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.     

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.     

RELATIVE IMPORTANCE OF CHOLINE TRANSPORT TO SPONTANEOUS AND POTASSIUM DEPOLARIZED RELEASE OF ACh

—The importance of extracellular choline transport to spontaneous and K⁺ depolarized release of ACh was studied using mouse brain cortex minces. The results suggest that extracellular choline transport is not essential to spontaneously released ACh but is essential to K⁺ depolarized ACh release. Similar cumulative amounts of choline and ACh were found in the incubation media following incubation of minces in either Krebs or 35 mm -K⁺ Krebs suggesting the same production of free choline during both conditions. Double reciprocal plots of choline accumulation by non-depolarized cortex minces yield high and low affinity components. Conversely, similar analysis of choline accumulation by depolarized minces yields a single Michaelis constant (68 μm ) similar to the low affinity (50 μm ) Michaelis constant determined for choline accumulation by non-depolarized minces. Kinetic analysis of ACh release as a function of extracellular choline concentration during K⁺ depolarization also yields a Michaelis constant of 68 μm These data suggest a link between choline transport and ACh release during K⁺ depolarization.     

Sedimentation and release properties of P2 fractions derived from rat cerebral cortex slices incubated with radiolabeled GABA for a short or long time period

On homogenization of rat cerebral cortex slices previously incubated with [³H] GABA or [¹⁴C]GABA for 5 or 30 min, respectively, particles were recovered in P₂ fractions which exhibited similar buoyant density, but different sedimentation velocity on linear sucrose density gradient centrifugation. The K⁺-evoked release of [³H]GABA from particles isolated from slices previously incubated for 5 min with [³H]GABA was increased in the presence of exogenous Ca²⁺. In contrast, the K⁺-evoked release from particles isolated from slices previously incubated for 30 min with [³H]GABA, was not influenced by the presence of exogenous Ca²⁺.These results suggest that, depending on the incubation time of slices, exogenously applied GABA can be detected in differnnt pools. These pools not only seem to differ in their Ca²⁺ dependency of K⁺-evoked release but also in their subcellular localization.     

Effect of ethanol on [3H]Dopamine release in rat nucleus accumbens and striatal slices

Ethanol (10–200 mM) transiently increased tritium overflow from superfused rat nucleus accumbens slices previously incubated with [³H]dopamine (DA) and [¹⁴C]choline. The effect was greater in striatal tissue and did not appear to be a non-specific membrane effect since [¹⁴C]acetylcholine (ACh) release was not affected. Lack of antagonism by picrotoxin suggested that -aminobutyric acid (GABA) receptors were not involved. Calcium was not a requirement and the DA uptake blocker, nomifensine, was without effect. Ethanol appeared to be causing [³H]DA release into the cytoplasm. K⁺-stimulated release of [³H]DA and [¹⁴C]ACh from nucleus accumbens and striatal slices was not affected. Clonidine-mediated inhibition of the K⁺-evoked release of [³H]DA remained unaltered. Ethanol attenuated the isoproterenol-induced enhancement of [³H]DA release. Ethanol therefore appeared to interact with components of the DA terminal causing a transient increase in the release of neurotransmitter without impairing K⁺-evoked release but apparently interfering with the isoproterenol-induced effect.     

Ionic and Metabolic Requirements for High-Affinity Choline Uptake and Acetylcholine Synthesis in Nerve Terminals at a Neuromuscular Junction

Abstract: We have shown previously that in the chick ciliary nerve-iris muscle preparation Na⁺-dependent high-affinity choline uptake was confined to the nerve terminals. In this paper the sodium-dependent high-affinity choline uptake (SDHACU), which is coupled to acetylcholine (ACh) synthesis, was further characterized by measuring uptake of [³H]choline and its conversion to [³hjach under a variety of ionic and metabolic perturbations. Mannitol equilibration with the extracellular space was found to occur in less than 1 min in this preparation. Na⁺-dependent choline (Ch⁺) uptake was shown to be linear for 16 min and to reach an equilibrium before Na⁺-independent Ch⁺ uptake, which continued to increase for 60 min. Elevated [K⁺]₀ concentrations inhibited Ch⁺ uptake and ACh synthesis. Glycolytic and respiratory inhibitors also reduced both processes, as did ouabain and omission of [K⁺]₀. Incubation conditions that reduce transmitter release had no effect on inhibition by high [K⁺]₀. Reduction of SDHACU and sodium-dependent ACh synthesis by depolarization with high [K⁺]₀ or by inhibition of Na, K-ATPase implies that the electrochemical gradients for Ch⁺ and Na⁺ are important in providing a driving force for high-affinity Ch⁺ uptake. The inhibition by metabolic blockers suggests active transport, but the effects may be indirect, caused by reduced Na, K-ATPase activity and alterations in membrane potential. While most metabolic inhibitors exerted parallel effects on both Ch⁺ uptake and ACh synthesis, in some cases Ch⁺ uptake was more strongly inhibited than ACh synthesis. This occurred in preparations incubated with high [K⁺]₀ and ouabain. Na⁺-dependent Ch⁺ uptake and ACh synthesis were found to be temperature-dependent with a Q₁₀ (20–30°) of 3.6 and 6.6, respectively and a Q₁₀ (30–40°) of 1.3 and 1.0, respectively. Inhibition of acetylcholinesterase by paraoxon increases to 92% the proportion of the Ch⁺ taken up which is converted to ACh. ACh did not reduce Ch⁺ transport when present at 100 μM.     

The ionophore X537A (Lasolocid) transiently increases acetylcholine release from rat brain invitro

The effect of X537A on acetylcholine (ACh) release was examined $\text{in vitro}$ in superfused slices of rat cerebrum and striatum. The ionophore (30 μM) induced a transient release of ACh which was not dependent on calcium in the medium. Also in contrast to K⁺-stimulated release, X537A-induced release was not sustained by 10^?5M choline in the superfusion medium and not inhibited by 5 × 10^?4M pentobarbital. The ionophore did not transport ACh or choline from an aqueous to an organic phase. Both K⁺ and X537A inhibited 1 μM (³H) choline uptake into striatal synaptosomes but this effect of X537A was more extensive and less reversible than that caused by K⁺. X537A did not inhibit choline acetyltransferase activity.     

Effects of High-Potassium-Induced Depolarization on Amino Acid Chemistry of the Dorsal Cochlear Nucleus in Rat Brain Slices

High K⁺ was used to depolarize glia and neurons in order to study the effects on amino acid release from and concentrations within the dorsal cochlear nucleus (DCN) of brain slices. The release of glutamate, -aminobutyrate (GABA) and glycine increased significantly during exposure to 50 mM K⁺, while glutamine and serine release decreased significantly during and/or after exposure, respectively. After 10 min of exposure to 50 mM K⁺, glutamine concentrations increased in all three layers of DCN slices, to more than 5 times the values in unexposed slices. In the presence of a glutamate uptake blocker, L-trans-pyrrolidine-2,4-dicarboxylic acid (PDC), glutamine concentrations in all layers did not increase as much during 50 mM K⁺. Similar but smaller changes occurred for serine. Mean ATP concentrations were lower in 50 mM K⁺-exposed slices compared to control. The results suggest that depolarization, such as during increased neural activity, can greatly affect amino acid metabolism in the cochlear nucleus.     

Spontaneous and evoked release of [3H]taurine from a P2 subcellular fraction of the rat retina

The effects of spontaneous and evoked [³H]taurine release from a P₂ fraction prepared from rat retinas were studied. The P₂ fraction was preloaded with [³H]taurine under conditions of high-affinity uptake and then examined for [³H]taurine efflux utilizing superfusion techniques. Exposure of the P₂ fraction to high K⁺ (56 mM) evoked a Ca²⁺-independent release of [³H]taurine. Li⁺ (56 mM) and veratridine (100 M) had significantly less effect (8–15% and 15–30%, respectively) on releasing [³H]taurine compared to the K⁺-evoked release. 4-Aminopyridine (1 mM) had no effect on the release of [³H]taurine. The spontaneous release of [³H]taurine was also Ca²⁺-independent. When Na⁺ was omitted from the incubation medium K⁺-evoked [³H]taurine release was inhibited by approximately 40% at the first 5 minute depolarization period but was not affected at a second subsequent 5 minute depolarization period. The spontaneous release of [³H]taurine was inhibited by 60% in the absence of Na⁺. Substitution of Br^– for Cl^– had no effect on the release of either spontaneous or K⁺-evoked [³H]taurine release. However, substitution of the Cl^– with acetate, isethionate, or gluconate decreased K⁺-evoked [³H]taurine release. Addition of taurine to the superfusion medium (homoexchange) resulted in no significant increase in [³H]taurine efflux. The taurine-transport inhibitor guanidinoethanesulfonic acid increased the spontaneous release of [³H]taurine by approximately 40%. These results suggest that the taurine release of [³H]taurine is not simply a reversal of the carrier-mediated uptake system. It also appears that taurine is not released from vesicles within the synaptosomes but does not rule out the possibility that taurine is a neurotransmitter. The data involving chloride substitution with permeant and impermeant anions support the concept that the major portion of [³H]taurine release is due to an osmoregulatory action of taurine while depolarization accounts for only a small portion of [³H]taurine release.     

Synthesis and Release of Dopamine in Rat Striatal Slices: Requirement for Exogenous Tyrosine in the Medium

When incubated in a tyrosine-free medium, the tissue dopamine (DA) level of rat striatal slices increased by about 921 ± 15 pmol/mg protein during 90 min of preincubation. In contrast, the tissue-free tyrosine level declined only 130 pmol/mg protein in the same assay period. Depolarization of the slices with high K⁺ increased both DA and DOPAC outputs and depleted tissue DA level by about 75%. Although 60 min of resting after high K⁺ depolarization significantly restored the tissue DA levels, neither this restoration nor depolarization-induced DA release was altered by exogenous tyrosine. Similarly, failure of exogenous tyrosine was also observed during three successive depolarization periods of striatal slices. These results indicate that nigrostriatal dopaminergic neurons are able to synthesize and release the DA in the absence of exogenous tyrosine in the medium. Since the free tyrosine level in the slices does not seem to be a sufficient source, it is likely that tyrosine mobilized from its bound source(s) supports the DA synthesis under in vitro experimental conditions.     

Evaluation of acetate uptake and its relative conversion to acetylcholine in Torpedo electric organ synaptosomes under different ionic and metabolic conditions

The uptake of acetate and its incorporation into acetylcholine were measured under various conditions in nerve terminals isolated from the electric organ in order to characterize acetate uptake and to study the relationship between acetate uptake and acetylcholine synthesis in a pure cholinergic preparation. It was found that increasing extracellular choline up to 10^?4 M had no effect on either acetate uptake or the conversion of acetate to ACh, while the addition of hemicholinium-3 to the incubation medium led to decreases in both parameters. Hence, it appears that endogenous levels of choline are sufficient to support ongoing acetylcholine synthesis in this preparation and that this synthesis depends to some extent on the uptake of extracellular choline. Nonetheless, in the absence of choline uptake, both the uptake of acetate and the conversion of acetate to acetylcholine remained substantial, indicating that internal sources of choline as well can be used for acetylcholine synthesis.Acetate uptake displayed a marked requirement for external Na⁺ and was decreased following depolarization of the synaptosomes by an elevated K⁺ concentration. The conversion of acetate to acetylcholine followed a similar pattern, except that a small reduction in acetylcholine synthesis was observed in the absence of external Ca²⁺, while acetate uptake was unaffected. The addition of ATP, AMP-PNP or phosphate to the incubation medium caused an increase in both the uptake and incorporation of acetate, but adenosine had no effect on either of these functions. Choline uptake, meanwhile, was unchanged in the presence of ATP, phosphate or adenosine. Acetate uptake appears to be more closely linked to its intracellular metabolism than to the transmembrane movement of choline itself.The mechanism by which acetate crosses the nerve terminal membrane has not been established, but the possibility that acetate is a substrate for a monocarboxylate transport system such as has been described in other systems can be ruled out as inhibitors of anion permeability do not block acetate uptake in this preparation.     

A comparison of the effects of scorpion venom tityustoxin and ouabain on the release of acetylcholine from incubated slices of rat brain.

The increase in the release of acetylcholine (ACh) from cortical slices of rat brain elicited by the depolarizing agents, ouabain and tityustoxin (TsTX) was compared in the presence of tetrodotoxin, an inhibitor of Na⁺ transport and of ethyleneglycol tetraacetic acid, a specific chelator of Ca²⁺. TsTX stimulated the release of ACh independently of K¹ but required both Na⁺ and Ca²⁺. Unlike ouabain, TsTX failed to inhibit the Na⁺, K⁺ -ATPase of rat brain homogenates. The uptake of ²⁴Na⁺ and of ⁴⁵Ca²⁺ by the slices was significantly enhanced by TsTX over the entire incubation period during which this process was compared to TsTX-free controls. A hypothesis of TsTX action is proposed which differs from that necessary to explain the ACh releasing effect of ouabain.     

Choline Uptake and Acetylcholine Synthesis in Synaptosomes: Investigations Using Two Different Labeled Variants of Choline

Abstract: Using sequential incubations in media of different K⁺ composition, we investigated the dynamics of choline (Ch) uptake and acetylcholine (ACh) synthesis in rat brain synaptosomal preparations, using two different deuterated variants of choline and a gas chromatographic-mass spectrometric (GC-MS) assay for ACh and Ch. Synaptosomes were preincubated for 10 min in a Krebs medium with or without high K⁺ and with 2 μM-[²H₉]Ch. At the end of the preincubation all variants of ACh and Ch were measured in samples of the pellet and medium. In the second incubation (4 min) samples of synaptosomes were resuspended in normal or high K⁺ solutions containing [²H₄]Ch (2 μM) and all variants of ACh and Ch were measured in the pellet and medium at the end of this period. This protocol allowed us to compare the effects of preincubation in normal or high K⁺ solution on the metabolism during a second low or high K⁺ incubation of a [²H₉]Ch pool accumulated during the preincubation period. Moreover, we were able to compare and contrast the effects of this protocol on [²H₉]Ch metabolism versus [²H₄]Ch metabolism. The most striking result we obtained was that [²H₉]Ch that had been retained by the synaptosomes after the preincubation was not acetylated during a subsequent incubation in normal or high K⁺ media. This result suggests that if an intraterminal pool of Ch is involved in ACh synthesis, the size of this pool is below the limits of detection of our assay. We have confirmed the observation that a prior depolarizing incubation results in an enhanced uptake of Ch during a second incubation in normal K⁺ Krebs. Moreover, Ch uptake is stimulated by prior incubation under depolarizing conditions relative to normal preincubation when the second incubation is in a high K⁺ solution. These results are discussed in terms of current models of the regulation of ACh synthesis in brain.     

Dopamine release induced by electrical field stimulation of rat hypothalamus invitro: Inhibition by melatonin

Microdissected slices of rat hypothalamus were incubated with ³H -dopamine and then subjected to two successive sets of electrical field stimulation in a superfusion chamber. Neurotransmitter release was found to be calcium dependent and the amount of release was determined by scintillation counting of the effluent buffer. The release obtained following the first train of stimuli served as an internal reference. The samples were exposed to drugs during the interval between the two sets of stimuli. Using this technique, as well as K⁺-evoked depolarization, we were able to show that subnanomolar concentrations of melatonin, the hormone secreted from the pineal gland, inhibits dopamine release from hypothalamic slices. The possibility that melatonin modulates neurotransmission in the brain is therefore indicated.     

Amyloid β-Peptide Inhibits High-Affinity Choline Uptake and Acetylcholine Release in Rat Hippocampal Slices

Abstract: The characteristic pathological features of the postmortem brain of Alzheimer's disease (AD) patients include, among other features, the presence of neuritic plaques composed of amyloid β-peptide (Aβ) and the loss of basal forebrain cholinergic neurons, which innervate the hippocampus and the cortex. Studies of the pathological changes that characterize AD and several other lines of evidence indicate that Aβ accumulation in vivo may initiate and/or contribute to the process of neurodegeneration and thereby the development of AD. However, the mechanisms by which Aβ peptide influences/causes degeneration of the basal forebrain cholinergic neurons and/or the cognitive impairment characteristic of AD remain obscure. Using in vitro slice preparations, we have recently reported that Aβ-related peptides, under acute conditions, potently inhibit K⁺-evoked endogenous acetylcholine (ACh) release from hippocampus and cortex but not from striatum. In the present study, we have further characterized Aβ-mediated inhibition of ACh release and also measured the effects of these peptides on choline acetyltransferase (ChAT) activity and high-affinity choline uptake (HACU) in hippocampal, cortical, and striatal regions of the rat brain. Aβ_1–40 (10^?8M) potently inhibited veratridine-evoked endogenous ACh release from rat hippocampal slices and also decreased the K⁺-evoked release potentiated by the nitric oxide-generating agent, sodium nitroprusside (SNP). It is interesting that the endogenous cyclic GMP level induced by SNP was found to be unaltered in the presence of Aβ_1–40. The activity of the enzyme ChAT was not altered by Aβ peptides in hippocampus, cortex, or striatum. HACU was reduced significantly by various Aβ peptides (10^?14 to 10^?6M) in hippocampal and cortical synaptosomes. However, the uptake of choline by striatal synaptosomes was altered only at high concentration of Aβ (10^?6M). Taken together, these results indicate that Aβ peptides, under acute conditions, can decrease endogenous ACh release and the uptake of choline but exhibit no effect on ChAT activity. In addition, the evidence that Aβ peptides target primarily the hippocampus and cortex provides a potential mechanistic framework suggesting that the preferential vulnerability of basal forebrain cholinergic neurons and their projections in AD could relate, at least in part, to their sensitivity to Aβ peptides.     

THE MECHANISM OF THE EXCLUSION OF SODIUM IONS AND THE CONCENTRATION OF POTASSIUM IONS BY GUINEA-PIG CEREBRAL CORTEX SLICES

—Guinea pig cerebral slices were incubated in oxygenated Krebs-Ringer bicarbonate glucose saline for periods of 1 s to 60 min, and their swelling and Na⁺ and K⁺ cone were measured. The swelling was at the rate of 8 per cent for the 1st min, and 0·8 per cent for the next 29 min; it fell significantly during the subsequent 30 min (P= 0·05). The Na⁺ and K⁺ concn in the tissue fluctuated during the 1st min of incubation, but the Na⁺ concn had risen to a mean of 108 mm after 1 min incubation and the K⁺ concn had fallen to a mean of 52 mm by 3 min. The concentrations of these cations did not change significantly after these times. Cerebral slices were also incubated for 30 min in isotonic media modified such that Na⁺, + K⁺, Na⁺+ choline⁺, or K⁺+ choline⁺ always added up to 150 mm . It was found that about half of the swelling (20-25 per cent) was independent of the Na⁺ or K⁺ concn and a further 20-25 per cent of the swelling varied with the cations only if Na⁺ and K⁺ were both present and was a function of the K⁺ concn in the medium (0·15 per cent m-mol). The Na⁺ concn in the tissue was a mean 8·4 mm after incubation in a Na⁺-free medium and 7·1 mm in K⁺ after incubation in a K⁺-free medium. Cerebral slices in the presence of Na⁺+ K⁺ excluded one molecule of Na⁺ for every four molecules in the incubating medium; they accumulated K⁺ from the medium until the concn in the medium exceeded 130 mm .     

Intrastriatal kainic acid elicits functional supersensitivity of muscarinic receptors regulating dopamine release

Acetylcholine enhanced in a concentration-dependent way the K⁺ (15 mM)-evoked release of [³H]dopamine from synaptosomes isolated from rat corpus striatum and prelabeled with the radioactive catecholamine. The concentration-effect curve of ACh obtained in presence of 1.2 mM Ca²⁺ was progressively shifted to the left when [Ca²⁺] was lowered to 0.4 and to 0.2 mM. Intrastriatal injections of kainic acid reduced (70%) the uptake of [³H]choline in synaptosomes prepared 8 days after the lesion but did not affect significantly the uptake of [³H]dopamine. Also the release of [³H]dopamine evoked by K⁺ was minimally affected by kainic acid treatment. In contrast, acetylcholine (tested in presence of 1.2 or 0.2 mM Ca²⁺) was much more effective in enhancing [³H]dopamine release in synaptosomes from kainic acid-lesioned than from unlesioned striata. The results suggest that muscarinic receptors located on dopamine nerve terminals undergo supersensitivity following intrastriatal kainic acid injection.     

Release of acetylcholine and GABA,and activity of their synthesizing enzymes in the rat pontine reticular formation

The aim of this study was to obtain neurochemical information on the possible role of acetylcholine (ACh) and -aminobutyric acid (GABA) as neurotransmitters in the pontine reticular formation (PRF). We studied the uptake of labeled choline and GABA, as well as the release of this amino acid and of ACh, in PRF slices of the rat. In addition, choline acetyltransferase, acetylcholinesterase and glutamate decarboxylase activities were assayed in PRF homogenates. The uptake of GABA was strictly Na⁺-dependent, whereas choline uptake was only partially Na⁺-dependent. The release of both ACh and GABA was stimulated by K⁺-depolarization, but only the former was Ca²⁺-dependent. Choline acetyltransferase activity in the PRF was 74% of that in the striatum, whereas acetylcholinesterase activity was considerably lower. Glutamate decarboxylase activity in the PRF was about half that observed in the striatum. These findings support the possibility that both ACh and GABA may act as neurotransmitters in the rat PRF.     

FURTHER EXPERIMENTS ON THE UPTAKE OF ACETYLCHOLINE AND ATROPINE AND THE RELEASE OF ACETYLCHOLINE FROM MOUSE BRAIN CORTEX SLICES AFTER TREATMENT WITH PHOSPHOLIPASES

—Uptake of acetylcholine (ACh) in mouse brain cortex slices, previously shown with ACh synthesized from tritiated choline is confirmed with acetyl[1-¹⁴C]choline. Radioactivity from tritiated sodium acetate also accumulates in slices, but forms hardly any ACh. Uptake of ACh increases in a Ca²⁺-free medium, decreases again upon addition of a 3 × 10⁵ molar concentration of an anticholinergic benzilate compound and is completely blocked by the same compound at 3 × 10³ m. Slices preloaded with labelled ACh release, after extensive washing, some of their radioactivity into an outer medium free from ACh. Phospholipase, A or C, increases the release of radioactivity from the slices. An equilibrium is reached both with controls and phospholipase-treated slices. Remaining radioactivity seems to be due to bound ACh. Calcium and magnesium ions have no effect on the uptake of tritiated atropine, although low concentrations of Ca²⁺ decrease the effects of phospholipase C on atropine uptake. The inhibitory effect of K⁺ on atropine uptake disappears completely after treatment with small amounts of phospholipase A, but even high concentrations of phospholipase C have no effect.     

A homeostatic mechanism counteracting K(+) -evoked choline release in adult brain

Choline (Ch) is an essential nutrient as the biosynthetic precursor of acetylcholine (ACh) and phospholipids. Under resting conditions, the intracellular accumulation of Ch (above 10-fold), which is positively charged, is governed by the membrane potential and follows the Nernst equation. Accordingly, in synaptosomes from adult rats during depolarization, we observed a linear relationship between release of free cytoplasmic Ch and KCl concentration (2.7-120 mm). The K(+) -evoked Ch release was Ca(2+) -independent and did not originate from ACh or phospholipid hydrolysis. In superfused brain slices of adult rats, however, a K(+) -induced Ch efflux was absent. Also, under in vivo conditions, 30-60 mm KCl failed to increase the extracellular Ch level as shown by microdialysis in adult rat hippocampus. On the contrary, in brain slices from 1-week-old rats, high K(+) as well as 4-aminopyridine evoked a marked Ch efflux in a concentration-dependent fashion. This phenomenon faded within 1 week. Hemicholinium-3 (HC-3, 1 and 10 microm), a blocker of cellular choline uptake, caused a marked efflux of choline from adult rat slices but no or significantly less release from immature slices. We conclude that depolarization of synaptic endings causes a Ca(2+) -independent release of free cytoplasmic Ch into the extracellular space. In adult rat brain, this elevation of Ch is counteracted by a homeostatic mechanism such as uptake into brain cells.