Effect of histamine and histamine antagonists on natural and antibody-dependent cellular cytotoxicity of human lymphocytes in vitro

The in vitro effect of histamine and its antagonists, cimetidine and clemastine fumarate, on natural killer (NK) and antibody-dependent cellular Cytotoxicity (ADCC) activities of human lymphocytes was investigated. The histamine 1 (H1) antagonist, clemastine fumarate, and the histamine 2 (H2) antagonist, cimetidine, but not histamine alone, inhibited the NK and ADCC activities of lymphocytes when added directly to the mixture of effector and target cells in a ⁵¹Cr-release assay. This inhibition was proportional to the concentration of drugs added and was observed at various effector to target ratios against several targets. H1 and H2 antagonists also inhibited NK activities of T cells as well as Percoll-separated, NK-enriched effector cells. The inhibition was significantly reversed by histamine. In target binding assays, clemastine fumarate and cimetidine also decreased the target binding capacity of effector lymphocytes. Further, PBL precultured with histamine (10^?3–10^?4M) for 24 hr showed a significant decrease in their NK and ADCC activities. In coculture experiments, PBL precultured with histamine suppressed the NK activity of normal autologous effector lymphocytes. PBL precultured with histamine showed an increased number of OKT8⁺ cells, as estimated using monoclonal antibodies. The suppression of Cytotoxicity was not due to either direct toxicity, steric hindrance, crowding, or cell death, but by functionally viable suppressor cells. An immunoregulatory role for histamine in NK and ADCC reactions is proposed.     

Association of decreased natural and antibody-dependent cellular cytotoxicity and production of natural killer cytotoxic factor and interferon in neonates

Cord blood lymphocytes (CBL) were compared with adult peripheral blood lymphocytes (a-PBL) for their: (i) natural killer (NK) and antibody-dependent cellular cytotoxic (ADCC) activities, (ii) target-binding capacity, (iii) ability to induce soluble natural killer cytotoxic factor (NKCF), (iv) interferon (IFN)-, interleukin 2 (IL-2)-, and lectin-induced augmentation of NK activity, and (v) ability to produce IFN against tumor targets in vitro. CBL depleted of adherent cells and Percoll-separated, NK-enriched subpopulations demonstrated significantly lower NK, ADCC, and target-binding activities compared to a-PBL. CBL produced significantly lower levels of NKCF directed against K562 tumor targets in comparison with a-PBL. Although the NK activity of CBL was not stimulated by either IFN or IL-2 to the same levels shown by a-PBL, the percentage enhancement of cytotoxicity of CBL by IFN and IL-2 was greater than that of a-PBL. Lectin-induced enhancement of cytotoxicity was significantly greater for CBL in comparison with a-PBL. Further, the ability of CBL lymphocytes to produce IFN-gamma in vitro against K562 target cells was significantly lower than that of adult PBL. These studies suggest an association between decreased NK, ADCC, and target-binding activities, induction of NKCF and IFN production by CBL, and increased susceptibility of neonates to infection.     

Suppression of human natural and antibody-dependent cytotoxicity by soluble factors from unstimulated normal lymphocytes

Serum-free culture supernatants of unstimulated normal human peripheral blood mononuclear cells contain soluble suppressor factor(s) (SSF) that significantly inhibit natural (NK) and antibody-dependent cellular cytotoxic (ADCC) activities of allogenic lymphocytes against a variety of target cells. Lymphocytes precultured with increasing concentrations of SSF showed a dose-dependent suppressive effect on these cytotoxic functions that was optimal at a concentration of 20% volume/volume. Adherent cells were not required for the production of SSF. Suppression was evident even at higher effector: target cell ratios and the inhibition was not reversed by washing lymphocytes. SSF was not itself cytotoxic, was stable at 56 degrees C, and its suppressive effect was maximal after 72 hr of incubation with effector lymphocytes. Initial estimate of the molecular weight of SSF by ultra-filtration was less than 20,000 daltons. Gel filtration of SSF on Sephacryl S-200 resulted in the elution of two peaks of activity; one in the region between markers of 13,700 and 25,000 daltons, and the other less than 13,700 daltons. Both fractions demonstrated significant suppressive activity on NK and ADCC functions of allogenic lymphocytes. SSF inhibition of NK activity could be partially reversed by incubating lymphocytes for 1 hr with human leukocyte interferon (IF) and almost completely reversed after 24 hr of IF treatment. A few selected monosaccharides (alpha-methyl-D-mannoside, L-fucose and L-rhamnose) showed a dose-dependent blocking effect on SSF activity, which suggests that SSF may act via receptor sites recognized by these sugars. As demonstrated for other lymphocyte functions, NK and ADCC activities may also be modulated by SSF elaborated by normal PBL.     

Inhibition of human natural killer (NK) activity and antibody dependent cellular cytotoxicity (ADCC) by lipomodulin, a phospholipase inhibitory protein

A highly purified preparation of lipomodulin, a phospholipase-inhibitory protein from rabbit neutrophils treated with glucocorticoids, inhibited NK and antibody-dependent cellular cytotoxicity (ADCC) activities of human peripheral blood lymphocytes in a dose-dependent manner. The presence of lipomodulin during the early period of the cytotoxicity assay was necessary to obtain maximal inhibition. The inhibition of NK or ADCC activity by lipomodulin was greater when effector cells were treated with lipomodulin than when target cells were incubated with lipomodulin. As lipomodulin did not block binding of effector cells to target cells, our results suggest that lipomodulin inhibits the cytolytic phase of NK and ADCC activities after binding to target cells, and imply that phospholipase(s) may be involved in NK and ADCC activities.     

Inhibition of natural killer cell activity by IgA

The in vitro effect of IgA on natural killer (NK) activities of human peripheral blood mononuclear cells was investigated. Purified myeloma polymeric IgA2 (pIgA2) and secretory IgA (S-IgA) from human colostrum inhibited NK activity, while myeloma polymeric IgA1 (pIgA1), monomeric IgA1 (mIgA1), IgG, and IgM were ineffective. Inhibition was proportional to the concentration of pIgA2 (0.125-1 mg/ml) and was observed after as little as 1 hr of incubation at various effector to K562 target cell ratios. pIgA2 and S-IgA also inhibited NK activity of NK cell-enriched lymphoid cells and gamma-interferon-treated effector cells, but did not interfere with effector-target cell binding. The inhibitory effect was slightly diminished after 24 hr culture in pIgA2-free medium. Inhibition of cytotoxicity was not due to direct toxicity on lymphoid cells by IgA because PBL treated with pokeweed mitogen in the presence of pIgA2 or S-IgA differentiated into immunoglobulin-producing cells. Viability after 24 hr of preculture with pIgA2 and S-IgA was comparable to that of untreated control cells. Morphological examination of effector cells cultured with pIgA2 or S-IgA showed a decrease in the number of granules, and the formation of cytoplasmic vacuoles. These morphological changes appeared to coincide with the depressed cytotoxicity of NK cells. The results demonstrate that purified pIgA2 and S-IgA have significant immunomodulatory effects on human NK activity.     

Target cell-directed inactivation and IL-2-dependent reactivation of LAK cells

In a previous study, we demonstrated that human natural killer cells (NK) lost their lytic activity after interaction with a sensitive target. The loss of NK activity also led to the loss of antibody-dependent cellular cytotoxicity (ADCC), prompting us to postulate that NK and ADCC activities may result from a common lytic mechanism. In this study, we examined whether nonadherent lymphocytes cultured 7 days in the presence of IL-2 (lymphokine-activated killer (LAK) cells) could also be inactivated and, subsequently, be reactivated in the presence of IL-2. We tested three populations of effector cells (EC): cells isolated from freshly drawn blood and tested immediately, cells cultured with IL-2 for 18 hr, and LAK cells. Once they have interacted with K562, all three cell populations lost greater than 90% of their NK-like lytic activity (NK-CMC) but only 80% of ADCC. However, when we treated the three cell types with antibody-coated K562, they lost 90-99% of NK-CMC and 90-97% of ADCC. In these inactivated effector cells we also observed: (i) a reduction in membrane expression of C-reactive protein; and (ii) a decrease in the expression of Leu-11a when EC were inactivated with antibody-coated K562. The loss of lytic activity against K562 was accompanied by a concomitant loss of activity against other LAK-sensitive targets as well as against antibody-coated targets (ADCC). In competitive inhibition experiments the inactivated effector cells failed to inhibit normal NK-CMC and ADCC activities mediated by fresh NK cells. As we have shown previously, this target-directed inactivation was not due to cell death or to lack of conjugate formation. Inactivated LAK cells regained their lytic potential when cultured with IL-2 and this effect was time dependent. By 72 hr, LAK cells inactivated with K562 regained 99% NK-CMC and 82% ADCC, whereas LAK cells inactivated with antibody-coated K562 regained only 80% NK-CMC and 70% ADCC. When we treated the effector cells with emetine, a potent inhibitor of protein synthesis, we could still inactivate the effector cells with K562 and with antibody-coated K562 but could not reactivate them with IL-2.     

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

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

Cells of the J774 macrophage cell line are primed for antibody-dependent cell-mediated cytotoxicity following exposure to gamma-irradiation.

Activation of macrophages (M phi) for host defense against tumor cells follows a sequence of priming events followed by an initiating stimulus that results in production and release of cytotoxic molecules that mediate target cell killing. We have developed a model to study specific macrophage cytotoxicity in vitro utilizing a cultured murine M phi cell line, J774. Specific cytotoxicity of cultured human gastrointestinal tumor cells is achieved in the presence of murine IgG2a monoclonal antibody (mAb) 17-1-A. The ability of these cells to mediate antibody-dependent cell-mediated cytotoxicity (ADCC) is greatly enhanced following gamma-irradiation. ADCC can be demonstrated at mAb 17-1-A concentrations greater than or equal to 1 microgram/ml and effector/target cell ratios greater than or equal to 2. Exposure to doses greater than or equal to 10 Gy of gamma-irradiation increases ADCC threefold. Varying the duration from J774 M phi exposure to gamma-irradiation until addition of antibody-coated target cells showed that the primed state for ADCC is stable for at least 8 days but approximately 24 hr is required for complete development of the primed state. mAb-dependent target cell death begins 8 hr after addition of mAb and labeled target cells to primed effector cells and is complete by 24 hr. Incubation of unirradiated J774 M phi effector cells with recombinant murine interferon-gamma (rmIFN-gamma) also results in enhanced ADCC, but the extent of target cell killing achieved is less than that following priming by gamma-irradiation. Concomitant priming of gamma-irradiated J774 M phi with rmIFN-gamma increases the extent of ADCC. Further study of irradiated J774 cells may elucidate the molecular pathways utilized by M phi for achieving and maintaining the primed state for ADCC. Irradiated J774 cells will also provide a homogenous, stably primed cell type in which to examine the mechanism(s) of cytotoxicity employed by tumoricidal M phi.     

Enhancement of natural cytotoxicity by beta-endorphin

The role of enkephalins, beta-endorphin, or other neuropeptides produced by the nervous system in the alteration of immune responsiveness is generally unknown. The present studies were undertaken to investigate the role of these neuropeptides in the modulation of human spontaneous cytotoxicity induced by natural killer (NK) cells. Natural cytotoxicity was measured by using a standard 51Cr release assay with radiolabeled K562 cells. NK activity was significantly enhanced by both beta-endorphin (30.5 +/- 11.5%, M +/- SE, relative enhancement at 50:1, effector:target (E:T) ratio, 10(-14)M beta-endorphin) and methionine-enkephalin (met-enkephalin) (27.4 +/- 9.7% relative enhancement at 10(-9)M). The magnitude of relative enhancement significantly correlated with increasing concentrations of beta-endorphin. Leucine-enkephalin, alpha-endorphin, and morphine did not augment NK activity. The enhancement of NK activity with beta-endorphin increased at all E:T ratios tested. Naloxone inhibited the augmentation of NK activity produced by beta-endorphin and met-enkephalin. By using a combination of a standard 51Cr release and soft agarose single cell analysis assays, beta-endorphin increased both the number of E:T cell conjugates and the number of active killer cells among target-binding cells. The maximal effector cell recycling capacity was increased by 170%. These studies provide new insight into the mechanisms by which neuropeptides produced by the nervous system can alter immune responsiveness.     

Histamine-induced suppressor factor inhibition of NK cells: reversal with interferon and interleukin 2

Culture supernatants of lymphocytes stimulated with 10(-3) to 10(-8) M histamine contain histamine-induced soluble suppressor factor (HISSF) that significantly inhibits the natural killer (NK) cell functions of allogeneic lymphocytes. Lymphocytes precultured with increasing concentrations of HISSF showed a dose-dependent suppressive effect on their NK activity. HISSF was not cytotoxic itself and produced suppressive effects on PBL, NK-enriched large granular lymphocytes (LGL), and isolated T cells. Suppression was evident throughout a range of effector:target cell ratios. Production of HISSF was specifically blocked by the H2 antagonist cimetidine, but not by the H1 antagonist clemastine fumarate. Furthermore, H1 and H2 antagonists themselves do not induce production of HISSF. Although HISSF could inhibit the cytotoxicity of LGL, LGL themselves do not produce HISSF. HISSF inhibition of NK activity could be completely reversed by treating effector lymphocytes with recombinant interferon-alpha (IFN) for 1 or 2 hr or culturing them with purified interleukin 2(IL 2) for 36 hr. Our data suggest that exogenous IFN and IL 2 may have therapeutic potential in the treatment of immunological diseases associated with histamine-induced suppressor cell activity.     

Activation of human B lymphocytes. XVII. Synergy between nonspecific and specific signals in the antigen-specific responses of human B cells

The incubation of human peripheral blood lymphocytes (PBL) with the natural killer (NK)-sensitive MOLT-4 cell line results in PBL-target cell conjugate formation by certain lymphocyte subpopulations. Following velocity sedimentation, the PBL depleted of these conjugate-forming subpopulations are markedly diminished in the ability to mediate either antibody-dependent cellular cytotoxicity (ADCC) or NK activity. The immediate testing of highly pure PBL subpopulations isolated from the NK target conjugates does not reveal the expected recovery of augmented ADCC or NK levels. Following in vitro incubation, however, the PBL NK target-binding subpopulations do manifest augmented levels of both NK and ADCC, whereas the depleted PBL continue to display diminished NK and ADCC levels. In addition, the degree of augmented NK and ADCC levels recovered by the NK target-binding PBL subpopulations appears dependent on both the time and the temperature of in vitro incubation. Moreover, the ADCC recovery patterns are identical to those observed for NK activity regardless of the time and temperature of in vitro incubation. These results directly demonstrate that the PBL subpopulations isolated from certain NK target cells are functionally enriched in the ability to mediate from ADCC and NK activity.     

Human monocyte-macrophage-mediated antibody-dependent cytotoxicity to herpes simplex virus-infected cells.

Human peripheral blood mononuclear cells which mediate antibody-dependent cellular cytotoxicity (ADCC) against herpes simplex virus- (HSV) infected target cells consist of both adherent (MA) and nonadherent (MNA) effector cell populations. These two cell populations can be distinguished by their different phagocytic properties and morphologic appearance, their requirement for antibody in the ADCC reaction, and the rapidity with which they lyse target cells in the presence of immune serum. The MA cells are predominantly phagocytic and have the morphologic characteristics of monocyte-macrophages, whereas the MNA cells are nonphagocytic and appear to be small to medium-sized lymphocytes. Optimal expression of ADCC by MA cells requires higher concentrations of immune serum than does MNA cell-mediated ADCC. MA-mediated cell killing is first detectable by 8 hr and reaches completion after 24 hr of incubation. In contrast, MNA-mediated ADCC produces target cell damage by 2 hr and reaches completion at 8 hr of incubation. Unlike MNA effector cells, the MA effector cells are profoundly inhibited after preincubation with either latex or silica particles. The HSV immune status of the donor had no effect on the ability of either cell population to mediate ADCC. These data demonstrate the participation of both nonadherent mononuclear cells, presumably K cells, and monocyte-macrophages, in ADCC directed against HSV-infected target cells.     

A Human Anti-M2 Antibody Mediates Antibody-Dependent Cell-Mediated Cytotoxicity (ADCC) and Cytokine Secretion by Resting and Cytokine-Preactivated Natural Killer (NK) Cells

The highly conserved matrix protein 2 (M2) is a good candidate for the development of a broadly protective influenza vaccine that induces long-lasting immunity. In animal models, natural killer (NK) cells have been proposed to play an important role in the protection provided by M2-based vaccines through a mechanism of antibody-dependent cell-mediated cytotoxicity (ADCC). We investigated the ability of the human anti-M2 Ab1-10 monoclonal antibody (mAb) to activate human NK cells. They mediated ADCC against M2-expressing cells in the presence of Ab1-10 mAb. Furthermore, NK cell pro-inflammatory cytokine and chemokine secretion is also enhanced when Ab1-10 mAb is present. We also generated cytokine-preactivated NK cells and showed that they still displayed increased effector functions in the presence of Ab1-10 mAb. Thus, our study has demonstrated that human resting and cytokine-preactivated NK cells may have a very important role in the protection provided by anti-M2 Abs.     

Virus-induced enhancement of lymphocyte-mediated antibody-dependent cytotoxicity (ADCC) in vitro

The effect of Parotis virus on antibody-dependent cellular cytotoxicity in vitro (ADCC) of human lymphocytes was investigated in a 51Cr-release assay and, at the effector cell level, in an ADCC plaque assay. Target cells were bovine or chicken erythrocytes, which are not susceptible to natural cytotoxicity (NK) of human lymphocytes. They were not killed when incubated with virus-treated lymphocytes in the absence of antibodies. Treatment of the lymphocytes or the target cells with small amounts of virus, however, resulted in a very significant enhancement of ADCC. The same results were obtained with live or UV-inactivated virus, suggesting that enhancement was a passive phenomenon not requiring infection. Enhancement was already significant after 3 hr of incubation, indicating that it was independent of endogenously released interferon. Enhancement of ADCC by virus was due to effector cell recruitment rather than due to the increase of the cytotoxic potential of the individual K cell. The highest frequency of effector cells was present in Percoll fractions enriched in large granular lymphocytes (LGL). Virus treatment resulted in recruitment of effector cells carrying T cell markers such as the T3 antigen (OKT3+), receptors for sheep erythrocytes, or Fc receptors for IgM. In contrast, the absolute number of K cells carrying the HNK-1 marker (Leu-7) or receptors for C3 fragments was not changed by the virus. It is concluded that Parotis virus enhances ADCC by improving effector cell-target cell contacts, resulting in recruitment of effector cells with T cell characteristics. Recruitment is accompanied by a significant reduction of the antibody concentration needed for ADCC induction. This virus-mediated enhancement of ADCC may be of importance for protection of the host in the early phases of a virus infection in which the amounts of anti-viral IgG antibodies capable of inducing cellular cytotoxicity may yet be very small.     

Natural killing (NK) and antibody-dependent cellular cytotoxicity (ADCC) in specific pathogen-free (SPF) miniature swine and germfree piglets. III. Two distinct effector cells for NK and ADCC

Effect of "anti-NK" sera on NK and ADCC activities was examined to study further the relationship between the effector cells for NK and ADCC in specific pathogen-free miniature swine. An appropriate dilution of "anti-NK" sera that had no effect on ADCC activity not only inhibited NK activity but also eliminated NK cells in the presence of C which supports the presence of NK cells distinct from K cells for ADCC.     

Effect of human recombinant interferon on cytotoxic activity of natural killer (NK) cells and monocytes

Studies have been performed on the in vitro immunologic effects of homogeneous recombinant human leukocyte interferon, IFLrA. Large granular lymphocytes, enriched for natural killer (NK) cell activity, were pretreated wtih IFLrA or natural interferon preparations and then tested for augmentation of NK activity and of antibody-dependent cell-mediated cytoxicity (ADCC). Monocytes were tested for cytolytic and cytostatic activity in 48–72 hr radioisotopic assays performed in the presence or absence of interferon. Treatment with IFLrA caused significant augmentation of NK, ADCC, and monocyte-mediated cytotoxic activities. Even 10 units of IFLrA induced augmentation of NK activity, and 100 units or more boosted monocyte-mediated activity. The effects in each of these assays were species-specific, with no detectable effects on the activity of mouse effector cells. These results indicate that homogeneous recombinant interferon has potent in vitro immunomodulating effects and thus provide a basis for carefully examining the in vivo effects of this protein on host defenses in forthcoming clinical trials with cancer patients.     

Virus-mediated induction in human lymphocytes of antibody-independent cytotoxicity (VDCC) and enhancement of antibody-dependent cytotoxicity (ADCC) against natural killer-resistant tumor target cells

The effect of Parotis virus on the in vitro cytotoxicity of human lymphocytes against NK-resistant mouse mastocytoma cells was studied. In the ⁵¹Cr-release assay, treatment of lymphocytes with virus induced a rapid cytotoxicity in the absence of anti-P8 15 antibody (virus-dependent cellular Cytotoxicity, VDCC) and strongly enhanced antibody-dependent cytotoxicity (ADCC). At the effector cell level, virus treatment was found to increase the frequency of target-binding cells (TBC) as well as the proportion thereof mediating VDCC and/ or ADCC, indicating recruitment of active effector cells. The recruited cells were heterogeneous but contained a major fraction bearing the T-cell-associated antigen T3. Virus was found to decrease rather than to increase the recycling capacity of the cytotoxic lymphocytes, suggesting that VDCC induction and ADCC enhancement were due to a virus-mediated improvement of effector cell-target cell interactions. VDCC and ADCC enhancement may be of protective importance in early phases of virus infection as well as for the production of nonspecific tissue injuries associated with viral disease.     

Depletion of NK cells with the lysosomotropic agent L-leucine methyl ester and the in vitro generation of NK activity from NK precursor cells

Human natural killer (NK) cell activity in peripheral blood lymphocytes (PBL) is totally inhibited by pretreatment of the effector cells with a lysosomotropic agent, L-leucine methyl ester (LeuOMe). This treatment specifically eliminates cells expressing the NK cell markers HNK-1, OKM1, B73.1, or Leu-11b, but has minimal effect on viability of cells with T cell markers Leu-1, OKT3, Leu-2a, or Leu-3a. LeuOMe also drastically decreased the proportion of K562 target-binding lymphocytes among PBL. PBL pretreated with LeuOMe respond normally in thymidine uptake to stimulation by phytohemagglutinin or allogeneic lymphocytes as long as irradiated autologous accessory cells are provided, indicating that the treatment is not toxic to T cells. NK activity can be regenerated in the NK cell-depleted PBL population by incubation with IL 2 or by mixed lymphocyte cultures, but not by alpha-interferon. Cells responsible for regeneration of such NK activity are probably large agranular lymphocytes, because they are resistant to LeuOMe treatment but have the same low buoyant density as NK cells in Percoll density gradient separation. The in vitro-generated NK is still sensitive to LeuOMe inhibition, but a higher concentration of the reagent is required to achieve total inhibition of the activity.     

Characterization of human K cells by surface antigens and morphology at the single cell level

Human lymphocytes killing bovine erythrocytes in vitro in antibody-mediated reactions were characterized at the effector cell level in the ADCC plaque assay. Five to 10% of highly purified peripheral blood lymphocytes are active K cells in this system. Forty to 50% of these were T gamma cells expressing the T cell-associated surface antigens T3 and Leu-1. These cells also expressed the T8/Leu-2a antigens (approximately 20%) or the T4/Leu-3a antigens. Although approximately 30% of the K cells were T4+ when examined after completion of the ADCC assay (18 hr), only less than 10% were T4+ (and Leu-3a+) when examined before the assay. The results indicated that exposure to antigen/antibody complexes during the assay induced increased T4 expression, probably linked to Fc gamma R modulation on some initially T4-/T3+ lymphocytes. The expression of the other antigens (including Leu-3a) was not affected by exposure of the lymphocytes to antigen/antibody complexes. Two-color fluorescence experiments further demonstrated that a minor fraction (10 to 20%) of the K cells carrying T cell-associated antigens also expressed the monocyte/null cell-associated antigen M1 as detected with the monoclonal antibody OKM1. A second major category of effector cells, composed of at least 25% of the K cells, were large granular lymphocytes (LGL) that lacked detectable T cell-associated antigens but expressed the HNK-1 (Leu-7) as well as the M1 antigen. As seen from the size of the plaques formed by different effector cells, K cells of the LGL type had a greater recycling capacity and/or cytolytic efficiency than those of T gamma type.     

Surface receptors and immune activity of purified human circulating mononuclear cells. III. The mechanisms of lysis, by lymphocytes and monocytes, of target cells in the lymphocyte-dependent and monocyte-dependent ADCC, NK, NOCC, and MICC cytotoxic reactions

The abilities of unfractionated mononuclear cells (MNC), monocytes (98-99% pure), and lymphocytes (98-99% pure) to carry out the lysis of target cells in the ADCC, NK, NOCC, and MICC assays were compared. Lymphocytes by themselves were able to lyse the CRBC (ADCC), K-562 (NK), and RRBC (MICC) target cells. The monocytes were very effective in the lysis of the CRBC (MICC) target cells. However, the lysis of two other target cells--RRBC (NOCC) and HRBC (ADCC)--required the simultaneous presence of both lymphocytes and monocytes in order to effect optimal lysis. Soluble factor(s) secreted by the cytotoxic cells capable of lysing the target cells were detected only in the NK assay. The activity of the soluble cytotoxic factor (NKCF) was only 25-40% of that exhibited by the cytotoxic NK cells and it was secreted by the cytotoxic cells after 48 hr of culture and not 24 hr of culture which is the usual assay condition. The NKCF was cytotoxic only to the NK target cells and not to the target cells used in the ADCC, NOCC, and MICC cytotoxic assays. Different classes of lymphocytes were cytotoxic in the monocyte-independent assays [ADCC (CRBC), NK (K-562), and MICC (RRBC)]. The null lymphocytes and the T lymphocytes were the primary cytotoxic cells in the ADCC and MICC assays, respectively, whereas the T, B, and null cells were almost equally cytotoxic in the NK assay. With respect to the monocyte-dependent assays [ADCC (HRBC), NOCC (RRBC), and MICC (CRBC)], the cytotoxic activity of any one class of lymphocytes failed to approach that of the unfractionated MNC. The T cells were the most cytotoxic; the B cells exhibited limited cytotoxic activity in only the ADCC assay and the null cells showed no cytotoxic activity. However, the combination of T and non-T cells and, to a lesser extent, T and B cells, exhibited much greater cytotoxic activity than the individual cells and together were as cytotoxic as the unfractionated MNC. It is concluded that, depending upon the selection of the target cells, lysis in the ADCC, NK, NOCC, and MICC assays may be effected by lymphocytes only, by monocytes only, by both monocytes and lymphocytes, or as a result of lymphocyte-monocyte collaboration. In the latter instance more than one class of lymphocytes must be present in order for maximum cytotoxic activity to be expressed.