Autoantibodies and CD4 T cells target a beta cell retroviral envelope protein in non-obese diabetic mice

We determined that, over a biologic time interval, from 4 to 8 weeks of age, female non-obese diabetic (NOD) mice develop antibodies against pancreatic beta-cell-surface antigens depending upon the presence of both the MHC class II susceptibility allele, I-A(g7), and other NOD background genes. We generated a mAb from a pre-diabetic NOD mouse that binds to the surface of insulinoma cells and isolated mouse beta cells, and identified the target as a retroviral envelope glycoprotein expressed on pancreatic beta cells. The cloned and expressed sequence for this protein was recognized by the mAb. The antibody as well as sera from pre-diabetic NOD mice recognized the recombinant protein. Spontaneous T cell reactivity against a peptide from the cloned protein was found in NOD mice. In conclusion, a beta cell retroviral envelope protein is a target antigen that is selected by the NOD mouse immune system early in the pathogenesis of autoimmune diabetes.     

Evidence for immunodominance between closely related epitopes in the selection of T cell repertoire: Hierarchy of T cell epitopes in a repeating sequence

In a protein antigen the number of epitopes that are presented by the MHC molecules to the T cells is generally limited. This phenomenon of immunodominance determines the T cell response to a given antigen. To understand the molecular basis of epitope selection we have analysed the hierarchy of T cell epitopes in a repeating synthetic polypeptide antigen Poly 18, Poly EYK(EYA)₅ in the mice of H-2^d haplotype. Because of its repeating nature, all the potential epitopes of Poly EYK(EYA)₅ generated as a result of antigen processing will have extensive sequence overlap, therefore, providing an excellent system to investigate the molecular basis of T cell peptide epitope selection in vivo. We have synthesized a series of 12 and 15 amino acid peptides to mimic these epitopes. In H-2^d mice Poly EYK(EYA)₅ elicits T cell clones that optimally react with 15 amino acid peptides EYK(EYA)₄ and/or (EYA)₅. Similar results were obtained when related 12 amino acid peptides EYK(EYA)₃ and/or (EYA)₄ are used. (EYA)₅ reactive T cell clones appear to be very heterogenous and much larger in number than EYK(EYA)₄ reactive clones. (EYA)₅ reactive clones could be elicited by at least three short Poly-18 derived epitopes (EYA)₄, EYK(EYA)₃ and (EYA)₃EYK while EYK(EYA)₄ reactive clones elicited only by the EYK(EYA)₃ epitope. However, we observed the dominance of (EYA)₅ reactive clones even when EYK(EYA)₃ was used as an immunogen and this could be related to the degeneracy of their antigen specificity. Our earlier antigen competition studies suggest that (EYA)₅ does not compete with EYK(EYA)₄ epitope in binding to I-A^d. Therefore, there is no intramolecular competition between these epitopes to activate T cells. The epitope (EYA)₃EYK appears to be subdominant since it can elicit Poly EYK(EYA)₅ specific T cells upon immunization but does not appear to be part of Poly EYK(EYA)₅ repertoire. Peptides such as (EYA)₂EYKEYA or EYAEYK(EYA)₂ with lysine substitution in the middle of the sequence were non immunogeneic. Similar results were obtained when the larger 15 amino acid peptides were used as antigen. Another level of epitope immunodominance is seen when substituted peptides of the two immunodominant epitopes are used. Some of these epitopes have potential to be part of the Poly 18 repertoire but they are greatly under represented when intact Poly 18 is used as antigen. The unusual hierarchy observed for immunodominance in these overlapping epitopes of EYK(EYA)₅ sequence suggest a bias in the selection of T cell repertoire based upon the crossreactivity between potential epitopes generated as a result of antigen processing.     

I-A alpha k transgene pairs with I-A beta b gene and protects C57BL10 mice from developing autoimmune myasthenia gravis.

The I-A beta gene has been implicated in the pathogenesis of experimental autoimmune myasthenia gravis (EAMG), with amino acids at positions 67, 70, and 71 of the I-A beta b chain that play a crucial role. In addition, the cell surface expression of the I-E molecule in C57BL10.E alpha k transgenic mice was associated with the partially suppressed serum anti-acetylcholine receptor antibody and clinical expression of EAMG. In this study, the contribution of the I-A alpha gene and the A beta b:A alpha k transpair in EAMG pathogenesis is assessed. The I-A alpha k transgene was introduced into the B10 (A beta b:A alpha b) strain, and the I-A alpha k chain was paired with I-A beta b; therefore, the A beta b:A alpha k complex was expressed on the cell surface. Expression of the A beta b:A alpha k transpair in C57BL10 transgenic mice suppressed the cellular and humoral autoimmune responses to acetylcholine receptors (AChR), reduced the amount of muscle AChR bound with antibody, and significantly reduced the incidence of muscle weakness and its associated abnormal electrophysiological response.     

Dissimilar background genes control susceptibility to autoimmune disease in the context of different MHC haplotypes: NOD.H-2(s) congenic mice are relatively resistant to both experimental autoimmune encephalomyelitis and type I diabetes

Nonobese diabetic (NOD) mice develop multi-organ autoimmune diseases, including type 1 diabetes. We hypothesized that backcrossing the MHC region from SJL (H-2(s)) mice, which have an endogenous PLP(139-151)-reactive repertoire, onto the background of autoimmune-prone NOD mice would result in a mouse strain that is highly susceptible to experimental autoimmune encephalomyelitis (EAE). Unexpectedly, although we detected an endogenous PLP(139-151) repertoire in the NOD.S mice, they did not develop spontaneous EAE and were relatively resistant to PLP(139-151)-induced EAE when compared to SJL mice. This resistance was associated with lower production of proinflammatory cytokines and a decreased expansion of PLP(139-151)-specific CD4(+) T cells after immunization and restimulation with PLP peptide in vitro. V(beta) chain usage among PLP(139-151)-reactive T cells differed between SJL and NOD.S mice. Furthermore, NOD.S mice were resistant to the development of insulitis and cyclophosphamide-induced diabetes, but not sialadenitis. Altogether, even though NOD mice develop spontaneous autoimmune diseases, they become relatively resistant to induction of EAE even when they express the EAE-permissive class II molecule I-A(s). Our data show that certain combinations of otherwise susceptibility-conferring MHC and non-MHC genes can mediate autoimmune-disease resistance when they are paired together. These findings do not support the "shared autoimmune gene" hypothesis.     

Relative resistance to nasally induced tolerance in non-obese diabetic mice but not other I-A(g7)-expressing mouse strains

I-A(g7) is a unique class II MHC molecule that is clearly associated with autoimmune diabetes in non-obese diabetic (NOD) mice. To determine if I-A(g7) is defective in its ability to deliver tolerogenic signals in vivo, H-2(g7) mice were nasally pretreated with antigen, prior to immunization, to induce antigen-specific regulation. Nasally pretreated NOR (H-2(g7)) and (NON).NOD (H-2(g7)) congenic mice showed responses similar to those of NON (H-2(nb1)), BALB/c (H-2(d)) and B10.PL (H-2(u)) mice-a reduced recall response and a deviated T(h) cytokine profile. However, we found that NOD (H-2(g7)) mice are comparatively resistant to immunological tolerance induced by nasal pretreatment, such that at the usually effective dose no significant reduction was seen in the proliferative recall responses to nominal antigen after immunization. (NOD x BALB/c)F(1) (H-2(g7/d)) and (NOD x NOR)F(1) (H-2(g7)) mice were similarly resistant to nasal-induced tolerance, although significantly higher nasal doses of antigen were able to overcome the resistance in NOD and F(1) mice. Interestingly, activated NOD T cells were resistant to cell death induced by re-stimulation with plate-bound anti-CD3. These results demonstrate that activated T cells in NOD mice are defective in their ability to respond to regulatory signals delivered in vivo or in vitro. Furthermore, NOD T cells have an increased resistance to tolerance induced by I-A(g7)-dependent (antigen) or I-A(g7)-independent (anti-CD3) mechanisms. Thus, while I-A(g7) may contribute to insulin-dependent diabetes mellitus by selecting a particular repertoire of self-reactive T cell clones, additional defects in the peripheral T cells themselves are required to allow the expansion of diabetogenic clones and the development of autoimmune disease.     

Genetic susceptibility or resistance to autoimmune encephalomyelitis in MHC congenic mice is associated with differential production of pro- and anti-inflammatory cytokines.

Experimental allergic encephalomyelitis (EAE) is a T(h)1-type cell-mediated autoimmune disease induced by immunization with myelin proteins and mediated by CD4(+) T cells. Although susceptibility to EAE is dependent largely on MHC background, the B10.S strain is resistant to induction of EAE despite sharing the I-A(s) MHC locus with the susceptible SJL strain. Furthermore, NOD mice which spontaneously develop diabetes are susceptible to EAE induction with myelin oligodendrocyte glycoprotein (MOG) 35-55, whereas a MHC congenic strain, III, which also expresses I-A(g7) MHC haplotype does not develop diabetes and is also resistant to EAE induction. We induced EAE in these four strains of mice with MOG peptides 92-106 (for I-A(s) strains) and 35-55 (for I-A(g7) strains) in complete Freund's adjuvant. In the susceptible strains (SJL and NOD) in vitro, there are high levels of IFN-gamma production, whereas the resistant strains (B10.S or III) secreted primarily IL-4/IL-10 and transforming growth factor (TGF)-beta, and had decreased levels of IFN-gamma. When brains from susceptible and resistant mice were examined by immunohistochemical methods for cytokine expression, the brains from resistant mice showed fewer infiltrates which predominantly expressed IL-4 and IL-10 and/or TGF-beta. Brains from NOD and SJL with EAE showed mainly IL-2 and IFN-gamma positive cells. Thus, resistance to MOG induced EAE in B10.S and III mouse strains is related to non-MHC genes and is associated with an altered balance of pro- and anti-inflammatory cytokines both in lymphoid tissue and in the brain following immunization with myelin antigens.     

Fibronectin receptor defects in NOD mouse leucocytes: possible consequences for type 1 diabetes

Integrins of the very late antigen (VLA) family mediate leucocyte traffic to lymphoid organs under physiological conditions and in chronic inflammatory situations such as autoimmunity. Accordingly, the current thinking is of a positive correlation between VLA expression and capability of the generation of autoimmunity. Herein we discuss recent findings on the defective expression of integrin-type fibronectin receptors alpha4beta1 (VLA-4) and alpha5beta1 (VLA-5) in the non-obese diabetic (NOD) mouse, a murine model of autoimmune insulin-dependent diabetes mellitus. As compared with normal animals, NOD thymocytes (including the CD4+CD25+ regulatory T cells) exhibit a decrease in the membrane expression of alpha5beta1, resulting in a functional impairment of fibronectin-mediated interactions, including cell migration. Interestingly, thymocytes that are trapped within the giant perivascular spaces seen in NOD thymus are consistently alpha5beta1 negative, suggesting that the progressive arrest of mature cells can be related to the alpha5beta1 defect. Peripheral T cells also exhibit decreased alpha5beta1 membrane expression and impaired fibronectin-driven migration. Additionally, we observed a defect in alpha4beta1 fibronectin receptor expression in NOD macrophages. Peritoneal, bone marrow-derived-precursor, as well as thymic macrophages of NOD mice showed an impaired upregulation of alpha4-integrin chain expression, dependent on the level of macrophage maturation. Overall these data lead to the notion that NOD leucocytes bear distinct fibronectin receptor-mediated cell migration defects, which may be involved in the pathogenesis and/or pathophysiology of the autoimmune events seen in NOD mice. Further studies will be helpful to define whether or not this concept can be applied for other autoimmune diseases.     

Adoptive transfer of islet antigen-autoreactive T cell clones to transgenic NOD.Ea(d)mice induces diabetes indicating a lack of I-E mediated protection against activated effector T cells

Transgenic insertion of the MHC class II Ea(d)gene in NOD mice restores I-E expression and prevents T-cell-mediated autoimmune diabetes (IDDM). The specific molecular and cellular mechanisms responsible for the diabetes resistance of transgenic NOD.Ea(d)mice remain unclear. We adoptively transferred islet antigen-specific T cell clones into NOD and transgenic NOD.Ea(d)mice to evaluate the level of protection provided by I-E expression against activated effector T cells. We have found that neither neonatal or 3-5-week-old I-E-expressing NOD.Ea(d)mice can completely inhibit the diabetogenic activities of activated islet antigen-specific T cell clones. These data indicate that Ealpha protein expression in NOD antigen presenting cells (APC) does not reduce islet autoantigen presentation in the context of I-A(g7)below the threshold required for stimulation of effector/memory diabetogenic T cells. Our results suggest that the mechanism of Ealpha protein-mediated diabetes resistance in NOD mice may be "antigen ignorance," in which the quantity of islet autoantigens presented in the context of I-A(g7)by APC is reduced below the threshold required to activate nai;ve islet antigen-specific T cells.     

Non-tolerance and differential susceptibility to diabetes in transgenic mice expressing major histocompatibility class II genes on pancreatic beta cells

In insulin-dependent diabetes mellitus aberrant expression of major histocompatibility complex (MHC) class II antigens might induce autoimmune destruction of insulin-producing pancreatic beta cells. Here we demonstrate that already the expression of single MHC class II chains (E alpha k and E beta b) is sufficient to cause diabetes without affecting beta cell morphology and cell numbers. Our transgenes interfere at least in two points of insulin production leading to a severely diabetic phenotype. In one case E beta b expression led to a 10-30-fold decrease of mouse insulin mRNA. In another case E alpha k expression reduced insulin secretion to background levels. In addition, we also found a patchy distribution of both insulin and E alpha k expression, indicating heterogeneity of the beta cell population, without the concomitant development of diabetes. Although the transgenic E alpha k E beta b MHC class II molecules were expressed on the surface of pancreatic beta cells, the transgenic mice did not prove to be tolerant for I-E antigen. Autoimmune reactions remained absent showing that aberrant MHC class II expression on pancreatic beta cells alone is not sufficient for the development of autoimmune diabetes in mice.     

A novel molecule expressing HLA-DR antigenic determinants

Our previous studies suggested that the polymorphism of HLA-DR antigens (the human equivalent of murine I-E antigens) was a result of structural variation in the small (beta) subunit. In order to more accurately define this polymorphism we have expanded these studies to include HLA-DR antigens isolated with monoclonal cells derived from genotypically HLA-homozygous DRw2, DR2w5, and DRw7 lymphoblastoid cells derived from offspring of consanguineous relationships. Our results indicate the large (alpha) subunits of DRw2 and DRw7 antigens are nearly identical, while their beta subunits show many differences. In contrast, both the alpha and beta subunits of the DRw5 antigen differ strikingly from the respective subunits of the DRw2 and DRw7 antigens. The significance of the variability of the DRw5 alpha subunit is in question at this point. One intriguing possibility is that DRw5 actually represents the human counterpart of the mouse I-A subregion antigen and that the monoclonal antibody is reacting with a determinant which is shared by the human equivalents of murine I-A and I-E antigens.     

Self-peptides that bind with low affinity to the diabetes-associated I-A(g7) molecule readily induce T cell tolerance in non-obese diabetic mice

Although non-obese diabetic (NOD) mice spontaneously develop T cell autoimmunity, it is not clear whether this phenomenon results from a defect in tolerance to self-Ag. Furthermore, as autoimmunity has been postulated to result from T cell responses directed toward self-peptides that bind with low affinity to NOD I-A(g7) MHC class II molecules, it is important to determine whether the expression of such peptides induces tolerance. We have constructed NOD transgenic (Tg) mice expressing the Leishmania antigen receptor for C kinase (LACK) Ag in either the thymus or pancreatic beta cells. We identified LACK peptides that were the targets of T cells in LACK-immunized NOD mice while binding to I-A(g7) with low affinity. While CD4(+) T cells from NOD mice secreted IFN-gamma, IL-4, IL-5 and IL-10 in response to LACK, those from LACK-expressing Tg mice secreted reduced levels of cytokines. Experiments using peptide/MHC multimers showed that LACK-expressing Tg mice exhibited self-reactive CD4(+) T cells with impaired proliferation capabilities. Hence, even self-peptides that bind to I-A(g7) with low affinity can induce tolerance in NOD mice. This result is important in light of the commonly held hypothesis that T cells reacting to peptides that bind to MHC with low affinity escape tolerance induction and cause autoimmunity.     

Anti-alpha/beta T cell receptor monoclonal antibody provides an efficient therapy for autoimmune diabetes in nonobese diabetic (NOD) mice.

The nonobese diabetic (NOD) mouse is a relevant model for studying human insulin-dependent diabetes mellitus (IDDM). The selective destruction of insulin-secreting cells in this model is subsequent to an autoimmune reaction directed towards the beta cells inside the islets of Langerhans of the pancreas. Given the key role played by T cells in the development of IDDM, we investigated a model of IDDM prevention in NOD mice by administration of a monoclonal antibody to the alpha/beta dimer of the T cell receptor for antigen. Our data provide evidence that aiming at the T cell receptor protects against both spontaneous and cyclophosphamide-induced diabetes in the NOD mouse. Interestingly, potential clinical application is suggested by the efficient and durable reversal of recent onset diabetes in mice treated with anti-alpha/beta monoclonal antibody within 1 week following the clinical discovery of IDDM.     

Functional degeneracy of residues in a T cell peptide epitope contributes to its recognition by different T cell hybridomas.

Synthetic antigen Poly EYK(EYA)5 induces T cells of narrowly defined fine specificity as represented by the two I-Ad-restricted T cell hybridomas, A.1.1 and B.1.1. Both these hybridomas recognize the minimum 15-amino-acid peptide sequence EYK(EYA)4. We have characterized the residues involved in the recognition of EYK(EYA)4 peptide by these hybridomas with synthetic peptides and discovered a distinct functional hierarchy for the residues in the sequence. Even with the repeating tripeptide (EYA)5, which is recognized by B.1.1 cells, the residues that are essential cluster near the middle of the sequence but not near the N- or C-terminal region. Different MHC binding and TCR contacting residues were found for each of the hybridomas. The results suggest that different T cells either recognize different parts of the peptide MHC complex or that the peptide binds to MHC in multiple conformations. This was supported by the fact that Poly EYK(EYA)5 is alpha-helical but the peptides used here showed only a slight propensity to adopt this structure and it did not correlate with their functional activity. We also found that (EYA)5 does not compete with EYK(EYA)4 in the stimulation of A.1.1 cells despite its obvious capacity to interact with I-Ad when it stimulates B.1.1 cells. This may be because these peptides have a low affinity for Ia and therefore only appropriate TCR interactions would stabilize the antigen-Ia complex. In conclusion, antigen-MHC-TCR interaction appears to be a dynamic process which allows recognition of different residues of a T cell determinant by different T cells.     

On the initial trigger of myasthenia gravis and suppression of the disease by antibodies against the MHC peptide region involved in the presentation of a pathogenic T-cell epitope

Myasthenia gravis (MG) is a disabling autoimmune disease caused by autoantibodies (auto-Abs) against the self-acetylcholine receptor (AChR). Although a great deal of information is known about the molecular and cellular parameters of the disease, its initial trigger, however, is not known. To study the possibility of the involvement of microbial antigens that mimic AChR in triggering MG, we have searched the microbial proteins in the data bank for regions that are similar in structure to the regions of human (h) AChR alpha chain recognized by auto-Abs in MG patients. Hundreds of candidate structures on a large number of bacterial and viral proteins were identified. To test the feasibility of the idea, we synthesized four microbial regions similar to each of the major autodeterminants of hAChR (alpha12-27, alpha111-126, alpha122-138, alpha182-198) and investigated their ability to bind auto-Abs in MG and normal sera controls. It was found that MG sera potentially recognized a significant number of these microbial regions. The results indicate that in some MG cases, immune responses to microbial antigens may cross-react with self-antigen (in this case hAChR) and could constitute initial triggers of the disease. Although anti-AChR Abs directly contribute to the degradation of AChR at the neuromuscular junctions, autoreactive T cells provide help to B cells that synthesize anti-AChR auto-Abs. To cause MG, T cells must recognize the pathogenic epitopes in the context of MHC class II molecules related to MG. The ability to regulate AChR presentation (hence AChR-reactive T-cell activation) could form the basis of an effective strategy for the control of autoimmunity in MG by selectively inhibiting the function of the Ir gene loci linked to disease susceptibility. An animal model of MG (experimental autoimmune MG, EAMG) can be induced in C57BL/6 (B6, H-2b) mice by immunization with Torpedo californica (t) AChR. A mutant mouse of B6, B6.C-H-2bm12 (bm12), which has three amino acid changes (at residues 67, 70, and 71) in the I-A beta(b) subunit, is resistant to EAMG development. Recently, we showed that region 62-76 of I-A beta(b), which contains the above residues, is involved in the binding to a pathogenic T-cell epitope within peptide t alpha146-162. We have prepared several monoclonal antibodies (mAbs) against peptide I-A beta(b)62-76, which are highly cross-reactive with I-A(b) molecules. These mAbs inhibited in vitro the proliferation of disease-related T cells of B6 specific to tAChR peptide t alpha146-162. Passive transfer of these mAbs suppressed the occurrence of clinical EAMG, which was accompanied by lower T-cell and Ab responses to tAChR. The results indicated that blocking disease-related MHC by targeting a disease-associated region on MHC molecules could be an effective, straightforward, and feasible strategy for immunointervention in MG.     

Restriction fragment length polymorphisms in the major histocompatibility complex of the non-obese diabetic mouse

The inbred non-obese diabetic (NOD) mouse is a spontaneous model for insulin-dependent diabetes mellitus (IDDM). As in man and BB rats, IDDM in the NOD mouse has an autoimmune aetiology. The disease is controlled by several genes, one of which, Idd-1, has been mapped to the major histocompatibility complex (MHC) on chromosome 17. However, Idd-1 has not yet been identified. To facilitate the identification of Idd-1 we have further analysed the MHC region for restriction fragment length polymorphisms and we find that the NOD mouse has a distinct haplotype: H-2K1nod Kd A beta nod A alpha d E beta nod TNF-alpha beta. In addition, the NOD mouse shows some similarities with the H-2b haplotype in the Q region, in that either the Q7 or the Q9 gene seems to be like that in the b-haplotype and that the Qa2 antigen is expressed, while other parts of this region are distinct from the b- as well as the d- haplotype. In contrast, the sister strain, the non-obese normal (NON) mouse, derived from the same cataract-prone line of mice as the NOD mouse, has an MHC Class I region indistinguishable from the b-haplotype, but the MHC Class II region is distinct from the NOD mouse as well as the b-, d- and k-haplotype.     

Interferon-Mediated Enhancement of Thyroid Major Histocompatibility Complex Antigen Expression

Epithelial expression of class II antigens encoded by the major histocompatibility complex (MHC) has been proposed as a means by which autoimmune thyroid disease may be initiated and maintained. We studied a rat thyroid epithelial cell line (FRTL-5), which constitutively expresses class I (OX18) but not class II (OX6 or OX17) determinants to quantify in vitro MHC antigen induction using flow cytometry. Recombinant rat gamma interferon (rIFN-gamma) induced dose-dependent expression of OX6 (I-A) antigen at greater than 48 h (maximum 80-90% of cells in culture at 100 U/ml), which was abrogated by DB-1, a monoclonal antibody to rat IFN-gamma. OX17 antigen (I-E) was also induced (86%) and OX18 (class I) markedly increased under these conditions. Other thyroid-active agents including the calcium ionophore A23187, dibutyryl cyclic AMP, thyroid-stimulating autoantibodies from Graves' disease patients (LATS), and TSH, caused no I-A induction. Supernatants from spleen cells stimulated with plant lectins (concanavalin A or phytohaemagglutinin), but not lectin alone, evoked substantial class II induction, which was inhibited by DB-1. These findings suggest that IFN-gamma is the central mediator of thyroid epithelial class II expression. FRTL-5 provides a powerful model for the analysis of thyroid MHC class II dynamics and a potential means of analysing the role of epithelial class II in autoimmune pathogenesis.     

Production of antibodies against murine class II antigens using unconjugated synthetic peptides of the beta chain region 63-78

synthetic peptides corresponding to residues 63-78 of the first domain of the beta chain of murine I-A/I-E class II antigens were used in the unconjugated rather than the traditional protein-conjugated form to immunize (129J X B6)F1 mice. The sequences made represented the four haplotypes; Ak beta, Ad beta, Abm-12 beta and Ed beta. These sequences were selected on the basis of computer algorithms used to predict surface accessibility and main-chain flexibility profiles, and by reported hypervariability and site-directed mutagenesis experiments of these regions. Factors such as the use of complete Freund's adjuvant, a continuous immunization regime, and the sex of the mice used were found to influence the amount of anti-peptide antibody produced when unconjugated peptide was used as the immunogen. Antibodies produced were shown by FACS analysis to react with I-A/I-E class II antigens expressed on the lymphocyte surface. These findings indicate that the use of unconjugated synthetic peptides representing sequences of proteins which are in close proximity to disulfide bonds may be an advantage over conventional methods of peptide conjugation to proteins.     

Evidence for shared recognition of a peptide ligand by a diverse panel of non-obese diabetic mice-derived,islet-specific,diabetogenic T cell clones

MHC class II-restricted autoreactive T cells play a major role in the development of autoimmune diabetes mellitus in both human and mouse. Two of our groups previously established panels of islet-reactive CD4+ T cell clones from prediabetic non-obese diabetic (NOD) mice. These clones express distinct sets of TCR V alpha , V beta , J alpha and J beta , and also differ in the structure of the junctional region of TCR. All of the T cell clones have been shown to cause insulitis and several induce diabetes when transferred to various recipients. The antigen specificities of these T cell clones have not been determined, but they do not react with defined islet cell antigens such as glutamic acid decarboxylase. To identify the peptide ligands recognized by these clones, we examined the reactivity of the T cell clones to peptide mixtures in which anchor residues for H2-A g7 were fixed. Most of the clones showed similar reactivity to the peptide mixtures. To further determine the peptide ligands of the T cell clones, we synthesized several peptides based on the favored amino acid motifs and examined clone reactivity to the synthetic peptides. Some of the peptides, e.g. HLAI-RM and HIPI-RM, could stimulate most of the T cell clones tested, even though the clones expressed different TCR. The results suggest that our islet-reactive T cell clones recognize in islet beta cells a natural ligand that is similar to these peptides.     

Secretory granule autoantigen in insulin-dependent diabetes mellitus is related to 62 kDa heat-shock protein (hsp60).

Recent studies in NOD mice suggest that cellular and humoral responses against beta cell protein(s) cross-reactive with mycobacterial heat-shock protein, hsp60, are implicated in the development of autoimmune diabetes. However, this putative, hsp60-related autoantigen has not yet been identified nor have the preceding events triggering the autoimmunity against it. Our recent studies show that antibodies to the mammalian hsp60 bind specifically to the 62 kDa protein located to insulin secretory granules and mitochondria of pancreatic beta cells of healthy mice [1]. In islets of prediabetic NOD mice affected by insulitis, the cellular distribution of this hsp60-related antigen was found to be altered. In the present report, we have examined whether this endogenous hsp60-related protein of secretory granules serves as an autoantigen in type I diabetes. The results of Western blot analysis indicate that diabetic mice sera show reactivity to a 62 kDa islet cell antigen. The NOD mice sera that were positive in detection of the 62 kDa islet cell antigen were also able to recognize the recombinant human hsp60. Immunogold electron microscopy revealed that diabetic NOD mouse sera, cross-reactive to human recombinant hsp60, recognize the antigen located in secretory granules of beta cells. Double-immunogold labelling demonstrated that antigens recognized by both diabetic NOD mice sera and monoclonal hsp60 antibodies co-localized in the same secretory granules of beta cells. Preincubation of islet cell sections with one type of antibody blocks subsequent binding of the other, indicating that epitopes recognized by both antisera on these proteins are shared. Moreover, preadsorption of diabetic sera with the recombinant human hsp60 abolished labelling of secretory granules. These results indicate that the hsp60-related protein of beta cell secretory granules is an autoantigen in type I diabetes in NOD mice.     

Molecular biology of murine MHC class II genes.

The murine class II genes are contained in the I region of the major histocompatibility complex (MHC). In the mouse, there are seven class II genes: A beta 3, A beta 2, A beta, E beta, E beta 2, A alpha, and E alpha. The A beta and A alpha genes code for the two polypeptide chains that form the I-A immune response molecule. The E beta and E alpha genes code for the two polypeptide chains that form the I-E immune response molecule. This review covers the genetic organization of the I region and the exon-intron structure of the class II genes. This review also discusses site-directed mutagenesis and exon shuffling studies and the effect of these changes on the function of Ia genes. Regulation of the cellular expression of Ia genes is discussed with emphasis on recent studies involving class II transgenic mice. Also, studies mapping recombination hotspots within the E alpha and E beta genes are reviewed.