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.     

Organogenesis of the pituitary, adrenal, and lung at birth in the wallaby, Macropus rufogriseus

The ultrastructure of the pituitary, the adrenal, and the lung was examined in the newborn wallaby, Macropus rufogriseus. Tissue from six wallaby neonates (less than 8 hr of age), two near-term fetuses (26 days after removal of suckling pouch young [RPY]), and a two-day-old pouch young was examined; and tissue levels of cortisol in the adrenal glands of five neonates and a near-term fetus (26 days) were measured by radioimmunoassay. At birth the adenohypophysis comprised the bulk of the pituitary gland. The pars distalis was well vascularized and many cells contained electron-dense, membrane-bound granules. The adrenal glands lacked specific zones but comprised two distinct populations of cells. The cytoplasm of one cell type contained electron-dense, membrane-bound granules, similar to those observed inside catecholamine-secreting cells of the adrenal medulla; the other cell type possessed large amounts of smooth endoplasmic reticulum and mitochondria with tubulo-vesicular cristae. These features are characteristic of cells which are actively synthesizing steroid hormones. The concentration of cortisol was 0.58 ng/adrenal in the wallaby at birth. The fetal lungs near term were at the glandular stage of development, and epithelial differentiation of type I and type II pneumocytes was imminent although attenuation was not evident. The canalicular neonatal lung did not contain true alveoli, but type II pneumocytes contained osmiophilic lamellar inclusions of surfactant. The fetal pituitary and adrenal are functional at birth and are thus capable of initiating parturition and of influencing lung maturation in the fetus.     

Catecholamine-storing cells in the adrenal medulla of the pre- and postnatal rat

Summary The development of the rat adrenal medulla was studied at the ultrastructural level with particular emphasis placed on early discrimination of different catecholamine-storing cells. The first granule-containing cells, phaeochromoblasts, were seen at day 15 of gestation migrating into the anlage of the cortex. These cells were characterized by a few small granules (80–120 nm in diameter) and a high nuclear to cytoplasmic ratio. Presumably due to differentiation into chromaffin cells, they were no longer present after the eighth postnatal day. Maturation of phaeochromoblasts was indicated by an increase in number and size of their storage granules and a decrease in the nuclear to cytoplasmic ratio. Noradrenaline and adrenaline cell types were first clearly discernible at day 21 of gestation. Another cell type, a giant cell, was also recognized at this stage. In the adult animal, noradrenaline, two morphologically different types of adrenaline, and small granule-containing cells were observed.By applying acetylcholinesterase histochemistry, it was found that at day 17 of gestation a small population of granule-storing cells showed strong positive staining in the endoplasmic reticulum. In the adult animal this cell type was further characterized by small-storage granules. Other chromaffin cells began to show weak staining within the endoplasmic reticulum at day 19 of gestation. This staining appeared more frequently within adrenaline than noradrenaline cells. However, even in the adult animal many cells of both types were completely negative.It is concluded that acetylcholinesterase histochemistry is a useful method for early discrimination of small granule-containing cells in the developing rat adrenal medulla.Supported by grants from the Deutsche Forschungsgemeinschaft     

Expression of the noradrenaline transporter and phenylethanolamine N-methyltransferase in normal human adrenal gland and phaeochromocytoma

Expression of the noradrenaline transporter (NAT) was examined in normal human adrenal medulla and phaeochromocytoma by using immunohistochemistry and confocal microscopy. The enzymes tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT) were used as catecholamine biosynthetic markers and chromogranin A (CGA) as a marker for secretory granules. Catecholamine content was measured by using high performance liquid chromatography (HPLC). In normal human adrenal medulla (n=5), all chromaffin cells demonstrated strong TH, PNMT and NAT immunoreactivity. NAT was co-localized with PNMT and was located within the cytoplasm with a punctate appearance. Human phaeochromocytomas demonstrated strong TH expression (n=20 samples tested) but variable NAT and PNMT expression (n=24). NAT immunoreactivity ranged from absent (n=3) to weak (n=10) and strong (n=11) and, in some cases, occupied an apparent nuclear location. Unlike the expression seen in normal human adrenal medullary tissue, NAT expression was not consistently co-localized with PNMT. PNMT also showed highly variable expression that was poorly correlated with tumour adrenaline content. Immunoreactivity for CGA was colocalized with NAT within the cytoplasm of normal human chromaffin cells (n=4). This co-localization was not consistent in phaeochromocytoma tumour cells (n=7). The altered pattern of expression for both NAT and PNMT in phaeochromocytoma indicates a significant disruption in the regulation and possibly in the function of these proteins in adrenal medullary tumours.     

Plasminogen activator inhibitor (type-1) in rat adrenal medulla

Summary Plasminogen activator inhibitor type-1 (PAI-1) was identified in extracts of rat adrenal medulla, and its immunohistochemical localization was studied together with that of tissue-type plasminogen activator (t-PA). By staining of adjacent sections and by doublestaining of the same section we demonstrate that the same cells of the adrenal medulla contain both PAI-1 and t-PA immunoreactivity in the cytoplasm. In addition a few ganglion cells of the adrenal medulla were found to contain PAI-1 but not t-PA. Neither of the components were found in the adrenal cortex. Analysis of extracts from isolated adrenal medulla using reverse zymography showed the presence of a plasminogen activator inhibitor with M _r46000. The inhibitory activity disappeared when the extract was passed through a column with sepharose-coupled anti-PAI-1 IgG, while the run-through from a similar column coupled with preimmune IgG still contained the inhibitor. The present findings suggest that PAI-1 could play a role in the regulation of t-PA activity in the rat adrenal gland medullary cells.     

Funktionsentwicklung der Nebenniere beim Goldhamster

Zusammenfassung Adrenalin-Granula lassen sich elektronenmikroskopisch im Mark von Goldhamsterfeten bereits 2 Tage vor der Geburt und damit 3 Tage früher als lichtmikroskopisch-histochemisch erkennen. Sie sind zu Beginn 0,1 m groß und nach Kalium-Bichromatvorbehandlung des Gewebes von den 15 Tage nach der Geburt auftretenden Noradrenalin-Granula gut zu unterscheiden.Im weiteren Verlauf der postnatalen Entwicklung nehmen die beiden Granulatypen unterschiedlich an Größe zu. Der beim erwachsenen Goldhamster gefundene mittlere Durchmesser der Adrenalin-Granula beträgt 0,16±0,05 m.Elektronenmikroskopisch-histochemisch können Adrenalin- und Noradrenalin-Granula auch dann eindeutig unterschieden werden, wenn sich ihre mittleren Durchmesser während eines begrenzten Entwicklungsabschnittes nicht signifikant unterscheiden.Die durch umgekehrte Micropinocytose aus dem Cytoplasma der Markzellen ausgeschleusten Granula konnten im Intercellularspalt, im interstitiellen Bindegewebe, in den Lumina der Markfollikel und Sinus und an Erythrozyten beobachtet werden.

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Summary Adrenaline granules can be seen in the electron microscope 2 days before birth in the adrenal medulla of the fetal golden hamster. This is 3 days earlier than by using histochemical methods in the light microscope. In the first time they are approximately 0.1 m in diameter and can be well differentiated from noradrenaline granules after treatment of tissue with potassium-bichromate.In postnatal development the mean diameters of both adrenaline and noradrenaline granules increase in a different degree. So the mean diameter of adrenaline granules in adult animals is 0,16±0,05 m whereas the one of noradrenaline granules comes to 0,26±0,05 m.Using a histochemical method adrenaline and noradrenaline granules can be well differentiated in the electron microscope regardless if during a period in ontogenesis their mean diameters do not differ significantly.Granules are extruded from the cytoplasma of medullary cells by reversed micropinocytosis. Either the material of granules or granules itself could be observed in intercellular space, at the interstitial connective tissue, at the lumina of medullar follicles and sinus, and adsorbed at erythrocytes.

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Unter technischer Assistenz von M. Tölken und H. Guckes.

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Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.

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Zur Zeit Gast am Anatomischen Institut Tübingen.     

On the uptake and storage of 5-hydroxytryptamine, 5-hydroxytryptophan and catecholamines by adrenal chromaffin cells and nerve endings

Summary Light-microscopic autoradiographs of the adrenal medulla at various intervals after the intravenous injection of [³H] 5-HTP, [³H] 5-HT, [³H] noradrenaline and [³H] adrenaline have been studied. The distribution of silver grains following [³H] 5-HTP uptake was found to be uniform over each of the two main cell populations, adrenaline-storing (A) cells and noradrenaline-storing (NA) cells in the adrenal medulla, but A cells were twice as active as NA cells in incorporating the isotope, a situation very similar to that found after [³H] dopa uptake. 5-HT administration resulted in a pattern resembling the distribution of [³H] noradrenaline uptake, with A cells being 4 or 5 times more active than NA cells and a gradient of activity from the periphery of the medulla inwards. However, the time-course for the loss of radioactivity was not the same for both amines: levels of 5-HT activity were not significantly reduced after one week whereas the degree of [³H] noradrenaline labelling after one week was less than 10% of that at one hour. Thus 5-HT may be bound to sites in the adrenal medulla normally occupied by noradrenaline but it would appear that the release mechanism is different. There was no evidence of 5-HT uptake by adrenal nerve endings.     

Localization of enkephalins in adrenaline cells and the nerves innervating adrenaline cells in rat adrenal medulla

The coexistence of met5- and leu5-enkephalin-like immunoreactivities with catecholamines in the rat adrenal medulla was studied with combined fluorescence microscopy and immunocytochemistry. Both met5- and leu5-enkephalin-like immunoreactivities were localized in few heavily stained adrenaline cells and in a population of nerves innervating adrenaline cells and as well as ganglion cells among the adrenaline cells. Only occasionally single noradrenaline cells exhibited light immunostaining for both enkephalins but no positive fibers could be found around the noradrenaline cells. In electron microscope the immunoreaction was seen in the granules of the adrenaline cells and in the large synaptic vesicles of the nerve terminals around the adrenaline cells. The present findings suggest that enkephalin-like immunoreactivity coexists mainly with adrenaline in rat adrenal medulla and that the enkephalin immunoreactive terminals regulate secretion of adrenaline from rat adrenal medulla.     

Ultrastructure of the Acidophilic Aerobic Photosynthetic Bacterium Acidiphilium rubrum

The ultrastructure of cells of Acidiphilium rubrum, which is an acidophilic aerobic photosynthetic bacterium containing zinc-complexed bacteriochlorophyll a, was studied by electron microscopy with the rapid substitution technique. Thin-section electron microscopy indicated that any type of internal photosynthetic membranes was not present in this organism despite a relatively high content of the photopigment. The majority of cells had poly-β-hydroxybutyrate granules and electron-dense spherical bodies identified as being polyphosphate granules. When the organism was grown chemotrophically with 0.1% FeSO₄, it produced another group of electron-dense granules that were associated with the inner part of the cytoplasmic membrane. An energy-dispersive X-ray analysis showed that these membrane-bound, electron-dense granules contained iron. Received: 24 November 1999 / Accepted: 5 January 2000     

Localization of enkephalin- and neurotensin-like immunoreactivities in cat adrenal medulla

Summary Enkephalin (ENK)- and neurotensin (NT)-immunoreactivities (IR) were localized in cat adrenal medulla using immunocytochemistry. ENK was localized mainly in adrenaline cells, 70%–80% of which were heavily labelled. About 5%–10% of the noradrenaline cells were ENK-immunoreactive (IR). A dense network of ENK-IR nerves was localized among adrenaline cells. NT was localized only in the noradrenaline cells, 60%–70% of which were immunoreactive. NT- and ENK-IR were localized in separate noradrenaline cells. A dense network of NT-IR nerves was restricted among noradrenaline cells.The present findings confirm that ENK- and NT-like peptides are localized in separate adrenal medullary cells and demonstrate that also the preganglionic nerves are divided in subpopulations according to their neuropeptide content. These nerves have a selective localization among adrenaline and noradrenaline cells and may have physiological significance in the control of secretion of catecholamines and neuropeptides from adrenal medulla.     

Localization of enkephalins in adrenaline cells and the nerves innervating adrenaline cells in rat adrenal medulla

Summary The coexistence of met5- and leu5-enkephalinlike immunoreactivities with catecholamines in the rat adrenal medulla was studied with combined fluorescence microscopy and immunocytochemistry. Both met5- and leu5-enkephalin-like immunoreactivities were localized in few heavily stained adrenaline cells and in a population of nerves innervating adrenaline cells and as well as ganglion cells among the adrenaline cells. Only occasionally single noradrenaline cells exhibited light immunostaining for both enkephalins but no positive fibers could be found around the noradrenaline cells. In electron microscope the immunoreaction was seen in the granules of the adrenaline cells and in the large synaptic vesicles of the nerve terminals around the adrenaline cells. The present findings suggest that enkephalin-like immunoreactivity coexists mainly with adrenaline in rat adrenal medulla and that the enkephalin immunoreactive terminals regulate secretion of adrenaline from rat adrenal medulla.     

Distinct distribution of immunoreactive dynorphin and leucine enkephalin in various populations of isolated adrenal cromaffin cells

The distribution of immunoreactive-dynorphin (ir-Dyn) in isolated subpopulations of bovine adrenal chromaffin cells was examined and compared with that of adrenaline (A), noradrenaline (NA) and ir-Leucine-Enkephalin (ir-Leu-Enk). Using a stepwise bovine serum albumin (BSA) gradient, various populations of catecholamine-storing cells were separated and designated as cell layers I, II and III. Cell layer I contained more NA than A; cell layer II contained slightly more A than NA whereas cell layer III was highly enriched in A. The original cell preparation contained 2.9 times more ir-Leu-Enk than ir-Dyn (4.7 and 1.6 pmoles per 10(6) cells, respectively). After separation of the cells on BSA gradient, ir-Dyn was mainly detected in cell layer I (4.0 pmoles/10(6) cells) whereas ir-Leu-Enk was concentrated in cell layer III (8.3 pmoles/10(6) cells). Both peptides were secreted in response to acetylcholine (5 x 10(-5) M), but the amount secreted was in accordance with the cell content in each peptide. After subcellular fractionation of the adrenal medulla, the neuropeptides were found in close association with catecholamines in the secretory granules. These results indicate that bovine adrenal chromaffin cells can be isolated according to their specific content in A, NA and opioid peptides and are consistent with the hypothesis of distinct biosynthetic pathways for Dyn and the Enk.     

Release of chromaffin granular content from staphylococcal enterotoxin B (SEB)-treated and-untreated PC12 cells

Summary The release of chromaffin granular content from staphylococcal enterotoxin B (SEB)-treated and-untreated PC12 cells was studied by electron microscopy. The treatment of the cells with SEB at the concentration of 20 μg/ml caused marked increase of the chromaffin granules that either bound to the plasma membrane by the characteristic rods, measuring 15 to 20 nm in length and showing a tubular structure, or budded off at the free cell surface, surrounded by a layer of rod-containing cytoplasm and enclosed by the plasma membrane. The binding between the granular and plasma membranes by the rods did not lead to membrane fusion and exocytosis of the granular content. Many of the bound granules showed vesiculation with loss of the electron-dense core material; at the same time, some of the binding rods contained intraluminal electron-dense material similar to the granular core material. These findings suggested that the electron-dense material (i.e., norepinephrine) of the bound granules was released extracellularly through channels within the rods. Although the granules were bound to the plasma membrane with equal frequency at the free and contiguous cell surfaces, the granular budding occurred only at the free cell surface, indicating that it occurred incidentally to some granules bound at the free cell surfaces. On the basis of the morphological observations, it is postulated that the electron-dense material of the bound granule is selectively released extracellularly through the rods, leaving the vesiculated granules behind in the cytoplasm. The same mode of release of the granular content was observed, though less frequently, in the untreated control cells. No morphological evidence that indicated that the granular content was released extracellularly by exocytosis was found in the treated and control cells. The present observations indicated that the SEB treatment of PC12 cells stimulated the binding of chromaffin granules to the plasma membrane by the rods and the budding of the bound granules at the free cell surface.     

Effect of hydrocortisone,reserpine, propranolol and phentolamine on in vivo uptake of exogenous amines by adrenal chromaffin cells

Summary An autoradiographic study was performed on the effects of hydrocortisone, reserpine, propranolol and phentolamine on the uptake of tritiated amines by adrenal medullary cells of the mouse. Oral feeding of hydrocortisone had no significant effect on the normal uptake pattern of dopamine, noradrenaline or adrenaline by medullary cells of different type (A cells or NA cells) or location (marginal or central), although the overall amounts taken up were markedly reduced. Handling the animals led to similar reductions in the uptake of all three amines and was thus clearly shown to be the important factor in this effect. Reserpine reduced the uptake of [³H] noradrenaline to 25 % of the control value although the relative distribution remained unchanged. Propranolol and phentolamine had no observed effect on [³H] noradrenaline uptake. These results are discussed in the light of the previously reported action of ACTH in reversing the effects of hypophysectomy on medullary amine uptake (Hirano and Kobayashi 1978), and it is concluded that ACTH must exert this effect directly on the adrenal medulla rather than through the secretion of adrenal corticosteroids. It is also suggested that reserpine acts, as in neurons, by blocking amine uptake into intracellular granules rather than by blocking uptake into the cell itself.     

Gamma-aminobutyric acid (GABA) immunoreactivity in the mouse adrenal gland

Gamma-aminobutyric acid (GABA) immunoreactivity was revealed by immunocytochemistry in the mouse adrenal gland at the light and electron microscopic levels. Groups of weakly or faintly GABA immunoreactive chromaffin cells were often seen in the adrenal medulla. By means of immunohistochemistry combined with fluorescent microscopy, these GABA immunoreactive chromaffin cells showed noradrenaline fluorescence. The immunoreaction product was seen mainly in the granular cores of these noradrenaline cells. These results suggest the co-existence of GABA and noradrenaline within the chromaffin granules. Sometimes thick or thin bundles of GABA immunoreactive nerve fibers with or without varicosities were found running through the cortex directly into the medulla. In the medulla, GABA immunoreactive varicose nerve fibers were numerous and were often in close contact with small adrenaline cells and large ganglion cells; a few, however, surrounded clusters of the noradrenaline cells, where membrane specializations were formed. Single GABA immunoreactive nerve fibers, and thin or thick bundles of the immunoreactive varicose nerve fibers ran along the blood vessels in the medulla. The immunoreaction deposits were observed diffusely in the axoplasm and in small agranular vesicles of the GABA immunoreactive nerve fibers. Since no ganglion cells with GABA immunoreactivity were found in the adrenal gland, the GABA immunoreactive nerve fibers are regarded as extrinsic in origin.     

K+ and Ca++ in the receptor lymph of arthropod cuticular mechanoreceptors

Summary Two types of cuticular strain detectors, the campaniform sensilla on the haltere of the blowfly,Calliphora vicina, and the slit sensilla on the tibia of the spider,Cupiennius salei, were investigated. In campaniform sensilla a transepithelial voltage (43.6±10.7 mV), which depends on an intact metabolism, occurs. In spider slit sensilla no transepithelial voltage exists. The occurrence and the lack of a transepithelial voltage is paralleled with differences in the ionic composition of the receptor lymph in the two arthropod sensilla. We used double-barrelled ion-selective microelectrodes to measure potassium and calcium content in the receptor lymph with respect to the hemolymph. The potassium concentration in campaniform sensilla (121±15 mM) is five times larger than that of the wing hemolymph (25±7 mM) and nine times larger than that of the haltere hemolymph (13±3 mM). These differences are statistically significant. The calcium concentration in campaniform sensilla (0.8±0.5 mM) does not differ significantly from that of the hemolymph (1.2±0.7 mM). In spider slit sensilla no significant difference occurs between the potassium concentration of the receptor lymph (9.5 mM±5.5 mM) and that of the hemolymph (8±3 mM). The calcium concentration of the hemolymph (1.6±0.9mM) is 3 times higher than that of the receptor lymph (0.6±0.3 mM). This difference is significant.Abbreviation TEV transepithelial voltage     

Intracellular localization of tyrosine hydroxylase immunoreactivity in the rat adrenal chromaffin and pheochromocytoma cells

The localization of tyrosine hydroxylase (TH) immunoreactivity in rat adrenal chromaffin and pheochromocytoma (PC12) cells was investigated by immunoelectron microscopy using monoclonal and polyclonal antisera against TH purified from rat adrenal medulla. Strong TH immunoreactivity was found uniformly in the granules of the adrenaline cells; the immunoreactivity was visible mainly within the periphery, but not in the clear space of the granules of the noradrenaline cells. In the PC12 cells, strong TH immunoreactivity was also observed uniformly in the granules. In addition, TH immunoreactivity was seen in the cytoplasm, the ribosomes attached to the endoplasmic reticulum and the free ribosomes of both the rat adrenal chromaffin and PC12 cells. These results suggest that TH may be localized in the granules, cytoplasm and ribosomes of rat adrenal chromaffin and PC12 cells.     

Localization of enkephalin- and neurotensin-like immunoreactivities in cat adrenal medulla

Enkephalin (ENK)- and neurotensin (NT)-immunoreactivities (IR) were localized in cat adrenal medulla using immunocytochemistry. ENK was localized mainly in adrenaline cells, 70%-80% of which were heavily labelled. About 5%-10% of the noradrenaline cells were ENK-immunoreactive (IR). A dense network of ENK-IR nerves was localized among adrenaline cells. NT was localized only in the noradrenaline cells, 60%-70% of which were immunoreactive. NT- and ENK-IR were localized in separate noradrenaline cells. A dense network of NT-IR nerves was restricted among noradrenaline cells. The present findings confirm that ENK- and NT-like peptides are localized in separate adrenal medullary cells and demonstrate that also the preganglionic nerves are divided in subpopulations according to their neuropeptide content. These nerves have a selective localization among adrenaline and noradrenaline cells and may have physiological significance in the control of secretion of catecholamines and neuropeptides from adrenal medulla.     

On the chromaffin cells in dog adrenal medulla; with special reference to the small granule chromaffin cells (SGC cells)

Small granule chromaffin cells (SGC cells) were identified in the adrenal medulla of adult dogs. They were small in size and usually showed a high nucleo-cytoplasmic ratio. Cytoplasmic projections were occasionally observed in some of these cells. They contained a variable number of small secretory granules with diameters ranging from 70 to 300 nm, but mostly from 100 to 200 nm. The densities of the secretory granules were variable, ranging from highly dense to less dense. These adrenal SGC cells were rich in free ribosomes and polysomes, but were relatively poor in other cell organelles. Chromaffin cells which were intermediate in their characteristics (IM cells) between the SGC cells and the typical A and N cells were also identified. These IM cells contained both highly electron dense and less dense granules in various proportions. The IM cells were classified into two subgroups, according to the proportions of adrenaline type granules and noradrenaline type granules. One group resembled A cells (IM-A cells) and the other resembled N cells (IM-N cells). Light microscopic histochemical studies of A cells stained with the ammoniacal silver solution demonstrated that they contained a small number of darkly stained granules. Electron microscopic cytochemistry revealed that the electron dense granuls in the SGC cells, IM cells and A cells reacted positively with both the potassium dichromate solution at pH 4.1 and the ammoniacal silver solution.     

Fluorescence properties of catecholamines in isolated storage organelles of adrenal medulla

THe quantum yield, the life time and the degree of polarization of the fluorescence of intact chromaffin granules isolated from bovine adrenal medulla were compared to those of catecholamines solutions and catecholamine/ATP mixtures. Rising concentrations of catecholamines in aqueous solutions exhibited increasing quenching and decreasing life times indicating that the quenching was collision induced. Similar effects occurred in mixtures of catecholamines with ATP and Ca²⁺ showing that the nucleotide did not remarkedly hinder the mobility of the catechol group. In suspensions of whole granules stron quenching and shortening of life time was observed compared with solutions of disrupted granules. Fluorescence yield and life time were decreased by about the same factor suggesting that storage of the amines was not correlated with a major immobilization of the catechol group. The degree of polarization of intact granules was higher than that of solutions of catecholamines alone, but similar to catecholamine/ATP mixtures with concentrations corresponding to those found in the granules. This indicates an interaction of catecholamines with ATP in the granules. The results are in agreement with a storage model for catecholamines in the chromaffin granules of adrenal medulla in which catecholamines are bound to ATP, but in a non-rigid way.