Alain Bienvenüe

Peptides and Membrane Fusion: Towards an Understanding of the Molecular Mechanism of Protein-Induced Fusion

Abstract. Processes such as endo- or exocytosis, membrane recycling, fertilization and enveloped viruses infection require one or more critical membrane fusion reactions. A key feature in viral and cellular fusion phenomena is the involvement of specific fusion proteins. Among the few well-characterized fusion proteins are viral spike glycoproteins responsible for penetration of enveloped viruses into their host cells, and sperm proteins involved in sperm-egg fusion. In their sequences, these proteins possess a ``fusion peptide, a short segment (up to 20 amino acids) of relatively hydrophobic residues, commonly found in a membrane-anchored polypeptide chain. To simulate protein-mediated fusion, many studies on peptide-induced membrane fusion have been conducted on model membranes such as liposomes and have employed synthetic peptides corresponding to the putative fusion sequences of viral proteins, or de novo synthesized peptides. Here, the application of peptides as a model system to understand the molecular details of membrane fusion will be discussed in detail. Data obtained from these studies will be correlated to biological studies, in particular those that involve viral and sperm-egg systems. Structure-function relationships will be revealed, particularly in the context of protein-induced membrane perturbations and bilayer-to-nonbilayer transition underlying the mechanism of fusion. We will also focus on the involvement of lipid composition of membranes as a potential regulating factor of the topological fusion site in biological systems.

Correlation between inhibition of cytoskeleton proteolysis and anti-vesiculation effect of calpeptin during A23187-induced activation of human platelets: are vesicles shed by filopod fragmentation?

Platelets were incubated in the presence of calpeptin to inhibit calpain-mediated cytoskeleton proteolysis during further activation by Ca2+ ionophore A23187. The appearance of filamin and myosin subfragments (93 kDa and 135 kDa, respectively) was inhibited by low calpeptin doses (1 microgram/ml). Higher doses (10-20 micrograms/ml) were required to completely inhibit talin and filamin degradation. Vesiculation strongly depended on cytoskeleton proteolysis and was reduced by 60% when platelets were preincubated with 10 micrograms/ml calpeptin. Activated platelets bore longer and more filopods when pretreated with calpeptin. Filopods were straight and regular when high calpeptin doses were used, whereas they were shorter and broader with bloated surfaces when calpeptin was omitted. Some bloated areas were also found in straight filopods. These results suggest that the cytoskeleton proteolysis, and more specifically filamin proteolysis, induced bloating of filopod surfaces, thus facilitating fragmentation of filopod into vesicles.

Mechanical constraint imposed on plasma membrane through transverse phospholipid imbalance induces reversible actin polymerization via phosphoinositide 3-kinase activation

Platelets were used to explore the effect of membrane curvature induced by phospholipid excess on cell shape and on organization of the actin cytoskeleton. We showed that the addition of short chain analogues of phospholipids to the outer leaflet of plasma membrane of resting platelets immediately induced a shape change with long filopodia formation containing newly polymerized actin. Cells recovered rapidly their discoid shape and their initial F-actin content only with the phosphatidylserine analogue, which was transported to the inner leaflet by aminophospholipid translocase. Filopodia formation and actin polymerization were inhibited in platelets pre-incubated with cytochalasin D. Both wortmannin and LY294002, two unrelated inhibitors of phosphoinositide 3-kinase, considerably reduced actin polymerization and filopodia formation. Phospholipid imbalance was accompanied by a reversible translocation of phosphoinositide 3-kinase from cytoplasm to plasma membrane. In agreement with a role for PI 3-kinase, when phospholipids were added to platelets, PtdIns(3,4)P2 increased two-fold and Akt protein was partly phosphorylated. A similar shape change was also observed in nocodazole-treated L929 fibroblasts which were incubated with the similar phospholipid analogues. In those nucleated cells, where the microtubule cytoskeleton was disrupted, a major actin-dependent membrane extension was induced by addition of short chain phospholipids that required the functional integrity of PI 3-kinase. We conclude that any physical constraint acting on plasma membrane and resulting on local changes in membrane curvature is sufficient to initiate transient actin polymerization via phosphoinositide 3-kinase activation.

Impaired redistribution of aminophospholipids with distinctive cell shape change during Ca2+‐induced activation of platelets from a patient with Scott syndrome

We have investigated phospholipid redistribution, membrane vesicle shedding, shape change, and granule release following A23187 activation of platelets from a patient with Scott syndrome, characterized by impaired transmembrane migration of phosphatidylserine (PS) accompanied by haemorrhagic complications, and two of her children. Electron spin resonance spectroscopy measurement of phospholipids redistribution showed that the internalization of PS was unaffected by the disorder but, after activation, PS exposure was significantly reduced in platelets from the homozygous‐type patient. Vesicle shedding was also reduced in these platelets. However, the slow redistribution of phosphatidylcholine was similar to that observed in normal platelets. When treated with calpeptin, platelets from the homozygous‐type patient, unlike normal or heterozygous Scott syndrome platelets, showed a smoothly rounded shape without filopods after activation. Following A23187 activation of normal platelets, filopod formation was consecutive to the re‐exposition of aminophospholipids on the outer leaflet of the plasma membrane, and the existence of a floppase (outward aminoPLs translocase) has been suggested. In homozygous Scott syndrome platelets the deficiency in PS re‐exposition, the absence of filopod formation, and low vesicle shedding are correlated with each other, and argue in favour of a disruption of the proposed floppase activity.

Modifications of LDL-receptor-mediated endocytosis rates in CEM lymphoblastic cells grown in lipoprotein-depleted fetal calf serum

The efficiency of supplying cholesterol by the LDL endocytic pathway of lymphoblastic T CEM cells was compared when incubated in the presence of either fetal calf serum (FCS) or lipoprotein-depleted fetal calf serum (LDFCS). In the presence of FCS, there were 8600 +/- 2000 LDL receptors/cell with a Kd of (2.2 +/- 0.8).10(-8) M and a receptor cycling time of about 7 min; about 90% of the internalized LDL was degraded. LDL degradation produced 98% of total cellular cholesterol and only 2% came from endogenous synthesis. The absence of LDL in the culture medium of lymphoblastic CEM cells deeply modified certain metabolic and structural characteristics of the cells. Their cholesterol content decreased; the total number of LDL receptors increased 6-fold, whereas their affinity for the ligand decreased by the same factor (Kd = (1.2 +/- 0.2).10(-7) M); the receptor cycling time increased 3-fold. Finally, LDL degraded by cholesterol-depleted CEM cells amounted to about 40% of that degraded by untreated CEM cells.

Involvement of ATP‐dependent pseudomonas exotoxin translocation from a late recycling compantiment in the lymphocyte intoxication procedure

Pseudomonas exotoxin (PE) is a cytotoxin which, after endocytosis, is delivered to the cytosol where it inactivates protein synthesis. Using diaminobenzidine cytochemistry, we found over 94% of internalized PE in transferrin (Tf) -positive endosomes of lymphocytes. When PE translocation was examined in a cell-free assay using purified endocytic vesicles, more than 40% of endosomal 125I-labeled PE was transported after 2 h at 37°C, whereas a toxin inactivated by point mutation in its translocation domain was not translocated. Sorting of endosomes did not allow cell-free PE translocation, whereas active PE transmembrane transport was observed after . 10 min of endocytosis when PE and fluorescent-Tf were localized by confocal immunofluorescence microscopy within a rab5-positive and rab4and rab7-negative recycling compartment in the pericentriolar region of the cell. Accordingly, when PE delivery to this structure was inhibited using a 20°C endocytosis temperature, subsequent translocation from purified endosomes was impaired. Translocation was also inhibited when endosomes were obtained from cells labeled with PE in the presence of brefeldin A, which caused fusion of translocationcompetent recycling endosomes with translocation-incompetent sorting elements. No PE processing was observed in lymphocyte endosomes, the full-sized toxin was translocated and recovered in an enzymatically active form. ATP hydrolysis was found to directly provide the energy required for PE translocation. Inhibitors of endosome acidification (weak bases, protonophores, or bafilomycin A1) when added to the assay did not significantly affect 125I-labeled PE translocation, demonstrating that this transport is independent of the endosome-cytosol pH gradient. Nevertheless, when 125I-labeled PE endocytosis was performed in the presence of one of these molecules, translocation from endosomes was strongly inhibited, indicating that exposure to acidic pH is a prerequisite for PE membrane traversal. When applied during endocytosis, treatments that protect cells against PE intoxication (low temperatures, inhibitors of endosome acidification, and brefeldin A) impaired 125I-labeled PE translocation from purified endosomes. We conclude that PE translocation from a late receptor recycling compartment is implicated in the lymphocyte intoxication procedure.

Phospholipids in Platelets: Localization, Movement and Physiological Function

Hemostasis is the control of blood circulation in vessels by a very complex and fast cascade of proteolytic reactions. In the case of vascular lesions, a major activator complex is formed between tissue factor (TF) and factor VII. At the same time, platelets adhering to subendothelial components secrete their granule contents and activate other platelets in a chain reaction. These platelets aggregate in turn while their plasma membrane rapidly becomes able to bind coagulating factors (VIIIa-IXa in tenase complex; VA-Xa in prothrombinase complex), essentially through their phosphatidylserine (PS) outer surface content. Finally, the procoagulant power of PS-containing membranes depends on their ability to assemble tenase and prothrombinase complexes and to protect activated factors against endogenous anticoagulating factors (Mann et al., 1990).

Protein-Lipid and Lipid-Lipid interactions in model systems and in biological membranes

A good indication for the importance of lipids is that cells need a huge amount of different lipids in strictly regulated location and composition. Essentially, the cell membranes fulfil 5 essential functions: acting as a semi permeable frontier with respect to ions, metabolites, peptides, proteins and larger assemblies; participating in cell organization and motion by bending, fusion and budding processes; solvating hydrophobic parts of integral proteins, stabilizing them in native conformation and correct lateral organization; interacting with extrinsic proteins in order to regulate their enzymatic activity or their binding and aggregation properties; stocking metabolites (fatty acids such as arachidonic acid, alkyl phospholipids, diacyl glyeerol, inositol phosphates…).