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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.
11

Pancreatic Endocrine Tumourigenesis : Genes of potential importance

Johansson, Térèse A. January 2008 (has links)
Understanding signalling pathways that control pancreatic endocrine tumour (PET) development and proliferation may reveal novel targets for therapeutic intervention. The pathogenesis for sporadic and hereditary PETs, apart from mutations of the MEN1 and VHL tumour suppressor genes, is still elusive. The protein product of the MEN1 gene, menin, regulates many genes. The aim of this thesis was to identify genes involved in pancreatic endocrine tumourigenesis, with special reference to Notch signalling. Messenger RNA and protein expression of NOTCH1, HES1, HEY1, ASCL1, NEUROG3, NEUROD1, DLK1, POU3F4, PDX1, RPL10, DKK1 and TPH1 were studied in human PETs, sporadic and MEN 1, as well as in tumours from heterozygous Men1 mice. For comparison, normal and MEN1 non-tumourous human and mouse pancreatic specimens were used. Nuclear expression of HES1 was consistently absent in PETs. In mouse tumours this coincided with loss of menin expression, and there was a correlation between Men1 expression and several Notch signalling factors. A new phenotype consisting of numerous menin-expressing endocrine cell clusters, smaller than islets, was found in Men1 mice. Expression of NEUROG3 and NEUROD1 was predominantly localised to the cytoplasm in PETs and islets from MEN 1 patients and Men1 mice, whereas expression was solely nuclear in wt mice. Differences in expression levels of Pou3f4, Rpl10 and Dlk1 between islets of Men1 and wt mice were observed. In addition, combined RNA interference and microarray expression analysis in the pancreatic endocrine cell line BON1 identified 158 target genes of ASCL1. For two of these, DKK1 (a negative regulator of the WNT/β-catenin signalling pathway) and TPH1, immunohistochemistry was performed on PETs. In concordance with the microarray finding, DKK1 expression showed an inverse relation to ASCL1 expression. Altered subcellular localisation of HES1, NEUROD1 and NEUROG3 and down-regulation of DKK1 may contribute to tumourigenesis.
12

Mechanisms of transcriptional regulation in the maintenance of β cell function

Maganti Vijaykumar, Aarthi 08 May 2015 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) Indiana University School of Medicine / The islet β cell is central to the maintenance of glucose homeostasis as the β cell is solely responsible for the synthesis of Insulin. Therefore, better understanding of the molecular mechanisms governing β cell function is crucial to designing therapies for diabetes. Pdx1, the master transcription factor of the β cell, is required for the synthesis of proteins that maintain optimal β cell function such as Insulin and glucose transporter type 2. Previous studies showed that Pdx1 interacts with the lysine methyltransferase Set7/9, relaxing chromatin and increasing transcription. Because Set7/9 also methylates non-histone proteins, I hypothesized that Set7/9-mediated methylation of Pdx1 increases its transcriptional activity. I showed that recombinant and cellular Pdx1 protein is methylated at two lysine residues, Lys123 and Lys131. Lys131 is involved in Set7/9 mediated augmented transactivation of Pdx1 target genes. Furthermore, β cell-specific Set7/9 knockout mice displayed glucose intolerance and impaired insulin secretion, accompanied by a reduction in the expression of Pdx1 target genes. Our results indicate a previously unappreciated role for Set7/9 in the maintenance of Pdx1 activity and β cell function. β cell function is regulated on both the transcriptional and translational levels. β cell function is central to the development of type 1 diabetes, a disease wherein the β cell is destroyed by immune cells. Although the immune system is considered the primary instigator of the disease, recent studies suggest that defective β cells may initiate the autoimmune response. I tested the hypothesis that improving β cell function would reduce immune infiltration of the islet in the NOD mouse, a mouse model of spontaneous type 1 diabetes. Prediabetic NOD mice treated with pioglitazone, a drug that improves β cell function, displayed an improvement in β cell function, a reduction in β cell death, accompanied by reductions in β cell autoimmunity, indicating that β cell dysfunction assists in the development of type 1 diabetes. Therefore, understanding the molecular mechanisms involved in β cell function is essential for the development of therapies for diabetes.
13

Diferenciace pankreatických kmenových buněk na β-buňky produkující inzulín. / Differentiation of pancreatic stem cells into insulin producing β-cells.

Leontovyč, Ivan January 2019 (has links)
Diabetes mellitus (DM) is a severe and frequent disease with increasing prevalence. It is not possible to achieve long term cure without late complications. Recent advances in cell fate modifications open a pathway to alternative cell therapies for DM cure. My doctoral thesis "Differentiation of pancreatic stem cells into insulin producing β- cells" is focused on the development of a new source of insulin secreting cells for transplantation. Combinatorial testing of numerous potential transcription factors and epigenetic modifiers resulted in a final protocol for the reprogramming pancreatic of exocrine cells into insulin secreting cells. The key transcriptional factors TF (Pdx1, Ngn3 a MafA) were applied in the form of synthetic mRNA. In four independent experiments we applied transcriptional factors in a specific sequence, thus obtaining 14.3 ± 1.9 % insulin positive cells. When challenged in vitro by the glucose levels of 2.5 and 20 mmol/l glucose, respectively, these cells exhibited glucose-sensitivity of insulin secretion (842 ± 72 and 1 157 ± 58 pg insulin/µg DNA/ml, n=5). They also demonstrated a sensitivity of insulin secretion (863 ± 78 and 1 025 ± 66 pg insulin/µg DNA/ml, n=5) to the concentration of depolarization agent KCl applied at 0 and 30 mmol/l, respectively together with 2.5...
14

Mechanisms of translational regulation in the pancreatic β cell stress response

Templin, Andrew Thomas January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / The islet beta cell is unique in its ability to synthesize and secrete insulin for use in the body. A number of factors including proinflammatory cytokines, free fatty acids, and islet amyloid are known to cause beta cell stress. These factors lead to lipotoxic, inflammatory, and ER stress in the beta cell, contributing to beta cell dysfunction and death, and diabetes. While transcriptional responses to beta cell stress are well appreciated, relatively little is known regarding translational responses in the stressed beta cell. To study translation, I established conditions in vitro with MIN6 cells and mouse islets that mimicked UPR conditions seen in diabetes. Cell extracts were then subjected to polyribosome profiling to monitor changes to mRNA occupancy by ribosomes. Chronic exposure of beta cells to proinflammatory cytokines (IL-1 beta, TNF-alpha, IFN-gamma), or to the saturated free fatty acid palmitate, led to changes in global beta cell translation consistent with attenuation of translation initiation, which is a hallmark of ER stress. In addition to changes in global translation, I observed transcript specific regulation of ribosomal occupancy in beta cells. Similar to other privileged mRNAs (Atf4, Chop), Pdx1 mRNA remained partitioned in actively translating polyribosomes during the UPR, whereas the mRNA encoding a proinsulin processing enzyme (Cpe) partitioned into inactively translating monoribosomes. Bicistronic luciferase reporter analyses revealed that the distal portion of the 5’ untranslated region of mouse Pdx1 (between bp –105 to –280) contained elements that promoted translation under both normal and UPR conditions. In contrast to regulation of translation initiation, deoxyhypusine synthase (DHS) and eukaryotic translation initiation factor 5A (eIF5A) are required for efficient translation elongation of specific stress relevant messages in the beta cell including Nos2. Further, p38 signaling appears to promote translational elongation via DHS in the islet beta cell. Together, these data represent new insights into stress induced translational regulation in the beta cell. Mechanisms of differential mRNA translation in response to beta cell stress may play a key role in maintenance of islet beta cell function in the setting of diabetes.

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