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     

Uptake of 3H-catecholamines by rat liver cells occurs mainly through a system which is distinct from uptake1 or uptake2

Isolated rat hepatocytes were incubated with 200 nmol/l ³H-(–)-noradrenaline or 50 nmol/l ³H(–)-adrenaline for 15 min, in Krebs-Henseleit solution at 37°C, gassed with 95% O₂ 5010 CO₂. Monoamine oxidase and catechol-O-methyl transferase were inhibited withpargyline (500 mol/l)and Ro 01-2812 (3,5-dinitropyrocatechol; 2 ol/l), respectively. Total radioactivity present in the cells, which corresponded mostly to intact ³H-amine, was measured.The content of ³H-noradrenaline increased with time of incubation, a plateau having been reached after 15 min of incubation. After 15 min of incubation,the cell: medium ratio for ³H-noradrenaline and ^3H-adrenaline was 0.6–0.7. Desipramine (an inhibitor of the neuronal uptake of catecholamines — uptake,; 1 mol/l) did not affect the uptake of either ³H-noradrenaline or ³H-adrenaline into hepatocytes. Corticosterone (an inhibitor of the extraneuronal uptake of catecholamines — uptake₂; 40 mol/l) slightly inhibited (by 28%) the uptake of ³H-adrenaline, and did not significantly reduce ³H-noradrenaline uptake. Probenecid (an inhibitor of the renal transport of organic anions; 100 mol/l) did not influence the amount of either ³H-noradrenaline or ³H-adrenaline in hepatocytes. Cyanine 863 (an inhibitor of the renal transport of organic cations; 10 mol/l) decreased by 62% the uptake of ³H-adrenaline into cells but did not significantly affect ³H-noradrenaline uptake. Bilirubin (a substrate of a hepatic transport for organic anions; 200 ol/l) produced a significant increase (50%) in the amount of ³H-noradrenaline and ³H-adrenaline present in the cells. When isolated hepatocytes were incubated in a sodium-free medium (sodium being replaced by choline or lithium) there was a very marked inhibition of ³H-noradrenaline and 3H-adrenaline uptake (by 85–97%). An increase in potassium content of the medium (from 6.6 to 50 mmol/l) did not affect the uptake of either ³H-amine into isolated cells.In conclusion, the uptake of catecholamines by isolated liver cells possesses characteristics that distinguish it from the classic uptake systems for catecholamines (uptake₁ and uptake₂): (1) it is sodium-dependent but not affected by desipramine; (2) it is only slightly sensitive to corticosterone and not affected by potassium-induced depolarization; (3) it is partially sensitive to cyanine 863. Moreover, the increase of ³H-amine content in the cells in the presence of bilirubin suggests the possibility of catecholamines being excreted from the hepatocytes through the bilirubin transporter.PhD student with a grant from JNICT (Programa Ciência)Abbreviations COMT catechol-O-methyl transferase - MAO monoamine oxidase - RTOC renal transport of organic cations Supported by Programa STRIDE (STRDA/P/SAU/259/92) Correspondence to: F. Martel at the above address     

Extraneuronal noradrenaline transport (uptake2) in a human cell line (Caki-1 cells)

Summary This study describes for the first time an experimental system for the extraneuronal transport mechanism of noradrenaline (uptake₂) which is based on a clonal cell line (Caki-1). Caki-1 cells were originally derived from a human renal cell carcinoma. The conclusion that these cells express uptake₂ is supported by several experimental findings. (1) The initial rate of ³H-noradrenaline uptake in Caki-1 cells is saturable, the K _m being 450 mol/l. (2) Inhibitors of uptake₂ such as corticosterone (1 mol/l) and O-methyl-isoprenaline (100 Emol/l) largely inhibit ³H-noradrenaline uptake in Caki-1 cells. Whereas inhibitors of the neuronal transport mechanism for noradrenaline (uptake₁) such as desipramine (1 mol/l) and cocaine (10 mol/l) do not reduce it. (3) Depolarization of Caki-1 cells by the elevation of extracellular potassium inhibits ³H-noradrenaline uptake. (4) There is a highly significant correlation between the IC₅₀'s of various compounds for the inhibition of ³H-noradrenaline uptake in Caki-1 cells and rabbit aorta known to possess uptake₂.Interestingly enough, uptake₂ in Caki-1 cells and rabbit aorta is inhibited by cimetidine, quinidine and procainamide which are substrates of the renal transport mechanism for organic cations. Moreover, ³H-cimetidine is shown to be a substrate of uptake₂ in the isolated perfused rat heart. These results indicate a striking similarity between uptake₂ and the renal transport mechanism for organic cations. Send offprint requests to E. Schömig at the above addressSupported by the Deutsche Forschungsgemeinschaft (SFB 176, Scho 373) and the Dr. Robert Pfleger Stiftung     

The effect of (±)-dobutamine on adrenergic nerve endings

Summary Possible effects of (±)-dobutamine on adrenergic nerve endings were determined in experiments with ghosts of bovine chromaffin granules, with rat phaeochromocytoma (PC-12) cells and with the rat vas deferens. Dobutamine inhibited the vesicular uptake of a mixture of 70% adrenaline + 30% ³H-noradrenaline into ghosts, with an IC₅₀ of 1.7 mol/l. Dobutamine inhibited uptake, of ³H-noradrenaline in PC-12 cells (with an IC₅₀ of 0.38 mol/l) without being a substrate. However, dobutamine easily entered PC-12 cells by diffusion. After inhibition of MAO, COMT and vesicular uptake dobutamine (15 and 45 mol/l) released tritium from rat vasa deferentia preloaded with ³H-noradrenaline. Equi-inhibitory concentrations of dobutamine and desipramine (against uptake₁) were equireleasing. On the other hand, when MAO and vesicular uptake were intact, dobutamine (15 mol/l) increased the efflux of tritium from preloaded vasa deferentia much more than did an equi-inhibitory concentration of desipramine. Most of the released tritium was then ³H-DOPEG.Dobutamine is a potent inhibitor of uptake₁ as well as of vesicular uptake; moreover, it easily diffuses into adrenergic nerve endings. Hence, it blocks the neuronal and the vesicular re-uptake of noradrenaline; consequently, when MAO and vesicular uptake are intact, dobutamine increases the net leakage of noradrenaline from the storage vesicles, thereby leading to an efflux of deaminated metabolites. However, dobutamine is virtually unable to release noradrenaline into the extracellular space.Abbreviations COMT catechol-O-methyl transferase - DOPEG dihydroxyphenylglycol - DOMA dihydroxymandelic acid - MAO monoamine oxidase Supported by the Deutsche Forschungsgemeinschaft (Gr 490/5 and SFB 176) Send offprint requests to P. Fischer at the above address     

Mechanisms of the release of 3H-noradrenaline by dimethylphenylpiperazinium (DMPP) in the rat vas deferens

Summary In the rat vas deferens, DMPP is a substrate of uptake, (K_rn = 11.5 mol/I). After block of vesicular uptake, monoamine oxidase and catechol-O-methyl transferase, after loading of the tissue with ³H-noradrenaline, and in calcium-free solution (i. e., when axoplasmic ³H-noradrenaline levels were high and when depolarization-induced exocytotic release was impossible), DMPP induced a pronounced outward transport of ³H-noradrenaline. On the other hand, when, in similar experiments, vesicular uptake and monoamine oxidase were intact (i.e., when axoplasmic ³H-noradrenaline levels were low), DMPP induced very little outward transport of ³H-noradrenaline. This discrepancy indicates that DMPP has little ability to mobilize vesicularly stored ³H-amine.When the medium contained calcium (catechol-O-methyl transferase inhibited, all other mechanisms intact), 100 (but not 10) mol/l DMPP induced a hexamethonium-sensitive release of ³H-noradrenaline of short duration. Hence, in the presence of extracellular calcium, 100 mol/l DMPP elicits exocytotic release via activation of hexamethonium-sensitive nicotinic acetylcholine receptors.DMPP inhibits the monoamine oxidase of rat heart homogenate with an IC₅₀ of about 100 mol/l.Abbreviations COMT catechol-O-methyl transferase - DMPP dimethylphenylpiperazinium - DOMA dihydroxymandelic acid - DOPEG dihydroxyphenylglycol - MAO monoamine oxidase - NMN normetanephrine - OM-fraction column chromatographic fraction containing all O-methylated ³H-metabolites - OMDA fraction containing O-methylated and deaminated metabolites Supported by the Deutsche Forschungsgemeinschaft (SFB 176) Send offprint requests to U. Trendelenburg at the above address     

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 mol/l amezinium or 15 mol/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 mol/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.Abbreviations COMT catechol-O-methyltransferase - DOMA 3, 4-dihydroxy-mandelic acid - DOPEG 3, 4–'dihydroxyphenylglycol - ECS extracellular space - FRL fractional rate of loss - IC ₅₀ inhibitor concentration that causes 50% inhibition - K _{m uptake} Michaelis or half-saturation constant for uptake - k _{M AO} rate constant for deamination - k _{out NA} rate constant for efflux of noradrenaline - MAO monoamine oxidase - MAO-Aa type A monoamine oxidase - MAO-B type B monoamine oxidase - T/M _NA tissue to medium ratio of noradrenaline - U-0521 3, 4-dihydroxy-2-methylpropiophenone - V _max maximal rate - v _st–st steady-state rate of metabolite formation Preliminary results of this study were presented to the 1993 Meeting of the Australasian Society of Clinical and Experimental Pharmacologists and Toxicologists (Bryan-Lluka 1993).     

The mechanism of the 3H-noradrenaline releasing effect of various substrates of uptake1: multifactorial induction of outward transport

Summary The mechanism of action of indirectly acting sympathomimetic amines was studied in the rat vas deferens, after inhibition of vesicular uptake (by reserpine), of MAO (by pargyline) and of COMT (by U-0521). 1. K _m-values for the neuronal uptake of 12 substrates were determined as the IC₅₀ of the unlabelled substrate inhibiting the initial rate of neuronal uptake of 0.2 mol/l ³H-(–)-noradrenaline. The IC₅₀ ranged from 0.35 mol/l (for (+)-amphetamine) to 44.3 mol/l (for 5-HT). The V _max (determined for 8 substrates) was substrate-dependent. 2. Tissues were loaded with 0.2 mol/l ³H-(–)-noradrenaline and then washed out with amine-free solution. All 12 substrates of uptake₁, induced an outward transport of ³H-noradrenaline, and equieffective concentrations were positively correlated with K _m. Moreover, the EC₅₀ for release greatly exceeded K _m. It is proposed that this discrepancy between EC₅₀ and K _m is indicative of the fact that at least four factors (each one in strict dependence on K _m) contribute to the initiation of outward transport of ³H-noradrenaline: a) the appearance of the carrier on the inside of the axonal membrane (facilitated exchange diffusion), b) the co-transport of Na⁺, c) the co-transport of Cl^– (both lowering the K _m for ³H-noradrenaline at the inside carrier), and d) inhibition of the re-uptake of released ³H-noradrenaline (through competition for the outside carrier). 3. At least for amezinium, V _max. appears to limit the maximum rate of outward transport. 4. For some substrates (especially for the highly lipophilic ones) bell-shaped concentration-release curves were obtained. Apparently, inward diffusion of the substrates can lead to partial saturation of the inside carrier. Moreover, if release is expressed as a FRL (fractional rate of loss), loading with 37 mol/l ³H-(–)-noradrenaline decreased the releasing effect of various substrates. In this case the inside carrier appears to be partially saturated by the high axoplasmic concentration of ³H-noradrenaline. 5. Very high concentrations (especially of highly lipophilic substrates) were able to induce an additional intraneuronal release mechanism, presumably by increasing the pH inside storage vesicles.Abbreviations COMT catechol-O-methyl transferase - DOMAA dihydroxymandelic acid - DOPEG dihydroxyphenylglycol - FRL fractional rate of loss (rate of efflux/tissue tritium content) - 5-HT 5-hydroxytryptamine - MAO monoamine oxidase - OM-fraction sum of all O-methylated metabolites of noradrenaline, deaminated or not This study was supported by the Deutsche Forschungsgemeinschaft (Bo 521, Tr 96 and SFB 176). Some of the results were presented to the German Pharmacological Society (Langeloh 1986)A. L. was the recipient of a fellowship of the Humboldt-Foundation Send offprint requests to: U. Trendelenburg     

Noradrenaline release from rat sympathetic neurons evoked by P2-purinoceptor activation

The effects of ATP and analogues on the release of previously incorporated ³H-noradrenaline were studied in cultured sympathetic neurons derived from superior cervical ganglia of neonatal rats. Electrical field stimulation (40 mA at 3 Hz) of the neurons for 10 s markedly enhanced the outflow of tritium. ATP applied for 5 s to 2 min at concentrations of 0.01 to 1 mmol/l caused a time- and concentration-dependent overflow with half maximal effects at about 10 s and 100 mol/l, respectively. 2-Methylthio-ATP was equipotent to ATP in inducing ³H-overflow. ADP (100 mol/l), when applied for 2 min, also caused a small ³H-overflow, but , -methylene-ATP (100 mol/l), AMP (100 mol/l), R(–)N⁶-(2-phenylsiopropyl)-adenosine (R(–)-PIA; 10 mol/l) and 5-N-ethylcarboxamidoadenosine (NECA; 1 mol/l) did not. The ³H-overflow induced by 10 s applications of 100 mol/l ATP was abolished by suramin (100 mol/l) and reduced by about 70% by reactive blue 2 (3 mol/l). Electrically evoked overflow, in contrast, was slightly enhanced by suramin, but not modified by reactive blue 2. Xanthine amine congener (10 mol/l) and hexamethonium (10 mol/l) did not alter ATP-evoked release. Removal of extracellular Ca²⁺ from the medium reduced ATP- and electrically induced overflow by about 95%. Tetrodotoxin (1 mol/l) abolished electrically evoked ³H-overflow but inhibited ATP-induced overflow by only 70%. The ₂-adrenoceptor agonist UK 14,304 at a concentration of 1 mol/l diminished both electrically and ATP-evoked tritium overflow by approximately 70%. These results indicate that activation of P₂-purinoceptors stimulates noradrenaline release from rat sympathetic neurons. The release resembles electrically induced transmitter release, but additional mechanisms may contribute. Correspondence to: S. Boehm 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     

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.     

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     

Veratridine-induced outward transport of 3H-noradrenaline from adrenergic nerves of the rat vas deferens

Summary 1. The neuronal release by 100 mol/l veratridine of preloaded ³H-noradrenaline was studied in the rat vas deferens, the MAO, COMT and vesicular uptake of which were inhibited. To prevent any exocytotic release of the ³-Hamine, all solutions were calcium-free. Veratridine induced an early and a late peak of tritium efflux. The early peak was abolished by the presence of 1 mol/l desipramine, the late peak was abolished by 1 mol/l tetrodotoxin (administered subsequently to the first peak). The administration of veratridine plus 1 mmol/l ouabain resulted in only the early peak of efflux. 2. The peak response to veratridine plus ouabain was increased by a very early administration of veratridine plus ouabain (after 40 min of wash-out instead of the usual 130 min) (i. e., when the relative size of the axoplasmic distribution compartment was increased). However, very high axoplasmic ³H-noradrenaline levels (after loading with 37 instead of the usual 0.2 mol/l) reduced the height of the peak (when expressed as a FRL). 3. Substantially similar responses to vcratridine plus ouabain were obtained after loading with ³H-noradrenaline, ³H-adrenaline or ³H-dopamine. 4. As the second peak of veratridine-induced release is ouabain-sensitive, it appears to be caused by exhaustion of neuronal ATP stores; this, in turn, raises the intravesicular pH and induces efflux of ³H-noradrenaline from the vesicles into the axoplasm. The first peak, on the other hand, represents outward transport of ³H-noradrenaline from the axoplasmic compartment. Evidently, a pronounced vesicular distribution of ³H-noradrenaline takes place even after inhibition by reserpine of the vesicular uptake. 5. In preparations with intact vesicular uptake (MAO and COMT inhibited) a plateauresponse was obtained; in the presence of 10 mol/l Ro 4-2184 (a reserpine-like compound) a peak response was restored after loading with 0.2 mol/l³H-noradrenaline, less so after loading with 37 mol/l. 6. It is confirmed that veratridine (plus ouabain) exerts a reserpine-like effect when applied to tissues with intact vesicular uptake and intact MAO.Abbreviations COMT catechol-O-methyl transferase - DOMA dihydroxy mandelic acid - DOPEG dihydroxyphenylglycol - DOPAC dihydroxyphenylacetic acid - FRL fractional rate of loss - MAO monoamine oxidase - 5-HT 5-hydroxytryptamine with technical assistance of Marianne BablSupported by the Deutsche Forschungsgemeinschaft (Bo 521 and SFB 176) Send offprint requests to: H. Bönisch     

The effects of (−)-cromakalim and glibenclamide on uptake2 in guinea-pig trachealis muscle

Summary In a recent study, we have shown that hyperpolarization of cells by -adrenoceptor agonists results in stimulation of the uptake₂ process for catecholamines. The aim of the present study was to further explore the hypothesis that uptake₂ is dependent on membrane potential by examining the effects of the K⁺-channel opening drug, (–)-cromakalim, and the K⁺-channel blocking drug, glibenclamide, on uptake₂ of isoprenaline. The effects of these drugs were examined in guinea-pig trachealis muscle, in which isoprenaline and cromakalim cause hyperpolarization, and in rat heart, in which isoprenaline and cromakalim have little effect on membrane potential.In guinea-pig trachealis muscle segments, 1 mol/l glibenclamide reduced uptake₂ (as measured by the steady-state rate of corticosterone-sensitive formation of ³H-3-O-methylisoprenaline normalized for the isoprenaline concentration) in tissues incubated in concentrations of ³H-(±)-isoprenaline that hyperpolarize the muscle (25 and 250 nmol/l) but not at an isoprenaline concentration that did not hyperpolarize the muscle (1 nmol/l). (–)-Cromakalim (10 mol/l), which hyperpolarizes the trachealis muscle, increased uptake₂ of isoprenaline (1 or 25 nmol/l) and this effect of (–)-cromakalim was inhibited by glibenclamide. In rat hearts perfused with 1 or 25 nmol/l ³H-(±)-isoprenaline and 10 mol/l U-0521 to inhibit catechol-O-methyltransferase, the rate of uptake₂ of isoprenaline was unaffected by cromakalim or glibenclamide.The results show that hyperpolarization of cells by various mechanisms can result in stimulation of uptake₂ of catecholamines and provide further evidence to support the hypothesis that the uptake₂ transport process is driven by the membrane potential of cells.Preliminary results of part of this study were presented to the German Society for Pharmacology and Toxicology (Bryan-Lluka and Vuocolo 1991)Correspondence to L. J. Bryan-Lluka at the above address     

Presynaptic dopamine DA2-receptors in rabbit jejunal arteries

Summary Excitatory junction potentials (e.j.ps) evoked by nerve stimulation with 15 pulses at 1 Hz were recorded from muscle cells of rabbit isolated jejunal arteries. LY 171555 1 mol/l, SKF 38393 10 mol/l, dopamine 10 ol/l and clonidine 0.1 mol/l depressed all e j.ps in the train. The percentage inhibition was inversely related to the number of pulses. S- and R-sulpiride, 10 mol/l, domperidone 1 mol/l, SCH 23390 1 mol/l and rauwolscine 1 mol/l did not change, or even depressed the first e j.ps. Of these compounds only S- and R-sulpiride, 10 mol/l and rauwolscine 1 mol/l facilitated the late e.j.ps. The percentage facilitation increased with the number of pulses until a maximum was reached; rauwolscine 1 ol/l had the largest effect. S- and R-sulpiride, 10 mol/l, as well as domperidone 1 ol/l antagonized the action of LY 171555 1 mol/l. S-Sulpiride was more potent than its R-isomer. SCH 23390 1 mol/l and rauwolscine 1 mol/l blunted the effect of SKF 38393 10 mol/l. Rauwolscine 1 mol/l slightly reduced the inhibition by dopamine 10 mol/l; S-sulpiride 10 mol/l was antagonistic only in the presence of rauwolscine 1 mol/l. When rauwolscine 1 mol/l, prazosin 0.1 mol/l, propranolol 1 mol/l and cocaine 10 mol/l was added to the medium, dopamine 10 mol/l continued to produce the same depression of e j.ps, as in the absence of these compounds. Under such conditions S-sulpiride 10 mol/l also counteracted dopamine 10 gmol/l. Rauwolscine 1 mol/l prevented the effect of clonidine 0.1 mol/l. The antagonists were not absolutely selective against only one type of agonist. We suggest that both presynaptic DA₂- and postsynaptic DA₁-receptors are present in rabbit jejunal arteries. The activation of either receptor-type may depress the e j.ps. Dopamine interferes with neuroeffector transmission due to ₂-adrenoceptor agonist properties; its DA₂-effect is unmasked only after ₂-adrenoceptor blockade. There was no evidence for a co-transmitter function of dopamine. Send offprint requests to P. Illes at the above address     

Cultured chick sympathetic neurons: ATP-induced noradrenaline release and its blockade by nicotinic receptor antagonists

The ATP-induced increase in tritium outflow from cultured chick sympathetic neurons prelabelled with [³H]-noradrenaline was investigated.Seven days-old dissociated cell cultures of embryonic paravertebral ganglia, loaded with [³H]-noradrenaline (0.05 M), were superfused in the presence of (+)-oxaprotiline and exposed to ATP, ATP-analogues, or 1,1-dimethyl-4-piperazinium (DMPP) for 2 min. ATP (3 LM-3 mM), 2-methylthio-ATP (3–100 M), as well as DMPP (10 and 100 M) induced a significant overflow of tritium. The EC₅₀-value of ATP was 20 M. Both the ATP-induced and the DMPP-induced tritium overflow was Ca²⁺-dependent and sensitive to tetrodotoxin (0.3 M) and -conotoxin (0.1 M); in addition, it was inhibited by the ₂-adrenoceptor agonist 5-bromo-6-(2-imidazoline-2-ylamino)-quinoxaline (UK-14,304; 1 M). The effects of ATP and DMPP were not additive. The ATP-induced as well as the DMPP-induced overflow of tritium was diminished by the P₂-purinoceptor antagonists suramin (300 M) and reactive blue 2 (3 M); in all 4 cases, the inhibition amouted to approximately 40%. The tritium overflow induced by ATP or DMPP was almost abolished by the nicotinic receptor antagonist mecamylamine (10 M) and markedly inhibited by hexamethonium (100 M). Neither ATP nor electrical stimulation caused an overflow of tritium from cultures loaded with [³H]-choline.The results suggest that ATP at molar concentrations induces noradrenaline release from cultured chick sympathetic neurons via an action on a subclass of the nicotinic cholinoceptor.     

Evidence against a functional link between noradrenaline uptake mechanisms and presynaptic alpha-2 adrenoceptors

Summary Slices prepared from rat cerebral cortex were labelled with ³H-noradrenaline and superfused. Electrical field stimulation was carried out 15 min (S₁) and 45 min (S₂) after the start of collection of 5-min samples using 4 pulses delivered at 100 Hz. Drugs acting at ₂-adrenoceptors were added 20 min before S₂, and their effects were evaluated using the S₂/S₁-ratio. The ₂-adrenoceptor antagonists idazoxan (1 mol/l) and rauwolscine (1 mol/l) failed to increase stimulation-evoked overflow of radioactivity in the absence or presence of the noradrenaline reuptake inhibitor desipramine (1 gmol/l). This indicates that the duration of electrical stimulation was too short to allow development of ₂-adrenoceptor-mediated auto-inhibition by released noradrenaline. The effect of clonidine (3–1000 nmol/l) on stimulation-evoked overflow of radioactivity was tested in the absence and presence of three different reuptake inhibitors (desipramine, 1 ol/l; maprotiline, 1 ol/l; cocaine, 10 mol/l). The analysis yielded identical concentration-response curves under all conditions. These results argue against an action of inhibitors of neuronal reuptake of noradrenaline at the presynaptic ₂-adrenoceptor and against the concept of a functional link between uptake site and receptor. Send offprint requests to E. A. Singer     

β-Endorphin-(1-27) is a naturally occurring antagonist of the reinforcing effects of opioids

Summary The influence of inhibitors of metabolism and uptake of noradrenaline on the ³H-noradrenaline removal from the perfusion fluid by the isolated rat liver was studied. Livers were perfused with 3 nmol/l ³H-noradrenaline and ³H-noradrenaline and ³H-metabolites were determined in effluent, liver and bile. After the perfusion with 14,900 ±920 dpm · g^–1 · min^–1 during 90 min, cumulative removal of tritium was 323,574 ± 63,103 dpm/g. ³H-metabolites recovered from the liver after 90 min perfusion represented 71.1 ± 9.0% of total metabolite formation. Only the OMDA-fraction appeared in the perfusate; its approach to steady state of efflux was slow. The inhibition either of MAO or COMT changed neither the total removal of tritium nor the ³H-metabolites recovered from the liver. Cocaine (10 mol/l) reduced the accumulation of ³H-noradrenaline in the liver. The uptake₂ inhibitor corticosterone (30 mol/l) diminished total removal of tritium and the ³H-metabolites recovered from the liver without changing the accumulation of ³H-noradrenaline. The hypothesis of two different compartments, one responsible for the metabolism and the other for the accumulation of the amine is discussed.Abbreviations NA noradrenaline - NMN normetanephrine - OMDA O-methylated deaminated metabolites - MAO monoamine oxidase - COMT catechol-O-methyl transferase Send offprint requests to M. C. Rubio     

The membrane potential of vascular smooth muscle appears to modulate uptake2 of 3H-isoprenaline

Summary Segments of the rabbit main pulmonary artery and of its two branches were exposed for 10 min to 50 nmol/l ³H-(±)-isoprenaline, and the accumulation of tritium in the tissue was determined; COMT was inhibited in all experiments. 1. The accumulation of the tritium label was sensitive to 3-O-methyl-isoprenaline (OMI), showing that this vascular smooth muscle possesses uptake₂. 2. In the presence of 0.01 to 1 mol/l (–)-noradrenaline, the accumulation of tritium was depressed (in a concentration-dependent manner). This decline involved the OMI-sensitive accumulation of ³H-isoprenaline. 3. The presence of any one of three selective alpha₁-adrenoceptor antagonists (1 gmol/l prazosin, 1 mol/l WB4101, 10 gmol/l corynanthine) prevented the effect of 1 mol/l (–)-noradrenaline on the accumulation of tritium. However, in the absence of (–)-noradrenaline, the three antagonists failed to affect the accumulation of tritium. 4. 10 mol/l nicorandil caused the accumulation of tritium to increase. 5. As stimulation of alpha₁-adrenoceptors is known to result in depolarization, and as nicorandil is known to hyperpolarize this smooth muscle, it is concluded that the resting membrane potential modulates uptake₂. Send offprint requests to U. Trendelenburg at the above address     

The transport of (+)-amphetamine by the neuronal noradrenaline carrier

Summary PC-12 cells (a clonal line of rat phaeochromocytoma cells) take up noradrenaline by a transport system which is identical with the neuronal amine transport system (uptake₁). The uptake of ³H-noradrenaline into reserpine-pretreated PC-12 cells (monoamine oxidase inhibited) was saturable (K_m=0.6±0.1 mol/l), dependent on sodium and chloride, and competitively inhibited by (+)-amphetamine (K_i=0.18±0.04 mol/l), cocaine (K_i=0.55±0.15 mol/l) and desipramine (K_i=4.3±0.6 nmol/l). The uptake and accumulation of ³H (+)-amphetamine showed characteristics comparable to those of ³H-noradrenaline, since the uptake of ³H (+)-amphetamine (0.1 mol/l) was reduced by omission of sodium or chloride from the incubation medium. The sodium-sensitive component of uptake and accumulation of ³H (+)-amphetamine was fully inhibited by cocaine and desipramine. The IC₅₀ of desipramine for inhibition of the sodium-sensitive component of the 1-min uptake of ³H (+)-amphetamine (20 nmol/l) was about 2 nmol/l, i.e., identical with the K_i for inhibition of uptake of ³H-noradrenaline. At concentrations above 1 mol/l, desipramine additionally caused an inhibition of the sodium-independent permeation of ³H (+)-amphetamine into PC-12 cells.Hence, by using a homogeneous population of cells endowed with uptake₁, it is possible to demonstrate — besides a pronounced lipophilic entry — a carrier-mediated uptake of ³H (+)-amphetamine.Some of the results were communicated to the German Pharmacological Society (Bönisch 1981). This study was supported by the Deutsche Forschungsgemeinschaft (Bo 521)     

Extraneuronal uptake and O-methylation of 3H-adrenaline in the rabbit aorta

Summary The influence of uptake₂ inhibitors on the Omethylation and accumulation of ³H-adrenaline by the isolated rabbit aorta was studied. Strips were incubated with 0.05 mol/l ³H-(–)-adrenaline during 15 min. Monoamine oxidase and uptake, were inhibited and the ³H-adrenaline present in the tissue was measured as well as the metabolites found in the tissue and in the incubation fluid. In another series of experiments, monoamine oxidase, uptake₁ and catechol-O-methyl transferase (COMT) were inhibited, and tritium accumulation was measured in the tissue.When COMT was inhibited, inhibitors of uptake₂ produced a maximal reduction of ³H-adrenaline accumulation that did not exceed 50%. When COMT was in tact, inhibitors of uptake₂ diminished total ³H-removal and, more markedly, O-methylation and concomitantly increased the tissue content of ³H-adrenaline.Mineralocorticoids (corticosterone and deoxycorticosterone acetate) inhibited ³H-adrenaline uptake (when COMT was inhibited) and ³H-metanephrine formation (when COMT was functional) as effectively as did sexual steroids (17--oestradiol, progesterone and testosterone); hydrocortisone (hemisuccinate or phosphate) had no effect (for concentrations up to 120 mol/l).At the end of the incubation some strips were washed out with amine-free solution. Compartmental analysis of the efflux showed that the amine had distributed into three extraneuronal compartments (compartment I, II and III, with half times of 0.4, 4 and 15 min, respectively). Corticosterone (120 mol/l). decreased the amount of ³H-adrenaline in compartment III and simultaneously increased the amount of the amine in compartment I (extracellular space).The extraneuronal accumulation of ³H-adrenaline in rabbit aorta can be only partially ascribed to uptake₂, as already stated by other authors; our results clearly show that inhibition of uptake₂ increases the amount of ³H-adrenaline in the extracellular space, i. e., uptake₂ creates a concentration gradient for ³H-adrenaline in the extracellular space; elastin and collagen represent very probably the site of binding of ³H-adrenaline which is independent of uptake₂.Abbreviations COMT Catechol-O-methyltransferase - DOCA deoxycorticosterone acetate - DOMA 3,4-dihydroxymandelic acid - DOPEG 3,4-dihydroxyphenylglycol - MAO monoamine oxidase - OMDA O-methylated and deaminated metabolites - MOPEG methoxyhydroxyphenylglycol - VMA methoxyhydroxymandelic acid A preliminary account of some of the results was presented to the 7th International Catecholamine Symposium in Amsterdam. Supported by Instituto Nacional de Investigação Cientffica (INIC, FmP1)PhD student with a grant from JNICT (Programa Ciência)Correspondence to F. Martel at the above address