Role Of Rco 1 In The Control Of Circadian Gene Expression And Metabolic Compensation Of The Neurospora Crassa Circadian Clock
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| Author | : Consuelo del Pilar Olivares Yáñez |
| Publisher | : |
| Total Pages | : |
| Release | : 2015 |
| Genre | : |
| ISBN | : |
Circadian clocks are endogenous molecular timekeepers, which organize physiology of organisms with respect to the external world, conferring daily rhythms to a large number of biological processes within the cell. These clocks are present in various organisms, impinging close to 24 hours rhythms in the regulation of gene expression, physiology and behavior. A circadian system can be conceptualized as composed of three parts: input mechanisms, a central oscillator and output pathways. Although a detailed molecular description of the core oscillator is available in model eukaryotes, there is limited information on the mechanisms that allows it to regulate rhythmic processes. Such "output pathways" are the least characterized aspect of circadian systems. The filamentous fungus Neurospora crassa has served for decades as a model organism for the study of circadian biology. In an effort to improve current knowledge of output pathways identifying new components involved in this process, a genetic screen was conducted in this fungus, and we identified potential regulatory candidates, among which we characterized the coKrepressor RCOK1 and its role in regulating circadian biology. RCOK1 is the orthologue of the Saccharomyces cerevisiae transcriptional coK repressor Tup1. Contrary to reports that emerged while developing this thesis, we provide evidence that RCOK1 is not an essencial core-clock component in Neurospora. We evaluated the status of the central clock observing that expression of the negative element of the core oscillator, frequency (frq), remains rhythmic in the absence of RCOK1.
| Author | : Zachary Austin Lewis |
| Publisher | : |
| Total Pages | : |
| Release | : 2005 |
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| ISBN | : |
Circadian rhythms are visible as daily oscillations in biochemical, physiological, or behavioral processes. These rhythms are produced by an endogenous clock that maintains synchrony with the external environment through responses to external stimuli such as light or temperature. The clock, in turn, coordinates internal processes in a time-dependent fashion. Genetic and molecular analysis of the filamentous fungus Neurospora crassa has demonstrated that the products of the frequency (frq) and white-collar (wc-1 and wc-2) genes interact to form an interlocked feedback loop that lies at the heart of the clock in this fungus. This feedback loop, termed the FRQ/WC oscillator, produces a %7E24h oscillation in frq mRNA, FRQ protein, and WC-1 protein. In turn, the FRQ/WC oscillator regulates rhythmic behavior and gene expression. The goal of this dissertation is to understand how rhythmic outputs are regulated by the FRQ/WC oscillator in Neurospora. To this end, we have taken a microarray approach to first determine the extent of clock-controlled gene expression in Neurospora. Here, we show that circadian regulation of gene expression is widespread; 145 genes, representing 20% of the genes we analyzed, are clock-controlled. We show that clockregulation is complex; clock-controlled genes peak at all phases of the circadian cycle. Furthermore, we demonstrate the clock regulates diverse biological processes, such as intermediary metabolism, translation, sexual development and asexual development. WC-1 is required for all light- and clock-regulated gene expression in Neurospora. We have shown that overexpression of WC-1 is sufficient to activate clock-controlled gene expression, but is not sufficient to induce all light-regulated genes in Neurospora. This result indicates that cycling of WC-1 is sufficient to regulate rhythmic expression of a subset of clockcontrolled genes. Conversely, a post-translational mechanism underlies WC-1 mediated light signal transduction in Neurospora. Finally, we have demonstrated the Neurospora circadian system is comprised of mutually coupled oscillators that interact to regulate output gene expression in the fungus.
| Author | : Paolo Sassone-Corsi |
| Publisher | : Springer |
| Total Pages | : 141 |
| Release | : 2016-04-04 |
| Genre | : Medical |
| ISBN | : 3319270699 |
Recent years have seen spectacular advances in the field of circadian biology. These have attracted the interest of researchers in many fields, including endocrinology, neurosciences, cancer, and behavior. By integrating a circadian view within the fields of endocrinology and metabolism, researchers will be able to reveal many, yet-unsuspected aspects of how organisms cope with changes in the environment and subsequent control of homeostasis. This field is opening new avenues in our understanding of metabolism and endocrinology. A panel of the most distinguished investigators in the field gathered together to discuss the present state and the future of the field. The editors trust that this volume will be of use to those colleagues who will be picking up the challenge to unravel how the circadian clock can be targeted for the future development of specific pharmacological strategies toward a number of pathologies.
| Author | : Rigzin N. Dekhang |
| Publisher | : |
| Total Pages | : |
| Release | : 2015 |
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The Neurospora crassa circadian clock is based on a highly regulated molecular negative feedback loop, similar to molecular clocks in all eukaryotes. A core component of the N. crassa molecular clock is the White Collar complex (WCC), composed of the blue light photoreceptor WC-1 and its partner WC-2. The WCC serves as a master regulator that controls light signaling, and the precise timing of target gene expression. Up to 40% of the eukaryote genome is under the control of the clock at the level of transcript abundance, but the molecular links between the core oscillator and downstream target genes, as well as the mechanisms controlling the phase of rhythmic gene expression, are not understood. Using chromatin immunoprecipitation coupled to high-throughput sequencing (ChIP-seq), about 400 binding sites for the WCC were identified throughout the N. crassa genome. We found that 24 transcription factors (TFs) were significantly enriched among the direct WCC target genes. As expected for genes that are controlled by the WCC, the first-tier TFs are both clock- and light-regulated. These data led to the hypothesis that the WCC functions to control rhythms in TFs, which in turn control rhythmicity and phase of downstream target genes and processes. To test this hypothesis, the first-tier TF ADV-1 (Arrested Development-1) was investigated in detail to characterize the downstream circadian genetic network. ADV-1 target genes were identified using ChIP- and RNA-seq, and as expected many ADV-1 downstream target genes were light-responsive and/or clock-controlled. An enrichment for ADV-1 target genes involved in cell fusion, a process that is critical for normal vegetative and sexual development in N. crassa, provided a rationale for the observed developmental defects in ADV-1 deletion cells, and suggested that cell fusion is clock-controlled. Importantly, this work revealed that the transduction of time-of-day information through ADV-1 to its downstream targets is more complex than anticipated. Specifically, I show that deletion of ADV-1 does not always lead to predicted changes in rhythmic gene expression and/or phase, suggesting that ADV-1 functions in combination with other first-tier TFs to control rhythmicity. In support of this idea, genome-wide binding profiles of all of the first-tier TFs uncovered complex feedback and feed forward regulation involving ADV-1. Thus, my data revealed that in order to fully understand how the clock signals phase information to downstream targets, we need to go beyond the candidate gene approach, and instead develop computational models from our TF ChIP-seq and rhythmic transcriptome data to model how time of day information is transduced in the molecular circadian output gene network. Predictions of the model can then be validated using ADV-1 deletion cells alone, or in combination with deletion of other first-tier TFs in the network, with the goal of deriving design principles that define conserved aspects of the circadian output network in all eukaryotes, and important in human health. To test this hypothesis, the first-tier TF ADV-1 (Arrested Development-1) was investigated in detail to characterize the downstream circadian genetic network. ADV-1 target genes were identified using ChIP- and RNA-seq, and as expected many ADV-1 downstream target genes were light-responsive and/or clock-controlled. An enrichment for ADV-1 target genes involved in cell fusion, a process that is critical for normal vegetative and sexual development in N. crassa, provided a rationale for the observed developmental defects in ADV-1 deletion cells, and suggested that cell fusion is clock- controlled. Importantly, this work revealed that the transduction of time-of-day information through ADV-1 to its downstream targets is more complex than anticipated. Specifically, I show that deletion of ADV-1 does not always lead to predicted changes in rhythmic gene expression and/or phase, suggesting that ADV-1 functions in combination with other first-tier TFs to control rhythmicity. In support of this idea, genome-wide binding profiles of all of the first-tier TFs uncovered complex feedback and feed forward regulation involving ADV-1. Thus, my data revealed that in order to fully understand how the clock signals phase information to downstream targets, we need to go beyond the candidate gene approach, and instead develop computational models from our TF ChIP-seq and rhythmic transcriptome data to model how time of day information is transduced in the molecular circadian output gene network. Predictions of the model can then be validated using ADV-1 deletion cells alone, or in combination with deletion of other first-tier TFs in the network, with the goal of deriving design principles that define conserved aspects of the circadian output network in all eukaryotes, and important in human health. The electronic version of this dissertation is accessible from http://hdl.handle.net/1969.1/155195
| Author | : |
| Publisher | : Academic Press |
| Total Pages | : 269 |
| Release | : 2011-09-16 |
| Genre | : Science |
| ISBN | : 0123876982 |
This latest volume in Advances in Genetics covers the genetics of Circadian rhythms. With an international group of authors this volume is the latest offering in this widely praised series.
| Author | : |
| Publisher | : Academic Press |
| Total Pages | : 198 |
| Release | : 2015-12-02 |
| Genre | : Science |
| ISBN | : 0128040793 |
Advances in Genetics provides the latest information on the rapidly evolving field of genetics, presenting new medical breakthroughs that are occurring as a result of advances in our knowledge of genetics. The book continually publishes important reviews of the broadest interest to geneticists and their colleagues in affiliated disciplines, critically analyzing future directions. Critically analyzes future directions for the study of clinical genetics Written and edited by recognized leaders in the field Presents new medical breakthroughs that are occurring as a result of advances in our knowledge of genetics
| Author | : Carol Louise Dieckman |
| Publisher | : |
| Total Pages | : 354 |
| Release | : 1980 |
| Genre | : Circadian rhythms |
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| Author | : Zhiyong Wang |
| Publisher | : |
| Total Pages | : 446 |
| Release | : 1998 |
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| Author | : Katsuya Nagai |
| Publisher | : CRC Press |
| Total Pages | : 216 |
| Release | : 1992-06-26 |
| Genre | : Medical |
| ISBN | : 9780849366574 |
This excellent book describes the roles of the suprachiasmatic nucleus (SCN) of the hypothalamus as a regulatory center of homeostatic mechanism and a circadian oscillator in mammals, including humans. The authors emphasize two important points based on their findings: 1) SCN plays a critical role in central regulation of energy metabolism through which a constant supply of glucose to the central nervous system (CNS) is well maintained; and 2) neurons responsible for the regulation of energy metabolism are located in the ventrolateral part of the SCN and receive retinal neural inputs through both the retinohypothalamic tract and the geniculohypothalamic tract. The authors then discuss the evolutionary importance of these points to the survival of mammals on earth. Other topics examined include the involvement of light in the regulation of neural activity of the autonomic nervous system through the retina and SCN, in addition to the relation of the SCN with regulations of other autonomic nerve functions, such as blood pressure and body temperature. Central Regulation of Energy Metabolism with Special Reference to Circadian Rhythm is important reading for researchers and students in neuroendocrinologists, neurobiologists, biochemists, endocrinologists, physiologists, chronobiologists, psychologists, pharmacologists, and others interested in the topic.
| Author | : Gary George Coté |
| Publisher | : |
| Total Pages | : 566 |
| Release | : 1986 |
| Genre | : Circadian rhythms |
| ISBN | : |
