Membrane Phospholipid Organization Research Articles

31P NMR analysis of membrane phospholipid organization in viable, reversibly electropermeabilized Chinese hamster ovary cells.

Chinese hamster ovary (CHO) cells were reversibly permeabilized by submitting them to short, high-intensity, square wave pulses (1.8 kV/cm, 100 microseconds). The cells remained in a permeable state without loss of viability for several hours at 4 degrees C. A new anisotropic peak with respect to control cells was observed on 31 P NMR spectroscopic analysis of the phospholipid components. This peak is only present when the cells are permeable, and normal anisotropy is recovered after resealing. Taking into account the fusogenicity of electropermeabilized cells, comparative studies were performed on 5% poly(ethylene glycol) treated cells. The 31P NMR spectra of the phospholipids displayed the same anisotropic peak as in the case of the electropermeabilized cells. In the two cases, this anisotropic peak was located downfield from the main peak associated to the phospholipids when organized in bilayers. The localization of this anisotropic peak is very different from the one of a hexagonal phase. We proposed a reorganization of the polar head group region leading to a weakening of the hydration layer to account for these observations. This was also thought to explain the electric field induced fusogenicity of these cells.

Abnormal membrane phospholipid organization in Plasmodium falciparum-infected human erythrocytes.

The membrane phospholipid organization in Plasmodium falciparum-infected human erythrocytes was analysed by employing phospholipase A2 and Merocyanine 540 as external membrane probes. Both bee venom and pancreatic phospholipases A2 failed to hydrolyse phosphatidylserine in uninfected human red cells isolated from in vitro P. falciparum cultures. However, these enzymes under identical conditions readily degraded this aminophospholipid in P. falciparum-infected erythrocytes. Phosphatidylethanolamine hydrolysis also increased in parasitized cells. The degree to which these aminophospholipids were cleaved by the enzymes in intact infected cells depended on the developmental stage of the intracellular parasite, and was maximum at the schizont stage. This was consistent with the finding that the 'fluid-sensing' fluorescent dye, Merocyanine 540, readily labelled both the schizont and trophozoite-infected cells but not the fresh, uninfected or ring-infected erythrocytes. These results demonstrate that P. falciparum produces stage-dependent changes in the membrane phospholipid organization of its host erythrocyte.

An intracellular simian malarial parasite (Plasmodium knowlesi) induces stage-dependent alterations in membrane phospholipid organization of its host erythrocyte.

The membrane phospholipid organization in monkey erythrocytes harbouring different developmental stages of the simian malarial parasite Plasmodium knowlesi was studied using phospholipase A2 from two different sources and Merocyanine 540 as the external-membrane probes. Experiments were done to confirm that the phospholipases did not penetrate into the infected cells or hydrolyse phospholipids during membrane isolation. The parasite-free erythrocyte membrane was isolated by differential centrifugation or by using the cationic beads Affi-Gel 731. The purity of the membranes was established by optical and electron microscopy, and by assaying the parasite-specific enzyme glutamate dehydrogenase. About 10% of the phosphatidylethanolamine and none of phosphatidylserine were hydrolysed by the phospholipases in intact normal monkey erythrocytes. However, accessibility of these aminophospholipids to the enzymes was significantly enhanced in the infected cells under identical conditions. The degree of this enhancement depended on the developmental stage of the intracellular parasite, but not on the parasitaemia levels in the infected monkeys, and increased with the parasite growth inside the cells. Analogously, Merocyanine 540 was found to label the trophozoite- or schizont-infected erythrocytes, but not the ring-infected or normal cells. These results demonstrate that the intracellular malarial parasite produces stage-dependent alterations in the membrane phospholipid organization of its host erythrocyte.

Membrane phospholipid organization in calcium-loaded human erythrocytes

Intracellular Ca 2+ levels in human erythrocytes were increased by incubating them with variable concentrations of Ca 2+ in the presence of ionophore A23187. Experiments were done to confirm that the Ca 2+ loading did induce changes in the cell shape and membrane protein composition. The effect of the increased cytoplasmic Ca 2+ levels on the membrane phospholipid organization was analysed using bee venom and pancreatic phospholipases A 2, Merocyanine 540 and fluorescamine as the external membrane probes. About 20% phosphatidylethanolamine (PE) and 0% phosphatidylserine (PS) were hydrolysed by the phospholipases in intact control cells, whereas in identical conditions these enzymes readily degraded, 20–30% PE and 7–30% PS, in Ca 2+-loaded erythrocytes, depending on the cytoplasmic Ca 2+ concentration. Also, Merocyanine 540 failed to stain the fresh or control erythrocytes, but it labeled the cells loaded with Ca 2+. Furthermore, fluorescamine labeled approx. 20% PE in fresh or control erythrocytes while in identical conditions, significantly higher amounts of PE were modified in intact Ca 2+-loaded cells. These results demonstrate that Ca 2+ loading in human erythrocytes leads to loss of the transbilayer phospholipid asymmetry, and suggest that, together with spectrin, polypeptides 2.1 and 4.1 may also play an important role in maintaining the asymmetric distribution of various phospholipids across the erythrocyte membrane bilayer.

Membrane phospholipid organization as a determinant of blood cell‐reticuloendothelial cell interactions

Membrane phospholipid organization as a determinant of blood cell‐reticuloendothelial cell interactions

Altered Plasma Membrane Phospholipid Organization in Plasmodium falciparum-Infected Human Erythrocytes

The intraerythrocytic development of the malaria parasite is accompanied by distinct morphological and biochemical changes in the host cell membrane, yet little is known about development-related alterations in the transbilayer organization of membrane phospholipids in parasitized cells. This question was examined in human red cells infected with Plasmodium falciparum. Normal red cells were infected with strain FCR3 or with clonal derivatives that either produce (K+) or do not produce (K-) knobby protuberances on the infected red cells. Parasitized cells were harvested at various stages of parasite development, and the bilayer orientation of red cell membrane phospholipids was determined chemically using 2,4,6-trinitrobenzene sulphonic acid (TNBS) or enzymatically using bee venom phospholipase A2 (PLA2) and sphingomyelinase C (SMC). We found that parasite development was accompanied by distinct alterations in the red cell membrane transbilayer distribution of phosphatidylcholine (PC), phosphatidylethanolamine (PE), and phosphatidylserine (PS). Increases in the exoplasmic membrane leaflet exposure of PE and PS were larger in the late-stage parasitized cells than in the early-stage parasitized cells. Similar results were obtained for PE membrane distribution using either chemical (TNBS) or enzymatic (PLA2 plus SMC) methods, although changes in PS distribution were observed only with TNBS. Uninfected cohort cells derived from mixed populations of infected and uninfected cells exhibited normal patterns of membrane phospholipid organization. The observed alterations in P falciparum-infected red cell membrane phospholipid distribution, which is independent of the presence or absence of knobby protuberances, might be associated with the drastic changes in cell membrane permeability and susceptibility to early hemolysis observed in the late stages of parasite development.

Altered plasma membrane phospholipid organization in Plasmodium falciparum-infected human erythrocytes

The intraerythrocytic development of the malaria parasite is accompanied by distinct morphological and biochemical changes in the host cell membrane, yet little is known about development-related alterations in the transbilayer organization of membrane phospholipids in parasitized cells. This question was examined in human red cells infected with Plasmodium falciparum. Normal red cells were infected with strain FCR3 or with clonal derivatives that either produce (K+) or do not produce (K-) knobby protuberances on the infected red cells. Parasitized cells were harvested at various stages of parasite development, and the bilayer orientation of red cell membrane phospholipids was determined chemically using 2,4,6-trinitrobenzene sulphonic acid (TNBS) or enzymatically using bee venom phospholipase A2 (PLA2) and sphingomyelinase C (SMC). We found that parasite development was accompanied by distinct alterations in the red cell membrane transbilayer distribution of phosphatidylcholine (PC), phosphatidylethanolamine (PE), and phosphatidylserine (PS). Increases in the exoplasmic membrane leaflet exposure of PE and PS were larger in the late-stage parasitized cells than in the early-stage parasitized cells. Similar results were obtained for PE membrane distribution using either chemical (TNBS) or enzymatic (PLA2 plus SMC) methods, although changes in PS distribution were observed only with TNBS. Uninfected cohort cells derived from mixed populations of infected and uninfected cells exhibited normal patterns of membrane phospholipid organization. The observed alterations in P falciparum-infected red cell membrane phospholipid distribution, which is independent of the presence or absence of knobby protuberances, might be associated with the drastic changes in cell membrane permeability and susceptibility to early hemolysis observed in the late stages of parasite development.

Alteration of red cell membrane organization in sickle cell anaemia.

Bee venom phospholipase A2 and the fluorescent probe merocyanine 540 were used to examine plasma membrane phospholipid organization in the spicules released by deoxygenation and reoxygenation of sickle red cells, as well as in reversibly and irreversibly sickled erythrocytes. Digestion of phosphatidyl ethanolamine in spicules was comparable to that of phosphatidyl choline, and these structures were stained by the fluorescent probe. Both assays suggest that membrane lipid asymmetry is disrupted in spicules. The residual cells, from which the spicules were derived, retain the normal asymmetry in phospholipid distribution between the outer and inner leaflets of the plasma membrane bilayer. Comparable experiments with cell fractions enriched in irreversibly sickled cells revealed a partial enhancement of phosphatidyl ethanolamine digestion, confirming the similar experiments of Lubin et al (1981). Staining of these cells with merocyanine 540, however, did not reveal a subfraction of stainable cells, indicating that this increase in phosphatidyl ethanolamine digestion is not due to the presence of a small fraction of cells which have completely lost their membrane asymmetry.

In vivo externalization of phosphatidylserine and phosphatidylethanolamine in the membrane bilayer and hypercoagulability by the lipid peroxidation of erythrocytes in rats.

Phospholipid distribution across erythrocyte membrane bilayer is asymmetrical. In normal erythrocytes, entire phosphatidylserine (PS) and most of the phosphatidylethanolamine (PE) is present on the cytoplasmic side of membrane bilayer, whereas phosphatidylcholine (PC) and sphingomyelin (SM) are predominantly present at the outer side of membrane bilayer. The present study was undertaken to determine whether membrane lipid peroxidation has any effect on the distribution of PS, PE, and PC across erythrocyte membrane bilayer in vivo in an animal model. Erythrocyte membrane lipid peroxidation was induced in rats by administering phenylhydrazine, an oxidant drug. Membrane phospholipid organization was determined by using bee venom phospholipase-A2 and indirectly by measuring clotting time on recalcification of normal human platelet-poor plasma in the presence of Russell's viper venom. Phenylhydrazine administration to rats caused significant membrane lipid peroxidation as measured by the accumulation of malonyldialdehyde (MDA), an end product of fatty acid peroxidation, as well as externalization of a significant portion of PS and PE from the inner to the outer side of membrane bilayer in erythrocytes. There was a significant positive correlation (r) between the amount of MDA accumulated in the erythrocytes and the movement of PS (r = 0.92) and PE (r = 0.96) from inner to the outer membrane bilayer and PC (r = 0.81) from outer to the inner membrane bilayer. Erythrocytes of phenylhydrazine-treated rats also showed significantly reduced clotting time. This reduction in clotting time had a significant positive correlation with MDA accumulation (r = 0.92) and PS externalization (r = 0.90). Both the effect of phenylhydrazine on erythrocyte membrane lipid peroxidation and alterations in phospholipid organization and coagulability were blocked when rats were simultaneously administered with vitamin E or C antioxidants.

Increased adherence of sickled and phosphatidylserine-enriched human erythrocytes to cultured human peripheral blood monocytes.

The precise mechanism by which sickle erythrocytes (RBC) are removed from the circulation is controversial, although it is possible that enhanced recognition of these cells by circulating mononuclear phagocytes could contribute to this process. We investigated this possibility by interacting sickle cells with cultured human peripheral blood monocytes. Our results show that both irreversibly sickled cells (ISC) and deoxygenated reversibly sickled cells (RSC) had a higher avidity for adherence to monocytes than did oxygenated sickle and normal RBC. ISC were the most adherent cell type. Adherence of RSC to monocytes was found to be reversible; reoxygenation of deoxygenated RSC resulted in a significant decrease in RSC--monocyte adherence. Concomitant with alterations in sickle RBC adherence were alterations in the organization and bilayer distribution of membrane phospholipids in these cells. Specifically, enhanced adherence was associated with increased exposure of RBC membrane outer leaflet phosphatidylserine (PS) and phosphatidylethanolamine, whereas lack of adherence was associated with normal patterns of membrane phospholipid distribution. To investigate the possibility of whether the exposure of PS in the outer membrane leaflet of these cells might be responsible for their recognition by monocytes, the membranes of normal RBC were enriched with the fluorescent PS analogue 1-acyl-2[(N-4-nitro-benzo-2-oxa-1,3-diazole)aminocaproyl]-phosphatidy lse rine (NBD-PS) via transfer of the exogenous lipid from a population of donor phospholipid vesicles (liposomes). RBC enriched with NBD-PS exhibited enhanced adherence to monocytes, whereas adherence of RBC enriched with similar amounts of NBD-phosphatidylcholine (NBD-PC) was not increased. Furthermore, preincubation of monocytes with PS liposomes resulted in a approximately 60% inhibition of ISC adherence to monocytes, whereas no inhibition occurred when monocytes were preincubated with PC liposomes. These findings strongly suggest that erythrocyte surface PS may be a ligand recognized by receptors on human peripheral blood monocytes and that abnormal exposure of PS in the outer leaflet of the RBC membrane, as found in sickle RBC, might serve to trigger their recognition by circulating monocytes. Our results further suggest that abnormalities in the organization of erythrocyte membrane phospholipids may have significant pathophysiologic implications, possibly including shortened cell survival.

Membrane Phospholipid Organization and Vesiculation of Erythrocytes in Sickle Cell Anaemia

This review has examined the lipid composition of the RBC membrane and the methods used to determine the distribution of the phospholipids within the membrane. The importance of the membrane cytoskeletal proteins, in particular spectrin and protein 4.1, in maintaining this distribution has also been described. Membrane vesiculation and altered membrane phospholipid asymmetry in sickle cell anaemia have been reviewed. The relationships between vesiculation and hypercoagulability and an abnormal reticuloendothelial system in sickle cell disease have been examined. It is apparent that the single amino acid substitution leading to the production of sickle haemoglobin has profound effects on the entire erythrocyte, reaching to the limits of the cell, its plasma membrane.

Uncoupling of the membrane skeleton from the lipid bilayer. The cause of accelerated phospholipid flip-flop leading to an enhanced procoagulant activity of sickled cells.

We have previously reported that the normal membrane phospholipid organization is altered in sickled erythrocytes. More recently, we presented evidence of enhanced transbilayer movement of phosphatidylcholine (PC) in deoxygenated reversibly sickled cells (RSC) and put forward the hypothesis that these abnormalities in phospholipid organization are confined to the characteristic protrusions of these cells. To test this hypothesis, we studied the free spicules released from RSC by repeated sickling and unsickling as well as the remnant despiculated cells. The rate of transbilayer movement of PC in the membrane of deoxygenated remnant despiculated cells was determined by following the fate of 14C-labelled PC, previously introduced into the outer monolayer under fully oxygenated conditions using a PC-specific phospholipid exchange protein from beef liver. The rate of transbilayer movement of PC in the remnant despiculated cells was significantly slower than in deoxygenated native RSC and was not very much different from that in oxygenated native RSC or irreversibly sickled cells. The free spicules had the same lipid composition as the native cells, but were deficient in spectrin. These spicules markedly enhanced the rate of thrombin formation in the presence of purified prothrombinase (Factor Xa, Factor Va, and Ca2+) and prothrombin, indicating the exposure of a significant fraction of phosphatidylserine (PS) in the outer monolayer. This effect was not observed when the spicules in this assay were replaced by normal erythrocytes, deoxygenated native RSC, or a deoxygenated sample of RSC after repetitive sickling/unsickling. The results are interpreted to indicate that the destabilization of the lipid bilayer in sickled cells, expressed by the enhanced flip-flop of PC and the exposure of PS in the outer monolayer, occurs predominantly in those parts of the membrane that are in spicular form.

Rhnull human erythrocytes have an abnormal membrane phospholipid organization.

Rhnull human erythrocytes lack the antigens of the Rhesus blood group system, have an abnormal shape and an increased osmotic fragility, and are associated with mild chronic haemolytic anaemia. Studies with phospholipase A2 and sphingomyelinase C show that the asymmetric distribution of phosphatidylethanolamine (PtdEtn) in the membrane of these cells differs from that found in control cells. The amount of PtdEtn which can be hydrolysed by phospholipase A2 in the presence of sphingomyelinase C in intact Rhnull cells is twice as high as that in normal erythrocytes. In intact Rhnull cells all of the phosphatidylcholine (PtdCho) present in the membrane can be readily exchanged with a PtdCho-specific exchange protein, whereas in control cells 75% is readily exchanged and 25% at a much lower rate. This indicates that PtdCho experiences a relatively fast transbilayer movement in the Rhnull cells. The observation that the loss of two membrane polypeptides in the Rhnull cells leads to abnormal shape, increased osmotic fragility, abnormal PtdEtn distribution and enhanced transbilayer mobility of PtdCho strongly suggests that one or both polypeptides are essential for the maintenance of a proper membrane-membrane skeleton interaction.

Electron spin resonance study on the mechanism of polyethylene glycol—membrane interaction

There is a growing interest in the application of cell fusion in various fields of modern bioiogy. Besides viruses, some chemicals are also effective in causing biological membranes to fuse. Among the most potent fusogens of this type appear to be polymers of ethylene glycol. Polyethylene glycol (PEG) has been used to fuse a great variety of cell types [l-3]. The wide applications of PEG-induced cell fusion stimulate research on the mechanism by which the polymer interacts with biological membranes. Most of the studies performed have been focussed on the effect of PEG on the organization of membrane phospholipids [4131. The molecular mechanism of PEG-membrane interaction and the sequence of events leading to cell fusion remain, however, not fully understood. Particularly little is known about the effect of PEG on the physica state of membrane proteins. Spin labels used in this study, 2,2,6,6-tetramethyl-4-maleimidopiperidine-I-oxyl (MSL) and 5-doxylstearic acid, were obtained from Syva (Palo Alto CA). Chromatographically pure egg yolk phosphatidylcholine and cholesterol were from Sigma (St Louis MO). Polyethylene glycol A4,6000 (PEG 6000) was supplied by Loba (Vienna). Human erythrocyte ghost membranes were prepared as in [14]. Protein spin-labeling with MSL and lipid spin-labeling with S-doxylstearic acid were performed as in [15].

Peroxidation, vitamin E, and sickle-cell anemia.

In summary, we propose the following scheme (Figure 5) to describe the role of peroxidation in the pathophysiology of SCA. Sickle erythrocytes are more susceptible to peroxidation than are normal erythrocytes. This increased susceptibility to peroxidation is, in part, due to decreased blood vitamin E levels and abnormal membrane phospholipid organization induced by sickling. The peroxidative damage of sickle erythrocytes may accelerate or contribute to loss of cell deformability and to chronic hemolysis. Peroxidative damage can produce abnormal cellular properties, such as potassium leak and reduced filterability, and contribute to formation of ISCs. Increased red cell rigidity can initiate episodes of capillary obstruction, leading to vasoocclusive painful crises and to tissue infarction. Liver dysfunction as well as increased production of bilirubin secondary to hemolysis could result in bile sludging and decreased secretion of bile salts into the intestinal lumen. Reduced bile salt secretion leads to partial fat and vitamin E malabsorption. Vitamin E deficiency enhances red cell susceptibility to peroxidation and promotes a vicious cycle in SCA. Although we have not studied factors that might initiate peroxidative damage, sickle hemoglobin and excess body iron should be considered as potential sources. Our studies suggest that vitamin E supplementation to sickle-cell patients could be of clinical benefit.

Membrane alterations in cellular aging: Susceptibility of phospholipids in density (age)-separated human erythrocytes to phospholipase A 2

Human erythrocytes were separated into four density (age) groups representing the top 10% (young), bottom 10% (old), and two middle fractions of 40% each (intermediary ages). When these erythrocytes of different age groups were treated with the low levels of a purified basic phospholipase A 2 from Agkistrodon halys blomhofii, under conditions where little or no hemolysis occurred, the optimum extent of phosphatidylcholine (PC) hydrolysis in all age groups was the same, but interestingly, the rate of its hydrolysis was two to three times faster in the older cells compared to younger erythrocytes. On the other hand, hydrolysis of phosphatidylethanolamine (PE) of younger erythrocytes by the phospholipase A 2 was negligible under the particular experimental conditions. However, in erythrocytes of older age groups, both the rate and extent of PE hydrolysis by the enzyme increased in a distinctive fashion. Concomitant with the above pattern of PC and PE hydrolysis, the shape changes in the erythrocytes also were different; whereas all older erythrocytes became echinocytic only two-thirds of the younger erythrocytes showed a similar shape change. These observations firmly establish that during in vivo aging of normal erythrocytes in circulation significant changes in the structural organization of membrane phospholipids take place. Importance of this phenomenon in membrane phospholipid asymmetry studies and in the elimination of senescent cells also is discussed.

92] Analysis of rod outer segment disk membrane phospholipid organization using parinaric acid fluorescent probes

Publisher Summary This chapter considers the application of the parinaric acid (PnA) fluorescent probes to the analysis of rod outer segment membrane phospholipid organization. This analysis is comprised of several parts: (1) the partition of PnA probes between aqueous phase and embranes, (2) the identification of phospholipid phase separation in rod outer segment membrane lipids with PnA probes, (3) the partition of PnA isomers between coexisting fluid and solid phospholipid phases, (4) the reconstruction of the thermal reorganization in rod outer segment membranes based on measurements of model dispersions comprising the individual membrane monolayers, and (5) the effects of Ca 2+ on rod outer segment phospholipids. This chapter concludes that membranes with broad, relatively featureless thermal behavior may well contain a superposition of relatively sharp thermal components. PnA probes or their methyl ester derivatives are readily incorporated into stirred membrane suspensions or phospholipid dispersions at 37 ° when added slowly as microliter aliquots of dilute ethanolic solutions (

Organization and role of platelet membrane phospholipids as studied with phospholipases A 2 from various venoms and phospholipases C from bacterial origin

Phospholipases A 2 from various snake or bee venoms and phospholipases C secreted as exotoxins by several bacteria have been used to study the transverse distribution of phospholipids in the platelet plasma membrane and their role in platelet activation. An asymmetric distribution was described for phospholipids, characterized by a preferential localization of sphingomyelin and phosphatidylcholine in plasma membrane outer leaflet, whereas the inner half contains almost all of the anionic procoagulant phosphatidylserine and phosphatidylinositol. Such a distribution might explain the latency of procoagulant activity in resting platelets and implies an intracellular localization of arachidonic acid, the precursor of prostaglandins and thromboxanes. The external arachidonic acid is involved in phospholipase A 2-induced aggregation, whereas phospholipase C from Clostridium welchii stimulates platelets through a thromboxane-independent pathway. The latter one is directly linked to the formation of phosphatidic and lysophosphatidic acids, which are able to activate cells through calcium mobilization. So, phospholipase C represents an interesting tool for studying the biochemical processes accompanying stimulation, since it is shown that it mimicks the effects of an intracellular phospholipase C, the role of which in platelet activation is discussed.

Abnormalities in membrane phospholipid organization in sickled erythrocytes.

In contrast to the wealth of information concerning membrane phospholipid asymmetry in normal human erythrocytes, very little is known about membrane phospholipid organization in pathologic erythrocytes. Since the spectrin-actin lattice, which has been suggested to play an important role in stabilizing membrane phospholipid asymmetry, is abnormal in sickled erythrocytes, we determined the effects of sickling on membrane phospholipid organization. We used two enzymatic probes: been venom phospholipase A2 and Staphylococcus aureus sphingomyelinase C, which do not penetrate the membrane and react only with phospholipids located in the outer leaflet of the bilayer. Our results suggest that the distribution of glycerophospholipids within the membrane of sickled cells is different from that in nonsickled cells. Compared with the normal erythrocyte, the outer membrane leaflet of the deoxygenated, reversibly sickled cells (RSC) and irreversibly sickled cells (ISC) was enriched in phosphatidyl ethanolamine in addition to containing phosphatidyl serine. These changes were compensated for by a decrease in phosphatidyl choline in that layer. The distribution of sphingomyelin over the two halves of the bilayer was unaffected by sickling. In contrast to ICS, where the organization of phospholipids was abnormal under both oxy and deoxy conditions, reoxygenation of RSC almost completely restored the organization of membrane phospholipids to normal. These results indicate that the process of sickling induces an abnormality in the organization of membrane phospholipids to normal. These results indicate that the process of sickling induces an abnormality in the organization of membrane lipids in RSC which become permanent in ISC.

Organization and role of platelet membrane phospholipids as studied with purified phospholipases

The action of various purified phospholipases on intact cells is reviewed, with special emphasis on platelets. Their effects are strongly dependent on the substrate specificity of the enzymes. Moreover, phospholipases can be divided into two groups according to their ability to hydrolyse phospholipids in an intact cell. Comparative studies of their behaviour towards phospholipid monolayers maintained at different surface pressures have allowed to estimate the surface pressure of erythrocyte and platelet membrane as 31–34 dynes/cm.