Iron depletion: Possible cause of tumor cell cytotoxicity induced by activated macrophages

The experiments reported here provide a possible molecular mechanism for the activated macrophage cytotoxic effect. Tumor cells that develop cytostasis and inhibition of mitochondrial respiration in response to cocultivation with activated macrophages release a significant fraction of their intracellular iron-59 content. Kinetic studies show that specific release of iron-59 from target cells begins 4–6 hours after initiating cocultivation which is the time point that inhibition of DNA synthesis is first detected. Treatment of tumor cells with metabolic inhibitors causing inhibition of respiration, protein synthesis, RNA synthesis, and DNA synthesis to a similar or greater extent than that caused by activated macrophages does not induce release of intracellular iron-59. It is significant that mitochondrial respiration and DNA replication, both strongly inhibited in target cells by activated macrophages, are metabolic pathways with enzymatic activity vulnerable to inhibition by depletion of intracellular iron.     

An indomethacin sensitive suppressor factor released by macrophages of leprosy patients

Reduction inF _c receptor expression as assayed by ‘erythrocyte’ rosetting of macrophage cultures from long term treated lepromatous leprosy patients (bactereologically negative) was seen in the presence of viableMycobacterium leprae. Macrophages with and without intracellular bacilli demonstrated this reduction. On the basis of this observation the conditioned medium ofMycobacterium leprae infected macrophage cultures of lepromatous patients, were tested on macrophages from normal individuals for [³H]-leucine incorporation and antigen specific physical interaction with lymphocytes. Both these parameters showed decreased values as compared to the controls which were not exposed to this conditioned medium. Lymphocyte transformation toMycobacterium leprae in leucocyte cultures of normal individuals was also reduced in the presence of the conditioned medium from lepromatous patients’ macrophages. The indication that this factor may be a prostaglandin was suggested by the observation that its synthesis was inhibited by indomethacin. Its importance in the non-specific depression in cell-mediated immunity seen in lepromatous patients is discussed.     

Interferon-gamma is required in activation of macrophages for tumor cytotoxicity

The participation of interferon-gamma in activation of murine macrophages for tumor cell lysis was investigated. Biochemically macrophage activation factor and interferon-gamma have not been separated. Antiviral titers correlated closely with macrophage activation in antigen- or mitogen-induced spleen cell supernatants. A monoclonal rat antibody that neutralized virus-induced interferon was also found to neutralize interferon-gamma in such supernatants. These monoclonal antibodies were coupled to CH-Sepharose 4B and used for absorption of antiviral activity from mitogen-induced spleen cell supernatants. Absorption of the interferon was paralleled by the reduction of the macrophage-activating capacity of the supernatants. Data from control absorptions supported the specificity of the absorption effect. These results indicate that interferon-gamma is required for activation of macrophages for tumor cell lysis. These results can be interpreted in two ways: (a) the monoclonal antibodies cross-react with interferon-gamma and with a mediator that is required for activation of macrophages for tumor cell lysis or (b) interferon-gamma itself is an essential cofactor for macrophage activation.     

Synergistic effect of tumor necrosis factor-alpha- and diphtheria toxin-mediated cytotoxicity in sensitive and resistant human ovarian tumor cell lines

Recent studies have demonstrated that diphtheria toxin (DTX) also mediates target cell lysis, and the mechanism of cytotoxicity has many features similar to those of cytotoxicity mediated by TNF-alpha. Thus, we hypothesized that DTX and TNF-alpha, used in combination, may result in either additive or synergistic cytotoxic activity. This was examined on three human ovarian carcinoma cell lines chosen for their differing sensitivities to TNF-alpha and DTX, i.e., 222, which is sensitive to both TNF-alpha and DTX, 222TR, a TNF-alpha-resistant DTX-sensitive variant of 222, and SKOV-3, which is resistant to both DTX and TNF-alpha. The simultaneous use of DTX and TNF-alpha at suboptimal concentrations resulted in synergistic cytotoxic activity against all three lines tested, thus overcoming the TNF-alpha resistance of 222TR and the double resistance of SKOV-3. DNA fragmentation was observed in all three lines treated with DTX and TNF-alpha and occurred as early as 4 h after treatment. Cycloheximide, actinomycin D, or emetine, at concentrations causing greater than 90% protein synthesis inhibition, did not result in cytotoxicity alone or synergy with TNF-alpha, suggesting that synergy by DTX was not due to its ability to inhibit protein synthesis. The use of energy poisons and pH conditions that inhibit DTX-mediated cytotoxicity resulted in the abrogation of synergy. These findings show that the two cytotoxic agents TNF-alpha and DTX, when used at suboptimal concentrations, synergize in their cytotoxic activity against sensitive and resistant cell lines. Because the SKOV-3 cell line used here is also resistant to chemotherapeutic drugs, combination treatment with DTX and TNF-alpha may be beneficial in overcoming drug resistance.     

The antimetastatic effect of macrophages restored by indomethacin: concomitant tumor immunity model

The role of macrophages acting as immunologic antitumor effectors and promoters of tumor growth are poorly understood as yet. We investigated the role of macrophage in model of concomitant immunity (CI), a phenomenon of secondary tumor rejection during the primary tumor growth. It has been shown that the period of CI weakening can coincide with appearance of tumor metastases. We used mammary carcinoma (MC) artificial lung metastases to evaluate the influence of macrophages from various period of CI on the development of metastases in mice. Our results indicated that macrophages are responsible for the late period of CI weakening and suppression. To investigate weather prostaglandins can mediate suppressive effect of macrophages we used experiments with indomethacin and we found that inhibition of prostaglandin E2 synthesis by indomethacin restored antimetastatic effect of concomitant immune macrophages.     

Characteristics of macrophage activation by gamma interferon for tumor cytotoxicity in peritoneal macrophages and macrophage cell line J774.1

We investigated the characteristics of macrophage-mediated tumor cytotoxicity (MTC) against Meth A target, H2O2 generation and release of effector molecule(s) for MTC, by comparing with those of peritoneal macrophages (PMP) and macrophage cell line J774.1 during stimulation with recombinant gamma interferon (IFN-gamma). In PMP, MTC was demonstrated when they were stimulated with IFN-gamma for 12 hr (short-term stimulation) and was abrogated when they were stimulated for 48 hr (long-term stimulation). Enhanced H2O2 generation was observed in PMP activated by long-term stimulation followed by triggering with PMA, but not observed by triggering with Meth A cells. By contrast, whereas non-treated J774.1 cells have already attained a definite level of MTC, a higher MTC level was demonstrated both by short- and long-term stimulations. Conversely, J774.1 cells were unable to generate H2O2 at any stage of IFN-gamma stimulation followed by triggering both with PMA or Meth A cells. The time course for stimulation of PMP by IFN-gamma for release of cytotoxic factor (CF) corresponded to that for MTC by PMP, and activities of the CF released from both activated PMP and J774.1 cells also closely corresponded to those of MTC by both cells. The serological and physicochemical characteristics of CF released from both activated PMP and J774.1 cells were determined to be closely related to those of tumor necrosis factor (TNF). These results indicate that in contrast to PMP, the J774.1 cell line is free from suppression stage for MTC and CF release during stimulation with IFN-gamma. The results suggest that TNF-like CF plays a crucial role for MTC against Meth A target, and that H2O2 is irrelevant for MTC against Meth A.     

Identification of a unique T cell-derived lymphokine that primes macrophages for tumor cytotoxicity

Macrophage activation factor (MAF) activity, assessed by the ability to activate macrophages (MO) to lyse RBL--a TNF-resistant, retrovirally transformed, tumor target--was detected in the PHA-stimulated supernatant (Sup) of LBRM, a murine T cell line. LBRM Sup provided a priming signal to MO, but required the subsequent addition of small amounts of LPS for the expression of tumor cytotoxicity. The identity of the lymphokine responsible for this MAF activity was investigated. IFN-gamma, the only previously characterized lymphokine capable of priming MO for tumor cytotoxicity, did have MAF activity in the assay, but IFN-gamma could not be detected by ELISA in LBRM Sup, and LBRM-derived mRNA lacked detectable message for IFN-gamma. Moreover, anti-IFN-gamma failed to inhibit the MAF activity of LBRM Sup, suggesting that the presence of small, undetectable amounts of IFN-gamma were neither responsible nor required for LBRM MAF activity. LBRM MAF activity appeared distinct from the other previously identified lymphokines produced by LBRM, since granulocyte-macrophage-CSF, IL-2, and IL-3 purified from LBRM Sup were unable to activate MO to lyse RBL. IL-4 and TNF, two lymphokines not known to be produced by LBRM but able to activate MO for cytotoxicity of some tumor targets, were also unable to activate MO for RBL cytotoxicity. LBRM MAF lacked antiviral activity in biologic assays, further distinguishing the lymphokine from IFN-gamma, and had an apparent Mr of 30,000 Da using gel filtration chromatography. Thus, the LBRM T cell line produces a previously undescribed lymphokine that primes MO for tumor cytotoxicity.     

Cyanide sensitive and insensitive bioenergetics in a clonal neuroblastoma x glioma hybrid cell line

The primary mechanism of cyanide (CN) intoxication is the inhibition of metabolism in the central nervous system. We determined the effects of CN on several biochemical processes in neuroblastoma x glioma hybrid NG108-15 cells, which possess numerous neuronal properties. These cells were not sensitive to a high concentration (1 mM) of NaCN, but became sensitive in the presence of the anaerobic glycolysis inhibitors sodium iodoacetate (IA) and 2-deoxyglucose (2-DG): cellular metabolic processes (e.g., DNA, RNA and protein synthesis) decreased, to about 40% of control due to treatment with 0.5 mM NaCN+0.05 mM IA and 0.1 mM NaCN+20 mM 2-DG. ATP in cells exposed to 0.01 or 0.1 mM NaCN+20 mM 2-DG was reduced 75% and 100%, respectively within one min. Pretreatment of cells with the CN antidote cobalt (II) chloride (CoCl₂) (0.06–0.18 mM) for 5 min prevented the depression of both [³H]leucine incorporation and ATP synthesis due to 1 mM NaCN+20 mM 2-DG in a concentration-dependent manner. A proposed CN antidote alpha-ketoglutaric acid (disodium salt) also prevented the depression of cellular metabolism due to NaCN plus 2-DG. These results indicate that blocking anaerobic glycolysis makes NG108-15 cells sensitive to a low concentration of CN. Thus NG108-15 cells should be useful to study the mechanisms of neurotoxicity of CN and to test antidotes.     

Triggering of interferon gamma-primed macrophages by various known complement activators for nonspecific tumor cytotoxicity

Five known complement activators were evaluated for their capacity to directly activate murine macrophages and to trigger activation of lymphokine primed macrophages for nonspecific tumor cytotoxicity. Bacterial lipopolysaccharide (LPS), Lipid A, polyinosinic-polycytidylic acid, cobra venom factor (CVF), and zymosan directly activated macrophages in a dose-dependent fashion at high concentrations. Subactivating concentrations of each of these agents were found to effectively trigger macrophages which were preprimed either by macrophage-activating factor or by murine recombinant interferon gamma for enhanced tumoricidal activity. An Fc receptor blockade with opsonized sheep erythrocytes abrogated LPS-mediated direct activation and triggering of interferon gamma-primed macrophages, but had no inhibitory effect on direct activation or triggering by CVF for nonspecific tumor cytotoxicity. This study characterizes the capacity of a diverse group of known complement activators to serve as second signal triggers for culmination of the activation process of interferon-primed macrophages for nonspecific tumoricidal activity. These findings suggest that complement activators may directly activate macrophages by stimulation of interferon beta production by macrophages for self-priming and, as we have shown, act as self-triggers. The putative role of macrophage-associated complement components in the activation process is discussed.     

Monoclonal antibodies directed against mouse macrophages in different stages of activation for tumor cytotoxicity

Three rat monoclonal antibodies against mouse peritoneal macrophages in different stages of activation were produced and characterized. One of these (AcM.1) bound to activated macrophages induced by pyran and Corynebacterium parvum, but not to resident and thioglycollate medium- (TGC) or proteose peptone- (PP) elicited macrophages. On the contrary, the antigen identified by MM9 monoclonal antibody was expressed only on resident and TGC- or PP-elicited macrophages. WE15 monoclonal antibody, on the other hand, reacted with all of the macrophages described above. In the assay for function, AcM.1 and WE15 monoclonal antibodies in the presence of complement (C) abolished the capacity of activated macrophages induced by pyran or C. parvum but not the capacity of killer T cells and natural killer (NK) cells to kill tumor target cells. On the other hand, MM9 and anti-Thy-1.2 monoclonal antibodies in the presence of C, as expected, did not affect the cytotoxicity of activated macrophages. However, none of the four monoclonal antibodies in the absence of C had any blocking effect on macrophage-mediated cytotoxicity. AcM.1 antibody reacted with two polypeptides with m.w. of 70,000 and 45,000 on pyran-activated macrophages; however, the antigens recognized by WE15 and MM9 have not been determined yet. These results indicate that the three rat monoclonal antibodies define different antigens present on macrophages at different stages of activation for tumor cytotoxicity, and that these antibodies should prove to be useful probes for analyzing the mechanism of activation of macrophages for tumor cytotoxicity.     

Properties of hypothalamic temperature sensitive and insensitive neurones.

Intracellular recordings show that some hypothalamic neurones are inherently warm sensitive and have branching dendrites that allow synaptic integration of different afferent pathways.     

Properties of a hybrid between lines sensitive and insensitive to contact inhibition of cell division

Hybrid cell lines have been prepared between 3T3, a line highly sensitive to contact inhibition of division, and cl 1-D, an L cell derivative which is not sensitive. A number of hybrid clones isolated were found to be quite sensitive, indicating that in this respect the 3T3 behavior is the more fully expressed in the hybrid. On serial subculture, the hybrid lines gave rise to variants less sensitive to contact inhibition.     

Induction of tumor necrosis factor and cytotoxicity by macrophages exposed to lactoperoxidase and microperoxidase

Peroxidases are involved in a number of cytotoxic reactions. Murine thioglycollate-induced peritoneal macrophages were exposed to either lactoperoxidase or microperoxidase in vitro. At a concentration of 17.7 microM, both of these enzymes induced between 100 and 200 units of tumor necrosis factor (TNF) per 0.1 ml. Furthermore, these substances were able to stimulate macrophages to kill 3T12 target cells in a dose dependent manner at concentrations of 0.177 microM to 17.7 microM. Per cent cytotoxicity varied from 20% up to 75% at the higher concentrations. It was concluded that these enzymes can induce macrophages to secrete TNF and become activated to the cytotoxic state.     

Effect of tumor cell culture media and sera from tumor hosts on spreading,phagocytosis, and antitumor cytotoxicity of C. parvum-activated murine macrophages

Summary We investigated whether the media of tumor cell cultures and sera from tumor-bearing hosts exert inhibitory effects upon macrophage spreading, phagocytosis, and cytotoxicity. Peritoneal macrophages from normal and Corynebacterium parvum-treated C3Hf/Bu mice were incubated in media from a syngeneic mammary carcinoma, allogeneic Ehrlich ascites carcinoma, and human malignant melanoma or cervical carcinoma cell cultures, or in the serum of hosts bearing these tumors. Such media and sera inhibited the ability of both normal and C. parvum-activated macrophages to spread on glass surfaces and to ingest latex particles. In contrast, they did not interfere with the in vitro destruction of tumorigenic L929 cells by C. parvum-activated macrophages. Media of murine embryo fibroblasts and a human benign tumor and sera from healthy mice or humans did not, however, inhibit either of the macrophage functions tested.     

IFN-gamma- and cell-to-cell contact-dependent cytotoxicity of allograft-induced macrophages against syngeneic tumor cells and cell lines: an application of allografting to cancer treatment.

In allogeneic tumor or skin transplantation, the rejection process that destroys the allogeneic cells leaves syngeneic cells intact by discrimination between self and nonself. Here, we examined whether the cells infiltrating into the allografts could be cytotoxic against syngeneic immortal cells in vitro and in vivo. The leukocytes (i.e., macrophages (Mphi; 55-65% of bulk infiltrates), granulocytes (20-25%), and lymphocytes (15-20%)) infiltrating into allografts, but not into autografts, in C57BL/6 mice were cytotoxic against syngeneic tumor cells and cell lines, whereas the cytotoxic activity was hardly induced in allografted, IFN-gamma-/- C57BL/6 mice. Among the leukocytes, Mphi were the major population of cytotoxic cells; and the cytotoxic activity appeared to be cell-to-cell contact dependent. When syngeneic tumor cells were s.c. injected into normal C57BL/6 mice simultaneously with the Mphi-rich population or allogeneic, but not syngeneic, fibroblastic cells, tumor growth was suppressed in a cell number-dependent manner, and tumor cells were rejected either with a Mphi:tumor ratio of about 30 or with an allograft:tumor ratio of approximately 200. In the case of IFN-gamma-/- C57BL/6 mice, however, the s.c. injection of the allograft simultaneously with tumor cells had no effect on the tumor growth. These results suggest that allograft or allograft-induced Mphi may be applicable for use in cancer treatment and that IFN-gamma induction by the allograft may be crucial for the treatment.     

Activation of cell stress response pathways by Shiga toxins

Shiga toxin-producing bacteria cause widespread outbreaks of bloody diarrhoea that may progress to life-threatening systemic complications. Shiga toxins (Stxs), the main virulence factors expressed by the pathogens, are ribosome-inactivating proteins which inhibit protein synthesis by removing an adenine residue from 28S rRNA. Recently, Stxs were shown to activate multiple stress-associated signalling pathways in mammalian cells. The ribotoxic stress response is activated following the depurination reaction localized to the α-sarcin/ricin loop of eukaryotic ribosomes. The unfolded protein response (UPR) may be initiated by toxin unfolding within the endoplasmic reticulum, and maintained by production of truncated, misfolded proteins following intoxication. Activation of the ribotoxic stress response leads to signalling through MAPK cascades, which appears to be critical for activation of innate immunity and regulation of apoptosis. Precise mechanisms linking ribosomal damage with MAPK activation require clarification but may involve recognition of ribosomal conformational changes and binding of protein kinases to ribosomes, which activate MAP3Ks and MAP2Ks. Stxs appear capable of activating all ER membrane localized UPR sensors. Prolonged signalling through the UPR induces apoptosis in some cell types. The characterization of stress responses activated by Stxs may identify targets for the development of interventional therapies to block cell damage and disease progression.     

Antibody production useful for cytotoxicity against mouse MM2 tumor cells by peritoneal macrophages.

We applied an antibody-dependent macrophage-mediated cytotoxicity (ADMC) test in order to analyze the effector mechanism of the host-mediated antitumor effects induced by OK-432. Adherent peritoneal exudate (PE) cells were obtained from each of high (C3H/He) and low (B10) responder mice treated with OK-432, and 51Cr-labeled MM2 tumor cells were used as target cells. The cytotoxic activity in vitro coincided well with the results obtained in in vivo antitumor experiments. When adherent PE cells from C3H/He mice reacted with anti-MM2 serum from B10 mice, the degree of ADMC was significantly lower than that obtained with the anti-MM2 serum from C3H/He mice. The removal of IgG1 from the anti-MM2 serum induced in B10 mice resulted in the enhancement of ADMC activity. Then mean level of IgG2 in each of anti-MM2 sera from C3H/He and B10 mice was higher than in normal serum, and the IgG1 level in the antiserum from B10 mice was also higher than that in the serum from normal B10 mice. The present work suggested that the active component(s) in anti-MM2 serum participating in ADMC was a specific antibody of the IgG2 subclass, and that the inhibiting factor(s) was the IgG1 subclass.