Cellular suppression of murine ADCC and NK activities induced by Corynebacterium parvum

Summary Administration of a single dose of C. parvum (CP) induces depression of splenic NK activity in mice after a lag period of 3–5 days and this depression lasts about 2 weeks. The depressed levels of NK activity noted in this study depended on time of CP administration and were associated with the induction of suppressor cell activity. Neonatally thymectomized or sublethally irradiated mice had unimpaired ability to generate suppressor cells following CP treatment. Depletion of adherent/phagocytic cells by carbonyl iron plus magnetism, Sephadex G-10 filtration, or both neither enriched NK activity nor removed suppressor activity from the spleens of CP-treated mice. Antibody-dependent cellular cytotoxicity (ADCC) against lymphoma targets was also depressed in CP-treated mice, accompanied by a concomitant appearance of suppressor cells that interfere with ADCC at the effector level.     

Suppression of natural killer cell cytotoxicity by splenocytes from Corynebacterium parvum-injected, bone marrow-tolerant, and infant mice.

Natural killer (NK) cell cytotoxicity to YAC-1 lymphoma was investigated in mice tolerant to bone marrow grafts (BM-tolerant), Corynebacterium parvum- (C. parvum) treated mice, and infant mice. Also the comparison was made between the NK cell and the hemopoietic-resistance effector (HR-E) cells. It was found that the BM-tolerant mice and C. parvum-treated mice showed either no or markedly decreased NK cell cytotoxicity. These mice were also nonresponders to bone marrow grafts in vivo. The lack of or decreased reactivity was apparently caused by the regulatory cell activities of the suppressor cell since the splenocytes from C. parvum-treated and BM-tolerant mice suppressed significantly the cytotoxic activities of otherwise fully functional NK cells. Similar suppressive effect on NK cells was mounted by splenocytes from infant mice, indicating again the suppressor cell regulation of NK cell cytotoxicity.     

Suppressor T-cell hybridomas that exhibit various capacities to negatively regulate PFC responses in a T-cell dependent mouse model

Splenic leucocyte effector cells from 3-month-old C3H/HeJ mice which were antibody negative for influenza A virus were found to be spontaneously cytotoxic for mouse L929 fibroblasts infected with influenza virus, but not for uninfected cells. The cytotoxic activity was significantly enhanced if the effector cells were preincubated with splenic leucocytes from older 6- or 9-month-old antibody-negative mice before being added to the target cells. Enhancement appeared to be due to a cooperative effect between leucocytes from mice of different ages. Preincubation of effector cells with autologous sera markedly suppressed spontaneous cytotoxicity, but the suppression was significantly less with sera from 7- or 10-month-old mice than with sera from 3-month-old mice. Most cytotoxic activity was observed with a nylon wool-adherent subpopulation of leucocytes, although some cytotoxicity remained in the non-adherent fraction. The results suggested that spontaneous cytotoxicity was due to two subpopulations of cells, possibly adherent monocyte-macrophages and nonadherent natural killer cells.     

Prostaglandin-mediated inactivation of natural killer cells in the murine decidua

Previous studies from this laboratory have demonstrated a large influx of null lymphocytes into the murine decidua during pregnancy. We had also shown that trophoblast cells of the murine placenta bear target structures recognized by NK cells. Since NK lineage cells belong to the null category of lymphocytes, we examined whether cells of this lineage appear in the murine decidua, and if so, whether their activity is locally regulated by NK suppressor cells. We further investigated the identity of the suppressor cells as well as their suppressor products. NK lineage cells, irrespective of their activation status, were identified morphologically in radioautographic preparations as the non-T, non-B (null) lymphocytes capable of binding YAC-1 lymphoma targets. NK activity of nucleated cells was measured with a 4-hr 51Cr-release assay against labeled YAC-1 targets. Studies with outbred CD1 mice, and to a smaller extent, inbred CBA mice revealed that the incidence of NK lineage cells remained fairly constant within the decidua throughout pregnancy, but their activity decreased steadily to negligible levels by Day 12-14 of gestation. This was found to result from an inactivation caused by NK-suppressor cells in the decidua. A mixing of Ficoll-Paque-separated nucleated cells of the decidua with normal splenic effector cells (at 1:1 ratio) led to a suppression of their NK activity tested immediately or after a 20-hr coculture. This suppression was MHC unrestricted. Suppressor cells were identified both in plastic nonadherent fraction highly enriched for typical decidual cells as well as in the plastic adherent fraction containing decidual cells and macrophages. Addition of indomethacin (10(-5) M), an inhibitor of prostaglandin synthesis, or anti PGE2 antibody, revived the NK activity in the mixed population, as well as in the decidua, suggesting a PGE2-mediated suppression. High levels of PGE2 were detectable in decidual cell supernatants with a sensitive radioimmunoassay. Addition of pure PGE2 (10(-7)-10(-6) M) but not PGF2 alpha (10(-6) M) during the NK assay or to the effector cells for a 20-hr period prior to the assay led to an inhibition of NK activity. These results reveal that NK cells appearing in the murine decidua are progressively inactivated by PGE2 produced by decidual cells and decidual macrophages.     

Suppression of natural killer activity in human blood and bone marrow cultures by bone marrow-adherent OKM1-positive cells

Maintenance and regulation of natural killer (NK) cell activity in human bone marrow cultures were studied using K562 leukemia cells as targets. Culture of bone marrow cells in medium supporting long-term generation of myeloid cells resulted in a rapid loss of NK activity in 1-3 days. In contrast, antibody-dependent cytotoxicity to an NK-resistant tumor was maintained for more than 7 weeks. Horse serum, a component of the myelopoietic culture medium, was found to diminish NK cytotoxicity of blood and bone marrow cultures whereas hydrocortisone supplement did not. In addition, an adherent cell is present in bone marrow which greatly inhibits NK activity. Nonadherent bone marrow cells exhibited higher cytotoxicity than unfractionated cells at all days of culture; adherent cells were not cytotoxic to K562. Purified adherent marrow cells inhibited the cytotoxic capacity of nonadherent blood or marrow mononuclear cells during coculture. Indomethacin, an inhibitor of protaglandin synthesis, augmented levels of NK activity in cultures of bone marrow cells, indicating that macrophages may be suppressing this effector function via prostaglandins. Further identification of the adherent suppressor cells came from experiments in which suppression was prevented by treatment of the adherent cells with monoclonal OKM1 antibody plus complement. This study shows that bone marrow-adherent OKM1-positive cells, presumably macrophages, negatively regulate NK activity, and it defines conditions for analysis of the generation and/or positive regulation of NK cells in human bone marrow.     

Splenic I-J-bearing antigen-presenting cells in activation of suppression: further characterization

A set of I-J-bearing murine splenic antigen-presenting cells (APC) has been found to be responsible for first order suppressor cell (Ts1, afferent suppressor cell) activation in the azobenzenearsonate (ABA) hapten system after intravenous administration. Suppressor cells induced by this set of hapten-coupled cells do not function in the efferent phase of the delayed hypersensitivity (DTH) response. The functional activity of this novel APC to activate afferent suppressor cells was resistant to a dose of ultraviolet radiation (UVR) sufficient to largely abrogate the ability of splenic APC to immunize for a DTH response. It was also found that the previously described splenic I-J-bearing APC needed for third-order suppressor cell (Ts3, effector-suppressor cell) activation is adherent and UVR resistant. The sets of I-J-bearing APC appear to be crucial elements in the activation of suppression and thus in determining the balance between immunologic reactivity and unresponsiveness. Furthermore, the UVR resistance of this set of novel APC may be relevant to the in vivo effects of UVR exposure to mice.     

BCG-induced murine effector cells. II. Characterization of natural killer cells in peritoneal exudates.

The cytotoxic activity in peritoneal exudates harvested from C57BL/6 mice 4 to 6 days after they had received viable Bacillus Calmette-Guérin (BCG) organisms i.p. was associatee with a nonadherent, nonphagocytic cell. The cytotoxic cell lacked demonstrable surface immunoglobulin and Thy 1 antigen and bore no readily detectable Fc receptors. Lytic activity was labile at 37 degrees C and was diminished after trypsinization of the effector cells. Preincubating effector cells with immune complexes was without effect on lytic expression. These features make it likely that the cytolytic activity was associated with "natural killer" (NK) cells, previously described in unimmunized mouse spleens and mesenteric lymph nodes. Whether BCG induced "activation" of resident NK cells, the de novo production of NK cells, or "homing" into the peritoneum of cells normally resident in other lymphoid tissue is not known.     

Enhancement by interferon of natural killer cell activity in mice.

Injection of mice with several interferon inducers, Newcastle Disease virus, polyinosinic-polycytidylic acid and tilorone resulted in an increase in spleen cell cytotoxicity for ⁵¹chromium-labeled mouse YAC tumor target cells in 4-hr in vitro assays. This increase in spleen cell cytotoxicity was abrogated by injection of mice with potent anti-mouse interferon globulin. Inoculation of mice with mouse interferon (but not human leucocyte or mock interferon preparations) also resulted in a marked enhancement of spleen cell cytotoxicity. The extent of enhancement of spleen cell cytotoxicity was directly proportional to the amount of interferon injected and a significant increase was observed after inoculation of as little as 10³ to 10⁴ units of interferon. An effect could be detected as soon as 1 hr after injection of interferon. The increase of spleen cell cytotoxicity after inoculation of an interferon inducer was not due to a localization and accumulation of cytotoxic cells in the spleen but reflected a general increase in cytotoxic cell activity in various lymphoid tissues (except the thymus). The splenic cytotoxic cells from interferon or interferon-inducer-injected mice had the characteristics of natural killer (NK) cells since (i) interferon enhanced spleen cell cytotoxicity in athymic (nu/nu) nude mice, (ii) classical spleen cell fractionation procedures by nylon wool columns, anti-Thy 1.2 serum plus complement, anti-Ig columns, and depletion of FcR+ rosette-forming cells, failed to remove the effector cells generated in vivo or in vitro. Therefore like NK cells, interferon-induced cytotoxic cells lack the surface markers of mature T and B lymphocytes, are not adherent, and are devoid of avid Fc receptors. Furthermore like NK cells, the spleen cells from interferon-treated mice lysed various target cells (known for their sensitivity to NK cells) without H-2 or species restriction. Incubation in vitro of normal spleen cells with interferon also resulted in an increase in cytotoxicity for YAC tumor cells. We conclude that interferon acts directly on NK cells and enhances the inherent cytotoxic activity of these cells.     

The differential ability of splenic adherent cells from B6.lpr mice to induce suppressor T cells

Hapten-coupled splenic adherent cells or resident peritoneal cells from autoimmune B6.lpr mice that are over 5 mo of age fail to induce first-order inducer suppressor T cells (Ts1). However, the same population of hapten-coupled cells can induce both delayed-type hypersensitivity responses and third-order effector suppressor T cells (Ts3). Thus, splenic and peritoneal antigen-presenting cells from B6.lpr mice display a defined defect in the ability to induce certain suppressor T cell responses. The cellular defect in Ts1 induction is controlled by the lpr gene, since age-matched congenic B6 mice do not display this defect. The splenic adherent cell defect is temporarily correlated with the autoimmunity that develops in B6.lpr animals. The antigen-presenting defect in the B6.lpr splenic adherent population for Ts1 induction is reversible by culturing the cells in interferon-gamma. The results are discussed as an illustration of the relationship between experimental models of autoimmunity and defects in a suppressor T cell cascade.     

Suppressor cells in the effector phase of autologous cytotoxic reactions in cancer patients

Summary Cytotoxicity was induced in lymphocytes (CL) from 10 out of 15 patients by autologous mixed lymphocyte tumor cell culture and further cultivation with recombinant interleukin-2. In cells from 3 of the 10 patients, cytotoxicity was suppressed by more than 50% when autologous peripheral blood mononuclear cells (PBMC) from the patients with large tumors were added to the autologous killing system. The cells responsible for suppressing the cytotoxicity in the effector phase were adherent or nonadherent to plastic depending on the patient examined. The T cell fraction from 1 patient significantly suppressed the cytotoxic activity, and this suppression was seen only in the autologous system. On the other hand, plastic adherent cells but not T cells from PBMC of 2 subjects suppressed the cytotoxic activity of CL. The reason why the main cell population suppressing the CL activity differed among the patients is unclear. However, the findings that the suppression was mostly abrogated following resection of the tumor mass suggested that suppressor cells, either of macrophage lineage or T cells, are induced in patients with a large tumor mass. This speculation is supported by the finding that the PBMC from a patient with tumor recurrence regained the suppressive activity.     

Suppressor cells for natural killer activity in carcinomatous pleural effusions of cancer patients

Summary Carcinomatous pleural effusions of 25 of 32 patients with lung cancer, which had markedly low or no natural killer (NK) activity against K562 cells in a 4 h chromium release assay, contained cells capable of suppressing the lytic function of blood NK cells from normal donors and cancer patients. Suppressor cells were found to be Sephadex G-10- and serum coated plastic dish-adherent monocyte/macrophages in 21 of 25 patients and nylon wool-nonadherent lymphocytes in the other four cases. Nonmalignant pleural effusions did not contain any type of suppressor cells. Twenty-four-hour preincubation of suppressor cells with effector cells was required for mediation of the suppressor function. Neither culture supernatants of effusion cells and NK cells nor effusion supernatants suppressed NK activity. The presence of indomethacin during the preincubation and cytotoxicity assay did not abrogate suppressor function. Suppressor cells did not reduce the number of lymphocyte/K562 conjugates. Contaminating tumor cells were not responsible for the suppression of cytotoxic activity. NK cells precultured with suppressor cells were not able to show cytotoxic function even after removal of the suppressor cells. When effusion mononuclear cells were passed through a Sephadex G-10 column and then preincubated for 24 h, these cells showed a significant increase in NK activity. The results suggest that carcinomatous pleural effusions contain at least two classes of suppressor cells for NK activity, monocyte/macrophages, and nylon wool-nonadherent lymphocytes, which could be one of the causes of impaired NK activity in carcinomatous pleural effusions.     

Effects of adriamycin on the activity of mouse natural killer cells

Adriamycin, a widely employed anti-neoplastic agent, was found to have either inhibitory or stimulatory effects on NK activity, depending on the site examined. A single i.p. administration of ADM resulted in a rapid increase of cytolytic activity by PEC of various mouse strains. The effector cells appeared to be NK cells, being nonadherent and nonphagocytic; they expressed low amounts of Thy 1.2 antigen and had the same pattern of specificity as splenic NK cells. In contrast to the stimulatory effects of NK activity of PEC, ADM caused a transient dose-dependent depression of NK activity in the spleen, with a peak reduction at day 3 and recovery within a few days thereafter. The depressed NK activity could be reversed by removal of adherent cells by passage through a nylon column. Moreover, ADM induced cytostatic activity against tumor cells by macrophages, suggesting that activated macrophages may be responsible for suppression of splenic NK activity. The possible modulation of the levels of NK activity by ADM-induced macrophages was supported by mixture experiments, in which plastic adherent spleen cells from ADM-treated mice, but not from normal mice, inhibited the NK activity of normal spleen cells.     

Suppressive Effect by Cooperation of Splenic and Peritoneal Adherent Cells on Generation of Cytotoxic T Lymphocytes

When spleen cells primed in vivo against allogeneic lymphoid cells were used as responder cells in secondary mixed lymphocyte cultures, a high degree of cytotoxicity was generated even in the absence of splenic adherent cells. However, removal of adherent cells from such primed responder spleen cells reduced the cytotoxicity to some extent. On the other hand, when these responder cells were transferred into the peritoneal cavity of irradiated syngeneic mice together with antigenic cells, unseparated responder cells generated a lower degree of cytotoxicity than did adherent cell-depleted responder cells. In an in vitro system, peritoneal adherent cells also suppressed the generation of cytotoxic T lymphocytes by unseparated responders; however they augmented the cytotoxic T lymphocyte generation by adherent cell-depleted responders. These adherent cell populations with augmenting activity became inhibitory when they coexisted. The mechanism of this inhibitory action remains unclear.     

Generation and characterization of purified adherent lymphokine-activated killer cells in mice

During the incubation of murine spleen, lymph node, or bone marrow cells with IL-2 (1000 U/ml) a small percentage of cells became adherent to the surface of plastic tissue culture flasks. After removal of the non-adherent lymphoid cells, plastic adherent lymphokine-activated killer (LAK) cells could be efficiently expanded in the presence of IL-2. Plastic adherent-derived A-LAK cells were characterized by high rates of proliferation and their cytotoxic activity was more than 10 fold higher than LAK cells generated in the bulk (unfractionated) spleen cell cultures. A-LAK cells could be continuously generated from the non-adherent cell population. Using multiple transfers (every 1 to 2 days) of non-adherent LAK cells into new flasks, new rounds of plastic adherent cells were generated with high expansion capability and high levels of cytotoxic activity. Morphologically, A-LAK cells were large granular lymphocyte and phenotypically expressed markers characteristic of NK cells (asialo GM1+, NK1.1+, Qa5+, Ly-6.2+, Thy-1.2+, but negative for Lyt-2.2 and L3T4). A-LAK cells generated from mice of different strains expressing low and high levels of NK cell activity were equally highly cytotoxic. However, A-LAK cells obtained from nude or beige mice had relatively lower levels of cytotoxicity. Stimulation of NK cell activity by poly I:C or inhibition by in vivo or in vitro treatment with anti-asialo GM1 serum did not affect the generation of A-LAK cells. A-LAK cells derived from spleen or bone marrow of C57BL/6 or nude mice treated with anti-asialo GM1 serum were found to be asialo GM1+ suggesting that A-LAK cell could be generated from the asialo GM1- precursor cells. Expansion of plastic adherent A-LAK cells in the presence of IL-2 could provide large numbers of highly purified cytotoxic A-LAK cells suitable for cancer immunotherapy.     

Origin and differentiation of natural killer cells. II. Functional and morphologic studies of purified NK-1.1+ cells

Cells bearing the NK-specific marker NK-1.1 were purified from mouse spleens by utilizing a monoclonal anti-NK-1.1 antibody and cell sorting. In normal adult mice, all of the splenic NK activity against YAC-1 cells was found in the NK-1.1+ fraction, whereas NK-1.1- cells were depleted of NK activity. The NK activity of sorted NK-1.1+ cells was enriched 15- to 30-fold over unfractionated spleen cells. Light and electron microscopic studies of purified NK-1.1+ cells showed a homogeneous population of cells, each containing one to four cytoplasmic granules. Mice whose bone marrow has been destroyed by chronic exposure to 17-beta-estradiol have very low NK activity. However, spleen cells of estradiol-treated mice contained a normal frequency of NK-1.1+ cells which bound to YAC-1 cells, but failed to lyse them even after purification and subsequent exposure to interferon-alpha/beta in vitro. It appears, therefore, that in the absence of intact bone marrow, NK-1.1+ cells may be arrested in a nonlytic and interferon-unresponsive state. Spleens of neonatal mice which have low NK activity were analyzed to ascertain whether immature NK-1.1+ cells, similar to those found in estradiol-treated mice, could be demonstrated. Spleens of 8- to 9-day-old mice also contained NK-1.1+ cells which had very low NK activity even after purification. Sorted NK-1.1+ cells were examined for cytotoxicity in mice whose NK activity was suppressed by pretreatment with Corynebacterium parvum (-15 days). In contrast to cells from estradiol-treated and neonatal mice, NK-1.1+ from mice treated with C. parvum had normal functional activity. Similarly, although NK activity of unfractionated bone marrow cells is low, sorted NK-1.1+ cells were greatly enriched for lytic activity. Thus, we conclude that cell sorting with monoclonal anti-NK-1.1 antibody provides a powerful tool for examining the mechanisms underlying various states of low NK activity, and there exist NK-1.1+, nonlytic, interferon-unresponsive cells which apparently require an intact marrow microenvironment for differentiation into mature, lytic NK cells.     

Adriamycin-induced activation of NK activity may initially involve LAF production

C3HeB/FeJ spleen cells (unseparated or passaged over nylon wool columns) were cultured overnight (1-2 X 10(6) cells/microwell) in the presence and absence of resident or ADM-induced PEC and anti-YAC-1 (4h) NK activity was determined. The addition of resident PEC to spleen cells had little effect on NK activity. However, the addition of ADM-elicited PEC (10 mg/kg, IP, day -1 and day -5) to spleen cells prior to culture significantly augmented NK activity. If ADM-induced PEC were treated with carbonyl iron prior to coculture with spleen cells, augmentation of anti-YAC-1 activity was not observed. This suggested that ADM-activated macrophages augmented cultured splenic NK activity. Supernatants from overnight-cultured resident or ADM-induced adherent PEC were then prepared, dialyzed (to remove ADM), and tested for mitogenic activity or cocultured with spleen cells overnight. ADM-induced adherent PEC supernatants stimulated the proliferation of murine thymocytes (both LAF and IL-2 also stimulate) but not cultured CTL (only IL-2 stimulates). ADM-induced adherent PEC supernatants (as well as LAF, IL-2, and IFN) augmented overnight-cultured C3HeB/FeJ splenic NK activity. However, only IL-2 and IFN could augment overnight-cultured athymic BALB/c . nu/nu splenic NK activity. This suggested that ADM-elicited macrophages produce LAF which may act directly on NK cells or, more likely, may induce T cells to produce IL-2, IFN, or both.     

Inhibition of murine lymphokine-activated killer (LAK) cell activity by adherent cells

The effects of adherent cell depletion, indomethacin, and prostaglandin E2 (PGE2) on murine LAK cell activity were investigated. Removal of plastic adherent cells from splenocyte suspensions either prior to 5-day culture with 1000 U/ml of recombinant human IL-2 (rIL-2) or prior to assay resulted in an enhanced LAK cell cytotoxicity compared to that of whole spleen cell suspensions. Indomethacin enhanced LAK cell cytotoxicity of whole splenocyte suspensions if present during the culture period, but had no effect on whole splenocyte or adherent cell-depleted cell suspensions if added just prior to assay. PGE2 suppressed LAK cell activity of nonadherent splenocyte but not whole splenocyte suspensions when present during the culture period. In vivo treatment of mice with indomethacin enhanced cytotoxicity directed toward both LAK sensitive, natural killer (NK) resistant (P-815) and LAK, NK sensitive (YAC-1) tumor cell targets. Splenocytes from indomethacin-treated mice cultured with additional indomethacin and rIL-2 exhibited highest LAK cell activity. The results from this study indicate that LAK cells are regulated by adherent cells which suppress LAK cell activity. This suppression can be reversed both in vitro and in vivo by indomethacin. This study has important implications for the possible clinical use of indomethacin in the potentiation of in vivo and in vitro LAK cell activity for immunotherapeutic protocols.     

Proliferative and cytotoxic immune functions in aging mice. IV. Effects of suppressor cell populations from aged and young mice

The changes with age in three splenic suppressor cell populations were studied in C57BL/6 mice. Allospecific Ts cells and nonspecific non-T suppressor cells were both generated in vitro in allogeneic MLC. The presence of "pre-existing" suppressor cells in fresh spleen cells from normal mice was examined. Suppressor cell activities were assayed for their ability to suppress proliferation in a fresh allogeneic MLC after treatment to prevent their own proliferation. The ability to generate both specific and nonspecific suppressor cells decreased with age, whereas pre-existing suppressor cells were detected in spleens from the majority of the aged animals but not in spleens from young animals. The decrease in suppressor cell activity was not due to any requirement for age matching between donors of suppressor and target cells. The specific and nonspecific MLC-generated suppressor cells inhibited both the proliferative response in the assay MLC and the generation of cytotoxic cells. The pre-existing suppressor cells only suppressed the proliferative response and not the generation of cytotoxic cells. The changes seen with age in these suppressor cell populations suggest that the ability to generate suppression (both allospecific and nonspecific) to newly encountered Ag declines with age, whereas a resident splenic suppressor cell population accumulates over the lifetime of the animals.     

Regulation of natural killer cell activation: implementation for the control of tumor metastasis

The cellular interactions that regulate natural killer (NK) cell-mediated cytotoxicity and antimetastatic activity following treatment with biological response modifiers (BRM) were studied. The transient activation of NK cells by a single injection of Corynebacterium parvum is followed by a refractory period during which a second injection of BRM fails to stimulate the already depressed NK cell activity. During this hyporesponsive period, the in vivo NK cell-dependent BRM-induced antimetastatic activity is markedly reduced and cannot be enhanced by multiple injections of BRM. A correlation exists between the generation of hyporesponsiveness to NK cell activation and the activation of suppressor macrophages by C. parvum. BRM that selectively activate NK cells without subsequently activating suppressor macrophages do not induce hyporesponsiveness to further activation of NK cells in vivo and, when given in multiple injections, retain the ability to inhibit hematogenous tumor metastasis.     

Indomethacin therapy abrogates the prostaglandin-mediated suppression of natural killer activity in tumor-bearing mice and prevents tumor metastasis

We have shown earlier that a decline in splenic natural killer (NK) activity during the development of transplanted or spontaneous tumors in mice results from an inactivation of NK lineage cells, mediated by prostaglandins (primarily PGE2) secreted by NK suppressor cells of the monocyte-macrophage lineage. In the present study we have used a C3H mouse mammary carcinoma model to examine whether this mechanism of NK suppression is conducive to tumor metastasis in vivo and whether a reversal of this suppression by a chronic indomethacin therapy can prevent metastatic spread from the primary tumor site. Three mammary tumor lines, all derived in our laboratory from a spontaneous C3H mammary tumor were employed: T-58 (uncloned parental line, having weak lung metastasizing ability from the subcutaneous site), C3 (a clone of T-58, showing high metastatic ability), and C10 (a nonmetastatic clone of T-58). Although the degree of NK susceptibility of these lines varied inversely with their metastatic potential, none was NK resistant. A chronic administration of indomethacin in the drinking water (14 micrograms/ml) to mice beginning on Day 4 after subcutaneous transplantation of 10(6) tumor cells resulted in a significant reduction in the growth rate of primary tumors in all hosts and led to a complete or nearly complete abrogation of lung metastasis in T-58- or C3-transplanted hosts examined at 1 month after tumor transplantation; C10-transplanted mice showed no metastasis in the control or the treated group. Concomitantly, there was a substantial restoration of splenic NK activity in all indomethacin-treated hosts. Plastic-adherent cells (greater than 95% macrophages) isolated from tumors growing in control mice, when coincubated for 20 hr with normal splenic effector cells caused a suppression of NK activity, reversible in the presence of indomethacin (10(-5) M) in vitro. Similar cells recovered from the residual primary tumors in indomethacin-treated mice had no suppressor ability. Chemically pure PGE2 (at concentrations of 0.5 to 1 X 10(-6) M, but not 0.25 X 10(-6) to 10(-8) M) also caused a suppression of NK activity of normal splenic effector cells, when added during the 4-hr 51Cr-release assay or allowed to interact with effector cells alone for a 20-hr incubation period; a removal of the cell-free PGE2 in the latter case prior to the NK assay did not relieve the suppression.(ABSTRACT TRUNCATED AT 400 WORDS)