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Molecular and Cellular Biology, September 1999, p. 5991-6002, Vol. 19, No. 9
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Inhibition of Mitogen-Activated Kinase Signaling
Sensitizes HeLa Cells to Fas Receptor-Mediated Apoptosis
Tim H.
Holmström,1,2,3
Stefanie E. F.
Tran,1,2,3
Victoria L.
Johnson,4
Natalie G.
Ahn,5
Sek C.
Chow,4 and
John E.
Eriksson1,*
Turku Centre for
Biotechnology1 and Turku Graduate School
of Biomedical Sciences,2 University of
Turku and Åbo Akademi University, FIN-20521
Turku,1 and Department of Biology, Åbo
Akademi University, BioCity, FIN-20520 Turku,3
Finland; Centre for Mechanism of Human Toxicity, University of
Leicester, Leicester LE1 9HN, United
Kingdom4; and Howard Hughes Medical
Institute, Department of Chemistry and Biochemistry, University of
Colorado, Boulder, Colorado 803095
Received 30 November 1998/Returned for modification 28 January
1999/Accepted 26 May 1999
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ABSTRACT |
The Fas receptor (FasR) is an important physiological mediator of
apoptosis in various tissues and cells. However, there are also many
FasR-expressing cell types that are normally resistant to apoptotic
signaling through this receptor. The mitogen-activated protein kinase
(MAPK) signaling cascade has, apart from being a growth-stimulating
factor, lately received attention as an inhibitory factor in apoptosis.
In this study, we examined whether MAPK signaling could be involved in
protecting FasR-insensitive cells. To this end, we used different
approaches to inhibit MAPK signaling in HeLa cells, including treatment
with the MAPK kinase inhibitor PD 98059, serum withdrawal, and
expression of dominant-interfering MAPK kinase mutant protein. All of
these treatments were effective in sensitizing the cells to
FasR-induced apoptosis, demonstrating that MAPK indeed is involved in
the control of FasR responses. The MAPK-mediated control seemed to
occur at or upstream of caspase 8, the initiator caspase in apoptotic
FasR responses. Transfection with the constitutively active MAPK kinase
abrogated FasR-induced apoptosis also in the presence of cycloheximide,
indicating that the MAPK-generated suppression of FasR-mediated
apoptotic signaling is protein synthesis independent. In cells
insensitive to FasR-induced apoptosis, stimulation of the FasR with an
agonistic antibody resulted in significant MAPK activation, which was
inhibited by PD 98059. When different cell types were compared, the
FasR-mediated MAPK activation seemed proportional to the degree of FasR
insensitivity. These results suggest that the FasR insensitivity is
likely to be a consequence of FasR-induced MAPK activation, which in
turn interferes with caspase activation.
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INTRODUCTION |
Apoptosis, or programmed cell death,
is an essential mechanism for maintaining homeostasis in multicellular
organisms (76). There are a number of cell surface receptors
that act as physiological mediators of apoptosis, and activation of
these receptors rapidly triggers the apoptotic signaling and effector
machinery. One of these receptors is the Fas receptor (FasR)
(26), which belongs to the increasing number of receptors in
the tumor necrosis factor (TNF) receptor family (60). The
FasR is a 48-kDa transmembrane protein (79), the cytoplasmic
region of which contains a death domain essential for transducing the
apoptotic signal (27). Upon oligomerization, several
proteins with distinct functions (33), among them a
cytosolic adaptor protein, FADD (8), are recruited to the
cytoplasmic domain of the FasR. FADD in turn contains a death effector
domain, which binds to the cystein protease caspase 8 (6).
This binding results in cleavage and activation of caspase 8 (44). The activated caspase-8 triggers a strictly regulated
process, which involves activation of effector caspases, eventually
leading to the characteristic signs of apoptosis, such as disruption of
normal cell and nuclear morphology, followed by DNA fragmentation
(9, 55). However, oligomerization of the FasR also leads to
recruitment of proteins other than those directly associated with the
caspase effector machinery (55). Consequently, FasR
activation has effects other than activation of the caspase cascade.
Several recent studies have shown that stimulation of the FasR and TNF
receptor I (TNF R1) involves activation of multiple kinases (38,
65, 66), among them the c-Jun N-terminal kinase (78)
and mitogen-activated protein kinase (MAPK) (59). The
activated FasR also recruits an inhibitory phosphatase (55), and it has been suggested that the phosphatidylinositol 3-kinase (PI-3K) pathway may have a role in regulating the functions of the FasR
(25). Taken together, these studies indicate that
phosphorylation-based signaling is likely to be involved in some
aspects of FasR activation and regulation.
For continued growth and/or differentiation, vertebrate cells depend on
survival factors that activate signal transduction pathways suppressing
apoptosis. However, the identities and targets of these inhibitory
signals have not been ascertained. Defects in apoptotic and
antiapoptotic signaling pathways have been implicated in many
pathological conditions, including cancer (12). Transformed cells benefit from oncogenes as well as extracellular signals that
activate cell proliferation and/or inhibit apoptosis (11). One way for cytotoxic T cells to terminate cancer cells is by Fas
ligand (FasL) expression, as the majority of tumor cells do express the
FasR. A possible strategy for cancer cells to escape this type of
immune system-mediated apoptosis is inhibited FasR expression along
with increased expression of the FasL (22, 58, 62).
Alternatively, cells may modulate their FasR responses. There are
indeed studies indicating that FasR-expressing tumor cells may be
completely insensitive to FasR-induced apoptosis (52, 68).
Interestingly, some cell lines have even been shown to respond to FasR
stimuli by accelerated cell growth (1, 14, 29, 53). A
possible signaling candidate which could generate this kind of response
is the MAPK pathway. Activation of the MAPK pathway is often associated
with increased cell division rates (36) and could thereby
also protect tumor cells from apoptosis. Further evidence for this
assumption is provided by studies showing elevated MAPK activities in
tumor cells (35, 37, 50). The paradigm of MAPK as an
inhibitory pathway in regulation of apoptosis is supported by a number
of studies showing that activation of MAPK can protect against various
apoptotic stimuli in different cell types (9, 16, 77).
Furthermore, we have also shown that MAPK specifically protects Jurkat
T cells from FasR-induced apoptosis (23). There are several
studies indicating that MAPK is activated in a variety of cell types
upon TNF R1 stimulation (21, 59, 74). This kind of
activation could also apply for FasR signaling and lead to inhibited
FasR responsiveness.
In the present study, we examined the role of MAPK signaling in the
sensitivity of various tumor cell lines against FasR-induced apoptosis.
We were especially interested in possible FasR-mediated MAPK
activation and the extent to which inhibition of MAPK, by either
pharmacological or molecular biology-derived means, could sensitize the
cells to FasR-induced apoptosis. Our results show that MAPK inhibition
results in a dramatic increase in FasR sensitivity in the
FasR-insensitive cell lines. Furthermore, we show that the
MAPK-mediated suppression of FasR-induced apoptosis is protein synthesis independent and occurs at or upstream of the initiating caspase, caspase 8.
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MATERIALS AND METHODS |
Cell culture.
The mouse cell line NIH 3T3 and the human cell
lines HeLa, HL60, Jurkat, and U937 were obtained from the American Type
Cell Collection (Rockville, Md.). The HeLa and NIH 3T3 cell lines were cultured in Dulbecco modified Eagle medium (DMEM), whereas the HL60,
Jurkat, and U937 cell lines were cultured in RPMI 1640 in a humidified
incubator with 5% CO2 in air at 37°C. The cell culture medium was supplemented with 10% inactivated fetal calf serum (FCS), 2 mM L-glutamine, penicillin (100 U/ml), and streptomycin (100 µg/ml). HeLa, HL60, and Jurkat cells were incubated with an
agonistic anti-human FasR immunoglobulin M antibody (100 ng/ml; Kamiya
Biomedical Company, Thousand Oaks, Calif.), whereas NIH 3T3 cells were
incubated with an agonistic anti-mouse hamster FasR immunoglobulin G
antibody (clone Jo2; Pharmingen, San Diego, Calif.), for the indicated
time periods in the absence or presence of 30 µM PD 98059 (Calbiochem, La Jolla, Calif.). HeLa cells were also incubated with 10 nM cycloheximide (CHX; Sigma, St. Louis, Mo.) 10 nM LY294002
(Calbiochem), and 100 nM wortmannin (Calbiochem).
Analysis of nuclear morphology.
For confocal microscopy,
cells were cultured on coverslips and subjected to different treatments
as previously described (24). After incubation, cells were
fixed in 3% formaldehyde in phosphate-buffered saline (PBS), washed
once, preincubated with 50 µM RNase A (Sigma), and stained for 30 min
with propidium iodide (PI; 10 µg/ml; Molecular Probes, Eugene, Oreg.)
in PBS. The cells were washed once with PBS before mounting with Mowiol
(Sigma) on coverslips and viewed under a Leica TCS40 confocal laser
microscope (Leica, Wetzlar, Germany).
Analysis of DNA fragmentation.
Detection of DNA
fragmentation into oligonucleosomal DNA fragments by agarose gel
electrophoresis was performed as described elsewhere (61).
To detect DNA fragmentation by flow cytometry, purified nuclei were
stained with PI and analyzed on a FACScan flow cytometer (Becton
Dickinson, Lincoln Park, N.J.) as previously described (15,
49); the results were plotted as means ± standard errors of
the means (SEM).
Immunoblotting techniques for analysis of caspase activation and
presence of the FasR.
HeLa cells (106/ml) were
subjected to various treatments, scraped off the culture plate with a
rubber policeman, and washed once with PBS. The cell pellets were lysed
in 30 µl of resuspension buffer (150 mM NaCl, 1 mM EDTA, 10 mM Tris
HCl [pH 7.6]) containing 10 mM phenylmethylsulfonyl fluoride. The
protein concentration of the total cell lysates was determined by the
Bradford assay with bovine serum albumin as a standard. The total cell
lysates (25 µg) were boiled with Laemmli sample buffer and
electrophoresed on a sodium dodecyl sulfate (SDS)-13% polyacrylamide
gel. The separated proteins were transferred to a nitrocellulose
membrane, probed with antibodies to caspase-3 (gift from Donald
Nicholson, Merck Frosst, Quebec, Quebec, Canada) and caspase-8 (Santa
Cruz Biotechnology, Santa Cruz, Calif.), followed by the appropriate horseradish peroxidase-conjugated secondary antibodies. Detection was
carried out by chemiluminescence (Supersignal; Pierce, Rockford, Ill.)
according to manufacturer's specifications.
MAPK activity assays.
Cells (2 × 106/sample) were lysed with 400 µl of lysis buffer (PBS
[pH 7.4], 1% Nonidet P-40, 0.5% sodium deoxycholate, 1 mM Na3VO4, 0.1% SDS, 1 mM EDTA, 1 mM EGTA, 20 mM
NaF, 1 mM phenylmethylsulfonyl fluoride, 1 µg each of aprotinin,
leupeptin, and pepstatin per ml). For MAPK immunoprecipitation, cell
lysates were centrifuged (3,000 × g for 15 min), and
the supernatant was incubated with a mouse antibody generated against
human p42 MAPK or ERK2 (Transduction Laboratories, Lexington, Ky.)
coupled to protein A- or protein G-Sepharose (Sigma).
Immunoprecipitates were then washed three times in lysis buffer and
three times in kinase assay buffer (10 mM Tris [pH 7.4], 150 mM NaCl,
10 mM MgCl2, 0.5 mM dithiothreitol). The kinase reaction
was carried out by adding 20 µl of kinase assay buffer to the
immunoprecipitate. The kinase assay buffer included 25 µM ATP, 2.5 µCi of [
-32P]ATP (Amersham, Buckinghamshire, United
Kingdom), and myelin basic protein (MBP; 1 mg/ml; Sigma) as the
substrate. The reaction was carried out for 15 min at 37°C and
stopped by addition of 3× Laemmli sample buffer. The samples were
resolved on an SDS-12.5% polyacrylamide gel, and MBP phosphorylation
was quantified with a phosphorimager (Bio Rad Laboratories, Hercules,
Calif.). In parallel with the immunocomplex kinase assays, we
determined the amount of ERK2 in the immunoprecipitates by using a
rabbit antibody specific for the human ERK1- and -2 isoforms (New
England Biolabs, Boston, Mass.). After coupling to a secondary antibody
(Zymed, San Francisco, Calif.), the proteins were visualized with the Amersham ECL (enhanced chemiluminescence) system.
Expression of mutated forms of MKK1.
Cells were transiently
transfected by electroporation (200 V, 960 µF), washed twice with
DMEM, and allowed to rest for 20 h before treatment. The DNA
constructs used were pMCL-HA-MKK1-S218E/S222D and pMCL-HA-MKK1-K97M,
expressing hemagglutinin (HA)-tagged constitutively active
(S218E/S222D) and dominant negative (K97M) forms of the MAPK kinase
(MKK1) (39, 40), respectively. In transient cotransfection experiments, 20 µg of an HA-tagged wild-type ERK2 construct
(pMCL4-wtERK; a kind gift from Melanie Cobb, Texas Southwestern Medical
Center, Dallas) was used together with 20 µg of S218E/S222D or K97M
MKK1 before immunoprecipitation with a monoclonal HA-specific antibody (12CA5; Boehringer, Mannheim, Germany), subsequently followed by the
MAPK activity assay.
For some experiments, we used a cell line with inducible expression of
constitutively active MKK1. This cell line was established as follows.
The constitutively active HA-tagged MKK1-S218E/S222D cDNA was cloned
into the NotI/SalI sites of plasmid pBI-4
(3) under the control of the tetracycline transactivator
(tTA)-regulated cytomegalovirus promoter. HeLa cells were first
transfected with both pUHD15-1, coding for tTA (19), and
pTK-Hyg (Clontech, Palo Alto, Calif.). Clones were selected for 2 weeks
on hygromycin (250 µg/ml; Calbiochem) and submitted to luciferase
assay after transient transfection of the reporter construct pBI-1
(3). Positive HeLa-tTA clones were simultaneously
transfected with the pBI-4/MKK1-S218E/S222D construct and the pSV2NEO
marker. Colonies were grown in tetracycline (1 µg/ml; Sigma),
selected 2 weeks on G418 (500 µg/ml; Calbiochem), and cloned by
limiting dilution. Positive double stable clones were assayed 48 h
after removal of tetracycline by HA immunostaining and Western blotting
with antibodies against HA or phospho-MAPK (data not shown). In this cell line, we have, after depletion of tetracycline, routinely observed
20 to 30% HA-MKK1-positive cells. We do not know why we do not get
100% penetrance of HA-MKK1 expression.
For detection of transfected cells, the cells were fixed for 30 min
with 3% formaldehyde in PBS. The cells were then washed once with PBS
and permeabilized with 0.1% Nonidet P-40 (Sigma) for 10 min at room
temperature. After washing with PBS, cells were incubated for 2 h
at room temperature with 10 µg of a monoclonal HA-specific antibody
(12CA5; Boehringer Mannheim) per ml in PBS with 1% bovine serum
albumin (Sigma). Cells were then washed three times with PBS and
incubated further for 1 h at room temperature with tetramethyl
rhodamine isothiocyanate-conjugated anti-mouse secondary antibody
(Zymed) and 10 mg of Hoechst 33342 (Molecular Probes) or 10 µg of PI
per ml in PBS with 1% bovine serum albumin. Cells were mounted in 50%
glycerol (Sigma) and viewed under a Leica RMB epifluorescence
microscope. For confocal images, cells were stained for HA as described
above, and the DNA was visualized by PI staining and viewed under a
Leica TCS40 confocal laser microscope.
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RESULTS |
Inhibition of MAPK signaling sensitizes HeLa cells to FasR-induced
apoptosis.
As mitogenic signaling through the MAPK cascade has
been shown to have an inhibitory effect on the induction of apoptosis, we wanted to determine whether MAPK-mediated signaling could be involved in protection of FasR-expressing cells that are normally insensitive to FasR activation. To examine if inhibition of MAPK signaling would affect FasR-induced apoptosis, we pretreated HeLa cells
with the specific MKK1 inhibitor PD 98059 (2) for 30 min
before addition of the agonistic anti-Fas antibody for the indicated
time periods. Normally, these cells were not sensitive to stimulation
of the FasR, as both control cells and cells incubated with the
agonistic FasR antibody displayed a normal chromatin pattern after
staining with PI (Fig. 1A). In contrast,
cells pretreated with PD 98059 before addition of the agonistic FasR
antibody displayed apoptosis-specific alterations of the chromatin
structure, including condensation and fragmentation of nuclei (Fig. 1).
Treatment with PD 98059 alone did not induce apoptosis in these cells
(Fig. 1). The sensitizing effect of PD 98059 was further confirmed by
conventional agarose gel electrophoresis, showing the distinct
apoptotic DNA laddering in HeLa cells pretreated with PD 98059 before
addition of anti-FasR antibody, whereas no effects were observed with
PD 98059 or FasR antibody alone (Fig. 1B).
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FIG. 1.
Specific inhibition of MAPK signaling sensitizes HeLa
cells to FasR-induced apoptosis. HeLa cells, which normally are not
responsive to FasR stimulation, were preincubated with the specific
MKK1 inhibitor PD 98059. This caused an almost complete sensitization
to FasR stimulation. (A) Representative confocal micrographs of cells
incubated for 24 h with medium alone (a) or in the presence of 30 µM PD 98059 (b) 100 ng of anti-FasR antibody per ml (c), and 30 µM
PD 98059 plus 100 ng of anti-FasR antibody per ml (d). Nuclear
alterations were visualized by PI staining. The micrographs show that
nuclei of apoptotic cells are fragmented into apoptotic bodies with
intense staining, whereas the nuclei of normal interphase cells show a
uniform and dimer staining. Bar = 10 µm. (B) The formation of
oligonucleosome-sized DNA fragments in cells subjected to the same
treatments as above was studied by agarose gel electrophoresis. (C)
Apoptotic DNA fragmentation was determined in PI-stained nuclei by flow
cytometric analysis. (D) Analysis of the time course of FasR-induced
apoptosis in HeLa cells in the presence of PD 98059. After treatments,
aliquots of cells were stained with a hypotonic PI solution, and the
proportion of apoptotic nuclei was determined with a FACScan flow
cytometer. The data represent means ± SEM from a minimum of three
separate experiments.
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To quantify the amount of apoptotic cells at different time points and
to compare the induction of DNA fragmentation by different
treatments,
we used flow cytometric (fluorescence-activated cell
sorter [FACS])
analysis of isolated nuclei as detected with the
DNA stain PI
(
49). The measurement is based on the fact that
apoptotic
nuclei show a lower DNA content due to leakage of DNA
fragments from
the nuclei. The amount of apoptotic cells is indicated
by a large
subdiploid peak on the FACS histogram, the events of
which represent
apoptotic nuclei and nuclear fragments (Fig.
1C).
Cells treated with PD
98059 for 24 h did not show any significant
induction of apoptosis
compared to the control (Fig.
1C and D).
In samples pretreated with PD
98059 before addition of anti-FasR
antibody, the number of apoptotic
cells started to rise after
incubation for 8 to 12 h and was
approximately 65 to 70% after
24 h. In contrast, cells incubated
with the anti-FasR antibody
alone displayed only a minor increase in
the number of apoptotic
cells (Fig.
1D).
Inhibition of mitogenic signals by serum starvation potentiates the
effects of PD 98059.
The major source of growth signals in
cultured cells is supplied by the addition of serum to the cell culture
medium. To investigate if a general inhibition of growth signals could
affect FasR-induced apoptosis, we preincubated HeLa cells for 1 h
in a medium containing 0.5% FCS before addition of agonistic anti-FasR
antibody and analyzed the samples for apoptotic cells by flow
cytometry. These analyses were carried out at 16 h, as the
potentiating effects were most obvious at the initial stages of the
triggering process (data not shown). Serum-starved cells were clearly
more sensitive to FasR stimulation than cells grown with 10% FCS (Fig.
2). Serum starvation also induced a
potentiation of the PD 98059-induced FasR sensitization at 16 h,
as the number of apoptotic cells was approximately doubled in
FasR-stimulated cells preincubated both with low serum and in the
presence of PD 98059 (Fig. 2).
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FIG. 2.
Inhibition of mitogenic stimuli by serum starvation
increases the FasR responsiveness in HeLa cells. HeLa cells were
incubated for 16 h in medium containing 0.5 or 10% FCS and in the
presence of PD 98059 (30 µM), anti-FasR antibody (100 ng/ml), or PD
98059 (30 µM) plus anti-FasR antibody (100 ng/ml), and the number of
apoptotic cells was determined by flow cytometric analysis as for Fig.
1C. The data represent means ± SEM from a minimum of three
separate experiments.
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Transient transfection with dominant negative MKK1 confirms the
involvement of MAPK signaling in FasR insensitivity.
To further
demonstrate that the observed PD 98059-mediated effect relates to
signaling by the MAPK cascade, we transfected HeLa cells transiently
with a dominant negative mutant of MKK1. While the dominant negative
(K97M [39, 40]) form of MKK1 by itself did not elevate
the number of apoptotic cells among the transfected cell population, it
clearly made the transfected cells more sensitive to FasR-induced
apoptosis (Fig. 3). Note that the incubation time in these experiments was 16 h, as the longer 24-h incubations resulted in loss of apoptotic cells from the coverslips. These results further corroborate the assumption that inhibition of
MAPK is a key feature of the sensitization to FasR-induced apoptosis.
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FIG. 3.
Transfection with dominant negative MKK1 sensitizes HeLa
cells to FasR-induced apoptosis. (A) Representative immunofluorescence
micrographs of cells transfected with a dominant negative (MKK1 K97M)
MKK1 construct and incubated for 16 h in the absence or presence
of anti-FasR antibody. PI staining (a and c) was used to detect
alterations in the nuclei, and a monoclonal anti-HA antibody linked to
an FITC-conjugated secondary antibody (b and d) was used to detect the
presence of the HA-tagged MKK1 in transfected cells. The arrows
indicate transfected cells. Bar = 10 µm. (B) Percentage of
apoptosis in transfected cells after treatment with an anti-FasR
antibody. Number on bars indicate how many transfected cells were
counted. The data represent means ± SEM from a minimum of three
separate experiments. Note that the incubation time with the agonistic
FasR antibody is 16 h.
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MAPK-mediated resistance to FasR-induced apoptosis is not dependent
on protein synthesis.
Many cells that are normally resistant to
FasR or TNF R1-induced apoptosis can be sensitized by inhibition of
protein synthesis (50, 69). Since we observed that
inhibition of MAPK signaling sensitizes HeLa cells to FasR-induced
apoptosis, we wanted to determine whether the MAPK-generated protection
requires protein synthesis. It is plausible that inhibition of MAPK
activation could inhibit the synthesis of some crucial inhibitor
proteins. For these experiments, we used a HeLa cell line with
inducible expression of a constitutively active mutant form of MKK1
(S218E/S222D [39, 40]) and pretreated the cells with
CHX before stimulation of the FasR. By using this cell line, we also
wanted convincingly confirm that the sensitization obtained with PD
98059 was indeed MAPK dependent by determining whether the
sensitization could be reversed by the constitutively active MKK1,
which should not be affected by this inhibitor. When cells had been
incubated for 48 h in the absence of tetracycline, 20 to 30% of
the cells were positive for the mutant MKK1, as indicated by HA
immunoreactivity (Fig. 4).
Immunoblotting with phospho-MAPK
antibodies confirmed that the cell line showed increased MAPK activity
along with increasing HA-MKK1 expression (data not shown). The PD
98059-induced effect was completely reversed in cells positive for
constitutively active HA-MKK1 (Fig. 4). Furthermore, HA-MKK1-positive
cells were efficiently protected against CHX-mediated sensitization in
FasR-stimulated cells (Fig. 4). Identical results were obtained with
transient transfections with the constitutively active MKK1 (Fig. 4B).
Taken together, these results indicate that the MAPK-generated
protection is not likely to be protein synthesis dependent.
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FIG. 4.
Constitutively active MKK1 inhibits FasR-induced
apoptosis in the presence of the protein synthesis inhibitor CHX. (A)
An HeLa cell line with the constitutively active MKK1 (MKK1
S218E/S222D) in a tTA-regulated expression vector was incubated for 48 h in the absence of tetracycline to yield maximal MKK1 expression. To
assess the effect of MKK1-induced MAPK activation on FasR-mediated
apoptosis, cells were incubated for 16 h in the absence (a and b)
or presence (c to h) of anti-FasR, and with preincubation with PD 98059 (e and f) or CHX (g and h). Arrows indicate HA-MKK1-positive cells.
Bar = 10 µm. (B) The effect of expression of constitutively
active MKK1 was quantified by counting apoptotic and nonapoptotic
transfected cells viewed under an epifluorescence microscope. The data
represent means ± SEM from a minimum of three separate
experiments. Numbers on bars indicate total of counted cells. Note that
the incubation time with the different compounds was 16 h. Similar
results were obtained both by transient transfections and with the
inducible MKK1 construct.
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Inhibition of PI-3K does not sensitize HeLa cells to FasR-induced
apoptosis.
Since activation of PI-3K has been shown to inhibit
different forms of apoptosis (10, 30, 33, 34), we
investigated if PI-3K could be involved in the protection of
FasR-insensitive cells. HeLa cells were preincubated for 30 min with
the specific PI-3K inhibitors LY294002 and wortmannin before addition
of anti-FasR antibody. Determination of the number of apoptotic cells
after 24 h by FACS analysis indicated that neither LY294002 nor
wortmannin sensitized HeLa cells to FasR-induced apoptosis (Fig.
5). Thus, it appears that PI-3K signaling
is not involved in the observed protection of HeLa cells against
FasR-induced apoptosis.
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FIG. 5.
Inhibition of PI-3K by LY294002 and wortmannin does not
sensitize HeLa cells to FasR-induced apoptosis. HeLa cells were treated
for 24 h with LY294002 (LY; 10 µM), wortmannin (100 nM),
LY294002 plus anti-FasR antibody (100 ng/ml), wortmannin plus anti-FasR
antibody, anti-FasR antibody, or PD 98059 (PD; 30 µM) plus anti-FasR
antibody. The degree of apoptosis was quantified by flow cytometric
analysis of apoptotic nuclei. The data represent means ± SEM from
a minimum of three separate experiments.
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The MAPK-dependent FasR insensitivity is maintained upstream from
the caspase effector machinery.
A key feature of FasR-mediated
apoptosis is activation of different caspases. All caspases are
activated by cleavage of inactive proforms (42). To assess
if the MAPK-mediated inhibition occurs at the initial phases of FasR
signaling, we analyzed the cleavage and activation of caspase 8 and
caspase 3 by immunoblotting with specific antibodies. Caspase 8 is the
initiator of the FasR-induced apoptotic effector and signaling
machinery. This protein exists as 55- and 54-kDa inactive proforms that
are cleaved and activated when recruited by adaptor proteins to the
oligomerized FasR complex (43, 47). The antibody that we
used for caspase 8 recognizes both of the 55- and 54-kDa proforms of
caspase 8 as well as the intermediate cleavage form corresponding to
~43/42 kDa. By using the fragmentation pattern as an indicator of
activation, we could observe a clear caspase 8 cleavage after 12 h
in FasR-stimulated HeLa cells incubated in the presence of PD 98059 (Fig. 6Aa). With this treatment, the
caspase 8 cleavage products had dramatically accumulated after 24 h of incubation. Caspase 3 has been shown to be activated during the
earliest phases of apoptotic induction (59). The 32-kDa
precursor protein of caspase 3 is rapidly cleaved via an intermediate
step into two subunits of 12 and 17 kDa (57). The antibody
that we used for detection of caspase 3 recognizes the 32-kDa proform,
the 20-kDa intermediate, and the 17-kDa subunit of activated caspase 3. When cell extracts were immunoblotted with this antibody, the first
signs of accumulation of the activated 17-kDa subunit could be observed
12 h following FasR stimulation in PD 98059-treated cells (Fig.
6Ab). In contrast to the PD 98059-sensitized cells, treatment with
anti-FasR antibody alone induced a minor cleavage and activation of
caspase 8 and caspase 3 after 24 h (Fig. 6A), corresponding to the
small number of apoptotic cells seen after this treatment. The
activation kinetics of both the initiator, caspase 8, and the effector,
caspase 3, corresponds very well to the time course of apoptosis
induction in these cells. As FasR-stimulated HeLa cells incubated in
the absence of PD 98059 showed only an insignificant activation of
caspases, the observed MAPK-mediated protection seemed to occur at the
level of or upstream of caspase 8. To confirm this assumption, we used
the above-mentioned HeLa cell line with inducible expression of the
constitutively active form of MKK1 (S218E/S222D) and tested the
MKK1-positive cells for activation of caspase 8. The cells were
incubated in the presence of FasR-stimulating antibody and PD 98059 for
24 h. As the penetrance in this cell line is relatively low (20 to 30%), most of the cells detached during this treatment. However, the
MKK1-positive cells remained attached and viable, as shown in Fig. 4.
The samples from the attached MKK1-positive cells showed a clearly
suppressed activity of the triggering factor, caspase 8 (Fig. 6B).
Since the attached cells also contained a contaminating fraction of
apoptotic cells that could not be shaken off, the attached cells showed
some degree of caspase-8 activation (Fig. 6B). The inducible cell line
seemed to be somewhat more sensitive to FasR stimulation (in the
absence of PD 98059) than normal HeLa cells, as there was a more
pronounced caspase 8 cleavage in these cells in the presence of
tetracycline (Fig. 6B) than in the parent cell line. We have obtained
identical results with adenovirus-based gene delivery of the
constitutively active MKK1 (S218E/S222D), which very efficiently
suppressed FasR-induced caspase 8 activation in HeLa cells sensitized
with PD 98059 (67). Taken together, these experiments
indicate that the MAPK-mediated protection occurs upstream of caspase 8 activation.
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FIG. 6.
Caspase 8 and caspase 3 activities in FasR-stimulated
cells are affected by modulation of MAPK activity. (A) To analyze the
kinetics of FasR-induced caspase activation in the presence and absence
PD 98059, HeLa cells were treated as outlined in the legend to Fig. 1.
Caspase activation can be observed as the appearance of active
fragments of the caspase proforms of caspase 8 (a) and caspase 3 (b)
(see text for details). No significant activation occurred in the
absence of PD 98059. (B) To test the effect of MAPK activation on the
activity of the apoptotic initiator, caspase 8, the cell line with the
constitutively active MKK1 (MKK1 S218E/S222D) was incubated for 3 days
in the presence or absence of tetracycline and then treated for 24 h as described for Fig. 1. The MKK1-negative cells detached during this
treatment and were washed off. The remaining cells were scraped off the
culture flasks, centrifuged, washed, and lysed prior to immunoblotting
with antibodies to caspase 8 as described in Materials and Methods.
Each well was loaded with 25 µg of protein.
|
|
Inhibition of the MAPK cascade does not affect the abundance or
distribution of the FasR.
One possible mechanism by which MAPK
inhibition could affect the Fas response is by altering the levels of
accumulated FasR protein or by changing the cellular
compartmentalization of the receptor. To exclude the possibility that
inhibition of mitogenic stimuli could affect the levels of receptor
protein, we analyzed the amounts of protein by Western blotting of
whole-cell extracts and the presence of the FasR on the cell surface by
FACS analysis in PD 98059-treated samples. Neither the amounts of
accumulated FasR nor the FasR levels on the cell surface were altered
by PD 98059 treatment (data not shown). These results exclude
alterations in FasR levels or organization as a mechanism behind the
sensitization of HeLa cells to FasR-induced apoptosis.
Stimulation of the FasR activates MAPK.
The synthetic MKK1
inhibitor PD 98059 has been shown to inhibit MKK1 activation induced by
Raf, probably by competitive inhibition of Raf binding to the
activation site on MKK1 (2). Since PD 98059 does not inhibit
MKK1 activity per se, we wanted to investigate if stimulation of the
FasR could activate MAPK. This kind of activation could provide an
explanation why a compound such as PD 98059 is so efficient in
rendering cells sensitive to FasR-induced apoptosis. MAPK activity was
analyzed by an immunocomplex kinase assay. The results show that
stimulation of HeLa cells with anti-FasR antibody induced a clear
increase in MAPK activity starting 2 h after stimulation of the
FasR and lasting up to 8 to 10 h after stimulation (Fig. 7A). The increase in MAPK activity peaked
at 4 to 6 h, being approximately 2.5-fold higher than the control
values (Fig. 7B). This activation was not due to increased synthesis of
MAPK, as the MAPK protein levels remained constant following FasR
stimulation (Fig. 7A). The FasR-induced MAPK activation was completely
inhibited by pretreatment of HeLa cells with 30 µM PD 98059 before
addition of anti-FasR antibody (Fig. 7A and B).
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|
FIG. 7.
Stimulation of the FasR activates MAPK in HeLa cells.
The effect of FasR stimulation on MAPK activity was followed 10 h
after addition of the agonistic FasR antibody in cells incubated in the
presence or absence of PD 98059. (A) The activation was measured by an
immunocomplex kinase assay with MBP as a substrate. To confirm equal
loading of MAPK and to check whether the observed effect could be due
to changes in the amounts of MAPK, the immunoprecipitates were
immunoblotted for the presence of ERK2 protein. A representative
autoradiograph and an ERK2 immunoblot of the immunocomplex kinase assay
are shown. The immunocomplex kinase assay with MBP as the substrate
showed that MAPK is significantly activated by FasR stimulation,
without any detectable changes in MAPK protein levels. (B)
Quantification from multiple parallel samples of the relative MAPK
activities (control = 1) at different time points was performed by
phosphorimager analysis of the MBP-associated 32P labeling.
The data represent means ± SEM from a minimum of five separate
experiments. The statistical significance between Fas- and PD
98059-plus-Fas-treated samples was tested by Student's t
test (*, P < 0.05; **, P < 0.01; ***,
P < 0.001). (C) The effect of FasR stimulation and treatment
with PD 98059 was also analyzed in cells cultured in medium containing
0.5 or 10% FCS and treated in the same way as for Fig. 2. Numbers
below the lanes indicate relative MAPK activity (control = 1).
ERK2 immunoblotting was used to confirm equal loading. Serum starvation
seemed to amplify the PD 98059-induced MAPK inhibition. (D) The
efficacy of transfection with dominant negative (K97M) and
constitutively active (S218E/S222D) MKK1 on the FasR-induced MAPK
activation and on overall MAPK activity was tested by MAPK activity
measurements of cells cotransfected with HA-tagged ERK2. The HA-ERK2
was immunoprecipitated with an HA-specific antibody, and the
immunocomplex assays were carried out as indicated above. Western
blotting of the immunoprecipitates with an ERK2-specific antibody was
used to confirm equal loading. wt, wild type.
|
|
To further relate the degree of MAPK activity to the observed FasR
resistance, we wanted to determine the efficacy of our
attempts to
modulate MAPK activity by the other methods used,
apart from employing
PD 98059. In Fig.
2, we observed that serum
starvation induced some
degree of sensitization and enhanced the
effect of PD 98059. MAPK
activity measurements of cells treated
as in Fig.
2 showed that the
serum starvation to some extent abrogated
the FasR-induced MAPK
activation on its own (Fig.
7C). The combination
of serum starvation
and treatment with PD 98059 abrogated the
FasR-induced MAPK activation
even more efficiently (Fig.
7C).
Hence, although these results were
obtained at the later stages
of exposure and by the time at which the
differences in MAPK activities
have leveled, it seems that the effect
of serum starvation is
likely based on its inhibition of MAPK activity.
In Fig.
3 and
4, transfection and inducible expression of dominant
negative
(K97M) and constitutively active (S218E/S222D) forms of MKK1
were
used to modulate MAPK activities. We could verify the efficacy
of
these constructs in modulating MAPK activity, as cotransfection
with
HA-tagged ERK2 showed that the activities of the immunoprecipitated
HA-ERK2 were significantly affected by both constructs (Fig.
7D).
Furthermore, the FasR-induced MAPK activation could be abolished
with
the dominant negative form of MKK1 (Fig.
7D).
Resistance to FasR-mediated apoptosis correlates with induction of
MAPK activity in different cell lines.
To correlate the PD
98059-induced sensitization to FasR-mediated apoptosis with induction
of MAPK activity and to further confirm that the observed sensitization
in HeLa cells is not a cell-type-specific phenomenon, we treated HL60,
NIH 3T3, Jurkat, and U937 cells (Fig. 8A
and B) with anti-FasR antibody with or without PD 98059, in the same
manner as with HeLa cells. All of these cell lines showed different
degrees of FasR sensitivity. In accordance with HeLa cells, HL60 cells
were resistant to FasR stimulation. Anti-FasR antibody treatment for
12 h did not induce apoptosis in these cells. However,
approximately 45% of HL60 cells pretreated with PD 98059 were
apoptotic (Fig. 8A). NIH 3T3 cells were moderately sensitive to FasR
stimulation. When these cells were incubated for 24 h with mouse
anti-FasR, approximately 40% of the cells were apoptotic (Fig. 8A).
However, pretreatment of NIH 3T3 cells with PD 98059 before addition of
anti-FasR antibody increased the amount of apoptotic cells to
approximately 55% (Fig. 8A). Both Jurkat and U937 cells are known to
be sensitive to FasR-mediated apoptosis; correspondingly, incubation of
Jurkat cells for 2 h and U937 cells for 4 h with anti-Fas
antibody induced apoptosis in 50% of the cells (Fig. 8A). In Jurkat
and U937 cells, pretreatment with PD 98059 did not affect the
sensitivity to FasR-mediated apoptosis (Fig. 8A). To examine how the
degree of apoptosis relates to the degree of MAPK activation following
FasR stimulation, we measured the MAPK activity after addition of
anti-Fas antibody (Fig. 8B) in the different cell types. HeLa cells
showed the strongest response, with up to a threefold activation after
4 h. Treatment of HL60 cells with anti-Fas antibody increased MAPK
activity almost 2.5-fold compared to untreated cells after 4 h,
whereas the increase in MAPK activity was approximately twofold in NIH
3T3 cells (Fig. 8B). In Jurkat and U937 cells, treatment with anti-Fas
antibody induced only a minimal MAPK activity, being approximately
1.2-fold after 15 to 30 min (Fig. 8B). The MAPK activation was not
elevated after these time points (data not shown). The earlier time
points, presented for Jurkat and U937 cells, were chosen to reflect the faster kinetics of apoptotic induction in these cells than in the other
cell types.
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|
FIG. 8.
Correlation between FasR-induced MAPK activity and
resistance to FasR-mediated apoptosis in different cell lines. HeLa,
HL60, NIH 3T3, Jurkat, and U937 cells were incubated for the indicated
time periods with medium alone and in the presence of anti-FasR
antibody, PD 98059 (PD; 30 µM), and PD 98059 plus anti-FasR antibody
(100 ng of anti-human FasR per ml was used for all cell lines except
NIH 3T3, which was incubated with 10 µg of Jo2 anti-mouse FasR per
ml). The degree of apoptosis was quantified by flow cytometric analysis
of apoptotic nuclei (A), and MAPK activity from multiple parallel
samples was quantified by phosphorimager analysis of the MBP-associated
32P-labeling (B). (C) The basal MAPK activity in each cell
line was measured by immunocomplex assays as indicated above. Western
blotting of the immunoprecipitates with an ERK2-specific antibody was
used to confirm equal loading. The results show that the degree of MAPK
activation upon FasR stimulation correlates with the degree of FasR
resistance, whereas the basal activity of each cell line does not
correlate with the sensitivity to FasR-mediated apoptosis. The data
represent means ± SEM from a minimum of three separate
experiments.
|
|
The induction of MAPK activity correlated well with the degree of FasR
sensitization observed with PD 98059 pretreatment.
Both of the cell
lines (Jurkat and U937) showing only minor MAPK
activation upon FasR
stimulation were highly sensitive to FasR
stimulation even without PD
98059 treatment (Fig.
8A and B). The
HeLa, HL60, and NIH 3T3 cells were
all clearly sensitized to FasR-mediated
apoptosis in the presence of PD
98059. Furthermore, in the latter
three cell lines, the degree of
FasR-mediated apoptosis following
treatment with PD 98059 showed a
strong negative correlation to
the degree of FasR-induced MAPK
activation in the absence of PD
98059 (Fig.
8A and
B).
We examined whether the differences between the tested cell lines could
be due to differences in the basal activities of MAPK.
When equal
amounts of MAPK from the different cell lines were
used for
immunocomplex kinase assays, HeLa, Jurkat, and U937 cells
showed
similar basal kinase activities (Fig.
8C). The HL60 and
NIH 3T3 cells
showed somewhat higher and lower activities, respectively,
than the
other cell lines. However, observed small differences
in the basal MAPK
activities did not correlate with the degree
of FasR insensitivity.
Hence, the crucial parameter in regulation
of FasR responses seems to
be the FasR-induced activation of MAPK,
not the basal MAPK
activity.
| |
DISCUSSION |
Inhibition of mitogenic signals sensitizes cells to FasR-induced
apoptosis.
Mitogenic signals are usually associated with induction
of cell growth or differentiation (36). However, recent
studies have indicated that such signals may also be involved in
inhibition of apoptosis. In this respect, it has been shown that
activation of two signaling cascades involved in mitogenic stimuli,
namely, the MAPK (9, 16, 23, 77) and PI-3K (10, 30, 33, 34) signaling pathways, are able to suppress apoptosis in
different cell lines. Our data show that inhibition of MAPK signaling
by a specific MKK1 inhibitor, by serum withdrawal, and by transfection with dominant negative MKK1 renders HeLa cells susceptible to FasR-induced apoptosis. Furthermore, we show that in HeLa, HL60, and
NIH 3T3 cells, the FasR is able to induce a significant MAPK activation. This kind of MAPK activation is likely to be involved in
protecting cells from FasR-induced apoptosis. These results could also
provide an explanation for why some tumor cells expressing the FasR are
resistant to FasR-induced apoptosis (52, 68). Furthermore,
our observations may explain why stimulation of the FasR with agonistic
FasR antibodies has been associated with stimulated cell growth in some
cell lines (1, 14, 29, 53). Recent reports have indicated
the PI-3K signaling cascade as a major antiapoptotic pathway (13,
41). Our results indicate that the PI-3K pathway is not involved
in the MAPK-dependent regulation of FasR responses that we observed.
The FasR is able to generate a MAPK-mediated signal which
suppresses activation of caspases.
Our data quite conclusively
show that the FasR is in some cells able to generate a dominant
survival signal. All of the included studies indicate that the
activation of MAPK induced by the FasR is the key factor in the
MAPK-mediated protection, not the levels of basal MAPK activity. This
result, showing that the FasR would be able to generate its own
survival signal, is rather surprising. There have been indications that
the FasR could activate the Ras pathway and that this activation would
have an apoptosis-promoting function (19). However, a later
study suggested that the Ras effect could perhaps be accounted for by
Rac (20). This could explain the seeming contradiction
between these studies and our study. The suggested mandatory role of
Ras would relate not to a requirement of the MAPK cascade for apoptotic
FasR responses but to some other Rac-induced signaling pathway.
Furthermore, our results do not favor the hypothesis of a requirement
of MAPK signaling in apoptotic FasR responses, as transfections with
the dominant negative MKK1 had only a sensitizing effect without any inhibitory effect.
In the present study, the increased sensitivity to FasR-induced
apoptosis by MAPK inhibition could be detected as caspase
8 and caspase
3 activation. Conversely, untreated cells displayed
only a minor
caspase activation upon FasR stimulation, which was
proportional to the
small number of apoptotic cells that were
detected under these
conditions. Furthermore, cells expressing
constitutively active MKK1
also showed abrogated caspase 8 activity
when they were stimulated with
PD 98059 and a FasR-specific antibody.
These results are in accordance
with our previous results (
23),
indicating that
MAPK-mediated inhibition of FasR-induced apoptosis
in Jurkat cells
occurs upstream or at the level of caspase activation.
Activation of
caspase 8 has been considered to be the first caspase
activated
following FasR stimulation with the subsequent assembly
of the
death-inducing signaling complex (
44). Our results imply
that in cells insensitive to FasR-induced apoptosis, stimulation
of the
FasR averts the FasR-mediated signal from the caspase effector
machinery. In cells insensitive to FasR-induced apoptosis, FasR
stimulation results in a significant MAPK activation, instead
of
activation of the caspase cascade. The resulting MAPK activation
seems
to interfere with some critical function required for caspase
activation. The inhibition of apoptosis at early steps in the
apoptotic
pathway, rather than at some intermediate stages in
the caspase
cascade, is likely desirable, as only in this way
cells could escape
from any detrimental effects of a partially
activated apoptotic
effector
machinery.
Possible downstream targets of MAPK.
The MAPKs are known to
phosphorylate many different proteins involved in various signaling and
regulatory pathways as well as in transcriptional regulation
(72). While the role of MAPKs in regulation of transcription
factors has received special attention, there is much less information
on MAPK-induced phosphorylation as a bona fide regulatory factor in
determining the functions of cytosolic targets. Phosphorylation of the
epidermal growth factor receptor by the MAPK pathway has been suggested
to down-regulate the receptor tyrosine kinase activation complex
(51, 74). According to this scheme, MAPK activation would
function as an autoregulatory loop for signaling through the epidermal
growth factor receptor (18, 47). Interestingly, our results
point to a similar autoregulatory loop, whereby the FasR would generate an intervention of its own apoptotic signaling by activation of MAPK.
However, our experimental setup is not able to distinguish whether MAPK
signaling affects the receptor complex directly or indirectly. An
attractive scenario is that the target for the MAPK-mediated regulation
of FasR responses will be found among the protein(s) in the
death-inducing signaling complex. We are currently testing whether the
MAPK-mediated signal can affect the phosphorylation state of some of
the proteins required for caspase activation. For example, both FasR
(31) and FADD have been shown to be phosphorylated (31,
32, 80) and hence possible targets for this kind of regulation.
Another possibility is that some known or unknown inhibitory protein,
with constitutive expression in the cells, is activated by a
phosphorylation event generated by the FasR-induced MAPK signal.
MAPK-mediated protection of FasR-induced apoptosis is not dependent
on protein synthesis.
It has been well established that many
different cell types that are resistant to FasR- or TNF R1-induced
apoptosis can be made sensitive when the cells are preincubated with
protein synthesis inhibitors such as CHX. In view of these
observations, it has been suggested that FasR and TNF R1 can elicit a
protein synthesis-dependent signal (69), which would be
distinct from the apoptotic signal. A number of studies also suggest an
inhibitory effect of viral as well as cellular proteins such as p35
(5), CrmA, (63), NF-
B (4, 70, 71),
Bcl-2 (28, 56), inhibitor of apoptosis proteins (43,
54) c-FLIP (25), and v-FLIP (64) in
FasR-induced apoptosis. On the other hand, there is evidence for
protective signals occurring postranslationally through
phosphorylation-based signaling pathways such as MAPK (9, 16, 23,
77) and PI-3K (10, 30, 33, 34). In the present study,
CHX-treated HeLa cells transfected with constitutively active MKK1 were
not sensitized to FasR-induced apoptosis. This result precludes the
requirement for protein synthesis in protection against FasR-induced
apoptosis. This hypothesis of a posttranslationally induced modulation
of FasR signaling is corroborated by our previous study, showing that
MAPK activation in the presence of CHX protects Jurkat cells efficiently against FasR-induced apoptosis (23). Thus, a
high constitutive MAPK activity seems to be sufficient for inhibition of the FasR-mediated apoptotic signal. Taken together, our results strongly support the hypothesis of direct phosphorylation-based modulation of FasR-mediated signaling.
The possible role of MAPK in resistance to FasR-induced
apoptosis.
During development, cells most likely need to modulate
their responsiveness to apoptosis-inducing cytokines, such as FasL and
TNF-
. Direct modulation by phosphorylation-based signaling could
have evolved to rapidly modulate FasR responsiveness in situations
where a cell is in an environment or developmental stage with rapidly
fluctuating conditions. Posttranslational regulation of receptor
functions is likely to be significantly faster and more dynamic than
regulation through, for example, protein inhibitors or activators that
are synthesized after transcriptional activation.
Cytotoxic T lymphocytes (CTLs) and natural killer cells are mediators
of immune responses against tumor cells and other potential
target
cells (
7,
73,
75). The mechanism by which CTLs mediate
their
cytotoxicity can be divided into two pathways, FasR and
perforin
dependent, whereas natural killer cells use only the
FasR pathway
(
48). Upon recognizing tumor cells, CTLs are activated
and
start to express FasL, and binding of FasL to FasR induces
apoptosis in
the target cells (
48). Resistance to FasR-induced
apoptosis
is beneficial for tumor cells, as this enables them
to escape immune
responses. According to this view, decreased
susceptibility of tumor
cells to FasR-induced apoptosis has been
shown to play a role in tumor
growth (
45,
46,
75). These
studies have indicated high
expression of Bcl-2 or FAP-1 or down-regulation
of the FasR as a
possible cause for the observed insensitivity.
Apart from these
inhibitory proteins, various FasR-resistant tumor
cells likely need
signaling mechanisms that participate both in
induction of cell growth
and in suppression of apoptosis (
11).
Little is known about
the signaling mechanisms that protect cells
from apoptosis and how they
act, although especially the PI-3K
and to some extent also the MAPK
pathways have been recognized
as potential inhibitory factors. The
inhibition of FasR-induced
apoptosis by activation of MAPK could both
during specific stages
of normal development and during tumorigenesis
be an important
factor in making cells resistant to immune
surveillance. This
inhibition seems to be independent of protein
synthesis, which
indicates that in any given cell there are direct
regulatory signaling
mechanisms at work, constantly integrating the sum
of incoming
stimulatory and inhibitory signals and thereby determining
whether
a cell will continue proliferation or differentiation or
whether
it will undergo
apoptosis.
| |
ACKNOWLEDGMENTS |
We thank Donald Nicholson, Merck-Frosst (Quebec, Quebec, Canada)
for caspase antibodies, Melanie Cobb (Southwestern Medical Center,
Dallas, Tex.) for the pMCL-wtERK2 construct, Päivi Koskinen (Turku Centre for Biotechnology, Turku, Finland) for the pSV2NEO construct, and Poul Jørgensen (University of Århus, Århus, Denmark) for the pBI-1, pBI-4, and pUHD15-1 constructs. We also thank Lea Sistonen and other members of our laboratories for critical comments on
the manuscript.
Financial support from the Academy of Finland (grant 35718),
Sigrid Jusélius Foundation, Erna and Victor Hasselblad
Foundation, Finnish Cancer Foundation, Nordic Academy for Advanced
Study (NorFA), and Cell Signaling Program of Åbo Akademi University is
gratefully acknowledged. T.H.H. is supported by the Turku Graduate
School of Biomedical Sciences. V.L.J. is a holder of an MRC studentship (United Kingdom).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Turku Centre for
Biotechnology, P.O.B. 123, FIN-20521 Turku, Finland. Phone:
358-2-333-8036. Fax: 358-2-333-8000. E-mail:
john.eriksson{at}mail.abo.fi.
| |
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Molecular and Cellular Biology, September 1999, p. 5991-6002, Vol. 19, No. 9
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Abstract
Introduction
