Zinc-iodide-osmium procedures as markers of subcellular structures. I. Standardization of staining of transmitter containing vesicles

In the present investigation certain stain properties of the zinc iodide-osmium tetroxide mixture were investigated. It was observed that the type of reaction of certain cell structures with a ZIO mixture largely depended on several factors, namely, the pH of the mixture, aldehyde prefixation and type (s) of buffer (s) used. The standardization of these parameters led to the development of four procedures, each one of them with distinct stain properties. A nomenclature to designate these methods is proposed. The following procedures were applied to material processed for electron microscopy: 1. C.4.4-ZIO-4 degree -18 h: the ZIO mixture was prepared in citric acid-disodium phosphate buffer pH 4.4 and the tissue was incubated at 4 degree C during 18 H; 2. K-P.7.4-C.4.4-ZIO-4 degree -18 h: the tissue was prefixed in Karnovsky fixative prepared in phosphate buffer pH 7.4 and then incubated in C.4.4-ZIO at 4 degree C during 18 h; 3. V.7.4-ZIO-4 degree -18 H: the ZIO was prepared in veronal buffer pH 7.4 and incubation of the tissue was at 4 degree during 18 H; 4.K-P.7.4-V.7.4-ZIO-4 degree -18 h: the tissue was prefixed in Karnovsky fixative prepared in phosphate buffer pH 7.4 and then incubated in V.7.4-ZIO at 4 degree C during 18 h. The chromaffin cells and the cholinergic endings of the rat adrenal medulla and the vas deferens nerves were studied. C.4.4-ZIO-4 degree -18 h: This procedure stained adrenaline and noradrenaline storing granules. Synaptic vesicles at cholinergic endings were not stained. K-P.7.4.4-ZIO-4 degree -18 h: One type of chromaffin granule (probably storing noradrenaline) and both, the small and the granulated synaptic vesicles of cholinergic endings were deeply stained with this method. The aminergic fibres of the vas deferens reacted synaptic vesicles at cholinergic endings were not stained. K-P.7.4.4-ZIO-4 degree -18 h: One type of chromaffin granule (probably storing noradrenaline) and both, the small and the granulated synaptic vesicles of cholinergic endings were deeply stained with this method. The aminergic fibres of the vas deferens reacted synaptic vesicles at cholinergic endings were not stained. K-P.7.4.4-ZIO-4 degree -18 h: One type of chromaffin granule (probably storing noradrenaline) and both, the small and the granulated synaptic vesicles of cholinergic endings were deeply stained with this method. The aminergic fibres of the vas deferens reacted negatively. V.7.4-ZIO-4 degree -18 H: Both types of chromaffin granules and only the small synaptic vesicles of cholinergic endings were revealed with this procedure. In addition, some compartments of the Golgi complex were also stained. K-P.7.4-V.7.4-ZIO-4 degree -18 h: This method did not stain adrenaline and noradrenaline storing granules. Cholinergic synaptic vesicles appeared stained. However, the most striking stain property of this procedure was the staining of many cell organelles. The probable mechanisms by which different factors affect the ZIO reaction are discussed.     

The cytoarchitecture of the adrenal medulla in the rat.

The disposition of adrenaline and noradrenaline storing cells in the adrenal medulla has been studied in the rat. It has been demonstrated that no morphological or functional reason exists for the follicular designation of clumps of chromaffin cells in the medulla. No significant difference was found between the outer and inner zone as regards the frequency of NA cells by morphometric and statistical methods. The cytoarchitectural differences between adrenaline- and noradrenaline-storing cell arrangement are described. Special features of the interrelation between noradrenaline storing cells, cortical cells and the connective tissue framework are stressed. The light and electron microscopic appearance of two types of cortical cells, assumed to represent different states of functional activity is described.     

Influence of the CNS Environment on Chromaffin Cell Survival and Catecholamine Secretion Patterns

Abstract: Chromaffin cells implanted into the CNS have been used as a potential source of sustained catecholamine delivery, although their survival and continued catecholamine secretion are controversial. In addition, chromaffin cells exhibit a high degree of neurochemical plasticity in response to environmental factors. The present aims were to determine whether the CNS provides a supportive environment for sustained catecholamine production in transplanted chromaffin cells and to assess whether this novel environment alters patterns of catecholamine secretion. Catecholamine release from bovine chromaffin cells implanted into the rat midbrain was determined in brain slices. In addition, alterations in catecholamine secretion patterns, particularly adrenaline/noradrenaline ratios, were compared in vitro versus in transplants. Results indicated that brain slices containing chromaffin cell implants released high basal and nicotine-stimulated levels of adrenaline and noradrenaline. It is surprising that although adrenaline/noradrenaline ratios steadily declined in culture, this did not occur when cells were transplanted to the CNS in the early postharvesting phases. However, if cells were transplanted following longer periods in culture, adrenaline/noradrenaline ratios remained low. Together, these results suggest that the CNS can provide a supportive environment for chromaffin cell survival and that the pattern of catecholamine secretion can be optimized by prior in vitro manipulation.     

Effects of adrenaline administration on the interrenal gland of the newt, Triturus carnifex: evidence of intraadrenal paracrine interactions

The existence of paracrine control of steroidogenic activity by adrenochromaffin cells in Triturus carnifex was investigated by in vivo adrenaline (A) administration. The effects were evaluated by examination of the ultrastructural morphological and morphometrical features of the tissues as well as the serum levels of aldosterone, noradrenaline (NA), and adrenaline. In March and July, adrenaline administration reduced aldosterone release (from 187.23 +/- 2.93 pg/ml to 32.28 +/- 1.85 pg/ml in March; from 314.60 +/- 1.34 pg/ml to 87.51 +/- 2.57 pg/ml in July) from steroidogenic cells. The cells showed clear signs of lowered activity: they appeared full of lipid, forming large droplets. Moreover, adrenaline administration decreased the mean total number of secretory granules in the chromaffin cells in July (from 7.74 +/- 0.74 granules/microm(2) to 5.14 +/- 1.55 granules/microm(2)). In this period T. carnifex chromaffin cells contain almost exclusively NA granules (NA: 7.42 +/- 0.86 granules/microm(2); A: 0.32 +/- 0.13 granules/microm(2)). Adrenaline administration reduced noradrenaline content (4.36 +/- 1.40 granules/microm(2)) in the chromaffin cells, enhancing noradrenaline secretion (from 640.19 +/- 1.65 pg/ml to 1030.16 +/- 3.03 pg/ml). In March, adrenaline administration did not affect the mean total number of secretory vesicles (from 7.24 +/- 0.18 granules/microm(2) to 7.25 +/- 1.97 granules/microm(2)). In this period the chromaffin cells contain both catecholamines, noradrenaline (3.88 +/- 0.13 granules/microm(2)), and adrenaline (3.36 +/- 0.05 granules/microm(2)), in almost equal quantities; adrenaline administration reduced adrenaline content (1.74 +/- 0.84 granules/microm(2)), increasing adrenaline release (from 681.27 +/- 1.83 pg/ml to 951.77 +/- 4.11 pg/ml). The results of this study indicate that adrenaline influences the steroidogenic cells, inhibiting aldosterone release. Adrenaline effects on the chromaffin cells (increase of noradrenaline or adrenaline secretion) vary according to the period of chromaffin cell functional cycle. The existence of intraadrenal paracrine interactions in T. carnifex is discussed.     

Morphology and distribution of chromaffin cells in the adrenal gland of cordylidae (Reptilia,Sauria): A comparative study

The distribution of the adrenaline and noradrenaline chromaffin cells in the adrenal glands of 10 members of the family Cordylidae have been examined. In the genus Gerrhosaurus, all the catecholamine cells lie on the surface of the adrenal gland, forming a continuous envelope of one or two layers of cells that mainly contain noradrenaline (NA). In the genus Platysaurus, the chromaffin envelope is intermittent. There are relatively large tracts of interspersed interrenal tissue containing some adrenaline cells (A). Islets of chromaffin cells are scattered between these interrenal tracts. In the genus Pseudocordylus and the genus Cordylus, the superficial chromaffin cells tend to gather into a multilayered dorsal mass, containing mainly NA cells. Inside the interrenal parenchyma, there are always numerous chromaffin islets, containing mainly A cells.     

The determination of the adrenal medullary cell fate during embryogenesis

One subset of neural crest cells, the sympathoadrenal precursors, undergoes a switch in phenotype expression, when they invade the adrenal anlagen and become associated with adrenocortical cells. To investigate the mechanisms responsible for the conversion of noradrenaline synthesizing precursors to adrenaline producing endocrine chromaffin cells we studied the role of glucocorticoids on the initial induction of adrenaline synthesis in embryonic adrenals and cultures of highly purified chromaffin precursor cells. We could show that in vivo differentiation of rat chromaffin precursors commences between 16.3 and 17.3 days of gestation. While adrenaline and the activity of the enzyme phenylethanolamine N-methyltransferase (PNMT), which converts noradrenaline to adrenaline, were present at Embryonic Day 17.3 (E17.3), they were not detectable in E16.3 adrenals. Small amounts of corticosterone were present in E16.3 adrenals and plasma, but in parallel with the initial induction of adrenaline biosynthesis, a sharp rise in organ and plasma glucocorticoid levels occurred until E17.3. Chromaffin precursor cells, isolated at E16.3 and cultured for 4 days, failed to express PNMT activity and adrenaline. However, 0.1 nM dexamethasone was already sufficient for the initial induction of adrenaline and its synthesizing enzyme. Specific glucocorticoid binding of freshly isolated chromaffin (precursor) cells revealed a developmental increase during embryogenesis, yet no glucocorticoid binding sites were detectable in chromaffin precursor cells at E16.3. They appeared at E17.3 in parallel with the initial induction of adrenaline biosynthesis and the enormous rise of adrenal and plasma corticosterone levels. We therefore conclude that glucocorticoids are essential and sufficient to trigger the differentiation of noradrenergic sympathoadrenal precursors to adrenergic chromaffin cells after a functional glucocorticoid receptor system has been established.     

An immunohistochemical study of the adrenal medulla of the ox

Summary The adrenal medulla of ox was studied by an indirect immunofluorescent technique using anti-ox chromaffin granule serum. The serum had a weak cross reaction with ox brain stem and splenic nerve. There was a species cross reaction with sheep, pig and horse. Immunoelectrophoresis showed five components in the serum against ox adrenal lysates. The whole adrenal medulla of ox was found to fluoresce by the immunofluorescent technique but not the cortex. The adrenals of sheep, pig and horse behaved similarly using the anti-ox serum. A serum prepared against ox chromogranin-A, the most abundant soluble protein of the chromaffin granules, was also used for immunofluorescence. Again both the adrenaline and noradrenaline storing cells fluoresced, but not the cortex.     

The periodic acid-schiff reaction in the adrenal medulla

Summary The PAS reaction in the adrenal medulla of rat, rabbit, hamster, ox, pig and sheep was investigated. The medullary cells were positive in cryostat sections and potassium dichromate fixed material but not in formaldehyde fixed paraffin sections. The latter result is due mostly to the extraction of PAS positive lipids and loss of PAS positive proteins. No glycogen was detected in the chromaffin cells histochemically. The catechol amines played no part in the PAS reaction unless the fixative contained dichromate. The connective tissue elements were also PAS positive, and the nerve fibres in ox, sheep and pig. Periodate cannot be used to differentiate between adrenaline and noradrenaline storing cells.     

Histological, histochemical and ultrastructural studies on the interrenal and chromaffin cells of the fathead minnow, Pimephales promelas Rafmesque

Light and electron microscopic examination of fathead minnow head kidneys revealed that the interrenal and chromaffin cells were intermingled and always closely associated with the cardinal veins and their tributaries. Histochemical tests for lipids in the interrenal cells were positive, and two types of chromaffin cells were indicated by chromaffin reactions. Interrenal cells contained abundant smooth endoplasmic reticulum and mitochondria with tubulo-vesicular cristae, characteristic of steroid-producing cells. Only one interrenal cell type was found. Two types of chromaffin cells were present with differences in cytoplasmic density and in types of granules. In light cells, adrenaline granules were most common, and in dark cells noradrenaline granules predominated.     

Combined Stereological and Biochemical Analysis of Storage and Release of Catecholamines in the Adrenal Medulla of the Rat

Adrenal medullae from rats injected with insulin 1 h prior to decapitation were analyzed by stereology and their catecholamine content was determined. In control animals the ratio between adrenaline- and noradrenaline- containing cells was 4.06 whereas the ratio between adrenaline and noradrenaline contents was 4.11. The glands from insulin-treated animals showed a 45% reduction in adrenaline content and a 42% decrease in the volumetric density of the adrenaline-containing granules. However, neither the noradrenaline content nor the volumetric density of noradrenaline-containing granules was modified in glands from insulin-treated animals. From these data, the amount and concentration of adrenaline or noradrenaline in a single granule have been calculated. The results are consistent with the view that chromaffin granules are the source of the released catecholamines. The present paper demonstrates that stereology combined with biochemistry is a useful tool for resolution of problems at the cellular and subcellular levels.     

Comparative data on acetylcholinesterase cytochemistry in various chromaffin cell types of Discoglossus pictus (Amphibia, Anura)

The cytochemical localization of acetylcholinesterase (AChE) activity was studied in the adrenal chromaffin cells of Discoglossus pictus. Reaction end-products were associated with all types of chromaffin cells, i.e. adrenaline (A), noradrenaline (N) and small granule chromaffin (SGC-A, SGC-N) cells, and nervous elements present in the gland. The SGC-A and SGC-N showed the same intensity of AChE reaction in A and N cells, respectively. On the whole, the A and SGC-A cells were more reactive than the N and SGC-N cells. The functional role of the SGC cells is discussed on the basis of the cytochemical results.     

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.     

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     

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.     

Catecholamine biosynthesis in vitro and in vivo in the chromaffin tissue of the Atlantic cod, Gadus morhua

1. The biosynthesis of [3H]catecholamines from [3H]L-tyrosine in the intact chromaffin tissue of cod posterior cardinal veins was studied in vitro and in vivo at 10 degrees C. 2. The tritiated products dopamine, noradrenaline and adrenaline were separated from the [3H]tyrosine by paper chromatography of tissue extracts and the radioactivity of 1 cm strips of the chromatogram was determined by liquid scintillation spectrophotometry. DOPA could never be demonstrated in the tissue extracts from any of the experiments performed. 3. The content of [3H]noradrenaline in pieces of the cardinal veins incubated in vitro was found to increase rapidly. The tissue content of dopamine and adrenaline remained at lower levels which were reached during the first few hours of the incubation. A similar pattern could be demonstrated in the chromaffin tissue in vivo after infusion of [3H]tyrosine, but the total content of the [3H]catecholamines was lower than in the in vitro experiments. 4. The results are consistent with the view that the methylation of noradrenaline is the rate-limiting step in the biosynthesis of adrenaline in cod chromaffin tissue.     

Calcitonin gene-related peptide (CGRP)-like immunoreactivity in scattered chromaffin cells and nerve fibers in the adrenal gland of rats

Summary The present immunohistochemical study reveals that a small number of chromaffin cells in the rat adrenal medulla exhibit CGRP-like immunoreactivity. All CGRP-immunoreactive cells were found to be chromaffin cells without noradrenaline fluorescence; from combined immunohistochemistry and fluorescence histochemistry we suggest that these are adrenaline cells. In addition, all CGRP-immunoreactive cells simultaneously exhibited NPY-like immunoreactivity. CGRP-chromaffin cells were characterized by abundant chromaffin granules with round cores in which the immunoreactive material was densely localized. These findings suggest the co-existence of CGRP, NPY and adrenaline within the chromaffin granules in a substantial number of chromaffin cells.Thicker and thinner nerve bundles, which included CGRP-immunoreactive nerve fibers, with or without varicosities, penetrated the adrenal capsule. Most of them passed through the cortex and entered the medulla directly, whereas others were distributed in subcapsular regions and among the cortical cells of the zona glomerulosa. Here the CGRP-fibers were in close contact with cortical cells. A few of the fibers supplying the cortex extended further into the medulla. The CGRP-immunoreactive fibers in the medulla were traced among and within small clusters of chromaffin cells and around ganglion cells. The CGRP-fibers were directly apposed to both CGRP-positive and negative chromaffin cells, as well as to ganglion cells. Immunoreactive fibers, which could not be found close to blood vessels, were characterized by the presence of numerous small clear vesicles mixed with a few large granular vesicles. The immunoreactive material was localized in the large granular vesicles and also in the axoplasm. Since no ganglion cells with CGRP-like immunoreactivity were found in the adrenal gland, the CGRP-fibers are regarded as extrinsic in origin. In double-immunofluorescence staining for CGRP and SP, all the SP-immunoreactive fibers corresponded to CGRP-immunoreactive ones in the adrenal gland. This suggests that CGRP-positive fibers in the adrenal gland may be derived from the spinal ganglia, as has been demonstrated with regard to the SP-nerve fibers.     

Acetylcholine-induced calcium signalling in adrenaline- and noradrenaline-containing adrenal chromaffin cells

Adrenal chromaffin cells secrete catecholamines in response to cholinergic receptor activation by acetylcholine (ACh). Characteristics of Ca(2+) transients induced by activation of nicotinic (nAChRs) and muscarinic (mAChRs) receptors were analyzed using Fura-2 fluorescent measurements on rat chromaffin cells. We first found two populations of chromaffin cells, which differently responded on AChR stimulation. In the first group (n-cells), consecutive ACh applications evoked persistent Ca(2+) transients, whereas desensitizing transients were observed in the other group (m-cells). The AChR agonists and antagonists precisely imitated or abolished the ACh action on n- and m-type cells, respectively. Cytochemical staining showed that n-cells contained adrenaline, whereas m-cells-noradrenaline. Thus, for the first time we found that nAChRs and mAChRs are differentially expressed in adrenergic and noradrenergic chromaffin cells, respectively. Our data suppose that chromaffin cells can be differentially regulated by incoming ACh signals and in such way release different substances-adrenaline and noradrenaline.     

Differentiation of adreno-chromaffin cells in the newborn rat, as detected by formaldehyde-induced fluorescence, compared with the chromaffin reaction

The newborn of 4 pregnant female rats were collected within 24 h of birth. Twelve neonates were used for the study of chromaffin reaction, by both the direct and the indirect methods. The medullary cells could be demonstrated at this stage; however, the demarcation between noradrenaline and adrenaline cells was not quite sharp. Application of formaldehyde-induced fluorescence to the newborn rat adrenal gland was highly significant. A clear distinction could be demonstrated between noradrenaline and adrenaline cells, the former giving off strong, white-green fluorescence and the latter being weakly green-fluorescent. A third type giving off moderate green fluorescence was interposed between the cells and possibly represented an equivocal cell type at this stage. Sympathetic nerves could be demonstrated in relation to blood vessels and medullary cells.     

Effects of noradrenaline administration on the interrenal gland of the newt, Triturus carnifex: evidence of intra-adrenal paracrine interactions

The existence of paracrine control of steroidogenic activity by adrenochromaffin cells in Triturus carnifex was investigated by in vivo noradrenaline (NA) administration. The effects were evaluated by examination of the ultrastructural morphological and morphometrical features of the tissues as well as the serum levels of aldosterone, NA, and adrenaline (A). In March and July, NA administration increased aldosterone release (from 187.23 +/- 2.93 pg/ml to 878.31 +/- 6.13 pg/ml in March; from 314.60 +/- 1.34 pg/ml to 622.51 +/- 2.65 pg/ml in July) from steroidogenic cells. The cells showed clear signs of stimulation, as evidenced by a strong reduction of lipid content. Moreover, NA administration decreased the mean total number of secretory vesicles in the chromaffin cells in March (from 7.24 +/- 0.18 granules/micro2 to 5.57 +/- 1.88 granules/micro2) and July (from 7.74 +/- 0.74 granules/micro2 to 6.04 +/- 1.13 granules/micro2). In March, however, when T. carnifex chromaffin cells contain both catecholamines, NA (3.88 +/- 0.13 granules/micro2) and A (3.36 +/- 0.05 granules/micro2) in almost equal quantities, NA administration reduced A content (1.29 +/- 1.04 granules/micro2) in the chromaffin cells, enhancing adrenaline secretion (from 681.27 +/- 1.83 pg/ml to 1527.02 +/- 2.11 pg/ml). In July, when the chromaffin cells contain almost exclusively NA granules (NA: 7.42 +/- 0.86 granules/micro2; A: 0.32 +/- 0.13 granules/micro2), NA administration reduced the number of NA granules (5.45 +/- 1.10 granules/micro2), thereby increasing noradrenaline release from the chromaffin cells (from 640.19 +/- 1.65 pg/ml to 1217.0 +/- 1.14 pg/ml). The results of this study indicate that NA influences the steroidogenic cells, eliciting aldosterone release. Noradrenalin effects on the chromaffin cells, increase of NA or A secretion, according to the period of chromaffin cell functional cycle, may be direct and/or mediated through the steroidogenic cells. The existence of intra-adrenal paracrine interactions in T. carnifex is discussed.     

The distribution of cGMP in the adrenal gland in the rat, guinea pig and mouse after stimulation with sodium nitroprusside

Nitric oxide (NO) acts as an intercellular messenger molecule in the nervous system. In the adrenal gland sympathetic preganglionic fibers innervating the medulla, as well as intrinsic neural ganglion cells, contain nitric oxide synthase (NOS). Nitric oxide stimulates the soluble enzyme guanylate cyclase forming cyclic GMP (cGMP). Using sodium nitroprusside (SNP) as nitric oxide donor we have studied the putative target cells for nitric oxide in the rat adrenal gland, both in vivo and in vitro. The guinea pig and a few mouse adrenal glands were studied after SNP perfusion for comparison. Our results show that after vascular perfusion with a high concentration (3 mM) of SNP both noradrenaline and adrenaline chromaffin cells express cGMP-like immunoreactivity in all three species. After incubation of rat adrenal slices with SNP primarily the noradrenaline chromaffin cells are cGMP-positive. In contrast, detectable levels of cGMP-like immunoreactivity were not found in neuronal ganglion cells. In the adrenal cortex cGMP-like immunoreactivity was seen in blood vessel walls, in small cells with processes forming a reticular network, at least partly presumably representing endothelial cells, as well as in some presumable nerve terminals. These findings support the view that chromaffin cells, especially the noradrenergic ones and blood vessels, are targets for nitric oxide in the adrenal gland.