Docking, not fusion, as the rate-limiting step in a SNARE-driven vesicle fusion assay

In vitro vesicle fusion assays that monitor lipid mixing between t-SNARE and v-SNARE vesicles in bulk solution exhibit remarkably slow fusion on the nonphysiological timescale of tens of minutes to several hours. Here, single-vesicle, fluorescence resonance energy transfer-based assays cleanly separate docking and fusion steps for individual vesicle pairs containing full-length SNAREs. Docking is extremely inefficient and is the rate-limiting step. Of importance, the docking and fusion kinetics are comparable in the two assays (one with v-SNARE vesicles tethered to a surface and the other with v-SNARE vesicles free in solution). Addition of the V_C peptide synaptobrevin-2 (syb(57–92)) increases the docking efficiency by a factor of ∼30, but docking remains rate-limiting. In the presence of V_C peptide, the fusion step occurs on a timescale of ∼10 s. In previous experiments involving bulk fusion assays in which the addition of synaptotagmin/Ca²⁺, Munc-18, or complexin accelerated the observed lipid-mixing rate, the enhancement may have arisen from the docking step rather than the fusion step.     

Secretory vesicle cholesterol: Correlating lipid domain organization and Ca2 + triggered fusion

Membrane organization has received substantial research interest since the degree of ordering in membrane regions is relevant in many biological processes. Here we relate the impact of varying cholesterol concentrations on native secretory vesicle fusion and the lateral domain organization of membrane extracts from these vesicles. Membranes of isolated cortical secretory vesicles were either depleted of cholesterol, had cholesterol loaded to excess of native levels, or were depleted of cholesterol but subsequently reloaded to restore native cholesterol levels. Lipid analyses confirmed cholesterol was the only species significantly altered by these treatments. Treated vesicles were characterized for their ability to undergo fusion. Cholesterol depletion resulted in a decrease of Ca^2 + sensitivity and the extent of fusion, while cholesterol loading had no effect on fusion parameters. Membrane extracts were characterized in terms of lipid packing by surface pressure–area isotherms whereas the lateral membrane organization was analyzed by Brewster angle microscopy. While no differences in the isotherms were observed, imaging revealed drastic differences in domain size, shape and frequency between the various conditions. Cholesterol depletion induced larger but fewer domains, suggesting that domain coalescence into larger structures may disrupt the native temporal–spatial organization of the fusion machinery and thus inhibit vesicle docking, priming, and fusion. In contrast, adding excess cholesterol, or rescuing with exogenous cholesterol after sterol depletion, resulted in more but smaller domains. Therefore, cholesterol is an important membrane organizer in the process of Ca^2 + triggered vesicular fusion, which can be related to specific physical effects on native membrane substructure.     

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⁺).     

The rate of fusion of phospholipid vesicles and the role of bilayer curvature

Kinetics of Ca²⁺-induced fusion of phosphatidylserine vesicles is studiied for lipid concentrations varying from 1 μM to 100 μM. Fusion is monitored by mixing of aqueous vesicle contents and by explicitly accounting for leakage. The analysis provides separately rates of aggregation and fusion. The rate of fusion per se decreases steeply with vesicle size.     

Effects of divalent ions on vesicle-vesicle fusion studied by a new luminescence assay for fusion

Summary A new assay has been developed for vesicle-vesicle fusion based upon the mixing of intravesicular contents of two sets of vesicles. Purified firefly luciferase and MgCl₂ were incorporated into one set of vesicles (LV) and ATP into the other (AV). Vesicles were prepared from soybean phospholipids. The luminescence that resulted from hydrolysis of ATP by luciferase was measured to determine the extent of mixing of the intravesicular contents. In the absence of divalent ions, incubation of a mixture of LV and AV did not produce luminescence. However, if Ca⁺⁺ or other divalent ions were present at millimolar concentrations, luminescence occurred. The luminescence did not result from extravesicular reaction of vesicle contents that had leaked into the medium. Instead, luminescence resulted from the mixing of intravesicular spaces of AV and LV in fused vesicles. Optical density changes and negative stain electron microscopy indicated that Ca⁺⁺ induced extensive aggregation of vesicles. However, quantitation of the maximum possible luminescence indicates that only a small percentage (less than 1%) of the vesicles actually fused in a fusion experiment.Addition of EDTA to chelate Ca⁺⁺ after luminescence had been induced resulted in a two-to threefoldincrease in light emission which then rapidly decayed. These results suggest that the sudden removal of Ca⁺⁺ caused a transient increase in fusion after which subsequent fusion was inhibited. It was also found that the vesicles were relatively stable to hypotonic solutions.     

Ca-induced fusion of cardiolipin/phosphatidylcholine vesicles monitored by mixing of aqueous contents

The kinetics of Ca²⁺-induced fusion of large (0.1 μm) unilamellar cardiolipin/phosphatidylcholine (1:1) vesicles have been investigated by continuous monitoring of the mixing of the aqueous vesicle contents. In parallel, release of vesicle contents to the external medium has been followed. Initial fusion of the vesicles is non-leaky, release of vesicle contents being largely a secondary phenomenon. The minimal Ca²⁺ concentration required for fusion in this system is approx. 9 mM. At higher Ca²⁺ concentrations fusion is extremely fast, occurring on the time scale of seconds.     

Leakage-free membrane fusion induced by the hydrolytic activity of PlcHR2, a novel phospholipase C/sphingomyelinase from Pseudomonas aeruginosa

PlcHR₂ is the paradigm member of a novel phospholipase C/phosphatase superfamily, with members in a variety of bacterial species. This paper describes the phospholipase C and sphingomyelinase activities of PlcHR₂ when the substrate is in the form of large unilamellar vesicles, and the subsequent effects of lipid hydrolysis on vesicle and bilayer stability, including vesicle fusion. PlcHR₂ cleaves phosphatidylcholine and sphingomyelin at equal rates, but is inactive on phospholipids that lack choline head groups. Calcium in the millimolar range does not modify in any significant way the hydrolytic activity of PlcHR₂ on choline-containing phospholipids. The catalytic activity of the enzyme induces vesicle fusion, as demonstrated by the concomitant observation of intervesicular total lipid mixing, inner monolayer-lipid mixing, and aqueous contents mixing. No release of vesicular contents is detected under these conditions. The presence of phosphatidylserine in the vesicle composition does not modify significantly PlcHR₂-induced liposome aggregation, as long as Ca²⁺ is present, but completely abolishes fusion, even in the presence of the cation. Each of the various enzyme-induced phenomena have their characteristic latency periods, that increase in the order lipid hydrolysis < vesicle aggregation < total lipid mixing < inner lipid mixing < contents mixing. Concomitant measurements of the threshold diacylglyceride + ceramide concentrations in the bilayer show that late events, e.g. lipid mixing, require a higher concentration of PlcHR₂ products than early ones, e.g. aggregation. When the above results are examined in the context of the membrane effects of other phospholipid phosphocholine hydrolases it can be concluded that aggregation is necessary, but not sufficient for membrane fusion to occur, that diacylglycerol is far more fusogenic than ceramide, and that vesicle membrane permeabilization occurs independently from vesicle fusion.     

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     

Control of membrane fusion by phospholid head groups I. Phosphatidate/phosphatidylinositol specificity

We have studied the characteristics of fusion of large unilamellar vesicles composed of phosphatidate and phosphatidylinositol alone and in mixtures with other naturally occurring phospholipids. Fusion was induced by the addition of Ca²⁺ or Mg²⁺ and was monitored by detecting the mixing of aqueous vesicle contents. Release of vesicle contents was measured by dequenching of carboxyfluorescein fluorescence. Aggregation was monitored by 90° light scattering. The results indicated striking differences with respect to the fusion capacity of the different vesicles. Phosphatidate vesicles fuse in the presence of both Ca²⁺ and Mg²⁺ at threshold concentration ranges of 0.03–0.1 mM (Ca²⁺) and 0.07–0.15 mM (Mg²⁺) depending on the pH of the medium, 8.5-6.0, respectively. In contrast, phosphatidylinositol vesicles do not fuse with either Ca²⁺ or Mg²⁺ even at 50 mM concentrations, in spite of aggregation induced by both cations in the range of 5–10 mM. A large difference in terms of fusion capacity is retained even when these two phospholipids are mixed with phosphatidylserine, phosphatidylethanolamine and phosphatidylcholine in 2 : 2 : 4 : 2 molar ratios. The results are discussed in terms of the molecular mechanism of membrane fusion and the possible role of the metabolic interconversion of phosphatidylinositol to phosphatidate as an on-off control system for membrane fusion phenomena involved in secretion.     

Ca2+-induced fusion of cardiolipin/phosphatidylcholine vesicles monitored by mixing of aqueous contents

The kinetics of Ca²⁺-induced fusion of large (0.1 μm) unilamellar cardiolipin/phosphatidylcholine (1:1) vesicles have been investigated by continuous monitoring of the mixing of the aqueous vesicle contents. In parallel, release of vesicle contents to the external medium has been followed. Initial fusion of the vesicles is non-leaky, release of vesicle contents being largely a secondary phenomenon. The minimal Ca²⁺ concentration required for fusion in this system is approx. 9 mM. At higher Ca²⁺ concentrations fusion is extremely fast, occurring on the time scale of seconds.     

Studies on membrane fusion. III. The role of calcium-induced phase changes

The interaction of phosphatidylserine vesicles with Ca²⁺ and Mg²⁺ has been examined by several techniques to study the mechanism of membrane fusion. Data are presented on the effects of Ca²⁺ and Mg²⁺ on vesicle permeability, thermotropic phase transitions and morphology determined by differential scanning calorimetry, X-ray diffraction, and freeze-fracture electron microscopy. These data are discussed in relation to information concerning Ca²⁺ binding, charge neutralization, molecular packing, vesicle aggregation, phase transitions, phase separations and vesicle fusion.The results indicate that at Ca²⁺ concentrations of 1.0–2.0 mM, a highly cooperative phenomenon occurs which results in increased vesicle permeability, aggregation and fusion of the vesicles. Under these conditions the hydrocarbon chains of the lipid bilayers undergo a phase change from a fluid to a crystalline state. The aggregation of vesicles that is observed during fusion is not sufficient in itself to induce fusion without a concomitant phase change. Mg²⁺ in the range of 2.0–5.0 mM induces aggregation of phosphatidylserine vesicles but no significant fusion nor a phase change.From the effect of variations in pH, temperature, Ca²⁺ and Mg²⁺ concentration on the fusion of vesicles, it is concluded that the key event leading to vesicle membrane fusion is the isothermic phase change induced by the bivalent metals. It is proposed that this phase change induces a transient destabilization of the bilayer membranes that become susceptible to fusion at domain boundaries.     

Resident CAPS on dense-core vesicles docks and primes vesicles for fusion

The Ca²⁺-dependent exocytosis of dense-core vesicles in neuroendocrine cells requires a priming step during which SNARE protein complexes assemble. CAPS (aka CADPS) is one of several factors required for vesicle priming; however, the localization and dynamics of CAPS at sites of exocytosis in live neuroendocrine cells has not been determined. We imaged CAPS before, during, and after single-vesicle fusion events in PC12 cells by TIRF micro­scopy. In addition to being a resident on cytoplasmic dense-core vesicles, CAPS was present in clusters of approximately nine molecules near the plasma membrane that corresponded to docked/tethered vesicles. CAPS accompanied vesicles to the plasma membrane and was present at all vesicle exocytic events. The knockdown of CAPS by shRNA eliminated the VAMP-2–dependent docking and evoked exocytosis of fusion-competent vesicles. A CAPS(ΔC135) protein that does not localize to vesicles failed to rescue vesicle docking and evoked exocytosis in CAPS-depleted cells, showing that CAPS residence on vesicles is essential. Our results indicate that dense-core vesicles carry CAPS to sites of exocytosis, where CAPS promotes vesicle docking and fusion competence, probably by initiating SNARE complex assembly.     

Cholesterol affects divalent cation-induced fusion and isothermal phase transitions of phospholipid membranes

The influence of cholesterol on divalent cation-induced fusion and isothermal phase transitions of large unilamellar vesicles composed of phosphatidylserine (PS) was investigated. Vesicle fusion was monitored by the terbium/dipicolinic acid assay for the intermixing of internal aqueous contents, in the temperature range 10–40°C. The fusogenic activity of the cations decreases in the sequence Ca²⁺ > Ba²⁺ > Sr²⁺ Mg²⁺ for cholesterol concentrations in the range 20–40 mol%, and at all temperatures. Increasing the cholesterol concentration decreases the initial rate of fusion in the presence of Ca²⁺ and Ba²⁺ at 25°C, reaching about 50% of the rate for pure PS at a mole fraction of 0.4. From 10 to 25°C, Mg²⁺ is ineffective in causing fusion at all cholesterol concentrations. However, at 30°C, Mg²⁺-induced fusion is observed with vesicles containing cholesterol. At 40°C, Mg²⁺ induces slow fusion of pure PS vesicles, which is enhanced by the presence of cholesterol. Increasing the temperature also causes a monotonic increase in the rate of fusion induced by Ca²⁺, Ba²⁺ and Sr²⁺. The enhancement of the effect of cholesterol at high temperatures suggests that changes in hydrogen bonding and interbilayer hydration forces may be involved in the modulation of fusion by cholesterol. The phase behavior of PS/cholesterol membranes in the presence of Na⁺ and divalent cations was studied by differential scanning calorimetry. The temperature of the gel-liquid crystalline transition (T_m) in Na⁺ is lowered as the cholesterol content is increased, and the endotherm is broadened. Addition of divalent cations shifts the T_m upward, with a sequence of effectiveness Ba²⁺ > Sr²⁺ > Mg²⁺. The T_m of these complexes decreases as the cholesterol content is increased. Although the transition is not detectable for cholesterol concentrations of 40 and 50 mol% in the presence of Na⁺, Sr²⁺ or Mg²⁺, the addition of Ba²⁺ reveals endotherms with T_m progressively lower than that observed at 30 mol%. Although the presence of cholesterol appears to induce an isothermal gel-liquid crystalline transition by decreasing the T_m, this change in membrane fluidity does not enhance the rate of fusion, but rather decreases it. The effect of cholesterol on the fusion of PS/phosphatidylethanolamine (PE) vesicles was investigated by utilizing a resonance energy transfer assay for lipid mixing. The initial rate of fusion of PS/PE and PS/PE/cholesterol vesicles is saturated at high Mg²⁺ concentrations. With Ca²⁺, saturation is not observed for cholesterol-containing vesicles. The highest rate of fusion for both Ca²⁺- and Mg²⁺-induced fusion is observed with vesicles containing 30 mol% cholesterol.     

Interactive, computer-assisted tracking of speckle trajectories in fluorescence microscopy: application to actin polymerization and membrane fusion

Analysis of particle trajectories in images obtained by fluorescence microscopy reveals biophysical properties such as diffusion coefficient or rates of association and dissociation. Particle tracking and lifetime measurement is often limited by noise, large mobilities, image inhomogeneities, and path crossings. We present Speckle TrackerJ, a tool that addresses some of these challenges using computer-assisted techniques for finding positions and tracking particles in different situations. A dynamic user interface assists in the creation, editing, and refining of particle tracks. The following are results from application of this program: 1), Tracking single molecule diffusion in simulated images. The shape of the diffusing marker on the image changes from speckle to cloud, depending on the relationship of the diffusion coefficient to the camera exposure time. We use these images to illustrate the range of diffusion coefficients that can be measured. 2), We used the program to measure the diffusion coefficient of capping proteins in the lamellipodium. We found values ∼0.5 μm²/s, suggesting capping protein association with protein complexes or the membrane. 3), We demonstrate efficient measuring of appearance and disappearance of EGFP-actin speckles within the lamellipodium of motile cells that indicate actin monomer incorporation into the actin filament network. 4), We marked appearance and disappearance events of fluorescently labeled vesicles to supported lipid bilayers and tracked single lipids from the fused vesicle on the bilayer. This is the first time, to our knowledge, that vesicle fusion has been detected with single molecule sensitivity and the program allowed us to perform a quantitative analysis. 5), By discriminating between undocking and fusion events, dwell times for vesicle fusion after vesicle docking to membranes can be measured.     

Phosphatidylinositol 4,5-bisphosphate regulation of SNARE function in membrane fusion mediated by CAPS

Ca²⁺-triggered vesicle exocytosis in neuroendocrine cells requires priming reactions that follow vesicle tethering/docking and precede triggered fusion. Priming requires PI(4,5)P₂ and priming factors, and likely involves SNARE protein complex assembly. In studies with proteoliposomes, the priming factor CAPS interacts with PI(4,5)P₂, binds the SNARE protein syntaxin-1, promotes trans SNARE complex formation, and stimulates PI(4,5)P₂- and SNARE-dependent liposome fusion. We propose that CAPS functions in priming vesicle exocytosis by coupling membrane binding to SNARE complex assembly.     

Studies on the mechanism of membrane fusion. Role of head-group composition in calcium- and magnesium-induced fusion of mixed phospholipid vesicles

We have investigated the contribution of various phospholipids to membrane fusion induced by divalent cations. Fusion was followed by means of a new fluorescence assay monitoring the mixing of internal aqueous contents of large (0.1 μm diameter) unilamellar liposomes. The rate and extent of fusion induced by Ca²⁺ in mixed phosphatidylserine/phosphatidylcholine vesicles were lower compared to those in pure phosphatidylserine vesicles. The presence of 50% phosphatidylcholine completely inhibited fusion, although the vesicles aggregated upon Ca²⁺ addition. When phosphatidylserine was mixed with phosphatidylethanolamine, however, rapid fusion could be induced by Ca²⁺ even in mixtures that contained only 25% phosphatidylserine. Phosphatidylethanolamine also facilitated fusion by Mg²⁺ which could not fuse pure phosphatidylserine vesicles. In phosphatidylserine/phosphatidylethanolamine/phosphatidylcholine mixtures, in which the phosphatidylcholine content was kept at 25%, phosphatidylethanolamine could not substitute for phosphatidylserine, and the fusogenic capacity of Mg²⁺ was abolished by the presence of merely 10% phosphatidylcholine. The initial rate of release of vesicle contents was slower than the rate of fusion in all the mixtures used. The presence of phosphate effected a considerable decrease in the threshold concentration of Ca²⁺ and also enhanced     

SNARE and regulatory proteins induce local membrane protrusions to prime docked vesicles for fast calcium‐triggered fusion

Synaptic vesicles fuse with the plasma membrane in response to Ca²⁺ influx, thereby releasing neurotransmitters into the synaptic cleft. The protein machinery that mediates this process, consisting of soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors (SNAREs) and regulatory proteins, is well known, but the mechanisms by which these proteins prime synaptic membranes for fusion are debated. In this study, we applied large‐scale, automated cryo‐electron tomography to image an in vitro system that reconstitutes synaptic fusion. Our findings suggest that upon docking and priming of vesicles for fast Ca²⁺‐triggered fusion, SNARE proteins act in concert with regulatory proteins to induce a local protrusion in the plasma membrane, directed towards the primed vesicle. The SNAREs and regulatory proteins thereby stabilize the membrane in a high‐energy state from which the activation energy for fusion is profoundly reduced, allowing synchronous and instantaneous fusion upon release of the complexin clamp.     

Docking and fast fusion of synaptobrevin vesicles depends on the lipid compositions of the vesicle and the acceptor SNARE complex-containing target membrane

The influence of the lipid environment on docking and fusion of synaptobrevin 2 (Syb2) vesicles with target SNARE complex membranes was examined in a planar supported membrane fusion assay with high time-resolution. Previously, we showed that approximately eight SNARE complexes are required to fuse phosphatidylcholine (PC) and cholesterol model membranes in ∼20 ms. Here we present experiments, in which phosphatidylserine (PS) and phosphatidylethanolamine (PE) were added to mixtures of PC/cholesterol in different proportions in the Syb2 vesicle membranes only or in both the supported bilayers and the Syb2 vesicles. We found that PS and PE both reduce the probability of fusion and that this reduction is fully accounted for by the lipid composition in the vesicle membrane. However, the docking efficiency increases when the PE content in the vesicle (and target membrane) is increased from 0 to 30%. The fraction of fast-activating SNARE complexes decreases with increasing PE content. As few as three SNARE complexes are sufficient to support membrane fusion when at least 5% PS and 10% PE are present in both membranes or 5% and 30% PE are present in the vesicle membrane only. Despite the smaller number of required SNAREs, the SNARE activation and fusion rates are almost as fast as previously reported in reconstituted PC/cholesterol bilayers, i.e., of 10 and ∼20 ms, respectively.     

Membrane fusion of secretory vesicles and liposomes Two different types of fusion

Secretory vesicles isolated from adrenal medulla were found to fuse in vitro in response to incubation with Ca²⁺. Intervesicular fusion was detected by electron microscopy and was indicated by the appearance of twinned vesicles in freeze-fractured suspensions of vesicles and in thin-sectioned pellet. Two types of fusion could be distinguished: Type I, occurring between 10^?7 M and 10^?4 M Ca²⁺, was specific for Ca²⁺, was inhibited by other divalent cations and was abolished by pretreatment of vesicles with glutaraldehyde, neuraminidase or trypsin. Fusion type I was linear with temperature. A second type of intervesicular fusion was elicited by Ca²⁺ in concentrations higher than 2.5 mM and was morphologically characterized by multiple fusions of secretory vesicles. This type of fusion was found to be similar to fusion of liposomes prepared from the membrane lipids of adrenal medullary secretory vesicles: Ca²⁺ could be replaced by other divalent cations, the effect of different divalent cations was additive and pretreatments attacking membrane proteins were ineffective. Fusion type II of intact secretory vesicles as well as liposome fusion was discontinuous with temperature. Liposome fusion could be detected within 35 ms and persisted for 180 min. Using liposomes containing defined Ca²⁺ concentrations we have not found a major influence of Ca²⁺ asymmetry on fusion. Incorporation of the ganglioside GM₃, which is present in the membranes of intact adrenal medullary secretory vesicles did not change the properties of liposomes fusion. Using a Ca²⁺-selective electrode we have identified in secretory vesicle membranes both high affinity binding sites for Ca²⁺ ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}\text{= 1.6 · 10}{}^{\mathrm{?6}}\text{M}$) and low affinity sites ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}\text{= 1.2 · 10}{}^{\mathrm{?4}}\text{M}$).     

Productive hemifusion intermediates in fast vesicle fusion driven by neuronal SNAREs

An in vitro fusion assay uses fluorescence microscopy of labeled lipids to monitor single v-SNARE vesicle docking and fusion events on a planar lipid bilayer containing t-SNAREs. For vesicles and bilayer comprising phosphatidylcholine (POPC, 84-85% by mol) and phosphatidylserine (DOPS, 15% by mol), previous work demonstrated prompt, full fusion (τ_fus = 25 ms). Substitution of 20-60% phosphatidylethanolamine (DOPE) for phosphatidylcholine in the v-SNARE vesicle with either 0 or 20% DOPE included in the t-SNARE bilayer gives rise to hemifusion events. Labeled lipids diffuse into the planar bilayer as two temporally distinct waves, presumably hemifusion of the outer leaflet followed by inner leaflet (core) fusion. The fusion kinetics with DOPE is markedly heterogeneous. Some vesicle/docking site pairs exhibit prompt, full fusion while others exhibit hemifusion. Hemifusion events are roughly half productive (leading to subsequent core fusion within 20 s) and half dead-end. In qualitative accord with expectations from studies of protein-free vesicle-vesicle fusion, the hemifusion rate k_hemi is 15-20 times faster than the core fusion rate k_core, and the fraction of hemifusion events increases with increasing percentage of DOPE. This suggests similar underlying molecular pathways for protein-free and neuronal SNARE-driven fusion. Removal of phosphatidylserine from the v-SNARE vesicle has no effect on docking or fusion.