Daily rhythm and regulation of clock gene expression in the rat pineal gland.

Rhythms in pineal melatonin synthesis are controlled by the biological clock located in the suprachiasmatic nuclei. The endogenous clock oscillations rely upon genetic mechanisms involving clock genes coding for transcription factors working in negative and positive feedback loops. Most of these clock genes are expressed rhythmically in other tissues. Because of the peculiar role of the pineal gland in the photoneuroendocrine axis regulating biological rhythms, we studied whether clock genes are expressed in the rat pineal gland and how their expression is regulated.Per1, Per3, Cry2 and Cry1 clock genes are expressed in the pineal gland and their transcription is increased during the night. Analysis of the regulation of these pineal clock genes indicates that they may be categorized into two groups. Expression of Per1 and Cry2 genes shows the following features: (1) the 24 h rhythm persists, although damped, in constant darkness; (2) the nocturnal increase is abolished following light exposure or injection with a beta-adrenergic antagonist; and (3) the expression during daytime is stimulated by an injection with a beta-adrenergic agonist. In contrast, Per3 and Cry1 day and night mRNA levels are not responsive to adrenergic ligands (as previously reported for Per2) and daily expression of Per3 and Cry1 appears strongly damped or abolished in constant darkness. These data show that the expression of Per1 and Cry2 in the rat pineal gland is regulated by the clock-driven changes in norepinephrine, in a similar manner to the melatonin rhythm-generating enzyme arylalkylamine N-acetyltransferase. The expression of Per3 and Cry1 displays a daily rhythm not regulated by norepinephrine, suggesting the involvement of another day/night regulated transmitter(s).

Syrian hamster and rat display developmental differences in the regulation of pineal arylalkylamine N-acetyltransferase.

In the Syrian hamster, the role of noradrenaline in the regulation of melatonin synthesis is less clear than in the rat. During pineal ontogenesis in the rat, noradrenaline is the major transmitter involved in the onset of melatonin synthesis and melatonin rhythm. We analysed the involvement of noradrenaline in the ontogenesis of melatonin synthesis in the Syrian hamster and compared it with that of the rat. We followed the developmental profile of melatonin content in parallel with those of mRNA expression and activity of AA-NAT, the melatonin rhythm-generating enzyme. In addition, we tested the effect of noradrenergic drugs at early steps of pineal ontogenesis. In the Syrian hamster, the night-time Aa-nat mRNA, first detected 3 days after birth, increases progressively up to a maximum reached at 30 days of age and then decreases significantly towards adulthood. The daytime level of Aa-nat mRNA remains always low. A significant day/night rhythm appears 10 days after birth, is maximal (200-fold nocturnal increase) 30 days after birth and decreases slowly towards adulthood. Ontogenesis of the AA-NAT activity rhythm is similar, although with a much lower amplitude of day/night variations (four-fold). The developmental pattern of melatonin content is similar to that of AA-NAT and could be correlated with the appearance of sympathetic innervation in the pineal gland. However, neither alpha- nor beta-adrenergic antagonists inhibit the night-time Aa-nat mRNA transcription in the 9-day-old Syrian hamster, in contrast to what is observed in the adult. For comparison, the beta-adrenergic antagonist propranolol inhibits Aa-nat gene expression in 2-day-old rat. These results show that both species are different in the regulation of the appearance of melatonin synthesis and that Syrian hamster is peculiar from birth in term of noradrenaline involvement in the activation of melatonin synthesis.

In vivo observation of a non-noradrenergic regulation of arylalkylamine N-acetyltransferase gene expression in the rat pineal complex.

The rodent pineal gland is the end point of several peripheral and central fibers innervating the superficial and deep parts of the gland. Up to now, only the sympathetic transmitter norepinephrine is thought to regulate melatonin synthesis, although numerous biochemical experiments have reported in vitro effects of various transmitters on melatonin synthesis. To find out whether there is non-noradrenergic regulation of in vivo pineal metabolism, the mRNA encoding the enzyme arylalkylamine N-acetyltransferase was studied using the highly sensitive technique of in situ hybridization. The existence of a marked nocturnal increase of arylalkylamine N-acetyltransferase mRNA in the superficial pineal gland was confirmed. Interestingly and for the first time, a similar daily variation was observed in the deep pineal. After removal of superior cervical ganglia, the daily rhythm in arylalkylamine N-acetyltransferase mRNA was abolished in both the superficial and deep pineal indicating that the rhythm is driven by sympathetic input in the entire pineal complex. Interestingly, the remaining arylalkylamine N-acetyltransferase mRNA level in the pineal of day- and night-time ganglionectomized rats was significantly higher than in the pineal of day-time intact animals. These data reveal a sympathetic-dependent day-time inhibition of arylalkylamine N-acetyltransferase gene expression. In addition, the day-time pineal arylalkylamine N-acetyltransferase mRNA expression in ganglionectomized rats persisted after adrenal gland removal but was reduced by 50% after propranolol injection. These results indicate that arylalkylamine N-acetyltransferase mRNA in ganglionectomized rats is not induced by circulating catecholamines and may be caused by both a centrally originated norepinephrine, as already suggested, and other non-adrenergic transmitter(s). In conclusion, this work shows that norepinephrine drives the nocturnal increase of arylalkylamine N-acetyltransferase gene expression both in the superficial and deep pineal and strongly suggests that other neurotransmitters are involved in day-time inhibition and night-time stimulation of pineal metabolism.

Melatonin sees the light: blocking GABA-ergic transmission in the paraventricular nucleus induces daytime secretion of melatonin.

Despite a pronounced inhibitory effect of light on pineal melatonin synthesis, usually the daily melatonin rhythm is not a passive response to the surrounding world. In mammals, and almost every other vertebrate species studied so far, the melatonin rhythm is coupled to an endogenous pacemaker, i.e. a circadian clock. In mammals the principal circadian pacemaker is located in the suprachiasmatic nuclei (SCN), a bilateral cluster of neurons in the anterior hypothalamus. In the present paper we show in the rat that bilateral abolition of gamma-aminobutyric acid (GABA), but not vasopressin, neurotransmission in an SCN target area, i.e. the paraventricular nucleus of the hypothalamus, during (subjective) daytime results in increased pineal melatonin levels. The fact that complete removal of the SCN results in a pronounced increase of daytime pineal mRNA levels for arylalkylamine N-acetyltransferase (AA-NAT), i.e. the rate-limiting enzyme of melatonin synthesis, further substantiates the existence of a major inhibitory SCN output controlling the circadian melatonin rhythm.

Molecular cloning of the arylalkylamine-N-acetyltransferase and daily variations of its mRNA expression in the Syrian hamster pineal gland.

The arylalkylamine-N-acetyltransferase (AA-NAT) expressed in the vertebrate pineal gland catalyzes the N-acetylation of the serotonin into N-acetylserotonin and is considered to be the rate limiting enzyme of the pineal melatonin synthesis. Indeed, dramatic changes in its activity throughout the 24-h period drive the large day/night variations in plasma melatonin concentrations. Recently, AA-NAT was cloned in the rat pineal. In this species, AA-NAT mRNA variations were demonstrated to be responsible of the well known AA-NAT activity and plasma melatonin circadian fluctuations. In the Syrian hamster, the pineal melatonin secretion pattern is characterized by a late-night short-duration peak of melatonin synthesis. We investigated whether this typical pattern could be due to a late-night delayed pineal AA-NAT mRNA expression. The first part of our study was dedicated to the molecular cloning of a Syrian hamster AA-NAT cDNA. A PCR-generated clone of 1045 bp encoding the AA-NAT has been isolated and sequenced. In situ hybridization using an AA-NAT cRNA probe revealed that the AA-NAT mRNA expression undergoes strong daily fluctuations in the Syrian hamster pineal, with undetectable level in the second half of the light period and a dramatic increase at night. After lights off, the AA-NAT mRNA expression requires 6-7 h to reach its maximum expression. This result thus suggests that the transcription of the AA-NAT mRNA in the Syrian pineal gland determines the lag period in pineal responsiveness and melatonin synthesis to darkness.

Photoperiodic control of the rat pineal arylalkylamine-N-acetyltransferase and hydroxyindole-O-methyltransferase gene expression and its effect on melatonin synthesis.

Photoperiodic changes of pineal melatonin (MEL) profile are accompanied by parallel changes of arylalkylamine-N-acetyltransferase (AA-NAT) activity. In the present study, the authors investigated, for the first time, whether two other important variables of pineal metabolism, AA-NAT and hydroxyindole-O-methyltransferase (HIOMT) gene expression, also may be affected by the photoperiod. Evening rises in AA-NAT and HIOMT mRNA and in circulating MEL occurred concomitantly with an increased delay from dark onset as scotophase shortened. On the opposite, the morning declines of all three variables occurred with different kinetics but were locked to light onset. These observations demonstrate that the daily rhythms in AA-NAT and HIOMT gene expression are modulated by the photoperiod and bring further evidence in favor of nor adrenaline as the possible link between the endogenous clock and MEL. Interestingly, the duration of the nocturnal peak in HIOMT mRNA was positively correlated with HIOMT activity. In conclusion, this study adds two important links to the chain of mechanisms involved in the photoperiodic control of pineal metabolism. First, photoperiodic modulation of the MEL rhythm primarily results from changes in the AA-NAT gene expression. Second, the photoperiodic regulation of HIOMT activity occurs at the transcriptional level.