Barbara L. Pope

Activation of suppressor T cells by low-molecular-weight factors secreted by spleen cells from tumor-bearing mice

The spleens of mice bearing large M-1 fibrosarcomas have been shown to contain several populations of cells which nonspecifically suppress antibody synthesis by cocultured normal spleen cells. It has now been shown that the spleens of tumor-bearing mice also contain inducer cells which secrete soluble factors capable of activating suppressor T cells from unprimed precursor cells. The activated suppressor cells are Thy 1+, Lyt 1+2+ and secrete a soluble suppressive factor. They inhibit the in vitro generation of antibody-forming cells by cocultured normal spleen cells stimulated by T-cell-dependent antigens. They do not, however, suppress the antibody response to T-cell-independent antigens and do not inhibit antibody synthesis by cocultured nude mouse spleen cells cultured with T-cell-dependent antigens and exogenous helper factors. In addition, suppression is blocked if conditioned medium containing T-cell growth factors is added to the suppressor cell assays. These data suggest that cells in the spleens of tumor-bearing mice secrete inducing factors which activate suppressor cells. These activated suppressor cells in turn secrete soluble suppressor factors which inhibit antibody synthesis, possibly by interfering with the synthesis or release of T-cell growth factors.

The involvement of protein kinase C, calcium, and 5-lipoxygenase in the production of tumor necrosis factor by a cloned interleukin-3 dependent cell line with natural cytotoxic activity.

The cloned interleukin-3 dependent cell line, M1-A5 was studied to determine whether protein kinase C, calcium mobilization, and 5-lipoxygenase activity were involved in the signal transduction pathways required for the production of TNF. TNF release was stimulated by 10 ng/ml phorbol myristate acetate (PMA), 2 microM calcium ionophore A23187, and 1 microgram/ml lipopolysaccharide (LPS) with synergism seen between PMA and A23187. All signals were blocked by phloretin and the PMA signal was blocked by H-7, both drugs acting as protein kinase C inhibitors. Desensitization of protein kinase C by PMA (1 microgram/ml for 24 h) provided evidence that both PMA- and LPS-stimulated TNF production were protein kinase C-dependent while A23187-stimulated TNF production was not. Both the calcium chelator, EGTA, and the intracellular calcium antagonist, TMB-8, inhibited TNF production stimulated by all agents, indicating that TNF stimulation by all agents was calcium dependent. Finally, the 5-lipoxygenase inhibitors, ketoconazole and L-656,224, but not the cyclo-oxygenase inhibitor ASA, inhibited TNF stimulated by all agents. These findings indicate that, although TNF production by M1-A5 cells can be stimulated either by a calcium/protein kinase C- or by a calcium-dependent signal, there is a convergence of signals at the level of 5-lipoxygenase activation.

In vivo enhancement of murine natural killer cell activity by 7-allyl-8-oxoguanosine (loxoribine).

7-Allyl-8-oxoguanosine (loxoribine) is a novel immunostimulatory compound which has been shown previously to enhance the antibody synthesis of antigen-stimulated B-lymphocytes. In this report, loxoribine was tested for the ability to activate murine natural killer (NK) cells. In studies in which mice were given a single subcutaneous (s.c.) or intravenous (i.v.) injection of loxoribine, splenic NK cell activity was increased in a dose-related manner with clear enhancement seen within 2 h of drug administration. The enhancement was optimal at 48 h but persisted for a minimum of 4 days. Slow and continuous administration of loxoribine via subcutaneously implanted infusion pumps successfully enhanced the NK activity for several days after all of the pump contents had been delivered. Peak NK responses were seen following s.c. or i.v. administration of 2-3 mg loxoribine per mouse in sesame oil, intralipid, or saline vehicles. Significant oral activity was seen after the administration of 8-10 mg/mouse in sesame oil or intralipid. The in vivo enhancement of NK activity was observed in spleen, blood, and bone marrow but was negligible in lymph nodes and thymus. Multiple injections of optimal concentrations of loxoribine did not tend to enhance the NK activity above that seen with a single injection, suggesting that the timing of injections was critical for optimal responsiveness.

Secretion of a suppressor cell inducing factor by an interleukin-3 dependent cell line with natural cytotoxic activity.

This report describes the morphology, surface markers, growth requirements, and functional activity of the M1-A5 cell line, which was established by the limiting dilution of spleen cells from a mouse bearing a large methylcholanthrene-induced fibrosarcoma. The M1-A5 cells share many of the morphological features of large granular lymphocytes and, in addition, express asialo GM1 and Ly-5 surface markers which are commonly found on natural killer cells (NK) cells. There is no expression of T-cell differentiation antigens, surface immunoglobulin, or the granulocyte/macrophage marker, MAC-1. M1-A5 cells are dependent on exogenous growth factor(s) for survival and will proliferate if cultured in interleukin 3 (IL-3), but not in interleukin 1 (IL-1), interleukin 2 (IL-2), or granulocyte/macrophage colony stimulating factor (GM-CSF). In addition, the M1-A5 cells do not absorb IL-2. Despite their morphology and surface characteristics, the M1-A5 cells do not lyse NK targets such as YAC-1 and RLM1 in 4- or 18-hr cytotoxic assays but do lyse the natural cytotoxic (NC) susceptible target, WEHI-164, and to a very small extent, the M-1 fibrosarcoma cells, in an 18-hr assay. Thus they exhibit NC-like cytotoxic activity. In addition, the M1-A5 cells secrete a small molecular weight factor which activates suppressor cells capable of inhibiting antibody synthesis by cocultured syngeneic spleen cells.

Activation of suppressor cells by low molecular weight factors secreted by spleen cells of tumor-bearing mice: Modulatory role of prostaglandins

We have shown previously that the spleens of mice bearing large M-1 fibrosarcomas contain inducer cells which secrete dialysable factors which activate suppressor T cells from unprimed, normal precursor spleen cells. Once activated, the suppressor cells inhibit the in vitro antibody synthesis of cocultured syngeneic splenocytes stimulated by T cell dependent antigens. In this paper we have examined the possibility that prostaglandins are involved in the activation process. Inducer and precursor cells were cultured in Marbrook vessels in chambers separated by dialysis membranes. Using this procedure, suppressor cells were activated following 12 h of culture but were not detectable after 6 h. The cyclooxygenase inhibitors, indomethacin, acetyl salicylic acid (ASA), and ibuprofen all prevented the activation of suppressor cells in a dose dependent manner. Prostaglandin (PG) E1, but not PGF2a or PGD2, restored the activation of suppressor cells in cultures containing the cyclooxygenase inhibitors. Restoration of suppressor cell activation was seen with 1 X 10(-7) M PGE1 but no activation of suppressor cells was seen in control cultures containing up to 1 X 10(-5) M PGE1. In addition, cultured spleen cells from tumor-bearing mice did not secrete higher quantities of PGE than did cells from age and sex matched normal mice. These data suggest that PGE has a modulatory rather than a direct role in the activation of suppressor cells by inducer factors from tumor-activated inducer cells.

Kinetic Analysis of the Inhibition of Natural Killer (NK) Activity by Multiple Populations of Tumor-Activated Suppressor Cells

Previous studies have shown that the progressive growth of the M-1 fibrosarcoma in DBA/2J mice is associated with the activation of suppressor cells which inhibit both mitogen-induced proliferative responses and antibody synthesis. In this study, we have analyzed the effect of tumor growth on NK cell activity. Mice in the advanced stages of tumor growth did have a significant depression in NK activity, and this depression could not be overcome by the injection of the interferon inducer, polyinosinic-polycytidylic acid (Poly I:C). The decline in NK activity was associated with the presence in the spleens of suppressor cells capable of inhibiting the NK activity of spleen cells from Poly I:C-treated syngeneic mice. In order to characterize the suppressor cells, we used a combination of negative selection procedures and kinetic analysis. These studies demonstrated that the spleens of tumor-bearing mice contained two distinct populations of suppressor cells which were not evident in normal mice. One population was non-adherent to nylon wool, Thy-1-, non-phagocytic, did not bind target cells, and had a non-competitive mechanism of suppression. The second population was adherent, Thy-1-, phagocytic, and had a competitive mechanism of suppression. In addition, the spleens of both normal and tumor-bearing mice contained an adherent, non-competitive suppressor cell population which was enriched following negative selection procedures removing T cells or phagocytic cells.

Induction of suppression by a murine nonspecific suppressor-inducer cell line (M1-A5).

A murine nonspecific suppressor-inducer cell line (M1-A5) was established by the limiting dilution method from the spleen cells of a mouse bearing an advanced methylcholanthrene-induced fibrosarcoma. Indirect immunofluorescence studies demonstrated that the M1-A5 cells were Thy-1-, sIg-, Ly-5+, MAC-, and 45% asialo GM1+. The M1-A5 cells were able to activate suppressor cells from unprimed, syngeneic normal spleen cells. These activated cells inhibited antibody production by cocultured syngeneic lymphoid cells. Induction of suppression by the M1-A5 cells was via the release of a suppressor-inducing factor, which was found to be protein in nature. Kinetic studies showed that when M1-A5 cells were separated from NSC by a dialysis tubing in Marbrook vessels, the M1-A5 cells required a minimum of 8 hr incubation period before suppressor cell activity could be demonstrated in precursor cells. On the other hand, induction of suppression by the suppressor-inducing factor required a minimum of 3 hr exposure of the precursor cells to the factor.

The effect of indomethacin on the activation and effector function of suppressor cells from tumor-bearing mice

SummaryThe spleens of mice with large M-1 fibrosarcomas contain two populations of suppressor cells with the properties of macrophages and T cells. In this study, we tested the effect of indomethacin on suppressor cell activation and effector function. Neither the activation nor the effector function of the suppressor macrophages was inhibited by indomethacin, and the activity of suppressor macrophages correlated with the tumor size. In contrast, the treatment of tumor-bearing mice with indomethacin from the day of injection of tumor cells completely blocked the in vivo activation of suppressor T cells. Indomethacin did not, however, depress suppressor T cell activity if mice were treated only during the third week of tumor growth. The effector function of the suppressor T cells, as assessed in mixing assays, was partially blocked by indomethacin, while selective suppression by low-molecular-weight factors was completely blocked if indomethacin was present in the cultures. Furthermore, the in vitro activation of suppressor cells by soluble factors secreted by tumor-bearer spleen cells was completely blocked by indomethacin, and this inhibition was reversed by prostaglandin E1. These data are consistent with the hypothesis that prostaglandins are involved in the activation, but not the effector function, of tumor-activated suppressor T cells.

Requirement for prostaglandin E1 (PGE1) for the secretion of suppressor cell inducer factors by spleen cells of tumor-bearing mice

We have demonstrated previously that spleen cells from mice bearing M-1 fibrosarcomas release low molecular weight factors capable of activating suppressor cells from unprimed normal spleen cells. Using Marbrook vessels to separate inducer and precursor populations, we found in the previous paper that cyclooxygenase inhibitors blocked the activation of suppressor cells and that this activation could be restored by exogenous PGE1. In this paper we have examined the site of action of the prostaglandins in the activation of suppressor cells. To do so, we tested cell-free supernatants from cultured spleen cells of tumor-bearing mice (inducer cells) for the ability to activate suppressor cells from unprimed normal spleen cells (precursor cells). Supernatants from acetyl salicylic acid (ASA) treated inducer cells did not activate suppressor cells and exogenous PGE1 could not restore the activity of this supernatant. In contrast, if inducer cells were treated with ASA and then incubated with PGE1, the supernatant was capable of activating suppressor cells. No role for prostaglandins at the level of the precursor cells or the effector suppressor cells was seen. These data suggest that the inducer cells in tumor-bearer spleens require prostaglandins for the release of an inducer factor but that prostaglandins are not required for the action of this factor on the precursor cells or for the effector function of the activated suppressor cells.

Splenic Natural Cytotoxic Activity is Enhanced during Growth of a Murine Fibrosarcoma

We have shown previously that the natural killer (NK) cell activity of DBA/2J mice bearing M-1 fibrosarcomas is consistently depressed at the later stages of tumor growth. The apparent mechanisms of inhibition are suppressor cell activation and prostaglandin E (PGE) production by tumor and lymphoid cells. In contrast, we show here that the natural cytotoxic (NC) activity of cells from the spleen, blood, and lymph nodes of mice bearing M-1 tumors is enhanced when compared to that of age- and sex-matched control mice. This enhanced NC activity does not appear to be due to increased cytolytic activity of macrophages but, rather, to enhanced cytolytic activity of multiple populations of non-adherent cells including B and T cells. Correlated with this is the finding that the NC activity of normal spleen cells is not inhibited in vitro by either PGE1 or PGE2 at levels which are inhibitory to NK cells. NC activity, although independent of PGE, is in fact enhanced by PGE1 in a dose-related fashion. These data indicate that NK and NC cells are regulated differently by PGE and during tumor growth. Utilizing a Winn assay, we also demonstrate that a cloned cell line with NC activity is capable of slowing tumor growth in vivo and that this action is improved if mice are treated with indomethacin concomitantly.