CHOLINE ESTERASE AND THE THEORY OF CHEMICAL MEDIATION OF NERVE IMPULSES

The maximum choline esterase activity of the superior cervical ganglion of the cat was measured and found to be, on the average, equivalent to the splitting of 0.10γ of acetyl choline chloride per second per milligram of fresh tissue at a pH of 7.4 and 38°. The least possible time required for destruction of the ester liberated by one nerve impulse was calculated to be 0.015σ. The dissociation constant of the reaction between the enzyme and acetyl choline chloride was determined, and a value of 0.001 was obtained. From the value of the dissociation constant, the time for hydrolysis at the minimum rate was calculated to be about 8 seconds. It was shown that a localization of enzyme and substrate within the ganglion cell would have to exist in order that enzymatic destruction of acetyl choline liberated by nerve impulses occur within the span of the refractory period.     

鸭血清胆碱酯酶的纯化及性质研究

首次采用新技术双水相萃取方法作为鸭血清胆碱酯酶(EC.3.1.1.8 CHE) 纯化的第一步,后经 DEAE-Sephadex A50,sephadex G200 柱层析,获得电泳纯鸭血清胆碱酯酶,提纯倍数1018倍,酶活力回收43.4%,比活274.9U/mg。鸭血清胆碱酯酶性质研究表明:此酶是糖蛋白和酸性蛋白水解酶,等电点 4.2 左右,最适 pH7.5 左右;对底物碘化硫代丁酰胆碱的 K_m=9.8×10^-5mol/L;SDS-PAGE 电泳和聚丙烯酰胺梯度电泳表明,鸭血清胆碱酯酶以相同亚基组成的不同聚合体形式存在,亚基分子量 78000,具有完整的酶活性.不同聚合体带电状态相同.     

THE FORMATION OF CHOLINE AND OF ACETYLCHOLTNE BY BRAIN IN VITRO

Abstract— Free choline and acetylcholine (ACh) in mouse or rat brain were assayed biologically. The subcellular distribution of ACh in brain slices that had been incubated in the presence of eserine was compared to that in control brain; during incubation, the ACh outside nerve endings increased four-fold, the ACh released from synaptosomes by osmotic shock doubled but the ACh bound firmly within nerve endings did not increase. The two nerve ending stores of ACh were labelled to similar specific radioactivities when slices were incubated with [³H]choline, but the specific radioactivity of the ACh formed was much lower than that of the added choline. Tissue incubated in the presence of eserine released choline and ACh into the medium and the tissue levels of both substances increased. Brain tissue exposed to Na⁺-free medium lost 84 per cent of its ACh and 66 per cent of its free choline; the amounts of both substances returned towards control values during subsequent incubation in a normal-Na⁺ medium (choline-free). Both the ACh outside nerve endings and the ACh associated with synaptosomes were depleted when tissue was incubated in Na⁺-free medium.     

ACETYLCHOLINE,CHOLINE AND CHOLINE ACETYLTRANSFERASE ACTIVITY IN THE DEVELOPING BRAIN OF NORMAL AND HYPOTHYROID RATS1

Abstract— Acetylcholine, choline and choline acetyltransferase activity were measured in the whole brains of normal and hypothyroid rats during development. At 1 day postpartum, brain acetylcholine was 73 per cent of adult levels. Propylthiouracil-induced hypothyroidism up to age 20 days did not alter brain acetylcholine concentrations, but at 30 days resulted in significantly decreased levels. At day 1, brain choline was 20 per cent higher than adult levels and decreased between days 8 and 10. In hypothyroid rats this phenomenon did not occur until days 15–20. At day 1 postnatally, choline acetyltransferase activity was only 7 per cent of adult levels, then between days 5 and 20 rose to 77 per cent of adult levels. Beginning at day 8, hypothyroidism resulted in significantly decreased enzyme levels. This effect could be reversed at day 17 by concurrent tri-iodothyronine substitution therapy. In hypothyroid rats, maximum brain choline acetyltransferase activity was 30 per cent less than normal adult levels.     

THE EFFECT OF THIAMINE DEFICIENCY ON THE ACETYLCOENZYMEA AND ACETYLCHOLINE LEVELS IN THE RAT BRAIN

Abstract— It is shown that transketolase activities in red blood cells and whole brain of normal and thiamine-deficient rats correlate well with heart frequencies.
The effect of thiamine depletion on the levels of acetylcoenzyme A (acetyl-CoA) and acetylcholine (ACh), and on the activities of pyruvate dehydrogenase, choline acetyl-transferase and acetylcholine esterase was studied in whole brains of thiamine-deficient, thiamine-supplemented ad libitum and pair-fed rats. The concentrations of acetyl-CoA and ACh decreased in thiamine-deficient brains by 42 and 35 per cent, respectively.
Total pyruvate dehydrogenase activity did not change during vitamin B₁ deficiency. The 'resolved' enzyme, reconstituted with thiamine diphosphate, had an association constant of 5.4 × 10⁻⁶ m . Choline acetyltransferase and acetylcholine esterase activities remained unchanged in thiamine deficiency.
Possible mechanisms which could explain the reduced Ach levels in vitamin B₁ deficiency are discussed.     

THE METABOLISM OF PALMITIC ACID IN THE PHOSPHOLIPIDS, NEUTRAL GLYCERIDES AND GALACTOLIPIDS OF MOUSE BRAIN

Abstract— Following intracerebral injection, [¹⁴C]palmitic acid was rapidly incorporated into a variety of brain lipids. After 12 hr, 78 per cent of the lipid radioactivity was in phospholipids, 15 per cent was in triacylglycerols, 1 per cent each was in free fatty acids and galactolipids, and the remainder was in other neutral glycerides. Over 65 per cent of the phospholipid radioactivity was found in the choline phosphoglycerides but this proportion decreased substantially with time. At later times, increasing portions of the radioactivity were present in the monounsaturated acyl groups and the alkenyl groups but no radioactivity was detected in cholesterol or polyunsaturated acyl groups. These results indicate that most of the extensive recycling of radioactivity took place without oxidative degradation of the palmitoyl groups. The relative rates of incorporation of radioactivity were compared at 12 hr after injection. The specific radioactivities of the serine, ethanolamine, and choline phosphoglycerides had ratios of 6:3:2 based on the palmitoyl group content and 1:2:4 based on their phosphorus content. The specific radioactivities of galactolipids with O -acyl groups were higher than the specific radioactivitiesof cerebrosides or cerebroside sulphates. A new solvent mixture for thin-layer chromatography of brain galactolipids was described (chloroform-acetone-methanol-water, 60:20:20:1, by vol.).     

ON THE ASSOCIATION OF NON-SPECIFIC ESTERASE ACTIVITY WITH CENTRAL NERVE MYELIN PREPARATIONS

Abstract— Isolated bovine central nerve myelin sheath preparations showed non-specific esterase activity towards naphthyl ester substrates of increasing chain length from acetate to palmitate. Short chain esters were hydrolysed much faster than long chain substrates by myelin, the specific activity for the hydrolysis of β-naphthyl acetate being the highest. Micro-somal fractions from brain white matter were much higher in esterase activity to all naphthyl ester substrates. NADPH-cytochrome c reductase activity was absent from isolated myelin samples. Distilled water and salt and buffer solutions of different ionic strengths and pH were ineffective in releasing non-specific esterase activity from myelin although tri-potassium citrate caused marked inhibition of the membrane-bound esterase activity. The detergent Triton X-100 released esterase activity from the myelin preparations but at a concentration of 0.1 per cent was also inhibitory.     

A COMPARISON OF THE NEURAL REGULATION OF TYROSINE HYDROXYLASE ACTIVITY IN SYMPATHETIc GANGLIA OF ADULT MICE AND RATS

Surgical decentralization of the superior cervical ganglion (SCG) in rats and mice led to a fall in ganglionic tyrosine hydroxylase (T-OH) activity, and a loss of more than 90 per cent of the preganglionic neurone marker, choline acetyl transferase. T-OH activity was reduced by more than 50 per cent in mice SCG ten days after surgery, but fell by only 25 per cent in rat SCG after 21 days. The surgical procedure did not cause obvious histo-logical damage or loss of SCG cells in either species. Both T-OH and choline acetyl transferase activities in rat and mouse SCG recovered to normal three months after surgery. Reserpine treatment was more effective in rats in causing increased ganglionic T-OH activity than in mice. Neither decentralization nor reserpine treatment caused any changes in DOPA-decarboxylase or monoamine oxidase activities in rat SCG. These results demonstrate that T-OH activity in SCG is subject to trans-synaptic regulation in both rats and mice; this regulation does not apply to DOPA-decarboxylase or monoamine oxidase. Differences in basal sympathetic tone may explain the different results obtained in mice and rats.     

LABELLING OF ACETYLCHOLINE IN THE BRAIN OF MICE FED ON A DIET CONTAINING DEUTERIUM LABELLED CHOLINE: STUDIES UTILIZING GAS CHROMATOGRAPHY—MASS SPECTROMETRY

—A method to achieve labelling of the acetylcholine stores of the brain under ideal physiological conditions is described. To this end, mice fed on a choline free diet were supplied with deuterium labelled choline in the drinking water. Labelled and unlabelled choline in plasma and in the brain as well as labelled and unlabelled acetyicholine in the brain were measured by a gas chromatographic-mass spectrometric method. It was found that after 1–25 days on the deuterium choline diet, substantial amounts of the plasma choline and brain acetylcholine were displaced by deuterium choline and deuterium acetylcholine, respectively. Already on the first day, the mole ratio of deuterium choline/total choline in plasma was 0·22, and it approached a maximum of 0·57 on the 14th day. The mole ratios of deuterium acetylcholine/total acetylcholine in the brain were slightly but significantly lower than those of deuterium choline/total choline in plasma 1–14 days, but asymptotically approached the mole ratios of deuterium Ch/total Ch in plasma by 25 days. Intact brains submitted to incubation at room temperature for 10 min increased their total choline content by about 500 per cent. Concurrently, in brains from animals kept on a deuterium choline diet for 1–2 days, the level of deuterium choline rose only by 50 per cent after incubation. Deuterium choline levels increased, however, by 200–300 per cent in the brains from animals kept on the deuterium diet for longer time periods. On the basis of these data it is suggested that: (a) choline in plasma is partly supplied from the food and partly from endogenous sources; (b) plasma choline rapidly equilibrates (less than one day) with a pool of Ch in the brain which is responsible for biosynthesis of acetylcholine; (c) the size of this choline pool is in the order of 34–40 nmol/g.     

ASPECTS OF ACETYLCHOLINE METABOLISM IN THE ELECTRIC ORGAN OF TORPEDO MARMORATA

Abstract— —The synthesis of acetylcholine and its compartmentation were studied in the electric organ of Torpedo marmorata. When electric organ was homogenized in iso-osmotic NaCl-sucrose some 55 per cent of its acetylcholine content was lost unless very potent cholinesterase inhibitors were present. Slices of electric organ incubated in a suitable medium were found to synthesize radioactive-labelled acetylcholine from [ N-Me-³ H] choline. The specific activity of the labelled acetylcholine was higher in the trichloracetic acid extract of the organ slices than in an NaCl-sucrose homogenate. Acetylcholine-containing vesicles isolated from the NaCl-sucrose homogenate contained labelled acetylcholine with about the same specific activity as the parent homogenate. There was thus a fraction of acetylcholine in the incubated tissue of higher specific radioactivity that was lost when the tissue was homogenized. The acetylcholine-containing vesicles lose their acetylcholine when submitted to gel filtration under hypo-osmotic conditions. On standing at 5°C there were only small losses of acetylcholine from the vesicles but at 20°C the losses were substantial. Vesicles containing labelled acetylcholine were studied. On gel filtration under iso-osmotic conditions there was a considerable loss of labelled acetylcholine without a concomitant loss of bio-assayable acetylcholine. The pools of radioactive and bio-assayable acetylcholine are therefore not homogeneous in the vesicles as isolated.     

GAS CHROMATOGRAPHIC ESTIMATION OF ACETYLCHOLINE IN THE RABBIT HEART USING A NITROGEN SELECTIVE DETECTOR

The distribution of ACh in the rabbit heart was investigated by a modified gas chromatographic estimation method. ACh was extracted with perchloric acid, precipitated as reineckate and demethylated with sodium benzenethiolate. The tertiary amines derived from ACh and other choline esters were concentrated by a microdistillation procedure. Gas chromatography was performed using a nitrogen selective detector. In the range of concentrations between 0.4 and 2.5 nmol ACh per tissue sample the coefficient of variation was 5.2 per cent. The recovery of ACh added to heart extracts was 101 per cent. Evidence for the identity of the choline ester isolated from rabbit hearts and authentic ACh was obtained by equal retention times and by correspondence of the ratio N/C of the respective tertiary amines. Parallel measurements using gas chromatography and bioassay on the rat blood pressure yielded closely corresponding values of ACh levels in the rabbit heart. The concentration of ACh was much higher in the atria than in the ventricles. In both atria, and ventricles the ACh concentration was higher in the right than in the left part of the rabbit heart. Endogenous propionylcholine or butyrylcholine were not detected.     

TRANSPORT, TURNOVER AND DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE AND ACETYLCHOLIN-ESTERASE IN THE VAGUS AND HYPOGLOSSAL NERVES OF THE RABBIT

Abstract— The transport, distribution and turnover of choline O -acetyltransferase (ChAc, EC 2.3.1.6) and acetylcholinesterase (AChE, EC 3.1.1.7) in the vagus and hypoglossal nerves were studied in adult rabbits. The enzymes accumulated proximally and distally to single and double ligatures on both nerves and thus indicated both a proximo-distal and retrograde flow of the enzymes. Double ligature experiments indicated that only 5–20 per cent of the enzymes were mobile in the axon. The rate of accumulation of both enzymes above a single ligature corresponded to the slow rate of axonal flow provided that all the enzymes were mobile, but to an intermediate or fast flow if only a small part of the enzymes was transported. The distribution of ChAc along the hypoglossal neurons was studied and only 2 per cent of ChAc was confined to cell bodies, 42 per cent was localized to the main hypoglossal nerve trunks and 56 per cent to the preterminal axons and axon terminals in the tongue. The ratio of AChE to ChAc was about 3 in the hypoglossal nerve and 32 in the vagus nerve.
Transection of the hypoglossal nerve was followed by a decrease in the activity of ChAc in the hypoglossal nucleus and nerve and in the axons and their terminals in the tongue. The activity of AChE decreased in the hypoglossal nucleus and nerve but not in the tongue. The half-life of ChAc in preterminal axons and terminals of the hypoglossal nerve was estimated to be 16-21 days from the results obtained on transport, axotomy and distribution of the enzyme. Intracisternal injection of colchicine inhibited the cellulifugal transport of both enzymes and led to an increase in enzyme activity in the hypoglossal nucleus.     

THE ASSOCIATION OF ACETYLCHOLINESTERASE AND MEMBRANE IN SUBCELLULAR FRACTIONS OF THE ELECTRIC TISSUE OF ELECTROPHORUS

Subcellular fractions of the electric tissue of the main organ of the eel Electrophorus electricus were prepared in sucrose media by differential centrifugation and differential discontinuous gradient centrifugation. The distributions of acetylcholinesterase, cytochrome oxidase, DNA, and protein were determined. The appearance of the fractions was determined by phase contrast microscopy and by electron microscopy. A fraction prepared by differectial centrifugation at 30,000 g for 20 minutes in 0.89 M sucrose contained 63 per cent of the total acetylcholinesterase activity at 4 times the specific activity of that of the tissue homogenate. A subfraction prepared by centrifugation in a discontinuous density gradient showed a peak of total and relative specific acetylcholinesterase activity of 35 per cent and 1.9, respectively. The average over-all purification was 7 times. The acetylcholinesterase peak was below the cytochrome oxidase peak and above the DNA peak in the density gradient. The presence of acetylcholinesterase in the fractions was correlated with the presence of large fragments of the cell membrane; however, the presence of other tissue components was noted. The acetylcholinesterase associated with membrane was found to be activated by incubation with sodium deoxycholate. The possible use of the peak fraction containing membranes rich in acetylcholinesterase for the investigation of other components of the acetylcholine system and of other properties of the membrane is discussed.     

THE REGIONAL AND SUBCELLULAR DISTRIBUTION OF CATECHOL-O-METHYL TRANSFERASE IN THE RAT BRAIN

Catechol-O-methyl transferase (COMT) activities determined in different regions of rat brain showed small variations. Highest activities were found in the hypothalamus and corpora quadrigemina, and lowest activities in the hippocampus and corpus striatum. The regional distribution of COMT was thus at variance with the distribution of DOPA decar- boxylase in this study and with the distribution of catecholamines and tyrosine hydroxylase reported in the literature. Determinations of the subcellular distribution of COMT in rat forebrain showed that 50 per cent of the activity was recovered in the high speed supernatant fluid and about 33 per cent in the crude mitochondrial fraction. Further separation of the latter by discontinuous sucrose gradients showed that the particulate COMT was found in the synaptosomal fraction in an occluded form. Full enzyme activity was only obtained after treatment with a detergent or after resuspension in water. After hypo-osmotic rupture of the crude mitochondrial fraction, COMT was recovered in the cytoplasmic fraction. The subcellular distribution of COMT was very similar to the ones of lactate dehydrogenase and DOPA decarboxylase. The proportions of soluble COMT obtained from homogenates of various regions of the brain differed from that of choline acetyl transferase and DOPA decarboxylase but were similar to that of lactate dehydrogenase. In conclusion, COMT is a cytoplasmic enzyme almost evenly distributed in the CNS. Its distribution does not resemble the distributions of the catecholamines or of the enzymes participating in the synthesis of catecholamines.     

UPTAKE OF [3H-METHYL]CHOLINE BY MICROSOMAL, SYNAPTOSOMAL, MITOCHONDRIAL AND SYNAPTIC VESICLE FRACTIONS OF RAT BRAIN

Abstract— Microsomal, mitochondrial, synaptosomal and synaptic vesicle fractions of rat brain took up [³H-methyl]choline by a similar carrier-mediated transport system. The apparent K_m for the uptake of [³H-methyl]choline in these subcellular fractions was about 5 × 10^?5 M. Choline uptake was also observed in microsomal fractions prepared from liver and skeletal muscle. Virtually identical kinetic properties for [³H-methyl]choline transport were found in the synaptosomal fractions prepared from the whole brain, cerebellum or basal ganglia. Countertransport of [³H-methyl]choline from the synaptosomal fraction was demonstrated against a concentration gradient. HC-3 was a competitive inhibitor of the uptake of [³H-methyl]choline in brain microsomal, synaptosomal and mitochondria] fractions with respective values for K_i of 4.0, 2.1 and 2.3 × 10^?5 M. HC-15 was a competitive inhibitor of the transport of [³H-methyl]choline in the synaptosomal fraction, with a K_i of 1.7 × 10^?4 M. Upon entry into the microsomal fraction, 74 per cent of the radioactivity could be recovered as unaltered choline, 10 per cent as phosphorylcholine, 1.5 per cent as acetylcholine and 2.5 per cent as phospholipid. Choline acetyltransferase (EC 2.3.1.6) was assayed with [¹⁴C]acetylCoA in synaptosomal fractions prepared from basal ganglia and cerebellum, and in the 31,000 g supernatant fraction of a rat brain homogenate. Enzyme activity was 11-fold greater in the synaptosomal fraction from the basal ganglia than in that from the cerebellum. HC-3 did not inhibit choline acetyltransferase and there was no evidence for acetylation of HC-3. Our findings suggest that choline uptake is a ubiquitous property of membranes in the CNS and cannot serve to distinguish cholinergic nerve endings and their synaptic vesicles.     

INACTIVATION OF PEPSIN BY IODINE AND THE ISOLATION OF DIIODO-TYROSINE FROM IODINATED PEPSIN

In the presence of iodine at pH 5.0–6.0 a solution of pepsin absorbs iodine and the specific proteolytic activity of the solution decreases. The activity is less than 1 per cent of the original activity when the number of iodine atoms per mol of pepsin is 35–40. If the pH is 4.5 or less, iodine reacts very slowly and there is a correspondingly slower loss in activity. Glycyl tyrosine reacts with iodine in a manner similar to pepsin. Experiments were performed to determine the extent to which oxidation of pepsin by iodine occurs during iodination, and if such oxidation were responsible for the loss in enzymatic activity. Although the results were not absolutely decisive, there seems to be no appreciable oxidation taking place during iodination and no relationship between the slight oxidation and loss in peptic activity. From a dialyzed preparation of completely iodinated pepsin which was inactive and contained 13.4 per cent bound iodine, 82 per cent of the iodine was obtained in a solution which analyzed as a solution of diiodo-tyrosine. Because of the presence of a material which contained no iodine and prevented quantitative crystallization, only 53 per cent of the iodine containing substance could be crystallized. This 53 per cent was, however, identified as diiodo-tyrosine. The part of the titration curve which in pepsin and most proteins represents the phenolic group of tyrosine was, in the curve for iodinated pepsin, shifted toward the acid region as expected. From these results, it appears that the loss in proteolytic activity of pepsin, when treated with iodine under the specified conditions, is due to the reaction of the iodine with the tyrosine in pepsin.     

CONTROL OF ACETYLCHOLINE SYNTHESIS—THE INHIBITION OF CHOLINE ACETYLTRANSFERASE BY ACETYLCHOLINE

Abstract— The inhibition of choline acetyltransferase by acetylcholine in vitro occurs at a concentration of 10 m m and increases progressively to 45 per cent at a concentration of 100 m m . The inhibition is competitive for choline and noncompetitive for acetyl-CoA. It is suggested that the synthesis of acetylcholine may be controlled by its accumulation in synaptic vesicles.     

LIPID COMPOSITION OF HUMAN, BOVINE AND SHEEP PINEAL GLANDS

Abstract— —The lipid composition of human, bovine and sheep pineal glands was determined. No characteristic species difference was found in lipid content and composition. The total lipid was 2·9–4·0 per cent of wet weight of which phospholipid comprised 58–71 per cent and cholesterol 13·9–15·8 per cent in the three species. The phospholipid composition was 45 per cent phosphatidyl choline, 22 per cent phosphatidyl ethanolamine, 14 per cent sphingomyelin, 9 per cent phosphatidyl serine, 8 per cent monophosphoinositide, and 2 per cent diphosphatidyl glycerol. The major fatty acids found were C14:0, C16:0, C18:0, C16:1, and C18:1. In contrast to other tissues, pineal sphingomyelin has a low C24:1 content. No significant amounts of polyphosphoinositides or gangliosides were detected. When its lipid composition is compared with that of a number of other tissues, pineal is found to be most similar to testes and unlike pituitary and brain.     

STUDIES ON ENZYMATIC HISTOCHEMISTRY : XXV. A MICRO METHOD FOR THE DETERMINATION OF CHOLINE ESTERASE AND THE ACTIVITY-PH RELATIONSHIP OF THIS ENZYME

The activity-pH relationship for choline esterase from horse serum, gastric mucosa of the pig, and cat brain was investigated, and an optimum was observed at pH 8.5 in each case. A micro method for the determination of choline esterase was developed capable of measuring the hydrolysis down to the order of that given by 1 x 10^–8 mol of ester.     

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.