1. Synaptic vesicles separated by density-gradient centrifugation from extracts of the cholinergic nerve terminals of the electric organ of Torpedo marmorata were found to contain appreciable amounts of ATP as well as acetylcholine. 2. Vesicular ATP was stable in the presence of concentrations of apyrase and myokinase that rapidly destroyed equivalent amounts of endogenous or added free ATP; pre-treatment of cytoplasmic extracts of electric tissue with these enzymes destroyed endogenous free ATP, but did not affect the vesicular ATP. 3. When [U-(14)C]ATP was added to electric tissue at the time of comminution and extraction of the vesicles, all the radioactivity was associated with soluble components in the subsequent fractionation: none was associated with vesicles or membrane fragments; thus it is unlikely that vesicular ATP can be accounted for by the sequestration of endogenous free ATP within any vesicles formed during comminution and extraction of the tissue. 4. When synaptic vesicles were passed through iso-osmotic columns of Bio-Gel A-5m, which separates vesicles from soluble proteins and small molecules, all the recovered ATP and acetylcholine passed through together in the void volume. 5. Regression analysis showed that vesicular ATP content was highly correlated with vesicular acetylcholine content in different experiments, the molar ratio acetylcholine/ATP being 5.32+/-(s.e.m.) 0.45 (21 expts.) for the peak density-gradient fraction. The ratio varied, however, somewhat across the density-gradient peak suggesting some degree of chemical heterogeneity in the vesicle population.
1. The turnover of synaptosomal (vesicular-cytoplasmic) and stable-bound (vesicular) acetylcholine isolated from cortical tissue was investigated after the administration, under local anaesthesia, of [N-Me-(3)H]choline into the lateral ventricles of guinea pigs. 2. Radioactive acetylcholine and choline present in acid extracts of subcellular fractions were separated by a combination of liquid and column ion-exchange and thin-layer chromatography. 3. The specific radioactivity and pattern of labelling of acetylcholine present in a fraction of monodisperse synaptic vesicles was found to be essentially the same as that of synaptosomal acetylcholine. 4. The specific radioactivity of stable-bound acetylcholine present in partially disrupted synaptosomes (fraction H) at short times (10-20min) after the injection of [N-Me-(3)H]choline was very variable and inversely related to the yield of acetylcholine in that fraction. 5. Evidence was found for the existence of two small, but highly labelled pools of acetylcholine, one which could be isolated in fraction H and the other which was lost when synaptosomes, after isolation by gradient centrifugation, were left at 0 degrees C or pelleted. 6. It is concluded that the results are best explained by metabolic differences among the nerve-ending compartments (thought to be vesicles) which contain stable-bound acetylcholine. Computer simulation of our experiments supports this possibility and suggests that the highly labelled pool in fraction H is present in vesicles close to the external membrane.
Abstract— The uptake of [N‐Me‐3H]choline into synaptosomes from squid optic lobes was studied using a Millipore filtration technique. When incubated in an artificial sea water medium at 26°C, but not at 0°C, the synaptosomes rapidly accumulated choline, most of which could be recovered as unchanged free choline. The accumulated choline was readily released by treatment of the synaptosomes with Triton X‐100 or exposing them to hypo‐osmotic conditions. The influx of choline increased with increasing concentrations of choline and could be resolved into saturable and non‐saturable components. Kinetic analysis revealed the presence of two saturable components one of high affinity (Km about 2 μm) and one of lower affinity (Km 25 μm). The rate of choline uptake by these synaptosomes was considerably greater than by mammalian brain synaptosomes. Both high and low affinity systems were Na+‐requiring and inhibited by hemicholinium no. 3, levorphanol and dextrorphan. NaCN, 2,4‐dinitrophenol and ouabain also inhibited choline uptake, the high affinity system being particularly sensitive to these agents. It is suggested that the high affinity system is specific for cholinergic terminals.
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