UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

When highly purified neonatal rat islet tissue, derived after 10 days in vitro, was allografted, it was found to be nonimmunogenic or weakly immunogenic. In contrast, nonislet pancreatic components, derived from the same culture system, transplanted with highly purified islet tissue resulted in rejection in 88% of cases. Extension of the culture period did not result in reduced immunogenicity of the nonislet material. Immunostaining of islet or nonislet tissue from the culture system failed to demonstrate major histocompatibility complex (MHC) class II positive cells in the islet tissue, whereas the presence of MHC class II staining cells in the nonislet components was clearly demonstrable. These results demonstrate that the islet tissue obtained by culture isolation is free of cells capable of stimulating an allogeneic immune response and are consistent with the hypothesis that the absence of MHC class II positive antigen-presenting cells reduces the immunogenicity of the tissue and enhances the survival of allogeneic grafts.
Diabetes 1989 Feb
PMID:Allotransplantation of culture-isolated neonatal rat islet tissue. Absence of MHC class II positive antigen-presenting cells in nonimmunogenic islets. 249 74

Insulin-dependent diabetes mellitus is widely believed to be an autoimmune disease. Recent onset diabetics show destruction of insulin-secreting pancreatic beta-cells associated with a lymphocytic infiltrate (insulitis), with autoantibodies to beta-cells being found even before the onset of symptoms. Susceptibility to the disease is strongly influenced by major histocompatibility complex (MHC) class II polymorphism in both man and experimental animal models such as the non-obese diabetic (NOD) mouse. As MHC class II molecules are usually associated with dominant immune responsiveness, it was surprising that introduction of a transgenic class II molecule, I-E, protected NOD mice from insulitis and diabetes. This could be explained by a change either in the target tissue or in the T cells presumed to be involved in beta-cell destruction. Recently, several studies have shown that I-E molecules are associated with ontogenetic deletion of T cells bearing antigen/MHC receptors encoded in part by certain T-cell receptor V beta gene segments. To determine the mechanism of the protective effect of I-E, we have produced cloned CD4+ and CD8+ T-cell lines from islets of recently diabetic NOD mice. These cloned lines are islet-specific and pathogenic in both I-E- and I-E+ mice. Both CD4+ and CD8+ cloned T cells bear receptors encoded by a V beta 5 gene segment, known to be deleted during development in I-E expressing mice. Our data provide, therefore, an explanation for the puzzling effect of I-E on susceptibility to diabetes in NOD mice.
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PMID:An explanation for the protective effect of the MHC class II I-E molecule in murine diabetes. 250 22

In vitro manipulation of pancreatic islets to decrease islet immunogenicity before transplantation has largely been directed at eliminating the major histocompatibility complex (MHC) class II-positive passenger leukocytes from the islets. The mixed islet-lymphocyte coculture (MILC) system was used to quantitate the efficacy of immunodepletion of MHC class II-positive cells from pancreatic islets in terms of reducing immunogenicity. With these experiments we compared the in vitro immunogenicity of MHC class II-depleted islets with untreated islets. B10.BR (H-2k) islets were treated with anti-Iak alloserum followed by complement. This treatment successfully eliminated MHC class II-positive cells from the islets, as demonstrated by indirect immunofluorescence techniques. Depleted islets generated slightly lower amounts of allospecific cytotoxic T-lymphocyte (CTL) activity when exposed to C57BL/6 (H-2b) splenocytes in the MILC than untreated control islets. Although the amount of CTL generated by the depleted islets was slightly less than that generated by untreated islets, there was significant stimulation of CTL by the MHC class II-depleted islets. Therefore, the presence or absence of MHC class II cells within the islet is unlikely to be the decisive factor contributing to islet immunogenicity.
Diabetes 1989 Jan
PMID:Effect of immunodepletion of MHC class II-positive cells from pancreatic islets on generation of cytotoxic T-lymphocytes in mixed islet-lymphocyte coculture. 264 41

A murine mixed islet-lymphocyte coculture system (MILC) was used to quantitate the immunogenicity of a pure population of pancreatic beta-cells to more clearly define whether stimulator major histocompatibility complex (MHC) class II-positive dendritic cells are a major component leading to islet immunogenicity. Pancreatic beta-cells express MHC class I antigen but not class II antigen. These experiments compared the in vitro immunogenicity of fluorescence-activated cell sorted (FACS-IV) pure beta-cells (MHC class I-positive cells only) relative to unpurified dispersed islet cells (MHC class I-positive cells and class II-positive cells). The results demonstrated the surprising finding that pure DBA/2J (H-2d) pancreatic beta-cells stimulated a strong cytotoxic T-lymphocyte (CTL) response when exposed to C57BL/6 (H-2b) allosplenocytes in the MILC, similar to DBA/2J nonpurified dispersed islet cells. Furthermore, the stimulation of CTL by both purified beta-cells and nonpurified dispersed islet cells was blocked by addition of MHC-specific anti-class I monoclonal antibody directed against stimulator MHC antigen. The data imply that the highly immunogenic MHC class II-positive passenger leukocytes present in the islets were not necessary for the generation of the immune response in the presence of MHC class I-positive beta-cells. Although most of the pretreatment regimens attempting to decrease islet immunogenicity have been directed at eliminating the MHC class II-positive passenger leukocytes from the islets, this work suggests that modulation of MHC class I antigen may be an important approach.
Diabetes 1989 Jan
PMID:Generation of allospecific cytolytic T-lymphocytes stimulated by pure pancreatic beta-cells in absence of Ia+ dendritic cells. 264 43

The spontaneous development of diabetes in the Bio-Breeding (BB) rat is an excellent model of human insulin-dependent diabetes mellitus (IDDM). Disease expression is dependent on several genetically determined abnormalities, including specific major histocompatibility complex (MHC) genes. At least one MHC class II locus of the U haplotype is a necessary, but not sufficient, condition for disease expression. The immune system of BB rats is markedly abnormal. There is a striking reduction in the number and function of mature cytotoxic/suppressor T cells, a poor proliferative response to mitogens and in mixed lymphocyte culture, poor interleukin-2 production, and a reduced ability to reject skin allografts. While these immune system abnormalities are closely related to the development of diabetes, the immune recognition and effector mechanisms resulting in islet cell destruction are still poorly understood. The hypothesis that MHC class II induction on pancreatic beta cells serves to target these lymphokines, natural killer (NK) cells, macrophages, etc.) have been implicated in islet cell killing. The incidence of IDDM is reduced by immunosuppressive therapy in both rats and humans, further supporting the role of immune mechanisms in this disease.
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PMID:Immunologic and genetic studies of diabetes in the BB rat. 265 Oct 2

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

Insulin-dependent diabetes mellitus (IDDM) is an autoimmune disease whose notorious pathologic feature is insulitis accompanied by destruction of beta-cells. In this morphological study, we examined the pancreatic events during the onset of diabetes in spontaneously diabetic BB/Organon rats. Dendritic cells were the first cells to accumulate around the islets, followed by lymphocytes. Scavenger macrophages and MHC class II-positive beta-cells were only seen late in the disease. These observations suggest a role for antigen-presenting dendritic cells in the onset of the beta-cell-specific autoimmune reaction and emphasize the necessity to distinguish between the several monocyte-macrophage subtypes in studies on the pathogenesis of IDDM.
Diabetes 1989 Dec
PMID:Dendritic cells and scavenger macrophages in pancreatic islets of prediabetic BB rats. 268 15

The BB or BB/Worcester (BB/W) rat is widely recognized as a model for human insulin-dependent diabetes mellitus (IDDM). Of at least three genes implicated in genetic susceptibility to IDDM in this strain, one is clearly linked to the major histocompatibility complex (MHC). In an attempt to define the diabetogenic gene(s) linked to the MHC of the BB rat, cDNA clones encoding the class II MHC gene products of the BB diabetes-prone and diabetes-resistant sublines have been isolated and sequenced. For comparison, the beta 1 domain of class II genes of the Lewis rat (RT1L) were sequenced. Analysis of the sequence data reveals that the first domain of RT1.D beta and RT1.B beta chain of the BB rat are different from other rat or mouse class II sequences. However, these sequences were identical in both the BB diabetes-prone and BB diabetes-resistant sublines. The significance of these findings is discussed in relation to MHC class II sequence data in IDDM patients and in the nonobese diabetic (NOD) mouse strain.
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PMID:Molecular characterization of MHC class II antigens (beta 1 domain) in the BB diabetes-prone and -resistant rat. 278 84

Nonobese diabetic (NOD) is an inbred mouse strain susceptible to development of T cell-mediated autoimmune diabetes. The strain is characterized by high percentages of T lymphocytes in lymphoid organs. The syngeneic mixed lymphocyte reaction (SMLR), a T cell response to self MHC class II Ag, is reportedly involved in the generation of a number of immunoregulatory cells, including suppressor inducers. A severely depressed SMLR characteristic of certain other autoimmune strains was found in NOD but not in nonautoimmune SWR/Bm mice. Moreover, IL-2 produced by NOD T cells at day 6 in an SMLR was at least one hundredfold reduced compared with SWR, and NOD T cells harvested from an SMLR at day 6 were functionally defective when tested for ability to induce suppression of an allogeneic MLR. However, functionally competent suppressor T cells were generated in NOD splenic leukocyte cultures in response to Con A, and IL-2 release from these was equivalent to that released by Con A-stimulated SWR splenocytes. A deficiency in cytokine release was not limited to IL-2, because peritoneal exudate cells from NOD exhibited a greatly diminished sensitivity to LPS-stimulated IL-1 release in comparison to SWR mice. IL-2 supplementation both in vitro and in vivo restored the ability of NOD T cells to respond in a SMLR, with production of cells capable of inducing suppression. Like SMLR-activated T cells from untreated SWR controls, SMLR blasts from IL-2-treated NOD mice were enriched for the L3T4 phenotype. IL-1 supplementation in vitro resulted in partial restoration of T suppressor activation in a SMLR. The depressed SMLR exhibited by NOD mice was apparently a stimulator cell dysfunction, because NOD stimulator cells failed to activate T cells from (SWR x NOD)F1 mice, whereas stimulators from SWR or F1 mice were capable of doing so. Collectively, these results suggest a defect in suppressor cell activation rather than an absence of this immunoregulatory cell population.
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PMID:Defective activation of T suppressor cell function in nonobese diabetic mice. Potential relation to cytokine deficiencies. 289 95

Aberrant expression of MHC class II molecules on endocrine cells has been proposed to induce autoimmune reactions in thyroid and endocrine pancreas. The present study examines whether MHC class II positive insulin-containing islet cells occur at the onset of diabetes in rats, in analogy to the findings in man. At the onset of diabetes, both streptozotocin-treated and diabetes-prone BB rats exhibited numerous class II positive islet cells that presented ultrastructural features of monocytes and were surrounded by class II negative islet B cells. These class II positive cells were characterized by vacuoles that contained insulin immunoreactive granules and disrupted membranes. Similar cells also appeared positive for the monocyte marker OX-42. The presence of class II positive monocytes with insulin-containing vacuoles may indicate a removal of damage B cells by infiltrating leukocytes. A similar electron microscopical study in man will be necessary to distinguish the putative endocrine pancreatic B cells with aberrant class II expression from infiltrating nonendocrine class II positive cells with insulin-containing phagosomes.
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PMID:In situ analysis of pancreatic islets in rats developing diabetes. Appearance of nonendocrine cells with surface MHC class II antigens and cytoplasmic insulin immunoreactivity. 304 67

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