Synaptosomal transport and acetylation of choline

Acetylcholine (ACh) synthesis can be impaired by reduction of the availability of either of its precursors, choline (Ch) or acetylcoenzyme A (AcCoA). The high affinity transport of Ch is inhibited by hemicholinium-3 and this results in reduced synthesis of ACh (1–3). Under some circumstances ACh metabolism in the brain appears to be affected by parenteral (4) or dietary (5, 14) administration of Ch. The production of AcCoA can apparently be reduced by inhibition of the utilization of pyruvate or glucose, which also decreases the synthesis of ACh (6, 7). Recent experiments by Barker and Mittag (8, 9) led them to propose that the high affinity transport of Ch and the subsequent transfer of an acetyl group from AcCoA, catalyzed by Ch acetyltransferase (CAT), were directly coupled. We have tested this hypothesis by reducing the availability of AcCoA and measuring both the rate of transport of Ch by the high affinity system and the rate at which it is converted to ACh.     

4-(1-Naphthylvinyl)pyridine Decreases Brain Acetylcholine In Vivo, but Does Not Alter the Level of Acetyl-CoA

The effects of intraperitoneally administered 4-(1-naphthylvinyl)pyridine (NVP; 200 mg/kg) on the concentrations of acetylcholine (ACh), choline (Ch), and acetyl-CoA (AcCoA) in rat striatum, cortex, hippocampus, and cerebellum were investigated. Twenty minutes after treatment, the content of ACh was significantly diminished, whereas that of Ch was increased. In response to stress (swimming for 20 min), these changes were enhanced. However, the AcCoA content did not change in any of the brain regions. It is thus very likely that the decrease of brain ACh concentration induced by NVP is due to the drug's effect on choline acetyltransferase (ChAT) and/or the reduction of the high-affinity Ch uptake, and not on the availability of AcCoA. Presumably, the pharmacologically diminished activity of ChAT may become the rate-limiting factor in the maintenance of ACh levels in cholinergic neurons.     

REGULATION OF ACETYLCHOLINE SYNTHESIS: CONTROL OF CHOLINE TRANSPORT AND ACETYLATION IN SYNAPTOSOMES

Abstract— The high affinity transport of choline (Ch) and the synthesis of acetylcholine (ACh) were measured in synaptosomes by measuring the utilization of [²H₄]Ch. The synthesis of ACh was reduced under several conditions which reduce the availability of acetyl coenzyme A (AcCoA) including no glucose added, replacement of glucose with succinate or impairment of glucose utilization by bromopyr-uvate, NaCN, or pentobarbital. These conditions did not reduce the amount of unacetylated [²H₄]Ch in the synaptosomes indicating that the high affinity transport of Ch is not directly coupled to the synthesis of ACh.     

Mechanisms controlling choline transport and acetylcholine synthesis in motor nerve terminals during electrical stimulation

Electrical stimulation of the chick ciliary nerve leads to a frequency-dependent increase in the Na+-dependent high affinity uptake of [3H]choline (SDHACU) and its conversion to acetylcholine (ACh) in the nerve terminals innervating the iris muscle. The forces that drive this choline (Ch) uptake across the presynaptic membrane were evaluated. Depolarization with increased [K+] out or veratridine decreases Ch accumulation. In addition to the electrical driving force, energy is provided by the Na+ gradient. Inhibition of the Na,K-ATPase decreased the Ch taken up. Thus, changes in the rate of Ch transport are dependent on the electrochemical gradients for both Ch and Na+. Ch uptake and ACh synthesis were increased after a conditioning preincubation with high [K+] out or veratridine. As is the case for electrical stimulation, this acceleration of Ch uptake and ACh synthesis was strongly dependent on the presence of Ca++ in the incubation medium. Na+ influx through a TTX-sensitive channel also contributed to this acceleration. Inasmuch as membrane depolarization reduces the initial velocity of Ch uptake and ACh synthesis, their increases during electrical stimulation therefore cannot be the direct effect of the depolarization phase of the action potential. Instead they are the result of the ionic fluxes accompanying the presynaptic spike. It is concluded that stimulation of Ch uptake and ACh synthesis by nerve activity depends first, on the ACh release elicited by Ca++ influx after depolarization and second, on the activation of the Na,K-ATPase due to Na+ entry. Furthermore, it is suggested that the release of ACh after stimulation drives translocation of cytoplasmic ACh into a protected compartment (probably vesicular). This recompartmentation of intraterminal ACh stimulates ACh synthesis by mass action, allowing further accumulation of Ch.     

Choline Transport and Metabolism in Soman-or Sarin-Intoxicated Brain

The metabolism and blood-brain transport of choline (Ch) were investigated in perfused canine brain under control conditions and for 60 min after inhibition of brain cholinesterases by the organophosphorus (OP) compounds soman (pinacolylmethylphosphonofluoridate). Ch and acetylcholine (ACh) in blood and brain samples were analyzed using gas chromatography-mass spectrometry methods. Net transport of Ch was determined by Ch analysis in arterial and venous samples. Unidirectional transport of [3H]Ch was determined using the indicator dilution method. During control perfusion periods of 90 min, net efflux of brain Ch occurred at a rate of 1.6 +/- 0.4 nmol/g/min, and the Ch content of the recirculated perfusate increased 10-fold to approximately 8 microM. Brain Ch content increased in proportion to the increase in perfusate Ch level, but brain ACh was unaltered. Rapid administration of soman (100 micrograms) or sarin (400 micrograms) into the arterial perfusate after a 40-min control period resulted in a greater than 10-fold increase in ACh content in cerebral cortex, brainstem, and hippocampus. The ACh content of cerebellum increased only slightly. The Ch level in all four brain regions studied also increased two- to fourfold above control levels. Ch efflux from brain, however, decreased to 0.2 +/- 0.1 nmol/g/min during the 60 min after OP exposure. Unidirectional influx of [3H]Ch was 0.49 +/- 0.07 nmol/g/min before and did not change significantly 10 or 40 min after OP exposure, thus indicating that the Ch transporter of the brain endothelial cell is not directly inhibited.2+ Based on these results, it is proposed that (a) efflux of brain Ch occurs from the extracellular compartment, which becomes depleted when ACh breakdown is inhibited;(ABSTRACT TRUNCATED AT 250 WORDS)     

ACETYLCHOLINE TRANSLOCATION IN SYNAPTIC VESICLE GHOSTS IN VITRO

Abstract— Translocation of acetylcholine (ACh) into cholinergic synaptic vesicles depleted of ACh and ATP was studied by Sephadex gel filtration. The hypo-osmotically shocked vesicles become transiently leaky, but retain ACh under iso-osmotic conditions. Intravesicular accumulation of [³H]ACh is due to a simple diffusional equilibration. Addition of 2mM-ATP and Mg²⁺ to the incubation medium is without effect. When acetylcoenzyme A (AcCoA) and choline (Ch ⁺) are used in place of preformed ACh, the intravesicular concentration of ACh does not exceed that of the newly synthesized, extravesicular ACh. However, in the absence of Na ⁺ the quantity of [³H]ACh associated with the vesicles increased, presumably due to ACh binding to ion-exchanger sites in the vesicles.     

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.     

In Vivo Effects of β-Bungarotoxin on the Acetylcholine System in Different Brain Areas of the Rat

The in vivo effects of beta-bungarotoxin (beta-BT) on the acetylcholine (ACh) system were studied in the whole cerebrum and in different brain regions. The effect of beta-BT on cerebral ACh and choline (Ch) contents was time-dependent. The results show that a single intracerebroventricular injection of 1 microgram toxin increased both the ACh and Ch contents in the cortex, hippocampus, and cerebellum, while in the striatum the ACh level was decreased. Ten nanograms of toxin injected into the lateral ventricle twice, on the first and third days, led to a reduced ACh level 2 days after the last treatment. In animals treated with the same dose three times, on the first, third, and fifth days, and sacrificed 2 days after the last injection, the choline acetyltransferase and acetylcholinesterase activities were reduced and the number of muscarinic acetylcholine receptors was decreased. A biphasic effect of the toxin was therefore demonstrated. It is suggested that in the first phase of the toxin effect the increased levels of ACh and Ch may be due to the inhibition of neuronal transmission, while in the second phase, when the elements of the ACh system are reduced, the neuronal degenerating effect of beta-BT plays a significant role.     

APPARENT IN VIVO ACETYLCHOLINE TURNOVER RATE IN WHOLE MOUSE BRAIN: EVIDENCE FOR A TWO COMPARTMENT MODEL BY TWO INDEPENDENT KINETIC ANALYSES

Abstract— Acetylcholine turnover has been determined in whole mouse brain using a newly available high specific activity [³H]choline (70 Ci/mmol). Animals were killed at various time points (0.25–10 min) after pulse adminstration of [³H]choline (Ch) by microwave irradiation of the head. Steady-state levels of ACh were determined by radioenzymatic analysis as described by G oldberg & M c C aman (1973) as modified by M c C aman & S tetzer , 1977. Ch levels were determined by a modification of the method of M c C aman & S tetzer (1977). Radiolabelled metabolites of [³H]Ch were separated by selective extraction of [³H]Ch and [³H]ACh inio tetraphenylboron in 3-heptanone (C arroll et al. , 1977) coupled with an enzymatic separation of [³H]Ch from [³H]ACh. A precursor-product relationship was verified for Ch and ACh specific activities. Acetylcholine turnover rate was determined by the biosynthesis ratio method (S chuberth et al. , 1969, Method 1) and by the finite-differences method (N eff et al. , 1971, Method 2). Both methods of kinetic analysis revealed two distinct turnover rates for acetylcholine. In the first phase (0.25–1.5 min post-[³H]Ch), the ACh turnover rate averaged 22nmol/g/min (both methods). During the second phase, (2–10 min) acetylcholine turnover rates were significantly ( P < 0.05 and P < 0.01) lower; i.e. 7nmol/g/min (Method 1) and 5.9 nmol/g/min (Method 2). The data are consistent with a 2-compartment model for ACh turnover in whole mouse brain. Additionally, the method described for the separation of radiolabelled metabolites of [³H]Ch allows an accurate determination of ACh turnover in as little as 2 mg of tissue.     

An enzymatic method for measuring picomole quantities of acetylcholine and choline in CNS tissue

A rapid and sensitive enzymatic assay for measuring picomole quantities of both acetylcholine (ACh) and choline (Ch) in tissue extracts has been developed. After ACh and Ch were extracted into 15% 1 n formic acid/85% acetone by the procedure of Toru and Aprison, lipids were removed by a heptane-chloroform extraction. All quaternary ammonium compounds were isolated by precipitation with periodide. After the precipitate (including ACh and Ch) was dissolved in a known volume of water, aliquots were taken for both assays. In the ACh assay, endogenous Ch was removed after conversion to choline phosphate by choline kinase, whereas ACh was subsequently hydrolyzed by base. In the presence of [¹⁴C]acetyl-CoA and choline acetyltransferase, the choline moiety was converted into [¹⁴C]ACh. The labeled ACh was extracted into sodium tetraphenylboron/butenenitrile and then counted in a scintillation counter. In the Ch assay, the first enzyme reaction step is omitted and only the second is used. The lower limit of sensitivity in both assays is 20 pmoles. Once the tissue has been carried through the extraction step, over eighty determinations can be made in one day. In vivo levels of ACh and Ch in the cerebrum of rats are reported for totally frozen rats and for rats sacrificed by the near-freezing procedure of Takahashi and Aprison. Mean ACh values in the two groups statistically were the same (26.5 ± 2.2 and 25.3 ± 1.7 nmoles/g, respectively) whereas the mean Ch values were significantly different (25.7 ± 0.9 and 64.0 ± 3.6 nmoles/g, respectively). The difference in the Ch levels as well as the importance of specifying the conditions that effect the measurement of ACh and Ch are discussed.     

Turnover Rate of Brain Acetylcholine Using HPLC Separation of the Transmitter

A simple, reliable method was developed for measuring brain acetylcholine (ACh) turnover using HPLC methodology. Mice were injected intravenously with [3H]choline ([3H]Ch), and the turnover rate of ACh was calculated from the formation of [3H]ACh. Ch and ACh were separated from phosphorylcholine and from other radioactive compounds using tetraphenylboron extraction and counterion/reverse-phase chromatography. Endogenous Ch and ACh were quantified electrochemically through hydrogen peroxide production in a postcolumn reactor containing covalently bonded ACh esterase and Ch oxidase. Labeled Ch and ACh were quantified in the same sample by collecting the chromatographic fractions for radioactive content determinations. The method is rapid, well adapted to large series, and highly reproducible, with recoveries of 72.1% for Ch and 79.3% for ACh. The turnover value in mouse cerebral hemispheres was 16.02 nmol g-1 min-1 and decreased to 9.94 nmol g-1 min-1 in mice treated with oxotremorine.     

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.     

Distinct Muscarinic Receptor Subtypes Differentially Modulate Acetylcholine Release from Corticocerebral Synaptosomes

The effect of McN-A-343 and oxotremorine on acetylcholine (ACh) release and choline (Ch) transport was studied in corticocerebral synaptosomes of the guinea pig. The synaptosomes were preloaded with [3H]Ch after treatment with the irreversible cholinesterase inhibitor, diisopropyl fluorophosphate, and then tested for their ability to release isotope-labeled ACh and Ch in the presence and absence of these agents. The kinetics of release were determined at the resting state (basal release) and in the presence of 50 mM K+. Under either condition, McN-A-343 enhanced the release of isotope-labeled ACh, whereas oxotremorine inhibited the K(+)-evoked release but had no effect on the basal release. The enhancing effect of McN-A-343 on basal ACh release was fully blocked by the selective M1 muscarinic antagonist, pirenzepine (100 nM). In contrast to its enhancing effect on ACh release, McN-A-343 potently inhibited Ch efflux as well as Ch influx. These effects were not blocked by atropine, a nonselective muscarinic antagonist. Oxotremorine had no effect on Ch transport. Binding studies showed that McN-A-343 was 3.6-fold more potent in displacing radiolabeled quinuclidinyl benzilate from cerebral cortex muscarinic receptors (mostly M1 subtype) than from cerebellar receptors (mostly M2 subtype), whereas oxotremorine was 2.6-fold more potent in the cerebellum. The displacements of radio-labeled pirenzepine and cis-dioxolane confirmed the M1 subtype preference of McN-A-343 and the M2 subtype preference of oxotremorine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acetylcholine release and choline uptake by cuttlefish (Sepia officinalis) optic lobe synaptosomes

Acetylcholine (ACh), which is synthesized from choline (Ch), is believed to hold a central place in signaling mechanisms within the central nervous system (CNS) of cuttlefish (Sepia officinalis) and other coleoid cephalopods. Although the main elements required for cholinergic function have been identified in cephalopods, the transmembrane translocation events promoting the release of ACh and the uptake of Ch remain largely unsolved. The ACh release and Ch uptake were quantitatively studied through the use of in vitro chemiluminescence and isotopic methods on a subcellular fraction enriched in synaptic nerve endings (synaptosomes) isolated from cuttlefish optic lobe. The ACh release evoked by K+ depolarization was found to be very high (0.04 pmol ACh.s(-1).mg(-1) protein). In response to stimulation by veratridine, a secretagogue (a substance that induces secretion) that targets voltage-gated Na+ channels, the release rate and the total amount of ACh released were significantly lower, by 10-fold, than the response induced by KCl. The high-affinity uptake of choline was also very high (31 pmol Ch.min(-1).mg(-1) protein). The observed ACh release and Ch uptake patterns are in good agreement with published data on preparations characterized by high levels of ACh metabolism, adding further evidence that ACh acts as a neurotransmitter in cuttlefish optic lobe.     

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.     

Multienzyme microbiosensor based on electropolymerized o-phenylenediamine for simultaneous in vitro determination of acetylcholine and choline

The electrochemical biosensors based on poly(o-phenylenediamine) (PoPD) and acetylcholinesterase (AChE) and choline oxidase (ChO) enzymes were fabricated on carbon fibre (CF) substrate. The electropolymerized PoPD was used to reduce the interfering substances. The electrode assembly was completed by depositing functionalized carbon nano tubes (FCNTs) and Nafion (Naf). Amperometric detection of acetylcholine (ACh) and choline (Ch) were realized at an applied potential of +750 mV vs Ag/AgCl (saturated KCl). At pH 7.4, the final assembly, Naf-FCNTs/AChE-ChO((10:1))/PoPD/CF(Elip), was observed to have high sensitivity towards Ch (6.3±0.3 μA mM(-1)) and ACh (5.8±0.3 μA mM(-1)), linear range for Ch (K(M)=0.52±0.03 mM) and ACh (K(M)=0.59±0.07 mM), and for Ch the highest ascorbic acid blocking capacity (97.2±2 1mM AA). It had a response time of <5s and with 0.045 μM limit of detection. Studies on different ratio (ACh/Ch) revealed that 10:1, gave best overall response.     

Electrosynthesized poly(pyrrole)/poly(2-naphthol) bilayer membrane as an effective anti-interference layer for simultaneous determination of acethylcholine and choline by a dual electrode amperometric biosensor

Several neural diseases appear related to the neurotransmitter acethylcholine (ACh) and its metabolite choline (Ch) brain levels so that their simultaneous determination is essential. A cross-talk and interference free dual electrode amperometric biosensor for the simultaneous determination of both analytes has been developed. Acetylcholinesterase (AChE) and choline oxidase (ChO) were immobilized by glutaraldehyde co-crosslinking with bovine serum albumin. A very efficient rejection of electroactive interferents has been achieved by a novel electrosynthesized polymeric bilayer membrane composed by overoxidised poly(pyrrole) and poly(2-naphthol) films. Sensitivities towards several electroactive interferents ranged from ca. 0.04% (e.g. ascorbate) to ca. 0.3% (e.g. dopamine) of those relevant to ACh and Ch (11 and 15 microA/microM, respectively). Detection limits (at S/N=3) in flow injection analysis were ca. 100 nM for both ACh and Ch at the ChO-AChE electrode and ca. 40 nM for Ch at the ChO sensor. Biosensor performances appear more than adequate for brain tissue homogenates and cerebrospinal fluids analysis where average levels in the low micromolar range are typically found.     

Endogenous acetylcholine release and labelled acetylcholine formation from [3H]choline in the myenteric plexus of the guinea-pig ileum.

The spontaneous release of acetylcholine (ACh) from the guinea-pig myenteric plexus - longitudinal muscle preparation superfused at a constant rate in the presence of physostigmine was 10 nmol-g-1-h-1. This release was decreased to one-third by tetradotoxin or by MnCl2 and increased 2.5 times by 0.1 Hz and 20 times by 16 Hz stimulation. The formation of [3H]ACh from [3H]choline increased from 3 to 33 nmol-g(-1)-h(-1) when the concentration of [3H]choline was increased from 1 muM to 50 muM. The rate of [3H]ACh formation was not affected by tetrodotoxin, MnCl2, or physostigmine in the absence of stimulation. It was increased by 50% by 0.1 Hz and by 100% by 16 Hz stimulation during the first 9 min of exposure to [3H]choline but not subsequently. The myenteric plexus - longitudinal muscle preparation contains 200 nmol/g choline. Results suggest that the apparent small [3H]ACh formation from low concentrations of [3H]choline is due to the dilution of [3H]choline by endogenous choline. The major part of [3H]ACh formation appears to be due to the intracellular turnover of ACh while the evoked release of [3H]ACh appears to originate from a small pool.     

High-performance liquid chromatography followed by peroxyoxalate chemiluminescence detection of acetylcholine and choline utilizing immobilized enzymes

A sensitive and selective method for the simultaneous determination of acetylcholine (ACh) and choline (Ch) is reported. ACh and Ch were separated on a reversed-phase column, passed through an immobilized enzymes (acetylcholine esterase and choline oxidase) column, and converted to hydrogen peroxide. The generated hydrogen peroxide was detected by the peroxyoxalate chemiluminescence reaction. The linear determination ranges were from 10 pmol to 10 nmol. The detection limit for both cholines was 1 pmol.     

An enzyme-reactor for electrochemical monitoring of choline and acetylcholine: applications in high-performance liquid chromatography, brain tissue, microdialysis and cerebrospinal fluid.

A sandwich-type enzyme reactor in which the enzymes are physically immobilized in a minimal dead space between two cellulose membranes, resulting in improved sensitivity, was developed for the electro-chemical detection of choline (Ch) and acetylcholine (ACh). The reactor contains the enzymes choline oxidase with or without acetylcholine esterase, for the detection of ACh and Ch, respectively. For the HPLC analysis of Ch and ACh the detection system was coupled post column. Levels of Ch and ACh of rat striatum tissue and human cerebrospinal fluid were found to be similar to those determined with published methods. Because of low back pressure--a further advantage of the reactor--the detection system could also be directly coupled to the outlet of a microdialysis device, allowing the on-line real-time measurement of extracellular brain Ch. The versatility of the enzyme reactor for the monitoring of analytes in HPLC eluates, flow injection analysis, with or without prepurification, is emphasized. The usefulness of the reactor-detector system in biomedical applications is illustrated by the measurement of increases of rat striatal extracellular Ch following cardiac arrest.