Prazosin and presynaptic alpha-receptors in the cardioaccelerator nerve of the dog.

In vagotomized, spinal-sectioned dogs, prazosin and phentolamine enhanced positive chronotropic responses to cardiac accelerator nerve stimulation. In additional dogs the inhibition by clonidine of heart rate response to continuous accelerator nerve stimulation (presynaptic effect), and the vasopressor effect of clonidine (post-synaptic effect), were antagonized by prazosin, phentolamine and yohimbine; cumulative doses for 50% antagonism of the cardiac chronotropic effect were 103, 50 and 13 microgram/kg i.v., respectively, and those for 50% antagonism of the vasopressor effect were 39, 38 and 3 microgram/kg i.v., respectively. On isolated rabbit pulmonary artery, prazosin antagonized electrically evoked contractions but had no effect on 3H output, whereas yohimbine enhanced both. The results indicate that prazosin, like phentolamine and yohimbine, blocks presynaptic alpha-adrenergic receptors on the cardiac accelerator nerve of the dog but, unlike yohimbine, prazosin does not block these receptors on noradrenergic nerves of rabbit pulmonary artery. It is concluded that the relative activity of a compound at pre- and postsynaptic alpha-receptors is not the same for all organs. The results are discussed relative to the fact that prazosin causes hypotension without significant reflex tachycardia in dog and man.     

Mezilamine, a new dopamine antagonist, blocks presynaptic but stimulates postsynaptic alpha-adrenoceptors.

Mezilamine (2-methylamino-4-N-methylpiperazino-5-methylthio-6-chloropyrimidine), a new antidopaminergic agent, induced a concentration dependent increase in the electrically stimulated overflow of ³-H-noradrenaline from rat cortical slices, without affecting the basal overflow. The mezilamine effect of ³H overflow was antagonized by clonidine. It could not be related to noradrenaline uptake inhibition firstly because mezilamine is a weak inhibitor of noradrenaline uptake and secondly because of the presence in the medium of cocaine, a potent noradrenaline uptake inhibitor. In the same way, mezilamine increased the electrically induced contraction of the rat vas deferens and clonidine reversed this effect. Clonidine and mezilamine induced contractions of the rat anococcygeus muscle. On the contrary, classical neuroleptics such as chlorpromazine or UK 177, another antidopaminergic agent of the same chemical class as mezilamine, antagonized as did yohimbine and phenoxybenzamine the anococcygeus muscle contraction induced by noradrenaline. In the pithed rat, contrary to chlorpromazine and UK 177 which, like yohimbine, antagonizezd the hypertensive effect of clonidine, mezilamine, like clonidine, increased the blood pressure. But, like chlorpromazine and yohimbine, mezilamine reversed the inhibitory effect of clonidine on the electrically stimulated tachycardia. All these results suggested opposite effects of mezilamine on presynaptic and postsynaptic α-adrenoceptors. Mezilamine acts as a presynaptic α-antagonist and a postsynaptic α-agonist.     

Differential control of Ca2+-dependent [3H]noradrenaline release from rat brain slices through presynaptic opiate receptors and alpha-adrenoceptors

The inhibitory actions of the Ca2+ antagonist Cd2+, morphine and noradrenaline (exogenously added + endogenously released) on electrically evoked release of [3H]noradrenaline from superfused rat neocortical slices were strongly reduced when release was enhanced by 4-aminopyridine. In the presence of 4-aminopyridine the release inhibiting effects of these drugs were restored by lowering the extracellular Ca2+ concentration. When release was enhanced by prolonging the pulse duration, only the release inhibiting effect of noradrenaline was reduced but the effects of Cd2+ and morphine were unchanged. Irrespective of the pulse duration, blockade of presynaptic alpha-adrenoceptors with phentolamine did not affect the release inhibiting effects of Cd2+ and morphine. The inhibitory effects of morphine and noradrenaline remained unchanged in Cl--free medium. Furthermore, these drugs strongly reduced the [3H]noradrenaline release induced by 20 mM K+ in the presence of tetrodotoxin. The results suggest that activation of presynaptic opiate-receptors inhibits Ca2+ entry through voltage-sensitive Ca2+ channels, whereas presynaptic alpha-adrenoceptors affect a step in the secretory process subsequent to Ca2+ influx. Moreover, the involvement of (direct) changes in Na+, K+ or Cl- permeability appears unlikely for both receptor systems.     

Presynaptic noradrenergic alpha-receptors and modulation of 3H-noradrenaline release from rat brain synaptosomes.

The depolarization (15 mM K+)-induced release of 3H-NA from superfused rat brain synaptosomes and the effects of alpha-noradrenergic drugs thereon were studied. Noradrenaline (NA; in the presence of the uptake inhibitor desipramine) reduced synaptosomal 3H-NA release. Reduction of the concentration of calcium ions in the medium during K+ stimulation greatly enhanced the sensitivity of 3H-NA release to alpha-receptor-mediated inhibition. Under these conditions NA dose-dependently inhibited 3H-NA release from synaptosomes obtained from cortex or hypothalamus, but did not affect 3H-NA release from striatal (i.e dopaminergic) synaptosomes. Adrenaline, clonidine and oxymetazoline potently inhibited 3H-NA release from cortex synaptosomes at concentrations in the nanomolar range. Phentolamine by itself did not affect synaptosomal 3H-NA release, but antagonized the inhibitory effects of both noradrenaline and adrenaline. The data obtained further substantiate the hypothesis that the alpha-receptors mediating a local negative feedback control of NA release are localized on the varicosities of central noradrenergic neurons, Furthermore, noradrenergic nerve terminals in the hypothalamus appear to be less senstive to alpha-receptor-mediated presynaptic inhibition than those in the cortex.     

The tetracyclic antidepressant mianserin: evaluation of its blockade of presynaptic alpha-adrenoceptors in a self-stimulation model using clonidine

It has been suggested that the tetracyclic antidepressant mianserin may be an antagonist at inhibitory presynaptic alpha-adrenoceptors. If mianserin exerted a selective antagonist effect it should produce effects that are essentially opposite to those of a selective agonist such as clonidine. This hypothesis was investigated in a shuttle-box self-stimulation model previously shown to be sensitive to alpha-adrenergic drugs. In this model a presynaptic alpha-adrenoceptor antagonist would be expected to enhance self-stimulation and to reverse the inhibitory effects of clonidine. Mianserin (2.5-4.0 mg/kg) did not enhance self-stimulation, but instead produced a selective inhibition of reward. Further, mianserin did not reverse the inhibitory effects of clonidine on self-stimulation. These data suggest that if mianserin is an antagonist of the presynaptic alpha-adrenoceptors it is not a selective antagonist. It is possible that the presynaptic alpha-adrenoceptor antagonism may be effects on postsynaptic alpha-adrenoceptors and/or on a presynaptic noradrenaline reuptake mechanism.     

Modulation of noradrenaline release from the sympathetic nerves of human right atrial appendages by presynaptic EP3- and DP-receptors

Strips of human right atrial appendages were preincubated with [³H]noradrenaline and then superfused with physiological salt solution containing inhibitors of uptake₁ and uptake₂. Tritium overflow was evoked by transmural electrical stimulation (standard frequency: 2 Hz). Prostaglandin E₂ (PGE₂) inhibited the electrically evoked tritium overflow; at the highest concentration investigated, tritium overflow was reduced by about 80% and the pIC_50% value was 7.14. The effect of PGE₂ was not affected by rauwolscine, which, by itself, increased the evoked overflow. Naproxen failed to affect the evoked tritium overflow and its inhibition by PGE₂. The inhibitory effect of PGE₂ on the electrically evoked tritium overflow was mimicked by prostaglandin E₁, the EP₁/EP₃-receptor agonist sulprostone and the EP₂/EP₃-receptor agonist misoprostol with the rank order of potency (pEC_50%): sulprostone (7.68) > misoprostol (7.10) > PGE₁ (6.39). In contrast, PGF_2α, the IP/EP₁-receptor agonist iloprost and the stable thromboxane A₂ analogue U46619 (9,11-dideoxy-11α,9α-epoxy-methanoprostaglandin F_2α) did not change evoked tritium overflow. PGD₂ caused facilitation. These results suggest that the sympathetic nerve fibres innervating human atrial appendages are endowed with presynaptic inhibitory EP₃ and facilitatory DP-receptors. The EP₃-receptors appear not to be tonically activated and do not interact with the α₂-autoreceptors. Received: 11 May 1998 / Accepted: 29 July 1998     

Effects of alpha-adrenoceptor agonists and antagonists on pre- and postsynaptically located alpha-adrenoceptors.

The effects of alpha adrenoceptor agonists and antagonists have been examined at pre- and post-synaptically located alpha-adrenoceptors in the pithed rat. The presynaptic receptors were those located at the cardiac sympathetic nerve terminals and the postsynaptic receptors were those present in vascular smooth muscle. Clonidine was approximately equipotent at pre- and post-synaptic alpha-adrenoceptors, whilst LSD and BAY-1470 were more active at the pre- than at post-synaptic sites. Oxymetazoline, naphazoline, methoxamine and phenylephrine were all much more active at the postsynaptic alpha-adrenoceptors. Phentolamine was the most potent antagonist at both pre- and post-synaptic alpha-adrenoceptors. Piperoxan, yohimbine and tolazoline were about 3-7X less potent than phentolamine at both sites. Thymoxamine was about 10X less potent than phentolamine at postsynaptic alpha-adrenoceptors but about 1000X less active at the presynaptic receptors. The differential actions of both agonsists and antagonists at pre- and post-synaptic alpha-adrenoceptors suggest that the receptors may be of different types.     

Evidence for the presynaptic location of the alpha-adrenoceptors which regulate noradrenaline release in the rat submaxillary gland

Summary Fifteen days after duct ligation, the wet weight of the rat submaxillary gland was reduced to 40% of the contralateral control. Under these experimental conditions, the noradrenaline (NA) content expressed as g/g was 1.2±0.1 in the control glands and 1.9±0.2 in the atrophied glands.The accumulation of ³H-NA in the tissue expressed as Ci/gland, did not differ when the atrophied glands were compared with the corresponding controls. Consequently, the uptake and retention of ³H-NA was not modified by the atrophy of the secretory cells of the gland.The spontaneous efflux of radioactivity from normal and atrophied submaxillary glands prelabelled with ³H-NA was similar. The analysis of the metabolic pattern in both experimental groups revealed that in the spontaneous outflow and also during potassium-induced depolarization, the formation of the O-methylated metabolite, ³H-normetanephrine (NMN) was reduced by more than 50% in the atrophied glands. During depolarization induced by K⁺, a 2-fold increase in the outflow of the deaminated glycol ³H-3,4-dihydroxyphenylglycol (DOPEG) was observed.The effect of phentolamine on the release of radioactivity induced by 60 mM K⁺ in normal and in atrophied submaxillary gland slices prelabelled with ³H-NA was also investigated. In both experimental groups, the fractional release of total radioactivity induced by K⁺ was similar. Phentolamine, 3.1 M, produced a 3-fold increase in the fractional release of radioactivity both in the control and the atrophied glands. These results indicate that the increase of K⁺-induced release of ³H-NA induced by phentolamine was independent of the presence or absence of the postsynaptic structures. It is concluded that phentolamine increases transmitter release by blocking alpha-adrenoceptors located in the noradrenergic nerve endings of the rat submaxillary gland.     

Transmitter release patterns of noradrenergic,dopaminergic and cholinergic axons in rabbit brain slices during short pulse trains,and the operation of presynaptic autoreceptors

Summary Slices of rabbit brain were field-stimulated either by single electrical pulses or by trains of 4 or 8 pulses at 1 or 100 Hz in order to study transmitter release patterns and the autoinhibition of transmitter release. The slices were preincubated with ³H-noradrenaline (cortex), ³H-dopamine (caudate nucleus) or ³H-choline (caudate nucleus).Slices preincubated with ³ H-noradrenaline were superfused with medium containing desipramine 1 gmol/l. The overflow of tritium elicited by single pulses amounted to 0 .19% of the tritium content of the tissue. The overflow elicited by 4 pulses/1 Hz was similar, whereas that elicited by 4 pulses/100 Hz was 5.1-fold higher. Yohimbine 101000 nmol/l increased up to 2.5-fold the overflow evoked by 4 pulses/1 Hz but did not change the overflow evoked by single pulses or 4 pulses/100 Hz. - Slices preincubated with ³ H-dopamine were superfused with medium containing nomifensine 1 mol/l. The overflow of tritium elicited by single pulses was 0.39% of the tritium content of the tissue. The overflow elicited by 4 pulses/1 Hz was 1.3-fold and the overflow elicited by 4 pulses/100 Hz 1.4-fold higher. Domperidone 1–100 nmol/l and sulpiride 10–1000 nmol/1 increased up to 2.4-fold the overflow evoked by 4 pulses/ 1 Hz but increased only slightly the overflow evoked by single pulses or 4 pulses/100 Hz. - Slices preincubated with ³ H-choline were superfused either with physostigmine-free medium or with medium containing physostigmine 1 mol/l. In physostigmine-free medium, atropine did not increase the evoked overflow of tritium at any stimulation condition. In physostigmine-containing medium, the overflow elicited by single pulses was 0.18% of the tritium content of the tissue. The overflow elicited by 8 pulses/1 Hz was 2.0-fold and the overflow elicited by 8 pulses/100 Hz 2.2-fold higher. Atropine 2–200 nmol/1 increased up to 2.4-fold the overflow evoked by 8 pulses/1 Hz but increased only slightly the overflow evoked bysingle pulses or 8 pulses/100 Hz. In physostigmine-free medium, sulpiride 10–1000 nmol/1 did not change the single-pulse-evoked overflow of tritium in the absence but increased it in the presence of nomifensine 1 mol/l.Single pulses elicit a large release of ³H-noradrenaline, ³H-dopamine and ³H-acetylcholine under the conditions of these experiments. Release elicited by single pulses is not subject to autoinhibition except for a small inhibition by spontaneously released transmitter in the case of dopaminergic and cholinergic axons. When 3 or 7 further pulses follow the first one at intervals of 1 s, they elicit much smaller release. At least a great part of the fall is due to autoreceptor mediated inhibition (for 3H-acetylcholine release in the presence of physostigmine only). When 3 or 7 further pulses follow at intervals of 10 ms, they elicit release that is either similar to that evoked by the first pulse (³H-noradrenaline) or much smaller (³H-dopamine, ³H-acetylcholine). However, the fall is not due to stimulation-dependent, auto-receptor-mediated inhibition; autoinhibition does not develop in these short high-frequency trains. Overall, the results are in accord with the autoreceptor theory. They demonstrate the role of autoinhibition in determining the transmitter release patterns of central noradrenergic, dopaminergic and cholinergic neurones. Send offprint requests to N. Limberger at the above address     

Inhibition of somato-sympathetic reflex via peripheral presynaptic alha-adrenoceptors.

In cats anaesthetized with chloralose--urethane (70/100 mg/kg) a somato-sympathetic reflex increase of blood pressure and heart rate was evoked by electrical stimulation of sensory fibres running within the tibial nerve. I.V. injection of 30 microgram/kg of the alpha-adrenoceptor agonist clonidine caused a reflex inhibition in intact and vagotomized animals. In contrast, injection of 2 microgram/kg clonidine into the vertebral artery elicited hypotension but no reflux inhibition. In small doses, phenylephrine which is known from in vitro experiments to prefer the postsynaptic alpha-adrenoceptor, potentiated the reflex increase in blood pressure by an additive effect on the vascular alpha-adrenoceptor, while oxymetazoline and tramazoline, which preferentially activate the presynaptic receptor, were inhibitory. The inhibitory effect of tramazoline on the reflex increase in blood pressure and heart rate was antagonized by the presynaptic alpha-adrenolytic drug yohimbine. The results suggest that peripheral presynaptic alpha-adrenoceptors are responsible for somato-sympathetic reflex inhibition. The importance of peripheral presynaptic alpha-adrenoceptors in the in vivo regulation of blood pressure is discussed.     

Electrically induced release of endogenous noradrenaline and dopamine from brain slices: pseudo-one-pulse stimulation utilized to study presynaptic autoinhibition

Summary Slices of rat hypothalamus (noradrenaline experiments) or rabbit caudate nucleus (dopamine experiments) were prepared, superfused, and field-stimulated using series of monophasic rectangular pulses. Noradrenaline, dopamine and the main dopamine metabolite, dihydroxyphenylacetic acetic acid (DOPAC), were determined using HPLC with electrochemical detection. Electrical stimulation was performed using the following protocols: 1) 4 pulses delivered at 100 Hz; this type of stimulation is referred to as pseudo-one-pulse stimulation (POP); its short duration of only 32 ms does not allow the development of autoinhibition; 2) 2 bursts of 4 pulses at 100 Hz, delivered 1 s apart (2-POP-stimulation); 3) 8 pulses at 1 Hz (dopamine experiments only); 4) 36 pulses at 3 Hz. Noradrenaline experiments. The ₂-adrenoceptor antagonist yohimbine (1 mol/l) did not enhance noradrenaline overflow following POP stimulation, but enhanced the overflow following 2-POP-stimulation by about 50% and that following 36-pulse-stimulation by almost 100%. Dopamine experiments. The D₂-dopamine receptor antagonist sulpiride (3 mol/l) facilitated the overflow of dopamine elicited with 2-POP-stimulation (66%), 8 pulses/1 Hz (92%), and 36 pulses/3 Hz (140%). It did not significantly facilitate the overflow of dopamine following POP-stimulation (19%). The overflow of DOPAC was not, or only slightly, increased by electrical stimulation, and its spontaneous outflow was more than three times higher than that of dopamine. Furthermore, the electrically induced overflow of dopamine did not exceed the outflow of DOPAC at any of the stimulation conditions employed.The results of the present study bear out important claims of the autoreceptor theory and confirm the data obtained in previous experiments using labelled transmitters. Correspondence to E. A. Singer at the above address     

The interaction between prazosin and clonidine at alpha-adrenoceptors in rats and cats.

In pithed rats prazosin (10μg/kg, i.v.) caused a prolonged antagonism of the hypertensive response to clonidine and (?)-noradrenaline, probably due to inhibition of vascular, postsynaptic α-adrenoceptors. The clonidine-induced reduction of the tachycardia evoked in pithed rats by electrical stimulation of cardiac sympathetic nerve fibres was antagonized by piperoxan and less effectively by prazosin, thus suggesting that prazosin displays a modest degree of cardiac presynaptic α-adrenoceptor blocking activity apart from its predominantly postsynaptic affinity. Prazosin (1 mg/kg, i.p.) significantly affected the hypotensive effect of clinidine (2 and 6 μg/kg, i.v.), but not the bradycardia induced by clonidine in pentobarbitone-anaesthetized, normotensive rats. Prazosin proved to be an effective hypotensive drug in anaesthetized cats. This action was peripheral as no central nervous origin could be demonstrated. Prazosin in low doses significantly reduced the central hypotensive effect of clonidine (1 μg/kg), injected into the left vertebral artery of chloralose-anaesthethized cats. Since the intravenous pretreatment with low doses of prazosin did not alter the central hypotensive response to clonidine, the interaction was likely to have occured within the brain-stem. Presumably, postsynaptic α-adrenoceptors in the brain, similarly to those in the periphery are inhibited by prazpsin, thereby preventing the central hypotensive effect of clonidine. It is submitted that clonidine and prazosin should not be combined in antihypertensive therapy in patients.     

Effects of α-adrenoceptor agents on norepinephrine release from vas deferens of several species including man

Unlike the situation with the vas deferens of rats, guinea-pigs, rabbits an dogs, neither phentolamine nor yohimbine enhanced electrically-evoked release of [³H]norepinephrine from the in vitro human vas deferens. However, clonidine produced, by a phentolamine-sensitive mechanism, a concentration-related inhibition of release inthe human vas deferens. The results indicate that, even though presynaptic α-adrenoceptors exist, a negative feedback regulation of release by norepinephrine, which occurs in the vas deferens of the other species, may not be functionally important in the vas deferens of the human.     

Inhibitory presynaptic imidazoline receptors on sympathetic nerves in the rabbit aorta differ from I1- and I2-imidazoline binding sites

The involvement of imidazoline receptors in modulation of noradrenaline release was investigated in the rabbit aorta preincubated with [³H]noradrenaline and superfused with physiological salt solution containing cocaine, corticosterone and propranolol.After blockade of ₂-autoreceptors by rauwolscine, the electrically evoked tritium overflow was inhibited by various imidazolines and guanidines. The rank order of potency was BDF 7579 (4-chloro-2-isoindolinyl) guanidine) BDF 6143 (4-chloro-2-(2-imidazolin-2-ylamino)-isoindoline] > BDF 6100 [2-(2-imidazolin2-y-lamino)-isoindoline] > clonidine > ST587 (2-(2-chloro-5-trifluoromethylphenylimino) imidazolidine nitrate) cirazoline > tolazoline > idazoxan > phentolamine. Comparison of the potencies of these drugs with those previously found for the presynaptic imidazoline receptors in the rabbit pulmonary artery revealed a very good correlation. In contrast, no positive correlation was found with their affinities for the I₁-and I₂-imidazoline binding sites in bovine adrenal medullary membranes and with their lipophilicity (log P values). The electrically evoked tritium overflow was also inhibited by the recently identified endogenous imidazoline receptor ligand agmatine, but was not affected by amiloride. In further series of experiments, the ability of putative antagonist at presynaptic imidazoline receptors to counteract the inhibitory effect of imidazoline derivatives was determined. Amiloride, imidazole-4-acetic acid and 1-benzylimidazole did not attenuate the inhibitory effect of BDF 6143 on the electrically evoked tritium overflow. In contrast, rauwolscine antagonized the inhibitory effect of various imidazolines; rauwolscine was clearly less potent in antagonizing the effect of clonidine, BDF 6143 and cirazoline (apparent pA₂ 6.48–7.32) than in antagonizing that of oxymetazoline and moxonidine (apparent pA₂ 8.33 and 8.12, respectively). In a final series of experiments, BDF 6143 (under the conditions applied a selective agonist at presynaptic imidazoline receptors) proved to be considerably less potent in inhibiting tritium overflow evoked by high K⁺ than by electrical stimulation, whereas moxonidine (in rabbit aorta a selective agonist at presynaptic ₂-adrenoceptors) exhibited similar potency in inhibiting the overflow evoked by both methods of stimulation.It is concluded that noradrenaline release in the rabbit aorta is inhibited via both ₂-autoceptors and presynaptic imidazoline receptors which can be activated by the endogenous imidazoline receptor ligand agmatine. The occurrence of such an ₂-adrenoceptor-independent mechanism is compatible with the ability of K⁺ ions to attenuate the inhibitory effect of an imidazoline receptor agonist but not of an ₂-adrenoceptor agonist, since susceptibility to K⁺ ions has been suggested to be a typical feature of imidazoline recognition sites. The presynaptic imidazoline receptor in rabbit aorta appears to be identical with the previously characterized presynaptic imidazoline receptor in rabbit pulmonary artery, but differs clearly from the I₁ and I₂ binding sites in the bovine adrenal medulla.     

Activation of presynaptic alpha-noradrenaline receptors in rat brain by the potent dopamine-mimetic N,N-dipropyl-5,6-ADTN

Rat cerebral cortex slices labeled with 3H-noradrenaline (NA) were superfused and 3H-NA release was induced with 20 mM K+. The release of 3H-NA was not affected by DA (1 micro M), but was inhibited by the 2-aminotetralins, 5,6-ADTN and N,N-dipropyl-5,6-ADTN (at a concentration of 1 micro M) by about 27% and 65%, respectively. The inhibitory effect of N,N-dipropyl-5,6-ADTN was concentration-dependent (3 x 10(-8) to 3 x 10(-7) M) and was antagonized by phentolamine but not by fluphenazine. The data indicate that, in addition to activating dopamine receptors, N,N-dipropyl-5,6-ADTN stimulates presynaptic alpha-NA receptors.     

Depression by neuropeptide Y of noradrenergic inhibitory postsynaptic potentials of locus coeruleus neurones

Summary Intracellular recordings were performed in a pontine slice preparation of the rat brain containing the locus coeruleus (LC). The spontaneous firing of action potentials was prevented by passing continuous hyperpolarizing current via the recording electrode. Focal electrical stimulation evoked a synaptic depolarization (PSP) followed by a hyperpolarization (IPSP). Neuropeptide Y (NPY; 0.1 mol/l) inhibited the IPSP only. Pressure ejection of noradrenaline produced hyperpolarization which was potentiated in the presence of NPY (0.1 mol/l). Hence, NPY appears to inhibit the release of noradrenaline from dendrites or recurrent axon collaterals of LC neurones. Correspondence to: P. Illes at the above address     

Increased noradrenaline release in rat portal vein during sympathetic nerve stimulation due to activation of presynaptic beta-adrenoceptors by noradrenaline and adrenaline.

With the aim of investigating whether exogenous noradrenaline (NA) and adrenaline (A) can modulate transmitter release via the stimulation of presynaptic beta-adrenoceptors, 3H-release from isolated portal veins was studied after pretreatment with 3H-1-NA, phenoxybenzamine, desipramine and normetanephrine. NA (10 muM) and A (0.05 muM) increased the fractional 3H-release elicited by sympathetic nerve stimulation by 30%. This effect could be blocked by d, 1-propranolol which per se reduced the release by 10%. It is concluded that NA can facilitate its own release via a presynaptic beta-adrenoceptor-mediated positive feed-back mechanism and that adrenaline can stimulate this beta-adrenoceptor-mediated mechanism.     

ACTH increases noradrenaline release in the rabbit heart

Summary The effects of ACTH on the release of noradrenaline and the increase of heart rate produced by sympathetic nerve stimulation (1 Hz) were studied in isolated perfused rabbit hearts. ACTH-(1–24) 0.1–100 nmol/l increased the stimulation-evoked overflow of noradrenaline concentration-dependently, reversibly and up to two-fold. The basal outflow of noradrenaline, the basal heart rate and the stimulation-evoked increase in heart rate were not changed. Human ACTH-(1–39) also increased the evoked overflow of noradrenaline. The effect of ACTH-(1–24) 0.3 nmol/l persisted after blockade of -adrenoceptors with propranolol and blockade of neuronal catecholamine uptake by cocaine. ACTH-(1–24) 3 nmol/l did not change the removal of noradrenaline from the perfusion fluid, when hearts were perfused with medium containing 59 nmol/l noradrenaline. The results show that ACTH increases the action potential-evoked release of noradrenaline from cardiac postganglionic sympathetic neurones, probably by activating specific presynaptic ACTH receptors. The high potency of ACTH suggests that these presynaptic receptors may be activated in vivo by circulating ACTH under certain pathophysiological conditions.Send offprint requests to B. Szabo at the above address     

Characterization of alpha-adrenoceptors participating in the central hypotensive and sedative effects of clonidine using yohimbine, rauwolscine and corynanthine

The central alpha-adrenoceptors responsible for mediating the clonidine-induced central hypotension in anaesthetized cats and sedation in mice have been characterized according to their sensitivities to the alpha-adrenoceptor antagonist yohimbine and its two diastereomeric congeners rauwolscine and corynanthine. Yohimbine and rauwolscine (1-10 microgram/kg) dose-dependently antagonized the central hypotensive response to clonidine (1 microgram/kg) applied 15 min later. Greater amounts of corynanthine (30-100 micrograms/kg) had to be administered to diminish the central depressor effect of clonidine. In these studies the drugs were infused via the left vertebral artery. The prolongation of the hexobarbitone-induced loss of the righting reflex in mice by clonidine (0.3 mg/kg, i.p.) was inhibited by previous treatment with yohimbine and rauwolscine (0.04-5 mg/kg, i.p.) in a dose-dependent manner, but not by corynanthine. Binding experiments with rat isolated cerebral membranes demonstrated the higher affinity of yohimbine and rauwolscine for the [3H] clonidine- than for the [3H]prazosin-specific binding sites. The reverse was found for corynanthine. The relative potencies of yohimbine, rauwolscine and corynanthine in inhibiting these central effects of clonidine are comparable to their order of efficacies in blocking peripheral alpha 2-adrenoceptors. Accordingly, clonidine-induced central hypotension and sedation are mediated by alpha 2-adrenoceptors.     

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