High cooperativity, specificity, and multiplicity in the protein kinase C-lipid interaction

The number of phosphatidylserine molecules involved in activating protein kinase C was determined in a mixed micelle system where one monomer of protein kinase C binds to one detergent:lipid micelle of fixed composition. Unusually high cooperativity, specificity, and multiplicity in the protein kinase C-phospholipid interaction are demonstrated by examining the lipid dependence of enzymatic activity. The rates of autophosphorylation and substrate (histone) phosphorylation are specifically regulated by the phosphatidylserine content of the micelles. Hill coefficients of 8-11 were calculated for phosphatidylserine-dependent stimulation of enzyme activity, with a maximum occurring in micelles containing greater than or equal to 12 phosphatidylserine molecules. The high specificity that exists is illustrated by the fact that phosphatidylethanolamine and phosphatidylglycerol, but not phosphatidylcholine or phosphatidic acid, can replace only some of the phosphatidylserine molecules. We propose that Ca2+ and acidic phospholipids cause the protein to undergo a conformation change revealing multiple phosphatidylserine binding sites and resulting in the highly cooperative and specific interaction of protein kinase C with phosphatidylserine. Consistent with this, the proteolytic sensitivity of protein kinase C increases approximately 10-fold in the presence of phosphatidylserine and Ca2+ compared to Ca2+ alone. The high degree of cooperativity and specificity may provide a sensitive method for the physiological regulation of protein kinase C by phospholipid.     

Lateral segregation of anionic phospholipids in model membranes induced by cytochrome P450 2B1: bi-directional coupling between CYP2B1 and anionic phospholipid

The lateral segregation of anionic phospholipids phosphatidic acid (PA), phosphatidylinositol (PI), and phosphatidylserine (PS) was detected after addition of cytochrome P450 2B1 (CYP2B1). The tendency of lipid clustering was highly dependent on the type of anionic phospholipids examined. PA was the most highly clustered while PI and PS clustered to a lesser degree. Moreover, liposomes containing anionic phospholipids form anionic phospholipid-rich microdomains in the presence of CYP2B1. Anionic phospholipids (mostly notably PA) also increased the ability of CYP2B1 to bind to lipid monolayers. In addition to the ability of CYP2B1 to modulate the physical properties of the membrane, the membrane itself can have reciprocal effects on the activity and conformation of CYP2B1. The catalytic activity of CYP2B1 increased as a function of anionic phospholipid concentration and in the presence of 10 mol% PA, the activity increased by 85%. These results suggest a bi-directional coupling between the CYP2B1 and anionic phospholipids.     

EFFECT OF EXOGENOUS LIPIDS ON ACTIVITIES OF THE RAT BRAIN CHOLESTEROL ESTER HYDROLASE LOCALIZED IN THE MYELIN SHEATH1

Abstract— Activity of cholesterol ester hydrolase localized almost exclusively in the myelin sheath (Eto & Suzuki , 1973a) was greatly affected by exogenous lipids added to the assay mixture. With isolated myelin as the enzyme source, phosphatidylserine was most effective in stimulating the activity. Other phospholipids were less effective. Efhanolamine phospholipid was slightly inhibitory and lysolecithin was strongly inhibitory. Differences in the fatty acid composition did not appear to account for such different effects. Glucosylceramide, galactosylceramide and digalactosylceramide were stimulatory while sulfatide, ganglioside and its asialo-derivative were inhibitory. Saturated fatty acids were generally stimulatory while corresponding unsaturated acids were strongly inhibitory. In order for exogenous lipids to be effective they had to be added to the assay mixture as free dispersion. When heat-inactivated myelin was used as the lipid source, no effect was observed, while equivalent amounts of a whole white matter lipid mixture was effective. Although phosphatidylserine was the most effective activator among the lipids tested, it could not completely replace sodium taurocholate present in the standard assay system. When isolated myelin was stored frozen, the activity of the enzyme declined gradually in the standard system without additional lipids. The stimulating effect of phosphatidylserine was greater for such partially inactivated enzyme sources, although it did not completely restore the activity to that of fresh preparations. When myelin was fractionated into basic protein, proteolipid protein and the high molecular weight acidic protein (Wolfgram) fractions, the last fraction contained most of the recovered activity. However, Wolfgram protein was less active than the intact myelin when assayed without additional lipid. The addition of phosphatidylserine completely restored the activity of this partially delipidated preparation.     

Phospholipids and regulation of protein kinase reaction

Naturally occurring phospholipids such as phosphatidylinositol and phosphatidylserine inhibited cAMP-dependent protein kinase by interacting with the substrate protein (phosphate acceptor). This inhibition was observed both in the presence and absence of cAMP when histone H2B, protamine, and myelin basic protein were used, but was not detected when casein was used as the substrate. Other phospholipids such as phosphatidylethanolamine and phosphatidylcholine did not inhibit the kinase but did stimulate the kinase when protamine served as the substrate. Both cAMP-dependent and cGMP-dependent protein kinases were inhibited by phosphatidylserine when histone H2B was used as substrate. The substrate protein binding to phosphatidylinositol and phosphatidylserine was observed when these phospholipids were added to the incubation mixture, suggesting that direct interaction between the substrate protein and the phospholipids resulted in inhibition of cAMP and cGMP-dependent protein kinase. Thus the substrate protein for protein kinase probably plays an important role in regulating the kinase activity related to various phospholipids.     

Augmentation of macrophage growth-stimulating activity of lipids by their peroxidation

Previously, we reported that some kinds of lipids (cholesterol esters, triglycerides, and some negatively charged phospholipids) that are constituents of lipoproteins or cell membranes induce growth of peripheral macrophages in vitro. In this paper, we examined the effect of peroxidation of lipids on their macrophage growth-stimulating activity because lipid peroxidation is observed in many pathological states such as inflammation. When phosphatidylserine, one of the phospholipids with growth-stimulating activity, was peroxidized by UV irradiation, its macrophage growth-stimulating activity was augmented in proportion to the extent of its peroxidation. The activity of phosphatidylethanolamine was also increased by UV irradiation. On the other hand, phosphatidylcholine or highly unsaturated free fatty acids, such as arachidonic acid and eicosapentaenoic acid, did not induce macrophage growth irrespective of whether they were peroxidized. The augmented activity of UV-irradiated phosphatidylserine was not affected by the coexistence of an antioxidant, vitamin E or BHT. These results suggest that some phospholipids included in damaged cells or denatured lipoproteins which are scavenged by macrophages in vivo may induce growth of peripheral macrophages more effectively when they are peroxidized by local pathological processes.     

Complex-formation between triphosphoinositide and experimental allergic encephalitogenic protein

1. Reactions between triphosphoinositide and the basic experimental allergic encephalitogenic (EAE) protein were examined in aqueous solution and in a biphasic solvent system (chloroform-methanol-water, 8:4:3, by vol.). 2. In the absence of salt an insoluble complex (I) is formed containing triphosphoinositide and EAE protein in proportions that represent complete neutralization of lipid and protein at the pH concerned. 3. In the presence of a low concentration (0.05m) of sodium chloride an insoluble positively charged complex (II) forms. It contains triphosphoinositide and EAE protein in a lower concentration ratio than complex I. This complex, which has a constant composition between pH7.5 and pH10, can take up additional micellar triphosphoinositide producing complex I, which can then be solubilized by excess of triphosphoinositide. 4. The complexes are dissociated by more concentrated sodium chloride solutions and low concentrations of calcium chloride, suggesting that they are largely stabilized by electrostatic bonds. The protein recovered after dissociation is immunologically active and has the same electrophoretic mobility as the original. 5. Water-insoluble ternary complexes containing triphosphoinositide, EAE protein and large amounts of phosphatidylcholine can be prepared. From these, chloroform-methanol (2:1, v/v) extracts only phosphatidylcholine. 6. An insoluble ternary complex of Ca(2+) ion, EAE protein and triphosphoinositide can be prepared by adding calcium chloride to a complex I preparation solubilized by excess of triphosphoinositide. 7. EAE protein will also form complexes with other acidic phospholipids, e.g. phosphatidic acid, phosphatidylserine and phosphatidylinositol, but not with phosphatidylcholine or phosphatidylethanolamine. The phosphatidylinositol and phosphatidylserine complexes are chloroform soluble, i.e. proteolipids. 8. The possibility that complexes between EAE protein and acidic phospholipids occur in vivo is discussed. Triphosphoinositide and EAE protein occur in ox brain myelin in approximately the same concentration ratios as they do in complex II, formed at physiological salt concentration and pH.     

Alterations in the protein-synthesis, -degradation and/or -secretion rates in hepatic subcellular fractions of selenium-deficient mice.

Conformational studies of myelin basic protein (MBP) in solution generally have used protein purified in organic solvents and acid. The use of such conditions raises the possibility that the secondary structure reported for the basic protein represents a denatured state. Therefore we have purified this protein by using a procedure that avoids denaturants. Bovine myelin was extracted with 0.2 M-CaCl2 and the protein was purified from the supernatant by chromatography on Sephadex G-75. The conformation of the basic protein was characterized by using c.d. and 1H-n.m.r. spectroscopy. In solution, it appeared to be predominantly randomly coiled, with only small segments of persistent structure. However, in the presence of myristoyl lysophosphatidylcholine the secondary structure of MBP became more ordered, and sedimentation-velocity experiments showed that MBP aggregated. Comparison of our results with published data indicates that Ca2+-extracted basic protein behaves similarly to the protein purified by traditional methods with respect to its ordered conformation in solution in the absence and in the presence of lipid and with respect to its self-association. Thus its thermodynamically stable structure in aqueous solution appears to be a highly flexible coil.     

Serinc, an activity-regulated protein family, incorporates serine into membrane lipid synthesis

Cell membranes contain various transporter proteins, some of which are responsible for transferring amino acids across membrane. In this study, we report another class of carrier proteins, termed Serinc1-5, that incorporates a polar amino acid serine into membranes and facilitates the synthesis of two serine-derived lipids, phosphatidylserine and sphingolipids. Serinc is a unique protein family that shows no amino acid homology to other proteins but is highly conserved among eukaryotes. The members contain 11 transmembrane domains, and rat Serinc1 protein co-localizes with lipid biosynthetic enzymes in endoplasmic reticulum membranes. A Serinc protein forms an intracellular complex with key enzymes involved in serine and sphingolipid biosyntheses, and both functions, serine synthesis and membrane incorporation, are linked to each other. In the rat brain, expression of Serinc1 and Serinc2 mRNA was rapidly up-regulated by kainate-induced seizures in neuronal cell layers of the hippocampus. In contrast, myelin throughout the brain is enriched with Serinc5, which was down-regulated in the hippocampus by seizures. These results indicate a novel mechanism linking neural activity and lipid biosynthesis.     

2'', 3''-Cyclic Nucleotide 3''-Phosphohydrolase and Lipids of Myelin from Multiple Sclerosis and Normal Brains

Abstract: A study of purified myelin samples from normal-appearing white matter of 10 multiple sclerosis (MS) brains was undertaken and the results were compared with 10 age-matched control brains. Statistical evaluations were carried out with Student's r-test for differences. In pathological samples the yield of myelin came to only two-thirds of the corresponding controls. Enzyme assays of the 2', 3'-cyclic 3'-phosphohydrolase revealed an obviously significant reduction of specific activity to one-half in MS myelins. In myelin the contents of protein, lipid classes as cholesterol, glycolipids and phospholipids did not differ significantly. No cholesterol esters or any lysophospholipid were detectable either in MS or in controls. Within the individual phospholipids the main components were in the same order, while a significant decrease of the acidic representatives and of sphingomyelin occurred. Analysis of the fatty acid pattern of phosphatidylcholine (PC), phosphatidylserine (PS) and phosphatidylethanolamine (PE), including the aldehydes from the last, revealed quite similar values with no significant differences, except C22: 4 fatty acid in the PE fraction and C20: 1 fatty acid in PS, which were reduced in MS myelin samples.     

Immune lysis of reconstituted myelin basic protein--lipid vesicles and myelin vesicles

Complement-mediated lysis of reconstituted lipid-myelin basic protein (BP) vesicles and myelin vesicles due to antibody raised against BP and isolated myelin is measured by determination of the amount of a water-soluble spin label, tempocholine chloride, released from the vesicles. The response is shown to be antigen-specific, antibody-dependent, and complement mediated. The relative response to different anti-BP antibody samples is similar to that determined by radioimmunoassay procedures. In contrast to immunoassays with BP in aqueous solution, this method measures immune recognition of the protein in either a synthetic or a natural membranous environment. This is important because this protein has been shown to have a different conformation when bound to lipid bilayers than in aqueous solution and its conformation depends on lipid composition. It is also a more rapid method because no separation of spin label still trapped in the vesicles and that released due to immune lysis is required. In synthetic membranes consisting of sphingomyelin, cholesterol, and an acidic lipid, either phosphatidylglycerol, phosphatidic acid, or phosphatidylserine, the response was greatest when the acidic lipid was phosphatidic acid. The response did not depend significantly on the antigen concentration expressed as molar ratio of BP to sphingomyelin, over the range 0.15:600 to 2:600, although it decreased at molar ratios less than 0.15:600. The antigen density required for immune lysis of vesicles containing this protein antigen is similar to that reported elsewhere for lipid antigens, although the time required for maximal lysis was greater. Both anti-BP and anti-myelin antibodies caused a greater specific complement-mediated response with synthetic vesicles than with myelin vesicles, which may be due to the different lipid and/or protein composition of myelin. Response was also obtained with the myelin vesicles, however, indicating that some determinants of BP can be recognized on the surface of the bilayer in isolated myelin by anti-BP.     

Proteolipids of brain myelin and synaptosomes in the frog and hen

Proteolipid complex of Folch-Lees has been obtained and purified from the myelin and synaptosomes of the brain of the frog Rana temporaria and hen Gallus domesticus. Relative content of this proteolipid and glycolipids in the myelin is almost twice higher, whereas that of phospholipids--1 1/2 times lower than in the synaptosomal membranes of the same animal. Protein content of this complex is higher for myelin than for synaptosomal membranes; opposite relation was found with respect to phospholipid content. Within this complex, lipids are presented mainly by phospholipids, especially by acid ones which amount to 30-60%. Proteolipid complexes fro the myelin and synaptosomes differ from each other by their lipid component. Myelin proteolipid complex contains mainly phosphatidylserine and phosphatid acid, whereas synaptosomal one--phosphatidylserine and diphosphatediglycerol. No significant differences were found in fatty acid composition of phospholipids from proteolipid complex from myelin and synaptosomes as compared to this composition in the initial membranes.     

Phospholipids differently modulate the activity of cytosolic protein-tyrosine kinase from porcine spleen

Effect of membrane phospholipids on the activity of cytosolic protein-tyrosine kinase from porcine spleen (CPTK-40) has been studied. Using poly(Glu Na, Tyr)4:1 as a substrate, phosphatidylethanolamine, phosphatidylcholine and phosphatidylserine had stimulatory effects on that phosphorylation activity, however phosphatidic acid had inhibitory and phosphatidylinositol had no effects. Similar results were obtained using[Val5]angiotensin II as a substrate. On the other hand using basic protein (H2B histone and myelin basic protein) as substrates, phosphatidic acid stimulated the activity of CPTK-40, while phosphatidylinositol inhibited the activity. Phosphatidylethanolamine, phosphatidylcholine and phosphatidylserine caused different effect on the activity of CPTK-40 depending on the substrate employed. However using acidic protein (tubulin and casein) as substrates, the activity of CPTK-40 was neither stimulated nor inhibited by any phospholipids. These results suggest that phospholipids may modulate the activity of CPTK-40.     

Regulation of the calcium-activated neutral proteinase (CANP) of bovine brain by myelin lipids

Since calcium-activated neutral proteinase (CANP; calpain) activation occurs at the plasmalemma and the enzyme is found in myelin, we examined myelin lipid activation of brain CANP. Purified lipids were dried, sonicated and incubated with purified myelin CANP. The CANP was assayed using [14C]azocasein as substrate and the Ca2+ concentration ranged from 2 microM for muCANP to 5 mM for mCANP. Phosphatidylinositol (PI), phosphatidylserine (PS) and dioleoylglycerol stimulated the mCANP activity by 193, 89 and 78%, respectively. PI stimulated both m- and muCANP in a concentration-dependent manner, while phosphatidylcholine was least effective. Cerebroside and sulfatide at higher concentrations (750 microM) were stimulatory. The phospholipid (PL)-mediated activation was inhibited by the PL-binding drug trifluoperazine. PI reduced the Ca2+ requirement for CANPs significantly (20-fold). These results suggest that acidic lipids and particularly acidic phospholipids activate membrane CANP.     

Photolabeling of myelin basic protein in lipid vesicles with the hydrophobic reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine

The hydrophobic photolabel 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine([125I]TID) was used to label myelin basic protein or polylysine in aqueous solution and bound to lipid vesicles of different composition. Although myelin basic protein is a water soluble protein which binds electrostatically only to acidic lipids, unlike polylysine it has several short hydrophobic regions. Myelin basic protein was labeled to a significant extent by TID when in aqueous solution indicating that it has a hydrophobic site which can bind the reagent. However, myelin basic protein was labeled 2-4-times more when bound to the acidic lipids phosphatidylglycerol, phosphatidylserine, phosphatidic acid, and cerebroside sulfate than when bound to phosphatidylethanolamine, or when in solution in the presence of phosphatidylcholine vesicles. It was labeled 5-7-times more than polylysine bound to acidic lipids. These results suggest that when myelin basic protein is bound to acidic lipids, it is labeled from the lipid bilayer rather than from the aqueous phase. However, this conclusion is not unequivocal because of the possibility of changes in the protein conformation or degree of aggregation upon binding to lipid. Within this limitation the results are consistent with, but do not prove, the concept that some of its hydrophobic residues penetrate partway into the lipid bilayer. However, it is likely that most of the protein is on the surface of the bilayer with its basic residues bound electrostatically to the lipid head groups.     

Enhancement of opiate binding by various molecular forms of phosphatidylserine and inhibition by other unsaturated lipids.

A study was undertaken on the possible involvement of phospholipids on stereospecific opiate binding to a rat brain membrane fraction comprised mainly of synaptic membranes. The addition of acidic phospholipids such as phosphatidylserine, phosphoinositides, and phosphatidic acid significantly enhanced opiate binding. With the exception of phosphatidylserine, when the acidic phospholipids contained a polyunsaturated acyl group, they were actually inhibitory, along with neutral phospholipids derived from brain. Both the C18:0, C18:1 form (derived from myelin) and the C18:0, C22:6 form of phosphatidylserine (derived from synaptic membranes) produced as much as a 45% enhancement in opiate binding. Unsaturated fatty acids were highly inhibitory, the degree of inhibition being related to the degree of unsaturation. Both phospholipase A and C were inhibitory; and the inhibitory effect of A could not be prevented by albumin or overcome with the addition of phosphatidylserine. With the use of the cross-linking agent, dinitrodifluorobenzene, it could be demonstrated that the phosphatidylserine of synaptic membranes appeared to be preferentially associated with membrane protein. The enhancement of opiate binding by phosphatidylserine diminished with increasing degree of cross-linking.     

Calorimetric studies on the interaction of gangliosides with phospholipids and myelin basic protein

Differential scanning calorimetry was employed to investigate the interaction of GM1 gangliosides with phospholipids (phosphatidylethanolamine, phosphatidylserine or phosphatidylcholine). It was found that GM1 is completely miscible with phosphatidylethanolamine; however, the interaction with phosphatidylserine is minimal. Addition of excess Ca2+ to the interaction products of GM1 with phosphatidylcholine or phosphatidylethanolamine did not induce phase separation. The influence of myelin basic protein on the thermotropic behaviour of GM1 was also studied. It was found that basic protein has a very strong perturbing effect on GM1 micelles.     

On the mechanism of activation of protein kinase FA (an activating factor of ATP.Mg-dependent protein phosphatase) in brain myelin

Protein kinase F_A (an activating factor of ATP·Mg-dependent protein phosphatase) has been characterized to exist in two forms in the purified brain myelin. One form of kinase F_A is spontaneously active and trypsin-labile, whereas the other form of kinase F_A is inactive and trypsin-resistant, suggesting a different membrane topography with active F_A exposed on the outer face of the myelin membrane and inactivu F_Q buried within the myelin membrane. When myelin was solubilized in 1% Triton X-100, all kinase F_A became active and trypsin-labile. Phospholipid reconstitution studies further indicated that when kinase F_A was reconstituted in acidic phospholipids, such as phosphatidylinositol and phosphatidylserine, the enzyme activity was inhibited in a dose-dependent manner, suggesting that kinase F_A interacts with acidic phospholipids which inhibit its activity. Furthermore, when myelin was incubated with exogenous phospholipase C, the inactive/trypsin-resistant F_A could be converted to the active/trypsin-labile F_A in a time- and dose-dependent manner. Taken together, it is concluded that membrane phospholipids play an important role in modulating the activity of kinase F_A in the brain myelin. It is suggested that phospholipase C may mediate the activation-sequestration of inactive/trypsin-resistant kinase F_A in the brain myelin through the phospholipase C-katalyzed degradation of acidic membrane phospholipids. The activation-sequestration of protein Kinase F_A may represent one mode of control modulating the activity of kinase F_A in the central nervous system myelin.     

Ca2+- and phospholipid-binding properties of Torpedo electric organ calelectrin

The Ca2+-regulated lipid-binding properties of the H- and L-forms of calelectrin present in the electric organ of Torpedo marmorata have been compared. Binding of H-calelectrin required Ca2+ in millimolar concentrations, whereas that of L-calelectrin occurred in the micromolar range. Dissociation of H-calelectrin previously bound to lipids in the presence of 2 mM Ca2+ took place only when the Ca2+ concentration was reduced to micromolar concentrations. Binding was most effective to acidic phospholipids such as phosphatidylserine. Both forms of calelectrin promoted the aggregation of membrane vesicles in the presence of Ca2+.Mg2+, Na+ and K+ inhibited the Ca2+-induced binding to phospholipid, decreasing in effectiveness in that order. Binding was also inhibited by high pH. The surface activity and hydrophobicity index showed that H-calelectrin is a hydrophilic molecule. It may represent a less active, more highly phosphorylated "down-regulated" form of L-calelectrin. The role of calcium in H-calelectrin binding to lipid appeared to be consistent with the formation of a ternary complex of the protein, an acidic lipid and Ca2+, rather than with a direct interaction of lipid with hydrophobic sequences in H-calelectrin whose accessibility is Ca2+-regulated.     

Myelin Proteins in Reverse Micelles: Tight Lipid Association Required for Insertion of the Folch-Pi Proteolipid into a Membrane-Mimetic System

The solubility and reactivity of the Folch-Pi proteolipid from bovine CNS have been studied in reverse micelles of sodium bis(2-ethylhexyl)sulfosuccinate, isooctane, and water. Such a membrane-mimetic system resembles the aqueous spaces of the native myelin sheath in terms of its physicochemical properties. Although the proteolipid is completely insoluble in water, it can be inserted into the water-containing micellar system. In contrast, the lipid-depleted protein failed to be incorporated into these organized assemblies. The lipid requirements for insertion of the proteolipid were studied, therefore, after delipidation by several precipitations with isooctane, a nondenaturing solvent. Novel extraction procedures and quantitative analyses by HPLC of the protein-bound lipids revealed the persistence of a lipid-protein complex (6 +/- 1 mol of lipid/mol of protein) displaying optimal micellar solubilization. Competition experiments carried out with brain lipids provide evidence for a preference of the myelin protein for sulfatide, phosphatidylinositol, and phosphatidylserine, in that order. The resulting proteolipid, although differing in relative composition, showed good solubility in the membrane-mimetic system. In contrast, reconstitution experiments carried out with the lipid-depleted protein resulted in weak lipid binding and poor micellar incorporation. These results suggest that the tightly bound acidic lipids may stabilize a protein conformation required for insertion into the micellar system.     

Antibodies to liposomal phosphatidylserine and phosphatidic acid

Polyclonal antisera to phosphatidylserine or phosphatidic acid were induced in rabbits by injecting liposomes containing phosphatidylserine or phosphatidic acid and lipid A. Adsorption of antisera with liposomes containing different phospholipids revealed that some degree of reactivity with one or more phospholipids other than the immunizing phospholipid was often observed. However, cross-reactivity with other phospholipids was not a universal phenomenon, and one antiserum to phosphatidylserine failed to cross-react (i.e., was not adsorbed) with liposomes containing other phospholipids. All of the antisera were inhibited by soluble phosphorylated haptens (e.g., phosphocholine but not choline), but one of the antisera to phosphatidylserine was inhibited both by phosphoserine and by serine alone. Liposomal membrane composition influenced the activity of antiserum to phosphatidylserine. Regardless of whether unsaturated (beef brain) or saturated (dimyristoyl) phosphatidylserine was used in the immunizing liposomes, the antisera reacted more vigorously with liposomes containing unsaturated than saturated phosphatidylserine. We conclude that liposomes containing lipid A can serve as vehicles for stimulating polyclonal antisera to phosphatidylserine and phosphatidic acid. Although cross-reactivity with certain other phospholipids can be observed, sera from selected animals apparently can exhibit a high degree of specific activity to the immunizing phospholipid antigen.