mPer2 antisense oligonucleotides inhibit mPER2 expression but not circadian rhythms of physiological activity in cultured suprachiasmatic nucleus neurons

Various day-night rhythms, observed at molecular, cellular, and behavioral levels, are governed by an endogenous circadian clock, predominantly functioning in the hypothalamic suprachiasmatic nucleus (SCN). A class of clock genes, mammalian Period (mPer), is known to be rhythmically expressed in SCN neurons, but the correlation between mPER protein levels and autonomous rhythmic activity in SCN neurons is not well understood. Therefore, we blocked mPer translation using antisense phosphothioate oligonucleotides (ODNs) for mPer1 and mPer2 mRNAs and examined the effects on the circadian rhythm of cytosolic Ca2+ concentration and action potentials in SCN slice cultures. Treatment with mPer2 ODNs (20microM for 3 days) but not randomized control ODNs significantly reduced mPER2 immunoreactivity (-63%) in the SCN. Nevertheless, mPer1/2 ODNs treatment inhibited neither action potential firing rhythms nor cytosolic Ca2+ rhythms. These suggest that circadian rhythms in mPER protein levels are not necessarily coupled to autonomous rhythmic activity in SCN neurons.     

MPer1 and mper2 are essential for normal resetting of the circadian clock

Mammalian Per1 and Per2 genes are involved in the mechanism of the circadian clock and are inducible by light. A light pulse can evoke a change in the onset of wheel-running activity in mice by shifting the onset of activity to earlier times (phase advance) or later times (phase delays) thereby advancing or delaying the clock (clock resetting). To assess the role of mouse Per (mPer) genes in circadian clock resetting, mice carrying mutant mPer1 or mPer2 genes were tested for responses to a light pulse at ZT 14 and ZT 22, respectively. The authors found that mPer1 mutants did not advance and mPer2 mutants did not delay the clock. They conclude that the mammalian Per genes are not only light-responsive components of the circadian oscillator but also are involved in resetting of the circadian clock.     

Temporal expression profiles of ceramide and ceramide-related genes in wild-type and <Emphasis Type="Italic">mPer1/mPer2</Emphasis> double knockout mice

Most living organisms exhibit circadian rhythms in physiology and behavior. These oscillations are generated by an endogenous circadian clock and control many biological processes. Ceramide has attracted attention as a signal mediator in diverse cell processes including cell death and differentiation. The relationships between ceramide expression levels and the circadian clock have not previously been investigated. To determine if there are circadian variations in the content of ceramide, we measured ceramide concentrations in the livers of wild-type (WT) and mPer1/mPer2 double knockout (DKO) mice. The ceramide concentration in WT mice was dramatically increased at Zeitgeber Time 9 (ZT9; 9 h after lights-on time) and ZT21 but no rhythmicity in ceramide expression was seen in DKO mice. Because ceramide can be generated by the hydrolysis of sphingomyelin via sphingomyelinase (SMase), or by ceramide synthase (CerS)-mediated synthesis, we assayed the expression patterns of ceramide-related genes using real-time PCR. CerS2 expression levels showed a biphasic pattern of expression in WT mice but no rhythmicity in DKO mice. While the neutral SMase (nSMase) and acidic SMase (aSMase) mRNA in WT mice were expressed in a circadian manner, the correlation between the expression levels of these SMases with times of day was weak in DKO mice. Collectively, our findings suggest that both SMases and CerS2 mRNA expression are regulated by the presence of mPer1/mPer2 circadian clock genes in vivo, and imply that ceramide may play a vital role in circadian rhythms and physiology.     

EXPRESSION PROFILING REVEALS A POSITIVE REGULATION BY MPER2 ON CIRCADIAN RHYTHM OF CYTOTOXICITY RECEPTORS: LY49C AND NKG2D

The mammalian circadian gene, mPer2, an indispensable component of the mammalian circadian clock, not only modulates endogenous circadian rhythms but also plays a crucial role in regulating innate immune function. Previously, we showed that mPer2 plays a crucial role in regulating cytotoxic response. To investigate the molecular mechanism for mPer2-controlled cytotoxic response, in the present study we conducted mRNA expression for 11 genes participating in cytotoxicity regulation in wild-type (WT) and mPer2 knockout (mPer2 ^{?;?;?/ ?;?;?}) mice bone marrow, that is, Dap-10, Ly49C, Ly49I, Rac1, Mapk1, Map2k1, Nkg2d, Shp-1, Pak1, Pik3ca, and Vav1. The mRNA levels of Ly49C (p?<?0.001), Ly49I (p?=?0.039), and Nkg2d (p?=?0.038) were significantly downregulated in mPer2 ^{?;?;?/ ?;?;?} mice. Time-dependence of expression profiling was then conducted for four core clock genes (Per1, Bmal1, Clock, Rev-erbα), and six out of these 11 cytotoxic regulation genes (Ly49C, Ly49I, Mapk1, Nkg2d, Shp-1, Pik3ca) in WT and mPer2 ^{?;?;?/ ?;?;?} entrained in light/dark (LD) or dark/dark (DD) cycles. Consistently, circadian oscillations were observed for Per1, Rev-erbα, Ly49C, and Nkg2d in WT mice under LD and DD cycles. However, these rhythmic expressions were either disrupted or dampened in mPer2 ^{?;?;?/ ?;?;?} mice. Comparison of gene expression between WT and mPer2 ^{?;?;?/ ?;?;?} mice showed that mPer2 knockout had systematically downregulated the mRNA expression of two cytotoxicity regulators, Ly49C and Nkg2d. FACS analysis further confirmed that the circadian expression of these genes was not due to the daily difference in cell numbers of NK, NKT, or T cells in bone marrow. Taken together, our results reveal that mPer2 is a critical clock component in modulating circadian rhythms in bone marrow. Furthermore, it implies that Ly49C and Nkg2d are two clock-controlled genes that may play an important role in mediating mPer2-controlled cytotoxic response. (Author correspondence: zsunusa@yahoo.com)     

Sleep rhythmicity and homeostasis in mice with targeted disruption of mPeriod genes

In mammals, sleep is regulated by circadian and homeostatic mechanisms. The circadian component, residing in the suprachiasmatic nucleus (SCN), regulates the timing of sleep, whereas homeostatic factors determine the amount of sleep. It is believed that these two processes regulating sleep are independent because sleep amount is unchanged after SCN lesions. However, because such lesions necessarily damage neuronal connectivity, it is preferable to investigate this question in a genetic model that overcomes the confounding influence of circadian rhythmicity. Mice with disruption of both mouse Period genes (mPer)1 and mPer2 have a robust diurnal sleep-wake rhythm in an entrained light-dark cycle but lose rhythmicity in a free-run condition. Here, we examine the role of the mPer genes on the rhythmic and homeostatic regulation of sleep. In entrained conditions, when averaged over the 24-h period, there were no significant differences in waking, slow-wave sleep (SWS), or rapid eye movement (REM) sleep between mPer1, mPer2, mPer3, mPer1-mPer2 double-mutant, and wild-type mice. The mice were then kept awake for 6 h (light period 6-12), and the mPer mutants exhibited increased sleep drive, indicating an intact sleep homeostatic response in the absence of the mPer genes. In free-run conditions (constant darkness), the mPer1-mPer2 double mutants became arrhythmic, but they continued to maintain their sleep levels even after 36 days in free-running conditions. Although mPer1 and mPer2 represent key elements of the molecular clock in the SCN, they are not required for homeostatic regulation of the daily amounts of waking, SWS, or REM sleep.     

Calcium and pituitary adenylate cyclase-activating polypeptide induced expression of circadian clock gene mPer1 in the mouse cerebellar granule cell culture

Mammalian circadian clock genes Per1 and Per2 are rhythmically expressed not only in the suprachiasmatic nucleus where the mammalian circadian clock exists, but also in other brain regions and peripheral tissues. The induced circadian oscillation of Per genes after treatment with high concentrations of serum or various drugs in cultured cells suggests the ubiquitous existence of the oscillatory mechanism. These treatments also result in a rapid surge of expression of Per1. It has been shown that multiple signaling pathways are involved in Per1 gene induction in culture cells. We used a dispersed primary cell culture made up of mouse cerebellar granule cells to examine the stimuli inducing the mPer genes and their signaling pathways in neuronal tissues expressing mPer genes. We demonstrated that mPer1, but not mPer2, mRNA expression was dependent on the depolarization state controlled by extracellular KCl concentration in the granule cell culture. Nifedipine treatment reduced mPer1 induction, suggesting that mPer1 mRNA expression depends on intracellular calcium concentration regulated through a voltage-dependent Ca2+ channel. Transient mPer1 mRNA induction was observed after elevating KCl concentration in the medium from 5 mM to 25 mM. This increased expression was suppressed by a calmodulin antagonist, or CaMKII/IV inhibitor, but not by MEK inhibitors. Addition of pituitary adenylate cyclase-activating polypeptide-38 to the medium also induced transient Per1 gene expression. This induction was mimicked by dibutyryl-cAMP and suppressed by a protein kinase A (PKA) inhibitor, but not by MEK inhibitors. These results suggest that Ca2+/calmodulin-dependent protein kinase II/IV- and PKA-dependent pathways are involved in high-KCl and PACAP-induced mPer1 induction, respectively, and neural tissues use multiple signaling pathways for mPer1 induction similar to culture cells.