UMLS:C1862103 - FACTA Search

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Query: UMLS:C1862103 (BDC)
459 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Maternal transfer of TCR clonotypic Ab protected young NOD mice against the adoptive transfer of diabetes by the BDC 2.5 T cell clone. The effect of maternal anti-TCR Vbeta-8 Ab on T cell development and function has now been investigated. SJL/J mice, which lack TCR Vbeta-8, were immunized with soluble, chimeric D10 TCR-IgG1 containing Vbeta-8.2. The (SJL/J x AKR/J) F1 offspring of immunized female SJL/J mice were severely depleted of peripheral T cells bearing Vbeta-8 until 11 to 17 wk of age. The loss of Vbeta-8 expression did not appear to be due to modulation of cell surface TCR. Since the Vbeta-8+ T cell population was unperturbed in the (AKR/J x SJL/J) F1 offspring of D10 TCR-IgG1-immunized AKR/J mothers making D10 clonotypic Ab, the effect was immunologically specific. The deletion of Vbeta-8+ T cells had functional consequences. In the in vitro response to the superantigen, staphylococcal enterotoxin B, the usually observed participation of Vbeta-8.2+ T cells was largely suppressed, whereas the recruitment of Vbeta-3+ T cells remained unaltered. In control mice, T cell responses to the 134- to 146-residue peptide of conalbumin (pCA(134-146)) were biased toward use of Valpha-2/Vbeta-8.2 TCR. In D10 TCR-IgG1 maternally immunized (SJL x AKR/J) F1 mice, the T cell responses to pCA(134-146) were suppressed, and T cell lines derived from these in vitro were devoid of Vbeta-8.2 expression. With an increased understanding of TCR V gene usage in autoimmune diseases, similar strategies for the depletion of autoreactive T cells may become feasible in humans.
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PMID:Maternal immunization with a soluble TCR-Ig chimeric protein: long term, V beta-8 family-specific suppression of T cells by maternally transferred antibodies. 955 Mar 91

To investigate host leukocytes recruited to the pancreas by diabetogenic T cells, we administered islet-specific CD4(+) T cell clones to 2-week-old nonobese diabetic (NOD) mice and examined the resulting pancreatic infiltrate by flow cytometry. Two different Vbeta4(+)CD4(+) T cell clones, BDC 2.5 and BDC 6.9, were found to recruit a heterogeneous T cell population as determined by staining with a panel of anti-TCR Vbeta monoclonal antibodies. The majority of the diabetes-initiating, Vbeta4(+) T cell clones migrated to the spleen whereas only 5-8% of the T cell population infiltrating the pancreas was Vbeta4(+). Anti-IL-2 receptor staining indicated that fewer than 10% of the total population of infiltrating lymphocytes within the pancreas were in a highly activated state. We have further found that normal splenic T cells from the NOD mouse proliferate poorly to IL-2 in vitro, yet secrete IFN-gamma in response to IL-2 stimulation. These results suggest that the recruited host T cells in our disease transfer system are not directly pathogenic but, rather, are responding to the small numbers of inflammatory T cell clones by providing cytokines that facilitate the disease process.
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PMID:Analysis of leukocytes recruited to the pancreas by diabetogenic T cell clones. 979 Jul 22

We have produced a panel of cloned T cell lines from the BDC-2.5 TCR transgenic (Tg) mouse that exhibit a Th2 cytokine phenotype in vitro but are highly diabetogenic in vivo. Unlike an earlier report in which T cells obtained from the Tg mouse were cultured for 1 wk under Th2-promoting conditions and were found to induce disease only in NOD.scid recipients, we found that long-term T cell clones with a fixed Th2 cytokine profile can transfer disease only to young nonobese diabetic (NOD) mice and never to NOD.scid recipients. Furthermore, the mechanism by which diabetes is transferred by a Tg Th2 T cell clone differs from that of the original CD4+ Th1 BDC-2.5 T cell clone made in this laboratory. Whereas the BDC-2.5 clone rapidly causes disease in NOD.scid recipients less than 2 wk old, the Tg Th2 T cell clones can do so only when cotransferred with other diabetogenic T cells, suggesting that the Th2 T cell requires the presence of host T cells for initiation of disease.
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PMID:Induction of diabetes in nonobese diabetic mice by Th2 T cell clones from a TCR transgenic mouse. 1070 96

It has been widely assumed that T cells from TCR-transgenic (Tg) mice better represent the behavior of T cells from normal mice than do in vitro cultures of T cell clones. We have found that autoreactive T cells arising in the presumably more physiological environment of the BDC-2.5 TCR-Tg mouse, despite being apparently "naive" in surface phenotype, are highly activated functionally and do not resemble CD4(+) T cells from a spontaneously diabetic nonobese diabetic (NOD) mouse or the NOD-derived, diabetogenic CD4(+) T cell clone of origin, BDC-2.5. Our results suggest that autoreactive T cells cloned from the spontaneously diabetic NOD mouse more closely resemble effector T cells arising during the natural disease process.
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PMID:Comparison of a T cell clone and of T cells from a TCR transgenic mouse: TCR transgenic T cells specific for self-antigen are atypical. 1116 Mar 10

Nonobese diabetic (NOD) mice carrying a transgenic TCR from an islet Ag-specific CD4 T cell clone, BDC2.5, do not develop diabetes. In contrast, the same transgenic NOD mice on the SCID background develop diabetes within 4 wk after birth. Using a newly developed mAb specific for the BDC2.5 TCR, we examined the interaction between diabetogenic T cells and regulatory T cells in NOD.BDC transgenic mice. CD4 T cells from NOD.BDC mice, expressing high levels of the clonotype, transfer diabetes to NOD.SCID recipients. In contrast, CD4 T cells expressing low levels due to the expression of both transgenic and endogenous TCR alpha-chains inhibit diabetes transfer. The clonotype-low CD4 T cells appear late in the ontogeny in the thymus and peripheral lymphoid organs, coinciding with resistance to cyclophosphamide-induced diabetes. These results demonstrate that diabetic processes in NOD.BDC mice are regulated by a balance between diabetogenic T cells and regulatory T cells. In the absence of specific manipulation, regulatory T cell function seems to be dominant and mice remain diabetes free. Understanding of mechanisms by which regulatory T cells inhibit diabetogenic processes would provide means to prevent diabetes development in high-risk human populations.
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PMID:Regulation of diabetes development by regulatory T cells in pancreatic islet antigen-specific TCR transgenic nonobese diabetic mice. 1205 28

Organ-specific or endocrine autoimmune diseases are complex, polygenic afflictions the penetrance of which is heavily dependent on various environmental influences. Important target tissues are the thyroid, the islets of Langerhans, gastric parietal cells and steroid-producing cells in the adrenal and ovary. The etiology of these diseases remains to be clarified. The pathogenesis is strongly associated with autoimmune phenomena. None of the current treatment approaches provides a cure; rather they represent replacement therapy. An important objective in the treatment of endocrine/organ-specific autoimmune diseases is the detection of individuals at risk for the development of such diseases and the development of interventions to prevent an outbreak of the diseases. This requires an exquisite knowledge of the early etio-pathogenic stages of these diseases. This review concentrates on the usefulness of animal models for a precise understanding of these very early stages. It must be emphasized that studying animal models cannot answer all the problems presented by endocrine/organ-specific autoimmune diseases as seen in the clinic. It must be expected - considering the different etiologies in the different animal models (see below) - that the causes of the diseases in the human and the involvement of various genes and environmental factors may also vary. Yet, particularly in the study of the pre-autoimmune phases of the diseases, there is hardly any alternative to the study of animal models. Only limited series of experiments can be carried out in human subjects at risk to develop such diseases. Moreover, a general semblance (blueprint) of the etio-pathogenesis found in the animal models can lead the way for human studies. Efforts to understand the patho-physiology of the early stages of endocrine/organ-specific autoimmune diseases have mainly involved animal models that "spontaneously" develop such diseases. Of these the bio-breeding diabetes-prone (BB-DP) rat and the non-obese diabetes (NOD) mouse are the most well studied, yet many studies have also been carried out in the obese strain (OS) chicken. Apart from these spontaneous models there are animal models that are induced by environmental perturbations (viruses, toxic substances), by thymectomy procedures or by genetic manipulations, e.g., the RIP-LCMV model and the BDC 2.5 TCR mouse model. A general blueprint has emerged from the studies into the early stages of the pathogenesis of endocrine/organ-specific autoimmune diseases in these animal models: animals at risk to develop endocrine/organ-specific autoimmune diseases show various pre-autoimmune aberrancies in their target glands, T cells, macrophages (Mphi) and dendritic cells (DC). The presumably aberrant target cells, T cells, DC and Mphi need to interact abnormally before autoimmune disease can fully develop. In this abnormal interaction additional aberrancies in other regulatory systems may play a role in a further exacerbation of the self-directed immune response, such as defects in the hypothalamus pituitary adrenal (HPA) axis system. The various aberrancies are partly genetically determined by a variety of separate genes, particularly MHC-related genes, but they may also be environmentally induced (e.g., via viruses, high iodine diet, and other experimental manipulations). Recently evidence has been gathered for pre-autoimmune aberrancies similar to the animal models in the DC/ Mphi compartment and the HPA axis in humans at risk to develop endocrine/organ-specific autoimmune diseases. However, analogous pre-autoimmune abnormalities in human target glands or in T cell function have not yet been found with certainty. We believe that animal models of endocrine/organ-specific autoimmune disease still hold immense promise for the discovery of pathways, genes and environmental factors that determine the development of endocrine/organ-specific autoimmune diseases. Animals affected by such diseases provide a unique opportunity to uncover disease-associated pathways, which are complicated to define in man.
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PMID:Animal models of endocrine/organ-specific autoimmune diseases: do they really help us to understand human autoimmunity? 1250 56

The MHC determines susceptibility and resistance to type 1 diabetes in humans and nonobese diabetic (NOD) mice. To investigate how a disease-associated MHC molecule shapes the T cell repertoire in NOD mice, we generated a series of tetramers from I-A(g7)/class II-associated invariant chain peptide precursors by peptide exchange. No CD4 T cell populations could be identified for two glutamic acid decarboxylase 65 peptides, but tetramers with a peptide mimetic recognized by the BDC-2.5 and other islet-specific T cell clones labeled a distinct population in the thymus of young NOD mice. Tetramer-positive cells were identified in the immature CD4(+)CD8(low) population that arises during positive selection, and in larger numbers in the more mature CD4(+)CD8(-) population. Tetramer labeling was specific based on the use of multiple control tetramers, including one with a single amino acid analog peptide in which a critical TCR contact residue was substituted. The T cell population was already present in the thymus of 2-wk-old NOD mice before the typical onset of insulitis and was detected in B10 mice congenic for the NOD MHC locus, but not B10 control mice. These results demonstrate that a T cell population can expand in the thymus of NOD mice to levels that are at least two to three orders of magnitude higher than estimated for a given specificity in the naive T cell pool. Based on these data, we propose a model in which I-A(g7) confers susceptibility to type 1 diabetes by biasing positive selection in the thymus and later presenting peptides from islet autoantigens to such T cells in the periphery.
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PMID:Ex vivo analysis of thymic CD4 T cells in nonobese diabetic mice with tetramers generated from I-A(g7)/class II-associated invariant chain peptide precursors. 1453 Mar 40

The wide diversity of the T and B Ag receptor repertoires becomes even more extensive postneonatally due to the activity of TdT, which adds nontemplated N nucleotides to Ig and TCR coding ends during V(D)J recombination. In addition, complementarity-determining region 3 sequences formed in the absence of TdT are more uniform due to the use of short sequence homologies between the V, D, and J genes. Thus, the action of TdT produces an adult repertoire that is both different from, and much larger than, the repertoire of the neonate. We have generated TdT-deficient nonobese diabetic (NOD) and MRL-Fas(lpr) mice, and observed a decrease in the incidence of autoimmune disease, including absence of diabetes and decreased pancreatic infiltration in NOD TdT(-/-) mice, and reduced glomerulonephritis and increased life span in MRL-Fas(lpr) TdT(-/-) mice. Using tetramer staining, TdT(-/-) and TdT(+/+) NOD mice showed similar frequencies of the diabetogenic BDC 2.5 CD4(+) T cells. We found no increase in CD4(+)CD25(+) regulatory T cells in NOD TdT(-/-) mice. Thus, TdT deficiency ameliorates the severity of disease in both lupus and diabetes, two very disparate autoimmune diseases that affect different organs, with damage conducted by different effector cell types. The neonatal repertoire appears to be deficient in autoreactive T and/or B cells with high enough affinities to induce end-stage disease. We suggest that the paucity of autoreactive specificities created in the N region-lacking repertoire, and the resultant protection afforded to the newborn, may be the reason that TdT expression is delayed in ontogeny.
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PMID:Terminal deoxynucleotidyltransferase deficiency decreases autoimmune disease in diabetes-prone nonobese diabetic mice and lupus-prone MRL-Fas(lpr) mice. 1503 81

When transplanted into type 1a diabetic recipients, islet allografts are subject both to conventional allograft immunity and, presumably, to recurrent autoimmune (islet-specific) pathogenesis. Importantly, CD4 T cells play a central role both in islet allograft rejection and in autoimmune disease recurrence leading to the destruction of syngeneic islet transplants in diabetic NOD mice. However, it is unclear how NOD host MHC class II (I-A(g7))-restricted, autoreactive CD4 T cells may also contribute to the recognition of allogeneic islet grafts that express disparate MHC class II molecules. We hypothesized that islet-specific CD4 T cells can target MHC-mismatched islet allografts for destruction via the "indirect" (host APC-dependent) pathway of Ag recognition. To test this hypothesis, we determined whether NOD-derived, islet-specific CD4 T cells (BDC-2.5 TCR transgenic cells) could damage MHC-mismatched islets in vivo independent of conventional allograft immunity. Results demonstrate that BDC-2.5 CD4 T cells can vigorously destroy MHC class II-disparate islet allografts established in NOD.scid recipients. Tissue injury is tissue-specific in that BDC-2.5 T cells destroy donor-type islet, but not thyroid allografts established in the same NOD.scid recipient. Furthermore, BDC-2.5 CD4 T cells acutely destroy MHC class II-deficient islet allografts in vivo, indicating that autoimmune pathogenesis can be completely independent of donor MHC class II expression. Taken together, these findings indicate that MHC-mismatched islet allografts can be vulnerable to autoimmune pathogenesis triggered by autoreactive CD4 T cells, presumably through indirect autoantigen recognition in vivo.
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PMID:MHC-mismatched islet allografts are vulnerable to autoimmune recognition in vivo. 1608

Several genetic insulin-dependent diabetes (Idd) intervals that confer resistance to autoimmune diabetes have been identified in mice and humans, but the mechanisms by which they protect against development of diabetes have not been elucidated. To determine the effect of Idd9 on the function of islet-specific T cells, we established novel BDC-Idd9 mice that harbor BDC2.5 TCR transgenic T cells containing the Idd9 of diabetes-resistant B10 mice. We show that the development and functional responses of islet-specific T cells from BDC-Idd9 mice are not defective compared with those from BDC mice, which contain the Idd9 of diabetes-susceptible NOD mice. Upon transfer, BDC T cells rapidly induced severe insulitis and diabetes in NOD.scid mice, whereas those from BDC-Idd9 mice mediated a milder insulitis and induced diabetes with a significantly delayed onset. BDC and BDC-Idd9 T cells expanded comparably in recipient mice. However, BDC-Idd9 T cells accumulated in splenic periarteriolar lymphatic sheaths, whereas BDC T cells were mainly found in pancreatic lymph nodes and pancreata of recipients, indicating that the transferred T cells differed in their homing. We provide evidence that the migration pattern of transferred BDC and BDC-Idd9 T cells at least partly depends on their differential chemotaxis toward the CCR7 ligand CCL19. Taken together, our data show that the Idd9 locus regulates development of type 1 diabetes by affecting the homing of islet-specific T cells.
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PMID:The autoimmune diabetes locus Idd9 regulates development of type 1 diabetes by affecting the homing of islet-specific T cells. 1662 13

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