Natural killer and lymphokine-activated killer cell activities from human marrow precursors. II. The effects of IL-3 and IL-4

Both IL-3 and IL-4 have multi-CSF activity on early marrow progenitors. We have examined the effect of IL-3 and IL-4 on the differentiation of NK cells from their marrow-derived precursors and have further examined the interactions of these cytokines with IL-2 and IL-1. We tested marrow which had been depleted of mature cells and of E rosette-positive cells (including NK cells) by treatment with soybean lectin and SRBC (SBA-E-BM). The cytolytic activities of the SBA-E-BM samples were tested in 51Cr-release assays after 7 days of liquid culture. K562 targets were used as a measure of NK activity and NK-resistant Daudi targets were used to measure lymphokine-activated killer (LAK) cell activity. Neither NK nor LAK activity was detectable in marrow cultured in medium without cytokines, or in medium containing IL-3, or IL-4 alone. Both of these cytokines were shown to be inhibitory to the IL-2-induced generation of NK and LAK activity from SBA-E-BM at concentrations as low as 1 U/ml. The inhibitory activity of both IL-3 and IL-4 was found to occur early in the marrow cultures, with little or no inhibitory effects seen if added 48 h after IL-2. IL-3 appeared to be specifically inhibitory to NK cell precursors since addition of IL-3 to cultures of PBMC did not inhibit IL-2-induced lytic activities. In contrast, IL-4 was equally inhibitory to the activation of marrow and peripheral blood NK cells by IL-2. Mixing experiments demonstrated that the reduced lytic activity in IL-3 or IL-4 containing marrow cultures were not due to suppression of the NK effectors, nor could marrow cultured in IL-3 or IL-4 serve as targets for IL-2-activated NK cells. Phenotype analysis of the lymphoid cells in marrow cultures containing IL-2 combined with IL-3 or IL-4 revealed fewer cells expressing Leu-11 (CD16), or Leu-19 (CD56) and fewer CD16, CD56 coexpressing cells compared with marrow cultured in medium containing IL-2 alone. The inhibitory activity of IL-4, but not IL-3, could be partially reversed if IL-1 was added to the cultures, suggesting that IL-1 and IL-4 have opposing activities on NK cells responsiveness to IL-2. These interactions between cytokines might be important in the regulation of NK cell differentiation and on the functional activity of mature NK cells.     

Generation of lymphokine-activated killer activity in T cells. Possible regulatory circuits.

CD4+ and CD8+ T cells do not develop significant lymphokine-activated killer (LAK) activity when PBL are cultured with IL-2 or even when they are activated with a T cell stimulus such as OKT3 mAb. The possibility that a T cell regulatory mechanism prevents the development of LAK activity by CD4+ or CD8+ cells in OKT3 mAb and IL-2 cultures was tested by depleting CD8+ or CD4+ cells from PBL before stimulation with OKT3 and IL-2. Under these conditions, the remaining CD4+ and CD8+ cells were able to generate non-MHC-restricted lysis of NK-resistant tumor targets. Our data suggested that a regulatory signal was present in the culture to prevent the development of lytic function by T cells. T cells removed from the PBL cultures were, upon culture with IL-2, able to generate high LAK activity, suggesting that inhibition of the CD4+ or CD8+ T cell-mediated LAK activity was an active ongoing process, which blocked the lysis at the level of the activated cell and not the precursor cell. Mixing experiments demonstrated that the CD4+ or the CD8+ cells isolated from the PBL cultures were able to inhibit the development of lytic function in the CD4-depleted and CD8-depleted cultures. Transforming growth factor-beta (TGF-beta) has been shown to block LAK activity of NK cells in IL-2-stimulated cultures. When TGF-beta was added to CD4(+)- or CD8(+)-depleted cultures, it also inhibited LAK activity of T cells in a dose-dependent fashion, without interfering with T cell growth. Lytic activity returned to activated levels when TGF-beta was removed from the culture medium, thereby demonstrating the reversibility of TGF-beta inhibition.     

Generation of MHC-nonrestricted and restricted oncolytic subsets from human bone marrow.

We analyzed the cytotoxicity and characterized the phenotype of oncolytic bone marrow (BM) lymphocyte subsets generated in vitro by interleukin-2 (IL-2) and stimulator cells (SC). Two irradiated B-lymphoblastoid cell lines (Daudi and EBV-transformed BSM) and fresh human acute myelogenous leukemia (AML) were used as SC. Stimulation with Daudi and IL-2 resulted in a substantial increase in cytotoxic activity (100- to 1000-fold) against a broad range of tumor targets, and total cellular expansion was higher compared to stimulation with IL-2 alone. The most prominent increase was observed in the CD16+ and CD56+/CD3- natural killer (NK) cell subset; however, a significant increase was also observed in CD56+/CD3+ T cells. Functional analysis of Daudi- and IL-2-generated subsets using fluorescence-activated cell sorting (FACS) revealed that most of the lytic activity was mediated by NK cells. Significant potentiation of oncolytic activity and cell growth was also seen in the cultures stimulated with BSM or fresh AML and IL-2. The highest oncolytic activity in the latter cultures was mediated primarily by CD8+, CD3+, and CD56- T cells, although NK cells also participated in cytotoxic activity. The T cell-mediated cytotoxicity was restricted by the major histocompatibility complex (MHC), since most cytotoxicity could be blocked by HLA I antibodies. Additionally, we observed that optimum stimulation of cytotoxicity required effector cell-stimulator cell contact. These data indicate that depending on the tumor used for stimulation, different lymphocyte subsets may be generated in IL-2 cultures. These different approaches may be useful in both specific and nonspecific immunotherapy.     

In vivo effects of recombinant IL-2. I. Isolation of circulating Leu-19+ lymphokine-activated killer effector cells from cancer patients receiving recombinant IL-2

This study was designed to isolate and phenotypically characterize lymphokine-activated killer (LAK) cells generated in vivo during administration of high dose rIL-2 to cancer patients. The development of circulating LAK effector cells in these patients was demonstrated by the ability of fresh PBL to exhibit lytic activity against the NK-resistant Daudi cell line and fresh tumor cells without prior in vitro culture with rIL-2. Kinetic studies demonstrated that circulating LAK effector cells are detectable 4 to 6 wk after the initiation of rIL-2 therapy. Cells isolated by FACS revealed that circulating LAK cells are Leu-19+, Leu-17+ but CD5-. We have previously reported that circulating Leu-19+ cells are heterogeneous with regard to the expression of CD16 and CD8. Since sorting of cells expressing Leu-19 and either low quantities of CD8 or CD16 resulted in cytolytic activity in both the positive and negative fractions, these latter two markers do not identify subpopulations of Leu-19+ cells with or without LAK cytolytic activity. Although all LAK cells generated in vivo were Leu-19+, we generated LAK cells from the Leu-19- subpopulation after in vitro culture with rIL-2, suggesting that at least some of in vitro generated LAK cells are derived from Leu-19- precursor cells. These LAK cells did not, however, express the Leu-19 surface marker. Based on the functional data reported in this paper, we conclude that circulating LAK effector cells are a phenotypically heterogeneous population that express surface Ag in association with NK cells and not T lymphocytes.     

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

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

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

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

Natural killer (NK) cell subsets in the mouse. NK-1.1+/LGL-1+ cells restricted to lysing NK targets, whereas NK-1.1+/LGL-1- cells generate lymphokine-activated killer cells

Our laboratory has recently identified a novel Ag, LGL-1, that is expressed on a major population of mouse NK cells. Two color immunofluorescence analysis has demonstrated that spleen cells consist of two major subsets of NK cells. We have identified an NK-1.1+/LGL-1+ subset that consists of 50% of the total NK cells and an NK-1.1+/LGL-1- subset comprising the remaining 50%. Because numerous reports have identified NK cells as the major cell type mediating lymphokine-activated killing (LAK), the NK-1.1+/LGL-1+ and NK-1.1+/LGL-1- subsets were examined for their contribution toward LAK generation, as defined by their ability to lyse P815 tumor targets. Antibody plus C depletion experiments with the use of anti-LGL-1 indicated that LGL-1+ cells were not found on LAK precursor or effector cells. Two-color cell sorting experiments were also performed to separate freshly isolated NK-1.1+/LGL-1+ spleen cells from the NK-1.1+/LGL-1- subset. It was found that the vast majority of LAK activity (greater than 95%) is derived from the NK-1.1+/LGL-1- cells. Cell sorting of LAK effectors also demonstrated that the NK-1.1+/LGL-1- cells mediated the vast majority of lysis against P815 targets. Similar results were obtained when NK cell subsets were analyzed for their contribution toward ADCC. These findings may prove important in understanding and further elucidating the contribution of NK cells to the LAK phenomenon. Our data also indicates that subsets of NK cells exist that may function differently in response to stimulation by various lymphokines and cytokines.     

IL-6 enhances the cytotoxic activity of thymocyte-derived CD56+ cells.

Thymocyte-derived lymphokine-activated killer (LAK) cells were used as a model for the study of the cytokine driven development of cytotoxicity. These cells are devoid of initial cytotoxic activity but upon culture in IL-2 they develop into cytotoxic effectors. The parameters of the response of thymocytes to IL-6 are similar to that of PBL in that IL-6, at concentrations as low as 1 mu/ml, increases cytotoxicity of thymocyte-LAK cells when generated in low doses (25-50 mu/ml) of IL-2. IL-6-enhanced thymocyte-LAK cytotoxicity is observed when tested against both NK-resistant and NK-sensitive tumor cell lines. IL-6 alone does not induce any cytotoxicity from thymocytes nor does IL-6 change the time course of thymocyte-LAK cell generation in IL-2 culture. IL-6 does not affect DNA synthesis, total cell number, proportion of CD56+ cells, or the expression of IL-2R (both P55 and P75 glycoproteins) in IL-2-cultured thymocytes. Instead, IL-6 used to treat mature thymocyte-LAK effector cells for as little as 1 hr prior to 51Cr-release assay increases LAK cytotoxicity. This enhancement is abrogated by pretreatment of effector cells with cycloheximide, suggesting that protein synthesis is required for IL-6 to enhance LAK cell activity. The precursor phenotypes of IL-6-responsive thymocyte-LAK cells are CD3-/CD5-. The effector phenotypes of IL-6-enhanced thymocyte-LAK cells are CD5-/CD56+. Thus, IL-6 depends on synthesis of rapid-turnover proteins to act on mature CD56+/CD5- LAK cells to increase their cytotoxic function.     

Interleukin-3 induces proliferation but not lymphokine activated killer activity from human and murine mononuclear cells

Recombinant IL-3 (rIL-3) is a potent colony stimulating factor capable of stimulating early hematopoietic pluripotential progenitor cells and of supporting the differentiation of multiple cells. IL-3 has also been shown to have effects on mature, differentiated circulating cells including eosinophils and T cells. We evaluated the role of exogenous rIL-3 in the generation of cells with LAK activity from murine splenocytes and human bone marrow, spleen, unseparated PBMC and purified null cell preparations. rIL-3 was unable to generate lytic activity from any of these populations by itself and appeared to decrease LAK activity in bone marrow cultures containing high dose IL-2, (bone marrow derived cells (n = 3) with LAK activity for fresh tumor, mean lytic units(LU) 94.6 +/- 63.5 vs 32.8 +/- 44.8 for IL-2 and IL-2 plus IL-3 cultures, respectively p2 less than 0.05). Unlike previous reports testing murine cells, IL-3 priming and subsequent culture in IL-2 of human unseparated bone marrow cells or human or murine splenocytes, failed to generate long-term cultures with lytic activity. IL-3 did, however, induce a dose dependent stimulation of bone marrow and null cell preparations (mean null cell stimulation (3H Thymidine incorporation) with IL-3, 436 +/- 168 cpm vs 9802 +/- 9799 cpm, for 0 vs 10(3) units of IL-3, respectively n = 4, p2 less than 0.05). Furthermore, in bone marrow, unseparated PBMC and null cell cultures, the addition of rIL-3 generated characteristic large blastic appearing cells with prominent basophilic granules.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lysis of human monocytes by lymphokine-activated killer cells

Human peripheral blood leukocytes (PBL), stimulated in vitro with recombinant human interleukin 2 (IL-2) for 2-7 days, were seen to lyse autologous and allogeneic monocytes in a 4-hr 51Cr-release assay. The lymphokine-activated killer (LAK) cells against monocytic cells were selective in that polymorphonuclear leukocytes (PMN) and nonadherent PBLs were not lysed by these cells. Monocytes which had been cultured for 2-7 days served as better targets than uncultured cells. Also, kinetic studies demonstrated parallel activation of cytolytic activity against monocyte targets and FMEX, an natural killer cell-insensitive human melanoma target. Separation of PBLs by discontinuous density centrifugation identified the effector population in the fractions enriched for large granular lymphocytes (LGL). Precursor cells were seen to express CD2, CD11, and some CD16 markers, but not CD3, CD4, CD8, CD15, Leu M3, or Leu 7. The effector population after IL-2 activation retained the phenotype of the precursor cell. These studies indicate that IL-2 can generate LAK cells against monocytic cells, and this cytolytic activity, especially against autologous monocytes, must be taken into account when IL-2 or LAK cells are used for immunomodulation in cancer patients.     

Similarities between LAK cells derived from human thymocytes and peripheral blood lymphocytes: expression of the NKH-1 and CD3 antigens

Human thymocytes are devoid of NK cells but develop lymphokine-activated killer (LAK) activity after culture with recombinant interleukin-2 (rIL-2). The most active precursor for this activity appears to be a CD3-negative cell. The purpose of these studies was to compare the phenotype and functional activities of thymocyte and peripheral blood lymphocyte (PBL) LAK cells. Following culture, rIL-2-activated thymocytes resemble PBL-generated LAk and PBL NK cells. For each of these populations, lytic activity is highest in NKH-1-positive cells. Two-color fluorescence of each population also indicates that NKH-1+ cells are highly granular, as measured by staining with the lysosomotropic vital dye quinacrine. PBL, PBL-derived LAK cells, and thymus-derived LAK cells have a portion of cells that express both CD3 and NKH-1. However, approximately 60-80% of NKH-1+ cells lack detectable CD3. This suggests that both CD3+ and CD3- cells may be capable of LAK activity. Thymic-derived LAK cells respond to interferon in a manner very similar to NK and PBL-derived LAK cells, but lack the NK-associated CD16 antigen. Thus, despite the absence of NK cells in the thymus, it is possible to generate thymocyte LAK activity which bears a strong resemblance to LAK activity derived from peripheral blood lymphocytes.     

IL-4-induced lymphokine-activated killer cells. Lytic activity is mediated by phenotypically distinct natural killer-like and T cell-like large granular lymphocytes

The purpose of the current study was to characterize lymphokine-activated killer (LAK) activity induced with IL-4/B cell stimulatory factor-1 and to compare IL-4-induced LAK activity with IL-2-induced LAK activity. Culture of murine lymphocytes with high concentrations of IL-4 induced nonspecific lytic activity against a wide variety of tumors. Lytic activity induced by IL-4 increased with increasing concentrations of IL-4 over the range of 1.0 to 25 ng/ml. The kinetics of LAK induction by IL-4 and IL-2 were similar; however, IL-4 was less effective than IL-2 in maintaining lytic activity for longer culture periods and provided lower viable cell yields than did IL-2. Similar to IL-2, IL-4 induced blastogenesis and the generation of large granular lymphocytes, all LAK activity observed was exclusively associated with the large granular lymphocyte fraction, and the cytolytic effector cells were heterogeneous in regards to cell surface phenotype. The majority of IL-4-induced lytic activity was associated with mutually exclusive NK-like (i.e., NK-1.1+ Lyt-2-) and T cell-like (i.e., NK-1.1- Lyt-2+) LAK cells. The precursors for each subset were distinct and expressed the asialo-GM1+ Lyt-2- and the asialo-GM1+ Lyt-2+ phenotypes, respectively. Although IL-4-induced LAK effector cells were morphologically and phenotypically similar to IL-2-induced LAK cells, IL-2 generated equivalent numbers of T cell-like and NK-like LAK cells, whereas IL-4 generated 3.5-fold more T cell-like LAK cells than NK-like LAK cells. It might eventually be possible to exploit the preferential activation of T cell-like LAK by IL-4 for therapeutic advantage.     

Enhanced interferon production and lymphokine-activated cytotoxicity of human placental cells

The immunologic competence of human placental mononuclear cells was compared to that of adult and cord blood mononuclear cells. Mononuclear cells were isolated from fresh placentas by digestion with collagenase and DNase, followed by Ficoll-Hypaque and discontinuous Percoll separation. Placental cells incubated with phytohemagglutinin (PHA) synthesized significantly more interferon-gamma (IFN-gamma) at 2 days (29 +/- 5.5 IU/ml) and 5 days (46 +/- 8.5 IU/ml) than PHA-activated cord cells (3.6 +/- 0.6 IU/ml at 2 days and 2.7 +/- 0.7 IU/ml at 5 days) but less than PHA-activated adult cells (81 +/- 20 IU/ml at 2 days and 270 +/- 161 IU/ml at 5 days). Placental and adult cells, but not cord cells, also synthesized significant quantities of IFN-gamma following incubation with interleukin-2 (IL-2). There was synergism between IL-2 and PHA activation for IFN-gamma production for some cord samples. After a 5- to 7-day incubation with IL-2, the lymphocyte-activated killer (LAK cell) cytotoxicity of placental cells (measured in a 3-hr chromium-release assay at an E:T ratio of 40:1) was enhanced 13-fold against K562 target cells (6 +/- 2% to 77 +/- 4%) compared to a 4-fold increase in cord cells (16 +/- 4% to 68 +/- 3%) and a 2-fold increase in normal adult cells (35 +/- 4% to 65 +/- 3%. Against the natural killer (NK)-resistant Raji target, placental cells increased their LAK cytotoxic activity (3 +/- 1% to 59 +/- 7%) compared to a 7-fold increase with cord cells (6 +/- 1% to 43 +/- 3%) and a 3-fold increase with adult cells (11 +/- 2% to 38 +/- 4%). A notable degree of cytotoxic activity in the absence of IL-2 against Molt targets was noted in 11 of 14 (79%) placental cell samples at 5 days. Only 10 of 24 (42%) adult and 17 of 37 (40%) cord samples showed spontaneous cytotoxic activity equal to or greater than 10%. Some placental samples actually showed an increase in cytotoxic activity when incubated without IL-2. The ability of placental cells to produce significant levels of IFN-gamma, to develop considerable LAK activity, and to maintain or develop cytotoxic activity in the absence of IL-2 suggests a vigorous, active immune system of the placenta compared to the relatively dormant immune system of the neonate. These observations suggest that placental cells may have a primary role in fetal defense.     

Augmentation of cell number and LAK activity in peripheral blood mononuclear cells activated with anti-CD3 and interleukin-2

Summary A wide variety of human cancers currently have no effective treatment and are potential targets for lymphokine-activated killer (LAK) cellular immunotherapy. Relapsed acute lymphocytic leukemia (ALL) and neuroblastoma are two of the major therapeutic challenges in pediatric oncology today. However, one problem which makes LAK immunotherapy in children particularly difficult is obtaining the large numbers of cells required. Present adult therapeutic LAK protocols have utilized short-term (5 day) cultures of interleukin-2 (IL2)-activated cells which are initially obtained from leukophersis. Since routine use of this procedure in small children is not practical, we have investigated a different approach to obtain increased cell numbers by activation of peripheral blood mononuclear cells with OKT3, a mitogenic anti-CD3 monoclonal antibody, and IL2. Cell growth and LAK activity in OKT3+IL2-activated cultures were compared to cultures activated with IL2 alone in 2 children with relapsed ALL and 2 children with stage IV neuroblastoma. OKT3+IL2-activated cultures had marked increases in cell number: after 14 days the OKT3+IL2-activated cultures yielded an approximately 500-fold increase in cell number compared to a 7-fold increase for cultures activated with IL2 alone. In vitro ⁵¹Cr release assays were used to estimate LAK activity of the cultures at 7 and 14 days. When tested against HL60, a natural killer (NK)-resistant tumor cell line, not only were total cytolytic units greatly increased in OKT3+IL2-stimulated cultures but lytic activity on a per cell basis (lytic units/1×10⁶ cells) had also markedly increased on day 14 of culture. Phenotypic analysis demonstrated that 80% to 90% of cells in OKT3+IL2-stimulated cultures were CD3+ T cells. Variable low percentages of CD16+ NK cells were seen in these cultures. In summary, OKT3+IL2 activation resulted in a large increase in cell yield and the development of high level LAK activity using peripheral blood mononuclear cells from children with cancer. This approach may facilitate the utilization of increased cell numbers in future adoptive immunotherapy protocols, especially in pediatric patients.Supported by the Children's Cancer Research Fund, and the USPHS Training Grant T32CA09445Supported by NIH AI17687, AI18326, AI19007, and AI72626     

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.     

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

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

Preadministration of a T-suppressor factor enhances tumor immunity in DBA/2 mice

Summary Human peripheral blood mononuclear cells (PBM) activated with recombinant interleukin-2 (IL-2) generate potent lytic activity (LAK) against a variety of malignant cells. IL-2 alone is sufficient for LAK generation, but high concentrations are needed to generate optimal cytotoxicity. Our recent studies based on combinations of biological agents indicated that alternative activation pathways may exist. Synergy for LAK induction was investigated using IL-2 and tumor necrosis factor- (TNF). Single-cell suspensions of primary human lung carcinomas were prepared from seven established cell lines and 32 fresh tumor specimens. Not only were all cell lines sensitive to allogeneic LAK, but also all fresh tumors were sensitive to some degree to both autologous and allogeneic LAK lysis measured by a 4-h ⁵¹Cr-release assay. LAK-mediated cytotoxicity, induced with a combination of human recombinant IL-2 (Cetus, 100 U/ml) and TNF (Genentech, 500 U/ml), showed a mean fourfold increase (range 0.7–16.3) over IL-2 alone. No lytic activity was generated from PBM incubated with media or TNF alone. The sequence dependence of adding IL-2 and TNF in enhancing cytolytic activity was also studied. In vitro kinetics data revealed that the addition of TNF 2–6 h before the addition of IL-2 greatly increased LAK activity over that obtained from the simultaneous addition of the two cytokines. These results demonstrated (a) the synergy of IL-2 and TNF for generating LAK; (b) the lysis of fresh primary lung cancer cells by LAK; and (c) the sequence dependence of IL-2 and TNF for the induction of optimal LAK activity.This work was supported by NCI Grants RO2-CA45225 and CAO 9611-01, and by an award from the Prouss Foundation     

Human monocytes inhibit lymphokine-activated killer cell expansion in vitro

Depleting monocytes from human peripheral blood mononuclear cells (PBMC) enhances the in vitro activation of lymphokine-activated killer (LAK) cells. To determine if monocytes also altered LAK-cell expansion, we evaluated two methods of depleting monocytes from PBMC: nylon wool adherence (NWA) and phenylalanine methyl ester (PME) treatment. Both methods of depleting monocytes enhanced interleukin-2 (IL-2) driven, LAK-cell expansion; LAK expansion, however, was significantly greater after depletion with NWA than after PME. LAK cytotoxicity after NWA and PME depletion was equivalent. The degree of monocyte depletion, determined by evaluating morphology and the number of Leu-M3 (CD14) positive cells, and the proliferation of Leu 19 (CD56), OKT-3 (CD3), Leu2 (CD8), and Leu 3a (CD4) positive cells was also equivalent. Exposure of IL-2 activated cells to PME did not alter their cytotoxic activity. However, sequential treatment of PBMC with NWA, then PME, or with PME and then NWA, resulted in reduced expansion. This reduction in expansion was similar to PBMC treated with PME alone. Exposure of PME-depleted cells to nylon wool or to supernatants obtained from cells adherent to nylon wool further decreased LAK expansion relative to cells treated with NWA alone. We conclude that even at relatively low cell density, human monocytes markedly inhibit LAK-cell expansion in IL-2 driven PBMC cultures. Further, depletion of monocytes by NWA adherence is more effective than by treatment with PME, possibly due to subtle cellular damage induced by this latter treatment. These findings have implication for the in vitro and in vivo generation of LAK-cells by IL-2.     

Autologous tumor cell killing activity of tumor-associated lymphocytes in patients with head and neck carcinomas

In order to select the most cytotoxic effector cells for adoptive immunotherapy, lymphokine activated killer (LAK) cells, tumor infiltrating lymphocytes (TILs) and autologous mixed lymphocyte tumor cell culture (MLTC) cells derived from peripheral blood mononuclear cells (PBMC) in the same subject with head and neck carcinomas were prepared. The autologous tumor cell killing activity and cell surface phenotypes of each of the three effector cells were studied. MLTC cells cultured with interleukin-2 (IL-2) showed the strongest cytotoxic activity among these three different effector cells. Although TILs had suppressed killing activity immediately after isolation, after successive cultivations with IL-2, a cytotoxic activity against autologous tumor cells stronger than that of LAK cells appeared. Both IL-2 stimulated MLTC cells and TILs showed an enrichment of CD8 positive and CDU negative cells in a CD3 positive subpopulation.Abbreviations CD cluster differentiation - IL-2 interleukin-2 - LA lymphokine activated - LAK lymphokine activated killer - MLTC mixed lymphocyte tumor cell culture - NK natural killer - PBMC peripheral blood mononuclear cells - TILs tumor infiltrating lymphocytes     

Target cell-directed inactivation and IL-2-dependent reactivation of LAK cells

In a previous study, we demonstrated that human natural killer cells (NK) lost their lytic activity after interaction with a sensitive target. The loss of NK activity also led to the loss of antibody-dependent cellular cytotoxicity (ADCC), prompting us to postulate that NK and ADCC activities may result from a common lytic mechanism. In this study, we examined whether nonadherent lymphocytes cultured 7 days in the presence of IL-2 (lymphokine-activated killer (LAK) cells) could also be inactivated and, subsequently, be reactivated in the presence of IL-2. We tested three populations of effector cells (EC): cells isolated from freshly drawn blood and tested immediately, cells cultured with IL-2 for 18 hr, and LAK cells. Once they have interacted with K562, all three cell populations lost greater than 90% of their NK-like lytic activity (NK-CMC) but only 80% of ADCC. However, when we treated the three cell types with antibody-coated K562, they lost 90-99% of NK-CMC and 90-97% of ADCC. In these inactivated effector cells we also observed: (i) a reduction in membrane expression of C-reactive protein; and (ii) a decrease in the expression of Leu-11a when EC were inactivated with antibody-coated K562. The loss of lytic activity against K562 was accompanied by a concomitant loss of activity against other LAK-sensitive targets as well as against antibody-coated targets (ADCC). In competitive inhibition experiments the inactivated effector cells failed to inhibit normal NK-CMC and ADCC activities mediated by fresh NK cells. As we have shown previously, this target-directed inactivation was not due to cell death or to lack of conjugate formation. Inactivated LAK cells regained their lytic potential when cultured with IL-2 and this effect was time dependent. By 72 hr, LAK cells inactivated with K562 regained 99% NK-CMC and 82% ADCC, whereas LAK cells inactivated with antibody-coated K562 regained only 80% NK-CMC and 70% ADCC. When we treated the effector cells with emetine, a potent inhibitor of protein synthesis, we could still inactivate the effector cells with K562 and with antibody-coated K562 but could not reactivate them with IL-2.