Browsing by Subject "Circadian rhythms"
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Item Human performance, physiological rhythms, and circadian time relations(Texas Tech University, 1975-05) Bethea, Nancy Jo JensenNot availableItem Organization of the circadian clock and control of rhythmicity in fungi(Texas A&M University, 2006-10-30) Greene, Andrew VanderfordCircadian 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 asexual 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.Item Roles for polyploidy, circadian rhythms, and stress responses in hybrid vigor(2014-05) Miller, Marisa Elena; Chen, Z. JeffreyHybrid plants and animals, like corn and the domestic dog, grow larger and more vigorously than their parents, a common phenomenon known as hybrid vigor or heterosis. In hybrids between Arabidopsis ecotypes or species (in allotetraploids), altered expression of circadian clock genes leads to increased starch and chlorophyll content and greater biomass. In plants and animals, circadian clock regulation plays a key role in optimizing metabolic pathways, increasing fitness, and controlling responses to biotic and abiotic stresses. In the allotetraploids, the increased level of heterosis is likely caused by interspecific hybridization as well as genome doubling. However, it is unknown how genome dosage and allelic effects influence heterosis, and whether additional clock output traits, such as stress responses, are altered in hybrids. In three related projects, the effects of genomic hybridization (including parent-of-origin effects) and genome dosage on heterosis were elucidated. In my first project, I found that although ploidy influenced many traits, including seed and cell size, biomass and circadian clock gene expression were most strongly influenced by hybridization. Additionally, parent-of-origin effects between reciprocal hybrids were frequently observed for many traits. In my second project, I described a unique role for RNA-directed DNA methylation (mainly CHH methylation) in mediating the parent-of-origin effect on expression of the circadian clock gene CCA1 in reciprocal hybrids. Altered CCA1 expression peaks were associated with heterosis of biomass accumulation in the reciprocal hybrids. Lastly, I used transcriptome sequencing in hybrids at different times of day to examine changes in downstream clock-regulated pathways. In the hybrids, many genes in photosynthetic pathways were upregulated, while many genes involved in biotic and abiotic stresses were repressed during the morning and afternoon, respectively. Additionally, natural variation between parents in stress-responsive gene expression was found to be crucial for producing vigorous hybrids. These conceptual advances increase the mechanistic understanding of heterosis, and may guide selection of parents for making better hybrids.