Investigation into the role of phosphatidylserine in modifying the susceptibility of human lymphocytes to secretory phospholipase A(2) using cells deficient in the expression of scramblase

Normal human lymphocytes resisted the hydrolytic action of secretory phospholipase A(2) but became susceptible to the enzyme following treatment with a calcium ionophore, ionomycin. To test the hypothesis that this susceptibility requires exposure of the anionic lipid phosphatidylserine on the external face of the cell membrane, experiments were repeated with a human Burkitt's lymphoma cell line (Raji cells). In contrast to normal lymphocytes or S49 mouse lymphoma cells, most of the Raji cells (83%) did not translocate phosphatidylserine to the cell surface upon treatment with ionomycin. Those few that did display exposed phosphatidylserine were hydrolyzed immediately upon addition of phospholipase A(2). Interestingly, the remaining cells were also completely susceptible to the enzyme but were hydrolyzed at a slower rate and after a latency of about 100s. In contradistinction to the defect in phosphatidylserine translocation, Raji cells did display other physical membrane changes upon ionomycin treatment that may be relevant to hydrolysis by phospholipase A(2). These changes were detected by merocyanine 540 and trimethylammonium diphenylhexatriene fluorescence and were common among normal lymphocytes, S49 cells, and Raji cells. The levels of these latter effects corresponded well with the relative rates of hydrolysis among the three cell lines. These results suggested that while phosphatidylserine enhances the rate of cell membrane hydrolysis by secretory phospholipase A(2), it is not an absolute requirement. Other physical properties such as membrane order contribute to the level of membrane susceptibility to the enzyme independent of phosphatidylserine.     

Role of membrane oxidation in controlling the activity of human group IIa secretory phospholipase A2 toward apoptotic lymphoma cells

The membranes of healthy lymphocytes normally resist hydrolysis by secretory phospholipase A₂. However, they become susceptible during the process of apoptosis. Previous experiments have demonstrated the importance of certain physical changes to the membrane during cell death such as a reduction in membrane lipid order and exposure of phosphatidylserine on the membrane surface. Nevertheless, those investigations also showed that at least one additional factor was required for rapid hydrolysis by the human group IIa phospholipase isozyme. This study was designed to test the possibility that oxidation of membrane lipids is the additional factor. Flow cytometry and confocal microscopy with a fluorescent probe of oxidative potential suggested that oxidation of the plasma membrane occurs during apoptosis stimulated by thapsigargin. When oxidative potential was high, the activity of human group IIa secretory phospholipase A₂ was enhanced 30- to 100-fold compared to that observed with conditions sufficient for maximal hydrolysis by other secretory phospholipase A₂ isoforms. Direct oxidation of cell membranes with either of two oxidizing agents also stimulated hydrolysis by secretory phospholipase A₂. Both oxidizers caused externalization of phosphatidylserine, but a change in lipid order did not always occur. These results demonstrated that membrane oxidation strongly stimulates human group IIa secretory phospholipase A₂ activity toward apoptotic cells. Interestingly, the change in membrane order, previously thought to be imperative for high rates of hydrolysis, was not required when membrane lipids were oxidized. Whether phosphatidylserine exposure is still necessary with oxidation remains unresolved since the two events could not be deconvoluted.     

Sequence of Physical Changes to the Cell Membrane During Glucocorticoid-Induced Apoptosis in S49 Lymphoma Cells

During apoptosis, physical changes in the plasma membrane prepare the cell for clearance by phagocytes and hydrolysis by secretory phospholipase A₂ (sPLA₂). The relationships among these changes have not been adequately established, especially for hormone-stimulated apoptosis. This study addresses these issues for glucocorticoid-induced apoptosis in S49 lymphoma cells. Flow cytometry, microscopy, and fluorescence spectroscopy were used to assess merocyanine 540 emission, laurdan generalized polarization, phosphatidylserine exposure, caspase activation, and membrane permeability to propidium iodide in the absence and presence of sPLA₂. The earliest event observed was activation of cellular caspases. Results with membrane probes suggest that interlipid spacing also increases early during apoptosis and precedes transbilayer migration of phosphatidylserine, DNA fragmentation, and a general increase in lipid order associated with blebbing and dissolution of the cells. The activity of sPLA₂ appeared to be linked more to lipid spacing than to loss of membrane asymmetry. The early nature of some of these events and their ability to promote activity of a proinflammatory enzyme suggests the possibility of an inflammatory response during T-lymphocyte apoptosis.     

Prostaglandin phospholipid conjugates with unusual biophysical and cytotoxic properties

The synthesis of two secretory phospholipase A₂ IIA sensitive 15-deoxy-Δ^12,14-prostaglandin J₂ phospholipid conjugates is described and their biophysical and biological properties are reported. The conjugates spontaneously form particles in the liposome size region upon dispersion in an aqueous buffer and both phospholipids are hydrolyzed by phospholipase A₂, but with different conversion rates and extent of hydrolysis. The cytotoxicity was evaluated in HT-29 and Colo205 cells and the conjugates induced cell death in the presence of phospholipase A₂ and surprisingly also in the absence of the enzyme.     

Mechanisms by which elevated intracellular calcium induces S49 cell membranes to become susceptible to the action of secretory phospholipase A2

Exposure of S49 lymphoma cells to exogenous group IIA or V secretory phospholipase A2 (sPLA2) caused an initial release of fatty acid followed by resistance to further hydrolysis by the enzyme. This refractoriness was overcome by exposing cells to palmitoyl lysolecithin. This effect was specific in terms of lysophospholipid structure. Induction of membrane susceptibility by lysolecithin involved an increase in cytosolic calcium and was duplicated by incubating the cells with calcium ionophores such as ionomycin. Lysolecithin also activated cytosolic phospholipase A2 (cPLA2). Inhibition of this enzyme attenuated the ability of lysolecithin (but not ionomycin) to induce susceptibility to sPLA2. Lysolecithin or ionomycin caused concurrent hydrolysis of both phosphatidylethanolamine and phosphatidylcholine implying that transbilayer movement of phosphatidylethanolamine occurred upon exposure to these agents but that susceptibility is not simply due to exposure of a preferred substrate (i.e. phosphatidylethanolamine) to the enzyme. Microvesicles were apparently released from the cells upon addition of lysolecithin or ionomycin. Both these vesicles and the remnant cell membranes were susceptible to sPLA2. Together these data suggest that lysolecithin induces susceptibility through both cPLA2-dependent and -independent pathways. Whereas elevated cytosolic calcium was required for both pathways, it was sufficient only for the cPLA2-independent pathway. This cPLA2-independent pathway involved changes in cell membrane structure associated with transbilayer phospholipid migration and microvesicle release.     

Asymmetry of the phospholipid bilayer of rat liver endoplasmic reticulum

The phospholipids of intact microsomal membranes were hydrolysed 50% by phospholipase C of Clostridium welchii, without loss of the secretory protein contents of the vesicle, which are therefore not permeable to the phospholipase. Phospholipids extracted from microsomes and dispersed by sonication were hydrolysed rapidly by phospholipase C-Cl. welchii with the exception of phosphatidylinositol. Assuming that only the phospholipids of the outside of the bilayer of the microsomal membrane are hydrolysed in intact vesicles, the composition of this leaflet was calculated as 84% phosphatidylcholine, 8% phosphatidylethanolamine, 9% sphingomyelin and 4% phosphatidylserine, and that of the inner leaflet 28% phosphatidylcholine, 37% phosphatidylethanolamine, 6% phosphatidylserine and 5% sphingomyelin. Microsomal vesicles were opened and their contents released in part by incubation with deoxycholate (0.098%) lysophosphatidylcholine (0.005%) or treatment with the French pressure cell. Under these conditions, hydrolysis of the phospholipids by phospholipase C-Cl. welchii was increased and this was mainly due to increased hydrolysis of those phospholipids assigned to the inner leaflet of the bilayer, phosphatidylethanolamine and phosphatidylserine. Phospholipase A₂ of bee venom and phospholipase C of Bacillus cereus caused rapid loss of vesicle contents and complete hydrolysis of the membrane phospholipids, with the exception of sphingomyelin which is not hydrolysed by the former enzyme.     

Phospholipase A2 activity in pancreatic islets is calcium-dependent and stimulated by glucose

Phospholipase A₂ activity in islet cell homogenates and dispersed islet cells of the rat was determined using an exogenous radiolabeled phospholipid substrate from $\text{E.}$$\text{coli}$ membranes. Phospholipase A₂ activity in islet homogenates was found to have two pH optima in acid or neutral/alkaline pH ranges. The enzyme activity at pH 7.5 was calcium dependent and responded to increasing calcium concentrations with graded increases in phospholipid hydrolysis. Preincubation of islets with a concentration of glucose known to elicit maximum rates of insulin secretion resulted in a stable activation of phospholipase A₂ activity which was assayable in islet homogenates. Glucose stimulated phospholipase A₂ in these preparations by as much as 220% above control. 2-Deoxy-D-glucose, a nonsecretory analogue of glucose, did not elicit a significant increase in islet phospholipase A₂ activity. The glucose sensitive enzyme was associated with a membrane-enriched subcellular fraction in which the glucose-stimulated activity was greater than 2-fold higher than control activity. Glucose stimulation potentiated the phospholipase A₂ activity measured in the presence of high calcium concentrations. Phospholipase A₂ activity was also found in dispersed islet cell preparations where glucose stimulation of what may be a partly externalized membrane enzyme was most apparent at low calcium concentrations. These data indicate that islet cells possess phospholipase A₂ activity which may be in part localized to the plasma membrane as well as other membrane systems, and which exhibits the characteristic properties of pH and calcium dependency, and sensitivity to secretagogue stimulation reported for the enzyme in other secretory systems.     

Relationship between membrane permeability and specificity of human secretory phospholipase A(2) isoforms during cell death

During apoptosis, a number of physical changes occur in the cell membrane including a gradual increase in permeability to vital stains such as propidium iodide. This study explored the possibility that one consequence of membrane changes concurrent with early modest permeability is vulnerability to degradation by secretory phospholipase A(2). The activity of this hydrolytic enzyme toward mammalian cells depends on the health of the cell; healthy cells are resistant, but they become susceptible early during programmed death. Populations of S49 lymphoma cells during programmed death were classified by flow cytometry based on permeability to propidium iodide and susceptibility to secretory phospholipase A(2). The apoptotic inducers thapsigargin and dexamethasone caused modest permeability to propidium iodide and increased staining by merocyanine 540, a dye sensitive to membrane perturbations. Various secretory phospholipase A(2) isozymes (human groups IIa, V, X, and snake venom) preferentially hydrolyzed the membranes of cells that displayed enhanced permeability. In contrast, cells exposed briefly to a calcium ionophore showed the increase in cell staining intensity by merocyanine 540 without accompanying uptake of propidium iodide. Under that condition, only the snake venom and human group X enzymes hydrolyzed cells that were dying. These results suggested that cells showing modest permeability to propidium iodide during the early phase of apoptosis are substrates for secretory phospholipase A(2) and that specificity among isoforms of the enzyme depends on the degree to which the membrane has been perturbed during the death process. This susceptibility to hydrolysis may be important as part of the signal to attract macrophages toward apoptotic cells.     

On the interaction between intrinsic proteins and phosphatidylglycerol in the membrane of Acholeplasma laidlawii.

About 30% of the phosphatidylglycerol in oleic acid-enriched Acholeplasma laidlawii membranes are not hydrolyzed at temperatures below 10 °C by phospholipase A₂ from porcine pancreas. Removal of 53% of the membrane proteins by proteolysis did not reduce the size of this inaccessible phosphatidylglycerol pool. However, modification of the membrane proteins with 2,4,6-trinitrobenzenesulfonic acid or glutaraldehyde did make an additional 70% of this protected pool of phosphatidylglycerol accessible to phospholipase A₂. Complete hydrolysis of phosphatidylglycerol at low incubation temperatures was achieved only after heat treatment of the membranes which resulted in an extensive aggregation of intrinsic membrane proteins as visualized by freeze-etch electron microscopy. Phospholipase A₂ from bee venom was more effective in hydrolyzing phosphatidylglycerol at low temperature than the pancreatic enzyme. These results show that the inaccessibility of phosphatidylglycerol is not due to resealing of isolated membranes, the presence of a crystalline phase in the membrane lipids, or a shielding effect of surface proteins. The protection against hydrolysis may be due to an interaction of phosphatidylglycerol with intrinsic membrane proteins which is stabilized at low temperatures. Increasing the temperature favors the exchange of protein-bound phosphatidylglycerol with other membrane lipids resulting in complete hydrolysis.     

Ionomycin causes susceptibility to phospholipase A2 while temperature-induced increases in membrane fluidity fail: Possible involvement of actin fragmentation

A diminution in the order of membrane lipids, which occurs during apoptosis, has been shown to correlate with increased membrane susceptibility to hydrolysis by secretory phospholipase A₂. Studies with artificial membranes, however, have demonstrated that the relationship between membrane order and hydrolysis is more complex than suggested thus far by cell studies. To better resolve this relationship, this study focused on comparisons between increasing temperature and calcium ionophore as means of decreasing membrane order in S49 cells. Although these two treatments caused comparable changes in apparent membrane order as detected by steady-state fluorescence measurements, only ionophore treatment enhanced phospholipase activity. Experiments with exogenously-added phosphatidylserine indicated that the difference was not due to the presence of that anionic phospholipid in the outer membrane leaflet. Instead, analysis of the equilibration kinetics of various cationic membrane probes revealed that the difference could relate to the spacing of membrane lipids. Specifically, ionophore treatment increased that spacing while temperature only affected overall membrane order and fluidity. To consider the possibility that the distinction with ionophore might relate to the actin cytoskeleton, cells were stained with phalloidin and imaged via confocal microscopy. Ionophore caused disruption of actin fibers while increased temperature did not. This apparent connection between membrane hydrolysis and the cytoskeleton was further corroborated by examining the relationship among these events during apoptosis stimulated by thapsigargin.     

Susceptibility of S49 lymphoma cell membranes to hydrolysis by secretory phospholipase A(2) during early phase of apoptosis

During cell death, plasma membranes of cells become vulnerable to attack by extracellular secretory phospholipase A(2). The purpose of this study was to identify the timing of this phenomenon relative to other events that occur during the process of cell death. Death was induced in S49 murine lymphoma cells by treatment with dexamethasone, dibutyryl cAMP, ionomycin, thapsigargin, or heat shock (1 h at 43 degrees C). The appearance of membrane susceptibility to secretory phospholipase A(2) was compared to the following apoptotic events: loss of mitochondrial membrane potential, phosphatidylserine exposure in the outer leaflet of the cell membrane, early DNA damage assessed by the comet assay, and changes in cell size and internal complexity assessed by flow cytometry. Each inducer of death was distinct in the time course of events produced. Although dead cells were susceptible to the action of phospholipase A(2), live cells (impermeable to propidium iodide) also became vulnerable to the enzyme during characteristic time courses after exposure to each inducer. In fact, susceptibility to sPLA(2) was observed in each case prior to or concurrent with the earliest of the markers of apoptosis. These results demonstrate that the onset of susceptibility to sPLA(2) is an early event in apoptosis suggesting that changes in membrane structure may be relevant to initial aspects of the apoptotic process.     

Modification of the tetrodotoxin receptor in Electrophorus electricus by phospholipase A2

The effects of phospholipase A₂ treatment on the tetrodotoxin receptors in Electrophorus electricus was studied. (1) The binding of [³H]tetrodotoxin to electroplaque membranes was substantially reduced by treatment of the membranes with low concentrations of phospholipase A₂ from a number of sources, including bee venom, Vipera russelli and Crotalus adamanteus and by $\text{β-}\text{bungarotoxin}$. (2) Phospholipase A₂ from bee venom and from C. adamanteus both caused extensive hydrolysis of electroplaque membrane phospholipids although the substrate specificity differed. Analysis of the phospholipid classes hydrolyzed revealed a striking correlation between loss of toxin binding and hydrolysis of phosphatidylethanolamine but not of phosphatidylserine. (3) The loss of toxin binding could be partially reversed by treatment of the membranes with bovine serum albumin, conditions which are known to remove hydrolysis products from the membrane. (4) Equilibrium binding studies on the effects of phospholipase A₂ treatment on [³H]tetrodotoxin binding showed that the reduction reflected loss of binding sites and not a change in affinity. (5) These results are interpreted in terms of multiple equilibrium states of the tetrodotoxin-receptors with conformations determined by the phospholipid environment.     

The preservation of Mycoplasma capricolum cell intactness after phospholipase A2 treatment

(1) By treating Mycoplasma capricolum cells with phospholipase A₂ about 80% of membrane phospholipids were rapidly hydrolyzed. The rate and extent of hydrolysis (at 37°C) were the same in intact cells and in isolated unsealed membranes. (2) Due to the low endogenous lysophospholipase activity detected in M. capricolum, phospholipase A₂ treatment resulted in the accumulation of lysophospholipids and free fatty acids. The free fatty acids were efficiently extracted from the cells by 1% bovine serum albumin whereas the lysophospholipids were almost fully retained within the cell membrane. (3) Following phospholipase A₂ treatment in the presence of 1% bovine serum albumin, cell intactness was preserved as indicated by the constant absorbance of the cell suspension and the retention of nucleic acids and NADH dehydrogenase activity within the cells. The treated cells showed, however, a slight decrease in K⁺ content and a decrease in cell viability. Viability was fully preserved after phospholipase A₂ treatment of cells grown with exogenous sphingomyelin. (4) Adapting M. capricolum to a cholesterol-poor medium resulted in a marked decrease in the cholesterol to phospholipid molar ratio (from about 1.1 to 0.3). Phospholipase A₂ treatment of the cholesterol-poor cells resuted in cell lysis. Cell lysis was induced in the cholesterol-rich cells by hydrolysing the lysophospholipids accumulated following phospholipase A₂ treatment. (5) It is suggested that after phospholipase A₂ treatment of M. capricolum cells, a relatively stable cell membrane is maintained and cell intactness is preseved due to the interaction of cholesterol, present in high amount in this membrane, with the lysophospholipids formed.     

Effects of cholesterol on physical properties of human erythrocyte membranes: impact on susceptibility to hydrolysis by secretory phospholipase A2

The ability of secretory phospholipase A₂ (sPLA₂) to hydrolyze cell membranes is highly dependent on the physical properties of the membrane. The effects of cholesterol on these properties have been characterized in artificial bilayers and found to alter sPLA₂ activity significantly. It is hypothesized that the natural difference in cholesterol content between erythrocytes and leukocytes is in part responsible for their differing susceptibility to hydrolysis by sPLA₂. To test this hypothesis, defined amounts of cholesterol were removed from erythrocyte membranes using methyl-β-cyclodextrin. Treatment of cells with methyl-β-cyclodextrin increased the hydrolysis rate and total substrate hydrolyzed by sPLA₂. In general, this effect of cholesterol removal was more pronounced at higher temperatures. Comparison of the level of membrane order (assessed with the fluorescent probe laurdan) with hydrolysis rate revealed that sPLA₂ activity was greatly enhanced upon significant reductions in lipid order. Additional treatment of the cells with calcium ionophore further enhanced the hydrolysis rate and altered the relationship with membrane order. These data demonstrated that interactions with sPLA₂ observed in artificial bilayers apply to biological membranes. It is also proposed that the high level of cholesterol in erythrocyte membranes is a protective mechanism to guard against hydrolytic enzymes.     

Action of phospholipase A2 of rabbit neuronal and glial cells on 1,2-diacyl-, 2-acyl-1-alk-1′-enyl-, and 2-acyl-1-alkyl-glycerophosphatides

Pronounced differences in the phospholipase A₂ activities were found in neurons and glia, the enzyme activity being two- to threefold higher in neurons than in glial cells. Both phospholipases A₂ hydrolyzed the 1,2-diacylglycerophosphatides more rapidly than the acylalkyl and acylalkenyl compounds. Choline plasmalogen and the corresponding alkyl derivative were cleaved at similar rates by the phospholipase A₂ from both glia and neurons. There was a tendency by the neuronal phospholipase A₂ to release arachidonic acid faster than linolenic acid from both phosphatidylcholine and ethanolamine, while arachidonic acid was removed less actively from phosphatidylethanolamine by the glial enzyme. The glial phospholipase A₂ showed a lag period of 10 or 20 min. Norepinephrine, injected into the lateral ventricle of the rabbit brain, stimulated the hydrolysis of the various 1,2-diacyl-, acylalkyl-, and acylalkenyl-glycerophosphatides by the phospholipase A₂ from both glia and neurons.     

Isolation and characterization of the major phospholipase a2 from the venom of trimeresurus purpureomaculatus (shore pit viper)

• 1.1. The major phospholipase A₂ (PLA-DE4) of the venom of Trimeresurus purpureomaculatus (shore pit viper) has been purified to electrophoretic homogeneity.
• 2.2. The isoelectric point of the purified enzyme was determined to be 4.20, and the mol. wt was 31,700 as estimated by Sephadex G-75 gel filtration chromatography; and 14.000 as estimated by SDS-polyacrylamide gel electrophoresis.
• 3.3. The purified enzyme hydrolyzed phosphatidylcholine (PC) faster than phosphatidylethanolamine (PE), whereas phosphatidylserine (PS) was not hydrolyzed at all (PC > PE > PS = 0). However, in reaction system consisted of mixtures of PC and PS, phosphatidylserine was effectively hydrolyzed by the enzyme.
• 4.4. The phospholipase A₂ exhibited edema-forming activity but not hemolytic, hemorrhagic or anticoagulant activities. It was not lethal to mice at a dosage of 10 μg/g by i.v. route.

     

Studies on the hemolytic and hydrolytic actions of phospholipases against mammalian erythrocyte membranes.

The hemolytic actions of three kinds of phospholipase C on horse and sheep erythrocytes were studied in relation to their hydrolytic activities on the phospholipid components of these red cells. Clostridium novyi (oedematiens) type A phospholipase C hemolyzed horse red cells by hydrolyzing phosphatidylcholine. However, the enzyme did not lyse sheep cells nor did it hydrolyze any phospholipid under the same conditions, although this enzyme hydrolyzed both sphingomyelin and phosphatidylethanolamine in the phospholipid mixture extracted from sheep red cells. Clostridium perfringens phospholipase C hemolyzed not only horse red cells by hydrolyzing phosphatidylcholine but also sheep red cells by hydrolyzing sphingomyelin. Sphingomyelin on sheep red cell membrane was hydrolyzed 10 times faster by this enzyme than that on horse red cell membrane. Pseudomonas aureofaciens phospholipase C hemolyzed horse red cells by attacking phosphatidylcholine and phosphatidylethanolamine. The enzyme did not attack sheep red cells but it did hydrolyze phosphatidylethanolamine in the extracted phospholipid mixture from sheep cells. The hemolytic activity of phospholipase C depends not only on the enzyme and the asymmetric distribution of phospholipids in the erythrocyte membrane but also on the accessibility of the enzymes to the phospholipids in the surface of the membranes. Hemolysis by phospholipase C belongs to a hot-cold type of lysis.     

Lactadherin Inhibits Secretory Phospholipase A2 Activity on Pre-Apoptotic Leukemia Cells

Secretory phospholipase A₂ (sPLA₂) is a critical component of insect and snake venoms and is secreted by mammalian leukocytes during inflammation. Elevated secretory PLA₂ concentrations are associated with autoimmune diseases and septic shock. Many sPLA₂’s do not bind to plasma membranes of quiescent cells but bind and digest phospholipids on the membranes of stimulated or apoptotic cells. The capacity of these phospholipases to digest membranes of stimulated or apoptotic cells correlates to the exposure of phosphatidylserine. In the present study, the ability of the phosphatidyl-L-serine-binding protein, lactadherin to inhibit phospholipase enzyme activity has been assessed. Inhibition of human secretory phospholipase A₂-V on phospholipid vesicles exceeded 90%, whereas inhibition of Naja mossambica sPLA₂ plateaued at 50–60%. Lactadherin inhibited 45% of activity of Naja mossambica sPLA₂ and >70% of human secretory phospholipase A₂-V on the membranes of human NB4 leukemia cells treated with calcium ionophore A23187. The data indicate that lactadherin may decrease inflammation by inhibiting sPLA₂.     

Differences in the pattern of attack of acidic,neutral, and basic phospholipases A2 of A. halys blomhofii on human erythrocyte membranes: Problems in interpretation of phospholipid location

Purified acidic (pI 4.9), neutral (pI 6.9), and basic (pI 8.7) phospholipase A₂ from Agkistrodon halys blomhofii showed characteristically different patterns of hemolysis and phospholipid hydrolysis of intact human erthyrocytes. Acidic and neutral enzymes were nonlytic in the early periods of incubations with intact erythrocytes whereas the basic enzyme caused immediate hemolysis (5–8%). Under nonlytic conditions acidic and neutral enzymes hydrolyzed only phosphatidyl choline (PC) (20 and 50%, respectively), whereas basic enzyme hydrolyzed not only PC (60%) but nearly 15% of the phosphatidylethanolamine (PE). Both PC and PE were hydrolyzed significantly when the three phospholipases A₂ were incubated individually with erythrocyte lysate or hypotonic ghosts (sealed or unsealed). The order of substrate preference for acidic and neutral enzymes was always PC > PE. On the contrary basic enzyme exhibited the property of substrate specificity reversal. It hydrolyzed PC faster than PE when the membranes were sealed whereas PE hydrolysis was faster than PC hydrolysis in unsealed membranes. Interestingly only the basic enzyme showed activity in the absence of Ca²⁺ and in the presence of 0.5 mm EDTA. Phospholipase C (Bacillus cereus or Clostridium perfringens) did not show the property of substrate specificity reversal although their ability to hydrolyze PC and PE was different. In general this study demonstrates the unique activity patterns of three physically different pure phospholipases A₂ on human erythrocyte membranes which could be of value in selectively modifying membrane phospholipids. In addition it also throws an important light on the fact that results obtained with phospholipases should be interpreted with caution particularly as regards the localization of phospholipids in membranes.     

Transverse asymmetry of phospholipids in subcellular membranes of rat liver

Subcellular membranes isolated from rat liver in a form impermeable to macromolecules were treated with phospholipase A₂ from Naga naja venom. The phosphatidylserine, phosphatidylethanolamine and about half of the phosphatidylcholine of microsomes, Golgi membranes, inner mitochondrial membranes, lysosomes and nuclear membranes were hydrolyzed. It is proposed that these phospholipids are localized in the outer surface of the membrane bilayer, which represents the cytoplasmic side in the living cell, while the remaining phosphatidylcholine and most of the phosphatidylinositol, sphingomyelin and cardiolipin may be assigned to the inner side of the bilayer.