Biosynthesis of catecholamines in organotypic cultures of peripheral autonomic nervous system: modifications by biopterin and other agents.

Organotypic cultures of chick-embryo sympathetic ganglion chains maintained in vitro for 3-4 weeks rapidly synthesized catecholamines, as demonstrated by the conversion of L-[U-14C]tyrosine to catechol derivatives and by histofluorescence assay. The biosynthesis of catechols from radioactive L-tyrosine leveled off at 6 hr of incubation and dropped slightly at 10 hr. The addition of DL-alpha-methyl-p-tyrosine to the culture medium did not affect protein synthesis, but produced a complete block in the synthesis of catecholamines from L-tyrosine, with consequent loss of fluorescence in the bodies and proximal processes of adrenergic neurons in 2 hr, and essentially complete loss in 6 hr. Our observations suggest that a major portion of the catecholamines were synthesized in the perikarya and transported via neuronal processes to their terminals. The addition of monoamine oxidase inhibitors to the incubation medium produced a moderate to pronounced increase in fluorescence; reserpine caused a rapid and profound loss of catecholamines. When added to the culture medium, crude biopterin produced an increase in the synthesis of catechol derivatives from radioactive L-tyrosine and a marked increase in fluorescence, beginning in the neuronal perikarya. This effect was completely blocked by DL-alpha-methyl-p-tyrosine. The mechanism of biopterin's action in the synthesis of catecholamines in cultures of sympathetic ganglia is not completely elucidated from these studies, but may be related to the role it plays as cofactor for tyrosine hydrocylase.     

Fluorescence spectra of the SIF cells in rat neuroganglia

The spectral curves of emission of paraform-induced fluorophores in small, intensely fluorescent (SIF) cells in lumbar ganglia of the sympathetic trunk and in the major pelvic ganglion were compared with the fluorescence spectra of lipofuscin granules in the perikaryons of the neurons of the vagus inferior ganglion. As a rule, the fluorescence spectra of SIF cells correlate with the content in them of catecholamines. The spectral characteristics of fluorophores of so-called "yellow" SIF cells have much in common with the fluorescence spectra of lipofuscin granules. Apparently, in some of cases small cells containing lipofuscin may be identified as "yellow" SIF cells.     

Catecholamines and catecholamine-synthesizing enzymes in guinea-pig sensory ganglia

Summary Cranial and spinal sensory ganglia of the guinea-pig were investigated by means of histochemistry and biochemistry for the presence of catecholamines and catecholamine-synthesizing enzymes. Sensory neurons exhibiting immunoreactivity to the rate-limiting enzyme of catecholamine synthesis, tyrosine nydroxylase (TH), were detected by immunohistochemistry in lumbo-sacral dorsal root ganglia, the nodose ganglion and the petrosal/jugular ganglion complex. The carotid body was identified as a target of TH-like-immunoreactive (TH-LI) neurons by the use of combined retrograde tracing and immunohistochemistry. Double-labelling immunofluorescence revealed that most TH-LI neurons also contained somatostatin-LI, but TH-LI did not coexist with either calcitonin gene-related peptide- or substance P-LI. TH-LI neurons did not react with antibodies to other enzymes involved in catecholamine synthesis, i.e., aromatic amino acid decarboxylase (AADC), dopamine--hydroxylase (DH), and phenylethanolamine-N-methyltransferase (PNMT). Petrosal neurons as well as their endings in the carotid body lacked dopamine- and L-DOPA-LI. Sensory neurons did not display glyoxylic acid-induced catecholamine fluorescence. Ganglia containing TH-LI neurons were kept in short-term organ culture after crushing their roots and the exiting nerve in order to enrich intra-axonal transmitter content at the ganglionic side of the crush. However, even under these conditions, catecholamine fluorescence was not detected in axons projecting peripherally or centrally from the ganglia. Sympathetic noradrenergic nerves entered the ganglia and terminated within them. Accordingly, biochemical analyses of guinea-pig sensory ganglia revealed noradrenaline but no dopamine. In conclusion, catecholamines within guinea-pig sensory ganglia are confined to sympathetic nerves, which fulfill presently unknown functions. The TH-LI neurons themselves, however, lack any additional sign of catecholamine synthesis, and the presence of enzymatically active TH within these neurons is questionable.     

Biosynthesis of catecholamines in organotypic cultures of the peripheral autonomic nervous system: Modifications by biopterin and other agents

Organotypic cultures of chick-embryo sympathetic ganglion chains maintained in vitro for 3–4 weeks rapidly synthesized catecholamines, as demonstrated by the conversion of L-[U-¹⁴C]tyrosine to catechol derivatives and by histofluorescence assay. The biosynthesis of catechols from radioactive L-tyrosine leveled off at 6 hr of incubation and dropped slightly at 10 hr. The addition of DL-α-methyl-p-tyrosine to the culture medium did not affect protein synthesis, but produced a complete block in the synthesis of catecholamines from L-tyrosine, with consequent loss of fluorescence in the bodies and proximal processes of adrenergic neurons in 2 hr, and essentially complete loss in 6 hr. Our observations suggest that a major portion of the catecholamines were synthesized in the perikarya and transported via neuronal processes to their terminals. The addition of monoamine oxidase inhibitors to the incubation medium produced a moderate to pronounced increase in fluorescence; reserpine caused a rapid and profound loss of catecholamines. When added to the culture medium, crude biopterin produced an increase in the synthesis of catechol derivatives from radioactive L-tyrosine and a marked increase in fluorescence, beginning in the neuronal perikarya. This effect was completely blocked by DL-α-methyl-p-tyrosine. The mechanism of biopterin's action in the synthesis of catecholamines in cultures of sympathetic ganglia is not completely elucidated from these studies, but may be related to the role it plays as cofactor for tyrosine hydroxylase.     

Consecutive demonstration of catecholamines and dopamine-β-hydroxylase within the same specimen

Summary A combined method was developed for characterization and differentiation of catecholamines in neuron populations containing more than one catecholamine, e.g. dopamine and norepinephrine. Its application to small intensely fluorescent (SIF-) cell clusters in sympathetic ganglia allows the successive demonstration of glyoxylic acid-induced catecholamine fluorescence and dopamine--hydroxylase by indirect immunofluorescence within the same tissue section. Applying this technique to an example, two types of SIF-cells were demonstrated in the guinea pig superior cervical ganglion.Supported by the Deutsche Forschungsgemeinschaft grant He 919/4     

Ganglion cells and paraganglionic cells in the developing superior cervical ganglion of normal and p-chlorophenylalanine treated rats

Ganglion cells and paraganglionic (PG) cells in the developing rat superior cervical ganglion were studied following postnatal treatment with p-chlorophenylalanine (pCPA) for 5 to 8 days. Litter mates, injected with saline solution, served as controls. Ganglion cells of control animals were differentiated ultrastructurally according to L. Er?nk? (1972a) into late sympathicoblasts and young sympathetic nerve cells. In both maturation stages treatment with pCPA caused marked swelling of mitochondria, concomitant with minor changes of other cell organelles. Parallel to the ultrastructural alterations, fluorescence microscopy and cytophotometry revealed a slight diminution of diffuse fluorescence intensity in sympathetic neurons as the expression of a mainly extragranular amine depletion. In distinction from ganglion blocking agents the alterations are regarded as a general toxic effect of pCPA upon maturing sympathetic neurons, which secondarily influences catecholamine storage sites. Following treatment with pCPA, in PG-cells an alteration of mitochondria was scarcely to recognize. Specific granules were distinctly decreased in number, in some cases to an almost complete degree. Concordant to ultrastructural observations a marked diminution of fluorescence intensity was demonstrable in SIF-cells. In addition in these elements the fluorescence spectrum shifted towards the green field. Fluorescence cytophotometric evaluations confirmed the optical impression. Provided, that PG-cells, demonstrated with electron microscopy, are identical with SIF-cells in fluorescence microscopy, the results are discussed on the basis of a specific decrease of primary catecholamines due to an enzyme inhibition involved in catecholamine synthesis.     

Hydrocortisone-induced increase in the number of small intensely fluorescent cells and their histochemically demonstrable catecholamine content in cultures of sympathetic ganglia of the newborn rat

Synopsis It is known that hydrocortisone causes a great increase in the number of small intensely fluorescent (SIF) cells in the sympathetic ganglia when injected into newborn rats. The effect of hydrocortisone on nervous tissuein vitro has not been studied previously.Pieces of newborn rat sympathetic ganglia were cultivated in Rose chambers. Hydrocortisone was dissolved in the medium in concentrations of 1–9 mg/l. Both control and hydrocortisone-containing cultures were examined daily by phase-contrast microscopy, and the catecholamines were demonstrated histochemically by formaldehyde-induced fluorescence after 7 days in culture.All cultures showed outgrowths of axons and supporting cells elements, although these were less extensive in the groups of cultures with hydrocortisone. After a week, SIF cells with a green fluorescence were observed in the control explants. In all cultures with hydrocortisone, a concentration-dependent increase was observed in the fluorescence intensity and the number of the SIF cells in the explant; numerous SIF cells were also seen in the outgrowth. Some SIF cells showed processes and the longest processes were seen in cultures with the highest concentration of hydrocortisone.It is concluded that hydrocortisone causes an increased synthesis of catecholamines in the SIF cellsin vitro, and an increase in their number by affecting either their division or their differentiation from a more immature form, or both. This effect was a direct one and not mediated by any system other than the ganglion itself. Induction of enzyme synthesis by hydrocortisone is proposed as an explanation of the increase in catecholamine concentration.University of Melbourne Senior Research Fellow, September 1971-August 1972Sunshine Foundation and Rowden White Trust Overseas Research Fellow in the University on Melbourne, September 1971-August 1972     

Trophoblastic invasion and modification of uterine veins during placental development in macaques

Summary Immunoreactivity to the rate limiting enzyme of catecholamine synthesis, tyrosine hydroxylase, has been described in the inferior sensory (= nodose) ganglion of the vagal nerve in the rat. The aim of the present study was to characterize further this neuronal population. The neurons do not represent displaced autonomic efferent neurons, since they do not receive synaptic input, as indicated by the absence of synaptophysin-immunoreactive terminals. In addition to the immunoreactivity to tyrosine hydroxylase, a tyrosine hydroxylase cRNA probe hybridizes with nodose ganglion neurons as demonstrated by in situ hybridization and Northern blotting. Many but not all of the tyrosine hydroxylase-immunoreactive neurons are also immunoreactive to the dopamine synthesizing enzyme, aromatic-l-amino-acid-decarboxylase, but lack the noradrenaline-synthesizing enzyme, dopamine--hydroxylase, thus favoring synthesis of dopamine. Neuropeptide Y, which is often colocalized with catecholamines, is also present in a subset of nodose ganglion neurons, as indicated by immunohistochemistry, in situ hybridization and Northern blotting. However, double-labeling immunofluorescence has revealed that these two antigens are localized in different cell populations. Retrograde neuronal tracing utilizing fluorescent dyes (Fast blue, Fluoro-gold) combined with tyrosine hydroxylase immunohistochemistry has demonstrated that the esophagus and stomach are peripheral targets of tyrosine-hydroxylase-containing vagal visceroafferent neurons.     

Loss of histochemically demonstrable catecholamines and acetylcholinesterase from sympathetic nerve fibres of the pineal body of the rat after chemical sympathectomy with 6-hydroxydopamine

Synopsis Newborn albino rats were injected daily for 8 days with 50 g/g of 6-hydroxydopamine. They were killed 3 weeks after the last injection together with untreated litter mate controls. Monoamines were demonstrated histochemically in the pineal body, in the iris and in the superior cervical ganglion with the formaldehyde-induced fluorescence method. Acetylcholinesterase was demonstrated in the pineal using acetylcholine as substrate and tetraisopropy-pyrophosphoramide (iso-OMPA) to inhibit non-specific cholinesterases.Treatment with 6-hydroxydopamine caused a complete disappearance of amine-containing fibres from the pineal, whereas some fluorescent ganglion cells remained in the superior cervical ganglion and in some rats a few amine-containing fibres in the iris. Acetylcholinesterase activity, located in fine nerve fibres of the pineal body, disappeared completely after treatment with 6-hydroxydopamine.Since 6-hydroxydopamine causes a selective destruction of the aminergic sympathetic fibres, it is concluded that the disappearance of the acetylcholinesterase activity indicates that in the pineal body this enzyme activity is located exclusively in truly aminergic nerve fibres.     

Pharmaco-histochemical studies on a specific monoamine in the gustatory epithelia of the rabbit

Summary The foliate, vallate and fungiform papillae of the rabbit's tongue were studied fluorescence-histochemically under normal and experimental conditions. In normal animals a yellow fluorescence suggesting the presence of a serotonin-like monoamine was demonstrated only in taste bud cells of the foliate papilla, though its intensity was very weak. The fluorescence disappeared completely following reserpine treatment, while it was significantly enhanced by the treatment with nialamide. The fluorescence of taste bud cells could be clearly distinguished from that of catecholamines by the treatment with -MMT followed by nialamide. When 5-HTP, 5-HT and 5,6-DHT were administered separately, each of these drugs was selectively taken up in taste bud cells of the foliate and vallate papillae, but no fluorescent cells were observed in the fungiform papilla.From the present results, it seems reasonable to conclude that the fluorigenic amine of taste bud cells may be 5-HT (serotonin), or at least an indoleamine derivative. Also, it is suggested that the taste bud of the vallate papilla contains a cell type which can potentially synthesize a biogenic amine in situ, or is actually synthesizing it in a very small amount just like in the case of the taste bud of the foliate one.     

Histochemical and electron microscopical demonstration of the sympathetic nerve fibers joining to the fourth and the sixth cranial nerves in rats

The localization of sympathetic fibers on the floor of the cranium was studied in rats using amine fluorescence histochemistry, neuropeptide-Y (NPY) immunohistochemistry, and electron microscopy. The vast majority of amine fluorescent fibers joined the abducent nerve and were localized in the peripheral zone under the perineurium. After advancing along this nerve for some distance, the fibers diverged into many bundles that converged to form the cavernous plexus at a rostral end of the trigeminal ganglion. On the dorsal surface of the trigeminal ganglion, one or two medium-calibered fluorescent bundles ran inside or in close proximity to the trochlear nerve, while many small-calibered, brightly fluorescent bundles also extended longitudinally in the epidural connective tissue. In rats that had undergone nerve severance, NPY-immunoreactive fibers were detected at the cut ends of the abducent and trochlear nerve. The differing amounts of NPY accumulated at the rostral and the caudal stumps indicated the direction of the NPY-bearing fibers. Electron microscopy confirmed the presence of unmyelinated fibers in both the abducent and trochlear nerves.     

A histochemical study of the primary catecholamines in the hypothalamic neurons of the rat in relation to the ontogenetic and sexual differentiation

Summary The alterations in the content of the primary catecholamines in the hypothalamus have been studied with the histochemical technique of para-formaldehyde induced fluorescence.In the adult normal rats, independent of the sex, the fluorescence is located in the cell bodies of a few arcuate neurons, around the perikarya of the arcuate, para-ventricular and supra-optic neurons, and in the nerve endings of the arcuate neurons in the median eminence.The appearance of the primary catecholamines takes place at the 20th day of gestation in the para-ventricular and arcuate-peri-ventricular regions. In the supra-optic nucleus the fluorescent nerve terminals are not seen before birth. In the outer layer of the median eminence the fluorescence develops around the 5th post-natal day. No sexual differences were observed in the maturation of the primary catecholamines during the ontogenic development of the rat.More fluorescent cell bodies and nerve endings are seen in the arcuate neurons during the late diestrus than during estrus. The number and intensity of the catecholamine fluorescent neurons in the arcuate nucleus increases during the pregnancy. Castration increases slightly the number and intensity of the fluorescent cell bodies in the arcuate nucleus, but it diminishes the fluorescence in the median eminence. The changes were compensated by a treatment with testosterone propionate. Hypophysectomy alone has no effect on the fluorescence of the hypothalamic neurons.Supported by a grant from The Finnish Medical Society Duodecim.     

Consecutive demonstration of catecholamines and dopamine-beta-hydroxylase within the same specimen.

A combined method was developed for characterization and differentiation of catecholamines in neuron populations containing more than one catecholamine, e.g. dopamine and norepinephrine. Its application to small intensely fluorescent (SIF-) cell clusters in sympathetic ganglia allows the successive demonstration of glyoxylic acid-induced catecholamine fluorescence and dopamine-beta-hydroxylase by indirect immunofluorescence within the same tissue section. Applying this technique to an example, two types of SIF-cells were demonstrated in the guinea pig superior cervical ganglion.     

Formaldehyde induced catecholamine fluorescence in the mouse inferior laryngeal paraganglion

Summary The presence of high concentrations of catecholamines is shown in the mouse's inferior laryngeal paraganglion by means of fluorescence histochemistry. In mice, the entire organ is composed of 20 to 25 small, intensely fluorescent cells of oval shape (about 15 m in diameter). The paraganglion is well provided with capillaries. The identification of catecholamines in the inferior laryngeal paraganglion, originally described as nonchromaffin (parasympathetic) paraganglion, presents additional evidence that all paraganglia store biogenic amines, are related to the sympathetic nervous system, and belong to the APUD cell series.Supported by the Deutsche Forschungsgemeinschaft, Project No: Bo 525/1     

Quantitative fluorescence studies of the effects of catecholamines and hydrocortisone on endogenous amine levels in neurones and small intensely fluorescent cells of embryonic chick sympathetic ganglia in vivo and in vitro

Summary Chick embryo lumbar sympathetic ganglia (11 day) cultured for three days and uncultured (in vivo) ganglia of comparable age were freeze-dried and processed by the formaldehyde-induced fluorescence technique for the demonstration of biogenic monoamines. The catecholamine levels within principal neurone cell bodies and small intensely fluorescent (SIF) cells were then examined in plastic sections of the in vivo and in vitro ganglia by a quantitative fluorescence method under various experimental conditions. Culture of ganglia for three days in the presence of hydrocortisone acetate (10g/ml) resulted in an increased SIF cell fluorescence (P<0.001 compared to control) and a green to yellow colour shift in the fluorophore of SIF cells. No detectable alteration in the fluorescence level of neurones was observed. When neurones after three days in culture were incubated for 1 h in exogenous catecholamines, a significant increase in fluorescence levels (interpreted as an increase in catecholamine content) occurred with noradrenaline (2×10^–6 M; 2×10^–5 M). SIF cells in ganglia removed directly from 14-day old chicks similarly took up noradrenaline and dopamine, and also adrenaline (2×10^–5 M). Morphological results are presented which indicate that the cellular appearances and architecture of cultured ganglion explants are very similar to those in comparable ganglia in vivo.This work was supported by a grant from the Medical Research Council. We thank Mrs. G. O'Shea, Mr. T.T. Lee and Mr. P.F. Hire for their valuable technical assistance     

Increased cardiac production of dihydroxyphenylalanine (DOPA) during sympathetic stimulation in anaesthetized dogs.

Entry of dihydroxyphenylalanine (DOPA) into plasma from specific organs may reflect regional activity of tyrosine hydroxylase, the enzyme responsible for the immediate synthesis of DOPA and rate-limiting for subsequent formation of catecholamines. Therefore, cardiac spillovers of DOPA, noradrenaline and the intraneuronal metabolite of noradrenaline, dihydroxyphenylglycol (DHPG), were examined during two periods of graded electrical stimulation of the sympathetic nerves to the heart in anesthetized dogs. Responses were examined before and after neuronal uptake blockade with desipramine. Cardiac spillover of DOPA increased by 1.8- and 4.4-fold during sympathetic stimulation before desipramine and by 1.6- and 3.3-fold after desipramine. Fold increases in cardiac spillover of DOPA were much lower than but positively related with fold increases in noradrenaline spillover (5.9- and 13.8-fold increases before and 9.0- and 15.8-fold increases after desipramine). Increases in cardiac spillover of DHPG (1.5- and 2.3-fold increases) were blocked by desipramine so that fold changes in spillover of DOPA were greater than and poorly related to changes in spillover of DHPG. Fold increases in cardiac spillover of DOPA showed a close one-to-one positive relationship with fold increases in the sum of cardiac spillovers of noradrenaline and dihydroxyphenylglycol before and after desipramine. For a given fold increase in noradrenaline release, transmitter turnover is increased fractionally and noradrenaline synthesis need also only increase fractionally to maintain transmitter stores constant. The close relationship between fold increases in cardiac spillover of DOPA and combined spillovers of noradrenaline and DHPG is consistent with regulation of tyrosine hydroxylase activity to match changes in noradrenaline synthesis with changes in noradrenaline turnover. Changes in cardiac spillover of DOPA appear to reflect local changes in tyrosine hydroxylase activity.     

Developmental expression of serotonin-like immunoreactivity in the sympathoadrenal system of the chicken

Summary The avian sympathoadrenal system has been used as a model to examine the differentiation of cells expressing neuroactive substances derived from the neural crest. Previous studies have dealt with the expression of the classical neurotransmitters acetylcholine and catecholamines and of the neuropeptides somatostatin and vasoactive intestinal polypeptide. We have used immunocytochemistry to examine the developmental expression of the monoamine serotonin (5HT) in the chicken sympathoadrenal system. 5HT-like immunoreactivity (5HT-LI) was found to be transiently expressed by cells of the sympathetic ganglia very early in development (E-5 to E-8), disappearing almost entirely at more advanced embryonic stages (E-10 to E-19) and posthatched chickens where only a population of cells similar to mammalian small intensely fluorescent cells express immunoreactivity to the amine. In contrast, in the adrenal gland of embryos and post-hatched chickens, most chromaffin cells also express 5HT-LI. Double labeling experiments show that in both the adrenal gland and the sympathetic ganglia catecholaminergic properties and somatostatin immunoreactivity are co-expressed with 5-HT-LI. Moreover, the cells that transiently express 5HT-LI in sympathetic ganglia also transiently express somatostatin. The catecholaminergic cells expressing serotonin and somatostatin appear to define a biochemical phenotype common to some chromaffin cells, small intensely fluorescent cells and early sympathoblasts.     

Loss of histochemically demonstrable catecholamines in the glomus cells of the carotid body after α-methyl-para-tyrosine treatment

Summary A statistically significant decrease in the intensity of catecholamine fluorescence of some carotid body glomus cells was observed after inhibition of the enzyme tyrosine hydroxylase by injection of 80 mg/kg -methyl-paratyrosine. The intensity of the formaldehyde-induced fluorescence was measured in individual glomus cells. The maximum decrease in the intensity was observed 4 to 6h after the -methyltyrosine injection. This suggests a rapid turnover in the catecholamines of the carotid body.     

Dopamine-containing small intensely fluorescent cells and sympathetic ganglion function

This article reviews some of the neuropharmacology of the dopamine (DA)-containing small intensely fluorescent cells of sympathetic ganglia. The major metabolite of DA found in the ganglia is 3,4-dihydroxyphenylacetic acid (DOPAC). DOPAC content appears to be a direct reflection of DA synthesis. DA synthesis can be enhanced by muscarinic agonists and diminished by muscarinic antagonists. Neuroleptic drugs stimulate DA synthesis in the ganglion, which suggests that a local negative neuronal feedback loop might operate within the ganglion. There may be a correlation between deficient DA synthesis in spontaneous hypertensive rats and the development of hypertension. It is possible that some of the peripheral side effects of drugs that act on dopaminergic neurons in the brain might originate from the drugs' action on peripheral dopaminergic neuronal systems such as the sympathetic ganglion.     

Histochemical evidence of chemical sympathectomy by guanethidine in newborn rats

Synopsis Guanethidine is known to cause a loss of catecholamines from sympathetically innervated tissues and sympathetic ganglia in adult animals but its effect on newborn animals has not been examined.Newborn rats were injected daily with guanethidine (20 mg/kg body weight) for 8 days. They were killed when 1 month-old along with untreated litter mate controls. Catecholamines were demonstrated in the iris, in the pineal body and in sympathetic ganglia, using the formaldehyde-induced fluorescence method.In the guanethidine-treated rats there was a complete loss of fluorescent nerve fibres from the pineal body and an almost complete loss of similar fibres from the iris. The sympathetic ganglia were reduced to less than 10% of the control ganglia, and the number of nerve cell bodies per unit area was decreased in the ganglion remnants.It is concluded that guanethidine causes, in newborn rats, an irreversible destruction of most sympathetic neurons, i.e. a chemical sympathectomy closely resembling that obtainable in newborn animals by injections of 6-hydroxydopamine or antiserum to nerve growth factor.