Stimulation of mouse migration inhibitory factor (MIF) production form MSV-immune lymphocytes by soluble tumor-associated antigen: requirement for histocompatible macrophages.

Spleen cells from C57BL/6 mice immunized with murine sarcoma virus (MSV) are capable of producing migration inhibition factor (MIF) in response to stimulation with a specific tumor-associated antigen prepared by solubilization with 3 M KCL. We have previously demonstrated that this response is T cell-dependent. Further investigations into the effector cells involved in the production of MIF have revealed that spleen cells from mice immunized with MSV cannot produce MIF when stimulated with tumor extract if the population has been previously depleted of macrophages. However, the response can be restored by adding nonimmune syngeneic macrophages but not by allogeneic macrophages. The inability of allogeneic macrophages to provide this function was not due to their increased suppressor activity since in mixing experiments they did not interfere with the ability of immune spleen cells to produce MIF. Furthermore, they were not defective since they could supply this "cooperative function" to appropriate F1 mice. The results indicate that macrophages are required for stimulation of MIF by soluble tumor antigens and that for efficient interaction the macrophages and lymphocytes must share some genetic similarities.     

The cellular basis for differential lymphokine responses to mitogen stimulation

Human mononuclear cells from some individuals produce macrophage migration inhibition factor (MIF) when stimulated with Con A while those of others produce migration stimulation factor (MStF). T cells were responsible for these different responses but T4 cells produced MIF and T8 cells produced MStF regardless of the global response which was not explained by the individual T4:T8 ratios. Admixing the T-cell subpopulations in vitro revealed that MIF responses switched to MStF responses between T4:T8 ratios of 75:25 and 50:50 with MStF responders switching at higher ratios than MIF responders. Pulse exposure to supernatants from Con A-stimulated T4-enriched cells significantly reduced migration indices resulting from stimulation of fresh cells, promoting MIF responses regardless of the responder status of the supernatant donor. In contrast, supernatants from T8-enriched cells, when obtained from MStF responders, significantly increased migration indices while there was no effect when the supernatants were obtained from MIF responders. These results suggest that soluble factors from T8 cells are primarily responsible for determining whether an individual mounts a MIF or MStF response to Con A stimulation.     

Lectin induction of lymphokines in cultured murine leukocytes

Antigens induce sensitized lymphocytes to undergo mitosis and to secrete soluble products, termed lymphokines, which modulate the immune response. Plant lectins are known to act as polyclonal lymphocyte mitogens and, in some cases, stimulate lymphocytes to produce lymphokines. In an effort to explore the relationship of specific cell surface glycoconjugates to the induction of mitosis and the production of lymphokine activities we have examined the ability of the mitogenic lectins, concanavalin A and Wistaria floribunda mitogen, and the nonmitogenic hemagglutinin from Wistaria floribunda seeds to stimulate the production of macrophage migration inhibition factor (MIF), macrophage chemotactic factor (CF), and lymphotoxin (LT). Concanavalin A causes lymphocytes to produce MIF and LT but no detectable CF activities. W. floribunda mitogen induces lymphocytes to produce soluble substances which exhibit all three lymphokine activities. The nonmitogenic W. floribunda agglutinin causes lymphocytes to produce MIF and CF but no observable LT activity. Within the sensitivity of the assays employed, the results indicate that mitogenesis is not a corequisite of the expression of either macrophage migration inhibition factor or lymphocyte-derived chemotactic factor but it may be associated with the induction of lymphotoxin. It is also apparent that the expression of each lymphokine activity is independent of the expression of the other lymphokines studied.     

Staphylococcal enterotoxin B induced release of macrophage migration inhibition factor from normal lymphocytes

Staphylococcal enterotoxin B (SEB), a potent lymphocyte mitogen, inhibits migration of peritoneal exudate cells from most guinea pigs but does not inhibit migration of purified macrophages. Experiments were designed to test the ability of highly purified SEB to induce normal lymphocytes to release migration inhibition factor (MIF). Supernatants of lymph node lymphocytes cultured with SEB inhibited the migration of purified macrophages, indicating the release of a migration inhibition factor. Mitomycin-C blocked the SEB-induced release of MIF. SEB-induced MIF localized in the albumin fraction on Sephadex G-200 chromatography. Antibody to SEB specifically blocked the inhibitory effect of SEB on migration of normal guinea pig peritoneal exudate cells.     

Radiation leukemia virus-transformed immunocompetent T cells. II. Antigen-induced macrophage migration inhibition factor and leukocyte migration inhibition factor production

OVA-specific T cells were immortalized by infection with radiation leukemia virus (RadLV). Some clones derived from such population were shown to exhibit helper activity. We then tested clones without such function and found among them some that secreted macrophage migration inhibition factor (MIF) and leukocyte migration inhibition factor (LIF) upon exposure to the antigen in vitro. The lymphokine-producing clones, which were Thy-1+, Ly-1+ and Ly-2-, did not secrete MIF and LIF constitutively. Like other antigen-specific T cells, the immortalized clones could not be stimulated by free soluble antigen but required macrophages for presentation and for triggering the lymphokine production. The antigen-activated clones exclusively produced MIF and LIF, but not interleukin 2 or colony-stimulating factor. They neither provided helper activity nor induced delayed-type hypersensitivity. The data suggest that the T-cell clones carry the antigen receptors and that their antigen-inducible biological function is restricted to the migration inhibitory factor production.     

Suppression of lymphokine production: II. Macrophage-dependent inhibition of production of macrophage activating factor

The ability of different populations of macrophages to affect the production of macrophage activating factor (MAF) by stimulated T lymphocytes was investigated. We found that activated macrophages, infiltrating MSV-induced regressing tumors or macrophages recovered from the peritoneum of mice injected with Corynebacterium parvum, were able to actively suppress the production of MAF. MAF production by antigen-stimulated MSV-immune or -alloimmune spleen cells and by normal spleen cells stimulated by Con A was susceptible to macrophage-dependent suppression to a similar extent. In contrast, resident macrophages or those elicited by light mineral oil or proteose-peptone did not affect MAF production. While suppressor macrophages added at the time of the lymphocyte stimulation inhibited MAF production, the same cells added 4–6 hr after stimulation were ineffective. Therefore, it seems that the macrophages suppressed the early events of lymphocyte activation leading to MAF production. Suppressor macrophages, by inhibiting MAF production, may limit the expansion of the cytotoxic activity. This regulation of macrophage functions, mediated by the effects of suppressor macrophages on T lymphocytes, could be responsible for an insufficient antitumor cytotoxic response by macrophages.     

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.     

Release of macrophage migration inhibitory factor(s) from lymphocytes stimulated by streptococcal preparations

Lymphocytes from apparently healthy subjects, incubated for 5 hours with cellular components or extracellular products of group A streptococci and then washed and reincubated, were found to release factor(s) capable of inhibiting guinea pig lung macrophage migration (“indirect method”). Inhibitition of macrophage migration was also obtained when the same preparations were tested directly on guinea pig lung cells, a macrophage-lymphocyte population (“direct method”). The guinea pigs had not been experimentally sensitized. The inhibition of migration appeared to depend on the presence of lymphocytes among the macrophages, since macrophages purified by repeatedly discarding nonadherent cells proved resistant to the migration inhibiting activity of the most active Streptococcal preparation, a 20 × concentrated filtrate. Reconstitution of the original lymphocyte-macrophage mixture reestablished the reactivity. The macrophage migration inhibition did not correlate with the age of the guinea pigs. It could not be obtained with preparations of group D streptococci or of Salmonella paratyphi. Group C streptococci did not inhibit the macrophage migration with the indirect method, but it did with the direct one.The factor(s) released into the medium on stimulation of apparently normal lymphocytes by Streptococcal preparations was relatively heat resistant, nondialyzable, and DNase and RNase resistant; its release was inhibited by puromycin. Pretreatment of the cells with trypsin prevented the absorption of the factor(s) and left migration unaffected. These characteristics are similar to those previously described for the migration inhibitory factor (MIF) produced by the interaction of sensitized lymphocytes and specific antigens. Whether or not these similarities indicate an identity remains to be determined.     

The mediator of cellular immunity: XI. Origin and development of MIF producing lymphocytes

Thoracic duct lymphocytes obtained from rats infected with Listeria monocytogenes were characterized with respect to size, turnover and their capacity to release macrophage migration inhibitory factor (MIF). Cells responsive to Listerial antigens (LMA) in the MIF assay were identified in lymph during the first week of an immunizing infection. These were immunoblasts or large lymphocytes, as evidenced by their sedimentation with S phase lymphocytes at unit gravity. When labeled cells from the lymph of Listeria-infected donors were infused into similarly infected recipients, donor S phase lymphocytes localized rapidly, and in substantial numbers, in peritoneal exudates induced by the unrelated organism, F. tularensis. Within this immigrant population were cells which conferred immunity against L. monocytogenes and released MIF in cultures containing LMA. Exudates harvested 36 hr or 61 hr after stimulation contained labeled lymphocytes that were smaller than the S phase cells recovered during the early post-induction period. The observed shift of radioactivity from large to smaller lymphocytes was parallelled by a shift MIF production to exudate fractions containing smaller cells. The MIF producing cells in exudates of advancing age also exhibited increasing resistance to inhibition by vinblastine. These findings suggest that MIF is released by a family of lymphocytes—large, medium and small. LMA-responsive lymphocytes are delivered to the thoracic duct soon after their formation, at a stage in development when they can be stimulated to release only low levels of MIF. These mediator producing cells circulate briefly in the blood and differentiate fully only after they extravasate into inflammatory foci.     

Partial characterization of murine migration inhibitory factor (MIF).

These studies describe the production of murine migration inhibitory factor (MIF)3 in sufficient quantities to allow its partial characterization by physiochemical and enzymatic methods. MIF was obtained from murine spleen cell cultures (C57BL/6 strain) stimulated with concanavalin A (Con A). Characterization of murine MIF was performed using Sephadex G-100 gel chromatography, isopycnic centrifugation in a CsCl density gradient, polyacrylamide disc electrophoresis, heat stability, and enzymatic treatment. MIF-containing and control fractions were assayed on normal C57BL/6 peritoneal exudate cells by using a microcapillary tube assay. Peak MIF activity was found in a Sephadex G-100 fraction containing molecules the size of albumin and slightly smaller, molecular weight 67,000 to 48,000. Murine MIF was stable to heating at 56 degrees C for 30 min but lost its activity at 80 degrees C for 30 min. Incubation of G-100 fractions containing MIF with water insoluble chymotrypsin destroyed the activity of MIF, indicating its protein nature. CsCl density gradient centrifugation revealed that murine MIF had a buoyand density greater than protein, consistent with its being a glycoprotein. Further, when subjected to disc electrophoresis on polyacylamide gels, murine MIF migrated in a region cathodal to albumin. Thus, mitogen stimulation of murine spleen cells produced MIF in quantities which allowed its partial characterization and purification, and its comparison with human and guinea pig MIF; this makes it feasible to analyze the role of murine MIF in cellular immunity and in its relationship to lymphocyte mediators which regulate humoral immune responses.     

Refractoriness to migration inhibitory factor of macrophages of LPS nonresponder mouse strains.

The responsiveness to macrophage migration inhibitory factor (MIF) of peritoneal exudate cells (PEC) from the LPS unresponsive C3H/HeJ and C57BL/10ScCR mice was assessed by the indirect agarose microdroplet macrophage migration inhibition assay. No migration inhibition with PEC from C3H/HeJ nor C57BL/10ScCR mice was detected, whereas PEC from both C3H/HeN and C57BL/10Sn mice were significantly inhibited by even a 1/32 dilution of MIF-containing supernatants. Responsiveness to MIF of C3H/HeJ PEC could, however, be induced. In vivo inoculations of Mycobacterium bovis, strain BCG, 7 days before in vitro assay rendered C3H/HeJ PEC responsive to MIF. The lack of responsiveness to MIF by C3H/HeJ PEC appeared related to some form of suppression, since a mixture of PEC from C3H/HeN mice with 10 to 15% PEC from C3H/HeJ mice resulted in undetectable migration inhibition at any MIF dilution. In contrast to the usual lack of responsiveness of their macrophage to MIF, C3H/HeJ mice were able to produce MIK in response to PPD as well as their counterpart C3H/HeN mice after BCG sensitization. These results demonstrate that macrophages from C3H/HeJ and C57BL/10ScCR mice are unable to be inhibited in their in vitro migration of MIF (possibly being directly or indirectly influenced by a suppressor cell), whereas lymphoid cells from at least one of these strains, the C3H/HeJ mice, can produce MIF in response to antigenic stimulation.     

Production of a human T lymphocyte chemotactic factor by T cell subpopulations

Concanavalin A-stimulated human peripheral blood mononuclear cells release a lymphocyte chemotactic factor. This lymphocyte chemotactic factor is produced optimally after 24 to 48 hr of culture and is not found before 3 hr of culture, which suggests that the factor is synthesized de novo and is not preformed and secreted after Con A stimulation. This is further supported by experiments showing that the protein synthesis inhibitors cycloheximide and puromycin totally prevent the production of the chemotactic factor. Experiments using cultured and uncultured T lymphocytes as responding cells show that cultured T cells respond more efficiently than uncultured T cells to this factor. Furthermore, the lymphocyte chemotactic factor preferentially stimulates T lymphocyte locomotion as compared to peripheral blood non-T lymphocyte migration. Fractionation of mononuclear cells into glass nonadherent lymphocytes, monocyte-enriched preparations, T lymphocytes, and non-T lymphocytes shows that lymphocyte chemotactic factor is produced by Con A-stimulated, glass nonadherent lymphocytes and T cells but not by monocytes or non-T lymphocytes. Further fractionation of T lymphocytes into Leu-2 and Leu-3 T cell subpopulations shows that the production of T lymphocyte chemotactic factor can be attributed to the Leu-2 suppressor/cytotoxic T cell subset. The generation of a T lymphocyte chemotactic factor by Leu-2 T cells may represent a means of recruiting other T cells to the site of its release.     

Characteristics of T-cells synthesizing macrophage migration inhibition factor in an H-2 system]

Migration inhibition factor (MIF) was found to be produced by T-cells rather than B-cells as shown by the indirect macrophage migration inhibition test in the H-2 system performed with fractionated lymphocytes. MIF-producers appeared to be more sensitive than T-killer cells to the cytotoxic action of anti-theta-antibodies, plus complement. MIF synthesis by lymph node cells developed earlier after immunization than the cytotoxic activity of these cells. These findings indicated that T-cell subpopulation producing MIF differed from the cytotoxic T-lymphocytes.     

Regulating effect of bone marrow cells on human T-lymphocyte function

A study was made of the regulatory effect of human bone marrow cells in two experimental systems: lymphocyte proliferation in response to PHA, and spontaneous and PHA-induced production of macrophage migration inhibition factor (MIF) by peripheral blood lymphocytes. It was shown that bone marrow cells inhibit the proliferative activity of stimulated peripheral blood lymphocytes and induced MIF production. The effect of bone marrow cells on spontaneous MIF production was found to be inconclusive.     

Macrophage migration inhibition by complement activators,migration inhibitory factor,and Lotus fucolectin: Evidence for common involvement of cell-associated esterase activity

Activators of the complement pathway were compared with migration inhibitory factor (MIF) and Lotus fucolectin, which mimics MIF, for their macrophage migration inhibitory (MMI) activity. Endotoxin (LPS), cobra venom factor (CVF), and zymosan, known complement (C3) activators, were found to produce dose-dependent MMI activity, similar to MIF, independent of requirements for nonadherent lymphocytes and serum complement. Comparable activity was observed by all migration inhibitors in the presence of freshly harvested unheated or heat-inactivated guinea pig serum as well as zymosan-adsorbed (C3-depleted) serum. Iscove's serum-free medium also promoted migration inhibition confirming a lack of requirement for serum complement in the reaction. Polymyxin B reversed MMI by LPS, but had no effect on the other inhibitors, indicating that the MMI activity of CVF, zymosan, MIF, and Lotus fucolectin was not primarily due to LPS contamination. Peritoneal macrophages (PM), depleted of nonadherent lymphocytes, responded as well as unpurified PM to the complement activators and MIF. ?-Amino-n-caproic acid (EACA), l-lysine, and tranexamic acid (TA), known inhibitors of the fibrinolytic activity of plasminogen activator (PA), were found to reverse migration inhibition of C3 activators, MIF, and Lotus fucolectin. In contrast bovine pancreatic trypsin inhibitor (BPTI) and soybean trypsin inhibitor (STI) had no effect on MMI activity. These results suggest a common mechanism for mediation of migration inhibition by complement activators and MIF which may involve activation of cell-associated complement to produce esterolytic end products capable of triggering the activation process.     

A soluble factor produced by bone marrow natural suppressor cells blocks interleukin 2 production and activity

We previously reported that a population of Fc gamma-receptor+ (Fc gamma R+) suppressor cells present in normal unstimulated rabbit bone marrow inhibited the growth of autologous rapidly proliferating bone marrow cells devoid of Fc gamma R. It is now reported that the Fc gamma R+ bone marrow cells produced a soluble, nondialyzable suppressor factor(s) (SF) which blocked the proliferation of Fc gamma R- bone marrow cells. In addition, the Fc gamma R+ cells and SF significantly inhibited spleen cell proliferation in response to concanavalin A (Con A), phytohemagglutinin, and pokeweed mitogen. The bone marrow SF exhibited a dose-dependent suppression of the growth of IL-2-dependent T lymphocytes in the presence of IL-2. SF also completely blocked the production or release of IL-2 by Con A-stimulated T cells. Thus, these bone marrow natural suppressor cells produced a soluble factor, which regulated the growth of rapidly proliferating bone marrow cells and also regulated T cell reactivity by modulating IL-2 production and activity.     

Mechanism of lymphocyte activation. II. Requirements for macromolecular synthesis in the production of lymphokines

Reversible inhibitors of protein synthesis, cycloheximide and puromycin, and an irreversible inhibitor of RNA synthesis, actinomycin D, were employed to study the kinetics and types of macromolecular synthetic events required for the production of migration inhibitory factor (MIF) and macrophage activating factor (MAF) by Con A-stimulated lymphocytes. Reversible inhibition of protein synthesis during the first 2 hr of stimulation completely inhibited MIF and MAF production. The same treatment, performed 4 hr after the beginning of the stimulation, had no effect. When the inhibitors of protein synthesis were left in the cultures, a block of lymphokine production was observed when the drugs were added at 6 hr as well as at time 0. In contrast, irreversible inhibition of RNA synthesis at 6 hr was ineffective and only treatment at the beginning of culture blocked lymphokine production. These data suggest that a critical protein is synthesized during the first few hours of stimulation, which is required for subsequent production of lymphokines. After this special early requirement, however, continued protein synthesis is needed for lymphokine production. In contrast, the RNA required for MIF and MAF production seemed to be completely synthesized within 4 to 6 hr of stimulation. The possibility that suppressor macrophages inhibit lymphokine production via modulation of macromolecular synthesis is discussed.     

Suppression of lymphokine production: I. Macrophage-mediated inhibition of MIF production

Macrophages have been found to suppress the in vitro production by stimulated T lymphocytes of a lymphokine, migration inhibitory factor. When macrophages isolated from primary MSV-induced tumors were added to antigen-stimulated MSV-immune spleen cells, a complete suppression of MIF production was observed. This suppression was nonspecific, since MIF production by antigen-stimulated alloimmune spleen cells and by PHA-stimulated normal spleen cells was also inhibited. Suppressor macrophages could also be induced by inoculation with Corynebacterium parvum, whereas light mineral oil-induced peritoneal macrophages had no detectable effect on MIF production. The failure to detect MIF in the supernatants of stimulated cultures containing activated macrophages appeared to be due to inhibition of lymphokine production rather than to absorption or inactivation of MIF or to interference with the assay for detection of MIF. Macrophages were able to suppress MIF production only when added during the first 4–5 hr of culture and they had no effect when added later. These data show that activated macrophages can nonspecifically suppress lymphokine production and that this appears to be due to inhibition of an early step in lymphocyte stimulation.     

Comparative assessment of the properties of a factor inhibiting macrophage migration and interferon]

The authors investigated some functional properties of interferon and the macrophages migration inhibitory factor (MIF) obtained by stimulation of human tonsil lymphocytes with the virus of Newcastle disease (NDV) or O-streptolysin. Both the interferon and MIF inhibited actively the migration of human tonsil cells, but differed by the anti-viral activity, and sensitivity to heating at 56 degrees C for 30 min. Stimulation of human tonsil lymphocytes with NDV leads to production of a more wide range of delayed hypersensitivity mediators than stimulation with O-streptolysin.