Diurnal variation in CREB phosphorylation and PER1 protein levels in lactotroph cells of melatonin-proficient C3H and melatonin-deficient C57BL mice: similarities and differences

The pineal hormone melatonin plays an important role in the maintenance of rhythmic functions of the hypophyseal pars tuberalis, which controls the lactotroph cells of the pars distalis. To analyze the effects of melatonin deficiency on the activity state of these cells, we have investigated the levels of Ser133-phosphorylated (p)CREB and PER1 protein in immunocytochemically identified lactotroph cells of melatonin-proficient C3H and melatonin-deficient C57BL mice at four different time points of a 12/12 LD cycle. At night, the percentage of lactotroph cells showing a positive nuclear pCREB and PER1 immunoreaction is significantly smaller in C57BL than in C3H mice. In both mouse strains, the percentage of pCREB-immunoreactive cells is minimal in the early morning and gradually increases to reach a maximum in the late night. PER1 levels show a parallel temporal variation in C3H, but in C57BL, they are drastically reduced in the early afternoon. The observation that, during darkness, the percentage of lactotroph cells with nuclear pCREB immunoreaction is significantly higher in C3H than in C57BL mice suggests the existence of a distinct cell population that is under the control of melatonin-dependent intrapituitary signaling. Interestingly, the percentage of pCREB- and PER1-immunoreactive lactotroph cells reaches minimal and maximal values at the same time points. This suggests that the correlation between CREB phosphorylation and PER1 induction differs between these cells and other neuroendocrine centers, e.g., the pineal organ and suprachiasmatic nucleus, displaying a temporal gap between CREB phosphorylation and PER1 induction.This study was supported by grants from the Deutsche Forschungsgemeinschaft (KO758/7-3)     

In vivo activation of insulin receptor tyrosine kinase by melatonin in the rat hypothalamus

Melatonin is the pineal hormone that acts via a pertussis toxin-sensitive G-protein to inhibit adenylate cyclase. However, the intracellular signalling effects of melatonin are not completely understood. Melatonin receptors are mainly present in the suprachiasmatic nucleus (SCN) and pars tuberalis of both humans and rats. The SCN directly controls, amongst other mechanisms, the circadian rhythm of plasma glucose concentration. In this study, using immunoprecipitation and immunoblotting, we show that melatonin induces rapid tyrosine phosphorylation and activation of the insulin receptor beta-subunit tyrosine kinase (IR) in the rat hypothalamic suprachiasmatic region. Upon IR activation, tyrosine phosphorylation of IRS-1 was detected. In addition, melatonin induced IRS-1/PI3-kinase and IRS-1/SHP-2 associations and downstream AKT serine phosphorylation and MAPK (mitogen-activated protein kinase) phosphorylation, respectively. These results not only indicate a new signal transduction pathway for melatonin, but also a potential cross-talk between melatonin and insulin.     

Sites and mechanisms of action of melatonin in mammals: the MT1 and MT2 receptors

The rhythmic secretion of melatonin by the pineal gland plays a key role in the synchronisation of circadian and seasonal functions with cyclic environmental variations. The biological effects of this neurohormone are relayed mainly by G-protein-coupled seven-transmembrane receptors. These receptors, known as MT1 and MT2, are present in a large number of central and peripheral structures in mammals, with considerable inter-species variations. However, only the suprachiasmatic nuclei of the hypothalamus, the site of the master circadian biological clock, and the pars tuberalis of the adenohypophysis contain melatonin receptors in the majority of species. Inhibition of the production of AMPc by a Gi/Go protein is one of the principal signalling pathways of the MT1 and MT2 receptors, although many other signal transduction pathways are also brought into play according to the cell type studied (PKC, Ca2+, K+ channels or GMPc in the case of MT2, etc.). Numerous factors or physiological stimuli are capable of influencing the number and functional status of the MT1 and MT2 receptors, such as melatonin, the photoperiod, the circadian clock or the phenomena of receptor dimerisation. Melatonin has numerous physiological effects for which the mechanisms of action and the specific role of the MT1 and MT2 receptors have not yet been clearly elucidated. However, selective pharmacological tools for each of the two receptor subtypes are currently being identified, notably in the Servier Group, for the purpose of furthering our knowledge of the functionality and physiological role of the MT1 and MT2 receptors in the central and peripheral structures.     

The avian pineal gland

The pineal gland plays a key role in the control of the daily and seasonal rhythms in most vertebrate species. In mammals, rhythmic melatonin (MT) release from the pineal gland is controlled by the suprachiasmatic nucleus via the sympathetic nervous system. In most non-mammalian species, including birds, the pineal gland contains a self-sustained circadian oscillator and several input channels to synchronize the clock, including direct light sensitivity. Avian pineal glands maintain rhythmic activity for days under in vitro conditions. Several physical (light, temperature, and magnetic field) and biochemical (Vasoactive intestinal polypeptide (VIP), norepinephrine, PACAP, etc.) input channels, influencing release of melatonin are also functional in vitro, rendering the explanted avian pineal an excellent model to study the circadian biological clock. Using a perifusion system, we here report that the phase of the circadian melatonin rhythm of the explanted chicken pineal gland can be entrained easily to photoperiods whose length approximates 24 h, even if the light period is extremely short, i.e., 3L:21D. When the length of the photoperiod significantly differs from 24 h, the endogenous MT rhythm becomes distorted and does not follow the light-dark cycle. When explanted chicken pineal fragments were exposed to various drugs targeting specific components of intracellular signal transduction cascades, only those affecting the cAMP-protein kinase-A system modified the MT release temporarily without phase-shifting the rhythm in MT release. The potential role of cGMP remains to be investigated.     

Molecular characterization of the long-day response in the Soay sheep, a seasonal mammal

In mammals, seasonal timekeeping depends on the generation of a nocturnal melatonin signal that reflects nightlength/daylength. To understand the mechanisms by which the melatonin signal is decoded, we studied the photoperiodic control of prolactin secretion in Soay sheep, which is mediated via melatonin responsive cells in the pars tuberalis of the pituitary. We demonstrate that the phases of peak expression of the clock genes Cryptochrome1 (Cry1), Period1 (Per1), and RevErbalpha respond acutely to altered melatonin secretion after a switch from short to long days. Cry1 is activated by melatonin onset, forming the dusk component of the molecular decoder, while Per1 expression at dawn reflects the offset of melatonin secretion. The Cry1-Per1 interval immediately adjusts to the melatonin signal on the first long day, and this is followed within 24 hr by an increase in prolactin secretion. The timing of peak RevErbalpha expression also responds to a switch to long days due to altered melatonin secretion but does not immediately reset to an entrained long-day state. These data suggest that effects of melatonin on clock gene expression are pivotal events in the neuroendocrine response and that pars tuberalis cells can act as molecular calendars, carrying a form of "photoperiodic memory."     

The Avian Pineal Gland

The pineal gland plays a key role in the control of the daily and seasonal rhythms in most vertebrate species. In mammals, rhythmic melatonin (MT) release from the pineal gland is controlled by the suprachiasmatic nucleus via the sympathetic nervous system. In most non‐mammalian species, including birds, the pineal gland contains a self‐sustained circadian oscillator and several input channels to synchronize the clock, including direct light sensitivity. Avian pineal glands maintain rhythmic activity for days under in vitro conditions. Several physical (light, temperature, and magnetic field) and biochemical (Vasoactive intestinal polypeptide (VIP), norepinephrine, PACAP, etc.) input channels, influencing release of melatonin are also functional in vitro, rendering the explanted avian pineal an excellent model to study the circadian biological clock. Using a perifusion system, we here report that the phase of the circadian melatonin rhythm of the explanted chicken pineal gland can be entrained easily to photoperiods whose length approximates 24 h, even if the light period is extremely short, i.e., 3L:21D. When the length of the photoperiod significantly differs from 24 h, the endogenous MT rhythm becomes distorted and does not follow the light‐dark cycle. When explanted chicken pineal fragments were exposed to various drugs targeting specific components of intracellular signal transduction cascades, only those affecting the cAMP‐protein kinase‐A system modified the MT release temporarily without phase‐shifting the rhythm in MT release. The potential role of cGMP remains to be investigated.     

Photic regulation of mt(1) melatonin receptors and 2-iodomelatonin binding in the rat and Siberian hamster

We have investigated the photic regulation of melatonin receptors both at the level of binding capacity and mt(1) mRNA expression in the suprachiasmatic nucleus (SCN) and the pars tuberalis (PT) of the pituitary of two species: a highly photoperiodic one, the Siberian hamster, and a nonphotoperiodic one, the Wistar rat. This study has been performed by looking at the effect of a light pulse applied during the night on the two receptor parameters. The results show that the photic regulations of mt(1) mRNA expression and receptor density are distinct from each other in both the SCN and PT of the two species studied. They also show that, depending on the species and the structure, this regulation may implicate either the circadian clock or melatonin.     

The distribution of melatonin binding sites in neuroendocrine tissues of the ewe

Specific high-affinity binding of 2-[125I]iodomelatonin (IMEL) was examined in 20-micrometer sections prepared from intact Suffolk ewes killed during late anestrus or the breeding season. The pars tuberalis contained by far the highest concentration of IMEL binding sites of all areas studied. Within the telencephalon, intense labeling was found in the mediolateral septum, the ventrolateral septal and septohypothalamic nuclei, the entorhinal cortex, the subiculum, and the inner and outer molecular layers of the hippocampus adjacent to the dentate gyrus. Melatonin binding in the medial preoptic nucleus, bed nucleus of the stria terminalis, and medial preoptic area was less striking but still distinct. Among diencephalic regions, melatonin binding sites existed in low concentrations in the anterior hypothalamus, the tuberal medial basal hypothalamus, and the paraventricular thalamic and supramammillary nuclei. Little binding was evident in the suprachiasmatic or ventromedial nuclei. In the midbrain, significant binding was restricted to the ventral raphe complex and the inferior colliculus. Little specific binding was found in the pars distalis or the pineal gland. The distribution of melatonin binding in the sheep brain is discussed in the context of the influence of this pineal hormone upon seasonal changes in neuroendocrine function.     

Circadian Clock Gene Per2 Is Not Necessary for the Photoperiodic Response in Mice

In mammals, light information received by the eyes is transmitted to the pineal gland via the circadian pacemaker, i.e., the suprachiasmatic nucleus (SCN). Melatonin secreted by the pineal gland at night decodes night length and regulates seasonal physiology and behavior. Melatonin regulates the expression of the β-subunit of thyroid-stimulating hormone (TSH; Tshb) in the pars tuberalis (PT) of the pituitary gland. Long day-induced PT TSH acts on ependymal cells in the mediobasal hypothalamus to induce the expression of type 2 deiodinase (Dio2) and reduce type 3 deiodinase (Dio3) that are thyroid hormone-activating and hormone-inactivating enzymes, respectively. The long day-activated thyroid hormone T₃ regulates seasonal gonadotropin-releasing hormone secretion. It is well established that the circadian clock is involved in the regulation of photoperiodism. However, the involvement of the circadian clock gene in photoperiodism regulation remains unclear. Although mice are generally considered non-seasonal animals, it was recently demonstrated that mice are a good model for the study of photoperiodism. In the present study, therefore, we examined the effect of changing day length in Per2 deletion mutant mice that show shorter wheel-running rhythms under constant darkness followed by arhythmicity. Although the amplitude of clock gene (Per1, Cry1) expression was greatly attenuated in the SCN, the expression profile of arylalkylamine N-acetyltransferase, a rate-limiting melatonin synthesis enzyme, was unaffected in the pineal gland, and robust photoperiodic responses of the Tshb, Dio2, and Dio3 genes were observed. These results suggested that the Per2 clock gene is not necessary for the photoperiodic response in mice.     

Hes1 regulates formations of the hypophyseal pars tuberalis and the hypothalamus

The hypophyseal pars tuberalis surrounds the median eminence and infundibular stalk of the hypothalamus as thin layers of cells. The pars tuberalis expresses MT1 melatonin receptor and participates in mediating the photoperiodic secretion of pituitary hormones. Both the rostral tip of Rathke’s pouch (pars tuberalis primordium) and the pars tuberalis expressed αGSU mRNA, and were immunoreactive for LH, chromogranin A, and TSHβ in mice. Hes genes control progenitor cell differentiation in many embryonic tissues and play a crucial role for neurulation in the central nervous system. We investigated the Hes1 function in outgrowth and differentiation of the pars tuberalis by using the markers for the pars tuberalis. In homozygous Hes1 null mutant embryos, the rostral tip was formed in the basal-ventral part of Rathke’s pouch at embryonic day (E)11.5 as well as in wild-type embryos. In contrast to the wild-type, the rostral tip of null mutants could not extend rostrally with age; it remained in the low extremity of Rathke’s pouch during E12.5–E13.5 and disappeared at E14.5, resulting in lack of the pars tuberalis. Development of the ventral diencephalon was impaired in the null mutants at early stages. Rathke’s pouch, therefore, could not link with the nervous tissue and failed to receive inductive signals from the diencephalon. In a very few mutant mice in which the ventral diencephalon was partially sustained, some pars tuberalis cells were distributed around the hypoplastic infundibulum. Thus, Hes1 is required for development of the pars tuberalis and its growth is dependent on the ventral diencephalon.     

Pineal circadian clocks gate arylalkylamine N-acetyltransferase gene expression in the mouse pineal gland

In mammals it has been thought that the circadian clock localizes only in the suprachiasmatic nucleus of the hypothalamus. Recent studies have revealed that certain brain regions and peripheral tissues may also have intrinsic circadian clocks. However, the roles played by 'peripheral circadian clocks' have not been fully elucidated. In this study, we investigated their function using mouse pineal glands, and found that expression of the arylalkylamine N-acetyltransferase (Aa-Nat, EC 2.3.1.87, the rate-limiting enzyme of melatonin synthesis) gene after adrenergic receptor stimulation depended on the time of day even in vitro (gating). Phase-dependent Aa-Nat responses were observed in both melatonin-proficient and melatonin-deficient mouse pineal glands. Phosphodiesterases are unlikely to suppress Aa-Nat induction because a phosphodiesterase inhibitor itself had no effect on the mRNA levels. Puromycin was ineffective in inducing Aa-Nat mRNA levels in either the presence or absence of isoproterenol, suggesting that newly synthesized proteins may not be necessary to gate the Aa-Nat responses. We also discovered circadian dependence of the expression of Period1-luminescence in Period1-luciferase transgenic mouse pineal glands: circadian clocks may be functional in culture. Aa-Nat mRNA levels showed no significant circadian rhythms in the absence of isoproterenol, thus suggesting that Aa-Nat mRNA levels are induced by adrenergic mechanisms, not by a pineal circadian clock. Our results suggest that the pineal circadian clock may determine timing when Aa-Nat gene expression can respond to inputs from the master circadian clock in the suprachiasmatic nucleus, e.g. adrenergic stimulation.     

Ancestral TSH mechanism signals summer in a photoperiodic mammal

In mammals, day-length-sensitive (photoperiodic) seasonal breeding cycles depend on the pineal hormone melatonin, which modulates secretion of reproductive hormones by the anterior pituitary gland [1]. It is thought that melatonin acts in the hypothalamus to control reproduction through the release of neurosecretory signals into the pituitary portal blood supply, where they act on pituitary endocrine cells [2]. Contrastingly, we show here that during the reproductive response of Soay sheep exposed to summer day lengths, the reverse applies: Melatonin acts directly on anterior-pituitary cells, and these then relay the photoperiodic message back into the hypothalamus to control neuroendocrine output. The switch to long days causes melatonin-responsive cells in the pars tuberalis (PT) of the anterior pituitary to increase production of thyrotrophin (TSH). This acts locally on TSH-receptor-expressing cells in the adjacent mediobasal hypothalamus, leading to increased expression of type II thyroid hormone deiodinase (DIO2). DIO2 initiates the summer response by increasing hypothalamic tri-iodothyronine (T3) levels. These data and recent findings in quail [3] indicate that the TSH-expressing cells of the PT play an ancestral role in seasonal reproductive control in vertebrates. In mammals this provides the missing link between the pineal melatonin signal and thyroid-dependent seasonal biology.     

Molecular components and mechanism of adrenergic signal transduction in mammalian pineal gland: regulation of melatonin synthesis

Rhythmic neural outputs from the hypothalamic suprachiasmatic nucleus (SCN), which programme the rhythmic release of norepinephrine (NE) from intrapineal nerve fibers, regulate circadian rhythm of melatonin synthesis. Increased secretion of NE with the onset of darkness during the first half of night stimulates melatonin synthesis by several folds. NE binds to both alpha1- and beta-adrenergic receptors present on the pinealocyte membrane and initiates adrenergic signal transduction via cyclic adenosine monophosphate (cAMP) and cyclic guanosine monophosphate (cGMP) generating pathways. The NE-induced adrenergic signal transduction switches 'on' melatonin synthesis during the early hours of night by stimulating expression of the rate-limiting enzyme of melatonin synthesis, N-acetyltransferase (AA-NAT) via cAMP-protein kinase A (PKA)-cAMP response element binding protein (CREB)-cAMP response element (CRE) pathway as well as by increasing AA-NAT activity via cAMP-PKA-14-3-3 protein pathway. Simultaneously, adrenergically-induced expression of inducible cAMP early repressor (ICER) negatively regulates aa-nat gene expression and controls the amplitude of melatonin rhythm. In the second half of night, increased release of acetylcholine from central pinealopetal projections, inhibition of NE secretion by SCN, withdrawal of adrenergic inputs and reversal of events that took place in the first half lead to switching 'off' of melatonin synthesis. Adrenergic signal transduction via cGMP-protein kinase G (PKG)-mitogen activated protein kinase (MAPK)-ribosomal S6 kinase (RSK) pathway also seems to be fully functional, but its role in modulation of melatonin synthesis remains unexplored. This article gives a critical review of information available on various components of the adrenergic signal transduction cascades involved in the regulation of melatonin synthesis.     

Melatonin receptors and signal transduction mechanisms

The ovine pars tuberalis (PT) still offers the best model for the study of signal transduction pathways regulated by the melatonin receptor. From the evidence accumulated so far, it seems likely that the cAMP signal transduction pathway will be a major effector of a stimulatory signal to the PT which can be regulated by melatonin. Thus a principal action of melatonin in the PT may be the repression of biochemical processes driven by cAMP. However, through the phenomenon of sensitization, melatonin may also act to amplify a stimulatory input to the cAMP signal transduction pathway in the PT. These events are mediated via the melatonin receptor, which is itself a target for regulation by the melatonin signal. Studies using the PT have identified several signalling pathways that may serve to positively or negatively regulate the expression of the melatonin receptor. These and other studies in the PT have alluded to cAMP-independent pathways regulated by the melatonin receptor.