Rapid transbilayer movement of spin-labeled steroids in human erythrocytes and in liposomes

The transbilayer movement and distribution of spin-labeled analogs of the steroids androstane (SLA) and cholestane (SLC) were investigated in the human erythrocyte and in liposomes. Membranes were labeled with SLA or SLC, and the analogs in the outer leaflet were selectively reduced at 4C using 6-O-phenylascorbic acid. As shown previously, 6-O-phenylascorbic acid reduces rapidly nitroxides exposed on the outer leaflet, but its permeation of membranes is comparatively slow and thus does not interfere with the assay. From the reduction kinetics, we infer that transbilayer movement of SLA in erythrocytes is rapid at 4C with a half-time of approximately 4.3 min and that the probe distributes almost symmetrically between both halves of the plasma membrane. We have no indication that a protein-mediated transport is involved in the rapid transbilayer movement of SLA because 1) pretreatment of erythrocytes with N-ethyl maleimide affected neither flip-flop nor transbilayer distribution of SLA and 2) flip-flop of SLA was also rapid in pure lipid membranes. The transbilayer dynamics of SLC in erythrocyte membranes could not be resolved by our assay. Thus, the rate of SLC flip-flop must be on the order of, or even faster than, that of probe reduction rate on the exoplasmic leaflet (half-time approximately 0.5 min). The results are discussed with regard to the transbilayer dynamics of cholesterol.     

Transbilayer movement of cholesterol in the human erythrocyte membrane

The rate of transbilayer movement of cholesterol was measured in intact human erythrocytes. Suspended erythrocytes were incubated briefly with [3H]cholesterol in ethanol at 4 degrees C, or with liposomes containing [3H]cholesterol over 6 hr at 4 degrees C to incorporate the tracer into the outer leaflet of erythrocyte plasma membranes. The erythrocytes were then incubated at 37 degrees C to allow diffusion of cholesterol across the membrane bilayer. Cells were treated briefly with cholesterol oxidase to convert a portion of the outer leaflet cholesterol to cholestenone, and the specific radioactivity of cholestenone was determined over the time of tracer equilibration. The decrease in specific radioactivity of cholestenone reflected transbilayer movement of [3H]cholesterol. The transbilayer movement of cholesterol had a mean half-time of 50 min at 37 degrees C in cells labeled with [3H]cholesterol in ethanol, and 130 min at 37 degrees C in cells labeled with [3H]cholesterol exchanged from liposomes. The cells were shown, by the absence of hemolysis, to remain intact throughout the assay. The presence of 1 mM Mg2+ in the assay buffer was essential to prevent hemolysis of cells treated with cholesterol oxidase perturbed the cells, resulting in an accelerated rate of apparent transbilayer movement. Our data are also consistent with an asymmetric distribution of cholesterol in erythrocyte membranes, with the majority of cholesterol in the inner leaflet.     

Transbilayer movement of phospholipids at the main phase transition of lipid membranes: implications for rapid flip-flop in biological membranes

The transbilayer movement of fluorescent phospholipid analogs in liposomes was studied at the lipid phase transition of phospholipid membranes. Two NBD-labeled analogs were used, one bearing the fluorescent moiety at a short fatty acid chain in the sn-2 position (C(6)-NBD-PC) and one headgroup-labeled analog having two long fatty acyl chains (N-NBD-PE). The transbilayer redistribution of the analogs was assessed by a dithionite-based assay. We observed a drastic increase of the transbilayer movement of both analogs at the lipid phase transition of DPPC (T(c) = 41 degrees C) and DMPC (T(c) = 23 degrees C). The flip-flop of analogs was fast at the T(c) of DPPC with a half-time (t(1/2)) of ~6-10 min and even faster at the T(c) of DMPC with t(1/2) on the order of <2 min, as shown for C(6)-NBD-PC. Suppressing the phase transition by the addition of cholesterol, the rapid transbilayer movement was abolished. Molecular packing defects at the phase transition are assumed to be responsible for the rapid transbilayer movement. The relevance of those defects for understanding of the activity of flippases is discussed.     

Transbilayer movement of monohexosylsphingolipids in endoplasmic reticulum and Golgi membranes

The transbilayer movement of glycosphingolipids has been characterized in Golgi, ER, plasma, and model membranes using spin-labeled and fluorescent analogues of the monohexosylsphingolipids glucosylceramide and galactosylceramide and of the dihexosylsphingolipid lactosylceramide. In large unilamellar lipid vesicles, monohexosylsphingolipids underwent a slow transbilayer diffusion (half-time between 2 and 5 h at 20 degrees C). Similarly, the inward redistribution of these sphingolipids in the plasma membrane of the hepatocyte-like cell line HepG2 and of erythrocytes was slow. However, in rat liver ER and Golgi membranes, we found a rapid transbilayer movement of spin-labeled monohexosylsphingolipids (half-time of approximately 3 min at 20 degrees C), which suggests the existence of a monohexosylsphingolipid flippase. The transbilayer movement of glucosylceramide in the Golgi and the ER displayed a saturable behavior, was inhibited by proteolysis, did not require Mg-ATP, and occurs in both directions. Treatment with DIDS inhibited the flip-flop of glucosylceramide but not that of phosphatidylcholine. These data suggest that the transbilayer movement of monoglucosylceramide in the ER and in the Golgi involves a protein that could be distinct from that previously evidenced for glycerophospholipids in the ER. In vivo, transbilayer diffusion should promote a symmetric distribution of monohexosylsphingolipids which are synthesized in the cytosolic leaflet. This should allow glucosylceramide rapid access to the lumenal leaflet where it is converted to lactosylceramide. No significant transbilayer movement of lactosylceramide occurred in both artificial and natural membranes over 1 h. Thus, lactosylceramide, in turn, is unable to diffuse to the cytosolic leaflet and remains at the lumenal leaflet where it undergoes the subsequent glycosylations.     

Relation between lipid polymorphism and transbilayer movement of lipid in rat liver microsomes

We have studied the effects of trinitrophenylation on the transbilayer movement of phosphatidylcholine and the macroscopic lipid structure in rat liver microsomal membranes. The transbilayer movement of phosphatidylcholine was investigated using the PC-specific transfer protein. ³¹P-NMR was employed to monitor the phospholipid organization in intact microsomal vesicles. The results indicate that modification of microsomes with trinitrobenzenesulfonic acid enhances the transbilayer movement of phosphatidylcholine at 4°C. Furthermore, phosphatidylethanolamine headgroup trinitrophenylation in microsomes increases the isotropic component in the ³¹P-NMR spectra even at 4°C, possibly representing the appearance of intermediate non-bilayer lipid structures. The observed parallel between these data suggests that phosphatidylethanolamine molecules in the microsomal membrane, probably in combination with a protein component, are able to destabilize the bilayer organization, thereby facilitating the transmembrane movement of phospholipids.     

Transbilayer distribution and movement of lysophosphatidylcholine in liposomal membranes

Single bilayer vesicles were prepared by sonication of 5 mol% 1-palmitoyl lysophosphatidylcholine and 95 mol% egg phosphatidylcholine. Incubation with lysophospholipase results in a fast hydrolysis of 80–90% of lysophosphatidylcholine. The remaining lysophosphatidylcholine is only very slowly hydrolysed. There results are interpreted as lysophosphatidylcholine being asymmetrically distributed over the two halves of the bilayer. The slow phase of lysophosphatidylcholine hydrolysis sets an upper limit to the rate of transbilayer movement of lysophosphatidylcholine. The half time of this process at 37° C is estimated to be about 100 h. Incorporation of cholesterol in the vesicles reduces the distributional asymmetry of lysophosphatidylcholine to the extent of an outside-inside ratio of 60 : 40. [¹⁴C]Lysophosphatidylcholine introduced into the outer monolayer of such vesicles by intervesicular transfer of lysophosphatidylcholine remains virtually completely available for hydrolysis by lysophospholipases, corroborating the interpretation that transbilayer movement of lysophosphatidylcholine in these vesicles is an extremely slow process.In handshaken liposomes consisting of 5 mol% 1-palmitoyl lysophosphatidylcholine and 95 mol% egg phosphatidylcholine 15–20% of lysophosphatidylcholine is readily available for exogenous lysophospholipase. This pool may represent lysophosphatidylcholine in the outer monolayer of the liposomes.     

Effect of the phase transition on the transbilayer movement of dimyristoyl phosphatidylcholine in unilamellar vesicles

Dimyristoyl phosphatidylcholine rapidly exchanges between vesicles at 37°C without vesicle fusion.The rate of the transbilayer movement of dimyristoyl phosphatidylcholine in sonicated vesicles has been measured employing ¹³C NMR using N-¹³CH_3? labeled lipids which are introduced into the outer monolayer of non-labeled vesicles by a phosphatidylcholine exchange protein. The rate of transbilayer movement of dimyristoyl phosphatidylcholine shows a distinct maximum (halftime 4 h) in the temperature range at which the hydrocarbon phase transition occurs.The activation energy of the flip-flop rate above the phase transition is 23.7 ± 2.0 kcal/mol.     

On the mechanism of transbilayer transport of phosphatidylglycerol in response to transmembrane pH gradients

Previous work [Hope et al. (1989) Biochemistry 28, 4181-4187] has shown that asymmetric transmembrane distributions of phosphatidylglycerol (PG) in PG-phosphatidylcholine (PC) large unilamellar vesicles can be induced in response to transbilayer pH gradients (delta pH). Here the mechanism of PG transport has been investigated. It is shown that PG movement in response to delta pH is consistent with permeation of the uncharged (protonated) form and that the half-time for transbilayer movement of the uncharged form can be on the order of seconds at 45 degrees C. This can result in rapid pH-dependent transmembrane redistributions of PG. The rate constant for transbilayer movement exhibits a large activation energy (31 kcal/mol) consistent with transport of neutral dehydrated PG where dehydration of the (protonated) phosphate presents the largest barrier to transmembrane diffusion. It is shown that acyl chain saturation, chain length, and the presence of cholesterol modulate the rate constants for PG transport in a manner similar to that observed for small nonelectrolytes.     

Barrier properties of glycophorin-phospholipid systems prepared by different methods

Glycophorin was incorporated into large unilamellar dioleoylphosphatidylcholine vesicles by either a detergent dialysis method using octylglucoside or a method avoiding the use of detergents. The vesicles were characterized and the permeability properties and transbilayer movement of lipids in both vesicles were investigated as a function of the protein concentration and were compared to protein-free vesicles. An insight in the permeability properties of the vesicles was obtained by monitoring the ratio potassium (permeant): dextran (impermeant) trap immediately after separation of the vesicles from the external medium. Glycophorin incorporated without the use of detergents in 1:300 protein:lipid molar ratio induces a high potassium permeability for the majority of the vesicles as judged from the low potassium trap (K⁺:dextran trap = 0.21). In contrast, the vesicles in which glycophorin is incorporated via the octylglucoside method (1:500 protein:lipid molar ratio) are much less permeable to potassium (K⁺:dextran trap = 0.67 and $\text{t}\text{1}\text{2}$ of potassium efflux at 22°C is 7.5 h.). The relationship between protein-induced bilayer permeability and lipid transbilayer movement in both vesicle preparations is discussed. Addition of wheat-germ agglutinin to glycophorin-containing vesicles comprised of dioleoylphosphatidylcholine and total erythrocyte lipids caused no or just a small effect (less than 20% release of potassium) on the potassium permeability of these vesicles. Also, addition of lectin to dioleoylphosphatidylethanolamine-glycophorin bilayer vesicles in a 25:1 lipid:glycophorin molar ratio had no effect on the permeability characteristics of the vesicles. In contrast, addition of wheat-germ agglutinin to bilayer vesicles made of dioleoylphosphatidylethanolamine and glycophorin in a 200:1 molar ratio resulted in a release of 74% of the enclosed potassium by triggering a bilayer to hexagonal (H_II) phase transition. The role of protein aggregation and the formation of defects in the lipid bilayer on membrane permeability and lipid transbilayer movement is discussed.     

Rapid transmembrane diffusion of ceramide and dihydroceramide spin-labelled analogues in the liquid ordered phase

In order to study the basic physical phenomena underlying complex lipid transbilayer movement in biological membranes, we have measured the transmembrane diffusion of spin-labelled analogues of sphingolipids in phosphatidylcholine (PC) large unilamellar vesicles in the absence or presence of cholesterol, going from a fluid ( liquid disordered) l_d, phase to a more viscous, liquid ordered (l_o), phase. We have found cholesterol to reduce the transverse diffusion of glucosylceramide (GlcCer) and galactosylceramide (GalCer) in a concentration-dependent manner. However, surprisingly, we could neither detect any influence of cholesterol on the rapid flip-flop of ceramide nor on the flip-flop of dihydroceramide, for which the τ_1/2 of flip-flop remains in the order of 1 minute at 20°C in the presence of cholesterol. As a consequence of rapid flip-flop of ceramide in both the l_o and the l_d phase, ceramide is likely to distribute between the two monolayers of a membrane, and could in principle partition into segregated domains in each side of the plasma membrane of eukaryotic cells.     

Effect of cholesterol on the valinomycin-mediated uptake of rubidium into erythrocytes and phospholipid vesicles

Human erythrocytes have been treated with lipid vesicles in order to alter the cholesterol content of the cell membrane. Erythrocytes have been produced with cholesterol concentrations between 33 and 66 mol% of total lipid. The rate of valinomycin-mediated uptake of rubidium into the red cells at 37°C was lowered by increasing the cholesterol concentration of the cell membrane. Cholesterol increased the permeability to valinomycin at 20°C of small (less than 50 nm), unilamellar egg phosphatidylcholine vesicles formed by sonication. Cholesterol decreased the permeability to valinomycin at 20°C of large (up to 200 nm) unilamellar egg phosphatidylcholine vesicles formed by freezethaw plus brief sonication. It is concluded that cholesterol increases the permeability of small membrane vesicles to hydrophobic penetrating substances while above the transition temperature but has the opposite effect on large membrane vesicles and on the membranes of even larger cells.     

Use of cyclodextrins to monitor transbilayer movement and differential lipid affinities of cholesterol

In view of the demonstrated cholesterol-binding capabilities of certain cyclodextrins, we have examined whether these agents can also catalyze efficient transfer of cholesterol between lipid vesicles. We here demonstrate that beta- and gamma-cyclodextrins can dramatically accelerate the rate of cholesterol transfer between lipid vesicles under conditions where a negligible fraction of the sterol is bound to cyclodextrin in steady state. beta- and gamma-cyclodextrin enhance the rate of transfer of cholesterol between vesicles by a larger factor than they accelerate the transfer of phospholipid, whereas, for alpha- and methyl-beta-cyclodextrin, the opposite is true. Analysis of the kinetics of cyclodextrin-mediated cholesterol transfer between large unilamellar vesicles composed mainly of 1-stearoyl-2-oleoyl phosphatidylcholine (SOPC) or SOPC/cholesterol indicates that transbilayer flip-flop of cholesterol is very rapid (halftime < 1-2 min at 37 degrees C). Using beta-cyclodextrin to accelerate cholesterol transfer, we have measured the relative affinities of cholesterol for a variety of different lipid species. Our results show strong variations in cholesterol affinity for phospholipids bearing different degrees of chain unsaturation and lesser, albeit significant, effects of phospholipid headgroup structure on cholesterol-binding affinity. Our findings also confirm previous suggestions that cholesterol interacts with markedly higher affinity with sphingolipids than with common membrane phospholipids.     

Rapid transmembrane movement of phosphatidylcholine in small unilamellar lipid vesicles formed by detergent removal

Small unilamellar phosphatidylcholine vesicles, formed by solubilizing phosphatidylcholine with sodium cholate and removing the detergent by gel filtration, have been studied in their interaction with phospholipid exchange protein. The exchange of phosphatidylcholine between the vesicles and erythrocyte ghosts was greatly stimulated by the phosphatidylcholine-specific exchange protein from bovine liver. It was found that 95% of the phosphatidylcholine was readily available for exchange within 3 h at 37°C. In similar vesicles prepared by sonication only 70% of the phosphatidylcholine was rapidly exchangeable. Our results indicate that the transmembrane movement of phosphatidylcholine across the bilayer of vesicles prepared by the cholate technique is a relatively fast process. The results are discussed with respect to the presence of trace amounts of lipid-associated cholate which may facilitate the transbilayer exchange of phosphatidylcholine.     

Protein-mediated transbilayer movement of lysophosphatidylcholine in glycophorin-containing vesicles

1. Sonicated glycophorin-containing vesicles of dioleoyl phosphatidylcholine have been made. The outside-inside distributions of the lipid molecules in these vesicles was measured with NMR and was found to be comparable with that of protein-free vesicles. 2. The transbilayer distribution of palmitoyl lysophosphatidylcholine in these vesicles is such that they have a significantly higher content of the lyso-compound in the inner monolayer when compared with vesicles without glycophorin. 3. Lysophosphatidylcholine, added to pre-existing glycophorin-containing vesicles, is incorporated in the outer monolayer of these vesicles. Subsequently it is able to move to the inner monolayer with an estimated half time of about 1.5 h at 4 degrees C. This was measured with 13C-NMR using [N-13CH3]lysophosphatidylcholine. 4. Treatment of co-sonicated vesicles of phosphatidylcholine and lysophosphatidylcholine containing glycophorin with the enzyme lysophospholipase results in a complete degradation of the lyso-compound. A half time of transbilayer movement of lysophosphatidylcholine during this experiment was estimated to be about 1 h at 37 degrees C.     

Nuclear magnetic resonance studies of amphiphile hydration: Effects of the gel-to-liquid crystalline phase transition on the hydration of dioleoyl lecithin

The hydration of dioleoyl lecithin (DOL) and dimyristoyl lecithin (DML) has been measured as a function of temperature between ?15 and ?30 °C, using low-temperature proton magnetic resonance. The hydration of DOL is considerably higher than that of DML. We detect 9 mol of unfrozen water/mol of phospholipid at ?25 °C (our “standard” temperature) for DOL, and only 6 mol of water/mol of phospholipid for DML. The gel-to-liquid crystalline phase transition in DOL centered at ca. ?19 °C is manifested by a 70% increase in hydration for both vesicles and dispersions. Preparations of either DML vesicles or vesicles of DOL which contain 33 mol% cholesterol would not be expected to undergo this phase transition, and the hydration increase observed for these preparations in the same range of temperature is less than 20%.     

Rapid flip-flop of phospholipids in endoplasmic reticulum membranes studied by a stopped-flow approach

The transbilayer movement of short-chain spin-labeled and fluorescent 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) phospholipid analogs in rat liver microsomes is measured by stopped-flow mixing of labeled microsomes with bovine serum albumin (BSA) solution. Extraction of analogs from the outer leaflet of microsomes to BSA can be directly monitored in conjunction with electron paramagnetic resonance or fluorescence spectroscopy by taking advantage of the fact that the signal of spin-labeled or fluorescent analogs bound to BSA is different from that of the analogs inserted into membranes. From the signal kinetics, the transbilayer movement and the distribution of analogs in microsomal membranes can be derived provided the extraction of analogs by BSA is much faster in comparison to the transbilayer movement of analogs. Half-times of the back-exchange for spin-labeled and fluorescent analogs were <3.5 and <9.5 s, respectively. The unprecedented time resolution of the assay revealed that the transbilayer movement of spin-labeled analogs is much faster than previously reported. The half-time of the movement was about 16 s or even less at room temperature. Transmembrane movement of NBD-labeled analogs was six- to eightfold slower than that of spin-labeled analogs.     

Kinetics of interfacial catalysis by phospholipase A2 in intravesicle scooting mode,and heterofusion of anionic and zwitterionic vesicles

In this and the following three papers we examine the kinetics of action of pig pancreatic phospholipase A₂ on vesicles of anionic phospholipids without any additives. The results provide the first unequivocal demonstration of interfacial catalysis in intravesicle scooting mode. In this paper we describe the conditions in which the action of pig pancreatic phospholipase A₂ on DMPMe (ester) vesicles in the absence of any additive commences without a latency. Under these conditions the free monomer substrate concentration is insignificant; the bilayer enclosed vesicle organization remains intact even when all the substrate in the outer monolayer has been hydrolyzed; the rate of intervesicle exchange and the rate of transbilayer movement (flip-flop) of molecules is negligibly slow; and the rate of fusion of vesicles is insignificant. Thus an enzyme molecule bound to one vesicle hydrolyzes all the DMPMe molecules in the outer monolayer of the vesicle by a first-order process with a rate constant of 0.6 per min at 30°C; or viewed another way, one enzyme molecule in a DMPMe vesicle can hydrolyze all the available substrate molecules at the rate of 3000 per min. At low anion concentrations excess substrate vesicles are not hydrolyzed unless the rate of intervesicle exchange of the bound enzyme is stimulated by anions in the aqueous phase. Higher calcium concentrations promote not only homofusion of DMPMe vesicles but also heterofusion of DMPMe and DMPC vesicles. It is proposed that calcium-induced isothermal lateral phase separation in DMPMe vesicles induces defects in the bilayer organization, and such defects are the sites for phospholipase A₂ binding and for heterofusion with DMPC (ester) vesicles which do not have such sites.     

Phospholipid vesicle fusion and drug loading: temperature,solute and cholesterol effects,and, a rapid preparation for solute-loaded vesicles

The fusion of sonicated dipalmitoylphosphatidylcholine (DPPC) vesicles was studied by gel-exclusion chromatography as a function of temperature, permeable and impermeable solute concentration, and cholesterol content of the bilayer membrane. Fusion is faster at lower temperatures: there is no fusion at or above 35.5°C (0.10 M DPPC/0.1 M K₂SO₄/0.01 M Hepes buffer (pH 7.4)/0.02% NaN₃). There is about 10% fusion after 1 week at 30°C, and about 60% fusion after 2 days at 13–25°C. Between 13 and 8°C, the fusion product changes from 700-Å-diameter vesicles to the 950-Å vesicles previously reported by Wong et al. (Wong, M., Anthony, F.W., Tillack, T.W. and Thompson, T.E. (1982) Biochemistry 21, 4126–4132). At 1°C, fusion is about 90% complete after 1 day. Membrane-impermeable solutes (NaCl, trehalose and glucose) inhibit fusion in a manner reflecting the total particle concentration. There is no detectable fusion after 3 days (22°C) in either 1.0 M NaCl or 2.0 M sugar, the highest concentrations studied. A suggested explanation is that impermeable solutes osmotically inhibit the influx of solution that accompanies the fusion of vesicles to form a larger vesicle, and, could conceivably thereby inhibit the fusion reaction. By contrast, membrane-permeable solutes (glycerol, ethylene glycol, propylene glycol and ethanol) dramatically increase the fusion rate. 1.0 M ethanol causes 100% fusion in 15–30 min at 22°C. The simultaneous presence of 0.15 M NaCl entirely negates the fusion-promoting effect of 1.0 M ethanol. 1 mol% cholesterol completely inhibits fusion in 0.1 M KCl (20°C), and greatly slows it down either in 1.0 M ethanol at 20°C or in 0.1 M KCl at 4°C. A suggested mechanism is that cholesterol might concentrate in and stabilize bilayer lattice defect sites that are critical for the fusion reaction. The trapping efficiency of vesicles formed by the fast ethanol fusion conditions in the presence of the water-soluble markers, chromate and arsenazo III, ranged from 9.0 to 12.7% of the marker captured in the vesicles, corresponding to trapped volumes of 1.8 to 2.5 1/mol DPPC. Bromophenol blue gave anomalously high values of 67% and 13 1/mol DPPC, which presumably reflect binding, in addition to encapsulation.     

Probing red cell membrane cholesterol movement with cyclodextrin

We probed the kinetics with which cholesterol moves across the human red cell bilayer and exits the membrane using methyl-beta-cyclodextrin as an acceptor. The fractional rate of cholesterol transfer (% s(-1)) was unprecedented, the half-time at 37 degrees C being ~1 s. The kinetics observed under typical conditions were independent of donor concentration and directly proportional to acceptor concentration. The rate of exit of membrane cholesterol fell hyperbolically to zero with increasing dilution. The energy of activation for cholesterol transfer was the same at high and low dilution; namely, 27-28 Kcal/mol. This behavior is not consistent with an exit pathway involving desorption followed by aqueous diffusion to acceptors nor with a simple one-step collision mechanism. Rather, it is that predicted for an activation-collision mechanism in which the reversible partial projection of cholesterol molecules out of the bilayer precedes their collisional capture by cyclodextrin. Because the entire membrane pool was transferred in a single first-order process under all conditions, we infer that the transbilayer diffusion (flip-flop) of cholesterol must have proceeded faster than its exit, i.e., with a half-time of <1 s at 37 degrees C.     

Effects of apolipoproteins on the kinetics of cholesterol exchange

The effects of apolipoproteins on the kinetics of cholesterol exchange have been investigated by monitoring the transfer of [14C]cholesterol from donor phospholipid/cholesterol complexes containing human apolipoproteins A, B, or C. Negatively charged discoidal and vesicular particles containing purified apolipoproteins complexed with lipid (75 mol % egg PC, 15 mol % dicetyl phosphate, and 10 mol % cholesterol) and a trace of [14C]cholesterol were incubated with a 10-fold excess of neural, acceptor, small unilamellar vesicles (SUV; 90 mol % egg PC and 10 mol % cholesterol). The donor and acceptor particles were separated by chromatography on DEAE-Sepharose, and the rate of movement of labeled cholesterol was analyzed as a first-order exchange process. The kinetics of exchange of cholesterol from both vesicular and discoidal complexes that contain apoproteins are consistent with an aqueous diffusion mechanism, as has been established previously for PC/cholesterol SUV. The addition of 2-3 molecules of apo A-I to a donor SUV does not significantly alter the half-time (t1/2), which is 80 +/- 9 min at 37 degrees C. However, addition of 5-12 apo A-I molecules progressively decreases t1/2 from 65 +/- 2 to 45 +/- 4 min. This enhancement in the rate of desorption of cholesterol molecules is presumed to arise from the creation of packing defects at boundaries around the apoprotein molecules, which are intercalated among the phospholipid and cholesterol molecules in the surface of the donor SUV.(ABSTRACT TRUNCATED AT 250 WORDS)