Conjugate Formation by Leukemic Blasts from Acute Myeloid Leukemia with Cytotoxic Lymphocytes

Conjugate formation by AML blasts with fresh peripheral blood lymphocytes (PBL) and lym-phokine activated killer (LAK) effectors was studied by flow cytometry. Leukemic blasts formed very low numbers of conjugates with fresh PBL and were resistant to natural killer (NK) cytotoxicity. When LAK effectors were used a significant increase in conjugate formation was observed, which in the majority of cases was followed by an increased killing. There was a positive correlation between the percentages of conjugates formed by AML blasts with LAK effectors and the susceptibility to lysis. No significant difference in binding activity between the CD3+ and CD56+ LAK subpopulations was found. There was no correlation between the expression of ICAM-1, LFA-3 and Transferrin receptor (CD71) and the conjugate formation. The blocking of CD71 on the control K562 cell line reduced the conjugate formation with LAK effectors but no such effect could be observed with CD71 + AML blasts.     

Human recombinant interleukin-4 inhibits lymphokine-activated killer activity of sheep erythrocyte rosette-forming (E+) and -non-forming (E-) human lymphocytes

The effect of human recombinant interleukin-4 (rIL-4) on lymphokine-activated killer activity (LAK) of peripheral blood lymphocytes (PBL) as well as sheep erythrocyte rosette-forming (E+) and -non-forming (E-) lymphocytes stimulated by human recombinant interleukin-2 (rIL-2) has been investigated. rIL-4 drastically inhibited LAK activity of PBL cultured for 18 hr and for 5 days in the presence of rIL-2. Distribution of T, B and IgG Fc-receptor-bearing lymphocytes, as assessed by immunofluorescence and flow cytometry, was no different at the end of the culture in the presence of rIL-2 plus rIL-4 than with rIL-2 alone. LAK activity of E+ and E- lymphocytes was similarly inhibited. Finally, rIL-4 did not affect the natural killer (NK) activity of rIL-2-activated PBL as assessed by the capacity of these cells to kill the appropriate NK target.     

Recombinant interleukin-2 activates peripheral blood lymphocytes from children with acute leukemia to kill autologous leukemic cells

In order to determine if recombinant interleukin-2 (rIL-2) can induce lymphokine-activated killer (LAK) cells able to lyse autologous leukemic cells, we incubated peripheral blood (PB) mononuclear cells from children with acute leukemia with 50 U/ml rIL-2 for 5 days. These PB effector cells were then tested for their ability to lyse autologous leukemic cells in a 51CR release assay. The PB cells before incubation with rIL-2 showed little or no cytotoxicity for autologous blasts (range, 0 to 12%; mean, 2%). However, after incubation with rIL-2, PB cells from four of five children with acute lymphoblastic leukemia (ALL) at diagnosis or in relapse, and from six of eight children with ALL in remission were able to lyse autologous blasts. The percent lysis (range) was 0 to 69% (mean, 37%) for the former group, and 0 to 113% (mean, 43%) for the latter group. The PB cells from three patients (one in relapse and two in remission) failed to develop LAK activity after incubation with rIL-2. However, in each case cytotoxicity versus K562 was increased after incubation with rIL-2. Furthermore, in a Phase I study of rIL-2 for the treatment of refractory leukemia, a patient was treated with rIL-2 for 3 weeks (nine injections of 3 x 10(6) U/m2 each). Her fresh PB mononuclear cells developed a low level of cytotoxicity (11% lysis) against her autologous blasts during this time. The finding that rIL-2 in vitro and in vivo induces LAK cells with cytotoxicity against autologous leukemic cells provides the rationale for the clinical trial of this agent in the treatment of children with ALL.     

Lysis of human leukemic cells by monocyte-derived macrophages activated with interferon-gamma and interleukin-2

Cytolysis of leukemic cells by peripheral blood-derived macrophages was examined by means of an in vitro 111In release assay. Monocytes prepared on culture dishes lyse YK-M2. However, when monocytes were cultured in vitro and transformed into macrophages, they lost most of their lytic activity. The addition of human recombinant interleukin-2 (rIL-2) on day 5 in culture enhanced the lytic activity significantly. Similarly, treatment of macrophages with human recombinant interferon gamma (rIFN-gamma) promoted the lysis of YK-M2 and K-562, although the extent of lysis was smaller than that by rIL-2. Macrophages activated with rIL-2 and rIFN-gamma also lysed human leukemic cells. Activated macrophages lysed leukemic cells of acute myelocytic leukemia more than acute lymphocytic leukemia cells. Macrophages derived from the peripheral blood of patients with leukemia were examined for their lytic activity against YK-M2. The patient's macrophages lysed more YK-M2 than did control macrophages when they were activated with rIL-2 and rIFN-gamma. The macrophages of two patients also demonstrated autologous leukemic cell lysis.     

Lysis of Human Leukemic Cells by Monocyte-derived Macrophages Activated with Interferon-γ and Interleukin-2

Cytolysis of leukemic cells by peripheral blood-derived macrophages was examined by means of an in vitro ¹¹¹In release assay. Monocytes prepared on culture dishes lyse YK-M2. However, when monocytes were cultured in vitro and transformed into macrophages, they lost most of their lytic activity. The addition of human recombinant interleukin-2 (rIL-2) on day 5 in culture enhanced the lytic activity significantly. Similarly, treatment of macrophages with human recombinant interferon gamma (rIFN-γ) promoted the lysis of YK-M2 and K-562, although the extent of lysis was smaller than that by rIL-2. Macrophages activated with rIL-2 and rIFN-γ also Iysed human leukemic cells. Activated macrophages lysed leukemic cells of acute myelocytic leukemia more than acute lymphocytic leukemia cells. Macrophages derived from the peripheral blood of patients with leukemia were examined for their lytic activity against YK-M2. The patient's macrophages lysed more YK-M2 than did control macrophages when they were activated with rIL-2 and rIFN-γ. The macrophages of two patients also demonstrated autologous leukemic cell lysis.     

Lymphokine-activated killer cell plus recombinant interleukin-2 therapy of erythroleukemia in mice

The antileukemic effects of lymphokine-activated killer (LAK) cells plus recombinant interleukin-2 (rIL-2) therapy were assessed in mice with Friend virus (FV)-induced erythroleukemia. LAK cells were generated by incubating normal spleen cells for 72 hr in the presence of rIL-2 (1000 units/ml). At the time of injection, the LAK cells were cytotoxic in vitro against FV-infected fibroblasts and NK-sensitive and -resistant tumor targets but not normal controls. To determine in vivo activity, fully leukemic mice (spleen weight greater than 0.75 g) were injected with either PBS or LAK cells (10(8) cells/mouse IV at 14 and 17 days post virus) and rIL-2 (10,000 units/mouse IP every 8 hr on days 14 through 18 post virus). More than 70% of the progressively leukemic mice experienced permanent leukemia regressions (disease-free for greater than 100 days) following LAK cell plus rIL-2 therapy. Regressions were characterized by return of spleen and liver weights to normal and elimination of virus-infected erythroid (CFU-E) and macrophage (CFU-C) progenitor cells from spleen and marrow. Leukemic animals treated with either LAK cells alone or IL-2 alone experienced only transient leukemia regressions. These results demonstrate that LAK cell plus rIL-2 treatment can induce permanent regressions in progressively leukemic mice and provide a responsive and manipulable model system to elucidate the mechanisms involved in this form of immunotherapy.     

Interleukin-2-activated lymphocytes from brain tumor patients. A comparison of two preparations generated in vitro

Two preparations of human recombinant interleukin-2 (rIL-2)-activated lymphocytes from patients harboring malignant brain tumors were characterized as autologous-stimulated lymphocytes (ASL) and lymphokine-activated killer (LAK) cells. ASL were generated from Ficoll-Paque-isolated, nonadherent, defibrinated peripheral blood lymphocytes (PBL) that were stimulated overnight with phytohemagglutinin (PHA) and cultured with rIL-2 (100 U/ml) for 10 days. LAK cells were produced by culturing all PBL in rIL-2 (500 U/ml) for 4 days. In 4-hour chromium release assays, LAK cells showed greater cytotoxicity than ASL against natural killer (NK)-sensitive and NK-resistant tumor cell lines; by 18 hours, the effectiveness of ASL equaled that of LAK cells. By electron microscopic study, PBL, LAK cells, and ASL showed differences. The helper/inducer to suppressor/cytotoxic ratio (T4+/T8+) of PBL, LAK cells, and ASL was 1.1:1, 1.0:1, and 0.4:1, respectively. ASL, when compared with PBL or LAK cells, have a significantly higher percentage of MO1+/DR+ and T8+/9.3+ subpopulations. ASL and LAK cells, used for the therapy of gliomas, are distinct.     

In vivo and in vitro activation of natural killer cells in advanced cancer patients undergoing combined recombinant interleukin-2 and LAK cell therapy

Patients with advanced metastatic cancer were given combined autologous lymphokine activated killer (LAK) cell and recombinant interleukin-2 (rIL-2) therapy on a National Cancer Institute extramural phase II trial. Systemic administration of rIL-2 resulted in pronounced lymphocytopenia. Within two days after completion of in vivo rIL-2 therapy, there was a dramatic increase in absolute numbers of circulating lymphocytes, and cytotoxic activity against tumor cell targets was mediated by peripheral blood lymphocytes, indicating in vivo generation of LAK activity. Patients were leukapheresed and cells cultured for three to four days in rIL-2. rIL-2 cultured cells from all patients demonstrated cytotoxic activity. In order to characterize the effector cell, T cells and natural killer (NK) cells were isolated to greater than 95% purity by flow cytometry. Cytotoxic activity was mediated by rIL-2--activated NK cells, whereas T cells demonstrated no substantial activity. The circulating in vivo cytotoxic effectors detected after in vivo rIL-2 therapy were also shown to be rIL-2--activated NK cells. Results from these studies demonstrate that all patients were capable of generating a cytotoxic response, and that the cytotoxic effector cells were rIL-2--activated NK cells, identified by the phenotype CD3--, Leu 19+.     

Increased susceptibility to lymphokine activated killer (LAK) lysis of relapsing vs. newly diagnosed acute leukemic cells without changes in drug resistance or in the expression of adhesion molecules.

The NK and LAK activity of peripheral blood lymphocytes of leukemic patients as well as the susceptibility of their acute myeloid (AML) and lymphoblastic (ALL) leukemia cells to autologous and allogeneic LAKs were examined. In addition, neoplastic cells at diagnosis and at relapse were compared in the same patients for several features, including in vitro susceptibility to LAKs and to the drugs used in the induction phase, expression of MDR phenotype and of adhesion molecules, and differentiation markers. The NK activity of patients' LAK cells on K562 was significantly lower than that of a group of healthy donors whereas no differences were found in LAK activity as evaluated on Daudi cells. Three of 5 AML and 3 of 4 ALL were significantly more susceptible to autologous and allogeneic LAK lysis when blasts obtained at relapse were compared with leukemic cells of the same patients at diagnosis. This different lysability was not associated with in vitro modified sensitivity to drugs used in induction treatment. Moreover, no elevation in the expression of the multidrug-resistance (MDR)-related P170 glycoprotein was noted in relapsing leukemic cells. Even the expression of adhesion molecules and differentiation markers did not correlate with lysability of leukemic cells. These data demonstrate that relapsing leukemic blasts can be significantly lysed by LAK cells and suggest a rationale for adoptive immunotherapy with IL-2 and LAK cells in the treatment of acute leukemic patients.     

Inhibition of colony formation of drug-resistant human tumor cell lines by combinations of interleukin-2-activated killer cells and antitumor drugs

The cytotoxicity of interleukin-2-activated killer (LAK) cells with or without anticancer drugs against cell lines with acquired drug resistance was evaluated in vitro by colony assay. Human non-small cell lung cancer cell lines, PC-9 and PC-14, human leukemia cell line, K-562, and their sublines resistant to cisplatin (CDDP), PC-9/CDDP and PC-14/CDDP, and to adriamycin (ADM), K-562/ADM, were used as target cells. PC-9/CDDP demonstrated a marked increase in susceptibility to killing by both peripheral blood lymphocytes (PBL) and LAK cells, as compared to the parental cell line, PC-9. The cytotoxicity of PBL and LAK cells against PC-14/CDDP and K-562/ADM was similar to that against their parental cell lines. Moreover, the combination of LAK and CDDP had a synergistic effect on PC-14 and PC-14/CDDP.     

Inhibition of Colony Formation of Drug-resistant Human Tumor Cell Lines by Combinations of Interleukin-2-activated Killer Cells and Antitumor Drugs

The cytotoxicity of interleukin-2-activated killer (LAK) cells with or without anticancer drugs against cell lines with acquired drug resistance was evaluated in vitro by colony assay. Human non-small cell lung cancer cell lines, PC-9 and PC-14, human leukemia cell line, K-562, and their sublines resistant to cisplatin (CDDP), PC-9/CDDP and PC-14/CDDP, and to adriamycin (ADM), K-562/ADM, were used as target cells. PC-9/CDDP demonstrated a marked increase in susceptibility to killing by both peripheral blood lymphocytes (PBL) and LAK cells, as compared to the parental cell line, PC-9. The cytotoxicity of PBL and LAK cells against PC-14/CDDP and K-562/ADM was similar to that against their parental cell lines. Moreover, the combination of LAK and CDDP had a synergistic effect on PC-14 and PC-14/CDDP.     

Lymphokine-activated killer (LAK) cells discriminate between Epstein-Barr virus (EBV)-positive Burkitt's lymphoma cells

We have generated in vitro lymphokine-activated killer (LAK) cells from healthy donors by stimulating their mononuclear leukocytes with recombinant interleukin-2 (rIL-2) (100 U/ml). After 6 days in culture, the lytic properties of the LAK cells were analyzed in the 51Cr-release assay by utilizing a target panel of 6 paired lines consisting of an Epstein-Barr virus (EBV)-positive Burkitt's lymphoma (BL) cell line and an EBV-transformed lymphoblastoid cell line (LCL) from the same donor, the Raji BL line and the natural killer (NK) cell-sensitive K562 line. The patterns of lysis showed that the LAK cells discriminated between two categories of BL cell lines. Group I/II BL tumor cells which expressed the common acute lymphoblastic leukemia antigen (CALLA), the BL-associated glycolipid antigen (BLA) and phenotypically resembled biopsy cells were strongly lysed whereas group III BL cells which had assumed an LCL-like phenotype during culture and lacked the CALLA and BLA surface markers were only poorly lysed. The LCL targets were generally resistant to lysis but the K562 cell line was particularly sensitive. The outcome of cell depletion and monoclonal antibody (MAb) studies indicated that the LAK cell populations were phenotypically and functionally heterogeneous and consisted of at least 2 subpopulations of effector cells; a tumor-specific component and an NK-cell-mediated component.     

Lymphokine-activated killer cells: culture conditions for the generation of maximal in vitro cytotoxicity in cells from normal donors

The current method for generating lymphokine-activated killer (LAK) cells for use in human clinical trials is both labor intensive and expensive. Therefore, we altered cell culture conditions to determine whether LAK cells with enhanced lytic activity could be generated. Culture of normal human peripheral blood leukocytes for 7 days generated LAK cells with 4-fold more lytic activity than culture for 3 days. Although cell viability over this 7-day period dropped from 94% on Day 3 to 73% by Day 7, the recovery of cells from culture increased from 61 to 106%. If cells were exposed to CO2, lytic activity was further enhanced by up to 30-fold. Culture at a density of 1 or 2.5 X 10(6) cells/ml caused no difference in cell viability, recovery, or LAK activity when cells were cultured for up to 4 days; however, when cells were cultured for longer times, an initial density of 1 X 10(6) cells/ml yielded maximal LAK activity. Several commercially available serum-free defined media as well as human serum albumin supported LAK cell activation comparable to serum-containing media over a 4-day culture period. One defined medium, AIM V, supported LAK cell activation over a 7-day period even when cells were cultured at a density twice as high (2 X 10(6) cells/ml) as cells cultured in serum-containing medium. The results demonstrate that simple manipulation of human LAK cell culture conditions generates cells with greatly enhanced lytic activity and that serum-containing medium may not be necessary for generating LAK cells under the current clinical protocols.     

Identification and selection of human lymphokine activated killer cell effectors and novel recycling intermediates by unique light-scattering properties

When peripheral blood lymphocytes (PBL) are incubated with interleukin 2 (IL 2), a novel cytotoxic lymphocyte subpopulation, termed lymphokine activated killers (LAK), arises. LAK are functionally defined as IL 2 responsive cells demonstrating major histocompatibility antigen-unrestricted cell-mediated cytotoxicity against fresh solid tumors and other natural killer cell-resistant and -sensitive tumor targets in the absence of prior antigen priming. Flow cytometric analysis of IL 2 activated PBL using forward and right angle light scatter and fluorescence intensity identified the emergence of a large, optically dense, autofluorescent cell population which paralleled the generation of LAK activity. These unique IL 2 induced lymphocytes have been named giant autofluorescent lymphocytes (GAL). These cells are readily distinguished from the small nonfluorescent lymphocytes (SNL) observed in fresh PBL, unstimulated cultured PBL, and those cells remaining after incubation with IL 2 which have not acquired GAL characteristics. In this investigation, LAK cultures were sorted on days 4, 5, and 6 into GAL and SNL populations and were tested for oncolytic activity against the natural killer-resistant Daudi and RC-1 tumor targets. Against these targets, lymphocytes from non-IL 2 activated PBL or the sorted SNL population expressed less than 2% of the oncolytic activity (measured in lytic units) exhibited by GAL effectors. The SNL and GAL populations were cultured in IL 2 for up to 48 h following the sorting procedure and then reassayed for tumor cytolytic activity. During this culture period, GAL but not SNL continued to express LAK killing against natural killer-resistant tumor targets. Using gamma-irradiation to prevent further cell cycling, it was shown that the functional half-life of the LAK effector was approximately 8.5 h. Therefore, the cytotoxicity expressed by the sorted GAL population after 48 h in culture (equivalent to five functional half-lives) must be expressed by progeny of the originally plated lymphocytes. These results indicate that in addition to the LAK effector, the GAL population contains a self-sustaining, recycling intermediate responsible for generating new LAK. Our data indicate that analysis of IL 2 activated PBL using GAL light-scattering properties has application in phenotyping LAK, monitoring of cellular kinetics, cell sorting, and enrichment of the LAK effector population, and in the clinical monitoring of IL 2 therapy.     

Phase I trial of intraperitoneal recombinant interleukin-2/lymphokine-activated killer cells in patients with ovarian cancer

Ten patients with ovarian cancer refractory to conventional therapy were treated with intraperitoneal (i.p.) recombinant interleukin-2 (rIL-2) and lymphokine-activated killer cells (LAK). The 28-day protocol consisted of 6 priming i.p. rIL-2 infusions on days 0, 4, 6, 8, 10, and 12. Leukapheresis was performed for mononuclear cell collection on days 15, 16, 17, and 18 and lymphokine-activated killer cells were given i.p. with the rIL-2 on days 19 and 21. Three additional i.p. rIL-2 infusions were given on days 23, 25, and 27. Three dose levels of rIL-2 were tested: 5 X 10(5), 2 X 10(6), and 8 X 10(6) units/m2 body surface area. The dose-limiting toxicity was abdominal pain secondary to ascites accumulation with significant weight gain. Other toxic effects included decreased performance status, fever, nausea and vomiting, diarrhea, and anemia. Peripheral lymphocytosis and eosinophilia were seen at all dose levels. The maximum tolerated dose is 8 X 10(6) units/m2/dose. Peripheral and peritoneal IL-2 levels were measured with a bioassay using an IL-2-dependent cell line. At the highest dose level, serum IL-2 was greater than 10 units/ml for 18 h. After the first infusion, a 2-log dilution of the i.p. IL-2 was measured in the serum. In the postleukapheresis i.p. IL-2-dosing period less IL-2 was detected in the serum than in the earlier i.p. IL-2-priming period. The induction and persistence of LAK activity were studied. Peritoneal LAK activity was detected as early as 4 days after the first i.p. infusion, by day 11 in all evaluable patients, and persisted for the 6-day interval between priming IL-2 and LAK/IL-2 infusion. Peritoneal lytic activity persisted until day 28 in 5 tested patients. These peritoneal cells retained lytic activity 48 h in culture medium without rIL-2 present. Peritoneal LAK activity correlated with the percentage of mononuclear cells and the percentage of CD56-positive mononuclear cells in the peritoneum. The yield of peripheral lymphocytes after the six i.p. priming doses of rIL-2 correlated with the dose level of rIL-2 infused. Peripheral blood LAK activity showed a minimal, however progressive, increase during the treatment protocol. LAK activity could be enhanced if rIL-2 was present during the 4-h assay. These studies indicate that i.p. rIL-2 infusion induced durable regional LAK activity and primes peripheral blood cells for LAK activity if exposed briefly to additional IL-2.     

Augmentation of the Susceptibility of Human Leukemia to Lymphokine-Activated Killer (LAK) Cells by Exposure of the Leukemic Target Cells to Cytotoxic Drugs in Vitro and in Vivo

Experimental studies have shown that interleukin-2-induced lymphokine-activated killer (LAK) cells are able to lyse fresh noncultured leukemia cells and that human leukemia cells have a distinct susceptibility to LAK-cell-mediated cytolysis. Cytolysis is considerably lower with fresh noncultured leukemia cells than with the leukemia cell lines K562 and Daudi. For therapeutic considerations it would be desirable to achieve as much cytolysis as possible. The current study revealed that incubating leukemia cells with cytotoxic drugs in vitro significantly augments their susceptibility to the lytic effect of LAK cells and, more importantly that exposing leukemia cells to anticancer agents in vivo during induction chemotherapy also increases their sensitivity to LAK-cell-mediated cytolysis. These results support a possible benefit from combining chemotherapy with immunotherapeutic approaches in leukemia treatment.     

Generation of lymphokine-activated killer cells in strain 2 guinea pigs and their use in the therapy of L2C, an acute B-cell leukemia

Lymphokine-activated killer (LAK) cells were induced by incubating strain 2 guinea pig splenocytes or lymph node-derived cells in recombinant human interleukin-2 (IL-2) for 3-5 days. These effector cells had the morphology of lymphoblasts and were able to lyse murine P815 tumor cell targets. Fresh, unstimulated, guinea pig effectors were not capable of lysing these targets. The therapy of the L2C leukemia, an acute B-lymphoblastic leukemia of strain 2 guinea pigs, using LAK cells and recombinant IL-2 was examined. Antitumor effects were demonstrated by premixing LAK and tumor cells prior to intradermal injection in Winn type assays and then measuring the growth of local tumor and survival of the animals. In further experiments i.p. administration of LAK cells, 4 h following tumor cell inoculation by the i.p. route, prolonged the survival of treated animals. The best results in this i.p. therapy model were obtained with a 10-fold excess of LAK cells over tumor cells plus additional treatment with 1000 units of IL-2 for 20 days. This resulted in a 10-day increase in median survival of treated animals. Despite these in vivo antitumor effects, lytic activity of LAK effector populations against L2C targets could not be demonstrated in vitro. The potential synergy between LAK cells, IL-2, and a monoclonal antibody directed against the idiotype of the neoplastic cell surface immunoglobulin was also investigated. In these experiments enhanced survival of the combined treatment group, beyond that of either singly treated group, was not found. This study shows that LAK cells are useful agents in the therapy of a widely disseminated, aggressive, B-cell lymphoblastic leukemia. The use of such effectors, even in cases where in vitro lysis of the target tumor cell cannot be demonstrated, is encouraged by these results.     

Lymphokine activated killing of fresh human leukaemias

The relative susceptibility of 10 human leukaemias comprising acute phase leucocytes from 5 acute myeloid and 5 lymphoid neoplasms, and 2 immunoblastic lymphomas to killing by peripheral blood mononuclear cells (PBMC), before and after target cell treatment with phytohaemagglutinin (PHA), and by interleukin-2 (IL-2) activated peripheral blood lymphocytes (PBL) was investigated in short term 51Cr release assays using effector cells from 10 allogeneic donors. Optimal lectin-dependent cellular cytotoxicity (LDCC) was verified against K562 and L1210 cells and lymphokine-activated killing (LAK) against K562 and Daudi cells. Under these conditions, the majority of the leukaemias tested revealed only a finite sensitivity to any of the cytotoxic mechanisms, which was dependent on the donor origin of the effectors. The leukaemias were more consistently susceptible to LDCC than LAK and removal of adherent cells to enrich for the latter activity in effector populations, was ineffective. Lymphocytes from a patient in long term (greater than 5 yr) remission exhibited LAK against the autologous target E84, a natural killer (NK)-sensitive acute myelomonocytic leukaemia. These cells failed to cross-compete for lysis of K562 by LAK cells, suggesting the existence of different recognition structure(s) on the two targets.     

Lymphokine-activated killer cells in rats: analysis of tissue and strain distribution, ontogeny, and target specificity

The coculture of lymphoid cells from Fischer 344 rats with recombinant human interleukin 2 (rIL-2) resulted in the generation of lymphokine-activated killer (LAK) cells. Maximal LAK activity was obtained between 200 and 1000 units/ml rIL-2. Lymphoid cells from spleen, thymus, bone marrow, peripheral blood, and lymph nodes were able to generate LAK activity although the kinetics and magnitudes of the responses were appreciably different among these tissues. Thus, while spleen and blood lymphocytes responded quickly (by day 3) and gave the highest level of LAK activity in response to rIL-2, bone marrow and thymus cells responded only by 7 to 9 days in culture. LAK activity could be generated from a variety of rat strains regardless of whether there were high or low levels of endogenous splenic natural killer (NK) activity, but the early (day 3) response was lower in the strains with low levels of NK activity. Cells with LAK activity could lyse a variety of tumor targets including fresh ascites or fresh syngeneic solid tumor explants but could not lyse fresh normal cells including syngeneic fibroblasts, peripheral blood lymphocytes, bone marrow cells, thymocytes, or T,B blasts. The generation of LAK activity required a concomitant proliferative response and could be completely abrogated by mitomycin C, actinomycin D, or X-irradiation above 500 rads. These treatments, however, did not affect natural killer activity or short-term (4 h) IL-2-boosted NK activity. LAK activity could be generated from spleen cells obtained from rats as early as 10 days of age but could not be generated from unfractionated neonatal spleen, neonatal liver, or peritoneal macrophages. The ontogeny of the development of splenic LAK activity correlated closely to the development of concurrent natural killer activity. When mixed with an NK-resistant mammary adenocarcinoma (MADB106) and adoptively transferred to normal syngeneic recipients in standard Winn-type assays, LAK cells were effective at inducing complete tumor inhibition.     

Functional analysis of cytotoxic cells in patients with acute nonlymphoblastic leukemia in complete remission

In the current study, we investigated the cytotoxic ability of peripheral blood mononuclear cells (PBMC) recovered from patients with acute nonlymphoblastic leukemia (ANLL) in complete remission (CR) against natural killer (NK)-sensitive, NK-resistant, autologous and allogeneic leukemic target cells taken at diagnosis. Our purpose was to define the role played by cytotoxic mechanisms in the control of leukemic cell growth in ANLL. Experiments were carried out at resting conditions and after in vitro activation with recombinant interleukin-2 (rIL-2) and anti-CD3 monoclonal antibody (moAb). At resting conditions, PBMC recovered from ANLL patients displayed a NK function that was not significantly different from controls (mean +/- standard error of the mean [SEM]: 21.9% +/- 3.9% versus control values of 27.5% +/- 2.9%; the P value was not significant [NS]), but they were unable to show cytotoxic activity against autologous and allogeneic leukemic cells. After in vitro boosting with rIL-2, PBMC were able to generate lymphokine activated killer (LAK) cells, as demonstrated by an increased killing of NK-resistant Daudi targets (16.3% +/- 2.7%). Although LAK activity was quantitatively lower than in control subjects (mean +/- SEM: 16.3% +/- 2.7% versus control values of 79.8% +/- 3.1%; P less than 0.001), it still exerted a cytotoxic effect against autologous and allogeneic leukemic cells. Similar results were obtained when anti-CD3 moAb was used as a stimulus in vitro. Our data suggest that nonspecific cytotoxic cells may be triggered to exert an in vitro cytotoxic effect on leukemic cells, which could possibly play a key role in vivo in the control of leukemic cell growth regulation.