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

Type 1 diabetes is associated with autoimmunity to insulin. Genetic susceptibility to type 1 diabetes is polygenic and includes the INS VNTR-IDDM2 locus which may regulate the expression of insulin in pancreas and thymus. In order to determine whether insulin autoimmunity could be attributed to a genetic susceptibility conferred by the INS VNTR-IDDM2 locus, peripheral blood T cell proliferation to human insulin and insulin autoantibodies (IAA) was measured in patients with new onset type 1 diabetes and control subjects. IAA were detected in 21 of 53 patients and in none of 25 control subjects, while T cell responses were low (stimulation index range 0.4-7.2) and similar in both groups. Both antibody and T cell responses were higher in younger subjects and IAA were more prevalent in patients with the HLA-DR4 allele. No relationship was observed between humoral and cellular responses to insulin. No association was found between the INS VNTR-IDDM2-susceptible allele and insulin autoimmunity. Increased T cell responses and IAA were found in patients with either the diabetes-susceptible or the diabetes-protective INS VNTR-IDDM2 locus genotypes, and increased T cell responses were also found in control subjects with either susceptible or protective INS VNTR-IDDM2 locus genotypes. This study confirms that primary T cell proliferative responses to insulin are low and detectable also in control subjects. The detection of T cell proliferation and autoantibodies to insulin in subjects with and without the protective INS VNTR-IDDM2 locus genotypes does not support the hypothesis of an allele-specific capacity for tolerance induction which could determine a susceptibility to develop autoimmunity against the insulin protein and subsequently diabetes.
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PMID:Autoimmune responses to the beta cell autoantigen, insulin, and the INS VNTR-IDDM2 locus. 984 45

Continuing progress has been made in elucidating the genetic factors involved in type 1 diabetes (insulin-dependent diabetes mellitus [IDDM]) in the past year. Two genome scans suggested additional susceptibility intervals and provided supporting evidence for several previously reported linkages. Other studies focused on the confirmation of linkage using multipoint sibpair analyses with densely spaced markers and multiethnic collections of families. Although significant and consistent linkage evidence was reported for the susceptibility intervals IDDM8 (on human chromosome 6q27), IDDM4 (on 11q) and IDDM5 (on 6q25), evidence for most other intervals varies in different data sets -probably due to a weak effect of the disease genes, genetic heterogeneity or random variation. Linkage disequilibrium mapping has become an increasingly important tool for both the confirmation and fine-mapping of susceptibility intervals, as well as identification of etiological mutations. Functional studies indicate, firstly, that the susceptible and protective HLA class II molecules HLA-DR and -DQ bind and present nonoverlapping peptides and, secondly, that the variable number of tandem repeats at the 5' end of the insulin gene (susceptibility interval IDDM2) regulates insulin expression in the thymus.
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PMID:Genetic susceptibility factors in type 1 diabetes: linkage, disequilibrium and functional analyses. 991 16

The phenomenon of genomic imprinting describes the differential behavior of genes depending on their parental origin, and has been demonstrated in a few rare genetic disorders. In complex diseases, parent-of-origin effects have not been systematically studied, although there may be heuristic value in such an approach. Data from a genome scan performed using 356 affected sibling pair families with type 1 diabetes were examined looking for evidence of excess sharing of either maternal or paternal alleles. At the insulin gene (IDDM2), evidence for excess sharing of alleles transmitted from mothers was detected, which is consistent with transmission disequilibrium results published elsewhere. We also identified additional loci that demonstrate allele sharing predominantly from one parent: IDDM8 shows a paternal origin effect, IDDM10 shows a maternal effect, and a locus on chromosome 16q demonstrates a paternal effect. We have also evaluated these loci for confounding by differences in sex-specific meiotic recombination by performing linkage analysis using sex-specific genetic maps. The analysis of the parental origin of shared alleles from genome scans of complex disorders may provide additional evidence for linkage for known loci, help identify regions containing additional susceptibility loci, and assist the cloning of the genes involved.
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PMID:The analysis of parental origin of alleles may detect susceptibility loci for complex disorders. 1043 81

The aetiology of Type I diabetes involves both genetic and environmental factors. The genes implicated are 'susceptibility genes', which modify risk. Individual susceptibility genes may not be required and are not sufficient for disease development. The strongest genetic risk component is encoded within the major histocompatibility complex (MHC) and is designated IDDM I. The HLA-DQ genes contribute to the risk, but so may other MHC-encoded genes. The susceptibility encoded by IDDM2 refers to a variable number of tandem repeats in the insulin gene region. Many other genomic regions have been designated as susceptibility intervals potentially containing candidate genes. Environmental factors appear to be important in disease expression in either a causative or a protective role. Epidemiological data indicate that such factors operate from early in life. Viral infection(s) may have a disease-initiating and/ or accelerating effect. A potential diabetogenic role for cows' milk protein remains unconfirmed. Further research is necessary to elucidate fully the aetiological factors involved and how they interact.
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PMID:The aetiology of Type I diabetes. 1076 62

Some environmental and genetic factors play important roles in etiopathogenesis of type 1 or insulin-dependent diabetes mellitus (IDDM). HLA genes, the IDDM1 locus located the human chromosome 6, were found to be associated with insulin-dependent diabetes mellitus. However, the incidence of IDDM varied greatly among various populations. To evaluate the pathogenetic factors contributing to the development of IDDM in Taiwan, HLA typing was performed in a group of IDDM unrelated individuals and IDDM pedigrees along with the normal controls from the northern Taiwan. DNA genotypes of class II HLA were done by polymerase-chain-reaction based oligotyping techniques. We confirmed that class II HLA genes were significantly associated with IDDM in Taiwan. To study detailed molecular structure of class II HLA molecules and disease association, we examined several amino acid residues on DQalpha and DQbeta chains and the molecular mechanisms to explain the heterozygotic effect of the DR3/DR4 and DR3/DR9 in the Chinese population. Linkage analysis in our pedigrees confirmed the association between HLA and IDDM in population association studies. Among the several class II alleles, a closer segregation of HLA-DQB1*0401 to the affected persons might suggest that HLA-DQB1*0401 itself or an allele closely linked to the DQB1 locus was the IDDM-predisposing allele in Taiwanese. For IDDM2 (INS) region, association with IDDM was not found due to that more than 90% of the population carried class I alleles. In our collection of IDDM, we found few cases (2.4%) carried mitochondrial DNA mutation. Our studies in Taiwanese confirm a multigenetic nature for IDDM.
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PMID:Genetic epidemiology of type 1 diabetes mellitus in Taiwan. 1102 83

The insulin minisatellite or variable number of tandem repeats locus (INS VNTR) is the best candidate for the type 1 diabetes mellitus (T1DM) susceptibility locus IDDM2. Small class I alleles associate with predisposition to T1DM, whereas large class III alleles associate with dominant protection. We have analysed variant repeat distribution within the minisatellite and combined this with flanking haplotypes to define five new ancestral allele lineages. Class III alleles divide into two highly diverged lineages, IIIA and IIIB, which correspond perfectly to the previously defined Protective (PH) and Very Protective (VPH) haplotypes, respectively. Class I alleles are divided into three newly defined lineages, IC+, ID+ and ID-, by a combination of variant repeat distributions and flanking haplotypes. All class I alleles are equally predisposing to T1DM except for ID- alleles which are protective when transmitted from ID-/III heterozygous fathers. Similar results have been previously reported for alleles of 42 repeats in length (allele 814) which represent a subset of the ID- lineage. Division of class ID- alleles into those of 42 repeats and those of other sizes suggested that this protective effect was a feature of all ID- alleles, irrespective of size. ID- alleles are only clearly distinguished from all other alleles by an MSPI(-) variant within IGF2 downstream of the minisatellite, suggesting that the apparent role of the minisatellite in susceptibility to T1DM may be modified by neighbouring haplotype and therefore that IDDM2 could have a multi-locus aetiology.
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PMID:Influence of allele lineage on the role of the insulin minisatellite in susceptibility to type 1 diabetes. 1111 36

Type 1 diabetes (T1D) is a genetically complex disorder of glucose homeostasis that results from the autoimmune destruction of the insulin-secreting cells of the pancreas. Two previous whole-genome scans for linkage to T1D in 187 and 356 families containing affected sib pairs (ASPs) yielded apparently conflicting results, despite partial overlap in the families analyzed. However, each of these studies individually lacked power to detect loci with locus-specific disease prevalence/sib-risk ratios (lambda(s)) <1.4. In the present study, a third genome scan was performed using a new collection of 225 multiplex families with T1D, and the data from all three of these genome scans were merged and analyzed jointly. The combined sample of 831 ASPs, all with both parents genotyped, provided 90% power to detect linkage for loci with lambda(s) = 1.3 at P=7.4x10(-4). Three chromosome regions were identified that showed significant evidence of linkage (P<2.2x10(-5); LOD scores >4), 6p21 (IDDM1), 11p15 (IDDM2), 16q22-q24, and four more that showed suggestive evidence (P<7.4x10(-4), LOD scores > or =2.2), 10p11 (IDDM10), 2q31 (IDDM7, IDDM12, and IDDM13), 6q21 (IDDM15), and 1q42. Exploratory analyses, taking into account the presence of specific high-risk HLA genotypes or affected sibs' ages at disease onset, provided evidence of linkage at several additional sites, including the putative IDDM8 locus on chromosome 6q27. Our results indicate that much of the difficulty in mapping T1D susceptibility genes results from inadequate sample sizes, and the results point to the value of future international collaborations to assemble and analyze much larger data sets for linkage in complex diseases.
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PMID:Seven regions of the genome show evidence of linkage to type 1 diabetes in a consensus analysis of 767 multiplex families. 1150 94

Type 1 diabetes mellitus is a T-cell-mediated autoimmune disease characterized by the selective destruction of pancreatic beta cells. Susceptibility to the disease is determined by a combination of genetic and environmental factors. The genetic factors are termed 'susceptibility genes' as they modify the risk of diabetes but are neither necessary nor sufficient for disease to develop. A large number of chromosomal regions have been identified as containing potential diabetes susceptibility genes. The IDDM1 locus, which encompasses the major histocompatibility complex on chromosome 6, is the major genetic risk factor. The HLA-DQ genes are the primary susceptibility genes within this region, although other genes may also contribute. The IDDM2 locus maps to a variable number of tandem repeats in the insulin gene region on chromosome 11. Further research is necessary to determine the precise location and identity of other diabetes susceptibility genes.
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PMID:Genetics of type 1 diabetes. 1155 71

At least 20 different chromosomal regions have been linked to type 1 diabetes (T1D) susceptibility in humans, using genome screening, candidate gene testing, and studies of human homologues of mouse susceptibility genes. The largest contribution from a single locus (IDDM1) comes from several genes located in the MHC complex on chromosome 6p21.3, accounting for at least 40% of the familial aggregation of this disease. Approximately 30% of T1D patients are heterozygous for HLA-DQA1*0501-DQB1*0201/DQA1*0301-DQB1*0302 alleles (formerly referred to as HLA-DR3/4 and for simplification usually shortened to HLA-DQ2/DQ8), and a particular HLA-DQ6 molecule (HLA-DQA1*0102-DQB1*0602) is associated with dominant protection from the disease. There is evidence that certain residues important for structure and function of both HLA-DQ and DR peptide-binding pockets determine disease susceptibility and resistance. Independent confirmation of the IDDM2 locus on chromosome 11p15.5 has been achieved in both case-control and family-based studies, whereas associations with the other potential IDDM loci have not always been replicated. Several possibilities to explain these variable results from different studies are discussed, and a key factor affecting both linkage and association studies is that the genetic basis of T1D susceptibility may differ between ethnic groups. Some future strategies to address these problems are proposed. These include increasing the sample size in homogenous ethnic groups, high throughput genotyping and genomewide linkage disequilibrium (LD) mapping to establish disease associated ancestral haplotypes. Elucidation of the function of particular genes ('functional genomics') in the pathogenesis of T1D will be a most important element in future studies in this field, in addition to more sophisticated methods of statistical analyses.
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PMID:Genetics of type 1 diabetes mellitus. 1214 Jul 42

Insulin is a predominant autoantigen in IDDM in man and the NOD mouse. Failure of negative selection of diabetogenic T cells in thymus may be an important pre-disposing cause of the disease. To obtain insight into negative selection against such T-cell clones the thymic expression of insulin was studied in NOD and Balb/c mice by quantitative competitive RT-PCR. We detected RNA for insulin in the thymus of 3-week-old Balb/c mice as well as in NOD mice. However, the NOD mice expressed only half as many insulin transcripts as the Balb/c mice. Also, insulin protein was detected in the thymic medulla of both Balb/c and NOD mice. Furthermore, thymic RNA preparations were investigated for the presence of insulin transcription factors. None of the known pancreatic transcription factors for insulin; Pdx-1, Pax6 or Nkx6.1 were detectable in the thymus of Balb/c mice. These results support the idea that low insulin expression in the thymus may be a predisposing cause for development of diabetes in NOD mice analogous with what has been found in humans with the disease-disposing IDDM2 allele. Furthermore, our results suggest that insulin expression in the thymus may be regulated by different principles from those in the pancreas.
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PMID:Low expression of insulin in the thymus of non-obese diabetic mice. 1247 41

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