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.     

Macrophage activation to kill Leishmania major: activation of macrophages for intracellular destruction of amastigotes can be induced by both recombinant interferon-gamma and non-interferon lymphokines

Macrophages treated with lymphokine (LK)-rich culture fluids from antigen- or mitogen-stimulated spleen cells or the hybridoma T cell 24/G1, or murine recombinant interferon-gamma (IFN-gamma) from either transfected monkey kidney cells (cos rIFN-gamma) or bacterial (E. coli) DNA (rIFN-gamma) developed the capacity to kill intracellular amastigotes of Leishmania major. Removal of IFN activity from LK by neutralizing fluid phase monoclonal anti-rIFN-gamma antibody, or by solid phase immunoadsorption, left residual macrophage activation factors that induced approximately 50% of the macrophage anti-leishmanial activity of untreated LK. In contrast, rIFN-gamma subjected to the same antibody treatments lost all capacity to induce this macrophage effector function. These results suggest that the intracellular destruction of amastigotes is regulated by several different factors. One of these factors is clearly IFN-gamma, which is pleiotropic in its effects on macrophage functions. The other non-IFN LK factors are immunochemically unrelated to IFN-gamma, and may regulate macrophage microbicidal activities in a more selective manner.     

Macrophage activation to kill Leishmania tropica: characterization of P/J mouse macrophage defects for lymphokine-induced antimicrobial activities against Leishmania tropica amastigotes

Macrophages from P/J mice demonstrated both quantitative and qualitative defects in lymphokine (LK)-induced activated macrophage antileishmanial effector reactions: a) these cells recognized the same LK signals that generated resistance to infection in responsive C3H/HeN macrophages, but more signal was required to observe maximal activity; b) LK-induced intracellular destruction of Leishmania tropica by P/J macrophages was minimal (less than 20%), and was induced by only one of three LK signals that regulate antimicrobial activities in C3H/HeN macrophages. The defective microbicidal activity of P/J macrophages observed with LK activation in vitro could also be demonstrated in vivo. Macrophages from P/J mice exposed to the macrophage-activating agent Mycobacterium bovis strain BCG in vivo were capable of restricting the intracellular replication of L. tropica but could not eliminate intracellular parasites, even with further incubation with LK during the 72-hr culture period. The defect of P/J macrophages for intracellular destruction of L. tropica, then, occurred in the activation sequence before the triggering stage that characterizes the macrophage defect of C3H/HeJ mice. Genetic regulation of the P/J macrophage defect appears to be by a single autosomal gene, with defective microbicidal activity as a recessive trait in these animals.     

Human monocyte activation for cytotoxicity against intracellular Leishmania donovani amastigotes: induction of microbicidal activity by interferon-gamma

Macrophages are pivotal cells in interactions of man and leishmania. Leishmanial disease results from intracellular infection of macrophages: parasitized cells are seen in smears or biopsy specimens of lesions; macrophages cultured in vitro support replication of parasites. Paradoxically, parasite destruction is also mediated by macrophages, which become highly cytotoxic after exposure to immune lymphocytes or their lymphokine (LK) products. The precise molecular mechanisms by which lymphocytes or LK induce macrophage activation for leishmanicidal activity, however, are not yet known. We analyzed interactions of leishmania amastigotes with human monocytes cultured in vitro as a nonadherent cell pellet. Leishmania donovani and L. major replicated in freshly isolated monocytes. Monocytes treated with greater than 200 IU/ml of the LK, human Interferon-gamma (IFN-gamma), destroyed tumor cells and L. donovani, but not L. major. Phorbol myristate acetate, endotoxic bacterial lipopolysaccharide, and recombinant human IFN-alpha and IFN-beta did not induce cytotoxicity. The time course for induction of cytotoxicity contrasted sharply with that of previously described monocyte antileishmanial activity: IFN-gamma induced cytotoxicity even when added after infection with L. donovani; induction of cytotoxicity did not require that IFN-gamma be present throughout the period of culture after infection: a 30-min preinfection pulse of IFN-gamma was sufficient to induce 70% of maximal activity; and freshly isolated monocytes and cells cultured for up to 4 days in vitro prior to infection and IFN-gamma treatment were equally responsive to IFN-gamma. These studies provide convincing evidence for intracellular cytotoxicity for L. donovani by freshly isolated human monocytes. This system provides an important base for further analysis of induction and expression of cytotoxic mechanisms against leishmania and other intracellular organisms that cause human disease.     

Differential susceptibility of activated macrophage cytotoxic effector reactions to the suppressive effects of transforming growth factor-beta 1

We examined the effects of TGF-beta 1 on induction of several activated macrophage antimicrobial activities against the protozoan parasite Leishmania, and on induction of tumoricidal activity against the fibrosarcoma tumor target 1023. TGF-beta by itself did not affect the viability of either the intracellular or extracellular target in concentrations up to 200 ng/ml. As little as 1 ng/ml TGF-beta, however, suppressed more than 70% of the intracellular killing activity of macrophages treated with lymphokines. In contrast, more than 100 ng/ml TGF-beta was required to suppress intracellular killing by cells activated with an equivalent amount of recombinant IFN-gamma. Addition of TGF-beta for up to 30 min after exposure to activation factors significantly reduced macrophage killing of intracellular parasites. Pretreatment of macrophages with TGF-beta was even more effective: treatment of cells with TGF-beta for 4 h before addition of activation factors abolished all macrophage intracellular killing activity. Regardless of treatment sequence, however, TGF-beta had absolutely no effect, at any concentration tested, on activated macrophage resistance to infection induced by lymphokines or by the cooperative interaction of IFN-gamma and IL-4. Effects of TGF-beta on tumoricidal activity of activated macrophages was intermediate to that of its effects on intracellular killing or resistance to infection. Lymphokine-induced tumor cytotoxicity was marginally (25%) affected by TGF-beta; 200 ng/ml was able to suppress IFN-gamma-induced tumoricidal activity by 40%. Thus, TGF-beta dramatically suppressed certain activated macrophage cytotoxic effector reactions, but was only partially or not at all effective against others, even when the same activation agent (IFN-gamma) was used. The biochemical target for TGF-beta suppressive activity in these reactions may be the pathway for nitric oxide production from L-arginine, because TGF-beta also inhibited the generation of nitric oxide by cytokine-activated macrophages.     

A lymphokine distinct from interferon-gamma that activates human monocytes to kill Leishmania donovani in vitro

Human interferon-gamma (IFN-gamma), a T cell lymphokine (LK), activates monocytes to kill many intra- and extracellular pathogens. In fact, previous reports assert that all activity in LK for macrophage activation is due to IFN-gamma. To test this assertion, we examined monocyte interactions with amastigotes of Leishmania donovani after treatment with recombinant DNA or affinity-purified leukocyte IFN-gamma and IFN-gamma containing LK. Cells treated with at least 200 IU/ml IFN-gamma were microbicidal for L. donovani. Analysis of IFN-gamma dose responses for induction of microbicidal activity by recombinant IFN-gamma (r-IFN-gamma) and LK, however, documented a striking difference: LK was 25-fold more efficient than r-IFN-gamma at equivalent IFN-gamma titers. This large difference suggested that monocyte activation factor(s) in LK may not be IFN-gamma. Rabbit anti-IFN-gamma completely inhibited antiviral activity in LK but did not abrogate the ability to induce monocyte cytotoxicity against leishmania. Furthermore, removal of IFN-gamma from LK by monoclonal anti-IFN-gamma affinity chromatography or by treatment with anti-IFN-gamma followed by staphylococcal protein A chromatography also did not inhibit LK activity. Fractionation of LK on Sephadex G-100 revealed two activity peaks: one in the 50,000 to 60,000 m.w. range coincident with IFN-gamma, and the other at 25,000 to 30,000 daltons with no IFN-gamma. These studies document LK physicochemically and antigenically distinct from IFN-gamma that activate monocytes to kill L. donovani. Such novel factors may have broad import for the study of macrophage-mediated host defenses and for development of immunotherapeutic regimens.     

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.     

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.     

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.     

Interferon-gamma modulates protein kinase C activity in murine peritoneal macrophages

The content of Ca2+-, phospholipid-dependent protein kinase activity (protein kinase C) in murine peritoneal macrophages treated with recombinant interferon-gamma (IFN-gamma) has been investigated. Protein kinase C activity was solubilized by nonionic detergent extraction of sonicated cells and separated by high performance liquid chromatography on a TSK 4000 SW gel filtration column. The enzyme eluted from the column in a molecular weight range of 60-80 X 10(3) and was identified by virtue of Ca2+ and phospholipid requirements. Macrophages treated with recombinant IFN-gamma exhibited a substantial increase in total protein kinase activity which could be accounted for entirely by increased protein kinase C activity. This activity was enhanced as much as 5-fold over that seen in untreated macrophages and was specific for IFN-gamma in that other agents known to signal changes in macrophage function had no effect. The time required for the elevation of kinase activity was identical to that required for induction of other functions by IFN-gamma in macrophages. These observations suggest that protein kinase C may be a focus of regulatory action in IFN-gamma-mediated macrophage activation.     

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.     

Role of protein kinase C and intracellular calcium mobilization in the induction of macrophage tumoricidal activity by interferon-gamma

These studies were designed to test the hypothesis that changes in intracellular Ca2+ levels and activation of the calcium ion- and phospholipid-dependent protein kinase C were required for the induction of macrophage tumoricidal activity by interferon-gamma (IFN-gamma). Phenothiazines and R24571, known antagonists of calcium-binding proteins and therefore nonspecific inhibitors of protein kinase C, blocked in a dose-dependent manner the induction of macrophage cytocidal activity by either natural or recombinant IFN-gamma. Macrophages depleted of intracellular Ca2+ by chelation with Quin 2, were also unresponsive to IFN-gamma. These treatments effected neither the binding of IFN-gamma to its cell surface receptor nor the normal intracellular processing of IFN-gamma. Activators of protein kinase C (such as phorbol esters) and Ca2+ ionophores when added alone did not effect the activation state of the macrophage population. However, macrophages exposed to both drugs in combination were elevated into the primed activation state such that in the presence of a second signal (lipopolysaccharide or heat killed Listeria monocytogenes), the cells were triggered to express full levels of tumoricidal activity. The capacity of phorbol esters to induce cellular activation correlated with their ability to bind and to activate protein kinase C. No synergistic effect was observed between IFN-gamma and protein kinase C activators and/or Ca2+ ionophores, indicating that the drugs could only prime and could not trigger macrophages for tumor cell killing. These results thus support the concept that protein kinase C activation and mobilization of intracellular Ca2+ are essential steps in the pathway of IFN-gamma-dependent induction of non-specific tumoricidal activity in macrophages.     

Components of the protein kinase C pathway induce Ia expression after injection into macrophages.

Macrophages are activated by a variety of microbial and cytokine stimuli. One feature of activation is the induction of class II Ag (Ia) on the cell surface. To understand the intracellular events that occur during activation, we investigated various agents with intracellular activities, and examined their effects on the induction of Ia. We first noted that several agents that activate protein kinase C (PKC) induced Ia, and that several inhibitors of PKC inhibited Ia induction by IFN-gamma. To directly test whether PKC induced Ia, we microinjected normal peritoneal macrophages with this enzyme and other intracellular mediators, then examined Ia expression. We observed that injection of PKC itself, or of other intracellular proteins thought to participate in the PKC pathway (Ras or phospholipase C gamma) strongly induced Ia expression. The Ia-inducing activity of transforming Ras protein was blocked by kinase inhibitor treatment of cells, suggesting that Ras signal transduction requires kinase activity. On the other hand, components of the protein kinase A pathway (phospholipase A2 and protein kinase A itself) did not induce Ia. Thus, the PKC pathway can control expression of macrophage surface Ia, possibly by regulating the genes of the MHC, and may play many other roles in the activation of macrophages.     

Leishmania major amastigotes initiate the L-arginine-dependent killing mechanism in IFN-gamma-stimulated macrophages by induction of tumor necrosis factor-alpha

Macrophages exposed to IFN-gamma and infected with amastigotes of Leishmania major develop the capacity to eliminate the intracellular pathogen. This antimicrobial activity of activated macrophages correlates with the initiation of nitrogen oxidation of L-arginine, yet other reports suggest that two signals are required for induction of this biochemical pathway for effector activity. In the present studies, macrophages treated with up to 100 U/ml IFN-gamma, or 100 ng LPS, or 10(7) amastigotes produced minimal quantities (less than 9 microM) of NO2- and failed to develop cytotoxic effector activities. In contrast, the combination of IFN-gamma and either LPS (greater than 0.1 ng) or amastigotes (10(6) induced high concentrations (much greater than 30 microM) of NO2- and macrophage cytotoxicity against intra- and extracellular targets. The induction of nitrogen oxidation by amastigotes could be dissociated from LPS-induced events by 1) performing the assays in the presence of polymyxin B (which blocked LPS effects, but not amastigote effects), 2) determining the threshold of IFN-gamma required to prime cells for subsequent trigger (1 U/ml for LPS trigger effects; 10-fold higher for amastigotes), and 3) determining the heat sensitivity of the two trigger agents (amastigote effects abolished at 100 degrees C; LPS effects unaffected at this temperature). Further, culture fluids from amastigote-infected macrophages did not contain detectable LPS (less than 6 pg/ml). Possible parasite and cell-associated factors that could contribute to the induction of nitrogen oxidation and cytotoxic activity of IFN-gamma treated macrophages were examined: only certain intact microorganisms, LPS from a variety of bacteria, and the cytokine TNF alpha were effective. Both NO2- production and intracellular killing were abolished by the addition of anti-TNF-alpha mAb in the assay. TNF-alpha was produced by amastigote-infected macrophages and IFN-gamma dramatically enhanced secretion of this cytokine; IFN-gamma alone had no effect. Endogenous TNF-alpha produced during infection of macrophages with L. major acted in an autocrine fashion to trigger the production of L-arginine-derived toxic nitrogen intermediates that killed the intracellular parasites.     

Kinetics and requirements for activation of macrophages for fungicidal activity: effect of protein synthesis inhibitors and immunosuppressants on activation and fungicidal mechanism.

Peritoneal-and pulmonary macrophages can be activated in vitro with lymphokines (LK) or IFN-gamma, without exogenous lipopolysaccharide, for fungicidal activity against several pathogenic fungi. However, neither the biochemical nor metabolic events of the activation process or of the effector phase have been defined. In the present work we sought to elucidate these events with time-course studies using inhibitors of protein synthesis as well as immunosuppressive agents. We found that protein synthesis inhibitors abrogated the activation process, because cycloheximide (CHX) (1-2 micrograms/ml) prevented activation of macrophages for fungicidal activity against Candida albicans, Blastomyces dermatitidis, and Paracoccidioides brasiliensis. Blocking of the activation process by CHX was not due to macrophage cytotoxicity, and CHX did not impair the ability of nonactivated macrophages to kill Candida parapsilosis. In kinetic studies we showed that activation of macrophages was induced in 4 hr of LK treatment and that CHX had no effect if added after this time. In contrast to CHX, therapeutic concentrations of hydrocortisone (HC), such as less than or equal to 5 micrograms/ml, or cyclosporin A (CsA), 5 micrograms/ml, did not significantly inhibit LK activation of macrophages for killing of fungi. In the effector phase, the fungicidal capacity of activated macrophages in short-term (less than or equal to 4 hr) killing assays could not be abrogated by CHX (5 micrograms/ml), HC (100 micrograms/ml), or CsA (10 micrograms/ml). These results demonstrate that the activation but not the effector mechanism of macrophages for fungicidal activity is blocked by inhibition of protein synthesis. In contrast, therapeutic concentrations of HC or CsA may not interfere with activation of macrophages or their killing mechanisms, thus providing a rationale for antifungal immunotherapy in certain clinical situations (e.g., infection in the immunosuppressed patient).     

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.     

IFN-gamma-dependent nitric oxide production is not linked to resistance in experimental African trypanosomiasis

Resistance to African trypanosomes is dependent on B cell and Th1 cell responses to the variant surface glycoprotein (VSG). While B cell responses to VSG control levels of parasitemia, the cytokine responses of Th1 cells to VSG appear to be linked to the control of parasites in extravascular tissues. We have recently shown that IFN-gamma knockout (IFN-gamma KO) mice are highly susceptible to infection and have reduced levels of macrophage activation compared to the wild-type C57BL/6 (WT) parent strain, even though parasitemias were controlled by VSG-specific antibody responses in both strains. In the present work, we examine the role of IFN-gamma in the induction of nitric oxide (NO) production and host resistance and in the development of suppressor macrophage activity in mice infected with Trypanosoma brucei rhodesiense. In contrast to WT mice, susceptible IFN-gamma KO mice did not produce NO during infection and did not develop suppressor macrophage activity, suggesting that NO might be linked to resistance but that suppressor cell activity was not associated with resistance or susceptibility to trypanosome infection. To further examine the consequence of inducible NO production in infection, we monitored survival, parasitemia, and Th cell cytokine production in iNOS KO mice. While survival times and parasitemia of iNOS KO mice did not differ significantly from WT mice, VSG-specific Th1 cells from iNOS KO mice produced higher levels of IFN-gamma and IL-2 than cells from WT mice. Together, these results show for the first time that inducible NO production is not the central defect associated with susceptibility of IFN-gamma KO mice to African trypanosomes, that IFNgamma-induced factors other than iNOS may be important for resistance to the trypanosomes, and that suppressor macrophage activity is not linked to either the resistance or the susceptibility phenotypes.     

Defective vaccine-induced immunity to Schistosoma mansoni in P strain mice. II. Analysis of cellular responses

Cellular immune responses against larval and adult schistosome antigens were studied in attenuated cercariae-vaccinated P and C57BL/6 mice to define differences correlating with the inability of P mice to develop vaccine-induced resistance to challenge Schistosoma mansoni infection. Vaccinated P mice failed to demonstrate delayed hypersensitivity upon skin-testing with soluble worm antigens, whereas mice of the highly resistant strain C57BL/6 developed a significant 24-hr response to worm antigens in vivo. Also, when schistosome antigens were injected i.p., vaccinated P mice failed to exhibit an activated macrophage response in vivo, whereas vaccinated C57BL/6 mice developed macrophages with significant larvicidal and tumoricidal activity at the site of specific antigen challenge. Immune sera from either vaccinated C57BL/6 or P mice were equally effective at opsonizing the schistosomula targets in the larvicidal assay. In vitro analyses of cellular defects revealed that although T lymphocytes from vaccinated P mice showed blastogenic responses to schistosome antigens that were similar in magnitude and kinetics to those of cells from the C57BL/6 animals, T cells from C57BL/6 mice produced higher levels of macrophage-activating lymphokines (LK), including gamma-interferon. Macrophages from control C57BL/6 mice were also more responsive to activation by LK than macrophages from P mice were, as assessed by stimulation of these cells to kill skin-stage schistosomula in vitro. These two aspects of cellular dysfunction in P mice had the combined effect of rendering P macrophages incapable of activation by LK from mice of their own strain, whereas macrophages from C57BL/6 mice were strongly activated by LK from vaccinated C57BL/6 mice in the same assays. Thus, a correlation exists between T lymphocyte/macrophage dysfunction and lack of resistance to challenge infection in vaccinated P mice, which suggests that delayed hypersensitivity response plays a major role in the immunity to S. mansoni infection that is induced by exposure to radiation-attenuated cercariae.     

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.