Immunochemical evidence that human apoB differs when expressed in rodent versus human cells

LDL from human apolipoprotein B-100 (apoB-100) transgenic (HuBTg+/+) mice contains more triglyceride than LDL from normolipidemic subjects. To obtain novel monoclonal antibody (MAb) probes of apoB conformation, we generated hybridomas from HuBTg+/+ that had been immunized with LDL isolated from human plasma. One apoE-specific and four anti-apoB-100-specific hybridomas were identified. Two MAbs, 2E1 and 3D11, recognized an epitope in the amino-terminal 689 residues of apoB in native apoB-containing lipoproteins (LpBs) from human plasma or from the supernatant of human hepatoma HepG2 cells, but did not react with LpB from HuBTg+/+ mice or LpB secreted by human apoB-100-transfected rat McArdle 7777 hepatoma cells. 2E1 reacted weakly and 3D11 reacted strongly with apoB from HuBTg+/+ mice after SDS-PAGE. The lack of expression of the 2E1 and 3D11 epitopes on native LpB from HuBTg+/+ mice did not solely reflect the abnormal lipid composition of murine LpB. Both epitopes were detected in all human plasma samples tested and in all human plasma LpB classes. Therefore, human apoB expressed by rodent hepatocytes or hepatoma cells appears to adopt a different conformation or undergoes different posttranslational modification than apoB expressed in human hepatocytes or hepatoma cells.     

The use of monoclonal antibodies to localize the low density lipoprotein receptor-binding domain of apolipoprotein B

Human apolipoprotein (apo) B-100 is composed of 4536 amino acids. It is thought that the binding of apoB to the low density lipoprotein (LDL) receptor involves an interaction between basic amino acids of the ligand and acidic residues of the receptor. Three alternative models have been proposed to describe this interaction: 1) a single region of apoB is involved in receptor binding; 2) groups of basic amino acids from throughout the apoB primary structure act in concert in apoB receptor binding; and 3) apoB contains multiple independent binding regions. We have found that monoclonal antibodies (Mabs) specific for a region that spans a thrombin cleavage site at apoB residue 3249 (T2/T3 junction) totally blocked LDL binding to the LDL receptor. Mabs specific for epitopes outside this region had either no or partial ability to block LDL binding. In order to define the region of apoB directly involved in the interaction with the LDL receptor we have tested 22 different Mabs for their ability to bind to LDL already fixed to the receptor. A Mab specific for an epitope situated between residues 2835 and 2922 could bind to its epitope on LDL fixed to its receptor whereas a second epitope between residues 2980 and 3084 is inaccessible on receptor-bound LDL. A series of epitopes near residue 3500 of apoB is totally inaccessible, and another situated between residues 4027 and 4081 is poorly accessible on receptor-bound LDL. In contrast, an epitope that is situated between residues 4154 and 4189 is fully exposed. Mabs specific for epitopes upstream and downstream of the region 3000-4000 can bind to receptor-bound LDL with a stoichiometry close to unity. Our results strongly suggest that the unique region of apoB directly involved in the LDL-receptor interaction is that of the T2/T3 junction.     

Regional specificities of monoclonal anti-human apolipoprotein B antibodies

The usefulness of monoclonal antibodies as probes of protein structure is directly related to knowledge of the structures and locations of the epitopes with which they interact. In this report we provide a detailed map of 13 epitopes on apoB-100 defined by our anti-apoB monoclonal antibodies based on current information on the amino acid sequence of apoB-100. To localize antibody specificities to smaller regions along the linear sequence of the apoB-100 molecule we used a) thrombin- and kallikrein-generated fragments of apoB-100; b) beta-galactosidase- apoB fusion proteins; c) heparin; and d) antibody versus antibody competition experiments. Most of the monoclonal antibodies elicited by immunization with LDL were directed towards epitopes within the first 1279 amino terminal (T4/K2 fragments) or last 1292 carboxyl terminal amino acid residues (T2/K4 fragments) of apoB-100. One epitope localized to the mid-portion of apoB-100 was elicited by immunization with VLDL (D7.2). Saturating amounts of heparin bound to LDL did not inhibit the binding of any of the monoclonal antibodies to their respective epitopes on apoB-100, indicating that none of the antibody determinants is situated close to any of the reported heparin binding sites on LDL apoB. We examined the expression of apoB epitopes on VLDL subfractions and LDL isolated from a normolipidemic donor. The apparent affinities with which the antibodies interacted with their respective epitopes on the VLDL subfractions and LDL uniformly increased as follows: LDL greater than VLDL3 greater than VLDL2 greater than VLDL1, suggesting that each of the major regions of apoB-100 is progressively more exposed as normal VLDL particles become smaller in size and epitopes are most exposed in LDL. Previous experiments utilizing hypertriglyceridemic VLDL subfractions yielded similar results, but the rank order of VLDL subfractions and LDL was not the same for all antibodies tested. Thus, differences in apoB epitope expression on VLDL particles of differing sizes is a general phenomenon, but the expression of apoB epitopes in hypertriglyceridemic VLDL appears to be more heterogeneous than is the case for VLDL from normolipidemic donors.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mapping apolipoprotein B on the low density lipoprotein surface by immunoelectron microscopy

Apolipoprotein B (apoB) was mapped using electron microscopy to visualize pairs of monoclonal antibodies binding to the low density lipoprotein (LDL) surface. The sites at which these monoclonals bind the apoB polypeptide sequence had already been established. The angular distances between all possible pairs of binding sites except one allowed the relative placement of six epitopes on the LDL sphere. We conclude that apoB extends over at least a hemisphere of the LDL surface since four epitopes are located in the Northern Hemisphere at sites arbitrarily designated as the North Pole, the Aleutian Islands, Bogotá, and in the Atlantic Ocean, while two are found in the Southern Hemisphere at Buenos Aires and at Madagascar. ApoB appears to possess a restricted flexibility, since these relative epitope locations show a substantial standard deviation in latitude and longitude. Mapping of additional epitopes may provide an answer to the question of whether apoB circumnavigates the LDL sphere.     

Antigenic mapping of human low density lipoprotein with monoclonal antibodies

Monoclonal anti-LDL antibodies were produced in a mouse spleen-myeloma system and purified by affinity chromatography on insolubilized low density lipoprotein (LDL). Five antibodies with different specificities could be distinguished by their immunoreactivities with chemically modified LDL preparations, and by their competition for binding to LDL. One of the antibodies inhibited the binding of (125)I-labeled LDL to the apoB,E receptors of cultured human fibroblasts. The same degree of inhibition was achieved using isolated Fab fragments. This antibody may bind to an antigenic site located near the cellular binding site of LDL-apoB.-Tikkanen, M. J., R. Dargar, B. Pfleger, B. Gonen, J. M. Davie, and G. Schonfeld. Antigenic mapping of human low density lipoprotein with monoclonal antibodies.     

An immunochemical marker of low density lipoprotein oxidation

Using monoclonal antibodies against apolipoprotein B (apoB) we studied changes in apoB immunoreactivity during copper ion-mediated oxidation of human low density lipoprotein (LDL). The radioimmunoassay experiments demonstrated the decrease of immunoreactivity of three different epitopes of apoB located in different parts of the protein; at the same time the immunoreactivity of another epitope, previously mapped to the C-terminal 20 amino acids of apoB increased markedly during the first 6 h of LDL oxidation and diminished gradually upon prolonged incubation with copper ions. The fate of LDL during oxidation was also monitored using electrophoretic techniques combined with immunodetection. These experiments showed a rapid fragmentation and disappearance of immunoreactive apoB. They also indicated that the diminishing LDL immunoreactivity detectable during oxidation is associated with apoB fragments still attached to the lipid core. The changes in apoB immunoreactivity during Cu2+ treatment of LDL are similar to those observed upon LDL aging. Therefore, it appears that the enhancement of immunoreactivity of the C-terminus of apoB is a general phenomenon associated with various kinds of oxidative modifications of LDL.     

Primary sequence mapping of human apolipoprotein B-100 epitopes. Comparisons of trypsin accessibility and immunoreactivity and implication for apoB conformation

Differential trypsin-accessibility and monoclonal antibodies (Mabs) to human apolipoprotein (apo) B-100 are both important tools for probing apoB structure and conformation on low-density lipoproteins (LDL). In this study, we have mapped greater than 80% of the C-terminal region (720 residues) of LDL apoB-100 using trypsin digestion. Our results extend our previous data [Yang et al. (1986) Nature (Lond.) 323, 738-742] confirming that the C-terminal region of about 420 residues of apoB-100 is largely inaccessible to trypsin, whereas the part just preceding this region has interspersed trypsin-accessible and inaccessible peptides. We have determined the amino acid sequence of specific apoB-100 peptides containing epitopes recognized by four separate Mabs: two epitopes have been mapped to within 20 residues, one has been mapped to 36 residues, and the last to 80 residues. We used polyclonal antisera to identify 16 overlapping clones of varying lengths of apoB-100 cDNAs extending from the C-terminus of apoB-100 cloned in the expression vector, lambda gt11. These clones were then tested against individual Mabs. By nucleotide sequence analysis of overlapping clones that show differential reactivities to different Mabs, we have mapped the individual epitopes of each Mab to within about 50-150 amino acid residues predicted from the DNA sequences. Confirmation and further fine mapping were accomplished by competition for LDL binding using partially purified fusion proteins and chemically synthesized oligopeptides. Two epitopes (Mabs 7 and 22) were mapped to the C-terminal 20 amino acids of apoB-100, one (Mab 16) to residues 4154-4189, and another (Mab 20) to residues 3926-4005. Mab 16 precipitates more than 80% of LDL particles. Mab 20 precipitates only denatured apoB but not native LDL apoB [Milne et al. (1987) Mol. Immunol. 24, 435]. Mabs 7 and 22 are unique in that they precipitate LDL apoB modified by storage much better than freshly isolated LDL-apoB. Although epitope expression and trypsin-accessibility represent two useful probes for the study of protein conformation, there was no obvious correlation between these two parameters when applied to LDL apoB for the antibodies we have examined.     

Intrahepatic assembly of very low density lipoproteins: immunologic characterization of apolipoprotein B in lipoproteins and hepatic membrane fractions and its intracellular distribution

Monoclonal antibodies, prepared against rat apoB, were used to examine apoB structure in serum lipoproteins and characterize the forms and localization of apoB in liver membrane fractions and cultured hepatocytes. Of the several antibodies obtained, four, having separate epitopes, were characterized. Western blot analysis showed that three (DB11, F4, and LB14) antibodies recognized both apoBL and apoBS. One antibody (HB41) recognized only apoBL. This antibody showed unusual properties. Competition ELISA assays showed that the epitope recognized by HB41 was more effectively expressed on low density lipoproteins (LDL) compared to very low density lipoproteins (VLDL). In addition, treatment of lipoproteins with detergents and sulfhydryl reducing agents also increased the expression of the HB41 epitope. Since HB41 has been found to inhibit LDL binding to hepatocyte receptors, these data indicate that the HB41 epitope is located on the carboxy-terminal side of the apoBS junction (probably within the LDL receptor binding domain). Western blotting hepatic microsomal subfractions showed that in the rough and smooth microsomes, HB41 recognized only apoBL, while in the Golgi it recognized both apoBL and a protein having a molecular weight slightly smaller. In contrast, Western blotting with a polyclonal antibody known to recognize both apoBL and apoBS showed that, in rough and smooth microsomes, proteins in addition to apoBL and apoBS having molecular weights between 120,000 and 30,000 were recognized. These proteins, likely to be proteolytic fragments of apoB, were barely detectable in the Golgi. Additional biosynthetic studies show that the [35S]methionine-labeled proteins smaller than apoB were immunoprecipitated from the rough microsome subfraction. Pulse-chase experiments show that these are produced with the same kinetics as full-size apoBL and apoBS, indicating that they are not incomplete nascent chains. Finally, immunofluorescence microscopy was used to determine the localization of monoclonal epitopes. ApoB monoclonal antibodies that recognized exclusively apoBL (HB41) and apoBL and apoBS (DB11) produced an immunofluorescence pattern characteristic of the endoplasmic reticulum, but not the Golgi. These data suggest that, in cultured rat hepatocytes, the majority of both molecular weight forms of apoB are localized in the endoplasmic reticulum, the initial site of VLDL assembly. The additional finding that proteolytic fragments of apoB are enriched in the microsomal fraction suggests that if the proteolysis occurs during subcellular fractionation, immature apoB is susceptible to proteolysis.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evolution of low density lipoprotein structure probed with monoclonal antibodies

To assess the relationship of apoB structures in different species of animals, the expressions of apoB epitopes in the sera or plasmas of 23 different mammalian species and one marsupial, and on the low density lipoprotein (LDL) from three species of apes, six species of monkeys, and eight non-primates were measured in competitive radioimmunoassays. The abilities of the sera or LDL to compete with 125I-labeled human LDL for binding to seven monoclonal antihuman LDL antibodies immobilized on microtiter plates were determined. LDL of apes bound to most antibodies, while monkey LDL bound to two or three antibodies. Other mammalian LDL bound only weakly to two of the antibodies or to none. The two monoclonal antibodies binding the LDL of more species were those antibodies which also inhibited the binding to and degradation of LDL by human fibroblasts. The rank order of binding of the LDL of a given species to the antibodies correlated with the rank order inhibition of binding and degradation of 125I-labeled human LDL in the human fibroblast system. This suggests that epitopes spatially located near the recognition site of apoB for cellular receptors have a greater tendency to be conserved.     

The influence of the triglyceride content of low density lipoprotein on the interaction of apolipoprotein B-100 with cells

To study the effect of triglyceride content of low density lipoprotein (LDL) on its physicochemical and biological properties, we have depleted the triglyceride by incubation with hepatic lipase (HL-LDL) and raised the triglyceride by incubation of HL-LDL with very low density lipoprotein and lipoprotein-deficient serum. HL-LDL was taken up by human monocyte-derived macrophages and by human skin fibroblasts at an increased rate compared to untreated LDL. Incubation of the various LDL preparations revealed that cellular LDL degradation as well as LDL-mediated cholesterol esterification were inversely related to the triglyceride content of the LDL preparation. Modification of the triglyceride content of LDL also was associated with changes in the free fatty acid content, but the interaction of the LDL with cells was unaffected by the level of this component. The triglyceride content of LDL was found to be reciprocally related to the number of free lysine amino groups of LDL apolipoprotein B (apoB) which could be labeled with trinitrobenzenesulfonic acid. 13C-Nuclear magnetic resonance (NMR) spectra of native LDL and HL-LDL samples containing [13CH3]2 lysine residues formed by reductive methylation (11-13% modification) showed that the arrangement of apoB lysines is perturbed by the exposure to hepatic lipase. The ratio of labeled lysines with pK 8.9 to those with pK 10.5 exposed on the surface of LDL particles was decreased by about 40% by lipase treatment. These effects are apparently due to changes in local apoB conformation because circular dichroism spectra revealed that the average secondary structure of the entire apoB molecule is the same in native LDL and HL-LDL. The triglyceride content of LDL reciprocally affected its binding to a monoclonal antibody which recognizes epitopes around the LDL receptor binding domain of apoB. The above evidence indicates that modulation of the core triglyceride and possibly also surface phospholipid content of LDL can alter the conformation of apoB on the surface of the particle, thereby influencing the interaction with cell surface LDL receptors.     

Modification of the core lipids of low density lipoproteins produces selective alterations in the expression of apoB-100 epitopes.

The conformation of the apolipoprotein B-100 associated with low density lipoproteins (LDL) is not fixed. Rather, the conformations of several regions are subject to alteration by a variety of metabolic and therapeutic perturbations that change either the lipid compositions and/or sizes of LDL particles. However, because these perturbations simultaneously alter several structural-compositional features of the particles it has been difficult to relate structural-compositional features of LDL to apoB-100 conformations. Furthermore, in in vivo studies several days pass between samplings, thus different sets of particles are studied before and after experimental perturbation. In the present experiments more discrete perturbations of LDL were obtained in vitro by incubating LDL with very low density lipoproteins (VLDL) in the presence of partially purified human plasma lipid transfer proteins. The conformations of apoB on the LDL particles then were examined a) by probing epitope expression and b) by examining interactions between LDL and LDL-receptors in cultured human fibroblasts. During incubations with VLDL and lipid transfer proteins, the diameters of LDL particles decreased; the percentage composition of LDL triglycerides increased three-to fivefold; concomitantly, cholesteryl esters decreased. Lipid transfer protein was required for the transfer to occur and the magnitude of the increase in LDL-triglycerides depended upon the duration of incubation, the ratio of VLDL/LDL, and unknown properties specific to the various LDL preparations. The fact that the triglyceride contents of all LDL preparations were not identically affected suggests that initial packaging of the core region may affect capacity for lipid exchange.(ABSTRACT TRUNCATED AT 250 WORDS)     

High affinity binding between lipoprotein lipase and lipoproteins involves multiple ionic and hydrophobic interactions, does not require enzyme activity, and is modulated by glycosaminoglycans

Lipoprotein lipase (LPL) physically associates with lipoproteins and hydrolyzes triglycerides. To characterize the binding of LPL to lipoproteins, we studied the binding of low density lipoproteins (LDL), apolipoprotein (apo) B17, and various apoB-FLAG (DYKDDDDK octapeptide) chimeras to purified LPL. LDL bound to LPL with high affinity (K(d) values of 10(-12) m) similar to that observed for the binding of LDL to its receptors and 1D1, a monoclonal antibody to LDL, and was greater than its affinity for microsomal triglyceride transfer protein. LDL-LPL binding was sensitive to both salt and detergents, indicating the involvement of both hydrophobic and hydrophilic interactions. In contrast, the N-terminal 17% of apoB interacted with LPL mainly via ionic interactions. Binding of various apoB fusion peptides suggested that LPL bound to apoB at multiple sites within apoB17. Tetrahydrolipstatin, a potent enzyme activity inhibitor, had no effect on apoB-LPL binding, indicating that the enzyme activity was not required for apoB binding. LDL-LPL binding was inhibited by monoclonal antibodies that recognize amino acids 380-410 in the C-terminal region of LPL, a region also shown to interact with heparin and LDL receptor-related protein. The LDL-LPL binding was also inhibited by glycosaminoglycans (GAGs); heparin inhibited the interactions by approximately 50% and removal of trace amounts of heparin from LPL preparations increased LDL binding. Thus, we conclude that the high affinity binding between LPL and lipoproteins involves multiple ionic and hydrophobic interactions, does not require enzyme activity and is modulated by GAGs. It is proposed that LPL contains a surface exposed positively charged amino acid cluster that may be important for various physiological interactions of LPL with different biologically important molecules. Moreover, we postulate that by binding to this cluster, GAGs modulate the association between LDL and LPL and the in vivo metabolism of LPL.     

Heterogeneity of apolipoprotein E epitope expression on human lipoproteins: importance for apolipoprotein E function

The conformations of apolipoproteins on the surfaces of lipoprotein particles affect their physiologic functions. The conformations of apoE on plasma lipoproteins were examined using a panel of eight anti-apoE monoclonal antibodies (MAbs). The antibodies, which reacted with the major isoforms of apoE (E2, E3, and E4), defined at least five epitopes on apoE. Proteolytic fragments and synthetic peptides of apoE were used in binding assays to assign antibody epitopes; the epitopes were all localized to the middle third of the apoE molecule. The expression of apoE epitopes on isolated apoE and on lipoproteins was probed in competitive microtiter plate immunoassays using the anti-apoE MAbs, 125I-labeled apoE as tracer, and isolated apoE, intermediate density (IDL), very low density (VLDL1-3), and high density (HDL2 and HDL3) lipoproteins as competitors. The antibodies determined the patterns of competition exhibited by the lipoprotein preparations. Antibodies of the IgM class (WU E-1, WU E-2, WU E-3) defined two sets of conformation-dependent epitopes that were assigned towards the middle and the carboxyl terminal of the middle third of apoE. Competition curves using these antibodies, apoE, and lipoproteins showed a large variability in ED50 values. MAbs WU E-4, WU E-7, and WU E-10 defined epitopes near the receptor recognition site on apoE. Competition curves demonstrated small ranges of ED50 values. MAbs WU E-11 and WU E-12, which defined epitopes toward the amino-terminal region of apoE, exhibited competition curves for apoE and lipoproteins that had consistent, but wider ranges of ED50 values. There was no strict relationship between lipoprotein flotation rates and epitope expression for any of the MAbs. Immunoaffinity chromatography of VLDL subfractions on four different MAb columns indicated that the differences in the competitive abilities of VLDL subfractions were partly due to heterogeneity of apoE epitope expression within any population of particles. VLDL particles specifically retained on two different anti-apoE MAb columns were better competitors than unretained fractions for 125I-labeled LDL binding to the apoB, E-receptor of cultured human fibroblasts, suggesting that increased accessibility of apoE on the surface of VLDL is associated with increased receptor recognition. These data suggest that individual epitopes of apoE can be modulated; epitope expressions are not determined solely by the sizes and/or densities of lipoprotein particles; and differences in apoE conformation have significant metabolic consequences.     

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.     

The molecular mechanism for the genetic disorder familial defective apolipoprotein B100

Familial defective apolipoprotein B100 (FDB) is a genetic disorder in which low density lipoproteins (LDL) bind defectively to the LDL receptor, resulting in hypercholesterolemia and premature atherosclerosis. FDB is caused by a mutation (R3500Q) that changes the conformation of apolipoprotein (apo) B100 near the receptor-binding site. We previously showed that arginine, not simply a positive charge, at residue 3500 is essential for normal receptor binding and that the carboxyl terminus of apoB100 is necessary for mutations affecting arginine 3500 to disrupt LDL receptor binding. Thus, normal receptor binding involves an interaction between arginine 3500 and tryptophan 4369 in the carboxyl tail of apoB100. W4369Y LDL and R3500Q LDL isolated from transgenic mice had identically defective LDL binding and a higher affinity for the monoclonal antibody MB47, which has an epitope flanking residue 3500. We conclude that arginine 3500 interacts with tryptophan 4369 and facilitates the conformation of apoB100 required for normal receptor binding of LDL. From our findings, we developed a model that explains how the carboxyl terminus of apoB100 interacts with the backbone of apoB100 that enwraps the LDL particle. Our model also explains how all known ligand-defective mutations in apoB100, including a newly discovered R3480W mutation in apoB100, cause defective receptor binding.     

Antigenic determinants of the constant region of human immunoglobin kappa-chain detected by monoclonal antibodies

Ten different monoclonal antibody (monAB) preparations reacting with human IgL chains of the kappa type have been obtained. Nine of the monAB interacted with the kappa-chain C domain, whereas only one monAB reacted with the V domain. It has been determined that monAB against the C domain react with three different epitopes. One epitope is expressed on intact Ig molecules as well as on isolated kappa-chains, whereas the other two epitopes are found only on isolated kappa-chains. The expression of these epitopes in 40 different myeloma kappa-chain preparations belonging to four various subgroups was studied. The level of this C domain epitope expression has been shown to depend on the variable subgroups of kappa-chains indicating a close association between V and C domains. This association leads to the alteration of antigenic activity of some C domain epitopes. The alterations are thought to be local because, as a rule, they involve only one of the three epitopes.     

Different apolipoprotein B breakdown patterns in models of oxidized low density lipoprotein.

Low density lipoprotein (LDL) oxidation is characterized by alterations in biological properties and structure of the lipoprotein particles, including breakdown and modification of apolipoprotein B (apoB). We compared apoB breakdown patterns in different models of minimally and extensively oxidized LDL using Western blotting techniques and several monoclonal and polyclonal antibodies. It was found that copper and endothelial cell-mediated oxidation produced a relatively similar apoB banding pattern with progressive fragmentation of apoB during LDL oxidation, whereas malondialdehyde (MDA)- and hydroxynonenal (HNE) -modified LDL produced an aggregated apoB. It is conceivable that apoB fragments present in copper and endothelial cell oxidized LDL lead to the exposure on the lipoprotein surface of different protein epitopes than in aggregated MDA-LDL and HNE-LDL. Although all models of extensively oxidized LDL led to increased lipid uptake in macrophages, mild degrees of oxidation interfered with LDL uptake in fibroblasts and extensively oxidized LDL impaired degradation of native LDL in fibroblasts. We suggest that in order to improve interpretation and comparison of results, data obtained with various models of oxidized LDL should be compared to the simpliest and most reproducible models of 3 h and 18 h copper-oxidized LDL (apoB breakdown) and MDA-LDL (apoB aggregation) since different models of oxidized LDL have significant differences in apoB breakdown and aggregation patterns which may affect immunological and biological properties of oxidized LDL.     

Use of bacterial expression cloning to localize the epitopes for a series of monoclonal antibodies against apolipoprotein B100.

Bacterial expression of apolipoprotein (apo) B cDNA constructs has been used to map a series of monoclonal antibodies (mAbs) to apoB by immunoblotting. In some cases assignments have been confirmed and refined by (i) semipurification of expressed protein, CNBr digestion, and assignment of the immunoreactive fragments; (ii) controlled digestion of the cDNA with the exonuclease Bal31 and bacterial expression of the truncated proteins that result; or (iii) expression of specific segments of cDNA amplified by the polymerase chain reaction. Forty mAbs were mapped to a minimum of 17 separate determinants on apoB. Tryptic fragments have been used to confirm the epitope assignments. In addition, this approach in conjunction with immunoassay, enables some deductions to be made about the trypsin-accessible regions in low density lipoprotein (LDL). The cleavage pattern obtained predicts retention of structure in the cysteine-rich domain of the amino terminus and also in the LDL receptor binding region. Trypsinized LDL was shown to bind to the LDL receptor by an authentic process, using monoclonal antibodies as competing ligands. In conjunction with the previous paper (Milne, R. W., Theolis, R., Maurice, R., Pease, R. J., Weech, P. K., Rassart, E., Fruchart, J.-C., Scott, J., and Marcel, Y. L. (1989) J. Biol. Chem. 265, 19754-19760) the mapped mAbs have been used to define the receptor-binding domain of apoB100 in LDL.     

Interaction of LDL, Lp[a], and reduced Lp[a] with monoclonal antibodies against apoB

Five monoclonal antibodies (2A, 9A, 6B, L3, L7) produced in mice against human apolipoprotein B were investigated by competitive and inhibitive electroimmunoassay (EIA) for their reactivity with low density lipoprotein (LDL), lipoprotein[a] (Lp[a]), and reduced Lp[a]. All of the antibodies reacted with apoB of the different lipoproteins indicated by very similar slopes of the binding curves. None of them gave a positive reaction with apolipoprotein[a]. The amount of apoB required for 50% inhibition of antibody binding varied for the different antibodies and lipoproteins. Antibody 9A showed almost the same affinity for LDL, Lp[a], and reduced Lp[a]. Antibodies 2A and 6B bound about twofold better to LDL and reduced Lp[a] than to untreated Lp[a]. Antibodies L3 and L7 needed nearly threefold higher amounts of Lp[a]-apoB for 50% inhibition of antibody binding than of apoB of LDL and reduced Lp[a]. The amount of apoB required for 50% inhibition of antibody binding was somewhat higher in inhibitive assay than in competitive assay. We suggest that apo[a] covers certain epitopes of apoB in native Lp[a] leading to a reduced reaction with the monoclonal antibodies. However, it could also be that the binding of the [a]antigen to apoB via disulfide bridges causes profound conformational changes of the apoB region exposed to the surface.     

Rat monoclonal antibodies to rabbit and human serum low-density lipoprotein.

A total of 16 hybrid myeloma clones secreting monoclonal antibodies (McAb) to rabbit or human serum low-density lipoprotein (LDL) were derived from the fusion of spleen cells from LOU or DA rats immunized with rabbit or human LDL and the rat myeloma lines Y3 Ag1.2.3 or YB2/0. Anti-(rabbit LDL) McAb showed limited reactivity with LDL from human, rhesus-monkey, rat and mouse serum. Six out of seven anti-(human LDL) McAb reacted with rhesus-monkey LDL, and only one showed partial cross-reaction with rabbit LDL. Binding-competition experiments indicated that the epitopes recognized by the anti-(rabbit LDL) IgG could be grouped into two major clusters: McAb in the first cluster reacted either with apo-(lipoprotein B-100) (apoB-100) and apo-(lipoprotein B-74) (apoB-74) or with apoB-100 but not with apo-(lipoprotein B-48) (apoB-48), the lower-Mr form of apoB of intestinal origin; the McAb in the second cluster all reacted with apoB-48 in addition to apoB-100 or apoB-100 and apoB-74. The six anti-(human LDL) IgG bound to separate epitopes on LDL. Further data on the epitope specificity of these McAb were obtained by antibody blotting after partial proteolysis of apoB-100 with trypsin or staphylococcal V8 proteinase, and the data confirmed the results obtained with the binding-competition experiments. One McAb to rabbit LDL inhibited the binding of LDL to the fibroblast LDL receptor (50% inhibition at a McAb/LDL molar ratio of 10). A similar result was produced by two other McAb at higher concentrations of antibody.