Deamination of released 3H-noradrenaline in the canine saphenous vein

Summary Experiments were designed to determine the effect of monoamine oxidase (MAO) inhibitors on the release and the metabolism of noradrenaline in the canine saphenous vein. Helical strips were incubated with ³H-noradrenaline and mounted for superfusion and measurement of the efflux of labelled transmitter and its metabolites; in certain experiments the tissue content of ³H-noradrenaline and its metabolites was also determined. The MAO-A inhibitor clorgyline, and the non-specific inhibitor pargyline, but not the MAO-B inhibitor deprenyl decreased the appearance of deaminated and O-methylated deaminated metabolites under basal conditions and during electrical stimulation. The MAO-A and the non-specific MAO inhibitor did not decrease the efflux of VMA to the same extent as that of the other deaminated metabolites. During superfusion with etidocaine, an agent causing increased leakage of stored transmitter, clorgyline abolished the appearance of DOPEG. Addition of semicarbazide in preparations treated with pargyline did not affect the efflux of deaminated and O-methylated deaminated metabolites. From the measurement of tissue VMA, it appeared that the efflux of VMA poorly reflects quick changes in the rate of its formation but that formation is abolished by pretreatment with pargyline. These experiments indicate that in the canine saphenous vein: (1) DOPEG is formed mainly in intraneuronal sites, while DOMA, MOPEG and VMA are formed extraneuronally; (2) VMA is retained in the tissue after its formation; and (3) the only subtype of MAO involved in the metabolism of ³H-noradrenaline released from adrenergic nerve endings can be classified as MAO-A.Supported in part by grant HL-05883     

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.     

Effects of S-11701 on accumulation, release and metabolism of norepinephrine in isolated canine saphenous veins.

1. The effects S-11701 ([morpholinyl-2)-methoxy]-8-tetrahydro-1,2,3,4 quinoline) on accumulation, overflow and metabolism of [3H]norepinephrine were investigated in isolated canine saphenous veins. 2. Saphenous veins were incubated with [3H]norepinephrine in the absence or the presence of S-11701; the drug caused a concentration-dependent inhibition of the tissue content of [3H]norepinephrine and its metabolites, except for 3-methoxy-4-hydroxymandelic acid (VMA). 3. In helical strips of canine saphenous veins previously incubated with [3H]norepinephrine and then suspended for isometric tension recording and measurement of the overflow of labelled transmitter and its metabolites, S-11701 (30 microM) significantly increased the spontaneous efflux of total 3H; this effect was almost exclusively due to an augmentation of the efflux of [3H]DOPEG. 4. During electrical stimulation (9 V, 1 Hz), S-11701 at 1 microM slightly increased the overflow of extraneuronal norepinephrine metabolites without affecting the contractile response. At the higher concentration (30 microM) the compound increased the contractive response and the overflow of 3H; the latter was due mainly to an increase in [3H]DOPEG and, to a lesser extent, in [3H]norepinephrine. 5. DMI (1 microM) did not interfere with the effects of S-11701 on DOPEG efflux. 6. These experiments indicate that in the canine saphenous vein, S-11701 causes a concentration-dependent inhibition of neuronal accumulation of [3H]norepinephrine. At higher concentrations, S-11701 enters the adrenergic nerve terminals independently of the neuronal amine carrier and displaces [3H]norepinephrine from its storage sites.     

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     

Effects of clorgyline and (−)deprenyl on the deamination of normetanephrine and noradrenaline in strips and homogenates of the canine saphenous vein

Summary The influence of specific inhibitors of MAO A (clorgyline) and MAO B [(–)deprenyl] on the metabolism of normetanephrine (NMN), in strips of canine saphenous vein was studied, both in the absence and in the presence of inhibitors of neuronal (cocaine) and extraneuronal (hydrocortisone) uptake. Moreover, the formation of metabolites of noradrenaline and of NMN by saphenous vein homogenates and the influence of clorgyline or (–)deprenyl on this formation are described.Clorgyline reduced to the same degree (by about 70%) the formation of methoxy-hydroxy-phenylglycol (MOPEG) and of vanillylmandelic acid (VMA) in strips incubated with NMN, whereas (–)deprenyl reduced by about 50% the formation of MOPEG and had no effect on VMA production. Hydrocortisone had effects very similar to those of (–)deprenyl.Saphenous vein, homogenates ()-methylation inhibited), deaminated both noradrenaline and NMN; clorgyline and (–)deprenyl reduced the formation of metabolites of both noradrenaline and NMN.It is concluded that both MAO A and B are able to deaminate noradrenaline and NMN, but that in the intact tissue the former has no access to MAO B. Even in intact tissues MAO B may play a role in the metabolism (but not in the inactivation) of noradrenaline by deaminating the NMN formed from noradrenaline and giving preferentially origin to MOPEG.Supported by Instituto Nacional de Investigação Científica (INIC, FmPl)On leave from Faculdade de Farmácia, Universidade de Coimbra, with a grant from Instituto Nacional de Investigação Científica     

The aziridinium derivative of DSP4 (N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine) accelerates the beating rate of isolated rat atria by enhancing the spontaneous release of noradrenaline

Summary The aziridinium derivative of the compound N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine hydrochloride (az-DSP4) depletes endogenous noradrenaline stores and exerts neurotoxic actions on noradrenergic neurons. These effects are persistent in the central nervous system and transient in the periphery. To determine if transmitter release plays a role in the noradrenaline depletion caused by az-DSP4, the action of the compound was studied in isolated and spontaneously beating rat atria. 1. az-DSP4 enhanced atrial beating rate when present in the incubation medium at concentrations ranging from 10^–3 M to 10^–4 M but at 10^–3 s M decreased that rate below basal levels. 2. Preincubation of atria for 30 min with the noradrenaline uptake blocker desimipramine (DMI, 10^–6 M) or with the betablocker propranolol (10^–7 M), abolished the positive chronotropic action of az-DSP4. 3. The rate-accelerating effect of az-DSP4 could be prevented by pretreating the rats with reserpine (5 mg/kg i. p. 24 h) or enhanced by pargyline pretreatment (100 mg/kg i. p. 18 h). 4. az-DSP4 stimulated the spontaneous efflux of tritium from the isolated atria previously labeled with ³H-noradrenaline (4 × 10^–7 M), an increase that was mainly accounted for by DOPEG. 5. COMT and MAO activities in atria homogenates were inhibited by az-DSP4 in a concentration-dependent manner. However, MAO inhibition did not result in a change of the metabolic pattern as could be expected. 6. The results obtained indicate that az-DSP4 enhances the rate of spontaneous beating of isolated rat atria. The positive chronotropic effect of az-DSP4 requires the interaction of the compound with the noradrenaline uptake system. The mechanism of the accelerating effect of az-DSP4 most probably involves the release of noradrenaline from adrenergic nerve terminals in the atria and its subsequent interaction with adrenergic beta-receptors.Abbreviations DSP4 N-(2-chloroethyl)-N-ethyl-2-bromobenzylamine hydrochloride - az-DSP4 aziridinium derivative of DSP4 - NA noradrenaline - 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) - COMT catechol-O-methyltransferase - MAO monoamineoxidase Send offprint requests to M. E. Landa     

Effects of flow-stop on the metabolism of noradrenaline released by nerve stimulation in the perfused spleen

Summary The metabolic pathway of ³H-noradrenaline released spontaneously and by nerve stimulation was studied in the isolated perfused spleen of the cat. The deaminated glycol, DOPEG, (3,4 dihydroxyphenylglycol) was the main metabolite in spontaneous outflow, accounting for 62.5±1.6% of the total radioactivity (n=13). Of the total increase in radioactive products elicited by nerve stimulation at 5 Hz or 10 Hz around 30% was accounted for by the noradrenaline metabolites, particularly DOPEG and the O-methylated fraction. In the presence of 2.9×10^–6 M of cocaine the total overflow of radioactivity induced by stimulation was unchanged but DOPEG formation from released noradrenaline was abolished. These findings indicate that DOPEG formation results from the recapture of the released transmitter by adrenergic nerve endings and subsequent intraneuronal deamination. The total overflow of noradrenaline was reduced by flow-stop while the metabolism of the released transmitter was increased significantly. Cocaine, 2.9×10^–6 M, prevented the increase in DOPEG when stimulation was applied under flow-stop conditions. The decrease in noradrenaline overflow induced by flow-stop is partly due to the increase in the metabolism of the released transmitter.     

The influence of inhibition of catechol-O-methyl transferase or of monoamine oxidase on the extraneuronal metabolism of 3H-(−)-noradrenaline in the rat heart

Summary The extraneuronal metabolism of ³H-(–)-noradrenaline (1 nmol/l) was determined in rat hearts obtained from reserpine-pretreated animals (in the presence of 30 mol/l cocaine).Inhibition of monoamine oxidase (MAO) (by pretreatment of the animals with pargyline) increased the formation of O-methylated metabolites by nearly that amount by which the formation of deaminated metabolites declined; hence, catechol-O-methyl transferase (COMT) seemed to be able to nearly fully compensate for the loss of MAO activity. However, when COMT was inhibited (by the presence of either 1 or 10 mol/l U-O521), the increase in the formation of deaminated metabolites was smaller than the decrease in the formation of O-methylated metabolites; hence, MAO seemed to be unable to fully compensate for the loss of COMT activity.These results are discussed with regard to the hypothesis that the two extraneuronal enzymes co-exist in one compartment. As inhibition of COMT causes a much greater increase in the steady-state tissue/medium ratio for ³H-(–)-noradrenaline than does inhibition of MAO, it is suggested that it is this increase in the intracellular concentration of ³H-(–)-noradrenaline which-by promoting an efflux of the unchanged amine that is proportional to the tissue/medium ratio-actually decreases the net removal of ³H-(–)-noradrenaline from the perfusion fluid.The results are compatible with (but no evidence for) the hypothesis that the two enzymes co-exist in the same extraneuronal compartment.The following abbreviations are used here NMN normetanephrine - DOPEG dihydroxyphenylglycol - DOMA dihydroxymandelic acid - MOPEG methoxyhydroxyphenylglycol - VMA methoxyhydroxymandelic acid - OMDA MOPEG+VMA Supported by the Deutsche Forschungsgemeinschaft     

The uptake and metabolism of 3H-catecholamines in rat cerebral cortex slices

Summary The accumulation and metabolism of ³H-catecholamines were studied in cerebral cortex slices obtained from rats pretreated with reserpine, during 30 min of incubation with 50 nmol/l of the ³H-amines. In some experiments neuronal uptake (uptake,) was inhibited by the presence of 0.3 mol/l desipramine, in others COMT was inhibited by 30 mol/l U-0521. When both MAO and COMT were intact, most of the metabolism of ³H-noradrenaline was neuronal (i. e., desipramine-sensitive). For ³H-adrenaline rates of neuronal metabolism were much lower than for ³H-noradrenaline, non-neuronal O-methylation accounting for about 50% of total metabolism. Rates of metabolism of ³H-dopamine were similar to those of ³H-noradrenaline, but with a predominance of non-neuronal metabolism, which involved O-methylation and deamination. Under these conditions, very little ³H-catecholamine was recovered from the tissues; moreover, desipramine tended to increase tissue levels. Hence, tissue content then appears to partly reflect extracellularly distributed ³H-amines. After block of MAO rates of metabolism of ³H-noradrenaline and ³H-dopamine were greatly reduced, and tissue levels were increased. Desipramine now antagonized the accumulation of ³H-amines in the tissue, while U-0521 increased it. Rates of O-methylation (in the presence of desipramine) increased in the order ³H-noradrenaline < ³H-dopamine. It is concluded that neuronal uptake is associated with MAO only, and rates of neuronal deamination increased in the order: ³H-adrenaline < ³H-dopamine « ³H-noradrenaline. Non-neuronal uptake is associated with both, COMT and MAO, and rates of non-neuronal metabolism increased in the order: ³H-adrenaline < ³H-noradrenaline « ³H-dopamine.Abbreviations COMT catechol-O-methyl transferase - DOMA dihydroxymandelic acid - DOPAC dihydroxyphenylacetic acid - DOPEG dihydroxyphenylglycol - DOPET dihydroxyphenylethanol - HVA homovanillic acid - MAO monoamine oxidase - MN metanephrine - MOPEG methoxyhydroxyphenylglycol - MOPET methoxyhydroxyphenylethanol - NMN normetanephrine - 3-OMT 3-O-methyl-tyramine - VMA vanillylmandelic acid Supported by the Deutsche Forschungsgemeinschaft (SFB 176) Send offprint requests to U. Trendelenburg at the above addresswith the technical assistance of M. Babl     

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     

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     

Predominance of oxidative deamination in the metabolism of exogenous noradrenaline by the normal and chemically denervated human uterine artery

Summary Longitudinal strips were prepared from human uterine arteries obtained at hysterectomy. The artery had a low content of noradrenaline and dopamine, contrasting with a high content of the deaminated catechols, dihydroxyphenylglycol (DOPEG) and dihydroxymandelic acid (DOMA), which together represented 98% of endogenous catechols.When incubated with ³H-noradrenaline (0.1 mol/l), the uterine artery removed, accumulated and metabolized noradrenaline. Deaminated metabolites predominated, DOMA being the most abundant metabolite.Cocaine markedly reduced the accumulation of ³H-noradrenaline and abolished ³H-DOPEG formation, but did not change ³H-DOMA. Selective monoamine oxidase (MAO) inhibitors (clorgyline, selegiline and 2-amino ethyl carboxamide derivatives) caused a marked decrease in the amounts of ³H-DOPEG, ³H-DOMA and ³H-O-methylated and deaminated metabolites (OMDA) formed by the tissue and an increase in ³H-normetanephrine (NMN) formation. Inhibition of catechol-O-methyltransferase suppressed NMN formation and reduced that of OMDA; hydrocortisone slightly depressed the formation of DOMA and OMDA.Homogenates of the uterine artery deaminated ³H-5-HT, ¹⁴C-phenylethylamine and ³H-tyramine; inhibition curves of the deamination of ³H-tyramine by clorgyline and selegiline were compatible with the presence of both MOA A and MOA B.Exposure of the strips to 6-hydroxydopamine (1.5 mmol/l for 20 min; 3 exposure periods followed by washout periods of 15,15 and 30 min) resulted in complete and selective chemical denervation of the arterial tissue. This chemical denervation had effects which were similar to those of cocaine. The 2-amino ethyl carboxamide derivatives markedly reduced the formation of deaminated metabolites by the denervated strips.The semicarbazide-sensitive amine oxidase inhibitor semicarbazide reduced the formation of ³H-DOMA and ³H-DOPEG in intact strips, but was devoid of action in the denervated ones.It is concluded that, in the human uterine artery, deamination predominates over O-methylation and that extraneuronal deamination, leading to the formation of DOMA (and of OMDA) plays a major role in the metabolism even of low concentrations of exogenous noradrenaline.Abbreviations COMT Catechol O-methyltransferase - DOMA dihydroxymandelic acid - DOPEG dihydroxyphenylglycol - HPLC-ED high pressure liquid chromatography with electrochemical detection - 5-HT 5-hydroxytryptamine - MAO monoamine oxidase - NMN normetanephrine - 6-OHDA 6-hydroxydopamine - OMDA O-methylated and deaminated metabolites of noradrenaline (3-methoxy-4-hydroxyphenylglycol and 3-methoxy-4-hydroxymandelic acid) - Ro 01-2812 3,5-dinitropyrocatechol - Ro-19-6327 N-(2-aminoethyl)-5-chloro-2-pyridine carboxamide hydrochloride - Ro 41-1049 N-(2-aminoethyl)-5-(mfluorophenyl)-4-thiazole carboxamide hydrochloride Supported by Instituto Nacional de Investigação Científica (INIC, FmP1) and Junta Nacional de Investigação Científica e Tecnológica (JNICT). Fatima Martel is a PhD student with a grant from JNICT Send offprint requests to W. Osswald 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     

The role of MAO-A and MAO-B in the metabolic degradation of noradrenaline in human arteries

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Modulation of the concentration of noradrenaline at the neuro-effector junction in human saphenous vein.

We studied the importance of neuronal and extraneuronal uptake and of the pre-junctional alpha-adrenergic feed-back mechanism for the junctional noradrenaline concentration in the human saphenous vein. All major metabolites of the enzymatic breakdown of noradrenaline were detected in the overflow of superfused veins loaded with [3H]-noradrenaline. The efflux of 3,4-dihydroxyphenylglycol (DOPEG) was drastically reduced in preparations labelled after neuronal uptake blockade indicating its neuronal origin; the other metabolites are formed extraneuronally since they behaved distinctly differently from DOPEG under several experimental conditions. Extraneuronal uptake followed by enzymatic breakdown removes the same amount of noradrenaline from the biophase during nerve activity as that diffusing intact out of the tissue, whereas neuronal uptake appears only half as effective since the overflow of intact noradrenaline increases by only 48% in the presence of desmethylimipramine (DMI). However, in preparations mounted for isometric tension recording, neuronal uptake blockade potentiated contractions to alpha-adrenergic activation, emphasizing the functional importance of the neuronal disposition mechanism. By contrast, no evidence was found for a hydrocortisone-sensitive extraneuronal uptake compartment, suggesting that extraneuronal removal may have little, if any, functional importance. During nerve stimulation, yohimbine increased the amount of labelled noradrenaline present in the superfusate, while exogenously added noradrenaline decreased it in the presence of cocaine. Thus, prejunctional alpha-adrenoceptors can modulate the junctional concentration of neurotransmitter in the human saphenous vein.     

The heterogeneity of the neuronal distribution of exogenous noradrenaline in the rat vas deferens

Summary After loading of the incubated rat vas deferens with 0.2 mol/l ³H-noradrenaline (followed by 100 min of wash-out with amine-free solution), the efflux of endogenous and exogenous compounds was determined by HPLC with electrochemical detection and by column chromatography with scintillation counting. Two different types of heterogeneity of labelling were found. The first one is due to the preferential labelling of varicosities close to the surface of the tissue, the second one to the preferential labelling of vesicles close to the surface of loaded varicosities. As diffusion distances within the tissue and within varicosities are then longer for endogenous than for exogenous amine and metabolites, the composition of spontaneous efflux of exogenous compounds differed from that for endogenous compounds. Because of preferential neuronal and vesicular re-uptake of endogenous noradrenaline, the percentage contribution by noradrenaline to overall efflux was: endogenous < exogenous. While ³H-DOPEG was the predominant exogenous metabolite, DOPEG and MOPEG equally contributed to the endogenous efflux.Desipramine abolished the consequences of the first heterogeneity of labelling, i.e., it increased the efflux more for endogenous than for exogenous noradrenaline; moreover it decreased the efflux of ³H-DOPEG, but increased that of ³H-MOPEG. The reserpine-like compound Ro 41284, on the other hand, abolished the consequences of the second type of heterogeneity; it reduced the specific activity of total efflux (i.e., of the sum of noradrenaline + DOPEG + MOPEG) to the specific activity of the tissue noradrenaline. The degree of heterogeneity of labelling was reduced after inhibition of monoamine oxidase and also when the tissues were loaded with 2 or 20 mol/l ³H-noradrenaline.It is proposed that the various compartments and pools of noradrenaline described in the literature reflect the two heterogeneities described here.Abbreviations COMT catechol-O-methyl transferase - DOMA dihydroxymandelic acid - DOPEG dihydroxyphenylglycol - FRL fractional rate of loss (= rate of efflux/tritium content of tissue measured at onset of collection period) - HPLC high performance liquid chromatography - MAO monoamine oxidase - MOPEG methoxyhydroxyphenylglycol - NMN normetanephrine - VMA vanillylmandelic acid Send offprint requests to E. Schömig at the above addressThis study was supported by the Deutsche Forschungsgemeinschaft (SFB 176, Gr 490/5 and Scho 383/1). Some of the results were presented to the German Pharmacological Society (Schönfeld 1990; Trendelenburg 1990)     

Metabolism of endogenous and exogenous noradrenaline in guinea-pig atria

Summary The outflow of noradrenaline, 3,4-dihydroxyphenylglycol (DOPEG) and 3,4-dihydroxymandelic acid (DOMA) from guinea-pig isolated atria was studied by chromatography on alumina followed by high pressure liquid chromatography with electrochemical detection. In the absence of drugs, the outflow of endogenous noradrenaline over a period of 3 h averaged 1.6 pmol×g^–1×min^–1 and the outflow of DOPEG 17 pmol×g^–1×min^–1. The outflow of DOMA was below the detection limit (<0.31 pmol×g^–1×min^–1). Tyramine greatly increased the outflow of noradrenaline and DOPEG, and the reserpine-like compound Ro 4-1284 selectively increased the outflow of DOPEG; DOMA remained below the detection limit. When atria were exposed to (–)-noradrenaline 1.7 or 17 M, the subsequent outflow of noradrenaline and DOPEG was enhanced. Moreover, substantial amounts of DOMA were now found. This outflow of DOMA was prevented when atria were exposed to (–)-noradrenaline in the presence of cocaine or after an initial incubation with amezinium. Exposure to (–)-noradrenaline 1.7 M mainly enhanced the formation of DOPGE, while exposure to (+)-noradrenaline 1.7 M mainly enhanced the formation of DOMA.Our experiments confirm some and qualify other conclusions drawn from studies in which exogenous ³H-noradrenaline had been used to examine the metabolism of noradrenaline in guinea-pig atria. In agreement with the isotope studies, DOPEG is a major metabolite of endogenous noradrenaline. In contrast to what the isotope studies had suggested, however, endogenous DOMA is a very minor product, at least as long as the neurones are at rest. DOMA is only formed when the tissue is exposed to high concentrations of exogenous noradrenaline. In further contrast to previous conclusions, DOMA is then formed intra- and not extraneuronally.     

Release and disposition of 3H-noradrenaline in the saphenous vein of neonate and adult dogs

Summary Release of ³H-noradrenaline and formation of ³H-metabolites were studied in the saphenous vein of newborn (mean age, 18 h) and adult dogs. Vein strips were incubated with 0.23 mol/l of ³H-noradrenaline during 1 h and washed out for 110 min; thereafter, the perifusion fluid was collected in 5-min samples. Electrical stimulation was applied at 120 min (1 Hz, 2 ms, 100 V, for 5 min). In some experiments the tissues were preincubated with 1 mmol/l pargyline (to inhibit monoamine oxidase). In these experiments, 12 mol/l cocaine (to inhibit uptake₁), 41 mol/l hydrocortisone (to reduce uptake₂) and 50 mol/l U-0521 (to inhibit COMT) were present during the perifusion. ³H-noradrenaline, ³H-DOPEG, ³H-NMN, ³H-DOMA and ³H-OMDA were separated by column chromatography. The noradrenaline content of the tissue was estimated by HPLC followed by electrochemical detection. A morphological study was also carried out by light and electron microscopy.The endogenous noradrenaline content of the saphenous vein was 4.3 times higher in adults than in neonates. The number of varicosities was similar in adults and newborns but the number of vesicles per varicosity profile was 5 times higher in adults. Hence, the endogenous noradrenaline content per vesicle was about the same in adults and newborns. The accumulation of ³H-noradrenaline per vesicle was about 5 times higher in newborns than in adults. On the other hand, the vein wall media of neonates was about 3 times thinner than that of adults. The evoked fractional release of tritium was about 10 times higher in neonates than in adults, whether the inactivation pathways were blocked or not. This difference in the evoked fractional release therefore cannot be ascribed to any difference in the efficacy of the inactivation pathways between neonates and adults. On the other hand, the difference also cannot be ascribed to a different alpha₂-adrenoceptor-mediated inhibition of ³H-noradrenaline release since, as previously shown, this mechanism is as effective in newborns as in adults.It is concluded that the evoked fractional release of ³H-noradrenaline is higher in neonates than in adults because in neonates the majority of varicosities (and vesicles) is situated closer to the surface of the tissue such that both uptake from the surrounding media into the stores and release from the stores into the surrounding media become easier in the neonates.Abbreviations COMT catechol-O-methyl transferase - DOMA 3,4-dihydroxymandelic acid - DOPEG 3,4-dihydroxyphenylglycol - HPLC high pressure liquid chromatography - MAO monoamine oxidase - NMN normetanephrine - OMDA 3-methoxy-4-hydroxyphenylglycol (MOPEG) plus 3-methoxy-4-hydroxymandelic acid (VMA) - U-0521 3,4-dihydroxy-2-methyl propiophenone Correspondence to D. Moura at the above address     

Uptake and metabolism of 3H-adrenaline and 3H-noradrenaline by isolated hepatocytes and liver slices of the rat

Summary Isolated rat hepatocytes were incubated with 0.05 mol/l or 0.2 mol/l ³H-(–)-noradrenaline or 0.05 mol/l ³H-(–)-adrenaline for 15 min and the content of amines as well as the formation of metabolites was measured.The removal Of both amines from the incubation medium was quantitatively similar, and mainly due to metabolism (which represented 96% of the removal of ³H-adrenaline and 98% of the removal of ³H-noradrenaline). O-methylation predominated for ³H-adrenaline: O-methylated and deaminated metabolites (³H-OMDA) and ³H-metanephrine (³H-MN) were the most abundant metabolites, accounting for 63% and 34% of total metabolite formation, respectively. Deamination predominated for ³H-noradrenaline: ³H-OMDA and ³H-dihydroxymandelic acid (³H-DOMA) were the most abundant metabolites, representing respectively 56% and 36% of total metabolite formation. The following activities of monoamine oxidase and catechol-O-methyl transferase were determined for ³H-noradrenaline: k_COMT 0.70±0.15 min^–1 and k_MAO 2.27±0.14 min^–1 In experiments with ³H-noradrenaline, inhibition of monoamine oxidase reduced the formation of ³H-OMDA and deaminated metabolites [³H-dihydroxyphenylglycol (³H-DOPEG) and ³H-DOMA] and increased the formation of ³H-normetanephrine (³H-NMN). Inhibition of catechol-O-methyl transferase, On the Other hand, decreased ³H-NMN and increased ³H-DOPEG formation. When both enzymes were inhibited, the formation of all metabolites was strongly reduced but surprisingly there was no accumulation of ³H-amines in the cells, as the cell: medium ratio for ³H-noradrenaline or ³H-adrenaline was about unity. In experiments with either ³H-noradrenaline or ³H-adrenaline, specific inhibitors of either uptake, or uptake₂ produced discrete effects, slightly decreasing the formation of ³H-OMDA and ³H-NMN or ³H-MN, and having no effect on ³H-amine content of the cells. Additional experiments were carried Out with rat liver slices incubated for 15 min with ³H-noradrenaline 0.2 mol/l. The pattern of metabolism of ³H-noradrenaline (³H-OMDA and ³H-DOMA were the most abundant metabolites) as well as the degree of metabolism of the amine removed from the incubation medium (91% of the removal) were similar to those of the isolated cells. Likewise, there was no accumulation of intact ³H-noradrenaline in the tissue. Moreover, the results obtained with enzyme inhibitors as wells as with uptake inhibitors were similar to those obtained with hepatocytes.In conclusion, isolated hepatocytes remove and metabolize catecholamines very efficiently, being one of the most active systems studied in this respect. Uptake₁ and uptake₂ are responsible for part of the removal of catecholamines by hepatocytes; the system(s) involved in the remaining removal seem(s) to be active, but possess(es) characteristics that do not allow us to characterize it (them) either as uptake₁ or uptake₂.Abbreviations COMT catechol-O-methyl transferase - DOMA 3,4-dihydroxymandelic acid - DOPEG 3,4-dihydroxyphenylglycol - HEPES 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid - MAO monoamine oxidase - MN metanephrine - NMN normetanephrine - OMDA O-methylated and deaminated metabolites (i.e., MOPEG = 4hydroxy-3-methoxyphenylglycol and VMA = 4-hydroxy-3-methoxymandelic acid) Supported by Programa STRIDE (STRDA/P/SAU/259/92)PhD student with a grant from JNICT (Programa Ciência) Correspondence to: F. Martel at the above address     

Desipramine and some other antidepressant drugs decrease the major norepinephrine metabolite 3,4-dihydroxyphenylglycol-sulphate in the rat brain

Summary The O-methylated and non-O-methylated end metabolites of norepinephrine (NE) in the rat brain were measured to investigate a presumed shift in metabolism of NE from intra- to extraneuronal metabolism by uptake inhibitory antidepressant drugs. Desipramine (DMI), protriptyline and maprotiline in doses from 2.5–20 mg/kg reduced the concentration of the major non-O-methylated NE metabolite 3,4-dihydroxyphenylglycolsulphate (DOPEG-SO₄) in the whole rat brain to about 60–70% of controls, while imipramine, amitriptyline, butriptyline and clorimipramine (20 mg/kg, 21/2 h) caused no significant decrease. The major O-methylated NE metabolite free plus conjugated 3-methoxy-4-hydroxyphenylglycol (total-MOPEG) was almost unaffected by all the drugs 21/2 h after administration. At longer time intervals, however, i.e. 5 h, a high dose of DMI (10 mg/kg, s.c.) decreased total-MOPEG to 75% of controls. DOPEG-SO₄ was decreased by DMI in all brain regions examined: cortex, hippocampus, cerebellum and brain rest. ³H-normetanephrine was increased 1/2h and 1 h after intraventricular injection of ³H-dopamine, and at the same time interval both total-³H-MOPEG and ³H-DOPEG-SO₄ were decreased. Amine storage in granules was not necessary for the action of DMI since DMI retained its metabolite-lowering effects in reserpinized rats. Inhibition of NE uptake in vivo did not induce the expected increase in the major extraneuronal NE metabolite MOPEG, but only the expected decreased in DOPEG-SO₄. The reduction of both the major NE metabolites by DMI suggests a decreased metabolism and turnover of NE.Abbreviations Used NE norepinephrine - DOPEG 3,4-dihydroxyphenylglycol - DOPEG-SO₄ DOPEG sulphate ester - MOPEG 3-methoxy-4-hydroxyphenylglycol - total-MOPEG free plus conjugated MOPEG - DOPAC 3,4-dihydroxyphenylacetic acid - HVA homovanillic acid - NM normetanephrine - DA dopamine - DMI desipramine - MAO monoamine oxidase