Stimulation with autologous lymphoblastoid cell lines: lysis of Epstein-Barr virus-positive and -negative cell lines by two phenotypically distinguishable effector cell populations

Human lymphocytes, stimulated in vitro for 6 days with x-irradiated or glutaraldehyde-treated autologous Epstein-Barr (EB) virus-transformed lymphoblastoid cell lines (LCL), are cytotoxic for autologous and allogeneic EB+ LCLs as well as for several EB- cell lines that are also susceptible to lysis by interferon-activated natural killer (NK) cells. To determine whether the apparent nonspecific lysis mediated by LCL-stimulated cells is due to a mixture of effector cells directed against different target cells, advantage was taken of our recent finding that monoclonal antibody OKT8 reacts with human cytotoxic T lymphocytes but not with NK cells or NK-like cells generated in mixed leukocyte cultures. The depletion of OKT8+ cells from LCL-stimulated cultures by treatment with OKT8 and complement abolished or markedly depleted cytotoxicity against all EB+ target cells tested, whereas cytotoxicity against EB-, NK-sensitive cell lines including K562, MOLT-4 and HSB-2 was not or only minimally reduced. These results indicate that stimulation with autologous LCL results in the generation of OKT8+ cytotoxic T lymphocytes that lyse EB virus-transformed LCL and OKT8- NK-like cells that lyse EB-, NK-sensitive cells.     

Depletion of human NK cells with monoclonal antibodies allows the generation of cytotoxic T lymphocytes without NK-like cells in mixed cultures

In vitro stimulation of human mononuclear cells with x-irradiated autologous lymphoblastoid cell line (LCL) or allogeneic normal cells in mixed leukocyte cultures (MLC) was previously shown to result in the generation of OKT3+ OKT8+ cytotoxic T lymphocytes (CTL) lytic for allogeneic and autologous LCLs and also of natural killer- (NK) like cells that are OKT3- and primarily OKT8- and are lytic for HLA- NK-sensitive K562 cells. The origin of the NK-like cells was not previously known because, although the majority of fresh human NK cells react with monoclonal antibodies OKM1 and B73.1, lymphocytes bearing these markers are not detected several days after the onset of MLC, when NK-like cells are present. In this study, experiments were undertaken to determine whether NK-like cells generated after stimulation with x-irradiated pooled allogeneic normal cells (poolx) or with autologous LCL are derived from cells expressing antigens reactive with monoclonal antibodies OKM1 or B73.1, which react with fresh NK cells. Mononuclear cells, depleted of monocytes, were stained with OKM1 or B73.1 and fluorescein-labeled goat anti-mouse IgG. Lymphocytes depleted of OKM1+ or B73.1+ cells, by fluorescence-activated cell sorting, and lymphocytes that were stained but not sorted were stimulated for 7 days with either poolx or autologous LCL. The generation of NK-like activity was decreased at least 90% after depletion of cells reactive with OKM1 or B73.1, whereas the generation of CTL against autologous and allogeneic LCL was minimally affected. These findings show that NK-like cells generated in MLC are derived from cells that express the phenotype of fresh NK cells (OKM1+ or B73.1+) and that CTL can be generated in cultures in which relatively little NK-like activity is concomitantly detected, by depleting NK cells with monoclonal antibodies before stimulation.     

In vitro generation of human activated lymphocyte killer cells: separate precursors and modes of generation of NK-like cells and "anomalous" killer cells

The activation of human peripheral blood mononuclear cells (PBM) in culture leads to the generation of nonspecific killer cells. These cells, termed activated lymphocyte killer (ALK) cells, can kill fresh tumor cells and tumor cell lines, in addition to the natural killer (NK) cell sensitive target K562. ALK cells have features in common with both T and NK cells, but their nature and origin are unknown. In the present study, it is shown that ALK cells are in fact heterogeneous and can be generated from both large granular lymphocytes with the same phenotype as NK cells and from T cells. Cell populations enriched for NK cells, when cultured with lymphokines, rapidly acquired a T cell phenotype, enhanced cytolytic activity against K562, and the ability to lyse NK-insensitive target cells such as a melanoma cell line LiBr; these ALK cells were described as NK-like cells. On the other hand, of the cloned cells derived from PBM stimulated with irradiated B lymphoblasts and grown in lymphokines, the major proportion of cytolytic T cells (CTC) able to kill the specific stimulator lymphoblasts were also found to kill LiBr but not K562 cells. These ALK cells, which were derived from the same precursors as CTC, were designated anomalous killer (AK) cells. Consistent with this, the presence of the pan T monoclonal antibody UCHT1 from the beginning of mixed cell cultures inhibited the generation of CTC and of the AK-type of ALK cell, which killed melanoma cells, but not the NK type, which killed K562 targets. By contrast, at the effector cell level, the antibodies UCHT1 and OKT8 only blocked specific killing by CTC but did not block the killing of LiBr or of K562 targets by ALK cells. However, at the effector cell level there was additional evidence for the heterogeneity of ALK cells. Thus, monoclonal antibody 9.1C3, which blocks killing by freshly isolated NK cells, also blocked the killing of K562 targets by NK-like cells, but did not block B lymphoblast killing by CTC or melanoma cell killing by AK cells. It is concluded that after mixed lymphocyte culture, the majority of ALK cells measured by the killing of melanoma target cells arise from the same precursors and are under the same influences as classical CTC (AK cells), whereas cells killing K562 targets are derived from NK cells (NK-like cells). Once generated, the AK cells have a different mechanism of killing from both classical CTC and from NK and NK-like cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Leu-Leu-OMe sensitivity of human activated killer cells: delineation of a distinct class of cytotoxic T lymphocytes capable of lysing tumor targets

Sensitivity to L-leucyl-L-leucine methyl ester (Leu-Leu-OMe) was used to characterize the phenotype of human activated killer cells. Natural killer cells (NK) and the precursors of both the alloantigen-specific cytotoxic T lymphocytes (CTL) and the NK-like activated killer cells generated after stimulation with allogeneic cells were deleted from human peripheral blood lymphocytes by preincubation with Leu-Leu-OMe. It was noted, however, that cytotoxic lymphocytes could be generated from Leu-Leu-OMe-treated lymphocyte precursors after 2 to 6 days of culture with the nonspecific mitogen, phytohemagglutinin (PHA). The characteristics of these killer cells indicated that they were a unique population that could be distinguished from other cytotoxic cells. Killing by these cells exhibited slow kinetics in that 18 hr cytotoxicity assays were required to detect full cytotoxic potential. When 18 hr assays were used, PHA-stimulated cytotoxic cells generated from Leu-Leu-OMe-treated lymphocytes were able to kill both NK-sensitive K562 cells and the relatively NK-resistant renal cell carcinoma cell line, Cur. These cytotoxic lymphocytes were HNK-1, Leu-11b (CD16), and OKM1 (CR3)-negative at both the precursor and effector stage of activation. Furthermore, these cells were derived from a CD3-positive precursor. Finally, killing by activated effectors was inhibited by OKT3. Unlike activation of Leu-Leu-OMe-sensitive large granular lymphocytes, generation of these cytotoxic T cells was totally prevented by treatment with mitomycin c before stimulation. Thus, a unique class of tumoricidal T cells can be characterized by resistance of lymphocyte precursors to a concentration of Leu-Leu-OMe, which has been shown to ablate NK, mixed lymphocyte culture-activated NK-like cytotoxic precursors, and the precursors of alloantigen-specific CTL.     

Studies on cytotoxicity generated in human mixed lymphocyte culture

Summary High levels of cytotoxic activity against the natural killer (NK) cell-sensitive target K562 and the NK-resistant target UCLA-SO-M14 (M14) can be generated in vitro either by mixed lymphocyte culture (MLC) or by culture of lymphocytes in interleukin 2 (IL2) (lymphokine activated killer (LAK) cells). The purpose of this study was to identify similarities and differences between MLC-LAK and IL2-LAK cells and allospecific cytotoxic T cells. Induction of cytotoxicity against K562 and M14 in both culture systems was inhibited by antibodies specific either for IL2 or the Tac IL2 receptor. Like NK effector cells, the precursors for the MLC-LAK cells were low density large lymphocytes. However these precursors differed from the large granular lymphocytes that mediated NK cytolysis in sensitivity to the toxic lysosomotropic agent L-leucine methyl ester (LME). The resistance of the MLC-LAK precursors to LME indicated that the precursors included large agranular lymphocytes. Although interferon-gamma (IFN-gamma) is produced in MLC and in IL2 containing cultures, it is not required for induction of either type of cytotoxic activity. Neutralization of IFN-gamma in MLC-and IL2-containing cultures with specific antibodies had no effect on the induction of cytotoxic activities. Both allospecific cytotoxic T lymphocyte (CTL) and LAK activities were enhanced by IL2 and IFN-gamma at the effector cell stage. However, the mechanism of cytolysis was different in the two systems. NK- and MLC-induced LAK activities were independent of CD3-T cell receptor complex while CTL activity was blocked by monoclonal antibodies specific for the CD3 antigen. These results suggest that NK and the in vitro induced LAK cytotoxicities are a family of related functions that differ from CTL. Furthermore, MLC-induced and IL2-induced cytotoxicities against K562 and M14 appear to be identical.This work was supported by NIH grant CA34442     

The role of transferrin in natural killer cell and IL-2-induced cytotoxic cell function

The growth factor transferrin (Tf) enhanced natural killer (NK) cell cytotoxicity. This enhancement was due to direct effects on NK cell function, and Tf treatment of the K562 target cell had no effect on their sensitivity. NK cells were highly enriched in the low-density large granular lymphocyte population (LGL) by Percoll gradient centrifugation. Despite the direct effect of Tf on NK cells, the number of cells expressing receptors for Tf (TfR) in NK-enriched LGL was the same as the NK-cell-depleted high-density small lymphocyte population (SL). All populations, tested without stimulation, had very few TfR+ cells. Interleukin 2 (IL-2) could induce very high NK-like activity in the LGL but not in SL. Similarly, only LGL could be induced by IL-2 to express TfR. In serum-free cultures, only limited NK-like activity could be developed which was greatly enhanced by supplementing with Tf in the cultures. The importance of Tf in NK-like development was confirmed by modulating the expression of TfR in IL-2 containing cultures with mouse monoclonal antibody OKT9 specific for TfR. OKT9 totally abrogated the induction of cytotoxic activity by IL-2 against K562 and NK-resistant target. OKT9 inhibited the induction of cytotoxicity in both lymphocytes containing active NK cells and in those predepleted of active NK cells, indicating that the development of NK-like activity from both precursor populations requires Tf. The inhibition by OKT9 was only during the induction phase. The same antibody had no effect on the cytotoxicity of fresh NK cells or the mature IL-2-induced NK-like cells. Our data therefore do not support the hypothesis of TfR as the NK recognition structure. Instead, these results indicate that Tf is important for the development of NK and NK-like activities.     

Cloned "anomalous" killer cells derived from allogeneic mixed leukocyte culture

In addition to allospecific cytotoxic lymphocytes, cytolytic effector cells capable of killing a broad range of targets are generated during mixed leukocyte culture (MLC). These cells, which have been previously called anomalous killer cells, are a distinct functional subset separate from natural killer cells or allospecific cytotoxic lymphocytes but display many characteristics of lymphokine-activated killers. In order to isolate anomalous killer cells for detailed analysis, we generated the cytolytic effectors from an allogeneic MLC using heat-inactivated stimulators. This treatment of the stimulator population abrogated the generation of classical allospecific cytotoxic lymphocytes but allowed the generation of anomalous killer cells which were subsequently cloned via limiting dilution. The clones derived by this method displayed the functional properties of anomalous killers seen in bulk MLCs. The clones demonstrated potent cytolytic activity against both NK-sensitive and NK-resistant tumor targets in vitro and also suppressed tumor growth in vivo. Ultrastructural studies revealed features similar to those of cloned antigen-specific cytolytic cells and clones with NK-like function. The cells expressed surface glycoproteins associated with both NK and T lymphocytes including Thy-1, Ly-2, T200, Qa-5, asialo GM1, and the antigens defined by the NK alloantisera NK-2.1 and NK-3.1. These cells may play an important role during early phases of the immune response, since cytolytic cells of broad specificity may protect the host until classical cytotoxic lymphocytes with restricted specificity are generated.     

Human killer cells and natural killer cells: distinct subpopulations of Fc receptor-bearing lymphocytes

Unstimulated human peripheral blood lymphocytes were depleted of K cells, which mediate antibody-dependent cellular cytotoxicity (ADCC) without removing NK cells, which mediate natural killing (NK). K cell depletion was achieved by buoyant centrifugation removal of lymphocytes that bound to glutaraldehyde-treated P815-AB cells at high lymphocyte-to-target ratios. Likewise, NK cells were removed with glutaraldehyde-treated K562 cells without removing K cells. Furthermore, both cytotoxic cell populations were observed directly in one agarose single-cell cytotoxic assay (ASCA) using P815-AB and K562 cells simultaneously as target cells. Moreover, the percentage of total cytotoxic cells was equal to the sum of the percentage of K and NK cells observed in separate ASCA. Collectively, these results indicate that K cells and NK cells are distinct subsets of FcR-bearing lymphocytes. One subset, K cells, has more avid Fc receptors (fcR) than NK cells and are 'activated' via thier FcR to kill antibody-coated target cells. The second subset, NK cells, have less avid FcR and are not 'activated' through their FcR to kill antibody-coated target cells.     

Clonal analysis of human tumor infiltrating lymphocytes reactive with autologous tumor cells: different target cell specificities of NK-like and cytotoxic T-cell clones

Lymphocytes, derived from surgically resected lung carcinoid tissue, were stimulated in mixed culture with irradiated autologous tumor cells (MLTC). The autologous MLTC-stimulated lymphocytes were found to have killing activity against both autologous tumor cells and NK-sensitive target cells. The lymphoblasts generated during MLTC were isolated and cloned under limiting dilution conditions in the presence of interleukin 2. The cloned cell lines were analyzed for cell phenotype and tested for cytotoxic activity. Three cloned cell lines, out of 19 tested, were found to be cytotoxic either against NK-sensitive target cells (natural killers) or the autologous tumor cells. Two clones, having OKT8 phenotype, caused no lysis of the autologous tumor cells, though both exerted NK-like activity against K562 cells. Only one clone with OKT4 phenotype showed specific cytotoxic activity against the autologous tumor, but no NK-like activity against a panel of tumor target cells. These results suggest the coexistence of two types of antitumor cytotoxic lymphocytes at the tumor site: precursors of NK-like cells and specific cytotoxic T cells. Target cell specificity provided a means of distinguishing between the two types.     

Detection of double target binders at the single cell level: an evaluation of the specificity of NK and MLC-induced NK-like cells

MLC-generated cells were tested on 7 consecutive days in the single cell cytotoxicity assay to determine the kinetics of natural and allospecific killing. Maximum cytotoxicity to the NK-sensitive target, K562, was found on Day 3 of MLC with an increase at that time in both the number of cells binding and the number of cells killing K562. The maximum allospecific response was found on Days 6 and 7 with an increase in cells able to bind and kill the alloantigen-bearing target. To determine whether the anti-K562 and allospecific killing were mediated by the same effector cells or different cell populations, both targets were tested simultaneously in the single cell assay. At no time during the 7 days were cells detected capable of simultaneously binding both K562 and allospecific targets. These data indicate that there are two different cell populations responsible for allospecific cytotoxicity and MLC-induced NK-like cytotoxicity. The cytotoxic specificity of unstimulated and MLC-generated NK-like cells was also investigated. When two different NK-sensitive targets (e.g., K562 and MOLT-4) were tested together in the single cell assay, there was no concurrent binding of targets by either fresh PBL prior to MLC stimulation or Day 3 MLC-generated cells. When unstimulated effector cells were enriched for NK activity by Percoll density gradient centrifugation, only a small number of effector cells simultaneously binding two different NK-sensitive targets was detected in the single cell assay. These results imply that the NK cell population is heterogeneous and composed of subpopulations recognizing diverse target specificities.     

Interferon production and tumor cell killing by human lymphocytes stimulated in mixed-lymphocyte culture

The in vitro synthesis of interferon (IFN) by human lymphocytes stimulated in mixed-lymphocyte culture (MLC) was examined. The production of IFN in MLC was restricted to T lymphocytes and maximum levels of IFN were detected in supernatants from cells incubated for 5 to 7 days. The IFN produced was identified as IFN-gamma by antibody neutralization. To identify the T cell responsible for IFN production, purified T lymphocytes were separated into subpopulations after incubation in 5 mM theophylline. Theophylline-resistant (T-res) T cells retain the ability to form sheep erythrocyte (SRBC) rosettes and are depleted in IgG Fc receptor-positive T cells (T gamma cells). Theophylline-sensitive (T-sens) T cells fail to form rosettes after theophylline treatment and are enriched in T gamma cells. In addition, analyses using monoclonal antibodies showed that T-sens cells were enriched in OKM1-, HNK-1-, and 7.2-positive cells and T-res cells contained increased numbers of 9.6- and OKT4-positive cells. Following MLC stimulation, equivalent levels of IFN-gamma were produced by T-res and T-sens cells and both subpopulations maintained natural killer (NK)-like cytotoxicity against K562 target cells. Addition of partially purified IFN-gamma to unstimulated T-res and T-sens cells resulted in the maintenance of NK-like cytotoxicity in a manner analogous to that observed after MLC. Additional experiments indicated that peripheral blood lymphocytes depleted of 9.6- or OKM1-positive cells by complement-mediated lysis were devoid of cytotoxicity against K562 cells. Furthermore, MLC stimulation of 9.6- or OKM1-depleted cells failed to restore cytotoxic activity. In summary, these experiments demonstrate that the maintenance of NK-like cytotoxicity by MLC-stimulated T cells is associated with the synthesis of IFN-gamma, that MLC stimulated T-res and T-sens T-cell subsets produce equivalent amounts of IFN, and that 9.6- or OKM1-positive cells are required for the maintenance of NK-like cytotoxicity in MLC.     

Monoclonal antibodies against the NK cell-FcR and the T3-complex potentiate normal lymphocyte killing

Pretreatment of normal human lymphocytes with monoclonal IgG against the NK cell-FcR (IgG) or the T3 complex was found to potentiate killing of most NK sensitive target cells with the exception of T-cell derived cells. Anti-FcR IgM monoclonals were suppressive for all target cells. IgG anti-FcR mediated potentiation required minute amounts of antibody but was also seen at high anti-FcR concentrations that modulated FcR activity. Potentiated and FcR modulated cells retained anti-FcR IgG on the membrane and conjugated normally to target cells. Anti-FcR potentiation blocked antibody-dependent killing but did not influence lectin-dependent killing, with anti-T3 the opposed effect was seen. Combined anti-FcR and anti-T3 treatment resulted in decreased potentiation. The results suggest that the NK cell-FcR may be activated during normal NK cell killing (without the addition of antibody) as suggested for FcR in B cell triggering.     

Stimulation of human lymphocytes with irradiated cells of the autologous Epstein-Barr virus-transformed cell line. I. Virus-specific and nonspecific components of the cytotoxic response

Peripheral blood lymphocytes were cocultivated with irradiated cells of the autologous EB virus-transformed cell line at different responder:stimulator (R:S) ratios and the cytotoxic response was assayed up to 12 days later. In cocultures set up at a R:S ratio of 4:1, the response from both EB virus antibody-positive (seropositive) and negative donors was dominated by a broad-ranging NK-like cytotoxicity which did not segregate within the E-rosette-forming subpopulation of effector cells. In contrast, cocultures set up at a R:S ratio of 40:1 and harvested after 10 to 12 days gave rise, in the case of seropositive donors only, to effector T-cell preparations which appeared to be both EB virus specific and HLA-A and B antigen restricted. Strong lysis of the autologous virus-transformed cell line and demonstrable activity against certain allogeneic HLA-A and/or B antigen-related virus-transformed lines occurred in the absence of any significant killing either of the corresponding lines from HLA-unrelated donors or of a variety of EB virus genome-negative target cells (K562, HSB2, BJAB) particularly sensitive to NK-like cytotoxicity; furthermore, lysis of the autologous cell line by these effector T cells was specifically inhibited by monoclonal antibodies binding to HLA-A, B, and C antigens on the target cell surface. This work demonstrates that an HLA-restricted EB virus-specific cytotoxic T-cell response can indeed be induced in vitro by stimulation of fresh lymphocytes with autologous EB virus-transformed cells providing cocultures are set up at the correct R:S ratio.     

A comparison of murine hepatic accessory cells and splenic dendritic cells

Accessory cells are required for proliferation and antibody synthesis of B lymphocytes and proliferation of T lymphocytes in primary immune responses in vitro. The obligatory cells derived from the spleen are referred to as dendritic cells. Accessory cells were isolated from normal adult livers which were functionally interchangeable with splenic DC. Both hepatic accessory cells (AC) and splenic DC adhere firmly to plastic culture dishes or wells within 2 hr; but hepatic AC, unlike splenic DC, do not detach during 22 hr additional incubation. Hepatic AC, unlike splenic DC, are not lysed or inactivated by monoclonal antibody 33D1 and C'. Hepatic AC and splenic DC are similarly sensitive to irradiation in vivo and insensitive to irradiation in vitro. Hepatic AC are separated with cells which are predominantly phagocytic and FcR+ and contain nonspecific esterase. Both hepatic AC and splenic DC are suppressed or eliminated by activation of NK cells in vivo, a phenomenon prevented by prior elimination of NK cells.     

Differentiation of NK-like cells from OKT3-, OKT11+, and OKM1+ small resting lymphocytes by culture with autologous T cell blasts and lymphokine

NK-like cells have been generated in vitro from a resting lymphocyte population of PBMC by 8 days culture with mitomycin C-treated autologous T cell blasts and lymphokine. The responder lymphocyte population was purified to the extent that it lacked classical NK cells, and lacked the precursors of MLC-derived NK-like cells and of lymphokine-activated killer cells. The NK-like cells were not generated when the responder lymphocytes were cultured with either T cell blasts or lymphokine alone. Thus, at least two signals are required for their activation. Metabolically inactive T cell blasts plus lymphokine were effective in stimulating the generation of NK-like cells, suggesting that a membrane determinant on the T cell blasts was involved in activation. The phenotype of the NK-like cells and their precursors was analyzed by monoclonal antibody and complement treatment. The phenotype of both precursor and effector cells was OKT3-, OKT11+, and OKM1+, with a distinct pattern of reactivity with OKT8 and Leu-7 for each individual donor tested. The NK-like cells were morphologically large granular lymphocytes, and they killed a variety of target cells. These studies show that signals provided by autologous T cell blasts and lymphokine are essential in triggering the differentiation of NK-like cells from appropriately purified resting lymphocytes. This mechanism of activation could occur in vivo, leading to the generation of NK cells subsequent to an antigen-specific T cell response.     

Interleukin-2- and mitogen-activated NK-like killer cells from highly purified human peripheral blood T cell (CD3+ N901-) cultures

In this study, highly purified (HP) CD3-positive N901-negative T lymphocytes could be induced to become natural killer (NK)-like in culture in the presence of recombinant interleukin-2 (rIL-2) and phytohemagglutinin (PHA). Thus, purified CD3+ N901- T cells from fresh human peripheral blood were obtained by negative selection using an indirect panning technique. To ensure that T lymphocyte fractions were completely devoid of any detectable NK cells, two additional purification procedures were employed: incubation of post-pan T cells with the NK-cytotoxic lysomotropic agent L-leucinemethylester, and complement-mediated lysis using the NK cell specific NKH1a monoclonal antibody. Purity of CD3+ N901- cells could be confirmed by surface marker analysis, whereby two NK-associated antigens, N901 and H-25, were undetectable, while 94 +/- 1% of cells expressed the CD3 (Leu-4) antigen. On functional analysis, fresh HP CD3+ N901- cells exhibited no cytotoxic activity against the standard NK target K562. When HP NK-depleted T lymphocytes were cultured for 7 days in the presence of rIL-2 (100 U/ml), neither surface antigen expression nor cytotoxic activity against K562 changed significantly. However, significant cytotoxicity against K562 [18 +/- 5% specific lysis at 25:1 effector:target (E/T) ratio] could be induced when HP CD3+ N901- cells were grown for 7 days in the presence of rIL-2 and PHA (0.5% v/v). Concomitantly, antigens N901 and H-25 were found to be coexpressed on a minor proportion (22 +/- 16 and 22 +/- 6%, respectively) of CD3+ (88 +/- 2% on day 7) cells. Four-week long-term culture of HP NK-depleted T cells in the presence of rIL-2 and PHA yielded a continuous increase in cytotoxicity against K562 cells (0 up to 46% specific lysis at 25:1 E/T ratio). Of particular interest was the emergence of cytotoxicity against the NK-resistant Daudi cell target (15 +/- 8% specific lysis at 25:1 E/T ratio on day 21). Expression of antigens N901 and H-25 as well as CD3 remained essentially unchanged in long-term culture. In sorting experiments, the H-25+ cell fraction was significantly enriched for cytotoxicity against K562, when compared to both H-25- and unseparated cell fractions. In summary, our results suggest that a proportion of HP CD3+ N901- T lymphocytes may give rise to cells that exhibit NK-like functional and phenotypic properties.     

A novel type of human T cell clone with highly potent natural killer-like cytotoxicity divorced from large granular lymphocyte morphology

Interleukin 2-dependent cloned lymphocytes derived from an allogeneic HLA class II-mismatched but class I-matched mixed lymphocyte culture were screened for cytotoxic activity on target cell lines known to be susceptible or resistant to lysis by natural killer (NK) cells. Of 24 clones, eight were found to display NK-like cytotoxicity. Two manifested extremely high cytotoxicity levels (50% lysis of K562 at an effector to target ratio of 1:1), whereas the remainder were only moderately active (about 20% lysis at 25:1). NK-like clones were studied with regard to cell surface markers defined by monoclonal antibodies, as well as for their morphologic and cytochemical characteristics, and were compared with clones displaying different functions. The moderately active NK-like clones exhibited characteristic large granular lymphocyte morphology (many azurophilic granules, indented nuclei, high cytoplasm to nucleus ratio, and a basophilic peripheral cytoplasmic zone). This was, however, also characteristic of the majority of lymphocyte clones displaying functions other than NK. Surprisingly, the two clones with high NK-like activity did not exhibit large granular lymphocyte morphology, with few granules, round nuclei, and low cytoplasm to nucleus ratio. The T3, T9, T10, and T11 markers, as well as HLA-DR determinants, were expressed on their surfaces, but in contrast to the other clones, they did not display OKT4-, OKT8-, or OKM1-defined antigens. No distinction between them was possible on the basis of a cytochemical profile in relation to their function, because all clones were positive for acid phosphatase, either focal or dispersed and negative for nonspecific esterase or chloracetate esterase. The highly active lytic clones were, however, distinguished by an exceptionally rapid growth rate in culture (cell doubling time: 9 hr as compared to 30 to 40 hr, as usually required). These results demonstrate two different types of human NK-active lymphocytes with remarkably disparate lytic capacity, cell surface markers, and morphology.     

Distinction of anti-K562 and anti-allocytotoxicity in in vitro-stimulated populations of human lymphocytes.

The properties of lymphocytes cultivated with K562 (MKC)—a cell line which lacks HLA antigens and is sensitive to natural cytotoxicity—was compared to conventional mixed lymphocyte cultures (MLC). The characteristics of the two cultures differed. In the MKC there were fewer E positive blasts and more FcR-positive cells, and a higher proportion of the T cells was nylon adherent. The cells of both cultures were cytotoxic against K562. Against the sensitizer alloblasts, MLC populations were regularly more active than lymphocytes derived from the same donor but cultivated with K562. As indicated by the relative cytotoxic efficiencies of MLC subsets, part of the the killer cells affecting K562 and alloblasts differed in the expression of E receptors. Acting similarly to natural killers in the fresh blood, anti-K562 effectors were more abundant in the subsets which did not sediment as SRBC rosettes. In contrast, the specific alloreactivity was more pronounced with the SRBC-rosetting cells.     

Effect of rabbit anti-asialo GM1 treatment in vivo or with anti-asialo GM1 plus complement in vitro on cytotoxic T cell activities

The susceptibility of cytotoxic effector lymphocytes and their induction to in vivo or in vitro treatment with rabbit anti-neutral glycolipid ganglio-N-tetraosylceramide (anti-ASGM1) antiserum was investigated. Intravenous injection of anti-ASGM1 antiserum eliminated measurable natural killer (NK) cell activity in spleen cells of mice infected for 5 days with Vaccinia virus, or for 8 days with lymphocytic choriomeningitis virus (LCMV) if injected 24 hr prior to testing. In addition, this treatment lowered measurable virus-specific cytotoxic T cell activity by 60 to 95%. Virus-specific cytotoxic T cell and NK cell activity generated during a primary infection in vivo was also sensitive to treatment in vitro with anti-ASGM1 antiserum (1/300 to 1/600 dilution) plus rabbit complement at a dilution of 1/15 (20 to 50% cell death, more than 30-fold decrease of cytotoxic activity); in vitro treatment with rabbit complement alone often enhanced NK and cytotoxic T cell activity slightly. In vivo treatment with anti-ASGM1 before primary immunization decreased generation of primary CTL only if high doses of anti-ASGM1 antiserum were injected twice. Antiviral T cells generated during secondary stimulation in vitro and alloreactive cytotoxic T cells from a mixed lymphocyte culture were resistant to treatment in vitro with anti-ASGM1 plus complement at the end of the culture period. Treatment in vitro of in vivo-primed responder spleen cells with anti-ASGM1 plus complement before their addition to a secondary restimulation culture resulted in complete inhibition of a secondary antiviral cytotoxic T cell response. In vivo treatment with anti-ASGM1 24 hr before their spleen cells were harvested and restimulated in vitro significantly reduced the virus-specific T cell activity of mice that had been immunized with virus several weeks previously. A cloned T cell line exclusively exerting NK-like activity was resistant, and two cloned virus-specific cytotoxic T cell lines were susceptible to treatment with anti-ASGM1 plus complement in vitro. These results caution the general use of rabbit anti-ASGM1 as a marker to distinguish NK from CTL cells; they indicate a possible relationship between NK and CTL cells and suggest that in vitro culture of lymphocytes may alter or select the cell surface expression or availability of the ASGM1 marker(s).     

Fucose-activated killer (FAK) cells: anomalous killers with augmented cytotoxic activity

The effects of monosaccharides on various lymphocyte functions have provided useful probes for the study of cell-cell interactions. In this report, we show that a monosaccharide, alpha-L-fucose, significantly enhances the cytolytic capacity of MLC-induced or preincubated effector cells. The increase in activity was seen against cytotoxic T lymphocyte (CTL) targets (:relevant PHA blasts), natural killer cell (NK) targets (:K562), and natural cytotoxic cell (NC) targets (:MA-160). In addition, traditionally NK-insensitive targets (Raji cells, irrelevant and autologous PHA blasts) were lysed after preincubation of effector cells with fucose. Conversely, ADCC activity was not significantly increased with fucose induction. The addition of fucose directly to assay cultures did not enhance NK or CTL activity, whereas other sugars, such as alpha-methyl-D-mannoside and D-fructose, were inhibitory. The proportion of target-binding cells was not affected by preincubation with fucose, but the percentage of lytic conjugates was doubled. Significant augmentation of NK activity could be observed within 24 hr of incubation with alpha-L-fucose. Conversely, when fucose was added more than 24 hr after initiation of the culture, the increase in cytolytic activity was not observed. Parallel to the increase in cytolytic activity, after preincubation with alpha-L-fucose, an increase in the expression of a newly defined human NC cell marker, HNC-1A3, was observed. The HNC-1A3+ cells were not the major subpopulation responsible for fucose-induced activity, as ascertained by the use of positively sorted cells. The populations expressing antigens defined by the antibodies OKT8 and Leu-7 showed no quantitative change. The treatment of cells with OKM1 and complement (C) before culture eliminated fucose-enhanced killing, whereas similar treatment with OKT8 and C had no significant effect. The induction of fucose-activated killers (FAK) does not result in higher concentrations of interferon (IFN) in culture supernatants, in contrast to poly I:C, which induced both higher cytolytic activity and high titers of IFN. In addition, the induction of FAK was not sensitive to 100 ng/ml of cyclosporin A, suggesting that IL 2 did not play a major role in fucose activation of killing. These results provide strong evidence that alpha-L-fucose is capable of augmenting nonspecific activity by acting on OKM1+ precursors of cytotoxic cells and influencing a postbinding event.