Phenotyping of Porcine Apolipoprotein E Using Isoelectric Focusing and Localization of the APOE Gene Within the Halothane-Susceptibility Linkage Group

A method has been developed for the phenotyping of pig apolipoprotein E. It was based on isoelectric focusing of sialidase-treated and delipidated blood plasma followed by immunoblotting. As the first antibody the anti-human apolipoprotein E antibody was used. The genetic polymorphism of pig apolipoprotein E appeared to be controlled by three alleles at one locus. A two-point linkage analysis was performed between certain loci belonging to the halothane linkage group and the APOE locus on material comprising 9 Zlotnicka Spotted boars, 30 Polish Large White sows, and their 160 offspring. A tight linkage between the A1BG and the APOE loci was documented (theta = 0.038).     

Analytical isoelectric focusing with immobilized pH gradients of human apolipoprotein E from very low density lipoproteins and total plasma

A method for analytical isoelectric focusing (IEF) of apolipoprotein E (apoE) in immobilized pH gradients (IPG) and immunodetection of the separated isoforms has been developed for use with either very low density lipoproteins (VLDL) or whole plasma. Both VLDL and plasma were sequentially delipidated with 1,4-dioxane, acetone-ethanol, and ether. Neuraminidase treatment preceded the delipidation when required. Using preformed plates, pH 5.0-6.0 (LKB, Bromma) after rehydration with 6 M urea and dextran T-10, the IPG focusing pattern of the common isoforms (E2, E3, E4) was found to be equivalent to conventional IEF with the added resolution of the E4 disialo form. The use of self-poured narrower gradients permitted the further resolution of the E4 monosialo form, a previously unrecognized heterogeneity of the E2, E3, and E4 monosialo isoforms and differentiation of the apoE2** mutant; all of these forms comigrate with the common isoproteins in conventional IEF. Finally, the conditions for IPG of whole plasma using apoE monoclonal antibodies and enzyme-conjugated anti-mouse IgG for detection were established. Thus, IPG focusing is shown to be a powerful method for resolution of the apoE sialoforms and apoE mutant forms. The method has important implications in accurate and diagnostic phenotyping. Moreover, it is a convenient method for phenotyping which requires only very small volumes of plasma.     

A simplified method for screening the apolipoprotein E polymorphism

A simple method for screening populations for the apolipoprotein E polymorphism which involves isoelectric focusing of delipidated samples on polyacrylamide gels of pH 4.5-5.8 followed by immunoblotting using a double-antibody technique is presented. The method is a synthesis of two previously published procedures and works well on samples that have been stored for as long as 15 years.     

Clinical chemistry of common apolipoprotein E isoforms

Apolipoprotein E plays a central role in clearance of lipoprotein remnants by serving as a ligand for low-density lipoprotein and apolipoprotein E receptors. Three common alleles (apolipoprotein E₂, E₃ and E₄) give rise to six phenotypes. Apolipoprotein E₃ is the ancestral form. Common apolipoprotein E isoforms derive from nucleotide substitutions in codons 112 and 158. Resulting cysteine-arginine substitutions cause differences in: affinities for low-density lipoprotein and apolipoprotein E receptors, low-density lipoprotein receptor activities, distribution of apolipoprotein E among lipoproteins, low-density lipoprotein formation rate, and cholesterol absorption. Accompanying changes in triglycerides, cholesterol and low-density lipoprotein may promote atherosclerosis development. Over 90% of patients with familial dysbetalipoproteinaemia have apolipoprotein E₂/E₂. Apolipoprotein E₄ may promote atherosclerosis by its low-density lipoprotein raising effect. Establishment of apolipoprotein E isoforms may be important for patients with diabetes mellitus and several non-atherosclerotic diseases. Apolipoprotein E phenotyping exploits differences in isoelectric points. Isoelectric focusing uses gels that contain pH4–7 ampholytes and urea. Serum is directly applied, or prepurified by delipidation, lipoprotein precipitation or dialysation. Isoelectric focusing is followed by immunofixation/protein staining. Another approach is electro- or diffusion blotting, followed by protein staining or immunological detection with anti-apolipoprotein E antibodies and an enzyme-conjugated second antibody. Apolipoprotein E genotyping demonstrates underlying point mutations. Analyses of polymerase chain reaction products are done by allele-specific oligonucleotide probes, restriction fragment length polymorphism, single-stranded conformational polymorphism, the primer-guided nucleotide incorporation assay, or denaturating gradient gel electrophoresis. Detection with primers that either or not initiate amplification is performed with the amplification refractory mutation system. Disparities between phenotyping and genotyping may derive from isoelectric focusing methods that do not adequately separate apolipoprotein E posttranslational variants, storage artifacts or faint isoelectric focusing bands.     

Genetic studies of human apolipoproteins. V. A novel rapid procedure to screen apolipoprotein E polymorphism

A simple and new method has been developed to detect apolipoprotein E polymorphism directly from plasma or serum without prior ultracentrifugation and delipidation. The method combines the use of dialyzed plasma or serum samples with or without neuraminidase treatment followed by monodimensional isoelectric focusing in simple or 3 M urea gels at a constant low power and progressively increasing voltage over a 3-hr period, and finally protein blotting to a nitrocellulose membrane. Apolipoprotein E phenotypes are identified immunologically using a double antibody reaction, the primary antibody being a monospecific, polyclonal goat anti-apolipoprotein E, and the secondary antibody being a rabbit anti-goat IgG conjugated with alkaline phosphatase. The method was employed to screen apolipoprotein E polymorphism in two white populations in the United States. The frequency values are comparable to those reported previously by other investigators using conventional detection methods. The procedure is simple, accurate, suitable for large scale epidemiologic, clinical, and genetic studies.     

Apolipoprotein A-IV polymorphism and its effect on plasma lipid and apolipoprotein concentrations

Recently, we determined the apolipoprotein E (apoE) phenotype distribution in 2,000 randomly selected 35-year-old male individuals by slab gel isoelectric focusing of delipidated plasma samples, followed by immunoblotting using anti-apoE antiserum. These blots have been successfully re-used for immunovisualization of apoA-IV isoelectric focusing patterns. In a population sample of 1,393 individuals, four distinct apoA-IV isoforms were detected, encoded by the alleles A-IV*0, A-IV*1, A-IV*2, and A-IV*3 with gene frequencies of 0.002, 0.901, 0.079, and 0.018, respectively. The mean of plasma cholesterol, triglyceride, apoB and E levels did not differ significantly among the different apoA-IV phenotype groups. For these lipoprotein parameters, less than 0.1% of the total phenotypic variance could be accounted for by the APOA-IV gene locus. Our results did not show any effect of apoA-IV polymorphism on plasma apoA-I levels nor could we find any correlation between plasma levels of apoA-I and apoA-IV within the different apoA-IV phenotype groups. The plasma level of apoA-IV in subjects bearing the A-IV*3 allele is significantly lower than in subjects without the A-IV*3 allele (5 mg/dl versus 14 mg/dl). We therefore conclude that, in contrast to the apoE polymorphism, the polymorphism at the APOA-IV locus does not influence any of the levels of the lipoprotein parameters considered except apoA-IV.     

Phenotyping of human apolipoprotein E from whole blood plasma by immunoblotting

Human apolipoprotein E (apoE) exists in the population in three common genetically determined isoforms, apoE-2, E-3, and E-4, that are coded for by three alleles epsilon-2, epsilon-3 and epsilon-4 at the apoE structural gene locus resulting in six phenotypes, three homozygotes (E 2/2, E 3/3, and E 4/4) and three heterozygotes (E 2/3, E 2/4, and E 3/4). A new procedure is described that allows identification of apoE isoforms and phenotypes from whole plasma or serum without the need for isolating apoE-containing lipoproteins or two-dimensional gel electrophoresis of serum. This rapid method combines cysteamine treatment of apoE in plasma, separation in parallel of cysteamine-treated and untreated hydrophobic serum proteins by charge-shift electrophoresis, and isoelectric focusing of apolipoproteins with immunoblotting. Compared to phenotyping of apoE after isolation of VLDL, the new procedure agreed in most cases and may be of special value in detecting apoE mutants that differ in their cysteine residues or either are spun off during isolation of lipoproteins or cofocus with other apoproteins and thus escape detection by conventional one-dimensional techniques. The method provides a simple tool to screen apoE isoforms that are known to have a major impact on individual plasma cholesterol levels.     

Apolipoprotein E phenotypes in Finnish youths: a cross-sectional and 6-year follow-up study

Apolipoprotein E (apoE) polymorphism is a genetic determinant of plasma lipid levels and of coronary heart disease (CHD) risk. We determined the apoE phenotypes and plasma lipid levels in 1577 youths aged 3 to 18 years in 1980. The subjects were randomly selected from five areas of Finland. ApoE phenotyping was performed directly from plasma by isoelectric focusing and immunoblotting. The apoE allele frequencies in the population sample were epsilon 2 = 0.039, epsilon 3 = 0.767, and epsilon 4 = 0.194. There were no differences in the apoE phenotype distribution between East and West Finland or between sexes. The concentrations of serum total cholesterol, low density lipoprotein cholesterol, and apolipoprotein B increased with apoE phenotype in the order of E2/2, E3/2, E4/2, E3/3, E4/3, and E4/4. This increase was already seen in 3-year-old children; it was observed in both sexes, but was clearer in males than in females. The mean levels of high density lipoprotein (HDL) cholesterol, apolipoprotein A-I, triglyceride, Lp[a] lipoprotein, and the activity of lecithin:cholesterol acyltransferase did not differ between the apoE phenotypes. The observed differences in serum cholesterol remained fairly stable during the 6-year follow-up from 1980 to 1986, while the mean serum cholesterol concentration in the whole study population decreased by 6.3%. This study confirms the reported higher frequency of the epsilon 4 allele in Finns as compared to most other populations; this may contribute to the high rates of CHD in Finland as compared to most other populations. The results do not, however, explain the higher rate of CHD in East Finland in comparison to the western part of the country.     

Studies on the protein composition of human serum very low density lipoproteins: demonstration of the beta 2-glycoprotein-I.

Human serum VLDL isolated by polyanion precipitation and ultracentrifugation have been delipidated with ethanal/diethyl ether. By electrophoresis in 10% polyacrylamide gels containing 8M urea, we found a protein which comigrated with apolipoprotein E. This protein was purified by column chromatography and turned out to be identical with beta 2-glycoprotein-I, the serum factor which is necessary for the precipitation of triglyceride-rich lipoproteins with sodium decyl sulfate or sodium dodecyl sulfate. Upon analytical isoelectric focusing, beta 2-glycoprotein-I gave four major bands in the pH region 5.7--6.6. All four bands gave an immunochemical reaction of identity with a monospecific antiserum. From its unique amino acid composition we conclude that beta 2-glycoprotein-I is distinct from all apolipoproteins described previously in the literature.     

Apolipoprotein E phenotyping with a single gel method: application to the study of informative matings

Two-dimensional gel electrophoresis or isoelectric focusing before and after treatment with cysteamine are currently used to determine the six apolipoprotein E isomorphic phenotypes from isolated very low density lipoproteins. A technique is described that makes this possible by performing isoelectric focusing on a single polyacrylamide cylindrical gel under standardized conditions. The technique is simple and accurate enough to obtain 99.5% concordance when the gels are interpreted independently by four different skilled and unskilled observers in the absence of any knowledge of the origin of the samples. There was complete agreement between our technique and the bidimensional method carried out independently in another laboratory on 74 aliquots of plasma very low density lipoproteins. Its application to 16 informative matings involving 101 subjects confirmed the recent demonstration that the apolipoprotein E phenotype inheritance is autosomal and compatible with three common alleles acting at a single genetic locus. Analyses of the contribution of apoE polymorphism to lipid and lipoprotein variability demonstrated a recessive allelic effect of epsilon 2 on plasma very low density lipoprotein cholesterol and a dominant epsilon 4 effect on low density lipoprotein cholesterol. As much as 30% of the variability in low density lipoprotein cholesterol was attributable to this polymorphic gene locus. A simplified scheme is proposed for the symbolic representation of the six phenotypes for clinical and genetic applications.     

Apolipoprotein E3-Leiden. A new variant of human apolipoprotein E associated with familial type III hyperlipoproteinemia

Summary A variant of apolipoprotein E, denoted apo E3-Leiden, has been identified in a 41-year-old male suffering from type III hyperlipoproteinemia with xanthomatosis. Apo E3-Leiden focus in the E3 position. In contrast with normal apo E3, apo E3-Leiden is defective in binding to the low density lipoprotein (LDL) receptor and does not contain cysteine as evaluated by cysteamine treatment of very low density lipoprotein followed by isoelectric focusing and conventional protein staining and by amino acid analysis. On sodium dodecyl sulfate polyacrylamide gel electrophoresis, apo E3-Leiden displays an electrophoretic mobility intermediate to that of normal apo E3 and apo E2 (Arg₁₅₈Cys). The mother and four siblings of the proband also have apo E3-Leiden and hyperlipoproteinemia type III; three of them with xanthomatosis. Two siblings do not show apo E3-Leiden in their VLDL fraction and do not have hyperlipoproteinemia type III. In the VLDL fractions of all affected family members only the presence of apo E3-Leiden could be detected after cysteamine treatment and isoelectric focusing followed by conventional protein staining. However, isoelectric focusing of cysteaminetreated sera followed by immunoblotting, using anti-apo E antiserum as first antiserum, demonstrates the presence of low amounts of normal apo E3 in addition to apo E3-Leiden in serum of the affected family members. These results indicate that all affected family members are heterozygotes E3/E3-Leiden and suggest that in this family type III hyperlipoproteinemia is transmitted as a dominant trait.     

Apolipoprotein E polymorphism in the Netherlands and its effect on plasma lipid and apolipoprotein levels

Summary By isoelectric focusing of delipidated sera followed by immunoblotting we studied the apolipoprotein (apo) E polymorphism in 2018 randomly selected 35-years-old males from three different areas in the Netherlands. Comparison of the APOE allele (E^*2, E^*3, and E^*4) frequencies estimated in this study with those reported for several other population samples showed that there are marked differences between the Dutch population and the populations of Japan, New Zealand, Finland, and the United States. These differences in APOE allele frequencies appeared to be mainly due to differences in frequencies of the E^*2 allele (decreased in Japan and Finland; increased in New Zealand) and the E^*4 allele (increased in Finland; decreased in Japan and the United States). No difference in APOE allele frequencies was found between the Dutch population and the populations of West Germany and Scotland. Measurements of plasma cholesterol and apo B and E concentrations showed that the E^*4 allele is associated with elevated plasma cholesterol and apo B levels and with decreased apo E concentrations, whereas the opposite is true for the E^*2 allele. In the Dutch population, the sum of average allelic effects of the common APOE alleles on plasma cholesterol and apo B levels is 6.8% and 14.2%, respectively, of the total population mean. The total average allelic effect on plasma apo E concentrations was more pronounced (50.1%), suggesting that the APOE alleles primarily affect apo E concentrations rather than plasma cholesterol and apo B levels. This hypothesis is sustained by the observation that for plasma apo E levels the genetic variance associated with the APOE gene locus contributed about 18% to the total phenotypic variance. For plasma cholesterol and apo B this contribution was only 1.4% and 2.3% and is relatively low as compared with that reported for other population samples.     

A method to screen apolipoprotein polymorphisms in whole plasma: description of apolipoprotein A-IV variants in dyslipidemias and a reassessment of apolipoprotein A-I in Tangier disease

A sensitive and rapid immunological detection method was used to screen for apolipoprotein A-IV variants. Antibodies to human lymph chylomicron or plasma apolipoprotein A-IV, and plasma apolipoprotein A-I were raised in rabbits. Antibodies to apolipoprotein A-I or apolipoprotein A-IV were shown to be monospecific to their respective antigens by reactivity against human chylomicron apolipoproteins by immunoblot analysis. Plasma samples were obtained from dyslipidemic subjects from the Lipid Research Clinic of Columbia University. The plasma samples were isoelectrically focused (pH 4-6) on slab gels. Plasma proteins were then transferred to nitrocellulose paper for immunoblotting. Apolipoprotein A-IV polymorphism was determined by specific immunological detection of apolipoprotein A-IV. Identical apolipoprotein A-IV isoprotein patterns were observed when either antibodies to lymph or plasma apolipoprotein A-IV were used for immunoblotting. All the dyslipidemic plasma samples screened contained the two major and one or two minor isoproteins of normal plasma. In two instances, new apolipoprotein A-IV variants having an additional isoform were detected. One subject was hypertriglyceridemic (triacylglycerols = 342 mg/dl, cholesterol = 251 mg/dl) and had an additional major acidic apolipoprotein A-IV isoform. Another subject with mild hypocholesterolemia (triacylglycerols = 209 mg/dl, cholesterol = 120 mg/dl) was found to have additional major and minor basic apolipoprotein A-IV isoforms. The specificity of this technique allows detection of polymorphism of apolipoproteins of similar isoelectric points by use of a single dimension isoelectric focusing gel. This technique also demonstrated the presence of altered apolipoprotein A-I isoforms in the plasma of a patient with Tangier disease. These isoforms were previously identified as isoforms 2 and 4 of normal plasma by use of two-dimensional gel electrophoresis. However, by use of this new technique and careful evaluation of previously published two-dimensional gels, we now identify these apolipoprotein A-I isoforms as being more acidic than those of normal plasma.     

Separation and isolation of human apolipoproteins C-II, C-III0, C-III1, and C-III2 by chromatofocusing on the Fast Protein Liquid Chromatography system

Chromatofocusing, which separates proteins based on differences in isoelectric point, has been used on the Fast Protein Liquid Chromatography (FPLC) system (Pharmacia) to separate the C apolipoproteins from human very low density lipoproteins (VLDL). Using a Mono P column (Pharmacia), a pH gradient between pH 6.2 and pH 4.0 was generated using buffers containing 6 M urea, at a flow rate of 0.5 ml/min. Typically, runs took approximately 45 min. Chromatofocusing of delipidated whole VLDL produced sharp, well-resolved peaks for the C apolipoproteins. However, as determined by analytical isoelectric focusing (IEF), the apolipoprotein E isoforms were not separated from apoC-II, and they contaminated the other apoC species to a variable extent. In addition, apoC-II was not resolved from apoC-III0. Preliminary precipitation of VLDL with acetone prior to delipidation removed both apolipoproteins E and B. Using a start buffer of 25 mM histidine, pH 6.2, and a 1:30 dilution of the polybuffer exchanger (eluting buffer), apoC-II, C-III0, C-III1, and C-III2 were well resolved in run-times of approximately 60 min. The C apoproteins proved to be pure by analytical IEF and immunoassay with monospecific antisera against apoC-II and C-III. Recovery was over 90% of the protein chromatographed. In addition, a variant of apoC-II present in VLDL of a hypertriglyceridemic subject was clearly resolved from the other C apolipoproteins. This technique is superior to conventional methodology in terms of its time saving and high resolution. The application of this technique to the study of C apolipoprotein variants and C apolipoprotein specific radioactivity determinations is possible.     

Isolation and lipid-binding properties of rat apolipoprotein A-IV

Apolipoprotein A-IV was isolated from the d less than 1.21 g/ml fraction of rat serum by gel filtration followed by heparin-Sepharose affinity chromatography; this method also facilitated the preparation of apolipoprotein A-I and apolipoprotein E. The apolipoprotein A-IV preparation was characterized by SDS-gel electrophoresis, isoelectric focusing, amino acid analysis and immunodiffusion. The lipid-binding properties of this protein were studied. Apolipoprotein A-IV associated with dimyristoylphosphatidylcholine (DMPC) to form recombinants which contained two molecules of apolipoprotein A-IV and had a lipid/protein molar ratio of 110. The density of the DMPC/apolipoprotein A-IV particles was determined to be 1.08 g/ml and the particles were visualized by electron microscopy as discs which were 5.8 nm thick and 18.0 nm in diameter. The stability of the DMPC/apolipoprotein A-IV recombinants, as determined by resistance to denaturation, was comparable to the stability of DMPC/apolipoprotein A-I complexes. However, by competition studies it was found that apolipoprotein A-I competed for the binding to DMPC more effectively than did apolipoprotein A-IV. It is concluded that, while rat apolipoprotein A-IV resembles other apolipoproteins in its lipid-binding characteristics, it may be displaced from lipid complexes by apolipoprotein A-I.     

A previously reported polymorphic plasma protein of dogs and horses, identified as apolipoprotein A-IV

By using immunoblotting with antiserum specific to human plasma apolipoprotein A-IV (apoA-IV), a previously reported polymorphic plasma protein of dogs viz postalbumin-2 (Pa2) and one of horses viz serum protein 2 (SP2), were identified as apoA-IV of these species. This along with earlier published results implied that: (1) both dog and horse show a high degree of polymorphism at the APOA4 locus with three common alleles in each of the two species; and (2) apoA-IV phenotyping in these two species can be done by analysing plasma/serum samples by a simple method of two-dimensional electrophoresis, conducted under non-denaturing conditions, followed by general-protein staining of gels.     

A previously reported polymorphic plasma protein of dogs and horses, identified as apolipoprotein A-IV

Summary. By using immunoblotting with antiserum specific to human plasma apolipoprotein A-IV (apoA-IV), a previously reported polymorphic plasma protein of dogs viz postalbumin-2 (Pa2) and one of horses viz serum protein 2 (SP2), were identified as apoA-IV of these species. This along with earlier published results implied that: (1) both dog and horse show a high degree of polymorphism at the APOA4 locus with three common alleles in each of the two species; and (2) apoA-IV phenotyping in these two species can be done by analysing plasma/serum samples by a simple method of two-dimensional electrophoresis, conducted under non-denaturing conditions, followed by general-protein staining of gels.     

Immunologic comparison of the conformations of apolipoprotein B. Investigation of methodologies for the reconstitution of delipidated and denatured apolipoprotein B with nonionic surfactants

Immunologic probes have been used to examine the conformation of apolipoprotein B (apo-B) as it exists within native low density lipoprotein (LDL) after lipid displacement with Triton X-100 and after denaturation with guanidine hydrochloride organic solvent delipidation and reconstitution with Triton X-100. Antigenic expression was assayed in two systems: by using either Triton X-100 or bovine serum albumin to maintain protein solubility. Apo-B delipidated by lipid displacement using Triton X-100 was virtually identical to LDL-apo-B in both systems, as assayed by polyclonal antisera prepared in rabbits against either antigen. Thus the native antigenic sites are preserved, although the displacement of the lipid core of LDL drastically alters the physical properties of the particle. Apo-B delipidated by solvent extraction in guanidine was reconstituted with Triton X-100 by several methods, and the products were examined immunologically. One method yielded a product that resembled apo-B as delipidated with Triton X-100, although full reconstitution could not be achieved. Nevertheless, Triton promoted refolding of apo-B to reform partial native structure as judged immunologically. By using both physical and immunologic methods for assessing structure, it is clearly evident that the perceptions of the conformational states of reconstituted apo-B can be very different, and multiple criteria need to be used to assess lipoprotein reconstitution.     

Astrocytes synthesize apolipoprotein E and metabolize apolipoprotein E-containing lipoproteins

We have previously demonstrated that astrocytes synthesize and secrete apolipoprotein E in situ. In the present work, primary cultures of rat brain astrocytes were used to study apolipoprotein E synthesis, secretion, and metabolism in vitro. The astrocytes in culture contained immunoreactive apolipoprotein E in the area of the Golgi apparatus. Incubation of the astrocytes with [35S]methionine resulted in the secretion of labeled immunoprecipitable apolipoprotein E, which constituted 1-3% of the total secreted proteins. The apolipoprotein E secreted in culture and the apolipoprotein E in rat brain extracts differed from serum apolipoprotein E in two respects: both had a slightly higher apparent molecular weight (approx. 36,000) and more acidic isoforms than serum apolipoprotein E. Sialylation of the newly secreted apolipoprotein accounted for the difference in both the apparent molecular weight and isoelectric focusing pattern of newly secreted apolipoprotein E and plasma apolipoprotein E. The astrocytes possessed apolipoprotein B,E(LDL) receptors capable of binding and internalizing apolipoprotein E-containing lipoproteins. The uptake of lipoproteins by the cells led to a reduction in the number of cell surface receptors and to the intracellular accumulation of cholesteryl esters. Since apolipoprotein E is present within the brain, and since brain cells can express apolipoprotein B,E(LDL) receptors, apolipoprotein E-containing lipoproteins may function to redistribute lipid and regulate cholesterol homeostasis within the brain.     

The role of apolipoprotein A-IV in reverse cholesterol transport studied with cultured cells and liposomes derived from an ether analog of phosphatidylcholine

Cholesterol efflux was studied in a model system in culture using apolipoproteins and phospholipids added in the form of liposomes at concentrations expected to be present in the extracellular fluid. Fibroblasts were seeded in medium containing [3H]cholesterol-labeled serum, grown till confluent, and the [3H]cholesterol efflux was studied in serum-free medium. Addition of delipidated HDL apolipoprotein resulted in a very low release of [3H]cholesterol, which did not increase with time of exposure or concentration of apolipoproteins. Addition of increasing amounts of HDL apolipoprotein to liposomes prepared from either dioleoylphosphatidylcholine (PC) or its nonhydrolysable ether analog, dioleylphosphatidylcholine (DOEPC) resulted in a 3-5-fold increase of [3H]cholesterol efflux, over that achieved with liposomes alone. This model system permitted the test of the putative role of apolipoprotein A-IV in cholesterol removal from cells. The ability of apolipoprotein A-IV to enhance [3H]cholesterol efflux from cells by DOEPC liposomes was compared to that of apolipoproteins A-I, E and C, which were added at equimolar concentrations. At nM concentrations, apolipoproteins A-IV, A-I and E were equally able to enhance cholesterol efflux, while C apolipoproteins were less effective at these low concentrations. Mixtures prepared from apolipoprotein A-IV, A-I and E and PC or DOEPC liposomes were equally effective in cholesterol removal, while phosphatidylethanolamine liposome apolipoprotein mixtures had a much lower capacity. The present study provides the first evidence that apolipoprotein A-IV can play a role in reverse cholesterol transport as was suggested on the basis of high concentrations of this apolipoprotein in nonlipoprotein form in plasma and extracellular fluid. The efficacy of DOEPC liposomes to serve as cholesterol acceptors might be of potential value for enhancement of reverse cholesterol transport in vivo.