UMLS:C0011854 - FACTA Search

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Query: UMLS:C0011854 (type 1 diabetes)
20,749 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Our understanding of how an autoantigen is processed and presented during the development of a major histocompatibility complex (MHC) class II-dependent and T-cell-mediated autoimmune disease, such as IDDM, is incompletely understood. We have used insulin as a model autoantigen in IDDM to address the question of whether MHC class II molecules play a role in the generation and/or preservation of an autoantigen peptide that stimulates T-cell activation. Analyses of the requirement of I-Ad class II molecules in the processing of the partially processed porcine insulin peptide A1-A14/B1-B16 demonstrate that the binding of this peptide to I-Ad is essential for it to be further processed and tailored into a T-cell epitope. Based on our observations, we propose a two-step model for insulin processing in which insulin is first processed by an enzyme(s) into an intermediate peptide that binds to class II and then class II functions as a template to guide the processing of this partially processed peptide by cathepsin D into a T-cell epitope. Our data further underscore the important realization that MHC class II-directed processing of an autoantigen (e.g., insulin) may regulate 1) the relative immunodominance of T-cell determinants in an autoantigen, 2) the self-reactivity to cryptic T-cell epitopes in autoantigens, and 3) the susceptibility to autoimmune disease.
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PMID:Major histocompatibility complex class II molecules function as a template for the processing of a partially processed insulin peptide into a T-cell epitope. 892 56

IDDM in humans and in nonobese diabetic (NOD) mice is a T-cell-dependent autoimmune disease in which the beta-cells of the pancreatic islets are destroyed. Several putative beta-cell autoantigens have been identified, but insulin and its precursor, proinsulin, are the only ones that are beta-cell specific. (Pro)insulin may be a key autoantigen in IDDM. To address the role of proinsulin in the development of IDDM, we generated NOD mice transgenic for the mouse proinsulin II gene driven off a major histocompatibility complex (MHC) class II promoter to direct expression of the transgene to MHC class II bearing cells, including those in the thymus, with the aim of deleting proinsulin-reactive T-cells. The mononuclear cell infiltration of the islets (insulitis) is almost completely absent, and diabetes is prevented in these transgenic NOD mice. The mononuclear cell infiltration of the salivary glands (sialitis) and immune responses to ovalbumin (OVA) are not altered, indicating that the protective effect of the transgene is specific for islet pathology and not due to general immunosuppression. We conclude that autoimmunity to proinsulin plays a pivotal role in the development of IDDM.
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PMID:Transgenic expression of mouse proinsulin II prevents diabetes in nonobese diabetic mice. 897 Oct 78

Diabetes-prone DP-BB rats spontaneously develop insulin-dependent diabetes mellitus resembling type 1 diabetes mellitus in man. Expression of T cell lymphopenia and presence of at least one class II major histocompatibility complex (MHC) RT1u haplotype are required for development of diabetes. Diabetes segregation was studied in lymphopenic backcross (BC) offspring from a cross between male DP-BB/HRI and female BN/Mol rats. Diabetes occurred in 75% of BC rats with genotype RT1u/u and in 18% of those being RT1n/u in genotype. The latter developed diabetes significantly later than MHC homozygotes and parental DP-BBs. Our data further point to the existence of additional genes of minor importance for development of IDDM. One of these seemed to be positioned on the X chromosome. The recently published linkage to chromosome 18 could not be confirmed however. Finally, the BN-derived non-albino allele of the C gene was associated with higher diabetes incidence. This points to the existence of minor susceptibility genes in other strains of rats.
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PMID:Segregation of autoimmune type 1 diabetes in a cross between diabetic BB and brown Norway rats. 908 Feb 98

Genome-wide scans for linkage of chromosome regions to type 1 diabetes in affected sib pair families have revealed that the major susceptibility locus resides within the major histocompatibility complex (MHC) on chromosome 6p21 (lambda s = 2.5). It is recognised that the MHC contains multiple susceptibility loci (referred to collectively as IDDM1), including the class II antigen receptor genes, which control the major pathological feature of the disease: T lymphocyte-mediated autoimmune destruction of the insulin-producing pancreatic beta cells. However, the MHC genes, and a second locus, the insulin gene minisatellite on chromosome 11p15 (IDDM2; lambda s = 1.25), cannot account for all of the observed clustering of disease in families (lambda s = 15), and the scans suggested the presence of other susceptibility loci scattered throughout the genome. There are four additional loci for which there is currently sufficient evidence from linkage and association studies to justify fine mapping experiments: IDDM4 (FGF3/11q13), IDDM5 (ESR/6q22), IDDM8 (D6S281/6q27) and IDDM12 (CTLA-4/2q33), IDDM4, 5 and 8 were detected by genome scanning, and IDDM12 by a candidate gene strategy. The results suggest that the clustering of type 1 diabetes in families is due to the sharing of alleles at multiple loci, and that the as yet unidentified environmental factors are not causing clustering, but instead appear to influence the overall penetrance of genetically programmed susceptibility. The data are consistent with a polygenic threshold model for the inheritance of type 1 diabetes.
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PMID:Genetics of type 1 diabetes. 929 67

The genes encoding the HLA-DQ heterodimer molecules, DQB1 and DQA1, have been found to have the strongest association with IDDM risk, although there is cumulative evidence for the effect of other gene loci within the major histocompatibility complex gene region. After the HLA-DQ locus, the HLA-DR locus has been suggested most often as contributing to the disease susceptibility. In this study we analyzed at the population level the effect of DR4 subtypes and class I, HLA-B alleles, on IDDM risk when the influence of the DQ locus was stratified. In all three populations studied (Estonian, Latvian, and Russian), DQB1*0302 haplotypes most frequently carried DRB1*0401 or DRB1*0404. DRB1*0401 was the most prevalent subtype in IDDM patients, whereas DRB1*0404 was decreased in frequency. DRB1*0402 was also prevalent among Russian haplotypes, but was not associated with IDDM risk. When HLA-B alleles were analyzed, strong associations between the presence of specific B alleles and DRB1*04 subtypes were detected. The HLA-B39 allele was found significantly more often in DRB1*0404-DQB1*0302-positive patients than in healthy control subjects positive for this haplotype: 27 of 54 (50%) vs. 4 of 49 (8.2%) (P < 0.0001). The results demonstrate that DQ and DR genes cannot explain all of the HLA-linked susceptibility to IDDM, and that the existence of a susceptibility locus telomeric to DR is probable.
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PMID:The effect of HLA-B allele on the IDDM risk defined by DRB1*04 subtypes and DQB1*0302. 935 41

Susceptibility to IDDM is strongly associated with major histocompatibility complex (MHC) class II genotypes. Nonobese diabetic (NOD) mice develop a similar autoimmune diabetes and have a unique MHC class II I-A allele that is required for the development of diabetes. A number of groups have shown that the introduction of resistant MHC class II alleles as transgenes into the NOD mouse protects from diabetes. We made control transgenic NOD mice, expressing their own I-Abetag7 molecule as a transgene. One of two lines of these mice showed a reduced incidence of diabetes, without any change in T-cell proliferative response to a number of diabetes autoantigens or any change in insulitis severity. This line developed a subtle decrease in the percentage of splenic B-cells that progressed with age. This defect was not associated with any other phenotypic abnormalities. Our findings suggest that assessment of splenic B-cell number is necessary in interpretation of the effects of MHC class II transgenes on the development of diabetes in the NOD mouse.
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PMID:Reduction in diabetes incidence in an I-Ag7 transgenic nonobese diabetic mouse line. 939 82

Type 1 diabetes (insulin-dependent diabetes mellitus, IDDM) is a disease controlled by the major histocompatibility complex (MHC) which results from T-cell-mediated destruction of pancreatic beta-cells. The incomplete concordance in identical twins and the presence of autoreactive T cells and autoantibodies in individuals who do not develop diabetes suggest that other abnormalities must occur in the immune system for disease to result. We therefore investigated a series of at-risk non-progressors and type 1 diabetic patients (including five identical twin/triplet sets discordant for disease). The diabetic siblings had lower frequencies of CD4-CD8- Valpha24JalphaQ+ T cells compared with their non-diabetic sibling. All 56 Valpha24JalphaQ+ clones isolated from the diabetic twins/triplets secreted only interferon (IFN)-gamma upon stimulation; in contrast, 76 of 79 clones from the at-risk non-progressors and normals secreted both interleukin (IL)-4 and IFN-gamma. Half of the at-risk non-progressors had high serum levels of IL-4 and IFN-gamma. These results support a model for IDDM in which Thl-cell-mediated tissue damage is initially regulated by Valpha24JalphaQ+ T cells producing both cytokines; the loss of their capacity to secrete IL-4 is correlated with IDDM.
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PMID:Extreme Th1 bias of invariant Valpha24JalphaQ T cells in type 1 diabetes. 942 63

T cells recognize peptide epitopes bound to major histocompatibility complex molecules. Human T-cell epitopes have diagnostic and therapeutic applications in autoimmune diseases. However, their accurate definition within an autoantigen by T-cell bioassay, usually proliferation, involves many costly peptides and a large amount of blood. We have therefore developed a strategy to predict T-cell epitopes and applied it to tyrosine phosphatase IA-2, an autoantigen in IDDM, and HLA-DR4(*0401). First, the binding of synthetic overlapping peptides encompassing IA-2 was measured directly to purified DR4. Secondly, a large amount of HLA-DR4 binding data were analysed by alignment using a genetic algorithm and were used to train an artificial neural network to predict the affinity of binding. This bioinformatic prediction method was then validated experimentally and used to predict DR4 binding peptides in IA-2. The binding set encompassed 85% of experimentally determined T-cell epitopes. Both the experimental and bioinformatic methods had high negative predictive values, 92% and 95%, indicating that this strategy of combining experimental results with computer modelling should lead to a significant reduction in the amount of blood and the number of peptides required to define T-cell epitopes in humans.
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PMID:Strategies for identifying and predicting islet autoantigen T-cell epitopes in insulin-dependent diabetes mellitus. 945 87

We analyzed 11 markers in the IDDM1 region in 120 IDDM patients and 83 healthy control subjects who were fully matched for the highest risk HLA-DQA1*0301-DQB1 *0302/DQA1*0501-DQB1*0201 genotype. Our study provides strong evidence that two regions in the major histocompatibility complex contribute to IDDM susceptibility or protection. First, despite selection for highest IDDM-associated risk DQ genotypes, this region displays extensive linkage disequilibrium (LD) differences between IDDM patients and control subjects. A second critical region was mapped around the microsatellite locus D6S273 centromeric of TNF, and it is approximately 200 kb in size. LD analysis shows that "diabetogenic haplotypes" may have resulted from a recombination telomeric of D6S1014 in the region of D6S273 and TNFa. Haplotype analysis using HLA and microsatellite loci refines IDDM risk assessment in carriers of the HLA-DQ highest risk genotype.
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PMID:Genetic structure of IDDM1: two separate regions in the major histocompatibility complex contribute to susceptibility or protection. Belgian Diabetes Registry. 951 23

Genetic susceptibility to type 1 diabetes in the nonobese diabetic (NOD) mouse involves at least 17 Idd loci. Idd1 has been mapped to a class II gene in the major histocompatibility complex (MHC), whereas the products and functions of the remaining Idd loci are unresolved. To investigate how non-MHC Idd genes regulate islet inflammation and IDDM progression, NOD mice were compared with the nonobese diabetes-resistant (NOR) mouse, a related MHC-identical strain that possesses a subset of the NOD-derived alleles at the Idd loci. Using quantitative reverse transcriptase-polymerase chain reaction amplification and immunohistochemistry, we observed that disease resistance in NOR mice is reflected by a protracted block at the earliest stage of insulitis. In NOD islets, early antigen-presenting cell (APC) recruitment to islet lesions was temporally coincident with progressive T-cell infiltration. In striking contrast, islet infiltrates in NOR mice were composed of APCs with minimal contribution from T-cells and T-cell-derived inflammatory cytokines, conferring apparent resistance to invasive insulitis and beta-cell destruction. This is the first evidence that a subset of Idd susceptibility loci independently regulate T-cell and APC participation in insulitis progression. As progress is made toward identification of the Idd gene products, it will be crucial to determine how they regulate diabetogenesis. Our data define distinct cellular stages of IDDM pathogenesis in which the impact of Idd genes can be readily analyzed.
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PMID:Independent genetic regulation of T-cell and antigen-presenting cell participation in autoimmune islet inflammation. 951 36

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