Dissipation mechanisms for 5-hydroxytryptamine in the coronary circulation of the isolated perfused heart of the rat.

1. The contribution of uptake into vascular endothelial cells, of neuronal uptake and of extraneuronal uptake in the dissipation of 5-hydroxytryptamine (5-HT) perfused through the coronary circulation of the rat heart was examined. 2. Hearts from reserpine-pretreated rats were isolated and perfused in vitro with 5-HT, in the absence or presence of inhibitors, and rates of appearance of the deaminated metabolite, 5-hydroxyindoleacetic acid (5-HIAA), in the venous effluent were measured using an h.p.l.c. assay. 3. The steady-state rates of 5-HIAA appearance in the venous effluent in hearts perfused with 1 microM 5-HT (422 +/- 8.48 pmol g-1 min-1, n = 12) were reduced by pretreatment of the rats with 6-hydroxydopamine (22% inhibition), and by inclusion in the perfusion solution of 30 microM cocaine (28% inhibition), 100 microM 3-O-methylisoprenaline (64% inhibition), 100 microM corticosterone (58% inhibition), or 30 microM cocaine and 100 microM 3-O-methylisoprenaline (87% inhibition). 4. The extraneuronal deamination of 5-HT in the heart was saturable (Km = 101 microM, Vmax = 31.2 nmol g-1 min-1). The neuronal deamination of 5-HT was saturated by about 50 fold lower concentrations of 5-HT than was extraneuronal deamination, but Km and Vmax values could not be determined. 5. In the coronary circulation of the rat heart, 5-HT was dissipated by the uptake processes for catecholamines, extraneuronal uptake (predominantly) and neuronal uptake, and subsequent metabolism by monoamine oxidase. There was no evidence that a cocaine-sensitive uptake of 5-HT into vascular endothelial cells made any significant contribution to 5-HT dissipation in the heart.     

The handling of five catecholamines by the extraneuronal O-methylating system of the rat heart

In a comparative study, the handling of five catecholamines by the extraneuronal O-methylating system of the rat heart was determined; all rats were pretreated with reserpine, monoamine oxidase and neuronal uptake were inhibited in all experiments. Hearts were perfused for 7 min with a tracer concentration of 3H-(+/-)-isoprenaline, either in the absence or in the presence of unlabelled catecholamines (which reduced the O-methylation of the tracer amine). IC50's were determined for unlabelled catecholamines and then converted to "half-saturating outside concentrations", i.e., to those concentrations in the perfusion fluid that half-saturate the intracellular catechol-O-methyl transferase (COMT). The values for the (-)-isomers of dobutamine, isoprenaline, adrenaline and noradrenaline and that for dopamine were low and rather similar (between 0.67 and 2.7 mumol/l). Stereoselectivity for isoprenaline probably reflected the preference of uptake2 for the (-)-isomer. The effects of (-)- and (+)-dobutamine indicated that both isomers are a) transported by uptake2 and b) good substrates of COMT. The Vmax for O-methylation [determined for 3H-(+/-)-isoprenaline, 3H-(+/-)-adrenaline, 3H-(+/-)-noradrenaline and 3H-dopamine] was rather similar for all four catecholamines. It is concluded that the extraneuronal O-methylating system of the rat heart handles the five catecholamines in a similar manner, although the Km for uptake2 had been found to increase substantially in the order: dobutamine less than isoprenaline less than adrenaline less than noradrenaline less than dopamine (Grohmann and Trendelenburg 1984b).     

Stereoselectivity of extraneuronal uptake of catecholamines in guinea-pig trachealis smooth muscle cells

The extraneuronal uptake of the (-)- and (+)-isomers of three catecholamines, isoprenaline, adrenaline and noradrenaline, were compared in guinea-pig trachealis smooth muscle cells, by a fluorescence microphotometric method. Preliminary experiments showed that the initial rates of uptake of the (-)-isomers were greater than those of the (+)-isomers in tissues incubated in 25 microM adrenaline or noradrenaline or 50 microM isoprenaline. More detailed experiments showed that the Km values of the (+)-isomers of the amines for extraneuronal uptake were not significantly different from each other, but the Km value of (-)-isoprenaline less than (-)-adrenaline less than (-)-noradrenaline. Thus, the order of the ratios of the Km values for the (+):(-)-isomers was isoprenaline greater than adrenaline greater than noradrenaline. The results showed that there is stereoselectivity of the extraneuronal uptake of catecholamines, but it is greatest for isoprenaline (4.9 fold), less for adrenaline (2.5 fold) and almost negligible (1.6 fold) for noradrenaline.     

The effects of acute reserpine administration on the sensitivity of the isolated pacemaker from rat heart to isoprenaline and noradrenaline

The effects of reserpine on the sensitivity of the isolated pacemaker from rat heart to the chronotropic effect of isoprenaline and noradrenaline were studied. A single large dose of reserpine (2m?5 mg kg^?1) administered to rats 24 h before killing induces supersensitivity of the isolated pacemaker to isoprenaline, leaving unaltered the responsiveness of the pacemaker to noradrenaline. Reserpine at the dose of 1m?0 mg kg^?1 did not alter the sensitivity of the pacemaker to the catecholamines. Only the larger dose of reserpine raised the corticosterone plasma level. It is possible that a corticosterone-mediated inhibition of the extraneuronal uptake process is responsible for the supersensitivity to isoprenaline. Large doses of reserpine should not be used in experiments aimed to study cardiac sensitivity to isoprenaline or extraneuronal uptake and metabolism of the catecholamine.     

Effects of uptake inhibitors on responses of sheep coronary arteries to catecholamines and sympathetic nerve stimulation.

1. Transmural stimulation of intrinsic sympathetic nerves and exogenous catecholamines produce beta 1-adrenoceptor mediated relaxant responses in strips of contracted sheep coronary artery. 2. The neuronal uptake inhibitors, metaraminol, cocaine and desipramine and the extraneuronal uptake inhibitor, cortisol, failed to potentiate responses to noradrenaline or sympathetic stimulation; responses to isoprenaline were enhanced by cortisol. 3. Oxytetracycline, which inhibits binding to connective tissue fibres, did not affect responses to noradrenaline or nerve stimulation. 4. 17 beta-Oestradiol, caffeine and U0521 proved to be unsuitable compounds for studying catecholamine inactivation since they non-selectively potentiated responses to noradrenaline and isoprenaline. 5. It is concluded that catecholamine inactivation processes do not modify transmitter function in sheep coronary arteries.     

The effect of partial inhibition of monoamine oxidase on the steady-state rate of deamination of 3H-catecholamines in two metabolizing systems

Two different "deaminating systems" were compared (i.e., intact tissues in which an uptake process translocates the 3H-catecholamine from the extracellular space to the intracellular MAO): the adrenergic nerve endings of the rat vas deferens exposed to 10 nmol/l 3H-(-)-noradrenaline, and the extraneuronal deaminating system of the rat heart perfused with 50 nmol/l 3H-(-)-adrenaline. Vesicular uptake and COMT were inhibited. In both systems MAO was partially inhibited by pargyline, and the steady-state tissue content of the 3H-catecholamine was determined as well as the steady-state rate of deamination. Rat vas deferens (preincubated with 10-40 nmol/l pargyline for 30 min). Inhibition of neuronal MAO caused not more than a moderate decrease of the steady-state rate of deamination of 3H-(-)-noradrenaline, but the steady-state tissue content was greatly increased. Determinations of the activity of MAO in homogenates of vasa deferentia showed that preincubation with 10 and 20 nmol/l pargyline inhibited the enzyme by 80 to 95%. Rat heart (of animals pretreated with 1 to 30 mg/kg pargyline). Inhibition of extraneuronal MAO caused a steep decline of the steady-state rate of deamination of 3H-(-)-adrenaline, but only a small rise in the steady-state tissue content. The decisive difference between the two deaminating systems lies in the fact that the ratio "kmao/kout" (where the two k-values characterize the activity of the unsaturated intracellular MAO and the ability of the 3H-catecholamine to leave the relevant cells, respectively) is much higher for the neuronal deaminating system exposed to 3H-(-)-noradrenaline than for the extraneuronal deaminating system exposed to 3H-(-)-adrenaline.(ABSTRACT TRUNCATED AT 250 WORDS)     

Temperature-dependent supersensitivity of isolated atria to catecholamines

Experiments with isolated guinea-pig atria show that lowering of temperature from 37 to 27°C induced supersensitivity to noradrenaline, isoprenaline, dopamine and orciprenaline which was not due to impairment of the uptake mechanisms (neuronal or extraneuronal) or to impairment of enzyme activity (catechol-O-methyl transferase or monoamine oxidase). While the reason for the supersensitivity remains to be analysed in detail, the results are inconsistent with the postulate of Muñoz-Ramíres et al. (1973) that an impairment of the activity of catechol-O-methyl transferase is responsible for hypothermia-induced supersensitivity to catecholamines.     

Effects of blockade of extraneuronal uptake on responses to isoprenaline in perfused rat heart

1. Isolated rat hearts accumulated 102 pmol/g wet wt/min of isoprenaline when perfused for 5 min with 0-6 muM (+/-)-3H-isoprenaline. 2. The 3-methoxy derivative of isoprenaline ('methoxy isoprenaline') (10 muM) significantly inhibited this uptake by 57%, metanephrine (10 muM) by 29% and normetanephrine (10 muM) by 21%. 3. (+/-)-Isoprenaline (0-6 muM) infused into isolated perfused rat hearts for 5 min activated glycogen phosphorylase 2-4-fold. Normetanephrine (10 muM) or metanephrine (10 muM included in the perfusate significantly potentiated this activation, but 3-0-methyl isoprenaline (10 muM significantly reduced it. However, 3-0-methyl isoprenaline potentiated the ability of 4-8 muM isoprenaline to stimulate phosphorylase. 4. Neither metanephrine (10 muM) nor normetanephrine (10 muM) altered peak inotropic responses to injections of (+/-)-isoprenaline into the solution perfusing isolated rat hearts. 3-0-methyl isoprenaline (10 muM) shifted the isoprenaline dose-response curve to the right, but did not affect the inotropic responses to CaCl2, confirming that 3-0-methyl isoprenaline possess beta-adrenoceptor antagonist activity. 5. Inotropic responses to isoprenaline were significantly prolonged by both 3-0-methyl isoprenaline and normetanephrine (10 muM). 6. These results indicate that blockade of extraneuronal accumulation of catecholamines causes potentiation of both metabolic and mechanical beta-adrenoceptor-mediated responses of the heart to isoprenaline. It is suggested that Uptake2 and the cardiac beta-adrenoceptor are separate entities, and that the beta-adrenoceptor is localized in the sarcolemma. The physiological function of Uptake2 may be to help clear the sympathetic synaptic gap of liberated neurotransmitter.     

Kinetic constants for uptake and metabolism of 3H-(—)noradrenaline in rabbit aorta

1. The neuronal uptake of 3H-(-)noradrenaline into aortic rings from reserpine-pretreated animals was a saturable process with a Km of 2.3 mumol X l-1 and a Vmax of 0.5 nmol X g-1 X min-1. Similar constants were obtained when the neuronal deamination of noradrenaline was taken as an index for neuronal uptake. When the tissue was incubated in the usual way, i.e., when the amine was allowed to enter the aortic rings via both the intimal and the adventitial surface, then there was no initial delay (tlag) for the neuronal uptake of noradrenaline (MAO and COMT inhibited). On the other hand, when the amine entry was restricted to the intimal surface, there was a tlag of 2 min, probably due to the slow equilibration of the extracellular space of the media with the incubation medium. Furthermore, for low amine concentrations the rate of uptake in the latter situation was about 10 times lower than that in the former one. Thus, the rate of uptake clearly depended on the way the amine entered the tissue. 2. The corticosterone-sensitive extraneural uptake of 3H-(-)noradrenaline determined in nerve-free aortic rings was characterised by a high Km (490 mumol X l-1) and Vmax (35 nmol X g-1 X min-1). For uptake2 a tlag of 1 min was observed. 3. The analysis of the extraneuronal O-methylating system in nerve-free aortic rings yielded a Km of 3.6 mumol X l-1 and a Vmax of 0.6 nmol X g-1 X min-1. The tlag for the O-methylation of noradrenaline was in the same order of magnitude as that for uptake2. At low amine concentrations the corticosterone-sensitive accumulation of noradrenaline was prevented by COMT, but not by MAO. The latter enzyme reduced the steady-state accumulation of noradrenaline by about 50%. When the amine entry was restricted to one surface only, the results indicated that the extraneuronal O-methylation of noradrenaline generated a steep concentration gradient of the parent amine within the extracellular space of the aorta. 4. All saturable processes fitted the Michaelis-Menten equation. However, kinetic constants determined in incubated organs may be falsified by poor diffusion of the substrate through the extracellular space.     

Influence of thyroid status on responses of rat isolated pulmonary artery, vas deferens and trachea to smooth muscle relaxant drugs.

1 Responses to relaxant drugs have been examined on isolated KCl-contracted smooth muscle preparations from rats in which thyroid status was changed by prior treatment with either thyroxine (T4) for 1 week (preparations of pulmonary artery, trachea and vas deferens) or methimazole for 10-12 weeks (pulmonary artery preparations). 2 On pulmonary artery preparations, T4 treatment caused a significant increase in the magnitude of the relaxant responses to noradrenaline and isoprenaline but not those to adrenaline. The potency of noradrenaline was increased 5.6 fold but that of isoprenaline and adrenaline was unchanged. This resulted in a change in the relative potencies from adrenaline greater than noradrenaline (controls) to noradrenaline = adrenaline (T4-treated). Methimazole treatment caused a significant reduction in the magnitude of the responses to noradrenaline and in its potency (2.8 fold). Isoprenaline and procaterol were unaffected. 3 On pulmonary artery preparations, T4 treatment did not affect the magnitude of the responses to forskolin, sodium nitrite or isobutylmethylxanthine (IBMX) or their potency. In vitro treatment with the monoamine oxidase (MAO) inhibitors, iproniazid or pargyline, did not potentiate responses to either noradrenaline or isoprenaline. Therefore, it was concluded that the T4-induced changes in the magnitude of the responses to noradrenaline and isoprenaline and in the potency of noradrenaline were unlikely to be due to reduced activity of cyclic nucleotide phosphodiesterase(s) or MAO. 4 On preparations of vas deferens and trachea, T4 treatment had no effect on the magnitude of the responses to noradrenaline, isoprenaline, adrenaline or procaterol.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thyroxine treatment of aged or young rats demonstrates that vascular responses mediated by beta-adrenoceptor subtypes can be differentially regulated.

Responses to vascular relaxant drugs were obtained on KCl (15 mM)-contracted isolated ring preparations of pulmonary artery and aorta from young (1-2 months old) and aged (greater than 16 months old) rats. These vessels contain both beta 1- and beta 2-adrenoceptors. Relaxant responses (i.e. relaxation expressed as a % of the KCl-induced contraction) to isoprenaline, procaterol (beta 2-selective partial agonist), fenoterol (beta 2-selective) and noradrenaline (beta 1-selective) but not those of forskolin, 3-isobutyl-1-methylxanthine, enprofylline or sodium nitrite, were smaller on preparations from aged rats than on those from young rats. Thyroxine (T4)-treatment (1 mg kg-1 s.c. thrice weekly for 3-5 weeks) of aged or young rats enhanced responses to isoprenaline and noradrenaline but reduced those to procaterol, when compared with preparations from age-matched saline-treated control rats. The agonist order of potency, determined in young rats, was isoprenaline greater than noradrenaline greater than adrenaline in preparations from T4-treated rats compared with isoprenaline greater than adrenaline greater than noradrenaline in saline-treated control rats. It is concluded (a) that the age-related decline in vascular responses to beta-adrenoceptor agonists involves beta-adrenoceptor mechanisms specifically and possibly beta 2-adrenoceptors more than beta 1-adrenoceptors; and (b) that T4-treatment of rats enhances beta 1-adrenoceptor-mediated and reduces, or does not change, beta 2-adrenoceptor-mediated responses of preparations of rat pulmonary artery and aorta. In preparations from control rats beta 2-adrenoceptors were functionally predominant but in preparations from T4-treated rats beta 1-adrenoceptors appeared to become functionally predominant.     

Mechanisms of inactivation of noradrenaline in the iris sphincter, tracheal muscle and facial artery of cattle: Implications for β-adrenoceptor-mediated responses

1 The role of neuronal and extraneuronal pathways of amine inactivation in regulating the inhibitory actions of noradrenaline was investigated in three bovine smooth muscle preparations in which the primary adrenoceptor is of the β-type.

2 The extraneuronal uptake inhibitor, 17β-oestradiol, sensitized the inhibitory responses to noradrenaline in the facial artery, the iris sphincter and in tracheal muscle preparations, indicating a major role for non-neuronal processes in agonist-inactivation in all three preparations. Cocaine also increased responses to noradrenaline, pointing to a role for neuronal uptake either as a terminating mechanism or as a process limiting access of exogenous agonist molecules to their site of action.

3 Cocaine did not enhance significantly responses to isoprenaline, a potent β-adrenoceptor agonist which is not taken up neuronally. Further, relaxations to metaraminol, a sympathomimetic amine which is taken up extraneuronally, but much less so than noradrenaline, were also less enhanced by 17β-oestradiol in the three preparations tested. These findings support the specificity of action of cocaine and 17β-oestradiol as neuronal and extraneuronal uptake inhibitors in the present experiments.

4 Studies of the uptake of [³H]-noradrenaline revealed that 17β-oestradiol reduced the uptake of amine in the presence of cocaine, confirming a cocaine-resistant site of action for the steroid in all three preparations.

5 It is concluded that extraneuronal uptake sites are located sufficiently close to the β-adrenoceptors to modulate the concentration and duration of action of noradrenaline at these sites of action. It is proposed that in smooth muscles which contain a preponderance of β-receptors, extraneuronal metabolism is a key event in terminating the inhibitory effects produced.

     

The neuronal and extraneuronal uptake and metabolism of 3H-(−)-noradrenaline in the perfused rat heart

1. Hearts were obtained from reserpine-pretreated rats and perfused with 0.95 micron 3H(-)-noradrenaline. The rate of removal of 3H-noradrenaline from the perfusion fluid was measured (from the arterio-venous difference) as well as the rate at which the 3H-metabolites appeared in the venous effluent. 2. When either 30micron corticosterone was added under steady-state conditions during perfusion with 3H-noradrenaline (to inhibit neuronal and extraneuronal uptake, respectively), each inhibitor reduced the removal of noradrenaline by about 50%; in the presence of both inhibitors removal was abolished. 3. Dihydroxymandelic acid (DOMA) was of neuronal, normetanephrine (NMN) of extraneuronal origin; dihydroxyphenylglycol (DOPEG) and the OMDA fraction (containing methoxyhydroxyphenylglycol-MOPEG-and methoxyhydroxymandelic acid-VMA) were formed both neuronally and extra-neuronally. 4. The extraneuronal metabolism of 3H-noradrenaline was in quick equilibrium with the 3H-noradrenaline in the perfusion fluid; most of the total formation of DOPEG, MOPEG and NMN was recovered from the venous effluent. 5. Extraneuronally formed DOPEG, MOPEG and NMN distributed in the tissue with half times corresponding to their half time for efflux. 6. Inhibition of monoamine oxidase (MAO) by pargyline increased the extraneuronal formation of NMN; MAO and catechol-O-methyl transferase (COMT) appear to be contained in the same extraneuronal compartment. 7. The extraneuronal accumulation of 3H-noradrenaline required 30 min or more to reach a steady state; inhibition of one or both enzymes slowed this process. Inhibition of MAO increased the extra-neuronal accumulation of 3H-noradrenaline; inhibition of COMT failed to do so, since the enzyme inhibitor (U-0521) was a weak inhibitor of extra-neuronal uptake. 8. The rate constants for the efflux of the metabolites of noradrenaline decreased in the order of MOPEG greater than DOPEG greater than NMN greater than DOMA greater than VMA.     

Uptake and metabolism of catecholamines in the perfused hearts of different species

1. The uptake of (+/-)-(3)H-noradrenaline was studied in isolated perfused hearts of rat, mouse, guinea-pig, pigeon and toad (Bufo marinus), and the IC50 (concentration causing 50% inhibition) values for inhibition of uptake of (+/-)-(3)H-noradrenaline by (-)-noradrenaline were calculated. IC50 values ranging from 0.28 muM (rat heart) to 2.34 muM (toad heart) were found.2. In all species except the toad, (-)-noradrenaline showed a higher affinity than (-)-adrenaline for the uptake process, but the reverse was found for the toad heart.3. Mouse and pigeon hearts contained increasing amounts of metabolites of noradrenaline with increasing perfusion concentrations of noradrenaline, but the guinea-pig and toad hearts did not. The in vitro activities of noradrenaline catabolizing enzymes in heart homogenates were measured but did not explain the differences in the pattern of catabolism of noradrenaline found in the intact hearts of the different species.4. In all hearts except the toad, cocaine was an effective blocking agent for the uptake of (+/-)-(3)H-noradrenaline and led to an increase in (3)H-normetanephrine in these hearts. In the pigeon heart, cocaine plus phenoxybenzamine in the perfusate resulted in an inhibition of both (3)H-noradrenaline uptake and (3)H-normetanephrine formation.5. In guinea-pig and pigeon perfused hearts, the uptake of (3)H-noradrenaline into atria and ventricles reflected the relative concentrations of endogenous catecholamines in these regions, but this was not found for rat, mouse and toad hearts.6. It was concluded that species differences exist for both the accumulation and metabolism of catecholamines in isolated perfused hearts.     

Errors introduced by a tritium label in position 8 of catecholamines

The neuronal and extraneuronal disposition of 3H-7,8- and 3H-7-labelled (-)-noradrenaline and dopamine was compared in in vitro studies. In agreement with earlier studies, the present results show that the presence of a tritium label in position 8 (i.e., on the alpha-carbon) has two consequences: a) the rate of deamination declines and b) part of the deamination results in the formation of an unlabelled aldehyde plus tritium water; tritium water is recovered from the OMDA-fraction of the column chromatographic procedure of Graefe et al. (1973). Whenever the deamination of a 3H-catecholamine is reduced (by tritium in position 8), the intraneuronal 3H-catecholamine concentration is increased. This increase, in turn, partly masks the decline in neuronal deamination (rat vas deferens). Irrespective of whether one determines the spontaneous efflux, the release of 3H-noradrenaline by nerve stimulation or the release of 3H-(-)-noradrenaline by the reserpine-like compound Ro 4-1284, the presence of tritium in position 8 distorts the results (experiments with rat vasa deferentia and/or rabbit aorta). In the extraneuronal system of the rat heart, two intracellular enzymes inactivate 3H-(-)-noradrenaline and 3H-dopamine: catechol-O-methyl transferase (COMT) and monoamine oxidase (MAO). Any hindrance of deamination (by tritium in position 8, COMT intact) leads to a shift of the metabolism of the 3H-catecholamines from the exclusively deaminated to the exclusively O-methylated metabolites. No differences between 3H-7,8- and 3H-7-labelled catecholamines were found after inhibition of MAO and COMT (extraneuronal accumulation and rate constant for efflux from the extraneuronal compartment III of the rat heart).(ABSTRACT TRUNCATED AT 250 WORDS)     

Lack of differences between the neuronal and extraneuronal handling of 3H-7- and 3H-ring-2,5,6-(−)noradrenaline

The neuronal disposition of the side chain-labelled 3H-7-(-)noradrenaline and the ring-labelled 3H-2,5,6-(-)noradrenaline of relatively high specific activity was compared in the (incubated) rabbit aorta, the extraneuronal one in the (perfused) rat heart. Furthermore, the metabolism by monoamine oxidase (MAO) and catechol-O-methyl transferase (COMT) of the labelled amines was studied in rat heart homogenates. In addition, some of the experiments were also carried out with the side chain-labelled 3H-7,8-(-)noradrenaline that is an inferior substrate of MAO. 1. In agreement with several other studies, the present results revealed the known differences between the two side chain-labelled amines brought about by the poorer deamination of 3H-7,8-(-)noradrenaline. This finding also indicated that the 3H-7-(-)noradrenaline used in this study was of the desired quality, i.e. was labelled exclusively in position 7. 2. In contrast to earlier findings, no differences between the side chain-labelled 3H-7-(-)noradrenaline and the ring-labelled 3H-2,5,6-(-)noradrenaline were observed with regard to neuronal and extraneuronal amine handling (intact tissues) and metabolism by MAO and COMT in rat heart homogenates. Hence, there is no reason to avoid the ring-labelled amine with high specific activity and, consequently, with slightly more than one tritium substituent per catecholamine molecule in experiments designed to analyse the neuronal and extraneuronal fate of (-)noradrenaline.     

Disposition of endogenous adrenaline compared to noradrenaline released by cardiac sympathetic nerves in the anaesthetized dog

Summary The fate of adrenaline released from cardiac sympathetic nerves was compared with that of noradrenaline before and during two periods of electrical stimulation of the left ansa subclavia in eight anaesthetized dogs. Cardiac spillovers and extractions of both catecholamines were estimated simultaneously using infusions of ³H-labelled adrenaline and noradrenaline. Animals were studied before and after neuronal uptake blockade with desipramine.Cardiac spillover of adrenaline, detectable at rest at 1.4 ± 0.3 pmol/min, increased to 4.0 ± 1.1 and 5.3 ± 1.2 pmol/min during sympathetic stimulation. Cardiac noradrenaline spillover increased from 49 ± 12 to 205 ± 40 and 451 ± 118 pmol/min. After desipramine, cardiac spillovers of adrenaline were decreased, whereas those of noradrenaline were increased so that the ratio of adrenaline to noradrenaline spillover, meaned before and during stimulation, decreased substantially from 1:42 to 1:166. The desipramine-induced decrease in cardiac extractions of ³H-labelled catecholamines indicated adrenaline was removed 60% less efficiently than noradrenaline by neuronal uptake, whereas the extractions remaining indicated adrenaline was removed 50% more efficiently by extraneuronal uptake.The differences in removal processes indicated that 35% of the adrenaline released by cardiac sympathetic nerves was recaptured compared to 88% for noradrenaline, leaving 53% to be removed extra-neuronally compared to 6.6% for noradrenaline, so that proportionally more released adrenaline than noradrenaline escaped to spillover into plasma (12% versus 5.4%). Since extraneuronal uptake was more efficient for adrenaline than noradrenaline, proportionally less released adrenaline than noradrenaline escaped local removal to spillover into plasma when neuronal uptake was blocked (17% versus 45%). This reversed the situation before blockade so that desipramine substantially decreased the ratio of adrenaline to noradrenaline spillover. Thus, differences in the efficiencies of neuronal or extraneuronal uptake are important determinants of the amounts of locally released adrenaline and noradrenaline that escape removal processes to act at neuroeffector sites or spillover into plasma.     

Beta 1-adrenoceptors mediate smooth muscle relaxation in mouse isolated trachea.

1. The relaxant effects to the beta-adrenoceptor agonists isoprenaline, adrenaline, noradrenaline, RO363, procaterol and fenoterol were investigated in carbachol-contracted mouse isolated tracheal preparations. 2. The order of potencies for those beta-adrenoceptor agonists that induced full relaxation of carbachol-contracted mouse tracheal preparations was isoprenaline greater than RO363 greater than noradrenaline = adrenaline greater than fenoterol. The EC50 value of isoprenaline for relaxation was 46 nM. The beta 1-adrenoceptor-selective agonist, RO363 was ten times more potent than the beta 2-adrenoceptor-selective agonist, fenoterol. The highly beta 2-adrenoceptor-selective agonist procaterol was a partial relaxant and induced only 28 +/- 4% relaxation. 3. Relaxations induced by noradrenaline and isoprenaline were not significantly affected by the neuronal uptake inhibitor, cocaine (10 microM) or by the extraneuronal uptake inhibitor, deoxycorticosterone acetate (25 microM) respectively. The alpha-adrenoceptor agonist methoxamine induced no observable elevation of mouse tracheal smooth muscle tone. 4. Schild plots for the beta-adrenoceptor antagonists, atenolol and betaxolol (beta 1-adrenoceptor-selective) and ICI 118,551 (beta 2-adrenoceptor-selective) were linear, with slope values approaching unity. Mean pA2 values derived for atenolol, betaxolol and ICI 118,551 for antagonism of beta-adrenoceptor-mediated relaxation were 7.1, 8.4 and 7.2, respectively. These data were independent of the use of isoprenaline or noradrenaline as the agonist. 5. These findings indicate that beta-adrenoceptor-mediated relaxations of mouse isolated trachea occur predominantly through activation of beta 1-adrenoceptors.     

Role of extraneuronal mechanisms in the termination of contractile responses to amines in vascular tissue.

1 The role of the uptake and release of agonist from extraneuronal sites in the termination of responses of rabbit aortic strips to amines was studied. 2 Strips were contracted with adrenaline or noradrenaline and after response plateau was reached, the muscle chambers were washed free of agonist and the relaxation in Krebs solution recorded. After inhibition of catechol-O-methyl-transferase, monoamine oxidase and neuronal uptake the relaxation rate was greatly prolonged. Evidence is provided that this very slow relaxation resulted from the accumulation of intact amine at extraneuronal sites during exposure to the agonist and its subsequent release past receptors due to a reversal of the concentration gradient after washout. 3 Pretreatment with the haloalkylamine, GD-131 (N-cyclohexylmethyl-N-ethyl-beta-chloroethylamine), an inhibitor of extraneuronal uptake, returned the slow relaxation rate after enzyme inhibition towards that of control strips. By blocking the extraneuronal transport of amines their accumulation at intracellular loci after enzyme inhibition was prevented. 4 The effects of GD-131 and 17beta-oestradiol on the relaxation rate of untreated strips contracted by adrenaline and noradrenaline confirmed that extraneuronal uptake to sites of enzymatic activity is the major mechanism terminating their action. 5 Inactivation of extraneuronal transport sites by GD-131 was prevented by protecting them with 17beta-oestradiol or normetanephrine during exposure to the haloalkylamine, pointing to a common site of action of these agents on a specific carrier system for amines. 6 Evidence is presented that the relaxation from contractions induced by histamine and 5-hydroxytryptamine also involves extraneuronal accumulation and release, probably by an uptake process which is identical to the one for catecholamines.     

Presynaptic changes promoted by alloxan diabetes in the cat isolated heart

Adrenergic presynaptic functions were evaluated in the cat isolated perfused heart preparation. The sympathetic nerve endings were labelled with [3H]noradrenaline ([3H]NA) and the effect of electric neural stimulation was determined in the presence of drugs which inhibit neuronal or extraneuronal uptake, or which antagonize alpha-adrenoceptors. [3H]NA overflow was measured in control and diabetic cats and was significantly increased by electric neural stimulation on both conditions. Perfusion with 0.1 microM phentolamine increased transmitter overflow in control hearts but failed to do so on organs obtained from alloxan-treated cats. The data provide evidence that in alloxan diabetic cats there is an abnormality of the adrenergic synapse.