Drug induced changes in free, labile and stable acetylcholine of guinea-pig brain

Effects of single or repeated administration of a carbamate, propoxur, and an organophosphate, DDVP, on jejunal cholinergic activities and contractile responses in rats

Wistar rats were injected once or repeatedly for 10 days with dichlorvos (DDVP, 5 mg kg-1), propoxur (10 mg kg-1), oxotremorine (0.1 mg kg-1) or atropine (5 mg kg-1). Animals were killed 20 min or 24 h after single or consecutive injections, respectively, for determinations of cholinergic activities and contractile responses to acetylcholine (ACh) of the jejunum. Single treatments: while DDVP and propoxur decreased acetylcholinesterase (AChE) activity, oxotremorine and atropine did not. Although DDVP, propoxur and oxotremorine increased levels of ACh, atropine decreased them. Contractile responses to ACh were enhanced by DDVP and reduced by oxotremorine and atropine. The Bmax value of binding of [3H]quinuclidinyl benzylate (QNB) to muscarinic ACh receptors was decreased by atropine. Consecutive treatments: DDVP and oxotremorine decreased AChE activity markedly and slightly, respectively. Although DDVP and oxotremorine increased levels of ACh, propoxur decreased them. Without affecting the contractile responses, DDVP caused a reduction and propoxur and atropine caused an increase in the Bmax value for binding of [3H]QNB. Both the contractile responses and the value of Bmax for binding of [3H]-QNB were decreased by oxotremorine. In summary, propoxur and DDVP showed similar effects mainly through their anticholinesterase properties in the case of single injection, but DDVP had similar effects to those of oxotremorine and propoxur had similar effects to those of atropine in the case of repeated injection.

Acetylcarnitine, carnitine and glucose diminish the effect of muscarinic antagonist quinuclidinyl benzilate on striatal acetylcholine content

The content of acetylcholine (ACh) in the striatum, brain cortex and hippocampus of rats was lowered 20-180 min after intraperitoneal injection of the muscarinic antagonist quinuclidinyl benzilate (QNB). The depletion of ACh content in the striatum was diminished in animals treated with a single dose of acetyl-L-carnitine, L- or D,L-carnitine, or D-glucose. It is likely that QNB stimulates ACh release by blocking presynaptic muscarinic autoreceptors and that acetylcarnitine, carnitine and glucose support the resynthesis of ACh by increasing the availability of acetylcoenzyme A. They do not have the same consistent effect in the brain cortex and hippocampus; this difference may be related to the lower turnover rate of ACh and to the difference in the anatomical arrangement of cholinergic structures in these parts of the brain.

Modulation of cortical in vivo acetylcholine release by the basal nuclear complex: role of the pontomesencephalic tegmental area

Acetylcholine (ACh) release in vivo from rat cortices was determined by microdialysis either after injection of drugs into the basal nuclear complex (NBM) or after electrolytic lesion of the pontomesencephalic tegmental nucleus (PPT). Scopolamine (SCOP) (5-10 micrograms) increased and oxotremorine (10 micrograms) reduced cortical ACh release, indicating that an inhibitory mechanism operates within the area. The gamma-aminobutyric acid (GABA)ergic antagonist, picrotoxin (2.5 micrograms), by disinhibiting the cholinergic basocortical neurons, induced an increase that was not affected by SCOP. Acute lesion of the cholinergic PPT efferents to NBM raised cortical basal release. Thus, ACh released from the PPT terminals apparently modulates the function of basocortical neurons mainly through a polysynaptic link via GABAergic neurons.

Acetylcholine and choline in rat adrenals and brain cortex prisms incubated at elevated concentrations of choline in the medium

Experiments were performed with rat adrenals and brain cortex prisms incubated in vitro in order to clarify whether it is possible to increase their acetylcholine (ACh) content by adding a high concentration of choline to the medium and whether the additional ACh formed can be released by subsequent depolarization. After 60 min incubation with 0.5 mmol/l choline, the concentration of ACh in the adrenals was increased by 116% (compared to the incubation without added choline), while in cortical prisms the observed increase (by 37%) was statistically non-significant. The content of ACh in both tissues was raised by paraoxon during incubations without added choline, but paraoxon did not augment the increased concentration of ACh in tissues incubated with added 0.5 mmol/l choline. The ACh that accumulated in the adrenals during 60 min preincubations with added choline could be released during subsequent depolarizing incubations; the release was Ca2+ independent. In contrast to brain cortex prisms and to the adrenals preincubated without choline, no resynthesis of ACh occurred during the period of depolarization in the adrenals preincubated with 0.5 mmol/l choline. Large amounts of choline accumulated in both tissues during incubations with 0.5 mmol/l choline and the accumulated choline could be released by depolarization; the release of choline from the adrenals was Ca2+ independent. Free choline was produced in the adrenals (presumably from choline esters) during the periods of depolarization. The reason for differences between the effects of increased concentrations of choline on ACh in the adrenals and in brain cortex is not known.(ABSTRACT TRUNCATED AT 250 WORDS)

Cholinergic system of brain tissue in rats poisoned with the organophosphate, 0,0-dimethyl 0-(2,2-dichlorovinyl) phosphate

The cholinergic system of the brain was investigated in rats acutely poisoned with the organophosphate, 0,0-dimethyl 0-(2,2-dichlorovinyl) phosphate (DDVP), (6 mg/kg, sc, with saline as a control). The amounts of three fractions of acetylcholine (ACh)--free (extraterminal), labile-bound (intraterminal/cytoplasmic), and stable-bound (intraterminal/vesicular)--increased in the rats over a period of 5 to 60 min after injection of DDVP, showing peaks which were 2.45, 1.82, and 1.4 times as high as the respective control amounts. No difference was seen in the amount of any fraction of ACh between treated and control rats killed 3 and 24 hr after injection. Acetylcholinesterase (AChE) activity decreased to between 12 and 43% of the control over a period of 5 to 180 min and recovered almost completely within 24 hr after injection. No appreciable changes were seen in either spontaneous or potassium-induced ACh release in brain tissue slices obtained from rats treated with DDVP. ACh synthesis in slices was suppressed significantly 20 min, but not 24 hr, after injection of DDVP. In the brain crude synaptosomal preparation, high-affinity choline uptake, which is generally thought to be a rate-limiting step for ACh synthesis, was suppressed 20 min after DDVP. No appreciable changes were seen in high-affinity choline uptake at 24 hr low-affinity choline uptake, and choline acetyltransferase activity after injection of DDVP. These results suggest that ACh synthesis and high-affinity choline uptake may be in a suppressed state when ACh concentration, especially intraterminal ACh, is increased and AChE activity is decreased in the brain cholinergic system of rats poisoned with DDVP. The increase in the intraterminal ACh may be due to an inhibition of AChE activity at this site and/or a re-uptake of ACh in the synaptic cleft, not to an inhibition of ACh release or an increase in ACh synthesis.

Effect of thiopental sodium and barbitone sodium on the total acetylcholine content and acetylcholinesterase activity in the brain tissue of Arvicanthis niloticus

The total ACh content and AChE activity were determined 1 hr after the i.p. injection of different doses of thiopental sodium (5, 10 and 20 mg/ml/100 g body wt) and barbitone sodium (20, 40 and 80 mg/ml/100 g body wt). The effect of different time intervals (1 min, 10 min, 30 min, 1 hr, 2.5 hr, 5 hr, 8 hr, 12 hr, 24 hr and 48 hr) on the total ACh content and AChE activity was investigated after i.p. injection of 10 mg thiopental sodium and 40 mg barbitone sodium/ml/100 g body wt. Both thiopental sodium and barbitone sodium increased the total ACh content in the brain tissue of Arvicanthis niloticus. Both drugs inhibited the brain AChE activity. It is thought that the increase in the total ACh content in the brain tissue of Arvicanthis niloticus may be due to a decrease in the release of ACh from the neuronal tissue and a decrease in AChE activity.

Effects of insecticidal carbamates on brain acetylcholine content, acetylcholinesterase activity and behavior in mice

Mice showed no toxic signs after a single injection of o-sec-butylphenyl methylcarbamate (BPMC, 10 mg/kg) or 2-isopropoxyphenyl-N-methylcarbamate (propoxur, 2 mg/kg). Each dose of BPMC or propoxur caused an increase in acetylcholine content and a decrease in acetylcholinesterase activity in the forebrain of mice at 10 min, followed by an almost complete recovery in the content at 60 min. Spontaneous motor activity was depressed 10 min after and recovered 60 min after, injection of BPMC or propoxur. Neither rotarod performance nor rectal temperature showed any change after injection of BPMC or propoxur. Spontaneous motor activity may therefore be a simple method for assessing small changes in the cholinergic system.

Effect of morphine on acetylcholine content of electrically stimulated brain slices

Acetylcholine (ACh) levels were measured in guinea-pig thalamic and caudatal slices kept at rest or electrically stimulated for different times (2-30 min.). The decrease of ACh content caused by electrical pulses at 1 Hz and 2 Hz in caudate nucleus and thalamus slices, respectively, was directly related to the time of stimulation. The depletion was potentiated by HC-3 10 microM. In this condition the relationship between ACh content and time of stimulation was shifted to the left. In the presence of HC-3, Morphine (Mo) 30 microM did not affect the ACh levels of thalamic and caudatal slices kept at rest. The opioid, on the contrary, reduced the depletion of ACh caused by 10 min stimulation. Naloxone (Nx) 10 microM antagonized the opioid effect in caudate nucleus, while it increased the stimulus-induced ACh depletion in the thalamus treated with Morphine 30 microM. In conclusion, the electrically-stimulated brain tissue perfused with HC-3 may be a suitable tool to study drug effects on ACh depletion. This may offer an indirect, mirror-like evaluation of ACh apparent turnover and release. The results obtained with Mo and Nx support this statement.

Effect of tranquilizers on the total acetylcholine content and acetylcholinesterase activity in the brain tissue of Arvicanthis niloticus

The effect of reserpine and meprobamate on the total acetylcholine content and acetylcholinesterase activity in the brain tissue of the kusu rat, Arvicanthis niloticus, was studied. The total acetylcholine content and acetylcholinesterase activity were determined 1 hr after i.p. injection of different doses of reserpine (0.25, 0.5 and 1 mg/ml/100 g body wt) and meprobamate (6.25, 12.5 and 25 mg/ml/100 g body wt). The effect of different time intervals (1, 10, 30 min, 1, 2.5, 5, 8, 12, 24 and 48 hr) on the total acetylcholine content and acetylcholinesterase activity was investigated after i.p. injection of 0.5 mg of reserpine and 12.5 mg of meprobamate/ml/100 g body wt. Both reserpine and meprobamate caused an increase in the total ACh content in the brain tissue of Arvicanthis niloticus which was suggested to be due to a decrease in the release of ACh, since both reserpine and meprobamate inhibited AChE activity after some tested periods. The effect of meprobamate was observed to be stronger than that of reserpine.

Postmortal decay of acetylcholine levels in the spinal cord of rat, chicken and frog

The decay of acetylcholine (ACh) after death of an animal has been estimated in the cervical spinal cord of rat, chicken and frog. The level of ACh in the frog (19.90 nmol/g wet weight) shows no variation from 20 to 500 s after death. In the rat and chicken, there is a decrease in the first 100 s after death to lower values; 4.35 nmol/g wet weight in the rat and 4.60 nmol/g wet weight in the chicken. The levels of ACh in the cervical spinal cord of the rat an chicken at the time of death were estimated by extrapolation to time 0 of the curve of the decay of ACh in the first 100 s. The values obtained were: 121.64 nmol/g wet weight in the chicken and 34.19 nmol/g wet weight in the rat.

Effects of 4-aminopyridine on acetylcholine output from the cerebral cortex of the rat in vivo

1 The effects of 4-aminopyridine (4AP) on the output of acetylcholine (ACh) from the cerebral cortex were investigated in unanaesthetized freely moving rats and in anaesthetized rats by means of the ;cup technique'. ACh was determined by bioassay on the dorsal muscle of the leech.2 In unanaesthetized rats intraperitoneal injection of 4AP (3 mg/kg) had no effect on the cortical output of ACh.3 After injection of morphine (10 mg/kg s.c.), which depressed the spontaneous output of ACh, 4AP increased the cortical output to a level significantly higher than that determined before morphine injection.4 In rats anaesthetized with either urethane or pentobarbitone, drugs known to decrease cortical output of ACh, 4AP (i.v. or i.p.) elicited a significant increase in the output of ACh. The time-courses of the 4AP-induced effects were different depending on the anaesthetic drug used: an immediate increase slowly fading in urethane anaesthesia and a gradual increase after delayed onset in pentobarbitone-anaesthetized rats.5 In some urethane-anaesthetized rats, respiratory frequency was kept constant (tracheotomy, connection to respirator, bilateral vagotomy) and prazosin (1 mg/kg i.v.) was administered to reduce the 4AP-induced increase of blood pressure. Cortical output of ACh was not related to changes in blood pressure. Moreover, the 4AP-induced increase in cortical ACh output was not related to changes in respiratory frequency.6 In summary systemic administration of 4AP in subconvulsive doses (1 and 3 mg/kg) increased cortical output of ACh in rats anaesthetized with urethane or pentobarbitone or after injection of morphine, but not in untreated freely moving rats. It is suggested that the anaesthetic agents and morphine may cause an imbalance between excitatory and inhibitory central pathways, and that this imbalance may play a role in their depressant effect on cortical output of ACh and/or in the 4AP-induced facilitation described in this paper.

An ultrastructural study into the effects of pentobarbitone on synaptic organization

A series of adult male rats was analyzed to test the effects of varying doses of pentobarbitone sodium on the ultrastructure of synapses in the molecular layer of the parietal cortex. The rats were divided into the following categories: unanaesthetized stunned, unanaesthetized cannulated and those subjected to 40, 80, 160, 300, or 400 mg/kg pentobarbitone. All material was examined both qualitatively and quantitatively after aldehyde-OsO4 or ethanolic phosphotungstic acid (E-PTA) treatment. The principal qualitative observations were: the preponderance in the unanaesthetized stunned and 160-400 mg/kg material of a variety of intraterminal profiles including synaptic vesicles, mitochondria, coated vesicles, tubular profiles, vacuoles, cisterns and double membrane profiles; the presence of exocytotic sites along the presynaptic membrane in the unanaesthetized stunned and cannulated material; the presence of endocytotic sites over the limiting membrane of the terminal away from the cleft in the unanaesthetized stunned and 160-400 mg/kg material; the prominence of the presynaptic network in the unanaesthetized and 40 mg/kg E-PTA material; discontinuity of the cleft material in the 40-160 mg/kg material. Findings to emerge from the quantitative aspect of the study show that pentobarbitone influences synaptic curvature, with a marked increase in curvature negativity over the 0-80 mg/kg dose range and a decrease in negativity at higher dose levels. The increase in curvature negativity is accompanied by an increase in synaptic length and dense projection numbers, with a consonant increase in the perimeter and area of the presynaptic terminal. Reversal of the negativity trend at higher dose levels is parallelled by reversal of these accompanying trends. Both sets of findings can be accounted for by membrane recycling within the terminal, supporting a membrane redistribution hypothesis.

Changes in regional brain acetylcholine levels during drug-induced convulsions

Acetylcholine (ACh) levels were determined in the brain of rats killed by decapitation or focussed microwave radiation during drug-induced convulsions. During metrazol or strychnine-induced convulsions a diffuse decrease in ACh levels was found in rats killed by decapitation. When the rats were killed by radiation and the brain was only divided into three large regions, strychnine caused no changes in ACh levels; metrazol caused a decrease in the cerebral cortex and lower brainstem. When discrete brain regions were investigated in rats killed by radiation, metrazol-induced convulsions were associated with a decrease in ACh level in all regions dissected and strychnine-induced convulsions with a decrease in the hippocampus and caudate nucleus only. Picrotoxin-induced convulsions were associated with a decrease in ACh level in the cerebral cortex, hippocampus, midbrain and medulla-pons, those induced by bicuculline with an increase in ACh level in the frontal cortex, hippocampus, midbrain and medulla-pons, by dimefline with an increase in the frontal cortex, midbrain and medulla-pons and a decrease in the caudate nucleus. The experiments show that each type of convulsant affects ACh levels in discrete brain regions in a different way.

Effects of physostigmine and electrical stimulation on the acetylcholine content of the guinea-pig ileum

Incubation with physostigmine (7.7 muM) caused an approximately 2 fold increase in the acetylcholine content of the myenteric plexus--longitudinal muscle preparation of the guinea-pig ileum. This effect was due mainly to an increase in 'free' acetylcholine, which was directly assayable in either the homogenate after removal of cell debris or the supernatant fraction (100,000 g for 60 min) after subcellular fractionation. Acetylcholine output during stimulation at 0.017, 0.1 or 1 Hz was maintained for 60 min at a rate 2--4 times greater than the non-stimulated output; there was no change in content. At 10 HZ, output was high at the start of stimulation and then decreased continuously; there was a proportionate loss of mainly 'free' acetylcholine from the tissue. Mn2+, hexamethonium, morphine and noradrenaline, which depressed acetylcholine output during stimulation at 0.1 HZ, had no effect on the acetylcholine content nor did they affect the increase in acetylcholine content during incubation with physostigmine.

Choline metabolism in the cerebral cortex of guinea pigs. Stable-bound acetylcholine

1. The turnover of synaptosomal (vesicular-cytoplasmic) and stable-bound (vesicular) acetylcholine isolated from cortical tissue was investigated after the administration, under local anaesthesia, of [N-Me-(3)H]choline into the lateral ventricles of guinea pigs. 2. Radioactive acetylcholine and choline present in acid extracts of subcellular fractions were separated by a combination of liquid and column ion-exchange and thin-layer chromatography. 3. The specific radioactivity and pattern of labelling of acetylcholine present in a fraction of monodisperse synaptic vesicles was found to be essentially the same as that of synaptosomal acetylcholine. 4. The specific radioactivity of stable-bound acetylcholine present in partially disrupted synaptosomes (fraction H) at short times (10-20min) after the injection of [N-Me-(3)H]choline was very variable and inversely related to the yield of acetylcholine in that fraction. 5. Evidence was found for the existence of two small, but highly labelled pools of acetylcholine, one which could be isolated in fraction H and the other which was lost when synaptosomes, after isolation by gradient centrifugation, were left at 0 degrees C or pelleted. 6. It is concluded that the results are best explained by metabolic differences among the nerve-ending compartments (thought to be vesicles) which contain stable-bound acetylcholine. Computer simulation of our experiments supports this possibility and suggests that the highly labelled pool in fraction H is present in vesicles close to the external membrane.

Cholinergic mechanisms and avoidance behavior acquisition: effects of nicotine in mice

Mice treated with nicotine sulfate showed, as compared with saline-treated controls, a decreased incidence of active avoidance conditioning without effects upon either passive avoidance acquisition or escape behavior. The effect of nicotine was to reduce significantly the ratio of bound: free acetylcholine in the cerebral cortex. This change was accounted for by a decreased content of stored amine, particularly in the synaptic vesicles, without any change in the turnover of the “free” storage pool. A difference in the ratio of brain acetylcholine storage pools accounting for different modes of avoidance is suggested.

The estimation of the "free" and "bound" acetylcholine content of rat brain

Rat brains, not frozen, were homogenized in saline solution containing physostigmine, and also cupric chloride to inhibit choline acetyl-transferase. When brains were homogenized for periods of up to 3 min, the amount of acetylcholine extracted was proportional to the duration of homogenization. After 3 min, there was no further significant increase in acetylcholine. The acetylcholine extracted in this way was termed “free”; whereas that remaining in the brain tissue and extracted by acid-ethanol solution was termed “bound”. The total amount obtained from each brain was not significantly different from the total amount extracted by a more conventional method from the brains of rats killed by rapid freezing in liquid air. This observation applied also to brains removed from animals during anaesthesia and convulsions.