Morphologic and phenotypic features of the subpopulation of Leu-2+ cells that suppresses B cell differentiation

The Leu-2 antigen is expressed on a subpopulation of human T cells that perform suppressor and cytotoxic functions. In addition, this antigen is also present on a portion of cells with morphologic characteristics of granular lymphocytes. Although both Leu-2+ cells and granular lymphocytes have been shown to suppress B cell differentiation, the interrelationship of these two suppressor populations has not previously been fully characterized. We recently produced a monoclonal antibody, termed D12 (anti-Leu-15), which reacts with a variety of cell types, including a subpopulation of Leu-2+ cells. Previous studies have indicated that the Leu-2+ cells that suppress T cell proliferative responses express the Leu-2+15+ phenotype, whereas the precursor and effector cytotoxic T cells that recognize class I major histocompatibility antigens are Leu-2+15- lymphocytes. For this report, we used the anti-Leu-2 and anti-Leu-15 monoclonal antibodies and fluorescence-activated cell sorter techniques to characterize the E+ cells that suppress PWM-induced B cell differentiation. These studies indicate that the vast majority of Leu-2+ cells that suppress this T cell-dependent B cell response have the Leu-2+15+ phenotype. Furthermore, when the morphologic and cytochemical characteristics of these Leu-2+15+ cells were studied, virtually all of these cells were granular lymphocytes. Most of the Leu-2+15+ suppressor cells co-expressed the HNK-1 (Leu-7) antigen, which is detected only on granular lymphocytes. In contrast, virtually none of the Leu-2+15+ granular lymphocytes expressed Fc receptors for IgG molecules. These data indicate that the Leu-2+ cells that suppress PWM-induced B cell differentiation are Leu-2+15+ (and predominantly Leu-7+) granular lymphocytes that do not express Fc receptors. The implications of these observations concerning the relationship of human Leu-2+ suppressor cells to murine Ly-2+ cells and the lineage of granular lymphocytes are discussed.     

Functional characterization of T lymphocytes grown in semisolid agar

T lymphocyte colony forming cells (TL-CFC) grown in agar in the presence of PHA were assayed for their capacity to induce or suppress polyclonal PWM dependent B lymphocyte differentiation into plasma cells. This was measured by identifying cells containing intracytoplasmatic immunoglobulins by direct immunofluorescence. To validate the helper and suppressor system used in this paper, the inductive capacity of unfractionated T lymphocytes and their subpopulations bearing Fc-receptors for IgM (TM) and for IgG (TG) was measured. The unfractionated T cells and the TM fraction showed helper activity, whereas the TG cells expressed suppressor activity. The TL-CFC grown in agar in the presence of PHA manifested helper activity at low cell concentration. However, increasing the TL-CFC concentration finally caused suppression of B cell differentiation. The suppressor effect could be abolished by prior irradiation of the TL-CFC before seeding them in agar. These results indicate that T cells grown in agar have the functional capacity of T helper and T suppressor cells to induce and suppress polyclonal PWM dependent B lymphocyte differentiation into plasma cells.     

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.     

Human lymphocyte differentiation antigens HB-10 and HB-11. II. Differential production of B cell growth and differentiation factors by distinct helper T cell subpopulations

Two monoclonal antibodies (HB-10 and HB-11), which react with human T, B, and NK cells, identify approximately 50% of the Leu-3+ T helper (TH) cells in adult blood. In the present studies, the functional capabilities of the HB-11+ and HB-11-TH cell subpopulations were examined after purification by fluorescence-activated cell sorting. Both subpopulations proliferated in response to PHA, Con A, PWM, and OKT-3 antibodies. The HB-11+ TH cells gave a minimal proliferative response to soluble tetanus toxoid antigen, whereas HB-11-TH cells responded well. After mitogen activation, both HB-11+ and HB-11-TH cells and to produce soluble factors which induce large B cells to proliferate. However, PWM-stimulated HB-11+TH cells were incapable of inducing B cells to differentiate into antibody-secreting plasma cells, whereas HB-11-TH cells were efficient in this regard. The results suggest that the HB-11 antigen is expressed on a subpopulation of virgin TH cells that can produce B cell growth factors but are deficient in the ability to produce B cell differentiation factors.     

Human B cell differentiation. II. Suppression by T cells of T-dependent and T-independent plasma cell maturation.

In vitro human plasma cell generation induced by both T-dependent (PWM) and T-independent (NWSM) mitogens was found to be suppressed by peripheral blood lymphocytes preincubated with human aggregated IgG. T cells, but not B lymphocytes, were able to mediate the suppressive activity; since aggregated (Fab)'2 fragments were found unable to generate suppressor cells, it was concluded that the suppressor cell was a T lymphocyte bearing Fcgamma receptors. These cells appeared to be largely radiosensitive. In most cases the proliferative responses remained unchanged. Since NWSM-induced activation is not dependent on the presence of T cells, these results show that, at least in this case, T cells exert their suppressor function directly on B lymphocytes. Whether PWM-induced B cell differentiation is suppressed by the same mechanism or/and by inactivation of T helper lymphocytes remains under investigation.     

Immunoregulatory T cell circuits in man. Identification of a distinct T cell subpopulation of the helper/inducer lineage that amplifies the development of alloantigen-specific suppressor T cells

Regulation of the immune response in man is dependent on interactions between cells of helper/inducer (Leu-3+/T4+) lineage and cells of suppressor/cytotoxic (Leu-2+/T8+) lineage. By using the mixed leukocyte reaction (MLR) as a model system, we have shown previously that alloantigen-primed Leu-3+ cells induce autologous Leu-2+ cells to differentiate into suppressor T cells that specifically inhibit the response of fresh T cells to the original allogeneic stimulator cells. The current study was undertaken to analyze the roles in this suppressor circuit of subpopulations of Leu-3+ cells distinguished from one another on the basis of their binding or lack of binding to monoclonal anti-Leu-8 antibody. Although both Leu-3+,8- and Leu-3+,8+ T cells proliferated in allogeneic MLR, alloactivated Leu-3+,8+ cells alone induced proliferation and differentiation of Leu-2+ suppressor cells. Leu-3+,8+ cells also induced Leu-3+,8- cells to proliferate, and following their activation in this manner, such autoactivated Leu-3+,8- cells augmented the differentiation of Leu-2+ suppressor cells, but only in the presence of alloactivated Leu-3+,8+ cells. Furthermore, this effect, like the suppressor effect, was specific for the inducer cells, and thus indirectly for the HLA-DR antigens of the original allogeneic stimulator cells as well. These results indicate that alloantigen-primed Leu-3+,8+ cells not only activate specific Leu-2+ suppressor cells but also activate specific Leu-3+,8- suppressor-amplifier cells, and in combination, these cells exert potent feedback inhibition of MLR.     

Characterization of a phenotypically distinct subpopulation of Leu-2+ cells that suppresses T cell proliferative responses

Two new monoclonal antibodies (termed 2D2 and D12) have been used to identify and to analyze phenotypically distinct subpopulations of human T cells. The 2D2 antibody recognized an antigenic determinant closely related, if not identical, to that reactive with the anti-Leu-2 monoclonal antibody. The D12 antibody reacted with a variety of cell types, which included a subpopulation of Leu-2+ (2D2+) T cells. These antibodies were used to isolate four phenotypically distinct T cell populations by sequential cell sorter techniques. Functional analyses demonstrated that the 2D2+D12+ subset was unique in its ability to suppress the antigen-induced proliferation of T cells. These cells also suppressed the proliferative responses of other T cell subsets stimulated with mitogens. Pretreatment of 2D2+D12+ T cells with mitomycin C before culture abrogated the suppressor cell activity of these cells. We propose that the cells within the Leu-2+ cytotoxic/suppressor T cell subpopulation that suppress T cell proliferation are phenotypically distinct and express the 2D2+D12+ membrane antigenic phenotype.     

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.     

Suppressor T cells activated by autologous B-cell derived lines inhibit blastogenic responses by peripheral lymphocytes to mitogens or autologous lymphoblastoid cell lines

EBV-transformed B-cell lines (LCL) suppressed peripheral lymphocyte responses to mitogens (PHA, PWM, and protein A). Cell separation experiments have shown that LCL cells activate autologous radiosensitive suppressor T cells that inhibit T-cell responses to mitogens (PHA and Con A) and to the autologous lymphoblastoid cell line itself. The significance of this autologous response and the way it may reflect on the effect of the suppressor T cells on the regulation of potential autoimmune responses is considered in relation to the in vivo phenomena observed in the course of acute mononucleosis.     

Immunophenotype and sister chromatid differentiation: a combined methodology for analyzing cell proliferation in unfractionated lymphocyte cultures

Combination of the MAC (morphology, antibody, chromosomes) and harlequin staining procedures offers a method for direct analysis of cell kinetics in cultures of unfractionated hematopoietic cells. In the present study unfractionated human mononuclear leukocyte cultures were stimulated with PHA or PWM mitogens and exposed to bromodeoxyuridine for various periods. For MAC, cytospin preparations were made and cells were classified with monoclonal B and T antibodies by the immunoperoxidase technique. After differentiation of the different lymphocyte subsets, the cells were stained by a fluorescence-plus-Giemsa method to distinguish sister chromatids and to determine the proportions of first, second, third, or subsequent mitoses among the previously identified subsets. The results showed (1) that the relative proportions of mitotic T and B cells are the same regardless of the mitogen used; (2) that T and B lymphocytes proliferate faster in cultures stimulated by PWM than in those stimulated by PHA; and (3) that T cells enter mitosis earlier than B cells when PHA or PWM are used as mitogens.     

A human alloreactive inducer T cell clone that selectively activates antigen-specific suppressor T cells

We showed previously that T cells with the phenotype Leu-3+,8+ are required for the induction of antigen-specific Leu-2+ suppressor cells. Furthermore, when mixed lymphocyte reactions are carried out in the presence of 1 microgram/ml cyclosporin A (CsA), such cultures lead preferentially to the activation of alloantigen-specific suppressor-inducer Leu-3+,8+ cells. In an attempt to generate a clone of T cells with such specific suppressor-inducer properties, we activated Leu-3+,8+ T cells with allogeneic (HLA-DR4+) lymphocytes in the presence of CsA. Clone SP-21, derived by propagating such activated T cells with conditioned medium containing IL 2, is a noncytotoxic, nonsuppressor clone that specifically proliferates to allogeneic cells bearing HLA-DR4 antigen. When cultured with fresh autologous Leu-2+ cells in the absence of HLA-DR4+ cells, clone SP-21 selectively activates Leu-2+ suppressor cells, which inhibit the response of fresh Leu-3+ cells to DR4+ stimulator cells. On the other hand, clone SP-21 fails to induce cytolytic T cells or to help B cell differentiation. These results demonstrate that a T cell clone with a remarkably narrow functional repertoire nonetheless contains and transmits all of the signals necessary for the activation of antigen-specific suppressor cells.     

IgG subclass expression by human B lymphocytes and plasma cells: B lymphocytes precommitted to IgG subclass can be preferentially induced by polyclonal mitogens with T cell help

The human IgG subclasses expressed by circulating B lymphocytes, tissue plasma cells, and plasma cells generated from B cell precursors in response to the polyclonal mitogens LPS and PWM were examined by immunofluorescence using subclass-specific monoclonal antibodies. The subclass distribution observed for circulating B lymphocytes was IgG2 (48%) greater than IgG1 (40%) greater than IgG3 (8%) greater than IgG4 (1%), while the distribution among IgG plasma cells in bone marrow, blood, spleen, and tonsils was IgG1 (64%) greater than IgG2 (26%) greater than IgG3 (8%) greater than IgG4 (1%). Multiple IgG isotypes were not observed on B cells or in plasma cells. Although IgG plasma cell responses to both LPS and PWM were T cell dependent, the distributions of IgG subclasses elicited were strikingly different. In control and LPS-stimulated cultures of blood mononuclear cells, the induced plasma cells expressed the IgG subclass distribution: IgG2 greater than 80%, IgG1 less than 20%, IgG3 less than 1%, IgG4 less than 1%. In PWM-stimulated cultures, the subclass distribution, IgG1 approximately 65%, IgG2 approximately 25%, IgG3 approximately 7%, IgG4 approximately 1%, was in perfect concordance with the in vivo subclass distribution of IgG plasma cells. Selective inhibition of suppressor T cell activity by x-irradiation and mitomycin C treatment did not alter the IgG subclass distribution pattern induced by LPS and PWM. Monoclonal antibodies were used to deplete selectively the B cell precursors bearing IgG1, IgG2, or IgG3 before PWM stimulation of blood mononuclear cells. In each instance, a reduction was observed only in the subpopulation of plasma cells producing the homologous IgG subclass. The results indicate that T cells can preferentially influence the terminal differentiation of B cells that are precommitted to different IgG subclasses.     

Induction of CD4 suppressor T cells with anti-Leu-8 antibody

To characterize the conditions under which CD4 T cells suppress polyclonal immunoglobulin synthesis, we investigated the capacity of CD4 T cells that coexpress the surface antigen recognized by the monoclonal antibody anti-Leu-8 to mediate suppression. In an in vitro system devoid of CD8 T cells, CD4, Leu-8+ T cells suppressed pokeweed mitogen-induced immunoglobulin synthesis. Similarly, suppressor function was induced in unfractionated CD4 T cell populations after incubation with anti-Leu-8 antibody under cross-linking conditions. This induction of suppressor function by anti-Leu-8 antibody was not due to expansion of the CD4, Leu-8+ T cell population because CD4 T cells did not proliferate in response to anti-Leu-8 antibody. However, CD4, Leu-8+ T cell-mediated suppression was radiosensitive. Finally, CD4, Leu-8+ T cells do not inhibit immunoglobulin synthesis when T cell lymphokines were used in place of helper CD4 T cells (CD4, Leu-8- T cells), suggesting that CD4 T cell-mediated suppression occurs at the T cell level. We conclude that CD4 T cells can be induced to suppress immunoglobulin synthesis by modulation of the membrane antigen recognized by anti-Leu-8 antibody.     

An autoreactive T cell clone that can be activated to provide both helper and suppressor function

To understand further the biologic significance of the autologous mixed lymphocyte reaction, we determined the functional properties of autoreactive T cell lines and clones. Initially, we found that cells in an uncloned autoreactive Leu-3+ T cell line helped immunoglobulin production when added to cultures containing fresh T and non-T cells in the absence of pokeweed mitogen (PWM) but suppressed immunoglobulin production in the same cultures in the presence of PWM. To explain this phenomenon, we studied the immunoregulatory potential of an autoreactive T cell clone termed MTC-4. This clone bore the phenotype Leu-3+, 2-, 8-, 11-, DR+ and underwent proliferation when co-cultured with autologous, but not allogeneic non-T cells. Of interest, the immunoregulatory potential of the MTC-4 cells varied according to how the cells were activated. When MTC-4 cells were cultured with autologous non-T cells in the absence of antigen or mitogen (unactivated non-T cells), polyclonal immunoglobulin production (detected by reverse PFC assay) was observed. This helper activity was MHC-restricted in that it was elicited only by autologous non-T cells or MHC-matched allogeneic non-T cells; however, once activated by autologous non-T cells, it could also help allogeneic non-T cells. In contrast, when MTC-4 cells were cultured with autologous non-T cells in the presence of PWM (activated non-T cells), immunoglobulin production was greatly suppressed. This suppression was also observed when MTC-4 cells were added to cultures containing exogenous T cell help (such as that provided by autologous fresh T cells) and was not due to a direct effect of PWM on the T cell clone, because preincubation of MTC-4 cells with PWM before culture with non-T cells did not result in suppression. On the basis of these data, we conclude that autoreactive T cells can have dual immunoregulatory function that is manifest, at least in part, at the single cell level. Moreover, these regulatory functions are differentially elicited depending on the state of activation of the stimulating autologous non-T cells: when stimulated by MHC antigens present on unactivated B cells, they provide helper activity; and when stimulated by MHC antigens present on activated B cells, they act as suppressor cells. Autoreactive T cells with dual regulatory potential appear to make up a substantial proportion of all autoreactive T cells and are cells that are uniquely adapted to maintain immunologic homeostasis.     

Soluble antigen-primed inducer T cells activate antigen-specific suppressor T cells in the absence of antigen-pulsed accessory cells: phenotypic definition of suppressor-inducer and suppressor-effector cells

This study was undertaken to characterize interactions among human T cell subpopulations involved in the generation of suppressor T cells specific for a soluble antigen. Purified PPD-primed Leu-3+ cells, when co-cultured for 7 days with fresh autologous Leu-2+ cells, induced differentiation of Leu-2+ but not Leu-3+ cells into specific suppressor T cells, which subsequently inhibited the proliferative response of fresh Leu-3+ cells to PPD but not to tetanus toxoid or allogeneic non-T cells. The PPD-specific suppressor effect of activated Leu-2+ cells was not due to altered kinetics of the PPD response and also extended to the secondary response of PPD-primed Leu-3+ cells. Furthermore, only those Leu-2+ cells that lacked the 9.3 marker, an antigen present on the majority of T cells including the precursors of cytotoxic T cells, differentiated into suppressor T cells. To analyze the inducer population, fresh Leu-3+ cells were separated into Leu-3+,8- and Leu-3+,8+ subpopulations with anti-Leu-8 monoclonal antibody, activated with PPD, and then were examined for inducer function. Although both Leu-3+,8- and Leu-3+,8+ cells proliferated in response to PPD and upon activation expressed comparable amounts of HLA-DR (Ia) antigens, the Leu-3+,8+ subpopulation alone induced Leu-2+ cells to become suppressor-effectors in the absence of PPD-pulsed autologous non-T cells. Once activated, however, Leu-2+ suppressor cells inhibited the PPD response of both Leu-3+,8- and Leu-3+,8+ cells. These results indicate that antigen-primed Leu-3+,8+ inducer cells can directly activate Leu-2+, 9.3- precursors of antigen-specific suppressor T cells in the absence of antigen-pulsed autologous non-T cells.     

Generation and characterization of continuous lines of CD8+ suppressor T lymphocytes

The ability to grow normal T lymphocytes in long term culture has advanced our understanding of T cell biology. The growth of CD4+ cell lines allowed a further evaluation and appreciation of functional subtypes within this group. Cytotoxic CD8+ T cells have been characterized as well. The routine and continuous culture of Ag-nonspecific CD8+ Ts cells has been difficult to achieve. We have found that CD8+ T cells that suppress T cell proliferation and lack cytotoxic activity against T cells can be routinely obtained from PWM or PHA-stimulated PBMC. Continuous culture of T cell blasts from PWM or PHA-stimulated PBMC resulted in the growth of CD4+ and CD8+ T cells. These lines developed suppressor cell activity within 7 days after stimulation with PWM and 3 to 4 wk after stimulation with PHA. Concomitant with the development of suppressor activity was the loss of CD4+ T cells resulting in homogeneous lines of CD8+ suppressor cells. These cell lines have been maintained in continuous culture for greater than 6 mo by addition of rIL-2 twice weekly and restimulation with feeder cells and PHA every 2 wk. Activity of these cell lines was relatively resistant to irradiation or treatment with mitomycin C. Both cell lines suppressed proliferation of autologous or heterologous CD4+ T cells stimulated with PWM, OKT3, or tetanus toxoid but failed to suppress proliferation of CD4+ T cells in a mixed lymphocyte reaction. CD4+ T cells stimulated with PWM produced equivalent amounts of IL-2 in the presence or absence of Ts cells but failed to express the IL-2R (TAC) on their surface in the presence of Ts cells. By contrast, CD4+ T cell lines or cytotoxic CD8+ T cell lines failed to suppress proliferation of CD4+ T cells. With these results we describe methods for the generation and continuous culture of Ag-nonspecific CD8+ Ts cells and define some of their properties. These cells lines should be helpful in further elucidating the functional and phenotypic repertoire of CD8+ Ts cells.     

Immune regulation by platelet-activating factor. I. Induction of suppressor cell activity in human monocytes and CD8+ T cells and of helper cell activity in CD4+ T cells

Platelet-activating factor (PAF) is a powerful mediator of inflammation. We have recently described a potential role for PAF in immune reactions, as it inhibits T cell proliferation and IL-2 production in response to mitogens. To further define the mechanism through which this inhibition is exerted, we used a coculture system in which PBML are preincubated with increasing concentrations of PAF for 24 h, followed by washing, treatment with mitomycin C and addition to fresh autologous PBML stimulated with PHA. In this context, a significant (40 to 60%) inhibition of proliferation was observed. In parallel, PAF-pre-treated cells induced a reduction (30 to 50%) of IL-2 production by PHA-stimulated lymphocytes. The PAF receptor antagonist BN52021 could partially block the PAF-induced suppressor cell activity, but also showed some suppressor cell-inducing properties of its own (20 to 30%). The expression of suppressor cell function during the co-culture could be partially abrogated by the inclusion of indomethacin, suggesting that cycloxygenase metabolites of arachidonic acid were involved in this phase of suppression. When PBML were fractionated into monocytes, lymphocytes, or T cell subsets before pre-incubation with PAF, indomethacin-sensitive suppressor cell function was generated in the monocyte population. Monocyte-depleted lymphocytes showed slight helper effect, whereas CD8+ T cells were induced to become indomethacin-resistant suppressor cells. CD4+ T cells, in contrast, were activated to exert very marked helper effect. When incubated with PAF for 24 h, monocyte-depleted lymphocytes showed a 30% decrease in CD4+ T cell numbers and a 50% increase in CD8+ T cell numbers. Our data suggest a novel immunoregulatory role for PAF and potentially important interactions of this lipid mediator of inflammation with lymphocyte and monocyte functions.     

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.     

A polyclonal assay for T helper function involving T-B cell contact mediated by L3T4 molecules

In the presence of pokeweed mitogen (PWM), T helper (TH) cell clones can induce differentiation of a very high proportion of normal B lymphocytes into plasmocytes. This property can be used to test TH cell function regardless of clonal specificity. We have investigated the role of L3T4 surface antigen in this new assay. Only TH cell clones expressing the L3T4 antigen have effector activity in this PWM-dependent helper assay; L3T4- TH cell variants are inactive. The involvement of L3T4 antigen is further shown by the ability of anti-L3T4 monoclonal antibody to inhibit the PWM-dependent polyclonal B cell differentiation induced by L3T4+ TH cell clones. This inhibition is not the consequence of arrested TH cell activation, nor of a lack of appropriate B cell stimulation by TH cell lymphokines. We show that PWM focuses TH cells on the B cell hybridoma LB15-13, and that anti-L3T4 mAb prevents the T-B cell clustering mediated by PWM. Thus, by a mechanism comparable with the one described for concanavalin A in the cytotoxicity assay, PWM acts by bridging TH cells and B cells; the T cell surface antigen L3T4 is involved in this process.     

Effect of T- and B-lymphocyte mitogens on interactions between lymphocytes and macrophages.

The mitogenic response of murine T cells ² to Con A, S-Con A and PHA was found to be macrophage-dependent. Optimal mitogenic responses were obtained when macrophage-depleted T-cell populations were reconstituted with 5% normal peritoneal macro-phages. Studies were carried out to investigate the effect of T- and B-cell mitogens on in vitro physical interactions between murine lymphocytes and macrophages. This was done by determining the number of T- or B cells binding to macrophages in the absence and in the presence of T- and B cell mitogens, and comparing the results of these experiments with the induction of lymphocyte proliferation. Con A increased the binding of T cells to macrophages when used in mitogenic doses (1–5 μg/ml). Dose response experiments showed that the same dose of Con A which produced maximal mitogenic stimulation also induced the greatest number of T cells to bind to macrophages. Nonmitogenic doses of Con A (20–50 μg/ml) did not enhance the binding of T cells, while identical doses of S-Con A both induced T cell mitogenesis and increased the number of T cells bound to macrophages. Similar results were obtained with PHA. None of the B-cell mitogens tested (LPS, EPO 127 and LAgl) increased the binding of either T or B cells to macrophages. PWM, which is mitogenic for both T and B cells, increased the binding of T cells to macrophages, but not that of B cells. In brief, the four T-cell mitogens tested (Con A, S-Con A, PHA, and PWM) induced specific physical interactions between T cells and macrophages, while none of the B-cell mitogens had any effect on the physical interactions between either B or T cells and macrophages when used in mitogenic doses.