The subcellular distribution of [N-Me-3H]-acetylcholine synthesized by brain in vivo

1. Three forms of acetylcholine occur in subcellular fractions of brain tissue: free acetylcholine, present in the high-speed supernatant from eserinized sucrose homogenates; stable bound acetylcholine, present in synaptic vesicles; and labile bound acetylcholine, present in the cytoplasm of synaptosomes (detached presynaptic nerve terminals). 2. The relationship between these forms has been investigated by isolating the subcellular fractions from the cortical tissue of cats and guinea pigs excised 1hr. after infiltration of [N-Me-(3)H]choline into the cortex in vivo. 3. Since choline is a ubiquitous metabolite, means were devised for isolating the radioactive acetylcholine on columns of the weak acid ion-exchange resin IRF-97; control experiments with samples of extracts treated with acetylcholinesterase showed that the radioactivity attributed to acetylcholine migrated to the choline peak after cholinesterase treatment. 4. The specific radioactivities of the various forms of acetylcholine were different: labile bound (synaptosomal cytoplasmic) acetylcholine had the highest, stable bound (vesicular) acetylcholine the next highest, and the high-speed-supernatant form the lowest. 5. It is concluded that the various forms of acetylcholine could not have arisen during fractionation from a single pre-existing pool of acetylcholine.     

Botulinum neurotoxin inhibits the release of newly synthesized acetylcholine from torpedo electric organ synaptosomes

In previous reports, we have shown that botulinum neurotoxin inhibits acetylcholine release from Torpedo marmorata electric organ and from its synaptosomal fraction. Here, we have focussed our attention on the study of the effect of botulinum neurotoxin on the metabolism of acetylcholine, namely, the precursors supply, the synthesis activity and the storage of the neurotransmitter into nerve endings isolated from Torpedo electric organ. Radiolabelled acetylcholine precursors (acetate and choline) uptake, choline O-acetyltransferase activity, and the compartmentalization of the transmitter into the synaptosomes were not modified by botullinum neurotoxin. When labelled nerve ending were depolarized by K⁺, the specific radioactivity of acetylcholine in the free pool fell markedly, but the specific radioactivity in the bound pool remained constant. Botulinum neurotoxin prevented this K⁺-induced decrease of specific radioactivity in the free pool.     

ASPECTS OF ACETYLCHOLINE METABOLISM IN THE ELECTRIC ORGAN OF TORPEDO MARMORATA

Abstract— —The synthesis of acetylcholine and its compartmentation were studied in the electric organ of Torpedo marmorata. When electric organ was homogenized in iso-osmotic NaCl-sucrose some 55 per cent of its acetylcholine content was lost unless very potent cholinesterase inhibitors were present. Slices of electric organ incubated in a suitable medium were found to synthesize radioactive-labelled acetylcholine from [ N-Me-³ H] choline. The specific activity of the labelled acetylcholine was higher in the trichloracetic acid extract of the organ slices than in an NaCl-sucrose homogenate. Acetylcholine-containing vesicles isolated from the NaCl-sucrose homogenate contained labelled acetylcholine with about the same specific activity as the parent homogenate. There was thus a fraction of acetylcholine in the incubated tissue of higher specific radioactivity that was lost when the tissue was homogenized. The acetylcholine-containing vesicles lose their acetylcholine when submitted to gel filtration under hypo-osmotic conditions. On standing at 5°C there were only small losses of acetylcholine from the vesicles but at 20°C the losses were substantial. Vesicles containing labelled acetylcholine were studied. On gel filtration under iso-osmotic conditions there was a considerable loss of labelled acetylcholine without a concomitant loss of bio-assayable acetylcholine. The pools of radioactive and bio-assayable acetylcholine are therefore not homogeneous in the vesicles as isolated.     

SYNTHESIS OF ACETYLCHOLINE IN DIFFERENT COMPARTMENTS OF BRAIN NERVE TERMINALS IN VIVO AS STUDIED BY THE INCORPORATION OF CHOLINE FROM PLASMA AND THE EFFECT OF PENTOBARBITAL ON THIS PROCESS

The time course of the incorporation of choline from plasma into a high and a low molecular weight fraction from mouse brain synaptosomes was studied. The fractions were obtained from lysed synaptosomes by gel filtration on Sephadex G-25. An extremely rapid incorporation of radioactivity into acetylcholine was found in both fractions and in the time interval 0.25-9 min after the intravenous administration of labelled choline, higher specific radioactivities of acetylcholine were found in the high molecular weight fraction than in the low molecular weight fraction. However, the specific radioactivity of choline in the high molecular weight fraction was much lower than that of acetylcholine. It was found that barbiturate anaesthesia caused a marked decrease in the labelling of acetylcholine in the high molecular weight fraction while the incorporation into the low molecular weight fraction was affected to a much smaller extent. Acetylcholine of the high molecular weight fraction showed properties similar to those of vesicle-bound acetylcholine. The recoveries of labelled and endogenous acetylcholine and choline from the brain homogenates were calculated in different steps of the fractionation procedure. In the fraction containing lysed synaptosomes the recovery of radioactive acetylcholine was lower than that of endogenous acetylcholine. This may indicate the presence of two types of bound acetylcholine in the synaptosomes. Different models for the intraneuronal synthesis of acetylcholine are discussed and it is proposed that a site of acetylcholine synthesis in vivo may be closely associated with some constituent of the high molecular weight fraction and directly coupled with the storage of the transmitter.     

Can mitochondria and synaptosomes of guinea-pig brain synthesize phospholipids?

1. The use of ;marker' enzymes for investigating the contamination by endoplasmic reticulum of mitochondrial and synaptosomal (nerve-ending) fractions isolated from guinea-pig brain was examined. NADPH-cytochrome c reductase appeared to be satisfactory. With the synaptosomal preparation there was a non-occluded enzymic activity believed to arise from contaminating microsomes and an occluded form released by detergent, which probably was derived from some type of intraterminal smooth endoplasmic reticulum. 2. Isolated brain mitochondria, both intact and osmotically shocked, could not synthesize more labelled phosphatidylcholine from CDP-[Me-(14)C]choline or phosphoryl[Me-(14)C]choline than could be accounted for by microsomal contamination. They could synthesize only phosphatidic acid and diphosphatidylglycerol from a [(32)P]P(i) precursor and not nitrogen-containing phosphoglycerides or phosphatidylinositol. 3. The synaptosomal outer membrane and the intraterminal mitochondria could not synthesize phosphatidylcholine from CDP-[Me-(14)C]choline but the synaptic vesicles and probably the intraterminal ;endoplasmic reticulum' appeared to be capable of catalysing the incorporation of label from this substrate into their phospholipids. 4. Microsomal fractions and synaptosomes from guinea-pig brain could incorporate [Me-(14)C]choline into their phospholipids by a non-energy-requiring exchange process, which was catalysed by Ca(2+). Fractionation of the synaptosomes after such an exchange had taken place revealed that the label was predominantly in the intraterminal mitochondria and not associated with membranes containing NADPH-cytochrome c reductase. 5. On the intraperitoneal injection of [(32)P]P(i) into guinea pigs, incorporation of radioactivity into phosphatidylinositol and phosphatidic acid was much faster than into the nitrogen-containing phosphoglycerides. Mitochondria and microsomal fractions showed a roughly equivalent incorporation into individual phospholipids, and that into synaptosomes was appreciably less, whereas the phospholipids of myelin showed little (32)P incorporation up to 10h.     

THE EFFECT OF ELECTRICAL STIMULATION ON THE TURNOVER OF PHOSPHATIDIC ACID IN SYNAPTOSOMES FROM GUINEA-PIG BRAIN

Synaptosomes prepared from guinea-pig cerebral cortex were suspended in a medium containing [³²P]orthophosphate and subjected to electrical stimulation. When the synaptosomal phospholipids were subsequently separated, the most highly labelled was phosphatidic acid and electrical stimulation over a 10 min period increased incorporation of ³²P₁ into this lipid. Stimulated synaptosomes were osmotically lysed and subsynaptosomal fractions isolated. The electrically stimulated increase in phosphatidic acid labelling was localized in a fraction enriched in synaptic vesicles. This phospholipid effect was not merely a reflection of an increased specific radioactivity of synaptosomal ATP, due to the electrically stimulated increase in respiration. The time course of the phosphatidic acid effect suggests that it is synchronous with release of transmitter.     

Characterization of synaptosomes from the central nervous system of insects

Nerve terminals from the head ganglia of Locusta migratoria were isolated by means of a modified microscale flotation technique. Enzymatic, ultrastructural and chemical analysis revealed that the synaptosomal fraction was highly enriched in well-preserved nerve endings containing almost no free mitochondria. Cholinergic activities (choline acetyltransferase, acetylcholinesterase, acetylcholine receptors) were found to be concentrated in the synaptosomal fraction. The cholinergic nature and the functional integrity of nerve endings isolated from locusts were further supported by the existence of a high affinity choline uptake system, which is abolished by hemicholinium-3 as well as by low temperature, is essentially sodium dependent and inhibited by elevated potassium concentrations. After slight modifications of the gradient densities, synaptosomes could also be isolated from other insect species.     

Antibodies directed against ubiquitin inhibit high affinity [3H]choline uptake in rat cerebral cortical synaptosomes

Sodium-dependent [3H]choline uptake and coupled [3H]acetylcholine synthesis were inhibited in rat cerebral cortical synaptosomes in a dose- (1-10 micrograms/ml) and time-dependent manner by affinity-purified antibodies directed against ubiquitin (anti-Ub). Neither sodium-independent [3H]choline uptake nor [3H]acetylcholine release was affected by up to 10 micrograms/ml anti-Ub, indicating that the cholinergic terminals were not depolarized by the anti-Ub. Binding of anti-Ub to synaptosomes, as measured with 125I-protein A, was saturable and occurred over the same concentration range (1-10 micrograms/ml) at which uptake inhibition was observed. Although preimmune IgG bound to the synaptosome preparation to a greater extent and was apparently not readily saturable, this fortuitous binding was without effect on high affinity choline uptake and conversion to acetylcholine. The results suggest the presence of a ubiquitin-protein conjugate on the synaptosomal surface and a functional relationship between this protein conjugate and the sodium-dependent choline transport system.     

The incorporation of radioactive fatty acids and of radioactive derivatives of glucose into the phospholipids of subsynaptosomal fractions of cerebral cortex.

1. Crude synaptosomal fractions (P2) from guinea-pig cerebral cortex were incubated in a Krebs-glucose medium containing labelled fatty acids and [3H]glucose. After the shortest incubation period (7.5 min) a high percentage (50-80%) of the total radioactive fatty acids was found in the P2 fractions. 2. After the incubation, the synaptosomal fractions were submitted to hypo-osmotic disruption and subsynaptosomal fractionation was carried out by using discontinuous-sucrose-gradient centrifugation. The specific radioactivities of phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and phosphatidylinositol were determined in fractions D (synaptic vesicles), E (microsomal preparation) and H (disrupted synaptosomes), as were the specific activities of a number of marker enzymes and the distribution of acetylcholine. 3. By using [14C]oleate, [14C]arachidonate, [3H]palmitate and [3H]glucose, the order to specific radioactivities in fraction D was found to be: phosphatidylinositol greater than phosphatidylcholine greater than phosphatidylserine greater than phosphatidylethanolamine. 4. The specific radioactivities of phosphatidylcholine and phosphatidylethanolamine were always higher in fraction D than in fraction E. As fraction E had higher specific activities of several membrane marker enzymes, the enhanced labelling found in fraction D was considered to be localized in the synaptic vesicles. In this fraction, phosphatidylinositol made particularly large contributions to the total phospholipid labelling derived from [14C]arachidonate and [3H]glucose. 5. The similar labelling ratios of fatty acid/glucose in the phospholipids of fractions D and E, and the high specific radioactivities in the total phospholipid of the soluble fraction O, suggested intrasynaptosomal phospholipid transport.     

Isolation of Hippocampal Synaptosomes on Percoll Gradients: Cholinergic Markers and Ligand Binding Sites

The S1 Percoll procedure, devised empirically for cortical tissue, provides highly purified, functionally viable synaptosomes on a four-step Percoll gradient. Here, for the first time, the procedure has been applied to rat hippocampus, and the gradient fractions have been analysed with respect to cholinergic markers and the synaptosomal index, lactate dehydrogenase. The presynaptic cholinergic markers choline acetyltransferase and [3H]choline uptake were most enriched in fraction 4. In contrast, acetylcholinesterase activity was broadly distributed across the gradient, consistent with the separation of synaptic plasma membranes (in fractions 1 and 2) from synaptosomes (in fractions 3 and 4). This is supported by the recovery of muscarinic binding sites labelled with [3H]quinuclidinylbenzilate in fractions 1 and 2. (-)-[3H]-Nicotine binding sites, however, were most enriched in fraction 4, consistent with their predominantly presynaptic localisation in the CNS. These results demonstrate the applicability of the S1 Percoll method to discrete brain regions for the recovery of homogeneous and viable synaptosome fractions. The separation of presynaptic terminals from post-synaptic membranes is a further advantage of this technique.     

Choline metabolism in the cerebral cortex of guinea pigs. Phosphorylcholine and lipid choline

1. The labelling of phosphorylcholine and choline-containing phospholipids in the subcellular fractions of guinea-pig cerebral cortex after the intraventricular injection of [N-Me-(3)H]choline into conscious animals has been studied. Special emphasis was placed upon the synaptosome fraction and early time-periods after administration. 2. The labelling of phosphorylcholine was rapid compared with that of phospholipid and was confined to two distinct subcellular fractions: the soluble cytoplasmic fraction and the synaptosome fraction. Most of the labelled phosphorylcholine of the synaptosome fraction was readily released by osmotic rupture indicating location in the nerve-ending cytoplasm. The two pools of phosphorylcholine had similar specific radioactivities at all observed times. 3. (3)H-labelled phospholipid was found in all membranous fractions. The labelling was confined to choline-containing phospholipids, notably phosphatidylcholine. 4. The labelling of the different membranous fractions was similar. 5. The half-life of the choline-containing phospholipids in the synaptic vesicle fraction was very much greater than the acetylcholine in this fraction. 6. Evidence is presented that synthesis de novo of phosphatidylcholine at nerve terminals occurs in vivo.     

A Synaptosomal Preparation from the Guinea Pig Ileum Myenteric Plexus

Abstract: Our interest in investigating the presynaptic modulation of acetylcholine release led to the development of a synaptosomal preparation from the guinea pig ileum myenteric plexus-longitudinal muscle. A crude synaptosomal fraction (P₂) was obtained by homogenization and differential centrifugation. The preparation exhibited a specific uptake system for choline and for nor-adrenaline (NA), but not for 5-hydroxytryptamine (5-HT). Synaptosomes were isolated from this P₂ fraction by an isoosmotic density gradient prepared from sucrose and metrizamide. The resultant synaptosomal fraction was enriched about sevenfold in both choline uptake and in choline acetyltransferase (ChAT). Choline was transported by a high-affinity system with a K_m of 6.5 × 10⁻⁷ M and a V_max of 41 pmol/mg protein/min. Electron microscopy confirmed the synaptosomal nature of the gradient fraction. Some synaptosomal profiles contained only small, translucent vesicles whereas others also contained large (approx. 100 nm diameter) electron-opaque vesicles. The crude synaptosomal fraction synthesized acetylcholine (ACh) from exogenous choline and it released the synthesized ACh in a calcium-dependent manner.     

Compartmentation and regulation of acetylcholine synthesis at the synapse.

Acetylcholine and choline release was measured by using an automated and modified version of the chemiluminescence technique of Israel & Lesbats [(1981) Neurochem. Int. 3, 81-90]. A comparison of acetylcholine and choline release from synaptosomes demonstrated that acetylcholine release was K+-stimulated and inhibited by the Ca2+ ionophore A23187 and cyanide. Choline release, however, did not vary markedly under different conditions, suggesting that it is not associated with acetylcholine release at the nerve ending. Total acetylcholine synthesis in synaptosomal preparations was measured concurrently with the incorporation of [14C]acetyl and [3H]choline moieties by using the chemiluminescence method. Under sub-optimal glucose concentrations or in the absence of treatment of the synaptosomes with the acetylcholinesterase inhibitor phospholine, the incorporation of radioactivity exceeded total synthesis, indicating that cycling between acetylcholine and its precursors may occur. After treatment with phospholine, acetyl-group incorporation from D-[U-14C]glucose occurred without dilution of the precursor at optimal (1.0 mM) and low (0.1 mM) glucose concentrations; however, at very low (0.01 mM) glucose concentrations, dilution by a small endogenous pool occurred. [14C]Acetyl incorporation into acetylcholine was compared with various metabolic parameters. A closer correlation was observed between [14C]acetyl-group incorporation into acetylcholine and the calculated acetyl-carrier efflux from the mitochondria than with the calculated pyruvate-dehydrogenase-complex flux. The results are discussed with respect to the regulation of acetylcholine concentrations at the synapse and the mechanism whereby turnover occurs.     

ISOLATION OF [3H]ACETYLCHOLINE POOLS BY SUBCELLULAR FRACTIONATION OF CEREBRAL CORTEX SLICES INCUBATED WITH [3H]CHOLINE

Abstract— Subcellular fractions were isolated from tissue incubated in [³H]choline with or without the addition of 33 mM-KCl. Radioactive and bioassayable ACh were measured in the synaptosomes, synaptosomal cytoplasm and in the vesicles. After incubation with KCI the vesicles, as isolated, contained ACh of a lower specific activity than the cytoplasmic ACh. Therefore the vesicle fraction as isolated does not represent the source of the high specific activity ACh released upon K⁺ stimulation. However the vesicle fraction is heterogeneous. Most of the bioassayable ACh but little of the radioactive ACh in the vesicles passed through iso-osmotic Sephadex columns. These results raise the question of the existence of vesicles which contain highly radioactive ACh but which lose it during their isolation by current methods. Different possible forms of heterogeneity are discussed.     

Separation of Recycling and Reserve Synaptic Vesicles from Cholinergic Nerve Terminals of the Myenteric Plexus of Guinea Pig Ileum

Acetylcholine-rich synaptic vesicles were isolated from myenteric plexus-longitudinal muscle strips derived from the guinea pig ileum by the method of Dowe, Kilbinger, and Whittaker [J. Neurochem. 35, 993-1003 (1980)] using either unstimulated preparations or preparations field-stimulated at 1 Hz for 10 min using pulses of 1 ms duration and 10 V . cm-1 intensity. The organ bath contained either tetradeuterated (d4) choline (50 microM) or [3H]acetate (2 muCi . ml-1); d4 acetylcholine was measured by gas chromatography-mass spectrometry. As with Torpedo electromotor cholinergic vesicle preparations made under similar conditions the distribution of newly synthesized (d4 or [3H]) acetylcholine in the zonal gradient from stimulated preparations was not identical with that of endogenous (d0, [1H]) acetylcholine, but corresponded to a subpopulation of denser vesicles (equivalent to the VP2 fraction from Torpedo) that had preferentially taken up newly synthesized transmitter. The density difference between the reserve (VP1) and recycling (VP2) vesicles was less than that observed in Torpedo but this smaller difference can be accounted for theoretically by the difference in size between the vesicles of the two tissues. At rest, a lesser incorporation of labelled acetylcholine into the vesicle fraction was observed, and the peaks of endogenous and newly synthesized acetylcholine coincided. Stimulation in the absence of label followed by addition of label did not lead to incorporation of labelled acetylcholine, suggesting that the synthesis and storage of acetylcholine in this preparation and its recovery from stimulation is much more rapid than in Torpedo.     

Studies on a Possible Functional Coupling Between Presynaptic Acetylcholinesterase and High-Affinity Choline Uptake in the Rat Brain

The relationships between presynaptic acetylcholinesterase (AChE) and high-affinity choline uptake (HACU) were investigated using a monolayer of rat cortex synaptosomes in superfusion conditions. The following sets of experiments were performed: determination of [3H]choline ([3H]Ch) uptake during superfusion with [3H]Ch; determination of [3H]Ch uptake during superfusion with acetylcholine (ACh) tritiated in the Ch moiety; evaluation of ACh hydrolysis during superfusion with ACh labelled in the acetate moiety; and comparison of the uptake of [3H]Ch generated by hydrolysis of [3H]ACh with that occurring during superfusion with [3H]Ch. Intact ACh was not taken up by superfused synaptosomes. The uptake of [3H]Ch during superfusion with 1 or 0.1 microM [N-methyl-3H]ACh was two-thirds of that occurring during superfusion with the same concentrations of [3H]Ch. The amount of [3H]Ch produced by hydrolysis during 16 min of superfusion was 1/25 of the amount passing through the synaptosomal monolayer during 16 min of superfusion with [3H]Ch. The results indicate that presynaptic AChE and HACU are located in close proximity to each other on the cholinergic terminal membrane, an observation suggesting the possibility of a functional coupling between the two mechanisms.     

Dipalmitoylphosphatidylcholine liposomes reduce [3H]acetylcholine levels in an eserine-sensitive manner in rat cerebral cortical synaptosomes

We investigated the effects of various phospholipids on the presynaptic levels of newly synthesized [³H]acetylcholine (ACh) in rat cerebral cortical synaptosomes. When administered as small unilamellar vesicles (200–500 Å diameters) dipalmitoylphosphatidylcholine (DPPC) reduced [³H]ACh levels in concentration and time-related manners, while increasing the efflux of labelled choline to a similar extent. The reductions in synaptosomal [³H]-ACh levels induced by DPPC (3 mg/ml) were found in the cytosolic S₃ but not microsomal P₃ fraction, arguing for a cytoplasmic, nonvesicular site of action. DPPC-induced reductions in [³H]ACh levels were blocked by 100 M eserine, a tertiary amine cholinesterase inhibitor, but not with 100 M neostigmine, a quaternary ammonium inhibitor. Large unilamellar vesicles (2000–5000 Å diameters) consisting of soybean-phosphatidylcholine reduced [³H]ACh levels to the same extent that small vesicles did at the same concentration (3 mg/ml). Taken together, these results suggest that DPPC can fuse with membranes to increase the hydrolysis of cytoplasmic ACh via a small intra-terminal subpopulation of cholinesterases.     

Exchangeability of radioactive acetylcholine with the bound acetylcholine of synaptosomes and synaptic vesicles

1. The exchangeability with added radioactive acetylcholine of the acetylcholine in isolated presynaptic nerve terminals (synaptosomes) and isolated synaptic vesicles was studied by a Sephadex-column method. 2. A substantial proportion of the synaptosomal acetylcholine is exchangeable with added radioactive acetylcholine. It is liberated by hypo-osmotic shock and ultrasonic treatment, and behaves as though it occupies the cytoplasmic compartment of synaptosomes. 3. Methods of isolating vesicles from hypo-osmotically ruptured synaptosomes in optimum yield are discussed. 4. The acetylcholine of synaptic vesicles isolated on a sucrose density gradient is released by hypo-osmotic conditions, suggesting that it is enclosed by a semi-permeable membrane; however, it is not easily released by ultrasonic treatment. 5. Added radioactive acetylcholine does not exchange with vesicular acetylcholine under a variety of different conditions. These include addition of ATP and Mg(2+), and pre-loading of the synaptosome with radioactive acetylcholine before hypo-osmotic rupture. This failure to exchange is discussed in terms of the possible storage mechanism of vesicular acetylcholine.     

The uptake and metabolism of plasma lysophosphatidylcholine in vivo by the brain of squirrel monkeys

1. Adult squirrel monkeys were injected intravenously with doubly labelled lysophosphatidylcholine (a mixture of 1-[1-(14)C]palmitoyl-sn-glycero-3-phosphorylcholine and 1-acyl-sn-glycero-3-phosphoryl[Me-(3)H]choline; (3)H:(14)Cratio 3.75) complexed to albumin, and the incorporation into the brain was studied at times up to 3h. 2. After 20min, 1% of the radioactivity injected as lysophosphatidylcholine had been taken up by the brain. 3. Approx. 70% of the doubly labelled lysophosphatidylcholine taken up by both grey and white matter was converted into phosphatidylcholine, whereas about 30% was hydrolysed. 4. The absence of significant radioactivity in the phosphatidylcholine, free fatty acid and water-soluble fractions of plasma up to 30min after injection of doubly labelled lysophosphatidylcholine rules out the possibility that the rapid labelling of these compounds in brain could be due to uptake from or exchange with their counterparts in plasma. 5. The similarity between the (3)H:(14)C ratios of brain phosphatidylcholine and injected lysophosphatidylcholine demonstrates that formation of the former occurred predominantly via direct acylation. 6. Analysis of the water-soluble products from lysophosphatidylcholine catabolism revealed that appreciable glycerophosphoryl-[Me-(3)H]choline did not accumulate in the brain and that radioactivity was incorporated into choline, acetylcholine, phosphorylcholine and betaine. 7. The role of plasma lysophosphatidylcholine as both a precursor of brain phosphatidylcholine and a source of free choline for the brain is discussed.     

UPTAKE OF [3H-METHYL]CHOLINE BY MICROSOMAL, SYNAPTOSOMAL, MITOCHONDRIAL AND SYNAPTIC VESICLE FRACTIONS OF RAT BRAIN

Abstract— Microsomal, mitochondrial, synaptosomal and synaptic vesicle fractions of rat brain took up [³H-methyl]choline by a similar carrier-mediated transport system. The apparent K_m for the uptake of [³H-methyl]choline in these subcellular fractions was about 5 × 10^?5 M. Choline uptake was also observed in microsomal fractions prepared from liver and skeletal muscle. Virtually identical kinetic properties for [³H-methyl]choline transport were found in the synaptosomal fractions prepared from the whole brain, cerebellum or basal ganglia. Countertransport of [³H-methyl]choline from the synaptosomal fraction was demonstrated against a concentration gradient. HC-3 was a competitive inhibitor of the uptake of [³H-methyl]choline in brain microsomal, synaptosomal and mitochondria] fractions with respective values for K_i of 4.0, 2.1 and 2.3 × 10^?5 M. HC-15 was a competitive inhibitor of the transport of [³H-methyl]choline in the synaptosomal fraction, with a K_i of 1.7 × 10^?4 M. Upon entry into the microsomal fraction, 74 per cent of the radioactivity could be recovered as unaltered choline, 10 per cent as phosphorylcholine, 1.5 per cent as acetylcholine and 2.5 per cent as phospholipid. Choline acetyltransferase (EC 2.3.1.6) was assayed with [¹⁴C]acetylCoA in synaptosomal fractions prepared from basal ganglia and cerebellum, and in the 31,000 g supernatant fraction of a rat brain homogenate. Enzyme activity was 11-fold greater in the synaptosomal fraction from the basal ganglia than in that from the cerebellum. HC-3 did not inhibit choline acetyltransferase and there was no evidence for acetylation of HC-3. Our findings suggest that choline uptake is a ubiquitous property of membranes in the CNS and cannot serve to distinguish cholinergic nerve endings and their synaptic vesicles.