Uptake of canine beta-very low density lipoproteins by mouse peritoneal macrophages is mediated by a low density lipoprotein receptor

The receptor on mouse peritoneal macrophages that mediates the uptake of canine beta-very low density lipoproteins (beta-VLDL) has been identified in this study as an unusual apolipoprotein (apo-) B,E(LDL) receptor. Ligand blots of Triton X-100 extracts of mouse peritoneal macrophages using 125I-beta-VLDL identified a single protein. This protein cross-reacted with antibodies against bovine apo-B,E(LDL) receptors, but its apparent Mr was approximately 5,000 less than that of the human apo-B,E(LDL) receptor. Binding studies at 4 degrees C demonstrated specific and saturable binding of low density lipoproteins (LDL), beta-VLDL, and cholesterol-induced high density lipoproteins in plasma that contain apo-E as their only protein constituent (apo-E HDLc) to mouse macrophages. Apolipoprotein E-containing lipoproteins (beta-VLDL and apo-E HDLc) bound to mouse macrophages and human fibroblasts with the same high affinity. However, LDL bound to mouse macrophages with an 18-fold lower affinity than to human fibroblasts. Mouse fibroblasts also bound LDL with a similar low affinity. Compared with the apo-B,E(LDL) receptors on human fibroblasts, the apo-B,E(LDL) receptors on mouse macrophages were resistant to down-regulation by incubation of the cells with LDL or beta-VLDL. There are three lines of evidence that an unusual apo-B,E(LDL) receptor on mouse peritoneal macrophages mediates the binding and uptake of beta-VLDL: LDL with residual apo-E removed displaced completely the 125I-beta-VLDL binding to mouse macrophages, preincubation of the mouse macrophages with apo-B,E(LDL) receptor antibody inhibited both the binding of beta-VLDL and LDL to the cells and the formation of beta-VLDL- and LDL-induced cholesteryl esters, and binding of 125I-beta-VLDL to the cells after down-regulation correlated directly with the amount of mouse macrophage apo-B,E(LDL) receptor as determined on immunoblots. This unusual receptor binds LDL poorly, but binds apo-E-containing lipoproteins with normal very high affinity and is resistant to down-regulation by extracellular cholesterol.     

Characterization of antigenic determinants on human solubilized apolipoprotein B. Conformational requirements for lipids

The expression of low density lipoprotein (LDL) antigenic determinants in the delipidated and solubilized apolipoprotein B (apo-B) free of sodium dodecyl sulfate (SDS) has been studied. Of the six distinct determinants which react with previously characterized monoclonal antibodies against LDL (Milne, R.W., Theolis , R., Jr., Verdery , R.B., and Marcel , Y.L. (1983) Arteriosclerosis 3, 23-30), only one, that recognized by antibody 1D1 , was expressed on the soluble apo-B, indicating that soluble apo-B may be partly denatured. The average immunoreactivity of apo-B with antibody 1D1 was similar to or lower than that of intact LDL (mean 36%, range 93-20%). Therefore, delipidation and solubilization did not expose on apo-B any additional site reactive with 1D1 . When apo-B was equilibrated with either SDS micelles or with cholesterol-lecithin liposomes, the immunoreactivity of the determinant recognized by antibody 2D8 was partially regenerated, but not that of the others. In contrast, incubation of apo-B with microemulsions containing a hydrophobic core of cholesteryl esters also restored the antigenicity of the determinants reacting with antibodies 3F5 , 4G3 , and 5E11 . However, the regeneration of these antigenic determinants could only be achieved when solubilized apo-B was treated with SDS prior to equilibration with microemulsion preparations. In conclusion, three types of antigenic determinants have been identified on apo-B. The first type, such as that recognized by antibody 1D1 , is expressed both on LDL and on apo-B and is constituted by the primary and secondary structure of apo-B. The second type, an example being that recognized by 2D8 , is a conformational determinant which requires the presence of amphipathic lipids such as lecithin and cholesterol or SDS micelles. The third type, which reacts with antibodies 3F5 , 4G3 , and 5E11 , represents different conformational determinants which require the association of apo-B with lipid structures having a cholesteryl ester hydrophobic core. It may be significant that the latter determinants are those close to the LDL receptor-binding site on apo-B and that this domain of apo-B has a complex tertiary and quaternary structure as evidenced by the conformational requirements of the antigenic determinants.     

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.     

Characterization of a monoclonal antibody that binds equally to all apolipoprotein and lipoprotein forms of human plasma apolipoprotein B. I. Specificity and binding studies

A stable mouse hybridoma cell line has been developed that produces monoclonal antibody to human plasma apolipoprotein B. This antibody was proven to be specific for apolipoprotein B immunoblotting and an enzyme immunoassay using apolipoprotein B and other apolipoproteins. The antibody bound with comparable affinities to soluble apolipoprotein B, chylomicrons, very-low-density (VLDL) and low-density lipoproteins (LDL). Coupled to agarose, this antibody allowed complete removal of apolipoprotein B-containing lipoproteins from normolipidemic, hypertriglyceridemic and hypercholesterolemic plasma. Desialyzation and deglycosylation had no effect on its binding to LDL. The described antibody had no effect on the receptor-mediated binding of radiolabeled LDL to the human hepatoma cells (HepG2) in culture. Analysis of 25 different samples of human plasma indicated identical expression of the corresponding epitope in these individuals. The described monoclonal antibody, most likely, binds to a rather stable domain of apolipoprotein B that is not altered by the interaction with lipids or polymorphism of the apolipoprotein B. We propose that this antibody be called 'Pan B' antibody.     

Mapping of antigenic determinants of human apolipoprotein B using monoclonal antibodies against low density lipoproteins

The reactivity of a series of monoclonal antibodies directed against human low density lipoproteins (LDL) has been tested with hepatic and intestinal apolipoprotein B (apo-B) termed B-100 and B-48, respectively (Kane, J. P., Hardman, D. A., and Paulus, H. E. (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 2465-2469). Whereas those antibodies that have been previously shown to recognize determinants close to the LDL receptor recognition site reacted only with B-100, two antibodies specific for other regions of apo-B reacted with both B-100 and B-48. Therefore, it is probable that sequence homologies exist between the two proteins and it must be considered that all or parts of the B-48 sequence may be contained within that of B-100. The specificity of the reaction of these antibodies with proteins designated B-74 and B-26 supports the concept that they represent complementary fragments of B-100. The present results have been incorporated in a theoretical map of the antigenic determinants recognized by these antibodies on the LDL apo-B.     

Characterization of monoclonal anti-rabbit apolipoprotein E antibodies and chemical composition of lipoproteins separated by anti-apolipoprotein E immuno-affinity chromatography

Six mouse monoclonal antibodies against rabbit apolipoprotein E (apo E) have been developed. Of these monoclonal antibodies, clone 5 revealed a high affinity for purified apo E, very low density lipoprotein (VLDL) and beta-VLDL. This monoclonal antibody was used to prepare an immunoaffinity column. Coupled to Sepharose 4B, this antibody allowed complete removal of lipoproteins containing apo E from plasma of New Zealand white (NZW) rabbits; 62, 46, 14, and 3% of VLDL-, IDL-, LDL-, and HDL-protein, respectively, were bound to the anti-apo E affinity column. The bound VLDL was significantly rich in free cholesterol (FC) and cholesteryl esters (CE) relative to the unbound VLDL, whereas bound IDL, LDL and HDL were significantly rich in FC only. All of the bound fractions were characterized by significantly increased ratios of FC/phospholipids (PL). These results indicate that the two lipoprotein populations with and without apo E have different lipid compositions. The relatively high content of cholesterol in lipoproteins containing apo E suggests a contribution of apo E to plasma cholesterol transport.     

Immunochemical properties of human low density lipoproteins as explored by monoclonal antibodies. Binding characteristics distinct from those of conventional serum antibodies

Spleen cells obtained from mice immunized with human plasma low-density lipoproteins (LDL) were fused with mouse myeloma cells. The resulting hybridoma cells secreting immunoglobulin specific for LDL were screened and scored by radioimmunoassay and cloned by multiple limiting dilutions. Immunochemical properties of the monoclonal antibodies were compared with convential mouse serum antibodies. It was found that conventional antibodies precipitated LDL and bound more than 95% of 125I-labeled LDL and the maximal binding was independent of temperature. The monoclonal antibodies were incapable of precipitating LDL and bound a maximum of only 20% of the total 125I-labeled LDL. The maximal binding between monoclonal antibodies and LDL was extremely temperature-dependent. An optimal degree of binding was observed at 4 degrees C, whereas binding at 37 degrees C was only 30% of that achieved at 4 degrees C. Although the binding at 37 degrees C was low, the maximal binding could be re-established following a subsequent incubation at 4 degrees C, suggesting that the antigenic structure of LDL is reversibly modulated at temperatures between 4 and 37 degrees C. Since the orientation of apolipoprotein B in LDL is known to be dynamic at different temperatures, this result suggests that monoclonal antibodies, but not conventional antibodies, are capable of detecting subtle conformational changes in LDL. In addition, we have determined the binding affinity of LDL to monoclonal antibodies and to conventional antibodies. Only monoclonal antibodies showed a linear Scatchard plot, suggesting that the binding was to a single site with a single affinity. The monoclonal antibodies also possessed high specificity and failed to react with porcine LDL, while serum antibodies could recognize both human and porcine LDL.     

Modulation of apolipoprotein B antigenic determinants in human low density lipoprotein subclasses

To investigate the effect of low density lipoprotein (LDL) heterogeneity on the conformation of LDL apolipoprotein B (apo-B), the immunoreactivities of 6 monoclonal antibodies against LDL apo-B were measured in 3 LDL subfractions isolated by equilibrium density gradient ultracentrifugation. To ensure a broad range of LDL particles, the LDL subfractions were prepared from normal subjects and patients with hyperapobetalipoproteinemia. With 3 of the antibodies, 1D1, 5E11, and 3A10, LDL fractions 1 (the most buoyant), 2 (the intermediate), and 3 (the densest) were equally immunoreactive and competed similarly with reference whole LDL. In contrast, with 3 other antibodies, 2D8, 3F5, and 4G3, fraction 1 was significantly more reactive than fraction 3; that is for each in turn, 290, 250, and 150% more of the densest LDL protein was required to achieve the same displacement as with fraction 1. Further, the immunoreactivities of the 3 LDL fractions with antibodies 2D8, 3F5, and 4G3 were negatively correlated with their LDL cholesterol to LDL protein ratio with r values of 0.727, 0.898, and 0.870, respectively, suggesting that as LDL particle size decreases, the conformation of the LDL apo-B changes progressively. It is of interest that the antigenic determinants recognized by 3F5 and 4G3 are close to the LDL receptor recognition site on LDL apo-B. Therefore, it is possible that the reduced immunoreactivity of these determinants in dense LDL may be the in vitro correlate of the reduced fractional catabolics rate of dense LDL compared to buoyant LDL previously observed in vivo.     

Conformation of apolipoprotein B-100 in the low density lipoproteins of tangier disease. Identification of localized conformational response to triglyceride content.

The low density lipoproteins (LDL) from patients with Tangier disease are enriched in triglycerides, 27% of LDL mass versus 7% for normal LDL. To study whether this unique LDL core lipid composition affects the surface disposition of apolipoprotein (apo) B-100, we analyzed the LDL by protease digestion and in competitive radioimmunoassays. Limited proteolytic digestion of Tangier LDL by Staphylococcus aureus V8 protease generated a prominent fragment of 120 kDa (cleavage site at residue 1076), which was not visible in similarly digested normal LDL. In competitive radioimmunoassay, Tangier LDL bound weakly to the apoB-specific monoclonal antibody MB20, compared with control LDL. We localized the MB20 epitope between residues 1031 and 1084 of apoB-100, probably very near residue 1076. DNA sequencing of exon 21 of apoB genomic clones (coding for residues 1014-1084) from a Tangier patient revealed no difference from the normal DNA sequence, thus eliminating a protein polymorphism as a basis for the altered protease sensitivity and antibody binding. When the triglyceride contents of Tangier LDL were reduced to 10% of mass by incubation with normal high density lipoproteins, production of the 120-kDa fragment by proteolysis decreased and MB20 binding increased in affinity, implying a change toward normal conformation of apoB-100. Thus, using two independent techniques, proteolytic digestion and binding of monoclonal antibodies, we have demonstrated an alternative conformation of apoB-100 in the vicinity of residue 1076, which reflects the content of triglycerides in the LDL particle.     

Isolation and characterization of the apolipoprotein E receptor from canine and human liver

Previous results have demonstrated that liver membranes possess two distinct lipoprotein receptors: a low density lipoprotein (LDL) receptor that binds lipoproteins containing either apolipoprotein (apo-) B or apo-E, and an apo-E-specific receptor that binds apo-E-containing lipoproteins, but not the apo-B-containing LDL. This study reports the isolation and purification of apo-B,E(LDL) and apo-E receptors from canine and human liver membranes. The receptors were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate and were partially purified by DEAE-cellulose chromatography. The apo-B,E(LDL) receptor was isolated by affinity chromatography on LDL-Sepharose. The apo-E receptor, which did not bind to the LDL-Sepharose column, was then purified by using an HDLc (cholesterol-induced high density lipoprotein)-Sepharose affinity column and an immunoaffinity column. Characterization of the receptors revealed that the hepatic apo-B,E(LDL) receptor is similar to the extrahepatic LDL receptor with an apparent Mr = 130,000 on non-reducing sodium dodecyl sulfate-polyacrylamide gels. The apo-E receptor was found to be distinct from the apo-B,E(LDL) receptor, with an apparent Mr = 56,000. The purified apo-E receptor displayed Ca2+-dependent binding to apo-E-containing lipoproteins and did not bind to LDL or chemically modified apo-E HDLc. Antibodies raised against the apo-B,E(LDL) receptor cross-reacted with the apo-E receptor. However, an antibody prepared against the apo-E receptor did not react with the apo-B,E(LDL) receptor. The apo-E receptor also differed from the apo-B,E(LDL) receptor in amino acid composition, indicating that the apo-E receptor and the apo-B,E(LDL) receptor are two distinct proteins. Immunoblot characterization with anti-apo-E receptor immunoglobulin G indicated that the apo-E receptor is present in the hepatic membranes of man, dogs, rats, and mice and is localized to the rat liver parenchymal cells.     

Immunological heterogeneity of rat apolipoprotein B epitope expression. A study using monoclonal antibodies to rat apolipoprotein B

Epitope expression of rat apolipoprotein B on lipoproteins was investigated with the help of six monoclonal antibodies produced from mice. Through a variety of techniques, which include cotitrations, ELISAs and quantitative immunoadsorption precipitation, we concluded that the six monoclonal antibodies recognize five different epitopes. LRB 110 and LRB 260 recognize epitopes that may be overlapping. LRB 240 and LRB 250 recognize epitopes that are preferentially expressed in triacylglycerol-rich particles. LRB 220 recognizes an epitope that is expressed by all apolipoprotein-B-containing lipoproteins. We have also determined that apolipoprotein B epitope expression in rat lipoproteins is very similar to its human counterpart. Both rat and human apolipoprotein B epitope expression on lipoproteins showed heterogeneities even in homologous lipoprotein preparations. We concluded that a variety of techniques are necessary to fully characterize monoclonal antibodies to apolipoproteins. The possible implications of epitope expression in pathophysiology are also discussed.     

Uptake of Endoneurial Lipoprotein into Schwann Cells and Sensory Neurons Is Mediated by Low Density Lipoprotein Receptors and Stimulated After Axonal Injury

During Wallerian degeneration of rat sciatic nerve, the expression of apolipoprotein E increases and apolipoprotein E-containing endoneurial lipoproteins accumulate in the distal nerve segment. In established primary cultures dissociated from dorsal root ganglia, Schwann cells and sensory neurons internalized rhodamine-labeled lipoproteins isolated from crushed rat sciatic nerve as well as low density lipoprotein (LDL) from human serum. The uptake of endoneurial lipoproteins could be inhibited by an excess of LDL or at low temperature (4 degrees C). After transection of nerve fibers in dorsal root ganglia explant cultures, the uptake of lipoproteins was markedly stimulated in Schwann cells that were in close proximity to degenerating neurites. A specific monoclonal antibody directed to the bovine LDL receptor (clone C7) was shown to cross-react with LDL receptor preparations of rat endoneurial cells. LDL receptor immunoreactivity was expressed by cell bodies and processes of cultured Schwann cells, sensory neurons, and fibroblasts from dorsal root ganglia. Incubation of Schwann cells and neurons with the LDL receptor antibody strongly inhibited the uptake of endoneurial lipoproteins. Our results provide direct evidence for the important role of the LDL receptor-mediated pathway to internalize endoneurial lipoproteins into Schwann cells and peripheral neurons required for reuse of cholesterol and other lipids in myelin and plasma membrane biogenesis during nerve repair.     

Defective hepatic lipoprotein receptor binding of beta-very low density lipoproteins from type III hyperlipoproteinemic patients. Importance of apolipoprotein E

Apolipoprotein (apo-) E2 and beta-migrating very low density lipoproteins (beta-VLDL) (which were isolated from type III hyperlipoproteinemic subjects) both demonstrated defective binding to apo-E and apo-B,E receptors on dog liver membranes and to apo-B,E low density lipoproteins (LDL) receptors on fibroblasts. The defective binding activity of the apo-E2 and beta-VLDL varied from very poor to nearly normal. The ability of the beta-VLDL to interact with hepatic apo-E receptors was enhanced by the addition of normal apo-E3 to the beta-VLDL. Furthermore, cysteamine treatment of the apo-E2 in beta-VLDL enhanced binding of the beta-VLDL to both apo-E and apo-B,E receptors. The importance of apo-E in mediating the receptor binding of beta-VLDL to these receptors was confirmed by using monoclonal antibodies. The residual binding activity of beta-VLDL to apo-E and apo-B,E receptors was inhibited by greater than 90% with anti-apo-E, while the addition of anti-apo-B had little effect. The apo-B in the beta-VLDL was capable of binding to apo-B,E receptors after the hydrolysis of the beta-VLDL triglycerides with milk lipoprotein lipase. Lipase treatment yielded, two subfractions of beta-VLDL. One fraction (d = 1.02 to 1.03 g/ml) was enriched with apo-B100; the other fraction (d less than 1.006 g/ml) was enriched with apo-B48 and apo-E2. Significantly increased amounts of the apo-B100-enriched fraction bound to apo-B,E receptors. Inhibition of this binding caused by the addition of anti-apo-B indicated that the binding activity of this subfraction was mediated by apo-B100. The apo-B48-enriched fraction did not show a significant increase in receptor binding, suggesting that apo-B48 does not bind to these receptors. In a control experiment, it was shown that triglyceride-rich VLDL, which contain normal apo-E3 and apo-B100, bind significantly to both liver apo-E receptors and fibroblast apo-B,E receptors. This binding activity was inhibited by greater than 90% with anti-apo-E. Lipase hydrolysis of the VLDL did not further enhance their receptor-binding activity. These results demonstrate that apo-E, and not apo-B, is the major determinant mediating the receptor-binding activity of cholesterol-rich beta-VLDL and triglyceride-rich VLDL.     

Lipolysis-induced degradation of apolipoproteins B and E of human very low density lipoproteins

We have found that in vitro lipolysis of human very low density lipoproteins (VLDL) by purified bovine milk lipoprotein lipase (LpL) promotes degradation of the apolipoprotein (apo) B moiety of VLDL. Analysis by sodium dodecyl sulfate-polyacrylamide gradient gel electrophoresis showed that lipolysis of VLDL by purified LpL for 1 h at 37 degrees C induced the selective degradation of the high Mr apo-B (apo-B-100) from most hypertriglyceridemic VLDL and from a few normolipidemic VLDL into several small fragments with molecular weights ranging from 90,000-490,000. No detectable degradation of apo-B occurred in control VLDL when incubated without LpL. The apo-E moiety of VLDL from certain individuals was also degraded following lipolysis of VLDL, and the extent of degradation of apo-B and -E in VLDL was varied among the individual VLDL. The major degradation products of apo-E, identified from the gel, were 31,000- and/or 28,000-Da species. In contrast to the apo-E moiety of VLDL, purified apo-E was not degraded when incubated with LpL. Incubation of low density lipoproteins (LDL) with LpL showed only a minimal effect on the apoproteins of LDL. When high density lipoprotein (HDL) was included in the lipolysis mixture as an acceptor of lipolytic surface remnants, the apoproteins of HDL remained unaltered, while the apo-B moiety of VLDL remnants in the mixture was degraded. Inclusion of protease inhibitors in the lipolysis mixture prevented the degradation of apo-B, but the hydrolysis of VLDL-triglyceride was minimally affected. A selective degradation of apo-B in VLDL also occurred during lipolysis of VLDL when VLDL was perfused through rat hearts. These results suggest that conformational changes in apo-B and apo-E caused by VLDL lipolysis may increase the susceptibility of apo-B and apo-E to degradation by the proteases co-isolated with VLDL. The consequences of the lipolysis-induced degradation of apo-B and apo-E on changes in metabolic properties of VLDL remnants remain to be determined.     

Provision of cholesterol to lymphocytes by high density and low density lipoproteins. Requirement for low density lipoprotein receptors

The capacity of lipoprotein fractions to provide cholesterol necessary for human lymphocyte proliferation was examined. When endogenous synthesis of cholesterol was blocked, proliferation of mitogen-stimulated normal human lymphocytes was markedly inhibited unless an exogenous source of sterol was supplied. All lipoprotein fractions with the exception of high density lipoprotein subclass 3 were able to provide cholesterol for lymphocyte proliferation. Each of the lipoprotein subfractions capable of providing cholesterol was also able to regulate endogenous sterol synthesis in cultured human lymphocytes. Provision of cholesterol by lipoproteins required the interaction of apolipoprotein B or apolipoprotein E with specific receptors on normal lymphocytes. Apolipoprotein modification by acetylation or methylation, which markedly reduced the ability to regulate sterol biosynthesis, also diminished the capacity of lipoproteins to provide cholesterol. In addition, depletion of apolipoprotein B- and apolipoprotein E-containing particles from high density lipoprotein decreased its ability to suppress cholesterol synthesis and prevented it from providing cholesterol to proliferating lymphocytes. Monoclonal antibodies directed against the receptor-recognition sites on apolipoprotein B and apolipoprotein E were used to define the specific apolipoproteins required for the provision of cholesterol to lymphocytes by the various lipoprotein fractions. The antibody to apolipoprotein B inhibited cholesterol provision by both low density lipoprotein (LDL) and other lipoprotein fractions. The antibody to apolipoprotein E did not decrease provision of cholesterol by LDL but did inhibit the capacity of other fractions to provide cholesterol. In addition, a monoclonal antibody against the ligand binding site on the LDL receptor inhibited provision of cholesterol to normal lymphocytes by all lipoproteins. Finally, lymphocytes lacking LDL receptors were unable to obtain cholesterol from any lipoprotein fraction. These studies demonstrate that LDL receptor-mediated interaction with apolipoprotein B or apolipoprotein E is essential for the provision of cholesterol to normal human lymphocytes from all lipoprotein sources.     

Structure and function of human low density lipoproteins. Studies using proteolytic cleavage by plasma kallikrein

Kallikrein digestion of human low density lipoproteins (LDL) has recently been shown to result in the degradation of apolipoprotein B (apo-B) into four major fragments, two of them being B-26 and B-74, which have been reported to be present in the LDL of some individuals. We studied the binding of kallikrein-treated LDL to human fibroblasts; digestion did not affect binding. Digested LDL was not taken up by macrophages, showing that it behaved like normal LDL. The activation of acyl-CoA cholesterol acyltransferase by LDL in fibroblasts was also not altered by kallikrein digestion. When delipidated LDL was treated with kallikrein, apo-B was digested into very small fragments, indicating that kallikrein can cleave apo-B at sites other than those which result in the formation of B-26 and B-74. The partial delipidation of LDL with heptane also resulted in more extensive digestion of apo-B, although binding to cells was unaffected. These studies suggest that the cholesterol core maintains the proper orientation of apo-B in the LDL particle and that kallikrein may be used as a tool to elucidate the association of apo-B and lipids in the LDL particle.     

Properties of an apolipoprotein E-enriched fraction of triglyceride-rich lipoproteins isolated from human blood plasma with a monoclonal antibody to apolipoprotein B-100.

A monoclonal antibody to apolipoprotein (apo) B-100 (JI-H) with unique binding properties has been used to separate a population of triglyceride-rich lipoproteins from blood plasma of normotriglyceridemic individuals and patients with various forms of hypertriglyceridemia. This antibody fails to recognize an apoE-rich population of very low density lipoproteins (VLDL) containing apoB-100 as well as all triglyceride-rich lipoproteins containing apoB-48, but it binds other VLDL that contain apoE and almost all lipoproteins that contain apoB-100, but no apoE. The unbound triglyceride-rich lipoproteins separated by ultracentrifugation after separation from plasma by immunoaffinity chromatography contained 10-13% of the apoB of triglyceride-rich lipoproteins from three normotriglyceridemic individuals, 10-29% of that from five patients with endogenous hypertriglyceridemia, 40-48% of that from three patients with familial dysbetablipoproteinemia, and 65% of that from a patient with lipoprotein lipase deficiency. In all cases, the unbound triglyceride-rich lipoproteins contained more molecules of apoE and cholesteryl esters per particle than those that were bound to monoclonal antibody JI-H, and they were generally depleted of C apolipoproteins. These properties resemble those described for partially catabolized remnants of chylomicrons and VLDL. The affinity of the unbound lipoproteins for the low density lipoprotein (LDL) receptor varied widely, and closely resembled that of the total triglyceride-rich lipoproteins from individual subjects. Our results demonstrate that remnant-like chylomicrons and a population of remnant-like VLDL can be isolated and quantified in blood plasma obtained in the postabsorptive state from normotriglyceridemic and hypertriglyceridemic individuals alike.     

Characterization of a monoclonal antibody that binds equally to all apolipoprotein and lipoprotein forms of human plasma apolipoprotein B. II. Isolation of apolipoprotein B-containing lipoproteins from human plasma

Monoclonal antibody ('Pan B' antibody) that binds equally to all major forms of human plasma apolipoprotein B was used in an immunoaffinity chromatography procedure to isolate apolipoprotein B-containing lipoproteins from hyperlipidemic human plasma. These lipoproteins were compared with lipoproteins in native plasma, with lipoproteins isolated by polyclonal antibodies and with lipoproteins isolated by the conventional ultracentrifugational method. Judged by the apolipoprotein and lipid composition, lipoproteins isolated with 'Pan B' antibody were virtually identical to those isolated by ultracentrifugation or polyclonal antibodies. Lipoproteins isolated by 'Pan B' antibody were comparable in size and shape to the lipoproteins in native plasma and to the lipoproteins isolated by polyclonal antibodies or ultracentrifugation. The immunoaffinity column with monoclonal 'Pan B' antibody retained all apolipoprotein B-containing lipoproteins and showed significantly higher capacity than polyclonal immunoaffinity column. The column with the highest capacity allowed the isolation from whole plasma of 0.144 mg of apolipoprotein B per ml of gel in less than 2 h.     

The recognition domain for the low density lipoprotein cellular receptor is expressed once on each lipoprotein particle

The stoichiometry of binding of monoclonal antibodies and Fab fragments to LDL was assessed. Increasing amounts of two [125I]-labelled antibodies which define epitopes at or near the LDL-receptor recognition domains of apoB were incubated with fixed amounts of LDL and antibody-LDL complexes were separated from free antibodies by heparin-MnCl2 precipitation. Saturation kinetics were obtained and data were analyzed according to Scatchard. One antibody or Fab fragment was bound per LDL particle. Homogeneity of binding was indicated by straight Scatchard lines and by the binding of virtually all LDL particles by an antibody affinity chromatographic column.     

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.