Cytolytic activities of activated macrophages versus paraformaldehyde-fixed macrophages; soluble versus membrane-associated TNF.

Membrane-associated tumor necrosis factor (TNF) and soluble TNF were compared as to their lytic activities, and as to the kinetics of their expression by macrophages activated with LPS and/or IFN-gamma in the presence or absence of cycloheximide. EL 4 tumor cells, resistant and sensitive to lysis by recombinant TNF or membrane-associated TNF (paraformaldehyde (PF)-fixed activated macrophages) were used as targets. In the presence of cycloheximide the TNF-resistant S-EL4 cells were lysed by both TNFs. PF-fixed macrophages was cytolytic after 1 hr activation but not after 3 or more hours of activation. Their activity was totally inhibited by anti-TNF antibodies and was a composite of transmembrane (integral) TNF and soluble TNF conjugated to macrophage membrane TNF receptors. Treatment of the macrophages with glycine pH 3.0 buffer dissociated the conjugated TNF without affecting the integral membrane TNF. When macrophages were activated with LPS +/- IFN-gamma in the presence of cycloheximide or activated just with IFN-gamma their activity after fixation with paraformaldehyde was no longer detected. Nonfixed macrophages under these conditions still remained cytotoxic. Tumor cell susceptibility to membrane-associated TNF activity, in contrast to recombinant (soluble) TNF, was greatly reduced in the presence of nicotinamide, an inhibitor of ADP-ribosyltransferase, suggesting that the mechanisms of lysis by these TNFs may be different. The lytic activity of both TNFs was found to be receptor-dependent in that tumor cells, whose TNF binding sites were "down-regulated" by TPA, were rendered resistant to lysis by both membrane-associated and soluble TNFs.     

Antibody-dependent cytolysis (ADCC) of tumor cells by activated murine macrophages is a two-step process: Quantification of target binding and subsequent target lysis

To analyze the antibody-dependent cell-mediated cytotoxicity (ADCC) reaction between tumor cells and activated murine macrophages in detail, it must be first determined if physical binding occurred between the two cell types. Over 15–20 min in vitro, antibody-coated HSB neoplastic targets became so firmly attached to the activated macrophages that they resisted removal with 4 vigorous washes. When a quantitative assay of binding was employed, attachment of tumor cells to activated macrophages was found to depend on the concentration of antibody and on the density of the macrophages. These two variables also determined the subsequent extent of cytolysis. Binding of antibody-coated targets by macrophages elicited with thioglycollate broth or activated by bacillus Calmette-Guerin (BCG) was comparable. Lysis by the activated macrophages, however, was far greater. Binding occurred at 4, 22, or 37 °C, while the subsequent lytic reaction occurred only at 37 °C. Thioglycollate broth effectively inhibited lysis but had no effect on binding. A porous filter placed between activated macrophages and targets resulted in abrogation of binding and lysis, even when antibody-coated targets were placed beneath the filters. When labeled, uncoated targets were added to cultures of macrophages in the presence of unlabeled antibody-coated targets, no lysis of the bystander (i.e., uncoated) targets was seen. The data suggest that ADCC is a multistep reaction, that vigorous physical binding of antibody-coated targets by activated macrophages is an initial and necessary step in ADCC, that such binding is not sufficient for ADCC, that such binding controls the selectivity of lysis in ADCC, and that the second step in ADCC results in target lysis.     

Auto-tumor lysis by blood lymphocytes in vitro

Summary Selectivity of the lysis of the tumor cells by autologous blood lymphocytes and its various subsets was investigated by means of the cold target competition assay. The effectors were autologous lymphocytes passed through a nylon-wool column (unfractionated: U) and their low-and high-density subsets, either without or after activation. The lymphocytes were activated (a) in autologous mixed lymphocyte tumor cell culture in autologous (MLTC), (b) in mixed lymphocyte culture (MLC), without and with interleukin-2, for 6 days, or (c) by phytohaemagglutinin for 3 days. Autologous-lymphocyte-mediated cytotoxicity (auto-tumor lysis: ALC) by the unfractionated, unmanipulated blood lymphocyte (U) population, its high-density fraction and those induced for auto-tumor lysis in the MLTC is regularly weak and affects only the autologous tumor cells. Their ALC function was inhibited only by the target identical unlabelled cells while the effect of separated low-density lymphocytes was inhibited also by allogeneic tumor cells.The cold-target competition assay indicated that several subsets with different specificities exist simultaneously in the effector populations activated in MLC, because the various targets did not cross-compete or did so only partially. Whenever interleukin-2 was added, at the start of the mixed cultures (MLTC or MLC), the lytic effects were no longer selective. Phytohaemagglutinin-activated effectors lysed several targets. These targets were inhibitory in a criss-cross fashion. Generally, populations showing auto-tumor selectivity had weak lytic effects, while the strongly activated effectors, with strong cytotoxic function, were not selective.     

Enhancement of selective tumor cell binding by activated murine macrophages in response to phorbol myristate acetate

The fundamental biology of how stable cell-cell bonds develop between activated macrophages and tumor cells, although essential to lysis of the neoplastic targets, remains poorly understood. To investigate whether this phenomenon could be pharmacologically manipulated, we analyzed the effect of phorbol diesters on tumor cell binding by macrophages. Activated murine peritoneal macrophages, treated in vitro with as little as 1 ng/ml of phorbol myristate acetate (PMA), bound significantly more tumor cells than did untreated macrophages. The effect was induced rapidly by PMA (i.e., maximum enhancement was seen within 15 min) and resulted in an average approximately twofold increase in the number of targets bound. The interaction between PMA-treated activated macrophages and tumor cells was completed much more rapidly than by untreated macrophages. The enhanced binding was seen only in macrophages treated with biologically active phorbol esters. Only the selective interaction between activated macrophages and tumor cells was affected (i.e., PMA treatment had no effect on nonselective interactions between activated macrophages and non-neoplastic targets or between nonactivated macrophages and any type of target). Pretreatment of activated macrophages with PMA apparently altered the requirements for microfilaments and microtubules in establishing binding, because cytochalasin B and colchicine, which inhibited control binding, as well as phagocytosis, had no effect on PMA-enhanced binding. PMA treatment did not alter energy requirements for binding, however, because low temperature (4 degrees C) or inhibitors of glycolysis and oxidative phosphorylation blocked both control and PMA-enhanced binding. The enhancement of binding apparently was not due to large quantities of secreted oxygen metabolites but did correlate closely with increased spreading and surface area of the macrophages. PMA treatment resulted in enhanced expression of trypsin-sensitive tumor-cell binding sites on the macrophage surface. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of macrophage membrane proteins labeled with 125I by the lactoperoxidase method revealed at least four trypsin-sensitive cell surface proteins that were re-expressed after PMA treatment. The data suggest that rearrangement and/or induced expression of surface binding sites may be an important step in the binding of tumor cells and indicate that PMA is a useful pharmacologic probe in dissecting the establishment of such binding into discrete steps.     

Studies on the antibody-dependent cell-mediated cytotoxicity (ADCC) of thioglycollate-stimulated and BCG-activated peritoneal macrophages

Peritoneal macrophages (mφ), activated by Bacillus Callmette-Guerin (BCG) or elicited by thioglycollate broth in vivo in C57BL/6J mice, were compared with regard to their ability to mediate antibody-dependent cellular cytotoxicity (ADCC). The BCG-activated mφ had several times higher ADCC activity than did the TG-mφ against erythroid targets. When human and murine tumor cells were employed as targets in the ADCC assay, the BCG-mφ lysed each of six separate target lines considerably, while the TG-mφ had little and, occasionally no, lytic activity against the six targets. Although F_c-dependent and -independent phagocytosis of the erythroid targets by the TG-mφ exceeded that by the BCG-mφ, this rapid and extensive phagocytosis did not account soley for the decreased lysis of the erythroid targets by the TG-mφ. The results indicate that BCG-activated peritoneal mφ, in comparision with TG-elicited inflammatory mφ, are potent effectors of ADCC against both erythroid and neoplastic target cells.     

Quantification of the strength of cell-cell adhesion: the capture of tumor cells by activated murine macrophages proceeds through two distinct stages

The binding of tumor cells by macrophages activated with Bacillus Calmette-Guerin is a necessary step toward destruction of those cells. Although several characteristics of the interaction have been defined, little is known of how the actual binding process develops. We used a technique to quantify the forces required to disrupt cell-cell interactions. Over a range of applied relative centrifugal forces, the majority of targets that bound to the activated macrophages fell on two distinct plateaus. Approximately 90% of added targets were bound to the monolayers of macrophages over the range of 1 to 100 X G; 25 to 30% remained bound from 1200 X G to 1500 X G. Two strengths of binding, termed weak and strong binding, respectively, were thus defined on the basis of these curves. Strong binding developed only between activated macrophages and tumor cells. By contrast, weak interactions occurred between either activated or nonactivated macrophages and neoplastic or non-neoplastic target cells. The strong binding required time (60 to 90 min), metabolic activity by the macrophages, and trypsin-sensitive surface structures on the macrophages for development, whereas the weak interaction occurred rapidly and required none of these. Additional evidence indicated the weak binding developed into strong when activated macrophages bound neoplastic cells. This stabilization increased the strength of force to separate tumor cells from the macrophages at least approximately 15 fold (i.e., from approximately 16 mu dynes/cell to approximately 240 mu dynes/cell). Of note, the development of strong binding of antibody-coated targets had distinct requirements for establishment. Taken together, the data suggest the stabilization of binding (i.e., the development of weak into strong binding) leading to effective cell-cell interaction is a complex and dynamic process that may vary depending upon the recognition system involved.     

Inhibition of natural killer cell lysis by natural killer-inhibitory substance: mechanism of suppression

The mechanism of suppression of NK-mediated lysis by a soluble product of peritoneal cells (NK-IS, natural killer-inhibitory substance) was investigated. Pretreatment of effector cells resulted in depressed NK lysis while pretreatment of targets had no effect, indicating suppression is due to alterations in effector cell function rather than changes in target cells. NK-IS had no effect on the formation of conjugates between effectors and NK-susceptible targets. When NK-IS was added to effector-target cell mixtures after the binding step had been successfully completed, ensuing lysis was significantly depressed, confirming that NK-IS inhibited a postbinding lytic event. The degree of suppression caused by NK-IS was directly related to the duration of exposure to the inhibitory molecule. In addition, a preliminary temperature-dependent step of binding to and/or intracellular entry of NK-IS into effectors is required before suppression can occur. NK-IS prevents the activation of NK cell lysis by interferon and Corynebacterium parvum and effectively inhibits lysis mediated by already activated effectors. The potent suppression of NK lysis and prevention of interferon and C. parvum-mediated activation of NK lysis by a soluble product of peritoneal cells may explain the extremely low level of NK effector cell function within the peritoneal cavity.     

A microassay for the rapid and selective binding of cells from solid tumors to mouse macrophages

Summary A microassay was developed to study the rapid binding characteristics of murine macrophages activated by gamma interferon and muramyl dipeptide to adherent neoplastic or nonneoplastic target cells. The binding of tumor cells to both activated and nonactivated macrophages was time- and temperature-dependent, and independent of tumor cell type. Activated macrophages bound more tumor cells than nonactivated macrophages. The initial binding of macrophages to target cells did not necessarily lead to lysis. First, primed macrophages bound tumor cells but did not lyse them, and second, nonactivated macrophages bound nontumorigenic cells without subsequent lysis. The rapid binding assay described here could prove useful in investigating the recognition mechanism(s) between macrophages and tumor cells derived from solid primary and metastatic cancers.     

Induction of tumor cell resistance to macrophage-mediated lysis by preexposure to non-activated macrophages

Thioglycollate-elicited peritoneal exudate (non-activated) macrophages do not lyse tumor cells and in contrast to activated macrophages bind less target cells. However, a non-lethal encounter of tumor cells with non-activated macrophages resulted in a pronounced effect on the subsequent tumor cell binding to and lysis by activated macrophages. Our results have shown that binding of tumor cells by non-activated macrophages was Ca2+ and temperature dependent; had a requirement for a Pronase-sensitive structure on macrophage surface membranes; was saturable; and was 2-3X less than that observed for activated macrophages. Experiments were conducted in which syngeneic tumor cells were incubated with a monolayer of non-activated macrophages and then assayed for selective binding and sensitivity to lysis. The important observations were that as a result of a 3-hr incubation with non-activated macrophages at an EC: TC ratio of 5:1 there was an increase in the number of tumor cells that bound to both activated and non-activated macrophages; a loss of selective binding in which the ratio of tumor cells bound to activated/non-activated macrophages (normally greater than 2) was lowered to 1.0; and a concomitant decrease in the susceptibility of tumor cells to macrophage-mediated cytolysis. The induction of tumor cell resistance to macrophage kill required an exposure to an excess number of non-activated macrophages, was reversible upon culturing with or without macrophages for 24 hr and required cell-cell contact. Our results reinforce the importance of selective binding between tumor cells and activated macrophages as an initial phase in tumor cell killing and also illustrates an active role for non-activated macrophages in vivo in allowing tumor cells to escape the immune surveillance by activated macrophages.     

The cloned cell line L10A2.J expresses natural cytotoxic activity

The analysis of natural cytotoxicity (NC) has been hampered by the lack of cloned NC effectors. In studies reported here we show that the cloned cell line L10A2.J expresses properties similar to those of splenic NC effectors. L10A2.J cells lyse NC-sensitive targets, but do not lyse NC-resistant targets which are sensitive to lysis by natural killer (NK) or cytotoxic T lymphocytes. The mechanism by which L10A2.J cells lyse NC-sensitive targets is similar to the lytic mechanism of splenic NC effectors in that both result in the release of 51Cr from targets with a lag of 5-7 hr after effectors and targets are mixed. In addition, inhibition of protein synthesis during the in vitro assays of NC or L10A2.J lytic activity causes some NC-resistant targets to become sensitive to lysis by both NC and L10A2.J effectors. The only functional difference detected between L10A2.J and splenic NC effectors is in their recognition of targets. While L10A2.J and splenic NC effectors recognize many of the same targets (NC resistant and NC sensitive), L10A2.J, unlike splenic NC effectors, does not recognize the NK-sensitive cell line YAC-1.     

Differential effects of protein synthesis inhibition on CTL and targets in cell-mediated cytotoxicity

The reactions that lead to target cell lysis by cytotoxic T cells (CTL) are despite intensive investigations poorly understood. To examine the relative roles effectors and targets play in the lytic reaction, protein synthesis in either CTL or targets was inhibited before assay of lysis. We show, in agreement with previous results, that de novo protein synthesis is not necessary in either effectors or targets during the cytolytic reaction. However, activation of CTL requires protein synthesis. Activated CTL respond to protein synthesis inhibitors with a cycling of activity, a result that is interpreted to be consistent with a stimulus secretion mechanism. Treatment of targets with protein synthesis inhibitors prior to incubation with CTL leads to a very rapid and irreversible loss of lytic susceptibility. It is shown that the decrease in lysability is not due to lack of proper CTL target interaction: MHC class I antigens are expressed on drug-treated targets and these cells serve as cold targets in competitive inhibition experiments. Moreover, drug-treated targets trigger transient Ca2+ mobilization and generation of inositol phosphates in CTL. It is therefore concluded that drug-treated targets are able to trigger CTL function but lack a component that is required for their successful lysis.     

Natural cytotoxic cells and tumor necrosis factor activate similar lytic mechanisms

The lytic activity of natural cytotoxic (NC) cells has several characteristics which clearly distinguish it from other cell-mediated lytic activities and from most soluble cytolytic factors. An exception is the lytic activity mediated by tumor necrosis factor (TNF). In this paper, we report a detailed comparison of NC and TNF lysis of target cells which are used as prototype NC targets or TNF targets, and show that the two cytolytic activities have very similar, if not identical, lytic mechanisms. We present data showing that target cells which are NC-sensitive are also TNF-sensitive and that target cells which are NC-resistant are also TNF-resistant. Moreover, cells selected either in vivo or in vitro for NC resistance are selected for TNF resistance, and cells selected for TNF resistance are selected for NC resistance. The analysis of the kinetics of 51Cr release mediated by NC cells or by TNF show that both activities affect similar kinetics, in that there is no cell lysis for several hours after targets and effectors first interact. However, NC and TNF lytic activities can be distinguished. By using the cell lines 10ME or B/C-N as targets, it can be shown that whereas NC-mediated lysis is dependent on protein synthesis, TNF-mediated lysis is not. We also show that targets which are resistant to NC-mediated lysis because they express a protein synthesis-dependent resistance mechanism also require protein synthesis to resist TNF-mediated lysis, suggesting that the same resistance mechanism protects cells against both NC cells and TNF. Together, these data strongly support the hypothesis that NC cells and TNF activate the same lytic mechanism within target cells and that TNF may mediate the lytic activity of NC effector cells.     

Mechanisms of tumor cell capture by activated macrophages: evidence for involvement of lymphocyte function-associated (LFA)-1 antigen

The lymphocyte function-associated (LFA)-1 molecule is expressed on certain populations of macrophages that have an augmented capacity to capture tumor cells. Accordingly, we analyzed the role of LFA-1 in the establishment of such cell-cell interactions. F(ab')2 fragments of the M17/4, anti-LFA-1 monoclonal antibody (MAb) inhibited the interaction between activated macrophages and tumor cells by up to 80% in a dose-dependent manner. The anti-LFA-1 MAb reduced (between 55 to 79%) the number of P815, LSTRA, or EL-4 tumor cells bound to trypsin-sensitive structures on bacillus Calmette Guerin activated macrophages. The inhibition appeared selective, because a F(ab')2 fragment of anti-Mac-1 did not inhibit such binding. Inhibition of tumor cell capture could be observed as soon as 15 min after the onset of the cell-cell interaction between activated macrophages and tumor cells. Optimal inhibition occurred when both tumor targets and macrophages were precoated with the MAb. Although P815, LSTRA, EL-4, and BW5147 tumor cells all expressed LFA-1, only the first three but not BW5147 cells were bound by activated macrophages. Furthermore, endotoxin-pulsed macrophages elicited by thioglycollate broth expressed the LFA-1 antigen but did not exhibit selective tumor cell capture. Finally, anti-LFA-1 inhibited the development of weak into strong binding. Taken together, the results suggest that LFA-1 molecules can participate in the interaction between activated macrophages and neoplastic cells.     

Lymphocytes infiltrating human ovarian tumors. I. Role of Leu-19 (NKH1)-positive recombinant IL-2-activated cultures of lymphocytes infiltrating human ovarian tumors

Tumor-infiltrating lymphocytes (TIL) were obtained from human ovarian tumors, expanded in the presence of IL-2 in culture and studied for cytotoxicity against fresh autologous and allogeneic ovarian carcinoma (CA) targets. TIL from ovarian tumors grew well in long term cultures, achieving from 8- to 682-fold expansion. TIL cultured with IL-2 were cytotoxic against both autologous and allogeneic fresh ovarian CA targets, and no specificity for autologous tumor could be demonstrated in any of the cultures. In all fresh TIL preparations, CD3+ lymphocytes were the major cell type and contained a high proportion (up to 51%) of activated (IL-2R+) cells as determined by two-color flow cytometry. Sorting of bulk TIL cultures followed by cytotoxicity assays identified the Leu-19+ cells, both CD3+ and CD3-, as effectors of cytotoxicity against autologous and allogeneic tumor cell targets. Cold target inhibition assays showed that allogeneic targets (both ovarian CA and a sarcoma) competed effectively with autologous ovarian CA targets for Leu-19+ effectors in TIL cultures. mAb to Leu-19 or Leu-2a did not block lysis of autologous targets by sorted effectors. OKT3 antibody augmented lysis of autologous targets by CD3+Leu-19- effectors only. These results show that non-MHC-restricted Leu-19+ effectors in cultures of TIL with 1000 U/ml of rIL-2 mediate lysis of autologous and allogeneic tumor cells. The CD3+Leu-19- cells, the main population in these cultures, do not mediate tumor lysis. To determine the phenotype of antitumor effectors in IL-2 cultures of TIL, cell sorting followed by functional assays are necessary.     

Effects of sodium periodate modification of lymphocytes on the sensitization and lytic phases of T cell-mediated lympholysis.

Sensitization of mouse splenic lymphocytes in vitro with sodium borohydride, suggesting that the biologic effects of sodium periodate are-treated autologous spleen cells stimulated a one-way mixed lymphocyte reaction and led to the generation of thymus-derived cytotoxic effector cells. These effectors were capable of lysing in 4 hr periodate-treated syngeneic and, to a lesser extent, periodate-treated allogeneic target cells. These results suggest that sensitization by periodate-treated autologous cells could result either from a specific reaction to modified self components or from a nonspecific mitogenic stimulation. Effector cells generated by allogeneic sensitization were detected on periodate-modified targets, irrespective of the H-2 antigens expressed by the targets. The effects of periodate modification on both stimulator and target cells were reversible by sodium periodate are dependent on the formation of a free aldehyde group on cell surface glycoproteins. Pretreatment of stimulator cells with neuroaminidase prevented the effect of periodate treatment, suggesting that the sensitization involves oxidized sialic acid residues. During the 4-hour 51Cr-release assay periodate-treated targets could be used to detect cytotoxic effector cells of any specificity. Fresh spleen cells and lymphocytes cultured for 5 days without antigen or in the presence of lipopolysaccharide did not lyse periodate-treated targets. An increasing level of cytotoxicity was detected on periodate-treated targets when the effector cells were generated, respectively, by stimulation with concanavalin A, by sensitization with periodate-modified autologous cells. Although the lysis of periodate-treated targets is itself nonspecific, effector cell specificity could be determined by selective blocking of the lytic phase with cells syngeneic to the stimulators. These results indicate that a nonspecific interaction can occur between lymphocytes and periodate-treated target cells, but that this interaction leads to lysis only when the lymphocytes were activated to become cytotoxic effectors.     

High strength binding of P815 mastocytoma cells is not necessary for their lysis by macrophages which have been primed and triggered in vitro

We have examined the hypothesis that binding of P815 mastocytoma cells is a necessary step in lysis of these cells by macrophages which are both "primed" and "triggered" in vitro, Macrophages "primed" by conditioned media containing IFN-gamma, or by rIFN-gamma have an increased ability to bind P815. However, adding either heat-killed Listeria or endotoxin to trigger the primed macrophages has opposite effects on lysis and binding of P815. Lysis is increased. Binding is dramatically decreased. This is true when centrifugal forces of 200 x g, 400 x g, and 800 x g are used to disrupt P815-macrophage binding. Although 100% of P815 cells bound by cytotoxic macrophages are lysed, a large additional population of unbound P815 is also lysed. Detailed kinetic studies indicate that macrophages do not rapidly bind and lyse several cycles of P815. There is an initial lag period of 4 to 6 h before P815 lysis can be detected, and completion of lytic events then occurs within 12 to 14 h. Lysis of P815 bound to cytotoxic macrophages is slightly slower than lysis of the total population of bound and unbound P815. In contrast, D3.1, a cloned CD4+ T cell line, is tightly bound to macrophages but not lysed efficiently. When macrophages are simultaneously confronted with P815 and macrophage-bound D3.1, only the former are lysed. Altogether, the data indicate that P815-macrophage binding, as operationally defined by our assay, is not a necessary step for lysis. These results, by use of macrophages primed and triggered in vitro, are in contrast to previously reported experiments examining P815 binding and lysis by macrophages activated in vivo by infection with bacillus Calmette-Guérin.     

Cytokines alter target cell susceptibility to lysis. II. Evaluation of tumor infiltrating lymphocytes

We studied the susceptibility of autologous and allogeneic tumors to lysis by human tumor infiltrating lymphocytes (TIL) after pre-incubation of the tumors with human rIFN-gamma and human rTNF-alpha. Preincubation of the tumor lines with IFN-gamma or TNF enhanced susceptibility to lysis significantly; the combination of both cytokines was more effective than either alone. Pretreatment for at least 24 h was required to enhance lytic susceptibility and maximal lysis was observed after pretreatment for 48 to 72 h. Highly specific TIL lysed only their autologous tumor targets and failed to lyse cytokine pretreated allogeneic tumor cells. In TIL populations with varying specificity, cytokine pretreatment of targets enhanced autologous lysis as well as allogeneic lysis. This cytokine-mediated effect could also be observed in a lectin-dependent cytotoxicity assay and did not correlate directly with enhanced expression of MHC class I Ag or the adhesion molecules LFA-3 and ICAM-1. These results suggest that enhancement of lysis may occur at a postbinding stage by making the target cell more sensitive to the cytotoxic factors delivered by the killer cell. The fact that lysis of cytokine treated targets by cells with LAK activity was not enhanced suggests that cells with lymphokine-activated killer activity and tumor-derived T cells kill tumor targets via different mechanisms.     

Susceptibility of Adenovirus 2-transformed rat cell lines to natural killer (NK) cells: direct correlation between NK resistance and in vivo tumorigenesis

The susceptibility to natural killer (NK)-mediated cell lysis of Adenovirus type 2 (Ad2)-transformed rat embryo fibroblast cell lines, which differed markedly in tumorigenic potential in vivo (T2C4 greater than F19 greater than F17), was investigated by using NK effector cells from F344 rat or athymic nude rat spleens. A comparison of the degree of NK-mediated lysis obtained with these tumor cell targets suggested a direct relationship between the resistance of a cell to NK cell lysis and its potential to form tumors in vivo. The cells were lysed in the following order of increasing susceptibility: T2C4 less than F4 less than F19 less than F17. Whether T cells or macrophages played a significant role in the observed lytic activity was determined by treating the NK effector cell population with anti-rat T cell serum (alpha T) and complement or by depletion of macrophages after binding to a glass bead column and treatment with carbonyl iron. A series of clonal sublines derived from the parental F17 and F4 cell lines further strengthened this relationship between tumorigenesis and resistance to NK-mediated cell lysis. Tumorigenic subclones from the non-tumorigenic F17 parental cells were demonstrated to be comparatively resistant to NK-mediated lysis. Tumorigenic subclones from tumorigenic F4 parental cell population showed a susceptibility to NK-mediated cell lysis virtually identical to the parental F4 cells. The implication of these results are discussed.     

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.     

TPA induction of EL4 resistance to macrophage-released TNF: role of ADP-ribosylation in tumoricidal activities of TNF and other factors

Activated macrophages synthesize and release numerous tumoricidal soluble factors that can be divided into receptor- or nonreceptor-dependent agents. Tumor necrosis factor (TNF) would be an example of the former. In our experimental model the killing of EL4 thymoma cells by syngeneic activated macrophages involves, but not exclusively, TNF. Our results show that approximately 50% of the anti-EL4 activity expressed by macrophages can be specifically inhibited with rabbit anti-mouse TNF antibody. EL4 variants resistant to the lytic activity of TNF were still susceptible to macrophage-mediated lysis. A tumor-promoting phorbol ester, TPA, rendered TNF-sensitive and -insensitive EL4 cells resistant to M phi-mediated lysis. However, TPA down-regulated TNF-specific binding sites on both TNF-sensitive and -resistant cell surface membranes, suggesting that resistance to TNF involves postligand:receptor events. Tumor cell G-protein involvement (ADP-ribosylation), as a result of TNF-TNF receptor interactions, was investigated. The results showed that pertussis toxin was cytotoxic against TNF-sensitive and -resistant EL4 cells but not against TPA-treated target cells. Inhibitors of ADP-ribosyltransferase inhibited pertussis toxin cytotoxicity and macrophage-mediated lysis but did not interfere with recombinant TNF lytic activity.