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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.
1

Purification and some properties of galactokinase from Escherichia coli

Sherman, John Roberts, January 1962 (has links)
Thesis (M.S.)--University of Wisconsin--Madison, 1962. / Typescript. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 20-21).
2

Biochemische, kinetische und strukturelle Eigenschaften der Galaktokinase in Organen menschlicher Foeten

Pouget, Eva., January 1979 (has links)
Thesis (doctoral)--Ludwig Maximilians-Universität zu München, 1979.
3

Purification and kinetic studies of galactokinase from Escherichia coli

Gulbinsky, Joseph Stephen, January 1966 (has links)
Thesis (M.S.)--University of Wisconsin--Madison, 1966. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.
4

Galactokinase is a Novel Modifier of Calcineurin-Induced Cardiomyopathy in Drosophila

Lee, Teresa Ena January 2014 (has links)
<p>Calcineurin is both necessary and sufficient to induce cardiac hypertrophy, an independent risk factor for arrhythmia, dilated cardiomyopathy, heart failure, and sudden cardiac death. However, current knowledge of the downstream effectors of calcineurin is limited. My study utilizes <italic>Drosophila melanogaster</italic> to 1) establish a reliable model for discovering novel modifiers of calcineurin-induced cardiomyopathy; and 2) discover and characterize novel modifiers of calcineurin-induced cardiomyopathy.</p><p>In this study, I generated sensitized <italic>Drosophila</italic> lines expressing constitutively active calcineurin (CanA<super>act</super>) that was either fused to yellow fluorescent protein (YFP) or a Flag epitope (Flag-tagged) specifically in the heart using the cardiac-specific tinC driver (<italic>tinC-CanA<super>act</super></italic>). These sensitized lines displayed significant cardiac enlargement as assayed via optical coherence tomography (OCT), histology, and confocal microscopy. The feasibility of this method was established by testing <italic>Drosophila</italic> expressing deficiency of a known calcineurin modifier, Mef2. </p><p>Employing a targeted deficiency screen informed by calcineurin modifier screens in the eye and mesoderm, Galactokinase (<italic>Galk</italic>) was discovered as a novel modifier of calcineurin-induced cardiomyopathy in the fly through 1) genetic deficiencies, transposable elements, and RNAi disrupting <italic>Galk</italic> expression rescued <italic>tinC-CanA<super>act</super></italic>-induced cardiomyopathy; and 2) transposable element in <italic>Galk</italic> rescued <italic>tinC-CanA<super>act</super></italic>-induced decreased life span. Further characterization identified that the genetic disruption of <italic>Galk</italic> rescued CanA<super>act</super>-induced phenotypes driven in the posterior wing, but not ectodermaly, mesodermaly, or ubiquitously driven phenotypes. In a separate region, genetic disruption of the galactoside-binding lectin, galectin, was also found to rescue <italic>tinC-CanA<super>act</super></italic>-induced cardiac enlargement.</p><p>Together, these results characterize <italic>tinC-CanA<super>act</super></italic>-induced cardiac enlargement in the fly, establish that the <italic>tinC-CanA<super>act</super></italic> sensitized line is a reliable model for discovering novel calcineurin regulators and suggest that galactokinase and galectin-regulated glycosylation is important for calcineurin-induced cardiomyopathy. These results have the potential to provide insight into new treatments for cardiac hypertrophy.</p> / Dissertation
5

Chromatin Remodeling and Transcriptional Memory: A Dissertation

Kundu, Sharmistha 18 December 2008 (has links)
Transcriptional regulation of gene expression is critical for all unicellular and multicellular organisms. The ability to selectively induce or repress expression of only a few genes from the entire genome gives cells the ability to respond to changing environmental conditions, grow and proliferate. Multicellular organisms begin life as a single totipotent cell, which undergoes many cell divisions during embryonic and later postnatal development. During this process, the dividing cells of the embryo progressively lose their pluripotency and adopt restricted cell fates. Cell fate restriction leads different cell types to gain unique transcriptional profiles. This transcriptional profile or gene expression pattern not only defines the cell types and restricts the ways in which they can respond to signals, it also has to be faithfully re-established in the progeny of these fate-restricted cells when they divide. Different mechanisms have evolved in multicellular organisms to propagate transcriptional memory of cell identity. Most of mechanisms involve modifications of chromatin such as epigenetic modification of DNA or alterations of associated histones. In contrast to multicellular organisms which have considerable cellular diversity and a long lifespan for which cell fates and transcriptional memory needs to be maintained, single celled budding yeast, Sachharomyces cerevisiae have a life cycle of about 90 minutes in normal nutrient rich conditions. However, even budding yeast have tremendous potential to respond to changing environmental conditions like nutrient availability by inducing expression of various genes. We observed that members of the GAL gene cluster, which encodes genes induced in response to and for metabolizing the sugar galactose, showed heritable transcriptional memory of previous activation. This dissertation thesis describes the studies I have done for my graduate research to define this phenomenon of transcriptional memory at the yeast GALgenes and to determine the mechanism by which it can be formed and inherited. Chapter I gives an introduction to different mechanisms of establishing transcriptional memory in unicellular and multicellular organisms. Chromatin based mechanisms have been well studied in multicellular organisms but not observed in budding yeast. We compare chromatin based or nuclear inheritance with cytoplasmic inheritance that can be observed in yeast. Chapter II describes work done to define the phenomenon of transcriptional memory at GAL1 gene. We define this as a faster rate of induction of the GAL1 gene, compared to a naïve gene, after a brief period of repression. We show that this cellular memory persists through mitosis and can be passed on to the next generation. We also show that chromatin remodeling enzymes appear to be required for rapid reinduction, raising the question if yeast may also possess chromatin associated, nuclear mechanisms for cellular memory. Chapter III describes experiments that show that cellular memory observed at GAL1 is cytoplasmic in nature and also compares our work with similar examples observed recently by other groups. Finally, Chapter IV offers a perspective of the significance of such cellular memory mechanisms in budding yeast and outlines some potential further experiments to better understand the control of GAL1 induction kinetics.

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