Immunological detection of mediatophore in motor end-plates and electric organ subcellular fractions of torpedo marmorata

A rabbit antiserum to mediatophore, a nerve terminal membrane protein involved in calcium dependent ACh release, was raised after immunization with the purified protein. An immunological assay for mediatophore was then developed and the subcellular distribution of this protein in Torpedo electric organ fractions was studied. A good agreement was obtained between the distribution in the different fractions of the antigen and of mediatophore related acetylcholine releasing activity as determined by reconstitution in proteoliposomes. Mediatophore was highly concentrated in presynaptic plasma membranes of electric organ, while very low contents were observed in electric nerves and electric lobes. Although some mediatophore was found in synaptic vesicle fractions, this most probably resulted from presynaptic membrane contamination as evaluated with other presynaptic membrane markers. Nerve terminals of motor end-plates were strongly stained with anti-mediatophore antibodies.     

Mediatophore, a protein supporting quantal acetylcholine release

After having reconstituted in artificial membranes the calcium-dependent acetylcholine release step, and shown that essential properties of the mechanism were preserved, we purified from Torpedo electric organ nerve terminals a protein, the mediatophore, able to release acetylcholine upon calcium action. A plasmid encoding for Torpedo mediatophore was introduced into cells deficient for acetylcholine release and for the expression of the cholinergic genomic locus defined by the co-regulated choline acetyltransferase and vesicular transporter genes. The transfected cells became able to release acetylcholine in response to a calcium influx in the form of quanta. The cells had to be loaded with acetylcholine since they did not synthesize it, and without transporter they could not concentrate it in vesicles. We may then attribute the observed quanta to mediatophores. We know from previous works that like the release mechanism, mediatophore is activated at high calcium concentrations and desensitized at low calcium concentrations. Therefore only the mediatophores localized within the calcium microdomain would be activated synchronously. Synaptic vesicles have been shown to take up calcium and those of the active zone are well situated to control the diffusion of the calcium microdomain and consequently the synchronization of mediatophores. If this was the case, synchronization of mediatophores would depend on vesicular docking and on proteins ensuring this process.     

Characterization of a polyclonal antiserum raised against mediatophore, a protein that translocates acetylcholine

A protein (the mediatophore) purified from Torpedo electric organ nerve terminals was identified by its ability to translocate acetylcholine upon calcium action. The recent large scale production of this protein led us to prepare a polyclonal antibody that was used to study the localization of the protein.     

The lipid requirements of mediatophore for acetylcholine release activity. Large-scale purification of this protein in a reactive form

The mediatophore, a protein which translocates acetylcholine, has been recently purified from the plasma membrane of the Torpedo electric organ nerve terminals. The functional integrity of the mediatophore requires the presence of lipids. Removal of associated lipids led to an irreversible loss of activity when obtained by ether precipitation of the protein. A two-phase extraction procedure was developed to gently remove the lipids. Conditions were found to reactivate the protein by emulsifying it with electric organ lipids. A large-scale preparation procedure of the delipidified mediatophore in a reactive form is described.     

Evoked Acetylcholine Release Expressed in Neuroblastoma Cells by Transfection of Mediatophore cDNA

Abstract: Transmitter release was elicited in two ways from cultured cells filled with acetylcholine: (a) in a biochemical assay by successive addition of a calcium ionophore and calcium and (b) electrophysiologically, by electrical stimulation of individual cells and real-time recording with an embryonic Xenopus myocyte. Glioma C6-Bu-1 cells were found to be competent for Ca²⁺-dependent and quantal release. In contrast, no release could be elicited from mouse neuroblastoma N18TG-2 cells. However, acetylcholine release could be restored when N18TG-2 cells were transfected with a plasmid coding for mediatophore. Mediatophore is a protein of nerve terminal membranes purified from the Torpedo electric organ on the basis of its acetylcholine-releasing capacity. The transfected N18TG-2 cells expressed Torpedo mediatophore in their plasma membrane. In response to an electrical stimulus, they generated in the myocyte evoked currents that were curare sensitive and calcium dependent and displayed discrete amplitude levels, like in naturally occurring synapses.     

Detection with Monoclonal Antibodies of a 15-kDa Proteolipid in Both Presynaptic Plasma Membranes and Synaptic Vesicles in Torpedo Electric Organ

A protein, the mediatophore, has been purified from Torpedo electric organ presynaptic plasma membranes. This protein mediates the release of acetylcholine through artificial membranes when activated by calcium and is made up of 15-kDa proteolipid subunits. After immunization with purified delipidated mediatophore, monoclonal antibodies binding to the 15-kDa proteolipid band on Western blots of purified mediatophore were selected. A 15-kDa proteolipid antigen was also detected in cholinergic synaptic vesicles. Using an immunological assay, it was estimated that presynaptic plasma membranes and synaptic vesicles contain similar proportions of 15-kDa proteolipid antigen. Detection by immunofluorescence in the electric organ showed that only nerve endings were labeled. In electric lobes, the staining was associated with intracellular membranes of the electroneuron cell bodies and in axons. Nerve endings at Torpedo neuromuscular junctions were also labeled with anti-15-kDa proteolipid monoclonal antibodies.     

Ultrastructural Changes Induced by 12-O-Tetradecanoylphorbol 13-Acetate in Pure Cholinergic Synaptosomes of Torpedo Electric Organ

We have studied the morphological changes induced by the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA) treatment on pure cholinergic synaptosomes from Torpedo electric organ. These changes were studied by both ultrathin sections and freeze-fracture techniques. We found that after a treatment with TPA, a redistribution of synaptic vesicles inside the nerve endings and exocytotic images could be observed. Also, TPA, under conditions that induced the acetylcholine release, did not change the density of intramembrane particles at the synaptosomal protoplasmic hemimembrane leaflet. Similar results were found when calcium was not present in the extrasynaptosomal medium, and our results suggest that acetylcholine release induced by phorbol ester is probably mediated by exocytosis of synaptic vesicles.     

Effect of cetiedil on acetylcholine release and intramembrane particles in cholinergic synaptosomes

The release of acetylcholine (ACh) from instantly frozen Torpedo electric organ synaptosomes in the course of stimulation is systematically associated with an increase in the number of large intramembrane particles counted on freeze-fracture replicas. The drug cetiedil, which is a potent inhibitor of ACh release, also blocks the increase in the number of large particles. The blockage was studied either after ionophore A 23187 or Glycera neurotoxin action in the presence of calcium.     

Neurotransmitter release at rapid synapses

The classical concept of the vesicular hypothesis for acetylcholine (ACh) release, one quantum resulting from exocytosis of one vesicle, is becoming more complicated than initially thought. 1) synaptic vesicles do contain ACh, but the cytoplasmic pool of ACh is the first to be used and renewed on stimulation. 2) The vesicles store not only ACh, but also ATP and Ca(2+) and they are critically involved in determining the local Ca(2+) microdomains which trigger and control release. 3) The number of exocytosis pits does increase in the membrane upon nerve stimulation, but in most cases exocytosis happens after the precise time of release, while it is a change affecting intramembrane particles which reflects more faithfully the release kinetics. 4) The SNARE proteins, which dock vesicles close to Ca(2+) channels, are essential for the excitation-release coupling, but quantal release persists when the SNAREs are inactivated or absent. 5) The quantum size is identical at the neuromuscular and nerve-electroplaque junctions, but the volume of a synaptic vesicle is eight times larger in electric organ; at this synapse there is enough ACh in a single vesicle to generate 15-25 large quanta, or 150-200 subquanta. These contradictions may be only apparent and can be resolved if one takes into account that an integral plasmalemmal protein can support the formation of ACh quanta. Such a protein has been isolated, characterised and called mediatophore. Mediatophore has been localised at the active zones of presynaptic nerve terminals. It is able to release ACh with the expected Ca(2+)-dependency and quantal character, as demonstrated using mediatophore-transfected cells and other reconstituted systems. Mediatophore is believed to work like a pore protein, the regulation of which is in turn likely to depend on the SNARE-vesicle docking apparatus.     

Immunolabelling of the presynaptic membrane of Torpedo electric organ nerve terminals with an antiserum towards the acetylcholine releasing protein mediatophore

Mediatophore is a nerve terminal membrane protein purified from Torpedo electric organ on its ability to translocate acetylcholine upon calcium action. An antiserum able to immunoprecipitate mediatophore activity was used to study the subcellular distribution of this protein. The presynaptic membrane exhibited a strong and discontinuous immunogold labelling, especially at the active zone where ACh is thought to be released. Two antigens were recognized on immunoblots of synaptosomal membranes: the 15-kDa subunit of mediatophore and a 14-kDa membrane protein that has a wide non-neuronal distribution. Antibodies purified from the serum on native mediatophore and monospecific towards the 15-kDa antigen still gave a high presynaptic membrane localized labelling. In addition, a few 14-kDa protein sites were present at the active zone. The Schwann cell finger interposed between the presynaptic membrane and the postsynaptic arch also exhibited the 14-kDa antigen raising the question of a possible interaction of mediatophore with the 14-kDa protein originating from the Schwann cell.     

Is the acetylcholine releasing protein mediatophore present in rat brain?

Mediatophore is a protein purified from the nerve terminal membranes of Torpedo electric organ. It confers to artificial membranes a calcium-dependent mechanism that translocates acetylcholine. When similar reconstitution experiments are applied to rat brain synaptosomal membranes they reveal the presence of mediatophore activity with properties close to those described for the Torpedo protein (extractability, sensitivity to calcium, and effect of the drug cetiedil). The activity was more abundant in synaptosomal membranes than in mitochondrial or myelinic membranes and in cholinergic areas as compared to cerebellum.     

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.     

Structural changes at pure cholinergic synaptosomes during the transmitter release induced by A-23187 inTorpedo marmorata

Summary Pure cholinergic synaptosomes isolated from the electric organ ofTorpedo 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 quickfreezing 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     

Cetiedil, a Drug That Inhibits Acetylcholine Release in Torpedo Electric Organ

The effects of cetiedil, a vasodilatator substance with reported anticholinergic properties, were examined on cholinergic presynaptic functions at the nerve electroplaque junction of Torpedo marmorata using either synaptosomes or slices of intact tissue. Cetiedil abolished the calcium-dependent release of acetylcholine (ACh) triggered by depolarization or by addition of A23187 ionophore, a finding localizing the site of action downstream from the calcium entry step. In addition, a direct effect on the release process itself was indicated by the observation that cetiedil blocks the release of ACh mediated by a recently isolated presynaptic membrane protein, the mediatophore, reconstituted into ACh-containing proteoliposomes. In all three preparations, ACh release was inhibited by cetiedil with a Ki of 5-8 microM. Under the conditions used in these release experiments, the synthesis of ACh and its compartmentation within the nerve terminals were not modified. However, the drug was able to reduce high-affinity choline uptake and vesicular ACh incorporation when it was given together with the radioactive precursor, a result showing that cetiedil has a broad inhibitory action on cholinergic uptake processes.     

The release of acetylcholine: from a cellular towards a molecular mechanism

The isolation of synaptic vesicles rich in acetylcholine (ACh) from the electric organ of Torpedo has indeed strengthened the hypothesis of transmitter exocytosis, but soon after it was found that non-vesicular free ACh was released and renewed upon stimulation. In contrast, vesicular ACh and the number of vesicles remained stable during physiological stimulations. In addition free ACh variations (representing the cytoplasmic pool) were correlated to the release kinetics as measured by the electroplaque discharge. Consequently, the mechanism releasing ACh from the cytoplasm in a packet form was searched at the presynaptic membrane itself. With synaptosomes isolated from the electric organ of Torpedo, it became possible to freeze them rapidly at the peak of ACh release and study their membrane and contents after cryofracture. A statistical analysis showed that the main structural change was the occurrence of large intramembrane particles at the peak of ACh release and under all release conditions. This impressive change contrasted with the stability in the number of vesicles. Another role for the vesicle was envisaged during intense stimulations when the cytoplasmic ACh and ATP pools become exhausted. The decrease in ATP leads to an increase in calcium and protons in the cytoplasm; this signals the depletion of vesicular ACh and ATP stores in the cytoplasm. Release can go on, while ATP promotes the uptake of calcium by vesicles. At the end of its cycle the vesicle will be full of calcium and will perhaps release it. As far as the mechanism of ACh release is concerned it probably depends on a membrane component (perhaps the large particles) activated by calcium and able to translocate ACh in a quantal or subquantal form. In most recent work we showed that if a lyophilized presynaptic membrane was used to make proteoliposomes filled with ACh, they released ACh upon calcium action.     

Acetylcholine Translocating Protein: Mediatophore at Rat Neuromuscular Synapses

The neuromuscular synapses of the rat sternomastoid muscles contain a membrane protein, mediatophore, that endows artificial membranes with a calcium-dependent acetylcholine release mechanism. Mediatophore and choline acetylase had similar distributions along the muscle. Sciatic nerve membranes contain mediatophore, and a purified preparation was obtained from the nerve.     

Calcium-Induced Desensitization of Acetylcholine Release from Synaptosomes or Proteoliposomes Equipped with Mediatophore, a Presynaptic Membrane Protein

A "fatigue" of acetylcholine (ACh) release is described in cholinergic synaptosomes stimulated with the calcium ionophore A23187 or gramicidin. A small conditioning calcium entry, which did not trigger a large ACh release, led to a decrease of transmitter release elicited by a second large calcium influx. This fatigue was half-maximal at approximately 30 microM external calcium and developed in a few minutes. In contrast, activation of release by calcium was very rapid and was half-maximal at approximately 0.5 mM external calcium. Activation and desensitization of release could be attributed to the recently identified presynaptic membrane protein, the "mediatophore." Proteoliposomes equipped with purified mediatophore showed a calcium-dependent activation and "fatigue" of ACh release similar to that of synaptosomes. It was found that the ionophore A23187 rapidly equilibrated internal and external calcium concentrations in proteoliposomes. Thus, the external calcium concentration gave the internal concentration required for activation or desensitization of proteoliposomal ACh release. The mediatophore showed remarkable calcium binding properties (20 sites/molecule) with a KD of 25 microM. The physiological implications of desensitization on the organization of release sites are discussed.     

Binding of a Glycera convoluta neurotoxin to cholinergic nerve terminal plasma membranes

The crude extract of venom glands of the polychaete annelid Glycera convoluta triggers a large Ca2+-dependent acetylcholine release from both frog motor nerve terminals and Torpedo electric organ synaptosomes. This extract was partially purified by Concanavalin A affinity chromatography. The biological activity was correlated in both preparations to a 300,000-dalton band, as shown by gel electrophoresis. This confirmed previous determinations obtained with chromatographic methods. This glycoprotein binds to presynaptic but not postsynaptic plasma membranes isolated from Torpedo electric organ. Pretreatment of intact synaptosomes by pronase abolished both the binding and the venom- induced acetylcholine release without impairing the high K+-induced acetylcholine release. Pretreatment of nerve terminal membranes by Concanavalin A similarly prevented the binding and the biological response. Binding to Torpedo membranes was still observed in the presence of EGTA. An antiserum directed to venom glycoproteins inhibited the neurotoxin so we could directly follow its binding to the presynaptic membrane. Glycera convoluta neurotoxin has to bind to a ectocellularly oriented protein of the presynaptic terminal to induce transmitter release.     

Hormones and neurotransmitters release: four mechanisms of secretion

Distinct mechanisms operate in different secreting systems, they are 1) free diffusion through the plasma membrane; 2) exocytosis resulting from fusion of a secretory granule with the plasma membrane; 3) fleeting release from a granule through a transient pore without full fusion; 4) release through a specialised plasmalemmal molecule such as the mediatophore. The latter mechanism is proposed to operate in rapid synapses in which the neurotransmitter is emitted as an abrupt chemical impulse of quantal composition. There, release is momentarily signalled in the plasma membrane by large intramembrane particles. Synaptic vesicles are also essential for regulation of this type of release. They fuse with the plasma membrane only late after activity and seem to be involved in calcium sequestration and extrusion.     

Opiates Inhibit Acetylcholine Release from Torpedo Nerve Terminals by Blocking Ca2+ Influx

Abstract: In the present communication we report that Ca²⁺-dependent acetylcholine release from K⁺-depolarized Torpedo electric organ synaptosomes is inhibited by morphine, and that this effect is blocked by the opiate antagonist naloxone. This finding suggests that the purely cholinergic Torpedo electric organ neurons contain pre-synaptic opiate receptors whose activation inhibits acetylcholine release. The mechanisms underlying this opiate inhibition were investigated by comparing the effects of morphine on acetylcholine release induced by K⁺ depolarization and by the Ca²⁺ ionophore A23187 and by examining the effect of morphine on ⁴⁵Ca²⁺ influx into Torpedo nerve terminals. These experiments revealed that morphine inhibits ⁴⁵Ca²⁺ influx into K⁺-depolarized Torpedo synaptosomes and that this effect is blocked by naloxone. The effects of morphine on K⁺ depolarization-mediated ⁴⁵Ca²⁺ influx and on acetylcholine release have similar dose dependencies (half-maximal inhibition at 0.5–1 μ M ), suggesting that opiate inhibition of release is due to blockage of the presynaptic voltage-dependent Ca²⁺ channel. This conclusion is supported by the finding that morphine does not inhibit acetylcholine release when the Ca²⁺ channel is bypassed by introducing Ca²⁺ into the Torpedo nerve terminals via the Ca²⁺ ionophore.