THE DISTRIBUTION OF ACETYL-CoA IN SPECIFIC AREAS OF THE CNS OF THE RAT AS MEASURED BY A MODIFICATION OF A RADIO-ENZYMATIC ASSAY FOR ACETYLCHOLINE AND CHOLINE1

A rapid and sensitive enzymatic assay for measuring picomole quantities of acetyl-CoA, acetylcholine (ACh), and choline from the same tissue extract has been developed. After ACh and choline were extracted into 15% 1 N formic acid/85% acetone, the pellet was further extracted with 5% trichloroacetic acid (TCA) to remove the remaining acetyl-CoA. The two extraction solvents were pooled and lipids, organic solvents, and TCA were removed first by a heptane-chloroform wash followed by an ether extraction. In the acetyl-CoA assay, endogenous ACh and choline were removed by extractions with sodium tetraphenylboron in butenenitrile prior to the enzymatic reactions. The acetyl-CoA remaining in the aqueous phase was then converted enzymatically to labelled ACh in the presence of [Me-¹⁴C]choline using choline acetyltransferase. The unreacted labelled precursor was converted to choline phosphate by the enzyme choline kinase. The [¹⁴C]ACh formed from acetyl-CoA was extracted into sodium tetraphenylboron in butenenitrile and a portion of the organic phase containing the [¹⁴C]ACh was counted in a scintillation counter. Acetylcholine and choline were assayed from the same tissue extracts by a modification of the procedure by SHEA & APRISON (1973). Acetyl-CoA levels in rat whole brain when killed by the near-freezing procedure were found to be 5.50 ± 0.2 nmol/g. The content of acetyl-CoA was the same whether the rats were killed by the near-freezing method or by total freezing in liquid nitrogen. The levels of acetyl-CoA did not change with time after death when the tissue was maintained at a temperature of ?10°C. In the same tissue extracts from rat whole brain killed by the near-freezing method, the content of ACh was 20.6 ± 0.7 nmol/g and choline 58.2 ± 1.2 nmol/g. Although reproducible, the level reported for choline is high when assayed under this condition. The content of choline however after total freezing was found to be 25.2 ± 2.0 nmol/g. The sensitivity (d. p. m. of sample twice blank) is 10 pmol for the acetyl-CoA assay and 25 pmol for the ACh and choline assays. The regional distribution of these three compounds in the brain of rats as well as the content of acetyl-CoA in heart, liver and kidney are presented.     

A radiochemical method for the estimation of choline acetyltransferase

1. A radiochemical method for the estimation of choline acetyltransferase (choline acetylase) has been devised which involves the formation of labelled acetylcholine from labelled acetate. 2. [1-(14)C]Acetate and coenzyme A are pre-incubated in the presence of non-rate-limiting concentrations of acetyl-coenzyme A synthetase to give [1-(14)C]acetyl-coenzyme A, which then reacts with choline in the presence of the acetyltransferase to give [(14)C]acetylcholine. 3. Any [(14)C]-acetyl-coenzyme A remaining at the end of the reaction is destroyed by the addition of excess of hydroxylamine, and [(14)C]acetylcholine is freed from other labelled compounds by precipitation with sodium tetraphenylborate (Kalignost). 4. The washed precipitate is dissolved in acetonitrile-benzyl alcohol and estimated by scintillation counting. 5. Advantages over other methods are discussed.     

A single-vial biphasic liquid extraction assay for choline acetyltransferase using [3H]choline

A single-vial liquid extraction assay for choline acetyltransferase that uses [³H]choline as the labeled substrate has been devised. [³H]Choline is incubated with an excess of acetyl-CoA in a small reaction vial which also serves as a scintillation vial. After a suitable reaction period, unreacted [³H]choline is quickly and quantitatively converted to phosphoryl-[³H]choline by the addition of an excess of choline kinase. This treatment is followed by the addition of scintillation fluid containing sodium tetraphenylboron after which the vial is capped, shaken, and counted. A two-phase system is produced in which product [³H]acetylcholine is selectively extracted into the scintillation fluid, where it is counted. Phosphoryl-[³H]choline remains in the aqueous phase and is not counted. This assay is rapid, simple, and quite sensitive. In comparison to assays using acetyl-CoA as the labeled substrate, it is less sensitive to interference by other enzymes and thus more suitable for measuring choline acetyltransferase in crude extracts and in the initial stages of purification. Similar single-vial radiometric assays are described for choline kinase and acetyl-CoA hydrolases.     

Inhibition of choline transport into human erythrocytes by choline mustard aziridinium ion.

Acetylcholine mustard aziridinium ion inhibited the transport of [3H]choline into human erythrocytes. Treatment of the erythrocytes with 1 X 10(-4) M tetraethylpyrophosphate prevented the inhibition of [3H]choline transport by acetylcholine mustard aziridinium ion. Hydrolyzed acetylcholine mustard aziridinium ion inhibited choline transport both in the presence and absence of 1 X 10(-4) M tetraethylpyrophosphate. The product of hydrolysis was equipotent with acetylcholine mustard in its ability to inhibit choline transport; incubation of this product with sodium thiosulfate prevented inhibition of choline transport thereby indicating the presence of an aziridinium ion. The hydrolysis product is likely to be choline mustard aziridinium ion. Results on the efflux of [3H]choline from erythrocytes in the presence of the proposed choline mustard aziridinium ion showed that the mustard moiety was transported into the red cells on the choline carrier. The rate of efflux of [3H]choline produced by choline mustard aziridinium ion was 55% of that produced by the same concentration of choline. It is concluded that acetylcholinesterase (EC 3.1.1.7) of red cells rapidly hydrolyzes acetylcholine mustard aziridinium ion to acetate and choline mustard aziridinium and the latter compound can act as a potent inhibitor of choline transport. This finding would indicate that the hemicholinium-like toxicity of acetylcholine mustard in the mouse is due to the formation of choline mustard aziridinium ion.     

Modified microassay for the rapid and sensitive determination of choline acetyltransferase activity using (3H)-acetyl-CoA and Fonnum's extraction.

A modified procedure for the quantitative estimation of choline acetyltransferase activity in brain tissue based upon the formation of [3H]-ACh from [3H]-acetyl-CoA is described. The labelled ACh is isolated by a modification of Fonnum's procedure using sodium tetraphenyl borate in ketonic solution. The ChAc-activity is independent on the specific activity of the [3H]-acetyl-CoA used. The substrate blank is higher than with [14C]-labelled substrate but highly stable and reproducible. The method permits the determination of ChAc activity in less than 5 mug of brain tissue. 30-40 samples may be handled by one person per hour easily.     

Differential assay for choline acetyltransferase

A rapid and sensitive radiochemical assay for choline acetyltransferase (EC 2.3.1.6) is reported. The assay allows for the fact that during incubation of [¹⁴C]acetyl-CoA and choline with a cell homogenate, at least one product is formed besides [¹⁴C]acetylcholine, which passes an anion exchange column. In contrast to [¹⁴C]acetylcholine, this major contaminant ([¹⁴C]acetylcarnitine) is not hydrolyzed apparently by Electrophorus acetylcholinesterase. Therefore, two types of assays are performed, the one in the presence of an acetylcholinesterase inhibitor, the other in the presence of acetylcholinesterase from Electrophorus. After passing the reaction mixtures over anion exchange columns, the radioactivities of the effluents are determined. Their difference is proportional to the choline acetyltransferase activity.     

The kinetic properties of human placental choline acetyltransferase

1. Michaelis constants for human placental choline acetyltransferase were shown to be dependent on the concentration of the second substrate present. The primary plots indicate a sequential rather than a Ping Pong mechanism and are of the same type with 300mm- and 500mm-sodium chloride. 2. Similar results have been obtained with rabbit brain choline acetyltransferase. 3. Product inhibition of the forward reaction has been studied. CoA inhibits competitively with respect to acetyl-CoA and non-competitively with respect to choline. Acetylcholine inhibits competitively with respect to choline and non-competitively with respect to acetyl-CoA. No inhibition is given by acetylcholine when the enzyme is saturated with choline. 4. It is concluded that human placental choline acetyltransferase has an ordered mechanism of the Theorell-Chance type.     

Synthesis and release of acetylcholine in the rabbit kidney cortex.

Several cholinergic processes were demonstrated and partially characterized in rabbit kidney cortical minces: choline uptake, acetylcholine synthesis and calcium-dependent release. Minces took up labelled choline, acetylated it, and stored it in a pool that was not readily accessible to physostigmine-sensitive cholinesterase activity. [3H]Acetylcholine synthesis but not [3H]choline uptake was inhibited by the removal of sodium ions or incubation at 0 degrees C. The release of newly synthesized [3H]acetylcholine was increased by 300 mOsmol urea in a calcium-dependent manner, but not by potassium depolarization (300 mOsmol), vasopressin (10 microM), or bradykinin (10 microM). These results suggest that acetylcholine may be synthesized by non-neuronal rabbit kidney cortical cells and that this transmitter may be released in response to physiological levels of urea.     

Acetyl-l-carnitine as a precursor of acetylcholine

Synthesis of [³H]acetylcholine from [³H]acetyl-l-carnitine was demonstrated in vitro by coupling the enzyme systems choline acetyltransferase and carnitine acetyltransferase. Likewise, both [³H] and [¹⁴C] labeled acetylcholine were produced when [³H]acetyl-l-carnitine andd-[U-¹⁴C] glucose were incubated with synaptosomal membrane preparations from rat brain. Transfer of the acetyl moiety from acetyl-l-carnitine to acetylcholine was dependent on concentration of acetyl-l-carnitine and required the presence of coenzyme A, which is normally produced as an inhibitory product of choline acetyltransferase. These results provide further evidence for a role of mitochondrial carnitine acetyltransferase in facilitating transfer of acetyl groups across mitochondrial membranes, thus regulating the availability in the cytoplasm of acetyl-CoA, a substrate of choline acetyltransferase. They are also consistent with a possible utility of acetyl-l-carnitine in the treatment of age-related cholinergic deficits.     

Synthesis of Acetylcholine from Acetate in a Sympathetic Ganglion

Abstract: The present experiments tested whether acetate plays a role in the provision of acetyl-CoA for acetylcholine synthesis in the cat's superior cervical ganglion. Labeled acetylcholine was identified in extracts of ganglia that had been perfused for 20 min with Krebs solution containing choline (10⁻⁵ M ) and [³H], [1-⁴C], or [2-¹⁴C]acetate (10³ M ); perfusion for 60 min or with [³H]acetate (10⁻² M ) increased the labeling. The acetylcholine synthesized from acetate was available for release by a Ca²⁺-dependent mechanism during subsequent periods of preganglionic nerve stimulation. When ganglia were stimulated via their preganglionic nerves or by exposure to 46 m M K⁺, the labeling of acetylcholine from [³H]acetate was reduced when compared with resting ganglia. The reduced synthesis of acetylcholine from acetate during stimulation was not due to acetate recapture, shunting of acetate into lipid synthesis, or the transmitter release process itself. In ganglia perfused with [2-¹⁴C]glucose, the amount of labeled acetylcholine formed was clearly enhanced during stimulation. An increase in acetylcholine labeling from [³H]acetate was shown during a 15-min resting period following a 60-min period of preganglionic nerve stimulation (20 Hz). It is concluded that acetate is not the main physiological acetyl precursor for acetylcholine synthesis in this sympathetic ganglion, and that during preganglionic nerve stimulation there is enhanced delivery of acetyl-CoA to choline acetyltransferase from a source other than acetate.     

The use of choline acetyltransferase for measuring the synthesis of acteyl-coenzyme A and its release from brain mitochondria

1. A method for measuring small amounts of acetyl-CoA synthesized in subcellular fractions of the brain from pyruvate and released from particles into the incubation medium has been developed by using placental choline acetyltransferase and choline in the incubation medium to transform acetyl-CoA into acetylcholine. Acetylcholine is measured by biological assay. Optimum conditions of incubation are described. 2. With fresh mitochondria, a decrease of acetyl-CoA output into the medium is observed in the presence of ATP or ADP, and an increase in the presence of calcium chloride or 2,4-dinitrophenol. Fluorocitrate and malonate have little or no effect. 3. After the mitochondria had been treated with ether, the release of acetyl-CoA into the medium is much larger; presumably, nearly all acetyl-CoA synthesized is then released and transformed into acetylcholine under the conditions used. The release of acetyl-CoA is diminished in the presence of Krebs-cycle intermediates and ADP. 4. Of all subcellular fractions, the highest acetyl-CoA production from pyruvate is found in the crude mitochondria; rates up to 51 mumoles of acetyl-CoA/g. of original tissue/hr. are observed in ether-treated samples. 5. The activities of acetyl-CoA synthetase and ATP citrate lyase found in homogenates and nerve-ending fractions of brain tissue are considerably lower than those of pyruvate oxidase complex and choline acetyltransferase. 6. The bearing of some of the findings on the question of the source of acetyl radicals for the synthesis of acetylcholine in vivo is discussed.     

A TECHNIQUE FOR THE STUDY OF ACETYLCHOLINE TURNOVER IN MOUSE BRAIN IN VIVO

Abstract— —A method to measure the rate of acetylcholine turnover in mouse brain in vivo has been developed. It is based on the formation of labelled acetylcholine from intravenously injected labelled choline. The isotopic dilution of choline in the brain has been measured by assaying endogenous choline in the brain by an enzymatic method using tritium-labelled acetyl-CoA and purified choline acetyltransferase.
The rate of acetylcholine turnover in the brain could be calculated at 50 n-moles acetylcholine/g/min in conscious mice. In anaesthetized mice and in mice treated with oxotremorine, a decrease of acetylcholine turnover to about 10 n-moles/g/min was found.     

Compartmentation and regulation of acetylcholine synthesis at the synapse.

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

PURIFICATION AND PROPERTIES OF CHOLINE ACETYLTRANSFERASE FROM OX BRAIN STRIATE NUCLEI

Abstract—

• 1 Choline acetyltransferase was purified from ox brain striate nuclei by an extraction step at pH 5, cation-exchange chromatography, fractional precipitation with ammonium sulphate, and chromatography on Sephadex G-200. The enzyme was obtained free of deacylases and cholinesterases, at specific activities of 01-0-3 μmol acetylcholine formed per min per mg protein.
• 2 The enzyme was found to be a stable and relatively basic protein, with a molecular weight of 65,000.
• 3 In the catalysed reactions, , k₁, was about four times k₂, and the equilibrium constant was approximately 40. For the forward reaction, the Michaelis constant for each substrate was independent of the concentration of the other (choline = 0-75 mM; acetyl-CoA = 10 μM), whereas in the back reaction one substrate increased the affinity for the other (acetylcholine = 0-75-5 MM; CoA = 25-150 μM).
• 4 CoA inhibited acetylcholine synthesis by competing with acetyl-CoA (K₁, = 16 μM). Acetylcholine slightly inhibited the forward reaction (e.g. 45 per cent in 200 mM) without competing with choline or acetyl-CoA. These data indicate an ordered reaction mechanism; acetyl-CoA probably always binds before choline.

     

DISTRIBUTION OF ACETYLCHOLINE, CHOLINE, CHOLINE ACETYLTRANSFERASE AND ACETYLCHOLINESTERASE IN REGIONS AND SINGLE IDENTIFIED AXONS OF THE LOBSTER NERVOUS SYSTEM

Abstract— Acetylcholine, its precursor (choline), and the enzymes of its biosynthesis and degradation (choline acetyltransferase and acetylcholinesterase, respectively) have been studied and quantified in extracts of several regions of the nervous system of the lobster and in single, isolated axons of identified efferent excitatory, efferent inhibitory and afferent sensory neurons. The choline acetyltransferase is a soluble enzyme similar to that from other species. The predominant acetylcholine-hydrolysing enzyme is largely membrane-bound and has been characterized as a specific acetylcholinesterase. A single peak of acetylcholinesterase activity can be detected upon velocity sedimentation analysis of Triton X-100-treated extracts of all regions of the nervous system. Choline acetyltransferase distribution parallels that of sensory neural elements, and its specific activity shows nearly a 500-fold difference from the richest to the poorest neural source. Acetylcholinesterase levels span only a 23-fold range, and activity is found in all neural regions, including those free of known sensory components. A radiochemical microassay for choline and acetylcholine in the range of 20–2000 pmol is described in detail. All 3 types of axons contain comparable levels of choline ( ca. 2 pmol/μg protein), but acetylcholine is asymmetrically distributed. Efferent axons contain no detectable acetylcholine, while sensory axons from abdominal muscle receptor organs have an average of 1·9 pmol/μg protein. Choline acetyltransferase is similarly distributed; sensory axons show at least 500-fold greater activity than efferent axons. Acetylcholinesterase is nearly uniformly distributed among the three types of fibres. These results are discussed in terms of a general view of transmitter accumulation in single neurons.     

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.     

Biosynthesis of acetyl-coenzyme A in the electric organ of Torpedo marmorata in relation to acetylcholine metabolism.

Formation of acetyl-CoA through acetyl-CoA synthetase (forward reaction) and through choline acyltransferase (backward reaction) was investigated in tissue extract from the electric organ of Torpedo marmorata. When the tissue extract was submitted to gel filtration on Sephadex G-25, the formation of acetyl-CoA by acetyl-CoA synthetase appeared fully dependent on ATP and CoA and partially dependent on acetate (an endogenous supply of acetate is discussed). Choline acetyltransferase was a potent source of acetyl-CoA, only requiring acetylcholine and CoA, and was much more efficient than acetyl-CoA synthetase for concentrations of acetylcholine likely to be present in nerve endings.     

Metabolism of acetylcholine in the nervous system of Aplysia californica. III. Studies of an indentified cholinergic neuron

[3H] choline and [3H] acetyl CoA were injected into the cell body of an identified cholinergic neuron, the giant R2 of the Aplysia abdominal ganglion, and the fate and distribution of the radioactivity studied. Direct eveidence was obtained that the availabliity of choline to the enzymatic machinery limits synthesis. [3H] choline injected intrasomatically was converted to acetylcholine far more efficiently than choline taken up into the cell body from the bath. Synthesis from injected [3H] acety CoA was increased more than an order of magnitude when the cosubstrate was injected together with a saturating amount of unlabeled choline. In order to study the kinetics of acetylcholine synthesis in the living neuron, we injected [3H] choline in amounts resulting in a range of intracellular concentrations of about four orders of magnitude. The maximal velocity was 300 pmol of acetylcholine/cell/h and the Michaelis constant was 5.9 mM [3H] choline; these values agreed well with those previously reported for choline acetyltransferase assayed in extracts of Aplysia nervous tissue. [3H] acetylcholine turned over within the injected neuron with a half-life of about 9 h. The ultimate product formed was betaine. Subcellular distribution of [3H] acetylcholine was studied using differential and gradient centrifuagtion, gel filtration, and passage through cellulose acetate filters. A small portion of acetylcholine was contained in particulates the size and density expected of cholinergic vesicles.     

Metabolism of acetylcholine in the nervous system of Aplysia californica. IV. Studies of an identified cholinergic axon

[3H]Choline, injected directly into the major axon of the identified cholinergic neuron R2, was readily incorporated into [3H]acetylcholine. Its metabolic fate was similar to that of [3H]choline injected into the cell body of R2. Over the range injected, we found that the amounts of acetylcholine formed were proportional to the amounts injected; the synthetic capability was not exceeded even when 88 pmol of [3H]choline were injected into the axon. Newly synthesized acetylcholine moved within the axon with the kinetics expected of diffusion. We could not detect any selective orthograde or retrograde transport from the site of the injection. In contrast, as indicated by experiments with colchicine, 30% of the [3H]acetylcholine formed after intrasomatic injection was selectively exported from the cell body and transported along the axon. Most of the [3H]acetylcholine was recovered in the soluble fraction after both intra-axonal and intrasomatic injection of [3H]choline; only a small fraction was particulate. The significance of large amounts of soluble acetylcholine in R2 is uncertain, and some may occur physiologically. The concentrations of choline introduced by intraneuronal injection into both cell body and axon were, however, greater than those normally available to choline acetyltransferase in the cholinergic neuron; nevertheless, these large concentrations were efficiently converted into the transmitter. The synthetic capacity of the neuron supplied with injected choline may exceed the capacity of storage vesicles and of the axonal transport process.