Trp2063 and Trp2064 in the factor Va C2 domain are required for high-affinity binding to phospholipid membranes but not for assembly of the prothrombinase complex

Interactions between factor Va and membrane phosphatidylserine (PS) regulate activity of the prothrombinase complex. Two solvent-exposed hydrophobic residues located in the C2 domain, Trp(2063) and Trp(2064), have been proposed to contribute to factor Va membrane interactions by insertion into the hydrophobic membrane bilayer. However, the prothrombinase activity of rHFVa W(2063, 2064)A was found to be significantly impaired only at low concentrations of PS (5 mol %). In this study, we find that 10-fold higher concentrations of mutant factor Va are required for half-maximal prothrombinase activity on membranes containing 25% PS. The ability of the mutant factor Va to interact with factor Xa on a membrane was also impaired since 4-fold higher concentrations of factor Xa were required for half-maximal prothrombinase activity. The interaction of factor Va with 25% PS membranes was also characterized using fluorescence energy transfer and surface plasmon resonance. We found that the affinity of mutant factor Va for membranes containing 25% PS was reduced at least 400-fold with a K(d) > 10(-7) M. The binding of mutant factor Va to 25% PS membranes was markedly enhanced in the presence of factor Xa, indicating stabilization of the factor Va-factor Xa-membrane complex. Our findings indicate that Trp(2063) and Trp(2064) play a critical role in the high-affinity binding of factor Va to PS membranes. It remains to be determined whether occupancy of this PS binding site in factor Va is also required for high-affinity binding to factor Xa.     

The physical significance of Km in the prothrombinase reaction

Key kinetic parameters for the prothrombinase complex formed on membranes of phosphatidylserine (PS)/phosphatidylcholine (PC) (40/60) (Km = 0.12 microM, kcat = 11 s-1) or PS/PC (2/98) (Km = 0.40 microM, kcat = 11 s-1) differed only slightly. In contrast, the density of proteins on the membrane surface at the km differed greatly for the two membranes. The kinetics appeared unaffected by conditions where the number of phospholipid vesicles (2% PS) exceeded the number of protein molecules. These results establish that the Km for the prothrombinase reaction is determined by the concentration of prothrombin in solution rather than its density at the membrane surface. This system can be treated as a dissociable enzyme acting on a soluble substrate.     

Effect of membrane fluidity and fatty acid composition on the prothrombin-converting activity of phospholipid vesicles.

Vesicles composed of phospholipids with different fatty acyl side chains have been utilized to examine the importance of the nonpolar membrane region for the prothrombin-converting activity of procoagulant phospholipid vesicles. Membranes composed of phosphatidylserine (PS) and phosphatidylcholine (PC) with unsaturated fatty acyl side chains were more active in prothrombin activation than membranes composed of phospholipids with saturated fatty acyl chains. This phenomenon was observed above the phase transition temperature, i.e., on membranes in the liquid-crystalline state. The prothrombin-converting activity of saturated phospholipids approached the activity of unsaturated phospholipids at high factor Va concentrations, which is indicative for a less favorable equilibrium constant for prothrombinase assembly on membrane surfaces composed of saturated phospholipids. The difference between saturated and unsaturated phospholipids was annulled on membranes with high mole percentages of PS. This may result from a compensating contribution of electrostatic forces to the binding equilibria involved in prothrombinase assembly. Additional effects on the prothrombin-converting activity were observed when membranes containing saturated phospholipids were studied below their phase transition temperature. In agreement with Higgins et al. [(1985) J. Biol. Chem. 260, 3604-3612], we found that the time required for the assembly of prothrombinase from membrane-bound factors Xa and Va is considerably prolonged on solid membranes. However, we also observed an effect of membrane fluidity on the steady-state rate of prothrombin activation. Kinetic experiments at saturating factor Va concentrations showed that the transition from the liquid-crystalline to the gel state caused a more than 9-fold decrease of the kcat of prothrombin activation without affecting the Km for prothrombin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Investigation of the interaction of pig muscle lactate dehydrogenase with acidic phospholipids at low pH

Interaction of pig muscle lactate dehydrogenase (LDH) with acidic phospholipids is strongly dependent on pH and is most efficient at pH values <6.5. The interaction is ionic strength sensitive and is not observed when bilayer structures are disrupted by detergents. Bilayers made of phosphatidylcholine (PC) do not bind the enzyme. The LDH interaction with mixed composition bilayers phosphatidylserine/phosphatidylcholine (PS/PC) and cardiolipin/phosphatidylcholine (CL/PC) leads to dramatic changes in the specific activity of the enzyme above a threshold of acidic phospholipid concentration likely when a necessary surface charge density is achieved. The threshold is dependent on the kind of phospholipid. Cardiolipin (CL) is much more effective compared to phosphatidylserine, which is explained as an effect of availability of both phosphate groups in a CL molecule for interaction with the enzyme. A requirement of more than one binding point on the enzyme molecule for the modification of the specific activity is postulated and discussed. Changes in CD spectra induced by the presence of CL and PS vesicles evidence modification of the conformational state of the protein molecules. In vivo qualitative as well as quantitative phospholipid composition of membrane binding sites for LDH molecules would be crucial for the yield of the binding and its consequences for the enzyme activity in the conditions of lowered pH.     

Investigation of the interaction of pig muscle lactate dehydrogenase with acidic phospholipids at low pH

Interaction of pig muscle lactate dehydrogenase (LDH) with acidic phospholipids is strongly dependent on pH and is most efficient at pH values<6.5. The interaction is ionic strength sensitive and is not observed when bilayer structures are disrupted by detergents. Bilayers made of phosphatidylcholine (PC) do not bind the enzyme. The LDH interaction with mixed composition bilayers phosphatidylserine/phosphatidylcholine (PS/PC) and cardiolipin/phosphatidylcholine (CL/PC) leads to dramatic changes in the specific activity of the enzyme above a threshold of acidic phospholipid concentration likely when a necessary surface charge density is achieved. The threshold is dependent on the kind of phospholipid. Cardiolipin (CL) is much more effective compared to phosphatidylserine, which is explained as an effect of availability of both phosphate groups in a CL molecule for interaction with the enzyme. A requirement of more than one binding point on the enzyme molecule for the modification of the specific activity is postulated and discussed. Changes in CD spectra induced by the presence of CL and PS vesicles evidence modification of the conformational state of the protein molecules. In vivo qualitative as well as quantitative phospholipid composition of membrane binding sites for LDH molecules would be crucial for the yield of the binding and its consequences for the enzyme activity in the conditions of lowered pH.     

Modulation of prothrombinase assembly and activity by phosphatidylethanolamine

Constituents of platelet membranes regulate the activity of the prothrombinase complex. We demonstrate that membranes containing phosphatidylcholine and phosphatidylethanolamine (PE) bind factor Va with high affinity (K(d) = ～10 nm) in the absence of phosphatidylserine (PS). These membranes support formation of a 60-70% functional prothrombinase complex at saturating factor Va concentrations. Although reduced interfacial packing does contribute to factor Va binding in the absence of PS, it does not correlate with the enhanced activity of the Xa-Va complex assembled on PE-containing membranes. Instead, specific protein-PE interactions appear to contribute to the effects of PE. In support of this, soluble C6PE binds to recombinant factor Va(2) (K(d) = ～6.5 μm) and to factor Xa (K(d) = ～91 μm). C6PE and C6PS binding sites of factor Xa are specific, distinct, and linked, because binding of one lipid enhances the binding and activity effects of the other. C6PE triggers assembly (K(d)(app) = ～40 nm) of a partially active prothrombinase complex between factor Xa and factor Va(2), compared with K(d)(app) for C6PS ～2 nm. These findings provide new insights into the possible synergistic roles of platelet PE and PS in regulating thrombin formation, particularly when exposed membrane PS may be limiting.     

Fusion in phospholipid spherical membranes. II. Effect of cholesterol, divalent ions and pH.

Effect of cholesterol, divalent ions and pH on spherical bilayer membrane fusion was studied as a function of increasing temperature. Spherical bilayer membranes were composed of natural [phosphatidylcholine (PC) and phosphatidylserine (PS)] as well as synthetic (dipalmitoyl-PC, dimyristoyl-PC and dioleoyl-PC) phospholipids. Incorporation of cholesterol into the membrane (33% by weight) suppressed the fusion temperature and also greatly reduced the percentage of membrane fusion. The presence of 1 mM divalent ions (Ca++, Mg++ or Mn++) on both sides or one side of the PC membrane did not affect appreciably its fusion characteristic with temperature, but the PS membrane fusion with temperature was greatly enhanced by the presence of divalent ions. The variation of pH of the environmental solution in the range of 5.5 approximately 7.0 did not affect the membrane fusion characteristic. However, at pH 8.5, the fusion with respect to temperature was shifted toward the lower temperature by approximately 3degreesC for PC and PS membranes, and at pH 3.0 the opposite situation was observed as the fusion temperature was increased by 6degreesC for PS membranes and by 4degreesC for PC membranes The results seem to indicate that membrane fluidity and structural instability in the bilayer are important for membrane fusion to occur.     

Exposure of platelet membrane phosphatidylserine regulates blood coagulation

This article addresses the role of platelet membrane phosphatidylserine (PS) in regulating the production of thrombin, the central regulatory molecule of blood coagulation. PS is normally located on the cytoplasmic face of the resting platelet membrane but appears on the plasma-oriented surface of discrete membrane vesicles that derive from activated platelets. Thrombin, the central molecule of coagulation, is produced from prothrombin by a complex ("prothrombinase") between factor Xa and its protein cofactor (factor V(a)) that forms on platelet-derived membranes. This complex enhances the rate of activation of prothrombin to thrombin by roughly 150,000 fold relative to factor X(a) in solution. It is widely accepted that the negatively charged surface of PS-containing platelet-derived membranes is at least partly responsible for this rate enhancement, although there is not universal agreement on mechanism by which this occurs. Our efforts have led to an alternative view, namely that PS molecules bind to discrete regulatory sites on both factors X(a) and V(a) and allosterically alter their proteolytic and cofactor activities. In this view, exposure of PS on the surface of activated platelet vesicles is a key regulatory event in blood coagulation, and PS serves as a second messenger in this regulatory process. This article reviews our knowledge of the prothrombinase reaction and summarizes recent evidence leading to this alternative viewpoint. This viewpoint suggests a key role for PS both in normal hemostasis and in thrombotic disease.     

Prothrombin activation on membranes with anionic lipids containing phosphate, sulfate, and/or carboxyl groups

Factor Xa catalyzed prothrombin activation is strongly stimulated by the presence of negatively charged membranes plus calcium ions. Here we report experiments in which we determined the prothrombin-converting activity of phosphatidylcholine (PC) membranes that contain varying amounts of different anionic lipids, viz., phosphatidylserine (PS), phosphatidic acid (PA), phosphatidylmethanol (MePA), phosphatidylglycerol (PG), phosphatidylethanolamine (PE), phosphatidyl-beta-lactate (PLac), sulfatides (SF), sodium dodecyl sulfate (SDS), and oleic acid. All anionic lipids tested were able to accelerate factor Xa catalyzed prothrombin activation, in both the absence and presence of the protein cofactor Va. This shows that the prothrombin-converting activity of negatively charged membranes is not strictly dependent on the presence of a phosphate group but that lipids which contain a carboxyl or sulfate moiety are also able to promote the formation of a functionally active prothrombinase complex. In the absence of factor Va, the prothrombin-converting activity of membranes with MePA, PG, PE, PLac, SF, or SDS was strongly inhibited at high ionic strength, while the activity of PS- and PA-containing membranes was hardly affected by ionic strength variation. This suggests that in the case of the ionic strength sensitive lipids electrostatic forces play an important role in the formation of the membrane-bound prothrombinase complex. For PS and to a lesser extent for PA we propose that the formation of a coordinated complex (chelate complex) with Ca2+ as central ion and ligands provided by the gamma-carboxyglutamic acid residues of prothrombin and factor Xa and the polar head group of phospholipids is the major driving force in protein-membrane association. Our data indicate that the anionic lipids used in this study can be useful tools for further investigation of the molecular interactions that play a role in the assembly of a membrane-bound prothrombinase complex. Membranes that were solely composed of PC can also considerably enhance prothrombin activation in the presence of factor Va. This activity of PC is only observed on membranes which are composed of PC that contains unsaturated hydrocarbon side chains. Membranes prepared from phosphocholine-containing lipids with saturated hydrocarbon side chains such as dimyristoyl-PC, dipalmitoyl-PC, distearoyl-PC, and dioctadecylglycerophosphocholine hardly accelerated prothrombin activation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Presence of anionic phospholipids rules the membrane localization of phenothiazine type multidrug resistance modulator

Substances able to modulate multidrug resistance (MDR), including antipsychotic phenothiazine derivatives, are mainly cationic amphiphiles. The molecular mechanism of their action can involve interactions with transporter proteins as well as with membrane lipids. The interactions between anionic phospholipids and MDR modulators can be crucial for their action. In present work we study interactions of 2-trifluoromethyl-10-(4-[methanesulfonylamid]buthyl)-phenothiazine (FPhMS) with neutral (PC) and anionic lipids (PG and PS). Using microcalorimetry, steady-state and time-resolved fluorescence spectroscopy we show that FPhMS interacts with all lipids studied and drug location in membrane depends on lipid type. The electrostatic attraction between drug and lipid headgroups presumably keeps phenothiazine derivative molecules closer to surface of negatively charged membranes with respect to neutral ones. FPhMS effects on bilayer properties are not proportional to phosphatidylserine content in lipid mixtures. Behavior of equimolar PC:PS mixtures is similar to pure PS bilayers, while 2:1 or 1:2 (mole:mole) PC:PS mixtures resemble pure PC ones.     

Cooperative roles of factor V(a) and phosphatidylserine-containing membranes as cofactors in prothrombin activation

Activation of prothrombin, as catalyzed by the prothrombinase complex (factor X(a), enzyme; factor V(a) and phosphatidylserine (PS)-containing membranes, cofactors), involves production and subsequent proteolysis of two possible intermediates, meizothrombin (MzII(a)) and prethrombin 2 plus fragment 1.2 (Pre2 & F1.2). V(max), K(m), or V(max)/K(m) for all four proteolytic steps was determined as a function of membrane-phospholipid concentration. Proteolysis was monitored using a fluorescent thrombin inhibitor, a chromogenic substrate, and SDS-PAGE. The kinetic constants for the conversion of MzII(a) and Pre2 & F1.2 to thrombin were determined directly. Pre2 & F1.2 conversion was linear in substrate concentration up to 4 microm, whereas MzII(a) proteolysis was saturable. First order rate constants for formation of MzII(a) and Pre2 & F1.2 could not be determined directly and were determined from global fitting of the data to a parallel, sequential model, each step of which was treated by the Michaelis-Menten formalism. The rate of direct conversion to thrombin without release of intermediates from the membrane-V(a)-X(a) complex (i.e. "channeling") also was adjusted because both the membranes and factor V(a) have been shown to cause channeling. k(cat), K(m), or k(cat)/K(m) values were reported for one lipid concentration, for which all X(a) was likely incorporated into a X(a)-V(a) complex on a PS membrane. Comparing previous results, which were obtained either with factor V(a) (Boskovic, D. S., Bajzar, L. S., and Nesheim, M. E. (2001) J. Biol. Chem. 276, 28686-28693) or with membranes individually (Wu, J. R., Zhou, C., Majumder, R., Powers, D. D., Weinreb, G., and Lentz, B. R. (2002) Biochemistry 41, 935-949), with results presented here we conclude that both factor V(a) and PS-containing membranes induce similar rate increases and pathway changes. Moreover, we have determined: 1) factor V(a) has the greatest effect in enhancing rates of individual proteolytic events; 2) PS-containing membranes have the greatest role in increasing the preference for the MzII(a) versus Pre2 pathway; and 3) PS membranes cause approximately 50% of the substrate to be activated via channeling at 50 microm membrane concentration, but factor V(a) extends the range of efficient channeling to much lower or higher membrane concentrations.     

Fluoride-dependent calcium-induced platelet procoagulant activity shows that calpain is involved in increased phospholipid transbilayer movement

Treatment of platelets with fluoride (10 mM) was found to result in a transient increase in Ca2+-permeability of the platelet plasma membrane. This phenomenon was used to provide supplementary evidence for the suggestions made earlier (Comfurius et al. (1985) Biochim. Biophys. Acta 815, 143; Verhallen et al. (1987) Biochim. Biophys. Acta 903, 206), that cytoskeletal disrupture by calpain is involved in the process leading to transbilayer movement of phosphatidylserine during expression of platelet procoagulant activity. This was achieved by relating both calpain activity and exposure of phosphatidylserine with platelet procoagulant activity. It was found that only upon addition of extracellular Ca2+ to fluoride-treated platelets, procoagulant activity, expressed as prothrombinase activity, and calpain activity, estimated from protein patterns after gel electrophoresis, were generated. Both Ca2+-inducible prothrombinase activity and calpain activity followed an identical time-course during incubation with fluoride: after a time-lag of about 10 min they sharply increased towards a peak level. Upon further incubation with fluoride, both activities decreased towards a final plateau, still above basal level. The presence of leupeptin during incubation with fluoride was found to inhibit Ca2+-inducible calpain activity and prothrombinase activity in an identical way. Ca2+-inducible exposure of phosphatidylserine, as determined with extracellular phospholipase A2, showed a similar pattern as Ca2+-inducible calpain activity and prothrombinase activity. From the strict parallelism between prothrombinase activity, calpain activity and exposure of phosphatidylserine, it is concluded that calpain plays an important role in the activation-dependent transbilayer movement of phosphatidylserine during expression of platelet procoagulant activity. It is suggested that degradation of the platelet membrane-skeleton by calpain disturbs the structural organization of the lipid bilayer of the platelet plasma membrane leading to enhanced transbilayer movement of phospholipids and appearance of phosphatidylserine at the platelet outer surface.     

The phosphatidylserine binding site of the factor Va C2 domain accounts for membrane binding but does not contribute to the assembly or activity of a human factor Xa-factor Va complex

Factors V(a) and X(a) (FV(a) and FX(a), respectively) assemble on phosphatidylserine (PS)-containing platelet membranes to form the essential "prothrombinase" complex of blood coagulation. The C-terminal domain (C2) of FV(a) (residues 2037-2196 in human FV(a)) contains a soluble phosphatidylserine (C6PS) binding pocket flanked by a pair of tryptophan residues, Trp(2063) and Trp(2064). Mutating these tryptophans abolishes FV(a) membrane binding. To address both the roles of these tryptophans in C6PS or membrane binding and the role of the C2 domain lipid binding site in regulation of FV(a) cofactor activity, we expressed W(2063,2064)A mutants of the recombinant C2 domain (rFV(a2)-C2) and of a B domain-deleted factor V light isoform (rFV(a2)) in Hi-5 and COS cells, respectively. Intrinsic fluorescence showed that wild-type rFV(a2)-C2 binds to C6PS and to 20% PS/PC membranes with apparent K(d) values of 2.8 microM and 9 nM, respectively, while mutant rFV(a2)-C2 does not. Equilibrium dialysis confirmed that mutant rFV(a2)-C2 does not bind to C6PS. Mutant rFV(a2) binds to C6PS (K(d) approximately 37 microM) with an affinity comparable to that of wild-type rFV(a2) (K(d) approximately 20 microM), although it does not bind to PS/PC membranes to which wild-type rFV(a2) binds with native affinity (K(d) approximately 3 nM). Both wild-type and mutant rFV(a2) bind to active site-labeled FX(a) (DEGR-X(a)) in the presence of 400 microM C6PS with native affinity (K(d) approximately 3-4 nM) to produce a solution rFV(a2)-FX(a) complex of native activity. We conclude that (1) the C2 domain PS site provides all but approximately 1 kT of the free energy of FV(a) membrane binding, (2) tryptophans lining the C2 lipid binding pocket are critical to C6PS and membrane binding and insert into the bilayer interface during membrane binding, (3) occupancy of the C2 lipid binding pocket is not necessary for C6PS-induced formation of the FX(a)-FV(a) complex or its activity, but (4) another PS site on FV(a) does have a regulatory role.     

Interaction of blood coagulation factor Va with phospholipid vesicles examined by using lipophilic photoreagents

Two different lipophilic photoreagents, [3H]adamantane diazirine and 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine (TID), have been utilized to examine the interactions of blood coagulation factor Va with calcium, prothrombin, factor Xa, and, in particular, phospholipid vesicles. With each of these structurally dissimilar reagents, the extent of photolabeling of factor Va was greater when the protein was bound to a membrane surface than when it was free in solution. Specifically, the covalent photoreaction with Vl, the smaller subunit of factor Va, was 2-fold higher in the presence of phosphatidylcholine/phosphatidylserine (PC/PS, 3:1) vesicles, to which factor Va binds, than in the presence of 100% PC vesicles, to which the protein does not bind. However, the magnitude of the PC/PS-dependent photolabeling was much less than has been observed previously with integral membrane proteins. It therefore appears that the binding of factor Va to the membrane surface exposes Vl to the lipid core of the bilayer, but that only a small portion of the Vl polypeptide is exposed to, or embedded in, the bilayer core. Addition of either prothrombin or active-site-blocked factor Xa to PC/PS-bound factor Va had little effect on the photolabeling of Vl with TID, but reduced substantially the covalent labeling of Vh, the larger subunit of factor Va. This indicates that prothrombin and factor Xa each cover nonpolar surfaces on Vh when the macromolecules associate on the PC/PS surface. It therefore seems likely that the formation of the prothrombinase complex involves a direct interaction between Vh and factor Xa and between Vh and prothrombin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fusion in phospholipid spherical membranes. I. Effect of temperature and lysolecithin.

A study concerning membrane contact and fusion phenomena was made for phospholipid spherical bilayer systems with respect to temperature. Specific temperatures were obtained for the spherical bilayer membranes of phosphatidyl choline (PC) and phosphatidyl serine (PS) which indicated a greater degree of membrane fusion and were designated Tf (the fusion temperature -- PC: 43 degrees C, PS: 38 degrees C). These temperatures were reduced by about 10 degrees C for the membranes incorporated with 20% lysophosphatidyl choline. The results of the contact and fusion observed in the spherical membranes are compared and discussed with the conductance characteristics of the PC and PS planar bilayer membranes as well as dissolution study on the phospholipid monolayers formed at the air/water interface with respect to temperature. Also, a possible molecular mechanism of membrane fusion is discussed in terms of the fluidity and instability of the membrane.     

Dynamics of lipid chain attached fluorophore 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) in negatively charged membranes determined by NMR spectroscopy

We have determined the average location and dynamic reorientation of the fluorophore 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) attached to a C12 sn-2 chain of a phosphatidylserine (PS) analogue (C12-NBD-PS) in zwitterionic phosphatidylcholine (PC) and negatively charged phosphatidylserine (PS) host membranes. (1)H magic angle spinning nuclear Overhauser enhancement spectroscopy indicates a highly dynamic reorientation of the aromatic molecule in the membrane. The average location of NBD is characterized by a broad distribution function along the membrane director with a maximum indicating the location of the probe in the lipid/water interface of the lipid membrane. This behavior can be explained by a backfolding of the sn-2 chain towards the aqueous phase. Small differences in the distribution profiles of the NBD group along the membrane normal between PC and PS host membranes were found: in a PC host membrane, the NBD distribution has its maximum in the glycerol region; in a PS host membrane, NBD resides mostly in the upper chain region. These differences may be accounted for by packing differences in the PC versus PS host membranes. As seen by (2)H NMR order parameters, PS bilayers show a much higher packing density compared to PC membranes. Consequently, backfolding of the sn-2 chain with the NBD group attached causes a larger decrease of molecular order of the sn-1 chain in PS than in PC membranes. The broad distributions obtained for lipid chain attached NBD molecules reflect the motional freedom and molecular disorder in the liquid-crystalline lipid membrane.     

The superoxide-generating respiratory burst oxidase of human neutrophil plasma membrane. Phosphatidylserine as an effector of the activated enzyme

The superoxide-generating respiratory burst oxidase is an integral membrane enzyme found in the plasma membrane of polymorphonuclear leukocytes (neutrophils). NADPH-dependent superoxide generation is seen in isolated plasma membranes and in their detergent extracts following activation of the intact cells with phorbol myristate acetate. We have herein examined the effects of phospholipids on the activity of the solubilized oxidase. Solubilization of plasma membranes with 0.5% each of Tween 20 plus deoxycholate resulted in an approximately 2-fold enhancement of activity. Inclusion of phospholipids in the extraction medium resulted in further activation. At 1.0 mg/ml the order of effectiveness was phosphatidylserine (PS) greater than cardiolipin greater than phosphatidylethanolamine greater than phosphatidylinositol; phosphatidylcholine and phosphorylated inositol lipids were not effective. The concentrations required for half-maximal activation by PS and phosphatidylethanolamine were 85 and 200 micrograms/ml, respectively. When PS was used at a maximally activating concentration (0.5 mg/ml), the activity was enhanced 3-5-fold. Detergent solubilization alone elevated the Km of the oxidase for NADPH from 68 microM in intact plasma membranes to 123 microM, but inclusion of PS with detergent restored the Km to near or below that seen in intact membranes. PS also increased the Vmax by a factor of 2-3, but had no effect on the pH optimum. A plot of the activity versus enzyme concentration was linear when membranes were used, but activity showed a quadratic dependence on concentration in solubilized membrane, with lower than expected activity at lower enzyme concentration. PS restored linearity of the concentration-activity plot. The activation by PS was not influenced by the addition of Ca2+, EGTA, or dioctanoylglycerol, indicating that activation was not dependent on protein kinase C. These results implicate phosphatidylserine as a direct effector of the NADPH-oxidase.     

Prothrombinase acceleration by oxidatively damaged phospholipids

The optimally efficient production of thrombin by the prothrombinase complex relies on suitable positioning of its component factors and substrate on phosphatidylserine-containing lipid membranes. The presence of oxidatively damaged phospholipids in a membrane disrupts the normal architecture of a lipid bilayer and might therefore be expected to interfere with prothrombinase activity. To investigate this possibility, we prepared phosphatidylserine-containing lipid vesicles containing oxidized arachidonoyl lipids, and we examined their ability to accelerate thrombin production by prothrombinase. Oxidized arachidonoyl chains caused dose-dependent increases in prothrombinase activity up to 6-fold greater than control values. These increases were completely attenuated by the presence of alpha-tocopherol, gamma-tocopherol, or ascorbate. Over the course of a 300-min oxidation, the ability of arachidonoyl lipids to accelerate prothrombinase peaked at 60 min and then declined to base-line levels. These results suggest that instead of being impeded by oxidative membrane damage, prothrombinase activity is enhanced by one or more products of nonenzymatic lipid oxidation.     

The structure of Staphylococcus aureus alpha-toxin-induced ionic channel

Polyethylene glycols (PEG) with molecular weight less than or equal to 3000 were shown to effectively protect human erythrocytes from osmotic lysis induced by alpha-staphylotoxin (ST). PEG with MW less than 3000 do not change the conductivity of ion channels induced by ST in bilayer lipid membranes (BLM). Changing the bilayer from a pure phosphatidylcholine (PC) to a negatively charged phosphatidylserine (PS) film results in an asymmetry of the current-voltage characteristics. This is evidenced by the asymmetrical position of the ST-channel pore in bilayer membranes. The results obtained allow to conclude that the ST-channel is an interprotein pore filled with water (with an inner diameter of 2.5-3 nm and a length of approximately 10 nm). It is composed of six molecules of alpha-toxin from Staphylococcus aureus. The ST-channel incorporates into a membrane with only one mouth in contact with the polar lipid heads and the other one protruding 4.5-5 nm from the bilayer plane in water solution.     

Action of α-l-fucoside fromOctopus vulgaris hepatopancreas on phospholipid vesicles containing the fucosylated ganglioside FucGM1

The behaviour of a highly purified -l-fucosidase (E.C. 3.2.1.51) extracted from octopus hepatopancreas was studied with phospholipid vesicles composed of phosphatidylcholine (PC) and phosphatidylserine (PS) containing the fucosylated ganglioside FucGM1, a potential natural substrate of the enzyme. The substrate recognition and hydrolysis take place only with PS/FucGM1 mixtures via an association process of the enzyme with the vesicles at acidic pH; the enzyme rapidly and stably binds to PS vesicles but not to PC vesicles. The data suggest that only the PS-associated enzyme is able to hydrolyse FucGM1 embedded in the same bilayer. The enzyme association with FucGM1/PS vesicles is a prerequisite for ganglioside hydrolysis but is followed by irreversible enzyme inactivation.