Cellular immune response to diverse islet cell antigens in IDDM

Autoimmune responses to the beta cell autoantigen, insulin, and the INS VNTR-IDDM2 locus

Type 1 diabetes is associated with autoimmunity to insulin. Genetic susceptibility to type 1 diabetes is polygenic and includes the INS VNTR-IDDM2 locus which may regulate the expression of insulin in pancreas and thymus. In order to determine whether insulin autoimmunity could be attributed to a genetic susceptibility conferred by the INS VNTR-IDDM2 locus, peripheral blood T cell proliferation to human insulin and insulin autoantibodies (IAA) was measured in patients with new onset type 1 diabetes and control subjects. IAA were detected in 21 of 53 patients and in none of 25 control subjects, while T cell responses were low (stimulation index range 0.4-7.2) and similar in both groups. Both antibody and T cell responses were higher in younger subjects and IAA were more prevalent in patients with the HLA-DR4 allele. No relationship was observed between humoral and cellular responses to insulin. No association was found between the INS VNTR-IDDM2-susceptible allele and insulin autoimmunity. Increased T cell responses and IAA were found in patients with either the diabetes-susceptible or the diabetes-protective INS VNTR-IDDM2 locus genotypes, and increased T cell responses were also found in control subjects with either susceptible or protective INS VNTR-IDDM2 locus genotypes. This study confirms that primary T cell proliferative responses to insulin are low and detectable also in control subjects. The detection of T cell proliferation and autoantibodies to insulin in subjects with and without the protective INS VNTR-IDDM2 locus genotypes does not support the hypothesis of an allele-specific capacity for tolerance induction which could determine a susceptibility to develop autoimmunity against the insulin protein and subsequently diabetes.

Prediction and prevention of type 1 diabetes

Clinical type 1 diabetes represents end-stage insulitis resulting from progressive beta-cell destruction over an asymptomatic period that may last for years. This knowledge and recent advances in our ability to identify individuals at increased risk for clinical disease have paved the way for trials aimed at preventing or delaying the clinical onset of type 1 diabetes. Individuals at risk for type 1 diabetes can be identified by a positive family history, or by genetic, immunological or metabolic markers. These markers can also be combined to achieve a higher positive predictive value. As long as there is no effective preventive modality available for clinical use, screening for the identification of risk individuals can be considered ethically acceptable only in the context of sound research protocols. Prevention of type 1 diabetes can be implemented at three different levels, out of which primary prevention includes all strategies aimed at decreasing the risk of developing type 1 diabetes in individuals without any signs of beta-cell damage. Secondary prevention aims to reduce the incidence of type 1 diabetes by stopping beta-cell destruction in individuals with signs of such a process, while the objective of tertiary prevention is to restore beta-cell function or prevent complications in patients with overt type 1 diabetes. At present, one primary prevention trial and four comprehensive secondary prevention trials are in progress. Common features of these intervention trials are that the recruitment of patients fulfilling the inclusion criteria is time-consuming and the trials must proceed for a long time, as clinical disease is the end point. The secondary prevention trials also require extensive screening for the identification of eligible patients. The ongoing intervention trials may, however, represent a new era in type 1 diabetes, i.e. the beginning of the end of this complicated disease.

Humoral and cellular immune parameters before and during immunosuppressive therapy of a patient with stiff-man syndrome and insulin dependent diabetes mellitus

OBJECTIVES

Humoral and cellular immune reactivity are reported for two neuroendocrine autoantigens-glutamic acid decarboxylase (GAD) and the protein tyrosine phosphatase IA-2-in a patient with the autoimmune type of stiff-man syndrome and insulin dependent diabetes (IDDM).

METHODS

Antibodies and T cell proliferation against GAD and IA-2 and cytokine release of antigen stimulated T cells (IFN-gamma) were determined before and several times during immunosuppressive therapy with prednisolone.

RESULTS

Raised GAD antibodies against full length GAD65 or chimeric constructs were detected before therapy and they remained at a high concentration despite a marked clinical improvement during cortisone treatment. Antibodies to IA-2 were undetectable, but weak T cell responses to both GAD and IA-2 were seen before therapy and once on reduction of high cortisone dosages when the patient showed signs of clinical deterioration. Cytokine profiles showed increased IFN-gamma production after stimulation with GAD or IA-2 suggesting increased activation of TH1 cells.

CONCLUSION

Immunosuppressive therapy --even with extremely high doses of 500 mg a day--does not lead to the reduction of antibody concentrations in the periphery nor to a switch in epitope recognition of such antibodies despite clinical improvement. The amount of T cell reactivity to various antigens, however, may be a useful marker to monitor the effectiveness of immunotherapy.

Autoimmune diabetes: the role of T cells, MHC molecules and autoantigens

Type 1 diabetes (IDDM) is a T cell mediated autoimmune disease which in part is determined genetically by its association with major histocompatibility complex (MHC) class II alleles. The major role of MHC molecules is the regulation of immune responses through the presentation of peptide epitopes of processed protein antigens to the immune system. Recently it has been demonstrated that MHC molecules associated with autoimmune diseases preferentially present peptides of other endogenous MHC proteins, that often mimic autoantigen-derived peptides. Hence, these MHC-derived peptides might represent potential targets for autoreactive T cells. It has consistently been shown that humoral autoimmunity to insulin predominantly occurs in early childhood. The cellular immune response to insulin is relatively low in the peripheral blood of patients with IDDM. Studies in NOD mice however have shown, that lymphocytes isolated from pancreatic islet infiltrates display a high reactivity to insulin and in particular to an insulin peptide B 9-23. Furthermore we have evidence that cellular autoimmunity to insulin is higher in young pre-diabetic individuals, whereas cellular reactivity to other autoantigens is equally distributed in younger and older subjects. This implicates that insulin, in human childhood IDDM and animal autoimmune diabetes, acts as an important early antigen which may target the autoimmune response to pancreatic beta cells. Moreover, we observed that in the vast majority of newly diagnosed diabetic patients or individuals at risk for IDDM, T cell reactivity to various autoantigens occurs simultaneously. In contrast, cellular reactivity to a single autoantigen is found with equal frequency in (pre)-type 1 diabetic individuals as well as in control subjects. Therefore the autoimmune response in the inductive phase of IDDM may be targeted to pancreatic islets by the cellular and humoral reactivity to one beta-cell specific autoantigen, but spreading to a set of different antigens may be a prerequisite for progression to destructive insulitis and clinical disease. Due to mimic epitopes shared by autoantigen(s), autologous MHC molecules and environmental antigens autoimmunity may spread, intramolecularly and intermolecularly and amplify upon repeated reexposure to mimic epitopes of environmental triggers.

Cloned T cells from a recent onset IDDM patient reactive with insulin B-chain

Insulin-dependent diabetes mellitus (IDDM) results from selective autoimmune destruction of insulin producing beta-cells. T-cell reactivity and autoantibodies to several islet proteins such as insulin, GAD and IA-2 are associated with IDDM in mice and men. In NOD mice, the majority of T cells from insulitis specifically recognize the insulin B-chain peptide amino acid 9-22, in contrast to the periphery where the precursor frequency is much lower. It is important to note that these cells are diabetogenic. Surprisingly, the same insulin B-chain region contains epitopes recognized by protective T cells. In fact, autoimmune diabetes in NOD mice could be prevented by prophylactic treatment with this immunodominant T-cell epitope. In humans, however, no immunodominant regions of insulin have yet been defined. We have isolated and characterized a human insulin-specific T-cell clone that was derived from peripheral blood of a newly diagnosed IDDM patient. This patient displayed weakly positive primary T-cell responses to insulin. The peptide recognized by the clone was mapped to the insulin B chain (B:11-27). Functionally, the human insulin-specific CD4+ T cells displayed a Th1/0 like cytokine profile and were restricted by HLA-DR. The previously proposed alternative superantigen-like binding of insulin-B chain peptide outside of the peptide binding groove of HLA-DR could not be confirmed, since T-cell recognition was inhibited in competition experiments of insulin-B chain peptide with HLA-DR16 binding influenza peptide HA307-319. Our results indicate that human clonal T cells isolated from a recent onset IDDM patient recognize an epitope overlapping with the insulin B-chain region that is immunodominant and potentially therapeutic in NOD mice. This observation may be useful in studying the role of insulin-specific T cells in IDDM, and may eventually help to establish peptide-based immunotherapies in IDDM.

T cell epitopes of insulin defined in HLA-DR4 transgenic mice are derived from preproinsulin and proinsulin

Approximately one-half of Caucasians with newly diagnosed insulin-dependent diabetes mellitus (IDDM) have autoantibodies to insulin, and the majority of those express the HLA-DR4 genotype [Ziegler, R., Alper, C. A., Awdeh, Z. L., Castano, L., Brink, S. J., Soeldner, J. S., Jackson, R. A. & Eisenbarth, G. S. (1991) Diabetes 40, 709-714]. However, it has been difficult to demonstrate T cell proliferative responses to human insulin in IDDM patients [Durinovic-Bello, I., Hummel, M. & Ziegler, A. G. (1996) Diabetes 45, 795-800]. We have immunized transgenic mice expressing the susceptible HLA-DR (alpha1*0101,beta1*0401) (hereafter called DRB1*0401) and human CD4 molecules on a murine major histocompatibility complex class II null background, with human preproinsulin (PPI), proinsulin (PI), and insulin and derived large panels of T cell hybridomas to determine the immunogenic epitopes of these proteins. These results show that the prohormones PI or PPI carry the major immunogenic T cell epitope in the DRB1*0401 transgenic mice. The PPI/PI immunodominant epitope LALEGSLQK was localized at the C-peptide/A-chain junction. This T cell epitope PPI/PI LALEGSLQK is unusual because, normally, it is proteolytically destroyed during the maturation of the insulin molecule. Additionally, this T cell epitope is both processed and presented by human DRB1*0401-positive Epstein-Barr virus transformed B cells, and it can also stimulate T cells from the peripheral blood of HLA-DR4-positive patients with type 1 diabetes. These findings may partly explain why susceptibility to type 1 diabetes is associated with HLA-DR4-positive individuals and why T cell responses to the mature insulin protein are rarely detected in IDDM patients.

Islet cell antigens in the prediction and prevention of insulin-dependent diabetes mellitus

Insulin-dependent diabetes mellitus (IDDM) is associated with both antibody and T-cell autoimmunity to pancreatic islet cell components. In recent years, considerable progress has been made in the identification of the molecular components of the pancreatic islets to which these immune responses are directed. These advances have led to the development of a number of immune markers for use in screening for individuals at risk for disease, and there is promise of antigen-specific immune intervention therapies to prevent diabetes in those identified as at risk. In this article, we review our current knowledge of autoantigens associated with IDDM and the implications this has on the prediction and prevention of the disease.

Disease-associated autoimmunity and prevention of insulin-dependent diabetes mellitus

Insulin-dependent diabetes mellitus (IDDM) is a chronic autoimmune disease with a subclinical prodromal period characterized by selective destruction of insulin-producing beta cells in the pancreatic islets. This process is assumed to be T-cell mediated, but the emergence of disease-associated autoantibodies into the peripheral circulation is usually the first noticeable sign of beta-cell autoimmunity in human IDDM. Recent observations have suggested that beta-cell autoimmunity may be induced in any individual at any time. There are also data indicating that such autoimmunity may have been initiated prenatally in some individuals. Only a proportion of those with signs of islet cell autoimmunity progress to clinical disease, and harmless beta-cell autoimmunity reflected by positivity for a single autoantibody specificity seems to appear without any relation to genetic IDDM susceptibility. One can hypothesize that in most subjects HLA-conferred protection against IDDM prevents the beta-cell process from progressing to a stage of destructive insulitis that may lead to clinical disease. Environmental factors may trigger initial beta-cell damage and subsequently accelerate the destructive process. Non-HLA genes may also be involved in the regulation of the progression rate. Prospective observations of prediabetic individuals have revealed that IDDM-associated autoantibodies tend to appear sequentially, and that those who progress to clinical disease mount a strong humoral immune response to most known disease-associated antigens. This indicates that the immune response associated with beta-cell destruction is not purely T-helper 1 biased. Antigen-specific immunotherapy may in the future offer effective measures to intervene in preclinical IDDM to prevent end-stage insulitis. Substantially more data have to be generated, however, on the mechanisms, efficacy and safety of such therapy before it is possible to judge its clinical applicability.

Identification of naturally processed T cell epitopes from glutamic acid decarboxylase presented in the context of HLA-DR alleles by T lymphocytes of recent onset IDDM patients

Glutamic acid decarboxylase (GAD) has been defined as a major target antigen in insulin-dependent diabetes mellitus (IDDM). To identify the molecular ligands triggering a T cell response to GAD, a panel of human GAD65-specific T lymphocyte lines was generated from peripheral blood of three recent onset IDDM patients. All lines derived from a patient expressing the high-risk-conferring HLA-DR*0301/ *0401 haplotypes recognized a single epitope localized between amino acid positions 270 and 283 of GAD65, a stretch that is located in close proximity to the homology region shared with Coxsackie virus P2-C protein. All lines with this specificity were restricted to the DRA, B1*0401 product of the DR4 haplotype. Analysis of the GAD-specific T cell response in a second patient homozygous for DR4 haplotypes demonstrated that the same DRA, B1*0401 allele selected T cells specific for a different determinant. The T cell response profile in a third patient showed that DR*1501/ *1601-encoding haplotypes could present at least three different epitopes to GAD65-specific T lymphocytes. One of these epitopes was presented by a DR allele associated with the resistance-conferring DRB1*1501 haplotype. GAD-specific T cell lines could not be isolated from HLA class II-matched normal individuals. Our data reveal that (a) the T cell response to GAD65 is quite heterogenous in recent onset IDDM patients; (b) HLA-DR, not DQ, seems to be the principal restriction element used by T cells present at the onset of the disease; and (c) T cells responding to epitopes containing identical sequences to Coxsackie virus P2-C protein were not detected.