Ontogeny of the expression of some catecholamine synthesising enzymes in the female porcine preoptic area

Ontogeny of the catecholaminergic system of the preoptic area (PA) was studied in various animal species including mice, rats, cats and lower vertebrates. Until now, there has been no data about development of catecholaminergic structures in the porcine PA. To study this problem, hypothalami from six groups of animals were collected. Three groups of foetuses (70, 84 and 112 days old) and three groups of female pigs (1 day, 10 weeks and 7-8 months old) were used. Nerve structures immunoreactive for the studied substances: tyrosine hydroxylase (TH), dopamine beta-hydroxylase (DbetaH) and phenylethanoloamine-N-metylthransferase (PNMT) were observed in different periods. In PA, TH-IR (immunoreactive) structures appeared before 70th day of foetal life, DbetaH-IR between 70th and 84th day of foetal live and PNMT-IR only in 10-week old and adult animals. In the PA of 70-day old foetuses, single smooth and varicose nerve fibres immunoreactive only to TH were found. In PA of 84-day old foetuses, additionally, single nerve cell bodies immunoreactive to TH were shown and some of them also contained immunoreactivity to DbetaH. In PA of 1-day old piglets, moderate numbers of nerve fibres immunoreactive to TH and only single TH/DbetaH-IR nerve terminals were observed. TH-IR nerve cell bodies were also moderate in number and many of them contained simultaneously immunoreactivity to DbetaH. In PA of 10-week old pigs, a moderate number of immunopositive nerve fibres was observed. They contained mainly TH, but part of them stained also for TH/DbetaH. Only very few nerve fibres containing exclusively DbetaH were found. These nerve terminals were observed in a close vicinity of blood vessels. In PA, moderate numbers of TH-IR nerve cell bodies were found, some of them contained also immunoreactivity to DH but never to PNMT. Perikarya containing PNMT were TH-negative. In the PA of sexually mature sows, additional, single, large nerve cell bodies (about 35 microm in a diameter) containing TH only were found. In many cases, TH- and DbetaH-IR "basket-like" structures surrounding nerve cell bodies were seen, suggesting an influence of those fibres on the neuronal activity.     

Catecholamines are present in larval Xenopus laevis: a potential source for cardiac control

Changes in noradrenaline (NA), adrenaline (A), and dopamine (DA) levels in the heart, kidneys, and whole body (without heart and kidneys) during embryonic development were investigated in the frog, Xenopus laevis using high-performance liquid chromatography (HPLC). In addition, the presence of cells immunoreactive to tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH) and/or phenylethanolamine-N-methyltransferase (PNMT) in the heart of Xenopus larvae was investigated using immunohistochemical techniques. The presence of nerve fibers was visualized using antibodies against acetylated tubulin (AcT). NA and DA concentrations in the heart were low and steady in NF 40-56, showed an increased value at NF 57, and decreased again in froglets. A trend toward higher concentrations of A was observed at NF 43-49 and NF 57. Cells immunoreactive to TH, DBH, and PNMT were found in the heart from NF 40, and the TH immunoreactive cells became more abundant in the whole heart at later stages. The presence of catecholamines in the non-innervated larval heart together with the finding of TH/DBH/PNMT immunoreactive cells suggests that catecholamines are synthesized and stored in the heart and could therefore have a paracrine role in cardiac control in Xenopus larvae. Detectable concentrations of catecholamines were also found in kidneys and whole bodies (except heart and kidneys). Therefore, catecholamine-producing cells outside the heart can be an important source of circulating catecholamines involved in adrenergic cardiac control in Xenopus larvae.     

大鼠第三脑室及中脑水管多巴胺能触液神经元的分布

目的观察大鼠第三脑室、中脑水管及中缝背核内多巴胺能触液神经元的分布情况.方法应用CB逆行追踪、TH免疫组织化学和CB/TH免疫荧光双重标记技术,观察多巴胺能触液神经元在间脑及中脑内的分布情况.结果 TH免疫阳性触液神经元分布在第三脑室尾侧部和中脑水管全程的腹侧室管膜上及室管膜内,其胞体呈倒置梨形、圆形或椭圆形、多角形和梭形;在中缝背核内可见少量CB/TH免疫荧光双重标记的远位触液神经元;另在正中隆起部位TH免疫阳性神经末梢含量丰富.结论大鼠第三脑室、中脑水管及中缝背核内存在多巴胺能触液神经元,其在脑-脑脊液之间的信息传递中有着重要的作用.     

Innervation of somatostatin synthesizing neurons by adrenergic, phenylethanolamine-N-methyltransferase (PNMT)-immunoreactive axons in the anterior periventricular nucleus of the rat hypothalamus

The adrenergic innervation of somatostatin synthesizing neurons located in the anterior region of the rat hypothalamic periventricular nucleus was studied by means of a light and electron microscopic immunocytochemical double labelling technique. This region which is the source of hypophysiotrophic somatostatin immunoreactive (IR) neurons also receives a dense plexus of adrenergic axons as determined by immunocytochemistry of phenylethanolamine-N-methyltransferase (PNMT), the marker enzyme for the central adrenergic system. The simultaneous detection of PNMT and somatostatin antigens in hypothalamic sections of colchicine pretreated animals revealed a congruency in the distribution of the labelled elements and also close juxtaposition of PNMT-IR axons to somatostatin producing neurons. At the ultrastructural level, axo-somatic and axo-dendritic synaptic connections were found between PNMT-containing axons and somatostatin expressing neurons. These morphological findings support the view that the central adrenergic system might influence the production and secretion of growth hormone in the pituitary gland by a direct monosynaptic interaction with somatostatin synthesizing neurons.     

Development of adrenal chromaffin cells is largely normal in mice lacking the receptor tyrosine kinase c-Ret

c-Ret encodes a receptor tyrosine kinase that is essential for normal development of the kidney as well as enteric and sympathetic neurons. Since sympathetic neurons and neuroendocrine chromaffin cells originate from a common progenitor cell, we have examined the relevance of c-Ret for the development of adrenal chromaffin cells by analyzing mouse mutants lacking c-Ret. Adrenal chromaffin cells express c-Ret mRNA at embryonic day (E) 12.5 and 13.5, yet levels of expression decline at later embryonic and postnatal ages. Adrenal medullae of c-Ret deficient mice show normal numbers of tyrosine hydroxylase (TH)-immunoreactive cells at E13.5 and at birth. Ultrastructurally, adrenal chromaffin cells of c-Ret(-/-) mice appear unaltered: chromaffin cells develop typical secretory chromaffin granules, the morphological hallmark of chromaffin cells, and synaptic terminals appear normal. However, adrenaline levels and numbers of chromaffin cells immunoreactive for the adrenaline synthesizing enzyme phenylethanolamine-N-methyltransferase (PNMT) are reduced by about 30% in c-Ret-deficient mice arguing for a direct or indirect role of c-Ret in the regulation of PNMT. Thus, despite expression of c-Ret, adrenal chromaffin cells develop largely normal in mice lacking c-Ret. We therefore conclude that sympathetic neurons and neuroendocrine chromaffin cells profoundly differ in their requirement for c-Ret signaling during development.     

Ganglion cells immunoreactive for catecholamine-synthesizing enzymes,neuropeptide Y and vasoactive intestinal polypeptide in the rat adrenal gland

Immunohistochemistry has been used to demonstrate tyrosine hydroxylase (TH), dopamine--hydroxylase (DBH), phenylethanolamine N-methyltransferase (PNMT), neuropeptide Y (NPY) and vasoactive intestinal polypeptide (VIP) immunoreactivities, and acetylcholinesterase (AChE) activity was demonstrated in rat adrenal glands. The TH, DBH, NPY and VIP immunoreactivities and AChE activity were observed in both the large ganglion cells and the small chromaffin cells whereas PNMT immunoreactivity was found only in chromaffin cells, and not in ganglion cells. Most intraadrenal ganglion cells showed NPY immunoreactivity and a few were VIP immunoreactive. Numerous NPY-immunoreactive ganglion cells were also immunoreactive for TH and DBH; these cells were localized as single cells or groups of several cells in the adrenal cortex and medulla. Use of serial sections, or double and triple staining techniques, showed that all TH- and DBH-immunoreactive ganglion cells also showed NPY immunoreactivity, whereas some NPY-immunoreactive ganglion cells were TH and DBH immunonegative. NPY-immunoreactive ganglion cells showed no VIP immunoreactivity. AChE activity was seen in VIP-immunopositive and VIP-immunonegative ganglion cells. These results suggest that ganglion cells containing noradrenaline and NPY, or NPY only, or VIP and acetylcholine occur in the rat adrenal gland; they may project within the adrenal gland or to other target organs. TH, DBH, NPY, and VIP were colocalized in numerous immunoreactive nerve fibres, which were distributed in the superficial adrenal cortex, while TH-, DBH- and NPY-immunoreactive ganglion cells and nerve fibres were different from VIP-immunoreactive ganglion cells and nerve fibres in the medulla. This suggests that the immunoreactive nerve fibres in the superficial cortex may be mainly extrinsic in origin and may be different from those in the medulla.     

Innervation of somatostatin synthesizing neurons by adrenergic,phenylethanolamine-N-methyltransferase (PNMT)-immunoreactive axons in the anterior periventricular nucleus of the rat hypothalamus

Summary The adrenergic innervation of somatostatin synthesizing neurons located in the anterior region of the rat hypothalamic periventricular nucleus was studied by means of a light and electron microscopic immunocytochemical double labelling technique. This region which is the source of hypophysiotrophic somatostatin immunoreactive (IR) neurons also receives a dense plexus of adrenergic axons as determined by immunocytochemistry of phenylethanolamine-N-methyltransferase (PNMT), the marker enzyme for the central adrenergic system. The simultaneous detection of PNMT and somatostatin antigens in hypothalamic sections of colchicine pretreated animals revealed a congruency in the distribution of the labelled elements and also close juxtaposition of PNMT-IR axons to somatostatin producing neurons. At the ultrastructural level, axo-somatic and axo-dendritic synaptic connections were found between PNMT-containing axons and somatostatin expressing neurons. These morphological findings support the view that the central adrenergic system might influence the production and secretion of growth hormone in the pituitary gland by a direct monosynaptic interaction with somatostatin synthesizing neurons.     

Demonstration of a different localization of perikarya immunoreactive to oxytocin and vasopressin in the cat hypothalamus

Using immunohistochemical techniques, we demonstrated oxytocin (OT) and vasopressin (AVP) neurons in the cat hypothalamus. The OT immunoreactive neurons were found mainly in the paraventricular nucleus, supraoptic nucleus and dorsal accessory group located lateral to the fornix. In addition to these hypothalamic structures, the AVP immunoreactive neurons were observed in the suprachiasmatic nucleus, ventral accessory group located in the retrochiasmatic area and lateral accessory group, dorsal to the supraoptic nucleus caudally, and ventral to the medial part of the internal capsule rostrally. We further demonstrated a different localization of the OT and AVP immunoreactive neurons in the paraventricular and supraoptic nuclei.     

Distribution and origin of neuropeptide Y-immunoreactive fibers in the penis of the rat

Summary The present study investigated the distribution of neuropeptide Y-immunoreactive fibers to the penis of the rat. In the corpora cavernosa penis, a dense plexus of fibers was asociated with arteries, intrinsic cavernosal muscle, and veins including the deep dorsal vein. In the corpus spongiosum, immunoreactive fibers were present around vascular smooth muscle and at the periphery of the acini of the paraurethral glands. Immunohistochemistry of penile neurons identified by retrograde tracer injection into the penis indicates that about 5% of the penile neurons in the pelvic plexus contained the neuropeptide while larger percentages of penile neurons in the sympathetic chains were immunoreactive for neuropeptide Y. Chemical and surgical sympathectomy greatly reduced the neuropeptide Y- and catecholamine-containing fibers in the erectile tissue but had no clear effect on the neuropeptide Y fibers around the paraurethral glands; a tissue that is not innervated by adrenergic fibers. It is concluded that (1) the widespread distribution of neuropeptide Y indicates that it may function in the control of penile blood flow, (2) with the possible exception of the paraurethral glands, the sympathetic chain is the most likely source of neuropeptide Y fibers in both erectile bodies of the penis, and (3) this peptide may play a role in the secretory functions of the paraurethral glands.     

Short and long term regulation of catecholamine biosynthetic enzymes by angiotensin in cultured adrenal medullary cells. Molecular mechanisms and nature of second messenger systems

The purpose of this study was to examine the effects of angiotensin on the enzyme activities and gene expression of two catecholamine synthesizing enzymes, tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT), in bovine adrenal medullary (AM) cells. Short term (15 min) incubation of cultured AM cells with 2 nM [Sar1]angiotensin II (s1-AII) did not increase basal secretion of catecholamines; however, longer incubations (3, 24, or 72 h) produced 4-10-fold increases. To determine whether angiotensin affects synthesis of catecholamines, the activities of TH and PNMT were examined. Incubation with s1-AII (15-30 min) decreased the Km of TH for its biopterine cofactor [6R)-5,6,7,8-tetrahydro-1-biopterin dihydrochloride (BH4] without affecting the Vmax, suggesting activation of TH. After long term incubation (72 h) the Km value was identical to that of control, while increases in the apparent Vmax were observed. PNMT activity was unaffected during a 30-min treatment with s1-AII; however, 2-fold increases occurred after a 48-72-h incubation. s1-AII (24 h) increased the relative abundance of TH and PNMT mRNAs, suggesting that the long term increase in enzyme activities reflected increased expression of TH and PNMT genes. Maximal increases were observed at 2 nM s1-AII and the changes were antagonized by saralasin. Induction of TH mRNA by s1-AII was additive to the effects of veratridine or forskolin indicating that effects of angiotensin were not due to membrane depolarization or increased cyclic AMP levels. Incubation with Ca2+ ionophore A23187 increased TH and PNMT mRNA levels in AM cells raising the possibility that the increase in cellular [Ca2+] could mediate effects of angiotensin. Angiotensin-induced increases in TH and PNMT mRNA were inhibited by nifedipine indicating involvement of voltage-dependent Ca2+ channels. In addition, the increases in TH, but not PNMT mRNA, were antagonized by dantrolene, which inhibits mobilization of Ca2+ from intracellular stores. Calmodulin involvement was suggested by the inhibition of s1-AII induced changes in mRNA with 1 microM calmidazolium.(ABSTRACT TRUNCATED AT 400 WORDS)     

"Blood-contacting neurons" in the brain of the Japanese eel Anguilla japonica

To discriminate "blood-contacting neurons" within the brain of the eel, Evans blue (EB) was injected intraperitoneally. After five days, six brain areas were externally stained blue with the dye; the saccus dorsalis (SD), the epiphysis (E), the area postrema (AP), the posterior part of the magnocellular preoptic nucleus (PM), the pituitary (Pit), and the saccus vasculosus (SV). Among the EB-positive area, some cells in the PM, the anterior tuberal nucleus (NAT) and the AP were discriminated as the "blood-contacting neurons" histologically, whereas EB-positive neurons were not detected in the SD, the E, the Pit and the SV regions. In the PM, most EB-positive neurons (90 %) were immunoreactive to vasotocin (AVT) antibody, indicating that these neurons are vasotocinergic. The remaining EB-positive neurons (10 %) were not immunoreactive to ANG II and tyrosine hydroxylase (TH) antibodies. Although some neurons in the PM were immunoreactive to ANG II antibody, they were EB-negative. In contrast, almost all EB-positive neurons in the AP showed TH-like immunoreactivity (-lir), indicating that these neurons utilize catecholamine(s) as a neurotransmitter. The EB-positive neurons in the NAT were not immunoreactive to AVT, ANG II and TH antibodies, whereas some neurons without EB-staining showed ANG II-lir. Possible roles of these neurons in regulating drinking behavior in eels are discussed.     

Partial expression of catecholaminergic traits in cholinergic chick ciliary ganglia: Studies in vivo and in vitro

We have previously demonstrated that at embryonic Day (E) 8, some cells of the chick ciliary ganglion (CG) contain the catecholaminergic (CA) enzyme tyrosine hydroxylase (TH), but not phenylethanolamine-N-methyltransferase (PNMT); and that in culture essentially all cells express both enzymes. In the present study, we sought to determine, first, whether the expression of adrenergic traits in the CG in vivo is transient or permanent in the CG. To do so, CGs were removed from E5 to postnatal Day 5, fixed, and processed for the immunocytochemical localization of the CA enzymes: TH, L-amino acid decarboxylase (AADC), and PNMT. At all stages examined, some CG neurons expressed TH immunoreactivity (TH-IR) and all contained AADC-IR. However, none stained with PNMT antibodies, indicating that these cells stably express some, but not all, of the CA enzymes. Second, we examined whether CG neurons in culture expressed other CA markers. CG neurons did not contain detectable levels of TH enzyme activity nor did they transport and store exogenously supplied monoamines. These results indicate that some but not all traits necessary for adrenergic function are present in CG neurons in vitro. Third, we sought to establish whether CA expression in CG neurons is affected by modification in culture conditions. Cultures of CG neurons continued to express TH-IR even when grown in the presence of either 50% HCM or 20 mM KCl for 5 days. Finally, the expression of the cholinergic enzyme, choline acetyltransferase (CAT) was assessed in CG cultures by biochemical assay. CAT activity increased five-fold between 5 and 17 days in vitro, irrespective of the presence of TH-IR in 100% of the CG neurons of sister cultures. These data suggest that at least a subpopulation of CG neurons express both TH and CAT in culture. We conclude that the postmitotic neurons of the CG are able to express some but not all of the traits characteristic of a CA phenotype while maintaining cholinergic expression. These findings suggest that (1) the appearance of the full complement of adrenergic properties is not coordinated and may be regulated by different environmental cues and (2) parasympathetic neurons can express both adrenergic and cholinergic traits simultaneously.     

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.     

Distribution of dopamine immunoreactive systems in brain stem and spinal cord of the chameleon

An immunohistochemical method, using glutaraldehyde fixation and a highly specific monoclonal antibody recently synthetized against dopamine (DA)-glutaraldehyde protein conjugate, permitted direct visualization of DA structures in the brainstem and spinal cord of a reptile (Chameleon). DA-immunoreactive cell bodies occurred in some contiguous areas of the midbrain tegmentum. The first one was located in the ventral tegmental area. Some somata intermingled with the oculomotor nucleus. The second group was the large round or oval DA-Immunostained neurons located in the substantia nigra. More caudally, a third group of round or fusiform DA-cell bodies was seen in an homologous area of so called mammalian A8 and were continuous with the substantia nigra group. In the medulla oblongata, the DA-containing cells were shown in the nucleus of solitary tract and in the dorsal lateral part of the dorsal motor nucleus of the vagus. The density of this DA-Immunoreactive neurons decreased more caudally. At the medullo-spinal level and upper cervical spinal cord, a few labelled cells were distinguished near the central canal. In the spinal cord DA-immunopositive cell bodies were observed in the vicinity of the central canal and formed a continuous column that extended throughout the rostral spinal cord. The apical processes of these neurons seemed to be in contact with the lumen of the central canal. This study constitute the first visualization of the immunoreactive DA-cell bodies at the medullo-spinal level which were already described, as TH immunoreactive in other species of reptiles.     

Immunocytochemical study of catecholaminergic neurons in grafted mesencephalon transplanted into the hypothalamus of the rat

Mesencephalic fragments from 14 day old embryonic rat brain were transplanted into the third ventricle of adult rats neonatally treated with monosodium glutamate. From two to twelve months after grafting, the implanted tissue was still present in the ventricle and contained TH immunoreactive neurons which displayed a normal appearance at ultrastructural level. While endogenous TH containing neurons were still present in dopaminergic regions of the recipient hypothalamus, grafted mesencephalic fragments could survive and develop. They contained TH immunopositive most probably dopaminergic neurons which are able, in some cases, to innervate the host brain. This model should be of interest in the study of neuroendocrine functions of dopaminergic neurons.     

Identification of neuron types in the submucosal ganglia of the mouse ileum

The continuing and even expanding use of genetically modified mice to investigate the normal physiology and development of the enteric nervous system and for the study of pathophysiology in mouse models emphasises the need to identify all the neuron types and their functional roles in mice. An investigation that chemically and morphologically defined all the major neuron types with cell bodies in myenteric ganglia of the mouse small intestine was recently completed. The present study was aimed at the submucosal ganglia, with the purpose of similarly identifying the major neuron types with cell bodies in these ganglia. We found that the submucosal neurons could be divided into three major groups: neurons with vasoactive intestinal peptide (VIP) immunoreactivity (51% of neurons), neurons with choline acetyltransferase (ChAT) immunoreactivity (41% of neurons) and neurons that expressed neither of these markers. Most VIP neurons contained neuropeptide Y (NPY) and about 40% were immunoreactive for tyrosine hydroxylase (TH); 22% of all submucosal neurons were TH/VIP. VIP-immunoreactive nerve terminals in the mucosa were weakly immunoreactive for TH but separate populations of TH- and VIP-immunoreactive axons innervated the arterioles in the submucosa. Of the ChAT neurons, about half were immunoreactive for both somatostatin and calcitonin gene-related peptide (CGRP). Calretinin immunoreactivity occurred in over 90% of neurons, including the VIP neurons. The submucosal ganglia and submucosal arterioles were innervated by sympathetic noradrenergic neurons that were immunoreactive for TH and NPY; no VIP and few calretinin fibres innervated submucosal neurons. We conclude that the submucosal ganglia contain cell bodies of VIP/NPY/TH/calretinin non-cholinergic secretomotor neurons, VIP/NPY/calretinin vasodilator neurons, ChAT/CGRP/somatostatin/calretinin cholinergic secretomotor neurons and small populations of cholinergic and non-cholinergic neurons whose targets have yet to be identified. No evidence for the presence of type-II putative intrinsic primary afferent neurons was found. This work was supported by a grant from the National Health and Medical Research Council of Australia (grant no. 400020) and an Australian Research Council international linkage grant (no. LZ0882269) for collaboration between the Melbourne and Bologna laboratories.     

Effect of vasopressin on the induction of adrenal tyrosine hydroxylase and phenylethanolamine N-methyltransferase

We have assessed the effect of arginine vasopressin (AVP) on adrenal tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT) activities. Both enzymes show marked increases after systemic administration of AVP in the range of 66 and 100 micrograms/day. To determine whether the pituitary gland plays a role in these inductions, the effect of AVP (66 micrograms per day, given divided into 3 doses for 4 days) on the adrenal enzymes was studied in hypophysectomized rats. These animals showed induction of TH but not PNMT. This indicates that a pituitary factor(s) mediates the increase in PNMT caused by AVP. Adrenal TH activity was measured after the injection of AVP (1 or 2 micrograms per rat) into the lateral ventricle: there was a statistically significant increase in TH. TH was not induced in the denervated adrenal gland of rats administered AVP systemically. These findings suggest that AVP may act centrally to induce the enzyme. The continuous s.c. infusion of AVP by osmotic minipump at the rate of 1 microgram/day for 6 days led to a striking increase in adrenal TH activity. However, PNMT did not increase significantly. It can be concluded that different mechanisms are involved in the induction of adrenal TH and PNMT caused by AVP. A neural mechanism is involved in TH induction, whereas PNMT induction requires release of a pituitary factor, presumably ACTH, but innervation of the adrenal is not needed for it. Moreover, the inductions of these two enzymes are differentially sensitive to the concentration of circulating AVP.     

Expression of the adrenergic phenotype in cultured fetal adrenal medullary cells: role of intrinsic and extrinsic factors

During embryogenesis of the rat the enzymes tryosine hydroxylase (TH) and dopamine-β-hydroxylase (DBH) are first detected by immunocytochemistry or biochemical assay on the 16th day of gestation (E 16). It is not until E 18 that the enzyme phenylethanolamine-N-methyltransferase (PNMT), which is required for biosynthesis of adrenaline, can be detected cytochemically or biochemically. In this study we sought to determine whether the delayed appearance of PNMT is consequent to invasion of the adrenal medulla by E 18 of cells destined to express PNMT, cues provided by the ingrowing splachnic nerves or the action of corticosterone (CS) secreted by the adrenal cortical anlage, a hormone which regulates PNMT in adult rats. When adrenal glands are removed on E 16 and placed in culture, PNMT cannot be detected cyto- or biochemically until 2 days later (E 16 + 2). While CS levels increase 100-fold in vivo between E 16 and E 18, the surge of CS is not necessary for expression of PNMT since (a) adrenals removed on E 16 and cultured in the absence of exogenous ACTH fail to increase CS yet still express PNMT and (b) addition of CS (10^?5M) to the cultures on E 16 does not alter the time of appearance of the enzyme. CS, on the other hand, increases the amount of PNMT protein and activity 3-fold with respect to control at all time points, without any effect on TH. We conclude that (a) it is the cells already present in the adrenal medulla at E 16 which differentiate to express PNMT; (b) the initial expression of PNMT is not controlled by nerves nor by corticosteroids; and (c) corticosteroids have a selective action on regulating the amount of PNMT, once it is expressed, but not TH enzyme protein. It remains to be determined whether the differentiation of PNMT is elicited by genetic or epigenetic signals.