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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Post-Transcriptional Control of Human Cellular Senescence: A Dissertation

Burns, David M. 15 July 2010 (has links)
The central dogma of biology asserts that DNA is transcribed into RNA and RNA is translated into protein. However, this overtly simplistic assertion fails to portray the highly orchestrated and regulated mechanisms of transcription and translation. During the process of transcription, RNA provides the template for translation and protein synthesis as well as the structural and sequence specificity of many RNA and protein-based machines. While only 1-5% of the genome will escape the nucleus to be translated as mRNAs, complex, parallel, highly-conserved mechanisms have evolved to regulate specific mRNAs. Trans-acting factors bind cis-elements in both the 5" and 3" untranslated regions of mRNA to regulate their stability, localization, and translation. While a few salient examples have been elucidated over the last few decades, mRNA translation can be reversibly regulated by the shortening and lengthening of the 3" polyadenylate tail of mRNA. CPEB, an important factor that nucleates a complex of proteins to regulate the polyadenylate tail of mRNA, exemplifies a major paradigm of translational control during oocyte maturation and early development. CPEB function is also conserved in neurons and somatic foreskin fibroblasts where it plays an important role in protein synthesis dependent synaptic plasticity and senescence respectively. Focusing on the function of CPEB and its role in mRNA polyadenylation during human cellular senescence, the following dissertation documents the important finding that CPEB is required for the normal polyadenylation of p53 mRNA necessary for its normal translation and onset of senescence. Cells that lack CPEB have abnormal levels of mitochondria and ROS production, which are demonstrated to arise from the direct result of hypomorphic p53 levels. Finally, in an attempt to recapitulate the model of CPEB complex polyadenylation in human somatic cells, I unexpectedly find that Gld-2, a poly(A) polymerase required for CPEB-mediated polyadenylation in Xenopus laevis oocytes, is not required for p53 polyadenylation, but instead regulates the stability of a microRNA that in turn regulates CPEB mRNA translation. Furthermore, I demonstrate that CPEB requires Gld-4 for the normal polyadenylation and translation of p53 mRNA.
22

Role of CPEB in Senescence and Inflammation: A Dissertation

Ivshina, Maria 28 July 2010 (has links)
Cytoplasmic polyadenylation element-binding protein (CPEB) is a sequence-specific RNA-binding protein that promotes polyadenylation-induced translation. While a CPEB knockout (KO) mouse is sterile but overtly normal, embryo fibroblasts derived from this mouse (MEFs) do not enter senescence in culture as do wild-type MEFs, but instead are immortal. Exogenous CPEB restores senescence in the KO MEFs and also induces precocious senescence in wild-type MEFs. CPEB cannot stimulate senescence in MEFs lacking the tumor suppressors p53, p19ARF, or p16INK4A; however, the mRNAs encoding these proteins are unlikely targets of CPEB since their expression is the same in wild-type and KO MEFs. Conversely, Ras cannot induce senescence in MEFs lacking CPEB, suggesting that it may lie upstream of CPEB. One target of CPEB regulation is myc mRNA, whose unregulated translation in the KO MEFs may cause them to bypass senescence. Thus, CPEB appears to act as a translational repressor protein to control myc translation and resulting cellular senescence. CPEB is a sequence-specific RNA binding protein that regulates cytoplasmic polyadenylation-induced translation. We report here that CPEB KO mice are hypersensitive to LPS-induced endotoxic shock, which correlates with elevated serum levels of the proinflammatory cytokines IL-6, IL-8 and IL-12. Peritoneal macrophages from the KO mice, as well as a CPEB-depleted macrophage cell line, not only secrete more IL-6 than control cells in response to LPS, but also have prolonged retention of NFϰB in the nucleus, which is responsible for elevated IL-6 transcription. The amount of nuclear NFϰB correlates with reduced levels of IϰBα, which is hyperphosphorylated and rapidly degraded. Collectively, these data suggest that CPEB deficiency enhances the inflammatory response via delayed resolution of NFϰB signaling.
23

Age-related Changes in the Neuronal Architecture of Caenorhabditis Elegans: A Dissertation

Khandekar, Anagha 16 October 2015 (has links)
Though symptoms such as loss of vision, decline in cognition and memory are evident during aging, the underlying processes that affect neuronal function during aging are not well understood. Unlike changes in other tissues and organs, age-related changes in the nervous system affect the overall physical, mental as well as social state of human beings. To start elucidating the molecular mechanisms underlying normal age-dependent brain decline, we have characterized structural neuronal changes occurring during Caenorhabditis elegans aging. Our analysis reveals distinct neuronal alterations that arise with age and that the types of changes and their age of onset are neuronal-type specific, highlighting the differential susceptibility of neurons to the stresses of life. We also find that these age-dependent neuronal changes are largely uncoupled from lifespan. As a first step towards understanding the neuropathological conditions manifested during senescence, we have characterized the role of the neuronal maintenance gene sax-7/L1CAM in normal C. elegans aging. Our comparison of age-related structural changes in the wild-type nervous system with that of sax-7 mutants, indicates that loss of function of sax-7 results in accelerated neuronal deterioration that mimics alterations occurring during normal aging. Conversely, overexpressing wild-type copies of SAX-7 delays some of the neuronal changes that accompany normal aging, indicating that SAX-7 plays a neuroprotective role. Additionally we find that x mechanical stress from body movements impacts the neuronal changes during adulthood. Taken together, our results give an entry point into the mechanisms of age-related neuroanatomical changes and neuronal protection.

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