Changes in Sympathetic Nerve Terminals in the Heart of Cold-Exposed Rats

Abstract: Changes in sympathetic nerve terminals of the heart after varying periods of exposure of rats to 4°C were investigated. Two indices were used for changes in the number of noradrenaline storage vesicles, i.e., vesicular dopamine β-hydroxylase (DBH) activity and noradrenaline storage capacity. The latter was obtained after uptake of [³H]noradrenaline; endogenous content, uptake of exogenous noradrenaline, and degree of saturation of the vesicles were calculated using the specific activity of the [³H]noradrenaline. As a measure of tyrosine hydroxylase activity, whole ventricular noradrenaline, dopamine, and dihydroxyphenylacetic acid content were used. After 4 h of cold exposure there was an increase in vesicular endogenous noradrenaline content, uptake, storage capacity, and DBH activity as well as a large increase in whole ventricular dopamine. After 6 h in the cold, vesicular endogenous noradrenaline content, storage capacity, and DBH activity were decreased. The results suggest that during cold exposure there is an initial increase followed by a decrease in the number of functional vesicles in the nerve terminal, which could explain the fluctuations in the rate of noradrenaline release.     

CHANGES IN VESICULAR DOPAMINE-β-HYDROXYLASE RESULTING FROM TRANSMITTER RELEASE

—Exposure of rats to 3°C for up to 30 min leads to a decrease of 30 per cent in the dopamine-β-hydroxylase activity of the vesicular pellet of the heart; this is greater than can be accounted for by loss of soluble DBH from the two populations of noradrenaline storage vesicles known to be present in the heart. Cold exposure in the presence of α-methyltyrosine causes a much smaller reduction in dopamine-β-hydroxylase activity; this suggests that there is a decrease in transmitter release when synthesis is inhibited. The noradrenaline concentration of the vesicular pellet rises briefly during cold exposure and is then maintained at control levels; the early rise is absent in the presence of α-methyltyrosine. The use of the noradrenaline : dopamine-β-hydroxylase ratio as an index of saturation of vesicular storage capacity suggests that during cold exposure an increased synthesis rate leads to increased filling of vesicles.     

Effect of ascorbic acid on release of acetylcholine from synaptic vesicles prepared from different species of animals and release of noradrenaline from synaptic vesicles of rat brain.

Low concentrations of L-ascorbic acid caused release of acetylcholine from isolated synaptic vesicles (rat, guinea-pig and rabbit) in the presence of 2mM ATP, 2 mM MgCl₂ and 10^?5 M CaCl. The half maximum effect was obtained with about 2 to 2.5 ωM L-ascorbic acid, and the effect was inhibited by addition of 1mM EGTA. The release of noradrenaline from rat synaptic vesicles was also enhanced by L-ascorbic acid, but the concentration for half maximal stimulation was about 20 ωM, indicating that noradrenaline release was less sensitive to L-ascorbic acid than acetylcholine release. The physiological function of L-ascorbic acid in the brain is discussed in relation to release of transmitters.     

The effects of repeated physical stress or fasting on catccholamine storage and release in the rainbow trout, Oncorhynchus mykiss

Rainbow trout, Oncorhynchus mykiss, were subjected to either physical stress (twice daily chasing to exhaustion for 5 days) or a period of 2 months of fasting. Following these treatments, the levels of catecholamines, adrenaline and noradrenaline, stored within the kidney and posterior cardinal vein (PCV) were determined. The ability of the catecholamine-storing chromaffin cells to release catecholamines in response to cholinergic stimulation was measured using an in situ saline-perfused PCV preparation. In the physically stressed fish, the concentration (μg catecholamine g^?1 tissue) of noradrenaline within the anterior and middle thirds of the kidney increased; the concentration of adrenaline was unchanged in all tissues. The content (μg) of noradrenaline or adrenaline, within the various tissues, was similar in both groups of fish with the exception of a higher noradrenaline content in the middle third of the kidney in the physically stressed fish. The total catecholamine content (μg catecholamine) of these tissues (kidney+PCV) was unaffected by physical stress. With the exception of a lower concentration of adrenaline in the middle third of the kidney, the concentrations of catecholamines were unaffected by fasting. There was a trend towards a greater content (μg) of noradrenaline within all of the tissue regions of the fed fish, however, a significant difference was only observed in the anterior third of the kidney. The content of adrenaline in the fed fish was greater in all regions of the kidney as well as the middle third of the PCV. The total catecholamine content (kidney + PCV) was lower in the fasted fish owing to significantly lower PCV and kidney masses. Prolonged physical stress caused a decrease in the responsiveness of the chromaffin cells to the cholinoceptor agonist carbachol (10^?8 to 10^?4mol). The ED₅₀ (the dose of carbachol required to elicit a half maximal response) for catecholamine release was 0·96 ± 10^?6mol carbachol in the physically stressed fish and 0·84 ± 10^?7 in the control fish. Fasting did not alter the pattern of catecholamine release. The ED₅₀ values were 0·96 ± 10^?7 and 1·24 ± 10^?7 mol for fasted and fed fish, respectively. Thus, a physical stress affected both catecholamine storage and release whereas fasting affected only storage and not the release process.     

Release of norepinephrine from the cat ovary: changes after ovulation.

The distribution of intraneuronal constituents involved in norepinephrine (NE) storage, uptake, and release were used to estimate changes in NE secretion from the cat ovary after ovulation induced with eCG plus hCG. The content of NE and ATP, which are principally stored in small noradrenergic vesicles (isolated at a density of 1.041 g/ml in Percoll gradient), decreased after ovulation. However, the activity of dopamine beta-hydroxylase, which is principally associated with large noradrenergic vesicles (isolated at a density of 1.033 g/ml in Percoll gradient), was only slightly decreased. Mg(2+)-dependent ATPase, located in both large and small storage vesicles, decreased only in the small storage vesicles, suggesting that preferential secretion from small noradrenergic vesicles occurred. The hormonal treatment also affected the functional capacity of the vesicles, as evidenced by the decrease in uptake and storage capacity as well as the decrease in the stimulated release of 3H-NE observed after ovulation. The aforementioned changes are characteristically seen after a sympathetic discharge; thus they strongly support the notion that ovarian sympathetic activity increases during the ovulatory process, resulting in the postovulatory decrease in both the size and functional capacity of the intraneuronal compartment where NE is stored.     

Large-scale preparation of plasma membrane vesicles from PC-12 Pheochromocytoma cells and their use in noradrenaline transport studies

Plasma membranes were isolated from rat pheochromocytoma cells (PC-12) grown in spinner culture. The rapid and simple isolation procedure consisted of a differential and isopycnic centrifugation (in a linear sucrose gradient) with the aid of a high capacity fixed angle rotor equipped with siliconized centrifuge tubes. The isolated membranes were closed and osmotically active vesicles (about 0.3 μm in diameter) with a mean intravesicular water space of 1.84 μl / mg protein. In the presence of an inward gradient of sodium chloride and an outward gradient of potassium, [³H]noradrenaline (50 nM) was taken up and accumulated 550-fold (at 31°C). The uptake and accumulation of [³H]noradrenaline was temperature-sensitive and inhibited by the tricyclic antidepressant desipramine. Membrane vesicles isolated from PC-12 cells represent a useful model for the investigation of the molecular mechanism of the neuronal noradrenaline transport system.     

Noradrenaline Storing Vesicles in Sympathetic Neurons and Their Putative Role in Neurotransmitter Release: An Historical Overview of Controversial Issues

More than 25 years have passed since the original demonstration that proteins such as chromogranin A and dopamine--hydroxylase, which are co-stored together with noradrenaline in large dense cored vesicles in adrenergic nerves, are released by exocytosis. Despite much evidence in favour, it was for a long time thought that large dense cored vesicles were not eminently involved in the release of noradrenaline. The present review attempts to demonstrate, making use of evidence from different approaches, that the release of noradrenaline from sympathetic neurons occurs ultimately from large dense cored vesicles. A model of the secretory cycle is proposed.     

Release of [3H]noradrenaline by α1-adrenoceptor agonists

Mouse isolated vas deferens preincubated with [³-H]noradrenaline was superfused and the effect of ₁-adrenoceptor agonists was studied on the release of total radioactivity ([³H]noradrenaline +³H-metabolites) and [³H]noradrenaline. Reverse phase high pressure liquid chromatography (HPLC) combined with scintillation spectrometry was used to separate [³H]noradrenaline from its metabolites. Among the ₁-adrenoceptor agonists (1-phenylephrine, ST-587(2-(2-chloro-5-trifluoromethyl phenylimino)-imidazole), (–)-amidephrine, methoxamine, cirazoline and l-noradrenaline) studied l-phenylephrine, ST-587 and l-noradrenaline were capable of releasing³H-noradrenaline. The effect of noradrenaline was stereospecific. As determined by HPLC combined with scintillation spectrometry the release of total radioactivity in response to l-noradrenaline is mainly due to [³H]noradrenaline. It is suggested that l-noradrenaline, l-phenylephrine, and ST-587 in addition to their direct effect on different receptors they also have indirect action through the release of noradrenaline which might be partly involved in the pharmacological responses. The mechanisms whereby l-noradrenaline and l-phenylephrine release noradrenaline would appear to involve a saturable Ca-independent and a cocaine and temperature sensitive process. On the basis of our findings among the ₁-adrenoceptor agonist studied (–)-amidephrine, methoxamine and cirazoline is a better choice than l-phenylephrine or ST-587 for selective stimulation of postjunctional ₁-adrenoceptor, they do not release noradrenaline.     

Alteration by methadone of catecholamine uptake and release in isolated rat adrenomedullary storage vesicles

Incubation of isolated rat adrenomedullary storage vesicles with methadone produced inhibition of ³H-epinephrine uptake and promotion of release of endogenous catecholamines. Neither effect was seen using morphine, nor could morphine antagonize methadone-induced catecholamine release, suggesting that these actions are not mediated by opiate receptors. Inhibition of uptake by methadone appeared to contain a competitive component with a lower Ki for methadone compared to the Km for ³H-epinephrine. Despite competitive inhibition by methadone, the maximal uptake capacity (analogous to Vmax) as determined by double-reciprocal plots, was increased by the drug, probably as a result of greater availability of intravesicular storage sites because of the drug-induced of release endogenous catecholamines. Agents which enhance or block catecholamine transport into vehicles had no effect on the catecholamine release by methadone, indicating that the latter is separable from the action on uptake. These alterations of catecholamine uptake and release may play a role in the effects of methadone on the adrenal medulla $\text{in vivo}$.     

Biochemical evidence for the presence of small and large noradrenergic storage vesicles isolated from cat ovary in isoosmotic conditions. Distribution of dopamine-β-hydroxylase activity

The cat ovary presents unusually high levels of noradrenaline that change according to the endocrine status of the animal. Their functional meaning remains unknown. The cat ovary innervation, unlike that of other organs receiving noradrenergic innervation, has been poorly characterized on biochemical grounds. We present here a biochemical characterization of the neurotransmitter storage. By using hyperosmotic and isoosmotic gradients evidence is presented that noradrenaline is associated to two different populations of vesicles. In hyperosmomolarity conditions (sucrose gradients) “light” vesicles (density 1.12 g/ml) and “heavy” vesicles (density 1.17 g/ml) appeared. In both vesicles, noradrenaline and dopamine-β-hydroxylase were found. In isoosmotic Percoll gradients distribution of the markers also suggested the presence of two vesicle populations. Light vesicles (density 1.033 g/ml) with high dopamine-β-hydroxylase activity but very low levels of noradrenaline and adenosine triphosphate; [³H]noradrenaline, used as a specific exogenous vesicle marker, was feebly incorporated in this fraction. Heavy vesicles (density 1.041 g/ml) containing high levels of noradrenaline, adenosine triphosphate, low levels of dopamine-β-hydroxylase activity are able to incorporate high amounts of [³H]noradrenaline. In these gradients, Mg²⁺ activated ATPase activity was present in both vesicle fractions.

Sedimentation analysis by analytical differential centrifugation also disclosed two types of vesicles: large vesicles with a sedimentation coefficient between 348 and 308 and small vesicles with a sedimentation coefficient of 96 . Large vesicles were associated with noradrenaline-β-hydroxylase activity, while small vesicles were associated only with noradrenaline.

In isoosmotic conditions the use of other microsomal markers allowed us to define the degree of contamination of the vesicle fractions. It was found that the noradrenergic heavy vesicles fraction presented under 11% of 5′-nucleotidase activity of the total activity present in the gradient and less than 5% of acid phosphatase, NADH-cytochrome c reductase and monoaminooxidase of the total activities in the gradients.

In isoosmotic conditions the physical properties of presumed vesicles were apparently undisturbed supporting the current morphometric observations. Our results then suggest prevailing roles for each type of vesicle: synthesis for light vesicles, and storage and/or release for heavy ones.     

Role of External and Internal Calcium on Heterocarrier-Mediated Transmitter Release

Abstract: Release-regulating heterocarriers exist on brain nerve endings. We have investigated in this study the mechanisms involved in the neurotransmitter release evoked by GABA heterocarrier activation. GABA increased the basal release of [³H]acetylcholine and [³H]noradrenaline from rat hippocampal synaptosomes and of [³H]dopamine from striatal synaptosomes. These GABA effects, insensitive to GABA receptor antagonists, were prevented by inhibiting GABA uptake but not by blocking noradrenaline, choline, or dopamine transport. Lack of extracellular Ca²⁺ or addition of tetrodotoxin selectively abolished the GABA-evoked release of [³H]noradrenaline, leaving unaffected that of [³H]acetylcholine or [³H]dopamine. 1,2-Bis(2-aminophenoxy)-ethane-N,N,N′,N′-tetraacetic acid acetoxymethyl ester (BAPTA-AM) or vesamicol attenuated the release of [³H]acetylcholine elicited by GABA. Reserpine, but not BAPTA-AM, prevented the effect of GABA on [³H]dopamine release. Autoreceptor activation inhibited the GABA-evoked release of [³H]noradrenaline but not that of [³H]acetylcholine or [³H]dopamine. It is concluded that (a) the release of [³H]noradrenaline consequent to activation of GABA heterocarriers sited on noradrenergic terminals meets the criteria of a conventional exocytotic process, (b) the extracellular [Ca²⁺]-independent releases of [³H]acetylcholine and [³H]dopamine appear to occur from vesicles possibly through involvement of intraterminal Ca²⁺, and (c) autoreceptor activation only affects heterocarrier-mediated vesicular release linked to entry of extracellular Ca²⁺.     

Effect of carbidine on the content and storage of adrenergic neurotransmitter in the synaptic vesicles]

The influence of carbidine, an original psychotropic drug, on the adrenergic neurotransmitter content and storage in the sympathetic nerves was studied with the use of cytochemical electron microscopy. The influence of carbidine on the uptake of the exogenous noradrenaline (NA) in the synaptic vesicles was also studied. Carbidine was found to be capable to decreasing the NA storage in the synaptic vesicles and failed to block the accumulation of the exogenous NA in the synaptic vesicles.     

Stressor-induced Release of Substances from the Rat Amygdala detected by the Push-Pull Cannula

THE push-pull cannula, originally used to determine the release of endogenous acetylcholine¹, has been combined with intraventricular injection of radioactively labelled noradrenaline² and other substances to investigate the release of noradrenaline and its metabolites after electrical brain stimulation in the free-moving rat³. The technique has also been used to study the release of noradrenaline, serotonin, urea, inulin and α-aminoisobutyric acid from the olfactory bulb after olfactory stimulation in anaesthetized rats⁴ and the release of noradrenaline, its metabolites and urea after injections of desipramine and reserpine⁵. Although noradrenaline has been detected in all cases, simultaneous release of such substances as inulin and urea⁴ has raised questions about the meaning and specificity of the release of noradrenaline.     

IS THERE BIDIRECTIONAL TRANSPORT OF NORADRENALINE IN SYMPATHETIC NERVES?

The experiments were designed to detect somatopetal transport of [¹⁴C]noradrenaline in the postganglionic sympathetic nerves supplying the cat spleen and sheep eye. The animals were treated with nialamide to protect the radioactive noradrenaline, after uptake into the nerve terminals, from monoamine oxidase. In the spleen, the transmitter stores were labelled by infusion of [¹⁴C]noradrenaline into a branch of the splenic artery. The branches of the nerves to the infused and non-infused sides of the spleen were ligated in an attempt to arrest, distal to the constriction, any noradrenaline transported somatopetally in the axons from their terminals. After 24 hr, however, there was less radioactivity in the nerves distal compared to proximal to the constriction, despite heavier labelling of the terminal transmitter stores in the infused portion of the spleen. The proximal accumulation of radioactivity could be attributed to a somatofugal transport of [¹⁴C]noradrenaline. Experiments were also done on the intact sympathetic nerve supply of the sheep eye. The sympathetic nerve terminals in the smooth muscle of the left eye were heavily labelled 5 days after the injection of [¹⁴C]noradrenaline into the left vitreous humour. However, both superior cervical ganglia were only lightly labelled, and there was no significant difference in the radioactivity present in the two ganglia. The results provide no support for a bidirectional transport of noradrenaline in sympathetic nerves but are consistent with a somatofugal transport of the amine storage vesicles from their site of synthesis in the soma to the axon terminals.     

Increased GABA Release in the Human Brain Cortex as a Potential Pathogenetic Basis of Hyperosmolar Diabetic Coma

Human cerebral cortical slices preincubated with [³H]GABA, [³H]noradrenaline, or 5-[³H]hydroxytryptamine and superfused with Krebs solution or Mg²⁺-free Krebs solution were used to investigate the influence of increased D-glucose concentrations on the release of these [³H]-neurotransmitters evoked by high K⁺ content or NMDA receptor activation, respectively. An increase in level of D-glucose (normal content, 11.1 mM) by 32, 60, and/or 100 mM (a range characteristic for hyperosmolar diabetic coma) increased the [³H]GABA release and inhibited the [³H]noradrenaline release evoked by both methods of stimulation. The K⁺-induced 5-[³H]hydroxytryptamine release was also inhibited by high D-glucose content. Blockade of GABA_B receptors by p-(3-aminopropyl)-p-diethoxymethylphosphinic acid (CGP 35348) attenuated the inhibitory effect of high D-glucose content on the K⁺-evoked release of [³H]noradrenaline and 5-[³H]hydroxy-tryptamine, suggesting that the effect on monoamine release is, at least to a major part, the result of the increased GABA release and, as a consequence, of an increased GABA concentration at inhibitory GABA_B receptors. The membrane-impermeable sorbitol mimicked the increasing effect of D-glucose on [³H]GABA release and its inhibitory effect on 5-[³H]hydroxytryptamine release. However, dimethyl sulfoxide, which is known to permeate rapidly through biological membranes, had no effect at concentrations equiosmolar to D-glucose. It is concluded that a reduction in brain cell volume caused by increased extracellular, compared with cytoplasmic, osmolarity is crucial for the changes in neuronal function observed at high D- glucose and sorbitol content, In view of the fact that GABA is the main inhibitory neurotransmitter in the brain, the increased GABA release may be assumed to contribute to the pathogenesis of hyperosmolar diabetic coma.     

Muscarinic receptor activation inhibits both release and synthesis of noradrenaline in rat hippocampal synaptosomes

Rat hippocampal synaptosomes were used to investigate the effects of muscarinic cholinergic drugs on the release of [³H]noradrenaline and the rate of noradrenaline synthesis. Oxotremorine and acetylcholine caused depression of K⁺-evoked release of [³H]noradrenaline; these effects were reversed by atropine and pirenzepine. Muscarinic agonists depressed 2-chloroadenosine- and isoprenaline-stimulated noradrenaline synthesis but had no effect on 8-Br-cyclic AMP-stimulated synthesis. Oxotremorine also depressed the K⁺-acceleration of noradrenaline synthesis. The action of pirenzepine suggests that the inhibition of release and synthesis are mediated by separate muscarinic receptor subtypes.     

INFLUENCE OF COLD EXPOSURE ON THE ACTIVITIES OF SOLUBLE AND MEMBRANE-BOUND DOPAMINE β-HYDROXYLASE IN RAT HEART VESICLES

Abstract— A fraction containing noradrenaline storage vesicles of the sympathetic nerve terminals in the rat heart was obtained by differential centrifugation. In this preparation, 17% of the dopamine β-hydroxylase was present in a soluble form. Cold exposure (3°C) for periods from 5 to 30 min led to an increase in the activity of soluble dopamine β-hydroxylase by about 50%, while the activity of membrane-bound dopamine β-hydroxylase was simultaneously decreased by approx 30%. The nor-adrenaline content of the vesicles rose concomitantly with the increase in the activity of soluble dopamine β-hydroxylase. This rise in noradrenaline content was caused by an enhanced synthesis and not by an alteration in the subcellular distribution. The results are discussed with respect to the fate of dopamine β-hydroxylase during enhanced sympathetic nerve activity.     

Studies on the mechanism of modulation of [3H]noradrenaline release from rat hippocampal synaptosomes by GABA and benzodiazepine receptors

Release of [³H]noradrenaline from rat hippocampal synaptosomes was triggered by pulses of 25 mM K⁺, 5 μM veratridine or superfusion with the Ca²⁺ ionophore A23187. GABA with bicuculline or chlordiazepoxide depressed the release of [³H]noradrenaline evoked by depolarisation but not by the Ca²⁺ ionophore. 8 Br-cAMP with [Ca²⁺]₀ 0.3 mM had no effect on spontaneous or K⁺-evoked release of [³H]noradrenaline and completely blocked the effect of chlordiazepoxide and GABA with bicuculline. With [Ca²⁺]₀ 1 mM 8 Br-cAMP enhanced spontaneous and K⁺-evoked release of [³H]noradrenaline, and reversed the depression caused by GABA with bicuculline. GABA alone evoked Ca²⁺-dependent release of [³H]noradrenaline which was sensitive to [Cl^?]₀. The results suggest that the GABA_A-receptor mediated release of [³H]noradrenaline is due to depolarisation resulting from increased Cl^? conductance whereas the depression of depolarisation-dependent release of [³H]noradrenaline by GABA_B or benzodiazepine receptors is mediated by a cAMP-dependent decrease in the voltage-dependent Ca²⁺ conductance.     

Ultrastructural characteristics of rat peritoneal mast cells undergoing differential release of serotonin without histamine and without degranulation

Summary Rat mast cells pretreated with the tricyclic antidepressant drug amitriptyline and stimulated with compound 48/80 secreted 60% of the total serotonin present in the cells, but only 15% of histamine, another amine stored in the same granules. Ultrastructural studies demonstrated that mast cells undergoing such differential release do not exhibit classical degranulation by compound sequential exocytosis. However, there were changes in granule shape and size, as well as alterations in many morphometric parameters consistent with secretion. Storage granules lost their homogeneity, exhibited greatly reorganized matrix and were surrounded by clear spaces which were often associated with small (0.1–0.01 m) cytoplasmic vesicles, some of which contained electron-dense material. Secretory granules often had bud-like protrusions or were fused together in series. Quantitative autoradiography localized ³H-serotonin outside the storage granules, close to small vesicles, while staining with ruthenium red demonstrated that vesicular structures associated with differential release were not endocytotic. These results suggest that amitriptyline may inhibit regular exocytosis and permit at least serotonin to be moved selectively from storage granules to the cytosol or small vesicles from which it is eventually released.     

Regulation of the efficacy of adrenergic synaptic transmission by adrenergic autoreceptors in rat brain slices

A mathematical model was developed based on the putative functional role of adrenergic autoreceptors for quantifying processes of synaptic depression, facilitation, stabilization of PSP amplitude, and rise in this amplitude produced by increased stimulation rate. Synaptic depression and facilitation are brought about by activation of - and -adrenergic autoreceptors respectively. A "steady release zone" is found between curves of adrenergic autoreceptor activity and this is responsible for stabilizing noradrenaline release during a series of presynaptic impulses. Experimental findings on labeled noradrenaline (³H-NA) release from rat brain slices showed that adrenergic autoreceptors do in fact form a stable release zone responsible for autofacilitation and stabilization of³H-NA release produced by 5-fold consecutive K⁺ depolarizations of slices spaced 30 min apart. Lack of a stable release zone in curves showing adrenergic autoreceptor activity produces destabilization of³H-NA release. These curves (together with the stable release zone) shift in the direction of high noradrenaline concentrations when stimulus intensity is increased.Institute of Higher Nervous Activity and Neurophysiology, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 19, No. 3, pp. 390–399, May–June, 1987.