Stimulatory effects of LH on release of melatonin and activities of its synthesizing enzymes NAT and HIOMT in organ-cultured pineal glands of female rats.

The pineal hormone melatonin (N-acetyl-5-methoxytryptamine) exerts antigonadotropic effects in some mammalian species. To evaluate the effect of luteinizing hormone (LH) on melatonin release and its synthesizing enzyme activities in pineal glands, pineals of adult female rats undergoing diestrus were organ-cultured in a medium containing 10(-12), 10(-10) or 10(-8) M LH for 6 h. Melatonin release increased significantly in pineals cultured with 10(-12) and 10(-10) M LH, as compared to control values. Similarly, the activity of arylalkylamine N-acetyltransferase (NAT), the key regulatory enzyme in melatonin biosynthesis, was significantly higher in pineals cultured with 10(-12) and 10(-10) M LH for 6 h, while LH at 10(-8) M had no effect. Although LH at 10(-10) M increased pineal hydroxyindole-O-methyltransferase (HIOMT) activity, which catalyzes the final step of melatonin biosynthesis, LH at 10(-12) and 10(-8) M had no effect. These results demonstrate that at relatively low physiological levels, LH stimulates pineal melatonin synthesis and release, mainly by increasing NAT activity.     

Retinally perceived light is not essential for photic regulation of pineal melatonin rhythms in the pigeon: studies with microdialysis

Using in vivo microdialysis, effects of retinally perceived light on pineal melatonin release and its rhythmicity was examined in the pigeon. In the first experiment, light-induced suppression of pineal melatonin release was studied. Although light given to the whole body during the dark strongly suppressed pineal melatonin release to a daytime level, light exclusively delivered to the eyes did not remarkably inhibit melatonin release. In the second experiment, in order to determine whether retinally perceived light has phase-shifting effects on pineal melatonin rhythms, pigeons were given a single light pulse of 2 h at circadian time (CT) 18 and the phases of the second cycle after the light pulse were compared with those of control pigeons without the light pulse. In this experiment, phase advances of pineal melatonin rhythms were observed when the light was given to the whole body but not when only the eyes were illuminated. In a third experiment, after entrainment to light-dark 12:12 (LD 12:12) cycles, birds whose heads were covered with black tapes were transferred into constant light (LL) conditions and only the eyes were exposed to new LD cycles for 7 days (the phase was advanced by 6 h from the previous cycles) using a patching protocol. This procedure, however, could not entrain pineal melatonin rhythms to the retinal LD cycles. These results indicate that the eyes are not essential for photic regulation of pineal melatonin release and its rhythmicity in the pigeon.Abbreviations CT circadian time - LD light-dark - LL constant light - SCN suprachiasmatic nucleus - LLdim constant dim light - NE norepinephrine - SCG superior cervical ganglia - WB whole body - E eye - EX extraretina - C control     

DHEA-sulfate causes a phase-dependent increase in melatonin secretion: a study of perifused rat pineal glands

Steroid hormones affect various metabolic activities, including melatonin synthesis, in mammals and nonmammals. We report here the effects of dehydroepiandrosterone (DHEA) and DHEA-sulfate (DHEA-S), two steroids with weak androgen potency, on the levels of isoproterenol-stimulated melatonin released by perifused rat pineal glands removed in the middle of the light and dark spans [7 and 19 Hours After Light Onset (HALO), respectively] in a L/D 12:12 regimen. DHEA-S but not DHEA was found to have a direct action on beta-adrenergic-stimulated melatonin release. DHEA-S increased melatonin secretion (by 50-80%) dose-dependently in pineals obtained during the light span. This effect depended on the circadian stage, because at night (19 HALO), only the highest concentration (10(-3) M) of DHEA-S increased melatonin secretion (by 25%). In contrast, DHEA had no effect on melatonin release in pineals obtained during the light span. This work shows that DHEA-S but not DHEA was able to stimulate melatonin secretion by adrenergic-stimulated pineals removed during the light phase. It also suggests that the effects observed, or their intensity, or both depend on the circadian stage.     

Gonadotropin-releasing hormone increases melatonin release in the pineal gland of the female rat in vitro.

To evaluate the effect of gonadotropin-releasing hormone (GnRH) on melatonin ( N-acetyl-5-methoxytryptamine) release and its synthesizing enzyme activities in pineal glands, pineals from adult female rats during diestrus were organ-cultured in a medium containing 10 -12, 10 -10, or 10 -8 M GnRH for 6 h. Melatonin release increased significantly in pineals cultured with 10 -10 and 10 -8 M GnRH compared to controls. However, in pineal glands that were organ-cultured in a medium containing 10 -12 to 10 -8 M GnRH, the activity of arylalkylamine N-acetyltransferase, which is the key regulatory enzyme in melatonin biosynthesis, showed no significant difference from controls. Likewise, GnRH at these concentrations had no significant effect on the activity of pineal hydroxyindole- O-methyltransferase, which catalyzes the final step of melatonin biosynthesis. These results show that GnRH stimulates pineal melatonin release, but suggest that GnRH does not affect its melatonin synthesis.     

Lack of effect of ghrelin treatment on melatonin production in rat pineal and Harderian glands

The effects of ghrelin, a peptide hormone secreted from the stomach, on melatonin remain unknown. The aim of the study was to investigate possible ghrelin-melatonin interactions by studying the effect of ghrelin treatment on melatonin production in rat pineal and Harderian glands. Young (9 weeks) and old (20 months) male Wistar rats, maintained under a light:dark cycle regimen of 12:12, were assigned randomly to either a single subcutaneous (s.c.) injection of saline or ghrelin (1 microg/rat or 15 microg/rat) 1 h before sacrifice in the middle of the dark phase, or repeated s.c. saline or ghrelin injections (15 microg/rat), 3, 2 and 1 h before sacrificed in the middle of the dark phase. Neither ghrelin doses (1 microg/rat or 15 microg/rat) nor type of treatment (acute or repeated) influenced melatonin levels or the melatonin synthesizing enzymes N-acetyltransferase and hydroxyindole-O-methyltransferase activities, either in pineal gland or in Harderian glands. At the concentrations used, ghrelin does not influence melatonin production in rat pineal and Harderian glands, and therefore is not involved in the regulation of melatonin secretion, at least under our experimental conditions.     

The profile of melatonin production in tumour-bearing rats

The pineal gland is involved in the regulation of tumour growth through the anticancer activity of melatonin, which presents immunomodulatory, anti-proliferative and anti-oxidant effects. In this study we measured melatonin content directly in the pineal gland, in an attempt to clarify the modulation of pineal melatonin secretory activity during tumour growth. Different groups of Walker 256 carcinosarcoma bearing rats were sacrificed at 12 different time points during 24h (12h:12h light/dark cycle) on different days during the tumour development (on the first, seventh and fourteenth day after tumour inoculation). Melatonin content in the pineal gland was determined by high-performance liquid chromatography with electrochemical detection. During tumour development the amount of melatonin secreted increased from 310.9 ng/mg of protein per day from control animals, to 918.1 ng/mg of protein per day 14 days after tumour implantation, and there were changes in the pineal production profile of melatonin. Cultured pineal glands obtained from tumour-bearing rats turned out to be less responsive to noradrenaline, suggesting the existence, in vivo, of putative factor(s) modulating pineal melatonin production. The results demonstrated that during tumour development there is a modification of pineal melatonin production daily profile, possibly contributing to cachexia, associated to changes in pineal gland response to noradrenaline stimulation.     

Daily profiles of plasma prolactin (PRL), growth hormone (GH), insulin-like growth factor-1 (IGF-1), luteinizing hormone (LH), testosterone, and melatonin, and of pituitary PRL mRNA and GH mRNA in male Long Evans rats in acute phase of adjuvant arthritis

We studied the effects of adjuvant arthritis (AA) on the endocrine circadian rhythms of plasma prolactin (PRL), growth hormone (GH), insulin-like growth factor-1 (IGF-1), luteinizing hormone (LH), testosterone, and melatonin and of pituitary PRL and GH mRNA in male Long Evans rats. Groups of control and AA rats (studied 23 days after AA induction) that were housed under a 12/12 h light/dark cycle (light on at 06:00 h) were killed at 4 h intervals starting at 14:00 h. Cosinor analysis revealed a significant 12 h rhythm in PRL and PRL mRNA (p < 0.001) in controls with peaks at 14:00 h and 02:00 h, respectively. The peak at 02:00 h was abolished in the AA group resulting in a significant 24 h rhythm in parallel with that of PRL (p < 0.05) and PRL mRNA (p < 0.0001). Growth hormone showed no rhythm, but a significant rhythm of GH mRNA was present in both groups (p < 0.0001). Insulin-like growth factor-1 showed a 24 h rhythm in control but not in AA rats. The mean values of GH, GH mRNA, and IGF-1 were significantly reduced in AA. Luteinizing hormone displayed a significant 24 h rhythm (p < 0.01) peaking in the dark period in the control but not AA group. Testosterone showed in phase temporal changes of LH levels with AA abolishing the 02:00 h peak. Melatonin exhibited a significant 24 h rhythm in control (p < 0.001) and AA (p < 0.01) rats with maximum levels during the dark phase; the mesor value was higher in the AA males. These results demonstrate that AA interferes with the rhythms of all the studied hormones except the non-24 h (arrhythmic) GH secretion pattern and the rhythm in melatonin. The persistence of a distinct melatonin rhythm in AA suggests the observed disturbances of hormonal rhythms in this condition do not occur at the level of the pineal gland.     

The ageing pineal gland and its physiological consequences.

Melatonin, the chief hormone of the pineal gland, is produced and secreted into the blood in a circadian manner with maximal production always occurring during the dark phase of the light:dark cycle. Whereas the 24h rhythm of melatonin production is very robust in young animals including humans, the cycle deteriorates during ageing. The rhythm of melatonin can be substantially preserved during ageing by restricting the food intake of experimental animals; this same treatment increases the life span of the animals. The exogenous administration of melatonin to non-food restricted animals also reportedly increases their survival. Moreover, melatonin has been shown to have immunoenhancing effects and oncostatic properties. The implication of these studies is that melatonin may have both direct and indirect beneficial effects in delaying ageing processes or it may retard the development of processes (e.g., immunodeficiency and tumor growth) which contribute to a reduced life span.     

Regulation by Light and Darkness of Melatonin Secretion from the Superfused Masu Salmon (Oncorhynchus masou) Pineal Organ

The pineal organ of masu salmon Oncorhynchus masou was maintained in a flow-through, whole-organ culture (superfusion) system and melatonin secretory profiles were determined at 15 °C under light-dark cycles of 12:12 h (LD 12:12) or the same in combination with constant darkness (DD) for 72 h. Under LD 12:12, superfused pineal organs showed a rhythmic melatonin secretion with high and low rates during the dark phase and the light phase, respectively. When the pineal organs maintained under LD 12:12 for 24 h were transferred to DD, melatonin secretion was consistently activated and no endogenous component was evident. When the pineal organs maintained under DD for 48 h were transferred to LD 12:12, melatonin secretion was reduced only during the light phase. These results indicate that melatonin secretion from the superfused pineal organ of masu salmon is regulated not by an intra-pineal circadian oscillator but by the environmental LD cycles, via local photoreceptors.     

Neuroendocrine effects of light

The light/dark cycle to which animals, and possibly humans, are exposed has a major impact on their physiology. The mechanisms whereby specific tissues respond to the light/dark cycle involve the pineal hormone melatonin. The pineal gland, an end organ of the visual system in mammals, produces the hormone melatonin only at night, at which time it is released into the blood. The duration of elevated nightly melatonin provides every tissue with information about the time of day and time of year (in animals that are kept under naturally changing photoperiods). Besides its release in a circadian mode, melatonin is also discharged in a pulsatile manner; the physiological significance, if any, of pulsatile melatonin release remains unknown. The exposure of animals including man to light at night rapidly depresses pineal melatonin synthesis and, therefore, blood melatonin levels drop precipitously. The brightness of light at night required to depress melatonin production is highly species specific. In general, the pineal gland of nocturnally active mammals, which possess rod-dominated retinas, is more sensitive to inhibition by light than is the pineal gland of diurnally active animals (with cone-dominated retinas). Because of the ability of the light/dark cycle to determine melatonin production, the photoperiod is capable of influencing the function of a variety of endocrine and non-endocrine organs. Indeed, melatonin is a ubiquitously acting pineal hormone with its effects on the neuroendocrine system having been most thoroughly investigated. Thus, in nonhuman photoperiodic mammals melatonin regulates seasonal reproduction; in humans also, the indole has been implicated in the control of reproductive physiology.Summary of a Plenary Lecture presented by the author in Vienna, August, 1990     

Regulation by Light and Darkness of Melatonin Secretion from the Superfused Masu Salmon (Oncorhynchus masou) Pineal Organ

The pineal organ of masu salmon Oncorhynchus masou was maintained in a flow-through, whole-organ culture (superfusion) system and melatonin secretory profiles were determined at 15 °C under light-dark cycles of 12:12 h (LD 12:12) or the same in combination with constant darkness (DD) for 72 h. Under LD 12:12, superfused pineal organs showed a rhythmic melatonin secretion with high and low rates during the dark phase and the light phase, respectively. When the pineal organs maintained under LD 12:12 for 24 h were transferred to DD, melatonin secretion was consistently activated and no endogenous component was evident. When the pineal organs maintained under DD for 48 h were transferred to LD 12:12, melatonin secretion was reduced only during the light phase. These results indicate that melatonin secretion from the superfused pineal organ of masu salmon is regulated not by an intra-pineal circadian oscillator but by the environmental LD cycles, via local photoreceptors.     

Impact of photoperiodic exposures during late gestation and lactation periods on the pineal and reproductive physiology of the Indian palm squirrel, Funambulus pennanti

Studies on the maternal transfer of photoperiodic information in mammals indicate that the daily photoperiod perceived by the mother during the gestation-lactation period is communicated to the fetus either through the placenta or via the milk. However, the impact of photoperiodic exposures during gestation and lactation on the maternal pineal and reproductive physiology has not been reported for any tropical rodent. The exposure of pregnant female Indian palm squirrels (Funambulus pennanti) to constant light (24 h light:0 h dark), constant dark (0 h light:24 h dark), long daylength (14 h light:10 h dark) or short daylength (10 h light:14 h dark) during early gestation (< 30 days) resulted in the resorption of pregnancy, while during late gestation (> 30 days), it did not interfere with the maintenance of pregnancy. Alterations in photoperiodic condition during late gestation and lactation altered the postpartum recovery process. Pineal gland activity, as assessed by pineal mass, protein content and plasma melatonin, was lowest during the breeding phase, but increased gradually after parturition until the next breeding phase. During gestation and lactation, constant light, long daylength and short daylength conditions were less effective, while constant dark condition had a profound effect in depressing pineal gland activity, which subsequently advanced postpartum recovery. Hence, lactating females under constant darkness prepare themselves for next mating much earlier than females under natural daylength (12 h light:12 h dark) conditions. Therefore, photoperiodic information, mediated via the pineal gland, may be important for maintaining gestation physiology as well as postpartum recovery in female rodents.     

Pineal melatonin: circadian rhythm and variations during the hibernation cycle in the ground squirrel, Spermophilus lateralis

Variations in pineal melatonin content throughout a 24-hour period and during different phases of the hibernation bout cycle were studied in the golden-mantled ground squirrel (Spermophilus lateralis). In addition to pineal melatonin, the circadian variation in the activities of pineal N-acetyltransferase (NAT) and hydroxyindole-O-methyltransferase (HIOMT) were also investigated in summer animals maintained at 22 +/- 2 degrees C, on a light:dark (L:D) schedule of 12:12 hr for 1 month (lights on at 08.00 hr). Pineal glands were collected from six animals in each group at 1200, 1600, 2000, 2400, 0200, 0400, and 0800 hr. Changes in pineal melatonin content during the hibernation bout cycle were investigated in ground squirrels housed at 4 +/- .05 degrees C in relative darkness (1.9-3.4 lux; 10:14 LD). Pineal glands were obtained between 12:00 and 18:00 hr from 30 animals during one of three phases of the cycle (deep hibernation, euthermic interbout, and entrance into hibernation). Pineal melatonin was also measured for comparison in six winter euthermic animals that were housed at 22 +/- 2 degrees C, on a L:D schedule of 10:14 hr. Melatonin was measured in individual pineal glands by radioimmunoassay. The daily melatonin rhythm in S. lateralis was characterized by a marked increase in pineal melatonin during the dark phase, in which peak nighttime values were nearly 20-fold greater than daytime basal levels. The daily rhythm for NAT activity paralleled the changes in melatonin, showing a peak activity at 0200 hr that was 45 times greater than mean daytime values.(ABSTRACT TRUNCATED AT 250 WORDS)     

Negative correlation of age and the levels of pineal melatonin, pineal N-acetylserotonin, and serum melatonin in male rats

Pineal concentrations of N-acetylserotonin and melatonin and serum levels of melatonin were studied in 3-wk-old (prepubertal), 8-wk-old (adult), and 17-mo-old (senile) male rats. They were adapted to a photoperiod of 12 h light/12 h darkness for a minimum of 1 wk and killed at mid-light and mid-dark. Melatonin and N-acetylserotonin were determined by radioimmunoassay. The concentrations of pineal N-acetylserotonin and melatonin were high in the dark period and low in the light period. Statistical analysis indicated that pineal N-acetylserotonin and melatonin levels per 100 gm body weight declined with age. Similarly, serum melatonin demonstrated diurnal changes in all the age groups studied. In addition, there was a significant reduction in the levels of serum melatonin with age. The parallel patterns of decrease in pineal and serum melatonin levels with age suggest a decline in pineal secretion of melatonin in the older animals.     

Influence of propranolol,phenoxybenzamine or phentolamine on the in vivo nocturnal rise of pineal melatonin levels in the syrian hamster

In the Syrian hamster, pineal melatonin levels exhibit a 15-fold rise during the dark phase of the light: dark cycle. This rise is believed to be mediated by the release of norepinephrine from the postganglionic sympathetic fibers which terminate within the pineal. In order to determine the nature of the adrenergic receptor involved in the norepinephrine mediated nocturnal increase in melatonin, male hamsters were treated with either α- or β-adrenergic blockers just prior to lights out. Subsequently, radioimmunoassayable levels of melatonin were measured at 7, 8 and 9 hours (0300, 0400 and 0500 h, respectively) into the dark period. Propranolol (20 mg/kg) completely suppressed the nocturnal rise of melatonin while phentolamine (10 mg/kg) had no effect upon the increase. The minimum amount of propranolol necessary to block the nighttime rise of melatonin was determined to lie between 1 mg/kg and 10 mg/kg. Phenoxybenzamine (20 mg/kg) exhibited a slight, although statistically significant, blockade of the nocturnal melatonin rise.     

Endogenous circannual rhythms and photorefractoriness of testis activity, moult and prolactin concentrations in mink (Mustela vison).

Mink are seasonal photosensitive breeders; testis activity is triggered when days have less than 10 h light. Increasing and decreasing plasma concentrations of prolactin induce the spring and autumn moults. In a 5 year experiment, males were maintained under short days (8 h light:16 h dark) at 13 degrees C or long days (16 h light:8 h dark) at 21 degrees C, winter and summer conditions, respectively. Under winter and summer conditions, circannual cycles of prolactin secretion and moulting were observed at intervals of about 11 months. Recurrence of testis cycles was not evident. In a second experiment, males were maintained under an 8 h light:16 h dark cycle from the winter solstice or under 10 h light:14 h dark, 12 h light:12 h dark or 14 h light:10 h dark cycles from 10 February. Under 8 h light:16 h dark cycle, testis regression was slightly later than under natural conditions, indicating photorefractoriness. However, mink remained sensitive to light: the longer the photoperiod, the faster the testis regression. In a third experiment, males were transferred under 8 h light:16 h dark or 16 h light:8 h dark from 15 May (group 1), 12 June (group 2) or 4 July (group 3); males submitted to long days received melatonin capsules on the day of transfer. Increasing concentrations of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) and testis volume were shown by half the males in group 2 and nearly all the males in group 3; the constant release of melatonin from implants was more efficient than short days; but in the three groups, prolactin concentrations decreased in the few days after short-day or melatonin treatment. Overall, the results demonstrate endogenous circannual rhythms of prolactin secretion, body weight and moulting. Although a refractory period to short days was observed, the annual cycle of testis activity totally relies on the annual changes in daylength.     

Two-phase response of rat pineal melatonin to lethal whole-body irradiation with gamma rays.

Male Wistar rats adapted to artificial light:dark (LD) regimen 12:12 h were whole-body irradiated with a single dose of 9.6 Gy of gamma rays and sham/irradiated in the night in darkness. The rats were examined 60 min, 1, 3 and 5 days after exposure between 22:00 and 01:30 h in the darkness. The results obtained indicate a two-phase reaction of pineal melatonin after the lethal irradiation of rats: the decline of melatonin concentration early after the exposure (at 60 min) with unchanged serotonin N-acetyltransferase (NAT) activity followed by an increase of melatonin synthesis, accompanied by an increase of pineal and serum melatonin on day 5 after the exposure. NAT activity was increased on day 3 after the exposure. Serum corticosterone concentrations in irradiated rats were increased 60 min and 3 days after exposure. With respect to the antioxidant, immunomodulating and stress-diminishing properties of melatonin, we consider the increase in melatonin synthesis during later periods after irradiation as part of adaptation of the organism to overcome radiation stress.     

Role of pineal gland in kidney-adrenal homeostasis

The effects of pineal gland on kidney-adrenal axis have been studied in male rats. Rats were pinealectomized and exposed to a photoperiod of 12 h light: 12 h dark. Plasma renin activity (PRA), corticosterone and corticotropin (ACTH) levels were measured at 10, 20 and 35 days postpinealectomy. Pinealectomy increased corticosterone and ACTH levels and decreased PRA in all age groups. A significant negative correlation was found between corticosterone and PRA, which suggest that changes in PRA were due to changes in circulating corticosterone, via feedback mechanism on renin secretion. On the other hand, melatonin administration prevents these effects of pinealectomy. It is suggested that the lack of this pineal indol is responsible for the pinealectomy-induced alterations in male rats.     

Reentrainment in Golden Hamsters: Effect of Melatonin, Age and Neonatal Clomipramine Treatment

Golden hamsters (young: 3 month-old; old: more than 12 month-old; or neonatally treated with clomipramine - a serotonin/noradrenaline re-uptake inhibitor antidepressant) were initially entrained to a 14:10 light:dark cycle, and their reentrainment rate after a 6 h phase advance in the photoperiod was determined. Animals took between 6 and 9 days to reentrain. Melatonin (1 mg/kg, i.p.) accelerated reentrainment to the LD cycle in all groups, except for the clomipramine-treated hamsters. These results support an important accelerating effect of the pineal hormone melatonin on resynchronization, no longer observed in clomipramine-treated hamsters.     

Correlations of serotonin and its metabolites in individual rat pineal glands over light:dark cycles and after acute light exposure

Profiles of pineal indolealkylamines were estimated by high performance liquid chromatography and were correlated in individual glands of male rats sacrificed over several light:dark cycles and after acute exposure to light at night. A significant and positive correlation of 5HIAA vs 5HT in individual glands over both normal and experimental lighting conditions suggested that oxidative deamination is not a major factor in photic regulation of pineal 5HT levels and that the formation of 5HIAA is dependent on substrate availability. Regression analysis of other indole constituents revealed that there was a positive and significant correlation between 5HT vs N-acetylserotonin, but not between 5HT vs melatonin and N-acetylserotonin vs melatonin in individual glands during the dark phase of a light:dark cycle. We propose that this effect may be related to a pulsatile release of melatonin into the blood stream and is the result of sampling glands at different stages in the storage/release of melatonin.