Suppression of a pokeweed mitogen-stimulated plaque-forming cell response by a human B lymphocyte-derived aggregated IgG-stimulated suppressor factor: suppressive B cell factor (SBF)

The mechanisms whereby formed immune complexes (IC) or immunoglobulin aggregates can suppress further antibody production were explored by culturing normal human peripheral blood mononuclear leukocytes (PBL) with heat-aggregated IgG (HAIgG) and collecting the culture supernatants at 24 hr. These supernatants were found to suppress a pokeweed mitogen (PWM)-induced rheumatoid factor plaque-forming cell (RF-PFC) response in normal individuals. PWM-induced anti-trinitrophenylated sheep red blood cell (TNP-SRBC) PFC were also inhibited by suppressor supernatants from HAIgG-stimulated PBL, suggesting that the polyclonal PFC response was inhibited by a suppressor factor. The suppressor factor inhibited PWM stimulated RF-PFC throughout the culture period, but suppression was maximal at the peak of the RF-PFC response. Suppressor factor was only effective at the initiation of cultures, suggesting that it inhibited early events in the PWM-stimulated RF-PFC response. Molecular weight determination of the suppressor factor by differential membrane fractionation suggested a m.w. range of 30,000 to 50,000, and chromatography on Sephadex G-100 showed a peak activity at an approximate m.w. of 32,000. Studies suggested the factor was not an interferon. Depletion of T lymphocytes by E rosetting and macrophages/monocytes by G-10 adherence did not affect the generation of suppressor factor. Depletion of T lymphocytes (OKT4, OKT8) and NK cells (Leu-11b) by antibody-dependent, complement-mediated cytotoxicity also did not affect the generation of suppressor factor. Depletion of B lymphocytes with OKB7 resulted in the generation of significantly less suppressor factor. Suppression produced by unstimulated purified B lymphocytes was approximately one-half that seen when B lymphocytes were stimulated with HAIgG. Differential membrane fractionation studies suggested that only HAIgG-stimulated B cell cultures contained peak activity in the 30,000 to 50,000 m.w. fraction. Supernatants from unstimulated purified T cells also generated suppression, which was approximately one-half of that seen with HAIgG-stimulated B cells, but no increase in suppressor activity was seen in T cell cultures after incubation with HAIgG. These studies demonstrate that HAIgG is capable of stimulating B lymphocytes to produce a lymphokine, suppressive B cell factor (SBF), which is capable of suppressing a polyclonal PFC response. SBF may be important in feedback control of human immunoglobulin production.     

Functional analysis of monkey lymphocyte subsets defined by OKT4 and OKT8 monoclonal antibodies

The percentages of rhesus monkey blood lymphocytes (PBL) reactive with OKT4 and OKT8 antibodies and the $\text{OKT}\text{4}\text{OKT}\text{8}$ ratio showed significant correlations with the log of the immunoglobulin plaque-forming cell (PFC) response after stimulation with pokeweed mitogen (PWM). These correlations suggested that monkey OKT4⁺ cells function as “helper” cells and OKT8⁺ cells function as “suppressor” cells for the PFC response. This was confirmed by separation and study of enriched T- and B-cell subpopulations. OKT8-depleted (OKT4⁺) and OKT4-depleted (OKT8⁺) cells were obtained by treatment of purified T cells with antibody and complement. OKT4⁺ cells augmented the PWM-induced B-cell differentiation into PFC but OKT8⁺ cells did not. OKT8⁺ cells suppressed the PFC response by mixtures of B cells and OKT4⁺ cells. OKT8 antibodies also detected a suppressive cell subset in African green monkeys since the percentage of OKT8⁺ cells showed a negative correlation with the log PFC response. OKT4 antibodies failed to bind to African green monkey PBL.     

Colony-forming B cells in F1 hybrid and transplanted CBA/N mice.

The conditions for evaluation of suppressor cell regulation of the pokeweed mitogen (PWM)-induced plaque-forming cell (PFC) responses of peripheral blood (PB) B cells in normal individuals using allogeneic cocultures is described. In 14 separate experiments, after preincubation with concanavalin A (Con A) for 2 days, PB cells suppressed the PWM-induced anti-sheep erythrocyte (SRBC) PFC response of fresh allogeneic PB cells to 17% of the expected PFC response (P < 0.05). In addition, control cells incubated for 2 days in the absence of Con A suppressed the PWM- induced PFC response of allogeneic cells in 6 of 14 experiments to the same extent as did the Con A-generated cells (P < 0.01). It was found that unstimulated control cells (without Con A activation) from normal subjects who themselves were nonresponders to PWM stimulation (< 50 PFC/10⁶ cells) usually suppressed the PFC response of allogeneic cells (P < 0.05), while control cells from normal subjects who consistently had a good PFC response to PWM stimulation (> 75 PFC/10⁶ cells) did not suppress the PFC response of allogeneic cells. The spontaneously occurring suppressor cell in nonresponder PB cell suspensions was sensitive to 3000-R irradiation, and the nonresponder state was not associated with a decreased blastogenic response to PWM. Thus, some normal subjects who themselves had a poor PWM-induced PFC response had irradiation-sensitive, spontaneously occurring suppressor cells which were capable of suppressing the PWM-induced PFC response of normal responders. The majority of normal subjects (90%) were good PFC responders to PWM stimulation and did not spontaneously suppress the PFC response of allogeneic cells to PWM, but did have PB cells which were capable of being activated by Con A to suppress.     

Impaired immunoregulation in systemic lupus erythematosus: defective adenosine-induced suppressor T lymphocyte generation

It is currently unclear whether the suppressor cell dysfunction observed during active systemic lupus erythematosus (SLE) reflects a primary T cell disorder or one that results from immunologic modulation of suppressor T cell activity by autoantibodies. To determine whether the suppressor T cell dysfunction of active SLE is the result of a primary T cell disorder, the model of adenosine-induced immunosuppression was utilized to study the suppressor T cell functions of 12 patients with SLE (seven active SLE, five inactive SLE) and 12 matched healthy controls. T lymphocyte phenotyping was performed by utilizing monoclonal antibodies directed against T cell-specific determinants. Suppressor T cell functions were assessed by two assays in parallel. The first technique tested the capacity of two suppressor T cell subsets (spontaneous suppressors, Ts; adenosine-inducible suppressors, TRA) to inhibit pokeweed mitogen- (PWM) induced B cell differentiation. In the second technique, the ability of enriched T cell preparations to suppress mitogen- and alloantigen-induced proliferation was assayed. It was demonstrated that brief treatment of the control theophylline-resistant T lymphocyte (TR) subset possessing inducer/helper activity with adenosine (10(-5) M, 30 min, 37 degrees C) triggered a rapid shift in phenotype (RFC gamma -, T-4+ leads to RFC gamma +, T-8+) in a proportion of the subset, and the development of radioresistant suppressor function. By contrast, exposure of active SLE TR to adenosine failed to induce either the switch of phenotype or suppressor activity. When compared to controls, both the TS and TRA suppressors failed to inhibit B cell differentiation (TS, p less than 0.001; TRA, p less than 0.001). Moreover, enriched T cell preparations incompletely suppressed the proliferative responses to phytohemagglutinin (p less than 0.003), PWM (p less than 0.0003), or alloantigens (p less than 0.01). During inactive SLE, the T cell responses were usually restored. Treatment of the TR subsets with adenosine induced a switch of phenotype in four of five patients and the subsequent expression of effective suppressor function. We conclude that a) during active SLE, there is impaired suppression of proliferation and B cell differentiation; b) the impaired suppression of B cell differentiation results from abnormal spontaneous (TS) and adenosine-inducible (TRA) suppressor functions; c) the defective generation of suppressor T cell function during active disease results, in part, from a block in the transition from inducer/helper to suppressor cell; and, d) the suppressor T cell dysfunction is reversible with disease remission. The investigation of immunopharmacologic events by using the adenosine-induced immuno-suppression model in T cells from normal donors and SLE patients may provide insights into the molecular basis of disordered immunoregulation in SLE.     

The regulatory effect of histamine on the immune response: characterization of the cells involved

Any immunological response is the end result of the equilibrium between many positive and negative regulatory factors. It has been recently demonstrated that histamine receptor-bearing T lymphocytes could play a role in this regulation. This work aims to study the effects of different cell populations after incubation with histamine on the proliferative response of normal lymphocytes. The histamine-incubated peripheral blood lymphocytes (PBL) lower the proliferative response of normal cells toward mitogens (phytohemagglutinin, concanavalin A) and antigens (mixed lymphocyte culture). In order to precise the cell subpopulations involved in this suppression, PBL have been depleted of adherent cells and B and T lymphocytes have been purified by a standard rosette technique. The enriched B cells do not suppress the normal response but the suppressor activity of T cells, as well as adherent cell-depleted PBL, are significantly reduced compared to the one of PBL. The initial suppressor activity is restored by addition of 1% adherent cells (and not 5 or 10%) to adherent cell-depleted lymphocytes and 10% adherent cells (not 1 or 5%) to T-enriched population. These observations suggest a role for adherent cells in this regulation.     

Suppression of pokeweed mitogen-stimulated immunoglobulin production in patients with rheumatoid arthritis after treatment with total lymphoid irradiation

Patients with intractable rheumatoid arthritis (RA) were treated with total lymphoid irradiation (TLI, 2000 rad). We previously reported long-lasting clinical improvement in this group associated with a persistent decrease in circulating Leu-3 (helper subset) T cells and marked impairment of in vitro lymphocyte function. In the present experiments, we studied the mechanisms underlying the decrease in pokeweed mitogen stimulated immunoglobulin (Ig) secretion observed after TLI. Peripheral blood mononuclear cells (PBL) from TLI-treated patients produced 10-fold less Ig (both IgM and IgG) in response to pokeweed mitogen than before radiotherapy. This decrease in Ig production was associated with the presence of suppressor cells in co-culture studies. By using responder cells obtained from normal individuals (allogeneic system), PBL from eight of 12 patients after TLI suppressed Ig synthesis by more than 50%. In contrast, PBL from the same patients before TLI failed to suppress Ig synthesis. Suppression by post-TLI PBL was also demonstrated in an autologous system by using responder cells cryopreserved before TLI. Again, only cells obtained after TLI were suppressive in four of seven patients. PBL with suppressive activity contained suppressor T cells, and the latter cells bore the Leu-2 surface antigen. In 50% of the patients studied, suppressor cells were also found in the non-T fraction and were adherent to plastic. Interestingly, the Leu-2+ cells from TLI-treated patients were no more potent on a cell per cell basis than purified Leu-2+ cells obtained before TLI. Additional experiments suggested that the suppression mediated by T cells after TLI is related to the increased ratio of Leu-2 to Leu-3 cells observed after radiotherapy.     

Suppression of B cell responses by natural killer cells is mediated through direct effects on T cells

We examined the ability of human natural killer (NK) cells to modulate T cell-dependent mitogen-induced B cell responses. Highly purified NK cells inhibited the polyclonal antibody responses of autologous pokeweed mitogen (PWM)-stimulated unfractionated mononuclear cells in a reverse hemolytic plaque-forming cell (PFC) assay. Investigation of the possible mechanism(s) of the suppressor activity of NK cells revealed that lysis of mitogen-stimulated cells was unlikely. Chromium-51 release cytotoxicity assays of PWM-stimulated mononuclear cells did not demonstrate lysis by NK cells. Additionally, the monoclonal antibody 13.3, which abrogates NK cell cytolysis, did not reverse NK cell-dependent suppression of PFC formation. The putative lytic molecule elaborated by NK cells, NK cytotoxic factor, did not suppress B cell responses, further supporting a nonlytic inhibitory mechanism. That NK cell-derived lymphokines such as IFN-alpha, IFN-gamma, or IL-2 were uninvolved in the down-regulation of B cells was corroborated by the failure of antibodies to these mediators to reverse the suppression. NK cells did not suppress PFC formation when T cells were replaced by supernatants from PWM-stimulated T cells; additionally, NK cells had no effect on the generation of these necessary T cell factors. However, the coculture of T cells with NK cells resulted in the induction of suppressor activity within the T cell population suggesting that this was the mechanism of NK cell-mediated suppression of B cell responses.     

Functional differentiation of B lymphocytes in agammaglobulinemia. III. Characterization of spontaneous suppressor cell activity.

The addition of fresh peripheral blood mononuclear cells (PBL) from four of seven patients with agammaglobulinemia to generated hemolytic plaque-forming cells (PFC) resulted in a dose-dependent suppression of PFC. This spontaneous suppressor cell activity (SSA) was restricted to the four patients who could generate a PFC response in vitro. SSA was mediated by a small subset of E-rosetting T lymphocytes characterized by theophylline-sensitive E-receptors and surface receptors for Fc-IgG. The effects of SSA were temperature dependent and reversible, and pokeweed mitogen could prevent the rapid decline of SSA observed during culture. Augmentation of SSA was achieved by agents known to increase intracellular levels of cyclic AMP, whereas lithium chloride abrogated SSA, including the drug-induced effects. Cells mediating SSA may play a role in preventing the normal transition of pre-B cells to B cells in patients with agammaglobulinemia without B lymphocytes.     

Developmental changes in humoral suppressor activity released from concanavalin A-stimulated human lymphocytes on B cell differentiation

Cell-free culture supernatants (Con A-activated supernatants) were obtained by incubating peripheral blood lymphocytes (PBL) from cord blood, healthy children of various ages, and healthy adults with mitogenic doses of concanavalin A (Con A) for 48 hr. It is well known that human T lymphocytes are activated by Con A to manifest suppressor function in vitro. One mechanism whereby these suppressor cells act has been shown to be by the secretion of a soluble suppressor factor. The present study has investigated the Con A-inducible suppressor cell function in cord blood, children of various ages, and adults by comparing the ability of each Con A-activated supernatant to inhibit the generation of immunoglobulin-producing cells (Ig-PC) in pokeweed mitogen- (PWM) stimulated cultures of adult PBL. Con A-activated supernatants from adults could markedly suppress the generation of Ig-PC by allogeneic as well as autologous PBL in response to PWM. Such suppression appeared to be equally effective on the generation of IG-PC of 3 major classes, IgG, IgM, and IgA. On the contrary, Con A-activated supernatants from cord blood and newborn infants showed only a negligible suppression on PWM-induced adult B cell differentiation. But the suppressor activity found in Con A-activated supernatants gradually increased with advancing age, and reached approximately to the adult level at 4 yr of age or later. The results suggest that human T lymphocytes may be relatively deficient in their Con A-induced suppressor cell function in the early period of life.     

Cytokinetic basis for the impaired activation of lymphocytes from patients with primary intracranial tumors

Patients with malignant brain tumors have a variety of immunologic abnormalities, including the impaired responsiveness of peripheral blood lymphocytes (PBL) to mitogens and alloantigens. We further investigated this impairment of lymphocyte reactivity by employing the techniques of limiting dilution analysis and cytokinetic analysis. PBL preparations from patients have approximately six times fewer phytohemagglutinin (PHA)-responsive cells than PBL from normal subjects. Similar results were obtained with purified T cell preparations. Cytokinetic analysis of PHA-induced [3H]thymidine incorporation employing colchicine blocking of mitosis demonstrated that the number of first generation cells entering the S-phase of mitosis for each 24-hr period was less for PBL from patients than for PBL from normal individuals. First generation responding cells from patients and normal subjects entered DNA synthesis at the same time (48 to 72 hr). Cytokinetic analysis over a period of 168 hr demonstrated that whereas PBL from normal individuals demonstrated second generation responding cells, PBL from the majority of patients did not, thus indicating a defect in their ability to undergo clonal expansion. Measurement of interleukin 2 (IL 2) activity in culture fluids from PHA-activated PBL from normal subjects and patients revealed significantly lower IL 2 levels in culture fluids from PBL from patients. The addition of various concentrations of lectin-free IL 2 to PBL from patients stimulated with PHA did not restore responsiveness to normal values. There was no difference between the levels of interleukin 1 (IL 1) produced by lipopolysaccharide-activated monocytes from normal subjects and patients. Overall, these results suggest that an intrinsic defect exists in T cells obtained from brain tumor patients that renders them unable to enter into normal mitogen-induced blastogenesis.     

Pregnancy-associated growth factor. II. A T-dependent polyclonal activator of human adult peripheral blood lymphocytes (PBL)

This study examined the ability of pregnancy-associated growth factor (PAGF), a substance found in crude human chorionic gonadotropin (hCG), to induce plaque-forming cells (PFC) in cultured human peripheral blood lymphocytes (PBL). PAGF, 0.25 to 1 mg/ml, induced maximal PFC at 6 to 7 days as measured by the staphylococcal protein A-coupled SRBC reverse hemolytic plaque assay with a rabbit anti-human Ig antiserum. PAGF-induced PFC/culture ranged from 1800 to 39,000 with a mean of 11,524 in unfractionated PBL (N = 24), as compared to 540 to 77,840 with a mean of 17,303 for pokeweed (PWM) (N = 22). Comparison of PAGF- and PWM-induced PFC showed that both induced specific IgG, IgA, and IgM PFC. In most individuals, PAGF induced more IgM and PWM more IgG PFC. The kappa: lambda ratio was 1.5 for unstimulated PBL, and approximately 3.5 for PAGF and PWM. To see if PAGF was a T-dependent polyclonal activator of B cells, T and non-T populations were obtained by SRBC rosettes and negatively selected T4 and T8 cells by complement-mediated lysis of SRBC+(T) cells. Only the recombined subsets which included T4 cells and non-T cells supported PAGF- and PWM-induced PFC. These data indicate that PAGF, a substance derived from commercial extracts of pregnancy urine, is a T4-dependent polyclonal activator of normal human B cells.     

Induction of monocytic suppression after stimulation of peripheral human mononuclear cells with staphylococcal protein A and Staphylococcus aureus

Staphylococcal protein-A (SPA) and Staphylococcus aureus are known to be polyclonal human B-cell activators. It was noted that they induced plaque-forming-cell (PFC) responses lower than those induced by pokeweed mitogen (PWM) and the possibility of early triggering of a suppressor cell was investigated in the present series of experiments. Peripheral mononuclear cells (MNC) were passed through Sephadex G-10 columns to eliminate monocytes. The PFC responses to SPA and S. aureus were thereby increased. PWM-driven PFC responses are suppressed by the simultaneous presence of SPA in a dose-related way, if present in the early phases of the cultures. MNC precultured with SPA or S. aureus have the ability to suppress the PFC response of autologous MNC to PWM. Interestingly this suppressor cell activity was radiation resistant and could not be abrogated by treatment with anti-T-cell monoclonal antibody plus complement. The above experiments clearly demonstrate that the observed low PFC responses of MNC after stimulation with SPA and S. aureus are due to the induction of suppressor cells by these stimulants. The suppressor cells are apparently of monocytic origin.     

MLC-derived human helper factor(s) that promote B cell differentiation: induction, functional characterization, and role of Ia antigens

Utilizing a PFC assay to quantitate the polyclonal activation of human peripheral blood B lymphocytes, we have investigated the induction and functional activity of MLC-derived human helper factor(s). Our data demonstrate that highly purified responder T cells, but not B or null cells, are required for the elaboration of MLC helper factor(s) that trigger the in vitro differentiation of B lymphocytes into PFC. Helper factor can trigger B cell maturation in the absence of helper T cells, since complement- (C) mediated lysis of the small (less than 5%) fraction of T cells present in anti-F(ab)2 immunoabsorbent column purified B cell population eliminates the PWM induced, but not the helper factor-induced PFC response. Responder T cells required for helper factor production do not bear surface membrane Ia, since alpha p23,30 + C treatment of this population does not affect helper factor generation. In contrast, alpha p23,30 + C treatment of the allogeneic stimulator cell population eliminates helper factor production. Taken together, these results demonstrate that interaction between Ia-bearing stimulator cells and Ia- responder T cells is required for the production of MLC-derived helper factor. In additional experiments, we determined that alpha p23,30, in the absence of C, totally abrogates the PFC response triggered by MLC helper factors. This result suggests an important role for Ia antigens in the functional activity of preformed helper factor molecules.     

Cell interactions in alveolar macrophage-mediated suppression of the immune response: an unusual suppressor pathway involving a population of T-cells that express Lyt-1, L3T4, and I-J

Studies from this laboratory have demonstrated that incubation of murine alveolar macrophages (AM) with SRBC-primed spleen cells (SC) results in suppression of the in vitro plaque-forming cell (PFC) response and that suppression is mediated by a soluble factor contained in supernatants obtained from cultures of AM and SC. In the present study, immunological techniques employing monoclonal antibody (MoAb) were used to isolate various T-cell subsets in order to determine the phenotype of the cells which interact with AM to produce suppression. Spleen cell populations depleted of Thy-1+-, Lyt-1+-, L3T4+-, or I-J+-bearing cells failed to generate suppressive supernatants when cultured with AM. Depletion of Lyt-2+ T-cells (the classical suppressor/effector subset) did not alter the ability of the remaining cell population to cooperate with AM for generation of suppressive supernatants. Direct suppression of the PFC response in cultures containing AM was abrogated after treatment of the spleen cells with anti-I-J, but not anti-Lyt-2 MoAbs. Reconstitution of the AM-mediated suppressive response with enriched populations of SC required the presence of T-cells which expressed Lyt-1, L3T4, and I-J. These results suggest the existence of an unusual suppressor pathway involving I-J restriction but which appears to be mediated by the interaction of AM with a population of T-cells that expresses surface markers characteristic of T-helper cells.     

Proliferation of chicken peripheral blood leukocytes in response to pokeweed mitogen is macrophage dependent

Chicken peripheral blood leukocytes (PBL) proliferate in vitro in response to a wide range of pokeweed mitogen (PWM) concentrations. The PWM response was not influenced by the major histocompatibility complex (MHC) haplotype nor by the intrinsic responsiveness of the PBL to concanavalin A (Con A). The results indicate that PWM under our conditions stimulates B-lineage cells, although a T-cell subset is also clearly induced to division. The PBL from B-cell-depleted animals gave substantially lower responses than those from normal controls. Pokeweed mitogen stimulation of PBL was adherent cell dependent. Thus the low PWM response of adherent cell-depleted PBL was reconstituted by the addition of irradiated unseparated PBL. Furthermore, purified irradiated adherent cells containing greater than 90% macrophages were also able to reconstitute PWM responses. Finally, we have shown that PWM was able to induce large numbers of B cells to produce cytoplasmic immunoglobulin. However, only a minor proportion of such cells were induced to immunoglobulin secretion.     

Regulation of the secondary in vitro antibody response by endogenous natural killer cells: kinetics, isotype preference, and non-identity with T suppressor cells

Our previous studies had demonstrated that depletion of endogenous natural killer (NK) cells resulted in an augmented primary antibody response in vivo and in vitro. We have now examined the effect of NK cell depletion on the in vitro secondary response to antigen. Treatment of primed murine spleen cells with anti-NK-1.1 allo-antibody and complement before culture resulted in a significant increase in the magnitude of the antigen-specific plaque-forming cell (PFC) response. This treatment did not affect the proportions of Lyt-2+, L3T4+, or sIg+ cells in the population, however, indicating that the augmentation in PFC was not due to changes in the ratio of T to B cells. Removal of endogenous NK cells had a greater effect on the IgG (indirect) PFC response (100 to 200% increase) than on the IgM (direct) PFC response (25 to 50% increase). In contrast, removal of Lyt-2+ cells before culture affected the IgM and IgG responses similarly. Moreover, the kinetics of augmentation differed between cultures depleted of Lyt-2+ cells and those depleted of NK-1.1+ cells. NK cells appeared to act earlier in the response than did T suppressor cells. The NK-1.1+ cells involved in antibody regulation were not involved in the generation of the in vitro derived T suppressor cells. The conclusion that the regulation of the antibody response by NK-1.1+ cells is distinct from that involving T suppressor cells was confirmed in experiments in which removal of both regulatory cell populations resulted in an increase in PFC that was greater than in cultures depleted of either NK or T suppressor cells.     

PPD-induced immunoglobulin production in human peripheral blood lymphocytes. I. Necessary conditions for inducing the response.

The ability of PPD to induce Ig production in human PBL was investigated. PPD proved to be a good B cell activator for inducing polyclonal Ig production in PBL from healthy Japanese. Comparative studies of this response with PWM-induced Ig production showed that the cellular mechanisms involved in the two responses were different. First, PBL from an atypical individual with a deficient IgM production to PWM responded normally to PPD with IgM production as well as IgG production. Secondly, in IgG production, the effects of the two mitogens (PPDand PWM) were additive. An analysis of the cellular requirements in PPD-induced Ig production clearly demonstrated that T cells played a role in this response as well as in the PWM-induced response. However, the head-to-head comparative study on the titration curves of helper T cells in the two responses showed that PWM-induced helper activity was 2 to 5 times more effective than PPD-induced helper activity. Moreover, PPD-induced helper activity was shown to be more sensitive to ionizing radiation than was PWM-induced helper activity. Thus, this system of PPD-induced Ig production may provide a useful tool for understanding the human antibody production system as well as the PWM-induced response.     

Suppression of B-cell differentiation by natural killer (asialo GM1+) cells in mice

Mice were injected intravenously with rabbit antiserum to ganglio-n-tetraosylceramide (asialo GM1, ASGM1), a neutral glycosphingolipid present at high quantities on the surface of natural killer (NK) cells. Spleen cells prepared from the mice were then examined for NK activity against YAC-1 targets, for phagocytic cells and by flow cytometric analysis for Thy1, Lyt1, Lyt2, ASGM1 and surface Ig (SIg) phenotypes. Administration of anti-ASGM1 in mice resulted in a complete depletion of NK activity and ASGM+1 cells in the spleen, but no changes in the proportions of Thy1+ cells and their Lyt1+ and Lyt2+ subsets and phagocytic cells. Corresponding to this selective depletion of ASGM+1 cells and NK activity, the spleen cells showed an increased number of SIg+ B cells and augmented mitogenic responses to B-cell but not T-cell mitogens. These NK-depleted spleen cells also showed production of pokeweek mitogen (PWM)-driven plaque-forming cells (PFC) to much higher levels than those of control spleens. In the spleens of mice treated with varying concentrations of anti-ASGM+1, a good correlation was found between the decreased NK activity and the enhanced PFC response. To directly test the possible suppressor activity of NK cells on PWM-induced PFC response, NK (ASGM+1) cells were highly purified from the spleen by a combination of Percoll gradients and cytolysis of T cells by monoclonal antibodies followed by indirect panning. When added to NK-depleted spleen cells, they suppressed the augmented PFC response of NK-depleted spleen cells, depending on the number of cells added. These results suggest that NK (ASGM+1) cells in mice exhibit a suppressor property on B cells, which are undergoing spontaneous or mitogen-induced differentiation.     

Regulation of B cell maturation and differentiation. I. Suppression of pokeweed mitogen-induced B cell differentiation by tumor necrosis factor (TNF)

Growth and differentiation of B cells into Ig-secreting plasma cells is regulated by both T cells and macrophages and/or their secreted factors. Although the regulatory role of various cell-derived factors has been examined, the involvement of the macrophage-derived factor, TNF, in human B cell growth and differentiation has not yet been investigated. In the present study we examine the role of rTNF in polyclonal B cell response of human PBL induced by PWM. The addition of rTNF at the initiation of the culture resulted in the dose-dependent inhibition of the generation of both IgG and IgM PFC. Inhibition of PFC development followed the same dose response as rTNF-mediated cytotoxicity against a TNF-sensitive tumor target. The mechanism of rTNF-mediated suppression was examined in different experimental systems. Recombinant TNF did not affect the viability or proliferation of either the T cell or B cell subpopulations, suggesting that TNF does not mediate its suppressive effect by cytotoxic mechanisms. Kinetic studies in which rTNF was added at different times after initiation of culture indicated that inhibition can be observed as late as 4 days of culture and suggested that TNF acts at a late phase of the growth and differentiation pathway of B cells. In further studies we examined the cellular level of TNF-mediated suppression. The addition of rTNF to supernatants containing helper factors and enriched B cells resulted in no inhibition, suggesting that TNF does not act at the B cell level. This was confirmed by demonstrating that rTNF does not inhibit spontaneous PFC development by the CESS B cell line. The effect of TNF on T cell subpopulations was examined by using normal or irradiated T cells, which inactivate suppressor cells. Addition of rTNF to B cells combined with either T cell population suppressed both IgG and IgM PFC development, indicating that the target cell for suppression is the T helper cell but not ruling out an effect on macrophages or the T suppressor cells. Combined, the observed results demonstrate that rTNF suppresses PWM-induced B cell differentiation without affecting B cell proliferation. TNF appears to mediate the suppression by acting directly on T helper cells or else by regulating the production of factors controlling T cell activation and lymphokine secretion.     

Suppressor cell function of human granular lymphocytes identified by the HNK-1 (Leu 7) monoclonal antibody

The HNK-1 (Leu 7) differentiation antigen defines a subpopulation of human granular lymphocytes with natural killer (NK) and K cell function. In this study, we investigated whether HNK-1+ cells, identified with the monoclonal antibody and purified with a fluorescence-activated cell sorter (FACS), could function as suppressor cells. The results demonstrated that purified HNK-1+ cells efficiently suppressed both PWM-induced IgG production by B cells and T cell proliferation in mixed lymphocyte reactions (MLR). Manifestation of this suppressor cell activity required immune complex activation and was partially sensitive to 2000 rad irradiation. This suppressor cell activity was predominantly mediated by a subset of HNK-1+ cells that have previously been shown to have maximum NK function and lack expression of the E rosette (ER) receptor and T cell antigens (e.g., T3 and T8). Thus, HNK-1+ER- cells suppressed a MLR by an average 52%; HNK-1+ER+ were one-half as efficient, causing an average 23% suppression. For comparison, we also examined the characteristics of Leu 2a+ suppressor T lymphocytes. In contrast to HNK-1+ cells, unactivated Leu 2a+ cells suppressed both B and T cell responses. This suppressor activity was not augmented by immune complex activation and was absolutely radio-sensitive in PWM assays. HNK-1+ cells, especially the HNK+ER- subset, can therefore mediate suppressor cell function in addition to their spontaneous cytotoxic function. Furthermore, some of their suppressor cell properties are distinct from those attributed to other types of suppressor lymphocytes.