L-tyrosine, L-dopa, and tyrosinase as positive regulators of the subcellular apparatus of melanogenesis in Bomirski Ab amelanotic melanoma cells

In cultured cells of the Bomirski Ab amelanotic hamster melanoma line, the substrates of tyrosinase, L-tyrosine, and L-DOPA induce the melanogenic pathway. In this report, we demonstrate that these substrates regulate the subcellular apparatus involved in their own metabolism and that this regulation is under the dynamic control of one of the components of this apparatus, tyrosinase, via tyrosine hydroxylase activity. Culturing cells with nontoxic but melanogenically inhibitory levels of phenylthiourea (PTU; 100 microM) strongly inhibits induction of both the tyrosine hydroxylase and DOPA oxidase activities of tyrosinase by L-tyrosine (200 microM) but has no effect on the induction of either activity by L-DOPA (50 microM). De novo synthesis of premelanosomes precedes the onset of tyrosine-induced melanogenesis. Thereafter, increases in the population of melanosomes (likewise inhibited by PTU) correlate positively with increases in tyrosinase activity induced by L-tyrosine. Melanogenesis induced by L-DOPA in the absence of L-tyrosine is rate-limited not by tyrosinase but by inadequate melanosome synthesis. Our findings indicate that in Bomirski Ab amelanotic hamster melanoma cells the synthesis of the subcellular apparatus of melanogenesis is initiated by L-tyrosine and is regulated further by tyrosinase and L-DOPA, which serves as a second messenger subsequent to tyrosine hydroxylase activity.     

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.     

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.     

Effects of dysthyroidism on central catecholaminergic neurons

After 15 years of research, it is clear that alterations in thyroidal status affect catecholaminergic neurons in the developing as well as in the adult brain. Experiments on fetal catecholaminergic brain areas grafted into the anterior eye chamber of adult thyroidectomized rat have shown the thyroid hormone dependency of the morphological differentiation of catecholaminergic neurons originating from the substantia nigra and the locus coeruleus. Furthermore, thyroid hormones also affect the metabolism of catecholaminergic neurons. Neonatal hypothyroidism induced either by ¹³¹I or by an antithyroid drug decreases the concentration of dopamine, noradrenaline and the activity of tyrosine hydroxylase at least in whole brain studies. Treatments with l-thyroxine of neonatally thyroidectomized rats reverse these neurochemical changes in a both time and dose dependent manner. These presynaptic modifications are associated with a decrease in the number of catecholaminergic receptors in different brain areas. On the opposite, experimental neonatal hyperthyroidism induced by daily administration of l-triiodothyronine increases the synthesis as well as the utilization of catecholamines. These changes are also associated with an alteration of catecholaminergic receptors. Despite numerous studies, there is, so far, no clear conclusion on the effects of neonatal dysthyroidism on the development of each catecholaminergic group. However, from these studies, it appears that the intensity of neonatal dysthyroidism greatly varies, depending of the monoamine and the brain area studied. The utilization of fetal brain cell cultures growing in a chemically defined medium has permitted to demonstrate the direct effect of thyroid hormones on fetal brain cells and the morphological effects of triiodothyronine on the size and the neurite length and arborization of fetal hypothalamic dopaminergic neurons.In the adult brain, hypothyroidism induced by surgical thyroidectomy, decreases the rate of catecholamines synthesis, decreases the number of alpha noradrenergic receptors and has no effect on striatal dopaminergic receptors. In contrast, hyperthyroidism increases the rate of catecholamines synthesis and induced an hypersensitivity of noradrenergic receptors. The intensity of the effects of dysthyroidism seems to be dependent on the monoamine and the brain area studied.In conclusion, it can be proposed that in the neonate thyroid hormones act on CA neuron activity mostly through a morphogenetic effect whereas in the adulthood they directly affect CA metabolism.     

Effect of hyperthyroidism and hypothyroidism on rat red blood cell insulin receptors and catecholamines: relationship with cellular ageing

Insulin receptor activity and its relationship with catecholamines in rat young, middle aged and old red blood cells were investigated in experimental hypothyroidism and hyperthyroidism. In control animals, a loss of insulin receptor activity was found with cellular ageing and increased levels of norepinephrine, epinephrine and glycosylated hemoglobin. There was down regulation of insulin receptors together with alterations in membrane bound catecholamines in thyroid hormones imbalances. These results suggest that loss of insulin receptor in cellular ageing is probably part of a more generalised alteration and rat serves as an excellent model in defining the role of thyroid hormones in carbohydrate tolerance.     

Glucocorticoids and catecholamines as mediators of acute-phase proteins, especially rat alpha-macrofoetoprotein.

Adrenal hormones were studied as possible triggering substances of the synthesis of acute-phase reactants in rats. alpha-Macrofoetoprotein, which rises sharply in concentration during inflammation, was used to monitor the acute-phase reaction. In normal rats glucocorticoids and catecholamines induce alpha-macrofoetoprotein synthesis; glucocorticoids only increase alpha-macrofoetoprotein to moderate levels in plasma, but catecholamines enhance alpha-macrofoetoprotein synthesis to very high levels, comparable with those observed in the post-injury phase. However, catecholamines in vivo also activate the adrenal cortex, suggesting a synergistic effect of both kinds of adrenal hormones. Our study showed that in adrenalectomized rats, the effect of catecholamines on alpha-macrofoetoprotein synthesis is greatly diminished, whereas the moderate effect of glucocorticoids remains. Combination of glucocorticoids and catecholamines induces extremely high alpha-macrofoetoprotein levels in both adrenalectomized and normal rats. With crossed immunoelectrophoresis it was shown that other acute-phase reactants, such as haptoglobin and alpha 1-major acute-phase protein, are affected differently by the hormones. Contrary to glucocorticoids, catecholamines give a pattern comparable with that found after surgical injury.     

beta-Adrenergic receptors in rat skeletal muscle. Effects of thyroidectomy.

Thyroid hormones may participate in the regulation of beta-adrenergic receptors in skeletal muscle sarcolemmal membrane. Since skeletal muscles are not innervated by sympathetic nerve endings, the biochemical mechanism involved in the control of beta-adrenergic receptors by thyroid hormones appears to be mediated by thyroid-induced regulation of serum levels of catecholamines.     

β-adrenergic receptors in rat skeletal muscle effects of thyroidectomy

Thyroid hormones may participate in the regulation of β-adrenergic receptors in skeletal muscle sarcolemmal membrane. Since skeletal muscles are not innervated by sympathetic nerve endings, the biochemical mechanism involved in the control of β-adrenergic receptors by thyroid hormones appears to be mediated by thyroid-induced regulation of serum levels of catecholamines.     

Expression of the enzymes of dopamine synthesis in non-dopaminergic neurons: functional significance and regulation

Dopamine(DA), the most widely distributed in the nervous system and functionally important chemical signal, is synthesized in DA-ergic neurons from L-tyrosine by means of two enzymes, tyrosine hydroxylase (TH) and aromatic L-amino acid decarboxylase (AADC). Apart from the enzymes, specific DA transporter is an attribute of DA-ergic neurons. In the mid eighties of the last century, in addition to DA-ergic neurons, those expressing only one enzyme, TH or AADC, have been discovered. These "monoenzymatic" neurons occurred to be more numerous and more widely distributed in the brain compared to DA-ergic neurons that manifests their wide involvement to the brain functioning. It has been demonstrated that the monoenzymatic neurons expressing complementary enzymes of DA synthesis produce this neurotransmitter in cooperation. In this case, L-tyrosine is transformed to L-DOPA in TH containing neurons that is followed by L-DOPA release and uptake from the intercellular space to AADC containing neurons for DA synthesis. Moreover, the L-DOPA uptake to DA-ergic or serotoninergic neurons results either in the increase or the onset of DA synthesis in addition to serotonin, respectively. The expression of the enzymes of DA synthesis in non-dopaminergic neurons is one of the adaptive reactions serving to compensate the functional insufficiency of DA-ergic neurons. For instance, hyperprolactinemia and the deficiency of DA, prolactin-inhibiting hormone, which is developed under degeneration of DA-ergic neurons of the arcuate nucleus, are compensated with time due to the increase of the number of monoenzymatic neurons and cooperative synthesis of DA in the nucleus. It is supposed that the same compensatory cooperative synthesis of DA is turned on under the degeneration of DA-ergic neurons of the nigrostriatal system that is manifested by the appearance of non-dopaminergic neurons expressing enzymes of DA synthesis in the deafferentated striatum. The expression of the enzymes of DA synthesis in non-dopaminergic neurons is under the control by intercellular signals, catecholamines, neurotrophic (growth) factors and, perhaps, hormones. Thus, non-dopaminergic monoenzymatic neurons expressing enzymes of DA synthesis produce this neurotransmitter in cooperation that is a compensatory reaction under functional insufficiency of DA-ergic neurons, in neurodegenerative diseases, hyperprolactinemia and Parkinson's disease, in particular.     

Induction of metamorphosis in the sand dollar Peronella japonica by thyroid hormones

The larva of the sand dollar Peronella japonica lacks a mouth and gut, and undergoes metamorphosis into a juvenile sand dollar without feeding. In the present study, it was found that thyroid hormones accelerate the metamorphosis of P. japonica larvae. The contents of thyroid hormones in larvae increased gradually during development. Thiourea and potassium perchlorate, inhibitors of thyroid hormone synthesis, delayed larval metamorphosis and simultaneously repressed an increase in the content of thyroxine in the larval body. These results suggest that the P. japonica larva has a system for synthesis of thyroid hormones that act as factors for inducing metamorphosis.     

Ultrastructural radioautography of synthesis and migration of proteins and catecholamines in the rat adrenal medulla

Summary The synthetic pathways of proteins and catecholamines in the rat adrenal medullary cells were compared systematically at the ultrastructural level, within a 24 h period, with 2 tracers, L-tyrosine 3,5-³H and L-3,4-dihydroxy [ring 2,5,6-³H] phenylalanine (L-dopa³H). Young rats were injected with either of these tracers and sacrificed in pairs at close time intervals. With L-tyrosine ³H, the label was about equal over rough endoplasmic reticulum (RER) and secretory granules at 2 min after injection and remained almost constant in intensity over the secretory granules throughout the period of observation. A peak of radioactivity was also observed in the Golgi complex between 5 and 20 min after injection. This indicates that L-tyrosine ³H participates in the synthesis of both granule proteins and catecholamines as confirmed by the results obtained after injection of L-dopa ³H. With this tracer, radioactivity over RER, Golgi complex, cytosol and cell surface remained very low at all times and was undetectable at several time intervals. In contrast, radioactivity over secretory granules was very high at all time intervals. The present results thus confirm that in both adrenaline- and noradrenaline-storing cells, the protein moiety of chromaffin granules is synthetized in the RER, packaged in the Golgi complex and rapidly found in newly formed secretory granules. Following either L-tyrosine ³H or L-dopa ³H injection, catecholamine synthesis occurs only in or in close vicinity to chromaffin granules in both cell types at all time intervals. Acknowledgements. This work was supported by a grant from the Medical Research Council of Canada to the Multidisciplinary Research Group of Hypertension of the Clinical Research Institute of Montreal and by the Canadian Heart Foundation     

Thyroid hormones and mitochondria

Because of their central role in the regulation of energy-transduction, mitochondria, the major site of oxidative processes within the cell, are considered a likely subcellular target for the action that thyroid hormones exert on energy metabolism. However, the mechanism underlying the regulation of basal metabolic rate (BMR) by thyroid hormones still remains unclear. It has been suggested that these hormones might uncouple substrate oxidation from ATP synthesis, but there are no clear-cut data to support this idea. Two iodothyronines have been identified as effectors of the actions of thyroid hormones on energy metabolism: 3',3,5-triiodo-L-thyronine (T3) and 3,5-diiodo-L-thyronine (T2). Both have significant effects on BMR, but their mechanisms of action are not identical. T3 acts on the nucleus to influence the expression of genes involved in the regulation of cellular metabolism and mitochondria function; 3,5-T2, on the other hand, acts by directly influencing the mitochondrial energy-transduction apparatus. A molecular determinant of the effects of T3 could be uncoupling protein-3 (UCP-3), while the cytochrome-c oxidase complex is a possible target for 3,5-T2. In conclusion, it is likely that iodothyronines regulate energy metabolism by both short-term and long-term mechanisms, and that they act in more than one way in affecting mitochondrial functions.     

Thyroid status and adenosine content of adipose tissue.

Fat-cells from hypothyroid rats lack the normal lipolytic response to catecholamines. We have suggested that this is due to increased sensitivity to the inhibitory actions of endogenous adenosine. In this paper we present evidence that thyroid hormones increase adipose-tissue adenosine contents and suggest that the increased sensitivity to adenosine in hypothyroidism is due to relief from desensitization by endogenous adenosine.     

Cyclic AMP as the second hormonal messenger in the in vitro folliculogenesis of the foetal thyroid gland of the rat

Thyroid-stimulating hormone, the catecholamine isoproterenol, and prostaglandins E1 and E2, all substances known to increase cAMP concentration in thyroid tissue, accelerate the formation of follicular cavities in explanted thyroid of 15-day-old rat foetuses. Dibutyryl-cAMP added to the medium, but not sodium fluoride, also stimulates the folliculogenesis. Since fluoride stimulates membrane adenylate cyclase but does not increase the intracellular cAMP level, these results show that cAMP is involved as a second messenger in the activation of foetal thyroid morphogenesis induced by hormones. They indicate also that the thyroid gland of the foetal rat is capable of responding to hormonal stimulation as early as the 15th day of pregnancy; this implies that on day 15, the foetal thyroid possesses receptors not only for the thyroid-stimulating hormone, but also for catecholamines and prostaglandins.     

Flow cytometry of isolated mitochondria during development and under some pathological conditions

Mitochondria play an essential role in the generation of the energy needed for eukaryotic cell life and in the release of molecules involved in initiation of cell death. Here we review the changes in isolated mitochondrial fluorescent populations as distinguished by flow cytometry during postnatal development and their regulation by thyroid hormones and catecholamines. The use of flow cytometry in the study of mitochondrial changes occurring under hypothyroidism, alcohol abuse and aging is also reviewed.     

Pituitary-thyroid axis reaction after myocardial infarction.

Within the first 36 hours following myocardial infarction, serum total thyroxine (T4) levels were supranormal in most cases in contrast to normal thyrotropin values. After one week, T4 levels dropped to normal while TSH values rose significantly. These findings suggest that, in the acute phase of myocardial infarction, the secretion of thyroid hormones is increased, thereby inhibiting the pituitary thyrotropes. The stimulation of thyroid secretion might be due to the high levels of blood catecholamines generally found in patients with myocardial infarction.     

Tyrosine content, influx and accumulation rate, and catecholamine biosynthesis measured in vivo, in the central nervous system and in peripheral organs of the young rat. Influence of neonatal hypo- and hyperthyroidism

The influence of neonatal hypo- and hyperthyroidism on different aspects of tyrosine metabolism in the hypothalamus, striatum, brainstem, adrenal glands, heart and brown adipose tissue (BAT) were studied in 14-day old rats. The synthesis rate of catecholamines (CA) was also determined in vivo after the injection of labelled tyrosine. Hypothyroidism increases tyrosinaemia and endogenous tyrosine concentration in the hypothalamus and BAT. Hyperthyroidism decreases tyrosinaemia and endogenous tyrosine levels in the striatum, adrenals and heart. The accumulation rate of tyrosine determined 30 min after an intravenous injection of the labelled amino acid has been determined in the organs, together with the influx of the amino acid, determined within 20s. Hypothyroidism increases tyrosine accumulation rate in all the organs studied, and tyrosine clearance is decreased in the striatum and brainstem; together with an increased tyrosinaemia, this leads to a normal influx. The influx of tyrosine is increased in the hypothalamus. Hyperthyroidism decreases tyrosine accumulation rate in all the organs except the adrenals. These results indicate that the thyroid status of the young rat can influence tyrosine uptake mechanisms, without modifying an organ's tyrosine content. The fact that hypothyroidism increases tyrosine influx in the hypothalamus without modifying it in the brainstem and striatum reflects an heterogeneous reactivity to the lack of thyroid hormones in different brain structures. Neonatal hypothyroidism decreases the CA synthesis rate in the striatum, the heart and the interscapular brown adipose tissue, while synthesis was enhanced in the brainstem and the adrenals. It is likely that these variations in CA synthesis are due to thyroid hormone modulation of tyrosine hydroxylase activity, the enzyme which catalyses the rate limiting step in CA biosynthesis.     

Analysis of catecholamines and related substances using porous graphitic carbon as separation media in liquid chromatography-tandem mass spectrometry

Capillary porous graphitic carbon (PGC) columns have been utilized for separation of several catecholamines and related compounds (i.e. L-tyrosine, L-DOPA, 3-O-methyl-DOPA, dopamine, 3,4-dihydroxy-phenyl-acetic acid (DOPAC), homovanillic acid, noradrenaline, vanillomandelic acid and adrenaline) on-line with electrospray ionization tandem mass spectrometry (ESI-MS/MS). The use of a mobile phase without ion-pairing agents and with high content of organic modifier facilitated the coupling to the selective and sensitive mass spectrometric detection. Minimum detectable sample concentration (MDC sample) for noradrenaline, dopamine and L-tyrosine in a standard solution was estimated to 3, 10 and 30 nM, respectively (3 S/N corresponds to MDQ for L-tyrosine of approximately 8 x 10(-14)mol). The developed strategy was applied for analysis of brain tissue, i.e. a substantia nigra (ns) sample.