Studies on the lethal hit stage of natural killer cell-mediated cytotoxicity. I. Both phorbol ester and ionophore are required for release of natural killer cytotoxic factors (NKCF), suggesting a role for protein kinase C activity

Previous studies in our laboratory on the natural killer (NK) lytic mechanism demonstrated that following interaction of target cell with effector cell, the effector cell releases NK cytotoxic factors (NKCF) that can then bind to and lyse the target cell. This study investigates the mechanism by which the target cell signals the effector cell to release NKCF. Studies on other cell systems with secretory functions have indicated that receptor-induced transmembrane signaling leads to the metabolism of phosphatidylinositol and activation of protein kinase C (PKC) by increased cytosolic Ca++ and diacylglycerol (DAG). We tested the hypothesis that a similar sequence of activation events occurs in human NK cells by examining the phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), and the calcium ionophores A23187 and ionomycin in their ability to induce release of NKCF. The amount of NKCF released was determined in a 20-hr 51Cr release assay against an NK-sensitive target cell. A23187, ionomycin, or TPA alone did not induce release of NKCF. However, ionophores (200 mM) in conjunction with TPA (20 ng/ml) induced release of NKCF. Several properties of the induced NKCF by TPA and ionophores were concordant with those of the NK cell-mediated cytotoxicity (CMC) reaction. The kinetics of release were faster (less than 1 hr) than when either Con A or target cells were used to stimulate NKCF. Only NK-sensitive target cells were killed by NKCF. Pretreatment of effector cells with interferon enhanced release of NKCF from effector cells. Several lines of evidence suggested that the pathway of activation takes place through phosphatidyl inositol metabolism. Activation of PKC was indicated because TPA and A23187 enhanced protein phosphorylation in the LGL-enriched fraction. Experiments that made use of oleoyl acetyl glycerol, a synthetic DAG, showed release of NKCF in the absence of A23187 but was augmented by the ionophore. The above studies suggest that NKCF is released from NK effector cells within a period of time consistent with NK CMC, and the release of NKCF results either directly or indirectly from protein phosphorylation by PKC.     

Phorbolester-treated human lymphocytes are susceptible to natural killer cell-mediated cytolysis

The tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) was found in this study to render normal human lymphocytes susceptible to allogeneic and autologous natural killer (NK) cell lysis. Both T and non-T cells became susceptible after culture for 3 days in the presence of 1 ng/ml TPA. Effector cells were nonadherent mononuclear cells of low density, enriched for large granular lymphocytes and HNK-1+ cells. Activation of effector cells with interferon increased lysis of TPA-treated lymphocytes. The present system may provide a new model to study NK cell target structures.     

Phosphoinositide breakdown and evidence for protein kinase C involvement during human NK killing

Conjugation between human NK cells and susceptible target cells (K562 and Jurkat) leads to breakdown of inositol lipids in the effector cells but not when conjugated with resistant target cells. Extracellular Ca2+ is required for this activation. Sphingosine inhibits NK killing in both normal and IL-2-activated NK cells. Phorbol esters, TPA, and PDBU enhanced NK killing at low concentrations, where 4-alpha-PDIDE did not. The diacylglycerol derivative OAG increased NK cell killing and activated PKC from human lymphocytes. These results strongly suggest that phosphoinositide breakdown and activation of PKC is involved in NK killing.     

Inhibition of human antibody-dependent cellular cytotoxicity, cell-mediated cytotoxicity, and natural killing by a xenogeneic antiserum prepared against "activated" alloimmune human lymphocytes

Xenogeneic antiserum (RH1) was prepared in Lewis rats by hyperimmunization with concanavalin A- (Con A) activated alloimmune human lymphocytes. The antiserum RH1 effectively inhibited human antibody-dependent cellular cytotoxicity (ADCC), cell-mediated cytotoxicity (CMC), and natural killing (NK) in the absence of complement (C). Inhibition by RH1 was dependent on the dilution of antiserum employed and the number of cytotoxic lymphocytes present during cytolysis. Pretreatment of lymphocytes with RH1 or the presence of RH1 in culture did not inhibit lymphocyte proliferation stimulated by Con A, phytohemagglutinin, or allogeneic cells; lymphokine production as measured by leukocyte-inhibiting factor production; antibody-dependent C lysis; or CMC mediated by murine cytotoxic T lymphocytes. Analysis of the mechanism of inhibition of cytotoxicity by RH1 revealed that 1) RH1 was not cytotoxic for human lymphocytes at 37 degrees C in the absence of C; 2) purified F(ab')2 fragments were equally inhibitory as whole serum; 3) pretreatment of lymphocytes with RH1 effectively inhibited their capacity to mediate ADCC, CMC, or NK, and this effect was reversible by culturing the cells overnight at 37 degrees C; 4) RH1 did not inhibit target cell binding by K cells, effector cells of ADCC, or alloimmune T cells, but did inhibit binding by NK cells; and finally, 5) the addition of RH1 to preformed lymphocyte-target conjugates in a single cell cytotoxicity assay inhibited killing of the bound target cells in all three systems without disrupting the conjugates. Collectively, these findings suggest that RH1 antiserum interacts with structures present on the surfaces of cytotoxic lymphocytes that are involved in the activation of the lytic mechanism(s) or with the actual lytic molecule or molecules themselves. Furthermore, the ability of RH1 to inhibit ADCC, CMC, and NK during the post-binding cytolytic phase of these reactions indicates that binding and cytolysis are distinct and separate events in all types of cell-mediated cytolysis.     

The role of apoptosis in antibody-dependent cellular cytotoxicity

Apoptosis in three lymphoma cell lines has been studied following cytotoxicity induced in vitro by normal human blood lymphocytes utilizing either natural killer (NK) or antibody-dependent cellular cytotoxic (ADCC) mechanisms. Guinea-pig L₂C leukaemic lymphocytes, but not the human cell lines Daudi and Jurkat, revealed a degree of time- and temperature-dependent apoptotic death upon simple culture in vitro. NK cytotoxicity at low effector: target ratios (E: T) induced both release of⁵¹Cr and apoptosis. However NK cytotoxicity at higher E : T, and ADCC at all E : T, increased the level of⁵¹Cr release while reducing the level of apoptosis. The findings were consistent with the apoptotic process being cut short by intervention of necrotic death. The same characteristics accompanied ADCC whether the effectors were recruited by Fc regions of antibody coating the targets, or by bispecific antibodies attaching one arm to the targets and the other to Fc receptors type III on effectors. This finding, and the high level of cytotoxicity elicited by the bispecific method, confirm the belief that NK cells, in addition to exerting NK cytotoxicity, represent the principal effectors for ADCC among blood mononuclear cells. Our results suggest that NK cells have both apoptotic and necrotic mechanisms available for killing their targets, but use only the latter for ADCC.     

Feline cytotoxic immune mechanisms against virus-associated leukemia and fibrosarcoma

Humoral and cellular cytotoxic immune mechanisms of cats were compared against feline leukemia virus (FeLV)- and feline sarcoma virus (FeSV)-transformed cells. The groups of animals studied were nonexposed control cats; FeLV-infected immune or viremic tumor-bearing cats; FeSV-inoculated tumor progressor or regressor cats, and cats immunized with FeSV-transformed autochthonous fibroblasts (ATF). Sera containing complement-dependent antibodies (CDA), which lysed FeLV-producer lymphoma lines, had no cytotoxic effects when tested against FeLV-producer FeSV-transformed fibroblasts. Sera with lytic CDA activity were also tested for antibody-dependent cellular cytotoxic (ADCC) effects with peripheral blood lymphocytes (PBL) from nonimmune cats. No ADCC activity was detected against either lymphoid or fibroblast target lines. To demonstrate that cat PBL contained ADCC effector cells, antibody-coated murine target cells were employed and positive results obtained. Natural killer (NK) assays were performed using PBL from normal and tumor-bearing cats. Cytotoxic effects were only detectable to FeLV-producer lymphomas, and comparable levels of NK activity were found in normal and lymphoid tumor-bearing animals. In cats immunized with ATF, a population of effector cells was found in peripheral blood which had functional characteristics of cytotoxic T lymphocytes (CTL). The killing of ATF by CTL-like cells was not inhibited by FeLV/FeSV immune sera or by sera from autochthonous immune cats. The comparative importance of humoral and cellular cytotoxic mechanisms against FeLV- and FeSV-induced tumors is discussed.     

Characterization of a monoclonal antibody enhancing porcine natural killer cell activity (PNK-E)

A monoclonal antibody, termed PNK-E, that functionally enhances porcine natural killer (NK) cell activity but not antibody-dependent cellular cytotoxicity (ADCC) is investigated in this report. When PNK-E and K562 target cells were simultaneously added to effector cells, killing of target cells could be detected as early as 30 min, and a dramatic enhancement of killing activity was observed in short term 51Cr-release assays. When a panel of five NK-sensitive targets were tested, PNK-E enhanced the killing of K562, MOLT-4, and U937 cells, but not the killing of CEM and YAC-1. F(ab)'2 fragments of PNK-E did not enhance NK activity, indicating a requirement for the Fc portion of PNK-E to elicit enhancement of NK. Immunofluorescence analysis shows that PNK-E antigen is expressed on approximately 15% of peripheral blood lymphocytes with a relatively dull fluorescence staining pattern. PNK-E-positive sorted cells were enriched for large granular lymphocytes (LGL) and contained all detectable NK activity as compared to the PNK-E-negative sorted cells. When analyzed by polyacrylamide gel electrophoresis, PNK-E antibody immunoprecipitated a protein from 125I-labeled peripheral blood lymphocyte (PBL) cell lysates that resolved as a single band of approximately 205 kDa under nonreducing conditions and as two bands of approximately 50 kDa and 47 kDa under reducing conditions. The present data demonstrate a functional association between PNK-E antigen and NK cell activation.     

K562 cells induced to differentiate by phorbol ester tumor promotors resist NK lysis

The effect of various phorbols and phorbol diesters on the NK sensitivity of the human leukemic K562 cells was studied. A marked decrease in K562 cell susceptibility was achieved by culture in the presence of either 12-O-tetradecanoyl-phorbol-13-acetate (TPA) or beta-phorbol-dibutyrate. The maximum protection against NK lysis was achieved when K562 cells were cultured in the presence of 160 nM TPA for 48 hr (mean percentage inhibition: 61% of specific lysis). As for untreated targets, the residual killing of K562 cells after TPA treatment was mediated through large granular lymphocytes (LGL). The experimental procedures required to achieve maximal NK protection with TPA resulted simultaneously in marked phenotypical changes in K562 cells: erythroid and early myeloid markers decreased, whereas the expression of megakaryocytic markers was increased as shown by staining with antiplatelet monoclonal antibodies and assessment of platelet peroxidase activity. Chemical phorbol analogs which were unable to induce K562 cell differentiation did not affect K562 cell sensitivity to NK lysis. De novo protein synthesis is involved in the TPA-induced NK resistance, since this effect was abolished by pretreatment of K562 cells with actinomycin D or cycloheximide. TPA has been previously demonstrated to reduce NK effector activity. In our data however, the observed TPA effects were not due to release of TPA acting on effector cells during the NK assay since TPA-treated K562 cell supernatants were unable to inhibit NK activity in control assays. Thus, TPA appears to decrease NK killing of malignant cells, both by depressing NK effector cells functions and by reducing the susceptibility to NK lysis of the target cells. In single-cell agarose assays, TPA-treated K562 cells demonstrated reduced NK-binding capacity and reduced sensitivity to lysis after binding. These defects could not be reversed by activation of the NK effector cells with interferon. The results here reported extend the previously suggested relations between the expression of NK-target structures and the differentiation stage of malignant cells.     

Mechanism of cell-mediated cytotoxicity at the single cell level. VI. Direct assessment of the cytotoxic potential of human peripheral blood non-lytic effector-target cell conjugates

Single cell cytotoxicity assays reveal that a large percentage of lymphocytes are unable to kill attached targets in a 4- to 18-hr assay. Additional signals (in the form of lectin or anti-target antibody) delivered to target-bound lymphocytes enable these previously non-lytic lymphocytes to kill attached target cells. This finding was obtained by using a modification of the single cell assay, in which lectin or target cell antibody is incorporated into agarose with preformed lymphocyte-target conjugates. Human peripheral blood lymphocytes (PBL) or Percoll density gradient-enriched large granular lymphocytes (LGL) were used as effector cells in natural killer (NK), antibody-dependent cellular cytotoxicity (LDCC) assay systems. The targets used were NK-sensitive K562 and Molt-4 and NK-insensitive Raji. Several findings were made in the modified single cell assay, namely a) the frequency of cytotoxic NK or ADCC effector cells was not augmented, suggesting that the initial trigger was sufficient for lytic expression in these instances. Furthermore, these results showed that the NK-sensitive targets used do not bind nonspecifically to the LDCC effector cells. K562 coated with Con A, however, serve as LDCC targets. b) The frequency of two target conjugate lysis by NK/K effectors was not augmented by Con A. These results suggest that Con A does not potentiate the killing of multiple targets bound to a single cytotoxic lymphocyte. c) Although conjugates formed between LGL or PBL and NK-insensitive Raji are non-lethal, significant lysis was observed when these conjugates were suspended in Con A or antibody agarose. These results demonstrate that Raji bind to cytotoxic NK, K, and LDCC effector cells, but are lysed only when the appropriate trigger is provided. d) The cytotoxic potential of non-lytic conjugates appears to lie within the low density Percoll fraction, although the high density lymphocytes are able to nonlethally bind to targets. Altogether the results demonstrate that target recognition and/or binding by the effector cells is a distinct event from the trigger or lytic process. The implications of these findings are discussed.     

Anti-idiotype antibodies to the 9.1C3 blocking antibody used to probe the lethal hit stage of NK cell-mediated cytolysis

We previously described a monoclonal antibody, 9.1C3, which blocked natural killer (NK) cell-mediated cytolysis by acting on effector cells during a late step in the lethal hit stage. The present work describes the production in rabbits of anti-idiotypic (anti-id) antibodies to the 9.1C3 antibody. In addition to reacting specifically with the 9.1C3 antibody, the anti-id antibodies bound strongly to the K562 target cell. The anti-id antibodies blocked killing of K562 targets by NK, antibody-dependent cellular cytotoxicity, and NK-like cells but did not inhibit killing by cytotoxic T lymphocytes (CTL). Pretreatment of cells and washing before assay indicated that blocking occurred at the target cell level. Of particular interest, single cell assays with Percoll-enriched large granular lymphocytes demonstrated that the antibodies caused no reduction in binding. These data are consistent with a model for NK cell-mediated lysis that involves a secondary target cell receptor independent of the primary NK-target cell interaction. The anti-id antibodies immunoprecipitated cell surface proteins of relative m.w. 79K and 62K unreduced, and 94K and 79K reduced from K562 target cells. The development of anti-id antibodies may be a useful procedure to explore the structure and function of cellular receptors involved in NK cell-mediated cytolysis.     

Tyrosine phosphorylation of the Fc gamma RIII(CD16): zeta complex in human natural killer cells. Induction by antibody-dependent cytotoxicity but not by natural killing.

NK cells are large granular lymphocytes capable of killing certain tumor cells and virally infected cells in a non-MHC-restricted manner. NK cells can also effect an antibody dependent cytotoxicity that is triggered by CD16, an FcR for IgG. In NK cells, CD16 is expressed in association with zeta, a signal transducing subunit of the TCR complex. Here we show that, just as T cell activation via the TCR complex results in tyrosine phosphorylation of zeta TCR, NK cell activation via CD16 results in tyrosine phosphorylation of zeta NK. Whereas antibody-dependent cytotoxicity also results in tyrosine phosphorylation of zeta, natural cytotoxicity does not. Our results indicate that zeta functions as a transducing element for antibody dependent, but not antibody independent killing by NK cells. Consequently, NK cells are likely to express at least two distinct receptor complexes capable of triggering cytolytic effector function.     

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.     

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)     

Mechanism of cell-mediated cytotoxicity at the single-cell level: VII. Trigger of the lethal hit event is distinct for NK/K and LDCC effector cells as measured in the two-target conjugate assay

Normal human peripheral blood lymphocytes (PBL) express several in vitro cytotoxic functions, among which are natural killer (NK), antibody-dependent cellular cytotoxicity (ADCC), and lectin-dependent cellular cytotoxicity (LDCC). The relationship of these various cytotoxic functions and the identity of cells involved has been a subject of controversy. Recently it was reported that NK and K for ADCC can be mediated by the same cell, suggesting that they constitute in large part a single subpopulation with multiple cytotoxic functions. The ability of this NK/K effector cell to mediate LDCC was examined here using the two target conjugate assay. The effector cells were Ficoll-Hypaque PBL or LGL-enriched fractions. The targets used were K562 or MOLT for NK, RAJI coated with antibody for ADCC, and RAJI coated with PHA or Con A or modified by NaIO₄ for LDCC. In the two-target conjugate assay, one of the targets is fluorescein labeled for identification. The results show that (a) LDCC copurifies with NK/K and is enriched in the LGL fraction, as measured in both the ⁵¹Cr-release assay and the single-cell assay for cytotoxicity; (b) single effector cells simultaneously bind to NK or ADCC and LDCC targets, revealing that single cells bear binding receptors for all targets; and (c) single lymphocytes were not able to kill both bound NK/K and LDCC targets. However, significant two-target killing was obtained when both targets were NK targets, ADCC targets, LDCC targets, or one NK and one ADCC target. These results demonstrate that the NK and LDCC effector cells are distinct subpopulations copurified in the LGL fraction. In addition, the results show that lectin is unable to trigger globally an NK effector cell to mediate cytotoxicity against a bound NK insensitive target. Thus, although both NK and LDCC effector cells are present in the LGL fraction and can bind to both types of targets, the trigger of the lethal hit event is the function of specialized effector cells.     

Enhanced lytic susceptibility of Ha-ras transformants after oncogene induction is specific to activated NK cells

C3H 10T1/2 mouse fibroblasts were transfected with a plasmid vector composed of EJ, the mutated c-Ha-ras, and a metallothionein promotor that induced amplified ras expression when activated by culture in the presence of zinc. Experiments were conducted to compare the effect of induction on killing by activated natural killer (NK) cells, cytotoxic T lymphocytes, activated macrophages, and antibody plus complement. The only effector that recognized increased ras expression and exhibited high-inducible cytolysis was an activated NK cell. The effectors from spleen were poly I.C. boostable, Lyt-1.1 negative, NK 1.2 positive, and asialo GM1 positive. Spleen cells from T cell-deficient nude mice, but not NK-deficient beige mice, exhibited high levels of killing activity, and experiments with NK cell clones demonstrated that these lines were also highly cytolytic and killed Ha-ras transfectants in parallel to YAC. Transfection of the same fibroblast line with c-myc did not alter the level of activated NK sensitivity. Cold target competition experiments revealed that Ha-ras-transfected and non-transfected 10T1/2 fibroblasts competed equally for lysis of either YAC or Ha-ras transfectants. Rat-1 fibroblasts did not compete, but gained this capacity when transformed with the v-Ki-ras oncogene but not v-fps. These data suggest that Ha-ras acts in target cells at a post-binding step, whereas Ki-ras may affect expression of target-effector binding structures. The findings that activated NK cell lysis may be specifically influenced by ras expression support a role for NK cells in host surveillance against early neoplastic changes.     

Decay-accelerating factor expression on either effector or target cells inhibits cytotoxicity by human natural killer cells.

Previous studies have shown that freshly isolated CD16+ NK cells are deficient in the expression of decay-accelerating factor (DAF), or CD55, a membrane regulator of C3 activation. In this study we investigated the significance, for NK cell-mediated lysis, of DAF expression on the target and effector cells. The effect of DAF expression on the susceptibility of NK cell targets was investigated by several means: first, DAF- cell lines were cloned from K562; second, the cloned DAF- cells were reconstituted with exogenous purified DAF; and third, anti-DAF F(ab')2 was used to block DAF function on the DAF+ K562 cells. Consistently, the presence of DAF in the target cell membrane, either naturally occurring or experimentally incorporated, afforded the target cell protection against lysis, and this protection could be blocked with anti-DAF. Similarly, targets for antibody-dependent cell-mediated cytotoxicity with exogenous DAF incorporated in their plasma membrane became less sensitive to antibody-dependent cell-mediated cytotoxicity by NK cells compared with the same target cells without incorporated DAF in their membranes. DAF incorporated in the plasma membranes of the effector NK cells made the NK cells less effective at killing K562 targets. The known function of DAF is to regulate C3 activation, and we were able to demonstrate that the isolated NK cell is capable of releasing C3. It is also possible that the participation of DAF in NK cell function represents a new, noncomplement-dependent function for DAF.     

Depletion of NK by cellular immunoadsorption.

The binding of human natural killer (NK) cells to their tumor cell targets was investigated by using monolayers of sensitive target cell lines. Monolayers of K562 and HSB, a myeloid and T cell line, respectively, were prepared on poly-L-lysine-coated plastic tissue culture dishes and briefly fixed with 0.2% formaldehyde. Freshly isolated peripheral blood lymphocytes (PBL) were incubated on the monolayers. Nonadherent PBL were then removed, after gentle agitation, by decanting and gently washing the monolayer. They were tested, along with unseparated controls, for NK activity in a short-term 51Cr release assay. PBL that were nonadherent to a tested monolayer had only 20 to 60% of the control cytotoxic activity. Our results suggest that NK recognition sites on the effector lymphocytes were able to interact with reciprocal determinants on the target cell monolayers, resulting in selective loss of NK effector cells from the PBL population. The specificity of the NK effector-target interaction was investigated by testing the ability of each monolayer to remove activity against both targets. These data imply heterogeneity with regard to recognition structure within the NK effector population as well as among the target cells.     

Phorbol diester enhances calcium ionophore A23187-induced [3H]acetate incorporation into platelet-activating factor in murine macrophages: predominant incorporation into 1-O-acyl-2-acetyl-sn-glycero-3-phosphocholine

Pretreatment of macrophages with 12-O-tetradecanoylphorbol-13-acetate (TPA) has been shown to enhance the release of arachidonic acid from cell phospholipids in response to agonist stimulation. This study describes the ability of TPA to also alter calcium ionophore A23187-induced incorporation of [3H]acetate into platelet activating factor (PAF). Cultured murine peritoneal macrophages were preincubated with [3H]acetate (25 muCi) and TPA (10 ng/ml) for 10 min, and subsequently incubated with 0.1 microM A23187 for 0.5-10 min. Buffer and cells were then extracted and PAF resolved by normal-phase HPLC. Sequential exposure to TPA and A23187 resulted in a greatly enhanced incorporation (11,861 dpm/10(6) cells) of [3H]acetate into PAF compared to TPA alone, which did not significantly influence [3H]acetate incorporation into PAF, and 0.1 microM A23187, which induced minimal incorporation (688 dpm/10(6) cells). Macrophage-produced [3H]PAF was resolved by HPLC, extracted, treated with phospholipase-C, and acetylated to facilitate quantitation of 1-O-alkyl-2-acetyl-GPC (PAF) from 1-O-acyl-2-acetyl-GPC (acylPAF). A23187 alone (1 microM) produced 72% 1-O-acyl-2-[3H]acetyl-GPC, and A23187 (0.1 microM) following TPA pretreatment produced 81% 1-O-acyl-2-[3H]acetyl-GPC. Less than 2% of the radioactivity of acylPAF was in the acyl moiety. These data support a role for protein kinase C in modulating agonist-induced PAF synthesis. The results also suggest that acetyltransferase of murine macrophages does not possess specificity for 1-O-alkyl-2-lyso-GPC, and that availability of specific species of lyso-phospholipid may determine the type of PAF produced.     

Differences in target cell DNA fragmentation induced by mouse cytotoxic T lymphocytes and natural killer cells

Fragmentation of YAC-1 target cell DNA during cytolysis mediated by mouse natural killer (NK) cells and cytotoxic T lymphocytes (CTL) was compared. Cleavage of nuclear chromatin was always an extensive and early event in CTL-mediated cytolysis, whereas with NK cell-mediated killing the degree of DNA fragmentation showed an unexpected relationship to the effector:target (E:T) ratio. At low NK:YAC-1 ratios, DNA fragmentation and 51Cr release were equivalent and increased proportionately until a ratio of about 50:1 was reached; at higher ratios, 51Cr release increased as expected but DNA fragmentation decreased dramatically. Comparison of time course data at E:T ratios producing similar rates of 51Cr release showed that the target cell DNA fragmentation observed in NK killing was not nearly as rapid nor as extensive as that observed with CTL effectors. These results suggest that NK cells induce target cell injury via two different mechanisms. One mechanism would involve lysis mediated by cell-to-cell contact, while the other may induce DNA fragmentation via a soluble mediator. In support of this notion, cell-free culture supernatants containing NK cytotoxic factor (NKCF) induced DNA fragmentation in YAC-1 cells. The DNA fragments induced by NK cells and NKCF-containing supernatants consisted of oligonucleosomes indistinguishable from those induced by CTL. The results presented here show distinct differences in target cell DNA fragmentation induced by CTL and NK cells, and suggest that these two effectors use different mechanisms to achieve the same end. CTL seem to induce DNA fragmentation in their targets by direct signaling, whereas NK cells may do so by means of a soluble factor.     

Normal hematopoietic progenitor cells and malignant lymphohematopoietic cells show different susceptibility to direct cell-mediated MHC-non-restricted lysis by T cell receptor-/CD3-, T cell receptor gamma delta+/CD3+ and T cell receptor-alpha beta+/CD3+ lymphocytes

To evaluate the capability of NK cells and cytotoxic T lymphocytes to interact with normal hematopoietic progenitor cells (HPC), as compared to neoplastic lymphohematopoietic cells, we investigated inhibition of colony growth of these cell populations in semi-solid culture systems, after incubation with cloned cytotoxic effector cells. Three different types of cloned effector cells were investigated: TCR-/CD3- NK cells, TCR-gamma delta+/CD3+ cells, and TCR-alpha beta+/CD3+ cytotoxic T lymphocytes. Effector cells showed differential levels of tumor cell colony inhibition, but no MHC-non-restricted lysis of normal HPC was observed. Pre-stimulation of normal HPC by culturing on established stromal layers had no effect. Cell-mediated lysis of HPC only occurred by Ag-specific MHC-restricted lysis by CTL, or by antibody-dependent cellular cytotoxicity. In cell mixing experiments, irradiated tumor cells, but not normal bone marrow cells inhibited tumor cell lysis. Furthermore, cloned effector lymphocytes were able to specifically eliminate malignant cells from tumor contaminated bone marrow without damaging normal HPC. When fresh leukemic cells were used as targets, growth of acute myeloblastic leukemia colonies was inhibited after incubation with several cytotoxic effector clones, whereas chronic myeloid leukemia precursor cells showed limited sensitivity to MHC-non-restricted cytolysis. These results indicate that MHC-non-restricted cytolysis by NK cells is selectively directed against neoplastic cells and not against normal HPC.