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.     

Prevention and reversal of experimental autoimmune thyroiditis (EAT) in mice by administration of anti-L3T4 monoclonal antibody at different stages of disease development

Experimental autoimmune thyroiditis (EAT) can be induced in CBA/J mice following the transfer of spleen cells from mouse thyroglobulin (MTg)-sensitized donors that have been activated in vitro with MTg. Since L3T4+ T cells are required to transfer EAT in this model, the present study was undertaken to assess the effectiveness of the anti-L3T4 monoclonal antibody (mAb) GK1.5 in preventing or arresting the development of EAT. Spleen cells from mice given mAb GK1.5 prior to sensitization with MTg and adjuvant could not transfer EAT to normal recipients and cells from these mice did not proliferate in vitro to MTg. Donor mice given GK1.5 before immunization did not develop anti-MTg autoantibody and recipients of cells from such mice also produced little anti-MTg. GK1.5 could also prevent the proliferation and activation of sensitized effector cell precursors when added to in vitro cultures. When a single injection of mAb GK1.5 was given to recipients of in vitro-activated spleen cells, EAT was reduced whether the mAb was given prior to cell transfer or as late as 19 days after cell transfer. Whereas the incidence and severity of EAT was consistently reduced by injecting recipient mice with GK1.5, the same mice generally had no reduction in anti-MTg autoantibody. Since EAT is consistently induced in control recipients by 14-19 days after cell transfer, the ability of mAb GK1.5 to inhibit EAT when injected 14 or 19 days after cell transfer indicates that a single injection of the mAb GK1.5 can cause reversal of the histopathologic lesions of EAT in mice. These studies further establish the important role of L3T4+ T cells in the pathogenesis of EAT in mice and also suggest that therapy with an appropriate mAb may be an effective treatment for certain autoimmune diseases even when the therapy is initiated late in the course of the disease.     

CD137 signaling interferes with activation and function of CD4+CD25+ regulatory T cells in induced tolerance to experimental autoimmune thyroiditis

Experimental autoimmune thyroiditis (EAT), a model for Hashimoto's thyroiditis, is a T cell-mediated disease inducible with mouse thyroglobulin (mTg). Pretreatment with mTg, however, can induce CD4+ T cell-mediated tolerance to EAT. We demonstrate that CD4+CD25+ regulatory cells are critical for the tolerance induction, as in vivo depletion of CD25+ cells abrogated established tolerance, and CD4+CD25+ cells from tolerized mice suppressed mTg-responsive cells in vitro. Importantly, administration of an agonistic CD137 monoclonal antibody (mAb) inhibited tolerance development, and the mediation of established tolerance. CD137 mAb also inhibited the suppression of mTg-responsive cells by CD4+CD25+ cells in vitro. Signaling through CD137 likely resulted in enhancement of the responding inflammatory T cells, as anti-CD137 did not enable CD4+CD25+ T cells to proliferate in response to mTg in vitro.     

Autoimmune thyroiditis induced in mice depleted of particular T cell subsets. I. Requirement of Lyt-1 dull L3T4 bright normal T cells for the induction of thyroiditis

T cell-depleted C3H/He or (C57BL/6xC3H/He)F1 (B6C3F1) mice were prepared by adult thymectomy and injection of antithymocyte serum, followed 3 wk later by lethal x-irradiation and bone marrow reconstitution. When these T cell-depleted mice were not injected or injected i.v. with normal spleen and lymph node cells treated with either anti-Thy-1, -L3T4 or -Lyt-2 antibody plus C or C alone, none of the groups of mice developed thyroiditis. In contrast, the adoptive transfer of normal cells treated with anti-Lyt-1 plus C resulted in high incidence of the production of antithyroglobulin antibody and the induction of typical thyroiditis lesion. The thyroid was the sole organ involved, because neither typical inflammatory lesion in other organs nor autoantibody such as anti-DNA antibody was detected in mice that exhibited thyroiditis. Analyses of surface phenotypes of cells required for inducing thyroiditis by the adoptive transfer revealed that an appreciable percentage of Lyt-1 dull T cells remained after the treatment of normal lymphoid cells with anti-Lyt-1 plus C. Almost all of these Lyt-1 dull T cells expressed magnitudes of L3T4 or Lyt-2 Ag comparable to those detected on Lyt-1 bright T cells. More important, the induction of thyroiditis was almost completely prevented by either in vitro or in vivo elimination of Lyt-1 dull L3T4+(bright) but not of Lyt-1 dull Lyt-2+(bright) T cells. These results indicate that Lyt-1 dull L3T4+ T cells existing in normal healthy individuals have potential to induce typical thyroiditis which is associated with the production of antithyroglobulin autoantibody, and that the activation and/or function of this T cell subset is regulated by the Lyt-1 bright T cell population coexisting in normal lymphoid cell population.     

Thymosin alpha 1-induced modulation of cellular responses and functional T-cell subsets in mice with experimental autoimmune thyroiditis

The effects of Ta-1, a peptide constituent of thymosin fraction 5, were studied on murine autoimmune thyroiditis using two congenic strains of mice, B10.Br (Br) and B10.D2 (D2), which are sensitive and resistant to experimental autoimmune thyroiditis (EAT) induction, respectively. EAT was induced by either 2 weekly iv injections of mouse thyroglobulin with adjuvant lipopolysaccharide (LPS) or intradermal injection of thyroglobulin mixed with complete Freund's adjuvant (CFA). The criteria for induction and intensity of thyroiditis were the level of lymphoid infiltration in the thyroid gland and the titer of anti-thyroglobulin antibodies. Ta-1 was given in 5 or 10 daily sc injections in doses ranging from 0.0001 to 0.1 microgram/injection. The injections were commenced at varying intervals from the 1st to the 4th week after immunization. T-Cell subsets in the spleens were determined 2 weeks after the first antigen injection and thyroid infiltration was determined 3 weeks later. Treatment with Ta-1 between the two antigen injections increased the level of thyroiditis in resistant mice, but had no effect in sensitive mice. Treatment for the first 2 weeks had similar effects in resistant mice, but also suppressed thyroiditis in the sensitive strain. Later treatments, during the 3rd and 4th weeks after immunization also revealed immunomodulating properties of Ta-1, with a suppressing effect on thyroiditis in sensitive mice and an enhancing effect in the resistant strain. Both effects of Ta-1 were dose dependent. The effects of Ta-1 on the individual phenotypes were also dose dependent. The dose of 0.01 microgram greatly lowered the percentages of Lyt-2+3+ cells in D2 mice and mildly increased the percentages in Br mice, but did not change the Lyt-1+ cell level in either strain. On the other hand, the dose of 0.001 microgram greatly increased the percentage of Lyt-1+ cells in D2 mice and mildly decreased it in the Br strain, but did not alter the Lyt-2+3+ cell subset in either strain. Thus, both doses of Ta-1 modulated Lyt-1+/2+3+ ratios, with each dose affecting a different T-cell subset. The changes in the response to thyroglobulin are apparently exerted through the regulation of the functional T-cell subset balance.     

Role of L3T4+ and LyT-2+ cells in experimental visceral leishmaniasis

In contrast to euthymic (nu/+) BALB/c mice, athymic nude (nu/nu) BALB/c mice fail to control the visceral intracellular replication of Leishmania donovani, do not generate the macrophage-activating lymphokine IFN-gamma, and show little or no granulomatous tissue response. To characterize the T cell requirement for successful defense against L. donovani, nude mice were first reconstituted with unfractionated nu/+ immune spleen cells, which readily conferred the capacity to control and eliminate visceral (hepatic) L. donovani. In reconstituted mice, acquired resistance was paralleled by the ability of spleen cells to generate high levels of leishmanial Ag-stimulated IFN-gamma and the development of well formed liver granulomas. In contrast, nude mice reconstituted with either L3T4+- or Lyt-2+-enriched immune spleen cells alone failed to control visceral parasite replication and did not develop effective granulomas despite the finding that transfer of L3T4+ cells largely and Lyt-2+ cells partially restored the capacity to secrete IFN-gamma. To determine whether both T cell subsets were also required in a normal host, nu/+ BALB/c mice were treated with cell-depleting anti-L3T4 and anti-Lyt-2 mAb. Depletion of either T cell subset inhibited the acquisition of resistance to L. donovani and impaired the tissue granulomatous response. Thus, successful T cell-dependent host defense towards intracellular L. donovani and the tissue expression (granulomas) of this mechanism appear to require both L3T4+ and Lyt-2+ cells. A primary role for the L3T4+ cell may be IFN-gamma production; the role of the Lyt-2+ cell and the precise interaction of the two T cell subsets remain to be identified.     

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.     

Induction of granulomatous experimental autoimmune thyroiditis in mice with in vitro activated effector T cells and anti-IFN-gamma antibody.

Experimental autoimmune thyroiditis (EAT) can be induced in mice after the transfer of mouse thyroglobulin (MTg)-sensitized donor spleen cells that have been activated in vitro with MTg. CD4+ T cells are required for the transfer of EAT in this model. Because CD4+ T cells produce various lymphokines, such as IFN-gamma, that may be involved in the activation or regulation of the immune response to MTg and the development of EAT, the present study was undertaken to determine whether a neutralizing mAb to IFN-gamma could modulate the induction or expression of EAT. The anti-IFN-gamma mAb XMG-1.2 had no effect on sensitization of donor cells. However, addition of XMG-1.2 mAb during in vitro activation of MTg-primed spleen cells resulted in more severe EAT in recipient mice. The thyroid lesions in recipients of cells cultured with MTg and XMG-1.2 mAb also exhibited granulomatous changes, which differed qualitatively from the predominantly lymphocytic cell infiltrates in recipients of cells cultured with MTg alone. Recipients of MTg-activated spleen cells also developed severe granulomatous EAT when they were given injections of XMG-1.2 mAb. The effects of XMG-1.2 could be neutralized by IFN-gamma. Recipients of cells cultured in the presence of XMG-1.2 mAb had augmented autoantibody responses, although there were no apparent differences in the IgG subclass distribution of the anti-MTg autoantibody responses. These studies suggest that neutralization of endogenous IFN-gamma results in increased activity of cells capable of inducing granulomatous EAT in mice.     

L3T4-positive T cells participate in the induction of graft-vs-host disease in response to minor histocompatibility antigens

The phenotype of T cells that initiate graft-vs-host disease (GVHD) in response to minor histocompatibility antigens (minor HA) was determined in three H-2 compatible strain combinations by using negative selection with monoclonal antibodies to Lyt-2 and L3T4 antigens to test the hypothesis that Lyt-2-positive T cells alone initiate GVHD. The phenotype of T cells required to initiate GVHD was different in each of the three strain combinations studied. Both Lyt-2+ and L3T4+ LP spleen cells were necessary to cause lethal GVHD in C57BL/6 recipients. In the reciprocal transplant, Lyt-2+, but not L3T4+ C57BL/6 spleen cells were sufficient to initiate GVHD in LP recipients. In contrast, L3T4+, but not Lyt-2+ B10.D2 spleen cells were found to initiate GVHD in BALB/c recipients. The optimal response to minor HA requires both Lyt-2+ and L3T4+ T cells because a mixture of the two subsets of spleen cells resulted in a more severe form of GVHD than either subset alone in all three strain combinations studied. This study demonstrates that L3T4+ cells participate in the initiation of GVHD in response to minor HA. The dominant T cell subset that initiates GVHD varies with the specific strain combination tested. The specific minor HA expressed in the transplant recipient, the H-2 type, and possibly non-major histocompatibility complex immune response genes of the donor strain appear to determine the phenotype of the initiator T cells.     

Expression and functional significance of the J11d marker on mouse thymocytes

Subpopulations of thymocytes have been characterized phenotypically and functionally in relation to their expression of the marker defined by the monoclonal antibody J11d. Cortical-type L3T4+, Lyt-2+ thymocytes are all J11d+. Thymocytes that share the phenotype L3T4-, Lyt-2+ with peripheral Lyt-2+ T cells contain a J11d+ and a J11d- subset. These J11d- cells behave like peripheral Lyt-2+ T cells in two functional assays: they form clonal growth bursts in response to immobilized antibody against the T cell antigen receptor, and they act as precursors of alloreactive cytotoxic T cells. The J11d+ cells are inert in both of these assays. In contrast, L3T4+, Lyt-2- thymocytes do not contain a J11d+ subset.     

Cellular basis of immunologic interactions in adoptive T cell therapy of established metastases from a syngeneic murine sarcoma

The adoptive transfer of specifically sensitized T lymphocytes can effectively mediate the regression of established local and metastatic tumors. Previous experiments using the weakly immunogenic MCA 105 sarcoma indicated that cellular interactions between transferred L3T4+ helper and Lyt-2+ cytotoxic immune T cells were necessary for mediating tumor regression. In this study, the kinetics of T-T cell interactions were analyzed by in vivo depletion of T cell subsets with mAb. The anti-tumor efficacy of transferred immune cells was abrogated by in vivo administration of either L3T4 or Lyt-2 mAb on the day of cellular therapy. However, if mAb were given 3 days after the transfer of immune cells, depletion of Lyt-2+ but not L3T4+ cells abrogated anti-tumor efficacy. T cell depletion on day 6 after transfer of immune cells had no adverse effect on tumor regression, indicating the period required for T cell reactivity in vivo. Furthermore, depletion of Ia+ cells by in vivo mAb treatment abrogated the anti-tumor efficacy of immune cells. It is thus hypothesized that there are two distinct but sequential phases of in vivo T cell interactions leading to the regression of established tumors after adoptive immunotherapy. An initial "helper/inducer" phase apparently requires the interaction of L3T4+ immune cells and the tumor Ag involving Ia+ cells. The inducement of L3T4+ cell activation is to provide helper function via the secretion of IL-2. The second phase designated as an "effector phase" involves differentiation of immune Lyt-2+ cells under the influence of IL-2 secreted during the helper/inducer phase for generation of mature Lyt-2+ effector cells. To further support the hypothesis of a two-phase process we have examined the phenotype and kinetics of tumor regression mediated by effector cells generated by secondary in vitro sensitization (IVS). Although the IVS cells were generated from fresh MCA 105 immune spleen cells, their anti-tumor efficacy was mediated solely by Lyt-2+ lymphocytes. Kinetic studies revealed that the in vivo requirement of IVS Lyt-2+ effector cells to mediate tumor regression was less than 3 days, and the anti-tumor reactivity of these cells was not affected by in vivo depletion of Ia+ cells. Thus, the IVS reaction is likely representative of the in vivo counterpart of the helper/inducer phase leading to the generation of mature Lyt-2+ immune effector cells. Tumor regression after transfer of Lyt-2+ cells generated in IVS therefore required a relatively shorter period of time than that required after the transfer of fresh noncultured MCA 105 immune spleen cells.     

Relationship among function, phenotype, and specificity in primary allospecific T cell populations: identification of phenotypically identical but functionally distinct primary T cell subsets that differ in their recognition of MHC class I and class II allodeterminants

The goal of the present study was to evaluate the relationship among function, Lyt phenotype, and MHC recognition specificity in primary allospecific T cell populations. By using Lyt-2+ and L3T4+ T cells obtained from the same responder populations, we assessed the ability of T cells of each phenotype to generate cytotoxic effector cells (CTL) and IL 2-secreting helper T cells in response to either class I or class II MHC allodeterminants. It was found that a discordance between Lyt phenotype and MHC recognition specificity does exist in primary allospecific T cells, but only in one T cell subpopulation with limited functional potential: namely, Lyt-2+ T cells with cytotoxic, but not helper, function that recognize class II MHC alloantigens. Target cell lysis by these Lyt-2+ class II-allospecific CTL was inhibited by anti-Ia monoclonal antibodies (mAb), but not anti-Lyt-2 mAb, indicating that they recognized class II MHC determinants as their "restriction" specificity and not as their "nominal" specificity even though they were Lyt-2+. A second allospecific T cell subset with limited functional potential was also identified but whose Lyt phenotype and MHC restriction specificity were not discordant: namely, an L3T4+ T cell subset with helper, but not cytotoxic, function specific for class I MHC allodeterminants presented in the context of self-Ia. Thus, the present study demonstrates that primary allospecific T cell populations contain phenotypically identical subpopulations of helper and effector cells that express fundamentally different MHC recognition specificities. Because the recognition specificities expressed by mature T cells reflect the selection pressures they encountered during their differentiation into functional competence, these findings suggest that functionally distinct but phenotypically identical T cell subsets may be selected independently of one another during ontogeny. Thus, the existence of Lyt-2+ CTL specific for class II allodeterminants can be explained by the hypothesis that the association of Lyt phenotype with MHC recognition specificity results from the process of thymic selection that these Lyt-2+ effector cells avoid.     

Frequency analysis of class I MHC-reactive Lyt-2+ and class II MHC-reactive L3T4+ IL 2-secreting T lymphocytes

The reactivity of Lyt-2+ or L3T4+ T cells stimulated with either mutant class I or class II MHC alloantigens was studied. Whereas stimulation with class I MHC antigens induced only Lyt-2+ T cells to proliferate and to secrete IL 2, stimulation with class II MHC alloantigens induced L3T4+ but not Lyt-2+ T cells. When the frequencies of precursors of IL 2-secreting T lymphocytes (IL 2TL-p) were determined by limiting dilution analyses, class I MHC-reactive Lyt-2+ T cells displayed frequencies (f = 1/200) as high in magnitude as those within class II MHC-reactive L3T4+ (f = 1/100). Clonally developing IL 2TL of either T cell subset were antigen-specific, as shown in split-culture experiments. Whereas L3T4+ helper TL could be induced to specific IL 2 secretion over a long time period (days 3 to 9), Lyt-2+ TL showed a marked time optimal on day 4; thereafter, the number of TL colonies inducible to secrete IL 2 decreased steadily. IL 2 production and IL 2TL-p frequencies of unseparated T responder cells were not the numerical superposition of the two individual T cell subsets (Lyt-2+ + L3T4+); the latter finding is likely to reflect regulatory influences of Lyt-2+ T cells on IL 2-secreting L3T4+ T cells.     

Cooperation between humoral factor(s) and Lyt-2+ T cells in effective clearance of Sendai virus from infected mouse lungs

The mechanism of cooperation between the L3T4+ and Lyt-2+ T cell subsets in effective clearance of Sendai virus from infected mouse lungs was studied by adoptive cell transfer using nude mice. Simultaneous transfer of a long-term-cultured Sendai virus-specific L3T4+ T cell line with L3T4+ cell-depleted immune spleen cell (L3T4-) fraction to infected nude mice could result in viral clearance, although single injection with either of these cells was not effective. Instead of the L3T4+ T cells, culture supernatants of the L3T4- T cell line or concanavalin A-stimulated mouse spleen cells and mouse serum immunized with the virus were also active in the cooperative viral clearance with L3T4- fraction. The role of the Sendai virus-sensitized L3T4- cell fraction in cooperative viral clearance with humoral factors could be replaced by neither T cell-deprived immune spleen cell fraction nor normal spleen cells. The 1,500 units of recombinant mouse interleukin 2 (IL-2), which was more than 12 times the IL-2 activity present in the supernatants of the T cell line or concanavalin A-stimulated spleen cells, failed to clear the virus in combination with the L3T4- fraction. Monoclonal antibodies to Sendai or mouse hepatitis viruses were also effective in the cooperative antiviral activity. IL-2 activity was not detected in these monoclonal antibodies and the mouse immune serum. Single injection of any humoral factors failed to clear the virus. These results indicate that Sendai virus-sensitized Lyt-2+ subset of T cells acts cooperatively with humoral factor(s) other than IL-2 or Sendai virus-specific antibody present in supernatants of the T cell line, of concanavalin A-stimulated spleen cells or hybridomas, and in mouse serum immunized with the virus.     

Both the Lyt-2+ and L3T4+ T cell subsets are required for the transfer of diabetes in nonobese diabetic mice

The nonobese diabetic mouse is a model of spontaneous type I diabetes mellitus. It is possible to induce diabetes in young, irradiated nonobese diabetic mice by using adoptive transfer of splenocytes or splenic T cells obtained from diabetic donors. This study demonstrates that the induction of diabetes in the adoptive transfer system is dependent on both the L3T4+ and Lyt-2+ subsets of T cells. Neither of these T cell subsets alone mediates the development of severe insulitis or diabetes when adoptively transferred to young, irradiated recipients. In addition, we show that both the L3T4+ and Lyt-2+ subsets must be obtained from diabetic donors in order to transfer diabetes; neither subset can be replaced with cells obtained from young, nondiabetic donors.     

Surface markers of T cells causing lethal graft-vs-host disease to class I vs class II H-2 differences

Information was sought on the phenotype of lymphoid cells causing lethal graft-vs-host disease (GVHD) in irradiated mice expressing whole or partial H-2 differences. In all strain combinations tested, pretreating donor lymph node (LN) cells with anti-Thy-1 monoclonal antibodies (MAb) plus complement (C) abolished mortality. With GVHD directed to class I H-2 differences, pretreating LN cells with anti-Lyt-2 MAb prevented mortality, whereas MAb specific for Ly-1 or L3T4 cell surface determinants caused severe mortality. These data imply that lethal GVHD directed to class I H-2 differences is mediated by L3T4-, Lyt-2+ cells; this subset of T cells was shown previously to control GVHD directed to multiple minor histocompatibility antigens, i.e., antigens seen in the context of self-class I molecules. With whole H-2 differences, GVHD appeared to be controlled largely but not exclusively by L3T4+, Lyt-2-T cells. This T cell subset was also the predominant cause of GVHD directed to class II differences. With class II incompatibilities, depleting donor cells of L3T4+ T cells, either by pretreatment with anti-L3T4 MAb + C or by fluorescence activated cell sorter selection, greatly reduced but did not completely abolish GVHD. These data might imply that L3T4-, Lyt-2+ cells have some capacity to elicit anti-class II GVHD. A more likely possibility, however, is that the residual GVHD to class II differences observed with Lyt-2+-enriched cells reflected minor contamination with L3T4+ cells.     

Suppression of Ia-unrestricted primary anti-Qa-1 cytotoxic T lymphocyte responses by class II major histocompatibility complex-restricted cellular interactions

A model has been established for investigating the cellular interactions for the generation and regulation of primary cytotoxic T lymphocyte (CTL) responses to Qa-1 alloantigens. Although NZB anti-BALB/c one-way mixed leukocyte cultures (MLC) generate anti-Qa-1b CTL, anti-Qa-1 CTL responses are not generated during BALB/c anti-NZB one-way MLC or during two-way MLC with NZB and BALB/c spleen cells. However, depletion of L3T4+ cells from the spleens of BALB/c mice before two-way MLC with NZB spleen cells resulted in anti-Qa-1b CTL responses. Likewise, the addition of anti-L3T4 monoclonal antibody (mAb) or anti-I-Ad mAb to two-way MLC with NZB and BALB/c spleen cells resulted in the generation of anti-Qa-1b CTL. Conversely, anti-Lyt-2 mAb inhibited the generation of anti-Qa-1 CTL. These data indicate that class II major histocompatibility complex-restricted cellular interactions are capable of suppressing the generation of Ia-unrestricted anti-Qa-1 CTL responses by Lyt-2+ responder cells. This model provides a novel opportunity to both characterize the cellular interactions responsible for regulating primary CTL responses to the Qa/Tla-encoded class I molecule Qa-1, and determine the contribution of this L3T4+ Ts-dependent defect in NZB mice to the pathogenesis of autoimmunity.     

B cell stimulatory factor 1 (IL-4) enhances the development of cytotoxic T cells from Lyt-2+ resting murine T lymphocytes

B cell stimulatory factor 1 (BSF-1) (IL-4) was shown to synergize with phorbol esters or with monoclonal anti-TCR antibody in stimulation of the development of CTL from small resting murine T cells. IL-2 also synergized with PMA in such differentiation but was less effective than BSF-1. The combination of these two lymphokines with PMA had the most potent effect on the development of CTL. BSF-1 plus PMA stimulated a significant increase in the intracellular content of N-benzyloxycarbonyl-L-lysine thiobenzylester esterase, a granule-associated biochemical marker, whereas IL-2 plus PMA was only marginally effective. Depletion of L3T4+ cells did not result in the abrogation of these effects. Lyt-2+ T cells that were incubated for 72 h with BSF-1 plus PMA accumulated N-benzyloxycarbonyl-L-lysine thiobenzylester esterase and secreted this intragranular marker after interaction with immobilized anti-T cell receptor mAb. These BSF-1/PMA-stimulated Lyt-2+, L3T4- T cells were also able to kill FcR positive target cells in a retargeting assay with a mAb to murine T3 Ag, providing evidence that BSF-1 plus PMA acted directly on precursors of cytotoxic T cells.     

The cellular basis for the Ia restriction in murine experimental autoimmune thyroiditis

Susceptibility to experimental autoimmune thyroiditis (EAT) in the mouse is linked to the I-A subregion of the major histocompatibility complex. EAT can be induced in susceptible strains of mice by immunization with mouse thyroglobulin (MTg) and adjuvant. We have described a cell transfer system wherein spleen cells from EAT-susceptible CBA/J mice primed in vivo with MTg and lipopolysaccharide (LPS) can be activated in vitro with MTg to transfer EAT to naive syngeneic recipients. This cell transfer system was used to elucidate the cellular basis for the I-A restriction in EAT. While the cell active in transferring EAT was Thy 1+ I-A-, depletion of I-A+ cells from the in vitro culture prevented the activation of EAT effector T cells. MTg-pulsed mitomycin C-treated naive syngeneic spleen cells as antigen-presenting cells (APCs) could replace the I-A+ cells in vitro. Allogeneic (Balb/c) APCs were ineffective. Using APCs from several recombinant inbred strains of mice, it was shown that C3H/HEN and B10.A(4R) APCs were effective in activating MTg/LPS-primed CBA/J spleen cells to transfer EAT while B10.A(5R) APCs were ineffective. This maps the H-2 restriction to the K or I-A subregions. Addition of polyclonal anti-Iak or monoclonal anti-I-Ak or anti-L3T4 during in vitro activation inhibited both the generation of EAT effector cells and the proliferative response to MTg. Irrelevant anti-Ia reagents, monoclonal anti-I-Ek, and monoclonal anti-I-Jk were ineffective. Thus the I-A restriction in murine EAT appears to result from an I-A restricted interaction between Ia+ APCs and Ia- EAT effector T cells.     

Higher frequency of Leishmania major-specific L3T4+ T cells in susceptible BALB/c as compared with resistant CBA mice

In previous studies, we reported that a) the adoptive transfer of parasite-specific L3T4+ T cells enhanced rather than inhibited the development of lesions induced by Leishmania major in normal BALB/c mice, and b) the depletion in vivo of L3T4+ T cells by administration of anti-L3T4 monoclonal antibody reversed the susceptibility of BALB/c mice to L. major. To further assess the role of specific L3T4+ T cells in the development of lesions induced by L. major in BALB/c mice, the frequency of parasite-specific T cells capable of mediating specific delayed-type hypersensitivity (DTH) reactivity was determined, by limiting dilution analysis, in the lymph nodes draining the lesions of susceptible (BALB/c) and resistant (CBA) mice. The numbers of L. major-specific DTH-mediating T cells was found to be substantially increased in the lymph nodes of infected BALB/c mice as compared with CBA mice. Moreover in CBA mice, analysis of the cell surface phenotype of the L. major-specific DTH-mediating T cells showed that these cells were equally represented in the L3T4+, Lyt-2-, and L3T4- Lyt-2+ subsets, whereas the majority of these cells in BALB/c mice expressed the L3T4+ Lyt-2- surface phenotype.