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.     

DNA fragmentation during apoptosis is caused by frequent single-strand cuts.

One of the hallmarks of apoptosis is the digestion of genomic DNA by an endonuclease, generating a ladder of small fragments of double-stranded DNA. We have examined the nature of the DNA breaks produced in mouse thymocytes triggered to undergo apoptosis by steroids or by stimulation of the T cell receptor. Whereas the typical ladder pattern of oligonucleosomal fragments was observed after agarose gel electrophoresis, numerous single-strand cuts were detected after electrophoresis under denaturing conditions. Single-strand nicks were found to be very frequent in the internucleosomal regions, but also to occur in the core particle-associated DNA. An identical pattern of single-strand nicks was obtained when chromatin DNA was exposed to the single-strand cleaving deoxyribonuclease I. The nicked DNA fragments, extracted from apoptotic thymocytes, were sensitive to the action of S1-nuclease. We propose that DNA fragmentation induced during apoptosis is not due to a double-strand cutting enzyme as previously postulated, but rather is the result of single-strand breaks. This ensures the dissociation of the DNA molecule at sites where cuts are found within close proximity.     

Interferon is able to reduce tumor cell susceptibility to human lymphokine-activated killer (LAK) cells

It is known that IL-2 induces lymphocytes to produce interferon-gamma (IFN-gamma) and this IFN type is particularly efficient in inducing tumor cell resistance to natural killer (NK) cell-mediated lysis. We have investigated the effect of IFN on tumor cell sensitivity to LAK cell-mediated cytotoxicity. Pretreatment of the human K562 leukemia and HHMS melanoma with IFN-gamma and the Daudi lymphoma with IFN-alpha caused a significant reduction in sensitivity to lysis by human LAK cells generated in vitro in the presence of human recombinant IL-2 (100 U/ml). The LAK activity was mediated by cells expressing NK cell markers (CD16,NKH1) as well as by cells with T cell markers (CD3, CD5). IFN-treated K562 cells were protected from lysis mediated by all these populations. Supernatants from LAK cultures containing IFN-gamma were able to induce NK and LAK resistance when used to pretreat K562 overnight. Antibodies to IFN-gamma but not to IFN-alpha were able to neutralize this activity. Taken together, these results indicate that the production of IFN-gamma by LAK cells may be of importance in induction of tumor cell resistance to LAK cell-mediated lysis.     

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.     

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.     

Interleukin-6 does not support interleukin-2 induced generation of human lymphokine-activated killer cells

Summary The activity of lymphokine-activated killer (LAK) cells is supported by various cytokines. The objective of this study was to see if recombinant interleukin-6 (IL-6) either alone or in combination with interleukin-2 (IL-2) has any effect on the generation of LAK cells. Peripheral blood mononuclear cells of healthy donors were cultured for 4 or 6 days with both cytokines either alone or in combination. LAK activity against K562 and natural killer-resistant Daudi cells was assessed by a 4-h and an 18-h⁵¹Cr-release assay at various effector to target ratios. IL-6 alone in increasing concentrations did not induce LAK cell activity. Neither additive nor synergistic effects of IL-6 with IL-2 were observed. Immunofluorescence analysis with phycoerythrin-conjugated anti-CD56 antibody demonstrated that IL-6 could not maintain or increase the number of CD56-positive cells over a 6-day culture period. These results suggest that IL-6 does not support LAK cell generation by itself or increase LAK cell activity in combination with IL-2.     

Target cell directed NK inactivation. Concomitant loss of NK and antibody-dependent cellular cytotoxicity activities

We investigated the inactivation of human NK cells, a population of large granular lymphocytes (LGL), with K562, an NK-sensitive target cell (TC) and KLCL, an NK-resistant TC, but which can be lysed by NK cells via antibody (Ab)-dependent cellular cytotoxicity. NK-enriched effector cells (ECc) were first treated with either K562 or Ab-coated KLCL (Ab-KLCL). After incubation, ECc were separated from their TC then examined for residual NK and ADCC activities, phenotypic changes, and changes in LGL morphology. K562-treated ECc and Ab-KLCL-treated ECc, when retested against the inactivating TC, respectively, lost greater than 90% of their lytic activities. However, K562-treated ECc lost 60 to 70% of their activity against Ab-KLCL, whereas Ab-KLCL-treated ECc lost less than 10% of their activity against K562. In contrast to what we observed with K562-treated ECc, we detected significant reductions in plasma membrane expression of Leu-11a and Leu-11b on Ab-KLCL-treated ECc. Although the proportion of OKM1+ cells remained unchanged after the inactivation process, the density of OKM1 on both K562-treated ECc and Ab-KLCL-treated ECc increased significantly. Morphologic analysis revealed no apparent differences in the percentages of LGL before and after treatment with K562 or Ab-KLCL. Finally, IL-2 restored lytic potential to both K562-treated ECc and Ab-KLCL-treated ECc and, in addition, IL-2-induced enhancement of Ab-KLCL-treated ECc was accompanied by a partial reexpression of Leu-11a. These data support the hypothesis that NK-cell-mediated cytotoxicity and antibody-dependent cellular cytotoxicity may result from a common lytic mechanism, although the initiation steps and regulation of the pathway are distinct.     

Human cytotoxic lymphocytes. IV. Frequency and clonal specificity of CD8+CD16-(Leu2+Leu11-) and CD16+CD3-(Leu11+Leu4-) cytotoxic lymphocyte precursors activated by alloantigen or K562 stimulator cells

Cell sorter-purified CD8+CD16- (Leu2+Leu11-) cytotoxic T cell precursors and CD16+CD3-(Leu11+Leu4-) natural killer (NK) cells were cultured under limiting dilution (LD) conditions with allogeneic stimulator cells or with K562 tumor cells in the presence of exogenous interleukin 2. One out of 100-200 alloantigen-stimulated Leu2+ T cells clonally developed into an alloantigen-specific cytotoxic T cell, but only 1 out of 500-3400 of these cells lysed NK-susceptible K562 target cells. In contrast, 1 out of 2-35 alloantigen-stimulated Leu11+ precursor cells developed into an effector cell that lysed K562, but less than 1 out of 500 of these cells lysed allogeneic Con A blast targets. However, clonal activation of Leu11+ precursor cells under LD conditions did not require alloantigenic stimulator cells. Comparable high frequencies (f = 1/3 to 1/28) of anti-K562 cytotoxic lymphocyte precursors were thus measured when Leu11+ precursor cells were cultured on autologous or K562 feeder cells. As shown by a split culture approach, the vast majority of alloantigen-activated Leu2+ effector cells were highly specific for the stimulating alloantigen (i.e., they did not lyse K562), while the majority of Leu11+ microcultures lysed K562 tumor cells but neither autologous nor allogeneic Con A blast targets. On a quantitative basis, these data show that CD8+CD16- T cells and CD16+CD3-NK cells are two mutually exclusive lymphocyte populations which clonally develop into cytotoxic effector cells specific for alloantigen or K562 target cells, respectively.     

Mismatch repair converts AID-instigated nicks to double-strand breaks for antibody class-switch recombination

Mismatch repair (MMR) proteins are important for antibody class-switch recombination (CSR), but their roles are unknown. We propose a model for the function of MMR in CSR in which MMR proteins convert single-strand nicks instigated by activation-induced cytidine deaminase (AID) into the double-strand breaks (DSBs) that are required for CSR. This model does not invoke any novel functions for MMR but simply posits that, owing to numerous single-strand nicks in the switch (S) regions of both DNA strands, when MMR proteins are recruited by U:G mismatches, they excise one strand of DNA and soon reach a nick on the opposite strand. This halts excision activity and creates a DSB. This model explains why B cells that lack either S mu and MSH2 or UNG and MSH2 cannot undergo CSR.     

Anti-tumor cytotoxic potential and effect on human bone marrow GM-CFU of human LAK cells generated in response to various cytokines.

The effects of various recombinant cytokines i.e. IL-1 alpha, IL-3, IL-4, IL-6, IFN-gamma, TNF-alpha and GM-CSF used either alone or in combination with IL-2, were investigated in this study. First, their capacity to induce killer cells from human PBL was examined by evaluating the degree of killing of human NK-sensitive K562 or NK-resistant Daudi cells. Second the effects of these cytokines, LAK cells (at 1/1, 2/1, 4/1 ratio LAK effectors/bone marrow cell targets) and of the supernatants from washed killer cell cultures, were examined on the colony forming ability of human bone marrow for GM-CFU in vitro. Various degrees of NK activity against K562 was observed in PBL stimulated with the cytokines, whereas LAK activity was found only with IL-2 alone. Culture of PBL with IL-2 + IL-1 alpha or IL-2 + IL-6 or IL-2 + GM-CSF resulted in the highest LAK killing. However, addition of TNF-alpha, or IFN-gamma to IL-2 in cultures resulted in a significant suppression of LAK cell activity. Addition of IL-1 alpha, IL-2, IL-3, and IL-4 to BM cultures had little or no effect on day 14 GM-CFU, whereas addition of IL-6 and GM-CSF resulted in a stimulatory effect. LAK cells induced with IL-2 alone had no significant suppressive effects on GM-CFU.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional heterogeneity of Leu 19"bright"+ and Leu 19"dim"+ lymphokine-activated killer cells

The functional heterogeneity of human lymphokine-activated killer (LAK) cells was characterized using LAK effector cells generated in vivo during rIL-2 therapy and separated by FACS into Leu 19"bright"+ and Leu 19"dim"+ subsets. The Leu 19"bright"+ subset mediated significantly greater levels of LAK lytic activity against NK-resistant COLO 205 target cells compared to Leu 19"dim"+ effector cells in chromium release assays. Single cell cytotoxicity assays showed that the Leu 19"bright"+ LAK effector cell subset contained a significantly higher percentage of cells capable of binding to and lysing COLO 205 or K562 target cells compared to the Leu 19"dim"+ subset. Furthermore, individual Leu 19"bright"+ LAK effector cells exhibited a more rapid rate of COLO 205 target cell lysis when compared to Leu 19"dim"+ LAK effector cells. In vitro culturing of Leu 19"bright"+ or Leu 19"dim"+ cells from normal donors with 1500 U/ml rIL-2 resulted in significantly greater levels of proliferation and LAK effector activity by Leu 19"bright"+ cells. Furthermore, whereas 86% of normal Leu 19"bright"+ cells maintained a Leu 19"bright"+ phenotype after rIL-2 stimulation, only 24% of Leu 19"dim"+ cells developed a Leu 19"bright"+ phenotype. These data demonstrate that Leu 19"bright"+ LAK cells are significantly more potent effectors than Leu 19"dim"+ cells due to quantitative and qualitative differences in the LAK effector cells contained within these subsets. Furthermore, these data indicate that Leu 19"bright"+ LAK cells that develop during rIL-2 therapy are derived from Leu 19"bright"+ precursor cells.     

Enhanced MHC I antigen expression on tumour target cells is inversely correlated to lysis by allogenic but not by xenogenic NK cells

Relationship between the levels of MHC class 1 antigen expressed on tumour cells and their susceptibility to allogenic and xenogenic NK cells was investigated. Mouse and human natural killer-resistance inducing factor (NK-RIF) preparations were used for augmenting/inducing MHC 1 antigen expression on murine YAC and human K562 tumour cells, respectively YAC cells with augmented MHC I antigen expression became relatively resistant to lysis by murine NK cells but not to rat NK cells. Similarly, induction of MHC I antigens on K562 cells reduced their susceptibility to human NK cells but not to monkey NK cells. These results indicate that the inverse correlation of MHC I antigen expression and NK susceptibility does not hold true for xenogenic pairs of NK effector and target cells.     

Modulation of natural cytotoxicity by alloantibodies. V. The mechanism of a selective augmenting effect of anti-H-2 antisera on the natural killer activity of mouse spleen cells

Treatment of mouse spleen cells with specific anti-H-2 antisera augments their natural killer (NK) activity against K562 cells but not against YAC target tumor cells. The same population of natural killer cells was found to lyse K562 as well as YAC target cells, since (a) depletion of YAC reactive NK cells by absorption on YAC monolayers resulted in a concomitant depletion of anti-K562 NK activity of mouse spleen cells, and (b) both K562 and YAC cells could inhibit their own as well as each others lysis in a cross-competition assay. Anti-H-2 antiserum could not induce anti-K562 NK activity in spleen cells previously depleted of NK cells by absorption on YAC monolayers, indicating that alloantiserum does not act by recruiting otherwise nonreactive cells to become cytotoxic toward K562 target cells. In a target-binding assay, K562 binding of NK cells (T-cell-, B-cell-, and macrophage-depleted spleen cells) increased five- to eightfold in the presence of anti-H-2 antiserum whereas YAC cells binding of NK cells was not increased. H-2 antigens per se did not appear to be involved in the alloantisera effect since anti-NK antiserum directed against a non-H-2 antigen selectively expressed on NK cells, showed a similar selective NK enhancing effect. Protein A, a reagent which binds to the Fc region of immunoglobulin molecules, completely blocked the alloantiserum induced augmentation of anti-K562 NK activity, but did not alter basal NK activity. Moreover, the F(ab)₂ fraction of alloantibodies failed to enhance anti-K562 cytotoxic activity of mouse spleen cells, indicating a crucial role for the Fc portion of the alloantibodies attached to the NK cells, in NK augmentation. Utilization of several target cell lines with or without membrane Fc receptors (FcR) revealed that alloantiserum enhanced the lysis of only FcR⁺ target cells. It is proposed that alloantibody-coated NK cells, as a result of a secondary interaction between attached alloantibody and Fc receptors on target cells, interact more readily with the target cells and thereby cause a higher level of lytic activity.     

Heterogeneity of human NK cells: comparison of effectors that lyse HSV-1-infected fibroblasts and K562 erythroleukemia targets

In this study, we compared the natural killer (NK) cells that lyse HSV-1-infected NK(HSV-1) or uninfected [NK-(FS)] fibroblasts to those that lyse K562 erythroleukemia cells [NK(K562)]. Activity against all three targets was found in Percoll gradient fractions enriched for large granular lymphocytes, which suggests that these effector cells have a common morphology. In competition studies between 51Cr-labeled targets and unlabeled targets, both the infected and the uninfected fibroblasts competed for lysis of NK(HSV-1) and NK(FS) activity, whereas K562 cells competed poorly. In contrast, when 51Cr-labeled K562 cells were used, the unlabeled K562 cells competed well, but HSV-1-infected and uninfected fibroblasts competed poorly. Panning studies and complement elimination experiments using monoclonal antibodies were performed to describe cell surface markers on the NK cell populations. Treatment with an antibody to an la framework antigen reduced NK(HSV-1) but not NK(K562) activity. In contrast, the majority of NK(K562) effectors were recognized by antibodies to the E-rosette receptor (Lyt-3 and OKT11A), whereas NK(HSV-1) activity was much less sensitive to this antibody. OKM1, OKT10, and Leu-7 (HNK-1) markers were found on a portion, but not all, of the cells that lysed both the HSV-FS and K562 targets, while treatment with HLA plus complement totally abrogated both NK activities. Taken together, these data are consistent with the concept that human NK cells are heterogeneous and that we are dealing with at least three subpopulations of effector cells--one that kills the infected or uninfected fibroblasts; one that kills K562 cells; and a third population that may be able to kill all three targets. Patient studies provide additional evidence for heterogeneity within the NK cells that lyse the fibroblasts and K562 cells. We have studied a number of individuals who have normal NK activity with one target (HSV-FS or K562) but have low or no activity against the other. These patients provide strong evidence not only that NK cells are heterogeneous but also that these NK subpopulations can be regulated independently of each other in vivo.     

DNA of human Raji target cells is damaged upon lymphocyte-mediated lysis

Human Raji target cells DNA is degraded by the introduction of single-strand breaks (alkali-sensitive sites) upon lymphocyte-mediated lysis. This type of DNA degradation appears earlier and is more extensive in lymphocyte-than in antibody + complement-mediated lysis of Raji cells, regardless of the species of effector lymphocytes (human or mouse). Mouse P815 target cell DNA is extensively fragmented (yielding 200 base pair fragments) when human or mouse lymphocytes are used to lyse P815. Thus, these observations indicate that both human and mouse target cell DNA are affected during lymphocyte-mediated lysis. Moreover, the pattern of DNA degradation in target cells lysed by effector lymphocytes is characteristic of the target cell species, suggesting that DNA degradation proceeds through the activation of target cell endonuclease(s).     

Interleukin 2 induces human acute lymphocytic leukemia cells to manifest lymphokine-activated-killer (LAK) cytotoxicity

Lymphokine-activated killer cells (LAK) were originally distinguished from natural killers (NK) and cytotoxic T lymphocytes. Recently, however, IL 2-activated NK cells were suggested as the major source of LAK reactivity in human peripheral blood (PBL). Because certain T cell acute lymphoblastic leukemia (T-ALL) cells are phenotypically similar to LAK precursors, we have asked whether these leukemic cells can be induced toward LAK-cytotoxicity and express NK reactivity before stimulation. Five out of seven T-ALL preparations were induced by IL 2 to kill target cells. The cytotoxicity of the leukemic-LAK cells resembled that of normal LAK effectors as they lysed efficiently the NK-resistant target Daudi, as well as fresh human sarcoma, carcinoma, and renal cancer cells but not normal PBL. The ALL-LAK precursors phenotype was T3-, T4-, T8-, and T11+, similar to most normal LAK precursors. In contrast to normal PBL that generated LAK effectors when their proliferation was inhibited, the irradiated, nonproliferating T-ALL leukemic cells did not respond to IL 2. Therefore, the T-ALL LAK cytotoxicity was attributed to the leukemic cells rather than to residual normal lymphocytes. The IL 2-responding T-ALL cells did not express autonomous NK type cytotoxicity, suggesting that they reflect LAK precursors of non-NK origin. The homogeneous leukemic preparations with inducible LAK cytotoxicity described herein provide a model system for studying normal LAK cells.     

Evidence for an early calcium-independent event in the activation of the human natural killer cell cytolytic mechanism

In this study, we examined the functional status of human natural killer (NK) cells after their direct interaction with the NK-sensitive tumor target cell (TC), K562. Human peripheral blood lymphocytes depleted of adherent cells were incubated for 4 hr with unlabeled K562 cells at an effector cell (EC) to TC ratio of 2:1. After incubation, the EC were separated from the TC via centrifugation over a single-step Percoll gradient. K562-treated and separated EC were subsequently shown to be unable to lyse fresh K562 TC when retested in the standard chromium-release assay. Kinetic studies revealed that greater than 90% inactivation of NK cell-mediated cytotoxicity (CMC) could be achieved within 2 hr. Inactivation of NK-CMC by K562 was not caused by a specific loss of NK cells, as detected by changes in the expression of two NK cell-associated markers, Leu-7 and Leu-11, or to alterations in EC viability and target binding cell capacity. Interestingly, NK inactivation also occurred in medium devoid of extracellular calcium, although parallel testing of NK-CMC in the same medium resulted in no chromium release. NK inactivation, however, was significantly prevented when the EC and TC were co-incubated at 4 degrees C, or in medium without magnesium. Additional studies revealed that inactivation of NK-CMC could be achieved with another NK-sensitive, but not with an NK-resistant TC. Overall, we demonstrated that NK cells rapidly lost their lytic potential after direct interaction with a sensitive TC, although the cells remained viable, expressed the same percentage of Leu-7 and Leu-11, and could still bind the TC; and NK inactivation occurred in the absence of extracellular calcium, but not when EC and TC were incubated in medium without magnesium. These latter results provide evidence for an early event in the activation of human NK cells that is binding dependent, temperature sensitive, and independent of extracellular calcium.     

Transforming growth factor-beta 1 (TGF-beta 1) and recombinant human tumor necrosis factor-alpha reciprocally regulate the generation of lymphokine-activated killer cell activity. Comparison between natural porcine platelet-derived TGF-beta 1 and TGF-beta 2, and recombinant human TGF-beta 1

We have investigated the ability of porcine-platelet-derived transforming growth factor-beta 1 (TGF-beta 1) to inhibit the generation of lymphokine-activated killer (LAK) cells by human rIL-2. The results demonstrate that TGF-beta 1, in a dose-related manner, significantly inhibits rIL-2-induced LAK cell activity against Daudi and COLO target cells and, to a lesser degree, against K-562 cells. Maximal inhibition was obtained by the addition of TGF-beta 1 at the time of culture initiation and, to a lesser degree, on day 1. Only minimal inhibition was obtained when TGF-beta 1 addition was delayed until day 2 of culture or when added directly into the LAK cell assay. Additional studies demonstrated that porcine platelet-derived TGF-beta 2 and human rTGF-beta 1 inhibited LAK cell generation similar to that obtained with TGF-beta 1. The inhibition of LAK cell activity by TGF-beta 1 was reversed by the addition of human rTNF-alpha at the initiation of culture. In addition, rTNF-alpha synergized with suboptimal levels of rIL-2 in the generation of LAK activity. After stimulation with rIL-2, LAK cells produced significant levels of IFN-gamma, TNF-alpha, and TNF-beta. TGF-beta 1 inhibited the production of these cytokines in a dose-related manner. The results extend the previous known activities for human rTNF-alpha and TGF-beta 1 and further demonstrate the reciprocal relationship between these two molecules in the regulation of certain immune functions.     

Enhancement of tumor cell susceptibility to lymphokine-activated killer cells by treatment with the streptococcal preparation OK432

We investigated whether tumor cell lysis by LAK cells was augmented by treatment with OK432in vitro. NK and LAK activity against K562 cells was not enhanced by their treatment with OK432. In contrast, the susceptibility of OK432-treated Daudi and KATO-III cells to lysis by LAK cells was enhanced. Succinate dehydrogenase activity and RNA synthesis were impaired in Daudi and KATO-III cells by treatment with OK432, and moreover the expression of HLA Class I antigen and ₂-microglobulin was inhibited in OK432-treated KATO-III cells. Thus, it is suggested that the enhancement of the susceptibility of OK432-treated tumor cells with regard to succinate dehydrogenase activity, RNA synthesis, and HLA Class I antigen expression.     

Human T cell clones exerting multiple cytolytic activities show heterogeneity in susceptibility to inhibition by monoclonal antibodies

Human cytotoxic T cell clones (CTL) were obtained by limiting dilution after in vitro priming against an allogeneic Epstein Barr virus (EBV)-transformed B cell line (B-LCL) BSM. Three OKT3+, OKT8+ E rosette-forming (RFC) but EA gamma-RFC- clones with cytotoxic activity against the stimulator cell and one "non-cytolytic" clone were expanded for over 50 generations and further characterized. Clone G9 showed allospecific lysis of Cw3+ lymphocytes and B cell lines. Three cytolytic clones (G9, D11, and A3) showed cytotoxicity to the stimulator B-LCL, to the human plasma cell leukemia-derived line LICR-LON-HMY2 and to short-term cultured melanoma cells (O-mel). Four other EBV-transformed B-LCL unrelated to the stimulator B-LCL were not lysed. These clones also exerted cytotoxic activity against NK-sensitive target cells (TC), e.g., the erythroleukemia cell line K562. Other NK-sensitive TC, e.g., lymphoma-derived Daudi cells, were killed provided they were pretreated with phytohemagglutinin (PHA). Cytolytic activity against the B-LCL cell LICR-LON and O-mel, but not against K562 or PHA-treated target cells, was inhibited by monoclonal anti-HLA ABC antibodies (MCA). The cytolytic activities of OKT3+,8+ clones G9 and A3 but not that of OKT3+,8+ clone D11 were inhibited by OKT8. Another MCA, 13.3, directed against the murine glycoprotein T-200, inhibited the cytolytic activity of clone D11 against K562 but not against the stimulator cells. Clone G9 was not inhibited by MCA 13.3. The four clones, including the OKT4+ "non-cytotoxic" clone K12, exerted lytic activity against TC that are normally resistant to lysis provided these TC were pretreated with PHA. The TC specificity range of the clones was confirmed by cold target inhibition experiments. A correlation between blocking of lytic activity by cold TC and the percentage of conjugate formation with the particular cold TC was observed. Because these clones also show differential susceptibility to inhibition of lysis by various MCA, it is concluded that human cytotoxic T cell clones can exert multiple lytic activities, i.e., the operationally defined lytic mechanisms differ at least at certain stages of the lytic cycle.