Cytokine-activated macrophages restrain the replication of intracellular parasites and disrupt the integrity of vacuolar pathogens. In this study, we show that inducible nitric oxide synthase and the immunity-related GTPase (IRG) family member Irgm3, respectively, are required for the ability of in vivo primed macrophages to restrain the growth of Toxoplasma gondii and to destroy the parasite’s intracellular niche. Remarkably, virulent Type I strains of T. gondii evade IRG-dependent vacuolar disruption, while remaining susceptible to iNOS-dependent restriction. The ability of virulent T. gondii to escape killing by macrophages is controlled at the level of the individual vacuole and is associated with differential permissiveness for association of the IRG proteins Irga6 (IIGP1) and Irgb6 (TGTP) to the vacuolar membrane. Surprisingly, expression of the Type I ROP-18 virulence determinant in an avirulent strain did not confer the evasive phenotype. These results pinpoint evasion of vacuolar disruption by IRG proteins as a new determinant of pathogen virulence.
Toxoplasma gondii is an obligate intracellular parasite that can invade and replicate in multiple cell types and cause infection and disease in diverse vertebrate species. Most healthy individuals infected by the parasite remain asymptomatic, because an efficient immune response can rapidly eliminate the acute tachyzoite stage of infection and provide immunosurveillance to maintain latent infection in organs where the encysted bradyzoite stage of the parasite persists. Considerable interest and effort has been focused on understanding the population structure and genetic basis of virulence in T. gondii (1, 2). Most Toxoplasma strains isolated in North America and Europe belong to three clonal lines referred to as: Type I, II, and III (3, 4). Type I strains are hypervirulent and infection with very low doses of tachyzoites causes death in immunocompetent mice. Type II and III strains cause nonlethal infections, characterized by the development of chronic latent infections of the CNS and skeletal muscles. Mice inoculated with low numbers of the hypervirulent Type I RH strain succumb to overwhelming parasite outgrowth and systemic overproduction of proinflammatory cytokines (5) and yet, the doubling time of Type I strains is not shorter than that of avirulent Type II and Type III strains (6). Thus, other biological features of Type I strains, including an altered expression program for latency-associated genes required for bradyzoite differentiation (4), increased migratory and invasive potential (7), and an enhanced ability to modulate and subvert the host cellular and immune responses have been invoked as potential virulence determinants for Toxoplasma.
Invasive Toxoplasma tachyzoites have been shown to modulate several aspects of the host immune response. Macrophages infected with the parasite have an impaired IL-12 and TNF-α cytokine response and a blockade in the translocation of NF-κB to the nucleus in response to TLR agonists (8). Remarkably, T. gondii infection of macrophages has been shown to induce phosphorylation of STAT-3, independently of the action of host cell derived IL-10 (9). Recently, a polymorphic parasite encoded serine-threonine kinase, ROP-16 from Type I and Type III strains has been shown to indirectly induce phosphorylation of STAT-3 and STAT-6 when expressed in a type II strain (10). The inability of Type II ROP-16 to induce prolonged STAT-3 phosphorylation may explain the more robust innate IL-12 response induced by type II parasites (11). T. gondii infection has also been shown to antagonize the induction of inducible nitric oxide synthase (NOS2)3 and MHC class II by IFN-γ (12). Transcriptional profiling of the effects of T. gondii on the gene expression response to IFN-γ in fibroblasts indicated a globally repressive effect of infection, through blockade of STAT-1 function in the nucleus and interference with STAT-1-induced expression of IFN regulatory factor 1, a transcriptional activator of many IFN-γ responsive genes (13). The ability of T. gondii to inhibit NF-κB and IFN regulatory factor 1 activation and STAT-1 function in response to immune agonists, coupled with its ROP-16 associated STAT-3/STAT-6 activating effect, would tend to favor dampening of the afferent arms of the innate and adaptive phase of the immune response. Recently, a patatin-like phospholipase of a Type II strain Toxoplasma has been shown to be essential for parasite survival and replication within IFN-γ-activated macrophages and for the suppression of macrophage NO production (14). Whether virulent and avirulent Toxoplasma strains differ in their abilities to evade and survive the onslaught of microbiostatic and microbicidal activities of already activated effector cells remains unknown. In this study, we report that virulent Type I strains of Toxoplasma are uniquely capable of resisting destruction of their intracellular vacuolar niche within fully armed effector macrophages that were elicited by in vivo priming.
Materials and Methods
Experimental animals, parasites, and macrophages
C57BL/6 and NOS2−/− mice were obtained from The Jackson Laboratory. These mice, along with immunity-related GTPase (IRG)m3−/− mice (15) and Irgm3/NOS2 double knockout mice (16) (both on the C57BL/6 background) were bred and maintained under specific pathogen-free conditions at the University of Medicine and Dentistry of New Jersey. The uracil auxotrophic CPS strain (17) of T. gondii was provided by D. Bzik (Dartmouth Medical School, Hanover, NH). CPS parasites were γ irradiated with 15,000 rads before use. Toxoplasma strains of GFP-PTG and GFP-RH were obtained from American Type Culture Collection. T. gondii Type I strain of GT-1, Type II strain of PE and Type III strains of CTG were obtained from L. David Sibley (Washington University, St. Louis, MO). Type 1 allele ROP-18-transgenic CTG strain (Type III) parasites have been described (18). The highly virulent V1 clone expressing Type 1 ROP-18 in a CTG background (CTG-ROP18 V1) was compared with the L1 mutant clone, which expresses a catalytically inactive form of ROP-18 (CTG-ROP18L1), and a control transformant of CTG containing the selectable marker (CTG-Ble). DsRed-RH was a gift of M.J. Gubbels (Department of Biology, Boston College, Boston, MA). For preparation of peritoneal exudate cells (PECs) including macrophages, mice were i.p. primed on days 0 and 4 with 1 × 106 irradiated CPS cells, respectively. PECs were harvested on day 7 by washing the peritoneum with 10 ml invasion medium (RPMI 1640 with 1% FBS) as previously described (19).
Ex vivo killing assay and GFP-PTG in vivo challenge
PECs were infected by GFP-PTG or GFP-RH in vitro at a multiplicity of infection of 1 in invasion medium. At 0, 13, and 26 h postinfection, cells were spun onto slides followed by fixation in methanol and staining in Hemacolor (Harleco) dye. Two hundred macrophages randomly selected from each slide were observed by light microscopy, and the numbers of total macrophages, infected macrophages, total vacuoles, and total parasites were counted. The replication of parasites was represented by the number of parasites per vacuole in infected macrophages at 0, 13, and 26 h postinfection. To measure relative resistance to T. gondii infection in vivo, mice were i.p. primed on day 0 with 1 × 106 irradiated CPS parasites and boosted on day 4 with 1 × 105 irradiated CPS. On day 7, 2.5 × 105 freshly prepared GFP-PTG were injected into peritoneum of mice. Percent survival mice were monitored for a total 16 days postchallenge. The number of mice used in each group is indicated in the figure legends.
Immunofluorescence and ultrastructural microscopy assays
For ex vivo infection, PECs were allowed to adhere onto coverslips for 2 h, and nonadherent cells were washed away with PBS. After incubation for 15 min with different T. gondii strains (as indicated in the figure legend) in invasion medium at 37°C, adherent macrophages were washed extensively with PBS to remove extracellular parasites. Infected macrophages were incubated in RPMI 1640 medium with 1% FBS at 37°C until being processed at different time points for immunofluorescent staining. Infected macrophages were washed with PBS twice before fixation with 4% formaldehyde (EMS) for 15 min at room temperature. After permeabilization (0.2% saponin in PBS for 10 min) and blocking (3% BSA, 0.1% saponin in PBS for 1 h), cells were incubated with rabbit anti-GRA-7 Ab (gift of Isabelle Coppens, John Hopkins University, Baltimore, MD), goat anti-Irgb6 (A20, Santa Cruz Biotechnology) and mouse anti-Irga6 5D9 (20) or rabbit anti-Irga6 165 (21T. gondii-infected macrophages were fixed in fixative (3% glutaraldehyde in 0.1 M sodium cacodylate buffer with 3% sucrose (pH 7.2)) and processed and imaged at John Radcliffe Hospital, Oxford, U.K.
Dissociation of toxoplasmacidal and toxoplasmastatic activities of primed macrophages
Mice lacking either Irgm3 (IGTP) or NOS2 exhibit enhanced susceptibility to T. gondii infection and their cytokine-activated macrophages have impaired resistance to Toxoplasma infection in vitro (15, 16, 22). However, the distinctive roles of Irgm3 and NOS2 in restricting parasite replication vs causing parasite death or immune elimination have not been clearly delineated. We therefore compared the toxoplasmacidal and toxoplasmastatic activities of primed macrophages derived from IGTP−/− or NOS2−/− mice to those from wild-type (WT) C57BL/6 mice. Toxoplasmastatic activity was defined as the ability of in vivo primed macrophages to restrict the replication of T. gondii tachyzoites within individual vacuoles while toxoplasmacidal activity was assayed by the ability of primed cells to eliminate vacuolar parasites. As a source of fully armed effector macrophages, we used adherent peritoneal cells harvested from mice immunized with the carbamoyl phosphate synthetase II (CPS)-deficient uracil auxotrophic strain of T. gondii and used avirulent GFP-tagged PTG strain tachyzoites for ex vivo challenge infection (16). We have previously shown that macrophages from these CPS-primed mice express very high levels of Irgm3 and NOS2 and are primed to resist T. gondii (a Type II GFP-PTG strain) infection in vivo and ex vivo. Consistent with previous reports, both NOS2−/− and Irgm3−/− cells show impaired resistance to Toxoplasma infection compared with WT control primed macrophages (Fig. 1⇓A), which showed a decrease in the number of parasite-infected cells over time. However, the underlying defects are mechanistically distinct. Although NOS2−/− macrophages can decrease the frequency of infected cells, they were inefficient in inhibiting intracellular tachyzoite multiplication, as measured by the average number of tachyzoites per parasitophorous vacuole (Fig. 1⇓B). In contrast, Irgm3−/− cells were clearly capable of restricting Toxoplasma replication but were ineffective in causing parasite elimination (Fig. 1⇓C). These results indicate separable roles for NOS2 in restricting parasite growth and for Irgm3 in parasite destruction by primed macrophages. As expected, a deficiency in both enzymes resulted in enhanced permissiveness of primed macrophages to ex vivo infection (Fig. 1⇓A) and rapid death of mice following in vivo infection with avirulent Type II strain T. gondii (Fig. 1⇓D). Interestingly, parasite replication in Irgm3−/−NOS2−/− cells was greater than in NOS2−/− macrophages (see Fig. 1⇓B), suggesting that Irgm3 may also exert or facilitate a toxoplasmastatic effect, in addition to its potent toxoplasmacidal function.
Virulent T. gondii strains resist primed macrophage-mediated destruction
To investigate whether virulent strains of T. gondii could resist the immune mechanisms deployed by in vivo activated macrophages, we compared the fate of virulent GFP-RH (Type I) strain vs avirulent (Type II) GFP-PTG within primed WT macrophages that were primed in vivo by CPS-vaccination and then tested ex vivo. Virulent RH and avirulent PTG parasites were equally sensitive to the NOS2-dependent toxoplasmastatic activity of macrophages (Fig. 2⇓A, middle). Remarkably, we observed that RH parasites were completely refractory to the Irgm3-dependent elimination activity of CPS-primed macrophages (Fig. 2⇓A, left). Thus, the virulent RH strain of Toxoplasma can resist immune destruction while remaining sensitive to NO-mediated cytostasis. To further investigate whether resistance to macrophage killing is a hallmark of virulence in Toxoplasma, we extended our analysis to additional virulent Type I as well as avirulent Type II and Type III strains. As shown in Fig. 2⇓A (right), only virulent Type I strains, but not avirulent Type II or Type III strains exhibited the ability to resist elimination by highly primed macrophages elicited in vivo by CPS vaccination.
Fate of parasitophorous vacuoles formed by virulent Toxoplasma
Previous studies in astrocytes and macrophages infected with avirulent Toxoplasma strains have shown that immune GTPases mediate vesiculation of the T. gondii parasitophorous vacuole membrane, resulting in the exposure of disrupted parasites to the host cytosol (16, 23, 24). In primed macrophages, large double-membraned autophagosomes were also observed that delivered parasite corpses to a pathway involving lysosomal destruction (16), although this phenomenon was not observed in macrophages activated in vitro (25). To investigate the point at which virulent RH parasites thwarted the IRG-dependent toxoplasmacidal process, we performed electron microscopy analyses of virulent RH and avirulent PTG profiles found within primed macrophages at 1 h and 4 h following ex vivo infection. We classified parasite profiles into three broad categories: those with intact parasitophorous vacuole membranes (PVM), those with disrupted PVM but intact parasite plasma membrane, and those with naked and degraded parasites with breached plasma membranes. Consistent with our previous report (16), avirulent PTG parasites invade primed macrophages but were rapidly subjected to vacuolar membrane disruption, with only 20% remaining within intact vacuoles 1 h post infection (Fig. 2⇑B, left). The fraction of intracellular PTG parasites exhibiting a moribund or disrupted profile, as expected, increased at 4 h post infection. In contrast, ultrastructural examination of invaded virulent RH strain parasites reveal that nearly all parasites established and persisted as normal parasites within intact vacuoles (Fig. 2⇑B, right), with no evidence of the PVM remodeling or plasma membrane disruption observed in vacuoles containing avirulent PTG parasites. Consistent with this conclusion, staining of the parasite dense granule protein GRA-7, which associates with the parasitophorous vacuole membrane demonstrated that the integrity of the PVM formed by RH parasites in primed macrophages remained persistently intact, while GRA-7 clearly “leaks-out” into the cytosol (23) of primed macrophages wherein disrupted PTG parasites were evident (Fig. 2⇑D). Together, the ultrastructural and immunofluorescence analyses indicate that the parasitophorous vacuole membrane formed by virulent RH strain parasites was able to resist or evade macrophage-instigated vesiculation and disruption, explaining the lack of RH parasite elimination.
Vacuole-autonomous mode of evasion by virulent Toxoplasma
Virulent RH parasites might escape destruction by globally inhibiting the critical functions of IRGs required for PVM disruption. Alternatively, virulent T. gondii could evade elimination by locally controlling the recruitment or activation of IRGs on the PVM. To distinguish between these alternative modes of resistance, we followed the fate of virulent RH and avirulent PTG parasites in dually infected cells. As depicted in Fig. 2⇑E (left), pre-infection of RFP-expressing virulent RH parasites did not prevent or inhibit disruption of vacuoles subsequently formed by GFP-PTG parasites. Avirulent parasites underwent vacuolar disruption regardless of whether they were inside cells singly infected or coinfected with virulent parasites (Fig. 2⇑E, middle and right). In the same way, vacuoles containing virulent parasites remained intact in singly infected cells or in cells also infected with an avirulent parasite. Thus, the fate of each tachyzoite and its ability to resist macrophage destruction is determined vacuole-autonomously. This observation argues against a scenario where virulence factor(s) produced by RH parasites globally result in functional inactivation of the macrophage’s GTPase-dependent toxoplasmacidal activity.
Differential trafficking of IRGs to the PVM formed by virulent and avirulent Toxoplasma
The apparent absence of vacuolar membrane damage in RH-infected macrophages raised the important question of whether IRGs were precluded from associating with the PVM. Several members of the IRG protein family, including Irgm3, Irga6, and Irgb6 are induced by Th1 cytokines (15, 16, 23, 24, 25) and have been shown to associate with the parasitophorous vacuole formed by T. gondii (23). Although both are essential for resistance to Toxoplasma, Irgm1 and endogenous Irgm3 are not readily detected in the PVM by immunofluorescence microscopy. In astrocytes, Irga6 and Irgb6 have been shown to be abundantly associated with the PVM before the PVM vesiculation and disruption (23), but the in vivo resistance phenotype of Irga6 and Irgb6 null-mice to Toxoplasma infection has not been reported. We therefore assayed for the presence of Irga6 and Irgb6 on the PVM formed by virulent RH and avirulent PTG parasites. As shown in Fig. 3⇓A, Irga6 localized to the PVM of both PTG and RH parasites. Interestingly, while the percentage of PTG parasites showing vacuolar Irga6 decreased with time (Fig. 3⇓A, right), the percentage of RH parasites with Irga6+ vacuoles remained elevated, likely a reflection of the fact that vacuoles formed remained intact and continually accumulate Irga6 (evident as an increase in Irga6 staining intensity, data not shown). In contrast to the pattern of Irga6 staining, no Irgb6 was seen to localize to RH vacuoles, while it readily associated with the PVM formed by avirulent PTG parasites (Fig. 3⇓B). These results demonstrate that the lack of PVM disruption in the RH vacuole is not due to a wholesale exclusion of IRG proteins. Instead, the picture that emerges is that selective exclusion of distinct IRG family members from the PVM could be responsible for the lack of vesiculation and disruption of the RH vacuolar membrane. To probe the status of the Irga6 recruited to the RH-vacuole formed in primed macrophages, we used the 10D7 mAb, which recognizes a conformational epitope of Irga6 when it is GTP-bound (26). As shown in Fig. 3⇓C, all Irga6+ RH and PTG vacuoles stained with a rabbit anti-Irga6 Ab were similarly positive for the 10D7 epitope. Thus, RH resistance is not associated with a failure of Irga6 to adopt a GTP-bound conformation at the PVM formed by virulent Toxoplasma. The recruitment of GTP-bound Irga6 to the RH PVM coupled with the apparent exclusion of Irgb6 from the PVM favors the view that virulent RH parasites passively evade vacuolar disruption, rather than actively inhibiting a critical yet unknown step in the IRG-mediated vacuolar disruption mechanism. The fact that Irgb6 and several murine guanylate-binding proteins (27) fail to associate with the PVM formed by virulent, but not avirulent Toxoplasma is consistent with this view.
Evasion of IRG-mediated vacuolar disruption as a new virulence determinant
Evasion of vacuolar disruption might represent a new virulence mechanism of Type I strains of Toxoplasma. The genetic and molecular basis for the ability of virulent parasites to evade IRG-mediated destruction is currently not known. Using forward genetic analysis of progeny between a Type I (GT-1) and a Type III parental strain, the polymorphic serine threonine kinase ROP-18 encoded by GT-1 parasites was identified as the major virulence factor for Type I strains of Toxoplasma (18, 28). Transgenic expression of Type I ROP-18 in a Type III CTG strain resulted in dramatic increases in mouse virulence (measured by mortality assays) and an enhancement of parasite growth and motility phenotypes. To ascertain whether the same ROP-18 allele accounts for the different outcomes of Type I vs Type III infection in primed macrophages, we followed the fate of a Type III (CTG) strain parasite lines expressing either WT ROP-18 (CTG-ROP18V1) or mutated ROP-18 lacking catalytic activity (CTG-ROP18L1) in CPS-primed effector macrophages. As shown in Fig. 4⇓, Type III CTG strain parasites were eliminated (Fig. 4⇓A), underwent vacuolar disruption with time (Fig. 4⇓, B and C), and did not exclude Irgb6 from the PVM (Fig. 4⇓C), regardless of whether they were expressing WT or mutated Type I ROP-18 allele. This result suggested that another polymorphic parasite protein, distinct from ROP-18, could mediate the evasive maneuver of Type I parasites. Preliminary linkage analysis of F1 progeny clones from a genetic cross between Type I and Type III parental strains (data not shown) supports ROP-18-independence of the evasive phenotype, consistent with the multilocus control of virulence in Toxoplasma.
Our data demonstrate that the microbiostatic and microbiocidal activities of primed macrophages are mediated by distinct gene products induced by the principal Th1 cytokine, IFN-γ. NOS2-generated NO radicals may target metabolic enzymes involved in DNA replication and in mitochondrial respiration resulting in inhibition of parasite multiplication. In contrast, members of the IRG protein family traffic to the Toxoplasma parasitophorous vacuole membrane, and are thought to effect vesiculation and physical disruption of the protective membrane formed by the parasite (23). In this report, we demonstrate that virulent Type I strains of T. gondii remarkably resist IRG-mediated disruption of their vacuoles and, ultimately, escape autophagic elimination, while simultaneously remaining vulnerable to NOS2-mediated growth restriction. The resistance phenotype of virulent Toxoplasma has also recently been found to be operative within IFN-γ-activated mouse fibroblasts (29). Resistance to killing by armed effector macrophages and cytokine-activated parenchymal cells may explain, in part, how virulent Toxoplasma strains invariably kill immunocompetent mice, even in the face of a full-blown Th1 response (5). The ability to forestall elimination could widen the parasite’s window of opportunity for deactivating the infected macrophage by suppressing de novo gene induction by IFN-γ. The molecular basis for how virulent T. gondii escapes destruction within the macrophage awaits further investigations, but our current results showing vacuole-autonomous control and the differential permissiveness for IRG protein recruitment are consistent with either passive or active models of evasive action. A polymorphic parasite molecule encoded by virulent Toxoplasma and present on the PVM may present a nonpermissive interface for the proper trafficking and assembly of the complement of IRGs required for effecting vacuole membrane vesiculation and disruption. Presumably, the same PVM-associated protein from avirulent strains allow for recruitment of critical GTPases and subsequent vacuolar membrane remodeling events. Alternatively, the PVM-localized virulent determinant could actively prevent the proper targeting of a subset of essential IRGs to the PVM by modifying a key host factor required for this process. Identification of the strain-variant Toxoplasma molecule(s) responsible for this evasive phenotype will not only further our understanding of parasite virulence mechanisms, but may also elucidate a key step(s) in the assembly and function of the IRG protein machinery responsible for vacuolar membrane disruption.
Microbial interference with the trafficking, assembly, and function of IRGs may prove to be a convergent theme underlying not only virulence characteristics, but also the host range and restriction of multiple pathogens. Exposure of mouse cells to IFN-γ induces the transcription and biosynthesis of a large group of GTPases, including many 47 kDa IRGs and 10 murine guanylate-binding proteins (27, 30, 31). The antimicrobial activities of IRGs have been implicated in resistance to different viruses, bacteria, and eukaryotic pathogens (32). With regard to host-species restriction of pathogens, it is interesting to note that the human pathogen Chlamydia trachomatis is effectively restricted, while the mouse pathogen Chlamydia muridarum is refractory to inhibition by cytokine-activated murine fibroblasts (33). Inclusion bodies containing C. trachomatis efficiently recruit multiple IRG proteins, while C. muridarum inclusion bodies remain negative. Although inefficient, C. muridarum can prevent recruitment of IRG proteins to the C. trachomatis vacuole in doubly infected mouse cells, suggesting that the chlamydial factor may be injected into the host cytosol and traffic more extensively between vacuoles in the same infected cell. In contrast, the vacuole-autonomous control of the virulent Toxoplasma-evasion phenotype suggests the putative Toxoplasma evasive determinant may be highly restricted to the PVM. In this regard, the localization of the principal Toxoplasma virulence determinant ROP-18 to the PVM made it an obvious candidate evasion molecule. Nevertheless, transgenic expression of the Type I allele of ROP-18 in an avirulent Type III parasite strain did not confer an evasive phenotype and was not sufficient to overcome the disruptive function of in vivo-primed effector macrophages, suggesting involvement of another polymorphic rhoptry protein encoded by virulent Toxoplasma. It is interesting to note that in primates, including humans, only two IRG gene homologues, neither of which is IFN-inducible, are present (31). Further, the existence of a pathway for vesiculation and disruption of the Toxoplasma PVM has not yet been documented in human cells. Thus, Toxoplasma may have to deploy a diverse set of evasive and resistance tactics, in anticipatory response to the variability of growth restrictive and parasite killing mechanisms used by different host cell types and species. In the case of Type I strain infection of laboratory mice, the evolution of a mechanism for evasion of vacuolar disruption by IRG proteins is seemingly maladaptive, resulting in acute virulence and premature death of both parasite and host. It may be that the same Type 1 polymorphism giving rise to virulence in laboratory mice conferred avirulence and a coadaptive advantage in distantly related rodent intermediate hosts, which possess a different genetic profile for immunity-related GTPases and which play a more significant role in the ecology of the parasite.
We thank Mike Ling for his initial contributions to the project and are grateful to our many colleagues (Isabelle Coppens, Jens Zerrahn, Marc Jan Gubbels, and Greg Taylor) for invaluable parasite, mouse, and Ab reagents, discussions and suggestions for improving the manuscript. We thank Utz Herbig (NJMS) for use of his fluorescent microscope.
The authors have no financial conflict of interest.
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
↵1 This work is supported by an R21 exploratory grant from the National Institutes of Health (AI074914 to G.S.Y.) and funds from University of Medicine and Dentistry of New Jersey-New Jersey Medical School. L.D.S. was supported by National Institutes of Health Grant AI036629.
↵2 Address correspondence and reprint requests to Dr. George S. Yap, Department of Medicine, New Jersey Medical School, University of Medicine and Dentistry of New Jersey, 185 South Orange Avenue, MSB F-649, Newark, NJ, 07101. E-mail address:
↵3 Abbreviations used in this paper: NOS2, inducible nitric oxide synthase; PEC, peritoneal exudate cell; WT, wild type; CPS, carbamoyl phosphate synthetase II; PVM, parasitophorous vacuole membrane; IRG, immunity-related GTPase.
- Received December 15, 2008.
- Accepted January 14, 2009.
- Copyright © 2009 by The American Association of Immunologists, Inc.