Familial longevity is characterized by high circadian rhythmicity of serum cholesterol in healthy elderly individuals

The biological clock, whose function deteriorates with increasing age, determines bodily circadian (i.e. 24h) rhythms, including that of cholesterol metabolism. Dampening of circadian rhythms has been associated with aging and disease. Therefore, we hypothesized that individuals with a familial predisposition for longevity have a higher amplitude circadian serum cholesterol concentration rhythm. The aim of this study was to investigate circadian rhythmicity of serum cholesterol concentrations in offspring of nonagenarian siblings and their partners. Offspring from nonagenarian siblings (n = 19), and their partners as controls (n = 18), were recruited from the Leiden Longevity Study. Participants (mean age 65 years) were studied in a controlled in‐hospital setting over a 24‐h period, receiving three isocaloric meals at 9:00 h, 12:00 h and 18:00 h. Lights were off between 23:00 h and 8:00 h. Serum total cholesterol (TC), HDL cholesterol (HDL‐C), non‐HDL‐C and triglycerides (TG) were determined every 30 min over a 24‐h period. Serum TC concentrations were higher during day than during night in offspring (5.2 vs. 4.7 mm , P < 0.001) and in controls (5.3 vs. 5.0 mm , P < 0.001). The difference in TC concentrations between day and night tended to be greater in offspring than in controls (0.5 vs. 0.3 mm , P = 0.109), reaching statistical significance in females (P = 0.045). Notably, the day–night serum differences in non‐HDL‐C were twofold greater in offspring than in controls (0.43 vs. 0.21 mm , P = 0.044) and most explicit in females (0.53 vs. 0.22, P = 0.078). We conclude that familial longevity is characterized by a high circadian rhythmicity of non‐HDL‐C in healthy elderly offspring from nonagenarian siblings.     

生物钟机制研究进展

由生物体内源性生物钟所产生的昼夜节律是近年来生命科学的研究热点之一。几种模型生物（蓝细菌、脉孢菌、拟南芥、果蝇、小鼠）的生物钟相关基因相继被克隆和鉴定,为理解昼夜节律的分子机制奠定了基础。振荡器蛋白对其编码基因的负反馈调控可能是不同生物的生物运作普遍机制,在此基础上,不同生物有不尽相同的调控方式;隐色素可能是高等生物的共同生物钟光受体。     

Food ingestion and circadian rhythmicity

Feeding is organised within the 24-h of the light - dark (LD) cycle. Food is ingested in a circadian manner in nature and in laboratory animals kept under constant conditions. The circadian rhythmicity in food ingestion is driven by a biological clock located in the suprachiasmatic nuclei (SCN) of the hypothalamus. The circadian organisation of food ingestion not only allows animals to live in harmony with their environment but food intake could also act as a zeitgeber for other rhythmic functions. Lesions in the area of the SCN result in the loss of most rhythmic functions as well as to a disrupted circadian rhythmicity of food and water intake. These findings, together with observations from daytime feeding experiments conducted in nocturnal animals, suggest that food intake may serve as a temporal signal for some peripheral organs to oscillate in phase with the SCN. This paper overviews and discusses how food intake interacts with the circadian system.     

Effect of temperature on circadian rhythm controlling the crepuscular activity of the burying beetle Nicrophorus quadripunctatus Kraatz (Coleoptera: Silphidae)

Locomotor activity rhythm was examined at various temperatures under a 16 h light : 8 h dark photoperiod (LD 16:8) or LD 12:12 using adults of the burying beetle Nicrophorus quadripunctatus. At 20°C, the locomotor activity of the beetles showed a bimodal daily pattern with two peaks around lights on and lights off under both photoperiods. This bimodal activity rhythm persisted under constant darkness; therefore, the activity of adult N. quadripunctatus is controlled by a circadian clock. Adults showed a bimodal activity pattern for temperatures ranging from 15 to 25°C. The evening peak of the daily activity was earlier at lower temperatures. These findings suggest that in the field, N. quadripunctatus shows crepuscular activity, and is active earlier in the afternoon in cooler seasons. In this species, therefore, temperature appears to play an important role in the determination of daily activity patterns.     

Residual circadian rhythmicity after bilateral lamina-medulla removal or optic stalk transection in the cricket, Gryllus bimaculatus

Bilateral optic stalk severance or lamina-medulla region removal were carried out in 47 adult male crickets Gryllus bimaculatus DeGeer. Effects of the operations on circadian locomotor activity were investigated under 12 h light: 12 h dark and at a constant temperature of 26°C. In the pre-operative days, 39 of the animals showed a typical nocturnal activity rhythm (normal rhythm), but the remaining 8 exhibited an atypical rhythm which is diurnal rather than nocturnal (abnormal rhythm). The operations eventually caused an arrhythmicity in all animals, suggesting that the crucial part of the central nervous system controlling the cricket circadian activity is located in the lamina-medulla region. However, in some of the post-operative crickets, the rhythm did not immediately disappear but persisted for a while: the diurnal increase of activity was observed up to 2 weeks in all 8 abnormal- and 4 normal-rhythm animals. In addition, 8 out of 39 normal-rhythm animals showed a single well-defined post-operative peak which occurred approximately in phase with the nocturnal peak prior to surgery. These results are discussed in relation to a possibility of involvement of the oscillatory structure outside the optic lobes.     

昆虫生物钟分子调控研究进展

昆虫生物钟节律的研究是人类了解生物节律的重要途径。昆虫在生理和行为上具有广泛的节律活动,如运动、睡眠、学习记忆、交配、嗅觉等节律活动,其中昼夜活动行为节律的研究广泛而深入。昆虫乃至高等动物普遍具有保守的昼夜节律系统,昼夜生物钟节律主要包括输入系统:用于接受外界光和温度等环境信号并传入核心振荡器,使得生物时钟与环境同步;核心时钟系统:自我维持的昼夜振荡器;输出系统:将生物钟产生的信号传递出去而控制生物行为和生理的节律变化。早期分子和遗传学研究主要关注昼夜节律振荡器的分子机制及神经生物学,阐明了昼夜生物钟节律的主要分子机制及相关神经网络。最近更多的研究关注生物钟信号是如何输入和输出。本文以果蝇运动节律的相关研究为主要内容,围绕生物钟输入系统、振荡器、输出系统这3个组成部分对昆虫生物钟研究进展进行总结。     

Modulation of circadian clocks by nutrients and food factors

Daily activity rhythms that are dominated by internal clocks are called circadian rhythms. A central clock is located in the suprachiasmatic nucleus of the hypothalamus, and peripheral clocks are located in most mammalian peripheral cells. The central clock is entrained by light/dark cycles, whereas peripheral clocks are entrained by feeding cycles. The effects of nutrients on the central and peripheral clocks have been investigated during the past decade and much interaction between them has come to light. For example, a high-fat diet prolongs the period of circadian behavior, a ketogenic diet advances the onset of locomotor activity rhythms, and a high-salt diet advances the phase of peripheral molecular clocks. Moreover, some food factors such as caffeine, nobiletin, and resveratrol, alter molecular and/or behavioral circadian rhythms. Here, we review nutrients and food factors that modulate mammalian circadian clocks from the cellular to the behavioral level.     

Photosynthetic circadian rhythmicity patterns of Symbiodium,the coral endosymbiotic algae

Biological clocks are self-sustained endogenous timers that enable organisms (from cyanobacteria to humans) to anticipate daily environmental rhythms, and adjust their physiology and behaviour accordingly. Symbiotic corals play a central role in the creation of biologically rich ecosystems based on mutualistic symbioses between the invertebrate coral and dinoflagellate protists from the genus Symbiodinium. In this study, we experimentally establish that Symbiodinium photosynthesis, both as a free-living unicellular algae and as part of the symbiotic association with the coral Stylophora pistillata, is ‘wired’ to the circadian clock mechanism with a ‘free-run’ cycle close to 24 h. Associated photosynthetic pigments also showed rhythmicity under light/dark conditions and under constant light conditions, while the expression of the oxygen-evolving enhancer 1 gene (within photosystem II) coincided with photosynthetically evolved oxygen in Symbiodinium cultures. Thus, circadian regulation of the Symbiodinium photosynthesis is, however, complicated as being linked to the coral/host that have probably profound physiochemical influence on the intracellular environment. The temporal patterns of photosynthesis demonstrated here highlight the physiological complexity and interdependence of the algae circadian clock associated in this symbiosis and the plasticity of algae regulatory mechanisms downstream of the circadian clock.     

Cholecystokinin neurons in mouse suprachiasmatic nucleus regulate the robustness of circadian clock

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哺乳动物昼夜节律生物钟研究进展

昼夜节律生物钟是一种以近似24小时为周期的自主维持的振荡器,在分子水平上,该振荡器是一个由9个基因组成的转录翻译反馈环路系统。它能受外界环境影响重新设置节律,使自身机体活动处于最佳状态。除了进行自我调节外,生物钟基因还能通过调节代谢途径中特定基因表达而影响机体生理生化过程。在过去的几年里,借用遗传学和分子生物学工具,我们对哺乳动物昼夜节律生物钟的分子基础有了新的认识,本文综述了这一进展,并展望了它们在研究人的昼夜节律行为异常领域的前景。     

Effect of LED light spectra on exogenous prolactin-regulated circadian rhythm in goldfish,Carassius auratus

We investigated the effect of light spectra on circadian rhythm by exogenous prolactin (PRL) using light-emitting diodes (LEDs): red, green and purple. We injected PRL into live fish or treated cultured brain cells with PRL. We measured changes in the expressions of period 2 (Per2), cryptochrome 1 (Cry1), melatonin receptor 1 (MT1) mRNAs, and MT1 proteins, and in the plasma PRL, serotonin and melatonin levels. After PRL injection and exposure to green light, MT1 expression and plasma melatonin levels were significantly lower, but the expressions of Per2 and Cry1 were significantly higher than the others. Plasma serotonin after PRL injection and exposure to red light was significantly lower than others. These results indicate that injection of high concentration PRL inhibits melatonin, and inhibited melatonin regulates circadian rhythm via clock genes and serotonin. Thus, exogenous PRL regulates the circadian rhythm and light spectra influence the effect of PRL in goldfish.     

Effects of bisphenol A and light conditions on the circadian rhythm of the goldfish Carassius auratus

We investigated how exposure to bisphenol A (BPA) under different photoperiodic conditions affected the expression of clock genes in the brain and liver of the goldfish, Carassius auratus. Three photoperiodic conditions were used: control, LD; continuous light, LL; and continuous dark, DD; the fish were exposed to three concentrations of BPA, namely 0, 10, or 100 μg/L. We measured changes in the expression of cryptochrome 1 (Cry1), period 2 (Per2), and melatonin receptor 1 (MT-R1). The levels of Cry1, Per2, and MT-R1 mRNAs decreased with increasing BPA concentration and with increasing exposure time. Expression of Cry1 and Per2 increased more in the LL group than in the LD and DD groups. However, for MT-R1, the DD group showed increased expression compared to the LL and LD groups. Our analysis shows that circadian rhythms in goldfish can be disrupted by exposure to BPA and that the response can be modified by regulating the photoperiod.     

The circadian system of Drosophila melanogaster and its light input pathways

The fruit fly Drosophila melanogaster has been a grateful object for circadian rhythm researchers over several decades. Behavioral, genetic, and molecular studies in the little fly have aided in understanding the bases of circadian time keeping and rhythmic behaviors not only in Drosophila, but also in other organisms, including mammals. This review summarizes our present knowledge about the fruit fly's circadian system at the molecular and neurobiological level, with special emphasis on its entrainment by environmental light-dark cycles. The results obtained for Drosophila are discussed with respect to parallel findings in mammals.     

Seasonal cues act through the circadian clock and pigment-dispersing factor to control EYES ABSENT and downstream physiological changes

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