Forced desynchronization model for a diurnal primate

The circadian system is organized in a hierarchy of multiple oscillators, with the suprachiasmatic nucleus (SCN) as the master oscillator in mammals. The SCN is formed by a group of coupled cell oscillators. Knowledge of this coupling mechanism is essential to understanding entrainment and the expression of circadian rhythms. Some authors suggest that light-dark (LD) cycles with periods near the limit of entrainment may be good models for promoting internal desynchronization, providing knowledge about the coupling mechanism. As such, we evaluated the circadian activity rhythm (CAR) pattern of marmosets in LD cycles at lower limits of entrainment in order to study induced internal dissociation. To that end, two experiments were conducted: (1) 6 adult females were under symmetrical LD cycles T21, T22 and T21.5 for 60, 35 and 48 days, respectively; and (2) 4 male and 4 female adults were under T21 for 24 days followed by 18 days of LL, back to T21 for 24 days, followed by 14 days of LL. The CAR of each animal was continuously recorded. In experiment 1, vocalizations were also recorded. Under Ts shorter than 24 days, a dissociation pattern was observed for CAR and vocalizations. Two simultaneous circadian components emerged, one with the same period as the LD cycle, called the light-entrained component, and the other in free-running, denominated the non-light-entrained component. Both components were displayed in the CAR for all the animals in T21, five animals (83.3%) in T21.5 and two animals (33.3%) in T22. Our results are in accordance with the multioscillatory nature of the circadian system. Dissociation is partial synchronization to the LD cycle, with at least one group of oscillators synchronized by relative coordination and masking, while another group of oscillators free runs, but is also masked by the LD cycle. Since only T21 promoted the emergence of both circadian components in the circadian rhythms of all marmosets, it was considered the promoter period of circadian rhythm dissociation in this species, and is proposed as a good animal model for forced desynchronization in non-human diurnal primates.     

A Noradrenergic Mechanism Influences the Circadian Timing System in Rats and Hamsters

Brainstem monoaminergic projections to the suprachiasmatic nucleus (SCN), and to the intergeniculate leaflet (IGL), appear to modulate both photic and non-photic effects on the circadian system. Recent work in this laboratory has concentrated on the role of noradrenaline in the regulation of circadian period and phase. Previously, this lab has shown that chronic administration of the alpha₂ adrenergic agonist, clonidine, to rats maintained in constant light (LL) shortens free-running circadian period and promotes dissociation of rhythmicity, while acute clonidine administration to hamsters produces phase shifts similar to those observed with photic stimuli. These results suggest an interaction between clonidine and photic input on circadian rhythmicity, and so the present study was designed to examine systematically the relationship between chronic clonidine administration and photic input in both rats and hamsters. In DD and low intensity LL, clonidine did not alter free-running circadian wheel-running rhythms of rats, but under moderate to high intensity LL, clonidine significantly reduced the period-lengthening effects of LL. Chronic clonidine administration also altered several aspects of circadian phase in hamsters; phase shifts in response to light pulses of varying intensity at CT 19 were reduced; steady-state entrainment phase under a 24-h light-dark cycle (LD 14:10)was delayed; and synchronization to a 23-h light-dark cycle (LD 13:10) was impaired. Clonidine appeared to have little effect on free-running period of hamsters, but a trend towards dissociation of rhythmicity under LL was observed. These effects may reflect an action of clonidine at the photic input pathways to the circadian system, or directly at the circadian pacemaker, since alpha 2 adrenoceptors have been localized both in the suprachiasmatic nucleus (SCN) and in several of its projection areas. As both clinical and experimental studies suggest that clonidine may have depressogenic properties, chronic administration of clonidine to rodents may provide an animal model of the alterations in circadian rhythmicity seen in human depression.     

A Noradrenergic Mechanism Influences the Circadian Timing System in Rats and Hamsters

Brainstem monoaminergic projections to the suprachiasmatic nucleus (SCN), and to the intergeniculate leaflet (IGL), appear to modulate both photic and non-photic effects on the circadian system. Recent work in this laboratory has concentrated on the role of noradrenaline in the regulation of circadian period and phase. Previously, this lab has shown that chronic administration of the alpha₂ adrenergic agonist, clonidine, to rats maintained in constant light (LL) shortens free-running circadian period and promotes dissociation of rhythmicity, while acute clonidine administration to hamsters produces phase shifts similar to those observed with photic stimuli. These results suggest an interaction between clonidine and photic input on circadian rhythmicity, and so the present study was designed to examine systematically the relationship between chronic clonidine administration and photic input in both rats and hamsters. In DD and low intensity LL, clonidine did not alter free-running circadian wheel-running rhythms of rats, but under moderate to high intensity LL, clonidine significantly reduced the period-lengthening effects of LL. Chronic clonidine administration also altered several aspects of circadian phase in hamsters; phase shifts in response to light pulses of varying intensity at CT 19 were reduced; steady-state entrainment phase under a 24-h light-dark cycle (LD 14:10)was delayed; and synchronization to a 23-h light-dark cycle (LD 13:10) was impaired. Clonidine appeared to have little effect on free-running period of hamsters, but a trend towards dissociation of rhythmicity under LL was observed. These effects may reflect an action of clonidine at the photic input pathways to the circadian system, or directly at the circadian pacemaker, since alpha 2 adrenoceptors have been localized both in the suprachiasmatic nucleus (SCN) and in several of its projection areas. As both clinical and experimental studies suggest that clonidine may have depressogenic properties, chronic administration of clonidine to rodents may provide an animal model of the alterations in circadian rhythmicity seen in human depression.     

Entrainment of the master circadian clock by scheduled feeding

The master circadian clock, located in the mammalian suprachiasmatic nuclei (SCN), generates and coordinates circadian rhythmicity, i.e., internal organization of physiological and behavioral rhythms that cycle with a near 24-h period. Light is the most powerful synchronizer of the SCN. Although other nonphotic cues also have the potential to influence the circadian clock, their effects can be masked by photic cues. The purpose of this study was to investigate the ability of scheduled feeding to entrain the SCN in the absence of photic cues in four lines of house mouse (Mus domesticus). Mice were initially housed in 12:12-h light/dark cycle with ad libitum access to food for 6 h during the light period followed by 4-6 mo of constant dark under the same feeding schedule. Wheel running behavior suggested and circadian PER2 protein expression profiles in the SCN confirmed entrainment of the master circadian clock to the onset of food availability in 100% (49/49) of the line 2 mice in contrast to only 4% (1/24) in line 3 mice. Mice from line 1 and line 4 showed intermediate levels of entrainment, 57% (8/14) and 39% (7/18), respectively. The predictability of entrainment vs. nonentrainment in line 2 and line 3 and the novel entrainment process provide a powerful tool with which to further elucidate mechanisms involved in entrainment of the SCN by scheduled feeding.     

Vasopressin deficiency provides evidence for separate circadian oscillators of activity and temperature

Vasopressin-containing Long-Evans and vasopressin-deficient Brattleboro rats were maintained in individual cages while telemetered activity (AC) and body temperature (BT) data were collected. Rats were initially exposed to a 12 h/12-h light/dark cycle (photic zeitgeber) and were allowed ad-libitum access to food and water. Daily feeding, care, and handling (nonphotic zeitgebers) occurred at the beginning of the second hour of the dark cycle. After a 14-day habituation period, rats were subjected to continuous light (LL) or dark (DD) and nonphotic cues were presented irregularly. During the habituation period, both strains exhibited clear 24-h circadian rhythms of AC and BT. In LL or DD, photic cues were removed and nonphotic cues were presented irregularly. There was a shift in the rhythm for Long-Evans animals to 26 h for both AC and BT in LL and 24.6 h in DD. Feeding, care, and handling were seen as minor artifact. In Brattleboro rats, although there were robust 26-h and 24.6-h circadian rhythms of AC in the LL and DD, respectively, BT data were inconsistent and showed sporadic fluctuations. In the BT rhythm of Brattleboro animals, strong peaks were associated with feeding, care, and handling times and trough periods were characterized by a dramatic drop in temperature. This experiment demonstrates that AC and BT are controlled by separate oscillators. In addition, the importance of vasopressinergic fibers in the control of circadian rhythms of BT is evidenced by the loss of circadian rhythms in animals lacking these functional fibers when exposed to free-running paradigms where there is no entrainment of photic or nonphotic oscillators.     

Photic entrainment is altered in the 5-HT1B receptor knockout mouse

The hypothalamic suprachiasmatic nucleus (SCN) is a circadian oscillator that receives glutamatergic afferents from the retina and serotonergic afferents from the midbrain. Activation of presynaptic serotonin 1B (5-HT1B) receptors on retinal terminals in the SCN inhibits retinohypothalamic neurotransmission and light-induced behavioral phase shifts. To assess the role of 5-HT1B receptors in photic entrainment, 5-HT1B receptor knockout (5-HT1B KO) and wild-type (WT) mice were maintained in non-24 h L:D cycles (T cycles). WT mice entrained to T = 21 h and T = 22 h cycles, whereas 5-HT1B KO animals did not. 5-HT1B KO animals did entrain to T = 23 h and T = 26 h cycles, although their phase angle of entrainment was altered compared to WT animals. 5-HT1B KO mice were significantly more phase delayed under T = 23 h conditions and significantly more phase advanced under T = 26 h conditions compared to WT mice. When 5-HT1B KO mice were housed in a T = 23 h short-day photoperiod (9.5L:13.5D), the delayed phase angle of entrainment was more pronounced. Light-induced phase shifts were reduced in 5-HT1B KO mice, consistent with their behavior in T cycles, suggesting an attenuated response to light. Based on previous work, this attenuated response to light might not have been predicted but can be explained by consideration of GABAergic mechanisms within the SCN. Phase-delayed circadian rhythms during the short days of winter are characteristic of patients suffering from seasonal affective disorder, and 5-HT has been implicated in its pathophysiology. The 5-HT1B KO mouse may be useful for investigating the altered entrainment evident during this serious mood disorder.     

Effects of photoperiod on rat motor activity rhythm at the lower limit of entrainment

The experiment described here studied the rat motor activity pattern as a function of the photoperiod of circadian light-dark cycles in the limits of entrainment (22-and 23-h periods). In most cases, the overt rhythm showed 2 circadian components: 1 that followed the external LD cycle and a 2nd rhythm that was free run. The expression of these components was directly dependent on the photoperiod, and there was a gradual transition in the manifestation of 1 or the other. The component with a period equal to that of the external cycle was more manifested under long photoperiods, while the other 1 was more expressed during short photoperiods. Also, the period of the free-running component was longer under T22 than T23. For each period, the free-running component was longer under a longer photoperiod. At first sight, the presence of these 2 components in most of the rats might appear to be due to the fact that in the limits of entrainment, some rats do not entrain and thus show a free-running rhythm plus masking. However, the gradation observed in the different patterns of the overt motor activity rhythm, especially those patterns related to the different balance between the 2 components and the length of the period of the free-running component under LD as a function of the photoperiod, suggests that the circadian system can be functionally dissociated.     

Forced desynchronization of dual circadian oscillators within the rat suprachiasmatic nucleus

The circadian clock in the suprachiasmatic nucleus of the hypothalamus (SCN) contains multiple autonomous single-cell circadian oscillators and their basic intracellular oscillatory mechanism is beginning to be identified. Less well understood is how individual SCN cells create an integrated tissue pacemaker that produces a coherent read-out to the rest of the organism. Intercellular coupling mechanisms must coordinate individual cellular periods to generate the averaged, genotype-specific circadian period of whole animals. To noninvasively dissociate this circadian oscillatory network in vivo, we (T.C. and A.D.-N.) have developed an experimental paradigm that exposes animals to exotic light-dark (LD) cycles with periods close to the limits of circadian entrainment. If individual oscillators with different periods are loosely coupled within the network, perhaps some of them would be synchronized to the external cycle while others remain unentrained. In fact, rats exposed to an artificially short 22 hr LD cycle express two stable circadian motor activity rhythms with different period lengths in individual animals. Our analysis of SCN gene expression under such conditions suggests that these two motor activity rhythms reflect the separate activities of two oscillators in the anatomically defined ventrolateral and dorsomedial SCN subdivisions. Our "forced desychronization" protocol has allowed the first stable separation of these two regional oscillators in vivo, correlating their activities to distinct behavioral outputs, and providing a powerful approach for understanding SCN tissue organization and signaling mechanisms in behaving animals.     

Spontaneous synchronization of coupled circadian oscillators

In mammals, the circadian pacemaker, which controls daily rhythms, is located in the suprachiasmatic nucleus (SCN). Circadian oscillations are generated in individual SCN neurons by a molecular regulatory network. Cells oscillate with periods ranging from 20 to 28 h, but at the tissue level, SCN neurons display significant synchrony, suggesting a robust intercellular coupling in which neurotransmitters are assumed to play a crucial role. We present a dynamical model for the coupling of a population of circadian oscillators in the SCN. The cellular oscillator, a three-variable model, describes the core negative feedback loop of the circadian clock. The coupling mechanism is incorporated through the global level of neurotransmitter concentration. Global coupling is efficient to synchronize a population of 10,000 cells. Synchronized cells can be entrained by a 24-h light-dark cycle. Simulations of the interaction between two populations representing two regions of the SCN show that the driven population can be phase-leading. Experimentally testable predictions are: 1), phases of individual cells are governed by their intrinsic periods; and 2), efficient synchronization is achieved when the average neurotransmitter concentration would dampen individual oscillators. However, due to the global neurotransmitter oscillation, cells are effectively synchronized.     

Neural mechanisms for entrainment and generation of mammalian circadian rhythms.

The identification of a direct retinohypothalamic tract (RHT) terminating in the supra-chiasmatic nuclei (SCN) has focused attention on the role of these structures in the entrainment and generation of circadian rhythms in mammals. Light effects on circadian rhythms are mediated by both the RHT and portions of the classical visual system. The complex interactions of these systems are reflected both in their direct anatomical connections and in the functional changes in entrainment produced by interruption of either set of projections. Destruction of the RHT/SCN eliminated both normal entrainment and normal free-running circadian rhythms. No circadian rhythms has survived SCN ablation in rodents, but a variety of non-circadian cycles can be generated by lesioned animals. The complex behavioral patterns produced by SCN-lesioned hamsters suggest that circadian oscillators continue to function in these animals, but that their activity is no longer integrated into a single circadian framework. The available evidence indicates that the mammalian pacemaking system comprises a set of independent oscillators normally regulated by the SCN and by light information that is transmitted via several retinofugal pathways.     

Organization and function of a central nervous system circadian oscillator: the suprachiasmatic hypothalamic nucleus

Circadian rhythms in mammals are generated by endogenous neural oscillating systems entrained to the light-dark cycle by specific visual pathways. We conclude from available data that the suprachiasmatic hypothalamic nuclei (SCN) are the principal circadian oscillators in the rodent brain and that a retinohypothalamic projection terminating in the SCN is the primary visual pathway subserving entrainment of circadian rhythms. Recent anatomical studies demonstrate that the SCN have distinct subdivisions in the rat. A dorsomedial component is comprised of a distinct neuronal population and contains a large population of interneurons, many of which produce peptides. It receives no direct or indirect visual input and has only very limited projections outside the SCN. A ventrolateral component is also made up of a distinctive neuronal population, receives both direct and indirect visual projections, and provides the major external projections of the SCN, which are to the hypothalamus, particularly the hypophysiotrophic area. The SCN are viewed in this review as containing multiple, mutually coupled oscillating systems that arise from a developmental process of interconnecting individual neuronal circadian oscillators into circuits that form the oscillating systems. A model for the organization of the systems is presented.     

Light pulses do not induce c-fos or per1 in the SCN of hamsters that fail to reentrain to the photocycle

Circadian activity rhythms of most Siberian hamsters (Phodopus sungorus sungorus) fail to reentrain to a 5-h phase shift of the light-dark (LD) cycle. Instead, their rhythms free-run at periods close to 25 h despite the continued presence of the LD cycle. This lack of behavioral reentrainment necessarily means that molecular oscillators in the master circadian pacemaker, the SCN, were unable to reentrain as well. The authors tested the hypothesis that a phase shift of the LD cycle rendered the SCN incapable of responding to photic input. Animals were exposed to a 5-h phase delay of the photocycle, and activity rhythms were monitored until a lack of reentrainment was confirmed. Hamsters were then housed in constant darkness for 24 h and administered a 30-min light pulse 2 circadian hours after activity onset. Brains were then removed, and tissue sections containing the SCN were processed for in situ hybridization. Sections were probed with Siberian hamster c-fos and per1 mRNA probes because light rapidly induces these 2 genes in the SCN during subjective night but not at other circadian phases. Light pulses induced robust expression of both genes in all animals that reentrained to the LD cycle, but no expression was observed in any animal that failed to reentrain. None of the animals exhibited an intermediate response. This finding is the first report of acute shift in a photocycle eliminating photosensitivity in the SCN and suggests that a specific pattern of light exposure may desensitize the SCN to subsequent photic input.     

Circadian locomotor analysis of male mice lacking the gene for neuronal nitric oxide synthase (nNOS-/-)

Nitric oxide (NO) is an endogenous gas that functions as a neurotransmitter. Because NO is very labile with a half-life of less than 5 sec, most functional studies of NO have manipulated its synthetic enzyme, NO synthase (NOS). Three isoforms of NOS have been identified: (1) in the endothelial lining of blood vessels (eNOS), (2) an inducible form found in macrophages (iNOS), and (3) in neurons (nNOS). Most pharmacological studies to date have blocked all three isoforms of NOS. Previous studies using such agents have revealed that NO might be necessary for photic entrainment of circadian rhythms; general NOS inhibitors attenuate phase shifts of free-running behavior, light-induced c-fos expression in the suprachiasmatic nucleus (SCN), and phase shifts of neural firing activity in SCN maintained in vitro. To assess the specific role of nNOS in mediating entrainment of circadian rhythms, mice with targeted deletion of the gene encoding the neuronal isoform of NOS (nNOS-/-) were used. Wild-type (WT) and nNOS-/- mice initially were entrained to a 14:10 light:dark (LD) cycle. After 3 weeks, the LD cycle was either phase advanced or phase delayed. After an additional 3 weeks, animals were held in either constant dim light or constant dark. WT and nNOS-/- animals did not differ in their ability to entrain to the LD cycle, phase shift locomotor activity, or free run in constant conditions. Animals held in constant dark were killed after light exposure during either the subjective day or subjective night to assess c-fos induction in the SCN. Light exposure during the subjective night increased c-fos expression in the SCN of both WT and nNOS-/- mice relative to animals killed after light exposure during the subjective day. Taken together, these findings suggest that NO from neurons might not be necessary for photic entrainment.     

Circadian organization in male mice lacking the gene for endothelial nitric oxide synthase (eNOS-/-)

Circadian (approximately 24 h) rhythms in physiology and behavior are generated by the bilateral suprachiasmatic nucleus (SCN) of the anterior hypothalamus. For these endogenous rhythms to be synchronized with the external environment, light information must be transmitted to pacemaker cells within the SCN. This transmission of light information is accomplished via a direct retino-hypothalamic tract (RHT). Nitric oxide (NO), an endogenous gas that functions as a neurotransmitter, has been implicated as a messenger necessary for photic entrainment. Three isoforms of the enzyme that form NO, NO synthase, have been identified (a) in neurons (nNOS), (b) in the endothelial lining of blood vessels (eNOS), and (c) as an inducible form in macrophages (iNOS). The present study was undertaken to determine the specific role of eNOS in circadian organization and photic entrainment. Wild-type (WT) and eNOS-/- mice were initially entrained to a 14:10 light:dark (LD) cycle. After 3 weeks, the LD cycle was phase advanced. After an additional 3 weeks, animals were held in constant darkness (DD). eNOS-/- animals did not exhibit a deficit in the ability to entrain to the LD cycle, phase-shift locomotor activity, or free-run in constant conditions. Animals held in DD were killed after light exposure during either the subjective day or the subjective night to assess c-fos induction in the SCN. Light exposure during the subjective night increased c-fos protein expression in the SCN of both WT and eNOS-/- mice relative to animals killed after light exposure during the subjective day. Taken together, these findings suggest that endothelial isoform of NOS may not be necessary for photic entrainment in mice.     

Modeling interactions between photic and nonphotic entrainment mechanisms in transmeridian flights

In transmeridian flights, photic and nonphotic entrainment mechanisms are expected to interact dynamically in the human circadian system. In order to simulate the reentrainment process of the circadian rhythms, the photic entrainment mechanism was introduced to our previous model, which consisted of three coupled oscillators. Regardless of flight direction, a large time difference beyond 10 h tended to induce the antidromic reentrainment. The partition between the oscillators resulted for the eastward flight over a 10-h or longer time difference and the westward over 6 h or longer. The simulated reentrainment processes almost coincided with empirical knowledge. Simulated effects of physical exercise showed that some antidromic reentrainments were switched to the orthodromic ones for the eastward flight and most of the partitions between the oscillators were prevented in the westward flight. These results are due to an augmentation of the entrainment pressure of the rest–activity cycle on the oscillators. The mechanisms underlying these various reentrainment patterns were explained based on the photic response, the interactions between the oscillators, and their adaptive modification. The simulation results suggest that an appropriate selection of departure time and physical exercise could ease the jet lag caused by transmeridian flight.This research was supported by a Grant-In-Aid for Scientific Research from the Ministry of Education, Culture, Sports, Science, and Technology of Japan (Nos. 14015205, 15014204, and 15560372).     

Plasticity of circadian behavior and the suprachiasmatic nucleus following exposure to non-24-hour light cycles

Period aftereffects are a form of behavioral plasticity in which the free-running period of circadian behavior undergoes experience-dependent changes. It is unclear whether this plasticity is age dependent and whether the changes in behavioral period relate to changes in the SCN or the retina, 2 known circadian pacemakers in mammals. To determine whether these changes vary with age, Per1-luc transgenic mice (in which the luciferase gene is driven by the Period1 promoter) of different ages were exposed to short (10 h light: 10 h dark, T20) or long (14 h light: 14 h dark, T28) light cycles (T cycles). Recordings of running-wheel activity in constant darkness (DD) revealed that the intrinsic periods of T20 mice were significantly shorter than of T28 mice at all ages. Aftereffects following the shorter light cycle were significantly smaller in mice older than 3 months, corresponding with a decreased ability to entrain to T20. Age did not diminish entrainment or aftereffects in the 28-h light schedule. The behavioral period of pups born in DD depended on the T cycle experienced in utero, showing maternal transference of aftereffects. Recordings of Per1-luc activity from the isolated SCN in vitro revealed that the SCN of young mice expressed aftereffects, but the periods of behavior and SCN were negatively correlated. Enucleation in DD had no effect on behavioral aftereffects, indicating the eyes are not required for aftereffects expression. These data show that circadian aftereffects are an age-dependent form of plasticity mediated by stable changes in the SCN and, importantly, extra-SCN tissues.     

Reorganization of the suprachiasmatic nucleus coding for day length

In mammals, the suprachiasmatic nucleus (SCN), the circadian pacemaker, receives light information via the retina and functions in the entrainment of circadian rhythms and in phasing the seasonal responses of behavioral and physiological functions. To better understand photoperiod-related alterations in the SCN physiology, we analyzed the clock gene expression in the mouse SCN by performing in situ hybridization and real-time monitoring of the mPer1::luc bioluminescence. Under long photoperiod (LP) conditions, the expression rhythms of mPer1 and Bmal1 in the caudal SCN phase-led those in the rostral SCN; further, within the middle SCN, the rhythms in the ventrolateral (VL)-like subdivision advanced compared with those in the dorsomedial (DM)-like subdivision. The mPer1::luc rhythms in the entire coronal slice obtained from the middle SCN exhibited 2 peaks with a wide peak width under LP conditions. Imaging analysis of the mPer1::luc rhythms in several subdivisions of the rostral, middle, caudal, and horizontal SCN revealed wide regional variations in the peak time in the rostral half of the SCN under LP conditions. These variations were not due to alterations in the waveform of a single SCN neuronal rhythm. Our results indicate that LP conditions induce phase changes in the rhythms in multiple regions in the rostral half of the SCN; this leads to different circadian waveforms in the entire SCN, coding for day length.