UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

When conjugated to various proteins, the nontoxic B-chain of cholera toxin (CTB) significantly increases the ability of these proteins to induce immunological tolerance after oral administration. Here, we investigated if a nonconjugated form of CTB enhances the induction of immune tolerance after oral insulin administration. Induction of immunological tolerance was studied after oral administration of insulin preparations in three mouse models; an insulin/ovalbumin coimmunization model, a model of virus-induced diabetes in transgenic RIP-LCMV-NP mice and in nonobese diabetic (NOD) mice serving as a model of spontaneous diabetes. In the immunization model, we demonstrate that mixing with CTB increases the tolerogenic potential of insulin, approximately 10 fold. Titration of the CTB concentration in this system revealed that an insulin : CTB ratio of 100 : 1 was optimal for the induction of bystander suppression. Further studies revealed that this insulin : CTB ratio also was optimal for the prevention of diabetes in a virus-induced, transgenic diabetes model. In addition, the administration of this optimal insulin-CTB preparation significantly prevented the onset of diabetes in old NOD mice with established islet infiltration. The data presented here demonstrate that CTB, even in its unconjugated form, functions as a mucosal adjuvant, increasing the specific tolerogenic effect of oral insulin.
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PMID:The cholera toxin B subunit is a mucosal adjuvant for oral tolerance induction in type 1 diabetes. 1275 99

The major predisposing genetic component in type 1 diabetes (T1D) maps to the MHC locus in both mice and humans. To better understand the HLA class II association with disease pathogenesis, we bred mice expressing HLA-DQ8 and -DR3, either alone or in combination, to transgenic mice expressing the co-stimulatory molecule B7-1 in the beta cells of islets of Langerhans. Spontaneous diabetes occurred only in RIP-B7-1 transgenic mice expressing transgenic HLA-DR3 or -DQ8 molecules and the incidence of diabetes was comparable between the two (approximately 30% in either sex up to 50 weeks of age). Presence of DR3 and DQ8 together only marginally elevated the overall incidence of spontaneous disease (38%). Non-specific activation of T cells by superantigen and provision of concomitant co-stimulation through 4-1BB (CD137) by an agonistic antibody did not accelerate the incidence of diabetes over a short period of time. Neither the antibody-mediated depletion of CD25+ T cells nor sublethal, whole-body irradiation of young, naive HLA transgenic mice expressing RIP-B7-1 resulted in diabetes. However, administration of only two doses of the beta cell toxin streptozotocin (STZ; 40 mg/kg) induced autoimmune diabetes in 85% of mice within 7 weeks after STZ treatment only when B7-1 was expressed on the pancreatic beta cells. This effect was HLA dependent as none of the STZ-treated RIP-B7-1 transgenic mice lacking HLA class II developed diabetes. In conclusion, this study confirmed the diabetogenic potential of HLA-DQ8 and established the role of HLA-DR3 in the pathogenesis of T1D.
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PMID:Autoimmune diabetes in HLA-DR3/DQ8 transgenic mice expressing the co-stimulatory molecule B7-1 in the beta cells of islets of Langerhans. 1291 55

We have studied the induction and effector function of Th2-like regulatory cells in mouse models for type 1 diabetes (NOD and RIP-LCMV). CD4+ lymphocytes with specificity for insulin can be induced by immunization with the insulin B chain via the oral route or by DNA vaccination. Such cells are protective upon adoptive transfer and prevent diabetes development in syngeneic pre-diabetic recipients. In comparison to non-regulatory insulin B-specific cell lines, they produce high amounts of interleukin (IL)4 and IL10, whereas interferon (IFN)gamma and tumour necrosis factor (TNF)alpha levels are comparable. Indeed, IL4 is essential for the protective capability, as evidenced by use of IL4-deficient mice and sorting of IL4+ versus IL4- lymphocytes prior to transfer. Mechanistically, these cells act as bystander suppressors in the pancreatic draining node, the location where their cognate antigen, insulin B, is presented during the pre-diabetic inflammatory process. As a consequence, the autoaggressive response is locally dampened. We propose that this is achieved by modulation of antigen presenting cells that lose the ability to propagate aggressive responses after exposure to IL4 or IL10 in vitro. The clinically attractive side of our strategy is that it only acts as the site of inflammation, thus circumventing systemic side effects. In order to avoid induction of insulin B-specific autoaggressive T cells we have demonstrated that administration of IL4 or IL10 at the time of immunization is beneficial and therefore should be part of a potential future clinical application. Interestingly, these Th2-like regulators share in our systems no features with the so-called CD25+ regulatory cells, whose antigen specificity is still unclear. However, we have recent evidence that virus specific CD25+ cells can be generated and are able to affect antiviral responses in vivo.
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PMID:Regulation of viral and autoimmune responses. 1460 23

Viruses can cause but can also prevent autoimmune disease. This dualism has certainly hampered attempts to establish a causal relationship between viral infections and type 1 diabetes (T1D). To develop a better mechanistic understanding of how viruses can influence the development of autoimmune disease, we exposed prediabetic mice to various viral infections. We used the well-established NOD and transgenic RIP-LCMV models of autoimmune diabetes. In both cases, infection with the lymphocytic choriomeningitis virus (LCMV) completely abrogated the diabetic process. Interestingly, such therapeutic viral infections resulted in a rapid recruitment of T lymphocytes from the islet infiltrate to the pancreatic draining lymph node, where increased apoptosis was occurring. In both models this was associated with a selective and extensive expression of the chemokine IP-10 (CXCL10), which predominantly attracts activated T lymphocytes, in the pancreatic draining lymph node, and in RIP-LCMV mice it depended on the viral antigenic load. In RIP-LCMV mice, blockade of TNF-alpha or IFN-gamma in vivo abolished the prevention of T1D. Thus, virally induced proinflammatory cytokines and chemokines can influence the ongoing autoaggressive process beneficially at the preclinical stage, if produced at the correct location, time, and levels.
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PMID:Cure of prediabetic mice by viral infections involves lymphocyte recruitment along an IP-10 gradient. 1470 11

Type 1 diabetes is an immune-mediated disease, in which T cells of the adaptive immune system mediate beta cell destruction. Recently the innate immune system has been linked to etiopathogenesis of several autoimmune diseases including type 1 diabetes, as innate effector cells (e.g. dendritic cells, monocytes/macrophages and NK cells) can prime and promote or regulate (auto)immune responses. We have previously developed an experimental autoimmune diabetes (EAD) model with insulin peptide B:9-23 immunization in transgenic H-2(d)mice expressing the costimulatory molecule B7.1 in their islets (under the Rat Insulin Promotor, RIP). We compared the induction of diabetes with polyinosinic-polycytidylic acid (Poly I:C), a mimic of double stranded viral RNA versus insulin B:9-23 peptide in mice following backcrossing of the B7.1 transgene on to BALB/c mice from original B7.1 C57Bl/6 mice. We find that diabetes induction by Poly I:C is C57Bl/6 associated, whereas B:9-23 peptide induced diabetes and induction of insulin autoantibodies (IAA) are dependent on BALB/c genes. This B:9-23 peptide induced diabetes is consistent with MHC class II H-2(d)being necessary for the response to this peptide. Of note Poly I:C induction of diabetes was lost while B:9-23 induction was retained with backcrossing to BALB/c mice. Interaction of genes and environment (antigenic epitope and viral mimic) can be important in the pathogenesis of immune mediated diabetes and activation of the innate immune system (e.g. Poly I:C) may be one key determinant.
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PMID:Genetic differentiation of poly I:C from B:9-23 peptide induced experimental autoimmune diabetes. 1512 Jul 54

Mice have two insulin genes that differ in the insulin sequence by two amino acids, including the B9 position. Given prior studies of the B:9-23 insulin peptide in NOD mice, a fundamental question is whether the immune response to the B:9-23 peptide of the two insulins is identical. We investigate responses to the immunization with B:9-23 insulin 1 and 2 peptides in NOD and RIP-B7.1 Balb/c mice. NOD and F1 (Balb/c x C57/Bl6) B7.1 transgenic mice were given either B:9-23 insulin 1, B:9-23 insulin 2 or tetanus toxoid (TT) control peptide. Insulin autoantibodies (IAA), and anti-B:9-23 antibodies (IgG1 and IgG2c) were measured. Subcutaneous injection of the insulin 2 but not the insulin 1 peptide significantly protected NOD mice from diabetes. Conceptually similar, insulin 1 peptide immunization accelerated diabetes in the B7.1 mice compared with insulin 2 peptide. Insulin 1 and 2 peptides induced similar levels of IAA in the NOD mice except at week 26, where insulin 2 induced higher levels of IAA. Anti-IgG1 B:9-23 peptide antibodies were higher in the insulin 2 immunized group of NOD mice, while IgG2c anti-B:9-23 peptide antibodies were higher in the insulin 1 group. Adoptive transfer of splenocytes from insulin 1 immunized mice to NOD.scid mice demonstrated accelerated diabetogenicity. The protection afforded by insulin 2 peptide but not insulin 1 peptide in the NOD mouse is reflected by its predominant Th2 humoral response. This may relate to the protection conferred by the insulin 1 knockout when bred onto NOD mice in contrast to acceleration of disease with an insulin 2 knockout.
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PMID:Differential immune response to B:9-23 insulin 1 and insulin 2 peptides in animal models of type 1 diabetes. 1523 49

Although HLA-DQ8 has been implicated as a key determinant of genetic susceptibility to human type 1 diabetes, spontaneous diabetes has been observed in HLA-DQ8 transgenic mice that lack expression of murine MHC class II molecules (mII(-/-)) only when the potent costimulatory molecule, B7.1, is transgenically expressed on pancreatic beta cells. To study the contribution of HLA-DQ8 to the development of diabetes in this model, we crossed RIP-B7.1mII(-/-) mice with a set of transgenic mouse lines that differed in their HLA-DQ8 expression patterns on APC subpopulations, in particular dendritic cells and cortical thymic epithelial cells. Surprisingly, we found that even in the absence of HLA-DQ8 and CD4 T cells, a substantial fraction of the RIP-B7.1mII(-/-) mice developed diabetes. This disease process was remarkable for not only showing insulitis, but also inflammatory destruction of the exocrine pancreas with diffusely up-regulated expression of MHC class I and ICAM-1 molecules. Expression of HLA-DQ8 markedly increased the kinetics and frequency of diabetes, with the most severe disease in the lines with the highest levels of HLA-DQ8 on cortical thymic epithelial cells and the largest numbers of CD4 T cells. However, the adoptive transfer of diabetes was not HLA-DQ8-dependent and disease could be rapidly induced with purified CD8 T cells alone. Expression of B7.1 in the target tissue can thus dramatically alter the cellular and molecular requirements for the development of autoimmunity.
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PMID:Expression of the B7.1 costimulatory molecule on pancreatic beta cells abrogates the requirement for CD4 T cells in the development of type 1 diabetes. 1524 Jun 65

To determine whether glucocorticoids are involved in pancreas development, glucocorticoid treatment of rat pancreatic buds in vitro was combined with the analysis of transgenic mice lacking the glucocorticoid receptor (GR) in specific pancreatic cells. In vitro treatment of embryonic pancreata with dexamethasone, a glucocorticoid agonist, induced a decrease of insulin-expressing cell numbers and a doubling of acinar cell area, indicating that glucocorticoids favored acinar differentiation; in line with this, expression of Pdx-1, Pax-6, and Nkx6.1 was downregulated, whereas the mRNA levels of Ptf1-p48 and Hes-1 were increased. The selective inactivation of the GR gene in insulin-expressing beta-cells in mice (using a RIP-Cre transgene) had no measurable consequences on beta- or alpha-cell mass, whereas the absence of GR in the expression domain of Pdx-1 (Pdx-Cre transgene) led to a twofold increased beta-cell mass, with increased islet numbers and size but normal alpha-cell mass in adults. These results demonstrate that glucocorticoids play an important role in pancreatic beta-cell lineage, acting before hormone gene expression onset and possibly also modulating the balance between endocrine and exocrine cell differentiation.
Diabetes 2004 Sep
PMID:Dissecting the role of glucocorticoids on pancreas development. 1533 41

Pdx1 has been shown to convert hepatocytes into both exocrine and endocrine pancreatic cells in mice, but it fails to selectively convert hepatocytes into pure insulin-producing cells (IPCs). The molecular mechanisms underlying the transdifferentiation remain unclear. In this study, we generated a stably transfected rat hepatic cell line named WB-1 that expresses an active form of Pdx1 along with a reporter gene, RIP-eGFP. Our results demonstrate that Pdx1 induces the expression of multiple genes related to endocrine pancreas development and islet function in these liver cells. We do not however find any expression of the late-stage genes (Pax4, Pax6, Isl-1, and MafA) related to beta-cell development, and the cells do not secrete insulin upon the glucose challenge. Yet when WB-1 cells are transplanted into diabetic NOD-scid mice, these genes become activated and hyperglycemia is completely reversed. Detailed comparison of gene expression profiles between pre- and posttransplanted WB-1 cells demonstrates that the WB-1 cells have similar properties as that seen in pancreatic beta-cells. In addition, in vitro culture in high-glucose medium is sufficient to induce complete maturation of WB-1 cells into functional IPCs. In summary, we find that Pdx1-VP16 is able to selectively convert hepatic cells into pancreatic endocrine precursor cells. However, complete transdifferentiation into functional IPCs requires additional external factors, including high glucose or hyperglycemia. Thus, transdifferentiation of hepatocytes into functional IPCs may serve as a viable therapeutic option for patients with type 1 diabetes.
Diabetes 2004 Dec
PMID:High glucose is necessary for complete maturation of Pdx1-VP16-expressing hepatic cells into functional insulin-producing cells. 1556 47

(Prepro)insulin is considered a central antigenic determinant in diabetic autoimmunity. Insulin has been used to modify diabetes development in NOD mice and prediabetic individuals. We have recently shown that (prepro)insulin can adversely promote diabetes development in murine type 1 diabetes. Based on these findings we have developed experimental autoimmune diabetes (EAD), a new mouse model characterized by (1) CD4(+)/CD8(+) insulitis, induced by (2) (prepro)insulin DNA vaccination, leading to (3) beta cell damage and insulin deficiency in (4) RIP-B7.1 transgenic mice (H-2(b)). EAD develops rapidly in 60-95% of mice after intramuscular, but not intradermal ("gene gun"), vaccination; and DNA plasmids expressing insulin or the insulin analogues glargine, aspart, and lispro are equally potent to induce EAD. Similar to NOD mice, diabetes is adoptively transferred into syngeneic recipients by spleen cell transplantation in a dose-dependent fashion. We have devised a two-stage concept of EAD in which T cell activation and expansion is driven by in vivo autoantigen expression, followed by islet damage that requires beta cell expression of costimulatory B7.1 for disease manifestation. Taken together, EAD is a novel, genetically defined animal model of type 1 diabetes suitable to analyze mechanisms and consequences of insulin-specific T cell autoimmunity.
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PMID:Experimental autoimmune diabetes: a new tool to study mechanisms and consequences of insulin-specific autoimmunity. 1569 19

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