Edouard M. Bevers

Surface exposure of phosphatidylserine in pathological cells

Abstract.The asymmetric phospholipid distribution in plasma membranes is normally maintained by energy-dependent lipid transporters that translocate different phospholipids from one monolayer to the other against their respective concentration gradients. When cells are activated, or enter apoptosis, lipid asymmetry can be perturbed by other lipid transporters (scramblases) that shuttle phospholipids non-specifically between the two monolayers. This exposes phosphatidylserine (PS) at the cells’ outer surface. Since PS promotes blood coagulation, defective scramblase activity upon platelet stimulation causes a bleeding disorder (Scott syndrome). PS exposure also plays a pivotal role in the recognition and removal of apoptotic cells via a PS-recognizing receptor on phagocytic cells. Furthermore, expression of PS at the cell surface can occur in a wide variety of disorders. This review aims at highlighting how PS expression in different cells may complicate a variety of pathological conditions, including those that promote thromboembolic complications or produce aberrations in apoptotic cell removal.

Changes in membrane phospholipid distribution during platelet activation

Exposure of phospholipids at the outer surface of activated and control platelets was studied by incubation with a mixture of phospholipase A2 from Naja naja and bee venom, solely or in combination with sphingomyelinase from Staphylococcus aureus, using conditions under which cell lysis remained below 10%. Incubation with phospholipase A2 alone revealed a markedly increased susceptibility of the phospholipids in platelets activated by a mixture of collagen plus thrombin, by the SH-oxidizing compound diamide, or by calcium ionophore A23187, as compared to control platelets or platelets activated separately by collagen or thrombin. Collagen plus thrombin, diamide, and ionophore treated platelets revealed an increased exposure of phosphatidylserine at the outer surface accompanied by a decreased exposure of sphingomyelin, as could be concluded from incubations with a combination of phospholipase A2 and sphingomyelinase. These alterations were much less apparent in platelets activated either by thrombin or by collagen alone. The increased exposure of phosphatidylserine in activated platelets is accompanied by an increased ability of the platelets to enhance the conversion of prothrombin to thrombin by coagulation factor Xa, in the presence of factor Va and calcium. It is concluded that the altered orientation of the phospholipids in the plasma membrane of platelets activated by collagen plus thrombin, by diamide, or by calcium ionophore, is the result of a transbilayer movement. Moreover, the increased exposure of phosphatidylserine in platelets stimulated by the combined action of collagen and thrombin might be of considerable importance for the hemostatic process.

Prothrombinase activity of human platelets is inhibited by β2-glycoprotein-I

Abstract In the present paper the influence of β 2 -glycoprotein-I, also known as apolipoprotein H, upon the prothrombinase activity of platelets and phospholipid vesicles was investigated. The results can be summarized as follows. 1. The prothrombinase activity of resting, non-activated platelets, lysed platelets and vesicles composed of phosphatidylserine and phosphatidylcholine at different molar ratios is inhibited by β 2 -glycoprotein-I in a dose-dependent manner. The concentration of glycoprotein which produces marked inhibition is within the physiological plasma concentration range of β 2 -glycoprotein-I. 2. The time dependence of this inhibition is a relatively slow process, which is not fully expressed before 1 h or incubation. 3. The effect of the glycoprotein is not due to a direct interaction with the components of the prothrombinase complex, i.e. factors X a , V a , Ca 2+ or prothrombin, nor is the inhibitory action abolished by increasing concentrations of coagulation factors X a and V a . This suggests that β 2 -glycoprotein-I causes a reduction of the prothrombinase binding sites of these coagulation factors to platelets or phospholipid vesicles. 4. The prothrombinase activity of platelets stimulated with ionophore A23187 or with collagen plus thrombin is also inhibited by β 2 -glycoprotein-I in a manner similar to that oberved for phospholipid vesicles or for lysed platelets. These findings suggest a regulatory role for β 2 -glycoprotein-I in the pathway of blood coagulation.

Loss of membrane phospholipid asymmetry in platelets and red cells may be associated with calcium-induced shedding of plasma membrane and inhibition of aminophospholipid translocase

Influx of calcium in platelets and red cells produces formation of vesicles shed from the plasma membrane. The time course of the shedding process closely correlates with the ability of both cells to stimulate prothrombinase activity when used as a source of phospholipid in the prothrombinase assay. This reflects increased surface exposure of phosphatidylserine, presumably resulting from a loss in membrane asymmetry. Evidence is presented that the shed vesicles have a random phospholipid distribution, while the remnant cells show a progressive loss of membrane phospholipid asymmetry when more shedding occurs. Removal of intracellular calcium produces a decrease of procoagulant activity of the remnant cells but not of that of the shed vesicles. This is consistent with reactivation of aminophospholipid translocase activity, being first inhibited by intracellular calcium and subsequently reactivated upon calcium removal. Involvement of aminophospholipid translocase is further supported by the observation that reversibility of procoagulant activity is also dependent on metabolic ATP and reduced sulfhydryl groups. The finding that this reversibility process is not apparent in shed vesicles may be ascribed to the absence of translocase or to a lack of ATP. These data support and extend the suggestion made by Sims et al. [1989) J. Biol. Chem. 264, 17049-17057) that membrane fusion, which is required for shedding to occur, produces transient flip-flop sites for membrane phospholipids. Furthermore, the present results indicate that scrambling of membrane phospholipids can only occur provided that aminophospholipid translocase is inactive.

Phospholipid scramblase: An update

The best understood consequence of the collapse of lipid asymmetry is exposure of phosphatidylserine (PS) in the external leaflet of the plasma membrane bilayer, where it is known to serve at least two major functions: providing a platform for development of the blood coagulation cascade and presenting the signal that induces phagocytosis of apoptotic cells. Lipid asymmetry is collapsed by activation of phospholipid scramblase(s) that catalyze bidirectional transbilayer movement of the major classes of phospholipid. The protein corresponding to this activity is not yet known. Observations on cells from patients with Scott syndrome, a rare hereditary bleeding disorder resulting from impaired lipid scrambling, have shown that there are multiple activation pathways that converge on scramblase activity.

Platelet procoagulant activity: physiological significance and mechanisms of exposure

This review describes an important function of blood platelets in the hemostatic process: the formation of a procoagulant surface. Two essential steps of the coagulation cascade, the formation of factor Xa and the formation of thrombin, require a catalytic surface on which the enzyme complexes can be assembled. This catalytic surface is provided by the phospholipids of the platelet plasma membrane. However, in the quiescent platelet, the negatively charged phospholipids which are essential to the catalytic properties of the surface, are located in the cytoplasmic leaflet of the membrane. Dependent on the activator, the normal asymmetric distribution of phospholipids is lost, resulting in the formation of a procoagulant surface. Although platelets are primarily predestined to exhibit this function, certain pathological conditions can lead to exposure of a procoagulant surface in other cells as well. Current views to explain the mechanisms of exposure of a procoagulant surface include the role of the cytoskeleton, the formation of microvesicles from the plasma membrane as well as the contribution of a membrane protein, which actively transports specific phospholipids from the outer-to inner leaflet of the membrane bilayer.

Platelet Adhesion Enhances the Glycoprotein VI–Dependent Procoagulant Response Involvement of p38 MAP Kinase and Calpain

Abstract— In the final stages of activation, platelets express coagulation-promoting activity by 2 simultaneous processes: exposure of aminophospholipids, eg, phosphatidylserine (PS), at the platelet surface, and formation of membrane blebs, which may be shed as microvesicles. Contact with collagen triggers both processes via platelet glycoprotein VI (GPVI). Here, we studied the capacity of 2 GPVI ligands, collagen-related peptide (CRP) and the snake venom protein convulxin (CVX), to elicit the procoagulant platelet response. In platelets in suspension, either ligand induced full aggregation and high Ca2+ signals but little microvesiculation or PS exposure. However, most of the platelets adhering to immobilized CRP or CVX had exposed PS and formed membrane blebs after a prolonged increase in cytosolic [Ca2+]i. Platelets adhering to fibrinogen responded similarly but only when exposed to soluble CRP or CVX. By scanning electron microscopic analysis, the bleb-forming platelets were detected as either round, spongelike structures with associated microparticles or as arrays of vesicular cell fragments. The phosphorylation of p38 mitogen-activated protein kinase (MAPK) elicited by CRP and CVX was enhanced in fibrinogen-adherent platelets compared with that in platelets in suspension. The p38 inhibitor SB203580 and the calpain protease inhibitor calpeptin reduced only the procoagulant bleb formation, having no effect on PS exposure. Inhibition of p38 also downregulated calpain activity. We conclude that the procoagulant response evoked by GPVI stimulation is potentiated by platelet adhesion. The sequential activation of p38 MAPK and calpain appears to regulate procoagulant membrane blebbing but not PS exposure.

Loss of membrane phospholipid asymmetry during activation of blood platelets and sickled red cells; mechanisms and physiological significance

Membrane phospholipid asymmetry is considered to be a general property of biological membranes. Detailed information is presently available on the non-random orientation of phospholipids in red cell- and platelet membranes. The outer leaflet of the lipid bilayer membrane is rich in choline-phospholipids, whereas amino-phospholipids are abundant in the inner leaflet. Studies with blood platelets have shown that these asymmetries are not maintained when the cells are activated in various ways. Undoing the normal asymmetry of membrane phospholipids in activated blood cells is presumably mediated by increased transbilayer movement of phospholipids. This process, which leads to increased exposure of negatively charged phosphatidylserine at the outer surface, plays an important physiological role in local blood clotting reactions. A similar phenomenon occurs in sickled red cells. Phospholipid vesicles breaking off from reversibly sickled cells contribute similarly to intravascular clotting in the crisis phase of sickle cell disease.The loss of membrane phospholipid asymmetry in activated platelets seems to be strictly correlated with degradation of cytoskeletal proteins by endogenous calpain. It is remarkable that membrane phospholipid asymmetry can be (partly) restored when activated platelets are treated with reducing agents. This leads to disappearance of phosphatidylserine from the outer leaflet where it was previously exposed during cell activation. These observations will be discussed in relation to two mechanisms which have been recognized to play a role in the regulation of membrane phospholipid asymmetry; i.e. the interaction of aminophospholipids to cytoskeletal proteins, and the involvement of a phospholipid-translocase catalyzing outward-inward transbilayer movement of amino-phospholipids.

Calcium-induced transbilayer scrambling of fluorescent phospholipid analogs in platelets and erythrocytes

The non-random distribution of phospholipids in the plasma membrane of human platelets and erythrocytes is at least partially maintained by the ATP-dependent aminophospholipid translocase, but can be disturbed by a calcium-induced scrambling of lipids. Using fluorescent NBD-phospholipid analogs, we demonstrate that in both cells the aminophospholipid translocase has a slightly higher preference for the naturally occurring L-isomer of the polar headgroup of phosphatidylserine as compared to the D-isomer. Calcium-induced outward movement of internalized phosphatidylserine probe, however, is not affected by the stereochemical configuration of the serine headgroup and is virtually identical to both the inward and outward movement of the phosphatidylcholine probe. The data also indicate that both in platelets and red blood cells the calcium-induced transbilayer movement is bidirectional and involves all major phospholipid classes, with reorientation rates of sphingomyelin being appreciably lower than that of the other phospholipid classes. While our results largely support earlier observations on red cells, they clearly differ from a recent study on platelets which suggested that calcium-induced scrambling is restricted to aminophospholipids and would not involve cholinephospholipids. The present results indicate that the same mechanism is responsible for calcium-induced lipid scrambling in red blood cells and platelets.

Regulatory Mechanisms in Maintenance and Modulation of Transmembrane Lipid Asymmetry: Pathophysiological Implications

The two leaflets of the plasma membrane of eukaryotic cells differ in lipid composition: the outer leaflet comprises mainly neutral choline containing phospholipids, whereas the aminophospholipids reside almost exclusively in the cytoplasmic leaflet. The importance of transmembrane lipid asymmetry may be judged from the fact that the cell invests energy to maintain this situation for which at least two regulatory mechanisms are held responsible. A translocase, selective for aminophospholipids, acts as an ATP-dependent pump for rapid inward movement of phosphatidylserine (PS) and phosphatidylethanolamine; in addition, a non-selective, but also ATP-dependent pump causes outward movement of phospholipids, be it at a much lower rate compared to the inward transport by the aminophospholipid translocase. These two systems, acting in concert, are thought to be the main players in the maintenance of a dynamic equilibrium of the phospholipids over both membrane leaflets. Dissipation of membrane lipid asymmetry can be elicited in different cell types under a variety of conditions; in particular, platelets upon activation rapidly lose their normal plasma membrane lipid distribution, but also in other blood cells, lipid asymmetry can be lost, be it at a much lower rate and extent than in platelets. A putative protein, referred to as ‘scramblase’ has been described, which requires the continuous presence of elevated intracellular Ca2+-levels, to allow a rapid, nonselective and bidirectional transbilayer movement of phospholipids. Although scrambling of lipids does not require ATP as such, preliminary studies suggest the possible involvement of one or more phosphorylated proteins. The most prominent consequence of the loss of phospholipid asymmetry is exposure of PS in the outer leaflet of the plasma membrane. Surface-exposed PS serves several important physiological functions: it promotes assembly of enzyme complexes of the coagulation cascade, it forms a signal for cell-cell recognition, which is important for cell scavenging processes. Surface-exposure of PS is an early phenomenon of apoptosis and appears to be involved in efficient removal of these cells. In addition, PS in the outer leaflet of cells is thought to play a role in cell fusion processes. It may be clear from the foregoing, that the amount of PS present at the cell surface needs to be tightly controlled, and that an impairment of this process leads to either excessive- or diminished exposition of PS which may have several pathophysiological consequences.