Effects of pinealectomy and melatonin administration on thyroid follicles of blind Syrian hamsters

The effects of exogenous melatonin on the morphology of thyrocytes in pinealectomized and irradiated rats

We investigated the effects of exogenous melatonin on the thyrocytes morphology in gamma-irradiated rats under condition where the pineal gland, as a main physiological source of endogenous melatonin, was removed. Three months after pinealectomy animals were divided into two groups: one group of animals was treated with 0.5 ml of vehicle (ethanol diluted in water) and other group was injected intraperitoneally 2 mg/kg of melatonin dissolved in 0.5 ml of vehicle daily during the period of fourteen days. After this treatment all the animals were irradiated with a single dose of 8 Gy gamma rays. Ionising radiation induced apoptosis, hydropic swelling or/and necrosis in both groups of animals, however these changes were less discerned in the thyrocytes of melatonin-treated animals. Our findings demonstrate that administration of exogenous melatonin prior to irradiation reduces radiation-induced thyrocytes damage.

Reductions in hamster serum thyroxine levels by melatonin are not altered by changes in serum testosterone

Daily melatonin injections reduce reproductive and thyroid hormones in male Syrian hamsters. The interrelationship between the decline in these hormones is not known. To explore this relationship, male Syrian hamsters were divided into four groups: castrated, implanted with testosterone (5-mm silastic implants), both treatments, or neither treatment. One-half of each group of hamsters (n = 7 or 8) were injected with melatonin (25 mg) daily at 1730 h. The other half of each group received daily vehicle injections. Ten weeks later, the hamsters were anesthetized and decapitated. Testes weights, serum testosterone, and serum thyroxine levels were measured. As expected, testes and serum testosterone levels were uniformly low in all of the melatonin-treated hamsters. All of the melatonin-treated groups also had lower than normal thyroxine values irrespective of gonadal treatment. Interestingly, in the non-melatonin-treated hamsters, serum thyroxine values were decreased in the castrated group and increased in the testosterone-implanted group. These results suggest that castration can reduce serum thyroxine levels in male Syrian hamsters and that replacement of testosterone restores these levels to normal. Notably, the declines in thyroxine levels produced by daily melatonin injections were not restored by testosterone implants in castrated or intact hamsters. Therefore, melatonin-induced reductions in thyroxine are not mediated by concurrent reductions in serum testosterone levels. It appears that melatonin-induced reductions in serum thyroxine levels do not use the same mechanism as castration-induced reductions.

Pineal rhythms are synchronized to light-dark cycles in congenitally anophthalmic mutant rats

Genetically mutant anophthalmic rats lacking a complete visual system due to the absence of eyeballs and optic nerves up to the optic chiasma were used as a model to study photo-regulated physiological activities. The photoreception in these mutant rats was determined by measuring the neuroendocrine response of the pineal gland-melatonin levels in the serum, and synaptic ribbon complexes (SRCs) in the pinealocytes. These parameters were studied in both normal and anophthalmic rats maintained under light-dark (LD 12:12), continuous dark (DD) and light (LL) conditions. Both normal and mutant anophthalmic animals showed nocturnal increases in serum melatonin levels and in the number and diameter of SRC and their vesicles in the pinealocytes in LD. The daily rhythms persisted even upon transfer to DD both in normal and mutant rats, whereas in LL, the nocturnal elevation of both the parameters disappeared. These observations suggested that congenitally blind rats can perceive light. The studies of these parameters in both normal and mutant rats in reversed-LD conditions confirmed that pineal rhythms can be entrained by light-dark cycles in congenitally anophthalmic mutant rats through a nonvisual system for light perception.

Melatonin inhibits the basal and TSH-stimulated mitotic activity of thyroid follicular cells in vivo and in organ culture

The aim of the present study has been to examine the effect of melatonin, administered to mice as daily subcutaneous injections for a total of 10 days, on the mitotic activity of thyroid follicular cells (TFC). The colchicine metaphase-arrest technique was employed in the experiment. We found that melatonin (10 micrograms and/or 100 micrograms injection) decreased significantly the mean mitotic activity rate (MMAR) of TFC in both male and female mice. Moreover, melatonin totally suppressed the stimulatory effect of TSH on the MMAR of TFC in both sexes of mice. Furthermore, the effect of melatonin (5 X 10(-7) M) on the proliferation of TFC in the organ-cultured rat and mouse thyroid explants was investigated. It was found that melatonin almost totally suppressed the MMAR of TFC in organ culture. Moreover, melatonin blocked the stimulatory effect of TSH on the MMAR of TFC in both rat and mouse thyroid explants. N-acetylserotonin (NAc-5HT, 10(-6) M) also decreased the MMAR of cultured thyroid explants, but its effect was less expressed when compared to melatonin inhibition. The present data indicate that melatonin can exert its inhibitory effect on the proliferation of TFC directly at the thyroid level, since this pineal indoleamine has been shown to suppress not only basal but also TSH-stimulated mitotic activity. The results are in agreement with the hypothesis of a pineal-thyroid negative feedback, assuming the direct inhibitory effect of melatonin on the thyroid growth.