Clonal anergy of memory B cells in epitope-specific regulation.

Immunization of carrier (keyhole limpet hemocyanin (KLH)) primed mice with the hapten-carrier TNP-KLH induces specific suppression for the IgG anti-TNP-response without interfering with the response to epitopes on the carrier molecule. To examine the status of hapten-specific memory B cells from suppressed mice, highly enriched populations of TNP-specific memory B cells were purified from the spleen of TNP-KLH (control) or KLH/TNP-KLH (suppressed) immunized mice and tested in vitro for their ability to respond to TD or TI (TNP-KLH, TNP-LPS) antigenic challenge in presence of a KLH-specific Th cell line. Similar numbers of TNP-specific B cells with the characteristics of memory B cells were obtained from control and suppressed mice. TNP-specific B cells from suppressed mice could be triggered to IgG production by TNP-LPS but had an impaired ability to differentiate into IgG-secreting cells in response to TNP-KLH. This impaired IgG response to TNP-KLH was not due to an active suppression by a subset of TNP-specific B cells, or to an impedence of memory cells to a class switching but to an intrinsic memory B cell defect. TNP-specific B cells from suppressed mice were as efficient as memory B cells from control mice to present TNP-KLH to KLH-specific Th cells and to proliferate in response to T cell help. Our data support the view that the effector mechanism of epitope specific regulation does not interfere with the development of hapten-specific memory B cells but that these cells have an intrinsic defect that prevents their differentiation into active IgG antibody secreting cells in response to a T-dependent antigenic challenge.     

Fractionation of Specific Antigen-reactive Cells in an <Emphasis Type="Italic">in vitro</Emphasis> System of Cell-mediated Immunity

ACCORDING to present concepts the diversity of antibodies is determined by a similar diversity of the precursors of antibody-producing cells. The existence of a diversified cell population in the lymphoid organs was most directly demonstrated by specific adherence of antigen-reactive cells on antigen columns. Antigen-binding cells were specifically eliminated from lymphoid cell populations of both preimmunized^1,2 and non-immunized donors^3–5. The non-bound cells were incapable of producing antibody to the antigen applied on the column, yet they could produce antibody to non-related antigens. Plaque forming cell precursors, plaque forming cells and memory cells towards various antigens were separated^1–5. In all these cases the cells which specifically adhered to the antigenic column were most probably bone marrow-derived lymphocytes (B cells). On the other hand, no such specific adherence was achieved with thymus-derived lymphocytes (T cells), such as those involved in carrier recognition during immunization with hapten carrier conjugates⁶ and in cell-mediated immunity.     

Idiotype and antigen-specific T cell responses in mice on immunization with antigen, antibody, and anti-idiotypic antibody.

Idiotypic determinants of immunoglobulin molecules can evoke both CD4(+) and CD8(+) T responses and exist not only as the integral components of a bona fide antigen binding receptor but also as distinct molecular entities in the processed forms on the cell surface of B lymphocytes. The present work provides experimental evidence for the concept that regulation of memory B cell populations can be achieved through the presentation of idiotypic and anti-idiotypic determinants to helper and cytotoxic cell. The potential of B cells to present antigens to helper and cytotoxic T cells through class II and class I MHC suggests a mechanism by which both B and T cell homeostasis can be maintained. We provide evidence for the generation of idiotype- and antigen-specific Th and Tc cells upon immunization of syngenic mice with antigen or idiotypic antibody (Ab1) or anti-idiotypic antibody (Ab2). The selective activation and proliferation of the antigen-specific Th and Tc cells mediated by idiotypic stimulation observed in these experiments suggests a B-cell-driven mechanism for the maintenance of antigen-specific T cell memory in the absence of antigenic stimulation, under certain conditions.     

Regulation of the anti-alpha(1----3) dextran IgG antibody response of BALB/c mice by idiotype-specific T suppressor lymphocytes.

The immune response of BALB/c mice against the so-called thymus-independent bacterial Ag alpha(1----3) dextran (Dex) is restricted to the expression of few major idiotypes (Id). It is furthermore under the control of T lymphocytes which regulate the isotype expression in such a way that they prevent anti-Dex IgG antibody production upon immunization. At the same time these T cells are part of a regulatory system for Dex-specific B cell memory formation. The underlying Ts cell activity has previously been analyzed by using euthymic and athymic congenic animals. Now we have isolated CD4-positive Id-specific T cell lines and clones which by several criteria are representatives of the above Ts cells. They inhibit in vitro proliferation and antibody secretion of Dex-specific hybridoma B cells. They prevent Id-restricted in vivo IgG anti-Dex antibody formation in T cell-reconstituted BALB/c nu/nu mice. At the same time they enforce, again Id-specific, accumulation of Dex-specific B memory cells. As has been shown previously under the influence of splenic Ts cells, these B memory cells are arrested in the original host but can be expanded and activated for anti-Dex IgG antibody formation upon adoptive transfer into X-irradiated allotype congenic nonresponder BALB.Ighb mice. The data show that the regulatory influence of T cells on the anti-Dex response is Id specific. It can now be studied by means of cloned Ts cells.     

Analysis of somatic mutation and class switching in naive and memory B cells generating adoptive primary and secondary responses

Clonal progeny of naive B cells (producing a primary antibody response) and of memory B cells (producing a secondary response) were identified in a cell transfer system. Primary response clones are typically derived from IgM precursors and express unmutated V regions. Multiple isotype switches occur in these clones. Secondary response clones derive from IgG1 precursors and express highly mutated V regions. Additional switches do not occur. With one exception, there was no evidence for somatic mutation during clonal expansion. The generation of mutated memory cells may thus represent a distinct differentiation pathway. Evidence is presented that, in this pathway, mutants that have lost antigen binding specificity but that remain available for stimulation by a different antigen arise upon antigenic stimulation.     

The affinity threshold for antigenic triggering differs for tolerance susceptible immature precursors vs mature primary B cells

The specificity of antibody responses is dependent on the extent to which a given antigen selectively stimulates cells from within a diverse B cell repertoire. Previous studies have shown that the triggering of B cells by T cell-dependent antigens is a highly discriminatory process, and that tolerance induction of immature B cells by antigen is equally discriminatory. This symmetry in the requirements for stimulation and tolerance induction could provide a basis for the capacity of antibody responses to discriminate among foreign antigens and yet minimize self recognition. The extent to which this potential for discriminate recognition is applicable to the mature immune system remains controversial, because B cells reactive to self antigens have been identified and, in addition, several investigators have identified heteroclitic immune responses, such as the response to NP of Ighb mice, wherein antibodies are found with higher affinities for analogues of the immunogen than for the immunogen itself. To further investigate the capacity of B cells to discriminate among closely related antigenic determinants, we analyzed the fine specificity and idiotypic distribution of monoclonal antibodies derived from both splenic B cells and immature sIg- bone marrow B cell precursors stimulated in fragment culture with NP-Hy and its structural analogues NIP-Hy and NNP-Hy. The results indicate that the majority of responsive B cells discriminate among these haptenic determinants; however, lambda-bearing B cells responsive to the NP and NIP determinants represent a highly overlapping set of clonotypes. Comparison of the responses to NP-Hy and NIP-Hy of splenic vs sIg- precursors of this clonotype family suggests that the T cell-dependent stimulation of both mature and immature B cells by antigen is highly affinity dependent. Significantly, the affinity thresholds for both stimulation and tolerance induction of immature B cells appears to be higher than that required for the stimulation of mature splenic B cells. Such a disparity in the requisites for triggering mature vs immature B cells could readily account for the presence of low-affinity self-reactive B cells in the mature B cell pools of normal individuals.     

Studies of antibody affinity in plasmacytoma-bearing mice: Evidence for a maturational defect of B lymphocytes

The antibody response of plasmacytoma-bearing mice (PC-mice) is severely reduced. In order to understand the nature of the effect of the tumor on the cells making antibody, quantitative and qualitative studies of the humoral response of PC-mice were undertaken. In these studies, the affinity of the antibody produced by tumor-bearing and normal mice was compared to determine whether the small amount of antibody produced by PC-mice is the product of a normal or an altered population of B cells. Antibody to TNP-Ficoll made by PC-mice 3 days after immunization was less heterogeneous and of an affinity lower than that of antibody made by normal mice. However, at 7 days, the antibody made by PC- and normal mice did not differ significantly. These data suggest that, prior to antigenic stimulation, the B cells of PC-mice are relatively immature, reflecting a possible retardation in the generation and turnover of B lymphocytes. The process of antigen-driven selection of high-affinity antibody-producing cells, however, appears to function normally in PC-mice. These studies, then, reveal a qualitative as well as quantitative defect in the primary humoral response of PC-mice which may reflect an abnormality in the development and differentiation of B cells in these mice.     

Transfer of memory cells into antigen-pretreated hosts. I. Functional detection of migration sites for antigen-specific B cells.

The distribution of functionally active hapten-specific B memory cells was investigated. Using antigen-pretreated lethally irradiated recipients, a marked accumulation of adoptively transferred B memory cells was demonstrated in lymph nodes containing specific antigen, but not in lymph nodes containing non-cross-reacting hapten conjugates. This difference in responsiveness between lymph nodes containing specific versus those containing nonspecific antigen developed over a period 3–5 days after memory cell transfer. The localization of antigen specific cells was T-cell independent; both carrier-primed T helper cells and specific antigenic challenge, however, were required to trigger the localized B memory cells into antibody production. Specific B memory cell accumulation did not result from an expansion of the antigen-specific cell population due to local proliferation induced by antigen depots in the lymph nodes to challenge. Rather, the results indicated that recirculating B memory cells had progressively accumulated through retention by antigen in the lymph node. These findings suggest that, in the absence of T-cell help and specific antigenic challenge, B memory cells accumulate in lymphoid tissue (follicles) without responding and provide persistent local memory for the humoral immune response.     

Biologic activity of antigen receptors artificially incorporated onto B lymphocytes

We describe a method for incorporating monoclonal antibody molecules onto viable murine lymphocytes and summarize the biologic activity of these artificial receptors on B cells. Mouse spleen cells incubated overnight with palmitate conjugates of a monoclonal anti-DNP IgA (protein 315) in the presence of deoxycholic acid incorporate about 50,000 antibody molecules per cell. When concentrations of deoxycholate and palmitoyl-protein 315 are carefully controlled, this labeling procedure does not affect the viability or the normal functions of the receptor-decorated cells. The incorporated antibody specifically binds DNP-antigens, although it appears to be unable to communicate directly with internal cellular components. Yet when these receptor-decorated, unprimed cells are challenged with any one of several DNP-antigens, up to 42,000 per 10(6) B cells differentiate into Ig-secreting cells. This response is about 23-fold greater than that induced in normal cell cultures and is of the same magnitude as that induced by the polyclonal B cell activator LPS. This, in addition to the observation that only about 3.6% of receptor-decorated B cells responding to DNP-conjugated polymerized flagellin (DNP-POL) produce hapten-specific antibody, demonstrates that these antigens cause polyclonal B cell differentiation. Normal spleen cells in the presence of DNP-POL and irradiated spleen cells bearing the artificial receptors do not exhibit the polyclonal antibody response. Also, the response of receptor-decorated B cell is blocked by high but nontoxic concentrations of the nonimmunogenic hapten DNP-lysine. These observations demonstrate that the polyclonal B cell response in this system requires the binding of antigen to artificial receptors on functionally viable cells. The polyclonal B cell response to a thymus-dependent antigen DNP-conjugated bovine gamma-globulin (DNP-BGG) requires the presence of the carrier-primed T cells. On the other hand, T cell depletion by anti-Thy-1.2 monoclonal antibody and complement causes only a slight reduction in the number of receptor-decorated B cells that respond to the relatively thymus-independent antigen DNP-POL. This type of phenomenon is also seen with natural antigen-specific B cells. Thus, polyclonal activation of receptor-decorated B cells exhibits the same gross helper cell requirements as antigenic activation of natural antigen-specific B cells. The results of this study are discussed in the context of the role of membrane-bound surface Ig in antigen-dependent B cell activation.(ABSTRACT TRUNCATED AT 400 WORDS)     

B lymphocyte regulation of the immune system. I. In vivo biologic activity of the novel lymphokine, B cell-derived enhancing factor (BEF)

B cell-derived enhancing factor (BEF) is a lymphokine of B cell origin which was originally identified and characterized by its ability to enhance in vitro antibody responses, an effect shown to be due to the ability of BEF to reduce the activation of suppressor T cells. The present study was undertaken to determine whether BEF could also be active in modulating antibody responses in vivo. The data presented here demonstrate that BEF is biologically active in vivo, as manifested by significantly enhanced primary IgM and IgG antibody responses in mice that were either injected with BEF prepared exogenously or implanted with growing BEF-secreting cells of a B cell line. Moreover, BEF was shown to enhance subsequent development of immunologic memory in mice pretreated with BEF at the time of primary immunization; these mice then displayed enhanced secondary responses when challenged with the same antigen some weeks later. The mechanism by which BEF exerts biologic activities to positively modulate in vivo antibody responses and immunologic memory reflects the ability of BEF to modulate one or more T cell functions, as evidenced by the following findings. 1) Transient in vitro exposure to BEF of T cells, but not of B cells, endowed such cells with the capacity to adoptively transfer enhanced primary antibody responses to irradiated recipients. 2) Utilizing adoptive in vivo antibody responses, in which fractionated B cell or T cell populations were obtained from BEF-pretreated mice, revealed that one effect of BEF which results in enhanced immunologic memory is related to its activity on T cells during the priming phase of the immune response. Finally, the existence of this B cell-derived lymphokine and the demonstration of its in vivo regulatory effects on the immune system provide yet another example of the emerging biologic importance of B lymphocytes in the overall regulation of the immune system.     

Reaginic antibody formation in the mouse. VI. Suppression of IgE and IgG antibody responses to ovalbumin following the administration of high dose urea-denatured antigen.

The major antigenic determinants in ovalbumin molecules (OA) were lost following denaturation in 8 M urea. The urea-denatured antigen (UD-OA) failed to combine with anti-OA antibody, but was capable of priming mouse T cells specific for OA. BDF₁ mice primed with alum-precipitated OA were given three intravenous injections of 100 μg UD-OA at 3, 5, and 7 days after the primary immunization. The treatment with UD-OA suppressed both IgE and IgG antibody responses to OA. The same treatment of OA-primed animals with intravenous injections of OA resulted in suppression of IgE antibody response but enhanced IgG antibody response. Intravenous injections of either OA or UD-OA suppressed both IgE and IgG anti-DNP antibody responses of DNP-OA-primed animals but failed to suppress anti-hapten antibody responses to DNP-keyhole limpet hemocyanin. The effect of the treatment on helper T cells and B memory cells in OA-primed animals was studied by adoptive transfer experiments. The results showed that the OA-treatment as well as UD-OA-treatment suppressed the development of both helper function of T cells and B memory cells in the spleen, but the UD-OA treatment was more effective than OA-treatment for the suppression of B cell development. Possible mechanisms for the suppression of the development of immunocompetent cells were discussed.     

The mouse mutant "motheaten." II. Functional studies of the immune system.

Motheaten mice have normal levels of T lymphocytes but reduced levels of B lymphocytes. Those B cells that are present show an impaired proliferative response to B cell mitogens and no plaque-forming cell response to thymus-independent antigens. T lymphocyte function is also defective in motheaten mice, as assayed by the proliferative responses to T cell mitogens, and by the capacity to develop cytotoxic killer cells against allogeneic cells. Motheaten mice possess spleen cells capable of suppressing normal B cell responses to thymus-independent antigens. This suppressor cell is not sensitive to anti-Thy-1 antibody plus complement treatment but is partially removed by adherence on plastic. Overall, the motheaten mouse suffers a functional severe combined immunodeficiency of both B and T cells, even though these cells are present. We postulate that the inescapable lethality of the motheaten defect is due to the lack of immunocompetence during the critical developmental period before adulthood and perhaps to an autoaggressive component as well.     

A mathematical model in immunoregulation where the spleen has a pivotal role.

A simple mathematical model is introduced to investigate collaborative interactions between thymus-derived T and bursal-influenced B lymphocytes in the presence of specific antigen, intravenously presented. Such encounters are assumed to lead to humoral antibody response, and antigen interacting to produce effector T cells in the absence of B cells is assumed to produce cell mediated immunity. The model is used further to consider (i) the resultant distribution of effector T cells, (ii) the effect of splenectomy on collaborative T-B cell interactions, and (iii) recent data relating to portal cirrhosis, sickle cell anemia, malignant lymphomas, and diseases involving an impaired thymic function.It is concluded that for soluble antigen, such T-B cell encounters normally predominate in the spleen, as compared with the lymph nodes. Developing principles of immunoregulation may be applied to the theoretical basis of the model.     

CD40 stimulation of human peripheral B lymphocytes: distinct response from naive and memory cells

During secondary immune response, memory B lymphocytes proliferate and differentiate into Ig-secreting cells. In mice, the binding of CD40 by CD154 clearly enhances the activation and differentiation of memory B lymphocytes. In humans, the role of CD40-CD154 in the stimulation of memory B lymphocytes is not as obvious since in vitro studies reported positive and negative effects on their proliferation and differentiation in Ig-secreting cells. In this study, we examine the response of peripheral memory and naive cells in relation to the duration of CD40-CD154 interaction. We measured the proliferation and differentiation of both subsets stimulated with CD154 and IL-4 for short- (4-5 days) and long-term (>7 days) periods. Following short-term stimulation, memory B lymphocytes did not expand but represented the only subset differentiating into IgG- and IgM-secreting cells. A longer stimulation of this population led to cell death, while promoting naive B lymphocyte proliferation, expansion, and differentiation into IgM- or IgG-secreting cells. This prolonged CD40 stimulation also triggered naive B lymphocytes to switch to IgG and to express CD27 even in absence of somatic hypermutation, suggesting that these latter events could be independent. This study suggests that naive and memory B lymphocytes have distinct requirements to engage an immune response, reflecting their different roles in humoral immunity.     

Role of the LFA-1 molecule in cellular interactions required for antibody production in humans

The lymphocyte function-associated antigen 1 (LFA-1) has been shown to play a role in various T cell functions in mice and humans including cytotoxicity, and proliferation to allogeneic cells and foreign antigens. These functions have been defined with specific monoclonal antibodies and were additionally confirmed by the investigation of patients with inherited deficiency in membrane LFA-1 expression. In this paper, we report our studies on the potential role of the LFA-1 molecule in T lymphocyte-dependent antibody responses. In a patient with a complete lack of membrane expression of LFA-1, there was no in vivo antibody response to vaccinal antigens such as tetanus, diphtheria toxoids, and polio virus, and no in vivo or in vitro antibody production to influenza virus, whereas serum immunoglobulin levels and antibodies to polysaccharides (isohemagglutinins, antibody to mannan, and a polysaccharide from Candida albicans) were detected in correlation with in vitro production of anti-mannan antibody. The defective antibody response to polypeptides was not secondary to poor antigen-specific T proliferation, because the latter was found to be present. Similarly, in vitro antibody production to influenza virus of normal cells was blocked by several anti LFA-1 monoclonal antibodies specific for the alpha subunit of the molecule, if they were added from the beginning of the culture. The antibody production blockade could be achieved with monoclonal antibody concentrations that partially preserved T cell proliferation. The helper effect of an influenza virus-specific helper T cell clone was also blocked. The targets of the blockade were shown by incubation experiments to be T cells and monocytes. In contrast, anti-LFA-1 monoclonal antibodies had no effect on pokeweed mitogen-induced B cell maturation into immunoglobulin-containing cells and on the anti-mannan antibody production. These combined data demonstrate that the LFA-1 molecule plays a role in T cell dependent antibody production to polypeptidic antigens but not in the antibody response to polysaccharides, although the antibody response to mannan is T cell dependent. It is proposed that the LFA-1 molecule is required to some extent for a antigen-presenting cells-T lymphocyte interaction and for the maintenance of a close association between antigen-specific helper T cells and small resting B lymphocytes. Polysaccharidic antigens that exhibit repetitive antigenic determinants might cross-link membrane immunoglobulins on B lymphocytes, thus allowing B cells to pass through a first step of activation requiring cognate T-B cell interaction.     

Temporal expression of membrane antigens during mouse spermatogenesis.

The temporal expression of cell surface antigens during mammalian spermatogenesis has been investigated using isolated populations of mouse germ cells. Spermatogenic cells at advanced stages of differentiation, including pachytene primary spermatocytes, round spermatids, and residual bodies of Regaud and mature spermatozoa, contain common antigenic membrane components which are not detected before the pachytene stage of the first meiotic prophase. These surface constituents are not detected on isolated populations of primitive type A spermatogonia, type A spermatogonia, type B spermatogonia, preleptotene primary spermatocytes, or leptotene and zygotene primary spermatocytes. These results have been demonstrated by immunofluorescence microscopy, by complement-mediated cytotoxicity, and by quantitative measurements of immunoglobulin (Ig) receptors on the plasma membrane of all cell populations examined. The cell surface antigens detected on germ cells are not found on mouse thymocytes, erythrocytes, or peripheral blood lymphocytes as determined by immunofluorescence and by cytotoxicity assays. Furthermore, absorption of antisera with kidney and liver tissue does not reduce the reactivity of the antibody preparations with spermatogenic cells, indicating that these antigenic determinants are specific to germ cells. This represents the first direct evidence for the ordered temporal appearance of plasma membrane antigens specific to particular classes of mouse spermatogenic cells. It appears that at late meiotic prophase, coincident with the production of pachytene primary spermatocytes, a variety of new components are inserted into the surface membranes of developing germ cells. The further identification and biochemical characterization of these constituents should facilitate an understanding of mammalian spermatogenesis at the molecular level.     

Microinjection of macromolecules into normal murine lymphocytes by means of cell fusion. II. Enhancement and suppression of mitogenic responses by microinjection of monoclonal anti-cyclic AMP into B lymphocytes

Reproducible methods are now available for introducing protein molecules such as antibodies into normal murine lymphocytes by fusion with protein molecule-containing erythrocyte ghosts. Monoclonal antibodies against cyclic AMP were raised by hybridoma technique and packed into erythrocyte ghosts. Then, monoclonal anti-cyclic AMP containing ghosts were fused with splenic B lymphocytes by polyethylene glycol-mediated fusion at various intervals after LPS stimulation. This method made it possible for us to quantitatively microinject antibodies into B lymphocytes. Microinjection of anti-cyclic AMP antibody molecules into lymphocytes at a very early stage of LPS stimulation resulted in a marked enhancement of DNA synthetic responses as well as increased numbers of plaque-forming cells. Intracellular cyclic AMP levels were found to be markedly decreased after microinjection of monoclonal anti-cyclic AMP, suggesting that lowering the intracellular cyclic-AMP level in the B lymphocytes at an early stage of stimulation might have induced the enhanced proliferative as well as differentiative responses to LPS. Similar enhancing effects on cell proliferation were obtained when antibodies were injected 18 hr after stimulation. Microinjection of anti-cyclic AMP at 12 hr after culture, however, inhibited the DNA synthetic responses, and induction of plaque-forming cells was suppressed when anti-cyclic AMP was injected 6 hr after LPS stimulation. The present data suggest the biphasic regulatory roles of cyclic AMP at the early stage of B lymphocyte activation. This approach may be useful in identifying regulatory molecules in B lymphocyte induced by mitogenic or antigenic stimulation.     

Regulatory mechanism of reagin production in mice at the T cell level. I. Suggestive evidence for the generation of class specific PPD-reactive helper T cell population in Mycobacterium-primed cells.

Helper T cell activities specific for purified protein derivative (PPD) generated by immunization with Mycobacterium tuberculosis (Tbc) or PPD were investigated concerning adoptive IgE and IgG antibody responses. It is interesting that preferential triggering activity of IgG antibody response was observed when PPD-reactive cells from mice immunized with Tbc were used as a helper cell source. The selective triggering of IgG B cells by Tbc-primed cells was consistently observed using DNP-primed B cell populations from mice immunized with DNP-carrier conjugate in either ICFA or alum. T cell dependency of helper activity was demonstrated by the fact that treatment of Tbc-primed cells with anti-Thy 1 antiserum plus complement abolished their helper activity. We also demonstrated that purified T cell populations selectively triggerred IgG B cells. Selective triggering of IgG B lymphocytes by Tbc-primed T cells may not be due to the influence of suppressor T cells supposedly present in Tbc-primed cells since this selectivity was not affected by X-irradiation of Tbc-primed T cell populations which may inactivate suppressor T cells. Furthermore, passive transfer of Tbc-primed cells into normal recipient mice, the condition which may detect the suppressor T cell effect much more sensitively in IgE production, or preimmunization with Tbc 2 weeks before, did not suppress primary anti-DNP IgE antibody response to DNP-PPD. Thus, the observations presented here are favorable to the concept of the presence of IgG class-specific helper T lymphocytes. Furthermore, PPD-reactive T cells from mice immunized with PPD itself exerted their helper function for triggering B cells of both IgE and IgG classes. This may also indicate that some of the components associated with Tbc other than PPD might negatively affect the development of PPD-reactive helper T cells specific to the IgE class. The generation of such IgG-specific T cell activity in the presence of Tbc will be discussed in the light of the T cell population involved in the regulation of antibody responses of different immunoglobulin classes.     

Suppressor cells in mice infected with Trypanosoma brucei.

Within 2 to 3 days of infection with Trypanosoma brucei strain S42, the ability of spleen cells from infected CBA mice to mount a primary in vitro antibody response to sheep red blood cells (SRBC) is profoundly reduced, and suppressor cells are generated as detected by cell mixture experiments. Suppressor cell activity lies in the T and adherent cell compartments of spleens from infected mice, but not in the B cell compartment, although antibody responses to a thymus-independent antigen, DNP-Ficoll, are significantly reduced. Suppression of antibody responses of normal spleen cells depends on viable cells from infected mice. The trypanosome, itself, plays no direct role in suppression, and we have ruled out the possibility of antigenic competition as a mechanism of suppression. Our data is consistent with the model of suppressor T cells induced by concanavalin A mitogenesis. We hypothesize that trypanosome antigens may directly stimulate T cells with the concomitant release of factors with affinity for macrophage surfaces thus becoming suppressive for T and B cell responses.