Serum amyloid A-containing human high density lipoprotein 3. Density, size, and apolipoprotein composition

Serum amyloid A protein (apo-SAA), an acute phase reactant, is an apolipoprotein of high density lipoproteins (HDL), in particular the denser subpopulation HDL3. The structure of HDL3 isolated from humans affected by a variety of severe disease states was investigated with respect to density, size, and apolipoprotein composition, using density gradient ultracentrifugation, gradient gel electrophoresis, gel filtration, and solid phase immunoadsorption. Apo-SAA was present in HDL particles in increasing amounts as particle density increased. Apo-SAA-containing HDL3 had bigger radii than normal HDL3 of comparable density. Purified apo-SAA associated readily with normal HDL3 in vitro, giving rise to particles containing up to 80% of their apoproteins as apo-SAA. The addition of apo-SAA resulted in a displacement of apo-A-I and an increase in particle size. Acute phase HDL3 represented a mixture of particles, polydisperse with respect to apolipoprotein content; for example, some particles were isolated that contained apo-A-I, apo-A-II, and apo-SAA, whereas others contained apo-A-I and apo-SAA but no apo-A-II. We conclude that apo-SAA probably associates in the circulation of acute phase patients with existing HDL particles, causing the remodeling of the HDL shell to yield particles of bigger size and higher density that are relatively depleted of apo-A-I.     

Affinity of lipid transfer protein for lipid and lipoprotein particles as influenced by lecithin-cholesterol acyltransferase

The effects of lecithin-cholesterol acyltransferase (LCAT) on the transfer of cholesterol esters mediated by lipid transfer protein (LTP) and its affinity for lipid and lipoprotein particles were investigated. When the single bilayer vesicle preparations (containing phosphatidylcholine, cholesterol, cholesteryl ester, and apolipoprotein- (apo) A-I at the molar ratio of 90:30:1.2:0.18) or high density lipoprotein 3 (HDL3) were used as the cholesteryl ester donor and low density lipoproteins (LDL) as the acceptor, the transfer activity of LTP was enhanced by the addition of low concentrations of LCAT. In contrast, no enhancement of cholesteryl ester transfer was observed upon addition of LCAT to either the discoidal bilayer particle preparations (containing phosphatidylcholine, cholesterol, cholesteryl ester, and apo-A-I at the molar ratio of 90:30:1.2:1.0) or high density lipoprotein 2 (HDL2). Although both apo-A-I and apo-A-II promoted the transfer of cholesteryl ester from vesicles to LDL, the additional enhancement of the transfer by LCAT was observed only with the vesicles containing apo-A-I. Gel permeation chromatography of LTP/vesicle and LTP/HDL3 mixtures in the presence and absence of LCAT showed that the affinity of LTP for both the vesicles and HDL3 increased upon addition of LCAT. In contrast, neither HDL2 nor discoidal bilayer particles showed any significant enhancement of LTP binding upon addition of LCAT. By using LCAT covalently bound to Sepharose 4B, a maximal interaction between LTP and bound LCAT was shown to occur at the ionic strength of 0.16. Deviation from this ionic strength reduced the extent of the interaction. At the ionic strength of 0.01 and 0.5, the elution volume of LTP was identical to that of bovine serum albumin.     

Particle distribution of human serum high density lipoproteins.

Density gradient ultracentrifugation of human serum high density lipoproteins (HDL) from both normolipemic males and females results in a distribution of HDL concentration versus subfraction hydrated density which has three maxima. Gradient gel electrophoresis of total HDL is characterized by three banding maxima, the positions of which suggest the presence of three particle size ranges: I. 10.8-12.0 nm, II. 9.7-10.7 nm, and III. 8.5-9.6 nm. Gradient gel electrophoresis of density gradient subfractions established an inverse relationship between particle size and particle hydrated density which was corroborated by electron microscopy and analytic ultracentrifugation. Comparison of male HDL from size ranges I, II, and III with female HDL from the same size ranges showed only small differences in the mean value of the peak F degrees 1.20 rate, size, molecular weight, protein weight percent, and weight protein/weight phospholipid. Major differences between males and females were seen in the relative amounts of HDL in density gradient subfractions 1-3 (size range I material) and 11-12 (size range III material); the percent total HDL in the group of subfractions 1-3 was greatly increased in female HDL while that of the group of subfractions 11-12 was increased in the male HDL. These studies indicate the presence of at least three major components in HDL instead of two (HDL2 and HDL3) and that peak F degrees 1.20 rate differences in HDL schlieren patterns between males and females are a function of the relative levels of these three components.     

A comparison of 3 methods of lipoprotein (a) isolation from human plasma]

Three methods for purification of lipoprotein (a) [Lp(a)] from human plasma were compared. Method I: two-stage ultracentrifugation with subsequent gel-filtration of Lp(a) containing fractions (1.063-1.090 g/ml) on Sepharose CL-4B. Method II: ultracentrifugation followed by affinity chromatography of plasma fraction (1.063 g/ml) on anti-apoB sorbent. Method III: affinity chromatography of the whole plasma on anti-apo(a) sorbent. The Lp(a) yield of these methods is 35, 54 and 41%, respectively. The method III is preferable of these three because it permitted high purification of a large amount of Lp(a) by single-step chromatography.     

Conversion of human plasma high density lipoprotein-2 to high density lipoprotein-3. Roles of neutral lipid exchange and triglyceride lipases

Cholesterol esters accumulating in human plasma high density lipoproteins (HDL) are important in conversion of HDL3 to larger HDL2. We studied whether mechanisms of removal of cholesterol esters from HDL might be important in a reverse direction, i.e. conversion of HDL2 to HDL3. Native HDL2 or HDL3 is incubated with very low density lipoproteins (VLDL) and lipoprotein-poor plasma (d greater than 1.21 g/ml) at 37 degrees C. After incubation, "modified" (M) VLDL, and HDL2 or HDL3 are reisolated by ultracentrifugation. In modified M-HDL2 or M-HDL3, triglyceride becomes the major core lipid as the triglyceride/cholesterol ester weight ratio increases 8-10-fold relative to native HDL. With only small changes in protein/phospholipid ratios in M-HDLs, the large decrease in cholesterol ester/protein ratios suggest net cholesterol ester loss from HDL. Quantitative recovery analyses prove that the cholesterol esters lost from HDL are transferred to M-VLDL, which is now richer in cholesterol ester and poorer in triglyceride. These substantial exchanges of HDL lipids are not associated by significant transfer of HDL apoproteins but are dependent on neutral lipid transfer factors present in human lipoprotein-poor plasma (d greater than 1.21 g/ml). Similar results are obtained when purified core lipid transfer protein replaces d greater than 1.21 g/ml plasma in these incubations. After depletion of cholesterol ester from HDL, most but not all, exchanged triglyceride can be removed by lipolysis with either hepatic or lipoprotein lipase, resulting in a post-lipolysis HDL2 with an increased triglyceride content relative to normal HDL. With successive incubations with VLDL, and core lipid transfer factors, HDL2 loses more than two-thirds of its cholesterol esters. After lipolysis of acquired triglyceride, HDL2 is remodeled, in both composition and flotation parameters, toward HDL3.     

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.     

Dissociation of apolipoprotein A-I from porcine and bovine high density lipoproteins by guanidine hydrochloride.

Dissociation of apolipoprotein A-I from pig and steer high density lipoproteins (HDL) deficient in apoA-II was determined by exposing native HDL fractions to 6 M guanidine hydrochloride (Gdn-HCl) at 37 degrees C for periods from 5 min to 18 h. Bovine high density lipoprotein (HDL-B) was isolated at d 1.063--1.100 g/ml while porcine high density lipoprotein (HDL-P) was isolated at d 1.125--1.21 g/ml. Incubation for 5 min with Gdn-HCl resulted in a 45 and 3% loss of apo-A-I from HDL-P and HDL-B, respectively. Exposure to the denaturant for 3 h resulted in a 75% loss of apoA-I from HDL-P and a 30% loss from HDL-B. Analytic ultracentrifugation, patterns paralleled the degree of apoA-I dissociation from each HDL species. The initial flotation peak for HDL-P shifted from F degrees 1.20 2.68 to F degrees 1.20 10.75 after 3 h exposure while HDL-B showed only a small shift from F degrees 1.20 8.30 to F degrees 1.20 8.96 after 3 h exposure. HDL-P particle diameter increased 25% after 5 min of Gdn-HCl treatment and large, flattened structures predominated after 3 h. There was no changes in the size of HDL-B after 5 min exposure and only 16% increase in particle diameter after 3 h. The difference in behavior of HDL-B and HDL-P to Gdn-HCl exposure is discussed in terms of differences in apolipoprotein A-I amino acid composition, interaction of apolipoprotein A-I with phospholipids and the possible involvement of the cholesteryl ester core.     

Binding of apolipoprotein A-I and A-II after recombination with phospholipid vesicles to the high density lipoprotein receptor of luteinized rat ovary

To determine the apolipoprotein specificity of high density lipoprotein (HDL) receptor, apolipoprotein A-I (apo-AI) and apolipoprotein A-II (apo-AII) purified from high density lipoprotein3 (HDL3) were reconstituted into dimyristoyl phosphatidylcholine vesicles (DMPC) and their ability to bind to luteinized rat ovarian membranes was examined. Both 125I-apo-A-I.DMPC and 125I-apo-A-II.DMPC were shown to bind to ovarian membranes with Kd = 2.87 and 5.70 micrograms of protein/ml, respectively. The binding of both 125I-apo-A-I.DMPC and 125I-apo-A-II.DMPC was inhibited by unlabeled HDL3, apo-A-I.DMPC, apo-A-II.DMPC, apo-C-I.DMPC, apo-C-II.DMPC, apo-C-III1.DMPC, and apo-C-III2.DMPC, but not by DMPC vesicles, bovine serum albumin.DMPC or low density lipoprotein. Since the binding labeled apo-A-I.DMPC and apo-A-II.DMPC was inhibited by the DMPC complexes of apo-C groups, the direct binding of 125I-apo-C-III1.DMPC was also demonstrated with Kd = 9.6 micrograms of protein/ml. In addition, unlabeled apo-A-I.DMPC, and apo-A-II.DMPC, as well as apo-C.DMPC, inhibited 125I-HDL3 binding. 125I-apo-A-I, 125I-apo-A-II, and 125I-apo-C-III1 in the absence of DMPC also bind to the membranes. These results suggest that HDL receptor recognizes apolipoprotein AI, AII, and the C group and that the binding specificity of the reconstituted lipoproteins is conferred by their apolipoprotein moiety rather than the lipid environment. In vivo pretreatment of rats with human chorionic gonadotropin resulted in an increase of 125I-apo-A-I.DMPC, 125I-apo-A-II.DMPC, and 125I-apo-C-III1.DMPC binding activities. However, no induction of binding activity was observed when the apolipoprotein was not included in DMPC vesicles. An examination of the equilibrium dissociation constant and binding capacity for 125I-apo-A-I.DMPC and 125I-apo-A-II.DMPC after human chorionic gonadotropin treatment revealed that the increase in binding activity was due to an increase in the number of binding sites rather than a change in the binding affinity. These results further support our contention that apo-A-I, apo-A-II, and the apo-C group bind to HDL receptor. In conclusion, the HDL receptor of luteinized rat ovary recognizes apolipoproteins A-I, A-II, and the C group but not low density lipoprotein, and the binding is induced by human chorionic gonadotropin in vivo.     

Non-leaky vesiculation of large unilamellar vesicles (LUV) induced by plasma high density lipoproteins (HDL): detection by HPLC

Interaction of large unilamellar phosphatidylcholine vesicles (LUV, 75nm) and plasma high density lipoproteins (HDL) resulted in a non-leaky vesiculation of LUV. This vesiculation was detected by a HPLC-system consisting of a combination of three TSK-gel columns (6000PW, 5000PW, 3000SW). With increasing incubation time liposomal [14C]PC, entrapped [3H]inulin, and apoprotein of HDL origin decreased. The decrease was accompanied by a formation of new particles, consisting of liposomal PC and apoprotein. These particles also enclosed [3H]inulin, reflecting a hydrophilic inner space. The formation of the particles reached a maximum after one day of incubation. Retention time was 21 minutes for LUV, 28 minutes for the new particles, and 36 minutes for HDL. In vesicles with membranes consisting of phosphatidylcholine and 30% cholesterol no interactions were observed.     

A hepatocyte receptor for high-density lipoproteins specific for apolipoprotein A-I

Apolipoprotein (apo) E-deficient rat high-density lipoproteins (HDL) bind to isolated rat hepatocytes at 4 degrees C by a process shown to be saturable and competed for by an excess of unlabeled HDL. Uptake (binding and internalization) at 37 degrees C was also saturable and competed for by an excess of unlabeled HDL. At 37 degrees C the HDL apoprotein was degraded as evidenced by the appearance of trichloroacetic acid-soluble radioactivity in the incubation media. The binding of a constant amount of 125I-apo-E-deficient HDL was measured in the presence of increasing concentrations of various lipoproteins. HDL and dimyristoyl phosphatidylcholine (DMPC) X apo-A-I complexes decreased binding by 80 and 65%, respectively. Human low-density lipoproteins, DMPC X apo-E complexes, and DMPC vesicles alone did not compete for apo-E-deficient HDL binding. However, DMPC X apo-E complexes did compete for the binding of the total HDL fraction that contained apo-E but to a lesser extent than did DMPC X apo-A-I. DMPC X 125I-apo-A-I complexes also bound to hepatocytes, and this binding was competed for by excess HDL (70%) and DMPC X apo-A-I complexes (65%), but there was no competition for binding by DMPC vesicles or DMPC X apo-E complexes. It thus appears that hepatocytes have a specific receptor for HDL and that apo-A-I is the ligand for this receptor.     

Characterization and catabolism of rat very high density lipoproteins

A previously unrecognized lipoprotein of very high density was isolated from rat serum. During zonal ultracentrifugation of whole serum or of fractions from Sepharose 4B chromatography, a peak comigrating with a peak of cholesterol was found between the typical high density lipoproteins and the residual serum proteins. Centrifugation of chylomicrons, very low density lipoproteins, and high density lipoproteins, radio-iodinated in their lipid and protein moieties and mixed with serum, did not yield this peak. The pooled fractions contained about 85% protein. The remainder was lipid comprising cholesteryl esters, free cholesterol, triglycerides, phosphatidylcholine, and sphingomyelin. Polyacrylamide gel electrophoresis revealed bands in the region of apolipoproteins E and C as the major components. The composition suggested a lipoprotein, and this was substantiated by electron microscopy which showed particles with a mean diameter of 150 A. Their average hydrated density was 1.23 g/ml and the apparent molecular weight was 1.35 X 10(6). These very high density lipoproteins are characterized by a rapid catabolism as compared to high density lipoproteins. Within 10 min, 84% and 70% of intravenously injected 125I-labeled very high density lipoproteins were removed from plasma of male and female rats, respectively, and did not appear to be converted to lipoproteins of a different density class. Ninety-five percent of the removed 125I was recovered in the liver and the radioactivity per gram of tissue was also highest for the liver. Accordingly, the rate of clearance of 125I-labeled very high density lipoproteins was markedly reduced in functionally eviscerated rats. Radioautography revealed that most of the silver grains representing very high density lipoproteins were associated with hepatocytes and only about 1% was found over v. Kupffer cells. Uptake and degradation by freshly isolated rat hepatocytes were mediated by a saturable and specific binding site. Composition and metabolic pathway are compatible with a function of very high density lipoproteins in the transport of protein and lipids to the liver.     

Factors controlling the release from human blood polymorphonuclear cells in vitro of a proteolytic activity directed against apolipoprotein A-II

Human high-density lipoprotein class-3 (HDL3) was incubated with freshly isolated blood polymorphonuclear leukocytes (PMN) at 37 and 4 degrees C. At both temperatures the release of proteolytic activity (PA) causing the specific hydrolysis of apo-A-II was dependent on the concentration of HDL3 in the medium. At 37 degrees C, the efflux of PA was linear and no saturation was reached up to an HDL3 protein concentration in the medium of 800 micrograms/ml. In turn, at 4 degrees C, maximal PA release was reached at a concentration below 600 micrograms/ml of HDL3 protein/ml in the medium. Canine HDL, which contains apo-A-I, but not apo-A-II, was as effective as human HDL3 in promoting the release of PA from PMN. This property was also exhibited by egg lecithin/cholesterol vesicles containing apo-A-I. At 4 degrees C, there was no strict correlation between efflux of PA affected by HDL3 and specific binding of 125I-apo-A-I (HDL3). In competitive binding experiments, a 50-fold excess of unlabeled HDL3 prevented more than 90% of the binding of 125I-apo-A-I (HDL3) to PMN, whereas an excess of unlabeled low-density lipoprotein exhibited no effect. When human HDL3 was incubated with PMN at 4 or 37 degrees C and then subjected to ultracentrifugation at d 1.21 g/ml, most of the PA that was initially associated with this lipoprotein was recovered in the bottom of the tube. By gel filtration, both PA and HDL3 were in the same peak in a low ionic strength buffer, but were dissociated from each other by a high-salt solution (d 1.21 g/ml). We conclude that both naturally occurring HDLs and apo-A-I-stabilized lipid vesicles favor the release from PMN of an enzymatic activity which cleaves human apo-A-II. This release appears to be dependent both on the interaction of the cells with the lipoprotein ligand and on the lipoprotein surface area acting as the acceptor for the enzyme, probably through electrostatic forces.     

Phosphatidylcholine substrate specificity of lecithin: cholestrol acyltransferase-in high density lipoproteins and in lipids dispersions.

Lecithin: cholesterol acyltransferase (LCAT) was more highly activated by apolipoprotein A-I (apoA-I) with dimyristoyl phosphatidylcholine (DMPC) than with dilinoleoyl phosphatidylcholine (DLPC) when lipid dispersion of cholesterol and each phosphatidylcholine was used as a substrate. When the enzyme reactions were activated by whole apolipoproteins of high density lipoproteins (HDL), DLPC was more available to the LCAT reaction than DMPC with high concentrations of apoHDL in an incubation mixture. However, no detectable enzyme reaction was observed with dipalmitoyl phosphatidylcholine (DPPC) under both conditions. On the other hand, all of these phosphatidylcholines acted as substrates of LCAT when they were incorporated into HDL coupled to Sepharose. The order of their relative reactivities to cholesterol was DMPC, DPPC, AND DLPC under the conditions used.     

Interaction of model discoidal complexes of phosphatidylcholine and apolipoprotein A-I with plasma components. Physical and chemical properties of the transformed complexes

Conversion of model discoidal complexes of egg yolk phosphatidylcholine and apolipoprotein A-I, upon interaction with a source of lecithin:cholesterol acyltransferase (plasma d greater than or equal to 1.21 g/ml fraction or partially purified enzyme) and with different sources of substrate unesterified cholesterol (LDL, VLDL or cholesterol incorporated into complexes), was investigated by gradient gel electrophoresis, gel filtration, equilibrium density gradient ultracentrifugation, electron microscopy and chemical analysis. When the incubation mixture contained an inhibitor of lecithin:cholesterol acyltransferase, discoidal complexes with mean long dimension of approximately 10.5 +/- 1.9 nm were converted (within 1 h) predominantly to small round particles and were partially depleted of their phospholipid content. Upon electrophoresis the small particles showed peak maxima within the migration intervals of the human plasma ( HDL3b ) gge and ( HDL3c ) gge subpopulations with associated particle size ranges of 7.8-8.2 and 7.2-7.8 nm, respectively. Within 1 h, in the presence of activated enzyme, the complexes were again converted in major part to the small particles. However, further incubation resulted in an apparent single-step conversion to a larger major product with peak maximum occurring within the migration intervals of the ( HDL2a ) gge and the ( HDL3a ) gge subpopulations (particle size ranges 8.8-9.8 and 8.2-8.8 nm, respectively). Formation of an apolar core was indicated by detection of cholesteryl esters in the conversion product. The form in which the substrate unesterified cholesterol was introduced did not markedly influence the size properties of the final conversion product. With VLDL as source of substrate, considerable incorporation of triacylglycerol occurred in company with a lower level of cholesteryl esters, suggesting transfer of these lipids during formation of the apolar core. Incubation of complexes with a partially purified (3000-fold) preparation of lecithin:cholesterol acyltransferase yielded a product similar in properties to that when the d greater than or equal to 1.21 g/ml fraction was used. Our model discoidal complexes and their conversion products exhibit properties very similar to those of potential precursors to HDL as well as of mature HDL particles. Their further investigation shows promise of providing detailed insight into the possible origin and heterogeneity of human plasma HDL.     

Studies of synthetic peptide analogs of the amphipathic helix. Correlation of structure with function

The four peptide analogs of the amphipathic helix whose interactions with dimyristoyl phosphatidylcholine were described in the preceding paper were compared with apolipoproteins (apo) A-I and A-II in ability to displace native apolipoprotein from high density lipoprotein (HDL) and in ability to activate lecithin:cholesterol acyltransferase. The rank order of the ability of the four peptide analogs to displace apo-A-I from intact HDL was 18A-Pro-18A greater than 18A greater than des-Val10-18A greater than reverse-18A, the same order suggested in the preceding paper for relative lipid affinities. Modified HDL from which 40% of the apo-A-I had been displaced by 18A was indistinguishable from unmodified HDL in its ability to act as a lecithin:cholesterol acyltransferase substrate. This suggests that the easily displaced apo-A-I molecules in polydisperse HDL are relatively ineffectual as lecithin:cholesterol acyltransferase activators and/or 18A replaces the lecithin:cholesterol acyltransferase activity lost. The peptide analog 18A-Pro-18A was found to be a powerful activator of lecithin:cholesterol acyltransferase when incubated with unilamellar egg phosphatidylcholine (PC) vesicles, reaching 140% of the activity of apo-A-I at a 1:1.75 peptide-to-egg PC ratio. In another experiment, it was found that discoidal egg PC complexes of 18A-Pro-18A, 18A, and des-Val10-18A, formed by cholate dialysis, had 30-45% of the activity of apo-A-I/egg PC discoidal complexes, also formed by cholate dialysis, at the same peptide/lipid weight ratio. Examination of the structures formed when the 18A-Pro-18A peptide was incubated with unilamellar egg PC vesicles indicated that the ability of 18A-Pro-18A to exceed apo-A-I in lecithin:cholesterol acyltransferase activating ability is due to the spontaneous conversion by 18A-Pro-18A of egg PC vesicles to small protein annulus-bilayer disc structures. Apo-A-I, apo-A-II, nor any of the other three peptide analogs of the amphipathic helix studied were able to convert a significant fraction of egg PC unilamellar vesicles to discoidal structures.     

Physical properties of isolated complexes of human and bovine A-I apolipoproteins with L-alpha-dimyristoyl phosphatidylcholine.

Human or bovine A-I apolipoproteins in solution form complexes with sonicated L-alpha-dimirystoyl phosphatidylcholine at 23 and 37 degrees, but not at 8 degrees, suggesting a strong dependence of the interaction on the physical state of the lipid (phase transition temperature 23 degrees). Complexes were isolated by gel filtration on a Sepharose 4B column and were subsequently analyzed for protein and lipid content, molecular weight, and physical state of the lipid portion. The average stoichiometry of all complexes, regardless of the initial concentrations or ratios of protein and lipid, was constant: 90 +/- 20 mol of phospholipid/mol of protein monomer, suggesting a highly cooperative interaction. Sedimentation equilibrium experiments indicated homogeneous macromolecular preparations and gave molecular weights around 235,000 (+/- 15%) for the complexes, with the human and bovine apo-A-I proteins contributing 77,000 (+/- 10%), i.e. about three protein subunits per complex. The lipid portion of the complexes retained some characteristics of a bilayer: it had a broad phase transition with a midpoint at 25.5 degrees as reported by the fluorescence polarization of the lipophilic probe diphenylhexatriene. Above the phase transition temperature the mobility of the phospholipids in the complexes with both apo-A-I proteins was considerably decreased relative to the pure L-alpha-dimyristoyl phosphatidylcholine dispersion; below the phase transition temperature the opposite was true, i.e. the protein fluidized the lipids. The results indicate that apol-A-I proteins interact stoichiometrically with L-alpha-dimyristoyl phosphatidylcholine vesicles above the gel to liquid-crystalline transition temperature of the lipid, promoting the destruction of vesicles and the formation of well defined particles of the general size of high density serum lipoproteins.     

Studies on human serum high density lipoproteins. Self-association of apolipoprotein A-I in aqueous solutions.

Human serum apolipoprotein A-I (apo-A-I), the major protein component of the human serum high density lipoproteins, was studied in aqueous solutions of differing ionic strength and pH by the techniques of sedimentation equilibrium ultracentrifugation and frontal analysis gel chromatography. The ultracentrifugal studies indicate the apo-A-I is a self-associating system that is dependent upon protein concentration, but relatively independent of the nature of the medium. The apparent weight average molecular weights obtained from solutions of initial apo-A-I concentration between 0.2 and 0.9 mg/ml were in the range of 3.0 to 16.7 x 10(4) (monomer molecular weight = 28,014). Of the several models of self-associated examined, that which gave the best theoretical fit was for the monomer-dimertetramer-octamer model. The self-association of apo-A-I in aqueous solutions was further documented by frontal analysis gel chromatography, which not only corroborated the ultracentrifugal results, but also indicated that the multiple species of apo-A-I in solution attain equilibrium rather rapidly. Besides having intrinsic importance, these results indicate that the solution properties of apo-A-I must be established before ligand binding studies are conducted and interpreted.     

31-P nuclear magnetic resonance studies on serum low and high density lipoproteins: effect of paramagnetic ion.

A paramagnetic quenching reagent, Mn-2+/EDTA (1:2.2), was developed for the purpose of investigating the phospholipid phosphate groupings of human serum low and high density lipoproteins through the quenching effect of the reagent on the 31-P nuclear magnetic resonance signals from these complexes. Systems investigated included native low and high density serum liproteins (LDL, HDL2, and HDL3), egg phosphatidylcholine vesicles together with appropriate phosphodiester model systems, diethyl phosphate in aqueous buffer, and phosphatidylcholine and sphingomyelin both in anhydrous methanol. The results of these studies indicated that ca. 50 percent of the phospholipid-phosphorus signal of LDL is quenched upon titration as compared to an 80-85 percent figure observed for HDL2 and HDL3. In all cases the spectral effects were totally reversible upon removalof the paramagnetic ion by dialysis. The results of the titration studies indicated a similar but not an identical behavior between HDL2 and HDL3. The results are consistent with model structures of HDL and LDL particles derived from low angle X-ray diffraction.     

Effects of serum amyloid A protein (SAA) on composition, size, and density of high density lipoproteins in subjects with myocardial infarction

The acute phase reactant serum amyloid A protein (SAA) circulates in plasma as a constituent of high density lipoproteins (HDL). Advantage has been taken of the induction of SAA in human subjects with myocardial infarction to study the effect of SAA on the physical and chemical properties of HDL. HDL were isolated by sequential ultracentrifugation and assayed for chemical composition. Apolipoprotein composition was assessed by SDS polyacrylamide gel electrophoresis. Size distribution of HDL was determined by gradient gel electrophoresis and density distribution by density gradient ultracentrifugation. In studies of 18 subjects with myocardial infarction, SAA accounted for 8-87% (median 52%) of the HDL apolipoprotein. These SAA-enriched HDL had a density comparable to that of normal HDL subfraction-3 (HDL3). Their chemical composition differed from normal HDL3, however, with a reduced phospholipid (17% vs 24%) and an increased triglyceride (7.7% vs 1.6%) value. When separated by gradient gel electrophoresis, the SAA-enriched HDL were much larger than normal HDL3, having a radius of 4.5-5.3 nm that extended well into the size range of HDL2; particle size correlated with SAA content. This disassociation between particle density and particle size was also observed with the SAA-enriched HDL isolated from a subject with secondary amyloidosis and also with normal HDL that had been enriched with SAA during incubation in vitro. Thus, the presence of high levels of SAA has been found to be associated with phospholipid-depleted particles of a density comparable to HDL3 but a size larger than normal HDL3.