Adherent cell requirement for PWM-stimulated factor suppression of natural killer cytotoxicity

Natural killer cytotoxicity is enhanced in a 5-day mixed-leukocyte culture (MLC). This augmentation of NK can be suppressed by factor released from pokeweed-mitogen (PWM)-activated peripheral blood cells. To maximize activity, the PWM-soluble factor must be present within the first 6 hr of the MLC, and is required to be in the culture for at least 4 hr. The affect of the PWM factor is not due to the destruction of either effector or stimulator cells. This factor does, however, require the presence of an adherent, non-T cell in the effector population. Directly incubating adherent cells with the PWM-induced soluble factor activates this population to mediate suppression. Thus the adherent cells are required for the PWM-induced suppression of NK cytotoxicity, indicating a possible regulatory mechanism for this cytotoxicity.     

Growth and characterization of T cell colonies from human thymus

A semisolid microculture system was used to study T cell colonies grown from human thymocytes. Colony growth was absolutely dependent upon media conditioned by peripheral blood leukocytes (PBL) in the presence of phytohemagglutinin. Plating efficiency was further enhanced by the addition of a non-T, adherent, radiation-resistant (7500 rad) PBL subpopulation, but was not enhanced by culture supernatants of these cells. The T colony precursor cell in the thymus occurred with a frequency of 8.0 X 10(-3) and had a surface receptor for the OKT3 monoclonal antibody. Thymocyte colony cells were functionally distinct from PBL and the major thymocyte population. The colony cells proliferated in response to T cell mitogens, but only in the presence of exogenous growth factors. The cells stimulated normal PBL in mixed leukocyte culture (MLC), but did not respond to alloantigens in MLC or in assays of spontaneous cytotoxicity. This culture system should prove helpful in the study of human thymocyte differentiation.     

In vitro effect of various mitogens on starfish (Asterias rubens) axial organ cells

The effects of various mitogens on axial organ (AO) cells of the sea star have been studied. Pokeweed mitogen (PWM) stimulates [³H]thymidine incorporation by the whole population of axial organ cells of the sea star. This effect occurs 24 hr after the addition of PWM and is maximal at 40 μg/ml. In contrast, no stimulation is observed when coelomocytes are treated with PWM under the same conditions. No stimulation of the whole AO cell population is observed in the presence of Con A or LPS. However, the AO cell population can be divided, on the basis of surface adherence properties, into two subpopulations, adherent and nonadherent. Con A stimulates the nonadherent cells, but not the adherent cells: The stimulating effect is maximal 24 hr after addition of Con A and at 0.2–0.5 μg/ml. In contrast, LPS stimulates the adherent but not the nonadherent cells and the stimulating effect is maximal at 24 hr and at 45 μg/ml.     

Passive transfer of experimental allergic encephalomyelitis in the Lewis rat with activated spleen cells: differential activation with mitogens

It has previously been shown that spleen cell transfer of clinical EAE requires donor cells to be cultured in vitro prior to transfer. Donor cells must be stimulated when cultured, and either Con A or the encephalitogen, guinea pig myelin basic protein (BP), satisfies this stimulation requirement. Following recovery from passive disease, recipients of these in vitro cultured cells will subsequently develop clinical symptoms of EAE sooner than controls when challenged with BP in complete Freund's adjuvant (BP-CFA). In the present study, three T-cell mitogens were evaluated as donor cell stimulants in the required in vitro culture period. Pokeweed mitogen (PWM) as well as Con A stimulated the donor cell population to the degree that clinical EAE could be transferred with 5 × 10⁶ cultured viable cells. Con A at culture levels below 0.25 μg/ml did not yield transfer active cells even though proliferation levels were similar to those found at concentrations of Con A that did yield transfer active cells. Phytohemagglutinin (PHA)-stimulated cultures did not transfer clinical disease even though the degree of lectin induced proliferation ([³H]thymidine uptake as well as recovered cells from culture) was equivalent to the PWM- or Con A-stimulated, transfer positive, cultures. Mixing experiments suggested that the inability of PHA or low doses of Con A to induce transfer active cells was not due to the induction of suppressor cells. Although cells cultured with PHA do not transfer clinical EAE, recipients of these cells as well as recipients of either PWM- or Con A-stimulated donor cells develop an early appearance of disease upon subsequent challenge with BP-CFA. This included cells incubated with a concentration of Con A (0.1 μg/ml) which did not induce cells capable of transferring clinical EAE. These results suggest that PHA and perhaps the low dose of Con A may stimulate the proliferation of the EAE effector cell precursor population without causing the additional differentiation of this precursor population into the effector cell population which is capable of transferring clinical disease. Alternatively, PHA may expand only the helper cell population while effective doses of Con A and PWM would expand both helper and effector cell populations.     

The assay, properties, and kinetics of human T cells forming clusters with sheep erythrocytes (CFC) in stimulated cultures.

This study describes a new method of detecting the in vitro stimulation of lymphocytes based on the appearance of cells having the property to cluster several layers of SRBC around themselves (CFC). The formation of multilayer rosettes is temperature dependent and requires trypan-blue-excluding, metabolically active blastoid cells. Non-separated cells as well as purified T cells stimulated with allogeneic leucocytes (MLR), specific antigens, or polyclonal mitogens (PWM, Con A) gave rise to CFC. Multilayer rosettes were not formed by separate B cells. In the MLR, CFC were detected 48 hr after the beginning of cultures and increased in number thereafter just like thymidine incorporation. The response to Con A and PWM was detected earlier and gave rise to two or three peaks, the first rise in the number of CFC coinciding with the peak of thymidine incorporation but the maximum increase occuring two or three days later. Treatment of blastoid cells with a serum specific for T cells, but not with an anti-immunoglobulin serum, abolished their ability to form ordinary or multilayer rosettes. When separated, however, on a nylon wool column, CFC were more adherent than the bulk of T cells. It is suggested that CFC form a subpopulation of T cells with distinct characteristics, allowing a direct assessment of membrane changes which take place when T lymphocytes are activated in vitro.     

Characteristics and mechanisms of action of the concanavalin A-activated suppressor cell in man.

Human peripheral blood lymphocytes treated for 24 to 48 hr with optimally mitogenic doses of concanavalin A suppressed the proliferative response of autologous T cells to mitogens and antigens. Con A-treated cells also suppressed the proliferative response and the immunoglobulin synthetic response of autologous B cells stimulated in vitro by T cell helper factor. The human Con A suppressor cell was sensitive to treatment with mitomycin C and to exposure to radiation doses exceeding 1000 rads. The Con A suppressor cell was shown to reside in the nylon wool-nonadherent, sheep red cell rosette-forming, histamine receptor-bearing population of lymphocytes and to lack surface DRW antigens. One mechanism of action of Con A suppressor cells was shown to be the inactivation of nonspecific T cell helper factor.     

A history of theories of acquired immunity

Alloimmune mouse spleen cells are capable of carrying out nonspecific cell-mediated cytolysis of syngeneic target cells when incubated in the presence of lectins such as Con A or PHA (lectin-dependent cell-mediated cytotoxicity). In the present study plant lectins from a variety of sources were examined for their ability to participate in alloimmune-LDCC. Reactivity was then compared to mitogenic activity and the ability to activate cytotoxic effector cells in vitro. Of the lectins tested only those reported to be T-cell mitogens were capable of participating in alloimmune-LDCC. Agglutinating but nonmitogenic lectins (e.g., WGA) or mitogens such as LPS or PWM failed to yield positive LDCC. Of the T-cell mitogens demonstrating positive reactivity in the alloimmune-LDCC assay, only a portion were able to generate cytolytic activity when incubated with normal spleen cells in vitro (Con A, GPA, lentil). Crude PHA, purified erythroagglutinin, or leukagglutinin failed to generate cytotoxic effector cells in this system even though these were mitogenic and demonstrated positive alloimmune-LDCC. The results suggest that T-cell mitogens interact with cytotoxic effector cells in a manner which specifically triggers cytolysis. The relationship of this interaction to other lymphocyte-lectin interactions is discussed.     

Insoluble immune complexes suppress mitogen-induced proliferation of human T lymphocytes bearing Fc gamma receptors.

Human peripheral blood lymphocytes were mixed with erythrocyte-antibody (EA) complexes and separated into EA-rosette forming cell (EA-RFC)-enriched and EA-RFC-depleted suspensions. Thymidine incorporation of EA-RFC-enriched population in the presence of T cell mitogens (PHA, Con A, PWM) was about half of that of EA-RFC-depleted or of unseparated cells. The dose-response curves and kinetics of proliferation were found to be very similar in the three populations. Proliferative response of EA-RFC-enriched lymphocytes was strictly T cell dependent, although non-T cells were later recruited to incorporate thymidine. The interaction of T lymphocytes bearing surface receptors for IgG (T_G) with insoluble complexes followed by a post-binding temperature sensitive event, resulted in the modulation of Fc receptors associated with an impaired proliferative response to PHA, Con A, and PWM, without significant change in metabolic cell activity as shown by cell viability, sponaneous leucine incorporation, or β₂ microglobulin release.     

Two phenotypically distinct suppressor T cell subpopulations inhibit the induction of B cell differentiation by phytohemagglutinin

Human B lymphocytes can be induced to differentiate into antibody-secreting plasma cells by Leu-3+ T lymphocytes stimulated with pokeweed mitogen (PWM), a polyclonal T cell activator. In contrast, other polyclonal T cell mitogens, such as phytohemagglutinin (PHA), also activate Leu-3+ T cells but are relatively ineffective inducers of B cell differentiation. We have performed a series of experiments to investigate the mechanism underlying this apparent paradox. When human B cells were cultured with unfractionated T cells and PWM or PHA, only PWM was able to induce plasma cell formation and immunoglobulin (Ig) secretion. However, when the T cells were treated with mitomycin C (MMC) before culture, both PWM and PHA were able to induce significant B cell differentiation. These data indicated that both mitogens were able to activate the helper T cells required for B lymphocyte differentiation and suggested that MMC-sensitive suppressor T cells were responsible for inhibiting the induction of antibody-secreting cells by MMC-untreated T cells stimulated with PHA. Phenotypic analysis of the T cells capable of suppressing PHA-induced B cell differentiation revealed that small numbers of either Leu-2+ or Leu-3+ T cells could profoundly suppress the B cell differentiation induced by PHA. In contrast, significant suppression of PWM-stimulated B cell differentiation was observed only with relatively large numbers of Leu-2+ T cells. These data confirm previous reports that OKT4+/Leu-3+ T cells can suppress human B cell differentiation and indicate that the difference in B cell differentiation induced by PWM and PHA with MMC-untreated T cells is largely a reflection of the relative potency of these mitogens to activate these phenotypically distinct suppressor T cell subpopulations.     

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

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

Selective responses of mouse T lymphocytes to different T mitogens and in mixed lymphocyte culture induced cytolysis reaction.

CBA spleen T lymphocytes were stimulated by the T mitogens concanavalin-A (Con-A), phytohemagglutinin (PHA), and leukoagglutinin (LA). On the 2nd to 3rd culture day the activated cells (blasts) were separated from the nonactivated cells (lymphocytes) by 1g velocity sedimentation. The lymphocytes which were not activated during the primary culture (lymphocyte fraction from the velocity sedimentation) were then stimulated by the same mitogens or in one-way MLC to DBA/2 m, and tested for relevant target lysis after MLC stimulation. Primary stimulation with Con-A abolished the responses to Con-A, to PHA, and to LA, whereas primary stimulation with PHA or with LA abolished the responses to these mitogens but left behind a considerable Con-A response. Stimulation with any one of the listed T mitogens did not significantly affect the MLC responses. While primary stimulation with Con-A abolished the relevant target cell lysis after MLC stimulation, primary stimulation with PHA or with LA reduced it only slightly. Assuming that the various mitogens stimulate separate subpopulations of T cells, the results seem to indicate that the Con-A-responsive population includes the PHA- and LA-responsive populations but not the MLC-responsive population. It also appears that the T cells generated to killer cells during MLC are mainly confined to the concanavalin-responsive population.     

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

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

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.     

A reappraisal of the effector cells mediating mitogen induced cellular cytotoxicity.

The ability of mitogens to induce cytotoxic effector reactions in vitro has been studied to investigate basic mechanisms of cell mediated cytotoxicity. The type of mitogen, the source of effector cells, and the nature of the target cell are all critical variables in determining the characteristics of the cytotoxic event in this system. Spleen cells and bone marrow cells from congenitally athymic nude mice as well as from their heterozygous control littermates were capable of mediating lysis of RBC targets in the presence of either PHA or Con A. Removal of macrophages from these effector populations by adherence columns, density gradient centrifugation, and carrageenan treatment failed to abrogate this cytotoxic capacity. However, purified macrophages themselves also were capable of mediating mitogen induced killing of RBC targets, although the kinetics of this cytotoxicity were substantially different from that induced by lymphocytes. In contrast to these observations, the capacity of mitogen stimulated cells to kill metabolically active complex targets like the P815 mastocytoma or cultured L cells appears to be exclusively a T lymphocyte dependent function. In addition, blastogenic transformation of the effector cells with the T cell mitogens PHA and Con A, but not with the B cell mitogen LPS, leads to enhanced killing of these complex targets. These data suggest that mitogen or lectin induced cellular cytotoxicity can detect at least three different active effector cell types (B cells, T cells, and macrophages) acting via at least four different mechanisms.     

Modulation of suppressor activity by thymosin

Modulation of suppressor cell activity by thymosin was evaluated in vivo in a murine tumor system, and in vitro on human lymphocytes. We showed that splenocytes from tumor bearing mice were able to enhance tumor growth in a syngeneic system. This enhancement was T dependent and disappeared by Thymosin treatment. A decrease of Tumor size associated with injection of bone marrow cells treated by thymosin was observed. In the human system we showed that ConA stimulated lymphocytes were able to suppress the response of normal lymphocytes to PHA, PWM and ConA, and in MLC. This effect was significantly blocked in presence of thymosin fraction 5.     

Immunologically specific cytolytic activity induced in long-term mixed leukocyte culture cells by concanavalin A.

Stimulation of cells from long-term primary MLC with Con A resulted in the generation of CTL activity comparable in magnitude to that induced by reexposure of the cells to the original stimulating cellular antigen. CTL generated by stimulation of long-term MLC cells with ConA had lytic activity specific for the original stimulating alloantigen used in primary MLC. The pattern of stimulation of long-term MLC cells with Con A differed from that of restimulation with alloantigen in that there was no detectable CTL activity the first 24 hr after Con A stimulation and the peak lytic activity occurred later. Unlike restimulation with alloantigen early lytic activity after Con A stimulation was dependent on DNA synthesis. PHA also proved to be an effective agent for stimulating cytolytic activity in long-term MLC cells. The response to PHA was comparable in magnitude to that generated by Con A. Stimulation of long-term MLC cells with T cell mitogens gave decreased cell recoveries relative to restimulation with alloantigen, however, the lytic activity per cells recovered was generally greater in the mitogen-stimulated cultures.     

Soluble suppressor activity of concanavalin A-activated spleen cells on B-lymphocyte colony formation in vitro.

Supernates from concanavalin A (Con A)-activated mouse spleen cell cultures suppress the formation of B-lymphocyte colonies (BLC) in soft agar culture by 30 to 95%. Con A-induced BLC suppressive culture supernates can be heated at 80 °C for 1 hr without losing activity. The BLC suppressive activity is eliminated totally by trypsin treatment and partly by treatment with β-galactosidase. Activity is unaffected by treatment with DNAse, RNAse, and α-glucosidase. By ultrafiltration the BLC suppressive factor(s) was shown to have a molecular weight greater than 300,000. These data suggest that BLC suppression is mediated by a protein-carbohydrate complex. BLC suppression was obtained when normal spleen cells were preincubated in Con A-activated supernates for only 1 hr at 37 °C. BLC suppressor activity was absent in the supernatant fluid of Con A exposed anti-θ-treated spleen cells, nonadherent spleen cells, extensively washed spleen cells, and spleen cells from nude (athymic) mice suggesting that cells responsible for Con A-induced BLC suppression are adherent, fragile cells of the T lineage. Con A-activated spleen cell supernates do not suppress colony formation in soft agar by normal mouse granulocyte-macrophage precursors, by plasmacytoma cells, T-lymphoma cells, or by carcinoma cells. However, colony formation by Abelson's murine leukemia virus transformed B-lymphoma cells was suppressed by 95% suggesting a relationship between this immature B-lymphoma line and B-lymphocyte colony-forming cells. Con A-activated spleen cell supernates do not suppress lymphocyte activation in liquid culture by phytohemagglutinin, Con A, or lipopolysaccharide. Heat-treated supernates—which inhibited BLC development by 90–95%—did not suppress the plaque formation by spleen cells immunized in vivo or in vitro by sheep red blood cells.     

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.     

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

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

Immunoregulation in experimental filariasis. I. In vitro suppression of mitogen-induced blastogenesis by adherent cells from Jirds chronically infected with Brugia pahangi

Nonspecific immunoregulatory events were examined in inbred jirds chronically infected with Brugia pahangi. The responsiveness of spleen cells from infected animals to the T cell mitogens PHA and Con A and to the B cell mitogens, LPS and PWM, was found to be suppressed by as much as 90% when compared with the reactivity of lymphocytes from normal animals. Furthermore, spleen cells from infected jirds were capable of suppressing the mitogen reactivity of normal spleen cells. Depletion of cells adherent to nylon wool, glass wool, or plastic alleviated the regulatory activity exerted by spleen cells from infected jirds. Addition of indomethacin, an inhibitor of prostaglandin synthetase, to cultures of spleen cells from infected animals did not alter the suppression observed. In contrast, lymphocytes from the peripheral lymph nodes of infected jirds did not exhibit depressed T cell mitogen reactivity and were incapable of suppressing the PHA or Con A responsiveness of normal lymph node cells. However, the reactivity of lymph node cells from infected jirds to B cell mitogens, LPS and PWM, was suppressed. These results imply the existence of multiple regulatory mechanisms, at least one of which is restricted to the spleen. The relevance of nonspecific regulation to development of parasite-specific immunologic reactivity and to the infection is discussed.