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.

Membrane interaction of TNF is not sufficient to trigger increase in membrane conductance in mammalian cells.

Tumor necrosis factor TNF can trigger increases in membrane conductance of mammalian cells in a receptor-independent manner via its lectin-like domain. A lectin-deficient TNF mutant, lacking this activity, was able to bind to artificial liposomes in a pH-dependent manner, but not to insert into the bilayer, just like wild type TNF. A peptide mimicking the lectin-like domain, which can still trigger increases in membrane currents in cells, failed to interact with liposomes. Thus, the capacity of TNF to trigger increases in membrane conductance in mammalian cells does not correlate with its ability to interact with membranes, suggesting that the cytokine does not form channels itself, but rather interacts with endogenous ion channels or with plasma membrane proteins that are coupled to ion channels.

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.

Transient increase of calcium in synaptic vesicles after stimulation.

Function-dependent changes of calcium distribution were studied in the nerve-electroplaque synapses of Torpedo marmorata before and after the transmission of a nerve impulse. For the cytochemical demonstration of calcium at the ultrastructural level the oxalate-pyroantimonate technique was combined with electron spectroscopic imaging. Cholinergic synapses of the electric organ were stimulated in the presence of 4-aminopyridine, a drug which powerfully potentiates transmitter release. A single stimulus evoked a giant electrical discharge, which was followed by a long refractory period. Calcium cytochemistry was performed by fixing the tissue at four well defined functional states: (i) before and (ii) immediately after the giant discharge, and (iii) at 1 min or (iv) at 30 min of subsequent rest, corresponding to partial and complete functional recovery, respectively. In the non-stimulated synapses about 20% of synaptic vesicles contained small electron-dense precipitates. The element specific mapping by electron spectroscopic imaging clearly showed that calcium was present in the vesicular granules. The volume density of synaptic vesicles did not change among the four experimental states, but we detected a significant increase in the proportion of calcium containing vesicles at 1 min after the giant discharge. The vesicular calcium accumulation was transient: it returned to the control value at the end of the recovery period. Our data suggest that the synaptic vesicles play a role in sequestering the excess calcium which enters the nerve terminal during stimulation.

Spontaneous quantal and subquantal transmitter release at the Torpedo nerve-electroplaque junction.

Focal electrodes were used to record the spontaneous miniature potentials generated on delimited patches of innervated membrane in the Torpedo electric organ. The main population of miniature potentials followed a bell-shaped amplitude distribution. In addition, we observed a second class of spontaneous events that were smaller and whose amplitude distribution was skewed. These subminiatures formed an homogenous population together with the regular miniatures with respect to their time course versus amplitude relationship. They were thus probably generated at the same sites. The proportion of potentials that were subminiature was less than 10% in resting, freshly excised tissue, but it increased markedly: (i) when the tissue was kept for 24-28 h in vitro after excision; (ii) in the period following a brief heat challenger or (iii) stimulation to exhaustion; and (iv) in the presence of dinitrophenol or dinitrofluorobenzene. In all these conditions, we measured the acetylcholine, adenosine 5'-triphosphate and creatine phosphate content of the tissue and found a correlation between the relative number of subminiature potentials and the lack of energy rich molecules. It is concluded that subminiature potentials are present in the electric organ as in neuromuscular junctions. They are probably produced at the same sites as the regular miniature potentials and their relative occurrence seems to increase greatly when the nerve terminals are in a state of energy deficiency.

Increase in the number of presynaptic large intramembrane particles during synaptic transmission at the Torpedo nerve-electroplaque junction.

Small pieces of Torpedo electric organ were treated with 4-aminopyridine, a drug which greatly increases the duration of transmitter release in a single nerve impulse, transforming the normally brief electroplaque potential to a giant discharge. Specimens of tissue were cryofixed by rapid freezing using liquid coolants at precise time intervals during transmission of a single giant discharge, and then examined by freeze fracture. In each experiment, we monitored the electrical response of one specimen during the freezing run to check the physiological responsiveness of the tissue and to determine the precise time of contact with the cryogenic liquid. The general appearance of nerve terminals after cryofixation was similar to that of terminals from chemically fixed and cryoprotected tissue. The major morphological change observed during the time course of the giant discharge was a marked increase in the density of intramembrane particles larger than 10 nm on both the protoplasmic and external faces of the presynaptic membrane. This change appeared in specimens frozen within the first few milliseconds after the stimulus, that is, at a time corresponding to the onset of the rising phase of the potential (3 ms). At the end of the giant discharge, the particle density returned to control values with the same time course as the potential trace. Pits of 20 nm or larger, probably due to vesicle-membrane interaction, were found in a small proportion of nerve terminals. Their occurrence increased only at 120-150 ms after the stimulus, that is, a long time after the beginning of the giant potential and of the change in intramembrane particles. The size distribution of particles was also determined in the membrane of synaptic vesicles exposed by cross fracture of terminal boutons; it was found to be similar to that of the unstimulated presynaptic membrane and it did not change during the giant discharge. Stimulation experiments were also carried out in a modified solution containing no added calcium, 20 mM magnesium and 4-aminopyridine. The propagation of impulses along the nerves to the electric organ was not inhibited in the modified solution but acetylcholine release was prevented and no increase in particle density was found on the presynaptic membrane. These and previous biochemical experiments on this tissue suggest that the release of the neuro-transmitter acetylcholine is associated with a transient occurrence of large intramembrane particles on the two fracture faces of the presynaptic membrane.(ABSTRACT TRUNCATED AT 400 WORDS)

Exo-endocytotic activity during recovery from a brief tetanic stimulation: a role in calcium extrusion?

Synaptic transmission, metabolism of calcium and ultrastructural changes were investigated at the nerve-electroplaque synapse of Torpedo marmorata during and after a brief tetanic stimulation. Calcium was found to accumulate in stimulated tissue as a function of the number of stimuli; it was subsequently expelled during the recovery period. This period was also accompanied by a marked hydrolysis of energy-rich phosphates (ATP and creatine phosphate). Histochemical localization combined with electron spectroscopic imaging showed calcium deposits in synaptic vesicles and in other substructures. The number of synaptic vesicles containing a calcium deposit transiently increased at the end of activity and declined later during the recovery phase. Rapid cryofixation of the tissue followed by freeze-fracturing revealed membrane openings (pits) in the presynaptic membrane. The density of pits was low in resting tissue; it did not rise during the tetanic stimulation. In contrast, the number of presynaptic pits increased significantly soon after, reaching a maximum value at 1 min after tetanus. These results are discussed in the light of current hypotheses. They suggest that synaptic vesicles play an important role in intraterminal calcium homeostasis. The vesicles might sequester calcium ions in synaptic terminals during activity and expel them afterwards by exocytosis.

Endo-exocytotic images and changes in synaptic transmission induced by diamide at a cholinergic junction.

Small tissue fragments excised from the electric organ of Torpedo marmorata were treated with diamide, a penetrating thiol oxidizing agent, until synaptic transmission was blocked. At this stage, we found an unexpected number of exo-endocytotic images in the presynaptic plasmalemma. Omega-shaped profiles, some of them coated, were seen in thin sections of fixed tissue and pits opened in the P-face of the presynaptic membrane in freeze-fracture replicas from rapidly-frozen preparations. Diamide-treated specimens were frozen at 1 ms time intervals before, during and after a single electrical stimulus. This stimulation did not result in a further increase in the density of presynaptic pits, not in any change affecting the density or size distribution of intramembrane particles. This result is in contrast with what is observed in untreated specimens where transmission of a nerve impulse is accompanied by a momentary rise in the number of large particles. The density of synaptic vesicles--especially that of a subpopulation of small size vesicles--transiently increased within the first 2 h of diamide treatment. During the first stages of intoxication, diamide prolonged the time course of postsynaptic potentials--both spontaneous and evoked--probably by altering the gating properties of receptors (acetyl-cholinesterase activity was not impaired). Later on, all evoked responses were blocked. The spontaneous transmitter release greatly increased, first in the form of quantal miniature potentials. These then subsided whereas a class of very small potentials was generated at a high frequency. Also under the action of diamide, calcium progressively accumulated in the tissue but the number of synaptic vesicles containing calcium deposits was reduced. It is concluded that diamide causes a marked increase in the number of exo-endocytotic images in the presynaptic membrane, suppresses quantal but not subquantal release, and interferes with calcium sequestration in and extrusion from terminals.

Presynaptic effects of 4-aminopyridine and changes following a single giant impulse at the Torpedo nerve-electroplaque junction.

The presynaptic changes caused by 4-aminopyridine were studied in the electric organ of Torpedo marmorata, in the resting state and during the period following transmission of a single giant discharge. Incubation with 4-aminopyridine provoked a 30-40% decrease in the density of synaptic vesicles in nerve terminals, and a similar decrease in the content of vesicular and free acetylcholine. These changes were not observed when 4-aminopyridine was applied in a low-calcium, high-magnesium solution. In the standard medium, 4-aminopyridine treated junctions were able to generate a giant electrical discharge of long duration in response to a single stimulus. During the seconds and minutes following the giant discharge, the number of synaptic vesicles was not found to be significantly altered in the whole population of nerve terminals. However, new membranous structures--looking like sacs with double membranes encircling a part of cytoplasm--were seen in approximately 25% of nerve endings; in those terminals, the number of synaptic vesicles was significantly decreased. At this stage, the junctions had not recovered their capability to generate a second giant discharge of full size and the yield of acetylcholine, adenosine 5'-triphosphate (ATP) and creatine phosphate was diminished. Thirty minutes after the single discharge, the functional recovery was achieved and the membranous sacs had disappeared; but the levels of acetylcholine, ATP and creatine phosphate were still not restored.

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.

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.

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.

Diffusion of drugs through stationary water layers as the rate limiting process in their action at membrane receptors.

1. Preparations bathed in a well stirred solution have been considered as heterogeneous systems in which the solid phase is enveloped by a thin layer of stationary liquid. Any substance applied into the bulk solution must pass through this layer by diffusion before reaching the receptors.2. The rate of diffusion through the stationary layer can govern the time course of the cellular responses to applied drugs provided that (i) all receptors involved in the response are situated at an equal distance from the solution and (ii) interaction with the receptor and consequent cellular events are very rapid.3. These conditions have been verified for two responses: the contraction of guinea-pig ileum by acetylcholine (ACh), carbamylcholine (CCh), histamine and KCl, and the depolarization of the rat isolated sympathetic ganglion by ACh in the presence of eserine. A method of analysis has been applied which allows a complete dose-response curve to be obtained from only two responses.4. Diffusion half-times measured for pieces of ileum were 4.13 +/- 0.13 s (S.E. of mean) for Ach, 3.60 +/- 0.05 s for CCh and 1.01 + 0.05 s for KCl. The equivalent thickness of the stationary layer calculated from these values was respectively 93 mum, 87 mum and 70 mum. The average diffusion half-time for ACh in sympathetic ganglia was 14.19 +/- 1.05 s. This gives an equivalent thickness of 173 mum.5. Diffusion half-times were increased by increasing the viscosity of the bathing solution without changing the concentration response relationship.6. The time course of contractions of guinea-pig ileum are no longer diffusion limited in the presence of a competitive antagonist or when the temperature is lowered from 35 degrees to 25 degrees C.

A unifying hypothesis for acetylcholine release.

Mediatophore is the only nerve terminal membrane protein known to translocate acetylcholine upon calcium action. It is localized at the active zone. In this review we attempted to describe its role in relation to the vesicular and membrane protein complexes that are formed at the active zone. The model pictures a possible set of sequential steps that lead to exocytosis. The smallest quantal events are attributed to mediatophore opening momentarily, while synaptic vesicles synchronize release by controlling the calcium microdomain. A clear distinction is made between sub-quantal ACh release preserved after Botulinum toxin action, and exocytosis of vesicular contents. A cybernetic model for release and exocytosis related to protein interactions is presented for future works.

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.

Flatten-peeled: a new approach to freeze-fracture morphology.

A new way to obtain in a replica vast pictures of membranes situated at the same level in the preparation is described. The tissue specimen is flattened during fixation with a given orientation. It can be fractured afterwards, either along the plane of fixation or, after rotation, perpendicular to this plane. The method utilizes standard freeze-fracture equipment and readily available materials. This approach has a large range of potential applications, especially with tissues displaying a layered organization such as epithelia, nervous system, etc. It was found very appropriate for studying pre- and postsynaptic membranes in the Torpedo electric organ, to reveal specific junctions between cells in organotypic cultures, and to examine photoreceptors and other layers of the mammalian retina. In those tissues we obtained in a fairly reproducible manner freeze fractures at the desired level and orientation. With Torpedo synapses, vast pictures of the nerve terminals were performed in a plane quasi-parallel to the membrane postsynaptic cells (electroplates). Using double or triple flatten-peeled, it has also been possible to render the whole tissue specimen thin enough to perform gold label fracture [Pinto da Silva and Kan (1984), J. Cell Biol., 99:1156-1161].

Simple goniometric search for electron microscopy.

We developed a special software to memorize specific points on a grid for later fine analysis. This program is based on a goniometry search, and implemented on the PC coupled microscope. This allows automatic shifting of the grid, but it can also be programmed on a simple pocket calculator.

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.

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.

Ultrastructure and biophysics of acetylcholine release: central role of the mediatophore.

We would like to review here some of the acquisitions gained by recent work in our two laboratories. Our approaches and results were intermingled and complementary. Thus we found it appropriate, for clarity and intelligibility, to merge them into a single chapter.