Increase in syntaxin 1B and glutamate release in mossy fibre terminals following induction of LTP in the dentate gyrus: a candidate molecular mechanism underlying transsynaptic plasticity.

A growing body of evidence suggests that modulation of certain proteins of the exocytotic machinery is, in part, involved in the biochemical changes that underlie long-term synaptic plasticity. We have previously shown that the induction of long-term potentiation (LTP) at perforant path to dentate granule cell synapses in the rat hippocampus induces changes in the mRNA levels of syntaxin 1B and synapsin I, known to be involved in neurotransmitter release. Immunohistochemical staining suggested that concomitant changes in these proteins occurred at mossy fibre synapses, downstream of those synapses at which LTP was induced, leading us to postulate that such a mechanism might underlie a form of transsynaptic plasticity. Here we have used a specific mossy-fibre synaptosome preparation to quantify levels of proteins and measure, using a chemiluminescent glutamate assay, depolarization-induced glutamate release from these synaptosomes after induction of LTP in the dentate gyrus in vivo. We show that 5 h after the induction of LTP, there is an increase in the protein levels of syntaxin 1B and, although to a lesser extent, the synapsins I and II, associated with an increase in depolarization-induced release of glutamate within these terminals. Increases in both the protein levels and glutamate release were not observed when dentate gyrus LTP was blocked by an NMDA receptor antagonist. From these results we propose a molecular mechanism for the propagation of synaptic plasticity through hippocampal circuits.

Enhanced acetylcholine release from cells that have more 15-kDa proteolipid in their membrane, a constituent V-ATPase, and mediatophore.

Mediatophore is a protein that translocates acetylcholine (ACh) on calcium action. It is a homopolymer of a 15-kDa proteolipid that is also a constituent of the membrane sector of vacuolar H+-adenosine trisphosphatase (V-ATPase; vacuolar proton pump). Experiments on neuroblastoma cell lines (N18TG-2) that are deficient for ACh release and on cells that are competent for release, such as the glioma C6BU-1 or the N18TG-2/C6BU-1 fusion product NG108-15, show that there is a correlation between ACh release and the 15-kDa proteolipid content of the cell membrane. In another cell line, L-M(TK-), it has been possible to up-regulate ACh release and the membrane proteolipid content after treating the cells with dibutyryl-cyclic AMP or dexamethasone. As mediatophore translocates ACh and as V-ATPase may help vesicular ACh storage, it was interesting to determine the respective role of the two proteins in the observed correlation between release and proteolipid content. After blocking vesicular loading with vesamicol, we did not affect release from these cells, suggesting that the observed correlation may be attributed to mediatophore. The acquisition of an ACh release mechanism would then depend on the process that guides the proteolipid to the plasma membrane of the cell.

Calcium-dependent release specificities of various cell lines loaded with different transmitters.

By loading cells in culture with acetylcholine (ACh) we have characterized a calcium-dependent release mechanism and shown that it was expressed independently of synthesis or storage of ACh. (Israël et al., 1994, Neurochemistry International 37, 1475-1483; Falk-Vairant et al., 1996a, Proc. Natl. Acad. Sci. U.S.A. 93, 5203-5207; Falk-Vairant et al., 1996b, Neuroscience 75, 353-360; Falk-Vairant et al., 1996c, Journal of Neuroscience Research 45, 195-201). The transmitter loading procedure was applied to two other transmitters, gamma-aminobutyric acid (GABA) and glutamate (Glu). We could then study the specificity of the release mechanism for the three transmitters in a variety of cell lines, including neural-derived cells. Four different calcium-dependent release phenotypes were identified: two were specific for ACh or GABA, and two co-released two transmitters ACh and GABA but not Glu, or ACh and Glu but not GABA. We conclude that release mechanisms having different specificities are expressed by the cell lines studied, they become functional after loading the cells with the relevant transmitters. These observations will help the identification of proteins controlling the specificity of release, and provide an interesting model for pharmacological studies.

A bioluminescent gamma-aminobutyrate assay for monitoring its release from inhibitory nerve endings.

A bioluminescent GABA assay is described. The principle of the procedure is based on the action of GABASE (GABA-aminotransferase plus succinic semialdehyde dehydrogenase), coupled to the detection of succinic semialdehyde and NADH, using Photobacterium luciferase. The method was used for monitoring GABA release from depolarized brain slices.

Enhancement of quantal transmitter release and mediatophore expression by cyclic AMP in fibroblasts loaded with acetylcholine.

Neuronal properties such as neurotransmitter uptake and release can be expressed in non-neuronal cells. We show here that fibroblasts-mouse cell line L-M(TK-)-are able to take up acetylcholine from the external medium and to release it in response to a calcium influx. Release was assessed biochemically by a luminescence method, but it was also elicited from individual fibroblasts and recorded in real-time using a Xenopus myocyte as an acetylcholine detector. After treatment for three to six days with dibutyryl-cyclic AMP, the cells changed their shape and acetylcholine release was greatly enhanced. Surprisingly, in differentiated fibroblasts the time-course transmitter release exhibited a high degree of variability even for the successive responses evoked from the same cell; many currents recorded in myocytes on electrical stimulation of fibroblasts had an extremely long duration (up to 1 s or more). This suggested that the release sites were kept open for a very long time. Cyclic AMP treatment also caused a marked increase in the expression of mediatophore 16,000 mol. wt proteolipid in fibroblast membranes. Mediatophore is an acetylcholine-translocating protein which is abundant in cholinergic presynaptic plasma membranes. It is concluded that cyclic AMP differentiation of fibroblasts prolongs the duration of acetylcholine release at individual sites and enhances the expression of the 16,000 mol. wt proteolipid-forming mediatophore.

Activation and desensitisation of acetylcholine release by zinc at Torpedo nerve terminals.

Treatment with 100 or 250 microM ZnCl2 irreversibly blocked neurotransmission in the Torpedo electric organ by inhibiting acetylcholine (ACh) release. In Zn2+-treated tissue, release failure did not result from impairment of Ca2+ entry since stimulation still provoked an accumulation of Ca2+. Also pretreatment of isolated synaptosomes with Zn2+ inhibited to the same extent the release elicited by KCl-evoked depolarisation and the release elicited by using the Ca2+ ionophore A23187. On the other hand, after application of A23187, Zn2+ by itself efficiently triggered ACh release from synaptosomes. This dual effect of Zn2+ was also observed to occur in proteoliposomes equipped with mediatophore (a protein of the presynaptic membrane characterised by its capability to support Ca2+-dependent transmitter release). Hence, Zn2+ mimicked two fundamental actions of Ca2+ on nerve terminals, which are: (1) the immediate activation of release, and (2) a more slowly developing desensitisation of release. Zn2+ was more powerful than Ca2+ for both actions. It is concluded that the dual action of Zn2+ on the mediatophore protein accounts at least in part for its complex effects on neurotransmission.

Cell lines expressing an acetylcholine release mechanism; correction of a release-deficient cell by mediatophore transfection.

Several neuronal and non-neuronal cell lines express a Ca(2+)-dependent mechanism of transmitter release that can be demonstrated after loading the cells with acetylcholine during culture. In contrast, a particular cell line, the neuroblastoma N18TG-2, was found to be deficient for release. We transfected N18TG-2 cells with a plasmid encoding Torpedo mediatophore, a protein able to translocate acetylcholine in response to calcium. The N18TG-2 cells expressed the Torpedo protein which reached their plasma membrane. At the same time, these cells acquired a Ca(2+)-dependent quantal release mechanism similar to the one naturally expressed by other cell lines. Hence, the presence of mediatophore in the plasma membrane seems essential for quantal release.

Quantal acetylcholine release induced by mediatophore transfection.

Mediatophore is a protein of approximately 200 kDa able to translocate acetylcholine in response to calcium. It was purified from the presynaptic plasma membranes of the electric organ nerve terminals. Mediatophore is a homooligomer of a 16-kDa subunit, homologous to the proteolipid of V-ATPase. Cells of the N18TG-2 neuronal line are not able to produce quantal acetylcholine release. We show here that transfection of N18TG-2 cells with a plasmid encoding the mediatophore subunit restored calcium-dependent release. The essential feature of such a release was its quantal nature, similar to what is observed in situ in cholinergic synapses from which mediatophore was purified.

Evoked acetylcholine release expressed in neuroblastoma cells by transfection of mediatophore cDNA.

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 Ca(2+)-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.

Acetylcholine accumulation and release by hybrid NG108-15, glioma and neuroblastoma cells--role of a 16kDa membrane protein in release.

A procedure is described to fill up cells in culture with ACh and study its calcium dependent release, by-passing the synthesis steps. Whether differentiated or not with dbc-AMP, the NG108-15 cells efficiently released ACh when stimulated with calcium and ionophore A23187. The release was also studied in the parent C6-BU-1 and N18TG2 cells. It was found that C6-BU-1 released ACh much better that N18TG2 in spite of their glial origin. The internalization by NG108-15 cells of an antisense oligonucleotide probe hybridizing the 16 kDa proteolipid messenger common to mediatophore and to the V-ATPase reduced ACh release indicated a role of this proteolipid in ACh translocation. This characteristic protein was found in the membrane extract of NG108-15 cells and also in the C6-BU-1 cells, but its amount was strongly reduced in the N18TG2 cell line and in the NG108-15 cells having internalized the antisense probe.

In vitro expression of the 15 kDa subunit of the mediatophore and functional reconstitution of acetylcholine release.

The mediatophore is a presynaptic oligomeric protein purified from the presynaptic plasma membrane of Torpedo synaptosomes on the basis of its ability to mediate a calcium-dependent acetylcholine release when solubilized and reconstituted into proteoliposomes. We investigated the ACh translocating activity of the 15 kDa proteolipid subunit of the mediatophore when expressed in Xenopus oocytes and reconstituted into proteoliposomes loaded with ACh. 1. A calcium-dependent ACh translocation was observed when oocytes were injected with polyadenylated mRNAs extracted from the electric lobe of the Torpedo brain or with an in vitro transcribed RNA encoding the 15 kDa subunit. 2. No release response was obtained when oocytes were non-injected or injected with Torpedo liver mRNAs. 3. This ACh translocation mechanism showed calcium-dependent activation and desensitisation and was inhibited by cetiedil, sharing these properties with the release of ACh observed at the synapse. 4. The ACh translocating activity of an N terminal deleted mediatophore 15 kDa subunit was strongly reduced and the deleted proteolipid appeared less sensitive to the action of cetiedil (alpha-cyclohexyl-alpha-(3-thienyl)-acetate of perhydroazepinyl-alpha-ethyl citrate monohydrate). 5. A significant ACh release response was observed when the 15 kDa proteolipid of the H(+)-ATPase from bovine chromaffin granules was tested. 6. These results show that this ACh translocating activity could be induced in the oocyte membranes by the expression of the 15 kDa subunit alone.

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.

Glutamate and acetylcholine release from cholinergic nerve terminals, a calcium control of the specificity of the release mechanism.

We describe, in the present work, a continuous procedure for measuring the release of glutamate, and have applied it to analyze the co-release of glutamate and acetylcholine from cholinergic nerve terminals of electric organ synaptosomes. The two substances were measured in similar conditions using the two continuous chemiluminescent assays. The protein "Mediatophore" reconstituted in proteoliposomes was also able to translocate both transmitters with a preference for glutamate when the external calcium was increased between 3 and 10 mM. However, at lower calcium concentrations a clear preference for acetylcholine was found. For a regulated calcium entry as obtained by electrical stimulation of the nerve the release mechanism was fully specific for acetylcholine. Since the specificity of mediatophore depends on the local calcium amounts, the possible role of mediatophore at acetylcholine or glutamate specific synapses may be envisaged and is discussed in relation to the calcium control of specificity.

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.

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.

[Comparison of synaptic vesicles of neuromuscular and nerve electroplaque junctions in Torpedo marmorata]. / Comparaison des vésicules synaptiqus des jonctions nerf-muscle et nerf-électroplaque chez Torpedo marmorata.

A morphological comparison of neuromuscular and nerve-electroplaque synapses of torpedo was performed. Synaptic vesicles are much smaller at the neuromuscular synapse. The question of the respective role of these populations is raised.

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.

A 15 kDa proteolipid found in mediatophore preparations from Torpedo electric organ presents high sequence homology with the bovine chromaffin granule protonophore.

Upon SDS PAGE of isolated mediatophore, an acetylcholine-translocating protein, a doublet at 15 kDa was identified. Amino acid sequencing after CNBr cleavage gave a 17 residue-long peptide completely homologous with a sequence of the proton-translocating proteolipid from bovine chromaffin granules. A 51-mer oligodeoxynucleotide corresponding to this sequence was used to screen a library of electric lobe cDNAs constructed in lambda Zap II. A positive recombinant clone was isolated and found to encode the complete sequence of a 15.5 kDa protein highly homologous to the bovine chromaffin or yeast vacuolar ATPase proteolipid. In vitro translation of sense RNA transcripts of the clone indeed yielded a single 15 kDa proteolipid. Northern blot analysis showed that the 1.3 kb mRNA encoding this protein is significantly expressed in nervous tissues but not in electric organ or liver of Torpedo marmorata.

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.

Effect of cetiedil analogs on acetylcholine and choline fluxes in synaptosomes and vesicles.

Cetiedil is a potent blocker of acetylcholine and choline fluxes. Several analogs of this compound have been synthesized and their effect on acetylcholine (ACh) and choline fluxes in synaptosomes and on ACh uptake in synaptic vesicles have been studied. The effects of these analogs were compared to those of other drugs acting on cholinergic functions. All these compounds were also studied in relation to the ACh translocating properties of the mediatophore, a protein recently purified from cholinergic nerve membranes and probably involved in the final step of release. We thus obtained a pattern of drug action for the three functions under study. The patterns of drug action on ACh release from synaptosomes or proteoliposomes were similar and clearly different from those for either synaptosomal choline transport or vesicular ACh uptake. In addition, the main outlines of the structure-function relationship for each of the functions studied, are described for cetiedil analogs.