Circadian variations of ?synaptic? bodies in the pineal glands of Brattleboro rats (original) (raw)
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“Synaptic” ribbons and spherules of the rat pineal gland: Day/night changes in vitro?
Experimental Brain Research, 1982
In the present study pineal glands of rats aged 69-71 days were studied in vivo and in vitro with respect to day/night changes of "synaptic" ribbons and spherules. It was found that ribbons outnumber spherules by a factor of 3. In vivo, both ribbons and spherules show a roughly 3-fold increase in number at 1 a.m. when compared to 1 p.m. Up to 39 h in vitro, the two structures in question did not reveal day/night differences in amount, suggesting that diurnal rhythmicity of the gland did apparently not persist in organ culture. After 3 h in organ culture, the spherules, but not the ribbons, showed a striking increase in number, showing that ribbons and spherules may be governed by different mechanisms.
Neuroscience Letters, 1990
There is evidence for an involvement of the hypothalamic paraventricular nuclei (PVN) in the regulation of pineal melatonin synthesis in rats. Since electrical stimulation of the PVN or the systemic administration of arginine-vasopressin (AVP) result in a depression of the nocturnal melatonin surge, this neuropeptide appears to be pivotal for the transduction of PVN-efferent, pinealopetal signals. We therefore used an AVP-deficient animal model, the Brattleboro rat, to further investigate the mechanisms responsible for pineal regulation. Anesthetized adult male animals received 2 min of bilateral electrical stimulation of the PVN either during the day or at night. Thirty min later, pineal glands were removed and pineal N-acetyltransferase (NAT) activities and melatonin contents were determined. Stimulation resulted neither during the day nor at night in any significant alterations of pineal NAT activity or melatonin content when compared to control or sham-stimulated animals. These data further support the proposed modulatory rote of AVP for the regulation of melatonin synthesis in the Epiphysis cerebri of genetically intact rats.
The American journal of anatomy, 1983
The present study deals with the functionally enigmatic "synaptic" ribbons and spherules of guinea pig pinealocytes. Whereas the ribbons have been shown to exhibit a 24-hr rhythmicity with low numbers during the day and high numbers at night, very little of a definitive nature is known about the spherules. Sixteen male guinea pigs of the Hartley strain were perfusion fixed, 8 between 0900-1100 hr, and 8 between 2100-2300 hr. The ribbons and spherules were counted in the pineal parenchyma of the proximal, intermediate, and distal regions. In confirmation of earlier studies, it was found that "synaptic" ribbons are equally abundant in the proximal, intermediate, and distal regions of the gland, during both the day and the night, and that they increase significantly in number at night when compared with daytime values. The spherules, by contrast, are more abundant proximally and are present in greater numbers during the day than at night. As ribbons and spherules ar...
Cell and Tissue Research, 1985
Previous studies have shown that the "synaptic" ribbons (SR) and spherules (SS) of the mammalian pineal gland may respond differently under physiological and various experimental conditions. The aim of the present study was to gain insight into the mechanisms that may be responsible for the numerical changes of these organelles during a 24-h cycle. As the possibility exists that the structures are influenced by substances synthesized within the pinealocyte, rat pineal glands were cultured with and without added melatonin or serotonin, using an experimental protocol such that the addition of melatonin and serotonin mimicks the circadian changes of the respective substances within the pineal. The tissue was processed for electron microscopy and the numbers of SR and SS were counted in a unit area of pineal tissue. The results obtained indicate that melatonin added to the incubation medium increases the number of SR in the first half of the night; serotonin decreases SR numbers in the morning. SS numbers, by contrast, decrease following melatonin administration in the afternoon, and increase in the morning following serotonin administration. It thus appears that the numbers of SR and SS are influenced by melatonin and serotonin and that the two structures are regulated by differential, but nevertheless biochemically closely related mechanisms. -Melatonin (effect of) -Serotonin (effect of) A functionally important feature of the mammalian pineal gland is the formation of melatonin (5-methoxy-N-acetyltryptamine), which undergoes a prominent circadian rhythm. During daytime, serotonin, the substrate for melatonin, increases strikingly; at night, one of the melatoninforming enzymes, serotonin-N-acetyltransferase (NAT), in-Send offprint requests to."
Day-night rhythm of acetylcholine in the rat pineal gland
Neuroscience Letters, 1997
Using high-performance-liquid-chromatography (HPLC) measurement of acetylcholine, choline acetyltransferase (ChAT) enzyme assay and anti-ChAT immunohistochemistry, we have investigated the expression of the cholinergic system in pineal glands of male rats. Glands procured during the day period (1200 h) contained significant amounts of acetylcholine (0.5 pmol/gland). A similar content was found in pineal glands after a 48 h culture period, i.e. when the intrapineal nerve fibres have degenerated. This strongly indicates that the pinealocytes are the cells which contain acetylcholine. To confirm this conclusion we demonstrate substantial ChAT-like immunoreactivity in pinealocytes. ChAT enzyme activity measured in homogenized glands (day period) was 7 ± 3 nmol/mg per h. Acetylcholine content as well as ChAT enzyme activity increased about 10-fold in pineal glands during the night period (2400 h). The present study demonstrates for the first time the presence of a day-night rhythm of ChAT and acetylcholine in rat pinealocytes. The function of pineal acetylcholine is not clear, but there are indications that acetylcholine may depress noradrenaline release from intrapineal sympathetic fibres and hence melatonin synthesis.
Neuroscience Letters, 1991
The endogenously synthesized nonapeptide arglnine vasopressin (AVP) is thought to be involved in transduction of photic information to the pineal gland. The enhancement of circulating AVP leads to a suppression of the nocturnal melatonin surge the mechanisms of which are unknown so far. We therefore studied the effect of dDAVP, an AVP analog with antidiuretic but without vasopressor activity, on pineal melatonin synthesis in Sprague-Dawley and AVP-deficient Brattleboro rats. The nocturnal intra-arterial application of dDAVP mimicked the inhibitory effect of AVP on the activity of the rate-limiting enzyme for pineal melatonin synthesis, N-acetyltransferase (NAT), in both rat strains. Furthermore, since the pineal is equipped with receptors for VP~ (the major proteolytic AVP fragmen0 only, the influence of this substance on the gland's metabolic activity was investigated in vitro. Neither this peptide nor AVP alone did affect NAT activity, but either substance potentiated the norepinephrineinduced enhancement of NAT activity. These results reveal that at least two mechanisms mediate the influence of AVP on pineal melatonin synthesis. The AVP-induced pineal inhibition in vivo is probably due to a receptor-mediated effect on pinealopetal signal transduction. This inhibition masks the potentiating effect of AVP on the pineal gland itself which is delayed by the conversion of AVP to VP,_9. The present results support the idea of a modulatory role of AVP and its metabolites in the generation and maintenance of the circadian melatonin rhythm in mammals.
Intra-arterially administered vasopressin inhibits nocturnal pineal melatonin synthesis in the rat
Comparative biochemistry and physiology. A, Comparative physiology, 1988
1. In order to investigate the possible involvement of arginine-vasopressin (AVP) in the inhibition of nocturnal pineal melatonin synthesis following electrical stimulation of the hypothalamic paraventricular nuclei, adult male rats received injections of 5 micrograms/100 g body weight of the peptide during either day- or night-time. Following survival times of 30 or 120 min, animals were killed and the activity of the melatonin synthesis enzyme N-acetyltransferase (NAT) was determined. 2. At night, NAT activity was significantly decreased 30 and 120 min following AVP injection. 3. During the daytime, NAT activity was unchanged following AVP administration. 4. It is suggested that pineal melatonin synthesis may be affected by PVN stimulation not only via neural pathways but possibly also by PVN-released blood-borne AVP.
Cell and Tissue Research, 1986
To characterize further the functionally enigmatic "synaptic" ribbons (SR) of the mammalian pineal gland and to study possible relationships to melatonin synthesis, in the present investigation rats were exposed to short pulses of light at night when both SR numbers and serotonin N-acetyltransferase (NAT) activity are high in comparison to day-time values. Male Sprague-Dawley rats were killed at 13:00 and 01:00 h, respectively, and at 01:10 and 02:00 h after exposure to light for 10 and 60 rain, respectively. The pineals were rapidly taken out and cut sagittally in half. One half was processed for electron-microscopic quantitation of SR numbers and the other half for NAT determinations. It was found that both SR numbers and NAT activity decreased significantly when the animals were exposed to light at night. Although both parameters showed corresponding changes, there was no clear-cut correlation between SR numbers and NAT activity in individual animals within a group, except after exposure to light for 60 rain when a positive correlation (R--0.939; p < 0.05) existed. After exposure to light the electron-lucent vesicles of the SR decreased in number, but the length of the SR was unchanged. These results show that numbers of pineal SR can be easily and quickly manipulated and that the presently used model may be ideal in studying the poorly understood mode in which degradation of SR occurs.
Journal of Neural Transmission, 1992
The pineal contains a large number of classical transmitters and neuropeptides. Some of these neurochemicals are involved in the regulation of serotonin N-acetyltransferase (NAT) activity and hence in melatonin synthesis. Synaptic ribbons present in the pineal gland also exhibit a numerical day/night rhythm parallel to that of NAT activity. There is scarcity of information regarding the regulation of synaptic ribbon (SR) numbers. In the present study, we have investigated in vitro effects of a number of classical neurotransmitters and neuropeptides. NAT activity was used to monitor melatonin synthesis under the experimental conditions used. Norepinephrine (NE), Delta sleep-inducing peptide (DSIP), vasoactive intestinal polypeptide (VIP), adenosine and N-acetylasp-glu (NAAG) significantly increased NAT activity in rat pineal. DSIP and VIP also increase the stimulatory effect of NE on NAT activity. These neurochemicals had no effect on SR numbers. Gamma aminobutyric acid (GABA), serotonin and taurine affected neither NAT activity nor SR. Somatostatin increased SR numbers significantly, without having any effect on NAT activity. The effect of somatostatin is regarded to be pharmacologic, since rather high dosages (10−4 M) were required to obtain a significant effect. Although somatostatin is present in the pineal and may change rhythmically, the inconsistency of the day/night rhythmicity and the lack of such a rhythm in female rats and male gerbils speaks against an important physiological role of somatostatin in regulating SR numbers.