Interferons as modulators of human monocyte-macrophage differentiation. I. Interferon-gamma increases HLA-DR expression and inhibits phagocytosis of zymosan

The development of HLA-DR (Ia) expression in the presence and absence of interferon-gamma was monitored in monocyte-macrophage cultures. Overnight incubation with doses as low as 5 U/ml gave elevated values for Ia expression and the maximum increase was obtained with 200 U/ml. In contrast interferon-alpha had only a slight effect on the expression of Ia at doses as high as 2000 U/ml. The increase seen at 24 hr was maintained during the first 2 days of culture. The interferon-gamma-treated cells expressed four to five times more Ia than fresh monocytes. During the same time, monocytes cultured in the absence of interferon expressed approximately two times the amount of fresh monocytes. When the surface density of Ia was calculated, the interferon-gamma-treated monocytes expressed twice that of the untreated cells. Major changes in morphology and size occurred between days 3 and 4 of monocyte to macrophage development. Consequently a rapid increase in Ia expression took place; however, when the surface density was calculated this value increased only slightly when the monocytes matured to macrophages. The interferon-gamma-treated cells continued to express more total Ia as well as having increased surface density of this antigen. Interferon-gamma was also added to monocyte-macrophages several days after culture initiation (days 3, 4, and 5). Despite being in different stages of maturation, the cells responded to the interferon with increased Ia expression and surface density. The phagocytic activity of opsonized zymosans was also monitored. In contrast to Ia expression, this activity was downregulated by interferon-gamma, and the lower levels of phagocytosis were maintained through the 7 days of observation. Thus, interferon-gamma appears to change the differentiation pathway of the monocyte. The signal stimulates an increased level of Ia that may assist in the initiation of immune responses, and at the same time downregulates the scavenger role of removing opsonized particles. Once the monocyte has received this specific signal it continues to develop in a pathway different from that of the nontreated monocytes.     

Membrane vesicles shed by murine melanoma cells selectively inhibit the expression of Ia antigen by macrophages

We previously demonstrated that membrane vesicles shed by the F10 variant of the murine B16 melanoma cell line inhibited the induction by interferon-gamma (IFN) of murine macrophage immune response region-associated (Ia) antigen expression. In this paper we present evidence that the inhibition of macrophage Ia antigen expression is a selective effect of vesicles and characterize its temporal requirements. Membrane vesicles shed from F10 cells did not affect the expression of macrophage H-2K or H-2D antigens under conditions shown to profoundly inhibit Ia antigen expression. Similarly, the induction of plasminogen activator and interleukin 1 from macrophages was not inhibited by the vesicles. The vesicles did not measurably decrease total cellular RNA or protein synthesis. Macrophages were sensitive to the inhibitory effects of the vesicles during the induction and maintenance phases of Ia expression. Pretreatment of macrophages with vesicles before culture with IFN did not reduce the induction of Ia. The rate of decline of Ia expression after removal of IFN was unaffected by the presence of vesicles. Removal of vesicles from cultures of IFN-treated macrophages resulted in only a partial recovery of Ia expression, suggesting that the inhibition of Ia expression may be a slowly reversible process. The selective and partially reversible inhibition of Ia expression by vesicles shed from the plasma membrane of tumor cells is a possible mechanism whereby tumor-bearing hosts may become immunocompromised.     

Inhibition of recombinant interferon-gamma-induced Ia antigen expression by shed B16 F10 melanoma cell membrane vesicles

The expression of immune region-associated (Ia) antigens by macrophages is a prerequisite for antigen presentation, which is necessary for the activation of T helper cell function. A decrease in macrophage Ia expression is associated with a decrease in immune function in vitro. However, the effect of diseases accompanied by immunosuppression, such as cancer, on macrophage Ia expression has not been studied. The expression of Ia antigen was induced by the culture of murine peritoneal macrophages with recombinant interferon-gamma (IFN). Maximal expression was achieved after 4 days of culture. Membrane vesicles shed from the murine B16 F10 melanoma cell line inhibited the in vitro induction of Ia expression by 40 to 90% in allogeneic and syngeneic systems. Inhibition was not due to toxicity, a reduction in IFN activity, phagocytosis or contamination of the vesicle preparation with endotoxin, which is an inhibitor of Ia expression. Inhibition exerted by vesicles was prostaglandin-dependent and was over-come by increasing concentrations of IFN. It is possible that the reduction of macrophage Ia antigen expression by tumor cell products, such as shed membrane vesicles, contributes to the immunosuppression of tumor-bearing hosts. Employing IFN to reverse the inhibition provides a strategy for improving the therapy of patients with cancer.     

Granules of human CD3+ large granular lymphocytes contain a macrophage regulating factor(s) that induces macrophage H2O2 production and tumoricidal activity but decreases cell surface Ia antigen expression.

CTL (cytotoxic T lymphocytes) and LGL (large granular lymphocytes) exocytose cytoplasmic granules on activation after recognition of their target, releasing granule-associated molecules. We have previously suggested that this process could release immunoregulatory molecules. In this study we investigated whether normal human LGL granules contained a factor regulating different macrophage activity. Human CD3+ LGL cells were generated by activating peripheral blood lymphocytes (PBL) for 10-12 days with recombinant human IL-2 (rhIL-2), and granules were isolated from disrupted cell homogenate by Percoll gradient fractionation. Solubilized granules were tested for macrophage-activating factor (MAF) activity in three different macrophage assays. When M-CSF-differentiated murine bone marrow-derived macrophages were incubated 9 hr with human LGL granules, they were fully activated to lyse the TNF-resistant P815 tumor cells. The granule-MAF showed a synergistic effect with rhIL-1 beta, rmTNF-alpha, and rmIFN-tau in the cytolytic assay. In addition, proteose-peptone-elicited murine peritoneal macrophages profoundly increased H2O2 production after activation with human LGL granules. However, unlike IFN-tau, no increase in peritoneal macrophage Ia antigen expression was detected after incubation with granules. Moreover, granule-MAF suppressed Ia induction by IFN-tau. These results confirm that human CD3+ LGL granules contain a molecule(s) capable of regulating macrophage function.     

Human mononuclear phagocyte-associated antigens: I. Identification and characterization

Rabbit antisera were produced against a lymphokine-activated human macrophage cell line, U937 (αU937), and human peritoneal macrophages (αPEMØ). After absorption with AB erythrocytes, pooled platelets, and B-lymphoblastoid cell lines, both antisera reacted by microcytotoxicity, indirect immunofluorescence (IF), and radioimmunoassay (RIA) with adherence-purified human peripheral blood monocytes, splenic and peritoneal macrophages, and leukemic myelomonoblasts. A panel of normal human T lymphocytes, B lymphocytes, and erythroid-myeloid or lymphoblastoid cell lines failed to react with both αU937 and αPEMØ. Although both heteroantisera reacted against polymorphonuclear leukocytes (PMNs), after absorption with PMNs specific reactivity against mononuclear phagocytes remained. Absorption of αU937 and αPEMØ with myelomonoblastic leukemia cells (AMML) removed IF and RIA activity against both PMNs and monocytes but not against splenic and peritoneal macrophages. In contrast, absorptions of both heteroantisera preparations with splenic macrophages abolished their IF and RIA reactivity not only to splenic and peritoneal macrophages but also to peripheral blood monocytes and leukemic myelomonoblasts. These results are consistent with (1) both antisera defining specific monocyte/macrophage-associated antigens(s) which are distinct from MHC-coded HLA-A,B,C, and DR antigens, and (2) expression of common monocyte/macrophage-associated antigen(s) and uniquely associated antigen(s) selectively expressed on tissue macrophages. These reagents will be useful in delineating human monocyte/macrophage differentiation as well as the immunological functions of mononuclear phagocytes.     

Expression of surface antigen and mRNA for the CD11c (alpha X, p150) subunit of the human leukocyte adherence receptor family in hematopoietic cells

We characterized the surface antigen and mRNA expression for the CD11c (alpha X, p150) subunit of the human leukocyte adherence receptor family during hematopoietic cell differentiation. The CD11c subunit antigen and mRNA are constitutively expressed in undifferentiated HL-60 promyelocytic leukemia cells, and levels increase markedly with differentiation along the monocyte/macrophage pathway using phorbol myristate acetate. Human monocyte-derived macrophages and human alveolar macrophages express elevated levels of the CD11c subunit antigen and mRNA, indicating that the changes observed in vitro are present in vivo. Dot blot analysis of immature and mature lymphoid and myeloid cells and cell lines demonstrate equivalent levels of CD11c mRNA expression. We conclude that CD11c gene expression is selectively increased during hematopoietic cell differentiation along the monocyte/macrophage pathway.     

Prostaglandins and inflammation: enhancement of monocyte chemotactic responsiveness by prostaglandin E2.

The effects of prostaglandins on human monocyte chemotaxis were studied in vitro. None of the prostaglandins tested, including members of the A, B, E or F series, were chemotactic for monocytes. Prostaglandin E2 however, enhanced the chemotactic responsiveness of monocytes to complement - activated human serum by almost 200%. The enhancement of chemotaxis was not directly related to the ability of PGE2 to raise intracellular cyclic AMP levels. These studies support a role for prostaglandins as modulators of the inflammatory response.     

Lung-specific delivery of cytokines induces sustained pulmonary and systemic immunomodulation in rats

The recombinant cytokines IFN-gamma and TNF-alpha stimulate several macrophage-mediated functions important in host defense. However, systemic administration of cytokines may be limited by significant host toxicity. We investigated whether aerosolized cytokines can stimulate alveolar macrophage and blood monocyte function, and whether they induce an inflammatory response in the lungs of normal rats. We found that aerosolized murine rIFN-gamma or recombinant human TNF-alpha increased IL-1 production by both alveolar macrophages and blood monocytes for at least 5 days after administration. Furthermore, murine rIFN-gamma increased the expression of Ia Ag on alveolar macrophages and human rTNF-alpha increased alveolar macrophage- and blood monocyte-mediated tumor lysis. Sequential aerosolization of IFN-gamma and TNF-alpha significantly increased both IL-1 release and Ia expression compared to either cytokine administered alone. Aerosolized human rTNF-alpha achieved lung levels comparable to those produced by an i.v. TNF-alpha dose reported to cause diffuse organ injury and death in rats. However, plasma TNF-alpha levels were several thousand-fold lower after aerosol administration. Aerosolized cytokines did not induce lung edema or an inflammatory cell infiltrate within the airways or alveoli. Aerosolized human rTNF-alpha alone, or murine rIFN-gamma and human rTNF-alpha, induced margination of leukocytes in pulmonary blood vessels 1 day after aerosolization, and a few small foci of pulmonary hemorrhage 5 days later. We conclude that aerosol administration of IFN-gamma or TNF-alpha enhances both pulmonary and systemic monocyte function, and that the combination of IFN-gamma and TNF-alpha produce additive or synergistic effects. Aerosolized cytokines induce only a minimal pulmonary inflammatory response. Aerosolized TNF-alpha produces high cytokine levels in the lung but very low uptake into the circulation.     

Evidence for effects of interleukin 4 (B cell stimulatory factor 1) on macrophages: enhancement of antigen presenting ability of bone marrow-derived macrophages

We have studied the effects of recombinant mouse interleukin 4 (IL 4) (previously known as B cell stimulatory factor 1) on the antigen-presenting ability of murine splenic B cells and bone marrow macrophages. Our assay is based on the induction of antigen-presenting ability in these cells after incubation with IL 4 for 24 hr. The presenting cells were then used to stimulate IL 2 production by antigen-specific, I-Ad-restricted T cell hybridomas, a response mainly dependent on the induction of Ia antigens. Consistent with our previously published data using partially purified natural IL 4, we show here that recombinant IL 4 (but not interferon-gamma (IFN-gamma) or IL 1) induces antigen-presenting ability in B cells. Recombinant IL 4 was also found to induce antigen-presenting ability in a cloned, bone marrow derived-macrophage cell line (14M1.4), and in normal bone marrow-derived macrophages. These macrophage populations also respond to IFN-gamma showing enhanced antigen-presenting ability (mediated by increased Ia antigen expression). A small but significant increase in Ia antigen expression was also detected in 14M1.4 macrophages induced with IL 4. However, additional analysis suggested that the effect of IL 4 on 14M1.4 is different from that of IFN-gamma, because IL 4 (but not IFN-gamma) is able to maintain the viability and increase the size of and metabolic activity of bone marrow macrophages. However, IL 4 may not affect all macrophages because the macrophage cell line P388D1, which responds to IFN-gamma, failed to show enhanced antigen-presenting function after stimulation with IL 4. These observations indicate that IL 4, a lymphokine previously considered to be B cell lineage specific, has effects on macrophages and may be involved in their activation.     

Cyclosporine inhibits macrophage-mediated antigen presentation

The influence of cyclosporine on antigen-specific, macrophage-dependent T cell activation was analyzed in vitro. Murine T cell activation by antigens derived from Listeria monocytogenes was monitored by the production of interleukin 2. Pretreatment (2 hr, 37 degrees C) of macrophages with cyclosporine resulted in a cell population with a markedly diminished capacity to support the activation of T lymphocytes. When cyclosporine-pretreated macrophages were added to cultures of untreated T cells and antigen, the dose of cyclosporine that produced 50% inhibition (ID50) was 1.5 micrograms/ml, and if antigen was present during the drug pretreatment, the ID50 was 0.6 micrograms/ml. Pretreatment of T cells also inhibited their subsequent activation by antigen and untreated macrophages, but a higher dose of cyclosporine was required to produce similar inhibition (ID50 = 4.4 micrograms/ml). Additional experiments focused on the mechanism of inhibition of antigen presentation when macrophages were pretreated with the drug. The addition of interleukin 1 or indomethacin to the cultures did not alter the inhibitory effect of cyclosporine. Under conditions that produced greater than 90% inhibition of antigen presentation, macrophage surface Ia expression was not altered, and the uptake and catabolism of radiolabeled antigen remained normal. Thus, cyclosporine had profound effects on antigen presentation that appear to be unrelated to decreases in interleukin 1 production, increases in prostaglandin production, decreases in Ia expression, or changes in antigen uptake and catabolism.     

Prostaglandins and inflammation: Enhancement of monocyte chemotactic responsiveness by prostaglandin E2

The effects of prostaglandins on human monocyte chemotaxis were studied $\text{in vitro}$. None of the prostaglandins tested, including members of the A, B, E or F series, were chemotactic for monocytes. Prostaglandin E₂ however, enhanced the chemotactic responsiveness of monocytes to complement - activated human serum by almost 200%. The enhancement of chemotaxis was not directly related to the ability of PGE₂ to raise intracellular cyclic AMP levels. These studies support a role for prostaglandins as modulators of the inflammatory response.     

Prostaglandin E specifically upregulates the expression of the mannose-receptor on mouse bone marrow-derived macrophages.

The macrophage mannose receptor (MMR) facilitates the binding and internalization of microorganisms and glycoproteins with terminal mannose residues. The receptor is progressively upregulated as bone marrow precursor cells mature into macrophages and thus may serve as a marker of differentiation. Prostaglandins of the E series (PGE) are known inhibitors of monocyte and macrophage precursor proliferation, an effect often associated with cellular maturation. MMR expression was therefore assessed after exposure of bone marrow macrophage precursor (BMMP) cells to these prostanoids. Receptor expression was determined by ligand binding and via immunoprecipitation of newly synthesized receptor molecules. PGE1 and PGE2 at 10(-9)-10(-6) M upregulated MMR surface expression and biosynthesis four- to sixfold in a dose-dependent manner. BMMPs responsive to prostaglandins were characterized by plastic adherence, F4/80 antigen expression, and nonspecific esterase activity. Prostaglandins accelerated the expression of the MMR in cells by 48-72h, with maximal levels of receptor expression being identical in control or treated cells. Thus, prostaglandins enhanced mannose receptor expression in adherent but not fully differentiated macrophage precursors. This effect is specific for PGE and is mimicked by dibutyrl cyclic AMP. These results indicate that prostaglandins accelerate MMR expression and hence the differentiation of macrophage precursor cells. Cells resident in the bone marrow secrete abundant prostaglandins, suggesting that a paracrine mechanism may exist to regulate MMR expression and function.     

The porcine 2A10 antigen is homologous to human CD163 and related to macrophage differentiation

The mAb 2A10 recognizes a 120-kDa protein with sequence homology to the human CD163 and whose expression is restricted to the cells of the porcine monocyte/macrophage lineage. While most of tissue macrophages express high levels of 2A10 Ag, bone marrow cells and a subset of blood monocytes are negative for this marker. The percentage of 2A10+ blood monocytes ranges between 5-50% depending on the donor. The phenotypic analysis indicates that these cells are more similar to mature macrophages than 2A10- monocytes. 2A10+ monocytes express higher levels of swine histocompatibility leukocyte Ag II, CD16, and the adhesion molecules very late Ag-4 (CD49d) and LFA-1 (CD11a) than 2A10- monocytes, while CD14 and SWC1 expression is lower. Both monocyte subsets also differ in their functional capabilities. 2A10+ monocytes induce a greater allogeneic response on T lymphocytes than 2A10- cells. LPS-stimulated 2A10+ and 2A10- monocytes both produce proinflammatory cytokines (TNF-alpha and IL-1alpha), but antiinflammatory IL-10 is only detected on the latter population. When 2A10- monocytes were cultured in medium containing pig serum, they acquired some phenotypic features of 2A10+ cells, expressing the 2A10 Ag. In contrast, when they were cultured in the presence of L929 supernatant as a source of GM-CSF, the 2A10 Ag expression remained low, scarcely increasing over basal levels. 2A10+ cells cultured with pig serum developed features that resemble monocyte-derived dendritic cells. These results indicate that 2A10+ monocytes could constitute a cell population in a more advanced maturation stage than 2A10- circulating monocytes.     

Antagonistic effect of interferon-beta on the interferon-gamma-induced expression of Ia antigen in murine macrophages

The cell surface expression of I region-associated (Ia) antigens by murine and human macrophages has been shown by investigators from a number of laboratories to be induced in a dose-dependent fashion by IFN-gamma, which is free of other lymphokines. The experiments described in this report demonstrate that fibroblast-derived IFN-beta exerts an antagonistic effect on IFN-gamma induced Ia expression in murine macrophages. Simultaneous addition of IFN-beta and IFN-gamma to peritoneal exudate macrophages results in decreased Ia expression when compared with macrophages treated with IFN-gamma only. Different sources of highly purified IFN-beta, as well as a recombinant human IFN-alpha (A/D Bgl; shown previously to be as active as IFN-beta in several other murine systems) acted in a similar antagonistic fashion to IFN-gamma-induced Ia induction. The down-regulation of Ia expression by IFN-beta is dose-dependent over a concentration range up to 100 U/ml. Time-course experiments indicated that for IFN-beta to down-regulate IFN-gamma-induced Ia, it had to be present either before stimulation with IFN-gamma or during the first 24 hr of simultaneous stimulation. Further experiments in which a highly specific antibody against IFN-alpha/beta was added to the cultures confirmed the findings of the time-course experiments. Inhibitors of the arachidonic acid pathway failed to reverse the effect of IFN-beta to reduce Ia antigen expression, which suggests that this inhibition is not prostaglandin mediated. Thus, these findings support a role for type I IFN as naturally occurring substances that negatively regulate the expression of class II molecules.     

Interleukin 1 can replace monocytes for the specific human B-cell response to a particulate antigen

It is shown that the anti-trinitrophenyl (TNP) response of human B cells to trinitrophenyl polyacrylamide beads (TNP-PAA) is monocyte dependent. This response is abolished by extensive adherent cell depletion and restored by the addition of monocytes. The optimal response is obtained with 3% monocytes, higher numbers being suppressive. Supernatants from muramyl dipeptide (MDP)-activated monocytes can restore the response of monocyte-depleted preparations even when cells are cultured at suboptimal concentration. A partially purified preparation of interleukin (IL-1) has a comparable restorative ability. The following arguments suggest that monocytes do not function as antigen-presenting cells for this particulate antigen: (i) anti-genpulsed monocytes induce neither an anti-TNP response nor a specific T-cell proliferative response; (ii) allogeneic monocytes function as well as autologous monocytes to restore the response of nonadherent cells; (iii) HLA-DR-negative cells from the human leukemia cell line K562 can replace monocytes for this response. Monocyte supernatants do not replace T cells for the response of B-enriched lymphocytes, showing that T cells are directly involved in B-cell activation.     

The handling of Listeria monocytogenes by macrophages: the search for an immunogenic molecule in antigen presentation

The activation of T lymphocytes for immunity to the intracellular pathogen Listeria monocytogenes requires that Ia-positive macrophages ingest the bacteria. The subsequent handling of Listeria by macrophages was examined in this report and related to antigen presentation to T cells. Macrophages pulsed with radiolabeled Listeria, besides releasing acid-soluble radioactivity--an indication of extensive catabolism of the Listeria-derived proteins--were also found to release acid-insoluble peptides. The rate of release of the peptides was not markedly affected by treatment with chloroquine, ammonia, or monensin and was independent of the state of activation and the level of Ia expression of the macrophage. The peptides were not associated with fragments of membranes and were represented by several molecular species. Listeria-derived peptides were also found associated with the macrophage plasma membrane. The membrane-associated peptides behaved like integral membrane proteins and could be released by proteases or detergents. Their expression was independent of the dose of Listeria and the level of Ia expression of the macrophage, and their presence could not be inhibited by protease inhibitors or chloroquine. The Listeria peptides released by the macrophages were very weakly immunogenic in a T cell proliferation assay. Purified plasma membranes from Listeria-pulsed macrophages, which contained membrane-associated Listeria peptides, were not immunogenic by themselves but could be reprocessed by additional macrophages to subsequently stimulate T cells. Trypsin treatment of Listeria-pulsed macrophages did not cause a significant reduction in their ability to stimulate T cells. No association was found between Ia molecules and either the membrane-associated or the released peptides with the use of several technical approaches. Hence, after internalization of Listeria, potentially immunogenic material can be found at the cell surface as well as in the culture fluid. The release of soluble peptides is a clear indication that proteins can be recycled after their internalization in vesicles.     

Monoclonal antibody-mediated inhibition of interferon-gamma-induced macrophage antiviral resistance and surface antigen expression

A monoclonal antibody (MAb) with specificity for murine interferon-gamma (IFN-gamma) was used as a probe for studying the effect of recombinant IFN-gamma (rIFN-gamma) on antiviral activity, Fc receptor expression, and Ia antigen induction in macrophages. Cultures of C3H/HeJ peritoneal exudate macrophages were used to allow direct comparison of all three functions in the same target cell system. Our data provide two major findings: the efficacy of the MAb is very different depending on whether murine fibroblasts or macrophages are used as the target cell in the antiviral assay, i.e., greater than 20 to 100 times more MAb was required to block antiviral activity in macrophage cultures; and 10 to 50 times more MAb was required to inhibit Fc receptor vs Ia antigen expression in response to rIFN-gamma. These latter findings confirm and extend previous observations, which indicate that the induction pathways of two important differentiation markers by IFN-gamma may be dissociable.     

Inhibition of macrophage-mediated antigen presentation by hemolysin-producing Listeria monocytogenes

T lymphocytes and macrophages from Listeria-infected mice were used to evaluate the processing and presentation of live Listeria monocytogenes in vitro. Antigen presentation to T cells was quantitated by interleukin-2 production. In contrast to inert antigens such as heat-killed Listeria, live bacteria were processed and presented poorly. To evaluate the role of hemolysin (Hly), we used isogenic pairs of Hly+ and Hly- Listeria as antigens. In contrast to live Hly- bacteria, which were presented as well as heat-killed Listeria, live Hly+ bacteria were presented poorly. Hly+ bacteria also inhibited the presentation of heat-killed Listeria. This effect was apparent with as few as 10 bacteria/macrophage and was not due to loss of macrophage viability or decreased Ia expression after exposure to the live bacteria. With respect to murine listeriosis, the LD50 values for the Hly- strains were at least 1000 times higher than those for the Hly+ strains. These results suggest that the ability of Hly+ bacteria to inhibit antigen processing and presentation may be an important determining factor in Listeria infection and immunity.     

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.     

Regulation of macrophage populations. V. Evaluation of the control of macrophage Ia expression in vitro

In response to a lymphokine (LK) produced by activated T cells, macrophages can be induced to express Ia in vitro. This appears to be a complex process comprised of a number of discernible events. Peritoneal macrophages elicited by different means, and unstimulated macrophage and monocyte populations, each had a distinct kinetic profile of Ia induction. This response was characterized most noticeably by a latent period before actual Ia expression. The latent period varied from 3 to 7 days, depending on the target population, and was correlated with the state of activation of the macrophage as reflected by 5' nucleotidase activity. In spite of the protracted time course for Ia expression, all macrophage populations could be "triggered" (committed to a subsequent program of Ia expression) by exposure to the LK for as little as 2 hr. To be triggered, however, macrophages first had to go through a period of culture as adherent cells. Both the spontaneous loss and LK-dependent acquisition of Ia correlated with the functional capacity of these macrophages as antigen-presenting cells, indicating that these events are functionally significant.