Immunochemical characterization of six monoclonal antibodies to human apolipoprotein A-I: epitope mapping and expression.

We have produced and characterized six murine monoclonal antibodies to human apolipoprotein A-I named A-I-9, A-I-12, A-I-15, A-I-16, A-I-19, and A-I-57. All monoclonal antibodies were specific for apolipoprotein A-I and bound between 55% and 100% of 125I-labeled high density lipoproteins (HDL) in a fluid phase radioimmunoassay. All antibodies possessed a higher affinity to apoA-I in HDL than to free, delipidated apoA-I. Two of them, particularly A-I-12 and A-I-15, which were directed to the same or very close epitopes on the molecule, recognized very poorly the delipidated protein. Binding of apoA-I to phospholipid restored the immunoreactivity of the monoclonal antibodies to the protein suggesting that lipids play an important role in determining the immunochemical structure of apoA-I. Using CNBr fragments and synthetic peptides, the epitopes for the antibodies were mapped as follows: A-I-19, CNBr fragment 1; A-I-12 and 15, CNBr fragment 2; A-I-9 and A-I-16, CNBr fragment 3; A-I-57, CNBr fragment 4. Antibody A-I-57 failed to recognized a mutant form of apoA-I, A-IMilano (Arg173----Cys) by immunoblotting and by competitive radioimmunoassay demonstrating that substitution of a single amino acid in human apoA-I may cause the loss of an antigenic determinant.     

Immunochemical characterization of two antigenic sites on human apolipoprotein A-I; localization and lipid modulation of these epitopes

Two monoclonal antibodies, A17 and A30, were raised against human apolipoprotein A-I (apo A-I). They were studied by competitive inhibition of 125I-labeled HDL3 with HDL subfractions, delipidated apo A-I, and complexes of dimyristoylphosphatidylcholine (DMPC) containing apo A-I and apo A-II. Immunoblotting located the A17 antibody on CNBr fragment 4 of apo A-I and the A30 antibody on CNBr fragment 1. The A17 antigenic determinant was expressed identically in all HDL subclasses, on delipidated apo A-I as well as all on the DMPC-apo A-I and DMPC-apo A-I/apo A-II complexes. In contrast, the apparent affinity constant of the A30 antibody for delipidated apo A-I was about 30-times less than for HDL3 or for apo A-I/apo A-II-phospholipid complexes. These data suggest that the association of apo A-I with phospholipids improves the reactivity of the A30 monoclonal antibody towards apo A-I, and that this antigenic determinant has a different conformation in delipidated apo A-I compared to apo A-I complexed with phospholipids. Turbidimetric and fluorescence experiments monitoring the phospholipid-apo A-I association in the presence and in the absence of the A17 and A30 antibodies were consistent with the competition experiments carried out by solid phase radioimmunoassay (RIA). After reaction of apo A-I with the A30 antibody, we observed an enhancement of the degradation kinetics of large multilamellar vesicles (LMV), while the A17 antibody did not have a significant effect. Calcein leakage experiments carried out below the transition temperature of DPPC showed an enhancement of the degradation kinetics with both monoclonal antibodies, while the phase-transition release was independent of the reaction of apo A-I with the monoclonal antibodies. These data therefore suggest the existence of at least two different types of epitope on apo A-I, which might account for the differences in immunological reactivity of apo A-I that is either delipidated or present on HDL.     

Apolipoprotein A-I from normal human plasma: definition of three distinct antigenic determinants

We have prepared, selected and cloned four mouse hybridomas that secreted monoclonal antibodies against human plasma apolipoprotein A-I. These antibodies are all of the IgG-I subclass, and were named anti-A-I 6B8, 5G6, 3D4 and 5A6. We characterized the specificity of the antibodies, finding that all four of them reacted similarly, and with only the major proteins having the molecular weight and isoelectric focusing characteristics of apolipoprotein A-I. The antibodies reacted with all known charge-polymorphs of apolipoprotein A-I and pro apolipoprotein A-I. Thus, the polymorphs of apolipoprotein A-I are alike in that they all contain the antigenic sites of these four antibodies. In a solid-phase, antibody competition radioimmunoassay we found inhibition or enhancement of antibody binding to apolipoprotein A-I, according to the pair of antibodies tested. Antibodies 6B8, 5G6 and 3D4 were different from one another and reacted with different antigenic determinants, but 5A6 was similar to 3D4 and reacted at the same site. We compared the reactions of the four antibodies with CNBr-cleaved fragments of apolipoprotein A-I separated by polyacrylamide gel electrophoresis. We found three different patterns of reaction with the apolipoprotein A-I fragments; 6B8, 5G6 and 3D4 were different, but 5A6 resembled 3D4. Thus, the four antibodies reacted with at least three different antigenic sites in apolipoprotein A-I, which were present in different CNBr fragments of apolipoprotein A-I, but not on fragment 4 which forms the carboxy-terminal segment.     

Monoclonal antibodies as probes of high-density lipoprotein structure: identification and localization of a lipid-dependent epitope

Eight stable murine monoclonal antibodies (mabs) were raised against human high-density lipoproteins (HDL). Three different antibody reactivities were demonstrated by immunoblotting. A group of five antibodies were specific for apolipoprotein A-I (apoA-I) and bound to similar or overlapping epitopes. The second type of reactivity, shown by mab-32, was specific for apoA-II. In the third group, two antibodies showed high reactivity with apoA-II and slight cross-reactivity with apoA-I. The properties of two antibodies, mab M-30 specific for apoA-I and mab M-32 specific for apoAII, were characterized in detail as probes of HDL structure. The association of 125I-labeled HDL or synthetic complexes of apoA-I and phosphatidylcholine with mab M-30 was lipid dependent. Mab M-32 binding to apoA-II was independent of lipid. The lipid-dependent epitope bound by mab M-30 has been localized to an 18 amino acid synthetic apoA-I peptide. Moreover, studies with HDL2, HDL3, and immunoadsorbed HDL subfractions indicate that binding of mab M-30 to HDL is influenced by some component within the microenvironment individual HDL particles. These lines of evidence suggest that the molar ratio of apoA-I to apoA-II is the critical determinant. Binding of mab M-32 to HDL increased the reactivity of HDL to mab M-30 in a dose-dependent manner, indicating an unusual form of cooperativity between two mabs that recognize different proteins in HDL. These monoclonal antibodies will be valuable in studies of the metabolic significance of protein-protein and lipid-protein interactions in HDL.     

Structure of high density lipoprotein. The immunologic reactivities of the COOH- and NH2-terminal regions of apolipoprotein A-I.

Only 5 to 10% of the apolipoprotein A-I (ApoA-I) of intact high density lipoprotein (HDL) is detectable by radioimmunoassay. In addition, when isolated ApoA-I is recombined with lipids in vitro, its immunologic reactivity is decreased by 30 to 95%. Thus, ApoA-I is less reactive immunologically in the presence of lipids. Our aim was to ascertain whether the COOH- or NH2-terminal regions of ApoA-I were equally reactive in intact HDL2. CNBr fragments of ApoA-I were produced by the method of Baker et al. (Baker, H.N., Jackson, R.L., and Gotto, A.M. (1973) Biochemistry 12, 3866-3871) and iodinated with lactoperoxidase. Double-antibody radioimmunoassays were set up using anti ApoA-I antisera and 125I-CNBr I (COOH-terminal region) or 125I-CNBr II (NH2-terminal). Both labels were bound by the antisera. Affinity columns were prepared by binding CNBr I or CNBr II to Sepharose 4B. Antibodies specific against CNBr I or CNBr II were isolated by means of these columns, suggesting that ApoA-I had at least two antigenic sites. In other assays using labeled fragments and anti ApoA-I antisera, 125I-CNBr I was displaced by CNBr I, ApoA-I , and HDL2 but not CNBr II. Conversely, 125I-CNBr II was displaced by CNBr II, ApoA-I, and HDL2 but not by CNBr I. Thus the assays were region-specific. The reactivities of isolated ApoA-I and the ApoA-I in intact HDL2-ApoA-I) were compared in these assays. On a molar basis, HDL2-ApoA-I was consistently more reactive (2- to 5-fold) in the 125I-CNBr I than in the 125I-CNBr II assays. The findings suggest (a) that the two terminal regions of ApoA-I are immunologically distinct, (b) that the two regions can be assayed independently of each other in intact HDL2, and (c) that the COOH-terminal region is more reactive immunologically than is the NH2-terminal. The results are compatible with a more "exposed" position for the COOH-terminal region on the surface of HDL2.     

The conformation of apolipoprotein A-I in high-density lipoproteins is influenced by core lipid composition and particle size: a surface plasmon resonance study

Plasma high-density lipoproteins (HDL) are a heterogeneous group of particles that vary in size as well as lipid and apoprotein composition. The effect of HDL core lipid composition and particle size on apolipoprotein (apo) A-I structure was studied using surface plasmon resonance (SPR) analysis of the binding of epitope-defined monoclonal antibodies. The association and dissociation rate constants of 12 unique apo A-I-specific monoclonal antibodies for isolated plasma HDL were calculated. In addition, the association rate constants of the antibodies were determined for homogeneous preparations of spherical reconstituted HDL (rHDL) that contained apo A-I as the sole apolipoprotein and differed either in their size or in their core lipid composition. This analysis showed that lipoprotein size affected the conformation of domains dispersed throughout the apo A-I molecule, but the conformation of the central domain between residues 121 and 165 was most consistently modified. In contrast, replacement of core cholesteryl esters with triglyceride in small HDL modified almost the entire molecule, with only two key N-terminal domains of apo A-I being unaffected. This finding suggested that the central and C-terminal domains of apo A-I are in direct contact with rHDL core lipids. This immunochemical analysis has provided valuable insight into how core lipid composition and particle size affect the structure of specific domains of apo A-I on HDL.     

Quantitation of plasma apolipoprotein A-I using two monoclonal antibodies in an enzyme-linked immunosorbent assay

A rapid sandwich enzyme-linked immunosorbent assay (ELISA) for the quantitation of human apolipoprotein (apo) A-I was developed. The assay uses a pair of noncompeting purified monoclonal antibodies to detect apoA-I in plasma. The antibodies used in this assay were selected because they bind greater than 90% of radioiodinated high density lipoprotein (HDL), they identify "fresh" nondeamidated epitopes on apoA-I, and they have comparable binding affinities for isolated HDL and HDL in plasma. The assay was standardized with a plasma secondary standard composed of lyophilized human serum. The assay was used to measure the apoA-I levels in normal subjects, patients with coronary artery disease, and patients with familial hypercholesterolemia. The results indicate that certain monoclonal antibodies can be used to reliably measure plasma levels of apoA-I in diverse groups of subjects.     

Expression of human apolipoprotein A-I epitopes in high density lipoproteins and in serum

The expression and immunoreactivity of apolipoprotein (apo) A-I epitopes in high density lipoproteins (HDL) and serum has been investigated using two series of monoclonal antibodies (Mabs) which have been described elsewhere. Series 1 Mabs, identified as 3D4, 6B8, and 5G6, were obtained by immunization and screening with apoA-I, and series 2 Mabs, identified as 2F1, 4H1, 3G10, 4F7, and 5F6, were obtained by immunization and screening with HDL. These Mabs were characterized with respect to their binding to HDL particles in solution. In series 2 Mabs, 2F1, 3G10, and 4F7, which react with apoA-I CNBr-fragments 1 and 2, could precipitate 100% of 125I-labeled HDL, while 4H1 and 5F6, which react with CNBr fragments 1 and 3, precipitated 90 and 60% of 125I-labeled HDL, respectively. Therefore, three distinct epitopes mapped to CNBr fragments 1 and 2 have been identified which are expressed on all HDL particles, indicating that several antigenic do mains exist on apoA-I which have the same conformation on all apoA-I-containing lipoproteins. The Mabs reacting at these sites have significantly higher affinity constants for 125I-labeled HDL than those that failed to precipitate 100% of HDL. This suggests that the high affinity Mabs react with apoA-I epitopes that are both expressed on all lipoproteins and located in thermo-dynamically stable regions of the molecules. All Mabs from series 1 precipitated 35% or less of 125I-labeled HDL prepared from freshly collected serum, but the proportion of HDL particles expressing the epitopes for these Mabs doubled or more upon serum storage at 4 degrees C. The time course of the alteration of apoA-I antigen in vitro was measured in three normolipemic donors. Upon storage of serum at 4 degrees C, the immunoreactivity of series 2 Mabs (4H1, 3G10) remained unchanged. However, the immunoreactivity of series 1 Mab 3D4 increased linearly at 38%/day for 4 weeks and by 12 weeks had plateaued at about 280-fold compared to day 1. The immunoreactivity of other series 1 Mabs also increased significantly with time in vitro. This process was partially inhibited in the presence of EDTA and by addition of antioxidants, however, the exact molecular nature of this in vitro alteration of apoA-I antigen was not identified.     

Immunochemical heterogeneity of human plasma high density lipoproteins. Identification with apolipoprotein A-I- and A-II-specific monoclonal antibodies

Three mouse monoclonal antibodies specific for human apolipoprotein (apo) A-I and one specific for human apo-A-II were characterized with respect to their binding of high density lipoprotein (HDL) particles in solution. The apo-A-II-specific antibody bound 85% of 125I-HDL and 100% of soluble 125I-apo-A-II. However, none of the apo-A-I-specific antibodies bound greater than 60% of either HDL or soluble apo-A-I. Technical issues such as limiting amounts of antibody or antigen, radioiodination of the ligands, unavailability of the epitopes for reaction with antibody, selective binding of apo-A-I isoforms, and individual allotypic differences in apo-A-I were not responsible for the observed incomplete binding of all HDL and apo-A-I. The results suggested the existence of intrinsic immunochemical heterogeneity of apo-A-I both as organized on HDL as well as in free apo-A-I in solution. The validity of this observed heterogeneity was supported by demonstrating that (i) increased binding of HDL occurred when each of the apo-A-I antibodies was combined to form an oligoclonal antibody mixture, and (ii) 100% binding of HDL occurred when two apo-A-I antibodies were combined with the single apo-A-II antibody. To understand the basis for the heterogeneity of expression of apo-A-I epitopes on HDL, two hypotheses were examined. The first hypothesis that these apo-A-I antibodies distinguished apo-A-I molecules from different synthetic sources was not substantiated. Two of the antibodies bound epitopes on apo-A-I molecules in both thoracic duct lymph as an enriched source of intestinal HDL and the culture supernatants of the hepatic cell line Hep G2 as a source of hepatic HDL. The second hypothesis that the antibodies identified differences in the expression of apo-A-I on HDL subpopulations that were distinguished on the basis of size or net particle charge, i.e. organizational heterogeneity, appeared to provide the best available explanation for the immunochemical heterogeneity of apo-A-I in HDL. Relative differences in the expression of three distinct apo-A-I epitopes were demonstrated in HDL subpopulations obtained by either density gradient ultracentrifugation or chromatofocusing. In light of these studies, we conclude that there is intrinsic heterogeneity in the expression of intramolecular loci representing the apo-A-I epitopes identified by our monoclonal antibodies. Such heterogeneity must be considered in analysis of the biology and physiology of apo-A-I and lipoprotein particles bearing this chain.     

Localization of two epitopes of apolipoprotein A-I that are exposed on human high density lipoproteins using monoclonal antibodies and synthetic peptides

To understand the structure of apolipoprotein A-I, we have used an immunochemical approach and identified specific regions of apoA-I that may be exposed on the apoprotein as it exists on high density lipoprotein (HDL). Twelve mouse monoclonal antibodies specific for human apoA-I were generated from six fusions. Thirteen synthetic peptides of between 5 and 16 amino acid residues in length, which span the amino-terminal two-thirds of apoA-I, were tested for their ability to react with each of the 12 antibodies. In a competitive solid-phase radioimmunoassay, a synthetic peptide, which represented residues 1-15 of mature apoA-I, inhibited the binding of antibody AI-16 to immobilized HDL. Similarly, a synthetic peptide, which represented residues 90-105 of apoA-I, inhibited the binding of antibody AI-18 to immobilized HDL. Using systematic changes in the size and sequence of the oligopeptides, the limits and essential amino acid residues of these epitopes were defined. Comparisons of the slopes of the competition curves obtained with immunoreactive peptides, isolated apoA-I, and HDL verified that these two regions of apoA-I are exposed on the surface of apoA-I as it exists on native HDL.     

Monoclonal antibodies to plasma high density lipoprotein (HDL) of eel (Anguilla japonica)

Six week-old female mice (Balb/c) injected intraperitonealy with 50 μg of eel high density lipoprotein (HDL) emulsified with equal volume of adjuvant three times every two weeks. Three weeks after the third injection, hyperimmunized mice were boosted by injection of 100 μg of HDL. After 5 days, the best responding mouse to injected HDL was sacrificed, and spleen cells were fused with mouse myeloma cells (Sp2/O–Ag14), and hybridomas were cultured in a selection medium. Monoclonal antibodies specific to apolipoprotein A-I or A-II (apoA-I or apoA-II) of HDL were obtained by cloning and recloning the hybridomas. Eighteen monoclonal antibodies specific to apoA-I and/or apoApII were isolated. Antibodies in the culture medium were purified by a HiTrap Protein G or an eel-HDL column. These purified antibodies belong to the subclass IgG1. The monoclonal antibodies specific to eel apoA-I and apoA-II secreted by clone 10D12 and 2G3, respectively, interact with serum proteins of some fish species such as red-sea bream and carp. The anti-eel apoA-I antibody of 10D12 did not bind to serum proteins of rat, rabbit, and chicken, while the anti-eel apoA-II of 2G3 antibody did.     

Expression of a monoclonal antibody-defined aminoterminal epitope of human apoC-I on native and reconstituted lipoproteins

Nine distinct mouse monoclonal antibodies were produced in two fusions using holo-human very low density lipoprotein (VLDL) as antigen. On immunoblotting first with human VLDL and then with isolated human apoC-I, seven of the antibodies, representing three isotypes, manifested specificity for apoC-I. Two antibodies were directed against apoB. To assess whether the seven anti-apoC-I antibodies were directed against the same or distinctively different epitopes, cross-competition assays were performed wherein 125I-labeled monoclonal antibodies were made to compete with unlabeled antibodies for occupancy on immobilized VLDL-associated apoC-I. All antibodies cross-competed to varying extents implying that they were directed against closely spaced epitopes, but based on these experiments three different epitopes were defined. On immunoblotting with CNBr fragments, all of the epitopes were assigned to the CNBr I fragment of human apoC-I (amino acids 1-38) suggesting that the NH2-terminal region of apoC-I is more immunogenic in mice than other parts of the molecule when apoC-I is associated with VLDL. A competitive solid-phase radioimmunoassay (RIA) was developed employing one of the anti-apoC-I antibodies (A3-4). VLDL was adsorbed to plastic microtiter wells, and a limiting amount of the antibody was reacted with the adsorbed VLDL. The amount of monoclonal antibody that bound to the immobilized VLDL-apoC-I was determined with a 125I-labeled goat anti-mouse IgG antibody. The addition of competitor apoC-I complexed with lipids resulted in reduced binding of the anti-apoC-I antibody to the immobilized VLDL-apoC-I. Competitor complexes consisted of an artificial lipid emulsion (Intralipid) incubated with apoC-I at phospholipid/apoC-I ratios of 1:1 to 60:1 (w/w). As the lipid/protein ratios were increased, the competitive displacement curves produced by the complexes become progressively steeper, while isolated lipid-free apoC-I produced curves with very shallow slopes, suggesting that a conformation-dependent epitope was being probed. Other apoproteins (C-II, C-III, A-I, A-II, and E) whether lipid-free or complexed with lipids did not compete. Fractionation of the 30:1 apoC-I-Intralipid complex by gel permeation chromatography suggested that apoC-I bound to phospholipids was the most effective competitor. This was confirmed by testing of apoC-I-DMPC complexes, which yielded curves that paralleled those produced by apoC-I-Intralipid.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies on the proteins involved in the interaction of high-density lipoprotein with isolated human small intestine epithelial cells.

Treatment of 125I-labelled high-density lipoprotein ([125I]HDL3) with monospecific polyclonal antibodies against apolipoproteins A-I and A-II resulted in a dose-dependent inhibition of the [125I]HDL3 binding to isolated human small intestine epithelial cells by 25% and 50%, respectively. Both antibodies also inhibited intracellular degradation of [125I]HDL3 by 80%. Treatment of enterocytes with polyclonal antibody against apolipoprotein A-I binding protein, a putative HDL receptor, inhibited both binding and degradation of [125I]HDL3 by these cells by 50%. Antibodies to apolipoprotein A-I, A-II and apo A-I-binding protein also inhibited [125I]HDL3 binding to cholesterol-loaded cells.     

Monoclonal antibodies specific for different regions of human apolipoprotein A-I. Characterization of an antibody that does not bind to a genetic variant of apoA-I (Glu----136 Lys)

Three monoclonal mouse hybridoma antibodies, designated 2AI, 4AI, and 5AI, specific for human plasma apolipoprotein A-I (apoA-I) were characterized. In an enzyme-linked immunosorbent assay (ELISA) each of the antibodies reacted with purified apoA-I and with A-I in normal human serum. Immunoblotting of apoA-I subjected to isoelectric focusing revealed that the three antibodies reacted with all the charge isomorphs of apoA-I and with proapoA-I. Using a solid phase competitive displacement assay, the antigenic determinant for antibody 5AI could be localized to cyanogen bromide fragment 3 of apoA-I (residues 113-148), while the epitope for antibody 4AI resided in cyanogen bromide fragment 4. Dot blot experiments and data obtained by the competitive displacement assay revealed that antibody 2AI reacts with high affinity with CNBr fragment 2 but that it also reacts with lower affinity with fragments 1 and 4. The antibody 5AI did not bind to a genetic variant of apoA-I (Glu----136 Lys), demonstrating that the substitution of a single amino acid in human apoA-I can cause the loss of an antigenic determinant.     

Epitope mapping of apolipoprotein A-I using endoproteinase cleavage and monoclonal antibodies in an enzyme-linked immunosorbent assay.

The epitopes for two monoclonal antibodies (MAbs) directed towards human apolipoprotein A-I (apoA-I), designated AI-1 and AI-3, have been more precisely defined. Previous work in our laboratory demonstrated that AI-1 and AI-3 recognize antigenic determinants located within cyanogen bromide (CNBr) fragments 1 (CF1) and 3 (CF3), respectively. Using peptides generated from endoproteinase cleavage of CF1 and CF3, we now report that both MAbs are specific for two previously unreported epitopes along the apoA-I molecule. The ability of whole endoproteinase digest mixtures to bind the MAbs, as determined by means of a competitive enzyme-linked immunosorbent assay (ELISA), indicated regions of CF1 and CF3 that were likely to form the epitopes. Purified peptides derived from the digests were then used to localize the epitopes recognized by MAbs AI-1 and AI-3 to within residues 28-47 and 140-147 of apoA-I, respectively. We have previously reported that the epitopes for both MAbs are exposed on HDL2, HDL3, and free apoA-I. Thus, the precise mapping of the binding sites recognized by AI-1 and AI-3 has enabled the identification of regions along apoA-I that are exposed on the surface of lipoprotein particles.     

Quantitative determination of apolipoprotein A-I in high-density lipoproteins and 'free' apolipoprotein A-I by two-dimensional agarose gel lipoprotein-'rocket' immunoelectrophoresis of human serum

A method has been developed for quantitative analysis of 'free' apolipoprotein A-I and apolipoprotein A-I associated with high-density lipoprotein (HDL) in serum. The method utilizes the difference between the rate of electrophoretic migration of apolipoprotein A-I associated with HDL (alpha) and 'free' apolipoprotein A-I (pre-beta) in agarose gel. Apolipoprotein A-I is subsequently quantitated by electrophoresis in a second dimensional gel containing anti-apolipoprotein A-I antibodies. Using this method all apolipoprotein A-I of normal fasting serum was found associated with HDL (n = 16). By contrast, 'free' apolipoprotein A-I accounted for up to 12% of the total in the serum of patients with isolated hypertriglyceridemia (n = 8) or mixed hyperlipoproteinemia (n = 8). Between 30 and 35% of 'free' apolipoprotein A-I was found in one patient afflicted with the apolipoprotein C-II deficiency syndrome. Also, 'free' apolipoprotein A-I could be detected in normal postabsorptive serum. 30 and 90 min following heparin-enhanced lipolysis 'free' apolipoprotein A-I accounted for 23 and 20%, respectively, of the total apolipoprotein A-I of serum. Apolipoprotein A-I associated with HDL remained unaltered. It appears, therefore, that 'free' apolipoprotein A-I is liberated from triglyceride-rich lipoproteins during lipolysis.     

Mapping of three carbohydrate attachment sites in embryonic and adult forms of the neural cell adhesion molecule

The sialic-rich carbohydrate moiety of the neural cell adhesion molecule (N-CAM) undergoes major structural changes during development and plays a significant role in altering the homophilic binding of the molecule. In order to understand the mechanism of these changes, a cyanogen bromide (CNBr) fragment that contained 90% of the sialic acid of N-CAM was isolated and characterized according to the number of carbohydrate attachment sites and reactivity with specific monoclonal antibodies. The CNBr sialopeptide migrated on SDS PAGE as a broad zone of Mr 42,000-60,000. Upon treatment with neuraminidase, it was converted to a single component of Mr 42,000, and subsequent, limited treatment with endoglycosidase F gave four evenly spaced components of Mr 35,000-42,000, suggesting that it contained three attachment sites for N-linked oligosaccharides. The fragment reacted with monoclonal antibody 15G8, which detects the sialic acid in embryonic N-CAM, and with a monoclonal antibody, anti-(N-CAM) No. 2. Treatment with neuraminidase or with endoglycosidase F destroyed reactivity with 15G8 but not with anti-(N-CAM) No. 2. A similar CNBr sialopeptide was obtained from adult N-CAM; it contained sialic acid, had three N-linked oligosaccharides and reacted with anti-(N-CAM) No. 2 but not with 15G8 monoclonal antibodies. A peptide fragment, Fr2, comprising the NH2 terminal and middle regions of the molecule yielded a CNBr fragment closely similar to the fragment obtained from the whole molecule. The CNBr fragment from Fr2 reacted with monoclonal antibody anti-(N-CAM) No. 2. Fr1, comprising the NH2 terminal region alone, failed to react. These data confirm that the majority of the sialic acid is localized in the middle region of the N-CAM molecule and support the hypothesis that embryonic to adult conversion of N-CAM is the result of differences in sialidase or sialytransferase activity.     

Epitope mapping of Escherichia coli cell division protein FtsZ with monoclonal antibodies.

A fusion between lacZ and ftsZ of Escherichia coli was constructed to obtain a beta-galactosidase-FtsZ fusion protein. This fusion protein was used to raise antibodies against cell division protein FtsZ. Six monoclonal antibodies were obtained, and they reacted with FtsZ from cytoplasm and membrane fractions. The epitopes in FtsZ were localized by studying the reactions of the monoclonal antibodies with fusion proteins truncated at the carboxy terminus and with fragments that were obtained by CNBr cleavage of purified FtsZ. Five different epitopes were defined. Epitopes I and III reacted with the same monoclonal antibody, without showing apparent amino acid homology. Epitope II was defined by monoclonal antibodies that cross-reacted with an unknown cytoplasmic 50-kDa protein not related to FtsZ. Epitopes IV and V were recognized by different monoclonal antibodies. All monoclonal antibodies reacted strongly under native conditions, so it is likely that the five epitopes are situated on the surface of native FtsZ. By using these data and computer analysis, a provisional model of FtsZ is proposed. The FtsZ protein is considered to be globular, with a hydrophobic pocket containing GTP-binding elements. Epitopes I and II are situated on each side of the hydrophobic pocket. Because the carboxy terminus contains epitope V, the carboxy terminus of FtsZ is likely oriented toward the protein's surface.     

Mapping of monoclonal antibody epitopes in the nucleolar protein fibrillarin (B-36) of Physarum polycephalum.

We have mapped the epitopes for nine monoclonal antibodies raised against the nucleolar protein fibrillarin of the slime mold Physarum polycephalum. This has been done using a combination of specific chemical and enzymatic cleavage, Western blotting and partial sequencing of fragments. Cleavage with cyanogen bromide reveals four prominent methionine cleavage sites within the protein. Western blotting shows that none of the monoclonal antibody epitopes are dependent on long range interactions. Eight highly-conserved epitopes are clustered in the carboxy terminal half of the protein, while a single less-conserved epitope (for monoclonal antibody P1G12) is located at the amino terminus and appears to lie within the Gly/DMA/Phe domain.     

Apolipoprotein A-II inhibits high density lipoprotein remodeling and lipid-poor apolipoprotein A-I formation

The high density lipoproteins (HDL) in human plasma are classified on the basis of apolipoprotein composition into those containing apolipoprotein (apo) A-I but not apoA-II, (A-I)HDL, and those containing both apoA-I and apoA-II, (A-I/A-II)HDL. Cholesteryl ester transfer protein (CETP) transfers core lipids between HDL and other lipoproteins. It also remodels (A-I)HDL into large and small particles in a process that generates lipid-poor, pre-beta-migrating apoA-I. Lipid-poor apoA-I is the initial acceptor of cellular cholesterol and phospholipids in reverse cholesterol transport. The aim of this study is to determine whether lipid-poor apoA-I is also formed when (A-I/A-II)rHDL are remodeled by CETP. Spherical reconstituted HDL that were identical in size had comparable lipid/apolipoprotein ratios and either contained apoA-I only, (A-I)rHDL, or (A-I/A-II)rHDL were incubated for 0-24 h with CETP and Intralipid(R). At 6 h, the apoA-I content of the (A-I)rHDL had decreased by 25% and there was a concomitant formation of lipid-poor apoA-I. By 24 h, all of the (A-I)rHDL were remodeled into large and small particles. CETP remodeled approximately 32% (A-I/A-II)rHDL into small but not large particles. Lipid-poor apoA-I did not dissociate from the (A-I/A-II)rHDL. The reasons for these differences were investigated. The binding of monoclonal antibodies to three epitopes in the C-terminal domain of apoA-I was decreased in (A-I/A-II)rHDL compared with (A-I)rHDL. When the (A-I/A-II)rHDL were incubated with Gdn-HCl at pH 8.0, the apoA-I unfolded by 15% compared with 100% for the apoA-I in (A-I)rHDL. When these incubations were repeated at pH 4.0 and 2.0, the apoA-I in the (A-I)rHDL and the (A-I/A-II)rHDL unfolded completely. These results are consistent with salt bridges between apoA-II and the C-terminal domain of apoA-I, enhancing the stability of apoA-I in (A-I/A-II)rHDL and possibly contributing to the reduced remodeling and absence of lipid poor apoA-I in the (A-I/A-II)rHDL incubations.