Macrophage activation for microbicidal activity against Leishmania major: inhibition of lymphokine activation by phosphatidylcholine-phosphatidylserine liposomes

Resident peritoneal macrophages from untreated mice develop microbicidal activity against amastigotes of the protozoan parasite Leishmania tropica (current nomenclature = Leishmania major) after in vitro exposure to LK from antigen-stimulated leukocyte culture fluids. This LK-induced macrophage microbicidal activity was completely abrogated by addition of 7:3 phosphatidylcholine: phosphatidylserine liposomes. Liposome inhibition was not due to direct toxic effects against the parasite or macrophage effector cell; factors in LK that induce macrophage microbicidal activity were not adsorbed or destroyed by liposome treatment. Other phagocytic particles, such as latex beads, had no effect on microbicidal activity. Moreover, liposome inhibition of activated macrophage effector function was relatively selective: LK-induced macrophage tumoricidal activity was not affected by liposome treatment. Liposome inhibition was dependent upon liposome dose (5 nmoles/culture) and time of addition of leishmania-infected, LK-treated macrophage cultures. Addition of liposomes through the initial 8 hr of culture completely inhibited LK-induced macrophage microbicidal activity; liposomes added after 16 hr had no effect. Similarly, microbicidal activity by macrophages activated in vivo by BCG or Corynebacterium parvum was not affected by liposome treatment. Liposome treatment also did not affect the increased resistance to infection induced in macrophages by LK. These data suggest that liposomes interfere with one or more early events in the induction of activated macrophages (macrophage-LK interaction) and not with the cytotoxic mechanism itself (parasite-macrophage interaction). These studies add to the growing body of data that implicate cell lipid in regulatory events controlling macrophage effector function.     

Role of protein synthesis in the activation of cytotoxic mouse macrophages by lymphokines

The role of protein synthesis during the activation of macrophages (M phi) by lymphokines (LK) was studied. Peritoneal murine macrophages elicited by proteose-peptone (pM phi) were activated with LK (supernatants from normal mouse spleen cells pulsed with concanavalin A) and tested for cytotoxicity in an 18 hr assay against 111In-labeled L5178Y lymphoma target cells. Reversible (cycloheximide and puromycin) or poorly reversible (emetine and pactamycin) inhibitors of protein synthesis were added during activation, and their effects on pM phi-mediated cytotoxicity and pM phi protein synthesis were measured. Minimal concentrations of inhibitors, reducing the rate of protein synthesis by more than 90% without toxic effects on macrophages, were chosen. Exposure of pM phi to LK for 2 to 18 hr in the presence of reversible inhibitors of protein synthesis did not affect the induction of cytolytic activity, indicating that protein synthesis was not required during the activation period. In contrast, activation of macrophages for 2 hr in the presence of poorly reversible inhibitors of protein synthesis resulted in a considerable reduction of cytolytic activity. The impairment of cytotoxic activity was also evident when pM phi were treated with such drugs during the first 2 hr of an 18 hr exposure to LK or when LK-activated macrophages were treated for 2 hr with the drugs before the addition of the targets. These results demonstrate that active protein synthesis is not required during the exposure of pM phi to LK, but that new proteins have to be synthesized to allow the expression of the cytotoxic activity in LK-activated pM phi.     

Macrophage activation for tumor cytotoxicity: Control of cytotoxic activity by the time interval effector and target cells are exposed to lymphokines

Macrophages continuously exposed to lymphokines (LK) and target cells throughout a 48-hr cytotoxicity assay exhibit 3-fold more tumoricidal activity than do cells optimally treated with LK before addition of tumor cells. Increased cytotoxic activity induced by continuous LK treatment was not due to direct toxic effects of LK on tumor target cells or to alterations in target cell susceptibility to cytopathic effects of LK-activated macrophages. Moreover, sensitivities of responsive macrophages to LK activation signals and time courses for onset and loss of tumoricidal activity during continuous exposure or LK pulse were identical. Analysis of macrophage or LK dose responses and time courses for development of cytotoxicity each suggest that differences in tumoricidal activity between macrophages continuously exposed or pulsed with LK were quantitative: the number of cytotoxic events was increased 2.7 ± 0.2-fold (mean ± SEM for 11 experiments) during continuous LK treatment. Optimal levels of macrophage tumoricidal activity then occur only if effector cells, target cells and activation stimuli are simultaneously present for a defined time interval: tumor cells need not be present during the initial 2 to 3 hr of culture; LK can be removed after 8 hr with little or no loss of cytotoxic activity. However, removal of LK or target cells during the critical 4- to 8-hr interval decreased levels of cytotoxicity 3-fold. Thus, nonspecific effector function by LK-activated macrophages in controlled by both the physicochemical nature of the LK mediator and the time interval effector and target cells are exposed to LK.     

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.     

Elimination of the yeast Candida parapsilosis from lymphoid cells and monolayer cells in culture

In our laboratory, airborne yeast contaminants of cell cultures have consistently been of the genus Candida (species Candida parapsilosis), which are difficult to control with fungicidal agents. To salvage cell lines that show the presence of this fungus, two effective methods may be employed. In early stages of infection, the addition of activated mouse peritoneal macrophages (5 X 10(5) cells/ml) to the culture medium containing 5 micrograms Fungizone /ml eliminates all spores by phagocytosis. More heavily contaminated cultures can be depleted of fungi by density centrifugation on a layer of 38% Percoll. Remaining single spores, often not detectable by light microscopy, can be removed by the addition of macrophages (2 X 10(5)/ml) and Fungizone (5 micrograms/ml) to the culture medium. Contaminated monolayer cells can be freed of blastospores by several washes with balanced salt solution and subsequent culturing for 4 d in medium containing 10 micrograms Fungizone /ml without any toxic effects to the cells. These procedures can rescue valuable cell lines and hybridomas that would otherwise be lost.     

Macrophage activation to kill Leishmania tropica: kinetics of macrophage response to lymphokines that induce antimicrobial activities against amastigotes

Lymphokine (LK) treatment of resident peritoneal macrophages from C3H/HeN mice induced two antimicrobial activities against Leishmania tropica: increased resistance of activated macrophages to infection with amastigotes and intracellular destruction of those parasites that entered activated cells. The onset and duration of these two antimicrobial activities were quite different. Resistance to infection was observed as early as 4 hr after the addition of LK, became maximal at 8 hr, and persisted in a subpopulation of treated cells for as long as 72 hr. In contrast, intracellular killing occurred with as little as 4 hr of LK treatment after infection, and maximal killing was observed in cultures exposed to LK 24 hr. Intracellular killing capacity of lymphokine-treated cells was progressively lost in macrophages treated longer than 12 hr before exposure to parasites. This decay in ability to destroy intracellular L. tropica was also seen in macrophages cultured longer than 12 hr before LK treatment, and may reflect loss of macrophage responsiveness to LK with increasing time in vitro. Thus, treatment of macrophages with lymphokines induced both a stable change in cell-parasite interactions, resistance to infection, and a short-lived capacity to destroy intracellular amastigotes.     

Regulation of activated macrophage antimicrobial activities. Identification of lymphokines that cooperate with IFN-gamma for induction of resistance to infection

Macrophages exposed to lymphokines (LK) before exposure to parasites develop the capacity to resist infection with amastigotes of Leishmania major. Activity of LK for induction of this activated macrophage effector function is abrogated by depleting the LK of IFN-gamma, yet IFN-gamma is incapable of inducing the activity by itself. To identify the factors in LK that serve as second signals for induction of resistance to infection, we exposed macrophages to the following cytokines available as recombinant or highly purified reagents: CSF-1, granulocyte/macrophage colony-stimulating factor (GM-CSF), IL-1, -2, -3, -4, and -5, and IFN-alpha/beta. None of these factors induced resistance to infection by themselves or in combination with each other; in the presence of 50 U/ml IFN-gamma, three cytokines were active: GM-CSF, IL-2, and IL-4. IFN-gamma was an essential component of the activation cascade but was insufficient by itself to induce the effector reaction. Cytokines that act as cofactors with IFN-gamma worked directly on macrophages and not through another cell in the peritoneal cell (PC) cultures. Activation of PC depleted of Thy-1.2+ cells (85 +/- 5% macrophages) and bone marrow-derived macrophages (100% macrophages) showed that 50% maximal doses of GM-CSF, IL-2, and IL-4 for these macrophage-enriched populations were not different than for untreated PC. Unlike other effector reactions of activated macrophages, bacterial LPS did not synergistically enhance the activity of any of the cytokines, alone or in combination with IFN-gamma. Antibody depletion of the active cytokines from LK, singly or in combination, failed to alter the dose response of the active factors in whole LK for induction of resistance to infection. Thus, multiple factors can provide the second signal for IFN-gamma in the induction of resistance to infection, namely, GM-CSF, IL-2, IL-4, and at least two additional undefined factors in whole LK. Resistance to infection may be the first example of an activated macrophage effector reaction that has an absolute requirement for more than one endogenous signal for its induction.     

B cell stimulatory factor-1 (interleukin 4) activates macrophages for increased tumoricidal activity and expression of Ia antigens

Macrophages are activated by lymphokines (LK) to kill tumor cell and microbial targets. Interferon-gamma (IFN) is the major LK activity in conventional, antigen or mitogen-stimulated spleen cell culture fluids for induction of these macrophage effector functions. In view of the recent demonstration that murine macrophage-like cell lines have receptors for B cell stimulatory factor-1/interleukin 4 (BSF-1), a possible role for BSF-1 in regulation of macrophage function was considered. In this communication, thioglycollate-elicited murine peritoneal macrophages were shown to express about 2300 high affinity (Ka approximately 2 X 10(10) M-1) BSF-1 receptors/cell. Peritoneal macrophages treated with purified, T cell-derived BSF-1 developed potent tumoricidal activity against fibrosarcoma target cells. The concentration of BSF-1 that induced 50% of maximal tumor cytotoxicity was 38 +/- 4 U/ml for seven experiments; similar dose-responses were observed with recombinant BSF-1. That BSF-1 dose-responses for induction of macrophage-mediated tumor cytotoxicity were not affected by 5 micrograms/ml polymyxin B suggested that contaminant endotoxins played little or no role in cytotoxic activity. BSF-1 alone (less than or equal to 500 U/ml) was not directly toxic to tumor cells or macrophages. Macrophage tumoricidal activity induced by BSF-1 but not by IFN was inhibited greater than or equal to 90% with monoclonal anti-BSF-1 antibody. BSF-1 induced Ia antigen expression on peritoneal macrophages and increased (twofold to threefold) FcR(II)-dependent binding of murine IgG immune complexes to bone marrow-derived macrophages (greater than 98% macrophages). Based on these findings, it was concluded that BSF-1 is a potent macrophage activation factor.     

Modulation of cyclic AMP-dependent protein kinase isozyme expression associated with activation of a macrophage cell line

We have used the RAW 264.7 macrophage (MO) cell line to study cAMPdPK isozymes during activation by lymphokine (LK) and lipopolysaccharide (LPS). Untreated cells were found to have two isozymes of cAMPdPK in their cytosol. PKI and PKII were differentiated based on the Mr of their regulatory subunits (RI, 45,500; and RII, 52,000, respectively) as determined by photoactivated incorporation of the cAMP analog 8-N3-[32P]cAMP. Loss of the RI subunit of PKI occurred in association with activation of the cell line by suboptimal concentrations of LK and LPS (1/40 dilution, 1 ng/ml) or high concentrations of LPS alone (10 ng/ml to 100 micrograms/ml). No modulation of the RII subunit of PKII was observed under these conditions. The loss of RI was dependent on the addition of a triggering signal to the MO. Treatment of RAW 264.7 cells with LK alone at dilutions from 1/10 to 1/1280 was not sufficient to cause a disappearance of the RI subunit from the cytosol or to induce antitumor activity. The addition of a suboptimal concentration of LPS after LK or a high dose of LPS alone was required for acquisition of cytolytic activity and loss of RI. The kinetics for the disappearance of RI from treated cells were found to be identical after activation with either LK and LPS or high concentrations of LPS alone. RI could no longer be detected in the cytosol 8 hr after the addition of activating agents. The antitumor activity of the RAW 264.7 cell line was transiently expressed after activation. Cells no longer exhibited tumoricidal activity 48 hr after the removal of activating agents. It was observed that the loss of cytolytic function was accompanied by the reexpression of RI in the cytosol. This study provides evidence that modulation of cAMPdPK isozymes occurs during activation, suggesting a potential mechanism for controlling the effects of cAMP on the MO.     

Calcineurin is essential for survival during membrane stress in Candida albicans

The immunosuppressants cyclosporin A (CsA) and FK506 inhibit the protein phosphatase calcineurin and block T-cell activation and transplant rejection. Calcineurin is conserved in microorganisms and plays a general role in stress survival. CsA and FK506 are toxic to several fungi, but the common human fungal pathogen Candida albicans is resistant. However, combination of either CsA or FK506 with the antifungal drug fluconazole that perturbs synthesis of the membrane lipid ergosterol results in potent, synergistic fungicidal activity. Here we show that the C.albicans FK506 binding protein FKBP12 homolog is required for FK506 synergistic action with fluconazole. A mutation in the calcineurin B regulatory subunit that confers dominant FK506 resistance (CNB1-1/CNB1) abolished FK506-fluconazole synergism. Candida albicans mutants lacking calcineurin B (cnb1/cnb1) were found to be viable and markedly hypersensitive to fluconazole or membrane perturbation with SDS. FK506 was synergistic with fluconazole against azole-resistant C.albicans mutants, against other Candida species, or when combined with different azoles. We propose that calcineurin is part of a membrane stress survival pathway that could be targeted for therapy.     

Effects of cycloheximide on in vitro testosterone secretion from RANA catesbeiana ovaries

A 1 hr exposure to 20 micrograms/ml of the protein synthesis inhibitor, cycloheximide (CHX), essentially abolished secretion of testosterone (T) by bullfrog ovarian fragments during simultaneous administration of homologous pituitary extract and CHX. Removal of CHX from the medium after 4 hr of treatment reversed the inhibition of T secretion, allowing it to attain control levels. Pre-exposure of ovarian fragments to CHX was not required to obtain an inhibition of T secretion. These data supported the hypothesis that protein synthesis is required for acute and chronic gonadotropic stimulation of steroidogenesis by the bullfrog ovary.     

Stimulation by conditioned medium of L-929 fibroblasts, E. coli lipopolysaccharide,and muramyl dipeptide of candidacidal activity of mouse macrophages

A simple, quantitative assay method for microbicidal activity of phagocytic cells was devised using normal mouse peritoneal macrophages as effector cells and Candida parapsilosis as target cells. The macrophages were seeded in 96-multiwell tissue culture plates and infected with serially diluted Candida cells. Outgrowth of Candida cells in each well was estimated after a 48-hr incubation period. The maximum number of microbes killed on macrophage monolayers was then determined. The conditioned medium of L-929 cells (L-CM) influenced the fungicidal activity of the macrophages a great deal. An addition of L-CM, to 20% of the culture medium, stimulated the killing activity more than 128-fold, compared with no addition of L-CM. In the medium containing the L-CM macrophages spread very well on the plastic with several dendritic processes, whereas cells spread poorly and gradually cytolysed in the medium lacking L-CM. It was found that muramyl dipeptide at 100 μg/ml and E. coli lipopolysaccharide at 1–10 μg/ml stimulated the activity 4 to 16 times. An application of this method to destroying other kinds of microbes, measuring the activity of other phagocytes, and screening immunomodulators was discussed.     

Regulation of activated macrophage antimicrobial activities. Cooperation of lymphokines for induction of resistance to infection

Macrophages treated with the soluble products of Ag-stimulated spleen cells from bacillus Calmette-Guérin-infected C3H/HeN mice (lymphokines) (LK] before infection developed the capacity to resist infection with obligately intracellular amastigotes of the protozoan parasite, Leishmania major: 40 to 60% fewer cells in LK-treated cultures were infected 2 h after exposure to parasites than cells in medium-treated controls. Macrophages treated with LK depleted of IFN-gamma failed to acquire this activated macrophage effector activity. Paradoxically, IFN-gamma by itself was also not effective. Activity of the ineffective, IFN-gamma-depleted LK was restored, however, by addition of 10 to 100 U/ml IFN-gamma, itself inactive. The induction of this antimicrobial activity was the result of the interaction of macrophages and several molecularly distinct LK, and IFN-gamma was a necessary but insufficient activation signal. The activation of macrophage resistance to infection by LK was 1) not signal sequence dependent, 2) absent in cells treated with the second signal at lower (4 degrees C) temperatures and in the presence of protein synthesis inhibitors, and 3) induced by the cooperation of IFN-gamma and LK of m.w. 45,000 and 33,000. These factors in LK constituted more than 85% total LK activity for induction of resistance to infection. A minor activity in LK, of m.w. 20,000, could apparently induce this effector activity in the absence of IFN-gamma: this activity was less than 15% of total LK activity.     

Differential effects of cyclosporin A on diverse B cell activation phenomena triggered by crosslinking of membrane IgM.

Cyclosporin A (CsA) was tested for its modulatory effects on the mIgM-mediated signaling of G0*-associated increases in class II MHC expression, G1-related RNA synthesis, and S phase-related DNA synthesis in human B cells. While CsA at concentrations as low as 10-100 ng/ml could completely ablate anti-IgM-induced DNA synthesis, earlier G1-associated RNA synthesis was only partially inhibited, and signaling of increased membrane class II MHC expression was unaffected by up to 1000 ng/ml of CsA. Similar phenomena were observed in a clonal population of leukemic B lymphocytes susceptible to anti-IgM-mediated activation in the absence of T cells and T cell factors indicating (a) that the inhibitory effects are not due to CsA-mediated suppression of cytokine production by contaminating T cells, and (b) that the varying effects of CsA on the diverse activation phenomena do not reflect B cell subpopulation diversity. Pulsing studies revealed that while maximal suppression of anti-IgM-induced G1-associated RNA synthesis required CsA at culture initiation, near maximal suppression of DNA synthesis occurred when CsA, or soluble human IgM, was added up to 30 hr after the initial exposure of resting B cells to the anti-IgM ligand. These latter findings are consistent with the possibility that the CsA-mediated suppression of S phase entry is due to the inhibition of a signaling event proximal to mIgM ligation which must be repeatedly initiated throughout the first 30 hr of activation.     

Stimulation of macrophage antibody-dependent killing of tumor targets by recombinant lymphokine factors and M-CSF

Macrophage colony-stimulating factor (M-CSF) was investigated as a stimulator of ADCC to the murine R1.1 thymoma target by murine peritoneal exudate macrophages which were elicited by proteose peptone. Both an 125IUdR release and a viable cell count assay were used. The latter assay avoids radiation damage, and the fate of the targets can be determined over a long period. Pretreatment of macrophages for several days in culture with lymphokine (LK) from concanavalin A-induced mouse spleen cells moderately stimulated ADCC. Preincubation of macrophages with conventional or recombinant human M-CSF or immunoaffinity-purified mouse M-CSF alone had little effect. However, M-CSF greatly enhanced ADCC to the tumor target when used as a costimulant with LK, IFN-gamma, IFN-alpha, IFN-beta, or IL-2 to pretreat macrophages. Incubation of macrophages with LK or LK plus M-CSF for 2 days generated stronger ADCC than 1- or 3-day incubations. Enhancement of LK-stimulated ADCC by M-CSF appeared to plateau at about 1000 U/ml. The enhancement of macrophage cytotoxicity when stimulated with IFNs or IL-2 was most effective at the lowest active concentration of these LKs. At 1 U/ml IFN-gamma or IL-2, or 5 U/ml IFN-alpha or IFN-beta, M-CSF boosted ADCC activity to that using 10-fold of the LK alone. IL-1, IL-4, and TNF had little or no stimulating activity for ADCC alone or with M-CSF, and the other hemopoietic growth factors IL-3 and GM-CSF did not promote this effector function alone or with IFN-gamma. We previously showed that M-CSF boosted macrophage antibody-independent killing of TU5 sarcoma targets with or without LK (Cell. Immunol. 105, 270, 1987). These studies thus show that M-CSF is a positive regulator of both macrophage-nonspecific tumor lysis and ADCC.     

Fungistatic and fungicidal effects of the ionophores monensin and tetronasin on the rumen fungus Neocallimastix sp. LM1

The ionophore antibiotics monensin and tetronasin have been reported to inhibit anaerobic fungi in vitro, and are suitable for animal use. In this study, their effectiveness in removing the anaerobic fungus Neocallimastix sp. LM1 from the rumen was investigated in vitro. Both antibiotics were fungistatic: tetronasin at 0.5 microgram/ml and monensin at 1.0 microgram/ml; exposure for 24 h did not inhibit subsequent growth after removal of the ionophore. The ionophores were fungicidal at much higher concentrations, 1 microgram/ml for tetronasin and 16 micrograms/ml for monensin. It seems likely that the combination of relatively high inhibitory dose and the fungistatic nature of monensin would explain difficulties in using this compound to eliminate anaerobic fungi from the rumens of experimental animals.     

Antifungal and fungicidal activities of tea extract and catechin against Trichophyton

We examined tea extract, (-) epigallocatechin gallate (EGCg) and theaflavin digallate (TF3) for their antifungal and fungicidal activities against Trichophyton mentagrophytes, T. rubrum, Candida albicans and Cryptococcus neoformans. Tea extract (2.5%) inhibited completely the growth of both T. mentagrophytes and T. rubrum. EGCg at 2.5 mg/ml failed to inhibit their growth, whereas TF3 at 0.5 mg/ml inhibited the growth. EGCg (1mg/ml) showed no fungicidal activity against Trichophyton. TF3 (1mg/ml) killed Trichophyton by a long time contact (72-96 hrs). Tea extract showed a fungicidal activity against Trichophyton in a dose- and contact time-dependent manner. It did not inhibit the growth of C. albicans, but at a high concentration, inhibited slightly the growth of C. neoformans. It had no fungicidal activity against C. albicans or C. neoformans.     

Expression of two distinct cytolytic mechanisms among murine CD4 subsets

A TNF (TNF-alpha and TNF-beta)-sensitive target, L929, and two TNF-resistant targets, P815 and LK were used to compare the cytolytic activity among subsets of CD4+ (Th) clones. Cytolytic activity was induced with either Con A, CD3-mAb, or Ag-pulsed LK cells. Six Th1 clones are strongly cytolytic against all three targets. In contrast, Th2 clones are either noncytolytic or weakly cytolytic. Although there is an apparent correlation between TNF production, killing of L929 cells, and the killing of TNF-resistant targets, an anti-TNF serum (capable of neutralizing both TNF-alpha and TNF-beta) selectively inhibits CD4 clones to lyse L929 cells, whereas the lysis of P815 or LK cells was unaffected. The continuous presence of noncytotoxic levels of Actinomycin D (AcD) and cycloheximide, but not mitomycin C, cyclosporin A (CsA), or cholera toxin (ChT) inhibits the lysis of Ag-pulsed, Ia-bearing LK cells; indicating a requirement for de novo synthesis of RNA and protein for cytolytic activity. Although pretreatment with AcD, CsA, or ChT strongly inhibits production of IL-2, TNF and IFN-gamma, only clones pretreated with AcD lose cytolytic activity against Ag-pulsed, Ia-bearing LK cells. These observations support a model of TNF-independent killing of TNF-resistant targets. The TNF-independent cytolytic activity does not correlate with serine esterase activity released into media upon activation of CD4 clones. Moreover, the effects of metabolic inhibitors on serine esterase release do not correlate with their effects on cytolytic activity. Collectively, the data demonstrate that activated CD4 cells express two distinct cytolytic activities; a TNF (and IFN-gamma)-mediated cytotoxicity and a TNF (and IFN-gamma)-independent cytolytic activity. Both pathways require de novo synthesis of RNA and protein and appear to be independent of granule enzyme release. Only the TNF-independent cytolytic activity is resistant to CsA and ChT inhibition.     

Macrophage activation to kill Leishmania tropica: characterization of a T cell-derived factor that suppresses lymphokine-induced intracellular destruction of amastigotes

Factors obtained from phorbol myristate acetate (PMA)-stimulated EL-4 thymoma cells, a continuous T cell line, suppressed lymphokine-induced macrophage activation to kill intracellular Leishmania tropica amastigotes. Suppression of this macrophage effector activity was dependent upon concentration of EL-4 fluids admixed with lymphokines in infected macrophage cultures, and was not due to residual PMA or factors released from unstimulated EL-4 cells. Fluids from PMA-stimulated EL-4 cells did not affect the expression of microbicidal activity by macrophages activated in vivo as a consequence of infections with Mycobacterium bovis strain BCG, nor did they abrogate intracellular killing activities by C3H/HeJ macrophages primed by BCG infection and triggered by lymphokines in vitro. That the action of this EL-4 suppressor activity was at the priming stage of macrophage activation was confirmed by kinetic studies: EL-4 fluids added to lymphokine-treated cells in the first 4 hr of treatment completely suppressed intracellular killing of L. tropica; fluids added after 4 hr were not effective. The effects of these EL-4 factors appeared to be selective: of three effector activities of activated macrophages tested, induction of resistance to infection, tumor cytotoxicity, and intracellular destruction of L. tropica, only intracellular killing by lymphokine-treated macrophages was significantly suppressed. These T cell-derived soluble suppressor factor(s) may provide insight into mechanisms of immunosuppression during leishmanial disease and perhaps other intracellular parasitic infections.     

Role of superoxide anion in the fungicidal activity of murine peritoneal exudate macrophages against Penicillium marneffei.

Penicillium marneffei is an important opportunistic fungal pathogen. The mechanisms of host defense against P. marneffei are not fully understood. In the present study, we, for the first time, investigated the role of superoxide anion (O2-) in the killing of two forms of P. marneffei, yeast cells and conidia, and the role of this killing mediator in the fungicidal activity of IFN-gamma-stimulated murine peritoneal macrophages. P. marneffei yeast cells were susceptible to the killing effect of activated macrophages and chemically generated O2, while conidia were not. These results suggested that O2- played some role in the fungicidal activity of macrophages. However, an oxygen radical scavenger, superoxide dismutase (SOD), did not suppress, but rather enhanced the fungicidal activity of IFN-gamma-stimulated macrophages against P. marneffei yeast cells. This inconsistency was explained by the release of insufficient concentrations of O2- by activated macrophages as compared with the amount of O2- necessary for the killing of yeast cells, which was predicted in a chemical generating system. On the other hand, SOD enhanced the production of nitric oxide (NO) by IFN-gamma-activated macrophages, and their increased fungicidal activity was significantly inhibited by N(G)-monomethyl-L-arginine (L-NMMA), a competitive inhibitor of NO synthase. Our results suggested that O2- does not function as the killing mediator of macrophages against P. marneffei, but rather plays an important role in the regulation of the NO-mediated killing system by suppressing NO production.