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.     

Alloantibody-induced cytotoxicity of macrophages.

Alloantibodies substantially alter the in vitro nonspecific cytotoxic effect of macrophages on bystanding allogeneic and xenogeneic target cells. Although the specific IgM alloantibody increased significantly the ability to parental macrophages to damage target cells, IgG alloantibody had an opposite effect and suppressed the macrophage cytotoxicity. Macrophages of F1 hybrid mice were less affected by this treatment unless alloantibodies against both parental strains were added together. Parental macrophages exposed in vitro to the concomitant action of both IgM and IgG alloantibodies exhibited a diminished cytotoxicity toward target cells. It is proposed that IgM and IgG alloantibodies induce different conformational changes of the macrophage surface.     

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.     

Promonocytes have the functional characteristics of natural killer cells.

Promonocytes isolated from a 5-day-old L-fibroblast-conditioned liquid bone marrow culture show strong NK cell cytotoxicity. They kill YAC target cells in a short-term 125IUDR-release assay whereas P815 targets are unaffected. This NK-like cytotoxicity is enhanced in the presence of interferon preparations. Morphologically, these promonocytes resemble a medium size lymphocyte with a high nucleus to cytoplasma ratio, they are nonadherent, nonphagocytic, and negative in nonspecific esterase staining. Promonocytes are precursor cells from macrophages, which have not yet developed the typical macrophage criteria. Within 24 to 48 hr they mature to adherent macrophages. We have shown previously, that the same promonocytes have the capacity to perform K cell killing of antibody-coated tumor target cells. The cytotoxic effector functions of promonocytes are abolished when the cells are treated with the alloantimacrophage serum Mphi 1.2 plus rabbit C. The relationship or similarity between K cells, NK cells and promonocytes is discussed.     

IFN-gamma differentially modulates the susceptibility of L1210 and P815 tumor targets for macrophage-mediated cytotoxicity. Role of macrophage-target interaction coupled to nitric oxide generation, but independent of tumor necrosis factor production

IFN-gamma primes murine macrophages to render them responsive for triggering by subactivating concentrations of bacterial LPS to mediate nonspecific tumor cytotoxicity. However, IFN-gamma also has direct anti-proliferative effects on transformed cells that serve as sensitive tumor targets for cytotoxic macrophages. We investigated the effects of preexposure of L1210 mouse leukemia and P815 mouse mastocytoma targets to rIFN-gamma on changes in their susceptibility to cytotoxicity by LPS-activated mouse peritoneal macrophages (PM). Co-incubation of inflammatory PM and either L1210 or P815 targets with IFN-gamma and LPS produced a classical synergistic cytotoxicity for both targets over that of IFN-gamma or LPS alone. Similar synergistic augmentation of cytotoxicity occurred when effector PM were preprimed for 24 h with IFN-gamma before testing for cytotoxicity of untreated targets. However, pretreatment of L1210 and P815 targets for 24 h with IFN-gamma (50 U) before assay produced divergent results in that L1210 was more susceptible, whereas P815 was less susceptible to cytotoxicity by LPS-activated macrophages. Similar results were obtained when both macrophages and targets were pretreated separately with IFN-gamma for 24 h before their combined assay for tumor cytotoxicity. Pretreatment of L1210 targets for 1, 4, or 24 h with IFN-gamma produced similar effects on their increased susceptibility to macrophage cytotoxicity. In contrast, P815 pretreated for 1 and 4 h with IFN-gamma showed an early increased susceptibility to macrophage cytotoxicity followed by a decrease after 24 h pretreatment. The pretreatment of L1210 or P815 targets with IFN-gamma before their exposure to LPS-activated macrophages had no effect on the production of TNF. However, there was a corresponding increase in nitric oxide generation by LPS-activated macrophages after their exposure to IFN-gamma pretreated L1210 targets and a decrease in the presence of IFN-gamma-pretreated P815 targets that correlated with their changes in susceptibility to macrophage killing. Nitric oxide generation by macrophages alone in response to LPS was found to be greater than when effector macrophages were exposed to the tumor targets and this was either increased by L1210 or decreased by P815 that had been pretreated with IFN-gamma. Our results indicate that IFN-gamma may act directly and differentially on tumor targets to alter their susceptibility for macrophage cytotoxicity, which was coupled to changes in the generation of cytotoxic nitric oxide, rather than TNF production by the macrophage.(ABSTRACT TRUNCATED AT 400 WORDS)     

Macrophages as effector cells of protective immunity in murine schistosomiasis: IV. Coincident induction of macrophage activation for extracellular killing of schistosomula and tumor cells

Peritoneal macrophages from Schistosoma mansoni-infected mice are activated both for nonspecific tumor cytotoxicity and for killing of skin-stage schistosomula in vitro. In the current study, mechanisms for induction of macrophage tumoricidal and schistosomulacidal activity have been compared. Examination of macrophages activated in vivo by BCG infection or C. parvum treatment, or in vitro by exposure to lymphokine prepared from antigen-stimulated BCG-immune spleen cells, showed that these effector functions were closely linked. Indeed, fractionation of lymphokine-rich supernatant fluids by Sephadex G-100 gel filtraction showed that activities responsible for induction of schistomula killing by inflammatory macrophages and for induction of tumoricidal activity cochromatographed as a single peak in the 50,000 MW region. Thus, development of macrophage-mediated cytotoxicity against these two extracellular (tumor cell or helminth) targets was coincident in several cell populations activated in vivo or in vitro. However, activation for tumoricidal and schistosomulacidal capacity appeared to be quantitatively dissociated in macrophages from mice with chronic schistosomiasis; those cells demonstrated low, yet significant, levels of larval killing ($\text{1}\text{3}$ to $\text{1}\text{5}$ those of BCG or lymphokine-activated cells) but maximal levels of tumor cell cytotoxicity. Furthermore, cytotoxicity by peritoneal cells from S. mansoni-infected mice was not increased in vitro by exposure to lymphokine. Identification of this functional alteration in S. mansoni-activated cells may help to clarify the role of macrophages in the partial immunity against challenge infection which is demonstrated by mice with chronic primary S. mansoni infection.     

L-arginine independent macrophage tumor cytotoxicity

We have investigated the role of L-arginine in macrophage tumor cytotoxicity in coculture. L929, EMT-6, MCA-26, and P815 targets were all susceptible to cytolysis by activated macrophages when cocultured in medium containing L-arginine. When cocultured in arginine-free medium, these targets displayed comparable or even higher levels of lysis. L1210 targets were lytically resistant under either condition. However, 59Fe release from this target did reflect strong dependence on the presence of arginine. The structural analogue, NG-monomethyl-L-arginine, was an effective inhibitor of iron-release from L1210 targets cocultured with activated macrophages, whereas it had minimal inhibitory effects on release of 51Cr from cocultured L929 cells. These results suggest that the L-arginine requiring cytotoxic pathway of activated macrophage is independent of major effector mechanisms involved in tumor cell lysis.     

Role of tumor-derived cytokines on the immune system of mice bearing a mammary adenocarcinoma. II. Down-regulation of macrophage-mediated cytotoxicity by tumor-derived granulocyte-macrophage colony-stimulating factor

Peritoneal elicited macrophages (PEM) from mammary tumor-bearing mice have a decreased capacity to become cytotoxic against syngeneic, allogeneic, and xenogeneic target cells upon in vitro stimulation with LPS, as compared with PEM of normal mice. A regulatory mechanism other than PG release is suggested because the addition of both indomethacin and LPS to macrophage cultures from tumor-bearing mice caused no changes in their cytotoxic capability. Because tumor products have been implicated in the down-regulation of immune responses, we investigated whether pretreatment with supernatants from the tumor cell line DA-3, derived from the in vivo mammary adenocarcinoma D1-DMBA-3, affects the cytolytic capacity of macrophages. This treatment inhibits, in a dose-dependent fashion, the ability of stimulated normal PEM to kill target cells. Partial purification of DA-3 cell line supernatant showed that most of the inhibitory activity was exerted by factors with a molecular mass greater than 10 kDa and less than 30 kDa. However, slight inhibition could also be observed with fractions containing molecules less than 10 kDa. The data suggest that more than one factor released by the mammary tumor cells may be involved in the down-regulation of macrophage-mediated cytotoxicity. Because the DA-3 cells constitutively produce granulocyte-macrophage CSF (GM-CSF), which has a molecular mass of 27 kDa, we pretreated PEM from normal mice in vitro with rGM-CSF for 24 h. This resulted in a dose-dependent decrease in their capacity to kill tumor target cells upon LPS stimulation. Furthermore, PEM from normal mice injected with rGM-CSF for 25 days displayed a profound decrease in their cytolytic ability against DA-3 targets upon in vitro stimulation with increasing amounts of LPS. The pretreatment of PEM from normal mice with a combination of DA-3 cell supernatants and specific anti-GM-CSF partially neutralized the inhibitory effect of the DA-3 supernatant on macrophage tumoricidal capability. These results indicate that tumor-derived GM-CSF is an important factor involved in the decreased macrophage cytotoxicity during mammary adenocarcinoma progression.     

IL-4 inhibits the costimulatory activity of IL-2 or picolinic acid but not of lipopolysaccharide on IFN-gamma-treated macrophages

We reported previously that IL-2 induces tumoricidal activity in IFN-gamma-treated murine macrophages. The present study was performed to investigate the regulation of IL-2-dependent tumoricidal activity in murine macrophage cell lines. The v-raf/v-myc-immortalized murine macrophage cell lines ANA-1, GG2EE, and HEN-CV did not express constitutive levels of cytotoxic activity against P815 mastocytoma cells. Moreover, these macrophage cell lines did not become tumoricidal after exposure to IL-4, IFN-gamma, IL-2 or LPS. However, these macrophages developed cytotoxic capabilities after incubation with either IFN-gamma plus IL-2 or IFN-gamma plus LPS. IL-4 inhibited IFN-gamma plus IL-2- but not IFN-gamma plus LPS-induced tumoricidal activity. This effect of IL-4 was not restricted to v-raf/v-myc-immortalized macrophage cell lines because similar results were obtained by using a macrophage cell line that was established from a spontaneous histiocytic sarcoma. The suppressive activity of IL-4 on the ANA-1 macrophage cell line was dose-dependent (approximately 12-200 U/ml) and was neutralized by the addition of anti-IL-4 mAb. IL-4 decreased the IFN-gamma-induced expression of mRNA for the p55 (alpha) subunit of the IL-2R in ANA-1 macrophages. Therefore, at least one mechanism by which IL-4 may have inhibited IFN-gamma plus IL-2-induced tumoricidal activity was by reducing macrophage IL-2R alpha mRNA expression. We have previously reported that picolinic acid, a tryptophan metabolite, is a costimulator of macrophage tumoricidal activity. We now report that IL-4 also inhibited IFN-gamma plus picolinic acid-induced cytotoxicity in ANA-1 macrophages. We propose that IL-2 and picolinic acid may have a common mechanism of action that is susceptible to IL-4 suppression.     

In vitro induction of polyclonal killer T cells with 2-mercaptoethanol and the essential role of macrophages in this process.

Killer T cells against allogeneic and syngeneic tumor cells were generated in vitro by the addition of 2-mercaptoethanol (2-ME) to the murine spleen cell culture in the absence of any antigenic stimulation. The maximum activity of T cell-mediated cytotoxicity (CMC) induced with 2-ME was observed on day 4 of culture and the induction of CMC was completely inhibited by the addition of inhibitor of DNA synthesis, hydroxyurea, or cytosin arabinoside. CMC induced with 2-ME was specifically inhibited by the addition of unlabeled target cells to the 51Cr-release assay system. These results indicated that killer T cells were generated in the presence of 2-ME as a result of nonspecific polyclonal activation of precursors into cytotoxic effector cells and that they recognized target cells with antigen-specific recognition receptors. Spleen cells deprived of adherent cells showed impaired induction of CMC with 2-ME. The addition of peritoneal exudate macrophages to splenic T cells restored this response. The result indicated that macrophages were essential for the induction of CMC with 2-ME. The possibility that the function of macrophages was mediated by soluble factor(s) released from macrophages was demonstrated by the separate culture of splenic T cells and macrophages in double-chambered, Marbrook-type vessels and by the addition of supernatants from macrophage cultures to splenic T cells. 2-ME and soluble factor(s) released from macrophages seemed to be required for the activation of precursors into killer cells.     

Mechanism and specificity of macrophage-mediated cytotoxity.

The cytotoxic effect of macrophages derived from alloimmunized mice (immune macrophages) was found to be immunologically specific. The immune macrophages killed only target macrophages carrying the alloantigens used for immunization in mixed macrophage cultures (MMC) under optimal conditions of contact between effector and target cells. T-sensitized lymphocytes, but not B cells, were capable of arming nonimmune macrophages and conferring upon them cytotoxic activity; the arming factor, which seemed to be a T mediator or T-cell receptor (membrane component) was removable by trypsin. Frequent rinsing or addition of hydrocortisone significantly decreased the cytotoxicity of the MMC. Pretreatment of peritoneal cells with anti-θ antisera and complement markedly decreased immune macrophage cytotoxic activity. It is suggested that the presence of a very small number of T-sensitized lymphocytes is required for strong cytotoxic activity to be manifested by the macrophages.     

Differential susceptibility of activated macrophage cytotoxic effector reactions to the suppressive effects of transforming growth factor-beta 1

We examined the effects of TGF-beta 1 on induction of several activated macrophage antimicrobial activities against the protozoan parasite Leishmania, and on induction of tumoricidal activity against the fibrosarcoma tumor target 1023. TGF-beta by itself did not affect the viability of either the intracellular or extracellular target in concentrations up to 200 ng/ml. As little as 1 ng/ml TGF-beta, however, suppressed more than 70% of the intracellular killing activity of macrophages treated with lymphokines. In contrast, more than 100 ng/ml TGF-beta was required to suppress intracellular killing by cells activated with an equivalent amount of recombinant IFN-gamma. Addition of TGF-beta for up to 30 min after exposure to activation factors significantly reduced macrophage killing of intracellular parasites. Pretreatment of macrophages with TGF-beta was even more effective: treatment of cells with TGF-beta for 4 h before addition of activation factors abolished all macrophage intracellular killing activity. Regardless of treatment sequence, however, TGF-beta had absolutely no effect, at any concentration tested, on activated macrophage resistance to infection induced by lymphokines or by the cooperative interaction of IFN-gamma and IL-4. Effects of TGF-beta on tumoricidal activity of activated macrophages was intermediate to that of its effects on intracellular killing or resistance to infection. Lymphokine-induced tumor cytotoxicity was marginally (25%) affected by TGF-beta; 200 ng/ml was able to suppress IFN-gamma-induced tumoricidal activity by 40%. Thus, TGF-beta dramatically suppressed certain activated macrophage cytotoxic effector reactions, but was only partially or not at all effective against others, even when the same activation agent (IFN-gamma) was used. The biochemical target for TGF-beta suppressive activity in these reactions may be the pathway for nitric oxide production from L-arginine, because TGF-beta also inhibited the generation of nitric oxide by cytokine-activated macrophages.     

Induction of cell-mediated cytotoxicity by shark 19S IgM

Plasma from unimmunized nurse sharks can mediate a reaction similar to antibody-dependent cell-mediated cytotoxicity (ADCC). Normal shark plasma contains numerous natural antibodies reactive with a variety of antigens, including the target employed. Adsorption of plasma with target cells removed a significant amount of activity, suggesting involvement of antibody. Purified 19s IgM was shown to be a component of shark plasma capable of inducing cytotoxicity. These cytotoxic reactions differ from observations in homeothermic vertebrates in that shark immunoglobulin appears to bind more avidly to the effector cells than to the targets. The effector leukocytes are glass adherent, but not susceptible to carbonyl iron treatment, which clearly separates them from the phagocytic effectors of spontaneous cytotoxicity. Thus, the shark possesses leukocytes with the capability of mediating an ADCC-like reaction. These leukocytes, in concert with those mediating spontaneous cytotoxicity, could provide the shark with an effective immunosurveillance system. These data also indicate that ADCC mechanisms, with IgM as the primary effector molecule, appeared early in evolution.     

Defective tumoricidal capacity of macrophages from A/J mice. I. Characterization of the macrophage cytotoxic defect after in vivo and in vitro activation stimuli.

Macrophages from A/J mice fail to develop tumoricidal activity after any of several in vivo or in vitro treatments that activate cells from C3H/HeN mice. Peritoneal macrophages from A/J mice treated i.p. with viable Mycobacterium bovis, strain BCG, killed Corynebacterium parvum, or pyran copolymer fail to develop in vitro tumoricidal activity; varying the numbers of macrophages from treated mice added to target cells, or the dose and time of treatment, or the treatment schedule of these in vivo activation stimuli did not evoke cytotoxic activity. Moreover, cytotoxic activity by macrophages from A/J mice was not observed with any of four target cell lines derived from three different mouse strains. In vitro treatment of peritoneal exudate macrophages from A/J mice with lymphokine-rich supernatants, bacterial endotoxins, or T cell mitogens was also ineffective; varying the numbers of treated macrophages added to target cells, the dose of in vitro activation stimuli, or the time of treatment did not evoke cytotoxic activity. Thus, A/J mice exhibit a profound defect in macrophage tumoricidal capacity to both in vivo and in vitro activation stimuli over a wide range of experimental conditions.     

Tumor target-derived soluble factor synergizes with IFN-gamma and IL-2 to activate macrophages for tumor necrosis factor and nitric oxide production to mediate cytotoxicity of the same target.

Inflammatory mouse peritoneal macrophages were activated by IFN-gamma in synergy with IL-2 or Lipid A to mediate TNF production for autocrine generation of cytotoxic nitric oxide (NO) to kill P815 or L1210 tumor targets. It was determined that for IL-2, but not Lipid A, to effectively trigger activation of IFN-gamma-primed macrophages, the tumor targets must be also present for interaction with effector macrophages to mediate the production of TNF and NO. IFN-gamma- and IL-2-activated macrophages from syngeneic DBA/2 and allogeneic C3H mice had identical MHC-unrestricted requirements for interaction with DBA/2 mouse-derived P815 and L1210 targets to mediate production of TNF and NO for tumor cytotoxicity. To further define the mechanistic requirements for macrophage-tumor target interaction, IFN-gamma- and IL-2-activated macrophages were separated from P815 targets in culture by a semipermeable membrane. Under these conditions, both TNF and NO were produced by the macrophage, which indicated that the requirement for tumor target-macrophage interaction may be due to a soluble factor produced by the target rather than to direct physical contact. This was confirmed by experiments in which 24-h cell-free culture fluids, derived from either P815 or L1210 tumor targets, substituted for the intact tumor cells in the stimulation of TNF mRNA synthesis and secretion with NO generation of TNF mRNA synthesis and secretion with NO generation by IFN-gamma- and IL-2-activated C3H or DBA/2 macrophages. The activity in 24-h culture fluids derived from P815 and L1210 tumor targets was tentatively designated as tumor-derived recognition factor(s) (TDRF) since it was produced constitutively by the tumor targets and synergized with IFN-gamma and IL-2 to induce macrophage production of TNF and NO for death of the same targets. A variety of nontransformed human and mouse fibroblasts, mouse spleen lymphocytes, and two adherent mouse fibrosarcomas did not produce detectable TDRF activity, whereas two mouse T lymphomas, EL4 and EL4.IL-2, produced TDRF activity similar to L1210 mouse leukemia and P815 mastocytoma. The C3H/MCA, a TDRF-nonproducing mouse fibrosarcoma, was susceptible to cytotoxicity mediated by macrophages activated by IFN-gamma and Lipid A, but not by IL-2 triggering. Exogenous TDRF derived from L1210 targets reconstituted the cytotoxic activity for C3H/MCA MCA targets mediated by IFN-gamma- and IL-2-activated macrophages accompanied by the production of TNF and cytotoxic NO.(ABSTRACT TRUNCATED AT 400 WORDS)     

Synergy between subpopulations of normal mouse spleen cells in the in vitro generation of cell-mediated cytotoxicity specific for "modified self" antigens.

Responding lymphoid cells cultured in vitro with irradiated trinotrophenyl (TNP)-modified syngeneic spleen cells develop direct cell-mediated cytotoxicity which is specific for target cells bearing both the TNP moiety and histocompatibility determinants of the modified sensitizing cell. Two subpopulations of normal mouse spleen cells have been shown to synergize in the in vitro generation of specific cell-mediated cytotoxicity to these "modified self" antigens. The synergizing populations are nylon wool column-adherent and column-nonadherent fractions of normal mouse spleen. When mixtures of these two cell populations are cultured in vitro with irradiated TNP-modified syngeneic spleen cells, greater cytotoxicity is generated in the two populations sensitized separately. The synergizing cell in the column-adherent population is resistant to lysis by rabbit anti-mouse brain serum, is distinct from the cytotoxic effector T lymphocyte, and is unresponsive to phytohemagglutinin; its synergizing function could not be replaced by peritoneal cells. These results suggest that it is a non-T cell which may be distinct from the macrophage.     

Effects of L2C leukemia on macrophage-mediated responses

Summary Preliminary experiments have suggested that guinea pig L₂C B-cell leukemia cells were able to evade macrophage-mediated lysis. To determine whether the L₂C cells were resistant to macrophage cytotoxic activity or whether factors associated with the L₂C leukemia contributed to a generalized inhibition of macrophage cytotoxic activity, pulmonary macrophages from strain 2 guinea pigs with L₂C leukemia were tested for their ability to lyse the susceptible K562 cell line after activation by lipopolysaccharide (LPS) or lymphokines. In addition, the potential presence of soluble inhibitors of macrophage tumoricidal activity in serum-free culture supernatants and in serum from strain 2 guinea pigs terminally ill with the leukemia was tested by determining the effects of leukemic guinea pig serum (LGPS) or L₂C-conditioned medium (CM) on the tumoricidal activity of normal pulmonary macrophages. Macrophages from guinea pigs terminally ill with L₂C leukemia were demonstrated to be depressed in their cytotoxic activity against the K562 cell after stimulation by either LPS or lymphokines when compared to normal macrophages. The lymphokine-stimulated cytotoxic activity of normal macrophages was inhibited in the presence of LGPS or CM. Oxidative burst activity of normal macrophages, as measured by zymosan-stimulated production of superoxide and hydrogen peroxide, was also inhibited under these conditions. The data presented here suggests that soluble factors associated with L₂C leukemia cells can suppress oxidative burst activity of macrophages in vitro and that this effect may contribute to the ability of the leukemia cells to evade macrophage-mediated cytotoxicity.     

Tumor cell killing by macrophages activated in vitro with lymphocyte mediators. II. Inhibition by inhibitors of protein synthesis.

The effect of inhibitors of protein synthesis on the killing of tumor cells by in vitro activated macrophages was determined. Cytotoxicity was inhibited by concentrations of puromycin, pactamycin, and actinomycin D that almost completely inhibited protein synthesis by guinea pig macrophages, but not by concentrations of drug that inhibited protein synthesis by only ± 50%. Cytotoxicity was inhibited when the effector macrophages were pretreated with the metabolic inhibitors, but not when the drugs were added 30 to 60 min after the initiation of the reaction. Pretreatment with puromycin or pactamycin also markedly inhibited the binding of tumor cells by mediator activated macrophages. These results are consistent with the hypothesis that one possible mechanism by which inhibitors of protein synthesis inhibit macrophage mediated cytotoxicity is by inhibiting close contact between effector and target cells. The finding that pretreatment of activated macrophages with trypsin also inhibits tumor cell killing suggests that protein synthesis may be necessary to maintain an adequate number of “recognition structures” on the macrophage membrane, structures that mediate the initial contact between the activated macrophage and the target tumor.     

Differential spontaneous killing of human and murine tumour cell lines by leucocyte subpopulations from carp peripheral blood leucocytes

Cell populations from carp (Cyprinus carpio L.) peripheral blood leucocytes (PBLs) were examined for nonspecific cytotoxicities. By using monoclonal antibodies (MAbs) against carp thrombocytes (TCL-HB8) and both neutrophils and monocytes (TCL-BE8), PBLs with a density of 1.08 g ml-1 were separated into three fractions: thrombocytes, a mixture of neutrophils and monocytes, and other cells (mainly lymphocytes), and the separated cells were tested for cytotoxic activities against mammalian tumour cell lines (K562, HeLa, P815 and Yac-1 cell). Consequently, the mixture of neutrophils and monocytes exhibited cytolysis against these target cells, whereas the lymphocyte-rich and thrombocyte fractions did not show any cytolysis. To isolate only neutrophils, which do not contain monocytes, the MAb (TCL-BE8) positive cells from PBLs with a density of 1.08-1.09 g ml-1 were separated. Pure isolated neutrophils showed cytotoxic activities against K562 cells, but not P815 cells. Furthermore, analysis of the cytolytic mechanisms indicated that killing of these cells depended on H2O2 or HOCl. These results suggest that both neutrophils and monocytes are effectors for nonspecific cytotoxicity in carp PBLs, and neutrophils may be distinct from monocytes in their reactivity in cytolysis, including target cell selectivity and/or target cell sensitivity, and the cytolytic pathway. In carp, cytotoxicity of target cells can be mediated by several populations of their leucocytes which have cytotoxic capacities with various recognition and cytolytic mechanisms.     

Relationship between trinitrophenol and H-2 antigens on trinitrophenyl-modified spleen cells. III. Quantitative aspects of trinitrophenol binding on cells treated with trinitrobenzene sulfonic acid

Splenic lymphoblasts or normal spleen cells were treated with varying concentrations of TNBS in order to assess whether cell membrane H-2 molecules were derivatized with TNP. Cells treated with high concentrations of TNBS had their cell membrane H-2 molecules derivatized and functioned antigenically as inhibitors in a cold target TNP-CML competition assay. In contrast, cells derivatized with lower concentrations of TNBS had a significant proportion of their membrane proteins derivatized with TNP but did not have their H-2 molecules derivatized. These latter cells were unable to block anti-TNP cytotoxic effector cells in the competition assay. When cells were treated with 3H-TNBS, it was observed that TNP couples to cell membrane H-2, Ia and Ig molecules, and an estimate of the number of TNP molecules bound per cell at varying concentrations of TNBS was determined. The data obtained are consistent with there being a requirement for TNP to directly derivatize H-2 molecules on the cell membrane in order to create antigenic determinants that can be recognized by cytotoxic anti-TNP effector cells. As an alternative, there may be a requirement for the presence of a high density of TNP molecules per cell rather than direct H-2 derivatization by TNP in order to account for activity.