Cell surface antigens and other characteristics of T cells regulating the antibody response to type III pneumococcal polysaccharide

The administration of a subimmunogenic dose of type III pneumococcal polysaccharide (SSS-III) produces an antigen-specific T cell-dependent phenomenon termed low-dose paralysis (immunologic unresponsiveness). This form of unresponsiveness can be transferred by spleen cells obtained 5 to 24 hr after priming, and the suppressive activity of the transferred cells is abolished by prior treatment with monoclonal anti-Lyt-2 and anti-I-J antibody in the presence of complement, indicating that suppression is mediated by a distinct subset of T cells (suppressor T cells). If primed spleen cells are transferred 24 to 72 hr after immunization with SSS-III, however, the resulting antibody response of immunized recipients is enhanced. Greater enhancement is noted when transferred cells, pretreated with monoclonal anti-Lyt-2 antibody plus complement to remove suppressor T cells, are used; such enhancement is attributed to amplifier T cells. These findings indicate suppressor T cells regulate the antibody response to SSS-III by influencing the expansion of SSS-III-specific clones of B cells as well as the expression of amplifier T cell activity; the latter causes B cells to proliferate further in response to SSS-III.     

Effect of concanavalin A on lymphocyte interactions involved in the antibody response to type III pneumococcal polysaccharide I. Comparison of the suppression induced by con A and low dose paralysis.

Concanavalin A (Con A) administered at the time of immunization induces suppression of the in vivo splenic plaque-forming cell (PFC) response to type III pneumococcal polysaccharide (SSS-III). As with low dose paralysis of the PFC response to SSS-III, Con A-induced suppression could not be demonstrated in congenitally athymic (nu/nu) mice and could be eliminated partially by treatment with anti-lymphocyte serum (ALS). The kinetics for Con A-induced suppression paralleled those for low dose paralysis of the antibody response to SSS-III. These findings support the view that Con A-induced suppression is produced in vivo by suppressor T cells and that this form of suppression shares with low dose paralysis a common pathway through which suppression is mediated.     

Effects of concanavalin A-induced cells on the proliferative response of T cells. Concanavalin A-induced suppressor and amplifier cells to the proliferative response of human T cells to trinitrophenyl-modified autologous lymphocytes.

Effects of Con A-induced human mononuclear cells on the proliferative response of peripheral T cells were examined by using TNP-modified autologous lymphocytes as stimulator cells. Cells induced by incubation with Con A contained both suppressor cells and amplifier cells. The former were induced from nylon wool-nonadherent T cells and these precursor cells were sensitive to mitomycin treatment. On the other hand, amplifier precursor cells were nylon wool-nonadherent T cells and were resistant to mitomycin treatment. Cell proliferation was required for the induction of suppressor cells but not for the induction of amplifier cells. Con A-induced suppressor effector cells were both nylon wool-adherent and nonadherent cells, on the contrary, Con A-induced amplifier effector cells were nonadherent cells. A small number of macrophages enhanced the suppressive activity of nonadherent T cells when added at the induction phase of suppressor T cells.     

Human suppressor T cells induced by concanavalin A: suppressor T cells belong to distinctive T cell subclasses.

Human peripheral blood lymphocytes were stimulated by concanavalin A (Con A) and then evaluated by their suppressive activity for thymus-derived (T) cell- and bone marrow-derived (B) cell-proliferative responses to mitogen and allogeneic cells. Con A-activated T cells markedly suppressed these responses, but Con A-activated B cells failed to demonstrate suppressor activity. Discontinuous bovine serum albumin (BSA) density gradient separation of T cells which had been activated by Con A demonstrated that a fraction containing blast cells as well as fractions containing unproliferated cells manifest the same degree of suppressor capabilities. However, when density gradient separation of T cells followed by subsequent incubation with Con A was performed, fractions of proliferating cells of low density exhibited no suppression; a fraction containing high density T cells produced marked suppression, but this fraction incorporated only little thymidine in response to Con A. Thus, these studies indicate that Con A-induced suppressor T cells belong to a distinctive subpopulation which has already been programmed to express this function before exposure to Con A and that cell proliferation may not be a prerequisite for the development of such suppressor T cells.     

Regulation of the antibody response to type III pneumococcal polysaccharide. V. Ontogeny of factors influencing the magnitude of the plaque-forming cell response.

Mice of different ages were evaluated with respect to their ability to give a plaque-forming cell (PFC) response to Type III pneumococcal polysaccharide (SSSIII), as well as the degree of amplifier and suppressor thymus-derived(T) cell activity present. Although the magnitude of the PFC response to an optimally immunogenic dose of SSS-III for 2-and 3-week old mice was only 7% and 14%, respectively, of that produced by adult (8-week old) mice, values comparable to those of adult animals were attained by 4 weeks of age; no significant changes in the ability to respond to SSS-III occurred thereafter. Amplifier T cell activity, which was minimal at 2 to 4 weeks of age, matured slowly and did not reach a maximum until 8 to 10 weeks of age. By contrast, suppressor T cell activity appeared to be fully developed at least as early as 2 weeks of age; here, the inhibitory effects produced could by abrogated by depletion of T cells, indicating that the unresponsiveneness induced by such cells does not result in the depletion ot irreversible inactivation of B cells capable of responding to SSS-III. These findings suggest that the inhibitory effects of suppressor T cells are predominant in young mice and that such cells may play an important role in determining the ease with which unresponsiveness is induced in neonates, and in the prevention of autoimmune disease. Also, studies conducted with adult-thymectomized mice showed that both amplifier and suppressor T cells, once seeded to the periphery, are stable and do not depend upon the presence of intact thymus for the expression or renewal of their activity.     

Sensitivity of amplifier T cells involved in the antibody response to type III pneumococcal polysaccharide to anti-lymphocyte serum.

Amplifier T cells responsible for enhancement of the antibody response to type III pneumococcal polysaccharide have been shown to be resistant to the effects of antilymphocyte serum (ALS) given at the time of immunization, a treatment that eliminates suppressor T cell activity. The resistance of amplifier T cells to ALS can be attributed to the fact that their activity develops after that of suppressor T cells. ALS given 1 or 2 days after immunization does abrogate amplifier T cell activity, independent of the mode by which that activity is elicited. The data emphasize the importance of kinetic considerations in understanding the effects produced by immunologically active agents such as ALS.     

Characteristics of amplifier T cells involved in the antibody response to the capsular polysaccharide of type III Streptococcus pneumoniae

Amplifier T cell activity can be transferred by spleen cells harvested 72 hr after priming with type III pneumococcal polysaccharide (SSS-III) and can be abolished by treating the transferred cells with monoclonal anti-Lyt-1, or anti-Thy-1 antibodies in the presence of complement; thus, amplifier cells represent a distinct subpopulation of T cells. Amplifier T cells were found to be sensitive to irradiation but not to treatment with cyclophosphamide. When amplifier cells were transferred to athymic nude (nu/nu) mice, the enhancement obtained was much greater than that produced in thymus-bearing (nu/+) mice; this is presumably due to the lack of suppressor T cell activity in nu/nu mice that enables amplifier T cell activity to be expressed more fully. Amplifier T cells also were found to be present in peripheral blood; these amplifier T cells were Lyt-2- in phenotype. Although the induction and activation of amplifier T cells appear to be antigen-specific, the product made by amplifier T cells may not be antigen specific in its mode of action. Because amplifier T cells can be induced and activated by exposure to immune B cells, specificity is presumably due in whole or in part to the ability of amplifier T cells to recognize the idiotypic determinants of B cell-associated antibody specific for SSS-III.     

Neonatal infection with mouse thymic virus: effects on cells regulating the antibody response to type III pneumococcal polysaccharide.

Mice infected neonatally with mouse thymic virus (TA) were evaluated at different ages with respect to their ability to give a plaque-forming cell (PFC) response to type III pneumococcal polysaccharide (SSS-III), as well as the degree of amplifier and suppressor thymus-derived (T) cell activity present. B cell activity matured rapidly from 2 to 4 weeks of age and was not affected by TA infection. Amplifier T cell activity matured progressively over the first 8 weeks of life and was transiently suppressed in TA-infected mice at 4 weeks of age. Suppressor T cell activity measured at 2,4, and 6 weeks of age was unaffected by TA. The findings suggest that TA is highly tropic for T cells and has selective effects on subpopulations of T cells.     

Effect of splenectomy on the expression of regulatory T cell activity.

The effect of adult splenectomy on the expression of suppressor and amplifier T cell activity was examined with respect to the serum antibody response to Type III pneumococcal polysaccharide (SSS-III) by using a sensitive radioimmunoassay. Suppressor T cell activity, as measured by the degree of low-dose paralysis induced, was not impaired in the least by splenectomy; however, amplifier T cell activity was almost completely eliminated within 7 days after splenectomy. These findings indicate that suppressor T cell activity is not confined solely to the spleen, the major site of antibody synthesis after immunization with SSS-III, and that the spleen may be an important site for the generation and/or maintenance of amplifier T cell activity.     

Production of soluble suppressor factor by spleen cells from mice immunized with type III pneumococcal polysaccharide

Supernatant fluid (SF) derived from spleen cell cultures, obtained from mice 16 hr after immunization with 0.5 microgram of Type III pneumococcal polysaccharide (SSS-III), suppressed the antibody response when SF was given (i.v.) 3 hr before immunization with SSS-III. Such suppression was antigen specific and could be reproduced by SF derived from cultures of T cells from mice immunized with SSS-III (0.5 microgram) or by SF derived from cultures of spleen cells from mice primed with a subimmunogenic dose of SSS-III (0.005 microgram). Adsorption of SF with SSS-III covalently bound to a Sepharose 4B column did not alter the ability of SF to suppress the SSS-III-specific antibody response. However, adsorption of SF with Ig+ (B) cells from mice immunized with 0.5 microgram SSS-III completely removed the suppressive activity. Significant (p less than 0.05) suppression of the antibody response was observed only when SF was administered (i.v.) 24 hr before to 24 hr after immunization with 0.5 microgram of SSS-III. These results suggest that suppressor T cells generated in response to SSS-III function by releasing a soluble factor(s) that binds to determinants on B cells rather than antigen; this soluble factor(s) acts directly on antigen-stimulated B cells or inhibits the induction of amplifier T cells.     

Lectin-induced modulation of the antibody response to type III pneumococcal polysaccharide

Several lectins were tested for their capacity to alter the antibody response to type III pneumococcal polysaccharide (SSS-III). The antibody response was enhanced by concanavalin A (Con A), phytohemagglutinin (PHA), as well as lectins from Phytolacca americana (Pa-2), Pisum sativum (PSA), and Lens culinaris (LCH), when these lectins were given 2 days after immunization with SSS-III; however, suppression was obtained when Con A and Pa-2 were given at the time of immunization. By contrast the lectins from Vicia villosa (VVL) and Bauhinia purpurea (BPA) did not alter the antibody response. Since the lectins PSA and LCH bind to the same monosaccharide as Con A, whereas the other lectins bind to different monosaccharides, these findings indicate that there is no relationship between nominal monosaccharide specificity and the capacity to modulate the antibody response. Substantial increases in the magnitude of the IgG₁ antibody response was noted after the administration of Con A whereas profound enhancement of IgG_2a antibody response was noted after PHA was given.     

Activation of human B lymphocytes. III. Concanavalin A-induced generation of suppressor cells of the plaque-forming cell response of normal human B lymphocytes.

Con A-induced suppression of the direct PFC response to polyclonal stimulation in human B cells has been described. Two types of experiments are presented. First, Con A was added directly to PWM-stimulated PB or tonsil cells resulting in a dose-dependent suppression of the PFC response, with maximal suppression occurring at a Con A concentration of 10 mug/ml. This suppression is completely removed by the simultaneous addition of alphaMM to the cultures. Secondly, Con A stimulation of tonsil or PB lymphocytes generated a population of cells which when added to autologous lymphocyte cultures induced a marked and reproducible suppression of the PFC response. The generation of suppressor cells is dependent on cell division and is blocked by alpha MM. Once generated the process of suppression is indpendent of the presence of Con A itself and is mediated by an activated lymphocyte population. These studies demonstrate a simple and reproducible model for the generation of a population of suppressor cells capable of inhibiting the direct PFC response to PWM-induced polyclonal activation of normal human B lymphocytes.     

Transferred B cells from autoimmune NZB/N mice fail to activate T suppressor cells

T-cell-mediated suppression of the antibody response of autoimmune NZB/N mice to Type III pneumococcal polysaccharide (SSS-III) can readily be induced in situ by priming with a subimmunogenic dose of SSS-III; however, the transfer of either "young" (8 weeks old) or "old" (42 weeks old) SSS-III-primed B cells, which activates suppressor T cells in normal BALB/cByJ mice, fails to induce suppression of the antibody response in recipient NZB/N mice, regardless of the number of cells transferred or the time interval between transfer and immunization. Transfer of 51Cr-labeled B cells demonstrated that syngeneic primed B cells home to the spleens of NZB/N mice in somewhat lower numbers than in BALB/cByJ mice, although the differences observed may not be sufficient to explain the complete absence of activation of suppressor T cells. These findings suggest that B cells from autoimmune NZB/N mice are unable to activate T suppressor cells upon transfer; this disorder in a normal regulatory mechanism may be important in the pathogenesis of disease.     

Expression of GAT-715 idiotype by GAT-specific plaque-forming cells from various strains of mice

The splenic plaque-forming-cell (PFC) response of mice to immunization with pneumococcal capsular polysaccharide (SSS-III), coupled with T-cell activation by phytohemagglutinin (PHA), is characterized by enhanced numbers of IgG-producing cells, largely restricted to the IgG2a and IgG2b subclasses. In contrast, immunization with SSS-III alone results in low numbers of IgG-producing cells, fairly evenly distributed among the subclasses IgG1, IgG2a, IgG2b, and IgG3. The enhanced IgG response and a concomitantly enhanced IgM response are T-cell dependent and occur only if PHA is given 2 days after SSS-III immunization. The absence of immunologic memory to SSS-III in mice previously immunized and treated with PHA implies that enhanced IgG production results from the activation of amplifier T cells and not the helper T cells which are required for memory.     

Regulation of immune response in allogeneic mixed spleen cell cultures. I. Influence of I-region on the generation of suppressor cells

The immune responses of allogeneic mixed spleen cell cultures (MLC) to the T-dependent antigen, SRBC, and to the T-independent antigen, DNP-PAA, were investigated. The immune response to DNP-PAA in MLC with certain strain combinations was always suppressed as compared with the expected PFC response calculated from the PFC responses of the individual strains. This suppression was eliminated by treating the spleen cells with RAMB antiserum plus complement before the incubation of the MLC with DNP-PAA. It can be concluded that the suppression in the PFC response to the T-independent antigen DNP-PAA in MLC is due to the generation of suppressor T-cells. The PFC response to the T-dependent antigen, SRBC, in MLC showed either suppression, no change, or rarely augmenation, suggesting that the allogeneic mixed spleen cell cultures can generate both suppressor and helper T cells and that the balance between helper and suppressor activity regulates the PFC response to a T-dependent antigen. Suppressor activity was also generated in a one-way MLC, but the degree of suppression depended upon which of the two strains was responding. Similar amounts of thymidine were incorporated in the one-way MLR irrespective of which strains was responding. Thus, the extent of proliferation in one-way MLR is not related to the degree of suppressor activity generated. The results further indicate that a difference between two strains in the I-C, S, and G regions of the major histocompatibility complex is required to generate suppressor activitiy that can depress the response to a T-independent antigen, MLC between strains differing in K, I-A, I-B, I-J, I-E, and D regions generate little or no suppressor activity in this system.     

Generation of low-dose paralysis in the absence of the ability to secrete antibody.

(CBA/N female x BALB/c male)F1 male mice carry an X-linked defect, originating from CBA/N mice, which renders them unable to generate an antibody response to SSS-III. Histocompatible (BALB/c female x CBA/N male) reciprocal F1 male hybrids do not carry the X-linked defect and therefore generate a readily detectable PFC response to SSS-III, which can be adoptively transferred into nonresponding reciprocal F1 male mice. In the present work, we show that this adoptive response could be inhibited in recipient (CBA/N female x BALB/c male)F1 male nonresponding mice in which low dose paralysis had been induced. Evidence is presented which indicates that such suppression is of host rather than donor cell origin. The capacity to develop low-dose paralysis, a phenomenon that is antigen specific and has been attributed to the action of suppressor T cells, indicates that nonresponding (CBA/N female x BALB/c male) F1 males (and presumably the CBA/N progenitor strain) have the ability to recognize this antigen. Furthermore, since these animals fail to make a serum antibody response to SSS-III, the signal that activates suppressor T cells cannot be circulating antibody or antigen-antibody complexes. These findings are most consistent with the view that low-dose paralysis of the response to SSS-III is not dependent on antibody-mediated feedback inhibition; rather, it is an active process mediated by suppressor T cells.     

Activation of human B lymphocytes. V. Kinetics and mechanisms of suppression of plaque-forming cell responses by concanavalin A-generated suppressor cells.

The kinetics and mechanisms of suppression of the PWM-induced PFC response of human PB lymphocytes by Con A-activated suppressor cells were investigated. It was necessary that Con A suppressor cells be present early in the process of activation of human B cells toward antibody syntheses, but maximal suppression of the PFC response occurred later in the culture period. In addition, Con A-activated cells, although suppressing the PFC response to PWM greater that 90% of control, did not significantly suppress the blastogenic response to PWM after 3 or 5 days in culture. On the contrary, after 3 days in culture, background tritiated thymidine incorporation as well as tritiated thymidine incorporation to PWM stimulation was increased when Con A suppressor cells are added to fresh autologous peripheral blood lymphocytes. This increased blastogenic response after three days most likely represented an autologous mixed lymphocyte reaction (MLR) or Con A suppressor cells against fresh autologous non-T cells. The induction of autoreactive cells may be one of several modes of suppression of PFC responses by Con A activated suppressor cells.     

The role of antigen in the activation of regulatory T cells by immune B cells

The transfer of B cells from mice immunized with Type III pneumococcal polysaccharide (SSS-III) results in the activation of suppressor and amplifier T cells that control the magnitude of the antibody response in recipient mice, immunized subsequently with SSS-III. Prior treatment of transferred B cells with an excess of enzyme (polysaccharide depolymerase) capable of hydrolyzing SSS-III, does not alter the capacity of these cells to activate regulatory T cells. These findings indicate that the activation of regulatory T cells by immune B cells is not mediated by residual antigen on the surface of transferred cells.     

Selective sensitivity to hydrocortisone of regulatory functions that determine the magnitude of the antibody response to type III pneumococcal polysaccharide.

Previous studies on the basis for the immunosuppressive potential of adrenal corticosteroids have stressed that the effects of these agents on immune functions depend on the animal species being considered, as well as the subpopulations of lymphocytes involved in the expression of immune functions examined. In the present work, we have evaluated the effect of a single dose of hydrocortisone on three different immunoregulatory functions that can influence the magnitude of an antibody response to Type III pneumococcal polysaccharide (SSS-III) in mice; these functions include suppressor, amplifier, and helper activity that are dependent upon the presence of distinct subpopulations of thymus-derived (T) cells. The results obtained show that a single injection of a relatively large dose of hydrocortisone, when given at the time of priming with carrier, eliminated all evidence of carrier-specific helper T cell activity; hydrocortisone was also found to eliminate a significant amount of helper T cell activity when given after such activity had been generated. But, under the same experimental conditions, suppressor and amplifier T cell activities were unaffected, even in this steroid-sensitive species. Such selective sensitivity may account for some of the immunosuppressive potency of steroids.     

Suppressor cells in contact sensitivity. Effect on T cells helping antibody production to picryl chloride.

T cells from mice injected with picryl sulfonic acid have previously been shown to suppress the effector and possibly other phases of contact hypersensitivity reactions to picryl chloride. In this report we examine their effect on T cells helping the early direct anti-TNP plaque-forming cell response of mice painted with picryl chloride. They did not directly inhibit the activity of the helper cells but did inhibit the ability of mice to generate helper cells after skin painting. The suppressor cells were T cells as tested by passage through nylon wool columns and sensitivity to anti-θ serum. Viable syngeneic cells were required for suppression and their effect was specific. The suppressor cells could not be generated in adult thymectomized mice but could be produced in mice treated with high doses (200 mg/kg) of cyclophosphamide. These properties are distinct from those of suppressor T cells produced following immunization with picryl chloride but are the same as those of other suppressor cells induced by PSA which inhibit contact hypersensitivity.