Activation of cytotoxic T cells and effector cells in experimental autoimmune thyroiditis by shared determinants of mouse and human thyroglobulins

Experimental autoimmune thyroiditis in the mouse

Experimental autoimmune thyroiditis (EAT) in mice is an excellent model for Hashimoto's thyroiditis (HT). It is induced with thyroglobulin (Tg), a known thyroid autoantigen that is common to both mouse and human and for which several conserved, thyroiditogenic epitopes have been identified. This unit describes induction and evaluation of EAT using thyroid histology and in vitro proliferative response assays. An ELISA is presented to detect the level of antibody to mouse thyroglobulin (MTg). To induce EAT, either bacterial lipopolysaccharide (LPS) or supplemented complete Freund's adjuvant (CFA) can be used as adjuvant. A support protocol for preparing MTg is included. The T cell proliferation assay can be used to examine the antigenicity of synthetic peptides derived from MTg or heterologous Tg. EAT can be adoptively transferred utilizing cells that have been expanded in vitro, as described. A protocol is provided for inducing tolerance using deaggregated MTg; induction of tolerance requires larger amounts of MTg but efficiently suppresses EAT development. Also included is a protocol to demonstrate the role of regulatory T cells in mediating tolerance. A protocol to delineate HLA association with HT is illustrated using HLA class II transgenic mice.

By-stander activation in autoimmune thyroiditis: Studies on experimental autoimmune thyroiditis in the GFP+ fluorescent mouse

We have taken advantage of GFP+ fluorescent protein (GFP) tagged lymphocytes to examine by-stander activity in experimental autoimmune thyroiditis in the mouse. To generate GFP-positive EAT-susceptible CBA/J mice (H-2k) (GFP-CBA/J mice), we backcrossed CBA/J (H-2k) with heterozygous GFP+ transgenic mice (C57Bl/6; H-2b). I-Ak and GFP expression on peripheral lymphocytes was used to select the resulting progeny up to the N7 generation. Mixed lymphocyte reactions using spleen cells from N7 GFP-CBA/J mice showed negative responses to spleen cells from CBA/J confirming the inbreeding and with marked reactivity to cells from C57BL/6. Immunization with human thyroglobulin (hTg) in GFP-CBA/J mice induced thyroiditis in 50% of the animals and high titers of Tg antibodies in all the animals. In addition, priming of GFP+ spleen cells in vitro with hTg induced a marked proliferative response (mean stimulation index = 24.7), These proliferating spleen cells were then transferred to CBA/J recipients. Fourteen days after transferring 30 x 10(6) Tg-primed GFP+ spleen cells into irradiated (500 rad) normal syngeneic hosts, a GFP+ lymphocytic infiltration was seen within their thyroid glands along with a GFP- lymphocytic infiltration arising from the host. This suggested that the hTg-specific transferred cells had initiated by-stander activation of naive host lymphocytes. This model of bystander cell detection confirmed that such an effect occurs in EAT and adds weight to the importance of this phenomenon in the initiation of autoimmune thyroid disease.

Superiority of thyroid peroxidase DNA over protein immunization in replicating human thyroid autoimmunity in HLA-DRB1*0301 (DR3) transgenic mice

Murine experimental autoimmune thyroiditis (EAT), characterized by thyroid destruction after immunization with thyroglobulin (Tg), has long been a useful model of organ-specific autoimmune disease. More recently, porcine thyroid peroxidase (pTPO) has also been shown to induce thyroiditis, but these results have not been confirmed. When (C57BL/6 x CBA)F(1) mice, recently shown to be susceptible to mouse TPO-induced EAT, were immunized with plasmid DNA to human TPO (hTPO) and cytokines IL-12 or GM-CSF, significant antibody (Ab) titres were generated, but minimal thyroiditis was detected in one mouse only from the TPO + GM-CSF immunized group. However, after TPO DNA immunization of HLA-DR3 transgenic class II-deficient NOD mice, thyroiditis was present in 23% of mice injected with TPO + IL-12 or GM-CSF. We also used another marker for assessing the closeness of the model to human thyroid autoimmunity by examining the epitope profile of the anti-TPO Abs to immunodominant determinants on TPO. Remarkably, the majority of the anti-TPO Abs was directed to immunodominant regions A and B, demonstrating the close replication of the model to human autoimmunity. TPO protein immunizations of HLA-DR3 transgenic mice with recombinant hTPO did not result in thyroiditis, nor did immunization of other mice expressing HLA class II transgenes HLA-DR4 or HLA-DQ8, with differential susceptibility to Tg-induced EAT. Moreover, our efforts to duplicate exactly the experimental procedures used with pTPO also failed to induce thyroiditis. The success of hTPO plasmid DNA immunization of DR3(+) mice, similar to our reports on Tg-induced thyroiditis and thyrotropin receptor DNA-induced Graves' hyperthyroidism, underscores the importance of DR3 genes for all three major thyroid antigens, and provides another humanized model to study autoimmune thyroid disease.

Thyroglobulin as an autoantigen: what can we learn about immunopathogenicity from the correlation of antigenic properties with protein structure?

Autoantibodies against human thyroglobulin are a hallmark of autoimmune thyroid disease in humans, and are often found in normal subjects. Their pathogenic significance is debated. Several B-cell epitope-bearing peptides have been identified in thyroglobulin. They are generally located away from the cysteine-rich regions of tandem sequence repetition. It is possible that our current epitopic map is incomplete because of the difficulty that proteolytic and recombinant approaches have in restituting conformational epitopes based upon proper pairing between numerous cysteinyl residues. Furthermore, the homology of cysteine-rich repeats with a motif occurring in several proteins, endowed with antiprotease activity, suggests that these regions may normally escape processing and presentation to the immune system, and brings attention to the mechanisms, such as oxidative cleavage, by which such cryptic epitopes may be exposed. A number of T-cell epitope-bearing peptides, endowed with thyroiditogenic power in susceptible mice, were also identified. None of them was dominant, as none was able to prime in vivo lymph node cells that would proliferate or transfer autoimmune thyroiditis to syngeneic hosts, upon stimulation with intact thyroglobulin in vitro. More than half of them are located within the acetylcholinesterase-homologous domain of thyroglobulin, and overlap B-cell epitopes associated with autoimmune thyroid disease, while the others are located within cysteine-rich repeats. The immunopathogenic, non-dominant character of these epitopes also favours the view that the development of autoimmune thyroid disease may involve the unmasking of cryptic epitopes, whose exposure may cause the breaking of peripheral tolerance to thyroglobulin. Further research in this direction seems warranted.

Thyroid-specific expression of IFN-gamma limits experimental autoimmune thyroiditis by suppressing lymphocyte activation in cervical lymph nodes

The role of IFN-gamma in the pathogenesis of autoimmune disease is controversial, being described as immunostimulatory in some studies and immunosuppressive in others. To determine the contribution of local expression of IFN-gamma, we derived NOD.H-2(h4) transgenic mice overexpressing IFN-gamma in a thyroid-restricted manner. Transgenic mice, which had serum IFN-gamma levels similar to wild-type littermates, showed up-regulation of MHC class II on thyrocytes, but did not develop spontaneous thyroiditis. Upon immunization with murine thyroglobulin, transgenic mice developed milder disease and reduced IgG1 responses compared with wild type. The milder disease was associated with decreased frequency of activated CD44(+) lymphocytes in the cervical lymph nodes. This suppressive effect was confirmed by showing that blockade of systemic IFN-gamma with mAb enhanced disease and increased IgG1 responses. The study supports a disease-limiting role of IFN-gamma in autoimmune thyroiditis. Furthermore, it provides the first evidence that local IFN-gamma activity in the thyroid is sufficient for disease suppression.

Coexpression of susceptible and resistant HLA class II transgenes in murine experimental autoimmune thyroiditis: DQ8 molecules downregulate DR3-mediated thyroiditis

Experimental autoimmune thyroiditis (EAT) can be induced in genetically susceptible mice by immunization with the self antigen, thyroglobulin (Tg). Since susceptibility is linked to H2 class II molecules, we have generated human leukocyte antigen (HLA) class II transgenic mice to study potential HLA associations with Hashimoto's thyroiditis. DR3 (HLA-DRA/DRB1*0301) and DQ8 (HLA-DQA1*0301/DQB1*0302) transgenes were introduced into class II-negative Ab(0)/B10 and Ab(0) nonobese diabetic (Ab(0)/NOD) mice. Previous work had shown that DR3 transgenic mice were susceptible to both mouse Tg and human Tg-induced EAT, whereas DQ8 transgenic mice were moderately susceptible only to human Tg induction. In this report, we examined the effect of DQ8 transgene on mouse Tg- and human Tg-induced EAT in double transgenic DR3/DQ8 mice. After mouse Tg induction, thyroiditis in DR3(+)DQ8(+) Ab(0)/B10 mice was significantly less severe than in DR3(+) mice but more severe than in DQ8(+) mice. No difference in thyroiditis was observed between DR3(+) and DR3(+)DQ8(+) mice in another background strain, Ab(0)/NOD. However, after immunization with human Tg, DQ8 coexpression downregulated thyroiditis severity, compared to DR3(+) mice, whereas thyroiditis was more extensive than in DQ8(+) mice. Thus, depending on the background strain and the Tg used to induce disease, the presence of the DQ8 transgene can reduce thyroiditis mediated by DR3 molecules.

Participation of Vbeta13(+) and Vbeta1(+) T cells in transfer thyroiditis after activation of mouse thyroglobulin-primed T cells by superantigen staphylococcal enterotoxin A

Murine experimental autoimmune thyroiditis (EAT) is a T-cell-mediated disease, but the T cell receptor (TCR) Vbeta gene usage in pathogenesis has not been well delineated. One approach is to utilize bacterial superantigens, such as staphylococcal enterotoxin (SE) A and B, to stimulate known sets of TCR Vbeta families in mouse thyroglobulin (mTg)-primed cells for thyroiditis transfer. Our previous use of SEB to activate mTg-primed cells led to no thyroiditis transfer, despite a major increase in Vbeta8(+) T cells. Unlike SEB, SEA activation did transfer thyroiditis. To determine which thyroiditogenic Vbeta(+) T cells were involved, SEA-activated T cells have now been analyzed. After repeated SEA activation in vitro, both mTg-reactive and thyroiditogenic cells persisted. FACS analysis indicated that most Vbeta13(+) cells were "large" cells (IL-2R(+)) and expressed the activation marker, transferrin receptor (CD71). RT-PCR analysis also showed the presence of both Vbeta13(+) and SEA-reactive Vbeta1(+) cells. Since our previous analyses by RT-PCR of the thyroid infiltrate after either induction or adoptive transfer have implicated both Vbeta13(+) and Vbeta1(+) cells, their activation by SEA to transfer thyroiditis further supports their role.

Characterization of a novel H2A(-)E+ transgenic model susceptible to heterologous but not self thyroglobulin in autoimmune thyroiditis: thyroiditis transfer with Vbeta8+ T cells

Recently we reported on a novel H2E transgenic, IA-negative model of experimental autoimmune thyroiditis (EAT) that excludes reactivity to self in its susceptibility pattern to heterologous thyroglobulin (Tg). In conventional, susceptible mouse strains, EAT is inducible with both homologous and heterologous Tg; e.g., human (h)Tg shares conserved thyroiditogenic epitopes with mouse (m)Tg. However, when an H2Ea(k) transgene is introduced into class II-negative B10.Ab(0) mice, which express neither surface IA (mutant Abeta-chain) nor surface IE (nonfunctional Ea gene), the resultant H2E(b) molecules are permissive for EAT induction by hTg, but not self mTg. Also, the hTg-primed cells do not cross-react with mTg. To explore this unique capacity of E+B10.Ab(0) mice to distinguish self from nonself Tg, we have developed T cell lines to examine the T cell receptor repertoire and observed a consistent Vbeta8+ component after repeated hTg stimulation. Enrichment and activation of Vbeta8+ T cells by either superantigen staphylococcal entertoxin B or anti-Vbeta8 in vitro enabled thyroiditis transfer to untreated A-E+ recipients, similar to hTg activation. Vbeta8+ T cells isolated by FACS from hTg-immunized mice also proliferated to hTg in vitro. These studies support the contribution of Vbeta8 genes to the pathogenicity of hTg in this H2A-E+ transgenic model.

Flexibility of TCR repertoire and permissiveness of HLA-DR3 molecules in experimental autoimmune thyroiditis in nonobese diabetic mice

Experimental autoimmune thyroiditis (EAT) is inducible in genetically susceptible mice by immunization with mouse thyroglobulin (mTg). With susceptibility linked to MHC class II, EAT is useful in studying human leukocyte antigen (HLA) associations with Hashimoto's thyroiditis. In non-obese diabetic (NOD) mice, approximately 10% thyroiditis incidence occurs with aging. This potential was exploited to examine the T cell repertoire and HLA association in EAT. Similar to B10.K-Vbeta(c)mice with TCRBV genes reduced by approximately 70%, mTg-immunized NOD-Vbeta(c)mice developed thyroiditis comparable to controls, indicating plasticity of the TCR repertoire for pathogenic epitopes. HLA association was evaluated by introducing HLA-DRA/DRB1*0301 (DR3) transgene into class II-negative NOD mice (Ab(0)/NOD). Previously, this HLA-DR3 transgene rendered EAT-resistant B10.M and Ab(0)mice susceptible to both mTg- and hTg-induced EAT. These results are now confirmed. mTg-induced thyroiditis in DR3+ Ab(0)/NOD mice was comparable to that in NOD and DR3- NOD mice, and the proliferative response was stronger. By comparison, NOD mice were only moderately susceptible to hTg-induced EAT. However, thyroiditis was more severe in DR3+ Ab(0)/NOD than in DR3- NOD mice, with no difference in proliferative response to hTg harbouring heterologous epitopes. The confirmed permissiveness of HLA-DR3 molecules on an NOD background for EAT induction by both mTg and hTg supports the importance of this class II gene implicated in some patient studies.

Newer insights into the pathogenesis of experimental autoimmune thyroiditis

Experimental autoimmune thyroiditis (EAT), produced in the mouse by immunization with murine thyroglobulin plus complete Freund's adjuvant, represents a valuable model for studying the pathogenesis of human chronic (Hashimoto's) thyroiditis. A major issue requiring clarification is the difference between benign autoimmunity, characterized solely by production of autoantibodies to thyroglobulin, and pathogenic autoimmunity where injury occurs to the thyroid cells. In this article, we describe the role of two key cytokines, IL12 and IFNgamma, in modifying the pathogenic immune response. EAT, defined by cellular infiltration of the thyroid and the development of thyroglobulin-specific autoantibodies, is a dynamic process. Consequently, a cytokine may exert a different effect at different times during the disease process. For purposes of discussion, we propose that there are three stages in the development of EAT: priming; initiation; and progression. Administration of anti-IL12 during the priming stage and initiation dramatically decreases disease and lowers autoantibody levels. In contrast, injection of recombinant IL12 after disease was established significantly decreases the severity of disease and reduces autoantibody levels. Unlike IL-12, IFNgamma was not essential for the priming of EAT. However, the severity of disease in the anti-IFNgamma-treated initiation- and progression-treated animals was higher than in controls, implying a regulatory role for IFNgamma. These findings emphasize that EAT involves a complex array of pathogenic mechanisms. The balance of cytokines produced during the early phase of the autoimmune reaction probably determines the progression from a harmless autoimmune response to autoimmune disease.

Flexibility of the thyroiditogenic T cell repertoire for murine autoimmune thyroiditis in CD8-deficient (beta2m -/-) and T cell receptor Vbeta(c) congenic mice

In murine experimental autoimmune thyroiditis (EAT), previous studies have revealed a highly adaptable thyroiditogenic T cell repertoire which involves both CD4+ and CD8+ T cells in the susceptible H2k strain. To further test this flexibility, congenic B10.K mice lacking CD8+ T cells (B2m -/-) or harboring 70% T cell receptor (TCR) Vbeta gene deletions (Vbeta(c)) were immunized with mouse thyroglobulin (MTg) and evaluated for EAT 28 days later. All B2m -/- mice developed moderate antibodies to MTg, and thyroidal inflammation was comparable to B10.K mice, averaging 35-40%. Spleen cells (SC) from MTg-immunized mice were then injected into syngeneic recipients after stimulation in vitro with MTg or with conserved, thyroxine (T4)- or thyronine (T0)- containing 12mer peptides, hT4(5), hT0(2553), or hT4(2553), derived from the primary hormonogenic sites at position 5 or 2553 of human Tg. As previously shown in another H2k strain (CBA/J), all three peptides activated MTg-primed SC to transfer EAT in B10.K mice. hT4(5) and hT4(2553) were further tested in B10.K-Vbeta(c) and beta2m- B10.K mice. Both peptides expanded thyroiditogenic T cells in either strain, resulting in severe thyroiditis in syngeneic recipients. That EAT can develop in the absence of CD8+ T cells or in the presence of a severely restricted TCR repertoire underscores the remarkable flexibility of the thyroiditogenic T cell profile in the susceptible k haplotype.

Thyroglobulin peptides of specific primary hormonogenic sites can generate cytotoxic T cells and serve as target autoantigens in experimental autoimmune thyroiditis

Previously we demonstrated that thyroxine (T4)-containing, 12-mer peptides from positions 5 (1-12) and 2553 (2549-2560), as well as thyronine (T0)-substituted 2553 peptide, derived from human (H) thyroglobulin (Tg) are capable of activating T cells that infiltrate the thyroid (thyroiditogenic). In contrast, peptides T4(2567) and T0(2567) (2559-2570) are not. To determine if these thyroiditogenic peptides, T4(5), T4(2553), and T0(2553), activated cytotoxic T cells (Tc) and served as target autoantigens when loaded onto indicator cells (BW5147 lymphoma, H2k), lymph node cells from CBA mice immunized with mouse (M) Tg were cultured in vitro with MTg, HTg, or Tg peptide. After MTg or HTg activation, Tc were detected for both MTg- and HTg-loaded target cells in an 18-h, 51Cr-release assay at an effector:target cell ratio of 50:1. These Tc also killed target cells labeled with T4(5), T4(2553), or T0(2553), but not the control peptide T4(2567). When MTg-primed lymphocytes were cultured with T4(5), T4(2553), or T0(2553), specific Tc were also generated against target cells labeled with the respective peptide. The data suggest that one of the thyroiditogenic properties of these peptides previously shown by adoptive transfer of thyroiditis is related to the generation of Tc. In addition, these conserved autoepitopes of Tg also serve as target antigens for Tc.

Primary hormonogenic sites as conserved autoepitopes on thyroglobulin in murine autoimmune thyroiditis: role of MHC class II

A few synthetic peptides corresponding to amino acid sequences on human thyroglobulin (Tg) have been reported to induce moderate thyroiditis or activate mouse Tg (MTg)-primed T cells to transfer thyroiditis in mice susceptible to experimental autoimmune thyroiditis. Using three pairs of 12-mer peptides (1-12, 2549-2560, 2559-2570), with thyroxine (T4) or noniodinated thyronine (T0) at the conserved, hormonogenic site 5, 2553, or 2567 respectively, we reported that iodination was not required for a Tg hormonogenic site to be a thyroiditogenic autoepitope. To determine the relative importance of MHC class II and T cell receptor (TCR) repertoire, we compared two EAT-susceptible k and s (CBA and A.SW) haplotypes and their respective MHC-identical strain (C57BR and SJL) with approximately 50% genomic deletion of TCR Vbeta genes. Whereas k and s strains develop MTg-induced EAT, vigorous immunization with peptides containing T4 or T0 at either 5 or 2553, but not at 2567, led to mild (10-20%) thyroiditis only in some mice of either k strain. TCR Vbeta gene differences played a minor role. T cell responses to all peptide pairs were quite similar in CBA and C57BR mice, and both hT0(2553) and hT4(2553) reciprocally primed and stimulated their T cells. In adoptive transfer, SJL mice were somewhat more responsive to peptide activation than A.SW but much weaker than k strains. By comparing T4- and T0-containing peptides in different haplotypes, we show further that antigenicity of conserved hormonogenic sites is intrinsic, dependent more on amino acid sequence and binding to appropriate class II molecules and less on TCR repertoire or iodination of T0.

Cloning and characterization of murine thyroglobulin cDNA

Thyroglobulin is used to induce in mice experimental autoimmune thyroiditis (EAT), a model for Hashimoto thyroiditis. Because murine thyroglobulin is a more potent inducer of EAT than heterologous thyroglobulins, it has been hypothesized that it contains unique pathogenic epitopes. The validation of this hypothesis has been hampered by the lack of the murine thyroglobulin sequence. To identify murine-specific areas in thyroglobulin, we cloned, by reverse transcriptase PCR, and sequenced the complete murine thyroglobulin cDNA. This encodes a polypeptide of 2748 amino acids that is 73.5 and 71.8% identical to bovine and human thyroglobulin, respectively. Six regions are unique to each species. We also analyzed through EpiMer the sequences able to bind to the I-Ek major histocompatibility allele and, therefore, function as T cell epitopes. EpiMer analysis showed seven murine-specific T cell epitopes in thyroglobulin. The availability of the complete murine thyroglobulin sequence should promote the understanding of the pathogenesis and immunoregulation of EAT.

Clinical significance of measurements of antithyroid antibodies in the diagnosis of Hashimoto's thyroiditis: comparison with histological findings

Measurements of antithyroglobulin and antimicrosomal (antiperoxidase) antibodies have been performed widely for the clinical diagnosis of autoimmune thyroid diseases. The present study was designed to compare these antibody titers with histological findings of the thyroid in patients with diffuse goiter who were suspected of having Hashimoto's thyroiditis. One hundred and ten euthyroid or hypothyroid patients (10 males and 100 females; age 48 +/- 15 (SD) years old) with diffuse goiter were studied for the measurement of antithyroglobulin and antimicrosomal or antiperoxidase antibodies by a hemagglutination technique (TGHA and MCHA, respectively) and by a newly developed radioassay (TgAb and TPOAb, respectively). The antibody titers were compared with the histological findings obtained by needle biopsy. TgAb, TPOAb, TGHA, and MCHA were detected in 80 (96.4%), 61 (73.5%), 37 (44.6%), and 54 (65.1%) of 83 patients with histologically proven Hashimoto's thyroiditis, respectively, but in only one (3.7%) of 27 patients without any inflammatory changes in the biopsy specimen. In 55 patients with negative TGHA and MCHA, the TgAb positivity was more closely associated with the histological diagnosis of Hashimoto's thyroiditis than the TPOAb positivity was, the incidence of each antibody in Hashimoto's thyroiditis being 89.7% (26/29) and 27.6% (8/29), respectively. In conclusion, the histological diagnosis of Hashimoto's thyroiditis can most precisely be predicted by the newly developed radioassay for TgAb.

Mouse thyroglobulin: conservation of sequence homology in C-terminal immunogenic regions of thyroglobulin

cDNA encoding 287 amino acids of the C-terminus of mouse thyroglobulin was cloned and sequenced. The amino acid homology between mouse and rat thyroglobulin was 96%, and was 78% between mouse and human. It was found that mouse thyroglobulin completely shared homology with two thyroiditogenic peptides described by other investigators. These findings are consistent with our hypothesis that in murine experimental thyroiditis, the primary thyroiditogenic epitopes are encoded by mouse-specific regions of thyroglobulin.

Depletion of CD4+ and CD8+ cells eliminates immunologic memory of thyroiditogenicity in murine experimental autoimmune thyroiditis

Experimental autoimmune thyroiditis (EAT) develops in genetically susceptible mice after immunization with mouse thyroglobulin (MTg), and is mediated by T cells, both CD4+ and CD8+, infiltrating the thyroid. Previous work showed that depletion of CD4+, but not CD8+, cells with rat monoclonal antibodies (mAbs) interfered with EAT induction. To test if concomitant CD4+ cell depletion and immunization led to EAT resistance, mice were reimmunized at an interval of 15 or 43 days after injection of CD4 mAbs. No resistance had been established; disease severity and anti-MTg titers were comparable to mice with primary immunization. Previous work also showed that treatment during advancing EAT with only CD4 mAbs on days 21, 25 led to long-lasting, reduced severity in EAT, whereas administration of CD8 mAbs alone reduced the smaller CD8+ subset only. However, therapy with both mAbs was most efficacious; > 50% of thyroids were purged of all cellular infiltrate after only two doses. Moreover, T cells emerging subsequent to depletion were not retained in the thyroid, despite ongoing antibody production. To test if nondepleting CD4 and CD8 mAbs were similarly effective for therapy, mAbs of the IgG2a isotype were administered during advancing EAT. No effect on thyroidal infiltration was observed, indicating that modulation of the CD4 and CD8 antigen without depletion was insufficient for efficacious therapy. To determine if combined therapy with depleting mAbs reestablished self tolerance, treated mice were reimmunized on days 70, 77, when T cell recovery was nearly complete. Thyroiditis was comparable to controls given primary immunization, despite high antibody levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Thyroglobulin-specific T cell line from a healthy individual does not produce proinflammatory cytokines on antigenic stimulation: an implication for possible fail-safe mechanism to avoid autoimmunity

In order to investigate the regulation of autoimmune response to thyroglobulin (Tg), one of the thyroid autoantigens, we established a Tg-specific T cell line by stimulation of peripheral blood mononuclear cells from a healthy volunteer with Tg and characterized its cytokine production pattern. The Tg-specific T cell line, designated DH5D1, obtained from a limiting dilution culture bore alpha beta T cell receptor and was CD4 and CD45RO positive. Upon stimulation with Tg, DH5D1 secreted little or no titers of IL-2, TNF-alpha, and IFN-gamma, whereas activation with combination of phorbol myristate acetate and calcium ionophore produced measurable levels of these cytokines. These results indicate that the Tg-specific T cell line is not defective in its capacity to produce proinflammatory cytokines and suggest that the inability of cytokine production by autoreactive T cells of healthy individuals is one fail-safe mechanism for preventing aggression of harmful autoimmune response.

A common T-cell epitope between human thyroglobulin and human thyroid peroxidase is related to murine experimental autoimmune thyroiditis

We have investigated functional common T-cell epitopes between human thyroglobulin (hTg) and human thyroid peroxidase (hTPO) in mice. Four hTg peptides, Tg-P1, Tg-P2, Tg-P3 and Tg-P4, in which 5 amino acid residues are identical to those of hTPO, and 1 hTPO peptide, TPO-P4 relevant to Tg-P4, were prepared. Among these peptides, only Tg-P4 (residues 2730-2743) and TPO-P4 (residues 118-131) were highly antigenic and both peptides shared the common T-cell epitope. In addition, when the spleen cells from mice immunized with mouse Tg (mTg) were restimulated in vitro by Tg-P4 or TPO-P4 as well as by mTg, these cells transferred thyroiditis to naive recipient mice. These findings indicate that this common T-cell epitope between hTg and hTPO is immunogenic and related to the development of murine experimental autoimmune thyroiditis.

Experimental autoimmune prostatitis (EAP): enhanced release of reactive oxygen intermediates (ROI) in peritoneal macrophages

The metabolic state of peritoneal macrophages is defined quantitatively for spontaneous ROI release and compared with those produced after cell contact with phorbol myristate acetate (PMA) or zymosan (OZ) particles. Peritoneal exudate cells (PEC) from EAP animals spontaneously released significantly more ROI than cells from controls rats, indicating that mononuclear phagocytes from autoimmune rats were more activated than populations cells arising from rats injected with BSA, with CFA or non-injected. These findings could indicate an in vivo activation state in PEC from autoimmune rats different from that obtained with heterologous antigens or CFA immunization procedures. The release of ROI induced after in vitro stimulus was, in general, higher in cells from autoimmune than in BSA or CFA treated rats. This differential responsiveness between the MAG, BSA and CFA injected macrophage populations could indicate that during the autoimmune process the autoantigen/s could amplify the inflammatory response triggered by them. Although release of oxygen metabolites represents only one of many potential mechanisms of tissue injury, this together with the lesions observed in the prostate gland indicate that oxygen radicals could be involved in this autoimmune disease.

Resistance to experimental autoimmune thyroiditis is correlated with the duration of raised thyroglobulin levels

We have used the mouse model of experimental autoimmune thyroiditis (EAT) to examine the hypothesis that the strengthening of self-tolerance to thyroglobulin by exogenous mouse thyroglobulin (MTg) or stimulation of endogenous MTg secretion by thyroid-stimulating hormone (TSH) is correlated with the length of time MTg rises above the normal range. Bacterial lipopolysaccharide (LPS) treatment increases the initial half-life of MTg from about 3 hr to about 5 hr, probably interfering with its clearance by the mononuclear phagocytic (reticuloendothelial) system. By pretreating mice with LPS, a subtolerogenic MTg dose is rendered tolerogenic. Similarly the effect of TSH infusion by osmotic minipumps, which stimulates MTg secretion and also strengthens tolerance to MTg, can be enhanced by injecting LPS shortly after pump implantation. The resulting increase in MTg level (due to delayed clearance of MTg) is greater than that from TSH alone and suppresses further the animals' susceptibility to disease induction by MTg and adjuvant. Moreover, resistance following pretreatment with LPS and subtolerogenic MTg is mediated by CD4+ suppressor T cells, as shown recently for the suppression in mice given high doses of tolerogenic MTg. These experiments are in full agreement with the hypothesis and confirm that small increases in circulating MTg concentrations, which could occur physiologically, can be effective in protecting against EAT induction.

A thyroxine-containing peptide can induce murine experimental autoimmune thyroiditis

A synthetic peptide based on a sequence containing thyroxine at position 2553 in thyroglobulin (Tg), and already shown to be recognized by two clonotypically distinct murine Tg autoreactive T cell hybridomas, can trigger primed lymph node cells to transfer thyroiditis to naive recipients. Donor lymph node cells could be prepared from mice immunized either with intact mouse Tg or with this peptide itself. After a second exposure to the priming antigen in vitro, both these populations induced 100% thyroiditis in recipient animals. The importance of the T4 residue in the development of disease was demonstrated by the failure of Tg tryptic peptides depleted of T4 to stimulate pathogenic effectors in vitro, even when the lymph node cells had been taken from mice primed with whole Tg. We conclude that this T4-containing 12mer sequence is a major thyroiditogenic epitope in CBA/J mice although we cannot exclude the possibility that there are other pathogenic epitopes present in the whole Tg molecule.

Suppression in murine experimental autoimmune thyroiditis: in vivo inhibition of CD4+ T cell-mediated resistance by a nondepleting rat CD4 monoclonal antibody

Genetically susceptible mice become resistant to experimental autoimmune thyroiditis (EAT) induction with mouse thyroglobulin (MTg) and lipopolysaccharide after pretreatment with deaggregated MTg (dMTg). Recent work showed this suppression to be mediated by CD4+ suppressor T cells (Ts). To study Ts action in vivo, we used a rat IgG2a monoclonal antibody (mAb), YTS 177.9, which modulates CD4 antigen in vivo without depleting CD4+ cells. Initial studies showed that after two 1-mg doses of mAb 7 days apart, extensive CD4 antigen modulation of peripheral blood leukocytes occurred within 4 days. Mice given CD4 mAb 24 hr before dMTg (2 doses, 7 days apart) were resistant to EAT induction when immunized with MTg and LPS 20 days later. Also, anti-rat IgG2a titers were reduced following challenge with heat-aggregated rat IgG2a compared to controls. Subsequent analysis of serum in CD4 mAb-treated animals revealed that mAb was present in the circulation for 14 days. Moreover, mice given CD4 mAb and dMTg, then challenged after only 10 days, when CD4 mAb was still circulating, developed a significantly higher incidence of thyroid damage than controls. These findings suggest that modulation of CD4 antigen does not interfere with Ts activation, but the presence of CD4 mAb, at the time of autoantigenic challenge, can interfere with tolerance to EAT induction. Thus, the direct relationship between the presence of CD4 mAb and inhibition of EAT suppression implicates a role for CD4 molecules in the mediation of suppression.

Synergism between mouse thyroglobulin- and vaccination-induced suppressor mechanisms in murine experimental autoimmune thyroiditis

Previous studies have shown that genetically susceptible mice can be rendered resistant to the induction of experimental autoimmune thyroiditis (EAT) by pretreatment with deaggregated mouse thyroglobulin (dMTg). This resistance is mediated by CD4+ suppressor T cells (Ts) which suppress the afferent/inductive phase of EAT. Recent work has also shown that resistance to EAT can be achieved by vaccination with irradiated spleen cells previously primed in vivo with MTg and cultured in vitro with MTg (gamma SC). The gamma SC-induced resistance also inhibits the afferent phase of EAT but is mediated by both CD4+ and CD8+ Ts. To determine if dMTg- and gamma SC-induced suppression can cooperate to prevent EAT, we pretreated mice with suboptimal doses of dMTg and gamma SC before challenge with MTg and adjuvant. Mice receiving dMTg or gamma SC only showed suppressed in vitro response to MTg, but the development of thyroid lesions was unaltered. However, mice given one or two subtolerogenic doses of dMTg followed by gamma SC not only showed suppressed in vitro response to MTg, but also little or no thyroiditis, indicating cooperation between these two mechanisms. The cooperation was not reciprocal since reversing the order, giving gamma SC first followed by dMTg, was not effective in suppressing EAT. Thus, suppressor mechanisms activated by pretreatment with dMTg and gamma SC can act synergistically to suppress EAT induction; the two mechanisms may cooperate in vivo to maintain self-tolerance provided that MTg-specific CD4+ Ts are initially activated.

In vivo evidence for CD4+ and CD8+ suppressor T cells in vaccination-induced suppression of murine experimental autoimmune thyroiditis

In several experimental autoimmune diseases, including experimental autoimmune thyroiditis (EAT), vaccination with attenuated autoantigen-specific T cells has provided protection against subsequent induction of disease. However, the mechanism(s) of vaccination-induced suppression remains to be clarified. Since we have previously shown that suppression generated by pretreatment with mouse thyroglobulin (MTg) or thyroid-stimulating hormone in EAT is mediated by CD4+, not CD8+, suppressor T cells, we examined the role of T cell subsets in vaccination-induced suppression of EAT. Mice were vaccinated with irradiated, MTg-primed, and MTg-activated spleen cells and then challenged. Pretreatment with these cells suppressed EAT induced by immunization with MTg and adjuvant, but not by adoptive transfer of thyroiditogenic cells, suggesting a mechanism of afferent suppression. The activation of suppressor mechanisms did not require CD8+ cells, since mice depleted of CD8+ cells before vaccination showed reduced EAT comparable to control vaccinated mice. Furthermore, depletion of either the CD4+ or the CD8+ subset after vaccination did not significantly abrogate suppression. However, suppression was eliminated by the depletion of both CD4+ and CD8+ cells in vaccinated mice. These results provide evidence for the cooperative effects of CD4+ and CD8+ T cells in vaccination-induced suppression of EAT.

Severe combined immunodeficient (SCID) mice: a model for investigating human thyroid autoantibody synthesis

We have studied the ability of lymphocytes from the blood, thyroid and lymph nodes of patients with autoimmune thyroid disease (AITD) to produce autoantibodies to thyroglobulin (Tg) and/or thyroid peroxidase (TPO) in SCID mice. Human IgG class Tg and/or TPO antibodies were detectable in plasma from SCID mice 7 days after transfer of 15-25 x 10(6) cells/mouse and the highest levels were recorded 2-3 weeks later. In contrast, Tg and/or TPO antibodies were undetectable in recipients of lymphocytes from thyroid antibody negative controls. AITD thyroid lymphocytes produced the most antibody in recipient mice and lower levels were observed in recipients of AITD blood and lymph node lymphocytes. The amounts of Tg and/or TPO antibody detected were in accordance with the ability of thyroid and lymph node lymphocytes to secrete these autoantibodies spontaneously in culture (indicating the presence of cells activated in the patient) and with the capacity of blood lymphocytes (probably B memory cells) to secrete Tg and/or TPO antibodies in culture in response to pokeweed mitogen. Tg antibodies in plasma from SCID recipients of thyroid lymphocytes were of subclasses IgG1, IgG2 and IgG4 and the proportions closely resembled those of the donor's serum Tg antibodies. Blood lymphocytes transferred to SCID recipients were also able to produce Tg antibodies of subclasses 1, 2 and 4 but the subclass distribution varied between mice and the reason for this is not clear at present. Since SCID mice provide an environment in which B lymphocytes from patients with AITD can be activated without mitogen to secrete thyroid antibodies, this model will provide a powerful system for elucidating the mechanisms regulating the secretion of human antibodies to Tg and TPO.

Thyroid-specific T cells in the normal Wistar rat. I. Characterization of lymph node T cell reactivity to syngeneic thyroid cells and thyroglobulin

Wistar rats are susceptible to the induction of experimental autoimmune thyroiditis (EAT) and recently a cloned Wistar thyroid epithelial cell line (WRT) has become available. In this study we have examined the in vitro proliferative response of Wistar rat lymphoid cells to the WRT cells as a model for better understanding thyroid cell-T cell interactions. Lymph node (LN) cells from normal Wistar rats showed an early and vigorous response to syngeneic thyroid cells (WRT). Further examination of the Wistar phenomenon revealed that unpurified lymphoid cells were also able to mount a proliferative response to rat thyroglobulin. The Wistar LN cell response to WRT cells consisted of T cell proliferation that was both MHC class I and class II restricted. There was a greater proliferation of CD8+ than CD4+ T cells, but WRT-stimulated lymphoblast cells were not cytotoxic to 51Cr-labeled WRT cell targets. These data suggest that normal Wistar rats have circulating thyroid-specific T cells that may be related to their known susceptibility to EAT. Furthermore, the interaction between such thyroid-specific T cells and cloned syngeneic thyroid cells offers a unique model for the further investigation of thyroid-immune interactions and the escape from tolerance induction.

Histological and functional changes in the thyroid glands of mice implanted with hybridomas secreting monoclonal autoantibody against mouse thyroglobulin

Mouse hybridoma cells secreting monoclonal antibody (mAb) against mouse thyroglobulin were established. The implantation of the hybridomas succeeded to induce high titers of circulating mAb against thyroglobulin in sera of mice. By using the implantation of the hybridomas in mice, the effect of autoantibody on the thyroid glands was studied histologically and functionally. In these mice the thyroid follicles were significantly swollen and warped, whereas there was no infiltration of inflammatory cells. The 125I-uptake in their thyroid glands was markedly decreased. There were no functional changes in control mice implanted with non-secreting P3U1 partner cells. Therefore, it was suggested that high titers of anti-thyroglobulin autoantibody could definitely cause the histological and functional damages in the thyroid glands.

Activation of cytotoxic cells by syngeneic prostate antigens in experimental autoimmune vesiculo-prostatitis

In our experimental model of autoimmune vesiculo-prostatitis, obtained by immunization with syngeneic male accessory glands (MAG) and complete Freund's adjuvant, the presence of specific autoreactive cells with cytotoxic activity against prostate antigens was studied. The specific cytotoxicity generated in MAG immunized rats was tested using 51Cr labelled syngeneic prostate cells or labelled chicken erythrocytes coated with specific antigens (MAG homogenate or chromatographic fractions from prostate homogenate) which were used as target cells in a medium free of complement. The addition of spleen sensitized cells to prostate cells suspension produced a significant release of 51Cr in regard to normal effector cells (11.87 +/- SE 1.12 versus 1.5 +/- 0.75). Similar results were obtained when MAG-coated erythrocytes were used as target cells (10.87 +/- SE 0.62 versus 1.50 +/- 0.25). Depletion of T but no B or adherent-cells was shown to abolish the lytic effect indicating that MAG immunization provides determinants which are recognized by sensitized T-cells on cells of the prostate gland where the most severe tissue alterations were previously observed. Erythrocytes coated with chromatographic fractions obtained from prostate homogenate were used to identify the antigens triggering the lytic effect. It was demonstrated that two fractions (FI and FII) functioned as in vivo sensitizing antigens as well as in vitro activating antigens for themselves. The restimulation in vitro of sensitized cells with purified prostate fractions induces an additional lytic effect suggesting that an expansion of effector cells may take place after contacting the antigens at the prostate site.(ABSTRACT TRUNCATED AT 250 WORDS)

The frequency of LPS-responsive B cells to autologous and heterologous thyroglobulin

The frequency of precursors within the mouse splenic B cell pool, reactive with mouse thyroglobulin (mTg) was estimated using a limiting dilution assay system. The mean frequency was found to be 1/3900 B cells. The results provide a minimal estimate of the frequency of mTg-reactive B cells. The frequency of mTg-reactive B cells was not influenced by the MHC locus, as both high- and low-responder strains showed similar frequencies. While the frequency of B cells reactive to human Tg was found to be similar to that reactive to mTg, only 20% of the mTg-reactive clones also cross-react with human Tg. Similarly, only 30% of huTg reactive clones were found to react with mTg. Therefore, a large proportion of Tg-reactive antibodies are restricted to self-determinants and not determinants to conserved regions of the Tg molecule.

Immunogenetic aspects of human thyroglobulin-reactive T cell lines and hybridomas

The in vitro proliferative response to T cells primed with human thyroglobulin (Tg) was compared in 11 independent haplotypes on B10 background. B10.K and B10.S mice were the most responsive, whereas, with the exception of B10.PL (H-2u), all other B10 congenics were intermediate responders. The two best responders to in vitro challenge with human Tg, of the k and s haplotype, are the same as those showing H-2-linked susceptibility to induction of experimental autoimmune thyroiditis (EAT) with mouse Tg. Since shared epitopes on human and mouse Tgs have been shown to be thyroiditogenic by adoptive transfer studies in CBA (H2k) mice, the findings indicate that shared epitopes may be studied in appropriate (i.e. EAT-susceptible) strains of mice. Therefore, we proceeded to develop methods to produce T-cell lines and hybridomas to human Tg in B10.K and B10.S mice, test their cross-reactivity to heterologous Tgs and their Ia restriction patterns. By using antigen-presenting cells from recombinant strains, we identified restriction elements encoded by the I-A subregion alone and a combinatorial molecule from the I-A/I-E subregions.

Suppression in experimental autoimmune thyroiditis: the role of unique and shared determinants on mouse thyroglobulin in self-tolerance

Previous studies have shown that T cells from mice genetically susceptible to experimental autoimmune thyroiditis (EAT) recognize determinants shared between mouse thyroglobulin (Tg) and heterologous Tgs. Some shared determinants are thyroiditogenic; lymphocytes from mice immunized with mouse Tg (MTg) or human Tg (HTg) and reciprocally restimulated in vitro with either Tg can transfer EAT. Studies on the mechanisms of self-tolerance have shown that pretreatment with soluble MTg suppresses in vitro proliferation to MTg and EAT induction with MTg. To determine the role of share epitopes in maintaining tolerance, mice were pretreated with soluble HTg and immunized with HTg or MTg and adjuvant. Cells from HTg-pretreated. HTg-immunized mice showed suppressed in vitro proliferative response to HTg. Following MTg immunization, the cells showed suppressed in vitro response to MTg. However, in contrast to MTg pretreatment, the subsequent development of EAT in vivo was unaltered in severity following HTg pretreatment. Thus, determinants shared between HTg and MTg can induce suppression of in vitro responses to HTg and MTg, but not inhibit the onset of thyroiditis, suggesting that T cells recognizing MTg-unique epitopes expanded to mediate thyroiditis. We conclude that recognition of both unique epitopes expanded to mediate thyroiditis. We conclude that recognition of both unique and shared epitopes on MTg are essential for the overall maintenance of self-tolerance.

In situ analysis of T cell subset composition in experimental autoimmune thyroiditis after adoptive transfer of activated spleen cells

T cells from genetically susceptible mice developing experimental autoimmune thyroiditis (EAT) proliferate in response to restimulation with mouse thyroglobulin (MTg) in vitro. The in vitro-activated cells adoptively transfer EAT as well as differentiate into cells cytotoxic for syngeneic thyroid monolayers. To examine the kinetics of T cell subset infiltration and distribution in situ after adoptive transfer, we applied the avidin-biotin-peroxidase labeling technique to thyroid sections, utilizing rat monoclonal antibodies followed by a biotinylated rabbit anti-rat antibody. Female CBA donor mice were immunized with MTg and lipopolysaccharide. Their spleen cells were obtained 7 days later, cultured with MTg, and transferred into recipient mice. The thyroids were removed on Days 7, 10, and 14 after transfer and serially sectioned. The early phase of transferred EAT showed a higher percentage of L3T4+ cells compared to Lyt-2+ cells, yielding a ratio of 2.3 and total T cells of about 35%. By Day 10, both T cell subsets had increased to a total of about 56%. However, the relative increase was greater in the Lyt-2+ subset; the nearly doubled percentage was statistically significant, resulting in a downward shift in the subset ratio to 1.7. Little change in the in situ distribution was seen on Day 14. The percentages of F4/80+ (macrophage) population in lesions examined on Days 10 and 14 were fairly constant and B cell involvement was minimal. These findings illustrate the pathogenic role of both T cell subsets in adoptively transferred EAT and the time-dependent changes in their relative proportions leading to thyroid gland destruction.

Long-term observation and effect of age on induction of experimental autoimmune thyroiditis in susceptible and resistant mice

After induction of experimental autoimmune thyroiditis (EAT) in mice, long-term observation on both the severity of thyroiditis and antibody formation against mouse thyroglobulin (MTg) was carried out over a period of 18 months. In EAT-susceptible strains (CBA, C3H/Anf), both the severity of thyroiditis and MTg antibody production continued for a long term. In EAT-resistant mice (BALB/c), thyroiditis remained minimal, if present, and the low antibody response to MTg became negligible. On the other hand, aging had a prominent effect on the EAT induction in susceptible mice; both MTg antibody response and thyroid infiltration were markedly reduced. These data were well correlated with reduced antibody formation against sheep red blood cells. Young and old mice were further compared as donors or recipients in adoptive transfer of concanavalin A-stimulated cells. Lymph node cells from either young or old MTg-immunized mice transferred appreciable thyroiditis to normal young and old recipient mice. However, similarly treated spleen cells from MTg-immunized old mice responded more poorly to in vitro stimulation with mitogens or MTg and transferred thyroiditis to very few normal young or old mice.

In situ kinetic analysis of thyroid lymphocyte infiltrate in mice developing experimental autoimmune thyroiditis

L3T4+ T cells from genetically susceptible mice developing experimental autoimmune thyroiditis (EAT) were shown earlier to proliferate in response to restimulation with mouse thyroglobulin (MTg) in vitro and to mediate the adoptive transfer of EAT, whereas Lyt-2+ cells differentiated in vitro into cells cytotoxic for thyroid monolayers. Leukocyte suspensions from disrupted thyroid glands examined on Days 13-21 after immunization revealed the accumulation of both T cell subsets in the infiltrate at varying ratios. To characterize the in situ kinetics of cellular infiltration in chronic EAT, we extended the observation intervals after immunization to include Days 21 to 42. The leukocytes in thyroid sections were labeled immunohistochemically first with rat monoclonal antibodies to L3T4, Lyt-2, Thy-1, k light chain, or F4/80 macrophage antigen, then with biotinylated anti-rat IgG, utilizing the avidin-biotin-peroxidase technique. Throughout the 21- to 42-day interval, no significant variations were detected in the percentages of L3T4+ subset, but those of Lyt-2+ cells increased and then declined. The shift in the L3T4+:Lyt-2+ ratio, down from 2.4 to 1.6 and then up to 3.0, was directly related to changes in the Lyt-2+ subpopulation. The F4/80+ and B cell populations changed little during this period. These findings illustrate the changing kinetics of T cell subsets in situ in the development and perpetuation of EAT and MTg-immunized mice.

Depletion of L3T4+ and Lyt-2+ cells by rat monoclonal antibodies alters the development of adoptively transferred experimental autoimmune thyroiditis

To delineate the contribution of L3T4+ and Lyt-2+ cells in the pathogenesis of experimental autoimmune thyroiditis (EAT), synergistic pairs of monoclonal antibodies (mAb) to the T cell subsets were used in conjunction with the adoptive transfer of mouse thyroglobulin (MTg)-activated cells from immunized mice. Initial experiments verified the important role of L3T4+ cells in the transfer of EAT. Subsequent experiments pointed to the relative contribution of both L3T4+ and Lyt-2+ cells, depending on the stage and extent of disease development. Treatment during disease with L3T4, but not Lyt-2, mAb alone significantly reduced thyroiditis. However, in situ analysis of the cellular infiltrate in thyroid sections revealed that, after treatment with mAb, the appropriate subset was eliminated without altering the amount of the other subset in the remaining lesion. In addition, treatment during severe thyroiditis following the transfer of MTg-activated lymph node cells showed that Lyt-2 mAb alone also reduced thyroid infiltration. When the recipients were pretreated with either pair of mAb before transfer, disease development was only moderately affected. We conclude that (i) donor L3T4+ cells are the primary cells responsible for the initial transfer and development of thyroiditis; and (ii) previous in vitro cytotoxicity data, plus current monoclonal antibody treatment of disease and in situ analysis, further implicate a role for Lyt-2+ cells in EAT pathogenesis.

Resistance to experimental autoimmune thyroiditis: L3T4+ cells as mediators of both thyroglobulin-activated and TSH-induced suppression

Mechanisms suppressive to induction of murine experimental autoimmune thyroiditis (EAT) can be activated by pretreatment with tolerogenic doses of mouse thyroglobulin (MTg) or prior TSH infusion to raise circulatory MTg levels. MTg-activated suppressor T cells (Ts), shown earlier to be Thy-1+ and probably I-J+, were further characterized by in vivo administration of paired rat monoclonal antibodies to distinct epitopes on the L3T4 or Lyt-2 molecule, either on the day of, or subsequent to, initiation of the tolerogenic regimes. The cells required at the time of MTg pretreatment were L3T4+, Lyt-2- and low anti-L3T4 doses had no effect on their activation. The cells that mediated the strong MTg-induced resistance following pretreatment were also L3T4+; their suppressor function could only be abrogated by depletion of L3T4+, but not Lyt-2+, cells. Injection of cyclophosphamide (20-100 mg/kg) either prior to EAT induction or after Ts activation did not affect the severity of disease. Similarly, the suppressor state evoked by TSH infusion could only be abrogated by anti-L3T4 treatment. These findings indicate that both MTg-activated and TSH-induced suppression are mediated by L3T4+ cells. We hypothesize that MTg-specific Ts are present in normal, EAT-susceptible mice in low numbers to contribute to the maintenance of self-tolerance and that they are stimulated by increased levels of circulatory MTg to expand/differentiate and mediate the marked resistance to EAT induction.

Induction of experimental autoimmune thyroiditis in B cell-depleted mice

The effect of B cell depletion on the induction and severity of murine experimental autoimmune thyroiditis was investigated. Thirteen CBA mice were given repeated intraperitoneal doses of 700 micrograms purified rabbit anti-mouse Ig antibody from 24 hours to 8 weeks after birth. Controls were given normal rabbit IgG (14 mice) or were left uninjected (10 mice). At six weeks all mice received two doses of 70 micrograms murine thyroid extract in complete Freund's adjuvant. Only 2/13 of the anti-Ig treated mice were fully B cell-deficient as determined by serum IgM, spleen cell immunofluorescence and responsiveness to LPS; however, the levels of anti-thyroglobulin autoantibodies were very low in 7/13 mice. The results demonstrate that thyroiditis can be actively induced in the absence of B cells and autoantibodies but that B cells may play a role in increasing disease severity.

The initiation and early development of autoimmune diseases

Our understanding of autoimmunity has changed considerably over the past years as a consequence of the demonstration that self-reactive B cells and T cells are not necessarily deleted from the immunological vocabulary. The critical event in initiating (or avoiding) autoimmune responses is presentation to T cells of the self-peptide-MHC antigen complex. Based on the premise that quantitative aspects are of paramount importance, we suggest that T-cell activity, MHC expression, and self-peptide binding determine the initiation of autoimmune responses.

T-cell receptor alpha chain V region polymorphism linked to primary autoimmune hypothyroidism but not Graves' disease

T-cell receptor alpha- and beta-chain polymorphisms have been investigated in patients with autoimmune thyroid disease. Using a cDNA probe for the T-cell receptor alpha chain, a 1.4-kb V alpha Taq I restriction fragment was found in 25 of 33 patients with autoimmune hypothyroidism compared to 33 of 61 control subjects (p less than 0.05) and 16 of 43 patients with Graves' disease (p less than 0.001 compared to patients with autoimmune hypothyroidism). Moreover, when Graves' patients were divided according to HLA-DR3 status, there was a significantly reduced frequency of the 1.4-kb V alpha fragment in HLA-DR3-negative patients (p less than 0.05 compared to controls). There was no significant association of either thyroid disorder with polymorphisms of the T-cell receptor alpha- or beta-chain-constant region genes, after Taq I and Bgl II digestion, respectively. These results show that inherited variation in T-cell receptor genes, recognizable before any somatic event has taken place, may play a role in susceptibility to autoimmune disease.

Resistance to experimental autoimmune thyroiditis induced by physiologic manipulation of thyroglobulin level

The role of circulatory mouse thyroglobulin (MTg) level in activating mechanisms suppressive to induction of experimental autoimmune thyroiditis (EAT) was studied by two regimens to strengthen normal maintenance of self-tolerance in genetically susceptible mice. One was to administer graded doses of exogenous MTg either 7 days apart or daily for 10 days and then challenge the animals with MTg + LPS. The other was to infuse TSH via an osmotic pump for 7 days. The steady TSH infusion for 7 days resulted in an increase in MTg level peaking on Day 3. Such kinetics of MTg concentration in response to TSH coincided with enhanced resistance to EAT induction. After an initial rapid clearance rate of t1/2 of 3 hr, tolerogenic doses of exogenous MTg sustained similar levels for 2-3 days. In contrast, subtolerogenic doses declined to baseline levels in 2 days or less. Clearance can be best explained by a two-compartment model for distribution with an initial alpha phase (t1/2 about 3 hr), followed by a beta phase (t1/2 about 10 hr). We conclude that, for the prevention of EAT induction in the presence of potent adjuvants (CFA or LPS), a threshold, but above baseline, level of either exogenous or endogenous MTg, represented by the beta phase, is required for a critical period (greater than 2-3 days) to activate suppressor mechanisms over and above homeostatic regulation. Whether MTg concentration raised by TSH (TRH) administration activates suppressor T cells as observed after the injection of a tolerogenic dose of MTg remains to be determined.