Shifts in macrophage (M phi) surface phenotypes during tumor growth: association of Mac-2+ and Mac-3+ M phi with immunosuppressive activity

Rat anti-mouse monoclonal antibodies (mAb), anti-Mac-1, -2, and -3, directed against macrophage (M phi) glycoprotein surface antigens, were used to demonstrate a tumor-induced shift in peritoneal M phi subpopulations. This study of the tumor-induced shift was approached in two steps. First, to show that separate phenotypic M phi subpopulations existed and second, to show that a shift in these populations was involved in immunosuppression of the host during tumor growth. Endogenous peroxidase activity was examined among normal and tumor-bearing host (TBH) M phi. A significant increase in the number of peroxidase-positive M phi occurred during tumor growth. Indirect immunofluorescence showed a decrease in Mac-2+ cells and an increase in Mac-3+ cells in TBH M phi populations. When the mAb, anti-Mac-1,-2, and -3 were used in the presence of complement (C), they were cytotoxic for M phi and showed differential depletion of normal and TBH M phi. Peroxidase-positive TBH M phi were susceptible to C-mediated lysis by anti-Mac-1 and -3 but not by anti-Mac-2, whereas no direct relationship was observed among normal host M phi. To demonstrate differences between normal and TBH M phi subpopulations, soluble inhibitory factors were examined from mAb plus C-modified M phi populations. Anti-Mac plus C-treated normal and TBH M phi produced supernatants with different regulatory capabilities as assessed in the mixed-lymphocyte reaction (MLR). Anti-Mac-2 plus C treatment significantly reduced the ability of TBH M phi to produce a soluble suppressor(s) but did not alter normal host M phi-derived suppressor production. In contrast, anti-Mac-1 and -3 plus C treatment of normal host M phi significantly reduced suppressor production. In the TBH, however, anti-Mac-1 plus C had no effect, while anti-Mac-3 plus C had only a limited reduction as compared to the normal host. Determination of levels of prostaglandin E2 (PGE2) in M phi supernatants showed that normal host Mac-1+ M phi were involved in down regulation of PGE2 production. This control was missing in the TBH M phi. Mac-2+ M phi were the apparent producers of PGE2 which accounts for the factor-mediated MLR suppression attributed to TBH Mac-2+ M phi. Collectively, these data suggest that tumor-induced aberrations in immunoregulation can in part be attributed to differences in anti-Mac mAb-defined M phi subpopulations.     

Tumor-induced alteration in macrophage accessory cell activity on autoreactive T cells

Using a tumor-model system, differences in the accessory cell capabilities on autoreactive T cells of splenic macrophages from normal and tumor-bearing hosts (TBH) were assessed in the syngeneic mixed lymphocyte reaction. Tumor development caused a drop in autoreactivity. At 0 and 7 days of tumor growth, no drop in reactivity occurred when TBH macrophages were used as accessory cells and L3T4+ autoreactive T cells from normal mice were used as responder cells. However, by day 14, there was a 32% drop in reactivity, and by day 21 only 22% of the T cell reactivity remained when TBH macrophages were used as accessory cells. Alterations in macrophage Ia antigen during tumor growth were first investigated as the potential cause of reduced autoreactivity. Before tumor growth (day 0) 59% of the splenic macrophages were found to be Ia+. Day-7 TBH macrophages showed no difference in Ia antigen expression when compared to day 0 macrophages. However, by day 14, TBH macrophages showed a 9% decrease, and by day 21 they showed a 36% decrease in the number which were Ia+. Concomitant with the decrease in the number of Ia+ cells was a decrease in the density of Ia antigen expression on day-14 and -21 TBH macrophages. In day-14 and -21 TBH macrophages, two populations were seen that were Ia+. The first had a 10%-20% decrease in Ia antigen expression per cell while the second population had a greater than 50% drop in Ia antigen expression per cell. By titrating and mixing TBH macrophages with normal host macrophages, we assessed whether they could actively mediate suppression of autoreactive T cells. A titratable suppressive phenomenon was demonstrated using day-21 TBH macrophages. In contrast, day-7 and -14 TBH macrophages titrated with normal host macrophages had no effect on the syngeneic mixed lymphocyte reactivity. Lastly, we investigated whether the macrophage-mediated suppression was caused by increased prostaglandin secretion. Addition of indomethacin to cultures increased autoreactive T cell reactivity stimulated by normal or TBH macrophages (59% and 99% increase, respectively). Although indomethacin reduced suppression mediated by TBH macrophages, autoreactivity did not return to levels induced by untreated or indomethacin-treated cells from a normal host. Taken together, the data suggested that tumor growth modulates the function of macrophage accessory cells with autoreactive T cells in at least two ways: by decreasing Ia antigen expression and by increasing suppressor activity.     

Characterization of an endogenous Lyt2+ T-suppressor-cell population regulating autoreactive T cells in vitro and in vivo

Autoreactive T cells have been defined by their capacity to respond to self-Ia antigens expressed on non-T cells. Several recent studies have suggested that these cells may play important immunoregulatory functions. However, it is not clear what regulates the responsiveness of autoreactive T cells and why such cells are not demonstrably stimulated in vivo, where they are in the constant presence of self-Ia antigens. In the present study we examined the role of T suppressor (Ts) cells in regulating autoreactive T cells. We observed that enhanced autoreactivity occurred in vitro when Lyt2+ T cells were depleted from the responding and/or stimulating spleen cells in a syngeneic mixed-lymphocyte reaction. Similarly, addition of irradiated Lyt2+ T cells but not L3T4+ T cells inhibited the response of L3T4+ T cells to self-Ia antigens. The activity of the suppressor cells was specific to the autoreactive T cells since antigen-specific and alloreactive T-cell proliferation were not inhibited. Furthermore, depletion of Lyt2+ T cells by in vivo treatment of mice with anti-Lyt2 monoclonal antibodies caused enhanced endogenous proliferation of lymph node and splenic T cells and increased the T-cell response to self-Ia antigens in vitro. These studies, therefore, suggest that T-cell tolerance to self-Ia antigens in vivo may be maintained by naturally occurring Lyt2+ Ts. Mice having enhanced autoreactivity may provide a useful tool to address the role of autoreactive T cells in the immune response to foreign antigens and in the pathogenesis of autoimmune diseases.     

Glucocorticosteroid modification of lymphocyte blastogenesis in tumor-bearing hosts

The present study was done to evaluate glucocorticosteroid modulation of the individual cells contributing to tumor-induced dualistic (macrophage and suppressor T-cell) suppression in mitogen-induced lymphocyte proliferation. Steroid-sensitive T cells from normal mice showed a characteristic decrease in phytohemagglutinin responsiveness in the in vitro presence of 0.1 μg hydrocortisone sodium-21 succinate (HC), while tumor-bearing host (TBH) T cells demonstrated little or no decrease. This correlates well with kinetic study results demonstrating decreased HC-mediated suppression of mitogen-induced TBH T-cell DNA synthesis at 8 to 10 days posttumor cell inoculation. Hydrocortisone-treated cells from mice with advanced tumors had significantly higher degrees of blastogenesis than untreated TBH cells. In the optimal presence of both macrophages (Mφ) and HC, TBH cells had significantly greater blastogenesis than their normal counterparts. Alone, Mφ or HC depressed normal host PHA responsiveness. Experiments were carried out to determine if the increased blastogenesis was due to the additional Mφ presence in TBH. In vivo administration of methylprednisolone acetate demonstrated that steroids can inhibit tumor growth. A significant delay in tumor appearance occurred when the steroid was administered 4 to 7 days after tumor transplant perhaps due to the measurable lack of suppressor T cells. These studies indicated that steroid suppression was directed against a sensitive suppressor T cell and possibly acts by preventing its differentiation. The role of the Mφ in the afferent limb of the cell-mediated immune response seems less clear, but the results suggest nonspecific inhibition of TBH T-cell response to blastogenic stimulus.     

Characteristics of immunosuppressive macrophages induced in spleen cells by Mycobacterium avium complex infections in mice

The profile of generation and characteristics of splenic macrophages (M phi s) which suppress the concanavalin A (Con A) mitogenic response of splenic T cells (designated as 'immunosuppressive M phi s') in host CBA/JN mice during the course of Mycobacterium avium complex (MAC) infection were investigated. In MAC-infected mice, reductions in some cellular functions of host splenic T cells, such as the Con A mitogenic response and mixed leucocyte reaction, were seen around 2 weeks after challenge of organisms, and this was accompanied by appearance of immunosuppressive M phi s in spleen cells. In this case, increase in immunosuppressive M phi activity was seen in terms of both activity per spleen and activity per individual M phi. In this phase of the infection, MAC-induced splenic M phi s showed a markedly increased ability to produce reactive oxygen radicals in response to phorbol myristate acetate. Thus, the expression of suppressor activity of MAC-induced M phi s seems to be closely linked to their activated state. A large proportion of the immunosuppressive M phi s exhibited suppressor activity dependent on prostaglandins and membrane functions related to microfilaments. It was also found that the generation of IL-2-reactive T cell populations in response to Con A was markedly inhibited by MAC-induced splenic M phi s, whereas they caused no significant reduction in the IL-2-producing ability of normal spleen cells.     

Prostaglandin E2 inhibits human T-cell proliferation after crosslinking of the CD3-Ti complex by directly affecting T cells at an early step of the activation process

We have studied the effects of prostaglandin E2 (PGE2) on in vitro human T-cell activation induced by crosslinking of the CD3-Ti complex with the monoclonal anti-CD3 antibodies OKT3 and UCHT-1. PGE2 (greater than or equal to 3 X 10(-9) M) when added simultaneously with anti-CD3 to cultures of peripheral blood mononuclear cells (PBMC), significantly suppressed, in a dose-dependent way, T-cell proliferation (P less than 0.002). However, when T cells were first preactivated with OKT3 for 3 days, subsequent proliferation driven by recombinant interleukin 2 (IL-2) was not inhibited by addition of PGE2. This indicates that PGE2 affects the activation step resulting from crosslinking of CD3-Ti, but not the IL-2-driven proliferative phase. Other manifestations of T-cell activation were therefore examined. Both IL-2 production and the expression of receptors for IL-2 (as detected with the anti-Tac monoclonal antibody) were inhibited by PGE2. The addition of purified interleukin 1 (IL-1) or recombinant IL-2 to the cultures did not reverse the inhibiting effect of PGE2 on IL-2-receptor expression. PGE2, added at the time of culture initiation, also inhibited T-cell proliferation in cultures which were supplemented with exogenous IL-1 or IL-2. Proof for a direct effect of PGE2 on T cells was obtained in experiments in which monocyte-depleted T cells were stimulated, in the presence of IL-1, with solid-phase-bound anti-CD3 antibody. Proliferation of T cells in this system is accessory cell independent and still was strongly inhibited by PGE2. Finally, preincubation of PBMC with PGE2 (3 X 10(-6) M) for 48 hr did not result in the generation of suppressor cells for anti-CD3-induced T-cell proliferation or for IL-2 production. Our results demonstrate that PGE2 has a direct inhibitory effect on an early step of T-cell activation, resulting in decreased IL-2 production, decreased IL-2-receptor expression, decreased responsiveness to exogenous IL-2, and decreased proliferation. However, PGE2 does not affect IL-2-driven proliferation of activated T cells. The inhibitory effect on T-cell activation is not mediated through suppressor T cells, nor through inhibition of accessory cell function.     

Two-color flow cytometric analysis of the expression of MAC and MHC class II antigens on macrophages during tumor growth

Tumor-bearing host (TBH) macrophages (M phi) exhibit immune dysfunction that is concomitant with phenotypic changes. We examined M phi subpopulations by changes in the expression of surface antigens Mac-1, -2, -3, and Ia on normal and TBH peritoneal and splenic M phi. M phi were double-labeled and analyzed by flow cytometry to observe multiple expression of surface antigens. Tumor growth alters the multiple expression of these M phi markers. Peritoneal and splenic M phi had different Mac+ and Mac+Ia+ population percentages. In TBH, peritoneal M phi had decreased percentages of Mac-1+2+, Mac-1+3+, Mac-2+3+, and Mac+Ia+ M phi. This decrease correlated with functional changes in TBH M phi. In contrast, there was an increase in Mac-2-Ia- TBH peritoneal M phi. Previously undiscovered Mac-1+2-3- and Mac-1-2-3+ populations were found. In contrast to peritoneal M phi, there was an increase in the percentage of Mac-1+2+, Mac-1+3+, and Mac-2+3+ splenic TBH M phi but, like peritoneal M phi, there was a decrease in the percentage of Mac+Ia+ M phi. Also, TBH splenic M phi showed a smaller but more uniform antigen density than normal host splenic M phi. Tumor growth modulated phenotypic alterations in peritoneal and splenic M phi subpopulations. Combined with earlier functional studies of M phi subpopulations, these data suggested a relationship between changes in M phi phenotype and tumor-induced dysfunction of M phi-modulated immune activity.     

Characteristics of immunosuppressive macrophages induced in host spleen cells by Mycobacterium avium complex and Mycobacterium tuberculosis infections in mice

The profile of generation and characteristics of immunosuppressive macrophages (M phi s), which suppress the ConA-mitogenic response of spleen cells (SPCs), in host CBA/JN mice during the course of Mycobacterium avium complex (MAC) and M. tuberculosis (MT) infections were investigated. In both infections, a marked reduction in ConA mitogenic response of splenic T cells was seen around 2 weeks after infection, and this was accompanied by generation of potent immunosuppressive M phi s in the SPCs of infected mice. The suppressive activity was much stronger in MT-infected mice than in MAC-infected ones. In both infections, the large part of the suppressive M phi s exhibited suppressor activity that depended on the arachidonic acid cascade, particularly mediated by prostaglandins (PGs), and the remainder showed the suppressor action independent from PGs. The unique finding of this study is that the generation of IL-2 reactive T cell populations in SPCs in response to ConA signal was markedly inhibited by the MAC- and MT-induced immunosuppressive M phi s, whereas the suppressive M phi s failed to reduce the IL-2-producing ability of splenic T cells. In any case, the present results indicate a close similarity in immunosuppressive M phi s induced by MAC and MT infections.     

Interleukin 2 (IL-2) activity during tumor growth: IL-2 production kinetics,absorption of and responses to exogenous IL-2

A temporal study assessed the relationship between fibrosarcoma growth and immunologic encumberance due to the inability of BALB/c mouse splenocytes to elaborate the lymphokine Interleukin 2 (IL-2). Nylon-wool fractionation and antiserum treatments suggested the existence of a mildly nylon-wool-adherent, anti-Lyt 2-sensitive tumor-induced suppressor T (T_s,) cell which significantly decreased IL-2 activity. Absorption investigations indicated that ligand-activated tumor-bearing host (TBH) spleen cells were less receptive to IL-2 than their normal counterparts. When splenocytes were antiserum treated before absorption, removal of Lyt 2⁺ (suppressor T) cells resulted in greater IL-2 absorption by the remaining cells. Purified IL-2 only partially restored suppressed TBH spleen cell mitogen- or alloantigen-induced blastogenesis; whereas, normal host reactivity was significantly augmented. The collective data suggest that TBH spleen cells were capable of producing IL-2 and of responding to the IL-2 amplification signal when tumor-induced T_s cells were depleted.     

Inhibition of macrophage-induced antigen-specific T-cell proliferation by interferon-gamma

The effects of IFN-gamma on macrophage (M phi)-mediated antigen-specific T-cell proliferation was investigated. A well-defined assay system using purified resident populations of antigen-pulsed peritoneal M phi and immune T cells was used to measure M phi-induced antigen-specific T-cell proliferation. Antibody affinity purified or recombinant IFN-gamma inhibited M phi-induced T-cell proliferation when KLH-pulsed M phi from mice given IFN-gamma prior to KLH were cultured with KLH immune T cells from normal mice. Monoclonal rat anti-IFN-gamma antibody neutralized the inhibitory effect of IFN-gamma. This inhibition of T-cell proliferation occurred despite the fact that these M phi appeared to be activated by IFN-gamma treatment as measured by increased tumoricidal activity. The mechanism for the inhibition was unrelated to class II (Ia) expression, IL-1 secretion, and prostaglandin secretion. These results demonstrate the complex and sensitive role IFN-gamma has in regulating the immune response.     

Paclitaxel enhances macrophage IL-12 production in tumor-bearing hosts through nitric oxide.

Tumor-induced macrophages (Mphis) mediate immunosuppression, in part, through increased production of factors that suppress T cell responsiveness and underproduction of positive regulatory cytokines. Pretreatment of tumor-bearing host (TBH) Mphis with the anticancer agent paclitaxel (Taxol) partially reverses tumor-induced Mphi suppressor activity, suggesting that paclitaxel may restore TBH Mphi production of proimmune factors. Because paclitaxel demonstrates LPS-mimetic capabilities and increased production of the LPS-induced immunostimulatory cytokine IL-12 could account for enhanced T cell responsiveness, we investigated whether paclitaxel induces Mphi IL-12 production. Tumor growth significantly down-regulated Mphi IL-12 p70 production through selective dysregulation of IL-12 p40 expression. LPS stimulation failed to overcome tumor-induced dysregulation of p40 expression. In contrast, paclitaxel significantly enhanced both normal host and TBH Mphi IL-12 p70 production in vitro, although TBH Mphi IL-12 production was lower than that of similarly treated normal host Mphis. Paclitaxel enhanced p40 expression in a dose-dependent manner. Through reconstituted Mphi IL-12 expression, paclitaxel pretreatment relieved tumor-induced Mphi suppression of T cell alloreactivity. Blocking Mphi NO suppressed paclitaxel's ability to induce IL-12 production. This suggests that paclitaxel-induced activities may involve a NO-mediated autocrine induction pathway. Collectively, these data demonstrate that paclitaxel restores IL-12 production in the TBH and ascribe a novel immunotherapeutic component to the pleiotropic activities of NO. Through its capacity to induce IL-12 production, paclitaxel may contribute to the correction of tumor-induced immune dysfunction.     

Normal and tumor-bearing host macrophage factor-mediated modulation of mixed-lymphocyte reaction responsiveness: Separation of T-lymphocyte subset susceptibility to enhancing and inhibitory factors

The mixed-lymphocyte reaction reactivity of normal and tumor-bearing host (TBH) T-cell subsets was examined in response to normal and TBH macrophage (Mø) supernatants. Both inhibiting and enhancing activities were identified in normal and TBH Mø supernatants. The present data suggest that TBH Mø supernatants contained more inhibitory activity than normal host Mø supernatants and that enhancing activity of Mø supernatants was restricted to the Lyt 2,3⁺ population of cells. TBH Lyt 2,3⁺ cells were more responsive to the enhancing molecule(s) than their normal counterparts. These data were consistent with studies which implicate Mø as being partially responsible for the immune dysfunction seen in TBH, and extends previous findings on the ability of Mø to regulate the immune response in an attempt to achieve homeostasis.     

The effect of bone marrow depletion on prostaglandin E-producing suppressor macrophages in mouse spleen

The i.p. injection of Corynebacterium parvum (CP) into CBA/J mice effected increases in macrophage colony-forming cells (M-CFC) when spleen cells were cultured with L cell culture filtrate as a source of colony-stimulating factor. Significant increases in phagocytic macrophages (M phi) with Fc receptors for IgG2a and IgG2b immune complexes were additionally noted among the spleen cells in these mice. These M phi effectively inhibited Con A-induced lymphocyte proliferation, probably reflecting a 10-fold increase above normal controls in prostaglandin E to 47 ng/3 X 10(6) spleen cells/ml. To determine whether the suppressor M phi are immediate derivatives of splenic M-CFC, we tried to induce suppressor M phi by the injection of CP into mice depleted of bone marrow M-CFC by the earlier administration of the bone-seeking isotope, 89Sr. This procedure reduced M-CFC in the bone marrow to less than 1% of normal for more than 30 days. Monocytes in the blood fell to 5% of normal by day 10 and were 30% on day 30. Levels of resident peritoneal M phi showed relatively little change in this period. By contrast, splenic M-CFC increased to 20-fold higher than the "cold" 88Sr controls. CP-induced suppressor M phi activity, however, was sharply reduced in 89Sr marrow-depleted mice on day 10, despite the striking increase in M-CFC. There was a threefold increase in the number of phagocytic M phi binding IgG2a immune complexes, with no significant increase in IgG2b binding M phi. The kinetics of recovery of suppressor M phi activity showed that on days 20, 30, and 50 after 89Sr injection the activities reached 20%, 30%, and 70% of the "cold" control, respectively, and correlated with the recovery of significant levels of M-CFC in the bone marrow. Taken together, these observations suggest that splenic M-CFC are not an immediate source of PGE-suppressor M phi in vivo. It appears more likely that the CP-inducible suppressor M phi, in particular, originate from radiosensitive bone marrow cells or require for differentiation a microenvironment provided by bone marrow cells. The data also suggest that the expression of the Fc gamma 2b receptor and of suppressor activity by CP-induced splenic M phi are related phenomena.     

Cyclophosphamide and abrogation of tumor-induced suppressor T cell activity

Summary Previously we have demonstrated that the in vitro generation of P815-specific anti-tumor cytotoxic T lymphocytes (CTL) was suppressed by splenic suppressor T cells from late tumor-bearing hosts (TBH). Suppression is not caused by in vitro growth of P815 from splenic metastases, since suppression was also seen with spleen cells from late TBH mice bearing a hypoxanthine/aminopterin/thymidine-sensitive subline (PHS-5) of P815 in the presence of HAT. Cyclophosphamide has been shown to inhibit theinduction of suppressor cells selectively in a number of immune responses, but evidence that it can inhibit active tumor-induced suppressor T cells is limited. We have found that suppressor T cells already induced by P815 in syngeneic late TBH are sensitive to low doses of cyclophosphamide (50 mg/kg) given 1 day before spleen harvest, but the in vitro CTL response of late TBH spleen cells could not be restored by pretreating the mice with cyclophosphamide, even when exogenous interleukin-2 was added to the cultures. Although 50 mg/kg cyclophosphamide did not inhibit the CTL response of spleen cells from mice immunized with P815 +Corynebacterium parvum, the same dose of cyclophosphamide eliminated the CTL response of spleen cells from early TBH. Interleukin-2 (IL-2) did not overcome this effect of cyclophosphamide, suggesting a direct effect on CTL. Ultra-low-dose cyclophosphamide (10 mg/kg) did not adversely effect early TBH CTL but was still able to eliminate suppressor T cell activity from late TBH. Nevertheless, late TBH CTL remained unresponsive after pretreatment of mice with ultra-low-dose cyclophosphamide, even when exogenous IL-2 was added in vitro. CTL precursor frequency analyses demonstrated that cyclophosphamide pretreatment had little or no effect on the numbers of CTL precursors from early TBH. Late TBH CTL precursor cells were not detectable in these studies, with or without suppressor T cell inhibition by cyclophosphamide pretreatment. Thus, it appears that most CTL precursor cells may be lost or irretrievably inactivated in the spleens of late TBH mice.This work was supported by grants CA42443, CA48075 and T32-CA09210 from the National Cancer Institute, Department of Health and Human Services, and an American Cancer Society Clinical Oncology Career Development Award (H. D. Bear)     

A low level of macrophages enhances anti-TNP plaque-forming cell generation by human lymphocytes against TNP-Brucella abortus, a T-independent antigen

Making use of trinitrophenyl-Brucella abortus (TNP-Ba), a T-independent antigen, the mechanism of antibody production in vitro by human lymphocytes was studied, focusing on the accessory role played by macrophages (m phi). Human tonsillar cells and peripheral blood lymphocytes (PBL), and their fractions which were depleted of T cells, M phi, or both by rosetting with sheep erythrocytes and glass adherence plus passage through a Sephadex G-10 column, were stimulated in vitro with TNP-Ba under optimal culture conditions. Substantial antibody response against the antigen was induced in the whole tonsillar cells, while no appreciable level of response was induced in the whole PBL. The level of response observed after T-cell depletion was not different from that of the whole cells. In contrast, the response was significantly enhanced both in tonsillar cells and in PBL by depleting M phi to a low level, such as 1-2% of the cultured cells. It was further shown that a small amount of M phi added back to the M phi-depleted fraction activity suppressed the response again to the level seen in the whole cells. If allogenic M phi were substituted for autologous ones, the same degree of suppressor function was observed irrespective of the difference seen in the HLA types.     

Francisella tularensis elicits IL-10 via a PGE₂-inducible factor, to drive macrophage MARCH1 expression and class II down-regulation

Francisella tularensis is a bacterial pathogen that uses host-derived PGE? to subvert the host's adaptive immune responses in multiple ways. Francisella-induced PGE? acts directly on CD4 T cells to blunt production of IFN-γ. Francisella-induced PGE? can also elicit production of a >10 kDa soluble host factor termed FTM?SN (F. tularensismacrophage supernatant), which acts on IFN-γ pre-activated M? to down-regulate MHC class II expression via a ubiquitin-dependent mechanism, blocking antigen presentation to CD4 T cells. Here, we report that FTM?SN-induced down-regulation of M? class II is the result of the induction of MARCH1, and that M? expressing MARCH1 "resistant" class II molecules are resistant to FTM?SN-induced class II down-regulation. Since PGE? can induce IL-10 production and IL-10 is the only reported cytokine able to induce MARCH1 expression in monocytes and dendritic cells, these findings suggested that IL-10 is the active factor in FTM?SN. However, use of IL-10 knockout M? established that IL-10 is not the active factor in FTM?SN, but rather that Francisella-elicited PGE? drives production of a >10 kDa host factor distinct from IL-10. This factor then drives M? IL-10 production to induce MARCH1 expression and the resultant class II down-regulation. Since many human pathogens such as Salmonella typhi, Mycobacterium tuberculosis and Legionella pneumophila also induce production of host PGE?, these results suggest that a yet-to-be-identified PGE?-inducible host factor capable of inducing IL-10 is central to the immune evasion mechanisms of multiple important human pathogens.     

Amplification of suppressor inducer pathway with monoclonal antibody, anti-2H4, identifying a novel epitope of the common leukocyte antigen/T200 antigen

The 2H4 antigen, comprised of a 200/220-kDa glycoprotein of the leukocyte common antigen (LCA) family, is expressed on a suppressor inducer, but not a helper inducer subset of T4 cells. Earlier studies have demonstrated that the T4+2H4+ subset of cells maximally responded to the AMLR and this molecule has an important role in generated suppressor signals in AMLR/Con A-activated T cell systems. In the present study, we examined the effect of a series of monoclonal antibodies including anti-2H4 antibody on the initial activation of T4 cells in response to self-Ia antigens. We found that the addition of anti-2H4 antibody resulted in an augmentation of the proliferative response of T4 cells in AMLR, whereas other antibodies reactive with LCA/T200 antigens lacked this ability. Furthermore, anti-2H4 antibody enhanced both IL-2 production and IL-2R expression in this AMLR system. This enhancing effect was inhibited by anti-T3 antibody. Moreover, the suppressor inducer function of AMLR T4 cells was enhanced with anti-2H4 antibody by increasing the number of 2H4+ cells with high antigen density. Taken together, these results suggest that the 2H4 antigen may serve as an accessory structure for enhancing the activation of the T4+2H4+ suppressor inducer subset at initiation of cell triggering.     

Sequential effects of prostaglandins and interferon-gamma on differentiation of CD8+ suppressor cells

We have previously demonstrated that differentiation of CD8+ Tp44- suppressor cells in pokeweed mitogen (PWM)-stimulated cultures requires soluble factors elaborated by CD4+ cells and monocytes, and that the monocyte signal for such differentiation can be replaced by prostaglandin E2 (PGE2). In this study, we explored the ability of interleukin 2 (IL 2) and interferon-gamma (IFN-gamma) to replace the CD4+ signal. When IL 2 or IFN-gamma was used at concentrations equivalent to those present in supernatants of PWM-pulsed cultures of CD4+ cells, no effect on differentiation of CD8+ cells was observed. However, a potent suppressor inducing activity was detected when IFN-gamma, but not IL 2, was mixed with supernatants derived from cultures of PWM-pulsed purified monocytes (M phi sup) or with 10(-8) M PGE2. Differentiated CD8+ suppressor cells (Ts) inhibited both PWM-stimulated proliferative response of CD4+ cells and immunoglobulin production by B cells. The signals mediated by the M phi sup or PGE2 and IFN-gamma were shown to act sequentially. That is, M phi sup or PGE2 was required initially, followed by an IFN-gamma-dependent differentiative step. These studies thus suggest a cascade of cellular interactions involving monocytes, CD4+ cells, and CD8+ Ts precursors that are required for the differentiation of CD8+ suppressor effector cells.     

Enhancement of cytotoxic T lymphocyte growth from spleens of P815-tumor-bearing host mice with mafosfamide

Summary Mafosfamide (Mafo) is an analog of cyclophosphamide that does not require hepatic activation and therefore has in vitro activity. The present study was conducted to determine the effects of in vitro treatment with Mafo on the generation and growth of cytotoxic T lymphocytes (CTL) from tumor-bearing host mice (TBH). In contrast to early (day-11) TBH splenocytes, splenocytes from late (days 18–20) P815 TBH mice suppress the in vitro generation of CTL. Treatment of late TBH splenocytes in vitro with 5–15 µM Mafo resulted in a reduced ability of these cells to suppress in vitro CTL generation. Treatment of late TBH splenocytes with 10 µM Mafo also inhibited their ability to suppress adoptive immunotherapy of intradermal tumors with immune splenocytes. These doses of Mafo were selectively toxic to the suppressive effects of late TBH splenocytes, since treatment of early TBH splenocytes with 1–10 µM Mafo did not significantly inhibit CTL generation. Spleen cells from early (days 10–12) TBH mice, carried in long-term in vitro sensitization cultures in the presence of tumor cells and 20 U/ml human recombinant interleukin-2, did not increase in cell number over time. However, when pretreated with 3 µM Mafo, this population of tumor-sensitized lymphocytes demonstrated 450-fold growth over 6 weeks as compared to the static cell numbers for the untreated controls. High levels of tumor-specific cytolytic activity were maintained in these expanded cells. These results suggest that Mafo pretreatment markedly and selectively inhibits suppressor cells that limit long-term expansion of splenic CTL in culture and inhibit adoptive immunotherapy of solid tumors.This work was supported by grants CA 42443, CA 48075 and T32-CA 09210 from the National Cancer Institute, Department of Health and Human Services, in part by PHS AI-25044, an American Cancer Society Clinical Oncology Career Development Award (H. D. B.) and by a Medical Scholar's Award from the A. D. Williams Foundation (T. H. I.)     

Effects of aging on cell cooperation and lymphocyte responsiveness to cytokines

Functional activities and cell cooperation of macrophages (Mphi), T cells, and B cells of young and old Lewis rats were compared. Splenic M phi from young and old rats provided accessory help for T cell mitogenesis and B cell mitogenesis, provided accessory help for generation of PFC, and produced IL 1 equally well as measured in costimulator assays. Splenic T cells of aged Lewis rats, however, were poorly responsive in mitogen assays and did not respond to supplemental IL 2 and antigen with blast transformation and with increased help for B cells to produce PFC. "Old" B cells did not respond in vitro to mitogens with help from M phi and T cells, nor did they respond to B cell helper factor with increased PFC. The data indicate that hyporesponsiveness of the immune system, especially of B cells, in aged rats is due in part to defective reactivity to interleukins and cytokine(s) and to defective cell-cell cooperation.