Biochemical studies of the chromaffin granule. III. Redistribution of lipid phosphate,dopamine-β-hydroxylase and chromogranin a after freezing and thawing of the isolated granule membranes

Freezing and thawing a dialysed suspension of lysed chromaffin granules and sedimented membrane preparations resulted in redistribution of lipid phosphate and protein. By this treatment the high ratios of lipid phosphate/protein in the membrane fragments, isolated on sucrose density gradient from the dialysed suspensions and the sedimented membrane preparation, were reduced from 1.56 to 1.03 μmoles/mg and from 1.97 to 0.83 μmoles/mg, respectively.Multilamellar, liposomal structures could be isolated from the frozen and thawed membrane preparations and were found to sediment in the 0.4 M sucrose layer by density gradient centrigugation. This fraction was without morphological resemblance to the intact chromaffin granules or their membranes and was found to account for 53% of the lipid phosphate, 35% of chromogranin A, 21% of dopamine-β-hydroxylase activity and 12% of the protein of the total preparation. The specific activities of chromogranin A and dopamine-β-hydroxylase in the artificially formed liposomal structures closely resembled that of the solubilized protein and was significantly higher than in the lipid phosphate-depleted membrane fragments recovered in the 1.1 M sucrose layers.It is concluded that freezing and thawing as a means of purifying the isolated granule membranes lead not only to the solubilization of chromogranin A, but also to removal of dopamine-β-hydroxylase activity and lipid phosphate from the labile membrane fragments.     

The chromaffin granule — Plasma membrane interaction as a model for exocytosis: Quantitative release of the soluble granular content

Bovine adrenal medullary plasma membranes induce the release of soluble components from chromaffin granules in a Ca²⁺ dependent manner. This interaction can be modulated by changing the temperature. Correlation of the concentrations of four released soluble markers (catecholamines, soluble protein, ATP and dopamine-β-hydroxylase) in samples incubated at different temperatures revealed that those markers were liberated simultaneously. Their ratio did not differ significantly from the ratio measured in chromaffin granule lysates. These results suggest the release of the total granular content upon incubation with plasma membranes. Further analysis of the free catecholamines showed a preferential release of adrenalin.     

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.     

Direct evidence for co-localization of adenylate cyclase,dopamine-β-hydroxylase and cytochrome b562 to bovine chromaffin granule membranes

Adenylate cyclase, dopamine-β-hydroxylase and cytochrome b₅₆₂ have been found to co-equilibrate on equilibrium sucrose gradients of lysed chromaffin granule membranes from bovine adrenal medulla. Peak activities for these enzymes, as well as maximum membrane protein concentration, were found to coincide at d = 1.11 gm cm^?3, and the ratios of adenylate cyclase to both dopamine-β-hydroxylase and cytochrome b₅₆₂ were constant across the entire peak. Adenylate cyclase activity has been reported previously to co-purify with chromaffin granule membranes, and we conclude, on the basis of these new data, that adenylate cyclase is also an intrinsic granule membrane enzyme.     

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.     

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.     

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 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.     

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.     

Composition of the aqueous phase of chromaffin granules.

Nuclear magnetic resonance spectroscopy has been used to determine the composition of the aqueous phase of bovine chromaffin granules. Relative concentrations of catecholamines (epinephrine plus norepinephrine), ATP and chromogranins have been measured from integrated intensities in the proton spectra using computer simulation techniques. Most or all of the catecholamines (97 +/- 8%) are present in the aqueous phase and contribute to the high resolution spectrum. The catecholamine:ATP molar ratio (4.41 +/- 0.45) determined by NMR is close to the value (4.45) derived from biochemical assay indicating that most or all of the ATP is present with catecholamine in the aqueous phase. Catecholamine:protein ratios show that approximately 45% of the soluble protein freed by lysis is not NMR visible. Intensity from this fraction does not appear under highly denaturing conditions (8 M urea) but reappears after hydrolysis. This behavior is similar to that of recently isolated soluble lipoprotein complexes. Variations in the NMR spectra associated with (1) different preparative procedures; (2) different suspension media, and (3) increasing osmolality are described. The fact that high concentrations of epinephrine and ATP (approximately 700 mM total) are dissolved in the aqueous phase implies that solution phase interactions at least partially ionic in nature are responsible for the low internal osmolality of chromaffin granules in vivo. Ordered phases containing a substantial fraction of the total catecholamine in an osmotically inactive form are not present.     

Composition of the aqueous phase of chromaffin granules

Nuclear magnetic resonance spectroscopy has been used to determine the composition of the aqueous phase of bovine chromaffin granules. Relative concentrations of catecholamines (epinephrine plus norepinephrine), ATP and chromogranins have been measured from integrated intensities in the proton spectra using computer simulation techniques. Most or all of the catecholamines (97 ± 8%) are present in the aqueous phase and contribute to the high resolution spectrum. The catecholamine: ATP molar ratio (4.41 ± 0.45) determined by NMR is close to the value (4.45) derived from biochemical assay indicating that most or all of the ATP is present with catecholamine in the aqueous phase. Catecholamine: protein ratios show that approximately 45% of the soluble protein freed by lysis is not NMR visible. Intensity from this fraction does not appear under highly denaturing conditions (8 M urea) but reappears after hydrolysis. This behavior is similar to that of recently isolated soluble lipoprotein complexes. Variations in the NMR spectra associated with (1) different preparative procedures; (2) different suspension media, and (3) increasing osmolality are described. The fact that high concentrations of epinephrine and ATP (approximately 700 mM total) are dissolved in the aqueous phase implies that solution phase interactions at least partially ionic in nature are responsible for the low internal osmolality of chromaffin granules in vivo. Ordered phases containing a substantial fraction of the total catecholamine in an osmotically inactive form are not present.     

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.     

Molecular mobilities and the lowered osmolality of the chromaffin granule aqueous phase

Carbon-13 spin-lattice relaxation times, T₁, have been measured in whole adrenal medullary tissue slices, in suspensions of isolated chromaffin granules, in the reconcentrated chromaffin granule lysate, and in various model solutions containing catecholamines, ATP, chromogranins and Ca²⁺. Reorientational correlation times have been calculated at 10°C using T₁ data and nuclear Overhauser enhancemments for protonated carbons on both catecholamines and nucleotides. Correlation times in all media are relatively short and characteristic of highly fluid aqueous phases. Adrenalin and ATP exhibit substantial differences in correlation times in all media, however, the ratio γ_R(ATP):γ_R(catecholamine) ranging from 2.4 in simple 3:1 adrenalin-ATP solutions to 4 in intact chromaffin granules. This difference, as well as the relatively high absolute reorientational mobilities of both components, confirms the importance of labile ionic interactions between ATP and catecholamines, but rules out the presence of high concentrations of base-stacked structures. Participation of the chromogranins in ternary complexes with catecholamines and ATP appears to be of minor importance. Ionic interactions to the protein are not reflected in either ¹³C T₁ values or chemical shifts of arginine or glutamate sidechain resonances, or in the ¹³C chemical shifts of ATP or catecholamines. Very labile protein-ATP binding appears to be reflected in the correlation time measurements, however, which show selective immobilization of ATP relative to catecholamine in the presence of soluble protein. Osmotic measurements indicate that solutions containing adrenaline, ATP and Ca²⁺ are highly nonideal, but probably not sufficiently so to account fully for the osmotic stabilization of the chromaffin granule aqueous phase. Even in the absence of specific intermolecular complexation, the chromogranins, through their polyelectrolyte properties, exert a significant influence on the intragranular osmolality. The osmotic lowering due to polyion-counterion interactions has been estimated semiquantitatively using a theory developed by Oosawa.     

CHARACTERIZATION AND TOPOGRAPHY OF THE GLYCOPROTEINS OF ADRENAL CHROMAFFIN GRANULES

The glycoproteins of the membranes of bovine chromaffin granules were characterized by two polyacrylamide gel electrophoresis systems. Five components (I-V) were demonstrated with apparent molecular weights ranging in the unreduced form from 45,000 to 150,000. Glycoprotein I was identified as the enzyme dopamine β-hydroxylase. Four of these glycoproteins (with the exception of component IV) were apparently also present in the membranes of pig and horse chromaffin granules. The soluble proteins of chromaffin granules contained at least three glycoproteins. Only glycoprotein I (dopamine β-hydroxylase) was present both in the soluble content and in the membranes of chromaffin granules. Affinity chromatography with lectins demonstrated that from the soluble proteins only dopamine β-hydroxylase was adsorbed by concanavalin A, whereas none of these proteins reacted with wheat germ lectin and Ricinus communis agglutinin. Three membrane proteins including dopamine β-hydroxylase and glycoprotein II as major components were adsorbed by concanavalin A, whereas wheat germ lectin bound only component II and a small amount of component III. By electron microscopy it was demonstrated that concanavalin A did not bind to intact chromaffin granules whereas ruthenium red and cationized ferritin did. Isotope labelling after galactose oxidase treatment revealed that at least the carbohydrate portion of the major glycoproteins is present on the inner side of the granule membranes facing the content.     

AXONAL TRANSPORT OF PHENYLETHANOLAMINE-N-METHYLTRANSFERASE IN TOAD SCIATIC NERVE

—The presence of phenylethanolamine-N-methyltransferase (EC 2.1.1.-) and dopamine-β-hydroxylase (EC 1.14.2.1) activities was demonstrated in the sciatic nerve of the toad, Bufo marinus. The rates of accumulation of phenylethanolamine-N-methyltransferase (PNMT) and dopamine-β-hydroxylase (DBH) proximal to a ligation of the sciatic nerve were studied. DBH accumulated proximal to the ligation at a more than 10-fold faster rate than PNMT. By measuring the rate of loss of enzyme activity distal to a ligation, an estimate of per cent clearance of each enzyme was made. Based on the per cent of enzyme activity free to move, the absolute transport rates for each enzyme were estimated to be: PNMT, 3.6 mm/24 h; DBH, 102 mm/24 h. PNMT activity (89 per cent) was recovered in the soluble fraction of sciatic nerve homogenates with no change occurring in the subcellular distribution of the enzyme proximal to ligations. In contrast, 43 per cent of DBH activity was found in the soluble fraction of sciatic nerve homogenates; but a disproportionate increase in paniculate DBH activity was found proximal to sciatic nerve ligations. Reduction of toad body temperature to 4°C resulted in a complete but totally reversible block of the axonal transport of both PNMT and DBH.     

The adrenal medulla: A model for studies of hormonal and neuronal storage and release mechanisms

Summary We have observed that phospholipids and protein of the catecholamine (CA) storage granules, i.e. the chromaffin granules, interact in anin vitro system to form liposomal particles, which in many respects resemble the intact matrix of the bovine chromaffin granule. A model has been suggested which consists of an aqueous phase, containing the acidic chromogranins and intact dopamine--hydroxylase (DBH) ATP and CA, embedded in a liquid crystal of the matrix phospholipids. Ca²⁺ may play a significant role in the sequence of functional transitions of such an organelle, not only in the accumulation of Ca²⁺, as during the secretory phase of the intact cell, but also as the agent inducing a separation of the outer membrane bilayer from the matrix phase to be released, as during exocytosis. Furthermore, a liposome model of the matrix may also tentatively explain the occurrence of intact matrices in the interstitium of stimulated glands.Recent evidence for the identity between chromogranin A and DBH subunits have been summarized and a possible role for the inactive subunits in the ionic binding of ATP and CA in the aqueous phase of the matrix is discussed.A role of Ca²⁺ and cyclic AMP in the mediation of-adrenergic modulation is postulated on the basis of our recent work on acetylcholine-induced release of CA from perfused and stimulated bovine adrenals. We conclude that such a-adrenergic modulation is secondary to that of the cholinergic response. Hence, this activation is able to enhance the output induced by mild cholinergic stimulation although insufficient to evoke a CA release by itself.An invited article.     

The interaction of dopamine-beta-hydroxylase with concanavalin A and its use in enzyme purification

Dopamine-β-hydroxylase forms a complex with concanavalin A and can be quantitatively dissociated from the complex with α-methyl-D mannoside. It can thus be separated from other chromaffin vesicle proteins that have no affinity for the lectin. Using this observation it was possible to purify the enzyme by a single passage through a column of concanavalin A-Sepharose. Analysis of the concentrated eluate by disc gel electrophoresis showed that the dopamine-β-hydroxy-last was 93% pure. The binding of this glycoprotein enzyme to concanavalin A indicates that the polysaccharide moiety is highly branched and contains α-D-mannopyranosyl and/or α-D-glucopyranosyl residues as the terminal sugars.     

On ortho-diphenol oxidase activity of dopamine-β-monooxygenase

Dopamine-β-monooxygenase obtained from chromaffin granules revealed, besides hydroxylating, the oxidase activity towards catechol and catecholamines. The oxidase reaction results in the formation of hydrogen peroxide and corresponding o-quinones which, in the case of catecholamines, further spontaneously transform to adrenochrome or related compounds. The oxidase activity, like hydroxylation, is inhibited by copper chelators and inorganic anions with hign affinities to copper atoms. Thus, dopamine-β-monooxygenase may be considered also as a “non-blue” copper-containing oxidase. For the oxidase activity of dopamine-β-monooxygenase, in contrast to its hydroxylating function, the additional reducing cofactor, such as ascorbate, is not necessary.     

Antibacterial Peptides Are Present in Chromaffin Cell Secretory Granules

1. Antibacterial activity has recently been associated with the soluble matrix of bovine chromaffin granules. Furthermore, this activity was detected in the contents secreted from cultured chromaffin cells following stimulation.2. The agents responsible for the inhibition of Gram+ and Gram– bacteria growth are granular peptides acting in the micromolar range or below. In secretory granules, these peptides are generated from cleavage of chromogranins and proenkephalin A and are released together with catecholamines into the circulation.3. Secretolytin and enkelytin are the best characterized; these two peptides share sequence homology and similar antibacterial activity with insect cecropins and intestinal diazepam-binding inhibitor. For some of the peptides derived from chromogranin A, posttranslational modifications were essential since antibacterial activity was expressed only when peptides were phosphorylated and/or glycosylated.4. The significance of this activity is not yet understood. It may be reminiscent of some primitive defense mechanism or may serve as a first barrier to bacteria infection during stress, as these peptides are secreted along with catecholamines.     

A radioimmunoassay of human circulatory dopamine-β-hydroxylase

A procedure for the radioimmunoassay of human circulatory dopamine-β-hydroxylase (DβH) using antibodies directed toward human DβH is described. A significant correlation between serum DβH activity and the amount of serum immunoreactive (IR) DβH was found in the analyzed population. The radioimmunoassay of serum DβH could be used in monitoring changes of sympathetic activity in various physiological and pathological states.