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Query: UMLS:C0011849 (
diabetes
)
277,896
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The BB rat spontaneously develops autoimmune abnormalities such as insulin-dependent
diabetes mellitus
and thyroiditis. The autoimmunity of the BB rat is controlled in part by genes of the major histocompatibility complex (MHC), known as the RT1 complex in the rat, and accumulating evidence suggests the involvement of
MHC class II
molecules. The RT1 complex specifies two types of class II molecules, which are encoded by the loci RT1.B and RT1.D. We have determined the relative steady-state mRNA levels of the class II genes RT1.B beta, RT1.D alpha, and RT1.D beta in splenic lymphocytes from individual autoimmune BB rats of various ages and from age-matched histocompatible normal Wistar-Furth (WF) rats. The relative steady-state mRNA levels of the RT1.D alpha and RT1.D beta genes, but not of the RT1.B beta gene, were elevated approximately 2.5-fold in lymphocytes of prediabetic BB rats 45-75 days old in comparison with age-matched normal WF rats and older BB rats greater than 75 days old. In the diabetic and nondiabetic BB rats greater than 75 days old, the RT1.D alpha and RT1.D beta transcripts were found at lower normal levels, similar to that of WF rats. In contrast, the RT1.B beta transcripts were found at comparable levels in lymphocytes of the BB and WF rats at all ages examined. The increased steady-state mRNA levels of the RT1.D alpha and RT1.D beta genes in the prediabetic BB rats may reflect differences in the proportion of lymphocytes expressing these genes and thus differences in splenic lymphocyte populations.(ABSTRACT TRUNCATED AT 250 WORDS)
Diabetes
1988 Dec
PMID:Elevated mRNA levels of major histocompatibility complex class II genes in lymphocytes of autoimmune BB rats. 314
Use of monoclonal antibodies specific for rat lymphocyte subsets and an anti-insulin marker has allowed us to document the following sequence of events leading to the development of clinical
diabetes
in this animal model. The first change observed in the pancreas is increased expression of
MHC class II
molecules on vascular endothelium and this precedes lymphocytic infiltration. Next, T cells of the T helper phenotype infiltrate the pancreas around blood vessels. Many of the infiltrating T cells show class II expression indicating that they are activated. A few cytotoxic and suppressor cells and B lymphocytes are also present and their numbers increase proportionately with rat age. Some macrophages are also seen. Finally, at a late stage class II MHC molecules can be detected in partially destroyed islets on beta cells which are still actively synthesising insulin. We have never observed expression of class II molecules on glucagon or somatostatin secreting cells which are invariably well preserved.
...
PMID:Pre-diabetes in the spontaneously diabetic BB/E rat: lymphocyte subpopulations in the pancreatic infiltrate and expression of rat MHC class II molecules in endocrine cells. 389 30
It is the aim of this study to characterize and quantify the cells within isolated rat islets that express
MHC class II
antigens. A set of five monoclonal antibodies and two polyclonal antisera of defined specificity were used in combination with a newly devised procedure for three-dimensional immunofluorescence evaluation of intact islets. It is shown that in addition to passenger cells, such as lymphocytes, macrophages, and dendriticlike cells, vascular endothelial and endocrine cells are also capable of expressing class II antigens. This expression is strongly influenced by in vitro culture, pregnancy, streptozotocin-induced
diabetes
, transplantation trauma, and alloantigenic stimuli. The possible role of the above cells in antigen presentation related to islet transplantation is discussed.
...
PMID:MHC class II antigen expression on the various cells of normal and activated isolated pancreatic islets. 392 62
Type I
diabetes
, an autoimmune disease that occurs in humans and animals, is characterized by the destruction of insulin-secreting islet beta-cells of the pancreas. Antibodies directed toward multiple islet protein can be detected before diagnosis of type I
diabetes
; however, the identity of the inciting autoantigen(s) that targets beta-cells for destruction has not been defined. Autorecognition of many self-proteins by CD4+ T lymphocytes is restricted by the products of class II immune response genes of the major histocompatibility complex (MHC), and in human type I
diabetes
such a MHC association has been described. The present study uses a rat
MHC class II
(RT1.Bl) peptide binding motif to predict potentially autoreactive CD4+ T cell epitopes in two key islet beta-cell constituents: the enzyme glutamic acid decarboxylase (GAD) and the insulin precursor hormone proinsulin (PI). Seventeen-amino-acid-long peptide fragments of GAD and PI containing the binding motif were synthesized and used to generate peptide-specific,
MHC class II
-restricted, CD4+ T cell lines. Once established, the T cell lines specific for rat islet GAD and PI were adoptively transferred to naive, MHC-compatible rats. At 10 days after transfer, insulitis had developed in rats receiving PI-specific T cells, whereas no insulitis was observed in pancreata of rats receiving GAD-specific T cells. Of particular interest is the finding that the pathogenic T cell epitope identified in PI spans the endogenous cleavage site between the B-chain and C-peptide of insulin. Moreover, the PI-specific T cells were able to react specifically with material produced in vitro by a rat insulinoma cell line. These results demonstrate that pathogenic T cell epitopes can be located in portions of molecules that are subsequently degraded during normal enzymatic processing. As PI is found highest concentrations in the beta-cells of pancreatic islets, it is possible that this molecule and not its individual degradation products (ie, insulin and C-peptide) might serve as an autoantigen in the pathogenesis of type I
diabetes
.
...
PMID:Experimental autoimmune insulitis. Induction by T lymphocytes specific for a peptide of proinsulin. 754 75
Inbred
diabetes
-prone (DP) BioBreeding/Worcester (BB/Wor) (RT1u) rats develop spontaneous autoimmune
diabetes
, which, like human insulin-dependent
diabetes mellitus
, is mediated by autoreactive T lymphocytes. Breeding studies have shown an absolute requirement for at least one copy of the major histocompatibility complex (MHC) RT1u haplotype for spontaneous
diabetes
expression. Concanavalin A-activated spleen cells from acutely diabetic DP rats adoptively transfer
diabetes
only to recipients that express at least one RT1u haplotype. To investigate the basis for the MHC requirement in BB/Wor autoimmunity,
diabetes
-inducing T cell lines were derived from the spleens of acutely diabetic DP rats. Upon activation in vitro with islet cells, the T cell lines adoptively transfer insulitis and
diabetes
into young DP recipients and non-
diabetes
-prone RT1 congenic rat strains that are class IIu. Recipients that are RT1u at only the class I A or C locus, but not at the class II B/D loci, do not develop
diabetes
after T cell transfer. The adoptive transfer of
diabetes
by Concanavalin A-activated diabetic DP spleen cells also requires that donor and recipient share class II B/Du gene products. Furthermore, the adoptive transfer of
diabetes
into MHC class IIu congenic rats is independent of the class I haplotype; i.e., it occurs in the presence of class I Aa Cu or Au Ca gene products. BB/Wor T cells can be activated in vitro for the transfer of
diabetes
with islet cell antigens and class II-positive but not class IIu-negative antigen-presenting cells. The inductive phase of BB
diabetes
is therefore
MHC class II
restricted, and this appears to operate at the level of interaction between inducing T cells and class IIu antigen-presenting cells. These results may explain the well-documented, but not yet understood,
MHC class II
genetic contribution to insulin-dependent
diabetes mellitus
pathogenesis, and they may facilitate the development of protocols designed to prevent
diabetes
onset in susceptible individuals.
...
PMID:A major histocompatibility complex class II restriction for BioBreeding/Worcester diabetes-inducing T cells. 756 95
The BB/Wor rat develops spontaneous autoimmune
diabetes mellitus
and also frequently develops lymphocytic thyroiditis. To clarify the role of T cell lymphopenia and the major histocompatibility complex (MHC) in the development of these autoimmune disorders, we studied back-cross animals between the inbred thyroiditis and
diabetes
-prone BBNB/Wor subline (MHC RT1.AuBuDuCu) and three nonlymphopenic MHC-congenic rat strains: PVG.RT.1u (RT1.AuBuDuCu), PVG.R8 (RT1.AaBuDuCu), and PVG.R23 (RT1.AuBaDaCav1). We observed that 1) lymphopenia is absolutely required for the development of spontaneous
diabetes
and insulitis, and is usually associated with the development of thyroiditis; 2) the MHC region to the right of the class I RT1.A locus is strongly correlated with
diabetes
and insulitis; and 3) this region is also significantly associated with the development of thyroiditis, but the susceptibility of certain
MHC class II
alleles (u and a) for disease development is distinct for insulitis and thyroiditis. Furthermore, no recombination was observed between lymphopenia (lyp) and the neuropeptide Y (Npy) gene polymorphism, which confirmed that lyp maps very close to Npy. The present data suggest that spontaneous insulitis and thyroiditis in the BB/Wor rat develop through common immune defects involving T cell lymphopenia, but do not always segregate together due to disease-specific interactions with the
MHC class II
-linked genes.
...
PMID:Genetics of the BB rat: association of autoimmune disorders (diabetes, insulitis, and thyroiditis) with lymphopenia and major histocompatibility complex class II. 758 30
Fig. 6 depicts a model for epitope spreading in T cell-mediated demyelination. The acute phase of disease is due to T cells specific for the initiating epitope, which can be either a determinant on the CNS target organ of the autoimmune response or a determinant on a persisting, CNS-tropic virus. The primary T cell response is responsible for the initial tissue damage by the production of proinflammatory Th1 cytokines which can affect myelination directly (Selmaj et al. 1991) and indirectly by their ability to recruit and activate macrophages to phagocytize myelin (Cammer et al. 1978). As a result of myelin damage and opening of the blood-brain-barrier during acute disease, T cells specific for endogenous epitopes on the same and/or different myelin proteins are primed and expand either in the periphery or locally in the CNS. These secondary T cells initiate an additional round of myelin destruction, leading to a clinical relapse by production of additional pro-inflammatory cytokines, similar to the bystander demyelination operative during acute disease. It will be of great interest to determine the relative contributions of local and systemic immune responses to these endogenous neuroepitopes. It is possible that local CNS presentation of endogenous neuroepitopes following acute CNS damage could be mediated by infiltrating inflammatory macrophages, activated microglial cells, endothelial cells and/or astrocytes. These tissue resident antigen presenting cells have been shown to upregulate expression of
MHC class II
(Sakai et al. 1986, Traugott & Lebon 1988), certain adhesion molecules (Cannella et al. 1990), and B7 costimulatory molecules (K. M. Nikcevich, J. A. Bluestone, and S. D. Miller, in preparation) in response to pro-inflammatory cytokines. The data on epitope spreading provided by the murine demyelinating disease models clearly illustrate the dynamic nature of the T cell repertoire during chronic inflammation in a specific target organ. The contribution of epitope spreading to chronic CNS demyelination could be considered to be a special case since tolerance to myelin epitopes would be expected to be inefficient due to their sequestration behind the blood-brain-barrier. However, the recent description of epitope spreading in response to pancreatic antigens in spontaneous
diabetes
in the NOD mouse may indicate that this phenomenon is operative in a variety of organ-specific experimental and spontaneous autoimmune diseases.(ABSTRACT TRUNCATED AT 400 WORDS)
...
PMID:Evolution of the T-cell repertoire during the course of experimental immune-mediated demyelinating diseases. 759 Aug 15
In order to study whether positive selection of T cells plays any role in the MHC-dependent protection from
diabetes
in the non-obese-diabetic (NOD) mouse, the T cell V beta repertoire has been studied in NOD mice and in NOD mice either transgenic for the wildtype
MHC class II
E alpha gene, or for delta Y, a promotor-mutagenized E alpha gene with a restricted tissue expression. The E alpha transgenic line is protected from both insulitis and
diabetes
. The delta Y transgenic line is neither protected from insulitis nor from
diabetes
, although it can perform both positive and negative E-mediated selection in the thymus. The V beta repertoire was studied in the pancreatic lymph nodes as these drain the area which is the target for the autoimmune attack. We see no evidence for E alpha TCR V beta repertoire differing from both nontransgenic NOD mice and delta Y mice despite its striking difference in susceptibility to autoimmunity. We conclude that none of the differences in the TCR V beta repertoire of E alpha-transgenic NOD mice hitherto observed are likely to explain the protective effect of E molecule expression in NOD mice.
...
PMID:No evidence for TCR V beta repertoire changes influencing disease protection in E-transgenic NOD mice. 763 Nov 35
In this article, we have summarized current facts, models and views of the autoimmunity that leads to destruction of insulin-producing beta-cells and consequent Type 1 (insulin-dependent)
diabetes mellitus
. The presence of strong susceptibility and resistance gene loci distinguishes this condition from other autoimmune disorders, but environmental disease factors must conspire to produce disease. The mapping of most of the genetic risk (or disease resistance) to specific alleles in the major histocompatibility locus (
MHC class II
) has direct functional implications for our understanding of autoimmunity in
diabetes
and directly implies that presentation of a likely narrow set of peptides is critical to the development of diabetic autoimmunity. While many core scientific questions remain to be answered, current insight into the disease process is beginning to have direct clinical impact with concerted efforts towards disease prevention or intervention by immunological means. In this process, identification of the critical antigenic epitopes recognized by
diabetes
-associated T cells has achieved highest priority.
...
PMID:Self and non-self antigen in diabetic autoimmunity: molecules and mechanisms. 765 21
MHC class II
genes have been shown to influence the development of the autoimmune disease insulin-dependent
diabetes mellitus
(IDDM) in the nonobese diabetic (NOD) mouse. In human IDDM it has been suggested that the presence of an aspartate at position 57 of the DQ beta-chain might be important in determining resistance to development of IDDM. The involvement of
MHC class II
genes in IDDM was investigated through the introduction of MHC encoding transgenes. We show that introduction of a mutated I-Ag7 Ab gene which encodes an aspartate at position 57 reduces the incidence of IDDM but does not prevent insulitis, sialadenitis, or the development of insulin and nuclear autoantibodies.
...
PMID:Aspartate at position 57 of nonobese diabetic I-Ag7 beta-chain diminishes the spontaneous incidence of insulin-dependent diabetes mellitus. 773 Jun 55
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