Estimation of the biophase concentration of noradrenaline at presynaptic α2-adrenoceptors in brain slices

Summary The aim of the present study was to determine the local concentrations of noradrenaline existing at presynaptic ₂-adrenoceptors during electrical pulse train stimulation of brain slices at different frequencies. The experiments are based on the assumption that the concentration of released noradrenaline at the ₂-adrenoceptors exerting a certain autoinhibition should be equal to the concentration of exogenous noradrenaline causing the same inhibition under conditions in which any influence of the released transmitter is excluded. In order to avoid autoinhibition, hippocampus and cortex slices of the rabbit and the rat, prelabelled with [³H]noradrenaline and superfused in presence of an uptake inhibitor, were electrically stimulated using 4 pulses delivered at 100 Hz (POP stimulation). Exogenous noradrenaline diminished the overflow of tritium elicited by POP stimulation in a concentration-dependent manner. In rabbit brain tissues the EC₅₀ value and maximum inhibition of noradrenaline release were found to be approximately 6 nmol/l and more than 95%, respectively, whereas in rat tissues the corresponding values were between 20 and 30 nmol/l and approximately 90%. When electrical stimulation was performed with trains of 36 pulses delivered at 0.1, 0.3 or 3 Hz in absence or presence of an uptake inhibitor, the ₂-adrenoceptor antagonist yohimbine (1 or 10 mol/l) enhanced the evoked tritium overflow in a manner which was dependent on the frequency of stimulation and on blockade of the re-uptake mechanism. The facilitatory effects of yohimbine reflected an extent of autoinhibition which was between 53% (36 pulses/0.1 Hz, no uptake inhibitor) and 85% (36 pulses/3 Hz, uptake inhibitor present) in rabbit and between 16% (36 pulses/0.3 Hz, no uptake inhibitor) and 71% (36 pulses/3 Hz, uptake inhibitor present) in rat brain slices. Accordingly, the corresponding estimated biophase concentrations of noradrenaline were generally higher in rat than in rabbit tissues (they were between 32.5 and 74.5 or 5.1 and 51.6 nmol/l in the presence or absence of an uptake inhibitor, respectively, in the rat, and between 15 and 23.1 or 6.1 and 18.6 nmol/l in the rabbit). The observed frequency dependence of the effect of re-uptake blockade on the calculated biophase concentrations of noradrenaline would be compatible with the idea of a dependence of the effectiveness of the re-uptake mechanism on the firing rate of the neurone in being more effective at lower frequencies. Moreover, the stikingly low biophase concentrations of noradrenaline suggest that also in brain tissue noradrenaline causes lateral inhibition of release as has recently been shown for guinea-pig vas deferens. Send offprint requests to C. Allgaier at the above address     

Blood pressure changes modify the release rates of catecholamines in the intermediate nucleus of the solitary tract

Summary In anaesthetized cats, the intermediate aspect of the nucleus of the solitary tract (NTS) was bilaterally superfused with artificial CSF through push-pull cannulae. The release of the endogenous catecholamines dopamine, noradrenaline and adrenaline was determined in the superfusates radioenzymatically. Blood pressure changes were elicited by intravenous injections of drugs (noradrenaline or chlorisondamine), or electrical stimulation of the intermediate NTS with the tip of the push-pull cannula.Intravenous injections of noradrenaline (3 or 10 g/kg) elicited a rise in the arterial blood pressure which was associated with a decrease in the release rate of adrenaline in the intermediate NTS. The release rates of dopamine and noradrenaline were not influenced. The intravenous injection of chlorisondamine (3 mg/kg) lowered blood pressure and diminished the release rate of dopamine in the intermediate NTS. The release rate of noradrenaline was not modified by chlorisondamine. Electrical stimulation of the intermediate NTS contralateral to the superfused nucleus increased moderately the arterial blood pressure and decreased the release rate of noradrenaline and dopamine, while the release of adrenaline was not influenced. The findings suggest that experimentally induced changes in the arterial blood pressure by drugs injected intravenously modify the release rates of adrenaline and dopamine in the intermediate NTS so as to counteract the blood pressure change. In the intermediate NTS, release of adrenaline from adrenergic nerve terminals seems to act hypertensive. The results obtained with chlorisondamine point to a hypotensive function of endogenous dopamine in the intermediate NTS. Send offprint requests to N. Singewald at the above addressThis work was supported by the Fonds zur Förderung der wissenschaftlichen Forschung     

Depression by neuropeptide Y of noradrenergic inhibitory postsynaptic potentials of locus coeruleus neurones

Summary Intracellular recordings were performed in a pontine slice preparation of the rat brain containing the locus coeruleus (LC). The spontaneous firing of action potentials was prevented by passing continuous hyperpolarizing current via the recording electrode. Focal electrical stimulation evoked a synaptic depolarization (PSP) followed by a hyperpolarization (IPSP). Neuropeptide Y (NPY; 0.1 mol/l) inhibited the IPSP only. Pressure ejection of noradrenaline produced hyperpolarization which was potentiated in the presence of NPY (0.1 mol/l). Hence, NPY appears to inhibit the release of noradrenaline from dendrites or recurrent axon collaterals of LC neurones. Correspondence to: P. Illes at the above address     

Effects of the novel dopamine DA2-receptor agonist carmoxirole (EMD 45609) on noradrenergic and purinergic neurotransmission in rat isolated kidney

Summary The effects of the classical dopamine DA₂-receptor agonist quinpirole (LY 171555) and the recently characterized DA₂-receptor agonist, carmoxirole (EMD 45609), on neurotransmission in rat isolated kidney were investigated. After preincubation with ³H-noradrenaline, the renal nerves were electrically stimulated. The stimulation induced (S-I) outflow of radioactivity was taken as an index of noradrenaline release. Quinpirole (0.3 mol/l) inhibited S-I outflow of radioactivity and pressor responses to renal nerve stimulation (RNS) at 1 Hz. Both effects of quinpirole were blocked by the DA₂-receptor antagonist S(–)-sulpiride (10 mol/l). The ₁, ₂-adrenoceptor antagonist phentolamine (1 mol/l) did not block the inhibitory effect of quinpirole. Carmoxirole (0.003 and 0.03 mol/l) did not alter and carmoxirole (0.3 mol/l) even enhanced S-I outflow of radioactivity, however, pressor responses to RNS were markedly reduced by carmoxirole (0.003–0.3 mol/l). Pressor responses to RNS were also markedly reduced by the ₁-adrenoceptor antagonist prazosin (0.1 mol/l). Carmoxirole (0.3 mol/l), prazosin (0.1 mol/l) and phentolamine (1 mol/l) totally abolished pressor responses to exogenous noradrenaline (0.05 mol/l). In contrast, quinpirole (0.3 mol/l) did not alter pressor responses to exogenous noradrenaline (0.05 mol/l). Furthermore, carmoxirole (0.003–0.3 mol/l) markedly reduced pressor responses induced by the ₁-adrenoceptor agonist methoxamine (1 mol/l) but even the highest concentration of carmoxirole (0.3 mol/l) had no effect on pressor responses induced by bolus injections of either neuropeptide Y (1.5 ng) or angiotensin II (1 ng). Phentolamine (1 mol/l) by itself markedly enhanced S-1 outflow of radioactivity and pressor responses to RNS were virtually unchanged. In the presence of phentolamine carmoxirole (0.03 and 0.3 mol/l) and quinpirole inhibited S-I outflow of radioactivity and pressor responses to RNS. Phentolamine resistant pressor responses to RNS were also inhibited by the P_2X-receptor desensitizing agent , -methylene adenosine triphosphate (mATP, 1 mol/l), which by itself in the presence of phentolamine did not alter S-I outflow of radioactivity. The inhibitory effects of carmoxirole (0.3 mol/l) in the presence of phentolame (1mol/l) were antagonized by S(–)-sulpiride (10 mol/l). The data suggest that activation of prejunctional DA₂-receptors by quinpirole inhibits noradrenaline release and thereby reduces pressor response to RNS at 1 Hz in rat isolated kidney. Carmoxirole activates prejunctional inhibitory DA₂-receptors, but this effect is masked by simultaneous blockade of inhibitory prejunctional -adrenoceptors. Pressor responses to RNS at 1 Hz in rat isolated kidney are largely due to neuronally released noradrenaline whereas phentolamine resistant pressor responses to RNS at 1 Hz are most likely due to ATP, which is co-released with noradrenaline. Carmoxirole inhibits pressor responses to RNS at 1 Hz as well as pressor responses induced by either exogenous noradrenaline or methoxamine by blocking postjunctional ₁-adrenoceptors. In addition carmoxirole and quinpirole seem to block phentolamine resistant pressor responses by inhibiting ATP release through activation of prejunctional DA₂-receptors. Send offprint requests to L. C. Rump at the above address     

Potentiation of potassium-evoked noradrenaline and neuropeptide Y co-release by cardiac energy depletion: role of calcium channels and sodium-proton exchange

Summary The role of the cardiac energy status in the potassium-evoked exocytosis of both noradrenaline and the sympathetic co-transmitter neuropeptide Y (NPY) was investigated in the guinea-pig perfused heart. The transmitter release was stimulated by potassium depolarization (10–80 mmol/l) during normoxic perfusion (pO₂ > 100 mmHg) in the presence of glucose (11 mmol/l) and at various periods (5–40 min) of cardiac energy depletion. Energy depletion was induced either by anoxia (pO₂ < 5 mmHg) or by cyanide intoxication (1 mmol/l), both in combination with glucose-free perfusion. Endogenous noradrenaline and NPY were determined in the coronary venous overflow by high-pressure liquid chromatography combined with electrochemical detection and by radioimmunoassay, respectively.Under normoxic conditions potassium depolarization evoked a co-release of both transmitters [molar ratio 862 (noradrenaline) :1 (NPY)] at a threshold concentration of 40 mmol/l potassium. This transmitter overflow was characterized by its dependence on extracellular calcium and calcium influx through voltage-dependent neuronal calcium channels of the N-type. Cardiac energy depletion was accompanied by an acceleration and an enhancement of the potassium-evoked transmitter overflow. In comparison to normoxia, a 10-fold increased transmitter overflow with a comparable molar ratio [709 noradrenaline :1 (NPY)] was evoked by 40 mmol/l potassium after 10 min of either anoxia or cyanide intoxication. This sensitization to potassium depolarization reached a peak after 10 min of energy depletion and was characterized by a markedly reduced threshold concentration (10 mmol/l potassium). The enhanced sympathetic transmitter overflow in anoxia was suppressed by addition of glucose (11 mmol/l) to the perfusion buffer, suggesting that the sensitization of the overflow of noradrenaline and NPY to potassium depolarization requires a cessation of energy metabolism. The sensitization of the potassium-evoked (20 mmol/l) sympathetic transmitter overflow by energy depletion was further characterized: Consistent with an exocytotic release mechanism, the overflow was calcium-dependent. In contrast to normoxia, however, blockade of neuronal N-type calcium channels by either co-conotoxin (100 nmol/1) or cadmium chloride (50 mol/l) failed to reduce the potassium-evoked overflow of noradrenaline and NPY. In anoxia blockade of sodium-proton exchange by amiloride (1 mmol/l) or more specifically by ethylisopropylamiloride (1 mol/l) markedly attenuated the potassium-evoked transmitter overflow. Likewise, suppression of the potassium-evoked overflow of noradrenaline and NPY from the energy-depleted heart was achieved by extracellular acidosis (pH 6.0). In contrast, during normoxia blockade of sodium-proton exchange by either ethylisopropylamiloride (1 mol/l) or by extracellular acidosis (pH 6.0) did not affect the potassium-evoked (80 mmol/l) transmitter overflow. These findings suggest that the sensitization of sympathetic nerve endings to potassium depolarization, caused by cardiac energy depletion, requires sodium entry into the sympathetic nerve ending via sodium-proton exchange.The results of the present study indicate, that the threshold concentration for the potassium-evoked exocytotic release of noradrenaline and NPY from the guinea-pig isolated perfused heart is intimately coupled to the energy status of cardiac sympathetic nerve fibres. The energy status not only determines the quantity of the transmitters released but also the mode of sodium and calcium entry triggering the depolarization-evoked transmitter overflow.Preliminary findings were reported at the 63rd Scientific Sessions of the American Heart Association, Dallas/USA (Haass et al., 1990b) and at the Annual Meeting of the European Section of the International Society for Heart Research, Leuwen/Belgium (Haass et al. 1991b)Supported by a grant from the Deutsche Forschungsgemeinschaft (SFB 320 — Herzfunktion and ihre Regulation) Correspondence to M. Haass at the above address     

Effect of chronic clonidine treatment on the turnover of noradrenaline and dopamine in various regions of the rat brain

Summary The turnover of noradrenaline (NA) and dopamine (DA) was estimated in various rat brain regions by measuring the depletion of the amines after inhibition of their biosynthesis by -methyltyrosine. Acute treatment with clonidine (0.1 mg/kg) reduced NA turnover in the brain stem, hypothalamus and rest of the brain but had no effect on DA turnover in the corpus striatum and rest of the brain. After chronic clonidine treatment (0.1 mg/kg, twice daily for 15 days), NA turnover was not affected by an additional injection of clonidine in the brain stem or in the hypothalamus but was still markedly reduced in the rest of the brain. In addition, DA turnover was reduced in the corpus striatum and rest of the brain, an effect which was also observed after a single injection of a high dose of clonidine (1 mg/kg). These findings suggest that a chronic administration of clonidine may cause regionally differential changes in the sensitivity of central NA receptors.     

Metabolism of endogenous and exogenous noradrenaline in the rabbit perfused heart

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

Blockade of presynaptic α-receptors and of amine uptake in the rat brain by the antidepressant mianserine

Summary Mianserine (Org GB 94, Tolvon^®) is 1, 2, 3, 4, 10, 14b-hexahydro-2-methyl-dibenzo [c, f] pyrazino [1, 3-a] azepine hydrochloride, a new antidepressant drug. Its effect on noradrenaline release and its capacity to inhibit amine uptake were investigated. Mianserine increased the release of ³H-noradrenaline from field-stimulated cortical slices previously labelled with the tritiated transmitter. The assumption that this effect is due primarily to the blockade of the presynaptic noradrenergic -receptors is supported by the fact that mianserine failed to augment ³H-noradrenaline release further after blockade of the presynaptic -receptors by phentolamine. In the reciprocal experiment, phentolamine failed to augment ³H-noradrenaline release after exposure of the slices to mianserine. The hypothesis is further reinforced by the fact that mianserine antagonized the reduction of ³H-noradrenaline release by clonidine in the same manner as the -blocking drugs phentolamine and phenoxybenzamine. Mianserine inhibited noradrenaline uptake in vitro and in vivo (in the rat heart and midbrain-diencephalon synaptosomes from pretreated rats.) Only a marginal inhibition of serotonin uptake was observed.It therefore appears that mianserine increases the concentration of noradrenaline in the synaptic cleft by blocking the presynaptic -receptors and inhibiting uptake. Whether or not this increase has functional consequences at postsynaptic noradrenergic receptor sites is unknown. It is possible, however, that postsynaptic receptor blockade counteracts the increase in available noradrenaline.A part of these results was presented at the 16th Spring Meeting of the German Pharmacological Society, Mainz, March 4–7, 1975     

Release of noradrenaline by the ionophore X537A from normal and reserpinized guinea-pig atrium

Summary The effects of ionophore X537A on the release of ³H-noradrenaline and its metabolites from the superfused guinea-pig left atrium were investigated. Concentrations of ionophore of 10 and 30 M greatly increased the release of tritium. Of the total increase in radioactivity elicited by X537A 44% was accounted for as noradrenaline and 50% was due to deaminated metabolites. The ionophore-evoked release of tritium was independent of the extracellular calcium ions and was not affected by agents which modify calcium movements such as verapamil, ryanodine, ruthenium red and tetracaine. X537A released ³H-noradrenaline from extragranular sites in MAO-inhibited atria from reserpine-treated animals and this release was also calcium independent. It is concluded that the ability of X537A to release noradrenaline from vesicular or cytoplasmic sites is not related to its ability to couple with and transport calcium ions through membranes. The ionophore might modify the ionic distribution outside and inside the neuronal membrane which would lead to leakage of the transmitter.     

Cardiac sensitization induced by phenobarbitone and prolonged by CS2

The arrhythmogenic effect of 8 g/kg noradrenaline given i.v. was increased in male rats pretreated 1–2 day s earlier with phenobarbitone and starved from the time of the first phenobarbitone injection (80 mg/kg followed by 50 mg/kg 6 h later). Daily exposure to 4.0 mg/l CS₂ (first exposure 24 h after the first phenobarbitone injection) for 4 h prevented the decline in susceptibility on the 3rd and 4th days after phenobarbitone, when the reaction of unexposed rats to noradrenaline returned to normal.