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The disruption of the circadian system in bipolar disorder and its association with the polymorphism of L-type calcium channel
Filipovská, Eva ; Bendová, Zdeňka (advisor) ; Novosadová, Zuzana (referee)
Bipolar affective disorder is a serious psychiatric disease with prevalence of about 1% in general population. Typical symptoms are mood changes: manic periods are followed by depressions, with possible asymptomatic period of variable duration between them. It alters patient's everyday life and often leads to suicidal tendencies. Bipolar disorder is related to impaired circadian rhytms that are regulated from suprachiasmatic nuclei in hypothalamus. Impaired circadian rhytms in bipolar disorder are manifested by abnormalities of sleep and daily activity and by disrupted circadian secretion of several hormons. One of many factors that link bipolar disorder to circadian system at molecular level is the function of voltage-dependent calcium channels of L-type. Expression of these channels is regulated by the clock genes and their proper function is important for maintaining endogenous oscillations in the main oscillator located in suprachiasmatic nuclei. A common finding in patients with bipolar disorder is polymorphism of the gene for 1 subunit of the Cav1.2 channel. Abnormal function of calcium channels, consequent to the polymorphism, may be one of the causes that alter circadian rhytms in bipolar disorder. Key words: circadian system, suprachiasmatic nucleus, bipolar disorder, L-type calcium...
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Circadian system and memmory
Skálová, Kateřina ; Bendová, Zdeňka (advisor) ; Houdek, Pavel (referee)
Circadian system is a part of all living organisms. It controls suitable timing of their physiological functions and behaviour. The molecular mechanism of interlocking transcription-translational feedback loops of clock genes and their protein products forms the core of the circadian system. The main structures of this system in mammalian organisms are suprachiasmatic nuclei of the hypothalamus. Memory is also closely connected with circadian system. It is one of the most important abilities of organism for creating knowledge. Both memory and circadian system enable to the organism to adapt to changes in its external environment. The expression of clock genes was detected in brain structures involved in mediation of memory such as hippocampus, amygdale and basal ganglia. The oscillations of these clock genes influence the formation and retrieval of memory traces. The aim of this work is to summarize current knowledge about the relationship between the memory and the circadian system. Key words: circadian system, memory, clock genes, suprachiasmatic nuclei, hippocampus
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Circadian system in bulbus olfactorius
Kyclerová, Hana ; Bendová, Zdeňka (advisor) ; Polidarová, Lenka (referee)
The mammalian circadian system is composed of major circadian pacemaker located in the hypothalamic suprachiasmatic nuclei and peripheral circadian oscillators. Molecular mechanism of interlocked transcription-translation feedback loops, as a characteristic of each circadian oscillator, results in circadian rhythms. Peripheral oscillators in other brain parts and body organs are driven by the signals from the suprachiasmatic nuclei. Some structures however generate oscillations independently from the major circadian pacemaker. The best described of them resides in the mammalian retina. The retinal circadian oscillator regulates local rhythmic synthesis of melatonin, retinal pH and photoreceptors viability. Recently, some studies occur charactering the existence of such an independent circadian oscillator also in bulbus olfactorius. For example, the olfactory bulb circadian oscillator drives olfactory sensitivity during the day. Studies about development of the mamalian circadian system have shown that the olfactory bulb circadian oscillator matures earlier than the major circadian pacemaker and represents its function during early development. Powered by TCPDF (www.tcpdf.org)
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Clock genes in mammalian circadian pacemaker
Cimerová, Veronika ; Bendová, Zdeňka (advisor) ; Polidarová, Lenka (referee)
The behavior of mammals and their physiological processes are dependent on the daily rhythms. These rhythms are controlled by an endogenous circadian clock that responds to light/dark cycles of environment. In mammals, the circadian clocks, are arranged hierarchically, and work in almost all cells and tissues. Suprachiasmatic nuclei (SCN) in the hypothalamus are at the top of the hierarchy and work as a major circadian pacemaker. This work presents the clock genes that have been discovered in the last twenty years in the SCN of mammals. The first chapter focuses on the general mechanism of circadian rhythms and structure of the SCN. The second chapter describes the transcriptional-translational feedback loops that are an essential part of the proper function of the circadian clock, and function of individual genes is briefly introduced in this chapter. The following chapters already include a chronological characterization of Clock, Bmal1, Period and Cryptochrome genes, as they were discovered. If the clock gene expresses different function from the clockwork mechanism, it is briefly introduced in the final paragraph on the chapter. The final chapters deal with other molecules, casein kinases, ROR and REV-ERB receptors that affect its function expression and degradation of circadian genes in the...
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