Mitogen-induced suppressor factor(s) from human lymphocytes: effects on lymphoid and nonlymphoid cells and biophysical properties

Concanavalin A (Con A) or phytohemagglutinin activate a population of human circulating lymphocytes to exert suppressive functions. We found that supernates from the activated human lymphocytes suppress lymphocyte responses to Con A, the mixed lymphocyte reaction and pokeweed mitogen-induced IgM production. Mitogen stimulated suppressor lymphocytes, or their supernates, inhibit also the spontaneous proliferation of human retinoblastoma cells (Y-79 line) and primary cultures of human keratocytes. A correlation was always noted between the levels of inhibitory activities of the lymphocytes and their supernates. Furthermore, a good correlation was found between the levels of inhibition by the supernates of lymphocyte functions (proliferation and IgM production) and of the nonlymphoid cells' proliferation. Some of the properties of this suppressor factor(s) are: (i) produced only by the T-cell population; (ii) appears after 8 hr of Con A stimulation, peaks at 24 to 48 hr and declines later on; (iii) stable at 56 °C and labile to 70 °C; (iv) nondialyzable and present in the 40K–100K dalton fraction of a G-200 Sephadex column; (v) labile to pH 2 treatment.     

Suppressor factor secreted by T hybridoma established from peripheral blood lymphocytes of a bone marrow transplantation patient. I. Establishment of human T-cell hybridoma and partial characterization of suppressor factor

A stable human T-cell hybridoma was established by cell fusion between activated human peripheral blood lymphocytes from an allogeneic bone marrow transplantation patient and the JD1-17 cell line, a subclone of the human T leukemia Jurkat cell line. This hybrid clone 1-8, which bore the surface phenotype of suppressor cells (CD8+HNK1+), spontaneously secreted a factor which, at high dilutions, suppressed the responses of T and B cells induced by mitogens and alloantigens. This suppressor factor was found to be heat-resistant (56 degrees C, 30 min), stable at alkaline but not acid pH, unaffected by 2-mercaptoethanol, and sensitive to trypsin. Preparative isoelectric focusing revealed an isoelectric point of 5.35. The suppressor activity was selectively absorbed by blast T cells. By gel filtration on Sephacryl S-200 and HPLC, the suppressor activity was found in two peaks corresponding to 40-45 kDa (monomer) and 90-95 kDa (dimer).     

Suppressor T lymphocyte induction by a factor released from cultured blastocysts

For the analysis of immunologic escape mechanisms of embryos during the implantation period in mice, the effects of culture supernatant of blastocysts on in vitro responsiveness to alloantigen of mice was investigated. Blastocyst-cultured conditioned medium was prepared by culturing late blastocysts of outbred ICR mice for 5 days. The addition of culture supernatant containing four or eight blastocysts to allogeneic mixed lymphocyte culture inhibited both the MLR responses and the generation of cytotoxic T lymphocytes (CTL). Preincubation of the culture supernatant with lymphocytes syngeneic to the responder cells of MLR induced potent suppressor cell activity in the MLR. The supernatant did not inhibit the activity of CTL at the effector phase, but preinduced suppressor cells obtained by incubation of splenocytes with the supernatant showed almost complete suppression of CTL activity at the effector phase. Both of the suppressor cells, active on MLR and at the generation phase of CTL as well as active at the effector phase, had a surface phenotype of Thy-1+ and Ig-. The suppressive material could be extracted from the eight-cell stage of fertilized ova or blastocysts but not from unfertilized ova, indicating that the production of the factor(s) is dependent on the stages of early embryogenesis. These results suggest that the active induction of suppressor T lymphocytes by the factor(s) released from implanted embryos is one of the protective mechanisms from maternal immunologic attack.     

Interleukin 1 secretion is not required for human macrophage support of T-cell proliferation

Interleukin 1 (IL-1) is a soluble factor secreted by stimulated monocytes (Mo) and animal macrophages (Mx). We have previously demonstrated that human Mo cultured in vitro for 1-6 days transform to Mx, and retain their ability to support concanavalin A (Con A)-driven T-cell proliferation. We have also shown that, paradoxically, these Mx do not secrete IL-1, when stimulated by endotoxin (LPS). In this study we examined two alternative hypotheses: T cells plus mitogen induce Mx IL-1 production, and human Mx deliver a second signal to T cells via a non-IL-1 mechanism. IL-1 was assayed in a mouse CD-1 thymocyte system without concanavalin A. Mo/Mx were cultured with T cells at low (2 X 10(4)/200 microliters) or high (1 X 10(5)/200 microliters) concentrations for 2 or 4 days, in the presence of Con A. Six hours prior to quantitation of proliferation, 50 microliters of supernatant was removed and assayed for IL-1. As expected both Mo and Mx enhanced T-cell proliferation eight- to tenfold. Mo secreted large amounts of IL-1; there was no demonstrable IL-1 activity present in supernatants from cultures containing either T cells and Mx, or Mx alone. Similar results were obtained by preincubating the cells (Mo, Mx, and T cells) with Con A for 12 hr and removing Con A prior to a 36-hr coculture. We examined the possibility that a small amount of IL-1 may be able to support Con A-stimulated T-cell proliferation and yet may not induce thymocyte proliferation. The highest dilutions of Mo supernatant (1:125) which supported T-cell proliferation also caused a fivefold increase in thymocyte proliferation. Supernatants from Mx failed to stimulate thymocyte proliferation or support Con A-driven T-cell proliferation. However, Mo and Mx lysates contain Il-1 activity. We conclude that human Mx support Con A-induced T-cell proliferation in the absence of IL-1 secretion. Mx may support T-cell proliferation by cell-bound IL-1 or by a non-IL-1 mechanism.     

Properties of histamine-induced suppressor factor in the regulation of lymphocyte response to PHA in mice

Splenic T lymphocytes release a suppressor factor into the culture supernatant when incubated for 24 hr with histamine (10^?4M). Histamine-induced suppressor factor (HISF) inhibits lymphocyte response to PHA; it is released by T lymphocytes (either nylon-nonadherent or nylon-adherent lymphocytes) and not by B-cells or macrophages; its production is not observed after depletion of histamine receptor-bearing lymphocytes and is blocked by the H2 receptor antagonist (cimetidine) but not by the H1 receptor antagonist (diphenhydramine). Gel filtration by Sephadex G100 chromatography indicates that HISF had an approximate MW of 45,000 to 68,000. Its inhibitory activity was removed by passage over a histamine RSA-Sepharose column, but not by passage over rabbit anti-mouse Ig-Sepharose column; it was blocked by prostaglandin synthetase inhibitor (PGS) (Ro 205720) indicating that this activity is mediated by a prostaglandin (PG) synthesis.     

Histamine-induced suppressor factor (HSF): effect on migration inhibitory factor (MIF) production and proliferation.

Histamine added in vitro to cultures of sensitized lymphocytes suppresses antigen-induced production of migration inhibitory factor (MIF) and proliferation by these cells. Recent studies have suggested that lymphocytes bearing histamine type-2 receptors play a regulatory role in these in vitro responses. The present studies were undertaken to determine if suppressor function by cells having histamine receptors was mediated through a soluble product. It was found that lymph node cells from nonimmune or immune strain 2 guinea pigs elaborate a nondialyzable factor into the culture supernatant when incubated with 10(-3) to 10(-5) M histamine (histamine-induced suppressor factor of HSF). HSF, when cocultured with sensitized lymphocytes, suppressed their MIF and proliferative responses to antigen. HSF was made by lymphocytes but not macrophages. Its production could be blocked by an H2 receptor antagonist (burimamide) but not an H1 receptor antagonist (chlorpheniramine). Furthermore, the inhibitory effect of HSF was reversible as lymphocytes washed free of the factor after 24 hr and recultured with fresh medium and antigen were able to produce MIF. Gel filtration by Sephadex G-100 chromatography indicated that HSF had an approximate m.w. of 23,000 to 40,000. These results suggest that the release of histamine at the sites of immediate hypersensitivity reactions, possibly by generating HSF activity, may play a regulatory role in the subsequent development of cellular-immune reactions at the same site.     

Natural killer (NK) cell activating factor produced by a human T-cell hybridoma.

A human T-cell hybridoma (KC8-1.10), whose culture supernatant augments peripheral blood lymphocytes (PBL)-mediated spontaneous cytotoxicity against K562 cells, was established. This activity [natural killer (NK) cell activating activity] appears to be not due to interferon-gamma (IFN-gamma) and interleukin-2 (IL-2) for the following reasons: 1) KC8-1.10 produced negligible or small amounts of IFNs and IL-2. 2) The NK cell activating activity in the KC8-1.10 culture supernatant was not neutralized by anti-IFN-gamma antiserum and stable even after pH 2 treatment for 24 hr, which is known to destroy IFN-gamma activity. 3) IL-2-dependent cell line absorbed IL-2 more efficiently than it absorbed the NK cell activating activity, and the latter activity was not retained by Blue Sepharose column in contrast with IL-2. The NK cell activating factor in the KC8-1.10 culture supernatant appears to be a glycoprotein, because the activity was abolished with pronase treatment or with boiling for 5 min and because the activity was retained by concanavalin A- and Pisum sativum agglutinin-agarose. Finally it was found that the NK cell activating activity requires Leu 11b+ cells to exert its effect.     

Suppression of cytotoxic T-lymphocyte activation by pyruvate and L-alanine

The activation of cytotoxic T lymphocytes (CTL) in allogeneic mixed-lymphocyte cultures was found to be strongly inhibited if 1-3 X 10(-2) M L-alanine or the structurally and biochemically related substance pyruvate was present in the period from 7 to 19 or from 19 to 120 hr. The cytotoxic response was not inhibited when L-alanine or pyruvate was present during the first 7 hr of the culture period. L-Alanine produced also little or no suppression, if added on Day 3 of the culture. L-Lactate or D-alanine at similar concentrations was not suppressive during the entire culture period. The suppression by pyruvate and L-alanine was strongly reduced by 1 X 10(-4) M adenosine. Adenosine in combination with an interleukin-2 (IL-2)-containing EL-4-cell supernatant was even more effective. Pyruvate and alanine (1-3 X 10(-2) M) also inhibited the DNA synthesis in mixed-lymphocyte cultures on Day 5 by about 50%, but both substances had practically no effect on DNA synthesis in cultures that had been supplemented with an IL-2-containing EL-4 supernatant. They had also no effect on the IL-2-dependent proliferation of several T-cell clones or of concanavalin A-activated thymocytes. These relatively selective regulatory effects of pyruvate and L-alanine may be useful for the analysis of the biochemical pathways during lymphocyte activation and/or for a selective manipulation of the immune response.     

Soluble suppressor of T cell proliferation in primary in vitro response to murine minor histocompatibility antigens

Normal mouse lymphocytes are not capable of mounting a primary cytotoxic T cell response to Mls encoded, non H-2, allodeterminants, although a strong lymphoproliferative response is observed in primary MLR between Mls incompatible cells. In this study it is reported that in the supernatant of primary cultures between AKR macrophages and CBA/H lymphocytes (H-2 identical, incompatible for Mls and other minor antigens) a suppressor of T cell proliferation in MLR is detected. By contrast, a suppressor is not detected in supernatants from primary cultures between BALB/C macrophages and CBA/H lymphocytes (H-2 incompatible, Mls identical), B10.BR macrophages and CBA/H macrophages and CBA/H lymphocytes (syngeneic) suggesting that the production of the suppressor factor occurs only when an Mls incompatibility exists. The suppressive activity of the Mls incompatible culture supernatant upon MLR between incompatible macrophages and lymphocytes is neither antigen specific nor Mls or H-2 restricted, nor is it due to an irreversible toxic effect on T lymphocytes or macrophages. The inhibition of T cell proliferation could be explained by inhibition of IL 2 production, by blocking its union to T cells or by a combination of both effects. Our findings could help explain previous observations that lymphocytes from mice preimmunized with Mls incompatible cells have a depressed proliferative response as well as depressed cytotoxicity against alloantigens.     

Immunoregulatory factors from a human macrophage-like cell line. II. A human T-cell lymphokine-induced suppressor factor for lymphocyte proliferation

It has been demonstrated that the human histiocytic lymphoma-derived cell line U937, which has monocytoid characteristics, responds to a concanavalin A-induced T-cell-derived suppressor supernatant (T-SFS) with the release of a factor markedly suppressing mitogen-stimulated proliferation of normal peripheral blood lymphocytes. The suppressor material is not dialyzable, appears within 2 hr of exposure of U937 cells to the T-SFS, persists for at least 24 hr, and has a Mr of approximately 40,000 by gel chromatography. The suppressor factor does not affect the proliferation of continuous T- and B-lymphoid cell lines, distinguishing it from the inhibitor of DNA synthesis also released by U937, but appears to be specific for a stage of activation of normal lymphocytes that is independent of (a) utilization of interleukin-2 and (b) inhibition of production of interleukin-2.     

Physiochemical characterization of human histamine-induced suppressor factor

A product of histamine-stimulated human lymphocytes, histamine-induced suppressor factor or HSF, was characterized by enzyme treatment, sensitivity to reduction and alkylation, by molecular sieve chromatography, and by polyacrylamide gel electrophoresis. HSF was found to have a wide pH stability (pH 3-10), sensitivity to temperatures greater than 80 degrees C, and to have the properties of a glycoprotein by virtue of its sensitivity to chymotrypsin, trypsin, sodium periodate, and neuraminidase. HSF did not appear to have a serine group(s) in its "active" site since its biologic activity remained intact following treatment with an irreversible serine esterase inhibitor (phenylmethylsulfonyl fluoride). Further, HSF did not appear to have inter- or intra-molecular disulfide linkages because treatment with denaturing and/or reducing agents, followed by alkylation, did not significantly alter its activity. Molecular sieve chromatography employing Sephadex G-100 revealed an apparent molecular weight for HSF of 25-40,000. Electrophoresis of HSF in polyacrylamide gels at pH 8.7 under nonreducing conditions revealed two regions of activity, one region migrating with albumin and the other region anodal to albumin. In addition to suppressing lymphocyte proliferation, the 25-40,000 Mr Sephadex G-100 fractions also inhibited the production of leukocyte inhibitory factor. Of particular interest, gel filtration of supernatants generated by stimulating mononuclear cells with either histamine, dimaprit (but not 2-pyridylethylamine), concanavalin A, or candida albicans resulted in similar elution profiles with regard to inhibition of lymphocyte proliferation. That is, 25-40,000 Mr fractions of supernatants generated by each stimulant suppressed lymphocyte proliferation to a similar degree. The latter findings provide indirect evidence that T lymphocytes, triggered in response to antigen-specific and nonspecific stimuli, elaborate suppressor molecules capable of modulating T-cell function that share certain similarities.     

Spontaneous production of a suppressor factor by a human macrophage-like cell line U937. II. Suppression of antigen- and mitogen-induced blastogenesis, IL 2 production and IL 2 receptor expression in T lymphocytes

U937, a human macrophage-like cell line, spontaneously produces a factor which inhibited blastogenic responses of human blood T lymphocytes stimulated with tuberculin-purified protein derivative (PPD) or phytohemagglutinin (PHA). We investigated the mechanism of suppressor action of the U937 factor. The U937 suppressor factor inhibited interleukin 2 (IL 2) production by human blood T lymphocytes stimulated with PPD or PHA. IL 1 did not overcome the inhibitory action of the U937 factor on PPD-induced IL 2 production by human blood T lymphocytes. The U937 factor also inhibited the production of IL 2 by a human leukemic cell line, JURKAT, stimulated with PHA. The U937 suppressor factor interfered with the expression of Tac antigen (IL 2 receptor) on PPD- or PHA-stimulated blood T lymphocytes. The inhibitory activity of the U937 factor on Tac expression was not affected by the addition of IL 2 or a crude lymphokine-containing T cell supernatant. Tac expression was more sensitive than IL 2 production to inhibition by U937-conditioned medium. The U937 suppressor factor was precipitable by 33 to 67% saturated ammonium sulfate and was inactivated at pH 2 or pH 11. Sephacryl S-200 Gel filtration analysis of U937 culture supernatants revealed that the inhibitory activities for blastogenesis, IL 2 production, and Tac expression co-purified in fractions with an apparent m.w. between 67,000 and 130,000. These data indicate that U937 spontaneously produces a macromolecular suppressive factor with major locus of action on the production of IL 2 and the expression of the IL 2 receptor.     

Human T-lymphocyte chemotactic activity: nature and production in response to antigen

Previous studies have shown that supernatants from concanavalin A-stimulated human peripheral blood mononuclear cells and isolated Leu-2 suppressor/cytotoxic T cells are chemotactic for Leu-3 helper/inducer T cells. The current study shows that lymphocyte chemotactic factor (LCF) is also produced following antigen (tetanus toxoid) challenge of mononuclear cells obtained from recently immunized human donors. LCF was detected in 24-hr supernatants from mononuclear cells challenged with tetanus and was produced maximally at 48 hr. Tetanus toxoid challenge of mononuclear cells obtained from individuals whom had not received a tetanus immunization for 7 to 10 years prior to testing showed little or no production of LCF. Serial studies of these individuals following a tetanus booster immunization showed that LCF was produced by antigen-challenged mononuclear cells obtained 1-5 days postimmunization, was produced optimally 5-15 days postimmunization, and was still produced by antigen-challenged mononuclear cells obtained 6 weeks later. Fractionation of mononuclear cells from immunized donors into glass wool nonadherent lymphocytes, T lymphocytes, and non-T lymphocytes showed that tetanus-toxoid-induced LCF was produced by nonadherent lymphocytes and T cells but not non-T cells. Further fractionation of T lymphocytes into Leu-2 and Leu-3 T-cell subpopulations showed that LCF production by antigen-challenged isolated subpopulations was limited to the Leu-2 suppressor/cytotoxic T-cell subset. Characterization of both Con A and tetanus toxoid-induced LCF by gel filtration on Sephadex G-100 demonstrated the presence of two peaks of LCF corresponding to molecular weights of approximately 14,000-17,000 and 40,000-50,000.     

Inhibition of interleukin 1 activity by a factor in submandibular glands of rats

With the sequential use of ammonium sulfate precipitation, gel filtration and chromatofocusing, we have partially purified from extracts of the submandibular glands of rats a factor (referred to as submandibular gland's immunosuppressive factor or SMG-ISF) capable of inhibiting the in vitro proliferation of mitogen- and antigen-stimulated murine lymphocytes. The semi-purified suppressor fractions had an isoelectric point of 4.4 to 4.5 and consisted of at least three molecular species. These active fractions suppressed the mitogenic effects of Concanavalin A phytohemagglutinin, and lipopolysaccharide. In vitro immune reactions such as the mixed lymphocyte culture MLC reaction and the production of cytotoxic T lymphocytes (CTL) across major histocompatibility barriers in mice were also suppressed. These in vitro immunosuppressive effects required the addition of the suppressor fractions early after the initiation of the cultures and were reversed if the factor was removed from the cultures at least 48 to 72 hr before the completion of the assays. The active fractions did not affect the proliferation of CTLL 2 cells induced by interleukin 2 (IL 2), but inhibited the mitogenic and co-stimulatory effects of IL 1 on mouse thymocytes, and in this effect showed a dose-response relation suggestive of a competitive mechanism. These characteristics of SMG-ISF indicate a specific inhibition of the activity of IL 1.     

The necessity for T cell help for human tonsil B cell responses to pokeweed mitogens: induction of DNA synthesis, immunoglobulin, and specific antibody production with a T cell helper factor produced with pokeweed mitogen.

Human B lymphocytes obtained from tonsils do not proliferate when stimulated with pokeweed mitogen. A soluble factor produced from T cells cultured with pokeweed mitogen stimulates B cells to synthesize DNA and differentiate into immunoglobulin producing cells. This PWM produced supernatant induced a PFC response to SRBC. The T cell supernatant activity is produced within 12 hr of stimulation in the presence of serum and without a requirement for T cell division. Optimal stimulation of B cells occurred at 7 to 9 days of culture. This helper factor activity eluted postalbumin from a column of Sephadex G-200. Insolubilized pokeweed mitogen was not mitogenic for B cells. The continuous presence of the lectin in culture was not required for B cell proliferation or for immunoglobulin synthesis.     

Regulatory Factors of Lymphocyte-Lymphocyte Interaction: I. Con A-Induced Mitogenic Factor Acts on the Late G1 Stage of T-Cell Proliferation

DNA synthesis in murine lymphocytes was augmented by a soluble factor in the supernatant of serum-free cultures of syngeneic spleen cells activated with concanavalin A (Con A). This so-called mitogenic factor (MF), which is probably identical with interleukin II, partially purified by DEAE-cellulose and Sephadex G-75 chromatography, is a fairly homogeneous molecule of 17–25 × 10³ daltons. By using partially purified MF, the role of MF in lymphocyte proliferation was investigated. Pretreatment of lymphocytes with Con A for the first 3 hr of culture, which does not in itself induce cell proliferation, markedly augmented the effect of MF. The presence of MF, however, is necessary only in a restricted stage (s) of lymphocyte proliferation. The addition and removal of MF at various times during culture showed that MF exerts its effect on a process which occurs 3–6 hr before the beginning of DNA synthesis. These results strongly suggest that MF regulates the proliferation of mitogen-stimulated lymphocytes by acting on a restricted stage (s) of the cell cycle.     

Characterization of an antigen-specific suppressive factor derived from a cloned suppressor effector T cell line

A cloned effector-type suppressor T cell line, 3D10, which is known to suppress the antibody response against dinitrophenylated keyhole limpet hemocyanin (KLH), produced a soluble KLH-specific factor (TsF) that can replace the function of parental T cell clones. High activity of TsF was released spontaneously into the culture supernatant when cultured in interleukin 2 (IL 2)-containing medium, requiring no antigenic stimulation. The culture supernatant of 3D10 was also capable of inhibiting the KLH-induced proliferative response of primed T cells in an antigen-specific manner. The direct target of TsF was found to be Lyt-1+2- T cells undergoing an early stage of antigen-specific proliferation. TsF was antigen binding but lacked any other serologic markers such as I-J and immunoglobulin heavy chain-linked allotypic determinants on T cells. No genetic restriction was found in its action on allogeneic T cells. The production of IL 2 in proliferative T cells by antigenic stimulation was not inhibited by TsF. These results indicate that the TsF described here is the legitimate mediator produced by the effector-type suppressor T cell that suppresses the antigen-specific responses of Lyt-1+2- T cells. The m.w. of TsF was approximately 75,000.     

T lymphocytes and their CD4 subset are direct targets for the inhibitory effect of calcitriol

We studied the direct effects of the hormone calcitriol on the activation and proliferation of pure T lymphocytes and their subsets. Calcitriol inhibited the proliferation of T lymphocytes stimulated in the absence of monocytes with phytohemagglutinin (PHA) and either a monocytic culture supernatant or a combination of monocyte-derived interleukin 1 and interleukin 6. This inhibition was not influenced by the concentration of the stimulating agents. The minimal effective concentration of calcitriol was 10(-10) M. In contrast, the interleukin 2 (10 U/ml)-driven growth of PHA-stimulated T lymphocytes was not significantly altered by calcitriol at 10(-8) M. The hormone had also no influence on the T lymphocyte proliferation induced by a combination of PHA and the anti-CD28 monoclonal antibody 9.3. Pure T lymphocytes, after incubation for 5 days with PHA and monocytic factors, expressed a high level of transferrin receptors. This phenomenon was strongly suppressed on both CD4 and CD8 subsets when 10(-8) M calcitriol had been present during the culture. Moreover, the proliferation of pure CD4 cells was directly inhibited by calcitriol in similar conditions as for unseparated T lymphocytes. We conclude that T lymphocytes and their CD4 subset are direct targets for the inhibitory effect of calcitriol.     

A series of murine interleukin molecules which stimulate both murine and human lymphocytes: I. Production by Phytolacca americana (pokeweed) lectin 2 (Pa-2)-stimulated thymus and thymus-derived cells

Cell-free supernatant fluid, from cultures of Phytolacca americana (pokeweed) lectin 2 (Pa-2)-pulsed murine spleen or thymus cells, contains factors which induce cultured lymphocytes to differentiate into IgM-secreting cells (assayed by a reverse plaque technique) and to proliferate (measured by the incorporation of tritiated thymidine) without the addition of mitogen. The factors in this supernatant fluid responsible for these activities have been designated as lymphocyte stimulating factors (LSF). LSF showed no genetic restrictions related to the major histocompatability complex; LSF made in one strain of mice worked in other strains. Indeed, LSF is not restricted by species barriers; human peripheral blood mononuclear cells were also stimulated by murine LSF to proliferate and differentiate into immunoglobulin-secreting cells without further addition of antigen or mitogen. Maximum production of LSF was achieved within 12 hr of culture and was independent of cell division. In contrast to TRF, no further production of LSF was detectable after 24 hr of culture. Unlike T-cell growth factor, this material stimulated increased mitosis of thymic, T, and B lymphocytes without the addition of mitogen or antigen. LSF also stimulated polyclonal B-cell differentiation into IgM-secreting cells. Maximal numbers of immunoglobulin-secreting cells were generated when LSF was added at the initiation of the culture. Indeed, unlike TRF, LSF needed to be present only during the first 6 hr of culture to achieve maximum stimulation, and did not require the presence of antigen. The production of LSF by a T-cell population in the spleen was shown by two independent methods. Spleen cells treated with anti-Thy 1 plus complement failed to produce detectable levels of LSF. On the other hand, purified populations of surface immunoglobulin-negative spleen cells produced LSF. Furthermore, the subset of thymocytes responsible for LSF production was the small population (approximately 10%) of cells in the thymus, which are not agglutinated by peanut agglutinin.     

Enhancement of macrophage Fc-dependent phagocytosis by resident thymocytes: effect of a unique heat-stable lymphokine

Lymphocytes, activated by lectins or specific antigens, have been shown to enhance macrophage phagocytosis through the elaboration of a heat-labile soluble factor(s). Recent evidence from our laboratory revealed that resident (nonactivated) murine thymocytes and splenic lymphocytes increase peritoneal macrophage glucose metabolism through the elaboration of a heat-stable soluble factor(s). Therefore, we investigated the effect of resident lymphocyte subpopulations on macrophage Fc-dependent phagocytosis. Thioglycollate-elicited and resident peritoneal macrophages from BALB/c mice were cultured in serum-free media with syngeneic resident thymocytes or splenic T lymphocytes. Macrophage Fc-dependent phagocytosis was assayed by measuring the ingestion of 51CrSHEA. After 4 days in vitro, resident thymocytes produced a mean 160 (+/- 31) and 136% (+/- 22) increase in Fc-dependent phagocytosis by thioglycollate-elicited (thio-macrophages) and resident peritoneal macrophages, respectively. Splenic T lymphocytes increased thio-macrophage phagocytosis by 112% (+/- 41) under similar conditions. Macrophage Fc-dependent phagocytosis was increased after 24 hr of co-culture by supernatant derived from resident thymocytes and could be further enhanced by supernatant from Con A-activated thymocytes. Supernatant from guinea pig embryo fibroblasts did not increase macrophage phagocytosis. The soluble factor(s) was produced by resident thymocytes after 24 hr of preculture. This factor was active despite heating at 100 degrees C for 30 min whereas the effect of Con A-activated thymocyte supernatant was heat-labile. The stimulatory effect of resident thymocyte supernatant was not observed when the macrophages and supernatant were cultured in 2% FCS. In contrast to the factor(s) produced by resident thymocytes, the factor(s) in FCS that increased phagocytosis was heat-labile. These data suggest thymocytes and splenic T lymphocytes promote macrophage Fc-dependent phagocytosis in the absence of antigenic or lectin stimulation. This previously unrecognized effect of resident thymocytes is due to a unique heat-stable soluble factor(s) that is concealed in the presence of serum.