冬眠哺乳动物氧化应激产生及抗氧化防御机制研究进展

哺乳动物的冬眠是一种季节性异温状态,是对外界恶劣自然环境的一种适应策略。冬眠-阵间觉醒周期中,伴随着生理功能的剧烈变化,从冬眠期间整体代谢的抑制,到阵间觉醒时氧代谢的急剧增加,使动物体内产生了大量的氧自由基。然而,冬眠动物出眠时并未表现出明显的氧化损伤迹象,因此,冬眠哺乳动物被认为是一种天然的抗氧化损伤模型。本文从氧化应激的产生、活性氧的来源、抗氧化防御等方面综述了冬眠哺乳动物对氧化应激的防御,并从其抗氧化的分子调控方面分析了冬眠哺乳动物对氧化应激的适应机制。     

哺乳动物的冬眠

冬眠是动物界,特别是变温动物中普遍存在的一种对寒冷等不利环境的适应现象。但在恒温的哺乳动物中有一些种类也进行冬眠,并且,冬眠时其体温下降,不再维持常温。为与变温动物和一般的恒温动物相区别,特称这类动物为异温动物(heterothermic animal)。本文介绍哺乳动物的冬眠及现在对它的认识。     

哺乳动物的蛰眠: 类型、物种分布与模式

哺乳动物的蛰眠(包括冬眠、夏眠和日蛰眠等)是最具吸引力的生命现象之一,是动物应对寒冷、食物
短缺、干旱等不良环境条件的适应策略之一。冬眠生理学(生态学) 研究具有重要的理论和实际意义。国际学
术界在该领域发展比较迅速,国内发展相对缓慢。本文从哺乳动物蛰眠的季节和持续时间、蛰眠期间所利用能
量的来源和贮存方式、启动蛰眠的信号来源等方面综述了哺乳动物蛰眠的类型;介绍了蛰眠的哺乳动物物种的
系统学分布;并对温带或北极动物的冬眠和冬眠阵及其各阶段的体温和代谢率变化特征、日温剧烈波动环境下
的冬眠特征以及日眠和日眠阵等方面进行了概括介绍,以期能促进国内相关领域的发展。     

瘦蛋白对摄食和能量平衡的调节及其在哺乳动物冬眠中的作用

白色脂肪合成和分泌的瘦蛋白(leptin)作用于下丘脑和外周的代谢产热器官,对摄食和能量平衡起调节作用。摄食和能量平衡的失调,如瘦蛋白抵抗,可以导致肥胖等一系列生理疾病。以体内贮存的脂肪为主要能源物质越冬的冬眠哺乳动物,体重的年周期波动幅度巨大,其摄食和能量平衡调节机制可能不同于一般的非冬眠物种,育肥阶段可能存在瘦蛋白抵抗机制。本文总结了瘦蛋白调节摄食和能量平衡的作用机制以及瘦蛋白对冬眠哺乳动物育肥和冬眠的影响,为进一步研究冬眠哺乳动物的能量平衡提供参考。     

皮质抑素在内分泌系统中的作用

皮质抑素（cortistatin, CST）是一种新型神经内分泌肽,因其在皮质中大量表达并抑制皮质的功能而得名,属于生长抑素基因家族新成员,与生长抑素(somatostatin)具有结构同源性．CST能与生长抑素受体、生长素释放肽受体、Mas相关基因2受体结合,发挥多种生物学效应,如诱导慢波睡眠、参与炎症过程、调节神经内分泌．研究表明,就内分泌系统而言,CST是生长抑素的一种天然替代物．本文重点从细胞、整体水平对CST在内分泌系统中的作用做一简介．     

哺乳动物的冬眠及其影响因素

冬眠不仅是生物学家研究的热点问题,也是其他领域科学家关注的焦点问题之一。结合最近国外的一些研究结果,阐述了哺乳动物冬眠的定义、冬眠期间的行为和生理表现以及影响冬眠的因素,同时也展望了冬眠在未来科学和医学领域中的价值。     

冬眠与免疫

免疫系统是机体防御机制的重要组份。冬眠季节,冬眠动物免疫系统的结构退化、机能抑制,与动物整体的活动相适应,春季恢复。综述民哺乳动物中枢与外周淋巴器官和免疫反应的季节性变化。对调控免疫系统变化的环境因素和受环境因素影响的内源性生理节律对免疫系统冬眠季节的抑制机理作了介绍,更从冬眠对免疫的抑制联系到冬眠净化机体内外环境、冬眠与肿瘤、冬眠与辐射乃至冬眠与长寿等临床关心的实验研究作了简要介绍。     

科学家发现冬眠的鱼

鱼是否能够像熊那样冬眠？据美国《科学》杂志在线报道，一种南极鳕鱼（Notothenia coriiceps）便很有可能冬眠。科学家发现，为了适应阳光的减少，这种鳕鱼能够将身体的新陈代谢速度减缓50％，同时将心率减半，并对触摸表现得很迟钝——这与哺乳动物的冬眠很类似。然而生物学家并没有搞清鳕鱼如何以及为什么会进化出这样的行为。研究人员在3月5日的《公共科学图书馆》网络版上报告了这一研究成果。     

脂筏与精子膜信号传导

脂筏是细胞膜内由特殊脂质与蛋白质构成的微域。小窝是脂筏的一种形式,小窝标记蛋白有小窝蛋白和小窝舟蛋白。脂筏或小窝与生物信号传导、细胞蛋白转运和胆固醇平衡有关。最近实验证实哺乳动物精子膜具有脂筏结构,脂筏与膜胆固醇外逸对于启动受精的信号传导具有重要作用。     

蛇胸腺巨噬细胞的形态学研究

近年的研究表明，哺乳动物胸腺巨噬细胞具有一定的异质性。巨噬细胞不仅具有吞噬凋亡的Ｔ淋巴细胞的功能，而且还具有分泌细胞因子和呈递抗原的作用，是构成胸腺微环境的一种重要的免疫调节细胞。但是，对非哺乳动物胸腺巨噬细胞异质性和生理功能方面的探讨还未见报道。本...     

The role of medial septal area in the neural control over hibernation

Hibernation (winter sleep) is a kind of unique adaptive behavior of small mammals subjected to fine and complex central control. One of the most promising approaches to this problem is a search for the mechanisms providing brain control under conditions of a sharp decrease in temperature, (virtually, to zero) and metabolic rate. Studies conducted at the Laboratory of System Organization of Neurons under the supervision of Professor O.S. Vinogradova confirmed the hypothesis of the special role of the septohippocampal system in the control of winter sleep. Together with a brief characterization of hibernation in general, the data obtained at the Laboratory are also summarized in the review. The experimental evidence for the role of the medial septal area as a "sentry post" in hibernation is presented.     

Response of Gut Microbiota to Fasting and Hibernation in Syrian Hamsters

Although hibernating mammals wake occasionally to eat during torpor, this period represents a state of fasting. Fasting is known to alter the gut microbiota in nonhibernating mammals; therefore, hibernation may also affect the gut microbiota. However, there are few reports of gut microbiota in hibernating mammals. The present study aimed to compare the gut microbiota in hibernating torpid Syrian hamsters with that in active counterparts by using culture-independent analyses. Hamsters were allocated to either torpid, fed active, or fasted active groups. Hibernation was successfully induced by maintaining darkness at 4°C. Flow cytometry analysis of cecal bacteria showed that 96-h fasting reduced the total gut bacteria. This period of fasting also reduced the concentrations of short chain fatty acids in the cecal contents. In contrast, total bacterial numbers and concentrations of short chain fatty acids were unaffected by hibernation. Denaturing gradient gel electrophoresis of PCR-amplified 16S rRNA gene fragments indicated that fasting and hibernation modulated the cecal microbiota. Analysis of 16S rRNA clone library and species-specific real-time quantitative PCR showed that the class Clostridia predominated in both active and torpid hamsters and that populations of Akkermansia muciniphila, a mucin degrader, were increased by fasting but not by hibernation. From these results, we conclude that the gut microbiota responds differently to fasting and hibernation in Syrian hamsters.Some mammalian species have evolved with the physiological phenomenon of hibernation to survive unfavorable winter environments (9). Hibernation is realized by entering torpor in order to eliminate the need to maintain a constant, high body temperature. During torpor, typical hibernating mammals, such as hamsters and ground squirrels, lower their body temperature to only a few degrees above ambient temperatures to reduce energy expenditure. Torpor is interrupted by periods of intense metabolic activity. During these interbout arousals, physiological parameters are restored rapidly to near-normal levels. Thus, hibernators alternate between hypothermic and euthermic states during hibernation.Some hibernating mammals awake to forage during torpor, while food-storing hibernators such as hamsters eat cached food during interbout arousals. However, hibernation essentially involves periods of fasting. Fasting is known to affect the gut microbiota in nonhibernating mammals such as mice (12); therefore, it is possible that hibernation also influences the gut microbiota. Given that the gut microbiota plays important roles in mammalian tissue development and homeostasis (28), it was of interest to investigate the changes in the gut microbiota that may take place during hibernation. To date, this issue has received little attention; to our knowledge, there are only two reports on the gut microbiota in hibernating mammals. Schmidt et al. showed that although the total counts of coliforms, streptococci, and psychrophilic organisms in the feces of arctic ground squirrels held in a cold room at 3°C remained constant the composition changed, with a decrease in coliform count and a 1,000-fold increase in the number of aerobic psychrophilic gram-negative bacteria (31). Barnes and Burton reported that although there was some reduction in total numbers of viable bacteria in the cecum during hibernation, composition of the microbiota remained stable (6). In terms of amphibians, Banas et al. and Gossling et al. reported a reduction and compositional changes of the gut microbiota in hibernating leopard frogs (4, 5, 18, 19).Only 20 to 40% of bacterial species from the mammalian intestinal tract can be cultured and identified using classical culture methods (22, 34, 36). In contrast, culture-independent methods based on the amplification of bacterial 16S rRNA genes by PCR have revealed a great diversity of microbiota in environmental samples (3, 37). The present study compared the gut microbiota in hibernating torpid Syrian hamsters with that in active counterparts by using culture-independent analyses.     

Circannual control of hibernation by HP complex in the brain

Seasonal hibernation in mammals is under a unique adaptation system that protects organisms from various harmful events, such as lowering of body temperature (Tb), during hibernation. However, the precise factors controlling hibernation remain unknown. We have previously demonstrated a decrease in hibernation-specific protein (HP) complex in the blood of chipmunks during hibernation. Here, HP is identified as a candidate hormone for hibernation. In chipmunks kept in constant cold and darkness, HP is regulated by an individual free-running circannual rhythm that correlates with hibernation. The level of HP complex in the brain increases coincident with the onset of hibernation. Such HP regulation proceeds independently of Tb changes in constant warmth, and Tb decreases only when brain HP is increased in the cold. Blocking brain HP activity using an antibody decreases the duration of hibernation. We suggest that HP, a target of endogenously generated circannual rhythm, carries hormonal signals essential for hibernation to the brain.     

Hibernation: when good clocks go cold

Hibernating animals have been a successful model system for elucidating fundamental properties of many physiological systems. Over the past 50 years, a diverse literature has emerged on the role of the circadian system in control and expression of winter torpor in several orders of birds and mammals. This body of research has also provided insights to circadian function in non-hibernating species. The aim of this review is to examine how this work applies to questions of general interest to chronobiologists, such as temperature compensation, the 2-oscillator model of entrainment, and suprachiasmatic nucleus (SCN) function. Convergent lines of evidence suggest a role for the SCN in timing daily torpor and controlling several parameters of hibernation. In addition to its role as a circadian pacemaker, the SCN may serve a noncircadian function in hibernators related to maintenance of energy balance.     

Advances in molecular biology of hibernation in mammals

Mammalian hibernation is characterized by profound reductions in metabolism, oxygen consumption and heart rate. As a result, the animal enters a state of suspended animation where core body temperatures can plummet as low as -2.9 degrees C. Not only can hibernating mammals survive these physiological extremes, but they also return to a normothermic state of activity without reperfusion injury or other ill effects. This review examines recent findings on the genes, proteins and small molecules that control the induction and maintenance of hibernation in mammals. The molecular events involved with remodeling metabolism, inducing hypothermia and maintaining organ function are discussed and considered with respect to analogous processes in non-hibernating mammals such as mice and humans. The advent of sequenced genomes from three distantly related hibernators, a bat, hedgehog and ground squirrel, provides additional opportunities for molecular biologists to explore the mechanistic aspects of this biological adaptation in greater detail.     

Hibernation does not reduce cortical bone density,area or second moments of inertia in woodchucks (Marmota monax)

Long periods of inactivity in most mammals result in bone loss that may not be completely recoverable during an individual's lifetime regardless of future activity. Prolonged inactivity is normal during hibernation, but it remains uncertain whether hibernating mammals suffer decreased bone properties after hibernation that affects survival. We test the hypothesis that relative cortical area (C_A), apparent density, bone area fraction (B.Ar/T.Ar), and moments of inertia do not differ between museum samples of woodchucks (Marmota monax) collected before and after hibernation. We used peripheral quantitative computed tomography to examine bone geometry in the femur, tibia, humerus and mandible. We see little evidence for changes in bone measures with hibernation supporting our hypothesis. In fact, when including subadults to increase sample sizes and controlling age statistically, we observed a trend toward increased bone properties following hibernation. Diaphyses were significantly denser in the humerus, femur, and tibia after hibernation, and relative mandibular cortical area was significantly larger. Similarly, relative mechanical indices were significantly larger in the mandible after hibernation. Although tests of individual measures in many cases were not significantly different prehibernation versus posthibernation, the overall pattern of average increase posthibernation was significant for relative C_A and densities as well as relative diaphyseal mechanical indices when examining outcomes collectively. The exception to this pattern was a reduction in metaphyseal trabecular bone following hibernation. Individually, only humeral B.Ar/T.Ar was significantly reduced, but the average reduction in trabecular measures post‐hibernation was significant when examined collectively. Because the sample included subadults, we suggest that much of the increased bone relates to their continued growth during hibernation. Our results indicate that woodchucks are more similar to large hibernators that maintain skeletal integrity compared to smaller‐bodied hibernators that may lose bone. This result suggests a potential size‐related trend in bone response to hibernation across mammals. J. Morphol., 2012. © 2012Wiley Periodicals, Inc.     

Morphological study of the heart innervation of bats Myotis daubentoni and Eptesicus serotinus (Microchiroptera: Vespertilionidae) during hibernation

The capability of bats to have heart rates fewer than 10 beats/min during hibernation and greater than 700 beats/min during flight surprises biologists and cardiologists. Cardioacceleration of hibernating bats is considered to be a function of their intracardiac nervous system. In the present study we investigated the morphology of the heart innervation of ten M. daubentoni and four E. serotinus bats during their natural hibernation in order to determine which intracardiac structures may be involved in cardioacceleration during their short-term (in av. 15-30 min) arousal from hibernation. The primary conclusions were as follows: (1) The innervation pattern of bats differs from many mammals in that bats have: (a) a subepicardiac nerve plexus which is vastly developed and contains a large number of intrinsic ganglia on both atria and ventricles, and (b) very small diameter axons within the unmyelinated nerve fibres, from 0.15 to 0.7 microm. (2) During hibernation an intercellular space of the sinoatrial node of M. daubentoni bats was in part filled with a cottony substance which can presumably be considered to be a temporary barrier between the conductive cardiomyocytes and nerve fibres. (3) In the hibernating bats, the acetylcholine vesicles were aggregated in the synaptic bulbs away from the presynaptic membrane. Possibly, the aggregation of the acetylcholine vesicles is capable of modifying cholinergic influences on the heart activity of hibernating bats. (4) The dense cores of catecholamine synaptic vesicles within, adrenergic axon terminals were seldomly observed in hibernating bats. Therefore, catecholamines probably do not play a crucial role in the cardioacceleration of hibernating bats.     

Primary sleep in vertebrates and its role in the genesis of hypobiosis in poikilotherms and hibernation in mammals

New data are presented on the homology between winter hibernation and hypobiosis in poikilotherms, as well as one of the resting forms of the primary sleep in vertebrates. Different stages of formation of a cycle "awakefulness-sleep" in evolution of vertebrates are discussed. On the basis of universal behavioural, somato-vegetative, neurophysiological, neurochemical correlates of resting forms, hypobiosis and winter hibernation, a discussion is made of the problem of genetic fixation in the genotype and phenotype of heterothermic mammals (hibernating ones) of those characters which are typical of the sleep in homoiothermic and poikilothermic vertebrates.