Complement proteins C5b-9 induce transbilayer migration of membrane phospholipids

179

146

A kinetic model for pore-mediated and perturbation-mediated flip-flop is presented and used to characterize the mechanism of peptide-induced phospholipid flip-flop in bilayers. The model assumes that certain peptides can bind to and aggregate within the membrane. When the aggregate attains a critical size (M peptides), a channel is created that results in a fast flip-flop of phospholipids. In addition, certain peptides induce flip-flop through perturbation of the membrane without forming a pore. Donor phospholipid vesicles with an asymmetrical distribution of the fluorescent phospholipid 1-oleoyl-2-[12-[(7-nitro-1,2,3-benzoxadiazol-4- yl)amino]dodecanoyl]phosphatidylcholine (NBD-PC) were used to measure the extent of flip-flop by quantitating the decrease in fluorescence as the NBD-PC exchanged from the donor vesicles to acceptor vesicles that contained a quencher of the NBD fluorescence. Flip-flop curves generated at lipid/peptide ratios ranging from 30/1 to 300000/1 could be well-simulated by the model. Pore-forming peptides, such as melittin or the synthetic peptide GALA (WEAALAEALAEALAEHLAEALAEALEALAA), induce rapid phospholipid flip-flop with half-times for flip-flop of seconds at low peptide/vesicle ratios. The deduced pore sizes are M = 10 +/- 2 for GALA and M = 2 - 4 for melittin. The synthetic peptide LAGA (WEAALAEAEALALAEHEALALAEAELALAA) can catalyze flip-flop via bilayer perturbation. In contrast, hydrophobic peptides such as gramicidin A and valinomycin intercalate into the membrane, but induce little flip-flop. Modeling of the kinetics of phospholipid translocation supports pore formation as the key factor in accelerating phospholipid flip-flop. Thus, amphipathic segments from membrane proteins may account for non-energy-dependent phospholipid flip-flop in biological membranes.

Section: Discussionmentioning

confidence: 95%

Pore-Forming Peptides Induce Rapid Phospholipid Flip-Flop in Membranes

Fattal

Nir²,

Parente³

et al. 1994

179

146

“…By contrast, the C5b-9 complex-which is also lipophilic, potentially lipolytic, and membrane pore-forming in its properties-has its site of action restricted exclusively to the plasma membrane. These complement proteins have also been shown to directly promote transbilayer exchange of membrane phospholipids (Van der Meer et al, 1989).…”

Section: Resultsmentioning

confidence: 99%

Binding of anticoagulant vitamin K-dependent protein S to platelet-derived microparticles

Dahlbäck

Wiedmer²,

Sims³

1992

Vitamin K-dependent protein S is an anticoagulant plasma protein serving as cofactor to activated protein C in degradation of coagulation factors Va and VIIIa on membrane surfaces. In addition, it forms a noncovalent complex with complement regulatory protein C4b-binding protein (C4BP), a reaction which inhibits its anticoagulant function. Both forms of protein S have affinity for negatively charged phospholipids, and the purpose of the present study was to elucidate whether they bind to the surface of activated platelets or to platelet-derived microparticles. Binding of protein S to human platelets stimulated with various agonists was examined with FITC-labeled monoclonal antibodies and fluorescence-gated flow cytometry. Protein S was found to bind to membrane microparticles which formed during platelet activation but not to the remnant activated platelets. Binding to microparticles was saturable and maximum binding was seen at approximately 0.4 microM protein S. It was calcium-dependent and reversed after the addition of EDTA. Inhibition experiments with monoclonal antibodies suggested the gamma-carboxyglutamic acid containing module of protein S to be involved in the binding reaction. An intact thrombin-sensitive region of protein S was not required for binding. The protein S-C4BP complex did not bind to microparticles or activated platelets even though it bound to negatively charged phospholipid vesicles. Intact protein S supported binding of both protein C and activated protein C to microparticles. Protein S-dependent binding of protein C/activated protein C was blocked by those monoclonal antibodies against protein S that inhibited its cofactor function. In conclusion, we have found that free protein S binds to platelet-derived microparticles and stimulates binding of protein C/activated protein C.(ABSTRACT TRUNCATED AT 250 WORDS)

“…These data imply that exposure of the membrane prothrombinase site is unrelated to the action of calpains upon cytoskeletal proteins. The C5b-9 proteins have been shown to directly induce exchange of phospholipid between inner and outer monolayers in a pure lipid system (Van der Meer et al, 1989). This direct effect on lipids might account for the ability of C5b-9 to increase acidic phospholipid on the platelet surface, thereby providing a catalytic surface for the prothrombinase enzyme complex.…”

Section: Discussionmentioning

confidence: 99%

Role of calcium and calpain in complement-induced vesiculation of the platelet plasma membrane and in the exposure of the platelet factor Va receptor

Wiedmer¹,

Shattil²,

Cunningham³

et al. 1990

162

The role of calcium and intracellular calpains in the expression of platelet prothrombinase activity was investigated. Incubation of gel-filtered platelets with complement proteins C5b-9 resulted in alpha-granule and dense granule secretion and exposure of membrane binding sites for coagulation factors Va and Xa. This was accompanied by the release of microparticles from the cell surface that incorporated plasma membrane glycoproteins GP Ib, IIb, and IIIa and the alpha-granule membrane protein GMP-140. Generation of these membrane microparticles was dependent on the presence of extracellular calcium and was accompanied by proteolytic degradation of the cytoskeletal proteins, actin binding protein (ABP), talin, and myosin heavy chain. Microparticle formation was also detected when unstirred platelets were activated by thrombin plus collagen, although proteolysis of ABP, talin, or myosin was not observed. Preincorporation of the calpain inhibitor leupeptin into the platelet cytosol completely blocked C5b-9-induced proteolysis of ABP, talin, and myosin. However, inhibition of this calpain-mediated proteolysis had no effect on platelet secretion, the generation of microparticles, the exposure of membrane sites for factors Va and Xa, or the expression of prothrombinase activity. Furthermore, the microparticles that formed in the presence of leupeptin contained intact ABP, talin, and myosin heavy chain. Prior depletion of ATP with metabolic inhibitors eliminated all platelet responses to thrombin plus collagen, but did not affect C5b-9-induced microparticle formation or exposure of binding sites for factor Va on the microparticles. These data indicate that the formation of microparticles and the expression of platelet prothrombinase activity in response to C5b-9 are dependent upon an influx of calcium into the platelet cytosol, but do not require metabolic energy or calpain-mediated proteolysis of cytoskeletal proteins.