Rhythmic expression of Fos-related proteins within the rat suprachiasmatic nucleus during constant retinal illumination

Real-time analysis of rhythmic gene expression in immortalized suprachiasmatic nucleus cells

Immortalized cells derived from the suprachiasmatic nucleus (SCN) retain many properties of the SCN including the capacity to generate circadian rhythms. Stably transfected SCN2.2 cells expressing the human c- promoter linked to a luciferase reporter gene ( /luc) were examined for evidence of transgene responses to stimuli known to induce c- expression and of endogenous rhythmic variation. Bioluminescence-reported transgene expression was induced in SCN2.2 /luc cells following stimulation with fetal bovine serum or KCl. SCN2.2 /luc cells showed 24 h rhythms of bioluminescence with a 9- to 19-fold difference between peak and minimum levels. These results demonstrate that the regulation of /luc transgene expression in SCN2.2 cells is similar to that of the endogenous c- gene in the SCN.

Is light-regulated AP-1 binding in the rat suprachiasmatic nucleus gated by the circadian clock?

In mammals, photic entrainment of circadian rhythms likely involves light- and clock-dependent expression of immediate early genes, including fos-like and jun-like genes, in the rat suprachiasmatic nucleus. Using an electrophoretic mobility shift assay, we evaluated whether the photic regulation of DNA-binding activity and composition of activating protein-1 (AP-1) complexes in the suprachiasmatic nucleus is also dependent on circadian phase. Phase-dependent light inducibility in the expression of fra-2 and c-fos genes and in immunoreactive Fra-2 and c-Fos protein expression was also evaluated, by in situ hybridization and immunocytochemistry. Light's effects on AP-1 DNA-binding differed both qualitatively and quantitatively according to the circadian phase at which light was applied. This phase dependence accounted for by both compartmentalization of proteins involved in constitutive AP-1 complexes within the nucleus or cytoplasm and control of the extent to which the expression of specific complexes was induced. It was then shown that the mechanisms by which the circadian clock gates the photic induction of AP-1 components differed according to the nature of the protein.

The physical imperative in circadian rhythm: a cytoskeleton-related physically resettable clock mechanism hypothesis

Organisms maintaining circadian rhythmicity are responding to physical constraint of a 24-hour cycle. Time-cue sensing is fundamental to the clock existence, and entrainment of circadian rhythm is indeed accessible to a wide variety of geophysical stimuli. Light-dark and temperature changes are the main time-cues. Additional physical forces such as barometric pressure, electrostatic and electromagnetic fields and gravity force, display a daily cyclic behavior and can function as secondary time-cues. A conceptual framework that contains explanations to all circadian properties including cell autonomous, environmental responsiveness and self-sustained character, is still lacking. It is argued that clock responsiveness to external cues is central to the cellular clock mechanism, and therefore, the nature of the time-cues and the pathways that enable the cell to respond to physical stimuli are of central importance. A role for cytoskeleton in clock entrainment mechanism is suggested in light of cytoskeleton's major involvement in cellular mechanotransduction.

The expression of Fos within the suprachiasmatic nucleus of the diurnal rodent Arvicanthis niloticus

Rhythms in the expression of the nuclear phosphoprotein Fos, have been demonstrated in the suprachiasmatic nucleus (SCN) of nocturnal rodents. When rats are housed in a 12:12-h light/dark (LD) cycle the number of Fos-immunoreactive (-IR) cells within the SCN is higher during the day than at night [9,23]. In the two experiments reported here, Fos-IR was examined in the SCN of a diurnal murid rodent, Arvicanthis niloticus. First, thirty-six adult male A. niloticus housed in a 12:12-h LD cycle were perfused at six equally spaced time points beginning 1 h after lights on (n=6 per time point). Brains were sectioned and treated with immunohistochemical procedures for the identification of Fos. The number of Fos-IR cells in the SCN varied significantly as a function of time, and was highest 1 h after lights on and decreased thereafter. The distribution of Fos-IR within the SCN overlapped with that of arginine-vasopressin-IR (AVP-IR) and vasoactive intestinal peptide-IR (VIP-IR), but not with that of gastrin-releasing peptide-IR (GRP-IR). In the second study, double-labeling techniques revealed extensive Fos expression within SCN neurons containing AVP-IR, but not neurons containing GRP-IR. In conclusion, although the overall rhythm of Fos-IR in the SCN is similar in diurnal and nocturnal rodents, differences may exist with respect to the relative distribution of Fos-immunoreacte cells within different SCN cell populations.

Long-term monitoring of circadian rhythms in c-fos gene expression from suprachiasmatic nucleus cultures

BACKGROUND

The AP-1 family of transcription factors has been implicated in the control of the expression of many genes in response to environmental signals. Previous studies have provided temporal profiles for c-fos expression by taking measurements from many animals at several points in time, but these studies provide limited information about dynamic changes in expression. Here, we have devised a method of continuously measuring c-fos expression.

RESULTS

A transgenic mouse line expressing the human c-fos promoter linked to the firefly luciferase reporter gene (fos/luc) was generated to continuously monitor c-fos gene expression. A second transgenic mouse line expressing luciferase under the control of the cytomegalovirus promoter (CMV/luc) served as a control. Luminescence originating from identifiable brain regions was imaged from fos/luc brain slice cultures. Expression of the fos/luc transgene accurately reflected transcriptional responses of the endogenous c-fos gene. Dynamic changes in fos/luc expression in suprachiasmatic nuclei (SCN) explant cultures were monitored continuously, and luminescence showed almost 24 hour rhythms lasting up to five circadian cycles. In contrast, bioluminescence monitored from CMV/luc SCN explant cultures was not rhythmic.

CONCLUSION

The fos/luc transgenic mouse will be useful for long-term, non-invasive monitoring of c-fos transcriptional responses to the changing cellular environment. Circadian rhythms in c-fos expression can be monitored non-invasively in real time from the SCN, clearly demonstrating that c-fos transcription is regulated by the circadian clock.

Differences in colocalization between Fos and PHI, GRP, VIP and VP in neurons of the rat suprachiasmatic nucleus after a light stimulus during the phase delay versus the phase advance period of the night

Two groups of four rats each received a 15-minute light stimulus during the first part of the night (ZT14) and the second part (ZT19), respectively. After 45-60 minutes, the animals were killed by perfusion fixation. Adjacent Vibratome sections through the suprachiasmatic nucleus (SCN) were double-immunostained for the presence of peptide histidine isoleucine (PHI), gastrin releasing peptide (GRP) or vasoactive intestinal peptide (VIP) with Fos by using fluorophore-conjugated secondary antibodies. A few sections were triple-immunostained for PHI, GRP or VIP with vasopressin (VP) and Fos. Sections were analyzed with a confocal laser scanning microscope. It turned out that the ZT19 light stimulus induced 4.2 times more nuclear profiles in the SCN immunoreactive for Fos than the light stimulus given at ZT14. The SCN of control animals did not show any Fos immunoreactivity. After the ZT14 light stimulus, approximately 33% of the Fos profiles showed colocalization with a perikaryal profile immunoreactive for PHI, GRP or VIP, whereas at ZT19, this percentage had doubled to approximately 65%. After the light stimulus at ZT14, the relatively low Fos induction was numerically and proportionally most prominent in the PHI-immunoreactive perikarya. As compared with ZT14, the increase of Fos after the ZT19 light stimulus was most pronounced in the GRP-immunoreactive perikarya (21x) followed by VIP (15x) and PHI (5x). This outcome suggests that at least three different cell groups characterized by, respectively, PHI alone, GRP, and VIP fully or partly colocalized with PHI, play a prominent role during light-induced phase shifts: the PHI neurons during light-induced phase delays, the GRP and VIP/(PHI) neurons during light-induced phase advances.

Light, immediate-early genes, and circadian rhythms

Many diverse behaviors exhibit clear circadian rhythms in their expression. In mammals, these rhythms originate from a neural circadian clock located in the suprachiasmatic nuclei (SCN). Recently, signaling pathways activated by light in the SCN have begun to be identified. A specific set of immediate-early genes is induced by light in the SCN, and their expression is correlated with the resetting of circadian behavioral rhythms. These light-regulated immediate-early genes offer multiple inroads into the biology of the SCN: first, they are functional markers for the activation of SCN neurons by light; second, they can direct us to the upstream light-activated (and clock-regulated) signal transduction pathways which mediate their induction; and finally, they encode transcription factor proteins which may play a role in the molecular mechanism of resetting the circadian clock.

Fos expression in rat visual cortex induced by ocular input of ultraviolet light

We used immunostaining for the cellular transcription factor Fos to assess patterns of neuronal activation in rat visual cortex during exposure to ultraviolet light. Exposure to monochromatic ultraviolet light (lambda max 360 nm: half-bandwidth 8.8 nm, 10 microW/cm2 at eye level) induced strong expression of Fos immunoreactivity in the primary visual cortex and associated cortical visual areas of dark-adapted rats. The stimulatory effect of ultraviolet light on Fos expression was related to exposure duration, was independent of stimulus novelty or phase of the circadian cycle in which exposure occurred, and it was mediated by a mechanism located in the eye. These results demonstrate that ocular input of ultraviolet light is capable of altering neuronal activity in cortical structures involved in visual processing and are consistent with the hypothesis that rodents may use ultraviolet light for vision.

Photic regulation of c-fos gene expression in the suprachiasmatic nucleus and the circadian rhythm of photosensitivity in the mink

The relationship between the photic stimulation of the c-fos gene product in cells of the suprachiasmatic nuclei and the photoperiodic control of testicular activity were examined in mink. Mink were kept in a short photoperiod (control, LD4:20), or in 'asymmetric skeleton photoperiods' (groups A and B). The light period for groups A and B was divided into two fractions (3 h 30 min and 30 min); the shorter fraction occurred in the night, 4 h (group A) or 8 h (group B) after the end of the main light period. There was no photic activation of the proto-oncogene c-fos on the control or group A, and 4 weeks on this photoperiodic treatment produced marked testicular development. In contrast, in group B, c-fos mRNA was induced 30 min after the end of the secondary photofraction, was maximal 30 min later and then decreased. Fos-like immunoreactivity was detected 2 h after the end of the secondary photofraction, with activity peaking 1 h later. The animals of this group remained sexually quiescent. These results suggest that photo-induction of the proto-oncogene c-fos is implicated in the gonadal inhibition induced in this species when the light period, extends into the photosensitive phase of the circadian rhythm of photosensitivity.

Molecular biological approach to the circadian clock mechanism

Many circadian phenomena have been described in a diverse range of species, from single cellular organisms to higher species of plants and animals. From several lines of evidence from Drosophila and Neurospora, the oscillation of the circadian clock seems to involve cycling gene expression. Although a great deal of information concerning the anatomy, neurophysiology and neurochemistry of circadian pacemakers has been obtained over the last decade, molecular and cellular approaches to this problem have only just begun. I will summarize recent progress of the molecular biological approach to the circadian clock mechanism. Finally, the importance of transcription factors to envision the common mechanism of circadian clock in the diverged species will be discussed considering with the existence of a hypothetical 'Time Box'.

Gene expression in suprachiasmatic nucleus and circadian rhythms

The suprachiasmatic nuclei (SCN) contain a circadian system consisting of circadian oscillator (clock) that is normally synchronized by the light/dark cycle (input) and drives circadian rhythms (output) that are intrinsic to the SCN. Gene expression of immediate-early genes, such as c-fos and jun-B, in the ventrolateral SCN is associated with circadian synchronization by light pulses and subjected to circadian control. Vasopressin and somatostatin gene expression shown distinct circadian rhythms intrinsic to the dorsomedial SCN with higher peptide levels occurring during the day. In addition, embryonic SCN grafted into the brain of an SCN-lesioned arrhythmic host define the period of the restored circadian locomotor rhythm. Taken together, these and other findings support the notion that the expression of genes underlying circadian synchronization, oscillation and output takes place within individual SCN neurons. However, no information regarding the nature and number of those neurons as well as the molecular mechanisms of the single cell-circadian oscillator and output is currently available. Therefore, we propose a simple two-neuron model as a framework for critically discussing the molecular genetic strategies to analyze the circadian system in SCN.

An immunohistochemical study of the c-fos protooncogene in the developing human retina

The localization and distribution of the protooncogene c-fos were studied immunohistochemically in the retina of human fetuses ranging in age from 15 to 40 weeks of gestation. The highest levels of immunoreactivity were observed in the retinae of younger fetuses, decreasing in intensity with increasing age. At 15 weeks of gestation intense immunoreactivity was observed in the inner nuclear layer while the photoreceptor cells exhibited moderate staining. At 26 weeks of gestation, immunoreactivity in the inner nuclear layer was reduced. The ganglion cells, amacrine cells and photoreceptor cells showed moderate immunopositivity throughout the 26-40 weeks period. The role of c-fos in development is discussed in the light of its other known functions.

Impact of light pulses on 6-sulphatoxymelatonin rhythms in rats

The acute and residual entraining effects of a 15 min pulse of light on rat pineal function in individual animals were investigated using the excretion rate of the melatonin metabolite, 6-sulphatoxymelatonin, as an index of melatonin production. In animals maintained in a 12-hr L:12-hr D photoperiod (lights off 1800), 15 min light exposure at 2000 had no significant effect on the metabolite rhythm. Light pulses at 2200 (i.e., after the onset of excretion) decreased the melatonin metabolite excretion rate for 3 hr, after which the excretion rate increased to normal. In contrast, pulses at 2400 and 0200 suppressed 6-sulphatoxymelatonin for the rest of the night such that total excretion was 58 +/- 8% and 66 +/- 6% of the amount excreted on the night before the pulse. A light pulse at 0400 had no significant effect on the 6-sulphatoxymelatonin excretion when compared with the first night collection. When the 6-sulphatoxymelatonin rhythm was assessed on the night following light pulses at 2000 and 0400, the onset of metabolite excretion was unaffected (0.2 +/- 0.75-hr advance and 0.75 +/- 0.15-hr delay, respectively). In contrast, pulses at 2200, 2400, and 0200 resulted in significant delays in the onset of 2.4 +/- 0.2-hr, 1.5 +/- 0.1-hr, and 2.1 +/- 0.3-hr, respectively (P < 0.05). The offset of metabolite excretion was not significantly affected by a prior light pulse, except in animals receiving light treatment at 0400 when the offset was advanced by 1.5 +/- 0.3 hr.(ABSTRACT TRUNCATED AT 250 WORDS)

Temporal regulation of light-induced Fos and Fos-like protein expression in the ventrolateral subdivision of the rat suprachiasmatic nucleus

We measured c-fos messenger RNA levels and Fos protein immunoreactivity in the suprachiasmatic nucleus of rats as a function of light and time of day. Immunohistochemistry demonstrated a daily rhythm of immunoreactive Fos in the ventrolateral subdivision of the suprachiasmatic nucleus of animals entrained to a 12 h/12 h light-dark cycle; expression was low during the dark phase, peaked about 2 h after light onset at dawn, and remained elevated at an intermediate level for the remainder of the light phase. Immunoblots of nuclear extracts showed a 54,000 mol. wt band that increased in density from the dark phase to the early light phase and decreased again during the late light phase. In situ hybridization using a radiolabeled cDNA probe revealed a c-fos messenger RNA signal that was detected as early as 15 min after dawn, prominent at 30 min, and absent by 2 h. The expression of c-fos messenger RNA and Fos immunoreactivity in the suprachiasmatic nucleus depended on the presence of ambient light. In rats entrained to two daily 1-h light pulses corresponding to dawn and dusk ("skeleton" photoperiod) instead of the complete light-dark cycle, immunoreactive Fos was elicited by the dawn pulse alone and was less persistent than during the complete photoperiod. In rats free-running in constant darkness, c-fos messenger RNA and Fos immunoreactivity were stimulated by 2-h light pulses administered only during the subjective night and early subjective day, but not by light pulses during the middle or late subjective day or in the absence of light pulses.

The circadian visual system

The retina transduces photic stimuli and transmits that information centrally for further processing. This review emphasizes the fact that the nervous system components governing circadian rhythmicity constitute a specialized subdivision of the vertebrate visual system. The brain houses different targets for retinal efferents parcellated according circadian or non-circadian function. Although the suprachiasmatic nucleus (SCN), being the site of the master circadian clock, is necessary for the generation of circadian rhythmicity, precise phase regulation of any rhythm is subject to modulation by SCN-afferent processes. Photic information necessary for entrainment arrives at the SCN via the retinohypothalamic tract. The geniculohypothalamic tract, originating in the intergeniculate leaflet (IGL), provides a secondary route by which photic information can reach the SCN. It also projects extensively to the contralateral IGL and receives reciprocal input from the SCN region. An interaction between the circadian and non-circadian visual systems may exist through connections of the superior colliculus with ventrolateral geniculate leaflet (VLG) and IGL. The SCN, IGL, VLG and superior colliculus are all innervated by serotonin-containing fibers. The following observations are likely to have an impact beyond the rhythm field itself: certain transneuronal tracers label only the circadian visual system; c-fos protein synthesis is induced in the circadian, but not non-circadian, visual system by a phasically active stimulus; blockade of SCN action potentials is unable to alter circadian rhythmicity; transplantation of dispersed fetal SCN cells to arrhythmic adults restores circadian periodicity, but not phase response to light; and the IGL is actually a very extensive part of the lateral geniculate complex.

Fos protein expression in the circadian clock is not associated with phase shifts induced by a nonphotic stimulus, triazolam

Recent studies have shown that light-induced phase shifts of the circadian rhythm of locomotor activity are associated with c-fos expression in the suprachiasmatic nucleus (SCN) and intergeniculate leaflet (IGL) of the lateral geniculate nucleus of rodents. In order to determine whether c-fos expression is necessary for the phase shifting effects of a non-photic stimulus, we assessed Fos-like immunoreactivity (Fos-lir) in the SCN and IGL at various times after an injection of the short-acting benzodiazepine, triazolam, at circadian time (CT) 6; i.e. at a time when triazolam induces an acute increase in locomotor activity and maximal phase advances in the circadian rhythm of locomotor activity. Specific Fos-lir staining was not observed in the SCN or IGL regions of any animals treated with triazolam or vehicle at any time point examined. These results indicate that exposure to an activity-inducing stimulus at circadian times when this stimulus induces phase shifts does not induce Fos protein synthesis in the SCN or IGL regions.

Circadian rhythms

The neurobiological substratum of circadian rhythmicity encompasses three levels of integration: firstly, generation of time signals by circadian pacemakers; secondly, entrainment of pacemakers by environmental influences; thirdly, coupling of circadian pacemakers among themselves and with target systems responsible for the expression of overt rhythms. From recent contributions, the notion that circadian organization results from the interaction of independent oscillators and pathways has been strengthened. In addition, recent evidence supports the existence of circadian rhythmicity in single isolated neurons. New information was produced on the gene control of circadian rhythm generation in Drosophila, as well as interesting advances in the understanding of neuronal mechanisms involved in the generation, entrainment and coupling of circadian rhythms in various species.

Photic induction and circadian expression of Fos-like protein. Immunohistochemical study in the retina and suprachiasmatic nuclei of hamster

Fos-immunohistochemistry was performed in the retina and at four rostro-caudal levels of the suprachiasmatic nuclei (SCN) in hamsters. Animals were sacrificed at four circadian times (CT) relative to activity onset (CT12): CT07, 11, 14, 19 either in permanent darkness (DD) or 1 h after light stimulation. Quantification of immunoreactive nuclei showed (i) endogenous CT related changes exclusively within the rostral SCN with maximum immunoreactivity at CT07, (ii) CT related responses to light in retinal displaced amacrines, ganglion cells and caudal SCN (maximum at CT19), (iii) expression differences in four subsets of SCN cells according to CT. The rostral subset could be implicated in the endogenous clock mechanism since it exhibited a fluctuation of Fos immunoreactivity in DD and expression of Fos protein at CTs 06 and 18 when light provokes transients in the free-running period. In the caudal SCN, a ventro-laterally localized set responded to light at CTs 13 and 18, a dorsal crescent of cells responded only at CT18 and a group located laterally between these two responded at CT18. These cellular subsets may have different functions in the light-entrainment mechanism since light stimuli at CT13 induced phase-delays and, at CT18, phase-advances in the onset of the free-running locomotor activity rhythm.

Circadian-clock regulation of gene expression

During the past year, our understanding of the cellular and molecular processes involved in the generation and control of circadian rhythms has advanced significantly. Progress has been made at the level of the circadian pacemaker mechanism itself, the input pathways that regulate the pacemaker, and the mechanisms by which the pacemaker regulates its various outputs. A common theme underlying all three of these processes is the involvement of transcriptional and translational control. This review is an updated and extended version of a review first published in Current Opinion in Neurobiology 1991, 1:556-561.