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Molecular and Cellular Biology, July 2001, p. 4818-4828, Vol. 21, No. 14
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.14.4818-4828.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
The Cell Cycle-Regulatory CDC25A Phosphatase
Inhibits Apoptosis Signal-Regulating Kinase 1
Xianghong
Zou,1
Tateki
Tsutsui,1,
Dipankar
Ray,1
James F.
Blomquist,2
Hidenori
Ichijo,3
David S.
Ucker,2 and
Hiroaki
Kiyokawa1,*
Departments of Molecular
Genetics1 and
Microbiology/Immunology,2 University of
Illinois College of Medicine, Chicago, Illinois 60607, and
Laboratory of Cell Signaling,3 Tokyo
Medical and Dental University, Tokyo 113-8549, Japan
Received 27 December 2000/Returned for modification 25 January
2001/Accepted 17 April 2001
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ABSTRACT |
CDC25A phosphatase promotes cell cycle progression by activating
G1 cyclin-dependent kinases and has been postulated to be an oncogene because of its ability to cooperate with RAS to transform rodent fibroblasts. In this study, we have identified apoptosis signal-regulating kinase 1 (ASK1) as a CDC25A-interacting protein by
yeast two-hybrid screening. ASK1 activates the p38 mitogen-activated protein kinase (MAPK) and c-Jun NH2-terminal protein
kinase-stress-activated protein kinase (JNK/SAPK) pathways upon
various cellular stresses. Coimmunoprecipitation studies demonstrated
that CDC25A physically associates with ASK1 in mammalian cells, and
immunocytochemistry with confocal laser-scanning microscopy showed that
these two proteins colocalize in the cytoplasm. The carboxyl terminus
of CDC25A binds to a domain of ASK1 adjacent to its kinase domain and
inhibits the kinase activity of ASK1, independent of and without effect
on the phosphatase activity of CDC25A. This inhibitory action of CDC25A
on ASK1 activity involves diminished homo-oligomerization of ASK1.
Increased cellular expression of wild-type or phosphatase-inactive CDC25A from inducible transgenes suppresses oxidant-dependent activation of ASK1, p38, and JNK1 and reduces specific sensitivity to
cell death triggered by oxidative stress, but not other apoptotic stimuli. Thus, increased expression of CDC25A, frequently observed in
human cancers, could contribute to reduced cellular responsiveness to
oxidative stress under mitogenic or oncogenic conditions, while it
promotes cell cycle progression. These observations propose a mechanism
of oncogenic transformation by the dual function of CDC25A on cell
cycle progression and stress responses.
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INTRODUCTION |
Cyclin-dependent kinases (CDKs)
are the central machinery that promotes cell cycle progression
(25, 50, 57, 65). Phosphorylation and dephosphorylation of
CDK proteins, as well as association with cyclins, control protein
kinase activity. CDC25 phosphatases remove inhibitory phosphates from
specific tyrosine and threonine residues within the ATP-binding domain
of the CDK proteins, thus activating these kinases (12).
The cell cycle-dependent expression of three CDC25 proteins suggests
that CDC25A activates cyclin E(A)-CDK2 during G1
to S transition, while CDC25B is involved in the regulation of cyclin
A-CDK2 or cyclin A-CDK1 during S to G2 transition
(15, 30). CDC25C activates cyclin B-CDK1 at the
G2-M boundary (44, 51). Expression
of CDC25A is controlled by proliferation regulatory signals involving
E2F and other transcription factors (8, 61).
Overexpression of CDC25A shortens the passage of serum-stimulated HeLa
cells through G1 (4), while
microinjection of anti-CDC25A antibody inhibits the initiation of
the S phase in rat kidney epithelial cells (30).
Thus, CDC25A participates in a rate-limiting mechanism for
G1 progression and initiation of DNA replication.
Intriguingly, CDC25A and CDC25B have been postulated to be oncogenes,
overexpressed in various types of cancers (6, 18, 19, 47,
63). These CDC25 phosphatases can cooperate with Ha-RAS
to transform rodent fibroblasts (18). These data suggest
that overexpression of CDC25A or CDC25B plays a critical role in
establishing transformed phenotypes, generally characterized by
unrestricted cell cycle progression and/or suppressed cell death.
Abrupt changes in cellular homeostasis, such as alterations in
the reduction-oxidation (redox) potential, DNA damage, and imbalance of
proliferation, cause cellular stress (1). Cells have
complex signaling mechanisms to trigger a variety of intracellular responses upon stress and undergo either cell death (apoptosis) or
survival with rescue from stress, depending on the amplitude of stress
and balance of death-inducing and -sparing genes. The stress-induced
signaling pathways involve cascades of protein kinases that ultimately
control expression of a number of stress-responsive genes
(31). Apoptosis signal-regulating kinase 1 (ASK1)
functions as an upstream component of the kinase cascades that
interacts with a variety of stress-induced signals (26, 27,
62). ASK1 phosphorylates and activates MKK4/7, which then
activates the c-Jun NH2-terminal protein kinases
(JNKs), also known as the stress-activated protein kinases, or
SAPKs (11, 24, 43, 54, 59, 64, 70). ASK1 also
phosphorylates and activates MKK3 and MKK6, leading to activation of
the p38 mitogen-activated protein kinases (MAPKs) (42, 49,
58). ASK1 is activated by oxidative stress (20, 53), genotoxic stress (9), and interaction with
death receptor-associated proteins, such as TRAFs and Daxx (7,
45). Downstream activation of JNKs influences multiple proteins
that control apoptosis, including c-Jun, p53, and Bax (2,
35). Activation of p38 kinases also affects a number of
transcription factors, such as ATF2, Elk-1, and NF-
B (28,
46). Activation of JNKs and p38 kinases seems to play a role in
induction of apoptosis (67), while it could also be
involved in cell survival, depending on cell type or cellular context,
e.g., the interaction with survival factors including NF-B
(36, 40).
Although complex regulatory cross talk exists between cell cycle
progression and cellular response to stress, our knowledge of its
molecular basis is still limited. In this study, we present evidence
that CDC25A inhibits ASK1 by physical association, and increased
expression of CDC25A inhibits oxidant-induced activation of ASK1 and
the downstream JNK and p38 pathways, reducing the sensitivity of cells
to oxidant-induced cell death. These findings provide a novel clue to
the interaction between the cell cycle machinery and stress-responsive mechanisms.
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MATERIALS AND METHODS |
Yeast two-hybrid screening.
The entire coding region
of human CDC25A cDNA was fused in frame to the GAL4 DNA-binding domain
by using the pTBG2 vector (56) to produce a fusion protein
with CDC25A as the amino terminus. A rat ovary cDNA library in pGAD-GH
(Clontech) was screened with this bait vector in Y190 yeast
(Saccharomyces cerevisiae) by standard two-hybrid
procedures as described previously. Library plasmids recovered from the
positive (His 3+ LacZ+)
clones were reexamined by cotransformation of SFY526 yeast with the
bait plasmid followed by a 
-galactosidase assay.
Cell lines and transfection.
COS-7 cells and OVCAR-8 cells
were cultured in RPMI 1640 medium supplemented with 10% fetal bovine
serum (FBS). COS cells were transfected with 10 µg of plasmid by
electroporation at the setting of 300 V, 950 µF. Human embryonic
kidney 293 cells were cultured in Dulbecco's modified minimum
essential medium (DMEM) supplemented with 10% FBS and transfected with
Superfect (Qiagen) according to the manufacturer's instructions. To
examine the effects of CDC25A on ASK1 homo-oligomerization, 293 cells
were transfected with pcDNA3-HA-ASK1 and pcDNA3-Flag-ASK1 (1 µg of
each) together with 3 µg of pcDNA3-CDC25A. 293 cells stably
expressing the tetracycline (tet) repressor from the
pcDNA6/TR plasmid (T-REx-293 cells) were obtained from Invitrogen. To
obtain clones with tetracycline-inducible expression of CDC25A,
T-Rex-293 cells in a 10-cm-diameter culture dish were transfected with
10 µg of the pcDNA4/TO plasmid (Invitrogen) carrying the coding
region of human CDC25A cDNA, by using Superfect, and subjected to
selection for stable transfectants with 0.4 mg of Zeocin per ml. Two
weeks later, colonies were picked, expanded, and tested for induction
of the transgene by doxycycline.
Antibodies.
Anti-CDC25A (DCS120 + 121) and anti-HA (12CA5)
monoclonal antibodies were obtained from Neomarkers and Boehringer
Mannheim, respectively. The production of anti-ASK1 peptide (DAV)
antiserum was described previously (7). Antibodies against
phosphorylated forms of MKK3/6, p38, and ATF2 were purchased from New
England Biolabs. Anti-JNK1 antibody (C-17) and antihemagglutinin (HA) polyclonal antibody were purchased from Santa Cruz Biotechnology. Anti-Flag monoclonal antibody (M2) and Sepharose conjugated with the M2
antibody were obtained from Sigma.
Immunocytochemistry and confocal laser-scanning microscopy.
Transfected 293 cells or OVCAR-8 cells without transfection were
cultured on a four-well chamber slides (Nalge Nunc) for 16 h.
Cells were fixed with 10% buffered-formalin, rinsed with
phosphate-buffered saline (PBS) supplemented with 0.2% Triton X-100.
Cells were incubated with primary antibodies in PBS containing 1%
bovine serum albumin (BSA) at 25°C for 16 h. The following
dilutions of the primary antibodies were used: anti-CDC25A monoclonal
antibody (DCS120 + 121), 1:200 for 293 cells and 1:50 for OVCAR-8
cells; anti-HA polyclonal antibody, 1:200; anti-ASK1 polyclonal
antibody (H-300), 1:50. These conditions were determined by several
pilot experiments in which negligible nonspecific signals were observed
in samples stained after preincubation of the antibodies with excess
purified antigens. After being washed with PBS, cells were incubated
with fluorescein-conjugated antimouse immunoglobulin G (IgG) antibody and Texas red-conjugated anti-rabbit IgG antibody (Vector Laboratories) in PBS containing 1% BSA at 25°C for 30 min. The slides were washed with PBS, and cover glasses were mounted with Vectashield with 4',6'-diamidino-2-phenylindole (DAPI) (Vector Laboratories). The stained samples were analyzed by an LSM510 laser-scanning confocal microscope (Carl Zeiss) equipped with a ×63 water immersion objective. Beams (488 nm for fluorescein, 568 nm for Texas red, and 351 and 364 nm for DAPI) from an argon krypton laser were used for
excitation, and green, red, and blue fluorescence emissions were
detected through LP505, LP560, and LP385, respectively. The collected
images were processed with Adobe Photoshop, version 6.0. To better
present nuclear structures in printed figure panels, the blue color was printed with a pseudo color (purple) in the panels showing nonmerged DAPI staining.
Protein expression and purification.
Site-directed
mutagenesis of cDNAs was performed with the QuikChange kit
(Stratagene). Recombinant baculoviruses for expression of ASK1, cyclin
E, and CDK2(R169L) were constructed with the pBluebacHis-2 vector
(Invitrogen). Extracts were prepared by sonication of virus-infected Sf9 cells in kinase buffer, which consisted of 50 mM HEPES-KOH (pH
7.5), 10 mM MgCl2, 1 mM dithiothreitol, and 10%
glycerol. Glutathione S-transferase (GST) fusion proteins,
including various forms of CDC25A and MKK6, were expressed in
Escherichia coli BL21 transformed with the pGEX-3X vectors
(Pharmacia) carrying the cDNAs, by growing bacteria with 0.2 mM
isopropyl--D-thiogalactopyranoside (IPTG) at
25°C for 8 h. Bacteria were then lysed by sonication in PBS, and
Triton X-100 was added to a concentration of 1%. Lysates were
incubated with glutathione-Sepharose 4B (Pharmacia) at 4°C for 1 h with rotation, and beads were then washed with PBS. Proteins were
eluted in 50 mM Tris-HCl (pH 8) containing 20 mM reduced glutathione,
followed by dialysis in kinase buffer.
Protein analyses.
Cells were lysed by sonication in lysis
buffer including 50 mM HEPES-KOH (pH 7.5), 150 mM NaCl, 1 mM EDTA, 2.5 mM EGTA, 1 mM dithiothreitol, 10 mM -glycerophosphate, 1 mM NaF, 0.1 mM sodium orthovanadate, 0.2 mM phenylmethylsulfonyl fluoride, 20 µg
of aprotinin per ml, 20 µg of leupeptin per ml, 1 µg of pepstatin A
per ml, 10 µg of soybean trypsin inhibitor per ml, 10% glycerol, and
1% NP-40 or Triton X-100. For ASK1 kinase activity, extracts of Sf9
insect cells infected with the ASK1 baculovirus were incubated with
purified GST or GST-CDC25A in kinase buffer at 30°C for 30 min, and
then [
-32P]ATP (20 µM, 10 µCi per
reaction) and 1 µg of purified GST-MKK6 were added to a final volume
of 30 µl. GST-MKK6 used for the assay was a kinase-inactive KM mutant
and did not display autophosphorylation (49). For some
experiments, ASK1-expressing Sf9 extracts were immunoprecipitated with
anti-ASK1 antibody (H-300) before incubation with purified GST or
GST-CDC25A. After 30 min of further incubation, reaction was terminated
by the addition of 4×-concentrated sodium dodecyl sulfate (SDS) sample
buffer. ASK1 activity in tet-CDC25A-293 cells was measured
by immunoprecipitation of lysates (200 µg of protein) with 2 µl of
anti-ASK1(DAV) antiserum followed by in vitro kinase assay with
GST-MKK6 as described above. p38 kinase activity was measured by
immunoprecipitation of cell lysates with anti-p38 antibody followed by
incubation with nonradioactive ATP and purified GST-ATF2 and
immunoblotting with anti-phosphorylated ATF2 antibody. JNK1 activity
was determined by immunoprecipitation of lysates with anti-JNK1
antibody followed by in vitro kinase assay with purified GST-c-Jun and
[-32P]ATP. The ability of CDC25A to activate
CDK2 was determined by incubating the sample with cyclin
E-CDK2(R169L) complex immunoprecipitated from
baculovirus-coinfected Sf9 cells, followed by histone H1 kinase assay
as described previously (52). To examine ASK1
homodimerization, lysates (200-µg proteins) of 293 cells transfected
with HA-ASK1 and Flag-ASK1 were incubated at 4°C for 60 min with
Sepharose beads conjugated with anti-Flag antibody, followed by
extensive washing with the lysis buffer and Western blotting with
anti-HA antibody. Western blotting was performed with chemiluminescence reagents (Pierce). Data from autoradiography and chemiluminescence were
quantitatively analyzed with the Molecular Imager system (Bio-Rad).
Cell death assays.
Cell death responses following treatment
with H2O2 (0.5 to 4 mM),
staurosporine (500 nM), actinomycin D (100 ng/ml), and cycloheximide (3 µg/ml) were assessed by a variety of criteria, as described previously (22). Apoptotic manifestations of cell death,
which include shrinkage and cell rounding, were visualized by
phase-contrast microscopy (Nikon Diaphot; Nikon, Garden City, N.Y).
Condensation of chromatin was examined by epifluorescence, following
incubation of cells with Hoechst 33342 (Sigma Chemical Co., St. Louis,
Mo.). Cells that had lost adhesion and those maintaining adherence were isolated separately for quantification (Coulter Multisizer II; Beckman
Coulter, Hialeah, Fla.). Nonadherent cells were recovered after gentle
rinsing of plates twice with serum-free medium; adherent cells then
were detached by trypsinization. The externalization of membrane
phosphatidylserine was revealed by the binding of fluorescein
isothiocyanate (FITC)-conjugated annexin V, and propidium iodide was
employed to assess plasma membrane integrity. Mitochondrial membrane
potential was revealed by staining cells with 100 nM tetramethyl
rhodamine ethyl ester (TMRE; Molecular Probes, Eugene, Oreg.) at 37°C
for 10 min.
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RESULTS |
Identification of ASK1 as a CDC25A-interacting protein.
To investigate previously unidentified function or regulation of
CDC25A, we performed a yeast two-hybrid screen for proteins that
physically interact with CDC25A (Fig.
1A). The entire coding region of CDC25A
was subcloned into the pTBG2 bait vector to express a CDC25A-Gal4-DNA
binding domain fusion protein. A rat ovary cDNA library, constructed
for expression of fusion proteins with the Gal4 activation domain, was
screened with this bait plasmid by standard procedures to identify His
3+ LacZ+ colonies. Of
2 × 106 clones screened, nine positive
clones were reexamined by retransformation with isolated library
plasmids. Five of these clones consistently gave the two-hybrid signal
(His 3+ LacZ+). One
represented the rat 14-3-3
, which has been demonstrated to
physically interact with CDC25A (10). Another clone was
found to encode a sequence that is 95% identical to the amino acid
residues 961 to 1020 of human ASK1. This domain of human ASK1 is
located almost adjacent to the 3' side of the kinase domain, residues 676 to 936. The sequences of the other three clones showed homology to
mouse expressed sequence tag sequences, the identities of which are unknown at this moment.
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FIG. 1.
ASK1 is a CDC25A-interacting protein. (A) Yeast
two-hybrid screening for CDC25A-interacting proteins. AD, activation
domain; BD, binding domain; UAS, upstream activation sequence; minimum,
TATA box minimum promoter; X, protein encoded in the library. (B)
Complex formation of CDC25A and ASK1 in transfected COS cells. COS-7
cells were transfected with pcDNA3 expression vectors encoding the
proteins shown in the panel. At 48 h posttransfection, extracts
were prepared and analyzed by Western blotting (WB) with antibodies as
shown (left panels). To detect complexes, extracts were
immunoprecipitated (IP) with anti-CDC25A monoclonal antibody, followed
by Western blotting with anti-HA monoclonal antibody (right panel). The
arrow indicates HA-tagged ASK1 detected in CDC25A immunoprecipitation.
Ig, IgG heavy chain in immunoprecipitation cross-reacted with the
secondary antibody. (C) CDC25A-ASK1 complex in untransfected ovarian
carcinoma cells. Extracts of exponentially growing OVCAR-8 cells were
immunoprecipitated with anti-ASK1 polyclonal antibody, anti-CDC25A
monoclonal antibody, or control mouse IgG, followed by Western blotting
with the anti-ASK1 antibody.
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To confirm that ASK1 is a CDC25A-interacting protein, COS-7 cells were
transfected with expression vectors for human CDC25A
and human ASK1
with an HA tag at the carboxyl terminus, and cell
lysates were
subjected to immunoprecipitation with anti-CDC25A
monoclonal
antibodies, followed by Western blotting with anti-HA
antibody (Fig.
1B). With this assay, we observed complex formation
between
full-length ASK1 and CDC25A proteins. Furthermore, we
attempted to
detect endogenous CDC25A-ASK1 complexes in mammalian
cells without
transfection (Fig.
1C). In exponentially proliferating
ovarian
carcinoma OVCAR-8 cells, ASK1 in complex with CDC25A was
detected by
immunoprecipitation followed by Western blotting.
These data
indicate that ASK1 is a CDC25A-interacting protein
in
mammalian
cells.
Subcellular localization of CDC25A and ASK1.
To extend our
observation that CDC25A can physically associate with ASK1, we examined
whether these proteins reside in the same cellular compartment. We
transfected human embryonic kidney 293 cells for expression of CDC25A
and HA-tagged ASK1. Immunocytochemistry followed by confocal
laser-scanning microscopy showed that CDC25A was expressed both in the
nucleus and in the cytoplasm (Fig. 2, upper panels). This expression pattern of CDC25A is consistent with
previous studies with mouse 3T3 fibroblasts stably transfected with
CDC25A (17). ASK1 was expressed mostly in the cytoplasm, partially colocalizing with CDC25A, as demonstrated by the yellow color
in the merge panel. Under these conditions, only ectopically expressed
CDC25A was detected, since the expression level of endogenous CDC25A
was low in 293 cells and we used a low concentration of anti-CDC25A.
HA-ASK1 was detected by anti-HA antibody. CDC25A functions in the
nucleus as an activator of G1 CDKs. The
colocalization of CDC25A and ASK1 in the cytoplasm observed in
transfected cells might be due to forced overexpression of these
proteins. To determine whether endogenous CDC25A and ASK1 colocalize in
vivo, we performed immunocytochemistry for CDC25A and ASK1 in
exponentially proliferating OVCAR-8 cells without transfection (Fig. 2,
lower panels), in which CDC25A-ASK1 complex was detected by
immunoprecipitation (Fig. 1C). Also in these cells, we detected both
nuclear and cytoplasmic expression of CDC25A. Anti-ASK1 antibody
demonstrated that ASK1 is predominantly expressed in the cytoplasm, and
confocal analysis indicated that these two proteins partially
colocalized in the cytoplasm. Background fluorescence was negligible
when anti-CDC25A and anti-ASK1 antibodies were replaced with nonimmune
mouse and rabbit IgG, and preincubation of the primary antibodies with
purified antigens abolished the detected signals (data not shown). The clear cytoplasmic colocalization of CDC25A and ASK1 is consistent with
the physical association of CDC25A and ASK1 demonstrated by the
coimmunoprecipitation studies.
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FIG. 2.
Subcellular localization of CDC25A and ASK1. Human
embryonic kidney 293 cells, transfected with pcDNA3 expression vectors
for CDC25A and HA-tagged ASK1, were stained with anti-CDC25A monoclonal
antibody and anti-HA polyclonal antibody (upper panels). Human ovarian
carcinoma OVCAR-8 cells, without transfection, were stained with
anti-CDC25A monoclonal antibody and anti-ASK1 polyclonal antibody
(lower panels). Signals were visualized by incubation with
fluorescein-conjugated antimouse IgG antibody and Texas red-conjugated
anti-rabbit IgG antibody, followed by analysis with a confocal
laser-scanning microscope. These results are representative of three
independent sets of experiments. Bar, 5 µm.
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CDC25A inhibits ASK1 in a manner independent of the phosphatase
activity.
To address functional consequences of the CDC25A-ASK1
interaction, we compared phosphorylation of MKK3/6, physiological
substrates of ASK1 kinase activity, in COS-7 cells transfected with
ASK1 and ASK1 plus CDC25A (Fig. 3A).
Immunoblotting of cell lysates with antibodies
specific for the phosphorylated active forms of MKK3/6 demonstrated that transfection of ASK1 increased the activating phosphorylation of MKK3/6 relative to that of a mock transfection control. Cotransfection of CDC25A with ASK1 abrogated this
ASK1-associated increase in MKK3/6 phosphorylation, whereas the
expression of ASK1 or MKK3 was not affected. These data suggested that
expression of CDC25A results in decreased activity of ASK1. To further
investigate the interaction of ASK1 with CDC25A in vitro, we
constructed a recombinant baculovirus encoding human ASK1. Extracts of
Sf9 cells infected with the ASK1-encoding baculovirus contained large
amounts (a range of 10 to 100 nM) of ASK1 protein (data not shown).
Immunoprecipitates from the ASK1 virus-infected extracts with anti-ASK1
antibody (Fig. 3B, lane 1), as well as the total extracts (Fig. 3C,
lane 2), were able to phosphorylate purified GST-tagged MKK6 protein in
vitro with high activity. Autophosphorylation of ASK1 also was observed
in this assay. In contrast, extracts of uninfected Sf9 cells had
negligible activity to phosphorylate MKK6 (Fig. 3C, lane 1). Addition
of purified GST-tagged CDC25A protein to immunoprecipitated ASK1 or
ASK1-expressing Sf9 cell extracts resulted in inhibition of both MKK6
phosphorylation and ASK1 autophosphorylation (Fig. 3B, lane 2; and C,
lanes 3 to 7). Interestingly, the incubation of GST-CDC25A with ASK1
led to phosphorylation of GST-CDC25A, which decreased in parallel with
MKK6 phosphorylation and ASK1 autophosphorylation as higher doses of
CDC25A were added. Incubation of immunoprecipitated ASK1 and GST-CDC25A
without MKK6 also resulted in phosphorylation of GST-CDC25A,
accompanied by a decrease in ASK1 autophosphorylation (data not shown).
Extracts of Sf9 cells infected with a kinase-inactive mutant of
ASK1, ASK1(K709R), phosphorylated neither MKK6 nor CDC25A (data
not shown). These results suggest that CDC25A is both an inhibitor and
a substrate of ASK1.
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FIG. 3.
CDC25A inhibits ASK1 in a manner independent of its
phosphatase activity. (A) Decreased ASK1-dependent MKK phosphorylation
by cotransfection with CDC25A. COS-7 cells were transfected with pcDNA3
vectors encoding the proteins shown in the top panel. Cell extracts
were prepared at 48 h after transfection and analyzed by
immunoblotting with antibodies for ASK1, CDC25A, MKK3, and
phosphorylated active MKK3/6. (B) CDC25A is both an inhibitor and a
substrate of ASK1. ASK1 was immunoprecipitated from Sf9 cells infected
with a human ASK1-encoding recombinant baculovirus and incubated at
30°C for 30 min with purified GST (lane 1) or GST-CDC25A (lane 2) in
the presence of [-32P]ATP and purified GST-MKK6
(kinase-inactive KM mutant form). Immunoprecipitates with normal IgG
were used as a negative control (lane 3). Phosphorylation of the
proteins was analyzed by SDS-polyacrylamide gel electrophoresis (PAGE)
and autoradiography. (C) Inhibition of ASK1 by CDC25A and
CDC25A(D383N/C430S). Extracts of Sf9 cells infected with the
ASK1-encoding baculovirus were preincubated for 30 min at 30°C with
purified GST-CDC25A, GST-CDC25A(D383N/C430S), or GST at the
indicated concentration, before the addition of
[-32P]ATP and GST- MKK6(KM). After incubation for 30 more min,
phosphorylation of the proteins was analyzed by SDS-PAGE and
autoradiography. Extracts of uninfected Sf9 cells were used as negative
controls (lanes 1 and 9). wt, wild type. (D) The
CDC25A(D383N/C430S) double mutant is phosphatase inactive. The
activity of CDC25A was assessed by its ability to activate cyclin
E-CDK2 in vitro. Sf9 cells were coinfected with baculoviruses for the
expression of human cyclin E and CDK2(R169L), a mutant CDK2 known to
accumulate inhibitory phosphorylation at Tyr 15. Cyclin E-CDK2
complexes were immunoprecipitated with anti-CDK2 antibody and incubated
at 30°C for 30 min with GST-CDC25A(D383N/C430S) or wild-type
GST-CDC25A. CDK2 kinase activity then was measured with histone H1 as a
substrate, and phosphorylation of histone H1 was analyzed by SDS-PAGE
and autoradiography.
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This inhibition of ASK1 by CDC25A could be a consequence of physical
association of these two proteins, suggested by the two-hybrid
and
coimmunoprecipitation analyses. Alternatively, the phosphatase
activity
of CDC25A might play a direct or indirect role in the
inhibition of
ASK1. To examine whether the catalytic activity
of CDC25A is involved
in ASK1 inhibition, we constructed and purified
mutant CDC25A proteins
that are phosphatase inactive. The active
catalytic site of CDC25A
resides in the carboxyl terminus. The
Cys 430 residue of CDC25A is
critical in the formation of a phosphate
binding loop, while the Asp
383 residue is structurally important
in forming a conserved buried
salt bridge that is essential for
phosphate hydrolysis (
13,
14) (also see Fig.
5A). Purified
GST-CDC25A exhibited
phosphatase activity in vitro, as measured
by the hydrolysis of a
simple paranitrophenylphosphate substrate
(data not shown) and by the
dephosphorylation-dependent activation
of an authentic CDK2 substrate
(
52) (Fig.
3D). In contrast,
GST-CDC25A(D383N,C430S) was
completely inactive as a phosphatase
(Fig.
3D). Strikingly, this CDC25A
double mutant was as effective
as the wild type in its ability to
inhibit ASK1 (Fig.
3C, lanes
11 to 15). ASK1 activity also was
inhibited similarly by purified
GST-CDC25A(C430S), which exhibited
minimum phosphatase activity
(data not shown). These results indicate
that the ability of CDC25A
to inhibit ASK1 is independent of its
activity to dephosphorylate
and activate CDKs and imply that the
physical interaction itself
is important for the inhibition. This is in
sharp contrast with
previous observations that CDC25A can bind to and
dephosphorylate
Raf-1 in vitro, (
17,
66). While Raf-1
appears to activate
CDC25A phosphatase in vitro
(
17), ASK1 did not significantly
affect the
phosphatase activity of CDC25A (data not shown). Thus,
CDC25A interacts
with and inhibits ASK1 in a unique and specific
manner.
CDC25A diminishes homo-oligomerization of ASK1.
It has been
demonstrated that the mechanism of ASK1 activation involves
homo-oligomerization of this kinase (20, 37). ASK1 can
form homo-oligomers in the cell, and coumermycin-dependent oligomerization of a gyrase B-ASK1 fusion protein results in activation of the kinase (20). TRAF2, an activator of ASK1, enhances
oligomerization of ASK1 (37). To determine whether the
inhibition of ASK1 by CDC25A involves an alteration in ASK1
oligomerization, HA- and Flag-tagged ASK1 proteins were expressed
in 293 cells. Western blotting of anti-Flag immunoprecipitates
with anti-HA antibody detected spontaneous oligomerization of ASK1
(Fig. 4). Coexpression of CDC25A resulted
in a 60% decrease in the oligomerization, without affecting the levels
of HA- and Flag-tagged ASK1 proteins. These observations suggest
that physical association with CDC25A diminishes homo-oligomerization of ASK1, which is consistent with the noncatalytic inhibitory action of CDC25A.
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FIG. 4.
Increased expression of CDC25A diminishes
homo-oligomerization of ASK1. 293 cells were cotransfected with pcDNA3
expression vectors encoding the proteins shown in the panel. After
36 h, cell lysates were prepared and subjected to Western blotting
(WB) or immunoprecipitation (IP) followed by Western blotting, with
antibodies against the epitopes shown in the panel. To confirm the
specificity of immunoprecipitation, normal mouse IgG-conjugated protein
A-Sepharose was used in lane 1, instead of Sepharose conjugated with
anti-Flag monoclonal antibody (lanes 2 and 3).
|
|
The carboxyl terminus of CDC25A contains residues important
for ASK1 interaction.
We dissected further the region of CDC25A
that interacts with ASK1. The amino-terminal portion of CDC25A, amino
acid residues 1 to 336, contains 14-3-3 binding sites
(68), while the carboxyl terminus has the catalytic domain
with a phosphatase loop motif in residues 429 to 436 (14)
(Fig. 5A). It is noteworthy that ASK1
also can bind 14-3-3 proteins via the consensus
motif within residues 961 to 1020 (71), overlapping with
the domain for association with CDC25A (Fig. 5A). Truncated forms of
CDC25A, residues 1 to 386, 1 to 168, and 336 to 523, were produced as
GST-fusion proteins and tested for their abilities to bind to ASK1 in
vitro (Fig. 5B). Immunoprecipitation followed by immunoblotting
demonstrated that the carboxyl-terminus form,
CDC25A(336-523) could bind to ASK1, whereas neither
CDC25A(1-168) nor CDC25A(1-386) showed detectable binding
with ASK1 (Fig. 5B) (data not shown). In this assay, we also observed
that CDC25A could bind to kinase-inactive ASK1(K709R), as well as
wild-type ASK1. In vitro kinase assays showed that CDC25A(336-523)
could inhibit ASK1 (Fig. 5C, lower panel), although the concentrations
of this mutant required for ASK1 inhibition were higher than those of
wild-type CDC25A. At the concentration of 4 µM, CDC25A(336-523)
decreased the MKK6 kinase activity of ASK1 by 61% ± 12%, whereas
wild-type CDC25A at the same concentration demonstrated 88% ± 9%
inhibition (mean ± standard deviation; n = 3).
These observations, as well as the weaker binding of
CDC25A(336-523) with ASK1 compared to that of full-length CDC25A
(Fig. 5B), imply that other unknown regions of CDC25A cooperate with
the carboxyl terminus in the inhibitory interaction with ASK1. In
contrast, CDC25A(1-168) did not inhibit ASK1 (Fig. 5C, upper
panel). CDC25A(1-386) also showed minimum effects on ASK1 activity
(data not shown). Interestingly, in these kinase assays, both
CDC25A(336-523) and CDC25A(1-168) were phosphorylated by
ASK1, suggesting that there are multiple ASK1-dependent phosphorylation
sites in CDC25A. The kinase-inactive ASK1(K709R) was unable to cause
phosphorylation of wild-type CDC25A or these truncated mutants (data
not shown). These data suggest that the inhibitory interaction of
CDC25A with ASK1 depends on the carboxyl terminus of CDC25A.
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FIG. 5.
The carboxyl terminus of CDC25A is sufficient to bind
and inhibit ASK1 in vitro. (A) Domain structures of ASK1 and CDC25A.
The numbers shown represent amino acid residues. Names of
proteins that bind to these proteins are listed below the
putative binding domains. (B) The carboxyl terminus of CDC25A binds to
ASK1 in vitro. The full-length and truncated fragments of CDC25A were
purified from bacteria and analyzed by Western blotting (WB) with
anti-GST antibody (upper panel). The asterisk indicates full-length
GST-CDC25A(1-523), and other bands in the lane are degraded
products in the preparation. ASK1 was immunoprecipitated (IP) from Sf9
cells infected with an ASK1-encoding baculovirus and then incubated at
30°C for 45 min with the GST-CDC25A fusion proteins. After extensive
wash of the protein A-Sepharose beads, complexes were analyzed by
Western blotting with anti-GST antibody (lower panel). (C) The carboxyl
terminus of CDC25A can inhibit ASK1 in vitro. Extracts of Sf9 cells
infected with the ASK1 baculovirus were incubated at 30°C for 30 min
with purified GST or GST-tagged truncated CDC25A mutants at the
indicated concentrations, before the addition of
[-32P]ATP and GST-MKK6(KM). After incubation for
30 more min, phosphorylation of the proteins was analyzed by
SDS-polyacrylamide gel electrophoresis and autoradiography. Extracts of
uninfected Sf9 cells were used as negative controls (lanes 1 and 9).
|
|
Increased expression of CDC25A suppresses oxidant-induced
activation of ASK1 and downstream kinases.
Our finding that CDC25A
inhibits ASK1 prompted us to test whether increased expression of
CDC25A interferes with stress-responsive pathways that involve ASK1
activation. To examine the effect of increased CDC25A expression on
acute stress responses, we established clones of 293 cells with
inducible expression of CDC25A, by using the tetracycline
(tet)-regulatory system (69). Treatment of the
clones with 10 ng of doxycycline per ml for 4 h increased CDC25A
expression by five- to eightfold over the basal levels of endogenous
CDC25A expression (Fig. 6A). We examined
the effects of elevated CDC25A expression on stress kinase cascades by
treating these tet-CDC25A-293 cells with
H2O2 (Fig. 6B). The
activities of JNK and p38, as well as that of ASK1, were increased
within 20 min after treatment with 2 mM
H2O2, indicating that these
stress-responsive kinase cascades were rapidly activated by the
oxidant, as previously reported (20). When cellular CDC25A
expression was elevated by prior induction with doxycycline, the levels
of activation of ASK1, JNK1, and p38 upon
H2O2 treatment were
diminished significantly. Activation of phosphorylation of MKK3/6 also
was blocked by CDC25A upregulation. The oxidant treatment did not
affect the expression of ASK1, MKK3, JNK1, or p38. We obtained similar
results by using three independent tet-CDC25A-293 cell
clones (data not shown). The induction of CDC25A over 4 h had no
detectable effect on cell cycle progression according to flow
cytometric analyses of cellular DNA content and
incorporation of bromodeoxyuridine (data not shown). To
further confirm that the diminished activation of the stress-responsive kinases is independent of the phosphatase activity of CDC25A, we
created 293 cells with tet-inducible expression of
phosphatase-inactive CDC25A(C430S) (Fig.
7A). Treatment of these cells with
H2O2 demonstrated that induced expression of CDC25A(C430S) resulted in
diminished activation of ASK1, MKK3/6, JNK1, and p38 in a similar
fashion to the expression of wild-type CDC25A (Fig. 7B). These data
indicate that elevated expression of CDC25A suppresses oxidative
stress-dependent activation of the JNK and p38 kinase cascades and are
consistent with the upstream inhibitory effect of CDC25A on ASK1.
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FIG. 6.
Increased expression of CDC25A suppresses activation of
the stress kinase cascades upon oxidative stress. (A) CDC25A expression
after a 4-h induction with doxycycline (Dox; 10 ng/ml) in 293 cells
carrying a tetracycline-inducible CDC25A transgene. Expression of
CDC25A was measured by immunoblotting. (B) Induced CDC25A expression
diminishes the activation of ASK1, JNK1, and p38 by
H2O2 treatment. Cells were treated with
doxycycline for 4 h, and then exposed to
H2O2 (2 mM) for 20 min. For the activities of
the stress-responsive kinases, cell extracts were immunoprecipitated
with antibodies against ASK1, JNK1, or p38, and the activities were
assayed as described in Materials and Methods. Phosphorylation of
MKK3/6 was examined by Western blotting with an antibody specific for
phosphorylated active forms. Total expression of MKK3, JNK1, and p38
was determined by Western blotting.
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FIG. 7.
Ectopic expression of phosphatase-inactive
CDC25A(C430S) suppresses activation of the stress kinase
cascades upon oxidative stress. (A) The expression of CDC25A(C430S)
after a 4-h induction with doxycycline (Dox; 10 ng/ml) in 293 cells
carrying a tetracycline-inducible transgene. The sum of expression of
CDC25A(C430S) and endogenous CDC25A was measured by immunoblotting.
(B) Ectopic CDC25A(C430S) expression diminishes the activation of
ASK1, JNK1 and p38 by H2O2 treatment. Cells
were treated with doxycycline for 4 h and then exposed to
H2O2 (2 mM) for 20 min. For the activities of
the stress-responsive kinases, cell extracts were immunoprecipitated
with antibodies against ASK1, JNK1, or p38, and the activities were
assayed as described in Materials and Methods. Phosphorylation of
MKK3/6 was examined by Western blotting with an antibody specific for
phosphorylated active forms. Total expression of MKK3, JNK1, and p38
was determined by Western blotting.
|
|
Increased expression of CDC25A reduces the sensitivity of
cells to oxidative stress-induced apoptosis.
We examined whether
CDC25A-mediated inhibition of oxidant-dependent stress kinase cascades
altered the death response of cells subjected to oxidative stress.
tet-CDC25A-293 cells underwent a rapid apoptotic response
when treated with H2O2.
Within 3 h of treatment with 2 mM
H2O2, approximately 30% of
cells already exhibited manifestations of apoptosis, including
chromatin condensation, loss of mitochondrial membrane potential,
membrane phosphatidylserine externalization, and alterations of
cellular morphology and light scatter properties (Fig.
8A and data not shown). Preinduction of CDC25A in these cells by a 3-h preincubation with
doxycycline consistently exerted a modest and significant reduction in
this death response. This is evident qualitatively as a reduction in the extent of cellular condensation and loss of adhesion triggered by
H2O2 (Fig. 8A, compare
right and center panels) and quantitatively as the reduced percentages
of cells that demonstrated the loss of mitochondrial membrane potential
and diminution of cell size (Fig. 8B). The responses of these cells to
other death stimuli, such as actinomycin D, staurosporine, and
cycloheximide, were not altered by CDC25A upregulation (Fig. 8B). The
data in Fig. 8C quantify the inhibitory effect of elevated CDC25A
expression on this death response across a range of
H2O2 concentrations. Cells
with induced expression of phosphatase-inactive CDC25A(C430S) exhibited similar reductions in the death response to
H2O2 (Fig. 8D), which is
consistent with the inhibitory effects of this catalytically inactive
CDC25A mutant on the stress kinase cascades shown in Fig. 7B. These
observations suggest that the inhibitory effect of CDC25A expression on
the initiation of oxidative stress-induced kinase cascades, which is
independent of the phosphatase activity, is manifest as well by its
suppression of oxidant-induced cell death.
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FIG. 8.
Ectopic expression of wild-type or phosphatase-inactive
CDC25A reduces the sensitivity of cells to oxidant-induced death
specifically. (A) The morphology of cells after a 3-h exposure to
H2O2 (2 mM) in 293 cells carrying a
tetracycline-inducible CDC25A transgene (tet-CDC25A-293
cells). The Dox group was preincubated for 3 h with doxycycline
(10 ng/ml) to increase cellular expression of CDC25A (Fig. 6A). Cells
undergoing apoptosis exhibit round and condensed bodies with decreased
adherence to the culture dish. (B) The extent of cell death was
evaluated in cultures of tet-CDC25A-293 cells after
treatment for 9 h with actinomycin (100 ng/ml), staurosporine (500 nM), cycloheximide (3 µg/ml), and H2O2 (1 mM). Death was assessed as the loss of mitochondrial membrane potential
(diminished TMRE staining) as well as diminution of cell size
(forward-angle light scatter). The open and solid columns represent
cultures with and without a 3-h preincubation with doxycycline. Data from three independent
experiments are presented as means ± standard errors. (C)
Percentages of dead nonadherent cells in cultures of
tet-CDC25A-293 cells after a 12-h exposure to
H2O2 at the concentrations shown. The Dox group
was preincubated for 3 h with doxycycline (10 ng/ml). Data from
three independent experiments are shown as means ± standard
errors. (D) Percentages of dead nonadherent cells in cultures of
tet-CDC25A(C430S)-293 cells after a 12-h exposure to
H2O2 at the concentrations shown. The Dox group
was preincubated for 3 h with doxycycline (10 ng/ml). See Fig. 7A
for induced expression of the phosphatase-inactive CDC25A(C430S).
Data from three independent experiments are shown as means ± standard errors.
|
|
| |
DISCUSSION |
Reactive oxygen species (ROS), including peroxide, superoxide,
singlet O2, and the highly reactive hydroxyl
radical, cause oxidative damage and cellular stress. The balance
between cellular life and death is, in part, a function of the ability
of a cell to control oxidant insult (3). Cellular
antioxidants and stress responses defend against the modification of
macromolecular targets exerted by ROS (32). Accumulation
of oxidative damage also has been implicated in the degenerative
pathologies associated with organismal aging (41) and in
the development of diseases such as atherosclerosis and cancer
(reviewed in reference 21). The role of ROS as a trigger
for apoptosis, in particular, has been suggested by a large body of
work (reviewed in reference 29). Cytotoxic stresses often
are accompanied by increases in intracellular ROS levels, and the
generation of ROS within the cell may serve as a second messenger in
the initiation of death responses triggered by other stimuli. Many
antioxidants delay apoptotic responses triggered, for example, by
anticancer drugs and gamma irradiation.
Activation of ASK1 is a critical cellular response to ROS,
affecting the balance of death and survival (1). Our
finding that CDC25A inhibits ASK1 suggests that CDC25A may play an
important role in the cross talk between the cell cycle machinery and
oxidative stress responsive pathways. That the inhibitory effect of
CDC25A is manifest with respect to oxidant-triggered cell death, but not all death responses, is consistent with a specific role in the
signaling phase (as distinct from the effector phase) of cell death.
Significantly, this role of CDC25A is independent of its function as a
CDK2 phosphatase in promoting cell cycle progression, suggesting that
the physical association, but not the catalytic action, of CDC25A is
important for the inhibition of ASK1. We have shown that overexpression
of CDC25A diminishes homo-oligomerization of ASK1. The binding of
CDC25A to ASK1 at the region adjacent to the kinase domain could
inhibit oligomerization of ASK1. Homo-oligomerization is an
important process for ASK1 activation (20, 37). ASK1 interacts physically with the reduced form of thioredoxin, a
redox-sensitive protein, and is sequestered in an inactive form
(53). Oxidation of thioredoxin by intracellular ROS
results in the activation of ASK1, involving homo-oligomerization of
ASK1 and its association with death receptor-associated proteins such
as TRAF2 (20, 23, 37, 45). Thus, physical association of
CDC25A is inhibitory to this series of events leading to full
activation of ASK1.
Our data also imply that CDC25A is involved in the control of
oxidative stress responses by mitogenic and oncogenic signals. The
expression of CDC25A is regulated by mitogenic signals via the E2F
transcription factors (61). A number of cancers, including breast and head or neck cancers, display overexpression of CDC25A (6, 18, 19, 47, 63). Increased expression of CDC25A under
these mitogenic or oncogenic conditions may be related to reduced
responsiveness of immortalized or transformed cells to oxidative stress
(21, 60). Ectopic expression of CDC25A has been reported
to trigger cell death under conditions of growth factor deprivation
(16). However, our data, together with those from another
work (34), suggest that CDC25A may not be involved in the
induction of apoptosis generally. The transforming ability of CDC25A in
rodent fibroblasts (18) rather implies that overexpression of CDC25A, together with that of Ras, facilitates survival of cells
with unrestricted cell cycle progression. During oncogenic transformation, cells are thought to undergo various stresses. CDC25A
could function simultaneously to inhibit stress-responsive pathways
that normally lead to apoptosis, while it promotes cell cycle
progression in mitogenically stimulated cells. The modest reduction in
cellular susceptibility to oxidant-induced death afforded by
upregulation of CDC25A may serve, under conditions of oncogenic
transformation, to enhance the frequency of productively transformed
cells that escape apoptosis. The expression of CDC25A also could affect
the responsiveness of cancer cells to oxidative and/or genotoxic
stresses caused by cancer therapies. In a recent study
(6), overexpression of CDC25A was found in 47% of
patients with small (<1 cm) breast carcinoma and was associated with
poor prognosis. In addition, we have recently observed that ovarian cancer cell lines expressing high levels of CDC25A tend to display diminished activation of JNK1 and p38 in response to oxidative stress,
compared with those lines expressing low levels of CDC25A (X. Zou and
H. Kiyokawa, unpublished observations).
Persistent accumulation of intracellular ROS could result in DNA
damage, which triggers checkpoint signals to inhibit cell cycle
progression. The G1 checkpoint largely relies on
the p53-mediated transcription of the CDK inhibitor p21 (5,
33), but also involves degradation of CDC25A protein triggered
by the checkpoint kinase Chk1 (39, 48). When ROS
accumulation causes DNA damage, activated Chk1 facilitates degradation
of CDC25A, and ASK1 could activate the downstream stress kinases
without the inhibitory interference from CDC25A. This presents a
feedback loop from the cell cycle checkpoint to the stress-responsive
pathways. Chk1 has been demonstrated to phosphorylate
G2/M-regulatory CDC25C, facilitating cytoplasmic
sequestration of CDC25C by some of the 14-3-3 proteins (38, 48,
55). Thus, CDC25 phosphatases are critical components of both
G1 and G2 checkpoints. In
this study, we have observed that CDC25A and ASK1 colocalize primarily
in the cytoplasm, while CDC25A exists as well within the nucleus. Nuclear CDC25A presumably functions as a CDK activator. At present, it
is unclear whether the subcellular localization of CDC25A is regulated
by some kind of checkpoint mechanisms under various cellular
conditions. We have observed no gross change in the localization of
CDC25A and ASK1 in
H2O2-treated OVCAR-8 cells
or tet-CDC25A-293 cells (unpublished observations). It
remains to be clarified whether other stressful conditions alter the
subcellular localization of these two proteins.
An increase in CDC25A expression, associated with oncogenic
transformation, could have diverse effects on the fine-tuned
network of the cell cycle checkpoint and stress responses.
Increased expression of CDC25A diminishes activation of the stress
kinase cascades upon oxidative stress and suppresses the acute death
response, as shown in this study. Disruption of the
G1 checkpoint by transient overexpression of
CDC25A has been shown to increase the amount of DNA breaks after UV
irradiation (39). Many factors, including the
extracellular environment, intracellular redox state, and expression of
various genes, contribute to the determination of cell fate (i.e., cell
death, survival with restored function, and transformation). We propose
that the expression of CDC25A is one important factor that pertains
particularly to the interplay of oxidative stresses, apoptotic stimuli,
and mitogenic signaling. The detailed mechanism of the role of CDC25A
at this interface awaits further investigation.
| |
ACKNOWLEDGMENTS |
We thank Dunya Lukovic and Keiichi Morita for providing
preliminary data; Mei Ling Chen for assisting in confocal
laser-scanning microscopy; Michele Pagano, Zhiyuan Shen, and Roger
Davis for generous gifts of plasmids; and David Moons, Victor Levenson, William Beck, Ron Yu, Tony Kong, Xiaoping Du, Shahab Uddin, Leonidas Platanias, Jun-ya Kato, and Tatyana Voyno-Yasenetskaya for helpful suggestions and discussions.
This work was supported in part by funds provided to H.K. by the
American Cancer Society (RPG-00-043-01-CCG), the American Cancer
Society Illinois Division (98-41 and 99-54), the National Institutes
of Health (R01HD38085), and the Cancer Center of the University of
Illinois and funds provided to D.S.U. by the National Institutes of
Health (R01GM38800). T.T. was supported by Osaka University.
Xianghong Zou and Tateki Tsutsui contributed equally to this work.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: 900 S. Ashland
Ave., M/C 669, Chicago, IL 60607. Phone: (312) 355-1601. Fax: (312) 413-0353. E-mail: kiyokawa{at}uic.edu.
Present address: Department of Obstetrics and Gynecology, Osaka
University Medical School, Osaka 565-0871, Japan.
| |
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Molecular and Cellular Biology, July 2001, p. 4818-4828, Vol. 21, No. 14
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.14.4818-4828.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
