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.     

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.     

Immunocytochemical mapping of basic fibroblast growth factor in the developing and adult rat adrenal gland

We studied the spatial and temporal pattern of basic fibroblast growth factor (bFGF) immunoreactivity in the rat adrenal gland during postnatal development. In the cortex the glomerulosa zone reveals a strong anti-bFGF immunoreactivity at all developmental ages studied. In the fasciculata zone the high number of anti-bFGF immunoreactive cells in the first week decreases during the second and third week. The late developing reticularis zone shows only few anti-bFGF labeled cells at all postnatal ages. This distributional pattern of bFGF immunoreactivity matches that of mitotic activity in the rat adrenal cortex strengthening the role of bFGF as an autocrine growth factor for adrenocortical cells. In the medulla anti-bFGF positive chromaffin cells become detectable at postnatal day (P) 8 and increase in number during the second and third week. In the adult rat the staining intensity of the chromaffin cells was higher than at P18. In the adult medulla bFGF colocalizes with noradrenaline suggesting its presence in a chromaffin cell subpopulation. In accordance with previous results the role of the chromaffin cell bFGF as a neurotrophic factor for preganglionic sympathetic neurons is discussed.     

Immunocytochemical mapping of basic fibroblast growth factor in the developing and adult rat adrenal gland

Summary We studied the spatial and temporal pattern of basic fibroblast growth factor (bFGF) immunoreactivity in the rat adrenal gland during postnatal development. In the cortex the glomerulosa zone reveals a strong anti-bFGF immunoreactivity at all developmental ages studied. In the fasciculata zone the high number of anti-bFGF immunoreactive cells in the first week decreases during the second and third week. The late developing reticularis zone shows only few anti-bFGF labeled cells at all postnatal ages. This distributional pattern of bFGF immunoreactivity matches that of mitotic activity in the rat adrenal cortex strengthening the role of bFGF as an autocrine growth factor for adrenocortical cells. In the medulla anti-bFGF positive chromaffin cells become detectable at postnatal day (P) 8 and increase in number during the second and third week. In the adult rat the staining intensity of the chromaffin cells was higher than at P18. In the adult medulla bFGF colocalizes with noradrenaline suggesting its presence in a chromaffin cell subpopulation. In accordance with previous results the role of the chromaffin cell bFGF as a neurotrophic factor for preganglionic sympathetic neurons is discussed.     

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.     

Morphological evidence for a close interaction of chromaffin cells with cortical cells within the adrenal gland

Summary The adrenal medulla appears to exert a regulatory influence on adrenocortical steroidogenesis. We have therefore studied the morphology of rat, porcine and bovine adrenals in order to characterize the contact zones of adrenomedullary and adrenocortical tissues. The distribution of chromaffin cells located within the adrenal cortex and of cortical cells located within the adrenal medulla was investigated. Chromaffin cells were characterized by immunostaining for synaptophysin and chromogranin A, both being considered specific for neuroendocrine cells. Cortical cells were characterized by immunostaining for 17-hydroxylase, an enzyme of the steroid pathway. Cellular contacts of chromaffin cells and cortical cells were examined at the electron microscopical level. In rat and porcine adrenals, rays of chromaffin cells, small cell clusters and single chromaffin cells or small invaginations from the medulla could be detected in all three zones of the cortex. Chromaffin cells often spread in the subcapsular space of the zona glomerulosa. In porcine and bovine adrenals, 17-hydroxylase immunoreactive cells were localized within the medulla. Single cortical cells and small accumulations of cells were spread throughout this region. At the ultrastructural level, the chromaffin cells located within the cortex in pig and rat adrenals formed close cellular contacts with cortical cells in all three zones. Our morphological data provide evidence for a possible paracrine role of chromaffin cells; this may be important for the neuroregulation of the adrenal cortex.     

Stimulatory Effect of Ascorbic Acid on Norepinephrine Biosynthesis in Digitonin-Permeabilized Adrenal Medullary Chromaffin Cells

The regulatory role of ascorbic acid in norepinephrine biosynthesis was studied using digitonin-permeabilized chromaffin cells. When permeabilized chromaffin cells were incubated with [3H]3,4-dihydroxyphenylethylamine ([3H]dopamine) in calcium-free medium, the amounts of radioactive dopamine and norepinephrine measured in the cell fraction were increased as a function of incubation time and dopamine concentration. Both the accumulation of dopamine and the formation of norepinephrine were shown to require the presence of Mg-ATP in the medium. These results indicate that the permeabilization of chromaffin cells by digitonin treatment does not disrupt the functions of chromaffin granules, including dopamine uptake, norepinephrine formation, and storage of these amines. Using this permeabilized cell system, the effect of ascorbic acid on the rates of dopamine uptake and hydroxylation was investigated. The formation of norepinephrine was stimulated by ascorbic acid at concentrations of 0.5-2 mM in the presence of Mg-ATP. By contrast, dopamine uptake was not affected by the presence or absence of ascorbic acid in the medium. These findings provide evidence that ascorbic acid may stimulate the conversion of dopamine to norepinephrine by increasing dopamine beta monooxygenase activity rather than by increasing the substrate supply of dopamine. These observations also suggest that the rate of norepinephrine biosynthesis in adrenal medullary cells may be regulated by the concentration of ascorbic acid within the cell cytoplasm.     

Neurohypophysial-adrenal gland responses to water-deprivation in the rose-ringed parakeet.

The aim of the present investigation is to study the relative influence of neuohypophysis, adrenal cortex and adrenal medulla under dehydration stress in the parakeet. Birds subjected to dehydration for 7 days lost body weight. Neurosecretory material (NSM) was partially depleted from the neurohypophysis. Adrenal gland weight was increased followed by a hypertrophy of the cortical tissue. A fall in adrenal cholesterol and ascorbic acid level was marked. Adrenaline and noradrenaline contents of the adrenal medulla were suppressed as was evident from cytochemical and biochemical findings. It is suggested that neurohypophysis, adrenal cortex and adrenal medulla are involved in maintaining water homeostasis in this avian species.     

Embryologic development of rat adrenal medulla in transplants to the anterior chamber of the eye

The morphological development and plasticity of embryonic and postnatal rat adrenal medullary cells were studied in homologous adrenal grafts to the anterior chamber of the eye. The eyes of recipient rats were adrenergically denervated 10 days prior to grafting by extirpation of the superior cervical ganglion in order to increase levels of NGF and NGF-like activities in the iris. Grafts taken at the 15th day of embryonic development (E15), i.e., at the beginning of immigration of medullary progenitor cells into the adrenal cortical anlagen, contained no cortical or mature medullary cells after 2 weeks in oculo. Numerous sympathoblastic cells, however, were located at the anterior surface of the iris. E 16 and E 17 transplants showed abundant mature cortical tissue after 2 weeks. Small groups of medullary cells with the ultrastructural characteristics of mature pheochromoblasts or young chromaffin cells were interspersed among cortical cells without forming a discrete medulla. Neuronal cells were exclusively found outside the cortical cell mass. Sympathoblasts grew at the surface of the iris, while young sympathetic nerve cells, which were invested by Schwann cells and received synaptic axon terminals, were embedded into the stroma of the iris. Grafting of E 21 adrenals yielded very similar results except that, in a few instances, young chromaffin cells were located outside the cortex and sympathetic nerve cells were seen to be in close contact with cortical cells. In transplants of adult medullary cells typical mature adrenaline and noradrenaline cells were clearly distinguishable after 8 weeks even in the absence of cortical cells. The only indication of phenotypical changes in these cells was the formation by some of them, of neuritic processes which could be visualized in glyoxylic acid-treated whole mounts of irises. These results are compatible with the idea that embryonic adrenal medullary cells have the environmentally controlled potential to develop along the neuronal or endocrine line, but could also be interpreted in terms of a selection of a specific subpopulation with predetermined potentialities by a specific microenvironment. Moreover, these results suggest that increasing differentiation of medullary cells is accompanied by progressive restrictions in their genetic program, which eventually prevent full transdifferentiation of mature chromaffin into neuronal cells.     

Autoradiographic localization of strychnine-sensitive glycine receptor in bovine adrenal medulla

The presence of an uptake system and a functional glycine receptor in adrenal medulla chromaffin cells was investigated using an autoradiographic technique in adrenal gland slices. Specific³[H]-glycine binding was observed in both adrenal cortex and medulla slices, while only specific binding of [³H]strychnine was seen only in chromaffin cells and was not associated with cortical cells. [³H]Glycine binding sites in the cortex are apparently different from those of [³H]strychnine binding sites in the medulla since excess strychnine does not displace [³H]glycine from adrenal cortex but does so from medulla. This difference supports biochemical evidence for glycine transport into medulla cells and glycine receptor sites on the chromaffin cell membrane.     

Ascorbic acid regulation of norepinephrine biosynthesis in isolated chromaffin granules from bovine adrenal medulla

The effect of ascorbic acid on the conversion of dopamine to norepinephrine was investigated in isolated chromaffin granules from bovine adrenal medulla. Ascorbic acid was shown to double the rate of [3H]norepinephrine formation from [3H]dopamine, despite no demonstrable accumulation of ascorbic acid into chromaffin granules. The enhancement of norepinephrine biosynthesis by ascorbic acid was dependent on the external concentrations of dopamine and ascorbate. The apparent Km of the dopamine beta-hydroxylation system for external dopamine was approximately 20 microM in the presence or absence of ascorbic acid. However, the apparent maximum velocity of norepinephrine formation was nearly doubled in the presence of ascorbic acid. By contrast, the apparent Km and Vmax of dopamine uptake into chromaffin granules were not affected by ascorbic acid. Norepinephrine formation was increased by ascorbic acid when the concentration of ascorbate was 200 microM or higher; a concentration of 2 mM appeared to induce the maximal effect under the experimental conditions used here. The effect of ascorbic acid on conversion of dopamine to norepinephrine required Mg-ATP-dependent dopamine uptake into chromaffin granules. In contrast to ascorbic acid, other reducing agents such as NADH, glutathione, and homocysteine were unable to enhance norepinephrine biosynthesis. These data suggest that ascorbic acid provides reducing equivalents for hydroxylation of dopamine despite the lack of ascorbate accumulation into chromaffin granules. These findings imply the functional existence of an electron carrier system in the chromaffin granule which transfers electrons from external ascorbic acid for subsequent intragranular norepinephrine biosynthesis.     

Ascorbic acid and catecholamine release from digitonin-treated chromaffin cells

The subcellular localization of catecholamines and ascorbic acid in cultured bovine adrenal chromaffin cells was studied by permeabilizing the cells with digitonin, a steroid glycoside. Catecholamine release from permeabilized chromaffin cells was dependent on the free calcium concentration and the temperature of the incubation mixture. By contrast, [14C]ascorbic acid, preloaded into the cells, was released by digitonin treatment in a manner independent of the concentration of free calcium and with only moderate regard to the incubation temperature. The sensitivity of ascorbic acid release to digitonin treatment was identical to that of calcium-dependent catecholamine release. These results thus suggest that ascorbic acid preloaded into the cells may directly efflux from the cell cytoplasm as a result of the permeabilization of the plasma membrane. Dimethylepinephrine, a permanently positively charged catecholamine analog which is known to be excluded from vesicular fractions, was also released by digitonin treatment in a manner independent of calcium. The time course of dimethylepinephrine release was very similar to that of ascorbic acid release. Thus, newly accumulated ascorbic acid in chromaffin cells may be localized to a free pool in the cell cytoplasm rather than in a vesicular compartment.     

Heterogeneous distribution of neurocalcin-immunoreactive nerve terminals in the mouse adrenal medulla

Neurocalcin is a novel calcium-binding protein found in bovine brain tissue. We investigated immunoreactivity for neurocalcin in the mouse adrenal medulla using light and electron microscopy. The immunoreactivity was present in nerve fibers, nerve terminals, and ganglion cells in the adrenal medulla, but chromaffin cells, sustentacular cells, and Schwann cells were negative in reaction. Nerve bundles containing neurocalcin-immunoreactive fibers passed through the adrenal cortex and extended into the medulla. Immunopositive nerve fibers branched off and projected varicose terminals around the chromaffin cells. These varicose terminals contained small and large-cored vesicles and made synapses with the chromaffin cells. We performed paraformaldehyde-induced fluorescence-histochemical studies for catecholamine combined with immunohistochemical studies for neurocalcin. Neurocalcin-immunoreactive nerve terminals were more abundant at noradrenaline (fluorescent) cell-rich regions than at adrenaline (non-fluorescent) cell-rich regions. These results show that neurocalcin-immunoreactive nerves mainly innervate noradrenaline-containing chromaffin cells in the mouse adrenal medulla and that neurocalcin may regulate synaptic function in the nerve terminals. Received: 21 October 1996 / Accepted: 12 February 1997     

Characterization of Two Chromaffin Cell Populations Isolated from Bovine Adrenal Medulla

Cultures of chromaffin cells isolated from the bovine adrenal medulla have been extremely useful for investigating secretory mechanisms, but such cultures used up to the present time represent mixed populations of adrenergic and noradrenergic cells. This report describes how, with slight modifications to standard procedures, two separate chromaffin cell populations may be separated from bovine adrenal medullae. These two cell fractions have been characterized by biochemical, immunocytochemical, and morphological techniques as enriched populations of adrenergic or noradrenergic cells, respectively. The adrenergic cell-enriched fraction consists of greater than 90% adrenergic cells, whereas the noradrenergic cell-enriched fraction contains greater than 60% noradrenergic cells. We also demonstrate that these cells may be cultured with their secretory machinery intact: analysis of secreted catecholamines from nicotine- or high K+ concentration-stimulated cells cultured from each fraction confirms that adrenaline is the major catecholamine secreted by one fraction, whereas noradrenaline is mainly secreted by the other.     

An immuno-electron-microscopic study of the localization of VIP-like immunoreactivity in the adrenal gland of the rat

Summary VIP-like immunoreactivity was revealed in a few chromaffin cells, medullary ganglion cells and a plexus of varicose nerve fibers in the superficial cortex and single varicose fibers in the juxtamedullary cortex and the medulla of the rat adrenal gland. VIP-like immunoreactive chromaffin cells were polygonal in shape without any distinct cytoplasmic processes and they appeared solitarily. Their cytoplasm contained abundant granular vesicles having a round core and the immunoreactive material was localized to the granular core. VIP-immunoreactive ganglion cells were multipolar and had large intracytoplasmic vacuoles. The immunoreactive material was localized not only in a few granular vesicles but also diffusely throughout the axoplasm. VIP-immunoreactive varicose nerve fibers in the superficial cortex were characterized by abundant small clear vesicles and some large granular vesicles, while those in the juxtamedullary cortex and medulla and the ganglionic processes were characterized by abundant large clear vesicles, as well as the same vesicular elements as contained in the nerves in the superficial cortex. The immunoreactive material was localized on the granular cores and diffusely in the axoplasm in both nerves. Based on the similarity and difference in the composition of the vesicles contained in individual nerves, it is likely that the VIP-immunoreactive nerve fibers in the medulla and the juxtamedullary cortex are derived from the medullary VIP-ganglion cells, while those in the superficial cortex are of extrinsic origin. The immunoreactive nerve fibers in both the cortex and the medulla were often in direct contact with cortical cells and chromaffin cells, where no membrane specializations were formed. The immunoreactive nerve fibers were sometimes associated with the smooth muscle cells and pericytes of small blood vessels in the superficial cortex. In addition they were often seen in close apposition to the fenestrated endothelial cells in the cortex and the medulla, only a common basal lamina intervening. Several possible mechanisms by which VIP may exert its effect in the adrenal gland are discussed.     

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.     

Cholinergic stimulation of chromaffin cells induces rapid coating of the plasma membrane

Stimulation of primary bovine adrenal chromaffin cells by carbachol produced a 6-fold increase in cell surface coated pits within 30 s. This coat appeared not to be recruited from a preformed pool at the plasma membrane, but from some pool transparent to electron microscopy. The number of coated pits appeared to decrease rapidly after 1 to 2 min stimulation, but processing for electron microscopy using tannic acid to enhance contrast indicated that both coated pits and closed coated vesicles were increased relative to unstimulated cells for up to 30 min. Analyses of purified adrenal medulla coated vesicles showed a lipid composition close to that expected for cell surface membrane, but there were only trace levels of plasma membrane marker enzymes. Coated vesicles contained significant amounts of both membrane and content proteins characteristic of the chromaffin granule, suggesting that medulla coated vesicles preferentially carry secretion granule proteins. The kinetics of stimulus-dependent formation of coated membrane in the cortical zone of chromaffin cells is closely similar to that observed for secretion granule membrane retrieval.     

An enzymecytochemical study on the adrenal of the freshwater teleost, Clarias batrachus (L.).

The adrenal homologue of C. batrachus is distributed around the postcardinal vein in the pronephric head kidney. The cortical cells are round or oval in shape. They showed positive reaction for total lipid, glycogen and ascorbic acid. Their intense delta5-3beta HSDH activity indicates their capacity for steroid biosynthesis. In addition, the cortical cells of C. batrachus exhibited strong G-6-PD, NADPH diaphorase, NADH diaphorase, MAO and weak SDH and LDH activity. The presence of MAO suggests the aminergic control of the adrenal in this species and the silver positive fibres seen the cortical cells were hypertrophied, degranulated and the lipid content was also decreased. The chromaffin or medullary cells were distributed in groups among the cortical cells. They are largely oval or angular in shape. They react positively to ferric ferricyanide, chromaffin and argentaffin reactions and ascorbic acid test.     

Lack of an adrenal cortex in Sf1 mutant mice is compatible with the generation and differentiation of chromaffin cells

The diversification of neural-crest-derived sympathoadrenal (SA) progenitor cells into sympathetic neurons and neuroendocrine adrenal chromaffin cells was thought to be largely understood. In-vitro studies with isolated SA progenitor cells had suggested that chromaffin cell differentiation depends crucially on glucocorticoids provided by adrenal cortical cells. However, analysis of mice lacking the glucocorticoid receptor gene had revealed that adrenal chromaffin cells develop mostly normally in these mice. Alternative cues from the adrenal cortex that may promote chromaffin cell determination and differentiation have not been identified. We therefore investigated whether the chromaffin cell phenotype can develop in the absence of an adrenal cortex, using mice deficient for the nuclear orphan receptor steroidogenic factor-1 (SF1), which lack adrenal cortical cells and gonads. We show that in Sf1-/- mice typical chromaffin cells assemble correctly in the suprarenal region adjacent to the suprarenal sympathetic ganglion. The cells display most features of chromaffin cells, including the typical large chromaffin granules. Sf1-/- chromaffin cells are numerically reduced by about 50% compared with the wild type at embryonic day (E) 13.5 and E17.5. This phenotype is not accounted for by reduced survival or cell proliferation beyond E12.5. However, already at E12.5 the 'adrenal' region in Sf1-/- mice is occupied by fewer PHOX2B+ and TH+ SA cells as well as SOX10+ neural crest cells. Our results suggest that cortical cues are not essential for determining chromaffin cell fate, but may be required for proper migration of SA progenitors to and/or colonization of the adrenal anlage.     

Expression of neurotrophin receptors trkB and trkC and their ligands in rat adrenal gland and the intermediolateral column of the spinal cord

Neurotrophins and their trk receptors constitute major classes of signaling molecules with important actions in the developing and adult nervous system. With regard to the sympathoadrenal cell lineage, which gives rise to sympathetic neurons and chromaffin cells, neurotrophin-3 (NT-3) and nerve growth factor (NGF) are thought to influence developing sympathetic neurons. Neurotrophin requirements of chromaffin cells of the adrenal medulla are less well understood than those for NGF. In order to provide the bases for understanding of putative functions of neurotrophins for the development and maintenance of chromaffin cells and their preganglionic innervation, in situ hybridization has been used to study the expression of brain-derived neurotrophic factor (BDNF) and NT-3, together with their cognate receptors trkB and trkC, in the adrenal gland and in the intermediolateral column (IML) of the spinal cord. BDNF is highly expressed in the embryonic adrenal cortex and later in cells of the cortical reticularis zone. Adrenal medullary chromaffin cells fail to express detectable levels of mRNAs for BDNF, NT-3, and their cognate receptors trkB and trkC. Neurons in the IML express BDNF and trkB, and low levels of NT-3 and trkC. Our data make it unlikely that BDNF and NT-3 serve as retrograde trophic factors for IML neurons but suggest roles of BDNF and NT-3 locally within the spinal cord and possibly for sensory nerves of the adrenal cortex.