Identification and initial characterization of concanavalin A- and interferon-induced human suppressor factors: evidence for a human equivalent of murine soluble immune response suppressor (SIRS)

Human suppressor T cells activated by leukocyte interferon have properties similar to murine suppressor cells activated by interferon or by concanavalin A. Murine suppressor cells release a soluble mediator, soluble immune response suppressor (SIRS), which accounts, at least in part, for suppressive activity in murine systems. To compare and contrast murine and human suppressor pathways, we evaluated the suppression of human polyclonal plaque-forming cell responses by concanavalin A, by leukocyte interferon, and by immune interferon, or by suppressor cells activated by these agents. In each instance, suppressive activity was prevented by levamisole, ascorbic acid, catalase, or 2-mercaptoethanol, agents known to interfere with murine SIRS activity. Furthermore, concanavalin A, immune interferon, and leukocyte interferon induced T lymphocytes to release 110,000 to 150,000 m.w. proteins which suppressed responses only when added early in the culture period. As with murine SIRS, suppression by each of these human factors was inhibited by 2-mercaptoethanol, ascorbic acid, catalase, or levamisole. The reaction of human suppressor factors with H2O2 (10(-6) M) activated suppressor factors so that they suppress responses when added late in the culture period. Human suppressor factors were protease- and acid (pH 2)-sensitive. The similarities between these human suppressor factors and murine SIRS show the existence of a human SIRS pathway.     

Mode of action of monoclonal-nonspecific suppressor factor (MNSF) produced by murine hybridoma

Monoclonal-nonspecific suppressor factor (MNSF), a product of murine T cell hybridoma, suppresses antibody response to lipopolysaccharide. In an attempt to clarify the functional mechanisms in vitro, we investigated the mode of action of MNSF. This factor inhibited the antibody response by B cells (depleting T cells and M?), thereby indicating that the lymphokine acts directly on B cells, without interaction between B and T cells or M?. MNSF activity was absorbed by mitogen-stimulated T or B cells, but not by resting lymphocytes. Proliferative responses to T cell and B cell mitogens were inhibited dose dependently by the addition of MNSF. Kinetic studies showed that MNSF suppressed the antibody response, in all culture periods, thereby indicating that immunoglobulin secretion and proliferation were inhibited. The effect of growth factor on MNSF-mediated suppression was investigated to search for a possible suppression of MNSF action. Interleukin 2 (IL-2) remarkably inhibited MNSF activity, and the effect of IL-1 or IL-4 was less. IL-2 was most effective when added on the fourth day of culture. MNSF also inhibits division in the plasmacytoma line MOPC-31C or in thymoma EL4, but not in L929 fibroblasts. Tumor necrosis factor (TNF) inhibits cell division of various tumor cells and suppresses the pokeweed mitogen-induced antibody response, without cytotoxic action, as does MNSF. While MNSF and TNF have similar biochemical and physiochemical properties, the cross-reaction tests showed that both are antigenically discrete lymphokines. Although MNSF lacks TNF activity, the concomitant addition of both factors to L929 increases the cytotoxic action, a finding indicative of a synergistic effect.     

Spontaneously Induced Suppressor Cells In Vitro: Nonspecific Suppression of In Vitro Antibody Formation

Nonspecific suppressor cells were induced during in vitro culture of normal mouse spleen cells (SPC) using the Marbrook culture system. The suppressor cells inhibited both the primary and secondary antibody-formation responses antigen nonspecifically in vitro, and both IgM- and IgG-responses were inhibited. The supernatants from suppressive precultured cells were not suppressive. The suppressor cells also inhibited the response of allogeneic SPC beyond H-2 compatibility. The induction of the suppressor cells did not require the presence of antigen but required fetal calf serum (FCS) or both FCS and 2-mercaptoethanol (2-ME). The suppressor cells were generated from the nylon-wool adherent, radiation-sensitive T cell population. On the other hand, the suppressor cells were nylon-wool nonadherent, relatively radiation-sensitive T cells. Actively antibody-producing cells were not affected by the suppressor cells. The suppressor cells inhibited the mitogenic responses of normal SPC to phytohemagglutinin-P (PHA), bacterial lipopolysaccharide (LPS) and concanavalin A (Con A). The suppressor cells themselves inhibited the growth of EL4 cells (T-cell leukemia of C57BL/6 mouse origin) and MOPCll cells (B cells, plasmacytoma of BALB/c mouse origin) even at a low effector-to-target cell ratio (E:T ratio = 1:1), but did not kill these tumor cells. These results indicate that the target cells of the suppressor cells are both T and B cells, and that the mechanism of action of the suppression is either inhibition of proliferation or inhibition of early events in the course of the immune response.     

Hormonal regulation of soluble immune response suppressor (SIRS): a possible role of SIRS in the maintenance of pregnancy

This study was conducted to investigate the effects of sex hormones upon the nature of soluble immune response suppressor (SIRS) produced by concanavalin A-stimulated Lyt-2+ T cells. Conventional SIRS affected IgM PFC only. However, SIRS made with progesterone (20-400 ng/ml or Prog-SIRS) suppressed IgM PFC, one-way MLR, and generation CTL; and SIRS made with estrogen (0.2-50 ng/ml or Est-SIRS) enhanced these responses. The factor(s) (MW 40,000-55,000) to stimulate macrophages to produce the second soluble factor (M phi-SF) was isolated from all preparations by gel filtration. Furthermore, Est-SIRS contained a factor(s) (MW 10,000-30,000) to enhance IgM PFC, MLR, and mitogen-induced blastogenesis of both T and B cells; and Prog-SIRS possessed the suppressive factor(s) to IgM PFC, MLR, and mitogen-induced T-cell proliferation. These activities were not impaired by 2-mercaptoethanol. Moreover, the suppressive activity of Prog-SIRS was completely absorbed by T cells only, but the enhancing activity of Est-SIRS was not completely absorbed by a single-cell population. These data suggest that progesterone can contribute to the suppression of allograft rejection through soluble factors, and estrogen can enhance host responses which may be affected by several soluble factors during pregnancy.     

Suppression of cytotoxic lymphocyte responses in vitro by soluble products of alloantigen-activated spleen cells.

Suppression of in vitro cytotoxic lymphocyte (CL) responses was mediated by soluble factor(s) produced when in vivo alloantigen-activated suppressor cells were re-exposed to alloantigen in vitro. Elaboration of suppressor factor (SF) was T cell dependent and was optimal 7 days after alloantigen injection. Suppressor factor failed to inhibit CL generation when alloantigen-primed cells rather than normal spleen cells were used as responders. Moreover, SF added at day 3 of incubation rather than at culture initiation was also ineffective, suggesting that suppression probably occurs during antigen induction or early differentiation. Additionally, suppression was abrogated by the presence of 2-mercaptoethanol. Studies combining SF and CL responder cells from a variety of H-2 disparate mouse sdrains revealed that suppression of CL responses: 1) was not alloantigen specific; 2) did not require H-2 homology between responder and suppressor strains; and 3) could not be demonstrated with CBA/J mice. Although CBA/J CL responses were not suppressed by any SF preparation, allo-sensitized CBA/J spleen cells did elaborate SF that inhibited BALB/c CL responses.     

Antigen-specific immune-suppressor factor in herpes simplex virus type 2 infections of UV B-irradiated mice.

UV B-irradiation (280 to 320 nm) of mice at the site of cutaneous infection with herpes simplex virus type 2 (HSV-2) induced suppressor T-cell circuits that decreased HSV-2-induced proliferative responses of HSV-2-immune lymph node cells. Adoptive transfer experiments indicated that splenocytes from UV B-irradiated HSV-2-infected animals contain L3T4+ cells that suppress proliferative responses in vivo, consistent with suppressor inducer cells. However, following in vitro culture of the splenocytes with HSV-2 antigen, the proliferation of immune lymph node cells was inhibited by Lyt2+ suppressor T cells, consistent with antigen-induced suppressor effector cells. Antigen-specific and nonspecific suppressor factors were fractionated from supernatants of HSV-2-stimulated spleen cells by molecular-sieve chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the Sephadex fraction that contained the antigen-specific suppressor factor, in the presence or absence of 2-mercaptoethanol, defined a 115-kilodalton protein consisting of two disulfide-bound components with molecular sizes of 70 and 52 kilodaltons. The implications of these results with respect to the regulation of HSV-induced cell-mediated immunity following UV B-irradiation are discussed.     

Suppressor T cell activation by human leukocyte interferon

Murine fibroblast interferon (IFN beta) activates murine suppressor T lymphocytes in vitro, which suppress plaque-forming cell responses by spleen cells. Suppression of human in vitro immune responses by IFN was investigated to determine whether human IFN also activates suppressor T cells. Human leukocyte IFN (IFN alpha) suppressed pokeweed mitogen-induced polyclonal immunoglobulin production by human peripheral blood mononuclear cells (PBMC) by 80 to 90% at doses of 200 to 350 U/ml. Responses by IFN alpha-treated PBMC were suppressed in a dose-dependent manner; control cultures had maximal responses on day 7. PBMC incubated with 10,000 U/ml of IFN alpha contained activated suppressor cells that decreased pokeweed mitogen-stimulated, polyclonal immunoglobulin production by autologous cells by 70 to 80%. Suppression mediated by these cells was prevented by catalase, ascorbic acid, and 2-mercaptoethanol (2-ME). In murine systems, these reagents interfere with expression of suppressor T cell activity by preventing activation of soluble immune response suppressor. Selection procedures with monoclonal antibodies identified the suppressor cell as an OKT8+ (suppressor/cytotoxic) T lymphocyte. Selected OKT8+ cells required less IFN alpha (1000 U/ml) for activation and were effective in smaller numbers than unfractionated activated PBMC. IFN alpha-activated suppressor cells also inhibited proliferation in mixed lymphocyte and mitogen-stimulated PBMC cultures; again, catalase and 2-ME blocked suppression. These results indicate that IFN alpha activates suppressor T cells in human PBMC cultures; the ability of catalase, 2-ME, and ascorbic acid to block suppression suggests that these suppressor T cells have certain similarities to IFN beta or to concanavalin A-activated murine suppressor T cells.     

Role of DNA synthesis in secretion of immunoglobulin from murine B cells stimulated by T cell derived lymphokines

We have investigated whether cell division is required for induction of Ig secretion from three types of B cells, which represent distinct activation states: normal splenic B cells, anti-Ig-treated B cells, and a monoclonal murine B cell tumor, BCL1. Polyclonal Ig secretion was stimulated in vitro by LPS or by lymphokines produced by EL-4 cells (EL-4 SN), which includes B cell growth factor II (BCGF II). LPS and EL-4 SN were mitogenic for all three cell populations and stimulated substantial IgM secretion from both B cells and anti-Ig blasts. Aphidicolin, a reversible inhibitor of DNA synthesis, abolished IgM secretion from B cells and anti-Ig blasts induced by either mitogen, indicating that Ig-secreting cells in these cultures are part of a cycling population. BCL1 tumor cells respond to BCGF II (but not to interleukin 2 or B cell stimulatory factor 1) with IgM secretion and cell division, allowing a direct assessment of the influence of BCGF II-stimulated cell division on secretion of IgM. Secretion by these cells during the first 24 hr of culture was not substantially affected by aphidicolin, but secretion at 48 or 72 hr was markedly inhibited. Culture of BCL1 cells for 48 hr with aphidicolin alone had no effect on cell viability or on subsequent responsiveness if the drug was removed, eliminating non-specific toxicity as an explanation of the drug's effect. Addition of aphidicolin during the last 24 hr of culture to either normal B cells or BCL1 cells was much less effective at inhibiting IgM secretion. These results indicate that the cells that secrete IgM in response to BCGF II also synthesize DNA when exposed to this factor. Thus, induction of high-rate Ig secretion from murine B cells by some stimuli, including BCGF II, may require at least one round of cell division.     

Multiple suppressive effects of transforming growth factor beta 1 on the immune response in chickens

The immunosuppressive effect of human recombinant TGF-beta 1 on chicken immune responses in vitro was evaluated. TGF-beta 1 at 1-10 ng/ml reduced T cell proliferation in response to concanavalin A by 50-80% and B cell proliferation in response to LPS by greater than 90%. In contrast, when added to immune spleen cells, it reduced the secondary PFC response to sheep erythrocytes by less than 50%, particularly when added at the same time as antigen on Day 2 of incubation. When TGF-beta 1 was added during a 2-day incubation to nylon wool-nonadherent immune or normal spleen cells, it caused the maintenance and/or appearance of suppressor cells. These suppressor cells, in coculture with immune spleen cells, inhibited the secondary PFC response in vitro without any further exposure to TGF-beta 1. The phenotype of the cells giving rise to suppressor cells under the influence of TGF-beta 1 was CT8+, TCR2+(alpha,beta), CT4-, TCR1-(gamma,delta) cells. The results suggest that, in addition to direct suppressive effects on the proliferation of B cells and of some T cells, TGF-beta 1 may suppress immune responses by maintaining or by promoting the development of suppressor T cells.     

Control of cell division in hepatoma cells by exogenous heparan sulfate proteoglycan

The effects of cell surface heparan sulfate proteoglycan (HSPG) prepared from log and confluent monolayers of a rat hepatoma cell line on hepatoma cell growth were studied. When HSPG isolated from confluent cells was added exogenously to log phase cells, it was internalized and free heparan sulfate (HS) chains appeared transiently in the nucleus. Concurrently, the growth of the treated cells was inhibited, but the cells resumed logarithmic growth as the level of nuclear HS fell, and the cells grew to confluence and became contact inhibited. When HSPG prepared from log-phase hepatoma cells was added exogenously to log phase cells, it was internalized but very little of the internalized HS appeared in the nucleus, and there was no change in the rate of cell growth. However, when the rate of cell growth was reduced by culture of the cells in serum- and insulin-deficient medium, HSPG prepared from log-phase cells stimulated the growth rate of these slow-growing cells. The cell cycle dependency of HSPG uptake and growth inhibition was studied in cultures synchronized by a thymidine/aphidicolin double block. When [35SO4]HSPG from confluent cells was added to synchronized cells just as they were released from the second block, a portion of the [35SO4]HSPG was internalized and [35SO4]HS appeared in the nucleus. However, at mitosis the [35SO4]HS disappeared almost completely from all of the cellular pools, and after mitosis, more of the [35SO4]HSPG was taken up and [35SO4]HS reappeared in the nucleus and remained in the nucleus until the cells divided again. When cultures were released from the aphidicolin block, both control and HSPG-treated cells progressed through the S, the G2, and the M phases of the cell cycle. However, the length of the G1 phase of the cycle was increased in the HSPG-treated cells. The treated cultures then progressed through the second S, G2, and M phases. Thus, the inhibition of cell division occurred in the G1 phase of the cell cycle, prior to the G1/S boundary. Addition of the HSPG to the synchronized cultures just after the first mitosis resulted in an immediate arrest of the cell cycle in G1.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of cell division of mature B cells by ionomycin and phorbol ester.

The growth of a human B lymphoma cell line B104, an experimental model for mature B cells, was inhibited by ionomycin but not 12-O-tetradecanoylphorbol-13-acetate (TPA). Ionomycin inhibited B104 cells from entering into the M phase of the cell cycle without affecting DNA synthesis. The inhibition of cell division of B104 cells by ionomycin occurred within 24 h after stimulation. Because such a mode of action resembles that of anti-IgM antibodies, signals transduced by Ca2+ may be responsible for the inhibition of cell division of B104 cells by anti-IgM antibodies. Indeed, EGTA suppressed the inhibition of cell division of B104 cells caused not only by ionomycin, but also by anti-IgM antibody. Although TPA itself did not have any ability to promote the growth of B104 cells, it could cancel the inhibition of cell division of B104 cells by ionomycin and increase the proportion of B104 cells entering into the M phase of the cell cycle. Staphylococcus aureus Cowan I causes the greatest proliferation of normal human peripheral blood B cells during the period from 48 to 72 h after stimulation. When ionomycin was added to S. aureus Cowan I-stimulated peripheral blood B cells at 48 h of culture, it inhibited cell division during this period without affecting DNA synthesis. In the presence of TPA, this activity of ionomycin was suppressed, and the proportion of M-phase cells increased. These results suggest that cell division of mature B cells is regulated by the signals mediated by Ca2+ and protein kinase C in a mode quite different from that of regulation of DNA synthesis.     

The relative effects of different types of growth factors on DNA replication, mitosis, and cellular enlargement

It was recently demonstrated that growth in cell size can be dissociated from DNA synthesis and mitosis. 3T3 cells starved to quiescence in low serum concentration can be stimulated to undergo DNA synthesis and one cell division without growing in size (unbalanced growth) (42-44). We report here that in cells stimulated to undergo unbalanced growth, the cell nucleus undergoes balanced growth, i.e., nearly doubles in size prior to mitosis. The reduced ability to grow in cell size under unbalanced growth conditions is thus mainly ascribable to the cytoplasm. Furthermore, the extent to which cells grow in size prior to mitosis is dependent on the serum concentration in the tissue culture medium (44). This data suggests that some macromolecular factor or factors in serum are required for growth in cell size prior to mitosis. We report in this study that epidermal growth factor (EGF) alone exerts a small but significant stimulatory influence on DNA synthesis and mitosis but does not affect cellular enlargement. In contrast, insulin added at supraphysiological concentrations does not stimulate quiescent cells to enter S phase but instead stimulates growth in cell size in the small fraction of dividing cells. Furthermore, cells stimulated to proliferate by EGF could be induced to undergo balanced growth when insulin was added concomitantly. Finally, platelet-derived growth factor (PDGF) stimulates quiescent sparse 3T3 cells to undergo DNA synthesis and mitosis. PDGF also exerts a limited but significant effect on cellular enlargement. However, PDGF alone could not induce a complete balanced growth, i.e., a doubling in cell size prior to mitosis.     

Interaction between T cells and non-T cells in suppression of cytotoxic lymphocyte responses.

Generation of cytotoxic T lymphocytes (CTL) in mixed leukocyte cultures was suppressed by a factor elaborated by alloantigen-activated T cells. This suppressor factor, CTL-TsF, in contrast to a factor that suppresses proliferative responses in mixed leukocyte reactions (MLR-TsF), was effective only when added during the first 24 hr of a 6-day-culture period. Moreover, removal of CTL-TsF 24 hr after culture initiation failed to restore CTL responses. CTL activity could be rescued from suppressed cultures, however, by addition of 2-mercaptoethanol on days 3 or 4. Similarly, transfer of nonadherent cells at 3 or 4 days from cultures treated with CTL-TsF to cultures of adherent cells initiated in control factor restored CTL responses. Mixing experiments with cells pulsed with CTL-TsF for 4 hr at culture initiation identified a target of CTL-TsF as a Thy-1 negative cell that was adherent to plastic and to Sephadex G-10. Suppression was not due to interference with physiologic accessory cell function, but more likely was accomplished via a negative signal from CTL-TsF-pulsed cells. The results thus suggest that CTL-TsF acts early, but reversibly, in the CTL differentiative process via a second suppressor effector cell, possibly a macrophage.     

The effects of autacoids on cloned murine lymphoid cells: modulation of IL 2 secretion and the activity of natural suppressor cells

The pharmacologic effects of histamine and isoproterenol (autacoids) were studied on clones of murine T helper (TH) and natural suppressor (NS) cells. The data are consistent with receptors for the autacoids being nonrandomly distributed on phenotypically and functionally distinct clones. The effects of histamine on IL 2 secretion by TH cells could be either inhibitory or stimulatory, depending on the conditions of incubation with the autacoid. When TH cells were pretreated with histamine, their secretion of IL 2 was augmented; conversely, if histamine was added to the TH cells in the presence of antigen, IL 2 secretion was inhibited. The suppressor function of NS cells was enhanced by preincubation with histamine (10(-4) M) for 4 hr before the washed NS cells were added to responder and stimulator cells in mixed lymphocyte cultures. Two H1 receptor antagonists, mepyramine (10(-6) M) and pyrobutamine (10(-7) M), each competitively blocked the histamine activation of the NS cells, but an H2 receptor antagonist cimetidine (10(-5) M) did not alter the suppressor-enhancing function of histamine. Activation of NS cells did not occur if histamine was added with responder, stimulator, and co-cultured cells in MLR. The effects of each autacoid were additive in cytolytic T cells alone. The adenylate cyclase pools that can be stimulated by isoproterenol and histamine in cytolytic T cells may be independent of each other, but further work will be needed to prove this point.     

T cell subsets in (responder x nonresponder)F1 mice regulating antibody responses to L-glutamic acid60-L-alanine30-L-tyrosine (GAT)

Immune responses to GAT are controlled by H-2-linked Ir genes; soluble GAT stimulates antibody responses in responder mice (H-2b) but not in nonresponder mice (H-2q). In nonresponder mice, soluble GAT stimulates suppressor T cells that preempt function of helper T cells. After immunization with soluble GAT, spleen cells from (responder x nonresponder: H-2b X H-2q)F1 mice develop antibody responses to responder H-2b GAT-M phi but not to nonresponder H-2q GAT-M phi. This failure of immune F1 spleen cells to respond is due to an active suppressor T cell mechanism that is activated by H-2q, but not H-2b, GAT-M phi and involves two regulatory T cell subsets. Suppressor-inducer T cells are immune radiosensitive Lyt-1 +2-, I-A-, I-J+, Qa-1+ cells. Suppressor-effector T cells can be derived from virgin or immune spleens and are radiosensitive Lyt-1-2+, I-A-, I-J+, Qa-1+ cells. This suppressor mechanism can suppress responses of virgin or immune F1 helper T cells and B cells. Helper T cells specific for H-2b GAT-M phi are easily detected in F1 mice after immunization with soluble GAT; helper T cells specific for H-2q GAT-M phi are demonstrated after elimination of the suppressor-inducer and -effector cells. These helper T cells are radioresistant Lyt-1+2-, I-A+, I-J-, Qa-1- cells. These data indicate that the Ir gene defect in responses to GAT is not due to a failure of nonresponder M phi to present GAT and most likely is not due to a defective T cell repertoire, because the relevant helper T cells are primed in F1 mice by soluble GAT and can be demonstrated when suppressor cells are removed. These data are discussed in the context of mechanisms for expression of Ir gene function in responses to GAT, especially the balance between stimulation of helper vs suppressor T cells.     

Recognition of a B cell lymphoma by anti-idiotypic T cells

Idiotypic IgM derived from a B cell lymphoma can act as a tumor-associated Ag, in that immunization with this purified protein generates an anti-idiotypic immune response that specifically suppresses tumor development. Spleens of immune mice contain T cells that proliferate in response to idiotypic IgM. However, idiotypic Ag is presented to the T cells most efficiently in its natural form at the surface of the lymphoma cells, than as soluble IgM plus presenting cells. Variant tumors that display either little or no idiotypic IgM at the cell surface, but which are otherwise indistinguishable from parental tumor, induce a weak response or fail to stimulate the T cells, respectively. Anti-idiotypic lines and clones have been derived from the splenic T cells by growth in the presence of irradiated tumor cells. Phenotypic analysis revealed that cells from both lines and clones express CD3 and CD4 Ag, but not CD8. Recognition of tumor Id, which required no added presenting cells, was inhibited by antibody against MHC class II Ag, and variably by anti-CD4. Proliferative responses were inhibited by anti-idiotypic antibodies, but also by antibodies against the constant region of the mu H chain, indicating that perturbation of the surface IgM abrogates availability of idiotypic determinants to the T cells.     

Effects of antigen-feeding on intestinal and systemic immune responses. III. Antigen-specific serum-mediated suppression of humoral antibody responses after antigen feeding.

Feeding mice sheep erythrocytes (SRBC) caused a significant decrease in splenic IgM antibody responses to SRBC given ip. Reduced IgM responses were due to a suppressor factor in the serum of fed mice rather than due to a lack of IgM antibody-forming cell precursors or to the presence of suppressor T cells. Although feeding initially primed mice to produce greater IgA and IgG anti-SRBC responses after SRBC challenge, the initial primed state was transitory. Mice fed SRBC for longer than 8 weeks had significantly reduced splenic IgG and IgA responses after SRBC challenge.Suppression of IgM responses by serum from fed mice was antigen-specific and not H-2 restricted. Serum from fed mice inhibited the induction of IgM anti-SRBC responses but did not block the expression of already established responses. The size of the suppressor factor and the ability to remove suppressor activity from serum by anti-mouse immunoglobulin suggested that suppression was mediated by antibody. However, the determinants against which the antibody was directed appeared to differ among batches of suppressor sera. Suppressor activity did not appear to be mediated by immune complexes, or soluble antigen. Oral feeding of antigen can have a marked influence on host systemic immune responses when the antigen used for feeding is subsequently administered parenterally. Thus, oral antigen administration may provide a way for specifically manipulating systemic immune responses in vivo. In addition, antigen-feeding may provide a means for producing transferable factors that suppress humoral antibody responses.     

Activation of human B lymphocytes. IV. Regulatory effects of corticosteroids on the triggering signal in the plaque-forming cell response of human peripheral blood B lymphocytes to polyclonal activation.

In vitro hydrocortisone in physiologic and pharmacologically attainable concentrations caused a marked enhancement of the PWM-induced PFC response of normal human peripheral blood B lymphocytes. This effect was seen only when hydrocortisone was added within the first 24 hr of culture and only when hydrocortisone and PWM were present together in cultures. Only suprapharmacologic concentrations of hydrocortisone (10(-3) M) were capable of suppressing early B cell activation. Late stages of antibody production and secretion were resistant to suppression by even these extraordinarily high concentrations. Hydrocortisone did not replace the T cell requirement of PWM-induced PFC responses. A single dose of in vivo hydrocortisone (400 mg) to normal adult volunteers did not produce this enhancing effect when PFC responses were measured in vitro in the absence of hydrocortisone. The data strongly suggest that the enhancing effect of hydrocortisone was due not to elimination of naturally occurring suppressor cells, but to a modulation of the triggering signal either directly on the B cell itself or via the balance of positive and negative T cell regulation of B cell activation.