Monoclonal antibody-defined surface markers of effector cells involved in human monocyte cytotoxicity

Human adherent peripheral blood mononuclear cells were cytotoxic in vitro against the murine TU5 line in a 48-hr [3H]thymidine-release assay. Monocyte-enriched adherent cell preparations contain a small and variable (usually less than 5%) contamination with large granular lymphocytes as assessed by morphology and staining with monoclonal antibody markers B73.1 and HNK1. To assess whether killing was in fact mediated by monocytes, mononuclear cells or monocyte-enriched preparations were separated using monoclonal antibodies directed against mononuclear phagocytes (Mo2, UCHM1, B44.1) or natural killer (NK) cells (B73.1 and HNK1), and a fluorescence-activated cell sorter. Cells positive for monocyte markers were highly cytotoxic against TU5, whereas negative cells were not. B73.1+ or HNK1+ cells had little or no activity. Cytotoxicity of cells positive for monocyte markers (Mo2, UCHM1, B44.1) was augmented by in vitro exposure to lymphokines or less frequently to interferon (IFN). However, cells negative for these monocytes markers were also stimulated to kill TU5 by lymphokine or IFN to an extent similar or greater than that of positive ones. IFN or lymphokines induced killing of TU5 by monocyte-depleted, B73.1-positive, lymphoid cells. These observations demonstrate that human monocytes do kill tumor cells, either in the absence of deliberate stimulation or after exposure to agents such as lymphokines. However, the possible contribution to "monocyte" cytotoxicity of minor NK cell contaminants must be taken into account particularly when agents such as IFN and lymphokines are applied, even when a relatively NK-cell-resistant target such as TU5 is used.     

Lipopolysaccharide stimulates monocyte adherence by effects on both the monocyte and the endothelial cell

The effects of the LPS moiety of endotoxin on monocyte adherence to an endothelial cell surface were investigated over times before the development of well described LPS-induced endothelial cell surface adhesive molecules. In an in vitro microtiter adherence assay, LPS in concentrations of 10 ng/ml to 10 micrograms/ml incubated for 20 to 60 min with human monocytes significantly stimulated monocyte adherence to human umbilical vein endothelial cell monolayers (HUVEC) and serum-coated plastic surfaces. The time course and concentration dependence of LPS-stimulated monocyte adherence to glutaraldehyde-fixed HUVEC did not differ significantly from that to unfixed HUVEC or serum-coated plastic surfaces. Pretreatment studies suggested that LPS acted on the monocyte within 25 min to stimulate adherence to untreated endothelial cells but required a minimum of 1.5 to 2 h to render the endothelial cell more adhesive for untreated monocytes. The potential role of TNF-alpha, IL-1 alpha, and IL-1 beta in this system was assessed by determining the ability of these cytokines (+/- cytokine antibodies) to increase monocyte adherence. TNF, but neither IL-1, stimulated early monocyte adherence (1 h). This TNF-stimulated monocyte adherence was abrogated by coincubation with anti-rTNF-alpha polyclonal antibody. However, the anti-rTNF antibody had no effect on LPS-induced monocyte adherence to endothelial cells or serum-coated plastic surfaces. An early action of LPS on the monocyte to induce adherence to endothelial cell surfaces may contribute to the initial localization of peripheral blood monocytes in tissues during endotoxemia. The later effects of LPS on the endothelial cell to stimulate monocyte adherence may then amplify these initial monocyte-endothelial cell interactions to prolong and intensify monocyte adherence prior to migration into tissues.     

Use of a microtitre plate chemiluminescence reader to study surface phagocytosis by human monocytes

Human mononuclear cells were separated from freshly obtained peripheral venous blood by density centrifugation and the number of monocytes present estimated by volume spectroscopy. The mononuclear cells were then placed directly into the wells of a microtitre plate and incubated for one hour at 37°C to promote adherence of the monocytes to the plastic wells. Non-adherent cells were then removed by washing, thus avoiding the need to treat the monocytes with EDTA or other reagents during cell preparation. The time course and dynamics of the chemiluminescence response of adherent monocytes towards opsonized zymosan was similar to those seen using non-adherent cells. The ability of adherent monocyte preparations to produce chemiluminescence following incubation for varying periods with T-lymphocyte conditioned medium was investigated. The use of a microtitre plate chemiluminescence reader allows several plates to be assayed over the 24-hour period and since small numbers of cells are required, many cultures can be analysed in one experiment. This technique (Patent applied for) promises to be a powerful tool for dissecting the cellular events which occur during macrophage activation and examining the effect of various lymphokines on the ability of monocytes to produce a chemiluminescence response.     

Potentiation of the cytolytic activity of peripheral blood monocytes by lymphokines and interferon

Human peripheral blood monocytes obtained by EDTA-reversible adherence to plastic surfaces precoated with autologous serum can rapidly lyse a variety of tumor cells. That the effector cells in this system are indeed monocytes has been demonstrated (1). Using a short-term (3 to 4 hr) 51Cr-release assay and the single cell conjugate cytotoxic assay, we studied the effects of lymphokine-rich supernatants containing gamma-interferon and partially purified fibroblast interferon on the monocyte cytolytic activity. Overnight incubation of the monocytes in fetal bovine serum-containing medium resulted in a relatively small decrease in cytotoxic activity compared to the one obtained with monocytes incubated in autologous serum. The addition of lymphokines or interferon under both incubation conditions resulted in augmented activity as measured in the 51Cr-release assay. However, the proportions of binding and cytotoxic monocytes, determined in the single cell conjugate assay, did not increase. These results suggest that augmented activity is not due to recruitment of inactive cells. Kinetics studies of tumor cell lysis indicate the increase in killing efficiency is probably due to both an increase in the rate of killing and in the recycling ability of the cytotoxic cells. Using the conjugate/agarose technique, we also demonstrated that excess tumor cells could impair the lytic machinery of freshly isolated monocytes, whereas monocytes treated with lymphokines or interferon partially lost their sensitivity to this inhibitory effect. The ability of tumor cells to impair the lytic machinery of monocytes could be one of the mechanisms by which tumors escape immunosurveillance.     

Human monocyte cytotoxic factor mediates cytolysis of WEHI 164 cells

Human monocytes can be activated to release a 40,000-Da cytostatic protein factor (CF). In this report we have investigated the cytolytic activity of CF on WEHI 164 cells which are sensitive to monocyte-mediated cytolysis. Monocyte supernatants containing CF induced cytolysis of murine WEHI 164 sarcoma cells, as determined in a 51Cr-release assay. Preincubation of WEHI 164 cells with actinomycin D enhanced cytolysis induced by supernatants containing CF, suggesting that CF may be involved in drug-dependent cellular cytotoxicity. The cytolytic activity was profoundly inhibited by a rabbit antiserum raised against purified CF, indicating that the cytolytic activity in the supernatants was in fact mediated by CF. These results indicate that CF may be an important effector molecule in monocyte-mediated cytostatic and cytolytic reactions.     

Characterization of bovine mononuclear cell populations with natural cytolytic activity against bovine herpesvirus 1-infected cells

Freshly isolated or overnight cultured peripheral blood mononuclear cells from immune or nonimmune animals had natural cytolytic activity against bovine herpesvirus 1 (BHV-1)-infected tumor target cells. No lysis was demonstrated against tumor target cells alone. This natural cytolytic activity was present in mononuclear cells from the spleen, lymph node, and peripheral blood but little or no cytolytic activity was detected in bone marrow or thymus cells. When monoclonal antibodies and complement to deplete bovine mononuclear cell subpopulations from the nonadherent cells were used, results indicated the effector cell was not a T cell, B cell, or activated monocyte. From nonadherent populations separated on density gradients, it was determined that the effector cells were large, low density mononuclear cells. These results indicate the nonadherent effector cells mediating lysis of BHV-1-infected xenogeneic adherent target cells were large null lymphocytes and/or immature monocytes.     

Lymphokine stimulation of human macrophage C2 production is partially due to interferon-gamma

Monocyte complement stimulator (MCS), a product of T lymphocytes, is defined by its ability to stimulate the synthesis and secretion of the second complement component (C2) by monocytes. Most macrophage-activating factor (MAF) activity present in lymphokine-rich culture supernatants has recently been found to be due to interferon-gamma (IFN-gamma). We therefore hypothesized that IFN-gamma may have MCS activity as well. We tested recombinant, E. coli-derived, human IFN-gamma (rIFN-gamma) for its effects on C2 production by adherent peripheral blood monocytes and U937 cells, a human monocytic cell line. Recombinant IFN-gamma in concentrations ranging from 0.1 to 300 U/ml (0.003 to 8.8 ng/ml) stimulates C2 production by both cell populations. Exposure of responding cells for at least 24 hr is required for maximal stimulation. To determine the contribution of IFN-gamma toward total MCS activity in crude lymphokine-rich supernatants, we employed a solid-phase immunoabsorption technique with the use of a monoclonal anti-IFN-gamma antibody. This technique removed all IFN-gamma detectable by a sensitive ELISA, but MCS activity was decreased by only 40 to 50%. Additionally, MCS activity of these supernatants did not correlate with IFN-gamma content as determined by ELISA. By using another method to eliminate IFN-gamma activity, acid dialysis destroyed all rIFN-gamma activity, as measured by stimulation of U937 C2 synthesis, but eliminated only 30 to 67% of MCS activity from crude lymphokine preparations. Thus IFN-gamma stimulates C2 production by monocytes and U937 cells and apparently accounts for some, but not all, MCS activity present in lymphokine-rich supernatants. Other lymphokines are present in such supernatants that also possess this activity.     

Augmentation of human monocyte-mediated cytolysis by interferon

Human monocytes, separated by either plastic adherence or adherence to microexudatecoated surfaces, from the peripheral blood of most normal donors were shown to have significant cytolytic activity against TU5, a mouse SV40-transformed target cell. Spontaneous cytolysis ranged from 0 to 32% at a 40:1 effector:target (E:T) ratio. Augmentation of cytolysis was usually seen when human fibroblast interferon (IF) (10³–10⁴ units/ml) was cultured with the effector and target cells for the duration of the assay. The mean increase in percentage cytolysis at 40:1 and 20:1 E:T ratios was greater with monocytes obtained by a microexudate method (24.1 and 22.4%) than with monocytes obtained by a plastic adherence method (16.0 and 8.1%). Only a slight augmentation of cytotoxicity was observed when the effector cells were pretreated with IF for 1-hr. The increased levels of cytotoxicity observed when IF was present during the assay did not appear to be due to the toxic effects of IF on the target cells or to a stable increase in the susceptibility of the target cells to lysis.     

Tumor-activated NK cells trigger monocyte oxidative metabolism

We have examined the hypothesis that tumor cells can stimulate a respiratory burst by human natural killer (NK) cells in vitro as measured by luminol-dependent chemiluminescence (CL). Percoll-purified NK cells, containing 40% HNK-1+ cells and less than 1 to 4% esterase-positive contaminating monocytes, can generate a strong CL response after stimulation with the NK-susceptible K562 tumor but not with the NK-resistant P815 tumor cells. Although the response was NK dependent, as shown by depletion with NK-directed monoclonal antibodies (HNK-1, OKT-11, and OKM-1), the cell generating the CL response was not the NK cell. On the basis of several independent experimental approaches the CL response always required the presence of monocytes in the NK preparation. a) Treatment with a monocyte-specific monoclonal antibody (MO2) and complement completely abolished CL. b) The cells producing the CL response were strongly adherent to nylon wool columns (NWC), and large granular lymphocyte preparations containing less than 0.1% esterase-positive cells were inactive. c) NK cells cultured in IL 2-containing medium and tested over several days did not generate CL. d) Optimal numbers of monocytes (less than 1 to 2%) added to a non-CL NWC-purified NK population restored CL, whereas larger or smaller amounts were ineffective. Neither these procedures nor the addition of superoxide dismutase (which completely blocked CL) had any effect on NK lytic activity. We subsequently demonstrated that a factor present in supernatants obtained from NK/K562 incubations, but not from NK or tumor cells alone, could stimulate monocyte CL. We therefore propose that the CL response measured in NK-enriched Percoll fractions originated from contaminating monocytes that were triggered by factor(s) released from tumor-activated NK cells, and that superoxide anion was not required for NK lysis.     

Monocyte-mediated augmentation of human natural killer cell activity: conditions, monocyte and effector cell characteristics

The characteristics of the effector cells and monocytes, and conditions required for the monocyte-mediated augmentation of human natural killer (NK) cell activity were investigated. Enriched null cell populations were further fractionated by Percoll centrifugation and used as effector cells. The LGL-enriched fraction was less susceptible than either the unfractionated cells or the other Percoll fractions to the monocyte augmentation when mixed with monocytes in the chromium-release assay and when precultured with monocytes for 12 hr, retrieved by carbonyl iron treatment, and tested for NK activity against K562. This differential susceptibility was reflected at the single cell level. The LGL-enriched Percoll fraction did not display the increase in target-binding cells with lytic activity that was exhibited by the other effector cell preparations after culture with monocytes. No differences in Leu-7 and Leu-11 phenotypes were detected between enriched null cells that had been cultured with and without monocytes for 12 hr. At the monocyte level, it was shown that pretreatment of the monocytes with LPS did not alter their NK-augmenting activity appreciably. Glutaraldehyde-fixed monocytes were not effective, and actinomycin D-treated monocytes were less effective than untreated or irradiated monocytes when mixed with enriched null cells in the assay. Actinomycin D-treated monocytes did not augment and possibly suppressed NK activity tested after 12-hr culture, and irradiated monocytes were less effective for augmenting NK activity than untreated cells. Monocyte-mediated augmentation could be detected when the medium used for null cell-monocyte coculture was supplemented with a) different lots of fetal bovine serum, b) human AB serum, c) autologous serum, or d) no serum. Polymyxin B and indomethacin did not alter the monocyte effect. Finally, the monocyte-mediated augmentation of human NK was not MHC restricted, since allogeneic combinations were also effective. These results suggest that 1) lymphocytes other than LGL participate in the monocyte-mediated augmentation of NK activity, 2) the augmentation is probably activational rather than maturational, 3) the monocytes must be viable to be effective when mixed with null cells during the assay, 4) de novo RNA and/or protein synthesis by the monocytes is required for the monocytes to induce augmented activity in null cells after 12-hr coculture, 5) prostaglandin synthesis and endotoxin are probably not involved in the augmentation, 6) the phenomenon is not MHC restricted, and 7) monocytes may express augmentative and suppressive activities concurrently.     

Suppression of B cell responses by natural killer cells is mediated through direct effects on T cells

We examined the ability of human natural killer (NK) cells to modulate T cell-dependent mitogen-induced B cell responses. Highly purified NK cells inhibited the polyclonal antibody responses of autologous pokeweed mitogen (PWM)-stimulated unfractionated mononuclear cells in a reverse hemolytic plaque-forming cell (PFC) assay. Investigation of the possible mechanism(s) of the suppressor activity of NK cells revealed that lysis of mitogen-stimulated cells was unlikely. Chromium-51 release cytotoxicity assays of PWM-stimulated mononuclear cells did not demonstrate lysis by NK cells. Additionally, the monoclonal antibody 13.3, which abrogates NK cell cytolysis, did not reverse NK cell-dependent suppression of PFC formation. The putative lytic molecule elaborated by NK cells, NK cytotoxic factor, did not suppress B cell responses, further supporting a nonlytic inhibitory mechanism. That NK cell-derived lymphokines such as IFN-alpha, IFN-gamma, or IL-2 were uninvolved in the down-regulation of B cells was corroborated by the failure of antibodies to these mediators to reverse the suppression. NK cells did not suppress PFC formation when T cells were replaced by supernatants from PWM-stimulated T cells; additionally, NK cells had no effect on the generation of these necessary T cell factors. However, the coculture of T cells with NK cells resulted in the induction of suppressor activity within the T cell population suggesting that this was the mechanism of NK cell-mediated suppression of B cell responses.     

Announcements

Human peripheral blood monocytes were reproducibly shown to lyse a variety of tumor cells in a 3- to 4-hr ⁵¹Cr release assay. Ficoll-Hypaque-purified mononuclear cells were suspended in medium supplemented with either 10% autologous serum or fetal calf serum (PCS). With either serum, highly purified (97–99%) and viable (>99%) monocyte suspensions were obtained by EDTA-reversible adherence to plastic surfaces which had been precoated with autologous serum. When used as effectors in cytotoxicity assays, the monocytes recovered from mononuclear cells suspended in FCS-supplemented medium exhibited higher cytolytic activity and were therefore used for further studies. Using FCS for both coating the plates and supplementing the suspension medium resulted in monocytes with low cytolytic activity. Tumor cell lysis measured by ⁵¹Cr release was detected within 2 hr of incubation and increased gradually with time. The level of lysis was dependent on the effector/target ratio and the tumor target cell employed. The involvement of natural killer lymphocytes in the observed tumoricidal activity was excluded. Detection of cytotoxic activity in a short-term assay will be very helpful in further studies of the mechanism of tumor cell killing by human monocytes since potential complicating effects of long-term in vitro cultivation will be minimized.     

Synergistic activation of human monocytes by granulocyte-macrophage colony-stimulating factor and IFN-gamma. Increased TNF-alpha but not IL-1 activity

TNF-alpha and IL-1 activities and PGE2 levels were investigated in the supernatants of highly purified human monocytes cultured for 18 h with recombinant human granulocyte-macrophage CSF (GM-CSF). GM-CSF alone did not stimulate IL-1 or TNF-alpha activities or the production of PGE2. GM-CSF with IFN-gamma, but not with LPS, consistently activated the monocytes for TNF-alpha activity. In contrast, for increased IL-1 activity, GM-CSF synergized weakly and irregularly with LPS, but not at all with IFN-gamma. For the third monocyte product investigated, GM-CSF was a weak and inconsistent inducer of PGE2 and only in the co-presence of IFN-gamma. Thus, GM-CSF can elicit different responses in human monocytes depending both on the co-stimulus as well as the monocyte product being investigated.     

Involvement of tumor necrosis factor in cytotoxicity mediated by human monocytes

Human monocytes cultured in a specially prepared medium free of lipopolysaccharide (LPS) constitutively produced a small, though significant, amount of tumor necrosis factor (TNF). Upon addition of LPS, the amount produced remained constant until the LPS concentration reached 1-10 ng/ml, whereupon the production of TNF dramatically increased, eventually becoming 100-fold greater than when the LPS concentration was below 1 ng/ml. Priming the monocytes with recombinant interferon-gamma (rIFN-gamma) before LPS exposure resulted in a 2- to 10-fold increase in TNF production, the highest relative increase being obtained at lower LPS concentrations and in the absence of LPS. Monocyte-produced TNF appears to be the effector molecule in monocyte-mediated killing of some target cell types, since antiserum against recombinant TNF inhibited killing of both actinomycin D-treated and untreated WEHI 164 cells by human monocytes. However, it also appears that TNF may not in all cases be an effector molecule in monocyte-mediated killing, since cytolysis of K562 cells mediated by IFN-gamma/LPS-activated monocytes was not inhibited by antiserum against recombinant TNF. Antiserum which was raised against a monocyte-derived cytotoxic factor and which neutralized recombinant TNF did, however, inhibit monocyte-mediated cytolysis of K562 cells, suggesting that an extracellular factor, perhaps related to TNF, was also involved in monocyte-mediated killing of K562 cells. A TNF-like activity was associated with the monocyte surface membrane, since paraformaldehyde-fixed monocytes expressed cytotoxic activity which was neutralized by antiserum against recombinant TNF. Fixed monocytes activated with rIFN-gamma in addition to LPS before fixation were generally more cytotoxic than those exposed to LPS alone, and those exposed to LPS were much more cytotoxic than those not exposed to LPS. Thus it is possible that high local TNF concentrations may be generated near the target cell upon direct contact between effector and target cells, and that also monocyte-associated TNF may in this way be involved in monocyte-mediated cytotoxicity.     

Increased monocyte MCP-1 production in acute alcoholic hepatitis.

Monocyte chemoattractant protein-1 (MCP-1) is a potent mononuclear cell-specific chemotactic protein. MCP-1 is a candidate chemoattractant for activation and hepatic infiltration of mononuclear cells in alcoholic hepatitis (AH). Blood was collected from 15 patients with AH (mean bilirubin 17.6+/-3.5 mg/dl; normal 0. 2-1.0 mg/dl) on admission and at time points for up to 6 months. Peripheral blood monocytes were isolated and MCP-1 production assessed by measuring MCP-1 concentrations in monocyte culture supernatants after overnight (20 h) incubation. Monocytes from normal subjects did not product detectable MCP-1 unless stimulated with endotoxin (LPS;5 microg/ml). The mean level of constitutive MCP-1 from AH patient monocytes was 4694+/-2432 pg/ml 20 h on admission. The mean MCP-1 level for LPS-treated monocytes was 4903+/-1540 pg/ml 20 h for normal subjects and was significantly elevated in AH patients to 11589+/-3266 pg/ml/20 h. AH patient monocyte MCP-1 production was decreased in vitro when monocytes were treated with N-acetylcysteine (5 mM) and also decreased over the 6-month study as the patients improved clinically. MCP-1 plasma levels were below the detection limits of the assay used in both AH patients and normal subjects. Thus, monocytes from AH patients not only constitutively product MCP-1, but also produce higher levels of MCP-1 with endotoxin stimulation. Further studies are needed to clarify the role of MCP-1 in the activation and hepatic infiltration of mononuclear cells in alcoholic liver disease.     

Human lymphokine-activated killer (LAK) cells: III. Effect ofl-phenylalanine methyl ester on LAK cell activation from human peripheral blood mononuclear cells: Possible protease involvement of monocytes,natural killer cells and LAK cells

Summary We have shown that depletion of monocytes from human peripheral blood mononuclear cells (PBMC) byl-phenylalanine methyl ester (PheOMe) enhanced lymphokine-activated killer cell (LAK) generation by recombinant interleukin-2 (rIL-2) at high cell density. In this study, we have investigated the mechanism of action of PheOMe on LAK activation by using trypsin, chymotrypsin, tosylphenylalaninechloromethanol (TPCK, a chymotrypsin inhibitor), tosyl-l-lysinechloromethane (TLCK, a trypsin inhibitor), phenylalaninol (PheOH), and benzamidine. PBMC were treated with 1–5 mM PheOMe for 40 min at room temperature in combination with the various agents, washed and assessed for their effects on natural killer (NK) activity against K562 cells and monocyte depletion. The treated cells were then cultured with or without rIL-2 for 3 days. LAK cytotoxicity was assayed against⁵¹Cr-labeled K562 and Raji tumor target cells. TPCK at 10 µg/ml partially inhibited depletion of monocytes by PheOMe. TLCK did not prevent depletion of monocytes nor inhibition of NK activity induced by PheOMe. TPCK and TLCK inhibited NK activity by themselves. TPCK but not TLCK inhibited rIL-2 induction of LAK cells. On the other hand, PheOH and benzamidine (analogs of PheOMe) lacked any effect on monocyte depletion but abrogated the inhibitory effect of PheOMe on NK activity. They had no effect on rIL-2 activation of LAK activity enhanced by PheOMe. Trypsin potentiated the inhibitory effect of PheOMe on NK activity and monocyte depletion. Trypsin partially inhibited IL-2 activation of LAK activity enhanced by PheOMe. Chymotrypsin had little effect on NK activity but prevented the inhibitory effect of PheOMe on NK activity. It had little effect on monocyte depletion induced by PheOMe. PheOMe was hydrolysed by monocytes and chymotrypsin to Phe and methanol as determined by HPLC. TPCK inhibited hydrolysis of PheOMe by monocytes. Our data suggest that the effects of PheOMe on monocytes, NK cells and LAK activation involve protease activities of monocytes.     

Anti-tumor activity of class II MHC antigen-restricted cloned autoreactive T cells. I. Destruction of B16 melanoma cells mediated by bystander cytolysis in vitro

Two Lyt-1+, L3T4a+ autoreactive T cell clones specific for self-class II major histocompatibility complex (MHC) gene products were established from lymph node cells and spleen cells of C57BL/6J mice, respectively, by different methods. They were stimulated to proliferate in culture in response to I-Ab antigen-bearing syngeneic spleen cells in a class II MHC-restricted manner. This stimulation was inhibited completely by the addition of anti-L3T4a (GK1.5) or anti-I-Ab (3JP) monoclonal antibodies. The autoreactive T cell clones lysed syngeneic I-Ab+ target cells such as lipopolysaccharide (LPS) blasts. They also lysed I-A- bystander cells such as Cloudman and B16 melanoma and lymphoid tumor cells in the presence of I-Ab+ stimulator cells but not I-Ad+ cells. This bystander killing was most likely mediated by soluble factors released from the autoreactive T cells in response to I-Ab antigens, because culture supernatants from activated autoreactive T cells inhibited the proliferation of B16 melanoma cells in vitro and also had significant cytolytic activity. Both lymphotoxin and interferon-gamma were released from activated autoreactive T cells, suggesting that these cytotoxic lymphokines were responsible for autoreactive T cell-mediated cytolysis. The finding that the two clones, established independently and by different methods, show self-class II MHC antigen-restricted cytolysis, and bystander cytolysis suggests that these properties are not restricted to a unique population of autoreactive T cells. These results favor the concept that in vivo, autoreactive T cells may express not only regulatory activity in regard to antibody responses, but also anti-tumor activity via bystander cytolysis.     

Human monocytes inhibit lymphokine-activated killer cell expansion in vitro

Depleting monocytes from human peripheral blood mononuclear cells (PBMC) enhances the in vitro activation of lymphokine-activated killer (LAK) cells. To determine if monocytes also altered LAK-cell expansion, we evaluated two methods of depleting monocytes from PBMC: nylon wool adherence (NWA) and phenylalanine methyl ester (PME) treatment. Both methods of depleting monocytes enhanced interleukin-2 (IL-2) driven, LAK-cell expansion; LAK expansion, however, was significantly greater after depletion with NWA than after PME. LAK cytotoxicity after NWA and PME depletion was equivalent. The degree of monocyte depletion, determined by evaluating morphology and the number of Leu-M3 (CD14) positive cells, and the proliferation of Leu 19 (CD56), OKT-3 (CD3), Leu2 (CD8), and Leu 3a (CD4) positive cells was also equivalent. Exposure of IL-2 activated cells to PME did not alter their cytotoxic activity. However, sequential treatment of PBMC with NWA, then PME, or with PME and then NWA, resulted in reduced expansion. This reduction in expansion was similar to PBMC treated with PME alone. Exposure of PME-depleted cells to nylon wool or to supernatants obtained from cells adherent to nylon wool further decreased LAK expansion relative to cells treated with NWA alone. We conclude that even at relatively low cell density, human monocytes markedly inhibit LAK-cell expansion in IL-2 driven PBMC cultures. Further, depletion of monocytes by NWA adherence is more effective than by treatment with PME, possibly due to subtle cellular damage induced by this latter treatment. These findings have implication for the in vitro and in vivo generation of LAK-cells by IL-2.