Imaging synaptic vesicle exocytosis and endocytosis with FM dyes

FM dyes have been used to label and then monitor synaptic vesicles, secretory granules and other endocytic structures in a variety of preparations. Here, we describe the general procedure for using FM dyes to study endosomal trafficking in general, and synaptic vesicle recycling in particular. The dye, dissolved in normal saline solution, is added to a chamber containing the preparation to be labeled. Stimulation evokes exocytosis, and compensatory endocytosis that follows traps FM dye inside the retrieved vesicles. The extracellular dye is then washed from the chamber, and labeled endocytic structures are examined with a fluorescence microscope. Fluorescence intensity provides a direct measure of the labeled vesicle number, a good measure of the amount of exocytosis. If the preparation is stimulated again, without dye in the chamber, dimming of the preparation provides a measure of exocytosis of labeled vesicles. With a synaptic preparation on hand, this protocol requires 1 day.     

Modulation of Synaptic Vesicle Exocytosis in Muscle-Dependent Long-Term Depression at the Amphibian Neuromuscular Junction

We have labeled recycling synaptic vesicles at the somatic Bufo marinus neuromuscular junction with the styryl dye FM2-10 and provide direct evidence for refractoriness of exocytosis associated with a muscle activity-dependent form of long-term depression (LTD) at this synapse. FM2-10 dye unloading experiments demonstrated that the rate of vesicle exocytosis from the release ready pool (RRP) of vesicles was more than halved in the LTD (induced by 20 min of low frequency stimulation). Recovery from LTD, observed as a partial recovery of nerve-evoked muscle twitch amplitude, was accompanied by partial recovery of the refractoriness of RRP exocytosis. Unexpectedly, paired pulse plasticity, another routinely used indicator of presynaptic forms of synaptic plasticity, was unchanged in the LTD. We conclude that the LTD induces refractoriness of the neuromuscular vesicle release machinery downstream of presynaptic calcium entry.     

A membrane marker leaves synaptic vesicles in milliseconds after exocytosis in retinal bipolar cells

Perhaps synaptic vesicles can recycle so rapidly because they avoid complete exocytosis, and release transmitter through a fusion pore that opens transiently. This view emerges from imaging whole terminals where the fluorescent lipid FM1-43 seems unable to leave vesicles during transmitter release. Here we imaged single, FM1-43-stained synaptic vesicles by evanescent field fluorescence microscopy, and tracked the escape of dye from single vesicles by watching the increase in fluorescence after exocytosis. Dye left rapidly and completely during most or all exocytic events. We conclude that vesicles at this terminal allow lipid exchange soon after exocytosis, and lose their dye even if they connected with the plasma membrane only briefly. At the level of single vesicles, therefore, observations with FM1-43 provide no evidence that exocytosis of synaptic vesicles is incomplete.     

Studying Synaptic Vesicle Pools using Photoconversion of Styryl Dyes

The fusion of synaptic vesicles with the plasma membrane (exocytosis) is a required step in neurotransmitter release and neuronal communication. The vesicles are then retrieved from the plasma membrane (endocytosis) and grouped together with the general pool of vesicles within the nerve terminal, until they undergo a new exo- and endocytosis cycle (vesicle recycling). These processes have been studied using a variety of techniques such as electron microscopy, electrophysiology recordings, amperometry and capacitance measurements. Importantly, during the last two decades a number of fluorescently labeled markers emerged, allowing optical techniques to track vesicles in their recycling dynamics. One of the most commonly used markers is the styryl or FM dye ¹; structurally, all FM dyes contain a hydrophilic head and a lipophilic tail connected through an aromatic ring and one or more double bonds (Fig. 1B). A classical FM dye experiment to label a pool of vesicles consists in bathing the preparation (Fig. 1Ai) with the dye during the stimulation of the nerve (electrically or with high K⁺). This induces vesicle recycling and the subsequent loading of the dye into recently endocytosed vesicles (Fig. 1A_i-iii). After loading the vesicles with dye, a second round of stimulation in a dye-free bath would trigger the FM release through exocytosis (Fig. 1A_iv-v), process that can be followed by monitoring the fluorescence intensity decrease (destaining). Although FM dyes have contributed greatly to the field of vesicle recycling, it is not possible to determine the exact localization or morphology of individual vesicles by using conventional fluorescence microscopy. For that reason, we explain here how FM dyes can also be used as endocytic markers using electron microscopy, through photoconversion. The photoconversion technique exploits the property of fluorescent dyes to generate reactive oxygen species under intense illumination. Fluorescently labeled preparations are submerged in a solution containing diaminobenzidine (DAB) and illuminated. Reactive species generated by the dye molecules oxidize the DAB, which forms a stable, insoluble precipitate that has a dark appearance and can be easily distinguished in electron microscopy ^2,3. As DAB is only oxidized in the immediate vicinity of fluorescent molecules (as the reactive oxygen species are short-lived), the technique ensures that only fluorescently labeled structures are going to contain the electron-dense precipitate. The technique thus allows the study of the exact location and morphology of actively recycling organelles.Open in a separate windowClick here to view.^{(49M, flv)}     

Spatial variability in release at the frog neuromuscular junction measured with FM1-43

We quantified the spatial variability in release properties at different synaptic vesicle clusters in frog motor nerve terminals, using a combination of fluorescence and electron microscopy. Individual synaptic vesicle clusters labeled with FM1-43 varied more than 10-fold in initial intensity (integrated FM1-43 fluorescence) and in absolute rate of dye loss during tetanic electrical nerve stimulation. Most of this variability arose because large vesicle clusters spanned more than one presynaptic active zone (inferred from postsynaptic acetylcholine receptor stripes labeled with rhodamine-conjugated alpha-bungarotoxin); when the rate of dye loss was normalized to the length of receptor stripe covered, variability from spot to spot was greatly reduced. In addition, electron microscopic measurements showed that large vesicle clusters (i.e., those spanning multiple active zones) were also thicker, and the increased depth of vesicles led to increased total spot fluorescence without a corresponding increase in the rate of dye loss during stimulation. These results did not reveal the presence of "hot zones" of secretory activity.     

Frequency-dependent kinetics and prevalence of kiss-and-run and reuse at hippocampal synapses studied with novel quenching methods

The kinetics of exo-endocytotic recycling could restrict information transfer at central synapses if neurotransmission were entirely reliant on classical full-collapse fusion. Nonclassical fusion retrieval by kiss-and-run would be kinetically advantageous but remains controversial. We used a hydrophilic quencher, bromophenol blue (BPB), to help detect nonclassical events. Upon stimulation, extracellular BPB entered synaptic vesicles and quenched FM1-43 fluorescence, indicating retention of FM dye beyond first fusion. BPB also quenched fluorescence of VAMP (synaptobrevin-2)-EGFP, thus indicating the timing of first fusion of vesicles in the total recycling pool. Comparison with FM dye destaining revealed that kiss-and-run strongly prevailed over full-collapse fusion at low frequency, giving way to a near-even balance at high frequency. Quickening of kiss-and-run vesicle reuse was also observed at higher frequency in the average single vesicle fluorescence response. Kiss-and-run and reuse could enable hippocampal nerve terminals to conserve scarce vesicular resources when responding to widely varying input patterns.     

Peculiarities of synaptic vesicle recycling in frog and mouse motor nerve terminals

Using electrophysiology and fluorescence microscopy with dye FM 1-43, a comparative study of peculiarities of neurotransmitter secretion, synaptic vesicle exo-endocytosis and recycling has been carried out in nerve terminals (NT) of the skin-sternal muscle of the frog Rana ridibunda and of the white mouse diaphragm muscle during a long-term high-frequency stimulation (20 imp/s). The obtained data have allowed identifying three synaptic vesicle pools and two recycling ways in the motor NT. In the frog NT, the long-term high-frequency stimulation induced consecutive expenditure of the pool ready to release, the mobilizational, and reserve vesicle pools. The exocytosis rate exceeded markedly the endocytosis rate; the slow synaptic vesicle recycling with replenishment of the reserve pool was predominant. In the mouse NT, only the vesicles of the ready to release and the mobilizational pools, which are replenished predominantly by fast recycling, were exocytosed. The exo- and endocytosis occurred practically in parallel, while vesicles of the reserve pool did not participate in the neurotransmitter secretion. It is suggested that evolution of the motor NT from the poikilothermal to homoiothermal animals went by the way of a decrease of the vesicle pool size, the more economic expenditure and the more effective reuse of synaptic vesicles owing to the high rates of endocytosis and recycling. These peculiarities can provide in NT of homoiothermal animals a long maintenance of neurotransmitter secretion at the steady and sufficiently high level to preserve reliability of synaptic transmission in the process of the high-frequency activity.     

Synaptic Vesicle Recycling in Cultured Cerebellar Granule Cells: Role of Vesicular Acidification and Refilling

Abstract: The role of the transvesicular protonmotive force in synaptic vesicle recycling was investigated in cultured cerebellar granule cells. The vesicular V-ATPase was inhibited by 1 µ M bafilomycin A1; as an alternative, the pH component of the gradient was selectively collapsed by equilibration of the cells with 10 m M methylamine and monitored with the fluorescent probe Lysosensor Green. Electrical field-evoked exocytosis of d -[³H]aspartate was inhibited by bafilomycin A1 but not by methylamine, indicating that a transvesicular membrane potential rather than pH gradient is required for transmitter retention within vesicles. In contrast, neither compound affected the field-evoked uptake, recycling, or destaining of the vesicle-specific dye FM2-10; thus, vesicles whose lumens were neutral and/or depleted of transmitter could still recycle in the nerve terminal. No exhaustion of d -[³H]aspartate exocytosis was observed when cells were subjected to six consecutive trains of field stimuli (40 Hz/10 s separated by 10 s). In contrast, the release of preloaded FM2-10 was reduced by ∼50%, with each stimulus indicating that unlabeled vesicles with accumulated d -[³H]aspartate were competing with labeled vesicles for exocytosis. As d -[³H]aspartate was accumulated rapidly across the vesicle membrane from the large cytoplasmic pool, the transmitter-loaded but unlabelled vesicles may represent refilled recycling vesicles. FM2-10 destaining and d -[³H]aspartate exocytosis were reduced in parallel at low frequencies, challenging a role for transient vesicle fusion.     

Vesicle cycle in mouse diaphragm motor nerve terminals

In our research on mouse diaphragm muscles the dynamic of neurotransmitter secretion and synaptic vesicles recycling (exo-endocytosis cycle) at the long-term rhythmic stimulation (20Hz) are explored using an intracellular microelectrode registration and a fluorescent microscopy. It have been shown, thate change of end plant potentials (EPP) amplitude at the rhythmic training occurs in three phases: initial transient decrease, long amplitude stabilization (1-2 min)--the plateau and secondary slow decrease. After 3 minute stimulations the EPP amplitude recovery observed during several seconds. Loading the synaptic vesicle by fluorescent endocytic dye FM 1-43 had shown that the rhythmic stimulation results to gradual (during 5-6 mines) fluorescence decrease in NT, indicating the synaptic vesicle exocytosis. The quantum analysis of the electrophysiological data and their comparison to the fluorescent researches date has allowed to assume, that mouse motor nerve terminals are characterized by high rate of endocytosis and fast synaptic vesicle reuse (average recycling time about 50 sec) that can provide effective maintenance of synaptic transmission at long high-frequency activity. Sizes of ready releasable and recycling synaptic vesicle pools are quantitatively determined. It is assumed, that vesicle recycling occurs on a short fast way to inclusion in recycling pool. So, in the stimulation protocol that were used the synaptic vesicles from reserve pool remain unused. Thus in our conditions recycling pool vesicles cycle repeatedly without reserve pool release.     

Evidence for sustained ATP release from liver cells that is not mediated by vesicular exocytosis

Extracellular ATP regulates many important cellular functions in the liver by stimulating purinergic receptors. Recent studies have shown that rapid exocytosis of ATP-enriched vesicles contributes to ATP release from liver cells. However, this rapid ATP release is transient, and ceases in ~30 s after the exposure to hypotonic solution. The purpose of these studies was to assess the role of vesicular exocytosis in sustained ATP release. An exposure to hypotonic solution evoked sustained ATP release that persisted for more than 15 min after the exposure. Using FM1-43 (N-(3-triethylammoniumpropyl)-4-(4-(dibutylamino)styryl)pyridinium dibromide) fluorescence to measure exocytosis, we found that hypotonic solution stimulated a transient increase in FM1-43 fluorescence that lasted ~2 min. Notably, the rate of FM1-43 fluorescence and the magnitude of ATP release were not correlated, indicating that vesicular exocytosis may not mediate sustained ATP release from liver cells. Interestingly, mefloquine potently inhibited sustained ATP release, but did not inhibit an increase in FM1-43 fluorescence evoked by hypotonic solution. Consistent with these findings, when exocytosis of ATP-enriched vesicles was specifically stimulated by 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB), mefloquine failed to inhibit ATP release evoked by NPPB. Thus, mefloquine can pharmacologically dissociate sustained ATP release and vesicular exocytosis. These results suggest that a distinct mefloquine-sensitive membrane ATP transport may contribute to sustained ATP release from liver cells. This novel mechanism of membrane ATP transport may play an important role in the regulation of purinergic signaling in liver cells.     

Use of a fluorescent dye to measure secretion from intact bovine anterior pituitary cells

The fluorescent dye FM1-43 has been used to indicate membrane changes in individual bovine anterior pituitary cells exposed to secretory stimuli. After ten minutes incubation with FM1-43 (2 M), cells showed three patterns of dye fluorescence: annular, partly filled and uniformly filled. FM1-43 fluorescence was increased in 61% of the cells by TRH (40 nM), a physiological stimulus for prolactin secretion, and in 89% of the cells by 60 mM external K⁺. The fluorescence also increased when cells incubated in the presence of quinpirole, a dopamine D2-receptor agonist which inhibits prolactin secretion, were exposed to raclopride, a D-2 antagonist. The increases in FM1-43 fluorescence caused by these treatments suggests that the dye acts as an indicator of secretion, possibly through incorporation into secretory vesicle membranes exposed on the cell surface during exocytosis. If the dye was washed away after loading, the fluorescence of partly and uniformly filled cells was retained and a rise in fluorescence could still be seen on stimulation by TRH. This suggests that some dye had been taken up by endocytosis and trapped in an intracellular compartment, which expanded through membrane recapture after TRH stimulation. FM1-43 could therefore be a useful probe for membrane cycling associated with secretory responses.     

Peroxynitrite affects exocytosis and SNARE complex formation and induces tyrosine nitration of synaptic proteins

The reactive species peroxynitrite, formed via the near diffusion-limited reaction of nitric oxide and superoxide anion, is a potent oxidant that contributes to tissue damage in neurodegenerative disorders. Peroxynitrite readily nitrates tyrosine residues in proteins, producing a permanent modification that can be immunologically detected. We have previously demonstrated that in the nerve terminal, nitrotyrosine immunoreactivity is primarily associated with synaptophysin. Here we identify two other presynaptic proteins nitrated by peroxynitrite, Munc-18 and SNAP25, both of which are involved in sequential steps leading to vesicle exocytosis. To investigate whether peroxynitrite affects vesicle exocytosis, we used the fluorescent dye FM1-43 to label a recycling population of secretory vesicles within the synaptosomes. Bolus addition of peroxynitrite stimulated exocytosis and glutamate release. Notably, these effects were strongly reduced in the presence of NaHCO(3), indicating that peroxynitrite acts mainly intracellularly. Furthermore, peroxynitrite enhanced the formation of the sodium dodecyl sulfate-resistant SNARE complex in a dose-dependent manner (100-1000 microm) and induced the formation of 3-nitrotyrosine in proteins of SNARE complex. These data suggest that modification(s) of synaptic vesicle proteins induced by peroxynitrite may affect protein-protein interactions in the docking/fusion steps, thus promoting exocytosis, and that, under excessive production of superoxide and nitric oxide, neurons may up-regulate neuronal signaling.     

The effects of hydrogen sulfide on the processes of exo- and endocytosis of synaptic vesicles in the mouse motor nerve endings

The effects of sodium hydrosulfide (NaHS), the donor of hydrogen sulfide (H2S), on the exo/endocytosis cycle of synaptic vesicles in the motor nerve ending of the mouse diaphragm were studied using intracellular microelectrode technique and fluorescent microscopy. NaHS increased the frequency of miniature end-plate potentials (MEPPs), without changing their amplitude-time parameters. NaHS also increased the amplitude of the evoked postsynaptic responses during single stimulation (0.3 Hz), which was the evidence of the enhanced synaptic vesicle exocytosis. During high-frequency stimulation (50 Hz), NaHS induced more significant decline of neurotransmitter release, probably due to the lower rate of synaptic vesicle mobilization from recycling pool to exocytic sites. NaHS also decreased the uptake of the fluorescent endocytic dye FM 1–43, which indicated the reduced endocytosis of synaptic vesicles. Thus, the H₂S donor increases exocytosis and decreases the processes of synaptic vesicle endocytosis and mobilization in the mouse motor nerve ending.     

Streamlined synaptic vesicle cycle in cone photoreceptor terminals

Cone photoreceptors tonically release neurotransmitter in the dark through a continuous cycle of exocytosis and endocytosis. Here, using the synaptic vesicle marker FM1-43, we elucidate specialized features of the vesicle cycle. Unlike retinal bipolar cell terminals, where stimulation triggers bulk membrane retrieval, cone terminals appear to exclusively endocytose small vesicles. These retain their integrity until exocytosis, without pooling their membranes in endosomes. Endocytosed vesicles rapidly disperse through the terminal and are reused with no apparent delay. Unlike other synapses where most vesicles are immobilized and held in reserve, only a small fraction (<15%) becomes immobilized in cones. Photobleaching experiments suggest that vesicles move by diffusion and not by molecular motors on the cytoskeleton and that vesicle movement is not rate limiting for release. The huge reservoir of vesicles that move rapidly throughout cone terminals and the lack of a reserve pool are unique features, providing cones with a steady supply for continuous release.     

Systematic heterogeneity of fractional vesicle pool sizes and release rates of hippocampal synapses

Hippocampal neurons in tissue culture develop functional synapses that exhibit considerable variation in synaptic vesicle content (20–350 vesicles). We examined absolute and fractional parameters of synaptic vesicle exocytosis of individual synapses. Their correlation to vesicle content was determined by activity-dependent discharge of FM-styryl dyes. At high frequency stimulation (30 Hz), synapses with large recycling pools released higher amounts of dye, but showed a lower fractional release compared to synapses that contained fewer vesicles. This effect gradually vanished at lower frequencies when stimulation was triggered at 20 Hz and 10 Hz, respectively. Live-cell antibody staining with anti-synaptotagmin-1-cypHer 5, and overexpression of synaptopHluorin as well as photoconversion of FM 1-43 followed by electron microscopy, consolidated the findings obtained with FM-styryl dyes. We found that the readily releasable pool grew with a power function with a coefficient of 2/3, possibly indicating a synaptic volume/surface dependency. This observation could be explained by assigning the rate-limiting factor for vesicle exocytosis at high frequency stimulation to the available active zone surface that is proportionally smaller in synapses with larger volumes.     

Olesoxime,a cholesterol-like neuroprotectant restrains synaptic vesicle exocytosis in the mice motor nerve terminals: Possible role of VDACs

Olesoxime is a cholesterol-like neuroprotective compound that targets to mitochondrial voltage dependent anion channels (VDACs). VDACs were also found in the plasma membrane and highly expressed in the presynaptic compartment. Here, we studied the effects of olesoxime and VDAC inhibitors on neurotransmission in the mouse neuromuscular junction. Electrophysiological analysis revealed that olesoxime suppressed selectively evoked neurotransmitter release in response to a single stimulus and 20 Hz activity. Also olesoxime decreased the rate of FM1–43 dye loss (an indicator of synaptic vesicle exocytosis) at low frequency stimulation and 20 Hz. Furthermore, an increase in extracellular Cl⁻ enhanced the action of olesoxime on the exocytosis and olesoxime increased intracellular Cl⁻ levels. The effects of olesoxime on the evoked synaptic vesicle exocytosis and [Cl⁻]_i were blocked by membrane-permeable and impermeable VDAC inhibitors. Immunofluorescent labeling pointed on the presence of VDACs on the synaptic membranes. Rotenone-induced mitochondrial dysfunction perturbed the exocytotic release of FM1–43 and cell-permeable VDAC inhibitor (but not olesoxime or impermeable VDAC inhibitor) partially mitigated the rotenone-driven alterations in the FM1–43 unloading and mitochondrial superoxide production. Thus, olesoxime restrains neurotransmission by acting on plasmalemmal VDACs whose activation can limit synaptic vesicle exocytosis probably via increasing anion flux into the nerve terminals.     

Biophysics of Active Vesicle Transport,an Intermediate Step That Couples Excitation and Exocytosis of Serotonin in the Neuronal Soma

Transmitter exocytosis from the neuronal soma is evoked by brief trains of high frequency electrical activity and continues for several minutes. Here we studied how active vesicle transport towards the plasma membrane contributes to this slow phenomenon in serotonergic leech Retzius neurons, by combining electron microscopy, the kinetics of exocytosis obtained from FM1-43 dye fluorescence as vesicles fuse with the plasma membrane, and a diffusion equation incorporating the forces of local confinement and molecular motors. Electron micrographs of neurons at rest or after stimulation with 1 Hz trains showed cytoplasmic clusters of dense core vesicles at 1.5±0.2 and 3.7±0.3 µm distances from the plasma membrane, to which they were bound through microtubule bundles. By contrast, after 20 Hz stimulation vesicle clusters were apposed to the plasma membrane, suggesting that transport was induced by electrical stimulation. Consistently, 20 Hz stimulation of cultured neurons induced spotted FM1-43 fluorescence increases with one or two slow sigmoidal kinetics, suggesting exocytosis from an equal number of vesicle clusters. These fluorescence increases were prevented by colchicine, which suggested microtubule-dependent vesicle transport. Model fitting to the fluorescence kinetics predicted that 52–951 vesicles/cluster were transported along 0.60–6.18 µm distances at average 11–95 nms⁻¹ velocities. The ATP cost per vesicle fused (0.4–72.0), calculated from the ratio of the ΔG_process/ΔG_ATP, depended on the ratio of the traveling velocity and the number of vesicles in the cluster. Interestingly, the distance-dependence of the ATP cost per vesicle was bistable, with low energy values at 1.4 and 3.3 µm, similar to the average resting distances of the vesicle clusters, and a high energy barrier at 1.6–2.0 µm. Our study confirms that active vesicle transport is an intermediate step for somatic serotonin exocytosis by Retzius neurons and provides a quantitative method for analyzing similar phenomena in other cell types.     

Y-27632 induces calcium-independent glutamate release in rat brain synaptosomes by the mechanism which is distinct from exocytosis

The inhibitor of Rho-kinase Y-27632 induces non-secretory exocytosis in PC12 cells. The influence of this compound on central synapses remains uninvestigated. We showed that Y-27632 at the concentration 100 jtM led to spontaneous [14C]glutamate release in synaptosomes, which was not accompanied by plasma membrane depolarization. Membrane potential was registered by fluorescent dye DiSC3(5). Y27632 induced an increase of acridine orange fluorescence, exercising no influence over fluorescence of FM2-10 dye. These results suggest that Rho-kinase inhibition decreases pH gradient of synaptic vesicles not inducing exocytosis. Dissipation of the gradient leads to leakage of neurotransmitters to cytosol pumping them out by plasma membrane transporters. Our results show the involvement of Rho-dependent branch of intracellular signaling in regulation of pH gradient in synaptic vesicles.     

Two endocytic recycling routes selectively fill two vesicle pools in frog motor nerve terminals

We have identified and characterized two vesicle recycling pathways in frog motor nerve terminals. We exploited the differential staining properties of FM dyes of varying hydrophobicity to label selectively two different vesicle pools, using optical imaging and electron microscopy of photoconverted dyes. During a 1 min tetanus, a rapidly recycling route places vesicles selectively into a small readily releasable pool comprising about 20% of vesicles. After the tetanus, a much slower pathway (from which FM2-10 but not FM1-43 can be rinsed) delivers vesicles via infoldings and cisternae selectively to a reserve pool with a halftime of about 8 min. Mixing between the two pools is slow. During stimulation at 30 Hz, 10-15 s is required to mobilize and release dye from the reserve pool.     

Myosin accelerates synaptic vesicle recycling in the motor nerve endings

Neurotransmitter release and exocytosis of synaptic vesicles in the motor nerve endings of the frog cutaneous-pectoris muscle were studied using electrophysiological and optical methods under the conditions of inhibition of the myosin light-chain kinase and non-muscle myosin by the specific inhibitors ML-7 (12 μM) and (–)-blebbistatin (100 μM). At high-frequency stimulation (20 pulses/s), these inhibitors strengthened suppression of transmitter release during the first 20–25 s and slowed down the release of the fluorescent dye FM 1-43. The obtained results indicate that myosin accelerates rapid synaptic vesicle recycling upon high-frequency stimulation.