Circadian rhythms in the mouse reproductive axis during the estrous cycle and pregnancy

Molecular and behavioral timekeeping is regulated by the circadian system which includes the brain's suprachiasmatic nucleus (SCN) that translates environmental light information into neuronal and endocrine signals aligning peripheral tissue rhythms to the time of day. Despite the critical role of circadian rhythms in fertility, it remains unexplored how circadian rhythms change within reproductive tissues during pregnancy. To determine how estrous cycle and pregnancy impact phase relationships of reproductive tissues, we used PER2::Luciferase (PER2::LUC) circadian reporter mice and determined the time of day of PER2::LUC peak (phase) in the SCN, pituitary, uterus, and ovary. The relationships between reproductive tissue PER2::LUC phases changed throughout the estrous cycle and late pregnancy and were accompanied by changes to PER2::LUC period in the SCN, uterus, and ovary. To determine if the phase relationship adaptations were driven by sex steroids, we asked if progesterone, a hormone involved in estrous cyclicity and pregnancy, could regulate Per2‐luciferase expression. Using an in vitro transfection assay, we found that progesterone increased Per2‐luciferase expression in immortalized SCN (SCN2.2) and arcuate nucleus (KTAR) cells. In addition, progesterone shortened PER2::LUC period in ex vivo uterine tissue recordings collected during pregnancy. As progesterone dramatically increases during pregnancy, we evaluated wheel‐running patterns in PER2::LUC mice. We confirmed that activity levels decrease during pregnancy and found that activity onset was delayed. Although SCN, but not arcuate nucleus, PER2::LUC period changed during late pregnancy, onset of locomotor activity did not correlate with SCN or arcuate nucleus PER2::LUC period.     

Resetting the brain clock: time course and localization of mPER1 and mPER2 protein expression in suprachiasmatic nuclei during phase shifts

The mechanism whereby brief light pulses reset the mammalian circadian clock involves acute Per gene induction. In a previous study we investigated light-induced expression of mPer1 and mPer2 mRNA in the suprachiasmatic nuclei (SCN), with the aim of understanding the relationship between gene expression and behavioural phase shifts. In the present study, we examine the protein products of mPer1 and mPer2 genes in the core and shell region of SCN for 34 h following a phase-shifting light pulse, in order to further explore the molecular mechanism of photic entrainment. The results indicate that, during the delay zone of the phase response curve, while endogenous levels of mPER1 and mPER2 protein are falling, a light pulse produces an increase in the expression of both proteins. In contrast, during the advance zone of the phase response curve, while levels of endogenous mPER1 and mPER2 proteins are rising, a light pulse results in a further increase in mPER1 but not mPER2 protein. The regional distribution of mPER1 and mPER2 protein in the SCN follows the same pattern as their respective mRNAs, with mPER1 expression in the shell region of SCN correlated with phase advances and mPER2 in the shell region correlated with phase delays.     

Behavioural rhythm splitting in the CS mouse is related to clock gene expression outside the suprachiasmatic nucleus

CS mice exhibit a spontaneous splitting in the circadian rhythm of locomotor activity under constant darkness, suggesting that they contain two weakly coupled oscillators in the circadian clock system regulating locomotor activity rhythm. In order to clarify whether the two oscillators are located in the suprachiasmatic nucleus (SCN), a site of the master circadian pacemaker in mammals, circadian rhythms in mRNA of mouse Period genes (mPer1, mPer2 and mPer3) in the SCN and cerebral cortex were examined during rhythm splitting by in situ hybridization. In the SCN, mPer1 and mPer2 showed a circadian rhythm with a single peak in both split and unsplit mice. The rhythms of mPer1 and mPer2 were slightly phase delayed during rhythm splitting in reference to the activity onset, but the phase relationship between the two rhythms was not changed. In the cerebral cortex, the expression of mPer1 and mPer2 underwent the bimodal fluctuation with peaks temporally corresponding to split activity components. The unsplit mice showed the circadian rhythms with a single peak. There was no difference in the mPer3 rhythms in either the SCN or the cerebral cortex between the split and unsplit mice. These results indicate that the circadian oscillations of mPer1, mPer2 and mPer3 in the SCN are not related to the rhythm splitting of CS mice. The split rhythms of the CS mice are suggested to be caused by uncoupling of oscillators located outside the SCN from the SCN circadian pacemaker.     

Dual regulation of clock gene Per2 expression in discrete brain areas by the circadian pacemaker and methamphetamine‐induced oscillator in rats

Behavioral rhythms induced by methamphetamine (MAP) treatment in rats are independent of the circadian pacemaker in the suprachiasmatic nucleus (SCN). To know the site and mechanism of an underlying oscillation (MAP‐induced oscillator; MAO), extra‐SCN circadian rhythms in the discrete brain areas were examined in rats with and without the SCN. To fix the phase of MAO, MAP was supplied in drinking water at a restricted time of day for 14 days (R‐MAP) and subsequently given ad libitum (ad‐MAP). Plain water was given to the controls at the same restricted time (R‐Water). Clock gene Per2 expression was measured by a bioluminescence reporter in cultured brain tissues. In SCN‐intact rats, MAO was induced by R‐MAP and behavioral rhythms were phase‐delayed from the restricted time under ad‐MAP with relative coordination. Circadian Per2 rhythms in R‐MAP rats were not affected in the SCN but were slightly phase‐advanced in the olfactory bulb (OB), caudate–putamen (CPU) and substantia nigra (SN) as compared with R‐Water rats. Following SCN lesion, R‐MAP‐induced MAO phase‐shifted more slowly and did not show a sign of relative coordination. In these rats, circadian Per2 rhythms were significantly phase‐shifted in the OB and SN as compared with SCN‐intact rats. These findings indicate that MAO was induced by MAP given at a restricted time of day in association with phase‐shifts of the extra‐SCN circadian oscillators in the brain dopaminergic areas. The findings also suggest that these extra‐SCN oscillators are the components of MAO and receive dual regulation by MAO and the SCN circadian pacemaker.     

The complex relationship between the light‐entrainable and methamphetamine‐sensitive circadian oscillators: evidence from behavioral studies of Period‐mutant mice

The methamphetamine‐sensitive circadian oscillator (MASCO) is an enigmatic circadian clock whose output is observed during continuous consumption of low‐dose methamphetamine. The MASCO rhythm persists when the light‐entrainable pacemaker in the suprachiasmatic nucleus (SCN) is lesioned, but the anatomical location of MASCO is unknown. We recently found that the period of the MASCO rhythm is unusually short (21 h) in mice with disruption of all three paralogs of the canonical clock gene, Period. In this study, we investigated the contribution of each Period paralog to timekeeping in MASCO. We measured wheel‐running activity rhythms in intact and SCN‐lesioned Per1‐, 2‐ and 3‐mutant mice administered methamphetamine, and found that none of the mice displayed a short (21‐h) period, demonstrating that no single Period gene is responsible for the short‐period MASCO rhythm of Per1^?/?/Per2^?/?/Per3^?/? mice. We also found that the periods of activity rhythms in constant darkness were lengthened by methamphetamine treatment in intact wild‐type, Per1^?/? and Per3^?/? mice but not Per2^?/? mice, and Per2^?/? mice had two distinct activity rhythms upon release to constant light. These data suggest that the SCN and MASCO are not coupled in Per2^?/? mice. The MASCO rhythm in Per1^?/?/Per2^?/? mice in constant darkness alternated between a short (22‐h) and a long (27‐h) period. This pattern could result from two coupled oscillators that are not synchronised to each other, or from a single oscillator displaying birhythmicity. Finally, we propose a working model of the in vivo relationship between MASCO and the SCN that poses testable hypotheses for future studies.     

Differential responses of circadian Per2 expression rhythms in discrete brain areas to daily injection of methamphetamine and restricted feeding in rats

Behavioral rhythms induced by methamphetamine (MAP) and daily restricted feeding (RF) in rats are independent of the circadian pacemaker in the suprachiasmatic nucleus (SCN), and have been regarded to share a common oscillatory mechanism. In the present study, in order to examine the responses of brain oscillatory systems to MAP and RF, circadian rhythms in clock gene, Period2, expression were measured in several brain areas in rats. Transgenic rats carrying a bioluminescence reporter of Period2‐dLuciferase were subjected to either daily injection of MAP or RF of 2 h at a fixed time of day for 14 days. As a result, spontaneous movement and wheel‐running activity were greatly enhanced following MAP injection and prior to daily meal under RF. Circadian Per2 rhythms were measured in the cultured brain tissues containing one of the following structures: the olfactory bulb; caudate‐putamen; parietal cortex; substantia nigra; and SCN. Except for the SCN, the circadian Per2 rhythms in the brain tissues were significantly phase‐delayed by 1.9 h on average in MAP‐injected rats as compared with the saline‐controls. On the other hand, the circadian rhythms outside the SCN were significantly phase‐advanced by 6.3 h on average in rats under RF as compared with those under ad libitum feeding. These findings indicate that the circadian rhythms in specific brain areas of the central dopaminergic system respond differentially to MAP injection and RF, suggesting that different oscillatory mechanisms in the brain underlie the MAP‐induced behavior and pre‐feeding activity under RF.     

Daily exposure to cold phase‐shifts the circadian clock of neonatal rats in vivo

Maternal rhythms entrain the prenatal and neonatal circadian clock in the suprachiasmatic nucleus (SCN) before light entrainment is established. However, the responsible time cues for maternal entrainment are not identified. To examine the role of cyclic changes of ambient temperature in maternal entrainment, blind neonatal rats carrying a clock gene (Per2) bioluminescence reporter were exposed to either of three ambient temperatures (10, 20 or 30 °C) during 6‐h maternal separation in the early light phase. Cold exposure was performed from postnatal day 1 (P1) to P5. On P6, the SCN was harvested and cultured for photometric monitoring of the circadian rhythm in Per2 expression. Here we demonstrate that the daily cold exposure phase‐delayed the circadian Per2 expression rhythms at P6 in a temperature‐dependent manner. Exposure to 10 °C produced the largest phase‐shift of 12.7 h, and exposure to 20 and 30 °C yielded moderate shifts of 4.1 and 4.5 h, respectively. There was no significant difference in the phase‐shifts between the latter two temperatures, indicating that ambient temperature is not the sole factor for the phase‐shift. Behavioral rhythms that developed after weaning reflected the phase‐shift of clock gene expression rhythm in the SCN. These findings indicate that a daily exposure to an ambient temperature of 10 °C during the neonatal period is capable of resetting the circadian clock in the SCN, but other factors yet unidentified are also involved in maternal entrainment.     

A hVIPR transgene as a novel tool for the analysis of circadian function in the mouse suprachiasmatic nucleus

A mouse bearing a novel transgene encoding the human VPAC2 receptor (hVIPR; Shen et al. (2000) PNAS, 97, 11575-11580) was used to investigate circadian function in the hypothalamic suprachiasmatic nuclei (SCN). Neurons expressing hVPAC2R, detected by a beta-galactosidase (beta-GAL) tag, have a distinct distribution within the SCN, closely matching that of neurophysin (NP) neurons and extending into the region of peptide histidine isoleucine (PHI) cells. In common with NP and PHI cells, neurons expressing hVPAC2R are circadian in nature, as revealed by synchronous rhythmic expression of mPERIOD (mPER) proteins. A population of SCN cells not expressing PHI, NP or hVPAC2R exhibited circadian PER expression antiphasic with the rest of the SCN. Nocturnal light exposure induced mPER1 in the ventral SCN and mPER2 widely across the nucleus. Induction of nuclear mPER2 in hVPAC2R cells confirmed their photic responsiveness. Having established their circadian properties, we tested the utility of SCN neurons expressing the hVIPR transgene as functionally and anatomically explicit markers for SCN tissue grafts. Prenatal SCN tissue from hVIPR transgenic pups survived transplantation into adult CD1 mice, and expressed beta-GAL, PER and PHI. Over a series of studies, hVIPR transgenic SCN grafts restored circadian activity rhythms to 17 of 72 arrhythmic SCN lesioned recipients (23.6%). By using heterozygous hVIPR transgenic grafts on a heterozygous Clock mutant background we confirmed that restored activity rhythms were conferred by the donor tissue. We conclude that the hVIPR transgene is a powerful and flexible tool for examination of circadian function in the mouse SCN.     

A hVIPR transgene as a novel tool for the analysis of circadian function in the mouse suprachiasmatic nucleus

A mouse bearing a novel transgene encoding the human VPAC2 receptor (hVIPR; Shen et al. (2000) PNAS, 97, 11575-11580) was used to investigate circadian function in the hypothalamic suprachiasmatic nuclei (SCN). Neurons expressing hVPAC2R, detected by a beta-galactosidase (beta-GAL) tag, have a distinct distribution within the SCN, closely matching that of neurophysin (NP) neurons and extending into the region of peptide histidine isoleucine (PHI) cells. In common with NP and PHI cells, neurons expressing hVPAC2R are circadian in nature, as revealed by synchronous rhythmic expression of mPERIOD (mPER) proteins. A population of SCN cells not expressing PHI, NP or hVPAC2R exhibited circadian PER expression antiphasic with the rest of the SCN. Nocturnal light exposure induced mPER1 in the ventral SCN and mPER2 widely across the nucleus. Induction of nuclear mPER2 in hVPAC2R cells confirmed their photic responsiveness. Having established their circadian properties, we tested the utility of SCN neurons expressing the hVIPR transgene as functionally and anatomically explicit markers for SCN tissue grafts. Prenatal SCN tissue from hVIPR transgenic pups survived transplantation into adult CD1 mice, and expressed beta-GAL, PER and PHI. Over a series of studies, hVIPR transgenic SCN grafts restored circadian activity rhythms to 17 of 72 arrhythmic SCN lesioned recipients (23.6%). By using heterozygous hVIPR transgenic grafts on a heterozygous Clock mutant background we confirmed that restored activity rhythms were conferred by the donor tissue. We conclude that the hVIPR transgene is a powerful and flexible tool for examination of circadian function in the mouse SCN.     

Methamphetamine-induced,suprachiasmatic nucleus-independent circadian rhythms of activity and mPer gene expression in the striatum of the mouse

While the suprachiasmatic nucleus (SCN) coordinates the majority of daily rhythms, some circadian patterns of expression are controlled from outside of the SCN. These include responses to daily methamphetamine (MAP) injection, or daily restricted feeding. The mechanisms underlying these SCN-independent circadian rhythms are unknown. A circadian oscillation in the expression of mPer1 and/or mPer2, mouse period, in the SCN is considered necessary to generate an SCN-dependent circadian rhythm. Therefore, in this experiment, we examined the association between mPer gene expression and the MAP-induced, SCN-independent circadian rhythm. Acute injection of MAP caused an elevation of mPer1, mBmal1, and mNpas2 gene expression in the striatum and mPer1 in the liver. Daily MAP injection at a fixed time for 6 days shifted the rhythmic mPer1 and mPer2 expression in the striatum from a nocturnal to a diurnal rhythm, but failed to affect that in the SCN. Although lesion of the SCN 'flattened'mPer gene oscillation in the striatum and liver, daily MAP injection caused both behavioural and mPer gene expression rhythms. Daily MAP injection at variable injection intervals (12-36 h) for 6 days, however, failed to produce mPer gene rhythm in the striatum. Daily repeated MAP signals may strengthen the oscillatory force of SCN-independent circadian behavioural and molecular rhythms. The present results suggest that daily oscillation of mPer genes outside the SCN is closely associated with the regulation of SCN-independent rhythms. Thus, the present experiment highlights strongly the important role of clock gene expression, in the brain, that underlies the circadian behavioural rhythm.     

A short half-life GFP mouse model for analysis of suprachiasmatic nucleus organization

Period1 (Per1) is one of several clock genes driving the oscillatory mechanisms that mediate circadian rhythmicity. Per1 mRNA and protein are highly expressed in the suprachiasmatic nuclei, which contain oscillator cells that drive circadian rhythmicity in physiological and behavioral responses. We examined a transgenic mouse in which degradable green fluorescent protein (GFP) is driven by the mPer1 gene promoter. This mouse expresses precise free-running rhythms and characteristic light induced phase shifts. GFP protein (reporting Per1 mRNA) is expressed rhythmically as measured by either fluorescence or immunocytochemistry. In addition the animals show predicted rhythms of Per1 mRNA, PER1 and PER2 proteins. The localization of GFP overlaps with that of Per1 mRNA, PER1 and PER2 proteins. Together, these results suggest that GFP reports rhythmic Per1 expression. A surprising finding is that, at their peak expression time GFP, Per1 mRNA, PER1 and PER2 proteins are absent or not detectable in a subpopulation of SCN cells located in the core region of the nucleus.     

Circadian rhythms of extracellular ATP accumulation in suprachiasmatic nucleus cells and cultured astrocytes

The master circadian pacemaker located within the suprachiasmatic nucleus (SCN) of the mammalian brain controls system-level rhythms in animal physiology. Specific SCN outputs synchronize circadian physiological rhythms in other brain regions. Within the SCN, communication among neural cells provides for the coordination of autonomous cellular oscillations into ensemble rhythms. ATP is a neural transmitter involved in local communication among astrocytes and between astrocytes and neurons. Using a luciferin–luciferase chemiluminescence assay, we have demonstrated that ATP levels fluctuate rhythmically within both SCN2.2 cell cultures and the rat SCN in vivo . SCN2.2 cells generated circadian oscillations in both the production and extracellular accumulation of ATP. Circadian fluctuations in ATP accumulation persisted with an average period ( τ ) of 23.7 h in untreated as well as vehicle-treated and forskolin-treated SCN2.2 cells, indicating that treatment with an inductive stimulus is not necessary to propagate these rhythms. ATP levels in the rat SCN in vivo were marked by rhythmic variation during exposure to 12 h of light and 12 h of dark or constant darkness, with peak accumulation occurring during the latter half of the dark phase or subjective night. Primary cultures of cortical astrocytes similarly expressed circadian oscillations in extracellular ATP accumulation that persisted for multiple cycles with periods of about 23 h. These results suggest that circadian oscillations in extracellular ATP levels represent a physiological output of the mammalian cellular clock, common to the SCN pacemaker and astrocytes from at least some brain regions, and thus may provide a mechanism for clock control of gliotransmission between astrocytes and to neurons.     

Differentiation of PC12 Cells Results in Enhanced VIP Expression and Prolonged Rhythmic Expression of Clock Genes

To examine for circadian rhythmicity, the messenger RNA (mRNA) amount of the clock genes Per1 and Per2 was measured in undifferentiated and nerve-growth-factor-differentiated PC12 cells harvested every fourth hour. Serum shock was needed to induce circadian oscillations, which in undifferentiated PC12 cultures lasted only one 24-h period, while in differentiated cultures, the rhythms continued for at least 3 days. Thus, neuronal differentiation provided PC12 cells the ability to maintain rhythmicity for an extended period. Both vasoactive intestinal polypeptide (VIP) and its receptor VPAC2 are expressed in the suprachiasmatic nucleus (SCN), and in agreement with VIP signaling being crucial for maintenance of rhythmicity, we found both VIP and VPAC2 mRNA increased after differentiation of PC12 cells. Pituitary adenylate cyclase activating polypeptide (PACAP) exerts time- and concentration-dependent effects on Per gene expression in the SCN. We added 1 nM and 1 microM PACAP to oscillating PC12 cells at times corresponding to midday and early and late night to evaluate whether the effects were similar as in SCN. Induction of Per1 mRNA was found at all three times, which differs from results in SCN. Thus, PC12 cells seem more useful for studying mechanisms behind acquirement of rhythmicity of cell cultures than for resetting of circadian rhythm.     

Temporal profile of circadian clock gene expression in a transplanted suprachiasmatic nucleus and peripheral tissues

The mammalian hypothalamic suprachiasmatic nucleus (SCN) is the master oscillator that regulates the circadian rhythms of the peripheral oscillators. Previous studies have demonstrated that the transplantation of embryonic SCN tissues into SCN-lesioned arrhythmic mice restores the behavioral circadian rhythms of these animals. In our present study, we examined the clock gene expression profiles in a transplanted SCN and peripheral tissues, and also analysed the circadian rhythm of the locomotor activity in SCN-grafted mice. These experiments were undertaken to elucidate whether the transplanted SCN generates a dynamic circadian oscillation and maintains the phase relationships that can be detected in intact mice. The grafted SCN indeed showed dynamic circadian expression rhythms of clock genes such as mPeriod1 (mPer1) and mPeriod2 (mPer2). Furthermore, the phase differences between the expression rhythms of these genes in the grafted SCN and the locomotor activity rhythms of the transplanted animals were found to be very similar to those in intact animals. Moreover, in the liver, kidney and skeletal muscles of the transplanted animals, the phase angles between the circadian rhythm of the grafted SCN and that of the peripheral tissues were maintained as in intact animals. However, in the SCN-grafted animals, the amplitudes of the mPer1 and mPer2 rhythms were attenuated in the peripheral tissues. Our current findings therefore indicate that a transplanted SCN has the capacity to generate a dynamic intrinsic circadian oscillation, and can also lock the normal phase angles among the SCN, locomotor activity and peripheral oscillators in a similar manner as in intact control animals.     

GFP fluorescence reports Period 1 circadian gene regulation in the mammalian biological clock

Endogenous cyclic activation of a specific set of genes, including Period 1 (Per1), drive circadian rhythms in the suprachiasmatic nucleus (SCN), a biological clock nucleus of the brain. We have produced transgenic mice in which a degradable form of recombinant jellyfish green fluorescent protein (GFP) is driven by the mouse Period 1 (mPer1) gene promoter. GFP protein is expressed in the circadian neural structures of the retina and SCN. Fluorescent signals are resolved at the level of individual neurons. mPer1-driven GFP fluorescence intensity reports light-induction and circadian rhythmicity in SCN neurons. This circadian reporter transgene captures the gene expression dynamics of living biological clock neurons and ensembles, providing a novel view of this brain function.     

Electrophysiological Effects of Melatonin on Mouse Per1 and non‐Per1 Suprachiasmatic Nuclei Neurones In Vitro

The master circadian pacemaker in the suprachiasmatic nuclei (SCN) regulates the nocturnal secretion of the pineal hormone melatonin. Melatonin, in turn, has feedback effects on SCN neuronal activity rhythms via high affinity G protein‐coupled receptors (MT₁ and MT₂). However, the precise effects of melatonin on the electrical properties of individual SCN neurones are unclear. In the present study, we investigated the acute effects of exogenous melatonin on SCN neurones using whole‐cell patch‐clamp recordings in brain slices prepared from Per1::d2EGFP‐expressing transgenic mice. In current‐clamp mode, bath applied melatonin, at near‐physiological concentrations (1 nm ), hyperpolarised the majority (63.7%) of SCN neurones tested at all times of the projected light/dark cycle. In addition, melatonin depolarised a small proportion of cells (11.0%). No differences were observed for the effects of melatonin between Per1::GFP or non‐Per1::GFP SCN neurones. Melatonin‐induced effects were blocked by the MT₁/MT₂ antagonist, luzindole (1 μm ) and the proportion of SCN neurones responsive to melatonin was greatly reduced in the presence of either tetrodotoxin (200 or 500 nm ) or gabazine (20 μm ). In voltage‐clamp recordings, 1 nm melatonin increased the frequency of GABA‐mediated currents. These findings indicate, for the first time, that exogenous melatonin can alter neuronal excitability in the majority of SCN neurones, regardless of whether or not they overtly express the core clock gene Per1. The results also suggest that melatonin acts mainly by modulating inhibitory GABAergic transmission within the SCN. This may explain why exogenous application of melatonin has heterogenous effects on individual SCN neurones.     

An essential role for peptidergic signalling in the control of circadian rhythms in the suprachiasmatic nuclei

Two structurally related neuropeptides, pituitary adenylate cyclase-activating polypeptide (PACAP), colocalized with glutamate in neurones of the retinohypothalamic tract, and vasoactive intestinal peptide (VIP), present in light-responsive cells of the suprachiasmatic nuclei (SCN), appear to play distinct and important roles in the control of mammalian circadian rhythms. Mice deficient in the PACAP-selective PAC1 receptor exhibit altered responsiveness of the SCN clock to light-induced phase-shifts, but display robust circadian patterns of wheel-running behaviour. By contrast, our studies of mice lacking the VPAC2 receptor, which responds to both PACAP and VIP, indicate that this receptor plays a critical role in rhythm generation in the SCN. The predominant factor determining wheel-running activity in VPAC2 receptor null (Vipr2-/-) mice is "masking" by light. Mutant animals re-entrain immediately to advances or delays in the light/dark cycle and do not exhibit robust circadian rhythms of behaviour when in constant darkness. The mice do not exhibit circadian expression of core clock genes (mPer1, mPer2, mCry1), or of the clock-controlled gene arginine vasopressin (AVP), in the SCN. We propose that VIP signalling between SCN neurones provides a paracrine reinforcing signal that is essential for sustained rhythm generation. The presence of VIP signalling in the SCN may explain why SCN neurones are capable of generating long-lasting self-sustained oscillations, whereas rhythmic clock gene expression in other tissues is dependent on periodic reinforcement by neural or hormonal signals.