Multiple fragments of human TG are capable of inducing oral tolerance to whole human TG.

Oral tolerance is the mechanism by which the immune system remains unresponsive to orally administered soluble antigens. Mice immunized with human TG (hTG), resulting in the induction of experimental autoimmune thyroiditis (EAT), provide an ideal in vivo system in which to examine oral tolerance to hTG. In the present study, we characterize epitopes of hTG that are capable of inducing oral tolerance. hTG is a large homodimeric protein, 660 Kd. The limited proteolysis of hTG using trypsin (TR) generates several smaller fragments of hTG ranging in size from 29 Kd to 145 Kd. Using hTG fragments h1TR (residues 1-521), h4bisTR (residues 2513-2713), h6TR (residues 522-1626), and h7TR (residues 1627-2512), prepared from both iodine rich and iodine poor hTG, we investigated the ability of these fragments to induce oral tolerance. The oral administration of iodine rich h6TR or h7TR suppresses hTG specific immune responses in a manner similar to whole hTG. In contrast, the oral administration of iodine rich h1TR or h4bisTR exacerbates hTG specific immune responses. Unlike iodine rich h1TR or h4bisTR, the oral administration of iodine poor h1TR or h4bisTR fails to augment hTG specific immune responses. In fact, h4bisTR suppresses hTG specific immune responses. These results indicate that hTG contains multiple epitopes that differentially affect oral tolerization. Tolerogenic epitopes reside within fragments h6TR and h7TR. The removal of iodine, and presumably hormone, from h4bisTR converts an immunogenic epitope to a tolerogenic epitope.

Relation of three polymorphisms of the CTLA-4 gene in patients with Graves' disease.

Graves' disease is an autoimmune disease believed to be caused by a combination of environmental and genetic factors. One of the candidate genes is CTLA-4, a negative regulator of T cell activation. Three polymorphisms of the gene have been described, in the promoter at position -318, at position 49 in exon 1, and an (AT)n repeat within the 3'-untranslated region of exon 4. Many studies describe the association between a polymorphism of the CTLA-4 gene and autoimmune disease. To investigate the association of these CTLA-4 gene polymorphisms with each other, we analyzed the combined frequencies of each polymorphism and calculated the disequilibrium coefficients. We studied DNA samples from 120 Graves' disease (GD) patients and 80 healthy donors (NC). The exon 1 position 49 A/G polymorphism and promoter polymorphism at position -318, were typed using a PCR-restriction fragment length polymorphism method (PCR-RFLP). The polymorphic (AT)n repeat in exon 4 was determined by PCR amplification of genomic DNA, resolution of the amplified products on sequencing gels, and detection by autoradiography. There was a significant difference between GD and NC patients and occurrence of the polymorphism in exon 1 and exon 3, but not for the polymorphism in the promoter region. Furthermore, we found that the genotype with both the G allele in exon 1 and the 106 bp allele of the AT repeat in exon 4 occurred with much higher frequency in GD than NC (p<0.01), and that these polymorphisms are in linkage disequilibrium with each other. These results support the concept that CTLA-4 plays a critical role in the autoimmune process in GD, and that GD depends on multiple genetic susceptibility factors. Because the exon 1 and exon 4 polymorphisms are in strong linkage disequilibrium. It is not possible at this time to determine their unique relation to CTLA-4 function. Studies relating each polymorphism to CTLA4 function are required to determine whether one, or both, polymorphism(s) promote autoimmune disease.

Characterization of the T lymphocyte subsets and lymphoid populations involved in the induction of low-dose oral tolerance to human thyroglobulin.

Using mice deficient in CD8alpha, TCRdelta, CD4, or CD120a, as well as adoptive transfer experiments in wild-type and RAG-1-deficient mice, we characterized the T lymphocyte subsets and lymphoid populations involved in the induction of low-dose oral tolerance to human thyroglobulin (hTg). The oral administration of hTg, but not the intraperitoneal (ip) administration of hTg, generates lymphocytes that can transfer tolerance. Purified CD8alpha+ lymphocytes successfully transfer tolerance, while the depletion of CD8alpha or TCRdelta lymphocytes prevents the transfer of tolerance. Oral tolerance can be induced in CD4-deficient mice and RAG-1-deficient mice reconstituted with cells from CD120a-deficient mice, but not in CD8alpha-, TCRdelta, or CD120a-deficient mice. These findings indicate that CD8alpha and TCRdelta T lymphocytes are necessary for the oral induction and transfer of tolerance to hTg. Additionally, functional Peyer's patches are necessary for the induction of low-dose oral tolerance to hTg.

CTLA-4 gene polymorphism at position 49 in exon 1 reduces the inhibitory function of CTLA-4 and contributes to the pathogenesis of Graves' disease.

Activation of T cells requires at least two signals transduced by the Ag-specific TCR and a costimulatory ligand such as CD28. CTLA-4, expressed on activated T cells, binds to B7 present on APCs and functions as a negative regulator of T cell activation. Our laboratory previously reported the association of Graves' disease (GD) with a specific CTLA-4 gene polymorphism. In theory, reduced expression or function of CTLA-4 might augment autoimmunity. In the present study, we categorized autoimmune thyroid disease patients and normal controls (NC) by genotyping a CTLA-4 exon 1 polymorphism and investigated the function of CTLA-4 in all subjects. PBMCs and DNA were prepared from GD (n = 45), Hashimoto's thyroiditis (HT) (n = 18), and NC (n = 43). There were more GD patients with the G/G or A/G alleles (82.2% vs 65.1% in NC), and significantly fewer patients with the A/A allele (17.8% vs 34.9% in NC). In the presence of soluble blocking anti-human CTLA-4 mAb, T cell proliferation following incubation with allogeneic EBV-transformed B cells was augmented in a dose-dependent manner. Augmentation induced by CTLA-4 mAb was similar in GD and NC (GD, HT, NC = 156%, 164%, 175%, respectively). We related CTLA-4 polymorphism to mAb augmentation of T cell proliferation in each subgroup (GD, HT, NC). Although PBMC from individuals with the G/G alleles showed 132% augmentation, those with the A/A alleles showed 193% augmentation (p = 0.019). CTLA-4 polymorphism affects the inhibitory function of CTLA-4. The G allele is associated with reduced control of T cell proliferation and thus contributes to the pathogenesis of GD and presumably of other autoimmune diseases.