Gamma interferon-induced inhibition of Toxoplasma gondii in astrocytes is mediated by IGTP

Toxoplasma gondii is an important pathogen in the central nervous system, causing a severe and often fatal encephalitis in patients with AIDS. Gamma interferon (IFN-gamma) is the main cytokine preventing reactivation of Toxoplasma encephalitis in the brain. Microglia are important IFN-gamma-activated effector cells controlling the growth of T. gondii in the brain via a nitric oxide (NO)-mediated mechanism. IFN-gamma can also activate astrocytes to inhibit the growth of T. gondii. Previous studies found that the mechanism in murine astrocytes is independent of NO and all other known anti-Toxoplasma mechanisms. In this study we investigated the role of IGTP, a recently identified IFN-gamma-regulated gene, in IFN-gamma inhibition of T. gondii in murine astrocytes. Primary astrocytes were cultivated from IGTP-deficient mice, treated with IFN-gamma, and then tested for anti-Toxoplasma activity. In wild-type astrocytes T. gondii growth was significantly inhibited by IFN-gamma, whereas in astrocytes from IGTP-deficient mice IFN-gamma did not cause a significant inhibition of growth. Immunoblot analysis confirmed that IFN-gamma induced significant levels of IGTP in wild-type murine astrocytes within 24 h. These results indicate that IGTP plays a central role in the IFN-gamma-induced inhibition of T. gondii in murine astrocytes.     

Murine gamma interferon fails to inhibit Toxoplasma gondii growth in murine fibroblasts.

Although treatment of human macrophages or fibroblasts with human gamma interferon results in the inhibition of intracellular Toxoplasma gondii, murine gamma interferon stimulated only murine macrophages, not murine fibroblasts, to inhibit T. gondii. This species difference may be important in understanding the control of acute and chronic toxoplasmosis.     

Dendritic cells as effector cells: gamma interferon activation of murine dendritic cells triggers oxygen-dependent inhibition of Toxoplasma gondii replication

Toxoplasma gondii is an obligate intracellular parasite that infects a wide variety of nucleated cells in its numerous intermediate hosts, including humans. Much interest has focused on the ability of gamma interferon (IFN-gamma)-activated macrophages to prevent intracellular replication, but some other cells (e.g., fibroblasts, endothelial cells, microglial cells, astrocytes, enterocytes and retinal pigment cells) can also be activated to induce this inhibition of proliferation. Dendritic cells are generally known to be involved in the induction of immune responses, but no previous study had investigated the possibility that dendritic cells may act as effector cells of this system. Our results show that IFN-gamma-activation inhibits the replication of T. gondii in dendritic cells, with the inhibition being dose dependent. Neither nitrogen derivatives nor tryptophan starvation appears to be involved in the inhibition of parasite replication by IFN-gamma. Experiments with oxygen scavengers indicate that intracellular T. gondii replication is oxygen dependent. Our findings suggest that, in addition to their essential role in stimulating the immune system, dendritic cells probably act as effector cells in the first line of defense against pathogen invasion.     

Cryopreservation of Toxoplasma gondii in infected murine tissues

Laboratory maintenance of the RH strain of Toxoplasma gondii is generally done by passage in mice, in vitro propagation in fibroblasts, or cryopreservation of peritoneal exudates from mice infected with T. gondii. To explore alternative techniques for preserving laboratory T. gondii tachyzoites, we propose a new method of freezing tissues from infected mice. The effect of storage of T. gondii tissue tachyzoites in two different cryoprotectant combinations and at two different temperatures was studied. The liver and spleen tissues, and peritoneal exudates from mice infected with RH-GFP strain of T. gondii, suspended in RPMI 1640 medium supplemented with 12 % glycerol plus 20 % calf serum, or 12 % dimethyl sulfoxide (DMSO) plus 20 % calf serum, were stored for 3 months at ?20 °C in an ordinary refrigerator or at ?80 °C in a deep freezer, respectively. The viability of tissue T. gondii tachyzoites was determined by animal inoculation method, which was assessed by monitoring survival and tissue parasitemia in recipient mice. Our data showed that toxoplasma tachyzoites in the above tissues remained viable after cryopreservation in 12 % DMSO plus 20 % calf serum at ?80 °C, the infectivity of tachyzoites from the tissues and peritoneal fluids was demonstrated in inoculated murine tissues. Our data indicate that freezing infected murine tissues at ?80 °C provides a simple and appropriate method for preservation of T. gondii tachyzoites in laboratory without the need for costly liquid nitrogen preservation procedures.     

Human platelet inhibition of Toxoplasma gondii growth

The human platelet contribution against the intracellular growth of the parasite in vitro in human pulmonary fibroblasts was explored. It was observed that tachyzoites of Toxoplasma gondii induced activation of human platelets and additionally that platelets mediated inhibition of intracellular growth in a virulent T. gondii strain. A prominent role for platelet-derived growth factor (PDGF) was demonstrated in this phenomenon, by testing human recombinant PDGF-AA, -AB and -BB and antibodies to human PDGF-AB that partially reversed its effects. Moreover, the effect of PDGF was significantly higher if the host cells were treated 2 h before parasite infection. PDGF was not directly ‘toxic’ to free tachyzoites, but only affected parasites within host cells. PDGF-mediated inhibition may involve the cyclooxygenase cycle of the fibroblasts being partially reversed by the cyclooxygenase inhibitors, acetylsalicylic acid and indomethacin. However, a thromboxane synthetase pathway was not implicated. PDGF action against intracellular tachyzoites may also include increased IL-6 production in fibroblasts. Finally, transforming growth factor-beta 1 (TGF-β1), another component of α-granules released at the same time as PDGF, may not be antagonistic to the PDGF parasite inhibitory effect in confluent host cells.     

Iron limitation and the gamma interferon-mediated antihistoplasma state of murine macrophages.

The zoopathogenic fungus Histoplasma capsulatum requires iron for growth. Intracellular growth of the fungus within mouse peritoneal macrophages is inhibited by recombinant murine gamma interferon (IFN-gamma). Such treatment of mouse peritoneal macrophages induces a marked downshift in transferrin receptors. We tested whether the antihistoplasma effect of IFN-gamma-treated macrophages is the result of iron deprivation. Treatment of mouse peritoneal macrophages with the intracellular iron chelator deferoxamine inhibits the intracellular growth of H. capsulatum. Exposure of macrophages to holotransferrin antagonizes the effect of both recombinant murine IFN-gamma and deferoxamine treatments. These results suggest that iron restriction may be one of the bases for the IFN-gamma-induced antihistoplasma effect of mouse macrophages.     

Tryptophan depletion as a mechanism of gamma interferon-mediated chlamydial persistence.

Previous studies have shown that the immune-regulated cytokine gamma interferon (IFN-gamma) activates host cells to restrict intracellular growth of the bacterial pathogen Chlamydia trachomatis by induction of the tryptophan-catabolizing enzyme indoleamine 2,3-dioxygenase (IDO). Recently, subinhibitory levels of IFN-gamma were used to generate an in vitro persistent chlamydial infection characterized by large aberrant, noninfectious reticulate bodies from which infectious progeny could be recovered following the removal of IFN-gamma. Studies were done to determine if the mechanism functioning to induce chlamydiae to enter a persistent state in the presence of low levels of IFN-gamma was similar to that reported to inhibit chlamydial growth. Host cells treated with levels of IFN-gamma required to induce persistence were assessed for IDO activity by high-performance liquid chromatography analysis of tryptophan and its catabolic products. Substantial tryptophan catabolism was detected in acid-soluble cellular pools, indicating that the intracellular availability of this essential amino acid was limited under these conditions. In addition, a mutant cell line responsive to IFN-gamma but deficient in IDO activity was shown to support C. trachomatis growth, but aberrant organisms were not induced in response to IFN-gamma treatment. Analyses of infected cells cultured in medium with incremental levels of exogenous tryptophan indicated that persistent growth was induced by reducing the amount of this essential amino acid. These studies confirmed that nutrient deprivation by IDO-mediated tryptophan catabolism was the mechanism by which IFN-gamma mediates persistent growth of C. trachomatis.     

Genetic control of murine resistance to Toxoplasma gondii.

The genetics of murine susceptibility to Toxoplasma gondii was investigated in inbred mice and their F1 and F2 offspring. Among four strains of congenic mice of the B10 background, those with H-2a/a and H-2b/b genotypes were more susceptible than were those with H-2d/d and H-2k/k genotypes. Breeding studies utilizing three of these strains demonstrated linkage between the H-2a allele and greater susceptibility. These data suggest the existence of an H-2-linked gene affecting susceptibility to T. gondii. In challenge of recombinant inbred mice derived from C57Bl/6J (high susceptibility) and BALB/c (low susceptibility) strains, lines BE, BJ, and BK were more susceptible than lines BD, BG, BH, and BI. These data are consistent with the existence of a second disease susceptibility gene linked to the H-13 locus. F1 offspring of the C57B1/6J X B10.D2 mice were significantly less susceptible than either parent. This phenotypic complementary suggests the presence of more than one genetic mechanism of resistance to T. gondii. From these combined data, we conclude that (i) susceptibility to T. gondii in mice is affected by at least two genes, (ii) one of the genes is linked to the H-2 and one to the H-13 locus, and (iii) more than a single mechanism of resistance must be considered to explain the observed genetic controls of susceptibility.     

Induction of bradyzoite-specific Toxoplasma gondii antigens in gamma interferon-treated mouse macrophages.

By using stage-specific monoclonal antibodies, an in vitro model has been developed to analyze the kinetics of expression of stage-specific antigens during the conversion process between tachyzoites and bradyzoites of Toxoplasma gondii. Following infection of murine macrophages with bradyzoites, the expression of bradyzoite-specific antigens declined, whereas the expression of tachyzoite-specific antigens increased during the first 72 h postinfection. Conversely, in gamma interferon-treated murine macrophages infected with tachyzoites, the inhibitory effect of gamma interferon on replication of parasites was accompanied by the induction of bradyzoite-specific antigens.     

小鼠淋巴细胞体外抗弓形虫作用的实验研究

目的：了解小鼠淋巴细胞体外抗御弓形虫速殖子的效果。方法：采用大鼠脾细胞培养技术，以乙酰螺旋霉素作为阳性对照，观察淋巴细胞本身以及加入扁桃酸(MA)后，对虫体侵入淋巴细胞及在淋巴细胞内增殖的影响。结果：与其他体细胞相比较，淋巴细胞在受到弓形虫侵害时，仍可抑制和杀灭弓形虫。当存在免疫作用的情况下，安全剂量的MA抑制弓形虫侵入的作用不显著，但抑制细胞内弓形虫增殖的作用显著。结论：以细胞介导的免疫作用是宿丰抗弓形虫感染的重要因素，因此，应注重提高机体的细胞免疫，同时加用药物，以增强机体抗虫的效果。     

CD40 restrains in vivo growth of Toxoplasma gondii independently of gamma interferon

CD40-CD154 interaction is pivotal for resistance against numerous pathogens. However, it is not known if this pathway can also enhance in vivo resistance in gamma interferon (IFN-gamma)-deficient hosts. This is an important question because patients and mice with defects in type 1 cytokine response can control a variety of pathogens. While blockade of endogenous CD154 resulted in a remarkable increase in parasite load in IFN-gamma-/- mice infected with Toxoplasma gondii, in vivo administration of a stimulatory anti-CD40 monoclonal antibody markedly reduced parasite load. This latter effect took place even in T-cell-depleted mice and was accompanied by induction of macrophage toxoplasmacidal activity. CD40 stimulation restricted T. gondii replication independently of STAT1, p47 GTPases, and nitric oxide. In vivo CD40 ligation enhanced tumor necrosis factor alpha (TNF-alpha) production by T. gondii-infected macrophages. In addition, CD40 stimulation required the presence of TNF receptor 2 to reduce parasite load in vivo. These results suggest that CD40-CD154 interaction regulates IFN-gamma-independent mechanisms of host protection through induction of macrophage antimicrobial activity and modulation of TNF-alpha signaling.     

Autophagy activated by Toxoplasma gondii infection in turn facilitates Toxoplasma gondii proliferation

Autophagy was found to play an antimicrobial or antiparasitic role in the activation of host cells to defend against intracellular pathogens, at the same time, pathogens could compete with host cell and take advantage of autophagy to provide access for its proliferation, but there are few articles for studying the outcome of this competition between host cell and pathogens. Therefore, the aim of our study was to investigate the relationship between autophagy activated by Toxoplasma gondii (T. gondii) and proliferation of T. gondii affected by autophagy in vitro. Firstly, human embryonic fibroblasts (HEF) cells were infected with T. gondii for different times. The monodansylcadaverine (MDC) staining, acridine orange (AO) staining, punctuate GFP-LC3 distribution, and transmission electron microscopy (TEM) assays were conducted, and the results were consistent in showing that gondii infection could induce autophagy. Secondly, HEF cells were infected with T. gondii and treated with autophagy inhibitor bafilomycin A1 or inducer lithium chloride for different times. Giemsa staining was conducted, and the results exhibited that T. gondii infection-induced autophagy could in turn promote T. gondii proliferation. Simultaneously, the results of Giemsa staining also revealed that autophagy inhibitor could reduce the number of each cell infected with T. gondii and inhibit T. gondii proliferation. In contrast, autophagy inducer could increase the number of each cell infected with T. gondii and encourage T. gondii proliferation. Therefore, our study suggests that T. gondii infection could activate autophagy, and this autophagy could in turn facilitate T. gondii proliferation in HEF cells for limiting nutrients.     

Activation of rat alveolar macrophages by gamma interferon to inhibit Toxoplasma gondii in vitro

We have investigated the effects of murine interferons on the ability of rat alveolar macrophages (AM) to inhibit the proliferation of the intracellular protozoan Toxoplasma gondii. This activity was determined by measuring suppression of 3H-uracil uptake into the Toxoplasma and by microscopic enumeration of the intracellular organisms. Recombinant gamma interferon (rMulFN-gamma), but not alpha/beta interferon (IFN-alpha/beta) was able to activate AM for antimicrobial activity in vitro. Maximum activation was achieved by incubation with 50-200 units/ml rMulFN-gamma and the activity was lost at one unit/ml. The highest levels of activation were obtained when macrophages were incubated with interferon for 48-72 h prior to the challenge with Toxoplasma organisms. Activation could still be obtained, however, when the interferon was added to the cultures as late as 2 h after the phagocytosis of Toxoplasma. Neither MDP nor low concentrations (1-1-ng/ml) of S. typhosa lipopolysaccharide (LPS) were able to activate these cells to inhibit the growth of Toxoplasma. Phagocytosis of Toxoplasma by AM did not result in the release of O2-, in fact the spontaneous release of O2- by these cells was inhibited by Toxoplasma. This inhibition was reversed by preincubation of the cells with rMulFN-gamma.     

Immunology of Toxoplasma gondii

Toxoplasma gondii is an obligate intracellular parasite. Following oral infection the parasite crosses the intestinal epithelial barrier to disseminate throughout the body and establish latent infection in central nervous tissues. The clinical presentation ranges from asymptomatic to severe neurological disorders in immunocompromised individuals. Since the clinical presentation is diverse and depends, among other factors, on the immune status of the host, in the present review, we introduce parasitological, epidemiological, clinical, and molecular biological aspects of infection with T. gondii to set the stage for an in-depth discussion of host immune responses. Since immune responses in humans have not been investigated in detail the present review is exclusively referring to immune responses in experimental models of infection. Systemic and local immune responses in different models of infection are discussed, and a separate chapter introduces commonly used animal models of infection.     

Inhibition of growth of Toxoplasma gondii in cultured fibroblasts by human recombinant gamma interferon.

The growth of Toxoplasma gondii in cultured human fibroblasts was inhibited by recombinant human gamma interferon at concentrations of 8 to 16 U/ml. The interferon was titrated by observing a total inhibition of parasite plaque formation 7 days after infection. Inhibition of the growth of T. gondii in the early days after infection was measured by marked reductions in the incorporation of radioactive uracil, a precursor that can only be used by the parasites. This assay showed that when cells were pretreated with gamma interferon for 1 day and then infected, inhibition of T. gondii growth could be readily detected 1 or 2 days after infection. When the pretreatment was omitted and parasites and gamma interferon were added at the same time, no inhibition of parasite growth could be detected 1 day later, although it was apparent after 2 days. Cultures from which the gamma interferon had been removed by washing after a 1-day treatment showed inhibition of T. gondii growth. Gamma interferon had no effect on the viability of extracellular parasites, but it did inhibit the synthesis of host cell RNA and protein by ca. 50% 3 days after treatment. This degree of inhibition is unlikely, of itself, to compromise the growth of T. gondii. Recombinant alpha and beta interferons had no effect on the growth of T. gondii.     

Mycobacterial lipoarabinomannan inhibits gamma interferon-mediated activation of macrophages.

The principal efferent role of the macrophage in acquired resistance to intracellular pathogens depends on activation by T-cell lymphokines, primarily gamma interferon (IFN-gamma). However, mouse macrophages that are heavily burdened with Mycobacterium leprae are refractory to activation by IFN-gamma and are thus severely compromised in their capacity for both enhanced microbicidal and tumoricidal activities. We report here that lipoarabinomannan (LAM), a highly immunogenic lipopolysaccharide that is a prominent component of the cell walls of M. leprae and M. tuberculosis, was a potent inhibitor of IFN-gamma-mediated activation of mouse macrophages in vitro. Inhibition of macrophage activation by LAM required preincubation for approximately 24 h, resulting in uptake of LAM into cytoplasmic vacuoles of macrophages. Intact LAM was necessary to inhibit IFN-gamma-mediated activation, as this property was lost when the acyl side chains were removed from LAM by mild alkaline hydrolysis. In addition, LAM was an abundant constituent of macrophages isolated from lepromatous granulomas of M. leprae-infected nude mice and likely contributed to the defective activation of granuloma macrophages by IFN-gamma.     

Genomic drift of Toxoplasma gondii

 We review herein studies concerning the genomic polymorphism of Toxoplasma gondii including 3 clones (1 linked with mouse pathogenicity), 5 zymodemes, and 13 schizodemes. Because mutations occur with some frequency and several allelic configurations are present in isolates grown in the same environment, we conclude that many of the mutations may not be affected by selection pressure. However, the gametocyte-forming ability is under selection pressure from the host and depends on the development of bradyzoites in tissue cysts. After prolonged multiplication exclusively in the tachyzoite stage in mice and, possibly, in patients the gametocyte-forming ability may be lost. To avoid this genomic change, isolates should be passed in the laboratory, permitting bradyzoite and tissue-cyst formation. Mouse pathogenicity is selected for during mouse passage. We find no major genomic instability justifying species or subspecies distinctions. Received: 13 July 1996 / Accepted: 2 August 1996     

Characterization of gamma interferon-mediated cytotoxicity to chlamydia-infected fibroblasts.

Addition of murine recombinant gamma interferon (IFN-gamma) to mouse fibroblast cultures infected with Chlamydia psittaci was found to induce a cytotoxic response that was dependent on the concentration of IFN-gamma added and the multiplicity of infection given. No cytotoxicity was observed for uninfected cells treated with IFN-gamma, nor did infection alone elicit cytotoxicity. Cytotoxicity was detected only if IFN-gamma was present for at least the first 18 h of a 30-h incubation period. Cytotoxic activity was not observed when infected cells were treated with 50 micrograms of chloramphenicol per ml, a drug which inhibits differentiation of infectious elementary bodies to noninfectious reticulate bodies. Cytotoxic activity was restored if addition of chloramphenicol was delayed until 18 h postinfection. Addition of 100 U of penicillin per ml to infected host cells reduced but did not abolish cytotoxic activity. Treatment of host cells with as little as 0.2 microgram of cycloheximide per ml inhibited cytotoxicity without interfering with chlamydial growth. When addition of cycloheximide was delayed until 12 h after infection and IFN-gamma treatment, cytotoxicity was restored. These data indicate that IFN-gamma functions as a cytotoxic cytokine against chlamydia-infected fibroblasts. Cytotoxicity was found to be dependent on chlamydial multiplicity of infection, differentiation of chlamydiae to the metabolically active form, and host cell protein synthesis.