ANA-1 Macrophages Research Articles

Regulation of inducible nitric oxide synthase expression in IFN-gamma-treated murine macrophages cultured under hypoxic conditions.

We recently reported that a hypoxia-responsive element mediates a novel pathway of transcriptional activation of the inducible nitric oxide synthase (iNOS) promoter in murine macrophages treated with IFN-gamma plus hypoxia (1% O2). In this study, we investigated the expression of NOS activity and the regulation of NOS induction in IFN-gamma treated ANA-1 murine macrophages or thioglycollate-elicited peritoneal macrophages cultured under hypoxic conditions. We found that murine macrophages stimulated with IFN-gamma plus hypoxia, despite a significant accumulation of iNOS mRNA, did not release nitrite into culture supernatant. However, cytosol from macrophages treated with IFN-gamma plus hypoxia contained significant levels of iNOS protein and enzymatic activity. Experiments in which cells were treated with IFN-gamma plus hypoxia and then cultured in normoxic conditions (20% O2) demonstrated that reoxygenation was required to achieve detectable accumulation of nitrite in the culture supernatant. Furthermore, we demonstrated that IL-4 inhibited IFN-gamma plus hypoxia-dependent induction of iNOS mRNA expression, iNOS protein, and enzymatic activity. Experiments in which ANA-1 macrophages were transfected transiently with the full-length iNOS promoter linked to a chloramphenicol acetyltransferase reporter gene demonstrated that IL-4 also down-regulated the IFN-gamma plus hypoxia-induced activation of the iNOS promoter. These data establish that hypoxia is a costimulus with IFN-gamma for the induction of iNOS activity in ANA-1 macrophages as well as in murine peritoneal macrophages, and they provide the first evidence that IL-4 inhibits hypoxia-inducible gene expression. In addition, our results suggest that hypoxia, which occurs in many pathologic conditions, may play an important role in the activation of murine macrophages.

Multiple Cytokines Inhibit Interleukin-6-Dependent Murine Hybridoma/Plasmacytoma Proliferation

A panel of cytokines was tested for inhibitors of interleukin-6 (IL-6)-dependent cell proliferation. Murine type I and II interferons (mIFNs) strongly inhibited proliferation of IL-6-dependent B9 and 7TD1 cells in a dose-dependent manner. Human tumor necrosis factor-α (hTNF-α) and human transforming growth factor-β (hTGF-β) potently inhibited B9 and to a lesser extent 7TD1 cells, while hIL-11, human oncostatin M (hOSM), and human leukemia inhibitory factor (hLIF) had no inhibitory effects on IL-6-dependent growth. Conversely, IL-11 and OSM but not LIF stimulated B9 and 7TD1 cell growth. However, compared with IL-6, up to 1000-fold higher IL-11 and OSM concentrations were required to induce maximal cell proliferation. Increasing concentrations of IL-6 (up to 100 ng/ml) could not overcome the antiproliferative effects of mIFNs, hTNF-α, and hTGF-β. Supernatants from mIFN-γ and lipopolysaccharide (LPS)-treated mouse macrophages (ANA-1 cell line) were tested in B9 cell assays to identify cytokines among stimulatory and inhibitory biological activities that can inhibit IL-6-dependent proliferation. Undiluted or relatively concentrated supernatants from ANA-1 macrophages treated with mIFN-γ and/or LPS did not contain detectable IL-6 bioactivity. However, diluted samples contained considerable amounts of detectable IL-6 bioactivity (nanogram levels). Testing the same samples for IL-6 immunoreactivity using enzyme-linked immunoabsorbent assay revealed comparable levels of mIL-6. We conclude that IFNs, TNF-α, and TGF-β and possibly other factors are potent, dominant inhibitors of IL-6-dependent plasmacytoma/hybridoma growthin vitro.

Exogenous nitric oxide regulates IFN-gamma plus lipopolysaccharide-induced nitric oxide synthase expression in mouse macrophages.

Abstract This study was performed to determine the effects of nitric oxide (NO) on the expression of inducible NO synthase (iNOS) in mouse macrophages. We used the NO donor diethylamine dinitric oxide (DEA/NO) and the mouse macrophage cell line ANA-1 in these experiments. ANA-1 macrophages did not express iNOS mRNA either constitutively or following exposure to 100 U/ml IFN-gamma alone, to 10 ng/ml LPS alone, or to 200 microM DEA/NO alone. Similarly, ANA-1 macrophages did not express detectable levels of iNOS mRNA following treatment with 100 U/ml IFN-gamma plus 200 microM DEA/NO. However, IFN-gamma (100 U/ml) plus LPS (10 ng/ml) induced high levels of iNOS mRNA in ANA-1 macrophages after 6 h. Low concentrations of DEA/NO (approximately 1 to 12 microM) caused up to a 2.5-fold augmentation of IFN-gamma plus LPS-induced iNOS mRNA expression. In contrast, 200 microM DEA/NO suppressed IFN-gamma plus LPS-induced iNOS mRNA expression (60% decrease). The effects of DEA/NO were gene-specific because DEA/NO did not affect the IFN-gamma plus LPS-induced expression of TNF-alpha mRNA. Moreover, the biphasic effects of DEA/NO were specifically due to released NO. Diethylamine and nitrite were unable to regulate IFN-gamma plus LPS-induced gene expression in ANA-1 macrophages. Time-response experiments suggested that the effects of NO were short-lived and occurred early during the induction of iNOS gene expression. The effects of NO were not limited to iNOS mRNA expression but were apparent at the level of iNOS protein expression and enzymatic activity. Overall, these results suggest that NO has immunoregulatory effects and may control the extent and duration of cytokine- and/or endotoxin-induced iNOS expression in macrophages.

Murine Th1 and Th2 cell clones differentially regulate macrophage nitric oxide production

Previous studies have demonstrated that the combination of the T helper cell 1 (Th1)-derived cytokines interleukin (IL)-2 and interferon (IFN)-gamma induces nitric oxide (NO) production and tumor cytolysis by mouse peritoneal macrophages and the mouse macrophage cell line ANA-1 in vitro. Conversely, the Th2-derived cytokine IL-4 inhibits IL-2 and IFN-gamma-induced NO production and tumor cytolysis by ANA-1 macrophages. To examine the paracrine regulatory effects of Th1 and Th2 cells on macrophages, various mouse T cell clones were tested for their ability to regulate NO production by mouse peritoneal macrophages or ANA-1 macrophages. Antigen, superantigen, and mitogen stimulated Th1 cells but not Th2 cells induced NO production by macrophages. Supernatants from these activated Th1 clones also induced NO production by peritoneal macrophages and ANA-1 macrophages. Neutralization analysis using monoclonal anticytokine antibodies revealed that both IL-2 and IFN-gamma production by activated Th1 cells were required for the production of NO by macrophages. Co-culture studies using a panel of Th2 cell clones that share the same antigen specificity revealed that these cells suppressed Th1-mediated macrophage activation. The Th2-mediated impairment of Th1-induced NO production was primarily due to the secretion of IL-4. IL-4 appeared to have a direct effect on macrophage activation because neither mitogen-induced proliferation of Th1 cells nor cytokine production by Th1 cells were affected by IL-4. Overall, these results suggest that a potent paracrine regulatory network involving Th1 cells and Th2 cells may control the activation of macrophages for NO production and antitumor cytotoxicity.

Characterization of nitric oxide–stimulated ADP-ribosylation of various proteins from the mouse macrophage cell line ANA-1 using sodium nitroprusside and the novel nitric oxide-donating compound diethylamine dinitric oxide

We examined the ability of nitric oxide (NO) to stimulate the ADP-ribosylation of proteins from the mouse macrophage cell line ANA-1. To demonstrate a specific effect of NO, we used a novel compound named diethylamine dinitric oxide (DEA/NO; 1,1-diethyl-2-hydroxy-2-nitrosohydrazine, sodium salt; [Et2NN(O)NO]Na), which releases NO in aqueous solution at neutral pH. DEA/NO stimulated the ADP-ribosylation of at least three cytosolic proteins (M(r) = 28,000, 33,000 and 39,000) from ANA-1 macrophages. The effect of DEA/NO on the ADP-ribosylation of the predominant target p39 was dose dependent (EC50 = 80 microM). Moreover, the effect of DEA/NO was attributed specifically to released NO rather than diethylamine or nitrite. Sodium nitroprusside (SNP) also stimulated the ADP-ribosylation of cytosolic proteins from ANA-1 mouse macrophages. However, SNP exhibited different time- and dose-dependent effects on the modification of p39. NO synthesized via the activity of interferon-gamma plus lipopolysaccharide-induced NO synthase also enhanced the ADP-ribosylation of p39, confirming that the effects of DEA/NO and SNP could be attributed to NO or reactive nitrogen oxide species. Neither pertussis toxin nor cholera toxin stimulated the ADP-ribosylation of p39; however, cholera toxin stimulated the ADP-ribosylation of proteins with approximate molecular weight of 28,000 and 33,000. These data suggest that the induced expression of NO synthase in tumoricidal macrophages may be associated with autocrine and paracrine effects of NO that include the ADP-ribosylation of various proteins. Moreover, these results indicate that DEA/NO and related compounds may be useful as pharmacologic tools for investigating the effects of NO and reactive nitrogen oxide species on macrophages.

Induction of tumor necrosis factor alpha gene expression by lipoprotein lipase requires protein kinase C activation.

We have previously found that lipoprotein lipase (LPL) induces tumor necrosis factor alpha (TNF alpha) mRNA expression and TNF alpha protein production in the ANA-1 macrophage cell line and in resident murine macrophages. The present study was designed to elucidate the intracellular signalling pathways involved in the LPL-induced TNF alpha gene expression. Treatment of macrophages with two protein kinase C (PKC) inhibitors, 1-(5-isoquinolinesulfonyl)-2-methylpiperazine hydrochloride (H7) and calphostin C, suppressed LPL-induced TNF alpha mRNA expression and protein production. In contrast, no inhibition of the TNF alpha mRNA expression occurred when macrophages were exposed to an inhibitor of calmodulin-dependent kinase N-(6-amino-hexyl)-5-chloro-1-naphthalene-sulfonamide hydrochloride (W7). Overnight treatment of ANA-1 cells with 100 ng/ml 4 beta-phorbol 12 beta-myristate 13 alpha-acetate (PMA) caused the suppression of both PKC activity and LPL-induced TNF alpha mRNA expression. We have also found that LPL treatment increased PKC activity in macrophages and induced a translocation of this enzyme from the cytosol to the membrane. Finally, we have demonstrated that H7 inhibited the enhancement of nuclear protein binding to the NFkB consensus sequence in the promoter of the TNF alpha gene that we observed in LPL-treated macrophages. Moreover, the treatment of macrophages with H7 abolished the stabilization of TNF alpha mRNA in response to LPL. Overall these data demonstrate that LPL induces TNF alpha mRNA expression in a PKC-dependent manner and that the PKC effect involves transcriptional events as well as posttranscriptional modifications.

Tumor necrosis factor as an autocrine and paracrine signal controlling the macrophage secretory response to Candida albicans

We have previously demonstrated that the hyphal form of Candida albicans (H-Candida), but not the yeast form (Y-Candida), acts as a macrophage-stimulating agent. The early response (1 to 3 h) of the macrophage cell line ANA-1 to H-Candida results in enhanced tumor necrosis factor (TNF) transcription and production. Here we show that when coincubation times are prolonged (3 to 24 h), Y-Candida also exhibits stimulatory properties. This phenomenon has been ascribed to the occurrence of the dimorphic transition, as demonstrated by microscopic evaluation of the cultures and by experiments in which both killed Y-Candida and the agerminative strain C. albicans PCA-2 failed to induce cytokine production. TNF produced in response to H-Candida acts as an autocrine and paracrine signal controlling the macrophage secretory response to C. albicans. In fact, addition of anti-TNF polyclonal antibodies to the coculture of ANA-1 macrophages and H-Candida results in a marked and time-dependent decrease of TNF transcript levels. Moreover, pretreatment of macrophages with recombinant TNF for 3 h enhances TNF and induces interleukin-1 production in response to both forms of Candida, while pretreatment for 18 h renders macrophages refractory to any stimuli. Interestingly, the kinetics of interleukin-1 transcription and secretion in response to H-Candida are delayed with respect to those of TNF. Overall, these data indicate that TNF, produced by macrophages in response to H-Candida, regulates its own production as well as that of other soluble factors, thus suggesting that this cytokine plays multiple roles in the immune mechanisms involved in Candida infection.

Picolinic acid, a catabolite of L-tryptophan, is a costimulus for the induction of reactive nitrogen intermediate production in murine macrophages.

In this study we investigated the effects of picolinic acid, a catabolite of L-tryptophan, on the production of L-arginine-derived reactive nitrogen intermediates in the murine macrophage cell line ANA-1. ANA-1 macrophages did not produce nitrite (NO2-) constitutively, but accumulated detectable levels of NO2- on exposure to IFN-gamma. Picolinic acid, although ineffective by itself, augmented IFN-gamma-induced NO2- production. The activity of picolinic acid was evident at 1 mM and reached its maximum at 4 mM. Picolinic acid also augmented the IFN-gamma-dependent expression of TNF-alpha mRNA, but did not appreciably affect the secretion of the TNF-alpha protein. Neutralizing concentrations of anti-TNF mAb completely abrogated IFN-gamma- and IFN-gamma plus rTNF-alpha-induced NO2- production in ANA-1 macrophages, but only decreased by approximately 50% the synergistic interaction between IFN-gamma and picolinic acid. Although IL-4 inhibited the expression of IFN-gamma plus picolinic acid-induced TNF-alpha mRNA and protein, it only partially suppressed picolinic acid-dependent NO2- production. Therefore, picolinic acid may affect NO2- production via both TNF-alpha-dependent and TNF-alpha-independent pathways. Overall, this study suggests that amino acid catabolites may be important for the activation and the expression of effector functions by murine macrophages, and provides the first evidence of a possible connection between tryptophan and arginine metabolism.

Tumor necrosis factor-alpha-dependent production of reactive nitrogen intermediates mediates IFN-gamma plus IL-2-induced murine macrophage tumoricidal activity.

We have previously established that IFN-gamma plus IL-2 induces murine macrophage tumoricidal activity. The purpose of this study was to identify the effector molecules that account for the IFN-gamma plus IL-2-induced macrophage cytotoxicity against P815 mastocytoma cells. ANA-1 macrophages and normal thioglycollate-elicited mouse peritoneal macrophages produced little or no detectable nitrite (NO2-) after incubation with IFN-gamma alone or IL-2 alone; however, IL-2 synergized with IFN-gamma for the production of NO2-. IFN-gamma plus IL-2 did not induce NO2- production or tumoricidal activity in ANA-1 macrophages that were cultured in medium devoid of L-arginine or in ANA-1 macrophages that were incubated with NG-monomethyl-L-arginine. As observed previously with ANA-1 macrophage tumoricidal activity, IL-4 inhibited IFN-gamma plus IL-2-induced, but not IFN-gamma plus LPS-induced, NO2- production. IL-4 also selectively decreased the ability of IFN-gamma and/or IL-2 to augment TNF-alpha mRNA expression in ANA-1 macrophages. Lastly, incubation of ANA-1 macrophages with anti-TNF mAb selectively inhibited the ability of IFN-gamma plus IL-2 to induce NO2- production and tumoricidal activity. These results indicate that IFN-gamma plus IL-2-induced tumoricidal activity is dependent upon the metabolism of L-arginine to reactive nitrogen intermediates, and they establish a role for TNF-alpha as a required intermediate for IL-2-dependent NO2- production and tumoricidal activity.

Candida albicans hyphal form enhances tumor necrosis factor mRNA levels and protein secretion in murine ANA-1 macrophages

We have demonstrated that Candida albicans in its hyphal form (H- Candida) acts as a stimulating agent in the cloned macrophage population ANA-1. Both tumor necrosis factor (TNF) mRNA levels and secreted biological activity augment in ANA-1 macrophages exposed to H- Candida. Such effects are observed at an effector-to-target cell ratio of 1:1 and occur after 1 and 3 hr of coincubation, respectively. The phenomenon is independent of the metabolic status of the fungus, since viable as well as heat-killed H- Candida are comparable in inducing TNF mRNA levels. The extent and kinetics of H- Candida-mediated effects are similar to those observed following exposure of ANA-1 macrophages to lipopolysaccharide (LPS). This implies that C. albicans in its hyphal form is a potent macrophage modulator; whether it acts through the same mechanism(s) as LPS remains to be elucidated.

Early differential molecular response of a macrophage cell line to yeast and hyphal forms of Candida albicans.

The dimorphic transition of Candida albicans from the yeast (Y-Candida) to the hyphal (H-Candida) form is a complex event; the relevance of this transition in fungal pathogenicity is still poorly understood. By using a cloned macrophage cell line (ANA-1), we questioned whether the interaction between macrophages and Y-Candida or H-Candida could affect specific cell functions, i.e., tumor necrosis factor and lysozyme production. We found that ANA-1 macrophages selectively responded to H-Candida with increased tumor necrosis factor and downregulated lysozyme, as assessed by measurement of relative mRNA levels and secreted biological activities. The H-Candida-mediated effects were (i) dependent upon the ratio between ANA-1 macrophages and H-Candida, (ii) detectable after 1 h of coincubation, and (iii) accomplished without fungal ingestion. Conversely, Y-Candida, which was found inside the ANA-1 macrophages, did not affect tumor necrosis factor and lysozyme production, nor did it prevent the macrophage response to other stimuli. Overall, these results indicate that a macrophage can distinguish between Y-Candida and H-Candida and that only the latter is able to modulate specific functions. H-Candida is recognized and probably processed as an extracellular target. The possible implication of macrophages as autocrine and paracrine regulatory cells during Candida infections is discussed.

IL-4 inhibits the costimulatory activity of IL-2 or picolinic acid but not of lipopolysaccharide on IFN-gamma-treated macrophages.

We reported previously that IL-2 induces tumoricidal activity in IFN-gamma-treated murine macrophages. The present study was performed to investigate the regulation of IL-2-dependent tumoricidal activity in murine macrophage cell lines. The v-raf/v-myc-immortalized murine macrophage cell lines ANA-1, GG2EE, and HEN-CV did not express constitutive levels of cytotoxic activity against P815 mastocytoma cells. Moreover, these macrophage cell lines did not become tumoricidal after exposure to IL-4, IFN-gamma, IL-2 or LPS. However, these macrophages developed cytotoxic capabilities after incubation with either IFN-gamma plus IL-2 or IFN-gamma plus LPS. IL-4 inhibited IFN-gamma plus IL-2- but not IFN-gamma plus LPS-induced tumoricidal activity. This effect of IL-4 was not restricted to v-raf/v-myc-immortalized macrophage cell lines because similar results were obtained by using a macrophage cell line that was established from a spontaneous histiocytic sarcoma. The suppressive activity of IL-4 on the ANA-1 macrophage cell line was dose-dependent (approximately 12-200 U/ml) and was neutralized by the addition of anti-IL-4 mAb. IL-4 decreased the IFN-gamma-induced expression of mRNA for the p55 (alpha) subunit of the IL-2R in ANA-1 macrophages. Therefore, at least one mechanism by which IL-4 may have inhibited IFN-gamma plus IL-2-induced tumoricidal activity was by reducing macrophage IL-2R alpha mRNA expression. We have previously reported that picolinic acid, a tryptophan metabolite, is a costimulator of macrophage tumoricidal activity. We now report that IL-4 also inhibited IFN-gamma plus picolinic acid-induced cytotoxicity in ANA-1 macrophages. We propose that IL-2 and picolinic acid may have a common mechanism of action that is susceptible to IL-4 suppression.

Characterization of IL-2 receptor expression and function on murine macrophages.

This study was designed to examine the expression and function of IL-2R on murine macrophages. We used a model system of murine macrophage cell lines (ANA-1 and GG2EE) that was established by infecting normal murine bone marrow-derived cells with the J2 (v-raf/v-myc) recombinant murine retrovirus. ANA-1 macrophages did not constitutively express detectable levels of mRNA for the p55, IL-2R alpha. However, a brief exposure to IFN-gamma was sufficient to induce IL-2R alpha mRNA in ANA-1 macrophages. Flow cytometric analysis indicated that ANA-1 macrophages expressed low constitutive levels of IL-2R alpha on their cell surface that were augmented after treatment of the cells with IFN-gamma. Affinity binding and cross-linking of [125I]IL-2 to ANA-1 macrophages demonstrated that IL-2R alpha and the p70-75, IL-2R beta were both present on ANA-1 macrophages constitutively. IFN-gamma increased the expression of IL-2R alpha on ANA-1 macrophages but did not increase the expression of IL-2R beta on these macrophages. Although IL-2 alone did not induce the tumoricidal activity of ANA-1 macrophages, IL-2 acted synergistically with IFN-gamma to induce macrophage tumoricidal activity. These data demonstrate the expression of IL-2R on murine macrophage cell lines and establish the role of IL-2 as a costimulator of macrophage-mediated tumoricidal activity.