Regional Acetylcholine Metabolism in Brain During Acute Hypoglycemia and Recovery

Insulin-induced hypoglycemia in normothermic rats caused progressive neurological depression and differentially altered regional cerebral acetylcholine metabolism. Reductions of plasma glucose from 7.7 mM (control) to 2.5-1.7 mM (moderate hypoglycemia associated with decreased motor activity) or 1.5 mM (severe hypoglycemia with lethargy progressing to stupor) decreased glucose concentrations in the cerebral cortex, striatum, and hippocampus to less than 10% of control. Moderate hypoglycemia diminished acetylcholine concentrations in cortex and striatum (21% and 45%, respectively) and reduced [1-2H2, 2-2H2]choline incorporation into acetylcholine (62% and 41%, respectively). Severe hypoglycemia did not reduce the acetylcholine concentration or synthesis in cortex and striatum further. The concentrations of choline rose in the cortex (+53%) and striatum (+130%) of animals that became stuporous but a similar rise in [1-2H2, 2-2H2]choline left the specific activities of choline in these structures unchanged. Even severe hypoglycemia did not alter the hippocampal cholinergic system. In rats that developed hypoglycemic stupor and were then treated with glucose, the animals recovered apparently normal behavior, and the concentrations of acetylcholine and the incorporation of [1-2H2, 2-2H2]-choline into acetylcholine returned to control values in the striatum but not in the cerebral cortex. Thus, impaired acetylcholine metabolism in selected regions of the brain may contribute to the early symptoms of neurological dysfunction in hypoglycemia.     

The Independency of Choline Transport and Acetylcholine Synthesis

The coupling of choline transport to acetylcholine synthesis has been investigated by measurement of the isotopic dilution of a pulse of [3H]choline during its incorporation into the recently synthesised acetylcholine of cerebral cortex synaptosomes. Recently synthesised acetylcholine was identified as that containing 14C-labelled precursors introduced by a preincubation before the pulse. When [14C]glucose was used to label acetyl-CoA coupling ratios (calculated as the inverse of the dilution of extracellular [3H]choline during its incorporation into [3H]acetylcholine) of about 0.05-0.2 were found at a choline concentration of 1 microM, rising to 0.5 at choline concentrations of 10-50 microM. Experiments using [14C]choline as a precursor gave similar results, and it was shown that the isotopic dilution did not occur extrasynaptosomally and was not affected by low glucose concentrations. Coupling ratios were always less than unity and rose as the choline concentration increased. It is concluded that choline transported into the nerve terminal has no privileged access to choline acetyltransferase. The results can be explained by a rate-controlling transport of choline into the terminal followed by its rapid acetylation rather than any linkage or coupling of the two processes.     

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.     

Inhibition of High-Affinity Choline Uptake and Acetylcholine Synthesis by Quinuclidinyl and Hemicholinium Derivatives

Choline uptake into cholinergic neurons for acetylcholine (ACh) synthesis is by a specific, high-affinity, sodium- and temperature-dependent transport mechanism (HAChU). To assess the role of choline availability in regulation of ACh synthesis, the structure-activity relationships of several hemicholinium (HC) and quinuclidinyl analogs were evaluated in a dose response manner. As confirms previous studies, the HCs, e.g., HC-3, acetylsecohemicholinium, and HC-15 are potent inhibitors of HAChU, HC-3 being the most potent (I50 = 6.1 X 10(-8) M). In the present study, the most potent quinuclidinyl derivative was the N-methyl-3-quinuclidinone (I50 = 5.6 X 10(-7) M). This compound had approximately 100-fold greater inhibitory activity than the corresponding racemic alcohol, suggesting that the 3-hydroxyl functional group is not absolutely essential for activity. Increasing the size of the N-functional group from a methyl to an allyl in the alcohol led to a 10-fold increase in activity. However, removal of the quaternizing N-methyl group yielding the tertiary amine, 3-quinuclidinol hydrochloride, greatly reduced its capacity to inhibit HAChU. Of the 2-benzylidene-3-quinuclidinone derivatives studied, only the m-chloro derivative significantly reduced HAChU.     

Acetylcholine and Choline in Neuronal Tissue Measured by HPLC with Electrochemical Detection

Abstract: A simple, rapid method is presented for the determination of acetylcholine (ACh) and choline (Ch) in neuronal tissue using HPLC with electrochemical detection. The method is based on the separation of ACh and Ch by reverse-phase HPLC and mixing the effluent as it emerges from the column with acetylcholinesterase and Ch oxidase, which converts endogenous Ch and Ch produced by the hydrolysis of ACh to betaine and hydrogen peroxide. Production of hydrogen peroxide is continuously monitored electrochemically. The sensitivity of the procedure is 1 pmol for Ch and 2 pmol for ACh. Specificity of the method is based on HPLC, two specific enzymatic reactions, and the detection of hydrogen peroxide.     

The Effect of Acetylcholine Release on Choline Fluxes in Isolated Synaptic Terminals

Abstract: As in intact tissues, choline influx into synaptosomes is enhanced after a period of depolarization induced release of acetylcholine. The activation of uptake is dependent on the presence of Ca²⁺ and inhibited by high Mg²⁺ concentrations in the medium during depolarization. Choline transport in erythrocytes was not activated by prior treatment with potassium. The permeability constant of the synaptosome membrane to choline was found to be 2.7 × 10^?8 cm·s^?1 and to acetylcholine 1.8 ′ 10^?8 cm·s^?1. Choline influx has been studied after pre-loading synaptosomes with choline. Different radiolabels were used to measure efflux of preloaded choline and influx simultaneously. Isotopic dilution in flux studies was estimated and corrected for. Influx was stimulated by high internal concentrations of choline, and efflux similarly stimulated by high outside concentrations of choline. The maximal influx and efflux at saturating opposite concentrations of choline were equal with a value of about 500 pmol·min^?1 per mg synaptosomal protein. A reciprocating carrier would explain the equality of the maximal influx and efflux. Acetylcholine competes with choline for binding to the carrier but is itself hardly transported. Increased acetylcholine concentrations were shown to inhibit both choline influx and efflux from the trans position. Raising intrasynaptosomal acetylcholine concentrations by pre-loading abolished the stimulation of influx by prior depolarization. It is proposed that high concentrations of acetylcholine immobilize the carrier on the inside of the synaptic membrane. The stimulation of choline influx consequent upon depolarization is caused by release of ACh which results in relief of this immobilisation. The enhanced supply of choline achieved by this mechanism is likely to be important in maintaining stores of the acetylcholine in vivo.     

Synaptosomal Phospholipase D Potential Role in Providing Choline for Acetylcholine Synthesis

The phospholipase D of the rat brain synaptic membrane possesses the highest activity of this enzyme of any mammalian tissue examined. The synaptic phospholipase D activity is latent and barely detectable in the absence of 4 mM sodium oleate. Several other fatty acids were either less effective or ineffective as stimulators of activity compared to this monounsaturated fatty acid. The activity was decreased by hemicholinium-3, an inhibitor of choline uptake and slightly activated by neostigmine, an acetylcholinesterase inhibitor. Incubation of synaptosomes in the presence of sodium oleate and acetyl-coenzyme A resulted in the formation of a product chromatographing with acetylcholine. Acetylcholine formation was nearly undetectable in the absence of sodium oleate or acetyl-coenzyme A. These results implicate synaptosomal phospholipase D in releasing choline from phosphatidylcholine for acetylcholine formation.     

Measurement of Acetylcholine Turnover Rate in Brain: An Adjunct to a Simple HPLC Method for Choline and Acetylcholine

Abstract: An existing method for measuring acetylcholine (ACh) and choline (Ch) is shown to be useful formeasuring the turnover rate of ACh in mouse brain. Methl-[3H]Ch is injected into mice. They are killed atdifferent times by microwave irradiation and Ch and AChextracted and separated by reverse-phase HPLC. Ch andACh are converted to hydrogen peroxide by a post-column enzyme reaction. Hydrogen peroxide, which isdirectly related to the tissue content of Ch or ACh, isdetermined electrochemically. The fractions that corre-spond to the detector response for Ch and ACh are col-lected for the measurement of radioactivity. In this wayspecific radioactivities of endogenous Ch and ACh areestimated in the same sample. We used the specific ra-dioactivity values determined by this procedure to esti-mate the turnover of ACh for striatum, cerebral cortex, and hippocampus of the mouse.     

Influence of Dietary Choline Availability and Neuronal Demand on Acetylcholine Synthesis by Rat Brain

The main objective of this study was to test the hypothesis that the chronic administration of choline supplements a bound pool of choline from which free choline can be mobilized and used to support acetylcholine synthesis when the demand for precursor is increased. For these experiments, brain slices from rats fed diets containing different amounts of choline were incubated in a choline-free buffer and acetylcholine synthesis was measured under resting conditions and in the presence of K+-induced increases in acetylcholine synthesis and release. Rats fed the choline-supplemented diet had circulating choline levels that were 52% greater than the controls, and striatal and cerebral cortical slices from this group produced significantly more free choline during the incubation than slices from the controls. However, the synthesis and release of acetylcholine by these tissues did not differ from those by controls, during either resting or K+-evoked conditions. In contrast, acetylcholine synthesis and release by striatal and hippocampal slices from choline-deficient rats, animals that had circulating choline levels that were 80% of control values, decreased significantly; the production of free choline by these tissues was also depressed. Results indicate that, despite an increased production of free choline by brain slices from choline-supplemented rats, the synthesis of acetylcholine was unaltered, even in the presence of an increased neuronal demand. In contrast, the choline-deficient diet led to a decreased release of free choline from bound stores and an impaired ability of brain to synthesize acetylcholine.     

Relations Between the Extracellular Concentrations of Choline and Acetylcholine in Rat Striatum

Abstract: Changes in extracellular levels of acetylcholine (ACh) and choline (Ch) in the striatum of rats were examined by in vivo microdialysis after intraperitoneal injections of drugs. A dopamine D₂ antagonist, sulpiride (20 mg/kg), and a muscarinic antagonist, atropine (3.5 mg/kg), increased ACh levels and decreased Ch levels. On the contrary, the D₂ agonist (±)-2-( N -phenylethyl- N -propyl)amino-5-hydroxytetralin (N-434; 5 mg/kg) and an anesthetic, pentobarbital (50 mg/kg), decreased ACh levels and increased Ch levels. Perfusion of 10 µ M hemicholinium-3 (HC-3), a Ch uptake inhibitor, through the striatum induced a complete inhibition of ACh release and increased Ch levels in all drug-treated groups. The degree of relative increase in the level of Ch induced by HC-3 differed among the drug-pretreated groups; compared with the control group, the relative increase was larger in the sulpiride- and atropine-treated groups and smaller in the N-434 and pentobarbital-treated groups. Thus, we demonstrated reciprocal relations between extracellular concentrations of Ch and ACh after treatments by drugs. The data suggest that in the striatum, which is rich in cholinergic innervation, the extracellular Ch concentration is to a large extent determined by activity of the cholinergic transmission reflected in high-affinity choline uptake.     

Exogenous Choline Enhances the Synthesis of Acetylcholine Only Under Conditions of Increased Cholinergic Neuronal Activity

Abstract: The effect of choline (60 mg/kg, i.p.) on fluphenazine- and pentylenetetrazol-induced alterations in the concentration of acetylcholine (ACh) and/or the rate of sodium-dependent high-affinity choline uptake (HACU) in rat striatum and hippocampus was studied. Systemic administration of the dopamine receptor blocking agent fluphenazine hydrochloride (0.5 mg/kg, i.p.) decreased the concentration of ACh in the striatum; this effect was prevented by the prior administration of choline. The central nervous system stimulant pentylenetetrazol (30 mg/kg, i.p.) reduced the concentration of ACh in both striatum and hippocampus and increased the velocity of HACU in the hippocampus. Pretreatment with choline totally prevented the depletion of ACh induced by pentylenetetrazol in the striatum. In the hippocampus, prior administration of choline prevented the pentylenetetrazol-induced increase in the rate of HACU and attenuated the effect of pentylenetetrazol on the levels of ACh. Results indicate that the acute administration of choline antagonizes pharmacologically induced alterations in cholinergic activity as assessed by the rate of HACU and the steady-state concentration of ACh. Furthermore, data support the hypothesis that the administration of choline increases the ability of central cholinergic neurons to synthesize ACh under conditions of increased neuronal activity.     

Calcium-Independent Release of Acetylcholine from Stable Cell Lines Expressing Mouse Choline Acetyltransferase cDNA

Abstract: Stably transfected cells expressing mouse choline acetyltransferase (ChAT) cDNA were established, and the synthesis and release of acetylcholine (ACh) were examined. A cDNA clone coding for mouse ChAT was inserted into an expression vector (pEF321) containing a promoter for human elongation factor 1α to construct pEFmChAT. Neuronal (NG108-15, NS20Y, N1E115, and Neuro2A) and nonneuronal cell lines (L cells and NIH3T3) were transfected with pEFmChAT, and the cell lines that stably expressed high ChAT activity were selected. These cells expressed the 66-kDa ChAT protein and accumulated ACh mostly in the cytosol. The concentration of intracellular ACh in the cells increased upon raising the choline level in the medium. The cells continuously released ACh in a Ca²⁺-independent fashion. Neither high K⁺ nor calcium ionophore stimulated release of ACh from the cells.     

The Synthesis and Release of Acetylcholine by Depolarized Hippocampal Slices Is Increased by Increased Choline Available In Vitro Prior to Stimulation

The objective of these experiments was to determine whether preincubating hippocampal slices with choline provides precursor that can be used during a subsequent incubation to support or enhance the synthesis of acetylcholine (ACh). Slices were preincubated for 60 min with 0, 10, 25, or 50 microM choline, washed, resuspended, and then incubated for 10 min in choline-free buffer containing 4.74 (Krebs-Ringer bicarbonate, KRB) or 25 mM KCl. The tissue contents of ACh and choline were determined prior to and after the preincubation, as well as after the incubation; the amounts of ACh and choline released were measured, and ACh synthesis was calculated. Preincubation in the absence of choline increased the tissue content of ACh to 242% of original levels; preincubation with 10 microM choline did not lead to a further increase, but preincubation with 25 or 50 microM choline increased the ACh content to 272% of original levels, significantly greater than that of slices preincubated with either 0 or 10 microM choline. When tissues were subsequently incubated for 10 min with either KRB or 25 mM KCl, ACh release from slices preincubated with 50 microM choline was greater than from slices preincubated with 0, 10, or 25 microM choline. Incubation of slices with KRB did not alter the tissue content of ACh, but when tissues were incubated with 25 mM KCl, the ACh content of slices preincubated with 0 or 10 microM choline decreased significantly, whereas that of slices preincubated with 25 or 50 microM choline did not.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of Increasing Choline, In Vivo and In Vitro, on the Synthesis of Acetylcholine in a Sympathetic Ganglion

Abstract: The experiments described in this paper were designed to test whether increasing choline availability over normal physiological levels increases acetylcholine synthesis in the cat's superior cervical ganglion. When ganglia were perfused with Krebs solution, an increase in the medium's choline concentration over physiological (10⁻³M) levels increased tissue choline but did not increase tissue acetylcholine or the release of acetylcholine from stimulated ganglia. However, increasing plasma choline in the whole animal increased ganglionic acetylcholine levels. The basis for this difference in the effects of in vivo and in Vitro exposure to elevated choline levels on the tissue acetylcholine content was found to involve plasma factor(s), rather than indirect actions of choline, and the acetylcholine content of isolated ganglia was increased when the tissue was perfused with plasma, instead of Krebs solution, containing 10⁻³M-choline. The extra acetylcholine generated by this procedure was associated with a subsequent transient increase in transmitter release during short intervals of stimulation, but most of the extra acetylcholine was not readily available for release from stimulated ganglia. It is concluded that increasing choline available to sympathetic ganglia over physiological concentration does not have a sustained effect on the turnover of releasable transmitter under the conditions of these experiments.     

Phosphoethanolamine Enhances High-Affinity Choline Uptake and Acetylcholine Synthesis in Dissociated Cell Cultures of the Rat Septal Nucleus

Dissociated rat septal nucleus cells cultured in defined medium exhibited twofold increases in the maximal rates of sodium-dependent, high-affinity choline uptake and acetylcholine formation when grown in the presence of phosphoethanolamine. The effect was concentration-dependent (EC50 = 15 microM) and appeared to be associated with in vitro maturation of cholinergic neurons rather than with enhanced survival. Choline acetyltransferase, acetylcholinesterase, and choline kinase activities were unaffected by this treatment. The effect of phosphoethanolamine was specific for cholinergic neurons, because treatment with this compound did not alter the kinetic constants for high-affinity neuronal uptake of gamma-aminobutyric acid or dopamine. The action appeared to be mediated primarily through activation of the sodium-dependent, high-affinity transport mechanism for choline as opposed to alterations in the storage and release of acetylcholine.     

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.     

Alterations of Acetylcholine and Choline Metabolism in Mammalian Preparations Treated with β-Bungarotoxin

Abstract: We have studied the effects of β-bungarotoxin on acetylcholine and choline metabolism in central and peripheral cholinergic preparations using a gas chromatographic-mass spectrometric assay for acetylcholine and choline. In contrast with previous reports, β-bungarotoxin did not inhibit the high-affinity uptake of labeled choline or the synthesis of acetylcholine in rat brain synaptosomal fractions. However, the toxin did cause a significant increase of medium choline when it was incubated with synaptosomal fractions. This increase of endogenous choline in the medium may account for the previously reported inhibition of choline uptake because of a dilution of the specific activity of the labeled choline in the medium. Several experiments are reported in which a further characterization was made of the effect of β-bungarotoxin on medium choline. β-Bungarotoxin was also shown to cause a large increase of acetylcholine release from rat brain minces and a depletion of the acetylcholine content of minces. A similar phenomenon was found in diaphragm preparations that were exposed continuously to β-bungarotoxin. However, diaphragms that were treated for only 30 min with toxin showed the previously reported increase of acetylcholine content. β-Bungarotoxin did not have any measurable effect on acetylcholine turnover in smooth muscle preparations from guinea pig ileum. These results help to explain certain inconsistencies in the literature regarding the action of β-bungarotoxin.     

High-Level Synthesis and Fate of Acetylcholine in Baculovirus-Infected Cells: Characterization and Purification of Recombinant Rat Choline Acetyltransferase

Rat choline acetyltransferase (ChAT) has been expressed at a high level in Spodoptera frugiperda Sf9 cells using a baculovirus expression system. A cDNA containing the coding sequence for ChAT was inserted into the transfer vector pAcYM1 to yield the recombinant vector pAcYM1/ChAT. Sf9 cells were then coinfected with pAcYM1/ChAT and the wild-type Autographa californica virus. One recombinant virus particle, containing the cDNA for ChAT, was selected that expressed a protein of 68.5 kDa. Forty hours after infection of cells with the recombinant virus, the specific activity of ChAT in the cytosol was 190 nmol of acetylcholine/min/mg of protein, accounting for approximately 24% of the cell cytosolic proteins as being ChAT. The apparent Km values of the enzyme for choline and acetyl-CoA were 299 and 221 microM, respectively, whereas the respective Vmax values were 10.6 and 11.4 mumol of acetylcholine/min/mg of protein. In addition, analysis of the protein revealed that ChAT is phosphorylated in Sf9 cells. About 0.5 mg of ChAT was obtained from a one-step purification procedure starting with 10(8) infected Sf9 cells. Addition of choline to the incubation medium led to accumulation of high amounts of acetylcholine in the cytosol of the infected cells. The neurotransmitter was not released by Sf9 cells in response to membrane depolarization or on ionophore-mediated calcium entry. Some acetylcholine, which most likely originated from cell death inherent to viral infection, accumulated in the culture medium. The infected insect cells, which synthesize and store neurotransmitter, provide a new and convenient model for analyzing synaptic transmission at the molecular level.     

Human Retinas Synthesize and Release Acetylcholine

Human retinas have the capacity to synthesize and release [3H]acetylcholine ([3H]ACh) after an incubation in [3H]choline ([3H]Ch). Synthesis of [3H]Ch by retinal homogenates was determined using either high-voltage paper electrophoresis (HVPE) or a two-step enzymatic/extraction assay for separating [3H]ACh from [3H]Ch. The enzymatic/extraction assay is shown to be accurate over a wide range of concentrations (10(-6)-10(-12) M). Homogenates of human retina synthesize [3H]ACh from [3H]Ch. We find an approximate Km of 50 microM and a Vmax of about 20 nmol/mg protein/h (at 37 degrees C) for the synthesis of labeled ACh by retinal homogenates. Human retinas also release [3H]ACh after a pulse of [3H]Ch. Release of labeled transmitter is stimulated by potassium depolarization. The potassium-stimulated release is partially blocked by magnesium or cobalt ions. Release data were analyzed by both the enzymatic/extraction assay and HVPE; the results are qualitatively identical in both cases. The data reported here provide additional evidence for cholinergic neurotransmission in the human retina.