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)

FOXP3/Scurfin, a member of forkhead/winged-helix proteins, is involved in the regulation of T-cell activation, and essential for normal immune homeostasis. The FOXP3/Scurfin gene is located on chromosome Xp11.23, which includes one of the type 1 diabetes susceptible loci. Therefore, we investigated whether the human FOXP3/Scurfin gene might be a new candidate gene for type 1 diabetes. We first screened the human FOXP3/Scurfin gene for microsatellite and single nucleotide polymorphisms. Next, we performed an association study between the FOXP3/Scurfin gene and type 1 diabetes. Then, the evaluation of promoter/enhancer activity of the intron with (GT)(n) polymorphism was performed by dual luciferase reporter assay. We demonstrated two regions contained microsatellite polymorphisms; one was (GT)(n), located on intron zero and the other (TC)(n) on intron 5, which were under linkage-disequilibrium. The (GT)(15) allele showed a significantly higher frequency in patients with type 1 diabetes than in controls (43.1% vs 32.6%, P=0.0027). The genotype frequencies of (GT)(15)/(GT)(15) in female patients and of (GT)(15) in male patients tended to be higher than those in female ( P=0.064) and male ( P=0.061) controls, respectively. A significant difference in the enhancer activity between (GT)(15) and (GT)(16) dinucleotide repeats was detected. In conclusion, the FOXP3/Scurfin gene appears to confer a significant susceptibility to type 1 diabetes in the Japanese population.
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PMID:A functional polymorphism in the promoter/enhancer region of the FOXP3/Scurfin gene associated with type 1 diabetes. 1275 Aug 58

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

Mutations of the forkhead/winged helix transcription factor FOXP3 gene on chromosome Xp11.23 cause a rare recessive monogenic disorder called IPEX (immune dysregulation, polyendocrinopathy, including type 1 diabetes, enteropathy, and X-linked syndrome). FOXP3 is necessary for the differentiation of a key immune suppressive subset of T-cells, the CD4+CD25+ regulatory T-cells. Previously, we reported a significant male-female bias in the common, multifactorial form of type 1 diabetes in Sardinia and evidence of linkage of chromosome Xp11 to the disease. These findings indicate that FOXP3 is a prime functional and positional candidate locus for the common form of type 1 diabetes. In the present study, we initially scanned 82 kb of the FOXP3 region for common polymorphisms, including sequencing all of the coding and functionally relevant portions of the gene in 64 Sardinian individuals. Then the most informative polymorphisms in 418 type 1 diabetic families and in 268 male case and 326 male control subjects were sequentially genotyped and tested for disease association. There is no evidence that variants in the FOXP3 regions analyzed are associated with type 1 diabetes and account for the male-female bias observed in Sardinia. Our data indicate that allelic variation in or near the coding regions of the FOXP3 gene does not have a major role in the inherited susceptibility to the common form of type 1 diabetes.
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PMID:No association between variation of the FOXP3 gene and common type 1 diabetes in the Sardinian population. 1522 Feb 19

Immunodysregulation, Polyendocrinopathy, Enteropathy, X-linked (IPEX) syndrome is a rare inborn error of immune regulation characterized by the early onset of one or more autoimmune diseases in boys. IPEX is caused by mutations in FOXP3, and is thus the homologue of the scurfy mutant mouse. The gene product, Scurfin, is required for the development of CD4+CD25+ T regulatory cells. In the absence of T regulatory cells, activated CD4+ T cells instigate multi-organ damage resulting in type 1 diabetes, enteropathy, eczema, hypothyroidism, and other autoimmune disorders. While effective therapies are currently limited, studies in the scurfy mouse are revealing aspects of pathophysiology and genetics that will lead to novel approaches for treating IPEX and other autoimmune disorders. Females carrying Foxp3 mutations are unaffected. In new experiments we show that female scurfy mice that are also heterozygous in trans for the X-linked recessive common gamma chain knockout contract autoimmune disease, proving that murine Foxp3 is subject to X-inactivation and providing an example of gene-gene interaction causing autoimmune disease in females. One explanation for the lesser disease severity in these females is proposed.
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PMID:IPEX and FOXP3: clinical and research perspectives. 1624 87

The FOXP3 gene encodes a transcription factor thought to be essential for the development and function of T regulatory cells. Two previous studies have tested common polymorphisms in FOXP3 for association with type 1 diabetes (T1D) with conflicting results. The aim of our study was to see whether there is any evidence of association between the FOXP3 polymorphisms previously reported to be associated with T1D, in a Caucasian population regarding T1D and coeliac disease (CD). We further looked for evidence of interaction between FOXP3 polymorphisms and HLA-DR3 in conferring susceptibility to T1D. Initially, we analysed two microsatellites in the FOXP3 gene in 363 T1D nuclear families. Our results indicated an association between FOXP3 and T1D (global p=0.004) and a possible interaction between FOXP3 and the HLA-DR3-DQ2 susceptibility haplotype. We then genotyped an additional independent set of 826 T1D patients and 1459 controls as well as one CD dataset consisting of 325 families. A similar tendency was revealed in the CD family material (pnc=0.055 for the associated allele). On the other hand, we were unable to reproduce our initial findings in the T1D case-control dataset (global p=0.6). Our results suggest that the tested FOXP3 markers do not have any major impact on susceptibility for these diseases.
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PMID:FOXP3 polymorphisms in type 1 diabetes and coeliac disease. 1699 48

The latent autoimmune diabetes in adults (LADA) is a subgroup of type 1 diabetes, which procession of autoimmune destruction of beta-cells was slower than classic type 1 diabetes. To investigate the pathogenesis of LADA, we examined the lymphocyte subsets including the CD4(+)CD25(+) T-cells in 60 LADA patients and 30 patients of type 2 diabetes and 30 healthy individuals by FACS. And we compared the expression of FOXP3 mRNA in CD4(+) T-cell between 10 patients of LADA and 10 matched healthy individuals by real time PCR. The percent of CD4(+)CD25(+) T-cells were higher (11.89+/-4.96% versus 8.16+/-3.65%, P<0.01), and the percent CD8(+) T-cells elevated (24.58+/-6.80% versus 19.39+/-7.12, P<0.01) in LADA patients than healthy individuals. While the expression of FOXP3 mRNA in CD4(+) T-cell was markedly decreased in LADA patients (0.52-fold, n=10, P=0.004) compared with normal subjects. In addition, the percent of CD8(+) T-cells related with GAD-Ab titers in LADA patients (r=0.292, P=0.03). Our results showed that there were cellular immune disorder and decreased CD4(+) regulatory T-cells in LADA patients. The adoptive transfer regulatory T-cells seem to be a potential therapeutics for LADA.
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PMID:The CD4(+) regulatory T-cells is decreased in adults with latent autoimmune diabetes. 1700 88

Regulatory T-cells are a subset of T cells that have beene extensively studied in modern immunology. They are important for the maintenance of peripheral tolerance, and have an important role in various clinical conditions such as allergy, autoimmune disorders, tumors, infections, and in transplant medicine. Basically, this population has a suppressive effect on the neighboring immune cells, thus contributing to the local modulation and control of immune response. There are two main populations of regulatory T cells - natural regulatory T cells, which form a distinct cellular lineage, develop in thymus and perform their modulatory action through direct intercellular contact, along with the secreted cytokines; and inducible regulatory T cells, which develop in the periphery after contact with the antigen that is presented on the antigen presenting cell, and their primary mode of action is through the interleukin 10 (IL-10) and transforming growth factor beta (TGF-alpha) cytokines. Natural regulatory T cells are activated through T cell receptor after contact with specific antigen and inhibit proliferation of other T cells in an antigen independent manner. One of the major difficulties in the research of regulatory T cells is the lack of specific molecular markers that would identify these cells. Natural regulatory T cells constitutively express surface molecule CD25, but many other surface and intracellular molecules (HLA-DR, CD122, CD45RO, CD62, CTLA-4, GITR, PD-1, Notch, FOXP3, etc.) are being investigated for further phenotypic characterization of these cells. Because regulatory T cells have an important role in establishing peripheral tolerance, their importance is manifested in a number of clinical conditions. In the IPEX syndrome (immunodysregulation, polyendocrinopathy and enteropathy, X-linked), which is caused by mutation in Foxp3 gene that influences the development and function of regulatory T cells, patients develop severe autoimmune reactions that involve autoimmune endocrine disorders (type 1 diabetes, thyroiditis), respiratory and nutritive allergy, eczema and severe infections. In different types of allergy (pollen allergy, dust mite, nutritive allergens, contact hypersensitivity, etc.) and autoimmune diseases (such as rheumatoid arthritis, multiple sclerosis and type 1 diabetes) a lower number or decreased functional capability of regulatory T cells have been described. In inflammatory conditions and infections, this cell population has an important task in restricting immune response and protecting the host from excessive damage. This ability of regulatory T cells can be used by some pathogens (Epstein Barr virus, Mycobacterium tuberculosis, Leishmania major, etc.) and tumor cells to avoid host response and therefore contribute to the development of some pathological conditions. The knowledge gained on the phenotype and function of regulatory T cells could be useful in many medical conditions. In allergy, autoimmune diseases and in transplant procedures in medicine it would be desirable to increase their function, thus to partially suppress the immune system activity. On the other hand, in some infections and tumors, it would be preferable to decrease the activity of regulatory T cells and boost the function of effector T cells. Regulatory T cells comprise a very active field of immunology, therefore monitoring and modulating of their activity is of great potential significance in a broad spectrum of clinical conditions. By developing and standardizing methods for their monitoring, it would be possible to follow additional parameters of certain clinical conditions and possibly utilize them in therapy.
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PMID:[Regulatory T cells]. 1721 1

At the time of this writing, a major void exists; the lack of a method to prevent and/or reverse type 1 diabetes in humans. We believe this void to a large extent is the result of our lack in understanding the mechanisms of autoimmunity that underlie beta cell destruction, a failure to understand the immunologic factors that contribute to type 1 diabetes, and the absence of immunologic tools which would allow for a better understanding of the mechanisms underlying disease development and monitoring of therapeutic interventions. Due to this, an intense degree of research interest has recently been generated to understand the mechanisms that regulate the immune response and form a state of immunological tolerance. While some progress has been made towards these goals, additional investigations are needed to address the aforementioned knowledge voids including the role for regulatory T cells (Treg), defined by their co-expression of CD4 and CD25 as well as the transcription factor FOXP3, in the pathogenesis and natural history of type 1 diabetes. We and others have recently reported findings related to the frequency and function of Treg cells in type 1 diabetes, yet the resulting literature represents a somewhat conflicting body of findings. Our studies did not support the notion that altered Treg frequencies are associated with type 1 diabetes, but rather did identify alterations in the functional (i.e., suppressive) activities of these cells in subjects with the disease. The need to bring resolution to the aforementioned published discrepancies in frequency and function of Treg in type 1 diabetes represents the impetus for this critical review. In addition, we hope to highlight the need for expanded studies that address specific knowledge gaps regarding the cellular and molecular mechanism(s) related to the frequency and function of Treg.
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PMID:Treg in type 1 diabetes. 1770 86

Until 1995, the etiology of 'neonatal' diabetes was totally unknown. In about a decade, mutations in 8 different genes (IPF1, EIF2AK3, GK, FOXP3, KCNJ11, ABCC8, PTF1A and GLIS3) have been discovered in patients with the permanent form of the disease, and 3 genetic abnormalities (defects in the paternally imprinted chromosomal region 6q24 and 'mild' activating mutations in KCNJ11 or ABCC8) have been detected in subjects with transient neonatal diabetes. Together with the advances in the understanding of the pathophysiology of this condition, clearly different from type 1 diabetes, also the temporal criterion by which one clinically defines a patient as being affected by neonatal diabetes has changed. In 1995, neonatal diabetes was defined as hyperglycemia that requires insulin treatment and occurs during the first month of life. In some patients with defects of KCNJ11, ABCC8 or EIF2AK3 genes however, diabetes can present at 6 months of age and beyond. It is now time to adopt a new definition in order to avoid the confusion originating by the misuse of the term 'neonatal'. I would suggest monogenic diabetes of infancy, which includes both the permanent and the transient types, irrespectively of the mechanism of disease.
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PMID:Diagnosis of neonatal and infancy-onset diabetes. 1798 29

Immunodysregulation, polyendocrinopathy, enteropathy, X-linked (IPEX) syndrome is a rare disorder caused by mutations in the FOXP3 gene that result in the defective development of CD4+CD25+ regulatory T cells which constitute an important T cell subset involved in immune homeostasis and protection against autoimmunity. Their deficiency is the hallmark of IPEX and leads to severe autoimmune phenomena including autoimmune enteropathy, dermatitis, thyroiditis, and type 1 diabetes, frequently resulting in death within the first 2 years of life. Apart from its clinical implications, IPEX illustrates the importance of immunoregulatory cells such as CD4+CD25+ regulatory T cells.
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PMID:IPEX as a result of mutations in FOXP3. 1831 33

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