Effect of altered membrane structure on NK cell-mediated cytotoxicity. III. Decreased susceptibility to natural killer cytotoxic factor (NKCF) and suppression of NKCF release by membrane rigidification

We have shown recently that alteration of the membrane fluidity of either effector or target cells results in significant and selective inhibition of NK cell-mediated cytotoxicity (NK CMC). However, the localization of the defective stage in the NK lytic pathway is not known. In the present study, we show that rigidification of the NK-sensitive U937 target cell membrane by lipid modulation reduces its sensitivity to lysis by NK cytotoxic factor (NKCF). This resistance was not due to loss of NKCF binding sites on the target cell because target cells with rigid membranes absorbed more NKCF than control cells. The enhanced ability to absorb NKCF by membrane modification was supported by data showing that NK-resistant Raji cells lacking NKCF-binding sites absorb NKCF after lipid modification. Furthermore, consistent with the lipophilic nature of NKCF, synthetic lipid vesicles absorb NKCF. In contrast to membrane rigidification, membrane fluidization of the target cell did not change the target cell properties. Rigidification of the NK effector cell membrane abrogates it ability to secrete active NKCF when stimulated by target cells or by mitogens. Membrane fluidization of the NK effector cells did not inhibit their ability to release NKCF. The results of these studies demonstrate that inhibition of NK CMC by rigidification of the target cell membrane results in cells that are inhibited in processing bound NKCF to lysis. Inhibition of NK CMC by rigidification of the NK effector cell results in defective trigger for activation of the NKCF release mechanism.     

Studies on the mechanism of natural killer cell-mediated cytotoxicity. V. Lack of NK specificity at the level of induction of natural killer cytotoxic factors in cultures of human, murine, or rat effector cells stimulated with mycoplasma-free cell lines

We have proposed that lysis of target cells by NK cells is mediated by NK cytotoxic factors (NKCF). According to our model, for a target cell to be NK-sensitive, it must be recognized by the NK cell, it must stimulate the release of NKCF, and it must be sensitive to lysis by these factors. This report examines whether the ability to stimulate release of NKCF is a characteristic restricted to NK-sensitive tumor cells or whether it is also a property of NK-resistant target cells. Many different types of cell lines were tested for their ability to stimulate release of NKCF in the human, rat, and murine systems. It was found that mycoplasma-free NK-sensitive cell lines, resistant cell lines, and Con A could stimulate the release of NKCF. Many different types of cell lines grown in suspension or in monolayers were found to be effective stimulators, including T or B lymphoid, myeloid, and those of histiocytic origin. Cells cultured in the absence of serum stimulated NKCF release, thus ruling out the possible involvement of serum components in stimulation. NKCF was also produced by xenogeneic combinations of effector and stimulator cells, demonstrating lack of species specificity in NKCF production. Factors stimulated by NK-resistant cell lines or by Con A exhibited the same NK target specificity as supernatants stimulated by NK-sensitive tumor cells. The finding that many different NK-resistant cell lines can stimulate the release of NKCF indicates that there is no apparent NK specificity at the level of induction of NKCF release from human, rat, or murine effector cells. Therefore, the NK specificity of a target cell is determined ultimately by its sensitivity to lysis by NKCF.     

Studies on the mechanism of natural killer cytotoxicity. III. Activation of NK cells by interferon augments the lytic activity of released natural killer cytotoxic factors (NKCF)

The mechanism by which interferon (IFN) pretreatment of effector cells augments natural killer (NK) cell-mediated cytotoxicity (CMC) was examined by determining whether IFN has any effect on the production of natural killer cytotoxic factors (NKCF). NKCF are released into the supernatant of co-cultures of murine spleen cells and YAC-1 stimulator cells, and their lytic activity is measured against YAC-1 target cells. It was demonstrated that pretreatment of effector cells with murine fibroblast IFN or polyinosinic-polycytidylic acid (pIC) resulted in the release of NKCF with augmented lytic activity. Evidence indicated that the IFN-induced augmentation of NKCF activity required protein synthesis during the IFN pretreatment period, because concurrent pretreatment with both IFN and cycloheximide abrogated the IFN effect. Protein synthesis, however, is not required for the production of base levels of NKCF because emetine pretreatment of normal spleen cells did not result in a decrease in NKCF production. Furthermore, substantial levels of NKCF activity could be detected in freeze-thaw lysates of freshly isolated spleen cells. Cell populations enriched for NK effector cells, such as nylon wool-nonadherent nude mouse spleen cells, produced lysates with high levels of NKCF activity, whereas lysates of CBA thymocytes were devoid of NKCF activity. Pretreatment of spleen cells with either IFN or pIC resulted in an augmentation of the NKCF activity present in their cell lysates. Taken altogether, these findings suggest that freshly isolated NK cells contain preformed pools of NKCF. Pretreatment of these cells with IFN causes de novo synthesis of additional NKCF and/or activation of preexisting NKCF. According to our model for the mechanism of NK CMC, target cell lysis is ultimately the result of transfer of NKCF from the effector cell to the target cell. The evidence presented here suggests that the IFN-induced augmentation of NK activity could be accounted for by an increase in the synthesis, activation, and/or release of NKCF.     

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.     

Studies on the mechanism of natural killer cytotoxicity. II. coculture of human PBL with NK-sensitive or resistant cell lines stimulates release of natural killer cytotoxic factors (NKCF) selectively cytotoxic to NK-sensitive target cells

This investigation has employed the "innocent bystander" type of experimental design to determine whether soluble cytotoxic factor(s) are released during interactions between human peripheral blood lymphocytes (PBL) and NK-sensitive target cells. PBL cocultured with NK-sensitive Molt-4 or K562 target cells in the lower well of a miniaturized Marbrook culture released natural killer cytotoxic factors (NKCF), which diffused across a 0.2-mu Nucleopore membrane and lysed Molt-4 or K562 target cells cultured in the upper chamber. Coculture of PBL with the NK-resistant Raji or WI-L2 cell lines also induced release of NKCF. These factors were selectively cytotoxic to NK-sensitive targets and lysed Molt-4 and, to a lesser extent, K562 cells. However, Raji, WI-L2, and RPMI 1788 cells were all resistant to lysis. In addition, low density fractions from Percoll density gradients that were enriched for NK effector cells also released increased levels of NKCF during coculture with Molt-4 cells. Lysis of Molt-4 and K562 targets was observed after exposure to NKCF for 48 hr and 60 to 70 hr, respectively. Cellfree supernatants containing NKCF were obtained after a short time of incubation (i.e., within 5 hr of coculture of PBL with NK target cells). The factors were nondialyzable, stable at 56 degrees C for 3 hr, and showed partial loss of activity on storage at 4 degrees C or -20 degrees C for 7 days. These data suggest that NKCF may be involved in the lytic mechanism of human NK cell-mediated cytotoxicity.     

Interleukin-12 secreted by mature dendritic cells mediates activation of NK cell function

Dendritic cells (DCs) are known to modulate immune response by activating effector cells of both the innate and the adaptive immune system. In the present study, we demonstrate that co-culture of DCs with paraformaldehyde-fixed tumor cells augments the secretion of interleukin (IL)-12 by DCs and these activated DCs upon co-culture with naive NK cells enhance the cytolytic activity of NK cells against NK-sensitive target YAC-1. Similarly, DCs isolated from tumor-bearing animals also activated NK cells in vitro. For efficient activation of NK cells, the ratio of activated DCs to NK cells is crucial. Addition of anti-IL-12 antibody to the culture system completely abolished activation of NK cells by DCs, suggesting that IL-12 secreted by DCs is an essential factor in NK cell activation. Adoptive transfer of DCs isolated from tumor-bearing animals into normal rats also induced activation of NK cells in normal animals.     

Mechanism of defective NK cell activity in patients with acquired immunodeficiency syndrome (AIDS) and AIDS-related complex. II. Normal antibody-dependent cellular cytotoxicity (ADCC) mediated by effector cells defective in natural killer (NK) cytotoxicity

Our studies and other investigations have shown that NK effector cells can also mediate antibody-dependent cellular cytotoxicity (ADCC) through the use of the Fc gamma receptor on the NK cell membrane. Peripheral blood lymphocytes (PBL) derived from patients with acquired immunodeficiency syndrome (AIDS) and AIDS-related complex exhibit a poor NK activity due to a defective "trigger" required for activation in the lethal hit stage of the NK lytic pathway. Consequently, it was important to delineate whether the defect in AIDS NK cells affected the ADCC function. By using the 51Cr-release assay, the ADCC cytotoxic activity of AIDS PBL was found to be within the normal range, despite the absence of significant NK activity. Several experiments corroborated that the same effector cells mediate both NK CMC and ADCC. Depletion of Fc gamma R-bearing cells resulted in elimination of both the ADCC and NK cytotoxic functions. Single cell analyses, using one- and two-target cell conjugates, revealed that the frequency of ADCC effector:target conjugates and the frequency of killer cells from AIDS PBL were comparable to the frequencies seen in the normal controls. However, when mixtures of NK and ADCC targets were used to form mixed two-target conjugates, the AIDS effector cells lysed only the bound ADCC target, whereas the normal effector cells lysed both the bound NK and ADCC targets. These results demonstrate clearly that the same NK/K effector cells from AIDS PBL, defective in NK activity, are not impaired in mediating ADCC activity. These findings were supported by the demonstration that AIDS PBL stimulated with ADCC targets, but not with NK targets, released NK cytotoxic factors, postulated mediators of the NK CMC reaction. These findings indicate that the NK/K cells in AIDS are triggered normally for ADCC activity but are not triggered for NK activity. Furthermore, the results indicate that the lytic machinery is not impaired in the AIDS NK/K cells.     

Depressed natural cytotoxicity but normal natural killer cytotoxic factor (NKCF) production by mononuclear cells derived from patients with hepatocellular carcinoma

Summary This study investigated the relation between the production of natural killer cytotoxic factors (NKCF) and the phenomenon of natural killing (NK) activity against target K562 cells. Two different models of defective NK cell activity were employed. In the first instance, cytotoxic activity of mononuclear cells (MN) derived from patients with hepatocellular carcinoma was compared to the ability of these cells to produce NKCF. Although direct cytotoxicity was considerably impaired in these patients, the ability of their MN to produce NKCF when stimulated with K562 cells was found to be normal. In the second model, MN treated with the lysosomotropic drug monensin showed considerably reduced direct cytotoxic activity, although they were capable of producing normal amounts of NKCF when activated by K562 cells. These results therefore indicate that there is no correlation between NK activity and corresponding NKCF release, and suggest that NKCF production and activity is independent of direct NK cytotoxic activity.     

Antibody-dependent cell lysis by NK cells is preserved after sarcoma-induced inhibition of NK cell cytotoxicity

Osteosarcoma and Ewing’s sarcoma tumor cells are susceptible to IL15-induced or antibody-mediated cytolytic activity of NK cells in short-term cytotoxicity assays. When encountering the tumor environment in vivo, NK cells may be in contact with tumor cells for a prolonged time period. We explored whether a prolonged interaction with sarcoma cells can modulate the activation and cytotoxic activity of NK cells. The 40 h coculture of NK cells with sarcoma cells reversibly interfered with the IL15-induced expression of NKG2D, DNAM-1 and NKp30 and inhibited the cytolytic activity of NK cells. The inhibitory effects on receptor expression required physical contact between NK cells and sarcoma cells and were independent of TGF-β. Five days pre-incubation of NK cells with IL15 prevented the down-regulation of NKG2D and cytolytic activity in subsequent cocultures with sarcoma cells. NK cell FcγRIIIa/CD16 receptor expression and antibody-mediated cytotoxicity were not affected after the coculture. Inhibition of NK cell cytotoxicity was directly linked to the down-regulation of the respective NK cell-activating receptors. Our data demonstrate that the inhibitory effects of sarcoma cells on the cytolytic activity of NK cells do not affect the antibody-dependent cytotoxicity and can be prevented by pre-activation of NK cells with IL15. Thus, the combination of cytokine-activated NK cells and monoclonal antibody therapy may be required to improve tumor targeting and NK cell functionality in the tumor environment.     

Mechanisms involved in NK resistance induced by interferon-gamma.

Human tumor cell lines were treated with interferon-gamma (IFN-gamma) and then used as target cells in NK assays to measure their ability to form conjugates and stimulate the production of NK cytotoxic factors (NKCF) and to determine their susceptibility to NKCF lysis. K562 and cell lines RS1, RS3, RS7, CAC, and CAP2, obtained from solid brain tumors, were used as targets, and peripheral blood lymphocytes (PBL) from normal donors were used as effector cells. IFN-gamma-treated cell lines had a decreased susceptibility to NKCF lysis and a decreased ability to induce the release of these factors without affecting target-effector cell binding. These results were not due to changes in HLA class I antigen expression, given that the level of HLA class I antigens on the tumor cell lines was not affected, the only exception being K562. In an attempt to further clarify the possible influence of HLA class I expression on K562, IFN-gamma-pretreated K562 cells were separated into HLA class I positive and HLA class I negative subsets for the NK assays. The results showed that both populations behaved similarly upon target-effector conjugate formation, whereas the HLA class I positive population showed a reduced susceptibility to lysis by NK cells and NKCF. Thus, these results establish that NK resistance induced by IFN-gamma is mediated by blocking the target cell's ability to activate NK cell triggering and release of NKCF and by blocking its susceptibility to lysis by these factors. This analysis helps to clarify not only the NK process but also the controversial regulatory effect of IFN in NK lysis.     

Natural killer cell immunodeficiency in patients with chronic myelogenous leukemia. IV. Interleukin-1 deficiency, gamma-interferon deficiency and the restorative effects of short-term culture in the presence of interleukin-2 on natural killer cytotoxicity, natural killer-target binding and production of natural killer cytotoxic factor

We report herein that defective natural killer (NK) cell cytotoxicity, NK cytotoxic factor (NKCF) production and NK target binding ability of patients with chronic myelogenous leukemia (CML) are functionally restorable after short-term culture (less than 1 week) with recombinant interleukin-2 (rIL-2). We have previously reported that, despite normal to increased numbers of CD16+ large granular lymphocytes, fluorescence-activated-cell-sorted NK cells from CML patients are profoundly defective in NK cell activity and are unable to lyse the CML blast-crisis-derived, NK-sensitive target K562. Since we and others have also previously shown that the defective NK cytotoxicity from CML patients is restorable after 1-4 weeks of incubation with rIL-2, we therefore deemed it important to study the kinetics of IL-2-mediated NK restoration at earlier time intervals (less than 1 week). In the present report, we have demonstrated a significant restoration of NK cell cytotoxicity in CML patients against K562 after 5 days of short-term culture with rIL-2. In addition, recovery of NKCF production and restoration of target-binding capacity to normal levels by NK cells from CML patients were also observed after short-term (less than 1 week) rIL-2 treatment. Finally, we have demonstrated in the present report that adherent cells and peripheral-blood lymphoid cells from CML patients, as compared to normal controls, are unable to produce IL-1 beta and interferon-gamma, respectively, after stimulation with phorbol myristate acetate (IL-1 beta) and phytohemagglutinin-M (interferon-gamma).     

Analysis of rat natural killer cytotoxic factor (NKCF) produced by rat NK cell lines and the production of a murine monoclonal antibody that neutralizes NKCF

Natural killer cytotoxic factor (NKCF) is produced as a result of the interaction of murine, rat, or human natural killer (NK) cells with NK-susceptible targets. This factor has been linked to the target cell lysis mediated by the NK effector cell. In the present results, culture supernatants from rat large granular lymphocyte (LGL) tumors exhibited NKCF activity which lysed the susceptible targets, MBL-2 and YAC-1. NKCF production from these rat tumor lines was spontaneous and was not significantly increased by co-incubation of the LGL tumors with target cells, target cell membranes, or by preincubation of the LGL tumor cells with interferon or interleukin 2. In addition to NKCF activity, the supernatants lysed L929, indicating the presence of tumor necrosis factor (TNF) in these preparations. The presence of this latter cytokine was verified using specific antibodies to recombinant murine TNF which neutralized the L929 activity while not affecting the NKCF activity against MBL-2 or YAC-1. Mouse monoclonal antibodies (mAb) A0287, A0462, and A0316) which significantly inhibit the NKCF cytolytic activity of these LGL-derived supernatants were also produced. These antibodies were shown to cross-react with human NKCF in a manner similar to that seen in the rat. Interestingly these same mAb demonstrated no inhibition of L929 cytotoxicity from either LGL-derived supernatants or by recombinant murine or human TNF. To examine further the specificity of these antibodies, they were chemically linked to Sepharose 4B and found to remove a significant proportion of the NKCF cytolytic activity from LGL supernatants, while not affecting the TNF reactivities in these preparations. In addition, these antibodies demonstrated significant inhibition of cell-mediated cytotoxicity by rat LGL against YAC-1 target cells. Biochemical analysis of labeled NKCF-containing supernatants indicated the major protein recognized by these anti-NKCF mAb to be approximately 12,000 m.w. The use of these mAb against NKCF should be very useful in further purification and biochemical characterization of NKCF and in studying its role in a variety of cell-mediated cytotoxicity assays.     

Mechanism of NK activation by OK-432 (Streptococcus pyogenes). I. Spontaneous release of NKCF and augmentation of NKCF production following stimulation with NK target cells

The biological response modifier OK-432 (Picibanil) (manufactured in Japan) is produced by lyophilization of cultures of the low virulent Su strain of group A Streptococcus pyogenes of human origin. This preparation has been shown to have multiple effects on the immune system and has been used as an anti-cancer therapeutic agent in man. It has been shown that OK-432 augments the cytotoxic activity of human natural killer (NK) cells. We have proposed that natural killer cytotoxic factors (NKCF) derived from NK cells play a role in the mechanism of NK cell-mediated cytotoxicity (CMC). The present study investigates the underlying mechanism of the OK-432-mediated enhancement of NK activity by determining whether OK-432 has an effect on the induction and activity of NKCF produced by NK cells. Treatment of peripheral blood lymphocytes (PBL) with OK-432 for 20 hr and wash resulted in significant augmentation of NK CMC and this enhancement was dependent on the concentration of OK-432 used. Coculture of the OK-432-treated PBL with U937 resulted in a several-fold enhanced production of NKCF in the supernatant. The NKCF produced were similar to those produced by untreated effector cells in that they had the same NK target specificity for lysis. The time kinetics of stimulation of PBL with OK-432 for optimal production of NKCF was found to be 8-12 hr. It was also observed that culture of OK-432-treated PBL in the absence of stimulator cells spontaneously release significant amounts of NKCF into the supernatant. The supernatant containing NKCF was tested for interleukin 2 (IL-2) activity using an IL-2-dependent HT-2 line. It was found that there was no direct correlation between the levels of NKCF and IL-2 activity. The results of this study demonstrate that OK-432 stimulates NK cells to produce NKCF in the presence or absence of stimulator cells. The optimum concentration of OK-432-induced augmentation of NK CMC paralleled that seen for optimum NKCF production, suggesting that one mode of action of OK432 is to enhance NKCF production in a manner reminiscent of IFN and IL-2. The results also point out that OK-432 acts by a mechanism independent of the action of IL-2.     

Studies on the mechanism of natural killer cell-mediated cytotoxicity. VI. Characterization of human, rat, and murine natural killer cytotoxic factors

Recent evidence has implicated natural killer cytotoxic factors (NKCF) as the lytic mediators of NK cell-mediated cytotoxicity reactions. The objective of this study was to examine and compare some of the biochemical and functional characteristics of human, rat, and murine NKCF. Supernatants containing NKCF were generated by stimulating effector cells with Con A or U937 (for human PBL) or YAC-1 (for rodent spleen cells) and tested for cytotoxic activity in a 20-hour (rodent) or 24-hour (human) 51Cr release assay. NKCF activity was inactivated by heating to 63 degrees C, 8 M urea, pH 2, and reduction and alkylation. These factors were highly sensitive to trypsin, moderately sensitive to papain and resistant to neuraminidase. Adsorption of human NKCF to U937 cells is inhibited by mannose-6-phosphate and adsorption of rodent NKCF to YAC-1 cells is inhibited by alpha-methyl-D-mannoside and fructose-6-phosphate. Oxidation of NKCF with sodium periodate abolished lytic activity. Pretreatment of NKCF with Con A but not pretreatment of target cells inhibited lytic activity. NKCF activity eluted in a single broad band of apparent MW of 15,000-40,000 after fractionation by HPLC gel permeating chromatography. Pooled fractions containing NKCF activity were subjected to some of the same tests performed on whole supernatants. Test result with semipurified NKCF confirmed that these factors are inactivated by trypsin or sodium periodate and that mannose-6-phosphate inhibits their binding to target cells. There were no major differences observed in NKCF produced by the three different species whether stimulated by Con A or NK-sensitive tumor cells. The evidence indicates that NKCF are glycoproteins in which disulfide bonding is essential for lytic activity. Furthermore, it appears that carbohydrate residues expressed on NKCF molecules are involved in the binding of these factors to the target cell membrane.     

Natural killer (NK) cells are present in mice with severe combined immunodeficiency (scid)

Spleen cells from C.B- 17 scid mice with severe combined immunodeficiency disease exhibit natural killer cell (NK) activity against YAC lymphoma targets in a standard 4-hr 51Cr release assay. The cytolytic activity is demonstrable only at high effector to target ratios but can be augmented at least sevenfold by the interferon inducer poly I:C. The pattern of target lysis is specific, because splenocytes from poly I:C-primed C.B-17 scid mice lyse NK-sensitive YAC cells and not the insensitive P815 mastocytoma. The presence of several NK-associated antigens on C.B-17 scid splenocytes was tested by pretreating cells with the appropriate antiserum plus complement before testing for NK activity. The results indicate that a proportion of NK effectors in C.B-17 scid mice bear surface NK 2.1 and Asialo GM1 but are negative for Thy-1.     

Analysis of rat natural killer cytotoxic factor (NKCF): mechanism of action and relationship to other cytotoxic/cytostatic factors

Natural killer cytotoxic factor (NKCF) has been proposed as one of the factors that mediates lysis induced by natural killer (NK) cells. Recently, an excellent source of NKCF has been found to be the rat large granular lymphocyte (LGL) tumor (RNK) cell line. In this study, the kinetics of lysis of the NK-sensitive, tumor target YAC-1 by the RNK-NKCF was analyzed and found to parallel that seen with NK cell-mediated killing. RNK-NKCF was also capable of killing the NK-resistant target cell, MBL-2, over a longer time period. This study utilized monoclonal antibodies (mAbs) prepared against granule protein, previously termed "anti-NKCF mAbs." These mAbs established the nature of RNK-NKCF as compared to other known cytotoxic factors in combination with studies that show that RNK-NKCF causes both 51Cr release and nuclear degradation. Antibody inhibition experiments have verified that RNK-NKCF is unique from tumor necrosis factor (TNF), leukoregulin, or complement. Anti-NKCF mAbs were capable, however, of neutralizing the RNK cell granule activity against YAC-1 tumor target cells. Based on these results, the ability of anti-NKCF mAbs to neutralize the cytolytic function of pore-forming protein (PFP), a component of these granules, was analyzed. In these experiments, the antibodies were found to inhibit the hemolytic activity of granules. Interestingly, the antibodies were effective in inhibiting the activity of unbound granule proteins as well as those bound to sheep red blood cell (SRBC) targets. Further studies to examine the target lysis requirements demonstrated that in contrast to PFP, the RNK-NKCF was able to lyse the tumor target in the absence of calcium. In addition, treatment of targets with RNA and protein synthesis inhibitors indicated that the mechanism of lysis of NKCF is quite unique from other defined cytotoxic moieties.     

An inducer of NKCF (NK cytotoxic factor) release: localization on target-cell membrane and initial characterization.

Natural killer (NK) cells are probably involved in the elimination of virus-infected cells and of certain tumor cells. NK cell-mediated cytotoxicity (NK-CMC) was extensively studied and was found to consist of several steps. Following recognition and conjugation between the effector and the target cell, the latter one induces release of NK cytotoxic factor (NKCF) from the effector cells. The NKCF binds to the target cell which is subsequently killed. None of the molecules involved in these steps was completely characterized. In the present study it is demonstrated that isolated membranes of target cells can effectively induce the release of NKCF. Furthermore, the activity of such isolated membranes was found to be modulated by interferon (IFN) treatment of the cells prior to membrane isolation. It was therefore concluded that an NKCF-inducing structure (NKIS) is present on plasma membranes and is distinct from the NK-recognition structure. Similarly, the sensitivity to NK-CMC could be transferred from sensitive cells to IFN-gamma-treated (NK-resistant) cells by membrane fusion with the aid of Sendai virus envelope glycoproteins. It is proposed that transfer of NKIS is responsible for the acquired sensitivity to NK-CMC. In addition, it is shown that NKIS activity was recovered following membrane solubilization and reconstitution. Its level on cell surface was modulated by treatment of cells with tunicamycin, thus indicating that NKIS was probably a cell surface glycoprotein.     

Human natural killer cytotoxic factor. Studies on its production, specificity, and mechanism of interaction with target cells

Human peripheral blood lymphocytes cultured in vitro for 2 days in serum-free conditions produced a natural killer (NK) cytotoxic factor (NKCF) which selectively killed NK-susceptible targets. Optimal release of NKCF was achieved under serum-free conditions, while the presence of fetal calf serum inhibited both the production and activity of the factor. Mechanistic studies with NKCF demonstrated that the factor could be adsorbed by the target cells within 6 h, with no further exposure to NKCF required for maximal levels of lysis of the treated targets after additional 30-48 h of incubation, as assessed by a 111I release microcytotoxicity assay. NKCF adsorption to target cells and its cytotoxic activity were inhibited by some phosphorylated sugars (mannose-6PO4 and glucose-6PO4), but not by fructose-6PO4 or nonphosphorylated sugars (mannose, glucose, galactose). These results suggest a role of sugar-6PO4 at the level of interaction of NKCF with NK target cells. This was further supported by the finding that inhibition of target cell glycosylation by tunicamycin also inhibited absorption of NKCF to the target cells and direct killing by NKCF. Therefore, it appears that NKCF is a large granular lymphocyte produced factor which produces lysis as a result of the interaction with glycosylated structures on target cell membranes. Purification studies were performed to begin biochemical characterization of human NKCF. The results indicated that NKCF has an apparent molecular weight between 20,000 and 40,000 dalton. Such approaches with radiolabeled NKCF should be useful for the further study of the biochemical characteristics of human NKCF and of its mechanism of action. The ability to elicit NKCF under serum-free conditions should facilitate its testing, purification, and biochemical characterization.     

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.     

K562 killing by K, IL 2-responsive NK, and T cells involves different effector cell post-binding trigger mechanisms

The monoclonal antibody 13.3 specifically blocks the trigger process of the NK-K562 cytolytic sequence at a post-binding effector cell level. This antibody was used to define differences in the lytic trigger processes of NK and other mechanisms of K562 lysis. Monoclonal antibody 13.3 inhibited lysis of K562 target cells by freshly isolated peripheral blood lymphocytes (PBL) and purified large granular lymphocytes (LGL), but had no inhibitory effect on antibody-dependent cell-mediated cytotoxicity to K562 by these effectors. Lectin-dependent cellular cytotoxicity (LDCC) to this target cell was also unresponsive to 13.3. The 13.3-induced inhibition of NK-K562 lytic activity persisted when PBL were activated in culture with interleukin 2 (IL 2) for periods up to 48 hr. After 48 hr of culture, the degree of inhibition diminished progressively in medium containing fetal calf serum but not in medium containing autologous serum. This 13.3-unresponsive lytic activity in cultured PBL could be attributed to more than one cell type and was present in both the LGL and Fc gamma receptor-depleted T cell fraction. Thus, K562 lysis by freshly isolated human lymphocytes via NK, K, and LDCC mechanisms is characterized by heterogeneity of the post-binding effector cell trigger mechanism. K562 lysis by lymphocytes cultured with IL 2 is similarly heterogeneous.