Generation of lymphokine-activated killer cell activity from non-NK precursor cells

It is possible to generate high levels of lymphokine-activated killer (LAK) activity in short-term culture from cells enriched for natural killer (NK) activity. To determine whether LAK activity can also be generated from non-NK cells, we have depleted peripheral blood lymphocytes (PBL) of NK cells prior to culture with IL-2. NK activity in PBL is correlated with the intensity of staining with the lysosomotropic vital dye quinacrine. Quinacrine dim PBL, which are devoid of lytic NK cells, are capable of developing LAK activity following culture with IL-2. We have also separated PBL using the NK-associated NKH-1 marker. Depleting NKH-1+ cells eliminates NK activity but the ability to develop LAK activity is retained. NKH-1-depleted cells generate less LAK activity than unseparated or NKH-1-positive cells and do not proliferate as well as unseparated cells to IL-2. When NK-depleted cells are subsequently examined for the expression of the NKH-1 antigen, this marker is absent from most cells at Day 3 of IL-1 culture, but is expressed on an increasing number of cells by Days 6-8. These results suggest that LAK derived from non-NK cells is functionally and phenotypically similar to LAK from PBL-containing NK cells, and may be the result of the activation of an NK precursor population.     

Lysosome rich cells contain the lytic activity of lymphokine-activated killer cell populations

Summary Little is known regarding the effectors of lymphokine-activated killer activity. Lysosomotropic agents such as quinacrine can be used to positively sort for lysosome rich cells in natural killer (NK) cell populations. We therefore decided to use this agent to sort lymphokine-activated killer (LAK) cells to characterize their lysosomal content. We found that the positively sorted population contained all the LAK activity, i.e., lysis of NK-resistant tumor cells (B16 melanoma cell line), with the negatively sorted cells having no killing activity. Therefore separation of interleukin-2-incubated cells for LAK activity could be accomplished using sorting after quinacrine staining. The treatment of positively sorted LAK cell populations with L-leucine methyl ester, a lysosomotropic dye which inhibits killing by lysosome rich cells, caused abrogation of killing of the B16 tumor by the treated populations. Single cell conjugate assays were also done on these sorted cells, with positively sorted cells forming the highest and negatively sorted cells the lowest percent of conjugates. Our data therefore indicates the important role of lysosome rich cells in the LAK cell population in the murine system.This work was supported by NIH grants R01 CA42962 and K04 CA0122, and by intramural funds from the Norris Cancer Center     

Human lymphokine-activated killer cells: further isolation and characterization of the precursor and effector cell

In a series of experiments we have demonstrated the progressive enrichment (5- to 40-fold) in lymphokine-activated killer (LAK) precursor activity by adherence depletion, sheep red cell rosetting, and depletion of CD3- and DR-positive lymphocytes. The LAK precursor cell thus appears to fall within the 'null' cell population. CD16 and CD11 are cell surface antigens expressed on the surface of the LAK precursor as demonstrated in sorting experiments. A 6- to 100-fold enrichment compared to unseparated peripheral blood was noted when sorted cells positive for CD16 and CD11 were tested. The LAK effector has been identified as being primarily CD3- and CD2+. Similar sorting equipment demonstrated a 7- to 500-fold difference in lytic activity for fresh tumor when comparing CD2+/CD3- and CD2+/CD3+ cells. The CD16+/CD11+ lymphocyte can proliferate in response to interleukin-2 (IL-2) alone in the absence of accessory cells and can be expanded in IL-2 alone with maintenance of lytic activity.     

Heterogeneity of the lymphokine-activated killer cell phenotype.

Lymphokine-activated killer cells (LAK) are functionally defined by their ability to mediate the MHC-unrestricted lysis of a range of tumor targets, while sparing normal cells. They can also lyse TNP-modified normal syngeneic lymphoblasts. We show here that lysis of TNP-modified targets is mediated by CD8+ LAK in a self-MHC-restricted manner, whereas lysis of tumor targets is largely by CD8- LAK and is MHC-unrestricted. LAK generated from the immune-deficient strains Balb/c nude and C.B-17 scid lyse tumor targets as effectively as LAK from normal mice but do not lyse TNP-modified normal targets. Further, lysis of TNP-modified targets, but not tumors, can be inhibited by antibody to the T cell receptor complex. These experiments strongly suggest that recognition of TNP-modified targets is not accomplished by the same mechanism as that of tumors. Rather, they are consistent with recognition of TNP-modified targets by CD8+ LAK cells being mediated via recognition through the T cell receptor.     

Natural killer and lymphokine-activated killer cell functions in chronic myeloid leukemia

Summary The natural killer (NK) and lymphokine-activated killer (LAK) cell activities of peripheral blood lymphocytes from chronic myeloid leukemia (CML) patients in remission and from healthy donors have been studied. Regression analysis to compare both cytotoxic responses in individual donors and the frequency of LAK cell precursors was also carried out. About 42% of CML patients in remission showed low NK activity (less than the mean percentage NK activity of healthy donors — 2 SD) and were categorised as low NK responders. The stage of remission or the drugs used to bring about remission did not influence the NK status. The LAK activity of low NK as well as normal NK responder CML patients was significantly low against the NK-sensitive K562 cell line and the NK-resistant VIP (melanoma) and T-24 (bladder carcinoma) tumor targets, as assessed by linear regression analysis. Allogeneic leukemic cells were more resistant to killing, especially by patients' LAK cells. The frequency analysis of LAK cell precursors revealed a significant reduction in the LAK cell progenitor frequency in CML patients in remission.     

Leukoregulin up-regulation of tumor cell sensitivity to natural killer and lymphokine-activated killer cell cytotoxicity

The present investigation demonstrates that leukoregulin, a cytokine secreted by natural killer (NK) lymphocytes up-regulates the sensitivity of tumor cells to lymphokine-activated killer (LAK) cell cytotoxicity. It has been previously established that leukoregulin increases the sensitivity of sarcoma, carcinoma and leukemia cells to natural killer (NK) cell cytotoxicity. Tumor cells were treated with leukoregulin for 1 h at 37 degrees C and tested for sensitivity to NK and LAK cytotoxicity in a 4-h chromium-release assay. NK-resistant Daudi, QGU and C4-1 human cervical carcinoma cells became sensitive to NK cytotoxicity after leukoregulin treatment, and their sensitivity to LAK was increased two- to sixfold. Y-79 retinoblastoma cells, which are moderately sensitive to NK and very sensitive to LAK, became increasingly sensitive (two- to four-fold) to both NK and LAK cell cytotoxicity. Recombinant granulocyte-macrophage colony-stimulating factor (GM-CSF), recombinant interleukin-1 (alpha and beta), recombinant interferon gamma, recombinant tumor necrosis factor or combinations of the latter two failed to up-regulate tumor cell sensitivity to NK and LAK cell cytotoxicity. However, treatment with recombinant interferon gamma for 16-18 h, GM-CSF and interleukin-1 beta for 1 h induced a state of target cell resistance to both NK and LAK cell cytotoxicity. Leukoregulin may have an important physiological function in modulating NK and LAK cell cytotoxicity by increasing the sensitivity of target cells to these natural cellular immunocytotoxicity mechanisms.     

Characteristics of interleukin-6-enhanced lymphokine-activated killer cell function

To study the effect of IL-6 on the development of cytotoxic cells, we examined lymphokine-activated killer (LAK) activity generated from human nonadherent PBL. Addition of rIL-6 at the initiation of 5-day PBL cultures significantly increases LAK activity in the presence of low concentrations (between 5 and 25 u/ml) of rIL-2. RIL-6 alone induces no PBL LAK activity but at doses as low as 0.8 u/ml rIL-6 enhances LAK activity with optimal enhancement of LAK at 5.0 u/ml of rIL-6. This enhancement is independent of effects on cells growth as rIL-6 did not affect the cell recovery of PBL cultured in rIL-2. RIL-6-enhanced LAK is mediated by the same type of effector cells as those of LAK from rIL-2 alone with effector cells primarily generated from large granular CD3-negative E rosetting lymphocytes. RIL-6 does not change the time course of LAK development and pretreatment of PBL with rIL-6 has no effect on the PBL response to subsequent rIL-2 induction of LAK. Addition of rIL-6 to LAK cultures 2 hr before the cytotoxicity assay shows equal enhancement as addition at the initiation of the culture. However, rIL-6 requires the presence of both rIL-2 and another factor in the supernatant from LAK cultures in order to enhance LAK. Our results indicate that IL-6 can modulate LAK activity at a very late stage of LAK development, and that the enhancement by IL-6 is dependent on the presence of IL-2 and another soluble factor generated during rIL-2 culture.     

Human monocytes inhibit lymphokine-activated killer cell expansion in vitro

Depleting monocytes from human peripheral blood mononuclear cells (PBMC) enhances the in vitro activation of lymphokine-activated killer (LAK) cells. To determine if monocytes also altered LAK-cell expansion, we evaluated two methods of depleting monocytes from PBMC: nylon wool adherence (NWA) and phenylalanine methyl ester (PME) treatment. Both methods of depleting monocytes enhanced interleukin-2 (IL-2) driven, LAK-cell expansion; LAK expansion, however, was significantly greater after depletion with NWA than after PME. LAK cytotoxicity after NWA and PME depletion was equivalent. The degree of monocyte depletion, determined by evaluating morphology and the number of Leu-M3 (CD14) positive cells, and the proliferation of Leu 19 (CD56), OKT-3 (CD3), Leu2 (CD8), and Leu 3a (CD4) positive cells was also equivalent. Exposure of IL-2 activated cells to PME did not alter their cytotoxic activity. However, sequential treatment of PBMC with NWA, then PME, or with PME and then NWA, resulted in reduced expansion. This reduction in expansion was similar to PBMC treated with PME alone. Exposure of PME-depleted cells to nylon wool or to supernatants obtained from cells adherent to nylon wool further decreased LAK expansion relative to cells treated with NWA alone. We conclude that even at relatively low cell density, human monocytes markedly inhibit LAK-cell expansion in IL-2 driven PBMC cultures. Further, depletion of monocytes by NWA adherence is more effective than by treatment with PME, possibly due to subtle cellular damage induced by this latter treatment. These findings have implication for the in vitro and in vivo generation of LAK-cells by IL-2.     

Generation of lymphokine-activated killer cell activity from human thymocytes

We have generated lymphokine-activated killer (LAK) cells from human thymocytes in order to assess the relationship between LAK cells and T cells. Fresh thymocytes lack natural cytotoxic activity, and cytotoxicity cannot be stimulated by short term (1 hr) incubation with interferon or recombinant interleukin 2 (rIL-2). In addition, thymocytes are phenotypically devoid of cells bearing the natural killer (NK)-associated markers cluster designation (CD) 16 and NKH-1. After culture for 5 to 8 days with rIL-2, thymocytes display high levels of cytotoxic activity against both NK-sensitive and NK-resistant targets. Thymocytes require slightly more IL-2 than do peripheral blood lymphocytes to generate LAK activity. We have examined the phenotype of the thymocyte LAK precursor and effector cells. Thymocyte LAK precursors are of low to medium density, CD1-negative, and predominantly CD3-negative. Although CD3-positive cells proliferate in response to rIL-2, they are low in cytolytic capabilities. The effector cells, like the LAK precursors, are low to medium density lymphocytes. The cytotoxic cells are predominantly CD3-negative, and cytotoxic activity cannot be blocked with the use of anti-CD3 monoclonal antibodies. The effector cells also lack most NK-associated markers (HNK-1, and the CD16 markers Leu-11b and B73.1) but possess the NK-associated marker NKH-1 (N901). The responsive cell appears to be at a very early stage of thymic development, and it does not appear to either require or express the CD3-T cell receptor complex.     

Cytostatic and cytotoxic activity of lymphokine-activated killer cell supernatants

Summary Incubation of peripheral blood mononuclear cells with interleukin-2 (IL-2) results in the release of a factor which is cytostatic and cytotoxic both to tumor cell lines (A375M, A375P, C480, MCF-7, Hey) and fresh tumor cells (in the human tumor cloning assay), including breast cancer, colon cancer, melanoma, myeloma and ovarian cancer. The factor cannot be detected in a 4-h chromium-release assay, but is best demonstrated after tumor cells have been to it for exposed 3 days. The factor is not cytotoxic to normal peripheral blood leukocytes or normal fibroblasts, and is not toxic to certain targets sensitive to lymphokine-activated killer (LAK) cells, such as K562 and Daudi cells. The factor is diffusible, non-dialyzable, relatively stable to heat and acid and does not contain appreciable amounts of targets resistant to interferon- and , tumor necrosis factor and interleukin-1. The data suggest that there are several mechanisms of LAK cell activity against tumor cells including one which requires direct interaction of LAK and tumor cells and one which is mediated by LAK cell supernatant. The former is detected by 4-h chromium release while the latter is not.Supported by a grant from the Arizona Disease Research Commission and by Grants CA-17094 and CA-23074 from the National Institute of Health     

Inhibition of lymphokine-activated killer cell generation by cultured tumor cell lines in vitro

Summary The co-culture of human peripheral blood mononuclear cells (PBMC) with high concentrations of interleukin 2 normally generates lymphokine-activated killer (LAK) cells capable of indiscriminate lysis of tumor targets. However, the addition of certain cell-line-derived tumor cells to the LAK generation cultures within the first 48 h of culture initiation resulted in the suppression of the LAK cytotoxicity measured after 3–4 days of culture. Suppression could be achieved with tumor cell:PBMC ratios as low as 1:50 when tumor cells were derived from melanoma and colorectal cancer (G361, COLO320, HT-29), but suppression was not observed with cells from the breast cancer cell line SKBr3. No suppression of LAK generation was observed with normal epithelial cells from colon or breast, with autologous or allogeneic lymphoblasts, or with allogeneic vascular endothelial cells. Suppression was independent of the removal of adherent cells from PBMC, could not be prevented by indomethacin and was not attributable to interleukin 2 absorption/adsorption by tumor cells. The suppressive activity of some tumor cells could be augmented by preculture in recombinant gamma interferon. Serum-free supernatants from G361, COLO320 and HT-29 (but not SKBr3 or endothelial cells) were also highly suppressive towards the generation of LAK cells. The elaboration by tumor cells of fractors capable of inhibiting LAK generation may partially explain the failure of LAK/interleukin 2 therapy in some experimental and clinical protocols.     

Regulation of lymphokine-activated killer cell induction by human recombinant IL-1 receptor antagonist. Obligate paracrine pathway of IL-1 during lymphokine-activated killer cell induction.

IL-2-stimulated human lymphocytes, referred to as lymphokine-activated killer (LAK) cells, can develop a broad range of lytic activity against fresh tumor cells and cultured tumor cell lines. IL-1, a pleiotropic cytokine shown to synergize with IL-2 on LAK induction, is endogenously synthesized and secreted by LAK cells. Immunoblot analysis demonstrated that IL-2-stimulated PBL produced the 31- to 34-kDa pro-molecules of IL-1 within 24 h and maintained their expression for at least 96 h. The role of secreted IL-1 has been examined using rIL-1R antagonist (IL-1ra). The addition of IL-1ra to LAK activation culture resulted in dose-dependent inhibited lytic activity, which was more apparent in LAK cells cultured with higher doses of IL-2. However, IL-1ra had no effect on proliferative responses elicited in LAK cells by IL-2. Moreover, when IL-1 binding was blocked by IL-1ra, the expression of the IL-2R p55 subunit was reduced compared with control LAK cells. The effect of IL-1 binding blockade on expression of other cytokine mRNA was further examined by polymerase chain reaction analysis, and, specifically, inhibition of both TNF-alpha and TNF-beta mRNA expression by IL-1ra was observed in PBL stimulated with IL-2. The reduced biologic activity of TNF in culture supernatants correlated well with the inhibition of mRNA expression. These findings suggest that autocrine/paracrine IL-1 is involved in the initial generation of LAK activity and, in particular, that TNF expression could be induced via an IL-1 autocrine pathway.     

Induction of lymphokine-activated killer cell against human leukemia cells in vitro

The induction of lymphokine-activated killer (LAK) cells against fresh human leukemia cells was investigated. Two thirds of the 62 leukemias examined were susceptible to the lytic effect of allogeneic IL-2 induced LAK cells in vitro. No substantial differences could be detected between myeloid or lymphoid leukemias or with regard to the FAB subtype or the immunophenotype. Culturing mononuclear cells from peripheral blood or bone marrow of leukemia patients with IL-2 resulted in an expansion of residual large granular lymphocytes and development of cytotoxic activity. The combination of IL-2 with IFN-gamma or the presence of tumor cells during the activation process led to an enhancement of LAK cell cytotoxicity. These results suggest that LAK cells may be useful in the treatment of leukemia.     

Chemotherapy-induced modulation of natural killer and lymphokine-activated killer cell activity in euthymic and athymic mice

Combinations of chemotherapy and interleukin-2 (IL-2) aimed at improving therapeutic efficacy in cancer patients have generally proved disappointing. Although chemotherapy blocks tumor growth and sometimes boosts immune functions, most drugs are immunosuppressive, at least transiently. Therefore, it is reasonable to assume that maximal exploitation of the immunostimulatory and antitumor activity of both modalities requires careful coordination of chemotherapy and IL-2 timing. We analyzed the temporal effect of 5-fluorouracil (5-FU, 100–120 mg/kg), cyclophosphamide (CY, 100 mg/kg), Adriamycin (8 mg/kg) and dacarbazine (100 mg/kg) on the activation of natural killer/lymphokine-activated killer (NK/LAK) cells by IL-2 in several strains of euthymic mice and in athymic nude mice. Following in vivo or in vitro exposure to IL-2 1–15 days after chemotherapy, the total lytic activity of the spleen and the number of LAK precursors (LAK-p) were measured. In euthymic mice injected with IL-2 (5×10⁴ Cetus units twice daily for 4–5 days), 5-FU augmented (up to 37-fold, days 1–9) and CY reduced (up to day 6) LAK activity, as compared with that in the IL-2 control. In bulk cultures containing IL-2 (1000 CU/ml, 3–4 days), both 5-FU and CY reduced LAK activity of euthymic mice splenocytes for up to 6 days after chemotherapy, which was followed on day 9 by full recovery. In splenocytes of nude mice, 5-FU increased and CY diminished LAK activation in bulk cultures, starting 3 days after chemotherapy. In athymic mice, 5-FU markedly augmented the total number of LAK-p/spleen (up to 30-fold, days 3–9), as determined by limiting-dilution cultures with IL-2 (for 7–8 days). In euthymic mice, in contrast, LAK-p levels decreased for up to 6–9 days after treatment with 5-FU, Adriamycin or dacarbazine, later recovering to pretreatment levels, whereas CY markedly increased LAK-p (up to 15-fold) when administered 6–12 days before limiting-dilution culture initiation. The effect of chemotherapy on LAK and NK activity was essentially similar. In other experiments, a subset of asialoGM1-LAK-p was found in the spleens of 5-FU-treated mice, but not in untreated mice. Our results suggest that the immunomodulatory effect of chemotherapy on NK/LAK activity in mice is variable and largely depends on the drug itself, the interval between chemotherapy and IL-2 administration, the strain of mice and the assay used.     

Murine lymphokine-activated killer (LAK) cells: phenotypic characterization of the precursor and effector cells

Murine and human lymphocytes incubated in recombinant interleukin 2 (RIL 2) generate a population of cytotoxic cells (lymphokine-activated killer cells [LAK]), which are able to lyse a wide array of fresh tumor cells but do not lyse fresh normal cells. Intravenous administration of these cells with the concomitant administration of RIL 2 can eliminate established pulmonary and hepatic metastases in mice. To characterize the cell that has in vitro LAK activity, we subdivided murine lymphocytes by lysing select subpopulations with the use of complement and antibodies against lymphocyte surface markers or by fluorescence-activated cell sorting. Thy-1.2-negative splenocytes were found to generate near normal amounts of LAK activity after RIL 2 incubation. Small and inconsistent LAK cell activity was generated from Thy-1.2-positive splenocytes. Ia-positive and surface immunoglobulin-positive splenocytes had little or no LAK precursor capability and did not appear to be necessary for LAK activation. Treatment of splenocytes with anti-asialo GM1 (anti-ASGM1) heterosera and complement markedly decreased their ability to generate LAK activity. At the effector stage, cytotoxic cells were of the Thy-1.2-positive, Ia-negative phenotype. Ia-depleted cells were separated into subpopulations bearing or not bearing the gamma Fc receptor (gamma FcR). The majority of cytotoxicity resided in gamma FcR-positive cells. Thus the precursors of murine LAK cells are "null" lymphocytes bearing neither T nor B cell surface markers but develop the Thy-1.2 cell surface marker in vitro, in association with the development of lytic activity for fresh tumor cells after stimulation by RIL 2.     

Cytokine regulation of cell-to-cell interactions in lymphokine-activated killer cell cytotoxicity in vitro

The permanent pancreas carcinoma cell line, PCI-24, was developed in order to analyse cytokine regulation on pancreas carcinoma and lymphokine-activated killer (LAK) cell interaction. PCI cells expressed ICAM-1 and HLA-ABC, but not HLA-DR antigens. PCI cells showed augmented ICAM-1 and HLA-ABC expression when incubated with interferon (IFN) and tumour necrosis factor . A similar but weak augmentary effect on the HLA-ABC and ICAM-1 surface expression was seen with interleukin-1 treatment. Natural attachment of LAK to PCI cells was augmented by recombinant IFN in close association with ICAM-1 up-regulation on PCI cells. In addition, natural attachment was significantly inhibited by anti-LFA-1 and anti-ICAM-1 antibody treatments. Cytotoxicity of the LAK cells against PCI cells was also significantly inhibited with the same treatment. Thus, the attachment of LAK cells to PCI cells through LFA-1/ICAM-1 molecules appeared to be essential for the cytotoxicity for PCI cells. Pretreatment of PCI cells, but not of LAK cells, with IFN or other cytokines resulted in a decrease of susceptibility for LAK cell cytotoxicity. The decreased susceptibility inversely correlated with HLA-ABC expression on the PCI cells. The collective evidence indicates that, although LAK cell attachment to pancreas carcinoma cells through the LFA-1/ICAM-1 molecule is augmented by IFN, IFN treatment of pancreas carcinoma cells reduces LAK cell cytotoxicity possibly through an increase in HLA-ABC or a regulation of molecules closely associated to HLA-ABC expression.     

TNF-alpha and IFN-gamma reverse IL-4 inhibition of lymphokine-activated killer cell function

Recombinant IL-4 inhibits IL-2-induced lymphokine-activated killer (LAK) cell development of PBMC. We evaluated the effect of various cytokines in reversing IL-4-mediated LAK inhibition. PBMC were cultured in IL-2 (10-1000 u/ml) with or without IL-4 (2-100 u/ml) and tested for cytotoxicity against the NK-sensitive K562 cells and NK-resistant UCLA-SO-M14 cells. Addition of IL-4 at the beginning of culture suppresses LAK activity in a dose-dependent fashion. Addition of IFN-gamma or TNF-alpha partially reverses IL-4-mediated inhibition (30-100%) in a dose-dependent fashion. IFN-gamma and TNF-alpha must be added within the first 24 hr of initiating culture in order to reverse IL-4 inhibition. Furthermore, IFN-gamma and TNF-alpha are most effective at reversing IL-4 inhibition at low concentrations of IL-2 (less than 100 u/ml). Addition of other IL-2-induced cytokines such as GM-CSF (50 u/ml), M-CSF (250 u/ml), and IFN-alpha (10-10,000 u/ml) fails to reverse IL-4 inhibition. In addition to suppression of LAK induction, IL-4 also inhibits IL-2-induced IFN-gamma and TNF-alpha protein production in PBMC. The reversal of IL-4-mediated LAK inhibition by TNF-alpha and IFN-gamma may therefore be due to resupply of these endogenously suppressed cytokines.     

Phenotypic and functional analysis of lymphokine-activated killer (LAK) cell clones

Summary Lymphokine-activated killer (LAK) cells are generated by the culture of peripheral blood lymphocytes with interleukin-2 (IL-2). A variety of cells, including T-lymphocytes and natural killer (NK) cells, can be activated by IL-2 to exhibit the ability to kill multiple tumor and modified-self targets. Recent reports indicate that culture conditions can determine the phenotype of cells expressing LAK activity. Using limiting dilution techniques, we first generated cloned LAK cells with three culture conditions: autologous human serum (AHS)+IL-2; AHS+IL-2+0.1 g/ml phytohemagglutinin and fetal bovine serum and IL-2. We determined that all but one of the 47 LAK cell clones generated with the three culture conditions were CD3⁺ and T-cell like; one NK-like clone was observed. Clones that were cytotoxic for one target could generally kill multiple targets, and the absence of phytohemagglutinin did not significantly affect the ability of the LAK cell clones to kill multiple targets. The presence of phytohemagglutinin was, however, necessary for the long-term maintenance of proliferation and cytotoxic activity of the LAK cell clones. The mechanism by which LAK cells kill tumor targets is not known. We here demonstrate that LAK cells and LAK cell clones can produce interferon- and tumor necrosis factor (TNF) when stimulated with an erythroleukemia cell, K562. Five of the six CD3⁺, LAK cell clones tested could be stimulated by K562 cells to produce both interferon- and TNF. However, the ability of the cloned LAK cells to kill K562 cells, as measured in a 4-h ⁵¹Cr-release assay, did not correlate with their ability to produce these cytokines. Furthermore, specific antibodies that neutralize the cytotoxic activity of interferon- and TNF did not inhibit killing of K562 cells by LAK cells as measured with a 4-h cytotoxic assay. The cytostatic and cytotoxic activities of interferon- and TNF for tumor cells are well documented, but these cytolytic activities are slower acting and exhibit their maximum effect after 48–96 h. We here propose that LAK cells kill tumor targets by a combination of cell-to-cell-mediated killing and by the release of slower acting cytostatic/cytotoxic cytokines that can inhibit the growth of tumors some distance from the effector cells.This work is supported in part by grants from the Arizona Disease Research Commission (3364-000000-1-1-AP-6621) and the National Institutes of Health (Grants GM 34121, CA-17094 and CA-23074)     

The effects of staphylococcal protein A on human lymphokine-activated killer cell induction

Summary A murine IgG2b monoclonal antibody directed to the constant part of the human / T cell receptor (BMA031) was investigated in a pilot study as an initial treatment for acute graft-versus-host disease (aGvHD) after allogeneic bone marrow transplantation. The treatment protocol consisted of 5 mg BMA031 on 5 consecutive days with continuation of the prophylactic baseline immuno suppression using cyclosporin. Seven patients with grades II–III acute graft-versus-host disease were entered on the protocol and six patients completed the full treatment course. Mild to moderate acute adverse reactions to the first BMA031 infusion occurred in three patients. A nearly complete decline of circulating T lymphocytes was observed during BMA031 therapy, but the T cells returned to pretreatment values within 1 week after the last infusion. Serum pharmacokinetics of free antibody best fitted to a two-compartment open model with a mean initial half-life of 6 h and an estimated mean terminal half-life of 40 h. One patient developed antimurine antibodies of the IgM subclass. In five patients a complete and sustained resolution of all disease manifestations was attained, while in one patient a temporary response of skin involvement with aGvHD was noted. These results indicate that BMA031 can be safely administered as initial treatment of aGvHD. The therapeutic responses observed warrant its further clinical evaluation in this setting.