Forward genetics is a powerful approach to identify genes in intracellular pathogens important for resistance to cell autonomous immunity. The current approach uses innate immune cells, specifically macrophages, to identify novel Toxoplasma gondii genes important for immune evasion.
Toxoplasma gondii, the causative agent of toxoplasmosis, is an obligate intracellular protozoan pathogen. The parasite invades and replicates within virtually any warm blooded vertebrate cell type. During parasite invasion of a host cell, the parasite creates a parasitophorous vacuole (PV) that originates from the host cell membrane independent of phagocytosis within which the parasite replicates. While IFN-dependent-innate and cell mediated immunity is important for eventual control of infection, innate immune cells, including neutrophils, monocytes and dendritic cells, can also serve as vehicles for systemic dissemination of the parasite early in infection. An approach is described that utilizes the host innate immune response, in this case macrophages, in a forward genetic screen to identify parasite mutants with a fitness defect in infected macrophages following activation but normal invasion and replication in naïve macrophages. Thus, the screen isolates parasite mutants that have a specific defect in their ability to resist the effects of macrophage activation. The paper describes two broad phenotypes of mutant parasites following activation of infected macrophages: parasite stasis versus parasite degradation, often in amorphous vacuoles. The parasite mutants are then analyzed to identify the responsible parasite genes specifically important for resistance to induced mediators of cell autonomous immunity. The paper presents a general approach for the forward genetics screen that, in theory, can be modified to target parasite genes important for resistance to specific antimicrobial mediators. It also describes an approach to evaluate the specific macrophage antimicrobial mediators to which the parasite mutant is susceptible. Activation of infected macrophages can also promote parasite differentiation from the tachyzoite to bradyzoite stage that maintains chronic infection. Therefore, methodology is presented to evaluate the importance of the identified parasite gene to establishment of chronic infection.
Toxoplasma gondii (T. gondii) is an obligate intracellular, protozoal pathogen. It is the causative agent of toxoplasmosis, a health hazard in immunocompromised individuals. It is also the model system for other apicomplexan pathogens that infect humans including Cryptosporidium and Cyclospora. Toxoplasmosis is most commonly acquired through ingestion of food or water contaminated with the bradyzoite or oocyst stage of the parasite. Upon ingestion, these stages convert to the tachyzoite stage of the parasite that replicates within host cells and disseminates systemically. T cells, IFN-γ and, to a lesser extent, nitric oxide 1-4, are important for control of infection but are not capable of eliminating the disease, as a proportion of tachyzoites convert to the bradyzoite stage that are protected within tissue cysts resulting in a long-lived chronic infection. In fact, there are no therapeutics effective against the chronic cyst stage of the disease. Severe toxoplasmosis is most often due to the reactivation of persistent infection, with the bradyzoite stage of the parasite converting back to the rapidly replicating tachyzoite stage characteristic of primary and acute infection.
Early survival in the face of the innate immune response is important to allow the parasite to reach sufficient parasite numbers, as well as to reach distal sites, to enable establishment of chronic infection. T. gondii has evolved strategies to counteract host defense mechanisms that likely contribute to its ability to replicate and disseminate early in infection. First, T. gondii forms a unique PV during parasite invasion that is largely segregated from the endocytic and exocytic processes of the host cell compared to other intracellular pathogens 5-9. Also, like all successful intracellular pathogens T. gondii modifies its host cell to create a permissive environment for growth. This includes reprogramming host cell gene expression by altering host cell transcription factors including those important for regulating cell activation 10-15. ROP16 16-19, GRA15 20, GRA16 21 and GRA24 22 have all been shown to be important in regulating the transcriptional response and cell signaling cascades of host cells infected with T. gondii. Recent studies using genetic crosses between parasite strains with distinct phenotypes have been highly productive in identifying parasite genes that underlie parasite genotype-dependent traits including evasion of immunity related GTPases (IRGs) 16,19,23-26. In mice, immunity related GTPases (IRGs) are critical for the control of Type II and III genotypes of the parasite while the very virulent Type I genotypes have evolved mechanisms to evade the murine IRGs. However, it is also clear that the parasite has evolved mechanisms to evade antimicrobial mediators in addition to the IRGs and that some of these mechanisms may be conserved across parasite genotypes 27,28. In addition, very little is known about the critical mediators of cell autonomous immunity against T. gondii during human toxoplasmosis. Parasite genes important for resistance to mediators of cell autonomous immunity may also be important for survival during tachyzoite to bradyzoite conversion which can also be triggered by host immune responses. For example, nitric oxide at high levels can suppress parasite replication in infected macrophages but it can also stimulate tachyzoite to bradyzoite conversion resulting in cyst production30-32.
ToxoDB is a functional genomic database for T. gondii that functions as a critical resource for the field in terms of providing sequence information for the parasite genome and access to published and unpublished genomic scale data including community annotations, gene expression and proteomics data 33. Similar to many protozoal pathogens, the majority of the genome consists of hypothetical genes with no information available based on gene homology to provide insight into their potential functions. Thus, forward genetics is a powerful tool to identify novel parasite genes important for immune evasion, cyst conversion and other functions critical for parasite pathogenesis as well as for conversion between distinct developmental stages. An additional strength of forward genetics is that it can be used as a relatively non-biased approach to interrogate the parasite as to the genes that are important for specific tasks in pathogenesis, including immune evasion and cyst formation. Recent improvements in next generation sequencing for mutational profiling have made it a method of choice for identifying the responsible parasite genes from forward genetics studies using both chemical and insertional mutagenesis 34-37.
It is important to identify vulnerabilities in T. gondii that can be exploited to enhance the effectiveness of cell autonomous immune mechanisms against the parasite particularly those that may also be active against the resistant cyst stage. Toward this aim, an in vitro murine macrophage infection and activation model was developed to identify mutations in the parasite that specifically impair T. gondii fitness following activation of infected macrophages but not in naïve macrophages. This macrophage screen was used to interrogate a library of T. gondii insertional mutants in order to ultimately identify T. gondii genes important for resistance to nitric oxide 27,28. The isolation of a panel of T. gondii mutants with impaired resistance to activation of infected macrophages, particularly a marked sensitivity to nitric oxide, proved the utility of the screen to identify parasite genes important for resistance to mediators of cell autonomous immunity other than the resistance mechanisms described for the murine IRGs 28. Insertional mutagenesis has advantages over chemical mutagenesis in terms of generating a limited number of random mutations in each parasite clone and, in theory, easier identification of the site of mutation. However, identifying the genomic site of plasmid insertion in T. gondii insertional mutants, in practice, has been surprisingly difficult in many cases 37. Insertion of a plasmid into a gene is also likely to disrupt the function of a gene in contrast to chemical mutagenesis that typically results in single nucleotide changes. However, chemical mutagenesis with either N-ethyl-N-nitrosourea (ENU) or ethylmethane sulfonate (EMS) may offer an increased ability to analyze a larger portion of the parasite genome, compared to insertional mutagenesis, as it creates multiple single nucleotide polymorphisms (estimated at 10 -100) per mutant34,38. Moreover, recent advances in whole genome profiling has made it possible to use next generation sequencing to identify the most likely candidate genes responsible for the identified phenotype of a mutated parasite 34,38. Regardless of the mutagenesis approach, confirmation of the role of the parasite gene in resistance to macrophage activation ultimately requires gene deletion and complementation to fulfill molecular Koch’s postulates.
The ability to dissect the function of a gene by genetic manipulation of both the parasite and the macrophage is important as many of the genes identified via forward genetics in T. gondii, as well as other pathogens, are still characterized as hypothetical genes with little to no sequence homology to other proteins with known functions. The current paper outlines a general approach that can be used to identify whether the disrupted gene in a mutant is important for resistance to a known or unknown mediator of cell autonomous immunity. The initial analysis of host antimicrobial factors is performed by evaluating the survival of wild type and mutant parasites in macrophages from wild type mice versus those with specific gene deletions in inducible nitric oxide synthase (iNOS), gp-91 phox (NADPH oxidase), and specific immunity related GTPases (IRGs). This will determine if the identified parasite genes are important for resistance to nitric oxide, reactive oxygen intermediates or immunity related GTPases 28 respectively or if an unknown immune mechanism is involved. Activation of infected macrophages with both IFN-γ and LPS, described in the current protocol, results primarily in the isolation of parasite genes important for resistance to nitric oxide 28. The use of pharmacological agents that induce nitric oxide in the absence of macrophage activation (nitric oxide donors) confirmed that the majority of the genes identified were important for resistance to nitric oxide rather than nitric oxide in concert with additional mediators associated with macrophage activation 28.
Step one and two describe a forward genetics screen designed to isolate parasite mutants with a fitness defect following activation of infected bone marrow-derived macrophages in vitro. Step one describes a dose titration analysis to empirically determine a dose of IFN- γ and LPS to use for macrophage activation that reduces parasite replication but does not fully inhibit replication of the wild type T. gondii parental strain that is used for creation of the library of parasite mutants. Step two describes the forward genetic screen of the mutant clones in macrophages in 96-well plates. Step three outlines an approach to confirm the phenotype of each mutant identified in the screen of the 96 well plates and to evaluate whether the defect in each mutant affects parasite survival, replication, or cyst production in response to macrophage activation. Step four describes the use of bone marrow-derived macrophages from mice with deletions in specific antimicrobial pathways to identify the immune mediators to which the parasite mutant is specifically susceptible. Step five outlines an approach to determine if a parasite mutant is also compromised for in vivo pathogenesis as evaluated by cyst production in the brains of infected mice.
NOTE: All protocols that involve the use of animals were performed in accordance with the guidelines and regulations set forth by the New York Medical College’s Animal Care and Use Committee.
NOTE: Detailed protocols for chemical mutagenesis 38, isolation of parasites by limiting dilution 38, isolation of murine bone marrow derived macrophages 39, growth of T. gondii in human foreskin fibroblast (HFF) cells and cyst production in macrophages and basic immunofluorescence analysis (IFA) 32 are referenced. Carry out all cell culture at 37 °C in 5% CO2 in D10 media (Dulbecco’s Modified High Glucose Eagle Medium supplemented with 10% fetal calf serum, 2 mM L-glutamine, 100 U/ml penicillin and 100 µg/ml streptomycin). Keep all reagents sterile throughout cell isolations and cell culture.
1. Dose Titration of IFN-γ and LPS to Determine the Concentrations to Use to Activate Infected Macrophages for the Forward Genetics Screen
2. Isolation of Parasite Mutants with a Fitness Defect Following Activation of Infected Macrophages
NOTE: A library of random T. gondii mutants is required for the forward genetics screen. Random mutagenesis of T. gondii can be performed by chemical (ENU/EMS) or insertional mutagenesis 27,28,38. Following mutagenesis, clone parasites by limiting dilution and grow individual clones in 96-well plates containing adherent HFF cells in a volume of 200 µl of D10 media 32,38. It is critical that 96-well plates for screening of parasites in macrophages by microscopy have optical bottoms to enable microscopic screening. Phase contrast and fluorescence microscopy for screening stained 96-well plates requires an inverted fluorescence microscope with phase contrast 4, 10, 20 or 40X objective equipped for long working distances. A 4X objective is useful for seeing the entire well but better resolution of the parasites is achieved with the 20X objective.
3. Evaluate the Mutants to Determine if the Defect is at the Level of Parasite Survival or Replication Following Activation of Infected Macrophages
4. Evaluate whether the Susceptibility of Mutant Parasites to Activation of Infected Macrophages is Associated with Known Anti-microbial Mediators
5. Evaluate whether the Defect in the Mutant Parasite Compromises Chronic Infection
Toxoplasma gondii replicates freely in naïve macrophages and has a doubling time between 6-12 hr depending on the strain of the parasite. Figure 1 shows representative parasites in naïve versus activated bone marrow-derived macrophages. Figure 2 shows the general morphology of parasites in HFF host cells at 2, 4, 8, 16 and 32 parasites/PV. In the current protocol, the parasite is allowed to invade naïve macrophages and establish a nascent parasitophorous vacuole (PV) prior to the delivery of a potent activation stimulus, LPS and IFN-, to the infected macrophages. In this model, replication of wild type parasites is slowed, but parasite replication still proceeds for approximately 24 hr during which time the macrophages become progressively more adept at inhibiting parasite replication. The screen is designed to function as a modified competition model between the time required for potent macrophage activation versus the time during which the wild type parasite or parasite mutant can continue to replicate within its PV. The first step in the screen is to choose a dose of LPS and IFN- γ to be used for activation of infected macrophages. The dose is empirically determined by evaluating parasite replication in macrophages activated with either a constant dose of IFN- γ in combination with a range of LPS concentrations or a constant dose of LPS with a range of IFN- concentrations (Step 1). The dose of the activation stimuli needs to be evaluated for the parental wild type parasites used for creation of the parasite mutants by chemical or insertional mutagenesis. Ideally the dose of LPS and IFN- γ will permit parasite replication to an average of 2-8 parasites per PV 24-30 hr after activation compared to 8-16 parasites per PV in naïve macrophages (Figures 1 and 2).
Once the appropriate concentration of LPS and IFN- γ is determined, the mutants are screened in 96-well optical bottom tissue culture plates. The optical bottom in the plates is important because irregularities in the plastic that is used for traditional tissue culture plates makes it difficult to achieve the appropriate resolution to screen the parasites by phase contrast and fluorescence microscopy. Phase contrast and fluorescence microscopy of the 96-well plates also requires an inverted fluorescence microscope with phase contrast 4, 10, 20 or 40x objective equipped for long working distances. Mutants are screened in replicate plates containing murine bone marrow-derived macrophages. After challenge with parasite mutants, infected macrophages in the wells of one plate are activated with LPS and IFN- γ while the other plate containing infected macrophages is cultured in only D10 media. Plates are incubated at 37 ° C and 5% CO2 for 24-30 hr after addition of LPS and IFN- γ . After incubation, cells are fixed, stained for parasites and analyzed by IFA using both fluorescence and phase contrast microscopy. Mutants are selected that have normal parasite numbers and replication in naïve macrophages but fewer parasites or smaller vacuoles with fewer parasites in infected macrophages that are activated. Once mutants are selected they should be rescreened in chamber slides (Step 3) in naïve and activated macrophages in two independent experiments to enable analysis of parasite morphology at higher magnifications (100X objective and oil) and to confirm that they have normal replication in naïve macrophages but a defect in replication/survival following macrophage activation.
The phenotypes of the mutants with defects in resistance to activation of infected macrophages typically fall into two broad categories: parasites that appear morphologically intact but are unable to replicate beyond a single parasite per PV; and parasites that appear to be degraded and may also be in amorphous spacious PVs (Figures 1 and 3). The morphology and ultrastructure of the parasite and PV is best viewed on slides using a 100X objective and oil and by phase contrast microscopy combined with fluorescence analysis. Staining of parasites for IFA with an antibody to lysosomal associated membrane protein-1 (LAMP1) is useful to determine whether the defect in the mutant is associated with an inability of the PV to prevent fusion with lysosomes. Shown in Figure 4 is a parasite within a phagolysosome (LAMP1 positive) versus a parasite that is in a PV that is largely segregated from the endocytic system of the host cell (LAMP1 negative). The phagolysosome is evident by a continuous solid rim of LAMP1 straining around the entire parasite. In contrast, a PV often has lysosome organelles in the vicinity but no continuous rim of LAMP1 staining around its circumference. The use of antibodies to defined structures/organelles within the parasite and/or PV are useful in follow up IFA studies to identify anomalies in each mutant associated with activation of infected macrophages. Such interrogations with antibodies may provide insight into the mechanisms that underlie the replication/survival defect in a mutant. For example, Figure 5 shows the T. gondii mitochondrion stained with monoclonal antibody 5F4 anti-F1 ATPase beta subunit (a kind gift from Peter Bradley) 24 hr after activation of macrophages infected with wild type parasites or parasite mutants. T. gondii was co-stained with a monoclonal anti-T. gondii antibody. Wild type T. gondii has a single mitochondrion that extends around the circumference of the parasite. The parasite’s sole mitochondrion in wild type parasites following activation of infected macrophages was intact compared to a fragmented mitochondrion in mutant parasites. Mitochondria fragmentation was evident not only in degraded/amorphous parasites but also in parasites that displayed normal morphology as evaluated by phase contrast microscopy. This suggests that the defect in the parasite mutant may increase the susceptibility of the parasite mitochondrion to host cell mediators induced by macrophage activation.
The current model uses a combination of IFN- γ and LPS to activate infected macrophages. IFN- γ stimulates the transcription factor STAT1. LPS, like TNF-α, stimulates the transcription factor NF-κB. Known IFN- γ -dependent antimicrobial mediators important in cell autonomous immunity against T. gondii include an array of IFN- γ -dependent immunity related GTPases (IRGs, GBPs) and reactive nitrogen and oxygen species in addition to other agents. In order to determine if the defect in each mutant is specifically associated with production of known IFN- γ -inducible antimicrobial mediators, bone marrow-derived macrophages are isolated from iNOS-/-, gp 91 phox-/- or specific IRG/GBP gene deleted mice and assayed for activity against the mutant parasites. The combination of IFN- γ and LPS to activate infected macrophages preferentially results in mutants with enhanced susceptibility to nitric oxide compared to wild type parasites 28.
Activation of infected macrophages can induce stage differentiation of the parasites from tachyzoites to bradyzoites that are contained in tissue cysts. Such cysts are characteristic of chronic infection. Thus, parasite mutants that are defective for replication/survival following activation of infected macrophages may also be defective for conversion to cysts during in vivo infection. In order to evaluate cyst production during chronic infection, mice are challenged intraperitoneally (ip) with a non-lethal dose of the parental parasite strain or the mutant clone. Cysts in the brain range in size from less than 10 μm in diameter to greater than 50 μm as shown in Figure 6. Count the number of both large and small cysts by IFA but keep the counts separate in order to determine if the parasite mutant is impaired for total cyst production or just for establishment and maintenance of large cysts.
Figure 1. Naïve murine bone marrow-derived macrophages are permissive for replication of T. gondii but activation with IFN- γ and LPS substantially inhibits replication. (A) A parasitophorous vacuole (PV) of wild type T. gondii 24 hr after invasion of naïve murine bone marrow-derived macrophages. (B) A PV of wild type T. gondii parasites consisting of four parasites per vacuole 24 hr after activation of infected macrophages. (C) An example of a mutant parasite unable to replicate and still at one parasite/PV 24 hr after activation of infected macrophages. (D) An example of a mutant parasite that appears degraded within an amorphous PV 24 hr after activation of infected macrophages. The top row shows phase images of the parasites and the bottom row shows fluorescent images using a polyclonal anti-serum against T. gondii. The scale bar represents 5 µm. Please click here to view a larger version of this figure.
Figure 2. Parasite replication evaluated by the number of parasites per PV. The pictures show 2, 4, 8, 16 and 32 parasites per PV in HFF cells. Each picture is a merged phase image that shows polyclonal antibody staining of the parasite in red and the HFF nucleus in blue (DAPI). The scale bar represents 5 µm. Please click here to view a larger version of this figure.
Figure 3. Mutants exhibit a range of phenotypes following activation of infected macrophages. The column on the left is a phase image of the parasite in macrophages, the center column is a fluorescent image using an antibody to T. gondii, and the right column is a merge of the phase and fluorescent image. The parasite is shown in green and the macrophage nucleus in blue. The scale bar represents 5 µm. Please click here to view a larger version of this figure.
Figure 4. LAMP1 staining distinguishes PVs from phagolysomes-containing parasites. Parasites are stained with a polyclonal anti-T. gondii antibody (red) and LAMP1 with the mAb 1D4B (green). An arrow marks a parasite PV that has fused with lysosomes. The parasite without the arrow is in a parasitophorous vacuole (PV) that has not fused with lysosomes. The scale bar represents 5 µm. Please click here to view a larger version of this figure.
Figure 5. Wild type parasites maintain an intact mitochondrion while the mitochondrion is degraded in parasite mutants following activation of infected macrophages. Mitochondrion (green) in wild type parasites (top panel) compared to three different mutant T. gondii parasites at different stages of degradation (bottom three panels) 24 hr after activation of infected macrophages. The scale bar represents 5 µm. Please click here to view a larger version of this figure.
Figure 6. Detection of parasite cysts in the brain using FITC-conjugated dolichos biflorus lectin. The cyst wall labeled with the lectin is shown in green. The scale bar represents 50 µm. Please click here to view a larger version of this figure.
The described protocol provides a non-biased approach that uses activation of murine bone marrow-derived macrophages and forward genetics to isolate T. gondii mutants with a defect in their ability to survive activation of infected macrophages. The phenotype of the mutants following macrophage activation typically falls into one of two broad categories: 1) The parasites appear intact but fail to replicate beyond 1 parasite per PV; 2) The parasites appear degraded and may be in spacious, amorphous PVs. The fact that the mutants have a phenotype like wild type parasites in naïve macrophages in the absence of activation proves the protocol can specifically be used to identify mutants that are specifically impaired in their ability to resist macrophage activation. The use of primary bone marrow-derived macrophages is recommended versus the RAW 264.7 macrophage cell line for the screen because the morphology of the parasites and parasite number per vacuole are more easily visualized in bone marrow-derived macrophages.
The described screen combined with forward genetics provides a versatile tool to dissect parasite genes and ultimately genetic pathways important for resistance to specific mediators of cell autonomous immunity. Such forward genetics studies are important to identify parasite genes that can be followed like a string to begin unravelling parasite pathways important for resisting specific antimicrobial mediators both in vitro and during pathogenesis. A previous difficulty with forward genetic approaches was identification of the key gene disrupted in each mutant. Cosmid library complementation in T. gondii has been quite effective for functional complementation of cell division mutants. However, the fact that replication of wild type parasites are also suppressed by IFN-γ and LPS just to a lesser extent than the mutants, makes functional complementation more difficult than for cell division mutants. Whole genome mutational profiling for both chemical and insertional mutants in T. gondii has recently emerged as a productive, and even cost effective, avenue to identify the genes responsible for phenotypes of mutants in forward genetics screens 34,36,37,44. Consequently, whole genome mutational profiling using next generation sequencing has enhanced the potential uses of chemical mutagenesis of T. gondii in forward genetic studies to identify genes important for specific functions. Such a forward genetics approach as described in the current protocol are important as most of the genome of T. gondii remains hypothetical with a majority of predicted genes having no homology to other genes or functional domains that might aid in the identification of candidate parasite genes important for immune evasion.
IFA analysis of 96 well plates is not generally considered a high throughput screening method. In our experience it is reasonable for one person to stain and screen 10 96-well plates in a day or approximately 960 mutants. In the paper by Skariah et al., approximately 8,000 mutants were analyzed and 14 independent mutants were isolated that were significantly impaired for survival/replication in activated but not naïve macrophages 28. The impaired survival of the mutants was predominately the result of increased susceptibility to nitric oxide. The limitation in the overall method is primarily at the level of obtaining single clones of the parasite rather than screening by microscopy as the initial screen in 96 well plates is qualitative and reasonably rapid. Confirmation of the phenotype of mutants identified in the screen of the 96 well plate is followed up in Step 3 by quantitative and qualitative analysis using macrophages in chamber slides and by adding equal numbers of wild type or mutant parasites. The use of other analytical screening methods such as fluorometry at the total population level of parasites, rather than the individual parasite level as evaluated by microscopy, are problematic in the current protocol as many of the degraded parasites stain with the polyclonal antibody against T. gondii as robustly as wild type parasites with the difference in the mutant being more qualitative than quantitative at the level of fluoresence intensity. Also, the dose of IFN-γ and LPS required to isolate mutants with a defect in resistance to activation of infected macrophages results in suppressed replication of wild type parasites albeit at later time points. Therefore, measurement of total parasite number for the forward genetics screen including the use of luminescent parasites is problematic. However, it is possible the staining protocol could be eliminated in the screening step if the parental parasite clones used for chemical or insertional mutagenesis expressed a constitutive or inducible fluorescent or luciferase marker. The described protocol using IFA and microscopy screening of macrophages in 96 well plates allows for isolation of mutants defective for survival/replication in activated macrophages but it also clearly misses some potential mutants due to the limited microscopic resolution achievable using the 96-well plate format as at this resolution amorphous swollen vacuoles that stain for parasite antigen may be mistaken for healthy replicating parasites within a normal PV. Substitution of 96 well cover glass plates, instead of 96 well plates with an optical surface, is likely to achieve greater resolution during the screen of infected macrophages in 96 well plates.
The vast majority of the mutants identified using IFN-γ and LPS in the described protocol to activate macrophages following parasite invasion have a defect in their ability to protect themselves from nitric oxide 28. In this regard, the screen although intended to be non-biased, may enrich for the isolation of parasite mutants with increased susceptibility to specific antimicrobial mediators depending on the activation conditions, the type and species of macrophages and the timing of parasite invasion relative to macrophage activation that are chosen for the screen. Thus the innate immune cell chosen for the screen and the activation stimuli applied are critical parameters that impact the type of antimicrobial mediators to which the resultant parasite mutants are likely to be susceptible. The genotype of the parasite is also a critical parameter as Type I genotypes of the parasite are relatively resistant to immunity related GTPases (IRGs) induced in response to IFN-γ while the Type II and III genotypes are more susceptible 26,45,46. In the described protocol, macrophages are activated after parasite invasion. Although the Type II genotype, Prugnaud strain, used in the described screen is susceptible to the action of immunity related GTPases, allowing the parasite to invade macrophages first enables replication of wild type parasites before full induction of the IRGs. Also, it is not clear that IRGs are effective against the parasite if they are induced in macrophages subsequent to parasite invasion and initiation of replication.
The described protocol uses macrophages to identify parasite genes important for resistance to IFN-γ-dependent mediators of cell autonomous immunity, particularly nitric oxide. The isolation of a pool of parasite mutants that share a marked susceptibility to nitric oxide as well as a shared phenotype of nitric oxide-dependent mitochondrial fragmentation provides a unique set of tools to identify parasite genes and pathways important for resistance to nitric oxide and for understanding the action of nitric oxide more broadly against T. gondii and other eukaryotic pathogens.The described protocol with minor modifications can be used for forward genetics studies to identify parasite genes important for resistance to different mediators of cell autonomous immunity. Potential modifications include altering the type of host cell infected, the activation stimuli, or the timing of activation relative to parasite invasion. For example, pre-activation of murine macrophages with IFN-γ before addition of parasites would result in activation of immunity related GTPases. Such a model could be used to identify parasite genes in Type I genotypes of T. gondii that may contribute to the resistance mediated by ROP18 and ROP5 to immunity related GTPases 24,25. Mediators of cell autonomous immunity against T. gondii in human innate immune cells are not as well defined as in rodents. Thus, the use of human peripheral blood monocytes to screen chemical mutants of T. gondii might identify both parasite genes important for survival during human infection in innate immune cells as well as mechanisms important in humans for antimicrobial resistance to T. gondii. Parasite genes important for resistance to specific antimicrobial mediators can be identified by isolating mutants unable to survive exposure of infected host cells to pharmacological agents such as reactive oxygen or nitrogen species. Similarly the protocol can be modified to isolate parasite mutants with increased susceptibility to inflammasome activation 47-49 or ATP stimulation of the macrophage purinergic receptors 50.
Taken together, the protocols describe an approach using forward genetics and innate immune cells to isolate parasite mutants important for T. gondii resistance to IFN-γ-dependent cell autonomous immunity. Importantly, the approach put forth is versatile and can be readily modified to isolate parasite genes important for evading specific antimicrobial mediators, parasite survival in specific types of host cells or resistance to stress conditions encountered during toxoplasmosis. Furthermore, parasite genes important for resisting host cell activation in many cases may also play a role directly or indirectly in cyst production in vivo during infection.
The authors have nothing to disclose.
Special thanks to Dr. Peter Bradley for the antibody to detect the T. gondii mitochondria. The work was supported by National Institute of Health Grants AI072028 and AI107431 to D.G.M and a generous donation to New York Medical College for the study of tropical medicine.
Name of the material | Company | Catalog number | Comments | |
DMEM | Hyclone | SH3008101 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29101&productId=3255471&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=0 |
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Hyclone FBS | Thermo | SH3091003 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=11737973&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=0 |
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Hyclone L-glutamine | Thermo | SH3003401 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=3311957&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType =PROD&hasPromo=0 |
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Hyclone Pen strep | Thermo | SV30010 | https://www.fishersci.com/ecomm/servlet/fsproductdetail?storeId=10652&productId=1309668 6&catalogId=29104&matchedCat No=SV30010&fromSearch=1& searchKey=SV30010&highlightPro ductsItemsFlag=Y&endecaSearch Query=%23store%3DRE_SC%23nav%3D0%23rpp%3D25%23offSet%3D0%23keyWord%3DSV30010%2B%23searchType%3DPROD%23SWKeyList%3D%5B%5D&xrefPartType=From&savings= 0.0&xrefEvent=1407777949003_0 &searchType=PROD&hasPromo=0 |
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Hyclone Hanks BSS | Thermo | SH3003002 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=3064595&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=0 |
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LPS | LIST biologicals | 201 | http://www.listlabs.com/products-tech.php?cat_id=4&product_id=81&keywords =LPS_from_%3Cem%3EEscherichia_coli%3C/em%3E_O111:B4 |
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IFN-g | Pepro Tech Inc | 50-813-664 | https://www.fishersci.com/ecomm/servlet/itemdetail?itemdetail='item'&storeId=10652& productId=2988494&catalogId=29 104&matchedCatNo=50813664& fromSearch=1&searchKey=murine+ifn+pepro+tech&highlightProductsItemsFlag =Y&endecaSearchQuery=%23store%3DRE_SC%23nav%3D0%23rpp%3D25%23offSet%3D0%23keyWord%3Dmurine%2Bifn%2Bpepro%2Btech%23searchType%3DPROD%23SWKeyList%3D%5B%5D&xrefPartType=From&savings =0.0&xrefEvent=1407778210608_ 12&searchType=PROD&hasPromo =0 |
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Chamber slides | Thermo | 177402 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=2164545&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=0 |
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96-well optical plates | Thermo | 165306 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=3010670&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=0 |
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96-well tissue culture plates | 353072 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=3158736&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=0 |
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Tissue culture flast T25 | 156367 | https://www.fishersci.com/ecomm/servlet/fsproductdetail?storeId=10652&productId=127039 67&catalogId=29104&matchedCat No=12565351&fromSearch=1& searchKey=156367&highlightProdu ctsItemsFlag=Y&endecaSearchQu ery=%23store%3DRE_SC%23nav%3D0%23rpp%3D25%23offSet%3D0%23keyWord%3D156367%23searchType%3DPROD%23SWKeyList%3D%5B%5D&xrefPartType=From&savings =0.0&xrefEvent=1407778974800_ 0&searchType=PROD&hasPromo =0 |
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Ted Pella EM grade formaldehyde | 18505 | http://www.tedpella.com/chemical_html/chem3.htm#anchor267712 | ||
Triton X-100 | Fisher | BP151 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=3425922&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=1 |
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Alexa 488 – protein conjugation kit | Life Technologies | A20181 | http://www.lifetechnologies.com/order/catalog/product/A10235 | |
goat serum | MP Biomedicals | ICN19135680 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=2133236&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&crossRefData =ICN19135680=2&searchType =PROD&hasPromo=0 |
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Vectashield mounting media | Vector Labs | H1200 | https://www.vectorlabs.com/catalog.aspx?prodID=428 | |
FITC-conjugated dolichos | Vector Labs | FL-1031 | https://www.vectorlabs.com/catalog.aspx?prodID=188 | |
Antibody to LAMP1 | Developmental Studies Hybridoma Bank | http://dshb.biology.uiowa.edu/LAMP-1 | ||
LysoTracker | Life Technologies | L-7526 | https://www.lifetechnologies.com/order/catalog/product/L7526?ICID=search-product | |
C57BL6 mice | Jackson Laboratories | 664 | http://jaxmice.jax.org/strain/000664.html | |
gp91 phox knock out mice | Jackson Labaoratories | 2365 | http://jaxmice.jax.org/strain/002365.html | |
iNOS knock out mice | Jackson Laboratories | 2609 | http://jaxmice.jax.org/strain/002609.html | |
sodium nitroprusside | ACROS Organics | AC21164-0250 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=2627727&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=1 |
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DETA NONOate | ACROS Organics | AC32865-0250 | https://www.fishersci.com/ecomm/servlet/itemdetail?storeId=10652&langId=-1&catalog Id=29104&productId=2252389&dis type=0&highlightProductsItemsFlag =Y&fromSearch=1&searchType= PROD&hasPromo=1 |
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Monoclonal mouse anti-Toxoplasma gondii Ab | 10T19A | http://1degreebio.org/reagents/product/1069274/?qid=652947 |