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J Biol Chem, Vol. 274, Issue 45, 31981-31986, November 5, 1999
From the Department of Urology, University of Texas Southwestern Medical Center, Dallas, Texas 75235-9110
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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DOC-2/DAB2, a novel phosphoprotein with
signal-transducing capability, inhibits human prostatic cancer cells
(Tseng, C.-P., Ely, B. D., Li, Y., Pong, R.-C., and Hsieh, J.-T.
(1998) Endocrinology 139, 3542-3553). However, its
mechanism of action is not understood completely. This study delineates
the functional significance of DOC-2/DAB2 protein phosphorylation and
demonstrates that in vivo activation of protein kinase C
(PKC) by 12-O-tetradecanoylphorbol-13-acetate (TPA) induces
DOC-2/DAB2 phosphorylation, including a serine residue at position 24. Mutation of Ser24 to Ala reduced DOC-2/DAB2 phosphorylation
by PKC. Using a synthetic Ser24 peptide
(APS24KKEKKKGSEKTD) or recombinant DOC-2/DAB2 as
substrates, PKC DOC-2 (deletion in ovarian
carcinoma 2), with a molecular mass of 82 kDa,
belongs to the Disabled (Dab) gene family.
Recently, we demonstrated that DOC-2/DAB2 is up-regulated in
degenerated rat ventral prostate induced by androgen deprivation (1).
Histologically, elevated levels of DOC-2/DAB2 are associated with an
enriched basal cell compartment, a progenitor cell for glandular
epithelium. This suggests that DOC-2/DAB2 may be involved in the
homeostasis of prostate regeneration (1). In addition, stable
expression of DOC-2/DAB2 in a prostatic cancer cell line significantly
reduces its in vitro growth rate concomitant with an
increase in G1 cell fractions. It also decreases
anchorage-independent growth on soft agar (1). Other types of cancer
cell lines, such as the SKOV3 ovarian cancer cell line (2) and the
choriocarcinoma cell lines Jar, JEG, and BeWo (3), demonstrate similar
results. Therefore, DOC-2/DAB2 appears to be a potent negative
regulator of carcinoma cell growth.
The primary structure of DOC-2/DAB2 reveals that DOC-2/DAB2 is a
putative signaling molecule with protein-protein interaction and
protein phosphorylation as two possible mechanisms modulating its
activity (1). The N-terminal phosphotyrosine-interacting domain shares
significant homology with mouse DAB1 (4). Disruption of the mouse
Dab1 gene disturbs neuronal layering in the cerebral cortex,
hippocampus, and cerebellum (5). The similar phenotypes of mouse
Dab1 null mice, Reeler, Scrambler, and
Yotari, indicate that mouse DAB1 functions as a signaling
molecule regulating cell positioning in the developing brain (6).
Indeed, the phosphotyrosine-interacting domain of mouse DAB1 is found
to bind SRC protein-tyrosine kinase, and therefore, mouse DAB1 may play
a key role in key signal transduction pathways involved in the
formation of neural networks (4). In addition to the
phosphotyrosine-interacting domain, DOC-2/DAB2 also contains a
C-terminal proline-rich domain that interacts with the SH3 domain of
GRB2 and reduces the binding between GRB2 and SOS. This suggests that
DOC-2/DAB2 may modulate growth factor/Ras pathways (7).
DOC-2/DAB2 contains several consensus protein kinase C
(PKC),1 casein kinase II
(CKII), and cAMP-dependent protein kinase phosphorylation sites (1), implying that protein phosphorylation may modulate DOC-2/DAB2 activity. Colony-stimulating factor-1 induces DOC-2/DAB2 protein phosphorylation in a mouse macrophage cell line (8). We also
found that the phosphorylation of DOC-2/DAB2 is modulated by receptor
protein-tyrosine kinase pathways, such as the epidermal growth
factor,2 and the PKC
activation pathway, such as stimulation by
12-O-tetradecanoylphorbol-13-acetate (TPA) as described in
this study. PKC is the receptor of TPA and is a member of the
serine/threonine kinase family composed of at least 12 isoforms (9).
Structural and functional studies indicate that PKC isoforms are likely
to have distinct and distinguishable functions (10-15).
One of the properties ascribed to activation of PKC by TPA is the
ability to alter gene expression. Among genes transcriptionally induced
by TPA are ornithine decarboxylase, collagenase, and stromelysin. The
promoter regions of several TPA-inducible genes share a conserved TPA-responsive element recognized by the transcription factor AP-1
(16). This study investigated the impact of DOC-2/DAB2 protein
phosphorylation on the PKC-mediated signal transduction cascade. We
have mapped the TPA-induced DOC-2/DAB2 protein phosphorylation site to
Ser24, which appears to modulate the DOC-2/DAB2 inhibition
of AP-1 transcription activity. Results indicate that phosphorylation of Ser24 is mediated by PKC Materials--
The AP-1 reporter gene construct Cell Cultures--
COS, NbE, and C4-2 cells were maintained in T
medium supplemented with 5% fetal bovine serum as described
previously (1).
Construction of Plasmids--
The
SalI-NotI fragments of pCI-neo-p82 and
pCI-neo-p59 (1) were subcloned into pET-21b(+); and the
XbaI-NotI fragments of pET-21b(+)-p82 and
pET-21b(+)-p59, containing p82 and p59 cDNA, respectively, were
subcloned back into the pCI-neo vector to make the T7-p82 and T7-p59
expression plasmids. The [32P]Orthophosphate Cell Labeling--
Metabolic
labeling of cells was performed as described (18), and
immunoprecipitated, 32P-labeled DOC-2/DAB2 was subjected to
phosphoamino acid analysis (19) or cyanogen bromide phosphopeptide
mapping (20).
In Vitro Protein Kinase Assay--
The immunocomplex PKC assay
was performed as described (21) in the presence or absence of the
activators. The CKII protein kinase assay was performed as described by
the manufacturer (Promega, Madison, WI) with equal molar concentrations
of the indicated substrates.
Reporter Gene Assay--
C4-2 cells (3 × 105
cells/35-mm plate) were transfected with an equal amount of DNA
mixture. In every experiment, 0.38 µg of Immunoprecipitation Assay--
The recombinant GRB2-GST fusion
protein was induced by
isopropyl-
Wild-type DOC-2/DAB2 protein and its mutant were expressed in COS
cells 24 h after DNA transfection. Cells were collected in 0.5 ml
of phosphate-buffered saline supplemented with 1% Triton X-100 and a
mixture of protease inhibitors. After a low speed centrifugation, 0.4 ml of the supernatant was incubated overnight at 4 °C with 60 µl
of GRB2-GST-glutathione-Sepharose or GST-glutathione-Sepharose alone.
After centrifugation, the pellet was washed twice and dissolved in the
sample buffer. After electrophoresis, the gel was transferred to a
filter and probed with antiserum against the T7 tag.
TPA Induces DOC-2/DAB2 Protein Phosphorylation at Serine
24--
DOC-2/DAB2 appears to be a phosphoprotein (8). However, the
nature of the phosphorylation and the upstream protein kinase that
mediates DOC-2/DAB2 phosphorylation have not yet been elucidated. To
study DOC-2/DAB2 protein phosphorylation, NbE cells were treated with
the PKC activator TPA (100 ng/ml). Both DOC-2/DAB2 (i.e. p82) and its splicing variant, p59, showed a mobility shift on SDS-polyacrylamide gel electrophoresis (PAGE) within 5 min, and this
was sustained for at least 30 min after TPA treatment (Fig. 1A). Transfection of the
T7-tagged p82 or p59 expression plasmid into COS or NbE cells (data not
shown) followed by TPA treatment also resulted in a similar mobility
shift of exogenously expressed DOC-2/DAB2. This finding suggests that a
protein modification occurred in DOC-2/DAB2 after TPA treatment.
To determine whether the mobility shift of protein on SDS-PAGE is
caused by changes in protein phosphorylation, we labeled T7-p59-transfected cells with [32P]orthophosphate, and
cell extracts were immunoprecipitated with the anti-T7 tag antibody 30 min after TPA treatment. A basal level of p59 phosphorylation occurred
in control cells, whereas TPA treatment resulted in an increase in p59
phosphorylation (Fig. 1B, left panel). The
majority of the phosphorylation occurred at the serine residue as
determined by phosphoamino acid analysis (Fig. 1B,
right panel). A series of DOC-2/DAB2 deletion mutants was
constructed to map the phosphorylation site (Fig. 1C,
upper panel). Although the basal level of protein
phosphorylation was still detected in the N-terminal deletion mutant
(
We have further used PKC Is a DOC-2/DAB2 Protein Kinase--
Since S24KK
appears to fit the consensus phosphorylation site for either PKC or
CKII, we tested whether PKC
To determine whether PKC directly phosphorylates Ser24 of
DOC-2/DAB2 in vitro, the recombinant proteins His-T7- Phosphorylation of Ser24 Is Essential for the
Inhibitory Effect of DOC-2/DAB2 on TPA-induced AP-1 Activity--
To
further delineate the possible impact of Ser24
phosphorylation on DOC-2/DAB2 function, we examined the effect of
DOC-2/DAB2 on the PKC-mediated signaling pathway. Since TPA enhances
the binding of the AP-1 transcription factor to a specific
cis-element of many growth-related genes and increases gene
transcription, we cotransfected the indicated DOC-2/DAB2 expression
plasmids with a luciferase reporter gene construct (i.e.
To further determine the significance of Ser24
phosphorylation of DOC-2/DAB2, we cotransfected a series of mutants
with the reporter gene construct into C4-2 cells. As shown in Fig.
4C, expression of N-terminal DOC-2/DAB2 Does Not Interact with GRB2
Protein--
Previously, DOC-2/DAB2 was demonstrated to interact with
GRB2 (7), which may be a potential underlying mechanism for its AP-1
inhibitory function. Therefore, we tested whether Although DOC-2/DAB2 is believed to be a candidate tumor suppressor
in several cancer cell lines (1-3), the mechanism of its inhibition of
cell growth is unknown. In this work, we describe the modulation of
DOC-2/DAB2 protein phosphorylation by the PKC activator TPA and the
critical role of the phosphorylation in determining its function. We
demonstrate that DOC-2/DAB2 serves as a negative regulator in the
PKC-mediated signaling axis and may inhibit cell growth through
inhibiting AP-1 activity that has been associated with cell
proliferation and tumorigenicity (23). In addition to our studies, Xu
et al. (7) have shown that the C terminus of DOC-2/DAB2
prevents GRB2 from binding to SOS. Although, the functional impact of
this interaction is unclear, it suggests that DOC-2/DAB2 may interfere
with the signal transduction pathway activated by receptor
protein-tyrosine kinase.
Several mitogenic stimuli, including colony-stimulating factor-1, TPA,
phosphatidylcholine-specific phospholipase C, and sphingomyelinase, are
known to induce phosphorylation of DOC-2/DAB2. However, unlike the DAB1
protein, which contains a phosphotyrosine moiety, our data and others
(8) demonstrate that the major protein phosphorylation site of
DOC-2/DAB2 is the serine residue. We mapped a key PKC-modulated DOC-2/DAB2 protein phosphorylation site to Ser24, a
conserved residue of DOC-2/DAB2 among human, mouse, and rat species
(1). The impact of Ser24 phosphorylation on the function of
DOC-2/DAB2 is very significant because mutation of Ser24 to
Ala abolishes the inhibitory effect of DOC-2/DAB2 on TPA-induced AP-1
activity (Fig. 4). Interestingly., we observed that the
Ser24 mutants of DOC-2/DAB2 can compete with their
wild-type proteins in a dose-dependent manner (Fig. 5 and
Table I), indicating that Ser24 in DOC-2/DAB2 is a critical
amino acid motif modulating its activity. Furthermore, TPA-induced AP-1
activity is substantially inhibited in the p59-expressing C4-2 sublines
(i.e. p59-18 and p59-23) (Table I). This may be one of the
underlying mechanism(s) contributing to the slower growth of both
p59-18 and p59-23 in vitro (1). Similarly, by transfecting
the AP-1 reporter construct into NbE cells with detectable endogenous
DOC-2/DAB2 levels (1), we found that TPA failed to increase AP-1
activity in this cell line (data not shown). Taken together, these data
indicate that DOC-2/DAB2 represents a novel factor in the modulation of
the PKC-elicited signaling pathway.
We still do not know how DOC-2/DAB2 inhibits AP-1 activity in the
nucleus, although Xu et al. (7) demonstrated that DOC-2/DAB2 can bind to GRB2, which may account for the inhibition of the GRB2-mediated signaling pathway. However, our results indicate that
N-terminal DOC-2/DAB2 (i.e. Another important issue is the mechanism controlling the
phosphorylation of Ser24. Among the protein kinases we
tested (PKC In summary, our results indicate that DOC-2/DAB2 is phosphorylated at
Ser24 by PKC, which plays a critical role in controlling
AP-1 activity. The regulation of DOC-2/DAB2 protein phosphorylation may
in turn regulate its inhibitory function in cell proliferation and
tumorigenicity. It may define a novel mechanism for the transduction of
negative growth signals from the membrane to the nucleus.
II, PKC
, and PKC
(but not casein kinase II)
directly phosphorylated Ser24 in vitro. This
indicates that DOC-2/DAB2 is a PKC-specific substrate. Since expression
of wild-type DOC-2/DAB2, but not the S24A mutant, inhibited TPA-induced
AP-1 activity in prostatic epithelial cells, phosphorylation of
Ser24 appears to play a critical role in modulating
TPA-induced AP-1 activity. Taken together, these data suggest that
PKC-regulated phosphorylation of DOC-2/DAB2 protein may help its growth
inhibitory function.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
II, PKC, and PKC, but
not CKII. This suggests that the PKC phosphorylation of
Ser24 in DOC-2/DAB2 may be an underlying mechanisms for
its tumor-suppressive function.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
73/+63-Col-luc
was provided by Dr. Michael Karin (University of California, San Diego,
CA). The T7-tagged pRSV-PKCII, pRSV-PKC and pRSV-PKC
expression plasmids have been described previously (17). The
Ser24 peptide (APS24KKEKKKGSEKTD) and
the Ala24 peptide (APA24KKEKKKGSEKTD)
were synthesized by Genemed Biotechnologies, Inc. (San Francisco, CA).
B mutant was created by deleting a
1.2-kilobase Bsu36I fragment from pCI-T7-p82. The N
mutant was generated by four-fragment ligation with appropriate restriction enzymes, resulting in the deletion of the first 636 base
pairs of p82. Site-directed mutagenesis with polymerase chain reaction
was used to create B-S24A, B-S32A, B-S24A,S32A, and B-S241A,S249A. The BsaBI fragments of both p82 and p59
were subcloned into BsaBI-digested B-S24A to create a
single amino acid mutant of both p82 and p59.
73/+63-Col-luc and 0.38 µg of pRSV--galactosidase plus the indicated amount of DOC-2/DAB2
expression plasmid were included. To ensure that an equal amount of DNA
mixture was added to each dish, pCI-neo (control plasmid) was used to
make up the differences between each condition. Luciferase and
-galactosidase activities were determined as described (21). -Fold
induction = (TPA(luciferase activity (treatment background))/(-galactosidase activity (treatment background)))/(ethanol(luciferase activity (treatment background))/(-galactosidase activity (treatment background))).
-D-thiogalactopyranoside for 4-6 h. The
bacteria were spun down, and lysed in phosphate-buffered saline
supplemented with 1% Triton X-100 and 1 mM
phenylmethylsulfonyl fluoride. The lysate was sonicated, and then all
insoluble material was spun down. The GRB2-GST protein was immobilized
on glutathione-Sepharose (Amersham Pharmacia Biotech) according to the
manufacturer's instruction. The supernatant was incubated with
glutathione-Sepharose for 30 min, washed three times, and resuspended
as a 50% slurry in phosphate-buffered saline supplemented with 1%
Triton X-100.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Characterization of TPA-induced DOC-2/DAB2
protein phosphorylation. A, mobility shift of
DOC-2/DAB2 after TPA treatment of NbE cells. Cell extracts harvested
from NbE cells after the indicated treatment were subjected to Western
blot analysis with the mouse p96 monoclonal antibody. B,
in vivo phosphorylation of p59 and phosphoamino acid
analysis. COS cells were transfected with T7-p59 and metabolically
labeled with [32P]orthophosphate (300 µCi/ml). After
incubation with either ethanol (E) or TPA (T) for
30 min, T7-p59 was immunoprecipitated, fractionated on
SDS-polyacrylamide gel (left panel), and subjected to
phosphoamino acid analysis (right panel). C,
schematic representation and in vivo phosphorylation of
T7-tagged DOC-2/DAB2 and its deletion mutants. COS cells were
transfected with the indicated plasmids and subjected to in
vivo phosphorylation analysis (upper panel). Portions
of the immunocomplexes were used to perform Western blot analysis with
the anti-T7 tag antibody for equal loading (lower panel).
IP, immunoprecipitation; WB, Western blot.
N), TPA-induced protein phosphorylation was abolished (Fig.
1C, lower panel). In contrast, TPA induced the
phosphorylation of a p82 mutant (B) with a deletion of the majority
of the C terminus (Fig. 1C, lower panel). To
avoid possible transfection artifacts, we demonstrated similar levels
of protein expression by each transfection as determined by Western
blotting (Fig. 1C, lower panel). The higher extra
band seen in B experiments by Western blotting is immunoglobulin
protein, which has a similar molecular mass compared with B. These
results suggest that the N terminus of DOC-2/DAB2 may harbor key
phosphoserine residue(s) responsive to TPA.
B to map the TPA-induced protein
phosphorylation site with CNBr phosphopeptide mapping (Fig.
2A). TPA treatment enhanced
the phosphorylation of at least two additional peptides, with estimated
molecular masses of 13.6/13.2 and 7.3 kDa, respectively, compared with
the ethanol control (Fig. 2B). The protein sequence of
DOC-2/DAB2 revealed four consensus PKC/CKII phosphorylation sites
(i.e. SKKE) at serines 24, 32, 241, and 249. The double
mutation of Ser241 and Ser249
(B-S241A,S249A) did not affect TPA-induced B phosphorylation (Fig. 2B). However, the double mutation of Ser24
and Ser32 (B-S24A,S32A) completely abolished the protein
phosphorylation of B by TPA, indicating that phosphorylation of
either Ser24 or Ser32 is induced by TPA (Fig.
2B). Therefore, a single mutation of Ser24 or
Ser32 was used to precisely map the TPA-induced protein
phosphorylation site in DOC-2/DAB2. As shown in Fig. 2C,
TPA-induced DOC-2/DAB2 protein phosphorylation was detected only in
B and B-S32A, but not B-S24A. In p82-S24A and p59-S24A, the
7.3-kDa phosphopeptide induced by TPA was also eliminated (Fig.
2D). Thus, Ser24 is one of the TPA-induced
protein phosphorylation sites in DOC-2/DAB2.
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Fig. 2.
TPA-induced DOC-2/DAB2 protein
phosphorylation at Ser24. A, shown are the
predicted sizes of CNBr-digested peptide fragments of B. Three major
peptides were generated in the CNBr digestion of B. B-D,
COS cells transfected with the indicated T7-tagged DOC-2/DAB2
constructs were metabolically labeled with
[32P]orthophosphate (300 µCi/ml). The T7-tagged
immunoprecipitated phosphoproteins were fractionated on a 10%
SDS-polyacrylamide gel and visualized by autoradiography (B
and C, upper panels). Portions of the
immunocomplexes were subjected to Western blot analysis with the
anti-T7 tag monoclonal antibody for the control of equal loading
(B and C, middle panels). The
DOC-2/DAB2 phosphoproteins were excised, and CNBr peptide mapping was
performed (B and C, lower panels; and
D). WT, wild-type; IP,
immunoprecipitation; WB, Western blot; E,
ethanol; T, TPA.
II, PKC, PKC, and CKII could use
the synthetic Ser24 peptide
(APS24KKEKKKGSEKTD) of DOC-2/DAB2 as an
in vitro substrate. In the presence of PKC activators, all
PKC isoforms tested demonstrated comparable PKC activity toward the
Ser24 peptide (Fig.
3A). In contrast, CKII failed
to phosphorylate the Ser24 peptide, whereas myelin basic
protein was phosphorylated significantly (Fig. 3B). The
phosphorylation of Ser24 by PKC was abolished when an
Ala24 peptide (APA24KKEKKKGSEKTD) of DOC-2/DAB2
was used (Fig. 3A), indicating that the Ser24
peptide is a specific substrate for PKC.
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Fig. 3.
PKC is the DOC-2/DAB2 protein kinase.
A, in vitro PKC assay. T7-PKC II, T7-PKC,
and T7-PKC were expressed in COS cells and immunoprecipitated with
the anti-T7 tag antibody. The immunocomplex protein kinase assays were
performed with the indicated peptides (5 µg/reaction) in the presence
or absence of PKC activators. B, in vitro CKII
protein kinase assay. CKII protein kinase assays using myelin basic
protein or the indicated peptides as substrates were performed as
described under "Experimental Procedures." C, expression
of the bacterial recombinant proteins His-T7-B and His-T7-B-S24A.
The recombinant proteins were purified with a His tag purification kit
and subjected to Western blot analysis with the anti-T7 tag antibody.
D, in vitro phosphorylation of His-T7-B and
His-T7-B-S24A by PKC. Equal amounts of His-T7-B and
His-T7-B-S24A (5 µg) were used as substrates in the in
vitro immunocomplex PKC assay. E, phosphopeptide
mapping by CNBr. The phosphoproteins His-T7-B and His-T7-B-S24A
in D were subjected to CNBr peptide mapping and visualized
by autoradiography. PS, phosphatidylserine; MBP,
myelin basic protein; EGF-R, epidermal growth factor
receptor.
B
and His-T7-B-S24A were generated (Fig. 3C). As shown in
Fig. 3D, His-T7-B was phosphorylated by PKCII, PKC,
and PKC, whereas His-T7-B-S24A phosphorylation was substantially
reduced in vitro. The CNBr phosphopeptide map revealed that
the 7.3-kDa phosphopeptide was the key substrate for PKCII, PKC,
or PKC (Fig. 3E) and was consistent with the in
vivo data shown in Fig. 3C. Clearly, protein
phosphorylation of DOC-2/DAB2 can be controlled by PKC activity.
73/+63-Col-luc) containing a TPA-responsive element derived from the
collagenase gene promoter into a human prostate cancer cell line
(C4-2). We found that p82 elicited a dose-dependent
inhibition of TPA-induced AP-1 activity (Fig.
4A). Similarly, expression of
p59 and B, but not N, in C4-2 cells demonstrated the inhibitory
effect on TPA-induced AP-1 activity, indicating that the N terminus of
DOC-2/DAB2 is critical in regulating AP-1 activity (Fig.
4B). We also observed a significant decrease in the AP-1
activity of the p59-transfected C4-2 sublines (1) with TPA compared
with that of wild-type or control plasmid-transfected C4-2 cells (Table
I). Such a decrease suggests that
DOC-2/DAB2 protein can function as a potent negative regulator to
modulate TPA-induced AP-1 activity.
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Fig. 4.
Different effects of DOC-2/DAB2 and its
mutants on TPA-induced AP-1 activity. A,
dose-dependent inhibition of TPA-induced AP-1 activity by
p82; B, deletion of the N terminus of DOC-2/DAB2 abolishes
the inhibitory effect of DOC-2/DAB2 on TPA-induced AP-1 activity;
C, mutation of Ser24 abolishes the inhibition of
TPA-induced AP-1 activity by DOC-2/DAB2. Increasing concentrations of
p82 (A) or 0.24 µg of DOC-2/DAB2 expression plasmid
(B and C) was cotransfected with 73/+63-Col-luc
and pRSV--galactosidase into C4-2 cells. Luciferase activity was
determined 24 h after TPA treatment and normalized with
-galactosidase activity. The data represent means ± S.D. from
three independent experiments.
A significant decrease in TPA-induced AP-1 activity in
DOC-2/DAB2-transfected cells
B-S24A, p82-S24A, and p59-S24A showed
greater luciferase activity than p82. Thus, Ser24 in
DOC-2/DAB2 is critical for maintaining its inhibitory effect on
TPA-induced AP-1 activity. Moreover, B-S24A and p82-S24A neutralized the inhibitory activity of B and p82 on AP-1 activity in a
dose-dependent manner (Fig.
5). In p59-expressing C4-2 cells (Table
I), increased expression of p59-S24A also decreased the inhibitory
effect of p59 on AP-1 activity. These results clearly indicate that
Ser24 phosphorylation of DOC-2/DAB2 plays a critical role
in modulating AP-1 inhibitory activity.
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Fig. 5.
Mutation of Ser24 abolishes the
inhibitory effect of DOC-2/DAB2 on TPA-induced AP-1 activity.
A, dose-dependent effect of B-S24A on
antagonizing the inhibitory activity of B on TPA-induced AP-1
activity; B, dose-dependent effect of p82-S24A
on antagonizing the inhibitory activity of p82 on TPA-induced AP-1
activity. Increasing concentrations of B-S24A (A) or
p82-S24A (B) were cotransfected with 73/+63-Col-luc and
pRSV--galactosidase into C4-2 cells. Luciferase activity was
determined 24 h after TPA treatment and normalized with
-galactosidase activity. The data represent means ± S.D. from
three independent experiments.
B or N interacts with GRB2. As expected, in the presence of GRB2, p82, p59,
and N could be precipitated (Fig. 6,
A and B). In contrast, in the presence of ethanol
(Fig. 6A) or TPA (Fig. 6B), B failed to be
precipitated by GRB2 protein. This indicates that the N-terminal DOC-2/DAB2 protein does not interact with GRB2 (Fig. 6, A
and B). This interaction appears to be specific because
GST-glutathione-Sepharose alone did not precipitate any DOC-2/DAB2
protein (Fig. 6C). Taken together, these data suggest that
the mechanism for the AP-1 inhibitory effect of DOC-2/DAB2 may be
mediated by GRB2-independent pathway(s).
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Fig. 6.
Interaction of GRB2 and DOC-2/DAB2
protein. COS cells (8 × 105 cells/60-mm Petri
dish) were transfected with each indicated cDNA construct (4 µg)
for 24 h. After incubation with either ethanol (A) or
TPA (B and C) for 30 min, cell lysates were
prepared from each condition. An aliquot of recombinant
GRB2-GST-glutathione-Sepharose (~200 µg; A and
B) or GST-glutathione-Sepharose (C) was incubated
with 400 µl of cell lysates. After overnight incubation and washing,
bound proteins were subjected to SDS-PAGE analyses and blotted with
either the anti-T7 tag antibody for DOC-2/GRB2 (upper
panels) or the anti-GST antibody for GRB2 (middle
panels). An aliquot of each cell lysate (~30 µg) was also
subjected to SDS-PAGE analysis and blotted with the anti-T7 tag
antibody (lower panels) as an internal control.
IP, immunoprecipitation; WB, Western blot.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
B), with or
without phosphorylation, does not interact with GRB2 (Fig. 6).
Therefore, this AP-1 inhibitory effect must be mediated by
GRB2-independent pathway(s). Alternatively, DOC-2/DAB2 may inhibit the
function of signal molecules in PKC-elicited pathway(s). However, we
observed that Ser24 and Ser24/Ser32
mutants appear to affect the phosphorylation status of other serine
residues as indicated by CNBr phosphopeptide mapping (Fig. 2),
suggesting a critical role for Ser24 phosphorylation in
modulating the protein conformation of DOC-2/DAB2. Moreover, analysis
of the amino acid sequence surrounding Ser24 revealed a
potential nuclear localization signal
(S24KKEKKKG). The sequence KKEK has been shown
to associate with the actin-interacting capability of villin (23),
suggesting that the subcellular localization of DOC-2/DAB2 may be
affected by protein phosphorylation. Interestingly, we observed that
TPA induces accumulation of DOC-2/DAB2 in the particulate fraction
(i.e. membrane fraction) of prostatic epithelial
cells.2 The accumulated DOC-2/DAB2 protein in the
particulate fraction appears to be phosphorylated as determined by the
mobility shift on SDS-PAGE. This observation is in accord with reports
suggesting that phosphorylation within the sequence immediately
N-terminal to the minimal nuclear localization signal modulates the
transport kinetics of the respective protein (24, 25). The effect of Ser24 phosphorylation on DOC-2/DAB2 protein localization,
which may explain how DOC-2/DAB2 regulates AP-1 activity, warrants
further investigation.
II, PKC, PKC, and CKII), PKC preferentially
phosphorylates DOC-2/DAB2 both in vivo and in
vitro. PKC has been implicated in many aspects of cellular functions, including cell proliferation and differentiation, T-cell activation, and gene activation (10-15). Although functional
redundancies between PKC isoforms have been shown, other reports
suggest that individual PKCs may have distinct functions (10-15,
26-28) and substrate specificity (13, 29-30). Similarly, as shown in
Fig. 3E, we observed a slightly different phosphorylation
profile for PKC. The largest phosphopeptide is not phosphorylated by
PKC. This suggests the distinct activity of PKC isoforms toward the
phosphorylation of B. In addition, there was an increased expression
of both DOC-2/DAB2 and PKC mRNAs in the enriched basal
epithelial cells of degenerated prostate in castrated rat
(1),2 suggesting the involvement of PKC in the control
of DOC-2/DAB2 activity in prostate gland homeostasis. Kinetic studies
with purified recombinant PKC will be required to further elucidate
whether Ser24 of DOC-2/DAB2 is a preferential substrate for
any PKC isoform.
| |
ACKNOWLEDGEMENTS |
|---|
We thank Dr. Megan J. Robinson for technical assistance with phosphoamino acid analysis, Drs. Melanie H. Cobb and John D. McConnell for critical review of this manuscript, and Andrew Webb for editing.
| |
FOOTNOTES |
|---|
* This work was supported in part by National Institutes of Health Grant CA59939 (to J.-T. H.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed. Tel.: 214-648-3988;
Fax: 214-648-8786; E-mail: hsieh@utsw.swmed.edu.
2 C.-P. Tseng, B. D. Ely, R.-C. Pong, Z. Wang, and J.-T. Hsieh, unpublished data.
| |
ABBREVIATIONS |
|---|
The abbreviations used are: PKC, protein kinase C; CKII, casein kinase II; TPA, 12-O-tetradecanoylphorbol-13-acetate; GST, glutathione S-transferase; PAGE, polyacrylamide gel electrophoresis.
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