Entrainment of the circadian system of mammals by nonphotic cues.

Although light is the principal zeitgeber to the mammalian circadian system, other cues can be shown to have a potent resetting effect on the clock of both adult and perinatal mammals. Nonphotic entrainment may have both biological and therapeutic significance. This review focuses on the effect of behavioral arousal as a nonphotic cue and the neurochemical circuitry that mediates arousal-induced entrainment in the adult rodent. In addition, it considers the role of nonphotic entrainment of the developing circadian system in perinatal life prior to the establishment of retinal input to the clock.

A thalamic contribution to arousal-induced, non-photic entrainment of the circadian clock of the Syrian hamster.

It is well established that the circadian clock of the suprachiasmatic nuclei (SCN) is entrained by light. More recently, the potent effects of arousing, non-photic cues on the clock have been recognized. The neural mediators of non-photic entrainment are yet to be identified. To examine the contribution of the thalamic intergeniculate leaflet (IGL) and its NPY-immunopositive projection, the geniculo-hypothalamic tract to non-photic entrainment by arousal, male Syrian hamsters received lesions of the IGL (IGLX) which ablated NPY-immunoreactivity in the SCN. Their circadian responses to both photic and non-photic cues were then tested. Lesions resulted in a delay in the timing of activity onset following lights out, but had no effect on the behavioural or cellular circadian responses to phase-advancing light pulses presented at circadian time (CT) CT19 (where CT12 represents the time of activity onset). Injection with a benzodiazepine (chlordiazepoxide, 100 mg/kg) at CT6 suppressed wheel-running, increased general locomotion of intact controls and induced large phase advances of the circadian rhythm of wheel-running. Chlordiazepoxide also inhibited wheel-running in lesioned animals, but there was no significant increase in general locomotion and the lesioned animals did not phase advance. Serial arousal by injection of saline at intervals of 23.5 h for 6 days entrained the circadian rhythm of wheel-running of intact hamsters and was associated with an increase in general locomotor activity. Entrainment by serial arousal was abolished by IGLX. However, the lesioned animals did show a clear behavioural response to every presentation of the non-photic cue. These results show that the IGL is a necessary component of the neural pathways mediating both arousal- and benzodiazepine-induced non-photic entrainment.

Non-photic signalling in the suprachiasmatic nucleus.

Scheduled arousal by handling and sub-cutaneous saline injection entrains the free-running clock of the adult Syrian hamster and outbred (ID(ICR)) but not inbred (C57B16) mice. Syrian hamsters bearing lesions of the intergeniculate leaflet of the thalamus remain able to entrain and phase-shift to light, but the lesions block completely entrainment by serial arousal, even though lesioned animals continue to respond acutely to the arousing cue. This suggests that the innervation from the IGL to the SCN is a necessary component of the pathways which signal an aroused state to the clock. Siberian hamsters do not entrain to serial arousal but they do entrain to serial injections of melatonin, whereas in adult Syrian hamster, systemic treatment with melatonin has no effect above that of arousal. In contrast to the adult, the foetal and neonatal Syrian hamster can be entrained by melatonin. These variations in sensitivity correlate with inter-specific and developmental differences in the pattern and level of expression of melatonin receptors in the SCN. The perinatal hamster can also be entrained by dopaminergic agonists. SCN tissue from neonatal Syrian hamsters was used to characterise the biochemical actions of dopamine and melatonin. In primary culture and tissue explants, forskolin, dopamine and glutamatergic agonists all stimulated the phosphorylation of the transcription factor CREB. This probably occurred via convergent actions through Ca2+ (glutamate) and cyclic AMP-dependent (forskolin, dopamine) signalling pathways. Dopamine induced phospho-CREB-ir exclusively in GABA-ir neurons and melatonin reversed this effect of dopamine, indicative of an inhibitory Gi protein linking via the Mel1a receptor to adenylyl cyclase. The regulation of phospho-CREB by multiple entraining cues in the SCN highlights its position as a point of convergence for regulators of the clock, and indicates a possible role in entrainment.

Gating of retinal inputs through the suprachiasmatic nucleus: role of excitatory neurotransmission.

The mammalian circadian clock, located in the hypothalamic suprachiasmatic nucleus (SCN) is important in the regulation of many circadian rhythms, including regulation of pineal gland metabolism and melatonin secretion. Transsection of the optic nerves, disrupting the retinohypothalamic pathway, lesion of the SCN, or lesion of the hypothalamic paraventricular nucleus (PVN) abolish the regulation of pineal serotonin N-acetyltransferase activity by light. Therefore, the pathways linking the retina and the pineal gland must be channelled from the retina through the SCN and the PVN. Many lines of evidence indicate that the major neurotransmitter in the retinal afferents is glutamate. The first aim was therefore to study the retinal target neurons by localising glutamate receptors in the rodent SCN. Using in situ hybridisation, we detected NMDA-R1 and NMDA-R2C mRNA subunits in the SCN. Using immunocytochemistry, immunoreactivity for the AMPA type receptors GluR1, GluR2,3 and GluR4 was also detected in the SCN. Presentation of a short light pulse during the subjective night [i.e. circadian time (CT) 14 or 19], when light induced phase-shifting of activity-rest cycles can be accomplished, also induces expression of the immediate early-genes c-fos and junB in the rodent SCN. The second aim was to use this cellular correlate of behavioural function to determine the location of potential retinal target neurons in the SCN, and to investigate the hypothesis that glutamatergic neurotransmission mediates the effects of light on the circadian system. Thus, the ability of the NMDA receptor antagonist MK-801 to block light-induced c-fos expression in the SCN was studied. In the rat, this antagonist blocked c-fos mRNA expression in a subpopulation of cells in the ventral SCN at doses of 6, but not 2 mg/kg. In contrast, in the hamster both doses blocked light-induced c-fos expression in the ventral SCN. These data provide support for the hypothesis that glutamate mediates effects of light in the SCN, although it appers that the complexes of NMDA receptor subunits, which are involved in light-induced expression of c-fos after light, are relatively insensitive to MK-801. The diversity, heterogeneous distribution, and complexity of glutamate receptor subunits in the SCN suggest that processing of light pulses in the SCN is mediated by several cell types in the SCN. Via an integration process in the clock, the transmission of photic information takes place to other brain structures.

Photoperiod regulates the LH response to central glutamatergic stimulation in the male Syrian hamster.

This study investigated central glutamatergic function in relation to photoperiodically-induced changes in the secretion of luteinizing hormone (LH). The experimental approach was to compare the central effects of glutamate agonists on LH secretion in reproductively active hamsters kept in long days (LD) with those in photoinhibited hamsters kept in short days (SD) for 6 weeks and having regressed testes. Agonists were delivered via a cannula into the III ventricle of freely moving hamsters, and blood samples collected 10 to 15 min after the start of the infusion. A high dose (3.0 nmole) of N-methyl-D-L-aspartate (NMDA) induced significant (P<0.01) increases in serum concentrations of LH in hamsters in both photoperiods, though the NMDA-induced increase relative to endogenous LH concentrations was greater in SD than in LD. However, a lower dose of NMDA (0.3 nmole revealed a difference in sensitivity. This dose significantly increased serum LH (P<0.05) in hamsters in SD but had no effect in those in LD. The seasonal difference in response to NMDA was compared with the response to an equimolar dose of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), a non-NMDA agonist. This dose of AMPA (0.3 nmole) induced a two-fold increase (P<0.05) in serum concentrations of LH in hamsters in both photoperiods, relative to vehicle-treated controls. In a third experiment the dose-response effects of central AMPA on LH secretion were examined more closely. The sensitivity of LH secretion to stimulation with AMPA did not differ between SD- and LD-housed hamsters. Thus the photoperiod-related difference in sensitivity to stimulation with glutamate agonists is specific for NMDA receptor-mediated activation, rather than a passive reflection of differences in the capacity to secrete GnRH/LH in SD and LD photoperiods. To investigate the site of action of NMDA, the expression of the c-fos immediate-early gene, as assessed by immunocytochemistry for its protein product Fos, was used as a marker of neuronal activation, because previous studies in rodents indicate that a high proportion of GnRH neurons express c-fos at the time of the mid-cycle LH surge. NMDA induced widespread expression of c-fos in many periventricular regions including the medial preoptic area (POA) and ventromedial hypothalamic nucleus. However, dual ICC revealed that in neither photoperiod was Fos present in GnRH-positive neurons 1 h after infusion of 3 nmole of NMDA, despite the increases in LH secretion induced by the infusion. AMPA injected icv at doses which released LH did not enhance expression of c-fos in the hypothalamus. Thus, in the male, enhanced expression of c-fos cannot be detected in GnRH neurons at the time of increased secretion of this hormone induced by glutamate agonists. In conclusion, these results show that both NMDA and non-NMDA glutamatergic pathways potentially regulated LH secretion in the Syrian hamster. The increased sensitivity to NMDA but unaltered sensitivity to AMPA in photoinhibited hamsters in SD is consistent with the view that changes in photoperiod might induce specific alterations in NMDA-mediated pathways that ultimately regulate GnRH neurosecretory activity.

Neuroendocrine rhythms.

Hormones are secreted with circhoral, circadian and seasonal periodicities. Circhoral pulsatility is a temporal code, many chronic and acute changes in neuroendocrine status being mediated by changes in the frequency of circhoral release. The identity of the neuronal circuits controlling circhoral release is not known. Circadian release of hormones occurs with a precise temporal order entrained to the light-dark cycle, synchronized to the activity/rest rhythm and generated by circadian oscillators, of which the suprachiasmatic nuclei are the most important. Seasonal rhythms are driven either by an endogenous circannual clock mechanism or by a process of photoperiodic time measurement which is dependent upon the duration of the nocturnal peak of the pineal hormone melatonin.

The hypothalamus and photoperiodic control of FSH secretion by melatonin in the male Syrian hamster.

In the photoinhibited castrated male Syrian hamster, removal of the pineal gland or transfer to long photoperiods was followed by a rapid increase in the serum concentration of FSH. Levels were significantly above those of controls within 10 days. Central passive immunization of pineal-intact photoinhibited castrated animals against melatonin had a stimulatory effect on serum FSH levels, comparable with that observed following pinealectomy or transfer to short days. The effects of pinealectomy were blocked by programmed s.c. infusions of melatonin in a time-dependent manner. Serum FSH levels remained low in animals receiving 100 ng melatonin delivered over 10 h but the same mass of melatonin delivered over 4 h had no effect on the response to pinealectomy. Lesions of the anterior hypothalamus had no effect on the pinealectomy-induced increase of serum FSH in animals receiving saline infusions. However, in lesioned animals, programmed infusions of melatonin were no longer able to suppress the rise in FSH following pinealectomy. These results demonstrated that pineal melatonin is the mediator of central photoperiodic control of FSH secretion. The duration of the melatonin signal determines its effectiveness and an intact anterior hypothalamus is necessary for the signal to be read and/or the appropriate neuroendocrine response expressed.

The effects of castration, testosterone replacement and photoperiod upon hypothalamic beta-endorphin levels in the male Syrian hamster.

Syrian hamsters kept in long day-lengths have active gonads and high circulating levels of gonadal steroids. Under the influence of the pineal gland, animals exposed to short photoperiods undergo testicular regression, have low circulating levels of testosterone and gonadotrophins and elevated levels of beta-endorphin within the hypothalamus. This paper describes the interaction between testosterone and photoperiod in the regulation of beta-endorphin levels in three regions of the hypothalamus. Hypothalamic beta-endorphin levels were measured by a combination of high-performance liquid chromatography and radioimmunoassay techniques that allows separation of the beta-endorphin (1-31) peptide from its metabolites and precursors. All of the beta-endorphin-like immunoreactivity in the hypothalamus of the male hamster, in both photoinhibited and photostimulated conditions, was found to represent the 31-amino-acid peptide. In photostimulated hamsters, chronic castration was associated with a significant increase of beta-endorphin levels in the anterior hypothalamus and mediobasal hypothalamus, which was reversed by treatment with exogenous testosterone. Castration prevented the ability of naloxone, an opiate receptor antagonist, to release luteinizing hormone, and this effect was also reversed by exogenous steroid. In photoinhibited hamsters, however, castration had no effect upon beta-endorphin levels in the preoptic area or mediobasal hypothalamus, and there was only a small increment in the anterior hypothalamus. Significantly, beta-endorphin levels in all areas of the hypothalamus of photoinhibited castrates were not decreased by testosterone treatment. In addition, administration of exogenous testosterone did not restore sensitivity to naloxone in these animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in photoperiod alter the daily rhythms of pineal melatonin content and hypothalamic beta-endorphin content and the luteinizing hormone response to naloxone in the male Syrian hamster.

This study examines the possible involvement of beta-endorphin in the photoperiodic control of reproduction in the Syrian hamster. beta-Endorphin and LHRH concentrations in the medial basal hypothalamus (MBH), anterior hypothalamus (AHA), and the preoptic area (POA) as well as pineal melatonin content were determined by RIA in male Syrian hamsters exposed to either a long day [(LD) 16-h light; 8-h dark; lights on 0700-2300] or short day [(SD) 8-h light, 16-h dark; lights on 0700-1500] for 8 weeks. Groups of eight animals from each photoperiod were killed by decapitation at 4-h intervals over 24 h. Twenty minutes before death half the animals from each photoperiod were given naloxone (5 mg/kg, sc), the other half saline. Exposure to a long photoperiod maintained testicular activity while a short photoperiod induced testicular regression. Pineal melatonin content in both photoperiods was maximal at 0500 h, i.e. 2 h before the onset of light (SD, 435.58 +/- 82.7 pg/pineal; LD, 276.78 +/- 56.8 pg/pineal). However, the duration of the nighttime rise in pineal melatonin content was increased in SD animals with elevated melatonin levels at 2100 h (157.10 +/- 41.8 pg/pineal) and 0100 h (199.11 +/- 58.9 pg/pineal). In contrast pineal melatonin content in LD animals was only higher than daytime values at 0500 h. A daily rhythm of beta-endorphin content within both the AHA and MBH of animals exposed to a short photoperiod coincided with this prolonged nighttime rise in pineal melatonin content, although a causal relationship between the two was not established. Peak levels of beta-endorphin occurred at 2100 h (AHA, 6.569 +/- 1.2 pmol/mg protein; MBH, 4.877 +/- 0.45 pmol/mg protein) and at 0100 h (AHA, 6.107 +/- 0.66 pmol/mg protein; MBH, 4.49 +/- 00.79 pmol/mg protein) which was 6 h and 10 h into the dark phase, respectively, with lowest levels in the middle of the light phase (AHA, 3.561 +/- 0.56 pmol/mg protein; MBH, 2.688 +/- 0.3 pmol/mg protein). This rhythm was absent in animals exposed to a long photoperiod. There was no effect of photoperiod or time of day on the content of beta-endorphin in the POA. LHRH levels were not altered by changes in photoperiod in all three brain regions studied. In the AHA and MBH, concentrations of LHRH were similar at all times of day whereas, in the POA, LHRH levels varied with time in both photoperiods. Peak levels occurred in the middle of the dark phase at 0100 h (LD, 2.774 +/- 0.24 pmol LHRH/mg protein; SD, 3.206 +/- 0.48 pmol LHRH/mg protein) with lowest levels during the light phase (LD, 1.664 pmol LHRH/mg protein; SD, 1.775 pmol LHRH/mg protein).(ABSTRACT TRUNCATED AT 400 WORDS)

Annual reproductive rhythms in mammals: mechanisms of light synchronization.

Animals restrict the time of birth of offspring to the most advantageous time of year, usually spring or summer. This is achieved by controlling the preceding period of fertility and, in some cases, by delaying implantation of the zygote. Seasonal changes in daylength, the principal, though not the only cue, regulate pulsatile release of hypothalamic releasing factors that in turn activates the pituitary-gonadal axis. The role of the neuroendocrine system is therefore to translate the photoperiodic stimulus into an endocrine signal (Figure 12). The measurement of day length is a function of the circadian system, environmental light being sampled on a 24-hour basis. Experimental manipulations of the photoperiodic response have revealed the existence of a rhythm of sensitivity to the presence of light that is entrained by the prevailing photoperiod. Light falling within the period of maximal sensitivity results in an LD type response. It is important to note that although different species measure day length in a similar manner, the gonadal response to a given photoperiod will vary between species depending upon the nature of their seasonal reproductive strategy. Photic information is conveyed from the retina to the pineal gland by way of the suprachiasmatic nuclei of the hypothalamus and the cervical sympathetic trunk. The central connections between these structures are poorly understood. The pineal is an essential mediator of the photoperiodic response. The effects of pinealectomy vary between species, but in all cases the responses to changes in day length are blocked. The gland is neither anti- nor progonadotrophic; it merely provides a signal. This signal is probably the nocturnal release of melatonin. Studies on in vivo melatonin production and the responses of photoperiodic species to timed administration of exogenous melatonin have suggested that the duration of nocturnal melatonin production by the pineal is read by the CNS as an indicator of the length of darkness. This model for PTM provides a physiological basis to the observed rhythm of sensitivity to light. This period of sensitivity is probably a parallel to the nocturnal rhythm of melatonin production. Light falling in this phase blocks melatonin production, truncates the pineal signal, and hence produces an LD response by the CNS. The site of the signal detector is not known, although the anterior hypothalamus may be involved. How the pineal signal triggers changes in the hypothalamic LHRH pulse generator is not known. The endogenous opioids, however, especially beta-END may have a major role in exercising photoperiodic control over pituitary action.

Melatonin and the brain in photoperiodic mammals.

The reproductive cycle of photoperiodic species is driven by seasonal changes in daylength. The pineal gland transduces photic information into an endocrine signal. The duration of the nocturnal bout of melatonin secretion is a direct indicator of night-length. The circadian rhythm of melatonin production is driven by a multisynaptic pathway from the suprachiasmatic nuclei (SCN), via the parvocellular portion of the paraventricular nucleus to the preganglionic sympathetic neurons of the thoracic spinal cord. The melatonin signal acts as an interval timer. The cellular basis of the detection of the signal is unknown. The site of detection is possibly within the anterior hypothalamus. The SCN are not essential components of the system that responds to the pineal interval timer. Photoperiod and the pineal melatonin signal have pronounced effects on the function of endogenous opioids, which are probably related to changes in the neuroendocrine mechanisms that regulate gonadotropin release.