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Molecular and Cellular Biology, June 2000, p. 3781-3794, Vol. 20, No. 11
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Granzyme B Short-Circuits the Need for Caspase 8 Activity during Granule-Mediated Cytotoxic T-Lymphocyte Killing by
Directly Cleaving Bid
Michele
Barry,1
Jeffrey A.
Heibein,1
Michael J.
Pinkoski,2
Siow-Fong
Lee,3
Richard W.
Moyer,4
Douglas R.
Green,2 and
R. Chris
Bleackley1,*
Department of Biochemistry, University of
Alberta, Edmonton, Alberta T6G 2H7,1 and
Department of Laboratory Medicine and Pathology, University of
Alberta Hospital, Edmonton, Alberta T6G 2B7,3
Canada; La Jolla Institute for Allergy and Immunology, San
Diego, California 921222; and Department
of Molecular Genetics and Microbiology, University of Florida,
Gainesville, Florida 32610-02664
Received 7 July 1999/Returned for modification 20 September
1999/Accepted 22 February 2000
 |
ABSTRACT |
Cytotoxic T lymphocytes (CTL) can trigger an apoptotic signal
through the Fas receptor or by the exocytosis of granzyme B and
perforin. Caspase activation is an important component of both
pathways. Granzyme B, a serine proteinase contained in granules, has
been shown to proteolytically process and activate members of the
caspase family in vitro. In order to gain an understanding of the
contributions of caspases 8 and 3 during granule-induced apoptosis in
intact cells, we have used target cells that either stably express the
rabbitpox virus-encoded caspase inhibitor SPI-2 or are devoid of
caspase 3. The overexpression of SPI-2 in target cells significantly
inhibited DNA fragmentation, phosphatidylserine externalization, and
mitochondrial disruption during Fas-mediated cell death. In contrast,
SPI-2 expression in target cells provided no protection against
granzyme-mediated apoptosis, mitochondrial collapse, or cytolysis,
leading us to conclude that SPI-2-inhibited caspases are not an
essential requirement for the granzyme pathway. Caspase 3-deficient
MCF-7 cells were found to be resistant to CTL-mediated DNA
fragmentation but not to CTL-mediated cytolysis and loss of the
mitochondrial inner membrane potential. Furthermore, we demonstrate
that granzyme B directly cleaves the proapoptotic molecule Bid,
bypassing the need for caspase 8 activation of Bid. These results
provide evidence for a two-pronged strategy for mediating target cell
destruction and provide evidence of a direct link between granzyme B
activity, Bid cleavage, and caspase 3 activation in whole cells.
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INTRODUCTION |
A critical event during apoptosis is
the proteolytic cleavage and activation of a family of cysteine
proteases which have been collectively referred to as caspases (8,
52). Caspase activation requires sequence-specific proteolytic
processing at internal aspartate residues in order to convert the
inactive zymogen to an active protease. Fourteen caspases have now been
identified, which can be divided into three subfamilies based upon
their distinct substrate specificities (77). Caspases 1, 4, and 5 (group 1) play a role in cytokine maturation and inflammation,
whereas group 2 (caspases 2, 3, and 7) and group 3 (caspases 6, 8, 9, and 10) caspases are directly involved in apoptosis. Group 2 and Group 3 can be further divided into initiator and effector caspases. Initiator caspases, such as caspase 8, 9, and 10, are responsible for
the activation of downstream effector caspases, such as caspases 3, 6, and 7, which in turn are responsible for the cleavage and inactivation
of a multitude of intracellular proteins and the eventual demise of the
cell (69).
A wide range of external stimuli induce caspase activation and
apoptosis, including the interaction of cytotoxic T lymphocytes (CTL)
with target cells. CTL are important for the removal of both
virus-infected and malignant cells and can destroy target cells by two
distinct caspase-dependent mechanisms (2). The first and
best-characterized pathway involves ligation of the Fas death receptor
on the surface of target cells (54). Engagement of the Fas
receptor culminates in the recruitment of caspase 8 via the adapter
molecule FADD (also called MORT1) (3, 50). Recruitment of
caspase 8 results in the autocatalytic activation of this caspase
(51, 80), which is then capable of activating downstream
caspases either by direct proteolytic cleavage or indirectly through
the activation of Bid and the release of mitochondrial apoptosis-inducing proteins such as cytochrome c (21,
28, 37, 40, 62, 82). The second pathway of CTL-induced cell death
involves the calcium-dependent exocytosis of cytolytic granules from
CTL. The granules of CTL are composed of a variety of proteins necessary for inducing target cell death (20, 66). Included among these are perforin, a pore-forming protein that is thought to
facilitate the entry of other granule-contained proteins, and a family
of the serine proteases known as granzymes.
Granzyme B displays unique substrate specificity for a member of the
serine proteinase family, proteolytically cleaving proteins following
aspartate residues (4, 53, 55). Significantly, the first
substrate identified for granzyme B was found to be a member of the
caspase family, caspase 3 (9). Multiple caspase proteins
have now been identified, and many serve as substrates for granzyme B
in vitro (6, 9, 13, 14, 22, 50, 57, 74, 78), suggesting that
granzyme B induces apoptosis by triggering the activation of multiple
caspases within intact cells. Additionally, studies have shown that
caspases 1, 2, 3, 6, 7, and 8 are proteolytically processed in cells
following granule-mediated apoptosis (1, 6, 9, 15, 16, 48,
64). Thus far, however, only caspases 8 and 3 have been shown to
be direct substrates for granzyme B in intact cells (1, 48,
81), indicating that the activations of caspases 8 and 3 are
potentially critical events during granule-mediated apoptosis.
Caspase 8 is the first caspase activated during Fas-mediated cell death
and is essential for activating the proapoptotic molecule Bid,
resulting in release of cytochrome c from the mitochondria (21, 28, 40, 82). Caspase 8 therefore represents a crucial step for Fas-induced apoptosis. Although granule-mediated apoptosis is
also known to result in the activation of caspases, including caspase
8, information is still lacking regarding the specific role that
activation of each caspase plays within whole cells. Since caspase 8 is
a direct substrate for granzyme B in whole cells (48) and
can activate other members of the caspase family, including caspase 3 (67, 68), it can be argued that the activation of caspase 8 by granzyme B may be an important step during granule-mediated cell
death. The contribution of caspase 8 activity during granule-mediated apoptosis, however, has not been fully evaluated.
Many viruses encode proteins that specifically interfere with caspase 8 (49), providing unique macromolecular tools for dissecting
caspase cascades induced by proapoptotic stimuli like CTL. One example
is the poxvirus-encoded serine proteinase inhibitor designated CrmA in
cowpox virus, which is also referred to as SPI-2 in other members of
the poxvirus family. CrmA/SPI-2 is a potent inhibitor of both caspase 1 and caspase 8 and has been used extensively for elucidating apoptotic
cascades (83). In order to investigate the contribution of
caspase 8 during granule-mediated cell death in whole cells, we
utilized Jurkat cells transfected with the rabbitpox virus
crmA gene, SPI-2. As anticipated, SPI-2 was an
excellent inhibitor of apoptosis induced through the Fas receptor. In
contrast, SPI-2 expression provided no protection against
granule-mediated cell death. Although caspase 8 was proteolytically cleaved during granule-mediated cell death, our data indicate that
granule-mediated CTL killing can short-circuit the need for caspase 8 activity. In support of this, we demonstrate for the first time that
granzyme B directly cleaves the proapoptotic molecule Bid.
Additionally, MCF-7 cells, a breast carcinoma cell line which is
naturally devoid of caspase 3, were found to be refractory to
granzyme-induced DNA fragmentation but were still susceptible to
CTL-mediated lysis, mitochondrial dysfunction, and death. The ability
of CTL to activate multiple caspase members in addition to inducing
cell death via caspase-independent processes through the activation of
Bid indicates that CTL are extremely well equipped to ensure target
cell death.
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MATERIALS AND METHODS |
Cell lines.
Jurkat cells were grown in RPMI 1640 medium
(Gibco BRL Life Technologies Inc.) supplemented with 10% fetal calf
serum (FCS) (Hyclone), 25 mM HEPES, 100 µM 2-mercaptoethanol, 100 µg of penicillin per ml, and 100 µg of streptomycin per ml (RHFM).
Stably transfected Jurkat cells were maintained in RHFM supplemented
with 800 µg of G418 (Gibco BRL Life Technologies Inc.) per ml. MCF-7
cells were purchased from the American Type Culture Collection and
routinely cultured in RHFM supplemented with 100 µM nonessential
amino acids (Gibco BRL Life Technologies Inc.). Human CTL (hCTL) were
generated as previously described (1) and maintained in RHFM
containing 90 U of interleukin 2 (Chiron) per ml.
Reagents.
The purification of human granzyme B from YT cells
was performed as previously described (5, 23). The
replication-deficient adenovirus type 5 dl1-70 was supplied
by J. Gauldie, McMaster University, Hamilton, Ontario, Canada. Murine
anti-human Fas antibody (clone CH-11) was purchased from Upstate
Biotechnology Incorporated and routinely used at 250 ng/ml to induce
DNA fragmentation. Staurosporine was purchased from Sigma and used at 5 µM. The caspase inhibitors zVAD-fmk and zIETD-fmk were purchased from
Kamiya Biomedical. Jurkat cells were pretreated with caspase inhibitors
for 60 min prior to the addition of apoptosis-inducing reagents.
Polyclonal rabbit anti-caspase 3 and anti-caspase 8 antiserum was
provided by D. W. Nicholson, Merck Frosst Centre for Therapeutic
Research, Pointe Claire, Quebec, Canada. The murine anti-SPI-2
monoclonal antibody was provided by R. W. Moyer, University of
Florida, Gainesville. The polyclonal rabbit anti-Bid antibody was
provided by X. Wang, University of Texas Southwestern Medical Center, Dallas.
Generation of stable transfected cell lines.
The rabbitpox
virus SPI-2 gene was subcloned into the XhoI site of
eucaryotic expression vector BMGneo (31). Jurkat cells (5 × 106) were stably transfected with 10 µg of
NotI-linearized DNA by electroporation (250 V, 250 µF).
Stably transfected cells were selected with 1 mg of G418 (GIBCO BRL
Life Technologies Inc.) per ml and cloned by limiting dilution. Once
selected, the resulting cells were routinely grown in RHFM containing
800 µg of G418 (Gibco BRL Life Technologies Inc.) per ml. Two clones
(clones 4 and 5) generated from this transfection were chosen for
further analysis.
Apoptosis induction.
Jurkat cells were resuspended at
106 cells/ml in RHFM. Granzyme B (1 µg/ml) and adenovirus
(10 PFU/cell) were added directly to the cell suspension. Cells were
incubated at 37°C for either 2 or 4 h. For Fas killing, 250 ng
of anti-Fas antibody (clone CH11) per ml was added directly to the
cells, and the cells were incubated at 37°C and then analyzed at the
times indicated.
Immunoblotting.
Cellular lysates were collected by directly
harvesting 106 cells into 100 µl of sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gel loading
buffer and subjected to SDS-PAGE analysis. Proteins were transferred to
nitrocellulose (Micron Separations Inc.) by using a semidry transfer
apparatus (Tyler Corp.) for 1 h at 150 mA. Membranes were blocked
in phosphate-buffered saline (PBS) containing 0.1% Tween 20 (ICN
Biomedicals Inc.) and 5% skim milk for 16 h. Caspases 3 and 8 were detected using polyclonal rabbit anti-caspase 3 or anti-caspase 8 antiserum at a dilution of 1:10,000 or 1:2,000 respectively. Expression
of SPI-2 in stably transfected Jurkat cells was verified by
immunoblotting using a murine anti-SPI-2 monoclonal antibody at a
dilution of 1:20. Bid expression and cleavage were detected using
polyclonal rabbit anti-Bid antiserum at a dilution of 1:3,000. All
primary antibodies were incubated with the membrane for at least 2 h, after which the blot was washed three times in PBS containing 0.1%
Tween 20. The membranes were probed with either a horseradish
peroxidase-conjugated goat anti-rabbit secondary antibody (Bio-Rad
Laboratories) at a 1:20,000 dilution or a horseradish
peroxidase-conjugated goat anti-murine secondary antibody (Jackson
ImmunoResearch Laboratories) at a 1:3,000 dilution. Transferred
proteins were visualized with a chemiluminescence detection system
(Amersham Inc.) for caspase 3 and 8 detection or with SuperSignal
substrate (Pierce) for SPI-2 expression according to the
manufacturers' directions.
Flow cytometric analysis of DNA fragmentation.
DNA
fragmentation in Jurkat cells was monitored by flow cytometric analysis
via the terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick
end labeling (TUNEL) method (19). Cells (106)
were harvested and washed in PBS containing 1% FCS. The cells were
then fixed in 200 µl of 2% paraformaldehyde for 30 min at room
temperature with constant agitation. Following fixation, cells were
washed three times in PBS containing 1% FCS prior to permeabilization
in 100 µl of 0.1% Triton X-100-0.1% sodium citrate for 2 min on
ice. The cells were washed again in PBS containing 1% FCS and then
incubated for 1 h at 37°C in 30 µl of 30 mM Tris (pH 7.2)-140
mM cacodylate-0.6 nmol of fluorescein-12-dUTP-3 nmol of dATP-1 mM
CoCl2-25 U of terminal deoxynucleotidyltransferase (Boehringer Mannheim). After incubation, cells were washed in PBS
containing 1% FCS prior to flow cytometric analysis performed on a
Becton Dickinson FACScan flow cytometer equipped with an argon-ion
laser with 15 mW of excitation at 488 nm. Emission wavelengths were
detected through the FL1 channel equipped with a 530-nm filter (20-nm
band-pass). Data were acquired on 10,000 cells per sample with light
scatter signals at linear gain and fluorescence signals at logarithmic gain.
Detection of phosphatidylserine externalization.
Phosphatidylserine externalization was monitored using the ApoAlert
annexin V apoptosis kit (Clontech) according to the protocol provided
by the manufacturer. Flow cytometric analysis was performed on a Becton
Dickinson FACScan flow cytometer equipped with an argon-ion laser with
15 mW of excitation at 488 nm. Emission wavelengths were detected
through the FL1 channel equipped with a 530-nm filter (20-nm
band-pass). Annexin V-fluorescein isothiocyanate binding was
quantitated using flow cytometric analysis by examining 10,000 cells
per sample.
Chromium and [3H]thymidine release assays.
51Cr and [3H]thymidine release assays were
performed as previously described (18). Briefly, target
cells were preincubated with 51Cr (Dupont NEN) or with
[3H]thymidine (Dupont NEN) at 37°C for 1 or 24 h,
respectively. Labeled target cells were incubated with hCTL at the
indicated effector-to-target ratios. 51Cr release was
quantitated after 4 h, and [3H]thymidine release was
quantitated after 2 h. 51Cr and
[3H]thymidine releases were calculated as follows:
percent lysis = 100 × (sample release 
spontaneous
release)/(total release spontaneous release).
Detection of mitochondrial transmembrane potential and production
of reactive oxygen species.
Changes in mitochondrial transmembrane
potential and production of reactive oxygen species were quantitated as
previously described (24). Briefly, cells were
simultaneously loaded with 40 nM 3,3'-dihexyloxacarbocyanine iodide
[DiOC6(3)] (Molecular Probes) and 2 µM hydroethidine
(Molecular Probes) prior to flow cytometric analysis in order to detect
changes in mitochondrial transmembrane potential and the production of
reactive oxygen species, respectively. As a control, cells were also
treated with the membrane uncoupler carbonyl cyanide
m-chlorophenylhydrazone (mClCCP) (Sigma) at a final
concentration of 5 µM (27).
In vitro cleavage of Bid.
Bid was in vitro transcribed and
translated in the presence of [35S]methionine using the
coupled transcription-translation TNT kit (Promega). Purified granzyme
B was added to in vitro-transcribed and translated Bid at a range of
amounts (0, 0.001, 0.0025, 0.01, 0.025, 0.1, 0.25, and 1.0 µg).
Following digestion, reaction products were analyzed by SDS-PAGE and
visualized by phosphorimager analysis using a Molecular Dynamics Storm 860.
| |
RESULTS |
SPI-2 expression protects cells from anti-Fas-mediated
apoptosis.
To determine whether caspase 8 activity was a critical
component of granule-mediated cell death, we stably transfected Jurkat cells with the rabbitpox virus serpin SPI-2. Expression of SPI-2 in
various G418-resistant Jurkat clones was monitored by Western blotting
analysis using a monoclonal antibody that was raised against
recombinant SPI-2 protein. Figure 1A
demonstrates that two Jurkat clones, clones 4 and 5, transfected with
BMGneo-SPI-2 both expressed SPI-2 protein (lanes 1 and 2) but that
Jurkat cells transfected with empty vector alone did not (lane 3).
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FIG. 1.
SPI-2 expression inhibits Fas-mediated DNA fragmentation
and caspase 3 activation. (A) Immunoblot analysis of SPI-2 expression
in stably transfected Jurkat cells. Jurkat cells transfected with SPI-2
BMGneo [JSPI-2(4) and JSPI-2(5)] (lanes 1 and 2) express SPI-2,
whereas cells transfected with the empty vector (Jneo) (lane 3) do not.
(B) Jurkat cells were treated with 250 ng of anti-Fas antibody per ml
for 8 h, and DNA fragmentation was monitored by TUNEL assay as
described in Materials and Methods. Panels: a, untreated Jneo cells; b,
Jneo cells treated with anti-Fas; c, Jneo cells treated with anti-Fas
in the presence of 100 µM zIETD-fmk; d, untreated JSPI-2 (clone 4);
e, JSPI-2 (clone 4) treated with anti-Fas; f, untreated JSPI-2 (clone
5); g, JSPI-2 (clone 5) treated with anti-Fas. Representative data from
three experiments are shown. (C) Caspase 3 activation in untreated Jneo
cells (lane 1), Jneo cells treated with anti-Fas antibody for 8 h
(lane 2), untreated JSPI-2 (clone 4) cells (lane 3), JSPI-2 (clone 4)
cells treated with anti-Fas (lane 4), untreated JSPI-2 (clone 5) cells
(lane 5), and JSPI-2 (clone 5) cells treated with anti-Fas (lane 6) was
monitored by Western blotting.
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|
Previous studies have shown that expression of cowpox virus CrmA and
rabbitpox virus and vaccinia virus SPI-2 protects cells
from
Fas-mediated apoptosis (
12,
25,
33,
41,
76). The
functionality of SPI-2 in our cloned cell lines was therefore
assessed
by determining whether the presence of SPI-2 could inhibit
DNA
fragmentation initiated via triggering the Fas surface receptor.
Cells
were treated with anti-Fas antibody for 8 h, and DNA fragmentation
was assessed using flow cytometry by quantitating the terminal
deoxynucleotidyl transferase-mediated addition of fluorescein-labeled
dUTP onto the ends of fragmented DNA. Untreated Jurkat cells
transfected
with the empty vector demonstrated 2% of the cells
undergoing
DNA fragmentation (Fig.
1B, panel a). Following 8 h of
anti-Fas
treatment, 59% of the cells transfected with the empty vector
underwent DNA fragmentation (Fig.
1B, panel b). This DNA fragmentation
could be completely abolished by preincubating the cells for 1
h
with the peptide-based caspase inhibitor zIETD-fmk (Fig.
1B,
panel c).
Jurkat cells transfected with SPI-2 in the absence of
anti-Fas antibody
demonstrated little DNA fragmentation (Fig.
1B, panels d and f). In
contrast to cells transfected with the
empty vector and treated with
anti-Fas antibody, both SPI-2-expressing
Jurkat clones showed
significantly less DNA fragmentation (15
and 17%, respectively) (Fig.
1B, panels e and g), indicating that
the SPI-2 expressed in these cells
was functional and provided
protection against Fas-mediated apoptosis.
Similar results were
obtained using a
3H release assay
(data not shown). In agreement with previous studies,
the expression of
SPI-2 in our Jurkat clones did not protect cells
from
staurosporine-induced DNA fragmentation (data not shown),
further
indicating that our cloned cell lines exhibited the normal
spectrum of
SPI-2 activities (
7).
To confirm that SPI-2 was in fact operating upstream of caspase 3 activation, we also monitored Fas-mediated caspase 3 processing,
since
caspase 3 is thought to be the major target for activated
caspase 8 (
63,
68). Caspase 3 activation was assessed by Western
blotting analysis using an antibody raised against the large subunit
of
the active caspase. Jurkat cells treated with anti-Fas antibody
showed
the conversion of full-length 32 kDa procaspase 3 to the
mature 19- and
17-kDa forms (Fig.
1C, lane 2). In contrast, both
Jurkat clones that
express SPI-2 demonstrated only minor amounts
of active caspase 3 in
response to Fas ligation (Fig.
1C, lanes
4 and
6).
Caspase 8 is processed during CTL-mediated cytotoxicity.
The
observation that purified granzyme B can proteolytically cleave and
activate members of the caspase family in vitro suggests that caspases
may be directly activated by granzyme B in intact cells. Since we and
others have previously shown that granzyme B directly cleaves and
activates caspase 3, it is possible that the activation of initiator
caspases, such as caspase 8, is not a necessary step during
granule-mediated cell death (1, 81). Caspase 8, however, has
previously been shown to be a substrate for granzyme B in vitro and is
processed during granule-mediated cell death in HeLa cells (48,
50).
To determine whether caspase 8 was in fact processed in Jurkat cells
during granule-mediated cell death, we monitored its
proteolytic
activation by Western blotting analysis. Jurkat cells
were treated with
hCTL, which have previously been demonstrated
to kill these cells via
the calcium-dependent granule-mediated
pathway, at an
effector-to-target ratio of 2:1 (
1). Caspase
8 processing
was visualized using an antibody raised against the
large 20-kDa
subunit of the active caspase. Jurkat cells treated
with zVAD-fmk in
the absence of hCTL demonstrated full-length
55-kDa caspase 8 (Fig.
2A,
lane 1). Unprocessed caspase 8 was
also detected in hCTL (Fig.
2A, lane 2). Processing of caspase
8 to a
44-kDa fragment was first detected after 60 min, and increased
amounts
were seen at 90 and 120 min (Fig.
2A, lanes 5, 6, and
7). Generation of
the 44-kDa product occurs as a result of removal
of the small 10-kDa
subunit from the full-length caspase (
47,
48). We also
routinely observed the generation of a 27-kDa fragment,
which was first
observed 90 min after the addition of hCTL (Fig.
2A, lane 6). Since the
caspase 8 antibody was raised against the
20-kDa subunit of the active
caspase, processing to the 27-kDa
fragment probably represents removal
of the prodomain from a fragment
containing both the 20- and 10-kDa
subunits of the active caspase.
Curiously, we were unable to observe
further processing to the
20-kDa subunit, which the antibody was raised
against, possibly
due to the rapid turnover of this subunit, as
previously suggested
(
58). Additionally, when Jurkat cells
were treated with anti-Fas
antibody for 4, 8, or 20 h, we also
observed processing of caspase
8 to a 44-kDa fragment and a 27-kDa
fragment (Fig.
2B, lanes 2
to 4) but could not observe further
processing to the 20-kDa subunit.
Taken together, these observations
indicate that during granule-mediated
cell death, caspase 8 undergoes
proteolytic processing.
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FIG. 2.
Caspase 8 is processed in target cells following the
addition of whole CTL or anti-Fas antibody. (A) Jurkat cells were
incubated with whole hCTL at an effector-to-target ratio of 2:1. Cell
lysates were generated at the times indicated and immunoblotted for
caspase 8 activation. (B) Jurkat cells were treated with 250 ng of
anti-Fas antibody per ml for 0, 4, 8, and 20 h, and caspase 8 activation was assessed by Western blotting analysis. (C) Jurkat cells
were incubated with whole hCTL at an effector-to-target ratio of 2:1.
Cell lysates were generated at the times indicated and immunoblotted
for caspase 3 activation.
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|
In order to determine the timing of caspase 8 activation with respect
to caspase 3 activation, we monitored caspase 3 cleavage
by Western
blotting. Untreated Jurkat cells and hCTL demonstrated
full-length
caspase 3 (Fig.
2C, lanes 1 and 2) which was rapidly
converted to the
p20 fragment following the addition of hCTL.
We were able to detect
activation of caspase 3 as early as 15
min after hCTL addition (Fig.
2C, lane 3). At 30 min the initial
conversion of p20 to p19 was evident
(Fig.
2C, lane 4), and this
increased with time (Fig.
2C, lanes 4 to
7).
Caspase 8 activity is not a necessary component of CTL-mediated
cytotoxicity.
Since multiple caspases are activated during
CTL-mediated killing and since both caspase 8 and caspase 3 have been
shown to be activated directly by granzyme B, we investigated the
contribution of caspase 8 activity during granule-mediated cell death
using cells expressing the poxvirus caspase 8 inhibitor SPI-2. Cells undergoing apoptosis display a number of characteristic biochemical features, such as DNA fragmentation, mitochondrial disruption, and
membrane alterations which include the externalization of phosphatidylserine residues on the outer leaflet of the plasma membrane
and 51Cr release. These morphological changes can be
monitored biochemically using a variety of assays.
Externalization of phosphatidylserine onto the surface of the plasma
membrane is an early indicator of apoptosis and is important
for the
recognition and clearance of apoptotic cells by phagocytes
(
35,
44,
61). We used flow cytometric analysis to monitor
the
externalization of phosphatidylserine by quantitating the
amount of
fluorescein-labeled annexin V binding. Cell death was
induced by
treatment either with anti-Fas or with granzyme B and
adenovirus, which
has previously been shown to replace the need
for perforin
(
16). Jurkat cells transfected with the empty vector
or
transfected with SPI-2 demonstrated little externalization
of
phosphatidylserine in the absence of proapoptotic stimuli (Fig.
3a, d,
and g). After exposure to anti-Fas
treatment for 8 h or
exposure to granzyme B and adenovirus for
4 h, 56 and 26%, respectively,
of the control cells displayed
phosphatidylserine on the outer
leaflet of the plasma membrane (Fig.
3b
and c). The expression
of SPI-2 resulted in an inhibition of
phosphatidylserine externalization
in response to anti-Fas (Fig.
3e and
h) but not after treatment
with granzyme B and adenovirus (Fig.
3f and
i). This indicates
that the presence of SPI-2 does not protect cells
from granzyme
B-mediated phosphatidylserine exposure and also
presumably the
subsequent engulfment of apoptotic cells by phagocytes.
Pretreatment
of Jurkat cells with the pan-specific caspase inhibitor
zVAD-fmk
completely blocked phosphatidylserine externalization in
response
to either anti-Fas or granzyme B and adenovirus treatment,
demonstrating
that caspase activation is a necessary component of
granzyme B-
and adenovirus-induced phosphatidylserine exposure
(reference
24 and data not shown). SPI-2 expression
in target cells, however,
had no effect on granzyme-mediated
phosphatidylserine externalization,
indicating that caspases not
inhibited by SPI-2 are important
for this phenomenon during
granzyme-mediated death.
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FIG. 3.
SPI-2 expression inhibits phosphatidylserine exposure in
response to anti-Fas but not in response to granzyme B. Phosphatidylserine exposure was quantitated by annexin V-fluorescein
isothiocyanate binding following treatment with 250 ng of anti-Fas per
ml or treatment with granzyme B (1 µg/ml) and adenovirus (10 PFU/cell). (a) Untreated Jneo cells; (b) Jneo cells treated with
anti-Fas; (c) Jneo cells treated with granzyme B and adenovirus; (d)
untreated JSPI-2 (clone 4); (e) JSPI-2 (clone 4) cells treated with
anti-Fas; (f) JSPI-2 (clone 4) cells treated with granzyme B and
adenovirus; (g) untreated JSPI-2 (clone 5); (h) JSPI-2 (clone 5) cells
treated with anti-Fas; (i) JSPI-2 (clone 5) cells treated with granzyme
B and adenovirus. Representative data from three experiments are
shown.
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|
Since the presence of granzyme B plays an essential role in the
induction of target cell DNA fragmentation during CTL-mediated
death
(
26), we also examined the ability of SPI-2 expression
to
inhibit granzyme B-induced DNA fragmentation. Jurkat cells
were treated
with purified granzyme B and adenovirus, and the
percentage of cells
undergoing DNA fragmentation was quantitated
by flow cytometry. Cells
transfected with the empty vector showed
little DNA fragmentation in
the presence of either granzyme B
alone or adenovirus alone (Fig.
4a, c, and d). When purified granzyme
B
and adenovirus were added together to these same cells, 65%
of the
cells displayed DNA fragmentation (Fig.
4b). Likewise,
Jurkat clones 4 and 5 expressing SPI-2 showed no DNA fragmentation
in the absence of
proapoptotic stimuli (Fig.
4e and g). When granzyme
B and adenovirus
were added, 71 and 62% of the cells, respectively,
were observed to
undergo DNA fragmentation (Fig.
4f and h). Thus,
we were unable to
detect any significant difference in the amount
of granzyme B-mediated
DNA fragmentation in Jurkat cells transfected
with the empty vector or
expressing SPI-2, although SPI-2 expression
inhibited Fas-mediated cell
death, as shown in Fig.
1B.
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FIG. 4.
SPI-2 expression in target cells does not inhibit
granzyme B-induced DNA fragmentation. Jurkat cells transfected with the
empty vector or expressing SPI-2 were treated with purified granzyme B
(1 µg/ml) and adenovirus (10 PFU/cell), and DNA fragmentation was
assessed by the TUNEL protocol. (a) Untreated Jneo cells; (b) Jneo
cells treated with granzyme B and adenovirus; (c) Jneo cells treated
with granzyme B alone; (d) Jneo cells treated with adenovirus alone;
(e) untreated JSPI-2 (clone 4) cells; (f) JSPI-2 (clone 4) cells
treated with granzyme B and adenovirus; (g) untreated JSPI-2 (clone 5)
cells; (h) JSPI-2 (clone 5) cells treated with granzyme B and
adenovirus. Representative data from three experiments are shown.
|
|
We also assessed the effect of SPI-2 expression on the ability of whole
CTL to induce DNA fragmentation and membrane damage
as measured by
[
3H]thymidine and
51Cr release. As shown in
Fig.
5A, the expression of SPI-2 provided
no protection against whole CTL-mediated membrane damage over
a range
of effector-to-target ratios. The addition of 10 mM EGTA
inhibited
chromium release, demonstrating that in these experiments
Jurkat cells
were killed by the calcium-dependent granule-exocytosis
pathway and not
by the calcium-independent Fas pathway (Fig.
5A).
In addition, no
significant difference was observed between the
empty-vector-transfected cells and SPI-2 expressing Jurkat cells
when
[
3H]thymidine release was measured over the same range of
effector-to-target
ratios (Fig.
5B). This further suggested that
caspases inhibited
by SPI-2, including caspase 8, are not a necessary
component of
granzyme-mediated DNA fragmentation.
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FIG. 5.
SPI-2 expression does not provide protection against
whole CTL-mediated DNA fragmentation or membrane damage. Labeled target
cells were incubated with whole CTL at a range of effector-to-target
ratios. (A) 51Cr release was measured after 4 h. (B)
[3H]thymidine release was measured after 2 h. The
means and standard deviations from triplicate samples are shown.
|
|
Much experimental evidence now indicates that mitochondrial disruption
is an important event during apoptosis (reviewed in
reference
36). These mitochondrial changes include the
production
of reactive oxygen species (ROS), loss of the inner membrane
transmembrane
potential (
m), and the release of
apoptosis-inducing proteins,
such as the recently identified
apoptosis-inducing factor (
71,
73), cytochrome
c
(
38,
39), and caspases (
43,
70). During
Fas-mediated cell death, activation of caspase 8 is essential
for the
initiation of these mitochondrial changes and subsequent
activation of
caspase 3 (
72,
79). Although loss of
m, production
of
ROS, and release of cytochrome
c have also recently been
shown
to occur during granzyme-mediated cell death, the precise
mechanisms
by which this occurs are not yet well understood (
24,
45).
We therefore assessed the ability of SPI-2 to affect
mitochondrial
disruption during both Fas- and granzyme-mediated
apoptosis. Loss
of
m and production of ROS can be monitored
simultaneously by
flow cytometry. The lipophilic dye
DiOC
6(3) targets to the negatively
charged environment of
the mitochondria, and when the
m dissipates
during apoptosis,
DiOC
6(3) leaks out of the mitochondria, leading
to
decreased fluorescence. The induction of ROS is measured by
treating
cells with hydroethidine, which is oxidized to ethidium
in the presence
of ROS. Using this assay, Jurkat cells transfected
with the empty
vector or transfected with SPI-2 in the absence
of proapoptotic stimuli
demonstrated normal mitochondria that
retained the DiOC
6(3)
dye with no production of ROS (Fig.
6a,
e, and
i). As a control, cells were also treated
with a membrane
uncoupler, the protonophore mClCCP (
27).
Treatment of cells
with mClCCP resulted in a loss of
DiOC
6(3) and an increase in
ethidium fluorescence as
demonstrated by the dramatic redistribution
of cells from the lower
right quadrant to the upper left quadrant
(Fig.
6b, f, and j). Cells
transfected with the empty vector and
treated with anti-Fas antibody
for 8 h also showed a loss of cells
from the lower right quadrant
compared to untreated cells (Fig.
6a and c). The loss of
DiOC
6(3) and production of ROS following
anti-Fas treatment
were significantly inhibited by expression
of SPI-2 (Fig.
6g and k). As
previously documented, treatment
of cells with granzyme B and
adenovirus for 2 h also resulted
in a redistribution of cells from
the lower right quadrant, representing
a loss of
m and production
of ROS (Fig.
6d) (
24). In contrast
to Fas-induced
mitochondrial disruption, however, loss of
m
and production of
ROS mediated by granzyme B and adenovirus treatment
were not inhibited
by the expression of SPI-2.
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FIG. 6.
SPI-2 expression inhibits m and ROS production
during Fas-mediated cell death but not during granzyme-mediated cell
death. Jurkat cells were treated either with anti-Fas or with granzyme
B and adenovirus (GB/AD). Mitochondrial transmembrane potential was
determined using 40 nM DiOC6(3), and the production of ROS
was assessed with 2 µM hydroethidine (HE). (a) Untreated Jneo cells;
(b) Jneo cells treated with the membrane uncoupler mClCCP; (c) Jneo
cells exposed to anti-Fas for 8 h; (d) Jneo cells treated with
purified granzyme B and adenovirus for 2 h; (e) untreated JSPI-2
(clone 4) cells; (f) JSPI-2 (clone 4) cells treated with the membrane
uncoupler mClCCP; (g) JSPI-2 (clone 4) cells exposed to anti-Fas for
8 h; (h) JSPI-2 (clone 4) cells treated with purified granzyme B
and adenovirus for 2 h; (i) untreated JSPI-2 (clone 5) cells; (j)
JSPI-2 (clone 5) cells treated with the membrane uncoupler mClCCP; (k)
JSPI-2 (clone 5) cells exposed to anti-Fas for 8 h; (l) JSPI-2
(clone 5) cells treated with purified granzyme B and adenovirus for
2 h. Representative data from three experiments are shown.
|
|
Caspase 3 activation occurs in SPI-2-expressing cells and is an
essential component in caspase-dependent, granzyme-mediated DNA
fragmentation.
Although caspase 8 is directly processed by
granzyme B in intact cells (48), we and others have
previously shown that caspase 3 is also directly activated by granzyme
B (1, 48, 81), implicating caspase 3 as an important caspase
during granzyme-induced apoptosis. To confirm that caspase 3 was
normally processed in the SPI-2-expressing cells during granule-induced
cell death, we treated Jurkat cells with hCTL at an effector-to-target
ratio of 2:1 and monitored caspase 3 activation by Western blotting analysis. SPI-2-expressing Jurkat cells and hCTL alone showed no
caspase 3 processing, and only full-length 32-kDa caspase could be
detected (Fig. 7, lanes 1 and 2).
Following the addition of hCTL to the SPI-2-expressing cells, caspase 3 processing to a 20-kDa form and a 19 kDa form could clearly be detected
over a period of 120 min (Fig. 7, lanes 3 to 7), which was similar in control Jurkat cells (Fig. 7, lane 9).
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FIG. 7.
Caspase 3 is normally activated in SPI-2 expressing
cells. Cells were treated with whole CTL at an effector-to-target ratio
of 2:1, and caspase 3 processing in both SPI-2-expressing cells (lanes
1 and 3 to 7) and Jneo cells (lanes 8 and 9) was monitored by Western
blotting.
|
|
To further examine the requirement for caspase 3 activation during
granzyme-induced cell death, we took advantage of the breast
carcinoma
cell line MCF-7. MCF-7 cells express no caspase 3 due
to a deletion
within exon three that is critical for correct processing
of the mRNA
(
30). When whole CTL at a range of effector-to-target
ratios
were added to MCF-7 cells, no DNA fragmentation could be
detected (Fig.
8A). In contrast, when Jurkat cells that
express
caspase 3 were used as targets, increasing amounts of
[
3H]thymidine release were detected, indicative of cells
undergoing
DNA fragmentation. In support of these observations, we were
also
unable to detect any DNA fragmentation in MCF-7 cells following
treatment with granzyme B and adenovirus (data not shown). These
results indicated that caspase 3 was crucial for granule-induced
DNA
fragmentation when whole CTL are used as effectors. Caspase
3, however,
was found to be completely dispensable for CTL-induced
membrane damage,
since caspase 3-deficient MCF-7 cells treated
with whole CTL
demonstrated
51Cr release (Fig.
8B). We and others have
found that peptide-based
caspase inhibitors are insufficient to inhibit
CTL-mediated membrane
damage as measured by
51Cr release
(references
24,
45, and
60 and
unpublished data).
These results reiterate that CTL can destroy cells
via a caspase
3-independent pathway (
24,
45,
60).
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FIG. 8.
Caspase 3 activation is a necessary component for
granule-mediated DNA fragmentation. MCF-7 cells lacking caspase 3 are
unable to undergo DNA fragmentation after treatment with whole CTL but
still undergo CTL-mediated membrane damage. (A) MCF-7 cells and Jurkat
cells were labeled with [3H]thymidine. Labeled cells were
incubated with a range of effectors-to-target ratios in the presence of
2 µg of concanavalin A per ml, and [3H]thymidine
release was measured after 2 h. Data from triplicate samples are
shown. (B) MCF-7 cells were labeled with 51Cr and incubated
with whole CTL at a range of effector-to-target ratios in the presence
and absence of 5 mM EGTA. 51Cr release was measured after
4 h. The means and standard deviations from triplicate samples are
shown. (C) MCF-7 cells were treated with hCTL at an effector-to-target
ratio of 2.5:1. Mitochondrial transmembrane potential was determined
using 40 nM DiOC6(3). Representative data from three
independent experiments are shown.
|
|
To further understand the contribution of caspase 3 during CTL-mediated
killing, we measured the loss of mitochondrial membrane
potential,
using DiOC
6(3), and phosphatidylserine exposure by
quantitating the amount of annexin V binding. MCF-7 cells were
incubated with hCTL at an effector-to-target ratio of 2.5:1, and
DiOC
6(3) loss from the mitochondria was monitored by flow
cytometry.
MCF-7 cells loaded with DiOC
6(3) for the
duration of the experiment
demonstrated no loss of fluorescence (data
not shown). Following
the addition of hCTL at 0, 1, and 4 h, MCF-7
cells showed a loss
of DiOC
6(3), which is indicative of
cells undergoing loss of mitochondrial
potential (Fig.
8C). This result
indicates that caspase 3 is not
essential for mitochondrial collapse
(Fig.
8C,
1 and
4 h) and
further indicates that granzyme
B-mediated mitochondrial collapse
is a caspase-independent event. In
contrast, we were unable to
detect any phosphatidylserine exposure in
MCF-7 cells treated
with hCTL in the same experiments (data not shown),
indicating
that the presence of caspase 3 is an important prerequisite
for
this phenomenon in MCF-7
cells.
Granzyme B is responsible for the cleavage and activation of
Bid.
Recently the proapoptotic molecule Bid has been identified as
a major player in Fas-mediated apoptosis. Since the direct cleavage of
Bid by granzyme B may be responsible for the caspase-independent mitochondrial collapse seen during granule-mediated killing, we examined the ability of granzyme B to activate Bid (21, 28, 40,
82). The involvement of Bid in the granzyme B pathway was
examined both in vitro and in vivo. First, to verify that Bid was a
substrate for granzyme B, Bid was translated in vitro in the presence
of [35S]methionine. The translated product was treated
with increasing amounts of purified granzyme B, and proteolytic
cleavage was analyzed by SDS-PAGE and autoradiography. Figure
9A demonstrates that translated Bid was
clearly cleaved by granzyme B in vitro. Granzyme B cleaves Bid
following aspartate 75, resulting in N-terminal and C-terminal fragments of similar size that are indistinguishable by SDS-PAGE (28).
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FIG. 9.
Granzyme B is responsible for cleaving Bid. (A) Granzyme
B cleaves Bid in vitro. Bid was translated in the presence of
[35S]methionine, and purified granzyme B was added in
increasing amounts (0, 0.001, 0.0025, 0.01, 0.025, 0.1, 0.25, and 1.0 µg). (B) Bid is cleaved in intact cells by granzyme B. Jurkat cells
were untreated (lane 1), treated with granzyme B (GB) (lane 2), treated
with adenovirus (AD) (lane 3), or treated with adenovirus and granzyme
B simultaneously for 15, 30, 60, 120, and 240 min (lanes 4 to 8, respectively). Jurkat cells were pretreated with 100 µM zVAD-fmk
prior to the simultaneous treatment with granzyme B and adenovirus for
15, 30, 60, 120, and 240 min (lanes 9 to 13, respectively). (C) Fas
activation results in Bid cleavage. Jurkat cells were untreated (lane
1), treated with anti-Fas antibody for 4, 8, and 20 h (lanes 2 to
4, respectively), or pretreated with 100 µM zVAD-fmk prior to the
addition of anti-Fas antibody (lanes 5 to 8).
|
|
Having determined that purified granzyme B could in fact
proteolytically cleave Bid, we asked if Bid was cleaved in intact
cells
during granzyme B-mediated killing. To perform these experiments,
we
assessed the cleavage of Bid using Western blotting analysis.
Jurkat
cells were treated with granzyme B and adenovirus in the
absence and
presence of zVAD-fmk over a period of 4 h. Using this
approach,
full-length Bid was found to be unprocessed in untreated
cells or cells
treated with granzyme B alone or adenovirus alone
(Fig.
9B, lanes 1 to
3). Following the simultaneous addition of
granzyme B and adenovirus,
processing of Bid into three fragments
(p15, p14, and p13) could
clearly be detected after 60 min (Fig.
9B, lanes 6 to 8). The
activation of Bid by caspase 8 results
in the cleavage of Bid at
residue 59, causing the appearance of
p15 and p13 fragments
(
28), whereas granzyme B is predicted
to cleave Bid at
residue 75, resulting in two fragments of equal
size corresponding to
p14 (
28). In the presence of zVAD-fmk,
only one cleavage
product of approximately 14 kDa (p14) could
be detected, indicating
that granzyme B was responsible for cleaving
Bid in the absence of
caspase activity (Fig.
9B, lanes 11 to 13).
In contrast, Fas-mediated
cleavage of Bid, which results in the
generation of a p15 fragment and
a p13 fragment, was completely
inhibited in the presence of the
pan-specific caspase inhibitor
zVAD-fmk (Fig.
9C). These data
demonstrate for the first time
that granzyme B is responsible for the
direct activation of Bid
during cell
death.
| |
DISCUSSION |
It is now generally accepted that an important component of CTL
killing is via induction of the internal cell suicide pathway resulting
in apoptosis. Activation of members of the caspase family is a critical
component of apoptosis, and many members of the caspase family can be
proteolytically processed by purified granzyme B in vitro (reviewed in
reference 10). These observations have led to the
suggestion that granzyme B initiates apoptosis by directly activating
caspases in intact cells. In order to gain insight into the
contributions of specific caspases during granule-mediated apoptosis in
intact cells, we have used target cells stably transfected with a
poxvirus macromolecular caspase inhibitor, SPI-2, and MCF-7 cells,
which are naturally devoid of caspase 3.
Viruses express proteins that specifically interfere with caspase
activity (49), thus presenting an opportunity to utilize these virus-encoded caspase inhibitors for the dissection of apoptotic cascades. The cowpox virus-encoded caspase inhibitor CrmA, also referred to as SPI-2 in other poxviruses, has been widely utilized for
this purpose. The crmA gene product is related to members of
the serine protease inhibitor family and inhibits apoptosis induced by
various apoptotic stimuli by directly inhibiting caspases (56; reviewed in references 11
and 46). CrmA is a potent inhibitor of both caspases
1 and 8 (34, 83) and also displays activity against other
group 1 caspases as well as caspases 9 and 10 (17).
Rabbitpox virus SPI-2 is a CrmA-related serine proteinase inhibitor
that displays 93% amino acid identity with cowpox virus-encoded CrmA
and inhibits caspase 1 with an efficiency equal to that of CrmA
(42). As expected, previous studies have shown that like
CrmA, rabbitpox virus SPI-2 is an excellent inhibitor of Fas-mediated
apoptosis during virus infection (41). Our studies have
extended this observation by further demonstrating that the heterologous expression of SPI-2 in Jurkat cells results in significant protection against anti-Fas-mediated apoptosis. Caspase 8 is the first
caspase activated during Fas-mediated cell death and is processed by
granzyme B in intact cells (3, 47, 48, 50). Using an
antibody that was raised against the large subunit of caspase 8, we
provide further evidence that caspase 8 is processed during
granule-mediated cell death (Fig. 2A). Although caspase 8 is directly
activated by granzyme B (48), our data indicate that the
activation of caspase 8 is not a critical component of CTL killing.
This conclusion is based upon the fact that expression of the serine
protease inhibitor SPI-2 has no detrimental effect on granule-mediated
cell death. Our data are supported by previous experimental results
with other cell lines showing that the presence of SPI-2 or CrmA in
rabbitpox- and cowpox virus-infected cells or the heterologous
expression of CrmA does not significantly inhibit granule-induced
51Cr release (41, 76). We have expanded upon
these observations by also examining DNA fragmentation,
phosphatidylserine externalization, and mitochondrial disruption in
addition to 51Cr release mediated by whole CTL as well as
by purified granzyme B and adenovirus. SPI-2 expression in cells does
not prevent cell death measured by any of these criteria. In an
additional study, expression of FLIP in target cells, which interacts
with both caspase 8 and FADD, also did not interfere with cell death
induced by granzyme B and perforin, granzyme B and adenovirus, or whole CTL (32). These results further indicate that caspase 8 activity is not an essential component of granule-mediated cytotoxicity and in combination with results presented here suggest that CTL can
bypass the need for caspase 8 activity by activating other caspases
within the cell. For example, although caspase 8 is normally activated,
under conditions where caspase 8 is inhibited, like during virus
infection, alternate caspase pathways may compensate.
In addition to inhibiting group 1 caspases and caspase 8, CrmA is also
a good inhibitor of caspases 9 and 10 (17). Since caspases
8, 9, and 10 function primarily during the initiation stage of
apoptosis, extrapolation of our data indicates that granzyme-mediated cell death can in fact bypass the need for activation of initiator caspases. Studies have shown that although CrmA is an effective inhibitor of initiator caspases, it displays little activity against caspases 2, 3, 6, and 7, suggesting that activation of these caspases may be critical during granule-mediated apoptosis (17). In
fact studies from our laboratory have demonstrated that granzyme B can
directly activate caspase 3 in intact cells (1), further suggesting that granzyme B can bypass the need for activation of
initiator caspases in whole cells. Experiments reported here demonstrate no interference with caspase 3 activation in cells expressing SPI-2 after treatment with whole CTL (Fig. 7), and we
routinely detect activation of caspase 3, by Western blotting, prior to
caspase 8 activation (Fig. 2C). When MCF-7 cells, which are devoid of
caspase 3, were treated with whole CTL, no DNA fragmentation could be
detected, indicating that caspase 3 was essential for granule-mediated
DNA fragmentation (Fig. 9A). Since MCF-7 cells express caspases 2, 5, 7, 8, 9, and 10 (29), the data indicate that none of these
caspases can replace the need for granzyme-induced caspase 3-mediated
DNA fragmentation in these cells. Recently, caspase 3 activation has
been linked to the generation of a caspase-activated deoxyribonuclease
activity necessary for DNA fragmentation (59), which is
dependent upon caspase 3 expression in MCF-7 cells (75). In
addition, in vitro experiments have demonstrated that caspase 3 activity is required for the activation of caspases 2, 6, 8, and 10 (65). The proteolytic activation of caspase 3 in intact cells may therefore represent a critical component of granzyme B-mediated apoptotic cell death.
Although caspase 3-deficient MCF-7 cells were resilient to CTL-mediated
DNA fragmentation, our data demonstrate that these cells are not
resistant to CTL-mediated killing. When MCF-7 cells were incubated with
whole CTL, membrane damage was clearly apparent as monitored by
51Cr release (Fig. 8B). Additionally, MCF-7 cells treated
with whole CTL also demonstrated loss of mitochondrial inner membrane
potential (Fig. 8C). Experiments reported here demonstrate that
mitochondrial collapse can occur in the absence of caspase 3 (Fig. 8C)
or in the absence of caspase 8 activity due to the expression of SPI-2 (Fig. 6). Additionally, we have recently demonstrated that
mitochondrial collapse and cytochrome c release occur
independent of caspase activation during granule-mediated cell death
(24). The recent finding that activation of the proapoptotic
molecule Bid results in mitochondrial damage and cytochrome
c release during Fas-mediated cell death led us to examine
the involvement of Bid in the granzyme B pathway (21, 28, 40,
82). We demonstrate that Bid is indeed a substrate for granzyme B
in vitro (Fig. 9A) and, more significantly, that Bid is cleaved in
intact cells (Fig. 9B). Under conditions where caspase activation is
inhibited, Bid is proteolytically cleaved into two fragments of
approximately 14 kDa, indicating that during CTL-mediated granule
killing, granzyme B directly activates Bid (Fig. 9B). In contrast, in
Fas-mediated apoptosis, Bid is cleaved into 15- and 13-kDa fragments,
and this cleavage is inhibited in the presence of zVAD-fmk (Fig. 9C).
During Fas-mediated death, the cleavage of Bid by caspase 8 results in translocation of Bid to the mitochondria, which is essential for mitochondrial disruption and cytochrome c release (21,
28, 40). We predict that in a similar fashion, granzyme
B-activated Bid also translocates to the mitochondria, resulting in the
caspase-independent release of cytochrome c during
CTL-mediated death. Thus, we demonstrate for the first time that Bid is
directly activated by granzyme B in intact cells, leading to
caspase-independent mitochondrial collapse. Our results support the
view that CTL can destroy target cells via both caspase-dependent and
caspase-independent mechanisms (24, 45, 60). In addition,
the ability of granzyme B to activate a variety of members of the
caspase family in addition to Bid adds another dimension to this
inherent flexibility.
In conclusion, we have demonstrated biochemically the absolute
requirement for caspase 8 activity during Fas-mediated apoptosis. This
is in stark contrast to the results observed with the granzyme pathway.
Under conditions where caspase 8 is inhibited by expression of SPI-2,
all of the hallmarks of apoptosis occurred unabated. Most importantly,
we demonstrate that granzyme B can directly cleave the proapoptotic
molecule Bid, resulting in caspase-independent mitochondrial collapse
and cell death. Clearly, CTL have evolved to counter virus-encoded and
tumor cell immune evasion strategies. In this case, cells expressing a
poxvirus protein that can block the initiator caspase 8 and tumor cells
devoid of caspase 3 can still be effectively destroyed by CTL. These
findings have important implications for the design of immunomodulatory
molecules that seek to block these effectors of cell-mediated immunity.
| |
ACKNOWLEDGMENTS |
This work was supported by the National Cancer Institute of
Canada, the Medical Research Council of Canada, and the Howard Hughes
Foundation (grants to R.C.B.). M.B. is the recipient of an Alberta
Heritage Foundation for Medical Research postdoctoral fellowship, and
J.A.H. is the recipient of a Medical Research Council of Canada
studentship. M.J.P. is the recipient of a Medical Research Council of
Canada postdoctoral fellowship. R.C.B. is a Medical Scientist of the
Alberta Heritage Foundation for Medical Research, a Howard Hughes
International Research Scholar, and a Distinguished Scientist of the
Medical Research Council of Canada.
We thank D. W. Nicholson for providing anti-caspase 3 and -caspase
8 antisera, X. Wang for providing anti-Bid antisera, J. Gauldie for
providing the replication-deficient adenovirus, G. McFadden for helpful
discussions, H. Everett for critically reading the manuscript, and T. Sawchuk and I. Shostak for technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 4-63 Medical
Sciences Building, Department of Biochemistry, University of Alberta, Edmonton, Alberta T6G 2H7, Canada. Phone: (780) 492-3968. Fax: (780)
492-0886. E-mail: Chris.Bleackley{at}ualberta.ca.
| |
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Molecular and Cellular Biology, June 2000, p. 3781-3794, Vol. 20, No. 11
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Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
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