Coupling-induced synchronization in multicellular circadian oscillators of mammals

In mammals, circadian rhythms are controlled by the neurons located in the suprachiasmatic nucleus (SCN) of the hypothalamus. Each neuron in the SCN contains an autonomous molecular clock. The fundamental question is how the individual cellular oscillators, expressing a wide range of periods, interact and assemble to achieve phase synchronization. Most of the studies carried out so far emphasize the crucial role of the periodicity imposed by the light-dark cycle in neuronal synchronization. However, in natural conditions, the interaction between the SCN neurons is non-negligible and coupling between cells in the SCN is achieved partly by neurotransmitters. In this paper, we use a model of nonidentical, globally coupled cellular clocks considered as Goodwin oscillators. We mainly study the synchronization induced by coupling from an analytical way. Our results show that the role of the coupling is to enhance the synchronization to the external forcing. The conclusion of this paper can help us better understand the mechanism of circadian rhythm.     

Phase shifts in circadian peripheral clocks caused by exercise are dependent on the feeding schedule in PER2::LUC mice

Circadian rhythms are regulated by the suprachiasmatic nucleus (SCN) clock, which is the main oscillator and peripheral clock. SCN clock can be entrained by both photic and non-photic stimuli, and an interaction exists between photic and non-photic entrainment. Moreover, peripheral circadian clocks can be entrained not only by scheduled restricted feeding, but also by scheduled exercise. Thus, the entrainment of peripheral circadian clocks may be the result of an interaction between the entrainment caused by feeding and exercise. In this study, we examined the effect of wheel-running exercise on the phase of the peripheral clocks (kidney, liver and submandibular gland) in PER2::LUC mice under various feeding schedules. Phase and waveforms of the peripheral clocks were not affected by voluntary wheel-running exercise. Exercise for a period of 4 h during the early dark period (morning) delayed the peripheral clocks, while exercise for the same duration during the late dark period (evening) advanced the peripheral clocks. The feeding phase was advanced and delayed by evening and morning exercise, respectively, suggesting that the feeding pattern elicited by the scheduled exercise may entrain the peripheral clocks. Exercise did not affect the phase of the peripheral clock under the 1 meal per day schedule. When the phase of the peripheral clocks was advanced by the feeding schedule of 2 or 4 meals per day during light and/or dark periods, wheel-running exercise during the morning period significantly and equally shifted the phase of all organs back to the original positions observed in mice maintained under free-feeding conditions and with no exercise. When the schedule of 2 meals per day during the dark period failed to affect the phase of peripheral clock, morning exercise did not affect the phase. Wheel-running exercise increased the levels of serum corticosterone, and the injection of dexamethasone/corticosterone instead of exercise shifted a phase that had advanced under the feeding schedule of 2 meals per day, back to the normal position. The liver and submandibular glands exhibit higher sensitivity to dexamethasone than the kidneys. In adrenalectomized mice, treadmill-induced normalization of the advanced phase under a feeding schedule of 2 meals per day was not observed. In summary, scheduled exercise-induced phase shifts were weaker compared to scheduled feeding-induced phase shifts. The phase advance caused by the feeding schedule of 2 or 4 meals per day was suppressed by wheel-running, treadmill exercise or dexamethasone/corticosterone injection in the early dark period (morning). Corticosterone release may be involved in exercise-induced phase shift of peripheral clocks. These results suggest that there is an interaction between the phase shifts caused by feeding and exercise schedules in peripheral clocks.     

Impaired daily glucocorticoid rhythm in Per1 Brd mice

Biological clocks have evolved in all kinds of organisms in order to anticipate and adjust to the daily light–dark cycle. Within the last decade, the molecular machinery underlying the circadian system was unraveled. In the present study, the impact of the loss of the Per1 or Per2 genes, key components of the core clock oscillator, on body mass, food and water intake, glucose metabolism, and hypothalamic-pituitary-adrenal axis, was investigated in the Per1 ^Brd and Per2 ^Brd mouse models. The results reveal that the lack of Per1 but not Per2 has severe consequences for the regulation of these parameters. Specifically, in Per1 ^Brd animals, we found an impaired daily glucocorticoid rhythm, with markedly elevated levels during the day compared to control animals. In addition, Per1 ^Brd mice showed significant differences in body mass as well as food and water intake. Although the Per1 ^Brd are lighter than wildtype mice, food and water intake per gram body mass is elevated. In addition, the Per1 ^Brd mice exhibit an increased glucose metabolism after i.p. injection with glucose. In conclusion, our study presents first evidence for a link between an altered metabolism in Per1 and Per2 deficient mice, which in the case of the Per1 ^Brd animals might be due to an impaired corticosterone rhythm.     

生物钟基因PER2在结直肠癌中的表达及意义

目的:探讨PER2基因表达水平和结直肠癌发生发展的关系。方法:收集203例在上海市第一人民医院接受根治性肠切除术结直肠癌患者的标本,通过实时定量PCR和免疫组织化学技术检测PER2在肿瘤组织和邻近正常组织中的表达水平,并对PER2的表达与患者的病理资料和临床预后的相关性进行统计学分析。结果:PER2在结直肠患者肿瘤组织的表达较正常组织减少(P0.001)。与PER2阳性患者相比,PER2阴性的结直肠癌患者有远处转移(P=0.026)、AJCC分期为IV期(P=0.011)的比例更高。结论:PER2基因在结直肠癌患者中存在低表达现象,其对于患者的AJCC分期评价以及了解患者有无远处转移有一定的参考价值。     

人外周血淋巴细胞核心钟基因Clock和Bmal1的昼夜节律性表达

探讨自然光制下正常成年人外周血淋巴细胞钟基因Clock和Bmal1的昼夜节律性表达。用实时定量RT-PCR方法,测定不同昼夜时点(ZT)受试者外周血淋巴细胞总RNA中核心钟基因Clock和Bmal1的mRNA表达量,通过余弦法和Clock Lab软件获取节律参数,并经振幅检验分析是否存在昼夜节律。结果发现正常成年人外周血淋巴细胞钟基因Clock和Bmal1的mRNA表达呈昼夜节律性振荡(P0.05),Clock的峰时和谷时分别位于ZT13和ZT1,Bmal1的峰时和谷时分别位于ZT12和ZT24;两个基因在所检测的各个昼夜时点中表达水平均有明显差异(P0.05),Bmal1的表达水平较Clock降低;二者表达的峰值相位、振幅、峰时和谷时相一致(P0.05),但Bmal1转录的中值水平以及峰时mRNA水平和谷时mRNA水平降低(P0.05)。提示正常成年人外周血淋巴细胞钟基因Clock和Bmal1的表达存在同步化的昼夜节律性转录特征。     

Impaired expression of the mPer2 circadian clock gene in the suprachiasmatic nuclei of aging mice

The expression of circadian clock genes was investigated in the suprachiasmatic nuclei (SCN) of young adult and old laboratory mice. Samples were taken at two time points, which corresponded to the expected maximum (circadian time 7 [CT7]) or minimum (CT21) of mPer mRNA expression. Whereas the young mice had a stable and well-synchronized circadian activity/rest cycle, the rhythms of old animals were less stable and were phase advanced. The expression of mPer1 mRNA and mPer2 mRNA was rhythmic in both groups, with peak values at CT7. The levels of mClock and mCry1 mRNA were not different depending on the time of day and did not vary with age. In contrast, an age-dependent difference was found in the case of mPer2 (but not mPer1) mRNA expression, with the maximum at CT7 significantly lower in old mice. The decreased expression of mPer2 may be relevant for the observed differences in the overt activity rhythm of aged mice. (Chronobiology International, 18(3), 559-565, 2001)     

The impact of prenatal circadian rhythm disruption on pregnancy outcomes and long-term metabolic health of mice progeny

Animal studies demonstrate that circadian rhythm disruption during pregnancy can be deleterious to reproductive capacity and the long-term health of the progeny. Our previous studies in rats have shown that exposure of pregnant dams to an environment that significantly disrupts maternal circadian rhythms programs increased adiposity and poor glucose metabolism in offspring. In this study, we used mice with a ClockΔ19 mutation to determine whether foetal development within a genetically disrupted circadian environment affects pregnancy outcomes and alters the metabolic health of offspring. Ten female ClockΔ19+MEL mutant mice were mated with 10 wildtype males, and 10 wildtype females were mated with 10 ClockΔ19+MEL mutant males. While genetically identical, the heterozygote foetuses were exposed to either a normal (wildtype dams) or disrupted (ClockΔ19+MEL mutant dams) circadian environment during gestation. Pregnancy outcomes including time to mate, gestation length, litter size and birth weight were assessed. One male and one female offspring from each litter were assessed for postnatal growth, body composition, intraperitoneal glucose tolerance test and intraperitoneal insulin tolerance test at 3 and 12 months of age. There was no effect of maternal genotype on pregnancy outcomes, with days to plug, gestation length, litter size and perinatal mortality not significantly different between wildtype and ClockΔ19+MEL mutant dams. Similarly, there was no effect of maternal genotype on weight of the offspring at birth or at any stage of postnatal growth. While there was an effect of sex on various tissue weights at 3 and 12 months of age, there were minimal effects of maternal genotype. Relative adrenal weight was significantly reduced (?32%) in offspring from ClockΔ19+MEL mutant dams, whereas gastrocnemius muscle was significantly increased (+16%) at 3 months of age only. Intraperitoneal glucose tolerance tests at 3 months of age revealed female offspring from ClockΔ19+MEL mutant dams had significantly reduced area under the curve following glucose administration (?25%), although no differences were found at 12 months of age. There was no effect of maternal genotype on intraperitoneal insulin tolerance at 3 or 12 months of age for either sex. These results demonstrate that foetal growth within a genetically disrupted circadian environment during gestation has no effect on pregnancy success, and only marginal impacts upon the long-term metabolic health of offspring. These results do not support the hypothesis that circadian rhythm disruption during pregnancy programs poor metabolic homeostasis in offspring. However, when maintained on a 12L:12D photoperiod, the ClockΔ19+MEL mutant dams display relatively normal patterns of activity and melatonin secretion, which may have reduced the impact of the mutation upon foetal metabolic programming.     

Evaluation of the circadian profile of peripheral plasma galanin concentrations in normal subjects

Galanin administration can influence pituitary function principally resulting in an increase in GH secretion. However, the role of circulating GAL levels in human endocrine function is still unknown. In the present study we simultaneously measured the circadian profiles of GAL, ACTH and GH in peripheral blood of ten adult subjects. Plasma samples were collected through an intravenous catheter at 0800, 1200, 1600, 2000, 2200, 2400, 0200, 0400 hours. The results were statistically evaluated by the cosinor analysis technique. A significant circadian rhythm of both plasma ACTH (p < 0.001) and GH levels (p < 0.03) was found with acrophases occurring at 0753 hrs and 0131 hrs for ACTH and GH, respectively. On the contrary, no significant rhythm was found in plasma GAL levels, indicating that no correlations exist between GAL and either GH or ACTH circadian profiles. Furthermore, the simultaneous assay of both GAL and GH plasma levels during a nocturnal frequent sampling performed in four volunteers showed the presence of peaks in GAL levels which, however, were not concomitant to the peaks in GH levels. These data demonstrate the lack of rhythmicity in the circadian profile of plasma GAL levels in healthy human subjects. The role of GAL in human endocrine function remains unknown and these results suggest that, in spite of the well documented increase in plasma GH concentrations following the intravenous administration of GAL, physiologically circulating levels of GAL are likely not involved in the regulation of GH secretion.     

The Circadian Clock Machinery During Early Development of Senegalese sole (Solea senegalensis): Effects of Constant Light and Dark Conditions

Circadian rhythms are established very early during vertebrate development. In fish, environmental cues can influence the initiation and synchronization of different rhythmic processes. Previous studies in zebrafish and rainbow trout have shown that circadian oscillation of clock genes represents one of the earliest detectable rhythms in the developing embryo, suggesting their significance in regulating the coordination of developmental processes. In this study, we analyzed the daily expression of the core clock components Per1, Per2, Per3, and Clock during the first several days of Senegalese sole development (0–4 d post fertilization or dpf) under different lighting regimes, with the aim of addressing when the molecular clock first emerges in this species and how it is affected by different photoperiods. Rhythmic expression of the above genes was detected from 0 to 1 dpf, being markedly affected in the next few days by both constant light (LL) and dark (DD) conditions. A gradual entrainment of the clock machinery was observed only under light-dark (LD) cycles, and robust rhythms with increased amplitudes were established by 4 dpf for all clock genes currently studied. Our results show the existence of an embryonic molecular clock from the 1st d of development in Senegalese sole and emphasize the significance of cycling LD conditions when raising embryos and early larvae. (Author correspondence: munoz.cueto@uca.es; carlos.pendon@uca.es)     

Clock polymorphisms and circadian rhythms phenotypes in a sample of the Brazilian population

A Clock polymorphism T to C situated in the 3' untranslated region (3'-UTR) has been associated with human diurnal preference. At first, Clock 3111C had been reported as a marker for evening preference. However these data are controversial, and data both corroborating and denying them have been reported. This study hypothesizes that differences in Clock genotypes could be observed if extreme morning-type subjects were compared with extreme evening-type subjects, and the T3111C and T257G polymorphisms were studied. The possible relationship between both polymorphisms and delayed sleep phase syndrome (DSPS) was also investigated. An interesting and almost complete linkage disequilibrium between the polymorphisms T257G in the 5' UTR region and the T3111C in the 3' UTR region of the Clock gene is described. Almost always, a G in position 257 corresponds to a C in position 3111, and a T in position 257 corresponds to a T in position 3111. The possibility of an interaction of these two regions in the Clock messenger RNA structure that could affect gene expression was analyzed using computer software. The analyses did not reveal an interaction between those two regions, and it is unlikely that this full allele correspondence affects Clock gene expression. These results show that there is no association between either polymorphism T3111C or T257G in the Clock gene with diurnal preference or delayed sleep phase syndrome (DSPS). These controversial data could result from the possible effects of latitude and clock genes interaction on circadian phenotypes.