生物钟与衰老的相关研究进展

众所周知,从单细胞生物到人,几乎所有生物体在生理和行为上都表现出昼夜节律。内源性生物钟是产生昼夜节律的物质基础,由母钟和子钟组成,母钟位于下丘脑视交叉上核（SCN）,子钟位于各个外周组织（肝脏、心脏等）。随着机体的逐渐衰老,反应生物钟输出信号的生理昼夜节律在振荡幅度、振荡周期和表达时相等方面发生了相应的变化。另一方面,生物钟控制的生理昼夜节律影响衰老的进程,生物钟功能紊乱会严重加速机体的衰老。本文概述了衰老与生物钟之间的相关研究进展,为进一步认识衰老机制及其对机体的影响提供了线索。     

视网膜生物钟研究进展

昼夜节律生物钟是以24h为周期的自主维持的振荡器。在高等的多细胞生物中,生物钟可以分为母钟和子钟。研究表明哺乳动物的母钟位于下丘脑视交叉上核(suprachiasmatic nucleus,SCN),由此发出信息控制全身的节律活动;子钟位于组织细胞内,调控效应器的节律。在分子水平上,生物钟的振荡由自身调控反馈环路的转录和翻译组成,并接受外界环境因素的影响,通过下丘脑视叉上核(Suprachiasmatic Nucleus,SCN)中枢震荡器的同步整和而产生作用。视网膜是一种十分节律性的组织,许多生化的、细胞的和生理的过程都是以节律的方式来进行的,如视觉灵敏度、视网膜杆细胞外片层脱落和视网膜色素上皮细胞的吞噬作用、光受体中的视觉色素基因的快速表达等。生物钟存在于很多脊椎动物的视网膜中,被认为是一种外周生物钟。本文综述了视网膜生物钟,生物钟信号传输以及生物钟网络等的最新研究进展。     

肾上腺糖皮质激素与生物钟基因表达调控的相关研究进展

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。哺乳动物中的昼夜节律系统由位于下丘脑SCN核内的主钟和位于多数外周细胞中的子钟组成。生物钟基因及其编码的蛋白质组成反馈回路,维持振荡系统持续进行并与环境周期保持同步。光照和食物是生物钟重要的授时因子, 光照刺激能引起肾上腺中基因表达变化以及糖皮质激素的分泌, 而肾上腺糖皮质激素能减缓由食物因子引起的外周生物钟时相的移动。可见, 肾上腺糖皮质激素与生物钟有着非常密切的关系。文章综述了两者的相互影响并对今后的研究方向做了展望。     

生物节律与生物钟 上

一、生物定时与生物周期现象大约60多年前,有位习惯在阳台上用早餐的学者,一天偶然看到有蜜蜂飞上阳台,叮在早餐的甜食上。在此后的几天里,他留心观察,发现蜜蜂几乎每天都在同一时间里飞来。接着他做了一个实验,从第五天起餐桌上不再放有甜食,结果连续两天蜜蜂仍每天按时飞来。这说明蜜蜂并不是无意间因餐桌上甜食的招引才飞来的。这种现象被称为生物定时(Biochroni-ze)。     

生物节律和生物钟

从众多的生物节律现象可看出,动物、植物的生理机能和生活习性好象受体内某种内在的时钟控制,这种神秘的时钟称为“生物钟”,即生物感知时间的能力。而生物节律实际上是由生物钟控制的,是生物钟的外在表现。生物节律和生物钟的研究经历了3个主要阶段:50年代及以前的生物节律现象的描述阶段;60年代的模型建造阶段;70年代以来利用生物化学和分子     

生物钟紊乱防治策略的研究进展

生物钟是机体为适应环境周期性变化而进化出的一种内在机制。保持体内时钟与外界时钟步调一致对健康至关重要，二者不同步(比如作息不规律、时差、分子时钟机制被破坏等)可能导致生物钟紊乱，可表现为睡眠-觉醒周期异常，激素分泌、血压、心率、体温等节律或水平异常，长期紊乱还与代谢性疾病、心血管疾病、肿瘤等常见重大疾病密切相关。为解决长久以来生物钟紊乱无药可医的局面，科学家们在细胞和动物水平对生物钟基因的功能及其在疾病发生、发展中的作用进行了大量的研究，并对数十万计的小分子化合物进行筛选以探索药物调整生物钟的可行性。此外，褪黑素、光照疗法、运动疗法、调整摄食时间、改变食物营养成分等也对生物钟紊乱起到一定的缓解作用。本文将从药物干预和非药物干预两个角度对生物钟紊乱防治策略的研究进展进行综述。     

动物昼夜生物钟的分子机制

动物的昼夜生物钟是一种十分重要的生物节律,对生物对环境的适应有着重要的意义。昼夜节律是一种综合适应,它体现在个体、器官、组织等不同的水平上。最近20几年来．人们通过对果蝇和鼠的昼夜生物钟振荡子的研究,逐渐揭示了动物生物钟的负反馈回路的分子机制。     

哺乳动物生物钟与能量代谢的相关研究进展

生物钟广泛存在于各种生物体中,是生命体的一种内源调节机制。哺乳动物生物钟系统与机体营养代谢和能量平衡有着密切的关系。概述了生物钟系统通过营养途径、限速酶途径、核受体途径对哺乳动物机体代谢活动和能量平衡的调控,以及哺乳动物代谢稳态对生物钟系统的影响,从而为从生物钟调控的角度治疗和防控代谢综合征提供新的思路。     

哺乳动物卵巢生物钟的研究进展

近年来,越来越多的研究发现生物钟系统在许多生理活动中,包括心血管、内分泌、免疫、生殖等系统的生理,都起着重要作用。随着2006年卵巢生物钟的发现,生殖系统生物钟成为新的研究热点。研究发现卵巢生物钟不仅影响排卵,而且还控制类固醇激素的释放。卵巢生物钟属外围生物钟,受到中央生物钟(SCN)神经内分泌信号的调控。还发现下丘脑-垂体-卵巢(HPG)轴上各水平都存在生物钟,HPG轴上各生物钟失同步影响生殖能力,这可能导致一些疾病发生的病因。本文总结近十年的关于卵巢生物钟的研究,列举哺乳动物卵巢生物钟存在的证据,并阐述生物钟在雌鼠正常生殖生理过程,及在生殖系统疾病病理过程中的作用及其分子机制。     

生物钟基因研究进展

昼夜节律是以大约24 h为周期波动的生物现象.这些节律包括血压、体温、激素水平、血中免疫细胞的数量、睡眠觉醒周期循环等.基因水平上的昼夜节律研究还只是刚起步,介绍不同物种控制昼夜行为的共同基因(如period 、timless 、clock基因等)的研究进展,特别是一些有关调控昼夜节律基因的转录因子的研究.同时讨论果蝇和人类生物钟调节的共同分子机制.     

Circadian Rhythms in NEUROSPORA CRASSA: Interactions between Clock Mutations

Mutations at four loci in Neurospora crassa that alter the period of the circadian rhythm have been used to construct a series of double mutant strains in order to detect interactions between these mutations. Strains carrying mutations at three of these loci have altered periods on minimal media: prd-1, several alleles at the olir (oligomycin resistance) locus and four alleles at the frq locus. A mutation at the fourth locus, cel, which results in a defect in fatty acid synthesis, also leads to lengthening of the period when the medium is supplemented with linoleic acid (18:2). The cel mutation was crossed into strains carrying the frq, prd-1 and olir mutations, and the periods of the double mutant strains with and without 18:2 supplementation were determined. In addition, data from the literature for other combinations of loci and/or chemical effects on the period have been reanalyzed.--It was found that both prd-1 and olir are epistatic to the effects of 18:2 on cel; in the series of cel frq double mutant strains, the period-lengthening effect of 18:2 is inversely proportional to the period of the frq parent, indicating an interaction between frq and cel; period effects reported in the literature can be described as changes by a fixed ratio or percentage of the period rather than by a fixed number of hours, and the data, therefore, can support a multiplicative as well as an additive model.--Several biochemical interpretations of these interactions are discussed, based on simple chemical kinetics, enzyme inhibition kinetics and the control of flux through metabolic pathways.     

Interactions between Light and the Circadian Clock in the Regulation of CAT2 Expression in Arabidopsis

In Arabidopsis seedlings germinated and grown in continuous light, CAT2 mRNA abundance peaks 1 d after imbibition, consistent with the role of catalase in detoxifying H2O2 generated during the [beta]-oxidation of fatty acids stored in the seed. A second peak of CAT2 mRNA abundance, of lower amplitude than the initial peak, appears 6 d after imbibition and may be associated with the development of photosynthetic competence and induction of photorespiration. This second peak in steady-state CAT2 mRNA abundance is regulated by light and is not seen in etiolated seedlings. CAT2 mRNA accumulation is induced by exposure to high-fluence blue or far-red light but not by red light. In addition, light induction is unaffected by several mutations that block blue light-mediated inhibition of hypocotyl elongation (blu1, blu2, blu3, hy4), suggesting phytochrome involvement. When etiolated seedlings are transferred to continuous white light, CAT2 mRNA rapidly (within 30 min) accumulates. It is interesting that in these seedlings CAT2 mRNA abundance undergoes pronounced oscillations with a circadian (24 h) periodicity, indicating control by the endogenous circadian clock. No such oscillations are detected in CAT2 mRNA abundance in etiolated seedlings prior to illumination. Control of CAT2 expression by the circadian clock is also seen in 5-week-old plants grown in a light-dark cycle and transferred either to continuous dark or to continuous light; in continuous light the circadian oscillations in CAT2 mRNA abundance persist for at least five circadian cycles, indicating the robustness of this circadian rhythm.     

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.     

Crosstalk between the Circadian Clock and Innate Immunity in Arabidopsis

The circadian clock integrates temporal information with environmental cues in regulating plant development and physiology. Recently, the circadian clock has been shown to affect plant responses to biotic cues. To further examine this role of the circadian clock, we tested disease resistance in mutants disrupted in CCA1 and LHY, which act synergistically to regulate clock activity. We found that cca1 and lhy mutants also synergistically affect basal and resistance gene-mediated defense against Pseudomonas syringae and Hyaloperonospora arabidopsidis. Disrupting the circadian clock caused by overexpression of CCA1 or LHY also resulted in severe susceptibility to P. syringae. We identified a downstream target of CCA1 and LHY, GRP7, a key constituent of a slave oscillator regulated by the circadian clock and previously shown to influence plant defense and stomatal activity. We show that the defense role of CCA1 and LHY against P. syringae is at least partially through circadian control of stomatal aperture but is independent of defense mediated by salicylic acid. Furthermore, we found defense activation by P. syringae infection and treatment with the elicitor flg22 can feedback-regulate clock activity. Together this data strongly supports a direct role of the circadian clock in defense control and reveal for the first time crosstalk between the circadian clock and plant innate immunity.     

Spatial Distribution of Circadian Clock Phase in Aging Cultures of Neurospora crassa

Neurospora crassa has been utilized extensively in the study of circadian clocks. Previously, the clock in this organism has been monitored by observing the morphological and biochemical changes occurring at the growing front of cultures grown on solid medium. A method has been developed for assaying the clock in regions of the culture behind the growing front, where no apparent morphological changes occur during the circadian cycle. Using this assay with Petri dish cultures that were 2 to 7 days old, the presence of a functional circadian clock not only at the growing front but in all other regions of the culture as well was demonstrated. Furthermore, the entire culture is not in the same phase, but shows a gradient of phases which is a function of the length of time the clock in a given part of the culture has been free-running. This gradient may be the result of a somewhat longer period of the oscillator behind the growing front compared to that at the growing front. The phase differences within a single culture of interconnected mycelium demonstrate the absence of total internal synchronization between adjacent regions of the hyphae under these conditions.     

The Timing of the Circadian Clock and Sleep Differ between Napping and Non-Napping Toddlers

The timing of the internal circadian clock shows large inter-individual variability across the lifespan. Although the sleep-wakefulness pattern of most toddlers includes an afternoon nap, the association between napping and circadian phase in early childhood remains unexplored. This study examined differences in circadian phase and sleep between napping and non-napping toddlers. Data were collected on 20 toddlers (34.2±2.0 months; 12 females; 15 nappers). Children followed their habitual napping and non-napping sleep schedules (monitored with actigraphy) for 5 days before an in-home salivary dim light melatonin onset (DLMO) assessment. On average, napping children fell asleep during their nap opportunities on 3.6±1.2 of the 5 days before the DLMO assessment. For these napping children, melatonin onset time was 38 min later (p = 0.044; d = 0.93), actigraphically-estimated bedtime was 43 min later (p = 0.014; d = 1.24), sleep onset time was 59 min later (p = 0.006; d = 1.46), and sleep onset latency was 16 min longer (p = 0.030; d = 1.03) than those not napping. Midsleep and wake time did not differ by napping status. No difference was observed in the bedtime, sleep onset, or midsleep phase relationships with DLMO; however, the wake time phase difference was 47 min smaller for napping toddlers (p = 0.029; d = 1.23). On average, nappers had 69 min shorter nighttime sleep durations (p = 0.006; d = 1.47) and spent 49 min less time in bed (p = 0.019; d = 1.16) than non-nappers. Number of days napping was correlated with melatonin onset time (r = 0.49; p = 0.014). Our findings indicate that napping influences individual variability in melatonin onset time in early childhood. The delayed bedtimes of napping toddlers likely permits light exposure later in the evening, thereby delaying the timing of the clock and sleep. Whether the early developmental trajectory of circadian phase involves an advance associated with the decline in napping is a question necessitating longitudinal data as children transition from a biphasic to monophasic sleep-wakefulness pattern.