Joan L. Weller

Indole Metabolism in the Pineal Gland: A Circadian Rhythm in N-Acetyltransferase

The activity of N-acetyltransferase in the rat pineal gland is more than 15 times higher at night than during the day. This circadian rhythm persists in complete darkness, or in blinded animals, and is suppressed in constant lighting. The N-acetyltransferase rhythm is 180� out of phase with the serotonin rhythm and is similar to the norepinephrine and melatonin rhythms. Experiments in vitro indicate that norepinephrine, not serotonin, regulates the activity of N-acetyl-transferase through a highly specific receptor.

Rapid Light-Induced Decrease in Pineal Serotonin N-Acetyltransferase Activity

Light acting by way of the eye causes the dark-induced activity of serotonin N-acetyltransferase in the pineal gland of the rat to decrease with a halving time of about 3 minutes. This effect, which is one of the more rapid physiological changes known to occur in the activity of any enzyme that metabolizes biogenic amines, appears to explain the rapid increase in the concentration of pineal serotonin that is caused by light exposure at night.

Pineal serotonin N-acetyltransferase: expression cloning and molecular analysis.

Pineal serotonin N-acetyltransferase (arylalkylamine N-acetyltransferase, or AA-NAT) generates the large circadian rhythm in melatonin, the hormone that coordinates daily and seasonal physiology in some mammals. Complementary DNA encoding ovine AA-NAT was cloned. The abundance of AA-NAT messenger RNA (mRNA) during the day was high in the ovine pineal gland and somewhat lower in retina. AA-NAT mRNA was found unexpectedly in the pituitary gland and in some brain regions. The night-to-day ratio of ovine pineal AA-NAT mRNA is less than 2. In contrast, the ratio exceeds 150 in rats. AA-NAT represents a family within a large superfamily of acetyltransferases.

Role of a pineal cAMP-operated arylalkylamine N-acetyltransferase/14-3-3-binding switch in melatonin synthesis.

The daily rhythm in melatonin levels is controlled by cAMP through actions on the penultimate enzyme in melatonin synthesis, arylalkylamine N-acetyltransferase (AANAT; serotonin N-acetyltransferase, EC 2.3.1.87). Results presented here describe a regulatory/binding sequence in AANAT that encodes a cAMP-operated binding switch through which cAMP-regulated protein kinase-catalyzed phosphorylation [RRHTLPAN → RRHpTLPAN] promotes formation of a complex with 14-3-3 proteins. Formation of this AANAT/14-3-3 complex enhances melatonin production by shielding AANAT from dephosphorylation and/or proteolysis and by decreasing the Km for 5-hydroxytryptamine (serotonin). Similar switches could play a role in cAMP signal transduction in other biological systems.

DEVELOPMENT OF A CIRCADIAN RHYTHM IN THE ACTIVITY OF PINEAL SEROTONIN N-ACETYLTRANSFERASE

Abstract— Pineal serotonin N‐acetyltransferase (EC 2.3.1.5) is a neurally regulated enzyme. It is detectable in the rat as early as 4 days prior to birth. A circadian rhythm in enzyme activity appears on the fourth day after birth. It develops most rapidly during the second week and achieves an adult magnitude by the end of the third week at which time nocturnal values are more than 30‐fold greater than daytime values. Norepinephrine, which appears to be the neurotransmitter regulating this enzyme, can cause a 2‐ to 3‐fold stimulation of N‐acetyltransferase in organ cultures of pineal glands from 4‐day‐old animals and a 17‐fold increase in the activity of glands from 15‐day‐old animals. Apparently the norepinephrinesensitive system controlling pineal N‐acetyltransferase activity also develops most rapidly during the first few weeks of life. The circadian rhythm in the activity of serotonin N‐acetyltransferase develops in the pineal glands of both male and female rats at the same rate. A similar rhythm for the enzyme was not observed in twelve other tissues of the rat.

Night/Day Changes in Pineal Expression of >600 Genes CENTRAL ROLE OF ADRENERGIC/cAMP SIGNALING

The pineal gland plays an essential role in vertebrate chronobiology by converting time into a hormonal signal, melatonin, which is always elevated at night. Here we have analyzed the rodent pineal transcriptome using Affymetrix GeneChip® technology to obtain a more complete description of pineal cell biology. The effort revealed that 604 genes (1,268 probe sets) with Entrez Gene identifiers are differentially expressed greater than 2-fold between midnight and mid-day (false discovery rate <0.20). Expression is greater at night in ∼70%. These findings were supported by the results of radiochemical in situ hybridization histology and quantitative real time-PCR studies. We also found that the regulatory mechanism controlling the night/day changes in the expression of most genes involves norepinephrine-cyclic AMP signaling. Comparison of the pineal gene expression profile with that in other tissues identified 334 genes (496 probe sets) that are expressed greater than 8-fold higher in the pineal gland relative to other tissues. Of these genes, 17% are expressed at similar levels in the retina, consistent with a common evolutionary origin of these tissues. Functional categorization of the highly expressed and/or night/day differentially expressed genes identified clusters that are markers of specialized functions, including the immune/inflammation response, melatonin synthesis, photodetection, thyroid hormone signaling, and diverse aspects of cellular signaling and cell biology. These studies produce a paradigm shift in our understanding of the 24-h dynamics of the pineal gland from one focused on melatonin synthesis to one including many cellular processes.

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.

PINEAL SEROTONIN N‐ACETYLTRANSFERASE ACTIVITY: PROTECTION OF STIMULATED ACTIVITY BY ACETYL‐CoA AND RELATED COMPOUNDS

—Rat pineal serotonin N—acetyltransferase activity increases 30–70‐fold at night in the dark and then decreases rapidly when animals are exposed to light. Activity of the enzyme is also stimulated by l‐norepinephrine in organ culture. When homogenates of glands stimulated by dark in vivo or NE in vitro are incubated at 37°C, enzyme activity will also rapidly decrease. This decrease can be prevented by one of the cosubstrates of the enzyme, acetyl–CoA. Protection can also be conferred by cysteamine (β‐mercaptoethylamine, HS–CH2–CH2–NH2) which is the terminal portion of the CoA molecule. This protection mechanism could be involved in the physiological control of enzyme activity.

Regulation of Arylalkylamine N-Acetyltransferase-2 (AANAT2, EC 2.3.1.87) in the Fish Pineal Organ: Evidence for a Role of Proteasomal Proteolysis

In fish, individual photoreceptor cells in the pineal organ and retina contain complete melatonin rhythm generating systems. In the pike and seabream, this includes a photodetector, circadian clock, and melatonin synthesis machinery; the trout lacks a functional clock. The melatonin rhythm is due in part to a nocturnal increase in the activity of the arylalkylamine N-acetyltransferase (AANAT) which is inhibited by light. Two AANATs have been identified in fish: AANAT1, more closely related to AANATs found in higher vertebrates, is specifically expressed in the retina; AANAT2 is specifically expressed in the pineal organ. We show that there is a physiological day/night rhythm in pineal AANAT2 protein in the pike, and that light exposure at midnight decreases the abundance of AANAT2 protein and activity. In culture, this decrease is blocked by inhibitors of the proteasomal degradation pathway. If glands are maintained under light at night, treatment with these inhibitors increases AANAT2 activity and protei...

Input and output signals in a model neural system: The regulation of melatonin production in the pineal gland

SummaryThe production of melatonin has been studied using organ cultures of pineal glands incubated with methionine-methyl-3H. Melatonin-O-methyl-3H was extracted from cultured pineal glands and incubation media, and the activity of N-acetyltransferase was measured. This is the first of two enzymes necessary for the conversion of serotonin to melatonin in the pineal. The treatment of pineal glands with norepinephrine or dibutyryl cyclic AMP increased the release of melatonin-O-methyl-3H into the incubation media and the concentration of melatonin-O-methyl-3H in the glands. These treatments also resulted in the stimulation of N-acetyltransferase, as compared to untreated glands. The transduction of neural information to biochemical, signals which regulate the melatonin pathway appears to involve the release of norepinephrine, which stimulates N-acetyltransferase activity through an adenyl cyclase-cyclic AMP mechanism, as evidenced by these and other studies discussed.In the present study the effects of harmine were studied. This hallucinogen is known to inhibit monoamine oxidase and stimulate melatonin production. Harmine was observed to stimulate N-acetyltransferase. This observation raises the possibility that an important action of this psychotropic drug may be on mechanisms which convert neural activity into biochemical events.