动物内源褪黑素调控生物节律的研究进展

内源褪黑素对人类和其他哺乳动物的节律行为具有调控功能。生物节律是自然进化赋予生命的基本特征之一,生物体的生命活动受到生物节律的控制与影响。在哺乳动物中,节律调控中心是松果体,其主要功能是合成和分泌褪黑素。褪黑素广泛参与生物体节律行为的调节,本文从褪黑素的产生和作用机制,分别阐述褪黑素对昼夜节律行为和多种年节律行为的调控作用,同时明确褪黑素与生物钟及神经内分泌系统的直接作用和反馈互动的复杂集合,进一步揭示褪黑素调控生物节律的重要作用,以期为褪黑素的基础研究以及未来探究生物体的生物钟内源性发生机制提供参考。     

褪黑素对人体睡眠和血压的影响

昼夜节律遵循体内的生物钟规律,调节着机体多种功能和代谢过程,如血压、睡眠周期和体温等,睡眠周期表现出明显的昼夜节律,血压的变化也遵循24小时昼夜模式.研究表明,昼夜节律异常是睡眠障碍和心血管疾病的危险诱因之一.昼夜节律的起搏点受褪黑素的调节,而褪黑素的合成和分泌也具有昼夜节律性.内源性褪黑素可以通过多种方式增强人类节律系统的功能,外源性褪黑素作为一种时相药,可以对人体昼夜节律紊乱产生调节作用.越来越多的研究发现,褪黑素与睡眠和血压的变化有紧密的联系,深入研究褪黑素在其中的作用有利于阐明该类疾病的发生机制.本文旨在就褪黑素对人体睡眠和血压的影响作一综述.     

O-GlcNAc修饰调节生物节律研究进展

生物体的睡眠/觉醒、进食等行为以及各种生理、生化、代谢过程都遵循着大约24 h的周期性变化,称为昼夜节律(circadian rhythms)。昼夜节律与能量代谢之间存在着紧密的联系。位于下丘脑视交叉上核(suprachiasmatic nuclei,SCN)的中枢生物钟与外周组织细胞中的生物钟共同组成了哺乳动物的昼夜节律系统。以CLOCK/BMAL1异二聚体为核心的转录/翻译负反馈环保障了节律系统的正常运行。各种蛋白质翻译后修饰参与了昼夜节律的调控。综述了氧连β-N-乙酰葡糖胺修饰(O-Glc NAcylation)在调节昼夜节律中发挥的重要作用。O-Glc NAc修饰可以增强一些生物钟蛋白的稳定性及转录活性,也可以影响其他一些生物钟蛋白的磷酸化及细胞定位。抑制生物钟蛋白的O-Glc NAc修饰导致细胞节律衰弱和多种节律基因表达下调。研究表明,O-Glc NAc作为机体能量代谢的感受器参与了多条细胞代谢相关信号转导通路的调节,O-Glc NAc修饰为能量代谢影响昼夜节律提供了一条新的途径。     

褪黑素调节卵巢功能及相关机制的研究进展

褪黑素是一种神经内分泌激素,在动物体内主要由松果体合成和分泌,具有调节昼夜节律的重要作用,包括卵巢生物钟系统。褪黑素在外周组织器官如女性生殖器官卵巢中也发挥重要生理作用。女性生殖过程中,卵泡不断产生并累积活性氧,进而造成组织细胞损伤。褪黑素可通过受体依赖或者受体非依赖的机制参与卵巢功能调节。最近研究发现,褪黑素还可通过调节细胞自噬机制发挥效应。该文就褪黑素对卵巢的保护作用及其相关机制的研究进展进行综述。     

褪黑激素对体重调节

褪黑激素是松果体分泌的一种激素,其分泌受光周期影响。很多研究在褪黑激素对季节性繁殖、睡眠、昼夜节律和抗氧化等方面的作用已作过阐述。本综述介绍了褪黑激素的结构、合成及分解代谢、分泌和作用机制,及其通过对能量代谢调节及与其他激素相互作用来调节体重的机制,并分析在不同物种中褪黑激素对体重的影响,展望褪黑激素对治疗人类肥胖的应用前景。     

核受体REV-ERBα整合生物钟与能量代谢

哺乳动物的各项生理活动以24 h为周期呈现节律性变化。稳定的昼夜节律由生物钟系统所精细调控，而昼夜节律的紊乱会导致代谢性疾病的发生。核受体超家族成员REV-ERBα是哺乳动物生物钟的重要组成部分，参与代谢、炎症、免疫和昼夜节律等多种生理过程的调节，是代谢性疾病、炎症性疾病和癌症的潜在治疗靶点。近年来发现了一系列新的REV-ERBα配体，其中大部分在疾病治疗方面具有潜在的应用价值。本文主要介绍核受体REV-ERBα在能量代谢以及炎症反应中的调节作用，以期为代谢综合征及相关疾病的治疗提供新的策略和参考。     

环境应激对雄性大鼠抑郁样行为及皮质酮和褪黑素昼夜节律的影响（英文）

环境应激(environmental stress,ES)是慢性不可预见性轻度应激中的应激成分。慢性不可预见性轻度应激抑郁模型通常用于研究抑郁症的发病机制,也可用于研究昼夜节律系统对抑郁的调节作用。然而,ES在多大程度上能对昼夜节律系统产生直接作用尚待研究。本研究旨在观察ES对大鼠抑郁样行为以及大鼠外周血中皮质酮和褪黑素昼夜节律的影响。大鼠分为对照组、低频率ES组和高频率ES组,通过糖水偏爱测试、旷场测试、体重增加及饮食,观察ES对大鼠抑郁、焦虑样行为的影响,并在24 h内每间隔4 h一次采集大鼠尾静脉血,共7次,采用ELISA检测大鼠外周血中24 h皮质酮和褪黑素节律性变化;选择ZT0一个时间点的血浆,检测调节饮食的胆囊收缩素、神经肽Y及瘦素变化。结果显示,与对照组相比,ES可导致大鼠血清中皮质酮和褪黑素的昼夜节律紊乱、瘦素水平增加、体重增量降低,而未表现出抑郁、焦虑样行为。以上结果提示,ES可引起大鼠皮质酮和褪黑素的昼夜节律紊乱。     

植物褪黑素研究进展

褪黑素最初是在动物中发现的一种吲哚类小分子,具有昼夜节律调节、清除自由基等多种生理功能,还具有改善睡眠的保健作用。后来在植物中也检测到了褪黑素,这表明植物也能合成褪黑素。随着对植物褪黑素的深入研究,发现褪黑素在调控植物生长发育、耐受干旱、高温、低温、高盐、重金属等非生物胁迫、抵御细菌和真菌病害方面具有重要作用。从植物褪黑素合成途径、生长发育调控和胁迫应答反应方面的研究进展进行了综述,以期为植物褪黑素研究提供参考。     

SIRT1功能及其对卵泡发育和卵母细胞成熟的调控作用 *

沉默信息调节因子1(silent information regulator1, SIRT1)是NAD⁺ 依赖的去乙酰化酶,通过使底物发生去乙酰化而参与细胞众多生理功能的调节,在糖脂代谢、衰老、细胞凋亡、氧化应激等过程中发挥了重要作用。另外,众多研究表明,SIRT1是调控动物卵巢老化、卵泡发育和卵母细胞成熟的重要因子,SIRT1 表达下降或活性改变将导致卵母细胞老化,降低动物的繁殖力。为了充分理解SIRT1功能,并通过调控SIRT1活性而延缓卵巢和卵母细胞老化,从而提高动物繁殖力,简述了SIRT1的激活及其参与细胞内调控的生物过程,并从能量代谢、抗氧化胁迫、染色质重塑的角度讨论了SIRT1的主要功能,重点阐述了SIRT1对动物卵泡发育和卵母细胞成熟的调控作用。     

植物褪黑素及其抗逆性研究

褪黑素(N-乙酰-5-甲氧基色胺)是脊椎动物的松果体产生的吲哚类激素,主要参与动物昼夜节律调节.现已证实褪黑素在高等植物中也普遍存在,但对其功能的研究还不甚深入.目前,植物中褪黑素的可能功能包括清除自由基、调节光周期、参与生长调节等.本文简述了植物中褪黑素的研究概况、含量及其合成途径,重点综述了其在提高植物抗逆性方面的功能,并对其研究前景进行展望.     

Melatonin and tryptophan as therapeutic agents against the impairment of the sleep-wake cycle and immunosenescence due to aging in Streptopelia risoria

All organisms present circadian rhythm in most of their physiological functions, and among them there stand out sleep, motor activity, immune function, the secretion of melatonin, and the production and release of numerous neurotransmitters, in particular of serotonin because of its relationship with the aforementioned factors. Aging changes these rhythms, altering sleep quality and contributing to immunosenescence. Treatment with exogenously administered melatonin or tryptophan may restore these impaired functions due to aging. In our animal model (Streptopelia risoria), both the hormone and the amino acid acted on the activity-rest rhythms, modulating the circulating levels of melatonin and serotonin, and increased the cell viability and resistance to induced oxidative stress of blood heterophils, at the same time as enhancing the phagocytic function and neutralizing the superoxide anions deriving from this immune function. Also, in the old individuals, the treatments with melatonin and tryptophan at the concentrations and times of administration considered suitable improved nocturnal rest besides reverting the immunosuppressory and oxidative effects accompanying phagocytosis at these advanced ages.     

Circadian rhythms, oxidative stress, and antioxidative defense mechanisms

Endogenous circadian and exogenously driven daily rhythms of antioxidative enzyme activities and of low molecular weight antioxidants (LMWAs) are described in various phylogenetically distant organisms. Substantial amplitudes are detected in several cases, suggesting the significance of rhythmicity in avoiding excessive oxidative stress. Mammalian and/or avian glutathione peroxidase and, as a consequence, glutathione reductase activities follow the rhythm of melatonin. Another hint for an involvement of melatonin in the control of redox processes is seen in its high-affinity binding to cytosolic quinone reductase 2, previously believed to be a melatonin receptor. Although antioxidative protection by pharmacological doses of melatonin is repeatedly reported, explanations of these findings are still insufficient and their physiological and chronobiological relevance is not yet settled. Recent data indicate a role of melatonin in the avoidance of mitochondrial radical formation, a function which may prevail over direct scavenging. Rhythmic changes in oxidative damage of protein and lipid molecules are also reported. Enhanced oxidative protein modification accompanied by a marked increase in the circadian amplitude of this parameter is detected in the Drosophila mutant rosy, which is deficient in the LMWA urate. Preliminary evidence for the significance of circadian rhythmicity in diminishing oxidative stress comes from clock mutants. In Drosophila, moderately enhanced protein damage is described for the arrhythmic and melatonin null mutant per⁰, but even more elevated, periodic damage is found in the short-period mutant per^s, synchronized to LD 12:12. Remarkably large increases in oxidative protein damage, along with impairment of tissue integrity and—obviously insufficient—compensatory elevations in protective enzymes are observed in a particularly vulnerable organ, the Harderian gland, of another short-period mutant tau, in the Syrian hamster. Mice deficient in the per2 gene homolog are reported to be cancer-prone, a finding which might also relate to oxidative stress. In the dinoflagellate Lingulodinium polyedrum [Gonyaulax polyedra], various treatments that cause oxidative stress result in strong suppressions of melatonin and its metabolite 5-methoxytryptamine (5-MT) and to secondary effects on overt rhythmicity. The glow maximum, depending on the presence of elevated 5-MT at the end of subjective night, decreases in a dose-dependent manner already under moderate, non-lethal oxidative stress, but is restored by replenishing melatonin. Therefore, a general effect of oxidative stress may consist in declines of easily oxidizable signaling molecules such as melatonin, and this can have consequences on the circadian intraorganismal organization and expression of overt rhythms. Recent findings on a redox-sensitive input into the core oscillator via modulation of NPAS2/BMAL1 or CLK/BMAL1 heterodimer binding to DNA indicate a direct influence of cellular redox balance, including oxidative stress, on the circadian clock.     

Heme metabolism and oxidative stress

The role of heme metabolism in oxidative stress development and defense reactions formation in mammals under different stress factors are discussed in the article. Heme metabolism is considered as the totality of synthesis, degradation, transport and exchange processes of exogenous heme and heme liberated from erythrocyte hemoglobin under erythrocyte aging and hemolysis. The literature data presented display normal heme metabolism including mammals heme-binding proteins and intracellular free heme pool and heme metabolism alterations under oxidative stress development. The main attention is focused to the prooxidant action of heme, the interaction of heme transport and lipid exchange, and to the heme metabolism key enzymes (delta-aminolevulinate synthase and heme oxygenase), serum heme-binding protein hemopexin and intracellular heme-binding proteins participating in metabolism adaptation under the action of factors, which cause oxidative stress.     

Circadian rhythms of indoleamines and serotonin N-acetyltransferase activity in the pineal gland

Conclusion The circadian rhythm of melatonin synthesis in the pineal glands of various species has been summarized. The night-time elevation of melatonin content is in most if not all cases regulated by the change of N-acetyltransferase activity. In mammals, the N-acetyltransferase rhythm is controlled by the central nervous system, presumably by suprachiasmatic nuclei in hypothalamus through the superior cervical ganglion. In birds, the circadian oscillator that regulates the N-acetyltransferase rhythm is located in the pineal glands. The avian pineal gland may play a biological clock function to control the circadian rhythms in physiological, endocrinological and biochemical processes via pineal hormone melatonin.     

The daily rhythms of mitochondrial gene expression and oxidative stress regulation are altered by aging in the mouse liver

The circadian clock regulates many cellular processes, notably including the cell cycle, metabolism and aging. Mitochondria play essential roles in metabolism and are the major sites of reactive oxygen species (ROS) production in the cell. The clock regulates mitochondrial functions by driving daily changes in NAD⁺ levels and Sirt3 activity. In addition to this central route, in the present study, we find that the expression of some mitochondrial genes is also rhythmic in the liver, and that there rhythms are disrupted by the Clock^Δ19 mutation in young mice, suggesting that they are regulated by the core circadian oscillator. Related to this observation, we also find that the regulation of oxidative stress is rhythmic in the liver. Since mitochondria and ROS play important roles in aging, and mitochondrial functions are also disturbed by aging, these related observations prompt the compelling hypothesis that circadian oscillators influence aging by regulating ROS in mitochondria. During aging, the expression rhythms of some mitochondrial genes were altered in the liver and the temporal regulation over the dynamics of mitochondrial oxidative stress was disrupted. However, the expression of clock genes was not affected. Our results suggested that mitochondrial functions are combinatorially regulated by the clock and other age-dependent mechanism(s), and that aging disrupts mitochondrial rhythms through mechanisms downstream of the clock.     

Aging impairs neurogenic contraction in guinea pig urinary bladder: role of oxidative stress and melatonin

The incidence of urinary bladder disturbances increases with age, and free radical accumulation has been proposed as a causal factor. Here we investigated the association between changes in bladder neuromuscular function and oxidative stress in aging and the possible benefits of melatonin treatment. Neuromuscular function was assessed by electrical field stimulation (EFS) of isolated guinea pig detrusor strips from adult and aged female guinea pigs. A group of adult and aged animals were treated with 2.5 mg x kg(-1) x day(-1) melatonin for 28 days. Neurotransmitter blockers were used to dissect pharmacologically the EFS-elicited contractile response. EFS induced a neurogenic and frequency-dependent contraction that was impaired by aging. This impairment is in part related to a decrease in detrusor myogenic contractility. Age also decreased the sensitivity of the contraction to pharmacological blockade of purinergic and sensitive fibers but increased the effect of blockade of nitrergic and adrenergic nerves. The density of cholinergic and nitrergic nerves remained unaltered, but aging modified afferent fibers. These changes were associated with an increased level of markers for oxidative stress. Melatonin treatment normalized oxidative levels and counteracted the aging-associated changes in bladder neuromuscular function. In conclusion, these results show that aging modifies neurogenic contraction and the functional profile of the urinary bladder plexus and simultaneously increases the oxidative damage to the organ. Melatonin reduces oxidative stress and improves the age-induced changes in bladder neuromuscular function, which could be of importance in reducing the impact of age-related bladder disorders.     

Photoperiod differentially regulates circadian oscillators in central and peripheral tissues of the Syrian hamster

In many seasonally breeding rodents, reproduction and metabolism are activated by long summer days (LD) and inhibited by short winter days (SD). After several months of SD, animals become refractory to this inhibitory photoperiod and spontaneously revert to LD-like physiology. The suprachiasmatic nuclei (SCN) house the primary circadian oscillator in mammals. Seasonal changes in photic input to this structure control many annual physiological rhythms via SCN-regulated pineal melatonin secretion, which provides an internal endocrine signal representing photoperiod. We compared LD- and SD-housed animals and show that the waveform of SCN expression for three circadian clock genes (Per1, Per2, and Cry2) is modified by photoperiod. In SD-refractory (SD-R) animals, SCN and melatonin rhythms remain locked to SD, reflecting ambient photoperiod, despite LD-like physiology. In peripheral oscillators, Per1 and Dbp rhythms are also modified by photoperiod but, in contrast to the SCN, revert to LD-like, high-amplitude rhythms in SD-R animals. Our data suggest that circadian oscillators in peripheral organs participate in photoperiodic time measurement in seasonal mammals; however, circadian oscillators operate differently in the SCN. The clear dissociation between SCN and peripheral oscillators in refractory animals implicates intermediate factor(s), not directly driven by the SCN or melatonin, in entrainment of peripheral clocks.     

Oxidative stress,mitochondrial DNA mutation,and impairment of antioxidant enzymes in aging

Mitochondria do not only produce less ATP, but they also increase the production of reactive oxygen species (ROS) as by-products of aerobic metabolism in the aging tissues of the human and animals. It is now generally accepted that aging-associated respiratory function decline can result in enhanced production of ROS in mitochondria. Moreover, the activities of free radical-scavenging enzymes are altered in the aging process. The concurrent age-related changes of these two systems result in the elevation of oxidative stress in aging tissues. Within a certain concentration range, ROS may induce stress response of the cells by altering expression of respiratory genes to uphold the energy metabolism to rescue the cell. However, beyond the threshold, ROS may cause a wide spectrum of oxidative damage to various cellular components to result in cell death or elicit apoptosis by induction of mitochondrial membrane permeability transition and release of apoptogenic factors such as cytochrome c. Moreover, oxidative damage and large-scale deletion and duplication of mitochondrial DNA (mtDNA) have been found to increase with age in various tissues of the human. Mitochondria act like a biosensor of oxidative stress and they enable cell to undergo changes in aging and age-related diseases. On the other hand, it has recently been demonstrated that impairment in mitochondrial respiration and oxidative phosphorylation elicits an increase in oxidative stress and causes a host of mtDNA rearrangements and deletions. Here, we review work done in the past few years to support our view that oxidative stress and oxidative damage are a result of concurrent accumulation of mtDNA mutations and defective antioxidant enzymes in human aging.