Home About us Contact
|
Home About us Contact | ||
|
|
||
Melatonin Production (melatonin + production)
Selected AbstractsChick Pineal Melatonin SynthesisJOURNAL OF NEUROCHEMISTRY, Issue 6 2000Cyclic AMP Control Abundance of Serotonin N -Acetyltransferase Protein, Light Abstract: Melatonin production in the pineal gland is high at night and low during the day. This rhythm reflects circadian changes in the activity of serotonin N -acetyltransferase [arylalkylamine N -acetyltransferase (AA-NAT); EC 2.3.1.87], the penultimate enzyme in melatonin synthesis. The rhythm is generated by an endogenous circadian clock. In the chick, a clock is located in the pinealocyte, which also contains two phototransduction systems. One controls melatonin production by adjusting the clock and the other acts distal to the clock, via cyclic AMP mechanisms, to switch melatonin synthesis on and off. Unlike the clock in these cells, cyclic AMP does not appear to regulate activity by altering AA-NAT mRNA levels. The major changes in AA-NAT mRNA levels induced by the clock seemed likely (but not certain) to generate comparable changes in AA-NAT protein levels and AA-NAT activity. Cyclic AMP might also regulate AA-NAT activity via changes in protein levels, or it might act via other mechanisms, including posttranslational changes affecting activity. We measured AA-NAT protein levels and enzyme activity in cultured chick pineal cells and found that they correlated well under all conditions. They rose and fell spontaneously with a circadian rhythm. They also rose in response to agents that increase cyclic AMP. They were raised by agents that increase cyclic AMP, such as forskolin, and lowered by agents that decrease cyclic AMP, such as light and norepinephrine. Thus, both the clock and cyclic AMP can control AA-NAT activity by altering the total amount of AA-NAT protein. Effects of proteosomal proteolysis inhibitors suggest that changes in AA-NAT protein levels, in turn, reflect changes in the rate at which the protein is destroyed by proteosomal proteolysis. It is likely that cyclic AMP-induced changes in AA-NAT protein levels mediate rapid changes in chick pineal AA-NAT activity. Our results indicate that light can rapidly regulate the abundance of a specific protein (AA-NAT) within a photoreceptive cell. [source] The relationship between melatonin and cortisol rhythms: clinical implications of melatonin therapyDRUG DEVELOPMENT RESEARCH, Issue 3 2005N. Zisapel Abstract Disturbances in circadian rhythm have been linked to chronic diseases such as insomnia, hypertension, diabetes, and depression. Here we review recent studies on the age-related changes in cortisol and melatonin rhythms and then present descriptive statistics on our preliminary findings on the rectification of the cortisol rhythms by melatonin therapy in elderly patients with insomnia. In adults, the melatonin onset typically occurs during low cortisol secretion. Administration of exogenous melatonin around dusk will shift the phase of the human circadian clock to earlier hours (advance phase shift) leading to phase advances in circadian rhythms (e.g., sleep, endogenous melatonin, cortisol). With aging, the production of melatonin declines and is shifted to later hours while the production of cortisol increases and its peak occurs earlier in the night. In a randomized placebo-controlled crossover study with 8 patients with insomnia aged 55 years and older, a group characterized by low and delayed melatonin production, administration of prolonged-release melatonin in the evening was able to rectify the early onset cortisol production. This delay in nocturnal cortisol onset may explain in part the improvement in sleep quality in elderly patients with insomnia, in schizophrenics, and in depressed patients. Support of circadian pacemaker function by melatonin may provide a new strategy in the treatment of disorders related to impairments in the internal temporal order. The clinical benefit from a decrease in cortisol during the early part of the night may lie beyond the improvement of sleep into a better control of blood pressure, metabolism, and mood. Drug Dev. Res. 65:119,125, 2005. © 2005 Wiley-Liss, Inc. [source] Analysis of cell signalling in the rodent pineal gland deciphers regulators of dynamic transcription in neural/endocrine cells,EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 1 2001Jörg H. Stehle Abstract In neurons, a temporally restricted expression of cAMP-inducible genes is part of many developmental and adaptive processes. To understand such dynamics, the neuroendocrine rodent pineal gland provides an excellent model system as it has a clearly defined input, the neurotransmitter norepinephrine, and a measurable output, the hormone melatonin. In this system, a regulatory scenario has been deciphered, wherein cAMP-inducible genes are rapidly activated via the transcription factor phosphoCREB to induce transcriptional events necessary for an increase in hormone synthesis. However, among the activated genes is also the inhibitory transcription factor ICER. The increasing amount in ICER protein leads ultimately to the termination of mRNA accumulation of cAMP-inducible genes, including the gene for the Aa-nat that controls melatonin production. This shift in ratio of phosphoCREB and ICER levels that depends on the duration of stimulation can be interpreted as a self-restriction of cellular responses in neurons and has also been demonstrated to interfere with cellular plasticity in many non-neuronal systems. [source] Chick Pineal Melatonin SynthesisJOURNAL OF NEUROCHEMISTRY, Issue 6 2000Cyclic AMP Control Abundance of Serotonin N -Acetyltransferase Protein, Light Abstract: Melatonin production in the pineal gland is high at night and low during the day. This rhythm reflects circadian changes in the activity of serotonin N -acetyltransferase [arylalkylamine N -acetyltransferase (AA-NAT); EC 2.3.1.87], the penultimate enzyme in melatonin synthesis. The rhythm is generated by an endogenous circadian clock. In the chick, a clock is located in the pinealocyte, which also contains two phototransduction systems. One controls melatonin production by adjusting the clock and the other acts distal to the clock, via cyclic AMP mechanisms, to switch melatonin synthesis on and off. Unlike the clock in these cells, cyclic AMP does not appear to regulate activity by altering AA-NAT mRNA levels. The major changes in AA-NAT mRNA levels induced by the clock seemed likely (but not certain) to generate comparable changes in AA-NAT protein levels and AA-NAT activity. Cyclic AMP might also regulate AA-NAT activity via changes in protein levels, or it might act via other mechanisms, including posttranslational changes affecting activity. We measured AA-NAT protein levels and enzyme activity in cultured chick pineal cells and found that they correlated well under all conditions. They rose and fell spontaneously with a circadian rhythm. They also rose in response to agents that increase cyclic AMP. They were raised by agents that increase cyclic AMP, such as forskolin, and lowered by agents that decrease cyclic AMP, such as light and norepinephrine. Thus, both the clock and cyclic AMP can control AA-NAT activity by altering the total amount of AA-NAT protein. Effects of proteosomal proteolysis inhibitors suggest that changes in AA-NAT protein levels, in turn, reflect changes in the rate at which the protein is destroyed by proteosomal proteolysis. It is likely that cyclic AMP-induced changes in AA-NAT protein levels mediate rapid changes in chick pineal AA-NAT activity. Our results indicate that light can rapidly regulate the abundance of a specific protein (AA-NAT) within a photoreceptive cell. [source] Local Corticosterone Infusion Enhances Nocturnal Pineal Melatonin Production In VivoJOURNAL OF NEUROENDOCRINOLOGY, Issue 2 2009P. A. C. M. Fernandes Melatonin, an important marker of the endogenous rhythmicity in mammals, also plays a role in the body defence against pathogens and injuries. In vitro experiments have shown that either pro- or anti-inflammatory agents, acting directly in the organ, are able to change noradrenaline-induced pineal indoleamine production. Whereas corticosterone potentiates melatonin production, incubation of the gland with tumour necrosis factor-, decreases pineal hormonal production. In the present study, we show that nocturnal melatonin production measured by intra-pineal microdialysis is enhanced in pineals perfused with corticosterone at concentrations similar to those measured in inflamed animals. In vitro experiments suggest that this enhancement may be due to an increase in the activity of the two enzymes that convert serotonin to N -acetylserotonin (NAS) and NAS to melatonin. The present results support the hypothesis that the pineal gland is a sensor of inflammation mediators and that it plays a central role in the control of the inflammatory response. [source] Activation of Arylalkylamine N -Acetyltransferase by Phorbol Esters in Bovine Pinealocytes Suggests a Novel Regulatory Pathway in Melatonin SynthesisJOURNAL OF NEUROENDOCRINOLOGY, Issue 9 2004C. Schomerus Abstract In all mammalian species investigated, noradrenaline activates a ,-adrenoceptor/cAMP/protein kinase A-dependent mechanism to switch on arylalkylamine N -acetyltransferase and melatonin biosynthesis in the pineal gland. Other compounds which are known to influence the melatonin-generating system are phorbol esters. The effect of phorbol esters on regulation of melatonin synthesis has been mainly investigated in rat pinealocytes. In these cells, phorbol esters do not increase cAMP levels and arylalkylamine N -acetyltransferase on their own; however, phorbol esters potentiate the effects on cAMP and AANAT activity induced upon ,-adrenoceptor stimulation. In the present study, we investigated the effect of phorbol esters on the regulation of melatonin synthesis in bovine pinealocytes. We show that, in these cells, the phorbol esters 4,-phorbol 12-myristate 13-acetate (PMA) or phorbol 12,13-dibutyrate have a direct stimulatory effect and induced 4,10-fold increases in AANAT protein levels, AANAT activity and melatonin production. The extent of these effects was similar to those induced by noradrenaline. Notably, responses to PMA were not accompanied by increases in cAMP levels. Northern blot analysis showed that Aanat mRNA levels did not change upon PMA treatment indicating that phorbol esters control AANAT at a post-transcriptional level. The effects on AANAT and melatonin production were reduced by use of protein kinase C inhibitors, but not by blockade of the cyclic AMP/protein kinase A pathway. Our results point towards a novel mechanism in the regulation of melatonin production that is cAMP-independent and involves protein kinase C. The study is of particular interest because regulation of melatonin biosynthesis in bovines may resemble that in primates more closely than that in rodents. [source] Evidence of immune system melatonin production by two pineal melatonin deficient mice, C57BL/6 and Swiss strainsJOURNAL OF PINEAL RESEARCH, Issue 1 2009Araceli Gómez-Corvera Abstract:, We evaluated two pineal melatonin deficient mice described in the literature, i.e., C57BL/6 and Swiss mice, as animal models for studying the immunomodulatory action of melatonin. Plasma melatonin levels in C57BL/6 and Swiss strains were detectable, but lower than levels in control C3H/HENHSD mice. Since these strains are suppose to be pineal melatonin deficient an extrapineal melatonin synthesis may contribute to plasma levels. Regarding cells and tissues from the immune system, all of them were found to synthesize melatonin although at low levels. N-acetyltransferase (AANAT) mRNA was also amplified in order to analyze the alternative splicing between exons 3,4 described for pineal C57BL/6 mice which generates an inclusion of a pseudoexon of 102 bp. For the pineal gland, both the wild type and the mutant isoforms were present in all mice strains although in different proportions. We observed a predominant wild type AANAT mature RNA in thymus, spleen and bone marrow cells. Peripheral blood mononuclear cells (PBMC) culture shown an evident AANAT amplification in all strains studied. Although the bands detected were less intense in melatonin deficient mice, the amplification almost reached the control cell intensity after stimulation with phytohemaglutinin (PHA). In summary, melatonin detection and AANAT mRNA expression in inbred and outbred mice clearly indicate that different cells and tissues from the immune system are able to synthesize melatonin. Thus, the pineal defect seems not to be generalized to all tissues, suggesting that other cells may compensate the low pineal melatonin production contributing to the measurable plasma melatonin level. [source] Seasonality of psychopathology and circannual melatonin rhythmJOURNAL OF PINEAL RESEARCH, Issue 3 2006A.L. Morera Abstract:, The association of seasonal changes in health and disease has been known for centuries. The prevalence of psychopathological symptoms with seasonal fluctuations and the use of melatonin as a biological marker of circadian and circannual rhythms is well documented. The aim of this work was to study the variability of melatonin secretion between summer and winter in our geographical area (28°N, 16°W) and relate the changes to the level of psychopathology. Ten drug-free, nonsmoker, healthy subjects were studied in summer (August) and winter (December). Blood samples for melatonin assays were collected every hour at night for 5 hr, from 22:00 to 02:00 hr, and next day at noon. Melatonin was assayed by an ELISA technique. Psychopathology was evaluated by means of the 28-item version of the General Health Questionnaire (GHQ-28). All subjects had a circadian rhythm of melatonin secretion in summer and winter. There was a seasonal rhythm with melatonin levels being significantly higher at night in winter than in summer. Melatonin levels at 22:00, 23:00, 24:00 and 01:00 hr and mean melatonin area under the curve (AUC) were significantly higher in winter than in summer. Melatonin AUC increased 80% in winter compared with summer. The GHQ-28 somatic and anxiety subscales and the total GHQ-28 score were significantly higher in winter than summer. Psychopathology scores were significantly and negatively correlated with melatonin production in summer and winter. Our data strongly suggest that melatonin production and psychopathology levels present seasonal fluctuations and these variations should be taken into account when conducting research in this field. [source] Gender-related differences in urinary 6-sulfatoxymelatonin levels in obese pubertal individualsJOURNAL OF PINEAL RESEARCH, Issue 3 2006Hugo L. Fideleff Abstract:, The objective of this study was to measure the urinary excretion of the main melatonin metabolite 6-sulfatoxymelatonin in obese and normal weight (wt) boys and girls. The study included 94 subjects, aged 4,15.7 yr (50 obese and 44 normal wt; 48 boys) classified as: mid-childhood (4,7.99 yr), late-childhood (8,12 yr) and pubertal (10.1,15.7 yr, Tanner II,IV). Normal wt subjects were children with a body mass index (BMI) between the 25th and 75th percentiles, and the group of obese subjects included children whose BMI was above the 97th percentile. A 24-hr urine sample was collected during two intervals: (i) 18:00,08:00 hr, and (ii) 08:00,18:00 hr. Analysis of urinary 6-sulfatoxymelatonin levels was performed by radioimmunoassay. Excretion of 6-sulfatoxymelatonin was expressed as: (i) total amount excreted (,g); (ii) ,g excreted per time interval, nocturnal or diurnal; and (iii) the difference between nocturnal and diurnal samples (,g, estimated amplitude). A factorial analysis of variance indicated that nocturnal 6-sulfatoxymelatonin excretion and amplitude were significantly higher in the obese individuals. A significant interaction ,BMI × age' was detected, i.e. the effect of BMI was significant in the pubertal group only. Total, nocturnal and diurnal 6-sulfatoxymelatonin excretion was significantly higher in girls. The increase in 6-sulfatoxymelatonin excretion found in obesity occurred only in boys and at the pubertal age. To what extent this increase in melatonin production contributes to a delayed puberty in some pubertal obese males remains to be established. [source] Suppression of melatonin biosynthesis in the chicken pineal gland by retinally perceived light , involvement of D1-dopamine receptorsJOURNAL OF PINEAL RESEARCH, Issue 2 2004Jolanta B. Zawilska Abstract:, In this study the role of retinal dopamine (DA) receptors in the light-induced suppression of melatonin biosynthesis in the chicken pineal gland was examined. Exposure of dark-adapted chickens to low intensity light (4 lux) at night significantly decreased the activity of serotonin N-acetyltransferase (AA-NAT; the penultimate and key regulatory enzyme in melatonin production) and melatonin content in the pineal gland. This suppressive action of light was blocked by intraocular (i.oc.) administration of SCH 23390 (a selective antagonist of D1-DA receptors), but was not affected by sulpiride (a selective antagonist of D2-DA receptors). Injection of DA (i.oc.) to dark-adapted chickens significantly decreased pineal AA-NAT activity and melatonin content in a dose- and time-dependent manner. The action of DA was mimicked by selective agonists of D1-DA receptors, SKF 38393 and SKF 81297, and non-hydrolyzable analogs of cyclic AMP (cAMP), dibutyryl-cAMP and 8-bromo-cAMP. However, i.oc. administration of quinpirole, a selective agonist of D2-DA receptors, did not modify pineal AA-NAT activity. In contrast, quinpirole potently decreased nocturnal AA-NAT activity in the retina. Systemic administration of SCH 23390 to chickens blocked the i.oc. DA-evoked decline in nighttime pineal AA-NAT activity, whereas sulpiride was ineffective. These findings indicate that light activation of retinal dopaminergic neurotransmission, with concomitant stimulation of D1-DA receptors positively coupled to the cAMP generating system, plays an important role in a cascade of events regulating pineal activity. [source] How important is stimulation of ,-adrenoceptors for melatonin production in rat pineal glands?JOURNAL OF PINEAL RESEARCH, Issue 4 2002V. A. Tobin The objective of this study was to determine the role of , -adrenoceptors in melatonin production by rat pineal gland. Pineal glands were isolated from adult male rats and maintained in organ baths. The perfusate was sampled every 5 min, stored, and later assayed for melatonin. Exposure to norepinephrine (10 ,M) or the , -adrenoceptor agonist orciprenaline (2,10 ,M) increased the glands' production of melatonin. The time courses of melatonin production in response to these agonists were unaffected by the rats' pretreatment in vivo with the , -adrenoceptor antagonist prazosin (2 mg/kg i.p., three times). Rats that had had their superior cervical ganglia removed were primed with either orciprenaline (2 mg/kg i.p) or both orciprenaline and phenylephrine (1 mg/kg i.p) 1 hr before decapitation. Exposure of the pineal glands from these rats to orciprenaline evoked melatonin release that was similar in each group. These results lend weight to the suggestion that the marked potentiation by , -adrenoceptor agonists of the stimulation of cAMP and N-acetyltransferase (NAT) by , -adrenoceptor agonists, demonstrated most readily in cultured glands or dispersed rat pinealocytes, does not carry over into significant augmentation of melatonin production in intact pineal glands. [source] Effect of propranolol plus exercise on melatonin and growth hormone levels in children with growth delayJOURNAL OF PINEAL RESEARCH, Issue 2 2001A. Muñoz-Hoyos The pineal gland in humans is under both ,- and ,-adrenergic control, although it seems that ,1 -adrenoceptors are mainly implicated in melatonin secretion. In the present study, we evaluated the role of ,-adrenergic innervation on melatonin production and its relation with the production of growth hormone (GH). Thirty-four children (15 males and 19 females, mean age 10.5±0.8 years) from the University of Granada Hospital were studied. The children were included in a protocol for the evaluation of growth delay using the propranolol+exercise test. This standardized test allowed us to study simultaneously the role of an unspecific ,-adrenergic blocker such as propranolol and of an adrenergic stimulus such as exercise on the pineal production of melatonin. Changes in plasma levels of melatonin and GH were determined at basal, 120 and 140 min after the test was applied. Hormonal determinations were carried out by commercial radioimmunoassay kits previously standardized in our laboratory. The results show a significant decrease in plasma melatonin levels at 120 and 140 min after the test (P<0.05), whereas GH levels increased significantly at 140 min (P<0.001). The decrease of melatonin levels was a consequence of the test, since in a control group, the circadian decay of melatonin was significantly less pronounced (P<0.05). These data suggest an inverse relationship between melatonin and GH after the propranolol+exercise test, and the reduction in melatonin may be related to its depletion by exercise-induced oxidative stress. [source] Melatonin disrupts circadian rhythms of glutamate and GABA in the neostriatum of the awake rat: a microdialysis studyJOURNAL OF PINEAL RESEARCH, Issue 4 2000B. Marquez de Prado The purpose of this study was to investigate possible circadian changes in extracellular concentrations of glutamate (GLU) and ,-aminobutyric acid (GABA), and the influence of melatonin on the levels of these neurotransmitters in the neostriatum of awake rats using in vivo microdialysis. At the same time, the concentrations of the amino acids taurine (TAU), glutamine (GLN) and arginine (ARG), as well as dopamine (DA) and its metabolites 3, 4-dihydroxyphenyl acetic acid (DOPAC) and homovanillic acid (HVA), were measured in the extracellular fluid. When dialysates were collected over a 24-hr period (6 hr dark, 12 hr light, 6 hr dark), both GLU and GABA, without the infusion of melatonin, exhibited statistically significant rhythms, with higher levels of these constituents during the dark and lower levels during the day. Perfusion with melatonin (for 19 consecutive hours) prevented the daytime reductions in both GLU and GABA. Of the amino acids measured in the dialysates collected from the neostriatum of non-perfused rats, only ARG exhibited a significant change during the light:dark cycle; again, lowest concentrations were measured during the day. While melatonin perfusion did not statistically significantly influence neostriatal levels of TAU and ARG, GLN levels continued to drop during the infusion of the indoleamine. Dialysate concentrations of DA, DOPAC and HVA exhibited circadian rhythms which were not influenced by melatonin perfusion. The findings indicate there are differential effects of melatonin on extracellular neurotransmitter concentrations in the neostriatum of the awake rat. The results also suggest that the day:night variations in GLU and GABA may relate to daily changes in endogenous melatonin production, while DA and its metabolites are minimally influenced by this secretory product. [source] Effect of stimulation of endogenous melatonin secretion during constant light exposure on 6-sulphatoxymelatonin rhythmicity in ratsJOURNAL OF PINEAL RESEARCH, Issue 1 2000D.J. Kennaway When light is presented unexpectedly at night to rats, melatonin production and secretion is acutely inhibited and the time of onset of production on the subsequent night is altered. In a series of experiments, we examined the effects of 6,12 hr light (200 lux) at night on melatonin metabolite excretion (6-sulphatoxymelatonin, aMT.6S). During the light exposure, we administered isoproterenol to stimulate endogenous production of melatonin by the pineal gland to determine if replacement of melatonin would block any phase shifting effects of the light. Exposure to 6 hr of light either during the first or second half of the night suppressed aMT.6S excretion during the light treatment and delayed the onset of melatonin secretion by 3.7±0.6 and 2.5±0.6 hr, respectively, compared to a change of 0.5±0.1 hr in animals maintained in darkness. Twelve hours light exposure (i.e. one night of continuous light) suppressed aMT.6S excretion completely and resulted in a delay in the onset the next night of 2.1±0.7 hr. When propranolol (10 mg/kg) was administered at 2-hr intervals during darkness, aMT.6S excretion was suppressed throughout the night, but on the subsequent release into constant darkness the onset of excretion was not delayed (0.6±0.1 hr delay). Administration of isoproterenol (10 mg/kg) to animals in constant light, at the time of expected lights off (CT12), and 5 hr later (CT17) resulted in an increase in melatonin production and aMT.6S excretion that was similar in duration and amount to the control night. The stimulation of endogenous melatonin production failed to block the phase shifting effects of the light exposure and, in fact, appeared to potentiate the delay at least on the first night (4.2±0.9 hr). The timing of the release into constant darkness following the light treatment had an unexpected effect on melatonin production on the cycle after treatment. Thus, animals exposed to 12 hr light and released into darkness at the normal time of lights off as above had a delay of about 2 hr and excreted 71±18% of the aMT.6S excreted on a control night. Animals released into darkness at the expected time of lights on failed to excrete more than 20 pmol/hr (i.e. no onset of excretion could be determined) at any time on the first subjective night after light treatment, which was no different from the excretion during the light treatment. On the next subjective night, the onset was delayed as expected and the amount of aMT.6S produced was restored. Treatment with isoproterenol at CT12 and CT17 failed to affect either the amount of aMT.6S excreted on the first subjective night after light treatment or the phase delay on the second night after treatment. The failure to produce melatonin on the first subjective night after 12 hr light exposure and release into darkness at CTO was not due to failure at the level of the pineal gland since injection of isoproterenol at CT12 and CT17 on the first subjective night after light restored the normal amount of melatonin production. These results suggest that the absence of melatonin during light stimulation at night is not responsible for the phase delay in melatonin production and excretion on subsequent nights. The basis of the failure of the rats to commence melatonin production following 12 hr extended light exposure followed immediately by continuous darkness is not known. [source] | |||||||||||||