Control of human B lymphocyte responsiveness: enhanced suppressor T cell activity after in vitro incubation.

Human peripheral blood mononuclear cells (PBM) lost the capacity to generate immunoglobulin-secreting cells (ISC) in response to pokeweed mitogen (PWM) after a period of preincubation in vitro. When fresh PBM were co-cultured with preincubated PBM their response to PWM was inhibited, indicating that enhanced suppressor activity developed in the aged PBM concomitant with the loss of PWM responsiveness. Suppressor cell activity of aged PBM was present within the T lymphocyte population. The suppressor T cell inhibited PWM responsiveness of autologous and homologous PBM to an equivalent degree. The action of the suppressor cell was abrogated by inhibitors of DNA synthesis or by hydrocortisone. A suppressor T cell population with similar characteristics was found in freshly prepared PBM before in vitro incubation. Expansion of this suppressor T cell population during preincubation required cell division. There was no change in the functional capability of the helper T cell population as a result of similar in vitro culture. These observations indicate that a T cell population capable of suppressing PWM-induced generation of ISC can be selectively expanded by in vitro incubation of normal human PBM without additional mitogenic stimulation. Moreover, these data emphasize that control of B lymphocyte differentiation involves a critical interrelationship between T lymphocyte subpopulations exerting both positive and negative influences.     

The role of B cell proliferation in the generation of immunoglobulin-secreting cells in man

The relationship of B cell proliferation and the generation of immunoglobulin-secreting cells (ISC) was explored in vitro by examining the effect of hydroxyurea (HU), an inhibitor of cellular DNA synthesis, on the generation of ISC from human peripheral blood mononuclear cells (PBM). HU completely inhibited the capacity of PBM to generate ISC in response to pokeweed mitogen (PWM) and other polyclonal B cell activators. Inhibition resulted from an effect on B cell proliferation, because HU also prevented the generation of ISC in cultures of purified B cells supplemented with either T cell supernatants or mitomycin C-treated T cells. Inhibiting B cell proliferation by treating them with mitomycin C before culture also abolished the generation of ISC. When ISC were enumerated after a 7-day incubation with PWM, the addition of HU as late as day 6 of culture was found to inhibit responsiveness markedly. This suggested that those cells that had acquired the capacity to secrete lg were actively dividing, and continued division was necessary for ongoing lg secretion. To examine this possibility, experiments were carried out in which responsiveness was assayed on a daily basis. ISC could be detected after a 3- or 4-day incubation and reached maximum at day 6 or 7. Addition of HU on days 3 to 7 caused a highly significant reduction in the number of ISC within 24 hr. ISC did not begin to show resistance to the effects of HU until later in culture. This observation supported the conclusions that ISC were a rapidly cycling cell population and that ongoing lg secretion, as well as expansion in the number of ISC, depended on continued proliferation of the ISC. To confirm directly that ISC were a cycling cell population, PBM were cultured with PWM for 6 days, fixed, stained for both cytoplasmic lg and DNA content, and analyzed on the fluorescence-activated cell sorter. This method made it possible to quantitate the DNA content of individual lg-synthesizing cells and thus to determine their position in the cell cycle. As many as 40% of cytoplasmic lg-positive cells were found to be in the S, G2, or M phases of the cell cycle. These data indicate that ISC generated in man after in vitro stimulation with a number of polyclonal activators are not stable terminally differentiated lg-secreting plasma cells but rather an actively cycling lg-secreting population. Furthermore, the results indicate that proliferation of the ISC themselves plays an important role in determining the magnitude of the resultant antibody response.     

Enhancement of human B cell proliferation and differentiation by tumor necrosis factor-alpha and interleukin 1

The role of tumor necrosis factor-alpha (TNF-alpha) in human B cell responses was examined and compared with that of interleukin (IL) 1 by assessing the ability of each cytokine to support proliferation and differentiation. Recombinant TNF-alpha (rTNF-alpha) and recombinant IL-1 (rIL-1) each enhanced the generation of immunoglobulin-secreting cells (ISC) in cultures of pokeweed mitogen-stimulated B cells incubated with T cells. To examine the direct effect of rTNF-alpha and rIL-1 on the responding B cell, highly purified peripheral blood B cells were stimulated with Cowan I Staphylococcus aureus (SA). In the absence of T cell factors, proliferation was minimal and there was no generation of ISC. Recombinant IL-2 (rIL-2) supported both responses. Although rTNF-alpha alone did not support SA-stimulated generation of ISC, it did increase SA-stimulated B cell DNA synthesis by two- to eightfold. In addition, rTNF-alpha augmented B cell proliferation in rIL-2 supported SA-stimulated cultures. Moreover, rTNF-alpha enhanced the generation of ISC stimulated by rIL-2 alone or rIL-2 and SA. rIL-1 also augmented DNA synthesis and generation of ISC by B cells stimulated with SA and rIL-2. However, rTNF-alpha enhanced proliferation and ISC generation in SA + rIL-2-stimulated cultures even when they were supplemented with saturating concentrations of rIL-1. Utilizing a two-stage culture system, it was found that the major effect of rTNF-alpha was to enhance responsiveness of SA-activated B cells to rIL-2, whereas it exerted only a minimal effect during initial stimulation. These results indicate that TNF-alpha as well as IL-1 augment B cell responsiveness. Moreover, the ability of rTNF-alpha to enhance B cell responsiveness was not an indirect effect resulting from the induction of Il-1 production by contaminating monocytes, but rather resulted from the delivery of a signal by rTNF-alpha directly to the responding B cell that promoted both proliferation and differentiation after initial activation. The data therefore indicate that human B cell responsiveness can be independently regulated by the action of two separate monocyte-derived cytokines.     

Inhibition of human B cell responsiveness by prostaglandin E2

The capacity of prostaglandin E2 (PCE2) to modulate human peripheral blood B cell proliferation and the generation of immunoglobulin-secreting cells (ISC) stimulated by Cowan 1 strain Staphylococcus aureus and mitogen-stimulated T cell supernatant was examined. PGE2 significantly inhibited both responses, whereas PGF2 alpha had no inhibitory effect. Responses of highly purified B cells obtained from spleen, lymph node, and tonsil were also inhibited. In addition PGE2 suppressed B cell responses supported by recombinant interleukin 2 rather than T cell supernatant. PGE2-mediated inhibition was mimicked by forskolin, a direct activator of adenylate cyclase. Kinetic studies indicated that PGE2 inhibited B cell responses by a progressively greater increment as cultures were prolonged. Evaluation by flow cytometry after staining with acridine orange or mithramycin indicated that PGE2 had no effect on initial B cell entry into the G1 phase of the cell cycle, passage through G1, and entry into S, G2, and M. Rather, PGE2 inhibited responses of postdivisional daughter cells. PGE2 inhibited responses in cultures stimulated by the calcium ionophore ionomycin and T cell supernatant but had minimal effects in cultures stimulated by the combination of ionomycin and phorbol myristate acetate. Moreover, phorbol myristate acetate reversed PGE2-mediated inhibition of proliferation stimulated by S. aureus or S. aureus + T cell supernatant. These results indicate that PGE2 suppresses the continued growth and differentiation of human B cells, although it has no effect on initial B cell activation and suggest that PGE2 may play a role in regulating human B cell responses in vivo.     

Identification and characterization of a B cell growth inhibitory factor (BIF) on BCGF-dependent B cell proliferation

The culture supernatants of Con A-activated human peripheral blood mononuclear cells (PBM) contained at least two regulatory factors upon B cell proliferation. One was B cell growth factor (BCGF), which activated antigen-stimulated B cells to proliferation and clonal expansion, and the other was its inhibitory factor, arbitrarily named B cell growth inhibitory factor (BIF). This BIF inhibited the effect of BCGF on anti-mu-stimulated B cells or the monoclonal mature B cell line (CLL-T.H.) obtained from the peripheral blood lymphocytes of B cell-type chronic lymphocytic leukemia patients, which were activated only with BCGF and without adding other proliferating stimuli (e.g., anti-mu). BIF activity was detected in the 24 hr culture supernatants of Con A-activated human PBM in FCS containing medium and also in serum-free RPMI 1640 medium. This substance with BIF activity could not be derived from FCS. Con A-induced BIF (m.w. of 80,000 and an isoelectric point of pH 5.4) was analyzed by Sephadex G-200 gel filtration and chromatofocusing. BIF was stable at pH 2.0 and at 56 degrees C for 30 min. Partially purified BIF had no effect on cell viability and almost no interferon activity (less than 1 IU/ml). BIF with high titer had a slight but significant inhibition on TCGF-dependent T cell growth and on PHA or Con A responses, but the extent of these inhibitions was far less than that of BCGF-dependent B cell growth. Absorption of BIF with Con A blasts made its inhibition on T cell growth even less. On the other hand, BIF activity could not be absorbed with Con A blasts but was almost absorbed with large numbers of CLL-T.H. cells. BIF had almost no inhibitory effect on the proliferation of a mouse fibroblast cell line (NIH 3T3), a mouse myeloma cell line (NS-1), human lymphoid cell lines (MOLT-4, HSB-2, and Daudi), or a human myeloid cell line (K-562). BIF-producing cells were estimated to be T cells and were identified as T8+ T cells. On the other hand, Con A-induced BCGF was demonstrated to be produced predominantly by T4+ T cells. These results show that human B cell proliferation is regulated by interaction between T4+ and T8+ cells via soluble factors, namely BCGF and BIF, respectively.     

Regulation of human B cell responsiveness by CD8+ T cells: differential effects of stimulation with monoclonal antibodies to CD3 and pokeweed mitogen

Previous studies have shown that human CD8-positive T cells activated by immobilized mAb to the CD3 complex have the capacity to support the generation of Ig secreting cells (ISC). The experiments reported here were undertaken to examine the nature of CD8+ T cell helper function in greater detail. CD8+ T cells that had been treated with mitomycin C (CD8+ mito) and stimulated by immobilized mAb to CD3 (64.1) provided help for the generation of ISC from resting B cells. By contrast, CD8+ mito did not support the generation of ISC in cultures stimulated by pokeweed mitogen (PWM). This could not be explained by differences in the production of IL2, since PWM and anti-CD3 induced comparable amounts of IL2 from CD8+ mito. In anti-CD3-stimulated cultures, CD8+ mito supported the generation of larger numbers of ISC when B cells were also activated with Staphylococcus aureus (SA). By contrast, in PWM-stimulated cultures, CD8+ mito did not provide help for SA-activated B cells. Rather, PWM-stimulated CD8+ mito appeared to suppress the generation of ISC induced by PWM-activated CD4+ mito or by SA + IL2, whereas anti-CD3-stimulated CD8+ mito did not. Only control CD8+ T cells, which were able to proliferate, exerted suppressive effects in anti-CD3-stimulated cultures. Examination of the functional capacities of a battery of CD8+ T cell clones indicated that the same clonal population of CD8+ cells could provide help or suppress responses when stimulated with anti-CD3 or PWM, respectively. The functional activities of CD8+ clones differed from those of fresh CD8+ cells. Thus, anti-CD3-stimulated CD8+ clones provided help for B cells regardless of whether they were treated with mitomycin C. Moreover, PWM stimulated suppression by CD8+ clones was abrogated by treating the clones with radiation or mitomycin C. These results indicate that helper T cell function is not limited to the CD4+ T cell population, but that help can also be provided by appropriately stimulated CD8+ T cells. Taken together, these results indicate that CD8+ T cells are not limited in their capacity to regulate B cell responses, but rather can provide positive or negative influences depending on the nature of the activating stimulus.     

Heterogeneity of human monocyte subsets in the promotion of B cell colonies and the role of interleukin 1

The abilities of human peripheral blood mononuclear-phagocyte (M phi) subpopulations and of interleukin 1 (IL 1) to support human B cell colony formation in semisolid cultures stimulated by staph protein A were analyzed. Human M phi subsets enriched for complement receptors (CR) effectively functioned as accessory cells supporting colony growth, whereas the responses obtained with CR-depleted M phi were 4.6-fold less. In experiments analyzing IL 1 production, CR-enriched M phi secreted four to 12 fold greater amounts of basal and stimulated IL 1 than CR-depleted M phi. Also, the addition of IL 1 to CR-depleted M phi resulted in a fourfold increase of colony numbers. The responses of cultures containing CR-depleted M phi plus IL 1, however, remained 30% less than those observed for cultures supplemented with CR-enriched M phi. Other studies showed that IL 1 was unable to substitute for M phi; the responses of cultures containing IL 1 and B cells were reduced 10-fold compared to cultures supplemented with autologous M phi. These findings indicate that human M phi subsets exist that differ in their ability to function as accessory cells. Although IL 1 can collaborate with certain M phi subsets to restore their accessory cell function, it cannot replace intact M phi. Thus, it is possible that other monokines or lymphokines play a role in M phi accessory cell function.     

Synergistic effect of concanavalin A and Bu-WSA on DNA synthesis in human peripheral blood lymphocytes

Butanol-extracted water soluble adjuvant (Bu-WSA) obtained from Bacterionema matruchotii was not mitogenic for human peripheral blood mononuclear cells (PBM) but was capable of enhancing (3H) thymidine uptake of T cells stimulated by concanavalin A (Con A) in the presence of B cells or macrophages (M phi) in vitro. The mechanisms of the synergy of Con A and Bu-WSA were studied by using separated cell populations from PBM. Both subfractioned OKT4+ and OKT8+ cells were responsive to co-stimulation by Con A and Bu-WSA in the presence of an accessory cell population. Allogeneic B cells and M phi as well as autologous cells had helper function as accessory cells. Heavy irradiation with gamma-rays did not affect the function of the accessory cells, but previous treatment of B cells with anti-Ig serum plus complement (C) or treatment of M phi with anti-M phi serum plus C deprived them of their function. The treatment of accessory cells with anti-HLA-DR serum, regardless of the presence or absence of C, resulted in loss of their helper function. Cultures in Marbrook-type vessels showed that a mixed cell population of T cells and accessory cells in the lower chamber produced some active factor(s) after co-stimulation with Con A and Bu-WSA, and by passing through the membrane filter separating the chambers, the factor(s) enhanced the proliferation of the Con A-activated T cell population in the upper chamber. The factor(s) was presumed to be interleukin 2 (IL 2), because it supported the growth of IL 2-dependent CTLL cells. These results indicate that the synergy of Con A and Bu-WSA on the proliferative response of human PBM is due to the elevation of growth factor production from T cells stimulated by those mitogens.     

Effect of T3 modulation on pokeweed mitogen-induced T cell activation: evidence for an alternative pathway of T cell activation

Modulation of the T3 molecule on human T cells with monoclonal anti-T3 antibodies has been shown to result in the disappearance of the T3-Ti complex from the membrane and to preclude subsequent T cell activation by various mitogenic and antigenic stimuli. We have examined the effect of T3 modulation on pokeweed mitogen (PWM)-induced T cell activation. T3 modulation was accomplished by incubating peripheral blood mononuclear cells (PBMC) or mixtures of T cells and non-T cells at 37 degrees C for 18 hr in the presence of UCHT-1, a mouse IgG1 anti-T3 monoclonal antibody. Only donors whose PBMC were unresponsive to the mitogenic activity of this antibody were selected. Although T3 modulation resulted in complete to substantial inhibition of T cell proliferation induced by low PWM concentrations of 5 or 50 ng/ml, it had no effect on T cell proliferation when PWM was added at a concentration of 0.5 and 5 micrograms/ml. The results demonstrate that the higher doses of PWM can induce T cell proliferation via an alternative pathway that does not involve participation of the T3-Ti complex. In contrast, irrespective of the PWM dose added, T3 modulation almost totally inhibited PWM-induced interleukin 2 (IL 2) production. The differential effect of T3 modulation on IL 2 production and on T cell proliferation induced by high doses of PWM suggests that this alternative pathway of T cell proliferation is IL 2 independent. This suggestion was additionally substantiated by the lack of effect of anti-Tac, and anti-IL 2 receptor antibody, on PWM-induced proliferation of T3-modulated T cells. In conclusion our data demonstrate that high doses of PWM can induce T cells to proliferate via an alternative pathway that does not involve perturbation of the T3-Ti complex.     

Monocyte dependence of pokeweed mitogen-induced differentiation of immunoglobulin-secreting cells from human peripheral blood mononuclear cells.

Human peripheral blood mononuclear cells (PBM) lost the capacity to generate immunoglobulin-secreting cells (ISC) in response to pokeweed mitogen (PWM) when depleted of adherent cells (AC). The diminished responsiveness of the nonadherent cells (NAC) could not be ascribed to cell death, altered PWM dose response characteristics, or a change in the length of incubation required to generate a response. Supplementation with autologous or homologous AC, but not 2-mercaptoethanol, restored the capacity of NAC to generate ISC after PWM stimulation. By standard criteria AC were found to contain 85 to 90% monocytes. Furthermore, the monocytes and not the few lymphocytes contaminating the AC were responsible for restoring PWM responsiveness to the NAC. PWM-induced DNA synthesis of NAC also was markedly reduced compared to PBM. Again, supplementation with monocytes restored responsiveness to NAC. The monocyte dependence of PWM-induced proliferation and generation of ISC was most apparent when cultural conditions were employed that limited cell-to-cell interaction.     

T cell-dependent activation of B cell proliferation and differentiation by immobilized monoclonal antibodies to CD3

The capacity of mAb directed at the CD3 molecular complex (64.1) to induce T cell-dependent B cell proliferation and differentiation was examined. Coculture of B cells with mitomycin C-treated T4 cells (T4 mito) stimulated by immobilized 64.1 resulted in marked B cell proliferation and Ig-secreting cells (ISC) generation in the absence of any additional stimulation. The magnitude of the B cell responses induced by immobilized 64.1-stimulated T4 mito was far greater than that induced by other stimuli, such as Staphylococcus aureus plus factors produced by mitogen-activated T cells, PWM, or soluble 64.1. The induction of maximal B cell responsiveness required direct contact between activated T cells and responding B cells. Of note, immobilized 64.1 also induced B cell proliferation and ISC generation in the presence of mitomycin C-treated T8 cells. By contrast, immobilized 64.1 stimulated T4 or T8 cells that had not been treated with mitomycin C induced very modest ISC generation and suppressed B cell responses supported by T4 mito even in the presence of exogenous IL-2 or factors produced by mitogen-activated T cells. The interactions between T and B cells in these cultures not only induced B cell responses, but also enhanced the production of IL-2 by activated T cells. Increased IL-2 production was facilitated when culture conditions afforded the opportunity for contact between B cells and activated T cells. These results indicate that the establishment of interactions between B cells and anti-CD3-stimulated T4 or T8 cells provides all of the signals necessary for proliferation and differentiation of B cells without other stimuli and also augments the production of lymphokines by the activated T cells. The data emphasize the role of Ag-nonspecific interactions between B cells and T cells in promoting polyclonal responses of both cell types.     

Induction of human B cell differentiation by Fc region activators. II. Stimulation of IL-6 production

Fc region fragments derived from the enzymatic cleavage of human IgG have been shown to induce human peripheral blood-derived B cells to differentiate into Ig secreting cells (ISC). The synthetic peptide p23, corresponding to residues 335 to 357 in the Fc region of human IgG1, represents a region of the molecule responsible for stimulation of ISC formation. Fc region-induced ISC formation requires at least two signals; one supplied by Fc region activators and one supplied by a T cell-derived factor(s). In this report we show that the coculture of human PBMC with pFc' or p23, results in the release of factor(s) that resemble IL-6 in its pattern of biologic activity. This conclusion is based on the observations that supernatants from Fc region-stimulated PBMC cultures contained increased levels of elements that scored as positive in two assays for IL-6: the B9.9 hybridoma growth and the CESS cell differentiation assays. Moreover, RNA from Fc region-stimulation PBMC contained increased levels of IL-6 cDNA-hybridizable elements. Finally, it was observed that rabbit anti-IL-6 inhibited the ability of supernatants derived from Fc region-stimulated PBMC cultures to induce B9.9 cell proliferation as well as p23-induced ISC formation in intact PBMC cultures. Fc region fragments induce both monocytes and T cells to produce IL-6. Taken together, these results indicate that IL-6 is produced in Fc region-stimulated PBMC cultures and is involved in B cell activation by these activators.     

IL-2 dependence of the promotion of human B cell differentiation by IL-6 (BSF-2)

The effect of rIL-6 on the growth and differentiation of highly purified human peripheral blood B cells was examined. IL-6 alone induced minimal incorporation of [3H]thymidine by unstimulated or Staphylococcus aureus (SA)-stimulated B cells and did not augment proliferation induced by SA and IL-2. Similarly, IL-6 alone did not support the generation of Ig-secreting cells (ISC) or induce the secretion of Ig by unstimulated or SA-stimulated B cells. However, IL-6 did augment the generation of ISC and the secretion of all isotypes of Ig induced by SA and IL-2. Maximal enhancement of B cell responsiveness by IL-6 required its presence from the initiation of culture. Delaying the addition of IL-6 to B cells stimulated with SA and IL-2 beyond 24 h diminished its effect on ISC generation. However, increased Ig production but not ISC generation was observed when IL-6 was added to B cells that had been preactivated for 48 h with SA and IL-2. This effect was most marked when the activated B cells were also stimulated with IL-2. IL-6 in combination with other cytokines such as IL-1 and IL-4 did not induce the secretion of Ig or generation of ISC in the absence of IL-2. Moreover, antibody to IL-6 did not inhibit the effect of IL-2 on the growth and differentiation of B cells stimulated with SA, but did inhibit the IL-6-induced augmentation of Ig secretion by B cells stimulated with SA and IL-2. IL-6 alone enhanced T cell dependent induction of B cell differentiation stimulated by PWM. Part of this enhancement was related to its capacity to increase the production of IL-2 in these cultures. These results indicate that IL-6 has several direct enhancing effects on the differentiation of B cells, all of which are at least in part dependent on the presence of IL-2. In addition, IL-6 can indirectly increase B cell differentiation by increasing IL-2 production by T cells.     

Inhibitory influence of IL-4 on human B cell responsiveness

The role of IL-4 in human B cell activation, proliferation, and differentiation was examined. rIL-2, but not rIL-4, was able to promote maximum proliferation and generation of Ig-secreting cells in cultures of highly purified B cells stimulated with Cowan I Staphylococcus aureus (SA). Addition of rIL-4 to rIL-2-supported cultures of SA-stimulated peripheral blood, spleen, or lymph node B cells dramatically suppressed both proliferation and differentiation. Results from experiments in which rIL-4 was added to culture at progressively later times indicated a requirement for rIL-4 to be present during the first 2 days of a 5-day incubation to cause inhibition of responsiveness. When a two-stage culture system was utilized, rIL-4 was found to support proliferation or differentiation of B cells initially activated with SA for 2 days only minimally. However, rIL-4 did not inhibit responses of SA preactivated B cells supported by IL-2. The presence of rIL-4 during the initial 48-h activation of B cells with SA and rIL-2 resulted in a profound inhibition of the ability of the activated B cells to respond subsequently to rIL-2 or lymphokine-rich T cell supernatants. A similar 48-h incubation with rIL-4 alone without SA had no effect on subsequent B cell responsiveness. The presence of rIFN-gamma during B cell activation decreased the inhibitory effect of IL-4. Other cytokines including IFN-alpha, IL-1, and commercially available low m.w. B cell growth factor also diminished the inhibitory effect of IL-4. These results indicate that IL-4 inhibits the capacity of human B cells to be activated maximally by SA and rIL-2 and therefore suggest a new immunomodulatory role for this cytokine.     

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.     

Modulation of human natural killer cell function by L-leucine methyl ester: monocyte-dependent depletion from human peripheral blood mononuclear cells

L-leucine methyl ester (Leu-OMe) causes lysosomal disruption and death of human monocytes (M phi). In addition, Leu-OMe removed natural killer cell (NK) activity from human peripheral mononuclear cells (PBM). Thus, a brief preincubation of PBM with Leu-OMe (greater than 1 mM) caused irreversible loss of NK function as assessed by the lysis of K562 targets. By contrast, a variety of other amino acid methyl esters, including L-glutamic dimethyl ester, L-valine methyl ester, and L-isoleucine methyl ester caused reversible inhibition of NK activity in a manner that was similar to other lysosomotropic agents such as chloroquine and ammonium chloride, but did not cause irreversible loss of all NK function. Leu-OMe appeared to cause actual removal of NK effector cells from PBM, because K562 target binding cells, Leu-11b+ lymphocytes, and OKM1+ lymphocytes were depleted. If M phi were removed from PBM before the incubation, Leu-OMe caused only reversible inhibition of NK function in a manner similar to that observed with other amino acid methyl esters. Upon the addition of freshly isolated M phi, polymorphonuclear leukocytes, or sonicates of these cells to M phi-depleted lymphocyte populations, irreversible ablation of NK function was again observed as a result of Leu-OMe exposure. After in vitro culture, M phi lost their susceptibility to Leu-OMe toxicity and the ability to mediate the irreversible deletion of NK cells resulting from Leu-OMe incubation. These results indicate that in the absence of M phi, Leu-OMe and a variety of other amino acid methyl esters are reversible inhibitors of NK function. However, Leu-OMe is unique in that it can interact with M phi or granulocytes to effect an irreversible loss of NK activity from human peripheral blood lymphocytes.     

Frequency of human B cells that differentiate in response to anti-CD3-activated T cells

Activation of T cells by mAb to the CD3 molecular complex induces the differentiation of many more Ig-secreting cells (ISC) from resting human B cells in bulk cultures than do other modes of polyclonal B cell activation. In the current experiments, a limiting dilution assay was used to demonstrate that this increase in ISC generation reflects an increased frequency of responding B cells. Highly purified B cells were cultured at densities of between 1000 cells and 0.5 cell per microwell with fresh, mitomycin C-treated T cells (T mito) or T cell clones stimulated by immobilized mAb to CD3. After 5 days in culture, the number of wells containing ISC was determined, and the frequency of responding B cells was calculated. The proportion of B cells responding to anti-CD3-stimulated T cells was very large (10.7 +/- 2.8%) and greatly surpassed that induced by other polyclonal activators. B cells cultured with anti-CD3-stimulated T cell clones responded better than did those cultured with T mito. The addition of exogenous IL-2 or IL-6 to cultures supported by activated T mito enhanced the frequency of responding B cells, whereas IL-4 did not increase the generation of ISC and inhibited the augmentation of B cell responses induced by IL-2. Supplementation of cultures with mitomycin C-treated B cells as accessory cells had less of an effect. The addition of both accessory cells and IL-2 markedly increased B cell responsiveness, with precursor frequencies of 60 to 80% noted. In some experiments, cultures were carried out for 7 to 14 days and supernatants were analyzed for IgM, IgG, and IgA secretion. B cells activated by anti-CD3-stimulated T cells produced all three Ig isotypes. When the classes of Ig produced by single B cells were examined, it was observed that the stimulation of individual B cell precursors led to the production of multiple Ig isotypes, suggesting that isotype switching occurs in these cultures. These results demonstrate that under optimum culture conditions, T cells stimulated with immobilized anti-CD3 can activate the majority of human peripheral blood B cells to produce Ig and induce isotype switching by many.     

The roles of T cell factors in activation, cell cycle progression, and differentiation of human B cells

The relationship of the T cell influences involved in human B cell activation and differentiation into immunoglobulin-secreting cells (ISC) was investigated. T cell supernatants (T supt) generated by stimulating T cells with phytohemagglutinin and phorbol myristate acetate contained activities capable of augmenting DNA synthesis and the growth of mitogen-stimulated B cells and supporting the differentiation of ISC. To examine the role of T supt in B cell activation and the progression through the cell cycle, T cell- and monocyte-depleted B cells were stimulated with formalinized Cowan I strain Staphylococcus aureus (SA), and the percentages of cells in G1, S, and G2 + M were determined by acridine orange staining and analysis. In all experiments, a similar percentage of cells entered G1 during the first 24 to 36 hr of culture when stimulated with SA or SA + T supt. Similar results were seen when B cell activation was analyzed by acquisition of a number of other markers of cell activation. Analysis of cell cycle progression with mithramycin staining of cellular DNA in the presence or absence of vinblastine to arrest mitosis indicated that SA-activated B cells were able to complete S and divide in the absence of T supt. Although an effect of T supt on the progression of B cells through the S phase was evident during the first cell cycle, the major effect only became apparent after the first round of cell division. Although T supt was not necessary for initial B cell activation, T cell influences were absolutely necessary for the differentiation of ISC. T supt did not need to be present during the initial 24 to 36 hr of incubation to permit subsequent generation of ISC. However, when T supt was present initially, an increased number of ISC were produced. Hydroxyurea elimination of cells traversing the G1-S interphase indicated that reception of the differentiation signal occurred before the S phase, but that the generation of ISC required subsequent DNA synthesis and/or cell division. Although precursors of ISC were entirely contained within the population triggered to divide by SA alone, there was no preferential expansion of such precursors as a result of SA stimulation. These results indicate that T cell signals are not absolutely necessary for initial B cell activation and progression through the first cell cycle, although T cell factors promote DNA synthesis by some activated B cells. In contrast, differentiation into ISC is completely dependent on T cell influences.(ABSTRACT TRUNCATED AT 400 WORDS)     

Characterization of a soluble suppressor of human B cell function produced by a continuous human suppressor T cell line. II. Evidence for suppression through a direct action of CTC-SISS-B on human B cells

CTC-SISS-B is an antigen-nonspecific suppressive lymphokine elaborated by an interleukin 2-dependent suppressor T cell line that produces noncytotoxic inhibition of human B cell but not T cell function. Like SISS-B, a soluble suppressive lymphokine present in the supernatants of Con A-activated peripheral blood T cell cultures, CTC-SISS-B is of 60,000 to 90,000 m.w., and its action is blocked by the simple sugar L-rhamnose. CTC-SISS-B inhibits human B cell Ig production and proliferation through a direct interaction with human B cells rather than through indirect effects on immunoregulatory T cells or monocytes. CTC-SISS-B suppression occurs through inhibition of an early event(s) in B cell activation since proliferation and Ig production by established human B cell lines are not inhibited by this lymphokine. Despite sharing many biochemical and biologic properties, CTC-SISS-B and gamma-interferon appear to be distinct mediators.     

Human peripheral blood B lymphocyte subpopulations: functional and phenotypic analysis of surface IgD positive and negative subsets

Highly purified human peripheral blood B cells stimulated with Cowan I Staphylococcus aureus (SA) and mitogen-activated T cell supernatants (T supt) generated large numbers of immunoglobulin (Ig)-secreting cells (ISC), whereas fewer ISC developed in cultures containing T supt in the absence of SA. To determine whether surface Ig isotype expression defined responsive B cell subsets, IgD+ and IgD- B cells were prepared with the fluorescence-activated cell sorter. Whereas both the IgD+ and IgD- B cells responded to SA + T supt, only the IgD- subset generated substantial numbers of ISC in response to T supt alone. Analysis of secreted Ig revealed that IgG and IgA were the predominant isotypes secreted by IgD- B cells in response to T supt or SA + T supt. By contrast, the IgD+ cells secreted predominantly IgM in response to SA + T supt but not to T supt alone. When responsiveness to pokeweed mitogen (PWM) was examined in the presence of supplemental T cells, the IgD- subset was found to be greatly enriched for responsive cells, and again, IgG and IgA were the predominant isotypes secreted, although these cells were also capable of secreting some IgM. The magnitude of the response induced by PWM from IgD- B cells was usually greater than that induced by SA + T supt. Although IgD+ B cells responded poorly to PWM, the differentiation of a small number of IgM-secreting cells was routinely stimulated by this polyclonal activator in the presence of T cells. The magnitude of the PWM response by IgD+ B cells was always greatly diminished compared with that stimulated by SA + T supt. Cell cycle analysis after acridine orange staining, cell volume measurement, and staining for expression of activation antigens (transferrin receptor and 4F2) indicated that the IgD- B cells were largely resting, but did contain a population of activated cells. Removal of activated 4F2+ cells from the IgD- subset diminished but did not abolish their capacity to generate ISC in response to SA + T supt or PWM in the presence of T cells. These results suggest that the IgD- population contains both an activated 4F2+ and a resting 4F2- subset. The data emphasize that multiple subpopulations of peripheral blood B cells contain precursors of ISC. Moreover, the responsiveness of the subsets to various stimuli and the Ig isotype subsequently secreted appear to be intrinsic features of each subset.