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.     

Defective B-cell tolerance in New Zealand black mice. Fc receptor-independence of resistance to low-epitope-density tolerogens

Trinitrophenyl (TNP) human gamma-globulin with low-epitope-density tolerizes B cells from normal BDF1 mice in a Fc gamma receptor-dependent manner but does not tolerize B cells from preautoimmune NZB mice. In order to investigate the relationships between tolerance induction and epitope density independently of Fc gamma receptor function in these two strains, TNP conjugates of two additional thymic-independent tolerogenic carriers, D-glutamic acid-D-lysine (D-GL) and carboxymethyl cellulose (CMC), were tested. A brief pulse with low-epitope-density conjugates such as TNP4.4-D-GL rendered unfractionated or T-cell-depleted spleen cells from BDF1 but not NZB mice tolerant in a hapten-specific manner. Spleen cells from NZB mice, however, were susceptible to tolerization with TNP13.5-D-GL. NZB mice were also resistant to tolerance induction in vivo with TNP5.5-D-GL, TNP3-CMC, and TNP6-CMC, all of which tolerize BDF1 mice in vivo. Both strains were tolerized with TNP13.5-D-GL and TNP13-CMC in vivo. NZB mice were also significantly less susceptible to tolerance induction with TNP3-CMC when TNP-Ficoll was substituted for TNP Brucella abortus as the challenge antigen. These findings militate against the possibility that an Fc gamma receptor defect is the principal mechanism of resistance of NZB B cells to tolerance induction with-low-epitope density conjugates.     

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 depolarization is induced in tolerant B lymphocytes by stimulation with antigen

Membrane depolarization is one of the earliest events in activation of cells by ligand receptor interaction. It is known that crosslinking of antigen-specific Ig receptors on B cells by antigen can induce membrane depolarization and subsequent Ia antigen expression on the cell surface. To determine whether a tolerance-inducing form of the antigen can also induce membrane depolarization after Ig receptor binding we used splenic B cells enriched for dinitrophenyl (DNP)-specific cells and determined relative membrane potential in these cells after binding of DNP-murine IgG2a (MGG) (tolerogen) or antigens (DNP-keyhole limpet hemocyanin (KLH) and DNP-Ficoll). Relative membrane potential was determined by loading the cells with the dye, 3.3-dipentyloxacarboxyanine (DiOC5(3)) after 2 hr incubation with ligand and determining relative fluorescence intensity on the fluorescence-activated cell sorter (FACS). Carriers alone did not depolarize these normal cell populations, but 100% of DNP-specific cells were depolarized by DNP-KLH and DNP-MGG while 85% were depolarized by DNP-Ficoll. To determine if tolerant B cells could be depolarized by antigen we induced tolerance in vitro or in vivo with DNP-MGG and measured the depolarization of DNP-specific B cells in response to antigens and tolerogen. DNP-specific B cells made tolerant by DNP-MGG underwent membrane depolarization when incubated with either DNP-KLH, DNP-MGG, or DNP-Ficoll but not with carriers alone. These data suggest that tolerogen induces membrane depolarization equally as well as antigen in normal cells. In addition, tolerant cells can be depolarized by Ig receptor crosslinking with either antigen or tolerogen. Thus, tolerance does not block the early membrane events induced by antigen in B cells.     

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.     

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.     

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.     

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.     

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.     

The Florey lecture, 1986. The regulatory biology of antibody formation

The regulatory biology of antibody formation entered a new phase of study with the development of selective theories of immunity. The discovery of the 'one cell - one antibody' dogma and the demonstration that only a small minority of B cells possessed receptors specific for a given antigen were consistent with Burnet's clonal selection hypothesis, which was later formally proven by preparing antigen-specific lymphocytes and inducing clonal activation in vitro. Clonal analysis has aided precise study of immunoregulation for both B and T lymphocytes. Clonal activation of B cells in the absence of T cells is now possible with high cloning efficiency. It requires the combined action of certain antigens and growth factors, collectively termed B-cell stimulatory factors (BSFS). Single cell analysis has shown that most BSFS so far tested, in contrast to most claims in the literature, possess the capacity (in synergy with antigen) to: stimulate B cells out of the G0 phase into active cell cycle; promote sequential mitotic divisions; and induce differentiation to active secretory status. This is clearly true for IL-1, IL-2, and BSF-p2. These multiple actions resemble those of the colony-stimulating factors in haemopoiesis. Regulation of antibody production by T lymphocytes can also be profitably analysed in clonal systems. The immunoregulatory problem of tolerance can also be analysed by means of clonal techniques. Studies are summarized which indicate that T-cell-mediated suppression and functional silencing of toleragen-specific lymphocytes are both cooperatively involved in many tolerance models. For the B lymphocyte, tolerance can be induced without an actual deletion of the cell involved; rather, the tolerant cell appears to have received and stored a negative signal, rendering it unresponsive to normally immunogenic stimuli. Thus, a state termed 'clonal anergy' has been induced within the cell. Functional clonal deletion has also been noted in several models to T-lymphocyte tolerance, but here it is not known whether clonal anergy or actual death of the relevant cell is at work. Self-tolerance sufficient to be consistent with good health need not mean a total absence of cells with any degree of self-reactivity. Indeed, it is clear that some B cells capable of forming antibody with some degree of affinity for self-constituents exist in the body, and can be activated, for example by lipopolysaccharide. The requirement is to limit the amount, affinity and duration of autoantibody production. A model suggesting how this may be achieved is presented.     

Macrophage-like suppressor cells in rats. I. Inhibition of natural macrophage-like suppressor cells by red blood cells

When trinitrobenzenesulfonic acid (TNBS), the reactive form of trinitrophenyl (TNP) hapten, is injected into a mouse, a brief intrinsic B-cell tolerance to TNP has been shown to result. Yet antigen-binding cells (ABC) with receptors for TNP persist in the TNBS-treated animal.After treatment with Pronase under conditions preserving cell recovery and viability, 80–90% of TNP-ABC failed to bind antigen. After 2 hr in vitro, Pronase-treated 4-day immune TNP-ABC displayed significant recovery of antigen binding, whereas nonimmune TNP-ABC performed the same feat by 18 hr. However, TNP-ABC tested 2 to 11 days after TNBS failed to replace digested receptors by 18 hr in vitro. Thirty days after TNBS, they had recovered this ability. This defective receptor replacement by TNP-ABC was not reversed by colchicine, and was not shared by the sheep-erythrocyte ABC of the same animals, which replaced receptors normally. When challenged with antigen (TNP-sheep erythrocytes) simultaneously with TNBS, recovery by 2 hr was evident on Day 11. When challenged with antigen 4 days after TNBS, receptor regeneration had returned to normal by the next day, and partial recovery of the anti-TNP plaque-forming cell response was evident 4 days later.Thus, the inability to replace receptors and immune unresponsiveness coincides in time, so that a causal relationship between these two defects may be hypothesized. This result contrasts with the membrane locking defect, previously described in the TNP-ABC of TNBS-treated animals, which far outlasted the unresponsive state.     

In vitro studies of the genetically determined unresponsiveness to thymus-independent antigens in CBA/N mice.

The X-chromosome-linked B lymphocyte defect of CBA/N mice has been studied in vitro by comparing the ability of (CBA/N X DBA/2)F1 (X-/X- X X+/Y) male (X-/Y) and female (X-/X+) spleen cells to respond to the thymus-independent antigen DNP (or TNP)-AECM-Ficoll. (CBA/N X DBA/2)F1 male spleen cells failed to generate significant in vitro anti-TNP antibody responses to DNP- or TNP-AECM-Ficoll, in contrast to spleen cells from F1 female (X-/X+) mice which responded normally to these T-independent antigens. Spleen cells from male F1 mice responded almost as well as F1 female cells to the thymus-dependent antigen, TNP-sheep red blood cells (TNP-SRBC) in vitro. Adding F1 male cells to F1 female cells failed to reduce the response of the latter to DNP-AECM-Ficoll, suggesting that the inability of F1 male cells to respond was not due to active suppression. The response of F1 male spleen cells to TNP-SRBC was not impaired by adding high concentrations of TNP-AECM-Ficoll indicating that the mechanism of unresponsiveness was not tolerance induction in all TNP-specific precursors. Lymphocytes from F1 male mice were capable of forming anti-TNP antibody after stimulation with lipopolysaccharide (LPS) in high concentrations; DNP-AECM-Ficoll had no effect on this polyclonal response. B lymphocytes from mice bearing only the X-chromosome of the CBA/N strain thus display a profound defect in B cell activation. This functional defect may represent either an inability of the defective B cells to be activated by thymus-independent antigens or the absence of a sub-class of B cells which respond to thymus-independent antigens.     

Depressed Cellular Formation of Antibody to Shigella Antigens In Vitro by Spleen Cell Cultures from Unresponsive Mice

Specific antibody plaque-forming cells (PFC) to Shigella-soluble antigen did not appear in spleen cell cultures from Shigella-tolerant mice, as occurred with similar cultures prepared from normal mice immunized with Shigella antigen prior to sacrifice. Cultures from tolerant mice also failed to form serologically detectable amounts of agglutinins in vitro. Exposure of cell cultures from tolerant mice in vitro to additional antigen had little or no effect on appearance of plaque-forming cells to Shigella. Spleen cells from normal control mice formed readily detectable levels of antibody, as well as specific antibody plaque-forming cells, after similar stimulation with antigen either in vivo or in vitro. The absence of antibody-forming cells in cultures prepared from spleens of tolerant mice was specific since such cultures, as well as those from normal control mice, formed numerous antibody plaques to unsensitized sheep erythrocytes in vitro after in vivo challenge of the mice with sheep erythrocytes. Tolerance to Shigella antigen, as assessed by absence of antibody-forming cells in vitro, persisted for several months. Spleen cell cultures from tolerant mice less than 3 to 4 months of age did not form significant numbers of antibody plaques, even after in vitro exposure to specific antigen. However, spleen cultures prepared from neonatally treated mice, approximately 6 to 8 months old, formed essentially normal numbers of specific PFC in vitro, indicating that the animals had "recovered" from tolerance and that their lymphoid cells were capable of responding to Shigella antigen in vitro. Absence of specific PFC in cell cultures from tolerant animals supports the concept that tolerance is due to a central failure of specific immunocompetent cells and not due to an inhibitory effect caused by either "excess" antigen or humoral antibody.     

The role of cytoplasmic free calcium concentration in B-cell tolerance

Calcium is an important factor in the immune response. Extracellular calcium is required for antibody production by B lymphocytes. Several investigators have demonstrated that crosslinking of receptors on B lymphocytes by anti-mu antibody induces an increase in intracellular calcium. There are few data on the role of intracellular calcium mobilization or calcium influx in tolerance induction in B cells. We studied changes in free intracellular calcium concentration ([Ca+2]i) induced by exposure of dinitrophenyl (DNP)-specific B cells to the tolerance-inducing conjugate DNP-murine IgG2a (DNP-MGG). Splenic B cells enriched for DNP-specific cells and DNP-specific continuous B-cell lines were used for the studies. Exposure of B cells to the tolerogen DNP-MGG, the antigen DNP-keyhole limpet hemocyanin (DNP-KLH), or the antigen DNP-Ficoll induced an increase in free [Ca+2]i which was due to both mobilization of Ca+2 from endoplasmic reticulum (ER) and influx of extracellular Ca+2. This increase was DNP specific since no significant change was seen with carriers alone and no change was seen in cells that were not DNP specific. The DNP-MGG and DNP-Ficoll induced the same amount of Ca+2 release from ER but the release induced by DNP-KLH was higher. When B cells, which were made tolerant by in vitro incubation with DNP-MGG, were incubated with antigens, a mobilization of Ca+2 from endoplasmic reticulum occurred that was the same as that of nontolerant B cells. Since Ca+2 mobilization is associated with Ig receptor-dependent early B-cell activation, it is likely that the tolerant B cell can still receive an activation signal through the Ig receptors.     

Establishment of an antigen-specific B cell clone by somatic hybridization

Splenic B cells of A/J mice immunized with 2,4,6-trinitrophenyl (TNP)-lipopolysaccharide were fused with 2.52M, a mutant of a B cell line, in the presence of polyethylene glycol and dimethyl sulfoxide. TP67.21, a subclone of a resulting hybridoma, expresses IAk, IEk, IgM, B220, P50, and receptors for C3 fragment of complement, the Fc portion of IgG, and interleukin 2 receptor on the cell membrane; it also possesses receptor molecules for TNP on its surface, derived from TNP-reactive B cells of A/J mice primed with TNP-lipopolysaccharide used for somatic hybridization, by a rosette-forming assay with TNP-sheep erythrocytes. In contrast, parental 2.52M lacks IAk and IEk on the cell membrane and does not bind to TNP-sheep erythrocytes under the same conditions. Thus, it is likely that TP67.21 is an antigen-specific B cell clone directed against TNP. The antigen binding of cells was markedly inhibited by the specific free hapten or anti-IgM antibodies. Interestingly, TP67.21 was induced to generate a significant amount of anti-TNP antibody when treated with TNP conjugates including T cell-independent and -dependent antigens, such as TNP-lipopolysaccharide, TNP-bovine serum albumin, TNP-ovalbumin, and TNP-keyhole limpet hemocyanine in the absence of T cell help, as well as polyclonal activators; this was followed by a marked decrease in the expression of B cell surface markers on the cell membrane. This suggests that the cross-linkage of receptor molecules on TP67.21 by antigen may directly provide a differentiative signal for maturation to a lineage of B cells, and consequently results in the generation of antigen-specific antibodies without T cell involvement.     

A selective defect in IgM antigen receptor synthesis and transport causes loss of cell surface IgM expression on tolerant B lymphocytes.

To explore the biochemical basis for maintaining immunological tolerance by functional inactivation of self-reactive B lymphocytes, transgenic mice carrying rearranged anti-lysozyme immunoglobulin transgenes and a lysozyme transgene were used as a source of large numbers of tolerant self-reactive B cells. Antigen receptors of the IgD isotype were expressed at normal levels on tolerant B cells, contained the heterodimeric MB1/B29 signalling component of the receptor complex and were structurally indistinguishable from IgD on nontolerant B cells. In contrast, cell surface expression of IgM receptor complexes on tolerant B cells was greatly reduced, despite normal expression of mRNA encoding the receptor components. Three-fold fewer immunoreactive mu heavy chains were detectable after a short period of biosynthetic labelling and the immunoreactive mu chains produced were paired with kappa light chains and assembled normally into intact receptor complexes containing the MB1/B29 heterodimer. Nascent IgM receptor complexes nevertheless failed to be processed into an endoglycosidase H-resistant form in the tolerant B cells and thus appeared to be selectively blocked in their transport from the endoplasmic reticulum to the medial Golgi. These findings demonstrate that intracellular trafficking of antigen receptor complexes is regulated by exposure to receptor stimuli at the cell surface causing a long-lasting decrease in surface receptor expression on tolerant B cells.     

Absence of suppression in natural and induced tolerance to F antigen

The role of suppression in natural and induced tolerance to F antigen was investigated in two sets of experiments. In the first, CBA mice were submitted to pretreatments which decrease suppression and the antibody response to self- or allo-F type was investigated. The second set of experiments involved the transfer of spleen cells from tolerized or from naturally tolerant mice into normal mice which were then primed with allo-F, as well as the co-transfer of tolerant and primed lymphocytes into normal mice, to test whether tolerant lymphocytes present suppressor cells. The results indicate that the immune response against allo-F antigen is normally kept in a low level by a suppressive mechanism, and that F-specific suppressor T cells are absent from tolerant mice.Abbreviations used in this paper ATx adult thymectomy - BSS buffered salt solution - CFA Freund's complete adjuvant - CY cyclophosphamide - F.1 type-1 F antigen - F.2 type-2 F antigen - PBS phosphate-buffered saline - RIA radioimmunoassay - Th T helper cell - Ts T suppressor cell     

Cellular aspects of tolerance. II. Unresponsiveness of B cells

The responsiveness of bone marrow cells from tolerant donors was examined by reconstitution of lethally irradiated tolerogen-free recipients. In these animals, stem cells from tolerant donors gave rise to immunologically competent antigen sensitive B cells. The antibody produced by these cells could be detected by a sensitive plaque assay in liquid and by antigen elimination. The antibody was not demonstrable by an assay which only detected plaque forming antibody which was highly avid or was formed in large quantity per cell. In lethally irradiated animals, partially purified B cells from a tolerant animal could not cooperate with T cells from normal donors to reconstitute immunological responsiveness to immunogenic doses of the tolerance inducing antigen. We concluded that antigen sensitive B cells in the bone marrow become unresponsive following administration of tolerogenic forms of antigen. Responsiveness of the reconstituted recipient animals was due to the differentiation of donor stem cells and subsequent antibody production by their descendants. Earlier contradictory findings could be unified in terms of these observations and conclusions.     

Active transformation of tolerogenic to immunogenic signals in T and B cells by 8-bromoguanosine

The injection of deaggregated human gamma-globulin (DHGG) into A/J mice results in the establishment of a state of unresponsiveness to subsequent challenge with immunogenic aggregated human gamma-globulin (AHGG). Administration of the B cell activator 8-bromoguanosine (8BrGuo) 3 hr after administration of DHGG converts the tolerogen to an immunogen and results in an antibody response of even greater magnitude than the primary response elicited by AHGG alone. Adoptive transfer studies with separated populations of T and B cells demonstrated that although transformation of the tolerogenic signal to an immunogenic signal involves effects of 8BrGuo on both T cells and B cells, the major effect appears to be activation of antigen-specific T cells that would otherwise become tolerant. Modulation of T cell tolerance could conceivably be mediated either by direct or indirect mechanisms. Interestingly, optimal responsiveness of B cells from animals treated with DHGG and 8BrGuo is not a T cell-independent event, but requires antigen-reactive T cells. 8BrGuo is not able to override unresponsiveness when given 10 to 20 days after tolerance induction, at a time point when both T and B lymphocytes are tolerant. However, when given at day 60, when T cells (but not B cells) remain tolerant to this antigen, the nucleoside is able to terminate the tolerant state prematurely, possibly by providing an alternate T helper-like signal directly to B cells or by recruiting nonspecific functional T helper cells.