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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.
91

Heat shock protein 90, a potential biomarker for type I diabetes: mechanisms of release from pancreatic beta cells

Ocaña, Gail Jean 23 May 2016 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / Heat shock protein (HSP) 90 is a molecular chaperone that regulates diverse cellular processes by facilitating activities of various protein clients. Recent studies have shown serum levels of the alpha cytoplasmic HSP90 isoform are elevated in newly diagnosed type I diabetic patients, thus distinguishing this protein as a potential biomarker for pre-clinical type I diabetes mellitus (TIDM). This phase of disease is known to be associated with various forms of beta cell stress, including endoplasmic reticulum stress, insulitis, and hyperglycemia. Therefore, to test the hypothesis that HSP90 is released by these cells in response to stress, human pancreatic beta cells were subjected to various forms of stress in vitro. Beta cells released HSP90 in response to stimulation with a combination of cytokines that included IL-1β, TNF-α, and IFN-γ, as well as an agonist of toll-like receptor 3. HSP90 release was not found to result from cellular increases in HSP90AA1 gene or HSP90 protein expression levels. Rather, cell stress and ensuing cytotoxicity mediated by c-Jun N-terminal kinase (JNK) appeared to play a role in HSP90 release. Beta cell HSP90 release was attenuated by pre-treatment with tauroursodeoxycholic acid (TUDCA), which has been shown previously to protect beta cells against JNK-mediated, cytokine-induced apoptosis. Experiments here confirmed TUDCA reduced beta cell JNK phosphorylation in response to cytokine stress. Furthermore pharmacological inhibition and siRNA-mediated knockdown of JNK in beta cells also attenuated HSP90 release in response to cytokine stress. Pharmacological inhibition of HSP90 chaperone function exacerbated islet cell stress during the development of TIDM in vivo; however, it did not affect the overall incidence of disease. Together, these data suggest extracellular HSP90 could serve as a biomarker for preclinical TIDM. This knowledge may be clinically relevant in optimizing treatments aimed at restoring beta cell mass. The goal of such treatments would be to halt the progression of at-risk patients to insulin dependence and lifelong TIDM.
92

Characterizing the Role Toll Like Receptor 3 (TLR3) Plays in Viral-Mediated Type 1 Diabetes in Female Non-Obese Diabetic (NOD) Mice

Benner, Sarah E. 04 June 2019 (has links)
No description available.
93

Islet insulin secretory patterns in diabetes and the role of UCP2

Lin, Jian-Man January 2002 (has links)
<p>During development of type 1 and type 2 diabetes plasma insulin patterns are altered. Since the islet insulin release pattern has been implicated in this development, insulin secretion from single islets was studied and linked to the islet protein levels of uncoupling protein-2 (UCP2). Islets were isolated from NOD- and KKA<sup>y</sup>- mice, GK- and GK-derived congenic rats, which are animal models of diabetes, and three human subjects with type 2 diabetes. At basal glucose (3 mM), insulin release from such islets was pulsatile and the amount released was comparable to that of control islets. When the glucose concentration was raised to 11 mM insulin release was essentially unchanged in islets isolated from older NOD- and KKA<sup>y</sup>- mice, GK- and Niddm1i congenic rats, and NIDDM persons. In islets from Niddm1f congenic rats, younger NOD- and KKA<sup>y</sup>-mice, control animals and normal human donors the secretion rate increased 2-9 fold when the glucose concentration was raised. This rise in secretion was manifested as increase of the amplitude of the insulin oscillations without affecting their frequency. Impaired glucose-induced insulin release was associated with reduction in glucose oxidation measured in NOD-islets, unaffected respiration measured in GK-islets and higher protein level of UCP2 measured in KKA<sup>y</sup>-islets. When the UCP2 amounts in KKA<sup>y</sup>-islets were reduced by culture to those of control islets, glucose-induced insulin secretion was essentially normalized. Our studies suggest that the deranged plasma insulin patterns observed in diabetes are related to decrease in the amplitude of insulin oscillations from the islets rather than loss of the oscillatory activity. This reduction of pulse amplitude may be related to impaired glucose metabolism and/or increased mitochondrial uncoupling. </p>
94

Islet insulin secretory patterns in diabetes and the role of UCP2

Lin, Jian-Man January 2002 (has links)
During development of type 1 and type 2 diabetes plasma insulin patterns are altered. Since the islet insulin release pattern has been implicated in this development, insulin secretion from single islets was studied and linked to the islet protein levels of uncoupling protein-2 (UCP2). Islets were isolated from NOD- and KKAy- mice, GK- and GK-derived congenic rats, which are animal models of diabetes, and three human subjects with type 2 diabetes. At basal glucose (3 mM), insulin release from such islets was pulsatile and the amount released was comparable to that of control islets. When the glucose concentration was raised to 11 mM insulin release was essentially unchanged in islets isolated from older NOD- and KKAy- mice, GK- and Niddm1i congenic rats, and NIDDM persons. In islets from Niddm1f congenic rats, younger NOD- and KKAy-mice, control animals and normal human donors the secretion rate increased 2-9 fold when the glucose concentration was raised. This rise in secretion was manifested as increase of the amplitude of the insulin oscillations without affecting their frequency. Impaired glucose-induced insulin release was associated with reduction in glucose oxidation measured in NOD-islets, unaffected respiration measured in GK-islets and higher protein level of UCP2 measured in KKAy-islets. When the UCP2 amounts in KKAy-islets were reduced by culture to those of control islets, glucose-induced insulin secretion was essentially normalized. Our studies suggest that the deranged plasma insulin patterns observed in diabetes are related to decrease in the amplitude of insulin oscillations from the islets rather than loss of the oscillatory activity. This reduction of pulse amplitude may be related to impaired glucose metabolism and/or increased mitochondrial uncoupling.
95

Prevention of type 1 diabetes mellitus in experimental studies

Holstad, Maria January 2001 (has links)
The aim of the study was to examine the immune response and different immunoprotective strategies in experimental type 1 diabetes mellitus. The autoimmune destruction of the insulin-producing pancreatic β-cells that leads to type 1 diabetes is complex and incompletely understood. Activated immune cells infiltrate the pancreatic islets at an early stage of the disease, and they produce and release cytokines, which may contribute to β-cell dysfunction and death. Several immunomodulatory agents with different mechanisms have recently been developed in order to suppress cytokine function such as MDL 201, 449A, a novel transcriptional inhibitor of TNF-α. At least in rodent β-cells, many of the toxic actions of cytokines depend on the synthesis of nitric oxide (NO). Aminoguanidine (AG), an inhibitor of NO formation, might therefore be an interesting compound for prevention of type 1 diabetes. Another substance that could influence the course of events leading to this disease is the pituitary hormone prolactin (PRL), since it has the ability to activate different immune cells. We have studied the effects of AG, PRL and MDL 201, 449A on the development of hyperglycaemia and pancreatic insulitis in multiple low dose streptozotocin induced autoimmune diabetes in mice. The natural course after syngeneic islet transplantation of pancreatic islets in NOD mice, a model of type 1 diabetes mellitus was also investigated. AG and PRL were also studied in vitro on cultured isolated rodent pancreatic islets. We suggest that the insulin-producing cells are specifically targeted by the inflammatory response after syngeneic islet transplantation in type 1 diabetic mice. Our data do not exclude a role for NO in type 1 diabetes, but it raises concerns about the use of AG as a therapeutic agent since an increased mortality and no decline in diabetes frequency was observed. AG did not seem to be directly harmful to β-cell function, but it could affect pancreatic and islet blood flows. PRL and MDL 201, 449A could both counteract hyperglycaemia and insulitis in the early phase of autoimmune diabetes.
96

Proteolytic Processing of Nlrp1b in the FIIND Domain is Required for Inflammasome Activity

Frew, Bradley 21 March 2012 (has links)
Nlrp1b is a NOD-like receptor of the innate immune system that upon sensing of anthrax lethal toxin oliogmerizes and forms a protein scaffold that binds to and activates pro-caspase-1; this complex is called an inflammasome. Nlrp1b is highly polymorphic and different alleles display an all or none ability to sense lethal toxin. Here I show that Nlrp1b is cleaved in the FIIND domain, and that the cleaved fragments remain associated even after activation by lethal toxin. The inflammasome activity of an inactive allele was restored by three mutations, one of which also restored cleavage. A heterologous cleavage site was inserted into an uncleaved mutant of Nlrp1b; induced proteolysis of the cleavage site rescued inflammasome activity. An uncleaved mutant of Nlrp1b showed no deficiency in FIIND self-association, but did have reduced recruitment of pro-caspase-1. These data provide evidence that cleavage of Nlrp1b is required for proper recruitment and activation of caspase-1.
97

Proteolytic Processing of Nlrp1b in the FIIND Domain is Required for Inflammasome Activity

Frew, Bradley 21 March 2012 (has links)
Nlrp1b is a NOD-like receptor of the innate immune system that upon sensing of anthrax lethal toxin oliogmerizes and forms a protein scaffold that binds to and activates pro-caspase-1; this complex is called an inflammasome. Nlrp1b is highly polymorphic and different alleles display an all or none ability to sense lethal toxin. Here I show that Nlrp1b is cleaved in the FIIND domain, and that the cleaved fragments remain associated even after activation by lethal toxin. The inflammasome activity of an inactive allele was restored by three mutations, one of which also restored cleavage. A heterologous cleavage site was inserted into an uncleaved mutant of Nlrp1b; induced proteolysis of the cleavage site rescued inflammasome activity. An uncleaved mutant of Nlrp1b showed no deficiency in FIIND self-association, but did have reduced recruitment of pro-caspase-1. These data provide evidence that cleavage of Nlrp1b is required for proper recruitment and activation of caspase-1.
98

Immunotherapy for autoimmune diabetes

Jain, Renu, Zaghouani, Habib. January 2008 (has links)
The entire dissertation/thesis text is included in the research.pdf file; the official abstract appears in the short.pdf file (which also appears in the research.pdf); a non-technical general description, or public abstract, appears in the public.pdf file. Title from PDF of title page (University of Missouri--Columbia, viewed on April 1, 2010). Vita. Thesis advisor: Habib Zaghouani. "May 2008" Includes bibliographical references.
99

The Humanized Mouse Model: The Study of the Human Alloimmune Response: A Dissertation

King, Marie A. 22 May 2008 (has links)
The transplantation of allogeneic cells and tissues for the treatment of human disease has been a life-saving procedure for many thousands of patients worldwide. However, to date, neither solid organ transplantation nor bone marrow transplantation have reached their full clinical potential. Significant limitations to the advancement of clinical transplantation stem from our current inability to prevent the rejection of allogeneic tissues by the immune system of the host. Similarly, in patients that receive allogeneic bone marrow transplants, we cannot permanently prevent the engrafted immune system from mounting a response against the patient. This problem, termed graft versus host disease is the most prevalent cause of morbidity and mortality in recipients of allogeneic bone marrow transplants. Clinically, we rely on lifelong immunosuppression to prolong survival of allogeneic tissues within the host. Our currently available therapeutics burden patients with side-effects that range from being unpleasant to life-threatening, while in most cases offering only a temporary solution to the problem of alloimmunity. Efforts are underway to develop protocols and therapeutics that more effectively prevent the pathology associated with alloimmunity. To minimize patient risk, extensive pre-clinical studies in laboratory animals are conducted to predict clinical responses. In the case of immunologic studies, many of these pre-clinical studies are carried out in murine models. Unfortunately, studies of murine immunity often do not predict outcomes in the clinic. One approach to overcome this limitation is the development of a small animal model of the human immune system. In this dissertation, we hypothesized that NOD-scid IL2rγnull mice engrafted with human peripheral blood mononuclear cells (PBMC), termed the hu-PBMC-NOD-scid IL2rγnull model, would provide a model that more accurately reflects human immunity in vivo than other models currently available. To investigate this possibility, we first investigated whether NOD-scid IL2rγnull mice were able to support the engraftment of human PBMC. We found that NOD-scid IL2rγnull mice engraft with human PBMC at much higher levels then the previous gold standard model, the NOD-scid mouse. We then investigated the kinetics of human cell engraftment, determined the optimal cell dose, and defined the influence of injection route on engraftment levels. Even at low PBMC input, NOD-scid IL2rγnullmice reproducibly support high levels of human PBMC engraftment. In contrast to previous stocks of immunodeficient mice, we observed low intra- and interdonor variability of engraftment. We next hypothesized that the human PBMC engrafted in NOD-scid IL2rγnull mice were functional and would reject transplanted allogeneic human tissues. To test this, human islets were transplanted into the spleen of chemically diabetic NOD-scid IL2rγnull mice with or without intravenous injection of HLA-mismatched human PBMC. In the absence of allogeneic PBMC, the human islets were able to restore and maintain normoglycemia. In contrast, human islet grafts were completely rejected following injection of HLA-mismatched human PBMC as evidenced by return to hyperglycemia and loss of human C-peptide in the circulation. Thus, PBMC engrafted NOD-scid IL2rγnull mice are able to provide an in vivomodel of a functional human immune system and of human islet allograft rejection. The enhanced ability of NOD-scid IL2rγnull mice to support human cell engraftment gave rise to the possibility of creating a model of graft versus host disease mediated by a human immune system. To investigate this possibility, human PBMC were injected via the tail vein into lightly irradiated NOD-scid IL2rγnull mice. We found that in contrast to previous models of GVHD using human PBMC-injected immunodeficient mice, these mice consistently (100%) developed GVHD following injection of as few as 5x106PBMC, regardless of the PBMC donor used. We then tested the contribution of host MHC in the development of GVHD in this model. As in the human disease, the development of GVHD was highly dependent on host expression of MHC class I and class II molecules. To begin to evaluate the extent to which the PBMC-engrafted NOD-scid IL2rγnull humanized mouse model of GVHD represents the clinical disease, we tested the ability of a therapeutic in clinical trials to modulate GVHD in these mice. In agreement with the clinical experience, we found that interrupting the TNFα signaling cascade with etanercept delayed the onset and severity of disease in this model. In summary, we conclude that humanized NOD-scid IL2rγnull mice represent an important surrogate for investigating in vivo mechanisms of both human islet allograft rejection and graft versus host disease.
100

The Genetic Basis of Resistance to Transplantation Tolerance Induced by Costimulation Blockade in NOD Mice: a Dissertation

Pearson, Todd 17 March 2003 (has links)
The NOD mouse is a widely studied model of type 1 diabetes. The loss of self-tolerance leading to autoimmune diabetes in NOD mice involves at least 27 genetic loci. Curing type I diabetes in mice and humans by islet transplantation requires overcoming both allorejection and recurrent autoimmunity. This has been achieved with systemic immunosuppression, but tolerance induction would be preferable. In addition to their genetic defects in self-tolerance, NOD mice resist peripheral transplantation tolerance induced by costimulation blockade using donor-specific transfusion and anti-CDl54 antibody. Failure has been attributed to the underlying autoimmunity, assuming that autoimmunity and resistance to transplantation tolerance have a common basis. Hypothesizing that these two abnormalities might be related, we investigated whether they had a common genetic basis. Diabetes-resistant NOD and C57BL/6 stocks congenic for various reciprocally introduced Idd loci were assessed for their ability to be tolerized. Surprisingly, in NOD congenic mice that are almost completely protected from diabetes, costimulation blockade failed to prolong skin allograft survival. In reciprocal C57BL/6 congenic mice with NOD-derived Idd loci, skin allograft survival was readily prolonged by costimulation blockade. Unexpectedly, we observed that (NOD x C57BL/6)F1 mice, which have no diabetes, nonetheless resist induction of tolerance to skin allografts. Further analyses revealed that the F1 mice shared the dendritic cell maturation defects and abnormal CD4+ T cell responses of the NOD but had lost its defects in macrophage maturation and NK cell activity. Finally, using a genome wide scan approach, we have identified four suggestive markers in the mouse genome that control the survival of skin allografts following DST and anti-CD154 mAb therapy. We suggest that mechanisms controlling autoimmunity and transplantation tolerance in NOD mice are not completely overlapping and are potentially distinct, or that the genetic threshold for normalizing the transplantation tolerance defect is higher than that for preventing autoimmune diabetes. We conclude that resistance to allograft tolerance induction in the NOD mouse is not a direct consequence of overt autoimmunity and that autoimmunity and resistance to costimulation blockade-induced transplantation tolerance phenotypes in NOD mice are not under identical genetic control.

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