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。     

The mammalian retina as a clock

Many physiological, cellular, and biochemical parameters in the retina of vertebrates show daily rhythms that, in many cases, also persist under constant conditions. This demonstrates that they are driven by a circadian pacemaker. The presence of an autonomous circadian clock in the retina of vertebrates was first demonstrated in Xenopus laevis and then, several years later, in mammals. In X. laevis and in chicken, the retinal circadian pacemaker has been localized in the photoreceptor layer, whereas in mammals, such information is not yet available. Recent advances in molecular techniques have led to the identification of a group of genes that are believed to constitute the molecular core of the circadian clock. These genes are expressed in the retina, although with a slightly different 24-h profile from that observed in the central circadian pacemaker. This result suggests that some difference (at the molecular level) may exist between the retinal clock and the clock located in the suprachiasmatic nuclei of hypothalamus. The present review will focus on the current knowledge of the retinal rhythmicity and the mechanisms responsible for its control.     

Plants measure the time

All eukaryotes, including plants, and most prokaryotes have developed elaborate mechanisms to anticipate external environmental changes associated with the Earth’s rotation. These mechanisms are mediated by a circadian clock, which regulates several physiological and biochemical processes. Microarray experiments using Affymetrix chips that included about 8000 of the 27000 Arabidopsis genes have demonstrated that as much as 6% of that genome may be under the control of this clock. While our understanding of such mechanisms is lagging, molecular genetics studies of Arabidopsis have allowed us to make great progress toward identifying and characterizing components of the plant circadian clock since its first component was isolated in 1995. The generation of 24-h rhythms by this clock appears to rely on mechanisms similar to those found in other organisms. However, an entirely different set of molecular components are recruited to perform these functions in Arabidopsis. In this review, we introduce useful and powerful approaches for identifying clock-associated genes and determining how they can act together in the interlocking feedback loops that comprise this particular clock.     

果蝇昼夜节律的分子机制研究进展

果蝇由于遗传易操作性而成为一个研究昼夜节律分子机制的理想模式生物 . 到目前为止,通过遗传学和生物化学方法已经鉴定到 10 多个时钟基因 (clock genes) 和许多时钟相关基因,包括时钟输入基因和钟控基因 . 这些时钟基因以及它们的相应产物组成两个互相依赖的转录 / 翻译反馈环路,从而调节行为和生理的昼夜节律 . 果蝇这种核心钟的工作原理同样见于哺乳动物 .     

The mammalian circadian clock

Organisms populating the earth are under the steady influence of daily and seasonal changes resulting from the planet's rotation and orbit around the sun. This periodic pattern most prominently manifested by the light-dark cycle has led to the establishment of endogenous circadian timing systems that synchronize biological functions to the environment. The mammalian circadian system is composed of many individual, tissue-specific clocks. To generate coherent physiological and behavioral responses, the phases of this multitude of clocks are orchestrated by the master circadian pacemaker residing in the suprachiasmatic nuclei of the brain. Genetic, biochemical and genomic approaches have led to major advances in understanding the molecular and cellular basis of mammalian circadian clock components and mechanisms.     

Systematic Identification of Rhythmic Genes Reveals camk1gb as a New Element in the Circadian Clockwork

A wide variety of biochemical, physiological, and molecular processes are known to have daily rhythms driven by an endogenous circadian clock. While extensive research has greatly improved our understanding of the molecular mechanisms that constitute the circadian clock, the links between this clock and dependent processes have remained elusive. To address this gap in our knowledge, we have used RNA sequencing (RNA–seq) and DNA microarrays to systematically identify clock-controlled genes in the zebrafish pineal gland. In addition to a comprehensive view of the expression pattern of known clock components within this master clock tissue, this approach has revealed novel potential elements of the circadian timing system. We have implicated one rhythmically expressed gene, camk1gb, in connecting the clock with downstream physiology of the pineal gland. Remarkably, knockdown of camk1gb disrupts locomotor activity in the whole larva, even though it is predominantly expressed within the pineal gland. Therefore, it appears that camk1gb plays a role in linking the pineal master clock with the periphery.     

The circadian conidiation rhythm inNeurospora crassa

The filamentous fungusNeurospora crassais one of the best organisms for analysing the molecular basis of the circadian rhythm observed in asexual spore formation, conidiation. Many clock mutants in which the circadian conidiation rhythm has different characteristics compared to those in the wild-type strain have been isolated since the early 1970s. With the cloning of one of these clock genes,frq, the molecular basis of the circadian clock inNeurosporahas become gradually clearer. Physiological and pharmacological studies have also contributed to our understanding of the physiological basis of the circadian clock inNeurospora. These studies strongly indicate that the circadian clock is based on or is closely related to a network of metabolic processes for cellular activities. Based on these studies, it may be possible to isolate new types of clock mutants which should contribute to a better understanding of the molecular basis of the circadian clock inNeurospora.     

Insect circadian clocks: is it all in their heads?

Circadian rhythms are ubiquitous in living organisms, synchronizing life functions at the biochemical, physiological, and behavioral levels. The rhythm-generating mechanisms, collectively known as circadian clocks, are not fully understood in any organism. Research in the fruit fly Drosophila has led to the identification of several clock genes that are involved in the function of the brain-centered clock, which controls behavioral rhythms of adult flies. With the use of clock genes as markers, putative circadian clocks were mapped in the fly peripheral organs and shown to be independent from clocks located in the brain. A homologue of fruit fly period gene has been identified in moths and other insects, allowing investigations of this gene's role in known insect rhythms. This approach may increase our understanding of how circadian clocks are organized into the circadian system that orchestrates temporal integration of life processess in insects.     

Signaling networks in the plant circadian system

Significant advances have been made during the past year in the genetic and molecular dissection of the plant circadian system. Several proteins involved in circadian clock regulation have been identified and the way that their interactions contribute to temporal organization is starting to emerge. In addition, genomic approaches have identified hundreds of genes under clock control, providing a molecular basis to our understanding of how the clock coordinates plant physiology and development with daily and seasonal environmental cycles.     

Interactions of circadian clock genes with the hallmarks of cancer

The molecular machinery of the circadian clock regulates the expression of many genes and processes in the organism, allowing the adaptation of cellular activities to the daily light-dark cycles.Disruption of the circadian rhythm can lead to various pathologies, including cancer. Thus, disturbance of the normal circadian clock at both genetic and environmental levels has been described as an independent risk factor for cancer. In addition, researchers have proposed that circadian genes may have a tissue-dependent and/or context-dependent role in tumorigenesis and may function both as tumor suppressors and oncogenes.Finally, circadian clock core genes may trigger or at least be involved in different hallmarks of cancer. Hence, expanding the knowledge of the molecular basis of the circadian clock would be helpful to identify new prognostic markers of tumorigenesis and potential therapeutic targets.     

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。     

Understanding circadian rhythmicity in Neurospora crassa: from behavior to genes and back again

Circadian clocks have been described in organisms ranging in complexity from unicells to mammals, in which they function to control daily rhythms in cellular activities and behavior. The significance of a detailed understanding of the clock can be appreciated by its ubiquity and its established involvement in human physiology, including endocrine function, sleep/wake cycles, psychiatric illness, and drug tolerances and effectiveness. Because the clock in all organisms is assembled within the cell and clock mechanisms are evolutionarily conserved, simple eukaryotes provide appropriate experimental systems for dissecting the clock. Significant progress has been made in deciphering the circadian system in Neurospora crassa using both genetic and molecular approaches, and Neurospora has contributed greatly to our understanding of (1) the feedback cycle that comprises a circadian oscillator, (2) the mechanisms by which the clock is kept in synchrony with the environment, and (3) the genes that reside in rhythmic output pathways. Importantly, the lessons learned in Neurospora are relevant to our understanding of clocks in higher eukaryotes.     

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.     

Beyond intuitive modeling: combining biophysical models with innovative experiments to move the circadian clock field forward

Two major approaches have been used to model circadian clocks. Qualitative modeling, used prior to the recent wealth of detailed molecular knowledge, makes general predictions but cannot provide detailed mechanistic insights. The more recent biophysical approach, on the other hand, incorporates the biochemical events that drive the clock and can make detailed and testable molecular predictions. These predictions are being tested using new experimental techniques that measure reaction kinetics and the behavior of individual cells. A joint modeling and experimental approach has recently been used to understand how mutations affecting phosphorylation can lead to a short circadian period in tau mutant hamsters and in humans with familial advanced sleep phase syndrome (FASPS). Another recent study has revealed novel single-cell phenotypes of clock gene mutations, demanding revision of current biophysical models yet validating certain model predictions that were previously overlooked. A new paradigm for clock research is emerging in which modeling inspires new experimental efforts, experimental data inspire new modeling efforts, and joint modeling/experimental studies lead to a deeper understanding of mammalian circadian rhythms.