Transfer of bovine J-blood-group determinant onto erythrocytes: isolation and identification of a blocker

The bovine J-blood-group determinant is transferred from a serum glycoprotein to an erythrocyte membrane lipid by incubation in vitro. This transfer is inhibited by a lipid (called 'blocker') occurring in bovine and human serum, in other bovine and human tissues, yeast and plant tissues. The blocker was isolated from bovine spleen and identified as phosphatidylserine. Moreover, phosphatidylinositol acts as a blocker, while a variety of other phospholipids, glycosphingolipids and neutral lipids have no function as blockers. Mild alkaline deacylation deletes the blocker activity of both phosphatidylserine and phosphatidylinositol. Methyl esters of these phospholipids, or exchange of the amino group for a hydroxyl group in phosphatidylserine or N-benzoylation of phosphatidylserine, do not affect the blocker function. The blocker function of phosphatidylinositol is lost after periodate oxidation. The blocker reacts with the J-containing serum protein, not with the erythrocyte membrane. After preincubation of the J-positive serum protein with the blocker and reextraction of excess blocker, the serum protein remains J-positive, but is then unable to transfer the J determinant to the erythrocyte membrane.     

The transfer of bovine J blood group activity to erythrocytes: chemical nature of transferable and of non-transferable J1

The bovine J blood group substance exists as a glycosphingolipid (ceramide deca-hexoside as well as ceramide dodecahexoside) and as a glycoprotein. The lipidic form occurs in erythrocyte membranes, both forms are found in serum. The lipidic J substances were isolated from erythrocytes and from serum, and identified by thin-layer chromatography with lipidic J substances isolated from spleen. The glycoprotein nature of the non-lipidic J of serum was evident by pronase-catalysed hydrolysis yielding J-active glycopeptides of lower molecular weights. The lipidic J was completely extracted from lyophilized stroma with chloroform/methanol. From lyophilized serum, however. it was completely extracted only in the presence of water, indicating different binding partners in serum and in erythrocyte membranes. The J lipid was incorporated as intact molecule into the erythrocyte membrane by a simple incubation technique. The incorporation was inhibited by various glyc-erophospholipids (called blockers). The J glycoprotein could not be transferred to the erythrocyte membrane. Three methods are descrjbed which are suitable for the preparation of a blocker-free fraction enriched with J lipids from J-positive serum.     

The distribution of J blood-group activity on lipoprotein and protein fractions of bovine serum.

There is a diversity of carriers of the J blood-group activity of bovine serum. The qualitative and quantitative distribution of the J activity on different carriers was studied, using various fractionation procedures. Approximately one third of J activity was found in the total lipids extracted from serum, two thirds in the lipid-free residue precipitated by lipid extraction. One third of the lipid J substance was found to be bound to the very low density lipoprotein, two thirds to the low density lipoprotein, while the high density lipoprotein was completely free of J activity. All non-lipidic J substance was present in the lipid-free protein. There was no J activity in the low molecular weight mucoproteins of serum and in the apoproteins of the lipoprotein fractions. The lipoprotein fractions were prepared by ultracentrifugation at different solvent densities. The lipoprotein fractions were characterized by chemical analyses and physical properties. The lower total cholesterol concentration of bovine serum, as compared to human serum, is reflected in a lower concentration of low density lipoprotein. The results obtained by ultracentrifugation coincide with the results obtained by precipitation of "beta-lipoproteins" with dextran sulfate and calcium chloride and with results obtained by gel filtration of bovine serum. The "beta-lipoprotein" fraction contains lipoproteins of very low and low density, and probably chylomicrons and a variety of other proteins, however no high density lipoprotein.     

Modification of the erythrocyte membrane by a non-specific lipid transfer protein

The non-specific phospholipid transfer protein purified from bovine liver has been used to modify the phospholipid content and phospholipid composition of the membrane of intact human erythrocytes. Apart from an exchange of phosphatidylcholine between the red cell and PC-containing vesicles, the protein appeared to facilitate net transfer of phosphatidylcholine from the donor vesicles to the erythrocyte and sphingomyelin transfer in the opposite direction. Phosphatidylcholine transfer was accompanied by an equivalent transfer (on a molar basis) of cholesterol. An increase in phosphatidylcholine content in the erythrocyte membrane from 90 to 282 nmol per 100 microliters packed cells was observed. Phospholipase C treatment of modified cells showed that all of the phosphatidylcholine which was transferred to the erythrocyte was incorporated in the lipid bilayer. The nonspecific lipid transfer protein used here appeared to be a suitable tool to modify lipid content and composition of the erythrocyte membrane, and possible applications of this approach are discussed.     

Modification of the erythrocyte membrane by a non-specific lipid transfer protein

The non-specific phospholipid transfer protein purified from bovine liver has been used to modify the phospholipid content and phospholipid composition of the membrane of intact human erythrocytes. Apart from an exchange of phosphatidylcholine between the red cell and PC-containing vesicles, the protein appeared to facilitate net transfer of phosphatidylcholine from the donor vesicles to the erythrocyte and sphingomyelin transfer in the opposite direction. Phosphatidylcholine transfer was accompanied by an equivalent transfer (on a molar basis) of cholesterol. An increase in phosphatidylcholine content in the erythrocyte membrane from 90 to 282 nmol per 100 μl packed cells was observed. Phospholipase C treatment of modified cells showed that all of the phosphatidylcholine which was transferred to the erythrocyte was incorporated in the lipid bilayer. The nonspecific lipid transfer protein used here appeared to be a suitable tool to modify lipid content and composition of the erythrocyte membrane, and possible applications of this approach are discussed.     

Accelerated transfer of neutral glycosphingolipids and ganglioside GM1 by a purified lipid transfer protein

The transfer of labeled neutral glycosphingolipids from sonicated phosphatidylcholine vesicles to erythrocyte ghosts is greatly stimulated by a nonspecific lipid transfer protein purified from beef liver. Globo-tetraglycosylceramide is transferred at a rate 40% of that for dipalmitoylphosphatidylcholine. II3-alpha-N-Acetylneuraminosyl-gangliotetraglycosylceramide is also transferred by the transfer protein, either from sonicated phosphatidylcholine vesicles or from ganglioside micelles to erythrocyte ghosts. The nonspecific lipid transfer protein catalyzes the net transfer of glycosphingolipids from brush border membrane vesicles (from rabbit intestine) to sonicated phosphatidylcholine/cholesterol vesicles.     

Effect of fetal calf serum and serum protein fractions on the uptake of liposomal phosphatidylcholine by rat hepatocytes in primary monolayer culture

We studied the effect of fetal calf serum and serum protein fractions on the interaction of phospholipid vesicles consisting of phosphatidylcholine, cholesterol and dicetylphosphate (molar ratio 7 : 2 : 1), with rat liver parenchymal cells in a primary monolayer culture. During incubation of such vesicles with fetal calf serum part of the labeled phosphatidylcholine is transferred to a lipoprotein particle similar to the one we identified previously as a derivative of high density lipoprotein (Scherphof, G., Roerdink, F.H., Waite, M. and Parks, J. (1978) Biochim. Biophys. Acta 542, 296–307). When the particle thus formed is incubated with the cells a transfer of the phospholipid label to the cells is observed. When vesicles are incubated with the cells in presence of serum such lipoprotein-mediated lipid transfer may conceivably contribute to the total lipid uptake observed. However, we found that the presence of fetal calf serum in the culture medium greatly diminished rather than increased the total transfer of liposomal lipid to the cells. Also bovine serum albumin and bovine β-globulins reduced this transfer, although to a lesser extent than whole serum. α-Globulins, on the other hand, were as effective as complete serum in reducing the uptake of liposomal phospholipid. A γ-globulin fraction failed to exhibit any effect on the uptake of [¹⁴C]phosphatidylcholine by the cells.All protein fractions which were able to inhibit cellular uptake of liposomal phospholipid were shown to bind to the phospholipid vesicles. Furthermore, lipid vesicles preincubated with fetal calf serum and then separated from it showed reduced transfer of labeled phosphatidylcholine to parenchymal cells.These observations were taken to suggest that the diminished uptake of liposomal lipid may be caused by a modification of the liposomal surface membrane as a result of the binding of certain serum proteins. On the other     

Studies on the chemical nature of the lipidic J blood-group substance of cattle

Total lipids extracted from J-positive cattle serum, erythrocytes or spleen exhibit J blood-group activity. The J subsance is concentrated in a lipid fraction obtained by column chromatography. Following mild alkaline hydrolysis or reduction with complex hydrides (LiAlH4, LiBH4), the J activity remains detectable in this lipid fraction even though all acyl ester groups have been destroyed as revealed by ester group determination. This disagrees with the suggestion that fatty acyl esters are essential for J activity. This was confirmed by experiments with a water-soluble J-active product prepared by ozone treatment of glycosphingolipids from bovine spleen. The results of these experiments are in favour of a glycosphingolipid containing anunusually lang oligosaccharide chain. Furthermore, it appears that the terminal moiety of the J determinant is not necessarily an N-acetyl galactosamine unit as suggested previously.     

Evidence for the presence of a glycosphingolipid-transfer protein in rat brain cytosol

Proteins in the postmicrosomal supernatant fraction of rat brain catalyzed the transfer of bovine brain galactocerebroside, sulfatide, and ganglioside GM1 from unilamellar liposomes to the rat erythrocytes or ghosts. The vesicles were made with egg yolk lecithin, cholesterol, 3H-labelled glycolipid, and a trace of [14C]triolein as a nonexchangeable marker. The routine assay of the glycosphingolipid transfer consisted of incubation of the donor liposomes with erythrocytes in the presence or absence of supernatant protein in physiological buffer at 37 degrees C for various time intervals. After the incubation, the erythrocytes were separated from the vesicles by centrifugation and the extent of protein-catalyzed transfer of labelled glycolipid in the membrane-bound total lipid fraction was determined by scintillation spectrometry. The fraction of [3H]glycosphingolipid transferred is represented by a change in the 3H/14C ratios at initial and subsequent time intervals. The glycosphingolipid transfer catalyzed by the supernatant protein was found to be logarithmic, whereas the protein-independent transfer was linear over a period of 3-4 h. The rate constant (K) and half time (t1/2) of the protein-catalyzed transfer reaction of cerebrosides and sulfatides were almost the same, while the transfer of ganglioside GM1 occurred at a slightly faster rate, probably owing to the greater aqueous solubility of this lipid. The transfer activity was also increased in a manner dependent on the amount of supernatant protein added up to 10 mg. The catalytic activity of the protein was lost when heated at 70 degrees C for 5 min. The pH optimum of the activity was around 7.4.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the chemical nature of the lipidic J blood-group substance of cattle

Total lipids extracted from J-positive cattle serum, erythrocytes or spleen exhibit J blood-group activity. The J subsance is concentrated in a lipid fraction obtained by column chromatography. Following mild alkaline hydrolysis or reduction with complex hydrides (LiAlH₄, LiBH₄), the J activity remains detectable in this lipid fraction even though all acyl ester groups have been destroyed as revealed by ester group determination. This disagrees with the suggestion that fatty acyl esters are essential for J activity. This was confirmed by experiments with a water-soluble J-active product prepared by ozone treatment of glycosphingolipids from bovine spleen. The results of these experiments are in favour of a glycosphingolipid containing an unusually lang oligosaccharide chain. Furthermore, it appears that the terminal moiety of the J determinant is not necessarily an N-acetyl galactos-amine unit as suggested previously.     

Effect of fetal calf serum and serum protein fractions on the uptake of liposomal phosphatidylcholine by rat hepatocytes in primary monolayer culture.

We studied the effect of fetal calf serum and serum proteins fractions on the interaction of phospholipid vesicles consisting of phosphatidylcholine, cholesterol and dicetylphosphate (molar ratio 7 : 2 : 1), with rat liver parenchymal cells in a primary monolayer culture. During incubation of such vesicles with fetal calf serum part of the labeled phosphatidylcholine is transferred to a lipoprotein particle similar to the one we identified previously as a derivative of high density lipoprotein (Scherphof, G., Roerdink, F.H., Waite, M. and Parks, J. (1978) Biochim. Biophys. Acta 542, 296--307). When the particle thus formed is incubated with the cells a transfer of the phospholipid label to the cells is observed. When vesicles are incubated with the cells in presence of serum such lipoprotein-mediated lipid transfer may conceivably contribute to the total lipid uptake observed. However, we found that the presence of fetal calf serum in the culture medium greatly diminished rather than increased the total transfer of liposomal lipid to the cells. Also bovine serum albumin and bovine beta-globulins reduced this transfer, although to a lesser extent than whole serum. alpha-Globulins, on the other hand, were as effective as complete serum in reducing the uptake of liposomal phospholipid. A gamma-globulin fraction failed to exhibit any effect on the uptake of [14C]phosphatidylcholine by the cells. All protein fractions which were able to inhibit cellular uptake of liposomal phospholipid were shown to bind to the phospholipid vesicles. Furthermore, lipid vesicles reincubated with fetal calf serum and then separated from it showed reduced transfer of labeled phosphatidylcholine ot parenchymal cells. These observation were taken to suggest that the diminished uptake of liposomal lipid may be caused by a modification of tm proteins. On the other hand, we cannot rule out that plasma membrane modifications are involved in the mechanism of inhibition as well.     

GPI-linked proteins do not transfer spontaneously from erythrocytes to liposomes. New aspects of reorganization of the cell membrane

Exposure of cells to liposomes results in the release of integral membrane proteins. However, it is still controversial whether the release is due to spontaneous protein transfer from cells to liposomes or shed vesicles released from cells. We investigated this issue in an erythrocyte-liposome system by examining the location of acetylcholinesterase (AChE, an integral membrane protein marker), cholesterol (erythrocyte membrane lipid marker), hemoglobin (cytosolic protein marker), and a nonexchangeable lipid marker in liposomes in a sucrose density gradient at high resolution. The density distribution showed that AChE is not transferred to the liposomes but is located on small (about 50 nm) light (10-20 wt % sucrose) or large (about 200 nm) heavy shed vesicles (more than 30 wt % sucrose). AChE in the light shed-vesicle fraction markedly increased even after its level in the heavy fraction reached a plateau. AChE was also released from isolated heavy shed vesicles and accumulated in the small light shed-vesicle fraction in the presence of liposomes. After incubation of spherical erythrocytes (morphological index, 5.0) with liposomes, AChE hardly appeared in the heavy shed-vesicle fraction, and the majority (>99%) appeared in the light shed-vesicle fraction, indicating that AChE is released from both the erythrocytes and heavy shed vesicles to the light shed-vesicle fraction, which becomes rich in AChE. Our results demonstrated for the first time that GPI-linked proteins do not spontaneously transfer from erythrocytes to liposomes. Our study also suggests that in vivo GPI-linked membrane proteins do not spontaneously transfer between cell membranes but that some catalyst is needed.     

Fluorescence assay of the specificity of human plasma and bovine liver phospholipid transfer proteins

The specificities of a human plasma and bovine liver phospholipid transfer protein were studied using a fluorescence assay based on the transfer of pyrenyl phospholipids. This method was used previously to determine the mechanism of spontaneous transfer of phospholipids between model lipoproteins (Massey, J.B., Gotto, A.M., Jr. and Pownall, H.J. (1982) Biochemistry 21, 3630-3636). The pyrenyl phospholipids varied in the headgroup moiety; pyrenyl phosphatidylcholines contained different fatty acyl chains in the sn-1 position. Model high-density lipoproteins (R-HDL) consisting of apolipoprotein A-I and 1-palmitoyl-2-oleoylphosphatidylcholine (POPC) were used as donor and acceptor particles. As previously shown, the bovine liver protein mediated the transfer of only phosphatidylcholine. In contrast, the human plasma protein transferred all species studied which included a phosphatidylserine, phosphatidylcholine, phosphatidylglycerol, phosphatidylethanolamine, phosphatidic acid, sphingomyelin, galactosylcerebroside, and a diacylglycerol. The activity of these transfer proteins was only slightly affected by changes in the acyl chain composition of the transferring lipid. Pyrenyl and radioactive ([3H]POPC) phospholipids were transferred with equal rates by the human transfer protein, suggesting that this protein has similar binding characteristics for pyrenyl and natural phospholipids. Spontaneous phospholipid transfer occurs by the aqueous diffusion of monomeric lipid where the rate is highly dependent on fatty acyl chain composition. In this study, no correlation between the rate of spontaneous transfer and protein-mediated transfer was found. The apparent Km values for R-HDL and low-density lipoprotein (LDL), when used as acceptors, were similar when based on the number of acceptor particles. The apparent Vmax for the bovine liver protein was identical for R-HDL and LDL but for the plasma protein Vmax was slightly higher for R-HDL. These results suggest that, like the bovine liver protein, the plasma protein functions as a phospholipid-binding carrier that exchanges phospholipids between membrane surfaces. The assay of lipid transfer proteins by pyrenyl-labeled lipids is faster and easier to perform than other current methods, which require separation of donor and acceptor particles, and is suitable for studies on the function and mechanism of action of lipid transfer proteins.     

Role of scavenger receptors SR-BI and CD36 in selective sterol uptake in the small intestine

The serum lipoprotein high-density lipoprotein (HDL), which is a ligand of scavenger receptors such as scavenger receptor class B type I (SR-BI) and cluster determinant 36 (CD36), can act as a donor particle for intestinal lipid uptake into the brush border membrane (BBM). Both cholesterol and phospholipids are taken up by the plasma membrane of BBM vesicles (BBMV) and Caco-2 cells in a facilitated (protein-mediated) process. The protein-mediated transfer of cholesterol from reconstituted HDL to BBMV depends on the lipid composition of the HDL. In the presence of sphingomyelin, the transfer of cholesterol is slowed by a factor of about 3 probably due to complex formation between cholesterol and the sphingolipid. It is shown that the mechanism of lipid transfer from reconstituted HDL to either BBMV or Caco-2 cells as the acceptor is consistent with selective lipid uptake: the lipid donor docks at the membrane-resident scavenger receptors which mediate the transfer of lipids between donor and acceptor. Selective lipid uptake implies that lipid, but no apoprotein is transferred from the donor to the BBM, thus excluding endocytotic processes. The two BBM models used here clearly indicate that fusion of donor particles with the BBM can be ruled out as a major mechanism contributing to intestinal lipid uptake. Here we demonstrate that CD36, another member of the family of scavenger receptors, is present in rabbit and human BBM vesicles. This receptor mediates the uptake of free cholesterol, but not of esterified cholesterol, the uptake of which is mediated exclusively by SR-BI. More than one scavenger receptor appears to be involved in the uptake of free cholesterol with SR-BI contributing about 25% and CD36 about 35%. There is another yet unidentified protein accounting for the remaining 30 to 40%.     

Composition and enzyme activities of Spiroplasma citri membranes.

Spiroplasma citri was cultured in three different media that supplied cholesterol and fatty acids from: (i) horse serum, (ii) pleuropneumonia-like organism (PPLO) serum fraction, or (iii) bovine serum albumin-fatty acid-cholesterol. The ability of PPLO serum fraction to support growth varied by lot number. Neither PPLO serum fraction nor the bovine serum albumin medium supported growth as well as the horse serum medium. Analysis of cholesterol, lipid phosphorus, and membrane protein showed the horse serum- and PPLO-grown cells to be indistinguishable, but the bovine serum albumin-grown cells were deficient in lipid phosphorus. The three cultures did not show markedly different fatty acid compositions, but, in all cases, the cultures preferentially incorporated palmitic acid and discriminated against linoleic acid. Cultures grown for different times from logarithmic growth through a degenerative phase showed relatively constant ratios of cholesterol/protein and lipid phosphorus/protein. Fatty acid composition was also relatively constant at the different stages. Adenosine triphosphatase and p-nitrophenyl phosphatase were mainly associated with the membrane, whereas reduced nicotinamide adenine dinucleotide oxidase was either readily removed or not associated with the membrane. The reduced nicotinamide adenine dinucleotide oxidase was inactivated at temperatures above 35 degrees C.     

Isolation and partial characterization of the heterophile antigen of infectious mononucleosis from bovine erythrocytes

The heterophile antigen (Paul-Bunnell antigen, PBA) of infectious mononucleosis was isolated by extraction of an aqueous suspension of bovine erythrocyte stromata with chloroform-methanol (2:1). The upper aqueous layer contained gangliosides, PBA, and a high-molecular-weight glycoprotein. PBA and gangliosides were separated from the high-molecular-weight glycoprotein by extraction of lyophilized upper layer with chloroform-methanol solvents. Separation of PBA from gangliosides was carried out by chromatography on DEAE-cellulose with chloroform-methanol solvents. PBA appeared to be a minor glycoprotein component of the erythrocyte membrane and had both hydrophobic and hydrophilic properties. It was soluble in either organic or aqueous solvents. On SDS-polyacrylamide gel electrophoresis, it migrated as a single component that stained for protein with Coomassie blue, for carbohydrate with periodic acid-Schiff reagent, and for lipid with oil red 0; it had an apparent molecular weight of 26,000. It was composed of 62% protein with major amino acids: glutamic acid, proline, glycine, isoleucine, leucine, and threonine (158, 116, 98, 90, 85, and 82 residues per 1,000 residues, respectively). Carbohydrate content was 9.2% with major sugar constituents: sialic acid, galactosamine, and galactose. Serologic activity of PBA was destroyed by pronase but not by trypsin.     

Chemical characterization of porcine blood serum components with A and SLA activity

The porcine A blood group substance is found in the serum as a Lipid and, additionally, in certain animals, as a glycoprotein. Swine lymphocyte antigens (SLA) occur in the serum only as glycoproteins. Heat treatment of the solid residue obtained by lipid extraction yielded a water-soluble fraction with low protein content, high A activity, but no SLA activity. Poly(glycosy1)ceramides with SLA activity do not occur in the serum; poly(glycosy1)ceramides with A activity cannot be excluded. Desialylation of protein fractions has no effect on A and SLA activity. Both A and SLA activities of protein fractions are stable to mild alkaline hydrolysis thus indicating N-glycosidic carbohydrate-peptide linkages.     

Characterization of inhibitor to leptospiral hemolysin present in bovine serum

Hemolysis by leptospiral hemolysin was strongly inhibited by bovine serum. The inhibitory activity was observed in the chloroform-methanol-soluble fraction of bovine serum. The inhibitor was eluted in a complex lipid fraction and was separated into two fractions (Fr. I and II) by silicic acid column chromatography. Fractions I and II inhibited approximately 75% and 95%, respectively, of hemolysis by leptospiral hemolysin. Fraction I was identified as phosphatidylethanolamine (PdE) by silica gel thin-layer chromatography (TLC). Two kinds of phospholipids (PLs) were detected in Fr. II by TLC. One was resistant to alkaline treatment and was identified as sphingomyelin (Spm), and the other was sensitive to such treatment and was identified as phosphatidylcholine (PdC). PLs, such as Spm, PdC, phosphatidylglycerol, PdE, phosphatidylserine and cardiolipin, inhibited hemolysis by leptospiral hemolysin, but phosphatidylinositol did not show any inhibitory activity. PLs lacking the amino group in the polar backbone of the molecules were more effective. From experiments using erythrocytes of various kinds of animals, it was revealed that the hemolytic sensitivity of mammalian erythrocytes to leptospiral hemolysin depended on the Spm content in the erythrocyte membrane. On the other hand, phospholipase C (PLase C) activity with Spm and PdC as substrates was detected in the culture supernatant of Leptospira. Therefore, leptospiral hemolysin was presumed to be PLase C, perhaps sphingomyelinase. The inhibitors of leptospiral hemolysin present in bovine serum were identified as PLs. PLs in bovine serum were suggested to function as inhibitors of the interaction between leptospiral hemolysin and the surface of the erythrocyte membrane.     

Peroxidation of liposomes in the presence of human erythrocytes and induction of membrane damage of erythrocytes by peroxidized liposomes

Hemolysis (Kobayashi, T., Takahashi, K., Yamada, A., Nojima, S. and Inoue, K. (1983) J. Biochem. 93, 675-680) and shedding of acetylcholinesterase-enriched membrane vesicles (diameter 150-200 nm) were observed when human erythrocytes were incubated with liposomes of phosphatidylcholine which contained polyunsaturated fatty acyl chains. These events occurring on erythrocyte membrane were inhibited by radical scavengers or incorporation of alpha-tocopherol into liposomes, suggesting that lipid peroxidation is involved in the process leading to membrane vesiculation and hemolysis. The idea was supported by findings that generation of chemiluminescence, formation of thiobarbituric acid reactive substance, accumulation of conjugated diene compounds in liposomes and decrease of polyunsaturated fatty acids in liposomes occurred concomitantly during incubation. Hemolysis was also suppressed by the addition of extra liposomes, insensitive to peroxidation, or of serum albumin even after the completion of peroxidation of liposomes. These results suggest that peroxidized lipids, responsible for vesiculation and hemolysis, may be formed first in liposomes and then gradually transferred to erythrocyte membranes. The accumulation of these lipids peroxides may eventually cause membrane vesiculation followed by hemolysis.     

Evidence for the Presence of a Ganglioside Transfer Protein in Brain

An extract from rat brain has been shown to catalyze the transfer of ganglioside GM1 from sonicated vesicles to erythrocyte ghosts. It also enhanced the transfer of GM1 to a crude neuronal membrane preparation, whereas myelin took up only a very limited amount. The transfer activity was heat-labile. Similar transfer activities were found in extracts from bovine gray and white matter, that of the former being comparable to rat brain whereas the latter was greater per milligram protein.