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

Pyrrole Plasma Polymer-Coated Electrospun Scaffolds for Neural Tissue Engineering

Promising strategies for neural tissue engineering are based on the use of three-dimensional substrates for cell anchorage and tissue development. In this work, fibrillar scaffolds composed of electrospun randomly- and aligned-oriented fibers coated with plasma synthesized pyrrole polymer, doped and undoped with iodine, were fabricated and characterized. Infrared spectroscopy, thermogravimetric analysis, and X-ray diffraction analysis revealed the functional groups and molecular integration of each scaffold, as well as the effect of plasma polymer synthesis on crystallinity. Scanning microscopy imaging demonstrated the porous fibrillar micrometric structure of the scaffolds, which afforded adhesion, infiltration, and survival for the neural cells. Orientation analysis of electron microscope images confirmed the elongation of neurite-like cell structures elicited by undoped plasma pyrrole polymer-coated aligned scaffolds, without any biochemical stimuli. The MTT colorimetric assay validated the biocompatibility of the fabricated composite materials, and further evidenced plasma pyrrole polymer-coated aligned scaffolds as permissive substrates for the support of neural cells. These results suggest plasma synthesized pyrrole polymer-coated aligned scaffolds are promising materials for tissue engineering applications.

Cholinergic Machinery as Relevant Target in Acute Lymphoblastic T Leukemia

Various types of non-neuronal cells, including tumors, are able to produce acetylcholine (ACh), which acts as an autocrine/paracrine growth factor. T lymphocytes represent a key component of the non-neuronal cholinergic system. T cells-derived ACh is involved in a stimulation of their activation and proliferation, and acts as a regulator of immune response. The aim of the present work was to summarize the data about components of cholinergic machinery in T lymphocytes, with an emphasis on the comparison of healthy and leukemic T cells. Cell lines derived from acute lymphoblastic leukemias of T lineage (T-ALL) were found to produce a considerably higher amount of ACh than healthy T lymphocytes. Additionally, ACh produced by T-ALL is not efficiently hydrolyzed, because acetylcholinesterase (AChE) activity is drastically decreased in these cells. Up-regulation of muscarinic ACh receptors was also demonstrated at expression and functional level, whereas nicotinic ACh receptors seem to play a less important role and not form functional channels in cells derived from T-ALL. We hypothesized that ACh over-produced in T-ALL may act as an autocrine growth factor and play an important role in leukemic clonal expansion through shaping of intracellular Ca²⁺ signals. We suggest that cholinergic machinery may be attractive targets for new drugs against T-ALL. Specifically, testing of high affinity antagonists of muscarinic ACh receptors as well as antagomiRs, which interfere with miRNAs involved in the suppression of AChE expression, may be the first choice options.

Axon terminals from the nucleus isthmi pars parvocellularis control the ascending retinotectofugal output through direct synaptic contact with tectal ganglion cell dendrites

The optic tectum in birds and its homologue the superior colliculus in mammals both send major bilateral, nontopographic projections to the nucleus rotundus and caudal pulvinar, respectively. These projections originate from widefield tectal ganglion cells (TGCs) located in layer 13 in the avian tectum and in the lower superficial layers in the mammalian colliculus. The TGCs characteristically have monostratified arrays of brush-like dendritic terminations and respond mostly to bidimensional motion or looming features. In birds, this TGC-mediated tectofugal output is controlled by feedback signals from the nucleus isthmi pars parvocellularis (Ipc). The Ipc neurons display topographically organized axons that densely ramify in restricted columnar terminal fields overlapping various neural elements that could mediate this tectofugal control, including the retinal terminals and the TGC dendrites themselves. Whether the Ipc axons make synaptic contact with these or other tectal neural elements remains undetermined. We double labeled Ipc axons and their presumptive postsynaptic targets in the tectum of chickens (Gallus gallus) with neural tracers and performed an ultrastructural analysis. We found that the Ipc terminal boutons form glomerulus-like structures in the superficial and intermediate tectal layers, establishing asymmetric synapses with several dendritic profiles. In these glomeruli, at least two of the postsynaptic dendrites originated from TGCs. We also found synaptic contacts between retinal terminals and TGC dendrites. These findings suggest that, in birds, Ipc axons control the ascending tectal outflow of retinal signals through direct synaptic contacts with the TGCs.

Estradiol regulates alternative splicing of estrogen receptor-alpha mRNA in differentiated NG108-15 neuronal cells

The biological actions of estrogen are mostly conveyed through interaction with two different types of estrogen receptor (ER), ER-alpha and ER-beta. With regard to ER-alpha, an alternatively spliced form and its translated product, truncated estrogen receptor product-1 (TERP-1), have been identified in the rat pituitary. TERP-1 has the ability to inhibit the ER binding to DNA response element by forming hetero-dimers with the wild-type ER. Furthermore, TERP-1 expression increased concurrently with serum estrogen levels. Although estrogen also plays important roles in the central nervous system, the existence and regulatory mechanism of alternatively spliced ER-alpha mRNA expression has remained unclear. The present study evaluated the expression of the alternatively spliced form of the ER-alpha gene, and examined the influence of a representative ER ligand, 17beta-estradiol (E2), on the expression in differentiated NG108-15 neuronal cells. A real-time RT-PCR analysis using primer sets designed to amplify from exons 3 to 4, exons 4 to 5, exons 5 to 6, exons 6 to 7, and exons 7 to 8 of the mouse ER-alpha gene revealed the existence of alternatively spliced ER-alpha mRNA and its putative transcription initiation site, located between exon 4 and exon 5. Although E2 had no apparent effect on the overall expression of ER-alpha mRNA, it reduced the incidence of the alternatively spliced form of ER-alpha. The down-regulation by E2 predominantly arose via binding to nuclear ERs. The present study demonstrated that alternatively spliced ER-alpha mRNA is expressed in differentiated NG108-15 neuronal cells, and provides evidence for the functional up-regulation of ER-alpha via the ligand-binding activation of ERs.

Expression of the acetylcholine release mechanism in various cells and reconstruction of the release mechanism in non-releasing cells

After loading cells in culture with acetylcholine (ACh), it was possible to identify cells that express a calcium-dependent release mechanism and cells that do not release. Mediatophore transfection restored the release capability of non-releasing cells. The transfection of choline acetyltransferase and the vesicular ACh transporter (VAChT) in cells that have already mediatophore in their membrane enables to study the effect of VAChT on the release kinetics. We also studied the properties of the mediatophore "pore" as a function of the concentration of ACh and also its temporal properties. A reconstruction of the release mechanism in cells particularly graftable cells, appears now possibly for ACh and probably for other transmitters.

Quantal transmitter release by glioma cells: quantification of intramembrane particle changes

Glial cells in situ are able to release neurotransmitters such as glutamate or acetylcholine (ACh). Glioma C6BU-1 cells were used to determine whether the mechanisms of ACh release by a glial cell line are similar or not to quantal release from neurones. Individual C6BU-1 cells, pre-filled with ACh, were moved into contact with a Xenopus myocyte that was used as a real-time ACh detector. Upon electrical stimulation, C6BU-1 cells generated evoked ACh impulses which were Ca(2+)-dependent and quantal (quantal steps of ca. 100 pA). Changes in plasma membrane ultrastructure were investigated by using a freeze-fracture technique designed for obtaining large and flat replicas from monolayer cell cultures. A transient increase in the density of medium and large size intramembrane particles--and a corresponding decrease of small particles--occurred in the plasma membrane of C6BU-1 cells stimulated for ACh release. Changes in interaction forces between adjacent medium and large particles were investigated by computing the radial distribution function and the interaction potential. In resting cells, the radial distribution function revealed a significant increase in the probability to find two particles separated by an interval of 24 nm; the interaction potential suggested repulsive forces for intervals shorter than 24 nm and attractive forces between 24 and 26 nm. In stimulated cells, this interaction was displaced to 21 nm and made weaker, despite of the fact that the overall particle density increased. The nature of this transient change in intramembrane particles is discussed, particularly with regard to the mediatophore proteolipid which is abundant in the membranes C6-BU-1 like in those of cholinergic neurones. In conclusion, evoked ACh release from pre-filled C6-BU-1 glioma cells is quantal and Ca(2+)-dependent. It is accompanied by a transient changes in the size distribution and the organisation of intramembrane particles in the plasma membrane. Thus, for the release characteristics, glioma cells do not differ fundamentally from neurones.

Cellular resistance to Evans blue toxicity involves an up-regulation of a phosphate transporter implicated in vesicular glutamate storage

It has recently been suggested that the brain-specific Na+-dependent phosphate inorganic co-transporter (BNPI) is able to support glutamate transport and storage in synaptic vesicles. A procedure for measuring the vesicular pool of glutamate is described and was used to select cell lines according to their glutamate storage capacity. Two cell lines were selected: C6BU-1, with a large intracellular glutamate storage capacity, and NG108-15, devoid of it. Their contents in BNPI mRNA were compared by RT-PCR. We found that both cell lines had BNPI, but in addition C6BU-1 alone expresses the other isoform, DNPI. We also carried out a clonal selection of NG108-15 cells in the presence of the dye Evans blue, a competitive inhibitor of vesicular glutamate transport, very toxic for cells in culture. It was assumed that only those that sequester and eliminate the drug by overexpressing a vesicular glutamate transporter would survive. We found that the NG108-15 clones resistant to Evans blue had an increased storage capacity for glutamate. These cells also up-regulated the BNPI isoform of the phosphate transporter as shown by RT-PCR and northern blot.

Stimuli that induce a cholinergic neuronal phenotype of NG108-15 cells upregulate ChAT and VAChT mRNAs but fail to increase VAChT protein

The vesicular acetylcholine transporter (VAChT) and choline acetyltransferase (ChAT) are encoded by genes organized in a single gene locus, and coregulation of the transcription of the two genes has been repeatedly reported in cholinergic tissues. In the present study, different stimuli were used to induce the differentiation of the hybridoma cells NG108-15 and we examined their effects on the modulation of VAChT and ChAT expression at the mRNA and protein levels. All agents upregulated the VAChT and ChAT mRNA levels, but to a different extent. ChAT activity was increased by retinoic acid, dexamethasone, and dibutyrylcyclic AMP (dbcAMP), and a synergistic effect was observed with a combined dexamethasone and dbcAMP treatment. Nonetheless, no changes in the VAChT protein level could be observed, as judged from ligand binding studies as well as from immunochemical detection. Hemicholinium-3-sensitive choline uptake, hemicholinium-3 binding, and acetylcholine content were increased by differentiating agents, with a rank order of potency comparable to their effects on ChAT activity. Prominent changes were observed in the expression of vesicular protein markers, particularly with the associated treatment dexamethasone and dbcAMP. Thus, it appears that although the different stimuli we have been using are able to stimulate neuronal features and activate the transcription of cholinergic genes, they did not contrive to increase the level of VAChT protein in these cells.

Effect of brefeldin A on acetylcholine release from glioma C6BU-1 cells

The glial C6BU-1 cell line, loaded with acetylcholine can release this neurotransmitter. This study was aimed at determining whether disruption of the Golgi-vesicular traffic by brefeldin A would change the acetylcholine release from these cells and affect proteins involved in transmitter release like the 15 kDa proteolipid, common to V-ATPase and mediatophore. Cells were treated for 24 or 36 h with brefeldin A (35.7 microM). The observed changes in cell morphology were typical for brefeldin A treated cells in which protein membrane supply has been stopped. Inhibition of membrane protein supply was confirmed in the present work. Moreover, the 15 kDa proteolipid also decayed to a very low level in the cell membrane fraction. The release of acetylcholine evoked by a calcium challenge and a calcium ionophore, or by electrical pulses decreased markedly. The life time of the release mechanism was of the order of 36 h and half decayed in 24 h. In addition, the electrically evoked release became much shorter. Considering that C6BU-1 cells are able to release large amounts of ACh and their membranes contain a sizeable amount of the 15 kDa proteolipid, these results suggest that this proteolipid may be one of the proteins forming the membrane complex responsible for transmitter release, at least in these cells.

Role of mediatophore in connection with proteins of the active zone in synaptic transmission

Mediatophore is a protein purified from Torpedo electric organ synaptosomes, which translocates acetylcholine (ACh) upon calcium action after reconstitution in artificial membranes. After expression in transfected cells, it endows these cells with a calcium-dependent release mechanism displaying clear quantal properties. The role of mediatophore in synaptic transmission is discussed in relation to the ultrastructural organization of the active zone and the cytosolic high calcium microdomains that transiently appear after presynaptic membrane depolarization.

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.

Quantal acetylcholine release: vesicle fusion or intramembrane particles?

Images of vesicle openings in the presynaptic membrane have regularly been shown to increase in number after stimulation of cholinergic nerves. However, with a very few exceptions, the occurrence of vesicle openings is delayed in time with respect to the precise moment of transmitter release. In contrast, a transient change in the size and distribution of intramembrane particles (IMPs) has constantly been found as a characteristic change affecting the presynaptic membrane in a strict time coincidence with the release of acetylcholine quanta. This is illustrated here in a rapid-freezing experiment performed on small specimens of the Torpedo electric organ during transmission of a single nerve impulse. A marked change affected IMPs in the presynaptic membrane for 3-4 ms, i.e., a population of IMPs larger than 10 nm momentarily occurred in coincidence with the passage of the impulse. The nicotinic receptors, abundantly visible in the postsynaptic membranes, also underwent very fleeting structural changes during synaptic transmission. In conclusion, for rapidly operating neurotransmitters like acetylcholine, a characteristic IMP change was regularly found to coincide in the presynaptic membrane with the production of neurotransmitter quanta, whereas images of vesicles fusion were either delayed or even dissociated from the release process. This is discussed in connection to the different modes of release recently described for other secreting systems.

Reconstitution of mediatophore-supported quantal acetylcholine release

Synaptic transmission of a nerve impulse is an extremely rapid event relying on transfer of brief chemical impulses from one cell to another. This transmission is dependent upon Ca2+ and known to be quantal, which led to the widely accepted vesicular hypothesis of neurotransmitter release. However, at least in the case of rapid synaptic transmission the hypothesis has been found difficult to reconcile with a number of observations. In this article, we shall review data from experiments dealing with reconstitution of quantal and Ca2+-dependent acetylcholine release in: i) proteoliposomes, ii) Xenopus oocytes, and iii) release-deficient cell lines. In these three experimental models, release is dependent on the expression of the mediatophore, a protein isolated from the plasma membrane of cholinergic nerve terminals of the Torpedo electric organ. We shall discuss the role of mediatophore in quantal acetylcholine release, its possible involvement in morphological changes affecting presynaptic membrane during the release, and its interactions with others proteins of the cholinergic nerve terminal.

Morphological changes related to reconstituted acetylcholine release in a release-deficient cell line

The membrane changes accompanying Ca(2+)-dependent acetylcholine release were investigated by comparing release-competent and release-incompetent clones of mouse neuroblastoma N18TG-2 cells. No release could be elicited in native N18 cells or in a N18-choline acetyltransferase clone in which acetylcholine synthesis was induced by transfection with the gene for rat choline acetyltransferase. However, acetylcholine release was operative in a To/9 clone which was co-transfected with complementary DNAs from rat choline acetyltransferase and Torpedo mediatophore 16,000 mol. wt subunit. In thin sections, the aspect of resting N18 and To/9 cells was identical: a very dense cytoplasm with practically no vesicle-like organelles. Cells were chemically fixed at different times during a stimulation using A-23187 and Ca2+, and examined following both freeze-fracture and thin section. Stimulation of To/9 cells induced a marked change affecting the intramembrane particles. The number of medium-sized particles (9.9-12.38 nm) increased, while that of the small particles decreased. This change was not observed in control, release-incompetent cell lines. In the To/9 clone (but not in control clones), this was followed by occurrence of a large new population of pits which initially had a large diameter, but subsequently became smaller as their number decreased. Coated depressions and invaginations became abundant after stimulation, suggesting an endocytosis process. By considering the succession of events and by comparison with data from experiments performed on synapses in situ, it is proposed that a particle alteration was the counterpart of acetylcholine release in co-transfected To/9 cells; this was followed by a massive endocytosis.

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.Key words: acetylcholine release, presynaptic proteins, quantal release, mediatophore, transfection.

Evoked acetylcholine release by immortalized brain endothelial cells genetically modified to express choline acetyltransferase and/or the vesicular acetylcholine transporter

Immortalized rat brain endothelial RBE4 cells do not express choline acetyltransferase (ChAT), but they do express an endogenous machinery that enables them to release specifically acetylcholine (ACh) on calcium entry when they have been passively loaded with the neurotransmitter. Indeed, we have previously reported that these cells do not release glutamate or GABA after loading with these transmitters. The present study was set up to engineer stable cell lines producing ACh by transfecting them with an expression vector construct containing the rat ChAT. ChAT transfectants expressed a high level of ChAT activity and accumulated endogenous ACh. We examined evoked ACh release from RBE4 cells using two parallel approaches. First, Ca2+-dependent ACh release induced by a calcium ionophore was followed with a chemiluminescent procedure. We showed that ChAT-transfected cells released the transmitter they had synthesized and accumulated in the presence of an esterase inhibitor. Second, ACh released on an electrical depolarization was detected in real time by a whole-cell voltage-clamped Xenopus myocyte in contact with the cell. Whether cells synthesized ACh or whether they were passively loaded with ACh, electrical stimulation elicited the release of ACh quanta detected as inward synaptic-like currents in the myocyte. Repetitive stimulation elicited a continuous train of responses of decreasing amplitudes, with rare failures. Amplitude analysis showed that the currents peaked at preferential levels, as if they were multiples of an elementary component. Furthermore, we selected an RBE4 transgenic clone exhibiting a high level of ChAT activity to introduce the Torpedo vesicular ACh transporter (VAChT) gene. However, as the expression of ChAT was inactivated in stable VAChT transfectants, the potential influence of VAChT on evoked ACh release could only be studied on cells passively loaded with ACh. VAChT expression modified the pattern of ACh delivery on repetitive electrical stimulation. Stimulation trains evoked several groups of responses interrupted by many failures. The total amount of released ACh and the mean quantal size were not modified. As brain endothelial cells are known as suitable cellular vectors for delivering gene products to the brain, the present results suggest that RBE4 cells genetically modified to produce ACh and intrinsically able to support evoked ACh release may provide a useful tool for improving altered cholinergic function in the CNS.

A chemiluminescent catecholamine assay: its application for monitoring adrenergic transmitter release

A chemiluminescent procedure for measuring catecholamines (dopamine, norepinephrine, epinephrine) is described. It is based on the observation that lactoperoxidase catalyses both the oxidation of catecholamines, and the chemiluminescent reaction of luminol with their oxidation product. The assay has been adapted for continuously monitoring the release of catecholamines from adrenergic tissues, from cell suspensions and from cells loaded in culture with dopamine.

Acetylcholine synthesis and quantal release reconstituted by transfection of mediatophore and choline acetyltranferase cDNAs

Neuroblastoma N18TG-2 cells cannot synthesize or release acetylcholine (ACh), and do not express proteins involved in transmitter storage and vesicle fusion. We restored some of these functions by transfecting N18TG-2 cells with cDNAs of either rat choline acetyltransferase (ChAT), or Torpedo mediatophore 16-kDa subunit, or both. Cells transfected only with ChAT synthesized but did not release ACh. Cells transfected only with mediatophore expressed Ca2+-dependent ACh release provided they were previously filled with the transmitter. Cell lines produced after cotransfection of ChAT and mediatophore cDNAs released the ACh that was endogenously synthesized. Synaptic-like vesicles were found neither in native N18TG-2 cells nor in ChAT-mediatophore cotransfected clones, where all the ACh content was apparently cytosolic. Furthermore, restoration of release did not result from enhanced ACh accumulation in intracellular organelles consecutive to enhanced acidification by V-ATPase, as Torpedo 16 kDa transfection did not increase, but decreased the V-ATPase-driven proton transport. Using ACh-sensitive Xenopus myocytes for real-time recording of evoked release, we found that cotransfected cells released ACh in a quantal manner. We compared the quanta produced by ChAT-mediatophore cotransfected clones to those produced by clones transfected with mediatophore alone (artificially filled with ACh). The time characteristics and quantal size of currents generated in the myocyte were the same in both conditions. However, cotransfected cells released a larger proportion of their initial ACh store. Hence, expression of mediatophore at the plasma membrane seems to be necessary for quantal ACh release; the process works more efficiently when ChAT is operating as well, suggesting a functional coupling between ACh synthesis and release.

Influence of retinoic acid and of cyclic AMP on the expression of choline acetyltransferase and of vesicular acetylcholine transporter in NG108-15 cells

Treatment of the cholinergic cell line NG108-15 with retinoic acid or cAMP results in an increase of choline acetyltransferase activity (ChAT) whereas none of these agents influences the amount of the vesicular acetylcholine transporter (VAChT) as judged from vesamicol binding and immunoblot studies. We suggest that immaturity of posttranslational events controlling the expression of VAChT protein is responsible for the apparent absence of coregulation of ChAT and VAChT protein expression.

An improved approach to freeze-fracture morphology of monolayer cell cultures

Much work is currently done on cell cultures to elucidate membrane processes associated with different cell functions. We describe here a modified freeze-fracture method to obtain systematically large fractured areas of the plasma membrane from monolayer cell culture in situ. Cells are grown until confluence on a Thermanox coverslip overlaid with poly-L-ornithine. After chemical fixation, the culture is flattened overnight by sandwiching it between the Thermanox coverslip, a Falcon membrane and a glass coverslip, under a 5 g weight. After freeze-fracture, vast pictures of the protoplasmic leaflets are obtained in a reproducible manner. Our approach was applied to cultures which were stimulated to release acetylcholine; it has been found very appropriate for studying modifications affecting intramembrane particles and vesicles openings in the plasmalemma. Accurate quantifications were performed and correlations were established between the membrane changes and the data revealed by thin sections. The present sandwich method can be applied to a variety of cell preparations, allowing for quantitative study of structure-function relationships.

In vitro reconstitution of neurotransmitter release

The vesicular hypothesis has stimulated fruitful investigations on many secreting systems. In the case of rapid synaptic transmission, however, the hypothesis has been found difficult to reconcile with a number of well established observations. Brief impulses of transmitter molecules (quanta) are emitted from nerve terminals at the arrival of an action potential by a mechanism which is under the control of multiple regulations. It is therefore not surprising that quantal release could be disrupted by experimental manipulation of a variety of cellular processes, such as a) transmitter uptake, synthesis, or transport, b) energy supply, c) calcium entry, sequestration and extrusion, d) exo- or endocytosis, e) expression of vesicular and plasmalemmal proteins, f) modulatory systems and second messengers, g) cytoskeleton integrity, etc. Hence, the approaches by "ablation strategy" do not provide unequivocal information on the final step of the release process since there are so many ways to stop the release. We propose an alternate approach: the "reconstitution strategy". To this end, we developed several preparations for determining the minimal system supporting Ca2+-dependent transmitter release. Release was reconstituted in proteoliposomes, Xenopus oocytes and transfected cell lines. Using these systems, it appears that a presynaptic plasmalemmal proteolipid, that we called mediatophore should be considered as a key molecule for the generation of transmitter quanta in natural synapses.

Acetylcholine release. Reconstitution of the elementary quantal mechanism

Choline acetyltransferase and vesicular acetylcholine transporter genes are the products of two adjacent genes defining a cholinergic locus. The release mechanism is expressed independently of this locus in some cell lines. A cholinergic neuron will therefore have to coordinate the expression of release with that of the cholinergic locus. Transfection of a plasmid encoding Torpedo mediatophore in cells that are unable to release this transmitter endows them with a Ca2(+)-dependent and quantal release mechanism. The synchronization of mediatophore activation results from a control of calcium microdomains by the synaptic vesicles. It is therefore dependent on the proteins that dock vesicles close to calcium channels.

Acetylcholine release and the cholinergic genomic locus

Choline acetyltransferase and vesicular acetylcholine-transporter genes are adjacent and coregulated. They define a cholinergic locus that can be turned on under the control of several factors, including the neurotrophins and the cytokines. Hirschprung's disease, or congenital megacolon, is characterized by agenesis of intramural cholinergic ganglia in the colorectal region. It results from mutations of the RET (GDNF-activated) and the endothelin-receptor genes, causing a disregulation in the cholinergic locus. Using cultured cells, it was shown that the cholinergic locus and the proteins involved in acetylcholine (ACh) release can be expressed separately ACh release could be demonstrated by means of biochemical and electrophysiological assays even in noncholinergic cells following preloading with the transmitter. Some noncholinergic or even nonneuronal cell types were found to be capable of releasing ACh quanta. In contrast, other cells were incompetent for ACh release. Among them, neuroblastoma N18TG-2 cells were rendered release-competent by transfection with the mediatophore gene. Mediatophore is an ACh-translocating protein that has been purified from plasma membranes of Torpedo nerve terminal; it confers a specificity for ACh to the release process. The mediatophores are activated by Ca2+; but with a slower time course, they can be desensitized by Ca2+. A strictly regulated calcium microdomain controls the synchronized release of ACh quanta at the active zone. In addition to ACh and ATP, synaptic vesicles have an ATP-dependent Ca2+ uptake system; they transiently accumulate Ca2+ after a brief period of stimulation. Those vesicles that are docked close to Ca2+ channels are therefore in the best position to control the profile and dynamics of the Ca2+ microdomains. Thus, vesicles and their whole set of associated proteins (SNAREs and others) are essential for the regulation of the release mechanism in which the mediatophore seems to play a key role.

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.

An ADP-ribosylation-factor(ARF)-like protein involved in regulated secretion

A rat ADP-ribosylation factor(ARF)-like protein named ARL184 was identified by cDNA cloning. The corresponding recombinant protein had an apparent molecular mass of 22,000. The deduced amino acid sequence had 55% identity with the human ARL1 and four functional GTP-binding sites. Immunofluorescent confocal microscopy studies showed that ARL184 was present in the cytosol as well as in the Golgi apparatus, raising the possibility that it has a role in a secretory pathway. The involvement of this ARF-like protein in secretion was confirmed by demonstrating that ARL184 potentiated acetylcholine release in stably transfected PC12 cells. Collectively these results suggest that this ARL protein is a component of a regulated secretory pathway involved in Ca2(+)-dependent release of acetylcholine.

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.

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.

Mediatophore and other presynaptic proteins. A cybernetic linking at the active zone

In rapidly transmitting synapses, the mediatophore, a protein located in the presynaptic membrane, seems to play a key role in the last step of transmitter release. Reconstituted either in proteoliposomes or in Xenopus oocytes, or transfected in particular cell lines, the mediatophore is able to release acetylcholine with characteristics which meet several typical features of transmitter release in natural synapses. Good correspondence between the two conditions was found for: i) the dependency of release upon calcium concentration; ii) the desensitisation of release by persistence of internal calcium; iii) the effect of several drugs; iv) the fleeting formation of a population of large intramembrane particles during the precise time of release; and v) the pulsatile or quantal nature of transmitter release. All these features therefore could well be ascribed to intrinsic properties of the mediatophore molecule. How is the mediatophore integrated in the whole presynaptic apparatus? To what extent is its function regulated by the other proteins of the active zone? These questions are far from being solved. We want nevertheless to propose here a general view in which characteristic presynaptic functions such as transmitter release, calcium entry, sequestration and extrusion, regulation of short- and long-term changes in release efficiency, are supported by an ordered succession of molecular events involving the proteins of the active zone. It will be seen that some proteins compete for a common binding site. It is thus expected that they will occupy this site in a regulated succession, according to simple cybernetic rules.