Effect of neuraminidase treatment on the topological distribution of phospholipids in chick brain microsomes

The desialylation of chick brain microsomal membranes affects the transbilayer distribution of phospholipids. When intact microsomes were treated with neuraminidase, less phosphatidylcholine and sphingomyelin could be hydrolysed with phospholipase C under experimental conditions which allowed the hydrolysis of the phospholipids of the external leaflet only. In contrast, the accessibility of phosphatidylethanolamine and phosphatidylserine to the external probes (trinitrobenzene sulfonic acid or phospholipase C) was not affected. After neuraminidase treatment of a microsomal fraction, less phosphatidylcholine, newly synthesized through the cytidine pathway, could be hydrolysed by phospholipase C, whereas the reaction of newly synthesized phosphatidylethanolamine molecules with trinitrobenzene sulfonic acid was not affected. The results suggest that in biological membranes some choline phospholipid molecules may interact with the sialyl residue of sialocompounds. This interaction may contribute to the maintenance of phospholipid asymmetry in brain membranes.     

Asymmetry of lipid organization in cholinergic synaptic vesicle membranes.

The lipid composition of purified Torpedo cholinergic synaptic vesicles was determined and their distribution between the inner and outer leaflets of the vesicular membrane was investigated. The vesicles contain cholesterol and phospholipids at a molar ratio of 0.63. The vesicular phospholipids are (mol% of total phospholipids): phosphatidylcholine (40.9); phosphatidylethanolamine (24.6); plasmenylethanolamine (11.5); sphingomyelin (12); phosphatidylserine (7.3); phosphatidylinositol (3.7). The asymmetry of the synaptic vesicle membranes was investigated by two independent approaches: (a) determining accessibility of the amino lipids to the chemical label trinitrobenzenesulphonic acid (TNBS); (b) determining accessibility of the vesicular glycerophospholipids to phospholipase C (Bacillus cereus). TNBS was found to render the vesicles leaky and thus cannot be used reliably to determine the asymmetry of Torpedo synaptic vesicle membranes. Incubation of the vesicles with phospholipase C (Bacillus cereus) results in biphasic hydrolysis of the vesicular glycerophospholipids. About 45% of the phospholipids are hydrolysed in less than 1 min, during which no vesicular acetylcholine is released. In the second phase, the hydrolysis of the phospholipids slows down markedly and is accompanied by loss of all the vesicular acetylcholine. These findings suggest that the lipids hydrolysed during the first phase are those comprising the outer leaflet. Analysis of the results thus obtained indicate that the vesicular membrane is asymmetric: all the phosphatidylinositol, 77% of the phosphatidylethanolamine, 47% of the plasmenylethanolamine and 58% of the phosphatidylcholine were found to reside in the outer leaflet. Since phosphatidylserine is a poor substrate for phospholipase C (B. cereus), its distribution between the two leaflets of the synaptic vesicle membrane is only suggestive.     

A study on the topological distribution of phospholipids in microsomal membranes of chick brain using phospholipase C and trinitrobenzenesulfonic acid

The transbilayer distribution of phospholipids in chicken brain microsomal membranes has been investigated using trinitrobenzenesulfonic acid and phospholipase C from Clostridium weichii. The exposure of intact microsomes to trinitrobenzenesulfonic acid showed that the labelling of aminophospholipids followed biphasic kinetics, indicating that these membranes contain a fast- and a slow-reacting pool of aminophospholipids. Use of microsomes radioiodinated on their surface led to the conclusion that the fast-reacting pool may be located on the outer leaflet of the microsomal vesicles. It contains about 35% of the phosphatidylethanolamine, 29% of the ethanolamine plasmalogens and 18% of the phosphatidylserine. The treatment of intact microsomes with the phospholipase C Cl. welchii produced the hydrolysis of 50% of the phospholipids without any loss of their permeability properties, indicating that they are not permeable to the hydrolase. Phospholipids extracted from the microsomes were hydrolyzed rapidly by the phospholipase C with the exception of phosphatidylserine and phosphatidylinositol. In intact microsomes about 90% of phosphatidylcholine, 32% of ethanolamine phospholipids and 60% of sphingomyelin were accessible to the phospholipase. These results suggest that the phospholipids have an asymmetric distribution in chicken brain microsomes, the external leaflet containing about 75% of the choline phospholipids and 25% of the aminophospholipids, whereas an opposite distribution is observed in the inner leaflet.     

Membrane phospholipid asymmetry in Semliki Forest virus grown in BHK cells

The distribution of phospholipids across the membrane bilayer of Semliki Forest virus grown in BHK cells has been examined by treating the virus with bee venom phospholipase A₂ and sphingomyelinase C from Staphylococcus aureus. From the amounts of different phospholipids which are degraded rapidly (half-time about 1 min for phospholipase A₂) we calculate that in virus isolated 16 h after infection about 95% of sphingomyelin, 55% of phosphatidylcholine, 20% of phosphatidylethanolamine and less then 5% of phosphatidylserine is present on the outer leaflet of the virus envelope. Less than 5% of the virus was permeable to macromolecules before or after treatment with phospholipases as judged by accessibility of the genome to external ribonuclease. A much slower (half-time about 1 h) breakdown by phospholipase A₂ of originally inaccessible phosphatidylcholine and phosphatidylethanolamine appeared to be due to an enzyme-induced loss of lipid asymmetry since the original asymmetric distribution of phospholipids was maintained for several hours when the virus alone was incubated at 37°C. However, virus incubated for 20 h at 37°C showed a marked loss of phosphatidylethanolamine and phosphatidylserine asymmetry and a greater susceptibility to lysis by longer treatment with phospholipase A₂.     

Phospholipid asymmetry in rough- and smooth-endoplasmic-reticulum membranes of untreated and phenobarbital-treated rat liver.

Phospholipase C was used as a probe for the distribution of phospholipids about the membrane of rough and smooth microsomal fractions from normal and phenobarbital-treated rat liver. All membranes exhibited an asymmetric distribution, with phosphatidylethanolamine and phosphatidylserine concentrated in the inner leaflet of the bilayer and phosphatidylcholine and sphingomyelin concentrated in the outer leaflet. The only phospholipid showing a significant difference in distribution between fractions was phosphatidylcholine, which was shifted towards the outer leaflet in the smooth microsomal fraction compared with the rough microsomal fraction, and towards the outer leaflet in both rough and smooth microsomal fractions from phenobarbital-treated liver compared with the same preparations from untreated rat liver. Apart from this small change, the asymmetric distribution of phospholipids was conserved in microsomal fractions which had proliferated in response to phenobarbital and in which the protein composition had changed.     

Asymmetry of the site of choline incorporation into phosphatidylcholine of rat liver microsomes.

[14C]Choline was incorporated into microsomal membranes in vivo, and from CDP-[14C]choline in vitro, and the site of incorporation determined by hydrolysis of the outer leaflet of the membrane bilayer using phospholipase C from Clostridium welchii. Labelled phosphatidylcholine was found to be concentrated in the outer leaflet of the membrane bilayer with a specific activity approximately three times that of the inner leaflet. During incorporation of CDP-choline and treatment with phospholipase C the vesicles retained labelled-protein contents indicating that they remained intact. When the microsomes were opened with taurocholate after incorporation of [14C]choline in vivo, the labelled phosphatidylcholine behaved as a single pool. Selective hydrolysis of labelled phosphatidylcholine in intact vesicles is not, therefore, a consequence of specificity of phospholipase C. These results indicate that the phosphatidylcholine of the outer leaflet of the microsomal membrane bilayer is preferentially labelled by the choline-phosphotransferase pathway and that this pool of phospholipid does not equilibrate with that of the inner leaflet.     

The transverse distribution of phospholipids in the membranes of Golgi subfractions of rat hepatocytes.

The transverse distribution of phospholipids in the membranes of subfractions of the Golgi complex was investigated by using phospholipase C and 2,4,6-trinitrobenzenesulphonic acid as probes. In trans-enriched Golgi membranes, 26% of the phosphatidylethanolamine is available for reaction with trinitrobenzenesulphonate or for hydrolysis by phospholipase C, and 72% of the phosphatidylcholine is hydrolysed by phospholipase C. In cis-enriched Golgi membranes, 45% of the phosphatidylethanolamine is available for reaction with trinitrobenzenesulphonate and for hydrolysis by phospholipase C, and 95% of the phosphatidylcholine is hydrolysed by phospholipase C. Under the conditions used with either probe the contents of the Golgi vesicles labelled with either [3H]palmitic acid or [14C]leucine were retained. Galactosyltransferase activity of the membrane vesicles was partially inhibited by the experimental procedures used to investigate the transverse distribution of phospholipids. However, the residual activity was latent, suggesting that the vesicles remained closed. Trinitrobenzenesulphonic acid caused no detectable morphological change in either Golgi fraction. Phospholipase C treatment caused morphological changes, including fusion of vesicles and the appearance of 'signet-ring' profiles in some vesicles; however, the vesicles remained closed and the bilayer was retained. It appears, therefore, that neither probe causes major disruption of the Golgi vesicles nor gains access to the inner surface of the membrane bilayer. These observations suggest that phospholipids have a transverse asymmetry in Golgi membranes, that this distribution differs in trans and cis membranes, and that the phospholipid structure of Golgi membranes is inconsistent with a simple flow of membrane bilayer from endoplasmic reticulum to Golgi membranes to plasma membrane.     

Evidence for a highly asymmetric arrangement of ether- and diacyl-phospholipid subclasses in the plasma membrane of Krebs II ascites cells

(1) Krebs II ascites cells were taken as a model of the neoplastic cells to investigate the transverse distribution of phospholipids in the plasma membrane. The experimental procedure was based on non-lytic degradation of phospholipids in the intact cell by Naja naja phospholipase A₂ and Staphylococcus aureus sphingomyelinase C and on phopholipid analysis of purified plasma membranes. It was shown that the three major phospholipids, i.e., phosphatidylcholine, phosphatidylethanolamine and sphingomyelin, are randomly distributed between the two halves of the membranes, whereas phosphatidylserine remains located in the inner leaflet. (2) The membrane localization of phosphatidylcholine and phosphatidylethanolamine subclasses (diacyl, alkylacyl and alkenylacyl) was also examined, using a new procedure of ether-phospholipid determination. The method involves a selective removal of diacyl species by guinea pig pancreas phospholipase A₁ and of alkenylacyl species by acidolysis. This analysis revealed a 50% increase of ether phospholipids in the plasma membrane as compared to the whole cell (36.5 and 23.1% of total phospholipid, respectively). Furthermore, a strong membrane asymmetry was demonstrated for the three phosphatidylcholine subclasses, since 1-alkyl-2-acyl-sn-glycerol-3-phosphocholine (alkylacyl-GPC) was entirely found in the inner leaflet, whereas both diacyl- and alkenylacyl-GPC displayed an external localization. The same pattern was observed for phosphatidylethanolamine subclasses, except for 1-alkenyl-2-acyl-sn-glycero-3-phosphoethanolamine, which was found randomly distributed. These results are discussed in relation to the process of cell malignant transformation and to the biosynthesis of platelet-activating factor (PAF-acether or 1-alkyl-2-acetyl-GPC).     

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.     

Enzyme and phospholipid asymmetry in liver microsomal membranes

The transverse distribution of enzyme proteins and phospholipids within microsomal membranes was studied by analyzing membrane composition after treatment with proteases and phospholipases. Upon trypsin treatment of closed microsomal vesicles, NADH- and NADPH-cytochrome c reductases as well as cytochrome b5 were solubilized or inactivated, while cytochrome P-450 was partially inactivated. When microsomes were exposed to a concentration of deoxycholate which makes them permeable to macromolecules but does not disrupt the membrane, the detergent alone was sufficient to release four enzymes: nucleoside diphosphatase, esterase, beta-glucuronidase, and a portion of the DT-diaphorase. Introduction of trypsin into the vesicle lumen inactivated glucose-6-phosphatase completely and cytochrome P-450 partially. The rest of this cytochrome, ATPase, AMPase, UDP-glucuronyltransferase, and the remaining 50% of DT-diaphorase activity were not affected by proteolysis from either side of the membrane. Phospholipase A treatment of intact microsomes in the presence of albumin hydrolyzed all of the phosphatidylethanolamine, phosphatidylserine, and 55% of the phosphatidylcholine. From this observation, it was concluded that these lipids are localized in the outer half of the bilayer of the microsomal membrane; Phosphatidylinositol, 45% of the phosphatidylcholine, and sphingomyelin are tentatively assigned to the inner half of this bilayer. It appears that the various enzyme proteins and phospholipids of the microsomal membrane display an asymmetric distribution in the transverse plane.     

Evidence for a highly asymmetric arrangement of ether- and diacyl-phospholipid subclasses in the plasma membrane of Krebs II ascites cells

(1) Krebs II ascites cells were taken as a model of the neoplastic cells to investigate the transverse distribution of phospholipids in the plasma membrane. The experimental procedure was based on non-lytic degradation of phospholipids in the intact cell by Naja naja phospholipase A2 and Staphylococcus aureus sphingomyelinase C and on phospholipid analysis of purified plasma membranes. It was shown that the three major phospholipids, i.e., phosphatidylcholine, phosphatidylethanolamine and sphingomyelin, are randomly distributed between the two halves of the membranes, whereas phosphatidylserine remains located in the inner leaflet. (2) The membrane localization of phosphatidylcholine and phosphatidylethanolamine subclasses (diacyl, alkylacyl and alkenylacyl) was also examined, using a new procedure of ether-phospholipid determination. The method involves a selective removal of diacyl species by guinea pig pancreas phospholipase A1 and of alkenylacyl species by acidolysis. This analysis revealed a 50% increase of ether phospholipids in the plasma membrane as compared to the whole cell (36.5 and 23.1% of total phospholipid, respectively). Furthermore, a strong membrane asymmetry was demonstrated for the three phosphatidylcholine subclasses, since 1-alkyl-2-acyl-sn-glycerol-3-phosphocholine (alkylacyl-GPC) was entirely found in the inner leaflet, whereas both diacyl- and alkenylacyl-GPC displayed an external localization. The same pattern was observed for phosphatidylethanolamine subclasses, except for 1-alkenyl-2-acyl-sn-glycero-3-phosphoethanolamine, which was found randomly distributed. These results are discussed in relation to the process of cell malignant transformation and to the biosynthesis of platelet-activating factor (PAF-acether or 1-alkyl-2-acetyl-GPC).     

The role of choline phospholipids in hypertonic cryohemolysis

Hemolysis resulting from a warm-to-cold temperature shift in a Hypertonie environment (hypertonic cryohemolysis) is studied with the use of phospholipases as membrane probes of the phospholipids of the outer leaflet of the bilayer. Bee venom phospholipase A₂ which attacks only phosphatidylcholine (PC) in the intact erythrocyte results in inhibition of cryohemolysis produced by both hypertonic sodium chloride and sucrose. In both cases, about 25% of the loss of PC occurs before any such inhibition, suggesting the possibility of functionally separate domains of PC in the outer leaflet of the bilayer. Sphingomyelinase also attacks only sphingomyelin in the intact erythrocyte and results in inhibition of cryohemolysis due to hypertonic sodium chloride but not of that due to sucrose. In each case, inhibition of the enzymatic hydrolysis by EDTA abolished the effect on cryohemolysis. It is postulated that cryohemolysis is inhibited when phosphylipid interaction with membrane (cytoskeletal) proteins are abolished, but present knowledge of membrane structure does not permit a detailed mechanism to be proposed.     

Asymmetric synthesis followed by transmembrane movement of phosphatidylethanolamine in rat liver endoplasmic reticulum

Studies with phospholipase C have indicated that two-thirds of the phosphatidylethanolamine of rat liver endoplasmic reticulum is located in the inner leaflet of the membrane bilayer. Phosphatidyl[¹⁴C]ethanolamine is synthesised in microsomes incubated with CDP[¹⁴C]ethanolamine. Using phospholipase C as a probe we have observed that the labelled phospholipid is initially (1–2 min) concentrated in the ‘outer leaflet’ of the membrane bilayer. The specific activity of this pool of phosphatidylethanolamine was 3.5 times that of the inner leaflet. If, however, the microsomes were opened with 0.4% taurocholate or the French pressure cell to make both sides of the bilayer available to phospholipase C, the phosphatidylethanolamine behaves as a single pool for hydrolysis. On longer incubation, up to 30 min, with CDP[¹⁴C]ethanolamine the specific activity of the outer leaflet phosphatidylethanolamine becomes close to that of the inner leaflet. In chase experiments, in which microsomal phosphatidylethanolamine was labelled by incubation with CDP[¹⁴C]ethanolamine for 1 min, the reaction stopped by addition of calcium, and the microsomes isolated by centrifugation and reincubated, labelled phosphatidylethanolamine was transferred from the ‘outer leaflet’ to the ‘inner leaflet’, so that both were equally labelled. These observations suggest that phosphatidylethanolamine is synthesised at the cytoplasmic leaflet of the endoplasmic reticulum and subsequently transferred across the membrane to the cisternal leaflet of the bilayer. Transmembrane movement is apparently temperature-dependent and independent of continued synthesis of phosphatidylethanolamine.     

Leakage-free membrane fusion induced by the hydrolytic activity of PlcHR(2), a novel phospholipase C/sphingomyelinase from Pseudomonas aeruginosa

PlcHR(2) is the paradigm member of a novel phospholipase C/phosphatase superfamily, with members in a variety of bacterial species. This paper describes the phospholipase C and sphingomyelinase activities of PlcHR(2) when the substrate is in the form of large unilamellar vesicles, and the subsequent effects of lipid hydrolysis on vesicle and bilayer stability, including vesicle fusion. PlcHR(2) cleaves phosphatidylcholine and sphingomyelin at equal rates, but is inactive on phospholipids that lack choline head groups. Calcium in the millimolar range does not modify in any significant way the hydrolytic activity of PlcHR(2) on choline-containing phospholipids. The catalytic activity of the enzyme induces vesicle fusion, as demonstrated by the concomitant observation of intervesicular total lipid mixing, inner monolayer-lipid mixing, and aqueous contents mixing. No release of vesicular contents is detected under these conditions. The presence of phosphatidylserine in the vesicle composition does not modify significantly PlcHR(2)-induced liposome aggregation, as long as Ca(2+) is present, but completely abolishes fusion, even in the presence of the cation. Each of the various enzyme-induced phenomena have their characteristic latency periods, that increase in the order lipid hydrolysis相似文献   

Studies on the mechanism of membrane fusion. Role of head-group composition in calcium- and magnesium-induced fusion of mixed phospholipid vesicles

We have investigated the contribution of various phospholipids to membrane fusion induced by divalent cations. Fusion was followed by means of a new fluorescence assay monitoring the mixing of internal aqueous contents of large (0.1 μm diameter) unilamellar liposomes. The rate and extent of fusion induced by Ca²⁺ in mixed phosphatidylserine/phosphatidylcholine vesicles were lower compared to those in pure phosphatidylserine vesicles. The presence of 50% phosphatidylcholine completely inhibited fusion, although the vesicles aggregated upon Ca²⁺ addition. When phosphatidylserine was mixed with phosphatidylethanolamine, however, rapid fusion could be induced by Ca²⁺ even in mixtures that contained only 25% phosphatidylserine. Phosphatidylethanolamine also facilitated fusion by Mg²⁺ which could not fuse pure phosphatidylserine vesicles. In phosphatidylserine/phosphatidylethanolamine/phosphatidylcholine mixtures, in which the phosphatidylcholine content was kept at 25%, phosphatidylethanolamine could not substitute for phosphatidylserine, and the fusogenic capacity of Mg²⁺ was abolished by the presence of merely 10% phosphatidylcholine. The initial rate of release of vesicle contents was slower than the rate of fusion in all the mixtures used. The presence of phosphate effected a considerable decrease in the threshold concentration of Ca²⁺ and also enhanced     

Phospholipid organization in H,K-ATPase-containing membranes from pig gastric mucosa

The transverse distribution of the phospholipids in vesicular H+-translocating membranes prepared from pig gastric mucosa was investigated with the aid of phospholipase C, sphingomyelinase, and trinitrobenzenesulfonic acid. The major part (80-90%) of the phosphatidylcholine and the phosphatidylethanolamine, 60% of the phosphatidylserine, and 45% of the sphingomyelin was located on the external, cytoplasmic side of the vesicle membranes. After treatment with phospholipase C the vesicles still behaved as osmometers and appeared as closed vesicles on the electron micrographs. 31P NMR indicated that the phospholipids in untreated vesicles as well as the unhydrolyzed phospholipids in phospholipase C-treated vesicles were arranged in lamellar structures. The 31P NMR spectrum of untreated vesicles to which Pr3+ ions had been added supported the conclusion that the major part of the membrane phospholipids was located on the external surface of the vesicles. A small fraction of the lipids, 3.6 mol %, was found to consist of glycosphingolipids which occurred at a concentration of 52 nmol/mg of protein.     

Regulatory aspects of mitochondrial phospholipase A2: correlation of hydrolysis rates with substrate configuration as evidenced by 31P-NMR

The influence of variation of the phospholipid composition in model membranes composed of phosphatidylcholine and phosphatidylethanolamine on the hydrolysis of these phospholipids by rat liver mitochondrial phospholipase A2 was investigated. With the pure phospholipids, phosphatidylethanolamine was hydrolyzed over 30-times faster than phosphatidylcholine. Upon increasing the mole percentage of phosphatidylethanolamine in mixtures, a gradual, though non-linear, increase in the initial rate of hydrolysis of this phospholipid was observed. By contrast, phosphatidylcholine hydrolysis remained constant up to about 50 mol% phosphatidylethanolamine, whereafter a sudden fall-off of activity was observed. This drop in the hydrolysis rate coincided with a transition of the phospholipid structure from bilayer to an as yet unidentified organization characterized by an isotropic signal in the 31P-NMR spectra recorded in the presence of Ca2+. The occurrence of this phase was clearly dependent on Ca2+, since mixtures with identical composition in the absence of Ca2+ remained largely in bilayer configuration. That the structure adopted by phospholipids is of importance for their susceptibility to attack by this intracellular phospholipase A2 became evident also in studies with the single phospholipids in the absence or presence of Triton X-100 above the critical micellar concentration. While phosphatidylcholine hydrolysis was inhibited in mixed micelles as compared to its bilayer organization, the hydrolysis of phosphatidylethanolamine in mixed micelles was 3-fold that in the hexagonal HII phase.     

Productive hemifusion intermediates in fast vesicle fusion driven by neuronal SNAREs

An in vitro fusion assay uses fluorescence microscopy of labeled lipids to monitor single v-SNARE vesicle docking and fusion events on a planar lipid bilayer containing t-SNAREs. For vesicles and bilayer comprising phosphatidylcholine (POPC, 84-85% by mol) and phosphatidylserine (DOPS, 15% by mol), previous work demonstrated prompt, full fusion (τ_fus = 25 ms). Substitution of 20-60% phosphatidylethanolamine (DOPE) for phosphatidylcholine in the v-SNARE vesicle with either 0 or 20% DOPE included in the t-SNARE bilayer gives rise to hemifusion events. Labeled lipids diffuse into the planar bilayer as two temporally distinct waves, presumably hemifusion of the outer leaflet followed by inner leaflet (core) fusion. The fusion kinetics with DOPE is markedly heterogeneous. Some vesicle/docking site pairs exhibit prompt, full fusion while others exhibit hemifusion. Hemifusion events are roughly half productive (leading to subsequent core fusion within 20 s) and half dead-end. In qualitative accord with expectations from studies of protein-free vesicle-vesicle fusion, the hemifusion rate k_hemi is 15-20 times faster than the core fusion rate k_core, and the fraction of hemifusion events increases with increasing percentage of DOPE. This suggests similar underlying molecular pathways for protein-free and neuronal SNARE-driven fusion. Removal of phosphatidylserine from the v-SNARE vesicle has no effect on docking or fusion.     

Leakage-free membrane fusion induced by the hydrolytic activity of PlcHR2, a novel phospholipase C/sphingomyelinase from Pseudomonas aeruginosa

PlcHR₂ is the paradigm member of a novel phospholipase C/phosphatase superfamily, with members in a variety of bacterial species. This paper describes the phospholipase C and sphingomyelinase activities of PlcHR₂ when the substrate is in the form of large unilamellar vesicles, and the subsequent effects of lipid hydrolysis on vesicle and bilayer stability, including vesicle fusion. PlcHR₂ cleaves phosphatidylcholine and sphingomyelin at equal rates, but is inactive on phospholipids that lack choline head groups. Calcium in the millimolar range does not modify in any significant way the hydrolytic activity of PlcHR₂ on choline-containing phospholipids. The catalytic activity of the enzyme induces vesicle fusion, as demonstrated by the concomitant observation of intervesicular total lipid mixing, inner monolayer-lipid mixing, and aqueous contents mixing. No release of vesicular contents is detected under these conditions. The presence of phosphatidylserine in the vesicle composition does not modify significantly PlcHR₂-induced liposome aggregation, as long as Ca²⁺ is present, but completely abolishes fusion, even in the presence of the cation. Each of the various enzyme-induced phenomena have their characteristic latency periods, that increase in the order lipid hydrolysis < vesicle aggregation < total lipid mixing < inner lipid mixing < contents mixing. Concomitant measurements of the threshold diacylglyceride + ceramide concentrations in the bilayer show that late events, e.g. lipid mixing, require a higher concentration of PlcHR₂ products than early ones, e.g. aggregation. When the above results are examined in the context of the membrane effects of other phospholipid phosphocholine hydrolases it can be concluded that aggregation is necessary, but not sufficient for membrane fusion to occur, that diacylglycerol is far more fusogenic than ceramide, and that vesicle membrane permeabilization occurs independently from vesicle fusion.