Showing papers on "Pinealocyte published in 2002"

Circadian rhythms in isolated brain regions.

Abstract: The suprachiasmatic nucleus (SCN) of the mammalian hypothalamus has been referred to as the master circadian pacemaker that drives daily rhythms in behavior and physiology. There is, however, evidence for extra-SCN circadian oscillators. Neural tissues cultured from rats carrying the Per-luciferase transgene were used to monitor the intrinsic Per1 expression patterns in different brain areas and their response to changes in the light cycle. Although many Per-expressing brain areas were arrhythmic in culture, 14 of the 27 areas examined were rhythmic. The pineal and pituitary glands both expressed rhythms that persisted for >3 d in vitro, with peak expression during the subjective night. Nuclei in the olfactory bulb and the ventral hypothalamus expressed rhythmicity with peak expression at night, whereas other brain areas were either weakly rhythmic and peaked at night, or arrhythmic. After a 6 hr advance or delay in the light cycle, the pineal, paraventricular nucleus of the hypothalamus, and arcuate nucleus each adjusted the phase of their rhythmicity with different kinetics. Together, these results indicate that the brain contains multiple, damped circadian oscillators outside the SCN. The phasing of these oscillators to one another may play a critical role in coordinating brain activity and its adjustment to changes in the light cycle.

Mammalian melatonin receptors: molecular biology and signal transduction.

Abstract: The pineal hormone, melatonin, is an important regulator of seasonal reproduction and circadian rhythms. Its effects are mediated via high-affinity melatonin receptors, located on cells of the pituitary pars tuberalis (PT) and suprachiasmatic nucleus (SCN), respectively. Two subtypes of mammalian melatonin receptors have been cloned and characterized, the MT1 (Mel1a) and the MT2 (Mel1b) melatonin receptor subtypes. Both subtypes are members of the seven-transmembrane G protein-coupled receptor family. By using recombinant melatonin receptors it has been shown that the MT1 melatonin receptor is coupled to different G proteins that mediate adenylyl cyclase inhibition and phospholipase Cβ activation. The MT2 receptor is also coupled to inhibition of adenylyl cyclase and additionally it inhibits the soluble guanylyl cyclase pathway. In mice with a targeted deletion of the MT1 receptor, the acute inhibitory effects of melatonin on SCN multiunit activity are completely abolished, while the phase-shifting responses to melatonin (given in physiological concentrations) appear normal. Furthermore, melatonin inhibits the phosphorylation of the transcription factor cyclic AMP response element binding protein, induced by the pituitary adenylate cyclase-activating polypeptide in SCN cells predominantly via the MT1 receptor. However, a functional MT2 receptor in the rodent SCN is partially able to compensate for the absence of the MT1 receptor in MT1 receptor-deficient mice. These findings indicate redundant and non-redundant roles of the receptor subtypes in regulating SCN function. In the PT, a functional MT1 receptor is essential for the rhythmic synthesis of the clock gene product mPER1. Melatonin produces a long-lasting sensitization of adenylyl cyclase and thus amplifies cyclic AMP signaling when melatonin levels decline at dawn. This action of melatonin amplifies gene expression rhythms in the PT and provides a mechanism for reinforcing rhythmicity in peripheral tissues which themselves lack the capacity for self-sustained oscillation. Mice with targeted deletion of melatonin receptor subtypes provide an excellent model to understand cellular mechanisms through which melatonin modulates circadian and photoperiodic rhythmicity.

Control of melatonin synthesis in the mammalian pineal gland: the critical role of serotonin acetylation.

Abstract: The large daily rhythm in circulating melatonin levels is a highly conserved feature of vertebrate physiology: high values always occur at night. The dynamics of the rhythm are controlled by the next-to-last enzyme in melatonin synthesis (serotonin → N-acetylserotonin → melatonin), arylalkylamine N-acetyltransferase (AANAT), the "melatonin rhythm enzyme". In vertebrate biology, AANAT plays a unique time-keeping role as the molecular interface between the environment and the hormonal signal of time, melatonin. This chapter describes the mammalian AANAT regulatory system, which includes the retina, neural structures, transsynaptic processes, and molecular events. In addition, special attention is paid to the functional characteristics of the systems which insure that the nocturnal increase in melatonin is an accurate and reliable indicator of the duration of the night, and why the melatonin rhythm is the most reliable output signal of the Mind's Clock.

The anatomy and innervation of the mammalian pineal gland.

Abstract: The parenchymal cells of the mammalian pineal gland are the hormone-producing pinealocytes and the interstitial cells. In addition, perivascular phagocytes are present. The phagocytes share antigenic properties with microglial and antigen-presenting cells. In certain species, the pineal gland also contains neurons and/or neuron-like peptidergic cells. The peptidergic cells might influence the pinealocyte by a paracrine secretion of the peptide. Nerve fibers innervating the mammalian pineal gland originate from perikarya located in the sympathetic superior cervical ganglion and the parasympathetic sphenopalatine and otic ganglia. The sympathetic nerve fibers contain norepinephrine and neuropeptide Y as neurotransmitters. The parasympathetic nerve fibers contain vasoactive intestinal peptide and peptide histidine isoleucine. Recently, neurons in the trigeminal ganglion, containing substance P, calcitonin gene-related peptide, and pituitary adenylate cyclase-activating peptide, have been shown to project to the mammalian pineal gland. Finally, nerve fibers originating from perikarya located in the brain containing, for example, GABA, orexin, serotonin, histamine, oxytocin, and vasopressin innervate the pineal gland directly via the pineal stalk. Biochemical studies have demonstrated numerous receptors on the pinealocyte cell membrane, which are able to bind the neurotransmitters located in the pinealopetal nerve fibers. These findings indicate that the mammalian pinealocyte can be influenced by a plethora of neurotransmitters.

Nonvisual photoreceptors of the deep brain, pineal organs and retina.

Abstract: The role of the nonvisual photoreception is to synchronise periodic functions of living organisms to the environmental light periods in order to help survival of various species in different biotopes. In vertebrates, the so-called deep brain (septal and hypothalamic) photoreceptors, the pineal organs (pineal- and parapineal organs, frontal- and parietal eye) and the retina (of the "lateral" eye) are involved in the light-based entrain of endogenous circadian clocks present in various organs. In humans, photoperiodicity was studied in connection with sleep disturbances in shift work, seasonal depression, and in jet-lag of transmeridional travellers. In the present review, experimental and molecular aspects are discussed, focusing on the histological and histochemical basis of the function of nonvisual photoreceptors. We also offer a view about functional changes of these photoreceptors during pre- and postnatal development as well as about its possible evolution. Our scope in some points is different from the generally accepted views on the nonvisual photoreceptive systems. The deep brain photoreceptors are hypothalamic and septal nuclei of the periventricular cerebrospinal fluid (CSF)-contacting neuronal system. Already present in the lancelet and representing the most ancient type of vertebrate nerve cells ("protoneurons"), CSF-contacting neurons are sensory-type cells sitting in the wall of the brain ventricles that send a ciliated dendritic process into the CSF. Various opsins and other members of the phototransduction cascade have been demonstrated in telencephalic and hypothalamic groups of these neurons. In all species examined so far, deep brain photoreceptors play a role in the circadian and circannual regulation of periodic functions. Mainly called pineal "glands" in the last decades, the pineal organs actually represent a differentiated form of encephalic photoreceptors. Supposed to be intra- and extracranially outgrown groups of deep brain photoreceptors, pineal organs also contain neurons and glial elements. Extracranial pineal organs of submammalians are cone-dominated photoreceptors sensitive to different wavelengths of light, while intracranial pineal organs predominantly contain rod-like photoreceptor cells and thus scotopic light receptors. Vitamin B-based light-sensitive cryptochromes localized immunocytochemically in some pineal cells may take part in both the photoreception and the pacemaker function of the pineal organ. In spite of expressing phototransduction cascade molecules and forming outer segment-like cilia in some species, the mammalian pineal is considered by most of the authors as a light-insensitive organ. Expression of phototransduction cascade molecules, predominantly in young animals, is a photoreceptor-like characteristic of pinealocytes in higher vertebrates that may contribute to a light-percepting task in the perinatal entrainment of rhythmic functions. In adult mammals, adrenergic nerves--mediating daily fluctuation of sympathetic activity rather than retinal light information as generally supposed--may sustain circadian periodicity already entrained by light perinatally. Altogether three phases were supposed to exist in pineal entrainment of internal pacemakers: an embryological synchronization by light and in viviparous vertebrates by maternal effects (1); a light-based, postnatal entrainment (2); and in adults, a maintenance of periodicity by daily sympathetic rhythm of the hypothalamus. In addition to its visual function, the lateral eye retina performs a nonvisual task. Nonvisual retinal light perception primarily entrains genetically-determined periodicity, such as rod-cone dominance, EEG rhythms or retinomotor movements. It also influences the suprachiasmatic nucleus, the primary pacemaker of the brain. As neither rods nor cones seem to represent the nonvisual retinal photoreceptors, the presence of additional photoreceptors has been supposed. Cryptochrome 1, a photosensitive molecule identified in retinal nerve cells and in a subpopulation of retinal photoreceptors, is a good candidate for the nonvisual photoreceptor molecule as well as for a member of pacemaker molecules in the retina. When comparing various visual and nonvisual photoreceptors, transitory, "semi visual" (directional) light-perceptive cells can be detected among them, such as those in the parietal eye of reptiles. Measuring diffuse light intensity of the environment, semivisual photoreceptors also possess some directional light perceptive capacity aided by complementary lens-like structures, and screening pigment cells. Semivisual photoreception in aquatic animals may serve for identifying environmental areas of suitable illumination, or in poikilotermic terrestrial species for measuring direct solar irradiation for thermoregulation. As directional photoreceptors were identified among nonvisual light perceptive cells in the lancelet, but eyes are lacking, an early appearance of semivisual function, prior to a visual one (nonvisual --> semivisual --> visual?) in the vertebrate evolution was supposed.

Distribution of melatonin MT1 receptor immunoreactivity in human retina.

Abstract: Melatonin is synthesized in the pineal gland and retina during the night Retinal melatonin is believed to be involved in local cellular modulation and in regulation of light-induced entrainment of circadian rhythms The present study provides the first immunohistochemical evidence for the localization of melatonin 1a-receptor (MT1) in human retina of aged subjects Ganglion, amacrine, and photoreceptor cells expressed MT1 In addition, MT1 immunoreactivity was localized to cell processes in the inner plexiform layer and to central vessels of the retina, as well as to retinal vessels but not to ciliary or choroidal vessels These results support a variety of cellular and vascular effects of melatonin in the human retina Preliminary evidence from patients with Alzheimer's disease (AD) revealed increased MT1 immunoreactivity in ganglion and amacrine cells, as well as in vessels In AD cases photoreceptor cells were degenerated and showed low MT1 expression

Genetic targeting: the serotonin N-acetyltransferase promoter imparts circadian expression selectively in the pineal gland and retina of transgenic rats.

Abstract: The arylalkylamine N-acetyltransferase (AA-NAT) gene is strongly expressed in the rat primarily in the pineal gland; low levels of expression are also found in the retina. AA-NAT catalyzes the key regulatory step controlling rhythmic melatonin output: the acetylation of serotonin. In the rat, the AA-NAT gene is expressed at night. This is controlled partly by cyclic AMP (cAMP) acting through a composite cAMP-responsive element-CCAAT site located upstream of the transcription start point. In the present study, we have extended our previous in vitro findings and found that additional elements in the 5' flanking region and first intron play an important role in the regulation of the AA-NAT gene. This led us to test the influence of an AA-NAT 5' flanking segment on the expression of the bacterial chloramphenicol acetyltransferase gene in a rat transgenic model. The results of this study clearly demonstrate that the segment of the AA-NAT gene that encompasses the minimal promoter and the first intron is able to confer the highly specific pineal/ retinal and time-of-day patterns of AA-NAT gene expression. This advance also provides a tool that selectively targets genetic expression to pinealocytes and retinal photoreceptors, providing new experimental opportunities to probe aene exoression in these tissues.

Melatonin Synthesis Enzymes in Macaca mulatta: Focus on Arylalkylamine N-Acetyltransferase (EC 2.3.1.87)

Abstract: Arylalkylamine N-acetyltransferase (AANAT; serotonin N-acetyltransferase, EC 2.3.1.87) plays a unique transduction role in vertebrate physiology as the key interface between melatonin production and regulatory mechanisms. Circulating melatonin is elevated at night in all vertebrates, because AANAT activity increases in the pineal gland in response to signals from the circadian clock. Circadian regulation of melatonin synthesis is implicated in a variety of human problems, including jet lag, shift work, insomnia, and abnormal activity rhythms in blind persons. In this report AANAT was studied in the rhesus macaque to better understand human melatonin regulation. AANAT mRNA is abundant in the pineal gland and retina, but not elsewhere; AANAT mRNA is uniformly distributed in the pineal gland, but is limited primarily to the photoreceptor outer segments in the retina. Day and night levels of pineal and retinal AANAT mRNA are similar. In contrast, AANAT activity and protein increase more than 4-fold at night in both tissues. The activity of hydroxyindole-O-methyltransferase, the last enzyme in melatonin synthesis, is tonically high in the pineal gland, but is nearly undetectable in the retina; hydroxyindole O-methyltransferase mRNA levels exhibited a similar pattern. This supports the view that the source of circulating melatonin in primates is the pineal gland. The discovery in this study that rhesus pineal AANAT mRNA is high at all times is of special importance because it shows that posttranscriptional control of this enzyme plays a dominant role in regulating melatonin synthesis.

The Mouse Crx 5′-Upstream Transgene Sequence Directs Cell-Specific and Developmentally Regulated Expression in Retinal Photoreceptor Cells

Abstract: Crx, an Otx-like homeobox gene, is expressed primarily in the photoreceptors of the retina and in the pinealocytes of the pineal gland. The CRX homeodomain protein is a transactivator of many photoreceptor/pineal-specific genes in vivo, such as rhodopsin and the cone opsins. Mutations in Crx are associated with the retinal diseases, cone-rod dystrophy-2, retinitis pigmentosa, and Leber's congenital amaurosis, which lead to loss of vision. We have generated transgenic mice, using 5'- and/or 3'-flanking sequences from the mouse Crx homeobox gene fused to the beta-galactosidase (lacZ) reporter gene, and we have investigated the promoter function of the cell-specific and developmentally regulated expression of Crx. All of the independent transgenic lines commonly showed lacZ expression in the photoreceptor cells of the retina and in the pinealocytes of the pineal gland. We characterized the transgenic lines in detail for cell-specific lacZ expression patterns by 5-bromo-4-chloro-3-indolyl beta-D-galactoside staining and lacZ immunostaining. The lacZ expression was observed in developing and developed photoreceptor cells. This observation was confirmed by coimmunostaining of dissociated retinal cells with the lacZ and opsin antibodies. The ontogeny analysis indicated that the lacZ expression completely agrees with a temporal expression pattern of Crx during retinal development. This study demonstrates that the mouse Crx 5'-upstream genomic sequence is capable of directing a cell-specific and developmentally regulated expression of Crx in photoreceptor cells.

Selective adrenergic/cyclic AMP-dependent switch-off of proteasomal proteolysis alone switches on neural signal transduction: an example from the pineal gland.

Abstract: The molecular processes underlying neural transmission are central issues in neurobiology. Here we describe a novel mechanism through which noradrenaline (NA) activates its target cells, using the mammalian pineal organ as a model. In this neuroendocrine transducer, NA stimulates arylalkylamine N-acetyltransferase (AANAT; EC 2.3.1.87), the key enzyme regulating the nocturnal melatonin production. In rodents, AANAT protein accumulates as a result of enhanced transcription, but in primates and ungulates, the AANAT mRNA level fluctuates only marginally, indicating that other mechanisms regulate AANAT protein and activity. These were investigated in cultured bovine pinealocytes. AANAT mRNA was readily detectable in unstimulated pinealocytes, and levels did not change following NA treatment. In contrast, NA increased AANAT protein levels in parallel with AANAT activity, apparently through a cyclic AMP-mediated mechanism. Immunocytochemistry revealed that the changes in AANAT protein levels occurred in virtually all pinealocytes. Inhibition of AANAT degradation by proteasomal proteolysis alone was found to switch-on enzyme activity by increasing AANAT protein levels five- to 10-fold. Accordingly, under unstimulated conditions AANAT protein is continually synthesized and immediately destroyed by proteasomal proteolysis. NA appears to act via cyclic AMP to protect AANAT from proteolytic destruction, resulting in accumulation of the protein. These findings show that tightly regulated control of proteasomal proteolysis of a specific protein alone can play a pivotal role in neural regulation.

Circadian clock system in the pineal gland

Abstract: The pineal gland is a neuroendocrine organ that functions as a central circadian oscillator in a variety of nonmammalian vertebrates. In many cases, the pineal gland retains photic input and endocrinal-output pathways both linked tightly to the oscillator. This contrasts well with the mammalian pineal gland equipped only with the output of melatonin production that is subject to neuronal regulation by central circadian oscillator located in the suprachiasmatic nucleus (SCN) of the hypothalamus. Molecular studies on animal clock genes were performed first in Drosophila and later developed in rodents. More recently, clock genes such as Per, Cry, Clock, and Bmal have been found in a variety of vertebrate clock structures including the avian pineal gland. The profiles of the temporal change of the clock gene expression in the avian pineal gland are more similar to those in the mammalian SCN rather than to those in the mammalian pineal gland. Avian pineal gland and mammalian SCN seem to share a fundamental molecular framework of the clock oscillator composed of a transcription/translation-based autoregulatory feedback loop. The circadian time-keeping mechanism also requires several post-translational events, such as protein translocation and degradation processes, in which protein phosphorylation plays a very important role for the stable 24-h cycling of the oscillator and/or the photic-input pathway for entrainment of the clock.

Rhythm and soul in the avian pineal.

Abstract: The avian pineal gland, like that of mammals, displays a striking circadian rhythm in the synthesis and release of the hormone melatonin. However, the pineal gland plays a more prominent role in avian circadian organization and differs from that in mammals in several ways. One important difference is that the pineal gland in birds is relatively autonomous. In addition to making melatonin, the avian pineal contains photoreceptors and a circadian clock (thus, an entire circadian system) within itself. Furthermore, avian pineals retain their circadian properties in organ or dispersed cell culture, making biochemical components of regulatory pathways accessible. Avian pinealocytes are directly photosensitive, and novel candidates for the unidentified photopigments involved in the regulation of clock function and melatonin production, including melanopsin, pinopsin, iodopsin, and the cryptochromes, are being evaluated. Transduction pathways and second messengers that may be involved in acute and entraining effects, including cyclic nucleotides, calcium fluxes, and protein kinases, have been, and continue to be, examined. Moreover, several clock genes similar to those found in Drosophila and mouse are expressed, and their dynamics and interactions are being studied. Finally, the bases for acute and clock regulation of the key enzyme in melatonin synthesis, arylalkylamine N-acetyltransferase (AA-NAT), are described. The ability to study entrainment, the oscillator itself, and a physiological output in the same tissue at the same time makes the avian pineal gland an excellent model to study the bases and regulation of circadian rhythms.

Organisation of the circadian system in melatonin-proficient C3H and melatonin-deficient C57BL mice: a comparative investigation.

Abstract: In all vertebrates melatonin is rhythmically synthesised in the pineal gland and functions as a hormonal message encoding for the duration of darkness. This review focuses on the role of melatonin in the circadian organisation of mammals by comparing signal transduction mechanisms in the pineal organ, the suprachiasmatic nucleus and the hypophyseal pars tuberalis in melatonin-proficient (C3H) and melatonin-deficient (C57BL) mice strains. Surprisingly, the major signal transduction cascades in the pineal organ did not differ between the two mouse strains. With regard to the suprachiasmatic nucleus, the site of the endogenous clock, it was found that melatonin at most sets the gain for clock error signals mediated via the retinohypothalamic tract, but has no effect on the rhythm generation itself or on the maintenance of the oscillation. In contrast, melatonin plays an essential role in the control of the hypophyseal pars tuberalis. Here it acts in concert with adenosine to elicit rhythms in clock gene expression. Melatonin opens a temporally restricted gate for adenosine to induce cyclic AMP (cAMP)-sensitive genes by sensitising the adenylyl cyclase. This interaction, which grants a temporally precise regulation of gene expression, may reflect the central role of melatonin, i.e. in synchronising peripheral clock cells that require unique phasing of output signals with the master clock in the brain.

Locally synthesized angiotensin modulates pineal melatonin generation.

Abstract: We aimed to study the mechanisms and the significance of the influence exerted by the renin-angiotensin system (RAS) on the pineal melatonin production. Pineal melatonin and other indoles were determined by HPLC with electrochemical detection after angiotensin AT1-receptor blockade with Losartan in vivo or in cultured glands. N-acetyltransferase (NAT) activity was radiometricaly measured. To test the in vivo relevance of the local RAS, pineal melatonin and its indole precursors were determined in transgenic rats with inhibited production of angiotensinogen exclusively in astrocytes, TGR(ASrAOGEN). Tryptophan hydroxylase (TPH) and NAT mRNA levels were determined by real-time RT-PCR. Pineal melatonin content was significantly decreased by AT1-receptor blockade in vivo, in cultured glands and in TGR(ASrAOGEN) (35%, 32.4% and 17.5% from control, respectively). Losartan produced a significant decrease of pineal 5-hydroxytryptophan, serotonin, 5-hydroxyindole acetic acid and N-acetylserotonin in pineal cultures. Also, the pineal content of the precursor indoles in TGR(ASrAOGEN) rats was significantly lowered. The reduction of 5-hydroxytryptophan levels by 33-75% in both in vivo and in vitro studies suggests a decreased activity of TPH. Moreover, the TPH mRNA levels in TGR(ASrAOGEN) rats were significantly lower than control rats. On the other hand, NAT activity was unaffected by Losartan in pineal culture and its expression was not significantly different from control in TGR(ASrAOGEN) rats. Our results demonstrate that a local pineal RAS exerts a tonic modulation of indole synthesis by influencing the activity of TPH via AT1-receptors.

l‐Aspartate but Not the d Form Is Secreted Through Microvesicle‐Mediated Exocytosis and Is Sequestered Through Na+‐Dependent Transporter in Rat Pinealocytes

Abstract: Rat pinealocytes accumulate glutamate in microvesicles and secrete it through exocytosis so as to transmit signals intercellularly. Glutamate is involved in the negative regulation of norepinephrine-stimulated melatonin production. In this study, we found that aspartate is also released from cultured rat pinealocytes during the exocytosis of glutamate. The release of aspartate was triggered by addition of KCI or A23187 (a Ca 2+ ionophore) in the presence of Ca 2+ and was proportional to the amount of L-glutamate released. Furthermore, the release of aspartate was inhibited by both botulinum neurotoxin type E and L- or N-type voltage-gated Ca 2+ channel blockers. Bay K 8644, an agonist for the L-type Ca 2+ channel, stimulated the release of aspartate 2.1-fold. Immunohistochemical analyses with antibodies against aspartate and synaptophysin revealed that aspartate is colocalized with synaptophysin in a cultured pinealocyte. HPLC with fluorometric detection indicated that the released aspartate is of the L form, although pinealocytes also contain the D form in their cytoplasm, corresponding to ∼30% of the total free aspartate. Radiolabeled L-aspartate was taken up by the microsomal fraction from bovine pineal glands in a Na + -dependent manner. The Na + -dependent uptake of L-aspartate was strongly inhibited by L-cysteine sulfinate, β-hydroxyaspartate, and L-serine-O-sulfate, inhibitors for the Na + -dependent glutamate/aspartate transporter on the plasma membrane. Na + -dependent sequestration of L-aspartate was also observed in cultured rat pinealocytes, which was inhibited similarly by these transporter inhibitors. These results strongly suggest that L-aspartate is released through microvesicle-mediated exocytosis from pinealocytes and is taken up again through the Na + -dependent transporter at the plasma membrane. The possible role of L-aspartate as an intercellular chemical transmitter in the pineal gland is discussed.

Chick pineal melatonin synthesis: light and cyclic AMP control abundance of serotonin N-acetyltransferase protein.

Abstract: Melatonin production in the pineal gland is high at night and low during the day. This rhythm reflects circadian changes in the activity of serotonin N-acetyltransferase [arylalkylamine N-acetyltransferase (AA-NAT); EC 2.3.1.87], the penultimate enzyme in melatonin synthesis. The rhythm is generated by an endogenous circadian clock. In the chick, a clock is located in the pinealocyte, which also contains two phototransduction systems. One controls melatonin production by adjusting the clock and the other acts distal to the clock, via cyclic AMP mechanisms, to switch melatonin synthesis on and off. Unlike the clock in these cells, cyclic AMP does not appear to regulate activity by altering AA-NAT mRNA levels. The major changes in AA-NAT mRNA levels induced by the clock seemed likely (but not certain) to generate comparable changes in AA-NAT protein levels and AA-NAT activity. Cyclic AMP might also regulate AA-NAT activity via changes in protein levels, or it might act via other mechanisms, including posttranslational changes affecting activity. We measured AA-NAT protein levels and enzyme activity in cultured chick pineal cells and found that they correlated well under all conditions. They rose and fell spontaneously with a circadian rhythm. They also rose in response to agents that increase cyclic AMP. They were raised by agents that increase cyclic AMP, such as forskolin, and lowered by agents that decrease cyclic AMP, such as light and norepinephrine. Thus, both the clock and cyclic AMP can control AA-NAT activity by altering the total amount of AA-NAT protein. Effects of proteosomal proteolysis inhibitors suggest that changes in AA-NAT protein levels, in turn, reflect changes in the rate at which the protein is destroyed by proteosomal proteolysis. It is likely that cyclic AMP-induced changes in AA-NAT protein levels mediate rapid changes in chick pineal AA-NAT activity. Our results indicate that light can rapidly regulate the abundance of a specific protein (AA-NAT) within a photoreceptive cell.

α1D L-Type Ca2+-Channel Currents: Inhibition by a β-Adrenergic Agonist and Pituitary Adenylate Cyclase-Activating Polypeptide (PACAP) in Rat Pinealocytes

Abstract: In this study the subunits of the dihydropyridine-sensitive L-type Ca2+ channels (L-channels) expressed in rat pinealocytes were characterized using reverse transcription (RT)-PCR analysis, and the modulation of these channels by adrenergic agonists and by pituitary adenylate cyclase-activating polypeptide (PACAP) was studied using the patch-clamp technique. RT-PCR analysis showed that rat pinealocytes expressed alpha 1D, alpha 2b, beta 2, and beta 4 Ca(2+)-channel subunit mRNAs. Other alpha 1 subunit transcripts were either not expressed or present at very low levels, indicating that the pinealocytes express predominantly alpha 1D L-channels. Electrophysiological studies confirmed that the pineal expressed a single population of L-channels. The L-channel currents were inhibited by two agonists that elevate cyclic AMP: the beta-adrenergic agonist isoproterenol and PACAP. Similar inhibition was observed with a cyclic AMP analogue, 8-bromo-cyclic AMP. The presence of a cyclic AMP antagonist, Rp-adenosine 3',5'-cyclic monophosphorothioate, blocked the inhibition by isoproterenol and PACAP. Norepinephrine, a mixed alpha- and beta-adrenergic agonist, also inhibited the L-channel currents, but the inhibition was smaller. The smaller inhibition by norepinephrine was secondary to the simultaneous activation of alpha- and beta-adrenergic receptors. These results indicate that (a) pinealocytes express predominantly alpha 1D L-channels, and (b) the beta-adrenergic agonist isoproterenol and PACAP inhibit the L-channel currents through elevation of cyclic AMP. However, an alpha-adrenergic-mediated mechanism also appears to be involved in the effect of norepinephrine on the L-channel currents.

Regulation of Period 1 Expression in Cultured Rat Pineal

Abstract: The aim of the present study was to investigate the in vitro expression of Period 1 (Per1), Period 2 (Per2) and arylalkylamine N-acetyltransferase (AA-NAT) genes in the rat pineal gland to understand the mechanism(s) regulating the expression of these genes in this organ. Pineals, when maintained in vitro for 5 days, did not show circadian rhythmicity in the expression of any of the three genes monitored. Norepinephrine (NE) induced AA-NAT and Per1, whereas its effect on Per2 was negligible. Contrary to what was observed in other systems, NE stimulation did not induce circadian expression of Per1. The effect of NE on Per1 level was dose- and receptor subtype-dependent, and both cAMP and cGMP induced Per1. Per1 was not induced by repeated NE - or forskolin - stimulation. Protein synthesis was not necessary for NE-induced Per1, but it was for reduction of Per1 following NE stimulation. Per1 transcription in pinealocytes was activated by BMAL1/CLOCK. Our results indicate that important differences are present in the regulation of these genes in the mammalian pineal. Copyright 2002 S. Karger AG, Basel.

Functional Expression of a GLT‐1 Type Na+‐Dependent Glutamate Transporter in Rat Pinealocytes

Abstract: Pinealocytes, the neuroendocrine cells that produce melatonin, accumulate glutamate in microvesicles through a specific vesicular transporter energetically coupled with vacuolar-type proton ATPase. The glutamate is secreted into the extracellular space through microvesicle-mediated exocytosis and then stimulates neighboring pinealocytes, resulting in inhibition of norepinephrine-dependent melatonin synthesis. In this study, we identified and characterized the plasma membrane-type glutamate transporter in rat pinealocytes. The [3H]glutamate uptake by cultured pinealocytes was driven by extracellular Na+, saturated with the [3H]glutamate concentration used, and significantly inhibited by L-glutamate, L-aspartate, beta-threo-hydroxyaspartate, pyrrolidine dicarboxylate, and L-cysteine sulfinate, substrates or inhibitors of the plasma membrane glutamate transporter. Consistently, the clearance of extracellular glutamate, as measured by HPLC, was also dependent on Na+ and inhibited by beta-threo-hydroxyaspartate and L-cysteine sulfinate. Immunological studies with site-specific antibodies against three isoforms of the Na+-dependent glutamate transporter (GLT-1, GLAST, and EAAC1) revealed the expression of only the GLT-1 type transporter in pineal glands. Expression of the GLT-1 type transporter in pineal glands was further demonstrated by means of reverse transcription-polymerase chain reaction with specific DNA probes. Immunohistochemical analysis indicated that the immunological counterpart(s) of the GLT-1 is localized in pinealocytes. These results suggested that the GLT-1-type Na+-dependent transporter is expressed and functions as a reuptake system for glutamate in rat pinealocytes. The physiological role of the transporter in the termination of the glutamate signal in the pineal gland is discussed.

Pituitary Adenylate Cyclase‐Activating Polypeptide: Control of Rat Pineal Cyclic AMP and Melatonin but Not Cyclic GMP

Abstract: In this study, the effects of pituitary adenylate cyclase-activating polypeptide (PACAP) on cyclic nucleotide accumulation and melatonin (MT) production in dispersed rat pinealocytes were measured. Treatment with PACAP (10(-7) M) increased MT production 2.5-fold. PACAP (10(-7) M) also increased cyclic AMP accumulation four- to fivefold; this effect was potentiated two- to three-fold by alpha 1-adrenergic activation. This potentiation appears to involve protein kinase C (PKC) because alpha 1-adrenergic activation is known to translocate PKC and the PACAP-stimulated cyclic AMP accumulation was potentiated ninefold by a PKC activator, 4 beta-phorbol 12-myristate 13-acetate (PMA). Phenylephrine and PMA also potentiated the PACAP-stimulated MT accumulation. These results indicate that cyclic AMP is one second messenger of PACAP in the pineal gland and that the effects of PACAP on cyclic AMP and MT production can be potentiated by an alpha 1-adrenergic-->PKC mechanism. In addition to these findings, it was observed that PACAP treatment with or without phenylephrine or PMA did not alter cyclic GMP accumulation. This indicates that PACAP is the first ligand identified that increases cyclic AMP accumulation in the pineal gland without increasing cyclic GMP accumulation. That PACAP fails to activate the vasoactive intestinal peptide/cyclic GMP pathway suggests that the vasoactive intestinal peptide receptors present in the pineal may be distinct from the type II PACAP receptors.

Plasma melatonin, pinealocyte morphology, and surface receptors/antigen expression on macrophages/microglia in the pineal gland following a high-altitude exposure.

Abstract: The present study examined the effects of high-altitude exposure on the pineal gland, the main source of production of melatonin. It was surmised that hypoxia experienced at high altitude, caused by decreased oxygen tension in the ambient air, might lead to some structural alterations in the pineal gland and, hence, affect its melatonin production. Adult Wistar rats were exposed to an altitude of 8,000 m for 2 hr in an altitude chamber and then sacrificed at various time intervals after the exposure. Normal rats kept at ground level were used as controls. Blood samples were collected at various time intervals for measurement of plasma melatonin level, and the pineal glands from both groups were processed for electron microscopy and immunohistochemistry. The plasma melatonin level showed a steady increase following altitude exposure peaking at 7 days and returned to control levels thereafter. Between 1 and 4 days after altitude exposure, the mitochondrial number and lipid droplets in the pinealocytes appeared to be reduced compared with those in control rats. At 7 days, however, the mitochondrial numbers and lipid droplets were noticeably increased. At the same time interval, the expression of complement type 3 receptors and major histocompatibility class II antigens as detected with the antibodies OX-42 and OX-6, respectively, in macrophages/microglia was up-regulated compared with that in the control rats and those killed at earlier times. This was attributed to the increased serum melatonin after the altitude exposure. By 14 and 21 days, the ultrastructure of pinealocytes and immunoreactivity of macrophages/microglia were comparable with those in the control rats. We conclude from this study that an altitude exposure in rats leads to an increase in melatonin production, which returned to control levels with passage of time.

Involvement of NF-Y and Sp1 in basal and cAMP-stimulated transcriptional activation of the tryptophan hydroxylase (TPH ) gene in the pineal gland.

Abstract: The expression of the tryptophan hydroxylase (TPH) gene, encoding the rate-limiting enzyme of serotonin biosynthesis, is tightly regulated both at the transcriptional and at the post-transcriptional levels. In the pineal gland, transcription of the gene is activated in response to an intracellular circadian increase of the cAMP concentration. We have previously shown that transcription of a 2.1-kb fragment of the human TPH promoter is induced by cAMP, although it lacks the canonical cAMP responsive element, CRE. The minimal promoter (-73/+29) has only weak transcriptional activity but is responsive to cAMP. It contains an inverted CCAAT box, which was demonstrated to be involved in this response. Here, we have extended our investigation to the functional features of the inverted CCAAT box in the -252/+29 TPH promoter, which has a higher basal activity. We show that an additional cis -acting sequence, the adjacent GC-rich region, cooperates with the inverted CCAAT box for the full activation of basal transcription, and that both elements are essential for the full cAMP response. We also show that in pinealocytes, NF-Y and Sp1 transactivators bind the inverted CCAAT box and GC-rich-region, respectively. These factors participate in a novel pathway for the cAMP-mediated response of the TPH promoter, which is independent of the canonical CRE-mediated response.

Synaptic Vesicle Protein SV2B, but Not SV2A, Is Predominantly Expressed and Associated with Microvesicles in Rat Pinealocytes

Abstract: Microvesicles are endocrine counterparts of neuronal synaptic vesicles, and accumulate and secrete classic neurotransmitters. In mammalian pinealocytes, microvesicles accumulate l-glutamate through a vesicular glutamate transporter and secrete it through exocytosis. To characterize the molecular organization of microvesicles in more detail, we investigated in this study the expression and localization of synaptic vesicle protein 2 (SV2) in rat pinealocytes. RT-PCR analysis indicated that transcripts specific for two isoforms, SV2A, a ubiquitous form present in neuronal and endocrine cells, and SV2B, a neuron-specific form, are amplified in pineal RNAs. Northern blotting with specific transcripts indicated that the mRNA for SV2B is predominantly expressed, whereas that for SV2A is below the detection limit. Site-specific antibodies against SV2B recognized a single 72-kDa polypeptide in the pineal membrane fraction, whereas anti-SV2A antibodies did not recognize any polypeptides. Immunohistochemical analysis of cultured cells indicated that SV2B is expressed in pinealocytes but not in other types of cells. SV2B is present in somata and is especially rich in processes, which are filled with microvesicles. SV2B is colocalized with synaptophysin and synaptotagmin, markers for microvesicles. Immunoelectron microscopy indicated that SV2B is associated with microvesicles. These results indicated that SV2B, but not SV2A, is expressed in rat pinealocytes and associated with microvesicles. As SV2B is also expressed in cultured αTC6 clonal pancreatic α cells, SV2B is not a protein specific for neurons.

Circadian binding activity of AP-1, a regulator of the arylalkylamine N-acetyltransferase gene in the rat pineal gland, depends on circadian Fra-2, c-Jun, and Jun-D expression and is regulated by the clock's zeitgebers.

Abstract: The daily rhythm in circulating melatonin is driven by a circadian rhythm in the expression of the arylalkylamine N-acetyltransferase gene in the rat pineal gland. Turning off expression of this gene at the end of night is believed to involve inhibitory transcription factors, among which Fos-related antigen 2 (Fra-2) appears as a good candidate. Circadian rhythms in the expression of three proteins of activating protein-1 (AP-1) complexes, namely, Fra-2, c-Jun, and Jun-D, are shown here to account for circadian variations in AP-1 binding activity. Quantitative variations in the Fra-2 component over the circadian cycle were associated with qualitative variations in protein isoforms. Destruction of the suprachiasmatic nucleus resulted in decreased nocturnal AP-1 activity, showing that AP-1 circadian rhythm is driven by this nucleus. Exposure to light during subjective night and administration of a serotonin 5-HT1A/5-HT7 receptor agonist during subjective day, respectively, induced a 50% decrease and a 50% increase in both AP-1 and Fra-2 expression. These effects were impaired by suprachiasmatic nucleus lesions. These data show that pineal AP-1 binding activity, which results from Fra-2 expression, can be modulated by light and serotonin through the suprachiasmatic nucleus according to a “phase dependence” that is characteristic of the rhythm of clock sensitivity to both zeitgebers.

Calcium and Photoentrainment in Chick Pineal Cells Revisited: Effects of Caffeine, Thapsigargin, EGTA, and Light on the Melatonin Rhythm

Abstract: Chick pineal cells in dispersed cell culture display a persistent, photosensitive, circadian rhythm of melatonin production and release. Light pulses have at least two distinguishable effects on these cells, i.e., acute suppression of melatonin output and phase shifts (entrainment) of the underlying circadian pacemaker. Previous results linked calcium influx through voltage-sensitive calcium channels in the plasma membrane to acute regulation of melatonin synthesis but denied a role for such influx in entrainment. Those experiments did not, however, address the role of intracellular calcium metabolism. Here we describe the effects of pulses of caffeine, thapsigargin, and EGTA on the melatonin rhythm, and their interactions with the effects of light pulses. Caffeine had two distinguishable effects on these cells, acute enhancement of melatonin output (attributable to phosphodiesterase inhibition) and phase shifts of the circadian pacemaker with a light-like pattern (attributable to effects on intracellular calcium). Phase shifts induced by light and caffeine were not additive. Thapsigargin (which specifically blocks the pump that replenishes intracellular calcium stores, thereby increasing cytoplasmic calcium and depleting intracellular stores) had no phase-shifting effects by itself but reduced the size of the phase advances induced by caffeine or light. Low calcium solution acutely suppressed melatonin output without inducing phase shifts or affecting those induced by caffeine or light. However, addition of EGTA (which specifically chelates calcium, thereby lowering cytoplasmic calcium and depleting intracellular stores) did reduce the size of phase advances induced by caffeine or light, in normal medium or in low calcium solution, without inducing a phase shift by itself at that phase. Taken together, these results point toward a role for intracellular calcium fluxes in entrainment of the circadian pacemaker.

Immunohistochemical characterization of pineal parenchymal tumors using novel monoclonal antibodies to the pineal body.

Abstract: To characterize the immunohistochemical nature of pineal parenchymal tumors (PPT), we examined nine cases of normal pineal bodies and 23 cases of PPT using several neuronal and glial antibodies and 10 novel monoclonal antibodies raised against human pineal tissue. The PPT were classified into four pineocytoma, five pineal parenchymal tumor of intermediate differentiation (Int-PPT), and 14 pineoblastoma. The pinealocytes, parenchymal cells of the pineal body, were labeled with five, neuronal and seven pineal monoclonal (from PP1 to PP7) antibodies in the normal pineal bodies. The subjects ranged from 3 to 85 years old, 12 female and eight male subjects were studied. Antibodies to glial cells PI1, PI2 and PX1, stained interstitial cells of the pineal body. Many of the PPT showed positive immunostaining for pinealocyte-associated antigens and neuronal markers. The intensity of immunostaining showed some association with the degree of differentiation of the tumor, but there was a considerable variety of staining from case to case. The pineocytomas are more immunopositive than are the Int-PPT or pineoblastoma for neuronal and pinealocyte-associated antibodies. In particular the neurofilament protein (NFP)68 kDa, PP1 and PP6 showed significant differences of reactivity between pineocytoma, Int-PPT and pineoblastoma, when compared in groups showing extensive positive staining (positive staining in almost all areas of the tumor). By using three representative antibodies, anti-NFP68kDa, PP1 and PP6, we were able to make a clear distinction between pineoblastoma, Int-PPT and pineocytoma. Glial fibrillary acidic protein (GFAP), PI1 and PI2 antibodies only occasionally showed a small number of positive cells in the tumor, and thus we considered these cells to be non-neoplastic interstitial cells or reactive astrocytes entrapped in the tumor. Our data suggest that the glial differentiation of PPT may occur, but that it seems to be a very rare event.

Vesicular monoamine transporter 1 is responsible for storage of 5-hydroxytryptamine in rat pinealocytes

Abstract: Vesicular monoamine transporters (VMATs) are involved in chemical transduction in monoaminergic neurons and various endocrine cells through the storage of monoamines in secretory vesicles. Mammalian pinealocytes contain more 5-hydroxytryptamine (5-HT) than any other cells and are expected to contain VMAT, although no information is available so far. Upon the addition of ATP, radiolabeled 5-HT was taken up by a particulate fraction prepared from cultured rat pinealocytes. The 5-HT uptake was inhibited significantly by bafilomycin A1 (an inhibitor of vacuolar H+-ATPase), 3,5-di-tert-butyl-4-hydroxybenzylidenemalononitrile (a proton conductor), or reserpine (an inhibitor of VMAT). RT-PCR analysis suggested that VMAT type 1 (VMAT1), but not type 2, is expressed. Antibodies against VMAT1 recognized a single polypeptide with an apparent molecular mass of approximately 55 kDa, and specifically immunostained pinealocytes. VMAT1 immunoreactivity was high in the vesicular structures in the varicosities of long branching processes and was associated with 5-HT, but not with synaptophysin, a marker protein for microvesicles. The 5-HT immunoreactivity in the long branching processes disappeared upon incubation with reserpine. These results indicate that 5-HT, at least in part, is stored in vesicles other than microvesicles in pinealocytes through a mechanism similar to that of various secretory vesicles.

Potentiation of agonist-stimulated cyclic AMP accumulation by tyrosine kinase inhibitors in rat pinealocytes

Abstract: To study cross-talk mechanisms in rat pinealocytes, the role of tyrosine kinase or kinases in the regulation of adrenergic-stimulated cyclic AMP production was investigated. Both norepinephrine- and isoproterenol-stimulated cyclic AMP accumulation were increased by two distinct tyrosine kinase inhibitors, genistein or erbstatin, in a concentration-dependent manner. A similar increase was observed with two other inhibitors, tyrphostin B44 and herbimycin. In contrast, daidzein, an inactive analogue of genistein, was ineffective; whereas vanadate, a phosphotyrosine phosphatase inhibitor, reduced the adrenergic-stimulated cyclic AMP accumulation. The tyrosine kinase inhibitors were effective in potentiating the cholera toxin-or forskolin-stimulated cyclic AMP accumulation, indicating that their sites of action are at the postreceptor level. Neither an activator nor inhibitors of protein kinase C influenced the potentiation of the cyclic AMP responses by genistein, suggesting that the potentiation effect by tyrosine kinase inhibitors does not involve the phospholipase C/protein kinase C pathway. However, when the phosphodiesterase was inhibited by isobutylmethylxanthine, genistein failed to potentiate and vanadate did not inhibit the adrenergic-stimulated cyclic AMP accumulation, indicating that the phosphodiesterase is a probable site of action for these inhibitors. These results suggest that cyclic AMP metabolism in the pinealocytes is tonically inhibited by tyrosine kinase acting on the cyclic AMP phosphodiesterase.

Regulation of gene expression by melatonin: a microarray survey of the rat retina.

Abstract: The pineal secretory product melatonin is synthesized by pinealocytes and retinal photoreceptors on a cyclic rhythm, with highest levels occurring at night. Our previous work has demonstrated that melatonin treatment increases the sensitivity of the rat retina to light-induced photoreceptor cell death. This raises the possibility that inappropriate exposure of photoreceptors to melatonin may result in visual impairment, caused by a loss of retinal photoreceptors. We hypothesize that retinal genes whose expression levels are altered in response to melatonin may be involved in processes that contribute to light-induced photoreceptor cell death. To identify retinal genes that are up- or down-regulated in response to melatonin receptor binding, rats were treated with or without melatonin, and the RNA from the neural retinas and retinal pigment epithelium (RPE) were analyzed for differential gene expression by hybridization of labeled cRNA probes to an Affymetrix rat genome microarray set. GeneChip algorithms were applied to measured hybridization intensities of compared samples and showed that in the neural retina, six genes were up-regulated, and eight were down-regulated. In the RPE, 15 genes were up-regulated, and two genes were down-regulated. The protein products of these specific genes are potentially involved in the molecular mechanism of melatonin action in the retina, and may play a role in the effect of melatonin on light-induced photoreceptor cell death. Identification of these candidate genes and their response to melatonin administration may provide a foundation for further studies on gene regulation by melatonin, the function of melatonin in the retina, and the role of circadian signaling in inherited and environmentally induced photoreceptor degenerations.

Expression of C-type natriuretic peptide in the bovine pineal gland.

Abstract: Recent studies have pointed to membrane-bound guanylyl cyclases (GCs) type A and type B in the rat pineal gland, which augment levels of cyclic GMP (cGMP) in response to atrial natriuretic peptide (ANP), brain-type natriuretic peptide (BNP), and C-type natriuretic peptide (CNP). The present report demonstrates for the first time the expression of CNP in the bovine pineal gland. The CNP prohormone transcript (unlike pre-pro-ANP) was found by reverse transcriptase (RT)-PCR in bovine pineal extracts. CNP immunoreactivity (ir) was revealed in a subpopulation of pinealocytes in situ and in nearly all pinealocytes in culture. Electron microscopic immunohistochemical investigations showed the presence of CNP-ir in cytoplasmic vesicles, providing evidence for the potential secretion of this peptide by pineal cells. Furthermore, the CNP receptor (GC-B) and GC-A (receptor for ANP and BNP) were identified by RT-PCR. Although melatonin secretion was unaffected, natriuretic peptides were able to elevate markedly cGMP production in cultured bovine pinealocytes with a rank order of potency of CNP > BNP = ANP. These findings describe a tissue CNP system in the bovine pineal gland and suggest that CNP may be a local auto- or paracrine modulator of pineal function.