Cholinergic signaling in the rat pineal gland

Summary 1. Innervation of the mammalian pineal gland is mainly sympathetic. Pineal synthesis of melatonin and its levels in the circulation are thought to be under strict adrenergic control of serotoninN-acetyltransferase (NAT). In addition, several putative pineal neurotransmitters modulate melatonin synthesis and secretion.2. In this review, we summarize what is currently known on the pineal cholinergic system. Cholinergic signaling in the rat pineal gland is suggested based on the localization of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE), as well as muscarinic and nicotinic ACh binding sites in the gland.3. A functional role of ACh may be regulation of pineal synaptic ribbon numbers and modulation of melatonin secretion, events possibly mediated by phosphoinositide (PI) hydrolysis and activation of protein kinase C via muscarinic ACh receptors (mAChRs).4. We also present previously unpublished data obtained using primary cultures of rat pinealocytes in an attempt to get more direct information on the effects of cholinergic stimulus on pinealocyte melatonin secretion. These studies revealed that the cholinergic effects on melatonin release are restricted mainly to intact pineal glands since they were not readily detected in primary pinealocyte cultures.     

Neuroendocrine mediated effects of electromagnetic-field exposure: possible role of the pineal gland

Reports from recent epidemiological studies have suggested a possible association between extremely low frequency (ELF; including 50- or 60-Hz) electric- and magnetic-field exposure, and increased risk of certain cancers, depression, and miscarriage. ELF field-induced pineal gland dysfunction is a possible etiological factor in these effects. Work in our laboratory and elsewhere has shown that ELF electromagnetic-field exposure can alter the normal circadian rhythm of melatonin synthesis and release in the pineal gland. Consequences of reduced or inappropriately timed melatonin release on the endocrine, neuronal, and immune systems are discussed. Laboratory data linking ELF field exposure to changes in pineal circadian rhythms in both animals and humans are reviewed. The authors suggest that the pineal gland, in addition to being a convenient locus for measuring dyschronogenic effects of ELF field exposure, may play a central role in biological response to these fields via alterations in the melatonin signal.     

Rhythmic control of endocannabinoids in the rat pineal gland

Endocannabinoids modulate neuroendocrine networks by directly targeting cannabinoid receptors. The time-hormone melatonin synchronizes these networks with external light condition and guarantees time-sensitive and ecologically well-adapted behaviors. Here, the endocannabinoid arachidonoyl ethanolamide (AEA) showed rhythmic changes in rat pineal glands with higher levels during the light-period and reduced amounts at the onset of darkness. Norepinephrine, the essential stimulus for nocturnal melatonin biosynthesis, acutely down-regulated AEA and other endocannabinoids in cultured pineal glands. These temporal dynamics suggest that AEA exerts time-dependent autocrine and/or paracrine functions within the pineal. Moreover, endocananbinoids may be released from the pineal into the CSF or blood stream.     

Ultrastructural examinations of the zone function of the rat pineal gland in terms of mitochondrial bioenergetics

Membrane-membrane relations in the pineal gland were analysed. It was found that neighbouring pinealocytes may be in different mitochondrial configurational states. The pinealocytes lying next to the same glial cell and around nerve endings are in one metabolic state. Close to blood vessels this uniformity occurred when the perivascular space was surrounded by one glial cell.     

Temporal organization of immune function and the pineal gland involvement

The immune system activity has a rhythmicity with circadian and seasonal periods. Some reviewed data shown that fluctuations of different immunological parameters may be result of rhythmical activity of the pineal gland.     

Tentative immunohistochemical demonstration of melatonin in the rat pineal gland

Summary In the present study an attempt was made to demonstrate melatonin in the rat pineal gland by means of immunohistochemistry. The anti-body used was raised against 5-methoxy-N-acetyltryptophan which is chemically similar to melatonin. Specific fluorescence was demonstrable only in pineals from rats killed during the night, when melatonin formation is high. It was restricted to parenchymal cells lying in a marginal zone of the organ. These results are discussed in relation to a subdivision of the pineal parenchyma into cortical and medullary areas.Supported by a grant of the Deutsche Forschungsgemeinschaft (VO 135/4) within the Schwerpunktprogramm Neuroendokrinologie     

Diurnal variation of dopamine content in the rat pineal gland

Levels of norepinephrine and dopamine in the rat pineal gland were determined by a radioenzymatic assay with modifications to separate the reaction products. Catecholamines were converted to 3-O-methylated derivatives in the presence of catechol-O-methyltransferase (EC 2.1.1.1) and S-adenosyl-L-[methyl-³H]-methionine. Following solvent extraction of the labelled normetanephrine and 3-methoxytyramine, the amines were separated by high-performance liquid chromatography. Contents of both catecholamines in the pineal gland varied with a 24-hr rhythm. The content of norepinephrine was maximal at about 6 A.M. (lights on from 8 A.M. to 8 P.M.) and declined gradually thereafter. In contrast to the level of norepinephrine, the dopamine level was highest at about 0 A.M. and fell rapidly to reach a trough after the lights were turned on. These observations suggest that the diurnal variation of norepinephrine is generated by changes in the contents of dopamine in sympathetic nerve terminals innervating the pineal.