Global ETD Search

61	Study of the molecular regulation of trypanosomatid phosphofructokinases as drug targets Kinkead, James Robert H. January 2018 (has links) The trypanosomatid parasites T. brucei, T. cruzi and Leishmania spp. are responsible for the ‘neglected diseases’ Human African Trypanosomiasis, Chagas disease and Leishmaniasis respectively. In their human infective form in the bloodstream all three trypanosomatid parasites rely heavily on glycolysis for ATP production. Phosphofructokinase (PFK) catalyses the third step of the glycolytic pathway in all organisms using aerobic respiration. It facilitates the phospho transfer from ATP to fructose 6-phosphate (F6P) to make the products fructose 1,6- bisphosphate (F16BP) and ADP. RNAi knockout of T. brucei PFK has shown the enzyme is essential for survival of the bloodstream form parasites. Trypanosomatid PFKs have a unique set of structural and regulatory differences compared to the mammalian host enzyme. These differences, coupled with the availability of trypanosomatid PFK crystal structures present an opportunity for the structure-based design of specific inhibitors against the enzyme. Here we present an enzymatic characterisation of recombinant PFKs from T. brucei, T. cruzi and Leishmania infantum trypanosomatids, their regulation by the allosteric activator AMP, and their inhibition by drug-like inhibitor compounds. Inhibitor compounds (‘CTCB compounds’) were designed against T. brucei PFK with the aim of developing novel treatments against Human African Trypanosomiasis (HAT). We describe the testing, ranking and biophysical characterisation of these compounds as part of a Wellcome Trust Seeding Drug Discovery program. We found that CTCB inhibitor compounds bound to an allosteric pocket unique to trypanosomatid PFKs. We show that the compounds are specific; neither competing with the natural substrates ATP or F6P nor inhibiting the human PFK enzyme. We describe the development and testing of highly potent and specific low molecular weight PFK inhibitors that translate to both killing of cultured T. b. brucei parasites and a cure of stage I HAT in mice models. We describe the tight, 1:1 binding of these compounds with trypanosomatid PFKs, and the thermodynamic characteristics of binding through various biophysical assays. We also show the unprecedented characterisation of the reverse PFK reaction by trypanosomatid and human forms of the enzymes. We found that PFK can also carry out the reverse enzymatic reaction, under physiologically relevant concentrations of ADP and F16BP to produce F6P and ATP. We show that the reverse reaction is also subject to allosteric regulation by AMP, and can be inhibited by the CTCB compounds with a similar potency to the forward reaction. Finally, we describe the mechanism of allosteric activation by AMP and inhibition by the drug-like compounds against trypanosomatid PFKs.
62	Endocytosis as an Additional Mechanism of Glucose Transport to the Hexose Transporter in Trypanosoma brucei Choi, JongSu 01 December 2018 (has links) Trypanosoma brucei is an extracellular kineotoplastid parasite that causes human African trypanosomiasis (HAT), also known as sleeping sickness. As trypanosomes undergo vector to host transition, heavy transcriptional adaptation such as metabolic shift to glycolysis and upregulated endocytosis occurs. Specifically, glycolysis in the infectious stage becomes the sole source of energy production; thus, the glucose transport mechanism in T. brucei provides one of the most promising therapeutic targets for development of new drugs to treat HAT. Despite an established trypanosome hexose transporter (THT) model for glucose transport across the plasma membrane, there remains gaps in the detailed mechanism of glucose transport especially as it relates to glucose transport across the glycosomal membrane. Using 2-NBDG, a fluorescent glucose analog, we measured glucose uptake rates in the presence of small molecule inhibitors and by using RNA interference (RNAi) to knockdown key proteins to investigate the mechanism of glucose transport in trypanosomes. We have confirmed a direct role of THT in glucose transport of BSF trypanosomes; however, in our investigations, we observed an unexpected ATP-dependence on glucose transport in live trypanosomes, which initiated further study where we focused on the role of endocytosis as an ATP-coupled bulk glucose transport mechanism. Experimental approaches that inhibited endocytosis reduced the observed glucose uptake rate confirming a role for endocytosis-coupled glucose transport in BSF trypanosomes. We provide evidence for an endocytosis-coupled glucose transport mechanism in BSF trypanosomes as an additional and important mechanism that functions in parallel with the established THT model. Trypanosoma brucei sleeping sickness trypanosome hexose transporter THT glucose transport endocytosis Physical Sciences and Mathematics
63	A computational approach for comparative oncogenomics using mouse models Brett, Benjamin Thomas 01 May 2014 (has links) Cancer is the second most common cause of death in the United States. It is a complex disease with environmental, genetic, and lifestyle factors influencing the likelihood of getting cancer and the development of any resulting tumor. Understanding the genetics of cancer is integral to developing novel patient-specific treatments. However, due to complexity, hundreds to thousands of tumors are required for sufficient power to identify the network of relationships among these genes. Animal models of cancer are commonly used to reduce cost and to control experimental variables allowing for more specific hypothesis testing. The Sleeping Beauty transposon mutagenesis system can be used to model cancer in mice. While the Sleeping Beauty mutagenesis system is an important tool in understanding cancer, it has specific computational needs. Experiments need to be analyzed in a fast, unbiased, and efficient manner. A computational method must also accurately model the system allowing for validation and interpretation. Here I present an updated Integration Analysis System and use this system to validate the assumptions present in forward genetic screens of cancer using the Sleeping Beauty. This system allows for rapid identification of cancer genes, but does not directly aid in understanding the relationship between the genes. Given the complexity of cancer, understanding the relationship between cancer genes is very difficult. I have created a connectedness network utilizing the STRING database to better derive an understanding of cancer genes. STRING is a database of known and predicted protein-protein interactions. The connectedness between pairs of genes is calculated using a network reliability metric. This database allows for increased power to detect known pathways when compared to STRING alone. Combining this connectivity network with the set of cancer genes identified by the Integration Analysis System is a strategy for rapid and efficient interpretation of the genetic results. Bioinformatics Cancer Comparative Oncogenomics Insertional Mutagenesis Network Biology Sleeping Beauty Genetics
64	Gynecological tissue homeostasis and tumorigenesis studies using mouse models Guimaraes-Young, Amy 01 December 2017 (has links) Gynecological cancers present a tremendous disease burden worldwide. Endometrial cancer, the most common gynecological malignancy, is predominantly a disease of deranged glandular function. The mechanisms by which known environmental risk factors influence the mutational profile of endometrial cancer are poorly understood. Non-HPV vulvar cancer, on the other hand, is a very rare gynecological malignancy of vulvar squamous cells with little known about its pathogenesis. Surgical resection of vulvar cancer is associated with high post-surgical morbidity. Pivotal to improving treatment and outcomes for patients with gynecological cancers is an understanding of the molecular drivers unique to each tumor type. To inform our understanding of endometrial gland regulation, I began my investigations with an assessment of normal endometrial adenogenesis in vivo and present the first evidence implicating the necessity of Sox17 in endometrial gland development. My data suggest Sox17 mediates adenogenesis via a non-cell autonomous mechanism from within the stromal compartment of the endometrium. I then interrogated the contribution of SOX17 to dysregulated glandular function in Type I endometrial adenocarcinoma in vitro. My findings reveal an oncogenic role of SOX17 in the Ishikawa Type 1 endometrial cancer cell line, with homozygous loss of SOX17 impairing cellular proliferation, blunting the cancer phenotype of these cells. The majority of cancers, including gynecological cancers, develop from the accumulation of genetic mutations that occur sporadically in cells over time. The complexity and heterogeneity of solid tumors, however, renders the identification of mutations responsible for driving tumorigenesis difficult. The Sleeping Beauty (SB) insertional mutagenesis system can be used to streamline sporadic tumor formation and driver mutation identification. I present results from an initial attempt to develop an SB model of endometrial cancer and discuss ways in which the SB system can be harnessed to evaluate tumorigenesis in a variety of tissue types and microenvironmental contexts. Finally, I present an SB model of metastatic vulvar cancer. Primary tumors from this model resulted in the identification of 76 novel candidate drivers of vulvar cancer, with the ubiquitin-specific peptidase, Usp9x, the most commonly disrupted gene in our screen. I show data suggesting that differential expression of Usp9x isoforms may underlie Usp9x-mediated tumorigenesis and preliminary data demonstrating the relevance of USP9X to human vulvar cancer. Taken as a whole, these data contribute to our scientific understanding of gynecological tissue homeostasis and cancers, lay the foundation for the development of an SB model of endometrial cancer, and describe the first reported model system for studying HPV-naive vulvar cancer in vivo. cancer endometrial development insertional mutagenesis Sleeping Beauty transposon Sox17 vulvar cancer Cell Anatomy Cell Biology
65	Design of a bioinformatics system for insertional mutagenesis analysis and its application to the Sleeping Beauty transposon system Nannapaneni, Kishore 01 May 2011 (has links) Cancer is one of the leading causes of death in the world. Approximately one fifth of deaths in the western industrial nations are caused by cancer. Every year several hundreds of thousands of new patients are diagnosed with cancer and several thousands die of cancer. Scientists have been conducting research from different angles for effective prevention, diagnosis and cure of Cancer. Ever since the genetic basis of cancer has been demonstrated, a race has been ignited globally in the scientific community to identify potential oncogenes and tumor suppressor genes. The genetics of the tumors are complex in nature where combinations of loss of function mutations in tumor suppressor genes and gain of function mutations in oncogenes cause cancers. The identification of these genes is extremely important to devise effective therapies to treat cancer. Insertional mutagenesis systems such as sleeping beauty provide an elegant way to identify genes involved in cancers. More and more researchers are adopting the Sleeping Beauty system for their insertional mutagenesis experiments to identify potential cancer causing genes. Given next generation sequence technologies and the vast amount of data they generate requires novel bioinformatics techniques to process, analyze and meaningfully interpret the data. The goal of this project is to develop a publicly available system for researchers worldwide to analyze the sequence data resulting from insertional mutagenesis experiments. This system will identify and annotate all the insertion sites resulting from the sequencing of the experiment. It will also identify the Common Insertion sites (CIS) and genes with Common Insertion Sites (gCIS). The Common Insertion Sites being the regions in the genome that are targeted more often than by chance. The whole system is accessible as a web application for use by researchers worldwide performing insertional mutagenesis experiments. Bioinformatics cancer CIS insertional Mutagenesis Sleeping Beauty transposon
66	Investigation of small molecules binding to UDP-galactose 4'-epimerase : - A validated drug target for <em>Trypanosoma brucei</em>, the parasite responsible for African Sleeping Sickness. Jinnelöv, Anders January 2009 (has links) No description available. African Sleeping Sickness Trypanosoma brucei UDP-galactose 4'-epimerase binding assays Molecular biology Molekylärbiologi
67	Deconstructing Sleeping Beauty : Angela Carter and <em>Écriture Feminine</em> Karjalainen, Anette January 2010 (has links) <p>When attempting to convey certain political or ideological agendas in literary texts maintaining specific writing strategies can work as a useful tool. From a feminist perspective the use of <em>écriture feminine</em> as a means of undermining patriarchy has been largely neglected as well as misunderstood by many feminists. However, as argued in this essay, <em>écriture feminine</em> is not only a useful tool for pursuing a feminist agenda, but is also something that needs to be discussed due to the many misunderstandings of it. Resting on the theoretical perspectives of Judith Butler, Hélène Cixous, Antonio Gramsci, Eve Kosofsky Sedgwick and Richard Slotkin this essay investigates Angela Carter’s short story “The Lady of the House of Love” in relation to <em>écriture feminine</em> by exploring how the text rejects patriarchy and its idea of the gender binary. In this short story Carter re-works the classic Sleeping Beauty fairy tale and provides us with a feminist’s version of it. The main thesis of this essay is therefore that Carter challenges the gender binary by de-victimizing “woman” and by engaging in a style of writing that overturns western culture’s definitions of “woman” Carter provides a version of Sleeping Beauty that radically differs from the hegemonic/patriarchal versions.</p> Angela Carter écriture feminine Sleeping Beauty feminism literature gender Hélène Cixous English language Engelska språket
68	Molecular and Cellular Complexity of Glioma : Highlights on the Double-Edged-Sword of Infiltration Versus Proliferation and the Involvement of T Cells Çağlayan, Demet January 2012 (has links) Glioblastoma multiforme (GBM), the most common and malignant brain tumor, is characterized by high molecular and cellular heterogeneity within and among tumors. Parameters such as invasive growth, infiltration of immune cells and endothelial proliferation contribute in a systemic manner to maintain the malignancy. Studies in this thesis show that the expression of Sox2 is correlated with Sox21 in human gliomas. We demonstrate that an upregulation of Sox21 induces loss of proliferation, apoptosis and differentiation in glioma cells in vitro and in vivo and seems to correlate with decreased Sox2 expression. Induced expression of Sox21 in vivo significantly reduces the tumor size and increase the survival extensively, suggesting that Sox21 can act as a tumor suppressor Our studies indicate that the balance of Sox21-Sox2 in glioma cells is decisive of either a proliferative or a non-proliferative state. Several TGFß family members have an important role in glioma development. TGFß promotes proliferation and tumorigenicity whereas BMPs mostly inhibit proliferation. We demonstrate that BMP7 can induce the transcription factor Snail in glioma cells and that this reduces the tumorigenicity with a concomitant increase in invasiveness. Thus, we have identified a mechanism to the double-edged sword of proliferation versus invasiveness in GBM, the latter contributing to relapse in patients. Experimental gliomas were induced with the Sleeping Beauty (SB) model in mice with different immunological status of their T cells. The tumors that developed were either GBMs or highly diffuse in their growth, reminiscent of gliomatosis cerebri (GC). GC is a highly uncommon form of glioma characterized by extensive infiltrative growth in large parts of the brain. It is an orphan disease and today there is practically a total lack of relevant experimental models. The SB system would constitute a novel experimental model to study the mechanisms behind the development of diffusely growing tumors like GC. The presence or absence of T cells did not affect tumor development. The work in this thesis demonstrates that the proliferative and the invasive capacities of glioma cells can be dissociated and that the SB model constitutes an excellent model to study the highly proliferative cells in GBMs versus the highly invasive cells in diffuse tumors like .GC. glioma Sox2 Sox21 Snail Bone morphogenetic protein Sleeping Beauty Gliomatosis Cerebri T lymphocytes T regulatory lymphocytes
69	Investigation of small molecules binding to UDP-galactose 4'-epimerase : A validated drug target for Trypanosoma brucei, the parasite responsible for African Sleeping Sickness. Jinnelöv, Anders January 2009 (has links) African sleeping sickness is a parasitic infection spread by the protozoan parasite Trypanosoma brucei, and drugs used today are toxic and painful. Galactose metabolism is essential for the survival of T. brucei and without a functional UDP galactose 4’ epimerase (GalE) galactose starvation occurs and cell death will follow. In this Master thesis project two assays observing binding of small molecules to TbGalE has been investigated in attempt to establish an assay that in the future could be used for screening for drugs. TbGalE was biotinylated through the Pinpoint Xa vector and expressed in E. coli cells. The protein was successfully immobilized to a Streptavidin chip for Surface Plasmon Resonance experiments and the binding of the substrates UDP-galactose and UDP-glucose was observed. Unfortunately, the assay was not optimal for screening due to low signal response. However, the established protocol for expressing biotinylated proteins that bind to Streptavidin surfaces could be used in further experiments with TbGalE and other drug targets for African sleeping sickness. The fluorescent sugar nucleotide analogue UDPAmNS, which is a known inhibitor for E. coli GalE, was synthesised and purified and then used to establish a displacement assay. IC50 of UDPAmNS against TbGalE was determined and a synergic effect in fluorescence between the protein and the inhibitor was proven. Further, evidence for a reduction in fluorescence by displacing UDPAmNS with UDP was obtained. This reduction in fluorescence was also shown by a predicted cofactor inhibitor. The IC50 against TbGalE for this compound was determined before the displacement assay, which showed that the cofactor inhibitor, at least partly, binds to the active site of TbGalE. The UDPAmNS displacement assay could have the potential of becoming a robust screening assay for TbGalE, in the effort to find a better drug for African sleeping sickness. African Sleeping Sickness Trypanosoma brucei UDP-galactose 4'-epimerase binding assays Molecular biology Molekylärbiologi
70	A description and analysis of a cohabiting sample in America Bower, Donald Wayne, 1952- January 1975 (has links) No description available. Sex customs -- United States. Sleeping customs -- United States. Sex. Sexology -- Research.

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