The induction of peripheral T cell unresponsiveness in adult mice by monomeric human gamma-globulin

Monomeric human gamma-globulin (HGG), when injected into adult mice, induces a state of specific immunologic unresponsiveness to further challenge with immunogenic forms of HGG. In this report we have directly determined the role of the thymus in the induction of HGG tolerance and the proliferative responsiveness of T cells from normal and HGG-tolerant mice. Draining lymph node T cells were isolated from HGG-tolerized and -challenged mice, and tested for their proliferative response to HGG in vitro. T cells from untreated but challenged adult CBA/CaJ and A/J mice proliferate in response to HGG, whereas such mice given monomeric HGG before challenge fail to show an HGG-specific proliferative response. APC from tolerant or nontolerant mice were equally effective in the support of Ag-specific proliferation of primed T cells. The influence of the thymus gland on HGG-induced T cell unresponsiveness was assessed by determining whether thymectomized mice could be tolerized to HGG. The results suggest that the generation of T cell tolerance to HGG is independent of thymic function as assayed by both antibody production in vivo and T cell proliferation in vitro. Unresponsiveness of T cells from tolerant mice was not a result of the presence of CD8+ cells since removal of CD8+ cells from lymph node T cells did not alter unresponsiveness to HGG in vitro. Further, mixing tolerant T cells with normal HGG-primed T lymphocytes did not inhibit proliferation of the HGG-primed cells. The results of this investigation suggest that this mouse model of tolerance to HGG represents a thymus-independent unresponsiveness of mature peripheral T cells to a nonself-Ag. Understanding the regulation of tolerance to HGG may give additional insight into the mechanisms required for the maintenance and possibly the induction of tolerance to certain self-Ag in peripheral lymphoid organs.     

Macrophage handling of a tolerogen and the role of IL 1 in tolerance induction in a helper T cell clone in vitro

The human gamma-globulin (HGG)-specific helper T cell clone AB.7.D7 can reconstitute the plaque-forming cell response of HGG-primed B cells. Tolerance induction at the level of T cell help results from exposure of the AB.7.D7 cells to 10 micrograms monomeric HGG. The monokine IL 1 was found to interfere with tolerance induction in AB.7.D7 cells in a dose-dependent manner. Furthermore, interference with tolerance induction was dependent upon the T cells being presented with IL 1 at the same time as monomeric HGG, the tolerogen. IL 1 and monomeric HGG could not be demonstrated to interact to make nontolerogenic soluble aggregates, however. It was found that monomeric HGG was unable to stimulate the production of either membrane or secreted IL 1 by splenic macrophages and in addition was not degraded by peritoneal exudate cells. Heat-aggregated HGG, which is highly antigenic and nontolerogenic, is a good stimulus for IL 1 production and is processed by macrophages into peptides of varying sizes. These data are consistent with the suggestion that a tolerogenic signal results from T cell recognition of a nondegraded antigen in the absence of a signal from IL 1. It is possible, however, that small amounts of processed antigen, undetectable by us, are involved.     

B cell presentation of a tolerogenic signal to Th clones.

Lightly irradiated (950 R) splenic B cells were inefficient, in comparison to unseparated spleen cells, in stimulating antigen-specific proliferation of Th1 clones specific for human gamma globulin (HGG). This inefficiency was due to antigen-specific inactivation: Th1 clones preincubated with HGG and lightly irradiated B cells or mitomycin C-treated B cells were unable to proliferate to HGG in secondary cultures. In contrast to Th1 clones, Th2 clones proliferated well in response to B cell APC, and showed no decrease in their subsequent antigen-induced proliferative capacity after exposure to lightly irradiated B cells and HGG. However, preincubation of Th2 with lightly irradiated B cells and HGG did inactivate the capacity of Th2 to provide help for antibody production in secondary cultures. These results suggest that under certain conditions B cells may present antigen to Th1 and Th2 cells in a tolerogenic rather than an immunogenic manner.     

Establishment of unresponsiveness in primed B lymphocytes in vivo

As an approach to examine the influence of the state of cellular activation on the ability to tolerize B cells, the induction of unresponsiveness in human gamma-globulin-(HGG) primed B lymphocytes was studied in an adoptive transfer system. In contrast to transferred normal spleen cells, spleen cells from HGG-primed mice are not readily rendered unresponsive when exposed to the tolerogen, deaggregated HGG (DHGG), in irradiated recipients. A kinetic study showed that unfractionated primed spleen cells do not respond to an antigenic challenge given between 6 and 10 days after cell transfer and injection of DHGG, indicating that they are transiently depressed. In contrast, isolated primed B cells are tolerized when transferred to recipients and treated with DHGG in the absence of T cells. Furthermore, primed B cells exposed to tolerogen in the recipients do not recover the ability to respond to HGG either after a secondary challenge with AHGG given up to 14 days after transfer, or after 2 consecutive challenges given on days 14 and 24 after transfer. The presence of primed T cells at the time of tolerization interferes with the induction of unresponsiveness in these primed B cells. These studies suggest that the presence of primed T cells is responsible for the inability to tolerize unfractionated primed spleen cells populations and that primed B cells themselves are not intrinsically resistant to the induction of unresponsiveness.     

Th1 and Th2 clones differ in their response to a tolerogenic signal.

Th1 and Th2 clones specific for human gamma globulin (HGG) were compared and shown to differ in terms of the effects of tolerance induction on Ag-induced proliferation and helper activity. In developing a method to induce tolerance, splenic APC that had been pulsed with HGG and then fixed with 0.15% paraformaldehyde (HGG-FAPC) were used as a means to present Ag to the Th clones in the absence of costimulatory signals. Both Th1 and Th2 clones recognized HGG-FAPC as evidenced by their ability to proliferate to HGG-FAPC. Unlike Th2, Th1 proliferated to HGG-FAPC only in the presence of T cell-depleted allogeneic spleen cells as a source of accessory cell signals. The inability of Th1 cells to proliferate in the absence of costimulatory signals was due to Ag-specific inactivation: Th1 clones preincubated with HGG-FAPC were unable to proliferate when recultured with HGG and irradiated APC. In contrast to Th1 clones, Th2 clones showed no decrease in their Ag-induced proliferative capacity after exposure to any concentration of HGG-FAPC. However, when examined by using a second assay system, that of providing help for anti-HGG antibody production by primed B cells, Th2 preincubated with HGG-FAPC were markedly inhibited (up to 90%) in their ability to provide help. Preincubation with HGG-FAPC also inhibited the helper activity of the one Th1 clone that was found to induce a significant secondary antibody response. Taken together, the results suggest that exposure of Th1 to tolerogen in the form of HGG-pulsed fixed APC inactivates Th1 proliferative capacity, and possibly Th1 helper activity as well. Exposure of Th2 cells to a tolerogen suppresses the mechanism by which the Th2 cells provide Ag-induced B cell help, but does not inhibit the mechanism by which they proliferate to HGG. Furthermore, the results define a model that incorporates Ag processing as well as Ag presentation in the induction of tolerance in vitro.     

Ability of tolerized Th1 and Th2 clones to stimulate B cell activation and cell cycle progression.

Tolerant and nontolerant murine Th1 and Th2 clones, specific for human gamma-globulin (HGG), were compared for their ability to promote cell cycle entry and progression by B cells in vitro. When stimulated with HGG, nontolerant Th1 and Th2 clones induced similar increases in B cell membrane MHC class II levels--a phenomenon associated with early B cell activation. Nontolerant Th1 and Th2 clones also induced B cell DNA synthesis, an event associated with subsequent G1 phase traversal, although Th2 cells were more efficient than Th1 cells in stimulating this activity. Exposure of Th clones to tolerogen in the form of HGG-pulsed chemically fixed APC inhibited the ability of Th1 clones, but not Th2 clones to promote polyclonal B cell DNA synthesis in HGG-stimulated secondary cultures. However, Th1 clones exposed to tolerogen did not lose their ability to increase the expression of MHC class II molecules on B cells in these cultures. These results indicate that tolerance induction does not inhibit the ability of Th1 clones promote B cell cycle progression. In contrast, exposure of Th2 cells to tolerogen does not inhibit significantly the ability of these cells to stimulate B cell cycle entry or progression.     

Effects of tolerance induction on early cell cycle progression by Th1 clones.

Human gamma-globulin (HGG)-specific mouse Th1 clones exposed to tolerogenic signals provided by HGG-pulsed paraformaldehyde-fixed splenocytes (HGG-FAPC) were analyzed for antigen-induced progression through the early phases of the cell cycle. Exposure of Th1 clones to HGG-FAPC in primary cultures inhibits the ability of the clones to synthesize DNA in response to HGG and normal APC in secondary cultures. The Th1 clones in these secondary cultures were found to be blocked in G1a phase as evidenced by cell cycle analysis and by reduced numbers of cells expressing high levels of IL-2R and TfR. This cell cycle blockade of Th1 cells was not observed if the secondary cultures were stimulated with IL-2-containing Con A CM instead of antigen. These data suggest that in our system the inhibition in antigen-induced cell cycle progression associated with Th1 tolerance induction occurs at the G1a/G1b phase transition.     

Differential abilities of Th1 and Th2 to induce polyclonal B cell proliferation.

Human gamma globulin-specific T helper cell (Th) clones, activated by HGG in the presence of antigen (Ag)-presenting cells, stimulated polyclonal B cell proliferation. Both Th1 and Th2 clones induced B cell proliferation, but Th1 clones were generally 5- to 10-fold less efficient than Th2 in this capacity. Th1 and Th2 each induced proliferation of both small and large B cells, although Th1 induced less B cell proliferation than Th2, regardless of B cell size. Th1-induced B cell proliferation was increased significantly by stimulating the Th1 clones with immobilized anti-CD3 mAb. The B cell response to Ag-activated Th1 clones was also increased by the addition of rIL-4 or culture supernatants from activated Th2 clones, and this enhancement was abolished by addition of anti-IL-4 mAb. The differential capacity of the Th subsets to stimulate B cells could not be attributed to differences in the degree of Ag-induced activation of the Th clones as reflected by Th proliferation or Th expression of activation markers, RL388 Ag, IL-2R, or TfR. Taken together the results suggest that even though Th1 and Th2 are similarly activated by Ag-presenting cells, Ag-activated Th2 interact more effectively with B cells than Ag-activated Th1. It is possible that inefficient interaction and subsequent intercellular signaling between Th1 and B cells results in inefficient Th1-induced B cell proliferation, and that this deficiency may be circumvented by signals (e.g., lymphokines) provided by Th2, or by the stimulation of Th1 with plate-bound anti-CD3 Ab rather than Ag.     

Immunologic unresponsiveness after gastric administration of human gamma-globulin: antigen requirements and cellular parameters

Gastric administration of human gamma-globulin (HGG) into adult A/J mice leads to the establishment of an antigen-specific unresponsive state to subsequent parenteral challenge with HGG. An unresponsive state is induced in both helper T and B lymphocyte populations. Unresponsiveness in helper T cells is of longer duration than in B cells, lasting at least 9 wk after intragastric intubation. Adoptive cell transfer of spleen cells from gastrically inoculated mice into healthy irradiated, syngeneic recipients revealed that the unresponsive state is stable upon cell transfer and that suppressor cells are present in the spleens of gastrically tolerized mice. The establishment of HGG-specific unresponsiveness is dependent upon both the dose and the form of the antigen adminstered. Soluble and deaggregated HGG are both more efficient than is heat-aggregated HGG in inducing unresponsiveness gastrically. The administered HGG is rapidly eliminated from the animal and only a small fraction reaches the circulation as immunoreactive protein. Although the cellular parameters of the systemic unresponsiveness induced by intragastric intubation with HGG appear similar to the parameters of parenterally induced unresponsiveness, the precise mechanisms by which gastric unresponsive states are established remain to be resolved.     

Successful priming and tolerization of T cells to orally administered antigens in B-cell-deficient mice

B cells have been shown to function as APCs capable of inducing both T cell priming and tolerization. Recently, B cells were also revealed to be essential in the organogenesis of Payer's patches (PPs), which have been supposed to play an important role in the initiation of mucosal immune responses. In this study, we examined the roles of B cells in T cell response to orally administrated antigen using B-cell-deficient mice. It was revealed that (1) both a single high dose and repeated low doses of orally administered OVA successfully induced tolerance of T cells in B-cell-deficient mice and (2) oral administration of OVA with cholera toxin successfully primed T cells in B-cell-deficient mice. Thus, it was revealed that B cells are not required for both priming and tolerization of T cells to orally administered antigens. These results also contradict the supposed roles of PPs in mucosal immune responses.     

Antigen-specific and nonspecific mediators of T-cell/B-cell cooperation. VI. Distinct patterns of cross-reactivity by two human gamma-globulin-primed helper T-cell subpopulations.

We have previously characterized the activities, in vitro, of two different helper T-cell subpopulations, primed with human γ-globulin (HGG). One T-cell subpopulation helps the response of B cells to determinants (e.g., haptens) bound to the same antigen to which the T cells are primed (specific help); the other helper T-cell subpopulation responds to the same priming antigen by secreting a nonspecific molecule which helps B-cell responses to erythrocyte antigens co-cultured with the priming antigen (nonspecific help). These subpopulations also differ in their frequency and dose response to antigen, both in vivo and in vitro. They are similarly susceptible to the induction of unresponsiveness to HGG. In order to determine whether these T-cell subpopulations share or differ in their ranges of antigen recognition, we have compared the reaction of these two HGG-primed helper T-cell subpopulations to a number of γ-globulins (γG's) from other species. Plaque-forming cells generated in response to HGG shared little or no cross-reactivity with any of the heterologous (γG's) tested. In contrast, HGG-primed nonspecific helper T cells responded with significant cross-reactivity when challenged in vitro with dog γG, but HGG-primed specific helper T cells did not respond with any such cross-reactivity. No other heterologous γG tested stimulated any significant cross-reactivity from either HGG-primed T-cell subpopulation. Thus, these two T-cell subpopulations differ in their antigenic recognition. Possible explanations of these data include: (i) a difference in receptor specificity; (ii) a difference in the receptor affinity; (iii) a difference in Ia determinants of the two subpopulations.     

Interference with tolerance induction of primed B cells by the Fc fragment of immunoglobulin

The capacity to interfere with tolerance induction in primed B cells was examined. Previous work had shown that TNP-specific splenic B cells from mice primed and boosted with TNP-KLH are highly susceptible to in vitro tolerization upon a brief exposure to TNP on a carrier unrelated to KLH. In the present work it was found that tolerance induction in these primed B cells could be partially disrupted by addition of the Fc fragment of immunoglobulin, a B-cell mitogen, and adjuvant, during exposure of the B cells to tolerogen. Addition of Fc fragments prepared by papain digestion of human IgG interfered with tolerization routinely in approximately 30-60% of the spleen cells susceptible to tolerogen. Addition of whole IgG or Fab fragments had no effect on tolerance induction. As little as 5 micrograms/ml of the Fc fragment preparation significantly interfered with tolerization and 32-64 micrograms/ml was optimal. Disruption of tolerization was most effective when the Fc fragment was added to the spleen cells either 4 hr prior to tolerogen or simultaneously with tolerogen; addition of the Fc fragment 4 hr after exposure to tolerogen was significantly less effective. Disruption of tolerization by the Fc fragment was not through polyclonal activation of B cells, as antigen was required for generation of significant numbers of PFC to TNP. Also, disruption was not through expansion of low avidity clones of B cells insusceptible to tolerogen, as the avidity of the antibody produced with and without Fc fragments present was approximately the same. These results show that the Fc fragment of IgG can partially interfere with tolerization of primed B cells. The manner in which Fc fragments may function to prevent tolerization through its lymphoid cell stimulatory capacities is discussed.     

Induction of peripheral T cell tolerance by antigen-presenting B cells. II. Chronic antigen presentation overrules antigen-presenting B cell activation

Ag presentation in the absence of danger signals and Ag persistence are the inductive processes of peripheral T cell tolerization proposed so far. Nevertheless, it has never been definitively shown that chronic Ag presentation per se can induce T cell tolerance independent of the state of activation of APCs. In the present work, we investigated whether chronic Ag presentation by either resting or activated B cells can induce tolerance of peripheral Ag-specific T cells. We show that CD4(+) T cells that re-encounter the Ag for a prolonged period, presented either by resting or activated Ag-presenting B cells, become nonfunctional and lose any autoimmune reactivity. Thus, when the main APCs are B cells, the major mechanism responsible for peripheral T cell tolerization is persistent Ag exposure, independent of the B cell activation state.     

Differential susceptibility of cytotoxic and helper T cell precursors to neonatal tolerization to histocompatibility antigens

The ability of various (C57BL/6J X CBA/HT6T6)F1 spleen cell subpopulations to induce tolerance to allogeneic histocompatibility antigens after injection into neonatal CBA/HT6T6 mice was examined. The requirements for tolerization of cytotoxic T lymphocyte precursors (CTLp) and IL 2-producing helper T cell precursors (IL 2Tp) appear to be coordinated but not identical. CTLp frequencies measured in limiting dilution analysis (LDA) were found to be decreased by 90 to 99% in mice injected neonatally with unseparated or a variety of semiallogeneic spleen cell fractions, including T cells, T cell-depleted spleen, the Ig+ and Ig- fractions of nylon-adherent, T-depleted spleen cells, Sephadex-G10 (G10)-nonadherent spleen cells, and T-depleted allogeneic C57BL/6J spleen cells. In contrast, IL 2Tp showed tolerization only after neonatal injection of unseparated or T cell-depleted F1 spleen cells, and not after injection of T or B cells or of G10-nonadherent or T-depleted allogeneic spleen cells. These studies show that the CTLp and IL 2Tp compartments have different requirements for neonatal tolerization, which appear to correlate with the presence of cells expressing class I or class II alloantigens in the inoculum: all spleen cell types tested were capable of tolerizing the CTLp compartment, whereas only whole spleen and T-depleted spleen cells could tolerize IL 2Tp; donor T cells, although capable of inducing CTLp tolerance, are not necessary for either CTLp or IL 2Tp tolerance induction; Ig+ B cells alone are marginally effective in tolerization of IL 2Tp, and G10-nonadherent cells are ineffective, suggesting that macrophages or another type of G10-adherent accessory cell may be required for tolerization of IL 2Tp, although it is not clear whether they are sufficient; and tolerization of CTLp can occur in the presence of a normal IL 2Tp compartment when certain inocula, such as T cells, are used for tolerance induction at birth.     

Functional heterogeneity among human inducer T cell clones

Analysis of mouse CD4+ inducer T cells at the clonal level has established that a dichotomy among CD4+ T cell clones exists with regard to types of lymphokines secreted. Mouse T cell clones designated Th1 have been shown to secrete IL-2 and IFN-gamma, whereas T cell clones designated Th2 have been shown to produce IL-4 but not IL-2 or IFN-gamma. To determine if such a dichotomy in the helper inducer T cell subset occurred in man, we examined a panel of human CD4+ helper/inducer T cell clones for patterns of lymphokine secretion and for functional activity. We identified human T cell clones which secrete IL-4 but not IL-2 or IFN-gamma, and which appeared to correspond to murine Th2 clones. In marked contrast to murine IL-2 secreting Th1 clones which do not produce IL-4 or IFN-gamma, we observed that some human T cell clones secrete IL-2, and IFN-gamma as well as IL-4. Southern blot analysis indicated that these multi-lymphokine-secreting clones represented the progeny of a single T cell. IL-4 secretion did not always correlated with enhanced ability to induce Ig synthesis. Although one T cell clone which secreted IL-2, IL-4, and IFN-gamma could efficiently induce Ig synthesis, another expressed potent cytolytic and growth inhibitory activity for B cells, and was ineffective or inhibitory in inducing Ig synthesis. These results indicate that although the equivalent of murine Th2 type cells appears to be present in man, the simple division of T cells into a Th1 and Th2 dichotomy may not hold true for human T cells.     

Induction of peripheral T cell tolerance by antigen-presenting B cells. I. Relevance of antigen presentation persistence

Various mechanisms of peripheral T cell tolerization have evolved to avoid responses mediated by autoreactive T cells that have not been eliminated in the thymus. In this study, we investigated the peripheral conditions of Ag presentation required to induce T cell tolerance when the predominant APCs are B cells. We show that transient Ag presentation, in absence of inflammation and in a self-context, induces CD4(+) T cell activation and memory formation. In contrast, chronic Ag presentation leads to CD4(+) T cell tolerance. The importance of long-lasting Ag presentation in inducing tolerance was also confirmed in the herpes stromal keratitis autoimmune disease model. Keratogenic T cells could be activated or tolerized depending on the APC short or long persistence. Thus, when APCs are B cells, the persistence of the Ag presentation itself is one of the main conditions to have peripheral T cell tolerance.     

Activated self-MHC-reactive T cells have the cytokine phenotype of Th3/T regulatory cell 1 T cells

In the present study, we show that human self-MHC-reactive (autoreactive) T cell clones are functionally distinct from Ag-specific T cell clones. Self-MHC-reactive T cells exhibited helper function for B cell Ig production when cultured with non-T cells alone, and they exhibit suppressor function when cultured with PWM- or rCD40 ligand (rCD40L)-activated non-T cells, whereas tetanus toxoid (TT)-specific clones exhibited only helper function in the presence of TT with or without PWM or rCD40L. Addition of neutralizing Abs to the cultures showed that the suppression was mediated by TGF-beta but not by IL-10 or IFN-gamma. The self-MHC-reactive clones also inhibited proliferation of primary CD4+ T cells and TT-specific T cell clones, but in this case the inhibition was mediated by both IL-10 and TGF-beta. In further studies, the interactions between self-MHC-reactive T cell clones and non-T cells that led to suppressor cytokine production have been explored. We found that prestimulation of non-T cells for 8 h with PWM or for 48 h for rCD40L results in non-T cells capable of inducing self-MHC-reactive T cell to produce high levels of TGF-beta and IL-10. In addition, these prestimulation times coincided with peak induction of HLA-DR and costimulatory B7 molecule (especially CD86) expression on B cells. Finally, addition of CTLA-4/Fc or blocking F(ab')2 anti-CTLA-4 mAb, plus optimally stimulated non-T cells, to cultures of self-MHC-reactive clones inhibited the induction of TGF-beta but not IL-10 or IFN-gamma production. In summary, these studies show that activated self-MHC-reactive T cells have the cytokine phenotype of Th3 or T regulatory cell 1 and thus may be important regulatory cells that mediate oral and peripheral tolerance and prevent the development of autoimmunity.     

T cell tolerization in vitro: modulation of helper and suppressor cell activities

This paper analyzes the conditions for in vitro tolerization of purified whole T cell populations and the consequences on helper and suppressor T cell functions. Highly purified splenic T cells from adult DBA/2 mice were incubated in vitro for 24 hr with high doses of trinitrophenyl coupled to human gamma-globulins (TNP-HGG). A profound inhibition of the TNP-specific helper function of these T lymphocytes was observed in a cooperative culture with normal purified splenic B cells and TNP-SRBC as antigen. This state of specific unresponsiveness was maintained after trypsin treatment of the cells, at the end of the 24-hr incubation with the tolerogen. We checked that this procedure removed the vast majority of F23.1 T cell receptor determinants from the cells. This result indicates that T cell receptors for antigen were not merely blocked by the tolerogen. In addition, B cells preincubated with tolerized T cells for 24 hr remained as responsive to TNP as B cells mixed with normal T cells in similar conditions. This demonstrates that the decreased response is not the result of secondary B cell tolerization. In addition, anti-Ia monoclonal antibodies were shown to block the induction of tolerance. We also showed that tolerized T cells significantly decreased the anti-TNP response of normal T and B cells in vitro, whereas the anti-SRBC response in the same cultures was unaffected. When tolerized T cells were separated into Lyt-2- and Lyt-2+ cells, it was found that tolerized Lyt-2- cells had lost about 75% of their helper activity and that Lyt-2+ cells suppressed 70% of the response of a normal T and B cell culture. Thus, in vitro induction of T cell tolerance results in a specific T cell unresponsiveness which is due to both helper T cell inactivation and induction of specific suppressor T cells.     

Defective B cell tolerance induction in New Zealand black mice. I. Macrophage independence and comparison with other autoimmune strains

B cell unresponsiveness was examined in vitro by using spleen cells from autoimmune NZB, BXSB/Mp male, MRL/Mp-Ipr/Ipr (MRL/l), and control mice, and the tolerogen trinitrophenyl human gamma-globulin (TNP-HGG). The B cell subset responsive to TNP-Brucella abortus in each autoimmune and control strain that was tested was highly susceptible to tolerance induction with the use of high epitope density conjugates (TNP30HGG and TNP32HGG). When a tolerogen with a lower epitope density was used (TNP7HGG), several control strains were all rendered tolerant in a thymic-independent and hapten-specific manner. NZB B cells were resistant to all concentrations of TNP7HGG tested, whereas B cells from BXSB/Mp male and MRL/1 mice were resistant to low concentrations of this tolerogen. NZB mice were resistant in addition to tolerance induction with TNP9HGG, TNP10HGG, and TNP12.7HGG. Experiments were performed to determine whether splenic macrophages played a role in resistance to tolerance in NZB mice. The mixing of NZB and control DBA/2J T cell-depleted splenocytes revealed no modulatory effects by the accessory cells in culture. Moreover, B cells rigorously depleted of macrophages by double Sephadex G-10 column passage exhibited characteristic patterns of resistance or susceptibility in NZB and control strains, respectively. These findings support the conclusion that resistance to tolerance in NZB mice is determined at the B cell level and are consistent with the hypothesis that diverse immunoregulatory disturbances contribute in varying degrees to the development of systemic lupus erythematosus in different inbred strains of mice.     

Suppression of antibody synthesis by CD4+ T cell clones and normal T cells stimulated with monoclonal anti-CD3 antibody

CD4+ve Th1 clones, as well as normal splenic T cells, were found to suppress LPS-driven antibody secretion in a non-Ag-specific and non-MHC-restricted manner when the T cells were activated with the anti-CD3 mAb, 145-2C11. Suppression was observed with both primed and naive B cells, as well as with purified hapten-specific B cells, a result that suggests a direct effect of anti-CD3-activated T cells on B cell differentiation. Th1 clones activated by cognate Ag also suppressed LPS-driven antibody secretion. Furthermore, suppression of LPS-driven antibody secretion could be achieved across a cell-impermeable porous membrane when T cells were activated with anti-CD3. Suppression by Th1 clones and by normal T cells could not be attributed to a concomitant decrease in B cell proliferation or to a shift in the kinetics or isotype of the antibody response. These data demonstrate that CD4+ve Th1 clones, as well as normal T cells, can effect suppression of polyclonal antibody formation.