Gene expression in the suprachiasmatic nuclei and the photoperiodic time integration.

In mammals, the 24 h-rhythmicity of many physiological events is driven by the circadian clock contained in the suprachiasmatic nuclei (SCN). In the SCN, clock gene expressions produce the rhythmicity and control the expression of clock-controlled genes which play a role in the distribution of daily messages. The daily expression of all these genes is modulated by the duration of the light phase (i.e. photoperiod). The aim of this study was first to determine if these daily changes of expression reflect a real integration of a new photoperiod by the circadian clock or reflect only a passive effect of the light. In this way, we performed a time course of the modifications of gene expression after a transfer of Syrian hamsters from long to short photoperiod (LP and SP). Our results demonstrate that the core of the SCN (clock genes) integrates quickly a new photoperiod which entrains a slow adaptation of the clock-controlled gene expressions and induces a differential daily functioning of an SCN-target tissue, the pineal gland. We next asked the question whether SCN are involved in the photorefractory phase observed in Syrian hamsters exposed to SP for 26 weeks. All genes analyzed present a similar daily expression in SP-refractory and in SP with the exception of Clock. Its particular expression in SP-refractory is different than ones observed in SP or in LP. Thus, Clock seems to play a role in the development of the photorefractory phase, or this physiological state may modify the expression of Clock in the SCN. As a conclusion, it appears that the photoperiodic time measurement involves daily modifications of the molecular functioning of the SCN and that SCN also play a role in the measurement of the duration of the time passed in a short photoperiod.

Expression of Tgfalpha in the suprachiasmatic nuclei of nocturnal and diurnal rodents.

Transforming growth factor alpha (TGFalpha) in the suprachiasmatic nuclei (SCN) has been proposed as an inhibitory signal involved in the control of daily locomotor activity. This assumption is based mainly on studies performed in nocturnal hamsters. To test whether the transcriptional regulation of Tgfalpha can be correlated with the timing of overt activity in other species, we compared Tgfalpha expression in the SCN of nocturnal Swiss mice and of diurnal Arvicanthis housed under a light/dark cycle (LD) or transferred to constant darkness (DD). In agreement with data on hamsters, Tgfalpha mRNA levels in the mouse SCN showed peak and trough levels around (subjective) dawn and dusk, respectively, roughly corresponding to the period of rest and activity in this species. In contrast, in Arvicanthis housed in DD, the circadian rhythm of SCN Tgfalpha was similar to that of the mice in spite of opposite phasing of locomotor activity. Furthermore, in Arvicanthis exposed to LD, Tgfalpha mRNA levels were constitutively high throughout the day. A tonic role of light in the regulation of Tgfalpha in Arvicanthis was confirmed by an increased expression of Tgfalpha in response to a 6-h exposure to light during daytime in animals otherwise kept in DD. In conclusion, this study shows that, contrary to what is observed in mice, Tgfalpha mRNA levels in the SCN of Arvicanthis do not match timing of locomotor activity and are modulated by light.

Calbindin expression in the hamster suprachiasmatic nucleus depends on day-length.

The mammalian circadian clock located in the suprachiasmatic nucleus (SCN) of the hypothalamus controls many physiological and behavioral rhythms. The SCN is compartmentalized in two functionally distinct subregions: a dorsomedial subregion that rhythmically expresses clock genes, and a ventrolateral subregion which, in contrast, mainly expresses clock genes at a constant level. In the golden hamster, this ventrolateral part of the SCN contains a subpopulation of neurons expressing calbindin D28k. This subpopulation has recently been implicated in the control of locomotor rhythmicity. Because both the pattern and level of locomotor activity are affected by day-length, we investigated whether photoperiod also affects calbindin expression. We show that calbindin expression is negatively correlated to the day-length. The number of calbindin immunopositive neurons and calbindin mRNA levels were markedly increased in hamsters exposed to short photoperiods (light/dark cycle [LD] 6:18 and LD10:14) when compared with hamster exposed to long photoperiods (LD18:6 and LD14:10). This suggests that calbindin neurons are involved in the encoding of seasonal information by the SCN.

Photoperiod differentially regulates clock genes' expression in the suprachiasmatic nucleus of Syrian hamster.

The suprachiasmatic nuclei (SCN) contain the master circadian pacemaker in mammals. Generation and maintenance of circadian oscillations involve clock genes which interact to form transcriptional/translational loops and constitute the molecular basis of the clock. There is some evidence that the SCN clock can integrate variations in day length, i.e. photoperiod. However, the effects of photoperiod on clock-gene expression remain largely unknown. We here report the expression pattern of Period (Per) 1, Per2, Per3, Cryptochrome (Cry) 1, Cry2, Bmal1 and Clock genes in the SCN of Syrian hamsters when kept under long (LP) and short (SP) photoperiods. Our data show that photoperiod differentially affects the expression of all clock genes studied. Among the components of the negative limb of the feedback loop, Per1, Per2, Per3, Cry2 but not Cry1 genes show a shortened duration of their peak expression under SP compared with LP. Moreover, mRNA expression of Per1, Per3 and Cry1 are phase advanced in SP compared with LP. Per3 shows an mRNA peak of higher amplitude under SP conditions whereas Per1 and Per2 peak amplitudes are unaffected by photoperiod changes. Bmal1 expression is phase advanced without a change of duration in SP compared with LP. Furthermore, the expression of Clock is rhythmic under SP whereas no rhythm is observed under LP. These results, which provide further evidence that the core clock mechanisms of the SCN integrate photoperiod, are discussed in the context of the existing molecular model.

Intergeniculate leaflets lesion delays but does not prevent the integration of photoperiodic change by the suprachiasmatic nuclei.

The duration of the photosensitive phase of the suprachiasmatic nuclei (SCN), as revealed by light-induced Fos protein expression, depends on the photoperiod and is tied to the length of the night. We show here in Syrian hamsters that after a transfer from long to short photoperiod, lengthening of the photosensitive phase of the SCN is significantly delayed but not abolished when the intergeniculate leaflets (IGL) are lesioned. Thus IGL modulate the integration by the SCN of a photoperiodic change.

Does the intergeniculate leaflet play a role in the integration of the photoperiod by the suprachiasmatic nucleus?

The circadian clock located in the suprachiasmatic nuclei (SCN) is influenced by the photoperiod. After the transfer from a long (LP 14:10) to a short photoperiod (SP 10:14), the adjustment of the light sensitivity of the SCN, in terms of Fos expression, takes 25 nights. To examine the contribution of the thalamic intergeniculate leaflet (IGL) and its NPY-immunoreactive projection in the extension of the duration of the photosensitive phase of the SCN, male Syrian hamsters received electrolytic lesions of the IGL. We showed a lower number of Fos-ir cells in the SCN of IGLx hamsters following a light pulse applied 13 h after dark onset, 25 nights after the transfer from LP to SP compared to sham operated hamsters. The present study shows that the integrity of the IGL is necessary to have a complete integration of photoperiodic changes by the SCN. This demonstrates the involvement of the IGL in the integration of photoperiodic information by the SCN.

Photoperiodic dependent changes in the number of neurons containing mRNA encoding neuropeptide Y in the intergeniculate leaflet of the Syrian hamster.

The intergeniculate leaflet (IGL) is a distinct division of the lateral geniculate complex that participates in the regulation of the circadian rhythm through its projections to the circadian pacemaker located in the suprachiasmatic nuclei of the hypothalamus. A high number of neuropeptide Y (NPY) cell bodies has been described in the IGL by immunohistochemistry and in situ hybridization. The present study investigated whether NPY in the IGL is influenced by the length of the daily photoperiod. By using in situ hybridization we show a significant increase of the number of NPY mRNA containing neurons in the mid-part of the IGL of Syrian hamsters maintained in a short photoperiod compared to those kept in a long photoperiod. On the other hand, NPY mRNA expression per cell in the IGL is similar in both photoperiods tested.

Effect of NMDA receptor antagonist MK-801 on light-induced Fos expression in the suprachiasmatic nuclei and on melatonin production in the Syrian hamster.

In mammals, circadian rhythms generated by the suprachiasmatic nuclei (SCN) are daily synchronized by a light-dark cycle. Photic information is transmitted to the SCN mainly through the direct retinohypothalamic tract, the neurotransmitters involved being excitatory amino acids. It is also commonly accepted that photoperiodic information coming from the retina via the SCN is transduced by the pineal into a nocturnal signal, i.e. melatonin production. Light exposure at night induces (1) an inhibition of melatonin synthesis and (2) an expression of c-fos in numerous cells of SCN. To determine the role of the NMDA receptor in these effects, we treated Syrian hamsters with ip injections of MK-801, a noncompetitive NMDA receptor antagonist. Several subpopulations of light-sensitive cells in the SCN are affected by MK-801. According to previous studies, MK-801 inhibits light-induced Fos immunoreactivity mainly in the most ventral part of the SCN. However, we observed that numerous other cells are still activated by light. When light is applied in the middle of the night, MK-801 pretreatment does not reduce Fos-ir in the dorsal SCN. At the beginning of the night, labeled cells in this part of the nucleus appear even more numerous after MK-801. We also found that MK-801 fails to reduce the light-induced inhibition of melatonin synthesis. Moreover, in control animals, which received no light stimulation, ip injection of MK-801 induces by itself a dose-dependent inhibition of melatonin production.

Photoperiod does not act on the suprachiasmatic nucleus photosensitive phase through the endogenous melatonin, in the Syrian hamster.

The duration of the sensitive phase to light of the suprachiasmatic nuclei, in terms of Fos protein expression, depends on the photoperiod. In Syrian hamsters, a 4 h lengthening of the photosensitive phase occurs within 3-4 weeks after a transfer from a long to a short photoperiod. The absence of endogenous melatonin following pinealectomy does not prevent the lengthening of the photosensitive phase. Thus, even if the pineal production is able to convey photoperiodic information, it does not feed back on the circadian clock to allow its integration.

Secretoneurin: a new neuropeptide in the rodent pineal gland.

The pineal gland of mammals is richly innervated by nerve fibres containing various peptides of central or sympathetic origin. In this study, we have investigated the presence, regulation and effect of secretoneurin (SN), a 33-amino-acid peptide discovered recently in the central and sympathetic nervous systems. The rat pineal gland contains about 34 fmol SN/pineal, although only 20% of the secretoneurin immunoreactivity (SN-IR) is the free peptide. SN-IR is localised in only a few nerve fibres found in the parenchyma of the gland and along the pineal stalk. In the rat pineal, SN-IR shows no midday/midnight differences but is significantly decreased (55%-65%) after superior cervical ganglionectomy or exposure to constant light. These observations suggest that, in the rat pineal, SN-IR originates partly from central areas and partly from the superior cervical ganglia. The pineal of the Syrian hamster contains much more SN-IR: 120 fmol SN-IR/pineal (about 20% being the free peptide). SN-IR is found both in nerve fibres and pineal cells. Some of the fibres run along the pineal stalk, indicating that they are of central origin, although a sympathetic origin cannot be ruled out. Pineal SN-IR is below detectable levels in the Siberian hamster. In cultured rat pinealocytes, SN significantly inhibits serotonin release and, to a lower extent, melatonin release.

How do the suprachiasmatic nuclei of the hypothalamus integrate photoperiodic information?

The suprachiasmatic nucleus of the hypothalamus (SCN) plays an essential role in the generation and maintenance of circadian rhythms in mammals. The SCN activity is also dependent upon the photoperiod. The duration of the SCN sensitive phase to light, in term of Fos induction, is variable and tied to the length of the night. The question is how and by which pathways can photoperiod influence SCN? It is possible following the theoretical model of evening and morning component of the clock that the SCN build itself the photoperiodic signal. That the SCN integrate the photoperiodic information through indirect neural or neuroendocrine pathways is also to consider. Data in favor of these different interpretations are presented.

Fos-like immunoreactivity in the circadian timing system of calorie-restricted rats fed at dawn: daily rhythms and light pulse-induced changes.

Daily rhythms of pineal melatonin, body temperature, and locomotor activity are synchronized to the light-dark cycle (LD) via a circadian clock located in the suprachiasmatic nuclei (SCN). A timed caloric restriction in rats fed at dawn induces phase-advances and further phase-stabilization of these rhythms, suggesting that the circadian clock can integrate conflicting daily photic and non-photic cues. The present study investigated the daily expression of Fos-like immunoreactivity (Fos-ir) and light pulse-induced Fos-ir in the SCN, the intergeniculate leaflet (IGL) and the paraventricular thalamic nucleus (PVT) in calorie-restricted rats fed 2 h after the onset of light and in controls fed ad libitum. A daily rhythm of Fos-ir in the SCN was confirmed in control rats, with a peak approximately 2 h after lights on. At this time point (i.e. just prior to the feeding time), the level of SCN Fos-ir was lowered in calorie-restricted rats. Concomitantly, IGL Fos-ir was higher in calorie-restricted vs. control rats. In response to a light pulse during darkness, Fos-ir induction was found to be specifically (i.e. phase-dependently) lowered in the SCN and IGL of calorie-restricted rats. Observed changes of Fos-ir in the PVT were possibly related to the wake state of the animals. This study shows that repetitive non-photic cues presented in addition to a LD cycle affect the Fos expression in the circadian timing system.

In Syrian and European hamsters, the duration of sensitive phase to light of the suprachiasmatic nuclei depends on the photoperiod.

Light induction of the expression of Fos protein in the suprachiasmatic nuclei was used to investigate the photosensitive state of the clock in Syrian and European hamster kept under different photoperiods. We observed that the duration of the photosensitive phase is variable and tied to the length of the night. A maximal extension has been determined in both species studied. Finally, a 4 h lengthening of the phase of photosensitivity take approximately 3 weeks, while 3 days only are needed for its shortening.

Time course of neuronal sensitivity to light in the circadian timing system of the golden hamster.

The mammalian suprachiasmatic nuclei of the hypothalamus (SCN) have been identified as containing the pacemaker for circadian rhythms. Photic stimulation is known to induce the expression of the immediate early gene c-fos in the SCN of rodents during the subjective night. In order to determine the exact time course of the light sensitivity in the different cell subgroups of the SCN, we have investigated the effect of a light pulse every hour of the subjective night in golden hamsters kept in constant darkness for 3 days. Three neuronal populations inside and outside the SCN have been identified as sensitive to light at different times of the subjective night. These findings indicate (1) that there are neurons outside the SCN that are activated by light which might be part of the pacemaker system, and (2) that the switch from light-induced phase delays to phase advances as illustrated by phase-response curves is linked to the appearance of sensitivity to light in the three cell populations defined here.

Photic induction of Fos immunoreactivity in the suprachiasmatic nuclei of the blind mole rat (Spalax ehrenbergi).

Exposure to light during the dark phase entrains c-fos expression in cells of the suprachiasmatic nuclei in the blind mole rat (Spalax ehrenbergi). Labeled cells are mainly located in the ventral region of the nucleus where retinal afferents terminate. Despite severe atrophy of the eye and regression of thalamic and tectal structures, the retinal pathways and central mechanisms involved in photoperiodic perception and circadian regulation appear to be similar to those in other rodents.

Differentiation of the melanotrophic cells of rat pituitary primordium in organotypic culture in defined medium.

Organotypic cultures, in defined medium, of pituitary primordia obtained from 15-day-old rat fetuses were performed in order to study the in vitro differentiation of melanotrophic cells. The morphological and ultrastructural features of the transplants resembled those of the gland developing in vivo. In situ hybridization on semi-thin sections, using a 35S-labelled oligonucleotide probe, revealed pro-opiomelanocortin-mRNA-containing cells on the first day of culture in the anterior lobe and after 2-3 days in the intermediate lobe. Immunoperoxidase labelling of adjacent sections showed that the same cells reacted with antibodies against alpha-melanocyte-stimulating hormone (alpha MSH), gamma 3MSH and adrenocorticotropic hormone in both lobes. The pro-opiomelanocortin-mRNA-containing cells formed progressively conspicuous areas in the intermediate lobe, which was almost uniformly labelled after 6 days. In the anterior lobe, these cells remained scattered in small cell groups, and colloidal gold immunolabelling showed the progressive disappearance of alpha MSH labelling from the secretory vesicles in cells exhibiting morphological features of adult corticotrophic cells. Both the alpha MSH content of the explants and alpha MSH release into the culture medium increased with time. Treatment with the dopamine agonist bromocriptine induced a strong dose-dependent decrease in alpha MSH secretion, which was significant after 3 days in culture, indicating that dopamine D2 receptors are able to regulate hormonal release of melanotrophic cells at early stages. This system constitutes a suitable model for further studies of factors controlling cell differentiation and cellular interactions involved in histogenesis.