Actions of a monoclonal antibody Tor 23 on rat brain presynaptic cholinergic processes

Tor 23 is a monoclonal antibody, generated against cholinergic terminals of theTorpedo californica, that has been found to bind to the extracellular surface of cholinergic neurons in a variety of tissues. This study shows that Tor 23 inhibits: 1) high affinity [³H]hemicholinium-3 binding to detergent-solubilized membranes prepared from rat neocortices; 2) high affinity [³H]choline uptake in rat neocortical and striatal P₂ preparations; and 3) [³H]acetylcholine synthesis in isolated nerve terminals. Tor 23 does not appear to affect low affinity [³H]choline uptake or [³H]acetylcholine release. These results are consistent with the hypothesis that Tor 23 may bind to nerve terminal high affinity choline transporters in the rat brain.     

Ciliary ganglion neurons in cell culture: high affinity choline uptake and autoradiographic choline labeling

Chick ciliary ganglion neurons grown in dissociated cell culture have a high affinity uptake mechanism for choline that has the properties expected for cholinergic neurons. The uptake has an apparent K_m of ca. 0.3 μM and is blocked by addition of 10 μM hemicholinium-3 or replacement of Na⁺ by Li⁺ in the uptake medium. When the choline uptake mechanism is used to label ciliary ganglion neuron-myotube cultures autoradiographically, over 99% of the neurons are labeled. A few cells with neuronal morphologies in such cultures (<1%) are labeled by γ-[³H]aminobutyric acid uptake. The number of [³H]choline-labeled neurons and the amount of Na⁺-dependent choline uptake is the same for ciliary ganglion neurons grown with and without skeletal myotubes. Rat superior cervical ganglion neurons, grown in cell culture under conditions that induce them to synthesize acetylcholine and form cholinergic synapses, are labeled by [³H]choline uptake, though not as heavily as ciliary ganglion neurons. In contrast, chick dorsal root ganglion neurons, a presumed population of noncholinergic neurons, are not labeled by [³H]choline uptake. Thus high affinity choline uptake can be used to label autoradiographically the cholinergic neurons tested, while at least one population of noncholinergic neurons remains unlabeled.     

SODIUM-DEPENDENT HIGH AFFINITY CHOLINE UPTAKE: A REGULATORY STEP IN THE SYNTHESIS OF ACETYLCHOLINE

The sodium-dependent high affinity choline uptake into synaptosomes from rat brain has been studied after in vivo treatments which would alter the activity of cholinergic neurons. We utilized a number of treatments to reduce the activity of cholinergc neurons in the brain. Administration of pentobarbital (65 mg/kg), chloral hydrate (40 mg/kg) and γbutyrelactone (750 mg/kg) caused a 50-80% reduction in sodium-dependent high affinity choline uptake in several brain regions (30 min). This depression was not found 24 h after injection. Interruption of the cholinergic septal-hippocampal or habenuleinterpeduncular tracts by lesions (10 min-1 h) also caused a similar, large reduction in sodium-dependent high affinity choline uptake in the hippocampus and the interpeduncular nucleus respectively. We reversed the inactivity after pentobarbital administration by direct electrical stimulation of the cholinergic septal-hippocampal tract. Stimulation (40 Hz) for 10-15 min completely reversed the depression in sodium-dependent high affinity choline uptake. Stimulation at lower frequencies or for shorter times caused a partial reversal. Administration of pentylenetetrazol (75 mg/kg), a convulsant, was utilized to increase the activity of central cholinergic neurons. After drug administration, we found a large (60%) increase in sodium-de-pendent high affinity choline uptake. This increase was not found in the hippocampus when cholinergic afferents were interrupted by septal lesion prior to drug administration. We also examined the uptake after administration of cholinergic drugs. Oxotremorine (0.75 mg/kg), a muscarinic agonist which reduces acetylcholine release and turnover, caused a reduction in uptake. On the other hand, administration of scopolamine (5 mg/kg), a cholinergic antagonist which increases acetylcholine turnover, caused an increase in sodium-dependent high affinity choline uptake. Addition of any drug utilized, drectly to uptake samples, did not alter uptake. We examined the conversion of [³H]choline to [³H]acetylcholine in hippocampal synaptosomes after septal lesion, pentylenetetrazol administration and in untreated controls. In all cases, 60-70% of the total sodium-dependent tritium content was present as [³H]acetylcholine. Evidence was presented that homoexchange is not or is less involved in choline uptake than in GABA uptake. A kinetic analysis of sodium-dependent high affinity choline uptake was performed after all treatments. We found changes in V_max, after all treatments, which were consistently in the same direction as the alterations in activity. The proposal is made that the sodium-dependent high affinity choline uptake is coupled to cholinergic activity in such a way as to regulate the entry of choline for the maintenance of acetylcholine synthesis. The findings also lead us to propose that sodium-dependent high affinity choline uptake in vitro be utilized as a rapid, relative measure of the activity of cholinergic nerve terminals in vivo.     

THE UPTAKE, METABOLISM AND RELEASE OF HOMOCHOLINE: STUDIES WITH RAT BRAIN SYNAPTOSOMES AND CAT SUPERIOR CERVICAL GANGLION

The accumulation of [³H]homocholine (3-trimethylamino-propan-1-01) by isolated synaptosomes prepared from rat brain was resolved kinetically into a high (K_T= 3.0 μM) and a low (K_T= 14.5 μM) affinity system. Although homocholine was not acetylated by solubilized choline acetyltransferase, 64% of the homocholine accumulated by intact synaptosomes via the high affinity uptake process was acetylated. Homocholine was also acetylated in the superior cervical ganglion of the cat, and the amount of acetylhomocholine formed was increased (12-fold) by preganglionic nerve stimulation. In ganglia, acetylhomocholine was available for release by preganglionic nerve impulses, and its release was Ca²⁺-dependent, It is concluded that homocholine can form a cholinergic false transmitter, and that the substrate specificity of choline acetyltransferase in vitro might be different from that in situ.     

THE EFFECTS OF BOTULINUM TOXIN ON ACETYLCHOLINE METABOLISM IN MOUSE BRAIN SLICES AND SYNAPTOSOMES

The effects of Type A botulinum toxin on acetylcholine metabolism were studied using mouse brain slice and synaptosome preparations. Brain slices that had been incubated with the toxin for 2h exhibited a decreased release of acetylcholine into high K⁺ media. Botulinum toxin did not affect acetylcholine efflux from slices in normal K⁺ media. When labeled choline was present during the release incubation, a‘newly-synthesized’pool of acetylcholine was formed in the tissue. In toxin-treated slices exposed to high K⁺, both the production and the release of this‘newly-synthesized’acetylcholine were depressed. A possible explanation for these actions of botulinum toxin would be via an inhibition of the high affinity uptake of choline. This hypothesis was tested by measuring the high affinity uptake of [³H]choline into synaptosomes prepared from brain slices. Previous exposure of slices to botulinum toxin caused a significant reduction in the accumulation of label by the synaptosomes. These data are discussed in terms of our current understanding of the mechanism of action of botulinum toxin and the toxin's interaction with the mechanisms regulating acetylcholine turnover.     

The characterization of a sodium-dependent high affinity choline uptake system unassociated with acetylcholine biosynthesis

The cardiac ganglion of the horseshoe crab, Limulus polyphemus, was incubated in Chao's solution containing 0.01 microM [3H]choline at room temperature (25 +/- 2 degrees C) and the ganglion readily accumulated the radiolabel. The ganglion uptake of [3H]choline was linear over 60 min. Kinetic analysis revealed dual choline uptake systems within the cardiac ganglion, a high affinity uptake system (Km = 2.2 microM, Vmax = 0.16 pmoles/mg/min) and a low affinity system (Km = 92.3 microM, Vmax = 3.08 pmoles/mg/min). The high affinity uptake system was sodium-dependent and inhibited by micromolar concentrations of hemicholinium-3. A 15 min pre-exposure of the ganglion to Chao's solution containing 90 mM potassium stimulated a significant increase in choline uptake. There was no detectable synthesis of [3H]acetylcholine from the [3H]choline taken up by the cardiac ganglion. The major portion of the extractable label appeared in a fraction which co-electrophoresed with phosphorylcholine. These results suggest that the sodium-dependent high affinity [3H]choline uptake system of the cardiac ganglion subserves a specific requirement for choline which is unrelated to a cholinergic function.     

HIGH AFFINITY CHOLINE TRANSPORT IN GUINEA PIG BRAIN AND THE EFFECT OF NOREPINEPHRINE

—The influence of 1-norepinephrine on the accumulation of [¹⁴C]choline by nuclei-free homogenates and synaptosomes of guinea-pig brain was studied. Kinetic analysis of choline accumulation by guinea-pig brain resulted in both high and low affinity Michaelis constants. Norepinephrine stimulated the high affinity choline transport process but not the low and the magnitude of its stimulation in 3 different brain regions was correlated with the choline acetyltransferase activity of those regions. Depletion of norepinephrine from the brainstem by pretreatment with the catecholamine depleter alpha-methyl-para-tyrosine significantly decreased the maximal velocity of choline transport. Both the alpha adrenergic receptor blocker phentolamine and the beta adrenergic receptor blocker propranalol inhibited norepinephrine induced stimulation of choline transport. Cocaine stimulated choline transport at low concentrations and pretreatment of animals with reserpine significantly antagonized cocaine's stimulation of choline transport. The results suggest that endogenous norepinephrine may modify the high affinity choline transport process in guinea-pig brain.     

Calcium-dependent [3H]acetylcholine release and muscarinic autoreceptors in rat cortical synaptosomes during development

A number of presynaptic cholinergic parameters (high affinity [³H]choline uptake, [³H]acetylcholine synthesis, [³H]acetylcholine release, and autoinhibition of [³H]acetylcholine release mediated by muscarinic autoreceptors) were comparatively analyzed in rat brain cortex synaptosomes during postnatal development. These various functions showed a differential time course during development. At 10 days of age the release of [³H]acetylcholine evoked by 15 mM KCl from superfused synaptosomes was Ca²⁺-dependent but insensitive to the inhibitory action of extrasynaptosomal acetylcholine. The muscarinic autoreceptors regulating acetylcholine release were clearly detectable only at 14 days, indicating that their appearance may represent a criterion of synaptic maturation more valuable than the onset of a Ca²⁺-dependent release.     

Autoradiographic labeling of spinal cord neurons with high affinity choline uptake in cell culture

Embryonic chick spinal cord neurons grown in dissociated cell culture have a high affinity uptake mechanism for choline. We find that, in addition to acetylcholine synthesis, the accumulated choline is used for the synthesis of metabolites such as lipids that are retained in part by conventional fixation techniques. As a result autoradiographic methods can be used to identify the cells that have the uptake mechanism in spinal cord cultures. About 60% of the neurons are labeled by [³H]choline uptake in cultures prepared with spinal cord cells from 4-day-old embryos, and about 40% are labeled in cultures prepared with cord cells from 7-day-old embryos. Neurons that innervate skeletal myotubes in spinal cord-myotube cultures are consistently labeled by [³H]choline uptake. Neurons unlabeled by the procedure are viable: they exclude the dye trypan blue and accumulate ¹⁴C-amino acids for protein synthesis. Most of the neurons unlabeled by [³H]choline uptake can instead be labeled by uptake of γ-[³H]aminobutyric acid, and vice versa. These results suggest that high affinity choline uptake can be used to label cholinergic neurons in cell culture, and that at least some populations of noncholinergic neurons are not labeled by the procedure. It cannot yet be concluded, however, that all labeled neurons are cholinergic since more labeled neurons are obtained per cord than would be expected from the number of neurons making up identified cholinergic populations in vivo. A three- to fourfold increase in the amount of high affinity choline uptake is observed between Days 3 and 15 in culture for spinal cord cells obtained from 4-day-old embryos. The number of [³H]choline-labeled neurons in such cultures decreases slightly during the same period, suggesting that the increase in uptake reflects neuronal growth or development rather than an increase in population size. Both the magnitude of the uptake and the number of [³H]choline-labeled neurons are the same for spinal cord cells grown with and without skeletal myotubes.     

Modulation of synaptosomal high affinity choline transport.

Depolarization of synaptosomes produced by incubation in 35mMK⁺ Krebs Ringer phosphate buffer results in an increased Vmax and no change in K_T of the high affinity transport of [³H]-choline as determined upon re-incubation in normal K⁺ Krebs Ringer phosphate buffer. The high K⁺ induced increase in the uptake of choline appears to be independent of transmitter release. The K⁺ stimulated increase in the Vmax of the high affinity transport of choline is totally blocked by high, 11mM, Mg⁺². The proportion of choline converted to acetylcholine in synaptosomes previously depolarized is the same as those incubated in normal K⁺ Krebs Ringer; thus the absolute rate of acetylcholine synthesis in nerve terminals is increased as a result of prior depolarization.     

A MODEL OF HIGH AFFINITY CHOLINE TRANSPORT IN RAT CORTICAL SYNAPTOSOMES

Abstract— Initial velocity of choline uptake by cortical synaptosomes from the Long-Evans rat has been measured as a function of both choline and sodium concentration. These data were then fitted to the rate equation for each of several possible models which characterize the participation of sodium in the transport process, and the models giving best fit were identified. Although one cannot unequivocally distinguish between a model including a high affinity carrier component plus diffusion and one including both high affinity and low affinity carriers, the conclusions concerning the high affinity component are the same in both cases. The major conclusions from the model are as follows: (1) The carrier may first combine with either choline or sodium; if the first reaction is with sodium, then there is an obligatory reaction with a second sodium before choline can interact with the carrier. (2) Translocation may occur as either CS or CNa₂S (C= carrier; S= choline; CS= carrier-substrate complex). (3) The apparent maximal velocity (Va) is dependent on the sodium concentration. (4) K₁, the choline concentration giving Va/2. is also dependent on the sodium concentration. K₁ increases with [Na] from 0 to 38.41 mm ; above 38.41 mm -[Na]. K₁ declines with [Na]. (5) There is a sigmoidal relationship between velocity of uptake and [Na]; however, uptake is not zero at [Na] = 0. (6) Jm. uptake at a given [choline] and infinite [Na]. is hyperbolically related to the choline concentration, but changes slowly over the range of 0.5–5.0 ± 10^-6m . (7) K_Na, the sodium concentration giving a velocity equal to Jm/2, is related to the choline concentration by a quadratic equation, and was found to be greater than physiological [Na] at choline concentrations of 0.5, 0.6, or 1.0 ± 10^-6m . but less than physiological [Na] at choline concentrations of 2.0 or 5.0 ± 10^-6m . The best fit model for the high affinity uptake of choline is very similar to what has been found in previous studies for the high affinity uptake of glutamic acid and GABA, thus raising the question of whether or not all high affinity synaptosomal mechanisms may be variations of a common model.     

CHOLINE ACETYLTRANSFERASE AND THE HIGH AFFINITY UPTAKE OF CHOLINE IN CORPUS STRIATUM OF RESERPINISED RATS1

Rats treated with reserpine show increased V_max for the high affinity uptake of choline into small slices of corpus striatum. The choline acetyltransferase activity of whole homogenates of striatum is also increased. These changes are consistent with increased cholinergic neuronal activity in the striatum and seem likely to be adaptations mediating increased rates of synthesis of acetylcholine. The maximal increases found occurred concurrently, consistent with coupling of the high affinity uptake of choline and its acetylation in cholinergic nerve terminals of the rat. That increased high affinity uptake is accompanied by increased choline acetyltransferase activity, suggests the input of choline is not the sole determinant of rates of synthesis of acetylcholine, in spite of the large Vmas for striatal choline acetyltransferase, compared with that for high affinity uptake. These results seem best explained by kinetic coupling, in the rat, of the high affinity uptake of choline with a limited pool of choline acetyltransferase preferentially localised at the nerve terminal plasma membrane.     

MECHANISM OF ACTION OF NOTEXIN AND NOTECHIS 11-5 ON SYNAPTOSOMES

The neurochemical activity of notexin and notechis II-5 was investigated using a synaptosomal preparation of rat cerebral cortices. In preparations preincubated with [³H]choline in order to label acetylcholine, the toxins caused a rapid release of the transmitter which was calcium-dependent. The toxins were also potent inhibitors of high affinity choline uptake. Both agents produced a marked depolarization of the synaptosomal preparation as measured by a fluorescent dye and at high concentrations lysed the preparation. At a concentration of 0.1 μM, notexin and notechis II-5 caused a 50% increase in the efflux of lactate dehydrogenase activity. These results, together with electron microscopic observations, indicated that the toxins disrupt the synaptosomal membranes presumably by their inherent phospholipase activity. The release of acetylcholine and inhibition of choline uptake, together with the depolarization of synaptosomal membranes noted in this study, could explain the observed electrophysiological effects of these toxins.     

Uptake and release of choline in cultures of human glioma cells

Human glioma cells (138MG) have a low-affinity uptake system for choline (Km = 20 µM; V_max = 56 pmol/min/10⁶ cells). The uptake is reduced by acetylcholine, hemicholinium-3, HgCl₂, and phosphodiesterase inhibitors. Release of [³H]choline from preloaded cultures showed two pools with half-lives of 1.3 and 160 min. Choline release was stimulated by 8-bromo-cAMP or isobutylmethylxanthine. The results suggest that release of choline occurs by a facilitated diffusion transport system and is increased by elevations of intracellular cAMP.     

ON THE RELATIONSHIP BETWEEN [3H]CHOLINE UPTAKE ACTIVATION AND [3H]ACETYLCHOLINE RELEASE

The depolarization-induced, calcium-dependent release of [³H]ACh from hippocampal synaptosomes was studied in a superfusion system. Release increased, with increasing depolarization. Barium and strontium effectively substituted for calcium during the depolarization, but magnesium inhibited the release. Releasable [³H]ACh is derived from the sodium-dependent component of the [³H]choline uptake which points out the physiologic importance of sodium-dependent choline transport. It is concluded that [³H]ACh release in this system has the same properties as neurotransmitter release in many other systems. Previous studies have shown that treatments which alter the activity of cholinergic neurons in vivo result in parallel changes in sodium-dependent choline uptake in vitro. When synaptosomes were utilized from animals treated to reduce cholinergic activity, there was a reduced release following the reduced uptake. Conversely, when synaptosomes were taken from animals treated to increase sodium-dependent choline uptake, there was an increase in the release. It is concluded that the changes in sodium-dependent choline uptake in vitro consequent to changes in neuronal activity in vivo result in parallel changes in releasable ACh. A comparison was made between the effect of a number of ions and agents on release and their effect on the in vitro, depolarization-induced activation of sodium-dependent choline uptake. Barium and strontium, ions which substitute for calcium in the release process, support the in vitro activation of uptake. Vinblastine and Bay a 1040, compounds which block release, prevented the in vitro activation of sodium-dependent choline uptake. However, magnesium blocked release in a dose-dependent manner, but did not block the activation of uptake in vitro. Rather, magnesium substituted for calcium and supported the activation of uptake in a dose-dependent fashion. It is concluded that acetylcholine release is not necessary for the activation of choline uptake.     

Uptake of GABA by neuronal and nonneuronal cells in dispersed cell cultures of postnatal rat cerebellum

A study was made of the time course and kinetics of [³H]GABA uptake by dispersed cell cultures of postnatal rat cerebellum with and without neuronal cells. The properties of GABA neurons were calculated from the biochemical difference between the two types of cultures. It was found that for any given concentration of [³H]GABA, or any time up to 20 min, GABA neurons in cultures 21 days in vitro had an average velocity of uptake several orders of magnitude greater than that of nonneuronal cells. In addition, the apparent K_m values for GABA neurons for high and low affinity uptake were 0.33 × 10⁻⁶ M and 41.8 × 10⁻⁴ M, respectively. For nonneuronal cells, the apparent K_m for high affinity uptake was 0.29 × 10⁻⁶ M. The apparent V_max values for GABA neurons for high and low affinity uptake were 28.7 × 10⁻⁶ mol/g DNA/min and 151.5 mmol/g DNA/min, respectively. For nonneuronal cells, the apparent V_max for high affinity uptake was 0.06 × 10⁻⁶ mol/g DNA/min. No low affinity uptake system for nonneuronal cells could be detected after correcting the data for binding and diffusion. By substituting the apparent kinetic constants in the Michaelis-Menten equation, it was determined that for GABA concentrations of 5 × 10⁻⁹ M to 1 mM or higher over 99% of the GABA should be accumulated by GABA neurons, given equal access of all cells to the label. In addition, high affinity uptake of [³H]GABA by GABA neurons was completely blocked by treatment with 0.2 mM ouabain, whereas that by nonneuronal cells was only slightly decreased. Most (75–85%) of the [³H]GABA (4.4 × 10⁻⁶ M) uptake by both GABA neurons and nonneuronal cells was sodium and temperature dependent.     

MULTIPLE FORMS OF CHOLINE ACETYLTRANSFERASE AND THE HIGH AFFINITY UPTAKE OF CHOLINE IN BRAIN OF DEVELOPING AND ADULT RATS

The multiple molecular forms of choline acetyltransferase (ChAT) were analysed during the postnatal development of rat brain. Changes in the sodium-dependent, high affinity uptake of [³H]choline (HAUC) and in the efficiency of conversion of labelled choline into ACh in vitro were also examined. Both mature and 7-day old brain contained three molecular forms of ChAT, with isoelectric points of pH 7.3, 7.9 and 8.3, but the immature brain appeared to contain smaller concentrations of the most basic form of the enzyme (pI = 8.3). Of the total choline uptake measured in slices of frontal cortex, adult samples exhibited a greater proportion of HAUC than 7-day samples and appeared to acetylate more efficiently the [³H]choline accumulated by high affinity uptake. This evidence suggests a basic molecular form of ChAT, appearing in rat brain during postnatal development, might be responsible for the efficient coupling of the high affinity uptake and subsequent acetylation of choline in cholinergic nerve terminals.     

Arachidonic Acid Inhibits Choline Uptake and Depletes Acetylcholine Content in Rat Cerebral Cortical Synaptosomes

The effects of arachidonic acid on [3H]choline uptake, on [3H]acetylcholine accumulation, and on endogenous acetylcholine content and release in rat cerebral cortical synaptosomes were investigated. Arachidonic acid (10-150 microM) produced a dose-dependent inhibition of high-affinity [3H]choline uptake. Low-affinity [3H]choline uptake was also inhibited by arachidonic acid. Fatty acids inhibited high-affinity [3H]choline uptake with the following order of potency: arachidonic greater than palmitoleic greater than oleic greater than lauric; stearic acid (up to 150 microM) had no effect. Inhibition of [3H]choline uptake by arachidonic acid was reversed by bovine serum albumin. In the presence of arachidonic acid, there was an increased accumulation of choline in the medium, but this did not account for the inhibition of [3H]choline uptake produced by the fatty acid. Arachidonic acid inhibited the synthesis of [3H]acetylcholine from [3H]choline, and this inhibition was equal in magnitude to the inhibition of high-affinity [3H]choline uptake produced by the fatty acid. A K+-stimulated increase in [3H]acetylcholine synthesis was inhibited completely by arachidonic acid. Arachidonic acid also depleted endogenous acetylcholine stores. Concentrations of arachidonic acid and hemicholinium-3 that produced equivalent inhibition of [3H]choline uptake also produced equivalent depletion of acetylcholine content. In the presence of eserine, arachidonic acid had no effect on acetylcholine release. The results suggest that arachidonic acid may deplete acetylcholine content by inhibiting high-affinity choline uptake and subsequent acetylcholine synthesis. This raises the possibility that arachidonic acid may play a role in the impairment of cholinergic transmission seen in cerebral ischemia and other conditions in which large amounts of the free fatty acid are released in brain.     

Taurine uptake in synaptosomal fractions of rat cerebral cortex.

Abstract— [³⁵S]Taurine was found to be accumulated in synaptosomal fractions of rat cerebral cortex. Kinetic analysis in the range of 1–800 μm -[³⁵S]taurine revealed at least two different uptake processes. A high affinity uptake with a K_m of 20 μM and a low affinity uptake with a K_m of about 450 μM. The high affinity component was dependent on temperature and energy, and virtually abolished in the absence of sodium. Examination of the influence of structural analogues and putative transmitter substances indicates that the high affinity uptake of taurine into synaptosomal fractions of rat cerebral cortex is unique and highly specific. No specific actions of several centrally acting drugs on taurine uptake could be observed.     

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.