Isolation and characterization of noradrenalin storage granules of bovine adrenal medulla

A method is described for the preparation of (1) the heavy population of bovine adrenal chromaffin granules ($\text{S}{}_{\mathrm{<mtext>H</mtext>}}\text{(}\text{average sedimentation coefficient}\text{) = 12 400}\text{S}$ in 0.25 M sucrose) essentially free from contamination with mitochondria and other organelles, and (2) a subpopulation of this heavy population which is highly enriched in noradrenalin ($\text{?95\%}$ of the total catecholamine is noradrenalin). The method is based on isopycnic gradient centrifugation using a self-generating gradient of polyvinylpyrrolidone-coated colloidal silica particles (Percoll) in 0.5 M sucrose medium.The isolated population of noradrenalin granules appeared highly electron dense in transmission electron microscopy and revealed a rather narrow size distribution. The specific content of amine and adenine nucleotides (with reference to total granule protein) was markedly higher than for the total population of heavy chromaffin granules. The molar ratio of amines to adenine nucleotides was, however, lower in the noradrenalin granules, i.e. 4.8 vs. 11.9.     

Annual cycle of the chromaffin cells of Triturus cristatus

Morphology of the chromaffin cells of Triturus cristatus during a complete annual cycle has been investigated. General ultrastructural characteristics are similar for all chromaffin cells, including numerous small mitochondria, well-developed Golgi apparatus and rough endoplasmic reticulum with short cisternae. The primary difference among cells is the type of the chromaffin granules they posses. These are of two kinds: adrenalin (A) and noradrenalin granules (NA). Both types are simultaneously present in the chromaffin cells but with different ratios during the year. During December–January and May–August, NA granules largely prevail, while in September–November and February–April, A and NA granules are present in about equal quantities. The total quantity of catecholamine granules, however, is relatively constant throughout the year. These findings suggest that T. cristatus has a single type of chromaffin cell, the granule content of which varies according to different functional states. The catecholamines are apparently discharged by exocytosis.     

Transfer of adenine nucleotides between the releasable and nonreleasable compartments of rabbit blood platelets

The metabolic pool of adenine nucleotides in platelets can be labeled by incubating platelets for 1 h in vitro with [14C]adenosine or [32P]orthophosphate. When these platelets are treated with thrombin, the adenine nucleotides released are not labeled. Because of this, Holmsen's suggestion of a metabolically inert pool of granule nucleotides has been generally accepted. We have found that upon incubation of labeled rabbit platelets for longer times (up to 6 h) in vitro, or upon reinjection and reharvesting at times up to 66 h, the releasable pool of adenine nucleotides becomes labeled. Because the rates of 32p and 14C incorporation into this releasable pool are similar, it seems likely that these labels enter the granules as ATP. Equilibrium between the metabolic and granule pools is complete by 18 h. When rabbit platelets are labeled in vivo by intravenous injection of [32P]orthophosphate, peak labeling occurs between 60 and 70 h; this corresponds to their maturation time. The platelets probably incorporate 32P during their production in the megakaryocytes. The specific radioactivity of the adenine nucleotides in the releasable (granule) pool of these platelets is the same as the specific radioactivity in the nonreleasable (metabolic) pool. Since inorganic phosphate in platelets (and undoubtedly in the megakaryocytes) exchanges with inorganic phosphate in plasma, and since the radioactivity of the latter decreases rapidly, the adenine nucleotides in the two pools must exchange to maintain the same specific radioactivity. Transfer of adenine nucleotides into storage granules may represent a general phenomenon because it has been observed in the chromaffin cells of the adrenal medulla also.     

Chromaffin granules and their cellular location in human skin

Summary In a series of biopsies from human skin chromaffin granules were demonstrated in the corium by means of approved tinctorial methods. Characteristically shaped cells with protrusions are described as carriers of the granules.In a supplementary series of human and animal materials, as well as of skin and other tissues the same types of granules and cells were observed. An irregular distribution was demonstrated in the corium, i. e. increase around vessels, nerve fibres and glands, and in the subepithelial layer of the connective tissue. Preliminary calculations showed 2 to 4 times larger amounts in skin from the calf than in skin from the abdomen. In skin from the calf a considerable reduction of the chromaffin granules and typical cells could be demonstrated 24 hours after death. The tinctorial superiority of the modified Sevki method is emphasized. In the material examined, this method proved capable of disclosing chromaffin substance to a much larger extent than other staining procedures. An account is given of the possibilities to differentiate between mast-cell granules and chromaffin granules.Histochemical demonstration of noradrenalin and adrenalin was successful in human skin and in skin, adrenal glands and prostate from a cat and, finally, in skin from rats. The characteristically stained granules seem to be identical with chromaffin granules stained differently. Certain findings are thought to rule out that the cells might appertain to the enterochromaffin system.     

Characteristics and determinants of osmotic lysis in chromaffin granules

(1) Using isolated bovine chromaffin granules, we demonstrate that osmotic lysis is not a random process and establish the osmotic pressure dependence of osmotic lysis in chromaffin granules, the so-called osmotic fragility curve. (2) We show by measuring the release of constituents of the granule core and correlating these with changes in spectroscopic parameters (turbidity and endogenous catecholamine fluorescence), that the latter can be safely used to measure lysis. (3) Within a particular granule population, noradrenaline granules lyse at higher osmolarities than adrenaline granules, suggesting a higher core osmolarity of the noradrenaline granules. (4) The size distribution of chromaffin granules as a function of lysis was determined by the use of whole mount electron microscopy. It is shown that the mean size of chromaffin granules decreases as a function of lysis. (5) On the basis of theoretical considerations three alternative models of the sequence of osmotic lysis in chromaffin granules are proposed. The experimental results best support a model which postulates that during partial osmotic lysis, granule membranes reseal into smaller vesicles after graded release of contents. The osmotic fragility would represent several cycles of lysis and resealing and would not be a reflection of the distribution of osmotic pressures in the granule population.     

Temperature-induced lysis of chromaffin granules provides evidence against the two-pool hypothesis of catecholamine storage

The temperature-dependent release of core constituents from isolated chromaffin granules in isotonic sucrose has been a controversial and puzzling phenomenon that has been interpreted either as selective catecholamine efflux from different catecholamine pools or as temperature-dependent lysis. We have analysed the kinetics, temperature dependence and physical basis of this process. Our results demonstrate that, upon increasing the ambient temperature, chromaffin granules show a shift in their osmotic fragility to higher osmolarities, which is linearly dependent on temperature and leads to measurable lysis in 0.26 M buffered sucrose at temperatures above 12 degrees C. It is possible to demonstrate both protein and dopamine beta-hydroxylase release when lysis as a function of temperature is measured in 0.26 M buffered sucrose. Real time measurements of the lysis kinetics were recorded on cassettes and analysed by a computer program for exponential decay kinetics. It is shown that the temperature-dependent lysis proceeds in two separate phases, the fast one of which is associated with temperature-dependent shift in the osmotic fragility curve. It has no characteristics of any exponential decay kinetics. The slow phase, when followed over several hours, leads to complete lysis of the granules in a sigmoidal time course at 30 degrees C. We conclude from the absence of exponentiality that there is no basis on which to assume the existence of different catecholamine pools. The fast phase of temperature-dependent lysis can be best explained as a simple temperature-dependent increase of the granule core solution's osmotic pressure, while the slow phase is probably caused by sucrose permeation into the granules. On the basis of these results, we warn against any efflux experiments measuring the temperature-dependent transmitter release from secretory vesicles with highly concentrated core solutions.     

Effects of stimulation by carbachol on the metabolism of the bovine adrenal medulla

1. A method is described that has made it possible to achieve a great decrease in the catecholamine and adenine nucleotide contents of the perfused bovine adrenal gland by the infusion of carbachol. 2. Although the catecholamines secreted were recovered in the perfusion medium, no evidence was obtained that the nucleotides are secreted by the gland. 3. It is concluded that the secretion of catecholamines is accompanied by extensive chemical alteration of the adenine nucleotides of the chromaffin granules. 4. The secretory response and the spontaneous release of catecholamines depends on the presence of Ca²⁺ in the perfusing Tyrode solution. 5. Anoxia does not have a significant effect on the carbachol-induced secretion of catecholamines. 6. Strips of bovine adrenal medullary tissue perfused with oxygenated Tyrode solution show an increased oxygen consumption when carbachol is added.     

Incorporation of adenosine into nucleotides of chromaffin cells maintained in primary cultures

Extracellular adenosine was incorporated into nucleotides of bovine chromaffin cells maintained in primary culture. In intact chromaffin tissue, a very low incorporation was found (0.8 pmol/10⁶ cells/h at an adenosine concentration of 11.45 μM), which increased 282 times in freshly isolated chromaffin cells. When maintained in primary culture, this value decreased to a value similar to that of chromaffin tissue, but later on, and in the presence of nerve growth factor (NGF), a time dependent increase of adenosine incorporation was observed which, in 84-h old cells reached up to 54 times more than that found in intact tissue. This incorporation might reflect changes in the adenosine transport at the cell membrane level, furthered by NGF effect. Incorporation, which was time-dependent, was weakly modified by stimulation of cells with 10^?4 M acetylcholine. However, acetylcholine-induced release of labelled nucleotides from chromaffin granules was observed, probably in relation to granule maturation.     

In Adrenal Medulla Synaptophysin (Protein p38) Is Present in Chromaffin Granules and in a Special Vesicle Population

We have analyzed the properties and subcellular localization of synaptophysin (protein p38) in bovine adrenal medulla. In one-dimensional immunoblotting the adrenal antigen appears identical to synaptophysin of rat synaptic vesicles. In two-dimensional immunoblotting it migrates as a heterogeneous band varying in pI from 4.5 to 5.8. Subcellular fractionation by various sucrose gradients revealed that synaptophysin was present in two different cell particles. More than half of the antigens present in adrenal medulla were confined to special membranes that sedimented both with the "large granules" and with microsomal elements. These membranes could be removed from the large granule sediment by washing. In gradients it equilibrated in regions of low sucrose density. These membranes did not contain any markers for chromaffin granules. Less than half of the amount of synaptophysin present in adrenal medulla copurified with chromaffin granules. Despite several variations in the fractionation scheme synaptophysin could not be removed from chromaffin granules. After washing of granule membranes with alkaline solution synaptophysin still cosedimented in gradients with typical granule markers. The concentration of synaptophysin in membranes of chromaffin granules is low (less than 10%) when compared with synaptic vesicles. It is concluded that in adrenal medulla synaptophysin is present in special membranes, probably in high concentration, and in membranes of chromaffin granules, either in a low concentration in all or in a higher concentration in some of them.     

Aggregation and dispersity of isolated chromaffin granules studied by intensity fluctuation spectroscopy

The aggregation and dispersity of isolated bovine adrenal secretory vesicles (chromaffin granules) were studied by intensity fluctuation spectroscopy. The degree of dispersity and the Z-average translational diffusion coefficients were calculated from the autocorrelation functions of the intensity fluctuations in lase light scattered from the granules in solution. Granules purified by sedimentation through 0.3 M sucrose/Ficoll/²H₂O showed greater dispersity than granules purified by sedimentation through 1.6 M sucrose. By monitoring the scattered light intensity and the diffusion coefficients of the granules, many of the difficulties encountered in the interpretation of absorbance measurements were avoided. Measurements over a range of granule concentrations in sucrose solutions (10 mM HEPES, pH 7.0), indicated that aggregation of the granules occurred at concentrations above 150 μg protein/ml. At low granule concentrations (15–30 μg protein/ml) Ca²⁺-induced aggregation was detected at a threshold of 2–10 mM calcium.     

The soluble components of chromaffin granules a carbon-13 NMR survey

Carbon-13 NMR spectra of the reconcentrated chromaffin granule lysate have been obtained at 50 MHz and 62.9 MHz. The spectrum contains a number of assignable resonances in addition to those of the main soluble components (catecholamines, adenine nucleotides and chromogranin). Guanine and uridine nucleotides are present at levels of 0.13 and 0.08 mol/mol adenine nucleotides, respectively. Concentrations of cytidine nucleotides and NAD⁺ are below the detection limit (0.02 mol/mol adenine nucleotides). An unidentified low molecular weight species, thought to be an adenine-containing oligonucleotide, is also present. Ascorbic acid was observed at a concentration of 0.14 mol/mol adenine nucleotides, but both dopamine and dehydroascorbic acid were below the detection limit. Protein resonances agree well with the reported amino acid composition of chromogranin A, with the exception of tryptophan and glutamine which have not previously been measured. The concentrations of these residues are estimated to be 12 ± 3 and 39 ± 5 residues per 77 000 dalton unit of chromogranin A. Substantial intensity due to unsaturated fatty acid side-chains in solubilized lipid is seen in the olefinic carbon region and in the methylene region, suggesting the presence of lipoprotein. Unassigned carbohydrate resonances are also present, but are largely obscured by sucrose in the isolation medium.     

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.     

Characterization of Proenkephalin-Cleaving Proteinases in Bovine Adrenal Chromaffin Granules Using [35S]Proenkephalin Copolymerized into Sodium Dodecyl Sulfate-Polyacrylamide Gel Electrophoresis

Proteinases capable of cleaving proenkephalin into smaller peptides have been identified in bovine adrenal chromaffin granules using [35S]methionine-labeled recombinant rat proenkephalin as a selective substrate in sodium dodecyl sulfate-polyacrylamide gel electrophoresis proteinase radiozymography. This technique was used for the screening of subcellular fractions, general characterization of pH optima, and the mechanistic characterization of proteinases with both reversible and irreversible inhibitors. Two enzymes with approximate molecular masses of 76 and 30 kDa were shown to be localized to the highest-density fractions of chromaffin granules by sucrose density gradient fractionation. Both were enriched in a 1 M NaCl wash of purified chromaffin granule membranes, were active at high pH, and were characterized as serine proteinases based on inhibition by soybean trypsin inhibitor. The 30-kDa enzyme was also inhibited by diisopropyl fluorophosphate, D-Phe-Pro-Arg-CH2Cl, and D-Val-Phe-Lys-CH2Cl and appeared to be the previously described adrenal trypsin-like enzyme. A third enzyme, of 66 kDa, was also associated with the 1 M NaCl wash of purified chromaffin granule membranes but was not localized exclusively to chromaffin granules in sucrose gradients. This proteinase was found to be Ca2+ activated and inhibited by EDTA but not diisopropyl fluorophosphate, soybean trypsin inhibitor, p-chloromercuriphenylsulfonic acid, 1,10-phenanthroline, or pepstatin.     

Turnover and Storage of Newly Synthesized Adenine Nucleotides in Bovine Adrenal Medullary Cell Cultures

The adenine nucleotide stores of cultured adrenal medullary cells were radiolabeled by incubating the cells with 32Pi and [3H]adenosine and the turnover, subcellular distribution, and secretion of the nucleotides were examined. ATP represented 84-88% of the labeled adenine nucleotides, ADP 11-13%, and AMP 1-3%. The turnover of 32P-adenine nucleotides and 3H-nucleotides was biphasic and virtually identical; there was an initial fast phase with a t1/2 of 3.5-4.5 h and a slow phase with a half-life varying from 7 to 17 days, depending upon the particular cell preparation. The t1/2 of the slow phase for labeled adenine nucleotides was the same as that for the turnover of labeled catecholamines. The subcellular distribution of labeled adenine nucleotides provides evidence that there are at least two pools of adenine nucleotides which make up the component with the long half-life. One pool, which contains the bulk of endogenous nucleotides (75% of the total), is present within the chromaffin vesicles; the subcellular localization of the second pool has not been identified. The studies also show that [3H]ATP and [32P]ATP are distributed differently within the cell; 3 days after labeling 75% of the [32P]ATP was present in chromaffin vesicles while only 35% of the [3H]ATP was present in chromaffin vesicles. Evidence for two pools of ATP with long half-lives and for the differential distribution of [32P]ATP and [3H]ATP was also obtained from secretion studies. Stimulation of cell cultures with nicotine or scorpion venom 24 h after labeling with [3H]adenosine and 32Pi released relatively twice as much catecholamine as 32P-labeled compounds and relatively three times as much catecholamine as 3H-labeled compounds.     

On-line measurement of adenosine triphosphate and catecholamine released from adrenal chromaffin cells.

Adenosine triphosphate (ATP) and catecholamine (CA) released from cultured porcine adrenal chromaffin cells were continuously measured with an ATP photometer (luciferin-luciferase method) and electrochemical detector, respectively. Application of acetylcholine (ACh, 0.1 mM) or high K+ (60 mM) caused increases of ATP and CA in perfused effluent with the same time course. The peak molar ratio of CA to ATP in the effluent was about 10 for ACh and high K+ stimulation. The high-performance liquid chromatographic (HPLC) analysis of adenine nucleotides in the collected effluent revealed that the relative amounts of ATP, ADP and AMP were almost the same throughout the period of stimulation, suggesting that ATP breakdown in the effluent was constant. Changes in the peak molar ratio of CA to ATP appearing in the effluent did not occur with repetitive high K+ or sustained Ba2+ stimulation (5 mM). The similarity between the time courses of ATP and CA appearing in the effluent suggests that releasable chromaffin granules have a constant molar ratio of CA to ATP. The on-line system developed is a simple and rapid method for examining ATP and CA secretion, simultaneously.     

Comparison of the ultrastructure of adrenaline and noradrenaline storage granules of bovine adrenal medulla

The ultrastructure of the membranes of noradrenaline (NA) and adrenaline (A) granules of the bovine adrenal medulla (Terland, O., T. Flatmark, and H. Kryvi, Biochim, Biophys. Acta 553, 460--468 (1979)) was analyzed by transmission, negative staining and freeze-etch electron microscopy. The two types of storage granules can be distinguished mainly by two morphological criteria: (a) The NA-granules have a more electron dense matrix core than the A-granules, (b) the NA-granules revealed less asymmetry in the distribution of intramembrane particles (nPF:nEF = 4,5:1) than the A-granules (nPF:nEF = 9:1). Thus, the trilaminar structure, negative staining pattern and size distribution of the intramembrane particles of the two fracture faces on freeze-etch electron microscopy were very similar for the two types of granules. Freeze-etching revealed a wide range of the particle size distribution for both fracture faces in both types of granules, with an average diameter of 12.6 +/- 2.7 nm (A-granules) and 10.2 +/- 2.8 nm (NA-granules) for the E-fracture faces and 11.4 +/- 2.7 nm (A-granules) and 9.8 +/- 2.4 nm (NA-granules) for the P-fracture faces. Some of the particles on the P-fracture face (outer surface of the membrane) revealed a subunit structure, most clearly seen in the specimens of NA-granules. Morhpometric analyses of sectioned bovine adrenal medulla revealed that the chromaffin granules on an average account for approx. 13.5% of the cytoplasmic volume in the total population of chromaffin cells.     

Ultrastructural and cytochemical characterization of adrenal medullary plasma membrane vesicles and their interaction with chromaffin granules

Plasma membrane vesicles obtained by density gradient centrifugation of bovine adrenal medullary homogenates were analyzed by electron microscopic methods, including negative staining, ultrathin sections and freeze-fracture replicas. Rapid freezing showed the intramembrane structure of plasma membrane vesicles to be distinct from that of other organelle membranes, such as chromaffin granules. Cytochemical demonstration of acetylcholinesterase (EC 3.1.1.7) activity on most membrane profiles confirmed that plasma membrane vesicles are derived predominantly from plasma membranes. About half of the plasma membrane vesicles were smaller than 0.15 micron and almost none larger than 0.55 micron. Practically all were composed of single shells. Most vesicles were impermeable to cytochemical markers of the size of Ruthenium red (Mr 800) and none were permeable to markers larger than 40 kDa. Surface charge probes, concanavalin A binding and endogenous actin decoration with heavy meromyosin indicated that the major fraction of plasma membrane vesicles is oriented right-side-out. A minor population with opposite orientation could also be detected. Isotonic ionic media caused vesicle aggregation in suspensions of plasma membrane vesicles and chromaffin granules. Freeze-fracturing always revealed clusters of membrane-intercalated particles at the sites of contact between aggregated membranes.     

Purine Nucleotide Synthesis in Adrenal Chromaffin Cells

Abstract: The synthesis of purine nucleotides from the salvage precursors adenine and adenosine, and from the de novo precursors formate and glycine, was studied in isolated adrenal chromaffin cells. Both [8-¹⁴C]adenine and [8-¹⁴C]adenosine from extracellular medium are effectively incorporated into intracellular nucleotides. [¹⁴C]Formate and [U-¹⁴C]glycine are also incorporated, but de novo synthesis is clearly lower than synthesis from salvage precursors, although similar to de novo synthesis in liver. The enzymes responsible for adenine and adenosine salvage, adenine phosphoribosyltransferase and adenosine kinase, were purified about 1,500-fold. Both enzymes are mainly cytosolic and exhibit a similar molecular weight of around 42,000. The results suggest that chromaffin cells can replenish their intracellular nucleotides lost during the secretory event by an active synthesis from salvage and de novo precursors.     

Extraction of corticosterone from cell homogenates and subcellular fractions of the rat adrenal cortex. II. ACTH-induced changes in subcellular corticosterone

Zona fasciculata-reticularis subcellular structures were implicated in corticosterone transport and secretion by noting changes in subcellular corticosterone during a 30-min period following ACTH stimulation. Six decapsulated adrenal homogenate subcellular fractions separated by gradient centrifugation were characterized cytochemically and morphologically. Predominant components in each of six fractions were: floating lipid droplets, 0.125 M sucrose (no organelles), cytosol (0.25 M sucrose supernatant with 0.25-1.2 micron electron dense granules), microsomes (interface between 0.5 M and 1.1 M sucrose layers), mitochondria (boundary between 1.1 M and 2.2 M sucrose layers) and nuclei (centrifuge pellet). Whole glands and most subcellular fractions showed peak corticosterone levels 10 to 15, and 30 min after stimulation. Sucrose and cytosolic fractions contained about 75% of the total corticosterone, responded to stimulation most significantly, and were rich in protein. In these two fractions only cytosol contained structures; these consisted of 0.15-1.2 micron electron dense granules.