ABSTRACT
Circadian clock is an internal autonomous time-keeping system, including central clocks located in the suprachiasmatic nucleus (SCN) and peripheral clocks. The molecular circadian clock consists of a set of interlocking transcriptional-translational feedback loops that take the clock-controlled genes 24 h to oscillate. The core mechanism of molecular circadian clock is that CLOCK/BMAL1 dimer activates the transcription of cryptochromes (CRYs) and Periods (PERs), which act as transcriptional repressors of further CLOCK/BMAL1-mediated transcription. In addition to this basic clock, there is an additional sub-loop of REV-ERBα and RORα regulating the transcription of BMAL1. Approximately 80% protein-coding genes demonstrate significant rhythmicity. The earth rotation is responsible for the generation of the daily circadian rhythms. To coordinate metabolic balance and energy availability, almost all organisms adapt to the rhythm. Studies have shown that circadian clock integrating with metabolic homeostasis increases the efficiency of energy usage and coordinates with different organs in order to adapt to internal physiology and external environment soon. As the central organ of metabolism, the liver performs various physiological activities nearly all controlled by the circadian clock. There are multiple interactive regulation mechanisms between the circadian clock and the regulation of liver metabolism. The misalignment of metabolism with tissue circadian is identified as a high-risk factor of metabolic diseases. This article reviews the recent studies on circadian physiological regulation of liver glucose, lipid and protein metabolism and emphasizes oscillation of mitochondrial function. We also take an outlook for new methods and application of circadian clock research in the future.
Subject(s)
CLOCK Proteins , Circadian Clocks/genetics , Circadian Rhythm , Liver , Suprachiasmatic NucleusABSTRACT
Most organisms have adapted to a circadian rhythm that follows a roughly 24-hour cycle, which is modulated by both internal (clock-related genes) and external (environment) factors. In such organisms, the central nervous system (CNS) is influenced by the circadian rhythm of individual cells. Furthermore, the period circadian clock 2 (Per2) gene is an important component of the circadian clock, which modulates the circadian rhythm. Per2 is mainly expressed in the suprachiasmatic nucleus (SCN) of the hypothalamus as well as other brain areas, including the midbrain and forebrain. This indicates that Per2 may affect various neurobiological activities such as sleeping, depression, and addiction. In this review, we focus on the neurobiological functions of Per2, which could help to better understand its roles in the CNS.
Subject(s)
Brain , Central Nervous System , Circadian Clocks , Circadian Rhythm , Depression , Hypothalamus , Mesencephalon , Neurotransmitter Agents , Prosencephalon , Suprachiasmatic NucleusABSTRACT
Circadian rhythms orchestrate biochemical and physiological processes in living organisms to respond the day/night cycle. In mammals, nearly all cells hold self-sustained circadian clocks meanwhile couple the intrinsic rhythms to systemic changes in a hierarchical manner. The suprachiasmatic nucleus (SCN) of the hypothalamus functions as the master pacemaker to initiate daily synchronization according to the photoperiod, in turn determines the phase of peripheral cellular clocks through a variety of signaling relays, including endocrine rhythms and metabolic cycles. With aging, circadian desynchrony occurs at the expense of peripheral metabolic pathologies and central neurodegenerative disorders with sleep symptoms, and genetic ablation of circadian genes in model organisms resembled the aging-related features. Notably, a number of studies have linked longevity nutrient sensing pathways in modulating circadian clocks. Therapeutic strategies that bridge the nutrient sensing pathways and circadian clock might be rational designs to defy aging.
Subject(s)
Animals , Humans , Aging , Metabolism , Pathology , Circadian Clocks , Suprachiasmatic Nucleus , Metabolism , PathologyABSTRACT
Mammals synchronize their circadian activity primarily to the cycles of light and darkness in the environment. Circadian rhythm is controlled by the central clock in the hypothalamic suprachiasmatic nucleus (SCN) and the peripheral clocks in various tissues. More importantly, the central clock can integrate photic/nonphotic signals to generate rhythmic outputs, and then drive the slave oscillators in peripheral tissues through neuroendocrine and behavioral signals. Human reproductive activities, as some other physiological functions, are controlled by the biological clocks. Accumulating lines of epidemiological and genetic evidence indicate that disruption of circadian clock can be directly involved in multiple pathological processes, including infertility. In this review, we mainly discuss the presence of a circadian clock in reproductive tissues and its roles in follicles development, ovulation, spermatogenesis, fertilization and embryo implantation, etc. As the increased shift work and assisted reproductive technologies possibly disrupt circadian rhythmicity to impact reproduction, the importance of circadian rhythms should be highlighted in the regulation of reproductive process.
Subject(s)
Animals , Biological Clocks , Circadian Rhythm , Hypothalamus , Light , Reproduction , Suprachiasmatic NucleusABSTRACT
El sueño forma parte de un ciclo circadiano (vigilia/sueño), proceso fisiológico necesario para el organismo. Durante la adolescencia, un período de importantes cambios fisiológicos, se producen en forma frecuente una serie de alteraciones en dicho proceso. Algunas de las principales causas son el cambio de hábito y la regulación de las normas sociales. El principal trastorno en esta edad es la privación crónica de sueño, que provoca trastornos en el aprendizaje, en la conducta y hor- monales. En el presente artículo se comentan además otros trastornos frecuentes como el insomnio, Síndrome de la Fase Retardada de Sueño e hipersomnias.
The sleep is circadian rhythms (wake/sleep), physiologic process necessary for the organism. The Adolescence, it's a very important time of physiologic changes. As with most sleep behaviors, these trends reflect the physiologic- chronobiologic, developmental, and social-environmental changes. The chronic sleep deprivation is the principal sleep problem in this age. Psychiatric, learning and hormonal disturbances can result from chronic sleep deprivation. Furthermore, another sleep problem can be insomnia, delayed sleep phase syndrome and hypersomnia.
Subject(s)
Humans , Adolescent , Sleep Wake Disorders/diagnosis , Sleep Wake Disorders/physiopathology , Sleep Wake Disorders/therapy , Suprachiasmatic Nucleus , Age Factors , Circadian Rhythm/physiology , Sociological FactorsABSTRACT
BACKGROUND: In mammals, the master circadian pacemaker is localized in an area of the ventral hypothalamus known as the suprachiasmatic nucleus (SCN). Previous studies have shown that pacemaker neurons in the SCN are highly coupled to one another, and this coupling is crucial for intrinsic self-sustainability of the SCN central clock, which is distinguished from peripheral oscillators. One plausible mechanism underlying the intercellular communication may involve direct electrical connections mediated by gap junctions. METHODS: We examined the effect of mefloquine, a neuronal gap junction blocker, on circadian Period 2 (Per2) gene oscillation in SCN slice cultures prepared from Per2::luciferase (PER2::LUC) knock-in mice using a real-time bioluminescence measurement system. RESULTS: Administration of mefloquine causes instability in the pulse period and a slight reduction of amplitude in cyclic PER2::LUC expression. Blockade of gap junctions uncouples PER2::LUC-expressing cells, in terms of phase transition, which weakens synchrony among individual cellular rhythms. CONCLUSION: These findings suggest that neuronal gap junctions play an important role in synchronizing the central pacemaker neurons and contribute to the distinct self-sustainability of the SCN master clock.
Subject(s)
Animals , Mice , Circadian Rhythm , Electrical Synapses , Gap Junctions , Hypothalamus , Luminescent Measurements , Mammals , Mefloquine , Neurons , Phase Transition , Suprachiasmatic NucleusABSTRACT
BACKGROUND: The aim of our research work was to quantify total flavonoid contents in the leaves of 13 plant species family Asteraceae, 8 representatives of family Lamiaceae and 9 plant species belonging to familyRosaceae, using the multiplex fluorimetric sensor. Fluorescence was measured using optical fluorescence apparatus Multiplex(R) 3 (Force-A, France) for non-destructive flavonoids estimation. The content of total flavonoids was estimated by FLAV index (expressed in relative units), that is deduced from flavonoids UV absorbing properties. RESULTS: Among observed plant species, the highest amount of total flavonoids has been found in leaves ofHelianthus multiflorus (1.65 RU) and Echinops ritro (1.27 RU), Rudbeckia fulgida (1.13 RU) belonging to the family Asteraceae. Lowest flavonoid content has been observed in the leaves of marigold (Calendula officinalis) (0.14 RU) also belonging to family Asteraceae. The highest content of flavonoids among experimental plants of family Rosaceae has been estimated in the leaves of Rosa canina (1.18 RU) and among plant species of family Lamiaceae in the leaves of Coleus blumei (0.90 RU). CONCLUSIONS: This research work was done as pre-screening of flavonoids content in the leaves of plant species belonging to family Asteraceae, Lamiaceae and Rosaceae. Results indicated that statistically significant differences (P > 0.05) in flavonoids content were observed not only between families, but also among individual plant species within one family.
Subject(s)
Animals , Humans , Mice , Biological Clocks/genetics , Casein Kinase 1 epsilon/deficiency , Circadian Rhythm/genetics , Mutation , tau Proteins/deficiency , tau Proteins/metabolism , Cell Line , Cells, Cultured , Casein Kinase 1 epsilon/antagonists & inhibitors , Casein Kinase 1 epsilon/physiology , Mice, Knockout , Mice, Transgenic , Nuclear Proteins/antagonists & inhibitors , Nuclear Proteins/deficiency , Nuclear Proteins/metabolism , Nuclear Proteins/physiology , Period Circadian Proteins , Phosphorylation , Suprachiasmatic Nucleus/physiology , Time Factors , tau Proteins/physiologyABSTRACT
El núcleo supraquiasmático (NSQ) es el principal reloj biológico de los mamíferos y sincroniza la actividad de la glándula pineal al ciclo luz-oscuridad a través de una vía polisináptica. El efecto de asa de retroalimentación neuroendocrina se lleva a cabo por la melatonina. El presente trabajo pretende demostrar que la glándula pineal modula la sensibilidad a la luz en el NSQ. Se utilizaron ratas Wistar, y se asignaron a 3 grupos: grupo A (falsa pinealectomía -sham-, sin luz), grupo B (falsa pinealectomía -sham- + luz) y grupo C al cual se le realizó la pinealectomía + luz, después de la manipulación se sacrifican para realizar inmunohistoquímica para c-Fos y al final conteo celular por técnica de estereología. Se obtuvo una reducción del 46,8% del promedio de células inmunorreactivas a c-Fos en el grupo C en comparación del grupo B. Este trabajo muestra que la sensibilidad a la luz está modulada por la actividad de la glándula pineal.
The suprachiasmatic nucleus (SCN) is the main and major biological clock in mammals and is responsible for the synchronization of the pineal gland to the light/darkness cycle through a polysynaptic pathway. The neuroendocrine feedback loop effect is carried out by melatonin. This study was carried out to demonstrate that the pineal gland adjusts the sensibility to light in the suprachiasmatic nucleus. Wistar rats were allocated in 3 groups: Group A (sham pinalectomy, without light), group B (sham pinealectomy + light) and group C which underwent real pinalectomy + light. After the intervention the animals were slain to perform immunohistochemistry for c-Fos and cell counting by stereology technique. A 46.8% average reduction in c-Fos immunoreactive cells was achieved in-group C as compared with group B. The present work shows that sensibility to the light is modulate by the activity of the pineal gland.
Subject(s)
Animals , Rats , Pineal Gland/metabolism , Suprachiasmatic Nucleus/metabolism , Biological Clocks , Endocrine Glands/surgery , Circadian Rhythm , Proto-Oncogene Proteins c-fos , Rats, Wistar , Epithalamus/surgery , Melatonin/metabolismABSTRACT
Animals have neural structures that allow them to anticipate environmental changes and then regulate physiological and behavioral functions in response to these alterations. The suprachiasmatic nucleus of the hypothalamus (SCN) is the main circadian pacemaker in many mammalian species. This structure synchronizes the biological rhythm based on photic information that is transmitted to the SCN through the retinohypothalamic tract. The aging process changes the structural complexity of the nervous system, from individual nerve cells to global changes, including the atrophy of total gray matter. Aged animals show internal time disruptions caused by morphological and neurochemical changes in SCN components. The effects of aging on circadian rhythm range from effects on simple physiological functions to effects on complex cognitive performance, including many psychiatric disorders that influence the well-being of the elderly. In this review, we summarize the effects of aging on morphological, neurochemical, and circadian rhythmic functions coordinated by the main circadian pacemaker, the SCN...
Subject(s)
Humans , Aging , Suprachiasmatic Nucleus , Circadian RhythmABSTRACT
"Sundowning" in demented individuals, as distinct clinical phenomena, is still open to debate in terms of clear definition, etiology, operationalized parameters, validity of clinical construct, and interventions. In general, sundown syndrome is characterized by the emergence or increment of neuropsychiatric symptoms such as agitation, confusion, anxiety, and aggressiveness in late afternoon, in the evening, or at night. Sundowning is highly prevalent among individuals with dementia. It is thought to be associated with impaired circadian rhythmicity, environmental and social factors, and impaired cognition. Neurophysiologically, it appears to be mediated by degeneration of the suprachiasmatic nucleus of the hypothalamus and decreased production of melatonin. A variety of treatment options have been found to be helpful to ameliorate the neuropsychiatric symptoms associated with this phenomenon: bright light therapy, melatonin, acetylcholinesterase inhibitors, N-methyl-d-aspartate receptor antagonists, antipsychotics, and behavioral modifications. To decrease the morbidity from this specific condition, improve patient's well being, lessen caregiver burden, and delay institutionalization, further attention needs to be given to development of clinically operational definition of sundown syndrome and investigations on etiology, risk factors, and effective treatment options.
Subject(s)
Humans , Alzheimer Disease , Antipsychotic Agents , Anxiety , Caregivers , Cholinesterase Inhibitors , Circadian Rhythm , Cognition , Dementia , Dihydroergotamine , Hypothalamus , Institutionalization , Melatonin , N-Methylaspartate , Phototherapy , Risk Factors , Suprachiasmatic NucleusABSTRACT
Sleep is not just a rest for brain activity during daytime, but also has a vital function for memory consolidation after learning as well as restoration of both body and brain. While restoration of the body mainly occurs during non-rapid eye movement (NREM) sleep, especially during slow wave sleep, restoration of brain and memory consolidation occurs mainly during REM sleep. Adenosine acts as a sleep-inducing agent, so called somnogen or hypnotoxin which accumulates while awake. Sleep deprivation results in the disruption of every aspect of physical, cognitive, and behavioral function, which can be reversed only by sleep. Many neurotransmitter-secreting nuclei in the brain stem, hypothalamus, and basal forebrain are key structures for wakefulness, NREM, and REM sleep. They have been localized in the basal forebrain (acetylcholine), ventrolateral preoptic area (VLPO, GABA and galanin), tuberomamillary nucleus (TMN, histamine), lateral and posterior hypothalamus (orexin/hypocretin), reticular formation (glutamate), substantia nigra/ventral tegmental area (SN/VTA, dopamine), pedunculopontine nucleus and lateral dorsal tegmentum (PPT-LDT, acetylcholine), locus ceruleus (norepinephrine), and the raphe nuclei (serotonin). All are activated during wakefulness except VLPO which secrets GABA and galanin, which suppress other nuclei for sleep induction. Acetylcholine-secreting PPT-LDT is a major locus for REM sleep, and is inhibited by the raphe nuclei and locus ceruleus which act as REM-off neurons inducing NREM sleep. The suprachiasmatic nucleus is a pacemaker for circadian rhythms, which can be modified by bright light and melatonin. It should be emphasized that the best performance of cognitive function including reactivity, abstract thinking, creativity, memory, executive function, and accurate and efficient work as well as physical well-being is achieved by sufficient and appropriate sleep.
Subject(s)
Adolescent , Child , Humans , Adenosine , Brain , Brain Stem , Circadian Rhythm , Creativity , Executive Function , Eye Movements , Galanin , gamma-Aminobutyric Acid , Hypothalamus , Hypothalamus, Posterior , Learning , Light , Locus Coeruleus , Melatonin , Memory , Neurons , Preoptic Area , Prosencephalon , Raphe Nuclei , Reticular Formation , Sleep Deprivation , Sleep, REM , Suprachiasmatic Nucleus , Thinking , WakefulnessABSTRACT
As a consequence of the Earth's rotation, almost all organisms experience day and night cycles within a 24-hr period. To adapt and synchronize biological rhythms to external daily cycles, organisms have evolved an internal time-keeping system. In mammals, the master circadian pacemaker residing in the suprachiasmatic nucleus (SCN) of the anterior hypothalamus generates circadian rhythmicity and orchestrates numerous subsidiary local clocks in other regions of the brain and peripheral tissues. Regardless of their locations, these circadian clocks are cell-autonomous and self-sustainable, implicating rhythmic oscillations in a variety of biochemical and metabolic processes. A group of core clock genes provides interlocking molecular feedback loops that drive the circadian rhythm even at the single-cell level. In addition to the core transcription/translation feedback loops, post-translational modifications also contribute to the fine regulation of molecular circadian clocks. In this article, we briefly review the molecular mechanisms and post-translational modifications of mammalian circadian clock regulation. We also discuss the organization of and communication between central and peripheral circadian oscillators of the mammalian circadian clock.
Subject(s)
Brain , Circadian Clocks , Circadian Rhythm , Hypothalamus, Anterior , Mammals , Protein Processing, Post-Translational , Suprachiasmatic NucleusABSTRACT
Sleep is defined on the basis of behavioural and physiological criteria dividing it into two states: non rapid eye movement (NREM) sleep which is subdivided into three stages (N1, N2, N3); and rapid eye movement (REM) sleep characterized by rapid eye movements, muscle atonia and desynchronized EEG. Circadian rhythm of sleep-wakefulness is controlled by the master clock located in the suprachiasmatic nuclei of the hypothalamus. The neuroanatomical substrates of the NREM sleep are located principally in the ventrolateral preoptic nucleus of the hypothalamus and those of REM sleep are located in pons. A variety of significant physiological changes occur in all body systems and organs during sleep as a result of functional alterations in the autonomic and somatic nervous systems. The international classification of sleep disorders (ICSD, ed 2) lists eight categories of sleep disorders along with appendix A and appendix B. The four major sleep complaints include excessive daytime sleepiness, insomnia, abnormal movements or behaviour during sleep and inability to sleep at the desired time. The most important step in assessing a patient with a sleep complaint is obtaining a detailed history including family and previous histories, medical, psychiatric, neurological, drug, alcohol and substance abuse disorders. Some important laboratory tests for investigating sleep disorders consist of an overnight polysomnography, multiple sleep latency and maintenance of wakefulness tests as well as actigraphy. General physicians should have a basic knowledge of the salient clinical features of common sleep disorders, such as insomnia, obstructive sleep apnoea syndrome, narcolepsy-cataplexy syndrome, circadian rhythm sleep disorders (e.g., jet leg, shift work disorder, etc.) and parasomnias (e.g., partial arousal disorders, REM behaviour disorder, etc.) and these are briefly described in this chapter. The principle of treatment of sleep disorders is first to find cause of the sleep disturbance and vigorously treat the co-morbid conditions causing the sleep disturbance. If a satisfactory treatment is not available for the primary condition or does not resolve the problem, the treatment should be directed at the specific sleep disturbance. Most sleep disorders, once diagnosed, can be managed with limited consultations. The treatment of primary sleep disorders, however, is best handled by a sleep specialist. An overview of sleep and sleep disorders viz., Basic science; international classification and approach; and phenomenology of common sleep disorders are presented.
Subject(s)
Adolescent , Adult , Aged , Aged, 80 and over , Child , Cytokines/metabolism , Electroencephalography , Humans , Middle Aged , Parasomnias , Restless Legs Syndrome , Sleep , Sleep Apnea, Obstructive/diagnosis , Sleep Wake Disorders/diagnosis , Sleep Wake Disorders/physiopathology , Sleep, REM , Suprachiasmatic Nucleus/pathologyABSTRACT
Los principios básicos de la fisiología postulaban la necesidad de un medio interno constante paramantener el equilibrio fisiológico y no enfrentar consecuencias graves en la salud. Ahora sabemosque la fisiología es rítmica y que el quebrantamiento de dicha ritmicidad puede generar gravesconsecuencias que incluso pueden llegar a ser fatales. Los relojes circadianos, encabezados por elnúcleo supraquiasmático en el sistema nervioso central, son los responsables de generar dicharitmicidad biológica. Estos relojes son afectados por señales externas como la luz (por los cambiosentre el día y la noche) y los ritmos de alimentación. En esta revisión se abordan los principiosbásicos del sistema circadiano y los conocimientos actuales en la neurobiología de los relojes biológicos,haciendo pauta en la relación entre el sistema circadiano, la ingesta de alimento, la nutricióny los procesos metabólicos que la acompañan. Además, las consecuencias que ocurren cuandoestos sistemas no se encuentran coordinados entre sí, como el desarrollo de patologías de tipocircadiano y metabólicas.
The basic principles of physiology postulated the necessity of the constancy of the internal environmentto maintain a physiological equilibrium and do not front serious consequences in health. Now weknow that physiology is rhythmic and that a break of this rhythmicity can generate seriousconsequences in health which even could be lethal. Circadian clocks, headed by the suprachiasmaticnucleus in the central nervous system, are the responsible for the generation of circadian rhythms.These clocks are affected by external signals as light (day-night cycles) and feeding. This reviewexamines the basic principles of the circadian system and the current knowledge in the neurobiologyof biological clocks, making emphasis in the relationship between the circadian system, feedingbehaviour, nutrition and metabolism, and the consequences that occur when these systems are notcoordinated each other, as the development of metabolic and circadian pathologies.
Subject(s)
Humans , Diet , Metabolism , Suprachiasmatic NucleusABSTRACT
Circadian timing is structured in such a way as to receive information from the external and internal environments, and its function is the timing organization of the physiological and behavioral processes in a circadian pattern. In mammals, the circadian timing system consists of a group of structures, which includes the suprachiasmatic nucleus (SCN), the intergeniculate leaflet and the pineal gland. Neuron groups working as a biological pacemaker are found in the SCN, forming a biological master clock. We present here a simple model for the circadian timing system of mammals, which is able to reproduce two fundamental characteristics of biological rhythms: the endogenous generation of pulses and synchronization with the light-dark cycle. In this model, the biological pacemaker of the SCN was modeled as a set of 1000 homogeneously distributed coupled oscillators with long-range coupling forming a spherical lattice. The characteristics of the oscillator set were defined taking into account the Kuramoto's oscillator dynamics, but we used a new method for estimating the equilibrium order parameter. Simultaneous activities of the excitatory and inhibitory synapses on the elements of the circadian timing circuit at each instant were modeled by specific equations for synaptic events. All simulation programs were written in Fortran 77, compiled and run on PC DOS computers. Our model exhibited responses in agreement with physiological patterns. The values of output frequency of the oscillator system (maximal value of 3.9 Hz) were of the order of magnitude of the firing frequencies recorded in suprachiasmatic neurons of rodents in vivo and in vitro (from 1.8 to 5.4 Hz).
Subject(s)
Animals , Rats , Circadian Rhythm/physiology , Models, Neurological , Mammals/physiology , Geniculate Bodies/physiology , Oscillometry/methods , Pineal Gland/physiology , Software , Suprachiasmatic Nucleus/physiologyABSTRACT
INTRODUÇÃO: As relações entre sono e epilepsia são complexas e de grande importância clínica. A melhor compreensão das inúmeras lacunas que permeiam essa relação reforçaria os alicerces para o desenvolvimento de abordagens terapêuticas mais eficazes que pudessem contribuir para o bem-estar do paciente portador de epilepsia e transtornos do sono. OBJETIVO: O presente estudo teve como principal objetivo o estudo comportamental e a caracterização eletrofisiológica do ciclo vigília-sono (CVS) de ratos adultos tornados epilépticos por pilocarpina. MÉTODO: Ratos Wistar machos (N=6), tornados epilépticos após status epilepticus (SE) induzido por pilocarpina e não epilépticos (N=6) foram submetidos à cirurgia extereotáxica para implante de elétrodos bipolares nas áreas corticais (A3, somatosensorial) e hipocampais (CA1) de ambos os hemisférios. Registros contínuos de 24 horas foram submetidos à minuciosa análise visual e os seguintes parâmetros foram analisados: identificação e quantificação dos padrões eletrofisiológicos das fases do ciclo CVS; duração dos episódios oníricos ocorridos durante o sono dessincronizado (SD); padrão de ocorrência do CVS assim como do ciclo de sono (CS), e análise do volume do núcleo supraquiasmático. Os estudos da distribuição do CVS e comportamento onírico foram submetidos à Análise de Variância Multivariada - MANOVA, ao passo que as análises da ocorrência dos ciclos (CVS e CS) e volume do núcleo supraquiasmático foram submetidas ao teste da Análise de Variância (ANOVA) de dois fatores e ao teste de Mann- Whitney, respectivamente. RESULTADOS: Todas as fases do CVS foram identificadas nos ratos epilépticos. As fases da vigília e do sono eram permeadas por espículas e outros grafoelementos epileptiformes, como ondas delta espiculadas no SS e potenciais de alta frequência e baixa voltagem durante VA e o SD. Ao contrário do padrão de ocorrência típico das fases de vigília e sono em ratos não epilépticos, o grupo epiléptico apresentou...
INTRODUCTION: Relationships between sleep and epilepsy are complex and have great clinical importance as well. The full understanding of the various gaps present in this relationship would pave the ground for new studies that could generate new clinical approaches aiming to contribute to the well-being of the patient suffering from epilepsy and sleep disorders. OBJECTIVE: The present study aimed to carry out a behavioral analysis and electro-oscillographic characterization of the phases of sleep-wake cycle (SWC) of pilocarpine- induced epilepsy in adult rats. METHODS: Male Wistar rats that became epileptic after 60 days of pilocarpine-induced status epilepticus (SE) (N=6) and non epileptic ones (N=6) were submitted to extereotaxic surgery for implantation of bipolar electrodes in cortical (A3, somestesic) and hippocampal (CA1) areas in both hemispheres. Twenty-four hour continuous registers were submitted to detailed visual analysis and the following parameters were studied: identification and quantification of electrophysiological parameters of phases of SWC, duration of oniric episodes during desynchronized sleep (DS), the pattern of occurrence of SWC and cycles of sleep (CS). In addition, the volume of suprachiasmatic nuclei was investigated. To analyze the architecture of sleep-wake phases and oniric behavior, Multivariate Analysis of Variance-MANOVA was utilized, whereas the pattern of cycles (SWC and CS) and volume of suprachiasmatic were submitted to Analysis of Variance with 2 factors-Two-way ANOVA and Mann-Whitney test, respectively. RESULTS: In the epileptic rats all phases of SWC were identified. The phases of wake and sleep were permeated by spikes and graph elements epileptiforms such as spiked delta waves in SS and low frequency waves with high voltage during AW and SD phases. In contrast to the pattern of normal rhythmic activity evident in non-epileptic rats the epileptic group presented significant differences concerning distribution...
Subject(s)
Animals , Guinea Pigs , Rats , Dreams , Epilepsy, Temporal Lobe , Pilocarpine , Rats, Wistar , Sleep , Sleep Disorders, Circadian Rhythm , Suprachiasmatic NucleusABSTRACT
In mammals, the mechanism for the generation of circadian rhythms and entrainment by light-dark (LD) cycles resides in the hypothalamic suprachiasmatic nuclei (SCN), and the principal signal that adjusts this biological clock with environmental timing is the light:dark cycle. Within the SCN, rhythms are generated by a complex of molecular feedback loops that regulate the transcription of clock genes, including per and cry. Posttranslational modification plays an essential role in the regulation of biological rhythms; in particular, clock gene phosphorylation by casein kinase I , both epsilon (CKIepsilon) and delta (CKIdelta), regulates key molecular mechanisms in the circadian clock. In this paper, we report for the first time that CKI activity undergoes a significant circadian rhythm in the SCN (peaking at circadian time 12, the start of the subjective night), and its pharmacological inhibition alters photic entrainment of the clock, indicating that CKI may be a key element in this pathway.
Subject(s)
Animals , Casein Kinase I/antagonists & inhibitors , Circadian Rhythm/physiology , Cricetinae , Enzyme Inhibitors/pharmacology , Isoquinolines/pharmacology , Light , Light Signal Transduction/drug effects , Male , Mesocricetus , Mice , Suprachiasmatic Nucleus/drug effectsABSTRACT
The sleep-wake cycle displays a characteristic 24-hour periodicity, providing an opportunity to dissect the endogenous circadian clock through the study of aberrant behaviour. This article surveys the properties of circadian clocks, with emphasis on mammals. Information was obtained from searches of peer-reviewed literature in the PUBMED database. Features that are highlighted include the known molecular components of clocks, their entrainment by external time cues and the output pathways used by clocks to regulate metabolism and behaviour. A review of human circadian rhythm sleep disorders follows, including recent discoveries of their genetic basis. The article concludes with a discussion of future approaches to the study of human circadian biology and sleep-wake behaviour.
Subject(s)
Animals , Humans , ARNTL Transcription Factors , Basic Helix-Loop-Helix Transcription Factors , Physiology , CLOCK Proteins , Circadian Rhythm , Genetics , Physiology , Neurons, Afferent , Physiology , Neurons, Efferent , Physiology , Polymorphism, Single Nucleotide , Sleep Disorders, Circadian Rhythm , Genetics , Suprachiasmatic Nucleus , Cell Biology , Physiology , Trans-Activators , PhysiologyABSTRACT
The role of neuropeptides in the central nervous system (CNS) has received increasing attention. Numerous peptide molecules are found in the mammalian CNS and many of them are thought to act as either neurotransmitters or neuromodulators. The neuropeptides found in high concentration in the hypothalamus include vasopressin (VP), vasoactive intestinal polypeptide, somatostatin, and oxytocin. The main approches to assess the involvement of neuropeptides can be focused on functions affecting the aging of the brain. Morphological aging of the CNS has been characterized by degenerative changes of fiber connections and cell loss, although degeneration does not always occur to the same extent throughout various parts of the brain and, moreover, varies for different cell types. Despite of many studies in VP containing neurons , there exist discrepancies in results about the changes of aged rat brain. The aim of the present study is, therefore, to investigative possible changes in the number and morphology of VPimmunoreactive neurons with aging in each area of the hypothalmus of the aged rats. As a result, the number of VP-immunoreactive neurons was decreased in hypothalamus nucleus of aged group. Especially, in VP-immunoreactive neurons of hypothalamus, the size of neuronal cell body and nuclei in aged group is larger than in young group and the fiber density of immunoreactivity neurons of median eminance (ME) in aged group is stronger than in young group. But, the total number of VP-immunoreactive neurons in the suprachiasmatic nucleus (SCN) of the aged group is larger than in the young group. These studies indicate the involvement of VP-immunoreactive neurons in aging process of hypothalamus, and aging process may affect the synthesis of VP in the neurons of hypothalamic nuclei. Whereas, in VP expression, aging process induces an enlargement of the cell size of surviving neurons to compensate.
Subject(s)
Animals , Rats , Aging , Brain , Cell Size , Central Nervous System , Hypothalamus , Neurons , Neuropeptides , Neurotransmitter Agents , Oxytocin , Paraventricular Hypothalamic Nucleus , Somatostatin , Suprachiasmatic Nucleus , Supraoptic Nucleus , Vasoactive Intestinal Peptide , VasopressinsABSTRACT
The aim of this study was to observe and compare the endogenous circadian rhythm and photoresponse of Clock gene transcription in the suprachiasmatic nucleus (SCN) and pineal gland (PG) of rats. With free access to food and water in special darkrooms, Sprague-Dawley rats were housed under the light regime of constant darkness (DD) for 8 weeks (n=36) or 12 hour-light: 12 hour-dark cycle (LD) for 4 weeks (n=36), respectively. Then, their SCN and PG were dissected out every 4 h in a circadian day, 6 rats at each time (n=6). All animal treatments and sampling during the dark phases were conducted under red dim light (<0.1 lux). The total RNA was extracted from each sample and the semi-quantitative RT-PCR was used to determine the temporal mRNA changes of Clock gene in the SCN and PG at different circadian times (CT) or zeitgeber times (ZT). The grayness ratio of Clock/H3.3 bands was served as the relative estimation of Clock gene expression. The experimental data were analyzed by the Cosine method and the Clock Lab software to fit original results measured at 6 time points and to simulate a circadian rhythmic curve which was then examined for statistical difference by the amplitude F test. The main results are as follows: (1) The mRNA levels of Clock gene in the SCN under DD regime displayed the circadian oscillation (P<0.05). The endogenous rhythmic profiles of Clock gene transcription in the PG were similar to those in the SCN (P>0.05) throughout the day with the peak at the subjective night (CT15 in the SCN or CT18 in the PG) and the trough during the subjective day (CT3 in the SCN or CT6 in the PG). (2) Clock gene transcription in the SCN under LD cycle also showed the circadian oscillation (P<0.05), and the rhythmic profile was anti-phasic to that under DD condition (P<0.05). The amplitude and the mRNA level at the peak of Clock gene transcription in the SCN under LD were significantly increased compared with that under DD (P<0.05), while the value of corresponding rhythmic parameters in the PG under LD were remarkably decreased (P<0.05). (3) Under LD cycle, the circadian profiles of Clock gene transcription induced by light in the PG were quite different from those in the SCN (P<0.05). Their Clock transcription rhythms were anti-phasic, i.e., showing peaks at the light phase ZT10 in the SCN or at the dark time ZT17 in the PG and troughs during the dark time ZT22 in the SCN or during the light phase ZT5 in the PG. The findings of the present study indicate a synchronous endogenous nature of the Clock gene circadian transcriptions in the SCN and PG, and different roles of light regime in modulating the circadian transcriptions of Clock gene in these two central nuclei.