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Molecular and Cellular Biology, August 2001, p. 4929-4937, Vol. 21, No. 15
Department of Molecular Biology, Cell
Biology, and Biochemistry, Brown University, Providence, Rhode Island
02912
Received 13 February 2001/Returned for modification 10 April
2001/Accepted 28 April 2001
The c-myc proto-oncogene encodes a transcription factor
that participates in the regulation of cellular proliferation,
differentiation, and apoptosis. Ectopic overexpression of c-Myc has
been shown to sensitize cells to apoptosis. We report here that cells
lacking c-Myc activity due to disruption of the c-myc gene
by targeted homologous recombination are defective in DNA
damage-initiated apoptosis in the G2 phase of the cell
cycle. The downstream effector of c-Myc is cyclin A, whose ectopic
expression in c-myc Mutations affecting the
c-myc proto-oncogene are among the most common genetic
lesions found in a variety of human and animal cancers (19,
39). The c-Myc protein is a transcription factor that functions
as an obligate heterodimer with its partner Max and binds the core
recognition sequence CACGTG (E-box) and a number of related
sequences (28). Genes whose expression is regulated by
c-Myc have been intensively sought (8), but our
understanding of downstream signal transduction pathways remains
fragmentary (7, 47). It is now well established that c-Myc
can repress, as well as activate transcription, but the relative
contribution of these mechanisms to the variety of physiological
responses mediated by c-Myc is not yet clear (6, 13).
The role of c-Myc as a positive effector of the cell cycle has been
extensively documented (40). Under appropriate
circumstances, both repression and overexpression of c-Myc can lead to
apoptosis. For example, in a variety of transformed cell types
c-myc antisense oligonucleotides cause growth inhibition,
which in some (but not all) cases is associated with the onset of
apoptosis (51). On the other hand, there are many examples
where c-Myc is required, to a greater or lesser degree, for the
efficient induction of apoptosis by a variety of stimuli
(42). Overexpression of c-Myc augments the apoptotic
program and rapidly induces cell death when cells are deprived of
survival factors (3, 12).
The tumor suppressor gene p53 has been implicated as a target of c-Myc
regulation (44, 45). c-Myc-induced apoptosis requires p53
in some (20, 53) but not all (46, 52) cases.
Likewise, Bcl-2 exerts a sparing effect on some (54, 55)
but not all (52) c-Myc-induced apoptotic responses. To
explain such discrepancies, it has been proposed that c-Myc acts to
sensitize the cell to a variety of apoptotic stimuli, both p53
dependent and p53 independent, that can be counteracted by survival
signals (11). Considerable evidence supports a dual
function for c-Myc as a coordinate activator of both proliferation and
apoptosis. According to this model, both functions would be intrinsic
to c-Myc and may involve distinct apoptosis priming and triggering
pathways, at least some of which may be mechanistically distinct from
the promotion of proliferation (42). Indeed, recent work
is beginning to uncover c-Myc targets or effectors, such as
p19ARF1 (57) and Bin1
(42), which appear to function in apoptosis but do not
affect proliferation.
The majority of studies on c-Myc have employed overexpression
paradigms. In some cases antisense or dominant-defective approaches have been used, but their interpretation is complicated by the incomplete inhibition of c-Myc expression, as well as uncertainties pertaining to the mechanisms of dominant-defective action. We have
isolated c-myc null cell lines (31) and have
initiated an investigation of their proliferative phenotypes
(32). In this study we use the
c-myc Cell lines and culture conditions.
TGR-1 is a subclone of
the immortalized rat embryo fibroblast cell line Rat-1
(43). The c-myc null cell lines have been described (31). The c-myc,
temperative-sensitive p53 (36), cyclin A, cyclin E, and
cyclin D1 cDNA transgenes were introduced in the retrovirus vector LXSH
(37). Clonal cell lines were selected with hygromycin and
screened by immunoblotting. TGR/p53-4 is a derivative of TGR-1 and
expresses the temperature-sensitive p53 transgene. HO/myc3, HO/p53-5,
HO/cycA-2, HO/cycA-4, HO/cycA-7, HO/cycE-2, and HO/cycD-2 are
derivatives of HO15.19 and express c-myc,
temperature-sensitive p53, cyclin A, cyclin E, and cyclin D1
transgenes, respectively. Cell lines HO/cycE-2 and HO/cycD-2 were
previously described as cell lines HO15E2 and HO15D2, respectively (31). Cells were cultured in Dulbecco modified Eagle
medium containing glutamine, pyruvate, high glucose, and 3.7 g of
sodium bicarbonate per liter, supplemented with 10% calf serum and
penicillin-streptomycin. Cells were maintained in a 5% CO2
atmosphere at 37°C. Drugs were added directly to the culture medium
at the times indicated in the figures at the following concentrations:
etoposide, 2 µM; cisplatin, 10 µg/ml; staurosporine, 5 µM;
aminopurvalanol, 10 µM. The cyclin-dependent kinase (Cdk) inhibitor
aminopurvalanol (5) was a kind gift of Peter G. Schultz
(The Scripps Research Institute, La Jolla, Calif.).
Apoptotic assays.
The dose response of TGR-1 cells to
etoposide and cisplatin treatment was determined by measuring the
extent of apoptosis at the end of a 48-h treatment, with the following
results: for etoposide, 0 µM, 0.5%; 0.5 µM, 38.4%; 0.75 µM,
58.6%; 1 µM, 76.8%; 1.5 µM, 86.2%; and 2 µM, 88.4%; and for
cisplatin, 0 µg/ml, 2%; 0.5 µg/ml, 35.6%; 1 µg/ml, 52.6%; 2.5 µg/ml, 77.8%; 5 µg/ml, 85.2%; 7.5 µg/ml, 87.4%; and 10 µg/ml, 88.9%. A 72-h treatment elicited 100% apoptosis in the range
of 1 to 2 µM etoposide and 2.5 to 10 µg of cisplatin per ml. We
chose 2 µM etoposide and cisplatin at 10 µg/ml as doses
representative of the early to mid plateau phase of each response.
Cisplatin elicited a strong apoptotic response in
c-myc Immunoblotting and kinase assays.
Samples were prepared by
rapid lysis of whole cells in Laemmli sample buffer supplemented with
protease inhibitors (10 µg of aprotinin per ml, 1 µg of leupeptin
per ml, 1 mM phenylmethylsulfonyl fluoride) and subjected to
immunoblotting analysis using standard methods (32).
Equivalent loading of lanes was carefully determined by running pilot
gels loaded with various dilutions of extracts and analyzing images of
Coomassie-stained gels using the Gel-Doc (Bio-Rad) digital gel
documentation system and the Molecular Analysis software package
(27, 32). Adjustments in sample volumes were made based on
this analysis, and the process was repeated until all the lanes were
equivalently loaded. This method can reliably establish equivalent
loading within a 10 to 20% error value for all lanes. For
immunoblotting, polyclonal antibodies to p53 (Novacastra), cyclin A
(Upstate Biotechnology), and poly-ADP-ribosyl polymerase (PARP; clone
C-2-10, SA-250; Biomol Research Laboratories) were used at 1 µg/ml.
c-Myc antibody was provided by Steve Hann (Vanderbilt). Signals were
visualized with ECL chemiluminescence (Amersham). Cdk activity was
assayed using Tween 20 lysis conditions (33), immunoprecipitation with the cyclin A (C-19) antibody (Santa Cruz), and
histone H1 as substrate as described earlier (32).
The role of c-Myc in DNA damage-triggered apoptotic processes was
first investigated by treating c-myc+/+ (TGR-1)
and two independently derived c-myc
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.15.4929-4937.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
c-Myc Is Necessary for DNA Damage-Induced
Apoptosis in the G2 Phase of the Cell Cycle
ABSTRACT
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
/ cells rescues the
apoptosis defect. The kinetics of the G2 response indicate
that the induction of cyclin A and the concomitant activation of Cdk2
represent an early step during commitment to apoptosis. In contrast,
expression of cyclins E and D1 does not rescue the apoptosis defect,
and apoptotic processes in G1 phase are not affected in
c-myc/ cells. These observations link DNA
damage-induced apoptosis with cell cycle progression and implicate
c-Myc in the functioning of a subset of these pathways.
INTRODUCTION
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
/ cell lines for the first time to
investigate the function of c-Myc in apoptotic pathways initiated by
DNA-damaging agents. This is a topic of considerable interest because
of its applications to the chemotherapy of cancer but, in contrast to
studies of survival signal withdrawal, it has received very little
attention (4, 9, 38).
MATERIALS AND METHODS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
/ cells in the 1 to 10 µg/ml range.
The percentage of cells undergoing apoptosis was calculated as the
ratio of apoptotic and total cells. Apoptotic TGR-1 cells become
detached from the substratum; thus, the extent of apoptosis can be
determined by counting floating and adherent cells. To perform in situ
TUNEL (terminal deoxynucleotidyl-transferase-mediated dUTP-biotin nick
end labeling) assays, floating cells were recovered from the medium by
centrifugation and pooled with the adherent cells collected with
trypsin. Cells were spun down onto polylysine-coated slides, and 3'-end
elongation was catalyzed using TdT enzyme and digoxigenin-11-dUTP,
which was detected with rhodamine-conjugated anti-digoxigenin antibody.
Hoechst 33258 was used at 0.5 µg/ml in phosphate-buffered saline. The
Apo-Direct kit (PharMingen) was used according to manufacturer's
instructions. At least two independent assays of apoptosis were used in
all experiments. The results of all apoptosis assays were always in
agreement. All experiments were repeated on at least two independent
occasions with consistent results. Error bars indicate the standard
deviations of a minimum of three datum points. The absence of error
bars indicates that the errors were smaller than the datum point symbols.
RESULTS
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
/ cell
lines (HO15.19 and HO16.4) with the topoisomerase II inhibitor etoposide, a drug known to elicit double-stranded DNA breaks (see Materials and Methods for the dose response to drug treatment). All
cultures were in the exponential phase of growth and subconfluent at
the time of drug addition. In contrast to the robust apoptosis observed
in c-myc+/+ cultures,
c-myc/ cells were severely impaired in their
apoptotic response, even after extended periods of incubation in the
presence of drugs (Fig. 1A). Restoration
of c-Myc activity by introducing a c-myc transgene on a
retrovirus vector reversed the apoptosis defect (Fig. 1B). Apoptotic
death in c-myc+/+ cells was confirmed by in situ
TUNEL assay (Fig. 1D and E), nucleosomal laddering (Fig. 1F), nuclear
condensation visualized by Hoechst dye staining (data not shown), and
cleavage of endogenous poly-ADP-ribosyl polymerase (PARP) protein (Fig.
2A). The apoptotic defect observed in
c-myc/ cells was not general, because a
variety of stimuli that do not involve DNA damage, such as the protein
kinase inhibitor staurosporine (Fig. 1C) or the proteasome inhibitor
MG132 (data not shown), were capable of eliciting a normal apoptotic
response. Furthermore, not all DNA damage-induced responses were
impaired, because cisplatin (Fig. 1C and 2B) and UV irradiation (data
not shown) were capable of eliciting a strong apoptotic response.
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FIG. 1.
(A) Apoptosis elicited in
c-myc+/+ and c-myc /
cells by treatment with etoposide (Eto). (B) Rescue of apoptosis by
reconstitution of c-Myc activity. (C) Apoptosis elicited in
c-myc/ cells by a variety of agents. Sts,
staurosporine; Cis, cisplatin; Eto, etoposide. Cells were treated for
48 h. (D and E) TUNEL assay of c-myc+/+ (D) and
c-myc/ (E) cells. TGR-1 and HO15.19 cells
were harvested after 24 and 96 h of treatment with etoposide,
respectively. (F) Nucleosomal laddering assay of
c-myc+/+ and c-myc/
cells. Cells were treated as in panels D and E, and 3 µg of DNA was
loaded into each lane. Cell lines: TGR-1,
c-myc+/+; HO15.19, HO16.4,
c-myc/; HO/myc3,
c-myc/ expressing ectopic c-myc.
HO/myc3 cells express wild-type murine c-Myc at a level two- to
threefold above that found in TGR-1 cells.
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FIG. 2.
PARP cleavage elicited by drug treatment of
c-myc+/+ and c-myc /
cells. Exponentially growing cultures of the indicated cell lines were
treated with drugs at the zero time point, collected at the indicated
times, and analyzed by immunoblotting. Eto, etoposide treatment; Cis,
cisplatin treatment. See Fig. 1 for a description of the cell lines.
c-myc/ cells proliferate approximately
threefold more slowly than c-myc+/+ cells, with
cell cycle durations of approximately 50 and 18 h, respectively
(31). The possibility that the apoptotic impairment in
c-myc/ cells may be caused primarily by
generalized metabolic defects was therefore considered. We believe this
explanation is unlikely for the following reasons. First, the initial
onset of apoptosis occurred within one cell cycle of drug treatment in
both c-myc+/+ and
c-myc/ cells, between 12 to 15 h and 48 to 56 h after drug addition, respectively. Thus,
c-myc/ cells initiated the apoptotic
response at a time commensurate with their reduced growth rate, but
apoptosis failed to proceed to normal levels. Second, 80 to 100% of
c-myc+/+ cells became apoptotic within three
cell cycle durations, whereas the extent of apoptosis in
c-myc/ cultures did not exceed 10 to 15% at
the commensurate times (i.e., the 156- and 192-h time points). Third,
the apoptotic profile of c-myc/ cells did
not change whether drug was added once at the time zero point or fresh
medium with drug was replenished at 48-h intervals (data not shown).
At the relatively low concentrations used in this study, etoposide
elicits DNA damage primarily in the S phase, and the ensuing apoptosis
occurs predominantly in the G2 phase (10). To
investigate the relationship between cell cycle progression and
apoptosis, drug-treated cultures were examined by flow cytometry (Fig.
3A and B). Both
c-myc+/+ and c-myc/
cultures showed a substantial (65 to 70%) accumulation of cells with
G2/M DNA content, and this plateau was reached within
18 h (c-myc+/+) and 56 h
(c-myc/) after addition of the drug. The
total number of cells in both cultures ceased to increase after
addition of the drug. These cell cycle profiles are consistent with the
accumulation of DNA damage during passage through S phase and a
subsequent arrest in G2, and the kinetics of the
progression are in good agreement with the doubling times of
c-myc+/+ and c-myc/
cells, 18 and 50 h, respectively (31). In
c-myc+/+ cultures the accumulation of cells with
a G2/M DNA content coincided with the initial appearance of
apoptosis 12 to 18 h after addition of the drug. Likewise, in
c-myc/ cells the first apoptotic cells were
detected at 48 to 56 h after addition of the drug, at which time the
G2/M content of the cultures had risen to 57 to 62%.
However, although both the extent of G2/M accumulation and
the initial onset of apoptosis were commensurate with cell cycle
progression in c-myc+/+ and
c-myc/ cells,
c-myc+/+ cultures became quickly consumed by a
wave of apoptosis, whereas in c-myc/
cultures apoptosis did not exceed 10 to 15% even at very late times
(156 to 192 h). Neither c-myc+/+ or
c-myc/ cells could be rescued by removal of
the drug (data not shown). c-myc/ cultures
could not be maintained beyond the 192-h time point because the
remaining nonapoptotic cells gradually degenerated with signs of
necrosis (data not shown).
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To investigate the effect of drugs that damage DNA irrespective of cell
cycle position, cultures were treated with cisplatin (Fig. 3C), a drug
that causes interstrand cross-links (see Materials and Methods for the
dose response to drug treatment). In c-myc+/+
cells cisplatin caused the same degree of apoptosis as had etoposide and, after an initial lag, cisplatin also elicited a strong apoptotic response in c-myc/ cells. The progression of
apoptosis was approximately twofold slower in
c-myc/ cultures but proceeded to the same
extent as in c-myc+/+ cultures. The twofold
delay in c-myc/ cultures may be related to
their reduced rate of proliferation and macromolecular synthesis
(31). It is therefore apparent that
c-myc/ cells, given an appropriate stimulus,
are capable of mounting a significant apoptotic response to DNA damage.
To investigate selectively apoptosis in the G1 phase, cells
were synchronized in G0 by serum deprivation and treated
with cisplatin for 2 h after serum-induced release into the cell
cycle (Fig. 3D). After a short initial lag both the kinetics and the
extent of apoptosis were identical in c-myc+/+
and c-myc/ cultures. Flow cytometry showed
that both c-myc+/+ and
c-myc/ cells became arrested with a
G1 DNA content (data not shown). UV light treatment gave
the same results as cisplatin (data not shown). Treatment of
G0 synchronized cells with etoposide did not elicit a
G1 arrest; in contrast to cisplatin, the cells progressed through S phase and accumulated with a G2/M DNA content
(data not shown). Again, the kinetics of G2/M accumulation
were commensurate with cell cycle progression rates in
c-myc+/+ and c-myc/
cells, but the extent of G2/M accumulation was the same in
both. Finally, the same apoptotic response as that seen in
exponentially cycling cells was observed:
c-myc+/+ cultures were quickly consumed by
apoptosis, whereas in c-myc/ cells apoptosis
did not exceed 10 to 15% even at very late times (156 h). Thus,
c-myc/ cells show a dramatic defect in
apoptosis in G2/M but appear capable of essentially normal
apoptosis in G1.
To further investigate the relationship between cell cycle position and
apoptosis, TUNEL and cell cycle assays were combined by two-parameter
flow cytometry. As previously seen, in c-myc+/+
cultures etoposide caused an accumulation of cells in G2/M
(Fig. 4B). In addition, the two-parameter
analysis showed that the majority of TUNEL-positive cells had a
G2/M DNA content, indicating that apoptosis was occurring
directly in the G2/M-arrested cells. In c-myc/ cells etoposide also caused an
accumulation in G2/M, but very few TUNEL-positive cells
were seen (Fig. 4E). Cisplatin caused strong apoptosis both in
G1 and G2/M in c-myc+/+
cells (Fig. 4C); this result confirms that cisplatin can cause DNA
damage irrespective of cell cycle position and that the Rat-1 cells
used in this study can undergo apoptosis in both G1 and G2/M phases. In contrast, c-myc/
cultures became depleted of G2/M cells and accumulated in
G1 (Fig. 3F), and TUNEL-positive cells were seen
predominantly with a G1 DNA content. Thus, in
c-myc/ cells even a drug that causes DNA
damage irrespective of cell cycle position elicits apoptosis
predominantly in G1. It therefore appears that
c-myc/ cells are compromised in their
apoptotic response in the G2/M phase of the cell cycle.
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Treatment of c-myc+/+ or
c-myc/ cells with etoposide, cisplatin, or
UV light (Fig. 5A and data not shown) in
all cases caused a marked accumulation of p53 protein. This effect is
known to occur primarily by the stabilization of the p53 protein, as
well as by a relatively minor induction of the mRNA (15,
29). The Rat-1 cell line used in this study has been reported to
express wild-type p53 protein (30). In
c-myc+/+ cells the increase in p53 protein
levels after drug treatment was greater than 10-fold, while induction
of the mRNA was only 2- to 3-fold (data not shown). Although the
increase in p53 protein expression was somewhat variable from
experiment to experiment, c-myc/ cells
reproducibly displayed a modest (two- to threefold) defect in p53
induction as detected by immunoblotting (Fig. 5A) or
immunoprecipitation (data not shown). It should be noted that because
of the decreased growth rate of c-myc/
cells, data spanning the critical first cell cycle after addition of
drug are presented for both cell lines. For example, the 24-h time
point for c-myc+/+ cells (ca. 1.3 cell cycles)
is most appropriately compared to the 72-h time point for
c-myc/ cells (1.4 cell cycles). p53 protein
expression in c-myc/ cells did not increase
beyond the 72-h time point and actually declined at later times (data
not shown).
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To address whether the small defect in p53 accumulation was responsible
for the apoptosis defect, stable cell lines expressing a
temperature-sensitive mutant of p53 were isolated. The
temperature-sensitive p53 protein displays wild-type activity at the
permissive temperature (32.5°C) and mutant activity at the
nonpermissive temperature (37°C) (36). Since
overexpression of wild-type p53 protein causes cell cycle arrest, this
strategy allowed the propagation of p53-overexpressing cells at 37°C,
as well as the analysis of functional p53 overexpression by shiftdown
to 32.5°C. Overexpression of the introduced temperature-sensitive p53
protein was documented by immunoblotting (Fig. 5B). Furthermore, the
introduced p53 protein was biologically active because at 32.5°C it
accelerated apoptosis in response to all drugs in
c-myc+/+ cells, and in response to cisplatin and
UV light in c-myc/ cells (data not shown).
Exponentially growing cells at 37°C were treated with etoposide and
shifted to 32.5°C to activate the p53 protein (Fig. 5C).
Overexpression of p53 did not restore apoptosis, even at late times
during incubation with etoposide. Apoptosis was also not restored when
the shiftdown to 32.5°C was delayed (up to 60 h) relative to the
addition of the drug (data not shown). Immunoblotting analysis showed
that p53 protein was overexpressed during the course of the experiment
(Fig. 5D). Thus, the small defect in p53 expression seen in
c-myc/ cells does not appear to be causally
linked to the apoptotic defect.
Position in the cell cycle may be important for susceptibility to
apoptosis, and Cdks have been implicated in apoptotic processes in
several experimental systems (2, 14, 18, 21, 34, 35). The
fact that we have previously documented activation defects of several
cyclin-Cdk complexes in c-myc/ cells made
this a compelling line of investigation. The recent development of a
highly specific and potent class of Cdk inhibitors, purvalanol and its
derivatives (5, 16), allowed us to rapidly evaluate
pharmacologically the involvement of these pathways in DNA
damage-induced apoptosis. Purvalanols, unlike earlier Cdk inhibitors
such as roscovitine and olomoucine, display a high degree of both
selectivity and potency for Cdk1 and Cdk2 (5, 16).
Exponentially growing c-myc+/+ cells were
treated with etoposide, cisplatin, or left without drug and at the same
time either exposed to aminopurvalanol or left untreated. The extent of
apoptosis was assessed after 48 h either by microscopic
observation of the cultures (Fig. 6A) or
by harvesting the cells and immunoblotting for PARP (Fig. 6B). As shown
previously, in the absence of aminopurvalanol, both etoposide and
cisplatin elicited a strong apoptotic response that was accompanied by
PARP cleavage. Strikingly, aminopurvalanol was strongly protective against etoposide-induced apoptosis, while it had no effect on the
response elicited by cisplatin.
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We have previously shown that exponentially growing
c-myc/ cells display a modest (two- to
threefold) defect in cyclin A expression, as well as in cyclin
A-associated Cdk activity (32). In
c-myc+/+ cells treatment with etoposide caused a
strong accumulation of cyclin A protein as early as 6 h after drug
addition, whereas in c-myc/ cells the
magnitude of the induction was reduced and the kinetics were delayed
(Fig. 7A). Cyclin B expression peaked at
24 h in c-myc+/+ cells and appeared at a
low level at the 72-h time point in c-myc/
cells (data not shown). Thus, as would be expected, cyclin B expression
followed kinetically that of cyclin A. It is of interest to note that
cyclin A induction was rapid and preceded the accumulation of p53
(compare results with Fig. 5A). Cyclin A-associated kinase activity
after etoposide treatment peaked at 12 h in
c-myc+/+ cells (Fig. 7D) and also clearly
preceded the onset of apoptosis at 18 to 24 h. The peak of cyclin
A-associated kinase activity in c-myc/ cells
was significantly delayed as well as reduced in magnitude. Cyclin
B-associated kinase activity peaked at 24 h in
c-myc+/+ cells and was also significantly
delayed and dampened in c-myc/ cells (data
not shown).
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To address the functional relevance of reduced cyclin A expression,
c-myc/ cell lines stably overexpressing
cyclin A were isolated. It should be noted that in the cell lines
chosen for study the overexpression of cyclin A was modest (Fig. 7B),
and no apoptosis was observed in the absence of DNA-damaging agents.
However, the expression of ectopic cyclin A in
c-myc/ cells restored to a significant
degree the ability of etoposide to elicit apoptosis (Fig. 7E). Control
experiments showed that in cyclin A-overexpressing cell lines etoposide
caused the expected G2/M arrest (Fig. 7G) and that cyclin A
was overexpressed at the time points when apoptosis was occurring (Fig.
7C). Several features of the cyclin A rescue were notable. First, the
rescue was dose dependent, such that the magnitude of the apoptotic
response correlated positively with the expression levels of cyclin A. Second, although the rescue was significant (50% apoptosis in
HO/cycA-2 cells versus 15% in HO15.19 cells), it was not complete and
apoptosis occurred with slower kinetics than in
c-myc+/+ cells (compare to Fig. 1A). In fact,
the kinetics of the apoptotic response to etoposide in the cyclin
A-rescued cells resembled the response elicited by cisplatin in
parental c-myc/ cells (compare to Fig. 3C).
Perhaps the most significant aspect of the cyclin A rescue of apoptosis
is that cyclin A overexpression had no effect whatsoever on the
slow-growth phenotype of c-myc/ cells and
did not affect progression through any phase of the cell cycle relative
to the parental c-myc/ cells. The cyclin
A-expressing cell lines used here were part of a larger study to
investigate the effects of cyclin overexpression on the growth
phenotype of c-myc/ cells (32).
That study found that expression of neither cyclin D1, E, nor A
(expressed singly) could rescue the proliferation defect of
c-myc/ cells. We subsequently tested cell
lines ectopically expressing cyclin D1 or E for the rescue of
etoposide-induced apoptosis and found that, in contrast to cyclin A,
neither cyclin D1 nor E had any effect on either the extent or the
kinetics of the apoptotic response (Fig. 7F). None of the cyclins
tested (D1, E, or A) had an effect on the apoptotic response elicited
by cisplatin (data not shown). These results further confirm that the
apoptotic defect in c-myc/ cells affects
predominantly processes in G2 phase.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Although it has been known for some time that elevated c-Myc
expression can predispose cells to apoptosis (3, 12) and that antisense oligonucleotide-mediated reduction of c-Myc expression can in some cases partially protect against apoptosis (9, 22, 25,
50), evidence that c-Myc is functionally required in any one DNA
damage-induced apoptotic pathway has been lacking. We show here that
c-Myc is necessary for the activation of DNA damage-induced apoptosis
in G2 phase. c-myc+/+ cells treated
with etoposide, a drug that causes DNA damage primarily in the S phase,
accumulate in G2 and subsequently undergo apoptosis. c-myc/ cells are strongly defective in this
apoptotic response. In contrast, c-Myc is not required for apoptosis in
G1, since cisplatin, a drug that causes DNA damage
irrespective of cell cycle position, causes robust apoptosis in
c-myc/ cells. It is important to note that
while cisplatin elicits apoptosis both in G1 and
G2 in c-myc+/+ cells, in
c-myc/ cells apoptosis is restricted to the
G1 compartment. This result argues that the apoptotic
defect in c-myc/ cells is due to a failure
to either initiate or execute apoptosis rather than to a defect in the
accumulation of DNA damage. UV light elicited the same response at
cisplatin. Restoration of c-Myc expression in
c-myc/ cells completely rescued the
apoptotic defect, making it unlikely that the cells have accumulated
secondary mutations that affect apoptosis. Furthermore, independently
gene targeted c-myc/ clones displayed the
same apoptotic phenotype.
The G2 checkpoint that monitors the integrity of the genome
is operational in all cells (17), including tumor cells
that are defective in the p53-dependent G1 checkpoint
(24). Overexpression of wild-type p53 in
c-myc/ cells did not rescue the
G2 apoptotic defect. Although this is a negative result, it
was obtained in clonal cell lines stably overexpressing a
temperature-sensitive p53 protein, which was biologically active
because it accelerated G1 apoptosis in response to
cisplatin. The failure of p53 to rescue is not consistent with c-Myc
acting functionally upstream of p53 in the G2 apoptotic pathway. The
result is consistent with a model (11) in which c-Myc acts
downstream of p53 to sensitize the cell to apoptotic stimuli. It is
formally also possible that the G2 DNA damage-triggered apoptotic pathway defective in c-myc/ cells
does not involve p53.
We have identified cyclin A as one critical effector of c-Myc-dependent
G2 apoptosis: cyclin A levels were reduced in c-Myc knockout cells, and restoration of cyclin A expression significantly rescued apoptosis. In contrast, overexpression of cyclin A had no
effect whatsoever on the slow growth of
c-myc/ cells (32). This result
argues strongly that the apoptotic defect in
c-myc/ cells is not caused by the cell cycle
defects observed in these cells. Other observations are also consistent
with this interpretation. First, c-myc/
cells show an approximately equivalent lengthening of both
G1 and G2 phases (31), whereas the
apoptotic defect is confined to G2. This argues that slow
cell cycle progression per se is not the cause of the apoptotic defect.
Furthermore, the duration of the S phase, the period when the majority
of etoposide-elicited lesions are accumulated, is essentially identical
in c-myc/ and
c-myc+/+ cells (31). Second, the
kinetics of apoptosis in response to cisplatin in G1 are
very similar in c-myc+/+ and
c-myc/ cells, indicating that the major
pathways for the execution of apoptosis are likely to be intact in both
cell lines. Third, it takes approximately one cell cycle interval (18 h) for c-myc+/+ cells to accumulate in
G2 and approximately two additional cell cycle intervals
(36 h) for apoptosis to be virtually completed (50 to 80%). In
contrast, while c-myc/ cells arrest in
G2 within one cell cycle interval (50 h), incubation for up
to 192 h after the addition of drug (three additional cell cycle
intervals) results in minimal (<15%) apoptosis. Thus, the kinetics of
the G2 arrest and ensuing apoptosis are also not consistent with the slow growth rate of c-myc/ cells
being the primary cause of the observed apoptotic defect.
The activation of Cdk kinases has been temporally associated with
apoptosis (2, 34), and inhibition of Cdk activation has
been shown to exert an apoptosis-sparing effect (35, 49). We show here that aminopurvalanol, a highly selective and potent inhibitor of Cdk activity (5), blocks the induction of
apoptosis by etoposide but not cisplatin. Thus, aminopurvalanol exerts
the same effect on these responses as the loss of c-Myc, which we have
previously shown results in the downregulation of Cdk activity (32). However, since both aminopurvalanol and loss of
c-Myc affect the activity of both G1 and G2
kinases, we performed rescue experiments by ectopically expressing
individual cyclin genes in c-myc/ cells.
These studies clearly implicated cyclin A as the relevant downstream
effector of c-Myc: cyclin A significantly rescued etoposide-induced apoptosis, while cyclin E and cyclin D1 were without effect. We were
unable, in spite of repeated attempts, to isolate cell lines overexpressing cyclin B. It is important to note that none of the
overexpressed cyclins rescued the proliferation defect of c-myc/ cells (32), thus
providing further evidence that the apoptosis defect observed in these
cells is not due to their slow growth.
In most (18), but not all (14) cases, the Cdk
activity implicated in apoptotic processes has been associated with
cyclin A. The fact that overexpression of cyclin A alone can in some cases drive cells into apoptosis (21) is consistent with
an important role in apoptotic processes. It should be noted that the
c-myc/ cell lines that we have engineered to
express ectopic cyclin A grow normally and do not display any signs of
apoptosis in the absence of drug treatment. Cyclin A thus joins
p19ARF1 (57) as a putative c-Myc
target gene that is specific for mediating proapoptotic functions.
Although a positive effect of c-Myc overexpression on cyclin A
expression was noted some time ago (23), it is unlikely that the cyclin A gene is a direct transcriptional target of c-Myc: the
promoter does not contain c-Myc binding sites, and the major regulator
responsible for cell cycle dependent expression has been identified as
E2F (48). The cyclin A promoter has also been shown to be
actively repressed by E2F-Rb complexes in G0 and early
G1 (41). These observations provide a good
explanation for the observed reduction of cyclin A expression in
c-myc/ cells, which display a significant
defect in the expression of the E2F-1, -2, and -3 genes, as well as
persistence of unphosphorylated Rb in late G1
(32).
The expression of cyclin A and associated Cdk activity in response to DNA damage displayed the characteristics of a DNA damage-inducible response that occurred independently of the changes in cell cycle distribution. Etoposide caused a rapid induction of cyclin A that somewhat preceded the progression into S and G2/M (compare Fig. 3A and 7A). More importantly, cisplatin (Fig. 7A) and UV light (data not shown) caused a robust induction of cyclin A in spite of the fact that the cell cycle distribution of the cultures did not change after treatment (compare Fig. 4A and C and Fig. 7A). Cyclin A induction has also been reported to accompany apoptosis in postmitotic cardiomyocytes (1), and transfection of a dominant-defective Cdk2 protected against apoptosis in this cell type. Etoposide-stimulated cyclin A-Cdk activity in c-myc+/+ cells decayed rapidly and was below basal levels at the time of maximum apoptosis. This contrasts with apoptosis induced by growth or survival factor deprivation, which typically occurs in G1, and where the induction of cyclin A/Cdk activity has been shown to be a late event (18, 26). The expression of c-Myc was not affected by DNA damage (data not shown), but its presence was clearly required for the normal induction of cyclin A. There are examples in other cell types where cytotoxic drugs can elicit an induction of c-Myc expression (56).
Although apoptosis in response to etoposide occurred at times of maximum G2 content of the cultures, the resolution of the flow cytometry data is not sufficient to rule out that some apoptosis was also taking place in the S phase. This possibility is also raised by the apparent involvement of cyclin A-Cdk2 complexes, which are known to be active during the S phase. Nevertheless, the kinetics of cell cycle progression and apoptosis in etoposide-treated cultures indicate that the majority of apoptosis was occurring only after most of the cells reached late S or G2.
In summary, we show here that the loss of c-Myc expression results in an impairment of DNA damage-initiated apoptosis in the G2 phase of the cell cycle. We propose a model wherein DNA damage-induced cyclin A-Cdk2 activity is required to initiate the apoptotic process. Apoptosis in G1 does not appear to require c-Myc and does not seem to be influenced by G1 cyclin-Cdk complexes in the cell type studied here. The kinetics of the G2 response indicate that the induction of cyclin A and the concomitant activation of Cdk2 represent an early step during commitment to apoptosis. Although c-Myc in not absolutely required for the induction of cyclin A, in its absence the magnitude of this response is significantly dampened. The involvement of c-Myc in these processes sheds new light on the mechanisms by which this important oncogene acts to sensitize cells to a wide variety of apoptotic stimuli.
| |
ACKNOWLEDGMENTS |
|---|
We thank P. Schultz and Y.-T. Chang for providing aminopurvalanol.
This work was supported by NIH grant R01-GM41690 to J.M.S. and NSF grant MCB-9630362 to J.H.W. A.J.O. was supported in part by a postdoctoral fellowship from the Ministerio Education y Cultura de Espana.
| |
FOOTNOTES |
|---|
* Corresponding author. Mailing address: Department of Molecular Biology, Cell Biology, and Biochemistry, Box G-J223, Brown University, Providence, RI 02912. Phone: (401) 863-9654. Fax: (401) 863-9653. E-mail: john_sedivy{at}brown.edu.
Present address: Second Department of Medicine, Tokyo Medical and
Dental University, Tokyo 113, Japan.
Present address: Area de Fisiologia, Facultad de Medicina,
Universidad de Oviedo, Oviedo 33006, Spain.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Molecular and Cellular Biology, August 2001, p. 4929-4937, Vol. 21, No. 15
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.15.4929-4937.2001
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