Ultrastructural changes and transmitter release induced by depolarization of cholinergic synaptosomes. A freeze-fracture study of a synaptosomal fraction from torpedo electric organ

VAMP (synaptobrevin) is present in the plasma membrane of nerve terminals

Synaptic vesicle docking and exocytosis require the specific interaction of synaptic vesicle proteins (such as VAMP/synaptobrevin) with presynaptic plasma membrane proteins (such as syntaxin and SNAP 25). These proteins form a stable, SDS-resistant, multimolecular complex, the SNARE complex. The subcellular distribution of VAMP and syntaxin within Torpedo electric organ nerve endings was studied by immunogoldlabeling of SDS-digested freeze-fracture replicas (Fujimoto, 1995). This technique allowed us to visualize large surface areas of the presynaptic plasma membrane and numerous synaptic vesicles from rapidly frozen nerve endings and synaptosomes. VAMP was found associated with synaptic vesicles, as also shown by conventional electron microscopy immunolabeling, and to the presynaptic plasma membrane (P leaflet). Syntaxin was also detected in the nerve ending plasma membrane, without gold labeling of synaptic vesicles. Comparison of gold particle densities suggests that the presynaptic plasma membrane contains 3 VAMP molecules per molecule of syntaxin. After biotinylation of intact synaptosomes, the synaptosomal plasma membrane was isolated on Streptavidin coated magnetic beads. Its antigenic content was compared to that of purified synaptic vesicles. VAMP was present in both membranes whereas syntaxin and SNAP 25 were highly enriched in the synaptosomal plasma membrane. This membrane has a low content of classical synaptic vesicle proteins (synaptophysin, SV2 and the vesicular acetylcholine transporter). The VAMP to syntaxin stoichiometry in the isolated synaptosomal membrane was estimated by comparison with purified antigens and close to 2, in accordance with morphological data. SDS-resistant SNARE complexes were detected in the isolated presynaptic membrane but absent in purified synaptic vesicles. Taken together, these results show that the presence of VAMP in the plasma membrane of nerve endings cannot result from exocytosis of synaptic vesicles, a process which could, as far as SNAREs are concerned, very much resemble homotypic fusion.

Cloning and expression of the vesamicol binding protein from the marine ray Torpedo. Homology with the putative vesicular acetylcholine transporter UNC-17 from Caenorhabditis elegans

Complementary DNA clones corresponding to a messenger RNA encoding a 56 kDa polypeptide have been obtained from Torpedo marmorata and Torpedo ocellata electric lobe libraries, by homology screening with a probe obtained from the putative acetylcholine transporter from the nematode Caenorhabditis elegans. The Torpedo proteins display approximately 50% overall identity to the C. elegans unc-17 protein and 43% identity to the two vesicle monoamine transporters (VMAT1 and VMAT2). This family of proteins is highly conserved within 12 domains which potentially span the vesicle membrane, with little similarity within the putative intraluminal glycosylated loop and at the N- and C-termini. The approximately 3.0 kb mRNA species is specifically expressed in the brain and highly enriched in the electric lobe of Torpedo. The Torpedo protein, expressed in CV-1 fibroblast cells, possesses a high-affinity binding site for vesamicol (Kd = 6 nM), a drug which blocks in vitro and in vivo acetylcholine accumulation in cholinergic vesicles.

Calcium channel antagonist omega-conotoxin binds to intramembrane particles of isolated nerve terminals

Voltage-sensitive calcium channels play a key role in evoked neurotransmitter release and their distribution in presynaptic membranes can be critical for fast signalling at chemical synapses. Using a biotinylated derivative of the neuronal calcium channel antagonist, omega-conotoxin, and a combination of colloidal gold labeling and freeze-fracture techniques, we have labeled calcium channels present at the membrane of nerve terminals isolated from the electric organ of Torpedo marmorata. The biotinylated blocker exerts an inhibitory action on the high potassium-evoked release of adenosine triphosphate as the native toxin does and its interaction with biological membranes is specific as shown in displacement experiments. This study shows that an antagonist specific for voltage-activated calcium channels binds to intramembrane particles in presynaptic membranes, reinforcing the idea that these particles, concentrated at neurotransmitter release sites, effectively represent calcium channels.

Acetylcholine transport, storage, and release

ACh is released from cholinergic nerve terminals under both resting and stimulated conditions. Stimulated release is mediated by exocytosis of synaptic vesicle contents. The structure and function of cholinergic vesicles are becoming known. The concentration of ACh in vesicles is about 100-fold greater than the concentration in the cytoplasm. The AChT exhibits the lowest binding specificity among known ACh-binding proteins. It is driven by efflux of protons pumped into the vesicle by the V-type ATPase. A potent pharmacology of the AChT based on the allosteric VR has been developed. It has promise for clinical applications that include in vivo evaluation of the density of cholinergic innervation in organs based on PET and SPECT. The microscopic kinetics model that has been developed and the very low transport specificity of the vesicular AChT-VR suggest that the transporter has a channel-like or multidrug resistance protein-like structure. The AChT-VR has been shown to be tightly associated with proteoglycan, which is an unexpected macromolecular relationship. Vesamicol and its analogs block evoked release of ACh from cholinergic nerve terminals after a lag period that depends on the rate of release. Recycling quanta of ACh that are sensitive to vesamicol have been identified electrophysiologically, and they constitute a functional correlate of the biochemically identified VP2 synaptic vesicles. The concept of transmitter mobilization, including the observation that the most recently synthesized ACh is the first to be released, has been greatly clarified because of the availability of vesamicol. Differences among different cholinergic nerve terminal types in the sensitivity to vesamicol, the relative amounts of readily and less releasable ACh, and other aspects of the intracellular metabolism of ACh probably are more apparent than real. They easily could arise from differences in the relative rates of competing or sequential steps in the complicated intraterminal metabolism of ACh rather than from fundamental differences among the terminals. Nonquantal release of ACh from motor nerve terminals arises at least in part from the movement of cytoplasmic ACh through the AChT located in the cytoplasmic membrane, and it is blocked by vesamicol. Possibly, the proteoglycan component of the AChT-VR produces long-term residence of the macromolecular complex in the cytoplasmic membrane through interaction with the synaptic matrix. The preponderance of evidence suggests that a significant fraction of what previously, heretofore, had been considered to be nonquantal release from the motor neuron actually is quantal release from the neuron at sites not detected electrophysiologically.(ABSTRACT TRUNCATED AT 400 WORDS)

Phospholipid transverse diffusion in synaptosomes: evidence for the involvement of the aminophospholipid translocase

We have studied in Torpedo marmorata electric organ synaptosomes the equilibration kinetics of spin-labeled phospholipid analogues initially incorporated into the outer plasma membrane monolayer. As assayed by evoked releases of both ATP and acetylcholine, the nerve endings were closed vesicles containing an energy source. The aminophospholipids (phosphatidylethanolamine and phosphatidylserine) were translocated toward the inner membrane leaflet faster and to a higher extent than their choline-containing counterparts (phosphatidylcholine and sphingomyelin). This difference was abolished by incubation of synaptosomal membranes with N-ethylmaleimide, suggesting that the accumulation of aminophospholipids in the inner layer was driven by a protein. This phenomenon is comparable with what was described in plasma membranes of other eucaryotic cells (erythrocyte, lymphocyte, platelet, fibroblast), and thus we would suggest that an aminophospholipid translocase, capable of moving the aminophospholipids from the outer to the inner layer at the expense of ATP, is also present in the synaptosomal plasma membrane.

Tetanus toxin blocks potassium-induced transmitter release and rearrangement of intramembrane particles at pure cholinergic synaptosomes

We have studied the action of tetanus toxin on the release of acetylcholine from a subcellular fraction of cholinergic nerve terminals (synaptosomes) isolated from the Torpedo electric organ. We have also studied the morphological changes induced by chemical stimulation on the presynaptic plasma membrane of poisoned synaptosomes. These changes were studied by means of freeze-fracture techniques. We found that tetanus toxin blocks the release of acetylcholine from isolated nerve terminals in a dose-dependent manner. The maximal inhibition is achieved at a concentration of 12.5 nM in 10 min. This effect is prevented by tetanus toxin antiserum. Tetanus toxin also blocks the rearrangement of intramembrane particles at plasma membrane of poisoned synaptosomes, specifically the decrease of small (less than or equal to 9.5 nm diameter) intramembranous particles at the protoplasmic hemimembrane leaflet and the increase of large (greater than 9.5 nm diameter) intramembrane particles at the external hemimembrane leaflet induced by potassium stimulation. These results suggest that intramembrane particle rearrangement could be related to acetylcholine secretion.

AH5183 and cetiedil: two potent inhibitors of acetylcholine uptake into isolated synaptic vesicles from Torpedo marmorata

Synaptic vesicles purified on a sucrose-KCl sedimentation gradient were tested for their ability to accumulate [1-14C]acetylcholine ([1-14C]ACh) in the absence and in the presence of AH5183 and cetiedil. Kinetic studies of ACh transport showed that it was time dependent and saturable as a function of ACh concentration, with a KT of 1.2 mM. The protein-modifying agents N-ethylmaleimide and 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole were powerful inhibitors of ACh uptake. In agreement with other studies, AH5183 was found to be a potent inhibitor of ACh uptake by synaptic vesicles. Inhibition was of the mixed noncompetitive type, and the inhibition constant was 45.2 +/- 3.4 nM. Cetiedil, a drug that resembles ACh, was previously shown on intact nerve endings to inhibit the translocation of newly synthesized ACh into the synaptic vesicle compartment, and we demonstrate here that cetiedil is indeed an efficient blocker of ACh uptake by isolated synaptic vesicles. It acted as a competitive inhibitor, with a Ki of 118.5 +/- 9.5 nM. Neither ATP-dependent calcium uptake nor Mg2+-ATPase activity was affected by the drugs, a finding showing their specificity toward the ACh uptake process. The binding of L-[3H]AH5183 to intact vesicles was characterized in the absence or the presence of ACh or cetiedil. Saturation experiments showed a total binding capacity of approximately 126 pmol/mg of vesicular protein and a dissociation constant of 19.9 +/- 4.1 nM under control conditions.(ABSTRACT TRUNCATED AT 250 WORDS)

Increase in reactive cholesterol in the presynaptic membrane of depolarized Torpedo synaptosomes: blockade by botulinum toxin type A

We have investigated the redistribution of filipin-cholesterol complexes at freeze-fractured presynaptic membrane of pure cholinergic synaptosomes isolated from Torpedo electric organ during acetylcholine release. After chemical depolarization, filipin-induced lesions increase at the presynaptic membrane. These changes do not take place when synaptosomes are stimulated in a calcium-free medium. Botulinum neurotoxin type A blocks both acetylcholine release and the rearrangement of filipin-induced lesions induced by depolarization. Since botulinum neurotoxin type A does not block either membrane depolarization or calcium entry into the nerve terminal, our results suggest that the redistribution of filipin-cholesterol complexes is linked to the acetylcholine release process.

Botulinum toxin type A blocks the morphological changes induced by chemical stimulation on the presynaptic membrane of Torpedo synaptosomes

The action of botulinum neurotoxin on acetylcholine release, and on the structural changes at the presynaptic membrane associated with the transmitter release, was studied by using a subcellular fraction of cholinergic nerve terminals (synaptosomes) isolated from the Torpedo electric organ. Acetylcholine and ATP release were continuously monitored by chemiluminescent methods. To catch the membrane morphological changes, the quick-freezing method was applied. Our results show that botulinum neurotoxin inhibits the release of acetylcholine from these isolated nerve terminals in a dose-dependent manner, whereas ATP release is not affected. The maximal inhibition (70%) is achieved at neurotoxin concentrations as low as 125 pM with an incubation time of 6 min. This effect is not linked to an alteration of the integrity of the synaptosomes since, after poisoning by botulinum neurotoxin type A, they show a nonmodified occluded lactate dehydrogenase activity. Moreover, membrane potential is not altered by the toxin with respect to the control, either in resting condition or after potassium depolarization. In addition to acetylcholine release inhibition, botulinum neurotoxin blocks the rearrangement of the presynaptic intramembrane particles induced by potassium stimulation. The action of botulinum neurotoxin suggests that the intramembrane particle rearrangement is related to the acetylcholine secretion induced by potassium stimulation in synaptosomes isolated from the electric organ of Torpedo marmorata.

Chronic ethanol consumption affects filipin-cholesterol complexes and intramembranous particles of synaptosomes of rat brain cortex

To assess the effect of ethanol on the planar distribution of cholesterol as well as on the surface architecture of presynaptic terminals of rats, synaptosomes isolated from cerebral cortex of rats chronically exposed to alcohol were incubated with filipin, a cytochemical marker for beta-hydroxycholesterol, and analyzed using both conventional (qualitative and quantitative) and freeze-fracture electron microscopy. Synaptosomes incubated in the absence of filipin were used as cytochemical controls. Biochemical determination indicates a 12% increase of cholesterol in synaptosomal membranes from alcohol treated rats. This increase was confirmed by a significant increment in the number of filipin-cholesterol complexes. Synaptosomes of treated rats showed a reduction in the total number of synaptic vesicles (SV) as well as a decrease in the density and total number of intramembranous particles (IMP) per synaptosome. In control rats, most synaptosomal IMP were distributed in clusters whereas in those of rats exposed to alcohol they were distributed at random. These changes in distribution of IMP were also observed in presynaptic terminals analyzed "in situ." These findings indicate that ethanol acts on the presynaptic terminals. The variations in cholesterol content as well as in the density and distribution of IMP appear to be related to alcohol-induced changes in the physicochemical properties of components of the synaptosomal membrane.

Structural changes at pure cholinergic synaptosomes during the transmitter release induced by A-23187 in Torpedo marmorata. A freeze-fracture study

Pure cholinergic synaptosomes isolated from the electric organ of Torpedo marmorata were stimulated by calcium ionophore A-23187. The effect of time course of stimulation on the changes in intramembrane particles (IMPs) on presynaptic membranes was studied by quick-freezing and aldehyde-fixation freeze-fracture. We showed that the decrease of small-particle density at the P-face and the increase of large-particle density at the E-face was maximum after 30 sec of A-23187 stimulation. Later, the density of synaptic vesicles decreased. We suggest that the redistribution of IMPs on the presynaptic membrane and acetylcholine (ACh) release from pure cholinergic synaptosomes have a similar time course when triggered by A-23187.

Solubilization and partial purification of a presynaptic membrane protein ensuring calcium-dependent acetylcholine release from proteoliposomes

In previous work, it was shown that cytoplasmic acetylcholine decreased on stimulation of Torpedo electric organ or synaptosomes in a strictly calcium-dependent manner. This led to the hypothesis that the presynaptic membrane contained an element translocating acetylcholine when activated by calcium. To test this hypothesis, the presynaptic membrane constituents were incorporated into the membranes of liposomes filled with acetylcholine. The proteoliposomes thus obtained released the transmitter in response to a calcium influx. The kinetics and calcium dependency of acetylcholine release were comparable for proteoliposomes and synaptosomes. The presynaptic membrane element ensuring calcium-dependent acetylcholine release is most probably a protein, since it was susceptible to Pronase, but only when the protease had access to the intracellular face of the presynaptic membrane. Postsynaptic membrane fractions contained very low amounts of this protein. It was extracted from the presynaptic membrane under alkaline conditions in the form of a protein-lipid complex of large size and low density which was partially purified. The specificity of the calcium-dependent release for acetylcholine was tested with proteoliposomes filled with equal amounts of acetylcholine and choline or acetylcholine and ATP. In both cases, acetylcholine was released preferentially. After cholate solubilization and gel filtration, the protein ensuring the calcium-dependent acetylcholine release was recovered at a high apparent molecular weight (between 600,000 and 200,000 daltons), its apparent sedimentation coefficient being 17S after cholate elimination. This protein is probably an essential coin of the transmitter release mechanism. We propose to name it mediatophore.

Demonstration of a receptor in Torpedo synaptic vesicles for the acetylcholine storage blocker L-trans-2-(4-phenyl[3,4-3H]-piperidino) cyclohexanol

Transport and storage of acetylcholine by purified Torpedo electric organ synaptic vesicles is blocked by the drug L-trans-2-(4-phenylpiperidino)cyclohexanol (AH-5183). This study sought evidence of a specific receptor for the drug. Highly tritiated L-trans-2-(4-phenyl [3,4-3H] piperidino)-cyclohexanol (L-[3H] AH5183) was synthesized. An excess of nonradioactive L-isomer competed with L-[3H]AH5183 for binding to purified Torpedo synaptic vesicles whereas nonradioactive D-isomer did so poorly. Dissociation of bound L-[3H]AH5183 was first order with a rate constant at 23 degrees C of 0.23 +/- 0.03 min-1, and association was too rapid to study. At equilibrium the amount of L-[3H]AH5183 bound at saturation varied in different vesicle preparations, but in one typical preparation specific binding of 181 +/- 15 pmol L-[3H]AH5183 per mg of synaptic vesicle protein was observed with a dissociation constant of 34 +/- 6 nM. Neither acetylcholine nor choline compete effectively with L-[3H]AH5183 for binding. The evidence suggests that about 3.7 +/- 0.3 enantioselective receptors for L-[3H]AH5183 are typically present in each cholinergic synaptic vesicle, and the L-AH5183 binding site does not recognize acetylcholine.

Ultracytochemical localization of acetylcholine-like cations in excited motor end-plates by means of ionic fixation

Using rapid ionic fixation with molybdic or tungstic heteropolyanions (strong precipitating agents of quaternary ammonium cations such as choline and acetylcholine), acetylcholine-like cations were localized as point-like precipitates in the synaptic vesicles of resting (electrically nonstimulated) motor nerve terminals. When performed at low temperature, the same procedure revealed spot-like precipitates (presumed to be exocytotically released acetylcholine-like cations) in the synaptic cleft in the vicinity of the active zone. These precipitates were often seen in paired forms. Unlike resting motor-nerve terminals, excited terminals (electrical stimulation with occasional 4-aminopyridine pretreatment) after ionic fixation exhibited, at first, laminar precipitates both in the vicinity of the active zone inside the nerve terminals and in the synaptic space. In the vicinity of the active zone, the laminar precipitates were directed towards the synaptic membrane, while those in the synaptic space showed no orientation. Ionic fixation also revealed diffused precipitates both around the synaptic vesicles and on the axoplasmic side of the presynaptic membrane. Finally, the same fixation procedure demonstrated the presence of empty synaptic vesicles (without point-like precipitates) in close contact with the presynaptic membrane. The laminar and diffused precipitates are presumed to be two different forms of the same salts of acetylcholine-like cations that are insolubilized by ionic fixation in both the nerve terminals and the synaptic space of excited motor end-plates.

Reconstitution of a functional synaptosomal membrane possessing the protein constituents involved in acetylcholine translocation

Reconstitution of a functional presynaptic membrane possessing calcium-dependent acetylcholine release properties has been achieved. The proteoliposomal membrane obtained gains its acetylcholine-releasing capabilities from presynaptic membrane proteins. At the peak of acetylcholine release, intramembrane particles became more numerous in one of the proteoliposomal membrane faces. This phenomenon resembles the intramembrane particle rearrangements found in stimulated synaptosomes. No visible structures capable of releasing acetylcholine as a result of the calcium influx were found inside the proteoliposomes. This supports the view that the release of free cytosolic acetylcholine from stimulated nerve terminals can be directly attributed to presynaptic membrane proteins. These proteins were extracted in a functional form from the synaptosomal membrane.

Temporal characteristics of potassium-stimulated acetylcholine release and inactivation of calcium influx in rat brain synaptosomes

The time course of Ca2+-dependent [3H]acetylcholine [( 3H]ACh) release and inactivation of 45Ca2+ entry were examined in rat brain synaptosomes depolarized by 45 mM [K+]0. Under conditions where the intrasynaptosomal stores of releasable [3H]ACh were neither exhausted nor replenished in the course of stimulation, the K+-evoked release consisted of a major (40% of the releasable [3H]ACh pool), rapidly terminating phase (t1/2 = 17.8 s), and a subsequent, slow efflux that could be detected only during a prolonged, maintained depolarization. The time course of inactivation of K+-stimulated Ca2+ entry suggests the presence of fast-inactivating, slow-inactivating, and noninactivating, or very slowly inactivating, components. The fast-inactivating component of the K+-stimulated Ca2+ entry into synaptosomes appears to be responsible for the rapidly terminating phase of transmitter release during the first 60 s of K+ stimulus. The noninactivating Ca2+ entry may account for the slow phase of transmitter release. These results indicate that under conditions of maintained depolarization of synaptosomes by high [K+]0 the time course and the amount of transmitter released may be a function of the kinetics of inactivation of the voltage-dependent Ca channels.

Synaptic membrane domains in photoreceptors of chick retina: a thin-section and a freeze-fracture study

In this freeze-fracture study of synaptic terminals of chick photoreceptors, three regions of synaptic terminal plasmalemma can be distinguished on the basis of intramembrane characteristics. The first region is the synaptic vesicle fusion region in which rows of P-face depressions and E-face mounds are observed. In the absence of exocytotic figures this zone is relatively free of P-face particles and E-face pits. Adjacent to this, a second region is seen, rich in P-face particles and complementary E-face pits. This second region waxes and wanes in size during dark and light stimulation (Cooper and McLaughlin, 1982) and may correspond to similar expansions and contractions of synaptic plasmalemma induced by less physiological modes of stimulation, as observed in other synaptic terminals (Ceccarelli et al., 1979b; Model et al., 1975; Boyne and McLeod, 1979). During the waxing period, P-face particles and E-face pits are present in this membrane, and its expansion gives rise to diverticula of the synaptic terminal. During the waning period when the diverticula begin to disappear, aggregates of P-face particles and complementary patches of E-face pits are seen in the diverticular membrane. The third region, the nonsynaptic plasmalemma enclosing the terminal, contains a high density of P-face particles but does not contain E-face pits. Serial sections of vacuoles within the cytoplasm demonstrate that some vacuoles retain connections with this nonsynaptic plasmalemma. Vacuoles that are connected in this way are depleted of intramembrane particles. Such regions appear to represent separate domains within the photoreceptor terminal and are discussed in the context of membrane addition and retrieval.

Isolation of a presynaptic plasma membrane fraction from Torpedo cholinergic synaptosomes: evidence for a specific protein

Synaptosomal plasma membranes were isolated from Torpedo cholinergic synaptosomes which had been purified as previously described or repurified by equilibrium centrifugation. The synaptosomal plasma membrane could be distinguished from postsynaptic membranes by the absence of postsynaptic specific markers (nicotinic AChR) and by its low intramembrane particle complement after freeze fracture. In addition, the presynaptic membrane fraction contained acetylcholinesterase. Gel electrophoresis permitted the identification of a major protein component of the presynaptic membrane fraction which had a molecular weight of 67,000. This protein was not found in postsynaptic membrane or synaptic vesicle fractions. Thus it appeared to be specific to the nerve terminal plasma membrane.

Binding of beta-bungarotoxin to Torpedo electric organ synaptosomes. A high resolution autoradiographic study

Isolated pure cholinergic synaptosomes from Torpedo electric organ were incubated in vitro with beta-bungarotoxin for 15, 30 and 60 min and processed for electron microscopy. It was found that no morphological damage was seen after 15 min but by contrast, severe disruption of synaptosomes was present at 30 or 60 min after incubation with toxin. Synaptosomes were incubated also for 15 min in the presence of 125I-labelled beta-bungarotoxin and the binding was evaluated by electron microscopic autoradiography. The toxin was found to bind to the presynaptic membrane. The surface density of toxin binding sites was calculated to be around 3000/micron2. In a minor population of synaptosomes, the toxin was translocated into large vesicles suggesting that the toxin-receptor complexes underwent endocytosis in such vesicles. These results give further support to the view that inhibition of transmitter release by the toxin is produced by its action on plasma membrane.

Continuous determination by a chemiluminescent method of acetylcholine release and compartmentation in Torpedo electric organ synaptosomes

The detection of acetylcholine (ACh) with a chemiluminescent procedure enables one to follow continuously the release of transmitter from stimulated synaptosomes and to study the compartmentation of ACh in resting and active nerve terminals. A compartment of ACh liberated almost entirely by a single freezing and thawing could be directly measured and compared with a compartment of ACh resistant to several cycles of freezing and thawing but liberated by a detergent (60-70% of the total). It is the compartment liberated by freezing and thawing that is reduced when synaptosomes are stimulated. Up to half the total synaptosomal ACh content is readily releasable provided the calcium entry is maintained, or if a strong releasing agent such as the venom of Glycera convoluta is used. In addition, it is shown that synaptosomes contain only negligible amounts of choline, and that the proportion of the two ACh compartments is not influenced by changing extracellular calcium just before their determination.

Acetylcholine incorporation by cholinergic synaptic vesicles from Torpedo marmorata

The ability of cholinergic vesicles to incorporate acetylcholine (ACh) was studied using highly purified synaptic vesicles from Torpedo electric organ. Depleted vesicles were capable of rapidly taking up exogenous ACh. Evidence that this represented true incorporation was that labelled ACh comigrated with vesicular ATP on gel filtration and that vesicle-associated ACh was protected against enzymatic hydrolysis and was releasable under hypoosmotic conditions. The total amount of ACh incorporated depended on the ACh concentration up to 100 mM. A sudden fall in the external ACh concentration did not cause leakage of the ACh incorporated in vitro. Preliminary results indicated that retention of ACh inside the vesicle was pH-dependent. Choline was also taken up by vesicles, but the time pattern strongly suggested that it was not being retained. The magnitude of ach incorporation was estimated with respect to the intravesicular space.

Simultaneous release of acetylcholine and ATP from stimulated cholinergic synaptosomes

The release of acetylcholine (ACh) and ATP from pure cholinergic synaptosomes isolated from the electric organ of Torpedo was studied in the same perfused sample. A presynaptic ATP release was demonstrated either by depolarization with KCl or after the action of a venom extracted from the annelid Glycera convoluta (GV). The release of ATP exhibited similar kinetics to that of ACh release and was therefore probably closely related to the latter. The ACh/ATP ratio in perfusates after KCl depolarization was 45; this was much higher than the ACh/ATP ratio in cholinergic synaptic vesicles, which was 5. The ACh/ATP ratio released after the action of GV was also higher than that of synaptic vesicles. These differences are discussed. The stoichiometry of that of synaptic vesicles. These differences are discussed. The stoichiometry of ACh and ATP release is not consistent with the view that the whole synaptic vesicle content is released by exocytosis after KCl depolarization, as is the case for chromaffin cells in the adrenal medulla.