Biological signals最新文献

Pineal and retinal melatonin has an important role in the control of avian circadian rhythms. In order to study the mechanisms of circadian rhythms of melatonin synthesis in the pineal and in the eye, in vivo microdialysis was applied to these organs. In both pigeons and Japanese quails, pineal and ocular melatonin levels were high during the dark and low during the day under light-dark (LD) cycles. These rhythms persisted under constant dim light (LLdim) conditions indicating the circadian nature of pineal and ocular melatonin release. Light has two effects on melatonin synthesis. One is acute inhibition of melatonin synthesis and the other is entrainment of circadian melatonin rhythms. We have examined photoreceptors mediating these effects in the pigeon. The results have indicated that the eyes are not involved in light-induced suppression and photic entrainment of pineal melatonin release, and pineal photoreceptors themselves are likely to mediate these effects. Concerning ocular melatonin, retinal photoreceptors seem to mediate light-induced suppression and photic entrainment and no evidence supporting mediation of extraretinal photoreceptors was obtained. Because dopamine is implicated in retinal melatonin synthesis, we measured dopamine and melatonin release simultaneously from the eye of pigeon. In contrast to melatonin rhythms, dopamine increased during the day and decreased during the dark. This antiphase relationship between melatonin and dopamine persisted in LLdim, suggesting an interaction between these two rhythms. The results of an intraocular injection of dopamine or melatonin in the phase of melatonin and dopamine rhythms indicated that the interaction is required for maintaining the antiphase relationship between the two rhythms.

The daily profile of serum level of melatonin was studied in 10 young and 13 elderly subjects. All of the subjects were physically and psychiatrically healthy and did not have any clinical symptoms related to rhythm disturbance. Blood samples were taken every 3 h for 1 day and serum melatonin levels were determined by RIA. All except for 1 of the elderly subjects exhibited a clear circadian rhythm of serum melatonin level with a nocturnal peak. In both subject groups, the melatonin rhythm showed significant diurnal variation. There was no significant difference in the total melatonin level per day between young and elderly groups, suggesting that there was no influence of aging on daily total melatonin secretion. However, there was a marked difference in the features of the melatonin rhythm between the two groups, i.e., a rapid decline of the melatonin level from the nocturnal peak in the elderly group, suggesting that the off-set time of melatonin secretion advances with aging. Our findings suggest that the pattern of melatonin rhythm alters significantly without clear clinical symptoms in the process of senescence.

Photic and circadian regulations of melatonin rhythms in the pineal organ and the retina of several teleosts were studied to investigate the regulatory mechanisms of melatonin rhythms in fishes. In the eyecup preparations of the goldfish, Carassius auratus, both time of day and lighting conditions affected melatonin production, with high melatonin production observed only in the dark-treated group incubated during the 'subjective' night. Thus, in the goldfish retina, local photoreceptors and an ocular circadian clock seem to regulate melatonin production, as in the zebrafish retina and in the pineal organ of a number of teleosts, including the goldfish. However, this circadian regulation of melatonin rhythms is not universal among fishes. Although the superfused pineal organ of the masu salmon Oncorhynchus masou secreted melatonin in a rhythmic fashion under light-dark (LD) cycles, the rhythm disappeared under constant darkness (DD), as in the rainbow trout, with a large amount of melatonin released both during the subjective day and the subjective night. These results suggest that all salmonids lack circadian regulation of melatonin rhythms. Furthermore, when ocular melatonin rhythms were compared in two cyprinids, the ugui Tribolodon hakonensis and the oikawa Zacco platypus occupying different ecological niches, ocular melatonin contents exhibited daily variations, with higher values during the dark phase of LD cycles in both species. The rhythmic changes persisted in the ugui under DD, with higher levels at subjective midnight than at subjective midday; however, ocular melatonin levels in the oikawa were consistently high under DD. Thus, the circadian regulation of melatonin rhythms in fishes is influenced not only by phylogeny, but also by the ecological niches of the animals. These results suggest that the physiological functions of melatonin in the circadian and photoperiodic systems differ among fishes.

The pineal gland conveys photoperiodic information to the brain through its daily pattern of melatonin (MEL) secretion. The duration of MEL secretion is proportional to the duration of the night. To determine the mechanism by which MEL transduces photoperiod, we used a protocol of daily MEL infusion given to sexually active pinealectomized Syrian hamsters. A long MEL signal (10 h) inhibited sexual activity, whereas a 5-hour infusion had no effect. However, animals given a 2.5-hour infusion twice separated by an interval of 3 h produced complete gonadal atrophy. Changes in the time interval between infusions blocked the potency of the MEL infusion, suggesting a tight temporal relationship between MEL signals. Additionally, the infusions were as effective whether applied during the day or during the night, in both long and short photoperiods. These data suggest that there is a rhythm of sensitivity to MEL involved in the photoperiodic response which is entrained by MEL itself.

There is considerable interest in the neuronal pathways involved in the generation and entrainment of circadian rhythms. We have monitored the output of the pineal gland via the urinary metabolite of melatonin, 6-sulphatoxymelatonin (aMT.6S), following drug treatment to provide information on the transmitters mediating the effects of light. As a check on the specificity of the response [suprachiasmatic nucleus (SCN) versus direct pineal effects] we also monitored in separate experiments c-Fos induction in the SCN in response to the treatments. Administration of the excitatory amino acid (EAA) antagonist MK-801 (3 mg/kg) failed to inhibit either the acute or entraining effects of light on melatonin production and only partially (approximately 30%) prevented the induction of c-Fos in the SCN. These results suggested that EAA are either not important in mediating the effects of light in the rat or that pathways utilising transmitters other than EAA may be involved. When the non-specific serotonin agonist quipazine was administered at CT 18, it mimicked both the acute and phase delaying effects of light on melatonin secretion and induced c-Fos in the SCN with a regional distribution identical to that observed following light treatment. Characterisation of the receptor subtypes involved in this response implicated the 5HT2c receptor on the basis of the response to (+/-)-1-(4-iodo-2,5-dimethoxyphenyl)-2-aminopropane HCl (DOI, 0.1-0.5 mg/kg) and the potent antagonism by ritanserin and ketanserin. DOI (0.5 mg/kg) also induced c-Fos in the SCN and the induction was prevented by ritanserin and ketanserin. Despite the potency of 5HT2c agonists in mimicking light effects on melatonin rhythmicity, at the time of preparation we have not been able to block the effects of 2-1x/1-min light pulses on the melatonin rhythm with either metergoline (15 mg/kg), ritanserin (3 mg/kg) or ketanserin (3 mg/kg). Similarly ritanserin (10 mg/kg) failed to block light-induced c-Fos induction in the SCN. We conclude that in the rat there may be two pathways mediating the effects of light on rhythmicity, one being the retino-hypothalamic tract (RHT) utilising excitatory amino acids and the other a retino-raphe-SCN pathway utilising 5HT2c receptors. These conclusions stand in stark contrast to the situation in the hamster where the RHT is paramount in the transmission of light to the SCN.

Plasma melatonin rhythm in humans was investigated: its stability, relationship to the sleep-wake rhythm, and response to light. The so-called day-to-day variation of reference phases of plasma melatonin rhythm was within 1.4 h when blood was sampled at 1-hour intervals. Therefore, a change in phase beyond this value is regarded as a phase shift of melatonin rhythm in individuals. Plasma melatonin rhythm was spontaneously desynchronized from the sleep-wake rhythm and probably regulated by the common circadian pacemaker which drives the rhythm in rectal temperature. When a bright-light pulse was applied, the melatonin rhythm produced a phase shift, but the amount of phase shift seems to be different for the ascending and descending phases of nocturnal melatonin rise. Finally, a partial entrainment was observed in a subject who developed a non-24-hour sleep-wake syndrome later, in which the plasma melatonin rhythm was free-running whereas the sleep-wake rhythm was apparently entrained by a 24-hour day-night alternation. It is concluded that the plasma melatonin rhythm is the best marker of the human circadian pacemaker so far available.

Serotonin N-acetyltransferase (AA-NAT; arylalkylamine N-acetyltransferase; EC 2.3.1.87) is the penultimate enzyme in melatonin synthesis and large changes in the activity of this enzyme appear to regulate the rhythm in melatonin synthesis. Recent advances have made it possible to study the mRNA encoding chicken AA-NAT, which has only been detected in the retina and pineal gland. Within the retina, AA-NAT mRNA is expressed primarily in photoreceptors. The levels of chicken retinal AA-NAT mRNA and activity exhibit 24-hour rhythms with peaks at night. These rhythms appear to reflect circadian clock control of AA-NAT mRNA abundance and independent effects of light and darkness on both mRNA levels and enzyme activity. The effects of darkness and light may occur through alterations in cAMP-dependent protein phosphorylation, which increases AA-NAT activity in photoreceptor cell cultures. The cAMP-dependent increase of AA-NAT enzyme activity reflects, at least in part, increased mRNA levels and inhibition of enzyme inactivation by a posttranslational mechanism. This review discusses a hypothetical model for the cellular and molecular regulation of AA-NAT activity by circadian oscillators and light in chicken retinal photoreceptor cells.

Pineal organ of the lamprey, Lampetra japonica, is essential to keep the circadian locomotor activity rhythm as previously reported. In this paper, we tried to show that an endogenous oscillator is located and is working in the pineal organ. When the pineal organs were excised and cultured in a plastic tube with M199 medium at 20 degrees C, melatonin secretion rhythms were clearly observed under both light-dark and continuous dark conditions. The circadian secretion of melatonin continued for more than five cycles under the continuous dark condition. This indicates that the pineal organ has an endogenous oscillator and that the melatonin secretion rhythm is controlled by this oscillator. These findings suggest the possibility that the locomotor activity rhythm of the lamprey is under the control of the oscillator in the pineal organ.

The pineal hormone, melatonin, plays an important role in the regulation of diurnal and seasonal rhythms in animals. In addition to the well established actions on the brain, the possibility of a direct melatonin action on the spinal cord has to be considered. In our laboratory, we have obtained data suggesting that melatonin receptors are present in the spinal cords of birds and mammals. Using radioreceptor binding and quantitative autoradiography assays with 2-[125I]iodomelatonin as the specific melatonin agonist, melatonin binding sites have been demonstrated in the rabbit and chicken spinal cords. These sites are saturable, reversible, specific, guanosine nucleotide-sensitive, of picomolar affinity and femtomolar density. The linearity of Scatchard plots of saturation data and the unity of Hill coefficients indicate that a single class of melatonin binding sites is present in the spinal cord membranes studied. The picomolar affinity of these sites is in line with the circulating levels of melatonin in these animals suggesting that these sites are physiologically relevant. Autoradiography studies in the rabbit spinal cord show that melatonin binding sites are localized in the central gray substance (lamina X). In the chicken spinal cord, these binding sites are localized in dorsal gray horns (laminae I-V) and lamina X. As lamina X and laminae I-II have similar functions, melatonin may have comparable roles in the chicken and rabbit spinal cords. Moreover, in the chicken spinal cord, the density of 2-[125I]iodomelatonin binding in the lumbar segment was significantly higher than those of the cervical and thoracic segments. The densities of these binding sites changed with environmental manipulations. When chickens were adapted to a 12L/12D photoperiod and sacrificed at mid-light and mid-dark, there was a significant diurnal variation in the density (maximum number of binding sites; Bmax) of melatonin binding sites in the spinal cord. After constant light treatment or pinealectomy, the Bmax of melatonin receptors in the chicken spinal cord increased significantly in the subjective mid-dark period. Moreover, there was an age-related decrease in the 2-[125I]iodomelatonin binding to the chicken spinal cord. Our results suggest that melatonin receptors in the chicken spinal cord are regulated by environmental lighting and change with development. These receptors may play an important role in the chronobiology of spinal cord function. The biological responses of melatonin on spinal cords have also been demonstrated in vitro. Melatonin decreased the forskolin-stimulated cAMP production in the chicken spinal cord explant. Preincubation with pertussis toxin blocked the melatonin effect. Our results suggest that melatonin receptors in the chicken spinal cord are linked to the adenylate cyclase via a pertussis toxin-sensitive G protein and that melatonin binding sites in spinal cords are melatonin receptors with biological functions. These receptors

Serotonin-immunoreactive (5-HT IR) photoreceptors are present in the pineal complex (pineal and parapineal organ) of the river lamprey, Lampetra japonica. They are so-called modified pineal photoreceptors and have been regarded as photoneuroendocrine cells which secrete melatonin. We reconstructed 5-HT IR cells with a computer to demonstrate their three-dimensional structures from optical sections taken by a confocal laser scanning microscope. The 5-HT IR cell possesses a basal process, and it appears that the process does not branch out. These processes contact each other at the basal region of the end vesicle, and a process extends to the soma of the neighboring 5-HT IR cell. These findings were obtained by three-dimensional analysis with a computer, which is a useful technique to demonstrate the interaction between cells. We suggest that the 5-HT IR photoreceptors interact with one another.