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Molecular and Cellular Biology, September 2000, p. 6731-6740, Vol. 20, No. 18
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Caspase-Resistant BAP31 Inhibits Fas-Mediated
Apoptotic Membrane Fragmentation and Release of Cytochrome c
from Mitochondria
Mai
Nguyen,
David G.
Breckenridge,
Axel
Ducret, and
Gordon C.
Shore*
Department of Biochemistry, McGill
University, Montreal, Quebec, Canada H3G 1Y6, and Merck-Frosst
Center for Therapeutic Research, Kirkland, Quebec, Canada H9H 3L1
Received 3 May 2000/Returned for modification 5 June 2000/Accepted 12 June 2000
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ABSTRACT |
BAP31 is a 28-kDa integral membrane protein of the endoplasmic
reticulum whose cytosolic domain contains two identical caspase recognition sites (AAVD.G) that are preferentially cleaved by initiator
caspases, including caspase 8. Cleavage of BAP31 during apoptosis
generates a p20 fragment that remains integrated in the membrane and,
when expressed ectopically, is a potent inducer of cell death. To
examine the consequences of maintaining the structural integrity of
BAP31 during apoptosis, the caspase recognition aspartate residues were
mutated to alanine residues, and Fas-mediated activation of caspase 8 and cell death were examined in human KB epithelial cells stably
expressing the caspase-resistant mutant crBAP31. crBAP31 only modestly
slowed the time course for activation of caspases, as assayed by the
processing of procaspases 8 and 3 and the measurement of total DEVDase
activity. As a result, cleavage of the caspase targets
poly(ADP-ribosyl) polymerase and endogenous BAP31, as well as the
redistribution of phosphatidylserine and fragmentation of DNA, was
observed. In contrast, cytoplasmic membrane blebbing and fragmentation
and apoptotic redistribution of actin were strongly inhibited, cell
morphology was retained near normal, and the irreversible loss of cell
growth potential following removal of the Fas stimulus was delayed. Of
note, crBAP31-expressing cells also resisted Fas-mediated release of
cytochrome c from mitochondria, and the mitochondrial
electrochemical potential was only partly reduced. These results argue
that BAP31 cleavage is important for manifesting cytoplasmic apoptotic
events associated with membrane fragmentation and reveal an unexpected
cross talk between mitochondria and the endoplasmic reticulum during
Fas-mediated apoptosis in vivo.
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INTRODUCTION |
Programmed cell death is
characterized by a series of morphological and structural changes
culminating in the coordinated packaging of cellular contents into
apoptotic bodies, which are ultimately eliminated via phagocytosis by
neighboring cells. Early events in this process typically include cell
rounding, loss of phospholipid asymmetry in the cell membrane,
extensive cytoplasmic membrane blebbing and fragmentation, nuclear
pyknosis, and internucleosomal DNA cleavage (26). Although
much remains to be learned about the mechanisms underlying these
events, programmed cell death is achieved in most cell death pathways
as a consequence of the proteolytic cleavage of a diverse array of
structural and regulatory proteins by the executors of apoptosis, the
caspase family of cysteine proteases (33, 46, 48). Several
of the caspase targets are known to have critical roles in at least
some of the apoptotic processes. These targets include the DFF40/CAD
inhibitor, DFF45/ICAD, which plays a role in the fragmentation of DNA
(23, 36), and the actin-associated capping protein gelsolin,
which plays a role in cytoplasmic membrane blebbing (17). In
addition, the activation of several kinases by caspase cleavage,
including PAK2 (20, 34) and the Ste20-related kinases MST1
(14, 19) and SLK (35), contributes to the loss of
focal adhesions and the retraction and disassembly of actin stress
fibers, events that are associated with elaborate changes to the
actomyosin network and membrane remodeling (26).
In contrast to many death-stimulating pathways, the proximal molecular
events following activation of Fas (also called CD95) with either Fas
ligand or agonistic anti-Fas antibody are well understood. Receptor
stimulation results in the assembly of a death-inducing signaling
complex that includes the adapter protein FADD and procaspase 8 (4, 5, 7, 28, 40). The resulting activation of this
initiator caspase (25) ultimately leads to the processing of
effector procaspases, including caspase 3, and apoptosis. A cytosolic
target of caspase 8, proapoptotic BID, is cleaved, and the truncated
product (tBID) translocates to mitochondria, where it stimulates the
release of intermembrane proteins, including cytochrome c
(15, 21, 24). BID appears to be a critical effector of this
pathway, at least in certain contexts, because death receptor-induced
redistribution of cytochrome c was not observed in
Bid
/ mouse thymocytes and hepatocytes
(47). Released cytochrome c in turn contributes
to the activation of initiator caspase 9 (22), which in many
death pathways is important for subsequent processing of downstream
effector procaspases (22, 39). In contrast, Fas stimulation
of certain cell types activates high levels of caspase 8 that are
sufficient to process effector procaspases directly, whereas other cell
types, at least in culture, activate low levels of procaspase 8 and
likely depend on mitochondrial events for amplification of the caspase
cascade (37, 38).
Here we show that human epithelial cells expressing a caspase-resistant
mutant of BAP31 (crBAP31), a preferred substrate for initiator caspases
8 and 1 (30), are resistant to a number of cytoplasmic
changes that typically occur during Fas-mediated apoptosis. BAP31 is a
28-kDa integral membrane protein that is ubiquitously expressed
(1, 27; unpublished data) and highly enriched in the
endoplasmic reticulum (ER) (3, 30), where it forms a homo-oligomer (31). The protein contains three predicted
transmembrane segments within its amino terminus that confer a topology
in the ER membrane in which the short hydrophilic amino terminus and an
approximately 37-amino-acid loop connecting TM2 and TM3 face the ER
lumen and a 14-kDa domain, terminating in a canonical KKXX ER retention
signal, faces the cytosol (30). The cytosolic tail is
predicted to contain a weak death effector and overlapping coiled-coil
(DECC) domain flanked on either side by identical caspase recognition
sites. These sites are cleaved in response to diverse death stimuli in
vivo (13, 31) and are preferably cleaved by caspases 8 and 1 and only weakly cleaved by effector caspase 3 in vitro (30).
The resulting membrane-integrated BAP31 fragment, called p20, is a
potent inducer of apoptosis when expressed ectopically, suggesting that
BAP31 cleavage may contribute in some manner to the death process.
Moreover, the influence of BAP31 may also extend to a role in
regulating caspases, which would be consistent with the observation
that BAP31 can associate with procaspase 8, BCL-2, and CED-4 in
cotransfected cells (30, 31). To investigate the
contribution of BAP31 cleavage to apoptosis, therefore, we have created
a cell line that expresses a caspase-resistant mutant form of the
protein and have examined its influence on the cell death pathway
initiated by independent stimulation of caspase 8 activity by the Fas
signaling complex.
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MATERIALS AND METHODS |
Plasmids and transfectants.
cDNA encoding human BAP31 with
the Flag peptide epitope sequence inserted between the codons for amino
acids 242 and 243 was incorporated into the pcDNA3.1 expression vector,
as previously documented (30). Site-directed mutagenesis was
performed to convert the codons for aspartate residues at positions 164 and 238 to codons for alanine residues, and the authenticity of the crBAP31-Flag mutant expression vector was confirmed by DNA sequence analysis. pcDNA3.1 vectors expressing CrmA (gift from V. Dixit), BAP31-Flag, and crBAP31-Flag were stably expressed in human KB epithelial cells, as previously described (30).
Antibodies and immunoblots.
The following antibodies were
employed: mouse anti-Flag (Sigma), chicken anti-human BAP31
(30), rabbit antibodies against the catalytic subunits of
human caspase 8 (gift from D. Nicholson) and caspase 3 (gift from
R. Sékaly), mouse anti-poly (ADP-ribosyl) polymerase (anti-PARP)
(Biomol), mouse monoclonal antibodies against cytochrome c
(2G8.B6 and 7H8.2C12) (gift from R. Jemmerson), and rabbit
anti-
-actin (gift from P. Braun). Cell extracts containing equivalent amounts of protein were resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), and the proteins
were transferred to nitrocellulose, incubated with a primary antibody,
and visualized with a secondary antibody coupled to enhanced chemiluminescence.
Immunofluorescence.
Cells were fixed in 4% paraformaldehyde
and incubated either with mouse monoclonal antibody 2G8.B6
(anti-cytochrome c) followed by goat anti-mouse
immunoglobulin G (IgG) conjugated to Texas red or with anti--actin
followed by goat anti-rabbit IgG coupled to Alexa 488 (Molecular
Probes). Cells were visualized by fluorescence confocal microscopy.
Electron microscopy.
Cells were treated with anti-Fas
antibody for various times. After two washes in phosphate-buffered
saline (PBS), cell pellets were fixed in 2.5% glutaraldehyde-0.1 M
sodium cacodylate for 2 h, washed, treated for 1 h with 0.1%
osmium tetroxide, and finally dehydrated in acetone. The pellets were
infiltrated with Epon-acetone and embedded in Epon. Thin sections
(approximately 100 nm thick) stained with 4% uranyl acetate-lead
citrate and thick sections (approximately 0.5 µm thick) stained with
toluidine blue were examined by electron and conventional light
microscopy, respectively.
Apoptosis assays.
Human KB epithelial cells were
maintained in 
-minimal essential medium supplemented with 10% fetal
bovine serum and treated at approximately 80% confluency with mouse
activating anti-Fas antibody (Upstate Biotechnology) and 10 µg of
cycloheximide (CHX) per ml. At the times indicated below, cells were
collected and analyzed. Cell viability and the structural integrity of
the plasma membrane were measured by the ability of cells to exclude
trypan blue, as determined microscopically. For assessing
phosphatidylserine redistribution and mitochondrial transmembrane
potential, cells were incubated for 15 min at 37°C in PBS containing
2% fetal bovine serum and a 40 µM concentration of the
mitochondrial-potential-sensitive dye DiOC6 (Molecular
Probes) or 0.1 µM fluorescein-conjugated human annexin V (R & D).
Following two washes in the same medium, fluorescence was measured by
flow cytometry. Caspase activity in whole-cell extracts was obtained by
treating the cells with a solution containing 50 mM HEPES (pH 7.4), 1%
Triton X-100, 5 mM EDTA, and 2 mM dithiothreitol and incubating them
with 50 µM acetyl-Asp-Glu-Val-Asp-7-amino-4-methylcoumarin
(AcDEVD-amc) for 30 min at 37°C. Fluorescence in the linear range of
DEVDase activity was measured with a plate reader (Tecan).
Cytochrome c.
Cells (4 × 106) were
washed in PBS and suspended in 0.1 ml of 200 mM mannitol-70 mM
sucrose-1 mM EDTA-10 mM HEPES (pH 7.5). After one cycle of
freeze-thaw, the cells were homogenized with 35 strokes in a motorized
Teflon-glass homogenizer operating at 2,000 rpm and then centrifuged at
800 × g for 10 min to remove nuclei and cell debris.
The supernatant was centrifuged at 100,000 × g for 10 min, and the membrane pellet was resuspended in homogenization buffer
to the same volume as that of the 100,000 × g
supernatant. Equivalent volumes of the pellets and supernatants were
subjected to SDS-PAGE and immunoblotting with mouse monoclonal antibody 7H8.2C12 (anti-cytochrome c).
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RESULTS |
crBAP31.
The schematic in Fig. 1 shows the
predicted topology of BAP31 in the ER membrane and the location of the
caspase recognition sites (AAVD.G) flanking the DECC domain in the
cytosolic tail (30). Treatment of human KB epithelial cells
with agonistic mouse antibody against Fas (0.5 µg/ml), in the
presence of 10 µg of CHX per ml to enhance sensitivity to Fas
activation (38), resulted in cleavage of the 246-amino-acid
full-length BAP31, generating two products of approximately 27 and 20 kDa (Fig. 1A). These corresponded to cleavages at aspartates 238 and
164, respectively (30). crBAP31 was produced by mutating
these residues to alanine residues, and both the construct encoding
crBAP31 and that encoding wild-type (wt) BAP31 were further manipulated
to include a Flag epitope inserted immediately upstream of the ER
retention signal, KKEE, located at the extreme carboxy terminus of the
protein. KB cell lines stably expressing wt BAP31 or crBAP31 were then examined by immunoblotting with anti-Flag antibody. crBAP31-Flag, but
not BAP31-Flag, was found to remain structurally intact in the face of
sustained stimulation with anti-Fas (Fig. 1B). In both cases, the
proteins were expressed at approximately three times the level of
endogenous BAP31, as assessed using a BAP31 polyclonal antibody (data
not shown).
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FIG. 1.
Human KB epithelial cells expressing crBAP31. (A)
Control (parental) KB cells were stimulated with 0.5 µg of anti-Fas
( Fas) antibody per ml in the presence of 10 µg of CHX per ml for
the indicated times, and whole-cell lysates were subjected to SDS-PAGE,
immunoblotted with chicken anti-BAP31 (BAP31) antibody, and
visualized by enhanced chemiluminescence (30). The positions
of full-length BAP31 and the BAP31 caspase cleavage products, p27 and
p20, are indicated. (B) KB cells stably expressing wt BAP31-Flag or
crBAP31-Flag were analyzed under the same conditions, but with mouse
anti-Flag antibody. (C) Schematic of crBAP31-Flag in the ER
(30), in which the caspase recognition aspartate residues
(asterisks) at positions 164 and 238 have been mutated to alanine
residues. The Flag epitope tag was inserted immediately upstream of the
COOH-terminal tetrapeptide ER retrieval signal, KKEE. aa, amino acid.
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crBAP31 inhibits Fas-mediated apoptotic membrane blebbing and
fragmentation.
Control (parental) KB epithelial cells and KB cells
stably expressing crBAP31-Flag or the cowpox serpin, CrmA, were
stimulated for 16 h with anti-Fas and examined by staining with
trypan blue to assess the integrity of the plasma membrane (Fig.
2A) and by immunoblotting with an antibody against the
catalytic subunit of caspase 8 to assess procaspase 8 processing (Fig.
2B). crBAP31 had little influence on Fas-mediated processing of
procaspase 8, as judged by the loss of the 54- to 55-kDa forms of
procaspase 8 (25). As expected, CrmA, an inhibitor of
caspase 8 that prevents activation of procaspase 8 in vivo (10,
28), significantly retarded procaspase 8 processing (Fig. 2B).
Despite the fact that crBAP31 had little or no influence on procaspase
8 processing in response to Fas stimulation, it was as effective as
CrmA at blocking the loss of cell membrane integrity, as visualized by staining of cells with trypan blue (Fig. 2A). This finding was investigated further and quantified by examining the appearance of the
cells with electron microscopy (Fig. 3). After
stimulation by Fas antibody, control cells exhibited extensive
membrane blebbing and the formation of apoptotic bodies; crBAP31
cells, on the other hand, remained intact (Fig. 3A). Numerical
scoring of these cells in thick sections stained with toluidine blue
revealed that more than 60% of control cells had undergone extreme
membrane remodeling by 7 h after stimulation by Fas, and this
figure increased to more than 90% by 16 h poststimulation (Fig.
3B). Membrane remodeling was inhibited by crBAP31 (Fig. 3B), to an
extent similar to that observed for CrmA-expressing cells (data not
shown). Note that no difference, in this or other assays, was observed
between control cells and cells expressing wt BAP31-Flag, indicating
that the observed effects of crBAP31-Flag, which was expressed at a
level similar to that of wt BAP31-Flag, were not due to the fact that these cells carried an approximately threefold excess of the BAP31 protein.
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FIG. 2.
crBAP31 permits Fas-mediated activation of caspase 8 but
inhibits the loss of plasma membrane integrity. (A) Control (parental)
KB cells or KB cells stably expressing crBAP31-Flag or CrmA were
stimulated with anti-Fas-CHX (Fas/CHX) or CHX alone for 16 h,
and the percentage of the cells that were stained with trypan blue was
determined. (B) Total cell lysates were subjected to SDS-PAGE and
immunoblotted with a rabbit antibody raised against the p18 catalytic
subunit of human procaspase 8. The positions of procaspase 8 a and
b (25) are indicated with the top and bottom arrows,
respectively.
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FIG. 3.
crBAP31 inhibits Fas-mediated apoptotic membrane
blebbing and fragmentation. (A) Transmission electron microscopy of
Fas-stimulated control (parental) KB epithelial cells and KB cells
stably expressing crBAP31-Flag. (B) The number of apoptotic
membrane-blebbing cells was scored in thick sections and expressed as a
percentage of total cells. The averages of three independent
determinations, with standard deviations, are presented.
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The early stages of apoptotic membrane remodeling have been associated
with actin redistribution to the cell periphery during
cell rounding
(reviewed in reference
26). A similar redistribution
of
-actin was observed 4 h after Fas stimulation of control KB
epithelial cells, whereas crBAP31 cells maintained a normal
distribution
of
-actin and remained flat and adherent even 15 h
poststimulation
(Fig.
4). Collectively, these findings
reveal that crBAP31 has
a strong inhibitory influence on both the cell
shape and cytoskeletal
changes and the remodeling of membranes into
blebs and vesicular
bodies that are characteristic of apoptosis.
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FIG. 4.
crBAP31 inhibits Fas-mediated redistribution of
-actin. Control (parental) KB epithelial cells and KB cells stably
expressing crBAP31-Flag were stimulated with anti-Fas-CHX (Fas/CHX)
for the indicated times and examined by immunofluorescence confocal
microscopy using a rabbit anti--actin antibody and goat anti-rabbit
IgG coupled to Alexa 488. Representative images are shown.
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Activation of caspases in cells expressing crBAP31.
To assess
the presence of caspase activity in extracts from control cells and
from cells expressing crBAP31 or CrmA, equivalent amounts of extract
protein were incubated with the fluorogenic peptide DEVD-amc, which is
a general substrate for effector caspases 3 and 7 (10). The
presence of crBAP31 appeared to delay the induction of DEVDase activity
in response to Fas stimulation, but after 15 h the level was
similar to that recorded for control cells (Fig. 5A). In
contrast, CrmA significantly inhibited the appearance of DEVDase
activity but did not reduce the activity to baseline, which was
established in control cell extracts using the noncleavable peptide
inhibitor DEVD-fluoromethylketone (DEVD-fmk) (Fig. 5A). This may
indicate that the expression level of CrmA in these cells was
insufficient to completely abolish all activation of caspase 8 in
response to Fas stimulation or that a small amount of DEVDase activity
arose in these cells independently of caspase 8 initiation. The
retardation of the appearance of DEVDase activity in the presence of
crBAP31 was reflected in a slower time course for Fas-stimulated
processing of procaspase 3 in crBAP31-expressing cells than in control
cells (Fig. 5C), but this was insufficient to significantly influence
the cleavage of the caspase 3 and 7 substrate PARP (Fig. 5D). Of note,
caspase cleavage of endogenous BAP31 in the crBAP31 cells was also
observed (Fig. 5B).
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FIG. 5.
Fas-mediated activation of caspases in
crBAP31-expressing cells. (A) Total cell lysates were prepared from
control (parental) KB epithelial cells or from KB cells stably
expressing crBAP31-Flag or CrmA. Equivalent, rate-limiting amounts of
protein were assayed for cleavage of DEVD-amc, during which the
resulting fluorescence was detected and quantified in the linear time
course range with an automated fluorescence plate reader detecting a
wavelength of 460 nm. Control cell lysate was also assayed in the
presence of a 1 µM concentration of the inhibitor DEVD-fmk. The
average of two independent determinations is presented. (B) As
described in the legend for Fig. 1, control (parental) and
crBAP31-Flag-expressing KB cells were subjected to SDS-PAGE and
immunoblotting with chicken anti-BAP31 (BAP31) (30) under
the conditions indicated. (C) The same experiment was performed as for
panel B, except that immunoblots were developed using rabbit
anti-caspase 3 (6). ProC-3, procaspase 3. (D) Immunoblots
were developed using a mouse monoclonal antibody against PARP
(PARP). 89K, 89-kDa caspase cleavage product (6). (E)
Cells were treated with or without anti-Fas-CHX (Fas) for 16 h
and stained in situ with annexin V, and fluorescence intensity was
determined by FACS analysis. (F) Cells received the same treatment as
for panel E, except that low-molecular-weight DNA was isolated,
resolved by agarose gel electrophoresis, and stained with ethidium
bromide (32). The intensely staining fragment migrating
toward the top of the gel has an approximate size of 25 kbp.
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Other hallmark features of apoptosis that are a consequence of caspase
activity include annexin V staining due to caspase-induced
redistribution of phosphatidylserine to the outer part of the
plasma
membrane and DNA fragmentation resulting from caspase-dependent
inactivation of DFF45/ICAD. Annexin V staining and fragmentation
of DNA
were both observed in crBAP31-expressing cells, and by
16 h after
stimulation by Fas they occurred to an extent similar
to that in
control cells (Fig.
5E and F). Therefore, the sustained
inhibition of
apoptotic cell morphology after Fas stimulation
that is conferred over
this time period by the presence of crBAP31
(Fig.
3 and
4) occurs in
the face of activated caspases, cleavage
of the caspase targets PARP
and endogenous BAP31, redistribution
of phosphatidylserine in the
plasma membrane, and fragmentation
of nuclear
DNA.
Influence of crBAP31 on Fas-induced transformations of
mitochondria.
Release of cytochrome c from the
mitochondrial intermembrane space is a common response to many death
signals and typically occurs at an early step in the apoptotic death
pathway (11). Figure 6A presents confocal
microscopic images of control and crBAP31-expressing KB
epithelial cells before and after stimulation with the activating
anti-Fas antibody for 7 h. Fas stimulation caused cytochrome
c to redistribute from a mitochondrial location to a diffuse
pattern throughout the cytoplasm. This redistribution of cytochrome
c was observed in intact, flat, adherent cells prior to the
acquisition of the condensed, membrane-fragmented apoptotic morphology
(Fig. 6A); this observation is consistent with release of cytochrome
c occurring early in the Fas-mediated death pathway. Strikingly, cells expressing crBAP31 resisted cytochrome c
redistribution in response to Fas stimulation (Fig. 6A), and this
finding was studied further by an analysis of total cell populations by
fractionation of cell homogenates and immunoblotting (Fig. 6B). In
control cells, prior to Fas stimulation, cytochrome c was
recovered in the membrane fraction containing mitochondria but not in
the high-speed supernatant fraction. Fas stimulation resulted in a
progressive increase in the recovery of cytochrome c in the
high-speed supernatant, reaching an apparent maximum after about 8 h. Again, crBAP31 cells generally retained cytochrome c in
the mitochondrial fraction, with a constant and low level recovered in
the high-speed supernatant throughout the time course of Fas
stimulation, up to 16 h (Fig. 6B).
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FIG. 6.
crBAP31 inhibits Fas-mediated release of cytochrome
c from mitochondria. (A) Control (parental) KB epithelial
cells and KB cells stably expressing crBAP31-Flag were stimulated with
anti-Fas (Fas/CHX) for the indicated times and examined by
immunofluorescence confocal microscopy with mouse monoclonal antibody
2G8.B6 (anti-cytochrome c) and anti-mouse IgG coupled to
Texas red. Cytochrome c release from mitochondria can be
observed in cells prior to membrane blebbing (arrow indicates an
obviously apoptotic cell). (B) At the indicated times of treatment,
cells were homogenized and the postnuclear supernatant was separated
into membranes (100,000 × g pellet [P]) and
supernatant (S), as indicated, and equal aliquots were subjected to
SDS-PAGE and immunoblotting with mouse monoclonal antibody 7H8.2C12
(anti-cytochrome c) (Cyt c). (C) Cells were treated with or
without anti-Fas ( Fas) for 16 h, stained with
DiOC6, and subjected to FACS analysis. The arrow indicates
the peak of fluorescence intensity obtained for cells in which the
mitochondrial electrochemical potential was collapsed following
treatment with 1 µM carbonyl cyanide
m-chlorophenylhydrazone.
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In addition to releasing cytochrome
c, the mitochondria
undergo other transformations in response to apoptotic stimuli,
including
a collapse of the transmembrane electrochemical potential at
the
inner membrane (inside negative). The status of the mitochondrial
electrochemical potential in control and crBAP31-expressing cells
with
and without Fas stimulation was monitored using the potential-sensitive
dye DiOC
6 and fluorescence-activated cell sorter (FACS)
analysis
(Fig.
6C). Whereas control cells exhibited a collapse of the
transmembrane
potential after 16 h of Fas stimulation equivalent
to that seen
after treatment with the protonophore carbonyl cyanide
m-chlorophenylhydrazone
(Fig.
6C), crBAP31-expressing cells
responded with a lower but
retained potential, indicating that
mitochondria in these cells
remained at least partly
polarized.
Recovery of cell growth potential following removal of the Fas
stimulus.
For Fig. 7, control KB cells and KB cells
expressing either crBAP31 or CrmA were treated for 7 h with
anti-Fas. The cells were collected following trypsinization and washed,
and then equivalent numbers of cells were examined for their ability to
attach to culture plates and to grow in fresh media lacking the Fas
stimulus. Neither CrmA nor crBAP31 conferred any growth difference on
these cells in the absence of external treatments (data not shown). However, whereas the treatment of control cells with anti-Fas resulted
in a low number of cells recovering and growing on cell plates by 4 days after the removal of the Fas death stimulus, more than 20 times
this number was recorded for cells expressing crBAP31 and about 50 times this number was recorded for CrmA-expressing cells. Of note,
after 7 h of stimulation by anti-Fas, most of the full-length PARP
in crBAP31-expressing cells was cleaved to the 89-kDa apoptotic
fragment (Fig. 5D). These results demonstrate, therefore, that a
significant number of crBAP31-expressing cells can at least delay the
irreversible loss of cell growth potential that is experienced by
control cells in response to Fas stimulation, despite the manifestation
of caspase activity.
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FIG. 7.
crBAP31 inhibits the loss of cell growth potential in
response to Fas stimulation. A total of 2 × 105 of
the indicated cells were seeded in 12-well dishes overnight and
stimulated with anti-Fas for 7 h. All cells were collected after
trypsinization, washed twice in PBS, and plated onto 100-mm plates.
After 4 days, cell counts were taken. Shown are the average counts from
three independent measurements (numerical values above the bars), with
standard deviations.
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BAP31 association with actomyosin.
As documented in
Discussion, the cytosolic domain of BAP31 exhibits sequence
similarities to the coiled coil of heavy-chain myosin. When extracts of
human HepG2 cells stably expressing BAP31-Flag were subjected to
precipitation with anti-Flag antibody and analysis of the precipitates
by SDS-PAGE and silver staining, two prominent bands at approximately
43 and 200 kDa were observed (Fig. 8). In addition,
endogenous BAP31 coprecipitated with BAP31-Flag, as confirmed by
immunoblotting with anti-BAP31 (data not shown) and consistent with the
existence of BAP31 as a homo-oligomer (31). None of these
bands was seen in control HepG2 cells. Analysis of the excised 43- and
200-kDa bands by exhaustive tandem mass spectrometry identified them as
-actin and nonmuscle myosin II heavy-chain B, respectively (A. Ducret, M. Nguyen, D. Breckenridge, and G. Shore, unpublished data).
Negligible 
-actin was detected in the 43-kDa band, indicating a high
degree of specificity for these interactions with BAP31.
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FIG. 8.
BAP31 associates with constituents of the actomyosin
complex. Extracts of HepG2 cells, either lacking or expressing
BAP31-Flag, were subjected to immunoprecipitation with the anti-Flag
antibody ( Flag) (31), and the precipitates were analyzed
by SDS-PAGE and silver staining. The positions of BAP31-Flag and BAP31
were determined separately by immunoblotting with anti-BAP31 (not
shown). Molecular mass markers and the light (LC) and heavy (HC) chains
of IgG are also indicated. The bands labeled non-muscle myosin II HC B
and -actin were identified by tandem mass spectrometry (see Results
and Discussion).
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DISCUSSION |
BAP31 is highly enriched in the ER, as judged by quantitative
cryoimmunocytochemistry employing protein A-gold and electron microscopy (30; unpublished data). Interestingly,
however, BAP31 has been reported to form associations with distal
constituents in the secretory pathway, including IgD (1) and
cellubrevin (3), which suggests that BAP31 plays a role in
the egress of at least certain proteins out of the ER (3).
Its potential role in apoptosis, on the other hand, was derived from
the finding that BAP31 can associate with BCL-2, which also localizes
to the ER (18) and is a target for caspases (30).
Moreover, BAP31 was found to form a complex with procaspase 8 and the
Caenorhabditis elegans caspase adapter, CED-4, in
cotransfected cells, suggesting that the BAP31 complex plays a role in
regulating caspase activity (30, 31). Here we have chosen to
investigate BAP31 as a target of caspases by independently activating
caspase 8 via the Fas signaling complex in cells that stably express
crBAP31. BAP31 is efficiently cleaved by caspase 8 and related
caspases, generating a product (p20) that remains integrated in the
membrane and, when expressed ectopically, is a potent inducer of
apoptosis (30). We have noted in diverse circumstances,
however, that p20 readily complexes with epitope-tagged full-length
BAP31 (for an example, see reference 31). For the
present study, therefore, it is not known if the effects of crBAP31 are
due to the preservation of the structural integrity of the protein
(preventing the loss of BAP31 function) or to interference with p20
proapoptotic activity by sequestering the cleaved molecule (preventing
the gain of p20 function).
Activation of caspase 8 is an important proximal event in the
Fas-activated cell death pathway (25, 44), and the ability of caspase 8 to initiate a caspase cascade, either directly or via
amplification of mitochondrion-dependent intermediate steps, provides
the mechanism for cellular execution by apoptosis (37, 38,
41). One target of caspase 8 in the Fas pathway, proapoptotic BID, is an important, and in certain contexts essential,
(47) effector of cytochrome c release from
mitochondria (15, 21, 24). Cleavage of BID by caspase 8 or
other caspases results in the removal of an inhibitory
NH2-terminal segment, rendering the BH3 domain of tBID
available for interaction with partner proteins (45). We
demonstrate here, however, that another target of caspase 8 (or other
caspases) in the Fas pathway, BAP31, may also play an important role
both in cytochrome c release from mitochondria and in the
extensive membrane remodeling associated with blebbing and formation of
apoptotic bodies during the cytoplasmic execution phase of cell death.
Interestingly, we observed no inhibition of BID cleavage in
Fas-stimulated KB cells expressing crBAP31 (data not shown). Thus,
while several studies have shown that incubation of mitochondria with
caspase 8-treated naïve cytosolic extracts or with tBID alone
can induce egress of cytochrome c from the organelles in
vitro (15, 21, 24), the present results argue that the
cellular environment or other factors related to the ER may be critical
for these events to manifest in vivo. Maintaining the structural
integrity of BAP31 in the ER even in the face of sustained caspase
activity may preclude these collateral cellular changes from occurring
in the Fas death pathway. Emerging evidence, for example, suggests that
BID may cooperate with BAX (or BAK) to stimulate cytochrome c release
from mitochondria (8) and that a conformational change in
BAX in response to a death signal is important for insertion of BAX
into the mitochondrial outer membrane (9, 12, 29). While
cytosolic factors such as BID and tBID can induce such conformational
changes in BAX in vitro (9), additional considerations may
apply in vivo. One report, for example, indicates that BAX activation
can occur in response to death signal-induced changes in cellular pH
(16). BAP31 or its cleavage product may influence this or
other ER-regulated conditions that favor a cellular environment in
which the proapoptotic activity of tBID and BAX or BAK can be realized.
The release of cytochrome c from mitochondria is an early
event in many death signaling pathways and contributes to downstream activation of a caspase cascade. In the human KB epithelial cells studied here, Fas-mediated cytochrome c release was not
essential for effector caspase activation, since crBAP31 inhibited the
former but not the latter. In this regard, these cells exhibited type I
properties (37, 38). Consequently, crBAP31-expressing cells resisted the morphological changes associated with cytoplasmic apoptosis in the face of sustained activity of caspases. The various stages of cytoplasmic apoptosis
release from extracellular matrix attachments and reorganization of focal adhesions (rounding), plasma
membrane changes associated with dynamic membrane blebbing, and finally
membrane fragmentation and formation of apoptotic bodies
(condensation)are typically associated with changes in the
organization of the cellular actomyosin complex, especially in the
later stages, which involve caspase-dependent cleavage of
actomyosin-associated structural proteins, regulators, and signaling
molecules (reviewed in reference 26). It is
noteworthy, therefore, that the cytosolic tail of BAP31, from leucine
122 to alanine 236, can be arranged in four segments of four heptads each, in which the frequency of hydrophobic residues at positions 1 and
4 is 71% (27), similar to the frequency observed in myosin heavy-chain coils (42). Moreover, the immunoprecipitation of BAP31-Flag and analysis of associated polypeptides by exhaustive tandem
mass spectrometry have identified both -actin and nonmuscle myosin
II heavy-chain B as proteins that may constitutively interact with the
BAP31 complex in vivo (A. Ducret et al., unpublished). These
associations are lost for p20 and, therefore, might contribute to the
apoptotic cell morphology.
Finally, a limited number of proteins have been identified whose
caspase-resistant mutants, like crBAP31, have relatively broad
inhibitory influences on the ability of the cell to undergo cytoplasmic
apoptosis. These include structural proteins, such as gelsolin
(17), and signaling molecules, such as PAK2 (20, 34). Additionally, however, cells expressing crBAP31 exhibited a
resistance against Fas-induced release of cytochrome c and
the collapse of the mitochondrial electrochemical potential, which presumably preserves or delays the cell from acquiring irreversible mitochondrial dysfunction (43). This may help to explain why at least a fraction of these cells were viable after 7 h of Fas stimulation, whereas control cells were not (Fig. 7). Moreover, the
identification of caspase-resistant mutants, such as crBAP31, that have
death-inhibiting influences may be relevant to recent suggestions that
caspases can play roles in physiological cell stimuli other than
apoptosis. For example, cleavage of certain caspase targets but not of
others has been noted during stimulation of T lymphocytes in the
apparent absence of apoptosis (2). Collateral regulation
that preserves the structural integrity of certain key caspase
substrates, including BAP31, DFF45/ICAD, and gelsolin, might provide
the mechanistic basis for this lack of apoptosis.
| |
ACKNOWLEDGMENTS |
We are grateful to D. Nicholson, R. Jemmersen, P. Braun, R. Sékaly, and V. Dixit for providing reagents and to J. Mui for helping with electron microscopy.
D.G.B. was the recipient of a studentship from the Medical Research
Council of Canada. This work was supported by the National Cancer
Institute and the Medical Research Council of Canada.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Biochemistry, McIntyre Medical Sciences Building, McGill University, 3655 Drummond St., Montreal, Quebec, Canada H3G 1Y6. Phone: (514) 398-7282. Fax: (514) 398-7384. E-mail:
shore{at}med.mcgill.ca.
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Abstract
Introduction
