Characteristics of the cocaine-sensitive accumulation and O-methylation of 3H-(-)-noradrenaline by rabbit endometrium

Amezinium and debrisoquine are substrates of uptake1 and potent inhibitors of monoamine oxidase in perfused lungs of rats

Previous studies have resulted in the classification of amezinium as a selective inhibitor of neuronal monoamine oxidase (MAO), because it is a much more potent MAO inhibitor in intact tissues, in which it is accumulated in noradrenergic neurones by uptake1, than in tissue homogenates. In the present study, the effects of amezinium on the deamination of noradrenaline were investigated in intact lungs of rats, since the pulmonary endothelial cells are a site where the catecholamine transporter is non-neuronal uptake1. In addition, another drug that is both a substrate of uptake1 and a MAO inhibitor, debrisoquine, was investigated in the study. The first aim of the study was to show whether amezinium and debrisoquine are substrates of uptake1 in rat lungs. After loading of isolated perfused lungs with 3H-noradrenaline (MAO and catechol-O-methyltransferase (COMT) inhibited), the efflux of 3H-noradrenaline was measured for 30 min. When 1 mumol/l amezinium or 15 mumol/l debrisoquine was added for the last 15 min of efflux, there was a rapid and marked increase in the fractional rate of loss of 3H-noradrenaline, which was reduced by about 70% when 1 mumol/l desipramine was present throughout the efflux period. These results showed that both drugs were substrates for uptake1 in rat lungs. In lungs perfused with 1 nmol/l 3H-noradrenaline (COMT inhibited), 10, 30 and 300 nmol/l amezinium caused 58%, 76% and 74% inhibition of noradrenaline deamination, respectively, and 30, 300 and 3000 nmol/l debrisoquine caused 56%, 89% and 96% inhibition of noradrenaline deamination, respectively. When MAO-B was also inhibited, 10 nmol/l amezinium caused 84% inhibition of the deamination of noradrenaline by MAO-A in the lungs. In contrast, in hearts perfused with 10 nmol/l 3H-noradrenaline under conditions where the amine was accumulated by uptake2 (COMT, uptake1 and vesicular transport inhibited), 10 nmol/l amezinium had no effect and 300 nmol/l amezinium caused only 36% inhibition of deamination of noradrenaline. The results when considered with previous reports in the literature show that amezinium is about 1000 times more potent and debrisoquine is about 20 times more potent for MAO inhibition in rat lungs than in tissue homogenates, and the reason for their high potencies in the intact lungs is transport and accumulation of the drugs in the pulmonary endothelial cells by uptake1. Amezinium is much less potent as a MAO inhibitor in cells with the uptake2 transporter, such as the myocardial cells of the heart. The results also confirmed previous reports that amezinium is highly selective for MAO-A.

Extraneuronal uptake of noradrenaline in rabbit dental pulp: evidence of identity with uptake1

The extraneuronal removal and disposition of noradrenaline in rabbit dental pulp was examined in view of earlier evidence that the tissue possessed an extraneuronal uptake process resembling neuronal uptake1. Pulp, which had been depleted of sympathetic nerves by homolateral superior cervical ganglionectomy, was incubated in vitro with 3H-noradrenaline in low concentrations (0.025 or 0.18 mumol/l). When the metabolising enzymes (monoamine oxidase, catechol-O-methyl transferase) were active, 3H retention by the denervated pulp, as indicated by the 3H content after the tissue had been washed for 30 min following incubation with 3H-noradrenaline, was less than 3% of that of the innervated pulp. When the enzymes were inhibited, retention rose to approximately 30% of that of the innervated pulp. Analysis of the time course of the 3H efflux indicated that the 3H-noradrenaline in the denervated pulp had accumulated in a single compartment characterised by a t1/2 for efflux of several hours. Accumulation did not occur under Na(+)-free conditions, and was inhibited by desipramine (IC50 less than 0.03 mumol/l) and by substrates of neuronal uptake1. Mean IC50 values of the latter were very similar to those for inhibition of neuronal uptake1 and comprised (in mumol/l): (+)amphetamine (0.29), dopamine (0.31), tyramine (0.39), (-)noradrenaline (0.70), (-)adrenaline (1.50), 5-hydroxytryptamine (20) and bretylium (35). Uptake2 inhibitors were less active (O-methyl isoprenaline, IC50 = 60 mumol/l) than uptake1 inhibitors, or were without inhibitory effects at the concentrations tested (hydrocortisone, 210 mumol/l; 2-methoxy oestrone, 10 mumol/l).(ABSTRACT TRUNCATED AT 250 WORDS)

Distribution of extraneuronal uptake1 in reproductive tissues: studies on cells in culture

Cultures of stromal cells from pregnant mouse uterus, and an FL cell line derived from human amnion, displayed significant capacities to O-methylate noradrenaline. O-methylation was inhibited in the stromal cells by uptake1-inhibitors, and in the FL cell line by uptake2 inhibitors. These findings are discussed in terms of the distribution and possible functional importance of catecholamine metabolising systems in the female reproductive system.

The interaction of transport mechanisms and intracellular enzymes in metabolizing systems

The life span of extracellular catecholamines is limited by the combination of uptake and subsequent intracellular metabolism by either monoamine oxidase (MAO) and/or catechol-O-methyl transferase (COMT). Three such "metabolizing systems" are involved in the inactivation of noradrenaline: 1) Neuronal uptake (high-affinity uptake1) in association with neuronal MAO (and vesicular uptake), 2) extraneuronal uptake (low affinity uptake2) in association with intracellular COMT and MAO (in smooth muscles, myocardial cells, glands), and 3) uptake1 of non-neuronal cells in association with intracellular COMT and/or MAO (in vascular endothelium of rat lung). Such systems function as "pump and leak systems with enzyme(s) inside". The analysis of either uptake or enzyme fails to reveal the characteristics of such systems; they are determined by the interaction of both components. Because of the high activity of these intracellular enzymes, it is unlikely that either COMT or MAO is ever saturated in vivo. However, in vitro saturation of extraneuronal COMT and MAO reveals that extraneuronal COMT is a high-affinity, but extraneuronal MAO a low-affinity enzyme. Hence, membrane-bound COMT appears to be responsible for the extraneuronal O-methylation of noradrenaline. If intracellular enzymes remain unsaturated, the determination of the rate constants describing the unsaturated enzyme (KENZYME = Vmax/Km) is of particular interest. KENZYME can be determined for metabolizing systems, since this rate constant is not affected by the (usually unknown) fractional size of the metabolizing system.