RESUMEN
Melatonin is synthesized and secreted during the dark period of the light-dark cycle. Thus, melatonin has an obvious association with sleep, at least in diurnal animals. Rhythmic nocturnal melatonin secretion is directly generated by the circadian clock, located in mammals within the suprachiasmatic nuclei (SCN), and is entrained to a 24-h period by the light-dark cycle. The periodic secretion of melatonin may be used as a circadian mediator to any system than can "read" the message. In addition, direct effects of the hormone on the SCN could explain some of melatonin effects on the circadian system. Duration of melatonin nocturnal secretion is directly proportional to the length of the night and it has been demonstrated experimentally to be the critical parameter for photoperiod integration. The two main hypotheses to explain the action of melatonin are the duration hypothesis (supporting that night length is coded by the duration of the melatonin secretory phase) and the coincidence hypothesis (holding that physiological responses are linked to the existence of a diurnal rhythm in sensitivity to melatonin). The sites and mechanisms of action of melatonin for circadian and photoperiodic responses are far from being elucidated, but action through specific membrane receptor sites is well documented. In view of melatonin s lipophilic nature, interactions with specific intracellular proteins like calmodulin or tubulin, or with nuclear receptor sites, have also been considered, whereas the physiological significance of the documented antioxidant effect of melatonin remains to be settled. Melatonin seems to act as an "arm" of the circadian clock, giving a time-related signal to a number of body functions; one of these, the circadian organization of an organism's defence, is discussed in some detail as an example.
RESUMEN
The best described function of the pineal hormone melatonin is to regulate seasonal reproduction, with its daily production and secretion varying throughout the seasons or the photoperiod. Additionally, a number of behavioral effects of the hormone have been found. This review describes the effects of melatonin in rodent behavior. We focus on: (a) inhibitory effects (sedation, hypnotic activity, pain perception threshold elevation, anti-convulsive activity, anti-anxiety effects); and (b) direct effects on circadian rhythmicity (entrainment, resynchronization, alleviation of jet-lag symptoms, phase-shifting). Most of these effects are clearly time-dependent, with a peak of melatonin activity during the night. One of the possible mechanisms of action for melatonin in the brain is the interaction with the GABAergic system, as suggested by neurochemical and behavioral data. Finally, some pineal hormone effects might be candidates as putative therapies for several human disorders.