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Journal of Virology, December 2001, p. 11437-11448, Vol. 75, No. 23
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.23.11437-11448.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Vaccinia Virus Infection Disarms the
Mitochondrion-Mediated Pathway of the Apoptotic Cascade by Modulating
the Permeability Transition Pore
Shawn T.
Wasilenko,
Adrienne F. A.
Meyers,
Kathleen
Vander Helm, and
Michele
Barry*
Department of Medical Microbiology and
Immunology, University of Alberta, Edmonton, Alberta, Canada T6G 2S2
Received 25 June 2001/Accepted 29 August 2001
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ABSTRACT |
Many viruses have evolved strategies that target crucial components
within the apoptotic cascade. One of the best studied is the caspase 8 inhibitor, crmA/Spi-2, encoded by members of the poxvirus family. Since
many proapoptotic stimuli induce apoptosis through a
mitochondrion-dependent, caspase 8-independent pathway, we hypothesized
that vaccinia virus would encode a mechanism to directly modulate the
mitochondrial apoptotic pathway. In support of this, we observed that
Jurkat cells, which undergo Fas-mediated apoptosis exclusively through
the mitochondrial route, were resistant to Fas-induced death following
infection with a crmA/Spi-2-deficient strain of vaccinia virus. In
addition, vaccinia virus-infected cells subjected to the proapoptotic
stimulus staurosporine exhibited decreased levels of both cytochrome
c released from the mitochondria and caspase 3 activation. In all cases we found that the loss of the
mitochondrial membrane potential, which occurs as a result of opening
the multimeric permeability transition pore complex, was prevented in
vaccinia virus-infected cells. Moreover, vaccinia virus infection
specifically inhibited opening of the permeability transition pore
following treatment with the permeability transition pore ligand
atractyloside and t-butylhydroperoxide. These studies indicate that vaccinia virus infection directly impacts the
mitochondrial apoptotic cascade by influencing the permeability
transition pore.
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INTRODUCTION |
An important function of the
cell-mediated immune response is the detection and elimination of
virus-infected cells as a means to arrest viral propagation. To
do this, immune effector cells rely on the production of cytokines and
the recognition of virus infected cells by cytotoxic T lymphocytes
(CTL) to induce programmed cell death, or apoptosis (31).
Apoptosis results in a variety of cellular changes including cell
shrinkage, DNA fragmentation, chromatin condensation, and finally the
formation of apoptotic bodies. These changes are mediated by
biochemical events involving a family of cysteine proteases termed
caspases (45, 61). Following an apoptotic stimulus,
caspases become proteolytically activated and function to cleave
cellular proteins, including other members of the caspase family.
Recently, it has also become clear that within cells instructed to die,
mitochondria play a central role in the execution of apoptosis
(13). The induction of apoptosis results in both
structural and physiological alterations to mitochondria, including
disruption of electron transport and energy metabolism, production of
reactive oxygen species, loss of the membrane potential, and release of
proapoptotic proteins, including cytochrome c
(37).
In order for a virus to replicate and disseminate within a host,
manipulation of the apoptotic process is essential (2, 48,
64). To ensure their survival, viruses have evolved strategies that target crucial components within the apoptotic cascade. For example, virus-encoded inhibitors of apoptosis have been identified that either directly or indirectly modulate caspase activation. One of
the best-studied viral caspase inhibitors is the cowpox virus-encoded
cytokine response modifier A (crmA), also known as Spi-2. crmA/Spi-2
inhibits both Fas- and tumor necrosis factor (TNF)-induced apoptosis
via interaction with caspase 8 (33, 59, 71). In a similar
manner, baculoviruses encode P35, a broad-spectrum caspase inhibitor
that protects infected cells from apoptosis (8, 70). As
well, baculoviruses and African swine fever virus modulate the
activation and activity of caspases through the expression of
inhibitors of apoptosis (IAPs) (11, 14, 46). In addition
to modulating caspase activity, viruses have also developed strategies
that interfere with other components of the death pathway. For example,
poxviruses encode secreted TNF receptors that inhibit TNF-
-induced
apoptosis by blocking ligand-receptor interactions (27, 52,
55). Gammaherpesviruses and the poxvirus molluscum contagiosum
encode viral Fas-associated death domain-like
interleukin-1
-converting enzyme inhibitory proteins (vFLIPs), which
interfere with recruitment of caspase 8 to the cytoplasmic domains of
Fas and TNF receptor 1 (5, 28, 60). Additionally,
adenovirus has evolved an elaborate scheme to stimulate the
internalization of cell surface Fas (53, 62).
Since mitochondria play a central role in cell death, viruses have also
established mechanisms to modulate the mitochondrial component of the
apoptotic pathway. Members of the cellular Bcl-2 family influence the
integrity of the mitochondria (10, 21), and many viruses
encoding Bcl-2-like proteins have been identified. Viral Bcl-2
homologues with antiapoptotic function have been found in adenovirus
(65) and African swine fever virus (1, 7) as
well as in members of the gammaherpesvirus family including Epstein-Barr virus, equine herpesvirus 2, herpesvirus saimiri, Kaposi's sarcoma-associated herpesvirus, bovine herpesvirus,
herpesvirus ateles, alcelaphine herpesvirus 1, and murine
gammaherpesvirus 68 (64). In addition, novel virus gene
products that act at the mitochondrial checkpoint but lack homology to
Bcl-2 have also been identified. VMIA, encoded by human cytomegalovirus
(HCMV), inhibits apoptosis and the release of cytochrome c
in HeLa cells through interaction with the adenine nucleotide
translocator (ANT) subunit of the permeability transition (PT) pore
(20). M11L, encoded by the rabbit-specific poxvirus myxoma
virus, localizes to the mitochondria and inhibits staurosporine-induced
loss of mitochondrial membrane potential and apoptosis
(17).
The large number of viruses encoding proteins that function to maintain
the integrity of the mitochondria led us to hypothesize that vaccinia
virus, a member of the poxvirus family, would employ a mechanism to
directly modulate the mitochondrial apoptotic pathway. To determine
whether vaccinia virus infection could inhibit the mitochondrion-mediated apoptotic pathway, we monitored the ability of
vaccinia virus strain Copenhagen, which is naturally devoid of the
caspase 8 inhibitor crmA/Spi2, to inhibit Fas- and
staurosporine-mediated apoptosis. We show here, for the first time,
that vaccinia virus modulates the apoptotic mitochondrial pathway by
inhibiting the PT pore, thereby preserving the mitochondrial membrane
potential and retaining cytochrome c.
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MATERIALS AND METHODS |
Cell and viruses.
Jurkat cells were grown in RPMI 1640 medium supplemented with 10% fetal calf serum (both from Gibco BRL
Life Technologies, Inc.), 100 µM 2-mercaptoethanol, 50 U of
penicillin/ml, and 50 µg of streptomycin/ml (RHFM). Stably
transfected Jurkat cells were generated as previously described
(3) and maintained in RHFM supplemented with 800 µg of
G418/ml. Recombinant vaccinia virus strain Copenhagen expressing
beta-galactosidase (VV65) was a gift from G. McFadden (Robarts Research
Institute, London, Ontario, Canada) (26). VV65 was
routinely propagated in baby green monkey kidney (BGMK) cells, a gift
from S. Dales, and grown in Dulbecco's modified Eagle medium
supplemented with 10% newborn calf serum (both from Gibco BRL Life
Technologies, Inc.), 50 U of penicillin/ml, 50 µg of streptomycin/ml,
and 2 mM glutamine. Viruses were isolated as previously described
(57).
Virus infection.
Jurkat cells were infected at a
multiplicity of infection (MOI) of 10 PFU per cell in 200 µl of RHFM
at 37°C. After 1 h, the cells were supplemented with additional
RHFM for 4 h and incubated at 37°C under 5%
CO2 before induction of apoptosis. The efficiency of virus infection was routinely quantified by colorimetric analysis using the lacZ gene. In all experiments, the efficiency of
infection was found to be greater than 95%. When necessary, VV65 was
UV inactivated for 60 min prior to infection and cytosine arabinoside (Sigma Chemical Co.) was added to a final concentration of 40 µg/ml.
Antibodies.
The p20 fragment of caspase 3 (C3p20) was
amplified by PCR from pSKII:CPP32 using the forward oligonucleotide
5'-GGATCCTCTGGAATATCCCTGGAC-3' containing a BamHI
restriction site and the reverse oligonucleotide 5'-GTCGACGTCTGTCTCAATGCCACA-3' containing a SalI
restriction site. Amplified C3p20 was subcloned into pGex4T-3
(Pharmacia Biotech) to construct pGex4T-3:C3p20. pGex4T-3-C3p20 was
transformed into BL21DE3, and protein expression was induced by the
addition of 0.1 mM
isopropyl--D-thiogalactopyranoside (IPTG)
(Rose Scientific Ltd.). Glutathione S-transferase
(GST)-C3p20 was purified utilizing glutathione Sepharose 4B according
to the manufacturer's instructions (Pharmacia Biotech). Pet15b-Bid, a
gift from X. Wang (University of Texas Southwestern Medical Center,
Dallas, Tex.) was used to express His-tagged Bid (40).
Recombinant His-tagged Bid was purified using a
Ni2+ column according to the manufacturer's
instructions (Novagen). Rabbits were immunized by injection of 500 µg
of bacterially expressed GST-caspase 3 or His-Bid in Freund's complete
adjuvant (Gibco BRL Life Technologies). At monthly intervals the
animals were boosted with 500 µg of antigen in Freund's incomplete
adjuvant (Gibco BRL Life Technologies), and antiserum was collected 10 days after the fourth boost. The anti-cytochrome c antibody
(clone 7H8.2Cl2) was purchased from PharMingen. Anti-human Fas
immunoglobulin M (IgM) (clone CH11) was purchased from Upstate
Biotechnology. Goat anti-mouse and goat anti-rabbit horseradish
peroxidase-conjugated antibodies were purchased from Bio-Rad and used
at dilutions of 1:3,000 and 1:10,000, respectively.
Apoptosis induction.
Cells were induced to undergo apoptosis
by addition of either 250 ng of activating anti-Fas/ml or 1 to 5 µM
staurosporine (Sigma Chemical Co.) as outlined in Results.
Chromium release assay.
51Cr release
assays were performed as previously described (4).
Briefly, cells were labeled with 100 µCi of
51Cr at 37°C for 1 h. Labeled target cells
were incubated with 250 ng of anti-Fas clone CH11/ml, and
51Cr release was quantitated after 8 h.
51Cr release was calculated by the following
equation: percent lysis = 100 × (sample release 
spontaneous release)/(total release spontaneous release).
Standard deviations were generated from three replicates.
Cytochrome c release assay.
Cytochrome
c release was monitored as previously described (25,
49). Following apoptosis treatment, 2 × 106 or 5 × 106 Jurkat
cells were permeabilized by incubation in digitonin lysis buffer
containing 75 mM NaCl, 1 mM
NaH2PO4, 8 mM
Na2HPO4, 250 mM sucrose,
and 190 µg of digitonin (Sigma Chemical Co.)/ml. Cells were incubated
on ice for 10 min, after which the mitochondria-containing pellet and
the cytosolic supernatant were separated by centrifugation at
10,000 × g for 5 min. Mitochondrial pellets were
resuspended in 0.1% Triton X-100-25 mM Tris (pH 8.0) prior to
sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis.
Measurement of mitochondrial membrane potential.
Changes in
mitochondrial membrane potential were quantified by staining cells with
tetramethylrhodamine ethyl ester (TMRE) (Molecular Probes) (16,
18, 43). Cells were loaded with TMRE by a 30-min incubation (at
37°C, under 5% CO2) in RHFM containing 0.2 µM TMRE. As a control, cells were also treated with a membrane uncoupler, carbonyl cyanide m-chlorophenylhydrazone (ClCCP)
(Sigma Chemical Co.), at a final concentration of 50 µM, for 15 min
at 37°C under 5% CO2. To trigger the
permeability transition, cells were treated with either 1 µM
staurosporine or 300 µM t-butylhydroperoxide (both from
Sigma Chemical Co.) for 1 or 2 h, respectively. Prior to flow
cytometric analysis, cells were washed with phosphate-buffered saline
(PBS) containing 1% fetal calf serum. TMRE fluorescence was acquired
through the FL-2 channel equipped with a 585-nm filter (band
pass, 42 nm). Data were acquired on either 10,000 or 20,000 cells per
sample with fluorescence signals at logarithmic gain. Data were
analyzed with CellQuest software, and standard deviations were
generated from three independent experiments.
Detection of DNA fragmentation.
DNA fragmentation was
assessed using the terminal deoxynucleotidyltransferase-mediated
dUTP nick end labeling (TUNEL) kit (Roche Diagnostics Co.).
Briefly, cells were harvested, washed in PBS containing 1% fetal calf
serum, fixed in 2% paraformaldehyde, and permeabilized in 0.1% Triton
X-100. Fixed and permeabilized cells were incubated for 1 h at
37°C in a solution containing 25 mM Tris (pH 6.6), 200 mM
cacodylate, 1 mM CoCl2, 0.6 nM
fluorescein-12-dUTP, and 25 U of terminal deoxynucleotidyltransferase
(Roche Diagnostics Co.). Analysis was performed on a Becton Dickinson
FACScan equipped with an argon laser at 15 mV with an excitation
wavelength of 488 nm. Emission wavelengths were detected through
the FL-1 channel equipped with a 530-nm filter (band pass, 20 nm). Data was acquired on 10,000 cells per sample with light scatter
signals at linear gain and fluorescence signals at logarithmic gain.
In vitro reconstitution assay.
Mitochondria were purified as
previously described (24, 49). For each test sample,
4 × 107 cells were washed in buffer A
containing 20 mM morpholinepropanesulfonic acid (MOPS; pH 7.4), 100 mM
sucrose, and 1 mM EGTA. Cells were resuspended in buffer B containing
20 mM MOPS (pH 7.4), 100 mM sucrose, 1 mM EGTA, 5% Percoll (Sigma
Chemical Co.), and 190 µg of digitonin/ml. Following a 15-min
incubation on ice with intermittent inversion, nuclei were pelleted at
2,500 × g for 10 min at 4°C. The pellet was
discarded, and the supernatant was centrifuged at 15,000 × g for 15 min at 4°C. The mitochondrial fraction was collected and washed three times in buffer A and resuspended in buffer
C containing 20 mM MOPS (pH 7.4), 300 mM sucrose, and 1.0 mM EGTA. The
protein concentration of the mitochondrial fraction was determined
using the bicinchoninic acid (BCA) kit from Pierce Chemical Company.
For the in vitro assay, 6 µg of purified mitochondria was either
incubated with 2, 5, or 10 ng of recombinant Bid in the presence or
absence of 0.25 µg of purified granzyme B or treated with 5, 10, or
15 mM atractyloside (Sigma Chemical Co.) for 40 min at 37°C. Granzyme
B was purified from YT-Indy cells was as previously described (9,
23). Following the addition of granzyme B and His-tagged Bid,
the samples were incubated at 37°C for 60 min. Samples were then
centrifuged at 15,000 × g to separate the mitochondrial pellet from the supernatant prior to SDS-PAGE analysis.
Immunoblotting.
Cellular lysates were analyzed by
electrophoresis on an SDS-15% polyacrylamide gel. Proteins
were transferred to nitrocellulose membranes (Osmonics Inc.) using a
semidry transfer apparatus (Tyler Research Instruments) for 2.5 h
at 500 mA. Membranes were blocked for at least 3 h in PBS
containing 0.1% Tween and 5% skim milk. Caspase 3 and Bid were
detected using polyclonal rabbit anti-caspase 3 and anti-Bid at a
dilution of 1:10,000. Cytochrome c was detected using a
monoclonal antibody at a 1:1,000 dilution. All primary antibodies were
incubated with the membranes overnight at 4°C. Membranes were probed
with either a goat anti-mouse (1:3,000) or a goat
anti-rabbit (1:10,000) horseradish peroxidase-conjugated antibody. Proteins were visualized with a chemiluminescence detection system according to the manufacturer's directions (Amersham Pharmacia Biotech).
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RESULTS |
Vaccinia virus strain Copenhagen-infected cells are resistant to
anti-Fas-mediated apoptosis.
To determine whether vaccinia virus
infection could inhibit the mitochondrion-mediated apoptotic pathway,
we monitored the ability of vaccinia virus strain Copenhagen to inhibit
anti-Fas-induced apoptosis of Jurkat cells. We utilized Jurkat cells,
since Fas-induced apoptosis occurs exclusively via the mitochondrial
pathway in this cell line (51). In addition, we utilized a
strain of vaccinia virus, strain Copenhagen, which is naturally devoid
of the caspase 8 inhibitor crmA/Spi-2 (19). Jurkat cells
were either mock infected or infected with vaccinia virus strain
Copenhagen. At 5 h postinfection, apoptosis was triggered by the
addition of anti-Fas and cell death was measured by
51Cr release. As shown in Fig.
1, mock-infected cells treated with anti-Fas displayed approximately 30% 51Cr
release. This release was completely inhibited by pretreating the cells
with the broad-spectrum caspase inhibitor zVAD.fmk, indicating that
cytolysis was directly dependent on caspase activation. Infection of
Jurkat cells with vaccinia virus strain Western Reserve, which
encodes a functional Spi-2, drastically reduced the levels of
51Cr released. As expected, Jurkat cells stably
transfected with either Spi-2 or Bcl-2 were protected from
anti-Fas-triggered death. Most significantly, Jurkat cells infected
with vaccinia virus strain Copenhagen, lacking a functional crmA/Spi-2,
also inhibited death mediated via the Fas pathway, clearly suggesting
that vaccinia virus strain Copenhagen employs an additional
antiapoptotic mechanism.
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FIG. 1.
Vaccinia virus strain Copenhagen protects cells from
anti-Fas-mediated death. Jurkat cells were either mock infected or
infected with either vaccinia virus strain Copenhagen or vaccinia virus
strain Western Reserve at an MOI of 10. Following 5 h of
infection, cells were treated with 250 ng of anti-Fas antibody/ml to
induce apoptosis, and cell death was monitored 8 h later by
51Cr release. As controls, Jurkat cells that overexpress
SPI-2 and Bcl-2 were also treated with anti-Fas, and Jurkat cells were
pretreated for 30 min with 100 µM zVAD.fmk prior to addition of
anti-Fas. Standard deviations were generated from three replicates.
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To begin to determine the point at which vaccinia virus strain
Copenhagen-infected Jurkat cells were resistant to cell death,
we
monitored anti-Fas-mediated caspase 3 activation. Caspase 3
activation
was assessed by Western blot analysis using an antibody
raised against
the large subunit of the active caspase. Over 8
h, uninfected
cells treated with anti-Fas showed processing of
caspase 3 from the
full-length 32-kDa procaspase to the mature
19- and 17-kDa forms (Fig.
2A). In contrast, cells infected with
vaccinia virus strain Copenhagen and treated with the anti-Fas
antibody
exhibited only minor amounts of active caspase 3 (Fig.
2B), indicating
that infected cells were protected from apoptosis.
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FIG. 2.
Vaccinia virus strain Copenhagen infection inhibits
activation of caspase 3. Jurkat cells were either mock infected or
infected with vaccinia virus strain Copenhagen at an MOI of 10 and
treated with 250 ng of anti-Fas antibody/ml for 2, 4, 6, or 8 h.
At the times indicated, cells were permeabilized with digitonin, and
caspase 3 processing was monitored by Western blot analysis. (A)
Mock-infected Jurkat cells; (B) Jurkat cells infected with vaccinia
virus strain Copenhagen.
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Since infection of Jurkat cells with vaccinia virus strain Copenhagen
inhibited the activation of caspase 3, and since mitochondrial
release
of cytochrome
c is necessary for caspase 3 activation,
we
assessed the ability of vaccinia virus strain Copenhagen to
inhibit the
release of cytochrome
c following treatment with anti-Fas
(
13,
37,
39). To detect the release of cytochrome
c, cells
were fractionated into mitochondrial and cytosolic
fractions and
the release of cytochrome
c was detected by
Western blot analysis.
Using this approach, apoptotic extracts
demonstrated the translocation
of cytochrome
c from the
mitochondria to the cytosolic fraction
(Fig.
3A). Translocation of cytochrome
c was first detected as
early as 4 h following the
addition of anti-Fas and was found
to increase over time (Fig.
3A). As
a control, we also monitored
cytochrome
c release in Jurkat
cells that overexpress the antiapoptotic
protein Bcl-2. As previously
documented, Bcl-2 expression inhibited
the translocation of cytochrome
c to the cytosol (Fig.
3B) (
35,
66).
Fas-mediated release of cytochrome
c was also monitored
in
Jurkat cells infected with vaccinia virus strain Copenhagen.
As shown
in Fig.
3C, infection with vaccinia virus strain Copenhagen
significantly interfered with the release of cytochrome
c,
indicating
that vaccinia virus strain Copenhagen inhibits the
Fas-mediated
apoptotic pathway upstream of cytochrome
c
release.
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FIG. 3.
Vaccinia virus strain Copenhagen inhibits cytochrome
c translocation. Jurkat cells were either mock infected
or infected with virus. Following infection, cells were treated with
250 ng of anti-Fas/ml for 2, 4, 6, or 8 h to induce cytochrome
c translocation. At the times indicated, cells were
permeabilized with digitonin and fractionated into the
mitochondrion-containing membranous fraction and the soluble
cytoplasmic fraction, and cytochrome c was assessed by
Western blot analysis. (A) Mock-infected Jurkat cells; (B) mock
infected Jurkat cells that overexpress Bcl-2; (C) Jurkat cells infected
with vaccinia virus strain Copenhagen.
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Vaccinia virus strain Copenhagen infection inhibits cytochrome
c release in isolated mitochondria but not cleavage of
Bid.
The ability of vaccinia virus strain Copenhagen to inhibit
Fas-induced cytochrome c release suggested to us that the
virus could potentially hinder apoptosis by interfering with activation of the proapoptotic Bcl-2 family member Bid. During Fas-mediated apoptosis, Bid is cleaved by caspase 8, prompting the translocation of
truncated Bid to the mitochondria, resulting in the release of
cytochrome c (38, 40). Additionally, the serine
proteinase granzyme B, which is released from activated CTL, is also
able to induce apoptosis through the cleavage of Bid (3,
24). To investigate the potential inhibition of Bid activation
by vaccinia virus strain Copenhagen, we performed an in vitro apoptotic
reconstitution assay involving isolated mitochondria, recombinant Bid,
and purified granzyme B. Mitochondria were purified from both
mock-infected and virus-infected Jurkat cells as well as from Jurkat
cells stably expressing Bcl-2. To ensure mitochondrial purity,
virus-infected samples were subjected to Western blot analysis to
detect Spi-1, a known vaccinia virus cytoplasmic protein (unpublished
data) (34). Isolated mitochondria were incubated with
increasing amounts of recombinant Bid, either in the presence or in the
absence of purified granzyme B, and proteolytic cleavage of Bid was
monitored by Western blot analysis. Figure
4A demonstrates that in the presence of
purified mitochondria and granzyme B, recombinant Bid underwent proteolytic cleavage and activation in this assay. In agreement with
previously published results, Bid was also processed in the presence of
isolated mitochondria from cells overexpressing Bcl-2 (22,
44) (Fig. 4B). The processing of Bid was found to be unaltered
when mitochondria from vaccinia virus-infected cells were used in the
same assay, indicating that vaccinia virus infection does not inhibit
the proteolytic processing of Bid (Fig. 4C).
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FIG. 4.
Vaccinia virus infection protects against granzyme
B-mediated cytochrome c release from isolated
mitochondria by a mechanism downstream of Bid activation. Mitochondria
were isolated from mock-infected Jurkat cells, Jurkat cells
overexpressing Bcl-2, and Jurkat cells infected with vaccinia virus
strain Copenhagen. Purified mitochondria were incubated for 60 min at
37°C with 2, 5, or 10 ng of recombinant Bid either in the presence or
in the absence of granzyme B. Following treatment, samples were
fractionated into mitochondria-containing and soluble fractions and the
proteins were resolved by SDS-PAGE. (A through C)Western blot analysis
of Bid cleavage in mitochondria isolated either from mock-infected
cells (A), from cells overexpressing Bcl-2 (B), or from vaccinia virus
strain Copenhagen-infected cells (C). (D through F) Western blot
analysis of cytochrome c translocation from purified
mitochondria to supernatant fractions in mitochondria isolated either
from mock-infected cells (D), from mock-infected cells overexpressing
Bcl-2 (E), or from vaccinia virus strain Copenhagen-infected cells
(F).
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Since vaccinia virus infection did not suppress granzyme B-induced Bid
cleavage, we next asked if mitochondria isolated from
vaccinia
virus-infected cells could inhibit granzyme B-induced
cytochrome
c release in the presence of Bid. Mitochondria isolated
from
mock-infected Jurkat cells were incubated with increasing
amounts of
recombinant Bid in the presence of granzyme B, resulting
in the
translocation of cytochrome
c from the mitochondria to
the
supernatant (Fig.
4D). As shown in Fig.
4D, an increase in
the amount
of cytochrome
c translocation was detected following
the
addition of granzyme B and increasing amounts of recombinant
Bid. At 5 and 10 ng of Bid, we found that some cytochrome
c
translocation
was independent of Bid cleavage, as previously reported
(
40,
67) (Fig.
4D). The release of cytochrome
c
was completely abolished
in mitochondria isolated from Jurkat cells
overexpressing the
antiapoptotic protein Bcl-2 (Fig.
4E). Inhibition of
cytochrome
c translocation was also seen in mitochondria
isolated from vaccinia
virus-infected cells (Fig.
4F). Taken together,
these results
indicated that cytochrome
c release was
inhibited in mitochondria
isolated from infected cells and suggested
that vaccinia virus
infection directly modulated the mitochondrial arm
of the apoptotic
pathway.
Vaccinia virus strain Copenhagen-infected cells are resistant to
staurosporine-mediated apoptosis.
In view of our findings
demonstrating that vaccinia virus strain Copenhagen could inhibit
Fas-mediated cytochrome c release and cytochrome
c release from isolated mitochondria, we assessed the
ability of vaccinia virus strain Copenhagen to directly inhibit the
mitochondrial route to apoptotic death. To determine if vaccinia virus
strain Copenhagen could directly inhibit the mitochondrial cascade, we
treated cells with the proapoptotic reagent staurosporine, which
triggers the mitochondrion-mediated apoptotic pathway (6, 58). Mock-infected or virus-infected Jurkat cells were treated with staurosporine, and the levels of DNA fragmentation were measured using the TUNEL assay and flow cytometry. As shown in Fig.
5, untreated cells demonstrated low
levels of DNA fragmentation (Fig. 5a, d, and f). Upon staurosporine
treatment, 42% of the mock-infected Jurkat cell population showed DNA
fragmentation (Fig. 5b). Preincubation with the broad-spectrum caspase
inhibitor zVAD.fmk completely inhibited staurosporine-induced DNA
fragmentation, clearly demonstrating that staurosporine-induced DNA
fragmentation occurred via caspase activation, as expected (Fig. 5c).
In addition, stably transfected Jurkat cells that overexpress Bcl-2
were also found to be resistant to apoptosis, indicating that
staurosporine-mediated cell death occurred via the mitochondrial
pathway (Fig. 5d). Most importantly, vaccinia virus strain
Copenhagen-infected Jurkat cells treated with staurosporine displayed
clear protection from apoptosis, with only 7% of the cells showing DNA
fragmentation (Fig. 5g). To determine if the block was upstream of
caspase 3 activation, cells were treated with staurosporine for 2, 4, or 6 h and caspase 3 processing was monitored by Western blot
analysis. As shown in Fig. 6A,
mock-infected Jurkat cells treated with staurosporine displayed rapid
conversion of the 32-kDa procaspase 3 to the active fragments. This
conversion was significantly inhibited both in Bcl-2-overexpressing
cells and in cells infected with vaccinia virus strain Copenhagen (Fig.
6B and C). Compared to mock-infected cells, vaccinia virus strain
Copenhagen-infected Jurkat cells treated with staurosporine displayed
drastic reductions in levels of the 19- and 17-kDa caspase 3 fragments
and maintenance of the full-length 32-kDa proform, indicating that
apoptosis inhibition occurred upstream of caspase 3 activation (Fig. 6A
and B).
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FIG. 5.
DNA fragmentation is blocked by vaccinia virus strain
Copenhagen infection. Jurkat cells were either mock infected or
infected with vaccinia virus strain Copenhagen. Following infection,
cells were treated with 2.5 µM staurosporine for 2 h, and DNA
fragmentation was assessed by TUNEL as outlined in Materials and
Methods. (a) Untreated Jurkat cells; (b) Jurkat cells treated with
staurosporine; (c) Jurkat cells treated with staurosporine in the
presence of 100 µM zVAD.fmk; (d) Jurkat cells overexpressing Bcl-2;
(e) Jurkat cells overexpressing Bcl-2 treated with staurosporine; (f)
Jurkat cells infected with vaccinia virus strain Copenhagen; (g) Jurkat
cells infected with vaccinia virus and treated with staurosporine.
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FIG. 6.
Staurosporine-induced caspase 3 activation is inhibited
by vaccinia virus strain Copenhagen infection. Jurkat cells were either
mock infected or infected with virus; following infection, they were
treated with 5 µM staurosporine for 0, 2, 4, or 6 h. At the
times indicated, cells were permeabilized with digitonin and the
proteins were resolved by SDS-PAGE. The activation of caspase 3 was
monitored by Western blot analysis. (A) Mock-infected Jurkat cells; (B)
mock-infected Jurkat cells that overexpress Bcl-2; (C) Jurkat cells
infected with vaccinia virus strain Copenhagen.
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Since Jurkat cells infected with vaccinia virus strain Copenhagen and
induced to undergo apoptosis with anti-Fas inhibited
cytochrome
c translocation from mitochondria to the cytosol, we
investigated the possibility that staurosporine-induced cytochrome
c translocation would be inhibited by virus infection as
well.
Mock-infected cells treated with staurosporine exhibited a
dramatic
loss of cytochrome
c from the mitochondrial
fraction and subsequent
accumulation in the cytoplasmic fraction (Fig.
7A). In contrast
to cells treated with
anti-Fas antibody, cells treated with staurosporine
displayed
cytochrome
c translocation as early as 2 h
posttreatment,
and we routinely detected complete translocation of
cytochrome
c to the cytoplasmic fraction after 6 h of
treatment. As anticipated,
staurosporine-induced translocation of
cytochrome
c was completely
inhibited in Jurkat cells
engineered to overexpress Bcl-2 (
35,
66) (Fig.
7B). Most
importantly, in cells infected with vaccinia
virus strain Copenhagen,
cytochrome
c release was drastically
reduced (Fig.
7C). In
contrast to the situation in mock-infected
cells, complete
translocation of cytochrome
c from the mitochondrial
to the
cytosolic fraction was inhibited by vaccinia virus infection,
and
cytosolic cytochrome
c was only partially evident at 4 and
6 h post-staurosporine treatment.
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FIG. 7.
Staurosporine-induced cytochrome c
release is inhibited by vaccinia virus strain Copenhagen infection.
Jurkat cells were either mock infected or infected with virus and were
treated with 5 µM staurosporine for 0, 2, 4, or 6 h. At the
times indicated, cells were fractionated into mitochondria-containing
membrane fractions and cytoplasmic fractions by the addition of
digitonin. The translocation of cytochrome c was
monitored by Western blot analysis. (A) Mock-infected Jurkat cells; (B)
mock-infected Jurkat cells that overexpress Bcl-2; (C) Jurkat cells
infected with vaccinia virus strain Copenhagen.
|
|
Vaccinia virus infection inhibits disruption of the mitochondrial
inner membrane potential and opening of the PT pore.
During
apoptosis the release of cytochrome c coincides with loss of
the inner mitochondrial membrane potential (41, 69). Disruption of the inner mitochondrial membrane potential is thought to
occur due to the opening of the PT pore (12, 36, 37). Since vaccinia virus strain Copenhagen infection inhibited cytochrome c translocation and apoptosis, we asked if vaccinia virus
infection was able to inhibit apoptosis by maintaining mitochondrial
integrity and the inner mitochondrial membrane potential. Changes in
the membrane potential were monitored by assaying the uptake of TMRE, a
fluorescent mitochondrion-specific dye (18, 50).
Disruption of the membrane potential in mock-infected and infected
cells following staurosporine treatment was monitored by TMRE
fluorescence. In untreated Jurkat cells, 94% of the cells demonstrated
TMRE fluorescence, indicating an intact mitochondrial membrane
potential (Fig. 8a). Upon staurosporine
treatment, 48% of the cells exhibited a reduction in TMRE fluorescence
(Fig. 8b). As a control, Jurkat cells were treated with a membrane
uncoupler, ClCCP, resulting in the reduction of TMRE fluorescence in
all cells (Fig. 8c). Jurkat cells treated with staurosporine in the
presence of the caspase inhibitor zVAD.fmk still demonstrated a loss in
membrane potential (Fig. 8d), indicating that staurosporine-induced
loss of the mitochondrial membrane potential occurred in a
caspase-independent manner. This is in contrast to what was observed
with DNA fragmentation (Fig. 5c), because staurosporine directly
induces the loss of the PT in a caspase-independent manner whereas DNA
fragmentation requires caspase activation (58). As
expected, Jurkat cells overexpressing Bcl-2 were completely resistant
to the staurosporine-induced collapse of the inner membrane potential
(Fig. 8e and f). Similarly, upon treatment with staurosporine, 87% of
Jurkat cells infected with vaccinia virus maintained a TMRE-positive
state (Fig. 8g and h), indicating that vaccinia virus infection
inhibited staurosporine-induced loss of the inner mitochondrial
membrane potential. The addition of cytosine arabinoside (araC), an
inhibitor of virus replication and late gene expression, had no effect
on the ability of vaccinia virus to inhibit staurosporine-induced loss
of the inner mitochondrial membrane potential, indicating that virus
replication and late gene expression were not necessary (Fig. 8i and
j). In contrast, UV inactivation of the virus resulted in reversal of
this observation, clearly showing that a productive vaccinia virus
infection was necessary for the inhibition (Fig. 8k and l).
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FIG. 8.
Vaccinia virus strain Copenhagen infection inhibits
staurosporine-induced disruption of the mitochondrial membrane
potential. Jurkat cells were either mock infected or infected with
vaccinia virus and treated with 1 µM staurosporine for 1 h, and
the mitochondrial membrane potential was determined using TMRE
fluorescence. (a) Untreated Jurkat cells; (b) Jurkat cells treated with
staurosporine; (c) Jurkat cells treated with the membrane uncoupler
ClCCP; (d) Jurkat cells treated with staurosporine in the presence of
100 µM zVAD.fmk; (e) untreated Jurkat cells overexpressing Bcl-2; (f)
Jurkat cells overexpressing Bcl-2 treated with staurosporine; (g)
untreated Jurkat cells infected with vaccina virus strain Copenhagen;
(h) vaccinia virus-infected cells treated with staurosporine; (i)
Jurkat cells infected with vaccinia virus strain Copenhagen in the
presence of 40 µg of araC/ml; (j) Jurkat cells infected with vaccinia
virus strain Copenhagen in the presence of araC and staurosporine; (k)
untreated cells infected with UV-inactivated vaccinia virus strain
Copenhagen; (l) Jurkat cells infected with UV-inactivated vaccinia
virus and treated with staurosporine.
|
|
Controlled permeabilization of the inner and outer mitochondrial
membrane is known to occur as a result of opening a mitochondrial
multiprotein complex known as the PT pore (
12,
36,
37).
The PT pore consists of the
outer-mitochondrial-membrane-localized
voltage-dependent anion
carrier (VDAC), the inner-membrane-localized
ANT, and the matrix
protein cyclophilin D (
12,
36,
37).
Two accessory
proteins, hexokinase and the peripheral benzodiazepine
receptor, are
also found associated with the PT pore. Members
of the Bcl-2 family
associate with components of the pore and
modulate pore activity,
thereby inhibiting apoptosis (
12,
37,
42).
Since infection of cells with vaccinia virus renders them resistant to
apoptosis and inhibits disruption of the mitochondrial
inner-membrane
potential, we asked if vaccinia virus strain Copenhagen
infection
regulated apoptosis by modulating the activity of the
PT pore.
Pore-specific ligands can act directly on components
of the pore,
resulting in dissipation of the inner-membrane potential
and the
release of cytochrome
c (
32,
68,
72). To
ascertain
if vaccinia virus infection could inhibit induction of the
permeability
transition and subsequent apoptosis, we treated purified
mitochondria
with the ANT ligand atractyloside and monitored cytochrome
c release.
Mitochondria were isolated from mock-infected,
vaccinia virus-infected,
or Bcl-2-overexpressing cells and induced to
undergo permeability
transition with various concentrations of
atractyloside, and the
translocation of cytochrome
c was
monitored by Western blot analysis.
As shown in Fig.
9A, cytochrome
c translocation
from mock-infected
mitochondria was detected following treatment with 5 mM atractyloside,
and increasing levels of cytochrome
c
release were detected with
higher concentrations of atractyloside.
Atractyloside-induced
cytochrome
c translocation was
completely inhibited in mitochondria
isolated from cells overexpressing
Bcl-2, a known PT pore-modulating
protein (
42) (Fig.
9B).
As shown in Fig.
9C, atractyloside-induced
cytochrome
c
release from mitochondria isolated from vaccinia
virus-infected cells
was also completely inhibited, indicating
that vaccinia virus strain
Copenhagen infection inhibited the
onset of atractyloside-induced
mitochondrial permeability transition
and the subsequent translocation
of cytochrome
c. To further confirm
that vaccinia virus
infection inhibited the opening of the PT
pore, we treated Jurkat cells
with another permeability transition
inducer,
t-butylhydroperoxide, and monitored mitochondrial membrane
potential using TMRE fluorescence (
68,
72). As shown in
Fig.
9D, treatment of mock-infected cells with
t-butylhydroperoxide
resulted in disruption of the
mitochondrial membrane potential,
as shown by a decrease in TMRE
fluorescence. Disruption of the
membrane potential following
t-butylhydroperoxide treatment was
not inhibited by
zVAD.fmk, confirming previous findings that indicate
that
t-butylhydroperoxide does not disrupt membrane potential
through caspase activation (
68) (Fig.
9D). Infection with
vaccinia
virus strain Copenhagen, however, prevented loss of TMRE
fluorescence,
indicating that vaccinia virus infection regulates
the PT pore
(Fig.
9D).
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FIG. 9.
Vaccinia virus strain Copenhagen inhibits opening of the
PT pore. (A through C) Atractyloside-induced cytochrome
c release is inhibited by vaccinia virus strain
Copenhagen infection. Mitochondria were purified and incubated at
37°C with 5, 10, or 15 mM atractyloside (Atrac.) for 40 min.
Following treatment, samples were fractionated into
mitochondria-containing and soluble fractions, and translocation of
cytochrome c was analyzed by Western blot analysis. (A)
Mitochondria isolated from mock-infected Jurkat cells; (B) mitochondria
isolated from mock-infected Jurkat cells overexpressing Bcl-2; (C)
mitochondria isolated from vaccinia virus strain Copenhagen-infected
Jurkat cells. (D) Vaccinia virus inhibits
t-butylhydroperoxide-induced disruption of the
mitochondrial membrane potential. Jurkat cells were either mock
infected or infected with vaccinia virus and treated with 300 µM
t-butylhydroperoxide for 2 h. The mitochondrial
membrane potential was determined using TMRE fluorescence in the
presence and absence of 100 µM zVAD.fmk. Standard deviations were
generated from three independent experiments.
|
|
| |
DISCUSSION |
In order to survive and replicate within a host, viruses possess
specific strategies to circumvent the multifaceted immune response,
including a variety of strategies to inhibit apoptosis (63). The detection and apoptotic elimination of
virus-infected cells is mediated by specialized classes of lymphocytic
cells referred to as CTL and natural killer cells. The
Poxviridae, of which vaccinia virus is the prototypic
member, are large double-stranded DNA viruses that encode many proteins
essential for evading the antiviral immune response (56).
Until now, the modulation of apoptosis by vaccinia virus has been
attributed primarily to expression of the serine proteinase inhibitor
Spi-2 (33, 59, 71). Previous reports, however, have
suggested that vaccinia virus may foster an additional mechanism to
interfere with apoptosis (15, 33, 54). In this study we
report for the first time that vaccinia virus strain Copenhagen
regulates the mitochondrial apoptotic pathway by inhibiting the PT pore.
Since recent advances in apoptosis have implicated mitochondria as a
central control point in cell death, we specifically asked if vaccinia
virus employed a mechanism to interfere with the mitochondrial
component of apoptotic death (13, 37). Considering that
numerous viruses encode mediators of this cascade, we predicted that
vaccinia virus infection would also result in maintenance of
mitochondrial integrity following the addition of a proapoptotic stimulus. To perform our studies we utilized Jurkat cells, which, due
to lower levels of caspase 8 activation, undergo Fas-mediated apoptosis exclusively through the mitochondrial route
(51). In addition, we chose to utilize vaccinia virus
strain Copenhagen, because it is naturally devoid of the caspase
8-inhibitor crmA/Spi-2 (19). Using this approach we found
that vaccinia virus strain Copenhagen infection inhibited cell death
mediated through the Fas surface receptor. Since this strain of
vaccinia virus does not contain a functional Spi-2 protein, this result
clearly indicated that vaccinia virus strain Copenhagen employed a
novel, Spi-2-independent antiapoptotic mechanism. Prior to this study,
other researchers have suggested the existence of a Spi-2-independent
antiapoptotic effect conferred by vaccinia virus infection. Dobbelstein
and Shenk found that some HeLa cells infected with a vaccinia virus lacking Spi-2 were still protected from apoptosis (15). In
addition, Kettle and coworkers reported the existence of a
Spi-2-independent mechanism that was capable of inhibiting
cycloheximide-induced apoptosis (33). More recently,
Shisler and Moss found that infection with a Spi-2-deficient virus
inhibited cleavage of the caspase 3 substrate PARP (54).
To define more clearly the mechanism of vaccinia virus apoptosis
inhibition, we monitored both the activation of caspase 3 and the
translocation of cytochrome c in response to treatment with
anti-Fas. Jurkat cells infected with vaccinia virus strain Copenhagen
and treated with anti-Fas displayed reductions in both the activation
of caspase 3 and the translocation of cytochrome c compared
to mock-infected cells, clearly indicating that the block in apoptosis
was upstream of cytochrome c release. Similarly, apoptosis induced by staurosporine was also dramatically inhibited in
cells infected with vaccinia virus strain Copenhagen. Once again, both
caspase 3 activation and cytochrome c release were inhibited, demonstrating that the novel mechanism employed by vaccinia
virus occurred upstream of cytochrome c release. Analysis of
Bid activation in an in vitro reconstitution assay indicated that
vaccinia virus did not inhibit cleavage of Bid, allowing us to rule out
the possiblity of interference with Bid activation. Western blot
analysis of cytochrome c in the same in vitro reconstitution assay using mitochondria purified from infected and uninfected cells
once again revealed that vaccinia virus interferes with the
translocation of cytochrome c. Taken together, the data
clearly suggest that vaccinia virus infection inhibited apoptosis by
functioning directly at the mitochondria. Recently, M11L,
encoded by the poxvirus myxoma virus, has been shown to localize to the
mitochondria and inhibit apoptosis (17). Numerous
virus-encoded Bcl-2 homologues and a novel protein from HCMV, vMIA,
also inhibit apoptosis by functioning at the mitochondria (20,
64). Interestingly, no open reading frame exists in vaccinia
virus strain Copenhagen that displays homology with known virus-encoded
or cellular apoptotic inhibitors, suggesting that vaccinia virus has
evolved a novel mechanism to inhibit cytochrome c release
and apoptosis (19).
Although the exact mechanism of cytochrome c release during
apoptosis is still controversial, the release of cytochrome
c has been linked to disruption of the
inner-mitochondrial-membrane potential (12, 36, 37, 41,
69). Dissipation of the inner-mitochondrial-membrane potential
is a common and irreversible feature of apoptosis. We found that
following treatment with staurosporine, cells infected with vaccinia
virus strain Copenhagen retained the inner-mitochondrial-membrane potential, as monitored by TMRE fluorescence. This result supported our
previous observations demonstrating that within infected cells the
integrity of the mitochondria was maintained and cytochrome c translocation was inhibited. Loss of the membrane
potential occurs by triggering opening of the PT pore, a phenomenon
known as the "permeability transition" (12, 36, 37).
Since disruption of the inner-mitochondrial-membrane potential and the
induction of apoptosis occurs as a result of opening of the PT pore,
our data suggested that perhaps vaccinia virus could maintain
mitochondrial integrity by regulating the opening of the PT pore. In
support of this we found that vaccinia virus infection inhibited
cytochrome c release from mitochondria treated with
increasing amounts of atractyloside, a pore agonist known to induce the
permeability transition and the release of cytochrome c
(32, 68, 72). In addition, we found that vaccinia
virus-infected cells treated with the pro-oxidant
t-butylhydroperoxide, which also causes disruption of the
mitochondrial transmembrane potential, demonstrated preservation of the
mitochondrial inner-membrane transmembrane potential (68). Thus, vaccinia virus infection inhibited the effects mediated by both
atractyloside and t-butylhydroperoxide, two reagents that trigger the permeability transition. In addition, both Bid and staurosporine can induce apoptosis via a PT pore-dependent mechanism, and we found that vaccinia virus infection also inhibited apoptosis induced by these reagents (58, 67). Our data are therefore compatible with the idea that vaccinia virus has evolved a mechanism to
directly modulate the permeability transition and thereby inhibit apoptosis (Fig. 10).
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FIG. 10.
Model of vaccinia virus-mediated apoptosis inhibition.
Fas initiated apoptosis occurs via activation of caspase 8 and by the
subsequent proteolytic cleavage of Bid. Once cleaved, Bid translocates
to the mitochondria, resulting in a loss of the
inner-mitochondrial-membrane permeability transition and the release of
cytochrome c. The release of cytochrome c
(Cyto. c) results in activation of caspase 9 via interaction with the
adapter molecule Apaf1 and the subsequent activation of caspase 3. Additionally, loss of the inner-membrane permeability transition can be
triggered by staurosoporine and atractyloside. Vaccinia virus infection
manipulates this pathway at two separate points. First, the vaccinia
virus-encoded serine protease inhibitor SPI-2/crmA inhibits the
activity of caspase 8. Second, vaccinia virus infection also inhibits
apoptosis by modulating the PT pore, thereby preventing the loss of
cytochrome c and activation of caspase 9.
|
|
Due to the multimeric nature of the PT pore, multiple targets for viral
modulation are possible. Both pro- and antiapoptotic members of the
Bcl-2 family associate with components of the PT pore and modulate
apoptosis (12, 37, 42). At least one component of the PT
pore has now been directly associated with virus-mediated apoptotic
inhibition. The vMIA protein from HCMV associates with the ANT and
inhibits apoptosis (20). Alternatively, proapoptotic viral
proteins such as Vpr encoded by human immunodeficiency virus and HBx
encoded by hepatitis B virus induce apoptosis by interaction with ANT
and VDAC, respectively (29, 30, 47). Collectively, Vpr,
HBx, and vMIA modulate apoptosis by interacting with components of the
PT pore and regulating the pore complex. Thus, a similar scenario to
account for vaccinia virus interference with the mitochondrial apoptotic pathway is likely, and we are currently looking for vaccinia
virus proteins that interact with known components of the pore. At
present, however, the exact composition of the PT pore is still
controversial, and the identification of a novel vaccinia virus-encoded
protein and its exact mechanism of action will lead to a clearer
understanding of the PT pore and its regulation in the future. In
addition, further investigation into vaccinia virus modulation of the
PT pore and apoptosis will result in valuable information regarding
virus-host interactions and the mechanisms of cell death.
| |
ACKNOWLEDGMENTS |
This work was supported by grants from the Canadian Institutes
for Health Research and the Alberta Heritage Foundation for Medical
Research (to M.B.). M.B. is the recipient of an Alberta Heritage
Foundation for Medical Research Scholar Award, and A.F.A.M. is the
recipient of a studentship from the Canadian Institutes for Health Research.
We thank D. Burshtyn and S. Slemko for critical review of the
manuscript and H. Everett for helpful discussions.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medical Microbiology and Immunology, 671 Heritage Medical Research
Center, University of Alberta, Edmonton, Alberta, Canada T6G 2S2.
Phone: (780) 492-0702. Fax: (780) 492-9828. E-mail:
michele.barry{at}ualberta.ca.
| |
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Journal of Virology, December 2001, p. 11437-11448, Vol. 75, No. 23
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.23.11437-11448.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
