Biochemical and Functional Studies of Cortical Vesicle Fusion: The SNARE Complex and Ca2+ Sensitivity

Cortical vesicles (CV) possess components critical to the mechanism of exocytosis. The homotypic fusion of CV centrifuged or settled into contact has a sigmoidal Ca²⁺ activity curve comparable to exocytosis (CV–PM fusion). Here we show that Sr²⁺ and Ba²⁺ also trigger CV–CV fusion, and agents affecting different steps of exocytotic fusion block Ca²⁺, Sr²⁺, and Ba²⁺-triggered CV–CV fusion. The maximal number of active fusion complexes per vesicle, <n\>_Max, was quantified by NEM inhibition of fusion, showing that CV–CV fusion satisfies many criteria of a mathematical analysis developed for exocytosis. Both <n\>_Max and the Ca²⁺ sensitivity of fusion complex activation were comparable to that determined for CV–PM fusion. Using Ca²⁺-induced SNARE complex disruption, we have analyzed the relationship between membrane fusion (CV–CV and CV–PM) and the SNARE complex. Fusion and complex disruption have different sensitivities to Ca²⁺, Sr²⁺, and Ba²⁺, the complex remains Ca²⁺- sensitive on fusion-incompetent CV, and disruption does not correlate with the quantified activation of fusion complexes. Under conditions which disrupt the SNARE complex, CV on the PM remain docked and fusion competent, and isolated CV still dock and fuse, but with a markedly reduced Ca²⁺ sensitivity. Thus, in this system, neither the formation, presence, nor disruption of the SNARE complex is essential to the Ca²⁺-triggered fusion of exocytotic membranes. Therefore the SNARE complex alone cannot be the universal minimal fusion machine for intracellular fusion. We suggest that this complex modulates the Ca²⁺ sensitivity of fusion.     

Docking and fusion of synaptic vesicles in cell-free model system of exocytosis

The present study involves the testing and characterization of synaptic vesicle (SV) docking and fusion as the steps of exocytosis using two different approaches in vitro.The interaction of SVs was determined by the changing of particles size in suspensions by the method of dynamic light scattering (DLS). Fluorescence assay is represented for studying the mechanism of SV membrane fusion. The sizes of membrane particles were shown to increase in the medium containing cytoplasmic proteins of synaptosomes. Therefore, the cytosolic proteins are suggested to promote the SVs into close proximity where they may become stably bound or docked. The specific effect of synaptosomal cytosolic proteins on the interaction of SVs in the cell-free system was demonstrated. The incubation of SVs with liver cytosol proteins or in the bovine serum albumin solution did not lead to the enlargement of the particles size. The fusion reaction of the SVs membranes occurred within the micromolar range of Ca²⁺ concentrations. Our studies have shown that in vitro process of exocytosis can be divided into Ca²⁺-independent step, termed docking and followed by fusion step that is triggered by Ca²⁺. The role of cytosolic proteins of synaptosomes in docking and fusion of SVs in cell-free system was further confirmed.     

Docking and fusion of synaptic vesicles in cell-free model system of exocytosis

The present study involves the testing and characterization of synaptic vesicle (SV) docking and fusion as the steps of exocytosis using two different approaches in vitro.The interaction of SVs was determined by the changing of particles size in suspensions by the method of dynamic light scattering (DLS). Fluorescence assay is represented for studying the mechanism of SV membrane fusion. The sizes of membrane particles were shown to increase in the medium containing cytoplasmic proteins of synaptosomes. Therefore, the cytosolic proteins are suggested to promote the SVs into close proximity where they may become stably bound or docked. The specific effect of synaptosomal cytosolic proteins on the interaction of SVs in the cell-free system was demonstrated. The incubation of SVs with liver cytosol proteins or in the bovine serum albumin solution did not lead to the enlargement of the particles size. The fusion reaction of the SVs membranes occurred within the micromolar range of Ca²⁺ concentrations. Our studies have shown that in vitro process of exocytosis can be divided into Ca²⁺-independent step, termed docking and followed by fusion step that is triggered by Ca²⁺. The role of cytosolic proteins of synaptosomes in docking and fusion of SVs in cell-free system was further confirmed.     

Fusion of isolated synaptic vesicles as a model of the terminal stage of regulated exocytosis

In the study of membrane fusion, which is the terminal stage of exocytosis, we used a simplified model consisting of homotypic membranes of isolated synaptic vesicles (SV) obtained from the synaptosomal fraction of rat brain tissue. It was shown that fusion of SV develops in the presence of cytoplasmic proteins and 10^–7 to 10^–5 M Ca²⁺ ions. This conclusion was made based on changes in the intensity of fluorescence of a probe, R18. Calcium ions were found to be the most effective activators of the membrane fusion when the effects of bivalent cations, Ca²⁺, Sr²⁺, and Ba²⁺, were compared. ATP induced membrane fusion both in the presence and in the absence of Ca²⁺, and the effects of ATP and Ca²⁺ were additive. These findings allow us to believe that there are factors in the system containing SV and soluble proteins of synaptosomes, which initiate fusion of the membranes under the influence of not only Ca²⁺ but also ATP. The intensity of Ca²⁺-dependent fusion of SV dropped after trypsin treatment, i.e., proteolysis resulted in modulation of the sensitivity of vesicular proteins and/or a change in their capability of evoking membrane fusion. Monoclonal antibodies against synaptotagmin and synaptobrevin inhibited fusion of SV, but only partly. Our results support the concept that Ca²⁺-regulated membrane fusion is possible without the involvement of the entire SNARE complex.Neirofiziologiya/Neurophysiology, Vol. 36, No. 4, pp. 272–280, July–August, 2004.This revised version was published online in April 2005 with a corrected cover date.     

Fusion of secretory vesicles isolated from rat liver

Summary Secretory vesicles isolated from rat liver were found to fuse after exposure to Ca²⁺. Vescle fusion is characterized by the occurrence of twinned vesicles with a continuous cleavage plane between two vesicles in freeze-fracture electron microscopy. The number of fused vesicles increases with increasing Ca²⁺-concentrations and is half maximal around 10^–6 m. Other divalent cations (Ba²⁺, Sr²⁺, and Mg²⁺) were ineffective. Mg²⁺ inhibits Ca²⁺-induced fusion. Therefore, the fusion of secretory vesiclesin vitro is Ca²⁺ specific and exhibits properties similar to the exocytotic process of various secretory cells.Various substances affecting secretionin vivo (microtubular inhibitors, local anethetics, ionophores) were tested for their effect on membrane fusion in our system.The fusion of isolated secretory vesicles from liver was found to differ from that of pure phospholipid membranes in its temperature dependence, in its much lower requirement for Ca²⁺, and in its Ca²⁺-specificity. Chemical and enzymatic modifications of the vesicle membrane indicate that glycoproteins may account for these differences.     

Specific lipids supply critical negative spontaneous curvature--an essential component of native Ca2+-triggered membrane fusion

The Ca²⁺-triggered merger of two apposed membranes is the defining step of regulated exocytosis. CHOL is required at critical levels in secretory vesicle membranes to enable efficient, native membrane fusion: CHOL-sphingomyelin enriched microdomains organize the site and regulate fusion efficiency, and CHOL directly supports the capacity for membrane merger by virtue of its negative spontaneous curvature. Specific, structurally dissimilar lipids substitute for CHOL in supporting the ability of vesicles to fuse: diacylglycerol, αT, and phosphatidylethanolamine support triggered fusion in CHOL-depleted vesicles, and this correlates quantitatively with the amount of curvature each imparts to the membrane. Lipids of lesser negative curvature than cholesterol do not support fusion. The fundamental mechanism of regulated bilayer merger requires not only a defined amount of membrane-negative curvature, but this curvature must be provided by molecules having a specific, critical spontaneous curvature. Such a local lipid composition is energetically favorable, ensuring the necessary “spontaneous” lipid rearrangements that must occur during native membrane fusion—Ca²⁺-triggered fusion pore formation and expansion. Thus, different fusion sites or vesicle types can use specific alternate lipidic components, or combinations thereof, to facilitate and modulate the fusion pore.     

Kinetics of Chloride-Bicarbonate Exchange Across the Human Red Blood Cell Membrane

We had previously shown that an influx of extracellular Ca²⁺ (Ca²⁺ _e ), though it occurs, is not strictly required for aminoethyldextran (AED)-triggered exocytotic membrane fusion in Paramecium. We now analyze, by quenched-flow/freeze-fracture, to what extent Ca²⁺ _e contributes to exocytotic and exocytosis-coupled endocytotic membrane fusion, as well as to detachment of ``ghosts' — a process difficult to analyze by any other method or in any other system. Maximal exocytotic membrane fusion (analyzed within 80 msec) occurs readily in the presence of [Ca<sup>2+</sup>] <sub>e</sub> ≥ 5 × 10<sup>−6</sup> m, while normally a [Ca<sup>2+</sup>] <sub>e</sub> = 0.5 mm is in the medium. A new finding is that exocytosis and endocytosis is significantly stimulated by increasing [Ca<sup>2+</sup>] <sub>e</sub> even beyond levels usually available to cells. Quenching of [Ca<sup>2+</sup>] <sub>e</sub> by EGTA application to levels of resting [Ca<sup>2+</sup>] <sub>i</sub> or slightly below does reduce (by ∼50%) but not block AED-triggered exocytosis (again tested with 80 msec AED application). This effect can be overridden either by increasing stimulation time or by readdition of an excess of Ca<sup>2+</sup> <sub>e</sub> . Our data are compatible with the assumption that normally exocytotic membrane fusion will include a step of rapid Ca<sup>2+</sup>-mobilization from subplasmalemmal pools (``alveolar sacs') and, as a superimposed step, a Ca²⁺-influx, since exocytotic membrane fusion can occur at [Ca²⁺] _e even slightly below resting [Ca²⁺] _i . The other important conclusion is that increasing [Ca²⁺] _e facilitates exocytotic and endocytotic membrane fusion, i.e., membrane resealing. In addition, we show for the first time that increasing [Ca²⁺] _e also drives detachment of ``ghosts' — a novel aspect not analyzed so far in any other system. According to our pilot calculations, a flush of Ca²⁺, orders of magnitude larger than stationary values assumed to drive membrane dynamics, from internal and external sources, drives the different steps of the exo-endocytosis cycle. Received: 27 September 1996/Revised: 11 February 1997     

Synaptobrevin N-terminally bound to syntaxin–SNAP-25 defines the primed vesicle state in regulated exocytosis

Rapid neurotransmitter release depends on the ability to arrest the SNAP receptor (SNARE)–dependent exocytosis pathway at an intermediate “cocked” state, from which fusion can be triggered by Ca²⁺. It is not clear whether this state includes assembly of synaptobrevin (the vesicle membrane SNARE) to the syntaxin–SNAP-25 (target membrane SNAREs) acceptor complex or whether the reaction is arrested upstream of that step. In this study, by a combination of in vitro biophysical measurements and time-resolved exocytosis measurements in adrenal chromaffin cells, we find that mutations of the N-terminal interaction layers of the SNARE bundle inhibit assembly in vitro and vesicle priming in vivo without detectable changes in triggering speed or fusion pore properties. In contrast, mutations in the last C-terminal layer decrease triggering speed and fusion pore duration. Between the two domains, we identify a region exquisitely sensitive to mutation, possibly constituting a switch. Our data are consistent with a model in which the N terminus of the SNARE complex assembles during vesicle priming, followed by Ca²⁺-triggered C-terminal assembly and membrane fusion.     

Studies on membrane fusion. II. Induction of fusion in pure phospholipid membranes by calcium ions and other divalent metals

The effect of divalent metals on the interaction and mixing of membrane components in vesicles prepared from acidic phospholipids has been examined using freeze-fracture electron microscopy and differential scanning calorimetry. Ca²⁺, and to a certain extent Mg²⁺, induce extensive mixing of vesicle membrane components and drastic structural rearrangements to form new membranous structures. In contrast to the mixing of vesicle membrane components in the absence of Ca²⁺ described in the accompanying paper which occurs via diffusion of lipid molecules between vesicles, mixing of membrane components induced by Ca²⁺ or Mg²⁺ results from true fusion of entire vesicles. There appears to be a “threshold” concentration at which Ca²⁺ and Mg²⁺ become effective in inducing vesicle fusion and the threshold concentration varies for different acidic phospholipid species. Different phospholipids also vary markedly in their relative responsiveness to Ca²⁺ and Mg²⁺, with certain phospholipids being much more susceptible to fusion by Ca²⁺ than Mg²⁺. Vesicle fusion induced by divalent cations also requires that the lipids of the interacting membranes be in a “fluid” state ($\text{T > T}{}_{\mathrm{c}}$). Fusion of vesicle membranes by Ca²⁺ and Mg²⁺ does not appear to be due to simple electrostatic charge neutralization. Rather the action of these cations in inducing fusion is related to their ability to induce isothermal phase transitions and phase separations in phospholipid membranes. It is suggested that under these conditions membranes become transiently susceptible to fusion as a result of changes in molecular packing and creation of new phase boundaries induced by Ca²⁺ (or Mg²⁺).     

Factors affecting the electrofusion efficiency ofPorphyra protoplasts

The effects of various factors on the electrofusion efficiencies ofPorphyra protoplasts were investigated. These factors were protoplast stabilizing reagents, divalent cations, membrane digestive enzymes and cold storage of the protoplasts. Fusion efficiencies were dependent on the concentrations of reagents used to adjust the osmotic pressure of the medium. With mannitol or sorbitol the maximum fusion efficiency (approximately 16%) was observed at concentrations of 0.6 to 0.7 M; glucose was less effective. Brief treatment of the protoplasts with pronase stimulated electrofusion, whereas treatment with proteinase K, trypsin, phospholipase C or lipase repressed fusion. The addition of Ca²⁺ at 10^-5 to 10^-4 M in the protoplast medium enhanced the fusion efficiency to approximately four times that of the non-treated control. Sr²⁺ and Co²⁺ also stimulated electrofusion, but less effectively than Ca²⁺. The fusion capacity of the protoplasts remained stable for about 3 h when kept on ice, but decreased gradually when left at room temperate.     

RIM‐binding proteins recruit BK‐channels to presynaptic release sites adjacent to voltage‐gated Ca2+‐channels

The active zone of presynaptic nerve terminals organizes the neurotransmitter release machinery, thereby enabling fast Ca²⁺‐triggered synaptic vesicle exocytosis. BK‐channels are Ca²⁺‐activated large‐conductance K⁺‐channels that require close proximity to Ca²⁺‐channels for activation and control Ca²⁺‐triggered neurotransmitter release by accelerating membrane repolarization during action potential firing. How BK‐channels are recruited to presynaptic Ca²⁺‐channels, however, is unknown. Here, we show that RBPs (for RIM‐binding proteins), which are evolutionarily conserved active zone proteins containing SH3‐ and FN3‐domains, directly bind to BK‐channels. We find that RBPs interact with RIMs and Ca²⁺‐channels via their SH3‐domains, but to BK‐channels via their FN3‐domains. Deletion of RBPs in calyx of Held synapses decreased and decelerated presynaptic BK‐currents and depleted BK‐channels from active zones. Our data suggest that RBPs recruit BK‐channels into a RIM‐based macromolecular active zone complex that includes Ca²⁺‐channels, synaptic vesicles, and the membrane fusion machinery, thereby enabling tight spatio‐temporal coupling of Ca²⁺‐influx to Ca²⁺‐triggered neurotransmitter release in a presynaptic terminal.     

Fusion of human erythrocytes induced by uranyl acetate and rare earth metals

Incubation of human erythrocytes with either uranyl ions (UO₂²⁺) or rare earth metals (La³⁺, Nd³⁺, Sm³⁺, Eu³⁺, Tb³⁺, Dy³⁺ and Yb³⁺) at 37°C for 30–45 min resulted in the fusion of erythrocytes. Redistribution of membrane-associated particles was observed using colloidal-iron charge labelling and freeze-fracture electron microscopy. The fusion of erythrocytes induced by these agents, unlike Ca²⁺, did not exhibit the absolute requirement for phosphate. Moreover, agglutination and fusion by these agents was observed in neuraminidase-treated erythrocytes in contrast to Ca²⁺- and phosphate-induced fusion. Inhibitors of intrinsic transglutaminase activity partially inhibited (35–45%) the fusion induced by UO₂²⁺ suggesting that cross-linking of membrane proteins results in protein-free areas of lipid where fusion may be initiated.     

Vesicular Calcium Regulates Coat Retention,Fusogenicity, and Size of Pre-Golgi Intermediates

The significance and extent of Ca²⁺ regulation of the biosynthetic secretory pathway have been difficult to establish, and our knowledge of regulatory relationships integrating Ca²⁺ with vesicle coats and function is rudimentary. Here, we investigated potential roles and mechanisms of luminal Ca²⁺ in the early secretory pathway. Specific depletion of luminal Ca²⁺ in living normal rat kidney cells using cyclopiazonic acid (CPA) resulted in the extreme expansion of vesicular tubular cluster (VTC) elements. Consistent with this, a suppressive role for vesicle-associated Ca²⁺ in COPII vesicle homotypic fusion was demonstrated in vitro using Ca²⁺ chelators. The EF-hand–containing protein apoptosis-linked gene 2 (ALG-2), previously implicated in the stabilization of sec31 at endoplasmic reticulum exit sites, inhibited COPII vesicle fusion in a Ca²⁺-requiring manner, suggesting that ALG-2 may be a sensor for the effects of vesicular Ca²⁺ on homotypic fusion. Immunoisolation established that Ca²⁺ chelation inhibits and ALG-2 specifically favors residual retention of the COPII outer shell protein sec31 on pre-Golgi fusion intermediates. We conclude that vesicle-associated Ca²⁺, acting through ALG-2, favors the retention of residual coat molecules that seem to suppress membrane fusion. We propose that in cells, these Ca²⁺-dependent mechanisms temporally regulate COPII vesicle interactions, VTC biogenesis, cargo sorting, and VTC maturation.     

Coupling of K+-gating and permeation with Ca2+ block in the Ca2+-Activated K+ channel inChara australis

Summary The patch-clamp technique is used here to investigate the kinetics of Ca²⁺ block in single high-conductance Ca²⁺-activated K⁺ channels. These channels are detected in the membrane surounding cytoplasmic drops fromChara australis, a membrane which originates from the tonoplast of the parent cell. The amplitudes and durations of single channel events are measured over a wide range of membrane potential (–300 to 200 mV). Ca²⁺ on either side of the channel reduces its K⁺ conductance and alters its ion-gating characteristics in a voltage-dependent manner. This Ca²⁺-induced attenuation of conductance is analyzed using the theory of diffusion-limited ion flow through pores. Interaction of external Ca²⁺ with the channel's ion-gating mechanism is examined in terms of a kinetic model for ion-gating that includes two voltage-dependent gating mechanisms. The kinetics of channel block by external Ca²⁺ indicates that (i) external Ca²⁺ binds at two sites, a superficial site and a deep site, located at 8 and 40% along the trans-pore potential difference, (ii) the external vestibule cannot be occupied by more than one Ca²⁺ or K⁺, and (iii) the kinetics of Ca²⁺ binding at the deep site is coupled with that of a voltage-dependent gate on the external side of the channel. Kinetics of channel block by internal Ca²⁺ indicates that more than one Ca²⁺ is involved.     

Control of membrane fusion by phospholipid head groups II. The role of phosphatidylethanolamine in mixtures with phosphatidate and phosphatidylinositol

Membrane fusion induced by Ca²⁺ and Mg²⁺ in large unilamellar vesicles composed of mixtures of phosphatidylethanolamine with phosphatidate and phosphatidylinositol was studied by means of a fluorescence assay for the intermixing of internal aqueous contents of the vesicles. The threshold concentrations of Ca²⁺ or Mg²⁺ required for fusion increased only moderately when up to 80 mol% phosphatidylethanolamine was included with phosphatidate at pH 7.4, but no fusion could be detected in vesicles containing 70 mol% phosphatidylcholine even at high concentrations of Ca²⁺ or Mg²⁺. Phosphatidate-phosphatidylethanolamine (1 : 4) vesicles could be induced to fuse by 0.1 mM Ca²⁺ in the presence of a Mg²⁺ concentration which alone was insufficient for fusion. When equimolar amounts of phosphatidylethanolamine was included with phosphatidylinositol, the vesicles were susceptible to fusion by Ca²⁺, although pure phosphatidylinositol vesicles themselves merely aggregate and do not fuse (Sundler, R. and Papahadjopoulos, D. (1981) Biochim. Biophys. Acta 649, 743–750, accompanying paper). The role of phosphatidylethanolamine acyl chains, and hence the possible involvement of the bilayer-hexagonal (H_II) transition in membrane fusion, was examined by the temperature dependence of Ca²⁺-induced fusion in phosphatidylinositol-dimyristoylphosphatidylethanolamine (1 : 1) vesicles. Fusion was strictly dependent on the gel-liquid crystalline transition of the mixture and not on the phase behavior of the phosphatidylethanolamines. Comparable fusion rates were obtained for both egg yolk phosphatidylethanolamine and dimyristoylphosphatidylethanolamine at 50°C. As the dimyristoylphosphatidylethanolamine does not convert to a non-bilayer phase in this temperature range, we conclude that the bilayer-hexagonal transition is not necessary for membrane fusion. We propose that the dehydration characteristics of the phospholipids and their metal ion complexes are the critical factors determining fusion suceptibility of phospholipid membranes.     

Phosphatidylserine Regulation of Ca2+-triggered Exocytosis and Fusion Pores in PC12 Cells

The synaptic vesicle protein synaptotagmin I (Syt I) binds phosphatidylserine (PS) in a Ca²⁺-dependent manner. This interaction is thought to play a role in exocytosis, but its precise functions remain unclear. To determine potential roles for Syt I-PS binding, we varied the PS content in PC12 cells and liposomes and studied the effects on the kinetics of exocytosis and Syt I binding in parallel. Raising PS produced a steeply nonlinear, saturating increase in Ca²⁺-triggered fusion, and a graded slowing of the rate of fusion pore dilation. Ca²⁺-Syt I bound liposomes more tightly as PS content was raised, with a steep increase in binding at low PS, and a further gradual increase at higher PS. These two phases in the PS dependence of Ca²⁺-dependent Syt I binding to lipid may correspond to the two distinct and opposing kinetic effects of PS on exocytosis. PS influences exocytosis in two ways, enhancing an early step leading to fusion pore opening, and slowing a later step when fusion pores dilate. The possible relevance of these results to Ca²⁺-triggered Syt I binding is discussed along with other possible roles of PS.     

Fusion of neurohypophyseal membranes in vitro

Freeze cleaving electron microscopy has shown that fusion of isolated secretory vesicles from bovine neurohypophyses was induced by Ca²⁺ in micromolar concentrations. Mg²⁺ and Sr²⁺ were ineffective. Mg²⁺ inhibited Ca²⁺-induced fusion.In suspensions containing secretory vesicles as well as sheets of cell membrane, release of vasopressin parallel to intervesicular fusion of secretory vesicles with sheets of cell membrane was observed after exposure to Ca²⁺. Mg²⁺ and Sr²⁺ were ineffective in replacing Ca²⁺ as trigger for fusion or vasopressin release.Intervesicular fusion and exocytotic profiles were observed when isolated neurohypophyses or neurosecretosome were exposed to cold.     

Assay of dense-core vesicle exocytosis using permeabilized PC12 cells

Exocytosis plays an essential role in fundamental cellular events by secreting neurotransmitters, hormones, and cytokines. Although the minimal molecular components termed SNARE that govern membrane fusion have been identified, the precise mechanisms behind the finely-tuned regulation of exocytosis executed by many molecules in addition to the actions of SNARE remain to be fully identified. Here, we evaluated a model system for assaying catecholamine secretion from permeabilized rat pheochromocytoma PC12 cells, in which the structural integrity required was preserved adequately. Among several chemical reagents used for the cell permeabilization and freezing-thawing procedures, the treatment of cells with digitonin at concentrations of 7.5–15 μM was most suitable for the secretion assay, as it was considered to cause mild disruption of the plasma membrane, enabling free access to small molecules such as Ca²⁺ and ATP to the minimal membrane fusion machinery. No additional cytosolic proteins were required to reconstitute the secretion. In this assay model, ATP was necessary to maintain the priming state before Ca²⁺-triggered exocytosis but was not required for the Ca²⁺-triggered membrane fusion process itself. The present study provides a useful cell model for exploring novel molecules that may be implicated in exocytosis such as those playing regulatory roles in addition to the “minimal membrane fusion machinery for exocytosis”, which does not require any additional special apparatus.     

Fusion of phospholipid vesicles arrested by quick-freezing. The question of lipidic particles as intermediates in membrane fusion

We have examined the early events in Ca²⁺-induced fusion of large (0.2 μm diameter) unilamellar cardiolipin/phosphatidylcholine and phosphatidylserine/phosphatidylethanolamine vesicles by quick-freezing freeze-fracture electron microscopy, eliminating the necessity of using glycerol as a cryoprotectant. Freeze-fracture replicas of vesicle suspensions frozen after 1–2 s of stimulation revealed that the majority of vesicles had already undergone membrane fusion, as evidenced by dumbbell-shaped structures and large vesicles. In the absence of glycerol, lipidic particles or the hexagonal H_II phase, which have been proposed to be intermediate structures in membrane fusion, were not observed at the sites of fusion. Lipidic particles were evident in less than 5% of the cardiolipin/phosphatidylcholine vesicles after long-term incubation with Ca²⁺, and the addition of glycerol produced more vesicles displaying the particles. We have also shown that rapid fusion occurred within seconds of Ca²⁺ addition by the time-course of fluorescence emission produced by the intermixing of aqueous contents of two separate vesicle populations. These studies therefore have produced no evidence that lipidic particles are necessary intermediates for membrane fusion. On the contrary, they indicate that lipidic particles are structures obtained at equilibrium long after fusion has occurred and they become particularly prevalent in the presence of glycerol.     

The fusion of synaptic vesicle membranes studied by lipid mixing: the R18 fluorescence assay validity

The various experimental approaches and octadecyl rhodamine B chloride (R18) assay's capability to meet the criteria for examining the Ca²⁺dependent synaptic vesicles (SVs) fusion with target membranes have been investigated. The existence of at least two simultaneous processes one of which attributed to real Ca²⁺-dependent membrane fusion, while another is considered to be non-specific probe transfer has been shown. The differences in response to temperature changes were found for R18 fluorescence dequenching upon stimulation of membrane fusion or nonspecific probe transfer. The temperature dependences of the probe dequenching rate were the same for heterotypic and homotypic membrane systems and increased with the temperature growth. The combination of R18 fluorescence studies with the data obtained by dynamic light scattering (DLS) offers a unique opportunity for the determination of SVs aggregation and the membrane fusion. The cholesterol content of the synaptosomal plasma membrane was modulated by methyl-β-cyclodextrin (MCD). The MCD molecule has proven to bind directly the membrane cholesterol and interact with lipophilic probe R18 that affects its fluorescence. The obvious distinctions in probe dequenching due to the membrane mixing or the MCD effect were observed. The cholesterol depletion from the synaptosomal plasma membranes was found to inhibit the process of Ca²⁺-induced membrane fusion with SVs. Thus, the manipulations with conditions of R18 probe dequenching at the model conditions, specific for the Ca²⁺-triggered fusion steps of regulated exocytosis, allowed us to determine the relative contribution of probe transfer and genuine membrane fusion to the overall fluorescence signal.