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.     

Axonal transport of muscarinic receptors in vesicles containing noradrenaline and dopamine-β-hydroxylase

Presynaptic muscarinic receptors labeled with [³H]dexetimide and noradrenaline in dog splenic nerves accumulated proximally to a ligature at the same rate of axonal transport. After fractionation by differential centrifugation, specific [³H]quinuclidinyl benzilate or [³H]dexetimide binding revealed a distribution profile similar to that of dopamine-β-hydroxylase and noradrenaline. Subfractionation by density gradient centrifugation showed two peaks of muscarinic receptors; the peak of density 1.17 contained noradrenaline and dopamine-β-hydroxylase whereas that of density 1.14 was devoid of noradrenaline. Therefore the foregoing experiments provide evidence that presynaptic muscarinic receptors are transported in sympathetic nerves in synaptic vesicles which are similar to those containing noradrenaline and dopamine-β-hydroxylase. This suggests a possible coexistence of receptor and neurotransmitter in the same vesicle.     

Effect of castration and testosterone on norepinephrine storage and on the release of [3H]norepinephrine from rat vas deferens

Norepinephrine and dopamine-β-hydroxylase, used as noradrenergic vesicle markers, were found to be decreased in the rat vas deferens 10 days after castration. Five days of testosterone administration to castrated animals increased the enzyme activity over that of controls but did not modify norepinephrine content. In tissue fractions obtained by differential centrifugation, the highest activities of the noradrenergic markers appeared in the vesicular fraction of controls and in the soluble fraction of castrated animals. Testosterone reversed the effect of castration: it increased dopamine-β-hydroxylase activity in the vesicular and soluble fractions, while norepinephrine increased only in the vesicular fraction. Results obtained after continuous sucrose gradient centrifugation of vesicular fractions suggested that these changes principally affected the number of light noradrenergic vesicles while testosterone increased the number of vesicles reduced by castration. Hormonal manipulations also modified some functional properties of nerve endings: norepinephrine depletion after transmural stimulation in the presence of tetraethylammonium, as well as the release of the neurotransmitter, were decreased after castration. These effects were reversed by testosterone. The results suggest a modulatory effect of testosterone on the norepinephrine storage system and on the functional properties of the adrenergic innervation of vas deferens.     

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.     

BOVINE ADRENAL MEDULLARY DOPAMINE-β-HYDROXYLASE: STUDIES ON INTERACTION WITH CONCANAVALIN A

Bovine adrenal medullary dopamine-β-hydroxylase binds with concanavalin A and forms an enzymically active precipitate. The formation of the insoluble complex is pH-dependent and can be inhibited by α-methyl-D-mannoside, D-mannose and D-glucose. The insoluble complex can be dissociated into two species with α-methyl-D-mannoside. From the results, it appears that the interaction between dopamine-β-hydroxylase and concanavalin A is due to the carbohydrate moiety of dopamine-β-hydroxylase. This property was used to purify the enzyme from a soluble lysate of chromaffin granules. Of all the proteins contained in the soluble lysate, dopamine-β-hydroxylase was the only one to be retained on a column of concanavalin A covalently bound to Sepharose 4B. The preparation of pure dopamine-β-hydroxylase exhibits a very high specific activity of 320 μmol of octopamine formed per 30 min per mg of protein.     

Formation in vitro of matrix-like aggregates of chromogranins and phospholipids derived from chromaffin granules of the bovine adrenal medulla

Matrix-like particles were formed in sonicated suspensions of soluble chromogranins and phospholipids extracted from the isolated membrane phase of chromaffin granules. The artificial particles which sedimented into 0.4–0.6 M sucrose layers during isopycnic centrifugation, consisted of liposomal vesicles and granular aggregates indicative of lamellar and possibly hexagonal organization patterns of phospholipids and the aqueous phase containing the soluble chromogranins. The ultrastructure of the granular aggregates was strikingly similar to the matrix phase of the intact chromaffin granule.The dopamine-β-hydroxylase activity (EC 1.14.2.1) of the soluble chromogranin preparation was potentiated by the addition of the phospholipids and further enhanced by the sonication procedure. The enzymic activity was highest in the 0.4–0.6 M sucrose layers, rich in the artificial matrix-like particles.The artificially formed particles incorporated ATP by further sonication and the presence of ATP in the particle fractions did not inhibit the specific dopamine-β-hydroxylase activity, even at ratios of 4 and 2 μmoles ATP/mg protein in the 0.4 and 0.6 M sucrose layers, respectively. Noradrenaline was incorporated into the particle fractions in presence of ATP. However, the presence of noradrenaline above 3·10^?6 M resulted in a 50–75% inhibition of the dopamine-β-hydroxylase activity of the artificial matrices.     

EFFECT OF DIBUTYRYL-CYCLIC AMP and DEXAMETHASONE ON NORADRENALINE SYNTHESIS IN ISOLATED SUPERIOR CERVICAL GANGLIA

Abstract— Incubation with dibutyryl-cyclic AMP increased levels of both noradrenaline and dopamine- β -hydroxylase in isolated rat superior cervical ganglia. Dexamethasone also increased the dopamine- β -hydroxylase content but did not affect noradrenaline levels. Cycloheximide blocked the effect of dibutyryl-cyclic AMP on ganglion dopamine- β -hydroxylase but did not affect the rise in noradrenaline content.
Dibutyryl-cyclic AMP increased the synthesis of noradrenaline from [¹⁴C]tyrosine but not from [³H]DOPA.
The results are discussed in terms of a possible role for cyclic AMP in the control of noradrenaline synthesis in sympathetic ganglia.     

SUBCELLULAR DISTRIBUTION OF DOPAMINE-β-HYDROXYLASE AND INHIBITORS IN THE HIPPOCAMPUS AND CAUDATE NUCLEUS IN SHEEP BRAIN

—The enzyme dopamine-β-hydroxylase (EC 1.14.17.1) which converts dopamine to noradrenaline was found to be present in substantial amounts in sheep brain hypothalamus and caudate nucleus and was located to the synaptic vesicle fractions in these two brain regions by subcellular fractionation. This dopamine-β-hydroxylase was associated with paniculate matter in these two brain regions since it was resistant to solubilization with butan-1-ol and 0.1% Triton X-100. As highly significant levels of dopamine-β-hydroxylase were present in the caudate nucleus, factors other than a simple lack of this enzyme must operate to maintain the low levels of noradrenaline and high levels of dopamine in the caudate nucleus. Purified adrenal dopamine-β-hydroxylase was substantially inhibited by two factors prepared from sheep brain hypothalamus and caudate nucleus. These were found to be cupric ions and a sulphydryl inhibitor. High levels of the sulphydryl inhibitor of dopamine-β-hydroxylase were found in synaptosomal fractions from sheep brain hypothalamus and caudate nucleus and the levels were comparable in both regions. Upon subfractionation of a synaptosome-containing fraction from the hypothalamus, the inhibitor was located predominantly in the soluble fraction, although there were significant levels in the synaptic vesicle fraction. Therefore, the sulphydryl inhibitor must be considered as a possible regulator of dopamine-β-hydroxylase activity. Free cupric ion concentrations as low as 2·5 μM were found to inhibit purified adrenal dopamine-β-hydroxylase in vitro and the concentration of copper in the soluble tissue component of hypothalamus and caudate nucleus was well above this minimal copper concentration. The percentage content of soluble copper in the caudate nucleus was significantly higher than in the hypothalamus. The importance of the soluble to particulate-bound ratio of copper in brain was shown in studies of the developing rat brain. A rapid increase in the level of copper in brain was found in the first 4 weeks but the level was constant by 2 months of age. The percentage of soluble copper, however, was maximal soon after birth and had declined to a constant figure by 2 months of age. A scheme for the regulation of dopamine-β-hydroxylase activity involving these factors is proposed.     

Storage and Release of Noradrenaline in Hypothalamic Synaptosomes

Abstract: The noradrenaline storage capacity of vesicles in hypothalamic synaptosomes was measured by incubating them with [³H]noradrenaline under saturating conditions. The normal noradrenaline content is 52% of storage capacity. Incubation or superfusion with 50 mm -potassium causes calcium-dependent release from the vesicles. Such release reduces not only the vesicular content, but also the noradrenaline storage capacity. This suggests that after exocytosis vesicles cannot refill with noradrenaline.     

AN INHERITED DEFICIENCY IN NORADRENALINE BIOSYNTHESIS IN THE BRINDLED MOUSE

—A reduction in central and peripheral synthesis of noradrenaline has been demonstrated in mice hemizygous for the X-linked brindled (Mo^br) mutant in the mouse. The results are consistent with defective hydroxylation of dopamine to NA, arising either as a result of a primary genetic defect in the enzyme dopamine-β-hydroxylase or from the presence of a highly specific inhibitor of this enzyme in mutant mice. Associated with this deficiency of noradrenaline are an increase in the activity of tyrosine hydroxylase in the central nervous system and an increase in the active uptake of tyrosine (and other amino acids sharing a common uptake mechanism with tyrosine) across the blood-brain barrier.     

Effect of cold pressor stimulation on plasma norepinephrine, dopamine-beta-hydroxylase, and renin activity

Changes in plasma levels of norepinephrine, dopamine-β-hydroxylase (DβH), and renin activity were observed in nine healthy volunteers during cold pressor stimulation. Increases in mean arterial blood pressure and heart rate during cold stimulation were accompanied by a sharp rise in plasma norepinephrine, while plasma DβH and renin activity showed little or no change. The results indicate that plasma norepinephrine accurately reflects acute activation of the sympathetic nervous system in contrast to plasma DβH and renin activity.     

EVIDENCE FOR EXTRANORADRENERGIC DOPAMINE-β-HYDROXYLASE ACTIVITY IN RAT SALIVARY GLAND

—Three days after superior cervical ganglionectomy of adult Sprague-Dawley rats, the levels of endogenous norepinephrine, the uptake process for [³H]norepinephrine and the activity of tyrosine hydroxylase decreased 99 per cent in the ipsilateral salivary gland. In contrast, the activity of dopamine-β-hydroxylase and DOPA decarboxylase fell to 30 per cent of the activity of the contralateral innervated gland. Examination of the cofactor requirements, the characteristics of activation by cupric ion and the immunologic identity of this residual hydroxylase activity indicated that it was authentic dopamine-β-hydroxylase. The residual dopamine-β-hydroxylase in the denervated gland had the same subcellular distribution as the enzyme in the innervated salivary gland. Procedures that caused atrophy or hypertrophy of the acinar cells did not affect the total content of dopamine-β-hydroxylase in the denervated salivary gland. Chemical sympathectomy with 6-hydroxy-dopamine caused a 40 per cent decrement in the serum levels of dopamine-β-hydroxylase but a 30 per cent increase in its activity in the denervated salivary gland. Although denervation caused a complete loss of endogenous norepinephrine in the salivary gland, it resulted in only a 15 per cent decrement in the levels of endogenous octopamine and β-phenylethanolamine, two other products of dopamine-β-hydroxylase.     

The presence of dopamine-β-hydroxylase-like enzyme in the vertebrate retina

An analysis of the dopamine-β-hydroxylase activity in various ocular tissues revealed low enzymatic activity in all the retinas analysed. Bovine and monkey retinas had the highest enzyme activity. The enzyme is also present in bovine optic nerve and pigment epithelium/choroid complex, and low levels are present in the vitreous. Immunohistochemical analysis of various retinas with an antiserum raised to bovine adrenal dopamine-β-hydroxylase-showed positive staining only in monkey and bovine retinas. In both instances dopamine-β-hydroxylase immunoreactivity was associated with cells in the ganglion cell layer. These cells are probably ganglion cells since some positive staining was also observed in the bovine optic nerve. Autoradiographical analysis of the uptake of [³H]noradrenaline showed that grains were associated with some structures in the ganglion cell layer. A single prominent layer of terminals at the junction of the inner nuclear and inner plexiform layer of the bovine retina was also apparent. This was considered to be due to [³H]noradrenaline accumulation by dopaminergic amacrine cells. The results suggest that a small number of noradrenergic and/or adrenergic ganglion cells may exist in certain retinas.     

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.     

Catecholamines,ATP and dopamine-β-hydroxylase in the adrenal medulla of the hedgehog in the prehibernating state and during hibernation

The adrenal medulla of the hedgehog (E. europaeus L.) was studied by electron microscopy and biochemical methods for a characterization of the seasonal changes in the cells and subcellular organelles responsible for catecholamine (CA) storage.In the prehibernating state noradrenaline accounted for about 25% of the total CA; these glands contained a number of cells with small, electron-dense cored vesicles not seen in hibernation when adrenalin was the only detectable amine.Upon entrance into hibernation the hedgehog adrenal medulla increased in total CA, ATP, and dopamine-β-hydroxylase (DBH) concomitant with a decline in weight of the medulla.In hibernation the adrenomedullary cells contained granules with cores of moderate electron density. However, most of the cytoplasmic space was occupied by lipid droplets and large, membrane-enclosed follicles. These were disrupted by homogenization concomitant with a relative increase in particle-free, soluble DBH activity.The present findings indicate that the hedgehog stores a reserve of soluble DBH within the adrenomedullary cells during hibernation, thereby appearing well prepared for a rapid switching-on of adrenomedullary CA synthesis upon arousal from hypothermia.     

Effect of tyramine and guanethidine on dopamine-β-hydroxylase activity and norepinephrine concentrations in vesicular fraction of the heart and plasma of rats

Repeated administration of high doses of tyramine to rats results in a striking increase in plasma levels of norepinephrine (NE) and a marked depletion in tissue content of NE. The drug also may produces a moderate increase in plasma levels of dopamine-β-hydroxylase (DBH) and a decrease in DBH in synaptic vesicles of sympathetic nerves in the heart. The latter effects are prevented by a ganglionic blocking agent, indicating that they may be mediated by neuronal activation secondary to the stress attending the drug administration. Chronic administration of guanethidine, which is reported to destroy most sympathetic nerves produces more marked decrease in plasma NE levels and plasma DBH activity. The possible sources of this activity are discussed.     

The presence of antibodies to human dopamine-β-hydroxylase in commercially available antisera

Three criteria have been used to demonstrate the presence of antibodies to human dopamine-β-hydroxylase in commercially available antisera directed against various human serum fractions. These criteria are the inhibition of enzyme activity, complement fixation and binding of ¹²⁵I-labelled dopamine-β-hydroxylase to the immobilized antisera. The level of antibody present in some of these antisera was sufficient to allow their use in the radioimmunoassay of the enzyme. The possibility of other useful antibodies occurring in these and similar antisera is suggested.     

Solubilization of histamine H-1, GABA and benzodiazepine receptors.

Dopamine 3-0-sulfate is present in considerable amounts in mammalian plasma and peripheral tissues. Incubation of dopamine 3-0-sulfate (0.1 μmole) with purified bovine dopamine-β-hydroxylase resulted in the formation of free norepinephrine (7.3 × 10^?3 μmole). The conversion to norepinephrine was inhibited by 0.6 mM of fusaric acid, an inhibitor of dopamine-β-hydroxylase. The reaction of dopamine 3-0-sulfate with dopamine-β-hydroxylase followed Michaelis-Menten kinetics. The calculated K_m was 17 mM, different from the K_m for free dopamine (0.1 mM). The incubation medium does not contain any sulfatase activity.     

CHANGES IN ADRENALS AND SYMPATHETIC NERVE TERMINALS FOLLOWING COLD EXPOSURE

Abstract— Rats kept at 3°C for 24 h show no significant change in the catecholamine content of the adrenals, although the protein content is raised. Whole heart ventricles show no change in noradrenaline content, but the vesicular pellet isolated from heart ventricles has a decreased noradrenaline concentration and DBH activity and an increased protein content.