Reactive changes of interstitial glia and pinealocytes in the rat pineal gland challenged with cell wall components from gram-positive and -negative bacteria

Lipopolysaccharide (LPS), the major proinflammatory component of gram-negative bacteria, is well known to induce sepsis and microglial activation in the CNS. On the contrary, the effect of products from gram-positive bacteria especially in areas devoid of blood-brain barrier remains to be explored. In the present study, a panel of antibodies, namely, OX-6, OX-42 and ED-1 was used to study the response of microglia/macrophages in the pineal gland of rats given an intravenous LPS or lipoteichoic acid (LTA). These antibodies recognize MHC class II antigens, complement type 3 receptors and unknown lysosomal proteins in macrophages, respectively. In rats given LPS (50 microg/kg) injection and killed 48 h later, the cell density and immunoexpression of OX-6, OX-42 and ED-1 in pineal microglia/macrophages were markedly increased. In rats receiving a high dose (20 mg/kg) of LTA, OX-42 and OX-6, immunoreactivities in pineal microglia/macrophages were also enhanced, but that of ED-1 was not. In addition, both bacterial toxins induced an increase in astrocytic profiles labelled by glial fibrillary acid protein. An interesting feature following LPS or LTA treatment was the lowering effect on serum melatonin, enhanced serotonin immunolabelling and cellular vacuolation as studied by electron microscopy in pinealocytes. The LPS- or LTA-induced vacuoles appeared to originate from the granular endoplasmic reticulum as well as the Golgi saccules. The present results suggest that LPS and LTA could induce immune responses of microglia/macrophages and astroglial activation in the pineal gland. Furthermore, the metabolic and secretory activity of pinealocytes was modified by products from both gram-positive and -negative bacteria.     

Permeability of the pineal gland of the rat to lanthanum: Significance of dark pinealocytes

The permeability of the pineal gland to lanthanum was investigated by means of transmission electron microscopy and X-ray microanalysis. Different pineal cell populations were studied. Light pinealocytes as well as glial cells were not permeated by the tracer lanthanum, which normally stays extracellularly. Dark pinealocytes showing different degrees of degenerative changes are permeated by lanthanum. The loss of plasma membrane integrity explains the entry of lanthanum into these cells. We conclude: (1) the lanthanum tracer can be used as an indicator of an alteration in membrane permeability, (2) dark pinealocytes appear as cells in the state of degeneration and represent a different physiological state than light pinealocytes.     

Melatonin synthesis and melatonin-membrane receptor (MT1) expression during rat thymus development: role of the pineal gland

To gain insight into the relationship between thymus and pineal gland during rat development, the melatonin content as well as the activity and expression of the two key enzymes for melatonin biosynthesis, i.e. N-acetyltransferase (NAT) and hydroxyindole-O-methyltransferase (HIOMT), were studied in the thymus at fetal and postnatal stages. Moreover, melatonin-membrane receptor (MT1) expression was also analyzed. We found both the expression and activity of thymic NAT and HIOMT at 18 days of fetal life. Additionally, there is production of melatonin in the thymus as well as MT1 expression at this fetal age. These results show values higher in day-time than at night-time. The pineal gland begins to produce significant levels of melatonin around postnatal day 16, and this synthesis shows a circadian rhythm with high values during the dark period; therefore the nocturnal serum melatonin may inhibit thymic melatonin production. To document this, we report an increased melatonin content of the thymus in pinealectomized rats compared with sham-pinealectomized. In conclusion, these results show, for the first time, the presence of the biosynthetic machinery of melatonin and melatonin production in developing rat thymus and that the pineal gland may regulate this process.     

Roles of nocturnal melatonin and the pineal gland in modulation of water-immersion restraint stress-induced gastric mucosal lesions in rats

The roles of melatonin and the pineal gland in the circadian variation of water-immersion restraint stress-induced gastric mucosal lesions in rats were investigated. Fasted rats were subjected to water-immersion restraint stress during both the diurnal and nocturnal phases of a light:dark cycle. Pinealectomized and sham-operated rats were also subjected to water-immersion restraint stress at night. The lesion area after 4 hr of stress during the dark phase was significantly lower than in light-phase controls. Pinealectomy increased the lesion area in the dark phase, compared to the sham operation, but this effect was counteracted by intracisternal melatonin preadministration at a dose of 100 ng/rat. Melatonin concentrations in control rats during the light phase were significantly increased 4 hr after water-immersion restraint stress. In contrast, melatonin concentrations 4 hr after water-immersion restraint stress in the dark phase were significantly depressed compared with the control levels at the corresponding time. Melatonin levels after stress exposure were markedly decreased in pinealectomized rats as compared with sham-operated rats. These results suggest that circadian rhythm has an important role in the formation of stress-induced gastric mucosal lesions in rats and that melatonin responses to water-immersion restraint stress differ between day and night. The pineal gland modulates the stress response and melatonin contributes to gastric protection via a mechanism involving the central nervous system.     

Influence of the pineal gland and circadian rhythms in circulating levels of thyroid hormones of male hamsters

Thyroxin (T4) and triiodothyronine (T3) were measured by radioimmunoassay in serum of hamsters sacrificed at 4-hr intervals throughout the daily light-dark cycle (14L/10D). Both T4 and T3 concentrations increased significantly during the L period of the daily cycle and decreased during the D period of the cycle; A.M. versus P.M. differences in free thyroxin indices (FTI) were also studied using the T4 and T3 uptake assays of Nuclear Medical Laboratories (Dallas, Texas). The free thyroxin index was significantly greater in serum samples of hamsters sacrificed at 7 P.M. than at 7 A.M. (lights on at 6:30 A.M.). Serum taken at 7 P.M. had less unsaturated binding sites than serum taken at 7 A.M. No significant A.M. versus P.M. differences in free thyroxin index were found in blind hamsters, although blind hamsters had significantly lower T4 and FTI than controls. Placing melatonin in the drinking water at a dose of 80 μg/ml did not significantly influence hormone levels. The greatest difference in hormone concentrations between control and blinded hamsters was found in P.M. samples. Blind hamsters had FTIs that were 48% of P.M. controls. Pinealectomy prevented the effects of blinding on T4 levels and FTIs.     

Phase-shifting effects of light on the circadian rhythms of 5-methoxytryptophol and melatonin in the chick pineal gland

In the chick pineal gland, 5-methoxytryptophol and melatonin concentrations fluctuate in a rhythmic manner. These rhythms are circadian in nature persisting in constant darkness and have opposite phases. Acute exposure of chicks to white light (30 lux for 5, 10, 20, and 30 min) at night increased the amount of pineal 5-methoxytryptophol and decreased pineal melatonin content. A 6 hr pulse of light (100 lux) applied early in the subjective night (CT12-CT18) caused a delay in the phase of the circadian rhythms of 5-methoxytryptophol and melatonin by 3.7 and 4.5 h, respectively, compared to untreated controls. When the 6 hr light pulse was given during the late subjective night (C18 CT24) it advanced the phase of the 5-methoxytryptophol and melatonin rhythms by 8.1 and 11.9 h, respectively. In the chick pineal the phase-advancing effects of light on the circadian rhythms of 5-methoxytryptophol and melatonin were more pronounced than the phase-delaying effects. Our results provide the first evidence that light is capable of phase shifting the 5-methoxytryptophol rhythm in a manner similar to its action on the melatonin rhythm.     

The pineal gland of the aging rat: Calcium localization and variation in the number of pinealocytes

Abstract: In the present study, we investigated the population of pinealocytes in the pineal gland of aging rats. Dark and light pinealocytes were analyzed as to their calcium content. Calcium localization was realized in dark and light cells by means of cytochemistry and X-ray microanalysis. Calcium was mainly localized in dark pinealocytes characterized by many ultrastructural signs of degeneration. The number of pinealocytes per square surface of aged rats (28 months) was com-pared to young ones (3–4 months). While there is a significant increase in the number of dark pinealocytes there is a decrease in the total number of pinealo-cytes in aged rats. This age-related loss of pinealocytes may explain the age-related functional decline of the pineal gland activity (e.g., the decrease of the nocturnal melatonin production).     

Daily cycles of putrescine, sperrnidine, and spermine in the liver, pineal gland, Harderian gland, anterior pituitary, and testes of rats kept in LD 12:12

A circadian rhythm in cellular polyamine levels was detected in the liver, pineal gland, anterior pituitary gland, Harderian gland, and testicular seminiferous tubules of male rats fed ad libitum and maintained in a light:dark cycle of LD 12:12 (lights on at 07:00). Liver putrescine content was highest at 24:00, showing a sixfold increase over 12:00 levels. Pineal spermidine and spermine contents reached a maximum at 06:00, late in the dark phase. A similar pattern was also detected in the Harderian gland. In the anterior pituitary, the polyamines putrescine, spermidine and spermine were highest at 18:00, late in the light phase. However, the increase in putrescine was not statistically significant. The three polyamine contents decreased late in the dark phase. In testicular seminiferous tubules putrescine, on the contrary, was highest (about a twofold increase) late in the dark phase.     

UV-A light regulation of arylalkylamine N-acetyltransferase activity in the chick pineal gland: role of cAMP and proteasomal proteolysis

Acute exposure of dark-adapted, cultured chick pineal glands to UV-A light significantly decreased the tissue cAMP concentration and the activity of arylalkylamine N-acetyltransferase (AANAT), the penultimate and key regulatory enzyme in the melatonin biosynthetic pathway. The magnitude of these changes was dependent on the duration of UV-A exposure. The UV-A light-evoked decline in pineal AANAT activity was blocked by cAMP protagonists (forskolin and dibutyryl-cAMP) and by inhibitors of the proteasomal degradation pathway (MG-132, proteasome inhibitor I, and lactacystin). These results indicate that the chick pineal gland is directly sensitive to UV-A light. By analogy to white light, the suppressive action of UV-A radiation on AANAT activity in the chick pineal gland involves changes in the tissue cAMP level and enhanced proteasomal proteolysis.     

The environmental neurotoxin β‐N‐methylamino‐L‐alanine inhibits melatonin synthesis in primary pinealocytes and a rat model

The environmental neurotoxin β‐N‐methylamino‐L‐alanine (BMAA) is a glutamate receptor agonist that can induce oxidative stress and has been implicated as a possible risk factor for neurodegenerative disease. Detection of BMAA in mussels, crustaceans, and fish illustrates that the sources of human exposure to this toxin are more abundant than previously anticipated. The aim of this study was to determine uptake of BMAA in the pineal gland and subsequent effects on melatonin production in primary pinealocyte cultures and a rat model. Autoradiographic imaging of 10‐day‐old male rats revealed a high and selective uptake in the pineal gland at 30 minutes to 24 hours after ¹⁴C‐L‐BMAA administration (0.68 mg/kg). Primary pinealocyte cultures exposed to 0.05‐3 mmol/L BMAA showed a 57%‐93% decrease in melatonin synthesis in vitro. Both the metabotropic glutamate receptor 3 (mGluR3) antagonist Ly341495 and the protein kinase C (PKC) activator phorbol‐12‐myristate‐13‐acetate prevented the decrease in melatonin secretion, suggesting that BMAA inhibits melatonin synthesis by mGluR3 activation and PKC inhibition. Serum analysis revealed a 45% decrease in melatonin concentration in neonatal rats assessed 2 weeks after BMAA administration (460 mg/kg) and confirmed an inhibition of melatonin synthesis in vivo. Given that melatonin is a most important neuroprotective molecule in the brain, the etiology of BMAA‐induced neurodegeneration may include mechanisms beyond direct excitotoxicity and oxidative stress.