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.     

Grid-immunoblotting: a fast and simple technique to test multiple allergens with small amounts of antibody for cross-reactivity

Grid-immunoblotting is a procedure that allows the simultaneous testing of up to 20 different antibodies such as monoclonal antibody-containing hybridoma supernatants or human sera for specific antibodies to up to 20 different antigens or allergens on a single sheet of nitrocellulose membrane. Since only 150 to 200 μl of antibody-containing solution are required this technique is uniquely suited to test growing hybridomas and small amounts of sera (e.g. mouse and children’s sera). Compared to a standard ELISA, approximately ten times less antibody is needed to obtain the same information.     

Antibodies to the carboxyl terminus of human apolipoprotein A-I. The putative cellular binding domain of high density lipoprotein 3 and carboxyl-terminal structural homology between apolipoproteins A-I and A-II.

We have studied the binding of 125I-labeled high density lipoproteins (HDL3) to liver plasma membranes, which are thought to contain specific HDL receptor sites, using anti-peptide antibodies directed against two sites in the carboxyl-terminal region of human apoA-I. Two distinct antibody populations raised to peptides corresponding to amino acid residues 205-220 and 230-243, respectively, recognized regions of apoA-I that are exposed in the lipid environment of HDL3. However, anti-AI[230-243] IgG, but not anti-AI[205-220] IgG, recognized HDL2, suggesting that residues 205-220 of apoA-I are expressed differently in the two HDL populations. In addition, anti-AI[230-243] IgG showed strong cross-reactivity toward apoA-II. Epitope mapping studies showed that anti-AI[230-243] binds to an epitope located in the carboxyl-terminus of apoA-II, demonstrating significant structural homology between the carboxyl-terminal of apoA-II, demonstrating significant structural homology between the carboxyl-terminal regions of apoA-I and A-II, two candidate proteins for mediating the specific cellular interaction of HDL3. Fab fragments from anti-AI[205-220] and anti-AI[230-243] inhibited the binding of 125I-HDL3 to liver plasma membranes by approximately 80% and 60%, respectively. These findings are in agreement with our recent work using isolated CNBr fragments of apoA-I (Morrison, J., Fidge, N. H., and Tozuka, M. (1991) J. Biol. Chem. 266, 18780-18785), which suggest that the carboxyl-terminal region of apoA-I contains a binding domain which mediates the specific interaction of HDL3 with liver plasma membranes, possibly through the involvement of specific HDL receptors.     

A Rapid Method to Characterize Mouse IgG Antibodies and Isolate Native Antigen Binding IgG B Cell Hybridomas

B cell hybridomas are an important source of monoclonal antibodies. In this paper, we developed a high-throughput method to characterize mouse IgG antibodies using surface plasmon resonance technology. This assay rapidly determines their sub-isotypes, whether they bind native antigen and their approximate affinities for the antigen using only 50 μl of hybridoma cell culture supernatant. Moreover, we found that mouse hybridomas secreting IgG antibodies also have membrane form IgG expression without Igα. Based on this surface IgG, we used flow cytometry to isolate rare γ2a isotype switched variants from a γ2b antibody secreting hybridoma cell line. Also, we used fluorescent antigen to single cell sort antigen binding hybridoma cells from bulk mixture of fused hybridoma cells instead of the traditional multi-microwell plate screening and limiting dilution sub-cloning thus saving time and labor. The IgG monoclonal antibodies specific for the native antigen identified with these methods are suitable for in vivo therapeutic uses, but also for sandwich ELISA assays, histology, flow cytometry, immune precipitation and x-ray crystallography.     

In vivo metabolism of apolipoprotein A-I on high density lipoprotein particles LpA-I and LpA-I,A-II.

Apolipoprotein (apo) A-I is the major protein in high density lipoproteins (HDL) and is found in two major subclasses of lipoproteins, those containing apolipoprotein A-II (termed LpA-I,A-II) and those without apoA-II (termed LpA-I). The in vivo kinetics of apoA-I on LpA-I and LpA-I,A-II were investigated in normolipidemic human subjects. In the first series of studies, radiolabeled apoA-I and apoA-II were reassociated with autologous plasma lipoproteins and injected into normal subjects. LpA-I and LpA-I,A-II were isolated from plasma at selected time points by immunoaffinity chromatography. By 24 h after injection, only 52.8 +/- 1.0% of the apoA-I in LpA-I remained, whereas 66.9 +/- 2.7% of apoA-I in LpA-I,A-II remained (P less than 0.01). In the second series of studies, purified apoA-I was labeled with either 131I or 125I and reassociated with autologous plasma. Isolated LpA-I and LpA-I,A-II particles differentially labeled with 131I-labeled apoA-I and 125I-labeled apoA-I, respectively, were simultaneously injected into study subjects. The plasma residence time of apoA-I injected on LpA-I (mean 4.39 days) was substantially shorter than that of apoA-I injected on LpA-I,A-II (mean 5.17 days), with a mean difference in residence times of 0.79 +/- 0.08 days (P less than 0.001). These data demonstrate that apoA-I injected on LpA-I is catabolized more rapidly than apoA-I injected on LpA-I,A-II. The results are consistent with the concept that LpA-I and LpA-I,A-II have divergent metabolic pathways.     

Formation of high density lipoproteins containing both apolipoprotein A-I and A-II in the rabbit

Human plasma HDLs are classified on the basis of apolipoprotein composition into those that contain apolipoprotein A-I (apoA-I) without apoA-II [(A-I)HDL] and those containing apoA-I and apoA-II [(A-I/A-II)HDL]. ApoA-I enters the plasma as a component of discoidal particles, which are remodeled into spherical (A-I)HDL by LCAT. ApoA-II is secreted into the plasma either in the lipid-free form or as a component of discoidal high density lipoproteins containing apoA-II without apoA-I [(A-II)HDL]. As discoidal (A-II)HDL are poor substrates for LCAT, they are not converted into spherical (A-II)HDL. This study investigates the fate of apoA-II when it enters the plasma. Lipid-free apoA-II and apoA-II-containing discoidal reconstituted HDL [(A-II)rHDL] were injected intravenously into New Zealand White rabbits, a species that is deficient in apoA-II. In both cases, the apoA-II was rapidly and quantitatively incorporated into spherical (A-I)HDL to form spherical (A-I/A-II)HDL. These particles were comparable in size and composition to the (A-I/A-II)HDL in human plasma. Injection of lipid-free apoA-II and discoidal (A-II)rHDL was also accompanied by triglyceride enrichment of the endogenous (A-I)HDL and VLDL as well as the newly formed (A-I/A-II)HDL. We conclude that, irrespective of the form in which apoA-II enters the plasma, it is rapidly incorporated into spherical HDLs that also contain apoA-I to form (A-I/A-II)HDL.     

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.     

Coupling of photoactivatable glycolipid probes to apolipoproteins A-I and A-II in human high density lipoproteins 2 and 3

High density lipoprotein (HDL) from human serum was subfractionated into HDL2 and HDL3 by rate-zonal density gradient ultracentrifugation. The orientation of apoproteins (apo) A-I and A-II in these subfractions was investigated by use of the photosensitive glycolipid probes, 2-(4-azido-2-nitrophenoxy)-palmitoyl[1-14C]glucosamine (compound A) and 12-(4-azido-2-nitrophenoxy)-stearoyl[1-14C]glucosamine (compound B). Both probes were added to the HDL-structures in a ratio of two or three probe molecules per particle and were photoactivated by irradiation at a wavelength above 340 nm. After delipidation the probe-apoprotein adducts were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both the "shallow" probe (compound A) and the "depth" probe (compound B) were coupled for 10-14% (of the label added) to apoA-I and apoA-II from HDL3 and for about 6% to apoA-I and apoA-II from HDL2. By taking into account the relative amounts of apoA-I and apoA-II, it was estimated that the "shallow" probe labeled apoA-I 40% more effectively than apoA-II in both HDL2 and HDL3; the "depth" probe labeled apoA-I and apoA-II equally well in both subfractions. The data suggest that towards the surface HDL2 and HDL3 contain a relatively larger portion of apoA-I than apoA-II, whilst towards the core both subfractions are occupied by an equal portion of apoA-I and apoA-II. Application of these photolabels has failed to point out differences in the structural organization of HDL2 and HDL3.     

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.     

Role of apoA-II in lipid metabolism and atherosclerosis: advances in the study of an enigmatic protein.

Our understanding of apolipoprotein A-II (apoA-II) physiology is much more limited than that of apoA-I. However, important and rather surprising advances have been produced, mainly through analysis of genetically modified mice. These results reveal a positive association of apoA-II with FFA and VLDL triglyceride plasma concentrations; however, whether this is due to increased VLDL synthesis or to decreased VLDL catabolism remains a matter of controversy. As apoA-II-deficient mice present a phenotype of insulin hypersensitivity, a function of apoA-II in regulating FFA metabolism seems likely. Studies of human beings have shown the apoA-II locus to be a determinant of FFA plasma levels, and several genome-wide searches of different populations with type 2 diabetes have found linkage to an apoA-II intragenic marker, making apoA-II an attractive candidate gene for this disease. The increased concentration of apoB-containing lipoproteins present in apoA-II transgenic mice explains, in part, why these animals present increased atherosclerosis susceptibility. In addition, apoA-II transgenic mice also present impairment of two major HDL antiatherogenic functions: reverse cholesterol transport and protection of LDL oxidative modification. The apoA-II locus has also been suggested as an important genetic determinant of HDL cholesterol concentration, even though there is a major species-specific difference between the effects of mouse and human apoA-II. As antagonizing apoA-I antiatherogenic actions can hardly be considered the apoA-II function in HDL, this remains a topic for future investigations. We suggest that the existence of apoA-II or apoA-I in HDL could be an important signal for specific interaction with HDL receptors such as cubilin or heat shock protein 60.     

A sensitive and specific ELISA detects methionine sulfoxide-containing apolipoprotein A-I in HDL

Oxidized HDL has been proposed to play a key role in atherogenesis. A wide range of reactive intermediates oxidizes methionine residues to methionine sulfoxide (MetO) in apolipoprotein A-I (apoA-I), the major HDL protein. These reactive species include those produced by myeloperoxidase, an enzyme implicated in atherogenesis. The aim of the present study was to develop a sensitive and specific ELISA for detecting MetO residues in HDL. We therefore immunized mice with HPLC-purified human apoA-I containing MetO(86) and MetO(112) (termed apoA-I(+32)) to generate a monoclonal antibody termed MOA-I. An ELISA using MOA-I detected lipid-free apoA-I(+32), apoA-I modified by 2e-oxidants (hydrogen peroxide, hypochlorous acid, peroxynitrite), and HDL oxidized by 1e- or 2e-oxidants and present in buffer or human plasma. Detection was concentration dependent, reproducible, and exhibited a linear response over a physiologically plausible range of concentrations of oxidized HDL. In contrast, MOA-I failed to recognize native apoA-I, native apoA-II, apoA-I modified by hydroxyl radical or metal ions, or LDL and methionine-containing proteins other than apoA-I modified by 2e-oxidants. Because the ELISA we have developed specifically detects apoA-I containing MetO in HDL and plasma, it should provide a useful tool for investigating the relationship between oxidized HDL and coronary artery disease.     

Different reactivities of high density lipoprotein2 subfractions with hepatic lipase.

Human high density lipoproteins2 (HDL2) consist of particles that contain both apolipoprotein (apo) A-I and apoA-II (A-I/A-II-HDL2) and others that contain apoA-I but are devoid of apoA-II (A-I-HDL2). When postprandial lipemia is pronounced, a fraction of HDL2 is converted into HDL2-like particles. These HDL3 exhibit lower apoA-I/apoA-II ratios than the parent HDL2, suggesting preferential conversion of A-I/A-II-HDL2 into HDL3 (J. Clin. Invest. 1984. 74: 2017-2023). Triglyceride transfer from triglyceride-rich lipoproteins to HDL2 and subsequent lipolysis by hepatic lipase are thought to mediate the conversion of HDL2 into HDL3. To understand why A-I/A-II-HDL2 are preferentially converted into HDL3, we separated postprandial HDL2 into A-I-HDL2 and A-I/A-II-HDL2 species by immunoaffinity chromatography using a monoclonal antibody for apoA-II, and determined the ability of HDL2 species i) to participate in protein-mediated lipid transfer; and ii) to interact with hepatic lipase in vitro. Triglyceride transfer from/to triglyceride-rich lipoproteins was similar for the two HDL2 species. In contrast, A-I/A-II-HDL2 were twice as effective as A-I-HDL2 in liberating hepatic lipase immobilized on HDL3-Sepharose. Lipolysis of triglycerides by hepatic lipase was 60% higher in postprandial A-I/A-II-HDL2 than in postprandial A-I-HDL2. Hydrolysis of phosphatidylcholine by hepatic lipase was threefold higher in A-II-containing HDL2 when compared with HDL2 devoid of apoA-II. The different lipolytic rates in HDL2 subspecies correlated with the size reduction of substrate lipoproteins. Reconstitution of postprandial A-I-HDL2 with apoA-II enhanced the rate of lipolysis by hepatic lipase to that observed in A-I/A-II-HDL2. We conclude that it is the interaction with hepatic lipase rather than the rate of triglyceride transfer that results in the preferred conversion of postprandial A-II-containing HDL2 into HDL3, and that apoA-II exerts a crucial role in this process.     

Comparison of the cytolytic effects in vitro on Trypanosoma brucei brucei of plasma, high density lipoproteins, and apolipoprotein A-I from hosts both susceptible (cattle and sheep) and resistant (human and baboon) to infection.

The African trypanosome, Trypanosoma brucei brucei causes a fatal wasting disease in livestock but does not ordinarily infect humans, apparently because this unicellular parasite is lysed by high density lipoproteins (HDL) in human serum. To assess whether there is a specific active constituent in trypanolytic HDL, we have systematically compared the cytotoxic action on T.b.brucei in vitro of native and delipidated HDL, and of individual apolipoproteins, from nonpermissive hosts (human and baboon) with their counterparts from susceptible hosts (cattle and sheep). When suspensions of trypanosomes were incubated for 2 h at 37 degrees C with human or baboon plasma most cells were lysed, but not with bovine or sheep plasma. Similarly, HDL isolated from human and baboon plasma were trypanolytic (typically about 95% and 60% lysis, respectively, at 1 mg protein/ml), whereas bovine and sheep HDL were benign (less than 8% lysis). Subfractionation of human HDL by serial isopycnic ultracentrifugation and by heparin-Sepharose affinity chromatography established that the denser and smaller particles had greater trypanolytic activity both in vitro and in vivo. When human HDL was delipidated, the trypanocidal activity was associated with the water-soluble protein (apolipoprotein) fraction and not with the lipid constituents. Bovine apolipoproteins were also weakly trypanolytic in free solution (20-40% lysis), but not when complexed with cholesterol-phospholipid liposomes (less than 10% lysis). The major apolipoprotein of human HDL, apolipoprotein (apo) A-I had full trypanolytic activity (89-95% lysis at 1 mg protein/ml) when purified, whether in solution or incorporated into liposomes, but other apolipoproteins isolated from human HDL, including apoA-II, apoC, and apoE, were nontrypanolytic. Purified baboon apoA-I was also trypanolytic, though less potent than human apoA-I, but apoA-I from permissive hosts (cattle and sheep) was inactive when presented in liposomes. Incubation of bovine or sheep HDL with purified human apoA-I, and subsequent separation of the HDL by ultracentrifugation, produced chimeric HDL containing significant amounts of the human apolipoprotein; these particles showed appreciable trypanolytic activity. By contrast, human HDL particles in which about 70% of the apoA-I had been displaced with apoA-II had markedly reduced lytic properties compared to the native HDL (30% versus 80% lysis at 0.6 mg total protein/ml). We tentatively conclude that the trypanolytic activity of native human or baboon plasma resides in the apoA-I content of the HDL particles and that, conversely, bovine and sheep plasma are inactive because the apoA-I polypeptide present in their HDL lacks trypanocidal activity.     

SR-BI-mediated selective lipid uptake segregates apoA-I and apoA-II catabolism

The HDL receptor scavenger receptor class B type I (SR-BI) binds HDL and mediates the selective uptake of cholesteryl ester. We previously showed that remnants, produced when human HDL(2) is catabolized in mice overexpressing SR-BI, become incrementally smaller, ultimately consisting of small alpha-migrating particles, distinct from pre-beta HDL. When mixed with mouse plasma, some remnant particles rapidly increase in size by associating with HDL without the mediation of cholesteryl ester transfer protein, LCAT, or phospholipid transfer protein. Here, we show that processing of HDL(2) by SR-BI-overexpressing mice resulted in the preferential loss of apolipoprotein A-II (apoA-II). Short-term processing generated two distinct, small alpha-migrating particles. One particle (8.0 nm diameter) contained apoA-I and apoA-II; the other particle (7.7 nm diameter) contained only apoA-I. With extensive SR-BI processing, only the 7.7 nm particle remained. Only the 8.0 nm remnants were able to associate with HDL. Compared with HDL(2), this remnant was more readily taken up by the liver than by the kidney. We conclude that SR-BI-generated HDL remnants consist of particles with or without apoA-II and that only those containing apoA-II associate with HDL in an enzyme-independent manner. Extensive SR-BI processing generates small apoA-II-depleted particles unable to reassociate with HDL and readily taken up by the liver. This represents a pathway by which apoA-I and apoA-II catabolism are segregated.     

A polymorphism affecting apolipoprotein A-II translational efficiency determines high density lipoprotein size and composition

High density lipoproteins (HDL) are heterogeneous particles consisting of about equal amounts of lipid and protein that are thought to mediate the transport of cholesterol from peripheral tissues to liver. We show that a previously identified polymorphism affecting HDL electrophoretic mobility in mice is due to a monogenic variation controlling HDL size and apolipoprotein composition. Thus, the HDL particles of various inbred strains of mice exhibit a striking difference in the ratio fo the two major apolipoproteins of HDL, apoA-I and apoA-II. HDL particles in all strains examined contain an average of about five apoA-I molecules; however, whereas the strains with small HDL contain two to three apoA-II molecules per particle, the strains with large HDL contain about five apoA-II molecules per particle. This increase in the protein content of the large HDL is also accompanied by increased lipid content. The HDL size polymorphism and apoA-II levels cosegregate with the apoA-II structural gene on mouse chromosome 1, indicating that a mutation of the apoA-II gene locus is responsible. The rates of synthesis of apoA-II are increased in the strains with large HDL and high apoA-II levels as compared to the strains with small HDL and low apoA-II levels. On the other hand, the fractional catabolic rates of both apoA-I and apoA-II among the strains are very similar, confirming that apoA-II concentrations are controlled at the level of synthesis. Despite the difference in rates of apoA-II synthesis between strains, the apoA-II mRNA levels in the strains are not discernibly different, suggesting that a mutation of the apoA-II structural gene controls apoA-II translational efficiency. This was confirmed by translating apoA-II mRNA in vitro using a rabbit reticulocyte lysate system. Sequencing of apoA-II cDNA from the strains revealed a number of nucleotide substitutions, which may affect translational efficiency. We conclude that the assembly of apoA-II into HDL does not have a set stoichiometry but, rather, is controlled by the production of apoA-II. As apoA-II levels increase, the HDL particles become larger and acquire more lipid, but apoA-I content per particle remains unchanged. These studies with mice provide a model for the metabolic relationships between apoA-I, apoA-II, and HDL lipid in humans.     

Expression of human apolipoprotein A-II and its effect on high density lipoproteins in transgenic mice.

Apolipoproteins A-I and A-II comprise approximately 70 and 20%, respectively, of the total protein content of HDL. Evidence suggests that apoA-I plays a central role in determining the structure and plasma concentration of HDL, while the role of apoA-II is uncertain. To help define the function of apoA-II and determine what effect increasing its plasma concentration has on HDL, transgenic mice expressing human apoA-II and both human apoA-I and human apoA-II were produced. Human apoA-II mRNA is expressed exclusively in the livers of transgenic animals, and the protein exists as a dimer as it does in humans. High level expression of human apoA-II did not increase HDL concentrations or decrease plasma concentrations of murine apoA-I and apoA-II in contrast to what was observed in mice overexpressing human apoA-I. The primary effect of overexpressing human apoA-II was the appearance of small HDL particles composed exclusively of human apoA-II. HDL from mice transgenic for both human apoA-I and human apoA-II displayed a unique size distribution when compared with either apoA-I or apoA-II transgenic mice and contain particles with both these human apolipoproteins. These results in mice, indicating that human apoA-II participates in determining HDL size, parallel results from human studies.     

Role of apolipoprotein A-II in the structure and remodeling of human high-density lipoprotein (HDL): protein conformational ensemble on HDL

High-density lipoproteins (HDL, or "good cholesterol") are heterogeneous nanoparticles that remove excess cell cholesterol and protect against atherosclerosis. The cardioprotective action of HDL and its major protein, apolipoprotein A-I (apoA-I), is well-established, yet the function of the second major protein, apolipoprotein A-II (apoA-II), is less clear. In this review, we postulate an ensemble of apolipoprotein conformations on various HDL. This ensemble is based on the crystal structure of Δ(185-243)apoA-I determined by Mei and Atkinson combined with the "double-hairpin" conformation of apoA-II(dimer) proposed in the cross-linking studies by Silva's team, and is supported by the wide array of low-resolution structural, biophysical, and biochemical data obtained by many teams over decades. The proposed conformational ensemble helps integrate and improve several existing HDL models, including the "buckle-belt" conformation of apoA-I on the midsize disks and the "trefoil/tetrafoil" arrangement on spherical HDL. This ensemble prompts us to hypothesize that endogenous apoA-II (i) helps confer lipid surface curvature during conversion of nascent discoidal HDL(A-I) and HDL(A-II) containing either apoA-I or apoA-II to mature spherical HDL(A-I/A-II) containing both proteins, and (ii) hinders remodeling of HDL(A-I/A-II) by hindering the expansion of the apoA-I conformation. Also, we report that, although endogenous apoA-II circulates mainly on the midsize spherical HDL(A-I/A-II), exogenous apoA-II can bind to HDL of any size, thereby slightly increasing this size and stabilizing the HDL assembly. This suggests distinctly different effects of the endogenous and exogenous apoA-II on HDL. Taken together, the existing results and models prompt us to postulate a new structural and functional role of apoA-II on human HDL.     

Mechanisms of HDL deficiency in mice overexpressing human apoA-II

To ascertain the mechanisms underlying the hypoalphalipoproteinemia present in mice overexpressing human apolipoprotein A-II (apoA-II) (line 11.1), radiolabeled HDL or apoA-I were injected into mice. Fractional catabolic rate of [(3)H]cholesteryl oleoyl ether HDL ([(3)H]HDL) was 2-fold increased in 11.1 transgenic mice compared with control mice and this was concomitant with increased radioactivity in liver, gonads, and adrenals. However, scavenger receptor class B, type I (SR-BI) was increased only in adrenals. [(3)H]HDL of 11.1 transgenic mice presented greater binding but decreased uptake compared with control mice when Chinese hamster ovary cells transfected with SR-BI were used, thereby pointing to unknown but SR-BI-independent mechanisms as being responsible for the increased (3)H-radioactivity seen in liver and gonads. Synthesis rate (SR) of plasma [(3)H]HDL was 2-fold decreased in 11.1 transgenic mice. Mouse (125)I-apoA-I was 2-fold more rapidly catabolized (mainly by the kidney) in transgenic mice. Mouse apoA-I displacement from HDL by the addition of isolated human apoA-II was reproduced ex vivo; thus, this mechanism may be involved in the increased renal catabolism of apoA-I. ApoA-I SR was 2-fold decreased in 11.1 transgenic mice and this was concomitant with a 2.3-fold decrease in hepatic apoA-I mRNA abundance. Our findings show that multiple mechanisms are involved in the HDL deficiency presented by mice overexpressing human apoA-II.     

The molecular structure of apolipoprotein A-II modulates the capacity of HDL to promote cell cholesterol efflux

The influence of apolipoprotein A-II (apoA-II) molecular structure on the capacity of high density lipoproteins (HDL) to promote cellular cholesterol efflux was investigated in cultured mouse peritoneal macrophages (MPM). Conversion by reduction and carboxamidomethylation of the naturally occurring dimeric apoA-II to its monomeric form in both native or reconstituted HDL did not change apolipoprotein secondary structure and lipoprotein size/composition. All particles containing monomeric apoA-II, i.e., native HDL₃ or reconstituted HDL with or without apoA-I, showed a higher ability to promote cholesterol efflux originating from plasma membrane and intracellular stores, compared to particles containing dimeric apoA-II. These findings indicate that apolipoprotein molecular structure is a major determinant of HDL capacity to promote cholesterol efflux from cells.     

Small HDL particles containing two apoA-I molecules are precursors in vivo to medium and large HDL particles containing three and four apoA-I molecules in nonhuman primates.

We hypothesized that small HDL particles, containing two apoA-I molecules but no apoA-II (LpAI), may be converted in vivo into medium and large HDL particles, containing three or four apoA-I molecules, respectively, and that more conversion will occur in animals with higher HDL concentrations. To test this possibility, kinetic studies of small LpAI were performed in African green monkeys with either high plasma HDL cholesterol concentrations (120 +/- 36 mg/dl, mean +/- SD, n = 3) or low plasma HDL cholesterol concentrations (40 +/- 13 mg/dl, n = 3). Tracer small LpAI was purified, without ultracentrifugation, by immunoaffinity and gel filtration. After injection, the specific activity of apoA-I in small, medium, and large HDL, consisting of both LpAI and LpAI:AII particles, was followed. A multicompartmental model was developed with the simultaneous analysis of urine and plasma turnover data for the kinetics of apoA-I in small, medium, and large HDL. These analyses indicated that small HDL is converted to either medium or large HDL with little or no interconversion of medium HDL and large HDL. Much of the metabolic conversion of small HDL occurs in a sequestered pool, effectively outside the circulating plasma, in a unidirectional manner before reentering the circulating plasma as medium or large HDL. The mean fractional catabolic rate of apoA-I in small, medium, and large HDL was not different comparing the high and low HDL group. In contrast, the mean production rate of apoA-I was greater in the high HDL group compared with the low HDL group. These data support the hypothesis that the plasma concentration of HDL is primarily a function of the rate of appearance of apoA-I in medium and large HDL.