Human macrophage-activating factors for cytotoxicity. I. Establishment of a human T-cell hybridoma that produces macrophage-activating factors for cytotoxicity

Human T cell hybridoma, H3-E9-6, that produces macrophage activating factors for cytotoxicity (MAF-C) was prepared by somatic fusion of phytohemagglutinin-activated peripheral blood lymphocytes with emetine/actinomycin D-treated cloned human acute lymphocytic leukemia cells (CEM 11). The activities of the following were assayed: (1) macrophage-activating factor for cytotoxicity of monocytes (MAF-C 1 day), (2) macrophage-activating factor for cytotoxicity of monocyte-derived macrophages (MAF-C 6 day), (3) macrophage-activating factor for cytotoxicity of murine macrophages (MAF-Cm), (4) macrophage-activating factor for glucose consumption (MAF-G), (5) macrophage-activating factor for O2- formation (MAF-O). The culture supernatant of H3-E9-6 showed MAF-C 1 day-MAF-C 6 day, MAF-Cm, and MAF-G activities. The MAF-Cm activity was considerably enhanced by the addition of murine recombinant interferon gamma (rIFN-gamma). The MAF-C 1 day activity in the H3-E9-6 sup was not decreased by heat treatment (56 C, 30 min), by pH 2 treatment or by the addition of monoclonal anti-human IFN-gamma antibody or polymyxin B. These data suggest that MAF-C in H3-E9-6 sup is distinct from human IFN-gamma or lipopolysaccharide (LPS).     

Induction by immunomodulatory agents of a macrophage antigen recognized by monoclonal antibody 158.2 and correlation with macrophage function

MA158.2, a rat monoclonal antibody with binding specificity for cells of the monocyte-macrophage lineage, reacts with an antigen (158.2) whose expression is enhanced on mononuclear cells activated to the tumoricidal phenotype by treatment with lymphokine supernatant containing macrophage activating factor (MAF). The functional relevance of enhanced expression of this antigen has been examined in mouse peritoneal macrophages treated with a variety of immunomodulatory agents and assayed for augmented macrophage-mediated defense reactions, including O-2 production, microbicidal, and tumoricidal activity. An interferon-gamma (IFN-gamma) preparation produced by recombinant DNA technology induced a dose-dependent increase in expression of the 158.2 antigen in inflammatory macrophages which was accompanied by acquisition of microbicidal activity against Listeria monocytogenes. However, these cells did not express tumoricidal activity and induction of this property required concomitant exposure to lipopolysaccharide (LPS). Similar results were obtained using macrophages elicited with pyran copolymer. Exposure to LPS alone induced enhanced expression of antigen 158.2 but did not elicit microbicidal activity. Macrophages challenged with IFN-alpha, IFN-beta, MDP, and bestatin did not exhibit increased 158.2 and also failed to acquire tumoricidal activity when treated concomitantly with LPS. Collectively, these data indicate that the MA 158.2 antibody recognizes an antigen expressed by macrophage populations displaying the so-called primed phenotype in which microbicidal activity is expressed but in which induction of tumoricidal activity requires the addition of a second signal such as LPS.     

Potentiation of lymphokine-induced macrophage activation by tumor necrosis factor-alpha

In this study, we examined the possible role of TNF-alpha and lymphotoxin (TNF-beta) as cofactors of macrophage activation. The results demonstrate that both TNF were capable of enhancing the cytostatic and cytolytic activity of murine peritoneal macrophages against Eb lymphoma cells. The potentiation of tumor cytotoxicity became apparent when macrophages from DBA/2 mice were suboptimally activated by either a T cell clone-derived macrophage-activating factor or by IFN-gamma plus LPS. Neither TNF-alpha nor TNF-beta could induce tumor cytotoxicity in IFN-gamma-primed macrophages, indicating that TNF cannot replace LPS as a triggering signal of activation. In LPS-resistant C3H/HeJ macrophages, which were unresponsive to IFN-gamma plus LPS, a supplementation with TNF fully restored activation to tumor cytotoxicity. Furthermore, TNF-alpha potentiated a variety of other functions in low-level activated macrophages such as a lactate production and release of cytotoxic factors. At the same time, TNF-alpha produced a further down-regulation of pinocytosis, tumor cell binding and RNA synthesis observed in activated macrophages. These data demonstrate new activities for both TNF-alpha and TNF-beta as helper factors that facilitate macrophage activation. In particular, the macrophage product TNF-alpha may serve as an autocrine signal to potentiate those macrophage functions that were insufficiently activated by lymphokines.     

A novel rat monoclonal antibody directed against a population of activated mouse peritoneal macrophages

A hybridoma clone secreting rat monoclonal antibody (MAB) designated as 3F3.5F and which reacted with a population of activated tumoricidal mouse peritoneal macrophage (M phi) was produced by the fusion of mouse myeloma cells with rat spleen cells immunized against adherent BCG-activated mouse peritoneal exudate cells (adherent BCG-PEC). The antibody was cytotoxic and of the rat IgM class. The specific reactivity of the antibody with mouse primary cells and cell lines was examined by complement-dependent cytotoxicity and indirect immunofluorescence flow cytometry analysis. The antibody was found to bind to about 40% of the adherent BCG-PEC activated in vivo and elicited peritoneal macrophages activated in vitro by lymphokine and lipopolysaccharide (LPS), to about 35% of polymorphonuclear neutrophils (PMN) 15 hr after intraperitoneal injection of BCG, to about 30% of bone marrow cells from BCG-infected mice, to about 10% of P815 mastocytoma cells and to thioglycollate-induced PEC to some degree. It did not bind to other cells tested including BCG-induced peritoneal lymphocytes, non-tumoricidal PEC, thymocytes, spleen cells, resting bone marrow cells from normal mice, lymphomas, myelomas, fibroblasts, or macrophage-cell lines. Pretreatment of adherent BCG-PEC with MAB 3F3.5F and rabbit complement caused a considerable decrease in tumor cytotoxicity toward P815 cells, but the same pretreatment of non-adherent BCG-PEC had no inhibitory effect on natural killer activity for YAC-1 cells.     

Immunological Properties of TtT/M-87 Cell Line Established from Murine Pituitary Tumor-Associated Macrophages

TtT/M-87 cell is a macrophage cell line established from thyrotropic pituitary tumor tissues in mouse. In this paper, we report the immunological properties of M-87 cells as a model of tumor-associated macrophage. Contrasting with resident peritoneal macrophages, M-87 cells constitutively secreted small but significant amounts of TNF-α and IL-1α, which were detectable in both biological assays (cytotoxic activity for L929 and co-mitogenic activity for Con A-induced T cell proliferation, respectively) and ELISA, and produced larger amounts of these cytokines upon stimulation with LPS. They expressed MHC class II molecules on their cell surface without stimulation by IFN-γ. The accessory or antigen-presenting cell activity in antibody-producing response of spleen lymphocytes to sheep red blood cells was shown to be much higher in M-87 cells than normal peritoneal macrophages. In addition, when normal spleen lymphocytes were cultured with allogeneic tumor cells, such as EL-4 and S-180, in the presence of M-87 cells, lymphocytes reactive to stimulator cells were activated to manifest inhibitory effect on the tumor cell growth and also to manifest specific cytotoxic effect on the allogeneic tumor cells. These results show that M-87 cells derived from tumor-associated tissue are activated macrophages and that they are inhibitory to tumor cell growth and augmentative in the induction of T-cell-mediated immune responses.     

A human macrophage hybridoma producing a cytotoxic factor distinct from TNF,LT, and IL-1

Summary A stable human macrophage hybridoma was established by somatic cell fusion between human peripheral blood monocyte-derived macrophages and an 8-azaguanine resistant clone of a human histiocytic lymphoma cell line U-937 (clone U-937-F9). The hybrid cell line (F9P) exhibited typical macrophage-like morphology and had 30 more chromosomes than U-937-F9 cells. Its macrophage characteristics were confirmed by the manifestation of intracellular nonspecific esterase, the detection of Mo-2 and LEU-M3 antigens on the cell surface, and the demonstration of phagocytic activity. Furthermore, when stimulated with lipopolysaccharide (LPS), this cell line could secrete a considerable amount of a cytotoxic factor (CTF). Distinct from the hybrid cell line, the parental U-937-F9 cells expressed neither Mo-2 nor LEU-M3 antigens on the cell surface, did not show phagocytic activity, and their culture supernatants did not show cytotoxic activity even after LPS stimulation. The activity of CTF in the culture supernatant of the LPS-stimulated hybrid cells could not be neutralized with anti-tumor necrosis factor, anti-interleukin-1, or anti-lymphotoxin antibodies. The CTF had a relative molecular mass of 45–60×10³ daltons as determined by gel filtration on a column of Superose 12, and an isoelectric point of 5.1. The cytotoxic activity was also induced when the hybrid cells were stimulated with the concentrated supernatants of a human T-cell hybridoma containing macrophage activating factor for cytotoxicity or with LP3 tumor cells which were used as target cells.     

Cytotoxic activity and production of toxic nitrogen oxides by macrophages treated with IFN-gamma and monoclonal antibodies against the 73-kDa lipopolysaccharide receptor.

The hamster IgM mAb 5D3 is specific for an 73-kDa LPS receptor on murine leukocytes. This mAb inhibits binding of radiolabeled LPS to splenocytes and acts as an agonist for induction of LPS-mediated changes in macrophage function. Resident peritoneal macrophages treated with IFN-gamma and mAb 5D3 developed potent cytotoxic activity against tumor cells. Cells treated with IFN-gamma or mAb 5D3 alone were inactive. Macrophage cytotoxic activity induced by IFN-gamma and mAb 5D3 was inhibited by NGMMLA and coincident with high levels of NO2-released into culture fluids. These data show that mAb 5D3 serves as an effective trigger signal for induction of cytotoxic activity with IFN-gamma-primed macrophages. Indeed, mAb 5D3 exactly mimicked the effects of LPS in these same systems. Unlike LPS, effects of mAb 5D3 on induction of macrophage cytotoxic activity and production of nitrogen oxides was abrogated after boiling, and not affected by addition of polymyxin B. The effects of LPS and mAb 5D3 as a trigger signal for IFN-gamma-primed macrophages were associated with production of TNF activity in culture fluids and inhibited by mAb against rTNF-alpha. Expression of class II MHC on macrophages induced by IFN-gamma treatment was suppressed by both LPS and mAb 5D3. These suppressive effects of LPS and mAb 5D3 were not affected by NGMMLA or mAb against rTNF-alpha. Finally, macrophages treated with LPS or mAb 5D3 before exposure to IFN-gamma and LPS or mAb 5D3 did not develop cytotoxic activity or high levels of NO2- in the culture fluids. These same cells developed both effector activities after addition of rTNF-alpha. These results in toto identify the 73-kDa protein as a receptor that mediates LPS-induced changes in macrophage effector function. The mAb 5D3 serves as a specific and defined reagent agonist for analysis of LPS receptor-linked change.     

Macrophage-activating factor for cytotoxicity produced by a human T-cell hybridoma

Human MAF-C (macrophage-activation factor for cytotoxicity)-producing hybridoma H2-E3-5 was prepared by somatic cell fusion of PHA-activated peripheral blood lymphocytes with emetine/actinomycin D-treated cloned human acute lymphatic leukemia cells (CEM). The following activities were assayed: (1) macrophage-migration-inhibitory factor (MIF), (2) macrophage-activation factor for glucose consumption (MAF-G), (3) macrophage-activation factor for O2-formation (MAF-O), and (4) macrophage-activation factor for cytotoxicity (MAF-C). After anion-exchange chromatography, MAF-C activity could be distinguished from MIF and MAF-O activities. It is shown that MAF-C is not the same as MAF-G from the culture supernatants of CEM 11, a parent cell line of H2-E3-5. Furthermore, MAF-C from H2-E3-5 culture supernatants activated differentiated macrophages but not monocytes.     

Human Macrophage-Activating Factors for Cytotoxicity

Two different factors (MAF-C I and MAF-C II) were obtained by anion exchange chromatography of the culture supernatant of a human T-cell hybridoma, H3-E9–6, which produces macrophage-activating factors for cytotoxicity (MAF-C). These 2 factors induced the cytotoxicity of monocytes synergistically as a priming signal (MAF-C I) and a triggering signal (MAF-C II), respectively. On gel filtration on a column of Superose 12, MAF-C II was eluted mainly at the void volume, whereas MAF-C I was eluted in the fractions corresponding to approximate molecular weights of 30–300 K. On the other hand, gel filtration in the presence of sodium deoxycholate revealed that MAF-C II has an approximate molecular weight of 40,000, but MAF-C I was unstable under these conditions. When the activity for mouse macrophages (MAF-Cm activity) was tested, the MAF-C II fraction showed high MAF-Cm activity in the presence of murine recombinant interferon gamma (rIFN-γ), but the MAF-C I fraction did not show MAF-Cm activity even in the presence of lipopolysaccharide (LPS). These results suggest that MAF-C I (priming lymphokine) has species specificity but MAF-C II (triggering lymphokine) does not.     

Induction of nitrite/nitrate synthesis in murine macrophages by BCG infection, lymphokines, or interferon-gamma

Macrophage synthesis of nitrite and nitrate after activation by BCG infection or by treatment in vitro with both T cell-derived (lymphokines (LK) or recombinant murine interferon-gamma (IFN-gamma] and bacterial (lipopolysaccharide (LPS) and heat-killed bacillus Calmette-Guerin (hk BCG] agents was studied by using macrophages from C3H/He and C3H/HeJ mice. Spleen and peritoneal macrophages isolated from BCG-infected donors that were producing nitrate continued to synthesize nitrite and nitrate in culture. LPS treatment in vitro (25 or 50 micrograms/ml) additionally increased this nitrite/nitrate synthesis. Thioglycolate-elicited macrophages from non-infected C3H/HeJ mice treated with LK also produced nitrite/nitrate, and concurrent LPS (0.1 to 50 micrograms/ml) treatment resulted in enhanced synthesis. Recombinant IFN-gamma also stimulated nitrite/nitrate synthesis by C3H/He and CeH/HeJ macrophages as did LPS (C3H/He only) and hk BCG. When given concurrently with either LPS or hk BCG, IFN-gamma enhanced C3H/He and C3H/HeJ macrophage nitrite/nitrate synthesis over that produced by macrophages treated with either LPS or hk BCG alone. Macrophages activated in vitro exhibited a 4 to 12 hr lag time before engaging in nitrite/nitrate synthesis, which then proceeded for 36 to 42 hr at linear rates. Daily medium renewal did not alter the synthesis kinetics but increased the total amount of nitrite/nitrate produced. Nitrate and nitrite were stable under the conditions of culture and when added did not influence additional macrophage synthesis. Taken together, these results indicate that T cell lymphokines and IFN-gamma are powerful modulators of macrophage nitrite/nitrate synthesis during BCG infection and in vitro, and nitrite/nitrate synthesis appears to be common property of both primed and fully activated macrophage populations.     

Prostaglandin E2 does not inhibit tumoricidal activity of mouse macrophages against adherent tumor cells

We determined whether endogenously produced PGE2 can down-regulate the tumoricidal properties of macrophages by a negative feedback mechanism. Peritoneal exudate macrophages or resident peritoneal macrophages of mice were incubated in medium (control) or in medium containing IFN-gamma and LPS. Activated macrophages were highly tumoricidal against syngeneic melanoma cells and secreted high levels of PGE2. Treatment with indomethacin or diclofenac sodium (voltaren) completely inhibited the production and secretion of PGE2 but not the tumoricidal activity of activated macrophages measured either immediately after activation or 1 to 3 days thereafter. Finally, the addition of exogenous PGE2 did not alter the ability of peritoneal exudate macrophages to respond to IFN-gamma or of LPS to produce high levels of tumor cell lysis. Collectively, these results show that PGE2 produced by activated macrophages is not a down-regulator of their tumoricidal activity against adherent tumor cells.     

Lymphokine maintains macrophage activation for tumor cell killing by interfering with the negative regulatory effect of prostaglandin E2

Mouse resident peritoneal macrophages activated with bacterial lipopolysaccharide (LPS) rapidly lost their ability to kill tumor cells in vitro. Such loss of killing has previously been attributed to the effects of prostaglandin E (PGE) produced by the LPS-stimulated macrophages. Macrophages exposed in the current study to both LPS and partially purified lymphokine did not lose cytolytic activity, in spite of the fact that these cells produced undiminished amounts of PGE, compared to controls. Cytolytic activity was shown to be retained under these conditions because lymphokine decreased the sensitivity of activated macrophages to the negative regulatory effects of PGE. The mechanism responsible for the lymphokine effect is not known; however, generalized inhibition of macrophage responsiveness to the hormone does not appear to be involved because lymphokine did not reduce the cyclic AMP response of macrophages, measured on a whole cell basis, after they were exposed to PGE.     

Effects of bacterial lipopolysaccharide on protein synthesis in murine peritoneal macrophages: relationship to activation for macrophage tumoricidal function

Early biochemical events in the response of murine peritoneal macrophages to bacterial lipopolysaccharide (LPS) have been examined (i.e., 0-4 hr after initiation of treatment). At concentrations of 10 ng/ml or less, LPS stimulated the new or enhanced synthesis of a series of at least six polypeptides of 85, 80, 75, 65, 57, and 38 kD. This effect was dependent upon the lipid A moiety of LPS as lipid A itself could induce the changes and the effect of LPS could be blocked by inclusion of polymixin B sulfate in the culture medium. The effect was specific for LPS in that other endotoxin-free agents known to alter macrophage physiology could not produce the same changes. The time course of LPS stimulation of macrophage protein synthesis was remarkable in that the synthesis of all six proteins was transient even in the continued presence of LPS, being first detected approximately 1 hr after exposure and no longer apparent by 8-10 hr after treatment was initiated. Furthermore, both pulse-chase and cumulative radiolabeling studies indicated that at least two of the proteins (85 and 38 kD) were short-lived and did not accumulate in LPS-treated cells, suggesting the possibility that they participate in a regulatory rather than a functional role. Macrophage tumoricidal activation involves cooperation in response to two independent signals; interferon gamma and LPS. Pretreatment of macrophages with interferon gamma increased the sensitivity of macrophages to LPS-stimulated protein synthesis by one to two orders of magnitude documenting such cooperativity in molecular terms. The LPS-induced stimulation of specific protein synthesis could be reproduced by treatment of macrophages with heat killed Listeria monocytogenes, a gram-positive, endotoxin-negative bacterial stain which has been shown to substitute effectively for LPS in macrophage tumoricidal activation. Furthermore, reversible inhibition (i.e., treatment with cycloheximide) of protein synthesis during LPS treatment abrogated the acquisition of tumoricidal function. These results identify an early biochemical response to LPS which may be a necessary component of the intracellular transduction of signals which regulate macrophage functional development.     

Lipopolysaccharide-mediated macrophage activation: the role of calcium in the generation of tumoricidal activity

As we have reported, calcium ionophore A23187 activates macrophages for tumor cell killing, and the activated macrophages produced a soluble cytotoxic factor (M phi-CF) that is similar, if not identical, to tumor necrosis factor. Based on these observations, we have investigated whether calcium is involved in the activation mediated by another potent macrophage activator, namely lipopolysaccharide (LPS). We first showed that A23187 caused uptake of extracellular calcium-45 by macrophage monolayers, whereas LPS did not. Because in this system rapid changes would not have been detected, several other approaches also have been used. We have examined the effect of depleting extracellular calcium by using medium containing no added calcium, supplemented with 1 mM EGTA. In no case did depletion result in decreased M phi-CF production by LPS-treated macrophages. Measurements using the fluorescent intracellular calcium indicator Quin 2 have also been performed. The calcium ionophore ionomycin caused a rapid change in the intracellular Quin 2 signal. LPS, even at a concentration in vast excess of that required to activate the macrophages, caused no change in the signal during a 2-hr period. If the macrophages were loaded with high doses of Quin 2 or another intracellular chelator, TMB-8, M phi-CF production decreased and cytotoxic activity was impaired. These data indicate that one or more of the processes involved in M phi-CF production does require calcium, but that activation mediated by LPS occurs without the influx of extracellular calcium or redistribution of intracellular calcium.     

Tumor target-derived soluble factor synergizes with IFN-gamma and IL-2 to activate macrophages for tumor necrosis factor and nitric oxide production to mediate cytotoxicity of the same target.

Inflammatory mouse peritoneal macrophages were activated by IFN-gamma in synergy with IL-2 or Lipid A to mediate TNF production for autocrine generation of cytotoxic nitric oxide (NO) to kill P815 or L1210 tumor targets. It was determined that for IL-2, but not Lipid A, to effectively trigger activation of IFN-gamma-primed macrophages, the tumor targets must be also present for interaction with effector macrophages to mediate the production of TNF and NO. IFN-gamma- and IL-2-activated macrophages from syngeneic DBA/2 and allogeneic C3H mice had identical MHC-unrestricted requirements for interaction with DBA/2 mouse-derived P815 and L1210 targets to mediate production of TNF and NO for tumor cytotoxicity. To further define the mechanistic requirements for macrophage-tumor target interaction, IFN-gamma- and IL-2-activated macrophages were separated from P815 targets in culture by a semipermeable membrane. Under these conditions, both TNF and NO were produced by the macrophage, which indicated that the requirement for tumor target-macrophage interaction may be due to a soluble factor produced by the target rather than to direct physical contact. This was confirmed by experiments in which 24-h cell-free culture fluids, derived from either P815 or L1210 tumor targets, substituted for the intact tumor cells in the stimulation of TNF mRNA synthesis and secretion with NO generation of TNF mRNA synthesis and secretion with NO generation by IFN-gamma- and IL-2-activated C3H or DBA/2 macrophages. The activity in 24-h culture fluids derived from P815 and L1210 tumor targets was tentatively designated as tumor-derived recognition factor(s) (TDRF) since it was produced constitutively by the tumor targets and synergized with IFN-gamma and IL-2 to induce macrophage production of TNF and NO for death of the same targets. A variety of nontransformed human and mouse fibroblasts, mouse spleen lymphocytes, and two adherent mouse fibrosarcomas did not produce detectable TDRF activity, whereas two mouse T lymphomas, EL4 and EL4.IL-2, produced TDRF activity similar to L1210 mouse leukemia and P815 mastocytoma. The C3H/MCA, a TDRF-nonproducing mouse fibrosarcoma, was susceptible to cytotoxicity mediated by macrophages activated by IFN-gamma and Lipid A, but not by IL-2 triggering. Exogenous TDRF derived from L1210 targets reconstituted the cytotoxic activity for C3H/MCA MCA targets mediated by IFN-gamma- and IL-2-activated macrophages accompanied by the production of TNF and cytotoxic NO.(ABSTRACT TRUNCATED AT 400 WORDS)     

Toxoplasma gondii partially inhibits nitric oxide production of activated murine macrophages

Activated macrophages produce nitric oxide (NO) and as such are able to control the multiplication of Toxoplasma gondii. Until now, no reports have described a possible modulation of NO production of macrophages after T. gondii infection. To investigate this possibility, murine blood monocyte-derived and peritoneal macrophages were activated in vitro with interferon-gamma and lipopolysaccharide and infected with T. gondii and Trypanosoma cruzi, and NO production was evaluated. NO was produced by monocyte-derived macrophages only if cultured in the presence of macrophage-colony-stimulating factor. Monocyte-derived or peritoneal macrophages infected with T. gondii presented a significant reduction in NO production. NO production inhibition was not detected after T. cruzi infection. Macrophages infected with higher T. gondii/macrophage ratios presented lower NO production. Furthermore, only viable T. gondii could cause partial inhibition of NO production. In macrophages activated 24 h before the interaction, partial inhibition was detected after 3 h of infection and continued for 48 h. In macrophages activated immediately after the interaction, partial inhibition was not detected at 12 h, but was observed at 24 h. T. gondii-infected macrophages present lower inducible nitric oxide synthase expression as assayed by immunofluorescence. T. gondii did not develop in monocyte-derived macrophages producing NO, but were not totally eliminated. These results demonstrate that T. gondii infection partially inhibits NO production by murine macrophages, suggesting that a deactivating macrophage mechanism may be used for better survival into phagocytic cells.     

Selective macrophage suppression during sepsis

Polymicrobial sepsis induces suppression of macrophage function as determined by a reduction of pro-inflammatory cytokine production upon re-exposure to lipopolysaccharide (LPS) in vitro. We examined whether macrophages were refractory to only LPS challenge or if they were immunoparalyzed and unable to respond to other stimuli such as lipoteichoic acid (LTA) or zymosan (ZYM). This study evaluated the capacity of peritoneal macrophages to produce pro-inflammatory and anti-inflammatory cytokines as well as chemokines following mild or severe sepsis induced by cecal ligation and puncture (CLP). Peritoneal macrophages were isolated 29 h after CLP and challenged with different stimuli. LPS was a more potent stimulus for cytokine induction than LTA or ZYM in both mild and severe sepsis. In mild sepsis, the macrophage cytokine response to LPS was selective and less refractory than in severe sepsis. While production of IL-6 and KC was reduced, secretion of TNF-alpha and MIP-1alpha was enhanced in those cells isolated from mice with mild sepsis. Production of IL-10 and the IL-1 receptor antagonist , MIP-2, and MCP-1 in response to LPS stimulation was equivalent to the amount produced by naive macrophages. Our results indicate that macrophages are not immunoparalyzed during sepsis and may still be induced to secrete some inflammatory mediators.     

Inducible expression of murine IP-10 mRNA varies with the state of macrophage inflammatory activity

We have examined the expression of inducible inflammatory genes in murine macrophages from different tissues and at different stages of inflammatory activity. Although i.v. administration of IFN-gamma (10,000 U/mouse) strongly induced expression of IP-10 mRNA in the adherent cell population of the spleen, thioglycollate-elicited peritoneal macrophages were essentially unresponsive at the same dose. In contrast, D3 mRNA was expressed in both cell populations. This differential sensitivity of IP-10 mRNA expression was not restricted to stimulation by IFN-gamma as it was also seen when LPS (25 micrograms/mouse) was administered i.v. Expression of JE and KC mRNA, which encode cytokines related to IP-10, were also differentially expressed in elicited peritoneal macrophages from mice injected with LPS. Differential sensitivity was at least partially related to the state of macrophage activation because IP-10 mRNA was highly inducible in resident but not thioglycollate-elicited peritoneal macrophages. The eliciting agent was also an important determinant because proteose-peptone-elicited peritoneal macrophages were nearly as sensitive as splenic macrophages with respect to expression of IP-10 mRNA. IFN-gamma treatment induced IP-10 and D3 mRNA rapidly and transiently with the same time course in the spleen. IP-10 mRNA was not induced by IFN-gamma in TG-elicited macrophages regardless of the time after treatment. This differential expression of IP-10 was a consequence of different concentration requirements for IFN-gamma in the two cell types; thioglycollate-elicited macrophages required five- to 10-fold more IFN-gamma than did resident cells to achieve comparable IP-10 mRNA levels whether the agent was provided in vitro or in vivo. Thus variable sensitivity for induction of IP-10 mRNA was a characteristic of the macrophage itself and was not mediated by other cellular or molecular elements present in the inflammatory peritoneal cavity. The reduced sensitivity to IFN-gamma or LPS for expression of IP-10, JE, and KC mRNA as compared with TNF-alpha or D3 mRNA suggests that this distinct pattern of regulation may be restricted to members of these two related cytokine gene families that exhibit cell-type specific chemoattractant activity.     

Interferon-gamma synergizes with tumor necrosis factor and with interleukin 1 and requires the presence of both monokines to induce antitumor cytotoxic activity in macrophages

Small concentrations of recombinant murine interferon-gamma (MuIFN-gamma), recombinant human interleukin 1 (HuIL-1), and recombinant murine tumor necrosis factor (MuTNF), added separately to cultures of thioglycolate-elicited peritoneal macrophages, produced no cytotoxic activity against L5178Y cells, a tumor cell line which is resistant to the direct toxic effects of these cytokines, either alone or in combination. However, small concentrations of MuIFN-gamma when combined with small concentrations of either HuIL-1 or MuTNF activated these macrophages to produce cytotoxic effects against L5178Y cells; small concentrations of HuIL-1 and MuTNF in combination had no macrophage activating activity. Specific antibody to MuTNF blocked the macrophage-activating synergistic effects of MuIFN-gamma + HuIL-1, and specific antibody to HuIL-1 blocked the macrophage-activating activity of MuIFN-gamma + MuTNF, indicating that MuTNF was induced in macrophage cultures treated with MuIFN-gamma + HuIL-1, and that murine IL-1 was induced in macrophage cultures treated with MuIFN-gamma + MuTNF. These results indicate that all three cytokines are required for induction of antitumor cytotoxic activation of macrophages. Experiments with a concentration of MuIFN-gamma which alone could activate macrophages revealed that both MuTNF and murine IL-1 were required for this activation. The demonstration that small concentrations of these three cytokines can act synergistically, but not separately, to activate macrophages indicates the importance of cytokine combinations in immunoregulation and in anti-tumor cell-mediated immune responses.     

The response of testicular leukocytes to lipopolysaccharide-induced inflammation: further evidence for heterogeneity of the testicular macrophage population

The majority of macrophages in the rat testis can be identified by the tissue-resident macrophage marker ED2. A smaller population of intratesticular macrophages do not express the ED2 antigen but are positive for the monocyte/macrophage marker ED1. Treatment of adult rats with the inflammatory stimulus lipopolysaccharide (LPS) had no effect on the number of testicular resident (ED2(+)) macrophages but caused a transient increase in ED1(+)ED2(-) monocyte-like macrophages (an average three-fold increase 12 h later). In both control and LPS-treated rat testes, a majority of macrophages that expressed ED1 and all Leydig cells were immuno-positive for the inducible isoform of nitric oxide synthase (iNOS). However, less than 6% of ED2(+) macrophages showed any iNOS expression, even after LPS treatment. This deficiency was confirmed by the finding that isolated ED2(+) testicular macrophages (>98% pure) stimulated with LPS did not produce NO in vitro. In contrast, resident macrophages from the peritoneum showed the expected NO response, and purified Leydig cells produced significant NO regardless of the presence or absence of LPS. Collectively, these data indicate the presence of at least two macrophage subsets in the adult rat testis: (1) the ED2(+) resident macrophages, which do not alter following LPS-treatment and mostly do not express iNOS or produce NO in response to an inflammatory stimulus, and (2) the ED1(+)ED2(-) monocyte-like macrophages, which increase in number after LPS-treatment and express iNOS even in the absence of exogenous inflammatory stimulation. It is highly probable that these different subsets have different functional roles within the testis.