The treatment of cultured rat-1 fibroblasts or H35 hepatoma cells with high concentrations of serum induces the circadian expression of various genes whose transcription also oscillates in living animals. Oscillating genes include rper1 and rper2 (rat homologs of the Drosophila clock gene period), and the genes encoding the transcription factors Rev-Erb alpha, DBP, and TEF. In rat-1 fibroblasts, up to three consecutive daily oscillations with an average period length of 22.5 hr could be recorded. The temporal sequence of the various mRNA accumulation cycles is the same in cultured cells and in vivo. The serum shock of rat-1 fibroblasts also results in a transient stimulation of c-fos and rper expression and thus mimics light-induced immediate-early gene expression in the suprachiasmatic nucleus.
In mammals, circadian oscillators reside not only in the suprachiasmatic nucleus of the brain, which harbors the central pacemaker, but also in most peripheral tissues. Here, we show that the glucocorticoid hormone analog dexamethasone induces circadian gene expression in cultured rat-1 fibroblasts and transiently changes the phase of circadian gene expression in liver, kidney, and heart. However, dexamethasone does not affect cyclic gene expression in neurons of the suprachiasmatic nucleus. This enabled us to establish an apparent phase-shift response curve specifically for peripheral clocks in intact animals. In contrast to the central clock, circadian oscillators in peripheral tissues appear to remain responsive to phase resetting throughout the day.
In mammals, all overt circadian rhythms are thought to be coordinated by a central pacemaker residing in the hypothalamic suprachiasmatic nucleus (SCN) [1]. The phase of this pacemaker is entrained by photic cues via the retino-hypothalamic tract. Circadian clocks probably rely on a feedback loop in the expression of certain clock genes (reviewed in [2,3]). Surprisingly, however, such molecular oscillators are not only operative in pacemaker cells, such as SCN neurons, but also in many peripheral tissues and even in cell lines kept in vitro [4-7]. For example, a serum shock can induce circadian gene expression in cultured Rat-1 fibroblasts [5]. This treatment also results in a rapid surge of expression of the clock genes Per1 and Per2, similar to that observed in the SCNs of animals receiving a light pulse [8-10]. Serum induction of Per1 and Per2 transcription does not require ongoing protein synthesis [5] and must therefore be accomplished by direct signaling pathways. Here, we show that cAMP, protein kinase C, glucocorticoid hormones and Ca2+ can all trigger a transient surge of Per1 transcription and elicit rhythmic gene expression in Rat-1 cells. We thus suspect that the SCN pacemaker may exploit multiple chemical cues to synchronize peripheral oscillators in vivo.
Pioneer transcription factors establish new cell-fate competence by triggering chromatin remodeling. However, many features of pioneer action, such as their kinetics and stability, remain poorly defined. Here, we show that Pax7, by opening a unique repertoire of enhancers, is necessary and sufficient for specification of one pituitary lineage. Pax7 binds its targeted enhancers rapidly, but chromatin remodeling and gene activation are slower. Enhancers opened by Pax7 show a loss of DNA methylation and acquire stable epigenetic memory, as evidenced by binding of nonpioneer factors after Pax7 withdrawal. This work shows that transient Pax7 expression is sufficient for stable specification of cell identity.
For many years, neurons of the suprachiasmatic nucleus (SCN) in the hypothalamus were thought to contain the unique mammalian clock controlling circadian rhythmicity of peripheral tissues via neural and humoral signals. Surprisingly, the cloning and characterisation of mammalian clock genes have revealed that they are expressed in a circadian manner throughout the body. It is generally accepted now that peripheral cells contain a circadian clock which is similar to the one present in SCN neurons, although only the latter seems to be self-sustained. It is still unclear how these peripheral clocks are synchronised by the central SCN clock, albeit humoral signals appear to be crucial. Interestingly, peripheral clocks can be uncoupled from the central clock in particular conditions such as restricted-feeding, allowing peripheral tissues to adapt themselves to cues incompatible to other cues perceived by the SCN (mainly the photoperiod). Whereas circadian clocks have been intensively dissected, little is known about the mechanisms by which these clocks regulate the expression of clock-controlled genes. Direct regulation for some of them by the products of clock genes was recently documented, but this probably represents the exception rather than the rule. We should soon be able to describe complete circadian transcriptional cascades from clock genes to enzymes and structural proteins. In addition to circadian humoral and neural signals, these cascades should help us to understand how gene expression, physiology and behaviour are influenced by the rotation of the Earth around its axis.
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