Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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

Curative islet transplantation for type 1 diabetes currently requires lifelong systemic immunosuppression. Induction of islet transplantation tolerance would be far preferable. We have previously demonstrated that blockade of costimulation by the administration of a donor-specific transfusion in combination with anti-CD154 monoclonal antibody leads to permanent islet and prolonged skin allograft survival in mice. The protocol requires the presence of CD4+ T cells, interferon-gamma, and CTLA4, and involves the deletion of CD8+ alloreactive T cells. Translation of this strategy into clinical practice will, however, require attention to at least two issues. First, we have observed that the presence of viral infection during tolerance interferes with tolerance induction. Second, we have observed that our tolerance induction protocol is ineffective in autoimmune nonobese diabetic mice. We hypothesize that resistance to tolerance induction in nonobese diabetic mice is due to the presence of memory autoreactive cells. To overcome the deleterious effects of viral infection and of primed memory responses, it may be necessary to modify current tolerance induction strategies based on costimulatory blockade. These modifications may require patient isolation, the generation of hematopoietic chimerism, or treatments that target the specific T-cell populations, cytokines, and/or costimulatory factors responsible for resistance. Such modifications may make it possible to extend tolerance induction to the "real world" situation of individuals with type 1 diabetes who are likely to harbor both memory allo-and autoreactive immune cells.
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PMID:Islet cell transplantation tolerance. 1188 56

We investigated the association of the CTLA4 +49 A/G dimorphism with type 1 diabetes in Czech children. Genotyping of 305 diabetic children and 289 controls by a novel PCR-ARMS assay revealed no significant differences in the genotypic or allelic frequencies. This may be another piece of evidence against the +49 A/G transition as the aetiological polymorphism within the CTLA4 gene.
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PMID:The CTLA4 +49 A/G dimorphism is not associated with type 1 diabetes in Czech children. 1204 57

Type 1 insulin-dependent diabetes is due to destruction of the insulin secreting cells of the islets of Langerhans. The disease is caused by non-genetic, probably environmental, factors operating in a genetically susceptible host to initiate a destructive immune process. These unknown environmental factors may operate over a limited period either in early or later and to a variable degree, playing a particularly substantial role in adults. The environment then induces an immune process associated with destruction of the islet beta cell that can be detected in early life and persists up to disease onset. Apart from an association with the insulin gene there is no evidence that genes associated with type 1 diabetes, including HLA and CTLA4 influence the targeting of the immune response to the insulin-secreting cells. The critical period of immune activation is probably short and the process leading to diabetes probably has a long prodrome but of variable duration that determines the age at presentation with clinical disease. The amplification both of this immune response and the destructive process is in part genetically determined, involving HLA genes. The clinical spectrum of the disease process associated with type 1 diabetes is wide, encompassing insulin-dependence, non-insulin dependence and even transient impaired glucose tolerance. Type 1 diabetes presenting in adults, in contrast to children, is predominantly determined by non-genetic factors with a reduced role for protective and susceptibility HLA alleles. Thus, the evidence is that genes involved in genetic susceptibility to type 1 diabetes operate predominantly in children not adults and in both amplify the immune response and the rate of disease progression.
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PMID:Impact of genetic and non-genetic factors in type 1 diabetes. 1211 72

Type 1 diabetes mellitus is an autoimmune disease with a strong genetic background. The CTLA4 gene region (IDDM12) has been implicated in genetic susceptibility to type 1 diabetes by genome scanning and both family- and population-based analyses. As the genes encoding the costimulatory molecules CTLA4 and CD28, which compete for the receptor B7, reside close together on chromosome 2q33 and have high sequence homology, we investigated a recently described polymorphism in intron 3 of the CD28 gene and the CLTA4 codon 17 polymorphism in 176 patients with type 1 diabetes and 220 healthy controls. Whereas CTLA4 was found to be associated with type 1 diabetes, the frequency of the CD28 polymorphism did not differ between patients and controls, either in the entire sample or after stratification for CTLA4 genotype. Thus, the CD28 intron 3 polymorphism does not appear to be associated with susceptibility to type 1 diabetes.
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PMID:A recently described polymorphism in the CD28 gene on chromosome 2q33 is not associated with susceptibility to type 1 diabetes. 1212 Dec 83

We have identified a large family in the northern part of Sweden with multiple cases of autoimmune diseases, namely type 1 diabetes (T1D), Graves' disease (GD) and Hashimoto's thyroiditis (HT). The family members affected by any of these diseases share a region of 2.4 Mb that comprises among others the CTLA4 gene. We determined that all affected members of the family shared the HLA susceptibility haplotype (DR4-DQA1*0301-DQB1*0302). Analysis of genetic interaction conditioning for HLA haplotype provided strong evidence that the critical region which includes the CTLA4 gene acts together with the HLA locus on the etiology of disease (lodscore 4.20 (theta=0.0). The study of this family allowed us to: (1) reinforce a number of reports on linkage and association of the CTLA4 region to T1D and AITD; (2) demonstrate that a single haplotypic variant in this region constitutes an etiological factor to disease susceptibility in T1D, GD and HT; (3) reveal a strong genetic interaction of the CTLA4 and HLA loci in the genetic architecture of autoimmune disease; (4) emphasise the value of large pedigrees drawn from isolated populations as tools to single out the effect of individual loci in the etiology of complex diseases.
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PMID:The CTLA4 region as a general autoimmunity factor: an extended pedigree provides evidence for synergy with the HLA locus in the etiology of type 1 diabetes mellitus, Hashimoto's thyroiditis and Graves' disease. 1252 10

The contribution of the candidate gene CTLA4 to type 1 diabetes is not well established. Although several polymorphisms have been repeatedly associated to the disease, several studies have not confirmed the association. The joint analysis of three SNPs in the CTLA4 promoter region (-1722, -1661, and -319), one SNP in the first exon (+49), and one dinucleotide repeat in the 3' untranslated region, in a case-control study in a North African population, shows a strong association of the CTLA4 region with the disease. The -1661G allele showed a significant association with an odds ratio of 2.13. Moreover, the internal structure of the dinucleotide repeat has been deeply analyzed. The present results reveal the importance of polymorphisms in the CTLA4 promoter region, their probable role in gene expression and, ultimately, their relation to the etiology of type 1 diabetes. Previous contradictory association studies might be due to the effect of linkage disequilibrium between the polymorphism analyzed and the alteration within the CTLA4 region. This alteration may be different depending on the genetic background of the population. The present work stresses the need to perform exhaustive analysis of the promoter region polymorphisms in order to detect association with the disease.
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PMID:Association of the CTLA4 promoter region (-1661G allele) with type 1 diabetes in the South Moroccan population. 1261 61

Type 1 diabetes is an autoimmune disease with a complex polygenic inheritance. Until recently, only three susceptibility genes had been reproducibly identified, namely HLA, INS-VNTR, and CTLA4. During the past 7 years, a number of new putative susceptibility genes have been isolated from both human and animal models of the disease. We present eight genes implicated in type 1 diabetes etiology and discuss them in relation to the pathogenesis of the disease: VDR, IL6, IL12B, AIRE, FOXP3, B2m, Cblb, and Lyp/Ian4l1.
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PMID:New autoimmune genes and the pathogenesis of type 1 diabetes. 1503 74

In ethnic Russians, MHC (HLA) was shown to be the major locus determining the predisposition to type 1 diabetes mellitus (T1DM). To map the regions linked to T1DM, families with concordant or discordant sib pairs were selected from the Russian population of Moscow. With these families, linkage to T1DM was demonstrated for CTLA4 (IDDM12, 2q32.1-q33), which codes for a T-cell surface antigen, and PDCD2 (IDDM8, 6q25-q27), which is homologous to the mouse programmed cell death activator gene. With polymorphic microsatellites, regions 3q21-q25 (IDDM9) and 10p12.2 (IDDM10) were also linked to T1DM. Case/control and family studies of the polymorphic markers from region 11p13 revealed a new T1DM-associated locus in the vicinity of the catalase gene (CAT); linkage to this locus was not reported earlier for other populations. Diabetic polyneuropathy (DPN) proved to be associated with single-nucleotide polymorphisms Ala(-9)Val (SOD2), Arg213Gly (SOD3), and T(-262)C (CAT) and with a polymorphic microsatellite of the NOS2 promoter. Hence oxidative stress, which results from hyperglycemia, increased mitochondrial production of superoxide radicals, and insufficient activities of antioxidative enzymes, was assumed to play an important part in DPN development in T1DM. Diabetic nephropathy (DN) showed no association with the antioxidative enzyme genes. However, the association was observed for the insertion/deletion (I/D) polymorphism of ACE and the ecNOS34a/4b polymorphism of NOS3, two genes involved in controlling vascular tonicity, and for the I/D polymorphism of APOB and the epsilon 2/epsilon 3/epsilon 4 polymorphism of APOE, two genes involved in lipid transport. In addition, polymorphic microsatellites of chromosome 3q21-q25 proved to be closely associated with DN. The tightest association was established for D3S1550, carriers of allele 12 or genotype 12/14 having high risk of DN (OR = 4.85 and 6.25, respectively). Region 3q21-q25 was assumed to contain a major gene determining DN development, while the other DN-associated genes mostly affect the progression of DN.
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PMID:[Genomics of type I diabetes mellitus and its late complications]. 1504 45

Coeliac disease is an autoimmune disorder, characterised by villous atrophy of the small intestine, which results from a T-cell-mediated response to gluten-derived peptides. The cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) is involved in the regulation of T-cell activation and the CTLA4 +49 A/G polymorphism in exon 1 has been implicated in several autoimmune disorders, including coeliac disease. However, this polymorphism was recently excluded as being the causal variant in Graves' disease, autoimmune hypothyroidism and type I diabetes mellitus. This causal variant was mapped to the 3' region of CTLA4, with the CT60 polymorphism showing the strongest association. The aim of this study was to determine the role of the CTLA4 gene in coeliac disease in the Dutch population. The +49 A/G and CT60 polymorphisms were genotyped in a case-control cohort of 215 patients and controls. The frequency of the +49 G-allele was increased in cases, although not significantly. However, the frequency of the CT60 G-allele was increased with borderline significance in coeliac disease patients (P = 0.048), although the genotype distributions did not show a significant difference between cases and controls. These results indicate the involvement of the CTLA4 gene in coeliac disease development. The haplotype carrying the CT60 G-allele was shown to be associated with lower mRNA levels of the soluble CTLA-4 isoform, providing a possible mechanism for the T-cell-mediated destruction of the small intestine.
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PMID:CTLA4 +49 A/G and CT60 polymorphisms in Dutch coeliac disease patients. 1519 80

There is growing evidence that genetic variation plays an important role in the determination of individual susceptibility to complex disease traits. In contrast to coding sequence polymorphisms, where the consequences of non-synonymous variation may be resolved at the level of the protein phenotype, defining specific functional regulatory polymorphisms has proved problematic. This has arisen for a number of reasons, including difficulties with fine mapping due to linkage disequilibrium, together with a paucity of experimental tools to resolve the effects of non-coding sequence variation on gene expression. Recent studies have shown that variation in gene expression is heritable and can be mapped as a quantitative trait. Allele-specific effects on gene expression appear relatively common, typically of modest magnitude and context specific. The role of regulatory polymorphisms in determining susceptibility to a number of complex disease traits is discussed, including variation at the VNTR of INS, encoding insulin, in type 1 diabetes and polymorphism of CTLA4, encoding cytotoxic T lymphocyte antigen, in autoimmune disease. Examples where regulatory polymorphisms have been found to play a role in mongenic traits such as factor VII deficiency are discussed, and contrasted with those polymorphisms associated with ischaemic heart disease at the same gene locus. Molecular mechanisms operating in an allele-specific manner at the level of transcription are illustrated, with examples including the role of Duffy binding protein in malaria. The difficulty of resolving specific functional regulatory variants arising from linkage disequilibrium is demonstrated using a number of examples including polymorphism of CCR5, encoding CC chemokine receptor 5, and HIV-1 infection. The importance of understanding haplotypic structure to the design and interpretation of functional assays of putative regulatory variation is highlighted, together with discussion of the strategic use of experimental tools to resolve regulatory polymorphisms at a transcriptional level. A number of examples are discussed including work on the TNF locus which demonstrate biological and experimental context specificity. Regulatory variation may also operate at other levels of control of gene expression and the modulation of splicing at PTPRC, encoding protein tyrosine phosphatase receptor-type C, and of translational efficiency at F12, encoding factor XII, are discussed.
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PMID:Regulatory polymorphisms underlying complex disease traits. 1559 5


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