Browsing by Subject "clock"
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Item Functional genomics of the avian circadian system(Texas A&M University, 2006-04-12) Bailey, Michael JThe genetic identification of molecular mechanisms responsible for circadian rhythm generation has advanced tremendously over the past 25 years. However the molecular identities of the avian clock remain largely unexplored. The present studies seek to determine candidate clock components in the avian species Gallus domesticus. Construction and examination of the transcriptional profiles of the pineal gland and retina using DNA microarray analysis provided a clear view into the avian clock mechanism. Investigation of the pineal and retina transcriptomes determined the mRNA profiles of several thousand genes over the course of one day in LD (daily) and one day in DD (circadian) conditions. Several avian orthologs of mammalian clock genes were identified and many exhibited oscillating patterns of mRNA abundance including several of the putative avian clock genes. Comparison of the pineal transcriptional profile to that of the retina revealed several intriguing candidate genes that may function as core clock components. Including the putative avian clock genes and several others implicated in phototransduction, metabolism, and immune response. A more detailed examination of several candidate photoisomerase/photopigment genes identified from our transcriptional profiling was conducted. These include peropsin (rrh), RGR-opsin (rgr), melanopsin (opn4) and cryptochrome 2 (cry2) genes. This analysis revealed several interesting patterns of mRNA distribution and regulation for these genes in the chick. First, the mRNA of all 4 genes is located within the Inner Nuclear Layer (INL) and Retinal Ganglion cell Layers (RGL) of the ocular retina, where circadian photoreception is present. Second, opn4 and cry2 mRNA is expressed in the photoreceptor layer of the chick retina where melatonin biosynthesis occurs. Lastly, the mRNA for all 4 candidate photopigment genes is regulated on a circadian basis in the pineal gland. As a whole these data yield significant insight into the mechanisms of the avian circadian system and present several candidate genes that may function to integrate photic information, and/or regulate circadian rhythm generation in birds.Item Roles for extra-hypothalamic oscillators in the avian clock(2009-05-15) Karaganis, Stephen PaulAvian circadian clocks are composed of a distributed network of neural and peripheral oscillators. Three neural pacemakers, located in the pineal, the eyes, and the hypothalamus, control circadian rhythms of many biological processes through complex interactions with slave oscillators located throughout the body. This system, an astonishing reflection of the life history of this diverse class of vertebrates, allows birds to coordinate biochemical and physiological processes and harmonize them with a dynamic environment. Much work has been done to understand what roles these pacemakers have in avian biology, how they function, and how they interact to generate overt circadian rhythms. The experimental work presented in this dissertation uses the domestic chicken, Gallus domesticus, as a model to address these questions and carry forward current understanding about circadian biology in this species. To do so, we utilized a custom DNA microarray to investigate rhythmic transcription in cultured chick pineal cells. We then sought to identify genes which might be a component of the pineal clock by screening for rhythmic transcripts that are sensitive to a phase-shifting light stimulus. Finally, we surgically removed the eyes or pineal from chickens to examine the roles of these extra-SCN pacemakers in regulating central and peripheral rhythms in metabolism and clock gene expression. Using these methods, we show that the oscillating transcriptome is diminished in the chick pineal ex vivo, while the functional clustering of clock controlled genes is similar. This distribution reveals multiple conserved circadian regulated pathways, and supports an endogenous role for the pineal as an immune organ. Moreover, the robustness of rhythmic melatonin biosysnthesis is maintained in vitro, demonstrating that a functional circadian clock is preserved in the reduced subset of the rhythmic pineal transcriptome. In addition, our genomic screen has yielded a list of 28 genes that are candidates for functional screening. These should be evaluated to determine any potential role they may have as a component of the pineal circadian clock. Finally, we report that the eyes and pineal similarly function to reinforce rhythms in brain and peripheral tissue, but that metabolism and clock gene expression are differentially regulated in chick.Item The subunit exchange rate of the cyanobacterial circadian clock component kaic is independent of phosphorylation state(2009-05-15) Ihms, Elihu CarlThe study of the in vitro circadian oscillator of the cyanobacterium Synechococcus elongatus has uncovered a complex interplay of its three protein components. Synchronization of the clock's central oscillatory component, KaiC, has been thought to be achieved through subunit shuffling at specific intervals during the clock?s period. By utilizing an established fluorescence-based analysis on completely phosphorylated and dephosphorylated mutants as well as wild-type KaiC, this study has shown that shuffling rates are largely unaffected by phosphorylation state. These findings conflict with previous reports and hence revise our understanding of this oscillator.