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

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

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

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

Inverse relationship in H-2-associated lysis between NK cells and rIL-2-activated killer cells: evidence from in vitro killing and metastatic experiments

We investigated the manner in which rIL-2 induced effectors in vitro (LAK cells), which, like NK cells, lyse targets nonspecifically and discriminate nonself, and how H-2 as the self-marker affects the LAK cell killing mechanism. NK cells showed an appreciably higher killing activity to B16 melanoma H-2- cells than to H-2+ cells. In contrast, LAK cells lysed more efficiently to H-2+ cells. The in vivo experiments showed that the NK cells prevented pulmonary metastasis of B16 H-2- cells in the normal syngeneic host, whereas the transferred LAK cells had a preferential inhibitory effect on the pulmonary metastasis of B16 H-2+ cells in the immunodeficient syngeneic hosts. Taken together, these results show that the H-2-encoded or H-2-associated molecules contribute to the triggering signal in the lysis by LAK cells, whereas the NK cells recognize the reduced self H-2 expression on the targets, thereby contributing to a trigger of the lysis.     

Augmentation by anti-T3 antibody of the lymphokine-activated killer cell-mediated cytotoxicity

This study showed that a mAb (145-2C11) against the T3 epsilon-chain of the TCR complex augmented the cytotoxic activity of the lymphokine-activated killer (LAK) effectors. The LAK cells were induced by culturing normal spleen cells with purified human rIL-2. Adding alpha T3 at the effector phase of the cytotoxic reactions augmented the LAK-mediated cytotoxicity. The alpha T3-augmented LAK killing was seen only with tumor targets, and there was no increase of killing against Con A-induced lymphoblasts. The augmentation effect was dose dependent on both the amounts of alpha T3 and the number of LAK cells added. A very low concentration of alpha T3 (1/10,000 dilution of culture supernatants) was sufficient to induce alpha T3-augmented LAK-mediated cytotoxicity. Human rIL-2 at 10 to 30 U/ml was sufficient to generate LAK cells for maximal alpha T3 augmentation, whereas 300 to 1000 U/ml of IL-2 were needed to generate maximal LAK activity when tested in the absence of alpha T3. LAK cells generated for longer periods of time showed a progressive increase of alpha T3-augmented cytotoxicity. For some targets, the alpha T3-augmented LAK killing was FcR dependent as evidenced by the ability of alpha FcR mAb 2.4G2 to inhibit, and for others it was not inhibited. The alpha T3-augmented killing did not correlate with the FcR expression on target cells as defined by 2.4G2. The LAK cells were both Lyt-2+ and Lyt-2-, but the LAK cells involved in alpha T3-augmented killing were exclusively Lyt-2+. Preincubation of LAK cells with alpha T3, but not preincubation of targets with alpha T3, resulted in augmented killing suggesting that the alpha T3 effect was unrelated to an antibody-dependent cell-mediated cytotoxicity. Our findings indicate that alpha T3 is a potent reagent to augment the cytotoxic reaction of LAK cells. These results suggested that a relationship might exist between the T3 complex and the cytotoxic activity of a subpopulation of Lyt-2+ LAK cells.     

IL-4 regulation of murine lymphokine-activated killer activity in vitro. Effects on the IL-2-induced expansion, cytotoxicity, and phenotype of lymphokine-activated killer effectors

The in vitro incubation of B6 splenocytes with purified, mouse rIL-4 for 4 to 5 days was sufficient to generate lymphokine-activated killer (LAK) activity. In addition, rIL-4 augmented LAK cytotoxic activity when combined with rIL-2, as measured in a 4 h 51Cr-release assay against fresh, syngeneic MCA-sarcoma (MCA-102 and MCA-105) cells. Interestingly, this augmentation was not observed against the cultured YAC-1 target. LAK generation and augmentation of cytotoxicity by rIL-4 was species-specific, because human rIL-4 (up to 20,000 U/ml) failed to elicit these effects in the mouse splenocyte cultures. When 5-day B6 LAK cells (splenocytes incubated in rIL-2 at 1000 U/ml for 5 days) were split and recultured in the combination of rIL-2 plus rIL-4 for 4 additional days at least a twofold greater expansion in cell number resulted compared to similar cells cultured in either rIL-2 or rIL-4 alone. Moreover, LAK cells expanded in rIL-2 plus rIL-4 exhibited substantial increases in in vitro cytolytic activity (on a per cell basis) against MCA-102 and MCA-105 sarcoma cells, but not against YAC-1 targets. FACS analysis or negative selection using Lyt-2 or NK-1.1 mAb plus C revealed no differences in effector phenotype(s) of LAK cells expanded in rIL-2 alone compared to rIL-2 plus rIL-4 to account for the differences observed in both expansion and cytolytic activity by rIL-4. The majority of cells was Thy-1+, Lyt-2+, T3+, and ASGM-1+. However, a marked increase in the granule-associated serine esterase, BLT-E, was found only in LAK cells expanded in the combination of both lymphokines. Collectively, these studies show that rIL-4 has potent regulatory activities on splenic LAK generation, expansion, and cytotoxic function in the mouse.     

Lymphocytes infiltrating human ovarian tumors. I. Role of Leu-19 (NKH1)-positive recombinant IL-2-activated cultures of lymphocytes infiltrating human ovarian tumors

Tumor-infiltrating lymphocytes (TIL) were obtained from human ovarian tumors, expanded in the presence of IL-2 in culture and studied for cytotoxicity against fresh autologous and allogeneic ovarian carcinoma (CA) targets. TIL from ovarian tumors grew well in long term cultures, achieving from 8- to 682-fold expansion. TIL cultured with IL-2 were cytotoxic against both autologous and allogeneic fresh ovarian CA targets, and no specificity for autologous tumor could be demonstrated in any of the cultures. In all fresh TIL preparations, CD3+ lymphocytes were the major cell type and contained a high proportion (up to 51%) of activated (IL-2R+) cells as determined by two-color flow cytometry. Sorting of bulk TIL cultures followed by cytotoxicity assays identified the Leu-19+ cells, both CD3+ and CD3-, as effectors of cytotoxicity against autologous and allogeneic tumor cell targets. Cold target inhibition assays showed that allogeneic targets (both ovarian CA and a sarcoma) competed effectively with autologous ovarian CA targets for Leu-19+ effectors in TIL cultures. mAb to Leu-19 or Leu-2a did not block lysis of autologous targets by sorted effectors. OKT3 antibody augmented lysis of autologous targets by CD3+Leu-19- effectors only. These results show that non-MHC-restricted Leu-19+ effectors in cultures of TIL with 1000 U/ml of rIL-2 mediate lysis of autologous and allogeneic tumor cells. The CD3+Leu-19- cells, the main population in these cultures, do not mediate tumor lysis. To determine the phenotype of antitumor effectors in IL-2 cultures of TIL, cell sorting followed by functional assays are necessary.     

Heterogeneous lymphokine-activated killer cell precursor populations

Summary We developed a monoclonal antibody (mAb) 211, which recognizes the precursors in peripheral blood of lymphokine-activated killer cells (LAK) induced by recombinant interleukin-2 (rIL-2). In conjunction with complement mAb 211 also eliminates natural killer cells (NK) and a majority of the cytotoxic T lymphocytes. B cells and monocytes do not express the 211 antigen. Since mAb 211 recognized such a large percentage of peripheral blood lymphocytes we examined which 211⁺ subpopulation was the predominant precursor of rIL-2-induced LAK cells using two-color fluoresence-activated cell sorting (fluorescein-conjugated 211 mAb plus phycoerythrin-CD11b). This method identified the 211⁺/ CD11b⁺ population as the predominant phenotype of the rIL-2-induced LAK precursor. In addition, we directly compared the phenotype of the LAK precursor induced by delectinated T-cell growth factor (TCGF) to that induced by rIL-2. The 211-depleted population, which was devoid of NK cells and LAK precursors (inducible by rIL-2), was capable of generating LAK activity when TCGF was used as the source of lymphokine. LAK cells induced by TCGF from the 211-depleted population lysed a fresh sarcoma and an NK-resistant cultured melanoma tumor target but not the Daudi cell line, which was lysed by rIL-2-induced LAK cells. Lymphoid subpopulations, depleted using NKH1a mAb, behaved similarly, generating high levels of lysis against the two solid tumor targets when cultured with TCGF but not with rIL-2. CD 3-depleted populations showed enrichment for LAK precursors using either rIL-2 or TCGF. These results indicate that while rIL-2-induced LAK precursors cannot be separated from cells with NK activity, TCGF-induced LAK cells can be generated from populations of peripheral blood mononuclear cells without NK activity.     

Effects of beta-2 microglobulin anti-sense oligonucleotides on sensitivity of HER2/neu oncogene-expressing and nonexpressing target cells to lymphocyte-mediated lysis.

The mechanism by which HER2/neu overexpressing tumor cells resist NK, LAK, and LDCC cytotoxic lymphocytes was investigated. Resistance was not explained by a delay in kinetics of lysis, concurrent resistance to TNF, or a diminished expression of the transferrin receptor. HLA-class I expression, however, was markedly elevated compared to HER2 nonexpressing targets suggesting a reason for resistance. To test the role of class I, we selectively decreased expression by incubation of targets with beta-2 microglobulin anti-sense oligonucleotides. Anti-sense-treated HER2+ targets, displaying levels of class I comparable to HER2- targets, were still markedly resistant to cytotoxic effectors. Down-regulation of class I expression in HER2- carcinoma cells also had no effect on sensitivity to cytotoxicity by anti-sense treatment of Raji and U937 targets resulted in enhanced sensitivity to NK and LAK effectors but not to T cells mediating LDCC. These data indicate resistance to cytotoxicity in HER2-expressing targets cannot be solely explained by heightened expression of class I. The data also support the concept that class I expression regulates sensitivity to NK and LAK cells (but not LDCC effectors) in selected targets.     

Phenotypic and functional heterogeneity of thymic and splenic lymphokine activated killer cells relative to ornithine sensitivity

We have previously reported the selective inhibition of cytotoxic T lymphocytes (CTL) by 10 mM ornithine (ORN) relative to natural killer (NK) cell-derived lymphokine activated killer cells (LAK). To determine if this were due to differences in the progenitor cells or the type of stimulus, we used cortisone-resistant thymocytes (CRT) as a source of mature T cells for induction of LAK and CTL, and compared the results with spleen. Thymic and splenic CTL precursors (CTLp) from C57B1/6 (B6) mice were CD8+, ASGM1-, ORN sensitive. Splenic LAK precursors (LAKp) were CD8-, ASGM1+, ORN resistant when assayed against both YAC-1 and P815 tumor targets. In contrast, CRT-derived LAKp were CD8-, ASGM1+, ORN resistant against YAC-1, whereas LAKp against P815 were CD8+, ASGM1+, ORN sensitive. ORN sensitivity was also observed among CTL and LAK in DBA/2 mice and was associated with CD8+ phenotype. Therefore, our initial observation of differential ORN sensitivity in CTL vs LAK was a function of the progenitor cells; furthermore, CD8+ cytolytic cells are ORN sensitive whether activated by antigen (CTL) or IL-2 (T-LAK).     

Sensitivity of ovarian tumor cells to effector cells generated by various biological response modifiers

The sensitivity of freshly derived human ovarian tumors (FOT) to various allogeneic cytotoxic effector cells stimulated by recombinant interleukin 2 (rIL-2), recombinant interferon alpha 2 (rIFN-alpha 2), OK-432, and concanavalin A was examined using the 51Cr release assay. Peripheral blood lymphocytes (PBL) of normal female donors were used as source of effector cells. Incubation of PBL with these biological response modifiers for 24 h generated effector cells with high natural killer activity, and only 20% (1/5) of the FOT examined were susceptible to lysis. By contrast, 83% (5/6) of the FOT were sensitive to lymphokine-activated killer (LAK) cells generated by rIL-2. OK-432 and concanavalin A activation of PBL also generated cytotoxic cells, though the cytotoxic activity against FOT was much less than that obtained by LAK cells. The addition of OK-432 to LAK culture medium containing rIL-2 generated effector cells with higher cytotoxicity against FOT than cultures with IL-2 alone. However, the addition of rIFN-alpha 2 in LAK culture medium resulted in the generation of effector cells with lower cytotoxicity. The addition of rIL-2, rIFN-alpha 2, or OK-432 to LAK cells during the in vitro cytotoxicity assay had no significant effect. When FOT target cells were pretreated with OK-432 they became more sensitive to LAK than nontreated tumor cells. However, pretreatment with rIL-2 or rIFN-alpha 2 did not influence cytolysis. These results suggest that the generation of LAK cells in vitro using rIL-2 plus OK-432 may be a more effective way to prepare these cells for adoptive immunotherapy in the treatment of ovarian cancer.     

Heterogeneity of the lymphokine-activated killer cell phenotype.

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

Generation of lymphokine-activated killer (LAK) cells from tumor-infiltrating lymphocytes

Culture of tumor-infiltrating lymphocytes (TIL) containing about 20% BMC2 tumor cells with recombinant human interleukin 2 (rIL-2) resulted in the diminish of tumor cells and the growth of lymphocytes. These IL-2-activated lymphocytes showed a strong cytotoxic activity against not only syngeneic tumor cells but also allogeneic tumor cells. Such broad-reactive killer cells, termed lymphokine-activated killer (LAK) cells, are also inducible from spleen cells by in vitro activation with IL-2. However, LAK cells generated from TIL (TIL-LAK) showed higher cytotoxic activity against BMC2 than LAK cells generated from spleen cells (S-LAK). Furthermore, it was demonstrated that TIL-LAK cells revealed marginal cytotoxic activity against normal Con A blasts and YAC-1 cells as opposed to S-LAK. Flow cytometric analysis of TIL-LAK indicated that TIL-LAK cells mainly consisted of Thy 1.2+, Ly 2+, asialo GM1+ cells. TIL-LAK cells displayed not only in vitro cytotoxicity but also in vivo anti-tumor activity. Furthermore, it was also confirmed that TIL-LAK cells could be induced in autochthonous mouse tumor systems and human gastric tumor systems.     

Effect of IL-2 in vitro on CTL generation in spleen cells of young and old mice: asialo GM1+ cells are required for the apparent restoration of the CTL response

The role of asialo GM1+ (ASGM1+) cells and exogenous IL-2 in the age-related decline in allospecific CTL activity was evaluated. Primary CTL were generated in mixed leukocyte culture (MLC) [BALB/cANN (H-2d) anti C57BL/6N (H-2b)] and tested for allospecific lytic activity against the EL-4 (H-2b) cell culture line, and for non-MHC-restricted activity against WEHI-3 (H-2d) and YAC-1 (H-2a). Cultures included responder cell populations which had been treated with antibody to ASGM1 plus complement or complement alone, and irradiated stimulator cells, in the presence or absence of rIL-2 or crude IL-2-containing supernatants. The amount of rIL-2 used to accommodate the age-related decline in IL-2 production was determined empirically to be 500 U by assessing IL-2 production in MLCs containing responder cells from young versus old animals. rIL-2 appeared to restore the allospecific CTL activity generated by spleen cells of old mice to the level of that of young. However, treatment with anti-ASGM1 antibody revealed that this restoration was due to an effect of the IL-2 on ASGM1+ cells. The allospecific target cells, EL-4, were not sensitive to lymphokine-activated killer (LAK) cells induced by IL-2 alone under the conditions used. It is suggested that the apparent restoration was due to increased LAK-like (or MHC-nonrestricted) activity mediated by an ASGM1+ cell in the CTL precursor population.     

Suppression of B-cell differentiation by natural killer (asialo GM1+) cells in mice

Mice were injected intravenously with rabbit antiserum to ganglio-n-tetraosylceramide (asialo GM1, ASGM1), a neutral glycosphingolipid present at high quantities on the surface of natural killer (NK) cells. Spleen cells prepared from the mice were then examined for NK activity against YAC-1 targets, for phagocytic cells and by flow cytometric analysis for Thy1, Lyt1, Lyt2, ASGM1 and surface Ig (SIg) phenotypes. Administration of anti-ASGM1 in mice resulted in a complete depletion of NK activity and ASGM+1 cells in the spleen, but no changes in the proportions of Thy1+ cells and their Lyt1+ and Lyt2+ subsets and phagocytic cells. Corresponding to this selective depletion of ASGM+1 cells and NK activity, the spleen cells showed an increased number of SIg+ B cells and augmented mitogenic responses to B-cell but not T-cell mitogens. These NK-depleted spleen cells also showed production of pokeweek mitogen (PWM)-driven plaque-forming cells (PFC) to much higher levels than those of control spleens. In the spleens of mice treated with varying concentrations of anti-ASGM+1, a good correlation was found between the decreased NK activity and the enhanced PFC response. To directly test the possible suppressor activity of NK cells on PWM-induced PFC response, NK (ASGM+1) cells were highly purified from the spleen by a combination of Percoll gradients and cytolysis of T cells by monoclonal antibodies followed by indirect panning. When added to NK-depleted spleen cells, they suppressed the augmented PFC response of NK-depleted spleen cells, depending on the number of cells added. These results suggest that NK (ASGM+1) cells in mice exhibit a suppressor property on B cells, which are undergoing spontaneous or mitogen-induced differentiation.     

Augmentation of killer activity of murine spleen cells against allogeneic and syngeneic tumor cells by inoculation of alloantigen in vivo

After C57BL/6 (B6) mice were inoculated with BALB/c spleen cells via tail vein, kinetics of cytotoxic activities in the B6 mice against sensitizing alloantigens (H-2d) and against syngeneic antigens were investigated using, as target cells, P815 mastocytoma cells (H-2d) and B16 melanoma cells (H-2b). Cytotoxic activity against P815 in the B6 spleen cells reached a peak 3 days after alloantigen inoculation, decreased drastically on day 5 and rose again thereafter. The profile of anti-B16 cytotoxic activity was similar to that of anti-P815 activity. The cytotoxic activity against P815 was inhibited partially by cold B16, but that against B16 was not inhibited by cold P815. Surface phenotype of cytotoxic cells against P815 was Lyt2+, Thy1+, Asialo GM1+ and that of cytotoxic cells against B16 was Lyt2-, Thy1+/-, and Asialo GM1+. The results indicate that inoculation of B6 mice with allogeneic BALB/c spleen cells induce two types of cytotoxic cells; one is similar to lymphokine-activated killer (LAK) cells and the other is activated natural killer cells.     

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.     

Resistance of lymphokine-activated T lymphocytes to cell-mediated cytotoxicity

We observed that lymphokine-activated T lymphocytes, obtained in short- and long-term cultures following stimulation with recombinant interleukin-2 (rIL-2), are resistant to cell-mediated cytotoxicity. In particular, lymphokine-activated killer (LAK) cells do not undergo self-lysis or lysis by alloreactive cytotoxic T lymphocytes (CTL), in line with recent reports concerning CTL clones. Similar findings were further confirmed in a lectin-dependent cell cytotoxicity assay. LAK cell lysis resistance was not due to an inability to recognize itself, since inactivated LAK cells used as cold competitors inhibited tumor cell lysis in a dose-dependent manner. In contrast, the addition on Day 0 of irradiated LAK cells or alloreactive CTL, as well as a CTL clone having LAK-like activity to rIL-2-stimulated cultures abrogated or strongly reduced LAK cell generation. Therefore, LAK cell precursors were most likely susceptible to the lytic activity of differentiated cytotoxic cells, as no inhibition was detected when cell to cell contact was prevented by using a diffusible chamber culture system. These findings, on the whole, suggest that the emergence of the lysis-resistant phenotype is most likely the result of a selective process occurring in vitro that leads to the elimination of lysis-susceptible lymphocytes present in culture.     

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.     

Resting human peripheral blood lymphocytes can be activated to cytolytic function by antibodies to CD3 in the absence of exogenous interleukin-2

We investigated the ability of anti-CD3 antibodies to activate resting human peripheral blood lymphocytes (PBL) to a cytolytic function. We found that two anti-CD3 antibodies, but not an anti-CD4, anti-CD8, or anti-CD2 antibody, could activate resting unseparated PBL to become killer cells in the absence of exogenous interleukin-2 (IL-2), although exogenous recombinant IL-2 (rIL-2) synergized with anti-CD3. We also found that these anti-CD3 antibodies were active in the absence of rIL-2 only when linked to a solid surface such as a Sepharose bead or a plastic tissue culture plate. Cytolytic activity was measured in several ways: (i) by the ability of activated PBL to lyse the NK-sensitive line K562, and (ii) by the ability of these cells to lyse a CD10+ (CALLA+), NK-resistant target in the presence of either concanavalin A (lectin-dependent lysis) or an anti-CD10-anti-CD3 heterodimer. At least two different types of cytolytic cells were activated by anti-CD3 antibodies, an NK-like cell, which was CD2+CD3-CD4-CD8-CD16+-NKH1a+, and a CTL-like cell, which was CD2+CD3+CD4-CD8+CD16-NKH1a-. The former cell lysed the K562 line and the latter cell lysed Namalwa in the presence of the anti-CD10-anti-CD3 heterodimer or concanavalin A. The NK-like cell was probably activated by endogenous IL-2 produced by the anti-CD3-activated CD3+ cells and both the NK and CTL-like cells required the presence of adherent cells for maximal activity. The dose response and the kinetics of anti-CD3 activation of PBL to cytolytic activity were also studied. The use of the anti-CD3-activated cytolytic cells as effectors in anti-CD3 heterodimer-mediated lysis of tumor cells may be a novel approach to the therapy of cancer, and a comparison with the well-studied rIL-2/lymphokine-activated killer (LAK) system is discussed.     

Factors determining the ability of cytokine-activated killer cells to lyse human ovarian carcinoma targets

Lysis of human ovarian carcinoma cells by natural killer (NK) cells, interferon-alpha activated NK cells (alpha-NK) and lymphokine-activated killers cells (LAK) was studied using both fresh tumor cells and a cell line (HEY) as targets. A clonogenic assay to measure cell kill was more sensitive than a 4-h 51Cr release assay. Both assays showed that single cells were more effectively lysed than were tumor clumps (spheroids). Freshly isolated tumor cells studied in the 51Cr release assay appeared equally susceptible to lysis by LAK cells whether in the form of clumps or single cells, but NK and alpha-NK effectors appeared much less effective in lysing susceptible target cells when they were in clumps. Tumor cells from some patients showed marked resistance to lysis by NK and alpha-NK cells in fractions enriched for clonogenic cells, even when tested in a single cell-suspension, whereas LAK cells were always cytolytic. These data suggest that intrinsic resistance of ovarian carcinoma to lysis by LAKs is unlikely to explain failure of LAK + IL-2 therapy to eradicate tumor in vivo.