Is the acetylcholine releasing protein mediatophore present in rat brain?

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

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

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

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

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

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

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

Purification of a presynaptic membrane protein that mediates a calcium-dependent translocation of acetylcholine.

A protein, which we call "mediatophore," that mediates calcium-dependent release of acetylcholine from proteoliposomes has been purified from the presynaptic plasma membrane. About 250 micrograms of this material was obtained from 500 g of Torpedo marmorata electric organ. Precipitation of the protein and subsequent removal of associated lipids inactivated the protein, which then became water soluble; this permitted evaluation of its Stokes radius (52 A) and its sedimentation coefficient (9.8 +/- 0.75 S) and, hence, an approximate molecular mass of 210 +/- 16 kDa could be determined. PAGE analysis showed that the protein is made of 17-kDa subunits, not linked by disulfide bonds. When this material was observed by electron microscopy after negative staining, the apparently pentameric structures had an average diameter of about 7 nm.

Large-scale purification of presynaptic plasma membranes from Torpedo marmorata electric organ.

The presynaptic plasma membrane (PSPM) of cholinergic nerve terminals was purified from Torpedo electric organ using a large-scale procedure. Up to 500 g of frozen electric organ were fractioned in a single run, leading to the isolation of greater than 100 mg of PSPM proteins. The purity of the fraction is similar to that of the synaptosomal plasma membrane obtained after subfractionation of Torpedo synaptosomes as judged by its membrane-bound acetylcholinesterase activity, the number of Glycera convoluta neurotoxin binding sites, and the binding of two monoclonal antibodies directed against PSPM. The specificity of these antibodies for the PSPM is demonstrated by immunofluorescence microscopy.

Large-scale purification of Torpedo electric organ synaptosomes.

A procedure for the large-scale purification of Torpedo electric organ synaptosomes is described. The synaptosomal fraction obtained is very pure as judged from biochemical and morphological data. In addition, acetylcholine (ACh) release was demonstrated after KCl depolarization of synaptosomes in the presence of calcium. Two hundred grams of electric organ can be fractionated in a single run, allowing biochemical studies on presynaptic membrane constituents.

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

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

Partial purification of ?-glycerotoxin, a presynaptic neurotoxin from the venom glands of the polychaete annelid glycera convoluta.

The venom secreted from glands appended to the jaws of Glycera convoluta, a Polychaete Annelid, increases the spontaneous quantal release of transmitter from nerve terminals. The component that is biologically active on vertebrate cholinergic nerve terminals has recently been shown to be a high molecular weight protein. In the present work, the crude extract from the venom apparatus was shown to be toxic for mammals and crustaceans. It was fractionated by gel filtrations and ion exchange chromatographies. The biologically active component at frog neuromuscular junctions, ?-glycerotoxin, was purified more than 1,000-fold. It is distinct from the components that are toxic for crustaceans. Purified ?-glycerotoxin is a globular protein of 300,000 +/- 20,000 mol wt. It has a Stokes radius of 65 A and a sedimentation coefficient of 11 S. By its molecular properties, ?-glycerotoxin appears distinct from other neurotoxins such as ?-latrotoxin, which also trigger transmitter release.

Reconstitution of a functional synaptosomal membrane possessing the protein constituents involved in acetylcholine translocation.

Reconstitution of a functional presynaptic membrane possessing calcium-dependent acetylcholine release properties has been achieved. The proteoliposomal membrane obtained gains its acetylcholine-releasing capabilities from presynaptic membrane proteins. At the peak of acetylcholine release, intramembrane particles became more numerous in one of the proteoliposomal membrane faces. This phenomenon resembles the intramembrane particle rearrangements found in stimulated synaptosomes. No visible structures capable of releasing acetylcholine as a result of the calcium influx were found inside the proteoliposomes. This supports the view that the release of free cytosolic acetylcholine from stimulated nerve terminals can be directly attributed to presynaptic membrane proteins. These proteins were extracted in a functional form from the synaptosomal membrane.

Binding of a Glycera convoluta neurotoxin to cholinergic nerve terminals triggers a Ca-dependent acetylcholine release.

The venom glands of the annelid Glycera convoluta contain a neurotoxin which triggers ACh release from frog motor terminals and Torpedo synaptosomes. This neurotoxin binds to presynaptic, but not postsynaptic plasma membranes prepared from Torpedo electric organ. The binding site is an ectocellularly oriented protein. The binding does not require Ca. It is inhibited by pretreatment of the membrane by Concanavalin A. The toxin induced ACh release is Ca-dependent and inhibited by D 600.

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

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

Acetylcholine release from proteoliposomes equipped with synaptosomal membrane constituents.

A lyophilized presynaptic membrane powder prepared from Torpedo electric organ synaptosomes was incorporated into liposomes. These proteoliposomes had a large internal volume. The P and E faces of their membrane showed particles which were comparable to the presynaptic membrane ones. The synaptosomal ecto-esterase activity was also incorporated. A large amount of acetylcholine could be entrapped in the proteoliposome which became permeable to acetylcholine in the presence of calcium. Acetylcholine was released in preference to choline. The calcium-induced acetylcholine release depended on the incorporation of a presynaptic membrane constituent. Proteoliposomes prepared from postsynaptic membrane powders gave a much slower acetylcholine efflux. The protein pattern of presynaptic and postsynaptic membrane proteoliposomes were compared.

Isolation of a presynaptic plasma membrane fraction from Torpedo cholinergic synaptosomes: evidence for a specific protein.

Synaptosomal plasma membranes were isolated from Torpedo cholinergic synaptosomes which had been purified as previously described or repurified by equilibrium centrifugation. The synaptosomal plasma membrane could be distinguished from postsynaptic membranes by the absence of postsynaptic specific markers (nicotinic AChR) and by its low intramembrane particle complement after freeze fracture. In addition, the presynaptic membrane fraction contained acetylcholinesterase. Gel electrophoresis permitted the identification of a major protein component of the presynaptic membrane fraction which had a molecular weight of 67,000. This protein was not found in postsynaptic membrane or synaptic vesicle fractions. Thus it appeared to be specific to the nerve terminal plasma membrane.

Partial purification of the Glycera convoluta venom components responsible for its presynaptic effects.

The crude extract of glands appended to the jaws of the polychaete annelid Glycera convoluta induces an important increase in the spontaneous quantal transmitter release on frog and crayfish neuromuscular junctions and on Torpedo nerve-electroplaque junctions. The venom similarly triggers acetylcholine (ACh) release from synaptosomes purified from Torpedo electric organ. At the frog neuromuscular junction, the reproducibility, the reversibility and the dose-dependence of the venom action permit a quantitative evaluation of the effect. The crude venom extract has been fractionated by gel-filtration. The effect on transmitter release has been found in a high molecular weight fraction distinct from those which contain the protease and phospholipase activities.

Evidence for a specific protein associated to the plasma membrane of cholinergic synaptosomes.

Synaptosomal plasma membrane fractions were prepared by fractionation of pure Torpedo cholinergic synaptosomes. A 67 000 dalton peptide was shown to be a major component of the presynaptic membrane. It appears specific for this membrane since (1) it copurifies with the synaptosomal plasma membrane; (2) it was not present in similar plasma membranes but prepared from Torpedo electric lobes or electric nerves, and since (3) rabbit antibodies to presynaptic antigens which were mainly directed to this 67 000 dalton peptide band were shown to bind to the nerve terminal network in Torpedo electric organ. A crude fraction of presynaptic plasma membrane prepared from electric organ homogenate could be a convenient material for the purification of this 67 000 dalton peptide.

Rearrangement of intramembrane particles as a possible mechanism for the release of acetylcholine.

1. A chemiluminescent procedure for measuring acetylcholine (ACh) has recently been described. The procedure is based on the hydrolysis of ACh by acetylcholinesterase and on the oxidation of choline to betaine and H2O2 by choline oxidase. The H2O2 generated reacts with luminol in presence of peroxidase to produce a light emission. This method is sensitive in the pmol/ml range. 2. On isolated synaptosomes from electric organ, it is possible to obtain an estimate of the cytoplasmic ACh compartment by measuring the light emission after a single freezing and thawing cycle. The vesicular pool which resists several freezing and thawing cycles is then estimated by opening the compartment with a detergent. Increasing the intensity of stimulation of synaptosomes with different agents depletes the ACh content down to the vesicular pool. 3. The release of ACh is not associated with any change in the number of synaptic vesicles as seen in cryofractured synaptosomes. The only ultrastructural change detected common to all stimulations was a decreased density of P face intramembrane particles smaller than 11 nm and an increased density of E face 8 to 18 nm particles. The very significant particle changes were more intense for the conditions releasing more ACh. It is suggested that these particles are involved in the release of ACh from the cytoplasm. An attempt to directly correlate the release of ACh with intramembrane particle changes is discussed.

Calcium uptake by cholinergic synaptic vesicles.

Pure synaptic vesicles have been isolated in sucrose-KCl media. They are able to take up calcium in the presence of ATP and Mg. This is based on the following evidence. First, the synaptic vesicle fraction is the gradient peak for calcium uptake. Second, it was not possible to separate ACh and ATP from the uptake peak after refractionation of synaptic vesicles. Third, the fraction appears very pure on morphological and biochemical grounds. The physiological significance of the calcium uptake by synaptic vesicles is discussed.