RNK granule extract cytolysis: increased tumor susceptibility and release of proteochondroitin sulphate inhibitor in high NaCl

The insensitivity of the natural killer (NK)-resistant L5178Y-F9 murine T-cell lymphoma to granule extracts from a rat NK leukemia could be preferentially reversed in increased NaCl (0.25 M) compared with the NK- and granule extract-sensitive SL2-5. The high salt effect predominated in the binding rather than the lytic phase of the extract reaction similar to the activity of extract inhibitory supernates preferentially produced from L5178Y-F9 cells. Exposure of the L5178Y-F9 to 0.25 M NaCl was associated with an increased production of inhibitory supernate and an increased sensitivity of the cell as an extract target. Pretreatment of inhibitor-containing supernatant or inhibitor-producing L5178Y-F9 cells with pronase or chondroitinase AC reduced the inhibitory activity of the resultant supernates, and L5178Y-F9 supernates treated with anti-chondroitin sulphate AC antibodies exhibited reduced inhibitory activity. These observations and the previously reported molecular weight heterogeneity and protease sensitivity of the inhibitor argue that chondroitin sulphate AC-containing proteoglycans released from the tumor cell surface may inhibit cytolysin activity, contributing to the preferential resistance of the L5178Y-F9 to rat NK granule extract cytolysis.     

Tumor progression in vitro: the paradoxical natural antibody and complement-selected phenotype

An in vitro model of tumor progression was employed to investigate the contribution of natural antibody (NAb) to antitumor resistance in vivo. Repeated cycles of L5178Y-F9 and SL2-5 tumor growth in the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) followed by the selective elimination of sensitive variants through complement-dependent syngeneic NAb lysis yielded tumors with a reduced sensitivity to NAb and complement, natural killer (NK) cells and the rapid elimination assay of natural resistance (NR). A dissection of the resistant phenotype revealed a reduction in the binding capacity of complement-fixing NAb and NK cells, a reduced susceptibility to hypotonic lysis and, paradoxically, increased fluorescence-detected NAb binding that correlated inversely with a reduced tumor frequency of threshold subcutaneous tumor inocula. The data distinguish tumor binding of NAb that leads to complement activation from other NAb binding and expose a difference between NR measured as the tumor frequency of threshold tumor inocula versus the rapid radiolabelled tumor elimination assay. Complement-dependent NAb lysis may not contribute significantly to the defense against small tumor foci; however, NAb-mediated processes associated with high fluorescence-detected NAb binding likely provide resistance.     

Phenotypic alterations in tumors that developed from threshold subcutaneous inocula. I. Reduced binding of natural antibodies and sensitivity to hypotonic lysis

Tumors obtained from the injection site of threshold subcutaneous inocula of L5178Y-F9 or SL2-5 lymphomas in syngeneic mice exhibited increased tumor frequencies and reduced sensitivities to other parameters of natural immune resistance in vivo and in vitro. An examination of the resistant phenotype of cells derived through this model of tumor progression revealed that the more aggressive in vivo grown cells were less able to inhibit natural killer (NK) cell cytolysis and to bind natural antibodies (NAb) measured through fluorescence analysis, although they could not be distinguished from the starting clones by absorption of NAb for complement-mediated lysis. The in vivo grown cells also exhibited a reduced sensitivity to hypotonic lysis, which was not detectable after preincubation at 4 degrees C or upon exposure to sodium azide, procedures that reduced the lysis of the starting clones. The differential susceptibility of the in vivo grown cells was increased to control levels by treatment with cycloheximide or colchicine. These studies suggest that a decreased sensitivity to lysis associated with a reduced autolytic process and an increased counterlytic mechanism, in addition to a reduced antigen expression for binding of NK cells and certain NAb contribute to this resistant phenotype, which may characterize tumors that arise under the selective pressure of natural resistance mechanisms in the natural course of neoplastic development.     

A noncytotoxic mast cell tumor line exhibits potent IgE-dependent cytotoxicity after transfection with the cytolysin/perforin gene

To test the granule exocytosis model for lymphocyte cytotoxicity, we have expressed the gene for the cytotoxic lymphocyte granule protein cytolysin (perforin) in the noncytotoxic rat basophilic leukemia (RBL) cell line, which undergoes granule exocytosis when its high affinity IgE receptor is cross-linked. Homogenates of RBL-cytolysin (RBL-cy) transfectants showed a calcium-dependent hemolytic activity in dense granule fractions, demonstrating that the expressed cytolysin protein was correctly targeted to secretory granules. RBL-cy transfectants showed a potent and calcium-dependent cytolytic activity against IgE-coated RBCs, while the parental RBL line was not cytotoxic under these conditions. RBL-cy cells did not lyse non-IgE-coated RBCs copelleted with targets: this sparing of "innocent bystanders" parallels cytotoxic T lymphocyte lysis and suggests a polarized secretion of cytolysin. In contrast to RBC targets, IgE-coated tumor cells were much less sensitive to lysis by RBL-cy transfectants.     

Resistance of cytolytic lymphocytes to perforin-mediated killing. Murine cytotoxic T lymphocytes and human natural killer cells do not contain functional soluble homologous restriction factor or other specific soluble protective factors

CTL and NK cells produce a cytolytic pore-forming protein (perforin, cytolysin) localized in their cytoplasmic granules. These cytotoxic cells are resistant to killing mediated by other lymphocytes and by purified perforin. A membrane factor, known as homologous restriction factor (HRF), has been suggested to confer protection to different cell types against both C- and perforin-mediated lysis. The granules of human large granular lymphocytes have been reported to contain, in addition to perforin, a soluble HRF activity that can be eluted from anion-exchange columns at 115 mM NaCl. Here, we report that a soluble HRF activity is absent in the granules or the cytosol of murine CTL and human NK cells. Our data indicate that the inhibition attributed to HRF could be explained by exogenous EDTA added during granule fractionation. EDTA was shown to bind to Mono Q and to elute at 90 to 120 mM NaCl. A second perforin-inhibitory activity was also eluted from such a column. However, it was present in preparations obtained not only from CTL and NK cells, but also from some perforin-susceptible tumor cell lines, indicating that it has nonrestricted distribution and suggesting that it is probably irrelevant to the perforin-protection mechanism. Our results argue against a role for soluble granule HRF or other soluble factors in mediating resistance of cytotoxic lymphocytes against perforin-mediated lysis.     

Growth factor-initiated proliferation of mouse embryonic fibroblasts induces cytotoxicity by natural killer cells and by a non-cytolysin cytotoxin in natural killer granules

NK cells preferentially kill normal embryonic fibroblasts. Because embryonic cells are growth factor responsive and maintain high proliferative rates, we examined the requirement for growth factor-initiated proliferation for NK susceptibility. Murine embryonic fibroblasts made quiescent in defined medium lacking growth factors were relatively resistant to NK cytolysis. However, reinitiation of proliferation with basic fibroblast growth factor (bFGF) or epidermal growth factor enhanced lysis in a dose-dependent fashion. TGF-beta, which blocked cell division, did not enhance cytotoxicity. Additionally, growth inhibition by prolonged incubation at confluence suppressed lysis. The enhanced NK cytotoxicity of bFGF-stimulated fibroblasts was caused by a post-binding event because no difference in cold target inhibition could be demonstrated with bFGF-treated cells. NK cytotoxicity has largely been attributed to the action of cytotoxins released from cytoplasmic granules. In a 51Cr release assay, bFGF-treated fibroblasts were insensitive to NK granules isolated from the RNK large granular lymphocyte leukemia. However, these same cells exhibited marked sensitivity to lysis in an 18-h adhesion assay normally utilized to detect TNF-alpha. With the use of this assay, a dose-dependent increase in sensitivity of bFGF-treated fibroblasts was observed, whereas quiescent fibroblasts were resistant to the action of isolated NK granules. Granule cytotoxicity was not caused by cytolysin/perforin because inactivation of granule hemolytic activity with CaCl2 did not affect fibroblast killing, and bFGF-treated cells were insensitive to purified cytolysin/perforin. This suggested that another granule associated cytotoxin was responsible for enhanced NK sensitivity of actively proliferating fibroblasts.     

Analysis of rat natural killer cytotoxic factor (NKCF): mechanism of action and relationship to other cytotoxic/cytostatic factors

Natural killer cytotoxic factor (NKCF) has been proposed as one of the factors that mediates lysis induced by natural killer (NK) cells. Recently, an excellent source of NKCF has been found to be the rat large granular lymphocyte (LGL) tumor (RNK) cell line. In this study, the kinetics of lysis of the NK-sensitive, tumor target YAC-1 by the RNK-NKCF was analyzed and found to parallel that seen with NK cell-mediated killing. RNK-NKCF was also capable of killing the NK-resistant target cell, MBL-2, over a longer time period. This study utilized monoclonal antibodies (mAbs) prepared against granule protein, previously termed "anti-NKCF mAbs." These mAbs established the nature of RNK-NKCF as compared to other known cytotoxic factors in combination with studies that show that RNK-NKCF causes both 51Cr release and nuclear degradation. Antibody inhibition experiments have verified that RNK-NKCF is unique from tumor necrosis factor (TNF), leukoregulin, or complement. Anti-NKCF mAbs were capable, however, of neutralizing the RNK cell granule activity against YAC-1 tumor target cells. Based on these results, the ability of anti-NKCF mAbs to neutralize the cytolytic function of pore-forming protein (PFP), a component of these granules, was analyzed. In these experiments, the antibodies were found to inhibit the hemolytic activity of granules. Interestingly, the antibodies were effective in inhibiting the activity of unbound granule proteins as well as those bound to sheep red blood cell (SRBC) targets. Further studies to examine the target lysis requirements demonstrated that in contrast to PFP, the RNK-NKCF was able to lyse the tumor target in the absence of calcium. In addition, treatment of targets with RNA and protein synthesis inhibitors indicated that the mechanism of lysis of NKCF is quite unique from other defined cytotoxic moieties.     

Cytolytic and biochemical properties of cytoplasmic granules of murine lymphokine-activated killer cells

The incubation of murine spleen cells in the lymphokine interleukin 2 (IL 2) gives rise to lymphokine-activated killer (LAK) cells capable of lysing fresh tumor cells in short-term lytic assays. During the course of cultures used to generate LAK cells, cytoplasmic granules were prepared and were analyzed for the presence of the cytolysin previously described in large granular lymphocytes (LGL) and cytotoxic T lymphocytes (CTL). Such cytolysin activity is initially undetectable, appears after 2 days of culture, and continues to increase until day 7. The LAK cytolysin has properties similar to those of previously described cytolysins with respect to nonspecific killing of various target cells, rapid kinetics, and absolute dependence on calcium. Antibodies raised against purified LGL tumor granules neutralized the activity of the LAK cytolysin. The precursors of both the LAK cells and the cells bearing the cytolysin are eliminated by treatment with anti-asialo-GM1 and complement, strongly suggesting that the actual LAK effector cells and the cytolysin-bearing cells are identical. Biochemical analysis of the LAK granules indicate that they contain the lysosomal enzyme arylsulfatase. The protein content of granules isolated from various days of culture with r-IL 2 undergoes a dramatic change, with major protein bands around 30,000 daltons becoming prominent, as well as the cytolysin protein band at 70,000 daltons. These data suggest that the mechanism of cell lysis by LAK cells is similar to that of CTL and natural killer-mediated lysis, and each of these forms of lymphocyte-mediated cytolysis is based on a granule exocytosis mechanism.     

Cytotoxicity with target DNA breakdown by rat basophilic leukemia cells expressing both cytolysin and granzyme A.

The noncytotoxic rat mast cell tumor line RBL was transfected with genes for the cytotoxic lymphocyte granule proteins cytolysin (perforin) and granzyme A, giving transfectants with mRNA and protein expression levels comparable with cloned cytotoxic T lymphocytes. Both RBL-cytolysin and RBL-cytolysin-granzyme A transfectants showed extremely potent killing of red cell targets and lysed 20%-60% of EL4 lymphoma targets at an effector-to-target ratio of 30. RBL transfectants expressing only granzyme A were not cytotoxic. Significant EL4 DNA breakdown accompanying lysis was observed only with RBL that was transfected with both cytolysin and granzyme A. These results support the granule-exocytosis model for lymphocyte cytotoxicity and show that effector granzyme A plays a role in target cell DNA breakdown.     

Mechanism of lysis by large granular lymphocyte granule cytolysin: generation of a stable cytolysin-RBC intermediate

The effect of ionic strength and pH on the hemolytic activity of large granular lymphocyte granule cytolysin was examined in detail. Cytolysin-mediated lysis of RBC was inhibited by either low ionic strength or low pH. Under these conditions a nonlytic cytolysin-RBC intermediate was formed as revealed by hemolysis when cytolysin pretreated cells were washed and resuspended at physiologic ionic strength and pH. Formation of the cytolysin-RBC intermediate at low ionic strength (250 mM sucrose), pH 7.3, required greater than 0.1 mM calcium. In contrast, formation of the intermediate at physiologic ionic strength (150 mM NaCl), pH 6.0, was calcium independent. Both types of intermediates were stable at 37 degrees C and required calcium to induce subsequent lysis. The degree of lysis of the intermediate generated at low ionic strength was similar to that measured under standard conditions with the use of either whole granule preparations or purified cytolysin. However, lysis of intermediates formed at pH 6.0 was much less efficient. Our data indicate that a stable cytolysin-RBC intermediate can be formed in which cytolysin is present in an unreactive state on the RBC surface; under conditions of physiologic ionic strength and calcium concentrations this intermediate rapidly lyses.     

Calcium-dependent natural killer and calcium-independent natural cytotoxic activities in an IL-2-dependent killer cell line

Using a cloned murine cell line, NKB61A2, that concomitantly exhibits both NK and natural cytotoxic (NC) activities, we investigated the biochemical mechanisms involved in natural cell mediated cytotoxicity against NK-sensitive YAC-1 tumor cells and against the NC-sensitive WEHI-164 tumor cells. Recent reports have suggested that target cell lysis by cytotoxic lymphocytes occurs by either a calcium dependent and/or a calcium-independent mechanism(s). To determine the role of calcium in NK and NC activities of the NKB61A2 cell line, we evaluated the effect of: 1) extracellular Ca2+ depletion by the divalent cation chelator, EGTA, 2) Ca2+ influx blockade by the Ca2+ channel blocker verapamil, and 3) blocking of intracellular Ca2+ mobilization by 3,4,5-trimethoxybenzoic acid 8-(diethylamino)octyl ester (TMB-8). We found that EGTA, verapamil, and TMB-8 were all capable of inhibiting NK activity, but they had little effect on NC activity of the NKB61A2 cells. Using 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine and N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide which are inhibitors of protein kinase C and calmodulin respectively, we determined that protein kinase C and calmodulin do play a role in the NK activity of NKB61A2 cells. 1-(5-isoquinolinylsulfonyl)-2-methylpiperazine and N-(6-aminohexyl)-5-chloro-1-naphthalanesulfonamide, similar to Verapamil and TMB-8, had no effect on NC activity. Thus, the data indicate that the NK activity of NKB61A2 cells is calcium dependent whereas NC activity is not. These results may explain the disparate reports seen in the literature of calcium-dependent and -independent lysis of tumor cells.     

Immediate-early gene expression is sufficient for induction of natural killer cell-mediated lysis of herpes simplex virus type 1-infected fibroblasts.

Herpes simplex virus type 1 (HSV-1)-infected human fibroblast (HSV-FS) targets are susceptible to lysis by natural killer (NK) cells, whereas uninfected FS are resistant to lysis. Studies were undertaken to determine the mechanism of this preferential susceptibility. HSV-FS were not intrinsically less stable than FS, as determined by a 51Cr release assay under hypotonic shock in the presence of rat granule cytolysin and by sensitivity to anti-human leukocyte antigen class I antibody plus complement. Single-cell assays in agarose demonstrated that although similar numbers of large granular lymphocytes bound to the HSV-FS and FS targets, the conjugates with HSV-FS were lysed at a much higher frequency than those with FS. These results suggested that both targets are bound by the NK cells but only the HSV-FS were able to trigger lysis. The requirement for active virus expression was demonstrated by failure of emetine-treated HSV-FS targets or targets infected with UV-inactivated HSV to be lysed by NK effectors. To evaluate the role of viral glycoproteins in conferring susceptibility to lysis, Fab were prepared from HSV-1-seropositive sera; these Fab were unable to block lysis of the HSV-FS. Furthermore, incubation in phosphonoacetic acid failed to reduce NK(HSV-FS) activity despite sharp reductions in viral glycoprotein synthesis. Finally, targets infected with tsLB2 at the nonpermissive temperature were lysed as well as or better than targets infected with wild-type virus, indicating that HSV immediate-early gene product expression is sufficient for conferring susceptibility to lysis. We conclude that expression of nonstructural viral proteins or virally induced cellular gene products early in the course of infection rather than structural glycoproteins is required for NK lysis of HSV-FS targets.     

Analysis of cytostatic/cytotoxic lymphokines: relationship of natural killer cytotoxic factor to recombinant lymphotoxin, recombinant tumor necrosis factor, and leukoregulin

Previous results that were obtained by using supernatants from the co-culture of human peripheral blood lymphocytes and the natural killer susceptible cell line K562 strongly inhibited the growth of various tumor cell lines. No correlation was observed between the susceptibility of the target cell lines to growth inhibition and to lysis by natural killer cells. Rather the spectrum of cytostatic activity and the characteristics of the soluble factor were similar to those of leukoregulin (LRG), a recently described lymphokine. Because of the recent availability of recombinant tumor necrosis factor (TNF) and lymphotoxin (LT), we compare the target selectivity and mechanism of action of these (TNF, LT, LRG) factors with natural killer cytotoxic factor (NKCF). The pattern of target cell susceptibility to growth inhibition or cytolysis by the factors were quite distinct from the pattern observed when cells were exposed to NKCF. Furthermore, antibodies to rLT or rTNF had no effect on LRG cytostasis or NKCF lysis, arguing against a requirement for or synergistic interaction with low levels of LT or TNF. Some of the targets susceptible to LRG were growth inhibited but were not lysed, thereby distinguishing it from NKCF. Furthermore, LRG cytostasis was not inhibited by mannose-6-PO4 or rabbit antibodies to granule cytolysin, both of which block natural killer cytotoxic factor. Therefore, LRG appears to be a cytostatic factor produced by large granular lymphocytes in response to K562 that is distinct from NKCF, TNF, and LT. In addition, NKCF, rLT, rTNF, and LRG, although having cytotoxic/cytostatic activity, are distinct functional factors and may represent a family of lytic factors.     

Liposomes can function as targets for natural killer cytotoxic factor but not for tumor necrosis factor

NK cells exert their lytic action through the release of NK cytotoxic factors (NKCF) after stimulation by the bound target cell. NKCF may be related to granule-derived perforin/cytolysin on one hand and to the pleiotropic cytokine TNF on the other hand. In the present study, we show that NKCF can also lyse artificial lipid vesicles, as had been reported previously for cytotoxic granules and cytolysin. The lysis of large unilamellar vesicles was monitored by measuring the release of the encapsulated fluorescent dye carboxyfluorescein. NKCF-induced lysis was only observed with liposomes composed of a complex mixture of lipids including acidic phospholipids. No lysis could be demonstrated if the liposomes contained phosphatidylcholine as the only phospholipid, suggesting some kind of lipid specificity for the action of NKCF. A remarkable finding was that neither recombinant nor natural TNF were able to lyse large unilamellar vesicles, irrespective of their lipid composition, indicating different ways of interaction of NKCF and TNF with artificial (and presumably also biological) membranes.     

Normal hematopoietic progenitor cells and malignant lymphohematopoietic cells show different susceptibility to direct cell-mediated MHC-non-restricted lysis by T cell receptor-/CD3-, T cell receptor gamma delta+/CD3+ and T cell receptor-alpha beta+/CD3+ lymphocytes

To evaluate the capability of NK cells and cytotoxic T lymphocytes to interact with normal hematopoietic progenitor cells (HPC), as compared to neoplastic lymphohematopoietic cells, we investigated inhibition of colony growth of these cell populations in semi-solid culture systems, after incubation with cloned cytotoxic effector cells. Three different types of cloned effector cells were investigated: TCR-/CD3- NK cells, TCR-gamma delta+/CD3+ cells, and TCR-alpha beta+/CD3+ cytotoxic T lymphocytes. Effector cells showed differential levels of tumor cell colony inhibition, but no MHC-non-restricted lysis of normal HPC was observed. Pre-stimulation of normal HPC by culturing on established stromal layers had no effect. Cell-mediated lysis of HPC only occurred by Ag-specific MHC-restricted lysis by CTL, or by antibody-dependent cellular cytotoxicity. In cell mixing experiments, irradiated tumor cells, but not normal bone marrow cells inhibited tumor cell lysis. Furthermore, cloned effector lymphocytes were able to specifically eliminate malignant cells from tumor contaminated bone marrow without damaging normal HPC. When fresh leukemic cells were used as targets, growth of acute myeloblastic leukemia colonies was inhibited after incubation with several cytotoxic effector clones, whereas chronic myeloid leukemia precursor cells showed limited sensitivity to MHC-non-restricted cytolysis. These results indicate that MHC-non-restricted cytolysis by NK cells is selectively directed against neoplastic cells and not against normal HPC.     

Natural killer cell-mediated lysis involves an hydroxyl radical-dependent step

The role of oxygen radicals in lysis of K562 target cells by human natural killer (NK) cells was determined by addition of scavengers of these free radicals. Lysis was greatly reduced under hypoxic conditions. Superoxide dismutase and cytochrome c, scavengers of superoxide anions, and catalase and scavengers of hypochlorite had no effect on lysis. Of 15 hydroxyl radical scavengers tested, 13 inhibited lysis. These were not toxic, because cell morphology and spontaneous chromium release were not affected and preculture with scavengers was not inhibitory. These scavengers differed widely in structure, but degree of inhibition of lysis correlated with their rate constants (k) for reaction with hydroxyl radical (k vs log inhibitor concentration required to decrease lysis by 50%: r = -0.9202, p less than 0.001), showing that inhibition was due to inactivation of the hydroxyl radical. Target cell binding was not reduced at concentrations that inhibited lysis. Inhibitors of the lipoxygenase pathway also decreased lysis, suggesting this pathway to be the source of hydroxyl radicals. In view of the reported requirements for hydroxyl radical-mediated lipid peroxidation for optimal secretory activity in a number of cell types, it appears that the generation of hydroxyl radicals by NK cells is required for delivery of cytotoxic factors.     

The contribution of alkylation to the activity of quinone antitumor agents

Studies have shown that the quinone group can produce tumor cell kill by a mechanism involving active oxygen species. This cytotoxic activity can be correlated with the induction of DNA double strand breaks and is enhanced by the ability of the quinone compound to bind to DNA by alkylation. The cytotoxic activity and the production of DNA damage by model quinone antitumor agents were compared in L5178Y cells, sensitive and resistant to alkylating agents, to assess the contribution of alkylation to the activity of these agents. The resistant L5178Y/HN2 cells were found to be two fold and six fold more resistant to the alkylating quinones, benzoquinone mustard and benzoquinone dimustard, respectively, than parent L5178Y cells. In contrast, the L5178Y/HN2 cells showed no resistance to the nonalkylating quinones, hydrolyzed benzoquinone mustard and bis(dimethylamino)benzoquinone. The alkylating quinones produced approximately two fold less cross-linking in L5178Y/HN2 cells compared with L5178Y sensitive cells. DNA double strand break formation by hydrolyzed benzoquinone mustard and bis(dimethylamino)benzoquinone was not significantly different in sensitive and resistant cells. However, the induction of double strand breaks by the alkylating quinones benzoquinone mustard and benzoquinone dimustard was reduced by 5-fold and 15-fold, respectively, in L5178Y/HN2 cells. These results show that the alkylating activity of the alkylating quinones cannot directly explain all of the enhanced cytotoxic activity of these agents. Furthermore, they provide strong evidence that the enhanced formation of DNA double strand breaks by alkylating quinone agents is directly related to the ability of these agents to bind to DNA. This increased formation of strand breaks may account for the enhanced cytotoxic activity of the alkylating quinones.     

Monocyte- and natural killer cell-mediated spontaneous cytotoxicity against human noncultured solid tumor cells

Unstimulated human peripheral blood mononuclear cells from healthy donors exhibited spontaneous cytotoxicity against noncultured solid tumor targets in a 12- to 24-hr 51Cr release or 111In release assay. Both purified monocytes (greater than 99% monocytes) and natural killer (NK)-enriched lymphocytes exhibited comparable levels of spontaneous cytotoxicity against fresh melanoma tumor targets. This cytotoxicity was observed under endotoxin-free conditions. NK-depleted lymphocytes did not lyse the melanoma targets. Culture supernatants of monocytes incubated with the melanoma tumor cells did not exhibit cytotoxic activity against these targets. Purified monocytes lacked NK activity against the K562 targets in a 4-hr 51Cr release assay. Treatment of the monocytes with anti-Leu 1 1b and anti-Leu7 monoclonal antibodies plus complement did not reduce monocyte-mediated lysis of the melanoma targets, demonstrating that contaminating NK cells, if any, were not responsible for the lysis of noncultured melanoma targets by monocytes. In contrast, Leu 1 1b+ NK cells were responsible for the lysis of the melanoma targets by NK-enriched lymphocytes. The addition of recombinant interferon-gamma (rIFN-gamma), but not lipopolysaccharide, into the 51Cr release assay or pretreatment of monocytes with rIFN-gamma significantly increased their cytotoxicity against noncultured solid tumor cells. Monocytes cultured for 3 days with medium alone lost their cytotoxic activity. The addition of rIFN-gamma from the beginning of these cultures prevented the loss of the cytotoxic activity of monocytes. In summary, both unstimulated monocytes and NK-enriched lymphocytes exhibit comparable levels of spontaneous cytotoxicity against fresh solid tumor targets.     

IFN-gamma treatment of K562 cells inhibits natural killer cell triggering and decreases the susceptibility to lysis by cytoplasmic granules from large granular lymphocytes

Pretreatment of human K562 leukemia cells with rIFN-alpha and rIFN-gamma resulted in decreased susceptibility to lysis by human peripheral blood NK cells. The reduction of NK-susceptibility after IFN treatment was not due to a general effect of IFN on the stability of the cell membrane because the susceptibility of K562 cells to lysis by antibodies plus C, distilled water, or lysolecithin was unaffected. Binding studies with effector cell preparations enriched for NK cells with large granular lymphocyte morphology revealed no difference in binding to control and IFN-gamma-treated target cells. The sensitivity to soluble NK cytotoxic factors was not affected significantly by the IFN treatment. In contrast, the susceptibility of IFN-treated target cells to the cytotoxic activity of purified cytoplasmic granules from a rat large granular lymphocyte tumor was significantly reduced, indicating that the IFN-induced resistance acted at the level of susceptibility to the lytic mechanism of NK cells. However, IFN-alpha was more effective than IFN-gamma in inducing resistance to the cytoplasmic granules although resulting in only a weak resistance in the cell-mediated cytotoxic assay. IFN-gamma but not IFN-alpha caused a reduction in the frequency of effector cells that had reoriented their Golgi apparatus toward their bound target cell. In addition, IFN-gamma treated K562 cells failed to elicit an influx of Ca2+ into effector cells. Taken together, the results suggest that IFN-gamma in addition to an increased resistance to the lytic molecules released by NK cells can also induce changes in the target cells which prevent the triggering and activation of the effector cell.     

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.