Deactivation of the respiratory burst in activated macrophages: evidence for alteration of signal transduction

Enhanced function of the respiratory burst, measured as stimulated release of superoxide anion (O2-) or hydrogen peroxide, characterizes activated macrophages. Activated macrophages undergo a decline in their capacity to release O2- (a deactivation) when placed in culture for 3 days. To better understand the molecular basis for the enhanced respiratory burst of activated macrophages, we explored the mechanisms underlying deactivation of activated mouse peritoneal macrophages. Deactivation was observed when the assay was performed in a physiologic Na+ buffer, and by day 3 of culture, release of O2- from activated macrophages stimulated with phorbol myristate acetate (PMA) was almost identical to that in resident (nonactivated) macrophages. In contrast, when the assay was performed in a buffer in which Na+ was replaced by K+, release of O2- from activated macrophages on day 3 was equal to or greater than that on day 0, suggesting that the enzyme responsible for the respiratory burst was not altered during culture. The number and affinity of PMA receptors were not changed during culture and were not affected by high external K+. Continuous assay of O2- release by coverslip-adherent macrophages in a cuvette indicated that the lag time between addition of stimulus and release of O2- was reduced, and the initial rate of O2- release was enhanced in K+ buffer. The potency of monovalent cations to support O2- release was K+ greater than Rb+ greater than choline+ greater than Cs+ = Na+ greater than Li+, suggesting that characteristics such as ionic radius or molecular size influence this effect, and the effect is not due simply to absence of Na+. Extracellular Ca2+ or Mg2+ was required for the maximal effect of high external K+, and enhancement by high K+ and divalent cations increased progressively during culture. These findings suggest that deactivation is caused primarily by changes in signal transduction from PMA receptors to the respiratory burst enzyme, rather than by changes in these receptors or the enzyme itself, and that signal transduction can differ in different macrophage populations.     

Phorbol ester-stimulated superoxide production by murine bone marrow-derived macrophages requires preexposure to cytokines

Murine resident peritoneal macrophages (RPM) generate superoxide (O2-) in response to stimulation with PMA or zymosan. Murine bone marrow-derived macrophages (BMM) generate O2- in response to zymosan but not PMA. However, the ability to generate O2- in response to PMA could be induced in BMM by pre-exposing the cells to certain cytokines, including granulocyte-macrophage CSF (GM-CSF), tumor necrosis factor-alpha (TNF-alpha), IFN-gamma, and, to a lesser extent, IL-1 alpha. Bacterial LPS also induced the ability to respond to PMA. These same agents were also shown to prime RPM for enhanced PMA-induced respiratory burst. In contrast to GM-CSF, CSF-1 did not enhance the ability of BMM or RPM to generate O2- in response to PMA. Pretreatment with GM-CSF or TNF-alpha did not significantly affect the zymosan-induced release of O2- by BMM. These results suggest that unprimed BMM have a deficiency in the PMA-dependent signaling pathway that is corrected by exposure to selected cytokines. The results also raise the possibility that the basal ability of tissue macrophages to generate a respiratory burst in response to PMA may be a reflection of in vivo exposure to cytokines.     

Comparison of wheat germ agglutinin- and phorbol myristate acetate-mediated triggering for macrophage H2O2 release: susceptibilities to various macrophage inhibitors

Murine peritoneal macrophages (M phi S) elicited by a single injection of zymosan A showed a higher responsiveness to the wheat germ agglutinin (WGA)-mediated triggering for H2O2 release than M phi S activated by double injections of the agent. On the contrary, the response to phorbol myristate acetate(PMA)-mediated triggering was higher in the latter M phi S than in the case of the former M phi S. Furthermore, PMA-triggered M phi H2O2 release was found to be inhibited by sarcoma 180 tumor cell-derived proteinaceous factor in a much more marked fashion than the WGA-triggered H2O2 release. These results indicate some significant differences between the cellular mechanisms of the WGA- and PMA-triggering for M phi oxidative burst. On the other hand, microfilament-inhibitors (cytochalasins B and E) and serine protease-inhibitors (tosyl-L-lysine-chloromethyl ketone and tosylamido-2-phenylethyl-chloromethyl ketone), but not microtubule-disrupting agents (colchicine, vinblastine, and vincristine), suppressed both the WGA- and PMA-triggerings for M phi H2O2 release to a similar degree, thereby indicating that the WGA- and PMA-triggerings for M phi oxidative burst have a common process which is dependent on microfilament and serine protease functions. In relation to this, the WGA- and PMA-triggerings for M phi spreading were also depressed by microfilament- and serine protease-inhibitors but not by microtubule-inhibitors, indicating a participation of common membrane functions in the signal transduction in cases of M phi oxidative burst, and cell spreading induced by the WGA- as well as PMA-triggering.     

Hyperoxia alters effect of calcium on rat alveolar macrophage superoxide production

The effect of hyperoxia on the Ca2+ dependence of stimulated superoxide anion radical (O2-.) production (the respiratory burst) of rat alveolar macrophages was investigated. Enhancement of the concanavalin A (con A)-stimulated respiratory burst by extracellular Ca2+ was suppressed by O2 exposure. Similarly, the inhibitory effect of verapamil on the con A-stimulated respiratory burst was reduced by O2 exposure. O2 exposure also inhibited con A stimulation that was independent of Ca2+ entry. Exposure to O2 also caused a decline in O2-. production stimulated by either A23187 or phorbol myristate acetate (PMA). With A23187 stimulation, extracellular Ca2+ was essential for either air-exposed (control) or O2-exposed cells. With PMA, stimulation was independent of extracellular Ca2+ for either air or O2-exposed macrophages and verapamil did not inhibit. Free intracellular Ca2+ concentration ([Ca2+]i) was measured in control and O2-exposed alveolar macrophages. Hyperoxic exposure did not alter [Ca2+]i in unstimulated cells. In controls, con A stimulated an immediate increase in [Ca2+]i followed by a rapid decrease and a second rise and fall. The second elevation was suppressed by verapamil or ethyleneglycol-bis (beta-aminoethylether)-N,N'-tetraacetic acid or O2 exposure. The results of both the respiratory burst assays and measurement of con A-stimulated changes in [Ca2+]i suggest that Ca2+ entry involved in stimulus-response coupling is suppressed in cellular O2 toxicity.     

Mycobacterium lepraemurium activates macrophages but fails to trigger release of superoxide anion

Mycobacterium lepraemurium failed to stimulate a normal respiratory burst when presented to mouse peritoneal or bone marrow macrophages. By comparison, Mycobacterium bovis (strain Bacillus Calmette-Guerin) or Saccharomyces cerevisiae, as expected, stimulated macrophages to release a large amount of superoxide anion (O2-). M. lepraemurium did not interfere with the response to yeast when both microbes were added together to macrophages. The low release of O2- induced by M. lepraemurium was not due to failure of M. lepraemurium to activate or prime macrophages, because exposure of macrophages to M. lepraemurium caused the expected enhancement of O2- release when the macrophages were stimulated by PMA. Similarly, macrophages taken from mice infected with M. lepraemurium were activated, as indicated by high PMA-stimulated O2- release. Macrophages primed in vitro by exposure to Escherichia coli LPS for 24 h did show a moderate O2- response when stimulated by M. lepraemurium, but macrophages primed by exposure to IFN-gamma muramyl dipeptide, or M. lepraemurium showed a weak response when subsequently challenged with M. lepraemurium. The priming effect of M. lepraemurium or LPS decreased substantially after macrophages were cultured in fresh medium for 24 h. Heat killing or opsonization of M. lepraemurium caused the M. lepraemurium to stimulate a high amount of O2- release from LPS-primed macrophages, but heat killing or opsonization of M. lepraemurium had no effect on release of O2- from unprimed macrophages. The results suggest that M. lepraemurium is taken into macrophages by a mechanism that bypasses the FcR and other receptors that are capable of triggering the production of O2-.     

Stimulation of macrophage H2O2 release by resident thymocytes: effect of a soluble factor distinct from interferon-gamma

Activated T cells are known to stimulate macrophage oxidative metabolism and antimicrobial activity through release of interferon-gamma (IFN-gamma). In contrast, the role of nonactivated T cells in regulating macrophage effector functions is less well defined. We have previously reported that a low molecular weight soluble factor derived from resident (nonactivated) thymocytes enhances macrophage receptor-mediated phagocytosis. In the present study, we examined the capacity of resident murine thymocytes to stimulate the respiratory burst and microbicidal activity of peritoneal macrophages. Macrophages cultured for 1-2 days with cell-free thymocyte supernatant (TS) released two to three times more H2O2 in response to PMA or opsonized zymosan than did control macrophages. The H2O2-stimulating factor in TS was distinguished from IFN-gamma by its heat stability (100 degrees C, 20 min), approximate MW of 2400 Da (gel filtration high-pressure liquid chromatography), and absence of interferon activity in both antiviral and enzyme-linked immunosorbent assays. TS-treated macrophages, however, did not exhibit a greater capacity to kill or inhibit the intracellular growth of Toxoplasma gondii, indicating that the thymocyte factor did not fully activate macrophage microbicidal mechanisms. These data suggest that thymocytes can increase the respiratory burst capacity of macrophages in the absence of antigen-specific immune responses.     

A role for oxygen-dependent mechanisms in killing of Leishmania donovani tissue forms by activated macrophages

Leishmania donovani, the causative agent of visceral leishmaniasis, infects macrophages (M phi ) of susceptible vertebrates. Immunologically activated M phi are leishmanicidal, but the mechanisms involved in the killing process are not well defined. We sought to investigate the role of reactive oxygen intermediates in the killing of L. donovani. Both the free-swimming promastigote and the intracellular amastigote forms were found to be susceptible to killing in vitro by hydrogen peroxide and other oxygen intermediates. Upon phagocytosis by mouse peritoneal M phi, promastigotes elicited a significantly stronger respiratory burst compared with amastigotes as measured by release of superoxide anion. Although amastigotes do not elicit a strong burst of M phi oxidative metabolism during the initial phagocytic event, immunologically activated M phi that acquired leishmanicidal capacity could be triggered to release substantial amounts of H2O2. Hence, the development of leishmanicidal capacity was correlated temporally with enhanced H2O2 generation by the M phi. In contrast, M phi that lost their ability to release significant amounts of H2O2 after several days in culture were unable to eliminate their parasite burden. Catalase markedly inhibited the elimination of amastigotes by lymphokine-stimulated M phi. In toto, the results implicate reactive oxygen intermediates in killing of the tissue form of L. donovani by its host cell, the mononuclear phagocyte.     

Cyclosporin A inhibits phorbol ester-induced activation of superoxide production in resident mouse peritoneal macrophages.

Peritoneal resident macrophages from mice are sensitive to inhibition by cyclosporin A (CsA) of phorbol 12-myristate 13-acetate (PMA)-stimulated oxidative burst. Inhibition was assessed in terms of superoxide anion (O2.-) and H2O2 production. Key findings were as follows. (a) CsA inhibited in a dose-dependent manner the production of O2.- when cells were stimulated with PMA. CsA did not alter the respiratory burst induced by other stimuli (zymosan, concanavalin A and fMet-Leu-Phe). It was verified that CsA itself had no scavenger effect. (b) A concomitant decrease in H2O2 liberation following CsA exposure was found. This inhibition was observed both in the initial rate of synthesis and in the accumulation after 15 min of incubation. (c) NADPH oxidase activity in the crude supernatant was unaffected by the previous incubation of macrophages with CsA. CsA does not inhibit glucose transport measured as 14CO2 production. (d) The production of O2.- was strongly dependent on the glucose concentration. Sodium oleate also stimulated O2.- production in resident macrophages. These data might be correlated with the inhibitory effect of CsA upon other functions of macrophages.     

Augmentation of c-fos mRNA expression by activators of protein kinase C in fresh, terminally differentiated resting macrophages.

Expression of c-fos mRNA was investigated in fresh, normal peritoneal macrophages (M phi), which are terminally differentiated, nonproliferating cells. The levels of c-fos mRNA were dramatically increased by stimulation with phorbol myristate acetate (PMA), calcium ionophore, or 1-oleoyl-2-acetoyl glycerol (OAG). Induction of c-fos mRNA by all the above agents followed similar kinetics, with a peak of mRNA 30 min after stimulation. These results demonstrate that c-fos mRNA can be augmented in fresh, terminally differentiated cells. Since the stimuli increasing c-fos mRNA are direct or indirect activators of protein kinase C, our data suggest that in M phi c-fos mRNA is controlled by protein kinase C activation. PMA, calcium ionophore, and OAG were biologically active in M phi. PMA and calcium ionophore induced respiratory burst and tumoricidal activity, respectively, whereas OAG and PMA were chemotactic for M phi. Interferons beta and gamma, potent M phi activators eliciting tumoricidal activity, did not alter the levels of c-fos mRNA. These results indicate that c-fos mRNA augmentation is a stimulus-specific rather than a function-specific response connected to activation of protein kinase C.     

Adenosine regulates the respiratory burst of cytokine-triggered human neutrophils adherent to biologic surfaces

The effect of adenosine on the respiratory burst was investigated using human neutrophils adherent to serum-coated surfaces. Adenosine caused complete suppression of the respiratory burst elicited by TNF-alpha, FMLP, or CSF for granulocytes; partial suppression of the response to CSF for granulocytes/macrophages, Staphylococcus aureus, Escherichia coli, Listeria monocytogenes, or uncoated polystyrene surfaces; and no suppression of the response to PMA. In most experiments, 4.7 x 10(-7) M and 2.5 x 10(-8) M adenosine caused 50% suppression of H2O2 release in response to TNF-alpha and FMLP, respectively, and 10 microM caused 100% suppression. Preexposure of neutrophils to ADP blocked the inhibitory effect of adenosine. With adherent neutrophils, there is a prolonged lag period in the onset of the respiratory burst in response to cytokines. Adenosine was fully suppressive if its addition was delayed past the first third of this lag period, or if it was removed during the last third of the lag period. A 10-min pulse with adenosine was most inhibitory when delivered in the middle third of the lag period. Dihydrocytochalasin B abolished the suppressive effect of adenosine on H2O2 release in response to FMLP. Thus adenosine, at concentrations found in human plasma, is a potent but selective inhibitor of the respiratory burst of adherent human neutrophils in response to physiologic, soluble stimuli, and ADP is a potentially physiologic counter-suppressant. Adenosine appears to exert most of its effect during a discrete interval within the lag period before onset of the respiratory burst, and may affect the coupling of agonist receptors to the cytoskeleton.     

Diminished protein kinase C-activated arachidonate metabolism accompanies rat macrophage differentiation in the lung

Alveolar macrophages (AM) differ from other macrophage (m phi) populations in their profile of eicosanoids synthesized from arachidonic acid (AA)3. Little information is available regarding possible differences in the regulation of AA metabolism among various m phi populations. In our study, we compared the ability of cultured resident rat AM and peritoneal m phi (PM) to release and metabolize AA in response to exogenous activators of protein kinase C (PKC). When stimulated with PMA, prelabeled PM released free [3H]AA in a dose-dependent manner over the concentration range 1 to 100 nM. As assessed by HPLC, PMA-stimulated PM metabolized AA to a variety of predominantly cyclooxygenase products. The dose-dependent synthesis of PGE2 by unlabeled PM stimulated with PMA was confirmed using RIA. The ability of PMA to trigger AA release and metabolism in PM was a function of its capacity to activate PKC, as indicated by the following: 1) an additional activator of PKC, oleoyl acetylglycerol, also triggered PM AA metabolism, whereas phorbol didecanoate, which lacks the ability to activate PKC, did not; 2) two structurally unrelated inhibitors of PKC activation (staurosporine and sphinganine) both abrogated PMA induced AA release in PM; and 3) pretreatment for 18 h with high dose PMA (used to deplete cellular PKC), but not phorbol didecanoate, rendered PM refractory to subsequent PMA stimulation of AA release. In contrast to PM, AM cultured in identical fashion failed to release or metabolize AA in response to either PMA or oleoyl acetylglycerol. PM and AM were also compared for their ability to release extracellular superoxide anion in response to PMA; once again, PM exhibited significantly greater release than did AM. Inasmuch as this unresponsiveness to activation of PKC distinguishes AM from other m phi populations, we conclude that it is a unique consequence of m phi differentiation in the lung. Moreover, because both AA metabolism and the respiratory burst are affected, this refractoriness appears to reflect a defect at some proximal level in PKC-mediated signaling.     

Macrophage colony-stimulating factor (M-CSF) enhances the capacity of murine macrophages to secrete oxygen reduction products

The capacity of macrophage colony-stimulating factor (M-CSF) to enhance respiratory burst activity in peritoneal macrophages was measured. Macrophages incubated for 48 hr or more with concentrated L cell-conditioned medium as a source of M-CSF released two to three times as much O2- in response to PMA as did unexposed macrophages. Stimulation was noted at concentrations of colony-stimulating activity from 0.1 to 2000 U/ml and was maximal at 10 to 100 U/ml. Purified, endotoxin-free CSF enhanced secretion to a similar degree as unpurified L cell-conditioned medium. Release of O2- by M-CSF macrophages occurred over 60 min and was triggered by opsonized zymosan as well as PMA. H2O2 release was also enhanced in macrophages exposed to both unpurified and purified M-CSF. These data indicate that M-CSF enhances the capacity of mature macrophages to release oxygen reduction products, and they are consistent with reports that CSF can stimulate the release of other secretory products.     

Rat macrophage treatment with lipopolysaccharide leads to a reduction in respiratory burst product secretion and a decrease in NADPH oxidase affinity

The effect of LPS on the respiratory burst in resident rat peritoneal macrophages has been examined. Rat macrophages secreted high levels of both O2- and H2O2 in response to triggering with phorbol esters, opsonized zymosan, and immune complexes. After culture in vitro with LPS these macrophages exhibited a marked diminution in their capacity to secrete high levels of respiratory burst products. The LPS-mediated loss of secretory activity was apparent after 2 hr of exposure to LPS and was inhibitable by polymyxin B in a dose-dependent fashion. The effect was not selective for any triggering agent type as inhibition of secretory activity occurred after triggering with PMA, zymosan and immune complexes. PGE2 added at levels secreted by the macrophages in response to LPS also inhibited respiratory burst product secretion. In addition, indomethacin prevented the LPS-mediated inhibition of secretion. Because the inhibition of secretion was common to all triggering agents tested, this suggested that the basis for the impaired secretion was at a level other than the receptor for the triggering agent. Both LPS and PGE2 treatment of the macrophages increased the Km of the oxidase for NADPH (1.7- to 2.3-fold) without affecting significantly the Vmax of the enzyme. These data suggest that stimulation of rat peritoneal macrophages by LPS results in an impaired ability to secrete respiratory burst products as a result of a PGE2-mediated decrease in NADPH oxidase affinity and that this alteration is independent of alterations in tumoricidal activity.     

Respiratory burst responses of rat macrophages to microsporidian spores.

This study investigated the respiratory burst responses of rat resident peritoneal macrophages and of peritoneal macrophages stimulated 5 days previously with viable spores of the fish infecting microsporidian Microgemma caulleryi. Nitric oxide production by resident macrophages and prestimulated macrophages in response to viable microsporidian spores was significantly lower than in response to Escherichia coli lipopolysaccharide (LPS) (nitrite concentration in medium 57 +/- 1 microM for resident macrophages stimulated with LPS versus 31 +/- 1 microM for resident macrophages stimulated with microsporidian spores and 36 +/- 4 microM for M. caulleryi prestimulated macrophages; P < 0.05). Extracellular release of reactive oxygen species (ROS) by resident macrophages in response to microsporidian spores was similar to that in response to Kluyveromyces lactis yeast cells and to that in response to phorbol myristate (a stimulator of protein C kinase). Intracellular ROS production by resident macrophages in response to microsporidian spores was similar to that produced in response to yeast cells. Both extracellular ROS production and intracellular ROS production (in response to all stimuli) were significantly lower after in vivo prestimulation of macrophages with microsporidian spores. These results demonstrate that microsporidian spores of species other than those that habitually infect mammals are capable of modulating the respiratory burst of rat peritoneal macrophages. Such modulation may contribute to avoidance by the microsporidian of cytotoxic responses associated with the respiratory burst.     

Failure of Trypanosoma cruzi to trigger the respiratory burst of activated macrophages. Mechanism for immune evasion and importance of oxygen-independent killing

Activated macrophages are thought to kill Trypanosoma cruzi, which lack catalase, by the generation of hydrogen peroxide. We investigated triggering of the respiratory burst of activated macrophages induced by phagocytosis of virulent T. cruzi, bloodform trypomastigotes, amastigotes obtained from spleens, and tissue culture organisms; and of relatively nonvirulent epimastigotes. All stages of T. cruzi prompted the release of less than 10% of hydrogen peroxide released by activated macrophages when stimulated with PMA or Candida. Superoxide anion production was not stimulated by PMA or Candida in activated macrophages nor was there a significant qualitative reduction of nitroblue tetrazolium induced by ingestion of virulent T. cruzi. Opsonization of T. cruzi with specific antibody did not promote the release of hydrogen peroxide or the reduction of nitroblue tetrazolium. Similar results were observed with activated spleen macrophages. Incubation of activated macrophages with catalase, catalase and superoxide dismutase, sodium benzoate with or without catalase, and respiratory burst-exhausting PMA failed to inhibit the killing of T. cruzi in vitro. These results indicate that 1) virulent opsonized or unopsonized T. cruzi do not trigger a respiratory burst by activated macrophages and 2) oxygen-independent killing of T. cruzi is of prime importance.     

Some biochemical and functional characteristics of macrophages activated by Tetrahymena pyriformis

Phagocytosis, enzyme activities and capacity to release hydrogen peroxide (H2O2) and superoxide anion (O2-) of peritoneal macrophages from mice inoculated with Tetrahymena pyriformis, a free-living ciliate, were examined in comparison with resident and BCG-activated macrophages. Fc receptor-mediated phagocytosis of sheep erythrocytes was markedly increased in Tetrahymena-activated macrophages to the same level as that seen in BCG-activated ones. Tetrahymena-activated macrophages showed an increased level of acid phosphatase (lysosomal enzyme) and a reduced level of alkaline phosphodiesterase I (plasma membrane ectoenzyme) as compared with resident macrophages. Similar changes in the activities of the two enzymes were also observed in BCG-activated macrophages. Both Tetrahymena- and BCG-activated macrophages exhibited more enhanced capacity to release H2O2 and O2- than resident macrophages when stimulated with phorbol myristate acetate. In the macrophages from mice inoculated with varying doses of Tetrahymena, a significant correlation was observed between the increased capacity of H2O2 and O2- release as observed in the present study, and the enhanced toxoplasmacidal activity as observed in a previous study, in a dose-dependent fashion.     

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.     

Regulation of arachidonic acid metabolism in macrophages by immune and nonimmune interferons

Mouse resident peritoneal M phi release AAA and metabolize it into cyclooxygenase- and lipoxygenase-derived eicosanoids, when triggered in vitro with different stimuli. Pretreatment of M phi with nonimmune IFN-alpha and IFN-beta dramatically decreased AA liberation from M phi phospholipids and eicosanoid formation after stimulation of M phi with Zy, A23187, or PMA. M phi exposed to immune IFN-gamma also showed a substantial impairment of both AA liberation and eicosanoid production upon exposure to Zy. However, AA and eicosanoid release was increased by IFN-gamma, rather than depressed, in PMA-triggered M phi. In addition, IFN-gamma showed differential effects on M phi stimulated with A23187. In fact, it inhibited AA release as well as formation of lipoxygenase-derived LTC4, but it highly increased the release of the cyclooxygenase products PGE2 and 6-keto PGF1 alpha. The ability of IFN-gamma to differentially modulate AA metabolism of M phi, depending on the nature of the triggering agent, sets forth the high specificity of the regulatory capacity of this molecule. This is at variance with the down regulation of AA metabolism that is generally observed with nonimmune IFN.     

Release of reactive nitrogen intermediates and reactive oxygen intermediates from mouse peritoneal macrophages. Comparison of activating cytokines and evidence for independent production

The capacity of 12 cytokines to induce NO2- or H2O2 release from murine peritoneal macrophages was tested by using resident macrophages, or macrophages elicited with periodate, casein, or thioglycollate broth. Elevated H2O2 release in response to PMA was observed in resident macrophages after a 48-h incubation with IFN-gamma, TNF-alpha, TNF-beta, or CSF-GM. Of these, only IFN-gamma induced substantial NO2- secretion during the culture period. The cytokines inactive in both assays under the conditions tested were IL-1 beta, IL-2, IL-3, IL-4, IFN-alpha, IFN-beta, CSF-M, and transforming growth factor-beta 1. Incubation of macrophages with IFN-gamma for 48 h in the presence of LPS inhibited H2O2 production but augmented NO2- release, whereas incubation in the presence of the arginine analog NG-monomethylarginine inhibited NO2- release but not H2O2 production. Although neither TNF-alpha nor TNF-beta induced NO2- synthesis on its own, addition of either cytokine together with IFN-gamma increased macrophage NO2- production up to six-fold over that in macrophages treated with IFN-gamma alone. Moreover, IFN-alpha or IFN-beta in combination with LPS could also induce NO2- production in macrophages, as was previously reported for IFN-gamma plus LPS. These data suggest that: 1) tested as a sole agent, IFN-gamma was the only one of the 12 cytokines capable of inducing both NO2- and H2O2 release; 2) the pathways leading to secretion of H2O2 and NO2- are independent; 3) either IFN-gamma and TNF-alpha/beta or IFN-alpha/beta/gamma and LPS can interact synergistically to induce NO2- release.     

IL-4 inhibits superoxide production by human mononuclear phagocytes

The activation of mononuclear phagocytes (M phi) and their generation of oxidative products is influenced by various cytokines as well as by normal maturational changes. We examined the effects of IL-4 on superoxide (O2-) production (cytochrome c reduction) by cultured M phi and the modulation of these effects by IFN-gamma and IL-1. Incubation of IL-4 (200 U/ml) with M phi inhibited M phi PMA (100 ng/ml)-stimulated O2-. production by 23% at 24 h, 34% at 48 h, and 70 to 85% at 72 to 96 h. IL-4 similarly inhibited M phi O2-. production in response to zymosan. IL-4 did not affect M phi viability, adherence to microtiter plates, or ability to phagocytose boiled yeast. In comparison with M phi, neutrophil O2-. production was not inhibited after 4 to 20 h incubation with IL-4. When IL-4 was washed out as early as 1 h after the initiation of M phi culture, significant inhibition of O2-. production was observed 4 days later. Sequential addition of either IL-4 or IFN-gamma to cultures demonstrated reciprocal cytokine effects on M phi; IL-4 partially inhibited O2-. production by M phi previously treated with rIFN-gamma whereas rIFN-gamma partially augmented O2-. production by M phi previously treated with IL-4. Because IL-4 has been reported to inhibit IL-1 production, add-back experiments were performed; addition of IL-1 only partly reconstituted O2-. production in IL-4-treated cells. Further characterization showed that although M phi protein synthesis was enhanced by both rIFN-gamma and IL-4 treatment, acid phosphatase, a marker of maturation to the macrophage phenotype, was markedly increased at an earlier time point in IL-4-treated M phi, and correlated with a decline in O2-. production. The ability of IL-4 to suppress M phi O2-. production implicates IL-4 as an important regulator of this aspect of the inflammatory response.