Circadian variation in the acetylcholinesterase activity of specific rat brain areas

Abstract

Acetylcholinesterase (AChE) activity of the adenohypophysis, cerebellum, cerebral cortex, hypothalamus, amygdala, hippocampus, midbrain, pons, medulla oblongata and caudate nucleus was determined by a spectro‐photometric method in adult, male rats adapted toan LD 12:12cycle. Results of the study show that AChE activity is highest during the light phase and lowest during the dark phase of the cycle in all the brain areas studied except the adenohypophysis, cerebellum, hippocampus and hypothalamus. These findings expand earlier observations on the circadian variation in rat brain AChE activity and suggests a relationship with reported circadian variation in the acetylcholine levels of rat brain.     

The human circadian clock and aging

The suprachiasmatic nucleus (SCN) of the hypothalamus is implicated in the timing of a wide variety of circadian processes. Since the environmental light-dark cycle is the main zeitgeber for many of the rhythms, photic information may have a synchronizing effect on the endogenous clock of the SCN by inducing periodic changes in the biological activity of certain groups of neurons. By studying the brains obtained at autopsy of human subjects, marked diurnal oscillations were observed in the neuropeptide content of the SCN. Vasopressin, for example, one of the most abundant peptides in the human SCN, exhibited a diurnal rhythm, with low values at night and peak values during the early morning. However, with advancing age, these diurnal fluctuations deteriorated, leading to a disrupted cycle with a reduced amplitude in elderly people. These findings suggest that the synthesis of some peptides in the human SCN exhibits an endogenous circadian rhythmicity, and that the temporal organization of these rhythms becomes progressively disturbed in senescence. (Chronobiology International, 17(3), 245-259, 2000)     

Procedures for numerical analysis of circadian rhythms

This article reviews various procedures used in the analysis of circadian rhythms at the populational, organismal, cellular and molecular levels. The procedures range from visual inspection of time plots and actograms to several mathematical methods of time series analysis. Computational steps are described in some detail, and additional bibliographic resources and computer programs are listed.     

Setting the biological time in central and peripheral clocks during ontogenesis

In mammals, the principal circadian clock within the suprachiasmatic nucleus (SCN) entrains the phase of clocks in numerous peripheral tissues and controls the rhythmicity in various body functions. During ontogenesis, the molecular mechanism responsible for generating circadian rhythmicity develops gradually from the prenatal to the postnatal period. In the beginning, the maternal signals set the phase of the newly developing fetal and early postnatal clocks, whereas the external light-dark cycle starts to entrain the clocks only later. This minireview discusses the complexity of signaling pathways from mothers and the outside world to the fetal and newborn animals' circadian clocks.     

Serotonergic innervation of the hypothalamic suprachiasmatic nucleus and photic regulation of circadian rhythms

Converging lines of evidence have firmly established that the hypothalamic suprachiasmatic nucleus (SCN) is a light-entrainable circadian oscillator in mammals, critically important for the expression of behavioral and physiological circadian rhythms. Photic information essential for the daily phase resetting of the SCN circadian clock is conveyed directly to the SCN from retinal ganglion cells via the retinohypothalamic tract. The SCN also receives a dense serotonergic innervation arising from the mesencephalic raphe. The terminal fields of retinal and serotonergic afferents within the SCN are co-extensive, and serotonergic agonists can modify the response of the SCN circadian oscillator to light. However, the functional organization and subcellular localization of 5HT receptor subtypes in the SCN are just beginning to be clarified. This information is necessary to understand the role 5HT afferents play in modulating photic input to the SCN. In this paper, we review evidence suggesting that the serotonergic modulation of retinohypothalamic neurotransmission may be achieved via at least two different cellular mechanisms: 1) a postsynaptic mechanism mediated via 5HT_1A or 5ht₇ receptors located on SCN neurons; and 2) a presynaptic mechanism mediated via 5HT_1B receptors located on retinal axon terminals in the SCN. Activation of either of these 5HT receptor mechanisms in the SCN by specific 5HT agonists inhibits the effects of light on circadian function. We hypothesize that 5HT modulation of photic input to the SCN may serve to set the gain of the SCN circadian system to light.     

Light-induced tyrosine phosphorylation of BIT in the rat suprachiasmatic nucleus

Circadian changes of protein tyrosine phosphorylation in the hypothalamic suprachiasmatic nucleus have been studied using rats maintained under 12-h light/ 12-h dark cycles as well as constant dark conditions. We found that tyrosine phosphorylation of BIT (brain immunoglobulin-like molecule with tyrosine-based activation motifs), a transmembrane glycoprotein of 90-95 kDa, was higher in the light period than in the dark period and was increased after light exposure in the dark period. Similar changes in tyrosine phosphorylation were observed under constant dark conditions, but its amplitude was weaker than that in 12-h light/12-h dark cycles. As the tyrosine-phosphorylated form of BIT is able to bind to the Src homology 2 domain of a protein tyrosine phosphatase, SHP-2, we examined association of these proteins in suprachiasmatic nucleus extracts and found that SHP-2 was coprecipitated with BIT in parallel with its tyrosine phosphorylation. These results suggest that tyrosine phosphorylation of BIT might be involved in light-induced entrainment of the circadian clock.     

树■排尿的昼夜节律及其在视交叉上核损毁后的变化

为探讨树视交叉上核是否参与泌尿昼夜节律的调控,对正常树及视交叉上核损毁后的树排尿的昼夜时间规律进行了观测分析。结果表明,正常树排尿呈现明显的昼夜节律———白天尿量为全天尿量的（８８５２±１５４０）％;视交叉上核损毁后,树排尿的昼夜节律明显改变———白天尿量仅为全天尿量的（６２８６±１８１８）％,同时树的尿量（特别是夜间的尿量）明显憎多。以上结果说明视交叉上核在树体内也参与了泌尿昼夜节律的调节。     

大鼠交叉上核中SS和VIPmRNA昼夜节律的研究

用Ｎｏｒｔｈｅｒｎｂｌｏｔ杂交方法分析ＬＤ循环条件下大鼠ＳＣＮ和ＣＸ的ＳＳｍＲＮＡ和ＶＩＰｍＲＮＡ丰度的昼夜变化,结果表明这两种ｍＲＮＡ昼夜间的相对含量在ＣＸ中基本不变,而在ＳＣＮ中则呈现规律性变化的模式,与双侧眼球摘除后大鼠ＳＣＮｍＲＮＡ丰度昼夜变化的实验结果相比较,ＳＳｍＲＮＡ丰度变化不受外界光的影响,具有内源性的昼夜节律,而ＶＩＰｍＲＮＡ丰度的昼夜变化则受外界光的影响。     

Orcadian Rhythm of Serotonin Binding in Rat Brain—I. Effect of the Light-Dark Cycle

High affinity serotonin binding to rat brain membranes showed a circadian rhythm with minimal binding at 1000 and a maximal binding at 0000. Brain serotonin levels were almost inverse to the rhythm of serotonin binding. Under reverse light-dark conditions, lights on from 1900 to 0700, a significant phase shift in serotonin binding and concentration of about 8-10 hr was found. The adaptation of the rats to the inverse light-dark cycle was ascertained by plasma ACTH and corticosterone assay.     

Different patterns of circadian oscillation in the suprachiasmatic nucleus of hamster,mouse, and rat

Although spontaneous neural firing in the mammalian suprachiasmatic nucleus is accepted to peak once during mid-subjective day, dual activity peaks have been reported in horizontal brain slices taken from hamsters. These two peaks were interpreted as new evidence for the theory of dual circadian oscillators and raised the expectation that such activity would be found in other circadian model systems. We examined hamster, mouse, and rat slices in both coronal and horizontal planes and found a second peak of activity only in hamster horizontal preparations. This raises interesting questions about the relative circadian physiology of these important experimental animals.Abbreviations CT circadian time - SCN suprachiasmatic nucleus P.W. Burgoon and P.T. Lindberg contributed equally to this work.     

哺乳动物昼夜节律组构中的下丘脑视交叉上核和松果腺

哺乳动物下丘脑视交叉上核（SCN）是昼夜节律最主要的起搏器,控制着机体的生理和行为的节律。它具有自身内在的节律性,同时也受光照周期信号和一些内源性化学物质的调节。检查腺分泌裉黑素（MEL）受SCN的调控,MEL通过作用于SCN上高亲和性MEL受体,启动第二、第三信使系统,调整SCN的昼夜节律活动。这种调整具有时间敏感性。     

Circadian modulation in photic induction of Fos-like immunoreactivity in the suprachiasmatic nucleus cells of diurnal chipmunk,Eutamias asiaticus

Photic induction of immediate early genes including c-fos in the suprachiasmatic nucleus (SCN) has been well demonstrated in the nocturnal rodents. On the other hand, in diurnal rodents, no data is available whether the light can induce c-fos or Fos in the SCN. We therefore examined whether 60 min light exposure induces Fos-like immunoreactivity (Fos-lir) in the SCN cells of diurnal chipmunks and whether the induction is phase dependent, comparing with the results in nocturnal hamsters. We also examined an effect of light on the locomotor activity rhythm under continuous darkness. Fos-lir was induced in the chipmunk SCN. The induction was clearly phase dependent. The light during the subjective night induced strong expression of Fos-lir. This phase dependency is similar to that in hamsters. However, unlike in hamsters, the Fos-lir was induced in some SCN cells of chipmunks exposed to light during the subjective day. In the locomotor rhythm, on the other hand, the light pulse failed to induce the phase shift at phases at which the Fos-lir was induced. These results suggest that the photic induction of Fos-lir in the diurnal chipmunks is gated by a circadian oscillator as well as in the nocturnal hamsters. However, the functional role of Fos protein may be different in the diurnal rodents from in the nocturnal rodents.     

Spatial and temporal regulation of mitogen-activated protein kinase phosphorylation in the mouse suprachiasmatic nucleus

Circadian and photic regulation of mitogen-activated protein kinase (MAPK) has been shown to associate closely with the function of the circadian clock in vertebrate clock tissues such as the mouse suprachiasmatic nucleus (SCN). Here we show that, in the central region of the mouse SCN, MAPK exhibited circadian and daily rhythms in phosphorylation with a peak at (subjective) night, and this activation was sustained for at least 8 h. In contrast, in the dorsomedial region of the SCN, MAPK showed an overt rhythm in phosphorylation with a transient peak at early subjective day, which was antiphase to that in the central region. Noticeably, the phospho-MAPK-immunoreactive cells observed in the dorsomedial region were distributed from the rostral to the caudal end of the SCN, whereas those observed in the central region were localized within the middle SCN along the rostral-caudal axis. Furthermore, a 15-min light pulse given at subjective night transiently evoked MAPK phosphorylation throughout the ventrolateral region of the SCN peaking within 15 min after the light onset, whereas nighttime-phosphorylated MAPK signals in the central-middle SCN become undetectable within 60 min after the light onset. Thus, the mode of circadian and photic regulation of MAPK phosphorylation varies remarkably among the three subregions within the SCN, suggesting divergent and cell type-specific roles of MAPK in the clock system of the mouse SCN.     

PINEAL INFLUENCE ON ANNUAL NUCLEAR VOLUME CHANGES IN VENTROMEDIAL HYPOTHALAMIC NUCLEUS (VMH) NEURONS OF THE MALE WISTAR RAT

The ventromedial hypothalamic nucleus (VMH) regulates various autonomic, endocrine, and behavioral activities. These activities show annual changes, and the pineal gland is involved in their adjustment to environmental cues. Therefore, this study investigated whether the VMH belongs to the effector structures of the pineal gland. To abolish the rhythmic melatonin release, male Wistar rats were subjected to pinealectomy (PX) or ganglionectomy (sympathetic denervation of the pineal gland, GX) regularly at the beginning of any of the four seasons. Brains from animals of PX-, GX-, and sham-operated control groups were prepared 3 months later for measurement of the nuclear volume, which changes according to the general gene activity. At each of the four seasons, 2000 nuclei of VMH neurons stemming from 18 animals per group were measured to obtain both seasonal daily mean values and annual mean values,respectively, as well as to calculate annual curves of the nuclear volume using empirical regression and locally adjusted polynomial approximation. The major findings are the following. First,inactivation of the pineal function influences the nuclear activity of VMH neurons. (2) PX and GX mainly depress the nuclear activity, indicating that the pineal influence on the VMH may predominantly be a stimulatory one. Third, size and direction of the changes caused by PX and GX vary in a seasonally dependent manner. Fourth, the annual rhythm of the nuclear activity of the VMH is modified by PX and GX.To explain how the pineal effects on the VMH may be mediated, a possible inhibitory influence of the suprachiasmatic nucleus (SCN),which has been activated in the same animals following both PX and GX, is discussed. In conclusion, the results confirm that the nuclear activity of VMH neurons underlies pineal influences. This also indicates an involvement of the pineal gland in many VMH-regulated functions.(Chronobiology International,17(1),15–28, 2000)     

Pineal influence on annual nuclear volume changes in ventromedial hypothalamic nucleus (VMH) neurons of the male Wistar rat

The ventromedial hypothalamic nucleus (VMH) regulates various autonomic, endocrine, and behavioral activities. These activities show annual changes, and the pineal gland is involved in their adjustment to environmental cues. Therefore, this study investigated whether the VMH belongs to the effector structures of the pineal gland. To abolish the rhythmic melatonin release, male Wistar rats were subjected to pinealectomy (PX) or ganglionectomy (sympathetic denervation of the pineal gland, GX) regularly at the beginning of any of the four seasons. Brains from animals of PX-, GX-, and sham-operated control groups were prepared 3 months later for measurement of the nuclear volume, which changes according to the general gene activity. At each of the four seasons, 2000 nuclei of VMH neurons stemming from 18 animals per group were measured to obtain both seasonal daily mean values and annual mean values,respectively, as well as to calculate annual curves of the nuclear volume using empirical regression and locally adjusted polynomial approximation. The major findings are the following. First,inactivation of the pineal function influences the nuclear activity of VMH neurons. (2) PX and GX mainly depress the nuclear activity, indicating that the pineal influence on the VMH may predominantly be a stimulatory one. Third, size and direction of the changes caused by PX and GX vary in a seasonally dependent manner. Fourth, the annual rhythm of the nuclear activity of the VMH is modified by PX and GX.To explain how the pineal effects on the VMH may be mediated, a possible inhibitory influence of the suprachiasmatic nucleus (SCN),which has been activated in the same animals following both PX and GX, is discussed. In conclusion, the results confirm that the nuclear activity of VMH neurons underlies pineal influences. This also indicates an involvement of the pineal gland in many VMH-regulated functions.(Chronobiology International,17(1),15-28, 2000)     

Phase advances of circadian rhythms in somatostatin depleted rats: effects of cysteamine on rhythms of locomotor activity and electrical discharge of the suprachiasmatic nucleus

Somatostatin is synthesized in the suprachiasmatic nucleus (SCN), a circadian pacemaker in mammals. To explore the functional significance of somatostatin in the circadian system, we examined rhythms of rat locomotor activity and electrical firing rate of SCN neurons in the brain slice after temporal depletion of somatostatin levels in the SCN. Intraperitoneal administration of cysteamine (200 mg/kg), a somatostatin depletor, significantly reduced somatostatin level in the in vivo SCN 5 min after injection and kept low level as long as 3 to 4 days. This administration, on the other hand, induced significant phase advances of about 51 min in the subsequent free-running rhythm of locomotor activity of the rat. A marked phase advance in the circadian rhythm of firing rate in the SCN was also observed after administration of cysteamine in coronal hypothalamic slices. These persistent phase shifts after administration of a somatostatin depletor may suggest that the change of somatostatin level in the SCN have a feedback influence on the circadian pacemaker.Abbreviations SCN suprachiasmatic nucleus - AVP arginine-vasopressin - VIP vasoactive intestinal polypeptide - CT circadian time - ZT zeitgeber time - i.p. intraperitoneally - 12L:12D 12 h light and 12 h dark - ANOVA analysis of variance     

Evolution of time-keeping mechanisms: early emergence and adaptation to photoperiod

Virtually all species have developed cellular oscillations and mechanisms that synchronize these cellular oscillations to environmental cycles. Such environmental cycles in biotic (e.g. food availability and predation risk) or abiotic (e.g. temperature and light) factors may occur on a daily, annual or tidal time scale. Internal timing mechanisms may facilitate behavioural or physiological adaptation to such changes in environmental conditions. These timing mechanisms commonly involve an internal molecular oscillator (a 'clock') that is synchronized ('entrained') to the environmental cycle by receptor mechanisms responding to relevant environmental signals ('Zeitgeber', i.e. German for time-giver). To understand the evolution of such timing mechanisms, we have to understand the mechanisms leading to selective advantage. Although major advances have been made in our understanding of the physiological and molecular mechanisms driving internal cycles (proximate questions), studies identifying mechanisms of natural selection on clock systems (ultimate questions) are rather limited. Here, we discuss the selective advantage of a circadian system and how its adaptation to day length variation may have a functional role in optimizing seasonal timing. We discuss various cases where selective advantages of circadian timing mechanisms have been shown and cases where temporarily loss of circadian timing may cause selective advantage. We suggest an explanation for why a circadian timing system has emerged in primitive life forms like cyanobacteria and we evaluate a possible molecular mechanism that enabled these bacteria to adapt to seasonal variation in day length. We further discuss how the role of the circadian system in photoperiodic time measurement may explain differential selection pressures on circadian period when species are exposed to changing climatic conditions (e.g. global warming) or when they expand their geographical range to different latitudes or altitudes.