Determination of melatonin in rat pineal,plasma and retina by high-performance liquid chromatography with electrochemical detection

A sensitive method for the routine measurement of endogenous melatonin (MEL) in pineal, retina and plasma rat tissues has been developed using reversed-phase high-performance liquid chromatography with electrochemical detection. Quantification limit for MEL was 0.2 ng/mg protein in pineal, 15 pg/ml in plasma and 2.0 pg/mg protein in retina. To improve both MEL quantification and the reproducibility of the assay, an internal standard was used when an extraction in organic solvent was required, in contrast with other available chromatographic methods. MEL values and the circadian profile obtained in this study from both rat pineal and plasma agree with those reported previously. This method allows MEL detection in mammal retina, particularly in rat, where MEL levels are very low.     

Determination of pineal melatonin by precolumn derivatization reversed-phase high-performance liquid chromatography and its application to the study of circadian rhythm in rats and mice

Determination of minute amounts of endogenous melatonin in rat and mouse pineal gland was performed using an RP-HPLC system. Melatonin was separated following precolumn derivatization and determined with a fluorescence detector at the emission wavelength of 380 nm with the excitation at 245 nm. The calibration curve of melatonin constructed by adding known amounts of melatonin to the homogenates of mouse pineal gland was linear over the range of 1-500 fmol (injection amount/20 microl). The detection limit of added melatonin was 1 fmol (S/N = 5). Repeatability and day-to-day precision for the melatonin spiked sample of mouse pineal gland was 4.0 and 3.8% (RSD), respectively. Using the present method, circadian changes of melatonin content in rat (Wistar) and mouse (C3H) pineal gland were determined. In addition, a minute amount of melatonin in ddY mouse pineal gland was determined, because pineal melatonin of many inbred mouse strains has been reported to be lower than the detection limit.     

Relationship of atypical melatonin rhythm with two circadian clock outputs in B6D2F(1) mice

Circadian rhythms in body temperature, locomotor activity, and the circadian changes of plasma and pineal melatonin content were investigated in B6D2F(1) mice synchronized by 12 h of light and 12 h of darkness. During 8 wk continuous recording, activity and temperature displayed a marked stable and reproducible circadian rhythm, with both peaks occurring near the middle of darkness. Both 24- and 12-h rhythmic components were also significantly detected. Mean plasma melatonin concentration rose steadily during the light span and reached a maximum (30.6 +/- 10.0 pg/ml) at 11 h after light onset (HALO), then gradually decreased after the onset of darkness to a nadir (4.7 +/- 0.4 pg/ml) at 20 HALO. Mean pineal content followed a pattern parallel to that of plasma concentration (peak at 11 HALO: 17.7 +/- 1.0 pg/gland; trough at 17 HALO: 4.7 +/- 1.0 pg/gland). In addition, a second sharp peak was observed at 21 HALO (20.2 +/- 3.5 pg/gland). Plasma and pineal contents displayed large and statistically significant circadian changes, with a composite rhythm of period (24 + 12 h). This mouse model has predominant production and secretion of melatonin during the day. This possibly contributes to a similar coupling between chronopharmacology mechanisms and the rest-activity cycle in these mice and in human subjects.     

Highly sensitive method for the determination of melatonin by normal-phase high-performance liquid chromatography with fluorometric detection

In the present study a new chromatographic method was developed to quantify melatonin in rat pineal that can be extended to other tissues. Melatonin was extracted from an acid homogenate with ethyl acetate to avoid amine interference. HPLC was performed with silica normal-phase column and fluorescence detection. This method is sensitive enough for detecting melatonin in a single pineal gland with a detection limit of 3 pg/mg tissue.     

Circadian rhythms of melatonin release from chicken pineal in vitro: modified melatonin radioimmunoassay

An improved and simplified radioimmunoassay for measuring pineal, serum, and in vitro cultured medium melatonin is described. Using 2-[125I]iodomelatonin as radiolabeled ligand and a polyclonal rabbit antimelatonin antiserum, melatonin concentrations were determined in all three types of samples by a 2-day direct equilibrium double-antibody assay method without prior extraction. Serial dilutions of pineal homogenates, serum, and cultured medium all gave parallel displacement curves. Cross-reactivity of the antisera with other indoles was negligible. Intraassay coefficients of variation (n = 3) were 5.09, 3.32, and 5.05% at 7.81, 62.5, and 500 pg/tube, respectively, and the interassay coefficients of variation (n = 20) were 12.18% at 62.5 pg/tube. A characteristic diurnal rhythm of melatonin was observed using this direct assay for measuring daytime and nighttime chicken pineal and serum samples. An in vitro incubation of chicken pineal glands with a lighting cycle of 12-hr light:12-hr dark showed that the diurnal rhythm of melatonin secretion into the cultured medium was maintained. The direct assay method described in this report for measuring chicken melatonin using 2-[125I]iodomelatonin as radiolabeled ligand coupled with the in vitro cultured chicken pineal gland clearly offers great potential for studying the chicken pineal circadian oscillator and its underlying mechanism.     

荒漠沙蜥松果体褪黑激素含量的季节性变化

应用高效液相色谱法(HPLC)-UV检测了不同季节荒漠沙蜥(Phrynocephalus przewalskii)松果体内褪黑激素的含量.结果显示,其高峰值发生在春季,为1 017±209 pg/pineal.低峰值出现在冬季(实验室内冬眠,2～4℃),为355±68.5 pg/pineal,秋季的含量(735±133.7 pg/pineal)高于夏季的含量(597±94.9 pg/pineal).表明荒漠沙蜥松果体褪黑激素含量呈现明显的年周期节律并与光周期和生殖周期的年节律基本相符.     

Nocturnal plasma levels of melatonin in quails (Coturnix japonica) injected with l-5-hydroxy-tryptophan.

This study aimed to demonstrate the influence of the systemic administration of l-5-hydroxy-tryptophan (L-HTP) on the plasma levels of melatonin during the dark period in quails. Throughout daylight, the plasma levels of melatonin did not differ significantly, oscillating between 110.2 +/- 15.8 pg.mL(-1) and 157.4 +/- 34.8 pg.mL(-1), from 8 to 16 hours. L-HTP (25 mg.kg(-1), through the intracelomic route) administered at 18 hours lessened significantly the nocturnal increase of the plasma levels of melatonin (controls, 327.3 +/- 20.1 and 315.8 +/- 20.9 pg.mL(-1) vs. 242.1 +/- 24.8 and 217.5 +/- 21 pg.mL(-1), respectively, at 20 and 24 hours, P < 0.05). The results obtained showed that the administration of LHTP reduced the nocturnal melatonin release, possibly by bringing about an increase in serotonin synthesis and synaptic release in the pineal. Therefore, the serotoninergic transmission from the raphe towards the pineal would constitute a mechanism of modulation of the synthesis and melatonin release in quails.     

Does melatonin modulate beta-endorphin, corticosterone, and pain threshold?

Converging lines of evidence suggest that the pineal hormone, melatonin, may regulate changes in pain threshold by modulating fluctuations in opioid receptor expression and levels of beta-endorphin (beta-END). This study investigated whether the circadian oscillation in plasma melatonin is involved in the modulation of plasma beta-END immunoreactivity (beta-END-ir), and whether fluctuations in pain threshold measured using the hotplate test are contingent upon the fluctuation of these two hormones in Rattus Norvegicus. The role of melatonin was explored using light-induced functional pinealectomy (LFPX) to suppress nocturnal melatonin release. Pinealectomized rats were found to have significantly elevated levels of beta-END-ir compared to control animals at both photophase (398 +/- 89 pg/ml versus 180 +/- 23 pg/ml) and scotophase (373 +/- 45 pg/ml versus 203 +/- 20 pg/ml) test-periods, thus supporting the putative melatonin-opioid axis. Similarly, latency to pain threshold of LFPX rats was significantly longer when compared to control animals at photophase (7.3 +/- 1.4 sec versus 4.8 +/- 0.7 sec) and scotophase (6.3 +/- 0.7 sec versus 5.1 +/- 0.7 sec). Previous studies have produced conflicting data regarding the role of the pineal system in modulating levels of corticosterone (CORT). We observed a moderate, but non-significant, increase in the CORT concentration of LFPX rats during the photophase test period.     

Determination of free and total (free plus protein-bound) melatonin in plasma and cerebrospinal fluid by high-performance liquid chromatography with fluorescence detection

A simple, sensitive and accurate method for the estimation of free and total (free plus protein-bound) melatonin (MLT) in human plasma and cerebrospinal fluid (CSF) is described. Via Chem-Elut cartridges, free and total MLT (the latter obtained after a deproteinization step) were quantified in dichloromethane-extracted samples and analyzed in one chromatographic run by high-performance liquid chromatography (HPLC) with fluorimetric detection. The column used was an Extrasil ODS-2 (3 microm, 150 x 4.6 mm I.D.), while the mobile phase consisted of 75 mM sodium acetate-acetonitrile (72:28, v/v) (pH 5.0). Repeatability and reproducibility of the method were 3.24 and 9.4%, respectively. The recovery of melatonin from plasma and CSF was 99.9+/-4.0% for non-deproteinized samples and 93.2+/-4.8% for deproteinized samples. The detection limit of the assay was 0.5 pg/ml. In human plasma, the mean+/-SD concentrations in the darkness period were 23.18+/-7.44 pg/ml for free melatonin and 82.5+/-36.48 pg/ml for total melatonin, while the lowest concentrations detected during daytime were 2.23+/-2.22 and 7.40+/-5.68 pg/ml, respectively. Detection of MLT in CSF was 5.01+/-2.31 and 28.55+/-6.95 pg/ml for the free and total fraction, respectively.     

Influence of light intensity on plasma melatonin and locomotor activity rhythms in tench

Melatonin production by the pineal organ is influenced by light intensity, as has been described in most vertebrate species, in which melatonin is considered a synchronizer of circadian rhythms. In tench, strict nocturnal activity rhythms have been described, although the role of melatonin has not been clarified. In this study we investigated daily activity and melatonin rhythms under 12:12 light-dark (LD) conditions with two different light intensities (58.6 and 1091 microW/cm2), and the effect of I h broad spectrum white light pulses of different intensities (3.3, 5.3, 10.5, 1091.4 microW/cm2) applied at middarkness (MD) on nocturnal circulating melatonin. The results showed that plasma melatonin in tench under LD 12:12 and high light conditions displayed rhythmic variation, where values at MD (255.8 +/- 65.9 pg/ml) were higher than at midlight (ML) (70.7 +/- 31.9 pg/ml). Such a difference between MD and ML values was reduced in animals exposed to LD 12: 12 and low light intensity. The application of 1 h light pulses at MD lowered plasma melatonin to 111.6 +/- 3.2 pg/ml (in the 3.3-10.5 microW/cm2 range) and to 61.8 +/- 18.3 pg/ml (with the 1091.4 microW/cm2 light pulse) and totally suppressed nocturnal locomotor activity. These results show that melatonin rhythms persisted in tench exposed to low light intensity although the amplitude of the rhythm is affected. In addition, it was observed that light pulses applied at MD affected plasma melatonin content and locomotor activity. Such a low threshold suggests that the melatonin system is capable of transducing light even under dim conditions, which may be used by this nocturnal fish to synchronize to weak night light signals (e.g., moonlight cycles).     

Radioimmunoassay of 5-methoxy tryptophol in sheep plasma and pineal glands

No 5-methoxytryptophol (ML) could be detected in sheep plasma using a specific, sensitive radioimmunoassay developed for the purpose. Blood samples were collected from sheep during darkness and daylight and during various stages of the estrous cycle, but in no sample was the ML content above the detection limit of the method. Addition of 1 mM pargyline and neostigmine to blood immediately after collection to block metabolism did not result in a detectable ML concentration. The failure to detect ML was not due to degradation since added ML was not degraded by blood enzymes even after 16 hours incubation at 37 degrees C. Injection of 100 microgram and 1 mg ML sc in sheep resulted in a rapid rise of ML to 95-130pg/ml and 560-1000pg/ml respectively and disappearing with a half life of approximately 15-20 minutes. Sheep pineal glands collected during the light phase contained ML (51 +/- 5pg/mg tissue. X +/- SE, n = 7) which represents less than 6% of the melatonin content. It is concluded that if ML is present in sheep blood it is present at very low levels. It is thus unlikely to be a major circulating pineal hormone in this species, however, its role within the CNS as a local hormone cannot be excluded.     

Determination of rat pineal gland melatonin content by a radioimmunoassay.

Melatonin content in individual rat pineal glands was measured by radioimmunoassay (RIA). The RIA used can very reliably detect as little as 50 pg of melatonin. The various precursors, analogues, and the metabolite of melatonin (6-hydroxymelatonin) which were tested for cross-reactivity were not recognized by the antibody. The effects on melatonin levels in rat pineal glands following the administration of L-tryptophan, 5-hydroxy-L-tryptophan, serotonin, N-acetylserotonin, melatonin and pargyline are also presented.     

Melatonin and adrenal cortex steroid production: in vivo and in vitro studies.

The present study was designed to clarify the interaction between the pineal melatonin and adrenal cortex steroid production. Experiments with male rats under chronic stress conditions (sleep deprivation) revealed that melatonin circadian pattern was fully destroyed and daytime plasma concentration were significantly elevated. Constant illumination (2500 lux) during the nighttime was not able to suppress melatonin production in the stressed animals. Plasma concentration of corticosterone were increased in the stressed rats as well. The modulatory effect of melatonin on corticosterone and progesterone production by rat adrenals was studied in a superfusion system. During melatonin challenge progesterone secretion was two-three fold elevated with no effect on corticosterone content in the plasma samples. Pineal cytoplasmic glucocorticoid and progesterone receptors were investigated as well. A specific binding was not observed in that case. Presented data support the existence of direct communication between the pineal and adrenal glands.     

Melatonin radioimmunoanalysis: evaluation of the pineal function in hyperprolactinemic male rats and controls

A sensitive and specific radioimmunoassay for melatonin quantification in rat pineal and biological fluids is described. The assay utilizes a specific antibody and H3-melatonin as tracer. Bound and free fraction were separated by a saturated sulphate ammonium solution. The sensitivity of the method is 9 pg/ml. The intra and interassay variation coefficient were 10.4 and 13.6% respectively. By means of this RIA the content of melatonin in the pineal gland in male rats made hyperprolactinemic on day 30 of life and their respective sham-operated controls has been evaluated. The results showed that the melatonin content measured at 2 a.m. was reduced in the transplanted animals when compared to control group, not only shortly (48 hours) after the transplant operation, but also in the chronic situation; though suggesting that further investigations are necessary to deepen and understand the interrelationships between prolactin and pineal gland and their effect on the hypothalamic-pituitary-gonadal axis.     

Influence of Light Intensity on Plasma Melatonin and Locomotor Activity Rhythms in Tench

Melatonin production by the pineal organ is influenced by light intensity, as has been described in most vertebrate species, in which melatonin is considered a synchronizer of circadian rhythms. In tench, strict nocturnal activity rhythms have been described, although the role of melatonin has not been clarified. In this study we investigated daily activity and melatonin rhythms under 12∶12 light‐dark (LD) conditions with two different light intensities (58.6 and 1,091 µW/cm²), and the effect of 1 h broad spectrum white light pulses of different intensities (3.3, 5.3, 10.5, 1,091.4 µW/cm²) applied at middarkness (MD) on nocturnal circulating melatonin. The results showed that plasma melatonin in tench under LD 12∶12 and high light conditions displayed rhythmic variation, where values at MD (255.8±65.9 pg/ml) were higher than at midlight (ML) (70.7±31.9 pg/ml). Such a difference between MD and ML values was reduced in animals exposed to LD 12∶12 and low light intensity. The application of 1 h light pulses at MD lowered plasma melatonin to 111.6±3.2 pg/ml (in the 3.3–10.5 µW/cm² range) and to 61.8±18.3 pg/ml (with the 1,091.4 µW/cm² light pulse) and totally suppressed nocturnal locomotor activity. These results show that melatonin rhythms persisted in tench exposed to low light intensity although the amplitude of the rhythm is affected. In addition, it was observed that light pulses applied at MD affected plasma melatonin content and locomotor activity. Such a low threshold suggests that the melatonin system is capable of transducing light even under dim conditions, which may be used by this nocturnal fish to synchronize to weak night light signals (e.g., moonlight cycles).     

Determination of plasma melatonin levels by enzyme-linked immunosorbent assay (EIA) in turbot (Scophtalmus maximus L.) and tench (Tinca tinca L.)

An enzymoimmunoassay (EIA) kit for plasma melatonin (MLT) measurements was employed in tench (Tinca tinca) and in turbot (Scophtalmus maximus). Tench and turbot plasma samples were purified with a C18 reversed phase extraction columns because this kit is designed for human serum measurements. The lowest detection limit of the technique was 11.48 pg/well with a sensitivity at 50% binding of 100 pg/well. Intra-assay and inter-assay CV (%) were always less than 5% (n=8), and 9% (n=6) in tench plasma samples, and less than 5% (n=8) and 13% (n=5) in turbot plasma samples, respectively. Correlation coefficients between EIA and RIA measurements in tench and turbot plasma samples were 0.93 and 0.89 (p<0.001) respectively. Diurnal and nocturnal plasma melatonin mean levels were 14.7+/-2.1 pg/ml and 87.4+/-11 pg/ml in tench (n=15), and 3.5+/-0.4 pg/ml and 28.1+/-2.1 pg/ml in turbot (n=15). These species showed a melatonin circadian rhythm as in other animals studied. The results suggest that the commercial kit used in this experiment could be a suitable and alternative method to RIA for plasma MLT determinations in tench and turbot although it is necessary to increase volumes (1ml) and concentrate daytime samples.     

Effects of shortened daylength and melatonin treatment on plasma prolactin and melatonin levels in pinealectomised and sham-operated ewes

Comparisons have been made between the effects of shortened daylength and melatonin treatment on plasma prolactin and melatonin levels in pinealectomised (Px) and sham-operated (Sh) ewes. Twenty-two anoestrous Merino crossbred ewes, maintained under normal grazing conditions, were assigned to four groups for a period of 9 weeks. Group 1 remained untreated (control), Group 2 was herded into a dark shed at 1600 h each day until dark (approx 4 h), ewes in Group 3 were injected with 100 μg melatonin s.c. at 1600 h each day and ewes in Group 4 were implanted with a melatonin capsule releasing 125–200 μg/day. Another group (Group 5) of 4 Px and 4 Sh ewes from the same flock was maintained in an animal house and subjected to shortened daylength (10. 5 h L : 13. 5 h D, lights off 1600 h). Three weeks after the treatments began, ewes in Groups 1–4 were exposed to a fertile ram and ewes in Group 5 to a vasectomised ram and the day of mating noted. No differences were evident between Groups 1–4 in the ewes' response to the ram, time taken to conceive, duration of gestation or number of lambs born. In untreated Px ewes no plasma melatonin (< 20 pg/ml) was found in either day or night samples, whereas intact animals showed the characteristic night-time rise. The silastic implants produced stable daytime blood levels of 90–120 pg/ml, whereas a single injection of 100 μg melatonin caused a transitory (2–3 h) rise. Shortened daylength (Group 2) or a single daily injection of melatonin (Group 3) lowered prolactin levels but only in ewes with an intact pineal gland, whereas melatonin implants (Group 4) caused a reduction in plasma prolactin in both Px and Sh sheep. The results indicate that light-induced alterations in prolactin production in sheep involve both the pineal gland and melatonin. Continuous melatonin release from implants caused changes in plasma prolactin levels similar to those seen following exposure to short days.     

5-methoxytryptophol in rat serum and pineal: Detection,quantization, and evidence for daily rhythmicity

A gas chromatography-mass spectrometric method is described which allows the simultaneous detection of melatonin and 5-methoxy-tryptopopthol in rat pineals and sera. The concentrations of 5-methoxytryptophol in the pineal were found to be as great as those of melatonin, and appear to vary with the time of day. Statistical analysis showed a significant correlation between pineal and sera 5-methoxytryptophol levels during the hours of darkness, however, the correlation disappeared during the light phase.     

Identification of highly elevated levels of melatonin in bone marrow: its origin and significance

Bone marrow is an important tissue in generation of immunocompetent and peripheral blood cells. The progenitors of hematopoietic cells in bone marrow exhibit continuous proliferation and differentiation and they are highly vulnerable to acute or chronic oxidative stress. In this investigation, highly elevated levels of the antioxidant melatonin were identified in rat bone marrow using immunocytochemistry, radioimmunoassay, high performance liquid chromatography with electrochemical detection and mass spectrometry. Night-time melatonin concentrations (expressed as pg melatonin/mg protein) in the bone marrow of rats were roughly two orders of magnitude higher than those in peripheral blood. Measurement of the activities of the two enzymes (N-acetyltransferase (NAT) and hydroxyindole-O-methoxyltransferase (HIOMT)) which synthesize melatonin from serotonin showed that bone marrow cells have measurable NAT activity, but they have very low levels of HIOMT activity (at the one time they were measured). From these studies we could not definitively determine whether melatonin was produced in bone marrow cells or elsewhere. To investigate the potential pineal origin of bone marrow melatonin, long-term (8-month) pinealectomized rats were used to ascertain if the pineal gland is the primary source of this antioxidant. The bone marrow of pinealectomized rats, however, still exhibited high levels of melatonin. These results indicate that a major portion of the bone marrow's melatonin is of extrapineal origin. Immunocytochemistry clearly showed a positive melatonin reaction intracellularly in bone marrow cells. A melatonin concentrating mechanism in these cells is suggested by these findings and this may involve a specific melatonin binding protein. Since melatonin is an endogenous free radical scavenger and an immune-enhancing agent, the high levels of melatonin in bone marrow cells may provide on-site protection to reduce oxidative damage to these highly vulnerable hematopoietic cells and may enhance the immune capacity of cells such as lymphocytes.     

Adrenal-mediated depression of N-acetyltransferase activity and melatonin levels in the rat pineal gland

N-acetyltransferase (NAT) is believed to be the rate-limiting enzyme in the synthesis of melatonin from serotonin in the pineal gland. Norepinephrine released from sympathetic nerve endings within the pineal gland stimulates NAT activity and, therefore, melatonin synthesis. When an animal is subjected to a stressful stimulus, it would be expected that the increase in plasma stimulus, it would be expected that the increase in plasma catecholamines originating from the adrenal medulla and/or the sympathetic nervous system would result in a stimulation of pineal NAT activity. Adult male rats were given a 1.5cc injection of physiological saline subcutaneously into the back leg. Compared to non-injected controls, animals stressed in this manner were shown to have significantly lower pineal melatonin content 10 min after the saline injection late in the light phase of the light/dark cycle (at 18.30 h-lights on at 07.00 h). To test this more thoroughly, a time course study was conducted during the dark phase (at 02.00 h-5 hours after lights out) when pineal NAT activity and melatonin levels are either increasing or elevated. NAT activity and melatonin levels in the pineal were significantly depressed in stressed animals as compared to controls by 10 min after the saline injection, and remained so until 60 min after injection. By 90 min they had returned to control values. In the next study the nighttime response of the pineal to stress was compared in intact and adrenalectomized rats. Adrenalectomy prevented the changes in NAT activity and melatonin content associated with the saline injection. Some factor, such as a catecholamine or corticosterone from the adrenal, seems to be eliciting the response in the pineal to the saline injection. It is not known if the factor is acting centrally or directly on the pineal gland.