Interaction of bovine brain phospholipid exchange protein with liposomes of different lipid composition

The major phospholipid exchange protein from bovine brain catalyzes the transfer of phosphatidylinositol and phosphatidylcholine between rat liver microsomes and sonicated liposomes. The effect of liposomal lipid composition on the transfer of these phospholipids has been investigated. Standard liposomes contained phosphatidylcholine-phosphatidic acid (98:2, mol%); in general, phosphatidylcholine was substituted by various positively charged, negatively charged, or zwitterionic lipids. The transfer of phosphatidylinositol was essentially unaffected by the incorporation into liposomes of phosphatidic acid, phosphatidylserine, or phosphatidylglycerol (5–20 mol%) but strongly depressed by the incorporation of stearylamine (10–40 mol%). Marked stimulation (2–4-fold) of transfer activity was observed into liposomes containing phosphatidylethanolamine (2–40 mol%). The inclusion of sphingomyelin in the acceptor liposomes gave mixed results: stimulation at low levels (2–10 mol%) and inhibition at higher levels (up to 40 mol%). Cholesterol slightly diminished transfer activity at a liposome cholesterol/phospholipid molar ratio of 0.81. Similar effects were noted for the transfer to phosphatidylcholine from microsomes to these various liposomes. Compared to standard liposomes, the magnitude of $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ tended to increase for liposomes which depressed phospholipid transfer and to decrease for those which stimulated; little change was observed in the values of $\text{V}$. Single phospholipid liposomes of phosphatidylinositol were inhibitory when added to standard liposomes.     

Some properties of phosphatidylcholine exchange protein purified from beef liver

A phospholipid exchange protein has been purified 2680-fold from beef liver. The assay of the exchange activity of the protein was based on the transfer of [¹⁴C]phosphatidylcholine from microsomes labeled with [¹⁴C]phosphatidylcholine to liposomes. The homogeneity of the protein has been established by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoelectrophoresis and isoelectric focusing. The protein has a molecular weight of approximately 22000 and an isoelectric point of 5.8. The amino acid composition has been determined. The protein contains one disulfide bridge and has glutamic acid as the N-terminal amino acid. Phospholipid, tentatively identified as phosphatidylcholine, was found to be present in the protein preparation. The protein stimulated specifically the exchange of phosphatidylcholine between mitochondria and microsomes from rat liver.     

Kinetic analysis of the interaction of the phosphatidylcholine exchange protein with unilamellar vesicels and multilamellar liposomes.

The mode of action of the phosphatidylcholine exchange protein from bovine liver has been studied by using unilamellar vesicles and multilamellar liposomes both of which membranes contain phosphatidylcholine and phosphatidic acid. The protein-mediated exchange of phosphatidylcholine between vesicles and liposomes fit the kinetic model presented in a previous study [V.D. Besselaar et al. (1975) Biochemistry, 1j, 1852]. Kinetic analysis of the rates of exchange indicate that the apparent dissociation constant of the exchange protein-vesicle complex decreases with an increasing phosphatidic acid content of the vesicles. Both vesicles and liposomes of 10 mol% phosphatidic acid show the same dissociation constant; on the other hand, both the formation and the disruption of the protein-membrane complex was 50--100-times higher for the vesicles than for the liposomes. This implies that the exchange protein can discriminate between vesicles and liposomes. Equilibrium gel chromatography of a column of Bio Gel A-5m confirmed that the exchange protein binds more strongly to vesicles of an increased phosphatidic acid content. The protein-mediated exchange of phosphatidylcholine in the vesicle-liposome system demonstrates a pH optimum at 4.0 to 5.5. The kinetic analysis at pH 5.0 as compared to pH 7.4 indicates that the enhanced exchange at pH 5.0 can solely be accounted for by altered interaction of the exchange protein with the liposomes.     

The protein-mediated net transfer of phosphatidylinositol in model systems

The phospholipid monolayer technique has been used to study the transfer activity of the phospholipid exchange protein from beef brain. In measuring the transfer between a monolayer consisting of equimolar amounts of phosphatidylcholine and phosphatidylinositol and liposomes consisting of 98 mol% phosphatidylcholine and 2 mol% phosphatidylinositol, the beef brain protein demonstrates an 8-fold higher transfer activity for phosphatidylinositol than for phosphatidylcholine. Under similar conditions the phosphatidylcholine exchange protein from beef liver showed a great preference for phosphatidylcholine. Phosphatidylcholine liposomes devoid of phosphatidylinositol still functioned as receptors of phosphatidylinositol when the beef brain exchange protein was present. This indicates that this protein can catalyse a net transfer of phosphatidylinopsitol. Binding of both phosphatidylinositol and phosphatidylcholine to the beef brain protein was shown.     

Use of liposomes in probing the uptake of liposomal phosphatidylcholine by rabbit lung in vitro.

The purpose of this study was to characterize the uptake of liposomal phosphatidylcholine by lung tissue and its subcellular organelles. Multilamellar liposomes were prepared from egg yolk phosphatidylcholine, dicetyl phosphate, and cholesterol (molar ratio 7 : 2 : 1). Liposomal phosphatidylcholine labeled with [1-14C]dipalmitoyl phosphatidylcholine was taken up by lung slices and incorporated into subcellular organelles including lamellar bodies, mitochondria, and microsomes. In addition, when liposomes were incubated with lamellar bodies, mitochondria, or microsomes, the transfer of liposomal phosphatidylcholine to these subcellular fractions was facilitated by the cytosolic fraction. In tissue slice experiments after 1 h of incubation, about 86% of the total radioactivity absorbed by lung slices and subcellular organelles was recovered in phosphatidylcholine. The ratio of the radioactivity of fatty acids at 1- and 2-positions of dipalmitoyl phosphatidylcholine recovered from all fractions was nearly 1 : 1. This suggests that most phosphatidylcholine molecules were taken up intact. In conclusion, this study provides a method using liposomes as a tool for probing the phosphatidylcholine transfer mechanism in lung.     

Asymmetry and transposition rates of phosphatidylcholine in rat erythrocyte ghosts.

Purified phospholipid exchange protein from beef heart cytosol is used to accelerate the exchange of phospholipids between labeled sealed ghosts and phosphatidylcholine/cholesterol liposomes. The purified protein accelerates the transfer of phosphatidylcholine and, to a lesser degree, that of sphingomyelin, phosphatidylinositol, and lysophosphatidylcholine. The presence of exchange protein does not accelerate the exchange of phospholipids between intact red blood cells and liposomes, but 75% of the phosphatidylcholine of sealed ghosts is readily available for exchange. The remaining 25% is also exchangeable but at a slower rate. When the exchange is assayed between inside-out vesicles and liposomes, 37% of the phosphatidylcholine is readily available, and 63% is exchanged at a slower rate. These results are consistent with an asymmetric distribution of phosphatidylcholine in isolated erythrocyte membrane fractions. The sum of the forward and backward transposition of phosphatidylcholine between the inside and outside layers of sealed ghost membranes amounts to 11% per hour, and the half-time for equilibration is 2.3 h. Significatnly lower values are obtained for the inside-out vesicles (half-time for equilibration: 5.3 h). These results suggest that, during the formation of the vesicles, the asymmetry of phosphatidylcholine is partially preserved, but structural changes occur in the membrane that affect the rate of membrane transposition of phosphatidylcholine.     

A phosphatidyl choline exchange protein isolated from germinated castor bean endosperms

A phospholipid exchange protein (PLEP) functioning between theendoplasmic reticulum and the mitochondrion was purified fromthe cytosolic fraction of germinated castor bean endosperms.In the protein fraction eluted from Sephadex G-100 column, theexchange rate reached 7.3µg phospholipids exchanged/mgprotein/15 min, which was 60-fold that of pota to tuber PLEP.The lipid transfer by this protein was specific for phosphatidylcholine and the transfer rate from microsomes to mitochondriawas as high as that from mitochondria to microsomes. Castorbean PLEP transferred phospholipid from castor bean microsomesto mitochondria from other sources such as potato tubers, cauliflowerinflorescences, pumpkin hypocotyls and rat livers, and to liposomes,but not to Avena etioplasts. In addition, it transferred phospholipidfrom potato microsomes to potato mitochondria. (Received November 17, 1978; )     

Effect of bilayer membrane curvature on activity of phosphatidylcholine exchange protein

Effect of bilayer membrane curvature of substrate phosphatidylcholine and inhibitor phosphatidylserine on the activity of phosphatidylcholine exchange protein has been studied by measuring transfer of spin-labeled phosphatidylcholine between vesicles, vesicles and liposomes, and between liposomes. The transfer rate between vesicles was more than 100 times larger than that between vesicles and liposomes. The transfer rate between liposomes was still smaller than that between vesicles and liposomes and nearly the same as that in the absence of exchange protein. The markedly enhanced exchange with vesicles was ascribed to the asymmetric packing of phospholipid molecules in the outer layer of the highly curved bilayer membrane. The inhibitory effect of phosphatidylserine was also greatly dependent on the membrane curvature. The vesicles with diameter of 17 nm showed more than 20 times larger inhibitory activity than those with diameter of 22 nm. The inhibitory effect of liposomes was very small. The size dependence was ascribed to stronger binding of the exchange protein to membranes with higher curvatures. The protein-mediated transfer from vesicles to spiculated erythrocyte ghosts was about four times faster than that to cup-shaped ghosts. This was ascribed to enhanced transfer to the highly curved spiculated membrane sites rather than greater mobility of phosphatidylcholine in the spiculated ghost membrane.     

Effect of liposomal phospholipid composition on cholesterol transfer between microsomal and liposomal vesicles.

Preincubation of rat liver microsomal vesicles at 37 degrees C in the presence of [3H]cholesterol/phospholipid liposomes results in a net transfer of cholesterol from liposomes to microsomal vesicles. This transfer follows first-order kinetics. For similar concentrations of the donor vesicles, rates of transfer are about 6-8 times lower with cholesterol/sphingomyelin liposomes compared with cholesterol/phosphatidylcholine liposomes. Also, transfer of cholesterol from cholesterol/sphingomyelin liposomes to microsomal vesicles reveals a larger activation energy than for the process from cholesterol/phosphatidylcholine liposomes. There is a significant correlation between the amount of liposomal cholesterol transferred to microsomal vesicles during preincubation and the increase found with acyl-CoA:cholesterol acyltransferase activity in these microsomes over their corresponding controls. If, however, liposomes made solely of phospholipids are substituted for the cholesterol/phospholipid liposomes in the preincubation system containing microsomal vesicles, then the acyl-CoA:cholesterol acyltransferase activity is decreased compared with the corresponding control system. Both sphingomyelin and phosphatidylcholine liposomes are equally effective in decreasing the enzyme activity. These results offer direct kinetic evidence for the positive correlation between cholesterol and sphingomyelin found in vivo in biological membranes.     

Effect of N-ethylmaleimide on rat liver phosphatidylcholine-specific and non-specific transfer protein activities: its dependence on donor liposome composition

Phosphatidylcholine exchange between liposomes and mitochondria catalyzed by rat liver phosphatidylcholine transfer protein is strongly stimulated by N-ethylmaleimide (NEM) when PC/PI (molar ratio, 4:1) donor liposomes are used. In the presence of PC/PE or PC liposomes the exchange activity by this protein is unaffected. In the same experimental conditions, the activity of rat liver non-specific transfer protein is always stimulated by N-ethylmaleimide with all the types of liposomes tested in the order PC/PI greater than PC/PE greater than PC. Since the effect of NEM depends on the type of liposomes used and appears to be similar for both phospholipid transfer proteins, the possibility that their mode of action implies the formation of a ternary complex should be considered. As far as non-specific transfer protein is concerned, its interaction could vary depending on the nature of the exchanging membranes. Data are also presented indicating that when the two transfer proteins are together their activity is additive, therefore suggesting a specific role in phospholipid biomembrane assembly for each of them.     

The Fusion of Liposomes to Rat Brain Microsomal Membranes Regulates Phosphatidylserine Synthesis

Rat brain microsomal membranes were fused to liposomes prepared with several pure lipids, namely, phosphatidylserine, phosphatidylinositol, phosphatidic acid, and mixtures of phosphatidic acid and phosphatidylcholine or phosphatidylethanolamine. The fusion between liposomes and microsomes was measured by the octadecyl rhodamine B chloride method. The extent and other properties of fusion largely depend on the lipid used to prepare liposomes; phosphatidic acid and phosphatidylinositol fuse more extensively than other lipid classes. The activity of serine base exchange is affected by the fusion between rat brain microsomes and lipids. It is strongly inhibited by phosphatidylserine, but it is activated by phosphatidic acid. The inhibition produced by phosphatidylserine on its own synthesis is proposed as a mechanism for controlling the formation of phosphatidylserine in rat brain microsomes.     

Disintegration of phosphatidylcholine liposomes in plasma as a result of interaction with high-density lipoproteins.

1. During in vitro incubation of liposomes or unilamellar vesicles prepared from egg-yolk or rat-liver phosphatidylcholine with human, monkey or rat plasma the phospholipid becomes associated with a high molecular weight protein-containing component. 2. The phosphatidylcholine . protein complex thus formed co-chromatographs with high-density lipoprotein on Ultrogel AcA34 and has the same immunoelectrophoretic properties as this lipoprotein. 3. Release of the phosphatidylcholine from liposomes was also observed when liposomes were incubated with pure monkey high-density lipoproteins. Under those conditions some transfer of protein from the lipoprotein to the liposomes was observed as well. 4. The observed release of phospholipid from the liposomes is a one-way process, as the specific radioactivity of liposome-associated phosphatidylcholine remained constant during incubation with plasma. 5. It is concluded that either the lipoprotein particle takes up additional phospholipid or that a new complex is formed from protein constituents of the lipoprotein and the liposomal phosphatidylcholine. 6. Massive release of entrapped 125I-labeled albumin from the liposome during incubation with plasma suggests that the observed release of phosphatidylcholine from the liposomes has a highly destructive influence on the liposomal structure. 7. Our results are discussed with special reference to the use of liposomes as intravenous carriers of drugs and enzymes.     

Catalytic properties of phospholipid exchange protein from bovine heart.

A protein which catalyzes the exchange of phosphatidylcholine between membranes has been purified from heart tissue homogenates up to 300-fold by acidic pH precipitation, (NH4)2SO4 precipitation, gel filtration, and ion-exchange chromatography. Binding of the protein to phosphatidylcholine liposomes as measured by Sepharose chromatography was nondetectable. However, isoelectric focusing experiments showed that individual molecules of phosphatidylcholine were transferred from liposomes to the soluble, partially purified protein. Exchange of phospholipid between liposomes and mitochondria was not affected by the presence of moderate amounts of cholesterol in liposomes. A search for competitive inhibitors among moieties similar to phosphatidylcholine failed to show strong binding sites in the hydrophilic part of the substrate. High concentrations of Na+, Ca2+ and Mg2+ impaired the exchange activity.     

Transfer of cholesterol between liposomal membranes.

The transfer of cholesterol between liposomal membranes was examined. On incubation of liposomes compsoed of egg yolk phosphatidylcholine, phosphatidic acid and cholesterol (molar percentage, 65.8 : 1.3 : 32.9 or 65.5 : 6.3 : 31.2), almost complete equilibration of the cholesterol pools was achieved within 6 to 8 h at 37 degrees C. The rate of transfer of cholesterol from the liposomes, in which cholesterol was introduced by 'the exchange reaction', was not significantly different from that from liposomes prepared in the presence of cholesterol, in which the cholesterol was distributed homogenously. These findings indicate that half life for 'flip-flop' of cholesterol molecules in egg yolk phosphatidylcholine liposomes is less than 6 h at 37 degrees C. The transfer of cholesterol between liposomes was strongly dependent on temperature and was affected by the fatty acid composition of the phospholipid, suggesting that the 'fluidity' of the membranes strongly influences the transfer rate. A preferential distribution of cholesterol molecules was observed in heterogeneous liposomes with different classes of phospholipids. The 'affinity order' of cholesterol for phospholipid deduced from the present experiments is as follows: beef brain sphingomyelin greater than dipalmitoylglycerophosphocholine = dimyristoylglycerophosphocholine greater than egg yolk phosphatidylcholine.     

Effect of liposome composition on the activity of detergent-solubilized acylcoenzyme A: cholesterol acyltransferase

Acylcoenzyme A:cholesterol acyltransferase (ACAT) was solubilized from Ehrlich ascites cell microsomes with Triton X-100. After removal of the detergent, ACAT activity per mg protein was reduced by 50 to 65% as compared with untreated microsomes. When this microsomal extract was combined with liposomes composed of cholesterol and egg phosphatidylcholine, the ACAT activity increased 5.4- to 6.7-fold. Under these conditions sucrose density gradient centrifugation indicated that more than 50% of the added lipid was incorporated into vesicles having the same density as the ACAT activity, suggesting the formation of a complex. ACAT activity increased 2.9-fold when the phosphatidylcholine content of the liposomes was raised from 0.5 to 5.0 mumol/mg microsomal protein. By contrast, the ACAT activity increased only 42% when the cholesterol content of the liposomes was raised from 0.17 to 0.57 mumol/mg microsomal protein. Addition of phosphatidylethanolamine to the liposomes produced little change in ACAT activity, whereas the activity was reduced by 25 and 50%, respectively, when sphingomyelin or phosphatidylserine was added. ACAT activity was five times higher when the liposomes were prepared from dioleoylphosphatidylcholine than from saturated phosphatidylcholines, including hydrogenated egg yolk, dimyristoyl or dipalmitoyl phosphatidylcholine. Likewise, the ACAT activity with liposomes made from soybean or egg yolk phosphatidylcholine was almost 3.5-fold greater than with those prepared from the saturated phosphatidylcholines. These results are consistent with the view that the activity of ACAT can be modified by changes in the composition of the membrane lipids with which the enzyme is associated.     

Sterol carrier and lipid transfer proteins

The discovery of the sterol carrier and lipid transfer proteins was largely a result of the findings that cells contained cytosolic factors which were required either for the microsomal synthesis of cholesterol or which could accelerate the transfer or exchange of phospholipids between membrane preparations. There are two sterol carrier proteins present in rat liver cytosol. Sterol carrier protein 1 (SCP1) (Mr 47 000) participates in the microsomal conversion of squalene to lanosterol, and sterol carrier protein 2 (SCP2) (Mr 13 500) participates in the microsomal conversion of lanosterol to cholesterol. In addition SCP2 also markedly stimulates the esterification of cholesterol by rat liver microsomes, as well as the conversion of cholesterol to 7 alpha-hydroxycholesterol - the major regulatory step in bile acid formation. Also, SCP2 is required for the intracellular transfer of cholesterol from adrenal cytoplasmic lipid inclusion droplets to mitochondria for steroid hormone production, as well as cholesterol transfer from the outer to the inner mitochondrial membrane. SCP2 is identical to the non-specific phospholipid exchange protein. While SCP2 is capable of phospholipid exchange between artificial donors/acceptors, e.g. liposomes and microsomes, it does not enhance the release of lipids other than unesterified cholesterol from natural donors/acceptors, e.g. adrenal lipid inclusion droplets, and will not enhance exchange of labeled phosphatidylcholine between lipid droplets and mitochondria. Careful comparison of SCP2 and fatty acid binding protein (FABP) using six different assay procedures demonstrates separate and distinct physiological functions for each protein, with SCP2 participating in reactions involving sterols and FABP participating in reactions involving fatty acid binding and/or transport. Furthermore, there is no overlap in substrate specificities, i.e. FABP does not possess sterol carrier protein activity and SCP2 does not specifically bind or transport fatty acid. The results described in the present review support the concept that intracellular lipid transfer is a highly specific process, far more substrate-specific than suggested by the earlier studies conducted using liposomal techniques.     

Partial purification of fatty-acid binding protein by ammonium sulphate fractionation

By fractionation of rat liver cytosol with 70% saturation ammonium sulphate, a soluble fraction showing high affinity for oleic acid was obtained. The binding of oleic acid to this fraction was inhibited by flavaspidic acid. The molecular weight of the main protein present in this fraction was 12 000 as determined by SDS-poly-acrylamide-gel electrophoresis. This soluble fraction stimulated the transfer of oleic acid from microsomes to phosphatidylcholine liposomes as demonstrated by a transfer assay in vitro. The behaviour of this fraction is similar to that described for fatty-acid binding protein.     

Phosphatidylcholine mobility in liver microsomal membranes

Purified phosphatidylcholine exchange protein from bovine liver was used to exchange rat liver microsomal phosphatidylcholine for egg phosphatidylcholine. It was found that at 25 and 37°C rat liver microsomal phosphatidylcholine was completely and rapidly available for replacement by egg phosphatidylcholine. In contrast, phosphatidylcholine in vesicles prepared from total microsomal lipids could only be exchanged for about 60%. At 8 and 0°C complex exchange kinetics were observed for phosphatidylcholine in rat liver microsomes. The exchange process had neither effect on the permeability of the microsomal membrane to mannose 6-phosphate, nor on the permeability of the phosphatidylcholine vesicles to neodymium (III) cations.Purified phospholipase A₂ from Naja naja could hydrolyze some 55–60% of microsomal phosphatidylcholine at 0°C, but 70–80% at 37°C. Microsomal phosphatidylcholine, remaining after phospholipase treatment at 37°C, could be exchanged for egg phosphatidylcholine at 37°C, but at a slower rate than with intact microsomes. Microsomal phosphatidylcholine remaining after phospholipase treatment at 0 and 37°C had a lower content of arachidonic acid than the original phosphatidylcholine.These results are discussed with respect to the localization and transmembrane movement of phosphatidylcholine in liver microsomes.     

Phosphatidylcholine transfer between liposomes and mitochondria. Testing system for the study of specific phospholipid exchange]

A system consisting of liposomes and mitochondria for studying the exchange of specific phospholipids is described. The liposomes were prepared from phosphatidylcholine labelled with 14C-palmitic acid. The transfer of liposomes to the mitochondria is specifically stimulated 2- to 3fold by the pH 5.1 supernatant, and proceeds in a linear fashion for 90 min.