In the mouse suprachiasmatic nucleus (SCN), melatonin activates MT1 and MT2 G-protein coupled receptors, which are involved primarily in inhibition of neuronal firing and phase shift of circadian rhythms. This study investigated the ability of melatonin to phase shift circadian rhythms in wild type (WT) and MT1 melatonin receptor knockout (KO) C57BL/6 mice. In WT mice, melatonin (90 microg/mouse, s.c.) administered at circadian time 10 (CT10; CT12 onset of activity) significantly phase advanced the onset of the circadian activity rhythm (0.60 +/- 0.09 hr, n = 41) when compared with vehicle treated controls (-0.02 +/- 0.07 hr, n = 28) (P < 0.001). In contrast, C57 MT1KO mice treated with melatonin did not phase shift circadian activity rhythms (-0.10 +/- 0.12 hr, n = 42) when compared with vehicle treated mice (-0.12 +/- 0.07 hr, n = 43). Similarly, in the C57 MT1KO mouse melatonin did not accelerate re-entrainment to a new dark onset after an abrupt advance of the dark cycle. In contrast, melatonin (3 and 10 pm) significantly phase advanced circadian rhythm of neuronal firing in SCN brain slices independent of genotype with an identical maximal shift at 10 pm (C57 WT: 3.61 +/- 0.38 hr, n = 3; C57 MT(1)KO: 3.45 +/- 0.11 hr, n = 4). Taken together, these results suggest that melatonin-mediated phase advances of circadian rhythms of neuronal firing in the SCN in vitro may involve activation of the MT2 receptor while in vivo activation of the MT1 and possibly the MT2 receptor may be necessary for the expression of melatonin-mediated phase shifts of overt circadian activity rhythms.
The hormone melatonin phase shifts circadian rhythms generated by the mammalian biological clock, the suprachiasmatic nucleus (SCN) of the hypothalamus, through activation of G protein-coupled MT2 melatonin receptors. This study demonstrated that pretreatment with physiological concentrations of melatonin (30-300 pM or 7-70 pg/mL) decreased the number of hMT2 melatonin receptors heterologously expressed in mammalian cells in a time and concentration-dependent manner. Furthermore, hMT2-GFP melatonin receptors heterologously expressed in immortalized SCN2.2 cells or in non-neuronal mammalian cells were internalized upon pretreatment with both physiological (300 pM or 70 pg/mL) and supraphysiological (10 nM or 2.3 ng/mL) concentrations of melatonin. The decrease in MT2 melatonin receptor number induced by melatonin (300 pM for 1 h) was reversible and reached almost full recovery after 8 h; however, after treatment with 10 nM melatonin full recovery was not attained even after 24 h. This recovery process was partially protein synthesis dependent. Furthermore, exposure to physiological concentrations of melatonin (300 pM) for a time mimicking the nocturnal surge (8 h) desensitized functional responses mediated through melatonin activation of endogenous MT2 receptors, i.e., stimulation of protein kinase C (PKC) in immortalized SCN2.2 cells and phase shifts of circadian rhythms of neuronal firing in the rat SCN brain slice. We conclude that in vivo the nightly secretion of melatonin desensitizes endogenous MT2 melatonin receptors in the mammalian SCN thereby providing a temporally integrated profile of sensitivity of the mammalian biological clock to a melatonin signal.
Previous studies have shown that, immediately after the addition of galactose or alanine to the solution bathing the mucosal surface of Necturus small intestine, there is a rapid depolarization of the electrical potential difference across the mucosal membrane (qmC). This is followed by a repolarization of ims that is paralleled by an increase in the ratio of the effective resistance of the mucosal membrane to that of the basolateral membrane (rm/rs); the latter was shown to be, at least in part, due to a marked increase in the conductance of the basolateral membrane. We now report the follow- results in a depolarization of qmc but no subsequent repolarization of And or increase in rm/rs; however, qAmc repolarizes and rm/rs increases when Ba21 is subsequently removed from the serosal bathing solution. We conclude that (i) the basolateral membrane normally possesses a Ba2+-inhibitable K conductance, which appears to be reduced in the presence of metabolic inhibitors; (it) after exposure of the tissue to a hypotonic solution or the addition of galactose to the mucosal solution, this conductance increases; and (iii) these responses can be blocked by metabolic inhibitors. These findings suggest that the delayed response of this tissue to the addition of sugars or amino acids to the mucosal solution may be the result of cell swelling resulting from the intracellular accumulation of these solutes in osmotically active forms.Previous studies from this laboratory have disclosed that the addition of galactose or alanine to the solution bathing the mucosal surface of Necturus small intestine, in vitro, brings about a rapid depolarization of the electrical potential difference across the mucosal (or apical) membrane and an increase in the conductance of that barrier (1). This initial response, which can be attributed to the activation of rheogenic Na'-coupled cotransport processes for sugar and/or amino acid entry across the mucosal membrane, is followed by a slower repolarization of the electrical potential difference across that barrier that is blocked by the presence of metabolic inhibitors in the bathing solutions and appears to be the result of an increase in the K+ conductance of the basolateral membrane (1, 2); however, the "intracellular signal" that elicits this delayed increase in basolateral membrane conductance was not definitively resolved in these studies.It has long been known that sugars and amino acids are accumulated within small intestinal cells in osmotically active forms and, thus, are accompanied by an increase in cell water content and volume (3-5). Recently, studies on several epithelia have indicated that the initial increase in cell volume resulting from exposure to hypotonic bathing solutions is followed by a partial or full restoration of the original cell volume (6-8). It appears that this "volume regulatory response" is due, at least in part, to an increase in the permeability of the basolateral membrane to K+, which results in a loss of K+ from the cells (presumably accompanied by Cl-...
This study assessed the role of melatonin in modulating running wheel(RW)-induced hippocampal neurogenesis in adult C3H/HeN mice. Chronic melatonin (0.02 mg/mL, oral for 12 days) treatment did not affect cell proliferation or cell survival determined by the number of BrdU-positive cells in dentate gyrus of mice with access to fixed wheel (FW). RW activity significantly increased cell proliferation [RW (n = 8) versus FW (n = 6): dorsal, 199 ± 18 versus 125 ± 12, P < 0.01; ventral, 211 ± 15 versus 123 ± 13, P < 0.01] and newborn cell survival [RW (n = 7) versus FW (n = 8): dorsal, 45 ± 8.5 versus 15 ± 1.8, P < 0.01; ventral, 48 ± 8.1 versus 15 ± 1.4)] in the dorsal and ventral dentate gyrus. Oral melatonin treatment further potentiated RW activity-induced cell survival in both areas of the dentate gyrus [melatonin (n = 10) versus vehicle (n = 7): dorsal, 63 ± 5.4 versus 45 ± 8.5 P < 0.05; ventral, 75 ± 7.9 versus 48 ± 8.1, P < 0.01] and neurogenesis [melatonin (n = 8) versus vehicle (n = 8): dorsal, 46 ± 3.4, versus 34 ± 4.5, P < 0.05; ventral, 41 ± 3.4 versus 25 ± 2.4, P < 0.01]. We conclude that melatonin potentiates RW-induced hippocampal neurogenesis by enhancing neuronal survival suggesting that the combination of physical exercise and melatonin may be an effective treatment for diseases affecting the hippocampus neurogenesis.
Advances in rodent behavior dissection using automated video recording and analysis allows detailed phenotyping. This study compared and contrasted 15 diurnal behaviors recorded continuously using an automated behavioral analysis system for a period of 14 days under a 14/10 light/dark cycle in single housed C3H/HeN (C3H) or C57BL/6 (C57) male mice. Diurnal behaviors, recorded with minimal experimental interference and analyzed using phenotypic array and temporal distribution analysis showed bimodal and unimodal profiles in the C57 and C3H mice, respectively. Phenotypic array analysis revealed distinct behavioral rhythms in activity-like behaviors (i.e. walk, hang, jump, come down) (ALB), exploration-like behaviors (i.e. dig, groom, rear up, sniff, stretch) (ELB), ingestion-like behaviors (i.e. drink, eat) (ILB) and resting-like behaviors (i.e. awake, remain low, rest, twitch) (RLB) of C3H and C57 mice. Temporal analysis demonstrated that strain and time of day affects the magnitude and distribution of the spontaneous homecage behaviors. Wheel running activity, water and food measurements correlated with timing of homecage behaviors. Subcutaneous (3 mg/kg, sc) or oral (0.02 mg/ml, oral) melatonin treatments in C57 mice did not modify either the total 24 hr magnitude or temporal distribution of homecage behaviors when compared with vehicle treatments. We conclude that C3H and C57 mice show different spontaneous activity and behavioral rhythms specifically during the night period which are not modulated by melatonin.
Behaviors vary over the 24 hr. light/dark cycle and these temporal patterns reflect in part modulation by circadian neural circuits and hormones, such as melatonin. The goal of this study was to investigate if MT1 melatonin receptors are involved in behavioral regulation by comparing male and female C57 wild type (WT) mice with C57 mice that had a genetic deletion of the MT1 receptor (MT1KO). A comprehensive array of fifteen distinct spontaneous behaviors was recorded continuously in the homecage over multiple days using the HomeCageScan system. Behaviors assessed were activity-like (i.e. come down, hang, jump, walk), exploration-like (i.e. dig, groom, rear up, sniff, stretch), resting-like (i.e. awake, remain low, rest, twitch) and ingestion-like (i.e. drink, eat). Phenotypic array and temporal distribution analysis revealed distinct behavioral rhythms that differed between WT and MT1KO mice. The rhythms were consistent from day to day in males and varied with the estrous cycle in females. We also studied the role of MT1 receptors on depressive and anxiety-like behaviors. Genetic deletion of MT1 receptors increased immobility time in the forced swim test and decreased the number of marbles buried in the marble burying test in both male and female C57 mice. We conclude that MT1 melatonin receptors are involved in neural pathways modulating diurnal rhythms of spontaneous behavior in the homecage as well as pathways regulating depressive and anxiolytic-like behaviors.
The addition of 10 mM glycine to a physiological saline bathing Ehrlich ascites tumor cells is followed by a slow increase in cell volume that plateaus between 15 and 30 min at a level -17% greater than the control volume; this increase is not observed when glycine is added to cells suspended in a Na+-free saline. The results of studies using the patch-clamp technique in the cell-attached mode indicate that, 0.5-3 min after the addition of glycine to the bathing solution, there is a marked increase in the activity of single channels, which in almost all instances were previously present and operant in the plasma membrane. Successfully excised patches ofmembrane that contained a channel stimulated by glycine fell into two categories. Some became inactive within 15 sec in spite of the fact that the Gil seal remained intact. Others persisted for the lifetime of the seal. All of the persistent channels had an 11-fold selectivity for ClP over K+ and a conductance of 23 pS when bathed by symmetrical 150 mM KCI solutions. Although the ionic specificities of the other channels have not been identified, there is reason to suspect that they might be K+ channels whose activities are dependent on factors lost when the patch is excised. Swelling induced by exposing these cells to a 50% hypotonic perfusate stimulated the activities of Clchannels whose properties closely resemble those stimulated by the addition of glycine to the perfusate, strongly suggesting that the glycine-induced stimulation of Cl-channel activity is part of a volume-regulatory response to cell swelling. If the increase in channel activity induced by the addition of glycine to the perfusate is indeed a response to cell swelling, then this volume-regulatory response must be extremely sensitive inasmuch as it appears to be "triggered" by an average increase in cell volume that does not exceed 5%.The results of previous studies reported by this laboratory indicate that the addition of sugars or amino acids to the solution bathing the mucosal surface of Necturus small intestine results in an initial, rapid depolarization of the electrical potential difference across the apical membrane (f/c) and a decrease in the ratio of the resistance of the apical membrane (rm) to that of the basolateral membrane (rs) i.e., (rI/rs). These responses are followed by a slower, partial repolarization of mc that is paralleled by an increase in (rm/rs) to levels that exceed those observed in the absence of the sugar or amino acid (1). The initial responses can be attributed to the activation of rheogenic and conductive carrier-mediated pathways for the coupled entry of Na+ and sugars or amino acids into the cell across the apical membrane (1, 2). The secondary responses appear to be, at least in part, due to an increase in the conductance of the basolateral membranes to K+, (gk), which is blocked by the presence of Ba2+ in the serosal solution and by exposure of the tissue to metabolic inhibitors (1, 3, 4).In addition, circumstantial evidence has been reported suggesting...
This study explored the role of the melatonin receptors in methamphetamine (METH)-induced locomotor sensitization during the light and dark phases in C3H/HeN mice with genetic deletion of theMT1 and/or MT2 melatonin receptors. Six daily treatments with METH (1.2 mg/kg, i.p.) in a novel environment during the light phase led to the development of locomotor sensitization in wild-type (WT), MT1KO and MT2KO mice. Following four full days of abstinence, METH challenge (1.2 mg/kg, i.p.) triggered the expression of locomotor sensitization in METH-pretreated but not in vehicle (VEH)-pretreated mice. In MT1/MT2KO mice, the development of sensitization during the light phase was significantly reduced and the expression of sensitization was completely abrogated upon METH challenge. During the dark phase the development of locomotor sensitization in METH-pretreated WT, MT1KO and MT2KO mice was statistically different from VEH-treated controls. However, WT and MT2KO, but not MT1KO mice receiving repeated VEH pretreatments during the dark phase expressed a sensitized response to METH challenge that is of an identical magnitude to that observed upon 6 days of METH pretreatment. We conclude that exposure to a novel environment during the dark phase, but not during the light phase, facilitated the expression of sensitization to a METH challenge in a manner dependent on MT1 melatonin receptor activation by endogenous melatonin. We suggest that MT1 and MT2 melatonin receptors are potential targets for pharmacotherapeutic intervention in METH abusers.
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