Natural cytotoxicity of human blood monocytes and natural killer cells and their cytotoxic factors: discriminating effects of actinomycin D

The effect of actinomycin D on target susceptibility to human blood natural killer (NK) cells and monocytes was analysed in direct cell-mediated and their cytotoxic factor-mediated cytotoxicity assays. Treatment of K562 cells with actinomycin D reduced their susceptibility to lysis by non-adherent lymphocytes and Percoll-purified large granular lymphocytes (LGL) in a 4-hr 51Cr-release assay, without affecting their sensitivity to monocytes purified by adherence to autologous serum-coated plastic surfaces. The drug treatment caused no shift in the kinetics of cytotoxicity. In the target binding assay LGL formed fewer conjugates with actinomycin-D-treated K562 cells than with untreated ones, while the binding of monocytes to targets was not reduced by the drug treatment of K562 cells. The cold target competition assay revealed that actinomycin-D-treated cold K562 cells showed less successful inhibition than untreated cold K562 cells. Lymphocytes and monocytes could be induced to release soluble cytotoxic factors, termed natural killer cytotoxic factors (NKCF) and monocyte cytotoxic factors (MCF), respectively, when co-cultured with K562 cells. Both cytotoxic factors lysed NK-sensitive target cells in a 48-hr assay. Actinomycin-D-treated K562 cells reduced or abolished the ability to stimulate the release of NKCF from lymphocytes, whereas they induced MCF secretion from monocytes as effectively as untreated ones. On the other hand, actinomycin D treatment of K562 cells enhanced their susceptibility to NKCF and MCF. This actinomycin-D-induced augmentation of target sensitivity to the cytotoxic factors was restricted to NK-sensitive target cells (K562 and Molt-4). NK-resistant target cells (Raji, YAC-I, EL4 and T blasts) were not lysed by NKCF and MCF even after they were treated with actinomycin D. The capacity of K562 cells to bind NKCF and MCF was not altered by actinomycin D. Treatment of the adherent cell population with OKMI or Leu-MI plus complement abrogated both cell-mediated cytotoxicity and MCF production, while Leu-IIb plus complement was ineffective. These results suggest that the effect of actinomycin-D treatment can be used to distinguish the two distinct types of blood mononuclear cells with natural cytotoxicity, NK cells and monocytes, and that each effector type recognizes different plasma membrane moieties of NK target cells, although the cytotoxic factors released from each effector cell similarly bind to and lyse the target cells.     

Tumor necrosis factor as effector molecule in monocyte mediated cytotoxicity

A newly developed assay system which uses actinomycin D (Act D) pretreated Wehi 164 target cells allows for the measurement of human monocyte cytotoxicity in a 7-h 51Cr release assay. Using the monocyte specific monoclonal antibody M42 in a direct rosetting procedure we confirm herein that among human peripheral blood mononuclear cells cytotoxicity is restricted to monocytes. When applying stringent conditions that exclude exogenous lipopolysaccharide (LPS) we could demonstrate that as little as 0.1 ng of LPS per ml triggers this cytotoxicity. Further, a factor can be detected in supernatants of mononuclear cells which is also cytotoxic against Act D treated Wehi 164 cells. This cytotoxic factor can be triggered by LPS within 4 h, but at as low a LPS concentration as 0.001 ng/ml. Since one of the LPS triggered monocyte products is tumor necrosis factor (TNF), we tested the effect of recombinant TNF cloned from the U937 cell line and we could show potent lytic activity against Act D pretreated but not, or only minimally, against untreated Wehi 164 target cells. Recombinant TNF rapidly lysed the target with significant specific release occurring as early as after 3 h in the assay. By contrast, recombinant interleukin 1 gave no lysis while lymphotoxin derived from the RPMI 1788 cell line was effective. An affinity purified antiserum directed against TNF neutralized the lytic activity of recombinant TNF and also the cytotoxic factor produced by LPS triggered mononuclear cells, while the antiserum was ineffective against lymphotoxin. Further, the antiserum when added to the assay of effector cells and Act D treated Wehi 164 cells also completely ablated cytotoxic activity. Size fractionation of cytotoxic factor and recombinant TNF by high pressure liquid chromatography led to a superimposable peak of cytotoxicity in the molecular weight range of 9,500-17,000. Further, immunoblotting with the anti-TNF antibody revealed the same Mr 15,500-16,500 band for the recombinant TNF and LPS triggered cytotoxic factor. Taken together, our data demonstrate that the cytotoxic activity of human monocytes against Act D treated Wehi 164 is mediated entirely by a LPS triggered molecule that is very similar or identical to the human tumor necrosis factor. The assay system thus provides a powerful tool to analyze the biology of TNF in humans.     

Natural cytotoxicity of human blood lymphocytes and monocytes and their cytotoxic factors: effect of interferon on target cell susceptibility

The effect of interferon (IFN) on target cell susceptibility to human natural killer (NK) cells and monocytes was analyzed in direct cell-mediated and their cytotoxic factor-mediated cytotoxicity assays. Treatment of K562 cells with IFN resulted in a decrease in their sensitivity to lysis by nonadherent lymphocytes and Percoll-purified large granular lymphocytes (LGL) when tested in a 4-hour 51Cr release assay. In contrast, the treatment did not affect the target susceptibility to monocytes purified by adherence to autologous serum-coated plastic surfaces. In the target-binding assay with LGL or monocytes the number of conjugates was not altered after IFN treatment of K562. Lymphocytes and monocytes were induced to release soluble cytotoxic factors, termed "natural killer cytotoxic factors (NKCF) and monocyte cytotoxic factors (MCF)," respectively, when co-cultured with K562. Both NKCF and MCF lysed K562 in a 48-hour microcytotoxicity assay or in an 18-hour 51Cr release assay in the presence of dactinomycin. IFN-treated K562 reduced or completely lost their ability to stimulate the release of NKCF, whereas they triggered MCF secretion as effectively as did the untreated K562. When lymphocytes or monocytes were pretreated with IFN, they released NKCF or MCF with augmented lytic activity. In contrast to the sensitivity to NK cell-mediated lysis, IFN pretreatment of K562 induced no change in their susceptibility to NKCF and MCF. When IFN was added to NKCF and MCF assays, the cytotoxicity was enhanced. The addition of IFN to K562 that had been pretreated with NKCF or MCF and washed resulted in no increase in lysis. The capacity of K562 to absorb the lytic activity of NKCF and MCF was not altered by IFN. These results indicate that IFN treatment of target cells can be used to distinguish the two distinct types of blood mononuclear cells with natural cytotoxicity, NK cells and monocytes, and that each effector cell type is stimulated to release cytotoxic factors by the different target determinant after the initial effector-target cell binding.     

Release of natural killer cytotoxic factor in patients with lymphoproliferative disease of granular lymphocytes

To further investigate the mechanisms accounting for defective natural killer (NK) activity observed in the majority of patients with lymphoproliferative disease of granular lymphocytes (LDGL), we have studied the generation of natural killer cytotoxic factor (NKCF) from peripheral blood lymphocytes recovered from twelve LDGL patients. On the basis of their cytotoxic activity against the K-562 target cells, cases under study were separated in two groups. Cells from five patients, referred to as NK+, were found to exhibit high levels of NK-cell mediated cytotoxicity; cells from seven patients, referred to as NK-, despite their ability to bind to the K-562 targets, displayed a defective NK function. The coculture of cells from NK+ patients with NK sensitive K-562 cells triggered a significantly higher production of NKCF with respect to NK- patients (p less than 0.001 at 1:2 dilution). Using phytohemagglutinin (PHA) as the NKCF stimulator, differences between the groups were not significant, due to a recovery of NKCF generation in NK- patients. Furthermore, a consistent lectin (PHA) dependent cellular cytotoxicity (LDCC) was exhibited by both groups of patients. The addition of gamma-interferon (IFN-gamma) or interleukin-2 (IL-2) during NKCF generation did not significantly modify the production of this factor. Our data point out that (a) NKCF is involved in the lytic activity of LDGL patients' cells, (b) a constitutional impairment in the generation of NKCF is not present in NK- patients, since recovery of lytic function occurs after PHA stimulation, and (c) IL-2 and IFN-gamma do not play a relevant role in triggering NKCF production when added during the generation of this factor. These studies help to clarify the factors involved in the cytotoxic machinery of LDGL patients' cells, suggesting that the defect of the cytotoxic function observed in some LDGL patients could lie at the level of target recognition.     

Human natural cytotoxic activity mediated by tumor necrosis factor: regulation by interleukin-2

Freshly obtained normal lymphoid cells kill certain tumor target cells in vitro. Using peripheral blood lymphocytes (PBLs) and the human tumor target cell line BT-20, we have defined a tumor necrosis factor (TNF)-dependent, cell-mediated cytotoxic mechanism that is homologous to the murine natural cytotoxic (NC) cell activity. Human NC cell activity was detected in freshly isolated PBLs and was augmented by short in vitro pulses with recombinant human interleukin-2 but not with recombinant human alfa interferon. Monoclonal anti-TNF antibodies inhibited the killing of the target cells. The independence of interferon and the mediation of killing by TNF distinguish human NC cell activity from natural killer and lymphokine-activated killer cell activities.     

Sera from patients with colon, breast and lung cancer induce resistance to lysis mediated by NK cytotoxic factors (NKCF)

Natural killer (NK) cells are involved in the antitumoral immunologic mechanism. These cells act through the release of cytotoxic molecules defined as NK cytotoxic factors (NKCF). Inhibitory factors of NK and NKCF mediated lysis have been described in in vitro assays. This study evaluates the induction of resistance to NKCF cytotoxicity by sera from 27 patients with colon, breast and lung cancer. Addition of these sera to the cytolytic assay where K562 cells and concentrated NKCF were used, induced resistance to NKCF mediated cytotoxicity in 21 cases (77%). The sera from the group with metastasis blocked NKCF lysis more markedly than the group with local tumours. However, no differences were observed when the groups with colon, breast and lung cancers were compared. This blocking effect was not found to be related to gamma interferon (IFN) levels. In a previous study, we described a tumour factor (NK-RIF) produced by human cell lines derived from metastatic adenocarcinomas. This factor blocked lysis of tumour target cells by NK cells. Consequently, it is proposed that the release of similar tumour factors with a capacity to induce resistance to NKCF may be involved in tumour growth and metastatic spreading in in vivo.     

Natural killer cytotoxic factor induction by K562 cells in patients with advanced cancer: correlation with production of interferon

Advanced cancer patients were studied for their ability to produce natural killer cytotoxic factor (NKCF). Of 23 patients with advanced epithelial cancers, 8 showed deficient natural killer (NK) activity, as measured in a standard 51Cr release assay. Lymphocytes from these patients did not generate NKCF (nonproducers) in the presence of K562 cells. In addition, 7 other patients whose NK activity was in the normal range did not generate NKCF. Thus the deficiency in NKCF production was only partially correlated with the level of NK activity. Supernatants generated for NKCF were also assayed for antiviral activity. Mean interferon (IFN) titer of supernatants generated from peripheral blood lymphocytes (PBL) of cancer patients was significantly lower than that of supernatants generated by PBL from normal donors. Supernatants from 10 of 15 NKCF nonproducers contained no detectable IFN, whereas the remaining 5 contained up to 100 U IFN. NKCF was never generated in the absence of IFN. The defect in NKCF production by PBL from cancer patients could be corrected by the incubation of effector cells with exogenous IFN-alpha or IFN-alpha inducers, such as other tumor cells or viruses. The relationship among NKCF, IFN, and NK activities is discussed.     

The interaction between recombinant human tumor necrosis factor and radiation in 13 human tumor cell lines

Tumor necrosis factor (TNF) was cytotoxic at concentrations of 10 to 1000 units/ml to 12 of 14 human tumor cell lines. Synergistic or additive cell killing between TNF and radiation was observed in 7 of 10 tumor cell lines, while independent tumor cell killing by each agent occurred in two tumor cell lines. The maximum synergistic effect was observed when TNF was added 4-12 hr prior to irradiation. This interaction was absent when TNF was added after irradiation. TNF also reduced potentially lethal damage repair in 3 of 5 cell lines tested. Possible mechanisms of interaction of TNF and X rays including induction of hydroxyl radicals and subsequent DNA damage by TNF and radiation are discussed.     

Synergistic action of a plant rhamnogalacturonan enhancing antitumor cytotoxicity of human natural killer and lymphokine-activated killer cells: chemical specificity of target cell recognition.

The spontaneous natural killer (NK) and lymphokine-activated killer (LAK) cytotoxicity of highly purified CD56+CD3- NK cells (90 to 95%) against NK-sensitive and NK-insensitive target cells was drastically enhanced when a rhamnogalacturonan contained in a commercially available Viscum album extract was present during 4-h cytotoxicity assays. This enhancement correlated strictly with an increased formation of NK cell or LAK cell/tumor cell conjugate formation. Information on the chemical specificity of NK cell and LAK cell interaction with target cells and with the rhamnogalacturonan was obtained from inhibition studies. The most efficient inhibitors (100% inhibition at 5 mg/ml) were acetylated D-mannose and acetylated L-mannonic acid gamma-lactone. They specifically inhibited in a dose-dependent manner: (a) the cytotoxicity of NK cells against K562 cells and the formation of NK cell/K562 cell conjugates; (b) the cytotoxicity of LAK cells against K562 cells and Daudi cells as well as the formation of LAK cell/K562 cell and of LAK cell/Daudi cell conjugates; and (c) the synergistic effects of the rhamnogalacturonan in the cytotoxicity assays and the target cell-conjugate formation assays with NK cells and LAK cells. The inhibitory effects observed after pretreatment of NK cells or LAK cells with acetylated mannose were completely reversible, but that obtained with acetylated mannonic acid gamma-lactone was only partly reversible, and the degree of reversibility depended on the inhibitor concentration applied during pretreatment. Nonacetylated mannose or mannose derivatives up to concentrations of 20 mmol showed no inhibitory effects. A mechanistic model representing the interaction of NK cells and LAK cells with target cells and with rhamnogalacturonan is proposed.     

Significance of cytotoxic activity of peripheral blood lymphocytes against autologous tumor cells in patients with bladder cancer

Cell-mediated immunity is an important and central mechanism of host resistance to cancer. Most reported studies have used cultured tumor cell lines as targets to assess antitumor cell-mediated cytotoxicity. However, it is difficult to translate the data generated from the cytotoxic activity against cultured tumor cell lines to cytotoxicity against autologous tumors. In a recent study, we have reported on the prognostic significance of circulating cytotoxic lymphocytes against autologous tumor cells in patients with bladder cancer. In this study, we examined whether established bladder cancer cell line like T24 or NK-sensitive K562 target cells can be substituted for autologous bladder cancer cells. The cytotoxic activity of peripheral blood lymphocytes (PBL) against freshly isolated autologous tumor cells, the T24 human bladder cancer cell line and the NK-sensitive K562 human myelogenous leukemia cell line was studied in 63 patients with primary initial bladder cancer by a 12-h 51Cr release assay. The mean percent cytotoxic activity of PBL directed against autologous tumor cells, T24 cells and K562 cells were 11.3%, 18.2% and 29.4%, respectively, using an E:T of 40:1. The cytotoxic activity against T24 cells in patients with bladder cancer was higher than that in normal individuals. The anti-K562 and the anti-T24 cytotoxic activities in patients with low-stage or low-grade bladder cancer were relatively higher than those in patients with high-stage or high-grade cancer, but not statistically significant. There was no correlation between the anti-autologous tumor cytotoxic activity and either the histologic grade or stage in patients with bladder cancer. The extent of the anti-autologous tumor cytotoxic activity was not paralleled with that of either the anti-K562 or the anti-T24 cytotoxic activity. In contrast, the anti-K562 cytotoxic activity correlated positively with the anti-T24 cytotoxic activity. Separation of PBL revealed that the anti-K562 and the anti-T24 cytotoxic activities were mediated mainly by the NK cells, whereas the anti-autologous tumor cytotoxic activity was mediated by both the NK cells and the T lymphocytes. These findings demonstrate that cytotoxicity against T24 or K562 cells is not of prognostic value. The magnitude of the anti-autologous tumor cytotoxic activity of PBL derived from bladder cancer patients might represent an independent and important immunological parameter to monitor disease progression.     

Synergistic effects of recombinant human tumor necrosis factor and hyperthermia on in vitro cytotoxicity and artificial metastasis

Synergy in cytotoxic effect between recombinant human tumor necrosis factor and hyperthermia (incubation at 38.5 degrees C or 40 degrees C) was observed to occur against L-M (mouse tumorigenic fibroblast) cells and shown to be related to an accelerated turnover rate of recombinant human tumor necrosis factor-receptor complex under elevated temperatures rather than to changes in number of cell receptors or binding strength. However, no synergy in cytotoxic effect was observed to occur against human embryonic lung (HEL) cells. A clearly synergistic inhibition of metastatic tumor growth by combined administration of recombinant human tumor necrosis factor (300 units) and whole-body hyperthermia (40 degrees C, 30 min) was also observed in BALB/c mice previously given injections of 1 x 10(6) Meth-A (MH) cells/mouse via tail vein, neither of which alone resulted in significant inhibition.     

Characterization of human tumor necrosis factor produced by peripheral blood monocytes and its separation from lymphotoxin

Cultures of human peripheral blood leukocytes (PBL) induced with phytohemagglutinin (PHA) and the phorbol ester 12-0-tetradecanoylphorbol 13-acetate (TPA) produced two types of cytotoxic proteins, indistinguishable in the in vitro assay employing murine L 929 cells as targets. One of these proteins had the antigenic and physicochemical properties of lymphotoxin (LT). We have identified the other cytotoxin as tumor necrosis factor (TNF), mainly on the basis of antigenic cross-reactivity demonstrated with antiserum to TNF, and also by its characteristic physicochemical properties and cell source. Unlike LT, PBL-derived TNF did not bind to Concanavalin A-Sepharose or to several other agglutinin-Sepharose columns specific for carbohydrate moieties common in glycoproteins. The molecular weight of native TNF determined by gel filtration was approximately 40,000 while SDS-PAGE revealed a single sharp peak of 16,500 +/- 500. When cultures of monocytes and lymphocytes separated by elutriation were stimulated with PHA and/or TPA, monocytes were the major source of TNF. In contrast, only lymphocytes produced LT. A mixture of antisera to TNF and LF neutralized all cytotoxicity of crude human lymphokine preparations for L 929 cells, suggesting that TNF and LT are either the only, or the major, cytotoxic proteins present in such crude lymphokine preparations demonstrable in this assay.     

Differential activation of lymphokine-activated killer cells with different surface phenotypes by cultivation with recombinant interleukin 2 or T-cell growth factor in gastric cancer patients

Fourteen days' culture of human peripheral blood lymphocytes (PBL) with recombinant interleukin 2 (rIL 2) or T cell growth factor (TCGF) results in the generation of lymphokine-activated killer (LAK) effector cells which have the unique property of lysing natural killer (NK)-resistant human tumor cells, Daudi, as well as NK-sensitive, K562 cells. LAK cells were generated from both normal and gastric cancer patients' PBL. However, LAK cell activities induced by rIL 2 or TCGF decreased with the progress of the tumor growth. In addition, TCGF-induced LAK cell activities were found to be lower than the rIL 2-induced LAK cell activities. Different mechanisms may be involved in the decreases of the rIL 2-induced and TCGF-induced LAK cell activities. This study further demonstrates that the cell types involved are also heterogeneous, as determined by phenotypic characteristics. The LAK-effector cell type was analyzed by two-color flow cytometry. RIL 2-induced LAK cells showed increased proportions of CD4+Leu 8- and Leu 7+CD16-, and a decreased proportion of CD8+CD11- cells, which are believed to be associated with killer T cell functions. In contrast, TCGF-induced LAK cells revealed significantly increased proportions of CD8+CD11- and CD4+Leu8- cells, and a decreased proportion of Leu 7+CD16- cells. Thus, LAK cells with different surface phenotypes were induced by the cultivations with rIL 2 and with TCGF.     

Comparison of recombinant tumor necrosis factor and the monocyte-derived cytotoxic factor involved in monocyte-mediated cytotoxicity

A direct comparison of recombinant tumor necrosis factor (rTNF) and the monocyte-derived cytotoxic factor (CF) which is involved in monocyte-mediated cytotoxicity revealed immunological, physiochemical, and biological similarities, indicating that TNF is an effector molecule in monocyte-mediated cytotoxicity. Neutralizing antiserum raised against rTNF completely inhibited the ability of CF-containing monocyte supernatants to induce cytolysis and cell death of sensitive target cells and, conversely, antiserum raised against purified CF completely inhibited the cytotoxic activity of rTNF. Both CF and rTNF have an apparent isoelectric point of 5.8-5.9 as determined by chromatofocusing, and a molecular weight of about 40,000 as determined by gel filtration. Moreover, when present in monocyte supernatants with a total protein concentration of about 1 mg/ml and 0.1% sodium dodecyl sulfate, both CF and rTNF migrated with a molecular weight of about 35,000 upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Pure rTNF, however, migrated with a molecular weight of 17,000, suggesting that the relative amount of sodium dodecyl sulfate to protein is critical for dissociating the apparent dimeric structure of TNF. CF and rTNF were also similar with respect to their ability to kill various types of target cells the sensitivity of which to TNF differ, and the dose-response curves of cytotoxicity obtained with CF-containing monocyte supernatants and rTNF were similar. As is the case with anti-CF serum, anti-rTNF serum inhibited drug-dependent cellular cytotoxicity and cytolysis mediated by both freshly isolated monocytes and in vitro cultured unactivated and lymphokine-lipopolysaccharide activated monocytes, indicating that TNF is an effector molecule in both drug-dependent cellular cytotoxicity and "classical" monocyte-mediated cytotoxicity.     

Reversible inhibition of lymphokine-activated killer cell activity by lipoxygenase-pathway inhibitors

Natural killer (NK) cells and lymphokine-activated killer (LAK) cells are anomalous cytotoxic cells which are potentially important in host defense against cancer. Several studies have demonstrated that natural killer (NK) cell activity can be suppressed by chemical inhibitors of the lipoxygenase pathway through inhibition of the production of leukotriene B4 (LTB4). The present study investigated the effects of the lipoxygenase inhibitors BW755C and nordihydroguaiaretic acid (NDGA) on NK and LAK cell activity. NK cell function of fresh peripheral blood mononuclear cells (PBMC) was determined via a standard chromium release assay employing K562 as the tumor target. The LAK cell activity of PBMC which had been stimulated with 10 IU of interleukin-2 for 72 hr was determined against the NK-resistant cell line Daudi. Both BW755C and NDGA inhibited NK and LAK cell function at a variety of concentrations. Indomethacin, a prostaglandin synthesis inhibitor, did not bring about an appreciable diminution in NK or LAK cell activity. Inhibition of NK and LAK cell activities by BW755C and NDGA could be reversed by washing the effector cell suspensions prior to the cytotoxic assay or by adding LTB4 (10(-11)-10(-8) M) directly to the effector:target suspensions. These data indicate that certain arachidonic acid oxidation products of the lipoxygenase pathway are essential for the function of LAK cells.     

A novel recombinant fusion toxin targeting HER-2/NEU-over-expressing cells and containing human tumor necrosis factor

Over-expression of the proto-oncogene HER2/neu in breast cancer and certain other tumors appears to be a central mechanism that may be partly responsible for cellular progression of the neoplastic phenotype. Transfection of mammalian cells and over-expression of HER2/neu appears to result in reduced sensitivity to the cytotoxic effects of tumor necrosis factor (TNF) and reduced sensitivity to immune effector killing. The single-chain recombinant antibody sFv23 recognizes the cell-surface domain of HER2/neu. The cDNA for this antibody was fused to the cDNA encoding human TNF, and this sFv23/TNF fusion construct was cloned into a plasmid for expression in Escherichia coli. The fusion protein was expressed and purified by ion-exchange chromatography. SDS-PAGE demonstrated a single band at the expected m.w. (43 kDa). Western analysis confirmed the presence of both the antibody component and the TNF component in the final fusion product. The fusion construct was tested for TNF activity against L-929 cells and found to have biological activity similar to that of authentic TNF (SA 420 nM). The scFv23/TNF construct bound to SKBR-3 (HER2-positive) but not to A-375 human melanoma (HER2-negative) cells. Cytotoxicity studies against log-phase human breast carcinoma cells (SKBR-3-HP) over-expressing HER2/neu demonstrate that the sFv23/TNF fusion construct was 1, 000-fold more active than free TNF. Tumor cells expressing higher levels of HER2/neu (SKBR-3-LP) were relatively resistant to both the fusion construct and native TNF. These studies suggest that fusion constructs targeting the HER2/neu surface domain and containing TNF are more effective cytotoxic agents in vitro than native TNF and may be effective against tumor cells expressing intermediate, but not high, levels of HER2/neu.     

Lymphokine-activated killer activity of tumor-associated and peripheral blood lymphocytes isolated from patients with ascites ovarian tumors

Peripheral blood lymphocytes (PBLs) and tumor-associated lymphocytes (TALs) were isolated from 36 patients with advanced ovarian adenocarcinoma and peritoneal effusions for study of lymphokine-activated killer activity. PBLs and TALs cultured in vitro for 3-5 days in the presence of interleukin-2 (IL-2, supernatant of the MLA 144 gibbon cell line, or human recombinant IL-2) expressed higher levels of cytotoxicity as compared to cells cultured in medium alone, against natural killer (NK)-susceptible (K562) or NK-resistant targets (Daudi and the human ovarian carcinoma cell line SW626). When ovarian tumor cells, freshly isolated from carcinomatous ascites or surgical specimens, were used as target cells in the cytotoxicity assay, 8 of 14 PBLs and 5 of 7 TAL preparations lysed the autologous tumor after treatment with IL-2, while no spontaneous reactivity was observed in any of the 14 patients tested. Although levels of lysis were usually relatively low, these data demonstrate that PBLs and TALs from ovarian cancer patients (TALs usually exhibiting low NK activity) when stimulated in vitro by IL-2 acquire some cytotoxic potential against the autologous tumor.     

Ewing's sarcoma: ex vivo sensitivity towards natural and lymphokine-activated killing

We studied the ex vivo cell-mediated cytotoxicity of natural killer (NK) and lymphokine-activated killer (LAK) cells against continuously cultured Ewing's sarcoma cells from 3 different patients. Target cell lysis was measured in a 4-hour 51Cr radioisotope release assay. At an effector to target (E:T) ratio of 50:1, the mean (+/- 1 SD) cytolysis by fresh purified large granular lymphocytes (NK cells) was 20 +/- 8, 25 +/- 2, and 21 +/- 3% in Ewing's sarcoma cell lines 6647, 5838, and A4573, respectively. Under identical conditions, NK cells lysed 56 +/- 7% of K562 (a standard NK target), and 3 +/- 3% of Daudi (a standard NK-resistant LAK target). When compared to fresh unseparated peripheral blood mononuclear cells (PBMC), purified NK cells did not exhibit an enhanced cytotoxic reactivity against either Ewing's sarcoma target. In contrast, LAK cells (i.e., PBMC that were preincubated for 4 days in the presence of rIL-2) were highly cytotoxic against all three Ewing's sarcoma targets. LAK activity was dependent on the concentration of rIL-2 used in PBMC cultures. Optimum cell-mediated toxicity against the standard LAK target Daudi (99 +/- 10% cytolysis at 50:1 E:T ratio) was achieved at rIL-2 concentrations of 1,000 u/ml. LAK cells grown under these conditions were also effective against Ewing's sarcoma cells. At an E:T ratio of 50:1, 86 +/- 16, 85 +/- 16, and 67 +/- 13% inhibition was observed in 6647, 5838, and A4573 cells, respectively, as compared to 17 +/- 10, 19 +/- 15, and 29 +/- 11% cytolysis by fresh uninduced PBMC. In summary, our results suggest that rIL-2-induced LAK-type immune effector cells may be of some therapeutic value in the treatment of poor prognosis Ewing's sarcoma.     

Susceptibility to lysis of pulmonary alveolar macrophages by human lymphokine-activated killer cells

In this study we addressed the question of whether lymphokine-activated killer (LAK) cells, besides killing neoplastic cells, may exert a certain degree of lysis on the normal counterpart; in particular we took into consideration the toxicity against pulmonary alveolar macrophages (PAM). We demonstrated that human LAK cells generated in vitro following incubation of peripheral blood mononuclear cells with recombinant interleukin 2 for 4 days were able to lyse normal PAM in a 4-h 51Cr release assay. Similarly, PAM recovered from patients suffering from nonneoplastic interstitial lung disorders, i.e., sarcoidosis and hypersensitivity pneumonitis, were shown to be susceptible to the cytotoxic function provided by LAK cells. Both autologous and allogeneic PAM were lysed by LAK cells, thus suggesting that the phenomenon we observed does not require a major histocompatibility complex restriction. Preincubation of PAM under study with gamma-interferon did not affect their susceptibility to the lysis mediated by LAK cells. Furthermore, cold target inhibition assay demonstrated that normal PAM could efficiently compete with both NK-sensitive and NK-resistant target lines for the binding sites on LAK cells, thus indicating that the putative receptor(s), or at least the mechanism of target recognition, is shared by PAM and these different target cell lines. The evidence herein provided that LAK cells are cytotoxic to normal, nontransformed PAM points out that the pathogenetic mechanisms involving this self-addressed lytic activity could account for some adverse reactions related to LAK/interleukin 2 immunotherapy.     

Lysis of fresh human tumor cells by autologous large granular lymphocytes from peripheral blood and pleural effusions

Human lymphocytes and their subpopulations from the peripheral blood and pleural effusions of cancer patients were tested for cytotoxicity against fresh tumor cells isolated from carcinomatous pleural effusions of the same patients. Fresh tumor cells were relatively resistant to lysis by autologous unseparated lymphocytes in a 4 h Cr-release assay. Positive reactions were recorded in 10 of 38 blood samples and 10 of 37 effusion specimens. Purification of large granular lymphocytes (LGL) by discontinuous Percoll gradient centrifugation resulted in enhancement of cytotoxic activity against autologous tumor cells and K562 cells, with no reactivity in LGL-depleted small T-lymphocyte populations. Significant lysis of effusion tumor cells by autologous LGL was observed in 15 of 22 blood specimens and 15 of 21 effusion samples. Further depletion of high-affinity sheep erythrocyte rosetting cells from Percoll-purified LGL populations gave an increase in autologous tumor-killing activity. Depletion of LGL/K562 conjugates from LGL populations decreased lysis of autologous tumor cells and K562 cells. Effusion tumor cells that were susceptible to lysis by allogeneic normal LGL were also killed by autologous LGL, and effusion tumor cells resistant to lysis by allogeneic NK cells were not lysed by autologous LGL. In a single-cell cytotoxicity assay in agarose, 4-26% LGL bound autologous tumor cells and 0.2-5% LGL killed these target cells, while 12-45% LGL bound K562 cells and 2-20% LGL lysed them. These results indicate that cytotoxic potential for autologous effusion tumor cells is present in the peripheral blood and pleural effusions of cancer patients; it is strongly associated with a minor proportion of LGL and restricted to the cell population that can lyse NK-sensitive K562 cells.