Macrophages and T cells control distinct phases of B cell differentiation in the humoral immune response in vitro

The differentiation of B cells in the in vitro PFC-response to red blood cell antigen proceeds through 2 phases. Antigen-reactive B cells acquire the ability to interact with helper T cells in the first phase. This phase is controlled by macrophages through a mediator that they release (Interleukin 1 ([Il-1]). B cells convert into antibody-secreting cells (PFC) in the second phase, which is controlled by helper T cells or by a mediator that they release (T cell-replacing factors [TRF]). This is demonstrated in experiments in which Il-1 increases the number of B cells capable of responding to T cell help. The majority of antigen-reactive B cells reaches that state of differentiation within 40 hr of incubation with Il-1. After this time, the response of B cells depends no longer on the presence of Il-1 but on the presence of T cells or TRF. The presented data suggest that antigen-primed helper T cells (but not unprimed T cells) induce the release of Il-1 by macrophages, thereby also influencing the early phase of B cell differentiation.     

The adjuvant activity of synthetic N-acetylmuramyl-dipeptide: evidence of initial target cells for the adjuvant activity.

MurNAc-l-Ala-d-isoGln (N-acetylmuramyl-l-alanyl-d-isoglutamine, MDP), a synthetic compound, acts as an adjuvant on the humoral immune response and on the T cell-mediated immune response. In this report, we attempted to directly demonstrate the initial target cells of MDP for its adjuvant activity in vitro by using cell separation procedures.It was demonstrated that MDP enhanced the immune response following direct interaction with antigen-stimulated T and B lymphocytes, but nonstimulated lymphocytes, shortly after triggering by antigen, and that there was no macrophage requirement for MDP to elicite the adjuvant action in the primary anti-SRBC PFC response in vitro. It has also been demonstrated that the adjuvant activity of MDP is due to an enhancing effect which is different from the possible mitogenic activity to spleen cells and MDP replaces neither a function of macrophages, which is substituted by 2-mercaptoethanol nor a helper function of T cells.     

Enhancement of carrier-specific helper T cell function by the synthetic adjuvant, N-acetyl muramyl-L-alanyl-D-isoglutamine (MDP).

The adjuvant effect of a synthetic peptidoglycan, muramyl dipeptide (N-acetyl muramyl-L-alanyl-D-isoglutamine, MDP), was studied by using the anti-Tnp PFC and hemagglutinin responses of BALB/c mice to hapten-carrier conjugates. Administration of Tnp-OVA and MDP in saline to mice, followed 2 weeks later by a boost of Tnp-OVA in saline, led to significantly higher IgM and IgG anti-Tnp PFC and total anti-Tnp-hemagglutinin responses than those obtained in mice not treated with MDP in the initial immunization. A similar adjuvant effect by MDP on anti-hapten PFC responses was seen if mice were primed with KLH together with MDP and challenged with Tnp-KLH 2 weeks later. This apparent effect on carrier priming for helper function was confirmed and quantitated by double adoptive transfer experiments with graded numbers of spleen cells from KLH +/- MDP-primed mice and a fixed number of hapten-primed spleen cells from syngeneic Tnp-OVA immunized animals. These data suggest that at least one mode of action of the synthetic adjuvant MDP is via the enhanced stimulation of the helper T cell function.     

The augmentation of tumor-specific immunity using haptenic muramyl dipeptide (MDP) derivatives

Summary Preinduction of potent haptenic muramyl dipeptide (MDP)-reactive helper T cell activity and subsequent immunization with MDP hapten-coupled syngeneic tumor cells resulted in enhanced induction of tumor-specific immunity through T-T cell collaboration between anti-MDP hapten helper T cells and tumor-specific effector T cells. The present study establishes two types of tumor-specific immunotherapy protocols utilizing helper T cells against MDP hapten cross-reactive with Bacillus Calmette Guérin (BCG). In the first model, naive normal C3H/He mice or mice in which MDP hapten-reactive helper T cells had been generated by BCG-sensitization were inoculated i.d. with syngeneic X5563 tumor cells. When both groups of mice were allowed to generate MDP hapten-modified tumor cells in the tumor mass in situ by intratumoral injection of MDP hapten, an appreciable number of growing tumors in the BCG-presensitized but not in the unsensitized group were observed to regress. In the second model, a growing X5563 tumor mass was removed by the surgical resection 9 days after the tumor implantation. Approximately 90% of C3H/He mice receiving such treatment died from tumor metastasis by about 30 days after the tumor resection. However, immunization of mice with MDP hapten-coupled X5563 tumor cells subsequent to the tumor resection resulted in an increased survival rate. Such protection from the tumor metastasis was appreciably stronger when compared to the protection obtained by immunization with MDP hapten-uncoupled tumor cells. The mice surviving in both models were also demonstrated to retain X5563 tumor-specific immunity. These results indicate that the presentation of MDP hapten-modified tumor cells to BCG-sensitized recipients results in potent tumor-specific immunity which contributes to the regression of the primary tumor or inhibition of metastatic tumor growth.This work was supported by a Grant-in-Aid for the Special Project Cancer Bioscience from the Ministry of Education, Science and Culture, Japan     

Maximal T cell IL-13 production requires monocyte or monokine participation

The T cell-secreted lymphokine interleukin 13 (IL-13) exerts pleiotropic effects on monocytes (Mphi) and B cells. Since accessory cells, like Mphi and B cells, also act in antigen-presenting and lymphokine augmentation of T cells, Mphi and B cells may be able to effect T cell IL-13 production. Purified T cells produced slightly less IL-13 than the lower T cell numbers contained in peripheral blood mononuclear cell population, further suggesting accessory cell augmentation. Addition of 10% B cells [either unstimulated or pokeweed mitogen (PWM)-stimulated] to autologous T cells only moderately augmented T cell IL-13 levels. PWM-stimulated B cell culture supernates had even less augmenting effect on T cell IL-13 levels and unstimulated B cell culture supernates did not augment T cell IL-13 production. In contrast to the moderately augmenting effect of B cells or their stimulated culture supernates, addition of 10% Mphi, either unstimulated or muramyl dipeptide (MDP)+IFN-gamma stimulated, to autologous T cells produced a highly significant increase in T cell IL-13 production. Mphi culture supernates were equally effective in augmenting T cell IL-13 levels, suggesting both that cell-to-cell contact is not critical for Mphi augmentation of T cell IL-13 levels, and that Mphi secreted factors are pivotal. CD64(+) Mphi (or their culture supernates), which are known as poor antigen-presenting cells, also effectively augmented T cell IL-13 production, further supporting the involvement of Mphi secreted factors. Finally, experiments with exogenous addition of recombinant monokines, as well as neutralization experiments with different cytokine antibodies, suggested IL-1beta as a primary cytokine involved in the augmentation of T cell IL-13 levels by accessory cells. However, these experiments also indicated other unidentified Mphi factors as playing a significant role in producing maximal T cell IL-13 production.     

Differences in the regulation of humoral responses between mice infected with Trypanosoma cruzi and mice administered T. cruzi-induced suppressor substance

In the present study, the effects of Trypanosoma cruzi and the T. cruzi-induced serum suppressor substance (SSS) on antibody responses were compared. Although infection with T. cruzi led to an alteration in T cell helper activity and a reduced specific B cell precursor frequency, SSS did not have a similar effect on either of these cell populations. The characteristics of the altered T cell helper activity was further investigated, and it was found that helper activity appeared earlier in infected mice than in normal or SSS-suppressed mice, and less antigen was required for optimal elicitation of T helper cells in infected mice. The potency of T cell helper activity also was shown to differ, and in the order T. cruzi-infected 6E normal 6E SSS-suppressed mice. It was found that spleen cells from T. cruzi-infected mice elaborated more potent specific helper factors than spleen cells from normal or SSS-suppressed mice, but did not produce a detectable nonspecific helper factor in vitro. Finally, the addition of B cells from low-dose primed, T. cruzi-infected mice to cultures of normal spleen cells resulted in subnormal responses to the priming antigen (sheep erythrocytes) but not to another unrelated antigen (trinitrophenyl-haptenated Brucella abortus), whereas similarly sensitized B cells from normal or SSS-suppressed mice caused no such effect.     

A requirement for nonspecific T cell factors in antibody responses to "T cell independent" antigens

Using murine splenic B cell preparations depleted of macrophages and rigorously depleted of T cells, we studied the role of nonspecific helper factors in in vitro antibody responses to T cell-independent (TI) type 1 and type 2 antigens. TNP-lipopolysaccharide, TNP-Brucella abortus, and DNP-liposomes containing lipid A were chosen as examples of TI type 1 antigens. DNP-Ficoll and DNP-liposomes without lipid A were chosen as TI type 2 antigens. Only the type 1 antigens were able to elicit significant, albeit very weak, responses without added helper factors. Both type 1 and 2 antigens required factors present in supernatants from concanavalin A-stimulated spleen cells (Con A SN) to stimulate optimum antibody responses. Interleukin 2- (IL 2) containing supernatant from the T cell hybridoma FS6-14.13 supported suboptimal responses to varying degrees with each TI antigen, in contrast to its lack of effect on responses to sheep red blood cells in the absence of additional factors. This activity of the FS6-14.13 supernatant was removed by absorption with the IL 2-dependent T cell line HT-2, suggesting that IL 2 was the active component. Another factor, IL-X, which is distinct from both IL 1 and IL 2 and is also found in Con A SN, was required in addition to IL 2 to achieve optimal responses with both types of TI antigens. These results clearly establish a role for factors derived from T cells in the activation of B cells by both type 1 and type 2 TI antigens.     

T cell exhaustion and Interleukin 2 downregulation

T cells reactive to tumor antigens and viral antigens lose their reactivity when exposed to the antigen-rich environment of a larger tumor bed or viral load. Such non-responsive T cells are termed exhausted. T cell exhaustion affects both CD8+ and CD4+ T cells. T cell exhaustion is attributed to the functional impairment of T cells to produce cytokines, of which the most important may be Interleukin 2 (IL2). IL2 performs functions critical for the elimination of cancer cells and virus infected cells. In one such function, IL2 promotes CD8+ T cell and natural killer (NK) cell cytolytic activities. Other functions include regulating naïve T cell differentiation into Th1 and Th2 subsets upon exposure to antigens. Thus, the signaling pathways contributing to T cell exhaustion could be linked to the signaling pathways contributing to IL2 loss. This review will discuss the process of T cell exhaustion and the signaling pathways that could be contributing to T cell exhaustion.     

Effects of interleukin 4 on neonatal B lymphocyte tolerance

Perturbation of antigen receptors on mouse neonatal B cells by rabbit antimouse IgM antibody was shown to inhibit cell proliferation in response to the B cell mitogen lipopolysaccharide. When these antibody-inactivated cells were challenged with lipopolysaccharide in the presence of the helper T cell product interleukin 4, a strong proliferative response was observed. Interleukin 4 alone did not cause proliferation of the antibody-treated B cells. Pretreatment with interleukin 4 did not prevent neonatal B cell inactivation by the antibody. Our results show that neonatal B cells inactivated directly through their antigen receptors can be reactivated by the combined signals of interleukin 4 and lipopolysaccharide.     

Generation of alloreactive cytotoxic T lymphocytes: production of T cell and macrophage helper factors in addition to IL 1 and IL 2 by peritoneal cells from mice immunized to Listeria monocytogenes

We investigate the production and biological activity of soluble helper factors produced by peritoneal T cells and macrophage derived from mice primed in vivo with Listeria monocytogenes. Supernatant fluids from co-cultures of these immune T cells and activated macrophages contained Interleukin 1 (IL 1) and Interleukin 2 (IL 2), and had the ability to assist the generation of cytotoxic T lymphocytes (CTL) from a population of nylon wool nonadherent spleen cells sensitized to allogeneic heat-treated thymocytes. The ability to assist CTL development involved T cell and macrophage factors in addition to IL 1 and IL 2. Immune T cells cultured alone produced a factor, devoid of significant IL 2 activity, that assisted CTL development only if adherent cells were present in the responding population. Activated macrophage produced a 38,000 dalton component, distinct from IL 1 on the basis of m.w., that assisted the development of CTL from nylon wool nonadherent splenic cells. Supernatants fluids from co-cultures of immune T cells and allogeneic, nonactivated macrophage contained a CTL helper factor but did not contain IL 1 or IL 2 activities. In contrast, supernatant fluids from co-cultures of immune T cells and syngeneic, nonactivated macrophage contained all 3 activities. This suggests a genetic restriction for the production of IL 1 and IL 2 that does not restrict the production of a CTL helper factor. These results demonstrate that T cell- and macrophage-derived helper factors distinct from IL 1 and IL 2 participate in the development of CTL.     

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.     

Soluble factor-independent stimulation of human B cell response by mouse thymoma cells. Cyclosporine A-resistant and -sensitive cell contact signals

In a Th cell-dependent antibody response, the Th act on B cells partly via a helper activity that is cell contact-dependent and cyclosporine A (CsA)-resistant. This activity seems to be required to induce responsiveness of the B cells toward T cell-derived soluble factors (cytokines) generally believed to be essential for B cell proliferation as well as for Ig secretion. In our study, we have investigated a system in which human B cells are stimulated by mutant EL-4 thymoma cells of mouse origin. It was found that human B cells proliferate and secrete Ig (either 1) in the presence of EL-4 cells plus human T cell supernatant (T-SUP), or 2) in the presence of EL-4 cells alone which have been induced with PMA or IL-1. The first situation conformed to the known synergy between CsA-resistant Th signal and cytokines. However, the B response due to PMA-induced EL-4 cells was special. The PMA-inducible helper activity was CsA-sensitive at the same CsA concentration that inhibited IL-2 secretion of EL-4 cells, but the murine factors in EL-4 supernatant had no effect on human B cells; the helper effect did not occur across a semipermeable membrane. Any contribution of soluble factors from contaminating human T cells was ruled out by adding single human B cells by flow microfluorimetry to cultures with EL-4 cells and PMA. Such B cells generated clonal IgM, IgG, and/or IgA responses. CsA, thus, interfered with some cell contact-mediated signal. However, CsA did not reduce the amount of LFA-1 molecules on EL-4 cells. In conclusion, EL-4 cells can induce proliferation and differentiation of human B cells in a soluble factor-independent manner, via CsA-resistant and CsA-sensitive helper activities. This may represent an alternative pathway of B cell activation.     

A human CD4- T cell leukemia subclone with contact-dependent helper function.

Helper T lymphocytes provide a contact dependent signal to resting B cells that is required for optimal differentiation into Ig-secreting cells. The surface structure(s) on T cells that mediate helper function have not been identified but are known to be induced by T cell activation. A CD4- subclone of the Jurkat leukemic T cell line (D1.1) was isolated and found to be distinct from CD4+ Jurkat clones and a variety of other T and non-T cell leukemic lines in that coculture of D1.1 with resting B cells induced B cells to specifically express surface CD23 molecules, a marker of B cell activation. Furthermore, Jurkat D1.1 induced B cell proliferation and terminal B cell differentiation into IgG-secreting cells in the presence of T cell-dependent B cell mitogens. Similar to the helper effector function of activated T cells, the effects of Jurkat D1.1 were neither Ag nor MHC restricted. Paraformaldehyde fixed Jurkat D1.1 cells remained competent to activate B cells while D1.1 supernatants and diffusible factors were inactive. The effect of Jurkat D1.1 on B cell activation was distinct from that of rIL-4 and was not inhibited by antibodies to IL-4. Together these observations suggested that surface structures on D1.1 and not secreted factors, mediated contact-dependent helper effector function.     

A human helper T cell clone secreting both killer helper factor(s) and T cell-replacing factor(s)

A human helper T cell clone (d4), which showed its helper effect on the differentiation of both T and B cells, was established by MLC reaction of normal T cells against a B lymphoblastoid cell line (CESS) followed by cloning in the presence of IL2 and x-irradiated CESS and autologous non-T cells. d4 cells helped the induction of cytotoxic T cells against UV-treated CESS cells. Antigen-stimulated d4 cells secreted helper factor(s) involved in the induction of cytotoxic T cells (killer helper factor(s), KHF), and KHF activity could be separated into two fractions, one with the m.w. of 15,000 to 20,000 and the other with the m.w. of 45,000 to 50,000. The factor with 15,000 to 20,000 m.w. showed IL 2 activity; the other factor showed gamma-interferon activity without IL 2 activity, suggesting that both IL 2 and gamma-interferon exerted KHF activity. d4 cells or their culture supernatant showed helper activity in the induction of IgG in a B cell line (CESS). The helper activity of the supernatant (TRF) was absorbed with CESS cells but not with IL 2-dependent CTLL, whereas KHF activity was absorbed with IL 2-dependent CTLL but not with CESS cells. The results showed that TRF and KHF were distinct molecules and a single helper T cell clone could secrete helper factors for both B and T cells.     

LPS and specific T cell responses: interleukin 1 (IL 1)-independent amplification of antigen-specific T helper (TH) cell proliferation

Lipopolysaccharide (LPS) fraction of endotoxin induces a significant potentiation of the antigen-specific proliferative response of T helper (TH) cell lines. This effect was obtained with LPS from different bacterial sources and reproduced with the lipid A moiety of endotoxin. Purified adherent spleen cells used as antigen-presenting cells (APC) support this LPS-enhanced TH cell proliferation. In addition, the effect of endotoxin on specific TH cell responses was found to be absolutely dependent on the interaction between TH lymphocytes and APC through antigen-specific recognition. Thus, it was not observed in the absence of specific antigen or when monoclonal antibodies against class II MHC products or against L3T4 antigens were used to inhibit the T cell-APC interaction. Similarly, it was found that APC from the B6.CH-2bm12 mutant do not support the LPS-mediated enhancing effect. Furthermore, interleukin 1 (IL 1) appears not to be involved in LPS-mediated enhancement, and this effect is not reproduced by muramyl dipeptide (MDP)-mediated activation of APC.     

In vitro immune response of human peripheral lymphocytes. I. The mechanism(s) involved in T cell helper functions in the pokeweed mitogen-induced differentiation and proliferation of B cells.

Human peripheral lymphocytes (PBL) upon stimulation with PWM proliferate and differentiate to IgM- and IgG-producing cells. The PWM-induced Ig production in B cells was dependent on T cells, and cell-free supernatant (CFS) obtained from PWM-stimulated PBL or T cell-rich fraction replaced T cell helper functions. The active substance(s) in CFS were most likely derived from T cells. The kinetic studies showed that the proliferation of B cells took place in advance of the final differentiation to Ig-producing cells and that T cells or T cell product(s) had to exist at the initiation of cultures in order to give the maximum helper effect. However, the final differentiation of B cells to Ig-producing cells was not dependent on T cells. The helper effect of T cells or T cell product(s) on PWM-induced proliferation and differentiation of B cells was exerted across the MHC barrier. This may make it possible to apply this experimental system to the assessment of quantitative and/or qualitative changes in human helper T cells in several immunologic diseases.     

Selective protection of murine thymic helper T cells from glucocorticosteroid inhibition by macrophage-derived mediators

We investigated the in vitro effects of dexamethasone (DEX) on the functional capacities of virgin murine T cells cultured in the absence and presence of adjuvant-stimulated macrophages or factors derived from them. Immunologically mature thymocytes, isolated on the basis of their inability to bind peanut agglutinin (PNA^? thymocytes), were used as virgin T cells. Treatment of PNA^? thymocytes with DEX for 24 hr in vitro eliminated their subsequent capacity to function as helper cells for primary humoral responses, to proliferate when stimulated by plant mitogens or allogeneic cells, or to generate T-cell-mediated cytotoxic responses. However, when PNA^? thymocytes were pretreated with DEX in combination with either adjuvant-activated macrophages or their culture supernatants, which contained Interleukin 1, the capacity of the T cells to subsequently express helper activity was preserved. The macrophage products, however, did not prevent DEX from inhibiting the capacities of PNA^? thymocytes to proliferate in response to plant mitogens or alloantigens or to generate cytotoxic effector cells; thus, protection was selective. The data indicate that, prior to activation, helper T cells are distinguished by their capacity to become steroid resistant in response to macrophage products. Although T-cell proliferative and cytotoxic responses have been reported to be protected from DEX inhibition by Interleukin 2, our results suggest that macrophages prevent steroid effects on virgin helper T cells by Interleukin-1-dependent mechanisms that do not involve Interleukin 2. While we have not delineated the biochemical pathways of protection, we show that the acquisition of DEX resistance by helper T cells cannot be attributed to the polyclonal induction of helper activity by macrophage factors.     

Enhancement of B-cell stimulation by muramyl dipeptide through a mechanism not involving interleukin 1 or increased Ca2+ mobilization or protein kinase C activation

Muramyl dipeptide (MDP) enhanced mitogenic stimulation of mouse lymphocytes by polyclonal B cell activators (peptidoglycan, lipopolysaccharide, Staphylococcus aureus Cowan I cells, and pokeweed mitogen), but not by T-cell mitogens (phytohemagglutinin and concanavalin A). Only adjuvant-active MDP analogs were effective, whereas adjuvant-inactive MDP analogs, muramic acid, peptidoglycan pentapeptide, and low Mr digests of peptidoglycan were not. The half-maximal enhancement was seen at 5-10 microM MDP and occurred at both optimal and suboptimal concentrations of B cell mitogens. The enhancing effect of MDP was exerted on the B cells, since it was T cell- and macrophage-independent and was not mediated by IL-1. MDP was effective during the first 12 hrs of culture, and most strongly enhanced the mitogen-induced DNA synthesis, although significant enhancement of RNA synthesis and B cell differentiation into antibody-secreting cells was also observed. The enhancement of mitogenic response was not due to changed requirements for extracellular or intracellular Ca2+ or to increased activation of protein kinase C. These results demonstrate a novel immunoenhancing effect of MDP that should be useful in the studies on the mechanism of B cell activation.     

Induction of proliferation and Ig production in human B leukemic cells by anti-immunoglobulins and T cell factors

The proliferation and differentiation of human leukemic B cells (B-CLL cells) with anti-Ig and T cell-derived helper factors are described. Stimulation of B-CLL cells with anti-Ig and T helper factors could induce proliferation as well as differentiation into IgM- and IgG-producing cells. Neither anti-Ig nor T helper factors alone could induce any proliferation and/or differentiation of B-CLL cells. Not only whole molecules of anti-Ig but also F(ab')2 fragments could induce proliferation and differentiation of B-CLL cells in the presence of T helper factors, but monovalent Fab' fragments were not effective. Induction of both IgM and IgG with the same idiotype was confirmed by immunofluorescent and SDS-PAGE analysis. By employing an IL 2-dependent cytotoxic T cell line and a TRF-responsive B cell line, T cell factors were separated into a fraction with IL2 activity but no TRF activity and a fraction with TRF activity but no IL 2 activity by chromatofocusing. Anti-Ig and IL 2 fraction could induce proliferation of B-CLL cells, but TRF fraction was not effective for the induction of proliferation in anti-IG-stimulated cells. For IgM and IgG production, anti-Ig and both IL 2 and TRF fractions were required. Depletion of IL 2 fraction in the first 2 days' culture inhibited Ig production, whereas the absence of TRF fraction in the first 2 days did not show any inhibitory effect on Ig production.     

Suppressive effect of human natural killer cells on pokeweed mitogen-induced B cell differentiation

The suppressive effect of human natural killer (NK) cells on B cell differentiation induced by pokeweed mitogen (PWM) was investigated. By using Percoll discontinuous density gradient centrifugation, peripheral blood nonphagocytic and nonadherent mononuclear cells were divided into low and high density fractions for which NK cells (Large granular lymphocytes, LGL) and T cells were enriched, respectively. These fractionated mononuclear cells were co-cultured with purified autologous B cells in the presence of PWM, and were examined for their helper and suppressor activities on differentiation of B cells to immunoglobulin-(IgM and IgG) producing cells by a highly sensitive reversed hemolytic plaque assay. The T cell-enriched high density fractions provided help for B cell differentiation to levels higher than that of unfractionated mononuclear cells. On the other hand, the NK-enriched low density fractions did not show helper activity, and when added to the culture of B cells plus helper T cells, they markedly suppressed B cell differentiation. This suppressive activity, as well as the NK cytotoxicity of the NK-enriched fractions, was abrogated by treatment of the cells with monoclonal antibody against human NK cells (HNK-1), but not against T cells (OKT3) in the presence of complement. NK cells also suppressed PWM-driven B cell differentiation in the presence of T4+ (helper/inducer T) but not T8+ (cytotoxic/suppressor T) cells; however, they showed no inhibition of soluble factor-induced B cell differentiation assayed in the absence of helper T cells. It is thus concluded that human peripheral blood NK cells exhibit an ability to suppress PWM-driven B cell differentiation, possibly by acting through the effect on helper T cells but not directly on B cells.