Phospholipid binding of annexin V: effects of calcium and membrane phosphatidylserine content.

We studied the binding of fluorescein-labeled annexin V (placental anticoagulant protein I) to small unilamellar phospholipid vesicles at 0.15 M ionic strength as a function of calcium concentration and membrane phosphatidylserine (PS) content. As the mole percentage of PS in the membrane increased from 10 to 50%, the stoichiometry of binding decreased hyperbolically from 1100 mol phospholipid/mol annexin V to a limiting value of 84 mol/mol for measurements made at 1.2 mM CaCl2. Over the same range of PS content, Kd remained approximately constant at 0.036 +/- 0.011 nM. A similar hyperbolic decrease in stoichiometry was observed with vesicles containing 10 or 20% PS when the calcium concentration was increased from 0.4 to 10 mM. Thus, the density of membrane binding sites is strongly dependent on the membrane PS content and calcium concentration. The effect of calcium on annexin V-membrane binding is proposed to be due to the formation of phospholipid-calcium complexes, to which the protein binds, rather than to an allosteric effect of calcium on protein-phospholipid affinity.     

Kinetic analysis of the interaction of the C1 domain of protein kinase C with lipid membranes by stopped-flow spectroscopy

The diacylglycerol (DG)/phorbol ester-dependent translocation of conventional protein kinase C (PKC) isozymes is mediated by the C1 domain, a membrane-targeting module that also selectively binds phosphatidylserine (PS). Using stopped-flow spectroscopy, we dissect the contribution of DG/phorbol esters (C1 ligand) and PS in driving the association and dissociation of the C1 domain from membranes. Specifically, we examine the binding to membranes of the C1B domain of PKCbeta with a substituted Trp (Y123W) whose fluorescence is quenched upon binding to membranes. Binding of this construct (C1Bbeta-Y123W) to phospholipid vesicles is cooperative with respect to PS content and dependent on C1 ligand, as previously characterized. Stopped-flow analysis reveals that the apparent association rate (k(on)(app)), but not the apparent dissociation rate (k(off)(app)), is highly sensitive to PS content: the 60-fold increase in membrane affinity for vesicles containing no PS compared with 40 mol % PS results primarily from a robust (30-fold) increase in k(on)(app) with little effect (2-fold) on k(off)(app). Membrane affinity is also controlled by the content and structure of the C1 ligand. In contrast to PS, these ligands markedly alter k(off)(app) with smaller effects on k(on)(app). We also show that the affinity for phorbol ester-containing membranes is 2 orders of magnitude higher than that for DG-containing membranes primarily resulting from differences in k(off)(app). Our data are consistent with a model in which the C1 domain is recruited to the membrane via an initial weak electrostatic interaction with PS, followed by a rapid two-dimensional search for ligand, the binding of which retains the domain at the membrane. Thus, PS drives the initial encounter, and DG/phorbol esters retain the domain on membranes. The decreased effectiveness of DG compared with phorbol esters in retaining the C1 domain on membranes contributes to the molecular dichotomy of the rapid, transient nature of DG-dependent PKC signaling versus the chronic hyperactivity of phorbol ester-activated PKC.     

Measurement of the affinity and cooperativity of annexin V-membrane binding under conditions of low membrane occupancy

We developed a method for measuring the binding affinity of annexin V for phospholipid vesicles and cells at very low levels of membrane occupancy. The annexin V-117 mutant was labeled with fluorescein iodoacetamide on its single N-terminal cysteine residue; binding to phospholipid vesicles containing phosphatidylserine (PS) and 2% rhodamine-phosphatidylethanolamine was measured by fluorescence quenching due to resonance energy transfer; binding to cells with exposed PS was measured by fluorometry after elution of bound protein. The equilibrium constant was calculated as a function of the midpoint of the calcium titration curve, the Hill coefficient, and the concentration of membrane binding sites. Calcium titrations at very low ratios of protein to membrane revealed Hill coefficients of approximately 8 for both vesicles and cells, far higher than previously measured, but as the protein-membrane ratio was increased above 3% of maximum membrane occupancy, the value of the Hill coefficient progressively decreased to a limiting value of about 2. High Hill coefficients were also observed for measurements performed at different ionic strengths and with membrane PS content varied over the range from 20 to 50%. This method allows the accurate determination of the affinity and cooperativity of annexin V-membrane binding and will be useful for the evaluation of modified annexin V derivatives intended for diagnostic and therapeutic applications.     

Binding of human factor VIII to phospholipid vesicles

Factor VIII, a protein cofactor involved in blood coagulation, functions in vitro on a phospholipid membrane surface to greatly increase the rate of factor X activation by factor IXa. Using gel filtration, rapid sedimentation, and resonance energy transfer we have studied the interaction of recombinant-derived human factor VIII with small and large unilamellar phospholipid vesicles composed of phosphatidylserine and phosphatidylcholine. Resonance energy transfer, from intrinsic fluorophores in factor VIII to dansyl-phosphatidylethanolamine incorporated into vesicles, has been adapted for quantitative equilibrium measurements. Factor VIII binds rapidly and reversibly to small and large vesicles. At 8 degrees C the interaction of factor VIII with small vesicles fits a simple bimolecular model with a KD of 2 nM and a phospholipid binding site defined by 180 phospholipid monomers. At 25 degrees C the binding of factor VIII to small vesicles containing 20% phosphatidylserine can be described by an apparent KD of 4 nM; the phospholipid/protein ratio at saturation was 170. Binding to large vesicles was demonstrated with a KD of 2 nM and a phospholipid/protein ratio at saturation of 385. Binding was dependent upon the phosphatidylserine mole fraction and was nonlinear from 0 to 30% phosphatidylserine content. A direct comparison of factor VIII and factor V binding indicated that the affinity of factor V to phospholipid vesicles was equivalent to that of factor VIII and that the phosphatidylserine requirement was lower. A model is proposed to explain the nonlinear phosphatidylserine dependence of binding for factor VIII.     

Lactadherin binds selectively to membranes containing phosphatidyl-L-serine and increased curvature

Lactadherin, a milk protein, contains discoidin-type lectin domains with homology to the phosphatidylserine-binding domains of blood coagulation factor VIII and factor V. We have found that lactadherin functions, in vitro, as a potent anticoagulant by competing with blood coagulation proteins for phospholipid binding sites [J. Shi and G.E. Gilbert, Lactadherin inhibits enzyme complexes of blood coagulation by competing for phospholipid binding sites, Blood 101 (2003) 2628-2636]. We wished to characterize the membrane-binding properties that correlate to the anticoagulant capacity. We labeled bovine lactadherin with fluorescein and evaluated binding to membranes of composition phosphatidylserine/phosphatidylethanolamine/phosphatidylcholine, 4:20:76 supported by 2 mum diameter glass microspheres. Lactadherin bound saturably with an apparent KD of 3.3+/-0.4 nM in a Ca++ -independent manner. The number of lactadherin binding sites increased proportionally to the phosphatidylserine content over a range 0-2% and less rapidly for higher phosphatidylserine content. Inclusion of phosphatidylethanolamine in phospholipid vesicles did not enhance the apparent affinity or number of lactadherin binding sites. The number of sites was at least 4-fold higher on small unilamellar vesicles than on large unilamellar vesicles, indicating that lactadherin binding is enhanced by membrane curvature. Lactadherin bound to membranes with synthetic dioleoyl phosphatidyl-L-serine but not dioleoyl phosphatidyl-D-serine indicating stereoselective recognition of phosphatidyl-L-serine. We conclude that lactadherin resembles factor VIII and V with stereoselective preference for phosphatidyl-L-serine and preference for highly curved membranes.     

Role of substrate in determining the phospholipid specificity of protein kinase C activation

The phospholipid selectivity of protein kinase C (PKC) activation was examined by using two substrates, histone and a random copolymer of lysine and serine [poly(lysine, serine)] (PLS), plus phospholipids provided as vesicles or as Triton-mixed micelle preparations. The results indicated that substrate-phospholipid interaction was an essential component of PKC activation and that many in vitro properties of PKC activation are attributable to this interaction. The substrate histone interacted with phospholipid-Triton mixed micelles containing phosphatidylserine (PS), but not with those containing phosphatidylinositol (PI) or phosphatidylglycerol (PG). In direct correlation, only PS-Triton mixed micelles were effective in supporting PKC activity. Also, the minimum PS composition (4 mol % in Triton) required to induce significant histone-PS interaction coincided with the minimum composition required for phosphorylation of histones. Moreover, the PS composition required for maximum activity varied with the histone concentration of the reaction. In contrast to histone, PLS interacted with phospholipid-Triton mixed micelles containing either PS, PI, or PG, and all these mixed micelles supported the phosphorylation of PLS. In fact, by selection of appropriate experimental conditions (e.g., concentration of substrate and phospholipid), any of the three mixed micelles could appear the most effective in supporting PKC activity. Phospholipid vesicles containing PS, PG, or PI were found to interact with both histone and PLS and to support the activity of PKC. Physical properties of the solution and conditions used for preparation of phospholipid vesicles had considerable influence on PKC activation. At high phospholipid concentrations, vesicles containing PS, PI, or PG supported the activity of PKC to essentially the same level, provided that the physical differences among the phospholipid vesicles were minimized.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phospholipid-binding properties of bovine factor V and factor Va.

Factor V and factor Va binding to single bilayer phospholipid vesicles was investigated by light-scattering intensity measurements. This technique allows the measurement of free and phospholipid-bound protein concentrations from which equilibrium constants can be obtained. As controls, the Ca2+-dependent phospholipid binding of prothrombin and factor X were also studied. The average values obtained for the dissociation constants (Kd) and lipid to protein ratio at saturation, moles/mole (n), for prothrombin (Kd = 2.3 X 10(-6) M, n = 104) and factor X (Kd = 2.5 X 10(-6) M, n = 46) binding to vesicles containing 25% Folch fraction III and 75% phosphatidylcholine in the presence of 2 mM Ca2+ were in agreement with those reported in the literature. The average factor V and factor Va values for the dissociation constants and lipid to protein ratio at saturation (moles/mole) were Kd = 7.2 X 10(-8) M and n = 270 for factor V and Kd = 4.4 X 10(-7) M and n = 76 for factor Va. In contrast to prothrombin and factor X, factor V and factor Va demonstrated Ca2+-independent lipid binding. In addition, the number of factor V and factor Va molecules bound per vesicle was found to be dependent both on the phosphatidylserine content of the vesicle and the ionic strength of the buffer.     

The interaction of bovine factor IX, its activation intermediate, factor IX alpha, and its activation products, factor IXa alpha and factor IXa beta, with acidic phospholipid vesicles of various compositions.

The interactions of bovine factor IX, its activation intermediate, Factor IX alpha, and its activation products, Factor IXa alpha and Factor IXa beta, with phospholipid vesicles, of mean radius of approx. 30 nm, containing various amounts of phosphatidylserine (PS) and phosphatidylcholine (PC), have been examined. For Factor IX, Factor IX alpha, Factor IXa alpha and Factor IXa beta, the dissociation constants, at saturating levels of Ca2+, are independent of the PS concentration in the vesicle after levels of 20-30% (w/w) have been reached, and attain minimum values of approx. 1.7, 1.7, 0.7 and 1.0 microM, respectively, with vesicles containing 50% PS. The amount of protein bound per vesicle particle is independent of the PS content, above 20% PS, for Factor IX and Factor IXa beta, with values of approx. 995-1197 and 1128-1566 molecules/vesicle, respectively. With Factor IX alpha, a dependence on the amount of protein bound with the content of PS is seen, which ranges from 338 to 619 molecules/vesicle with membranes containing 30-50% PS. For Factor IXa alpha, no regularity is noted and a range of 583-1083 molecules of protein/vesicle is observed with the systems employed. Examination of the radii of the proteins on the vesicle demonstrates that Factors IX alpha and IXa alpha occupy considerably more of the surface than do Factors IX and IXa beta, suggesting that a reason for the decreased number of binding sites for the former two proteins on the vesicle may be related to their greater surface spatial requirements.     

Reconstitution of the purified platelet fibrinogen receptor. Fibrinogen binding properties of the glycoprotein IIb-IIIa complex

Several lines of evidence indicate that the platelet membrane glycoprotein IIb-IIIa complex (GP IIb-IIIa) is necessary for the expression of platelet fibrinogen receptors. The purpose of the present study was to determine whether purified GP IIb-IIIa retains the properties of the fibrinogen receptor on platelets. Glycoprotein IIb-IIIa was incorporated by detergent dialysis into phospholipid vesicles composed of 30% phosphatidylcholine and 70% phosphatidylserine. 125I-Fibrinogen binding to the GP IIb-IIIa vesicles, as measured by filtration, had many of the characteristics of 125I-fibrinogen binding to whole platelets or isolated platelet plasma membranes: binding was specific, saturable, reversible, time dependent, and Ca2+ dependent. The apparent dissociation constant for 125I-fibrinogen binding to GP IIb-IIIa vesicles was 15 nM, and the maximal binding capacity was 0.1 mol of 125I-fibrinogen/mol of GP IIb-IIIa. 125I-Fibrinogen binding was inhibited by amino sugars, the GP IIb and/or IIIa monoclonal antibody 10E5, and the decapeptide from the carboxyl terminus of the fibrinogen gamma chain. Furthermore, little or no 125I-fibrinogen bound to phospholipid vesicles lacking protein or containing proteins other than GP IIb-IIIa (i.e. bacteriorhodopsin, apolipoprotein A-I, or glycophorin). Also, other 125I-labeled plasma proteins (transferrin, orosomucoid) did not bind to the GP IIb-IIIa vesicles. These results demonstrate that GP IIb-IIIa contains the platelet fibrinogen receptor.     

Role of phosphatidylethanolamine in assembly and function of the factor IXa-factor VIIIa complex on membrane surfaces

Phospholipid membranes play a significant role during the proteolytic activation of blood coagulation proteins. This investigation identifies a role for phosphatidylethanolamine (PE) during the activation of factor X by the tenase complex, an enzymatic complex composed of the serine protease, factor IXa, a protein cofactor, factor VIIIa, a phospholipid membrane, and Ca(2+). Phospholipid vesicles composed of PE, phosphatidylserine (PS), and phosphatidylcholine support factor Xa generation. The K(m) and k(cat) for factor X activation by the tenase complex are independent of PE in the presence of 20% PS. At lower PS concentrations, the presence of 20 or 35% PE lowers the K(m) and increases the k(cat) as compared to those in vesicles without PE. The effect of PE on the k(cat) of the tenase complex is mediated through factor VIIIa. PE also enhances factor Xa generation by facilitating tenase complex formation; PE lowers the K(d(app)) of factor IXa for both phospholipid/Ca(2+) and phospholipid/Ca(2+)/factor VIIIa complexes in the presence of suboptimal PS. In addition, the K(d)s of factor IXa and factor X were lower for phospholipid vesicles containing PE. N-Methyl-PE increased the k(cat) and decreased the K(d(app)), whereas N,N-dimethyl-PE had no effect on either parameter, indicating the importance of headgroup size. Lyso-PE had no effect on kinetic parameters, indicating the sn-2 acyl chain dependence of the PE effect. Together, these results demonstrate a role for PE in the assembly and activity of the tenase complex and further extend the understanding of the importance of PE-containing membranes in hemostasis.     

Enhanced binding of phosphatidylserine-containing lipid vesicle targets to RAW264 macrophages

Summary Phosphatidylserine was found to significantly enchance the binding of phospholipid vesicles to RAW264 macrophages. We have measured the kinetics of non-specific uptake of unilamellar vesicles as a function of phosphatidylserine concentration in these model target membranes. Dimyristoylphosphatidylcholine was the principle component of these phospholipid vesicles. In most experiments, radiolabeled phospholipid and 1 mol % each of both a fluorescent phospholipid and a hapten-containing lipid headgroup were utilized. In the presence of specific anti-hapten antibody phosphatidylserine-containing vesicles are rapidly taken up via phagocytosis. The antibody-independent non-specific uptake of phosphatidylserine-free vesicles was low, as previously reported. However, the presence of 5 mol % phosphatidylserine dramatically enhanced the uptake of phospholipid vesicles by macrophages. This uptake was shown to be principally due to binding to the macrophage surface. Incubation of macrophages in the presence of sodium azide or at 4°C, conditions which are known to inhibit phagocytosis, do not influence the uptake of the lipid vesicles. Fluorescence video-intensification microscopy was used to observe the interaction of carboxyfluorescein-loaded vesicles with macrophages. Fluorescence could not be observed when using phosphatidylserine-free vesicles. However, phosphatidylserine-containing vesicles can be observed bound to the cell periphery. Intracellular fluorescence could not be observed. The binding of phosphatidylserine-containing vesicles was enhanced roughly four-fold over phosphatidylserine because the effect could not be observed with membranes containing 1 mol % or 2.5 mol% phosphatidylserine. In addition, the binding enhancement required the presence of divalent cations in the incubation medium.Abbreviations DMPC dimyristoylphosphatidylcholine - PS phosphatidylserine - DNP-PE dinitrophenyl---minocaproyl-phosphatidylethanolamime - NBDPE N-4-nitrobenzo-2-oxa-1, 3-diazole phosphatidylethanolamine - EDTA ethylenediaminetetraacetic acid     

Membrane components can modulate the substrate specificity of protein kinase C

The cationic amphiphile, cholesteryl-3-carboxyamidoethylene-trimethylammonium iodide, can alter the substrate specificity of protein kinase C (PKC). The phosphorylation of histone catalyzed by PKC requires the binding of the enzyme to phospholipid vesicles. This cationic amphiphile reduces both the binding of PKC to lipid and as a consequence its rate of phosphorylation of histone. In contrast, PKC bound to large unilamellar vesicles (LUVs) composed of 50 mol % POPS, 20 mol % POPC, and 30 mol % of this amphiphile catalyzes protamine sulfate phosphorylation by an almost 4 fold greater rate. This activation requires phosphatidylserine (PS) and is inhibited by Ca²⁺. The extent of activation is affected by the time of incubation of PKC with LUVs. This data suggests a novel mechanism by which PKC-dependent signal transduction pathways may be altered by altering the protein targets of this enzyme.     

Phosphatidylinositol 4,5-bisphosphate competitively inhibits phorbol ester binding to protein kinase C

Calcium phospholipid dependent protein kinase C (PKC) is activated by diacylglycerol (DG) and by phorbol esters and is recognized to be the phorbol ester receptor of cells; DG displaces phorbol ester competitively from PKC. A phospholipid, phosphatidylinositol 4,5-bisphosphate (PIP2), can also activate PKC in the presence of phosphatidylserine (PS) and Ca2+ with a KPIP2 of 0.04 mol %. Preliminary experiments have suggested a common binding site for PIP2 and DG on PKC. Here, we investigate the effect of PIP2 on phorbol ester binding to PKC in a mixed micellar assay. In the presence of 20 mol % PS, PIP2 inhibited specific binding of [3H]phorbol 12,13-dibutyrate (PDBu) in a dose-dependent fashion up to 85% at 1 mol %. Inhibition of binding was more pronounced with PIP2 than with DG. Scatchard analysis indicated that the decrease in binding of PDBu in the presence of PIP2 is the result of an altered affinity for the phorbol ester rather than of a change in maximal binding. The plot of apparent dissociation constants (Kd') against PIP2 concentration was linear over a range of 0.01-1 mol % with a Ki of 0.043 mol % and confirmed the competitive nature of inhibition between PDBu and PIP2. Competition between PIP2 and phorbol ester could be demonstrated in a liposomal assay system also. These results indicate that PIP2, DG, and phorbol ester all compete for the same activator-receiving region on the regulatory moiety of protein kinase C, and they lend support to the suggestion that PIP2 is a primary activator of the enzyme.     

Ammodytoxins, potent presynaptic neurotoxins, are also highly efficient phospholipase A2 enzymes

The enzymatic activity of ammodytoxins (Atxs), secreted phospholipases A(2) (sPLA(2)s) in snake venom, is essential for expression of their presynaptic neurotoxicity, but its exact role in the process is unknown. We have analyzed in detail the enzymatic properties of Atxs, their mutants, and homologues. The apparent rates of phospholipid hydrolysis by the sPLA(2)s tested vary by up to 4 orders of magnitude, and all enzymes display a strong preference for vesicles containing anionic phospholipids, phosphatidylglycerol or phosphatidylserine (PS), over those containing zwitterionic phosphatidylcholine (PC). Nevertheless, Atxs are quite efficient in hydrolyzing pure PC vesicles as well as PC-rich plasma membranes of intact HEK293 cells. The presence of anionic phospholipids in PC vesicles dramatically increases the interfacial binding affinity and catalytic activity of Atxs, but not of their nontoxic homologue ammodytin I(2), that displays unusually low binding affinity and enzymatic activity on PS-containing vesicles and HEK293 plasma membranes. Aromatic and hydrophobic residues on the interfacial binding surface of Atxs are important for productive binding to both zwitterionic and anionic vesicles, while basic and polar residues have a negative impact on binding to zwitterionic vesicles. When tightly bound to the membrane interface, Atxs can reach full enzymatic activity at low micromolar concentrations of Ca(2+). Although Atxs have evolved to function as potent neurotoxins that specifically target presynaptic nerve terminals, they display a high degree of phospholipolytic efficiency on various phospholipid membranes.     

Lactadherin binds selectively to membranes containing phosphatidyl-l-serine and increased curvature

Lactadherin, a milk protein, contains discoidin-type lectin domains with homology to the phosphatidylserine-binding domains of blood coagulation factor VIII and factor V. We have found that lactadherin functions, in vitro, as a potent anticoagulant by competing with blood coagulation proteins for phospholipid binding sites [J. Shi and G.E. Gilbert, Lactadherin inhibits enzyme complexes of blood coagulation by competing for phospholipid binding sites, Blood 101 (2003) 2628-2636]. We wished to characterize the membrane-binding properties that correlate to the anticoagulant capacity. We labeled bovine lactadherin with fluorescein and evaluated binding to membranes of composition phosphatidylserine/phosphatidylethanolamine/phosphatidylcholine, 4:20:76 supported by 2 μm diameter glass microspheres. Lactadherin bound saturably with an apparent K_D of 3.3±0.4 nM in a Ca⁺⁺-independent manner. The number of lactadherin binding sites increased proportionally to the phosphatidylserine content over a range 0-2% and less rapidly for higher phosphatidylserine content. Inclusion of phosphatidylethanolamine in phospholipid vesicles did not enhance the apparent affinity or number of lactadherin binding sites. The number of sites was at least 4-fold higher on small unilamellar vesicles than on large unilamellar vesicles, indicating that lactadherin binding is enhanced by membrane curvature. Lactadherin bound to membranes with synthetic dioleoyl phosphatidyl-l-serine but not dioleoyl phosphatidyl-d-serine indicating stereoselective recognition of phosphatidyl-l-serine. We conclude that lactadherin resembles factor VIII and V with stereoselective preference for phosphatidyl-l-serine and preference for highly curved membranes.     

Interaction of vitamin K-dependent protein Z with thrombin. Consequences for the amidolytic activity of thrombin and the interaction of thrombin with phospholipid vesicles

Protein Z is a vitamin K-dependent protein of unknown function present in normal bovine plasma at a concentration of approximately 0.1 microM. Quantitative affinity chromatographic studies using diisopropylphosphoryl (DIP)-thrombin-Affi-Gel 10 as the affinity matrix and free DIP-thrombin as the competitor demonstrated that protein Z interacts with DIP-thrombin with a dissociation constant of 0.15 +/- 0.05 microM. Binding was independent of Ca2+. Protein C and factor IX, other vitamin K-dependent clotting proteins with the same domain structure as that of protein Z, did not interact with immobilized DIP-thrombin under these conditions; and factor X interacted with an affinity 20-fold lower than that for protein Z. The Michaelis constant, Km, for hydrolysis of pyro-Glu-Pro-Arg-p-nitroanilide by thrombin was increased 1.8-fold, from 130 to 230 microM, as a result of the binding of protein Z and the Km for H-Val-Leu-Arg-p-nitroanilide 1.4-fold, from 390 to 560 microM. From these kinetic studies, a dissociation constant of 0.11 +/- 0.04 microM was calculated for the binding of protein Z to alpha-thrombin. Protein Z bound to large phospholipid vesicles (25% phosphatidylserine, 75% phosphatidylcholine) with a dissociation constant of 0.39 +/- 0.16 microM at a phospholipid to protein ratio of 82 mol of phospholipid/mol of protein Z at saturation. In the presence of protein Z thrombin associated with phospholipid vesicles, whereas thrombin did not interact with phospholipid vesicles in the absence of protein Z. These studies, therefore, demonstrate a physiologically relevant interaction between protein Z and thrombin. They also suggest a mechanism whereby thrombin is localized to an injury site by virtue of its interaction with protein Z bound to phospholipid surfaces.     

Low affinity binding of taurine to phospholiposomes and cardiac sarcolemma

A sarcolemma-enriched membrane fraction was prepared from the hearts of Sprague-Dawley rats and its ability to bind taurine (0.5-150 mM) was measured. In the absence of cations, the sarcolemma bound a maximum of 661 nmol taurine/mg protein, with a dissociation constant of 19.2 mM and a Hill coefficient of 1.9, indicating positive cooperativity. Scatchard analysis of taurine binding to sarcolemma gave a bell-shaped curve. Neither beta-alanine nor guanidinoethane sulfonate, inhibitors of taurine transport, affected the degree of taurine binding to sarcolemma. However, hypotaurine was an effective antagonist. Equimolar concentrations of Ca2+, Na+ or K+ also reduced taurine binding. Heterogeneous phospholipid vesicles of phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, and phosphatidylserine (18:19:2:1) also bound taurine with positive cooperativity, yielding a bell-shaped Scatchard curve. The affinity of taurine for these mixed phospholipid vesicles was enhanced by the inclusion of cholesterol (50%). Taurine associated in a maximum ratio of 1:1 with homogeneous vesicles of phosphatidylcholine or phosphatidylserine. Vesicles of phosphatidylethanolamine bound taurine in a maximum ratio of 2:1, whereas those of phosphatidylinositol bound insignificant amounts of taurine. These studies demonstrate a low affinity binding to sarcolemma of taurine at concentrations normally present in rat heart. Similar levels of binding were observed in phospholipid vesicles, suggesting that the interaction of taurine with biological membranes involves phospholipids.     

Activation of human endothelial cell-type plasminogen activator inhibitor (PAI-1) by negatively charged phospholipids

The endothelial cell-type plasminogen activator inhibitor (PAI-1) may exist in an inactive, latent form that can be converted into an active form upon treatment of the protein with denaturants, such as sodium dodecyl sulfate, guanidine HCl, or urea. The present paper demonstrates that latent PAI-1 can be activated by lipid vesicles containing the negatively charged phospholipids phosphatidylserine (PS) or phosphatidylinositol. The presence of a net negative charge on the phospholipid headgroup is essential for activation, since lipid vesicles consisting exclusively of zwitterionic phospholipids, such as phosphatidylcholine and phosphatidylethanolamine, do not activate PAI-1. In the presence of PS vesicles, PAI-1 inhibited tissue-type plasminogen activator 50-fold more effectively than in the absence of phospholipids, whereas sodium dodecyl sulfate enhanced PAI-1 activity by 25-fold. In mixed phospholipid vesicles containing PS and phosphatidylcholine in various molar ratios, the extent of PAI-1 activation was directly related to the PS content of the phospholipid membrane. Ca2+ ions interfered with the inhibitory activity of PS-activated PAI-1, suggesting that Ca2+ ions may regulate PAI-1 activity in the presence of negatively charged phospholipids. An important consequence of these findings is that, as in blood coagulation, negatively charged phospholipids may play an important regulatory role in controlling the fibrinolytic system by activating an inhibitor of tissue-type plasminogen activator.     

Membrane binding kinetics of protein kinase C betaII mediated by the C2 domain.

Conventional isoforms of protein kinase C (PKC) are activated when their two membrane-targeting modules, the C1 and C2 domains, bind the second messengers diacylglycerol (DG) and Ca2+, respectively. This study investigates the mechanism of Ca2+-induced binding of PKC betaII to anionic membranes mediated by the C2 domain. Stopped-flow fluorescence spectroscopy reveals that Ca2+-induced binding of the isolated C2 domain to anionic vesicles proceeds via at least two steps: (1) rapid binding of two or more Ca2+ ions to the free domain with relatively low affinity and (2) diffusion-controlled association of the Ca2+-occupied domain with vesicles. Ca2+ increases the affinity of the C2 domain for anionic membranes by both decreasing the dissociation rate constant (k(off)) and increasing the association rate constant (k(on)) for membrane binding. For binding to vesicles containing 40 mol % anionic lipid in the presence of 200 microM Ca2+, k(off) and k(on) are 8.9 s(-1) and 1.2 x 10(10) M(-1) x s(-1), respectively. The k(off) value increases to 150 s(-1) when free Ca2+ levels are rapidly reduced, decreasing the average lifetime of the membrane-bound C2 domain (tau = k(off)(-1)) from 110 ms in the presence of Ca2+ to 6.7 ms when Ca2+ is rapidly removed. Experiments addressing the role of electrostatic interactions reveal that they stabilize either the initial C2 domain-membrane encounter complex or the high-affinity membrane-bound complex. Specifically, lowering the phosphatidylserine mole fraction or including MgCl2 in the binding reaction decreases the affinity of the C2 domain for anionic vesicles by both reducing k(on) and increasing k(off) measured in the presence of 200 microM Ca2+. These species do not affect the k(off) value when Ca2+ is rapidly removed. Studies with PKC betaII reveal that Ca2+-induced binding to membranes by the full-length protein proceeds minimally via two kinetically resolvable steps: (1) a rapid bimolecular association of the enzyme with vesicles near the diffusion-controlled limit and, most likely, (2) subsequent conformational changes of the membrane-bound enzyme. As is the case for the C2 domain, k(off) for full-length PKC betaII increases when Ca2+ is rapidly removed, reducing tau from 11 s in the presence of Ca2+ to 48 ms in its absence. Thus, both the C2 domain and the slow conformational change prolong the lifetime of the PKC betaII-membrane ternary complex in the presence of Ca2+, with rapid membrane release triggered by removal of Ca2+. These results provide a molecular basis for cofactor regulation of PKC whereby the C2 domain searches three-dimensional space at the diffusion-controlled limit to target PKC to relatively common anionic phospholipids, whereupon a two-dimensional search is initiated by the C1 domain for the more rare, membrane-partitioned DG.