Melatonina inhibe la respuesta de cortisol a ACTH: posible mediación a través del gen reloj Per1 / Melatonin inhibition of the cortisol response to ACTH may be exerted through period circadian protein homolog 1 (Per1)

Background: Circadian cortisol production results from the interaction of the circadian production of ACTH, the autonomic nervous system and intrinsic factors within the gland. An additional regulator is the neuro-hormone melatonin. In human adrenal gland cultures, melatonin inhibited ACTH stimulated cortisol production and Per1 mRNA expression. ACTH actions on the adrenal involve early and late responses. Aim: To investigate the effects of melatonin on the time course of ACTH stimulated cortisol production and of Per1 expression in the lamb adrenal gland. Material and Methods: Adrenal glands and plasma of five newborn lambs were obtained. Adrenal glands were cut in 15 mg explants. Three of these explants were stored for RNA extraction. The rest of explants were using in different culture protocols with ACTH and melatonin. Results: Lambs had an in vivo a circadian variation in plasma cortisol and in adrenal Per1 expression. In vitro, ACTH stimulated an early and late increase in cortisol production and an early increase in Per1 expression reaching a maximum at 3 hours of treatment. Melatonin inhibited the early Per1 response to ACTH without affecting the early ACTH stimulated cortisol production. However, melatonin inhibited the late response of cortisol production to ACTH. Conclusions: The inhibitory actions of melatonin on Per1 response to ACTH may contribute to the inhibitory effects of melatonin on adrenal steroidogenic response to ACTH.

La melatonina reduce la respuesta de cortisol al ACTH en humanos / Melatonin reduces cortisol response to ACTH in humans

Background: Melatonin receptors are widely distributed in human tissues but they have not been reported in human adrenal gland. Aim: To assess if the human adrenal gland expresses melatonin receptors and if melatonin affeets cortisol response to ACTH in dexamethasone suppressed volunteers. Material and methods: Adrenal glands were obtained from 4 patients undergoing unilateral nephrectomy-adrenalectomy for renal cáncer. Expression of mRNA MT1 and MT2 melatonin receptors was measured by Reverse Transcriptase Polymerase Chain Reaction (RT-PCR). The effect of melatonin on the response to intravenous (i.v.) ACTH was tested (randomized cross-over, double-blind, placebo-controlled tríal) in eight young healthy males pretreated with dexamethasone (1 mg) at 23:00 h. On the next day at 08:00 h, an i.v. Une was inserted, at 08:30 h, and after a blood sample, subjeets ingested 6 mg melatonin or placebo. At 09:00 h, 1-24 ACTH (Cortrosyn, 1µg/1.73 m² body surface área) was injected, drawing samples at 0, 15, 30, 45 and 60 minutes after. Melatonin, cortisol, cortisone, progesterone, aldosterone, DHEA-S, testosterone and prolactin were measured by immunoassay. Results: The four adrenal glands expressed only MT1 receptor mRNA. Melatonin ingestión reduced the cortisol response to ACTH from 14.6+1.45µg/dl at 60 min in the placebo group to 10.8+1.2µg/dl in the melatonin group (p <0.01 mixed model test). It did not affect other steroid hormone levels and abolished the morningphysiological decline of prolactin. Conclusions: The expression ofMTl melatonin receptor in the human adrenal, and the melatonin reduction of ACTH-stimulated cortisol production suggest a direct melatonin action on the adrenal gland .

The Circadian Timing system: Making Sense of day/night gene expression

The circadian time-keeping system ensures predictive adaptation of individuals to the reproducible 24-h day/night alternations of our planet by generating the 24-h (circadian) rhythms found in hormone release and cardiovascular, biophysical and behavioral functions, and others. In mammals, the master clock resides in the suprachiasmatic nucleus (SCN) of the hypothalamus. The molecular events determining the functional oscillation of the SCN neurons with a period of 24-h involve recurrent expression of several clock proteins that interact in complex transcription/translation feedback loops. In mammals, a glutamatergic monosynaptic pathway originating from the retina regulaltes the clock gene expression pattern in the SCN neurons, synchronizing them to the light:dark cycle. The emerging concept is that neural/humoral output signals from the SCN impinge upon peripheral clocks located in other areas of the brain, heart, lung, gastrointestinal tract, liver, kidney, fibroblasts, and most of the cell phenotypes, resulting in overt circadian rhythms in integrated physiological functions. Here we review the impact of day/night alternation on integrated physiology; the molecular mechanisms and input/output signaling pathways involved in SCN circadian function; the current concept of peripheral clocks; and the potential role of melatonin as a circadian neuroendocrine transducer.