Reconstitution of lipoprotein(a) by infusion of human low density lipoprotein into transgenic mice expressing human apolipoprotein(a).

Lipoprotein(a) (Lp(a)) is an atherosclerosis-causing lipoprotein that circulates in human plasma as a complex of low density lipoprotein (LDL) and apolipoprotein(a) (apo(a)). It is not known whether apo(a) attaches to LDL within hepatocytes prior to secretion or in plasma subsequent to secretion. Here we describe the development of a line of mice expressing the human apo(a) transgene under the control of the murine transferrin promoter. The apo(a) was secreted into the plasma, but circulated free of lipoproteins. When human (h)-LDL was injected intravenously, the circulating apo(a) rapidly associated with the lipoproteins, as determined by nondenaturing gel electrophoresis. Human HDL and mouse LDL had no such effect. When h-VLDL was injected, there was a delayed association of apo(a) with the lipoprotein fraction which suggests that apo(a) preferentially associated with a metabolic product of VLDL. The complex of apo(a) with LDL formed both in vivo and in vitro was resistant to boiling in the presence of detergents and denaturants, but was resolved upon disulfide reduction. These studies suggest that apo(a) fails to associate with mouse lipoproteins due to structural differences between human and mouse LDL, and that Lp(a) formation can occur in plasma through the association of apo(a) with circulating LDL.     

Identification and characterization of apolipoprotein(AII-E2-AII) complex in human plasma lipoprotein.

A new apolipoprotein complex designated as the apo(AII-E2-AII) complex was identified in the lipoprotein fractions of human plasma with apoE phenotypes containing apoE2 (E4/E2, E3/E2, and E2/E2). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) followed by an immunoblotting assay using anti-apoE or anti-apoAII antibodies, established that the apo(AII-E2-AII) complex, with a molecular weight of 58,000, was identical to the complex consisting of apoE and apoAII, and that it also dissociated following reduction with beta-mercaptoethanol. This new complex was also demonstrated to be distinct from the apo(E-AII) complex and apoE monomer by isoelectric focusing, in the samples that were not treated with beta-mercaptoethanol. In apoE phenotype E3/E2, the apo(AII-E2-AII) complex was primarily included in the high-density lipoprotein (HDL, 1.063 < d < 1.21 g/ml) fraction, but was also observed in a small quantity in the very-low-density lipoprotein (VLDL, d < 1.006 g/ml) fraction. For further characterization, the apo(AII-E2-AII) complex was isolated by preparative SDS-PAGE, and no contamination of apo(E-AII) complex and apoE monomer was detected by immunoblotting assay using an anti-apoE antibody. It was confirmed by an enzyme-linked immunosorbent assay (ELISA) system that a molecular ratio between apoAII monomer and apoE in the isolated apo(AII-E2-AII) complex was approx. 2, when the apo(E-AII) complex was used as a standard with the ratio of 1:1. It indicates that the apo(AII-E2-AII) complex is formed from two molecules of apoAII monomer and one molecule of apoE.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of lipoprotein X-like particles in rat plasma following Intralipid infusion.

Fasting rats were infused with 10% Intralipid for 24 h (0.33 mL/h per 100 g body weight) and the plasma lipoproteins isolated and compared with those of fed animals and animals with bile duct ligatures as controls. There was a 6- to 10-fold increase in the free cholesterol and phospholipid content of total plasma in animals infused with Intralipid or with ligated bile ducts. The changes were largely restricted to the low density lipoproteins (d=1.019--1.063 g/mL) where free cholesterol and phospholipid increased 30- to 60-fold compared with fed control animals. Hydroxylapatite chromatography of the low density lipoprotein fractions of both Intralipid-infused and bile duct ligated animals yielded a subfraction which was rich in free cholesterol (27%), phosphatidylcholine (66%), and protein (6%); the latter was composed primarily of albumin and apo C proteins. The electrophoretic mobility and polyanionic precipitation properties of the abnormal lipoprotein were indistinguishable from those of lipoprotein X isolated from the animals with bile duct ligatures. The albumin in the abnormal lipoprotein from both groups of experimental animals was detected immunochemically only after delipidation of the lipoprotein. Twice as much of the lipoprotein X accumulated in Intralipid-infused than in the bile duct ligated animals. On rechromatography of the residual low density lipoprotein other subfractions could be isolated which possessed lipid and protein proportions intermediate between those of the lipoprotein X and of normal rat plasma low density lipoprotein. The activity of lecithin cholesterol acyl transferase was increased twofold in the Intralipid-infused animals when compared with control animals, but it decreased by 50% in the animals with bile duct ligatures. It is concluded that the unusual lipoprotein X accumulates in the plasma of Intralipid-infused animals owing to incomplete clearance of the exogenous phospholipid, which mobilized tissue cholesterol and in the form of vesicular particles serves as a lipid phase for apo C proteins. A comparable mechanism is suggested for the formation of lipoprotein X in the animals with bile duct ligature.     

Early incorporation of cell-derived cholesterol into pre-beta-migrating high-density lipoprotein

Cultures of human skin fibroblasts were labeled to high cholesterol specific activity with [3H]cholesterol and incubated briefly (1-3 min) with normal human plasma. The plasma was fractionated by two-dimensional agarose-polyacrylamide gel electrophoresis and the early appearance of cholesterol label among plasma lipoproteins determined. A major part of the label at 1-min incubation was in a pre-beta-migrating apo A-I lipoprotein fraction with a molecular weight of ca. 70,000. Label was enriched about 30-fold in this fraction relative to its content of apo A-I (1-2% of total apo A-I). The proportion of label in this lipoprotein was strongly correlated with its concentration in plasma. Further incubation (2 min) in the presence of unlabeled cells demonstrated transfer of label from this fraction to a higher molecular weight pre-beta apo A-I species, to low-density lipoprotein, and to the alpha-migrating apo A-I that made up the bulk (96%) of total apo A-I in plasma. The data suggest that a significant part of cell-derived cholesterol is transferred specifically to a pre-beta-migrating lipoprotein A-I species as part of a cholesterol transport transfer sequence in plasma.     

Zone electrophoresis study of the bile lipoprotein complex.

Sucrose gradient column electrophoresis was performed with human hepatic and gallbladder bile. It is shown that bile phosphatidylcholines exhibit a more rapid anodic mobility than do bile salts and serum albumin. This high mobility of bile phosphatidylcholines is not due to the negatively charged lipids which are present in bile, i.e. bile salts or free fatty acids. It is demonstrated that phosphatidylcholines are associated with anionic polypeptides. Electrophoresis of reassociations between these purified polypeptides and dilaurylphosphatidylcholine showed that these anionic polypeptides are primarily responsible for the high anodic mobility of the bile lipoprotein complex. This work describes a procedure for the purification of the bile lipoprotein complex which can be useful for the study of other kinds of lipid-polypeptide associations.     

Characterization of apolipoprotein M isoforms in low-density lipoprotein

Apo M is a recently discovered human lipoprotein thought to be involved in the metabolism of lipids and lipoprotein particles. Here, a proteomic approach was applied to examine the glycosylation pattern of apo M in human LDL. We treated LDL proteins with N-glycosidase or neuraminidase, studied mobility shifts of Apo M by two-dimensional gel electrophoresis, and different isoforms were then identified with mass spectrometry. This way, we demonstrated the presence of five isoforms of apo M in LDL: three that are both N-glycosylated and sialylated, one that is N-glycosylated but not sialylated, and one that is neither N-glycosylated nor sialylated. As judged from the examination of LDL from 20 healthy human subjects, the three N-glycosylated and sialylated forms are most abundant (80-100% of the total apo M in LDL) whereas the unsialylated and unglycosylated variants constitute at most 20%. Comparative analysis showed that the same five isoforms of apo M are also present in HDL. Further studies aiming at elucidating the role of apo M in health and disease will have to take this polymorphism of apo M proteins into account.     

Proposed mechanisms for binding of apo[a] kringle type 9 to apo B-100 in human lipoprotein[a].

The protein component of human lipoprotein[a] consists primarily of two apolipoproteins, apo[a] and apo B-100, linked through a cystine disulfide(s). In the amino acid sequence of apo bd, Cys4057 located within a plasminogen kringle 4-like repeat sequence (3991-4068) is believed to form a disulfide bond with a specific cysteine residue in apo B-100. Our fluorescence-labeling experiments and molecular modeling studies have provided evidence for possible interactions between this apo[a] kringle type and apo B-100. The fluorescent probe, fluorescein-5-maleimide, was used in parallel experiments to label free sulfhydryl moieties in lipoprotein[a] and low-density lipoprotein (LDL). In apo B-100 of LDL, Cys3734 was labeled with the probe, but this site was not labeled in autologous lipoprotein[a]. The result strongly implicates Cys3734 of apo B-100 as the residue forming the disulfide linkage with Cys4057 of apo[a]. To explore possible noncovalent interactions between apo B-100 and apo[a], the crystallographic coordinates for plasminogen kringle 4 were used to generate molecular models of the apo[a] kringle-repeat sequence (3991-4068, LPaK9), the only plasminogen kringle 4 type repeat in apo[a] having an extra cysteine residue not involved in an intramolecular disulfide bond. The Cys4057 residue (henceforth designated as Cys67 in the LPaK9 sequence) is believed to form an intermolecular disulfide bond with a cysteine of apo B-100. In computer graphics molecular models of LPaK9, Cys67 is located on the surface of the kringle near the lysine ligand binding site. Selected segments of the LDL apo B-100 sequence that contain free sulfhydryl cysteines were subjected to energy minimization and docking with the ligand binding site and adjacent regions of the LPaK9 model. In the docking experiments, apo B-100 segment 3732-3745 (PSCKLDFREIQIYK) displayed the best fit and the largest number of van der Waals contacts with models of LPaK9. Other apo B-100 peptides with sulfhydryl cysteine were found to be less compatible when minimized with this kringle. These results support and extend previously suggested mechanisms for a complex interaction between apo[a] and apo B-100 that involve more than a simple covalent disulfide bond.     

Lipoprotein[a] is the major apoB-containing lipoprotein in the plasma of a hibernator, the hedgehog (Erinaceus europaeus)

We have undertaken studies aimed at elucidating the interrelationships existing between the seasonal modifications in endocrine status (already demonstrated by Saboureau, M., and J. Boissin. 1978. C.R. Acad. Sci. (Paris) 286D: 1479-1482) and plasma lipoprotein metabolism in the male hedgehog. During the course of these studies, we discovered that a lipoprotein comparable to human Lp[a] was a prominent component of the plasma lipoprotein spectrum in the hedgehog. This lipoprotein was present in the 1.040-1.100 g/ml density range (approximately), exhibited pre beta mobility upon agarose gel electrophoresis, and its Stokes diameter was 275 A. Its apolipoprotein moiety consisted of two proteins with molecular weights and amino acid compositions similar to those of human apoB-100 and apo[a], respectively. These two apolipoproteins were present in hedgehog Lp[a] as a complex that could be dissociated using dithiothreitol and whose stoichiometry could be 1:1. Lp[a] polymorphism due to size heterogeneity of apo[a] appeared to be present in the hedgehog as in man. The chemical composition of hedgehog Lp[a], obtained from animals bled during spring and summer, differed from that of its human counterpart in that the proportion of triglycerides was approximately three times higher in the hedgehog particle (13% vs. 4%), to the detriment of cholesteryl esters. Dissociation of the apoB:apo[a] complex has allowed us to obtain Lp[a] devoid of its specific polypeptide (Lp[a-]), a particle that retained the characteristics of Lp[a] as regards its lipid composition but whose Stokes diameter decreased by 30 to 40 A. The plasma concentration of LDL particles, defined as lipoproteins containing apoB-100 as their sole apolipoprotein constituent, was considerably lower than that of Lp[a]. These findings suggest that the hedgehog could be a unique animal model for studies regarding Lp[a] metabolism.     

The interaction of lipolysis products of very low density lipoprotein with plasma high density lipoprotein (HDL): perfusate HDL with plasma HDL subfractions

The nature of the interaction of high density lipoproteins (HDL), formed during lipolysis of human very low density lipoprotein (VLDL) by perfused rat heart, with subfractions of human plasma HDL was investigated. Perfusate HDL, containing apoliproproteins (apo) E, C-II, and C-III but no apo A-I or A-II, was incubated with a subfraction of HDL (HDL-A) containing apo A-I and A-II, but devoid of apo C-II, C-III, and E. The products of the incubation were resolved by heparin-Sepharose or hydroxylapatite chromatography under conditions which allowed the resolution of the initial HDL-A and perfusate HDL. The fractions were analyzed for apolipoprotein content and lipid composition and assessed for particle size by electron microscopy. Following the incubation, the apo-E-containing lipoproteins were distinct from perfusate HDL since they contained apo A-I as a major component and apo C-II and C-III in reduced proportions. However, the HDL-A fraction contained apo C-II and C-III as major constituents. Associated with these changes in apolipoprotein composition, the apo-E-rich lipoproteins acquired cholesteryl ester from the HDL-A fraction and lost phospholipid to the HDL-A fraction. The HDL-A fraction maintained a low unesterified cholesterol/phospholipid molar ratio (0.23), while the apo-E-containing lipoproteins possessed a high ratio (0.75) characteristic of the perfusate HDL.(ABSTRACT TRUNCATED AT 250 WORDS)     

Very low density lipoprotein. Dissociation of apolipoprotein C during lipoprotein lipase induced lipolysis.

The fate of apo C in rat plasma very low density lipoprotein (VLDL) during lipolysis was studied using VLDL labeled specifically with 125I-labeled apo C and purified bovine milk lipoprotein lipase. Incubations were carried out in vitro and included serum-containing systems and albumin containing systems. Free fatty acids generation proceeded with time of incubation in the two systems. It, however, was enhanced 1.5--2 fold by the presence of serum. 125I-labeled apo C equilibrated between very low and high density lipoprotein (HDL) in both systems even when enzyme was not present in the incubation medium, or when the incubation was carried out at 0 degrees C. Upon initiation of lipolysis, more 125I-labeled apo C was transferred to HDL and the transfer was proportional to the magnitude of free fatty acids release. 125I-labeled apo C was also progressively removed from VLDL in the albumin-containing system, although no known lipoprotein acceptor to apo C was present in the medium. The 125I-labeled apo C was recovered predominantly with the medium fraction of d greater than 1.21 g/ml (60--70%), and to a lesser degree with that of d= 1.019--1.21 g/ml. However, the relationship between lipolysis (measured as free fatty acids release) and removal of 125I-labeled apo C from VLDL were indistinguinshable in the albumin containing system and the serum containing system. On the basis of these observations, it is postulated that the removal of apo C during lipolysis of VLDL reflects the nature of the partially degraded VLDL particles, and is independent of the presence of a lipoprotein acceptor to apo C.     

Cellular metabolism of human plasma intermediate-density lipoprotein (IDL)

The cellular metabolism of human plasma intermediate-density lipoprotein (IDL) was investigated in cultured human skin fibroblasts and hepG-2 cell in the absence and presence of exogenous recombinant or plasmatic apo E-3. IDL (d 1.006-1.019 g/ml) and LDL (d 1.019-1.063 g/ml) were prepared by centrifugation from the plasma of apo E-3/3 or 4/3 normolipidemic human subjects. Without added apo E-3, IDL binding and cell association are similar or slightly reduced while their degradation is one third to one half. This results in degradation to binding ratios for IDL that are half those for LDL. Exogenous apo E-3 enhances binding, association and degradation of IDL by 50-150%, but the degradation to binding ratio remains low. Exogenous apo E-3 also increased the ability of IDL but not LDL, to down-regulate the incorporation of [14C]acetate to sterol by the cells. The optimal concentration of apo E-3 is 4 micrograms protein/10 micrograms IDL protein and at that concentration appreciable amounts of the apo E are found associated with the lipoprotein. Apo E-2 has no effect on the cellular metabolism of IDL and apo E-3 is not effective in receptor-negative human fibroblasts. Monoclonal antibodies that block apo E binding to B,E (LDL) receptor (1D7) abolish the cellular metabolism of IDL while antibodies against B-100 (4G3) are ineffective. In competitive binding experiments, IDL is slightly more effective than LDL in displacing 125I-LDL from receptors in hepG-2 cells and appreciably more effective than LDL when tested against 125I-IDL. Apo E-3 increases the capacity of IDL to compete with either 125I-LDL or 125I-IDL. Addition of apo E-3 also increases the binding affinity of IDL to hepG-2 receptors, with Kd values of 2.50, 0.93 micrograms protein/ml, respectively. The study demonstrates the essential role that functional apo E molecules play in the interaction of human IDL with cellular receptors. Yet, in spite of presence of apo E in IDL (2-3 molecules/particle) and enrichment of IDL with apo E-3 (to 4-5 molecules/particle) the proteolytic degradation of the lipoprotein by specific cellular receptor is similar to LDL.     

Study of the lipid binding characteristics of the apolipoproteins from human high density lipoprotein. I. Electron microscopic and gel filtration studies with synthetic phosphatidylcholines.

The characteristics of the lipid - protein complex produced by the addition of the major apolipoproteins (apo AI and apo AII) of human high-density lipoprotein to synthetic phospholipids has been studied. Under the in vitro conditions utilized, apo AI binds to 1,2-dimyristoyl-sn-glycerophosphocholine and 1,2-dipalmitoyl-sn-glycerophosphocholine liposomes, but does not alter their morphologic characteristics. This binding occurs at temperatures above or below that of the transition (Tt) of the lipid bilayer. In contrast, apo AII spontaneously generates small, homogeneous disc-shaped lipid-protein complexes (50 X 10 a) from large phospholipid globules or from liposomes prepared with these lipids. This type of complex was only formed when the lipid/apo AII mixtures were warmed above the transition temperatures. The incorporation of apo AI into this small complex with apo AII may be greatly facilitated or inhibited depending on the sequence of addition of the various components. Under optimal circumstances, a maximum of 1 molecule of apo AI is incorporated with each molecule of apo A II into complexes with these two synthetic phospholipids.     

On the heritability of serum high density lipoprotein in twins.

To estimate the relative contributions of hereditary vs. environmental factors in the variation of high density lipoprotein, we measured the concentrations of its main apoprotein components, apoprotein A-I (apo A-I) and apoprotein A-II (apo A-II), in serum samples from 65 monozygotic (MZ) and 70 dizygotic (DZ) like-sexed twin pairs. Evidence for a genetic component of variance was found for apo A-II, giving heritability (h2) estimates of .35 and .30 for males and females, respectively. No genetic contribution to the variance of apo A-I could be demonstrated. Additionally, males had lower concentrations of apo A-I, but higher of apo A-II, than females.     

Isolation and partial characterization of apolipoprotein (a) from human lipoprotein (a)

A procedure was developed for the dissociation of apolipoprotein (a) (apo (a)) from pure human lipoprotein (a) (Lp(a)) prepared by density gradient ultracentrifugation and gel filtration. Lp(a) was ultracentrifuged through a layer of saline which was adjusted to a density of 1.182 g/mL and contained 30 mM dithiothreitol (50 mM) and phenylmethylsulfonyl fluoride (1.25 mM). Following centrifugation, the lipid and apolipoprotein B (apo B) were recovered as a lipoprotein (Lp(a) B) in the supernatant fraction, while the apo (a) was recovered as a lipid-poor protein pellet. An investigation of the supernatant lipoprotein by electron microscopy and compositional analysis revealed that it was similar in size and composition to low density lipoprotein (LDL) isolated from the same density range and contained apo B100 with an amino acid and carbohydrate composition which was similar to apo B from LDL. Estimates of the apparent molecular weight of the apo (a) varied amongst individuals but was always greater than apo B100 (congruent to 450,000). The amino acid composition of apo (a), which was very distinct from apo B, was characterized by a higher content of serine, threonine, proline, and tyrosine, but lower amounts of isoleucine, phenylalanine, and lysine when compared with apo B of Lp(a) or LDL. The apo (a) contained a much higher proportion of carbohydrate, in particular N-acetylgalactosamine, galactose, and N-acetylneuraminic acid (which were three- to six-fold higher) than the apo B of Lp(a). It is concluded that apo (a) is distinct from other apolipoproteins owing to its low avidity for lipid and the nature of the interaction with apo B. Lp(a) consists of an LDL-like particle with a carbohydrate-rich apo (a) attached to the surface of apo B.     

A role for apolipoprotein(a) in protection of the low-density lipoprotein component of lipoprotein(a) from copper-mediated oxidation

Low-density lipoprotein (LDL) oxidation is stimulated by copper. Addition of a recombinant form of apolipoprotein(a) (apo(a); the distinguishing protein component of lipoprotein(a)) containing 17 plasminogen kringle IV-like domains (17K r-apo(a)) protects LDL against oxidation by copper. Protection is specific to apo(a) and is not achieved by plasminogen or serum albumin. When Cu(2+) is added to 17K r-apo(a), its intrinsic fluorescence is quenched in a concentration-dependent and saturable manner. Quenching is unchanged whether performed aerobically or anaerobically and is reversible by ethylenediaminetetraacetate, suggesting that it is due to equilibrium binding of Cu(2+) and not to oxidative destruction of tryptophan residues. The fluorescence change exhibits a sigmoid dependence on copper concentration, and time courses of quenching are complex. At copper concentrations below 10 microM there is little quenching, whereas above 10 microM quenching proceeds immediately as a double-exponential decay. The affinity and kinetics of copper binding to 17K r-apo(a) are diminished in the presence of the lysine analogue epsilon -aminocaproic acid. We propose that copper binding to the kringle domains of 17K is mediated by a His-X-His sequence that is located about 5A from the closest tryptophan residue of the lysine binding pocket. Copper binding may account for the natural resistance to copper-mediated oxidation of lipoprotein(a) relative to LDL that has been previously reported and for the protection afforded by apo(a) from copper-mediated oxidation of LDL that we describe in the present study.     

Human apolipoprotein E N-terminal domain displacement of apolipophorin III from insect low density lipophorin creates a receptor-competent hybrid lipoprotein

The surface of Manduca sexta low density lipophorin (LDLp) particles was employed as a template to examine the relative lipid binding affinity of the 22 kDa receptor binding domain (residues 1–183) of human apolipoprotein E3 (apo E3). Isolated LDLp was incubated with exogenous apolipoprotein and, following re-isolation by density gradient ultracentrifugation, particle apolipoprotein content was determined. Incubation of recombinant human apo E3(1–183) with LDLp resulted in a saturable displacement of apolipophorin III (apo Lp-III) from the particle surface, creating a hybrid apo E3(1–183)-LDLp. Although subsequent incubation with excess exogenous apo Lp-III failed to reverse the process, human apolipoprotein A-I (apo A-I) effectively displaced apo E3(1–183) from the particle surface. We conclude that human apo E N-terminal domain possesses a higher intrinsic lipid binding affinity than apo Lp-III but has a lower affinity than human apo A-I. The apo E3(1–183)-LDLp hybrid was competent to bind to the low density lipoprotein receptor on cultured fibroblasts. The system described is useful for characterizing the relative lipid binding affinities of wild type and mutant exchangeable apolipoproteins and evaluation of their biological properties when associated with the surface of a spherical lipoprotein.     

The turnover of human plasma very low density lipoprotein protein.

The plasma decay of three groups of iodinated apoproteins on human very low density lipoproteins were evauluated in two normals, two subjects with endogenous hypertriglyceridemia and another two with dysbetalipoproteinemia. The apo beta decay was more rapid than that of the C apoproteins in all patients. The apo beta decay was more rapid for the normals than for either the subjects with hypertriglyceridemia or dysbetalipoprotenemia. The apo C protein had an irregular decay in the normals but decayed less irregularly for the hypertriglyceridemics. The arginine rich apoprotein had a decay somewhat similar to apo C protein in the normals. The apo beta protein of the alpha2 very low density lipoprotein of a dysbetalipoproteinemic was consistent with a precursor relationship to the apo beta of beta very low density lipoprotein of this subject, but the arginine rich apoprotein was not.     

Lipoprotein secretion by the human hepatoma cell line Hep G2: differential rates of accumulation of apolipoprotein B and lipoprotein lipids in tissue culture media in response to albumin, glucose and oleate

Serum low-density lipoprotein (LDL) concentration is a major determinant of susceptibility to the development of atherosclerosis. A major component of the protein moiety of LDL and its precursor very-low-density lipoprotein is apolipoprotein B (apo B). The human hepatoma cell line, Hep G2, was used as a model for the investigation of mechanisms which control hepatic secretion of the apo B and lipid components of lipoproteins. Using a sensitive immunoradiometric assay for apo B developed in this laboratory, we showed that bovine serum albumin inhibited and glucose, and fatty acids enhanced the rate of accumulation of apo B in the culture medium of Hep G2 cells. However, these substances did not necessarily affect LDL lipids in the same way as apo B. This finding appeared to be due to Hep G2 cells expressing lipase activities which led to triacylglycerol and phospholipid hydrolysis and lipid reuptake. Reuptake of apo B also occurred, but its rate of accumulation in the culture medium suggested it was a closer reflection of its true secretory rate.     

Evaluation of the secondary structure of apo B-100 in low-density lipoprotein (LDL) by infrared spectroscopy

The secondary structure of the apo B-100 protein present in human low density lipoprotein has been investigated by transmission and attenuated total reflection infrared spectroscopy. The amount of beta-sheet (41%) is significantly higher than that determined by CD spectroscopy in the present study (12%) and elsewhere (15-16%). The high percentage of beta-sheet structure in apo B-100 supports the importance of such segments in maintaining the lipid-protein assembly in LDL. Polarized infrared spectroscopy indicates that the beta-sheet component of apo B-100 adopts a preferential orientation with respect to the phospholipid monolayer surrounding the LDL, whereas no such orientation is observed for the other secondary structure components.     

Measurement of human high density lipoprotein apolipoprotein A-1 in serum by radioimmunoassay.

A sensitive and specific double antibody radioimmunoassay for the major apolipoprotein (apo A-I) of human serum high density lipoprotein (HDL) was developed. Initial studies indicated that direct measurements of apo A-I concentration in whole untreated sera or isolated high density lipoprotein fractions yielded variable results, which were lower than those obtained in the corresponding samples which had been subjected to delipidation. Subsequently, it was observed that heating diluted sera or HDL for 3 hr at 52 degrees C prior to assay resulted in maximal increases in apo A-I immunoreactivity to levels comparable to those found in the delipidated specimens. This simple procedure permitted multiple sera to be assayed efficiently with full recovery of apo A-I.