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.     

Increased sensitivity to MHC-nonrestricted lysis of BL6 melanoma cells by transfection with class I H-2Kb gene

An H-2Kb- negative clone of BL6 melanoma (BL6-8) was transfected with neor, H-2Kb, or H-2IAk genes. In an 18-h cytotoxicity assay clones with high levels of H-2Kb Ag expression were found more sensitive to lysis by spleen cells of syngenic and allogeneic mice than H-2Kb low clones. NK cells were involved in the lysis of H-2Kb+ BL6 melanoma clones, with spleen cell cytotoxicity of mice increased after poly I:C stimulation or decreased after pretreatment with anti-asialo GM1 serum or NK1.1 mAb. Anti-TNF Ab were also able to reduce the cytotoxicity of normal spleen cells and completely abolished the cytotoxicity of the NK-depleted spleen cells suggesting involvement of NC cells in lysis of H-2Kb+ BL6 melanoma clones. Increase in sensitivity of H-2Kb+ BL6 cells to natural cell-mediated cytotoxicity was associated with the appearance of NK recognizable determinants as assessed by the cold target inhibition assay. All BL6 clones, irrespective of sensitivity to natural cell-mediated cytotoxicity, showed high sensitivity to lysis by LGL-derived granules. In contrast, all H-2Kb low BL6 clones were resistant and all H-2Kb highly positive clones were sensitive to lysis by TNF-alpha. When an H-2Kb highly positive clone was selected in vitro for resistance to TNF, it concomitantly showed increased resistance to cytotoxicity by spleen cells, confirming the importance of TNF in spleen cell cytotoxicity against H-2Kb+ melanoma cells. Taken together, the data indicate that class I H-2Kb but not class II H-2IAk gene product could increase the sensitivity of BL6 cells to lysis by NK and natural cytotoxic cells as well as TNF. We hypothesize that these effects could be due to pleiotropic effects of H-2Kb gene products on various biologic properties of BL6 melanoma cells some of which may be more directly involved in regulation of tumor cell sensitivity to lysis by NK and/or natural cytotoxic cells.     

Lack of galactose-alpha-1,3-galactose expression on porcine endothelial cells prevents complement-induced lysis but not direct xenogeneic NK cytotoxicity

The galactose-alpha-1,3-galactose (alphaGal) carbohydrate epitope is expressed on porcine, but not human cells, and therefore represents a major target for preformed human anti-pig natural Abs (NAb). Based on results from pig-to-primate animal models, NAb binding to porcine endothelial cells will likely induce complement activation, lysis, and hyperacute rejection in pig-to-human xenotransplantation. Human NK cells may also contribute to innate immune responses against xenografts, either by direct recognition of activating molecules on target cells or by FcgammaRIII-mediated xenogeneic Ab-dependent cellular cytotoxicity (ADCC). The present study addressed the question as to whether the lack of alphaGal protects porcine endothelial cells from NAb/complement-induced lysis, direct xenogeneic NK lysis, NAb-dependent ADCC, and adhesion of human NK cells under shear stress. Homologous recombination, panning, and limiting dilution cloning were used to generate an alphaGal-negative porcine endothelial cell line, PED2*3.51. NAb/complement-induced xenogeneic lysis of PED2*3.51 was reduced by an average of 86% compared with the alphaGal-positive phenotype. PED2*3.51 resisted NK cell-mediated ADCC with a reduction of lysis ranging from 30 to 70%. However, direct xenogeneic lysis of PED2*3.51, mediated either by freshly isolated or IL-2-activated human NK cells or the NK cell line NK92, was not reduced. Furthermore, adhesion of IL-2-activated human NK cells did not rely on alphaGal expression. In conclusion, removal of alphaGal leads to a clear reduction in complement-induced lysis and ADCC, but does not resolve adhesion of NK cells and direct anti-porcine NK cytotoxicity, indicating that alphaGal is not a dominant target for direct human NK cytotoxicity against porcine cells.     

Natural killer activity against cultured human neural tumor and fetal brain cells

Ten human neural tumor lines and three established from normal human brain were analyzed for sensitivities to natural killer (NK) cytolysis. Compared to MOLT-4, fetal brain cells were sensitive, but those from adult brain and eight of ten neural tumor cell lines demonstrated marked NK resistance. The frequencies of target-binding cells (TBC) and single-cell lysis of glioma cells bound within tumor cell conjugates demonstrated that the resistance of two lines was explained either by a decrease in the frequencies of TBC or reduced ability of bound NK cells to lyse the tumor cell conjugates. A third resistant line demonstrated decreases in both TBC and tumor cell conjugate lysis. Two glioma lines with less NK resistance had greater frequencies of TBC or conjugate lysis than the resistant lines. Thus, NK resistance can result from decreased recognition of targets, diminished NK lysis of bound targets, or a combination of both.     

H-2 antigen expression and sensitivity of BL6 melanoma cells to natural killer cell cytotoxicity

The sensitivity of H-2b-high and H-2b-low variants of BL6 melanoma to the cytotoxic action of NK and lymphokine-activated killer cells was investigated. BL6 mouse melanoma cells lack detectable H-2Kb and had low levels of expression of H-2Db Ag. The BL6T2 variant cells, obtained after treatment of BL6 cells with mutagen N-methyl-N-nitro-N'-nitro-soguanidine, had relatively high levels of expression of class I H-2b Ag. Poly(I:C)-stimulated spleen cells of nude mice were highly cytotoxic for BL6T2, whereas H-2b-low BL6 cells were less sensitive to NK activity in an 18-h 51Cr-release assay. Similar results were obtained after 4-h incubation of radio-labeled tumor cells with IL-2-activated effector cells. In contrast, both lines were equally sensitive to lysis by purified granules derived from rat large granular lymphocytes (LGL) or by macrophages. By using various clones selected from BL6 or BL6T2 cells, it was found that BL6 or BL6T2 clones with low H-2b Ag expression were less sensitive to lysis by NK cells than H-2b-high clones. After IFN treatment of either BL6 or BL6T2, the target cells became more resistant to lysis by either NK cells or by purified LGL granules. IFN-treated BL6 cells had substantially increased expression of H-2b Ag and in this respect became similar to untreated BL6T2. However, IFN-treated BL6 cells were more resistant than BL6T2 cells to lysis by NK cells and LGL granules, suggesting that augmentation of H-2b Ag expression and NK resistance could be two independent IFN-induced effects. With a cold target inhibition assay, it was found that BL6T2 or its H-2 positive clones were highly competitive and inhibited the cytotoxic activity of NK and lymphokine-activated killer cells against radiolabeled YAC-1 and BL6T2, whereas BL6 cells or H-2-negative clones of BL6T2 and BL6 lines showed poor competitive ability. Thus, our data indicate that the NK resistance of H-2-low BL6 cells may be due to a paucity of NK recognizable determinants. N-Methyl-N-nitro-N'-nitroguanidine treatment of BL6 melanoma cells was associated with an increase in class I H-2b Ag expression and NK sensitivity, suggesting the involvement of class I MHC Ag in the sensitivity of tumor cells to NK cell-mediated cytotoxicity.     

Tumor growth in vivo selects for resistance to tumor necrosis factor

The relationship between in vivo tumor growth and resistance to TNF in WEHI-164 cells has been examined. When a highly TNF-sensitive clone of WEHI-164 was grown in vivo in syngeneic mice it became resistant to rTNF such that a 4 to 5 log higher concentration of TNF was required to produce tumor lysis in vitro. When compared with an in vitro selected TNF-resistant variant, the in vivo selected line was significantly more tumorigenic. The resistant phenotype of both the in vivo and in vitro selected variants was stable in culture and both selected lines were also resistant to lysis by syngeneic spleen cells with natural cytotoxic activity. The parental clone and the two variants were equally sensitive to lysis by allo-CTL and expressed similar levels of MHC class I Ag. Resistance to TNF in the two variants was not a function of de novo production of TNF measured as supernatant TNF activity or TNF mRNA expression. These studies are the first to demonstrate that in vivo tumor growth results in resistance to TNF and therefore may have direct relevance to the efficacy of TNF in the treatment of human neoplasms.     

Inverse correlation between natural antitumor antibodies and tumor susceptibility in individual xid-bearing mice

Natural antibodies (NAb), natural killer (NK) cells and activated macrophages have all been implicated in the rejection of threshold syngeneic tumor inocula. Previous analysis of tumor susceptibility in normal versus inbred and F1 mice bearing the B cell deficiency associated with the xid mutation of CBA/N mice demonstrated an inverse relationship between the tumorigenicity of the RI-28, a radiation-induced leukemia of the CBA/H strain, and the pooled anti-RI-28 serum NAb levels in mice with the same genetic origins. No relationship with tumor susceptibility was seen with NK cell or in vivo activated macrophage cytolysis. Flow-cytometric determination of antitumor serum NAb bled from individual male and female (CBA/N X CBA/J)F1 mice 1 week prior to the threshold tumor inoculation has revealed extensive heterogeneity within the NAb levels of each sex. A comparative analysis of tumor fate with NAb activity revealed that tumors appeared in only 26.3% of animals with a mean fluorescence channel binding above 60 channels in contrast with 77.3% of animals with lower NAb levels. These data extend to the level of individual hosts the support for an inverse relationship between host NAb activity and tumor susceptibility. In addition, subsequent analysis of serum antitumor NAb levels, splenic NK cytolysis and in vitro lymphokine-activated macrophage activity with all three mediators originating from the same individual F1 mice showed no consistent correlations between these natural resistance activities, arguing for the exclusion of deficiencies in NK cell or macrophage function as the basis for the differential tumor susceptibility in individual F1 mice.     

The isolation of natural killer (NK)-resistant variants of the K562 cell line by mutagenesis and selection with antibodies which inhibit NK cell-mediated lysis

Mechanisms involved in the lysis of tumor cells by natural killer (NK) cells were investigated by using mutagenized K562 targets resistant to the effects of NK cells. K562 cells were treated with the mutagen methyl methanesulfonate (MMS) and, to select for resistant mutants, rabbit anti-idiotypic (anti-id) antibodies were used. This anti-id was raised to a monoclonal antibody 9.1C3 which itself blocked lysis by NK cells by binding to the effector cells; the anti-id inhibited killing by binding to the K562 targets, presumably to a cell surface protein relevant to a secondary event in the NK lytic pathway. MMS-derived mutants showed a heterogeneity of staining with the anti-id, allowing the antibody to be used with flow cytometry to select a population of K562 cells relatively negative in antigen expression. The degree of reactivity of K562 cultures with the anti-id antiserum and the resistance to lysis by NK cells were inversely related. Cultures of NK-resistant K562 cells with low expression of the anti-id structure were cloned by limiting dilution: 96 clones were analyzed and one subclone, C9/2, which was six-to sevenfold less sensitive to lysis than the parental K562 cell line, was used in further studies by cold target inhibition and single cell binding assays. The increased resistance to lysis of C9/2 was not due to a reduced expression of target recognition structures, and resistance could not be overcome by prolonging the time allowed for lysis to 18 hr nor by adding exogenous recombinant leukocyte interferon. Killing of the NK-resistant variant was inhibited by mannose-6-phosphate but not by the monoclonal antibody against which the anti-id antibody was raised. It is therefore suggested that the structure on the K562 cells recognized by the anti-id antibodies is a novel secondary receptor which is important in the later stages of the NK cell cytolytic cascade.     

Distinct effects of interferon-gamma and MHC class I surface antigen levels on resistance of the K562 tumor cell line to natural killer-mediated lysis

Various investigators have examined the relationship between tumor cell susceptibility to natural killer (NK) cell lysis and the expression of HLA class I antigens on the tumor cell. There is controversy as to whether or not an inverse relationship exists, and if so, the basis of the relationship between these two phenomena remains undefined. To address these questions, the genomic clones for two HLA antigens were transfected into the erythroleukemia cell line K562, a cell line that is used as the standard to assess human NK and major histocompatibility complex (MHC) nonrestricted cytolysis. Susceptibility to NK lysis was not affected by the de novo expression of HLA antigens on the K562 after DNA mediated gene transfer. Interferon-gamma (IFN-gamma) treatment of K562 induced levels of MHC class I antigen surface expression comparable to those found on the transfected cells; however, the IFN-gamma-treated cells were resistant to NK lysis. When very high levels of surface HLA antigens were induced on the transfectants, a potential effect of class I MHC expression on K562 lysis could be discerned that was distinct from the resistance to NK lysis induced by IFN-gamma-treatment.     

Drug resistance in rat colon cancer cell lines is associated with minor changes in susceptibility to cytotoxic cells

The development of resistance to anticancer drugs urges the search for different treatment modalities. Several investigators have reported the concomitant development of drug resistance and resistance to natural killer (NK), lymphokine-activated killer (LAK) or monocyte/macrophage cell lysis, while others described unchanged or even increased susceptibility. We investigated this subject in the rat colon carcinoma cell line, CC531-PAR, which is intrinsically multidrug-resistant (MDR), and in three sublines derived from this parental cell line: a cell line with an increased MDR phenotype (CC531-COL), a revertant line from CC531-COL (CC531-REV), which demonstrates enhanced sensitivity to anticancer drugs of the MDR phenotype, and an independently developed cisplatin-resistant line (CC531-CIS). In a 4-h⁵¹Cr-release assay we found no difference in susceptibility to NK cell lysis. No significant differences in lysability by adherent LAK (aLAK) cells were observed in a 4-h assay. In a prolonged 20-h⁵¹Cr-release assay an enhanced sensitivity to aLAK-cell-mediated lysis was observed in the revertant, P-glycoprotein-negative cell line and in the cisplatin-resistant cell line (CC531-CIS). None of the cell lines was completely resistant to lysis by aLAK cells. Therefore, a role for immunotherapy in the treatment of drug-resistant tumors remains a realistic option.     

Human oncogene-transfected tumor cells display differential susceptibility to lysis by lymphokine-activated killer cells (LAK) and natural killer cells

NIH 3T3 tertiary transfectants containing the N-ras or c-Ha-ras oncogenes derived from human tumors were tested for susceptibility to lymphokine-activated killer (LAK) cell and natural killer (NK) cell lysis. N-ras tertiary transfectants contained a human acute lymphocytic leukemia-derived N-ras oncogene. C-Ha-ras transfectants contained either the position 61-activated form of the oncogene (45.342, 45.322, and 45.3B2) or the position 12-activated form (144-162). In 4 hr 51Cr release assays, seven of seven in vivo grown human oncogene transfected NIH 3T3 fibroblasts were lysed by murine LAK effectors, whereas six of seven were lysed by human LAK effectors. There was no difference in susceptibility to lysis between cells transfected with the N-ras oncogene, the position 61 activated c-Ha-ras oncogene, or the position 12 activated c-Ha-ras oncogene. Cultured NIH 3T3 fibroblasts, as well as in vitro and in vivo grown NIH 3T3 tertiary transfectants were resistant to lysis by murine NK effectors and were relatively resistant (4/6 were not lysed) to lysis by human NK effectors. We conclude that human oncogene-transfected tumors are susceptible to lysis by both murine and human LAK cells while being relatively resistant to lysis by murine and human NK cells. Different oncogenes or the same oncogene activated by different point mutations do not specifically determine susceptibility to lysis by LAK or NK. Also the presence of an activated oncogene does not appear to be sufficient for inducing susceptibility to these cytotoxic lymphocyte populations.     

Effect of altered membrane structure on NK cell-mediated cytotoxicity. II. Conversion of NK-resistant tumor cells into NK-sensitive targets upon fusion with liposomes containing NK-sensitive membranes

There is a large body of evidence that supports the notion that NK cells exert important immune surveillance functions in vivo, against a variety of virus-infected and neoplastic cells. However, certain targets are not susceptible to lysis by NK cells. The exact mechanism by which resistance or sensitivity is conferred on target cells is not known. We investigated whether the selectivity to NK lysis is a property of the membrane of the target cell. This was examined by the application of a recently developed method which is aimed at changing the membrane structure of the target cell by cell-liposome fusion. Our studies demonstrate that NK-resistant tumor cells acquired sensitivity to lysis by NK cells after fusion with reconstituted vesicles which contained membrane components derived from NK-sensitive target cells. The fusion required the presence of Sendai virus envelope glycoproteins and exogenous lipids (soybean lecithin and cholesterol) for maximal efficiency. This finding was demonstrated in both the human system (with U937 and Raji as NK-sensitive and -resistant cell lines, respectively) and the rat/murine system (with YAC-1 as NK-sensitive target and P815 and YAC-asc as NK-resistant targets). Both the 51Cr-release assay and the single cell assay showed lysis of the modified target cells in a 3-hr incubation period. The magnitude of the cytotoxic activity was found to depend on the concentration of reconstituted vesicles used in the fusion step. The effect seen was specific because target cells were not lysed when fused with vesicles which contained membrane constituents derived from either NK-resistant targets or NK-sensitive targets from another species (human vs mouse). The resistance of modified target cells to lysis by xenogeneic NK cells was not due to failure of membrane fusion, as detected by immunofluorescence, or to failure to form conjugates. These results demonstrate the feasibility of converting a resistant NK target to a sensitive target by cell-liposome fusion. Furthermore, the data indicate that susceptibility to lysis by NK cells is a property of the membrane composition of the target cell. The significance of these findings is discussed.     

Studies on the mechanism of natural killer cell-mediated cytotoxicity. V. Lack of NK specificity at the level of induction of natural killer cytotoxic factors in cultures of human, murine, or rat effector cells stimulated with mycoplasma-free cell lines

We have proposed that lysis of target cells by NK cells is mediated by NK cytotoxic factors (NKCF). According to our model, for a target cell to be NK-sensitive, it must be recognized by the NK cell, it must stimulate the release of NKCF, and it must be sensitive to lysis by these factors. This report examines whether the ability to stimulate release of NKCF is a characteristic restricted to NK-sensitive tumor cells or whether it is also a property of NK-resistant target cells. Many different types of cell lines were tested for their ability to stimulate release of NKCF in the human, rat, and murine systems. It was found that mycoplasma-free NK-sensitive cell lines, resistant cell lines, and Con A could stimulate the release of NKCF. Many different types of cell lines grown in suspension or in monolayers were found to be effective stimulators, including T or B lymphoid, myeloid, and those of histiocytic origin. Cells cultured in the absence of serum stimulated NKCF release, thus ruling out the possible involvement of serum components in stimulation. NKCF was also produced by xenogeneic combinations of effector and stimulator cells, demonstrating lack of species specificity in NKCF production. Factors stimulated by NK-resistant cell lines or by Con A exhibited the same NK target specificity as supernatants stimulated by NK-sensitive tumor cells. The finding that many different NK-resistant cell lines can stimulate the release of NKCF indicates that there is no apparent NK specificity at the level of induction of NKCF release from human, rat, or murine effector cells. Therefore, the NK specificity of a target cell is determined ultimately by its sensitivity to lysis by NKCF.     

Reduced humoral and cellular cytotoxic sensitivity in major histocompatibility variants of the YAC (Moloney) lymphoma

Previously we have reported that two sublines of the YAC lymphoma selected for reduced expression of H-2^a and Moloney-virus determined cell-surface (MCSA) antigens are, in contrast to YAC, allotransplantable in H-2-incompatible recipients, and resistant to rejection by preimmunized semisyngeneic hosts. A third YAC variant with reduced MCSA but unchanged H-2-antigen expression, was not allotransplantable and showed only a slight decrease in its immunosensitivity in preimmunized semisyngeneic hosts in vivo. This suggested that H-2-antigen expression may be more important than MCSA expression for recognition and rejection by semisyngeneic mice. We have now tested the sublines expressing low H-2^a for their in vitro sensitivity to humoral and cell-mediated lysis. — The variants were more resistant than YAC to complement lysis by anti-H-2^a, anti-MCSA, anti-Thy 1.2 and antispecies sera. Absorption tests with antispecies serum indicated that the decreased cytolytic sensitivity of the variants was not related to the concentration of the relevant antigens, which was similar to that of the original YAC tumor. As expected from the low amount of H-2^a the variants showed a decreased sensitivity to the killing effect of allogeneic cytotoxic T lymphocytes (CTL). They were also lysed to a lesser extent than YAC by semisyngeneic CTL, probably directed against virally determined antigens. However, they were also less sensitive to lysis by natural killer (NK) cells, although NK lysis is probably unrelated to MHC expression. In conclusion, our selection for reduced H-2-expression appears to have resulted in the isolation of variants with a generally increased resistance to various humoral and cell-mediated lytic functions.On leave from Instituto Venezolano de Investigaciones Cientificas (IVIC), Caracas, Venezuela.     

Segregation of the NK-sensitive phenotype in human x mouse somatic cell hybrids reveals separate genetic control of recognition and postrecognition determinants

In an attempt to investigate the nature of tumor cell-derived membrane surface determinants involved in natural killer cell (NK) recognition or postrecognition events, we have constructed human X mouse interspecies somatic cell hybrids. Highly NK-sensitive (NKs) human tumor cells were fused with NK resistant (NKr) mouse fibroblasts (LMTK-) in polyethylene glycol and selected in hypoxanthine/aminopterin/thymidine medium and ouabain. Hybrids generated from NKs erythroleukemia cells (K-562) or NKs retinoblastoma cells (Y-79) with LMTK- displayed an intermediate NK-sensitive phenotype. One Y-79 X LMTK- hybrid (YL-22) retained a high level of susceptibility to NK binding and cytolysis, as determined by 51Cr release and in cold-target inhibition assays. On the other hand, human NKr RAJI cells generated NK-resistant hybrids when fused with LMTK- fibroblasts. Four hybrids (KL-12, YL-2, YL-22, and YL-43) displaying consistent NK sensitivity were subsequently cloned by limiting dilution. Various hybrid clones derived from the KL-12 hybrid (K-562 X LMTK-) demonstrated a range of NK-sensitive phenotypes. However, the uncloned KL-12 and most cloned lines derived from this hybrid competed against 51Cr-labeled K-562 targets as well as unlabeled K-562 parental cells, regardless of their NK-sensitive phenotype. These findings raise the possibility that chromosomal segregation may be affecting a postbinding step in this hybrid system. The NK-sensitive hybrids exhibited a limited number of human chromosomes as assessed by quinacrine banding. Furthermore, human transferrin receptor (TfR) expression, as monitored by flow cytometry using the B3/25 monoclonal antibody, demonstrated no clear correlation with NK sensitivity or competitive ability in either KL or YL hybrid clones, thus arguing against the involvement of the TfR in human NK recognition. These results suggest that the NK-sensitive phenotype in human tumor cells may be regulated by genes encoded by a limited number of human chromosomes.     

Murine trophoblast resists cell-mediated lysis. II. Resistance to natural cell-mediated cytotoxicity

The susceptibility of murine trophoblast cells to natural cell-mediated cytotoxicity has been assessed. Primary short-term cultures of murine trophoblast cells isolated from 14-day placentas were found to be resistant to endogenous and interferon-activated natural killer (NK) cells and natural cytotoxic cells. That the relevant target structures are expressed on the surface of trophoblast cells and accessible to the effectors was demonstrated by their ability to inhibit the lysis of NK-sensitive target cells (YAC-1) in a dose-dependent manner. The lytic resistance of trophoblast cells was unaffected by neuraminidase treatment, inhibition of protein synthesis, or extending the assay time to 12 hr. Moreover, trophoblast cells were resistant to antibody-dependent cell-mediated cytotoxicity when coated with an alloantibody capable of mediating their lysis in the presence of heterologous complement. Neither the preincubation of effector cells in concentrated trophoblast culture supernatants nor the direct exposure of effectors to monolayers of trophoblast cells inhibited their NK lytic activity, indicating that the secretion of a suppressive factor or the direct inactivation of the NK cells was not responsible for the observed resistance to lysis. These observations, together with previous results showing the resistance of trophoblast to cytotoxic T cell-mediated lysis, reveal that murine trophoblast cells possess a resistance mechanism against several forms of cell-mediated lysis. This feature of trophoblast cells at the maternal-fetal interface is likely to play an important role in protecting the fetoplacental allograft from immune rejection.     

Tumorigenicity of persistently infected tumors in nude mice is a function of both virus and host cell type.

Although BHK-21 cells persistently infected with wild-type vesicular stomatitis virus (VSV) are sensitive to natural killer (NK) cells and do not form tumors in athymic nude mice, BHK-21 cells persistently infected with a previously isolated mutant virus (VSV-P) are resistant to NK cells and form tumors in nude mice. We used this VSV-P mutant to persistently infect HeLa cells and mouse tumor cell lines. A mouse mastocytoma line (P815) persistently infected with VSV-P was similar to BHK-21 cells in that it was resistant to NK cell lysis and formed tumors in nude mice. However, neither HeLa cells nor mouse myeloma lines persistently infected with VSV-P were resistant to NK cell lysis in vitro, and neither formed tumors in nude mice. Rejection by nude mice of HeLa cells and mouse myeloma cell lines persistently infected with VSV-P could be ablated by rabbit antiserum to asialo-GM1, implicating NK cells in the in vivo rejection of these persistently infected tumors. These results suggest that NK cell recognition and killing of virus-infected cells in vivo and in vitro depend upon genetic contributions from both the virus and the host cell.     

Ultraviolet light-induced increase in tumor cell susceptibility to TNF-dependent and TNF-independent natural cell-mediated cytotoxicity

Previously we demonstrated that two consecutive in vitro irradiations of MCA 102 cells with high doses of UVC light (610 and 457 J/m2) resulted in a selection of a permanent line MCA 102UV that manifested high sensitivity to natural cell-mediated cytotoxicity (NCMC). In the present study analysis of the effector cells involved in lysis of these tumor cells was performed by comparing the cytotoxicity of normal spleen cells which mediated both NK and NC cell activity with (a) normal spleen cells in which NC activity was neutralized by anti-TNF Abs (NK+,NC-), (b) NK-depleted or NK-deficient spleen cells (NK-,NC+), and (c) NK-deficient or -depleted spleen cells with NC activity neutralized by anti-TNF Abs (NK-,NC-). Results of these studies indicate that lysis of the original MCA 102 tumor cells was relatively low and was mediated by NC cells. UV irradiation significantly increased MCA 102 tumor cell sensitivity to lysis by both NK and NC cells. Analysis of the mechanisms involved in UV-induced NK sensitivity revealed that UV irradiation increased tumor cell susceptibility to lytic NK-derived granules. NC sensitivity of MCA 102UV tumor cells was associated with their increase in sensitivity to TNF and selection of MCA 102UV cells for resistance to rTNF resulted in a decrease in their susceptibility to NC cells. To determine how fast UV-induced sensitivity to NCMC and rTNF can be established, 51Cr-labeled MCA 102 cells were irradiated in vitro with 38-304 J/m2 of UVC light and their sensitivity to lysis by spleen cells and rTNF was tested immediately in an 18-hr cytotoxicity assay. UV treatment with the same doses was repeated 12 days later. The data obtained showed that tumor cell sensitivity to NCMC and TNF appeared shortly after UV irradiation, was stable, and was further substantially augmented by the second round of UV treatment. Thus, in vitro UV irradiation of tumor cells could be an effective modulator of tumor cell sensitivity to TNF-dependent and TNF-independent cell-mediated cytotoxicity.     

Cell lines cultured at high density are resistant to lysis by tumor necrosis factor and natural cytotoxic cells

It has been suggested that natural cytotoxic (NC) cell activity and tumor necrosis factor (TNF), the molecular mediator of NC activity, are capable of protecting individuals against the progression of incipient tumors or could be useful in cancer therapy regimens. Much of this speculation arises as a result of in vitro studies, on a variety of tumor cells, demonstrating the cytolytic and cytostatic properties of NC and TNF activities. Here, evidence is presented showing that certain mouse fibroblast cell lines, generally considered sensitive to NC and TNF lysis, are quite resistant to these lytic activities when cultured at high cell density. Although a soluble factor that renders these same target cells resistant to NC and TNF lysis has been described, no such factor is involved in this high density-induced resistance. Rather, it appears that cell to cell contact of the targets is critical. Moreover, the induced resistance to NC and TNF lysis does not result from loss of either NC recognition determinants or TNF receptors by the target cells, but is the consequence of increased expression of a protein synthesis-dependent resistance mechanism. These observations raise the issue of the in vivo phenotype of cells characterized in vitro as sensitive to NC and TNF lysis. It is entirely possible that certain cells which are considered sensitive to NC and TNF activities are, in fact, resistant to these cytolytic activities when growing as tumors (i.e., at high cell density). Should this be the so, NC and TNF cytolytic activities may not function in vivo or may function only via some indirect means.