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.     

Effect of phentolamine on noradrenaline uptake and release

Summary The influence of phentolamine on the uptake of exogenous noradrenaline infused into the aortic cannula and on the overflow of endogenous noradrenaline caused by sympathetic nerve stimulation was investigated in the isolated perfused rabbit heart. 10^–6 M phentolamine doubled the overflow of endogenous noradrenaline, but did not change noradrenaline uptake. 10^–5 M phentolamine increased the stimulation-induced overflow of noradrenaline 4-fold and inhibited amine uptake by about 50%. 10^–4 M phentolamine elevated the overflow of noradrenaline less than 10^–5 and 3×10^–5 M did. The augmentation of transmitter overflow was only partly reversed by 13 min perfusion with drug-free medium.Pretreatment of hearts with 1.5×10^–5 M cocaine or with 10^–7 or 10^–6 M desipramine did not change the effect of phentolamine on the overflow of noradrenaline evoked by nerve impulses. Pretreatment of hearts with 10^–5 M, but not with 10^–6 M, phentolamine prevented the increase of transmitter overflow by cocaine.It is concluded that low concentrations of phentolamine potentiate the overflow of noradrenaline during nerve stimulation by a mechanism different from that of cocaine, i.e. different from inhibition of neuronal re-uptake. The nature of this mechanism is discussed.This work was supported by the Deutsche Forsehungsgemeinschaft. We have the pleasure to thank Mrs. Ch. Arts, Miss B. Piel and Mr. E. Hagelskamp for skilful technical assistance.     

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.     

Presynaptic α-adrenoceptor blocking properties among tri- and tetra-cyclic antidepressant drugs

1 The effect of various antidepressants (5 × 10^-8 to 2 × 10^-5 M) on the resting overflow of tritium, on the evoked overflow and the contractile response to electrical stimulation (2.5 Hz, 2.0 ms) has been determined in mouse vas deferens previously incubated with [³H]-(—)-noradrenaline.

2 Mianserin and ORG GC 94 produced a concentration-dependent increase of more than two fold in the electrically evoked overflow and the contractile response and, at the highest concentration, slightly increased resting release. These effects were largely unchanged in the presence of a concentration of cocaine effective in blocking noradrenaline uptake (1.1 × 10^-5 M).

3 The ability of phentolamine (1 × 10^-5 M) to increase both the evoked overflow of tritium and the contractile response was greatly reduced when these parameters were already elevated by the presence of mianserin or ORG GC 94.

4 The inhibitory effect of exogenous (—)-noradrenaline on evoked overflow was greatly reduced in the presence of mianserin or ORG GC 94 (4 × 10^-6 M).

5 The inhibitory effect of clonidine on the twitch response of the mouse vas deferens was antagonized by mianserin and ORG GC 94 in a competitive manner (pA₂ values 7.3 and 7.1 respectively).

6 Maprotiline, desipramine and nortriptyline (> 3 × 10^-6 M) produced a parallel fall in both evoked tritium overflow and in the contractile response and increased the resting overflow at higher concentrations. These effects were largely unchanged in the presence of cocaine (1.1 × 10^-5 M).

7 Doxepin, imipramine and iprindole all increased resting overflow at high concentrations (2 × 10^-5 M) but produced only small changes in evoked overflow and in the contractile response at lower concentrations.

8 It is concluded that mianserin and ORG GC 94 produce a blockade of presynaptic α-adrenoceptors which could contribute to an antidepressant effect but that this type of action is not common to all antidepressants.

     

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.     

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     

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.     

Mibefradil- and ω-conotoxin GVIA-induced inhibition of noradrenaline release from the sympathetic nerves of the human heart

Segments of human right atrial appendages preincubated with [3H]noradrenaline and superfused with physiological salt solution containing desipramine and corticosterone were used to determine the effects of mibefradil, ω-conotoxin (ω-CTx) GVIA and nifedipine on tritium overflow evoked by transmural electrical stimulation. Mibefradil (which predominantly blocks T-type, and at lower potency also N-type, Ca²⁺ channels) at concentrations of 0.3–3μM reduced the electrically evoked tritium overflow in a reversible and concentration-dependent manner (IC_50%: 1μM), whereas 0.1–10μM nifedipine (a selective blocker of L-type channels) was ineffective. The evoked tritium overflow was almost abolished by 0.2μM ω-CTx GVIA (a selective blocker of N-type channels). It is concluded that noradrenaline release from cardiac sympathetic nerves is triggered by Ca²⁺-influx via N-type, but not L-type, Ca²⁺ channels and that the inhibitory effect of mibefradil at clinically relevant concentrations on noradrenaline release is probably due to its blocking action on N-type Ca²⁺ channels. This property of mibefradil is unique among the therapeutically applied Ca²⁺ channel blockers and may contribute to the slight negative chronotropic effect of the drug in vivo. Received: 24 September 1997 / Accepted: 3 November 1997     

Opposite modulation of cotransmitter release in guinea-pig vas deferens: increase of noradrenaline and decrease of ATP release by activation of prejunctional β-adrenoceptors

Effects of isoprenaline on contraction, release of noradrenaline and release of ATP elicited by electrical field stimulation (210 pulses, 7 Hz) as well as on contractions elicited by exogenous noradrenaline and ATP were studied in the isolated 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 luciferin-luciferase technique.In [³H]-noradrenaline-pretreated tissues, electrical stimulation elicited an overflow of tritium and ATP and a biphasic contraction. Isoprenaline (1–100 nM) reduced the contraction, mainly phase I, and enhanced the evoked overflow of tritium; evoked overflow of ATP was not changed significantly. No, or almost no, contraction remained in [³H]-noradrenaline-pre-treated tissues exposed to both prazosin (0.3 M) and suramin (300 M), and the evoked overflow of ATP was reduced by about 82%. Under these conditions, isoprenaline (1–100 nM) again enhanced the evoked overflow of tritium, but it now decreased the evoked overflow of ATP. Propranolol (1 M), when added on top of prazosin and suramin, prevented the effects of isoprenaline (1–100 nM). In some tissues not pretreated with [³H]-noradrenaline, purinergic and adrenergic components of the neurogenic contraction (again to 210 pulses, 7 Hz) were isolated by exposure to prazosin (0.3 M) and suramin (300 M), respectively. Isoprenaline (1–100 nM) decreased the isolated purinergic component but did not change significantly the isolated adrenergic component. Contractions elicited by ATP (1000 M) were not changed and contractions elicited by noradrenaline (100 M) were slightly increased by isoprenaline (1–100 nM). Isoprenaline (100 nM) did not change the degradation of ATP (100 M) by pieces of the vas deferens.It is concluded that, in the guinea-pig vas deferens, activation of prejunctional -adrenoceptors modulates the neural release of noradrenaline and ATP in opposite directions: release of noradrenaline is enhanced, whereas release of ATP is decreased.     

Modulation of neural noradrenaline and ATP release by angiotensin II and prostaglandin E2 in guinea-pig vas deferens

Effects of angiotensin II and prostaglandin E₂ on contractions, release of noradrenaline and release of ATP elicited by electrical stimulation (210 pulses, 7 Hz) were studied in the isolated vas deferens of the guinea pig. Release of noradrenaline was assessed as overflow of tritium after preincubation with [³H]-noradrenaline. ATP was measured by means of the luciferin-luciferase technique. In some experiments postsynaptic a ₁-adrenoceptors and P_2X-purinoceptors were blocked by prazosin and suramin, respectively, to isolate the neural fraction of the overflow of ATP.Electrical stimulation elicited an overflow of tritium and ATP and, in the absence of prazosin and suramin, contraction. In the absence of prazosin and suramin, angiotensin II (1–100 nM) enhanced contractions as well as the evoked overflow of tritium and ATP. All parameters were increased by about the same percentage for a given concentration of angiotensin 11. The effect of prostaglandin E₂ (1–100 nM) was complex. Contractions were mainly enhanced, the evoked overflow of tritium was reduced, whereas the evoked overflow of ATP was predominantly increased. No or almost no contraction remained in the presence of prazosin and suramin, and the evoked overflow of ATP was decreased to about 16%. Angiotensin II (1–100 nM) again enhanced the evoked overflow of tritium and ATP. Both were increased by about the same percentage for a given concentration of angiotensin II and also were increased by about the same percentage as obtained in the absence of prazosin and suramin. Prostaglandin E₂ (1–100 nM) decreased the evoked overflow of tritium and ATP in the presence of prazosin and suramin, both by about the same percentage at a given prostaglandin E₂ concentration.It is concluded that neural release of ATP, like the release of noradrenaline, is presynaptically facilitated by angiotensin II and depressed by prostaglandin E₂. In the case of angiotensin II, increases in neural and postsynaptic ATP release contribute to the increase in ATP over flow observed in the absence of prazosin and suramin. In the case of prostaglandin E₂, an increase in postsynaptic ATP release can override the reduction in neural ATP release and give rise to an increase in ATP overflow in the absence of prazosin and suramin. No evidence for a differential modulation of neural noradrenaline versus ATP release was found. Correspondence to: B. Driessen at the above address     

The effect of amitriptyline on presynaptic mechanisms in noradrenergic nerves.

1 Electrically evoked and resting overflow of tritium was measured from mouse vas deferens previously incubated with [3H]-(--)-noradrenaline. 2 At low concentrations (1.6 X 10(-7) to 4 X 10(-6)M) amitriptyline increased only the evoked tritium overfow while higher concentrations increased both evoked and resting overflow. 3 In the presence of atropine (1 X 10(-6 M) amitriptyline still produced an increase in evoked tritium overflow. 4 In the presence of a concentration of cocaine (1.1 X 10(-5) M) which produced a maximal blockade of the uptake of exogenous noradrenaline the application of amitriptyline still produced an increase in evoked tritium overflow. 5 In the presence of a concentration of phentolamine (1 X 10(-5) M) that produced complete blockade of the presynaptic alpha-adrenoceptors, amitriptyline still produced an increase in evoked tritium overflow. 6 In the presence of cocaine and phentolamine together the effect of amitriptyline on evoked overflow was abolished. 7 It is concluded that amitriptyline may raise synaptic levels of noradrenaline by blocking presynaptic alpha-adrenoceptors controlling noradrenaline release and by blocking its uptake into sympathetic neurones.     

Alpha-receptor-mediated modulation of transmitter release from central noradrenergic neurones

Summary Slices of rat cerebral cortex were preincubated with 10^–7 M (-)-³H-noradrenaline, and the outflow of tritium was determined. Oxymetazoline, phentolamine and cocaine did not change the spontaneous efflux. The overflow of tritium evoked by electrical field stimulation was decreased by oxymetazoline, and enhanced by phentolamine, phenoxybenzamine, and cocaine. Oxymetazoline did not counteract the increase of the stimulation-induced overflow caused by cocaine, but strongly antagonized the increase caused by phentolamine and phenoxybenzamine. When the stimulation-induced overflow was large under control conditions (high frequency of stimulation, addition of cocaine), the inhibitory effect of oxymetazoline was diminished. The results indicate that an -receptor-mediated feed-back control of noradrenaline release, previously demonstrated in postganglionic sympathetic nerves, also operates in central noradrenergic neurones.     

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.     

Morphine tolerance and dependence in noradrenaline neurones of the rat cerebral cortex

Summary By subcutaneous implantation of 2 or 13 morphine pellets (75 mg morphine/pellet), rats were made tolerant to, and dependent on narcotic analgesics. Occipital cortex slices from dependent animals and placebo-implanted controls were incubated with (-)-³H-noradrenaline and subsequently superfused with physiological salt solution. The accumulation of ³H-noradrenaline was not changed by pretreatment with 2, but was slightly decreased by pretreatment with 13 morphine pellets. The overflow of tritium evoked by electrical field stimulation was higher in slices from morphine-implanted rats than in those from placebo controls. Morphine and levorphanol, added in vitro, inhibited the stimulation-induced overflow of tritium at, similar concentrations and to a similar degree in slices from morphine-and placebo-pretreated animals. —It is concluded that, during chronic treatment with morphine, an adaptation takes place in the brain to compensate for the acute effect of narcotic analgesics, i.e. inhibition of the release of noradrenaline by nerve impulses. The chain of events from the drug-receptor interaction to the depression of the release process can be excluded as substrate of this adaptation. During with-drawal, the compensatory changes provoke an enhanced increase of extracellular noradrenaline during nerve impulses.     

Pharmacological characterization of the inhibitory effects of neurotensin on the rabbit ileum myenteric plexus preparation.

1 [³H]-amezinium is taken up selectively into noradrenergic axons and their transmitter-storing vesicles and is released from these axons by action potentials. We used it as a non-α-adrenergic marker in order to study the α-adrenergic autoinhibition of noradrenaline release.

2 Rat occipitocortical slices were preincubated with [³H]-amezinium 0.03 μM and then superfused and stimulated electrically (3 Hz for 3 min). The stimulation-evoked overflow of tritium was measured in six groups of slices: from saline-pretreated rats; from saline-pretreated rats, the slices being exposed to exogenous noradrenaline before preincubation with [³H]-amezinium; from saline-treated rats, slices from which were exposed simultaneously to noradrenaline and cocaine before preincubation with [³H]-amezinium; from rats in which noradrenaline stores had been depleted by pretreatment with α-methyltyrosine (α-MT); from α-MT-treated rats, the slices being exposed to noradrenaline before preincubation with [³H]-amezinium; and from α-MT-treated rats, slices from which were exposed to noradrenaline plus cocaine before preincubation with [³H]-amezinium.

3 The stimulation-evoked overflow of tritium, expressed as a percentage of the tritium content of the tissue, was 1.15% in slices from saline-pretreated rats, and was similar in slices from saline-pretreated rats after exposure to noradrenaline or noradrenaline plus cocaine. It was 2.56% in slices from α-MT-treated rats, 1.20% from α-MT-treated rats after exposure to noradrenaline, and 2.88% from α-MT-treated rats after exposure to noradrenaline plus cocaine.

4 Yohimbine 0.1 and 1 μM increased the stimulation-evoked overflow of tritium in slices from all groups of saline-pretreated rats and in those slices from α-MT rats that had been in contact with exogenous noradrenaline. Yohimbine did not change the evoked overflow in slices from α-MT rats that had not been exposed to noradrenaline, or had been exposed to noradrenaline plus cocaine.

5 Clonidine 0.01-1 μM decreased the stimulation-evoked overflow of tritium moderately in slices from saline-pretreated rats, markedly in slices from α-MT-treated rats, and moderately again when the latter slices had been exposed to noradrenaline.

6 It is concluded that the action potential-evoked release of [³H]-amezinium as well as the modulation of this release by yohimbine and clonidine depend on the presence or absence of α-adrenergic autoinhibition caused by the co-secretion of noradrenaline. When there is co-secretion of noradrenaline, the evoked release of [³H]-amezinium is relatively small, yohimbine increases the release, and clonidine can cause only moderate inhibition. When there is no or very little co-secretion of noradrenaline, the evoked release of [³H]-amezinium is at least doubled, yohimbine causes no further increase and clonidine produces strong inhibition.

     

Noradrenaline release from slices of the thalamus of normal and morphine-dependent rats

Summary The effect of morphine on potassium-induced stimulation of (³H)-noradrenaline release from slices of the rat thalamus was investigated. The in vitro addition of morphine (10^–6 M) significantly depressed potassium-induced tritium overflow by 42% and this was prevented by the prior addition of naloxone (3×10^–6 M) to the medium. The stimulation-evoked overflow of tritium from slices of the thalamus of morphine-dependent rats was not significantly different from normal controls. Addition of naloxone (10^–5 M) 10 min before exposure of the tissues to 20 mM K⁺ significantly enhanced noradrenaline release from dependent slices. The results suggest that the basic release mechanism may have adapted to the continuous presynaptic inhibition of release by morphine.     

Adenosine and the endothelium-dependent modulation of 3H-noradrenaline release in the canine pulmonary artery

This study aimed at characterizing the influence of endothelium on noradrenaline release from the canine pulmonary artery. Tritium overflow from intact or endothelium-free vessels preloaded with 0.2 mol.1^{–1 3}H-noradrenaline was evoked by electrical stimulation (1 Hz, during 5 min) or potassium (25–100 mmol. 1^–1).The fractional release of tritium evoked by electrical stimulation was increased by removing the endothelium [from 1.7 (1.2; 2.4) to 2.7(2.3; 3.2) × 10^–5. pulse^–1, n = 10; P < 0.05]. Neither N^G-nitro-l-arginine methyl ester (l-NAME) (up to 300 mol.l^–1) nor indomethacin (up to 30 ml.l^–1), nor endothelin-1 (up to 30 nmol.l^–1), nor suramin (up to 300 mol.l^–1) changed tritium release evolved by electrical stimulation. In contrast, the selective A₁-adenosine antagonist 1,3-dipropyl-8-cyclopentylxanthine (DPCPX) (3.3-33 nmol.l^–1) concentration-dependently increased, and the selective A₁-adenosine agonist N⁶-cyclopentyladenosine (CPA) (3.3–100 nmol. l^–1) concentration-dependently decreased the evoked release of noradrenaline. Since the effects of DPCPX were observed in endothelium-intact tissues only, it may be concluded that adenosine secreted by the endothelium activates prejunctional release-inhibiting A₁-receptors. Tetraethylammonium (TEA) (3.3–33 mmol. l^–1) enhanced tritium overflow evoked by electrical stimulation more in endothelium-free than in endothelium-intact vessels, indicating that some K⁺-channel opener is involved in the inhibitory role of endothelium on noradrenaline release. Since it had been previously shown that A₁-adenosine receptors are coupled to K⁺-channels, it is suggested that adenosine may inhibit noradrenaline release through the opening of K⁺-channels.In conclusion, the results show that in the canine pulmonary artery, adenosine is a good candidate for the endothelium-dependent inhibitory factor which is responsible for the reduction of noradrenaline release evoked by electrical stimulation.     

Corelease of noradrenaline and ATP by brief pulse trains in guinea-pig vas deferens

Contractions and overflow of tritium and ATP elicited by single electrical pulses or short pulse trains were studied in the guinea-pig isolated vas deferens preincubated with [³H]-noradrenaline. ATP was measured using the luciferase technique.A single pulse caused only a small contraction and minimal tritium and ATP overflow. In contrast, trains of 6 pulses elicited marked contractions as well as tritium and ATP overflow. In experiments with 6 pulses/100 Hz, prazosin 0.3 M reduced the contraction by 73 %, did not change the evoked overflow of tritium, and reduced the evoked overflow of ATP by 85%. Suramin 300 M reduced the contraction by 69% but changed neither the evoked overflow of tritium nor that of ATP. The combination of prazosin 0.3 gM and suramin 300 M abolished the contraction, did not change the evoked overflow of tritium, and reduced the evoked overflow of ATP by 70%. When 6 pulses were applied at frequencies of 1, 2, 10 or 100 Hz, all responses increased with frequency up to a maximum at 10 Hz, but contractions and the evoked overflow of ATP increased with frequency to a greater extent than the evoked overflow of tritium. A similar frequency overflow relationship was observed when the medium contained prazosin 0.3 M and suramin 300 M (and evoked ATP overflow was greatly reduced). Yohimbine 1 M did not affect the overflow of tritium evoked by 6 pulses/100 Hz but increased that evoked by 6 pulses/10 Hz.The results demonstrate an overflow of both noradrenaline and ATP in response to short pulse trains. As observed previously for prolonged pulse trains, the major part of the evoked overflow of ATP was derived from non-neural cells. The ATP overflow remaining during ₁-adrenoceptor blockade by prazosin and P₂-purinoceptor blockade by suramin is likely to reflect neural release of ATP. The results support the view that release of ATP increases with frequency to a greater extent than release of noradrenaline. The latency for the onset of prejunctional ₂-autoinhibition in guinea-pig vas deferens is between 50 and 500 ms. Correspondence to: I. von Kügelgen at the above address     

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.     

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