Cellular basis of the genetic control of immune responsiveness to murine thyroglobulin in mice

The Essential Role of Circulating Thyroglobulin in Maintaining Dominance of Natural Regulatory T Cell Function to Prevent Autoimmune Thyroiditis

Several key findings from the late 1960s to mid-1970s regarding thyroid hormone metabolism and circulating thyroglobulin composition converged with studies pertaining to the role of T lymphocytes in autoimmune thyroiditis. These studies cemented the foundation for subsequent investigations into the existence and antigenic specificity of thymus-derived natural regulatory T cells (nTregs). These nTregs prevented the development of autoimmune thyroiditis, despite the ever-present genetic predisposition, autoantigen (thyroglobulin), and thyroglobulin-reactive T cells. Guided by the hypothalamus-pituitary-thyroid axis as a fixed set-point regulator in thyroid hormone metabolism, we used a murine model and compared at key junctures the capacity of circulating thyroglobulin level (raised by thyroid-stimulating hormone or exogenous thyroglobulin administration) to strengthen self-tolerance and resist autoimmune thyroiditis. The findings clearly demonstrated an essential role for raised circulating thyroglobulin levels in maintaining the dominance of nTreg function and inhibiting thyroid autoimmunity. Subsequent identification of thyroglobulin-specific nTregs as CD4(+)CD25(+)Foxp3(+) in the early 2000s enabled the examination of probable mechanisms of nTreg function. We observed that whenever nTreg function was perturbed by immunotherapeutic measures, opportunistic autoimmune disorders invariably surfaced. This review highlights the step-wise progression of applying insights from endocrinologic and immunologic studies to advance our understanding of the clonal balance between natural regulatory and autoreactive T cells. Moreover, we focus on how tilting the balance in favor of maintaining peripheral tolerance could be achieved. Thus, murine autoimmune thyroiditis has served as a unique model capable of closely simulating natural physiologic conditions.

A novel pathogenic peptide of thyroglobulin (2208-2227) induces autoreactive T-cell and B-cell responses in both high and low responder mouse strains

Experimental autoimmune thyroiditis (EAT) is commonly induced by thyroglobulin (Tg) or Tg peptides in mice genetically susceptible to thyroiditis. In the present study, we investigated the immunogenic and pathogenic potential of a novel 20mer human Tg peptide, p2208 (amino acids 2208-2227), in mouse strains classified as low (LR) or high (HR) responders in EAT. The peptide was selected for its content in overlapping binding motifs for MHC class II products, associated with either resistance (A(b)), or susceptibility (A(s), E(k)) to EAT. We therefore immunized LR BALB/c (H-2(d)) and C57BL/6 (H-2(b)) strains, as well as HR CBA/J (H-2(k)) and SJL/J (H-2(s)) mice with 100 nmol of p2208 in adjuvant and collected their sera, lymph nodes and thyroid glands for further analysis. The p2208 peptide was found to contain B-cell and cryptic T-cell epitope(s) in two of the four strains examined, one LR and one HR. Specifically, it elicited direct EAT in C57BL/6 mice (two of seven mice, infiltration index 1-3), as well as in SJL/J mice (two of six mice, infiltration index 1-2). Such an EAT model could provide insights into the immunoregulatory cascades taking place in resistant hosts.

Identification of pathogenic T cell epitopes near cathepsin cleavage sites in thyroglobulin

Experimental autoimmune thyroiditis, induced in mice after challenge with thyroglobulin (Tg), is known to be under the genetic control of the H2A(k) locus. Because cathepsins are known to influence proteolytic processing of Tg in vivo, we examined in this study whether putative H2A(k)-binding Tg epitopes, located near cathepsin cleavage sites within mouse Tg, have immunopathogenic properties. Cathepsin L, B, and D cleavage sites in mouse Tg were predicted based on homology with known cathepsin cleavage sites in rabbit Tg. We used an algorithm-based approach to identify H2A(k)-binding motifs within 20-aa residue segments adjacent to cathepsin cleavage sites, and five 12mer peptides encompassing these sequences were synthesized. Two of them, p2369 (aa 2369-2380) and p2439 (aa 2439-2450) were immunogenic, eliciting significant proliferative T cell responses using lymph node cells from peptide-primed mice and production of IL-2 and IFN-γ in recall assays in vitro. Both peptides induced experimental autoimmune thyroiditis upon direct challenge of CBA/J mice with peptide in CFA and by adoptive transfer of peptide-primed lymph node cells into naive recipient hosts, but neither peptide was characterized as dominant.

The genetics of autoimmune thyroiditis: the first decade

Most of our current understanding of the genetic predisposition to autoimmune disease can be traced to experiments performed in the decade from 1971 to 1981. Chella David was a key contributor to this research. Many of these early steps came from studies of experimental autoimmune thyroiditis. This model has been especially valuable because essentially the same disease can occur spontaneously in selected strains of animals or can be induced by deliberate immunization. From a genetic point of view, the disease has been investigated in three different species: mice, rats and chickens. The same antigen, thyroglobulin, initiates the disease in all three species. Among the main discoveries were the relationship of autoimmune disease to the major histocompatibility complex (MHC), the interplay of different subregions within the MHC in promoting or retarding development of disease, the differing roles of MHC class II and MHC I class genes in induction and effector phases, respectively, and the cumulative effect of non-MHC genes, each of which represents a small addition to overall susceptibility. Other experiments revealed that genetic differences in thyroglobulin allotypes influence susceptibility to thyroiditis. Thyroid glands differed in different strains in vulnerability to passive transfer of antibody. The first evidence of modulatory genes on the sex-related X chromosome emerged. All of these genetic findings were concurrently translated to the human disease, Hashimoto's thyroiditis, where thyroglobulin is also the initiating antigen.

The immunological basis of autoimmune disease

Organ-specific diseases often involve cell surface antigens which when functionally characterized prove to have some receptor function. Certain restricted parts of the molecule are autoantigenic but the response to these epitopes is similar to that provoked by foreign antigens with respect to diversity of class, clonality and probably idiotypy. The mechanisms controlling the response to components on the surface of the body's cells are not fully understood but might be circumvented by polyclonal activators or by the development of T suppressor dysfunction. The latter could occur through a generalized defect in T suppressor cells, which would account for the association of autoimmune diseases in given individual subjects. Alternatively, or in addition (since genetic studies suggest multifactorial influences), the suppressor defect could be antigen specific. Our studies in chickens with spontaneous autoimmune thyroiditis show that normal antigen is obligatory for both the development and maintenance of autoantibody production and that it is possible that some abnormality or change in the presentation of the autoantigen (rather than its structure) is concerned in the initiation process.

Pathogenicity of a human thyroglobulin peptide (2340-2359) in mice with high or low genetic susceptibility to thyroiditis

We have previously identified a 20-mer peptide of human thyroglobulin (hTg), p2340 (aa2340-2359), which induced experimental autoimmune thyroiditis (EAT) in AKR/J (H-2(k)) and HLA-DR3 transgenic mice. In this study, we investigated the thyroiditogenic potential of p2340 in 'high responder' CBA/J (H-2(k)) and SJL/J (H-2(s)) or 'low responder' C57BL/6 (H-2(b)) and BALB/c (H-2(d)) mice. Mice were immunized subcutaneously with 100 nmol of p2340 in complete Freund's adjuvant (CFA) and both the proliferative capacity of their lymph node cells in the presence of p2340 or intact Tg and the production of peptide-specific antibodies were investigated. The p2340 peptide was found to contain B-cell and non-dominant T-cell epitope(s) in all strains tested. Moreover, it elicited EAT in CBA/J (2/6, infiltration index (I.I.) 1) and SJL/J (5/5, I.I. 1-3) mice after direct challenge and in BALB/c (4/7, I.I. 1) and C57BL/6 (1/5, I.I. 1) after adoptive transfer of p2340-primed lymph node cells. P2340 is the first Tg peptide found to be pathogenic in low as well as high responder mouse strains and thus will allow us to investigate mechanisms of EAT induction in a genetically resistant host.

Role of thyroglobulin in the pathogenesis of Graves' ophthalmopathy: the hypothesis of Kriss revisited

One of the hypothesis to explain the pathogenesis of Graves' ophthalmopathy (GO) was formulated by Joseph P. Kriss in the early 1970s. He postulated that the initiating event in the pathogenesis of GO is the deposition and accumulation of thyroglobulin (Tg) in orbital tissues, followed by an autoimmune reaction against Tg. In the last 30 yrs several studies have addressed this hypothesis, through various, different experimental approaches, raising results that are both in favor and against the possibility that Tg plays a role in the pathogenesis of GO. The finding that intact Tg is present in orbital tissues of GO patients supports Kriss' hypothesis, although the role of Tg as an autoantigen seems to be unlikely, as GO is not significantly associated with serum TgAb and mice immunized with Tg do not develop GO. Whether Tg is indeed involved in the pathogenesis of GO remains to be established. Our current view is that, provided that Tg plays a role, it is unlikely the only factor involved and Tg in orbital tissues may rather reinforce or worsen a damage initiated by other mechanisms.

Development of a murine model of autoimmune thyroiditis induced with homologous mouse thyroid peroxidase

Autoimmune thyroid disease (AITD) is a common autoimmune disease. Thyroid peroxidase (TPO) is a well characterized autoantigen in AITD. Autoantibodies and autoreactive T lymphocytes to TPO are believed to play a major role in the pathogenesis of lymphocytic thyroiditis. To understand the pathogenic mechanisms of AITD and the role of TPO, we have established a mouse model of lymphocytic thyroiditis by immunizing C57Bl/6 (H-2(b)), CBA (H-2(k)), and C57Bl/6 x CBA F1 mice with recombinant murine TPO (rmTPO) ectodomain comprising amino acid residue 1-837 produced in Escherichia coli. Mice were immunized with 30 microg purified ectodomain in complete Freund's adjuvant. Antibodies against rmTPO were detected in the serum of all mice from day 21 onward. Draining lymph node cells from rmTPO-immunized animals showed dose-dependent proliferation to TPO stimulation. Mice killed at d 50 and 90 revealed variable degrees of thyroiditis with infiltration of mononuclear cells and destruction of thyroid follicles. C57Bl/6 and the F1 mice, in comparison with CBA mice, showed a greater degree of thyroiditis. There was a lack of correction between the intensity of thyroiditis and the anti-TPO response. Immunotyping of the thyroid cellular infiltrates showed predominantly CD4+ T cells and B220+ B cells but scanty CD8+ T cells. None of the control mice injected with the purified fusion partner developed anti-TPO antibodies and thyroiditis. In conclusion, a genuine autoimmune mouse model of lymphocytic thyroiditis was established using autologous mouse TPO. This new model induced with autologous TPO will lead to a better understanding of the mechanisms in destructive thyroiditis and will assist in the development of new strategies for modulating the pathogenic immune response.

Induction of murine thyroiditis by a non dominant E(k)-restricted peptide of human thyroglobulin

We have previously shown that the human thyroglobulin (hTg) 20-mer peptide p2340 (aa 2340-2359) contains an epitope recognized by Tg-reactive B cells in patients with Graves' disease. The presence of several Ek-binding motifs within p2340 prompted us to examine whether this peptide can stimulate a T-cell response and elicit experimental autoimmune thyroiditis (EAT) in AKR/J (H-2k) mice. The peptide was found to be immunogenic at the T-cell level since it induced specific proliferative responses as well as interleukin-2 and interferon-gamma secretion in secondary cultures of peptide-primed lymph node cells (LNC). The p2340-specific proliferation was blocked almost completely by an Ek-specific monoclonal antibody (mAb) but was unaffected by a control Ak-specific mAb. Peptide-primed LNC did not respond to intact hTg and conversely, LNC primed in vivo with hTg did not respond to p2340 in culture, suggesting that p2340 contains non-dominant T-cell epitope(s). Direct subcutanaeous challenge of AKR/J mice (n = 9) with p2340 in adjuvant, elicited mild to moderate EAT (infiltration index of 1-2) and strong p2340-specific immunoglobulin G responses in all mice tested. These data delineate a new thyroiditogenic sequence within the carboxyl terminal region of hTg.

Delineation of five thyroglobulin T cell epitopes with pathogenic potential in experimental autoimmune thyroiditis

Experimental autoimmune thyroiditis (EAT) is a T cell-mediated disease that can be induced in mice after challenge with thyroglobulin (Tg) or Tg peptides. To date, five pathogenic Tg peptides have been identified, four of which are clustered toward the C-terminal end. Because susceptibility to EAT is under control of H-2A(k) genes, we have used an algorithm-based approach to identify A(k)-binding peptides with pathogenic potential within mouse Tg. Eight candidate synthetic peptides, varying in size from 9 to 15 aa, were tested and five of those (p306, p1579, p1826, p2102, and p2596) were found to induce EAT in CBA/J (H-2(k)) mice either after direct challenge with peptide in adjuvant or by adoptive transfer of peptide-sensitized lymph node cells (LNCs) into naive hosts. These pathogenic peptides were immunogenic at the T cell level, eliciting specific LNC proliferative responses and IL-2 and/or IFN-gamma secretion in recall assays in vitro, but contained nondominant epitopes. All immunogenic peptides were confirmed as A(k) binders because peptide-specific LNC proliferation was blocked by an A(k)-specific mAb, but not by a control mAb. Peptide-specific serum IgG was induced only by p2102 and p2596, but these Abs did not bind to intact mouse Tg. This study reaffirms the predictive value of A(k)-binding motifs in epitope mapping and doubles the number of known pathogenic T cell determinants in Tg that are now found scattered throughout the length of this large autoantigen. This knowledge may contribute toward our understanding of the pathogenesis of autoimmune thyroiditis.

Megalin in thyroid physiology and pathology

Megalin, a member of the low density lipoprotein endocytic receptor family, is expressed on the apical surface of thyroid epithelial cells, directly facing the follicle lumen, where colloid is stored in high concentrations. Studies in vivo and with cultured thyroid cells have provided evidence that megalin expression on thyroid cells is TSH-dependent. Thyroglobulin (Tg), the major protein component of the colloid and the precursor of thyroid hormones, binds to megalin with high affinity and megalin mediates in part its uptake by thyrocytes. Tg internalized by megalin avoids the lysosomal pathway and is delivered by transepithelial transport (transcytosis) to the basolateral membrane of thyrocytes, from which it is released into the bloodstream. This process competes with pathways leading to thyroid hormone release from Tg molecules, which occurs following internalization of Tg molecules from the colloid by other means of uptake (fluid phase endocytosis or endocytosis mediated by low affinity receptors) that result in proteolytic cleavage in the lyosomes. During transcytosis of Tg, a portion of megalin (secretory component) remains complexed with Tg and enters the circulation, where its detection may serve as a tool to identify the origin of serum Tg in patients with thyroid diseases. Tg endocytosis via megalin is facilitated by the interaction of Tg with cell surface heparan sulfate proteoglycans, which occurs via a carboxyl terminal heparin binding site of Tg functionally related with a major megalin binding site. Although autoantibodies against megalin can be found in the serum of approximately 50% of patients with autoimmune thyroiditis, a role of megalin in this and other thyroid diseases remains to be established.

Serum antibodies against megalin (GP330) in patients with autoimmune thyroiditis

Megalin (gp330) is a multiligand receptor found on the apical surface of selected epithelial cells, including thyroid cells. We recently showed that megalin is a high-affinity receptor for thyroglobulin. Megalin is capable of inducing autoantibodies, as shown in the rat model, Heymann nephritis. Based on this consideration and on the knowledge that autoantibodies against several thyroid antigens develop in patients with autoimmune thyroid diseases, we searched for antimegalin antibodies in 78 patients with autoimmune and nonautoimmune thyroid diseases. We developed an assay, based on flow cytometry, to measure binding of serum IgGs to L2 cells, a rat carcinoma cell line that expresses abundant megalin. After incubation of L2 cells with serum samples and then with fluorescein isothiocynate-conjugated antihuman IgG Fc-specific antibody, the mean fluorescence intensity (MFI) was determined. Using results obtained in sera from 32 normal subjects, we established a cutoff value for MFI (50.62), above which, tests were considered positive. Significantly elevated values were found in 18 patients, including 13 of 26 patients with autoimmune thyroiditis (50.0%) and in 2 of 19 patients with Graves' disease (10.5%). Furthermore, 2 of 19 patients with nontoxic goiter (10.5%) and 1 of 14 patients with differentiated thyroid cancer (7.14%) had MFI values greater than 50.62, associated with the presence of circulating antithyroid autoantibodies. As a control cell line, we used Chinese hamster ovary cells, which do not express megalin. We found that, among the 18 patients with positive tests for binding to L2 cells, only 1 patient with nontoxic goiter had significant binding of serum IgGs to Chinese hamster ovary cells. Binding of serum IgGs to L2 cells was significantly reduced by coincubation with purified megalin in 15 of 18 positive patients (83.33%) and by a rabbit antimegalin antibody in 11 patients (61.11%). Further and more conclusive evidence that positive tests (MFI >50.62) for binding to L2 cells were attributable to serum antimegalin antibodies was demonstrated by immunoprecipitation experiments. After incubation of serum samples with L2 cell extracts, incubation with antihuman IgG Fc-specific agarose beads resulted in immunoprecipitation of megalin in all the 18 positive patients, but not in normal subjects, as assessed by Western blotting using a monoclonal antibody against megalin. Furthermore, the intensity of the band corresponding to megalin precipitated by serum IgGs in the above 18 patients was significantly correlated with the L2 binding MFI. This is the first clear-cut demonstration of antibodies against megalin in humans. Further studies are needed to determine whether antimegalin antibodies have pathogenic significance or diagnostic value in autoimmune thyroid diseases.

Suppression of murine thyroiditis via blockade of the CD40-CD40L interaction

The CD40 ligand (gp39) is transiently expressed on activated CD4+ T cells and mediates cognate helper function by interacting with CD40 on B cells. Increasing evidence suggests, however, critical involvement of gp39 not only in antibody-mediated responses but also in the development of effector T cells. Here, we have investigated the effect of in vivo gp39 blockade on the induction of murine experimental autoimmune thyroiditis (EAT), a T-cell-mediated disease. Over a 5-week period, EAT was induced in SJL mice with thyroglobulin (Tg) and adjuvant. Concomitantly, mice received intraperitoneal (i.p.) injections of MR1, a gp39-specific hamster monoclonal antibody (mAb), at 4-day intervals. Control mice were challenged with Tg but received equivalent doses of hamster immunoglobulin (HIg). It was observed that the control mice developed severe thyroiditis whereas the MR1-treated mice exhibited very low levels of infiltration that were mostly focal in nature. Blockade of gp39 was effective since the Tg-specific IgG titres were low or undetectable in all MR1-treated animals compared with the controls. In addition, upon restimulation with Tg in vitro, lymph node cells (LNC) from Tg-primed, MR1-treated mice proliferated less strongly and secreted significantly lower amounts of interleukin-2 (IL-2) and interferon-gamma (IFN-gamma) than LNC from untreated or HIg-treated controls. These results strongly suggest that in vivo blockade of gp39 suppresses EAT by inhibiting the priming of inflammatory Tg-specific T-helper type 1 cells.

Thyroid-specific T cells in the Wistar rat: 3. Induction of anergy by a syngeneic thyroid cell line

Using a syngeneic Wistar rat model we have shown that the Wistar rat thyroid (WRT) cell line causes significant and specific proliferation of lymph node T cells from normal Wistar rats, and of splenic T cells from a thyroiditis prone line of BB/W rats, when cultured in the presence of irradiated feeder cells. These T cell responses were associated with a marked increase in the number of CD8+ T cells. However, using normal Wistar rat T cells which had been previously exposed to WRT cells, rested and then re-exposed to WRT cells as antigen, we consistently found that the T cell population had been rendered unreactive, or anergic, to further thyroid cell stimulation. However, if recombinant rat IL-2 was added to the cultures, then T cell responsivity was seen on re-exposure to WRT cells. The lymphopenic BB/W rat also had T cells which showed a primary T cell response to the WRT cell line accompanied by a marked increase in CD8+ T cells. In contrast to the Wistar rat T cells, the BB/W T cells retained a proliferative responsiveness to WRT cells on re-exposure although such responsiveness could also be markedly enhanced with IL-2. These data suggested that antigen-mediated inhibitory signals were induced in normal Wistar rat T cells by the syngeneic WRT cell line, independent of the presence of co-stimulatory molecules. Furthermore, the thyroiditis prone BB/W rat T cells appeared to be less responsive to such anergy induction, perhaps contributing to their susceptibility to autoimmune thyroid disease.

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.

T cell mapping of one epitope from thyroglobulin inducing experimental autoimmune thyroiditis (EAT)

These data collect the advance made in the last few years in our laboratory in defining one epitope from the thyroglobulin (Tg) molecule (660 KDa) inducing Experimental Autoimmune thyroiditis (EAT) in CBA/J mice. We achieved the characterization of one EAT-inducer Tg peptide by combining "in vitro" biochemical and immunological approaches and "in vivo" studies. Since T cells recognize degraded forms of the antigen and since endogenous antigens preferentially activate class I-restricted T cells, we hypothesized that one cytotoxic T cell hybridoma, named HTC2, which prevents further EAT induction in mice injected with Tg would be specific for one EAT inducer peptide. In order to identify one Tg epitope inducing EAT, enzymatic treatment of the protein by trypsin, HPLC purification and sequence analysis were performed. Simultaneously, tryptic digests were used to pulse CBA/J macrophages and tested for their ability to be recognized by HTC2 cells. Lastly, when digests were recognized by HTC2 cells their capacity to induce EAT in CBA/J mice was evaluated. To further assess the pathogenicity of the sequenced Tg peptide, one synthetic peptide was made and its capacity to induce EAT verified. By this procedure we identified for the first time one 40 amino-acid peptide from human thyroglobulin inducing EAT in CBA/J mice.

Is focal chronic autoimmune thyroiditis an age-related disease? Differences in incidence and severity between Japanese and British

The incidence of chronic lymphocytic thyroiditis in autopsy material from Japanese and British subjects was evaluated. Lymphocytic infiltration in representative thyroid sections from 1826 Japanese cases collected from four different institutions was analysed. The overall incidence of lymphocytic infiltration was significantly higher in females (22.2 per cent) than in males (13.9 per cent). In females, the incidence reached 23.2 per cent in the fourth decade and showed no increase with age thereafter. The overall incidence of lymphocytic infiltration in thyroid sections from 810 British cases was 42.5 per cent in females and 19.4 per cent in males; an increase in the incidence of thyroiditis from the sixth decade onwards was noted in British females, the figure reaching 50.0 per cent in those aged over 70 years. These findings suggest possible racial differences in susceptibility to chronic thyroiditis. The disorder is not necessarily related to age, increasing severity of disease with age being found only in British females.

Experimental autoimmune oophoritis. II. Both lymphoid cells and antibodies are successful in adoptive transfer

Experimental autoimmune oophoritis can be readily induced by passive transfer of peripheral blood lymphocytes, lymph node cells, spleen cells, T- and B-enriched cell suspensions, immune serum and gamma globulins, from ovary antigen immunized rats to naive recipients. Adoptive transfer was markedly enhanced when recipient rats were injected simultaneously with sensitized lymphoid cells and anti-ovary antibodies. Histologically, this passively induced disease was much the same as the actively induced disease. By syngeneic lymph node assay it was shown that regional lymph nodes of neonatally thymectomized rats did not enlarge upon injection of EAOO lymphocytes which otherwise produced a marked effect in lymph nodes of normal recipient rats. Therefore, it appears that enlargement of the draining lymph node was dependent on the participation of host T cells. The possibility that development of EAOO may involve cooperation between antigen-reactive and effector classes of lymphocytes was discussed.

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.

Experimental murine thyroiditis induced by porcine thyroid peroxidase and its transfer by the antigen-specific T cell line

Thyroid peroxidase purified from porcine thyroid (pTPO) was found to induce an experimental murine thyroiditis with genetic restriction which was very different from that induced by mouse thyroglobulin (mTg). C57BL/6 and C57BL/10 (both H-2b) were good responders for thyroiditis, whereas A/J (H-2a), BALB/c (H-2d), DBA/2 (H-2d), CBA (H-2k), C3H/He (H-2k), and SJL/J (H-2s) were poor responders. Genetic analyses using congenic or recombinant strains revealed the following results: The H-2-linked gene (probably the I-A subregion) had a weak association with the induction of thyroiditis, and at least one non-H-2-linked gene controlled the development of thyroid lesions; antibody production to pTPO, porcine thyroglobulin (pTg) and mTg did not correlate with the incidence of thyroiditis in any strain. None of the murine thyroid microsome-specific antibodies tested by the indirect immunofluorescent technique was detected. The T cell line specific for pTPO was successfully transferred to produce thyroid lesions in C57BL/6 mice. Thyroiditis appeared 3 days after the transfer of T cell blasts, and a low concentration of anti-pTPO antibodies was detected concurrently. Thyroid lesions remained up to 48 days with almost the same extent of thyroiditis, but anti-pTPO antibodies gradually increased. In the vaccination experiments using either 0.645 C/kg (2500 rad)-irradiated or 0.3% glutaraldehyde-fixed T cell blasts, the induction of thyroid lesions by transfer was strongly suppressed. Glutaraldehyde fixation was more effective than X-irradiation in preventing thyroiditis after the transfer of T cell blasts. Vaccination also suppressed significantly the development of thyroid lesions after pTPO administration.

The T-cell receptor alpha, beta and gamma polymorphism in Japanese

Polymorphism in the genes encoding the alpha (alpha), beta (beta) and gamma (gamma) chains of the human T-cell receptors was analyzed both in population and family studies. Against twelve unrelated Japanese, several out of the 15 restriction endonucleases tested, revealed restriction fragment length polymorphism. The segregation of the polymorphic fragments were confirmed among 15 members of three families. In most of the cases paternal and/or maternal haplotypes could be assigned. By testing the polymorphic enzymes among the random healthy Japanese, the frequency of each polymorphic fragment was then determined. Although the polymorphism found in this study was similar to that reported in Caucasians, some differences were observed. Such differences are discussed. The restriction fragment length polymorphism in both population and family studies, derived from alpha, beta and gamma chains of the T-cell receptor found in this report, might be useful markers for genetic analysis of the T-cell function in relation to immunological disorders.

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.

Experimental autoimmune thyroiditis in mice chronically treated from birth with anti-IgM antibodies

The role of T lymphocytes in the pathogenesis of experimental autoimmune thyroiditis in mice is well established while the role of B lymphocytes is unclear. Mice with thyroid lesions have thyroglobulin antibodies whereas these antibodies can occur in mice immunized with Tg that do not develop thyroid lesions. To determine whether thyroglobulin antibodies are necessary for the development of the thyroid infiltrates with mononuclear cells, which are characteristic for experimental autoimmune thyroiditis, AKR mice chronically treated from birth with goat anti-mouse IgM antibodies were immunized with mouse thyroglobulin in Freund's complete adjuvant when they were 7 weeks old. Control mice, similarly immunized, were chronically injected from birth with normal goat gamma-globulin. Three weeks after immunization, all mice were sacrificed, thyroglobulin antibodies in the serum were measured by hemagglutination assay and enzyme-linked immunosorbent assay, and thyroid pathology was assessed. The serum concentration of IgG and IgM, the percentage of B and T lymphocytes in the spleen (flow cytometry), and the in vitro proliferative response of spleen lymphocytes to stimulation by PHA, LPS, and Tg were also measured. All mice treated with anti-IgM antibodies did not have detectable thyroglobulin antibodies but 63% of these mice and 88% of control mice (all of which had thyroglobulin antibodies) had thyroid lesions. Mice treated with anti-IgM antibodies that did not have thyroid lesions had a more pronounced depression of B lymphocytes than similarly treated mice that had thyroid lesions. These experiments suggest that thyroglobulin antibodies are not necessary for the development of thyroid infiltrates with mononuclear cells. B lymphocytes could still participate in the production of experimental autoimmune thyroiditis by presenting thyroglobulin to helper T lymphocytes.

Induction of autoimmunity with dendritic cells: studies on thyroiditis in mice

The initiation and maintenance of thyroid autoimmunity by professional antigen-presenting cells were assessed by observing thyroiditis and induction of IgG antibodies to thyroglobulin (Tg). Dendritic cells (DC) were purified from spleens of CBA mice and T cells removed with anti-Thy 1 and complement. Some DC were pulsed with 25-500 micrograms/ml of mouse Tg in vitro and normal syngeneic mice received injections of 10(5) cells intravenously. In untreated animals only 1 thyroid out of 40 showed a lymphocyte infiltrate and antibody to Tg was rarely seen. In animals receiving normal DC without Tg, lymphocyte infiltration was seen 2-6 weeks later in 5 out of 33 thyroids and some animals produced low levels of antibody to thyroglobulin (8 of 33 animals). DC pulsed with 500 micrograms Tg/ml in vitro caused thyroid infiltration in 6 out of 15 animals but did not increase the incidence of anti-Tg antibodies. Lower doses had no effect. When 10(5) DC were given from animals with experimental allergic thyroiditis (EAT, induced with Tg in complete Freund's adjuvant, CFA) more than half of the recipient animals showed thyroiditis (8 out of 15) and autoantibody production (12 of 15 animals). DC may therefore play a role in the initiation and maintenance of autoimmunity by providing a stimulus for antigen-specific T cells.

The induction of organ-specific antibodies during the graft-vs.-host reaction

During the parent (P) into F1 hybrid graft-vs.-host reaction (GVHR), nuclear, leukocyte and erythrocyte autoantibodies are commonly seen. The specificity of these autoantibodies is reminiscent of those found in systemic lupus erythematosus (SLE) patients and SLE-prone mice. Organ-specific antibodies, however, including thyro-globulin (Tg) antibodies do not arise spontaneously. There have been conflicting reports about the ability of exogenous Tg to induce an anti-Tg response during the GVHR. We have re-examined this question in greater detail. Using the murine P----F1 GVHR system, the results of this work demonstrate that mouse thyroglobulin (MTg)-specific antibodies can be induced during a GVHR. However, mice must both be undergoing a GVHR, and have received exogenous MTg. The highest autoantibody response occurs if mice are injected with mouse thyroid extract or purified MTg at the time of P----F1 cell transfer. The anti-MTg response is MTg dose dependent. The ability to induce anti-MTg antibody was not major histocompatibility complex restricted, for both the DBA/2----B6D2F1 (low responder H-2 haplotypes to MTg), and AKR or DBA/2----AKD2F1 (high/low responder----high responder haplotype) GVHR gave similar responses. The anti-MTg titers peaked between days 7-10 and declined thereafter. In contrast, antibodies to dsDNA were not present at this early time, but developed after several weeks. We conclude that organ-specific autoantibodies can be induced during a GVHR if the appropriate antigen(s) are presented near the time of GVHR induction.

Genetic control of immune response to staphylococcal exfoliative toxin A in mice

Different inbred and congenic resistant strains of mice were immunized with staphylococcal exfoliative toxin A (ETA). In antibody responses measured in sera of mice by a passive hemagglutination technique, A/J, DBA/2, BALB/c, B10A, B10D2, B10S, and A.SW were high responders. C57BL/10 (B10), A.BY, and DBA/1 were low responders. The congenic C3H/HeJ and C3H.SW mice were, respectively, high and low responders. The observation that the immune responses of the mice to ETA were closely linked with the haplotypes of their H-2 complexes suggests the existence of an H-2-linked immune response (Ir) gene coding for the production of humoral antibodies to ETA. Four B10A recombinants were used to map this gene within the H-2 complex. The finding that B10A(2R) and B10A(4R) were high responders, whereas B10A(3R) and B10A(5R) were low responders, indicates that the gene controlling antibody response to ETA is located in the I-A subregion or the H-2K end within the H-2 complex. We wish to propose the name Ir-ETA for this gene. The function of Ir-ETA seems to be at least related to antigen recognition at the T-lymphocyte level. Neonatal mice are generally susceptible to ETA regardless of their H-2 haplotypes. However, the neonatal mice born to a high-responder mother immunized with ETA were resistant to the subcutaneous challenge of ETA, but those born to an immunized low-responder mother were susceptible to the challenge. This result suggests that if the mother is a high responder to ETA and is effectively immunized with ETA, the maternal immunity makes it possible to neutralize this toxin in neonatal mice.

Augmentation of transfer of experimental autoimmune thyroiditis (EAT) in mice by irradiation of recipients

Experimental autoimmune thyroiditis (EAT) can be adoptively transferred to normal syngeneic recipients using spleen cells from susceptible strains of mice primed in vivo with mouse thyroglobulin (MTg) and lipopolysaccharide (LPS) following in vitro activation of spleen cells by culture with MTg. Irradiation of recipient animals markedly augments the severity of thyroiditis induced in this system. Irradiation of recipients does not alter the time course of the development of thyroiditis, nor does it alter the requirement for both in vivo priming and in vitro activation of spleen cells for the development of EAT. Spleen cells from EAT-resistant strains of mice (e.g., Balb/c) do not induce EAT in irradiated recipients. Irradiated recipients develop significant levels of anti-MTg antibodies while unirradiated recipients have little detectable antibody response. The augmenting effect of irradiation can be substantially reversed by transferring naive spleen cells to recipients prior to the transfer of MTg/LPS-primed in vitro-activated spleen cells. In addition athymic CBA/Tufts nude mice develop more severe EAT than CBA/Tufts nude/+ littermates following transfer of activated CBA/J spleen cells. These data suggest that natural suppressor cells may regulate the development of EAT at the effector cell level.

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.

The differences of susceptibility of the target thyroid gland to autoimmune thyroiditis and of antigenicity of thyroid gland for induction of experimental autoimmune thyroiditis

By using a recently developed method for producing thyroiditis in mice consisting of implantation of a fresh thyroid gland into the peritoneal cavity or under the capsule of the kidney with subsequent injection of lipopolysaccharide, differences were shown in susceptibility of the target thyroid gland to autoimmune destruction and in antigenicity of the thyroid gland for induction of experimental autoimmune thyroiditis. Using recombinant congenic mice, the H-2 haplotypes of the target thyroid gland were found to be as important as those of the immune system in development of autoimmune thyroiditis. On the other hand, the H-2 haplotypes of the thyroid gland are unimportant for induction of autoimmune thyroiditis.

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

Previous studies have shown that T cells from genetically susceptible mice developing experimental autoimmune thyroiditis (EAT) proliferate in response to restimulation with mouse thyroglobulin (MTg) in vitro and differentiate into cells cytotoxic for syngeneic thyroid monolayers. To examine further the effector cells involved in pathogenesis and the determinants on MTg responsible for their activation, spleen cells (SC) and lymph node cells (LNC) from mice immunized with MTg or human (H) Tg, and adjuvant (complete Freund's adjuvant (CFA) or lipopolysaccharide (LPS] were cultured in vitro with MTg or HTg. Control cultures were incubated with concanavalin A (Con A) or purified protein derivative (PPD). The in vitro-activated cells which proliferated in response to MTg, HTg, or Con A adoptively transferred thyroiditis to normal recipients, whereas cells transferred directly without in vitro culture were very ineffective. The capacity to transfer EAT was abrogated by irradiation (1500 R), and SC from CFA-immunized control mice which responded in vitro to PPD stimulation did not transfer thyroiditis. The serum titers of MTg autoantibodies were uniformly low and were not correlated with severity of disease. The localization of EAT-effector (precursor) cells depended upon the site of immunization; they were found in the spleens after inguinal (subcutaneous) or systemic (intravenous) immunizations, but were present in the popliteal lymph nodes after hind footpad injections. Both homologous MTg and heterologous HTg functioned as in vivo sensitizing antigen and in vitro activating antigen for each other; such cultured cells transferred thyroiditis in vivo and became cytotoxic for thyroid monolayers in vitro. These findings show that shared determinants are autoantigenic and thyroiditogenic, and support the hypothesis that EAT-effector cells responsible for initiating thyroid damage include cytotoxic cells.

Strain-dependence and cellular aspects of the acceleration of age-dependent shift in class-specific helper and suppressor activity in the thymus of MRL/Mp mice by the LPR gene

Previous studies of the immunoregulatory activity of thymocytes from SJL/J mice have shown loss of suppressor activity for the antibody response by 24 weeks of age with appearance of helper activity. At the same time, suppressor cells developed which inhibit the generation of cytotoxic T lymphocytes (CTL). We now show a similar pattern of helper and suppressor activity in MRL/Mp mice. Presence of the lpr/lpr genotype significantly accelerated the onset of these changes in thymocyte activity. A similar pattern of thymocyte activity was not detected in C57B1/6 mice. In aged MRL-lpr mice, evidence of increased suppressor cell activity for the CTL response could be demonstrated in spleen, and the suppressor was sensitive to treatment with anti-thy 1.2 + complement. The magnitude of the deficiency in the CTL response in MRL-lpr mice was greater than could be accounted for by suppressor cell activity alone. Measurement of the frequency of CTL precursors (CTLP), the yield of CTL per CTLP, and the ability to produce and to respond to interleukin 2 (IL-2) indicated that a drop in CTLP frequency, subnormal generation of IL-2, and probably an intrinsic defect in the responsiveness of MRL-lpr CTLP to IL-2 was contributing to the defective CTL response. We were not able to link suppressor T cells with reduced responsiveness to IL-2. Ageing involves different patterns of change in immunoregulatory T-cell subsets in different strains of mice, depending on their genetic constitution. The general implications of this conclusion for prediction of immune dysfunction with age in genetically distinct members of an outbred population are discussed.

Effects of natural or synthetic microbial adjuvants on induction of autoimmune thyroiditis

Natural and synthetic adjuvants of microbial origin were compared for their capacity to potentiate the induction of experimental autoimmune thyroiditis (EAT) with the autoantigen mouse thyroglobulin (MTg). Regardless of the immunomodulator used, severe thyroiditis was observed only in EAT-susceptible strains of the k haplotype and not in EAT-resistant strains of the d haplotype. Compared to phenol-extracted lipopolysaccharide, a potent adjuvant for enhancing EAT induction, phthalyl-substituted, detoxified lipopolysaccharide, even at doses 15- to 50-fold greater, led to only low anti-mouse thyroglobulin titers and mild thyroid infiltration. The synthetic adjuvant N-acetylmuramyl-L-alanyl-D-isoglutamine (MDP) and three of its analogs, N-acetylmuramyl-L-alanyl-D-isoglutamine-L-alanyl-D-glycerol mycolate (MDP-L-Ala-Glyc-Myc), N-acetylmuramyl-L-alanyl-D-glutamyl-(decyl)methyl ester [MDP(decyl)methyl], and N-acetylmuramyl-L-alanyl-D-glutamine-alpha n-butyl ester [MDP-(Gln)-OnBu], designated murabutide, were tested in incomplete Freund adjuvant or in saline. In incomplete Freund adjuvant, MDP-L-Ala-Glyc-Myc was inefficient in inducing EAT, murabutide induced very mild involvement, and MDP and, more so, MDP(decyl)methyl were active but to a lesser degree than CFA. When saline was used, low levels of thyroid infiltration were observed in a few of the MDP-treated animals in only one experiment, whereas no lesions were observed when murabutide was used.

Transfer of experimental autoimmune thyroiditis to normal syngeneic mice by injection of mouse thyroglobulin-sensitized T lymphocytes after activation with concanavalin A

Induction of autoimmune thyroiditis in normal syngeneic CBA/J mice was achieved by injection of 72-hr concanavalin A (Con A)-induced lymphoblasts from donor mice which had been immunized with mouse thyroglobulin (MTg) emulsified with complete Freund's adjuvant (CFA). Injection of lymph node or spleen cells, or frequent injection of serum taken from mice with autoimmune thyroiditis failed to transfer appreciable thyroiditis to recipient mice. Selection by treatment of incubated cells with monoclonal antibody and complement revealed that effector cells in Con A-induced lymphoblast populations for the transfer of autoimmune thyroiditis were Thy-1.2+, Lyt-1.1+, and Lyt-2.1- lymphocytes. These results demonstrate that experimental autoimmune thyroiditis can be adoptively transferred into naive mice by activated Thy-1+, Lyt-2- lymphoblasts.

Analyses of the specificity of mouse monoclonal antibodies to syngeneic and allogeneic thyroglobulins

Fourteen mouse monoclonal antibodies (mAbs) to syngeneic and allogeneic thyroglobulins (Tgs) were prepared to study antigenic determinants, their variation among mouse Tgs, and cross-reactivity with various species Tgs. The binding pattern to the Tg panel classified mAbs into three groups but the clustering by competitive-binding inhibition with unlabeled mAbs suggested that at least five antigenic regions existed on the Tg molecule. Mouse Tgs showed no antigenic variation to our mAbs. The cross-reaction with other species Tgs was strictly limited to rat Tgs, excluding one mAb (8.1.1) which reacted with rat and human Tgs. The competitive-binding inhibition by various doses of Tgs substantiated the binding pattern to the Tg panel and furthermore demonstrated that both complete and partial cross-reactions existed.

The difference of susceptibility of target thyroid gland to autoimmune thyroiditis induced by a combination of implantation of thyroid gland and injection of lipopolysaccharide

Autoimmune thyroiditis was induced in CBA/J mice by a newly developed method consisting of a combination of implantation of one whole syngeneic thyroid gland under the capsule of the kidney and subsequent injection of lipopolysaccharide (LPS) intravenously 6 hr after implantation. This procedure was repeated once, a week later. With this method the implanted thyroid gland, after becoming necrotic due to circulatory disturbance and regenerating, also developed definite thyroiditis, quite similar to that of the intact thyroid gland on Day 49. With respect to the H-2 haplotype of the mice, both intact and implanted thyroid glands of CBA/J (H-2k) and C3H/He (H-2k) mice showed severe thyroiditis, whereas those of BALB/c (H-2d) and C57BL/6 (H-2b) mice developed mild inflammation. With a combination of implantation of thyroid glands derived from parental good (CBA/J) or poor responder (BALB/c) mice and subsequent injection of LPS into (good X poor responder) (CBA/J X BALB/c)F1 hybrid mice, it was found that the genetic background of the target thyroid tissue itself has a strong influence on susceptibility.

Genetic control of mouse antibody production to human thyroglobulin

Genetic control of immune responses in mice against human thyroglobulin was studied using the enzyme-linked immunosorbent assay and passive haemagglutination test. Our results revealed that mice of H-2a, H-2d, H-2q, H-2k and H-2r haplotypes were high responders for antibody production to human thyroglobulin, while mice of H-2b and H-2s haplotypes were low responders. High responsiveness to human thyroglobulin was transmitted to F1 mice in a dominant fashion. Study of the genetic mapping of the immune responses to human thyroglobulin using various congenic mice showed that I-A subregion gene(s) control the immune response to human thyroglobulin.

Mechanisms of autoimmunity: a role for cross-reactive idiotypes

Ehrlich was rarely given to trivial pronouncements and his recognition of the central importance of the distinction between self and non-self by the immune system, embodied in his concept of 'horror autotoxicus'(1), is no exception. This is despite the apparent paradox of the idiotype network in which antibodies recognize self-epitopes on other antibody molecules or antigen receptors as part of the normal process of immune regulation. In this review Anne Cooke and her colleagues examine the possible factors which may contribute to the breakdown of self-tolerance and the establishment of autoimmune states.

Experimental autoimmune thyroiditis. In vitro cytotoxic effects of T lymphocytes on thyroid monolayers

Effector mechanisms in experimental autoimmune thyroiditis (EAT) were studied in vitro by establishing a cytotoxicity system with thyroid target cells. Lymph node cells (LNC) from popliteal and inguinal lymph nodes were obtained from CBA/J mice (8-10 wk old) 12-18 d after immunization with 120 micrograms mouse thyroglobulin (MTg) in complete Freund's adjuvant (0.2 ml to both hind footpads and thighs) and were cultured with MTg (10-50 micrograms/ml). On day 5 of culture, viable LNC were added to labeled thyroid monolayers and their cytoxicity was assayed after 16 h. Functional thyroid target cells, as reflected by MTg production for up to 9 d, were prepared by adding 1 mM dibutyryl adenosine 3',5'-cyclic monophosphate and 60 microU thyroid-stimulating hormone/ml to the culture medium. On days 5-7, confluent monolayers were labeled with 111In and used as targets. Specific 111In-release ranged from 56 to 85%. The cytotoxic response is MTg specific and H-2 restricted. Pretreatment of thyroid target cells with rabbit antiserum to MTg completely inhibited cytotoxicity. Pretreatment with mouse antiserum to either Kk or Dk products resulted in approximately 50% inhibition, whereas the combined use of both antisera led to total inhibition. No cytotoxicity was observed when control BALB/c thyroid cultures were the target cells. The kinetics of the expansion of Thy-1+ cytotoxic cells by in vitro exposure to MTg were then studied. The cytotoxic response required 5 d to develop and was abolished by treating LNC on day 4 with monoclonal antibody to Lyt-1.1, but not to Lyt-2.1, plus complement. In contrast, by day 5, cytotoxicity was abrogated by similar treatment with antiserum to Lyt-2.1, but not to Lyt-1.1. We conclude that cytotoxic cells derived from MTg-immunized mice are Lyt-2-bearing cells but require the presence of Lyt-1-bearing cells for their generation and/or differentiation.

T and B cell reactivity in experimental autoimmune thyroiditis

Using several immunization protocols, T cells specific for self Tg were shown to be activated to only a limited degree compared with the ability to activate T cells to a foreign Tg. Thus, a high degree of tolerance exists in T cells to self Tg, while tolerance is not maintained in B cells. Whether the small degree of T cell activation that is induced under stringent immunization procedures plays a role in the induction of the spontaneous disease is unknown. Preliminary results are also presented showing that experimental autoimmune thyroiditis (EAT) can be more readily induced in aged than in young adult mice and these results are discussed in terms of the generalized decrease in T cell reactivity in aged mice.

Age-dependent separation of class-specific suppressor cells in thymus of SJL/J mice

The thymus of SJL/J mice of age 3-6 weeks has been previously shown to contain suppressor cells that inhibit the antibody response to lymph node cells to SRBC. The effect of these suppressor cells disappear as the animals age (24 weeks or more). We find that these aged animals acquire thymic suppressor cells which suppress the generation of cytotoxic T-cells both in vitro and in vivo. Although such suppressors are not present in the thymuses of young SJL/J mice, suppression can be induced by treatment with estrogen and progesterone. The differentiation of functionally different suppressor cell populations in thymus may be affected by both age and hormonal status.