The induction of hapten-specific immunological tolerance and immunity in B lymphocytes. V. Evidence for b-cell deletion in vitro with serum from tolerant mice.

The serum from mice that had been rendered specifically tolerant (TolS) to the trinitrophenyl (TNP) hapten by the injection of trinitrobenzenesulfonic acid (TNBS) is effective in the in vitro induction of immunological unresponsiveness in murine spleen cells. This tolerance system was investigated with particular emphasis upon the mode of induction. The observed inhibition by TolS of responses to the thymic-independent (TI) antigen TNP-lipopolysaccharide (TNP-LPS) was stable following adoptive transfer to lethally irradiated recipients and was due neither to the delay of in vitro responsiveness nor to effector cell blockade at the level of the antibody-forming cell. Neither suppressor cells nor cell-bound tolerogen carry-over were responsible for the tolerance induced by TolS. TNP-LPS doses, including a wide range of polyclonal activating concentrations, were ineffective in reversing the unresponsive state induced by cocultivation with TolS. Additionally, unconjugated LPS in either fetal calf serum (FCS)-containing or FCS-free cultures did not break tolerance. This failure of polyclonal activating substances to reverse the unresponsive state suggests that blockade of TNP-specific receptors is not the mechanism of tolerogenesis, since such compounds trigger cells polyclonally through nonimmunoglobulin receptors. Tolerance induced by incubation of spleen cells with TolS for 24 hr followed by extensive washing was stable whether the immunogenic stimulus was the TI antigen TNP-LPS or the thymic-dependent (TD) form of the hapten, TNP-sheep erythrocytes (TNP-SRC). Washing spleen cells at elevated temperatures after preculturing with TolS to avoid possible reassociation of surface Ig (sIg)-bound TNP conjugates did not lead to escape from tolerance. Antigen-free incubation for 24 hr following cultivation with TolS was equally unsuccessful in reversing the unresponsive state. Thus, extensive washing following tolerance induction and antigen-free cultivation where unblocking or turnover and resynthesis of sIg receptors should have taken place provided no support for receptor blockade as the mode of in vitro induction and maintenance of tolerance by TolS. Treatment with the proteolytic enzyme pronase with the intention of removing potential tolerogen from the cell surface revealed a stable tolerant state. Incubation with anti-Ig or anti-TNP antisera under conditions designed to allow capping and removal of sIg-bound tolerogen or surface-bound TNP conjugates also failed to reverse the tolerance induced by incubation with TolS. The results presented here and previously lend no support to active or passive suppression or blockade of reactive cells as the mechanism of tolerance induction in vitro by TolS. The data are consistent with the hypothesis that TolS-induced unresponsiveness is due to a functional deletion of TNP-specific B lymphocytes. Furthermore, the similarities observed between the induction of tolerance by TNBS injection and TolS-induced unresponsiveness are consistent with the suggestion that TNBS-induced tolerance in vivo is mediated by a component of TolS which is active as a tolerogen in vitro.     

Abnormal expression of surface immunoglobulin isotypes on antigen-binding B lymphocytes from mice tolerant to trinitrophenyl determinants

Temporary B-cell tolerance to the trinitrophenyl (TNP) hapten can be produced in BDF1 mice by intraperitoneal injection of trinitrobenzene sulfonic acid (TNBS). Antigen-binding cells (ABC) specific to TNP, measured as TNP donkey erythrocyte rosettes, are found in tolerant mice as well as in immune mice. We have studied the surface immunoglobulin isotype profile of these TNP-binding lymphocytes (TNP-ABC) in four groups of animals: nonimmune, immune, tolerant, and tolerant-challenged. Immune mice received intravenous TNP sheep erythrocytes (TNP-SRC), whereas tolerant-challenged mice received TNP-SRC and TNBS on Day 0. TNP-ABC from mice immunized with TNP-SRC exhibit increased expression of surface IgG and decreased expression of surface IgD, compared to the ABC from nonimmune mice. Tolerant mice have a higher proportion of ABC with surface IgG, and a lower proportion with surface IgD, than nonimmune mice. Tolerant-challenged mice have a lower proportion of ABC with surface IgG, and a higher proportion with surface IgD, than immune mice. Thus, B-cell tolerance in this model entails an attenuation of the surface immunoglobulin isotype switch (loss of IgD and gain of IgG) on ABC seen in the normal immune response. For most TNP-ABC, tolerogen exposure prevents the switch in surface isotypes normally induced by exposure to TNP antigen; i.e., the tolerance lesion precedes the surface isotype switch. However, a minority of the TNP-ABC appear to switch surface isotypes in response to the tolerogen itself.     

Studies on the resistance to tolerance induction against human IgG in DDD mice. I. Organ differences of tolerogen susceptibility and cellular sites responsible for the resistance.

Cellular sites of the tolerogen resistance in DDD mice against human IgG (HGG) were examined by reconstitution experiments in which cells of various lymphoid organs from tolerized mice were transferred into lethally irradiated syngeneic recipients with or without the supplement of an excess number of untreated T or B cells. It was shown that T cells but not B cells in the spleen and bone marrow-locating B cells were tolerogen resistant. Kinetic profiles of tolerance induction were compared among thymus, lymph node, and spleen T cells. Thymus cells fall into unresponsive state as early as 2 days after the tolerogen (tHGG) injection when only partial tolerance was observed in lymph node T cells. By 1 week of tolerogen treatment, the tolerant state was completed in both thymus cells and lymph node T cells, while spleen T cells showed marked resistance. Tolerance induced in thymus cells and spleen T cells was of relatively short duration and responsiveness was completely recovered by 5 weeks after the injection of tHGG. At this time lymph node T cells still showed hyporesponsiveness. The differences in tolerance inducibility were also shown among different lymphoid organs in tolerogen dose response. Lymph node T cells were very sensitive to tolerance induction, giving no response even by the injection of 0.01 mg of tHGG. Thymus cells were much less sensitive with the gradual loss of responsiveness by increasing the amount of tHGG. In contrast, spleen T cells showed gradual resistance with increasing amount of tHGG, indicating that some positive response was evoked in spleen T cells by a relatively high dose of tHGG. These results seem to suggest that the tolerogen resistance of spleen T cells may be due to their capability of showing positive response against the tolerogenic material. This was also suggested by the fact that the treatment with cyclophosphamide following the tolerogen injection diminished completely the responsiveness against the subsequent challenge immunization.     

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.     

Membrane defects of the tolerant B cell. I. Failure of antigen-induced capping.

In order to study the membrane function of tolerant B antigen-binding cells, tolerance to the trinitrophenyl (TNP) determinant was induced in mice by injecting the reactive form of the hapten, trinitrobenzene sulfonic acid (TNBS). By appropriate transfer experiments, Fidler and Golub (J. Immunol.112, 1891, 1974) had previously shown that this form of tolerance is a B-cell property, induced and expressed in the absence of T cells. Hapten inhibition demonstrated the TNP-specificity of receptors on TNP-donkey erythrocyte(TNP-D)-binding cells in tolerant and nontolerant mice. About 88% of these cells were B cells by immunofluorescence, and the remainder were T cells. In the tolerant mice, challenge with TNP-sheep erythrocytes failed to expand the TNP-binding population, but sheep erythrocyte binders and anti-sheep plaque-forming cells expanded normally. Despite little or no change in TNP-binding cell numbers after tolerance induction, the TNP-binding cells of tolerant animals could not cap their receptors, in contrast to the sheep erythrocyte-binding cells from the same animals which capped normally. Although there is no anti-TNP plaque-forming cell response when tolerogen and immunogen are given simultaneously, capping failure is not evident until 2–4 days after tolerogen exposure. By Day 7, substantial recovery of immune responsiveness had occurred, yet even 12 months after a single dose of tolerogen there was no restoration of capping. Thus despite the association of both capping failure and unresponsiveness with tolerogen exposure, these lymphocyte functional defects appeared not to be causally related.     

Primed lymphoid cell tolerance. II. In vivo tolerization of highly tolerogen-sensitive hapten-primed, potentially IgG-producing B cells

The relative ease of tolerizing IgM-bearing versus IgG-bearing B cells was investigated. Previous work had shown that IgG-bearing trinitrophenyl (TNP)-specific B cells from mice primed and boosted with TNP-keyhole limpet hemocyanin (TNP-KLH) are highly susceptible to tolerization in vitro by TNP presented on an unrelated carrier. TNP-OVA was used as tolerogen, as it may represent a more general class of tolerogens than those which are nonmetabolizable or immunoglobulin containing. This study showed that highly primed B cells are tolerizable in vivo using TNP-OVA, with the IgG response to TNP-KLH easier to tolerize than the IgM response. To determine if the ease of tolerization of the IgG response in vivo was due to intrinsic differences in B-cell precursors of the IgM and IgG responses, tolerance was performed in vitro with B cells of defined surface isotypes. A T-independent antigen, TNP-endotoxin, was employed to minimize T-cell effects. At least 10 times as much TNP-OVA was required to tolerize B cells bearing the IgM surface isotype than those with the IgG surface isotype. Thus, the ease of inhibition of the IgG response as compared to the IgM response in vivo by preexposure to TNP-OVA may be at least partially explained by inherent differences in IgM and IgG B-cell precursors.     

Cellular events in tolerance. V. Detection, isolation and fate of lymphoid cells which bind fluoresccinated antigen in vivo.

The binding of tolerogen to specific receptors of lymphocytes and the subsequent fate of such cells was directly studied in Lewis rats injected with fluorescein-labeled sheep gamma globulin (F-SGG). This tolerogen produced unresponsiveness both in SGG-specific T cells (carrier tolerance) and F-specific antibody-forming cell precursors. The former (T-cell tolerance) was still significant more than 60 days after tolerogen whereas tolerance in the latter (B-cell tolerance) had waned by that time.Cells which have bound the tolerogen (antigen-binding cells, ABC) in vivo were detectable by direct immunofluorescence of washed spleen cell suspensions from rats injected with F-SGG up to 7 days previously. These cells were isolated using antifluorescein affinity columns, and shown to contain immunocompetent precursors for F- and SGG specific responses.The frequency of such ABC was between 30 and 80 per 10⁵ spleen, lymph node or bone marrow cells; no ABC were detected in the thymus. Both Ig positive and Ig negative cells were found to be ABC; Ig negative ABC usually showed a “capped” fluorescent pattern whereas Ig positive ABC generally were “spotted.”By 10 days after injection, ABC were not detectable in the spleen, lymph nodes, thymus or bone marrow of tolerant rats. Furthermore, reinjection of F-SGG after this time did not label any cells. This suggests that antigen-binding cells are not present at this time or that such cells, if available, lack receptors. In contrast, rats previously injected with a lower non-tolerogenic dose of F-SGG or an immunogenic form (F-SGG on bentonite) possessed cells at these later times which could be labeled with F-SGG. Thus, ABC remain detectable following immunogen or a subtolerogeic dose of F-SGG, but disappear in tolerant rats.By approximately 40 days after initial high dose tolerogen injection (when B cell tolerance has started to wane), cells capable of binding a second dose of F-SGG again became detectable. It is suggested that high doses of F-SGG are bound by specific lymphocytes (identifiable as ABC) and that these cells either fail to regenerate new receptors or die. As tolerance begins to wane, either new receptors or new cells are generated.     

Carrier-induced tolerance to nucleic acid antigens.

BALB/c and SJL mice were treated with nucleosides-IgG1 as a tolerogen, before either primary or secondary immunization with nucleosides-keyhole limpet hemocyanin. Nucleoside-specific responses were measured serologically by a modified Farr assay, with either 14C-labeled denatured DNA or nucleosides-131-I-labeled BSA as test antigen. Specificity of the response was tested by hapten inhition experiments. Multiple doses of nucleosides-IgG1 tolerogen given before the primary or secondary immunization effectively suppressed the secondary and tertiary anti-nucleoside responses. The tolerogen did not suppress the response to an unrelated hapten-KLH conjugate. The IgG alone did not suppress the anti-nucleoside response of BALB/c mice to nucleosides-KLH. Single doses of tolerogen before the primary or secondary immunization were less effective. Residual antibody in partially suppressed BALB/c mice showed changes in specificity as compared to controls. Suppression of the secondary response of SJL mice was measured much more readily by binding of nucleosides-131-I-BSA than by binding of denatured DNA. This reflected an altered specificity of the residual antibody; in control animals, antibodies were directed against all four nucleosides, whereas the antibodies of partially suppressed animals were directed only against guanosine. Suppression of anti-nucleic acid antibody responses may have therapeutic application in the management of systemic lupus erythematosus.     

B cell tolerance. I. Analysis of hapten-specific unresponsiveness induced in vitro in adult and neonatal murine spleen cell populations.

The cellular mechanisms and tolerogen dose requirements of hapten-specific unresponsiveness induced in vitro by using 2,4,6-trinitrophenyl human gamma-globulin (TNP17HgG) were analyzed in adult and neonatal murine splenocytes. Tolerance induction in both cell populations was found to be independent of non-B cell effects including BAtheta-positive cells, Ly 2.2-positive cells, adding or reducing the number of macrophages, and large excesses of HgG. The tolerance induced was specific and not "infectious", further excluding a role for suppressor T cells. Neonatal splenic B cells were rendered tolerant by doses of TNP17HgG 1000-fold less than those required to produce similar tolerance in splenic B cells from adults. These findings support the concept of functional clonal abortion as a mechanism for producing tolerance to self antigens.     

The use of haptenated-immunoglobulin molecules to induce tolerance in B cells from neonatal mice

The role of the Fc region of trinitrophenylated (TNP)-immunoglobulins (Ig) in their ability to induce tolerance in immature B cells was examined. With the use of B cells from neonatal mice, tolerogens that could or could not bind to Fc receptors were assessed for their ability to induce tolerance. This was accomplished by tolerizing spleen cells in bulk culture and assessing the degree of tolerance by challenging the cells with the thymus-independent antigen TNP-Brucella abortus (TNP-BA) in limiting dilution cultures. It was found that by using tolerogens containing 10 to 11 haptens per Ig molecule, immature B cells were very susceptible to tolerance induction. Mature B cells were not as susceptible. This increased susceptibility was independent of the Fc portion of the tolerogen, because TNP11-HGG and a TNP10-F(ab')2 induced equivalent degrees of unresponsiveness. When the TNP density was lowered to approximately five haptens per Ig molecule, those Ig molecules that contained Fc portions were superior tolerogens with the use of B cells from 6-day-old mice. Thus, a TNP4-HGG, TNP7-mouse IgG1, and TNP6-mouse IgG2a were more effective tolerogens than either TNP5-F(ab')2 or TNP6-mouse IgG3. These results confirm previous findings that immature B cells are inherently more susceptible to tolerance induction than mature B cells. They also suggest that very lightly haptenated Ig molecules may depend on Fc receptor-binding for effective tolerance induction. Finally, by means of a cytofluorograph, the surface IgD (sIgD) and sIgM phenotypes of splenic B cells from neonates of increasing age were determined. When comparing the phenotype of maturing cells with their tolerance susceptibilities, a correlation between the appearance of sIgD and the acquisition of resistance to tolerance was observed.     

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.     

Regulation of the hapten-specific T cell response. I. Preferential induction of hyporesponsiveness to the D-end of the major histocompatibility complex in the hapten-specific cytotoxic T cell response

In this paper we have examined the phenomenon of hapten-specific tolerance in the cytolytic T lymphocyte (CTL), using the trinitrophenyl (TNP) and azobenzenearsonate haptens. We found that the H-2 K and H-2 D-end restricted CTL in H-2a mice are differentiable in the ease with which they are tolerized to the TNP hapten. With TNP modified syngeneic spleen cells (TNP-SC), or low amounts of trinitrobenzylsulfonic acid as tolerogen, preferential hyporesponsiveness of D-end restricted CTL can be observed. Larger doses of hapten, e.g. a higher amount of trinitrobenzylsulfonic acid, will tolerize both K- and D-end restricted TNP-specific CTL in H-2a mice. The phenomenon of preferential D-end restricted CTL hyporesponsiveness is not observed in H-2d, H-2k, or H-2b mice, nor is it observed in H-2a mice with respect to the azobenzenearsonate hapten. We have also shown that the clones of CTL responsible for lysis of TNP-modified allogeneic targets (cross-reactive lysis) in H-2a mice probably overlap with the D-end restricted TNP-specific CTL since D-end restricted hyporesponsiveness induced by intravenous injection of TNP spleen cells also results in the elimination of cross-reactive lysis of TNP-modified allogeneic targets. The possible mechanisms of preferential D-end hyporesponsiveness to the TNP hapten in the H-2a mice as well as its significance and relationship to previous work in this area are discussed in this paper.     

Immunological tolerance to hapten prevents subsequent induction of hapten-immune pulmonary interstitial fibrosis (HIPIF).

Pulmonary interstitial fibrosis (PIF) is a morphological term which in part can be defined as accumulation of collagen in the extracellular matrix. Previously we showed that hamsters sensitized with 2,4,6-trinitro-1-chlorobenzene (TNCB) developed PIF 14 days after an intratracheal challenge with 2,4,6-trinitrobenzene sulfonic acid (TNBS). The participation of delayed-type hypersensitivity (DTH) in lung collagen deposition was clearly demonstrated. In this paper, we use an adaptation of this model to mice and show that the lung collagen deposition observed was related to the genetic ability of the strain to maintain a DTH response to the immunizing hapten (TNP). Specifically, the lung collagen deposition on Day 14 in hapten-sensitized, challenged animals in high responder to TNP (BALB/c, H-2d) was higher than that in low responder mouse (C57BL/6, H-2b). Furthermore, aged C57BL/6 strain (retired breeders) possessed a DTH response to TNP and produced significantly higher accumulation of hydroxyproline than that of TNBS-challenged-only animals. A DTH mechanism for the induction of the fibrosis is consistent with the observation that responder mice that were made tolerant to the antigen were unable to respond to the lung challenge with a specific increase in lung index or collagen deposition. These results suggest that effector T lymphocytes that are important in DTH play a key role in the regulation of lung collagen deposition in hapten-immune pulmonary interstitial fibrosis (HIPIF) in mice.     

The use of haptenated immunoglobulins to induce B cell tolerance in vitro. The roles of hapten density and the Fc portion of the immunoglobulin carrier

The relationship between the Fc region of trinitrophenylated (TNP)-immunoglobulins (Ig), and their ability to induce tolerance was examined. It was found that adult B cells responding to a T-independent (TI) antigen were tolerized by TNP11 human gamma globulin (HGG), but not by TNP10F(ab')2 fragments of HGG. Increasing the hapten density on the F(ab')2 fragments overcame their inability to induce tolerance. Thus, a TNP17-F(ab')2 was an effective tolerogen. Murine myeloma proteins of different IgG subclasses were similarly tested. A TNP12-IgG2a and a TNP11-IgG1 induced tolerance, whereas two TNP11-12-IgG3 did not. However, a more heavily haptenated TNP18-IgG3 was tolerogenic. These results suggest that lightly haptenated immunoglobulins depend upon Fc receptor binding to induce tolerance in adult B cells. Non-Fc receptor-binding carriers are not tolerogenic unless they are more heavily haptenated. Finally, T cell and macrophage depletion experiments suggest that the tolerogens act directly on the B cells.     

Membrane defects in the tolerant B cell. II. Mechanism of capping failure and reversal by antigen exposure.

The demonstration that TNP-binding B lymphocytes from animals whose B cells have been rendered tolerant to TNP by trinitrobenzene sulfonic acid cannot undergo antigen-induced capping of their TNP receptors for at least a year despite recovery of immune responsiveness has led to a search for the mechanism of the capping failure. Microtubule-dependent membrane “locking” analogous to that induced by concanavalin A appears to afflict the tolerant B cells, in that capping TNP receptors is restored after exposure to 10^?4M colchicine or overnight incubation at 4 °C. Assignment of the defect to the cytoskeleton rather than the receptors themselves is also supported by the observations that enzymatic stripping and regrowth of receptors does not unlock the cell and that non-Ig membrane molecules recognized by antilymphocyte serum also cannot be capped on the tolerant cells. Cells which have remained locked for 4 days to 8 months after a single tolerogen exposure become unlocked 4 days after immunogen is given. Four days after immunogen, tolerogen fails to lock the membranes of TNP-binding cells. These results suggest that tolerogen contact interferes in a much broader range of functions in the TNP-binding cell than those which affect the immune response. Among these effects is a remarkably stable “locked” configuration of the cytoskeleton which is independent of immune responsiveness or receptor turnover, but which can be reversed by exposure to immunogen whether or not an immune response ensues.     

Functional differentiation of T cell precursors. I. Parameters of carrier-specific tolerance in murine helper T cell precursors.

Irradiated mice reconstituted with bone marrow from sheep gamma-globulin- (SGG) tolerant syngeneic donors display reduced IgG responsiveness to challenge with trinitrophenylated (TNP)-SGG compared with recipients of normal marrow. This effect is SGG-specific and is due neither to suppressor T cells nor to antigen carryover. "Helper T cell precursor tolerance" can be induced with as little as 40 micrograms tolerogen (SGG). Unlike mature helper T cells, these precursors show both a rapid induction and rapid waning patterns, suggesting a high rate of turnover. Our results imply that marrow helper T cell precursors bear antigen-specific receptors and that the T cell repertoire must be at least partially generated before residence in the thymus.     

B Cell Tolerance

The mechanisms of B cell tolerance were studied in an attempt to learn whether B cells rendered tolerant are present in the immune system in a potentially responsive form. The author tested the in vitro anti-trinitrophenyl (TNP) antibody-forming cell (anti-TNP AFC) response to TNP-immunogens and polyclonal B cell activators (PBA) of spleen cells taken from mice injected with a tolerogen, TNP-carboxymethylcellulose (TNP-CMC). Spleen cells from mice injected 5 days previously with 10 μg of TNP-CMC did not respond to TNP-sheep red blood cells (TNP-SRBC), T-dependent (TD) antigen or TNP-Ficoll, T-independent (TI) antigen. However, the same spleen cells responded to PBA, lipopolysaccharide (LPS) of Salmonella enteritidis and purified protein derivative (PPD) of BCG. The results indicate that B cells specific for TNP are present in a potentially responsive form. Spleen cells from mice injected with 500 μg of TNP-CMC did not respond to either TNP-immunogens or PBA. The state of unresponsiveness to PBA lasted for 12 days after the tolerogen injection. Responsiveness to PBA reappeared within the short period of 2 days, whereas unresponsiveness to TNP-immunogens lasted much longer. Unresponsiveness to PBA was relieved considerably by treating tolerant spleen cells with the proteolytic enzyme trypsin before in vitro stimulation. These results indicate that B cells rendered refractory are present in the immune system in a potentially responsive form.     

Nucleoside specificity in the carrier IgG-dependent induction of tolerance.

Induction of tolerance to nucleoside haptens in BALB/c mice with isologous IgG conjugates bearing four nucleosides simultaneously (A, G, C, T)-IgG was confirmed. A mixture of separate nucleoside-IgG tolerogens (A-IgG, G-IgG, C-IgG, and T-IgG) was as effective or more effective that the (A, G, C,T)-IgG form in suppressing the response to (A, G, C, T)-KLH. The nucleosides acted independently and simultaneously, since tolerogens with varying combinations of nucleosides caused specific suppression of the respones to only those nucleosides present on the tolerogen. Nucleoside-IgG conjugates did not suppress the response to denatured DNA-methylated bovine serum albumin, in which larger oligonucleotide determinants predominate. In varying combinations, guanosine was the dominant nucleoside both for immunization and for induction of tolerance. After three or four immunizations, control immunized animals made mainly IgG anti-nucleoside antibodies and this IgG antibody formation was preferentially suppressed in tolerogen-treated animals. Tolerance could be established before the primary or secondary immunization and it then persisted for at least 75 days through a fourth course of immunization. The same dosage of tolerogen did not reverse a strongly established anti-nucleoside antibody production after a tertiary response.     

Transmission of hapten-specific tolerance to an unrelated carrier

The principle of linked recognition is well defined in response and suppression. Yet, to our knowledge, it is not explored in the context of tolerance. To investigate, whether the status of tolerance toward a hapten (TNP) can be transferred to a subsequently introduced carrier, animals which were tolerized by a subimmunogenic dose of hapten (TNP) coupled to syngeneic monoclonal anti-TNP IgG, with the rationale of combining the phenomena of low zone tolerance and syngeneic IgG-induced suppression, were challenged with TNP-horse red blood cells (HRBC). Conjugates of high density (40 mM) TNP-syngeneic IgG (TNP40-IgG) were immunogenic and after challenge with TNP-HRBC, animals responded to TNP and to HRBC. Yet, spleen cells (SC) of mice injected with TNP2.5-IgG and challenged with TNP-HRBC were tolerant against TNP as well as the carrier. Limiting dilution (LD) analysis revealed that subimmunogenic doses of TNP coupled to IgG resulted in diminished activation of help, failure to activate contrasuppressor T cells (TCS), and significantly augmented activation of suppressor T cells (TS). On the other hand, after challenge with TNP-HRBC, activation/expansion of carrier-specific helper (TH), suppressor, and contrasuppressor T cells were not affected by previous immunization with subimmunogenic or immunogenic doses of TNP-IgG conjugates, but HRBC-specific TCS could not interact with TNP-specific TS. Hence, to initiate tolerance it was necessary (and sufficient) that an activated and expanded TS population was not counterregulated by TCS. In this situation, an established status of dominance of suppression for the epitope TNP could not be disrupted by an immunogene carrying a multitude of new epitopes; i.e., tolerization by subimmunogenic doses of the individual epitope TNP resulted in unresponsiveness against any immunogen carrying this epitope.     

Modulation of help and suppression in a hapten-carrier system.

Provision of beta-galactosidase (GZ) under defined conditions of dose and time can either help or suppress a subsequent response to trinitrophenyl (TNP)-GZ in CBA/J mice. The optimal helper effect occurs when 10(7) spleen cells from mice primed 9 or more days previously with 10 mug GZ are adoptively transferred to irradiated recipients which are than challenged with 10 mug TNP50GZ. Optimum suppression results from the transfer of spleen cells from mice primed 3 days previously with 100 mug GZ and challenge of recipients with TMP150GZ. Both help and suppression are carrier-specific and mediated by T cells. In experiments where helper or suppressor cells were mixed with normal cells, the anti-TNP response was proportional to the number of primed cells transferred. The results point to a wave of suppression as the initial event after immunization, which is succeeded by period in which the helper effect dominates.