Genetic suppression of agrin reduces mania-like behavior in Na+ , K+ -ATPase α3 mutant mice

Myshkin mice heterozygous for an inactivating mutation in the neuron-specific Na(+) ,K(+) -ATPase α3 isoform show behavior analogous to mania, including an abnormal endogenous circadian period. Agrin is a proteoglycan implicated as a regulator of synapses that has been proposed to inhibit activity of Na(+) ,K(+) -ATPase α3. We examined whether the mania-related behavior of Myshkin mice could be rescued by a reduction in the expression of agrin through genetic knockout. The suppression of agrin reduced hyperambulation and holeboard exploration, restored anxiety-like behavior (or reduced risk-taking behavior), improved prepulse inhibition and shortened the circadian period. Hence, agrin is important for regulating mania-like behavior and circadian rhythms. In Myshkin mice, the suppression of agrin increased brain Na(+) ,K(+) -ATPase activity by 11 ± 4%, whereas no effect on Na(+) ,K(+) -ATPase activity was detected when agrin was suppressed in mice without the Myshkin mutation. These results introduce agrin as a potential therapeutic target for the treatment of mania and other neurological disorders associated with reduced Na(+) ,K(+) -ATPase activity and neuronal hyperexcitability.

Memory for time of training modulates performance on a place conditioning task in marmosets

In rodents, the expression of a reward-conditioned place preference (CPP) is regulated in a circadian pattern such that the preference is exhibited strongly at the circadian time of prior training but not at other circadian times. Because each animal is trained only at a single circadian phase, the concept of time as a context cue is derived from a rhythmic internal state rather than learned explicitly from the external cues. We now report that the same "time memory" is expressed following context conditioning in the common marmoset (Callithrix jacchus). Animals were trained at a specific time to discriminate between an unpaired context and a context paired with food reward. Marmosets were then tested for preference at circadian times that were either the same or different from the training time. Preference was expressed only when training and testing times matched. The results show that time of day learning can be generalized to this new world primate implying that a similar circadian mechanism might regulate craving for reward in diverse mammals including human beings.

Circadian pacemakers in vertebrates

The identification and isolation of circadian pacemaker cells is of critical importance to studies of circadian clocks at all phylogenetic levels. In the vertebrate classes, a few structures of diencephalic origin have been implicated as potential sites but for only two, the avian pineal and the mammalian suprachiasmatic nucleus (SCN), has a pacemaker role in addition to oscillatory behaviour been demonstrated by the transfer of pacemaker properties from one organism to another. Studies of the mammalian system in particular have benefited from the ability to restore circadian function using transplantation of tissue from the SCN and from the availability of a hamster period mutant, tau, that allows donor-derived and host-derived rhythms to be distinguished easily. Initial cross-genotype transplantation studies and the subsequent creation of circadian chimeras expressing two phenotypes simultaneously demonstrated the pacemaker capability of the SCN, and demonstrated the relative autonomy of this nucleus as a pacemaking structure. Despite an abundance of information regarding the anatomy, physiology and pharmacology of these nuclei, the identity of the pacemaker cells and their methods of communication with each other and the organism remain obscure. None the less, it is possible under certain conditions to create chimeras with two clocks that interact. The behaviour of these animals provides a unique opportunity to study the nature and timing of pacemaker communication.

Senescence, sleep, and circadian rhythms

The goal of this review article is to summarize our knowledge and understanding of the overlapping (interdisciplinary) areas of senescence, sleep, and circadian rhythms. Our overview comprehensively (and visually wherever possible), emphasizes the organizational, dynamic, and plastic nature of both sleep and circadian timing system (CTS) during senescent processes in animals and in humans. In this review, we focus on the studies that deal with sleep and circadian rhythms in aged animals and how these studies have closely correlated to and advanced our understanding of similar processes in ageing humans. Our comprehensive summary of various aspects of the existing research on animal and human ageing, both normal and pathological, presented in this review underscores the invaluable advantage of close collaboration between clinicians and basic research scientists and the future challenges inherent in this collaboration. First, our review addresses the common age-related changes that occur in sleep and temporal organization of both animals and humans. Second, we examine the specific modifications that often accompany sleep and CTS during aging. Third, we discuss the clinical epidemiology of sleep dysfunctions during ageing and their current clinical management, both pharmacological and non-pharmacological. Finally, we predict the possible future promises for complementary and alternative medicine (CAM) that pave the way to the emergence of a "Holistic Sleep Medicine" approach to the treatment of sleep disorders in the ageing population. Further studies will provide additional valuable insights into the understanding of both sleep and circadian rhythms during senescence.

Circadian phase-shifted rats show normal acquisition but impaired long-term retention of place information in the water task

It is thought that circadian rhythms may influence learning and memory processes. However, research supporting this view does not dissociate a mnemonic impairment from other performance deficits. Furthermore, published reports do not specify the type of memory system influenced by the circadian system. The present study assessed the effects of phase shifting on acquisition and expression of place navigation in the water maze, a task sensitive to hippocampal dysfunction. The results showed that phase-shifting circadian rhythms in rats impaired the expression of place information on a retention test but not initial acquisition or encoding of place information. These results suggest that disruption of circadian rhythms may impair consolidation of previously encoded hippocampal place information.

Brain-stimulation reward thresholds raised by an antisense oligonucleotide for the M5 muscarinic receptor infused near dopamine cells

Oligonucleotides targeting M5 muscarinic receptor mRNA were infused for 6 d into the ventral tegmental area of freely behaving rats trained to bar-press for lateral hypothalamic stimulation. The bar-pressing rate was determined at a range of frequencies each day to evaluate the effects of infusions on reward. M5 antisense oligonucleotide (oligo) infusions increased the frequency required for bar pressing by 48% over baseline levels, with the largest increases occurring after 4-6 d of infusion. Two control oligos had only slight effects (means of 5 and 11% for missense and sense oligos, respectively). After the infusion, the required frequency shifted back to baseline levels gradually over 1-5 d. Antisense oligo infusions decreased M5 receptors on the ipsilateral, but not the contralateral, side of the ventral tegmentum, as compared with a missense oligo. Therefore, M5 muscarinic receptors associated with mesolimbic dopamine neurons seem to be important in brain-stimulation reward.

Circadian rhythms, aging and memory

In human beings and animal models, cognitive performance is often impaired in natural and experimental situations where circadian rhythms are disrupted. This includes a general decline in cognitive ability and fragmentation of behavioural rhythms in the aging population of numerous species. There is some evidence that rhythm disruption may lead directly to cognitive impairment; however, this causal link has not been made for effects due to aging. We have tested this link by examining rhythms and performance on contextual conditioning with the conditioned place preference task, in elderly, age-matched hamsters. Young healthy hamsters developed a preference for a context that is paired with the opportunity to engage in wheel-running (experiment 1). Aged animals with consolidated locomotor rhythms developed similar degrees of preference, whereas the age-matched hamsters with fragmented rhythms did not (experiment 2). The degree of preference was also correlated with activity amplitude. These results support the notion that age-related rhythm fragmentation contributes to the age-related memory decline.

Circadian rhythms, aging and memory

In human beings and animal models, cognitive performance is often impaired in natural and experimental situations where circadian rhythms are disrupted. This includes a general decline in cognitive ability and fragmentation of behavioural rhythms in the aging population of numerous species. There is some evidence that rhythm disruption may lead directly to cognitive impairment; however, this causal link has not been made for effects due to aging. We have tested this link by examining rhythms and performance on contextual conditioning with the conditioned place preference task, in elderly, age-matched hamsters. Young healthy hamsters developed a preference for a context that is paired with the opportunity to engage in wheel-running (experiment 1). Aged animals with consolidated locomotor rhythms developed similar degrees of preference, whereas the age-matched hamsters with fragmented rhythms did not (experiment 2). The degree of preference was also correlated with activity amplitude. These results support the notion that age-related rhythm fragmentation contributes to the age-related memory decline.

The effect of amphetamine on locomotion depends on the motor device utilized. The open field vs. the running wheel

The effect of amphetamine on the level of locomotion exhibited on two different motor devices was examined in the Golden hamster. Increasing concentrations of the psychostimulant from 4 to 10 mg/kg significantly enhanced locomotor activity in hamsters exposed to an open field. A further increase to 25 mg/kg inhibited ambulatory activity to levels below the control baseline, while augmenting the occurrence of stereotypic behaviors. The activating effect of amphetamine on ambulatory activity was observed regardless of the time of testing (day or night) or lighting condition, with no apparent modulation by the circadian system. On the other hand, home-cage wheel-running activity was maximally inhibited by 10 mg/kg amphetamine, whereas a smaller dosage (1.5 mg/kg) had no effect over the wheel-running activity baseline of saline controls. Although both the running wheel and the open field quantify locomotion, the dissociation obtained shows that they measure different components of it. The results are interpreted within Lyon and Randrup's hypothesis on the actions of amphetamine (16).

Retinal GABA(A) receptors participate in the regulation of circadian responses to light

A role for retinal gamma-aminobutyric acid Type A (GABA(A)) receptors in the regulation of circadian responses to light was examined. Intraocular injections of the GABA(A) antagonist, bicuculline, were performed during the early (Circadian Time [CT] 13.5) and late subjective night (CT 20), followed by a light pulse. Bicuculline significantly decreased the magnitude of phase delays induced by light to 65%, whereas it had no effect on phase advances. To explore the nature of the inhibition elicited by bicuculline, an intensity-response curve was performed. Intraocular injections of bicuculline inhibited phase delays only when induced by high-saturating light illuminances (20 and 100 lux). No effect was observed at light intensities < or = 5 lux. These results suggest that retinal GABA(A) receptors modulate the responsivity of the circadian system to light.

The significance of circadian organization for longevity in the golden hamster

While functional roles for biological clocks have been demonstrated in organisms throughout phylogeny, the adaptive advantages of circadian organization per se are largely matters of conjecture. It is generally accepted, though without direct experimental evidence, that organisms derive primary benefits from the temporal organization of their physiology and behavior, as well as from the anticipation of daily changes in their environment and their own fluctuating physiological requirements. However, the consequences of circadian dysfunction that might demonstrate a primary adaptive advantage and explain the natural origins and apparent ubiquity of circadian systems have not been documented. The authors report that longevity in hamsters is decreased with a noninvasive disruption of rhythmicity and is increased in older animals given suprachiasmatic implants that restore higher amplitude rhythms. The results substantiate the importance of the temporal organization of physiology and behavior provided by the circadian clock to the health and longevity of an organism.

Conservation of locomotor behavior in the golden hamster: effects of light cycle and a circadian period mutation

Locomotor activity in rodents is restricted temporally by the animal' s circadian system. The relative stability of both the species-specific pattern and the amount of locomotor activity per cycle suggested that this behavior may be regulated by conservative mechanisms. In these experiments, the wheel-running behavior of golden hamsters carrying the circadian period mutation, tau, was analyzed in animals housed in a 24-h light:dark cycle (LD) and in constant dark (DD) conditions to determine which aspects of this behavior were conserved. In DD, apart from the change in period which defines the mutation, no main effects of allele combination were found in either average amount of activity, activity profile, or length of the activity phase. In LD, wild-type behavior did not differ from that in DD; however, heterozygous mutants exhibited early onsets of activity, significant fragmentation of both activity and rest, an increase in the duration of the active phase, and an overall decrease in the amount of activity. Despite these differences, the total amount of time spent on the wheel in LD or DD was the same for all environment/genotype combinations. The data show that a conservative mechanism that may influence daily patterns of locomotor behavior is related more to a drive to perform the behavior than the quantity or timing of the behavior itself.

Regulation of circadian photic responses by nitric oxide

A role for nitric oxide in circadian responses to light has been indicated in previous studies. To determine the specific function of NO-, the authors manipulated NO- and nitric oxide synthase (NOS) activity prior to light pulses that would normally induce phase shifts. The NOS inhibitor, L-NAME, selectively attenuated phase advances of locomotor rhythms and had no effect on phase delays. The NO- donor, SNAP, potentiated both photic responses, and phase delays were larger than the maximum responses that could be obtained with light alone. The date suggest a model in which NO- participates in the adaptation of the system to environmental lighting conditions by regulating in a phase-dependent manner responsiveness to light.

cGMP-dependent protein kinase inhibitors block light-induced phase advances of circadian rhythms in vivo

Synchronization of circadian rhythms is thought to be accomplished primarily through daily phase delays and advances of the endogenous circadian clock that, in mammals, is located in the hypothalamic suprachiasmatic nucleus (SCN). In the SCN, numerous second messenger pathways may participate in photic signal transduction. In these studies, the involvement of cyclic nucleotide-dependent kinases was examined in vivo using inhibitors of adenosine 3',5'-cyclic monophosphate (cAMP)- and guanosine 3',5'-cyclic monophosphate (cGMP)-dependent kinase (PKA and PKG, respectively). In constant dark, selective and nonselective inhibitors of PKG injected near the SCN of hamsters had no effect on phase delays produced by light pulses given in the early subjective night (early in the animals' active period) but significantly attenuated phase advances induced late in the subjective night. PKA inhibition had no effect at either time point. In addition, cGMP agonists had no effect on rhythmicity in the absence of light. The results suggest that PKG activity is necessary, but not sufficient, for normal photic responsiveness and that PKA activity is not required. The phase dependence of the effect of PKG inhibition supports the notion that photic entrainment is influenced by biochemical pathways that differentially regulate sensitivity in a phase-dependent manner.

The circadian system of c-fos deficient mice

We examined the role of c-fos in the synchronization of circadian rhythms to environmental light cycles using a line of gene-targeted mice carrying a null mutation at this locus. Circadian locomotor rhythms in mutants had similar periods as wild-type controls but took significantly longer than controls to entrain to 12:12 light-dark cycles. Light-induced phase shifts of rhythms in constant dark were attenuated in mutants although the circadian timing of phase delays and advances was not changed. A functional retinohypothalamic projection was indicated from behavioral results and light-induced jun-B expression in the SCN. The results indicate that while c-fos activation is not an absolute requirement for rhythm generation nor photic responses, it is required for normal entrainment of the mammalian biological clock.

Pacemaker interactions in the mammalian circadian system

Circadian rhythms in mammals are generated by pacemaker cells located in the suprachiasmatic nucleus (SCN) of the anterior hypothalamus. The identity of these cells, however, is not known, and little information exists regarding the mechanisms by which they communicate with each other and with the organism. Nonetheless, pacemaker interactions must occur to produce single, coherent rhythms of behavior and physiology. Recently it has become possible to observe the result of these interactions using circadian chimeras, animals with two clocks with distinct periods, that have been produced by SCN transplantation. Using the tau mutation in golden hamsters, chimeras expressing two circadian rhythms of behavior simultaneously were created. The two rhythms exhibited complex interactions including cases of relative coordination. This basic result indicates that pacemaker interactions are rhythmic and phase dependent. Further analysis should help to elucidate the nature of the coupling signal and the identity of the pacemaker cells.

Let there be light: signal transduction in a mammalian circadian system

Mammalian circadian rhythms are controlled by a biological clock located in the hypothalamic suprachiasmatic nuclei (SCN). This clock is entrained by light through a retinohypothalamic pathway that interacts with the SCN through glutamate neurotransmission. Light pulses during the subjective night induce phase shifts of behavioral rhythms, and also trigger intracellular changes such as the expression of immediate-early genes and activation of transcription factors. In this review, we present a model of the signal transduction pathway leading to photic synchronization of the circadian clock, including the activity of specific second messenger systems, gene expression, and interaction between potential agents capable of producing phase shifts.

Circadian locomotor rhythms in aged hamsters following suprachiasmatic transplant

Circadian activity rhythms that have been eliminated by lesions of the suprachiasmatic nucleus (SCN) can be restored by fetal SCN grafts. Partial lesions of the host allow simultaneous expression of both donor and host rhythms. Because partial SCN ablation produces characteristic changes in activity rhythms that are similar to those that occur with age, including shortened period, reduced amplitude, and fragmentation, we investigated the extent to which fetal SCN grafts may be expressed by an animal whose activity rhythm exhibits these age-dependent changes. The results indicate that expression of a transplanted clock is possible in an unlesioned aged host. Grafts of fetal SCN into young hosts and cortical tissue grafts into intact aged hosts have no effect. In those aged animals that received SCN grafts, three patterns of expression emerged in the subsequent locomotor activity record: complete dominance of locomotor rhythmicity by the donor; relative coordination between donor and host rhythms; and spontaneous switching between host and donor phenotypes. The results suggest that the expression of rhythmicity by the grafted SCN may depend on the relative amplitude or strength of signals produced by the host and donor SCN.

Circadian responses to light: the calmodulin connection

KN-62, an inhibitor of CaM kinase II, attenuated phase shifts induced by low intensity light pulses and reduced light-induced phosphorylation of the transcription factor, CREB, in the suprachiasmatic nucleus. The calmodulin inhibitor, W-7, had similar effects: neither drug produced a complete block of photic responses. The results support the hypothesis that circadian responses to light are mediated in part by CaM kinase activity and CREB, and suggest that other signal transduction pathways also take part.

Circadian modulation in the rat acoustic startle circuit

The acoustic startle reflex (ASR) in rats exhibits robust circadian modulation, with ASR amplitudes greater during subjective night. To identify the location of this modulation, startle reactions were evoked either acoustically or electrically via electrodes implanted in the primary ASR circuit. Startle amplitudes were compared at different times in the circadian cycle. In constant environmental conditions, startle amplitudes were greater in subjective night for acoustically evoked and for electrically evoked reactions from the ventral lateral lemniscus and medial longitudinal fasciculus. The results show that at least 1 site of circadian modulation must occur at some point in the circuit after the last brainstem synapse in the caudal pontine reticular formation, at the level of spinal interneurons or motoneurons or at the neuromuscular junction.

Circadian modulation in the rat acoustic startle circuit

The acoustic startle reflex (ASR) in rats exhibits robust circadian modulation, with ASR amplitudes greater during subjective night. To identify the location of this modulation, startle reactions were evoked either acoustically or electrically via electrodes implanted in the primary ASR circuit. Startle amplitudes were compared at different times in the circadian cycle. In constant environmental conditions, startle amplitudes were greater in subjective night for acoustically evoked and for electrically evoked reactions from the ventral lateral lemniscus and medial longitudinal fasciculus. The results show that at least 1 site of circadian modulation must occur at some point in the circuit after the last brainstem synapse in the caudal pontine reticular formation, at the level of spinal interneurons or motoneurons or at the neuromuscular junction.

Growth hormone-releasing hormone mediates feeding-specific feedback to the suprachiasmatic circadian clock

Growth hormone-releasing hormone (GHRH) is known to stimulate food intake in a circadian phase-dependent manner in rats. The suprachiasmatic nucleus (SCN) is an important site of action for this effect. In light of the central role played by the SCN in the control of circadian rhythms, together with the phase-dependent nature of GHRH-induced feeding, we sought to determine the possible involvement of SCN GHRH activity in the regulation of circadian rhythmicity. Two studies were conducted using hamsters as subjects. Study one replicated the daytime feeding-stimulatory effects of GHRH in hamsters, thereby validating its appetitive effects in this species. Study two showed that, in free-running hamsters, intra-SCN microinjections of GHRH produced phase advances when injected during the subjective day while having little effect during the subjective night. The GHRH phase-response curve was found to resemble that observed for nonphotic influences on the clock. It is suggested that GHRH input to the SCN is a neural representation of a nonphotic influence (perhaps feeding specific) on the clock.

Inhibition of GABA transaminase enhances light-induced circadian phase delays but not advances

The CNS neurotransmitter GABA is distributed extensively throughout the suprachiasmatic nucleus, the site of circadian pacemaker cells in mammals. Pharmacological agents that act at GABAA receptors alter specific circadian responses to light and may induce phase shifts of circadian rhythms. In the present study, the role of endogenously released GABA in rhythm regulation was investigated using vigabatrin (gamma-vinyl GABA), an agent that has been shown to increase chronically or acutely the CNS levels of this neurotransmitter by inhibiting GABA transaminase. In Experiment 1, hamsters in constant darkness (DD) received a saline or a vigabatrin injection 1 hr before a 15-min, 700-lux light pulse. Vigabatrin increased photic phase delays but did not affect advances. In Experiment 2, vigabatrin delivered chronically via osmotic minipump treatment did not affect locomotor activity period in DD. However, after 14 days of infusion, photic phase delays (but not advances) were greatly increased in the vigabatrin group. In Experiment 3, in constant light (LL), chronic vigabatrin-treated animals showed an increased period that returned to pretreatment values after the 14-day drug infusion. The results are consistent with the phase-dependent effects of other agents that alter GABA neurotransmission. The data support the general hypothesis that GABA modulates the circadian responses to light in a phase-dependent manner, and may participate in entrainment to light-dark cycles by influencing the relative responsiveness to light in the early and late subjective night.

KN-62, an inhibitor of Ca2+/calmodulin kinase II, attenuates circadian responses to light

Expression of immediate early genes and phosphorylation of the transcription factor CREB are induced in the suprachiasmatic nucleus after light pulses that cause phase shifts of circadian rhythms. To test for a direct role of this signalling pathway in mediating circadian responses to light in hamsters, we used KN-62 to inhibit the activity of CaM kinase II (known to phosphorylate CREB) prior to giving light pulses at times that would normally induce phase shifts. Central administration of KN-62 significantly inhibited phase delays and advances induced by bright pulses of light. The data support a model for photic responses of the circadian clock in the SCN that includes the phosphorylation of CREB by activation of CaM kinase II.

Light-induced phase shifts and Fos expression in the hamster circadian system: the effects of anesthetics

In the present study, we examined the effect of administration of anesthetics on light-induced phase shifts of the circadian system. This information is of critical importance, because many studies of light input to the mammalian suprachiasmatic nucleus (SCN) have been performed on anesthetized animals. We found that light-induced phase shifts were blocked by all drugs used at anesthetic doses. We then determined the effect of two of these agents on light induction of Fos-like immunoreactivity in the SCN. We found that the administration of sodium pentobarbital prevented light induction of Fos expression in the SCN, whereas the administration of urethane did not. These results raise cautions about the use of anesthetized animals to answer questions about the photic regulation of neuronal activity in the SCN.

The role of extracellular calcium in generating and in phase-shifting the Bulla ocular circadian rhythm

Since extracellular calcium is known to be involved in the entrainment of the circadian pacemaker in the retina of Bulla gouldiana, we have assessed the requirement for extracellular calcium in the generation of the circadian rhythm. To enable us to assay the state of the pacemaker during low-calcium treatment, which often obscures rhythmicity, long-duration pulses of low-calcium artificial seawater (no added calcium, 10 mM EGTA, calculated calcium concentration = 4.5 x 10(-10) M) were applied, and the phase of the subsequent rhythm was measured. Pulse treatments started at zeitgeber time (ZT) 6, and durations ranged from 4 to 72 hr. Although no phase shifts followed pulses ending before the next projected dawn (ZT 24), phase delays of up to 4 hr followed pulses ending after projected dawn, and delays of up to 8 hr followed pulses spanning two dawns. Some activity records exhibited unequivocal circadian rhythmicity during the long low-calcium treatments, with phases and periods similar to untreated control eye records; this finding suggests that the phase delays observed following long low-calcium pulses are attributable to the pulsatile nature of the treatment. These data suggest that extracellular calcium is not an essential requirement for the pacemaker in generating the circadian rhythm.

Behavioral inhibition of circadian responses to light

Circadian locomotor rhythms in rodents may be synchronized by either photic or nonphotic events that produce phase shifts of the rhythm. Little is known, however, about how these two types of stimuli interact to produce entrainment. The well-characterized circadian photic response of the golden hamster was examined in situations where a short light pulse and locomotor activity, a nonphotic event, occurred simultaneously. Light-induced phase advances were attenuated when animals were active during light exposure. The results show that circadian responses to light depend upon the environmental situation in which the light is given, and call into question the implicit assumption in circadian rhythm research that phase shifting and entrainment to light-dark cycles depend simply on photic activation of well-known retinofugal pathways. Moreover, since light therapy is becoming an important component in the treatment of circadian-based disorders in humans, the results emphasize the need for evaluation of the behavioral aspects of light therapy protocols.

Phase response curve to anisomycin in tau mutant hamsters

Administration of the protein synthesis inhibitor, anisomycin, to wild type hamsters produces phase shifts in their circadian rhythms that have similarities to shifts produced by non-photic behavioral stimulation. A mutation that shortens the period of rhythms in hamsters results in altered responsiveness to non-photic input. However, responses of the mutants to anisomycin are unaffected: their phase response curve (PRC) for anisomycin is similar to that of wild types. This suggests that 1) anisomycin is not acting on mechanisms specifically involved in non-photic behavioral phase shifting, and 2) the mutation affects the non-photic input pathway or the pacemaker itself at a point that is upstream from anisomycin's site of action.

Protein differences in tau mutant hamsters: candidate clock proteins

In the tau mutant hamster, the period of the circadian rhythm is shortened from about 24 h to about 22 h in heterozygotes and to about 20 h in homozygotes. Understanding the biochemical basis of the period changes in the tau mutant may elucidate the regulation of the vertebrate pacemaker. Using two-dimensional gel electrophoresis, we have found two sets of proteins that differ between the different genotypes. P33tau (about 33 kDa; pI 6.5) was found in all gels from wild type and heterozygous animals, but was absent in gels from all except one of the homozygous mutant animals. P32tau (about 32 kDa; pI 4.8) was a chain of spots, which showed a striking difference in pattern between gels from wild type animals and from mutant animals. P33tau was greatly enriched in soluble cellular fractions, whereas P32tau was found only in insoluble fractions. These differences between P33tau and P32tau were apparent in gels from both SCN and cortical tissue, suggesting that both proteins are distributed throughout the brain. These proteins should be useful as new tools to explore the biochemistry of circadian pacemakers.

The Drosophila per gene homologs are expressed in mammalian suprachiasmatic nucleus and heart as well as in molluscan eyes

This study presents evidence for the conservation of Drosophila per gene homologs in mammalian DNA and for their expression in a number of tissues which are involved in various aspects of circadian timekeeping. Distinct 5 kb sequences, which hybridized to a non repetitive fragment of the Drosophila per gene under stringent conditions, were detected by Southern blotting. Sequences homologous to per gene of Drosophila were also amplified from rat and mouse brain cDNA libraries and from a mouse anterior hypothalamus and human hypothalamus libraries. Degenerate PCR primer design was based on conserved segments of the per protein. The per homologs were shown directly (by RT-PCR) to be expressed in hamster and mouse SCN, in hamster heart and in Aplysia and Bulla eyes.

Nonphotic phase shifting in hamster clock mutants

Golden hamsters with the tau mutation were kept in the dark and induced to become active through confinement to a novel running wheel for 3 hr. The response of the mutants to this nonphotic phase-shifting stimulus differed from that of wild-type hamsters. The mutants showed larger phase shifts, and their phase response curves differed in shape, with an advance portion at about circadian time 24, a phase at which wild types show delays. The results establish that the tau mutation, in addition to its already known effects, alters the response of the circadian system to nonphotic events.

Does low intracellular pH stop the motion of the Bulla circadian pacemaker?

The eye of the mollusk Bulla has proven itself useful as an in vitro neural circadian pacemaker. Here, we report that treatments applied to lower intracellular pH may stop the motion of this circadian pacemaker in a phase-dependent manner. Lowering the extracellular pH of the artificial seawater bath to 6.9, or application of the stilbene derivatives 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS) or 4,4-di-isothiocyanostilbene-2,2'-disulfonic acid (DIDS), abolishes the circadian rhythm in optic nerve compound action-potential frequency. Because these treatments are known to lower intracellular pH, these data suggest that the pacemaker may be inhibited by low intracellular pH. In order to assess the state of the pacemaker during low extracellular pH treatment, pulses of seawater at pH 6.8 were applied, and the phase of the rhythm subsequent to the pulse was observed. All pulses started 1 hr after subjective dusk [circadian time (CT) 13] and were applied to eyes in constant darkness; pulse lengths varied from 4 to 47 hr for different preparations. The phases of the eye rhythms following pulses that ended before subjective dawn (about CT 24) were not different from untreated preparations. However, for pulses longer than 11 hr and therefore ending after subjective dawn, the subsequent phase of the rhythm was a function of the ending time of the pulse. These data suggest that the pacemaker's motion was stopped at dawn during the low-pH treatment and resumed following restoration of normal pH. To distinguish between phase and duration dependence of this effect in the above experiment, phase shifts were obtained to 14-hr pulses of pH 6.8 seawater applied at three different phases.(ABSTRACT TRUNCATED AT 250 WORDS)

Transplantation: a new tool in the analysis of the mammalian hypothalamic circadian pacemaker

The suprachiasmatic nucleus (SCN) of the hypothalamus is the site of pacemaker cells that generate circadian rhythmicity in mammals. Transplantation of the nucleus into animals whose own nucleus has been ablated results in the restoration of overt rhythmicity to the arrhythmic host. By using donors and hosts with genetically different circadian characteristics, the unambiguous recognition of the donor rhythm expressed in a transplant recipient is possible. The reappearance of a rhythm indicates that not only has the grafted tissue survived the transplantation procedure, but that pacemaker cells that generate circadian rhythms were included in the graft; this is essential in interpreting results of such transplantation experiments. The restoration of circadian function by neural transplantation has become an important tool for studying the generation and expression of biological rhythms in mammals, and is being used in the investigation of basic questions in this field.

Do NMDA receptors mediate the effects of light on circadian behavior?

We report here the results of experiments designed to evaluate whether a specific NMDA receptor antagonist, (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,b]cyclohepten-5,10-imine maleate (MK-801), blocks the phase shifting effects of light on the circadian rhythm of wheel-running activity in golden hamsters. Intraperitoneal administration of (+)-MK-801 produced a dose-dependent blockade of both light-induced phase advances and delays. The effect was stereoselective and treatment with related compounds, phenylcyclidine and ketamine, also blocked light-induced phase shifts. MK-801, by itself, did not cause any consistent effect on the phase of the rhythm. These data, coupled with previous findings, indicate that excitatory amino acid receptors play an important role in the transmission of light information from the retina to the circadian system.

Chloride conductance contributes to period determination of a neuronal circadian pacemaker

The isolated eye of Bulla gouldiana, a marine mollusc, is a circadian pacemaker. Previous studies have shown that membrane potential changes of neurons at the base of the Bulla retina play a critical role in the expression of the circadian rhythm and that the free-running period can be modified by chronic alteration of the resting membrane potential. We now report that treatments which inhibit CI- conductance shorten the free-running period. Substitution of CI- with the anions SO4(2-), isethionate and glutamate significantly shorten the period of the ocular rhythm in vitro. Furthermore, addition of the CI- channel blocker 9-anthracene-carboxylic acid (9-AC) is also effective at shortening the period of the circadian rhythm. These data suggest that a CI- conductance participates in determining the free-running period of the circadian pacemaker cells. This is the first report of CI- conductance involvement in a circadian system and the effect is remarkable in that few treatments are known which reliably shorten the period of circadian clocks.

Circadian and light-induced conductance changes in putative pacemaker cells of Bulla gouldiana

The ocular circadian rhythm of compound action potential frequency in Bulla gouldiana is driven by rhythmic changes in the membrane potential of putative circadian pacemaker cells. Changes in the membrane potential of these neurons is required for light-induced phase shifts of the rhythm. We have tested the proposition that these changes in membrane potential reflect underlying changes in ionic conductances. We have found that: 1. Membrane conductance in the dark is highest during the subjective night when the cells are hyperpolarized, decreases as the cells depolarize spontaneously near projected dawn and is lowest during the subjective day. The changes in membrane potential and conductance follow a similar time course. 2. Long pulses of light delivered to eyes during their subjective night produce a characteristic response: There is initially a large, phasic depolarization accompanied by a burst of CAPs; this is followed by a repolarizing phase during which CAP activity is reduced to zero; and finally a tonic depolarization develops that is accompanied by a resumption of CAP activity at a steady rate. 3. During the subjective night, the tonic depolarization is accompanied by a decrease in conductance compared to the previous dark value. However, light pulses of similar duration delivered to eyes during their subjective day causes tonic depolarizations and increased CAP activity, but no measurable change in conductance. 4. Membrane responses to light are sensitive to agents that reduce Ca2+ flux. Light pulses during the subjective night produce a phasic depolarization, but the repolarization phase is eliminated in low Ca2+/EGTA seawater and is reduced in 5 mM Ni2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Transplanted suprachiasmatic nucleus determines circadian period

The pacemaker role of the suprachiasmatic nucleus in a mammalian circadian system was tested by neural transplantation by using a mutant strain of hamster that shows a short circadian period. Small neural grafts from the suprachiasmatic region restored circadian rhythms to arrhythmic animals whose own nucleus had been ablated. The restored rhythms always exhibited the period of the donor genotype regardless of the direction of the transplant or genotype of the host. The basic period of the overt circadian rhythm therefore is determined by cells of the suprachiasmatic region.

GABA regulation of circadian responses to light. I. Involvement of GABAA-benzodiazepine and GABAB receptors

Light-induced phase shifts of the circadian locomotor rhythm of hamsters can be blocked by agents that alter GABA neurotransmission. The GABA antagonist bicuculline blocks phase delays induced by light and the benzodiazepine diazepam, which can potentiate GABA activity, blocks light-induced phase advances. In the experiments reported here, we found that the bicuculline blockade of phase delays was reduced by agents that mimic or potentiate GABA activity. Conversely, the diazepam blockade of phase advances was reduced by both competitive and noncompetitive antagonists of GABA. This indicates that the GABA-benzodiazepine receptor-ionophore complex is the most likely site of action for the effects of these drugs on circadian rhythms. However, competitive GABA agonists did not mimic the blocking effects of benzodiazepines, nor did the antagonist picrotoxin mimic the blocking effect of bicuculline. Therefore, the classic action of GABA, increased chloride conductance, may not be the effector mechanism in this case. We also found that the GABAB agonist baclofen blocked both phase advances and delays and that the blockade of advances was reversed by the antagonist delta-aminovaleric acid. Taken together, these results indicate that GABA is involved in the regulation of circadian responses to light and that the regulation is mediated by both GABAA and GABAB receptors.

A mutation of the circadian system in golden hamsters

A mutation has been found that dramatically shortens the period of the circadian locomotor rhythm of golden hamsters. The pattern of inheritance of this mutation suggests that it occurred at a single, autosomal locus (tau). Wild-type animals have rhythms with free-running periods averaging about 24 hours; animals heterozygous for the mutation have periods of about 22 hours, whereas homozygous animals have rhythms with periods close to 20 hours. Animals that carry the mutant alleles exhibit abnormal entrainment to 24-hour light:dark cycles or are unable to entrain.

The intergeniculate leaflet partially mediates effects of light on circadian rhythms

Photic signals affect circadian activity rhythms by both phasic and tonic mechanisms that modulate pacemaker phase and period. In mammals, the effects of light on circadian activity are mediated by the retina, which communicates with the suprahiasmatic nucleus (SCN) by two different anatomical routes: the retino-hypothalamic tract (RHT), originating in the retina, and the geniculo-hypothalamic tract (GHT), arising from a retino-recipient nucleus, the intergeniculate leaflet (IGL). We assessed the roles of these two afferent systems in mediating phasic and tonic effects of light on circadian activity in IGL-lesioned animals. Destruction of the IGL significantly affected phase shifts produced by brief light pulses (phasic effect) and modified the change in period (tau) of the free-running activity rhythm produced by changing the level of constant light (LL) (tonic effect). Phase advances produced by brief light pulses were decreased in amplitude while phase delays were increased in IGL-lesioned animals as compared to controls. The free-running period in constant dark (tau DD) of IGL-lesioned animals was greater than tau DD of controls, and the lengthening of tau normally produced by LL was not observed or was greatly reduced in IGL-lesioned animals. Entrainment to light-dark cycles was unaffected by the lesions, as were other aspects of the circadian activity rhythm that normally change in response to LL (e.g., activity-rest ratio, total activity, splitting). Our data support the interpretation that the IGL plays a significant role in relaying information regarding illumination intensity to the SCN.

Effects of diazepam on circadian phase advances and delays

Phase advances of hamster locomotor rhythms, which normally can be induced by light pulses in the late subjective night, were blocked in a dose-dependent manner by the benzodiazepine, diazepam. Light-induced phase delays were unaffected at doses that significantly blocked phase advances. Diazepam caused small phase delays of the free-running rhythm when given without a light pulse at either phase advance or phase delay time points. These results are discussed with regard to the possibility that different neurochemical mechanisms are required to process light-induced phase advances and delays and that GABA neurotransmission may be involved in the modulation of light input to the clock.

Bicuculline blocks circadian phase delays but not advances

Phase delays of hamster locomotor rhythms, which normally can be produced by light pulses given in the early subjective night, were blocked by bicuculline, a selective antagonist of gamma-aminobutyric acid (GABA) activity. Phase advances induced by light pulses given in the late subjective night were unaffected by bicuculline. This suggests that GABA may be involved in the mediation of some, but not all, light input to the mammalian circadian system. Furthermore, it raises the possibility that light input may be mediated at different circadian time points by functionally separate pathways.