Requirements for activation of contrasuppressor T cells by type III pneumococcal polysaccharide

Either S3-coupled spleen cells (S3-SC) or soluble S3 activates two populations of regulatory T cells, T suppressor cells (Ts) and contrasuppressor T cells (Tcs). The latter cells function to mask the activity of Ts in unfractionated T cell populations, so that Ts can be detected only after removal of Tcs. Activation of Tcs by S3 may be required for induction of an antibody response to S3. This is suggested by the findings that Tcs are activated only by immunogenic doses of S3, that Tcs are not detectable in the spleens of mice tolerant to S3, and that (CBA/N X BALB/c)F1 male (xid) mice, which are genetically unresponsive to S3, do not develop Tcs after immunization with S3. Moreover, the kinetics of activation of Tcs by S3 closely parallels the kinetics of the antibody response to S3. Tcs have no detectable activity in the absence of Ts, indicating that these cells do not function as amplifier or helper T cells.     

Requirement for B cells for activation of contrasuppressor T cells by type III pneumococcal polysaccharide

Type III pneumococcal polysaccharide (S3) is unable to activate S3-specific contrasuppressor T cells (Tcs) in mice depleted of B cells by chronic anti-IgM treatment or in immune defective xid mice that lack the B cell subset required for anti-S3 antibody responses. The inability of S3 to activate Tcs in xid mice was shown to be due to a requirement of B cells for Tcs activation rather than to an absence of Tcs in xid mice. The B cells from normal mice that are required for Tcs activation apparently function to present the S3 Ag to Tcs. S3 physically coupled to spleen cells (S3-SC) prepared from normal BCF1 SC could activate Tcs in both xid and BCF1 mice whereas S3-SC prepared from xid SC or B cell-depleted BCF1 SC could not activate Tcs in either strain. B cell APC function was abrogated by 3000 R irradiation and by treatment of the B cells with either chloroquine or paraformaldehyde. Interestingly, B cells from mice previously immunized with S3 were unable to function in Tcs activation; preimmunization of B cell donors with an irrelevant Ag or with a T-dependent form of S3 had no effect on their ability to function as APC. These latter observations are discussed in terms of the in vivo persistence of polysaccharide Ag and their ability to induce B cell tolerance under the experimental conditions used for these experiments. The results of this study provide evidence that B cells play an important and apparently obligatory role in the activation of Tcs by S3; B cells apparently function to present Ag to Tcs, resulting in the activation of this regulatory T cell subset.     

Characterization and activity of contrasuppressor T cells induced by type III pneumococcal polysaccharide

Optimally immunogenic amounts of type III pneumococcal polysaccharide (S3) activate a population of contrasuppressor T cells (Tcs), which have been shown to play an important role in the induction of anti-S3 antibody responses. These Tcs belong to a unique T cell subset that has the surface phenotype Lyt 1+2- L3T4- I-J+ I-A+. These Tcs are also cyclophosphamide (Cy)-sensitive and sensitive to antilymphocyte serum (ALS) and mitomycin C. Tcs have antigen-binding receptors, indicating that any interactions of Tcs with B cells or T suppressor cells (Ts) (both of which also have antigen-binding receptors) must be via an antigen bridge rather than an idiotype-anti-idiotype interaction. Tcs are also Igh restricted in their action. Contrasuppression is manifest only when the Tcs are Igh compatible with both the Ts and the responding B cells. Tcs apparently mediate their effects by releasing a soluble factor, since a soluble factor extracted from Tcs is able to abrogate the effects of S3-specific Ts.     

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.     

Direct evidence for the involvement of T suppressor cells in the expression of low-dose paralysis to type III pneumococcal polysaccharide

Prior treatment (priming) with a subimmunogenic dose of type III pneumococcal polysaccharide results in the development of an antigen-specific state of unresponsiveness termed low-dose paralysis. Such unresponsiveness can be transferred by spleen cells obtained from mice within 5 to 24 hr after priming; the suppressive activity of transferred cells is abolished by treatment with monoclonal anti-Thy-1.2 antibody and complement. These findings show clearly that low-dose paralysis is mediated by T suppressor cells.     

Direct demonstration of specific suppressor T cells in the mice tolerant to type III pneumococcal polysaccharide: two-step requirement for development of detectable suppressor cells

Spleen cells from CAF1 mice made tolerant to type III pneumococcal polysaccharide (S3) with S3 coupled to syngeneic spleen cells (S3-SC) develop S3-specific suppressor T cells (Ts). These Ts could be demonstrated consistently only when spleen cells from tolerant mice were cultured in vitro with the specific antigen and the specific tolerogen. Spleen cells from normal mice cultured under the same conditions did not suppress the antibody response to S3. When different numbers of Ts were transferred to normal CAF1 mice, an unusual dose-effect pattern was observed. Maximal suppression of the S3 response occurred when relatively low numbers of Ts, 3 to 30 x 10(5) per recipient, were transferred, whereas larger numbers of cells, 150 x 10(5) per recipient, were not suppressive. These results indicate that a presumably T-independent antigen, S3, can activate antigen-specific Ts. These Ts exhibit unusual dose effects upon transfer and require both an in vivo induction period and in vitro activation for development of maximal activity. These latter observations suggest that S3 may activate a different population of T cells with suppressor function than do conventional T-dependent antigens. The loss of suppression observed when greater than optimal numbers of cells were transferred suggests that a second type of T cell, which has the ability to 'neutralize' the activity of S3-specific Ts, is also induced in the same spleen cell population.     

Regulation of contact sensitivity reaction: contrasuppressor T cells and contrasuppressor factor downregulate efferent T suppressor cells.

Contact sensitivity (CS) reaction mediated by CD 4+8- Th 1 cells is under the control of several antigen-specific regulatory lymphocytes. Reaction is downregulated at the induction stage by T afferent suppressor T cells (Ts-aff) that prevent immunization and at the effector stage by efferent T suppressor cells (Ts-eff) that made immune Th 1 cells inoperative. Both suppressor cells are CD 4-8+ Th 1 effector cells and are protected against the suppressive action of Ts-eff cells by CD 4+8- contrasuppressor T cells (Tcs). As has been already shown there are also regulatory interactions between regulatory cells themselves and Ts-aff cells in addition to their effect on precursors of Th 1 cells, also preventing the induction of Ts-eff cells. The present experiments extend these findings and demonstrate that Ts-eff cells are also under negative control of Tcs lymphocytes. Likewise, antigen-specific factor produced by contrasuppressor T-T cell hybridoma, used in lieu of Tcs cells, impedes the activation of Ts-eff cells. In both cases regulation is aimed at the precursors of Ts-eff cells. Our experiments demonstrate that the outcome of immunization is dependent not only on the balance between immune cells and regulatory cells, but also on interactions between regulatory cells themselves.     

Anti-idiotypic B cells are required for the induction of suppressor T cells

A nylon wool-adherent, B cell-enriched population is required during the in vitro induction of third order effector suppressor T cells (Ts3). This B cell population expresses IgM and IgD and is devoid of conventional T cell markers such as Thy-1, L3T4, and Lyt-1. Treatment of the B cell population with anti-NP antibodies expressing the NPb idiotype and complement specifically eliminated the ability to generate Ts cell activity, suggesting that the critical B cells expressed anti-idiotypic receptors. To independently verify the role of anti-idiotypic B cells in the generation of Ts cells, B cells were panned on antibody-coated plates. The results demonstrated that only NPb idiotype-binding B cells could induce effector suppressor cells from naive T cell populations. The combined data demonstrate the role of Ig network interactions in the generation of Ts cells.     

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.     

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.     

Kinetics of the antibody response to type III pneumococcal polysaccharide. I. Evidence that suppressor cells function by inhibiting the recruitment and proliferation of antibody-producing cells.

For the first 126 hr after immunization of mice with an optimally immunogenic dose (0.5 mug) of Type III pneumococcal polysaccharide (SSS-III), splenic antibody-forming PFC and serum antibody levels were measured at 2- and 8-hr intervals, respectively. PFC were detected at 28 hr after immunization and then increased through 86 hr after immunization; thereafter, the number of PFC remained nearly constant for the next 20 to 24 hr, and then began to decline. In contrast, serum antibody was first detected 60 hr after immunization. The accumulation of serum antibody continued to lag behind the increase in numbers of PFC by 16 to 20 hr until maximal serum antibody levels were attained; curves fitted to the values obtained for each parameter were nearly parallel.     

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.     

Suppression of IgM responses to type III pneumococcal polysaccharide by lipopolysaccharide (LPS).

Lipopolysaccharide (LPS) suppressed the primary IgM response of mice to Type III pneumococcal polysaccharide (S3). LPS and S3 had to be given together in order for maximum suppression to occur and suppression was not due to a change in the time of the peak response in mice which received LPS. Suppression was not due to an effect of LPS on T cells since S3 responses of nude mice were suppressed by LPS. LPS did not suppress S3 responses of C₃H/HeJ mice and base hyrolysis of LPS destroyed the suppressive effect, i.e., suppression was dependent of B cell mitogenic activity of the LPS. The suppressive effect of LPS was presumably directed against virgin B cells since LPS did not suppress the S3 response of primed mice and did not suppress the development of IgG memory responses to S3.     

Metabolic activity is necessary for activation of T suppressor cells by B cells

Ag-primed B cells must express cell-surface IgM, but not IgD or Ia Ag, and must remain metabolically active, in order to activate suppressor T cells (Ts) specific for type III pneumococcal polysaccharide. Ag-primed B cells that were gamma-irradiated with 1000r, or less, retained the ability to activate Ts; however, Ag-primed B cells exposed to UV light were not able to do so. gamma-Irradiated and UV-treated Ag-primed B cells both expressed comparable levels of cell-surface IgM, and both localized to the spleen after in vivo transfer; neither could proliferate in vitro in response to mitogens. By contrast, gamma-irradiated primed B cells were still able to synthesize proteins, whereas UV-treated primed B cells could not. These findings suggest that in order for Ag-primed B cells to activate Ts, they must a) express cell-associated IgM (sIgM) antibody bearing the idiotypic determinants of antibody specific for type III pneumococcal polysaccharide, and b) be able to synthesize protein for either the continued expression of sIgM after cell transfer, or for the elaboration of another protein molecule that is also required for the activation of Ts; this molecule does not appear to be Ia Ag.     

Imaging early steps of human T cell activation by antigen-presenting cells.

In this work the Ca2+ response and the morphological changes elicited by Ag in human CD4+ T cells are described at the single cell level. The APC used to present the diphtheria toxoid Ag to a human diphtheria toxoid-specific T cell clone were murine L cell fibroblast transfectants expressing MHC class II molecules. The increase of the intracellular Ca2+ concentration, [Ca2+]i, which is one of the earliest steps of the response to TCR stimulation, was followed by fluorimetry with fura-2 on an imaging system. This response was a specific consequence of successful Ag presentation, because it only took place when fibroblasts expressed both class II MHC molecules and Ag. CD4 molecules were also involved in this intercellular interaction, because the Ca2+ response could be inhibited by preincubating the T cells with an anti-CD4 antibody. The response induced by APC started after a delay of at least 6 min, after which large Ca2+ oscillations took place, with a pseudo period of 100 s at 35 degrees C. The frequency of these oscillations decreased with temperature. The oscillations became progressively more damped during the first 30 to 40 min of cell-to-cell interaction, after which they completely stopped; however, [Ca2+]i remained well above its resting level for more than 1 h after the contact. The Ca2+ oscillations were entirely dependent on Ca2+ influx because they immediately disappeared when external calcium was removed. Similar oscillations were observed when the cells were stimulated with an anti-CD3 antibody. After stimulation with APC, many T cells abandoned their spherical shape and tended to flatten and elongate. This aspect of the T cell response was not observed after stimulation with an anti-CD3 antibody. In the presence of cytochalasin B, the morphologic changes elicited by the APC were blocked, whereas the Ca2+ response was slightly enhanced. However, when T cells were loaded with the Ca2+ chelator BAPTA, both Ca2+ and morphologic changes were inhibited, suggesting that the Ca2+ response plays a permissive role for the morphologic changes.     

Regulation of IgG responses by helper and suppressor T cells activated by pneumococcal capsular polysaccharides

Type 2 antigens are usually unable to prime the helper T cells (TH) required for secondary IgG antibody responses. However, previous results from this laboratory indicated that low doses of the type 2 antigen polyvinylpyrrolidone (PVP) could activate T cells which provided help to PVP-primed B cells for the production of PVP-specific IgG antibody. Therefore, it was of interest to determine if other type 2 antigens may also be able to activate TH. Low doses of S19 or S3 (subimmunogenic for a primary IgM response) activated TH capable of providing help to S19- or S3-CRBC-primed B cells for a secondary IgG response. Higher doses of these antigens (optimally immunogenic for a primary IgM response) activated suppressor T cells (TS). Removal of these TS prior to transfer of T cells to recipient mice resulted in expression of TH function. Therefore, the preferential activation of TH versus TS was dependent on the dose of antigen used for priming. TH activated by low doses of S19 expressed Thy 1 and L3T4 and were antigen specific. In contrast to the ability of low doses of PVP to prime B cells for secondary IgG responses, low doses of S3 and S19 did not prime capsular polysaccharide-specific IgG memory B cells. High doses of S3 were able to prime B cells if TS precursors were first removed by treatment of mice with cyclophosphamide (Cy), whereas high doses of S19 did not prime B cells for secondary IgG responses in either Cy-treated or control mice. These results are discussed in relation to the general observations that type 2 antigens may not activate antigen-specific TH.     

Alloantigen-specific suppressor T cells are not inhibited by cyclosporin A, but do require IL 2 for activation

Alloantigen-specific suppressor T cells are activated from normal murine spleen cells in mixed lymphocyte reactions (MLR). These T cells are radioresistant and suppress the activation of cytotoxic T lymphocytes (CTL) in second primary MLR cultures. This report demonstrates that cyclosporin A (CsA) blocks the activation of these suppressor cells at a dose of 1 microgram/ml. However, reconstitution of CsA blocked cultures with IL 2 restores the activation of the suppressor T cells, but fails to significantly restore the activation of CTL in these same cultures. This differential activation requirement was used to establish T cell lines that demonstrate enriched suppressor cell activity but depletion of CTL activity. These findings are discussed in terms of the mechanism of action of CsA in these distinct T cell subsets and the relevance to models of allograft unresponsiveness.