Influence of morphine and naloxone on the release of noradrenaline from rat brain cortex slices

Summary In slices of rat brain cortex preincubated with (–)-³H-noradrenaline, the influence of morphine and naloxone on the efflux of tritium was investigated. The spontaneous outflow of tritium was not changed by 10^–7–10^–5 M morphine and by 10^–6–10^–4 M naloxone, but was accelerated by 10^–4 M morphine. Electrical field stimulation augmented tritium outflow. The overflow evoked per ppulse decreased as the frequency of stimulation was increased from 0.3 to 3 Hz, but remained approximately constant when it was further increased to 10 Hz. At frequencies of 0.3, 1, and 3 Hz, but not at 10 Hz, morphine in concentrations of 10^–7–10^–5 M depressed the stimulation-induced overflow of tritium. 10^–4 M morphine did not influence the overflow induced by stimulation at 0.3 and 1 Hz and increased that evoked by stimulation at 10 Hz. Naloxone (10^–6–10^–4 M) did not change the response to stimulation. In the presence of 10^–4 M naloxone, 10^–6 M morphine did not diminish, and 10^–5 M morphine even enhanced the stimulation-induced overflow of tritium. The inhibitory effect of 10^–6 M morphine was not reduced, after tyrosine hydroxylase had been blocked by -methyltyrosine-methylester. It is concluded that morphine through an action on specific opiate receptors inhibits the release of transmitter from cerebrocortical noradrenergic neurones evoked by nerve impulses. By an action unrelated to opiate receptors, morphine at high concentrations increases the stimulation-induced overflow of noradrenaline, presumably by inhibiting its re-uptake into nerve endings.     

Influence of morphine and naloxone on the release of noradrenaline from rat cerebellar cortex slices

Summary In slices of rat cerebellar cortex preincubated with (-)-³H-noradrenaline, the influence of morphine and naloxone on the efflux of tritium was investigated. The spontaneous outflow was not changed by 10^–5 M of either morphine or naloxone. On the other hand, morphine caused a concentration-dependent decrease of the overflow, of tritium evoked by electrical field stimulation. Naloxone did not change the stimulation-induced overflow, but prevented its inhibition by morphine. It is concluded that morphine, through an action on opiate receptors located on cerebellar noradrenergic neurones, inhibits the secretion of the transmitter in response to nerve impulses.     

Interaction between 5-HT uptake inhibition and activation of 5-HT autoreceptors by exogenous agonists in rat cerebral cortex slices and synaptosomes

Summary Rat cerebral cortex slices or synaptosomes were labelled with ³H-5-hydroxytryptamine (³H-5-HT) and subsequently superfused. They were depolarized by electrical stimulation (slices) or with high K⁺ (slices and synaptosomes). Continuous electrical stimulation (2 Hz, 24 mA, 2 ms) and continuous or discontinuous K⁺ depolarization (15–25 mM) were used. 1. Continuous electrical stimulation or continuous K⁺-depolarization of slices evoked a steady overflow of tritium that slowly decayed with time. 2. Exposure to increasing concentrations of 5-methoxy-3(1,2,3,6-tetrahydropyridin-4-yl)-1H-indole succinate (RU 24969) (0.001–0.1 M) during continuous electrical stimulation produced a concentration-dependent decrease in tritium overflow. Citalopram (1 M) counteracted the effect of RU 24969. 3. RU 24969 inhibited the evoked ³H-overflow and citalopram reduced the effect of RU 24969 also during continuous depolarization of slices with 20 mM K⁺. Similar results were obtained by using 5-methoxytryptamine or LSD. 4. In slices 1 M citalopram increased significantly the tritium overflow evoked by electrical stimulation or by 20 mM K⁺-depolarization. 5. Increasing the K⁺ concentration from 20 mM to 25 mM mimicked the effects of 1 M citalopram both on the RU 24969 activity and on the evoked tritium overflow. 6. RU 24969 (0.001–0.1 M) decreased in a concentration-dependent way the release of tritium from cortical synaptosomes depolarized with K⁺ (15–20 mM). The presence of 1 M citalopram did not modify significantly the effect of the agonist. Citalopram was ineffective also when the serotonin uptake carrier in superfused synaptosomes was activated by tryptamine. In conclusion, in slices of rat cerebral cortex, the action of exogenous 5-HT autoreceptor agonists is inhibited by 5-HT uptake blockers independently of the depolarizing agent (electrical stimulation or high-K⁺) used to elicit ³H-5-HT release. Increasing K⁺-concentration, which probably increases serotonin in the biophase, mimics the presence of the reuptake inhibitor. These data together with the finding that, in superfused synaptosomes, 5-HT uptake inhibition did not affect the potency of autoreceptor agonists, favours the idea that, in cerebral cortex slices, inhibitors of 5-HT reuptake prevent activation of autoreceptors by exogenous agonists by increasing the concentration of 5-HT in the autoreceptor biophase. Send offprint requests to M. Raiteri at the above address     

Influence of fentanyl,levorphanol and pethidine on the release of noradrenaline from rat brain cortex slices

Summary In slices of rat brain cortex preincubated with (–)-³H-noradrenaline, the influence of fentanyl, levorphanol and pethidine on the efflux of tritium was investigated. The spontaneous outflow of tritium was not changed by low, and was accelerated by high concentrations of the drugs. The overflow of tritium evoked by electrical stimulation at 3 Hz was diminished by 10^–8–10^–7 M fentanyl and by 10^–7–10^–6 M levorphanol, but was augmented by 10^–5 M levorphanol. Naloxone prevented the inhibitory effect of fentanyl and levorphanol. In contrast to fentanyl and levorphanol, pethidine did not decrease, but at concentrations of 10^–6–10^–5 M greatly increased the stimulation-induced overflow of tritium. However, the increase was abolished, and the stimulation-evoked overflow slightly reduced, after the re-uptake of noradrenaline had been blocked by cocaine. It is concluded that fentanyl, levorphanol and pethidine share with morphine the ability to inhibit the release of transmitter from cerebrocortical noradrenaline neurones evoked by nerve impulses.     

Adenosine but not an adenine nucleotide mediates tonic purinergic inhibition,as well as inhibition by glutamate,of noradrenaline release in rabbit brain cortex slices

Summary A possible contribution of adenine nucleotides to the endogenous purinergic, A₁-receptor-mediated inhibition of noradrenaline release was studied in rabbit occipito-parietal cortex slices. The slices were preincubated with [³H]-noradrenaline and then superfused and stimulated electrically, in most experiments by trains of 6 pulses/100 Hz. A few experiments were carried out in rat occipito-parietal cortex slices. The A₁-purinoceptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX; 1–100 nmol/l) as well as the enzyme adenosine deaminase (0.1–10 U/ml) increased the electrically evoked overflow of tritiated compounds. The maximal increase was by about 85% for both DPCPX and adenosine deaminase. The increases obtained with maximally effective concentrations of DPCPX and adenosine deaminase were not additive. The ₁-adrenoceptor-selective agonist methoxamine (10 but not 1 mol/l) reduced the evoked overflow. Its effect was antagonized by yohimbine 1 mol/l but then not attenuated further by DPCPX100 nmol/l.L-Glutamate (300 mol/l–2.3 mmol/l) also reduced the evoked overflow of tritium. Its effect was not changed by yohimbine 1 mol/l but greatly, and to the same extent, attenuated by DPCPX 100 mol/l and adenosine deaminase 3 U/ml. Neither the N-methyl-D-aspartate (NMDA) receptor antagonist dizocilpine nor omission of Mg⁺⁺ changed the inhibition by glutamate. Glutamate did not alter the basal efflux of tritium from rabbit cortex slices under any experimental condition. In contrast, glutamate (100 mol/l and 1 mol/l) caused an immediate, marked and transient acceleration of tritium outflow from rat occipitoparietal cortex slices (medium without Mg⁺⁺). It is concluded that adenosine but not an adenine nucleotide mediates the tonic purinergic presynaptic inhibition of noradrenaline release in rabbit brain cortex. The marked degree of disinhibition by DPCPX and adenosine deaminase underscores the potential physiological role of this inhibition. The purinergic inhibitory tone is reinforced by glutamate, indicating that glutamate releases adenyl compounds in rabbit brain cortex. Again adenosine but not an adenine nucleotide mediates the indirect inhibition by glutamate of the release of noradrenaline. The noradrenaline-releasing effect that glutamate exerts in rat occipito-parietal cortex does not occur in rabbit occipito-parietal cortex. Methoxamine depresses the release of noradrenaline in rabbit brain cortex directly at presynaptic ₂-adrenoceptors rather than by release of purines.Correspondence to I. von Kügelgen at the above address     

P2-purinoceptor-mediated autoinhibition of sympathetic transmitter release in mouse and rat vas deferens

Effects of drugs acting at P₂-purinoceptors on the release of newly taken up [³H]-noradrenaline were studied in slices of mouse and rat vas deferens. The slices were superfused and stimulated electrically, in most experiments by trains of 60 pulses/8 Hz.In mouse vas deferens, the P₂-purinoceptor antagonists reactive blue 2 (1.8–100 M) and brilliant blue G (10–300 M) increased the stimulation-evoked overflow of tritium in a concentration-dependent manner as shown previously for suramin. Reactive blue 2, which preferentially blocks the P_2Y-subtype, was the most potent compound and the compound with highest maximal effect, an increase by 104%. Pyridoxalphosphate-6-azophenyl-2,4-disulfonic acid (PPADS), in contrast, caused a small increase only at a single concentration (30 M). The effects of reactive blue 2, brilliant blue G and suramin were not additive. The P₂ agonist adenosine 5-O-(3-thio)-triphosphate (ATPS) reduced the evoked overflow of tritium. As shown previously for suramin, reactive blue 2 30 M and brilliant blue G 100 M antagonized the effect of ATPS. From the shift of the ATPS concentration-response curve to the right, an apparent pK_B value of 5.3 was estimated for reactive blue 2 and an apparent pKB of 4.5 for brilliant blue G. In rat vas deferens, reactive blue 2 (3–30 M), brilliant blue G (10 M) and suramin (30–300 M) also increased the evoked overflow of tritium. As in the mouse, reactive blue 2 was the most potent compound and the compound with highest maximal effect, an increase by 9001o. As previously demonstrated in the mouse, suramin (300 M) increased the evoked overflow of tritium only when rat vas deferens slices were stimulated by trains of 60 pulses at 1 or 8 Hz, but not when they were stimulated by trains of 6 pulses/100 Hz.The results confirm the operation of a P₂-purinoceptor-mediated prejunctional negative feedback controlling the release of noradrenaline in mouse vas deferens and demonstrate the same mechanism in rat vas deferens. The prejunctional P₂-purinoceptors are P_2Y-like in both species. They are a novel kind of autoreceptors, operating in parallel to prejunctional ₂-autoreceptors. Correspondence to: I. von Kügelgen at the above address     

Cardiac electrophysiology of four neuroleptics: Melperone,haloperidol, thioridazine and chlorpromazine

Summary Effects of dopamine receptor agonists and antagonists on the release of dopamine were studied in the caudate nucleus of the rabbit. The nucleus contained 6.7 g/g of dopamine, but negligible levels of noradrenaline and dopamine--hydroxylase. No formation of ³H-noradrenaline was detected in caudate slices preincubated with ³H-dopamine, and more than 95% of the tritium content of the tissue consisted of ³H-dopamine.When caudate slices were preincubated with ³H-dopamine and then superfused with amine-free medium, there was a basal outflow of tritium that was not or only slightly changed by tetrodotoxin (10^–7 and 10^–6 M), apomorphine (up to 10^–5 M), bromocriptine (up to 10^–6 M), chlorpromazine (up to 10^–6 M), haloperidol (up to 10^–7 M), or omission of calcium. Electrical stimulation (3 Hz, 24 mA, 2 ms pulse duration, 2-min periods) greatly increased the outflow of tritium. The stimulation-evoked overflow was abolished by tetrodotoxin (10^–7 and 10^–6 M) and in calcium-free medium. Apomorphine (10^–8–10^–5 M) and bromocriptine (10^–8–10^–6 M) reduced, whereas chlorpromazine (10^–7 and 10^–6 M) and haloperidol (10^–8 and 10^–7 M) enhanced the evoked overflow. The inhibitory effect of apomorphine and bromocriptine was antagonized by chlorpromazine and haloperidol, but not by phentolamine.Silicone tubings that had been in contact with ³H-haloperidol retained tritiated material that was slowly eluted during perfusion with water or physiological salt solution. The material was identified as ³H-haloperidol. When silicone tubings pretreated with unlabelled haloperidol were used in subsequent dopamine release experiments, the inhibitory effect of apomorphine was not reproduced.It is concluded that, in the caudate nucleus of the rabbit, apomorphine and bromocriptine depress, whereas chlorpromazine and haloperidol facilitate action potential-evoked release of dopamine. The effects are mediated by specific receptors which may be located on the dopaminergic nerve terminals. The receptors appear to be normally activated by released dopamine itself, which thus inhibits its own further release. Part of the discrepancies in the literature concerning dopaminergic modulation of dopamine release may be due to retention of neuroleptic drugs in superfusion assemblies, followed by slow elution and interference with subsequent experiments.     

Stimulus-evoked release of tritiated monoamines from rat periaqueductal gray slices in vitro and its receptor-mediated modulation

Summary The periaqueductal gray is a brain region of considerable interest. It is innervated by monoamine-containing neurons as well as by a variety of peptidergic fiber systems, and it participates in the regulation of various functions. Virtually nothing is known about monoamine release in the periaqueductal gray and its receptor-mediated modulation. We therefore studied the release of radioactivity from periaqueductal gray slices preloaded with tritriated monoamines, using an in vitro superfusion method.The release of radioactivity from superfused periaqueductal gray slices after preloading of the tissue with [³H]noradrenaline increased upon electrical stimulation in a frequency-dependent manner. The stimulus-evoked release of radioactivity was Ca²⁺-dependent. Clonidine reduced and yohimbine enhanced the release. The inhibition curve for the effect of clonidine was shifted to the right in the presence of 10^–6 M yohimbine. While phenylephrine, isoprenaline, SK&F 38393, quinpirole, carbachol, [Arg⁸]vasopressin, -MSH and ACTH-(1-24), at a concentration of 10^–6 M, did not influence the electrically evoked release of radioactivity, [Leu⁵]enkephalin reduced it. The selective -opioid receptor agonists [d-Ala²,NMePhe⁴,Gly-ol⁵]enkephalin and [d-Arg²,Lys⁴]-dermorphin-(1–4)-amide reduced the release of radioactivity, whereas the selective opioid receptor agonist [d-Pen²,d-Pen⁵]enkephalin and the selective K opioid receptor agonist U-69593 had no effect. In the presence of naloxone, which by itself had no effect on the release of radioactivity, the effect of [d-Arg²,Lys⁴]dermorphin-(1–4)-amide was abolished. These results show that the release of noradrenaline from periaqueductal gray slices is via a Ca²⁺-dependent. exocytotic process, and that it is modulated through ₂-adrenoceptors as well as via -opioid receptors. Though the overflow of radioactivity from slices preloaded with [3H]dopamine in the presence of desipramine was measurable, there are reasons to assume that we are dealing here with the release of tritiated catecholamines from a population of nerve endings consisting of noradrenergic and dopaminergic terminals.The release of radioactivity from periaqueductal gray slices preloaded with [³H]5-hydroxytryptamine upon elevation of the K⁺ concentration in the superfusion medium was much more pronounced than that induced by electrical stimulation. The K⁺-evoked release of radioactivity was almost completely abolished in the absence of Cat²⁺; showing that the release is via a Ca²⁺-dependent process. 5-Hydrotryptamine reduced the K⁺-evoked release of radioactivity in a concentration-dependent manner.Some of these data were presented at the XIth International Congress of Pharmacology, 1–6 July 1990, Amsterdam, The Netherlands (Eur J Pharmacol 183:408) Send offprint requests to D. H. G. Versteeg at the above address     

P1-purinoceptor-mediated modulation of neural noradrenaline and ATP release in guinea-pig vas deferens

The effect of P₁-purinoceptor activation on contractions, release of noradrenaline and release of ATP elicited by electrical field stimulation (210 pulses, 7 Hz) was studied in the superfused vas deferens of the guinea pig. Release of noradrenaline was assessed as overflow of total tritium after preincubation with [³H]-noradrenaline. ATP was measured by means of the luciferinluciferase technique.Electrical stimulation elicited reproducible contraction, tritium overflow and ATP overflow. In the absence of other drugs, adenosine (10–100 M) did not change evoked contractions but reduced the evoked overflow of tritium and ATP. In subsequent experiments ₁-adrenoceptors were blocked by prazosin, P₂-purinoceptors by suramin and ₂-adrenoceptors by rauwolscine. No or almost no contraction remained under these conditions. The evoked overflow of tritium was 505% and the evoked overflow of ATP 34% of that observed in the absence of prazosin, suramin and rauwolscine. Adenosine (1–100 M) again reduced the evoked overflow of tritium and ATP, and so did the A₁-selective agonist 2-chloro-N⁶-cyclopentyladenosine (CCPA; 0.032–0.32 M). Adenosine and CCPA decreased the evoked overflow of ATP to a greater extent than the evoked overflow of tritrium.It is concluded that neural release of both postganglionic sympathetic cotransmitters, noradrenaline and ATP, is decreased upon activation of prejunctional P₁- (A₁-) purinoceptors in guinea-pig vas deferens. The A₁-receptor-mediated inhibition of the release of ATP is more marked than the inhibition of the release of noradrenaline, a pattern opposite to the inhibition produced by activation of prejunctional ₂-autoreceptors. Correspondence to: B. Driessen at the above address     

Adenosine analogs do not inhibit the potassium-stimulated release of substance P from rat spinal cord slices

Summary Adenosine agonists produce antinociception when injected directly onto the spinal cord of rats and mice. One mechanism to account for this effect could be inhibition of neurotransmitter release from nociceptive sensory neurons. Consequently, we studied whether these agents could inhibit the potassium stimulated release of one such transmitter, substance P, from rat spinal cord slices. A 2 cm section of lumbar spinal cord was dissected from male Sprague-Dawley rats, chopped into 0.5 × 0.5 mm sections and perfused at 37°C with a modified Krebs bicarbonate buffer containing either 3.5 mM, 30 mM, or 50 mM KCl in the presence and absence of various adenosine analogs. Perfusates, collected every 2 min, were assayed for substance P by radioimmunoassay. Exposure of tissue to 50 mM KC1 produced an approximate three-fold increase in the release of substance P over basal release. This increase in release was calcium dependent. Perfusion of spinal cord tissues with either adenosine (10^–3 M), N⁶-cyclohexyladenosine (10^–5 M or 5 × 10^–5 M), 5-N-ethylcarboxamide adenosine (10^–5 M) or L-N⁶-phenylisopropyladenosine (10^–5 M) did not significantly alter basal or potassium-stimulated release of SP when compared to controls. In contrast to the adenosine agonists, exposure of the spinal cord tissue to 10^–5 M morphine significantly reduced the potassium-stimulated release of substance P. Pretreatment of the slices with 10^–5 M theophylline or 8-phenyltheophylline did not significantly attenuate the inhibition of substance P release produced by morphine. Theophylline alone (10^–5 M) had no significant effect on either basal or potassium-stimulated release of SP. These studies demonstrate that adenosine does not inhibit the release of SP from spinal cord slices and does not appear to mediate the morphine-induced inhibition of SP release. The results suggest that the mechanism of the antinociceptive effects of adenosine at the level of the spinal cord is not via inhibition of substance P release. Send offprint requests to M. R. Vasko at the above address     

On the mechanism of alpha-receptor mediated modulation of 3H-noradrenaline release from slices of rat brain neocortex

Summary Brain cortical slices were superfused with Krebs-Ringer media and the effects of oxymetazoline (an -adrenoceptor agonist) and phentolamine (an -antagonist) on depolarization-induced ³H-NA release were examined. Depolarization was effected by various K⁺-concentrations or by electrical pulses.The effects of the -receptor agents on stimulated ³H-NA overflow appeared to be dependent on the strength of the depolarizing stimulus. Thus, at low K⁺-concentrations (13 or 26 mM) oxymetazoline decreased and phentolamine increased the stimulated overflow, while at 56 mM K⁺ little or no modulation was found. The agents acting on -receptors modulated ³H-NA release in a dose-dependent way (5 · 10^–8–10^–5 M).The lack of modulation by oxymetazoline of ³H-NA release induced by 56 mM K⁺ seems not to be due to a high concentration of NA released into the synaptic cleft, since reduction of the endogenous NA level by pretreatment with -methyl-para-tyrosine did not reveal such modulation.However, oxymetazoline was found to decrease 56 mM K⁺-induced ³H-NA release effectively, if the Ca²⁺-concentration in the medium was lowered from 1.2 to 0.2 mM. This suggests that -receptor mediated modulation of release may occur as a result of a change in Ca²⁺-availability to the depolarization-secretion process. In addition, hyperpolarization of nerve endings might be involved in the modulatory process, as concluded from calculations of the (theoretical) trans-membrane potential at various K⁺-concentrations.Although the -receptors modulating NA release seem to be localized presynaptically, their precise location remains uncertain. Experiments with tetrodotoxin suggested that the -receptor mediated modulation does not operate via a local interneuronal loop.     

Phencyclidine and ketamine: Comparison with the effect of cocaine on the noradrenergic neurones of the rat brain cortex

Summary In slices of the rat occipital cortex, the influence of phencyclidine and ketamine on the accumulation of ³H-noradrenaline and the subsequent outflow of tritium was investigated, and was compared with the effect of cocaine.-All three drugs inhibited the accumulation of tritium during incubation of the slices with ³H-noradrenaline. Phencyclidine was slightly, whereas ketamine was much less effective than cocaine.-All three drugs accelerated the spontaneous outflow of tritium from slices preincubated with ³H-noradrenaline. The acceleration caused by low concentrations probably reflects an inhibition of the re-uptake of spontaneously released ³H-noradrenaline; in addition, high concentrations (10^–4M phencyclidine, 3×10^–4–10^–3M cocaine and 10^–3–3×10^–3M ketamine) appear to release tritiated compounds from the neurones. The distance between uptakeinhibiting and releasing concentrations was much greater for cocaine than for phencyclidine and ketamine.-All three drugs enhanced the overflow of tritium evoked by electrical field stimulation. The increase probably reflects an inhibition of the re-uptake of released ³H-noradrenaline; in addition, phencyclidine appears to enhance the release of noradrenaline per pulse.-The actions of phencyclidine and ketamine on central noradrenergic neurones may contribute to the characteristic psychotropic side-effects of these general anaesthetics.     

Acetylcholine release in rat nucleus accumbens is regulated through dopamine D2-receptors

Summary Experiments in slices of rat nucleus accumbens were carried out in order to investigate whether the release of acetylcholine in this tissue is modulated through dopamine receptors. The slices were preincubated with ³H-choline and then superfused and stimulated electrically twice for 2 min each at a frequency of 3 Hz.The electrically evoked overflow of tritium averaged 2.9–3.9% of the tritium content of the tissue in the various groups. The D₂-selective agonist quinpirole (0.01–1 mol/l) reduced the evoked overflow of tritium by maximally 56%, an effect antagonized by the D₂-selective antagonist (–)-sulpiride (1 mol/l). The D₁-selective agonist 2,3,4,5-tetrahydro-7,8-dihydroxy-1-phenyl-1H-3-benzazepine (SKF 38393) caused a slight decrease only at the high concentration of 10 mol/l. (–)-Sulpiride (0.1–10 mol/l) moderately increased the evoked overflow of tritium when given alone. The dopamine uptake inhibitor nomifensine (10 mol/l) caused a decrease, and in its presence the increase produced by (–)-sulpiride became much more marked, amounting to maximally 149%. (+)-Sulpiride (0.1–1 mol/l) failed to change the evoked overflow of tritium in the presence of nomifensine. The dopamine-releasing agent (±)-amphetamine (1 mol/l) also reduced the evoked overflow, an effect abolished by (–)-sulpiride. Finally, bretylium (1 mmol/l), which blocks the release of dopamine, increased the evoked overflow. (–)-Sulpiride (1 mol/l) lost its facilitatory effect in slices treated with bretylium.We conclude that the release of acetylcholine in rat nucleus accumbens, like its release in the nucleus caudatusputamen, is modulated through dopamine D₂-receptors. The receptors are activated by endogenous dopamine under the conditions of these experiments. Send offprint requests to K. Starke at the above address     

Inhibitory and excitatory muscarinic receptors modulating the release of acetylcholine from the postganglionic parasympathetic neuron of the chicken heart

Summary The effects of muscarinic receptor antagonists on ACh release were studied in the absence or presence of cholinesterase (ChE) inhibition using the isolated perfused chicken heart. Presynaptic inhibitory muscarinic autoreceptor were characterized by determining the potency of various antagonists to enhance [³H]-ACh release evoked by field stimulation (3 Hz, 1 min). The order of potencies was: (±)-telenzepine > atropine > 4-DAMP > silahexocyclium > pirenzepine > hexahydro-siladifenidol > AF-DX 116. The comparison with known pA₂ values for M₁-, M₂- and M₃-receptors revealed that the presynaptic autoreceptor meets the criteria of an M₁-receptor. Basal, not electrically evoked overflow of unlabelled ACh into the perfusate was caused by leakage release (non-exocytotic), as it was independent of extracellular Ca²⁺ . Muscarinic receptor antagonists failed to enhance basel overflow. In contrast, when ChE activity was inhibited by 10^–6M tacrine or pretreatment with 10^–4M DFP, the ACh overflow was partially Ca²⁺-dependent and was reduced by tetrodotoxine. Moreover, block of the inhibitory muscarinic autoreceptors by (±)-telenzepine or pirenzepine caused a several-fold enhancement of the ACh release. The potencies of these antagonists were identical to those found for the electrically evoked [³H]-ACh release. The rate of ACh release enhanced by ChE inhibition plus telenzepine corresponds to about 12% of the total ACh pool per min, which is about the maximum amount of ACh that is available for any kind of stimuli. The release was dependent on the presence of exogenous choline. Hence elevation of ACh release led to a correspondingly enhanced ACh synthesis. The dramatic enhancement of ACh release by the ChE inhibition in combination with a block of presynaptic muscarinic autoinhibition was not inhibited by (+)-tubocurarine but by atropine (10^–9 to 10^–7 M) or 10^–6 M telenzepine. It is concluded that basal release of ACh in the heart was due to non-exocytotic leakage release. Inhibition of ChE led to a marked stimulation of excitatory muscarinic receptors of the intrinsic parasympathetic neuron with a consecutive postganglionic release of ACh. The strong postganglionic excitation was obvious when the inhibitory muscarinic autoreceptors were selectively blocked. Of the two described muscarinic receptors found in the parasympathetic postganglionic neuron of the chicken heart only the inhibitory was classified as being M₁, whereas the subtype of the excitatory one is unlike M₁ and remains to be identified.Preliminary results have been presented at the Spring meeting of the German Pharmacological Society in 1992 (Brehm and Lindmar 1992) Correspondence to R. Lindmar at the above address     

Neural ATP release and its α2-adrenoceptor-mediated modulation in guinea-pig vas deferens

Summary Contractions, release of previously stored [³H]-noradrenaline (measured as overflow of total tritiated compounds) and release of ATP elicited by electrical field stimulation (210 pulses, 7 Hz) were studied in the superfused vas deferens of the guinea pig. Prazosin and suramin were used to suppress non-neural ATP release, and effects of bromoxidine and rauwolscine on the neural release thus isolated were examined.Electrical stimulation elicited reproducible contraction, tritium overflow and ATP overflow. Both prazosin (0.03–3 M) and suramin (30–300 M) reduced contractions as well as the evoked overflow of ATP. No visible contraction remained in 21 of 28 tissues exposed to prazosin 0.3 M combined with suramin 300 M. The evoked overflow of ATP under these conditions was about 17% of that observed in the absence of drugs. In the presence of prazosin 0.3 M and suramin 300 M, bromoxidine (0.01–1 M) decreased and rauwolscine (0.1–10 M) increased the evoked overflow of both tritium and ATP. Rauwolscine increased the evoked overflow of tritium to a significantly greater extent than the overflow of ATP.It is concluded that the overflow of ATP elicited by electrical (neural) stimulation in the presence of prazosin 0.3 M and suramin 300 M reflects purely neural release of ATP. This release of ATP, like the release of noradrenaline, is modulated through prejunctional ₂-adrenoceptors. The ₂-adrenoceptor modulation of the release of noradrenaline seems to be more marked than the modulation of the release of ATP. Correspondence to B. Driessen at the above address     

Cyclic AMP facilitates the electrically evoked release of radiolabelled noradrenaline,dopamine and 5-hydroxytryptamine from rat brain slices

Summary The adenylate cyclase activator forskolin as well as 8-bromo-cyclic AMP enhanced the electrically evoked release of³H-noradrenaline and³H-5-hydroxytryptamine from superfused rat neocortical slices and that of³H-dopamine from neostriatal slices with comparable EC₅₀'s of about 0.5 and 50 M, respectively, without affecting spontaneous tritium efflux. The phosphodiesterase inhibitor ZK 62771 (3–100 M) also enhanced³H-noradrenaline and³H-dopamine release but slightly reduced³H-5-hydroxytryptamine release. However, this drug profoundly enhanced spontaneous tritium release in the latter case. The facilitatory effect of forskolin (0.3 M) on the release of the amine neurotransmitters was potentiated in the presence of ZK 62771 (30 M). Therefore, cyclic AMP appears to exert a general facilitatory effect on the release of these biogenic amines from central nerve terminals.     

Effect of extracellular dopamine on the release of dopamine in the rabbit caudate nucleus: Evidence for a dopaminergic feedback inhibition

Summary Slices of the head of the rabbit caudate nucleus were preincubated with 10^–7 M ³H-dopamine and then superfused, and the effect of unlabeled dopamine on the outflow of tritium was investigated. In most experiments, nomifensine was added throughout superfusion in order to block uptake of the unlabeled amine. Nomifensine was a potent inhibitor of the uptake of ³H-dopamine into rabbit caudate synaptosomes, with an IC₅₀ of 5·10^–8 M at a ³H-dopamine concentration of 4·10^–8 M.In the absence of nomifensine, unlabeled dopamine (10^–7 M and higher concentrations) accelerated the basal outflow of tritium from preincubated slices. 10^–5 M nomifensine strongly counteracted the acceleration. In the presence of nomifensine, unlabeled dopamine (10^–7 to 10^–6 M) caused a concentrationdependent decrease of the overflow of tritium evoked by electrical stimulation at 0.1 Hz. Chlorpromazine and haloperidol (in the presence of nomifensine) increased the stimulation evoked overflow and antagonized the inhibitory effect of dopamine.It is concluded that extracellular dopamine shares with other dopaminergic agonists the ability to inhibit action potential-evoked release of intraneuronal dopamine. The inhibition is mediated by specific receptors. The results support the hypothesis that previously released dopamine, by an action on these receptors, can inhibit further release of dopamine.     

Cardiovascular effects of agmatine,a “clonidine-displacing substance”, in conscious rabbits

Agmatine has been identified as a clonidine-displacing substance in extracts from bovine brain. We studied its effect on cardiovascular regulation and the role played in this effect by ₂-adrenoceptors.In conscious rabbits, agmatine 10 g kg^–1 injected intracisternally (i.e.) caused no change, whereas agmatine 30, 100 and 300 g kg^–1 i.e. increased renal sympathetic nerve firing, the plasma concentration of noradrenaline and adrenaline and arterial blood pressure. Heart rate tended to be decreased. Yohimbine 1.5 g kg^–1 i.e. caused no change, whereas yohimbine 5, 15 and 50 g kg^–1 increased renal sympathetic nerve activity, the plasma concentration of noradrenaline and adrenaline, blood pressure and heart rate. In rabbit brain cortex slices preincubated with [³H]-noradrenaline, agmatine 1 to 100 M did not modify the electrically evoked overflow of tritium (either 4 pulses at 100 Hz or 36 pulses at 3 Hz). The evoked overflow was reduced by 5-bromo-6-(2-imidazolin-2-ylamino)quinoxaline (UK 14304) 0.03 to 30 nM (4 pulses at 100 Hz), and this inhibition was not affected by agmatine 10 and 100 M. Agmatine did not change the basal efflux of tritium.The results show that agmatine, like yohimbine, causes central sympathoexcitation when given i.e., but agmatine differs from yohimbine in that it does not increase heart rate. Agmatine acts neither as an agonist nor as an antagonist at the ₂-autoreceptors in rabbit brain cortex. ₂-Adrenoceptors, therefore, are probably not involved in its cardiovascular effects. An action at imidazoline receptors in the medulla oblongata or some other hitherto unknown mechanism may be responsible for the sympathoexcitation.     

Presynaptic serotonin receptors regulate the release of 3H-serotonin in hypothalamic slices of the rabbit

Summary Hypothalamic slices of the rabbit brain were incubated with 10^–7 M of ³H-serotonin (³H-5HT). After the incubation and an initial washout period, a nearly constant basal efflux of tritium was detected. This basal efflux was not significantly altered by Ca²⁺-free solution or by the 5HT-antagonist metitepin (10^–5 M), but was augmented by chlorimipramine (10^–5 M) and by unlabelled 5HT (10^–6 M); the acceleration caused by unlabelled 5HT was absent in presence of chlorimipramine (10^–5 M). Both electrical stimulation (4 Hz, 50 mA, 2 min) and high K⁺ (50 mM) induced an overflow of ³H. This overflow was nearly abolished in Ca²⁺-free solution. In presence of chlorimipramine (10^–5 M) both the tritium overflow evoked by electrical stimulation and that evoked by high K⁺ were augmented by metitepin (10^–5 M) and decreased in a concentration dependent manner by unlabelled serotonin (10^–8–10^–6 M); the latter effect was antagonized by metitepin (10^–6 M and 10^–5 M). These experiments suggest that in rabbit hypothalamic slices, the release of ³H-5HT is controlled by a negative feedback mechanism acting via presynaptic serotonin receptors.     

Long-term administration of 1,3-dipropyl-8-sulphophenylxanthine (DPSPX) alters α2-adrenoceptor-mediated effects at the pre- but not at the postjunctional level

The present investigation was undertaken to see whether a long-term inhibition of adenosine receptors —leading to hypertension — interferes with ₂-adrenoceptor-mediated modulation of noradrenaline release. Rat tail arteries were removed from normal and from hypertensive animals obtained by chronic treatment with intraperitoneally infused DPSPX (1,3,-dipropyl-8-sulphophenylxanthine) or orally administered L-NAME (N^G-Nitro-L-arginine methyl ester). To study prejunctional effects, the influence of UK-14,304 (5-bromo-6(imidazoline-2-ylamino)-quinoxaline) and yohimbine on the overflow of tritium evoked by electrical stimulation (100 V; 1 Hz; 2 ms; 5 min) from tissues preloaded with ³H-noradrenaline was analysed. To study postjunctional effects, concentration-response curves to UK-14,304 were determined. In DPSPX-treated rats there was an enhancement of the prejunctional effects of UK-14,304: its EC_30% was reduced from 381 (250; 579) to 85 (73; 99) nmol.l^–1 (n = 5; P<0.05) and its maximal effect — expressed as percent reduction of tritium overflow-increased from 45 ± 5% to 61 ± 5% (n = 6; P < 0.05). In L-NAME-treated rats there was no change in either of these two parameters. At the postjunctional level, there was no change in the sensitivity to UK-14,304 in tissues from either DPSPX- or L-NAME-treated rats. Yohimbine (10–1000 nmol.l^–1) caused a concentration-dependent increase of tritium overflow evoked by electrical stimulation in both control and hypertensive animals (either DPSPX- or L-NAME-treated). The EC_50%-pre-antagonist values (concentration of the antagonist that increases the evoked overflow by 50%) were not significantly different in the three situations. We conclude that long-term administration of DPSPX increases the sensitivity to the prejunctional effects of UK-14,304 without changing that to its postjunctional effects, showing a specific interaction between -adrenoceptors and adenosine receptors at a prejunctional level. The question arises whether there is any link between that alteration and the development of the hypertensive state. Correspondence to: S. Guimaraes at the above address