Similarities and distinctions between murine natural killer cells and lymphokine-activated killer cells

Pretreatment of mice with rabbit anti-asialo GM1 removes both natural killer (NK) effector cells and NK cells responsive to interleukin 2 (IL-2). Spleen cells from these mice do possess normal lymphokine-activated killer (LAK) activity. Young mice (less than 3 weeks of age) do not have NK activity and do not possess IL-2-inducible NK effector cells. Similarly to anti-asialo GM1-treated mice, LAK cells can be generated from these mice. While these experiments indicate clear distinctions between a certain level of NK and LAK precursors, the distinctions are not as clear when analyzing mice congenitally deficient in NK cells. Beige mice which lack NK effector cells and IL-2-inducible NK cells also lack the ability to generate LAK cells. The relationships and differences between NK- and LAK-cell precursors and effectors are discussed.     

Comparison of lymphokine-activated killer activities between thymocytes and splenocytes in rats with brain tumors

Summary We studied the lymphokine-activated killer (LAK) activity in splenocytes and thymocytes of rats with brain tumors chronologically from the early stage to the late stage, in order to clarify how much LAK activity would be developed at each stage. Simultaneously the natural killer (NK) activity in splenocytes, as one aspect of the host immunocompetence, was also determined. The splenic NK activity was significantly depressed in rats with brain tumors during the 2nd and 3rd weeks after tumor transplantation, as compared with normal controls. On the other hand, the splenocytes incubated with interleukin-2 showed the same killer activity in rats with brain tumors as in normal rats at all times. The LAK activity in thymocytes from rats with brain tumors was significantly higher than that of controls in the 1st and 2nd weeks and became equal to that of the controls during the 3rd week. The killer activity after incubation with interleukin-2 in thymocytes was superior to that in splenocytes throughout the experiment in both tumor-bearing rats and controls, which suggested that the precursor of LAK cells was not NK cells.     

Lymphokine-activated killer cells are rejected in vivo by activated natural killer cells

A 4-h in vivo cytotoxicity assay was used to study the fate of implanted IL-2-generated, lymphokine-activated killer (LAK) cells in mice undergoing an activated NK cell response. 125Iododeoxyuridine-labeled LAK cells were rejected from selected organs of C57BL/6 mice infected with lymphocytic choriomeningitis virus or treated with IL-2 or the IFN inducer poly I:C. This rejection was abrogated by the selective depletion of NK cells with antibodies to asialo-GM1 and NK1.1 Ag. Similar results were noted when LAK cells were generated from the spleens of B and T cell-deficient severe combined immunodeficiency mice and when LAK cells were implanted into severe combined immunodeficiency mice. These data indicate that NK cells activated by virus infections or by IL-2 infusions directly or indirectly eliminate implanted LAK cells. Because LAK cells are used in the treatment of certain human cancers, the strategy of accompanying this therapy with IL-2 infusions should be reassessed in light of these results.     

Alterations in cell-surface carbohydrates of rat large granular lymphocytes associated with interleukin-2 activation

The activation of large granular lymphocytes (LGLs)/natural killer (NK) cells with interleukin-2 (IL-2) has been shown to increase the ability of these cells to lyse NK-resistant tumor target cells. Activated LGLs, termed LAK (lymphokine-activated killer) cells, have been demonstrated to be of therapeutic value in vivo against metastatic tumors. The mechanism by which IL-2 induces broadened cytolytic capability, as well as the molecular basis of target recognition and killing by the activated cells has not yet been elucidated. Since carbohydrate moieties have been demonstrated to be of possible significance in the cytolytic cascade of a variety of effector cells, the current study was undertaken to determine if the activation of LGLs with IL-2 is accompanied by an alteration of cell-surface carbohydrates. Two-color flow cytometry was performed to identify LGL/NK cells in populations of nylon wool-nonadherent splenic mononuclear cells and to assess the binding of various lectins to activated as well as nonactivated LGLs. Increases were observed in the binding of four lectins to LGLs after IL-2 activation; Triticum vulgaris (wheat germ agglutinin), Phytolacca americana (pokeweed mitogen), Lycopersicon esculentum (tomato lectin), and Griffonia simplicifolia I-B4 (GSI-B4). The wheat germ, pokeweed, and tomato lectins recognize complex carbohydrates structure consisting of GlcNAc(Bl,4GlcNAc)n while GSI-B4 recognizes alpha-D-galactose terminal end groups. Lectin binding to the activated LGLs was homogenous (i.e., flow cytometry revealed only a single population of fluorescent cells). Lectin binding to LGLs prior to activation was more heterogeneous, however, the tomato lectin uniquely revealed a bimodal distribution of receptors. These data indicate that LGL/NK cells from the rat are heterogeneous in their ability to bind specific lectins, and that IL-2 activation of these cells results in altered expression of specific cell-surface carbohydrates.     

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.     

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.     

Functional studies on the precursors of human lymphokine-activated killer cells

Human peripheral blood lymphocytes cultured for 4 days in the interleukin 2 (IL-2)-containing cell-free supernatant of the MLA144 cell line (MLA144CM) are cytolytic to NK-susceptible and NK-resistant tumor target cells. This lymphokine-activated killer (LAK) activity is dependent on IL-2 as development of LAK activity is inhibited in the presence of a monoclonal antibody (MoAb) reacting with the IL-2 receptor (anti-Tac). Addition of cyclosporin A (CyA) to mixed lymphocyte cultures inhibits the development of allospecific cytotoxic activity and inhibits the development of IL-2 responsiveness. However, development of LAK activity is unaffected by the inclusion of CyA in the cultures, showing that the LAK precursor can be functionally distinguished from the allospecific cytotoxic precursor cell. Development of LAK activity does not require mature NK cells as shown by the generation of LAK activity from NK inactive human thymocytes and lymph node cells. In addition, depletion of NK activity from human PBL does not impair the development of LAK activity.     

Lymphokine-activated killer cells in rats: generation of natural killer cells and lymphokine-activated killer cells from bone marrow progenitor cells

The coculture of rat bone marrow cells with recombinant interleukin-2 induced the generation of cells mediating natural killer (NK) activity and subsequent lymphokine-activated killer (LAK) activity depending upon the dose of IL-2 and time of culture. NK activity was detected as early as 4 to 5 days after the addition of IL-2 and could be evoked with as little as 5 to 50 U/ml. The induced NK cells had large granular lymphocyte (LGL) morphology and expressed 0X8 and asialo GM1 surface markers but did not express 0X19 or W3/25 markers. LAK activity was detected only after 5 days of culture, and required above 100 U/ml IL-2. Cells mediating LAK activity also expressed 0X8 and asialo GM1 but not 0X19. The generation of detectable NK and subsequent LAK activity was due to induction of early progenitor cells and not contaminating mature LGL/NK cells within the bone marrow population since of removal of such mature NK cells with L-leucine methyl ester (L-LME) did not affect the subsequent generation of either activity. Moreover, the removal of actively dividing cells as well as mature NK cells from the bone marrow by treatment with 5-fluorouracil (5-FU) in vivo enriched the remaining bone marrow population for both NK and LAK progenitor cells. The phenotype of the L-LME- and 5-FU-resistant NK and LAK progenitor cells within populations of bone marrow was determined by antibody plus complement depletion analysis. Although treatment of normal bone marrow with anti-asialo GM1 + C reduced the induction of NK and LAK activity in 5-day cultures, treatment of 5-FU marrow with anti-asialo GM1 + C did not affect either activity. Treatment with a pan-T cell antibody + C did not affect the development of NK or LAK activity under any conditions. Thus, the 5-FU-resistant NK/LAK progenitors were asialo GM1 negative but became asialo GM1+ after induction by IL-2. Finally, evidence that bone marrow-derived LAK cells were generated directly from the IL-2-induced NK cells was obtained by treating the IL-2-induced LGL/NK cells with L-LME.(ABSTRACT TRUNCATED AT 400 WORDS)     

High expression of NKR-P1 is not an absolute requirement for natural killer activity in BDIX rats

 NKR-P1 has been identified as a triggering structure selectively expressed on rat natural killer (NK) cells and adherent lymphokine-activated killer (A-LAK) cells. In vivo treatment with anti-NKR-P1 monoclonal antibody (mAb 3.2.3) was shown to induce complete inhibition of NK cytotoxicity and elimination of LAK cell precursors in Lewis and Fisher rat strains. We investigated the effects of mAb 3.2.3 in a colon tumor model in BDIX rats. Inoculation of animals with mAb 3.2.3 even at very high doses induced a strong but incomplete inhibition of NK cytotoxicity in nylon-wool-non-adherent spleen and peripheral blood cells. Generation of adherent A-LAK cells from their spleen precursors was also strongly but not fully inhibited. We also investigated the effect of treatment with mAb 3.2.3 on the tumorigenicity of the NK-sensitive REGb cell line. When subcutaneously inoculated in syngeneic animals, REGb cells induce tumors that first grow for 2 weeks, then spontaneously regress and disappear. In contrast with previous results using anti-asialoGM1, no significant difference in tumor growth was observed between rats treated with mAb 3.2.3 and control animals, even with a long-term treatment. In vitro, mAb 3.2.3 exhibited the same incomplete efficiency. Nylon-wool-non-adherent spleen cells treated with mAb 3.2.3 plus complement were completely free of 3.2.3^bright cells, but retained a substantial NK activity and generated LAK cells after culture with IL-2. After an overnight incubation in standard medium of 3.2.3-depleted spleen cells, 3.2.3^bright cells were partially recovered and the NK cytotoxic activity, as well as the generation of LAK cells, was significantly enhanced. These results suggest that a strong expression of NKR-P1 is not required for BDIX mononuclear cells to exhibit NK function and generate LAK cells under IL-2 activation. Received: 11 July 1995 / Accepted: 16 November 1995     

小鼠LAK细胞对粒—单系祖细胞增殖的影响

Murine lymphokine-activated killer (LAK) cells were generated from spleen cells of C57/BL6 mice by culture of spleen cells in vitro for 72 hours in medium containing 500 units/ml recombinant human interleukin 2 (IL-2), and effects of these LAK cells on proliferation of syngenic myeloid progenitor cells (CFU-GM) were observed. After 3 days culture, LAK cells were assayed for their cytotoxicity in a 4 hours 51Cr-release test. Either natural killer (NK) cell sensitive YAC-1 lymphoma cells or NK cell resistant LP-3 and WEHI-164 fibrosarcoma cells were efficiently lysed by murine LAK cells. When LAK cells were added into culture system in a final concentration of 5 x 10(4)/ml, 2 x 10(5)/ml, 8 x 10(5)/ml, CFU-GM were increased by 55.2%, 165.5%, and 194.4% of control respectively. LAK-CM also showed augmentative effect on CFU-GM growth. When 10% (v/v) of LAK-CM were added into culture system, CFU-GM were increased by 51.4% of control, but LAK-CM alone could not stimulate CFU-GM growth. Again, effects of LAK-BMC interaction on CFU-GM formation were investigated. CFU-GM were inhibited to 27.6% of control when 1 x 10(5) BMC were mixed with 8 x 10(5) LAK cells and incubated for 4 hours prior to CFU-GM culture. These data suggest that (1) LAK cells may secrete co-CSF which showed synergistic effect with CSF on CFU-GM proliferation: (2) When LAK cells contact with BMC, they showed significant cytotoxicity to myeloid progenitor cells which mediated decrease of CFU-GM formation.     

In vivo administration of low-dose human interleukin-2 induces lymphokine-activated killer cells for enhanced cytolysis in vitro

We have examined the effect of the intradermal administration of IL-2 on the generation of natural killer (NK) cell and lymphokine-activated killer (LAK) cell activity. Peripheral blood mononuclear cells (PBMC) obtained from borderline lepromatous (BL) and lepromatous leprosy (LL) patients and normal volunteers prior to and after IL-2 injection were stimulated in vitro with IL-2 and their cytolytic activities compared against 51Cr labeled target K562 cells, Daudi cells, and monocytes. Before IL-2 administration, PBMC obtained from BL/LL patients and normal volunteers possessed similar levels of NK cell activity indicating that the NK cell activity of the BL/LL patients was intact. LAK cell activity was induced with IL-2 in vitro in both BL/LL patients and in normal volunteers. The level of LAK cell activity in BL/LL patients was, however, suboptimal. A single intradermal dose of 25 micrograms IL-2 had no effect on the phenotype of circulating mononuclear cells in either patients or normal volunteers. However, 6-12 days after IL-2 injection and subsequent restimulation of the PBMC with IL-2 in vitro, cytolytic activity of LAK cells obtained from the BL/LL patients was enhanced while cells from normal volunteers expressed the same high levels of activity as observed before IL-2 injection.     

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.     

Human lymphokine-activated killer (LAK) cells: III. Effect ofl-phenylalanine methyl ester on LAK cell activation from human peripheral blood mononuclear cells: Possible protease involvement of monocytes,natural killer cells and LAK cells

Summary We have shown that depletion of monocytes from human peripheral blood mononuclear cells (PBMC) byl-phenylalanine methyl ester (PheOMe) enhanced lymphokine-activated killer cell (LAK) generation by recombinant interleukin-2 (rIL-2) at high cell density. In this study, we have investigated the mechanism of action of PheOMe on LAK activation by using trypsin, chymotrypsin, tosylphenylalaninechloromethanol (TPCK, a chymotrypsin inhibitor), tosyl-l-lysinechloromethane (TLCK, a trypsin inhibitor), phenylalaninol (PheOH), and benzamidine. PBMC were treated with 1–5 mM PheOMe for 40 min at room temperature in combination with the various agents, washed and assessed for their effects on natural killer (NK) activity against K562 cells and monocyte depletion. The treated cells were then cultured with or without rIL-2 for 3 days. LAK cytotoxicity was assayed against⁵¹Cr-labeled K562 and Raji tumor target cells. TPCK at 10 µg/ml partially inhibited depletion of monocytes by PheOMe. TLCK did not prevent depletion of monocytes nor inhibition of NK activity induced by PheOMe. TPCK and TLCK inhibited NK activity by themselves. TPCK but not TLCK inhibited rIL-2 induction of LAK cells. On the other hand, PheOH and benzamidine (analogs of PheOMe) lacked any effect on monocyte depletion but abrogated the inhibitory effect of PheOMe on NK activity. They had no effect on rIL-2 activation of LAK activity enhanced by PheOMe. Trypsin potentiated the inhibitory effect of PheOMe on NK activity and monocyte depletion. Trypsin partially inhibited IL-2 activation of LAK activity enhanced by PheOMe. Chymotrypsin had little effect on NK activity but prevented the inhibitory effect of PheOMe on NK activity. It had little effect on monocyte depletion induced by PheOMe. PheOMe was hydrolysed by monocytes and chymotrypsin to Phe and methanol as determined by HPLC. TPCK inhibited hydrolysis of PheOMe by monocytes. Our data suggest that the effects of PheOMe on monocytes, NK cells and LAK activation involve protease activities of monocytes.     

Lysis of fresh murine mammary tumor cells by syngeneic natural killer cells and lymphokine-activated killer cells

Summary We have compared the ability of natural killer (NK) cells from two substrains of C3H mice that differ with respect to their susceptibility to the development of mammary adenocarcinomas to lyse fresh syngeneic mammary tumor cells. Single cell suspensions of mammary tumors from retired breeder females were used as targets in 22-h ⁵¹Cr-release cytotoxicity assays with syngeneic NK cells. Tumor cell suspensions were prepared by enzymatic digestion of finely minced tissue followed by centrifugation through a discontinuous Percoll gradient. Effector cells were prepared by passing spleen cells over nylon wool followed by centrifugation through Percoll fraction 7. Syngeneic NK cells had significant levels of lysis against 5/8 tumors studied. NK cells from low risk animals (C3Heb/FeJ) consistently demonstrated greater cytotoxicity against tumor cell preparations than did effectors from the high tumor substrain (C3H/OuJ). Study of cytocentrifuge preparations stained with Wright-Giemsa revealed that the two substrains were identical with respect to the number of azurophilic granules present in the cytoplasm of their NK cells. We have also shown that lymphokine-activated killer (LAK) cells can be generated from splenocytes in C3H mice. While LAK cells from both substrains were capable of lysing fresh syngeneic mammary tumor cells in vitro, LAK cells from the animals at high risk for the formation of mammary adenocarcinomas had greater cytotoxicity against tumor cell suspensions than LAK cells from the low tumor substrain.     

Induction of human lymphokine-activated killer cells by IFN-alpha and IFN-gamma

By traditional definitions, NK cells can be activated by cytokines to exhibit two functionally distinct levels of cytotoxicity. Whereas IL-2-mediated activation of NK cells leads to the development of lymphokine-activated killer (LAK) cytotoxicity, characterized by the acquisition of cytolytic activity against NK-resistant targets, IFN-treated NK cells become activated without the acquisition of novel cytolytic specificities. In this study we show that NK cells activated by 18 to 24 h of stimulation with either IFN-alpha or IFN-gamma do acquire LAK cytolytic activity, demonstrated by the ability of IFN-treated PBMC to lyse NK-resistant COLO 205 cells as well as fresh tumor targets. The level of IFN-alpha-induced LAK activity was significantly greater than that induced by IFN-gamma, although IL-2-induced LAK activity was considerably greater than IFN-alpha-induced LAK cytotoxicity. Maximal IFN-induced LAK cytotoxicity occurred after 24 h of culture, and occurred with the use of IFN-alpha at 500 U/ml and IFN-gamma at 1000 U/ml. Whereas neutralizing antibody experiments demonstrated that IFN-alpha-induced LAK activation did not involve the participation of endogenously produced IL-2, the partial inhibition (63%) of IFN-gamma-induced LAK cytotoxicity by anti-IL-2 and of IL-2-induced LAK by anti-IFN-gamma (33.3%) indicates that the induction of LAK cytotoxicity by either of these individual cytokines involves the endogenous production and participation of the other cytokine. Similar to IL-2-induced LAK cells, phenotypic analysis revealed that IFN-alpha/gamma LAK cells were Leu-19+, although the Leu 19"dim"+ subset exhibited greater IFN-induced LAK activity than the Leu-19"bright"+ subset. The results of this study clearly demonstrate that IFN-alpha and IFN-gamma induce classic LAK activity and IFN-gamma plays a participatory role in the optimal induction of LAK cells by IL-2.     

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.     

Mycophenolate mofetil does not suppress the graft-versus-leukemia effect or the activity of lymphokine-activated killer (LAK) cells in a murine model

Background: Graft-versus-leukemia (GVL) effect is an essential component in the course of allogeneic stem cell transplantation (SCT). However, both prevention and treatment of established graft-versus-host disease (GVHD), including with drugs such as cyclosporine, can suppress GVL effects. Mycophenolate mofetil (MMF) is becoming a standard of care in SCT recipients for better prevention of GVHD as well as for promoting stem cell engraftment. Aims: To evaluate the effect of MMF, an immunosuppressive drug increasingly used for prevention of GVHD, on disease recurrence following SCT in a preclinical animal model. Since GVL effects may be also induced by alloreactive natural killer (NK) cells, the goal was to investigate the effects of MMF on the activity of lymphokine-activated killer (LAK) cells. Methods: MMF was administered by daily intraperitoneal injection starting at day 1 post-SCT. Cytotoxic LAK activity was measured by 5-h ³⁵S-release assay, and GVL was tested by the appearance of BCL1 leukemia in a semi-mismatched (C57BL/6 donors to [BALB/c × C57BL/6] F₁ recipients) murine model. Results: A dosage regimen of 28–200 mg/kg per day MMF had no negative effect on either cytotoxic LAK activity or GVL (as measured by finding of leukemic cells in recipient spleen by PCR or the appearance of clinical leukemia with adoptive transfer). Conclusions: These results suggest that MMF does not impair GVL effects or reduce LAK cell activity in mice.     

Identification and characterization of a cell-surface molecule that is selectively induced on rat lymphokine-activated killer cells

We have identified a 40- to 45-kDa cell-surface molecule designated gp42, that is expressed in high levels by rat lymphokine-activated killer (LAK) cells of NK cell origin. gp42 cannot be detected on the precursors of LAK cells and is not present on resting or activated T cells. Rather, expression of gp42 is selectively induced on NK cells by the high concentrations of rIL-2 that are required for the induction of LAK activity. Although the function of gp42 is not known, the selective nature of its expression suggests a role for this molecule in regulating responses that are unique to IL-2-activated NK cells.     

Accessory cells, dendritic cells, or monocytes, are required for the lymphokine-activated killer cell induction from resting T cell but not from natural killer cell precursors

In this study we have investigated the role of accessory cells in the development of lymphokine-activated killer cells (LAK) from highly purified human NK and small resting T cell progenitors. As accessory cells we used autologous, as well as allogeneic, monocytes, and dendritic cell enriched cells. Both NK and T cells were able to generate LAK activity, but their activation requirements were different. NK cells were activated merely by IL-2, and accessory cells did not enhance their lytic activity in the presence or absence of IL-2. Conversely, T cells were practically unresponsive to even high concentrations of IL-2 having a strict requirement for accessory cells for the development of lytic activity and proliferation. Accessory cells differed in their ability to activate T cells presumably depending on their ability to induce IL-2 synthesis, allogeneic dendritic cells being the most effective accessory cells and IL-2 synthesis stimulators. Allogeneic accessory cells could induce lytic activity in T cells even in the absence of exogenous IL-2. Thus, accessory cells play a central role in expanding the LAK effector cell population.     

IL-7 induces human lymphokine-activated killer cell activity and is regulated by IL-4.

Induction of lymphokine-activated killer (LAK) activity by IL-2 has been described and characterized as broadly cytolytic activity against both fresh and cultured tumors. rIL-7 in the absence of IL-2 also induces LAK activity in human cells. This activity is unique for IL-7, because it is not shared by other cytokines including IL-1, IL-4, IL-6, and TNF-alpha. IL-7 also induces either de novo or increased expression of the surface markers CD25 (Tac, IL-2R alpha-chain), CD54 (ICAM-1), Mic beta 1 (IL-2R beta-chain) and CD69 (early T cell activation Ag). IL-7-induced LAK activity is independent of IL-2 secretion, because it is not abrogated by IL-2 antisera. The LAK precursor responding to IL-7 stimulation is enriched in the null cell fraction as has been demonstrated for IL-2-induced LAK cells. TGF-beta and IL-4 interfere with generation of LAK activity by IL-7. Anti-IL-4 antiserum enhances IL-7-induced LAK activity and augments induction of surface marker expression by IL-7. This may be indirect evidence that IL-7 stimulation leads to induction of IL-4 activity. Our results describe the activation of mature lymphoid cells by IL-7. This and the previously described role of IL-7 in lymphohemopoiesis makes it a cytokine of potential therapeutic value for treatment of immunodeficiency states and possibly the immunotherapy of cancer.