On the uptake of exogenous catecholamines by adrenal chromaffin cells and nerve endings

Summary Light-microscopic autoradiography has revealed characteristic labelling patterns in adrenal medullary cells following the intravenous administration of different catecholamines. The uptake patterns for [³H] dopa, [³H] dopamine, [³H] noradrenaline and [³H] adrenaline have been compared. In all cases A cells were more active than NA cells and cells situated in the zone nearest the cortex demonstrated a markedly higher rate of uptake than central cells. It was concluded that adjacent chromaffin cells with very similar morphology may differ as much as 50 fold in their capacities to incorporate exogenous amines. The adrenergic nature of the innervation of the vessels of the adrenal cortex and capsule in the mouse was confirmed.     

Antagonism of 5-Hydroxytryptamine by Methiothepin shown in Micro-electrophoretic Studies of Neurones in the Lateral Geniculate Nucleus

THERE has been little success in the search for a specific antagonist of the actions of 5-hydroxytryptamine (5-HT) on central neurones, although several compounds reduce the effects of both tryptamine derivatives and catecholamines in the central nervous system^1,2. The recent report that lysergic acid diethylamide blocked the excitant action of 5-HT, but not that of noradrenaline, on medullary reticular neurones³ has not been confirmed⁴. Moreover, an earlier investigation of olfactory bulb neurones indicated that lysergic acid diethylamide blocked the action of noradrenaline more readily than that of 5-HT⁵.     

Effects of neurotransmitters and other pharmacological agents on 32Pi incorporation into phospholipids of the iris muscle of the rabbit

The effects of norepinephrine, other catecholamines, α- and β- adrenergic receptor blocking agents and acetylcholine on the incorporation of ³²Pi into phospholipids of the iris muscle of the rabbit were studied $\text{in vitro}$. There was a marked stimulation of ³²Pi into phosphatidic acid (PhA), phosphatidyl inositol (PhI) and to a much lesser extent phosphatidyl choline but not into phosphatidyl ethanolamine. The increase in the ³²P labeling of PhA and PhI in the presence of norepinephrine or acetylcholine, which ranged from 2- to 6-fold, was found to be time- and concerntration-dependent. Under our experimental conditions, several adrenergic drugs, including DL-propranolol, phentolamine, isoproterenol, phenylephrine, but not sotalol, increased markedly (nearly up to 5-fold) the ³²Pi incorporation into PhA and PhI of the iris. In contrast, phenoxybenzamine, an α-receptor blocker, blocked completely the stimulatory effects of norepinephrine on phospholipid synthesis. The stimulation of phospholipid synthesis by acetylcholine was completely abolished by atropine. Incorporation of ³²Pi into PhA and PhI was significantly increased in the presence of serotonin, dopamine, epinephrine or histamine. Addition of γ-aminobutyric acid or cyclic AMP was ineffective. These observations suggest that in the iris muscle of the rabbit, which is innervated by cholinergic and adrenergic fibers, the phospholipid effect is probably a membrane effect that is not associated with synaptic transmission.     

Basic properties of beta adrenergic receptors mediating melanosome dispersion of melanophores in a cyprinid fish, Zacco temmincki

In melanophores of a cyprinid fish, Zacco temmincki, receptor mechanisms of melanosome dispersion induced by catecholamines were examined. While possessing a melanosome-aggregating action in higher concentrations, isoproterenol and epinephrine in lower concentrations acted to disperse melanosomes. Norepinephrine, epinine and dopamine altered their action from melanosome aggregation to melanosome dispersion after alpha adrenergic blockade. The catecholamine-induced melanosome dispersion was inhibited by beta adrenergic blocking agents. Mediation of dispersion is regulated through beta adrenergic receptors. The beta adrenergic responses were unaffected by mersalyl, a sulfhydryl inhibitor. A prospective substance acting in dispersing melanosomes appears to be adrenaline, but not noradrenaline.     

Blood Concentrations of Adrenaline in Dogs after Intravenous Administration of 5-Hydroxytryptamine

THE release of catecholamines from the adrenal medulla of the cat by close intra-arterial injection of 5-hydroxytryptamine (5-HT) has been demonstrated by Reid¹. We have shown a similar release of catecholamines following intravenous injections of 5-HT in the dog, identified the catecholamine as adrenaline and demonstrated an enhancement of the release by treatment of the dog with hexamethonium.     

Regulation of Ca<Superscript>2+</Superscript> influx in proliferating and differentiating murine myoblasts with participation of L-type Ca<Superscript>2+</Superscript> channels

The basic mechanisms of regulation of Ca²⁺ influx have been studied in murine myoblasts proliferating and differentiating in culture. The presence of L-type Ca²⁺ channels in proliferating myoblasts is shown for the first time. It is also shown that the influx of Ca²⁺ through these channels is regulated by the adrenergic system. The influx of Ca²⁺ after activation of the adrenergic system by addition of adrenaline has been estimated in comparison with the contribution of reticular stocks exhausted by ATP in calcium-free medium. The Ca²⁺ influx in proliferating myoblasts is regulated by β-2 adrenergic receptors whose action is mediated by adenylate cyclase through L-type calcium channels. In differentiating myoblasts, the adrenaline-induced Ca²⁺ influx is substantially lower than in proliferating cells, and maximal influx of Ca²⁺ may be reached only upon exhaustion of reticular stocks.     

Calcium-activated potassium channels in liver cells

Activation of certain membrane receptors increases the concentration of Ca²⁺ in the cytosol of hepatocytes. Since in most species these cells possess a P_K(Ca) mechanism, the outcome is a rise in P_K. This can be blocked by quinine, apamin and certain neuromuscular blocking agents. The binding of labelled apamin to hepatocytes has been studied under physiological conditions, and the relationship between the binding sites and K⁺ channels is discussed. The physiological role of the P_K(Ca) mechanism in hepatocytes is unclear, though it is largely responsible for ‘adrenaline hyperkalaemia’.     

The effects of biogenic monoamines and related agonists and antagonists on the isolated,perfused branchial heart of sepia officinalis L. (cephalopoda)

1. The chronotropic and inotropic effects of biogenic monoamines were examined on the isolated and perfused branchial heart of the common cuttlefish Sepia officinalis (L.).2. Adrenaline, noradrenaline and dopamine caused concentration-dependent increases in pressure amplitude, dopamine being 100-fold less potent than adrenaline and noradrenaline. The catecholamines hardly affected frequency.3. Octopamine, histamine and GABA did not influence normal heartbeat.4. Serotonin was either ineffective or produced variable responses, whereby the efficacy of the substance was not graded to the concentrations applied. It is supposed that serotonin is not involved in branchial heart regulation.5. The actions of different adrenergic agonists and antagonists indicate the presence of a myocardial adrenoceptor which closely resembles the α₁-type.     

Metabolic responses to catecholamines in dogs injected with a single dose of triiodothyronine.

Lipolytic and glycogenolytic responses to catecholamine infusions were studied in resting dogs before and 20 h following administration of a single dose (0.1 mg/kg) of triiodothyronine (T3). In the dogs pretreated with T3 much higher increases in the plasma FFA concentration were found both during noradrenaline and adrenaline infusions in comparison with control experiments. Adrenaline-induced increases in blood LA and glucose levels were also significantly higher in T3-pretreated dogs than in controls. The blockade of beta-adrenergic receptors with propranolol prevented the increases in blood FFA and LA concentrations during subsequent adrenaline infusion. Phentolamine -- the alpha-adrenergic blocking agent -- infused to the T3-pretreated dog inhibited the adrenaline-induced rise in blood glucose level. The observed changes in the metabolic responses to catecholamines induced by triiodothyronine pretreatment indicate that at least in the dog this hormone potentiates both the lipolytic and glycogenolytic effects of catecholamines acting on appropriate adrenergic receptors.     

On the axonal migration of catecholamines in constricted sciatic nerve of the rat

Summary The radioautographic technique has been used to study the axonal migration of catecholamines in sympathetic fibres of the sciatic nerve of rats after ligature. A first series of experiments aimed at ascertaining the capacity of the proximal portion of adrenergic fibres to take up and store exogenous tritiated catecholamines (³H-DOPA; ³H-DA and ³H-NA) 3 to 22 hours after ligation. The results are qualitatively similar in rats pretreated and non-pretreated with IMAO, but the intensity of the radioautographic reaction is lower in the latter cases. Most of the labeled axons are filled mainly with vesicular and tubular profiles of endoplasmic reticular origin, large dense bodies (probably lysosomes) and/or mitochondria. The silver grains are generally superimposed on the vesicular and/or the tubular profiles, but in some cases on the large dense bodies, suggesting that exogenous catecholamines can be stored in lysosomes. The question whether SGV specifically store catecholamines also in the modified adrenergic fibres has been investigated in KMnO₄ fixed material. These results show that beside a large number of fibres in which there is a strict correlation between labeling and SGV, some fibres containing SGV do not retain the ³H-NA. Conversely some fibres which contain mainly agranular vesicles display radioautographic reaction. Therefore, in case of ligated fibres, SGV cannot be considered the specific organelles for storage of catecholamines.The axonal migration of labeled catecholamines has been studied in animals pretreated with IMAO. A moderate, but selective, labeling is present in the proximal portion of sciatic fibres of rats in which administration of labeled catecholamine preceeded of 2 hours the ligature and this was performed 22 hours before fixation.From these combined types of experiments, it is concluded that despite the presence of all the structures necessary for the storage of a high amount of catecholamines in the modified adrenergic fibres, only a small fraction of catecholamines accumulated above the ligature has been transported by axonal migration. Therefore, the axonal migration of catecholamines appears as an epiphenomenon related to the distal migration of enzymatic and storage proteins from the perikaryon.Part of this work was presented to the 84th Annual Session of American Association of Anatomists (Sotelo and Taxi, 1971).Some of the electron microscopic observations were made at the Unité 106 I.N.S.E.R.M.     

The action of angiotensin on the isolated perfused cat heart

The effects of angiotensin I (AI) and angiotensin (AII) on myocardial contractility, heart rate and coronary perfusion were observed in the isolated perfused cat heart. AII (10^?11 mol) and AI (10^?10 mol) both caused slowly developing sustained increases in systolic pressure of approximately 55%. There were inconsistent small increases in heart rate. Coronary perfusion was initially diminished, but later increased to above control values during the positive inotropic effect. The actions of both AI and AII were blocked by 1 sar 8 ile AII (10^?9 mol). The converting enzyme inhibitors SQ 20881 (10^?8 mol) and SQ 14225 (10^?8 mol) blocked the effect of AI. The actions of AII or AI were not blocked by α or β adrenergic blockade or by prior treatment with reserpine.     

Regulation of atrial contraction in the seawater-adapted eel,Anguilla japonica

The atrium isolated from the seawater-adapted eel beats spontaneously in normal Ringer solution for more than 10 hr. The strength of beating was inhibited by acetylcholine (ACh) and the inhibitory effects were blocked by atropine, a muscarinic ACh-receptor antagonist, indicating existence of muscarinic ACh-receptor on the atrium. The atrial contractility was stimulated by catecholamines and their agonists; the order of potency being isoproterenol > adrenaline (AD) = noradrenaline (NA) > phenylephrine > clonidine. The stimulatory effects of AD was completely blocked by propranolol, a β-adrenoceptor antagonist, but not by phentolamine, an α-adrenoceptor antagonist. These data were consistent with characteristics of β-adrenoceptors. Further characterization of the β-receptor was not attempted. The positive inotropic and chronotropic actions of AD were not completely blocked either by atenolol, a β₁-adrenoceptor antagonist, or by ICI 118551, a β₂-adrenoceptor antagonist. When electrical current with a short duration (0.25 msec) was passed through the atrium, the beating was inhibited initially, then enhanced later. The initial inhibition was inhibited by atropine and the later enhancement was blocked by propranolol. These results indicate that the electrical stimulation releases ACh and catecholamine(s) from the nerve endings. The positive inotropic and chronotropic effects of catecholamines were mimicked by tyramine, a catecholamine releaser from sympathetic nerve endings.     

Studies on rat sympathetic neurons developing in cell culture. III. Cholinergic transmission.

Principal neurons were dissociated from the superior cervical ganglia of newborn rats and grown in culture with several types of non-neuronal cells. As described in the second paper of this series, the neurons in such mixed cultures formed two types of excitatory synapses with each other, electrical and chemical. Evidence is presented here that transmission at the chemical synapses was cholinergic. Four nicotinic ganglionic blocking agents (curare, hexamethonium, tetraethylammonium, and mecamylamine) strongly attenuated or eliminated the excitatory postsynaptic potentials (e.p.s.p.'s) at moderate concentrations; atropine at relatively high concentrations also blocked transmission. Iontophoretic application of acetylcholine (ACh) to the surface of the neurons gave rise to depolarizations that could be made to resemble the e.p.s.p.'s in size and time course; the ACh potentials and the e.p.s.p.'s were then similarly affected by nicotinic blocking agents. The sensitivity to ACh was often distributed nonuniformly on the neuronal surface; it was common to find small, sharply localized regions of high sensitivity. Catecholamines (norepinephrine, epinephrine, and dopamine) had only inhibitory actions; in a few experiments adrenergic blocking agents (phenoxybenzamine, propranolol) were found to have no effect on the e.p.s.p.'s. These observations leave no doubt that the neurons released ACh and had ganglionic, nicotinic ACh receptors on their surfaces. The significance of the fact that a high proportion of the sympathetic neurons in mixed cultures formed cholinergic synapses is discussed.     

Hypoxic alligator embryos: chronic hypoxia, catecholamine levels and autonomic responses of in ovo alligators

Hypoxia is a naturally occurring environmental challenge for embryonic reptiles, and this is the first study to investigate the impact of chronic hypoxia on the in ovo development of autonomic cardiovascular regulation and circulating catecholamine levels in a reptile. We measured heart rate (f(H)) and chorioallantoic arterial blood pressure (MAP) in normoxic ('N21') and hypoxic-incubated ('H10'; 10% O(2)) American alligator embryos (Alligator mississippiensis) at 70, 80 and 90% of development. Embryonic alligator responses to adrenergic blockade with propranolol and phentolamine were very similar to previously reported responses of embryonic chicken, and demonstrated that embryonic alligator has α and β-adrenergic tone over the final third of development. However, adrenergic tone originates entirely from circulating catecholamines and is not altered by chronic hypoxic incubation, as neither cholinergic blockade with atropine nor ganglionic blockade with hexamethonium altered baseline cardiovascular variables in N21 or H10 embryos. In addition, both atropine and hexamethonium injection did not alter the generally depressive effects of acute hypoxia - bradycardia and hypotension. However, H10 embryos showed significantly higher levels of noradrenaline and adrenaline at 70% of development, as well as higher noradrenaline at 80% of development, suggesting that circulating catecholamines reach maximal levels earlier in incubation for H10 embryos, compared to N21 embryos. Chronically elevated levels of catecholamines may alter the normal balance between α and β-adrenoreceptors in H10 alligator embryos, causing chronic bradycardia and hypotension of H10 embryos measured in normoxia.     

N-Methylation of Dopamine to Epinine in Brain Tissue using N-Methyltetrahydrofolic Acid as the Methyl Donor

DURING biosynthetis of catecholamines, the final step in adrenaline formation involves transfer of a methyl group from S-adenosylmethionine (SAM) to the nitrogen of noradrenaline¹; such N-methylation has been demonstrated in vitro with dopamine by the use of an enzyme from the adrenal medulla². We propose a simplified model more compatible with the concept of intracellular compartments; in our model epinine should be considered as the immediate precursor of adrenaline².     

Nerve impulse-induced release of endogenous noradrenaline and adrenaline from the perfused cod spleen

Summary Release of endogenous catecholamines (CA) by electrical nerve stimulation (NS) was studied in the isolated perfused spleen of the Atlantic cod,Gadus morhua. An HPLC-system for the analysis of endogenously released CA is described. Cocaine (COC) was used to block neuronal re-uptake of endogenous CA released by NS. Splanchnic NS at frequencies of 1–40 Hz for 20 s resulted in release of noradrenaline (NA) and adrenaline (A) with a maximal total overflow at 20 Hz for both amines. The release of CA was frequency-dependent. COC (0.1 mmol·l^-1) increased NS-evoked (40 Hz) overflow of NA and A by 4.8 and 2.2 times, respectively, and reduced the overflow of dihydroxyphenylglycol (DOPEG) to spontaneous efflux levels or less. It can be concluded that the HPLC-technique used was adequate for measurement of NS-evoked release of endogenous CA and DOPEG from the isolated perfused cod spleen, and the model presented can therefore be used when studying adrenergic mechanisms in fish spleen.Abbreviations A adrenaline - CA catecholamines - COC cocaine - DA dopamine - DHBA 3,4-dihydroybenzylamine hydrobromide - DOPAC 3,4-dihydroxyphenylacetic acid - DOPEG 3,4-dihydroxyphenylglycol - l-DOPA 3,4-dihydroxyphenylalanine - NA noradrenaline - NS nerve stimulation - PCA perchloric acid     

Catecholamine-induced Regulation in Vitro and ex Vivo of Intralymphocyte Ionized Magnesium

Despite the importance of the adrenergic activity and of the metabolism of magnesium in some important cardiovascular pathologies, very little is known about how intracellular ionized magnesium (Mg _i ²⁺ ) is regulated by catecholamines. We made an in-vitro study of the variations in the concentration of ionized magnesium in human lymphocytes using the fluorescent probe furaptra in response to different catecholamines. We also made an ex-vivo study of the changes in intracellular ionized magnesium in lymphocytes in 20 subjects with essential arterial hypertension, 10 treated with 120 mg/d of propranolol and 10 with placebo. Norepinephrine and isoproterenol significantly decrease Mg _i ²⁺ and this effect is blocked by β-blockers but not by α-blockers. The EC ₅₀ of the effect of norepinephrine is within the range of concentrations physiologically present in plasma. The substitution of extracellular sodium with choline blocks the decrease in intracellular ionized magnesium induced by norepinephrine, which leads us to suppose that the magnesium-reducing effect of catecholamines is a result of the activation of a Na⁺-Mg²⁺ exchanger. We were not able to demonstrate any change in intracellular ionized magnesium after 1 and 17 days of active treatment in essential hypertensives. The impossibility of demonstrating ex vivo the mechanism of catecholamine-mediated regulation that is evident in vitro is perhaps due to our experimental conditions or to substances which in vivo inhibit the action of the catecholamines on magnesium, such as insulin and/or glucose.     

Effects of adrenaline in human colon adenocarcinoma HT-29 cells

AimsStress has been implicated in the development of cancers. Adrenaline levels are increased in response to stress. The effects of adrenaline on colon cancer are largely unknown. The aims of the study are to determine the effects of adrenaline in human colon adenocarcinoma HT-29 cells and the possible underlying mechanisms involved.Main methodsThe effect of adrenaline on HT-29 cell proliferation was determined by [³H] thymidine incorporation assay. Expression of cyclooxygenase-2 (COX-2) and vascular endothelial growth factor (VEGF) were detected by Western blot. Matrix metalloproteinase-9 (MMP-9) activity and prostaglandin E₂ (PGE₂) release were determined by zymography and enzyme immunoassay, respectively.Key findingsAdrenaline stimulated HT-29 cell proliferation. This was accompanied by the enhanced expression of COX-2 and VEGF in HT-29 cells. Adrenaline also upregulated MMP-9 activity and PGE₂ release. Adrenaline stimulated HT-29 cell proliferation which was reversed by COX-2 inhibitor sc-236. COX-2 inhibitor also reverted the action of adrenaline on VEGF expression and MMP-9 activity. Further study was performed to determine the involvement of β-adrenoceptors. The stimulatory action of adrenaline on colon cancer growth was blocked by atenolol and ICI 118,551, a β₁- and β₂-selective antagonist, respectively. This signified the role of β-adrenoceptors in this process. In addition, both antagonists also abrogated the stimulating actions of adrenaline on COX-2, VEGF expression, MMP-9 activity and PGE₂ release in HT-29 cells.SignificanceThese results suggest that adrenaline stimulates cell proliferation of HT-29 cells via both β₁- and β₂-adrenoceptors by a COX-2 dependent pathway.     

Cellular Aspects of the Control of Physiological Color Changes in Amphibians

SYNOPSIS. The present paper is concerned mainly with the melanin-dispersingeffect of melanocyte-stimulating hormones (MSH's) on the skinmelanophores of amphibians. In addition, some of the more recentevidence for the unihumoral theory of the control of color changeis reviewed. The mechanism of dispersion of melanin is stillunknown, but evidence is accumulating that the action of MSHmay be mediated by an increase in the melanophoric content ofadenosine 3', 5'-monophosphate (cyclic AMP). For example, cyclicAMP has a specific, reversible melanin-dispersing effect onthe melanophores of the isolated skin of R. pipiens and Xenopuslaevis. It also has a reversible "melanophore—expanding"effect on the tissue—cultured embryonic melanophores ofthe spotted salamander, Ambystoma maculatum. The effect of cyclicAMP on melanophores of R. pipiens does not require sodium butis inhibited by hypertonicity. Finally, new evidence is presented that confirms that the melanin-dispersingeffect of catecholamines on melanophores of X. laevis is mediatedby beta adrenergic receptors,because it is blocked by the highlyspecific ß—blocking agent, propranolol. On theother hand, the melanin-aggregating effect of catecholamineson amphibian melanophores appears to be mediated by alpha adrenergicreceptors. There is even a possibility that the effects of catecholaminesare also mediated through a control of cyclic AMP levels inmelanophores, with beta adrenergic stimulation producing anincrease in cyclic AMP levels, followed by dispersion of melanin,and alpha adrenergic stimulation producing a decrease in cyclicAMP levels, followed by aggregation of melanin.