Received 23 October 2000/Returned for modification 5 December
2000/Accepted 19 April 2001
The ability of the c-Myc oncoprotein to potentiate apoptosis has
been well documented; however, the mechanism of action remains ill
defined. We have previously identified spatially distinct apoptotic
pathways within the same cell that are differentially inhibited by
Bcl-2 targeted to either the mitochondria (Bcl-acta) or the endoplasmic
reticulum (Bcl-cb5). We show here that in Rat1 cells expressing an
exogenous c-myc allele, distinct apoptotic pathways can be
inhibited by Bcl-2 or Bcl-acta yet be distinguished by their
sensitivity to Bcl-cb5 as either susceptible (serum withdrawal, taxol,
and ceramide) or refractory (etoposide and doxorubicin). Myc expression
and apoptosis were universally associated with Bcl-acta and not
Bcl-cb5, suggesting that Myc acts downstream at a point common to these
distinct apoptotic signaling cascades. Analysis of Rat1
c-myc null cells shows these same death stimuli induce
apoptosis with characteristic features of nuclear condensation, membrane blebbing, poly (ADP-ribose) polymerase cleavage, and DNA
fragmentation; however, this Myc-independent apoptosis is not inhibited
by Bcl-2. During apoptosis, Bax translocation to the mitochondria
occurs in the presence or absence of Myc expression. Moreover, Bax mRNA
and protein expression remain unchanged in the presence or absence of
Myc. However, in the absence of Myc, Bax is not activated and
cytochrome c is not released into the cytoplasm.
Reintroduction of Myc into the c-myc null cells restores Bax activation, cytochrome c release, and inhibition of
apoptosis by Bcl-2. These results demonstrate a role for Myc in the
regulation of Bax activation during apoptosis. Moreover, apoptosis that
can be triggered in the absence of Myc provides evidence that signaling pathways exist which circumvent Bax activation and cytochrome c release to trigger caspase activation. Thus, Myc
increases the cellular competence to die by enhancing disparate
apoptotic signals at a common mitochondrial amplification step
involving Bax activation and cytochrome c release.
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INTRODUCTION |
Among the known proto-oncogenes, the
cellular myc gene (c-myc) is one of those most
frequently implicated in carcinogenesis. Deregulated expression of the
structurally unaltered Myc protein is sufficient to drive continuous
cell proliferation and programmed cell death in response to
growth-promoting and growth-inhibitory signals, respectively. As a
regulator of gene transcription, Myc is thought to drive such disparate
activities by controlling distinct subsets of target genes. The ability
of Myc to trigger apoptosis is key to the control of tumor development.
Apoptosis is thought to function as an intrinsic safety mechanism to
limit the life of a cell that acquires deregulated c-myc
expression, thus preventing further transformation. However, loss of
this function through any additional mutation that prevents Myc from
triggering apoptosis will promote survival and strongly cooperate with
Myc to allow the continued proliferation, mutation, and carcinogenic
evolution of the affected clone (4, 5, 12, 18, 19, 25, 27, 37,
47, 49).
The apoptotic process can be divided into three interdependent phases:
induction, decision, and execution. For simplicity, inducers have been
categorized as those that trigger apoptosis through death receptor
activation (e.g., CD95 and tumor necrosis factor receptor) and those
that stimulate apoptosis by a non-death receptor mechanisms (e.g.,
chemotherapeutic drugs, metabolic inhibitors, and withdrawal of
survival factors). The decision phase is largely regulated by the Bcl-2
family of apoptotic regulators, including both pro- and antiapoptotic
members. These molecules integrate a wide variety of signaling cascades
and, through protein-protein interaction and subcellular localization,
determine whether the balance of signals dictates that cell death will
proceed or terminate. A hallmark of the execution phase is the
activation of caspases and their substrates that essentially dissolve
the normal structure and function of a cell while compartmentalizing
the remains for noninflammatory clearance and engulfment. Another
feature that is sufficient, but not essential, for cell death is the
collapse of mitochondrial membrane integrity. The release of
mitochondrial constituents such as cytochrome c stimulates a potent
execution program involving formation of the apoptosome, activation of
downstream caspases, and the subsequent demise of the cell (21,
24, 35, 43).
The capacity of Myc to drive apoptosis was first established under
growth-limiting conditions where its deregulated expression was
uncoupled from growth factor controls (5, 18). Following growth and survival factor withdrawal, sustained c-myc
expression triggered cells to undergo apoptosis. In addition, an
essential role for Myc in T-cell receptor activation-induced apoptosis
has been demonstrated in studies using antisense oligonucleotides (52). Myc is also a critical component of the death signal
initiated by tumor necrosis factor and enhances the magnitude of
response to stimulation of the CD95/Fas death receptor (15, 28,
29, 34). In addition to triggering apoptosis during growth
factor deprivation, Myc has also been shown to enhance apoptosis
induced by hypoxia, glucose deprivation, heat shock, chemotoxins, DNA damage, and cancer therapeutics (3, 26, 53, 56). Thus, Myc
activation can sensitize cells to a wide variety of mechanistically distinct antiproliferative stimuli.
The role of Myc in potentiating apoptosis has led to several models for
the mechanism of action (10, 17, 47, 55). One
well-supported model suggests that Myc acts at a common node in the
regulatory and effector machinery of apoptosis. In this dual-signal
model, Myc alone is not sufficient to induce apoptosis but rather
sensitizes cells to apoptotic stimuli that are insufficient or only
weakly elicit the full death response. This model is also in agreement
with results showing that Myc is essential for the induction of
apoptosis by sublethal doses of cytotoxic agents or a block to cell
proliferation but is not required in cases where the apoptotic stimulus
is independently potent and sufficient to trigger apoptosis. It has
been reported that Myc can induce the release of cytochrome
c from the mitochondria (8, 30). However,
neither the mechanism by which Myc elicits this response nor the
precise step in the pathway activated by Myc has been identified. Thus,
Myc is able to act as a sensitizer to numerous disparate triggers of
apoptosis, but the mechanism remains unclear.
One of the most potent Myc-cooperating oncoproteins is Bcl-2, which
functions as a global inhibitor of apoptosis, likely through multiple
mechanisms (2, 24, 48). Endogenous Bcl-2 is expressed at
both the outer mitochondrial membrane and the endoplasmic reticulum (ER) which is contiguous with the nuclear membrane. We have previously shown that apoptosis induced by serum withdrawal in the presence of
ectopically expressed Myc can be suppressed equally well by Bcl-2
located at either the mitochondria or ER. By contrast, apoptosis induced by the apoptotic agonist etoposide is inhibited by Bcl-2 targeted specifically to the mitochondria but not the ER. These results
show that by assessing the differential protection by organelle-targeted Bcl-2, we can distinguish spatially distinct apoptotic pathways triggered within the same cell. Moreover, these observations raised an important question as to whether the additional ER apoptotic pathway is Myc specific, or whether it is part of the
overall apoptotic pathway initiated by serum withdrawal. To investigate
whether Myc drives an ER-specific apoptotic pathway, we have examined
apoptosis triggered by a variety of stimuli in the presence and absence
of Myc, using organelle-specific Bcl-2.
Previous work aimed at addressing the role of Myc in apoptosis has been
confounded by the lack of a cell system in which to study apoptosis in
the complete absence of Myc. To date, most of the work done in this
area has made use of an inducible chimeric MycER protein in the
presence of endogenous Myc (references 10, 19, and 47
references therein). Here, we report the first use of c-myc
null cells to determine the rate-limiting step controlled by Myc in apoptosis.
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MATERIALS AND METHODS |
Reagents.
Etoposide, cisplatin, doxorubicin, and taxol
(paclitaxol) were purchased from Sigma. C2-ceramide was purchased from
Calbiochem Pharmaceuticals.
Cell culture and cell lines.
TGR-1 and HO15.19 Rat1
fibroblasts have been previously described (38). HOMyc3
cells were kindly provided by M. Cole and have also been previously
described (7). The targeted Bcl-2 mutants were constructed
as described in reference (58). cDNAs encoding the
different Bcl-2 constructs were subcloned into the retroviral vector
pMNiresGFP, which was used to transfect the retroviral packaging cell
line Phoenix-Eco. Viral supernatants were used to infect HO15.19 and
HOMyc3 cells in the presence of Polybrene (8 µg/ml; Sigma) for 18 h.
Cells successfully infected were selected by fluorescence-activated
cells sorting to collect cells expressing the green fluorescent protein
from the internal ribosomal entry sequence within the provirus of
infected cells. A minimum of 250,000 cells were collected to constitute
final pools of cells expressing the selected constructs. All cell lines were maintained in Dulbecco's H21 medium supplemented with 10% calf serum.
Cell growth and death assays.
DNA fragmentation was detected
by cell death detection enzyme-linked immunosorbent assay (ELISA)
(Roche Biochemicals), which was performed according to the
manufacturer's instructions. Briefly, cells were seeded as
subconfluent monolayers onto 60-mm-diameter tissue culture dishes and
allowed to settle overnight. The following day, medium was replaced
with fresh medium containing apoptotic agonist or vehicle control, and
cells were further incubated at 37°C and 5% CO2 until
time of assay. Cells were collected, and identical aliquots were
further analyzed: one aliquot for cell death detection by ELISA, and a
second aliquot that was used to derive cell counts. ELISA readings were
normalized according to the cell number tested, and at least 10,000 cells were assayed from duplicate samples in each case. All experiments
were done in duplicate and were repeated independently at least twice.
Statistical analysis was conducted using the f test to
determine whether the data curves for the Bcl-2-expressing cells
differed significantly from those derived for control cells. Data
curves for cells expressing the mutant Bcl-2 proteins were also
compared to those for cells expressing the wild-type version of the
protein. Curves were considered significantly different only when
P were less than 0.05.
To measure the growth rates of HOMyc3 and HO15.19 cells expressing
either empty vector or Bcl-2, 150,000 (HOMyc3) or 53,000 (HO15.19)
cells were seeded per well onto six-well dishes. Adherent and
nonadherent cells were then collected at the indicated time points and
analyzed for cell viability by trypan blue exclusion. Duplicate samples
were each counted three times independently to derive standard
deviations for each time point.
Immunoblotting.
Subconfluent, growing cells were lysed in
sample buffer (10% glycerol, 1% sodium dodecyl sulfate, 30 mM
Tris-HCl [pH 6.8]), separated by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis, and then transferred to
nitrocellulose membranes for subsequent immunodetection.
Affinity-purified antibodies to rat Bcl-2, human Bcl-2 (Stan), and Bax
(
IDI) (Exalpha Biologicals) were used at dilutions of 1:1,000,
1:10,000, and 1:5,000, respectively, anti-
-actin antibodies (Sigma)
were used at a dilution of 1:10,000, affinity-purified anti-cytochrome
c antibodies (Exalpha Biologicals) were used at a dilution
of 1:5,000, and anti-poly (ADP-ribose) polymerase (PARP) antibodies
(BioMol) were used at a dilution of 1:10,000. Blots were developed
after incubation with peroxidase-conjugated secondary antibodies
(Amersham), using the Renaissance enhanced chemiluminescence detection
system (Mandel).
Cell fractionation.
Cells were seeded as subconfluent
monolayers onto 100-mm-diameter tissue culture dishes and were treated
as above for the ELISA cell death assay. At the indicated time points,
cells were harvested using a rubber policeman and then pelleted by
centrifugation in a clinical centrifuge for 3 min at 4°C. The cell
pellet was washed twice with the cell buffer (250 mM sucrose, 20 mM
HEPES [pH 7.5], 2 mM MgCl2, 1 mM sodium EDTA, 1 mM
phenylmethylsulfonyl fluoride, 1 mM dithiothreitol, cocktail of
protease inhibitors). The final pellet was resuspended in an equal
volume of buffer suspension and held at 150 lb/in2 for 15 min on ice in a 45-ml nitrogen bomb (Parr Instruments), and cells were
disrupted by releasing pressure. The nuclei and cell debris in the
expelled lysate were removed by centrifugation at 500 × g for 2 min at 4°C. The resulting supernatant, termed whole-cell
lysate, was then split into a cytosolic (S100) and pellet (P100)
fraction by centrifugation at 100,000 × g for 1 h
in Beckman TLA100 rotor at 4°C. Protein samples were then snap-frozen in liquid nitrogen and stored at 
80°C. Densitometry was performed by phosphorimager analysis using Image Quant software.
Immunofluorescence.
Cells were seeded as subconfluent
monolayers onto glass coverslips and treated as above for the ELISA
cell death assay. Cells were fixed with 4% paraformaldehyde,
permeabilized with 0.2%
3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS) in
phosphate-buffered saline, and processed conventionally for
immunofluorescence. Cells were costained with the conformation-specific Bax antibody 6A7 (1:50 dilution; Exalpha Biologicals) and
affinity-purified cytochrome c antibodies (1:750 dilution;
Exalpha Biologicals). Cells stained with the 6A7 antibody were counted
by two independent observers, using identical stored images of fields
of cells generated with Zeiss LSM Image Browser software on the Carl
Zeiss LSCM 510 system. The agreement between the two observers for the
different conditions varied from 0 to 4.8% (median, 0.9%).
Mitotracker staining was performed as described elsewhere
(4a). Briefly, after exposure to drug, cells were treated
with 150 nM Mitoracker (Molecular Probes). After incubation for 15 min
in the dark, fresh medium was added and the cells were incubated for an
additional 15 min in the dark. These samples were then processed for
immunofluorescence of activated Bax, using 6A7 antibody as described
above. For competition experiments, purified 6A7 antibody was incubated
in 3% BSA bovine serum albumin-phosphate-buffered saline containing
either 5 µg of purified Bax glutathione S-transferase
(GST), 5 µg of GST-Bcl-2, or an equal volume of buffer at room
temperature for 1 h prior to staining. This antibody was then used
for immunofluorescence as described above.
Bax-GST is a carboxyl-terminal fusion of GST to amino acids 1 to 230 of
Bax (plasmid pMAC1045). Gst-Bcl-2 is an amino-terminal fusion of GST to
amino acids 1 to 187 of Bcl-2 (plasmid pMAC482). Both proteins were
expressed in bacteria under the control of tac promoter and
purified on glutathione-Sepharose 4B (Amersham Pharmacia Biotech)
according to the manufacturer's protocol.
| |
RESULTS |
To compare signaling events and apoptotic pathways induced by
different antiproliferative agents in the presence or absence of Myc,
we used HO15.19 and HOMyc3 cell lines. HO15.19 cells are derived from
an immortalized Rat1 fibroblast cell line, TGR-1, in which both alleles
of the c-myc gene have been knocked out by homologous
recombination (38); HOMyc3 cells are a c-myc
null cell line in which an exogenous c-myc allele was stably
introduced by retroviral infection (7).
Retrovirus-containing human Bcl-2 constructs in which the C-terminal
insertion sequence of the native protein has been replaced with the
C-terminal insertion sequences of proteins expressed at either the
mitochondria or the ER (as described previously [58])
were used to infect the TGR-1, HO15.19, and HOMyc3 cells. Selection of
these infected cells resulted in the generation of pooled cell
populations expressing empty vector, wild-type Bcl-2, Bcl-acta
(targeted to the mitochondria), or Bcl-cb5 (targeted to the ER). These
cells permit the evaluation of signaling events and apoptotic pathways
induced by different agents in the presence or absence of Myc in the
same genetic background.
To verify and compare levels of Bcl-2 protein in the stably infected
TGR-1, HO15.19, and HOMyc3 cell lines, protein extracts from
subconfluently growing cells of each population were isolated for
immunoblot analysis using an antibody specific to the exogenous human
Bcl-2 protein (Fig. 1A) and endogenous
rat Bcl-2 protein (Fig. 1B) as well as -actin as a loading control.
Immunoblot analysis showed that levels of relative ectopic Bcl-2
protein in each cell line were comparable and that the levels of the
endogenous protein were not significantly different in any of the
derived cell lines. Immunofluorescence and confocal microscopy
demonstrated that the different Bcl-2 variants were correctly targeted
in these cells as previously described (58) (data not
shown).
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FIG. 1.
Expression of targeted Bcl-2 protein in c-myc
null and c-myc-reconstituted cell lines. HO15.19 and HOMyc3
cells were stably infected with control retrovirus or retrovirus
carrying Bcl-2, Bcl-acta, or Bcl-cb5. Protein extracts from pooled cell
populations (10 µg/lane) were analyzed by immunoblotting for ectopic
human Bcl-2 (A) and endogenous rat Bcl-2 (B) expression. Blots were
also probed for -actin as a control for equal protein loading of
lanes.
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Spatially distinct apoptotic pathways are triggered in the presence
of ectopic Myc.
To screen a number of apoptotic agents for their
antiproliferative effect on Rat1 fibroblast cells, we used the
reduction of the tetrazolium salt
3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT
assay). Five disparate apoptotic agonists (etoposide, taxol, ceramide,
doxorubicin, and serum withdrawal) were chosen for further study, as
they induced dose-dependent death responses that were inhibited by
Bcl-2 in the Rat1 fibroblasts (data not shown). We then measured
apoptosis using an ELISA for cellular DNA fragmentation in TGR-1,
HO15.19, and HOMyc3 cell lines expressing the targeted Bcl-2
constructs after exposure to low, intermediate, or high doses of these stimuli.
After one cell cycle, both the TGR-1 and the
c-myc-reconstituted cells (HOMyc3) underwent apoptosis in a
dose-dependent manner that was inhibitable by Bcl-2 (Fig. 2A and
B). Moreover, apoptosis was
differentially inhibited by Bcl-2 targeted to specific subcellular locations. Consistent with our previous results, both Bcl-acta and
Bcl-cb5, as well as Bcl-2, abrogated apoptosis induced upon serum
withdrawal with equal efficacy. Interestingly, only Bcl-2 and Bcl-acta
efficiently inhibited etoposide-induced apoptosis. Doxorubicin-induced
apoptosis, like that induced by etoposide, was not inhibited by Bcl-cb5
yet was protected by Bcl-2 and Bcl-acta. By contrast, taxol- and
ceramide-induced death was inhibited by Bcl-cb5 as well as Bcl-2 and
Bcl-acta. As expected, HOMyc3 cells, which express an activated
c-myc allele, showed higher levels of DNA fragmentation than
the TGR-1 parental cells upon exposure to the same concentrations of
apoptotic stimuli. However, the pattern of Bcl-2 protection did not
alter despite higher levels of apoptosis in the presence of deregulated
Myc expression. From these data, spatially distinct apoptotic pathways
can be characterized as either Bcl-cb5 refractory or Bcl-cb5 inhibited,
both of which can be potentiated by Myc. Moreover, Myc is not
universally associated with an ER-specific apoptotic pathway (Fig. 2B).
Interestingly, Bcl-acta was effective against all stimuli tested,
suggesting a convergence point at the mitochondria for apoptotic
signaling in the presence of Myc.
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FIG. 2.
Distinct apoptotic pathways are triggered in the
presence of Myc. TGR-1 (A), HOMyc3 (B), and HO15.19 (C) cells
expressing empty vector control, Bcl-2, Bcl-acta, or Bcl-cb5 were
exposed to a concentration range of serum, etoposide, taxol, doxorubin,
and ceramide for one cell cycle (22 h for TGR-1 cells, 18 h for
HOMyc3 cells, and 54 h for HO15.19 cells). Apoptosis was measured
(optical density [OD]) by quantitation of DNA fragmentation.
Statistical analysis of HOMyc3 data shows that the curves indicated by
* are significantly different from control curves (P < 0.001) and that curves indicated by ** are significantly
different from Bcl-2 curves (P < 0.001). In the case
of HO15.19 cells, statistical analysis shows that Bcl-2, Bcl-acta, and
Bcl-cb5 curves are not significantly different from control curves in
response to any of the above agonists (P > 0.05).
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To determine whether Myc was critical to any one apoptotic pathway, and
to further delineate the role of Myc in apoptosis induced by different
agonists, we induced apoptosis in the c-myc null cells
(HO15.19) expressing the targeted Bcl-2 constructs. HO15.19 cells were
exposed to the same stimuli used above but for 54 h, to
accommodate one cell cycle in these more slowly dividing cells
(38). The levels of apoptosis observed in vector control cells or in cells expressing Bcl-2, Bcl-acta, or Bcl-cb5 in response to
different agonists were indistinguishable and not statistically different (Fig. 2C). These results suggested that the extent of apoptosis induced by these stimuli after one cell cycle in HO15.19 cells may not have been sufficient to distinguish the protective effects of Bcl-2. To achieve levels of apoptosis which were comparable to the death seen in HOMyc3 cells, we assayed for apoptosis in HO15.19
cells over an extended time course.
Time course experiments were performed using intermediate doses of
either etoposide or taxol (Fig. 3), and
apoptosis was further visualized and quantified by photomicrography
(Fig. 4) and time-lapse cinematography as
well as trypan blue exclusion (data not shown). Etoposide and taxol
were used as examples of Bcl-cb5-refractory and -susceptible pathways,
respectively. Upon exposure of HOMyc3 cells to either etoposide or
taxol over an extended time course, maximum detectable apoptosis was
achieved after 24 h. However, Bcl-2 was able to suppress apoptosis by
approximately 50% (Fig. 3A). When HO15.19 cells were exposed to the
same concentrations of taxol or etoposide, the levels of apoptosis at
96 h were equivalent to levels seen in the HOMyc3 control cells at
18 h (Fig. 3 and 4). However, statistical analysis of the kinetic
curves showed no significant difference between the response of the
HO15.19 control or HO15.19 Bcl-2 cells to either agonist (Fig. 3B). By contrast, concomitant analysis shows that ectopic Bcl-2 expression does
not affect cell growth of either HO15.19 or HOMyc3 cells (Fig. 4 and
5). Thus, an indirect affect on cell
growth could not account for the lack of Bcl-2 inhibition in HO15.19
cells induced to undergo apoptosis.
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FIG. 3.
Bcl-2 can inhibit apoptosis in the presence, but not in
the absence, of Myc expression. HOMyc3 (A) and HO15.19 (B) cells
expressing either empty vector control ( ) or Bcl-2 ( ) were
exposed to 0.5 µM taxol or 6 µM etoposide. Cells were harvested at
indicated time points and apoptosis was analyzed by DNA fragmentation.
All samples were tested in duplicate, and each time course experiment
was repeated at least twice with similar results. Statistical analysis
shows that the curves indicated by * are significantly different from
control curves (P < 0.001).
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FIG. 4.
Equivalent cell death occurs in c-myc null
and c-myc-reconstituted cells exposed to etoposide or taxol,
yet Bcl-2 confers survival only in the presence of Myc. (A) HOMyc3
cells expressing empty vector (control) or Bcl-2 were left untreated or
exposed to 0.5 µM taxol or 6 µM etoposide and photographed at
18 h using in a phase-contrast microscope. (B) HO15.19 cells
expressing empty vector (control) or Bcl-2 were treated with identical
doses of taxol or etoposide and photographed under similar conditions
at 96 h.
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FIG. 5.
Ectopic Bcl-2 expression does not affect cell growth of
either HO15.19 or HOMyc3 cells. HOMyc3 (A) and HO15.19 (B) cells
expressing either empty vector control () or Bcl-2 () were seeded
subconfluently, and the total number of live cells was assessed at the
indicated time points by trypan blue exclusion. Error bars indicate the
standard deviation calculated for each time point (see Materials and
Methods).
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To confirm the apoptotic nature of the cell death occurring in the
c-myc null and c-myc-reconstituted cells by an
independent assay, we assayed for cleavage of the caspase substrate
PARP in response to either taxol or etoposide. PARP cleavage was
clearly observed at 12 h after exposure to either agonist in
HOMyc3 cells and after 48 h exposure to taxol or etoposide in
HO15.19 cells (Fig. 6). These results are
consistent with time points at which DNA fragmentation was also
observed in these cells by ELISA. As an additional measure of
apoptosis, cells that had been exposed to an intermediate dose of each
agonist were fixed and stained with 4', 6'-diamidine-2-phenylindole
dihydrochloride (DAPI). In all cases, the treated cells exhibited
typical apoptotic morphologies: condensed chromatin, membrane blebbing,
and nuclear fragmentation (data not shown). Therefore, in cells with
ectopic Myc expression, mechanistically different apoptotic stimuli
induce a rapid cell death by pathways that are spatially distinct and
inhibited by Bcl-2. By contrast, in c-myc null cells, these
agents elicit apoptosis, but cell death occurs more slowly and is not
inhibitable by Bcl-2. As Bcl-2 is not effective, we cannot determine if
these pathways remain spatially distinct in the absence of Myc.
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FIG. 6.
PARP cleavage in response to etoposide or taxol in
c-myc null and c-myc-reconstituted cells. HOMyc3
(A) and HO15.19 (B) cells were exposed to either 0.5 µM taxol or 6 µM etoposide, and protein was isolated at the indicated time points.
PARP cleavage was detected by immunoblot analysis using a PARP-specific
antibody. PARP cleavage is detected by the appearance of the smaller
cleaved fragment and a relative decrease in full-length protein in
cells undergoing apoptosis.
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Myc is required for release of cytochrome c from
mitochondria during apoptosis.
When Myc is expressed, Bcl-2
targeted specifically to the outer mitochondrial membrane is able to
inhibit apoptosis induced by all agonists tested. The mitochondria are
key regulators and amplifiers of the apoptotic response, and the
release of cytochrome c from the mitochondria is a feature
of apoptosis induced by many stimuli (22). Cytosolic
cytochrome c plays a central role as a component of the
apoptosome and forms a proapoptotic complex with Apaf-1 and caspase 9 to stimulate the effector caspase cascade. Moreover, in Rat1
fibroblasts with inducible ectopic expression of MycER, the release of
cytochrome c is increased after exposure to several
different apoptotic stimuli (30). To determine whether differences in this mediator of apoptosis were evident in HOMyc3 and
HO15.19 cells, we investigated the release of cytochrome c by subcellular fractionation of cells disrupted by low-pressure nitrogen cavitation. This method offers benefits over other
homogenization procedures, as cells lysed by cavitation in iso-osmotic
buffer retain intact outer mitochondrial membranes (1).
The cytosolic and membrane fractions (S100 and P100, respectively) from
HOMyc3 and HO15.19 cells were analyzed by immunoblotting with
affinity-purified antibodies to cytochrome c to assess the
extent of cytochrome c release and with antibodies to Hsp60
as a mitochondrial marker and an indicator of the integrity of the
inner mitochondrial membrane (Fig. 7). In
untreated cells, cytochrome c was found in the membrane fraction, whereas after exposure of c-myc-reconstituted
cells (HOMyc3) to either etoposide or taxol, cytochrome c
was detected in the cytosolic fractions as early as 6 h after drug
addition. However, in parallel experiments performed in the
c-myc null cells (HO15.19), cytochrome c remained
in the membrane fraction and was not detected in the cytosolic
fractions even at later time points when PARP cleavage and DNA
fragmentation were clearly detectable (Fig. 7A). Therefore, we have
established that Myc expression is essential for the release of
cytochrome c during apoptosis triggered by disparate
apoptotic stimuli, consistent with previous reports that the induction
of MycER enhances cytochrome c release by these agents
(8, 30, 32).
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FIG. 7.
Myc is essential for cytochrome c release.
HOMyc3 and HO15.19 cells were exposed to either 0.5 µM taxol or 6 µM etoposide for the indicated times, and then cell lysates were
prepared by nitrogen cavitation. W, whole-cell lysate after cavitation
and removal of cell debris. Cytosolic proteins are in the supernatant
fraction (S100), and membrane-associated proteins including
mitochondrial proteins are in the pellet fraction (P100).
Ten micrograms of whole-cell lysate and equivalent volumes of each
fraction were analyzed by immunoblotting for cytochrome c
(A) and Hsp60 (B).
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Myc is not required for Bax translocation to membranes during
apoptosis.
Although a role has been previously ascribed to Myc in
the release of cytochrome c, no clues about mechanism have
been forthcoming. Another critical feature of many apoptotic pathways
previously linked to cytochrome c release is the
translocation of Bax from the cytoplasm to the mitochondria, where it
becomes inserted into the outer membrane (23, 33). It has
been suggested that Myc may directly regulate Bax expression through
binding to E-box elements in the promoter region of the Bax gene
(40, 41). To address whether Myc was influencing
mitochondrial events during apoptosis through a direct regulation of
this proapoptotic molecule, total RNA was extracted from asynchronously
growing cells, and the relative amount of Bax mRNA was determined. No
significant differences in Bax transcript levels were detected in
either the c-myc-null or c-myc-reconstituted cell
lines compared to the parental TGR-1 cells (data not shown). Next, to
examine whether Myc played a role in the up-regulation of Bax protein
expression during apoptosis, the relative levels of Bax protein were
compared in HO15.19 and HOMyc3 cells exposed to either etoposide or
taxol. No differences in Bax protein expression were detected in either
the presence or absence of Myc (Fig. 8).
Together, these data suggest that Myc expression does not alter the
expression profile of Bax during growth or apoptosis in these cells.
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FIG. 8.
Myc expression does not alter the expression profile of
Bax during growth or apoptosis. HOMyc3 and HO15.19 cells were exposed
to either 6 µM etoposide or 0.5 µM taxol, and protein was isolated
at 18 h (HOMyc3) or 96 h (HO15.19). Bax was detected by
immunoblot analysis using a Bax-specific antibody. Blots were also
probed for -actin as a control for equal protein loading between
lanes.
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Translocation of Bax to the mitochondria and subsequent membrane
insertion has been reported to induce cytochrome c release by the creation of a membrane pore or by altering the normal function of other preexisting mitochondrial pores (6, 16, 46). To determine whether the persistence of cytochrome c in
mitochondria during apoptosis in c-myc null cells was due to
a defect in Bax translocation, membrane and cytosolic protein
fractions, as described for Fig. 7, were probed with a Bax-specific
antibody (Fig. 9A). Although Bax was
clearly in the cytosolic fractions of both untreated HO15.19 and HOMyc3
cells, after exposure to either etoposide or taxol, Bax was detectable
in the membrane fractions of both cell types, indicating Bax
translocation to membranes of both cell types in response to apoptotic
agonists. The percentage of total Bax which relocalized to the membrane
fraction during apoptosis was determined by densitometry of data from
two independent experiments and shown to be on average 25.6 and 34.4%
in HOMyc3 cells and 39.5 and 40.1% in HO15.19 cells in response to
taxol and etoposide (Fig. 9B). Therefore, regardless of the Myc status
in the cell, Bax is translocated to the mitochondria in response to
different apoptotic agonists. Nevertheless, cytochrome c is
released only in cells expressing exogenous Myc (Fig. 7A). This result
suggests that Myc contributes to cytochrome c release
downstream of Bax translocation.
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|
FIG. 9.
Myc is not required for translocation of Bax to
membranes. (A) HOMyc3 and HO15.19 cells were exposed to either 0.5 µM
taxol or 6 µM etoposide for the indicated times, and then cell
lysates were prepared by nitrogen cavitation as described for Fig. 7.
Ten micrograms of whole-cell lysate (W) and equivalent volumes of each
fraction were analyzed by immunoblotting for Bax. (B) Immunoblots as in
panel A were analyzed by densitometry, and the percentage of total Bax
localized to the P100 membrane fraction was calculated for HOMyc3
and HO15.19 cells either untreated or exposed to 0.5 µM taxol or 6 µM etoposide for 18 h (HOMyc3) or 96 h (HO15.19). Error bars
indicated the range between two independent experiments.
|
|
Myc is required for activation of Bax.
Previous reports have
suggested that translocation to the mitochondria and activation of Bax
are regulated by a change in conformation that allows membrane
integration via its insertion sequence (14, 23). The
change in Bax conformation necessary for activation is detectable using
the conformation-specific antibody 6A7 (42). Our
observation in HO15.19 cells that cytochrome c release does
not occur, despite translocation of Bax to mitochondria, demonstrates
that translocation of Bax may not be synonymous with its activation. To
determine if the latter process was regulated by Myc expression, we
assessed Bax activation in HOMyc3 and HO15.19 cells after exposure to
etoposide or taxol, using the 6A7 antibody, by confocal microscopy
(Fig. 10). In addition, cells were
costained with antibodies to cytochrome c to assess its
release into the cytoplasm. To use the 6A7 monoclonal antibody to
assess Bax conformation, it is necessary to permeabilize cells with
CHAPS, as other detergents induce conformational changes in Bax that
expose the 6A7 epitope. When cells are permeabilized with CHAPS,
staining of cytochrome c in the cytosol is intense and
clearly evident, while staining of cytochrome c in
mitochondria is less intense. This is likely a consequence of
inefficient permeabilization of mitochondria by CHAPS, as equivalent
intensity of cytochrome c staining is evident in both the
mitochondria and cytosol with other detergents (data not shown). Thus,
permeabilization with CHAPS and subsequent staining allows for the
simultaneous detection of Bax activation and cytochrome c
release into the cytoplasm.
View larger version (65K):
[in this window]
[in a new window]
|
FIG. 10.
Bax is not activated in the absence of Myc. (A) HOMyc3
and HO15.19 cells were either left untreated or exposed to 0.5 µM
taxol or 6 µM etoposide for 12 h (HOMyc3) or 48 h (HO15.19). The
staining pattern of cytochrome c (red) and presence of
activated Bax detected by the 6A7 antibody (green) were assessed by
immunofluorescence and laser scanning confocal microscopy. All fields
have been magnified similarly. Original confocal images can be viewed
at
http://www.science.mcmaster.ca/biochem/faculty/andrews/lab/index.html.
(B) A minimum of three fields of 40 cells each were counted
independently by two different observers for each of the indicated
conditions and time points to determine the percentage of cells stained
by 6A7. Error bars indicate the range between the two observers.
|
|
After exposure to either drug, a proportion of HOMyc3 cells were 6A7
positive, and only these cells showed evidence of cytochrome c release (Fig. 10A). The number of 6A7-positive cells was
substantially greater in HOMyc3 cells exposed to either etoposide or
taxol compared to untreated controls (Fig. 10B). At 18 h, 18 and
24% of HOMyc3 cells were 6A7 positive in response to taxol and
etoposide, respectively. As this analysis can be conducted only on
cells that are still adherent, and many of the HOMyc3 cells have
detached from the dish at this time, these figures are relatively low
estimates of proportion of cells with activated Bax. By contrast, we
were we not able to detect 6A7-positive HO15.19 cells above background in taxol- or etoposide-treated cells, nor did we observe cytochrome c release in the HO15.19 cells, consistent with results
obtained after cell fractionation and immunoblotting (Fig. 7A). Similar experiments using the 6A7 antibody in combination with Mitotracker, a
mitochondrion-specific fluorescent dye, showed localization of
activated Bax at the mitochondria (Fig.
11, top). The specificity of the
6A7-activated Bax interaction was confirmed by competition experiments
with active-conformation Bax-GST fusion protein (Fig. 11, bottom).
Pretreatment of 6A7 antibody with recombinant Bax-GST fusion protein
was able to overide endogenous activated Bax-6A7 interactions. By
contrast, recombinant GST-Bcl-2 was unable to bind and compete with
6A7 antibody for interaction with activated endogenous Bax protein
(data not shown). We can conclude that 6A7 binds specifically to
activated Bax in these cells. Taken together, these results show that
Myc expression is necessary for the activation of Bax during apoptosis
but is not required for the translocation of Bax to the mitochondria.
Moreover, Bax translocation occurs prior to and is independent of the
conformational change detected by the 6A7 antibody.
View larger version (41K):
[in this window]
[in a new window]
|
FIG. 11.
Activated Bax is localized at the mitochondria. HOMyc3
cells were either left untreated or exposed to 0.5 µM taxol or 6 µM
etoposide for 18 h. The staining pattern of Mitotracker (red) and
presence of activated Bax detected by the 6A7 antibody (green) were
assessed by immunofluorescence and laser scanning confocal microscopy.
All fields have been magnified similarly. Competition experiments were
performed under similar conditions with the addition of 5 µg of
recombinant Bax-GST fusion proteins in conjunction with 6A7 antibody
(bottom) to verify the specificity of the activated Bax-6A7 interaction
in these cells (see Materials and Methods).
|
|
| |
DISCUSSION |
First, our data demonstrate that spatially distinct apoptotic
pathways triggered by a variety of stimuli can be inhibited by Bcl-2
and Bcl-acta and can be further characterized as susceptible or
refractory to inhibition by Bcl-cb5. Apoptotic cascades stimulated by
serum withdrawal, taxol, and C2-ceramide can be blocked by Bcl-cb5. By
contrast, apoptosis in response to etoposide and doxorubicin stimulates
a Bcl-cb5-refractory pathway. Interestingly, upon constitutive expression of Myc, apoptosis is potentiated, as expected, yet the
pattern of Bcl-cb5 protection does not alter. As the activity of
Bcl-cb5 does not partition with ectopic Myc expression in a global
manner, Myc does not universally drive an apoptotic pathway that is
associated with the ER. Consistent with these results, we did not see
differences in ER-regulated pH or calcium concentrations in the
presence or absence of Myc expression (S. Grinstein, K. Szaszi, E. L. Soucie, and L. Z. Penn, unpublished data). While the mechanisms
of ER-regulated apoptosis and inhibition by Bcl-2 at this subcellular
location are of interest, our data suggest that the role of Myc in
apoptosis lies downstream at a position more central to both
Bcl-cb5-sensitive and -refractory pathways.
Our analysis with the Bcl-2-targeted molecules clearly showed that
apoptosis triggered in the presence of Myc expression by all agonists
tested was universally inhibited by Bcl-acta, suggesting that Myc plays
a role in the regulation of apoptosis at the level of the mitochondria.
This is consistent with accumulating evidence suggesting that Myc
action is focused at a common mitochondrial signaling element of many
apoptotic pathways. Indeed, we show that Myc is essential for
cytochrome c release from mitochondria in response to
mechanistically distinct chemotherapeutic agents. These observations
extend recent reports indicating that induction of MycER potentiates
the release of cytochrome c following serum deprivation
(8, 30, 32). Moreover, our analysis of the upstream
processes that lead to cytochrome c release reveals that Bax
translocation and activation are uncoupled, and the latter is dependent
on Myc expression. To date, Bax translocation has been synonymous with
activation; however, these events can be independently regulated, and
Myc is required for Bax activation in conjunction with an apoptotic stimulus.
The lack of Bax activation in HO15.19 c-myc null cells
likely accounts for the absence of cytochrome c release, as
activated Bax has been shown to regulate this critical step in the
control of apoptosis (14, 16, 31). Numerous mechanisms of
Bax activation and cytochrome c release have been proposed,
including Bax oligomerization, activation of an independent or
preexisting mitochondrial pore, or a novel protein-protein interaction.
Myc may directly activate Bax after both proteins translocate to the
mitochondria in response to apoptotic stimuli. A similar mechanism has
recently been described for the nuclear orphan receptor TR3/Nur77,
another transcription factor that can induce apoptosis through the
release of cytochrome c (36). Alternatively,
Myc may indirectly control Bax activation and cytochrome c
release, perhaps by regulating an upstream activator of Bax.
Interestingly, during revision of this report, it was reported that
apoptosis induced by serum withdrawal in the presence of deregulated
Myc expression was deficient in Bax-null mouse embryo fibroblasts
(40). This work further supports our data showing that Bax
is critical for Myc potentiation of apoptosis. Further analysis of the
c-myc null cell system is needed to identify the
rate-limiting step controlled by Myc in the sensitization of cells to
diverse apoptotic stimuli.
Analysis of this system shows that Bax expression is not directly
regulated by Myc at the level of either mRNA or protein. Identification
and verification of endogenous Myc target genes essential for apoptosis
has been a slow and difficult process, due in part to the ubiquitous
nature of Myc expression. A definitive all-or-none c-myc
null cell system to address the identity, function, and regulation of
Myc target genes has not been available. Both c-myc and
N-myc knockout mice are embryonic lethal at approximately day 10, and mouse embryo fibroblasts null for myc expression
cannot be derived (9, 13, 54). This major obstacle has
been overcome through the development of the Rat1 somatic cell knockout
system (38). This novel experimental tool has already had
a significant impact on the field (7, 39, 44, 57).
Comparison of c-myc null cells and null cells reconstituted
with an exogenous allele of c-myc has been instrumental in
distinguishing the putative Myc-regulated genes that are indeed
dependent on Myc for regulation (7, 44). Moreover, it is
thought that the Myc-regulated growth and death program can be
uncoupled and that Myc regulates unique subsets of genes which in turn
mediate these disparate activities (11, 20, 45). Clearly,
this system will likely be instrumental in both identifying and
verifying Myc-regulated genes critical for apoptosis.
The characteristics of apoptotic pathways that we have identified in
HO15.19 and HOMyc3 cells are reminiscent of the two types of response
that have been recently described for CD95 signaling (50,
51). In type I cells, where the components of the death-inducing signaling complex are not limiting, direct activation of downstream effector caspases by caspase 8-mediated cleavage is sufficient to
induce apoptosis. This apoptosis is not blocked by Bcl-2. In type II
cells, death receptor signaling to effector caspases through direct
means is insufficient, and therefore a mitochondrial amplification loop
that involves caspase 8 cleavage of Bid, Bax activation, and cytochrome
c release is required. Our results parallel these observations; in the absence of Myc, cells undergo apoptosis by a type
I-like, Bcl-2 noninhibited mechanism, whereas in the presence of Myc, a
mitochondrion-dependent, Bcl-2-inhibited type II-like cell death is
evident. Further investigation into the nature of this Myc-independent
pathway is required, as it points to an alternative apoptotic pathway
which is able to circumvent downstream signaling events at the mitochondria.
Our data further support the dual-signal model, as we show that Myc is
essential but not sufficient for Bax activation, cytochrome c release, and apoptosis induction. Both Myc expression and
a growth-inhibitory signal are required to trigger cell death. Our hypothesis is that Myc derepresses at least one level of apoptotic control, removing a rate-limiting event in the regulation of apoptosis and rendering cells more competent to die in response to a diverse set
of stimuli. Our work shows that Myc likely regulates a common point of
control, despite the diversity of signaling cascades with which it can
collaborate to trigger apoptosis. We show that point of control to be
at the level of Bax activation. This is consistent with previous
reports showing Bcl-2 cooperates strongly with Myc in tumorigenesis, as
it is a potent inhibitor of Myc-regulated apoptosis. Indeed, other
inhibitors of Myc-stimulated apoptosis, such as insulin-like growth
factor and Akt/protein kinase B, also function through a mechanism that
targets Bcl-2 activity or cytochrome c release (20,
26, 30, 32). Together, these observations further support our
data showing that Myc regulation of apoptosis is focused at the
mitochondria and controls an apoptotic amplification step by regulating
Bax activation.
We thank members of the Penn lab for helpful discussions
during preparation of the manuscript.
This work was supported by CIHR and NCIC grants to L.Z.P. as well as a
CIHR grant to D.W.A. and B.L. E.S. is the recipient of a CIHR doctoral
research award.
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Abstract
Introduction
This paper is dedicated to the memory of Arnold Greenberg.
