Originally published In Press as doi:10.1074/jbc.M112483200 on March 1, 2002
J. Biol. Chem., Vol. 277, Issue 19, 16733-16743, May 10, 2002
ERK8, a New Member of the Mitogen-activated Protein Kinase
Family*
Mark K.
Abe
§,
Matthew P.
Saelzler,
Rafael
Espinosa III¶,
Kristopher T.
Kahle,
Marc B.
Hershenson,
Michelle
M.
Le Beau¶, and
Marsha Rich
Rosner
From the Department of Pediatrics, The Ben May
Institute for Cancer Research and the Department of
Neurobiology, Pharmacology, and Physiology, Section of Hematology and
Oncology, and the ¶ Department of Medicine, and the Cancer
Research Center, University of Chicago, Chicago, Illinois 60637
Received for publication, December 31, 2001, and in revised form, February 26, 2002
 |
ABSTRACT |
The ERKs are a subfamily of the MAPKs that have
been implicated in cell growth and differentiation. By using the rat
ERK7 cDNA to screen a human multiple tissue cDNA library, we
identified a new member of the ERK family, ERK8, that shares 69% amino
acid sequence identity with ERK7. Northern analysis demonstrates that ERK8 is present in a number of tissues with maximal expression in the
lung and kidney. Fluorescence in situ hybridization
localized the ERK8 gene to chromosome 8, band q24.3.
Expression of ERK8 in COS cells and bacteria indicates that, in
contrast to constitutively active ERK7, ERK8 has minimal basal kinase
activity and a unique substrate profile. ERK8, which contains two
SH3-binding motifs in its C-terminal region, associates with the c-Src
SH3 domain in vitro and co-immunoprecipitates with c-Src
in vivo. Co-transfection with either v-Src or a
constitutively active c-Src increases ERK8 activation
indicating that ERK8 can be activated downstream of c-Src. ERK8 is also
activated following serum stimulation, and the extent of this
activation is reduced by pretreatment with the specific Src family
inhibitor PP2. The ERK8 activation by serum or Src was not affected by
the MEK inhibitor U0126 indicating that activation of ERK8 does not
require MEK1, MEK2, or MEK5. Although most closely related to ERK7, the
relatively low sequence identity, minimal basal activity, and different
substrate profile identify ERK8 as a distinct member of the MAPK family
that is activated by an Src-dependent signaling pathway.
| |
INTRODUCTION |
The mitogen-activated protein kinases
(MAPKs)1 are a superfamily of
serine/threonine protein kinases that are evolutionarily conserved and
whose members have been implicated in key cellular processes including
cell proliferation, differentiation, apoptosis, and stress responses
(1-4). Regulation of the activity of MAPK depends on the
phosphorylation state of the threonine and tyrosine residues in a
Thr-X-Tyr (TXY) motif within the kinase domain. This canonical MAPK TXY motif has also been used to classify
MAPKs into three main groups. Members of one group, the extracellular signal regulated kinases (ERKs), can be identified by their TEY (Thr-Glu-Tyr) activation motif and include ERK1, ERK2, ERK5, and ERK7.
Recently, p97, an ERK5-related kinase identified through affinity
purification that is selectively recognized by anti-pTEpY antibodies,
was shown to be involved in a signaling pathway leading to
differentiation (5). ERK1 and ERK2 were the first members of the ERK
family to be identified and are the most widely studied. The 44-kDa
ERK1 and the 42-kDa ERK2 have been implicated in cellular pathways that
mediate growth factor regulation of proliferation and/or
differentiation in most cell types (2, 3).
The recently identified ERK5 and ERK7 are significantly larger than the
originally identified ERK1 and ERK2 due to an extended C-terminal
domain. ERK5, also known as big mitogen-activated kinase 1 (6, 7), is
110 kDa, and ERK7 is 61 kDa. Recent information indicates that the
C-terminal regions of these ERKs have important regulatory functions.
The C-terminal region of ERK5 appears to regulate negatively its kinase
activity (6) and contains a putative bipartite nuclear localization
signal required for nuclear translocation of ERK5 in vivo
following activation (8). The C-terminal region of ERK5 also contains a
myocyte enhancer-binding factor 2-interacting region and a potent
transcriptional activation domain (9). ERK7 is activated by
autophosphorylation, which is regulated through interactions with the
C-terminal domain (10). In addition, the C-terminal region is required
for the ability of ERK7 to localize to the nucleus and inhibit growth
(11). The recent identification and characterization of these larger ERKs suggest that there may be additional members of the ERK family with extended C-terminal regions.
To explore this possibility, we screened a multiple human tissue
library using ERK7 cDNA as a probe, and we identified a protein kinase with the characteristic TEY activation motif. The relatively low
sequence identity shared between this new ERK, termed ERK8, and the
previously identified rat ERK7 suggests that it is a novel MAPK. In
contrast to ERK7, ERK8 does not display significant constitutive kinase
activity, does not phosphorylate c-Fos, and is activated in response to
stimulation by Src or serum. These divergent biochemical characteristics confirm that ERK8, although most closely related to
ERK7, represents a new member of the ERK family.
| |
EXPERIMENTAL PROCEDURES |
Materials
Bovine serum albumin (BSA), myelin basic protein (MBP),
triethylamine, glycine, glycerol, peroxidase-conjugated goat
anti-rabbit IgG, peroxidase-conjugated goat anti-rat IgG, and
peroxidase-conjugated goat anti-mouse IgG were purchased from Sigma.
Fibronectin and collagen were purchased from BD PharMingen. Dulbecco's
modified Eagle's medium, modified Eagle's medium, FBS, trypsin,
penicillin, streptomycin, and the eukaryotic TA cloning kit were
purchased from Invitrogen. Protein A-Sepharose was purchased from
RepliGen Corp. (Needham, MA). Protein G-Sepharose, CNBr-activated
Sepharose, the unique site elimination mutagenesis kit, and the GST
purification system was purchased from Amersham Biosciences. The Human
Universal cDNA Library array was purchased from Stratagene (La
Jolla, CA). The Marathon-ReadyTM Human Testis cDNA,
Advantage-HF 2, and Advantage-GC 2 PCR kits were purchased from
CLONTECH (Palo Alto, CA). High affinity rat monoclonal antibody (3F10) against the hemagglutinin (HA) epitope was
purchased from Roche Diagnostics. Mouse monoclonal antibody (HA.11)
against the HA epitope was purchased from Covance Research Products,
Inc. (Richmond, CA). Affinity-purified peroxidase-conjugated goat
anti-rabbit IgG was purchased from Jackson ImmunoResearch. Phospho-p44/42 MAPK polyclonal antibody and GST-ATF2 were purchased from Cell Signaling Technology (Beverly, MA). Enhanced
chemiluminescence reagents and [
-32P]ATP (6000 Ci/mmol) were purchased from PerkinElmer Life Sciences. PCR and
sequencing primers were synthesized by the University of Chicago
Oligonucleotide Facility or purchased from Integrated DNA Technologies
(Coralville, IA). The University of Florida DNA Sequencing Core Lab
(Gainesville, FL) and the University of Chicago Cancer Research Center
DNA Sequencing Facility performed the sequencing.
Methods
Library Screening--
The entire rat ERK7 cDNA
(GenBankTM accession number AF078798) was used to screen
the Stratagene Human Universal cDNA Library array according to the
manufacturer's instructions. An identified 3208-bp clone was
found to contain four introns and a partial coding region. 5'-Rapid
amplification of cDNA ends and PCR were used to obtain the
full-length ERK8 cDNA from human testis first strand cDNAs
(purchased from CLONTECH). The sequence of the
full-length clone was verified by sequence comparison to the putative
coding region of the original 3208-bp clone.
Tissue Northern Analysis--
ERK8 cDNA was radiolabeled
with 32P using a nick translation method and was used to
probe a poly(A)+ RNA human multiple tissue Northern blot
(purchased from CLONTECH) using ExpressHyb
hybridization solution according to the manufacturer's instructions
(CLONTECH). The blot was washed extensively with 0.1× SSC (15 mM NaCl, 1.5 mM sodium citrate)
0.1% SDS at 65 °C, and exposed to x-ray film at 80 °C.
Plasmid Construction and Preparation--
A hemagglutinin
antigen tag, YPYDVPDY, was inserted immediately following the start
methionine of ERK8 using PCR and was verified by sequencing. The
HA-ERK8 was subcloned into the mammalian expression vector pCR3.1
(Invitrogen). Unique site elimination mutagenesis (12) was performed to
generate ERK8 mutants (K42R, T175A, Y177F, and T175A/Y177F). The
mutated sequences were verified by sequencing. The ERK7 constructs were
prepared as described previously (11). The c-Src, kinase-deficient
c-Src (K295R), constitutively active c-Src (Y527F), and v-Src plasmids
were a gift from D. Foster (13-15). The pCMV5c-Src plasmid was a gift
from J. Brugge. Plasmid DNAs were prepared by CsCl-ethidium bromide
gradient centrifugation or by purification through columns according to
the manufacturer's instructions (Qiagen, Chatsworth, CA).
Cell Culture--
COS cells (American Type Culture Collection)
were cultured in Dulbecco's modified Eagle's medium supplemented with
10% fetal bovine serum (FBS) and antibiotics (50 units/ml penicillin
and 50 µg/ml streptomycin). Quiescent cells were obtained by
incubating cells in serum-free medium supplemented with 0.5% BSA for
at least 18 h. 16HBE14o human bronchial epithelial cells were a
gift from D. Gruenert (16). The 16HBE14o cells were cultured on
tissue culture plasticware coated with fibronectin, collagen, and BSA. The cells were grown in modified Eagle's medium supplemented with 10%
FBS, L-glutamine (4 mM), and antibiotics (50 units/ml penicillin and 50 µg/ml streptomycin). Both cell types were
maintained at 37 °C in a 95% air, 5% CO2 atmosphere.
Transient Transfections and Preparation of Cell
Extracts--
COS cells were transfected as described previously
(10). Cultured cells were washed twice with ice-cold phosphate-buffered saline (PBS) and lysed with either 1% Triton-based lysis buffer (TLB)
as described previously (10) or with RIPA containing 1% Triton X-100,
1% sodium deoxycholate, 0.1% SDS, 50 mM Tris-HCl, pH 7.5, 40 mM 
-glycerophosphate, 100 mM NaCl, 50 mM NaF, 2 mM EDTA, 1 mM sodium
vanadate, 1 mM phenylmethylsulfonyl fluoride, 1 µg/ml
aprotinin, 1 µg/ml leupeptin, and 20 mM 
-nitrophenyl phosphate. Protein concentration of the cleared supernatant was estimated as described previously (10).
Western Analysis--
Cell extracts (10-60 µg of protein per
lane) were resolved on an 8 or 10% acrylamide separating gel by
SDS-PAGE. Proteins were transferred to a nitrocellulose membrane.
Membrane blocking, washing, antibody incubation, and detection by
enhanced chemiluminescence were performed as described previously
(17).
Immunoprecipitation and Immune Complex Kinase Assay--
Immune
kinase assays were performed using ectopically expressed epitope-tagged
ERK8 from COS cells as described previously for ERK7 (10). Proteins
were isolated by SDS-PAGE on an 8% acrylamide separating gel. The gels
were either stained with Gelcode Blue (Pierce) and dried or transferred
to nitrocellulose and subjected to autoradiography. Quantitation of
substrate phosphorylation was determined either by scintillation
counter or by the STORM system (Molecular Dynamics). The presence of
HA-tagged or TEY-phosphorylated proteins in the immunoprecipitates was
verified by Western analysis with 3F10 monoclonal and anti-phospho-ERK
polyclonal antibodies, respectively. Quantification of HA-tagged and
TEY-phosphorylated proteins was performed using densitometric scanning
(SigmaScan Pro, Jandel Corp., San Rafael, CA). Multiple exposures were
utilized to verify linearity of the samples analyzed.
Immunoprecipitation assays were performed in a similar fashion;
however, the immune complexes were eluted prior to the kinase reaction
and subjected to Western analysis.
GST Fusion Proteins--
Plasmids encoding glutathione
S-transferase (GST)-c-Fos-(210-313), GST-c-Jun-(1-93),
GST-c-Myc, GST-c-Max, GST-paxillin, GST-ELK-1-(307-428), GST-Grb2, and
GST-c-Src SH3 were generously provided by T. Deng, E. Wattenberg, N. Hay, C. Turner, R. Treisman, W. Li, and B. Mayer, respectively.
GST-HA-ERK7 and GST-HA-ERK7 K43R were constructed as described
previously (10). GST HA-ERK8 and GST-HA-ERK8 K42R were constructed
using PCR to insert a BglII restriction site upstream of the
HA tag. The PCR product was verified by sequencing. HA-ERK8 and HA-ERK8
K42R were subsequently cloned into pGEX-2T using the
BglII/BamHI and EcoRI sites. GST
fusion proteins were prepared using a GST purification system (Amersham
Biosciences) as described previously (10). Thrombin cleavage of
GST-c-Fos was performed as specified by the manufacturer. Purified
proteins were separated on 10 or 15% SDS-PAGE and quantitated by
densitometric scanning using BSA as a standard.
In Vitro Kinase Assay--
Purified GST fusion proteins were
incubated in kinase buffer (20 mM HEPES, pH 7.4, 10 mM MgCl2, 10 mM MnCl2,
1 mM dithiothreitol, 0.2 mM sodium vanadate, 10 mM -nitrophenyl phosphate, 5 µCi of [-32P]ATP) with each substrate at 30 °C for varying
lengths of time. Reactions were terminated by adding 4× Laemmli sample
buffer and heating at 95 °C for 5 min. Samples were subsequently
processed as described above for the immune complex kinase assay.
Fluorescence in Situ Chromosomal Hybridization--
Human
metaphase cells were prepared from phytohemagglutinin-stimulated
peripheral blood lymphocytes. The ERK8 probe was a cDNA
probe consisting of 3208 bp containing both coding and non-coding regions of ERK8. Fluorescence in situ hybridization was
performed as described previously (18). Biotin-labeled probes were
prepared by nick translation using Bio-16-dUTP (Enzo Diagnostics, New
York, NY). Hybridization was detected with fluorescein-conjugated
avidin (Vector Laboratories, Burlingame, CA), and chromosomes were
identified by staining with 4,6-diamidino-2-phenylindole dihydrochloride.
Anti-ERK8 Antibody--
Anti-ERK8 rabbit antiserum (Cocalico
Biologicals, Reamstown, PA) was raised against a peptide representing
the last 14 amino acids of the C-terminal domain of ERK8. The ERK8
peptide was synthesized by the University of Chicago Cancer Research
Center Peptide Facility. The anti-ERK8 antiserum was purified by
affinity chromatography using the ERK8 peptide coupled to
CNBr-activated Sepharose. Antibodies were eluted using 100 mM glycine, pH 2.5, followed by 100 mM
triethylamine, pH 11.5. The eluents were neutralized with 1 M Tris-Cl, pH 8.0, and dialyzed against PBS, pH 7.5. A
protein A-Sepharose column was used to isolate the IgG fraction. The
purified antibody was eluted using 100 mM glycine, pH 3.0, neutralized with 1 M Tris-Cl, pH 8.0, and dialyzed against
30% glycerol in PBS, pH 7.5. Peroxidase conjugation of the
affinity-purified anti-ERK8 antibody was performed using the
EZ-LinkTM-activated peroxidase antibody labeling kit
according to the manufacturer's instructions (Pierce).
GenBankTM Accession Number--
The
GenBankTM accession number for the ERK8 cDNA reported
here is AY065978.
| |
RESULTS |
Identification of the ERK8 Sequence--
The ERK8 cDNA is 1896 bp long and contains a 544-codon open reading frame (1632 bp) (Fig.
1). Initially, we identified ERK8 by
hybridization of rat ERK7 cDNA with a 3208-bp clone from the Stratagene Human Universal cDNA Library. Sequence analysis of this
clone indicated that it contained three introns and 537 codons (of 544 codons) suggesting that it represented immature mRNA (Table I). The full-length ERK8 cDNA was
obtained through a combination of 5'-rapid amplification of cDNA
ends and PCR using human testis first strand cDNA as a template. A
BLAST search (19) of the National Center for Biotechnology Information
public human genome data base did not identify any matches. However, a
Blast search (19) of the Celera Consensus Human Genome data base
identified the gene hCG31703 consisting of 5830 bp (231 of these
nucleotides were not specifically identified). Analysis of this
sequence indicates that the human ERK8 gene consists of 14 exons (Table II).
View larger version (59K):
[in this window]
[in a new window]
|
Fig. 1.
Primary structure of ERK8. The
nucleotide and deduced protein sequence of ERK8 cDNA. The threonine
and tyrosine residues within the activation motif are marked with
asterisks. The two putative SH3-binding motifs,
PXXP, within the C-terminal region are
underlined. The GenBankTM accession number for
ERK8 is AY065978.
|
|
View this table:
[in this window]
[in a new window]
|
Table I
Sequences at the exon-intron junctions of the partially processed ERK8
clone
The 3208-bp ERK8 clone isolated from the Stratagene Human Universal
cDNA Library contains three introns whose lengths are listed in
base pairs. The exon numbering is based on sequence analysis of the
Celera Consensus Human Genome data base gene hCG31703. The
nucleotide position corresponds to the cDNA sequence beginning at
the start codon and indicates the position of the first nucleotide of
the exon. The exon coding sequences are in capital letters. The deduced
amino acid single-letter code is indicated above the first nucleotide
of the corresponding codon. The GT-AG consensus splice donor-acceptor
sites are underlined.
|
|
View this table:
[in this window]
[in a new window]
|
Table II
Sequences at the exon-intron junctions of ERK8
The nucleotide position corresponds to the cDNA sequence beginning
at the start codon and indicates the position of the first nucleotide
of the exon. The exon and intron base pair lengths are listed. The exon
coding sequences are in capital letters. The deduced amino acid
single-letter code is indicated above the first nucleotide of the
corresponding codon. The GT-AG consensus splice donor-acceptor sites
are underlined.
|
|
The overall amino acid identity of the human ERK8 and rat ERK7
sequences is 69% (Fig. 2). Comparison of
the kinase domains reveals a sequence identity of about 82%, whereas
the amino acid sequence identity of the C-terminal regions is only
53%. By contrast, sequence identity between other ERK orthologues is
significantly higher. Rat and human ERK1 and ERK2 share 97 and 99%
overall sequence identity, respectively. Even mouse and human ERK5
share 92% sequence identity (20). Therefore, sequence comparison of
ERK8 and ERK7 suggests that they are related, but distinct, members of
the ERK family.
View larger version (46K):
[in this window]
[in a new window]
|
Fig. 2.
Sequence alignment of ERK8 with ERK7.
Computer-generated alignment (Vector NTI, InforMax, Bethesda, MD) of
ERK8 and ERK7. Roman numerals indicate the 11 conserved
protein kinase domains. The GenBankTM accession number for
ERK7 is AF078798.
|
|
Tissue Distribution of Human ERK8--
The tissue distribution of
human ERK8 was determined by Northern analysis of poly(A)+
RNA from multiple human tissues (Fig. 3).
Three transcript sizes of 5.3, 3.5, and 2.0 kb were identified that
could represent immature mRNA. ERK8 mRNA appears to be
expressed in multiple tissue types, and, of those evaluated, it is most
highly expressed in lung and kidney. A Blast search (19) of the
National Center for Biotechnology Information public human expressed
sequence tags (ESTs) data base revealed several ESTs with high sequence
identity with ERK8 (Table III). These
ESTs were generated from a variety of tissue sources and like the
Northern analysis suggest that ERK8 is expressed in multiple
tissues.
View larger version (77K):
[in this window]
[in a new window]
|
Fig. 3.
Tissue distribution of ERK8. A human
multiple tissue poly(A)+ RNA Northern blot
(CLONTECH) was probed with radiolabeled ERK8
cDNA. The positions of the RNA size markers in kilobases are noted
on the left.
|
|
View this table:
[in this window]
[in a new window]
|
Table III
Human expressed sequence tags homologous to ERK8
Partial results of a Blast search (19) of the National Center for
Biotechnology Information public human expressed sequence tags (EST)
database using the 1896 base pair ERK8 cDNA sequence (GenBankTM
accession number AY065978).
|
|
Mapping of ERK8 to Chromosome Band 8q24.3--
To localize the
ERK8 gene, we performed fluorescence in situ
hybridization of a biotin-labeled ERK8 probe to normal human metaphase chromosomes. Hybridization of the ERK8 cDNA
probe resulted in specific labeling only of chromosome 8 (Fig.
4). Specific labeling of 8q24.2-24.3 was
observed on four (6 cells), three (13 cells), or two (6 cells)
chromatids of the chromosome 8 homologues in 25 cells examined. Of 75 signals observed, 5 (7%) signals were located at 8q24.2, and 70 (93%)
signals were located at 8q24.3. No background signals were observed at
other chromosomal sites. We observed specific signal at 8q24.3 in an
additional hybridization experiment using this probe. These results
suggest that the ERK8 gene is localized to chromosome 8, band q24.3.
View larger version (51K):
[in this window]
[in a new window]
|
Fig. 4.
ERK8 is localized to chromosome band
8q24.3. In situ hybridization of a biotin-labeled
ERK8 probe to human metaphase cells from
phytohemagglutinin-stimulated peripheral blood lymphocytes. The
chromosome 8 homologues are identified with arrows; specific
labeling was observed at 8q24.3. The inset shows partial
karyotypes of two chromosome 8 homologues illustrating specific
labeling at 8q24.3 (arrowheads). Images were obtained using
a Zeiss Axiophot microscope coupled to a cooled charge coupled device
camera. Separate images of 4,6-diamidino-2-phenylindole
dihydrochloride-stained chromosomes and the hybridization signal were
captured and merged using image analysis software (IP
LabSpectrum).
|
|
Human ERK8 Expression--
To verify that ERK8 is expressed in
cells, an antibody against a 14-amino acid peptide from the C-terminal
region of ERK8 was generated. Western analysis of a human bronchial
epithelial cell line, 16HBE14o (16), using this antibody revealed the presence of a band of ~60-kDa (Fig. 5,
A and B). Recognition of this band by Western
analysis was prevented when the anti-ERK8 antibody was incubated with
the ERK8 peptide (Fig. 5, A and B) indicating
that endogenous ERK8 is expressed in this human lung cell line.
Comparison of the signal strength of endogenous ERK8 to that of
exogenously expressed ERK8 (Fig. 5A) suggests that endogenous ERK8 is expressed at a very low level in this cell type.
Western analysis of primary human bronchial epithelial cells also
revealed an extremely low level of endogenous ERK8 (data not
shown).
View larger version (32K):
[in this window]
[in a new window]
|
Fig. 5.
ERK8 is expressed in mammalian cells and is a
functional kinase. A, whole cell lysates from a
human bronchial epithelial cell line, 16HBE14o and from COS cells
transfected with ERK8 were prepared and analyzed by immunoblotting with
the affinity-purified anti-ERK8 polyclonal antibody with (+) and
without () ERK8 blocking peptide at a final concentration of 10 µM. B, whole cell lysates from 16HBE14o
cells were analyzed by immunoblotting with the peroxidase-conjugated,
affinity-purified anti-ERK8 antibody with (+) and without () ERK8
blocking peptide at a final concentration of 10 µM.
C, COS cells were transfected with pcDNA3, HA-ERK8,
HA-ERK7, and their kinase-inactive mutants. The kinase-inactive ERK8
mutant, K42R, and the kinase-inactive ERK7 mutant, K43R, were made by
replacing the highly conserved lysine in the ATP-binding region with
arginine. Lysates from transfected cells were prepared and analyzed by
immunoblotting with either the anti-HA 3F10 monoclonal antibody
(top) or the anti-phospho-ERK antibody (middle
and bottom). A longer exposure of the anti-phospho-ERK
Western analysis is depicted at the bottom.
D, COS cells were transiently transfected either with
pcDNA3, HA-ERK8, K42R, or the HA-ERK8 TEY mutants. Lysates from
transfected cells were prepared and analyzed by immunoblotting with
either the anti-HA 3F10 monoclonal antibody (top) or the
anti-phospho-ERK antibody (bottom). E, COS
cells were transiently transfected either with pcDNA3, HA-ERK8,
K42R, HA-ERK7, or K43R and lysed with 1% TLB. Enzyme activity of
proteins immunoprecipitated using the anti-HA monoclonal antibody
(HA.11) was measured by an in vitro kinase assay using 2 µg of GST-c-Fos as a substrate (top). The
immunoprecipitated proteins were analyzed by Western blotting with the
anti-HA 3F10 monoclonal antibody (bottom).
F, COS cells were transiently transfected either with
pcDNA3, HA-ERK8, or K42R and lysed with 1% TLB. The ability of
proteins immunoprecipitated using the anti-HA monoclonal antibody
(HA.11) to autophosphorylate was measured by an in vitro
kinase assay. The data shown are representative of three
experiments.
|
|
To study ERK8 in intact cells, an HA-tagged human ERK8 construct and
the HA-ERK8 K42R kinase-deficient mutant were expressed in COS cells.
For comparison, the wild-type and kinase-deficient HA-ERK7 were also
expressed. Both HA-ERK8 and HA-ERK8 K42R migrated on SDS-PAGE as a
single band of ~60-kDa when analyzed by immunoblotting with the 3F10
anti-HA monoclonal antibody (Fig. 5C, top). In
contrast, wild-type ERK7 is typically detected as a doublet suggesting
that it is multiply phosphorylated (Fig. 5C,
top). Western analysis using the anti-phospho-ERK polyclonal
antibody (pAb) revealed that only ERK7 is TEY-phosphorylated to a
significant degree (Fig. 5C, middle). The
wild-type ERK8 could be identified by Western analysis with the
anti-phospho-ERK pAb only with significantly longer exposure times
(Fig. 5C, bottom) or increased protein amounts, and neither kinase-deficient mutant cross-reacted even after prolonged exposure. These findings are consistent with our data published previously (10, 11) indicating that ERK7 has significant constitutive activity. Therefore, the difference in recognition by the
anti-phospho-ERK pAb suggests that the basal activity level of ERK8 is
significantly lower than that of ERK7.
To determine the specificity of the anti-phospho-ERK pAb for the dually
phosphorylated TEY ERK8, the TEY activation domain was mutated either
by changing the threonine residue to alanine (T175A), changing the
tyrosine residue to phenylalanine (Y177F), or mutating both residues to
T175A/Y177F. COS cells were transfected either with pcDNA3,
HA-ERK8, or the mutant forms of ERK8. Western analysis of lysate from
transfected cells revealed expression of all the mutants (Fig.
5D, top), whereas Western analysis using the
anti-phospho-ERK pAb showed significant cross-reactivity only with the
wild-type ERK8 (Fig. 5D, bottom). This result
suggests that the TEY motif within the activation domain of wild-type
ERK8 can be dually phosphorylated.
Direct comparison of the level of kinase activity between ERK8 and ERK7
was attempted using an in vitro kinase assay. The HA-tagged
proteins were immunoprecipitated from COS cells transfected either with
the empty vector, HA-ERK8, HA-ERK8 K42R, HA-ERK7, or HA-ERK7 K43R.
In vitro kinase assays were performed using GST-c-Fos, a
known substrate for ERK7 (Fig. 5E, top). Under
identical conditions, GST-c-Fos was phosphorylated by
immunoprecipitated HA-ERK7 but not HA-ERK8. However, HA-ERK8 was able
to autophosphorylate under these conditions (Fig. 5F)
indicating that it is a functional kinase.
Because GST-c-Fos-(210-313) is not a substrate for ERK8,
identification of an in vitro substrate was attempted using
bacterially expressed GST-HA-ERK8 and GST-HA-ERK8 K42R. Despite the use
of protease inhibitors, both GST-HA-ERK8 and GST-HA-ERK8 K42R were highly degraded when purified from bacteria (Fig.
6A, top).
Bacterially expressed GST-HA-ERK7 and its kinase-deficient mutant were
similarly degraded (Fig. 6A, top). Despite being
degraded, both GST-HA-ERK8 and GST-HA-ERK7 were recognized by the
anti-phospho-ERK pAb (Fig. 6A, bottom). Similar
to results obtained with the mammalian expression system, GST-HA-ERK8
was recognized with significantly lower affinity. The ability of
GST-HA-ERK8, but not the GST-HA-ERK8 K42R mutant, to autophosphorylate
(Fig. 6B, top) and phosphorylate MBP (Fig. 6B, bottom) indicates that it is a functional
kinase when expressed in bacteria. However, bacterially expressed
GST-HA-ERK8 did not phosphorylate GST-c-Fos (Fig. 6B,
top) or c-Fos cleaved from the GST tag by thrombin (data not
shown). Additional substrates tested that were not efficiently
phosphorylated by bacterially expressed GST-HA-ERK8 included
GST-c-Jun-(1-93), histone H1, Ets-1, GST-c-Myc, GST-c-Max,
GST-Elk-1-(307-428), and GST-paxillin (data not shown). Although MBP
could be phosphorylated by bacterially expressed GST-HA-ERK8, it was a
poor substrate for immunoprecipitated HA-ERK8 from mammalian cellular
lysates due to a high level of background phosphorylation (data not
shown). The fact that bacterially expressed ERK8 could phosphorylate
MBP but not c-Fos confirms that ERK8 is a functional kinase with an
in vitro substrate profile that differs from that of
ERK7.
View larger version (23K):
[in this window]
[in a new window]
|
Fig. 6.
Bacterially expressed GST-HA-ERK8 is a
functional kinase. A, GST-HA-ERK8, GST-HA-ERK8
K42R, GST-HA-ERK7, and GST-ERK7 K43R were expressed in
Escherichia coli, purified using glutathione-Sepharose, and
assessed by Western analysis using an anti-HA monoclonal antibody
(top) and the anti-phospho-ERK antibody (bottom).
The positions of the molecular mass markers in kilodaltons are noted on
the right. B, enzymatic activity of purified
GST-HA-ERK8, GST-HA-ERK8 K42R, GST-HA-ERK7, and GST-ERK7 K43R was
measured using an in vitro kinase assay with either 2 µg
of GST-c-Fos-(210-313) (top) or 2 µg of MBP
(bottom) as a substrate. The data shown are representative
of three experiments.
|
|
ERK8 Associates with c-Src--
Sequence analysis of ERK8 revealed
the presence of two potential SH3 domain binding motifs,
PXXP, within its C-terminal region (Fig. 1). To determine
whether ERK8 can interact with proteins containing SH3 domains, an
in vitro binding assay was performed using whole cell lysate
from HA-ERK8-transfected COS cells and a GST-c-Src SH3 domain fusion
protein purified from bacteria. HA-ERK8 specifically bound to GST-c-Src
SH3 but not GST (Fig. 7A). To
determine whether ERK8 can also associate with c-Src in vivo, COS cells were transiently co-transfected with HA-ERK8 and either c-Src or the control vector. After immunoprecipitation with an
anti-c-Src antibody, the immunoprecipitated proteins were resolved by
SDS-PAGE and analyzed by Western blotting with the anti-HA monoclonal
antibody. As shown in Fig. 7B, HA-ERK8 co-precipitated with
c-Src. HA-ERK8 was seen in immunoprecipitates from both control and
c-Src-transfected cells, suggesting that ERK8 associated with the
endogenous c-Src as well as the exogenous c-Src. However, expression of
exogenous c-Src dramatically increased the level of HA-ERK8
co-immunoprecipitated (Fig. 7B, compare lanes 3 and 4). Surprisingly, when HA-ERK8 was immunoprecipitated
first from cells co-transfected with HA-ERK8 and c-Src, c-Src could not
be detected (data not shown). It is possible that the anti-HA antibody bound to protein G beads sterically inhibits HA-ERK8 from interacting with c-Src. Two different anti-c-Src antibodies gave identical results,
and Western analysis of whole cell lysates containing HA-ERK8 indicated
that neither of the anti-c-Src antibodies cross-reacted with ERK8 (data
not shown). These results indicate that ERK8 can associate with c-Src
in cells.
View larger version (12K):
[in this window]
[in a new window]
|
Fig. 7.
ERK8 associates with c-Src.
A, in vitro binding of ERK8 and the c-Src
SH3 domain. Lysate from COS cells transiently transfected with HA-ERK8
was incubated either with GST or GST-c-Src SH3. After extensive
washing, bound proteins were separated by SDS-PAGE and analyzed by
Western blotting with the anti-HA monoclonal antibody (3F10). The
position of HA-ERK8 is depicted in the whole cell lysate
(WC) separated simultaneously by SDS-PAGE.
B, co-immunoprecipitation of c-Src and ERK8 in COS
cells. COS cells were transiently transfected either with pcDNA3
and c-Src (1st lane), pcDNA3 and HA-ERK8 (2nd
lane), c-Src and HA-ERK8 (3rd lane), or pcDNA3
alone (4th lane). Lysates were immunoprecipitated with an
anti-c-Src polyclonal antibody and resolved by SDS-PAGE. Samples were
analyzed by immunoblotting with the anti-HA 3F10 monoclonal antibody.
The data shown are representative of three experiments.
|
|
ERK8 Can Be Activated by a Src-dependent Signaling
Pathway--
To determine whether ERK8 can be activated by a pathway
involving Src, COS cells were transiently co-transfected with HA-ERK8 and either v-Src, constitutively active c-Src (c-Src Y527F),
kinase-deficient c-Src (c-Src K295R), or the control vector. Western
analysis using the anti-HA antibody indicated that the level of HA-ERK8
protein expression was comparable between transfection groups (Fig.
8A, top). However,
Western analysis with the anti-phospho-ERK pAb revealed a marked
increase in TEY-phosphorylated ERK8 when co-transfected with the
constitutively active c-Src or v-Src (Fig. 8A,
bottom). Exogenous ERK8 activation by Src was also seen in
NIH3T3 and 16HBE14o cells (data not shown). In addition, an increase
in the TEY phosphorylation of the ERK8 kinase-deficient mutant was
observed when the mutant was co-expressed with v-Src (Fig.
8B, bottom), consistent with phosphorylation by
an upstream kinase. An in vitro kinase assay based on ERK8
autophosphorylation was used to verify increased kinase activity
following co-transfection with v-Src. Presumably the majority of
activated ERK8 is phosphorylated in vivo prior to the
in vitro kinase assay; therefore, the amount of
autophosphorylation measured in this assay underestimates the level of
ERK8 activation. As shown in Fig. 8, C and D, a
small but consistent increase in ERK8 autophosphorylation was seen when
ERK8 was co-transfected with v-Src. Taken together, these results
indicate that ERK8 binds to and is activated by c-Src in cells.
View larger version (33K):
[in this window]
[in a new window]
|
Fig. 8.
ERK8 can be activated by an
Src-dependent signaling pathway. A,
COS cells were transiently transfected with pcDNA3 or HA-ERK8 and
either pEVX, c-Src, the constitutively active c-Src (Y527F), or v-Src.
Lysates were prepared, separated by SDS-PAGE, and analyzed by Western
blotting with either the anti-HA 3F10 monoclonal antibody
(top) or the anti-phospho-ERK polyclonal antibody
(bottom). B, COS cells were transiently
transfected with the kinase-dead HA-ERK8 mutant (K42R) and either pEVX,
c-Src, the kinase inactive c-Src (K295R), or v-Src. Lysates were
prepared, separated by SDS-PAGE, and analyzed by Western blotting with
either the anti-HA 3F10 monoclonal antibody (top) or the
anti-phospho-ERK polyclonal antibody (bottom).
C, ERK8 autophosphorylation assay. COS cells were
transiently transfected with either the kinase-deficient HA-ERK8 mutant
(K42R) or HA-ERK8 and either pEVX, the kinase-deficient c-Src (K295R),
or v-Src. Lysates were immunoprecipitated using the anti-HA (HA.11)
monoclonal antibody, and enzyme activity was measured by an immune
complex kinase assay (top). Western analysis of the
immunoprecipitated proteins was performed with the anti-HA 3F10
monoclonal antibody (bottom). D, graphical
depiction of the relative kinase activity of ERK8 following
co-transfection with v-Src. ERK8 autophosphorylation was normalized to
the amount of enzyme present as determined by densitometric scanning of
the anti-HA 3F10 Western analysis. The value for ERK8 alone was
empirically determined to be 1. The data represent the summary of four
independent experiments. E, COS cells were transiently
transfected with HA-ERK8 and either pEVX, the constitutively active
c-Src (Y527F), or v-Src. Cells from each transfection group were
treated with 10 µM U0126 or the vehicle,
Me2SO, for 15 min. Lysates were prepared, separated by
SDS-PAGE, and analyzed by Western blotting with either the anti-HA 3F10
monoclonal antibody (top) or the anti-phospho-ERK polyclonal
antibody (middle and bottom). The data represent
the summary of three independent experiments.
|
|
Other than ERK7, members of the ERK family require an upstream MEK for
activation. We used a potent MEK inhibitor to determine whether MEK1,
MEK2, or MEK5 are involved in the activation of ERK8 by Src. Cells
co-transfected with HA-ERK8 and either the empty vector, c-Src Y527F,
or v-Src were pretreated with 10 µM U0126 or
Me2SO for 15 min. Cell lysates were analyzed by Western blotting with either the anti-HA antibody (Fig. 8E,
top) or the anti-phospho-ERK antibody (Fig. 8E,
middle and bottom). Both c-Src Y527F and v-Src
increased ERK8 activation as determined by increased TEY
phosphorylation (Fig. 8E, middle). However,
whereas U0126 inhibited TEY phosphorylation of ERK1 and ERK2 (Fig.
8E, bottom), no difference in TEY phosphorylation
was seen between cells pretreated with or without U0126 (Fig.
8E, middle). These results indicate that ERK8
activation by c-Src or v-Src is independent of MEK1, MEK2, and MEK5.
ERK8 Can Be Activated by Serum--
To identify physiologic
activators of ERK8, COS cells transfected with HA-ERK8 were treated
with 20% FBS following serum starvation. When normalized for ERK8
protein amount, Western analysis using the anti-phospho-ERK antibody
revealed a 2.5-fold increase in ERK8 TEY phosphorylation (Fig.
9A). This increase, observed
between 30 and 60 min following serum stimulation, was sustained for at least 2 h. Additional measurements done at 1, 10, and 15 min
showed no change in TEY phosphorylation from base line (data not
shown). To determine whether Src family members play a role in serum
activation of ERK8, cells were pretreated with the Src inhibitor PP2
(21). At a concentration of 10 µM PP2, a small but
consistent reduction in ERK8 TEY phosphorylation following stimulation
with 20% FBS was seen (Fig. 9B). At a concentration of 50 µM PP2, a 50% reduction in ERK8 TEY phosphorylation was
observed (Fig. 9B, middle). PP2 inhibited the
serum-induced increase, because pretreatment with PP2 alone did not
reduce the basal level of ERK8 TEY phosphorylation (data not shown). At
these concentrations of PP2, similar reductions in ERK1 and ERK2 TEY
phosphorylation were seen (Fig. 9B, bottom). Western analysis also detected a similar reduction in the
Tyr-416-phosphorylated form of exogenously expressed c-Src in these
cells (data not shown). This activation loop tyrosine is phosphorylated
in active forms of c-Src (22). To determine whether MEK1, MEK2, or MEK5
play a role in the serum activation of ERK8, cells transfected with HA-ERK8 were pretreated with 10 µM U0126. No difference
in TEY phosphorylation was seen between cells pretreated with or
without U0126 (Fig. 9C, top and
middle). On the other hand, increased TEY phosphorylation of
ERK1 and ERK2 was inhibited completely (Fig. 9C,
bottom). These results suggest that activation of ERK8 following serum stimulation requires Src family kinases but occurs independently of MEK1, MEK2, and MEK5.
View larger version (37K):
[in this window]
[in a new window]
|
Fig. 9.
ERK8 can be activated by serum.
A, COS cells were transiently transfected with HA-ERK8,
serum-starved for 18 h, and treated with 20% fetal bovine serum
(FBS) for the times indicated. Lysates were prepared, separated by
SDS-PAGE, and analyzed by Western blotting with either the
anti-phospho-ERK polyclonal antibody (top) or the anti-HA
3F10 monoclonal antibody (bottom). B, COS
cells transfected with HA-ERK8 and serum-starved for 18 h were
pretreated with either PP2 or the vehicle, Me2SO, for 15 min. FBS was added at a final concentration of 20% for 60 min to the
indicated groups. Lysates were prepared, separated by SDS-PAGE, and
analyzed by Western blotting with either the anti-HA 3F10 monoclonal
antibody (top) or the phospho-ERK polyclonal antibody
(middle and bottom). C, COS cells
transiently transfected with HA-ERK8 were serum-starved for 18 h
and then pretreated with either 10 µM U0126 or the
vehicle, Me2SO, for 15 min. FBS was added at a final
concentration of 20% for 60 min to the indicated groups. Lysates were
prepared, separated by SDS-PAGE, and analyzed by Western blotting with
either the anti-HA 3F10 monoclonal antibody (top) or the
phospho-ERK polyclonal antibody (middle and
bottom). The data shown are representative of three
experiments.
|
|
| |
DISCUSSION |
ERK8, identified through a library screen using the ERK7 cDNA
as a probe, is a newly identified member of the ERK family. Analysis of
the evolutionary tree (Fig. 10)
suggests that ERK7 and ERK8 form a discrete branch within the ERK
family of MAPKs. Although ERK8 and ERK7 share an overall amino acid
sequence identity of 69%, this sequence identity is significantly
lower than that shared between the orthologues of ERK1, ERK2, or ERK5
which are highly conserved across mammalian species. For example, rat
and human ERK1 and ERK2 share 97 and 99% overall sequence identity, respectively. Even the much larger ERK5 with its extended C-terminal region shares an overall sequence identity of 92% between mouse ERK5
and human ERK5 (20). The sequence identity shared between the kinase
domains of ERK7 and ERK8 is only 82%, and the isolated C-terminal
regions share only 53% amino acid identity. The primary sequences,
taken in the context of the other ERK family members, indicate that
ERK7 and ERK8 are related but distinct molecules.
View larger version (13K):
[in this window]
[in a new window]
|
Fig. 10.
ERK8 kinase domain phylogenetic tree. A
computer-generated phylogenetic tree of the kinase domains of ERK8 and
various serine/threonine kinases was constructed using the Neighbor
Joining method (34) with Kimura's correction (InforMax, Inc. Bethesda,
MD). The multiple sequence alignment used was generated using the
ClustalW algorithm (35). The amino acid identities of the kinase
domains between ERK8 and the other kinases are indicated at the
right as percentages. The GenBankTM accession
numbers are human CDK2 (CAA43807), human ERK1 (X60188), human ERK2
(M84489), human ERK5 (U25278), human ERK8 (AY065978), rat ERK7
(AF078798), human STK9 (XM_010185), human KKIALRE (X66358), and human
MOK (AB022694).
|
|
The biochemical properties of ERK8 verify this distinction. ERK7 is
unique because it displays a high level of constitutive activity even
in serum-starved cells (10, 11). ERK8, on the other hand, does not have
the same degree of constitutive activity. Because we have not yet
identified a suitable in vitro substrate, a direct
comparison of their kinase activities could not be made. However,
Western analysis of lysates from mammalian cells using an antibody that
preferentially recognizes the dually phosphorylated TEY motif suggests
that, under similar conditions, ERK8 is not as highly
TEY-phosphorylated as ERK7. By contrast, both serum and Src increase
TEY phosphorylation of ERK8 but not ERK7. These results indicate that,
unlike ERK7, a significant fraction of ERK8 is not TEY-phosphorylated
in the basal state. Although lack of an effective ERK8 substrate limits
our ability to characterize ERK8 biochemically, it also supports the
conclusion that ERK8 and ERK7 are distinct members of the ERK family.
GST-c-Fos is an in vitro substrate for ERK7 (11). However,
ERK8 does not phosphorylate GST-c-Fos in vitro even
following activation by v-Src (data not shown). Not surprisingly,
orthologues of ERK1, ERK2, and ERK5, as well as other members of the
MAPK family share the same activation and substrate profiles across
several species. The relatively low sequence identity and different
substrate profile indicate that ERK8 is a distinct member of the ERK family.
A possible clue to the cellular function of ERK8 may come from the
finding that v-Src and c-Src can activate ERK8. The Src family of
nonreceptor tyrosine kinases, like the MAPKs, has been implicated in a
wide range of cellular pathways involving signals initiated from
G-protein-linked receptors, growth factor receptor protein tyrosine
kinases, integrins, cytokine receptors, and even ion channels (23).
There are at least nine members of the Src family (Blk, Hck, Fgr, Fyn,
Lck, Lyn, Src, Yes, and Yrk). The common structural features include an
SH3 domain and an SH2 domain that are N-terminal to the kinase domain.
The crystal structure of c-Src indicates that these domains interact to
regulate the kinase activity of Src (24, 25). In addition to regulating its activity, the SH3 and SH2 domains are also involved in interactions with its substrates. For example, phosphatidylinositol 3-kinase can
bind to c-Src through an interaction between its p85 subunit and the
SH3 domain of c-Src (26), as does paxillin (27). Similarly, Sam68 and
actin filament-associated protein p110 interact with the SH3 and SH2
domains of c-Src (28, 29), and cortactin and focal adhesion kinase
interact with the SH2 domain (30, 31). SH3 domains are known to bind to
proteins that contain a proline-rich motif, PXXP (32). ERK8
contains two of these motifs within its C-terminal region that could
facilitate its interaction with SH3 domain-containing proteins such as
c-Src. The ability of the specific Src family inhibitor PP2 to
partially inhibit ERK8 activation following serum stimulation supports
the notion that activation of ERK8 by c-Src is physiologically
relevant. Taken together with the observation that Src both associates
with and activates ERK8 in cells, these results suggest that ERK8 is a
downstream effector of one or more Src family kinases.
It seems unlikely that c-Src, a tyrosine kinase, activates ERK8
directly because ERK activation requires phosphorylation of the
threonine residue in addition to the tyrosine residue within the TEY
activation motif. For ERK1, ERK2, and ERK5, this dual phosphorylation
is performed by MEK1, MEK2, or MEK5. The inability of the specific MEK
inhibitor U0126 to block ERK8 activation by Src or serum indicates that
these MEKs are not the upstream activators of ERK8 (33). However, it is
possible that Src activates ERK8 through a classical signaling cascade
involving an unidentified MEK. The ability of ERK8 to interact directly
with c-Src suggests that they are components of a larger signaling
complex that may serve as a selective activation mechanism, a potential
feedback regulator, or a means for cellular localization of ERK8.
Because c-Src has been implicated in several intracellular signaling
pathways including those originating from receptor protein tyrosine
kinases, integrins, G-protein-coupled receptors, and cytokine
receptors, additional studies will be required to determine the
specific pathway(s) that involve ERK8. Identification of natural substrates will certainly provide insight into its cellular function. Nonetheless, the identification of ERK8 expands the ERK family of MAPKs
and reinforces the notion that additional members with regulatory
C-terminal regions may exist.
| |
ACKNOWLEDGEMENTS |
We thank C. Spackman and S. Gomes for
technical assistance and J. Brugge, T. Deng, D. Foster, D. Guernert, N. Hay, W. Li, B. Mayer, C. Turner, R. Treisman, and E. Wattenberg for
generously providing reagents.
| |
FOOTNOTES |
*
This work was supported by National Institute of Health
Grants HL03867 (to M. K. A.), HL54685 (to M. B. H.), HL63314 (to
M. B. H.), HL56399 (to M. B. H.), CA40046 (to M. M. L.), and
GM61038 (to M. R. R.), the American Lung Association of Metropolitan
Chicago (to M. K. A.), the Dorothy and Gaylord Donnelley Foundation
(to M. K. A.), and a gift from the Cornelius Crane Trust Fund for Eczema Research (to M. R. R.).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.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EBI Data Bank with accession number(s) AY065978.
§
To whom correspondence should be addressed: Pulmonary Biology and
Critical Care, University of Chicago, 5841 S. Maryland Ave., MC4064,
Chicago, IL 60637-1470. Tel.: 773-702-9659; Fax: 773-702-4041; E-mail:
markabe@ben-may.bsd.uchicago.edu.
Published, JBC Papers in Press, March 1, 2002, DOI 10.1074/jbc.M112483200
| |
ABBREVIATIONS |
The abbreviations used are:
MAPKs, mitogen-activated protein kinases;
ERKs, extracellular signal-regulated
kinases;
BSA, bovine serum albumin;
MBP, myelin basic protein;
HA, hemagglutinin;
FBS, fetal bovine serum;
PBS, phosphate-buffered saline;
TLB, Triton-based lysis buffer;
GST, glutathione
S-transferase;
PMSF, phenylmethylsulfonyl fluoride;
pAb, polyclonal antibody;
EST, expressed sequence tags;
SH, Src
homology.
| |
REFERENCES |
| 1.
|
Pearson, G.,
Robinson, F.,
Beers Gibson, T., Xu, B.,
Karandikar, M.,
Berman, K.,
and Cobb, M. H.
(2001)
Endocr. Rev.
22,
153-183[Abstract/Free Full Text]
|
| 2.
|
Lewis, T. S.,
Shapiro, P. S.,
and Ahn, N. G.
(1998)
Adv. Cancer Res.
74,
49-139[Medline]
[Order article via Infotrieve]
|
| 3.
|
Robinson, M. J.,
and Cobb, M. H.
(1997)
Curr. Opin. Cell Biol.
9,
180-186[CrossRef][Medline]
[Order article via Infotrieve]
|
| 4.
|
Waskiewicz, A. J.,
and Cooper, J. A.
(1995)
Curr. Opin. Cell Biol.
7,
798-805[CrossRef][Medline]
[Order article via Infotrieve]
|
| 5.
|
Janulis, M.,
Trakul, N.,
Greene, G.,
Schaefer, E. M.,
Lee, J. D.,
and Rosner, M. R.
(2001)
Mol. Cell. Biol.
21,
2235-2247[Abstract/Free Full Text]
|
| 6.
|
Zhou, G.,
Bao, Z. Q.,
and Dixon, J. E.
(1995)
J. Biol. Chem.
270,
12665-12669[Abstract/Free Full Text]
|
| 7.
|
Lee, J. D.,
Ulevitch, R. J.,
and Han, J.
(1995)
Biochem. Biophys. Res. Commun.
213,
715-724[CrossRef][Medline]
[Order article via Infotrieve]
|
| 8.
|
Yan, C.,
Luo, H.,
Lee, J.-D.,
Abe, J.,
and Berk, B. C.
(2001)
J. Biol. Chem.
276,
10870-10878[Abstract/Free Full Text]
|
| 9.
|
Kasler, H. G.,
Victoria, J.,
Duramad, O.,
and Winoto, A.
(2000)
Mol. Cell. Biol.
20,
8382-8389[Abstract/Free Full Text]
|
| 10.
|
Abe, M. K.,
Kahle, K. K.,
Saelzler, M. P.,
Orth, K.,
Dixon, J. E.,
and Rosner, M. R.
(2001)
J. Biol. Chem.
276,
21272-21279[Abstract/Free Full Text]
|
| 11.
|
Abe, M. K.,
Kuo, W. L.,
Hershenson, M. B.,
and Rosner, M. R.
(1999)
Mol. Cell. Biol.
19,
1301-1312[Abstract/Free Full Text]
|
| 12.
|
Deng, W. P.,
and Nickoloff, J. A.
(1992)
Anal. Biochem.
200,
81-88[CrossRef][Medline]
[Order article via Infotrieve]
|
| 13.
|
Chao, T. S.,
Abe, M.,
Hershenson, M. B.,
Gomes, I.,
and Rosner, M. R.
(1997)
Cancer Res.
57,
3168-3173[Abstract/Free Full Text]
|
| 14.
|
Johnson, P. J.,
Coussens, P. M.,
Danko, A. V.,
and Shalloway, D.
(1985)
Mol. Cell. Biol.
5,
1073-1083[Abstract/Free Full Text]
|
| 15.
|
Kmiecik, T. E.,
and Shalloway, D.
(1987)
Cell
49,
65-73[CrossRef][Medline]
[Order article via Infotrieve]
|
| 16.
|
Cozens, A. L.,
Yezzi, M. J.,
Kunzelmann, K.,
Ohrui, T.,
Chin, L.,
Eng, K.,
Finkbeiner, W. E.,
Widdicombe, J. H.,
and Gruenert, D. C.
(1994)
Am. J. Respir. Cell Mol. Biol.
10,
38-47[Abstract]
|
| 17.
|
Abe, M. K.,
Chao, T. S.,
Solway, J.,
Rosner, M. R.,
and Hershenson, M. B.
(1994)
Am. J. Respir. Cell Mol. Biol.
11,
577-585[Abstract]
|
| 18.
|
Espinosa, R., III,
and Le Beau, M.
(1997)
Methods Mol. Biol.
68,
53-76[Medline]
[Order article via Infotrieve]
|
| 19.
|
Altschul, S. F.,
Gish, W.,
Miller, W.,
Myers, E. W.,
and Lipman, D. J.
(1990)
J. Mol. Biol.
215,
403-410[CrossRef][Medline]
[Order article via Infotrieve]
|
| 20.
|
Kamakura, S.,
Moriguchi, T.,
and Nishida, E.
(1999)
J. Biol. Chem.
274,
26563-26571[Abstract/Free Full Text]
|
| 21.
|
Hanke, J. H.,
Gardner, J. P.,
Dow, R. L.,
Changelian, P. S.,
Brissette, W. H.,
Weringer, E. J.,
Pollok, B. A.,
and Connelly, P. A.
(1996)
J. Biol. Chem.
271,
695-701[Abstract/Free Full Text]
|
| 22.
|
Brown, M. T.,
and Cooper, J. A.
(1996)
Biochim. Biophys. Acta
1287,
121-149[Medline]
[Order article via Infotrieve]
|
| 23.
|
Thomas, S.,
and Brugge, J.
(1997)
Annu. Rev. Cell Dev. Biol.
13,
513-609[CrossRef][Medline]
[Order article via Infotrieve]
|
| 24.
|
Xu, W.,
Harrison, S.,
and Eck, M.
(1997)
Nature
385,
595-602[CrossRef][Medline]
[Order article via Infotrieve]
|
| 25.
|
Xu, W.,
Doshi, A.,
Lei, M.,
Eck, M. J.,
and Harrison, S. C.
(1999)
Mol. Cell
3,
629-638[CrossRef][Medline]
[Order article via Infotrieve]
|
| 26.
|
Liu, X.,
Marengere, L. E.,
Koch, C. A.,
and Pawson, T.
(1993)
Mol. Cell. Biol.
13,
5225-5232[Abstract/Free Full Text]
|
| 27.
|
Turner, C. E.,
and Miller, J. T.
(1994)
J. Cell Sci.
107,
1583-1591[Abstract]
|
| 28.
|
Fumagalli, S.,
Totty, N. F.,
Hsuan, J. J.,
and Courtneidge, S. A.
(1994)
Nature
368,
871-874[CrossRef][Medline]
[Order article via Infotrieve]
|
| 29.
|
Flynn, D. C.,
Leu, T. H.,
Reynolds, A. B.,
and Parsons, J. T.
(1993)
Mol. Cell. Biol.
13,
7892-7900[Abstract/Free Full Text]
|
| 30.
|
Okamura, H.,
and Resh, M. D.
(1995)
J. Biol. Chem.
270,
26613-26618[Abstract/Free Full Text]
|
| 31.
|
Xing, Z.,
Chen, H. C.,
Nowlen, J. K.,
Taylor, S. J.,
Shalloway, D.,
and Guan, J. L.
(1994)
Mol. Biol. Cell
5,
413-421[Abstract]
|
| 32.
|
Yu, H.,
Chen, J. K.,
Feng, S.,
Dalgarno, D. C.,
Brauer, A.,
and Schrieber, S. L.
(1994)
Cell
76,
933-945[CrossRef][Medline]
[Order article via Infotrieve]
|
| 33.
|
Mody, N.,
Leitch, J.,
Armstrong, C.,
Dixon, J.,
and Cohen, P.
(2001)
FEBS Lett.
502,
21-24[CrossRef][Medline]
[Order article via Infotrieve]
|
| 34.
|
Saitou, N.,
and Nei, M.
(1987)
Mol. Biol. Evol.
4,
406-425[Abstract]
|
| 35.
|
Thompson, J. D.,
Higgins, D. G.,
and Gibson, T. J.
(1994)
Nucleic Acids Res.
22,
4673-4680[Abstract/Free Full Text]
|
Copyright © 2002 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
|
|
 
T. Boutros, E. Chevet, and P. Metrakos
Mitogen-Activated Protein (MAP) Kinase/MAP Kinase Phosphatase Regulation: Roles in Cell Growth, Death, and Cancer
Pharmacol. Rev.,
September 1, 2008;
60(3):
261 - 310.
|
TOP
ABSTRACT
INTRODUCTION
