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

Non-vesicular lipid transport by lipid-transfer proteins and beyond

The movement of lipids within and between intracellular membranes is mediated by different lipid transport mechanisms and is crucial for maintaining the identities of different cellular organelles. Non-vesicular lipid transport has a crucial role in intracellular lipid trafficking and distribution, but its underlying mechanisms remain unclear. Lipid-transfer proteins (LTPs), which regulate diverse lipid-mediated cellular processes and accelerate vectorial transport of lipid monomers between membranes in vitro, could potentially mediate non-vesicular intracellular lipid trafficking. Understanding the mechanisms by which lipids are transported and distributed between cellular membranes, and elucidating the role of LTPs in intracellular lipid transport and homeostasis, are currently subjects of intensive study.

Structure and function of phosphatidylcholine transfer protein (PC-TP)/StarD2

Phosphatidylcholine transfer protein (PC-TP) is a highly specific soluble lipid binding protein that transfers phosphatidylcholine between membranes in vitro. PC-TP is a member of the steroidogenic acute regulatory protein-related transfer (START) domain superfamily. Although its biochemical properties and structure are well characterized, the functions of PC-TP in vivo remain incompletely understood. Studies of mice with homozygous disruption of the Pctp gene have largely refuted the hypothesis that this protein participates in the hepatocellular selection and transport of biliary phospholipids, in the production of lung surfactant, in leukotriene biosynthesis and in cellular phosphatidylcholine metabolism. Nevertheless, Pctp(-/-) mice exhibit interesting defects in lipid homeostasis, the understanding of which should elucidate the biological functions of PC-TP.

Effect of cholesterol and dipalmitoyl phosphatidylcholine enrichment on the kinetics of Na-Li exchange of human erythrocytes

The effects of cholesterol loading and depletion and of a 10% replacement of native phosphatidylcholine by dipalmitoyl phosphatidylcholine (di 16:0-PC) on kinetic properties of human red cell Na-Li exchange have been studied. Compared to control erythrocytes (cholesterol/phospholipid ratio (C/P = 0.8-0.9], Vmax of phloretin-sensitive Li uptake and of Li efflux stimulated by extracellular Na (Nao) were reduced by 15-30% in cholesterol-loaded red cells (C/P = 1.05-1.33). The apparent Km values for external Li (Lio) and for internal Li (Lii) were decreased by about one-third in these cells. Cholesterol depletion (C/P = 0.7) exerted opposite effects on the kinetics of Nao-dependent Li efflux. On augmenting C/P from 0.66 to 1.0, Vmax of Nao-dependent Li efflux was reduced by about 30%; increasing C/P above 1.0 caused no further lowering of Vmax.Li leakage rates monotonically decreased over the whole range of C/P ratios examined (0.66-1.3). This indicates that Na-Li exchange and Li leak are differentially affected by cholesterol. Incorporation of di 16:0-PC (replacement of 3% of total red cell phospholipids) caused similar kinetic alterations of Na-Li exchange as a rise in membrane cholesterol by 20-50%. Notably, selective incorporation of di 16:0-PC into the outer monolayer increased both intra- and extracellular Li binding affinities of Na-Li exchange and lowered its maximum velocity. Thus, both di 16:0-PC enrichment and cholesterol loading exerted an uncompetitive type of transport inhibition.(ABSTRACT TRUNCATED AT 250 WORDS)

Lipid transfer proteins

Translocations of various lipid species between membranes have been extensively studied. The transport of water-insoluble lipids is thought to require the participation of lipid transfer proteins (LTP). Several LTP, differing in their physiochemical properties and substrate specificities, have been purified to homogeneity from blood plasma, eucaryotic and procaryotic cells. Depending on their site of activity, they can be classified as extracellular and intracellular LTP. Extracellular LTP are found in the blood plasma and intracellular LTP, which were originally characterized as phospholipid exchange proteins, are ubiquitous in nature. Despite the enormous knowledge about their physicochemical properties and their function in vitro their physiological role has not been clearly demonstrated. However, their ubiquitous occurrence indicates an important role in cellular events. This review gives an overview of this interesting category of proteins, which are able to catalyze inter-membrane transfer and exchange of lipids.

Purification and characterization of glycolipid transfer protein from bovine brain

Bovine brain contains a lipid transfer protein that is specific for neutral glycosphingolipids and gangliosides but does not stimulate phospholipid or neutral lipid intermembrane transfer (Brown, R.E., Stephenson, F.A., Markello, T., Barenholz, Y. and Thompson, T.E. (1985) Chem. Phys. Lipids 38, 79-93). This report describes a new procedure for purifying glycolipid transfer protein from bovine brain as well as a characterization of the resulting protein. Chief among the newly introduced approaches are dye-ligand and fast protein cation-exchange liquid chromatography. Other modifications include increasing the overall scale of purification, incorporating a pH precipitation step and adding different proteinase inhibitors. The resulting procedure simplifies and accelerates the purification process while yielding a homogeneous protein. The purified protein has a molecular weight near 23 kDa as estimated by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Chromatofocusing reveals that glycolipid transfer protein activity co-elutes with the 23 kDa protein and has an isoelectric point near pH 9.0. A similar isoelectric point is observed using denaturing isoelectric focusing conditions. The protein's amino acid composition reveals high levels of amino acids with non-polar side chains (48%). Based on the findings reported here and on previously published data, bovine brain glycolipid transfer protein has been compared to other lipid transfer proteins as well as lysosomal sphingolipid activator proteins.

Replacement of molecular species of phosphatidylcholine: influence on erythrocyte Na transport

The phosphatidylcholine-specific transfer protein (PC-Tp) from bovine liver was used to replace endogeneous erythrocyte phosphatidylcholine (PC) with various amounts of five different molecular species of PC. Furosemide-sensitive (FS) Rb uptake, Na-Li exchange, and Na-K pump rates were considered in relation to the nature and extent of those replacements. Changes in fatty acid contents of PC after incorporation of different molecular species fell within a variation range (10-30%) similar to that found in large populations of healthy individuals. Di16:0-PC accelerated Na-Li exchange and FS Rb uptake by approximately 40 and 25%, respectively. Some reduction (20%) in FS Rb uptake was seen in 16:0/18:2-PC-enriched erythrocytes. Incorporation of 16:0/22:6-PC accelerated Na-Li exchange and FS Rb uptake by greater than 40 and 20%, respectively. Apart from inhibitory effects of 16:0/18:1-PC and di16:0-PC (24 and 19%, respectively) the Na-K pump rate was virtually unchanged by incorporation of different PC molecular species. Exogeneous PC molecules are exclusively inserted in the outer membrane leaflet and, particularly in the case of di16:0-PC, migrate slowly to the cytoplasmic leaflet. Prolonged incubation of cells (up to 21 h) after replacement with di16:0-PC showed that both Na-Li exchange and FS Rb uptake rates responded differently to redistribution of newly inserted molecules over both bilayer halves. Compared with cells exhibiting a selective incorporation of di16:0-PC in the outer monolayer, additional enrichment with disaturated species in the inner monolayer accelerated FS Rb uptake, whereas Na-Li exchange rate reverted to control values. It is concluded that small changes in fatty acid composition of PC induced by limited replacement of phospholipid molecular species can cause considerable changes in Na-Li exchange rate and FS Rb uptake. Differences in phospholipid molecular species composition could contribute to known interindividual variability of both Na-Li exchange and Na-K cotransport.

General kinetic model for protein-mediated phospholipid transfer between membranes

Phospholipid transfer protein catalyzes the transfer of phospholipids between bilayer membranes. A general model is developed for describing the kinetics of this process. While previous models derive detailed expressions only for the initial rate of transfer from donor to acceptor membranes, this model takes into account donor-to-donor, acceptor-to-acceptor, and acceptor-to-donor transfers, in addition to the usual donor-to-acceptor transfer. The apparent rate of transfer along any of these specific routes is given as the product of the total rate of transfer (the sum of the rates of transfer along all four routes) and a probability function uniquely defined for each route. The model explains adequately the effects of membrane concentration on phospholipid transfer activity as well as the consequences of varying membrane surface charge and size. Using bovine liver phosphatidylcholine transfer protein, the model is applied to the kinetic analysis of phosphatidylcholine transfer between two populations of small unilamellar vesicles. Rates of protein-catalyzed phosphatidylcholine transfer between vesicles with identical phosphatidic acid content (2 or 6 mol%) are determined experimentally as a function of total vesicle concentration to calculate apparent dissociation constants and maximum rates of transfer; apparent rates of transfer between various combinations of vesicles containing 2 or 6 mol% phosphatidic acid are then deduced from the derived velocity expression. Reasonably good agreement is seen between theoretical apparent rate-vesicle concentration relationships and those measured experimentally. The results support the general treatment of the kinetics of protein-mediated phospholipid transfer and permit an estimation of useful kinetic parameters.

The effect of polyphosphoinositides and phosphatidic acid on the phosphatidylinositol transfer protein from bovine brain: a kinetic study

The phosphatidylinositol transfer protein from bovine brain (PI-TP) has lipid transfer characteristics which make it well suited to maintain phosphatidylinositol (PI) levels in intracellular membranes (Van Paridon, P.A., Gadella, Jr., T.W.J., Somerharju, P.J. and Wirtz, K.W.A. (1987) Biochim. Biophys. Acta 903, 68-77). Using a continuous fluorimetric transfer assay we have investigated in what way phosphatidylinositol 4-phosphate (PIP), phosphatidylinositol 4,5-bisphosphate (PIP2) and phosphatidic acid (PA) affect the transfer activity of this protein in model systems. The effects were analysed by application of a kinetic model which yielded the association constant (K) and dissociation rate constant (k-) for the PI-TP/vesicle complex. Incorporation of PA, PIP and PIP2 into the phosphatidylcholine-containing vesicles increased the association constant solely by diminishing the dissociation rate constant. This effect could be completely accounted for by changes in the membrane surface charge density. In contrast to the inhibitory effect of PA, the inhibition caused by PIP2 was completely abolished by the addition of neomycin, in agreement with the observed preferential binding of this polyamine antibiotic to PIP2. A rise in pH from 5.5 to 8 drastically reduced the association constant for vesicles containing 16 mol% PA (e.g., from 38 to 2 mM-1), without affecting the Vmax. This effect could be mainly attributed to an increase in the negative charge on PI-TP (isoelectric point 5.5), resulting in an enhanced repulsion. Increasing the negative membrane surface charge at pH 7.4 had the opposite effect. This is interpreted to indicate that the membrane interaction site on PI-TP must be positively charged, overcoming the repulsive forces between PI-TP and the vesicle. Addition of PIP2 micelles as a third component in the transfer assay strongly inhibited PI-TP transfer activity. The extent of inhibition suggests a very high affinity of PI-TP for this lipid.

Effect of acceptor membrane phosphatidylcholine on the catalytic activity of bovine liver phosphatidylcholine transfer protein

Protein-mediated transfer of phosphatidylcholine (PC) by bovine liver phosphatidylcholine transfer protein (PC-TP) was examined using a vesicle-vesicle assay system. Donor and acceptor membranes were prepared from Escherichia coli phospholipids and limiting amounts of egg yolk PC. PC transfer between vesicles of E. coli lipid/egg PC was markedly higher than transfer of PC from vesicles of E. coli lipid/egg PC to vesicles of E. coli lipid. Kinetic parameters of the interaction between PC-TP and E. coli lipid vesicles with or without PC was investigated. The apparent dissociation constants of the complex formed between PC-TP and these vesicles were determined kinetically and from double-reciprocal plots of intrinsic PC-TP fluorescence intensity increase versus vesicle concentration. The magnitude of the dissociation constant decreased as the PC content of the vesicles increased from 0 to 5 mol%. In addition, kinetic analysis revealed that the presence of PC in acceptor vesicles increased both the association and dissociation of PC-TP from vesicles. The effect of membrane PC molecules on transfer rates was examined using bis-phosphatidylcholine, a dimeric PC molecule which is not transferred by PC-TP. Rates of PC transfer to acceptor vesicles comprised of E. coli lipid/bis-PC were virtually identical to rates observed with acceptors vesicles prepared from E. coli lipid. The results suggest that transfer of PC by PC-TP is enhanced only when insertion of protein-bound PC occurs concurrently with the extraction of a molecule of membrane PC, i.e., a concerted, one-step catalytic mechanism for phospholipid exchange.

Design, synthesis, and characterization of bis-phosphatidylcholine, a mechanistic probe of phosphatidylcholine transfer protein catalytic activity

The design, synthesis, and characterization of 1-(17,18-dithiatetratriacontandioyl)-bis(2-hexadecanoyl-sn-glycero -3- phosphocholine) is described. Bis-phosphatidylcholine is a dimeric phospholipid comprised of two glycerophosphocholine groups linked together by a disulfide bond at the distal ends of the sn-1 fatty acyl chains. Electron microscopy and [14C]glucose trapping studies indicate that hydrated dispersions of bis-phosphatidylcholine form closed, spherical structures which have diameters in the range of 125-500 nm. Sensitivity to phospholipase hydrolysis suggests that this bipolar lipid is organized in a membrane such that the two polar head groups of the molecular are oriented at the same surface of the membrane. Using conditions in which bovine liver phosphatidylcholine transfer protein transfers both unsaturated and saturated diacyl phosphatidylcholines between fluid phosphatidylcholine vesicles, no transfer of the bipolar phospholipid is observed. The lack of activity toward bis-phosphatidylcholine suggests that this molecule may be a useful tool for elucidating the role of membrane phosphatidylcholine in the catalytic mechanism of the phosphatidylcholine transfer protein.

Identification of an essential lysine residue in the phosphatidylcholine-transfer protein from bovine liver by modification with phenylisothiocyanate

Modification by phenylisothiocyanate inhibits the phosphatidylcholine-transfer protein from bovine liver. Inhibition by this apolar reagent was greatly enhanced in the presence of vesicles, indicating that an effective modification of an essential lysine residue(s) from the interface may occur. Labeling with [14C]phenylisothiocyanate demonstrated that Lys55 was the major site of modification. We propose that Lys55 is part of the peptide segment that interacts with the membrane.

The rate of uptake and efflux of phosphatidylcholine from human erythrocytes depends on the fatty acyl composition of the exchanging species

The rate of uptake of radioactive phosphatidylcholine molecules of different fatty acid composition in intact erythrocytes as facilitated by a phosphatidylcholine-specific transfer protein has been studied. When trace amounts of radiolabeled phosphatidylcholine molecules are present in donor vesicles consisting of egg phosphatidylcholine and cholesterol, the transfer of the radiolabeled species depends strongly on their fatty acyl composition: dipalmitoylphosphatidylcholine is transferred at the lowest rate, 1-saturated-2-unsaturated species are transferred faster and the highest rate is observed for dioleoyl phosphatidylcholine. Transfer of the various phosphatidylcholine molecules was measured furthermore using donor systems in which the bulk phosphatidylcholine was varied in its fatty acyl composition. Also in this type of experiment, the transfer protein preferentially stimulated transfer of unsaturated phosphatidylcholine molecules, especially from an environment containing more saturated molecules. Finally, the efflux of labeled phosphatidylcholine from intact erythrocytes to plasma in the absence of the phosphatidylcholine-specific transfer protein was studied and it became clear that in this case the nature of the effused molecules itself, rather than the composition of the bulk lipids, determined the effuse rates. An important conclusion to be drawn from these experiments is that radiolabeled phosphatidylcholine molecules, when used as markers for phospholipid exchange or transfer, should resemble in their fatty acid composition the composition of the bulk lipid in order to provide reliable data on rates and extents of the process studied.

Phospholipid transfer proteins: mechanism of action

Phospholipid transfer proteins are generally localized in the cytosolic fraction of cells and are capable of catalyzing the flux of phospholipid molecules among membranes. Artificial membranes also participate in protein-catalyzed phospholipid movements. In this review the major phospholipid transfer proteins are discussed with respect to their phospholipid substrate specificity and the contributions of membrane physical properties to this process. The phenomenon of net transfer of phospholipids is described. The use of various kinetic approaches to the study of these catalysts is reviewed. A detailed consideration of the distinct phospholipid binding and membrane interaction domains of one phospholipid transfer protein is presented. Finally, some recent applications of phospholipid transfer proteins to the examination of membrane structure and function and further directions for the continued research activity with this class of proteins are summarized.

Intracellular localization of phospholipid transfer activity in Rhodopseudomonas sphaeroides and a possible role in membrane biogenesis

The cellular content of phospholipid transfer activity in Rhodopseudomonas sphaeroides was examined as a function of both oxygen partial pressure and light intensity used for growth. Cells grown under high light conditions (100 W/m2) had over two times the cellular level of phospholipid transfer activity when compared with cells grown under other conditions. Although cells grown under low light conditions (3 W/m2) had the lowest amount of total phospholipid transfer activity, they had the highest level (49%) of membrane-associated transfer activity. The soluble phospholipid transfer activity was further localized into periplasmic and cytoplasmic fractions. The distribution of phospholipid transfer activity in cells grown under medium light intensity (10 W/m2) was calculated as 15.1% membrane-associated, 32.4% in the periplasm, and 52.5% in the cytoplasm. The phospholipid transfer activities in the periplasmic and cytoplasmic fractions had distinctly different properties with respect to their molecular weights (56,000 versus 27,000) and specificities of transfer (phosphatidylethanolamine greater than phosphatidylglycerol versus phosphatidylglycerol greater than phosphatidylethanolamine).

Lipid molecular shape affects erythrocyte morphology: a study involving replacement of native phosphatidylcholine with different species followed by treatment of cells with sphingomyelinase C or phospholipase A2

In a previous report it was shown that the replacement of native erythrocyte phosphatidylcholine (PC) with different PC species which have defined acyl chain compositions can lead to morphological changes (Kuypers, F.A., W. Berendsen, B. Roelofsen, J. A. F. Op den Kamp, and L.L.M. van Deenen, 1984, J. Cell Biol., 99:2260-2267). It was proposed that differences in molecular shape between the introduced PC species and normal erythrocyte PC caused the membrane to bend outwards or inwards, depending on the shape of the PC exchanged. To support this proposal, two requirements would have to be fulfilled: the exchange reaction would take place only with the outer lipid monolayer of the erythrocyte, and the extent of lipid transbilayer movement would be restricted. If this theory is correct, any treatment causing unilateral changes in lipid molecular shape should lead to predictable morphological changes. Since this hypothesis is a refinement of the coupled bilayer hypothesis, but so far lacks experimental support, we have sought other means to change lipid molecular shape unilaterally. Shape changes of human erythrocytes were induced by the replacement of native PC by various PC species using a phosphatidylcholine-specific transfer protein: by hydrolysis of phospholipids in intact cells using sphingomyelinase C or phospholipase A2, and by the combination of both procedures. The morphological changes were predictable; additive when both treatments were applied, and explicable on the basis of the geometry of the lipid molecules involved. The results strongly support the notion that lipid molecular shape affects erythrocyte morphology.

Properties of a specific glycolipid transfer protein from bovine brain

A transfer protein specific for glycolipids has been isolated from bovine brain. As judged by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis, the protein is 68% pure and has a molecular weight of 20 000. Three different assays were employed to study the protein's specificity and glycolipid binding properties. The protein transferred several different neutral glycosphingolipids and ganglioside GM1 equally well, but failed to accelerate phosphatidylcholine or sphingomyelin intervesicular movement. The protein's ability to interact with glycolipids was strongly influenced by the physical properties of the matrix phospholipid in which the glycolipids reside. Both the phase state of the phospholipid matrix and bilayer curvature affected glycolipid intervesicular transfer rates. Protein binding to phospholipid vesicles containing either tritium-labeled or pyrene-labeled glucosylceramide could not be demonstrated by density gradient centrifugation or fluorescence energy transfer measurements, respectively. A specific association of the transfer protein for pyrene-labeled glucosylceramide was found when the fluorescence emission of the pyrene excimer-to-monomer ratio was measured suggesting that a portion of the fluorescent glycolipid was being sequestered from the phospholipid vesicles and was binding to the freely soluble protein.

Chemical modification of methionine residues of the phosphatidylcholine transfer protein from bovine liver. A spin-label study

The role of methionine residues in the interaction of the phosphatidylcholine transfer protein from bovine liver with phospholipid vesicles was investigated by specific modification of these residues with iodoacetamide. The modified protein was digested with cyanogen bromide in order to determine which methionine residues had become resistant to this cleavage. Automated Edman degradation on the digest indicated that after 72 h of reaction, Met-1 was modified for 80%, Met-73 for 50%, Met-109 for 20%, whilst Met-173 and Met-203 were found to be unmodified. This distinct modification did not result in any loss of phosphatidylcholine transfer activity. The interaction of the phosphatidylcholine transfer protein with phospholipid vesicles was investigated by making use of electron spin resonance spectroscopy. The interaction of unmodified protein with vesicles composed of phosphatidylcholine/phosphatidic acid/spin-labeled phosphatidylethanolamine (79:16:5, mol%) or composed of phosphatidylserine/spin-labeled phosphatidylethanolamine (95:5, mol%), gave an increase of about 50% in the rotation correlation time. A similar increase was observed with the modified protein. This interaction was further investigated by labeling Met-1 and Met-73 in the transfer protein with iodoacetamidoproxyl spin-label. Spin-labeling did not inactivate the transfer protein. In addition, the electron spin resonance spectra of the spin-labeled protein were not affected upon addition of vesicles composed of phosphatidylcholine/phosphatidic acid (80:20, mol%). These experiments strongly suggest that Met-1 and Met-73 are not part of the site that interacts with the membrane.

Shape changes in human erythrocytes induced by replacement of the native phosphatidylcholine with species containing various fatty acids

Phosphatidylcholine-specific transfer protein from beef liver has been used to replace native phosphatidylcholine (PC) molecules from intact human erythrocytes by a variety of PC species differing in fatty acid composition. These replacements changed neither the total phospholipid content of the membrane, nor the composition of this fraction in terms of the various phospholipid classes. The morphology of the erythrocyte was not modified when native PC was replaced by 1-palmitoyl,2-oleoyl PC, 1-palmitoyl,2-linoleoyl PC, egg PC, or PC isolated from rat liver microsomes. Replacement with the disaturated species 1,2-dimyristoyl PC, 1,2-dipalmitoyl PC, and 1,2-distearoyl PC resulted in the formation of echinocytes and, at higher levels of replacement, in spheroechinocytes. Echinocyte-like erythrocytes were also observed after replacement with 1-palmitoyl,2-arachidonoyl PC, whereas stomatocytes were formed upon replacement with PC species containing two unsaturated fatty acids, e.g., 1,2-dioleoyl PC and 1,2-dilinoleoyl PC. The observations show that the erythrocyte membrane structure and the overall discoid cell shape of the human erythrocyte are optimally stabilized by PC species that contain one saturated and one mono- or diunsaturated fatty acid, and that the cell tolerates only limited variations in the species composition of its PC.

Bovine brain phosphatidylinositol transfer protein. Effects of pH, ionic strength and lipid composition on transfer activity

Phosphatidylinositol and phosphatidylcholine are transferred between bilayer membranes in the presence of a specific phosphatidylinositol transfer protein isolated from bovine brain. The effects of pH, ionic strength and lipid composition on the rate of transfer of these phospholipids between small unilamellar vesicles have been investigated. At low ionic strength, phosphatidylinositol transfer between vesicles prepared from phosphatidylcholine and 5 mol% phosphatidylinositol was maximal at about pH 5 and moderately dependent on hydrogen ion concentration in more alkaline regions. A similar dependence on pH was noted for phosphatidylcholine transfer between membranes containing phosphatidylcholine or mixtures of phosphatidylcholine and 5 mol% phosphatidylinositol, phosphatidic acid, phosphatidylglycerol, phosphatidylethanolamine or stearylamine. The rate of transfer between anionic vesicles was somewhat higher than that between neutral or cationic vesicles. At higher ionic strength the transfer reactions in neutral and alkaline regions were less sensitive to pH. Phospholipid transfers between vesicles containing 5 mol% of anionic lipid increased sharply as ionic strength decreased below 0.1. In contrast, phosphatidylcholine transfer between membranes which contained only zwitterionic phospholipids or 5 mol% stearylamine was unaffected by variations of ionic strength. Irrespective of the lipid composition of membranes, pH affected both the apparent Km and Vmax, while ionic strength generally affected the apparent Vmax. These results indicate a significant role of electrostatic interactions in the phospholipid transfer catalyzed by phosphatidylinositol transfer protein.

Static and time-resolved fluorescence studies of fluorescent phosphatidylcholine bound to the phosphatidylcholine transfer protein of bovine liver

Phosphatidylcholine analogues containing a cis- parinaroyl chain at the sn-1, sn-2, or both sn-1 and sn-2 positions (1-PnA-PC, 2-PnA-PC, and diPnA -PC, respectively) have been used to investigate the lipid binding site of the phosphatidylcholine transfer protein (PC-TP) from bovine liver by fluorometric techniques. Binding of these fluorescent lipids to the protein was registered by measuring the enhancement of parinaroyl fluorescence and the quenching of the tryptophanyl fluorescence. The fluorescence intensity of 1-PnA-, 2-PnA- and diPnA -PC bound to PC-TP was proportional to the chromophore content. The energy-transfer efficiency between the tryptophan residues and the bound chromophores was approximately 40% for 1-PnA- and 2-PnA-PC and 60% for diPnA -PC. Quenching of the tryptophanyl fluorescence was, in part, accounted for by a decrease of the fluorescence lifetimes. The orientation of the 1 and 2 fatty acyl chains of the PnA-PC analogues on the transfer protein was analyzed by time-resolved fluorescence anisotropy measurements. The fluorescence anisotropy decayed according to a single exponential function yielding a rotational correlation time of 26 ns for 1-PnA-PC, 11 ns for 2-PnA-PC, and 15 ns for diPnA -PC. These correlation times indicate that both fatty acyl chains are immobilized at different positions on the protein. From the difference in correlation time we propose that the shape of the phosphatidylcholine transfer protein is ellipsoidal (axial ratio congruent to 2.5) with the 1 fatty acyl chain oriented parallel to the long symmetry axis and having an angle of 60-90 degrees with the 2 fatty acyl chain.

The membrane of intact human erythrocytes tolerates only limited changes in the fatty acid composition of its phosphatidylcholine

Using the phosphatidylcholine specific transfer protein from bovine liver, native phosphatidylcholine from intact human erythrocytes was replaced by a variety of different phosphatidylcholine species without altering the original phospholipid and cholesterol content. The replacement of native phosphatidylcholine by the disaturated species, 1,2-dipalmitoyl- and 1,2-distearoylphosphatidylcholine, proceeded at a low rate and extensive replacement could only be achieved by repeatedly adding fresh donor vesicles. The replacement by disaturated molecules was accompanied by a gradual increase in osmotic fragility of the cells, finally resulting in hemolysis when 40% of the native PC had been replaced. Up to this lytic concentration, the replacement did not affect the permeability of the membrane for potassium ions. Essentially, all of the PC in the outer monolayer of the membrane could be replaced by 1-palmitoyl-2-oleoyl- and 1-palmitoyl-2-linoleoylphosphatidylcholine. These replacements did not alter the osmotic fragility of the cells, nor the K+ permeability of the membrane. Increasing the total degree of unsaturation of the phosphatidylcholine species modified the properties of the membrane considerably. Replacement by 1,2-dilinoleoylphosphatidylcholine resulted in a progressive increase in osmotic fragility and hemolysis started to occur after 30% of the native PC had been replaced by this species. K+ permeability was found to be slightly increased in this case. Cells became leaky for K+ upon the introduction of 1-palmitoyl-2-arachidonoylphosphatidylcholine in the membrane. The increased permeability was also reflected by an apparent increase in the resistance of the cells against osmotic shock. The conclusions to be drawn are that (i) 1-palmitoyl-2-oleoyl- and 1-palmitoyl-2-linoleoylphosphatidylcholine are species which fit most optimally into the erythrocyte membrane; (ii) loss of membrane stability results from an increase in the degree of saturation of phosphatidylcholine (unsaturation index greater than 0.5) and (iii) the permeability is enhanced by increasing the content of highly unsaturated species (unsaturation index greater than 1.0).

Phospholipid exchange activity in developing rat brain

Phospholipid exchange activity has been determined in the supernatant fraction of rat brain from birth through to maturity by measuring the protein-catalysed transfer of total and individual 32P-labelled phospholipids from microsomal membranes to mitochondria, and the transfer of [14C]phosphatidylcholine from liposomes to mitochondria. Transfer activity has also been compared in brain and liver supernatant. Overall phospholipid exchange activity in the brain increased only slightly with age. The activity at birth was 75% of the adult value. However, the transfer of individual phospholipids showed markedly different trends during postnatal brain development. The transfer of phosphatidylinositol (PI) and ethanolamine phospholipids increased postnatally to a maximum at 9 days of age, with lowest values in adult brain. Phosphatidylcholine (PC) transfer increased from 9 days to reach maximum values in the mature brain. The transfer of sphingomyelin was highest immediately after birth. PI transfer activity was higher in brain than liver, while PC and ethanolamine phospholipid transfer activity was higher in liver. The heterogeneity of phospholipid exchange proteins in central nervous system tissue is reflected in the developmental changes in exchange activity towards individual phospholipids. The various exchange proteins appear to have separate induction mechanisms. The presence of exchange-protein activity from birth in the rat indicates the functional importance of phospholipid transport during cell acquisition and membrane proliferation. Activity is not primarily associated with membrane formation such as the formation of the myelin sheath, and therefore is more likely to be involved in the process of phospholipid turnover.

The influence of the internal content of negatively charged liposomes on their interaction with high-density lipoprotein

The release of the internal content of negatively charged phosphatidylcholine/phosphatidylserine vesicles under the influence of high density lipoprotein was studied. Under standard conditions (the same composition outside and inside the compartment) the leakage of negative liposomes increased significantly. However, a high internal concentration of calcein provoked a sealing effect, exhibited both in sucrose and in calcein release. This sealing effect is not related to the size of vesicles, the fluidity of the membrane, the distribution of phosphatidylserine molecules, or the membrane potential. Our data indicate that surface potential influences this effect, probably in addition to a lateral pressure effect such as with cholesterol. The surface potential, as measured by the water-lipid partition coefficient of fatty acids, is strongly affected by internal ionic strength when liposomes contain calcein as well as other polyanions (6-carboxyfluorescein, sodium citrate).

Protein-mediated lipid transfer. The effects of lipid-phase transition and of charged lipids

The protein-mediated phospholipid exchange between small unilamellar vesicles was investigated by fluorescence polarization measurements with diphenylhexatriene as optical probe. Thermotropic phase-transition measurements were taken after mixing two vesicle preparations of distinct and different phase-transition temperatures or having different states of charge. From the heights of each phase-transition step, we were able to follow the lipid-exchange process in the presence, as well as in the absence (natural exchange), of so-called transfer protein isolated from beef liver. A strong enhancement of the lipid transfer was observed at the corresponding lipid-phase-transition temperature, which is explained by the presence of fluctuating fluid and ordered domains co-existing at the lipid-phase-transition temperature. A unidirectional lipid transfer of the neutral component was observed between negatively charged phosphatidic acid and neutral phosphatidylcholine vesicles. Fluorescence polarization measurements showed the disappearance of the phosphatidylcholine phase transition, whereas the phosphatidic acid phase transition broadened and its phase transition temperature became lower.

Identification of the lipid-binding site of phosphatidylcholine-transfer protein with phosphatidylcholine analogs containing photoactivable carbene precursors

The lipid binding site of the phosphatidylcholine transfer protein from bovine liver has been investigated by use of phosphatidylcholine analogs which carry a diazirinophenoxy group linked to the omega-carbon of either the sn-2-[1-14C]hexanoyl (PC I) or sn-2-[1-14C]undecanoyl chain (PC II). Photolysis of the PC I(PC II)-transfer protein complex resulted in a covalent coupling of 30-40% of the label to the protein as shown by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Upon mild alkaline treatment of the photolysed complex the protein containing covalently coupled 14C-label was separated from the noncoupled 14C-label by gel permeation chromatography. The 14C-labeled protein was degraded with protease from Staphylococcus aureus, trypsin and cyanogen bromide and specific 14C-labeled peptides were sequenced by automated Edman degradation. Major sites of coupling shown by release of radioactivity were identified as Tyr54 and the peptide segment Val171-Phe-Met-Tyr-Tyr-Phe-Asp177. Both PC I and PC II coupled extensively to Tyr54 (90% and 50% of total labeling, respectively). The remainder of the radioactivity was released from the peptide Val171-Asp177 with a distinct difference in in the pattern of release depending on whether PC I or PC II were used. Thus, coupling occurred preferentially to Tyr175 and Asp177 with PC I while Val171 and Met173 were labeled preferentially with PC II. This shift in coupling is compatible with an increase of 0.6 nm for the sn-2-fatty-acyl chains of PC I and II, assuming that the peptide Val171-Asp177 has adopted the strongly predicted beta-strand configuration. These data have been interpreted in terms of the localization of phosphatidylcholine in the phosphatidylcholine transfer protein.

Modulation of phospholipid transfer protein activity. Inhibition by local anesthetics

The transfer of phospholipid molecules between biological and synthetic membranes is facilitated by the presence of soluble catalytic proteins, such as those isolated from bovine brain which interacts with phosphatidylinositol and phosphatidylcholine and from bovine liver which is specific for phosphatidylcholine. A series of tertiary amine local anesthetics decreases the rates of protein-catalyzed phospholipid transfer. The potency of inhibition is dibucaine greater than tetracaine greater than lidocaine greater than procaine, an order which is compared with and identical to those for a wide variety of anesthetic-dependent membrane phenomena. Half-maximal inhibition of phosphatidylinositol transfer by dibucaine occurs at a concentration of 0.18 mM, significantly lower than the concentration of 1.9 mM required for half-maximal inhibition of phosphatidylcholine transfer activity of the brain protein. Comparable inhibition of liver protein phosphatidylcholine transfer activity is observed at 1.6 mM dibucaine. For activity measurements performed at different pH, dibucaine is more potent at the lower pH values which favor the equilibrium toward the charged molecular species. With membranes containing increasing molar proportions of phosphatidate, dibucaine is increasingly more potent. No effect of Ca2+ on the control transfer activity or the inhibitory action of dibucaine is noted. These results are discussed in terms of the formation of specific phosphatidylinositol or phosphatidylcholine complexes with the amphiphilic anesthetics in the membrane bilayer.

Tissue distribution and subcellular localization of phosphatidylcholine transfer protein in rats as determined by radioimmunoassay

A radioimmunoassay for the phosphatidylcholine-transfer protein from rat liver was used to measure levels of PC-transfer protein in rat tissues. The assay as described before (Teerlink, T., Poorthuis, B.J.H.M., Van der Krift, T.P. and Wirtz, K.W.A., Biochim. Biophys. Acta 665 (1981) 74-80) was modified in order to measure PC-transfer protein in tissue homogenates and subcellular membrane fractions. To this end both a detergent (Triton X-100) and a proteolytic enzyme inhibitor (aprotinin) were added to the assay medium. The radioimmunoassay measured levels of PC-transfer protein in the range of 5-50 ng and was specific for PC-transfer protein from rat tissues. Subcellular distribution studies showed that in 10% (w/v) homogenates of liver approximately 60% of the PC-transfer protein was present in the 105000 X g supernatant fraction, the remainder being evenly distributed over the particulate fractions. PC-transfer protein associated with the particulate fractions was almost completely removed by a single washing step, suggesting a dynamic equilibrium between membrane-bound and soluble PC-transfer protein. Both 105000 X g supernatants and homogenates of various rat tissues were assayed. The highest levels of PC-transfer protein were measured in liver and intestinal mucosa. Lower values were found in kidney, spleen and lung, whereas heart and brain contained hardly any PC-transfer protein. PC-transfer protein levels in regenerating rat liver did not differ significantly from levels in normal liver. In fetal lung a change in PC-transfer protein content during development was observed, with a clear maximum 2 days before term, suggesting an involvement of PC-transfer protein in the secretion of lung surfactant.

Prediction of secondary structural elements in the phosphatidylcholine-transfer protein from bovine liver

Secondary structural elements of the phosphatidylcholine-transfer protein from bovine liver have been predicted from its primary structure with the aid of two computerized methods. The predicted alpha-helix and beta-strand content have been compared with the values derived from circular dichroism spectra. The hydrophobicity profile (Rose plot) of the protein indicated that the supposed lipid-binding site occurs in the most hydrophobic region. The predicted secondary structural elements have been folded in a tentative model of the protein molecule according to its hydrophobicity profile.

A new fluorimetric method to measure protein-catalyzed phospholipid transfer using 1-acyl-2-parinaroylphosphatidylcholine

A new, simple and versatile method to measure phospholipid transfer has been developed, based on the use of a fluorescent phospholipid derivative, 1-acyl-2-parinaroylphosphatidylcholine. Vesicles prepared of this phospholipid show a low level of fluorescence due to interaction between the fluorescent groups. When phospholipid transfer protein and vesicles consisting of non-labeled phosphatidylcholine are added the protein catalyzes an exchange of phosphatidylcholine between the labeled donor and non-labeled acceptor vesicles. The insertion of labeled phosphatidylcholine into the non-labeled vesicles is accompanied by an increase in fluorescence due to abolishment of self-quenching. The initial rate of fluorescence enhancement was found to be proportional to the amount of transfer protein added. This assay was applied to determine the effect of membrane phospholipid composition on the activity of the phosphatidylcholine-, phosphatidylinositol- and non-specific phospholipid transfer proteins. Using acceptor vesicles of egg phosphatidylcholine and various amounts of phosphatidic acid it was observed that the rate of phosphatidylcholine transfer was either stimulated, inhibited or unaffected by increased negative charge depending on the donor to acceptor ratio and the protein used. In another set of experiments acceptor vesicles were prepared of phosphatidylcholine analogues in which the ester bonds were replaced with ether bonds or carbon-carbon bonds. Assuming that only a strictly coupled exchange between phosphatidylcholine and analogues gives rise to the observed fluorescence increase, orders of substrate preference should be established for the phosphatidylcholine- and phosphatidylinositol transfer proteins.

Modification of the phosphatidylcholine-transfer protein from bovine liver with butanedione and phenylglyoxal. Evidence for one essential arginine residue

1. Modification of arginine residues with 2,3-butanedione and phenylglyoxal completely inhibits the transfer activity of the phosphatidylcholine transfer protein from bovine liver. Removal of borate and butanedione leads to a slow reactivation of the protein. 2. Both alpha-dicarbonyl reagents modify three of the ten arginine residues present per protein molecule. The extent of modification is linearly related to the loss of activity. 3. Inactivation with butanedione is greatly diminished when the protein is bound to strongly negatively charged vesicles. Under these conditions a rapid modification of two arginine residues is observed. This suggests that the transfer protein contains one arginine residue essential for activity, probably as a binding site for the negatively charged phosphate group of the phosphatidylcholine molecule. 4. This study provides convincing evidence that arginine residues may play an essential role in phospholipidprotein interactions.

Intermembrane phospholipid fluxes catalyzed by bovine brain phospholipid exchange protein

Bovine brain phospholipid exchange protein catalyzes the transfer of phosphatidylinositol and phosphatidylcholine between two populations of single bilayer vesicles. The inclusion of lactosylceramide in one of the vesicle populations and the ability to precipitate those vesicles in the presence of Ricinus communis agglutinin assures the quantitative separation of donor and acceptor vesicles following incubation with exchange protein. When both vesicle populations contain phosphatidylinositol and phosphatidylcholine and transfers are monitored in both directions, the flux of phosphatidylinositol (or phosphatidylcholine) in the forward direction equals that in the reverse. When one of the vesicle populations initially lacks phosphatidylinositol, a net unidirectional transfer of that phospholipid occurs. Concurrently, a compensatory flux of phosphatidylcholine takes place in the opposite direction, such that the bidirectional fluxes of total phospholipid are equal. A net transfer of phosphatidylcholine is also demonstrated. A mechanism of true molecular exchange between vesicles, rather than net transfer, is proposed for the bovine brain phospholipid exchange protein.

An in vitro ESR study of uncatalyzed rat liver protein-catalyzed spin-labeled phosphatidylcholine exchange

ESR spectrometry has been used to study fatty acid spin-labeled phosphatidylcholine exchange from single bilayer donor vesicles to various acceptor systems, such as intact or differently treated mitochondria, phospholipid multilamellar vesicles or single bilayer vesicles. This exchange is catalyzed by soluble non-specific rat liver protein, first investigated by Bloj and Zilversmit in 1977 (J. Biol. Chem. 252, 1613--1619). Non-catalyzed phosphatidylcholine exchange has also been studied. Full inhibition of both mechanisms occurs with lipid-depleted acceptor mitochondria, while N-ethylmaleimide-treated mitochondria behave as good acceptors during catalyzed exchange but are in no way effective during spontaneous exchange. Non-catalyzed exchange does not take place with phospholipase D-treated mitochondria as acceptors, while the pure catalyzed mechanism is inhibited by 28%. Neither multilamellar nor single bilayer phospholipid vesicles exchange spin-labeled phosphatidylcholine in the absence of protein, the former being a poorer acceptor system than the latter during catalyzed exchange, when this activity is 31 and 80%, respectively, of that of intact mitochondria. The hypothesis is made that the spontaneous mechanism is active among intact natural membranes and could be of some importance in vivo. Furthermore, the biomembrane protein moiety is assumed to be involved in the catalyzed exchange more as a phospholipid spacer than as a binder between the exchange protein and the membrane involved. Phospholipids, on the contrary, appear to be important for both functions.

Hemolysis of rat erythrocytes by replacement of the natural phosphatidylcholine by various phosphatidylcholines

Vesicles of a variety of types of phosphatidylcholine have been shown to be suitable donors of phosphatidylcholine to intact rat erythrocytes in the presence of a specific phosphatidylcholine exchange protein. Coincident with the progression of phosphatidylcholine exchange is the onset of hemolysis, occurring at degrees of exchange characteristic for the type of phosphatidylcholine employed. During exchange with the dimyristoyl, dipalmitoyl and distearoyl species, hemolysis starts when 27%, 25% and 22% of the native phosphatidylcholine is replaced by these disaturated species, respectively. In the case of dielaidoylglycerophosphocholine and 1-stearoyl-2-oleoylglycerophosphocholine hemolysis starts after the introduction of 30% and 28%, respectively. In contrast, the replacement of native erythrocyte phosphatidylcholine with egg phosphatidylcholine, and the dioleoyl species up to levels of 60% does not result in rapid hemolysis. Despite such functional consequences, overall contents of the individual phospholipids and cholesterol are normal. Accompanying the biochemical events are morphologic changes, including echinocyte an spherocyte formation. The structure-function implications and possible mechanisms of hemolysis are discussed.

Phospholipid transfer activities in Morris hepatomas and the specific contribution of the phosphatidylcholine exchange protein

Phospholipid transfer activities for phosphatidylcholine, phosphatidylinositol and phosphatidylethanolamine were measured in three hepatomas of increasing growth rate and degree of dedifferentiation, the hepatomas of 9633 and 7777, and compared to the activities found in normal and host liver. A 2-3-fold increase was found in the phosphatidylcholine and phosphatidylinositol transfer activities in the fast-growing 7777 hepatoma, while these activities were moderately or not increased in the 7787 and 9633 hepatomas. Phosphatidylethanolamine transfer was found to be extremely low in all three hepatomas. The possible significance of these findings with respect to the altered phospholipid content and composition of the hepatoma membranes is discussed. The contribution of the phosphatidylcholine specific exchange protein to the total phosphatidylcholine transfer activity was determined in normal and host liver and in the hepatomas 7777 and 9633 with the aid o f a phosphatidylcholine exchange protein specific antiserum. To this end a new procedure for the purification of the phosphatidylcholine exchange protein from rat liver was developed which leads to a final purification factor of 5300 and a high overall yield of 17%. In addition, this protein was chemically and immunologically characterized and its properties were compared to those of the bovine phosphatidylcholine exchange protein purified in our laboratory previously.

Protein-stimulated exchange of phosphatidylcholine between intact erythrocytes and various membrane systems

Phosphatidylcholine specific exchange protein from beef liver was found to catalyze the exchange of phosphatidylcholine between intact rat and human erythrocytes and various artificial membranes. Both multilamellar liposomes and single bilayer vesicles prepared from egg lechithin, cholesterol and phosphatidic acid (46:50:4, mol/mol) appeared to be effective phospholipid donor systems. Some merits and disadvantages of the various donor systems are discussed.

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.

Transbilayer distribution and mobility of phosphatidylcholine in intact erythrocyte membranes. A study with phosphatidylcholine exchange protein

1. The exchange of phosphatidylcholine between intact human or rat erythrocytes and rat liver microsomes was greatly stimulated by phosphatidylcholine-specific exchange proteins from rat liver and beef liver. It was found, however, that compared to the exchange reaction between phospholipid vesicles and rat liver microsomes, much higher concentrations of exchange protein were required in the case of intact red blood cells and microsomes. 2. In human erythrocytes, 75% of the phosphatidylcholine was available for exchange within 2 h at 37 degrees C. No additional exchange was observed during the next 2 h, indicating slow, if any, transbilayer movement of the residual phosphatidylcholine. 3. In rat erythrocytes 50--60% of the phosphatidylcholine was readily available for the exchange proteins. The residual phosphatidylcholine was exchanged at a much lower rate with a half time for equilibration of 7 h. 4. These results confirm in an independent way the asymmetric distribution of phosphatidylcholine over the membrane of human and rat erythrocytes as well as the occurrence of a slow transbilayer movement of this lipid in rat erythrocytes.

Determination of the hydrophobic binding site of phosphatidylcholine exchange protein with photosensitive phosphatidylcholine

1-Acyl-2-(7-(4-azido-2-nitrophenoxy)-[1-14C]heptanoly)-sn-glycero-3-phosphocholine was synthesized in order to study the lipid-binding site of the phosphatidylcholine exchange protein from bovine liver. Photosensitive phosphatidylcholine was incorporated into the protein by incubation with vesicles of this phosphatidylcholine derivative. The lipid-protein complex was separated from the vesicles by chromatography on Biogel A-0.5m. Photolysis of the complex by irradiation with light of a high pressure mercury lamp at a wavelength above 340 nm generated the highly reactive nitrene. Sodium dodecyl sulfate gel electrophoresis of the photolysed complex indicated that 30% of the endogenous 14C-labeled phosphatidylcholine was covalently linked to the protein. Peptides were isolated after digestion of the photolysed complex with protease from Staphylococcus aureus and trypsin. It was determined that the 2-acyl chain of the phosphatidylcholine molecule was linked to the peptide segment -Gly-Ser-Lys-Val-Phe-Met-Tyr-Tyr-. This segment was part of a protease peptide of about 65 residues of which the sequence was determined by Edman degradation for the first 38 residues. This peptide contains a cluster of apolar residues -Val-Phe-Met-Tyr-Tyr-Phe with an extremely high hydrophobicity index and with a predicted beta-sheet conformation. It is concluded that this hydrophobic cluster forms part of the binding site.