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:C0751781 (NOD)
6,696 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have cloned and sequenced the upstream regulatory region of tumor necrosis factor alpha (Tnfa) gene in 12 different mouse strains and identified an allelic polymorphism in the upstream regulatory region of the mouse Tnfa gene. The TNF allele found in the NZW strain is distinct from those of all other H-2 haplotypes, supporting our previous suggestion that this allele may be associated with a regulatory or structural defect. In addition, simple tandem repeat sequences (microsatellites) within the promoter region of the Tnfa gene and the 3' untranslated region of one of the members of the HSP70 family (Hsp68c clone) were utilized as genetic markers. Ten TNF size variants and twelve HSP70 variants were identified in over forty mouse strains. Using these markers in a set of congenic mice, we mapped this member of the HSP70 family to the central portion of the H-2 complex, centromeric to the Tnfa gene. The NOD and NZW strains carry unique HSP70 alleles based on the variability in the length of this marker. These findings raise the possibility that this protein may play a role in the association of the major histocompatibility complex with these autoimmune diseases.
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PMID:Definition of microsatellite size variants for Tnfa and Hsp70 in autoimmune and nonautoimmune mouse strains. 161 51

Transgenic mice have been used for analyses of cis-acting elements which are involved in the tissue-specific and developmental-specific expression, for analyses of physiological function of genes, or for the production of a human disease model. This approach is especially successful in the fields of immunology and oncology. Several years ago it was shown that the major histocompatibility complex (MHC) class II gene is identical to the immune response gene by demonstrating that the immune response can be restored by the new expression of class II molecules on immunocompetent cells. Recent evidence suggests that the class II molecule is involved in the generation of autoimmune disease, such as insulin-dependent diabetes mellitus (IDDM). The NOD (non-obese diabetic) mouse is shown to be a mouse model for human IDDM. Concerning the class II genes, the NOD mouse has two characteristic features, the lack of I-E and the presence of unique I-A. It is discussed how the role of class II molecules in the development of IDDM in the NOD mouse can be analyzed. In addition, the transgenic technique can be applied to the study of differentiation and oncogenesis of lymphoid cells. Factors or molecules that affect these processes will also be discussed.
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PMID:Transgenic mouse as a tool for the study of autoimmune disease: insulin-dependent diabetes mellitus. 161 97

The mechanisms contributing to the development of autoimmune insulin-dependent diabetes mellitus have been analyzed in allophenic mouse chimeras of the NOD in equilibrium with C57BL/6 strain combination (where NOD is nonobese diabetic). Occurrence of lymphoid cell infiltration (insulitis) in pancreatic islets was observed in the majority of such chimeras. The development of insulitis was found to correlate with major histocompatibility complex chimerism in lymphoid cells and in thymus cortical regions. Chimeras with more than 50% of C57BL/6 lymphoid cells rarely developed insulitis. Our data suggest that the correlation with the thymic cortical region is absolute. Thus, all individuals displaying NOD or NOD/C57BL/6 thymic cortical regions developed insulitis, whereas we have not observed insulitis in chimeras with only C57BL/6 thymic cortical regions. Thus the positive selection of T cells appears to play a crucial role in the development of insulin-dependent diabetes mellitus.
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PMID:The phenotype of lymphoid cells and thymic epithelium correlates with development of autoimmune insulitis in NOD in equilibrium with C57BL/6 allophenic chimeras. 192 97

It is generally held that one of the recessive genes controlling diabetes in the NOD mouse is linked to the major histocompatibility complex (MHC). Unique substitution of Asp57 with Ser in the A beta chain is considered to make the A beta gene the MHC-linked susceptibility gene. We therefore analysed the nucleotide sequences of the A beta second exon in ILI, CTS, and NON mice, which are nondiabetic inbred strains but are derived from the same Jcl-ICR mice as the NOD mouse. The DNA sequence analyses revealed that the A beta second exon sequences in the ILI and CTS mice, but not in the NON mouse, are identical to that of the NOD mouse. Possible roles of Ser57 of the A beta chain in the nondiabetic sister strains are discussed.
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PMID:The unique nucleotide sequence of the A beta gene in the NOD mouse is shared with its nondiabetic sister strains, the ILI and the CTS mouse. 196 45

Type 1 (insulin-dependent) diabetes mellitus results from an autoimmune disease which is directed to insulin-secreting islet cells. In man, it is closely associated to definite major histocompatibility complex alleles. The islets are infiltrated by inflammatory cells (insulitis). Anti-islet cell autoantibodies are present in most patients and represent a valuable marker for the autoimmune reaction. The major role of autoreactive T lymphocytes has been demonstrated in animal models of spontaneous insulin-dependent diabetes (the BB rat and the NOD mouse). Such pathophysiological concepts already have clinical applications. The presence of anti-islet cell antibodies identifies patients with type 1 diabetes of slow onset who initially present with non-insulin dependent diabetes. In the same respect it is now feasible to predict the possible occurrence of diabetes in 'at risk' subjects (such as siblings of a diabetic patient) on the basis of HLA typing and the presence of markers of anti-beta cell immunity. Lastly, both in animal models and in human diabetes, it has been demonstrated that immune intervention can alter the course of anti-islet autoimmunity. From these results one may hope in the future to get preventive treatment of type 1 diabetes before the onset of metabolic disturbances.
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PMID:[Type 1 diabetes mellitus, autoimmune disease: physiopathologic aspects and practical applications]. 206 84

Very little is known about the genes involved in the pathogenesis of IDDM. One component is known to be linked to the major histocompatibility complex, but the other components are unknown. We know from the major animals models of IDDM, both the NOD mouse and the BB rat, that the disease is under multigenic control. However, due to the size and complexity of the mammalian genome as well as to the lack of useful clues, the location and identity of the other genes remains a mystery. This is compounded by the fact that well-characterized genetic markers are not available for all regions of the mammalian genome, and it is likely that at least some of the genes of interest are located in these regions. The testing of pedigrees for the linkage of RFLP with the genetic factors involved in IDDM promises to be the most effective means of mapping, and ultimately identifying, these genes. However, the number of genes which are theoretically necessary to test for linkage makes even this approach impractical. Here, we have described here how the amount of work and time can be significantly reduced by utilizing repetitive DNA sequences as probes for the linkage of random RFLPs to diabetes. With each screening, one can simultaneously test multiple unlinked loci in the genome. Preliminary results which show promising linkage to two of the genetic components have been presented, thereby supporting the usefulness of this approach.
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PMID:The genetics of insulin-dependent diabetes in the BB rat. 219 68

The role of tumor necrosis factor alpha (TNF-alpha) in the pathogenesis of autoimmune diabetes mellitus was tested in the nonobese mouse (NOD) model system. The effects of TNF-alpha were assessed on three levels: (i) insulitis development, (ii) development of overt diabetes, (iii) adoptive transfer of diabetes by splenic lymphocytes. Spontaneous diabetes mellitus was blocked in NOD mice by long-term treatment with recombinant TNF-alpha. Treatment with TNF-alpha caused a significant reduction in the lymphocytic infiltration associated with the destruction of the insulin-producing beta cells. Class II major histocompatibility complex Ia expression by islet cells was not up-regulated by TNF-alpha. Moreover, TNF-alpha was able to suppress the induction of diabetes in adoptive transfer of lymphocytes from diabetic female mice to young nondiabetic male NOD mice. These activities of TNF-alpha were shared by interleukin 1 alpha in this system. These studies have implications for the pathogenesis and therapy of autoimmune diabetes mellitus.
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PMID:Prevention of diabetes in nonobese diabetic mice by tumor necrosis factor (TNF): similarities between TNF-alpha and interleukin 1. 240

The NOD mouse has been recently developed as a model for autoimmune insulin-dependent diabetes mellitus. The NOD mouse is further characterized by a genetic linkage with genes mapping within the major histocompatibility complex at the I-A locus. The present work demonstrates the presence in NOD mice of circulating autoantibodies specific for a 58 kDa antigen which is present in membrane extracts prepared from the murine insulin-secreting tumoral cell line Rin5F. This 58 kDa antigen shows a cross reactivity with NOD mouse class II antigens as indicated by its recognition by anti-I-A(NOD) monoclonal antibodies.
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PMID:[Cross-reactivity between major histocompatibility complex class II antigens in mice NOD and an islet antigen with 58 kDA molecular weight]. 250 91

Diabetes in the NOD mouse strain is a genetically programmed T cell-mediated autoimmune process that is directed against an as yet unknown antigen target(s) on pancreatic beta cells. To investigate whether the course of the autoimmune disease could be altered by immune manipulations of the T cell repertoire, we have induced allogeneic tolerance by injecting F1 semiallogeneic spleen cells into NOD neonates. This procedure resulted in a significant protection against both insulitis and diabetes. However, although it requires the induction of tolerance, as shown by the failure of non-tolerizing irradiated cells to prevent autoimmunity, protection appeared to be independent of the major histocompatibility complex haplotypes of the F1 spleen cells injected at birth, e.g. (C57BL/6 x NOD)F1, (CBA/Ca x NOD)F1 or (BALB/c x NOD)F1 cells. In addition, a similar degree of protection was induced, whether the tolerant state, as assessed by mixed lymphocyte reaction studies in vitro, was of short duration, approximately 6 weeks, or lasted for more than 12 weeks. Putative veto or suppressor functions of chimeric T cells were ruled out, since mice tolerized with T cell-depleted F1 spleen cells were equally protected. We conclude that the expression of spontaneous T cell-mediated autoimmunity can be modulated by immune manipulations at birth. Whether the protection observed in the present experiments resulted from the production of one or several specific holes in the autoimmune T cell repertoire, i.e. cross-tolerance, or whether it resulted from nonspecific disturbances of the emerging T cell repertoire remains to be elucidated.
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PMID:Neonatal induction of allogeneic tolerance prevents T cell-mediated autoimmunity in NOD mice. 252 99

Experimental results and therapeutic strategies. Insulin-dependent diabetes mellitus (IDDM) results from an autoimmune aggression toward beta cells in genetically predisposed individuals. Examination of the frequency of the different antigens coded by the major histocompatibility complex reveals an increased proportion of DR3-DQ2 and DR4-DQ8 haplotypes in IDDM subjects. Sequencing DQ-beta chains in such patients indicates the absence of aspartate in position 57 when compared to control individuals. Islet cell cytoplasmic autoantibodies are early markers of ongoing autoimmunity in addition to insulin autoantibodies before administration of exogenous insulin. Experimental models of autoimmune diabetes like the NOD (NonObese Diabetes) mouse underline the predominant role of T lymphocytes in the constitution of both insulitis and beta cell destruction. In humans, an increased proportion of activated T lymphocytes can be observed but is not specific of the disease. This underlines the need for new cellular markers of the autoimmune process. Transgenic mice allow studies on the consequences of abnormal expression of new molecules on beta cell surface like cytokines or MHC class II molecules which represent a new field of investigation on the pathogenesis of IDDM. Prospective studies in first degree relatives of type I diabetic patients indicate the existence of an asymptomatic phase of beta cell destruction where specific autoimmune markers can be individualized. In some individuals abnormal insulin response to glucose--loss of first phase insulin release during intravenous glucose tolerance test--precedes insulin deficiency. The identification of an autoimmune process leading to beta cell destruction allows new therapeutic approaches with immunointervention at early stages of the disease.
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PMID:[Autoimmunity and insulin-dependent diabetes mellitus. Experimental data and therapeutic prospects]. 267 68


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