The circadian regulation of photosynthesis

Correct circadian regulation increases plant productivity, and photosynthesis is circadian-regulated. Here, we discuss the regulatory basis for the circadian control of photosynthesis. We discuss candidate mechanisms underpinning circadian oscillations of light harvesting and consider how the circadian clock modulates CO₂ fixation by Rubisco. We show that new techniques may provide a platform to better understand the signalling pathways that couple the circadian clock with the photosynthetic apparatus. Finally, we discuss how understanding circadian regulation in model systems is underpinning research into the impact of circadian regulation in crop species.     

The meter of metabolism

The circadian system orchestrates the temporal organization of many aspects of physiology, including metabolism, in synchrony with the 24 hr rotation of the Earth. Like the metabolic system, the circadian system is a complex feedback network that involves interactions between the central nervous system and peripheral tissues. Emerging evidence suggests that circadian regulation is intimately linked to metabolic homeostasis and that dysregulation of circadian rhythms can contribute to disease. Conversely, metabolic signals also feed back into the circadian system, modulating circadian gene expression and behavior. Here, we review the relationship between the circadian and metabolic systems and the implications for cardiovascular disease, obesity, and diabetes.     

Interaction of the circadian rhythms of the functional activity of the hypophyseal-adrenal system and of the mitotic activity in the esophageal epithelium of rats with experimental hypo- and hypercorticism

In experimental hypercorticism the average daily concentration of glucocorticoids in blood plasma is 4 times higher than in control one, the amplitude of the circadian rhythm increases almost 3 times, the time of maximum concentration does not change. The adrenocorticotrophic hormone (ACTH) average circadian concentration decreases twofold. The adrenalectomy results in abrupt smoothing down of the circadian rhythm of glucocorticoids concentration and in increasing (in 2,4 times) of the average circadian concentration of ACTH. The pattern of circadian rhythm remains, however the acrophase of hormone secretion is shifted. The circadian rhythm of cells devision in esophagus epithelium changes. The maximum of mitotic index is absent in adrenalectomized rats and the amplitude of its circadian variations decreases. In experimental hypercorticism the biphase rhythm of mitoses in induced.     

昼夜节律钟调控代谢的研究进展

生理和行为的昼夜节律性调控对健康生活是必需的。越来越多的流行病学和遗传学证据显示昼夜节律的破坏与代谢紊乱性疾病相关联。在分子水平上,昼夜节律受到时钟蛋白组成的转录一翻译负反馈环的调控。时钟蛋白通过以下两种途径调节代谢：首先,时钟蛋白作为转录因子直接调节一些代谢关键步骤的限速酶和代谢相关核受体的表达,其次作为代谢相关核受体的辅调节因子来激活或抑制其转录活性。虽然时钟蛋白对代谢途径的调节导致代谢物水平呈昼夜节律振荡,但是产生的代谢物反过来又可以影响昼夜节律钟基因的表达,进而影响昼夜节律钟。深入研究昼夜节律钟与代谢的交互调节可能为治疗某些代谢紊乱性疾病提供新的治疗方案。     

Real-time monitoring of chloroplast gene expression by a luciferase reporter: evidence for nuclear regulation of chloroplast circadian period

Chloroplast-encoded genes, like nucleus-encoded genes, exhibit circadian expression. How the circadian clock exerts its control over chloroplast gene expression, however, is poorly understood. To facilitate the study of chloroplast circadian gene expression, we developed a codon-optimized firefly luciferase gene for the chloroplast of Chlamydomonas reinhardtii as a real-time bioluminescence reporter and introduced it into the chloroplast genome. The bioluminescence of the reporter strain correlated well with the circadian expression pattern of the introduced gene and satisfied all three criteria for circadian rhythms. Moreover, the period of the rhythm was lengthened in per mutants, which are phototactic rhythm mutants carrying a long-period gene in their nuclear genome. These results demonstrate that chloroplast gene expression rhythm is a bona fide circadian rhythm and that the nucleus-encoded circadian oscillator determines the period length of the chloroplast rhythm. Our reporter strains can serve as a powerful tool not only for analysis of the circadian regulation mechanisms of chloroplast gene expression but also for a genetic approach to the molecular oscillator of the algal circadian clock.     

Roles of circadian clock genes in insect photoperiodism

Functional involvement of a circadian clock in photoperiodism for measuring the length of day or night had been proposed more than 70 years ago, and various physiological experiments have supported the idea. However, the molecular basis of a circadian clock has remained veiled in insects. Nevertheless, our knowledge of the functional elements of a circadian clock governing circadian rhythmicity has advanced rapidly. Since both circadian rhythms and photoperiodism depend on the daily cycles of environmental changes, it is easy to assume that the same clock elements are involved in both processes. Recently, the RNA interference (RNAi) technique clarified that the molecular machinery of a circadian clock governing photoperiodism is identical to that governing circadian rhythmicity. Here, I review the theoretical background of photoperiodic responses incorporating a circadian clock(s) and recent progress on the molecular clockwork involved in photoperiodism in the bean bug Riptortus pedestris and other insect species. I have focused on the intense controversy regarding the involvement of a circadian clock in insect photoperiodism.     

生物节律影响巨核细胞发育和血小板产生的研究进展

自然界中生物体的生命活动、生活习性都存在着一定的周期性变化。生物昼夜节律的产生是以内源性的生物钟系统为基础的。生物钟不仅易受到外界环境的影响,而且可以通过调控一系列特定的下游基因的表达,影响生物体的生理生化过程。巨核细胞是生成血小板的前体细胞,经过分化、增殖、成熟和裂解,最终生成血小板。血小板是一种没有细胞核的特殊细胞,在生理性止血和器官修复上发挥着重要作用,同时参与血栓等多种疾病的发生。近几年借助现代分子生物学和细胞生物学手段,证实了哺乳动物的巨核细胞和血小板的生成呈现明显的周期性的变化,利用生物钟基因缺失模型进一步发现了生物钟基因对巨核细胞和血小板的影响。本文概述了生物节律对巨核细胞和血小板的影响,为进一步研究巨核细胞的发育和血小板生成机制提供了参考。     

Integration of human sleep-wake regulation and circadian rhythmicity.

The human sleep-wake cycle is generated by a circadian process, originating from the suprachiasmatic nuclei, in interaction with a separate oscillatory process: the sleep homeostat. The sleep-wake cycle is normally timed to occur at a specific phase relative to the external cycle of light-dark exposure. It is also timed at a specific phase relative to internal circadian rhythms, such as the pineal melatonin rhythm, the circadian sleep-wake propensity rhythm, and the rhythm of responsiveness of the circadian pacemaker to light. Variations in these internal and external phase relationships, such as those that occur in blindness, aging, morning and evening, and advanced and delayed sleep-phase syndrome, lead to sleep disruptions and complaints. Changes in ocular circadian photoreception, interindividual variation in the near-24-h intrinsic period of the circadian pacemaker, and sleep homeostasis can contribute to variations in external and internal phase. Recent findings on the physiological and molecular-genetic correlates of circadian sleep disorders suggest that the timing of the sleep-wake cycle and circadian rhythms is closely integrated but is, in part, regulated differentially.     

Correlation between circadian periods and cellular activities in Paramecium bursaria

Paramecium bursaria shows a circadian rhythm of photoaccumulation: photoaccumulation is stronger during the day than at night. We obtained five strains of P. bursaria having different circadian periods under continuous light conditions, ranging from 20.9 to 27.9 h. Various physiological activities were compared in the cells of these strains. The periods of contractile vacuole contraction were in the range 10–15 s, which was almost proportional to the periods of the circadian rhythm in each strain. Swimming velocities were inversely proportional to the circadian period; i.e. swimming velocities were high in strains whose circadian periods were short. Resting membrane potential was more depolarized in strains with longer circadian periods. Finally, the membrane resistance of the resting state was reduced in proportion to the increase of the circadian period. Such correlation between the cellular properties and the circadian period suggests that the circadian clock mechanism is associated with various physiological activities of the cell.     

Sirt1与生物钟的相互调控

生物钟调控机制广泛存在于各种类型的细胞中,控制着细胞代谢的节律性变化.最近的研究发现,NAD+依赖的组蛋白去乙酰化酶Sirt1参与了生物钟调控过程,对维持正常的生物钟节律具有重要作用;另一方面,Sirt1的表达也受到生物钟系统的调控,呈现出昼夜节律性的表达.因此Sirt1能与生物钟进行相互调控,并且这一作用机制很可能广泛参与了不同类型细胞内的信号转导和能量代谢过程.本文总结了Sirt1与生物钟之间相互调控的一些研究进展,对它们之间的分子调控机制进行了概述.     

昼夜节律紊乱与胰岛β细胞缺陷关系的研究进展

生物的许多生命现象多有其固有的周期,呈现出昼夜节律、月节律和年节律性。昼夜节律是人类生命活动最普遍存在的一种节律形式,但这种节律周期可能被现代许多生活方式所破坏。人群流行病学和动物实验研究表明昼夜节律的紊乱与2型糖尿病的发病危险相关,但其机制尚未完全阐明。胰岛β细胞缺陷是2型糖尿病发生发展的必要机制,而昼夜节律紊乱与胰岛β细胞缺陷有一定关联。本文结合最新研究进展阐述昼夜节律紊乱与胰岛β细胞缺陷的相关性及其可能机制。     

The pineal gland influences rat circadian activity rhythms in constant light.

Mammalian circadian organization is believed to derive primarily from circadian oscillators within the hypothalamic suprachiasmatic nuclei (SCN). The SCN drives circadian rhythms of a wide array of functions (e.g., locomotion, body temperature, and several endocrine processes, including the circadian secretion of the pineal hormone melatonin). In contrast to the situation in several species of reptiles and birds, there is an extensive literature reporting little or no effect of pinealectomy on mammalian circadian rhythms. However, recent research has indicated that the SCN and circadian systems of several mammalian species are highly sensitive to exogenous melatonin, raising the possibility that endogenous pineal hormone may provide feedback in the control of overt circadian rhythms. To determine the role of the pineal gland in rat circadian rhythms, the effects of pinealectomy on locomotor rhythms in constant light (LL) and constant darkness (DD) were studied. The results indicated that the circadian rhythms of pinealectomized rats but not sham-operated controls dissociated into multiple ultradian components in LL and recoupled into circadian patterns only after 12-21 days in DD. The data suggest that pineal feedback may modulate sensitivity to light and/or provide coupling among multiple circadian oscillators within the SCN.