Control Of Rhythmic Output From The Circadian Clock In Neurospora Crassa
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| Author | : Zachary Austin Lewis |
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| Release | : 2005 |
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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 | : Rigzin N. Dekhang |
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| 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 | : Alejandro Correa |
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| Total Pages | : 324 |
| Release | : 2002 |
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| Author | : Stuart Brody |
| Publisher | : Academic Press |
| Total Pages | : 269 |
| Release | : 2011-09-26 |
| Genre | : Science |
| ISBN | : 0123876907 |
In this book an international group of authors describes recent research on circadian rhythms in bacteria, fungi, plants, animals, and humans.
| Author | : Consuelo del Pilar Olivares Yáñez |
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| Release | : 2015 |
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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 | : Andrew Vanderford Greene |
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| Release | : 2006 |
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Circadian rhythms in biological processes occur in a wide range of organisms and are generated by endogenous oscillators. In Neurospora crassa, the FRQ-oscillator (comprised of FRQ, WC-1 and WC-2) is essential for rhythms in a sexual sporulation and gene expression. How this oscillator signals to the cell to control rhythmicity is unknown. Furthermore, under certain growth conditions, rhythms are observed in FRQ-null strains, indicating the presence of one or more FRQ-less oscillators (FLOs). Interestingly, while circadian rhythms are observed in the related Aspergillus spp., they lack the frq gene, leading to the hypothesis that a FLO is responsible for rhythms in Aspergillus. Thus, Aspergillus provides a useful organism to investigate the components of the FLO. To investigate how an oscillator controls circadian output, we characterized the role of N. crassa NRC-2. The nrc-2 gene is under control of the clock and encodes a putative serine-threonine protein kinase. In a NRC-2-null strain cultured in low glucose conditions, FRQ-oscillator-dependent outputs are arrhythmic, but are rhythmic in high glucose. Our data suggests a model whereby NRC-2 relays metabolic information to the FRQ-oscillator to control rhythmic output. To understand the role of FLO(s) in the N. crassa circadian system, we examined regulation of the ccg-16 gene. We show that ccg-16 transcript rhythmicity is FRQ-independent, but WC-1-dependent. Furthermore, in contrast to current models for the FRQ-oscillator, we observed that rhythms in WC-1 protein accumulation persist in the absence of FRQ. These data support a new model involving two oscillators that are coupled through the WC-1 protein and that regulate different outputs. One approach to identify components of the FLO involved characterizing circadian rhythms in Aspergillus spp, which lacks FRQ. We find that A. flavus and A. nidulans, display circadian rhythms in sporulation and gene expression, respectively. Together, these findings provide a foundation for the identification of FLO components in both Aspergillus and N. crassa, that will ultimately lead to an understanding of how a multi-oscillator system can generate and coordinate circadian rhythmicity.
| Author | : Sabrina Perrino |
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| Total Pages | : 264 |
| Release | : 2007 |
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| Author | : Lindsay Danielle Bennett |
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| Total Pages | : 169 |
| Release | : 2014 |
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Circadian clocks are ubiquitous in eukaryotic organisms, providing the ability to anticipate regularly occurring stressful environmental changes. The molecular clock leads to a change in physiology of the organism such that it is prepared for predictable changes. While the external signals detected by the clock, as well as the molecular mechanism of clock components have been extensively characterized, less is known about how the clock manifests time of day information to the organism as a whole. Our lab has focused on identifying output pathways from the clock, using the model organism Neurospora crassa. We have previously demonstrated the circadian regulation of the conserved Mitogen Activated Protein Kinase (MAPK) OS-2 pathway, a homolog of the mammalian p38 pathway, and necessary for maintaining osmotic homeostasis in Neurospora. I present data indicating the circadian regulation of the 2 other MAPK pathways in Neurospora, the mammalian ERK1 and ERK2 like MAPKs, MAK-1 and MAK-2, and show that they are outputs of the clock. Furthermore, I identified around 500 genes that are mis-regulated when MAK-1 is deleted; greater than 25% of those genes are predicted to be clock-controlled. I demonstrated that the clock is signaling through the MAK-1 pathway to regulate 3 clock-controlled genes (ccgs) that encode proteins involved in several different biological processes including, stress response, cell wall formation, and mitochondrial phosphate transport. I established the circadian regulation of the transcript levels of 2 of the MAK-1 cascade components, mek-1 and mak-1. Additionally, I found that the accumulation of MEK-1 protein is clock-controlled, suggesting this is one mechanism by which the clock regulates the activity of MAK-1. Additional studies were carried out to elucidate the proteins that directly regulate the expression of mek-1 and mak-1; however, the mechanisms of direct clock control remain unclear and require further investigation. The finding that the circadian clock regulates all MAPK pathways in Neurospora, combined with the conservation of both the circadian clock and MAPK pathways in mammals provide compelling evidence that mammalian MAPK pathways are also regulated as clock output pathways to control circadian physiology. There is a strong link between aberrations in mammalian clocks, MAPKs, and disease, and therefore, an urgent need to further characterize the circadian regulation of the MAPK families, which will reveal new avenues for therapeutic treatments. The electronic version of this dissertation is accessible from http://hdl.handle.net/1969.1/151801
| Author | : Derek J. Chadwick |
| Publisher | : John Wiley & Sons |
| Total Pages | : 348 |
| Release | : 2008-04-30 |
| Genre | : Science |
| ISBN | : 0470514604 |
Prestigious contributors describe the genetic, molecular, anatomical and neurochemical mechanisms and pathways that operate to regulate and control circadian rhythmicity and functioning in organisms ranging from unicellular algae to human beings. Also considers the implications of the basic and clinical research for humans.
| Author | : He Huang |
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| Release | : 2010 |
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Circadian clocks are present in most eukaryotes and some prokaryotes and control rhythms in behavior, physiology and gene expression. One well-characterized circadian clock is that of Neurospora crassa. In addition to the well-described N. crassa FRQ/WCC oscillator, several lines of evidence have implied the presence of other oscillators which may have important functions in the N. crassa circadian clock system. However, the molecular details are only known for the core FRQ/WCC oscillator. The light mutant oscillator (LMO) was identified by two mutations (LM-1 and LM-2) and shown to control developmental rhythms in constant light (LL), conditions in which the FRQ/WCC oscillator is not functional. The objective of this project was to determine whether the developmental rhythms driven by the LMO are circadian, whether the components of the LMO communicate with components of the FRQ/WCC oscillator, and to begin to define the molecular nature of the LMO. First, the conditions for growth of the LM-1 mutant strain that reveals the best circadian rhythm of development in LL were found. Second, the LMO was determined to display the three properties required of a circadian oscillator. Third, the LMO was shown to function independently of the FRQ/WCC oscillator to control developmental rhythms in LL. However, evidence suggests that the FRQ/WCC oscillator and the LMO communicate with each other. Finally, using Cleaved Amplified Polymorphic Sequence (CAPS) markers, the LM-1 mutation was genetically mapped to the right arm of linkage group I within a 1069 kb region. Together, these results provide a start towards understanding of the complexity of oscillators that form a circadian clock in organisms.
