beta-Endorphin augments the cytolytic activity and interferon production of natural killer cells

We have investigated the in vitro effects of the neurohormone beta-endorphin (b-end) on natural killer (NK) activity and interferon (IFN) production mediated by large granular lymphocytes (LGL). LGL-enriched fractions from peripheral blood mononuclear cells (PBMC) from normal human volunteers were obtained by fractionation over discontinuous Percoll gradients. LGL were preincubated with or without various concentrations of b-end or the closely related peptides alpha-endorphin (a-end), gamma-endorphin (g-end), or D-ALA2-beta-endorphin (D-ALA2-b-end), a synthetic b-end analogue. NK activity was assayed on 51Cr-labeled K562 target cells. Preincubation of LGL effectors (but not K562 targets) for 2 to 18 hr with concentrations of b-end between 10(-7) M and 10(-10) M produced significant augmentation of NK cytolytic activity (mean percentage increase: 63%). The classic opiate antagonist naloxone blocked the enhancing effect when used at a 100-fold molar excess relative to b-end. Neither a-end nor g-end could augment NK activity, whereas D-ALA2-b-end produced an enhancement comparable with that produced by b-end. In addition, incubation of LGL with b-end in the presence of phytohemagglutinin or poly I:C significantly augmented IFN production. These findings demonstrate that b-end enhances NK activity and IFN production of purified LGL, and suggests that b-end might bind to an opioid receptor on LGL that can be blocked by naloxone. These results lend support to the concepts of regulation of the immune response by neurohormones and the functional relationship between the nervous and immune systems.     

Lysis of fresh human tumour cells by autologous tumour-associated lymphocytes: Two distinct types of autologous tumour killer cells induced by co-culture with autologous tumour

Summary The specific and natural killer (NK)-restricted nature of auto-tumour cytotoxicity of tumour-associated lymphocytes was studied in cancer patients with malignant pleural effusions. Large granular lymphocytes (LGL) and small T lymphocytes were isolated from carcinomatous pleural effusions by centrifugation on discontinuous Percoll gradients. Tumour cells freshly isolated from pleural effusions were classified according to their susceptibility to lysis by Percoll-purified LGL from the blood of normal donors in a 4-h ⁵¹Cr release assay. Of 12 NK-sensitive tumour samples, 11 were killed by autologous fresh effusion LGL, whereas only 2 were lysed by autologous T cells. Neither LGL nor T cells were cytotoxic to NK-resistant autologous tumour cells. T cells and LGL were each cultured in vitro with autologous tumour cells for 6 days. Effusion LGL maintained their auto-tumour killing activity in 10 of 12 autologous mixed lymphocyte-tumour cultures (MLTC) with NK-sensitive tumour, while LGL lost the activity when cultured alone. Removal of high-affinity sheep erythrocyte-rosetting cells from Percoll-purified LGL enriched effector cells. Autologous MLTC-derived LGL could also kill NK-sensitive allogeneic effusion tumour cells and K562 cells, as did fresh LGL. In autologous MLTC LGL failed to acquire lytic function to NK-resistant autologous tumour cells. In contrast, in vitro activation of effusion T cells with autologous tumour cells induced auto-tumour killer cells in 9 of 12 NK-sensitive tumour samples and 3 of 6 NK-resistant tumour cases. However, cultured T cells were incapable of killing allogeneic tumour cells and K562 cells. In the autologous MLTC effusion T cells proliferated vigorously in response to autologous tumour cells, whereas LGL showed no proliferation. The enrichment of blasts from cultured T cells on discontinuous Percoll gradients resulted in an enhancement of auto-tumour cytotoxicity, with no reactions recorded in blast-depleted, small, resting T cells. These results indicate that two distinct types of auto-tumour-recognising lymphocytes, LGL and T cells, are present in carcinomatous pleural effusions of cancer patients and that each effector type recognises different membrane moieties of autologous effusion tumour cells.     

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.     

NK-leukocyte chemotactic factor (NK-LCF): a large granular lymphocyte (LGL) granule-associated chemotactic factor

A chemotactic factor was identified in the supernatants of human large granular lymphocytes (LGL) activated by a glutaraldehyde-fixed NK-sensitive tumor, K562. The factor stimulated migration of human LGL, rat alveolar macrophage (RAM), and human monocytes and neutrophils (PMN). The locomotor response was chemotactic and chemokinetic on the basis of unidirectional migration in concentration gradients. The cell producing the factor was detected exclusively in LGL-rich Percoll fraction coincident with the peak of NK lytic activity and HNK-1+ cells. The monoclonal phenotype of the cell was HNK-1+, partially OKT-11+, OKM-1-, OKT-3-, OKT-4-, and OKT-8-. The factor was released by LGL within 20 min of incubation with Sr++, a cation that is able to induce LGL degranulation. A powerful chemoattractant was also detected in the granules of the rat LGL leukemia, RNK. Chemotactic activity coincided with granule enzyme beta-glucuronidase and cytolysin after RNK nitrogen cavitation and Percoll fractionation of subcellular constituents. The RNK granule chemoattractant induced unidirectional migration of human LGL and was also active against rat alveolar macrophages and human PMN. Anti-RNK granule antibody conjugated to Sepharose 4B was able to deplete the chemotactic activity from both K562-induced LGL supernatants and solubilized RNK granules. These observations indicate that a leukocyte chemotactic factor (NK-LCF) is present in NK cell granules and is probably released after tumor-induced granule exocytosis.     

Natural cytotoxicity of lymphocytes from lymph nodes draining breast carcinoma and its augmentation by interferon and OK432

Summary Lymphocytes isolated from axillary lymph nodes draining breast carcinoma were tested for natural killer (NK) activity against K562 in a 4-h ⁵¹Cr-release assay, and the in vitro effects of interferon (IFN) and OK432 (a streptococcal preparation) on their cytotoxicity were examined in comparison with NK activity of autologous peripheral blood lymphocytes (PBL). The levels of NK activity were lower in lymph node lymphocytes (LNL) than in PBL of the same patients. Significant levels of LNL-mediated lysis were recorded in 14 of 42 (33%) lymph node samples and in nine of 14 (64%) patients. Purification of large granular lymphocytes (LGL) from lymph node cells by discontinuous Percoll density gradient centrifugation resulted in an induction or enhancement of cytotoxic activity, with no reactivity in LGL-depleted, small T-lymphocyte populations. Positive reactions were observed with 10 of 13 (77%) LGL samples. The low reactivity of LNL was not attributable to coexistent suppressor cells for NK function, since lymph node cells failed to suppress NK activity of normal PBL. Partially purified human IFN and OK432 augmented NK activity of patients' PBL in approximately 70% and 90% of the cases, respectively, while LNL-mediated lysis was augmented in only 7% and 36% of the lymph node samples by IFN and OK432, respectively. These results indicate that K562-reactive NK cells and/or their precursors may frequently be present at subthreshold levels in the lymph nodes draining breast carcinoma, and that the augmentation of LNL-mediated cytotoxicity by OK432 might provide a local potentiation of natural immune function at the host-tumor interface rather than IFN.     

Natural killer-sensitive targets stimulate production of TNF-alpha but not TNF-beta (lymphotoxin) by highly purified human peripheral blood large granular lymphocytes

Highly purified populations of large granular lymphocytes (LGL) have been shown to mediate natural killer (NK) cell activity. The mechanism of target cell killing by NK cells is as yet undefined; however, it has been postulated that such killing may involve soluble cytotoxic factors produced and secreted by NK cells. The data presented show that NK-sensitive, but not NK-resistant, tumor cell lines induce highly purified populations of human LGL to produce factors with cytotoxic and/or cytostatic activities. We have identified one of these factors as tumor necrosis factor-alpha (TNF-alpha), and have shown that production of this factor is enhanced by recombinant human interferon-gamma (rHuIFN-gamma). We have also examined the role of TNF-alpha in the cytotoxic function of NK cells. The data show that although highly purified LGL populations produce low levels of TNF-alpha, the cytotoxic/cytostatic activity of this lymphokine on tumor target cells does not correlate with the cytotoxic activity of highly purified populations of LGL on tumor target cells. Furthermore, NK cell-mediated cytotoxicity is not reliably inhibited by antibodies directed against various epitopes of recombinant human TNF-alpha and/or recombinant TNF-beta (lymphotoxin) or rHuIFN-gamma. These data show that although TNF-alpha is produced by highly purified NK-containing LGL cell populations, this factor does not appear to be responsible for NK cell cytotoxicity against classical NK target cells such as Molt-4 or K562. We suggest that NK function can be attributed to a combination of factors rather than to a single factor alone, and that at least two major phenomena are involved in LGL function: the rapid cytotoxic events which lead to the cell lysis measured in classical in vitro NK assays such as against K562; and the release of factors such as TNF-alpha with cytotoxic/cytostatic activities which would inhibit the growth of invading tumor cells in vivo.     

Effects of natural and recombinant IL 2 on regulation of IFN gamma production and natural killer activity: lack of involvement of the Tac antigen for these immunoregulatory effects

Highly enriched populations of human large granular lymphocytes (LGL), natural killer (NK) cells, and T cells were obtained from low and high density fractions, respectively, of discontinuous Percoll gradients. The NK cells were composed of 75 to 90% LGL, with the majority of the contaminating cells being monocytes. The T cells were greater than 95% OKT3+. The proliferative and cytotoxic progenitors in both fractions were examined by using a limiting dilution assay with interleukin 2 (IL 2) from four sources: 1) crude supernatant of a gibbon lymphoma (MLA-144), 2) purified (150,000-fold) MLA-144 IL 2, 3) partially purified human IL 2, and 4) purified recombinant human IL 2. The proliferative capacity was measured at day 7 by [3H]thymidine incorporation, whereas the progenitors of cells with NK-like activity were evaluated by assessing cytotoxic activity against K562 cells at day 8 in a 4-hr 51Cr-release assay. The frequency of proliferative progenitors among T cells was approximately 1/5 and was approximately 1/60 with LGL. Titration of the highly purified IL 2 preparation demonstrated that LGL proliferated with as little as 2 U of IL 2. The frequency of detectable cytotoxic progenitors in the LGL population, however, fell sharply when less than 40 U of IL 2 were employed. The T cells failed to demonstrate cytotoxic activity against the NK-susceptible target cells at any concentration of IL 2 tested. The IL 2 preparations also were examined for their ability to directly and rapidly enhance the cytotoxic activity of highly purified NK cells. All four preparations of IL 2 enhanced the cytotoxic activity of LGL without any detectable accessory requirement after incubation for as little as 6 hr, even though the MLA-144 IL 2 preparations were devoid of detectable interferons (IFN). These data indicate that IL 2 has dual effects on NK cells, regulating their activity was well as promoting their proliferation. Collectively, these results demonstrate that highly purified IL 2, devoid of other detectable lymphokines, is capable of supporting the growth of human NK cells and augmenting their in vitro activity. In parallel experiments, these same IL 2 preparations were quite active in causing the proliferation of T lymphocytes, clearly demonstrating a role of IL 2 in promoting the proliferation of NK cells as well as T cells. The mechanism of IL 2 boosting appears to be a direct interaction with LGL, resulting in the production of IFN gamma.(ABSTRACT TRUNCATED AT 400 WORDS)     

Natural killer cell-mediated antitumor reactivity of rhesus monkeys

We have analyzed natural killer (NK) cell-mediated antitumor activity or peripheral blood mononuclear cells of rhesus monkeys. All monkeys displayed significant NK cell cytolytic activity against the human tumor cell lines K-562, Daudi and CEM in a short-term (3 h) 51Cr-release assay. Similar to NK cells described in other species, the cytotoxic cells of monkeys were relatively nonadherent to nylon wool columns, exhibited low density after separation on discontinuous Percoll density gradients, and displayed large granular lymphocyte (LGL) morphology. Analysis of the mechanism of NK cell cytotoxicity of rhesus monkeys demonstrated that on the average, 7.1% (range: 3.1-13.2%) of lymphocytes bound to K-562 tumor, and that approximately 14.8% (range: 7.9-26.3%) of these tumor-binding cells (TBC) were cytolytically active. Examination of TBC on cytocentrifuge slides indicated that the majority of binders displayed LGL morphology. The cytotoxic reaction mediated by monkey NK cells exhibited Michaelis-Menten kinetics pattern; the maximum rate of lysis (Vmax) of K-562 was found to be 1-2 X 10(4) following 3 h of incubation. Using similar culture conditions, the recycling capacity of NK cells of this species was estimated at 2-6 times. Finally, it was observed that the NK cell activity of most monkeys could be potentiated following in vitro exposure to the biological response modifier, interleukin-2.     

Cytotoxic activity against trophoblast and choriocarcinoma cells of large granular lymphocytes from human early pregnancy decidua

Large granular lymphocytes (LGL) are the most abundant cell type in first trimester human pregnancy decidua. We have shown previously that CD56-positive decidual LGL have cytotoxic activity against the natural killer (NK) target K562, and that this cytotoxicity is augmented by pretreatment with interleukin-2 (IL-2). We now report that flow cytometrically purified populations of CD56-positive decidual LGL have no cytotoxic activity against either the BeWo choriocarcinoma cell line or freshly isolated term trophoblast. Incubation of unfractionated decidual cells with IL-2 induced cytotoxicity against BeWo, but term trophoblast remained resistant to lysis. Both BeWo and trophoblast showed much lower binding frequencies to decidual or peripheral blood cells than K56 targets, and excess trophoblast did not inhibit cytotoxic activity against K562. This suggests that the resistance of trophoblast to lysis by either decidual or peripheral blood LGL is due to the lack of accessible NK target structures on the surface of trophoblast.     

Characterization of the cytolytic reaction mechanism of the human natural killer (NK) lymphocyte: resolution into binding, programming, and killer cell-independent steps

Various parameters of the cytolytic reaction mechanisms of the human natural killer (NK) lymphocyte were studied to characterize the lytic cycle. NK cytolysis was determined to occur in three definable steps. 1) Binding of PBL to the NK-sensitive targets Molt-4 or K562 was rapid (less than 1 min), occurred at temperatures below 37 degrees C, was Mg++3-dependent, Ca++3-independent, and was prevented by dispersion of the cells into 10% dextran. 2) Subsequent to binding, programming for lysis as determined by a Ca++ pulse method was more protracted, requiring up to 2 hr to occur and was strictly dependent on Ca++ for cytolysis to proceed. In standard cytotoxicity assays, however, programming for lysis was more rapid occurring in 10 to 30 min. Programming was inhibited by EDTA, EGTA/Mg++ and by temperatures below 37 degrees C. Furthermore, after binding but in the absence of initiation of programming for lysis, the frequency of target binding cells did not change and the NK cell did not lose its lytic potential. 3) Killer cell-independent cytolysis (KCIL) was determined by the addition of EDTA to "programmed" targets and dispersion of these cells into dextran-containing medium, which resulted in virtually 100% dissociation of conjugated cells. KCIL was Ca++ and Mg++-independent and was blocked at reduced temperatures only if the dextran was prechilled to 4 degrees C before addition. The kinetics of 51Cr release during KCIL was rapid and complete 30 min after dispersion. Interferon-activated NK cells expressed an increased rate of cytolysis in Ca++ pulse experiments. This was due to an increased rate of the Ca++-dependent step(s) during the programming events. The rate of the Ca++-independent steps, however, were similar with control and IFN-activated cells.     

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.     

Selective inhibition of leukotriene C4 synthesis and natural killer activity by ethacrynic acid

We have investigated the role of arachidonic acid (AA) metabolism in natural killer (NK) cell activity. Human nonadherent (NA) peripheral blood lymphocytes were used as effector cells against 51Cr-labeled K562 target cells. Synthesis of leukotriene C4 (LTC4) is dependent on glutathione S-transferase (GST). We have chosen to study three putative GST inhibitors, namely, ethacrynic acid (ET), caffeic acid (CA), and ferulic acid (FA), with regard to NK activity and with regard to their effect on AA metabolism. The GST inhibitors inhibited NK lysis when added directly to the NK assay. The GST inhibitors inhibited LTC4 synthesis as induced by calcium ionophore A23187 in a dose-dependent manner similar to their inhibition of NK activity. However, only ET was selective, for it had little effect on LTB4, 5-hydroxyeicosatetraenoic acid, and prostaglandin E2 synthesis. LTC4 synthesis was associated with the NK-enriched fractions obtained from discontinuous Percoll gradients. NK-specific anti-Leu-11b antibody and C treatment could abrogate NK activity and LTC4 synthesis. ET was also inhibitory when NA cells were cultured at 37 degrees C for 18 hr. In this case, LTC4 could reverse the inhibitory effect of ET. Our data suggest that LTC4 plays an important role in NK activity.     

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.     

Generation of large granular T lymphocytes in vivo during viral infection

Cytolytic lymphocytes were isolated from the spleens of lymphocytic choriomeningitis virus (LCMV)-infected mice and were characterized in regards to function, cell size, antigen phenotype, and cell morphology. Only 2% of the Lyt-2+ cells from uninfected mice were large granular lymphocytes (LGL), whereas 21% of the Lyt-2+ cells isolated 7 days postinfection were LGL. The day 7 Lyt-2+ populations contained all of the LCMV-specific, class I histocompatibility antigen-restricted cytotoxic T lymphocyte (CTL) activity, but no natural killer (NK) cell activity. The NK cell activity was consistently recovered in Lyt-2- populations isolated from both control mice and mice on day 7 postinfection. The LGL isolated on day 7 postinfection were concluded to be predominantly T cells and not NK cells because 1) the proportions of LGL in fractionated cell populations 7 days postinfection correlated with levels of CTL-mediated lysis but not NK cell-mediated lysis, 2) they were recovered in the Lyt-2+ population, and 3) antibody to asialo GM1, known to eliminate NK cell-mediated lysis but not T cell-mediated lysis, dramatically reduced NK cell LGL numbers in vivo on day 3 postinfection but only marginally affected LGL numbers on day 7. Virus-induced inflammation elicited a 50-fold increase in LGL numbers in the peritoneum on day 7 postinfection. The peritoneal exudate LGL were also associated with CTL activity and were resistant to treatment with antibody to asialo GM1. These results indicate that in vivo-generated CTL have the morphology of LGL and that the appearance of cytoplasmic granules correlates with the ability of cells to mediate lysis. To focus on cells being stimulated during infections, activated blast cells were separated from small resting cells by centrifugal elutriation. Coincidental with the peak in overall spleen leukocyte cytotoxic activity, the peaks of blast NK cells and CTL were at days 3 and 7 postinfection respectively. More than 50% of the blast lymphocytes isolated on either day 3 or day 7 postinfection were LGL. The CTL activity in the blast populations on day 7 postinfection was mediated by Lyt-2+ cells, and 37 to 64% of these Lyt-2+ blast cells were LGL. Cytolytic NK cell and CTL LGL could not be distinguished by morphology or by cell densities, because they overlapped in low density Percoll gradient fractions. Since this technique has been used to enrich for LGL, these data indicate that heterogeneity in LGL populations may result from the presence of both CTL and NK cell LGL.     

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.     

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.     

Chemotaxis of large granular lymphocytes

The hypothesis that large granular lymphocytes (LGL) are capable of directed locomotion (chemotaxis) was tested. A population of LGL isolated from discontinuous Percoll gradients migrated along concentration gradients of N-formyl-methionyl-leucyl-phenylalanine (f-MLP), casein, and C5a, well known chemoattractants for polymorphonuclear leukocytes and monocytes, as well as interferon-beta and colony-stimulating factor. Interleukin 2, tuftsin, platelet-derived growth factor, and fibronectin were inactive. Migratory responses were greater in Percoll fractions with the highest lytic activity and HNK-1+ cells. The chemotactic response to f-MLP, casein, and C5a was always greater when the chemoattractant was present in greater concentration in the lower compartment of the Boyden chamber. Optimum chemotaxis was observed after a 1 hr incubation that made use of 12 micron nitrocellulose filters. LGL exhibited a high degree of nondirected locomotion when allowed to migrate for longer periods (greater than 2 hr), and when cultured in vitro for 24 to 72 hr in the presence or absence of IL 2 containing phytohemagluttinin-conditioned medium. The chemotactic LGL was HNK-1+, OKT11+ or HNK-1+, OKT11- on the basis of monoclonal antibody and complement depletion. They did not bear either T cell or monocyte cell surface markers, exhibiting an OKT3-, OKT4-, OKT8-, OKM1-, and MO2- phenotype, and did not form E rosettes at 29 degrees C, which is characteristic of lytic NK cells in contrast to T cells. Furthermore, a rat LGL leukemia (RNK) exhibited a chemotactic response to both f-MLP and casein. LGL chemotaxis to f-MLP could be inhibited in a dose-dependent manner by the inactive structural analog CBZ-phe-met, and the RNK tumor line specifically bound f-ML[3H]P, suggesting that LGL bear receptors for the chemotactic peptide.     

Activation of rat and human alveolar macrophage intracellular microbicidal activity by a preformed LGL cytokine

An alveolar macrophage-activating factor was released from Percoll fractionated large granular lymphocytes (LGL) within minutes of contact with either the natural killer (NK)-sensitive K562 tumor or heat-killed Staphylococcus aureus. The factor enhanced the intracellular killing of S. aureus without altering the rate of phagocytosis. Factor release was blocked by treatment of LGL with monensin, a carboxylic ionophore that inhibits vesicular traffic, but was unaffected by actinomycin D and cycloheximide pretreatment, suggesting that the cytokine was performed. The cell producing the factor was found only in Percoll fractions containing high concentrations of lytic NK cells and LGL, and the phenotypes of the LGL were HNK-1+ and E rosette-. The macrophage activating factor was a small protein of 10,000 to 20,000 daltons, as determined by gel fractionation, and was sensitive to proteolytic enzymes and heat and pH labile. Active supernatants were devoid of antiviral (interferon; IFN) or interleukin 2 (IL 2) activity, and IFN-beta, IFN-gamma, IL 2, and interleukin 1 were unable to activate staphylococcidal activity, suggesting that the LGL macrophage activating factor was distinguishable from these cytokines.     

Relationship between target cell recognition and temporal fluctuations in intracellular Ca2+ of human NK cells

Temporal changes in intracellular Ca2+ concentration, [Ca2+]i, of resting human peripheral blood NK cells in response to target cell binding were evaluated by flow cytometry. [Ca2+]i was significantly elevated in PBL and purified NK cells bound to NK-sensitive K562 and HSB2 target cells, but not in those bound to NK-resistant MD1 B-lymphoblastoid cells. Thus, a) the ability of a target cell to elicit a Ca2+ flux response correlated with its sensitivity to lysis of NK cells, and b) adhesion alone was not a sufficient stimulus for response induction. Conjugates of NK cells bound to K562 target cells were sorted onto agarose-coated slides on the basis of relative NK cell [Ca2+]i and evaluated in 19-hr single cell agarose cytotoxicity assays. In contrast to those with basal levels of [Ca2+]i, NK cells with elevated [Ca2+]i bound more strongly to target cells, as judged by the stability of conjugates to sort-related shear forces (p less than 0.01), and more frequently killed the target cell to which they were attached (p less than 0.05). Temporal fluctuations in [Ca2+]i were observed in target-bound NK cells in both the presence and absence of extracellular Ca2+. Thus, influx of extracellular Ca2+ and release of Ca2+ from internal stores both appeared to contribute to the NK cell Ca2+ flux response triggered by adhesion to appropriate target cells. These results support the hypothesis that such fluctuations in NK cell [Ca2+]i constitute an early signal flagging the occurrence of NK cell recognition.     

Phospholipase C treatment of certain human target cells reduces their susceptibility to NK lysis without affecting binding or sensitivity to lytic granules.

Phosphatidylinositol-specific phospholipase C (PI-PLC) is an enzyme that has the capacity to release glycosyl-phosphatidyl inositol (G-PI)-anchored proteins from the cells surface. Pretreatment of the human T-cell leukemia cell line Molt-4 with PI-PLC resulted in a decrease in the susceptibility to lysis by natural killer (NK) cells. Treatment of the erythroleukemia cell line K562 with PI-PLC had no effect on its NK susceptibility. PI-PLC-treated and untreated Molt-4 bound equally well to lymphocytes in target-binding studies with effector cell preparations enriched for NK cells. Susceptibility to cytolytic granules isolated from rat LGL tumor cells remained the same after treatment of Molt-4 or K562 with PI-PLC. Combined treatment of Molt-4 with PI-PLC and rlFN-alpha or rlFN-gamma resulted in additive reductions of the NK susceptibility, suggesting that PI-PLC and interferons act on different mechanisms to protect cells from NK lysis. When expression of a number of antigens on Molt-4 and K562 was analyzed in flow cytometry, only the expression of CD58 was reduced after PI-PLC treatment. The susceptibility of Con A blasts to MLR derived cytotoxic T-cells was not altered by treatment with phospholipase. These data suggest that PI-PLC treatment reduces the capacity of some target cells to activate NK cells upon contract. The mechanism behind this phenomenon is presently unclear.