A macrophage derived blastogenic factor -MBF- induces cytokines and cytotoxic effectors in human peripheral blood mononuclear cells.

A soluble macrophage-derived blastogenic factor, previously reported as MBF, is secreted from macrophages activated with galactose oxidase. It was previously shown that MBF is able to induce IFN-gamma production and proliferation of T lymphocytes. In this study we found that MBF is able to induce in human peripheral blood mononuclear cells (PBMC) production of interleukin 1 (IL-1) beta, interleukin 2 (IL-2) and tumor necrosis factor (TNF) alpha and generation of MHC-unrestricted cytotoxic activity. The induction of killer cells is likely to rely on IFN-gamma production in that in PBMC treated with a monoclonal antibody (Mab) against IFN-gamma, the MBF induced cytotoxic activity was drastically reduced. A comparison of MBF induced cytotoxic effectors with those induced by IL-2 showed that both cytotoxic effectors pertain to NK lineage, in that they were CD3- and CD16+. On the contrary, the precursors of MBF and IL-2 induced killer cells were different; MBF cytotoxic precursor cells were highly sensitive to L-Leucine methyl ester (Leu-OME), a drug able to eliminate monocytes and NK cells, whereas IL-2 cytotoxic precursors were unaffected by this drug.     

Large-scale expansion of CD3<Superscript>+</Superscript>CD56<Superscript>+</Superscript> lymphocytes capable of lysing autologous tumor cells with cytokine-rich supernatants

We have developed culture conditions for the efficient expansion of cytotoxic effector cells from peripheral blood mononuclear cells (PBMC) by the timed addition of cytokine-rich supernatants collected from allogeneic PBMC cultures stimulated with anti-CD3 monoclonal antibody (mAb) (allogeneic CD3 supernatants; ACD3S). These cytotoxic effectors belonged primarily to CD56(+) natural killer (NK) cells, and the cell subset with the greatest cytotoxic activity was an otherwise rare population of CD3(+)CD56(+) cells (NKT cells) that expand dramatically under these conditions. CD3(+)CD56(+) cytotoxic effectors were generated from the PBMC of 16 patients with several types of cancer. The CD3(+)CD56(+) cell subset expanded significantly and efficiently lysed NK- as well as lymphokine-activated killer (LAK)-sensitive targets. More importantly, ACD3S-activated CD3(+)CD56(+) cells were capable of efficiently lysing autologous tumor cells including metastatic colorectal, ovarian, breast, lung and pancreatic tumor cells as well as melanoma cells. ACD3S-expanded CD3(+)CD56(+) cells exhibited increased levels of cytoplasmic interleukin-2 (IL-2), tumor necrosis factor-alpha (TNF-alpha), gamma-interferon (IFN-gamma) and perforin. CD3(+)CD56(+) cell-mediated cytotoxicity was not restricted by major histocompatibility complex (MHC) gene products, since it was not blocked by anti-MHC class I mAb but was highly inhibited in the presence of CD2- and CD18-specific mAb. These data suggest that CD3(+)CD56(+) cells expanded under the presence of ACD3S may be utilized in clinical protocols for cancer immunotherapy.     

Identification of a new surface molecule expressed by human LGL and LAK cells production of a specific monoclonal antibody and comparison with other NK/LAK markers

Recently we described a new monoclonal antibody, termed LAK1, which recognizes a 120-kDa surface antigen that is expressed on virtually all LGL and LAK precursors and effectors. In the present study we describe a second mAb, termed LAK2, which was derived against cloned LAK cells. The LAK2 mAb, similar to the LAK1 mAb reacts with a subset of peripheral blood lymphocytes which includes the precursors of LAK cells. In addition, among IL2-activated peripheral lymphocytes, this antibody defines cells displaying LAK activity. The expression of the LAK2 molecule on PBMC was analyzed by two-color cytofluorometric analysis in comparison with the expression of both T cell and LGL markers. We show that most resting LAK2+ cells lack surface expression of CD3, whereas nearly 60% express CD2 antigen. Moreover, all CD16+ and CD56 (NKH1)+ lymphocytes coexpressed both LAK2 and LAK1 antigens. Morphological analysis of LAK2+ lymphocytes indicated that the majority of these cells was represented by LGL. Thus the expression of the LAK2 molecule on LGL-enriched populations was compared by two-color cytofluorometric analysis to that of other known LGL markers such as CD16, CD57 (HNK1), and LAK1. Most LGL coexpressed LAK1, LAK2, CD16 and CD57 antigens Finally, the surface molecule recognized by LAK2 mAb is composed of two chains with apparent molecular masses of approximately 110 and 140 kDa.     

Characterization of interleukin 2-expanded human peripheral blood lymphocytes: not only NKH-1+-NK cells but also NKH-1+ and NKH-1- T cells are LAK effectors

In vitro culture of human peripheral blood mononuclear cells (PBMC) with interleukin 2 (IL-2) results in the expansion of lymphocytes including lymphokine-activated killer (LAK) cells. Using flow cytometry, studies were undertaken to determine the phenotype and LAK activity of each subset of lymphocytes expanded in vitro as a result of incubation for 2 weeks with 2500 U/ml of recombinant IL-2. Such expanded PBMC, when examined by two-color staining with various combinations of anti-CD3, 4, 8, 16, and NKH-1 monoclonal antibodies, consisted of the following six subgroups of cells: (1) CD3+4+8-, (2) CD3+4-8+, (3) CD3+4-8-, (4) CD3-16+NKH-1+, (5) CD3-16-NKH-1+, and (6) CD3-16-NKH-1-. Of the six subgroups, all five subgroups that could be tested, i.e., CD3+ T cells (CD3+4+8-, CD3+4-8+, CD3+4-8-), CD16+ natural killer (NK) cells (CD3-16+NKH-1+), and CD3-16-NKH-1- non-T non-NK cells, possessed LAK activity. Both NKH-1- as well as NKH-1+ T and non-T cells possessed LAK activity.     

IL-4 inhibits IL-2-mediated induction of human lymphokine-activated killer cells, but not the generation of antigen-specific cytotoxic T lymphocytes in mixed leukocyte cultures

Human rIL-4 was studied for its capacity to induce lymphokine-activated killer (LAK) cell activity. In contrast to IL-2, IL-4 was not able to induce LAK cell activity in cell cultures derived from peripheral blood. IL-4 added simultaneously with IL-2 to such cultures suppressed IL-2-induced LAK cell activity measured against Daudi and the melanoma cell line MEWO in a dose-dependent way. IL-4 also inhibited the induction of LAK cell activity in CD2+, CD3-, CD4-, CD8- cells, suggesting that IL-4 acts directly on LAK precursor cells. IL-4 added 24 h after the addition of IL-2 failed to inhibit the generation of LAK cell activity. Cytotoxic activity of various types of NK cell clones was not affected after incubation in IL-4 for 3 days, indicating that IL-4 does not affect the activity of already committed killer cells. No significant differences were observed in the percentages of Tac+, NKH-1+ and CD16+ cells after culturing PBL in IL-2, IL-4 or combinations of IL-2 and IL-4 for 3 days. IL-4 also inhibited the activation of non-specific cytotoxic activity in MLC, as measured against K-562 and MEWO cells. In contrast, the Ag-specific CTL activity against the stimulator cells was augmented by IL-4. Collectively, these data indicate that IL-4 prevents the activation of LAK cell precursors by IL-2, but does not inhibit the generation of Ag-specific CTL.     

Interleukin 2 induces human acute lymphocytic leukemia cells to manifest lymphokine-activated-killer (LAK) cytotoxicity

Lymphokine-activated killer cells (LAK) were originally distinguished from natural killers (NK) and cytotoxic T lymphocytes. Recently, however, IL 2-activated NK cells were suggested as the major source of LAK reactivity in human peripheral blood (PBL). Because certain T cell acute lymphoblastic leukemia (T-ALL) cells are phenotypically similar to LAK precursors, we have asked whether these leukemic cells can be induced toward LAK-cytotoxicity and express NK reactivity before stimulation. Five out of seven T-ALL preparations were induced by IL 2 to kill target cells. The cytotoxicity of the leukemic-LAK cells resembled that of normal LAK effectors as they lysed efficiently the NK-resistant target Daudi, as well as fresh human sarcoma, carcinoma, and renal cancer cells but not normal PBL. The ALL-LAK precursors phenotype was T3-, T4-, T8-, and T11+, similar to most normal LAK precursors. In contrast to normal PBL that generated LAK effectors when their proliferation was inhibited, the irradiated, nonproliferating T-ALL leukemic cells did not respond to IL 2. Therefore, the T-ALL LAK cytotoxicity was attributed to the leukemic cells rather than to residual normal lymphocytes. The IL 2-responding T-ALL cells did not express autonomous NK type cytotoxicity, suggesting that they reflect LAK precursors of non-NK origin. The homogeneous leukemic preparations with inducible LAK cytotoxicity described herein provide a model system for studying normal LAK cells.     

IL-4 regulates IL-2 induction of lymphokine-activated killer activity from human lymphocytes

IL-4 is a pluripotent lymphokine acting on various cell types. We investigated the role of human IL-4 on the generation of lymphokine-activated killer (LAK) activity. Human IL-4 alone did not induce LAK activity and inhibited IL-2 induction of LAK activity from unstimulated PBMC, peripheral blood null cells, spleen cells, and lymph node cells in a dose-dependent manner. IL-4 also inhibited several phenomena induced by IL-2 such as cell proliferation, augmentation of NK activity, increase of Leu-19+ cells, and expression of IL-2R(p55) on either CD3+ or Leu-19+ cells. IL-4, however, augmented cell proliferation with other T cell mitogens including PHA, Con A, PMA, or allo-MHC Ag with or without IL-2. In contrast to unstimulated cells, IL-4 alone induced marked cell proliferation and LAK activity as well as Leu-19+ cells from in vitro IL-2 preactivated PBMC or null cells, and did not inhibit IL-2 induced cell proliferation, LAK activity, Leu-19+ cells and IL-2R(p55) expression, but rather augmented them with low doses of IL-2. Although IL-4 alone induced LAK activity from peripheral blood of some patients previously given IL-2, IL-4 inhibited in vitro LAK generation with IL-2 from these cells in most cases. Therefore, IL-4 appears to directly inhibit the IL-2 activation pathway via IL-2R(p70) and prevent resting LAK precursors from proliferating and differentiating into final effector cells. However, once cells were sufficiently preactivated by IL-2, IL-4 induced LAK activity and did not inhibit IL-2 activation of these cells. These data suggest an immunoregulatory role of IL-4 on human null cells and T cells.     

Leu-Leu-OMe sensitivity of human activated killer cells: delineation of a distinct class of cytotoxic T lymphocytes capable of lysing tumor targets

Sensitivity to L-leucyl-L-leucine methyl ester (Leu-Leu-OMe) was used to characterize the phenotype of human activated killer cells. Natural killer cells (NK) and the precursors of both the alloantigen-specific cytotoxic T lymphocytes (CTL) and the NK-like activated killer cells generated after stimulation with allogeneic cells were deleted from human peripheral blood lymphocytes by preincubation with Leu-Leu-OMe. It was noted, however, that cytotoxic lymphocytes could be generated from Leu-Leu-OMe-treated lymphocyte precursors after 2 to 6 days of culture with the nonspecific mitogen, phytohemagglutinin (PHA). The characteristics of these killer cells indicated that they were a unique population that could be distinguished from other cytotoxic cells. Killing by these cells exhibited slow kinetics in that 18 hr cytotoxicity assays were required to detect full cytotoxic potential. When 18 hr assays were used, PHA-stimulated cytotoxic cells generated from Leu-Leu-OMe-treated lymphocytes were able to kill both NK-sensitive K562 cells and the relatively NK-resistant renal cell carcinoma cell line, Cur. These cytotoxic lymphocytes were HNK-1, Leu-11b (CD16), and OKM1 (CR3)-negative at both the precursor and effector stage of activation. Furthermore, these cells were derived from a CD3-positive precursor. Finally, killing by activated effectors was inhibited by OKT3. Unlike activation of Leu-Leu-OMe-sensitive large granular lymphocytes, generation of these cytotoxic T cells was totally prevented by treatment with mitomycin c before stimulation. Thus, a unique class of tumoricidal T cells can be characterized by resistance of lymphocyte precursors to a concentration of Leu-Leu-OMe, which has been shown to ablate NK, mixed lymphocyte culture-activated NK-like cytotoxic precursors, and the precursors of alloantigen-specific CTL.     

Interferon-gamma-treated K562 target cells distinguish functional NK cells from lymphokine-activated killer (LAK) cells

In vitro incubation of the erythroleukemic cell line K562 with interferon-gamma (IFN-gamma) renders these cells relatively resistant to natural killer (NK) cell lysis. However, such treatment does not alter their sensitivity to LAK cell lysis. Thus, the lytic susceptibility of interferon-gamma-treated K562 (I-K562) cells to LAK cells as opposed to its relative resistance to NK cell lysis provides a functional assay to help distinguish these two types of effector cells. The relative resistance of I-K562 for NK cell-mediated lysis was not secondary to the release of soluble factors or the frequency of Leu-19+, CD3+ T cells, residual IFN-gamma, or expression of MHC Class I molecules. Coincubation of I-K562 cells with NK or LAK cells overnight did not appreciably change the pattern of lytic responses against K562 and I-K562 target cells. However, incubation of PBMC in vitro with I-K562 but not native K562 in the presence of r-IL-2 leads to a marked decrease in the generation of LAK cells. The inhibition of LAK cell generation was not secondary to differences in the consumption of bioactive levels of IL-2. Differences in the lytic capability of NK and LAK effector cells suggest heterogeneity among cells that mediate such non-MHC-restricted lysis. Use was made of cells from a patient with a large granular lymphocyte lymphoproliferative disease (greater than 85% Leu-19+) to determine if such cells could be used to distinguish clonal population of cells which would represent NK or LAK cell function. Of interest was the finding that such cells, even after incubation in vitro with IL-2, showed lytic function representative of NK cells but not LAK cells. Data concerning the inhibition of LAK cell generation by I-K562 cells have important implications for future therapeutic trials of IFN-gamma and IL-2 in the treatment of human malignancies.     

Induction of LAK-like cells in the peritoneal cavity of mice by inactivated Candida albicans

We have investigated the effect of multiple administrations of inactivated Candida albicans (CA) cells on induction of non-MHC-restricted antitumor cytotoxic responses both in normal and congenitally athymic (nude) mice. Intraperitoneal inoculation of CD2F1 mice with five doses of 2 x 10(7) CA cells over a 2-week interval was associated with the induction of peritoneal exudate cells (PEC) that mediated natural killer cell activity. These cells, in contrast to those elicited by a single dose of CA, killed both NK-sensitive and NK-resistant tumor target cells in vitro. This broad-spectrum, antitumor cytotoxicity peaked 1 day after the last injection of CA, and decreased to control values within 6 (NK-resistant) or 14 (NK-sensitive target cells) days. Cytotoxicity could be recalled to a high level by a boosting injection of CA or a major mannoprotein-soluble antigen (MP) from the Candida cell wall, given 30 days after multiple CA treatment. Upon a 24-hr in vitro incubation, CA-induced peritoneal immunoeffectors lost their killing activity unless human recombinant interleukin-2 (rIL-2) was added to cultures. The non-MHC-restricted cytotoxic PEC activity induced by CA was mainly associated with nonadherent, nonphagocytic large granular lymphocytes (LGL) which exhibited the following phenotypes: (i) asialo GM1+, Lyt 2.2-, and partially Thy 1.2+ (effectors active against NK-sensitive targets) and (ii) asialo GM1+, Lyt 2.2-, and Thy 1.2+ (effectors active against NK-resistant targets). Nude mice also responded to multiple CA inoculations by displaying high cytotoxic activity against NK-sensitive targets and significant cytotoxicity against NK-resistant targets. This cytotoxicity could be recalled on Day +30, and the cytotoxic effectors involved were highly sensitive to anti-asialo GM1 plus complement treatment. Overall, the results add further experimental evidence to the wide range of immunomodulatory properties possessed by C. albicans, and demonstrate that the majority of antitumor cytotoxic activity induced by fungal cells was due to lymphokine-activated killer (LAK)-like effectors.     

LAK1: a novel leucocyte differentiation antigen shared by lymphoid and endothelial cells

Lymphokine activated killer (LAK) cells have been utilized as a useful tool in cancer adoptive immunotherapy. The lineage origin of this population has always been controversial since it shares phenotypic markers with both myelomonocytic cells and T lymphocytes. Recently we described a new monoclonal antibody (MoAb), termed LAK1, which recognizes a 120 Kd surface molecule expressed on human large granular lymphocytes (LGL) and LAK precursors and effectors. LAK1 MoAb defines two different populations of positive cells amongst peripheral lymphocytes: the first subset (20%), represented by brightly stained cells, belongs to the non T-LGL population, whereas the second subset (30%) displays low fluorescence intensity and was partially composed of T lymphocytes. More interestingly, LAK1 is shared by some other cell types, such as monocytes and vascular endothelial cells. Immunohistochemical staining performed on muscle, endometrium and lymphoid or other non lymphoid tissues shows that LAK1 antigen is selectively expressed by the reticuloendothelial system.     

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 and characterization of cytotoxic activity against tumor cell lines in human peripheral blood mononuclear cells stimulated "in vitro" by a glucomannan-protein preparation of Candida albicans

Human peripheral blood mononuclear cells (PBMC) proliferated and generated non-specific cell-mediated cytotoxicity (CMC) after stimulation with a cell-wall glucomannan-protein (GMP) fraction of Candida albicans or chemically-inactivated intact microrganism. No effects were observed using other fungal cell wall components such as glucan or alkali-acid treated glucomannan. The highest CMC level was detected after 7-10 days of PBMC incubation in the presence of 50 micrograms/ml of whole Candida cells and the cytotoxic immunoeffectors elicited by these antigenic stimulations equally affected NK-susceptible (K562) and NK-resistant (Raji, Daudi and Jurkat) tumor cell lines. Both Interleukin-2 (IL-2) and gamma interferon (IFN-gamma) were produced by GMP-stimulated PBMC, the IL-2 peak production constantly preceding that of IFN production. GMP-induced generation of natural CMC was potentiated by the addition of IFN-gamma and a monospecific anti IFN-gamma serum totally abrogated both IFN activity and CMC generation. The cytolytic effectors were shown to be OKT3-, OKT8- and HLA-DR-. They did not possess typical NK markers (e.g. Leu-7 and AB8.28) but were partially recognized by A10, a IgG2a monoclonal antibody reacting to PBMC-NK lymphocytes and activated T cells. These results suggest that the antitumor cytolytic effectors generated in PBMC cultures exposed to Candida material belong either to a discrete subset of natural effectors lacking classical NK markers or to other lymphokine-activated cells. This study also suggests that the human indigenous microrganisms C.albicans may play a role in raising nonspecific antitumor effects in normal host.     

Fungicidal activity of Candida albicans-induced murine lymphokine-activated killer cells against C. albicans hyphae in vitro.

Multiple intraperitoneal injections of inactivated Candida albicans cells resulted in the generation of cytotoxic peritoneal cells with phenotypical and functional properties similar to in vitro-generated lymphokine-activated killer (LAK) cells. Using an in vitro [3H]glucose uptake assay, C. albicans-induced LAK-like (CA-LAK) cells exhibited high levels of anti-hyphal activity, the effects being effector to target cell (E:T) ratio- and time-dependent. Maximal levels of anti-C. albicans activity (approximately 60%) were observed after 4 h and at E:T greater than or equal to 300:1. Similar patterns of anti-C. albicans activity were exerted by in vivo-activated natural killer (NK) cells, in vitro interleukin-2- (IL-2) generated LAK cells and polymorphonuclear cells. The anti-hyphal activity of CA-LAK cells was enriched by separation on a Percoll gradient, F2 and F3 fractions retaining most of the activity. Experiments using immunodepressed animals demonstrated that the in vivo lethality of the C. albicans hyphal form is significantly affected by in vitro pre-exposure to CA-LAK cells. While control mice receiving C. albicans alone had a median survival time of 2 d, mice receiving C. albicans pre-exposed to CA-LAK cells (E:T = 300:1) had a median survival time of 15 d. Overall, the susceptibility of the C. albicans hyphal form to CA-LAK cells suggests that C. albicans-induced effectors might play a significant role as a second-line defence mechanism against the C. albicans hyphal form.     

Human lymphokine-activated killer (LAK) cells: identification of two types of effector cells

We analyzed the antigenic phenotype of lymphokine-activated killer (LAK) effector cells. Human blood lymphocytes were cultured for 3 days with 100 U/ml recombinant interleukin 2 (rIL 2), subpopulations isolated with monoclonal antibodies and a fluorescence-activated cell sorter (FACS) and assayed for cytotoxic activity against 51chromium labeled noncultured melanoma tumor cells. Initial experiments compared the LAK effector function of CD5+ T lymphocytes vs CD5- cells (predominantly CD16+ NK cells). The mean percent specific release at a 10:1 effector:target (E:T) ratio was 25% +/- 16 for CD5- cells, 10% +/- 6 for CD5+ cells, and 22% +/- 9 for unsorted cells. In contrast, when lymphocyte subpopulations were isolated before rIL 2 culture (LAK precursors), CD5- cells but not CD5+ cells developed LAK activity (28% +/- 12 vs 1% +/- 1, mean percent specific release, 10:1 E:T ratio), confirming our previous results showing that only CD16+ cells were LAK precursors. The discrepancy between LAK effector and precursor phenotypes suggested that LAK precursors acquired CD5 determinants during rIL 2 culture; however, double label immunofluorescence of rIL 2 cultured CD16+ cells showed that this was not the case. The data suggested that in the presence of other cell types, some T lymphocytes may develop LAK activity, but purified blood T lymphocytes do not develop LAK function when cultured with rIL 2 alone. We also analyzed LAK effector function in lymphocyte subpopulations defined by CD4 and CD8 antigens. The data showed that lymphocytes with a low density expression of CD8 and no expression of CD4 were enriched for LAK effector cells, whereas CD4+ and CD8- had less activity than unsorted cells. Lymphocytes with a high density expression of CD8 had activity similar to unsorted cells. We also assessed the contribution of Leu-7 (HNK-1) granular lymphocytes to LAK effector function. After culture with IL 2, lymphocytes were depleted of Leu-7+ cells by antibody and complement treatment and then were sorted into CD5+ and CD5- fractions. The cytotoxic activity of Leu-7-CD5+ cells was a mean 5% +/- 5 vs a mean 14% +/- 8 for the total CD5+ population (20:1 E:T ratio). The activity of Leu-7- CD5- was slightly less than the total CD5- fraction (21% +/- 9 vs 28% +/- 14, 10:1 E:T ratio). In conclusion, LAK effector function was highest in non-T cell (CD5- CD16+) populations and some activity was also present in T cell populations (CD5+ and predominantly Leu-7+).     

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.     

Human lymphokine-activated killer (LAK) cells

Summary Pretreatment of peripheral blood mononuclear cells (PBMC) with 5 mMl-phenylalanine methyl ester (PheOMe) provides an efficient means to deplete monocytes. PheOMe does not affect the number of large granular lymphocytes after the pretreatment, but does inhibit natural killer cell cytotoxicity temporarily after the pretreatment. However, depletion of monocytes by PheOMe allows lymphokine-activated killer (LAK) cell generation with recombinant interleukin-2 (rIL-2) at high cell density (> 5 × 10⁶ cells/ml). The time of the PheOMe pretreatment is 40–60 min, though some effect could be observed within 15 min, and the pretreatment could be performed at room temperature. Pretreatment density of PBMC with 5 mM PheOMe could be achieved at cell density up to 3 × 10⁷ cells/ml. PheOMe-pretreated cells could be activated by rIL-2 in serumless media at high cell density. Pretreatment of PBMC with 5 mM PheOMe provides an efficient means to deplete monocytes, as compared to plastic and nylonwool adherence. LAK cell generation is similar in both methods of monocyte depletion; therefore, depletion of monocytes allows, LAK cell generation at high cell density. The PheOMe procedure provides an improved and convenient process for preparing LAK cells for adoptive immunotherapy.     

Potentiated lymphokine-activated killer cell activity generated by low-dose interleukin-2 and mismatched double-stranded RNA

Summary Lymphokine-activated killer (LAK) cell activity was measured in human peripheral blood mononuclear cells (PBMC) treated in vitro for 3 days with recombinant interleukin-2 (rIL-2) and mismatched double-stranded RNA (dsRNA). Lytic activity was measured utilizing K562 (NK-sensitive) and 786-0 (NK-resistant) target cells. PBMC cultured with rIL-2 (10–1000 BRMP U/ml) alone showed concentration-dependent lytic activity against the 786-0 target cells, while cells cultured in unsupplemented medium or medium supplemented with mismatched dsRNA (200 µg/ml) alone could not lyse the 786-0 targets. The combination of mismatched dsRNA with suboptimal concentrations of rIL-2 (10–30 U/ml) showed enhancement of both natural killer (NK) and LAK cell activities. The uptake of [³H]thymidine by treated effector cells was dependent on time and rIL-2 concentration and was not increased in the cells treated with low-dose rIL-2/mismatched dsRNA, compared to those treated with low-dose rIL-2 or mismatched dsRNA alone. Similarly, changes in the expression of CD3, CD4, CD8, CD57, CD16 and CD25 cell surface antigens were dependent on rIL-2 concentration and not altered by the presence of mismatched dsRNA. These results indicate that mismatched dsRNA can potentiate rIL-2-induced LAK cell activity by increasing the functional activity per cell, rather than by increasing the number of activated cells.     

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.     

Heterogeneity of long-term cultured activated killer cells induced by anti-T3 antibody

The present study has characterized the short term and long term cultured murine-activated killer (AK) cells that are induced by antibody directed against the epsilon-chain of T3 complex. The conventional lymphokine AK (LAK) cells were generated by culturing normal B6 spleen cells with purified human rIL-2. The alpha T3-induced AK cells (T3AK) were induced by culturing normal B6 spleen cells with alpha T3 and were then maintained in culture medium supplemented with human rIL-2 and/or alpha T3. After initial activation with alpha T3, lymphocyte proliferation and generation of cytotoxic effectors (T3AK) were noted, and these events were related to the endogenous production of IL-2 and IL-4. Addition of alpha IL-2 and/or alpha IL-4 suppressed both the proliferative response and the cytotoxic response induced by alpha T3. In comparing the T3AK cells with the conventional LAK cells, there were many similarities as well as some distinct differences. Both cells displayed a similar cytotoxic spectrum against a variety of tumor targets. The T3AK cells usually gave much higher levels of cytotoxic activity against susceptible targets. However, the susceptibility of different tumor targets to conventional LAK cells and T3AK cells varied. The time course for the generation of lytic activity also differed between the conventional LAK and T3AK cells. One distinct difference was their ability to survive in vitro. The conventional LAK cells survived in culture for only 1 wk. The T3AK cells could survive for at least 4 to 5 wk with active growth. The serologic phenotype of the LAK precursors was asialo GM1 (AsGM1+) cells, but the T3AK precursors could be either AsGM1+ or AsGM1-, depending on the target cell. The LAK effectors were both Lyt-2+ and Lyt-2-, but the short-term T3AK effectors were exclusively Lyt-2+. The long term T3AK cells (cultured for more than 2 wk) were found to consist of Lyt-2+ and Lyt-2- cells, and these subsets of T3AK cells showed different target specificities. These findings demonstrate the heterogeneity of LAK and T3AK cells, and this heterogeneous property may contribute to their diversity in specificity against different tumor targets and thus may affect their effectiveness in the immunotherapy of cancer.