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Tunable hydrogels for pancreatic tissue engineeringRaza, Asad 03 January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Type I diabetes is an autoimmune disorder characterized by the loss of insulin producing islet cell mass. While daily insulin injection provides an easy means of glycemic control, it does not prevent long-term complications associated with diabetes. Islet transplantation has been suggested as a permanent cure for type 1 diabetes. However, the recurrence of host immunity and shortage of donor islets hinder the prevalence of islet transplantation. Biomaterial strategies provide an alternative route to solving the problems associated with host immune response and shortage of donor islets. One highly recognized platform for achieving these goals are hydrogels, which are hydrophilic crosslinked polymers with tissue-like elasticity and high permeability. Hydrogels prepared from poly(ethylene glycol) (PEG) derivatives are increasingly used for a variety of tissue engineering applications, including encapsulation of pancreatic islets and serving as a material platform for pseudo-islet differentiation. PEG hydrogels formed by mild and rapid thiol-ene photo-click reactions are particularly useful for studying cell behaviors in three-dimension (3D). Thiol-ene PEG-based hydrogels can be rendered biodegradable if appropriate macromer and cross-linker chemistry is employed. However, the influence of hydrogel matrix properties on the survival, growth, and morphogenesis of cells in 3D has not been fully evaluated. This thesis aims at using norbornene-functionalized PEG macromers to prepare thiol-ene hydrogels with various stiffness and degradability, from which to study the influence of hydrogel properties on pancreatic cell fate processes in 3D. Toward establishing an adaptable hydrogel platform
for pancreatic tissue engineering, this thesis systematically studies the influence of hydrogel properties on encapsulated endocrine cells (e.g., MIN6 beta-cells) and exocrine cells (PANC-1 cells), as well as human mesenchymal stem cells (hMSC). It was found that thiol-ene photo-click hydrogels provide a cytocompatible environment for 3D culture of these cells. However, cell viability was negatively affected in hydrogels with higher cross-linking density. In contrast to a monolayer when cultured on a 2D surface, cells with epithelial characteristic formed clusters and cells with mesenchymal features retained single cell morphology in 3D. Although cells survived in all hydrogel formulations studied, the degree of proliferation, and the size and morphology of cell clusters formed in 3D were significantly influenced by hydrogel matrix compositions. For example: encapsulating cells in hydrogels formed by hydrolytically degradable macromer positively influenced cell survival indicated by increased proliferation. In addition, when cells were encapsulated in thiol-ene gels lacking cell-adhesive motifs, hydrolytic gel degradation promoted their survival and proliferation. Further, adjusting peptide crosslinker type and immobilized ECM-mimetic bioactive cues provide control over cell fate by determining whether observed cellular morphogenesis is cell-mediated or matrix-controlled. These fundamental studies have established PEG-peptide hydrogels formed by thiol-ene photo-click reaction as a suitable platform for pancreatic tissue engineering
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Mechanisms of translational regulation in the pancreatic β cell stress responseTemplin, 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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Novel Roles of p21 in Apoptosis During Beta-Cell Stress in DiabetesHernández-Carretero, Angelina M. January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Type 2 diabetes manifests from peripheral insulin resistance and a loss of functional beta cell mass due to decreased beta cell function, survival, and/or proliferation. Beta cell stressors impair each of these factors by activating stress response mechanisms, including endoplasmic reticulum (ER) stress. The glucolipotoxic environment of the diabetic milieu also activates a stress response in beta cells, resulting in death and decreased survival. Whereas the cell cycle machinery (comprised of cyclins, kinases, and inhibitors) regulates proliferation, its involvement during beta cell stress in the development of diabetes is not well understood. Interestingly, in a screen of multiple cell cycle inhibitors, p21 was dramatically upregulated in INS-1-derived 832/13 cells and rodent islets by two independent pharmacologic inducers of beta cell stress - dexamethasone and thapsigargin. In addition, glucolipotoxic stress mimicking the diabetic milieu also induced p21. To further investigate p21’s role in the beta cell, p21 was adenovirally overexpressed in 832/13 cells and rat islets. As expected given p21’s role as a cell cycle inhibitor, p21 overexpression decreased [3H]-thymidine incorporation and blocked the G1/S and G2/M transitions as quantified by flow cytometry. Interestingly, p21 overexpression activated apoptosis, demonstrated by increased annexin- and propidium iodide-double-positive cells and cleaved caspase-3 protein. p21-mediated caspase-3 cleavage was inhibited by either overexpression of the anti-apoptotic mitochondrial protein Bcl-2 or siRNA-mediated suppression of the pro-apoptotic proteins Bax and Bak. Therefore, the intrinsic apoptotic pathway is central for p21-mediated cell death. Like glucolipotoxicity, p21 overexpression inhibited the insulin cell survival signaling pathway while also impairing glucose-stimulated insulin secretion, an index of beta cell function. Under both conditions, phosphorylation of insulin receptor substrate-1, Akt, and Forkhead box protein-O1 was reduced. p21 overexpression increased Bim and c-Jun N-terminal Kinase, however, siRNA-mediated reduction or inhibition of either protein, respectively, did not alter p21-mediated cell death. Importantly, islets of p21-knockout mice treated with the ER stress inducer thapsigargin displayed a blunted apoptotic response. In summary, our findings indicate that p21 decreases proliferation, activates apoptosis, and impairs beta cell function, thus being a potential target to inhibit for the protection of functional beta cell mass.
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