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Previous Article | Next Article 
Infection and Immunity, May 1999, p. 2233-2240, Vol. 67, No. 5
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Replication of Toxoplasma gondii, but Not
Trypanosoma cruzi, Is Regulated in Human Fibroblasts
Activated with Gamma Interferon: Requirement of a Functional
JAK/STAT Pathway
Isabela Penna
Cerávolo,1
Andréa
C. L.
Chaves,1
Cláudio A.
Bonjardim,2
David
Sibley,3
Alvaro J.
Romanha,1 and
Ricardo
T.
Gazzinelli4,5,*
Cellular and Molecular Parasitology
Laboratory1 and Chagas' Disease
Laboratory,5 Centro de Pesquisas René
Rachou, FIOCRUZ, and Viruses Laboratory, Microbiology
Department,2 and Biochemistry and
Immunology Department,4 ICB, UFMG, Belo
Horizonte, Brazil, and Molecular Microbiology Department,
Washington University, St. Louis, Missouri3
Received 28 September 1998/Returned for modification 18 November
1998/Accepted 12 February 1999
 |
ABSTRACT |
To study the role of tryptophan degradation by indoleamine
2,3-dioxygenase (INDO) in the control of Trypanosoma cruzi
or Toxoplasma gondii replication, we used human fibroblasts
and a fibrosarcoma cell line (2C4). The cells were cultured in the
presence or absence of recombinant gamma interferon (rIFN-
) and/or
recombinant tumor necrosis factor alpha (rTNF-
) for 24 h and
were then infected with either T. cruzi or T. gondii. Intracellular parasite replication was evaluated 24 or
48 h after infection. Treatment with rIFN- and/or rTNF- had
no inhibitory effect on T. cruzi replication. In contrast,
54, 73, or 30% inhibition of T. gondii replication was
observed in the cells treated with rIFN- alone, rIFN- plus rTNF-, or TNF- alone, respectively. The replication of T. gondii tachyzoites in cytokine-activated cells was restored by
the addition of extra tryptophan to the culture medium. Similarly,
T. gondii tachyzoites transfected with bacterial tryptophan
synthase were not sensitive to the microbiostatic effect of rIFN-.
We also investigated the basis of the cytokine effect on parasite
replication by using the three mutant cell lines B3, B9, and B10
derived from 2C4 and expressing defective STAT1 (signal transducer
and activator of transcription), JAK2 (Janus family of cytoplasmic
tyrosine kinases), or JAK1, respectively, three important elements of a signaling pathway triggered by rIFN-. We found that rTNF- was able to induce low levels expression of INDO mRNA in the parental cell
line, as well as the cell line lacking functional JAK2. In contrast to
the parental cell line (2C4), rIFN- was not able to induce the
expression of INDO mRNA or microbiostatic activity in any of the mutant
cell lines. These findings indicate the essential requirement of the
JAK/STAT pathway for the induction of high levels of INDO mRNA,
tryptophan degradation, and the anti-Toxoplasma activity
inside human nonprofessional phagocytic cells.
| |
INTRODUCTION |
Several of the gene products and
functions induced by gamma interferon (IFN-) in either professional
or nonprofessional phagocytic cells (PPC and NPPC) have been implicated
in resistance to microbial infection. In macrophages or PPC the
activation by IFN- leads to the production of reactive oxygen
intermediates (31) and reactive nitrogen intermediates
(1, 16), the generation of leukotrine derivatives
(54), and tryptophan degradation (8, 35), all of
which are involved in the control of intracellular pathogens. Thus, the
growth of different intracellular protozoa, such as
Leishmania spp., Toxoplasma gondii, and
Trypanosoma cruzi (28, 29, 30, 38, 55), is
tightly regulated inside macrophages activated by IFN-. Many of
these microbiostatic-microbicidal functions induced by IFN- have
also been shown to be potentiated by tumor necrosis factor alpha
(TNF-) (16, 23).
In human NPPC, indoleamine 2,3-dioxygenase (INDO) appears to be the
main enzyme induced by IFN- and is implicated in the control of the
intracellular replication of T. gondii tachyzoites (35). INDO is the first enzyme in a major pathway
responsible for the degradation of tryptophan. More specifically,
this enzyme catalyzes the oxidative decyclization of
L-tryptophan to N-formylkynurenine (36,
48). In both PPC and NPPC, inhibition of intracellular parasite
replication induced by IFN- can be reversed by the addition of
tryptophan to the tissue culture medium (17, 35). These results indicate that the induction of INDO by IFN- leads to tryptophan depletion and to the interruption of parasite replication inside the vertebrate host cells (9, 10, 49).
Since, like T. gondii tachyzoites, the T. cruzi
amastigotes can also replicate inside most nucleated cells from their
vertebrate hosts, it is tempting to speculate that not only macrophages
but also NPPC may display mechanisms that will lead to resistance to
infection with this latter parasite. In this study, we proposed to
investigate the regulation of T. cruzi replication inside
NPPC of human origin activated with rIFN- and/or rTNF-. T. gondii parasites were used as a control since their replication is
known to be controlled inside human NPPC after activation with IFN-. In addition, mutant cell lines were used to test the effect of different elements from the signaling pathway(s) triggered by recombinant IFN- [rIFN-] on the induction of INDO and the
control of intracellular protozoa inside NPPC. Our results, show that (i) in contrast to T. gondii, T. cruzi parasites
can grow even in the presence of low levels of tryptophan inside NPPC
cells activated with rIFN- alone or in combination with rTNF-;
(ii) rTNF- triggers low levels of INDO mRNA, which was associated with low microbiostatic activity against T. gondii; (iii)
rTNF- also increased, in an additive manner, the effect of IFN-
on the induction of INDO mRNA as well as on tachyzoite growth
regulation inside cells from the fibroblast lineage; and (iv) JAK1
(Janus family of cytoplasmic tyrosine kinases), JAK2, and STAT1
(signal transducer and activator of transcription) are all required for the maximal induction of INDO mRNA, tryptophan degradation, and the
control of parasite replication by rIFN- alone or when added with
rTNF-.
| |
MATERIALS AND METHODS |
Cell lines.
The human fibrosarcoma cell lines 2C4, B3, B9,
and B10 and the human foreskin fibroblast line CRL1634 (a gift from
Alan Sher, National Institute of Allergy and Infectious Diseases,
National Institutes of Health) were used.
The mutants (B3, B9, and B10) were selected from the 2C4 human cell
line, which was derived from a human fibrosarcoma HT1080 (5, 24,
57). The mutant cell lines were mutagenized with ICR 191 (acridine mutagen; Sigma Chemical Co., St. Louis, Mo.). After five
rounds of mutagenesis, the cells were fluorescence activator cell
sorted and then were grown and clonally selected in the presence of
IFN- (51). Thus, the mutants termed B3, B9, and B10 were
independent isolates derived from 2C4 (5). B3 was defective
in STAT1 and B10 and B9 were defective in JAK1 and JAK2,
respectively, three important elements of a signaling pathway triggered
by IFN- (6, 11, 32, 53). The genotypes of these cells
(gene deletions) were all confirmed by genetic crosses involving
mutants from the same and from different complementation groups, as
well as by biochemical analysis (5, 49). Further, by
measuring the cytokine-induced expression of membrane surface proteins
(e.g., transfected CD2 and major histocompatibility complex class I and
class II), the steady-state levels of 9-27,2',5'-oligoadenylate synthetase, and the guanylate binding protein mRNAs, we confirmed the
expected phenotype of the B3, B9, and B10 cell lines. Thus, we showed
that B3 and B10 are unresponsive to both IFN type 1 (IFN-/
) and
type 2 (IFN-), whereas B9 conserved intact the IFN type 1 signaling
pathway (5).
The cells were grown in Dulbecco modified Eagle medium (DMEM; GIBCO
Laboratories, Grand Island, N.Y.) or RPMI 1640 medium (GIBCO) and
supplemented with 10% heat-inactivated fetal bovine serum, 5 µM
L-glutamine, 100 IU of penicillin and 100 µg of
streptomycin per ml, and 25 mM of HEPES buffer (pH 7.3). The tryptophan
concentrations in the DMEM and RPMI media were 16 mg (78.4 µM) and 5 mg (24.5 µM) per liter, respectively. All cell lines were cultured at
37°C in humidified air containing 5% CO2. The cells were
counted in a Neubauer hemocytometer after trypsin treatment, and their
viability was assessed by trypan blue exclusion.
Parasites.
The Y strain of T. cruzi
(44) and the RH strain of T. gondii were used in
the parasite growth assays. An RH strain transfected with the
tryptophan synthase (TS) gene from Escherichia coli
(43) was used in some experiments. Both parasites were
maintained by serial passages in 2C4 human fibroblast monolayer
cultures. The T. cruzi trypomastigote and T. gondii tachyzoite forms were obtained on days 5 and 2 of cell
culture, respectively.
T. gondii and T. cruzi cell
infection.
Confluent cells were trypsinized (0.034% trypsin in
0.1% EDTA; both from Sigma), added to eight-well tissue culture
chamber slides (Nunc, Inc.) in duplicates at a final concentration of 3 × 104 cells/well in 430 µl of DMEM or RPMI in the
presence or absence of cytokines, and incubated at 37°C in 5%
CO2 at 95% humidity for 24 h. The medium was changed
after 24 h, and T. gondii or T. cruzi was
added at a ratio of 3/1 and 10/1 parasites per cell, respectively, in a
volume of 200 µl, with or without the cytokines. After 3 h of
infection for T. gondii and 6 h for T. cruzi, the parasites that had not infected the cells were removed
by washing, replaced with 430 µl of fresh medium, and further
incubated with or without the cytokines for 24 or 48 h at 37°C
and 5% CO2. In the case of the T. cruzi, the
infected cells were incubated at 33°C in 5% CO2 at 95%
humidity (4). After 24 or 48 h of incubation, the
chambers were washed with phosphate-buffered saline (PBS), fixed with
methanol, stained with May-Grunwald-Giemsa, and mounted on slides. The
results evaluated under light microscopy were expressed as an infection
index. The infection index is the average number of parasites per 100 cells obtained from three independent experiments performed in duplicate.
In order to verify the effect of exogenous tryptophan in restoring the
parasite replication, the 2C4 cells activated with cytokines were
cultured as described above, in the presence or absence of exogenous 1 mM L-tryptophan (Sigma), and then infected with either
tachyzoite or trypomastigote forms. The intracellular parasites were
counted at 24 h postinfection. To further certify a tryptophan
requirement for the intracellular growth of T. gondii or
T. cruzi, parasite replication was evaluated in a culture
medium prepared from a kit supplied by GIBCO that had all the
components of a complete medium except tryptophan. The tryptophan-free
medium was supplemented with 3% dialyzed heat-inactivated fetal bovine serum and 100 µM indole. Parasite intracellular growth was evaluated at 24 and 48 h postinfection.
Cytophatic assay.
Vaccinia virus strain WR was a gift from
C. Jungwirth (University of Würzburg, Würzburg, Germany).
It was propagated in Vero cells and purified as previously described by
Joklik (19). The 2C4 parental and mutant cell lines were
cultured as described above at a density of 1.5 × 104/well on a 24-well plate and, when 90% of confluence
was reached, rIFN- (500 IU/ml) was added overnight. Fresh medium
supplemented with rIFN- was added to the cultures, which were then
infected with vaccinia virus at a 0.01 multiplicity of infection for
2 h. The infection was stopped by aspirating and replacing the
medium with 2 ml of fresh medium. After 30 h, the virus plaques
were visualized by adding 1 ml of 0.3% crystal violet in formalin
solution (7).
Cytokines.
Human rIFN- and rTNF-, with a specific
activity of 3 × 107 U/mg of protein, were provided by
Genentech, Inc. (San Francisco, Calif.) and were maintained at 4°C.
The concentrations used in the assays were 900 IU/ml for rIFN- and
60 IU/ml for rTNF-. These concentrations were chosen after previous
titrations of the cytophatic effect of the vesicular stomatitis virus
in 2C4 cells.
INDO mRNA expression assay.
In order to verify the induction
of INDO mRNA expression, 75-cm2 culture flasks containing
2 × 106 to 5 × 106 cells were used.
Briefly, the cells were incubated in the presence or absence of
cytokines for 14 to 16 h. The medium was discarded, and the cells
were washed with PBS. Total RNA was extracted with TRIzol (GIBCO)
according to the manufacturer's instructions. The cDNA synthesis was
obtained in a final volume of 100 µl containing 200 U of reverse
transcriptase (RT) obtained from Moloney murine leukemia virus
(Pharmacia), 200 mM concentrations of each deoxynucleoside triphosphate
(Promega), 2.5 µl of buffer (0.1 M MgCl2, 0.5 M Tris-HCl, 1 mM DTT, 2 mg of bovine serum albumin per ml; pH 7.2 at 20°C) (Boehringer Mannheim), 240 pmol of oligo-dT10 (Boehringer
Mannheim) per µl, 0.1 M dithiothreitol (Bio-Rad), 1 U of the RNase
inhibitor RNasin (Promega) per µl, and 0.4 µg of total RNA. The
cDNA samples were stored at 
20°C.
The INDO mRNA and glyceraldehyde-3-phosphate dehydrogenase
(GAPDH) were detected in the host cells by RT-PCR assays. The
primers 5'-AGT TGA GAA GTT AAA CAT GC-3' and 5'-CAT GAT CGT GGA TTT GGT GA-3' were used to detect INDO mRNA. The expected fragment size was 487 bp. The mRNA expression of the human housekeeping gene GAPDH was used
as a reference for the inducible INDO. The primers 5'-GTG GTG AAG CAG
GCG TCG-3' and 5'-GAC TGA GTG TGG CAG GGA-3' were used to detect GAPDH
mRNA expression. The expected fragment size was 311 bp. The RT-PCR
program consisted of 30 cycles with an initial denaturation at 95°C
for 5 min, annealing at 55°C for 1 min, extension at 72°C for 1 min, and a final annealing of 1 min at 55°C and an extension at
72°C for 5 min. The amplification was carried out in a thermocycler
(PTC 100; MJR Research) in a final volume of 10 µl containing 0.5 U
of Taq DNA polymerase (CENBIOT, RS, Porto Alegre, Brazil),
200 mM concentrations of each deoxynucleoside triphosphate, 1.5 mM
MgCl2, 50 mM KCl, and 10 mM Tris-HCl (pH 8.5), together
with 10.0 and 1.0 pmol of the INDO and GAPDH primers, respectively. The
reaction mixture was overlaid with 20 µl of mineral oil. After
amplification, 3 µl of the products was mixed with 3 µl of a 2×
sample buffer (0.25% bromophenol blue, 0.25% xylene cyanol, 30%
glycerol) and subjected to electrophoresis through a 6% nondenaturing
polyacrylamide gel. Gels were fixed with 10% ethanol-0.5% acetic
acid for 10 min, and the bands were revealed by staining with 0.2%
silver nitrate for 10 min with 0.75 M NaOH-0.1 M formaldehyde for 10 min as previously described (40).
TS-transfected T. gondii.
The expression of the TS in
the transgenic strain of T. gondii (43) was
confirmed by PCR. The reaction components were the same as those
described for INDO and GAPDH except for the use of 1.0 pmol of primers
5'-CCC CTA TTT TGG TGA GTT TG-3' and 5'-CCC CTA TTT TGG TGA GTT TG-3'
and either 1.0 or 10.0 ng of template DNA. The expected fragment size
was 1,155 bp. The PCR program consisted of 30 cycles, with an initial
denaturation at 95°C for 5 min, annealing at 50°C for 1 min, and
extension at 72°C for 1 min, followed by annealing at 50°C for 1 min and a final extension of 5 min.
Statistical analysis.
Differences between groups were
assessed with the Student t test. P values of
<0.05 were considered statistically significant.
| |
RESULTS |
Differential regulation of T. cruzi and T. gondii growth in rIFN- activated NPPC cells through tryptophan
degradation.
In order to study the regulation of parasite growth
inside NPPC, we used the fibrosarcoma cell line (2C4). Initially, we
compared the ability of human foreskin fibroblasts (Fig.
1A) and the 2C4 cell line (Fig. 1B),
exposed to rIFN- and/or rTNF-, to control T. gondii
and T. cruzi replication. The human fibroblasts or 2C4 cells
were cultured in the absence or presence of the cytokines rIFN- (900 IU/ml) and/or rTNF- (60 IU/ml) for 24 h and then infected with
either T. cruzi trypomastigotes or T. gondii
tachyzoites. The cell culture was interrupted at 48 h
postinfection, and the intracellular parasites were counted. The
results presented on Fig. 1A (human foreskin fibroblasts) and 1B (2C4
cell line) and illustrated in Fig. 1C (2C4 cell line), show that
activation of either human fibroblasts or 2C4 cells with rIFN-
resulted in a strong inhibitory effect of intracellular tachyzoite
growth. The rTNF- alone had a persistent, small inhibitory effect on T. gondii growth, which was observed in different
experiments. However, this difference was not statistically significant
within a single experiment. The addition of rIFN- and rTNF-
resulted in an additive inhibitory effect on the tachyzoite growth.
Interestingly, activation of either human foreskin fibroblasts or the
2C4 cell line with rIFN- and/or rTNF- had no effect on the
intracellular growth of T. cruzi amastigotes.
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FIG. 1.
(A) Effect of rIFN- (900 IU/ml) and/or rTNF- (60 IU/ml) on intracellular parasite replication in human foreskin
fibroblasts. The replication was evaluated 48 h postinfection. An
asterisk indicates a result statistically different from the control
group (P < 0.05). Results indicate the means ± the standard errors of the means from two independent experiments done
in duplicate. (B) Effect of rIFN- (900 IU/ml) and/or rTNF- (60 IU/ml) on intracellular parasite replication in 2C4 cells. The
replication was evaluated at 48 h postinfection. An asterisk
indicates a result statistically different from the control group
(P < 0.05). Results indicate the means ± the
standard errors of the means from three independent experiments done in
duplicate. (C) Illustration of rIFN- effect on intracellular
replication of T. gondii tachyzoites and T. cruzi
amastigotes. Note that, in contrast to T. gondii, T. cruzi growth was observed in the presence or absence of
rIFN-.
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Because previous studies have demonstrated that the activation of human
NPPC with IFN- results in degradation of the intracellular pool of
tryptophan (10, 35, 36), which is responsible for the
inhibition of parasite replication, we decided to repeat the above
experiment without tryptophan. The 2C4 cell line was cultured in
regular medium or in medium lacking tryptophan in the presence or
absence of rIFN- and/or rTNF- for 24 h and was then infected with either T. gondii (Fig.
2A) or T. cruzi (Fig. 2B). In
agreement with early studies (35), tachyzoite growth was
largely inhibited in the tryptophan-free medium even in absence of
cytokines. A small but not statistically significant effect on T. cruzi growth was observed in cells cultured in the absence of
tryptophan. Thus, our data indicate that T. cruzi
amastigotes presented an equal ratio of parasite replication at both
low and high levels of tryptophan inside the host cells. Consistent
with the hypothesis that tryptophan degradation mediates the inhibition
of tachyzoite growth induced by rIFN-, we observed that in the
presence of an excess amount of tryptophan, the inhibitory effect of
intracellular tachyzoite growth induced by either rIFN- or rIFN-
plus rTNF- was reversed (Fig. 3).
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FIG. 2.
Effect of the absence of L-tryptophan
(L-Trp) in 2C4 cells stimulated with rIFN- (900 IU/ml) and/or
rTNF- (60 IU/ml) and infected with (A) T. gondii or (B)
T. cruzi. The cells and parasites were maintained without
L-tryptophan as described in Materials and Methods. The
replication was evaluated 24 h postinfection. An asterisk
indicates a result statistically different from the control group
(P < 0.05). Results indicate the means ± the
standard errors of the means from three independent experiments done in
duplicate.
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FIG. 3.
Effect of the addition of L-tryptophan
(L-Trp) on the intracellular replication of T. gondii
tachyzoites in 2C4 cells activated with rIFN- (900 IU/ml) and/or
rTNF- (60 IU/ml). Tryptophan was added to the culture medium at a
final concentration of 1 mM immediately after the parasite infection,
and the replication was evaluated 24 h later. An asterisk
indicates a result statistically different from the control group
(P < 0.05). Results indicate the means ± the standard
errors of the means from three independent experiments done in
duplicate.
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We also tested the ability of T. gondii parasites
transfected with the enzyme TS from E. coli to survive
inside 2C4 cells under rIFN- stimulation. The results presented in
Fig. 4 show that, in contrast to the wild
type, the replication of transgenic parasites was not sensitive to NPPC
exposure to rIFN- and/or rTNF- in the presence (Fig. 4A) or in
the absence of tryptophan (Fig. 4B). Figure 4C shows the detection of
the TS gene by PCR by using DNA extracted from wild-type tachyzoites
(lanes 1 and 2), transfected parasites (lanes 3 and 4), E. coli (lanes 5 and 6), and a negative control of the PCR reaction
(lane 7). In contrast to transfected parasites and E. coli,
PCR with DNA from wild-type parasites did not yield a PCR product of
the predicted size (1,155 bp).
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FIG. 4.
Comparison of effects of rIFN- (900 IU/ml) and/or
rTNF- (60 IU/ml) on 2C4 human fibroblasts infected with wild-type or
transfected strains of T. gondii and maintained in the
presence (A) or in the absence (B) of L-tryptophan (L-Trp).
Both strains were maintained in tryptophan-free medium. RPMI was
supplemented with 3% dialyzed heat-inactivated fetal bovine serum and
100 µM indole. The replication was evaluated 24 h after
infection. An asterisk indicates a result statistically different from
the control group (P < 0.05). Results indicate the
means ± the standard errors of the means from three independent
experiments done in duplicate. (C) PCR products of TS from E. coli. PCR was performed as described in Materials and Methods. The
PCR product (3 µl) was electrophoresed in 6% polyacrylamide gel and
silver stained. DNA of bacteriophage  X digested by endonuclease
HaeIII was used as a molecular size marker. Lanes: 1 and 2, DNA from T. gondii RH wild-type strain, 1 and 10 ng,
respectively; 3 and 4, T. gondii TS-transfected strain, 1 and 10 ng, respectively; 5 and 6, E. coli, 1 and 10 ng,
respectively; 7, negative control (no DNA added). An 1,155-bp fragment
was expected.
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Study of the involvement of the JAK/STAT pathway in the induction
of both INDO mRNA expression and antiparasite effector function by
IFN-.
To further investigate the ability of rIFN- to induce
INDO expression and the regulation of parasite expression in NPPC, we
used three mutant cell lines, derived from 2C4 line, that have specific
defects on the IFN- signaling pathway. As shown in Fig. 5, the mutant cell lines B3, B9, and B10
are defective in STAT1, JAK2, and JAK1, respectively. Recent studies
have demonstrated that cells lacking functional JAK1 can exhibit
substantial expression of genes induced by IFN-. However, the
antiviral activity is only exhibited in cells which have functional
JAK1, JAK2, and STAT1 (15, 18, 45). We also tested cells
lacking different components from the JAK/STAT pathway (Fig. 5) in
their ability to control viral replication (Fig.
6A), T. gondii tachyzoite
growth (Fig. 6B), and INDO mRNA expression (Fig. 6C). Interestingly, we
found that JAK2-deficient cell line (B9) can express low levels of INDO
mRNA in response to rTNF- but not in response to IFN-. As with
the antiviral activity, maximal induction of INDO mRNA and control of
tachyzoite replication was only observed in cells with functional JAK1
and JAK2 (and STAT1).
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FIG. 6.
(A) Cytophatic effect of vaccinia virus infectivity
assay in parental 2C4 and mutant B3 and B10 cells. Row a shows the
controls, in duplicate, with the three cell lines without vaccinia
virus and rIFN-. b1, c1, and d1 show the protective effect of
rIFN- (500 IU/ml) against vaccinia virus in 2C4 cells. b2 and c2
show the viral effect on 2C4 cells without rIFN-. d2 shows rIFN-
plus 2C4 cells. b3, c3, and d3 show the viral effect on the B3 mutant
cell line plus rIFN-. b4 and c4 show the effect of the virus on the
mutant B3 cells. d4 shows rIFN- plus B3 cells. b5, c5, and d5 show
the viral effect on the B10 mutant cell line plus rIFN-. b6 and c6
show the viral effect on the B10 cells. d6 shows rIFN- plus B10
cells. (B) Effect of rIFN- (900 IU/ml) and/or rTNF- (60 IU/ml) on
the parental (2C4) and mutant (B3, B9, and B10) cells infected with
T. gondii. The replication was evaluated 48 h after
infection. An asterisk indicates a result statistically different from
control group (P < 0.05). Results indicate the means ± the standard errors of the means from three independent experiments
done in duplicate. (C) Effect of rIFN- (900 IU/ml) and/or rTNF-
(60 IU/ml) on the induction of INDO mRNA. The parental (2C4) and mutant
(B3, B9, and B10) cells were incubated with rIFN- and/or rTNF-
for 14 to 16 h. Lanes 1, 5, 9, and 13 are controls without
cytokine; lanes 2, 6, 10, and 14 are rIFN-; lanes 3, 7, 11, and 15 are rIFN- plus rTNF-; lanes 4, 8, 12, and 16 are rTNF-; and
lane 17 is the negative control (no cDNA added). Expression of INDO and
GAPDH mRNA was detected by RT-PCR. PCR products (3 µl) were
electrophoresed in 6% polyacrylamide gel and silver stained. The
expected fragment sizes were 487 bp for the INDO and 311 bp for the
GAPDH genes.
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In addition, we observed a smaller ratio of infectivity when we
compared the mutant cells to the parental cell line. However, these
differences were observed in some but not all of the experiments performed.
| |
DISCUSSION |
Different studies indicate that the activation of human
macrophages and NPPC with IFN- leads to the induction of INDO, a key
enzyme involved in the degradation of the essential amino acid
tryptophan. In NPPC and macrophages, tryptophan starvation has been
shown to be an important IFN--induced mechanism involved in the
regulation of intracellular pathogen replication (3, 10, 35,
55). Thus, the addition of extra tryptophan completely restores
replication of the intracellular protozoan T. gondii and the
bacteria Chlamydia psittaci and Chlamydia
pneumoniae inside human fibroblast and epithelial cells,
respectively (8, 35, 46). In contrast, additional tryptophan
has only a partial effect in restoring the replication of T. gondii, Leishmania donovani, and C. psittaci
inside human macrophages activated with IFN- (10, 30).
These latter results suggest that mechanisms other than tryptophan
degradation may be triggered in PPC by activation with IFN-
(12, 34, 47).
Because T. cruzi can infect any nucleated cell from its
vertebrate host, it is tempting to speculate that cytokine activation of NPPC may also result in the induction of microbiostatic function, which is responsible for the control of parasite replication during the
chronic stage of infection. Furthermore, IFN- and/or TNF- have
been shown to play an important role in resistance to T. cruzi during the activation of both human and mouse macrophages (13, 26, 27); we therefore decided to study the capacity of
these cytokines to induce anti-T. cruzi activity in human
fibroblasts. As a control we used T. gondii tachyzoites,
whose replication inside human fibroblasts has been shown to be
sensitive to activation by IFN-. Interestingly, our results showed
that in contrast to T. gondii tachyzoites, replication of
T. cruzi inside human fibrosarcoma cells or fibroblasts was
not affected by cell activation with rIFN-. Consistent with these
observations, T. cruzi replication was not affected by
tryptophan starvation, i.e., when parasites were cultured in tissue
culture and medium lacking tryptophan. In contrast, tachyzoite
replication was almost abolished in the same culture conditions. In
agreement with our findings are the studies showing that T. cruzi replication is not affected in NPPC originating from humans
or other mammals activated with human lymphoblastoid IFN and IFN
obtained by infecting monolayers of human amniotic cells with
inactivated Newcastle disease virus (14, 33). However,
different studies suggest that IFN-, as well as IFN-/, may
inhibit T. cruzi replication inside rat or murine NPPC
(31, 37). The reasons for these discrepancies are still unclear.
The mechanism by which T. cruzi escapes tryptophan
starvation is completely unknown. One possibility would be the
expression of an enzyme which is involved in the synthesis of
tryptophan. In measuring the amount of indole consumed, we detected
only trace amounts of TS activity when we used T. cruzi
epimastigote or trypomastigote extracts compared to our findings with
E. coli. Moreover, by using primers specific for the
conserved E. coli TS sequence, we were unable to amplify a
fragment that showed homology with the sequence of E. coli
TS (data not shown). Another explanation for this effect would be the
generation of free tryptophan in the host due to the parasite protease
activity. In fact, early studies demonstrated that parasite treatment
with specific protease inhibitors reduced the amount of T. cruzi replication inside host cells (25). It is also
noteworthy that all of the parasites sensitive to tryptophan starvation
(i.e., T. gondii, L. donovani, and
Chlamydia sp.) reside within a parasitophorous vacuole, in
contrast to T. cruzi amastigotes, which replicate in the
host cell cytoplasm (2). Thus, one could speculate that the
residual pool of tryptophan in cells activated with IFN- would be
less available in the parasitophorous vacuole. It is also possible that
the tryptophan starvation only reduces the speed of parasite
replication inside NPPC. Since the T. cruzi replication is
slower than the T. gondii tachyzoite replication, the
proliferation of the former parasite is not affected by the decreased
levels of tryptophan inside host cells.
Finally, we also studied the ability of IFN- to induce
microbiostatic activity in fibroblasts, as well as expression of INDO mRNA in the 2C4 parental cell lines and in derivative cells lacking functional elements (i.e., STAT1, JAK1, and JAK2) of the IFN- signaling pathway. As expected, our results show that 2C4 cells were
responsive to IFN-, whereas none of mutant cell lines showed antiviral, antiparasitic activity or INDO mRNA expression when stimulated with rIFN-. Thus, these results indicate the involvement of the JAK/STAT pathway on the induction of INDO mRNA expression and
microbiostatic function in NPPC exposed to IFN-.
Interestingly, we found that rTNF- was able to trigger the
expression of low levels of INDO mRNA in the mutant B9 cell line, which
has an intact signaling pathway to respond to type 1 IFNs. Previous
studies have also shown that TNF- and IFN- can trigger the
expression of INDO mRNA (41, 42, 52) and that TNF- is
able to induce mRNA synthesis of IFN- in human fibroblasts (21,
39, 50). In light of our findings, we suggest that TNF- may be
triggering INDO mRNA expression through the induction IFN- synthesis
in human fibroblasts. However, the levels of INDO mRNA induced by
TNF- and IFN- are apparently not high enough to efficiently
control T. gondii replication inside fibroblasts.
These results clearly establish the involvement of the JAK/STAT
signaling pathway in the INDO-mediated antimicrobial activity of
IFN-, as suggested earlier by nucleic acid sequence analysis (22) and functional studies with plasmid constructs
containing INDO gene promoter (11, 22). However, in contrast
to previously reported studies, our results demonstrate for the first
time the involvement of individual components (i.e., JAK1, JAK2, and
STAT1) of the IFN- signaling cascade in the induction of both INDO
mRNA expression and microbiostatic activity in NPPC.
| |
ACKNOWLEDGMENTS |
This work was supported in part by the Conselho Nacional de
Desenvolvimento Científico e Tecnológico
(CNPq-522.056-95/4), the Fundação de Amparo a Pesquisa do
Estado de Minas Gerais (FAPEMIG-CBS 1221/95), and PAPES/FIOCRUZ.
R.T.G., A.J.R., and C.A.B. are research fellows from CNPq. I.P.C. and
A.C.L.C. are graduate fellows from Coordenação de
Aperfeiçoamento de Pessoal de Nível Superior (CAPES) and
CNPq, respectively.
We are grateful to J. C. Magalhães for technical assistance
on the virus infectivity assays.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Chagas' Disease, CPqRR-FIOCRUZ, CEP 30190-002, Cx. Postal 1743, Av.
Augusto de Lima 1715, Belo Horizonte, MG 30190-002, Brazil. Phone:
031-295-3566. Fax: 031-295-3115. E-mail:
ritoga{at}mono.icb.ufmg.br.
Editor:
J. M. Mansfield
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Abstract
Introduction
