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Molecular and Cellular Biology, January 2001, p. 249-259, Vol. 21, No. 1
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.1.249-259.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Biochemical and Biological Functions of the
N-Terminal, Noncatalytic Domain of Extracellular Signal-Regulated
Kinase 2
Scott T.
Eblen,
Andrew D.
Catling,
Marcela C.
Assanah,
and
Michael J.
Weber*
Department of Microbiology and Cancer Center,
School of Medicine, University of Virginia, Charlottesville,
Virginia 22908
Received 20 April 2000/Returned for modification 30 May
2000/Accepted 11 October 2000
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ABSTRACT |
Extracellular signal-regulated kinase 1 (ERK1) and ERK2 are
important components in signal transduction pathways involved in many
cellular processes, including cell differentiation and proliferation.
These proteins consist of a central kinase domain flanked by short N-
and C-terminal noncatalytic domains. While the regulation of ERK2 by
sequences within the kinase domain has been extensively studied, little
is known about the small regions outside of the kinase domain. We
performed mutational analysis on the N-terminal, noncatalytic domain of
ERK2 in an attempt to determine its role in ERK2 function and
regulation. Deleting or mutating amino acids 19 to 25 (ERK2-
19-25)
created an ERK2 molecule that could be phosphorylated in response to
growth factor and serum stimulation in a MEK (mitogen-activated protein
kinase kinase or ERK kinase)-dependent manner but had little kinase
activity and was unable to bind to MEK in vivo. Since MEK acts as a
cytoplasmic anchor for the ERKs, the lack of a MEK interaction resulted
in the aberrant nuclear localization of ERK2-19-25 mutants in
serum-starved cells. Assaying these mutants for their ability to affect
ERK signaling revealed that ERK2-19-25 mutants acted in a
dominant-negative manner to inhibit transcriptional signaling through
endogenous ERKs to an Elk1-responsive promoter in transfected COS-1
cells. However, ERK2-19-25 had no effect on the phosphorylation of
RSK2, an ERK2 cytoplasmic substrate, whereas a nonactivatable ERK
(T183A) that retained these sequences could inhibit RSK2
phosphorylation. These results suggest that the N-terminal domain of
ERK2 profoundly affects ERK2 localization, MEK binding, kinase
activity, and signaling and identify a novel dominant-negative mutant
of ERK2 that can dissociate at least some transcriptional responses
from cytoplasmic responses.
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INTRODUCTION |
The extracellular signal-regulated
kinases (ERKs), or mitogen-activated protein (MAP) kinases, are
ubiquitous serine/threonine protein kinases that lie in a signaling
pathway downstream of the ras oncogene. These kinases are
involved in signaling cascades that regulate a number of cellular
pathways, including the control of both cell proliferation and
differentiation (29). The two best-characterized ERKs,
ERK1 and ERK2, are activated by phosphorylation on threonine and
tyrosine in a TEY sequence within the kinase domain (19,
31) by the dual-specificity kinases MEK1 and MEK2 (MAP kinase
kinase kinase or ERK kinase). Activation of various MAP kinase family
members by MEKs in mammalian cells has recently been shown to be
facilitated by scaffold proteins that selectively bind and bring
together specific components of the signaling pathway (35,
41).
In cultured cells deprived of serum and growth factors, ERK1 and ERK2
are predominantly inactive and reside in the cytoplasm (10, 18,
27, 34). Ectopic expression of ERKs causes their localization in
the nucleus and in the cytoplasm of serum-starved as well as
proliferating cells (13, 18). Cytoplasmic retention of the
ERKs under serum-starved conditions can be controlled by association
with the MEKs and by MAP kinase phosphatase 3 (MKP-3), which act as
cytoplasmic anchors for the ERKs due to the presence of nuclear export
signals in these anchoring proteins (5, 13, 15, 28).
Immunofluorescence studies have demonstrated that MEKs appear to be
predominantly cytoplasmic in both quiescent and proliferating cells
(27, 48); however, nuclear localization of MEK has been
observed under certain conditions (22, 40).
Upon mitogen stimulation of the cell, the ERKs are quickly
phosphorylated by the MEKs and a portion of the active ERK population translocates to the nucleus (10, 18, 27). Phosphorylation of the ERKs results in their dimerization, which facilitates their nuclear localization (6, 25). Nuclear localization appears to occur by both active transport and passive diffusion
(1). In addition, neosynthesis of unstable proteins
appears to be required to facilitate sustained ERK nuclear
localization, suggesting that these unidentified labile proteins may
serve as nuclear anchors for the ERKs (26). ERK activation
and nuclear translocation have been demonstrated to be required for
cellular proliferation and S-phase entry in fibroblasts (5,
30).
The ERK proteins consist of a central kinase domain flanked by short N-
and C-terminal extensions. Crystallographic studies of ERK2 have
demonstrated that the phosphorylation of the activating sites causes
major structural changes within the kinase domain involving rotation of
the phosphorylation lip that allows the active kinase to bind substrate
(6, 47). The N- and C-terminal extensions outside of the
kinase domain lie on the surface of the molecule and undergo only small
alterations in position upon phosphorylation of ERK2 (6,
47).
While the activation and regulation of the ERKs has been extensively
studied, little is known about the short N-terminal region that resides
outside of the kinase domain. A portion of the C-terminal domain was
shown to be required for ERK dimerization and nuclear translocation
(6). Recent reports have focused on the C-terminal domain's role as a docking site for interactions between ERK2 and its
regulators, as well as its role in the subcellular localization of ERK2
(33, 39).
We used deletion and substitution mutagenesis of short sequences within
the N-terminal noncatalytic domain of ERK2 in an effort to determine
what function, if any, it has in regulation of the protein's
activation and function. ERK2 mutants containing mutations in amino
acids 19 to 25 did not associate with MEK in cotransfected cells and
had little kinase activity but did retain the ability to be
phosphorylated on their activating sites in a MEK-dependent manner in
response to mitogens. The failure of these mutants to bind to MEK was
associated with their nuclear localization even in serum-starved cells.
Screening these mutants for their ability to affect signaling to ERK
substrates revealed that they acted as dominant-negatives in signaling
to nuclear, but not to cytoplasmic, ERK substrates. These results
identify the N-terminal domain as being important in regulating the
activity, MEK association, substrate targeting, and localization of ERK2.
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MATERIALS AND METHODS |
Cell culture, transfections, and plasmids.
COS-1 cells were
grown in Dulbecco's modified Eagle medium (DMEM) (Life Technologies,
Rockville, Md.) supplemented with 10% fetal calf serum (FCS) at 37°C
with 5% CO2. All transfections were performed using
Lipofectamine (Life Technologies). FLAG-ERK2 has been described
previously (37). ERK2 mutants were generated using the
Transformer mutagenesis kit (Clontech, Palo Alto, Calif.). ERK2-3-7
and ERK2-10-19 also contain a C-terminal nonfunctional KT3 tag
sequence, which accounts for the increase in the size of the protein
product. Hemagglutinin (HA)-MEK constructs have been described
previously (8). 5X GAL4-luciferase and GAL4-Elk1 were
provided by Richard Maurer. HA-tagged Ras V12 was provided by Channing
Der. HA-RSK2 was provided by Thomas Sturgill.
Luciferase assays.
COS-1 cells were cotransfected in
triplicate with 1 µg of 5X GAL4-luciferase, 50 ng of GAL4-Elk1, 100 ng of HA-Ras V12 (or 100 ng of HA-MEK1 S218/222D), and a FLAG-ERK2
plasmid as indicated. Differing amounts of ERK2 plasmid were required
to obtain equal protein expression. Wild-type (WT) ERK2 (WT-ERK2)
plasmid amounts were 5, 10, 50, and 100 ng. ERK2-10-19 amounts were
10, 20, 100, and 200 ng. ERK2-10-25 and ERK2-19-25 plasmid
amounts were 40, 80, 400, and 800 ng. All transfection amounts were
brought up to a total of 1.95 µg of DNA per transfection with the
appropriate empty vector. After transfection the cells were placed in
serum-free DMEM overnight and harvested at 24 h. Luciferase
activity was determined on a Monolight 2010 Luminometer (Analytical
Luminescence, Ann Arbor, Mich.). Western blot analyses for protein
expression were performed on an equal amount of lysate from each
sample. For the MEK1-versus-MEK2 experiment, 100 ng of either one was cotransfected with 100 ng of WT-ERK2, 200 ng of ERK2-10-19, or 800 ng of an ERK2-19-25 mutant. For the competition experiment, 100 ng
of HA-MEK1 S218/222D was cotransfected with 800 ng of ERK2-19-25 or
empty vector. WT-ERK2 was titrated in with 5, 10, 25, 50, and 100 ng of plasmid.
Coimmunoprecipitations.
COS-1 cells were cotransfected with
2 µg of HA-MEK2 plasmid and a total of 4 µg of FLAG-ERK2 plasmid
and empty vector in order to obtain equal ERK2 protein expression.
After transfection the cells were incubated overnight in DMEM
supplemented with 10% FCS. The following day the cells were washed
twice and placed in serum-free DMEM for 4 h to inactivate the ERK
pathway. The cells were harvested in hypotonic buffer, and
immunoprecipitations were performed as described previously (7,
13).
For RSK2 and GAL4-ELK experiments, the cells were starved for 5 h
and either harvested or stimulated for 10 min with 10 ng of epidermal
growth factor (EGF) per ml. Cells were harvested in hypotonic buffer
(20 mM HEPES [pH 7.4], 2 mM EDTA, 2 mM EGTA) and lysed by
centrifugation. For the GAL4-Elk1 experiment, the cells were sonicated
prior to centrifugation. Coimmunoprecipitations were performed as
described above.
Immunofluorescence.
COS-1 cells were cotransfected with
HA-MEK2 and FLAG-ERK2 plasmids as indicated. The following day the
cells were replated onto coverslips and later serum starved for 4 h before fixing in 4% paraformaldehyde and permeabilizing with 0.2%
Triton X-100. The fixed cells were blocked in 20% goat serum and then
probed with monoclonal M2 anti-FLAG antibody (Sigma) and polyclonal
anti-HA antibody (Babco, Richmond, Calif.) in 5% goat serum. After
washing in 0.05% Tween 20 in phosphate-buffered saline, the cells were probed with fluorescein isothiocyanate-conjugated anti-mouse and Texas
red-conjugated anti-rabbit antibodies (Jackson Immunoresearch, West
Grove, Pa.). Cells were DAPI stained (Sigma), dried, and mounted with
Vectashield mounting media (Vector Laboratories, Burlingame, Calif.).
Indirect immunofluorescence examination was performed on a Leica microscope.
Kinase assays.
COS-1 cells were transfected with ERK2
plasmids to obtain equal protein expression. All transfections were
brought up to 2.0 µg of total DNA with pCDNA3 vector. The following
day, the cells were serum starved for 4 h and either harvested or
stimulated for 5 min with either 10% FCS or 10 ng of EGF (Upstate
Biotechnology, Lake Placid, N.Y.) per ml. For the PD098059 experiment,
either 50 µM PD098059 (BIOMOL, Plymouth Meeting, Pa.) or the dimethyl sulfoxide (DMSO) vehicle was added for the last hour of serum starvation and during the stimulation. The cells were harvested, and
the kinase assays were performed on immunoprecipitated FLAG-ERKs as
described previously (35). Phosphorylated myelin basic
protein (MBP) was cut from the membrane and quantitated by Cerenkov
counting. FLAG-ERKs were visualized by Western blotting using M5
anti-FLAG antibody (Sigma). Anti-phospho-ERK blotting was performed
using a polyclonal antibody that specifically recognizes the dually phosphorylated (T183 and Y185), active forms of the ERKs
(46).
Cell fractionation.
COS-1 cells were transfected with 1 µg
of HA-MEK2 and ERK expression plasmids and empty vector to obtain equal
protein expression. Cells were serum starved for the last 4 h
before harvest at 24 h posttransfection. Cells were harvested in
RSB (10 mM Tris-HCl [pH 7.4], 2 mM MgCl2, 2 mM
phenylmethylsulfonyl fluoride, 5 µg of aprotinin per ml, 1 µg of
leupeptin per ml, 200 µM Na orthovanadate) and left on ice for 5 min.
Triton X-100 was added from a 10% stock to a final concentration of
0.5%, and the cells were left for another 5 min on ice. The cells were
sheared by passage through a 21-gauge needle three times and then spun
for 5 min at 1,000 × g through a 1 M sucrose pad to
pellet the nuclei. The supernatant (cytoplasm and membranes) was
removed, and the pellets (nuclei) were washed once in 3 ml of RSB and
centrifuged as before. Equal cell equivalents were run on sodium
dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) gels and immunoblotted.
RSK phosphorylation.
COS-1 cells were transfected with 0.1 µg of HA-RSK2, 0.1 µg of HA-RasV12, and either 0.875 µg of
WT-ERK2, 2 µg of ERK2 T183A, or 7 µg of ERK2-19-25-7A to obtain
equal ERK expression. Cells were put in 10% serum overnight and serum
starved for 5 h before harvest at 24 h in FLAG buffer
(35). HA RSK2 was immunoprecipitated with 12CA5 antibody
preconjugated to protein A-agarose (Roche), and the pellets were washed
three times in lysis buffer and run on a 10 to 15% acrylamide-SDS
gel. Phospho-RSK2 was determined by immunoblotting with an antibody to
phospho-Ser 380 of RSK1 (Upstate Biotechnology), a site of
autophosphorylation in response to ERK phosphorylation
(11).
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RESULTS |
N-terminal ERK2 mutants.
ERK2 consists of a central Ser/Thr
kinase domain that is flanked by short N- and C-terminal domains that
lie on the surface of the protein (47). To examine roles
that the N-terminal region may play in the function of ERK2, a series
of deletion and substitution mutants was constructed. These constructs
were placed into the pCDNA3 vector containing a sequence coding for an
N-terminal FLAG epitope (Fig. 1A). Figure
1B shows the crystal structure of unphosphorylated ERK2
(47), with the sequences affected by the mutations
highlighted.
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FIG. 1.
Diagram of ERK2 mutants and crystal structure of ERK2,
with mutated regions highlighted. (A) The amino acid sequence of the N
terminus of murine ERK2 up to the beginning of the kinase domain is
shown, with the open boxes indicating sequences that were deleted from
the various mutants and the underlining indicating sequences that were
mutated to Ala. The shaded box indicates the kinase domain, and the
open box indicates the C terminus. All constructs encode an N-terminal
FLAG epitope tag, while mutants ERK2-3-7 and ERK2-10-19 contain
an additional nonfunctional KT3 tag at the C terminus, which accounts
for their decreased mobility in SDS-PAGE compared to wild-type ERK2.
(B) The crystal structure of unphosphorylated ERK2, solved by Zhang and
colleagues (47), is shown using the RasMol program.
Mutated sequences are colored as follows: ERK2-3-7 is yellow,
ERK2-10-19 is green, ERK2-10-25 is green and red, and
ERK2-19-25 is red. Lys 52 is shown in blue; Thr 183 and Tyr 185 are
shown in purple.
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Mutants lacking residues 19 to 25 are phosphorylated in response to
mitogens but have little activity.
As an initial means to
characterize these N-terminal ERK2 mutants, we determined their ability
to be phosphorylated and activated in response to mitogens. WT-ERK2 and
the ERK2 mutants were transiently transfected into COS-1 cells, and the
cells were serum starved and then stimulated with EGF or serum for 10 min. Immunoprecipitated FLAG-ERKs were assayed for their ability to
phosphorylate MBP (Fig. 2), an ERK2
substrate that does not have an ERK2 docking site (39). As
expected, the activity of WT-ERK2 was greatly stimulated by both serum
and by EGF, with kinase activity being induced 15.6-fold and 12-fold,
respectively, over that seen in starved cells. The activity of
ERK2-10-19 was also stimulated in response to mitogens (20-fold by
serum and 17.7-fold by EGF), although the overall level of activity was
not as high as that of WT-ERK2. This suggests that deletion of a
portion of the N terminus in ERK2-10-19 caused this mutant to lose
activity compared to WT-ERK2, although the fold stimulations in
activity compared to WT-ERK2 were similar.
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FIG. 2.
ERK2-19-25 mutants are phosphorylated in response to
mitogens but have little kinase activity. COS-1 cells were transfected
with either empty vector, WT-ERK2, or an ERK2 mutant. The following day
the cells were serum starved for 4 h before stimulation for 5 min
with either 10 ng of EGF per ml or 10% serum. FLAG-ERK
immunoprecipitates were used for an in vitro kinase assay using MBP as
the substrate. The reaction mixtures were immunoblotted with antibodies
for FLAG and phospho-ERK to determine protein expression and
phosphorylation. SF, serum-free; P-ERK, phospho-ERK.
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In contrast, ERK2-
19-25 and ERK2-
19-25-GP (Fig.
2), as well as
ERK2-
10-25 and ERK2-
19-25-7A (data not shown) had less
than 1%
of the kinase activity towards MBP compared to WT-ERK2
when cells were
stimulated by either mitogen, suggesting that
deletion or mutation of
this region destroys the kinase activity
of ERK2. This reduction of
kinase activity was in agreement with
experiments in which a large
portion of the N terminus of ERK2
was replaced with that of p38
(
43). However, ERK2-
19-25 and
ERK2-
19-25-GP were
nonetheless phosphorylated on the regulatory
sites by endogenous MEKs
in response to mitogens, as shown by
a phospho-ERK blot of the
immunoprecipitates from the kinase assay
using an antibody that
recognizes only the dually phosphorylated
forms of the ERKs
(
46). So while ERK2-
19-25 and ERK2-
19-25-GP
had
little kinase activity, they were phosphorylated in response
to EGF and
serum to the same level as WT-ERK2 and ERK2-
10-19.
Metabolic
labeling of transfected cells demonstrated that ERK2-
19-25
was
phosphorylated on Thr and Tyr to the same extent as WT-ERK2
in response
to EGF stimulation (data not
shown).
To confirm that the mutations had not changed the specificity of ERK2
as an in vivo substrate for MEK, the experiment was
repeated with
parallel dishes of cells treated with either DMSO
or the MEK inhibitor
PD098059 (Fig.
3). This drug specifically
inhibits the activation of MEK1 and MEK2 (
2). As expected,
treatment of cells with PD098059 inhibited the phosphorylation
of
WT-ERK2 and ERK2-
10-19 by EGF and serum. PD098059 also inhibited
the
phosphorylation of ERK2-
10-25 and ERK2-
19-25 in response
to
mitogens, indicating that the observed phosphorylation of these
mutants, as with WT-ERK2, was dependent on endogenous MEKs. Similar
results were obtained with the MEK inhibitor U0126 (
12),
and
both inhibitors were effective towards phosphorylation of
ERK2-
19-25-7A
and ERK2-
19-25-GP (data not shown). These mutants
can therefore
be phosphorylated in a MEK-dependent manner, but they
have almost
no kinase activity. The fact that endogenous MEKs still
phosphorylate
them to the same level as WT-ERK2 in vivo suggests that
the mutations
do not result in gross distortions of ERK2 structure,
since MEK
will not phosphorylate denatured ERKs (
19,
36).
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FIG. 3.
Phosphorylation of ERK2 mutants in response to EGF is
MEK dependent. COS-1 cells were transfected and serum starved as
described for Fig. 2. For the last hour of serum starvation the cells
were treated with either DMSO or 50 µM PD098059 to inhibit MEK
activation. The cells were then stimulated for 10 min with either EGF
or serum in the presence of either DMSO or PD098059. The cells were
harvested, and FLAG-ERK2 immunoprecipitates were immunoblotted with
anti-FLAG and anti-phospho-ERK antibodies. SF, serum-free. P-ERK,
phospho-ERK.
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ERK proteins with mutations at residues 19 to 25 do not
coimmunoprecipitate with MEK.
MEK binds to ERK through the
N-terminal domain of MEK (3, 15). We next determined if
the N-terminal domain of ERK2 was required for association with MEK.
WT-ERK2 or an ERK2 deletion mutant was cotransfected with HA-MEK2 into
COS-1 cells and harvested after serum starvation (Fig.
4). FLAG-ERK2-HA-MEK2 complexes were immunoprecipitated with antibodies to the HA epitope. The results indicate that WT-ERK2, ERK2-3-7, and ERK2-10-19 were all bound equally to MEK2 in serum-starved COS-1 cells (Fig. 4A). However, no
ERK2 mutant that contained either a deletion or substitution mutation
in residues 19 to 25 could be found to associate with MEK2 in
coimmunoprecipitations (Fig. 4), suggesting that residues 19 to 25 of
ERK2 were required for MEK2 association. Identical results were
obtained in experiments using HA-MEK1 (data not shown).
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FIG. 4.
Mutation of residues 19 to 25 of ERK2 inhibits binding
to MEK. COS-1 cells were transfected with plasmids for HA-MEK2 and
FLAG-ERKs as indicated. (A and B) The following day the cells were
serum starved for 4 h before harvest at 24 h
posttransfection. The cells were lysed in hypotonic buffer, and the
proteins were immunoprecipitated with antibodies to the HA epitope. The
immunoprecipitations were immunoblotted with antibodies to FLAG and HA.
For the lysate blots, an equal amount of soluble cell lysate was run on
SDS-PAGE gels and immunoblotted for FLAG-ERK. IP, immunoprecipitate.
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ERK2 mutants that do not bind to MEK localize to the nucleus and
cytoplasm of serum-starved cells.
In cycling COS-1 cells grown in
culture, ERK1 and ERK2 exist in the nucleus and cytoplasm. Four hours
of serum withdrawal is sufficient to inactivate the ERK pathway,
causing the ERKs to be retained in the cytoplasm (data not shown).
Recent reports have identified the MEKs as cytoplasmic anchors for the
ERKs, retaining the ERKs in the cytoplasm under conditions of serum starvation (15). To determine if the localization of
ERK2-19-25 and ERK2-19-25-GP in serum-starved cells was altered
compared to WT-ERK2 by their inability to bind to MEK, COS-1 cells were transfected with wild-type and mutant ERKs, with or without
cotransfected HA-MEK2. The cells were serum-starved before fixation and
processed for immunofluorescence. In the absence of cotransfected MEK2, WT-ERK (Fig. 5A), ERK2-10-19 (Fig.
5B), ERK2-19-25 (Fig. 5C), and ERK2-19-25-GP (Fig. 5D) localized
in the nucleus and the cytoplasm. The nuclear localization of exogenous
ERK was most likely due to the inability of the endogenous ERK
anchoring proteins (e.g., MEKs) to hold the excess FLAG-ERKs in the
cytoplasm, causing the ERKs to enter the nucleus (15).
Cotransfection of HA-MEK2 resulted in the redistribution of WT-ERK2 to
the cytoplasm in serum-starved cells (Fig. 5E). In addition,
ERK2-3-7 (data not shown) and ERK2-10-19 (Fig. 5F) behaved in a
manner similar to WT-ERK2, with mostly cytoplasmic staining and little
nuclear staining in starved cells cotransfected with MEK2. This
supported the coimmunoprecipitation data in Fig. 4, demonstrating that
the ERKs that bind to MEK2 colocalize with it in the cytoplasm of
serum-starved cells. In contrast, ERK2-19-25 (Fig. 5G),
ERK2-19-25-GP (Fig. 5H), ERK2-19-25-7A (data not shown), and
ERK2-10-25 (data not shown) had prominent staining in both the
nucleus and the cytoplasm of cells cotransfected with MEK2. The
overexpression of MEK2 within the cell did not appear to alter the
localization of these ERK-19-25 mutants. Therefore, it appeared that
the mutation of the 7-amino-acid sequence in the N terminus of ERK2
prevented the colocalization of these mutants with MEK2 in vivo,
allowing these mutant ERKs to enter the nucleus under conditions of
serum starvation, a time when ERK2 is normally retained in the
cytoplasm. In all of the cotransfected cells HA-MEK2 was localized in
the cytoplasm (Fig. 5I to L), consistent with previous reports that
defined a nuclear export signal present in the N terminus of MEK
(14). Localization of HA-MEK2 did not appear to be
modified by the presence of exogenous ERK (data not shown).
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FIG. 5.
ERK2-19-25 mutants localize to nucleus and cytoplasm
of serum starved cells cotransfected with MEK2. COS-1 cells were
cotransfected with plasmids for FLAG-ERKs and empty vector (A to D) or
FLAG-ERKs (E to H) and HA-MEK2 (I to L). The cells were serum starved
before fixing in 4% paraformaldehyde at 48 h posttransfection.
Fixed cells were probed with monoclonal M2 anti-FLAG and polyclonal
anti-HA antibodies. Empty vector was cotransfected with plasmids for
WT-ERK2 (A), ERK2-10-19 (B), ERK2-19-25 (C), or ERK2-19-25-GP
(D). Parallel cultures were cotransfected with WT-ERK2 (E) and MEK2
(I), ERK2-10-19 (F) and MEK2 (J), ERK2-19-25 (G) and MEK2 (K), or
ERK2-19-25-GP (H), and MEK2 (L).
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To confirm the intracellular localization of WT-ERK2 and the ERK2
mutants under conditions of serum starvation, cell fractionation
was
performed on serum-starved COS-1 cells cotransfected with
HA-MEK2 and
FLAG-ERKs. As expected, transfected MEK2 was localized
in the cytoplasm
of serum-starved COS-1 cells (Fig.
6).
WT-ERK2
and ERK2-
10-19 were also found exclusively in the cytoplasm
of
serum-starved cells, presumably being anchored there by the
cotransfected
MEK2. However, in agreement with the immunofluorescence
data (Fig.
5), ERK2-
10-25 and ERK2-
19-25 were localized both in
the cytoplasm
and in the nucleus (Fig.
6). These mutants appeared to be
equally
distributed in the nucleus and cytoplasm regardless of the
presence
of cotransfected MEK2.
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FIG. 6.
Cellular distribution of FLAG-ERK proteins by
fractionation. COS-1 cells were cotransfected with plasmids for HA-MEK2
and either a FLAG-ERK2 or empty vector. The cells were washed and serum
starved for 4 h before harvest at 48 h posttransfection.
Nuclear and cytoplasmic fractions were prepared, and equal cell
equivalents of each lysate were subjected to SDS-PAGE. Proteins were
transferred to nitrocellulose and blotted with antibodies to FLAG and
HA. N, nucleus; C, cytoplasm.
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ERK2-19-25-GP is deficient in association with ERK substrates in
vivo.
To determine if the mutation affected the ability of
ERK2-19-25-GP to associate with known ERK2 substrates in vivo, we
performed coimmunoprecipitation experiments with Elk1, a member of the
ets transcription factor family and a nuclear ERK target,
and RSK2, an ERK cytoplasmic target. The D domain of Elk1 associates
with an unknown region of ERK2 (45). COS-1 cells were
cotransfected with plasmids for a GAL4-Elk1 fusion protein and either
WT-ERK or ERK2-19-25-GP. The cells were later serum-starved and
stimulated with EGF. GAL4-Elk1 was coimmunoprecipitated with WT-ERK2
only from stimulated cells, but not from serum-starved cells, in
agreement with a previous report that only phosphorylated ERK2 was able to associate with Elk1 (45). GAL4-Elk1 could not be
coimmunoprecipitated with ERK2-19-25-GP when the cells were starved
or stimulated with EGF, demonstrating that ERK2-19-25-GP was
deficient in Elk1 binding even when it was phosphorylated.
ERK2 has been reported to bind to the cytoplasmic substrate RSK through
aspartic acid residues in the C terminus of ERK2 interacting
with
lysine residues in RSK (
39). We tested the ability of
WT-ERK2
and ERK2-
19-25-GP to associate with RSK2 in
coimmunoprecipitation
experiments in cotransfected COS-1 cells that
were starved or
stimulated with EGF (Fig.
7B). In agreement with results reported
by Smith et al. (
38), WT-ERK2 was associated with RSK2 in
both
starved and stimulated cells. However, ERK2-
19-25-GP was only
weakly associated with RSK2 under either condition. These data
demonstrate that ERK2-
19-25-GP was deficient in binding to ERK
substrates.
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FIG. 7.
ERK2-19-25-GP has reduced association with ERK2
substrates. (A) COS-1 cells were cotransfected with plasmids for
GAL4-Elk1 and either WT-ERK2 or ERK2-19-25-GP. The cells were serum
starved for 5 h and stimulated with EGF for 15 min as indicated.
FLAG-ERK immunoprecipitates were run on a gel and immunoblotted with
antibodies for Elk1 and FLAG. (B) Cells were cotransfected with
plasmids for HA-RSK2 and either WT-ERK2 or ERK2-19-25-GP. The cells
were starved and stimulated with EGF as described for panel A. Anti-HA
immunoprecipitates were run on a gel and immunoblotted with antibodies
for FLAG and HA. IP, immunoprecipitate; exp., exposure.
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ERK2-19-25 mutants inhibit ERK nuclear signaling to Elk1.
To screen these mutants for their effect on ERK nuclear signaling, we
determined their ability to stimulate transcriptional activation of
Elk1. MAP kinases including the ERKs, JNKs, and p38 proteins are able
to phosphorylate and activate Elk1, phosphorylating residues in the
C-terminal transcriptional activation domain (9, 16, 17, 24,
42). The ability of WT-ERK2 and the ERK2 mutants to signal to a
fusion protein consisting of the DNA binding region of GAL4 fused to
the transcriptional activation domain of Elk1 was assayed by use of a
luciferase reporter construct containing five GAL4 consensus binding
sites in the promoter (32). A constitutively activated
form of Ras, RasV12, was also cotransfected to activate the ERK pathway
under serum-free conditions. The addition of RasV12 was able to
stimulate Elk1-specific transcription sixfold over the basal activity
seen by addition of GAL4-Elk1 alone (Fig.
8A). The RasV12 was presumably activating
endogenous MAP kinase pathways, including the ERKs and stress-activated
protein kinases, to phosphorylate and activate GAL4-Elk1.
Cotransfection with increasing amounts of WT-ERK2 further stimulated
GAL4-Elk1 transcriptional activity in the presence of RasV12 in a
dose-dependent manner. Addition of increasing amounts of ERK2-3-7 or
ERK2-10-19 also stimulated Elk1 transcriptional activity to levels
similar to those stimulated by WT-ERK2 (Fig. 8A and data not shown).
However, expression of ERK2-10-25 or ERK2-19-25 inhibited
signaling to Elk1 in a dose-dependent manner compared to cells that
received RasV12 and empty vector (Fig. 8A), with both mutants
decreasing luciferase activity by about 30%. This data suggested that
ERK2 molecules lacking amino acids 19 to 25 were capable of acting in a
dominant-negative manner to inhibit signaling of RasV12 through
endogenous MAP kinase pathways to Elk1. Similar results were obtained
with ERK2-19-25-7A and ERK2-19-25-GP (data not shown). Blotting
for expression of the transfected constructs shows that equal amounts
of RasV12 were present in each sample and that expression of WT-ERK2
and of the deletion mutants was comparable.
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|
FIG. 8.
ERK2-19-25 mutants act as dominant negatives in
signaling to an Elk1 responsive reporter. (A) COS-1 cells were
cotransfected in triplicate with plasmids for 5X GAL4-luciferase,
GAL4-ELK1, HA-RasV12, and increasing amounts of the indicated FLAG-ERK2
construct. The cells were incubated in serum-free DMEM overnight before
harvesting at 24 h and determination of luciferase activity. An
equal amount of protein from one lysate of each triplicate closest to
the mean was immunoblotted with anti-FLAG and anti-HA antibodies to
determine the expression of HA-RasV12 and FLAG-ERK2 in each sample. (B)
The same experiment as described for panel A was performed, except MEK1
S218/222D was transfected in place of HA-RasV12. (C) 5X
GAL4-luciferase, GAL4-ELK1, ERK2 plasmids, and either mutationally
activated MEK1 or MEK2 were transfected into COS-1 cells in triplicate
and luciferase assays were performed on cell lysates as described for
panel B. (D) COS-1 cells were cotransfected in triplicate with 5X
GAL4-luciferase, GAL4-ELK1, HA-MEK1 S218/222D, ERK2-19-25 and
increasing amounts of WT-ERK2, as indicated. Luciferase activity was
determined 24 h after transfection. S/D, S218/222D.
|
|
The ability of ERK2-
10-25 and ERK2-
19-25 to only partially
inhibit signaling stimulated by RasV12 could mean that additional
signaling to GAL4-Elk1 occurs through stimulation of the JNKs
and p38
stress-activated kinases as well as the ERKs. To specifically
target
signaling through the ERKs to GAL4-Elk1, we performed the
same
experiment using a mutationally activated form of MEK1, MEK1
S218/222D,
instead of RasV12, so that the only signaling to GAL4-Elk1
would be
through the ERK pathway. Cotransfection of MEK1 S218/222D
with the
GAL4-Elk1 reporter system increased luciferase activity
twofold over
that seen in the absence of MEK1 S218/222D, suggesting
that indeed only
a portion of the signaling by RasV12 to GAL4-Elk1
may have occurred
through the ERKs. As was seen in Fig.
8A, titration
of increasing
amounts of WT-ERK2, ERK2-
3-7, or ERK2-
10-19 increased
luciferase
activity in a dose-dependent manner over that seen
with MEK1 S218/222D
and empty vector (Fig.
8B and data not shown).
However, expression of
ERK2-
10-25 or ERK2-
19-25 effectively
inhibited the luciferase
expression activated by MEK1 S218/222D
in a dose-dependent fashion.
While approximately 30% of signaling
of RasV12 to GAL4-Elk1 was
inhibited by ERK2-
10-25 or ERK2-
19-25
(Fig.
8A), there was
complete inhibition of signaling by ERK2-
10-25
or ERK2-
19-25 when
MEK1 S218/222D was the upstream stimulus (Fig.
8B). Thus, these ERK
mutants were able to completely inhibit the
ability of MEK1 S218/222D
to signal through endogenous ERKs to
GAL4-Elk1. To determine if this
inhibition was specific for a
MEK isoform, we repeated the experiment
using mutationally activated
MEK1 or mutationally activated MEK2 in the
presence of a single
amount of WT-ERK2 or ERK2 mutant (Fig.
8C). The
data demonstrate
that signaling by both isoforms of MEK through
endogenous ERKs
to Elk1 was inhibited by ERK2-
19-25,
ERK2-
19-25-7A, or ERK2-
19-25-GP.
To determine if increased expression of WT-ERK2 can rescue the
dominant-negative effect of ERK2-
19-25 on signaling to GAL4-Elk1,
the luciferase assays were performed using a constant amount of
ERK2-
19-25 cotransfected with MEK1 S218/222D (Fig.
8D). The
expression
of increasing amounts of WT-ERK2 was able to overcome the
dominant-negative
affect of ERK2-
19-25 and restore signaling to
GAL4-Elk1 in a
dose-dependent
manner.
ERK2-19-25-7A does not inhibit phosphorylation of the ERK
substrate RSK2.
To determine if ERK2-19-25 mutants inhibited
signaling not only to a nuclear target but to a cytoplasmic ERK
substrate as well, we assessed the ability of ERK2-19-25-7A to
affect phosphorylation of the ERK substrate RSK2. RSK isoforms are
phosphorylated and activated upon ERK activation and translocate to the
nucleus (10). ERKs phosphorylate Ser 363 of RSK1,
stimulating kinase activity and autophosphorylation of RSK1 at Ser 380 (11). Analogous phosphorylation sites exist in RSK2
(11). To determine if RSK2 activation was dependent on MEK
activity in response to activated Ras, cells cotransfected with RasV12
were treated with DMSO or the MEK inhibitor U0126 (12).
Immunoblotting HA-RSK immunoprecipitates with antibodies against
phosphorylated serine 380 of RSK1 showed that RSK2 was only weakly
phosphorylated under serum-starved conditions but that its
phosphorylation could be stimulated by cotransfection of RasV12 (Fig.
9A). This increase in RSK2
phosphorylation was MEK dependent, as addition of the MEK inhibitor
U0126 inhibited RSK2 phosphorylation. To determine the effect of ERK
cotransfection on RSK phosphorylation, WT-ERK2, ERK2 T183A, or
ERK2-19-25-7A was cotransfected with RasV12 (Fig. 9B).
Cotransfection of WT-ERK2 increased the amount of phospho-HA-RSK2,
while cotransfection of ERK2 T183A, a phosphorylation site mutant and a
dominant-negative ERK2 that can bind to MEK, inhibited RSK2
phosphorylation. However, ERK2-19-25-7A had no effect on the
phosphorylation of RSK2. These data demonstrate that ERK2-19-25-7A
did not act as a dominant negative in signaling to a cytoplasmic ERK
substrate.
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|
FIG. 9.
ERK2-19-25-7A does not inhibit phosphorylation of
cytoplasmic ERK substrate RSK2. (A) COS-1 cells were transfected with
plasmids for HA-RSK2 and HA-RasV12 and serum starved for 5 h
before harvest at 24 h. The MEK inhibitor U0126 was added for the
last 2 h before harvest. HA immunoprecipitates were immunoblotted
for phospho-RSK and HA-RSK2. Lysates were immunoblotted for HA-RasV12.
(B) COS-1 cells were transfected as described for panel A with the
addition of cotransfection with the indicated ERK plasmid. HA-RSK2 was
immunoprecipitated and immunoblotted with antibodies for
HA-phosphorylated RSK. Lysates were immunoblotted for FLAG-ERK and
HA-RasV12. P-RSK, phospho-RSK.
|
|
| |
DISCUSSION |
In this paper we characterize the role of the short N-terminal,
noncatalytic domain of p42 ERK2 in ERK2 regulation. Mutation of amino
acids 19 to 25 (VGPRYTN) in the N terminus caused profound effects in
ERK2 activity, MEK binding, localization, and signaling. Mutation of
these residues to alanine gave identical results, as did leaving the
glycine and proline intact and replacing the other five residues with
alanine. This region lies in a random coil structure at one end of the
molecule and appears to be necessary for kinase activity of ERK2, as
mutations in this region generated a mutant protein with little
activity (Fig. 2). This is in agreement with a previously described
chimera of ERK2 and p38, in which the N terminus of ERK2 through
subdomain II was replaced with that of p38. As with ERK2-19-25, this
p38-ERK2 chimera suffered a major loss in kinase activity
(43).
While the binding site for the ERKs on MEKs has been localized to a
small region in the N terminus of MEK, the region(s) of the ERKs
required for MEK binding are as yet unclear. Experiments by Brunet and
Pouyssegur (4) suggest that MAP kinases receive upstream
signals in a region between kinase subdomains III and IV of the MAP
kinases. Other investigators have proposed that there are several sites
on the ERKs that are required for recognition by the MEKs
(43). In agreement with this, recent reports identify acidic residues in the C terminus (39) and a broad region
in the N terminus (44) of ERK2 as being necessary for ERK
phosphorylation and MEK binding. The crystal structure of
unphosphorylated ERK2 (47) shown in Fig. 1B shows that the
N and C termini of ERK2 lie on the surface of the molecule. The
observation that both N- and C-terminal mutations affect binding to
MEKs suggests that the tertiary structure formed by these regions is
important in MEK binding. In addition, it has been observed that
ERK2-10-25 and ERK2-19-25 cannot bind to MKP-3 (S. Eblen,
unpublished observation), a cytoplasmic anchor and phosphatase for the
ERKs (5, 28), in agreement with Tanoue et al.
(39) who suggest that MEK and MKP-3 share a common binding
site. We propose that the N- and C-terminal regions collectively form a
protein-protein interaction domain, with both regions being necessary
and neither sufficient to form a MEK/MKP3 binding site. This sequence
is identical in ERK1 except for the last residue, which is a glutamine,
suggesting that this conserved region may also be required for ERK1
activity and interactions. In addition, recent work from our laboratory has identified a protein called MP1 that appears to stabilize the
interaction between MEK1 and ERK1 specifically, demonstrating that
other proteins may also be involved in the MEK/ERK interaction (35).
Besides being activators of ERK2, the MEKs bind to and retain ERK1 and
ERK2 in the cytoplasm of unstimulated cells, preventing premature
nuclear entry of the ERKs (15). In serum-starved cells cotransfected with plasmids for WT-ERK2 and MEK2, WT-ERK2 was retained
in the cytoplasm (Fig. 5 and 6). However, under the same conditions,
ERK2-19-25 mutants were localized in both the nucleus and the
cytoplasm, supporting the coimmunoprecipitation experiments by
demonstrating that these mutants do not colocalize with MEK in
serum-starved cells. This inability to bind to MEK resulted in the
aberrant nuclear localization of these mutants under conditions of
serum starvation.
One of the best-characterized nuclear targets of the ERKs and the
stress-activated protein kinases is the nuclear transcription factor
Elk1, which contains several MAP kinase phosphorylation sites in the
C-terminal transactivation domain (20). Phosphorylation of
these sites by MAP kinase family members increases transcriptional activation by Elk1 (9, 16, 17, 24, 42). Using Elk1 transcriptional activity as a readout of ERK activation in a luciferase reporter system (32), cotransfection of WT-ERK2 or ERK2
mutants that bind to MEK with either a mutationally activated form of MEK1, MEK2, or Ras increased transcriptional activation of Elk1 in a
dose-dependent manner (Fig. 8). However, cotransfection with ERK2-10-25 or ERK2-19-25 partially inhibited the ability of activated Ras to signal through endogenous ERKs to Elk1. Inhibition may
be only partial due to the ability of Ras to activate other MAP kinase
pathways to activate Elk1. This concept was supported by the
observation that ERK2-10-25 and ERK2-19-25 were able to fully
inhibit the Elk1 activation by activated MEK1 or MEK2, which can only
signal through ERK1 and ERK2. Thus, these ERK mutants act as
dominant-negatives in inhibiting signaling through endogenous ERKs.
Interestingly, no inhibition of phosphorylation of the ERK2 cytoplasmic
substrate RSK2 was observed in the presence of ERK2-19-25-7A, suggesting that ERK2-19-25 mutants may only inhibit signaling to
nuclear substrates, while not affecting cytoplasmic substrates. The
differences in the effects on RSK and ELK activation are most likely
not due to differences in the ability of ERK2-19-25 mutants to bind
to these substrates, as ERK2-19-25 mutants showed no binding to
GAL4-Elk1 and had a greatly reduced ability to bind to RSK compared to
WT-ERK2 in coimmunoprecipitation experiments (Fig. 7).
A recent report describes the creation of dominant-negative ERK mutants
by the addition of a CAAX box to the C terminus, causing membrane
localization (21). The authors propose that these proteins inhibit ERK nuclear signaling by dimerizing with endogenous ERKs, tethering them to the membrane and preventing nuclear localization. We
believe that the dominant-negative mutants that we have described here,
which were created by mutating a natural part of ERK2, also inhibit ERK
nuclear signaling through their localization, albeit in a different
manner. Our hypothesis is that the aberrant constitutive nuclear
localization of a pool of ERK2-19-25 mutants inhibits endogenous ERK
nuclear signaling. This unregulated, inappropriate nuclear localization
of a kinase-dead ERK could interfere with the ability of endogenous
ERKs to signal to the nucleus by affecting the nuclear translocation or
retention of endogenous ERKs. ERKs require neosynthesis of labile
nuclear anchor proteins in order to be retained in the nucleus for
extended periods of time after initial translocation (26).
ERK2-19-25 could act as a dominant negative by either binding to
proteins that facilitate nuclear import or by taking up nuclear binding
sites for ERKs. In either scenario, these mutants would decrease the
amount of active endogenous ERKs in the nucleus at any given time.
While the coimmunoprecipitation experiments discussed above suggest
that these mutants have a decreased ability to bind substrate, these
interactions may have a stronger affinity in vivo. Elk1 contains a MAP
kinase binding domain, called the D domain, responsible for binding to
ERKs and stress-activated protein kinases (45), while
other ERK substrates contain an FXFP motif that ERKs bind
(23). Binding of ERKs through these motifs is often
required for ERK to phosphorylate their substrates (23,
45). If ERK2-19-25, which has little kinase activity even
when phosphorylated, could bind to ERK nuclear substrates and keep
endogenous ERKs from binding and phosphorylating them, transcriptional
activation by endogenous ERKs could be inhibited. Other methods of
determining in vivo interactions, such as the immunofluorescence and
fractionation experiments (Fig. 5 and 6) used in conjunction with the
MEK coimmunoprecipitations, would be required to determine the extent
of these interactions.
If the dominant-negative effects of the ERK2-19-25 are due to
saturation of nuclear targets, one might expect cytoplasmic substrates
to be unaffected by expression of the mutant. This is what we observed:
ERK2-19-25-7A did not inhibit RSK2 phosphorylation, while treatment
with U0126 (12), a MEK inhibitor, and ERK T183A, a
dominant-negative phosphorylation site mutant of ERK2 that can still
bind to MEK, both inhibited the phosphorylation of RSK2 induced by
RasV12. Whether this scenario will be observed with other ERK
substrates requires a further analysis of many more ERK targets. The
data suggest that this mutant ERK is able to differentially inhibit
signaling by specific pools of endogenous ERK proteins. Thus, in
addition to elucidating regulatory functions of the ERK N terminus,
this study reports the construction of a novel dominant-negative ERK
mutant that should be useful in dissecting the diverse role of MAP
kinases in cell regulation.
| |
ACKNOWLEDGMENTS |
This work was supported by Public Health Service Grants GM47332
and CA40042 from the National Institute of Health. S. Eblen was
supported by National Research Service Award 5F32 GM18672-02.
We thank the members of the Weber lab, PWP, and Jesse Kwiek for helpful
discussions. We also thank Scott Weed for pCDNA3-FLAG, Channing Der for
RasV12, Tom Sturgill for RSK2, Richard Maurer for GAL4-Elk1 and 5X GAL4
luciferase, and Alexis Rahal for technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, Box 441, Rm. 216, Jordan Hall, University of Virginia, Charlottesville, VA 22908. Phone: (804) 924-5022. Fax: (804) 982-0689. E-mail: mjw{at}virginia.edu.
Present address: Department of Pathology, College of Physicians and
Surgeons, Columbia University, New York, NY 10032.
| |
REFERENCES |
| 1.
|
Adachi, M.,
M. Fukuda, and E. Nishida.
1999.
Two co-existing mechanisms for nuclear import of MAP kinase: passive diffusion of a monomer and active transport of a dimer.
EMBO J.
18:5347-5358[CrossRef][Medline].
|
| 2.
|
Alessi, D. R.,
A. Cuenda,
P. Cohen,
D. T. Dudley, and A. R. Saltiel.
1995.
PD 098059 is a specific inhibitor of the activation of mitogen-activated protein kinase kinase in vitro and in vivo.
J. Biol. Chem.
270:27489-27494[Abstract/Free Full Text].
|
| 3.
|
Bardwell, L.,
J. G. Cook,
E. C. Chang,
B. R. Cairns, and J. Thorner.
1996.
Signaling in the yeast pheromone response pathway: specific and high-affinity interaction of the mitogen-activated protein (MAP) kinases Kss1 and Fus3 with the upstream MAP kinase kinase Ste7.
Mol. Cell. Biol.
16:3637-3650[Abstract].
|
| 4.
|
Brunet, A., and J. Pouyssegur.
1996.
Identification of MAP kinase domains by redirecting stress signals into growth factor responses.
Science
272:1652-1655[Abstract].
|
| 5.
|
Brunet, A.,
D. Roux,
P. Lenormand,
S. Dowd,
S. Keyse, and J. Pouyssegur.
1999.
Nuclear translocation of p42/p44 mitogen-activated protein kinase is required for growth factor-induced gene expression and cell cycle entry.
EMBO J.
18:664-674[CrossRef][Medline].
|
| 6.
|
Canagarajah, B. J.,
A. Khokhlatchev,
M. H. Cobb, and E. J. Goldsmith.
1997.
Activation mechanism of the MAP kinase ERK2 by dual phosphorylation.
Cell
90:859-869[CrossRef][Medline].
|
| 7.
| Catling, A. D., S. T. Eblen, H. J. Schaeffer, and M. J. Weber. Scaffold protein regulation of
the MAP kinase cascade. Methods Enzymol., in press.
|
| 8.
|
Catling, A. D.,
H. J. Schaeffer,
C. W. Reuter,
G. R. Reddy, and M. J. Weber.
1995.
A proline-rich sequence unique to MEK1 and MEK2 is required for raf binding and regulates MEK function.
Mol. Cell. Biol.
15:5214-5225[Abstract].
|
| 9.
|
Cavigelli, M.,
F. Dolfi,
F. X. Claret, and M. Karin.
1995.
Induction of c-fos expression through JNK-mediated TCF/Elk-1 phosphorylation.
EMBO J.
14:5957-5964[Medline].
|
| 10.
|
Chen, R. H.,
C. Sarnecki, and J. Blenis.
1992.
Nuclear localization and regulation of erk- and rsk-encoded protein kinases.
Mol. Cell. Biol.
12:915-927[Abstract/Free Full Text].
|
| 11.
|
Dalby, K. N.,
N. Morrice,
F. B. Caudwell,
J. Avruch, and P. Cohen.
1998.
Identification of regulatory phosphorylation sites in mitogen-activated protein kinase (MAPK)-activated protein kinase-1a/p90rsk that are inducible by MAPK.
J. Biol. Chem.
273:1496-1505[Abstract/Free Full Text].
|
| 12.
|
Favata, M. F.,
K. Y. Horiuchi,
E. J. Manos,
A. J. Daulerio,
D. A. Stradley,
W. S. Feeser,
D. E. Van Dyk,
W. J. Pitts,
R. A. Earl,
F. Hobbs,
R. A. Copeland,
R. L. Magolda,
P. A. Scherle, and J. M. Trzaskos.
1998.
Identification of a novel inhibitor of mitogen-activated protein kinase kinase.
J. Biol. Chem.
273:18623-18632[Abstract/Free Full Text].
|
| 13.
|
Fukuda, M.,
I. Gotoh,
M. Adachi,
Y. Gotoh, and E. Nishida.
1997.
A novel regulatory mechanism in the mitogen-activated protein (MAP) kinase cascade. Role of nuclear export signal of MAP kinase kinase.
J. Biol. Chem.
272:32642-32648[Abstract/Free Full Text].
|
| 14.
|
Fukuda, M.,
I. Gotoh,
Y. Gotoh, and E. Nishida.
1996.
Cytoplasmic localization of mitogen-activated protein kinase kinase directed by its NH2-terminal, leucine-rich short amino acid sequence, which acts as a nuclear export signal.
J. Biol. Chem.
271:20024-20028[Abstract/Free Full Text].
|
| 15.
|
Fukuda, M.,
Y. Gotoh, and E. Nishida.
1997.
Interaction of MAP kinase with MAP kinase kinase: its possible role in the control of nucleocytoplasmic transport of MAP kinase.
EMBO J.
16:1901-1908[CrossRef][Medline].
|
| 16.
|
Gille, H.,
M. Kortenjann,
O. Thomae,
C. Moomaw,
C. Slaughter,
M. H. Cobb, and P. E. Shaw.
1995.
ERK phosphorylation potentiates Elk-1-mediated ternary complex formation and transactivation.
EMBO J.
14:951-962[Medline].
|
| 17.
|
Gille, H.,
T. Strahl, and P. E. Shaw.
1995.
Activation of ternary complex factor Elk-1 by stress-activated protein kinases.
Curr. Biol.
5:1191-1200[CrossRef][Medline].
|
| 18.
|
Gonzalez, F. A.,
A. Seth,
D. L. Raden,
D. S. Bowman,
F. S. Fay, and R. J. Davis.
1993.
Serum-induced translocation of mitogen-activated protein kinase to the cell surface ruffling membrane and the nucleus.
J. Cell Biol.
122:1089-1101[Abstract/Free Full Text].
|
| 19.
|
Her, J. H.,
S. Lakhani,
K. Zu,
J. Vila,
P. Dent,
T. W. Sturgill, and M. J. Weber.
1993.
Dual phosphorylation and autophosphorylation in mitogen-activated protein (MAP) kinase activation.
Biochem. J.
296:25-31.
|
| 20.
|
Hill, C. S.,
R. Marais,
S. John,
J. Wynne,
S. Dalton, and R. Treisman.
1993.
Functional analysis of a growth factor-responsive transcription factor complex.
Cell
73:395-406[CrossRef][Medline].
|
| 21.
|
Hochholdinger, F.,
G. Baier,
A. Nogalo,
B. Bauer,
H. H. Grunicke, and F. Überall.
1999.
Novel membrane-targeted ERK1 and ERK2 chimeras which act as dominant negative, isotype-specific mitogen-activated protein kinase inhibitors of Ras-Raf-mediated transcriptional activation of c-fos in NIH 3T3 cells.
Mol. Cell. Biol.
19:8052-8065[Abstract/Free Full Text].
|
| 22.
|
Jaaro, H.,
H. Rubinfeld,
T. Hanoch, and R. Seger.
1997.
Nuclear translocation of mitogen-activated protein kinase kinase (MEK1) in response to mitogenic stimulation.
Proc. Natl. Acad. Sci. USA
94:3742-3747[Abstract/Free Full Text].
|
| 23.
|
Jacobs, D.,
D. Glossip,
H. Xing,
A. J. Muslin, and K. Kornfeld.
1999.
Multiple docking sites on substrate proteins form a modular system that mediates recognition by ERK MAP kinase.
Genes Dev.
13:163-175[Abstract/Free Full Text].
|
| 24.
|
Janknecht, R.,
W. H. Ernst,
V. Pingoud, and A. Nordheim.
1993.
Activation of ternary complex factor Elk-1 by MAP kinases.
EMBO J.
12:5097-5104[Medline].
|
| 25.
|
Khokhlatchev, A. V.,
B. Canagarajah,
J. Wilsbacher,
M. Robinson,
M. Atkinson,
E. Goldsmith, and M. H. Cobb.
1998.
Phosphorylation of the MAP kinase ERK2 promotes its homodimerization and nuclear translocation.
Cell
93:605-615[CrossRef][Medline].
|
| 26.
|
Lenormand, P.,
J. M. Brondello,
A. Brunet, and J. Pouyssegur.
1998.
Growth factor-induced p42/p44 MAPK nuclear translocation and retention requires both MAPK activation and neosynthesis of nuclear anchoring proteins.
J. Cell Biol.
142:625-633[Abstract/Free Full Text].
|
| 27.
|
Lenormand, P.,
C. Sardet,
G. Pages,
G. L'Allemain,
A. Brunet, and J. Pouyssegur.
1993.
Growth factors induce nuclear translocation of MAP kinases (p42mapk and p44mapk) but not of their activator MAP kinase kinase (p45mapkk) in fibroblasts.
J. Cell Biol.
122:1079-1088[Abstract/Free Full Text].
|
| 28.
|
Muda, M.,
U. Boschert,
R. Dickinson,
J. C. Martinou,
I. Martinou,
M. Camps,
W. Schlegel, and S. Arkinstall.
1996.
MKP-3, a novel cytosolic protein-tyrosine phosphatase that exemplifies a new class of mitogen-activated protein kinase phosphatase.
J. Biol. Chem.
271:4319-4326[Abstract/Free Full Text].
|
| 29.
|
Nishida, E., and Y. Gotoh.
1993.
The MAP kinase cascade is essential for diverse signal transduction pathways.
Trends Biochem. Sci.
18:128-131[CrossRef][Medline].
|
| 30.
|
Pages, G.,
P. Lenormand,
G. L'Allemain,
J. C. Chambard,
S. Meloche, and J. Pouyssegur.
1993.
Mitogen-activated protein kinases p42mapk and p44mapk are required for fibroblast proliferation.
Proc. Natl. Acad. Sci. USA
90:8319-8323[Abstract/Free Full Text].
|
| 31.
|
Payne, D. M.,
A. J. Rossomando,
P. Martino,
A. K. Erickson,
J. H. Her,
J. Shabanowitz,
D. F. Hunt,
M. J. Weber, and T. W. Sturgill.
1991.
Identification of the regulatory phosphorylation sites in pp42/mitogen-activated protein kinase (MAP kinase).
EMBO J.
10:885-892[Medline].
|
| 32.
|
Roberson, M. S.,
A. Misra-Press,
M. E. Laurance,
P. J. Stork, and R. A. Maurer.
1995.
A role for mitogen-activated protein kinase in mediating activation of the glycoprotein hormone  -subunit promoter by gonadotropin-releasing hormone.
Mol. Cell. Biol.
15:3531-3539[Abstract].
|
| 33.
|
Rubinfeld, H.,
T. Hanoch, and R. Seger.
1999.
Identification of a cytoplasmic-retention sequence in ERK2.
J. Biol. Chem.
274:30349-30352[Abstract/Free Full Text].
|
| 34.
|
Sanghera, J. S.,
M. Peter,
E. A. Nigg, and S. L. Pelech.
1992.
Immunological characterization of avian MAP kinases: evidence for nuclear localization.
Mol. Biol. Cell
3:775-787[Abstract].
|
| 35.
|
Schaeffer, H. J.,
A. D. Catling,
S. T. Eblen,
L. S. Collier,
A. Krauss, and M. J. Weber.
1998.
MP1: a MEK binding partner that enhances enzymatic activation of the MAP kinase cascade.
Science
281:1668-1671[Abstract/Free Full Text].
|
| 36.
|
Seger, R.,
N. G. Ahn,
J. Posada,
E. S. Munar,
A. M. Jensen,
J. A. Cooper,
M. H. Cobb, and E. G. Krebs.
1992.
Purification and characterization of mitogen-activated protein kinase activator(s) from epidermal growth factor-stimulated A431 cells.
J. Biol. Chem.
267:14373-14381[Abstract/Free Full Text].
|
| 37.
|
Slack, J. K.,
A. D. Catling,
S. T. Eblen,
M. J. Weber, and J. T. Parsons.
1999.
c-Raf-mediated inhibition of epidermal growth factor-stimulated cell migration.
J. Biol. Chem.
274:27177-27184[Abstract/Free Full Text].
|
| 38.
|
Smith, J. A.,
C. E. Poteet-Smith,
K. Malarkey, and T. W. Sturgill.
1999.
Identification of an extracellular signal-regulated kinase (ERK) docking site in ribosomal S6 kinase, a sequence critical for activation by ERK in vivo.
J. Biol. Chem.
274:2893-2898[Abstract/Free Full Text].
|
| 39.
|
Tanoue, T.,
M. Adachi,
T. Moriguchi, and E. Nishida.
2000.
A conserved docking motif in MAP kinases common to substrates, activators and regulators.
Nat. Cell Biol.
2:110-116[CrossRef][Medline].
|
| 40.
|
Tolwinski, N. S.,
P. S. Shapiro,
S. Goueli, and N. G. Ahn.
1999.
Nuclear localization of mitogen-activated protein kinase kinase 1 (MKK1) is promoted by serum stimulation and G2-M progression. Requirement for phosphorylation at the activation lip and signaling downstream of MKK.
J. Biol. Chem.
274:6168-6174[Abstract/Free Full Text].
|
| 41.
|
Whitmarsh, A. J.,
J. Cavanagh,
C. Tournier,
J. Yasuda, and R. J. Davis.
1998.
A mammalian scaffold complex that selectively mediates MAP kinase activation.
Science
281:1671-1674[Abstract/Free Full Text].
|
| 42.
|
Whitmarsh, A. J.,
P. Shore,
A. D. Sharrocks, and R. J. Davis.
1995.
Integration of MAP kinase signal transduction pathways at the serum response element.
Science
269:403-407[Abstract/Free Full Text].
|
| 43.
|
Wilsbacher, J. L.,
E. J. Goldsmith, and M. H. Cobb.
1999.
Phosphorylation of MAP kinases by MAP/ERK involves multiple regions of MAP kinases.
J. Biol. Chem.
274:16988-16994[Abstract/Free Full Text].
|
| 44.
|
Xu, B.,
J. L. Wilsbacher,
T. Collisson, and M. H. Cobb.
1999.
The N-terminal ERK-binding site of MEK1 is required for efficient feedback phosphorylation by ERK2 in vitro and ERK activation in vivo.
J. Biol. Chem.
274:34029-34035[Abstract/Free Full Text].
|
| 45.
|
Yang, S. H.,
P. R. Yates,
A. J. Whitmarsh,
R. J. Davis, and A. D. Sharrocks.
1998.
The Elk-1 ETS-domain transcription factor contains a mitogen-activated protein kinase targeting motif.
Mol. Cell. Biol.
18:710-720[Abstract/Free Full Text].
|
| 46.
|
Zecevic, M.,
A. D. Catling,
S. T. Eblen,
L. Renzi,
J. C. Hittle,
T. J. Yen,
G. J. Gorbsky, and M. J. Weber.
1998.
Active MAP kinase in mitosis: localization at kinetochores and association with the motor protein CENP-E.
J. Cell Biol.
142:1547-1558[Abstract/Free Full Text].
|
| 47.
|
Zhang, F.,
A. Strand,
D. Robbins,
M. H. Cobb, and E. J. Goldsmith.
1994.
Atomic structure of the MAP kinase ERK2 at 2.3 A resolution.
Nature
367:704-711[CrossRef][Medline].
|
| 48.
|
Zheng, C. F., and K. L. Guan.
1994.
Cytoplasmic localization of the mitogen-activated protein kinase activator MEK.
J. Biol. Chem.
269:19947-19952[Abstract/Free Full Text].
|
Molecular and Cellular Biology, January 2001, p. 249-259, Vol. 21, No. 1
0270-7306/01/$04.00+0 DOI: 10.1128/MCB.21.1.249-259.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
