Allogeneic recognition and killing capacity of immune macrophages in mixed macrophage cultures (MMC).

Stimulation of DNA and RNA synthesis did not occur in mixed macrophage cultures (MMC) consisting of macrophages growing in different allogeneic combinations, compared with syngeneic cultures. Incubation of immune macrophages with either macrophages bearing those alloantigens used for immunization or unrelated alloantigens led to suppression of ³HTdR incorporation. Specific killing, studied by ⁸⁶Rb uptake, was effected by immune macrophages growing in contact with target macrophages bearing the sensitizing alloantigens. Repeated immunization was found to be important for optimal macrophage cytotoxic capacity. Cell crowding was important for maximum killing effect, and no killing occurred when immune macrophages were separated from the specific allogeneic target cells. Immune spleen cells were capable of arming nonimmune macrophages and rendering them cytotoxic. This suggests that macrophage cytotoxicity may be due to a product(s) derived from lymphocytes and attached to the macrophage surface.     

Immune reactivity in SL2 lymphoma-bearing mice compared with SL2-immunized mice

Summary We have studied the rather paradoxical phenomenon of the growth of an antigenic tumor in an immunocomponent host. This phenomenon was studied by comparing (a) the lymphocyte reactivity and (b) the macrophage cytotoxicity, during SL2 growth in DBA/2 mice (SL2-bearing mice) and in DBA/2 mice immunized against SL2 tumor cells (SL2-immune mice). Immune mice rejected a challenge of tumor cells. The immune T-lymphocytes rendered macrophages cytotoxic (arming) and were able to transfer tumor resistance to naive animals. Nonimmunized mice did not reject a challenge of SL2 cells. In these tumor-bearing mice various forms of immune reactivity were tested. Lymphocytes with the capacity to arm macrophages could not be found in the lymphoid organs. However, lymphocytes isolated from the tissue directly surrounding the subcutaneous SL2 tumor could arm macrophages in vitro.Shortly after subcutaneous tumor grafting cytotoxic macrophages were found in the peritoneal cavity. In the serum macrophage arming factors were detected that rendered macrophages cytotoxic in vitro. This cytotoxicity of the peritoneal macrophages and the presence of macrophage arming factors in the serum showed a similar biphasic pattern. The first phase of cytotoxicity between day 3 and 8 after tumor grafting was tumor (SL2) specific. The second phase from day 12 and onwards was not tumor specific. During the first 4 days after SL2 grafting the DBA/2 mice expressed a specific concomitant immunity to a second tumor graft. Then 7 or more days after grafting the first SL2 tumor, the concomitant immunity was nonspecific as the growth of a second SL2 tumor graft and a L5178Y (DBA/2) tumor graft were inhibited. In addition, the immune suppressive activity of serum and lymphocytes was tested. Neither serum nor lymphocytes from SL2-bearing mice suppressed the macrophage arming capacity of SL2 immune lymphocytes. Lymphocytes from tumor-bearing mice did not inhibit the capacity of SL2-immune lymphocytes to transfer resistance to naive animals. On the contrary, lymphocytes obtained from SL2-bearing mice 14 days after SL2 grafting transfered tumor resistance in a Winn-type assay. These data suggest that the growth of an antigenic tumor is due to the inability of the immune system to mount an effective antitumor effector cell population during tumor growth, rather than an immune suppression of the antitumor reactivity, as a limited immune reactivity could be detected in tumor-bearing mice, whereas immune suppression could not be detected.     

Action of hydrocortisone on the cytotoxic reactions in delayed hypersensitivity to microbial antigens

A study was made of the effect of hydrocortisone (HC) injected to animals with delayed hypersensitivity (DH) to BCG antigens on the cytotoxic activity of lymphocytes and production of lympho- and macrophage toxins. The cytotoxic test with the use of sensitized lymphocytes and preparation of lympho- and macrophage toxins were performed in vitro in the presence of specific microbial antigens. It was shown that HC exerts the most intense inhibitory action on the production of macrophage toxin. High doses of the hormone also inhibited the production of lymphotoxin. At the same time the cytotoxic activity of lymphocytes of the lymph nodes in DH was not inhibited by the employed doses of HC. No reduction was seen either in the sensitivity of autologous adhesive cells (macrophages) used as target cells for studying the cytotoxic activity of lymphocytes.     

Macrophage activation for tumor cytotoxicity: Control of cytotoxic activity by the time interval effector and target cells are exposed to lymphokines

Macrophages continuously exposed to lymphokines (LK) and target cells throughout a 48-hr cytotoxicity assay exhibit 3-fold more tumoricidal activity than do cells optimally treated with LK before addition of tumor cells. Increased cytotoxic activity induced by continuous LK treatment was not due to direct toxic effects of LK on tumor target cells or to alterations in target cell susceptibility to cytopathic effects of LK-activated macrophages. Moreover, sensitivities of responsive macrophages to LK activation signals and time courses for onset and loss of tumoricidal activity during continuous exposure or LK pulse were identical. Analysis of macrophage or LK dose responses and time courses for development of cytotoxicity each suggest that differences in tumoricidal activity between macrophages continuously exposed or pulsed with LK were quantitative: the number of cytotoxic events was increased 2.7 ± 0.2-fold (mean ± SEM for 11 experiments) during continuous LK treatment. Optimal levels of macrophage tumoricidal activity then occur only if effector cells, target cells and activation stimuli are simultaneously present for a defined time interval: tumor cells need not be present during the initial 2 to 3 hr of culture; LK can be removed after 8 hr with little or no loss of cytotoxic activity. However, removal of LK or target cells during the critical 4- to 8-hr interval decreased levels of cytotoxicity 3-fold. Thus, nonspecific effector function by LK-activated macrophages in controlled by both the physicochemical nature of the LK mediator and the time interval effector and target cells are exposed to LK.     

Immunological Properties of TtT/M-87 Cell Line Established from Murine Pituitary Tumor-Associated Macrophages

TtT/M-87 cell is a macrophage cell line established from thyrotropic pituitary tumor tissues in mouse. In this paper, we report the immunological properties of M-87 cells as a model of tumor-associated macrophage. Contrasting with resident peritoneal macrophages, M-87 cells constitutively secreted small but significant amounts of TNF-α and IL-1α, which were detectable in both biological assays (cytotoxic activity for L929 and co-mitogenic activity for Con A-induced T cell proliferation, respectively) and ELISA, and produced larger amounts of these cytokines upon stimulation with LPS. They expressed MHC class II molecules on their cell surface without stimulation by IFN-γ. The accessory or antigen-presenting cell activity in antibody-producing response of spleen lymphocytes to sheep red blood cells was shown to be much higher in M-87 cells than normal peritoneal macrophages. In addition, when normal spleen lymphocytes were cultured with allogeneic tumor cells, such as EL-4 and S-180, in the presence of M-87 cells, lymphocytes reactive to stimulator cells were activated to manifest inhibitory effect on the tumor cell growth and also to manifest specific cytotoxic effect on the allogeneic tumor cells. These results show that M-87 cells derived from tumor-associated tissue are activated macrophages and that they are inhibitory to tumor cell growth and augmentative in the induction of T-cell-mediated immune responses.     

Shark cytotoxic macrophages interact with target membrane amino groups

The types of target structures recognized by cytotoxic macrophages have been described for various microorganisms, but have not been defined for tumor cells. Tumoricidal macrophages are selective in their destructive mechanisms, sparing normal cells while directing their lytic machinery toward neoplastic targets. The cytotoxic activity of macrophages from a primitive vertebrate, the nurse shark, closely resembles the activity of mammalian tumoricidal macrophages. Host defense mechanisms of these animals appear to rely on antigen nonspecific cellular effector systems, and it has been postulated that macrophage-mediated cytotoxicity plays a dominant role in protection during periods of decreased environmental temperatures when lymphocyte responses of poikilothermic vertebrates are compromised. Similar to mammalian tumoricidal macrophages shark macrophages display selective recognition of target cells. Previous studies showed that TNP modification of targets was protective, preventing recognition by the shark spontaneously cytotoxic macrophage. Additionally, it was shown that cytotoxic activity was inhibited in a dose dependent fashion by the addition of excess unlabeled targets. In the present study, similar inhibition experiments with hapten-modified targets have been used to determine the nature of the target structures recognized by the shark cytotoxic macrophage. Cold targets modified with haptens which react covalently with free amino groups on cell membranes, trinitrobenzene sulfonic acid (TNBS) and flourescein isothiocyanate (FITC), are not recognized by the cytotoxic macrophage. The relative amount of membrane bound TNP was correlated with inhibition of cytotoxicity. Conversely, target cells modified with sulfhydryl reacting reagents, N-iodoacetyl-N'-(5-sulfonic-1-naphthyl) ethylene diamine and dithionicotinic acid, are recognized similarly to untreated targets. Moreover, TNP-containing lipids, permitted to diffuse into target membranes without covalent binding, do not alter target recognition, indicating that TNP itself has no effect on macrophage:target interaction. From these data, it is concluded that the shark cytotoxic macrophage interacts with membrane bound amino, but not sulfhydryl groups. The ability to distinguish between membrane structures may have appeared early in evolution as a means of preserving self cells while retaining protective nonspecific cytotoxic mechanisms.     

The role of host lymphocytes and host macrophages in antitumor reactions after injection of sensitized lymphocytes and tumor target cells into naive mice

Summary DBA/2 mice were immunized i.p. against syngeneic SL2 lymphosarcoma cells. At various days after the last immunization peritoneal and spleen lymphocytes were collected. The lymphocyte suspensions were enriched for T-cells by nylon wool filtration.The peritoneal T-cells from immunized mice (a) expressed direct specific antitumor cytotoxicity in vitro, (b) induced macrophage cytotoxicity in vitro, and (c) exerted tumor neutralization measured in a Winn-type assay. Spleen T-cells from these immunized mice (a) expressed no direct specific antitumor cytotoxicity in vitro, (b) only induced moderate macrophage cytotoxicity in vitro, but (c) exerted tumor neutralization in a Winn assay.For effective tumor neutralization in vivo effector target cell ratios of 1000:1 were required. When the effector/target ratio of 1000:1 was maintained but the absolute numbers of effector and target cells were lowered from 10⁶ to 10⁵ lymphocytes and 10³ to 10² target cells respectively, no tumor neutralization was obtained.The major effect of the sensitized-transferred T-lymphocytes seemed to be the induction of cytotoxic macrophages in the (naive) recipient mice, as the peritoneal macrophages collected from the recipient mice 7 days after i.p. injection of a mixture of sensitized T-cells and tumor cells were cytotoxic. Purified peritoneal T-lymphocytes collected from these recipient mice were able to induce macrophage cytotoxicity in vitro but expressed no cytotoxic T-cell activity.In conclusion, our results show that in the tumor system used, tumor neutralization after transfer of sensitized lymphocytes is not dependent on the presence of cytotoxic T-lymphocytes. Lymphocytes with the strongest potency to render macrophages cytotoxic (in vitro and in vivo) also induce the best tumor neutralization in vivo, suggesting an important role for host macrophages as antitumor effector cells.     

Macrophage T lymphocyte interactions in the anti-tumor immune response: a mathematical model

In this paper we present a model of the macrophage T lymphocyte interactions that generate an anti-tumor immune response. The model specifies i) induction of cytotoxic T lymphocytes, ii) antigen presentation by macrophages, which leads to iii) activation of helper T cells, and iv) production of lymphoid factors, which induce a) cytotoxic macrophages, b) T lymphocyte proliferation, and c) an inflammation reaction. Tumor escape mechanisms (suppression, antigenic heterogeneity) have been deliberately omitted from the model. This research combines hitherto unrelated or even contradictory data within the range of behavior of one model. In the model behavior, helper T cells play a crucial role: Tumors that differ minimally in antigenicity (i.e., helper reactivity) can differ markedly in rejectability. Immunization yields protection against tumor doses that would otherwise be lethal, because it increases the number of helper T cells. The magnitude of the cytotoxic effector cell response depends on the time at which helper T cells become activated: early helper activity steeply increases the magnitude of the immune response. The type of cytotoxic effector cells that eradicates the tumor depends on tumor antigenicity: lowly antigenic tumors are attacked mainly by macrophages, whereas large highly antigenic tumors can be eradicated by cytotoxic T lymphocytes only.     

Cytotoxic activity against maedi-visna virus-infected macrophages.

The cell type predominantly infected by maedi-visna virus (MVV) is the macrophage, and we have looked at the ability of MVV-infected macrophages to interact with cytotoxic T lymphocytes (CTL), important effector cells against virus infections. MVV-specific CTL precursors were detected, after in vitro culture with MVV antigen and recombinant human interleukin-2, in peripheral blood lymphocytes of all MVV-infected sheep. MVV-infected monocyte-derived macrophages and alveolar macrophages were able to stimulate CTL activity in vitro and were targets for these activated CTL. The major effector cell population using MVV-infected macrophage targets was CD8+ lymphocytes, although another population, lymphokine-activated killer cells, may also have been involved. There was no direct cytotoxic activity found in alveolar lymphocytes from MVV-infected sheep without lung lesions.     

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.     

Peroxidases enhance macrophage-mediated cytotoxicity via induction of tumor necrosis factor

Tumor necrosis factor (TNF) is a monokine which is involved in macrophage-mediated cytotoxicity (MMC). We have previously reported that peroxidases can activate thioglycollate-induced macrophages to the tumoricidal state in vitro. The present study was undertaken in an attempt to correlate peroxidase-induced MMC with production of TNF. Horseradish peroxidase (HRP) was used as the principal model for these studies. Resident and thioglycollate-induced macrophages exposed to peroxidases were examined for both MMC against 3T12 cells and production of TNF. Thioglycollate-induced macrophages exposed to HRP, bovine lactoperoxidase, or human myeloperoxidase demonstrated enhanced secretion of TNF. When exposed to HRP, both resident and thioglycollate-induced macrophages secreted significant amounts of TNF and acquired the ability to lyse 3T12 cells. However, resident macrophages were considerably less efficient in both their cytotoxic activity and TNF secretion. Macrophage-mediated cytotoxicity was eliminated by the addition of specific antisera to TNF. In addition, replacement of culture supernatants within 24 hr after exposure of the macrophages to HRP increased tumor cell killing in the absence of additional detectable TNF production, suggesting that other factors may be involved in peroxidase-induced MMC. These results indicate that TNF is intimately associated with peroxidase-induced MMC and suggest a possible role for peroxidases as immunomodulators via augmentation of macrophage capacities and functions.     

Multiple effector roles of lymphocytes in allograft immunity

Several classes of cytotoxic lymphoid cells were detected in the spleens of mice immunized with allogeneic lymphoma cells. Two types of radioresistant cells (retaining cytotoxicity after exposure to 1000 R x-rays) were detected 7 days after immunization with allogeneic cells, one a T-cell independent antibody-secreting cell type, the other T-cell dependent, directly cytotoxic and complement-independent in action. At 21 days after immunization only directly cytotoxic thymus dependent cells were found. These cells were radiosensitive (cytotoxicity ablated by 500 R x-rays), although after contact with specific antigen they were changed into a more radioresistant state. Sensitized lymphoid cells capable of rendering normal macrophages specifically cytotoxic to target cells were also found to be of T-cell origin. Immune cells which are directly cytotoxic and those which release the specific macrophage arming factor (SMAF) may differ, although both are thymus-derived and both respond biochemically to the specific antigen.     

Functional heterogeneity among peritoneal macrophages: I. Effector cell activity of macrophages against syngeneic and xenogeneic tumor cells

Peritoneal exudate cells from immunized and nonimmunized animals were separated into subpopulations by centrifugation on discontinuous bovine serum albumin (BSA) density gradients. Cells in the several subpopulations were then tested for their cytostatic or cytotoxic activity against syngeneic and xenogeneic tumor cells. Nonimmune macrophages isolated at the 8 to 11% BSA interface were highly inhibitory to the growth of syngeneic and xenogeneic tumor cells during coculture for 24 to 48 hr. A second macrophage subpopulation of heavier density was not as effective in preventing tumor growth and frequently augmented it. Cytotoxic activity against (C58NT) D tumor cells could not be detected with macrophages or subpopulations of macrophages from immune as well as nonimmune animals, as determined by a 4-hr chromium release assay. The cytotoxic activity of the immune peritoneal exudate cells observed by this assay could be accounted for by the small percentage of lymphocytes present.     

Differences in the tumor necrosis factor-alpha-mediated lysis by fixed natural cytotoxic cells and fixed cytotoxic macrophages

TNF-alpha has been shown to be associated with macrophage cell membranes in such a way as to retain cytolytic activity despite fixation of the macrophage effector cells with paraformaldehyde. In this paper we report that, similar to cytotoxic macrophages, natural cytotoxic (NC) cells also use cell-associated TNF to lyse sensitive target cells. However, in contrast to fixed cytotoxic macrophages, NC cells do not retain cytolytic activity after fixation with paraformaldehyde. Additionally, the cytolytic activity of paraformaldehyde-fixed NC cells is not increased by incubation with LPS or by incubation with rTNF before fixation. Western blot analysis indicates that, unlike macrophages, NC cells use a smaller (17 kDa) constitutively active form of TNF. These results indicate that, although both macrophages and NC cells use effector cell-associated TNF to mediate lysis of sensitive targets, the way in which TNF is associated with these two types of effector cells must be different.     

Analysis of therapeutic effect in experimental chemoimmunotherapy for rat ascites tumor

Summary The lyophilized, squalene-treated Nocardia rubra cell wall skeleton (N-CWS) was confirmed to produce tumoricidal peritoneal macrophages resulting in inhibition of tumor growth when injected locally into the syngeneic ascites fibrosarcoma, AMC 60 in ACI/N rats. Furthermore, N-CWS was found to augment therapeutic effect when administered repeatedly after a single local injection of mitomycin-C (MMC). To analyze the effects, various in vitro cytolysis assays were performed using N-CWS-activated peritoneal macrophages. When tumor target cells were exposed in vitro to MMC, the resulting cytolysis in the presence of N-CWS-activated macrophages was similar to cytolysis of intact target cells. On the other hand, when N-CWS-activated macrophages were exposed to MMC, the tumoricidal activity was lost significantly, depending on exposure to MMC. When tumor target cells and N-CWS-activated macrophages were simultaneously exposed to MMC, tumor-cell cytolysis was strikingly depressed. In the final experiment, combined injection of MMC and N-CWS into the ascites tumor resulted in remarkable increases not only in peritoneal exudate cell number, but also in in vitro tumoricidal activity of peritoneal macrophages as compared to those induced by either agent alone. In addition, the production of tumoricidal macrophages by IP injection of MMC alone was also noticeable, as described previously. These results possibly indicate the involvement of macrophage activation in induction of therapeutic effect in chemoimmunotherapy.This work was supported in part by grants from the Ministry of Health and Welfare, and the Ministry of Education, Science and Culture     

Use of peritoneal macrophages labeled with Cr51 and cultivated in vitro as target cells for quantitative assessment of the cytotoxic activity of immune T-lymphocytes]

Peritoneal macrophages previously labeled in a suspension with 51Cr and grown in the form of a discontinuous monolayer on glass, pretreated with poly-l-lysin were used as target cells. This permitted to estimate the cytotoxic activity of immune lymphocytes by 51Cr release for the period of 4 and 20 hours of incubation with the target. 51Cr release from such a target incubated with normal lymphocytes for 20 hours did not exceed 10-20% of the maximum release. Application of a 2% solution of sodium dodecylsulfate ensured a 100 per cent solubilization of labeled macrophages growing on the glass surface, and permitted the cytotoxic effect to be determined by measuring the label remaining in the intact cells.     

Two specific T cell factors that initiate immune responses in murine allograft systems. A comparison of biologic functions

It has been suggested that Ag-specific T cell factors play a role in the early phase of cellular immune responses. Two of these factors are studied in this paper. The first factor is specific macrophage arming factor (SMAF), that binds to (arms) macrophages and renders them specifically cytotoxic against tumor cells. The second factor is involved in the induction of an early (2 h) mast cell-dependent hypersensitivity reaction, that precedes the delayed-type hypersensitivity response (mast cell arming T cell factor; MTCF). In this study we compare both factors in an allogeneic murine tumor system (C57BL (H-2b) mice sensitized against SL2 (H-2d) lymphoma cells), both factors were: 1) dependent on T lymphocytes for their production, 2) detectable in serum 2 to 3 days after immunization, and 3) MHC (H-2)-Ag specific. Immunochemical studies showed that both factors have a molecular mass between 45 and 90 kDa and bind to the mAb 14-30 (directed against specific T cell factors), but not to anti-kappa/lambda L chain antibodies. Furthermore, it was shown that SMAF produced in vitro could induce a mast cell-dependent early 2-h hypersensitivity reaction against SL2 tumor cells, and resembled in this way MTCF. We concluded that the biologic activities and immunochemical characteristics of SMAF and MTCF are similar. Both factors are produced during the early stages of the immune response and seem to play a role in the initiation of the cell-mediated immune response.     

B cell stimulatory factor-1 (interleukin 4) activates macrophages for increased tumoricidal activity and expression of Ia antigens

Macrophages are activated by lymphokines (LK) to kill tumor cell and microbial targets. Interferon-gamma (IFN) is the major LK activity in conventional, antigen or mitogen-stimulated spleen cell culture fluids for induction of these macrophage effector functions. In view of the recent demonstration that murine macrophage-like cell lines have receptors for B cell stimulatory factor-1/interleukin 4 (BSF-1), a possible role for BSF-1 in regulation of macrophage function was considered. In this communication, thioglycollate-elicited murine peritoneal macrophages were shown to express about 2300 high affinity (Ka approximately 2 X 10(10) M-1) BSF-1 receptors/cell. Peritoneal macrophages treated with purified, T cell-derived BSF-1 developed potent tumoricidal activity against fibrosarcoma target cells. The concentration of BSF-1 that induced 50% of maximal tumor cytotoxicity was 38 +/- 4 U/ml for seven experiments; similar dose-responses were observed with recombinant BSF-1. That BSF-1 dose-responses for induction of macrophage-mediated tumor cytotoxicity were not affected by 5 micrograms/ml polymyxin B suggested that contaminant endotoxins played little or no role in cytotoxic activity. BSF-1 alone (less than or equal to 500 U/ml) was not directly toxic to tumor cells or macrophages. Macrophage tumoricidal activity induced by BSF-1 but not by IFN was inhibited greater than or equal to 90% with monoclonal anti-BSF-1 antibody. BSF-1 induced Ia antigen expression on peritoneal macrophages and increased (twofold to threefold) FcR(II)-dependent binding of murine IgG immune complexes to bone marrow-derived macrophages (greater than 98% macrophages). Based on these findings, it was concluded that BSF-1 is a potent macrophage activation factor.     

Leishmania enriettii: Immune induction of macrophage activation in an experimental model of immunoprophylaxis in the mouse

This study describes some of the parameters of the cellular immune response elicited in mice by inoculation of the nonpathogenic protozoan parasite, Leishmania enriettii. Incubation in vitro of leishmania-infected mouse peritoneal macrophages with spleen cells from syngeneic leishmania-immune animals resulted in activation of the phagocytes, leading to intracellular parasite destruction. Activation required interaction of sensitized lymphocytes with parasite antigen released or displayed by infected macrophages. The effect was dependent both on the dose of parasites used for in vivo priming and on the number of spleen cells cocultivated with parasitized macrophages. The activating capacity of lymphocytes was abrogated by anti-Thy-1 antiserum treatment and was retained in the effluent cells after nylon-wool separation. Activation was followed by lysis of part of the macrophage monolayer. Destruction of the phagocytes did not appear to result from the activation process per se and may represent a cytotoxic activity of sensitized lymphocytes for macrophages bearing parasite antigen on their surface.     

Granules of human CD3+ large granular lymphocytes contain a macrophage regulating factor(s) that induces macrophage H2O2 production and tumoricidal activity but decreases cell surface Ia antigen expression.

CTL (cytotoxic T lymphocytes) and LGL (large granular lymphocytes) exocytose cytoplasmic granules on activation after recognition of their target, releasing granule-associated molecules. We have previously suggested that this process could release immunoregulatory molecules. In this study we investigated whether normal human LGL granules contained a factor regulating different macrophage activity. Human CD3+ LGL cells were generated by activating peripheral blood lymphocytes (PBL) for 10-12 days with recombinant human IL-2 (rhIL-2), and granules were isolated from disrupted cell homogenate by Percoll gradient fractionation. Solubilized granules were tested for macrophage-activating factor (MAF) activity in three different macrophage assays. When M-CSF-differentiated murine bone marrow-derived macrophages were incubated 9 hr with human LGL granules, they were fully activated to lyse the TNF-resistant P815 tumor cells. The granule-MAF showed a synergistic effect with rhIL-1 beta, rmTNF-alpha, and rmIFN-tau in the cytolytic assay. In addition, proteose-peptone-elicited murine peritoneal macrophages profoundly increased H2O2 production after activation with human LGL granules. However, unlike IFN-tau, no increase in peritoneal macrophage Ia antigen expression was detected after incubation with granules. Moreover, granule-MAF suppressed Ia induction by IFN-tau. These results confirm that human CD3+ LGL granules contain a molecule(s) capable of regulating macrophage function.