Membrane Potential Mediates H+-ATPase Dependence of ``Degradative Pathway' Endosomal Fusion

In some epithelial cell lines, the uptake and degradation of proteins is so pronounced as to be regarded as a specialized function known as ``degradative endocytosis.' The endosomal pathways of the renal proximal tubule and the visceral yolk sac share highly specialized structures for ``degradative endocytosis.' These endosomal pathways also have a unique distribution of their H⁺-ATPase, predominantly in the subapical endosomal pathway. Previous studies provide only indirect evidence that H⁺-ATPases participate in endosomal fusion events: formation of vesicular intermediates between early and late endosomes is H⁺-ATPase dependent in baby hamster kidney cells, and H⁺-ATPase subunits bind fusion complex proteins in detergent extracts of fresh rat brain. To determine directly whether homotypic endosomal fusion is H⁺-ATPase dependent, we inhibited v-type H⁺-ATPase during flow cytometry and cuvette-based fusion assays reconstituting endosomal fusion in vitro. We report that homotypic fusion in subapical endosomes derived from rat renal cortex, and immortalized visceral yolk sac cells in culture, is inhibited by the v-type H⁺-ATPase specific inhibitor bafilomycin A1. Inhibition of fusion by H⁺-ATPase is mediated by the membrane potential as collapsing the pH gradient with nigericin had no effect on homotypic endosomal fusion, while collapsing the membrane potential with valinomycin inhibited endosomal fusion. Utilizing an in vitro reconstitution assay this data provides the first direct evidence for a role of v-type H⁺-ATPase in mammalian homotypic endosomal fusion. Received: 29 October 1996/Revised: 8 December 1997     

The Roles of Histidines and Charged Residues as Potential Triggers of a Conformational Change in the Fusion Loop of Ebola Virus Glycoprotein

Ebola virus (EBOV) enters cells from late endosomes/lysosomes under mildly acidic conditions. Entry by fusion with the endosomal membrane requires the fusion loop (FL, residues 507–560) of the EBOV surface glycoprotein to undergo a pH-dependent conformational change. To find the pH trigger for this reaction we mutated multiple conserved histidines and charged and uncharged hydrophilic residues in the FL and measured their activity by liposome fusion and cell entry of virus-like particles. The FL location in the membrane was assessed by NMR using soluble and lipid-bound paramagnetic relaxation agents. While we could not identify a single residue to be alone responsible for pH triggering, we propose that a distributed pH effect over multiple residues induces the conformational change that enhances membrane insertion and triggers the fusion activity of the EBOV FL.     

A Glycoprotein from Rat Liver Endoplasmic Reticulum Promotes Both Aggregation and Fusion of Liposomes at Acidic pH

Low-pH-induced fusion of liposomes with rat liver endoplasmic reticulum was evidenced. Fusion was inactivated by treatment of microsomes with trypsin or EEDQ (N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline), indicating the involvement of a protein. The protein was purified 555-fold by chromatographic steps. The identification and purification to homogeneity was obtained by electroelution from a slab gel, which gave a still active protein of about 50 kDa. The protein promoted the fusion of liposomes; laser light scattering showed an increase of mean radius of vesicles from 60 up to about 340 nm. Fusion was studied as mass action kinetics, describing the overall fusion as a two-step sequence of a second order aggregation followed by a first order fusion of liposomes. For phosphatidylcholine containing liposomes aggregation was not rate-limiting at pH 5.0 and fusion followed first order kinetics with a rate constant of 13 · 10⁻³ sec⁻¹. For phosphatidylethanolamine/phosphatidic acid liposomes aggregation was rate-limiting; however, the overall fusion was first order process, suggesting that fusogenic protein influences both aggregation and fusion of liposomes. The protein binds to the lipid bilayer of liposomes, independently of pH, probably by a hydrophobic segment. Exposed carboxylic groups might be able to trigger pH-dependent aggregation and fusion. It is proposed that the protein inserted in the lipid bilayer bridges with an adjacent liposome forming a fused doublet. Since at endoplasmic reticulum level proton pumps are operating to generate a low-pH environment, the membrane bound fusogenic protein may be responsible for both aggregation and fusion of neighboring membranes and therefore could operate in the exchange of lipidic material between intracellular membranes. Received: 25 August 1997/Revised: 28 April 1998     

Effects of Mutations in Proline 345 on Insertion of Diphtheria Toxin into Model Membranes

Translocation of the catalytic domain of diphtheria toxin (DT) across the endosomal membrane to the cytoplasm of mammalian cells requires the low-pH-dependent insertion of a hydrophobic helical hairpin (TH8-TH9) that is buried within the T domain of the native protein. Mutations of Pro345, which terminates helix TH8, have been reported to block toxicity for Vero cells. We found that mutant toxins in which Pro345 had been replaced by Cys, Glu, or Gly were profoundly defective at low pH in forming channels in planar phospholipid bilayers and in permeabilizing phospholipid vesicles to entrapped fluorophores. Experiments with isolated T domain containing a polarity-sensitive fluorophore attached to Cys at position 332 suggest that the P345E mutation blocks membrane insertion. None of the Pro345 mutations shifted the pH-dependence of binding in solution of the hydrophobic fluorophore, 2-p-toluidinyl-naphthalene 7-sulfonate. The results indicate that proline at position 345 is required for the T domain to insert into phospholipid bilayers or to adopt a functional conformation within the bilayer. Received: 23 July 1998/Revised: 19 October 1998     

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

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. Received: 3 August 1998/Revised: 15 October 1998     

Cell Surface Area Regulation and Membrane Tension

The beautifully orchestrated regulation of cell shape and volume are central themes in cell biology and physiology. Though it is less well recognized, cell surface area regulation also constitutes a distinct task for cells. Maintaining an appropriate surface area is no automatic side effect of volume regulation or shape change. The issue of surface area regulation (SAR) would be moot if all cells resembled mammalian erythrocytes in being constrained to change shape and volume using existing surface membrane. But these enucleate cells are anomalies, possessing no endomembrane. Most cells use endomembrane to continually rework their plasma membrane, even while maintaining a given size or shape. This membrane traffic is intensively studied, generally with the emphasis on targeting and turnover of proteins and delivery of vesicle contents. But surface area (SA) homeostasis, including the controlled increase or decrease of SA, is another of the outcomes of trafficking. Our principal aims, then, are to highlight SAR as a discrete cellular task and to survey evidence for the idea that membrane tension is central to the task. Cells cannot directly ``measure' their volume or SA, yet must regulate both. We posit that a homeostatic relationship exists between plasma membrane tension and plasma membrane area, which implies that cells detect and respond to deviations around a membrane tension set point. Maintenance of membrane strength during membrane turnover, a seldom-addressed aspect of SA dynamics, we examine in the context of SAR. SAR occurs in both animal and plant cells. The review shows the latter to be a continuing source of groundbreaking work on tension-sensitive SAR, but is principally slanted to animal cells. Received: 1 May 2000/Revised: 14 August 2000     

pH-Sensitive Liposomes

Abstract

pH sensitive liposomes are lipid compositions that can be destabilized when the external pH is changed; usually from a neutral or slightly alkaline pH to an acidic pH. They are designed to circumvent delivery of liposome contents to the lysosomes of cells following internalization of the vesicle via the endocytic pathway. In the majority of compositions, a lipid containing a pH titratable group is mixed with phosphatidylethanolamine containing unsaturated acyl chains in a molar ratio (pH sensitive component/PE) of 1/4 or greater. There are five major groups of phosphatidylethanolamine containing pH-senstive lipid compositions. These can be classified by their acid-titratable component: phospholipids, acylated amino acids, fatty acids, cholesterol derivatives and miscellaneous double chain amphiphiles. The biophysical mechanism of action involves a transition of the lipids from the lamellar phase to the hexagonal phase. In cell culture, pH sensitive vesicles can increase the delivery of fluorescent markers, proteins, cytotoxic compounds, RNA and DNA into the cytoplasm. The mechanism of delivery is suggested to involve the destabilization of the liposome in the endosome as the pH is reduced from 7.4 to 5.0 and subsequent destabilization of, or fusion with, the endosomal membrane; some of the liposome contents are introduced into the cytoplasm. In most cases, the extent of liposome contents delivery into the cytoplasm is less than 1% of the amount that becomes cell associated. However further studies, with more reliable assays to differentiate cytoplasmic from lysosomal delivery, are required to place an exact value on this efficiency. The efficiency of pH sensitive liposomes in vivo is limited by stability of certain of the liposome compositions in serum and targeting to the appropriate cell. Cholesterol hemisuccinate is a particularly attractive component for in vivo use since it stabilizes the liposome when in serum at pH 7.4. The use of pH sensitive liposomes in drug delivery should continue to expand due to the increasing number of macromolecular therapeutic agents with intracellular targets.     

Neuronal Plasma Membrane Dynamics Evoked by Osmomechanical Perturbations

When neurons swell and shrink they extensively reorganize their plasma membrane. A striking aspect of these membrane dynamics is the transient appearance of vacuole-like dilations (VLDs) which, counterintuitively, expand as the neurons shrink. Here, confocal microscopy of cultured molluscan (Lymnaea) neurons was used in conjunction with aqueous phase and membrane dyes to examine changing VLD membrane topology as VLDs form, reverse or recover. We show that VLDs start as discrete invaginations at the adherent surface, so VLD and plasma membranes are initially contiguous. Over the next few minutes VLDs expand and penetrate the cytoplasm. At the substratum, the mouths of VLDs develop into irregular annuli of motile adherent processes whereas deeper in the cytoplasm, VLD membrane profiles are smooth. Subsequently VLDs spontaneously shrink; as this recovery proceeds, constriction of the motile VLD mouth leads to the internalization of plasma membrane. Washout experiments with aqueous phase dyes demonstrated that VLD constriction yields bona fide vacuoles, i.e., membrane-bound compartments isolated from the external medium. VLDs can also be experimentally eliminated by returning cells to swelling conditions; this reversal process drives membrane back to the surface. VLD formation and reinternalization of VLD membrane can be seen as aspects of plasma membrane surface area regulation. We postulate that area adjustments, driven by regional membrane tension differences, become noticeable when excessive perturbations overload normal membrane reprocessing steps. Both the changes in VLD membrane topology, and previously established capacitance changes accompanying cell shrinking and swelling, argue that osmomechanically perturbed neurons regulate their surface area as their volume changes. Received: 13 May 1998/Revised: 18 September 1998     

Increased Activity of Calcium Leak Channels Caused by Proteolysis Near Sarcolemmal Ruptures

Dystrophin, a 427 kD membrane-associated structural protein in muscle cells, is thought to confer strength to the myofiber sarcolemma and protect the membrane from rupture during the stresses of contraction. Dystrophin is absent in muscle cells from Duchenne muscular dystrophy (DMD) patients and mdx mice, a DMD model. Dystrophic muscle membranes undergo more frequent transient, nonlethal tears than normal cell membranes, especially during exercise. In addition, the mean open probability of a background (``leak') calcium channel is higher in dystrophic muscle cells, which leads to higher intracellular free calcium levels. Because elevated calcium levels may contribute to the eventual necrosis of muscle cells in DMD, we examined the possibility that the history of sarcolemmal rupture at a specific location on the membrane affects the open probability of nearby calcium leak channels. Membrane ruptures left by the excision of cell-attached patch-clamp electrodes were used to mimic natural tears. Patches made within 5 microns of excision sites contained channels with a fourfold greater mean open probability than channels in patches 50 μm away from ruptures. The increased leak channel activity near ruptures was seen continuously through the duration of the recordings and was not seen if the rupture was made in the presence of the protease inhibitor leupeptin. Calcium background channels proteolytically activated near ruptures, perhaps in a calcium-dependent manner, may thus be the lasting consequence of the weaker dystrophic sarcolemma, leading to chronically raised intracellular free calcium, increased calcium-dependent proteolysis and, eventually, necrosis. Received: 29 November 1999/Revised: 13 April 2000     

Partners in Protection: Interdependence of Cytoskeleton and Plasma Membrane in Adaptations to Applied Forces

In mechanically active environments mammalian cells must cope with potentially injurious forces to survive, but the most proximal mechanosensors are largely unknown. How mechanoprotective responses to applied forces are generated and regulated is still a mystery. We consider recent evidence that suggests cellular mechanoprotective adaptations involve a coordinated remodeling of the cell membrane and the associated cytoskeleton. The plasma membrane ``protects' the cytoskeleton by maintenance of intracellular ionic balance and can modulate force-induced cytoskeletal rearrangements by stretch-activated (e.g., Ca²⁺) ion channels and mechanosensitive enzymes (e.g., Phospholipase A₂ and Phospholipase C). Conversely, the cytoskeleton protects the plasma membrane by providing structural support, reinforcement of the cortical framework at sites of force application, modulation of mechanosensitive ion channels and by potentially contributing to the membrane resealing process after mechanical rupture. We suggest that the plasma membrane and the cytoskeleton are partners in the cytoprotective response to physical forces. Received: 8 September 1999/Revised: 15 December 1999     

Directly Observed Membrane Fusion Between Oppositely Charged Phospholipid Bilayers

A novel method was developed for the direct examination of pairwise encounters between positively and negatively charged phospholipid bilayer vesicles. Giant bilayer vesicles (unilamellar, 4–20 μm in diameter) prepared from 1,2-dioleoyl-sn-glycero-3-ethylphosphocholine, a new cationic phospholipid derivative, were electrophoretically maneuvered into contact with individual anionic phospholipid vesicles. Fluorescence video microscopy revealed that such vesicles commonly underwent fusion within milliseconds (1 video field) after contact, without leakage. Fusion occurred at constant volume and, since flaccid vesicles were rare, the excess membrane was not available after fusion. Hemifusion (the outer monolayers of each vesicle fused while the inner monolayers remained intact) was inferred from membrane-bound dye transfer and a change in the contact area. Hemifusion was observed as a final stable state and as an intermediate to fusion of vesicles composed of charged phospholipids plus zwitterionic phospholipids. Hemifusion occurred in one of three ways following adhesion: either delayed with an abrupt increase in area of contact, immediately with a gradual increase in area of contact, or with retraction during which adherent vesicles dissociated from a flat contact to a point contact. Phosphatidylethanolamine strongly promoted immediate hemifusion; the resultant hemifused state was stable and seldom underwent complete fusion. Although sometimes single contacts between vesicles led to rupture of both, in other cases, a single vesicle underwent multiple fusion events. Direct observation has unequivocally demonstrated the fusion of two, isolated bilayer-bounded bodies to yield a stable, non-leaky product, as occurs in cells, in the absence of proteins. Received: 25 November 1998/Revised: 23 March 1999     

pH-Sensitive Gating Kinetics of the Maxi-K Channel in the Tonoplast of Chara australis

The most frequently observed K⁺ channel in the tonoplast of Characean giant internodal cells with a large conductance (ca. 170 pS; Lühring, 1986; Laver & Walker, 1987) behaves, although inwardly rectifying, like animal maxi-K channels. This channel is accessible for patch–clamp techniques by preparation of cytoplasmic droplets, where the tonoplast forms the membrane delineating the droplet. Lowering the pH of the bathing solution, that virtually mimicks the vacuolar environment, from an almost neutral level to values below pH 7, induced a significant but reversible decrease in channel activity, whereas channel conductance remained largely unaffected. Acidification (pH 5) on both sides of the membrane decreased open probability from a maximum of 80% to less than 20%. Decreasing pH at the cytosolic side inhibited channel activity cooperatively with a slope of 2.05 and a pK _a 6.56. In addition, low pH at the vacuolar face shifted the activating voltage into a positive direction by almost 100 mV. This is the first report about an effect of extraplasmatic pH on gating of a maxi-K channel. It is suggested that the Chara maxi-K channel possesses an S4-like voltage sensor and negatively charged residues in neighboring transmembrane domains whose S4-stabilizing function may be altered by protonation. It was previously shown that gating kinetics of this channel respond to cytosolic Ca²⁺ (Laver & Walker, 1991). With regard to natural conditions, pH effects are discussed as contributing mainly to channel regulation at the vacuolar membrane face, whereas at the cytosolic side Ca²⁺ affects the channel. An attempt was made to ascribe structural mechanisms to different states of a presumptive gating reaction scheme. Received: 8 May 1998/Revised: 18 September 1998     

MITO-Porter: A liposome-based carrier system for delivery of macromolecules into mitochondria via membrane fusion

Mitochondria are the principal producers of energy in higher cells. Mitochondrial dysfunction is implicated in a variety of human diseases, including cancer and neurodegenerative disorders. Effective medical therapies for such diseases will ultimately require targeted delivery of therapeutic proteins or nucleic acids to the mitochondria, which will be achieved through innovations in the nanotechnology of intracellular trafficking. Here we describe a liposome-based carrier that delivers its macromolecular cargo to the mitochondrial interior via membrane fusion. These liposome particles, which we call MITO-Porters, carry octaarginine surface modifications to stimulate their entry into cells as intact vesicles (via macropinocytosis). We identified lipid compositions for the MITO-Porter which promote both its fusion with the mitochondrial membrane and the release of its cargo to the intra-mitochondrial compartment in living cells. Thus, the MITO-Porter holds promise as an efficacious system for the delivery of both large and small therapeutic molecules into mitochondria.     

Induction of Cell-Cell Fusion by Ebola Virus Glycoprotein: Low pH Is Not a Trigger

Ebola virus (EBOV) is a highly pathogenic filovirus that causes hemorrhagic fever in humans and animals. Currently, how EBOV fuses its envelope membrane within an endosomal membrane to cause infection is poorly understood. We successfully measure cell-cell fusion mediated by the EBOV fusion protein, GP, assayed by the transfer of both cytoplasmic and membrane dyes. A small molecule fusion inhibitor, a neutralizing antibody, as well as mutations in EBOV GP known to reduce viral infection, all greatly reduce fusion. By monitoring redistribution of small aqueous dyes between cells and by electrical capacitance measurements, we discovered that EBOV GP-mediated fusion pores do not readily enlarge—a marked difference from the behavior of other viral fusion proteins. EBOV GP must be cleaved by late endosome-resident cathepsins B or L in order to become fusion-competent. Cleavage of cell surface-expressed GP appears to occur in endosomes, as evidenced by the fusion block imposed by cathepsin inhibitors, agents that raise endosomal pH, or an inhibitor of anterograde trafficking. Treating effector cells with a recombinant soluble cathepsin B or thermolysin, which cleaves GP into an active form, increases the extent of fusion, suggesting that a fraction of surface-expressed GP is not cleaved. Whereas the rate of fusion is increased by a brief exposure to acidic pH, fusion does occur at neutral pH. Importantly, the extent of fusion is independent of external pH in experiments in which cathepsin activity is blocked and EBOV GP is cleaved by thermolysin. These results imply that low pH promotes fusion through the well-known pH-dependent activity of cathepsins; fusion induced by cleaved EBOV GP is a process that is fundamentally independent of pH. The cell-cell fusion system has revealed some previously unappreciated features of EBOV entry, which could not be readily elucidated in the context of endosomal entry.     

The Role of Membrane Lateral Tension in Calcium-Induced Membrane Fusion

Calcium-induced fusion of liposomes was studied with a view to understand the role of membrane tension in this process. Lipid mixing due to fusion was monitored by following fluorescence of rhodamine-phosphatidyl-ethanolamine incorporated into liposomal membrane at a self-quenching concentration. The extent of lipid mixing was found to depend on the rate of calcium addition: at slow rates it was significantly lower than when calcium was injected instantly. The vesicle inner volume was then made accessible to external calcium by adding calcium ionophore A23187. No effect on fusion was observed at high rates of calcium addition while at slow rates lipid mixing was eliminated. Fusion of labeled vesicles with a planar phospholipid membrane (BLM) was studied using fluorescence microscopy. Above a threshold concentration specific for each ion, Ca²⁺, Mg²⁺, Cd²⁺ and La³⁺ induce fusion of both charged and neutral membranes. The threshold calcium concentration required for fusion was found to be dependent on the vesicle charge, but not on the BLM charge. Pretreatment of vesicles with ionophore and calcium inhibited vesicle fusion with BLM. This effect was reversible: chelation of calcium prior to the application of vesicle to BLM completely restored their ability to fuse. These results support the hypothesis that tension in the outer monolayer of lipid vesicle is a primary reason for membrane destabilization promoting membrane fusion. How this may be a common mechanism for both purely lipidic and protein-mediated membrane fusion is discussed. Received: 27 September 1999/Revised: 22 March 2000     

Citrate Uptake into Tonoplast Vesicles from Acid Lime (Citrus aurantifolia) Juice Cells

Citrate transport into the vacuoles of acid lime juice cells was investigated using isolated tonoplast vesicles. ATP stimulated citrate uptake in the presence or in the absence of a ΔμH⁺. Energization of the vesicles only by an artificial K⁺ gradient (establishing an inside-positive Δψ) also resulted in citrate uptake as was the case of a ΔpH dominated ΔμH⁺. Addition of inhibitors to endomembrane ATPases showed no direct correlation between the inhibition to the tonoplast bound H⁺/ATPase and citrate uptake. The data indicated that, although some citrate uptake can be accounted for by Δψ and by a direct primary active transport mechanism involving ATP, under in vivo conditions of vacuolar pH of 2.0, citrate uptake is driven by ΔpH. Received: 27 April 1998/Revised: 8 September 1998     

Photofrin II Sensitized Modifications of Ion Transport Across the Plasma Membrane of an Epithelial Cell Line: I. Electrical Measurements at the Whole-Cell Level

Photofrin II is a photosensitizer frequently applied in photodynamic therapy. Light-induced tumor cell inactivation observed in the presence of this substance has been suggested to start with modifications at the level of cellular membranes. In the present study electrophysiological techniques are applied in order to investigate the action of photofrin II on functional properties of the plasma membrane of opossum kidney (OK) cells (as an epithelial model system) and of fibroblasts. Illumination of the cells in the presence of photofrin II (or Zn-phthalocyanine) leads to comparatively fast depolarization of the membrane potential. It is caused by a strong change of the membrane conductance which proceeds in two phases. Both phases contribute to a loss of ion selectivity of the plasma membrane between K⁺ and Na⁺. In the first phase, specific pathways for K⁺, which determine the resting potential under physiological conditions, are inactivated. The second phase is distinguished by a marked increase of a nonselective conductance. The increase of the latter — after light-induced initiation — continues in the dark. The conclusions are derived from light-induced, time-dependent changes of the membrane conductance and of the shape of the current-voltage relationship detected under different experimental conditions. Received: 26 May 1998/Revised: 8 September 1998     

Lipid-Induced Organization of a Primary Amphipathic Peptide: A Coupled AFM-Monolayer Study

To better understand the nature of the mechanism involved in the membrane uptake of a vector peptide, the interactions between dioleoylphosphatidylcholine and a primary amphipathic peptide containing a signal peptide associated with a nuclear localization sequence have been studied by isotherms analysis of mixed monolayers spread at the air-water interface. The peptide and the lipid interact through strong hydrophobic interactions with expansion of the mean molecular area that resulted from a lipid-induced modification of the organization of the peptide at the interface. In addition, a phase separation occurs for peptide molar fraction ranging from about 0.08 to 0.4 Atomic force microscopy observations made on transferred monolayers confirm the existence of phase separation and further reveal that mixed lipid-peptide particles are formed, the size and shape of which depend on the peptide molar fraction. At low peptide contents, round-shaped particles are observed and an increase of the peptide amount, simultaneously to the lipidic phase separation, induces morphological changes from bowls to filamentous particles. Fourier transform infrared spectra (FTIR) obtained on transferred monolayers indicate that the peptide adopts a β-like structure for high peptide molar fractions. Such an approach involving complementary methods allows us to conclude that the lipid and the peptide have a nonideal miscibility and form mixed particles which phase separate. Received: 31 July 1998/Revised: 4 November 1998     

Fusion of Human Sperm to Prostasomes at Acidic pH

Prostasomes are membranous vesicles (150–200 nm diameter) present in human semen. They are secreted by the prostate and contain large amounts of cholesterol, sphingomyelin and Ca²⁺. In addition, some of their proteins are enzymes. Prostasomes enhance the motility of ejaculated spermatozoa and are involved in a number of additional biological functions. The possibility that they may fuse to sperm has never been proved. In this work, we studied the fusion of sperm to prostasomes by using various methods (relief of octadecyl Rhodamine B fluorescence self-quenching, fluorescence microscopy and flow cytometry) and we found that it occurs at acidic pH (4–5), but not at pH 7.5 pH-dependent fusion relies on the integrity of one or more proteins and is different from the Ca²⁺-stimulated fusion between rat liver liposomes and spermatozoa that does not require any protein and occurs at neutral pH. We think that the H⁺-dependent fusion of prostasomes to sperm may have physiological importance by modifying the lipid and protein pattern of sperm membranes. Received: 19 June 1996/Revised: 4 September 1996     

The Calculation of Intracellular Ion Concentrations and Membrane Potential from Cell-attached and Excised Patch Measurements. Cytosolic K+ Concentration and Membrane Potential in Vicia faba Guard Cells

Ion channel activity in cell-attached patch recordings shows channel behavior under more physiological conditions than whole-cell and excised patch measurements. Yet the analysis of cell-attached patch measurements is complicated by the fact that the system is ill defined with respect to the intracellular ion activities and the electrical potential actually experienced by the membrane patch. Therefore, of the several patch-clamp configurations, the information that is obtained from cell-attached patch measurements is the most ambiguous. The present study aims to achieve a better understanding of cell-attached patch measurements. Here we describe a method to calculate the intracellular ion concentration and membrane potential prevailing during cell-attached patch recording. The first step is an analysis of the importance of the input resistance of the intact cell on the cell-attached patch measurement. The second step, and actual calculation, is based on comparison of the single channel conductance and reversal potential in the cell-attached patch and excised patch configurations. The method is demonstrated with measurements of membrane potential and cytosolic K⁺ concentrations in Vicia faba guard cells. The approach described here provides an attractive alternative to the measurement of cytosolic ion concentrations with fluorescent probes or microelectrodes. Received: 3 April 1998/Revised: 6 August 1998