RATE OF ACCUMULATION OF ACETYLCHOLINE IN DISCRETE REGIONS OF THE RAT BRAIN AFTER DICHLORVOS TREATMENT

Abstract– The time course for accumulation of acetylcholine was measured in rat brain regions after treatment with 15 mg/kg, i.v., dichlorvos. With this dose of dichlorvos 84-96% of the brain cholinester-ase is inhibited within 1 min. After killing and concomitant enzyme inactivation through microwave irradiation, the acetylcholine levels were measured by pyrolysis-gas chromatography. In the brain regions studied, the striatum had the highest rate of accumulation of acetylcholine and the cerebellum had the lowest. The calculated turnover time in minutes for the regions of the brain were cerebral cortex 0.9; hippocampus 1; striatum 1.4; cerebellum 1.7; medulla-pons 2.2; midbrain 4.5; thalamus 5.6.     

Determination of 1-Methylimidazole-4-Acetic Acid in Brain Tissue from Rat and Mouse

The concentration of the histamine metabolite 1-methylimidazole-4-acetic acid was determined in brain tissue from rat and mouse with a gas chromatographic-mass spectrometric method. Mouse brain contained 1.7-3.2 nmol/g, depending on the strain. The concentration in cerebrum from Sprague-Dawley rats was 1.2 nmol/g, whereas cerebellum contained 0.24 nmol/g. The concentration of tele-methylhistamine in mouse brain was 1.4-2.2 nmol/g. The concentration of 1-methylimidazole-4-acetic acid in rat brain after death did not change significantly during 2 h at room temperature.     

鼠类对敌鼠钠盐的敏感性与耐性的初步研究及其应用

敌鼠钠盐在近几年来已逐步推广使用,并取得较好的效果。一些作者曾用敌鼠钠盐对长爪沙鼠(Meriones unguiculatus)、高原鼠兔(Ochotona curzoniae)及小白鼠等作过毒力测定和现场灭鼠(夏武平1976,何新桥等1973),但对于我国常见的广布鼠种对敌鼠钠盐的敏感性和耐性方面的研究报告,仍为少见。耐性指中毒未死,抗药性增强,是后天获得的。为了正确合理地使用这一毒鼠剂,以利灭鼠工作的顺利开展,我们于1975年夏初曾以我国各地较常见的黑线姬鼠（Apodemus agrarius）、黄胸鼠（Rattus flavipectus）和褐家鼠（Rattus norvegicus）为实验动物,对这方面问题进行初步探讨,现报告如下。     

THE CONTROL OF PYRUVATE DEHYDROGENASE IN ISOLATED BRAIN MITOCHONDRIA

Abstract— The activity and control of the pyruvate dehydrogenase complex in isolated rat brain mitochondria has been studied. The activity of this complex in mitochondria as isolated from normal fed rats was 78 ± 10nmol.min⁻¹ mg mitochondrial protein⁻¹ (n = 18) which represented 70% of the total pyruvate dehydrogenase activity. The pyruvate dehydrogenase in isolated brain mitochondria could be inactivated by incubation in the presence of ATP, oligomycin and NaF. The rate of inactivation was dependent upon the added ATP concentration but inactivation below approx 30% of the total pyruvate dehydrogenase activity could not be achieved. The inactivation of pyruvate dehydrogenase in brain mitochondria was inhibited by pre-incubation with pyruvate. Reactivation of inactivated pyruvate dehydrogenase in rat brain mitochondria was incomplete in the incubation medium unless 10mM-Mg²⁺+ 1 mM-Ca²⁺ were added; NaF, however, prevented any reactivation (Fig. 4). It is concluded that the pyruvate dehydrogenase complex in rat brain mitochondria is controlled in a manner similar to that in other tissues, and that pyruvate protection of pyruvate dehydrogenase activity may be important in maintaining brain energy metabolism.     

MEASUREMENT OF ACETYLCHOLINE TURNOVER WITH GLUCOSE USED AS PRECURSOR: EVIDENCE FOR COMPARTMENTATION OF GLUCOSE METABOLISM IN BRAIN

The turnover of acetylcholine in whole mouse brain in vivo has been determined using [U-¹⁴C]glucose as a precursor of the acetyl moiety. The standard requirements for the measurement of turnover were met: the injection did not change the concentrations of precursor or product, the amount of radioactivity in the brain was proportional to the amount injected, and the relationship between the specific activity of glucose and that of acetylcholine was typical of a precursor and a product. The value for acetylcholine turnover was 64 pmol/min per mg protein, approx 6.4 nmol/min per g brain. Treatment with amobarbital (0.16 mmol/kg) decreased the incorporation of glucose into acetylcholine by 73 × 7%, and treatment with atropine increased it by 18 × 6%. These values agree with those using choline as a precursor, supporting the validity of the values for turnover obtained with either labelled precursor. The specific activity of acetylcholine was higher than that of pyruvate at all times in mouse brain in vivo and in rat brain slices in vitro. These observations demonstrate compartmentation of glucose metabolism with respect to acetylcholine synthesis in the brain. They agree with observations by others of compartmentation of acetyl metabolism. They provide an explanation for the close linkage which has been observed between carbohydrate catabolism and acetylcholine synthesis in the CNS.     

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.     

Oxindole, a Sedative Tryptophan Metabolite, Accumulates in Blood and Brain of Rats with Acute Hepatic Failure

Abstract: Rats treated with oxindole (10–100 mg/kg i.p.), a putative tryptophan metabolite, showed decreased spontaneous locomotor activity, loss of the righting reflex, hypotension, and reversible coma. Brain oxindole levels were 0.05 ± 0.01 nmol/g in controls and increased to 8.1 ± 1.7 or 103 ± 15 nmol/g after its administration at doses of 10 or 100 mg/kg i.p., respectively. To study the role that oxindole plays in the neurological symptoms associated with acute liver failure, we measured the changes of its concentration in the brain after massive liver damage, and we investigated the possible metabolic pathways leading to its synthesis. Rats treated with either thioacetamide (0.2 and 0.4 g/kg i.p., twice) or galactosamine (1 and 2 g/kg i.p.) showed acute liver failure and a large increase in blood or brain oxindole concentrations (from 0.05 ± 0.01 nmol/g in brains of controls to 1.8 ± 0.3 nmol/g in brains of thioacetamide-treated animals). Administration of tryptophan (300–1,000 mg/kg p.o.) caused a twofold increase, whereas administration of indole (10–100 mg/kg p.o.) caused a 200-fold increase, of oxindole content in liver, blood, and brain, thus suggesting that indole formation from tryptophan is a limiting step in oxindole synthesis. Oral administration of neomycin, a broad-spectrum, locally acting antibiotic agent able to reduce intestinal flora, significantly decreased brain oxindole content. Taken together, our data show that oxindole is a neurodepressant tryptophan metabolite and suggest that it may play a significant role in the neurological symptoms associated with acute liver impairment.     

On the Use of Microwave Radiation Energy for Brain Tissue Fixation

Abstract: Focused microwave irradiation (MWR) is an increasingly accepted method of sacrifice of laboratory animals such as the mouse or rat. By fixing the brain within a fraction of a second with heat inactivation, the investigation of fast neurochemical events may be obtained. Even though the technique is widely utilized, its application is inconsistent. This report illustrates some of the requirements necessary for the proper application of MWR for the sacrifice of animals, particularly those related to the length of time MWR is applied and the efficiency with which generated MWR power is coupled to the brain tissue. Studies were performed on the mouse, using either a 2.5 KW or 6.3 KW generator with a focused, closed system waveguide at time intervals of 350 or 500 ms or 1.4 s. During each of these intervals MWR was varied so that core brain temperatures for all groups were held between 83 and 95°C. In contrast with reported studies that used full animal restraint, all animals were minimally restrained for less than 1 s before sacrifice. Tissue content of cyclic AMP, an index of neuronal activity grossly affected by subtle changes in the activity of adenylate cyclase and/or phosphodiesterases, was monitored. No differences in tissue cyclic AMP content in any of 12 brain regions were detected after MWR, either at 350 or 500 ms. A substantial increase in cyclic AMP content occurred in 8 of 12 brain regions examined following microwave irradiation for 1.4 s. On the basis of these experiments, accurate determination of cyclic AMP in rodent brain requires that the maximum time interval of MWR exposure should not exceed 500 ms.     

PHOSPHATE ACTIVATED GLUTAMINASE ACTIVITY AND GLUTAMINE UPTAKE IN PRIMARY CULTURES OF ASTROCYTES

Abstract— Uptake and release of glutamine were measured in primary cultures of astrocytes together with the activity of the phosphate activated glutaminase (EC 3.5.1.2). In contrast to previous findings of an effective, high affinity uptake of other amino acids (e.g. glutamate, GABA) no such uptake of glutamine was observed, though a saturable, concentrative uptake mechanism did exist (K _m = 3.3 ± 0.5 m m ; V _max= 50.2 ± 12.6 nmol ± min⁻¹± mg⁻¹). The phosphate activated glutaminase activity in the astrocytes (6.9 ± 0.9 nmol ± min⁻¹± mg⁻¹) was similar to the activity found in whole brain (5.4 ± 0.7 nmol ± min ^−l± mg⁻¹), which may contrast with previous findings of a higher activity of the glutamine synthetase (EC 6.3.1.2) in astrocytes than in whole brain. The observations are compatible with the hypothesis of an in vivo flow of glutamate (and GABA) from neurons to astrocytes where it is taken up and metabolized, and a compensatory flow of glutamine towards neurons and away from astrocytes although the latter cell type may be more deeply involved in glutamine metabolism than envisaged in the hypothesis.     

COMPARATIVE STUDIES ON THE DEGRADATION OF GABA and TAURINE IN THE BRAIN

Abstract— The degradation of taurine and GABA in mammalian brain was studied in vivo and in vitro. Small amounts of [³⁵S]isethionate (10–20 pmol/g brain wet weight) and [³⁵S]sulphate (about 2 pmol/g) were detected in mouse brain after intramuscular injection of [³⁵S]taurine. Taurine also produced isethionate in rat brain homogenates (about 20 nmol/h/g protein) and subcellular fractions (about 40 nmol/h/g protein in synaptosomes and about 300 nmol/h/g in mitochondria), but the reaction was not stimulated either by external electrical pulses or by the addition of various cofactors (NAD and NADP in both oxidized and reduced forms, riboflavin, glutathione. pyridoxal-5'-phosphate, ATP) to the incubation medium. [¹⁴C]GABA was readily metabolized to [¹⁴C]succinate both in vivo and in vitro. Isethionate formation activity was concentrated in the mitochondrial fraction, as was also GABA-T activity. Partially purified GABA-T from calf brain also slightly catalysed the formation of [³⁵S]isethionate (about 1.3 μmol/min/g protein) from [³⁵S]taurine. It appears that the slight formation of isethionate from taurine is coupled to GABA-T activity. The formation of isethionate from taurine is so small, that it apparently has no role in the control of the brain taurine pool.     

Cholinergic constituents in plants: Characterization and distribution of acetylcholine and choline

Acetylcholine in plants was identified by gas chromatography/mass spectrometry. Acetylcholine was found in the following species from 13 families: Betula pendula, Codiaeum variegatum, Ilex opaca, Liquidambar styraciflua, Lonicera japonica, Phaseolus aureus, Phaseolus vulgaris, Pisum sativum, Plantago rugelli, Populus grandidentata, Prunus serotina, Rhus copallina, Smilax hispida, Viburnum dilatatum , and Zea mays . Levels of acetylcholine in leaves ranged from a low of 0.14 ± 0.05 (mean ± SEM) nmol (g fresh weight)⁻¹ in I. opaca to a high of 53 ± 6.6 nmol (g fresh weight)⁻¹ in P. aureus . Acetylcholine was found in all tissues examined regardless of the organ (leaves, stems, or roots) or developmental stage (seedlings, mature plants, or seeds). For P. aureus , continuous light exposure increased acetylcholine levels of leaves, and decreased levels in stem when compared to dark controls. Levels of choline, a precursor of acetylcholine, found in leaves ranged from a low of 84 ± 7.0 nmol (g fresh weight)⁻¹ in L. styraciflua to a high of 3700 ± 200 nmol (g fresh weight)⁻¹ in P. aureus . With these findings, three out of the four components of the cholinergic system have now been identified in plants.     

Mannose-6-p and mannose-1-p in rat brain, kidney and liver.

The approximate concentrations of mannose-6-phosphate and mannose-1-phosphate in female rat brain, kidney and liver are respectively 51, 29 and 99 nmole/g (Man-6-P), and 13, 12, 15 nmol/g (Man-1-P). Intraperitoneal injection of mannose (20 nmol/kg body weight, 15, 30 or 60 min before sacrifice) raises the liver Man-6-P to 0.4 to 4.3 μmol/g and Man-1-P to 100 to 186 nmol/g.     

INTRACELLULAR AMINO ACID CONTENT OF NEURONAL, GLIAL, AND NON-NEURAL CELL CULTURES: THE RELATIONSHIP TO GLUTAMIC ACID COMPARTMENTATION

Abstract— A protocol for the accurate determination of intracellular levels of amino acids in tissue cultured cells has been developed and used in the measurement of intracellular amino acids levels in neuronal, glial, and non-neural cell lines, with the objective of establishing morphological correlates for large and small glutamic acid compartments and of examining hypotheses for the morphological basis of glutamic acid compartmentation. This survey of intracellular amino acid levels has revealed striking differences among the cell lines tested, but these differences did not correlate with cell type, i.e. neuronal vs glial, in contrast to earlier results (R ose , 1968) based on bulk separated neuronal and pial fractions from rat brain. Amino acid levels were found to be dependent upon tissue culture conditions, yet reproducible differences could be observed when growth and experimental conditions were carefully controlled. Glutamic acid levels for various cell lines ranged from 50.8 ± 14.3 to 158 ± 8.5 nmol/mg protein. Intracellular glutamine levels demonstrated even greater difference, with values ranging from 0.8 ± 0.2 to 107 ± 42.4 nmol/mg protein. Statistically significant differences in intracellular amino acid levels between cell lines were also observed for aspartic acid, praline, glycine, alanine, valine, cystathionine, isoleucine, and leucine. A number of cell lines demonstrating highly elevated elevated levels of γ-aminobutyrate and β-alanine were identified. The significance of neuronal and glial levels of glutamic acid, glutamine and γ-aminobutyrate to models for glutamic acid compartmentation is discussed.     

Hydrolysis of Inositol Trisphosphate by Purified Rat Brain Myelin

Abstract: Highly purified rat brain myelin was found to hydrolyze inositol 1,4,5-trisphosphate to inositol 1.4-bisphosphate, but subsequent hydrolysis of the latter, characteristic of whole brainstem, did not occur. Inositol 1,4,5-trisphosphate 5-phosphatase in myelin was ∼ 33% of the level in microsomes and 127% that of the cytosolic fraction from brainstem. The myelin and microsomal enzymes had similar properties, as follows: activation by saponin, requirement for Mg²⁺ and similar K_act (0.16 and 0.13 mM), K_m (8.7 ± 2.5 and 7.0 ± 1.0 μM), and pH optima (6.6-6.8). V_max values were 11.2 ± 1.0 and 26.3 ± 2.0 nmol/mg/min for myelin and microsomes, respectively. A possible role for this enzyme in phosphoinositide-mediated signal transduction within myelin and its subcompartments 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.     

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.     

Effect of antinociceptive doses of oxotremorine on mouse brain acetylcholine turnover rate

The effect of antinociceptive doses of oxotremorine on the steady-state level and turnover rate of acetylcholine (ACh) was investigated in male Swiss-Webster mice. Oxotremorine produced dose-related increases in ACh levels which attained statistical significance (p ≥ 95; Dunnett's T) with the ED₈₄ antinociceptive dose in two sacrifice methods. The increased steady-state level of ACh was temporally correlated with the peak antinociceptive effect of oxotremorine. ACh turnover rate decreased with increasing doses of oxotremorine. The ACh turnover rate decreased from 11.06 ± 1.62 nmol/g/min to 5.38 ± 0.71 nmol/g/min by decapitation method and 30.20 ± 1.8 nmol/g/min to 19.99 ± 1.6 nmol/g/min by the microwave irradiation method (Ed₈₄ oxotremorine doses). The decrease in turnover rate of ACh produced by antinociceptive doses of oxotremorine is of a lesser magnitude than that produced by tremorogenic doses (1,2).     

LYSINE METABOLISM IN THE RAT BRAIN: BLOOD—BRAIN BARRIER TRANSPORT, FORMATION OF PIPECOLIC ACID AND HUMAN HYPERPIPECOLATEMIA

Through the use of intravenous pulse injection of L-[U-¹⁴C] lysine, the blood-brain barrier transport of L-lysine was studied. The uptake of L-lysine plus metabolites in the brain remained essentially unchanged at approx 0.002–0.005 nmol/g in the low dose (3μg per kg body weight) injection, and 20–40 nmol/g in the high dose (30 mg/kg) injection throughout the time intervals of up to 60 min. The uptake of L-lysine plus metabolites in the heart, however, decreased substantially from 0.03 to 0.003 nmol/g in the low dose injection and from 320 to 62 nmol/g in the high dose injection. The plasma to heart uptake ratio only decreased slightly through the 60 min period: from 6 to 2 in either the low or high dose L-lysine injection. The plasma to brain uptake ratio, however, decreased rapidly from a high of 62 to a low of about 4 in either the low or high dose injection throughout the 60-min time course. Study of labeled L-pipecolate formation in the plasma and individual organs indicates that this compound was formed only in the brain to a significant level within 0.5 min of ¹⁴C-L-lysine intravenous pulse injection. Labeled pipecolate was recovered from heart, liver, kidney and plasma in significant quantities only at 2 min or later after pulse-injection. It is concluded that the blood-brain barrier of L-lysine in the rat is not particularly strong and that the rat brain may be primarily responsible for L-pipecolate synthesis from L-lysine. The possible etiology of human hyperpipecolatemia is also discussed in light of the current findings.     

A high-pressure liquid chromatographic method for measuring 3', 5'-cyclic AMP in brain.

A method is described for the estimation of adenosine 3′,5′-monophosphate (3′,5′-cyclic AMP) in rat brain by high-pressure liquid chromatography (HPLC). The nucleotide is purified initially by being passed through two columns, alumina and AG-1X2. The peak in HPLC was identified by a number of methods. Optimum parameters for HPLC were obtained by using 1 mm KH₂PO₄ buffer, pH 4.8, at a flow rate of 57 ml/hr at room temperature. Using this technique the concentration of 3′,5′-cyclic AMP in rat brain was found to be 2.53 ± 0.40 nmol/g (mean ± SD, n = 5).     

Identification and Distribution of Phenylacetic Acid in the Brain of the Rat

Abstract: Phenylacetic acid, the major metabolite of phenylethylamine, has been identified and quantitated in rat brain regions by capillary column high-resolution gas chromatography mass spectrometry. Its distribution is heterogeneous and correlates with that of phenylethylamine. The values obtained were (ng/g ± SEM): whole brain, 31.2 ± 2.7; caudate nucleus, 64.6 ± 6.5; hypothalamus, 60.1 ± 7.4; cerebellum, 31.3 ± 2.9; brainstem, 33.1 ± 3.3, and the "rest," 27.6 ± 3.0.