Department of Bacteriology, Georg-August-University Göttingen, Kreuzbergring 57, D-37075 Göttingen, Germany
*Author for correspondence (e-mail: clueder{at}gwdg.de)
Accepted July 2, 2001
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SUMMARY |
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Key words: Apoptosis, Toxoplasma gondii, Poly(ADP-ribose) polymerase, Caspase, Mitochondria, Mcl-1
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INTRODUCTION |
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The obligate intracellular protozoan parasite Toxoplasma gondii is ubiquitously distributed and infects a wide range of warm-blooded hosts, including up to 30% of the human population worldwide (Holliman and Greig, 1997). Infection of immunocompetent humans is most often asymptomatic, but leads to lifelong persistence of the parasite (Gross et al., 1996). However, T. gondii may lead to life-threatening disease in fetuses or newborns from primarily infected mothers or after reactivation of dormant parasites in immunocompromised patients (i.e. those with AIDS or those under immunosuppressive therapy).
We (Goebel et al., 1999) and others (Nash et al., 1998) have recently reported that T. gondii downregulates apoptosis that has been induced by multiple stimuli in human and murine cell lines, respectively. An increased expression of heat shock protein 65 (HSP65) by peritoneal macrophages after infection has been correlated with reduced apoptosis of these cells (Hisaeda et al., 1997), and A1, an anti-apoptotic member of the Bcl-2 family, is upregulated in exudate cells during T. gondii-induced inflammation in the peritoneum (Orlofsky et al., 1999). However, detailed analyses of those mechanisms by which T. gondii interferes with apoptosis-inducing signalling pathways of the host cell have not yet been described.
Apoptosis may be initiated through receptor engagement by external stimuli, such as TNF- or FasL or by internal stimuli such as chemotherapeutic agents, irradiation, and serum or growth factor deprivation (Vaux and Strasser, 1996). These signals lead via different pathways to the activation of a family of cysteine proteases with specificity for aspartic acid residues, referred to as caspases (Thornberry and Lazebnik, 1998). Mitochondria play a critical role in the transduction of upstream pathways into the apoptotic effector cascade (Green and Reed, 1998). Release of cytochrome c from mitochondria into the cytosol and subsequent activation of the Apaf-1/procaspase 9-complex c have been shown to activate downstream caspases (Li et al., 1997; Pan et al., 1998). Furthermore, many proteins of the Bcl-2 family with either anti-apoptotic (e.g. Bcl-2, Bcl-xL or Mcl-1) or pro-apoptotic function (e.g. Bax, Bak or Bik) reside in the outer mitochondrial membrane (Adams and Cory, 1998). Activation of the caspase cascade finally leads to cleavage of a variety of target proteins with structural or regulatory function, including poly(ADP-ribose) polymerase (PARP), nuclear lamins, protein kinase C (PKC) and others, leading to disassembly of the cell.
Mechanisms of microbial interference with host cell apoptosis have been characterized for a variety of viruses and some bacteria (Liles 1997; Fan et al., 1998) and several anti-apoptotic genes have been identified (Barry and McFadden, 1998). However, little is known about the mechanisms by which more complex eukaryotic parasites interfere with apoptosis-inducing signalling. Here, we show that the anti-apoptotic activity of T. gondii was accompanied by interference with mitochondrial cytochrome c release and subsequent downregulation of caspase activation. Furthermore, the protein level of PARP was prominently downregulated by the parasite. This suggests that T. gondii has evolved different mechanisms that may contribute to the inhibition of host cell apoptosis.
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MATERIALS AND METHODS |
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Tachyzoites of the mouse-avirulent T. gondii strain NTE (Gross et al., 1991) were propagated in L929 fibroblasts as host cells. Tachyzoites were harvested after initiation of host cell lysis. For infection of HL-60 and U937 cells, tachyzoites were isolated from L929 cocultures as described (Goebel et al., 1999). Briefly, contaminating host cells were pelleted by centrifugation at 35 g for 5 minutes. The supernatant was then centrifuged at 1350 g for 10 minutes and tachyzoites were resuspended in RPMI 1640 (as above).
Infection with T. gondii and induction of apoptosis
For DNA fragmentation assays and western blot analyses, 1x106 HL-60 or U937 cells per well were cultured in 6-well tissue culture plates (Costar, Bodenheim, Germany), for RT-PCR analyses, 5x106 HL-60 or U937 cells were cultured in 90 mm tissue culture dishes (Nunc, Roskilde, Denmark), and for immunofluorescence microscopy, 2x105 HL-60 cells per well were seeded in 24-well plates (Costar) containing 13 mm round glass coverslips. Before infection with T. gondii and induction of apoptosis, HL-60 cells were treated for 24 hours with 5 nM phorbol 12-myristate 13-actetate (PMA; Sigma, Deisenhofen, Germany) to render cells adherent, and were then washed three times to remove PMA. HL-60 and U937 cells were infected with T. gondii at parasite to host cell ratios of 10:1 or 30:1; addition of parasites at these ratios routinely yielded infection rates of 10-15% and 40-50%, respectively, as revealed by microscopic analysis of HL-60 cells after immunofluorescence staining. Thirty minutes post infection (p.i.), apoptosis was induced in infected and uninfected HL-60 and U937 cells by treatment with 5 µg/ml actinomycin D (actD; Calbiochem, Bad Soden, Germany) or 40 ng/ml TNF- (Boehringer, Mannheim, Germany) in combination with 2 µg/ml cycloheximide (Sigma), respectively. Treated and untreated control cells were maintained for 8 hours at 37°C and 5% CO2 in saturated humidity.
DNA fragmentation assay
The DNA fragmentation assay was performed as described (Eldadah et al., 1996). Briefly, 2x106 HL-60 or U937 cells were lysed in 2 ml of 7 M guanidine hydrochloride. Genomic DNA was isolated using the Wizard® Plus Minipreps DNA Purification Kit as recommended by the manufacturer (Promega, Madison, WI). After elution from the Wizard® minicolumns, contaminating RNA was digested by incubation with 1 µg RNAse A (Sigma) for 30 minutes at 37°C. DNA was then electrophoretically separated in a 1.5% agarose gel and visualized by ethidium bromide staining. Results were quantified by densitometric analyses of bands corresponding to fragmentated DNA on a BioDoc II digital imaging system (Biometra, Göttingen, Germany).
Western blot analyses
The total cellular content of caspases 3, 8 and 9, PARP, nPKC, Bcl-2, Mcl-1 and actin was analysed by western blotting. Equal amounts of T. gondii-infected HL-60 and U937 cells or uninfected controls were washed in PBS (pH 7.4; Biochrom) and lysed in 50 mM Tris-HCl, pH 7.4, 150 mM NaCl, 1% Triton X-100, 0.5% sodium desoxycholate (NaDOC), 0.1% sodium dodecylsulfate (SDS), 10 µg/ml leupeptin, 1 µg/ml each of aprotinin and pepstatin A, and 1 mM each of PMSF and sodium orthovanadate. After 30 minutes on ice, the samples were centrifuged at 13,000 g for 15 minutes and equal amounts of supernatant were resolved in 10% (PARP) or 15% (all proteins except PARP) polyacrylamide gels by standard SDS-PAGE under reducing conditions. After semi-dry transfer to nitrocellulose, equal loading of each lane was confirmed by ponceau S staining (Sigma) and membranes were blocked with 5% nonfat dried milk, 0.2% Tween 20, 100 mM NaCl in 10 mM Tris-HCl, pH 7.4. Membranes were then incubated for 90 minutes with rabbit anti-caspase 3 polyclonal antibody (pAb; No. 65906E; 1:1500), mouse anti-caspase 8 pAb (No. 66231A; 1:250), rabbit anti-Mcl-1 pAb (No. 13656E; 1:1000), mouse anti-PARP mAb (clone C2-10; 1:2000; all Ab from Pharmingen, Hamburg, Germany), rabbit anti-caspase 9 pAb (H-83; 1:100), rabbit anti-PKC
pAb (C-20; 1:2000; both from Santa Cruz Biotechnology, Santa Cruz, CA), mouse anti-Bcl-2 mAb (clone 100; 3 µg/ml), or mouse anti-actin mAb (clone JLA20; 3 µg/ml; both from Calbiochem). Bound Ab were visualized with 0.04 µg/ml HRPO-conjugated F(ab')2 fragment goat anti-rabbit or anti-mouse IgG (Dianova, Hamburg, Germany), or with 0.05 µg/ml HRPO-conjugated goat anti-mouse IgM (Calbiochem) and ECL chemiluminescence detection as recommended by the manufacturer (Amersham Pharmacia Biotech). Signals were densitometrically quantified on a BioDoc II imaging system (Biometra).
To determine the subcellular distribution of cytochrome c, digitonin-soluble and -insoluble fractions of infected and uninfected HL-60 cells were prepared as described (Single et al., 1998). This method has been shown to separate cytosolic fractions from heavy organelles including mitochondria (Single et al., 1998). Briefly, 4x106 cells were resuspended in 125 µl PBS and mixed with an equal volume of 150 µg/ml digitonin (Fluka, Deisenhofen, Germany) in 0.5 M sucrose. After 30 seconds on ice, mitochondria were pelleted by centrifugation for 60 seconds at 14,000 g. The supernatants were saved as digitonin-soluble fractions, and pellets were lysed as described above for preparation of total cell lysates. After centrifugation at 13,000 g for 15 minutes, equal amounts of supernatants (digitonin-insoluble fractions) were separated together with the digitonin-soluble fractions by SDS-PAGE. Cytochrome c was detected by immunoblotting as described above using mouse anti-cytochrome c mAb (clone 7H8.2C12; 2 µg/ml; Pharmingen) and HRPO-conjugated F(ab')2 fragment goat-anti mouse IgG (as above). In parallel, mitochondrial contamination of digitonin-soluble extracts or extraction of control proteins from the mitochondria by digitonin lysis was controlled using a cytochrome c oxidase (COX)-specific mAb (subunit IV, clone 10G8-D12-C12; 2 µg/ml; Molecular Probes, Leiden, The Netherlands).
Semi-quantitative RT-PCR analyses
Total cellular RNA was isolated from T. gondii-infected HL-60 or U937 cells and uninfected controls using the Rneasy® Mini Kit as recommended by the manufacturer (Qiagen, Hilden, Germany). Reverse transcription and PCR were carried out by the OneStep RT-PCR protocol (Qiagen) using the following oligonucleotide primers: PARP forward 5'-AAGCCCTAAAGGCTCAGAAC-3'; PARP reverse 5'-TTGGGTGTCTGTGTCTTGAC-3'; ß-actin forward 5'-GTGGGGCGCCCCAGGCACCA-3'; ß-actin reverse 5'-CTCCTTAATGTCACGCACGATTTC-3'. To exclude amplification of contaminating genomic DNA, control reactions were performed by inhibition of reverse transcriptase activity. PCR products were electrophoresed on a 1.5% agarose gel and amplified DNA visualized by ethidium bromide staining. Results were quantified by densitometry using an digital imaging system (Biometra).
Immunofluorescence staining and confocal microscopy
The distribution of cytochrome c in T. gondii-infected and uninfected cells was morphologically analysed by triple immunofluorescence staining and confocal microscopy. Eight hours after induction of apoptosis with 5 µg/ml actinomycin D, infected and uninfected HL-60 cells were washed in PBS and fixed with 4% paraformaldehyde (Merck, Darmstadt, Germany) in PBS, pH 7.4 for 30 minutes at room temperature. After washing, cells were quenched for 10 minutes in 50 mM NH4Cl in PBS and permeabilized for 1 hour with 0.1 mg/ml saponin (Sigma, Deisenhofen, Germany) in PBS containing 1% bovine serum albumin (Sigma). Cells were then simultaneously incubated with mouse anti-cytochrome c mAb (clone 6H2.B4; 10 µg/ml; Pharmingen) and rabbit anti-Toxoplasma serum diluted in PBS with saponin and BSA. After 1 hour at room temperature, coverslips were washed and were then incubated for 1 hour in 1.4 µg/ml Cy3-conjugated F(ab')2 fragments donkey anti-mouse IgG and 6.5 µg/ml Cy5-conjugated F(ab')2 fragments donkey anti-rabbit IgG (secondary Ab from Dianova, Hamburg, Germany). After washing, apoptotic cells were visualized using the in situ terminal deoxynucleotidyl transferase-mediated dUTP nick end labelling (TUNEL) assay as recommended by the manufacturer (Boehringer Mannheim, Mannheim, Germany). Coverslips were mounted with Mowiol (Calbiochem, Schwalbach, Germany) and were examined by confocal laser scanning microscopy using Leica TCS SP2. For selected cells, 10 optical sections at intervals of 0.5 µm were generally recorded. To analyse the intracellular distribution of cytochrome c quantitatively, the optical sections from a selected cell preparation were superimposed, and the fluorescence intensity profile of the cytochrome c-labelling in apoptotic and non-apoptotic cells was determined.
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RESULTS |
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Since proteolytic activation of caspases in a cascade-like fashion is a central component in the execution of apoptosis (Thornberry and Lazebnik, 1998), we next analysed expression and cleavage of several key caspases in T. gondii-infected and uninfected cells by immunoblotting. Caspase 3 is one of the critical downstream members of the caspase family and is thought to be an essential effector of cell death (Thornberry and Lazebnik, 1998). Induction of apoptosis in HL-60 and U937 cells by treatment with actinomycin D or TNF- in combination with cycloheximide induced prominent activation of caspase 3 in non-infected cells, as indicated by the increase in active cleavage products and the decrease in inactive proform (Fig. 2A). After concomitant infection with T. gondii, however, proteolytic cleavage of the procaspase 3 into the active subunits was clearly diminished in both cell lines. Quantitative analyses by densitometry showed that the appearance of the active caspase 3 after induction of apoptosis decreased 3.4- or 3.2-fold in T.gondii-infected compared with that seen in uninfected HL-60 and U937 cells, respectively, thus indicating interference of the parasite with activation of the caspase cascade (Fig. 2D). Cleavage of the effector caspase 3 may be mediated by activation of upstream initiator caspases 8 and 9, which are associated with apoptosis induced by death receptor engagement or apoptosis-inducing cytotoxic agents, respectively (Thornberry and Lazebnik, 1998). Therefore, we asked which of these caspases might be affected by T. gondii. The amount of inactive procaspase 9 diminished after induction of apoptosis in HL-60 and U937 cells; however, this decrease was inhibited 2.3-fold in both cell lines after concomitant infection with T. gondii (Fig. 2B,D). Although the antibody used for these analyses only recognized the proform but not the active subunits of caspase 9, these data suggested that proteolytic cleavage of caspase 9 during apoptosis in HL-60 and U937 cells is downregulated by T. gondii. No differences were observed in the appearance of the inactive procaspase 8 after treatment of infected and uninfected HL-60 cells with actinomycin D, which rules out an involvement of caspase 8 in actinomycin D-induced apoptosis in HL-60 cells (Fig. 2C). Furthermore, T. gondii only slightly altered the protein level of procaspase 8 in untretaed as well as treated HL-60 cells (Fig. 2D). By contrast, the amount of inactive caspase 8 considerably decreased in U937 cells treated with TNF-
in combination with cycloheximide, compared with that in untreated control cells (Fig. 2C). However, this decrease was even more prominent in parasite-infected cells than in uninfected ones (Fig. 2D), suggesting that T. gondii does not abrogate proteolytic cleavage of caspase 8 after receptor engagement by TNF-
. Taken together, these results indicated that T. gondii partially inhibits cleavage of caspase 3 and 9, but not caspase 8 after induction of apoptosis in HL-60 and U937 cells.
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Inhibition of mitochondrial cytochrome c release by T. gondii
To further characterize those upstream signalling pathways by which T. gondii may downregulate activation of the caspase cascade, we next analysed release of cytochrome c from the mitochondria into the cytosol, a process that regulates caspase activation by multiple apoptosis inducers (Green and Reed, 1998; Li et al., 1997). Therefore, HL-60 were fractionated into digitonin-soluble and -insoluble fractions containing cytosolic and mitochondrial proteins, respectively (Single et al., 1998), which were subsequently analysed by immunoblotting. In untreated cells (i.e. those cultured without actinomycin D), cytochrome c was almost exclusively detected in the digitonin-insoluble fraction and was not or only faintly visible in digitonin-soluble fractions, suggesting a mitochondrial localization (Fig. 5A). Furthermore, contamination of the digitonin-soluble extracts with mitochondria, as well as extraction of mitochondrial proteins by the digitonin lysis was excluded since the control protein COX was detected in the digitonin-insoluble fraction only (Fig. 5B). Treatment of uninfected HL-60 cells with actinomycin D induced release of cytochrome c from the mitochondria into the cytosol, as indicated by the prominent decrease of cytochrome c in the digitonin-insoluble fraction and a simultaneous increase in the digitonin-soluble fraction (Fig. 5A). However, in parasite-infected cells, the actinomycin D-induced cytochrome c redistribution was considerably diminished compared with that in uninfected control cells, indicating that T. gondii inhibits mitochondrial cytochrome c-release during apoptosis.
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DISCUSSION |
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Consistent with our previous findings (Goebel et al., 1999), T. gondii dose-dependently downregulated host cell apoptosis in human-derived HL-60 and U937 cells treated with different pro-apoptotic stimuli. Nevertheless, it should be mentioned that even after addition of T. gondii at the highest parasite to host ratio, apoptosis was not completely eliminated. Since protection against apoptosis by T. gondii requires the presence of intracellular parasites (Goebel et al., 1999), this finding probably reflects the fact that, after addition of T. gondii at a parasite to host ratio of 30:1, infection rates do not exceed 50% (data not shown), the remaining parasite-negative host cells still being susceptible to induction of apoptosis.
Activation of caspases represents a central step in the apoptosis signalling cascade and transduces regulatory upstream signals into the cell death-executing machinery. Our results clearly show that T. gondii interferes with this caspase cascade by downregulating activation of caspase 3 and 9. Interestingly, this was not only observed after treatment of HL-60 cells with actinomycin D but also after treatment of U937 cells with TNF-. This confirms recent findings that the mitochondria/caspase 9 pathway is activated not only by internal pro-apoptotic stimuli but also during receptor-mediated induction of apoptosis (Kuwana et al., 1998; Budihardjo et al., 1999; Scaffidi et al., 1999), and amplifies receptor-mediated apoptosis at least under certain conditions (Scaffidi et al., 1999). In contrast to caspase 3 and 9, proteolytic cleavage of procaspase 8 after treatment of U937 cells with TNF-
and cycloheximide was even enhanced after T. gondii infection, indicating that the parasite downregulates proteolysis of distinct caspases only, rather than generally alters caspase activation. Despite continuous activation of caspase 8, apoptosis in U937 cells was nevertheless downregulated after infection, indicating that induction of apoptosis under these conditions may mainly involve the mitochondria/caspase 9 pathway rather than direct activation of caspase 3. This is supported by Tafani et al., who show that apoptosis can indeed be prevented by inhibition of the mitochondrial pathway despite continuous activation of caspase 8 (Tafani et al., 2000). However, it should be mentioned that induction of apoptosis in U937 cells by TNF-
requires the presence of low concentrations of cycloheximide (Vanags et al., 1996), the contribution of which to the signalling pathway is unknown.
Activation of the caspase 9/caspase 3 pathway during apoptosis involves release of mitochondrial cytochrome c into the cytoplasm, which then leads to dATP-dependent formation of an Apaf1/caspase 9-complex and to activation of caspase 9 (Li et al., 1997; Pan et al., 1998). Results from both subcellular fractionation analyses and confocal microscopy indicated that T. gondii inhibits such mitochondrial cytochrome c release. On the single cell level, the presence of intracellular parasites positively correlated with a mitochondrial distribution of cytochrome c and the absence of DNA strand breaks as a characteristic feature of apoptosis. This confirms and extends our previous findings that protection of HL-60 cells from apoptosis requires the presence of viable, but not neccessarily replicating, intracellular parasites (Goebel et al., 1999). Thus, intracellular T. gondii might secrete a parasitic factor that mediates inhibition of mitochondrial cytochrome c release, leading to decreased activation of the caspase 9/caspase 3 pathway. Alternatively, active invasion by the parasite (Dobrowolski and Sibley, 1996) may irreversible modify the host cell physiology, which results in protection against induction of apoptosis. Downregulation of host cell apoptosis induced by different pro-apototic stimuli in human-derived cell lines via inhibition of cytochrome c release has been similarly described for Chlamydia trachomatis and was correlated with the presence of viable intracellular chlamydia (Fan et al., 1998).
Proteins of the Bcl-2 family are known to regulate mitochondria-associated induction of apoptosis (Adams and Cory, 1998). For example, Bcl-2 inhibits apoptosis by preventing the translocation of cytochrome c into the cytoplasm (Yang et al., 1997; Kluck et al., 1997), and a variety of virus-encoded Bcl-2 homologues have been shown to modulate host cell apoptosis after infection (Barry and McFadden, 1998). However, expression of Bcl-2 was not altered after infection by T. gondii. By contrast, parasitic infection increased the steady state levels of Mcl-1 protein (Kozopas et al., 1993), another anti-apoptotic member of the Bcl-2 protein family, after induction of apoptosis in HL-60 and U937 cells. In HL-60 cells, an increase of Mcl-1 has been associated with inhibition of apoptosis by downregulating mitochondrial cytochrome c release (Wang and Studzinski, 1997) and may thus contribute to the anti-apoptotic activity of T. gondii, at least in this cell type. Interestingly, upregulation of A1, a protein with similarity to Mcl-1 (Lin et al., 1993), has recently been described in exudate cells from T. gondii-infected mice (Orlofsky et al., 1999), indicating that additional members of the Bcl-2 family may also be involved in T. gondii-induced inhibition of apoptosis. In addition, these results demonstrate that upregulation of proteins of the Bcl-2 family occurs not only after parasitic infection in vitro but also in T. gondii-infected mice in vivo. However, the exact contribution of Mcl-1 or similar proteins to the inhibition of host cell apoptosis by T. gondii awaits further clarification.
Execution of apoptosis involves caspase-mediated cleavage of several target proteins leading to disassembly of the cell. Reduced activation of the effector caspase 3 after infection with T. gondii, as described here, partially inhibited cleavage of PKC, indicating that parasitic interference with the caspase cascade is of functional relevance to proteolysis of target proteins. Interestingly, our initial attempts to determine the extent of PARP cleavage, a commonly used marker for apoptosis research (Duriez and Shah, 1997) revealed that T. gondii prominently downregulates the protein levels of PARP in HL-60 and U937 cells, irrespective of whether these cells have been treated with pro-apoptotic stimuli or left untreated. Since PARP mRNA levels were not altered by T. gondii, such downregulation may be achieved post-transcriptionally; however, the detailed mechanisms of this interference needs further investigations. Although these results hampered the determination of PARP cleavage in infected and uninfected cells after induction of apoptosis, our novel finding of decreased PARP protein levels after parasitic infection is nevertheless of major interest since it not only may contribute to T. gondii-induced inhibition of host cell apoptosis, but also may be of fundamental relevance for the host-parasite interaction. PARP is thought to be involved in a variety of cellular functions by catalyzing the transfer of ADP-ribose from NAD+ to acceptor proteins and by its activity as a transcriptional coactivator (Jacobsen and Jacobsen, 1999; Meisterernst et al., 1997). Although the role of PARP during apoptosis is not completely understood (Le Rhun et al., 1998), recent evidence suggests that under conditions of excessive DNA damage PARP promotes cell death (Jacobsen and Jacobsen, 1999). Indeed, depletion or inhibition of PARP has been shown to protect different cell lines, including HL-60 and U937 cells, against apoptosis induced by a variety of pro-apoptotic stimuli (Nosseri et al., 1994; Tanaka et al., 1995; Shiokawa et al., 1997; Simbulan-Rosenthal et al., 1998; Pacini et al., 1999). Downregulation of PARP expression by T. gondii may thus contribute to parasite-induced inhibition of host cell apoptosis either by inhibiting excessive depletion of cellular NAD+ and ATP (Simbulan-Rosenthal et al., 1998) or by preventing irreversible binding of the 24 kDa PARP fragment to DNA strand breaks (Duriez and Shah, 1997). Further experiments will clarify the exact contribution of reduced PARP expression on inhibition of apoptosis by T. gondii as well as on the parasite-host interaction in general.
In conclusion, T. gondii interferes with at least two different components of the apoptosis-inducing signalling cascade of its host cell. Evolution of different mechanisms to downregulate host cell apoptosis possibly explains how parasite-induced protection against a variety of apoptosis inducers may be achieved.
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ACKNOWLEDGMENTS |
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