Circadian rhythms in epidermal mitotic activity

Virchows Archiv B Cell Pathology - Circadian variations in mitotic index, mitotic rate (cells entering mitosis per hour) and mitotic duration were investigated in the epidermis of the back and ear...     

Circadian rhythms in the retina of rats with photoreceptor degeneration

Previous studies have demonstrated that the mammalian retina contains a circadian clock system that controls several retinal functions. In mammals the location of the retinal circadian clock is unknown whereas, in non-mammalian vertebrates, earlier work has demonstrated that photoreceptor cells contain the circadian clock. New experimental evidence has suggested that in mammals the retinal circadian clock may be located outside the photoreceptor cells. In this study we report that circadian rhythms in Aa-nat mRNA (in vivo) and melatonin synthesis (in vitro) are still present in the retina of rats lacking photoreceptors. The circadian pacemaker(s) controlling such rhythms is probably located in kainic acid sensitive neurons in the inner retina since kainic acid injections abolished the rhythmicity. These data are the first direct demonstration that circadian rhythmicity in the mammalian retina can be generated independently from the photoreceptors and the suprachiasmatic nuclei of the hypothalamus.     

Circadian rhythms of feeding and drinking behavior of rats aged from 3 to 21 months

Circadian rhythms and patterns of feeding and drinking behavior of 8 male and 8 female Long-Evans rats were followed from 3 months of age (mo) to 21 mo at 3 month intervals. Meal number, draft number and feeding events/min/meal of female rats were greater than those of male rats of the same age, while intermeal intervals, interdraft intervals and licking events/min/draft of male rats were greater than those of female rats. Sex differences of meal number, intermeal intervals and feeding events/min/meal as a group disappeared by 21 mo. Light/dark differences of meal number of both sexes, intermeal intervals of females and licking events/min/draft of males as a group also disappeared by 21 mo and difference of feeding events/min/meal disappeared by 15 and 18 mo in males and females, respectively. Occurrence of age-related change varied from 6 to 21 mo depending upon the parameter of the behavior and period (light or dark). Meal number and feeding events/min/meal showed the most clear-cut age-related changes and the decline occurred earlier and was more remarkable in males than in females. The age-related decline of patterns and the power spectrum of drinking behavior was less prominent than that of feeding behavior. These results indicate that feeding behavior is more affected by the aging process than is the drinking behavior of rats, and that male rats show more prominent aging changes than females.(ABSTRACT TRUNCATED AT 250 WORDS)     

Circadian rhythms of photorefractory siberian hamsters remain responsive to melatonin

Short day lengths increase the duration of nocturnal melatonin (Mel) secretion, which induces the winter phenotype in Siberian hamsters. After several months of continued exposure to short days, hamsters spontaneously revert to the spring-summer phenotype. This transition has been attributed to the development of refractoriness of Mel-binding tissues, including the suprachiasmatic nucleus (SCN), to long-duration Mel signals. The SCN of Siberian hamsters is required for the seasonal response to winter-like Mel signals, and becomes refractory to previously effective long-duration Mel signals restricted to this area. Acute Mel treatment phase shifts circadian locomotor rhythms of photosensitive Siberian hamsters, presumably by affecting circadian oscillators in the SCN. We tested whether seasonal refractoriness of the SCN to long-duration Mel signals also renders the circadian system of Siberian hamsters unresponsive to Mel. Males manifesting free-running circadian rhythms in constant dim red light were injected with Mel or vehicle for 5 days on a 23.5-h T-cycle beginning at circadian time 10. Mel injections caused significantly larger phase advances in activity onset than did the saline vehicle, but the magnitude of phase shifts to Mel did not differ between photorefractory and photosensitive hamsters. Similarly, when entrained to a 16-h light/8-h dark photocycle, photorefractory and photosensitive hamsters did not differ in their response to Mel injected 4 h before the onset of the dark phase. Activity onset in Mel-injected hamsters was masked by light but was revealed to be significantly earlier than in vehicle-injected hamsters upon transfer to constant dim red light. The acute effects of melatonin on circadian behavioral rhythms are preserved in photorefractory hamsters.     

Circadian rhythms of locomotor activity in Drosophila

Drosophila is by far the most advanced model to understand the complex biochemical interactions upon which circadian clocks rely. Most of the genes that have been characterized so far were isolated through genetic screens using the locomotor activity rhythms of the adults as a circadian output. In addition, new techniques are available to deregulate gene expression in specific cells, allowing to analyze the growing number of developmental genes that also play a role as clock genes. However, one of the major challenges in circadian biology remains to properly interpret complex behavioral data and use them to fuel molecular models. This review tries to describe the problems that clockwatchers have to face when using Drosophila activity rhythms to understand the multiple facets of circadian function.     

Circadian rhythms in rat brain alpha- and beta-adrenergic receptors are modified by chronic imipramine

Circadian rhythms of α- and ß-adrenergic receptor number, with different wave forms, as well as differences in timing of maximal binding, are present in rat brain. Chronic treatment with the tricyclic antidepressant drug imipramine modifies these rhythms: peak binding of both receptors occurs 4–12 hours later than in controls, the 24-hour mean is decreased by 15–30%, and the amplitude is increased by 20–30%. Delaying of the phase position of neurotransmitter receptor rhythms by a tricyclic antidepressant may be relevant to its clinical mode of action, since depressive patients appear to have abnormally phase-advanced circadian rhythms.     

Circadian rhythm of circulating corticosterone and urinary excretion of catecholamines, serotonin and their catabolites in rats treated with imipramine

The circadian rhythm of serum corticosterone was assessed in rats entrained to a 12:12 LD cycle and treated with tricyclic imipramine (25 mg/kg/day) via osmotic pumps for a period of 14 days; urinary excretion of catecholamines, serotonin and their catabolites was also assessed. We observed that imipramine did not modify the phase position of the corticosterone rhythm but rather lowered the animal's responsiveness as shown by the lower peak of corticosterone at 2000 and by the smaller amplitude of its circadian rhythm; moreover imipramine had no effect on urinary excretion of catecholamines, serotonin and their catabolites during LD cycle.     

Entrainment of split circadian activity rhythms in hamsters

Hamsters that showed splitting of their circadian rhythms of wheel-running activity following long-term exposure to constant illumination (LL) were exposed to light-dark (LD) cycles with 2-hr dark segments, and with periods of 24.00, 24.23 or 24.72 hr. For comparison, hamsters showing nonsplit rhythms were also studied. In all cases of split rhythms, at least one of the two split components entrained to the LD cycles. In some animals, the second component continued to free-run until it merged with the entrained component, while in others, the second component also entrained to the LD cycle but maintained a stable phase angle of 6-14.5 hr relative to dark onset. These results were obtained in cases where the period of the LD cycle was shorter than that of the split rhythms and in cases where it was longer, implying that split components can be phase-advanced as well as phase-delayed by 2 hr of darkness. Three hamsters that showed stable entrainment of split rhythms were allowed to free-run in LL. The LD cycles were then reinstated, but instead of overlapping with the first component, as it did before, the dark segment was timed to overlap with the second. The entrainment patterns that ensued were similar to the ones obtained during the first LD exposure, indicating that the two split components respond to darkness in a qualitatively similar fashion. These results are further evidence that the pacemaker system underlying split circadian activity rhythms in hamsters is composed of two mutually coupled populations of oscillators that have similar properties, including a bidirectional phase response curve. Such a dual-oscillator organization may also underlie normal, or nonsplit, activity rhythms, as suggested by Pittendrigh and Daan (1976c), but the data are also compatible with the alternative view that the circadian pacemaker consists of a large number of coupled oscillators, which only dissociate into two separate populations in some animals under conditions of moderate LL intensity.     

Circadian and seasonal rhythms in the radiosensitivity of mongrel white rats

From experiments in albino mongrel rats it is shown that the radiosensitivity of gamma-irradiated (60Co) animals follows a daily rhythm. A synchronization of the daily rhythms in radiosensitivity was noted in winter and during the first spring month which was impaired in April. Established were the rhythms of radiosensitivity for three seasons, i. e. winter, spring and summer, with the extremes in the dependence upon mean annual values varying significantly.     

内蒙古草原小毛足鼠的活动性、代谢特征和体温的似昼夜节律

小毛足鼠(Phodopus roborovskii)是分布在内蒙古草原沙地的一种小型哺乳动物,关于其生物学和生态学特征,尤其是生理学特征还知之甚少。似昼夜节律是动物行为学和生理生态学中备受关注的一个领域。在室内条件下通过体内埋置无线电传感器连续监测小毛足鼠的体温、用自动监测系统连续监测活动性和TSE LabMaster呼吸代谢测定系统连续测定了其代谢率的昼夜节律性。结果发现:小毛足鼠在夜间的平均体温是(37.27±0.39)℃,昼间的平均体温是(36.11±0.18)℃;在夜间的平均代谢率是(4.65±1.10)mLO2·g-1·h-1,昼间的平均代谢率是(3.09±0.42)mLO2·g-1·h-1;在夜间的平均活动率为(237±145)次/0.1h,昼间的平均活动率为(38±5)次/0.1h。小毛足鼠的代谢率、活动性和体温的峰值相位主要集中在夜间,属典型的夜行性动物。实验结果从行为学特性和生理学特征等新的角度支持了野外观察小毛足鼠是夜行性动物的推断。综合活动性、代谢率和体温三方面同步变化的特征,为小毛足鼠的似昼夜节律变化提供了新的机理性解释。研究也表明小毛足鼠是研究野生动物似昼夜节律变化机理的好模型。     

Circadian rhythms of self-selected lighting in golden hamsters: relation to gonadal condition

Golden hamster (20 males, 8 females) were maintained in isolation boxes for 4-7 weeks. The animals had access to wheels and selected their own lighting by pressing one bar to turn light-on and another bar to turn the light-off. All hamsters maintained circadian rhythms of wheel-running activity. Seventeen of 28 hamsters selected lighting with a circadian periodicty. For 9 hamsters, there was a significant positive correlation between wheel-running activity and self-selected darkness, while this correlation was significantly negative for 10 hamsters. Four hamsters had regressed testes at the end of the experiment. These 4 had significant positive correlations between activity and self-selected darkness, while none of the hamsters with significant negative correlations between activity and self-selected darkness had regressed testes. Light in phase with activity seems to be more important to the prevention of testicular regression than is the total daily amount of light.     

Circadian rhythms of demand-feeding and locomotor activity in rainbow trout

Under free-running conditions, most rainbow trout displayed circadian feeding rhythms, although the expression of circadian rhythmicity depended on the experimental condition: 16·7% of fish under constant dim light (LL dim), 66·1% under a 45 :45 min light-dark cycle (LD pulses), and 83·8% under constant light (LL). Under LD pulses, the period length of the free-running rhythms for feeding was significantly shorter (21·9 ± 0·7 h, n =8) than under LL (26·2 ± 0·3 h, n =10). Period length for locomotor activity under LL was 25·8 ± 0·6 h ( n =4). Under LD conditions, the daily demand-feeding profile was always confined to the light phase and chiefly composed of two main episodes, directly after lights on (light elicited) and in anticipation to lights off (endogenous). Contrasting to feeding, the diel locomotor activity profile varied remarkably: a diurnal activity pattern at the bottom, while a clearly nocturnal pattern at the surface. These results contribute to a better understanding of feeding and locomotor rhythms of rainbow trout, providing evidence for the existence of a biological clock involved in their circadian control. This finding contrasts with the previously recorded lack of an endogenous oscillator in the pineal organ driving the rhythmic secretion of melatonin, which suggests different locations from the pineal for the circadian pacemakers in this species.     

Masking of circadian activity rhythms in hamsters by darkness

Summary Wheel-running activity was recorded in male golden hamsters (Mesocricetus auratus) kept in constant dim illumination. For periods of several weeks the lights in the cabinet were turned off daily at the same time of day, either for 1 h or 2 h. Despite these periodically recurring dark pulses, the circadian activity rhythms continued to free-run, and consequently crossed through the pulses at a more or less regular speed. During a dark pulse, the activity was usually enhanced. The amount of these masking effects varied with the phase of the circadian cycle at which the pulse occurred. The responses were maximal a few hours after the onset of spontaneous activity, and minimal during the rest-time of the animal.     

Circadian rhythms of indoleamines and serotonin N-acetyltransferase activity in the pineal gland

Conclusion The circadian rhythm of melatonin synthesis in the pineal glands of various species has been summarized. The night-time elevation of melatonin content is in most if not all cases regulated by the change of N-acetyltransferase activity. In mammals, the N-acetyltransferase rhythm is controlled by the central nervous system, presumably by suprachiasmatic nuclei in hypothalamus through the superior cervical ganglion. In birds, the circadian oscillator that regulates the N-acetyltransferase rhythm is located in the pineal glands. The avian pineal gland may play a biological clock function to control the circadian rhythms in physiological, endocrinological and biochemical processes via pineal hormone melatonin.