Metabolism of endogenous and exogenous noradrenaline in the rabbit perfused heart

Summary The outflow of noradrenaline, 3,4-dihydroxyphenylglycol (DOPEG) and 3,4-dihydroxymandelic acid (DOMA) from rabbit perfused hearts was studied by chromatography on alumina followed by high pressure liquid chromatography with electrochemical detection. In the absence of drugs and without nerve stimulation, the outflow of endogenous noradrenaline over a period of 108 min averaged 0.17 pmol×g^–1×min^–1 and the outflow of DOPEG 2.1 pmol×g^–1×min^–1. The outflow of DOMA was below the detection limit (<0.13 pmol×g^–1×min^–1). The effect of perfusion with (–)-noradrenaline 0.1, 1 or 10 mol/l for 18 min was then investigated. As the concentration of noradrenaline increased so did the outflow of DOPEG. Moreover, DOMA was found in the venous effluent during and after perfusion with noradrenaline 1 or 10 mol/l. The increase in the outflow of DOPEG and DOMA was almost abolished when cocaine 10 mol/l was present during the perfusion with noradrenaline 1 mol/l. The release of endogenous noradrenaline by sympathetic nerve stimulation or tyramine 10 mol/l, but not the release evoked by nicotine 30 mol/l, was accompanied by an increase in the outflow of DOPEG; an outflow of DOMA was not observed.It is concluded that, in the rabbit perfused heart, DOPEG is an important metabolite of endogenous noradrenaline. DOMA is at best a minor product, either when the neurones are at rest or when noradrenaline is released by sympathetic nerve stimulation, nicotine or tyramine. DOMA is formed in detectable amounts when the tissue is exposed to a high concentration of exogenous noradrenaline. Like DOPEG, it is formed intraneuronally. The results confirm and extend those obtained previously on guinea-pig incubated atria. They make it unlikely that, in these tissues at least, DOMA formation is one of the physiological pathways of noradrenaline catabolism.     

Time-dependent changes in neuronal net uptake of noradrenaline after pretreatment with pargyline and/or reserpine

Summary Isolated rabbit hearts were perfused with 20 to 200 ng/ml of (–)-noradrenaline and arterio-venous differences were determined at various times to measure the rate of net removal of the amine from the perfusion fluid. Animals were untreated or pretreated with reserpine and/or pargyline to block vesicular retention and/or intraneuronal monoamine oxidase (MAO).The arterio-venous difference (in percent of the arterial concentration) remained rather constant during prolonged perfusions of untreated hearts with (–)-noradrenaline, the magnitude of the difference being inversely related to the arterial concentration. After block of MAO the rate of net removal declined exponentially with time; the rate of decline increased with increasing arterial concentration of the amine and also after the additional pretreatment with reserpine. The time-dependent decline in the rate of net removal was shown to be due to an increased efflux of the amine from the nerve endings. The net removal of noradrenaline-H³ at the 5th min of perfusion of pargyline-pretreated hearts was mainly due to neuronal net uptake, since a) O-methylation accounted for only 5% of the removal, and b) cocaine (10–30 (g/ml) virtually abolished net removal.Initial rates of removal were not affected by the various pretreatments.In untreated hearts retention of exogenous (–)-noradrenaline increased linearly with the duration of the perfusion but the increase was exponential after block of MAO. Apparently, the storage capacity becomes exhausted during prolonged perfusions of pargyline-pretreated hearts.The ratio noradrenaline retained by the heart/noradrenaline removed by the heart was quite small in untreated (0.16), very small in reserpine-pretreated (0.03) and nearly unity in pargyline-pretreated hearts.It is concluded that any impairment of the intraneuronal mechanisms of inactivation (vesicular storage and MAO) leads to an increase in the axoplasmic concentration of free noradrenaline which causes an increased efflux of the amine, while the influx remains unchanged. The axoplasmic concentration of free noradrenaline seems to rise more after block of MAO than after pretreatment with reserpine and is most pronounced after both. Changes in the sensitivity of the pacemaker to (–)-noradrenaline were found to be correlated with changes in the rate of removal of the amine from the perfusion fluid.Part of this study was supported by the Deutsche Forschungsgemeinschaft.     

Release of noradrenaline proposed as a mechanism for the positive inotropic action of dipyridamole

Summary In the arterially blood-perfused canine papillary muscle, i.a. injections of dipyridamole (10–300 g) produced a dose-dependent increase in developed tension amounting to about 45% of the basal developed tension at 300 g. The positive inotropic response to dipyridamole was greatly reduced by a prior i.a. injection of propranolol (10 g) or by pretreatment with reserpine (0.2 mg/kg s.c. for 3 consecutive days) but not affected by a prior i.a. injection of tetrodotoxin (1 g) or desmethylimipramine (3–10 g). The positive inotropic response to dipyridamole reduced by pretreatment with reserpine was restored by i.a. infusion of noradrenaline (0.03 g/min). Dipyridamole did not modify the positive inotropic responses to noradrenaline and tyramine. These results suggest that the positive inotropic response to dipyridamole is largely due to noradrenaline released from adrenergic nerve endings by a mechanism that differs from those operative in the action of tyramine or in liberation of noradrenaline upon excitation.     

Evidence for uptake2-mediated O-methylation of noradrenaline in the human amnion FL cell-line

Summary The uptake and metabolism of ³H-noradrenaline has been examined in the FL cell-line derived originally from human amnion. Cell cultures metabolised ³H-noradrenaline (1.0 mol/l) to ³H-normetanephrine and, to a lesser extent, to metabolites (not distinguished) of the O-methylated deaminated fraction; primary deaminated metabolites were not detected. ³(H-normetanephrine formation a) was not saturable in the noradrenaline concentration range 0.2–150 mol/l, b was decreased to 20%–30% of control levels by uptake₂ inhibitors (O-methylisoprenaline, 20 and 100 mol/l; cimetidine, 10 mol/l; hydrocortisone, 200 mol/l) and c, was almost insensitive to uptake₁ inhibitors (cocaine, 30 mol/l; desipramine, 3 mol/l).Uptake of noradrenaline was manifested after 30 minutes as a 6-fold increase in the cell content of the amine following inhibition of catechol-O-methyl transferase, either alone or in conjunction with inhibition of monoamine oxidase. Uptake was decreased maximally to 40% of control levels by O-methylisoprenaline. IC₅₀ values for inhibition of the O-methylisoprenaline-sensitive component of uptake were (in mol/l): corticosterone (0.3), papaverine (1.1), O-methylisoprenaline (3.0), cimetidine (6.0), (–)noradrenaline (460), and tetraethylammonium (2230). Except for the last agent, for which a comparative value is not available, the IC₅₀'s are in good agreement with those for inhibition of uptake₂ in the Caki-1 cell-line reported by other investigators.The component of uptake resistant to O-methylisoprenaline was depressed by papaverine (a 50% decrease at 50 mol/l), but was not affected by the other uptake₂ inhibitors or by cocaine (30 mol/l).It is concluded that the FL cell possesses an extraneuronal metabolising system very similar to the system in tissues such as heart and smooth muscle where transport of noradrenaline into the cell by uptake₂ is followed by rapid O-methylation via catechol-O-methyl transferase. The only difference appears to be the absence of saturation of ³H-normetanephrine formation in the FL cell at low micromolar concentrations of ³H-noradrenaline. The presence of a second uptake process is suggested by the inhibitory effect of papaverine on uptake resistant to O-methylisoprenaline; lack of effect of cocaine implies that this second process is not uptake,.Abbreviations COMT catechol-O-methyl transferase - DOMA dihydroxymandelic acid - DOPEG dihydroxyphenylethylene glycol - MAO monoamine oxidase - NMN normetanephrine - OMDA O-methylated and deaminated metabolite fraction - OMI 3-O-methylisoprenaline - TEA tetraethylammonium Correspondence to I. S. de la Lande at the above address     

Effects of 6-hydroxydopamine treatment at birth on the submaxillary gland of the rat

Summary Six and 18 months after neonatal administration of 6-hydroxydopamine or surgical sympathetic denervation the submaxillary gland of the rat showed a marked depletion of noradrenaline stores. Six months after removal of the superior cervical ganglion the gland's endogenous noradrenaline was lowered to 0.032±0.004 g/g while after neonatal 6-hydroxydopamine the values were 0.228±0.023 g/g (controls 2.145±0.382 g/g). Eightheen months after either type of sympathetic denervation the neurotransmitter was still depleted. In rats treated with 6-hydroxydopamine the sialagogue effect of injected noradrenaline was potentiated 2.7-fold while the potentiation of the effect of noradrenaline was 3.6 times after surgical denervation. The magnitude of the supersensitivity developed to isoprenaline did not differ between both types of denervation. No supersensitivity to the cholinomimetic agent, methacholine, was observed. Cocaine administration or removal of the superior cervical ganglion slightly increased the supersensitivity to noradrenaline in rats treated with 6-hydroxydopamine. Eighteen months after surgical or chemical denervation, the activity of choline-acetyltransferase in the submaxillary gland was increased by about 50%. Of the respiratory enzymes studied, succinic dehydrogenase, fumarase and cytochrome oxidase, the activity of only the latter was markedly reduced by chronic sympathetic denervation. From the results obtained it is concluded that neonatal treatment with 6-hydroxydopamine causes a permanent and almost complete sympathectomy of the submaxillary gland of the rat.Supported partially by grant N⁰ 3211/73, Consejo Nacional de Investigaciones Cientificas y Técnicas.     

The role played by the extraneuronal system in the disposition of noradrenaline and adrenaline in vessels

Summary The role played by extraneuronal sites in the disposition of noradrenaline and adrenaline was studied in the saphenous vein and in the mesenteric artery of the dog, taking as parameters the influence of blockade of these sites on the sensitivity to and on the time for half-relaxation (t ₅₀) (both in oil and in Krebs solution) of these agonists. Preliminary experiments have shown that the t ₅₀ values are not significantly changed by the changes in the height of the contraction provided the contraction is caused by the same concentration of the agonist.The results obtained permit us to conclude that in both vessels the removal of amines depends on the concentrations used. In low (0.023 and 0.23 M) or in moderately high (2.3 M) concentrations, adrenaline is removed preferentially by extraneuronal sites, whereas noradrenaline preferred neuronal sites.The selectivity of adrenaline for extraneuronal sites was present for such low concentrations that a possible physiological role of these sites in the inactivation of circulating adrenaline must be considered.The results obtained by studying the relaxation in oil or in Krebs solution and by using cortexone (60 M) or U-0521 (dihydroxy-2-methyl propiophenone; 0.1 mM) support the view that, at least in the vein, adrenaline may accumulate in extraneuronal cells and diffuse back into the biophase during the relaxation, thereby slowing the latter.Both in the veins and in the arteries noradrenaline was inactivated more rapidly than adrenaline. The difference in the rate of inactivation of these amines, already observed in controls (when all inactivation pathways are operative) became more marked when both neuronal and extraneuronal sites were blocked. The existence of an important pathway not blocked by cocaine + cortexone + iproniazid which may preferentially inactivate noradrenaline cannot be ruled out.This study was supported by a grant from the Instituto de Alta Cultura (PMC-2)Preliminary results were presented at the VI International Congress of Pharmacology (Helsinki, July 1975)     

Different effects of noradrenaline,angiotensin II and BAY K 8644 on the abolition of autoregulation of renal blood flow by verapamil

Summary To examine the role of Ca channels in autoregulation of renal blood flow in response to changes of perfusion pressure, experiments were performed with perfused kidney in anesthetized dogs using a Ca channel activator, BAY K 8644, and vasoconstrictors such as noradrenaline and angiotensin II. Control observations usually showed excellent autoregulation of renal blood flow at pressures between 120 and 200 mm Hg, the autoregulatory index being less than 0.2. Verapamil (50 g/min, i.a. infusion) obviously inhibited the renal autoregulation. Simultaneous infusion of 5 g/min of BAY K 8644 with verapamil prevented both the increase of renal blood flow and the impairment of the autoregulation caused by verapamil. Whereas simultaneous infusion of noradrenaline (1 and 3 g/min) or angiotensin 11 (0.1 and 0.3 g/min) with verapamil dose-dependently reduced renal blood flow, these drugs could not antagonize the inhibitory effect of verapamil on autoregulation. The present experiments show that Ca channels play an important role in establishing renal autoregulation, and that a mere vasoconstriction by noradrenaline and angiotensin II is distinguished from autoregulatory performance.     

Dopamine and adrenaline,but not isoprenaline,are substrates for uptake and metabolism in isolated perfused lungs of rats

Summary The uptake and subsequent metabolism by catechol-O-methyltransferase (COMT) and monoamine oxidase (MAO) of dopamine, adrenaline, isoprenaline and noradrenaline in isolated perfused lungs of rats has been examined. In lung preparations in which COMT and MAO were inhibited, the uptake of ³H-labelled dopamine, (–)-adrenaline and (–)-noradrenaline, but not (±)-isoprenaline, was reduced by cocaine (10 or 100 mol/l) The rank order of the Km values of the amines that were substrates for uptake in the lungs were: dopamine (0.246 mol/l) < noradrenaline (0.967 mol/l) < adrenaline (3.32 mol/l). These results are consistent with transport of catecholamines in rat lungs by Uptake₁.In lung preparations with COMT and MAO intact, dopamine and noradrenaline were removed from the circulation (50% and 32%, respectively) and mainly metabolized. There was very little (3.0%) removal of isoprenaline by the lungs and adrenaline was not included in this part of the study. In lung preparations in which only MAO was inhibited, the rank order of COMT activity for O-methylation of the amines was dopamine noradrenaline adrenaline (k_COMT values: 4.98 min^–1, 0.357 min^–1, and 0.234 min^–1, respectively).If dopamine or adrenaline are perfused through the pulmonary circulation in isolated lungs of the rat, they are taken up and then metabolized by COMT and MAO, as also occurs for noradrenaline. Isoprenaline is not a substrate for uptake in the lungs. There was less uptake of adrenaline than noradrenaline, indicating that uptake and metabolism in the lungs may not be a significant removal process for adrenaline in the circulation of rats in vivo. The more marked uptake of dopamine (than of noradrenaline) indicates that uptake and metabolism by the lungs, at least in the rat, may play an important role in the removal of dopamine from the circulation in vivo.Abbreviations COMT catechol-O-methyltransferase - DOMA 3,4-dihydroxymandelic acid - DOPAC 3,4-dihydroxyphenylacetic acid - DOPEG 3,4-dihydroxyphenylglycol - DOPET 3,4-dihydroxyphenyl ethanol - MAO monoamine oxidase - MN metanephrine - MTA 3-methoxytyramine - NMN normetanephrine - OMDA O-methylated deaminated metabolites - OMI 3-O-methylisoprenaline - U-0521 3,4-dihydroxy-2-methylpropiophenone Some of the results of this study were presented to the Australasian Society of Clinical and Experimental Pharmacologists (Bryan and O'Donnell 1987, 1988; Bryan et al. 1989; Bryan-Lluka 1990) Send offprint requests to L.J. Bryan-Lluka at the above address     

Release of vesicular noradrenaline in the rat tail artery induced by cocaine

Summary The effects of cocaine on overflows of endogenous noradrenaline and DOPEG from isolated rat tail arteries were examined. 1. Both overflows increased progressively with increasing concentration of cocaine, while the (NA overflow)/(DOPEG overflow) ratio first increased and then decreased. The changes in the overflows induced by cocaine (0.1 mmol/l) appeared reversible. 2. Exposure of the tissue for 30 min to cocaine, 1 mmol/l, resulted in a significant decrease in the proportion of storage vesicles containing electron-dense cores. 3. The changes in overflows of noradrenaline and DOPEG induced by cocaine (0.1 mmol/l) were unaffected by the presence of desipramine (0.1 mol/l) or removal of extracellular Ca²⁺. The effect of cocaine on the overflow of noradrenaline was potentiated by prior inhibition of MAO with clorgyline. 4. Exposure of segments to a Ca²⁺-free, high K, low Na incubation medium was accompanied by increased overflow of noradrenaline. Cocaine (0.1 mmol/l) reduced the overflow of noradrenaline to about a half, and substantially increased the overflow of DOPEG. 5. The increase in the overflow of DOPEG from segments bathed in HEPES-buffered solutions, the pH of which ranged from 6.80 to 7.38, was approximately proportional to the calculated concentration of unprotonated (uncharged) cocaine. 6. Quantitatively similar changes in the overflows were observed when norcocaine was substituted for cocaine. Ecgonine methyl ester was much less potent than cocaine, and O-benzoyl ecgonine was ineffective. 7. The small increases in the overflow of noradrenaline observed at relatively low concentration (<30 mol/l) of cocaine can be attributed primarily to inhibition of reuptake of the released transmitter by the cocaine- and desipramine-sensitive amine carrier. The overflows of NA and DOPEG in the presence of higher concentrations of the alkaloid exhibit features compatible with the following hypothesis: (A) Cocaine is translocated across the axonal membrane mainly in the form of the unprotonated species, a large fraction of which is reprotonated upon the entry into the axon. (B) Cocaine releases noradrenaline from storage vesicles into the extravesicular space, where the bulk of the amine is converted to DOPEG. (C) Efflux of the remaining noradrenaline from the axon is not mediated by the Na⁺-dependent, cocaine- and desipramine-sensitive neuronal amine carrier. It seems to represent uncoupled efflux of the protonated form of noradrenaline.Abbreviations DOPEG 3,4-dihydroxyphenylethylene glycol - DOMA 3,4-dihydroxymandelic acid - HEPES N-(2-hydroxyethyl)piperazine-N-ethanesulfonic acid - MAO monoamine oxidase - MOPEG 3-methoxy-4-hydroxyphenylethylene glycol - NA (–)noradrenaline - pH_j pH in the extravesicular space of the axon - pH_o pH of the bathing solution - pK_a negative logarithm of the dissociation constant This study was supported by the British Columbia Heart Foundation Send of fprint requests to V. Palaty at the above address     

Protection of presynaptic α-adrenoceptors against irreversible blockade by phenoxybenzamine: preservation of the modulatory effects of exogenous noradrenaline and yohimbine

Summary 1. Receptor protection experiments were carried out in order to study the site of action of -adrenoceptor agonists and antagonists on the release of noradrenaline. Cerebrocortical slices from rabbits were preincubated with ³H-noradrenaline. They were then superfused with medium containing cocaine 30 mol/l and stimulated electrically (3 Hz) three times, after 60, 250 and 295 min of superfusion (S₁, S₂, S₃). Phenoxybenzamine 10 mol/1 when used, was added between S₁ and S₂ for 30 min; putative protecting drugs (clonidine 100 mol/1 or yohimbine 10 mol/1) were present 5 min before and during the exposure to phenoxybenzamine and then washed out together with the latter. Either the voltage drop between the electrodes at S₂ and S₃ or the Ca²⁺-concentration of the superfusion medium at S₂ and S₃ was diminished, if necessary, in order to bring the overflow evoked by S₂ close to the overflow at S₁. Blockade by phenoxybenzamine, or protection against the blockade, was examined by addition of the test compounds noradrenaline 0.1 mol/1 or yohimbine 1 mol/1 before S₃. 2. In slices not exposed previously to -adrenoceptor ligands, noradrenaline 0.1mol/1 greatly reduced, whereas yohimbine 1 mol/1 greatly increased the evoked overflow of tritium. Both effects were abolished in slices treated with phenoxybenzamine 10 pmol/1 alone between S₁ and S₂. 3. In contrast to phenoxybenzamine alone, exposure to phenoxybenzamine 10 mol/1 in the presence of either clonidine 100 pmol/1 or yohimbine 10 mol/1 failed to abolish the effects of the test compounds noradrenaline 0.1 mol/1 and yohimbine 1 mol/1, although the effects were reduced. 4. It is concluded that the irreversible antagonist phenoxybenzamine, the protecting agents clonidine and yohimbine, the test compounds noradrenaline and yohimbine, and by inference endogenous noradrenaline as well, all act at the same site, namely the presynaptic -autoreceptor. Send offprint requests to K. Starke at the above address     

Accumulation of 3H-(±)-noradrenaline by isolated rat liver cells

Summary Using hepatocytes isolated by collagenase perfusion, we studied the accumulation of ³-noradrenaline. Cells incubated during 15 min in the presence of 0.4 mol/l ³H-noradrenaline (without inhibition of noradrenaline metabolism) accumulated 8.32 ± 1.77 pmol/10⁶ cells (n = 3). The accumulation of ³H-noradrenaline in isolated parenchymal liver cells was sensitive to 10 mol/l cocaine (inhibition 36.6 ± 7.9%, n = 3) and 1 mol/l desipramine (inhibition 27.2 ± 6.9, n = 3). Accumulation of ³H-noradrenaline was temperature and sodium dependent (inhibition 33.2 ± 9.4%, n = 9, when Na⁺ was replaced by Tris⁺) and was influenced by the inhibition of the membrane Na⁺-K⁺-adenosine triphosphatase (Na⁺-K⁺-ATPase) by 150 mol/l ouabain (34.7 ± 6.9% inhibition, n = 3). Accumulation of 3H-noradrenaline in the hepatocytes was not affected by the presence of uptake₂ inhibitors, normetanephrine (30 mol/l) and corticosterone (30 mol/l), but was reduced by 30 mol/l isoprenaline (76.3 ± 5.0% inhibition, n = 6). Thus, the system that takes up and accumulates noradrenaline in the isolated rat liver cells possesses some characteristics of both, uptake₁ and uptake₂ systems and appears to be different from other extraneuronal cocaine-sensitive systems, such as the one reported for pulmonary endothelial cells. Send offprint request to M. I. Masana at the above address     

Selective inhibition by amezinium of intraneuronal monoamine oxidase

Summary Intra- and extraneuronal compartments of rat hearts were selectively labelled by perfusion with ³H-noradrenaline in the presence of corticosterone 87 M or cocaine 30 M, respectively. The subsequent outflow of ³H-compounds was examined. As little as 1 nM amezinium diminished the outflow of intraneuronally formed ³H-DOPEG. This effect was antagonized by cocaine. Amezinium 1 M was necessary to diminish the outflow of extraneuronally formed ³H-DOPEG. This effect was not counteracted by corticosterone. The results indicate that amezinium is both a potent and, at low concentrations, selective inhibitor of intraneuronal MAO.Abbreviations used DOMA 3,4-dihydroxymandelic acid - DOPEG 3,4-dihydroxyphenylglycol - MAO monoamine oxidase (EC 1.4.3.4) - NA noradrenaline - NMN normetanephrine - OMDA O-methylated deaminated metabolites     

Nicotine receptors do not modulate the 3H-Noradrenaline release from the isolated rat heart evoked by sympathetic nerve stimulation

Summary Isolated rat hearts with the right sympathetic nerves attached were perfused at a constant flow rate of 7 ml/min with Tyrode's solution. (-)-³H-Noradrenaline (final concentration 10–13.9 nM) was infused for 10 min to label the noradrenaline stores. After wash-out the sympathetic nerves were stimulated electrically (3 Hz, 180 impulses, 1 ms, 20–30 mA) three times (S1–S3) at intervals of 15 min. ³H-Noradrenaline and its metabolites were determined by liquid scintillation counting according to Graefe et al. (1973).Both, nicotine 50 M and p-aminophenethyltrimethylammonium (PAPETA) 30 M, enhanced the ³H-noradrenaline overflow in the absence of nerve stimulation. The effect of PAPETA was biphasic and was still observed in the presence of N-methylatropine 0.1 M. Hexamethonium 10 M abolished the first phase only, but cocaine 10 M antagonized both phases.The decline of the stimulation-evoked overflow of ³H-noradrenaline from the first to the third stimulation period was similar in the absence and in the presence of cocaine 10 M starting before S1 and perfused throughout. Cocaine 10 M added before S2, however, enhanced the evoked overflow by 77%.PAPETA 30 M increased the stimulation-evoked overflow by 67% in the absence, and by 73% of the respective control in the presence, of hexamethonium 10 M. PAPETA 30 M failed to enhance the evoked overflow in the presence of cocaine. Hexamethonium (added before S2) did not modify the effectiveness of nerve stimulation.Nicotine, neither when perfused from 6 min before S2, nor when added to the perfusion fluid simultaneously with the onset of nerve stimulation, caused changes in the ³H-noradrenaline output upon S2.Upon stimulation a rather discrete increase in ³H-DOPEG overflow was observed. This increase was abolished by cocaine and/or PAPETA.It is concluded that nicotine and PAPETA stimulate the output of ³H-noradrenaline from the rat heart sympathetic nerves by activation of nicotine receptors. However, the amount of transmitter released is small. Neither drug appeared to modulate the output of ³H-noradrenaline upon electrical nerve stimulation via nicotine receptors.PAPETA, like cocaine, appears to block the reuptake of released transmittsrs thereby enhancing the ³H-noradrenaline overflow and reducing the overflow of ³H-DOPEG (formed intraneuronally from recaptured noradrenaline after nerve stimulation).Abbreviations used DOMA 3,4-dihydroxymandelic acid - DOPEG 3,4-dihydroxyphenylglycol - MOPEG 3-methoxy-4-hydroxy-phenylglycol - NA noradrenaline - NMN normetanephrine - OMDA O-methylated deaminated metabolites (sum of MOPEG and VMA) - PAPETA p-aminophenethyltrimethylammonium - VMA 3-methoxy-4-hydroxymandelic acid     

Electrically-evoked release of taurine in the rat vas deferens: evidence for a purinoceptor-mediated effect

Release of taurine evoked by electrical stimulation (2700 pulses; 5 Hz; 10 mA unless stated otherwise) and its dependence on noradrenaline and ATP was studied in isolated, perifused rat vas deferens. Outflow of noradrenaline was also measured in some experiments.The basal outflow of taurine averaged 3.90±0.32 nmol/g tissue per min. Electrical stimulation increased the outflow to about 4 times basal values. The electrically-evoked overflow averaged 128.0±11.7 nmol/ g. An increase in current strength to 40 mA increased the evoked overflow by about 50%. At either current strength, the evoked overflow of taurine (and noradrenaline) was abolished by tetrodotoxin. Ca²⁺-deprivation blocked the overflow of taurine elicited by 10 mA and increased the overflow elicited by 40 mA pulses (but abolished noradrenaline overflow under either condition). Neither prazosin nor pretreatment of the rats with reserpine reduced electrically-evoked overflow of taurine (although reserpine pretreatment abolished evoked noradrenaline overflow). Tyramine (100 mol/1; 9 min) caused an overflow of taurine 36% of that caused by electrical stimulation (but an overflow of noradrenaline 3 times higher than that evoked by electrical stimulation). Exogenous noradrenaline (9 min) caused a concentration-dependent overflow of taurine with a maximal effect at 162 mol/1, amounting to 33% of the electrically-evoked overflow. ,\-Methylene ATP (19 mol/1) elicited an overflow of taurine that faded despite continued exposure to the drug and amounted to 62% of the response to electrical stimulation. Thirty minutes after the start of application of , \.-methylene ATP, electrically-evoked overflow of taurine was greatly reduced. Suramin (100 mol/1) also reduced taurine overflow in response to electrical stimulation.It is concluded that electrical (neural) stimulation releases taurine in rat vas deferens. The release is mainly postjunctional in origin, secondary to ATP release from sympathetic axon terminals, and a consequence of postjunctional P_2x-purinoceptor activation.     

Conclusive evidence for distinct transporters for 5-hydroxytryptamine and noradrenaline in pulmonary endothelial cells of the rat

The aims of this study were to obtain conclusive evidence about the roles of a 5-hydroxytryptamine [5-HT] transporter and uptake, in the dissipation of 5-HT in the lungs of the rat and to compare the properties of the 5-HT transporter in rat lungs with that in other tissues, including brain and platelets. In the first part of the study, the IC₅₀ values of a range of selective inhibitors and substrates of the 5-HT transporter or uptake₁ were determined for inhibition of uptake of 5-HT or noradrenaline in intact perfused lungs of rats. Monoamine oxidase was inhibited and, in experiments with noradrenaline, catechol-O-methyltransferase was also inhibited. Initial rates of uptake of 5-HT or noradrenaline were measured in lungs perfused with 2 nmol/l ³H-5-HT or ³H-noradrenaline for 2 min, in the absence or presence of at least three concentrations of paroxetine, citalopram, fluoxetine, 7-methyltryptamine, tryptamine, nisoxetine, imipramine, 5-HT, desipramine, (+)-oxaprotiline, cocaine or tyramine. The results showed that pharmacologically distinct transporters are involved in the uptake of 5-HT and noradrenaline in rat lungs, since there was no significant correlation between the IC₅₀ values for inhibition of 5-HT and noradrenaline uptake in the lungs. However, there were significant correlations between the IC₅₀ values for (a) inhibition of 5-HT uptake in rat lungs and of uptake by the 5-HT transporter in rat brain and (b) inhibition of noradrenaline uptake₁ in rat lungs and of uptake, in rat phaeochromocytoma PC-12 cells. The results support the conclusion that 5-HT uptake in rat lungs occurs, at least predominantly, by a 5-HT transporter which is very similar to or the same as that in other tissues, such as the brain, and provide further evidence for transport of noradrenaline by uptake₁.Further experiments were carried out to determine whether there is any transport of 5-HT by uptake₁ or of noradrenaline by the 5-HT transporter in rat lungs. Lungs were perfused with 2 nmol/1 ³H-5-HT or ³H-noradrenaline for 2 min in the absence or presence of 1 mol/l citalopram, desipramine, or citalopram and desipramine. The results showed that there was no evidence of any transport of 5-HT in the lungs by uptake₁ or of noradrenaline by the 5-HT transporter, in that desipramine had no effect on 5-HT uptake (in the absence or presence of citalopram) and citalopram had no effect on noradrenaline uptake (in the absence or presence of desipramine).The final series of experiments was carried out to determine whether, at high concentrations of the amine, there is any interaction of 5-HT with uptake₁ or of noradrenaline with the 5-HT transporter. Noradrenaline, at a concentration of 10 mol/l, did not affect 5-HT uptake in lungs perfused with 2 nmol/l ³H-5-HT for 2 min (uptake₁ inhibited), but 50 mol/l 5-HT inhibited noradrenaline uptake by 56% in lungs perfused with 2 nmol/l ³H-noradrenaline for 2 min (5HT transporter inhibited). These and the above results show that the 5-HT transporter appears to be exclusively responsible for 5-HT uptake in rat lungs, despite the possible interaction of 5-HT at high concentrations with the uptake, transporter in the cells. On the other hand, noradrenaline is transported exclusively by uptake₁ in the lungs, and there is no evidence that it interacts with the 5-HT transporter, even at high concentrations.Preliminary results of this study were presented to the December 1993 meeting of the Australasian Society of Clinical and Experimental Pharmacologists and Toxicologists (Paczkowski and Bryan-Lluka 1993).     

Cocaine-sensitive O-methylation of noradrenaline in dental pulp of the rabbit: Comparison with the rabbit ear artery

Summary Incisor pulp from the rabbit metabolises exogenous noradrenaline in concentrations between 0.12 and 1.2 mol/l mainly to NMN.Effects of chronic sympathetic denervation indicated that in incisor pulp the NMN is extraneuronal in origin, and that DOPEG and DOMA formation, as well as a major part of the noradrenaline which accumulates in the tissue, are associated with the sympathetic nerves.NMN formation was unaffected by hydrocortisone 210 mol/l, but was strongly inhibited by cocaine 30 mol/l. These effects contrasted with those in the rabbit ear artery, where NMN formation was increased by cocaine 30 mol/l and decreased by hydrocortisone 210 mol/l.In COMT-inhibited denervated pulp, cocaine inhibited the accumulation of noradrenaline.Monoamine fluorescence histochemistry of pulp exposed to noradrenaline 50 mol/l indicated that cocaine-sensitive uptake occurred in fibroblasts.It is concluded that O-methylation of noradrenaline in dental pulp involves prior uptake of the amine by a process resembling uptake, but which is distinguished from uptake₁ by its extraneuronal location.Abbreviations DOMA 3,4-dihydroxy mandelic acid - DOPEG 3,4-dihydroxyphenylethyleneglycol - NMN normetanephrine - OMDA O-methyl deaminated metabolite fraction, comprising vanillyl-mandelic acid (VMA) plus the 3-methoxy derivative of DOPEG (MOPEG) - MAO monoamine oxidase - COMT catecholO-methyl transferase Send offprint requests to I. S. de la Lande at the above address     

Influence of cooling on the responsiveness of rat isolated anococcygeus muscle to noradrenaline

Summary The isolated anococcygeus muscle of the rat was used to study the effect of temperature on noradrenaline-induced contraction. The preparation was suspended in an organ bath containing Krebs bicarbonate solution for isometric tension recording. A decrease of the bath temperature from 37°C to 20°C (cooling) produced an increase in tissue sensitivity to noradrenaline, as reflected in a 5.37-fold leftward shift in the concentration-response curve, and increased the maximum contractile response to this agonist (14.3%). Cooling had no effect on tissue sensitivity to a selective ₁-adrenoceptor agonist, methoxamine, but increased (12.4%) the maximum contraction to a similar extent to that to noradrenaline. 6-Hydroxydopamine pretreatment or nortriptyline (1 mol/l) induced a leftward shift of the noradrenaline concentration-response curve at 37°C, and profoundly inhibited the potentiating effect of cooling on tissue sensitivity to the catecholamine; the effect of cooling on the maximum response was unaffected. The affinity of noradrenaline or methoxamine for ₁-adrenoceptors at 37°C, determined from its dissociation constant (K _A), was not significantly different from that at 20°C. K _A values were determined by use of irreversible antagonism with phenoxybenzamine. On the other hand, diltiazem at concentration of 3 mol/1, which almost completely abolished the calcium ion-induced contraction of the potassium ion-depolarized muscle, caused only slight inhibition in the concentration-response curve for noradrenaline. The contractile responses to Ca²⁺ of the K⁺-depolarized muscle and of the tissue incubated in Ca²⁺-free (EGTA 0.1 mmol/1) Krebs solution containing diltiazem and noradrenaline were both depressed by cooling. However, the contractile response of the anococcygeus muscle caused by noradrenaline or methoxamine in Ca²⁺-free Krebs solution was augmented at 20°C. At 37°C, vanadate (1 mol/1) also augmented the methoxamine-induced contraction of the tissue incubated in Ca²⁺-free solution. This potentiating effect of vanadate was not observed at 20°C. From these observations, it is concluded that increased responsiveness of the rat anococcygeus muscle to noradrenaline with lowered temperature may involve the inhibition of neuronal uptake mechanism of the catecholamine and the inhibition of removal mechanism of Ca²⁺ which is released from intracellular stores associated with the postsynaptic ₁-adrenoceptors. Send offprint requests to T. Ishii at the above address     

The effects of ageing on neuronal uptake of noradrenaline in the rat

Summary We have examined the effects of ageing on the physiological function of the neuronal noradrenaline uptake system by comparing responses to cocaine in young adult (5 month) and aged (22 month) male Sprague-Dawley rats. In rat atria pre-incubated with [³H]-noradrenaline, cocaine (3–30 mol/l) significantly augmented the 2 Hz stimulation-evoked release of noradrenaline in tissues from young but not from old rats. Cocaine (1 mg/kg) produced a greater increase of the pressor response to noradrenaline in young than in old pithed rats. Cocaine significantly increased the tachycardia to noradrenaline only in young pithed rats, but in old pithed rats the duration of the response to noradrenaline was significantly increased. It is concluded that ageing in the rat is associated with a decreased function of the neuronal noradrenaline uptake system, at least in the cardiovascular system. Send offprint requests to J. R. Docherty at the above address     

The effects of quinpirole and fenoldopam on the potassium-evoked overflow of endogenous dopamine and noradrenaline in dog mesenteric arteries

Summary (1) Dopamine and noradrenaline overflow from the main trunk of the dog mesenteric artery and its proximal branches, elicited by K⁺ (52 mmol/l), was measured by high pressure liquid chromatography with electrochemical detection. (2) Quinpirole (0.1, 1 and 10 nmol/l) produced a concentration dependent reduction of dopamine and noradrenaline overflow in both segments of the mesenteric artery. The inhibitory effect of quinpirole (10 nmol/l) on amine overflow was antagonized by sulpiride (1 mol/l) but not by phentolamine (0.2 mol/l) or the selective dopamine (DA₁), antagonist SK&F 83566 (1 ol/l). (3) Fenoldopam (0.1 and 1 mol/l) did not alter dopamine and noradrenaline overflow from both segments of the mesenteric artery; only 10 mol/l fenoldopam was found to increase the overflow of dopamine and noradrenaline in both segments of the mesenteric artery. This effect of fenoldopam on amine overflow was not altered by the addition to the perifusion fluid of SK&F 83566 (1 ol/l). (4) Clonidine (100 nmol/l) significantly reduced amine overflow from both segments of the mesenteric artery and this effect was antagonized by fenoldopam (10 mol/l) (5) These results suggest that quinpirole inhibits sympathetic neurotransmission through the activation of prejunctional dopamine receptors of the DA₂ subtype. The facilitatory effect of fenoldopam (10 mol/l) on amine release appears to be mediated through the blockade of prejunctional ₂-adrenoceptors. Send offprint requests to P. Soares-da-Silva at the above address     

Dopaminergic modulation of hippocampal noradrenaline release

Summary ³H-Noradrenaline release in the rabbit hippocampus and its possible modulation via presynaptic dopamine receptors was studied. Hippocampal slices were preincubated with ³H-noradrenaline, continuously superfused in the presence of cocaine (30 mol/l) and subjected to electrical field stimulation. The electrically evoked tritium over-flow from the slices was reduced by 0.1 and 1 mol/l dopamine and apomorphine, but significantly enhanced by 10 mol/l apomorphine or by 0.1 and 1 mol/l bromocriptine. If the ₂-adrenoceptor antagonist yohimbine (0.1 mol/l) was present throughout superfusion, the inhibitory effects of dopamine and apomorphine were more pronounced and even 10 mol/l apomorphine and 1 mol/l bromocriptine inhibited noradrenaline release. Qualitatively similar observations were made in the presence of another ₂-antagonist, idazoxane (0.1 mol/l). In the presence of the D2-receptor antagonist domperidone (0.1 mol/l) the inhibitory effects of dopamine were almost abolished, whereas both apomorphine (>1 mol/l) and bromocriptine (>0.01 mol/l) greatly facilitated noradrenaline release. The D2-receptor agonist LY 171555 (0.1 and 1 mol/l) significantly reduced the evoked noradrenaline release whereas the D1-selective agonist SK & F 38393 was ineffective at similar concentrations. The effects of LY 171555 were abolished in the presence of domperidone (0.1 mol/l) but remained unchanged in the presence of yohimbine or idazoxane (0.1 mol/l, each).At 1 mol/l the D2-receptor antagonists domperidone and (-)sulpiride significantly increased the evoked noradrenaline release by about 10%. However, at this concentration, domperidone (but not (-)sulpiride) affected also basal tritium outflow. Bulbocapnine and the preferential D1-receptor antagonists SCH 23390 enhanced the evoked noradrenaline release already at 0.1 mol/l. Their marked facilitatory effects (50 to 60% increase at 1 mol/l) were reduced in the presence of idazoxane (0.1 mol/l) and almost abolished in the presence of 0.1 mol/l yohimbine, whereas the increase due to 1 mol/l (-)sulpiride persisted under these conditions.The evoked tritium efflux from rabbit hippocampal slices preincubated with ³H-serotonin was not affected by dopamine receptor agonists.From our results we conclude that hippocampal noradrenaline, but not serotonin release, is modulated via D2-dopamine receptors. In addition, our results provide evidence for more or less pronounced ₂-adrenoceptor agonistic properties of dopamine and ₂-adrenoceptor antagonistic properties of apomorphine, bromocriptine, SCH 23390 and bulbocapnine in this noradrenaline release model from CNS tissue.