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.     

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.     

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.     

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.     

ASSOCIATION OF SYNTAXIN WITH SNAP 25 AND VAMP (SYNAPTOBREVIN) IN TORPEDO SYNAPTOSOMES

Two proteins of the presynaptic plasma membrane, syntaxin and SNAP 25, and VAMP/synaptobrevin, a synaptic vesicle membrane protein, form stable protein complexes which are involved in the docking and fusion of synaptic vesicles at the mammalian brain presynaptic membrane. Similar protein complexes were revealed in an homogeneous population of cholinergic synaptosomes purified from Torpedo electric organ by combining velocity sedimentation and immunoprecipitation experiments. After CHAPS solubilization, virtually all the nerve terminal syntaxin was found in the form of large 16 S complexes, in association with 65% of SNAP 25 and 15% of VAMP. Upon Triton X100 solubilization, syntaxin was still recovered in association with SNAP 25 and VAMP but in smaller 8 S complexes. A small (2–5%) percentage of the nerve terminal 15 kDa proteolipid subunit of the v-H⁺ ATPase and of mediatophore was copurified with syntaxin, using two different antisyntaxin monoclonal antibodies. The use of an homogeneous population of peripheral cholinergic nerve terminals allowed us to extend results on the composition of the brain presynaptic protein complexes to the Torpedo electric organ synapse, a model of the rapid neuromuscular synapses. Copyright © 1996 Elsevier Science Ltd     

The same 15 kDa proteolipid subunit is a constituent of two different proteins in torpedo, the acetylcholine releasing protein mediatophore and the vacuolar HATPase

Using the monoclonal antibody 15KI, we have studied, at the cellular and subcellular levels, the distribution of a 15 kDa proteolipid, identified as the subunit of mediatophore, a presynaptic membrane protein able to release acetylcholine when activated by calcium. Aside from the electric lobe, the antigen distribution in the brain of Torpedo paralleled that of the synaptic vesicle antigen SV2 and did not appear to be related to that of acetylcholine and choline acetyltransferase. The 15 kDa proteolipid antigen was therefore present in all nerve endings and not restricted to cholinergic ones. At the ultrastructural level, on cholinergic nerve endings, the antigen was detected associated to synaptic vesicles and, to a lesser extent, to the presynaptic plasma membrane. Indeed, considering the high sequence homology between the mediatophore subunit (Birman et al., 1990) and the proteolipid subunit of the vacuolar type H⁺ATPase, a major enzyme constituent of synaptic vesicles, this distribution was not surprising.

To determine whether antibody 15KI recognizes the vacuolar type H⁺ATPase, we chose a non neuronal cell type which possesses a high content of this enzyme, the kidney proton secreting epithelial cells. Indeed, antibody 15KI intensely labelled the apical plasma membrane of mitochondria rich epithelial cells in kidney tubules. A high density of the antigen was also found associated to intracellular membrane structures such as lysosomal multivesicular bodies, both in kidney epithelial cells and in electromotoneurons. The 15 kDa proteolipid antigen was associated with other vacuolar H⁺ATPase subunits in kidney membranes which was not the case in presynaptic plasma membranes. This illustrates that the 15 kDa proteolipid antigen is a constituent of two different protein complexes, which exhibit very different functional properties.     

Antipeptide Antibodies Against a Torpedo Cysteine-String Protein

Abstract: An antipeptide antiserum was raised against the C-terminal undecapeptide of a Torpedo cysteine-string protein (csp), a putative subunit or modulator of presynaptic calcium channels. This antiserum was shown to identify selectively the 27-kDa in vitro translation product of the csp cRNA both by immunoprecipitation and on immunoblots. When affinity-purified anti-csp antibodies were used to probe immunoblots of membrane proteins from Torpedo electric organ or liver, specific immunoreactivity was detected only in electric organ. This immunoreactivity was associated principally with a single protein species of about 34 kDa. These results indicate that csp immunoreactivity is detectably expressed in electroplax, a heavily innervated tissue, but not in liver, which should have an appreciably lower abundance of presynaptic calcium channel proteins. Moreover, the increased relative molecular mass of csp in electric organ (compared with in vitro translated material) implies that csp is posttranslationally modified. Finally, immunoblot analysis of either intact, alkali-treated, or solubilized membrane fractions of electric organ reveals that csp is predominantly a membrane protein.     

Evidence for an Association of the 15-kDa Proteolipid of Mediatophore with a 14-kDa Polypeptide

The present report shows that mediatophore, a nerve terminal membrane protein that translocates acetylcholine on calcium action, forms a complex with a 14-kDa polypeptide. The complex was identified based on the following results. (a) A polyclonal antimediatophore antiserum that immunoprecipitates activity precipitates both the 15- and 14-kDa polypeptides. (b) After HPLC purification of mediatophore, both antigens were found in the same peak. (c) After 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate solubilization of presynaptic membranes or of the purified mediatophore, an immunoaffinity column made with the anti-14-kDa antigen monoclonal antibody retained both the 14-kDa and the 15-kDa polypeptide. Similarly, immunoprecipitation experiments using protein A-coated beads sedimented an immunocomplex in which both antigens were found. (d) The 14-kDa antigen could be localized in the synaptosomal membrane where mediatophore and its 15-kDa component are found.     

Characterization of two ectocellularly oriented 67 K presynaptic proteins. Lack of effect of their removal on acetylcholine release

A presynaptic plasma membrane fraction was purified after subfractionation of pure cholinergic synaptosomes prepared from Torpedo electric organ. Two 67 kdalton proteins were highly enriched in the synaptosomal plasma membrane (SPM): the hydrophobic form of AChE and a protein against which we raised a monoclonal antibody (C1–8). These two proteins exhibit similar biochemical properties: both exist as disulphide linked dimers with the same molecular weight; they are glycoproteins binding Concanavalin A; they are exposed on the external surface of the SPM and detached as almost entire molecules by Pronase. Nevertheless, using the C1–8 monoclonal antibody, it was possible to show that they are different proteins. The C1–8 binding protein appears to be specific for the SPM in Torpedo electric organ since it was not detected in plasma membranes from the electroplaque, the electric nerve trunks or the electric lobe. The hydrophobic AChE and the C1–8 binding protein appear therefore to be useful markers of the SPM. Pronase treatment of intact synaptosomes removes most of the ectocellularly exposed proteins of the SPM, which amount to 35% of the SPM protein. Presynaptic AChE and the C1–8 binding protein are detached. But ACh release can still be induced by depolarization of the Pronase treated synaptosomes. This demonstrates that the two 67 kdalton presynaptic proteins are not directly involved in the release of the neurotransmitter.     

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.     

Calcium-induced acetylcholine release and intramembrane particle occurrence in proteoliposomes equipped with mediatophore.

Proteoliposomes obtained from the mediatophore, a purified Torpedo electric organ nerve terminals protein, and endogenous lipids were used for a study of calcium-induced release of acetylcholine and freeze-fracture electron microscopy. Large intramembrane particles were induced by the influx of calcium into proteoliposomes, as previously observed for synaptosomes or stimulated electric organ nerve terminals. The involvement of mediatophore in a calcium dependent acetylcholine translocation seems therefore to be related to the occurrence of a category of intramembrane particles in the course of the release process.     

Effect of N,N-Dicyclohexylcarbodiimide on Acetylcholine Release from Torpedo Synaptosomes and Proteoliposomes Reconstituted with the Proteolipid Mediatophore

The mediatophore is a presynaptic membrane protein that has been shown to translocate acetylcholine (ACh) under calcium stimulation when reconstituted into artificial membranes. The mediatophore subunit, a 15-kDa proteolipid, presents a very high sequence homology with the N,N'-dicyclohexylcarbodiimide (DCCD)-binding proteolipid subunit of the vacuolar-type H(+)-ATPase. This prompted us to study the effect of DCCD, a potent blocker of proton translocation, on calcium-dependent ACh release. The present work shows that DCCD has no effect on ACh translocation either from Torpedo synaptosomes or from proteoliposomes reconstituted with purified mediatophore. However, using [14C]DCCD, we were able to demonstrate that the drug does bind to the 15-kDa proteolipid subunit of the mediatophore. These results suggest that although the 15-kDa proteolipid subunits of the mediatophore and the vacuolar H(+)-ATPase may be identical, different domains of these proteins are involved in proton translocation and calcium-dependent ACh release and that the two proteins have a different membrane organization.     

Isolation of Membrane Fractions with Sodium Channels Sensitive to Veratridine and tetrodotoxin from the Electric Organ of the Eel Electrophorus electricus

The veratridine/tetrodotoxin-sensitive sodium influx was measured in membrane fractions isolated from the electric organ of Electrophorus electricus. The fractions were characterized, and the main biochemical markers and their acetylcholine receptor content were determined. The innervated and noninnervated faces of the electroplax were separated. The different biochemical criteria used indicate that the pre- and postsynaptic membranes of the innervated face were isolated. Sodium influx increased by veratridine and blocked by tetrodotoxin was found in fractions from the presynaptic membrane. Because some of the vesicles in this fraction are in the inside-out conformation, tetrodotoxin had to be applied to both faces of the vesicles so that sodium influx was blocked completely. The fractions from the innervated face of the electroplax contained sodium channels with sensitivities to tetrodotoxin and veratridine similar to those of fractions from other nerve membrane preparations.     

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.     

Association of acetylcholinesterase with the external surface of the presynaptic plasma membrane in Torpedo electric organ

A high acetylcholinesterase (AChE) activity was found associated with pure cholinergic synaptosomes prepared from Torpedo electric organ. This activity was bound to the presynaptic plasma membrane upon subfractionation on sucrose density gradients. It was not solubilized in the presence of 2 M MgCl₂ but in the presence of Triton X 100. This presynaptic AChE activity corresponded to a hydrophobic form of the enzyme with a sedimentation coefficient of 5.5 S in our conditions. More than 80% of the AChE activity of intact synaptosomes was externally oriented. The presynaptic AChE activity could represent as much as 25% of the total activity in Torpedo electric organ.     

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.     

Ganglioside composition of subcellular fractions,including pre- and postsynaptic membranes,fromTorpedo electric organ

Gangliosides were isolated from four subcellular fractions of the electric organ ofTorpedo marmorata: synaptosomes, presynaptic membranes, postsynaptic membranes, and synaptic vesicle membranes. This exploited a principal advantage offered by this tissue: facile separation of pre-and postyynaptic elements. Total ganglioside concentration in presynaptic membranes was approximately twice that of synaptosomes and 15 times that of postsynaptic membranes (47.7, 24.4, and 3.21 g of lipid sialic acid per mg protein, respectively). Synaptic vesicle membranes had the highest overall concentration (78.9) relative to protein, but a concentration approximately comparable to that of presynaptic membranes when expressed relative to phospholipid. The thin-layer patterns of these two fractions were similar, both in terms of total pattern and the specific pattern of gangliotetraose structures as revealed by overlay with cholera toxin B subunit; these were notable for the paucity of monosialo structures and the virtual absence of GM1. Postsynaptic membranes, on the other hand, had a significantly higher content of monosialogangliosides including the presence of GM1. The synaptosomal pattern resembled that of the presynaptic membranes and synaptic vesicles. Thus, a clear difference in ganglioside pattern could be discerned between the pre- and postsynaptic elements of the electric organ.Abbreviations SVs synaptic vesicles - TLC thin-layer chromatography - cholera B-HRP B subunit of cholera toxin linked to horseradish peroxidase     

A Monoclonal Antibody Raised Against Plasma Membrane of Cholinergic Nerve Terminals of the Torpedo Inhibits Choline Acetyltransferase Activity and Acetylcholine Release

Monoclonal antibodies were raised against the synaptosomal plasma membranes (SPMs) purified from the electric organ of the Torpedo. One antibody that reacts preferentially with SPMs rather than with other membrane fractions isolated from this tissue was previously found to inhibit hydrophilic and amphiphilic choline-O-acetyltransferase (ChAT) activity. On immunoblots of SPMs, this antibody recognizes two polypeptides of 135 and 66 kilodaltons that are related; the 66-kilodalton polypeptide appears to exist as a monomer and as a dimer in SPMs. The antibody was also able to inhibit the calcium-dependent release of acetylcholine in Torpedo synaptosomes without affecting the total neurotransmitter content. This inhibition was dependent on the antibody concentration and was observed when the release was elicited by either KCl depolarization or the calcium ionophore A23187; this suggests that inhibition was not mediated by a blockage of the depolarization-activated calcium influx. The inhibition could not be prevented by atropine, a result indicating that the antibody does not block release by mimicking the action of acetylcholine on presynaptic muscarinic autoreceptors. Thus, the antigen recognized by this antibody appeared to be involved in acetylcholine release; this antigen could be membrane-bound ChAT, another protein of the SPMs, or both.