparison to plasma LDL. In conclusion, our results indicate that lesion-free human aortic intima contains two types of apoB- and apoE-containing lipoprotein particles, both of which might be potentially atherogenic.     

Receptor-mediated binding and degradation of subfractions of human plasma low-density lipoprotein by cultured fibroblasts

The receptor-mediated metabolism of human plasma low-density lipoprotein (LDL) subfractions was studied. LDL was isolated from healthy donors and further fractionated by density gradient ultracentrifugation into three subfractions: (I) d = 1.031-1.037, (II) d = 1.037-1.041 and (III) d = 1.041-1.047 g/ml, comprising 24 +/- 7%, 46 +/- 8% and 30 +/- 9% of the total LDL protein, respectively. As assessed by electron microscopy and gradient gel electrophoresis, the LDL particle size decreased and the relative protein content increased from fraction I towards fraction III. Fraction II had the highest (Kd 2.6 micrograms/ml) and fraction I the lowest (Kd 5.8 micrograms/ml) binding affinity to LDL receptors of human fibroblasts at 4 degrees C. The rate of receptor-mediated degradation of fraction II was also higher than that of the other two fractions at 37 degrees C. These results suggest that LDL subfractions have different rates of receptor-mediated catabolism depending on particle size or composition, and therefore their metabolic fate and atherogenic properties may also differ.     

Effects of reconstituted HDL on charge-based LDL subfractions as characterized by capillary isotachophoresis

Modified LDL in human plasma including small, dense LDL (sdLDL) and oxidized LDL carries a more negative charge than unmodified LDL and is atherogenic. We examined the effects of apolipoprotein A-I (apoA-I)/POPC discs on charge-based LDL subfractions as determined by capillary isotachophoresis (cITP). Three normal healthy subjects and seven patients with metabolic disorders were included in the study. LDL in human plasma was separated into two major subfractions, fast- and slow-migrating LDL (fLDL and sLDL), by cITP. Normal LDL was characterized by low fLDL, and mildly oxidized LDL in vitro and mildly modified LDL in human plasma were characterized by increased fLDL. Moderately oxidized LDL in vitro and moderately modified LDL in a patient with hypertriglyceridemia and HDL deficiency were characterized by both increased fLDL and a new LDL subfraction with a faster mobility than fLDL [very-fast-migrating LDL as determined by cITP (vfLDL)]. cITP LDL subfractions with faster electrophoretic mobility (fLDL vs. sLDL, vfLDL vs. fLDL) were associated with an increased content of sdLDL. Incubation of a plasma fraction with d>1.019 g/ml (depleted of triglyceride-rich lipoproteins) in the presence of apoA-I/POPC discs at 37 degrees C greatly decreased vfLDL and fLDL but increased sLDL. Incubation of whole plasma from patients with an altered distribution of cITP LDL subfractions in the presence of apoA-I/POPC discs also greatly decreased fLDL but increased sLDL. ApoA-I/POPC discs decreased the cITP fLDL level, the free cholesterol concentration, and platelet-activating factor acetylhydrolase activity in the sdLDL subclasses (d=1.040-1.063 g/ml) and increased the size of LDL. ApoA-I/POPC discs reduced charge-modified LDL in human plasma by remodeling cITP fLDL into sLDL subfractions.     

Physicochemical studies of two major subpopulations of low density lipoproteins by differential scanning calorimetry and n.m.r. spectroscopy

Two subpopulations, layer 2 (density 1.025-1.029 g/ml) and layer 3 (density 1.032-1.043 g/ml) of low density lipoproteins (LDL) were isolated from fresh human plasma of normal lipidaemic subjects by density gradient ultracentrifugation. Chemical analyses demonstrated the ratios of triglyceride/cholesterol ester decreased with increasing densities of subfractions. These subfractions together with triglyceride-rich lipoproteins (layer 1, density less than 1.019 g/ml) were subjected to physicochemical studies by differential scanning calorimetry (d.s.c.) and nuclear magnetic resonance (n.m.r.) spectroscopy. The average transition temperature (Tt) of layer 2 was 34.20 +/- 0.83 degrees C and that of layer 3 was 37.25 +/- 0.35 degrees C. In addition, many of the layer 3, but not layer 2 and layer 1, samples showed structural alteration and gave rise to an average Tt of 39.18 +/- 1.24 degrees C. The structural alteration could be detected with polarizing light microscopy showing birefringent spherulites at body temperature. The peak Tt values obtained by d.s.c. were in good agreement with those by n.m.r. spectroscopy. These results demonstrate the physicochemical heterogeneity within the LDL density region and suggest that layer 3 subpopulation is much more labile than the others.     

Dissociable and nondissociable forms of platelet-activating factor acetylhydrolase in human plasma LDL: implications for LDL oxidative susceptibility

Platelet-activating factor acetylhydrolase (PAF-AH) is transported by lipoproteins in plasma and is thought to possess both anti-inflammatory and anti-oxidative activity. It has been reported that PAF-AH is recovered primarily in small, dense LDL and HDL following ultracentrifugal separation of lipoproteins. In the present studies, we aimed to further define the distribution of PAF-AH among lipoprotein fractions and subfractions, and to determine whether these distributions are affected by the lipoprotein isolation strategy (FPLC versus sequential ultracentrifugation) and LDL particle distribution profile. When lipoproteins were isolated by FPLC, the bulk (～85%) of plasma PAF-AH activity was recovered within LDL-containing fractions, whereas with ultracentrifugation, there was a redistribution to HDL (which contained ～18% of the activity) and the d>1.21 g/ml fraction (which contained ～32%). Notably, re-ultracentrifugation of isolated LDL did not result in any further movement of PAF-AH to higher densities, suggesting the presence of dissociable and nondissociable forms of the enzyme on LDL. Differences were noted in the distribution of PAF-AH activity among LDL subfractions from subjects exhibiting the pattern A (primarily large, buoyant LDL) versus pattern B (primarily small, dense LDL) phenotype. In the latter group, there was a relative depletion of PAF-AH activity in subfractions in the intermediate to dense range (d=1.039–1.047 g/ml) with a corresponding increase in enzyme activity recovered within the d>1.21 g/ml ultracentrifugal fraction. Thus, there appears to be a greater proportion of the dissociable form of PAF-AH in pattern B subjects. In both populations, most of the nondissociable activity was recovered in a minor small, dense LDL subfraction. Based on conjugated dienes as a measure of lipid peroxidation, variations in PAF-AH activity appeared to contribute to variations in oxidative behavior among ultracentrifugally isolated LDL subfractions. The physiologic relevance of PAF-AH dissociability and the minor PAF-AH-enriched oxidation-resistant LDL subpopulation remains to be determined.     

Both inherited susceptibility and environmental exposure determine the low-density lipoprotein-subfraction pattern distribution in healthy Dutch families.

A lipoprotein profile characterized by a predominance of small, dense, low-density lipoprotein (LDL) particles has been associated with an increased risk of atherosclerosis. To investigate whether genetic factors are involved in determining this heavy LDL subfraction pattern, this study was undertaken with the aim of resolving the effects that major genes, multifactorial heritability, and environmental exposures have on the LDL subfraction pattern. In a random sample of 19 healthy Dutch families including 162 individuals, the distribution of the LDL subfraction pattern was determined by density gradient ultracentrifugation. For each subject a specific LDL subfraction profile was observed, characterized by the relative contribution of the three major LDL subfractions--LDL1 (d = 1.030-1.033 g/ml), LDL2 (d = 1.033-1.040 g/ml), and LDL3 (d = 1.040-1.045 g/ml)--to total LDL. A continuous variable, parameter K, was defined to characterize each individual LDL subfraction pattern. Complex segregation analysis of this quantitative trait, under a model which includes a major locus, polygenes, and both common and random environment, was applied to analyze the distribution of the LDL subfraction pattern in these families. The results indicate that the LDL subfraction pattern, described by parameter K, is controlled by a major autosomal, highly penetrant, recessive allele with a population frequency of .19 and an additional multifactorial inheritance component. The penetrance of the more dense LDL subfraction patterns, characterized by values of K < 0, was dependent on age, gender, and, in women, on oral contraceptive use and postmenopausal status. Furthermore, multiple regression analysis revealed that approximately 60% of the variation in the LDL subfraction pattern could be accounted for by alterations in age, gender, relative body weight, smoking habits, hormonal status in women, and lipid and lipoprotein levels. In conclusion, our results indicate that genetic influences as well as environmental exposure, sex, age and hormonal status in women are important in determining the distribution of the LDL subfraction patterns in this population and that these influences may contribute to the explanation of familial clustering of coronary heart disease.     

Physicochemical properties of low-density lipoproteins of normal human plasma. Evidence for the occurrence of lipoprotein B in associated and free forms

1. Low-density (d 1.006-1.063g/ml) lipoproteins from normal human plasma were separated by differential preparative ultracentrifugation into six subfractions. Each low-density (LD) lipoprotein subfraction contained lipoprotein B as the major and lipoproteins A and C as the minor lipoprotein families. 2. Three lipoprotein B subfractions (LP-B), LP-B-III (d 1.019-1.030g/ml), LP-B-IV (d 1.030-1.040g/ml) and LP-B-V (d 1.040-1.053g/ml) were prepared from the corresponding LD lipoprotein subfractions by immunoprecipitating small amounts of lipoproteins A and C. 3. Determination of hydrodynamic properties indicated that LD lipoproteins consisted of three molecular segments characterized by a stepwise change in the molecular weight: LDL-I and LDL-II subfractions (d 1.006-1.019g/ml) with an average mol.wt. of 4.75x10(6), LDL-III (d 1.019-1.030g/ml) with a mol.wt. of 3.99x10(6), and LDL-IV, LDL-V and LDL-VI (d 1.030-1.063g/ml) with a mol.wt. of 2.85x10(6). 4. All three lipoprotein B subfractions had an average mol.wt. of 3.16x10(6). 5. The LDL-I and LDL-II subfractions consisted of lipoprotein B and lipoprotein C families which were present in the form of an association complex. This was isolated from serum by immunoprecipitation with antibodies to lipoprotein B. The complex had a mol.wt. of 4.35x10(6). 6. The results indicate a fundamental difference between the LD lipoprotein subfractions with d 1.006-1.019g/ml and those subfractions with d 1.030-1.063g/ml. In the former, lipoprotein B occurs as a part of an association complex, whereas in the latter it occurs as a separate entity.     

ApoB-75, a truncation of apolipoprotein B associated with familial hypobetalipoproteinemia: genetic and kinetic studies.

We have identified a mutation of apolipoprotein B (apoB) in a kindred with hypobetalipoproteinemia. Four affected members had plasma concentrations of total cholesterol of 115 +/- 14, low density lipoprotein (LDL)-C of 48 +/- 11, and apoB of 28 +/- 9 (mg/dl mean +/- SD). The values correspond to approximately 30% the values for unaffected relatives. Triglyceride and high density lipoprotein (HDL)-C concentrations were 92 +/- 50 and 49 +/- 4, respectively, neither significantly different from unaffected relatives. Western blots of plasma apoB of affected subjects showed two major bands: apoB-100 and an apoB-75 (mol wt of approximately 418,000). DNA sequencing of the appropriate polymerase chain reaction (PCR)-amplified genomic DNA segment revealed a deletion of the cytidine at nucleotide position 10366, resulting in a premature stop codon at amino acid residue 3387. In apoB-75/apoB-100 heterozygotes, two LDL populations containing either apoB-75 or apoB-100 could be distinguished from each other by gel permeation chromatography and by immunoblotting of nondenaturing gels using monoclonal antibodies B1B3 (epitope between apoB amino acid residues 3506-3635) and C1.4 (epitope between residues 97-526). ApoB-75 LDL were smaller and more dense than apoB-100 LDL. To determine whether the low concentration of apoB-75 was due to its enhanced LDL-receptor-mediated removal, apoB-75 LDL were isolated from the proband's d 1.063-1.090 g/ml fraction (which contained most of the apoB-75 in his plasma) by chromatography on anti-apoB and anti-apoA-I immunoaffinity columns. The resulting pure apoB-75 LDL fraction interacted with the cells 1.5-fold more effectively than apoB-100 LDL (d 1.019-1.063 g/ml). To determine the physiologic mechanism responsible for the hypobetalipoproteinemia, in vivo kinetic studies were performed in two affected subjects, using endogenous labeling of apoB-75 and apoB-100 with [13C]leucine followed by multicompartmental kinetic analyses. Fractional catabolic rates of apoB-75 VLDL and LDL were 2- and 1.3-fold those of apoB-100 very low density lipoprotein (VLDL) and LDL, respectively. Production rates of apoB-75 were approximately 30% of those for apoB-100. This differs from the behavior of apoB-89, a previously described variant, whose FCRs were also increased approximately 1.5-fold relative to apoB-100, but whose production rates were nearly identical to those of apoB-100. Thus, in contrast to the apoB-89 mutation, the apoB-75 mutation imparts two physiologic defects to apoB-75 lipoproteins that account for the hypobetalipoproteinemia, diminished production and increased catabolism.     

Immunochemical analysis of the electronegative LDL subfraction shows that abnormal N-terminal apolipoprotein B conformation is involved in increased binding to proteoglycans

Electronegative LDL (LDL(-)) is a minor subfraction of modified LDL present in plasma. Among its atherogenic characteristics, low affinity to the LDL receptor and high binding to arterial proteoglycans (PGs) could be related to abnormalities in the conformation of its main protein, apolipoprotein B-100 (apoB-100). In the current study, we have performed an immunochemical analysis using monoclonal antibody (mAb) probes to analyze the conformation of apoB-100 in LDL(-). The study, performed with 28 anti-apoB-100 mAbs, showed that major differences of apoB-100 immunoreactivity between native LDL and LDL(-) concentrate in both terminal extremes. The mAbs Bsol 10, Bsol 14 (which recognize the amino-terminal region), Bsol 2, and Bsol 7 (carboxyl-terminal region) showed increased immunoreactivity in LDL(-), suggesting that both terminal extremes are more accessible in LDL(-) than in native LDL. The analysis of in vitro-modified LDLs, including LDL lipolyzed with sphingomyelinase (SMase-LDL) or phospholipase A(2) (PLA(2)-LDL) and oxidized LDL (oxLDL), suggested that increased amino-terminal immunoreactivity was related to altered conformation due to aggregation. This was confirmed when the aggregated subfractions of LDL(-) (agLDL(-)) and oxLDL (ag-oxLDL) were isolated and analyzed. Thus, Bsol 10 and Bsol 14 immunoreactivity was high in SMase-LDL, ag-oxLDL, and agLDL(-). The altered amino-terminal apoB-100 conformation was involved in the increased PG binding affinity of agLDL(-) because Bsol 10 and Bsol 14 blocked its high PG-binding. These observations suggest that an abnormal conformation of the amino-terminal region of apoB-100 is responsible for the increased PG binding affinity of agLDL(-).     

Evaluation of a monoclonal antibody-based enzyme-linked immunosorbent assay as a candidate reference method for the measurement of apolipoprotein B-100

A monoclonal antibody-based direct binding enzyme-linked immunosorbent assay (ELISA) for apoprotein (apo) B-100 has been developed for use as a reference method. The assay uses the two well-characterized monoclonal antibodies, MB24 and MB47. MB47, which recognizes an epitope at the low density lipoprotein (LDL) receptor-binding domain of apoB and is specific for apoB-100, is bound to the microtiter plate as the capture antibody. MB24, which binds an epitope in the amino terminal half of the apoB-100 and identifies both apoB-100 and apoB-48, is conjugated to horseradish peroxidase and is utilized as the indicating antibody. The assay was calibrated with LDL (d 1.030-1.050 g/ml) and the LDL protein was determined by a sodium dodecyl sulfate (SDS) Lowry procedure. The working range of the assay is 0.25-1.25 micrograms/ml. Optimal dilution of whole plasma was found to be 1:2000. In the assay, MB47 bound approximately 97% of the apoB in all low density lipoprotein, and greater than 90% of the apoB in the majority of very low density lipoprotein preparations. Small dense LDL from subjects with familial combined hyperlipidemia (FCHL) and large bouyant LDL from subjects with familial hypercholesterolemia (FH) exhibited binding properties similar to LDL from healthy normolipidemic subjects when tested in the reference ELISA. The intra- and interassay coefficients of variation averaged 2.5% and 6.0%, respectively. Plasma B-100 levels were not influenced by freezing and thawing or storage at 4 degrees C for up to 3 weeks or storage at -70 degrees C for up to 11 months. Excellent agreement was obtained between the reference ELISA and a polyclonal RIA which measures total apoB (r = 0.93, n = 105, mean ELISA B-100 value = 100 mg/dl, mean RIA value = 101 mg/dl, Sy = 9.6). Reference ELISA B-100 values of samples pretreated with bacterial lipase were not significantly increased in most samples with plasma triglyceride levels below 600 mg/dl. To help reduce the large among-laboratories variability of apoB measurements, we recommend that this candidate reference direct binding ELISA be used to assign apoB target values to apoB reference pools.     

Assembly of very low density lipoproteins in mouse liver: evidence of heterogeneity of particle density in the Golgi apparatus

The assembly of very low density lipoproteins (VLDL) by hepatocytes is believed to occur via a two-step process. The first step is the formation of a dense phospholipid and protein-rich particle that is believed to be converted to VLDL by the addition of bulk triglyceride in a second step. Previous studies in our laboratory led us to hypothesize a third assembly step that occurs in route to or in the Golgi apparatus. To investigate this hypothesis, nascent lipoproteins were recovered from Golgi apparatus-rich fractions isolated from mouse liver. The Golgi fractions were enriched 125-fold in galactosyltransferase and contained lipoprotein particles averaging approximately 35 nm in diameter. These lipoproteins were separated by ultracentrifugation into two fractions: d < 1.006 g/ml and d1.006;-1.210 g/ml. The d < 1.006 g/ml fraction contained apolipoprotein B-100 (apoB-100), apoB-48, and apoE, while the d1.006;-1.210 g/ml fraction contained these three apoproteins as well as apoA-I and apoA-IV. Both fractions contained a 21-kDa protein that was isolated and sequenced and identified as major urinary protein. Approximately 50% of the apoB was recovered with the denser fraction. To determine if these small, dense lipoproteins were secreted without further addition of lipid, mice were injected with Triton WR1339 and [(3)H]leucine, and the secretion of apoB-100 and apoB-48 into serum VLDL (d < 1.006 g/ml) and d1.006;-1.210 g/ml fractions was monitored over a 2-h period. More than 80% of the newly synthesized apoB-48 and nearly 100% of the apoB-100 were secreted with VLDL. These studies provide the first characterization of nascent lipoproteins recovered from the Golgi apparatus of mouse liver. We conclude that these nascent hepatic Golgi lipoproteins represent a heterogeneous population of particles including VLDL as well as a population of small, dense lipoproteins. The finding of the latter particles, coupled with the demonstration that the primary secretory product of mouse liver is VLDL, suggests that lipid may be added to nascent lipoproteins within the Golgi apparatus.     

Lipolysis of LDL with phospholipase A2 alters the expression of selected apoB-100 epitopes and the interaction of LDL with cells

To assess the effects of perturbing the surface of low density lipoprotein (LDL) on the conformation of apoB-100, LDL (d 1.030-1.050 g/ml) isolated from normal subjects were treated with phospholipase A2 (PL-A2) for 0.5 to 15 min. The resulting P-LDL and concurrent control LDL (C-LDL) incubated without PL-A2 were isolated by gel permeation chromatography. Approximately 50% of LDL-phosphatidylcholine was hydrolyzed in 2 min and approximately 85% in 5 min. Lysophosphatidylcholine compounds (LPC) and free fatty acids (FFA) accumulated during lipolysis but most of the LPC and all of FFA could be removed by adding FFA-free albumin to the lipolysis mixtures. Immunoreactivities of P-LDL and C-LDL were evaluated in competitive radioimmunoassays, using a library of anti-human LDL monoclonal antibodies directed against the major regions of apoB-100 (the T4, T3, and T2 thrombin fragments). One epitope defined by monoclonal antibody 465B6C3 and localized near the carboxyl end of the apoB-100 molecule became less immunoreactive (ED 50s increased); three other epitopes on the T2 fragment near the LDL receptor recognition site and four epitopes localized towards the middle (T3) and amino terminal (T4) regions did not change. Altered immunoreactivities were not related to LPC and FFA contents. Thus, the conformation of apoB-100 was selectively altered by phospholipolysis. The interactions of P-LDL with cultured fibroblasts were grossly altered: P-LDL were bound nonspecifically to fibroblasts of both normal and homozygous familial hypercholesterolemic subjects and P-LDL were not degraded. LPC and FFA retained in LDL did not explain these alterations, nor did changes of epitope expression near the LDL receptor recognition site. It is likely that the apoB-100 aberrant cell interaction is due to loss of surface phospholipids and "uncovering" of core lipids that react nonspecifically with cell surface components.