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Previous Article | Next Article 
Molecular and Cellular Biology, June 2001, p. 3684-3691, Vol. 21, No. 11
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.11.3684-3691.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Cisplatin Induces the Proapoptotic Conformation of
Bak in a 
MEKK1-Dependent Manner
Aleksandra
Mandic,1
Kristina
Viktorsson,1
Magnus
Molin,2
Göran
Akusjärvi,2
Hidetaka
Eguchi,3
Shin-Ichi
Hayashi,3
Masakazu
Toi,4
Johan
Hansson,1
Stig
Linder,1 and
Maria C.
Shoshan1,*
Radiumhemmet's Research Laboratory, Cancer Center
Karolinska, Department of Oncology-Pathology, Karolinska Institute,
S-171 76 Stockholm,1 and Department of
Medical Biochemistry and Microbiology, BMC, Uppsala University,
S-751 23 Uppsala,2 Sweden, and Saitama
Cancer Center Research Institute, Kita-adachigun, Saitama
362-0806,3 and Tokyo Metropolitan
Hospital, Bunkyo-ku, Tokyo,4 Japan
Received 20 September 2000/Returned for modification 29 November
2000/Accepted 22 February 2001
 |
ABSTRACT |
In a panel of four human melanoma cell lines, equitoxic doses of
cisplatin induced the proapoptotic conformation of the Bcl-2 family
protein Bak prior to the execution phase of apoptosis. Because
cisplatin-induced modulation of the related Bax protein was seen in
only one cell line, a degree of specificity in the signal to Bak is
indicated. Little is known about upstream regulation of Bak activity.
In this study, we examined whether the apoptosis-specific pathway
mediated by a kinase fragment of MEKK1 (
MEKK1) is involved in the
observed Bak modulation. We report that expression of a kinase-inactive
fragment of MEKK1 (dominant negative MEKK [dnMEKK]) efficiently
blocked cisplatin-induced modulation of Bak and cytochrome c release and consequently also reduced DEVDase activation
and nuclear fragmentation. Accordingly, expression of a kinase-active MEKK1 fragment (dominant positive MEKK) was sufficient to induce modulation of Bak in three cell lines and to induce apoptosis in two of
these. dnMEKK did not block cisplatin-induced c-Jun N-terminal kinase
(JNK) activation, in agreement with a specifically proapoptotic role
for the MEKK1 pathway. Finally, we show that reduction of Bak
expression by antisense Bak reduced cisplatin-induced loss of
mitochondrial integrity and caspase cleavage activity in breast cancer
cell lines. In summary, we have identified Bak as a cisplatin-regulated
component downstream in a proapoptotic, JNK-independent MEKK1 pathway.
| |
INTRODUCTION |
Increased mitochondrial permeability
is a crucial event in many types of drug-induced apoptosis and leads to
release of a number of apoptosis-related proteins, e.g., AIF, DIABLO,
and cytochrome c, from the mitochondrial intermembrane
space. Cytochrome c is a component of the apoptosome complex
which activates procaspase 9, which in turn activates the
effector caspases, notably, caspase 3 and caspase 7 (DEVDases)
(20).
Regulation of mitochondrial permeability during apoptosis is complex,
but key roles are played by Bak and Bax, two proapoptotic Bcl-2 family
members, which contribute to mitochondrial pore formation, allowing
release of cytochrome c (16, 25). In
staurosporine-induced apoptosis, this function of Bak and Bax was
recently shown to involve conformational changes in both proteins
rather than an increase in expression (5, 10). Similar
results have been obtained with other drugs and with Bax mutants
(10, 18). However, little is known about how the upstream
apoptotic signal(s) is relayed to these proteins.
The stress-activated protein kinase (SAPK) pathways have long been of
interest in apoptosis research. The roles of the c-Jun N-terminal
kinase (JNK)/SAPK isoforms are, however, not yet clear, since they are
reported to have survival-promoting functions as well as proapoptotic
ones, depending on the signaling context (3). Activators
upstream of JNK/SAPK include ASK1, MEKK1, and Tpl-2 (3).
Apoptosis induced by such divergent agents as genotoxins, anti-Fas
ligation, and loss of cell adherence (anoikis) all involve activation
of JNK/SAPK and proteolytic cleavage of MEKK1, leading to a
constitutively active kinase fragment (MEKK1) (1, 4, 27).
A model for the roles of full-length and cleaved MEKK1 has been
proposed (1, 27). According to this model, activated full-length MEKK1 may be part of a survival pathway involving JNK/SAPK,
whereas MEKK1 is involved in amplification of the apoptotic signal.
Overexpression of MEKK1 is reported to be lethal to several cell
types, and it can also sensitize cells to genotoxic damage, e.g., by
cisplatin (13, 27, 28). Although the model indicates interaction of MEKK1 with molecules involved in the control of apoptosis (27), no downstream components of the MEKK1
pathway have been identified.
Cisplatin is a widely used DNA-damaging anticancer drug which activates
JNK (23, 30, 31) and induces MEKK1 cleavage and caspase
activation (27). As with most chemotherapeutic drugs, tumors may show inherent or acquired resistance against cisplatin. The
clinical problem of response variability has engendered research and
knowledge of a number of resistance mechanisms, e.g., increased DNA
repair (21). However, considering the reactivity of
cisplatin and the complexity of the cellular responses to DNA damage,
cisplatin-induced apoptotic signaling likely involves several pathways.
Because of its suggested role in caspase activation, in this study we
investigated the proapoptotic MEKK1 pathway and the involvement of
Bak and Bax in cisplatin-induced apoptosis in human metastatic melanoma cells.
| |
MATERIALS AND METHODS |
Cells and cisplatin treatment.
We screened a panel of four
human metastatic melanoma cell lines (224, FM55, AA, and DFW) for
cisplatin sensitivity by assessing nuclear fragmentation after 24 h of treatment with different doses (Table
1). All four cell lines had similar
levels of Bcl-2 protein as determined by Western blotting. Only the 224 cell line expresses mutant p53. Being the most sensitive cell line, 224 cells were chosen for experiments involving blocking of
cisplatin-induced apoptosis. The cisplatin concentration used was 20 µM. MCF-7 breast carcinoma cells and two sublines stably expressing
antisense Bak (6) were also used for assessment of the
role of Bak in cisplatin-induced apoptosis. All cell lines were
maintained at 37°C in 5% CO2 in RPMI medium supplemented
with fetal calf serum (10%), L-glutamate, penicillin, and
streptomycin.
Assessment of apoptosis.
Cells were harvested with cell
dissociation solution (Sigma Aldrich), resuspended in 50 to 100 µl of
hypotonic salt solution with 30 mM glycerol, and smeared on glass
slides. Air-dried smears were fixed in acetone-methanol (2:1) for 5 min
and then covered with ethidium bromide (5 ng/ml in distilled water) for
5 min. After being rinsed in tap water, stained cells were examined by UV microscopy. At least 100 cells per sample were counted, and the
percentage of cells with condensed and fragmented nuclei was assessed
in each sample.
In addition to cytochrome c release and DNA-dependent
protein kinase (DNA-PK) cleavage (see Results), apoptosis was also
assessed by quantitation of DEVDase activity against the Ac-DEVD-AMC
substrate (CaspACE assay; Promega) and by a similar caspase 9 assay
using Ac-LEHD-AMC (Enzyme Systems Products Inc.) as the substrate.
Harvested cells were centrifuged, washed in ice-cold phosphate-buffered saline (PBS), and resuspended in lysis buffer (25 mM HEPES [pH 7.5],
5 mM MgCl2, 5 mM EDTA, 5 mM dithiothreitol, 2 mM
phenylmethylsulfonyl fluoride, 10 µg each of pepstatin and leupeptin
per ml). Cells were lysed by three cycles of freeze-thawing in liquid
nitrogen. Lysates were centrifuged (16,000 × g; 20 min), and supernatant fractions were collected. Caspase activity was
assayed according to manufacturer's instructions. The fluorescence
produced upon cleavage of the labeled substrate is proportional to the
caspase activity in the sample. Addition of DEVD or LEHD inhibitor to all samples with caspase activity abrogated the whole signal.
Inducible expression of dnMEKK and dpMEKK.
The cDNA of a
dominant negative mutant of MEKK1 (dnMEKK; 37-kDa kinase fragment with
a K432M point mutation) or a dominant positive MEKK1 mutant (dpMEKK;
37-kDa active kinase fragment) (both generously provided by T. Maniatis) were cloned into a recombinant adenovirus vector for use in
an inducible adenovirus gene transfer system (17),
consisting of two recombinant adenovirus vectors, one encoding a
transactivating protein (adeno-rtTA) and another encoding the protein
of interest. The constitutively expressed activator protein rtTA
requires an inducer (doxycycline [DOX], a tetracycline derivative) to
undergo a conformational change which allows it to bind to and activate
the promoter of the gene of interest.
Cell (106/dish) were seeded and after 6 h infected
with adeno-dnMEKK and adeno-rtTA constructs (5 to 10 PFU of each per
cell). After 20 h in the presence of 1 µM DOX, cells were either
postincubated with freshly added DOX or treated with cisplatin in the
presence of freshly added DOX. Western blotting confirmed dnMEKK
expression. Because DOX at 5 µM or more was initially found to induce
apoptosis on its own, in accordance with similar effects on several
types of cells, e.g., osteosarcoma (7), 1 µM DOX was
subsequently included in all samples. The procedure for induction of
dpMEKK expression was identical to that for induction of dnMEKK.
Western blot analysis.
Cell extract proteins (20 µg) were
resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis
and transferred onto a polyvinylidene difluoride membrane for Western
blotting. The following antibodies were used: anti-phospho-JNK
(Biolabs), anti-MEKK1 (Santa Cruz Biotechnology), anti-DNA-PK
(Labvision), anti-cytochrome c (PharMingen), anti-cytochrome
c oxidase subunit IV (Molecular Probes), anti-caspase 9 (Oncogene Research Products), and antitubulin (Sigma Aldrich). Tubulin
was used as an internal standard for loading.
Cytochrome c release.
Cells (224 cell line) were
treated with 20 µM cisplatin for 20 h in the presence or absence
of dnMEKK. After harvesting (107 cells per sample), cells
were centrifuged (600 × g, 5 min, 4°C), washed in
ice-cold PBS, and resuspended in 3 volumes of isolation buffer (20 mM
HEPES-KOH [pH 7.5], 250 mM sucrose, 10 mM KCl, 1.5 mM
MgCl2, 1 mM each EDTA, EGTA, and dithiothreitol, 2 mM
phenylmethylsulfonyl fluoride, 20 µg of leupeptin per ml, 10 µg of
aprotinin and pepstatin per ml). After chilling on ice for 15 min,
cells were disrupted by 40 strokes in a glass homogenizer. Homogenates
were centrifuged at 700 × g and thereafter at
2,500 × g for 10 min at 4°C. After centrifugation at
12,000 × g (30 min, 4°C), cytosolic proteins (25 µg) in supernatant fractions were analyzed by Western blotting for
cytochrome c. Possible mitochondrial contamination in the same samples was monitored using an antibody against mitochondrial cytochrome c oxidase subunit IV.
Flow cytometric analysis of Bak- and Bax-associated IFL.
Upon induction of apoptosis, the proapoptotic Bax and Bak proteins
undergo conformational changes which expose otherwise inaccessible N-terminal epitopes (10, 11). In the present study, we
have used the same two antibodies that were shown to specifically
recognize these epitopes. Using a fluorescein isothiocyanate
(FITC)-conjugated secondary antibody, the increases in accessibility of
these epitopes can be monitored by flow cytometry
(fluorescence-activated cell sorting [FACS] analysis)
(10). At specific time points after cisplatin treatment,
cells were detached using cell dissociation solution (Sigma). Cells
were then fixed in paraformaldehyde (0.25%, 5 min), washed three times
in PBS, and incubated for 30 min with a mouse monoclonal antibody
against amino acids 1 to 52 of Bak (AM03, clone TC100; Oncogene
Research Products) or against amino acids 12 to 24 of Bax (clone 6A7;
PharMingen). Antibodies were diluted 1:50 in PBS containing digitonin
(100 µg/ml). After three washes in PBS, cells were incubated with
FITC-labeled anti-mouse antibody for 30 min, washed twice in PBS, and
resuspended in PBS. Negative controls using an irrelevant primary
antibody (rabbit anti-MEKK1) were also prepared. Cells (10,000/sample)
were analyzed on a FACSCalibur flow cytometer, using Cell Quest
software. To quantitate the results, cell debris was first excluded
from the analysis by electronic gating. The median fluorescence of the irrelevant antibody sample (fI) was subtracted from the median Bak/Bax-associated immuno fluorescence (IFL) in cells with fluorescence above fI. Data are presented as fold increase in IFL from control levels.
| |
RESULTS |
Cisplatin induces the proapoptotic conformation of Bak but
not Bax in the melanoma cell line 224.
The human melanoma cell
line 224 is sensitive to cisplatin (50% lethal dose
[LD50], 20 µM [Table 1]), which induces apoptosis, as
seen by nuclear fragmentation as well as cytochrome c
release, activation of DEVDases (caspases 3 and 7, which have similar
substrate specificities) and caspase 9, and by DNA-PK cleavage (see below).
In vivo, cytochrome c release is promoted by the
proapoptotic Bcl-2 family proteins Bak and Bax (25). To
examine proapoptotic conformational changes in Bak and Bax, we
incubated control and cisplatin-treated cells, in the presence of
digitonin, with monoclonal antibodies recognizing the N-terminal
epitopes of Bak and Bax. An FITC-conjugated secondary antibody allowed
detection of bound anti-Bak/Bax antibodies by flow cytometry. A shift
to the right in the resulting graph or histogram indicates an increase
in Bak/Bax-associated IFL.
With this method, we show for the first time that cisplatin induces an
increase in the proapoptotic conformation of Bak, as seen in 224 cells
treated with 20 µM cisplatin for 16 h (Fig. 1A). Similar shifts were seen also at 14 and 18 h (not shown). By contrast, cisplatin treatment did not
lead to Bax modulation at 16 h (Fig. 1B). Staurosporine treatment
(1 µM; 5 h) did lead to Bax modulation (Fig. 1C), showing that
this effect was not constitutively abrogated in 224 cells. Western
blotting confirmed that Bak protein levels were similar in control and
cisplatin-treated cells (Fig. 1D). Approximately equitoxic doses of
cisplatin were found to induce Bak modulation also in three other human
melanoma cell lines, whereas Bax modulation was not a general
feature, being seen only in FM55 cells (Table 1).
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FIG. 1.
Cisplatin-induced modulation of Bak but not Bax. Human
melanoma 224 cells were treated with cisplatin (20 µM, 16 h) or
staurosporine (1 µM, 5 h), as indicated, before samples were
prepared for FACS analysis of Bak or Bax-associated IFL. Control cells,
gray peak; treated cells, black line. (A) Bak-associated IFL after
cisplatin treatment; (B) Bax-associated IFL after cisplatin treatment;
(C) Bax-associated IFL after staurosporine treatment; (D) Western blot
showing Bak protein levels in control cells and after 16 h of
cisplatin (CISPL) treatment. Tubulin ( -TUB) was used as an internal
loading control. Ig2a, immunoglobulin 2a.
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dnMEKK blocks cisplatin-induced apoptosis and cytochrome
c release but not JNK activation.
Since Bak and Bax
functions ultimately lead to caspase activation, and since an
apoptosis-specific MEKK1 pathway is implied in caspase activation
(1, 27, 28), we examined the effects of kinase-active and
-inactive MEKK1 mutants on Bak/Bax modulation, caspase activation,
and nuclear fragmentation in cisplatin-induced apoptosis. An adenovirus
vector system (17) was used to inducibly express dpMEKK,
consisting of the kinase domain of MEKK1, and dnMEKK, carrying an
inactivating point mutation (K432M).
In 224 cells preinduced to express dnMEKK, cisplatin-induced nuclear
fragmentation was significantly decreased (Fig.
2). Similarly, dnMEKK inhibited nuclear
fragmentation by 50 to 75% in the other three cell lines (not shown).
Expression of dnMEKK did not per se cause nuclear fragmentation, nor
did it activate caspases or lead to DNA-PK cleavage (see below).
Infection with adeno-rtTA only and subsequent DOX treatment did not
block nuclear fragmentation, showing that blocking was not an
unspecific adenovirus-mediated effect.
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FIG. 2.
Effect of dnMEKK on cisplatin-induced nuclear
fragmentation. Cells were treated with 20 µM cisplatin in the
presence or absence of adeno-dnMEKK. Expression of dnMEKK was induced
with DOX at 20 h before cisplatin treatment. (A) Nuclear
fragmentation in 224 cells after 16 and 24 h of cisplatin
treatment; (B) Western blot showing expression of dnMEKK (37 kDa) in
the same samples. A faint endogenous band is seen also in the extracts
from cells which were not infected and is thus not due to leakage. The
experiment was repeated with similar results.
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Cisplatin-induced release of cytochrome c at 20 h was
abrogated in 224 cells expressing dnMEKK (Fig.
3A). To confirm that dnMEKK blocks
upstream of cytochrome c release, we used betulinic acid
(BA) as an apoptosis-inducing agent. BA is reported to have a direct
effect on mitochondria, leading to mitochondrial permeability transition followed by cytochrome c release, caspase
activation, and nuclear fragmentation (8). In agreement
with dnMEKK blocking an event upstream of cytochrome c
release, dnMEKK did not block BA-induced apoptosis (not shown), nor did
it block BA-induced DEVDase activation seen at 16 and 24 h (Fig.
3B).
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FIG. 3.
dnMEKK blocks upstream of cytochrome c
release without blocking JNK activation. 224 cells were treated with 20 µM cisplatin or 15 µg of BA per ml in the presence or absence of
adeno-dnMEKK. Expression of dnMEKK was induced with DOX at 20 h
before drug treatment. (A) Western blot for cytochrome c
(CYT. C) in cytosolic extracts at 20 h after addition of cisplatin
(CISPL). The membrane was also probed with an antibody against
mitochondrial cytochrome oxidase subunit IV to ensure lack of
mitochondrial contamination of the extracts (not shown). -TUB.,
tubulin. (B) BA (BET. ACID)-induced DEVDase activity measured in
extracts (50 µg) of cells at the indicated time points. Results are
shown as fold activation relative to control cells. (C)
Cisplatin-induced activation of JNK1 and -2, as seen by phosphorylation
at the indicated time points in the presence or absence of dnMEKK, was
assessed by Western blotting using an antibody specific for
phosphorylated JNK1 and -2 (P-JNK1 and -2). Tubulin was used as an
internal loading control.
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Because sustained JNK activation between 3 and 12 h of treatment
is implied in cisplatin-induced apoptosis (23), JNK
activity at 4, 7, and 16 h was assessed with an antibody specific
for phosphorylated JNK1 and JNK2. Cisplatin-induced JNK1 and -2 phosphorylation at these time points and expression of dnMEKK did not
block this effect (Fig. 3C).
Time course experiments were carried out to determine when expression
of dnMEKK was required to block apoptosis. At 2 h of DOX
treatment, there was no expression of the mutant, while some expression
was seen after 4 h (Fig. 4A). When
DOX was added at 2 h after cisplatin, apoptosis was blocked to the
same extent as in cells which expressed dnMEKK already at the time of
cisplatin addition (Fig. 4B). Even later addition of DOX also afforded
some protection against apoptosis (Fig. 4B). This experiment shows that
dnMEKK inhibition of apoptosis occurs at a stage later than 4 to 6 h after addition of cisplatin.
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FIG. 4.
Delayed induction of dnMEKK expression blocks nuclear
fragmentation. (A) Western blot showing 37-kDa dnMEKK expression at
different time points after DOX addition. (B) 224 cells infected with
adeno-dnMEKK were induced to express dnMEKK by addition of DOX at the
indicated time points, which are relative to the time of cisplatin
addition (20 µM) at 0 h. Nuclear fragmentation levels were
assessed at 24 h and compared to fragmentation induced in the
absence of adeno-dnMEKK.
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dnMEKK blocks caspase activation.
If dnMEKK blocks cytochrome
c release, it should also block caspase activation.
Cisplatin-induced DEVDase activity in 224 cells exhibited a 15-fold
increase at 24 h (Fig. 5).
Expression of dnMEKK partly inhibited this activation (Fig. 5).
Blocking of DEVDase activity was confirmed in the same samples by a
reduction in cisplatin-induced cleavage of DNA-PK, a nuclear caspase 3 substrate (Fig. 5).
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FIG. 5.
dnMEKK blocks cisplatin-induced DEVDase activity. 224 cells were treated with 20 µM cisplatin for the indicated time
periods, in the presence or absence of adeno-dnMEKK. Expression of
dnMEKK was induced with DOX at 20 h before cisplatin treatment.
After harvest, cells were aliquoted for apoptosis and DEVDase assays
and for western blotting. Apoptosis levels, seen as nuclear
fragmentation, are shown above the relevant bars. Filled bars, DEVDase
activity against a synthetic substrate (Ac-DEVD-AMC), measured in cell
extracts at the indicated time points. Results are shown as induction
of activity relative to that in control samples. Empty bars, cleavage
of DNA-PK, as assessed by densitometric scanning of the 160-kDa
proteolytic fragment on Western blot films. Results are shown as
fragment levels relative to that in control samples.
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Cell extracts made at several time points after cisplatin
treatment were then assayed for DEVDase and caspase 9/LEHDase
activity in the presence and absence of dnMEKK (Fig.
6). These experiments confirmed
that a major increase in DEVDase activity occurred at 13 h
and beyond and that this increase was partly inhibitable by dnMEKK
(Fig. 6A). An enzymatic assay of caspase 9 seen as LEHDase activity
showed 1.6- and 3-fold activation at 13 and 19 h, respectively (Fig. 6B). This caspase 9/LEHDase activity was furthermore inhibited in
the presence of dnMEKK (Fig. 6B). To confirm this result, we performed
Western blotting of caspase 9. The 35-kDa active cleavage fragment of
procaspase 9 appeared as a faint band at 13 to 16 h and was easily
observed at 19 h of cisplatin treatment (Fig. 6C). In accordance
with the enzymatic assay, dnMEKK was found to reduce the fragment
signal at all three time points (Fig. 6C). In attempts to examine
DEVDase cleavage fragments in these cells by Western blotting, we
consistently failed to detect any with a range of commercially
available antibodies against caspases 3 and 7.
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FIG. 6.
Kinetics of cisplatin-induced DEVDase and caspase
9/ LEHDase activities. 224 cells were treated with 20 µM
cisplatin for the indicated time periods in the absence or presence of
adeno-dnMEKK. Expression of dnMEKK was induced with DOX at 20 h
before cisplatin treatment. Empty bars, cisplatin only; filled bars,
cisplatin treatment in the presence of dnMEKK. (A) DEVDase activity on
the synthetic substrate Ac-DEVD-AMC was assessed twice for each
duplicate sample. The inhibitor DEVD-CHO reduced all activity to
background in all parallel samples. Results are shown as fold increase
in activity in untreated (control [C]) cells. (B) Caspase 9/LEHDase
activity on the synthetic substrate Ac-LEHD-AMC. The inhibitor LEHD-CHO
reduced all activity to background in all parallel samples. (C) Cell
extracts (30 µg/lane) were analyzed by Western blotting of caspase 9. The 35-kDa cleavage fragment represents the active form. -TUB.,
tubulin; CISPL, cisplatin.
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dnMEKK blocks cisplatin-induced Bak modulation.
In accordance
with a blocking effect upstream of cytochrome c release and
caspase 9 activation in 224 cells, dnMEKK was found to block
cisplatin-induced Bak modulation in 224 and AA cells (Fig.
7). dnMEKK did not block
staurosporine-induced Bak modulation (not shown), suggesting a degree
of specificity for this pathway.
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FIG. 7.
dnMEKK blocks cisplatin-induced modulation of Bak. (A)
224 cells were treated with 20 µM cisplatin for 16 h in the
absence or presence of adeno-dnMEKK. Expression of dnMEKK was induced
with DOX at 20 h before cisplatin treatment. Shown are overlaid
FACS graphs indicating Bak-associated IFL. Gray peak, control cells;
dark lines, cisplatin treatment in the presence or absence of dnMEKK,
as indicated. (B) Quantitation of cisplatin-induced Bak modulation in
the presence or absence of dnMEKK in 224 and AA cell lines. Cells were
treated with LD50s of cisplatin (CISPL.). Results are shown
as fold increase in median IFL signal relative to controls.
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Induction of Bak modulation and apoptosis by dpMEKK.
The
constitutively active kinase fragment of MEKK1 has been shown to be
important for amplification of the apoptotic signal (1, 27,
28). Using the same protocol as with dnMEKK, cells were infected
with an adenovirus vector expressing the constitutively active 37-kDa
kinase fragment of MEKK1 (dpMEKK). At 24 h postinduction, dpMEKK
had induced Bak modulation in AA, FM55, and DFW cells but not in 224 cells (Fig. 8A). dpMEKK did not elicit
apoptosis in 224 or DFW cells, while in FM55 and AA cells it induced 19 and 13% apoptosis, respectively (Fig. 8B).
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FIG. 8.
Induction of Bak modulation and apoptosis by dpMEKK. (A)
Cells were infected with adeno-dpMEKK, and Bak-associated IFL was
assessed at 24 h after addition of DOX. For comparison, Bak
modulation at 16 h induced by LD50s of cisplatin
(CISPL) is also shown. Results are shown as fold increase in median IFL
signal compared to controls. (B) Cells were infected with adeno-dpMEKK,
and nuclear fragmentation was assessed at 24 h after addition of
DOX. Background levels in control cells varied but did not exceed
6%.
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Modulation of Bax by cisplatin and dpMEKK.
In three out of
four cell lines, neither cisplatin treatment for 16 h nor dpMEKK
could induce Bax modulation. FM55 cells were thus unique in that they
were the only cells to show Bax modulation by either treatment (Fig.
9). Staurosporine treatment of 224 and AA
cells showed that Bax modulation is not constitutively abrogated in
these cell lines (Fig. 9).
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FIG. 9.
Induction of Bax modulation. Bax-associated IFL was
assessed at 16 h after cisplatin (CISPL) addition or at 24 h
after addition of DOX to induce dpMEKK expression in
adeno-dpMEKK-infected cells. The effect of staurosporine (STSN; 1 µM,
5 h) on Bax modulation in 224, AA, and FM55 cells is also shown.
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Antisense Bak reduces cisplatin-induced apoptotic responses.
Since dnMEKK blocked cisplatin-induced Bak modulation as well as
apoptosis, we also wished to examine the effect of cisplatin in cells
expressing antisense Bak. We therefore compared the effects of
cisplatin on parental MCF-7 breast carcinoma cells and two sublines
stably expressing antisense Bak (6). Because MCF-7 cells
lack caspase 3 expression and thus may have aberrant DNA fragmentation,
apoptosis was assessed using an antibody, M30, specifically recognizing
caspase-cleaved fragments of cytokeratin 18, which can be cleaved by
activated caspases other than caspase 3 (2, 6). The M30
antibody is used for immunohistochemical detection of apoptosis or, as
we have done here, in an enzyme-linked immunosorbent assay (ELISA)
system (Peviva AB, Stockholm, Sweden) (14). We found that
at 21 h after addition of 20 µM cisplatin, caspase cleavage of
cytokeratin 18 was significantly reduced in the cell lines expressing
antisense Bak compared to parental cells (Fig.
10A). Cisplatin treatment also induced
mitochondrial depolarization, and this effect was blocked in cells
expressing antisense Bak but not in parental cells (Fig. 10B).
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FIG. 10.
Reduced apoptotic responses in cells expressing
antisense Bak. Parental MCF-7 and two subclones with stable expression
of antisense Bak were treated with 20 µM cisplatin for 21 h. (A)
Caspase activity was assessed by ELISA-based quantitation of the
caspase-cleaved fragment of cytokeratin 18 in cell lysates as
instructed by the manufacturer (Apoptosense ELISA kit; Peviva AB).
Results are shown as fold increase in the levels of fragment
specifically recognized by the antibody M30. (B) The mitochondrial
transmembrane potential was determined in duplicate samples as
retention of tetramethylrhodamine ethyl ester (TMRE; Molecular Probes
Inc.), a cationic, lipophilic fluorochrome dye that accumulates in the
negatively charged mitochondrial matrix. Depolarization of
mitochondria, as seen during apoptosis, is quantitated as loss of TMRE
fluorescent signal assessed by flow cytometry. Results are shown as
fold increase in the fraction of cells with depolarized mitochondria,
i.e., cells showing a median TMRE signal less than 5% of the median
signal in controls. AS #8 and AS #9 are clones stably expressing
antisense Bak.
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DISCUSSION |
Bax and Bak, proapoptotic members of the Bcl-2 family, are
involved in cytochrome c release (16, 25), and
their proapoptotic function is dependent on a specific conformational
change (5, 10, 11, 18). This is the first report to show
that cisplatin-induced apoptosis involves induction of the apoptotic
conformation of Bak. Thus, in the four cell lines tested, approximately
equitoxic cisplatin treatment led to Bak modulation prior to the onset
of nuclear fragmentation. Bak modulation was seen both in the presence of mutant p53 (224 cells) and in the other three cell lines, expressing wild-type p53. In contrast to Bak, an effect on Bax was seen only in
one of the cell lines (FM55). This suggests a degree of specificity in
the signal to Bak.
A specific pathway involving a constitutively active MEKK1 fragment
(MEKK1) in preapoptotic cells has been implied in apoptosis induced
by genotoxic stress or by anti-Fas treatment (1, 4, 27),
likely by leading to caspase activation (24), although the
molecular details are not known. We have here used kinase-active and
-inactive MEKK1 fragment mutants to study the relationship(s) between
Bak and Bax, caspase activation, and the proapoptotic MEKK1 pathway in
cisplatin-induced apoptosis. We show that a 37-kDa kinase-inactive
MEKK1 mutant (dnMEKK) inhibits cisplatin-induced modulation of Bak,
cytochrome c release, caspase activation, and nuclear fragmentation.
Because cisplatin-induced Bak modulation and nuclear fragmentation were
affected by dnMEKK, we examined whether dpMEKK would have effects
similar to those of cisplatin. First, we found that the dpMEKK signal
is potentially sufficient to induce apoptosis. Thus, in AA and FM55
cells, dpMEKK induced some apoptosis; this was higher in FM55 cells, in
which dpMEKK modulated both Bak and Bax. Although dpMEKK has been shown
to inhibit growth in a range of cell lines in a clonogenic assay over 2 weeks (24), this is the first study to show an actual
ability to induce apoptosis within 24 h. Second, we found that,
like cisplatin, dpMEKK expression may be sufficient to induce Bak
modulation, as seen in the AA, FM55, and DFW cell lines.
The exceptions to these findings suggest that in some cell lines, Bak
modulation and/or its effects require a signal in addition to that
provided by dpMEKK and that cisplatin likely induces such a signal.
This may explain the resistance of 224 cells to dpMEKK-induced responses. The weak apoptotic response of DFW cells to dpMEKK-induced Bak modulation may in turn be explained by the recent finding that some
metastatic melanomas have lost expression of Apaf-1 by gene
inactivation due to methylation (26). Because of the role
of Apaf-1 in caspase activation downstream of mitochondrial events,
reduced Apaf-1 levels will block caspase activation but not
mitochondrial events such as Bak modulation.
The existence of additional cisplatin-induced signals, other than via
MEKK1, were indicated also by the findings that dnMEKK very
efficiently blocked Bak modulation and cytochrome c release in 224 cells, whereas DEVDase activation and nuclear fragmentation were
reduced only by half. This suggests the presence of a Bak-independent, dnMEKK-insensitive DEVDase activation which should be cytochrome c independent. Another possibility is the existence of
different intracellular pools of caspase 3 with different activation
mechanisms, since it has been reported that the caspase 3 precursor has
both a cytosolic and a mitochondrial distribution, likely with
different modes of activation (12, 15, 32).
As cisplatin-induced apoptosis has been reported to require JNK
activation (23, 30), it is interesting that dnMEKK
inhibited apoptosis without inhibiting JNK activation. Apoptosis
inhibition was seen also when the inducer (DOX) was added later than
cisplatin. DOX treatment for approximately 4 h was required to
induce dnMEKK expression, which means that dnMEKK was not expressed at
time points when JNK was already activated. The blocking effect of dnMEKK in this system is thus independent at least of early JNK activation.
JNK activation by apoptosis-inducing agents is not necessarily MEKK1
dependent, as JNK activation by UV was not impaired in MEKK1-deficient
cells (29) and dnMEKK1 did not block JNK activation by
tumor necrosis factor alpha (27). Cisplatin-mediated JNK activation has been reported to be independent of SEK1
(19). If so, it is independent of the classical MEKK1
pathway and dnMEKK should not block. It is interesting to speculate
whether dnMEKK-insensitive JNK activation is responsible for
dnMEKK-insensitive, Bak-independent DEVDase activation.
In conclusion, we here demonstrate that cisplatin-induced apoptosis
involves induction of the apoptotic conformation of Bak, whereas a
similar modulation of Bax is not a general feature. In accordance with
a role for Bak in cisplatin-induced apoptosis, we also show that MCF-7
subclones stably expressing antisense Bak display a significantly
reduced apoptotic response to cisplatin compared to parental MCF-7
cells. Bak modulation and the subsequent cytochrome c
release and caspase 9 activation are all blocked by a kinase-negative
MEKK1 fragment (dnMEKK). Conversely, a kinase-active MEKK1 fragment
(dpMEKK) was able to induce Bak modulation and apoptosis. Our findings
thus connect an upstream kinase activity to mitochondrial events in the
execution phase of apoptosis.
| |
ACKNOWLEDGMENTS |
K.V. and A.M. contributed equally to this work.
We thank T. Maniatis for generously providing the plasmid constructs of
dn- and dpMEKK, and we gratefully acknowledge M. Varsanyi for
analyzing p53 status.
This work was funded by grants from the Swedish Cancer Society and by
Cancerföreningen Stockholm. K.V. was supported by a grant from
the Swedish Foundation for Strategic Research.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Radiumhemmet's
Research Laboratory, Cancer Center Karolinska, Department of
Oncology-Pathology, Karolinska Institute, S-171 76 Stockholm, Sweden.
Phone: 46 8 51 77 54 60. Fax: 46 8 33 90 31. E-mail:
mimmi.shoshan{at}onkpat.ki.se.
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Molecular and Cellular Biology, June 2001, p. 3684-3691, Vol. 21, No. 11
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.11.3684-3691.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
