The suprachiasmatic nucleus is the master circadian clock and resets the peripheral clocks via various pathways. Glucocorticoids and daily feeding are major time cues for entraining most peripheral clocks. However, recent studies have suggested that the dominant timing factor differs among organs and tissues. In our current study, we reveal differences in the entrainment properties of the peripheral clocks in the liver, kidney, and lung through restricted feeding (RF) and antiphasic corticosterone (CORT) injections in adrenalectomized rats. The peripheral clocks in the kidney and lung were found to be entrained by a daily stimulus from CORT administration, irrespective of the meal time. In contrast, the liver clock was observed to be entrained by an RF regimen, even if daily CORT injections were given at antiphase. These results indicate that glucocorticoids are a strong zeitgeber that overcomes other entrainment factors regulating the peripheral oscillators in the kidney and lung and that RF is a dominant mediator of the entrainment ability of the circadian clock in the liver. (Endocrinology 153: 2277-2286, 2012) M ost living organisms have developed internal clock mechanisms that generate precise rhythms around a 24-h cycle. One such system, termed the circadian clock, governs daily variations in physiology and behavior. In mammals, the suprachiasmatic nucleus (SCN) is the center of the circadian clock and resides in the hypothalamus (1). The molecular oscillator in the SCN consists of interacting positive and negative transcription/translation feedback loops (2-4). The transcriptional activators CLOCK and BMAL1 form heterodimers and stimulate the transcription of other clock genes, such as the Period (Per) genes (Per1, Per2, and Per3), the Cryptochromes (Cry) (Cry1 and Cry2), retinoid-related orphan receptors (ROR) (ROR␣, ROR, and ROR␥) and Rev-erbes (Rev-erb␣ and Rev-erb) that bind to the E-box response elements in the promoter regions of these genes. Accumulated PER and CRY proteins form a complex that represses the transcriptional activity of the CLOCK/BMAL1 heterodimer. The ROR transcriptional activators and REV-ERB repressors control the transcriptional regulation of Clock and Bmal1 through their binding to the REV response element (RRE). This autoregulatory loop generates gene expression oscillations of approximately 24 h. In addition, the mammalian SCN can adapt to environmental changes in day/night cycles. Light information from the retinas is delivered to the SCN via the retino-hypothalamic tract and is the most effective time cue for the central clock. Nocturnal light induces the Per1 and Per2 genes, which leads to a resetting of the circadian clock in the SCN (5).The molecular circadian clock operates not only in the SCN but also in peripheral organs and tissues (6, 7). The peripheral clocks are entrained by the central circadian clock in the SCN and express overt circadian rhythms during physiological events (8, 9). Hence, it is commonly assumed that the mammalian circadian system is a complex h...
Most biological processes accelerate with temperature, for example cell division. In contrast, the circadian rhythm period is robust to temperature fluctuation, termed temperature compensation. Temperature compensation is peculiar because a system-level property (i.e., the circadian period) is stable under varying temperature while individual components of the system (i.e., biochemical reactions) are usually temperature-sensitive. To understand the mechanism for period stability, we measured the time series of circadian clock transcripts in cultured C6 glioma cells. The amplitudes of Cry1 and Dbp circadian expression increased significantly with temperature. In contrast, other clock transcripts demonstrated no significant change in amplitude. To understand these experimental results, we analyzed mathematical models with different network topologies. It was found that the geometric mean amplitude of gene expression must increase to maintain a stable period with increasing temperatures and reaction speeds for all models studied. To investigate the generality of this temperature–amplitude coupling mechanism for period stability, we revisited data on the yeast metabolic cycle (YMC) period, which is also stable under temperature variation. We confirmed that the YMC amplitude increased at higher temperatures, suggesting temperature-amplitude coupling as a common mechanism shared by circadian and 4 h-metabolic rhythms.
During mouse skin wound healing, mRNAs encoding IL-1, activins, and TGF-βs significantly increased. To elucidate involvement of IL-1 in the regulation of activins and related factors in the wounded skin, human foreskin fibroblasts were stimulated with IL-1β, and levels of mRNAs encoding activins, TGF-βs, and follistatin family proteins were examined by quantitative real-time PCR. IL-1β increased activin βA (INHBA) and follistatin (FST) mRNA expression within 6 h. A p38 MAPK inhibitor, SB202190, a MAPK/ERK kinase inhibitor, U0126, and an nuclear factor κB pathway inhibitor, SC-514, significantly suppressed the IL-1β-stimulated INHBA and FST mRNA expression. A prostaglandin-endoperoxide synthase inhibitor indomethacin, a potent inhibitor of prostaglandin E(2) (PGE(2)) synthesis, also significantly suppressed the IL-1β-stimulated INHBA but not FST mRNA expression. Furthermore, stimulation of fibroblasts with PGE(2) significantly increased INHBA mRNA. The PGE(2)-induced INHBA mRNA expression was significantly suppressed by U0126 and a protein kinase C inhibitor, Gö 6983. Although IL-1β stimulated FST mRNA in an acute phase, long-term exposure of fibroblasts to IL-1β revealed time-dependent stimulatory and inhibitory effects of IL-1β on FST mRNA expression. On the other hand, coculture with keratinocytes significantly increased INHBA mRNA expression in dermal equivalents. In summary, the present study indicates that the p38 MAPK, the MAPK/ERK kinase, the nuclear factor κB pathway, and PGE(2) mediate the effects of IL-1β on INHBA mRNA expression. Furthermore, it is indicated that keratinocyte-derived factor of factors stimulate INHBA mRNA expression during wound healing.
Aquaporin 4 (AQP4) is a predominant water channel protein in mammalian brains, localized in the astrocyte plasma membrane. The regulation of AQP4 is believed to be important for the homeostasis of water in the brain, but the AQP4 regulatory mechanisms are not yet known. In this study, we investigated the effect of a protein kinase C (PKC) activator on the expression of AQP4 mRNA in cultured rat astrocytes. Cultured rat astrocytes constitutively expressed AQP4 mRNA. Treatment of the cells with 0.1 microM of phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA), an activator of PKC, caused a rapid decrease in AQP4 mRNA. This effect was time- and dose-dependent. The TPA-induced decrease in AQP4 mRNA was inhibited by a relatively specific PKC inhibitor, 1-(5-isoquinoline sulfonyl)-2-methylpiperazine (H7) in a dose-dependent manner. Moreover, prolonged treatment of the cells with TPA eliminated the subsequent decrease in AQP4 mRNA by TPA. These results strongly suggest that the TPA-induced decrease in AQP4 mRNA is mediated by PKC activation. To test whether the effect of TPA requires protein synthesis, astrocytes were pretreated with cycloheximide, an inhibitor of protein synthesis. Pretreatment of the cells with cycloheximide did not inhibit the decrease in AQP4 mRNA induced by TPA. To test whether the TPA-induced decrease in AQP4 was due to a decrease in the mRNA stability, we examined the effect of actinomycin D, an inhibitor of transcription, on TPA-treated cells. The stability of AQP4 mRNA was not decreased by the pretreatment of the cells with actinomycin D. The results suggest that AQP4 mRNA is inhibited by TPA via PKC activation without de novo protein synthesis, and that the inhibition of AQP4 mRNA could be at the transcriptional level.
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