In vivo and in vitro induction of natural killer cells by cloned human tumor necrosis factor

Summary The natural killer (NK) cell activity of mice in the peritoneal cavity is very low or undetectable and testing peritoneal NK cells is a useful model for studying the influence of activating substances upon local injection. Injection of tumor necrosis factor (TNF) at doses of 10–200 ng caused a marked activation of NK cell activity which was maximal after 24 h and declined rapidly on day 2. A similar effect was observed when interferons alpha and beta were injected, and there were additive results when interferon was injected together with TNF. The NK cell nature of the effector cells activated by TNF was substantiated by the finding that previous injection with anti-asialo GM 1 antibody prevented activation. Interferon could not be detected in the peritoneal wash fluid after injection of TNF suggesting interferon-independent activation. In further experiments after i.p. injection of TNF peritoneal exudate cells (PECs) only killed YAC-1 targets in a 4-h assay. There was no additional killing in an 18-h assay towards neither YAC-1 cells or P815 cells, suggesting that macrophages were not involved. Furthermore TNF was also active in vitro by activating NK cells in isolated human peripheral blood cells. However in the PECs stimulated in vitro no significant induction of cytotoxic capacities by TNF was measured. Our data suggest that the action of TNF is not restricted to the lysis of tumor cells but can also induce immunological properties in the host defense against virus infections and neoplasms.     

Role of interferon in natural kill of HSV-1-infected fibroblasts

The production of interferon during natural killer (NK) assays against HSV-1-infected fibroblasts (NK(HSV-1)) was studied to determine whether this interferon was responsible for inducing the preferential lysis of herpes-virus-infected target cells over uninfected target cells. The interferon produced during NK(HSV-1) assays was analyzed and found to have the properties of HU-IFN-alpha. Little or no IFN was produced during NK assays against uninfected fibroblasts (NK(FS)) or K562 (NK(K562)) cells. Although the appearance of interferon in the culture supernatants seemed to parallel the development of cytotoxicity during NK(HSV-1) assays, the levels of cytotoxicity and IFN generated did not correlate, arguing against a strict quantitative dependence of cytotoxicity upon IFN production. NK(K562) and NK(FS) cytotoxicity developed with little or no production of IFN. When IFN-pretreated effector cells were used, there was still a preferential lysis of infected over uninfected target cells. This preferential lysis by IFN-treated effector cells of infected over uninfected targets was seen as early as 2 hr into the assay. Anti-IFN antibodies added to the NK assays, although neutralizing all the IFN produced during the assays, had no effect on NK(FS) or NK(K562) cytotoxic activity and caused a slightly reduction of NK(HSV-1) activity only in one of three experiments. We conclude that although IFN is generated during NK(HSV-1) assays, this IFN cannot solely account for the increased lysis of infected over uninfected cells and that NK(HSV-1) activity is in some other way dependent on the virus infection.     

Effect of altered membrane fluidity on NK cell-mediated cytotoxicity. I. Selective inhibition of the recognition or post recognition events in the cytolytic pathway of NK cells

NK cell-mediated cytotoxicity results from membrane interactions between NK effector and target cells. The role of membrane fluidity in these events is not known. The present study was undertaken to investigate the effect of changes in membrane lipid fluidity of NK effector and NK-sensitive target cells on the lytic pathway of NK cell-mediated cytotoxicity. Fluidity was modulated by various lipids and measured by fluorescence polarization. NK effector cells treated with phosphatidylcholine complexed with polyvinylpyrrolidone (PVP) and bovine serum albumin (BSA) showed increased membrane fluidity. This fluidization of the effector cell membrane resulted in a significant inhibition of cytotoxic activity in the 51Cr-release assay. Single cell analysis revealed that the inhibition was due to a decrease in the frequency of NK target conjugates and reduced killing of conjugated targets. Rigidification of the NK effector cell membranes by treatment with cholesteryl hemisuccinate complexed with PVP and BSA also resulted in inhibition of cytotoxicity. This inhibition was post binding, because binding was increased and lysis was abrogated. Fluidization of K562 target cell membranes caused a slight but insignificant increase in their lysis by NK cells without affecting the binding step. On the other hand, rigidification of K562 membranes decreased the sensitivity of these target cells to lysis. Single cell analysis revealed that this inhibition of NK lysis is post binding, because the frequency of killers was significantly decreased. It was also shown that membrane rigidification of target cells that were programmed for lysis during the lethal hit stage and subsequently separated from effector cells, rendered the programmed cells resistant to killing during the killer cell-independent lysis step. These results demonstrate that fluidization or rigidification of the plasma membrane of either effector or target cells affect different stages of the NK cell-mediated cytolytic events.     

Induction of natural killer cell activity in mice by injection of indomethacin

The natural killer (NK) cell system of mice in the peritoneal cavity is of very low to undetectable activity, and testing peritoneal NK cells is a useful model to study the influence of activating substances upon local injection. Injection of indomethacin at doses of 100-400 micrograms/mouse caused a marked activation of NK cell activity which was maximal at 3 days and lasted for a total of 6 days. A similar albeit less marked effect was observed with other cyclooxygenase inhibitors such as aspirin. Prostaglandin E2 reversed the activation of NK cells induced by injection of indomethacin. The cellular count of the peritoneal population was 2-fold elevated after indomethacin injection but the percentage of macrophages in the washed-out cell population was decreased from 60% (controls) to around 20%. The NK cell nature of the effector cells activated by indomethacin was substantiated by the finding that previous injection of anti-asialo GM1 antibody prevented activation. Interferon could not be detected in the peritoneal wash fluid after injection of indomethacin, suggesting interferon-independent activation. However, the possibility of small interferon quantities being locally produced could not be excluded. In further experiments we found after intraperitoneal injection of indomethacin not only cells that killed YAC-1 targets in a 4-hour assay but also killer cells that were insensitive to anti-asialo GM1 and killed P815 cells in an 18-hour assay. We assumed that these were macrophages and have done further experiments with in vitro grown bone-marrow-derived macrophages. These could be activated for killing of P815 targets by the addition of indomethacin, but (to a lesser degree) also for killing of YAC-1 lymphoma cells.     

Enhanced lysis of herpes simplex virus type 1-infected mouse cell lines by NC and NK effectors

Spontaneously cytotoxic murine lymphocytes lysed certain cell types infected by herpes simplex virus type 1 (HSV-1) better than uninfected cells. The levels of virus-directed lysis varied widely from target to target, and we found that differences in virus-directed lytic efficiency could be attributed both to the characteristics of HSV-1 replication in the different targets and to the subgroup of natural effector cells which mediated lysis. Although HSV-1 adsorbed to the surface of all the target cells, those in which the virus replicated more efficiently were lysed to a greater extent. As targets, we used cell lines that, when uninfected, were spontaneously lysed by NK cells (YAC-1) or by NC cells (WEHI-164). We also used a fibroblastoid cell line (M50) and a monocytic tumor line (PU51R), which were not spontaneously killed. Using complement-mediated elimination of Qa-5-positive or asialo-GM1-positive NK cells to distinguish NK from NC activity, we found that NK cells lysed HSV-1-infected YAC cells better than uninfected cells, and an NC-like activity selectively lysed HSV-1-infected WEHI cells. In addition, we showed that both NK and NC cytotoxicities contributed to the lysis against the HSV-1-infected fibroblastoid line, M50, but the infected PU51R cells were killed by only NK effectors. These findings were consistent with the results of experiments performed to define the role of interferon in induction of virus-augmented cytolysis. Increased lysis of YAC-HSV and PU51R-HSV was entirely due to interferon activation and was completely abolished by performing the 51Cr-release assay in the presence of anti-interferon serum. Because NC activity was not augmented by interferon, virus-enhanced NC lysis of M50-HSV and WEHI-HSV was not due to this nonspecific mechanism. Together, our data show that HSV-1 infection of NK/NC targets induces increased cytotoxicity, but the effector cell responsible for lysis is determined by the uninfected target, or by an interaction between the virus and target cell, rather than by a viral determinant alone.     

Target-effector interaction in the natural killer cell system. IV. Modulation by cyclic nucleotides.

Dibutyryl cAMP (dB-cAMP) and the cAMP elevating agents, prostaglandin E1, theophylline, and histamine markedly suppressed NK cytolytic function in a dose- and rate-dependent manner. The inhibition was rapidly induced and persisted in the presence of the drugs. Separate pretreatment of targets and highly purified NK cells, isolated by a target binding and velocity sedimentation technique, revealed that PGE1 and dB-cAMP acted at the level of the effector cell in a short-term cytolytic assay. In contrast to the inhibitory effects of cAMP elevating agents, dB-cGMP and carbamylcholine caused a small but significant acceleration in the rate of lysis and could compete with inhibitory doses of dB-cAMP to reduce the level of suppression thereby suggesting that the cAMP-cGMP ratio might be important in NK-mediated lysis. Insulin had no effect on NK activity, whereas T cell-mediated cytolysis was augmented by insulin and cGMP if the effector cells were taken early after alloimmunization but not later. Neither cAMP- nor cGMP-elevating agents affected the frequency of NK-target cell conjugates. These results are compatible with the hypothesis that cyclic nucleotides may be involved in triggering the lytic event within NK cells.     

Interferon and butyrate treatment leads to a decreased sensitivity of NK target cells to lysis by homologous but not by heterologous effector cells

Human K-562 and HHMS cells were pretreated with human recombinant interferon (IFN)-gamma and used as targets in NK assays against human and murine effector cells. A protective effect against NK lysis was observed only in the homologous assay, whereas no change or even a slight increase in NK sensitivity against heterologous effector cells was found. In cold target inhibition experiments IFN-treatment of K-562 cells led to a decrease in their capacity to act as competitors in the homologous NK assay, leaving their inhibitory capacity unaltered in the heterologous assay. In accordance with results observed using human NK targets, murine YAC-1 cells treated with mouse recombinant IFN-gamma did not lose their susceptibility to human NK cells. However, they were markedly less susceptible to lysis mediated by murine effectors. Butyrate, another compound causing decreased sensitivity of K-562 cells for human natural killing, also failed to reduce the susceptibility against murine NK cells. The results indicate that the NK-resistant tumor target phenotype caused by IFN or differentiation-inducing agents can only be detected by homologous but not by heterologous effector cells. This suggests that major differences exist between the inter- and intraspecies NK killing mechanisms.     

Augmentation of human natural cytotoxic cell activity by leukotriene B4 mediated by enhanced effector-target cell binding and increased lytic efficiency

The addition of leukotriene B4 (LTB4) to cytotoxicity assays measuring natural killer (NK) or natural cytotoxic (NC) cell activities resulted in significantly augmented killing of K562 or herpes simplex virus (HSV)-infected target cells, respectively. Since the mechanism of cytotoxicity implies several steps, including the binding of effectors to targets which is Mg2+-dependent and the programming of lysis of the target which is Ca2+-dependent, we undertook to define the step(s) at which LTB4 acted in augmenting cytotoxicity. Our results showed that LTB4 significantly increased the percentage of effector-target conjugates when K562- or HSV-infected targets were incubated with lymphocytes. Maximal binding occurred at a concentration of LTB4 of 1 X 10(-10) M. Preincubation of lymphocytes and not target cells with LTB4 was sufficient to observe the increased binding. PBML binding to and killing of the NK-resistant target clone I, derived from K562, was not enhanced by LTB4. In the absence of Ca2+, cytotoxicity was impaired and LTB4 could not restore it. Use of a single cell lytic assay demonstrated augmented efficiency of lysis of both K562 and HSV-infected targets in the presence of LTB4. These findings suggest that LTB4 may augment natural cytotoxicity by enhancing target cell recognition by cytotoxic effector cells and subsequently by augmenting their lytic efficiency.     

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.     

IFN-gamma treatment of K562 cells inhibits natural killer cell triggering and decreases the susceptibility to lysis by cytoplasmic granules from large granular lymphocytes

Pretreatment of human K562 leukemia cells with rIFN-alpha and rIFN-gamma resulted in decreased susceptibility to lysis by human peripheral blood NK cells. The reduction of NK-susceptibility after IFN treatment was not due to a general effect of IFN on the stability of the cell membrane because the susceptibility of K562 cells to lysis by antibodies plus C, distilled water, or lysolecithin was unaffected. Binding studies with effector cell preparations enriched for NK cells with large granular lymphocyte morphology revealed no difference in binding to control and IFN-gamma-treated target cells. The sensitivity to soluble NK cytotoxic factors was not affected significantly by the IFN treatment. In contrast, the susceptibility of IFN-treated target cells to the cytotoxic activity of purified cytoplasmic granules from a rat large granular lymphocyte tumor was significantly reduced, indicating that the IFN-induced resistance acted at the level of susceptibility to the lytic mechanism of NK cells. However, IFN-alpha was more effective than IFN-gamma in inducing resistance to the cytoplasmic granules although resulting in only a weak resistance in the cell-mediated cytotoxic assay. IFN-gamma but not IFN-alpha caused a reduction in the frequency of effector cells that had reoriented their Golgi apparatus toward their bound target cell. In addition, IFN-gamma treated K562 cells failed to elicit an influx of Ca2+ into effector cells. Taken together, the results suggest that IFN-gamma in addition to an increased resistance to the lytic molecules released by NK cells can also induce changes in the target cells which prevent the triggering and activation of the effector cell.     

High cytotoxic activity against herpes simplex virus type 1 infected targets found in murine peritoneum

Unelicited murine peritoneal cells (PC) were found to efficiently lyse the natural cytotoxic (NC) cell target, WEHI-164, as well as herpes simplex virus-type 1 (HSV-1)-infected WEHI-164 and 3T3 cells but not the natural killer (NK) target, YAC-1. Lysis by PC of HSV-1-infected WEHI-164 and 3T3 cells required longer culture times than splenic cell lysis of YAC-1 cells. The PCs which lysed these targets were found to be slightly adherent to nylon wool but non-phagocytic, and were not augmented by preincubation with interferon. Also, PC effectors lacked Qa-5 and asialo GM1 markers which are found on splenic NK cells which lysed YAC-1 targets. We found that there was no correlation between peritoneal NC activity and genetic resistance to HSV-1.     

The isolation of natural killer (NK)-resistant variants of the K562 cell line by mutagenesis and selection with antibodies which inhibit NK cell-mediated lysis

Mechanisms involved in the lysis of tumor cells by natural killer (NK) cells were investigated by using mutagenized K562 targets resistant to the effects of NK cells. K562 cells were treated with the mutagen methyl methanesulfonate (MMS) and, to select for resistant mutants, rabbit anti-idiotypic (anti-id) antibodies were used. This anti-id was raised to a monoclonal antibody 9.1C3 which itself blocked lysis by NK cells by binding to the effector cells; the anti-id inhibited killing by binding to the K562 targets, presumably to a cell surface protein relevant to a secondary event in the NK lytic pathway. MMS-derived mutants showed a heterogeneity of staining with the anti-id, allowing the antibody to be used with flow cytometry to select a population of K562 cells relatively negative in antigen expression. The degree of reactivity of K562 cultures with the anti-id antiserum and the resistance to lysis by NK cells were inversely related. Cultures of NK-resistant K562 cells with low expression of the anti-id structure were cloned by limiting dilution: 96 clones were analyzed and one subclone, C9/2, which was six-to sevenfold less sensitive to lysis than the parental K562 cell line, was used in further studies by cold target inhibition and single cell binding assays. The increased resistance to lysis of C9/2 was not due to a reduced expression of target recognition structures, and resistance could not be overcome by prolonging the time allowed for lysis to 18 hr nor by adding exogenous recombinant leukocyte interferon. Killing of the NK-resistant variant was inhibited by mannose-6-phosphate but not by the monoclonal antibody against which the anti-id antibody was raised. It is therefore suggested that the structure on the K562 cells recognized by the anti-id antibodies is a novel secondary receptor which is important in the later stages of the NK cell cytolytic cascade.     

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.     

Inhibition of postbinding target cell lysis and of lymphokine-induced enhancement of human natural killer cell activity by in vitro exposure to ultraviolet B radiation

In vitro exposure of human peripheral blood mononuclear cells (PBMC) to ultraviolet B (uvB) radiation has been shown to inhibit natural killer (NK) cell-mediated cytotoxicity in a dose-dependent fashion. The purpose of this study was to examine the manner by which uvB produced these deleterious effects. Inhibition of NK activity was not due to lethal injury to NK cells since the viability of cell populations enriched for NK activity was greater than 90% with the uvB doses employed. uvB appeared to directly affect NK cells since procedures which removed suppressor mechanisms, such as removal of monocytes and pharmacologic inhibition of the cyclooxygenase pathway, failed to reverse the response. Furthermore, no suppression of activity of unirradiated NK cells could be produced by coincubation of unirradiated NK cells with uv-irradiated NK cells. When the single cell assay for binding and killing was employed to determine at which stage in the lytic sequence inhibition occurred, it was found that binding was normal but lysis of bound targets and the recycling capacity of active NK cells were markedly reduced. At uvB doses above 50 J/m2, both interferon alpha (IFN-alpha) and interleukin 2 (IL-2) were ineffective in augmenting NK cell-mediated cytotoxic reactions after cells had been irradiated with uvB. Furthermore, incubation of NK cells with IFN-alpha prior to irradiation failed to protect against the inhibitory effects. These studies provide evidence that in vitro exposure of NK cells to uvB radiation inhibits their function by a direct nonlethal effect and that this inhibition occurs selectively at the postbinding stage of target cell lysis.     

Antibodies to adhesion molecules inhibit the lytic function of MHC-unrestricted cytotoxic cells by preventing their activation.

We evaluated the effect of the antibodies to adhesion molecules CD2, CD11a/CD18 (LFA-1), and CD56 (N-CAM) on MHC-unrestricted cytotoxicity mediated by polyclonal NK cells and LAK cells or by CD3+ or CD3- cytolytic cell clones against a panel of tumor cell targets selected according to expression or absence of the corresponding ligands. We show that (i) antibodies to CD11a/CD18 and, to a lesser extent, antibodies to CD2 inhibit target cell lysis, whereas anti-CD56 antibodies exert little if any effect; (ii) in a model system using polyclonal NK/LAK cells as effectors and K562 or HL60-R (NK-resistant) cells as targets, inhibition of cytotoxicity occurs without a significant impairment of effector to target cell binding; (iii) the cytotoxic function of CD3+ or CD3- cytotoxic cell clones is inhibited differentially by antibodies to adhesion molecules; (iv) conjugates formed in the presence of antibodies which inhibit target cell lysis display a significant reduction of target to effector cell contact surface; and (v) this may lead to defective activation of effector cells, as indicated by lack of redistribution of the microtubular apparatus. We conclude that (i) MHC-unrestricted cytotoxicity is regulated by a number of molecular interactions that span far beyond our present knowledge and that it is strictly dependent on the surface phenotype of the effector cell and of the target cell; (ii) in certain types of effector/target cell interactions, antibodies to adhesion molecules do not prevent conjugate formation but reduce the extent of cell-to-cell surface contact which, in turn, leads to defective activation of the effector cell and, therefore, to inhibition of target cell lysis.     

Influence of interferon on the functional expression of natural killer target structures of murine lymphoma cells

Murine lymphoma cells (YAC-1), induced by Moloney leukemia virus, nontreated (YAC) or pretreated in vitro with interferon (YAC-IF), were tested for their susceptibility to natural killer (NK)-mediated cytolysis. In line with previous reports YAC-IF were less susceptible to NK lysis than YAC cells. In cold competition assay, YAC-IF inhibited cytotoxicity to a lesser extent than YAC lymphoma when labeled target YAC cells were used. However, when radioactive YAC-IF cells were used as targets, cold competition attained with both YAC and YAC-IF was essentially the same. Furthermore, effector splenocytes, depleted of NK effector cells through immunoabsorption on YAC monolayer, were inactive against both YAC and YAC-IF targets. On the other hand, effector lymphocytes, absorbed on YAC-IF monolayer, retained NK activity against YAC cells but not against YAC-IF targets. These results are compatible with the hypothesis that interferon (IF) modulates negatively a subset of "interferon-susceptible" (IFS) NK target structure(s) (TS) of YAC cells, which would then express membrane determinants not functionally present on YAC-IF cells. On the other hand YAC and YAC-IF cells share "interferon-resistant" (IFR) TS not affected by pretreatment with IF. In order to test whether IFS X TS and IFR X TS are present on the same cell or clonally distributed, YAC cells were cloned and tested for NK susceptibility following IF pretreatment. The results did not support the hypothesis of a clonal distribution of both IFS X TS and IFR X TS since IF pretreatment of all clones, obtained by limiting dilution, resulted in a net impairment of target susceptibility to NK effector cells.     

Lysis of human cytomegalovirus infected fibroblasts by natural killer cells: demonstration of an interferon-independent component requiring expression of early viral proteins and characterization of effector cells

We investigated the susceptibility of cells infected with human cytomegalovirus (HCMV) to lysis by human natural killer (NK) cells, examining in particular its relationship to sequential viral protein expression, interferon (IFN), and the nature of the effector cells. HCMV-infected fibroblasts were lysed by peripheral blood mononuclear cells from normal seronegative individuals. The effector cells were large granular lymphocytes of Leu-7+, Leu-11+, and to a lesser extent Leu-7- phenotype. Depletion studies suggested they were the same population of NK cells that lyse uninfected fibroblasts, but a subset of NK cells that lyse K562 cells. HCMV-infected cells treated with phosphonoformate and cells infected for 16 hr that only express the nonstructural HCMV immediate early and early proteins and not the late (structural) proteins were susceptible to lysis by IFN-pretreated effector cells, whereas cells expressing immediate early antigens alone were not. This enhanced susceptibility to lysis was associated with increased effector:target binding in target cell binding assays, and was competitively inhibited by uninfected fibroblasts in cold target competition assays. It was independent of IFN release from the infected target cells or effector cells. These results suggest that the increased susceptibility to lysis by NK cells produced by a human herpes virus HCMV i) is manifest when early viral proteins are expressed, ii) is related to enhanced expression of a target structure likely to be present on uninfected fibroblasts, and iii) has a major component that is independent of IFN.     

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.     

Quantitation and sorting of vitally stained natural killer cell-target cell conjugates by dual beam flow cytometry

We have detected formation of stable associations, or conjugates, between fluorescein diacetate-(FDA) stained human natural killer (NK) cells and Hoechst 33342-(HO342) stained tumor cells by dual laser flow cytometry. Conjugates in mixtures of effectors and targets emitted both green (FDA) and blue (HO342) fluorescence. This was confirmed by cell sorting. More than 90% of the conjugates included one target and one effector cell. Conjugate formation frequency was temperature independent between 4 and 37 degrees C, optimized by 10 min, and stable for 1 hr. Enrichment of effector populations for cells mediating lysis of standard NK targets and for cells reacting with OKM1, Leu-7, and Leu-11b monoclonal antibodies also enriched conjugate-forming cells. Lysis of either OKM1+, Leu-11b+ effector subpopulations with antibody and complement eliminated, but treatment with these antibodies alone had no effect on, conjugate formation. Effector pretreatment with Leu-4 or 3A1 and complement increased the frequency of conjugation slightly. Flow-determined frequencies of NK-conjugate formation with 14 target cell lines correlated well with data derived from standard microscopic assays. However, the flow method was more rapid, could be used when target and effector were of comparable size, and permitted isolation of conjugates by sorting.     

Natural killer cell activity correlates with the amount of beta 2-microglobulin on human peripheral blood lymphocytes

Two cytotoxic assays, lectin-dependent cytotoxicity and natural killer (NK) cytotoxicity, were used to assess the competence of cord blood and neonatal peripheral blood mononuclear cell (PBMC) and T-cell cytotoxic reactions. The effect of exogenous interferon was also studied. Results were compared with cytotoxic capabilities of adult cells and cells from patients with primary immunodeficiency syndromes. Lectin-dependent cytotoxicity (LDCC), a property of both T and non-T cells, was assessed by lysis of chromium-labeled EL4 tumor target cells in the presence or absence of exogenous fibroblast interferon (IFN-β). Natural killer cytotoxicity was assessed by lysis of two different chromium-labeled tumor target cells, Molt 4f and K562 in the presence or absence of IFN-β. Lectin-dependent cytotoxicity (LDCC) of PBMC of cord blood (32 ± 4% SEM) and adult cells (36 ± 2% SEM) were equivalent but neonatal cells had slightly decreased LDCC (22 ± 3% lysis). T-depleted cells from cord or neonatal blood had increased LDCC but T-enriched (>95% sheep erythrocyte rosette-forming cells) from both cord (22 ± 3%) and neonatal blood (18 ± 5%) had significantly reduced LDCC compared to 55 ± 2% for adult T cells. This deficiency corrects with age and is near normal after age 2. Preincubation with IFN-β did not enhance LDCC of newborn or adult cells. The LDCC of some cord T cells was markedly reduced and was in the same low range as patients with severe combined immunodeficiency. Natural killer (NK) cytotoxicity of PBMC from cord and adult cells was equivalent at three effector:target ratios against the Molt 4f target but against the K562 target, cord PBMC had significantly less NK activity (22 ± 11 SD) compared to adult NK activity (50.5 ± 22.2 SD) at a 50:1 effector:target ratio. Similar differences were noted at 25:1 and 10:1 target:effector ratios. NK cytotoxicity against Molt 4f targets of adult cells was significantly enhanced by preincubation with IFN-β but NK of cord cells was only variably enhanced. By contrast, IFN-β enhanced NK against K562 targets of both adult and cord cells, adult greater (67.7 ± 20) than cord cells (37.8 ± 2.0). These T-cell effector deficiencies are in marked contrast to the vigorous proliferative responses of newborn T cells, and parallel deficiencies of certain neonatal lymphokines. These defects may explain the newborns' enhanced susceptibility to intracellular viruses and to congenital viral infections.