CHOLINE ACETYLTRANSFERASE, ACETYLCHOLINESTERASE AND AROMATIC l-AMINO ACID DECARBOXYLASE IN SINGLE IDENTIFIED NERVE CELL BODIES FROM SNAIL HELIX ASPERSA

—The distribution of choline acetyltransferase, aromatic l -amino acid decarboxylase and acetylcholinesterase in the nervous system of Helix aspersa has been studied using homogenates of whole ganglia, microdissection from freeze-dried sections and dissection of single neurons from fresh tissue. Choline acetyltransferase was found in both the cell body and neuropil layers of all the Helix ganglia. The enzyme was not specifically localized to any ganglion or region of ganglion. Between 10 and 30 per cent of the isolated single cell bodies contained the enzyme. The enzymic activity corresponded to 50–200 mmol ACh/1 cell bodies/h. Choline acetyltransferase is probably a specific marker for cholinergic cells in this species. Aromatic l -amino acid decarboxylase was more selectivity localized and its distribution corresponded well with that of monoamine containing cells as visualized by the fluorescence histochemical technique. A large proportion of cell bodies were localized in the boundary between the visceral and right parietal ganglia and in the pedal ganglion. The other ganglia contained few such cells. The activity of aromatic l -amino acid decarboxylase corresponded 10–50 mmol dopamine/1 cell bodies/h. A method was developed to measure the enzyme activity towards 5-hydroxytryptophan and DOPA in single cells simultaneously. The ratio between the activity towards both substrates did not vary significantly for the different cells. The enzyme is probably a specific marker for monoamine cells, but cannot be used to differentiate between the different monoamine cells. Acetylcholinesterase was uniformly distributed in the ganglia and was probably present in all nerve cells.     

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 DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE ACTIVITY IN VERTEBRATE RETINA1

Abstract— Choline acetyltransferase (ChAc) activity was determined in retinal layers from 10 vertebrates. In all animals, the highest activity was in the inner plexiform layer, intermediate activity in the inner nuclear and ganglion cell layers, and very low activity in the photoreceptor and outer plexiform layers and optic nerve. The pattern of distribution of enzyme activity within the inner nuclear layer corresponds quantitatively to the distribution of amacrine cells within that layer. A species difference of almost 90-fold was found between the lowest and highest values for ChAc activity in inner plexiform layer. The variation in enzyme activity found among homeotherms in inner nuclear and inner plexiform layers is related to the number of amacrine cell synapses in the inner plexiform layer. But the differences in enzyme activity are generally greater than those which have been found in numbers of amacrine cell synapses between species. The data suggest that cholinergic neurons in retina are to be found predominantly among the amacrine cell types and that not all amacrine cells will be found to be cholinergic.     

CHOLINE ACETYLTRANSFERASE CONTENT IN DISCRETE REGIONS OF THE RAT BRAIN STEM

—Choline acetyltransferase (ChAc) content of 50 separate rat brain stem nuclei and cerebellum removed by microdissection was determined using a sensitive radiometric assay. The distribution of ChAc activity is uneven, with extremely high levels in the cranial motor nuclei and the nucleus salivatorius. Low ChAc concentrations were observed in the cranial sensory nuclei, the nuclei of the reticular formation, the raphe nuclei and the nuclei of the acoustic system. The lowest ChAc levels were measured in the cerebellum. Comparison of the distribution of ChAc with histochemical localization of acetylcholinesterase revealed generally good agreement, and notable exceptions are discussed.     

THE CORRELATION BETWEEN CHOLINE ACETYLTRANSFERASE AND ACETYLCHOLINESTERASE ACTIVITY IN DIFFERENT AREAS OF THE CEREBELLUM OF RAT AND GUINEA PIG

Abstract— Choline acetyltransferase (ChAc) and acetylcholinesterase (AChE) levels were measured quantitatively in samples from the archi- and paleocerebellar vermis (Larsell's Lobules IX c,d,-X, and Lobules VII-VIII, respectively) and from the cerebellar peduncles, nuclei and white matter of rat and guinea pig. Lesions to isolate archi- or paleocerebellar areas were made in some rats and the effect on enzyme levels and ultrastructure were studied. In the rat there was a striking correlation between the activity of ChAc and AChE in the different areas; thus in the archicerebellar cortex the levels of both enzymes were 3–4 times those in the paleocortex. Deafferentation caused a fall in ChAc and this practically paralleled the fall in AChE in the same area. The reduction in both enzymes was more pronounced in the archi- than in the paleocerebellar cortex. In the guinea pig the results were very different. The ChAc activity was much lower than in the rat and was equal in the archi- and paleocerebellum. The AChE activity was also uniform in the different areas but, in contrast to ChAc, was higher than in the rat.     

DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE AND GLUTAMATE DECARBOXYLASE WITHIN THE SUBSTANTIA NIGRA AND IN OTHER BRAIN REGIONS FROM CONTROL AND PARKINSONIAN PATIENTS

—The distribution of choline acetyltransferase (ChAc, EC 2.3.1.6) and l -glutamate 1-carboxylyase (glutamate decarboxylase, GAD, EC 4.1.1.15) was studied in serial frontal slices of the substantia nigra (SN) (pars compacta, PC; pars reticulata, PR; an intermediate region, IR) as well as in other brain areas from post mortem tissue of control and Parkinsonian patients. Within the SN from control brain ChAc and GAD activities showed a distinctive distribution: ChAc activity in PC was higher than in PR and IR by 427% and 253% respectively and within PC the enzyme activity in the rostral part exceeded that in the control part by 353%. The GAD activity in PC was higher by 41% than that in PR and within PC seemed to be higher in the caudal than in the rostral part. For both enzyme activities there were no significant differences between PR and IR or within these regions. In Parkinsonian brain both ChAc and GAD activities were reduced to 15-25% of controls in all 3 regions of the SN. The distinctive distribution of ChAc and GAD activity found in the SN of control brain was abolished: no difference was observed between the 3 regions. However, within PC the ChAc activity was lower in the medial than in the rostral part. Since nigral ChAc is possibly located in interneurons, the decrease in enzyme activity may be connected with the cell loss observed in the SN of Parkinsonian brain. By contrast, nigral GAD is probably contained in terminals of strio-nigral neurons and the decrease in enzyme activity in Parkinson's disease in the absence of striatal cell loss, may reflect a change in the functional state of these GABA neurons. Among various areas of control brains ChAc activity was highest in caudate nucleus and putamen while GAD was highest in SN. caudate nucleus, putamen and cerebral cortex. In Parkinsonian brain the most severe reduction in ChAc and GAD activities was found in the SN.     

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.     

华支睾吸虫神经系统的乙酰胆碱酯酶定位

应用乙酰胆碱酯酶显示的华支睾吸虫神经构造十分清晰,呈左右对称排列。它由中枢神经节、神经连合、纵行神经干、神经联系以及双极和多极神经细胞所组成。中枢神经节位于咽下方的两侧,由粗大的神经连合相连。从中枢神经节向前伸出咽、前背、前腹、前侧4对神经干;向后伸出后背、后腹、后侧3对神经干。以后腹神经干为最粗大,并从其伸出分支分布于腹吸盘、消化道、卵黄腺和生殖器官。后3对纵行神经干又由许多横向神经联系将其互相连接构成神经网。体内广泛分布双极和多极神经细胞,前者较小,数目众多,而后者略大,数目较少。     

微波辐射对小鼠脑内乙酰胆碱含量及胆碱乙酸转移酶活性的影响

用频率为2450MHz功率密度为10mW/Cm~2(WBASAR约11.4W/kg)的微波(连续波)对置于微波暗室内的昆明种雄性小鼠急性全身照射1小时后,立即按常规方法断头,取脑,制成样品,然后用放射免疫测定法测量小鼠脑内乙酰胆碱(ACh)含量及胆碱乙酰转移酶(ChAT)活性。结果表明:照射组的ACh含量为11.6±1.4pmol/mg(脑鲜重),ChAT活性为45.4±8.7pmolACh/min.mg(脑鲜重);而对照组的分别为16.0±2.1pmol/mg和61.0±13.8pmolACh/min.mg。证明微波照射后可引起动物脑内ACh水平和ChAT活性下降,提示微波辐射对中枢胆碱能系统确有不利影响。     

RELATIONSHIP BETWEEN CHOLINE AVAILABILITY AND ACETYLCHOLINE SYNTHESIS IN DISCRETE REGIONS OF RAT BRAIN

Abstract— The relationship between choline availability and the synthesis of acetylcholine in discrete brain regions was studied in animals treated with the organophosphorus cholinesterase inhibitor paraoxon. Administration of paraoxon (0.23 mg/kg) inhibited acetylcholinesterase activity by approx 90% in the striatum, hippocampus and cerebral cortex and increased acetylcholine levels to 149%, 124% and 152% of control values, respectively. Free choline levels were unaltered by paraoxon in the hippocampus and cerebral cortex, but were significantly decreased in the striatum to 74% of control. When animals were injected with choline chloride (60 mg/kg), 60 min prior to the administration of paraoxon, the paraoxon-induced choline depletion in the striatum was prevented and the paraoxon-induced acetylcholine increase was potentiated from 149% to 177% of control values. Choline pretreatment had no significant effect in either the hippocampus or cerebral cortex, brain regions that did not exhibit a decrease in free choline levels after paraoxon administration. Results indicate that choline administration, which had no significant effect on acetylcholine levels by itself, increased acetylcholine synthesis in the striatum in the presence of acetylcholinesterase inhibition. However, this effect was not apparent in either the hippocampus or the cerebral cortex at similar levels of enzyme inhibition. It appears that choline generated from the hydrolysis of acetylcholine may play a significant role in the regulation of neurotransmitter synthesis in the striatum, but not in the other brain areas studied. The evidence supports the concept that the regulatory mechanisms controlling the synthesis of acetylcholine in striatal interneurons may differ from those in other brain regions.     

TOPOGRAPHICAL AND SUBCELLULAR DISTRIBUTION OF CHOLINE ACETYLTRANSFERASE AND GLUTAMATE DECARBOXYLASE IN PIGEON OPTIC TECTUM

Abstract— The distribution of choline acetyltransferase (ChAT) and glutamate decarboxylase (GAD) in different layers of the pigeon optic tectum and in some nuclei of the optic lobe have been investigated. About 40% of GAD and 25% of ChAT were found in the superficial part of tectum, but negligible activity was found in the stratum opticum. The highest GAD activity was found in layers 3-7 (according to the nomenclature of C ajal , 1911) with a peak in layer 4. ChAT activity peaked in layers 3, 5. 8 and 10/11. Its distribution correlated well with the staining pattern of AChE, particularly in the superficial part of the tectum. The distribution of ChAT and GAD did not change significantly 4 weeks after enucleation. ChAT and GAD activities were high in the nucleus isthmi, pars parvocellularis (Ipc). The activity of GAD was also high in the nucleus intercollicularis (ICo), the other nuclei showed less activity of both enzymes.     

CHOLINE AND ACETYLCHOLINE IN RATS: EFFECT OF DIETARY CHOLINE

Abstract– The concentration of free choline in peripheral tissues (duodenum, heart, kidney, liver, stomach and plasma) of rats was found to be related to the amount of free choline in the diet. Under steady-state conditions, the concentration of free choline in plasma varied from a minimum of approx 6 nmol/ml (in rats fed a choline-deficient diet) to a maximum value not exceeding 21 nmol/ml. The concentration of plasma choline was elevated above 21 nmol/ml for a short time after parenteral administration of choline chloride or one of its precursors (CDP choline or phosphorylcholine), but was not affected by stress, endocrine manipulations, drug treatments or the time of day when rats were killed. The metabolism of intravenously administered [methyl-³H] choline was accelerated in peripheral tissues (except plasma) of choline-deficient rats, indicating that free choline is not preserved during choline deficiency by a reduction in its rate of turnover. Furthermore, the decrease in concentration of plasma choline that occurred in rats fed a choline-deficient diet was prevented by addition of deanol (dimethylaminoethanol) to the diet. These results indicate that free choline in peripheral tissues of rats is derived from both free choline in the diet, and from precursors of choline present within the diet. In contrast to the effects in peripheral tissues, the concentration of free choline in brain was not reduced by dietary deprivation of free choline; however, the increase in free choline that occurred when rats were decapitated was reduced in brains by deficiency of choline, suggesting a decrease in the concentration of esterified forms of cerebral choline. The concentration of acetylcholine was not reduced in the brain, duodenum, heart, kidney or stomach of 21-week old rats raised from birth on a choline-deficient diet, in the duodenum of rats given a choline-deficient diet for 1, 5 or 11 days, or in brains of rats deprived of free choline for 1 or 11 days. However, the rate of in vivo synthesis of ACh from [methyl-³H]choline was accelerated in cholinergic tissues that were depleted of free choline (i.e. duodenum, heart and stomach).     

CHOLINE ACETYLTRANSFERASE AND THE HIGH AFFINITY UPTAKE OF CHOLINE IN CORPUS STRIATUM OF RESERPINISED RATS1

Rats treated with reserpine show increased V_max for the high affinity uptake of choline into small slices of corpus striatum. The choline acetyltransferase activity of whole homogenates of striatum is also increased. These changes are consistent with increased cholinergic neuronal activity in the striatum and seem likely to be adaptations mediating increased rates of synthesis of acetylcholine. The maximal increases found occurred concurrently, consistent with coupling of the high affinity uptake of choline and its acetylation in cholinergic nerve terminals of the rat. That increased high affinity uptake is accompanied by increased choline acetyltransferase activity, suggests the input of choline is not the sole determinant of rates of synthesis of acetylcholine, in spite of the large Vmas for striatal choline acetyltransferase, compared with that for high affinity uptake. These results seem best explained by kinetic coupling, in the rat, of the high affinity uptake of choline with a limited pool of choline acetyltransferase preferentially localised at the nerve terminal plasma membrane.     

MEMBRANE AFFINITIES AND SUBCELLULAR DISTRIBUTION OF THE DIFFERENT MOLECULAR FORMS OF CHOLINE ACETYLTRANSFERASE FROM RAT

Choline acetyltransferase from rat brain is present in three different molecular forms with isoelectric points at pH 7·4-7.6, 7·7-7·9 and 8·3. The three forms were identified in a highly purified enzyme preparation, in a preparation of synaptosomes and in a cyto-plasmic preparation from disrupted axons and perikarya (fraction S₃). The three molecular forms differed in their affinities for synaptosome membranes and for a cation exchange resin (CM-Sephadex C-50). The positive surface charges of the different molecular forms and their affinities for membranes correlated well with their isoelectric points. The molecular form with jsoelectric point 8·3 had the largest positive surface charge and the highest membrane affinity. On isoelectric focusing of an extract from rat brain synaptosomes, the molecular form with isoelectric point 8·3 formed a complex with a negatively charged compound, presumably a protein. A method was developed to remove this compound by treatment with DEAE-Sephadex or by precipitation with vinblastine. These procedures are similar to methods known to remove the neurotubular protein. The complex formation did not occur in fraction S₃.     

REGIONAL DISTRIBUTION OF PUTRESCINE, SPERMIDINE AND SPERMINE IN RELATION TO THE DISTRIBUTION OF RNA AND DNA IN THE RAT NERVOUS SYSTEM

—Putrescine, spermidine, spermine, RNA, DNA and protein concentrations were determined in 14 parts of the rat nervous system. If the concentrations are expressed in DNA units, putrescine and spermidine concentrations change concomitantly in the different brain parts, with the exception of hypothalamus, where relatively higher putrescine than spermidine concentrations are observed. The constancy of putrescine/spermidine ratios indicates the value of putrescine concentration as an index of spermidine biosynthesis. Spermidine correlates with RNA, except in medulla, spinal cord and peripheral nerves. It is assumed that the relative excess of spermidine in these structures indicates an additional functional role. Spermine/DNA ratios are remarkably constant in the diencephalic and telencephalic regions; they are also nearly constant, but significantly lower in midbrain, medulla, spinal cord and cerebellum. This observation gives additional support for the preferential interrelation of spermidine with RNA and spermine with DNA; i.e. for different functional roles of these two narrowly related polycations.     

MULTIPLE FORMS OF CHOLINE ACETYLTRANSFERASE AND THE HIGH AFFINITY UPTAKE OF CHOLINE IN BRAIN OF DEVELOPING AND ADULT RATS

The multiple molecular forms of choline acetyltransferase (ChAT) were analysed during the postnatal development of rat brain. Changes in the sodium-dependent, high affinity uptake of [³H]choline (HAUC) and in the efficiency of conversion of labelled choline into ACh in vitro were also examined. Both mature and 7-day old brain contained three molecular forms of ChAT, with isoelectric points of pH 7.3, 7.9 and 8.3, but the immature brain appeared to contain smaller concentrations of the most basic form of the enzyme (pI = 8.3). Of the total choline uptake measured in slices of frontal cortex, adult samples exhibited a greater proportion of HAUC than 7-day samples and appeared to acetylate more efficiently the [³H]choline accumulated by high affinity uptake. This evidence suggests a basic molecular form of ChAT, appearing in rat brain during postnatal development, might be responsible for the efficient coupling of the high affinity uptake and subsequent acetylation of choline in cholinergic nerve terminals.     

THE STIMULATION OF ARGININE PHOSPHOKINASE IN LOBSTER AXONS BY GABA

GABA at physiological concentrations has been shown to stimulate the synthesis of arginine phosphate in lobster walking nerves. This effect can be observed both in intact axons and in axonal homogenates. The stimulatory activity of GABA on the synthesis of arginine phosphate appears to be on the V_max of arginine phosphokinase whereas in the reverse reaction the effect is referable to the K_m of ADP.     

CHOLINE ACETYLTRANSFERASE LEVELS IN DIENCEPHALIC NUCLEI OF THE RAT

Choline acetyltransferase levels have been measured in specific nuclei of the diencephalon. On the whole, the thalamic nuclei contain higher concentrations of this enzyme than do the hypothalamic and preoptic nuclei. Those nuclei which seem to receive the most dense cholinergic innervation contain the highest levels of choline acetyltransferase.