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)     

Generation and characterization of purified adherent lymphokine-activated killer cells in mice

During the incubation of murine spleen, lymph node, or bone marrow cells with IL-2 (1000 U/ml) a small percentage of cells became adherent to the surface of plastic tissue culture flasks. After removal of the non-adherent lymphoid cells, plastic adherent lymphokine-activated killer (LAK) cells could be efficiently expanded in the presence of IL-2. Plastic adherent-derived A-LAK cells were characterized by high rates of proliferation and their cytotoxic activity was more than 10 fold higher than LAK cells generated in the bulk (unfractionated) spleen cell cultures. A-LAK cells could be continuously generated from the non-adherent cell population. Using multiple transfers (every 1 to 2 days) of non-adherent LAK cells into new flasks, new rounds of plastic adherent cells were generated with high expansion capability and high levels of cytotoxic activity. Morphologically, A-LAK cells were large granular lymphocyte and phenotypically expressed markers characteristic of NK cells (asialo GM1+, NK1.1+, Qa5+, Ly-6.2+, Thy-1.2+, but negative for Lyt-2.2 and L3T4). A-LAK cells generated from mice of different strains expressing low and high levels of NK cell activity were equally highly cytotoxic. However, A-LAK cells obtained from nude or beige mice had relatively lower levels of cytotoxicity. Stimulation of NK cell activity by poly I:C or inhibition by in vivo or in vitro treatment with anti-asialo GM1 serum did not affect the generation of A-LAK cells. A-LAK cells derived from spleen or bone marrow of C57BL/6 or nude mice treated with anti-asialo GM1 serum were found to be asialo GM1+ suggesting that A-LAK cell could be generated from the asialo GM1- precursor cells. Expansion of plastic adherent A-LAK cells in the presence of IL-2 could provide large numbers of highly purified cytotoxic A-LAK cells suitable for cancer immunotherapy.     

Effector and precursor phenotypes of lymphokine-activated killer cells in mice with severe combined immunodeficiency (scid) and athymic (nude) mice

The lineage of lymphokine-activated killer (LAK) cells is poorly understood. To examine the relationship between LAK and natural killer (NK) cells we utilized two congenitally immunodeficient mice, namely severe combined immunodeficient (scid) and athymic (nude) mice that lack T cells but have normal NK cells. LAK activity was evaluated by the ability to lyze NK-resistant P815 cells. When cultured with human recombinant interleukin 2, splenocytes of scid and nude mice could generate LAK activity at levels comparable to or more than those of normal C.B-17 mice. LAK effector cells in these immunodeficient mice as well as normal mice had the phenotype resembling that of NK cells with asialo-GM1 (aGM1) expression. In vivo treatment with anti-aGM1 antiserum completely abolished the induction of LAK activity from splenocytes of normal mice. In contrast, LAK activity in splenocytes of scid and nude mice was still demonstrable even after this treatment, indicating that most LAK precursors in both mice were cells without aGM1 antigen. The aGM1- progenitors for LAK activity, probably in common with NK progenitors, appeared to be more expanded in scid and nude mice than in normal mice. The use of such congenitally immunodeficient mice should be helpful in studying the differentiation step of LAK as well as NK cells from their precursors.     

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.     

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

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

Induction of murine lymphokine-activated killer cells by recombinant IL-7

The data demonstrate that IL-7, a cytokine that was originally identified, purified, and cloned based upon its ability to support the growth of pre-B cells in vitro, also induces proliferation and promotes the generation of lymphokine-activated killer (LAK) cell activity in populations of resting peripheral lymphoid cells. Although the kinetics of LAK induction by IL-7 (which peaked at days 6 to 8 of culture) was slower than that detected in cultures containing IL-2 (which peaked at day 4), IL-7 was significantly more effective at maintaining cytotoxic activity over longer periods of time, and greater viable cell recoveries, than was IL-2. A wide range of murine tumor target cells were found to be lysed in an MHC-unrestricted fashion by IL-7 induced LAK, but syngeneic Con A-induced lymphoblasts were not; nor were target cells from the human tumors K562 or Daudi lysed by IL-7 LAK. IL-7 LAK were induced in populations of lymphoid cells obtained from secondary lymphoid tissues (peripheral lymph nodes and spleen), but not from primary lymphoid tissues (thymus and bone marrow). LAK induced by IL-7 from unfractionated populations of lymphoid cells were completely eliminated by treatment with anti-CD8 or anti-Thy-1+C, and unaffected by treatment with anti-CD4, anti-asialo GM1 or anti-NK1.1+C. Interestingly, although no detectable CD4+ effector cells could be detected in populations of LAK generated from unfractionated populations of lymphoid cells stimulated by IL-7, they were found to be generated from populations of lymphoid cells from which CD8+ cells had been eliminated before being cultured in medium containing IL-7. These data suggest that CD4+ T cells do not normally give rise to IL-7-induced LAK unless they are first separated from CD8+ T cells. LAK induced by IL-7 appear to be distinct from LAK activity induced by IL-2 in that there is no detectable involvement of NK-like effector cells at either the precursor or effector cell stages.     

Origin and differentiation of natural killer cells. I. Characteristics of a transplantable NK cell precursor

To study the origin and differentiation of natural killer (NK) cells, we developed an assay for the transplantable precursor of NK(YAC-1) cells present in the bone marrow. Mice were depleted of endogenous NK(YAC-1) cells by injection of anti-asialo GM1 antibody, followed by lethal whole body irradiation. Normal syngeneic bone marrow cells were transplanted into such pretreated mice. Regeneration of NK(YAC-1) activity in the recipient mice was monitored by two different assays: the ability of spleen cells to lyse YAC-1 cells in vitro and the ability to clear i.v. injected, 125IUdR-labeled YAC-1 cells from the lungs. With both assays, a dose-response relationship between the number of bone marrow cells injected and the degree of NK(YAC-1) activity generated could be demonstrated. However, the lung clearance assay appeared superior because the NK regeneration could be detected earlier and with lower numbers of injected marrow cells. With this assay, several characteristics of the NK precursors and their differentiation could be defined. 1) The generation of mature, lytic NK cells from their transplantable precursor requires an intact "marrow microenvironment" in the recipient mice, because differentiation failed to occur in mice rendered osteopetrotic by estradiol treatment. 2) The NK(YAC-1) precursors lack the surface antigens (NK-2.1, asialo GM1, Qa-5, Thy-1) that are characteristically seen on mature NK cells. 3) The NK-precursors could be eliminated from the bone marrow with anti-Qa-2 or anti-H-2 antisera + complement, indicating that these two antigens are expressed on the precursors. The relationship between NK(YAC-1) precursors and multipotent myeloid stem cells (CFU-S) was investigated by utilizing W/Wv and Sl/Sld mutant mice. Bone marrow cells of W/Wv anemic mice, although markedly deficient in CFU-S, have a normal frequency of NK(YAC-1) precursors. Sl/Sld mice that lack a suitable microenvironment for the development of CFU-S allowed normal differentiation of NK(YAC-1) precursors when transplanted with normal bone marrow cells. Together, these data suggest that multipotent myeloid progenitor cells, as defined by the CFU-S assay, and the NK(YAC-1) precursors are not closely related.     

Differential sensitivity of cytotoxic T lymphocytes and lymphokine-activated killer cells to inhibition by L-ornithine

The selective inhibition of murine cytotoxic T lymphocyte (CTL) differentiation in C57B1/6 (B6) anti-DBA/2 mixed leukocyte cultures (MLC) by the amino acid L-ornithine (Orn) could not be reversed by addition of up to 1000 U/ml IL-2. Analysis of the effects of Orn on induction of lymphokine-activated killer (LAK cells), using dosages of IL-2 from 10-1000 U/ml and measuring cytolytic activity against two tumor targets (P815 and YAC-1) over the course of 5 days, indicated that LAK cells were not suppressed by Orn. LAK precursors and effector cells were CD8- and ASGM1+, indicating that they were derived from natural killer (NK) cells. We also found that the growth and maintenance of cloned CTL lines were not sensitive to inhibition by Orn; nor was their acquisition of nonspecific cytolytic activity in the presence of high lymphokine concentrations. Thus, induction of naive CTL shows differential susceptibility to Orn inhibition relative to LAK and LAK-like activities by NK and cloned CTL lines in response to IL-2.     

Comparison of murine lymphokine-activated killer cells, natural killer cells, and cytotoxic T lymphocytes

Precursors and effectors of murine lymphokine-activated killer cells, natural killer cells, and cytotoxic T lymphocytes are compared. Natural killer cells are resistant to gamma-irradiation (1000 R) whereas precursors of lymphokine-activated killer cells and cytotoxic T lymphocytes are sensitive. Lower doses of gamma-irradiation (500 R) remove precursors for cytotoxic T lymphocytes but not lymphokine-activated killer cells. In addition, lymphokine-activated killer cells are regenerated before classical CTL after sublethal doses of gamma-irradiation. Natural killer cells are resistant to anti-Thy 1 and C' and anti-thymocyte serum, but sensitive to anti-asialo GM1 and complement. Precursors of cytotoxic T lymphocytes are sensitive to anti-Thy 1 and complement and anti-thymocyte serum, but are resistant to anti-asialo GM1 and complement. Precursors of lymphokine-activated killer cells are partially sensitive to anti-Thy 1 and complement and anti-thymocyte serum, but are resistant to anti-asialo GM1 and complement. Effector cells of cytotoxic T lymphocytes are sensitive to anti-Thy 1 and complement and resistant to anti-asialo GM1 and complement. Lymphokine-activated killer cell effectors are sensitive to anti-asialo GM1 and complement at 24 hr after activation. These effectors are more closely aligned with classical natural killer effectors. Lymphokine-activated killer effectors, 7 days after activation, are resistant to anti-asialo GM1 and complement and sensitive to anti-Thy 1 and complement. Relationships and differences among these cytotoxic subsets are discussed.     

Lymphokine-activated killer cells in rats. IV. Developmental relationships among large agranular lymphocytes, large granular lymphocytes, and lymphokine-activated killer cells

The developmental relationships among large agranular lymphocytes (LAL) large granular lymphocytes (LGL) and the activation of these cells into lymphokine-activated killer (LAK) cells by rIL-2 was investigated. Highly enriched populations of LAL were isolated from Fischer 344 spleen cells by a combination of nylon-wool filtration (to remove B cells and macrophages), treatment with a pan T cell antibody plus complement (to remove T cells) and incubation in L-leucine methyl ester (to remove LGL). The resultant cells were highly enriched in morphologically identifiable LAL which expressed asialo GM1 and partially expressed the OX8 surface marker. The enriched LAL did not contain detectable NK cytotoxic activity, did not express pan T cell (OX19), Ia, Ig, or laminin surface markers and contained less than 0.2% LGL. Incubation of LAL in a low dose of rIL-2 (100 U/ml) induced the generation of LGL having NK activity within 24 h of culture. Longer culture periods (48 h) resulted in a continued increase in the percentage of LGL and higher levels of NK activity. However, with this low dose of rIL-2, little or no LAK activity (i.e., reactivity against NK-resistant target cells) was generated. With a high dose of rIL-2 (500 U/ml), LAL responded by first generating LGL with NK activity (within 24 h), with subsequent generation of LAK activity by 48 h. Evidence that the development of granular lymphocytes from LAL was responsible first for NK activity and then LAK activity was demonstrated by depletion of the generated granular NK or LAK effector cells by second treatments with L-leucine methyl ester. Concomitant with the induction of LGL with NK or LAK activity, rIL-2 also caused LGL to proliferate and expand four- to five-fold in 48 h. This occurred in the presence of high or low dose rIL-2. These results indicate that LAL are the precursors of LGL/NK cells, that LAL, LGL/NK cells and LAK cells appear to represent sequential developmental or activation stages and that LAL may comprise major source of LAK progenitors in lymphoid populations having few LGL or mature active NK cells.     

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.     

Precursor phenotype of lymphokine-activated killer cells in the mouse

Lymphokine-activated killer (LAK) activity has been proposed to functionally differ from natural killer (NK) activity largely on the basis of a broader target cell spectrum and different kinetics of response to interleukin 2 (IL 2). Similarly, it has been proposed that the precursor cells for LAK activity are phenotypically distinct from NK cells. In most precursor studies, phenotype comparisons have been made between fresh NK cells and LAK cells which have been generated by 3 to 5 days of culture in IL 2. In the present study, we utilized positive selection with monoclonal antibodies to characterize the surface phenotype of precursor cells which give rise to rIL 2-augmented NK activity within 24 hr and to classically generated LAK activity which appears after 3 to 5 days of culture in rIL 2. The results demonstrated that highly purified (93 to 95%) Lyt-2+ or L3T4+ T lymphocytes were unable to generate appreciable amounts of either augmented NK activity or LAK activity when cultured with rIL 2, whereas the highly purified (98%) Lyt-2-, L3T4-, asialo GM1+ lymphocyte subset gave rise to both augmented NK and LAK activities. These findings demonstrate that both augmented NK and LAK activities can arise from precursors expressing the same phenotype. Overall, the results suggest that NK cells in mouse spleen constitute a major precursor component for the generation of LAK activity from that organ.     

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.     

Studies on the relationship of human natural killer and lymphokine-activated killer cells with lysosomal staining and analysis of surface marker phenotypes

We have previously demonstrated that natural killer (NK) cells are lysosome-rich and stain more intensely with lysosomotropic agents such as neutral red and quinacrine (Qu) than do non-NK cells. In this study we combined the quantitation of Qu staining with surface marker staining to define subpopulations of NK cells. While all NK activity was contained within the Qu+ population, most but not all NK cells expressed the surface marker CD16. A subpopulation of NK cells was found to be Qu+CD16- composed of medium- to large-sized cells with a granular appearance on Giemsa staining. Culture with interleukin-2 (IL-2) induced enhanced cytotoxicity in peripheral blood lymphocytes (PBL) against NK-sensitive and NK-resistant tumor cells. Like NK cells, these lymphokine-activated killer (LAK) cells were predominantly Qu+CD16+. However, some LAK cells were Qu+CD16-. The Qu+CD16+ cells were typical large granular lymphocytes (LGL). The Qu+CD16- cells were also large lymphocytes, more than 50% of which were proliferating. However, the granulation in some Qu+CD16- cells, as detected by Giemsa staining, was more prominent and numerous than others in the same population. No LAK activity was ever detected in Qu- cells, which were uniformly small lymphocytes. Quantitation of Qu staining in effector cells was therefore demonstrated to have a good correlation with NK and LAK functions, and with surface markers can help to characterize both types of cells. Moreover, these results indicate that both NK and LAK populations include a small subset of CD16- cells in each.     

Lymphokine-activated killer cells are generated before classical cytotoxic T lymphocytes after bone marrow transplantation in mice

Lymphokine-activated killer (LAK) cells are demonstrable within 2 wk after syngeneic or allogeneic (H-2-compatible) bone marrow transplantation in mice. Classical cytotoxic T lymphocytes (CTL) are not active until at least 4 wk after transplant. Both LAK cells and CTL bear the Thy-1 marker and do not possess the murine natural killer cell marker asialo GM.     

Murine natural killer cells limit coxsackievirus B3 replication

Previous indirect evidence suggested that natural killer (NK) cells play a role in coxsackie virus B3 serotype 3, myocarditic variant (CVB3m)-induced myocarditis by limiting virus replication. In this study, we present direct evidence that NK cells can limit CVB3m replication both in vitro and in vivo. Virus titers are lowered in primary murine neonatal skin fibroblast (MNSF) cultures incubated with activated splenic large granular lymphocytes (LGL) taken from mice 3 days postinoculation of CVB3m, a time of maximal NK cell activity. The antiviral effect of this cell population is diminished by complement-mediated lysis with the use of anti-asialo GM1 antiserum but not with anti-Lyt-2 monoclonal antibody. Neither interferon nor anti-CVB3m-neutralizing antibody was detected in these cultures. Although activated LGL initiate lysis within CVB3m-infected MNSF in vitro within 3 hr of addition, they do not lyse uninfected MNSF cultures. CVB3m replication is required for expression of surface changes on MNSF that result in lysis by NK cells because cell cultures treated with compounds that prevent CVB3m replication are not killed by LGL. LGL also do not lyse MNSF cultures inoculated with UV-inactivated virus. Mice inoculated with activated LGL and subsequently challenged with CVB3m had reduced titers of virus in heart tissues in comparison to titers of CVB3m in heart tissues of mice not given LGL. The antiviral activity of the LGL preparation was abolished by prior treatment with anti-asialo GM1 antiserum plus complement but not by prior treatment with anti-Lyt-2 monoclonal antibody and complement. These data suggest that NK cells can specifically limit a nonenveloped virus infection by killing virus-infected cells.     

Differential expression of lymphokine-activated killer cells and natural killer cells in adoptive transfer experiments utilizing fractionated bone marrow

Precursors of murine natural killer (NK) cells and lymphokine-activated killer (LAK) cells can be distinguished by utilizing an adoptive transfer system in which donor bone marrow is fractionated on Percoll discontinuous gradients. Although precursors of LAK cells are present in all fractions, one fraction (greater than 65% Percoll) contains LAK precursors and is depleted of NK precursors. Both in vitro NK activity and in vivo hybrid resistance is abrogated in recipients of bone marrow from the greater than 65% Percoll fraction, whereas LAK activity can be readily demonstrated.     

Phenotypic characterization of murine lymphokine-activated killer cells

Short-term culture of murine lymphocytes in interleukin 2 (IL-2), in the absence of any priming antigen, has been shown to result in the differentiation of an activated killer cell population capable of potent cytotoxic activity against tumor cells. The progenitor and lineage of these lymphokine activated killer cells (LAK) remains controversial. The present study was initiated to combine both complement-mediated depletion and flow cytometry to examine the cell surface membrane markers on murine LAK precursors and effectors. Selective depletion of antigen-positive cells from the precursor or effector population followed by functional assays demonstrates that the LAK effector is derived from a non-thymus-processed cell (Thy-1 negative). Paradoxically, the effector acquires Thy-1 expression in parallel to the IL-2 induced acquisition of killer cell effector function. These studies clearly show that both precursor and effector cells express the "NK-associated" Qa 5 and asialo GM-1 surface antigens. Mature effectors, but not the precursors, exhibit both Lyt-2 and the "NK-associated" NK-1.1 cell surface marker. Our flow cytometric analyses of murine spleen cells activated in rIL-2 have identified a distinct large, granular cell population which contains the LAK effector. This population, which can be readily discerned using light scattering properties with a flow cytometer, demonstrates both quantitative and qualitative changes in cell surface antigen expression.     

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 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.