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Molecular and Cellular Biology, November 1999, p. 7539-7548, Vol. 19, No. 11
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
JSAP1, a Novel Jun N-Terminal Protein Kinase
(JNK)-Binding Protein That Functions as a Scaffold Factor in the JNK
Signaling Pathway
Michihiko
Ito,1
Katsuji
Yoshioka,2,*
Mizuho
Akechi,1
Shinya
Yamashita,3
Nobuhiko
Takamatsu,1
Kenji
Sugiyama,4
Masahiko
Hibi,5
Yusaku
Nakabeppu,6
Tadayoshi
Shiba,1 and
Ken-Ichi
Yamamoto2
Department of Biosciences, School of Science,
Kitasato University, Kanagawa 228,1
Department of Molecular Pathology, Cancer Research Institute,
Kanazawa University, Kanazawa 920,2
Central Research Laboratory, Nippon Suisan Kaisha Ltd., Tokyo
192,3 Nippon Boehringer Ingelheim Co.,
Ltd., Kawanishi Pharma Research Institute, Department of
Molecular and Cellular Biology, Hyogo 666,4
Department of Molecular Oncology, Biomedical Research Center,
Osaka University Medical School, Osaka 565,5 and
Department of Biochemistry, Medical Institute of Bioregulation,
Kyushu University, and CREST, Japan Science and Technology, Fukuoka
812,6 Japan
Received 17 June 1999/Returned for modification 28 July
1999/Accepted 12 August 1999
 |
ABSTRACT |
The major components of the mitogen-activated protein kinase (MAPK)
cascades are MAPK, MAPK kinase (MAPKK), and MAPKK kinase (MAPKKK).
Recent rapid progress in identifying members of MAPK cascades suggests
that a number of such signaling pathways exist in cells. To date,
however, how the specificity and efficiency of the MAPK cascades is
maintained is poorly understood. Here, we have identified a novel mouse
protein, termed Jun N-terminal protein kinase (JNK)/stress-activated
protein kinase-associated protein 1 (JSAP1), by a yeast two-hybrid
screen, using JNK3 MAPK as the bait. Of the mammalian MAPKs tested
(JNK1, JNK2, JNK3, ERK2, and p38
), JSAP1 preferentially
coprecipitated with the JNKs in cotransfected COS-7 cells. JNK3 showed
a higher binding affinity for JSAP1, compared with JNK1 and JNK2. In
similar cotransfection studies, JSAP1 also interacted with SEK1 MAPKK
and MEKK1 MAPKKK, which are involved in the JNK cascades. The regions
of JSAP1 that bound JNK, SEK1, and MEKK1 were distinct from one
another. JNK and MEKK1 also bound JSAP1 in vitro, suggesting that these
interactions are direct. In contrast, only the activated form of SEK1
associated with JSAP1 in cotransfected COS-7 cells. The unstimulated
SEK1 bound to MEKK1; thus, SEK1 might indirectly associate with JSAP1 through MEKK1. Although JSAP1 coprecipitated with MEK1 MAPKK and Raf-1
MAPKKK, and not MKK6 or MKK7 MAPKK, in cotransfected COS-7 cells, MEK1
and Raf-1 do not interfere with the binding of SEK1 and MEKK1 to JSAP1,
respectively. Overexpression of full-length JSAP1 in COS-7 cells led to
a considerable enhancement of JNK3 activation, and modest enhancement
of JNK1 and JNK2 activation, by the MEKK1-SEK1 pathway. Deletion of the
JNK- or MEKK1-binding regions resulted in a significant reduction in
the enhancement of the JNK3 activation in COS-7 cells. These results
suggest that JSAP1 functions as a scaffold protein in the JNK3 cascade.
We also discuss a scaffolding role for JSAP1 in the JNK1 and JNK2 cascades.
| |
INTRODUCTION |
The mitogen-activated protein kinase
(MAPK) cascades, in which the major components are MAPK, MAPK kinase
(MAPKK), and MAPKK kinase (MAPKKK), are conserved eukaryotic signaling
pathways (2, 7, 14, 46). The general function of the MAPK
cascades is to link a variety of extracellular stimuli to nuclear
responses, i.e., the modulation of gene expression (45).
MAPK is activated by dual phosphorylation on threonine and tyrosine
residues catalyzed by MAPKK, and MAPKK is activated by serine/threonine
phosphorylation catalyzed by MAPKKK. In mammals, at least three MAPK
cascades have been identified. The MAPKs in each pathway are ERK
(extracellular signal-regulated kinase), JNK/SAPK (c-Jun N-terminal
kinase/stress-activated protein kinase), and p38. The ERK cascade is
mostly responsive to mitogenic and differentiation stimuli, whereas the
JNK and p38 cascades are strongly activated by proinflammatory
cytokines, such as interleukin 1 (IL-1) and tumor necrosis factor alpha
(TNF-), and extracellular stresses, such as UV irradiation and
osmotic shock (4, 23, 29, 36).
In the ERK cascade, Raf (Raf-1, A-Raf, and B-Raf), MEK (MEK1 and MEK2),
and ERK (ERK1 and ERK2) correspond to MAPKKK, MAPKK, and MAPK,
respectively (36). The p38 cascade contains
p38/CSBP/RK/Mxi2 (12, 25, 37, 56) and p38
(18) as MAPKs and MKK3 (9) and MKK6 (6, 13,
32, 35, 42) as MAPKKs, while in the JNK cascade the MAPKs are
JNK1, JNK2, and JNK3 (also known as SAPK
, SAPK, and SAPK,
respectively) (8, 11, 19, 22, 31), and the MAPKKs are
SEK1/MKK4/JNKK1 (9, 26, 38) and MKK7/JNKK2 (33, 44,
48). The specificity of the MAPKKKs involved in the JNK and p38
cascades is less clear. For instance, the TAK1 (52), ASK1
(16), and MLK3 (43) MAPKKKs can activate both the
JNK and p38 cascades, while the MEKK1 (28, 50, 53) and MEKK4
(10) MAPKKKs selectively activate the JNK cascade.
The identification of numerous components of the MAPK cascades as
described above suggests that there are a number of these distinct
signaling pathways in cells. Furthermore, studies of JNK3-deficient
mice (54) indicate the existence of a JNK3-specific cascade
that cannot be complemented by the other JNK family members, even
though JNK1, JNK2, and JNK3 exhibit over 80% identity, and these JNKs
seem to be similarly regulated by the upstream kinases, at least in
transiently transfected cells. The tissue distributions of the JNKs are
quite different: JNK3 is specifically expressed in the brain, while
JNK1 and JNK2 are widely expressed. How the specificity and efficiency
of the MAPK cascades is maintained is largely unknown.
In this paper, we report the molecular cloning and characterization of
a novel JNK-binding protein, termed JSAP1 (JNK/SAPK-associated protein
1). Through cotransfection studies of COS-7 cells, we observed
preferential interactions between JSAP1 and the JNKs (JNK1, JNK2, and
JNK3), SEK1, and MEKK1. The regions of JSAP1 that bind JNK, SEK1, and
MEKK1 were distinct from one another. JNK3 exhibited higher binding
affinity to JSAP1 compared with JNK1 and JNK2. JNK and MEKK1 also bound
JSAP1 in vitro, suggesting that these interactions are direct. In
contrast, only the activated form of SEK1 interacted with JSAP1 in
cotransfected cells. The unstimulated SEK1 bound to MEKK1; thus, SEK1
might associate with JSAP1 through MEKK1. Overexpressing full-length
JSAP1 in COS-7 cells considerably enhanced the JNK3 activation, and
modestly enhanced the JNK1 and JNK2 activation, through the MEKK1-SEK1 pathway. JSAP1 mutants lacking the JNK- or MEKK1-binding regions significantly reduced of the enhancement of the JNK3 activation. These
results suggest that JSAP1 functions as a scaffold protein in the JNK3
cascade. A scaffolding role of JSAP1 in the JNK1 and JNK2 cascades is
also discussed.
| |
MATERIALS AND METHODS |
Isolation of cDNAs.
A mouse brain cDNA library (Stratagene)
was screened by using a partial JSAP1 cDNA fragment, obtained from a
yeast two-hybrid screen, as a probe. A full-length cDNA was isolated,
and the open reading frame (ORF) of JSAP1 was sequenced. cDNAs
containing the ORFs of JNK1, -2, and -3 were isolated from the same
cDNA library. The probes used to screen the library were generated by
PCR, with mouse brain cDNA as the template and using the following
primers, whose design was based on the rat JNK1, -2, and -3 cDNA
sequences (22), respectively: JNK1-S
(5'-GCAGATTCTACATTCACAGTCCTA-3'; 5' end at nucleotide 46),
JNK1-A (5'-CATTTCTCCCATAATGCACCCCAC-3'; 5' end at 654),
JNK2-S (5'-GTGGCAGACTCAACTTTCACTGTT-3'; 5' end at 43),
JNK2-A (5'-GTAGCCCATGCCCAGGATGACTTC-3'; 5' end at 606), JNK3-S (5'-ACAGTTCTAAAGCGCTACCAGAAC-3'; 5' end at 61), and
JNK3-A (5'-GTGACGAACCTATTCTCCCATGAT-3'; 5' end at 663).
Nucleotide numbering starts with +1, which represents the first
nucleotide in the initiation codon ATG of the corresponding rat JNK gene.
The partial nucleotide sequence of mouse MEKK1 cDNA has been reported
elsewhere (24). MEKK1 residues 656 to 1488 were amplified from mouse spleen cDNA by PCR using the primers
5'-TACACTCCTTGCCACAGTCTGGCA-3' and
5'-ACTACCACGTGGTACGGAAGACCG-3'.
Mouse MEKK1 cDNA encoding the N-terminal region was isolated from a
mouse spleen cDNA library (Stratagene). The probe used to screen the
library was generated by two-step PCR using the following primers,
whose design was based on the rat MEKK1 cDNA sequence (50):
MEKK1-S1 (5'-ACCTGTATGCCTGCCTGGAAGCAC-3'; 5' end at 544),
MEKK1-S2 (5'-TGGTGGTGAAACCAATCCCTATTA-3'; 5' end at 602),
MEKK1-A1 (5'-TTGAGCTACGCCTACTGTGGTATT-3'; 5' end at 1165), and MEKK1-A2 (5'-TTCCGAGATGGAGCTTTGATTCTT-3'; 5' end at
1187. Numbering of the nucleotides is as described above.
The first PCR was performed with MEKK1-S1 and -A2 primers with mouse
spleen cDNA. An aliquot (1 µl) of the first PCR product
was used in
the second PCR with the nested MEKK1-S2 and -A1 primers.
The
full-length human Raf-1 cDNA was obtained from Health Science
Research
Resources Bank, Osaka, Japan. The ORFs of ERK2, MKK6,
p38
, MKK7,
MEK1, and SEK1 were amplified by PCR from human lymphocyte
(for ERK2
and MKK6), mouse thymus (for p38
, MKK7, and MEK1),
or mouse brain
(for SEK1) cDNA. The products were inserted into
the
EcoRV
site of pBluescript II KS(+) (Stratagene), and the nucleotide
sequences
were confirmed by DNA
sequencing.
Plasmid construction.
The ORFs of JNK1, JNK2, JNK3, and ERK2
were amplified by PCR. The products (each of which contains a
NcoI site at the 5' end and a BamHI site at the
3' end of the sense strand) were first digested with NcoI,
filled in, ligated with a phosphorylated NotI linker
(5'-pGCGGCCGC-3'), and then digested with NotI
and BamHI. The NotI-BamHI fragments
were subcloned into NotI/BamHI-digested pFlag-CMV2 (Kodak) to generate pFlag-CMV2-JNK1, -JNK2, -JNK3, and
-ERK2. The ORF of p38 was amplified by PCR. The product (containing a NotI site at the 5' end and a BamHI site at the
3' end of the sense strand) was inserted into the EcoRV site
of pBluescript II KS(+). The NotI-BamHI fragment
of the plasmid was subcloned into
NotI/BamHI-digested pFlag-CMV2 to generate
pFlag-CMV2-p38.
A double-stranded Flag linker consisting of annealed and phosphorylated
oligonucleotides 5'-pAGCTACCATGGACTACAAAGACGATGACGACA-3'
and
5'-pAGCTTGTCGTCATCGTCTTTGTAGTCCATGGT-3' was inserted at the
HindIII site of pcDNA3 (Invitrogen) to generate
pcDNA3-Flag. The
ORFs of SEK1, MEK1, MKK6, and MKK7 were amplified by
PCR. The
products (each of which contains a
HindIII site
at the 5' end
and an
XbaI site at the 3' end of the sense
strand) were inserted
into the
EcoRV site of pBluescript II
KS(+). The
HindIII-
XbaI
fragments of the
plasmids were subcloned into
HindIII/
XbaI-digested
pcDNA3-Flag
to generate pcDNA3-Flag-SEK1, -MEK1, -MKK6, and -MKK7.
The N-terminal
region (residues 1 to 327) of Raf-1 was amplified
by PCR. The product
(containing an
EcoRI site at the 5' end and
a stop codon at
the 3' end of the sense strand) was digested with
EcoRI and
subcloned into
EcoRI/
EcoRV-digested pcDNA3-Flag
to generate
pcDNA3-Raf-N. Similarly, the C-terminal region (residues
316 to
648) of Raf-1 was amplified by PCR. The product (containing a
stop codon followed by an
XhoI site at the 3' end of the
sense
strand) was digested with
XhoI and subcloned into
EcoRV/
XhoI-digested
pcDNA3-Flag to generate
pcDNA3-Flag-Raf-C. pcDNA3-Flag-
Raf is
identical to
pcDNA3-Flag-Raf-C. The region encoding residues 1169
to 1488 of MEKK1
was amplified by PCR. The product (containing
a
HindIII
site at the 5' end and a
BamHI site at the 3' end of
the
sense strand) was digested with
HindIII and
BamHI and subcloned
into
HindIII/
BamHI-digested pcDNA3-Flag to
generate pcDNA3-Flag-
MEKK.
The
BamHI-
NcoI
fragment (containing a 15-bp 5' flanking sequence
and 1,653-bp coding
sequence [residues 1 to 551]) was excised
from MEKK1 N-terminal cDNA.
The region encoding residues 551 to
640 of MEKK1 was amplified by PCR.
The product (containing an
NcoI site at the 5' end and a
stop codon followed by an
EcoRI
site at the 3' end of the
sense strand) was digested with
NcoI
and
EcoRI.
The
BamHI-
NcoI and
NcoI-
EcoRI fragments were subcloned
together into
BamHI/
EcoRI-digested pcDNA3-Flag to generate
pcDNA3-Flag-MEKK-N.
The
NcoI-
EcoRV fragment
(containing an 2,814-bp coding sequence
[residues 551 to 1488], a
stop codon, an 8-bp 3' flanking sequence,
and a
HindIII
site followed by an
EcoRV site at the 3' end of
the sense
strand) was excised from a mouse MEKK1 cDNA. The
BamHI-
NcoI
and
NcoI-
EcoRV
fragments were subcloned together into
BamHI/
EcoRV-digested
pcDNA3-Flag to generate
pcDNA3-Flag-MEKK1. pcDNA3-Flag-MEKK1 was
used for in vitro
transcription-translation.
A 0.2-kb
BalI-
XhoI fragment of pET32b (Novagen)
containing multiple cloning sites, a His-tag coding sequence, and an
S-tag
coding sequence was inserted into
HindIII (filled
in)/
XhoI-digested
pcDNA3 to generate pcDNA3-His-S. The
N-terminal region (residues
1 to 343) of JSAP1 was amplified by PCR.
The product (containing
an
EcoRI site at the 5' end and a
HindIII site at the 3' end of
the sense strand) was
digested with
EcoRI and
HindIII and subcloned
into
EcoRI/
HindIII-digested pcDNA3-His-S to
generate pcDNA3-His-S-JSAP1-N.
The C-terminal region (residues 1233 to
1305) of JSAP1 was amplified
by PCR. The product (containing an
ApaI site at the 5' end and
a stop codon followed by an
XhoI site at the 3' end of the sense
strand) was digested
with
ApaI and
XhoI. The
HindIII-
ApaI fragment
(encoding residues 343 to 1233) was excised from the JSAP1 cDNA.
The
HindIII-
ApaI and
ApaI-
XhoI fragments were subcloned
together
into
HindIII/
XhoI-digested
pcDNA3-His-S-JSAP1-N to generate pcDNA3-His-S-JSAP1.
To
generate deletion mutants of JSAP1, portions of JSAP1 were
amplified by
PCR, and the products were inserted into pET32b or
pcDNA3-His-S. The
ORF of SEK1 was amplified by PCR. The products
(containing a
BamHI site at the 5' end and an
XhoI site at 3'
end of the sense strand) was digested with
BamHI and
XhoI. The
BamHI-
XhoI fragment was
subcloned into
BamHI/
XhoI-digested pET32a
to
generate pET32-SEK1. The deletion mutants pcDNA3-His-S-JSAP1-
1,
-
2, -
3, -
4, and -
5 encode residues 1 to 1053, 744 to 1305,
1054 to 1305, 343 to 1053, and 1 to 343, respectively. The deletion
mutants pcDNA3-His-S-JSAP1-
J, -
S, and -
M include deletions
of
the JNK-binding region (residues 115 to 233), the SEK1-binding
region
(residues 1054 to 1305), and the MEKK1-binding region (residues
343 to
744), respectively. pcDNA3-His-S-JSAP1-
S is identical
to
pcDNA3-His-S-JSAP1-
1. The deletion in pcDNA3-His-S-JSAP1-
J
was
generated by overlapping PCR (
1). The
HindIII
site at nucleotide
1025 in the JSAP1 cDNA was changed to a
BamHI site by PCR. The
BamHI site and the other
BamHI site at nucleotides 2228 were ligated
to generate the
deletion in the pcDNA3-His-S-JSAP1-
M. pcDNA3-Flag-MEKK
was first
digested with
BamHI, filled in, ligated with a
phosphorylated
HindIII linker (5'-CCAAGCTTGG-3'),
and then digested with
HindIII.
The
HindIII fragment containing the ORF of MEKK1 was
subcloned
into
HindIII-digested pcDNA3-His-S to generate
pcDNA3-His-S-MEKK1.
The
HindIII-
XbaI
fragments of pcDNA3-Flag-SEK1 and -MEK1 were
subcloned into
HindIII/
XbaI-digested pcDNA3-His-S to
generate
pcDNA3-His-S-SEK1 and -MEK1,
respectively.
To generate expression vectors for Trx (thioredoxin)-His-S-JSAP1 (T-0,
T-1, T-2, and T-3), site-directed mutagenesis was carried
out by using
overlapping PCR (
1). Mutated sequences were confirmed
by DNA
sequencing. The glutathione
S-transferase (GST)-c-Jun
(residues
1 to 79) expression vector was described previously
(
15).
The primers 5'-AAATCTAGATAAACGCTCAACTTTGGCC-3' and
5'-TTTACTGTCACCCATGGCGTA-3' were used in a PCR with
SR
-3XHA (
20) (a
gift from T. Deng) as the template. The
PCR product (which contains
an
XbaI site at the 5' end and
an
NcoI site at the 3' end of the
sense strand and
HA
3 [hemagglutinin] coding sequence) was inserted
into
the
EcoRV site of pBluescript II KS(+). The resulting
plasmid
(termed pKS-3XHA) has two
XbaI sites outside the
HA
3 coding sequence.
The region encoding residues 1169 to
1488 of MEKK1 was amplified
by PCR. The product (containing an
NcoI site at the 5' end and
a
BamHI site at the
3' end of the sense strand) was digested with
NcoI and
BamHI and subcloned into
NcoI/
BamHI-digested pKS-3XHA
to generate
pKS-3XHA-
MEKK. The
XbaI filler fragment of pEF-BOS
(
30) was replaced with the
XbaI fragment of
pKS-3XHA-
MEKK to
generate pEF-3XHA-
MEKK. A 0.28-kb
BamHI-
XhoI fragment of pCS3+MT
(a gift from D. Turner and R. Rupp) containing a Myc-tag coding
sequence was filled in
and inserted into
HindIII (filled in)-digested
pcDNA3 to
generate pcDNA3-Myc. pcDNA3-Flag-MEK1 was digested with
HindIII, filled in, and then digested with
XbaI. The
HindIII (filled
in)-
XbaI
fragment containing MEK1 ORF was subcloned into
NotI
(filled
in)/
XbaI-digested pcDNA3-Myc to generate pcDNA3-Myc-MEK1.
pGEM-3Zf(+) (Promega) was digested with
EcoRI, filled in,
ligated with phosphorylated
NcoI linker
(5'-pGCCATGGC-3'), digested
with
NcoI, and
self-ligated to generate pGEM-NCO. The ORF of JNK3
was amplified by
PCR. The product (containing an
NcoI site at
the 5' end a
BamHI site at the 3' end of the sense strand) was
digested
with
NcoI and
BamHI and subcloned into
NcoI/
BamHI-digested
pGEM-NCO and pAS2 (Clontech)
to generate pGEM-JNK3 and pAS2-JNK3,
respectively. pGEM-JNK3 and
pAS2-JNK3 were used for in vitro transcription-translation
and the
yeast two-hybrid screen,
respectively.
Two-hybrid screen.
A mouse brain cDNA library in pGAD10
(Clontech) was transfected into Saccharomyces cerevisiae
CG1945 harboring pAS2-JNK3. The Clontech yeast two-hybrid system was
used according to the manufacturer's instructions.
Northern blotting analysis.
Northern blotting analysis was
performed as described previously (55), using
32P-labeled JNK3, JSAP1, and -actin cDNA probes.
Analyses of protein-protein interactions in vitro and in
vivo.
Trx-His-S-JSAP1 proteins were expressed in Escherichia
coli and purified with S-protein-agarose or
nickel-nitrilotriacetic acid-agarose according to the manufacturers'
instructions. The TNT T7 Quick Coupled transcription-translation system
(Promega) was used for in vitro translation. The Trx-His-S-JSAP1
proteins bound to S-protein-agarose were mixed with in
vitro-translated 35S-labeled JNK3 or MEKK1 in buffer A (50 mM Tris-HCl [pH 7.5], 150 mM NaCl, 0.5% NP-40), rotated for 2 h
at 4°C, spun, and washed three times with buffer A. The precipitates
were separated by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) and subjected to autoradiography. The
phosphorylated form of Trx-His-S-JSAP1 (residues 115 to 274) was
prepared as follows. Flag-JNK3 that was activated by MEKK in COS-7
cells was immunoprecipitated with anti-Flag monoclonal antibody M5
(Kodak), resuspended in buffer B (50 mM HEPES [pH 7.5], 150 mM NaCl,
1% NP-40, 10% glycerol, 2 mM MgCl2, 1 mM EGTA, 20 mM
-glycerophosphate, 2 mM Na3VO4, 1 mM
phenylmethylsulfonyl fluoride, 0.2 mM dithiothreitol) containing unphosphorylated Trx-His-S-JSAP1 (residues 115 to 274), incubated for
30 min at 30°C in the presence of 1 mM ATP, and purified with S-protein-agarose. COS-7 cells transfected with Flag-tagged expression vectors were lysed in buffer C (20 mM Tris-HCl [pH 7.5], 150 mM NaCl,
0.5% NP-40, 0.5 mM EDTA, 0.5 mM dithiothreitol), mixed with immobilized Trx-His-S protein, Trx-His-S-JSAP1, or Trx-His-S-SEK1, rotated for 2 h, spun, and washed three times with buffer C. The precipitates were examined by immunoblotting with anti-Flag monoclonal antibody M5. For the analysis of protein-protein interactions in intact
cells, the expression vectors were cotransfected into COS-7 cells with
TransIT-LT1 (Mirus) according to the manufacturer's instructions.
After 34 h, cells were lysed in buffer B and precipitated by
S-protein-agarose. The recovered fractions were separated by SDS-PAGE
and transferred to Immobilon-P (Millipore). The membranes were probed
with anti-Flag monoclonal antibody M5 or anti-c-Myc monoclonal antibody
9E10 (Boehringer Mannheim) and visualized with the Amersham enhanced
chemiluminescence detection system. The phosphorylated forms of JNK3
and SEK1 were detected by phospho-specific JNK/SAPK and SEK1/MKK4
antibodies, respectively (New England Biolabs).
Protein kinase assay.
COS-7 cells were transfected with
pFlag-CMV2-JNK3 with expression vectors, using TransIT-LT1. After
34 h, the cells were lysed in buffer B and precipitated with
anti-Flag monoclonal antibody M5 bound to protein G-agarose. The
immunocomplex kinase assay was performed as described previously
(8).
Nucleotide sequence accession numbers.
The nucleotide
sequences of mouse JNK1, -2, and -3 cDNAs have been deposited in
DDBJ/EMBL/GenBank with accession no. AB005663, AB005664, and AB005665,
respectively. The nucleotide sequence of the mouse MEKK1 cDNA encoding
the N-terminal region has been deposited in DDBJ/EMBL/GenBank with
accession no. AB014614. The nucleotide sequence of JSAP1 cDNA has been
deposited in DDBJ/EMBL/GenBank with accession no. AB005662.
| |
RESULTS |
Molecular cloning of JSAP1, a novel JNK-binding protein.
We
used a yeast two-hybrid system to search for proteins that directly
interact with JNK3. A group of positive clones encoding a protein,
termed JSAP1, was identified by screening approximately 2 × 106 transformants. To identify a full-length clone, we
screened a mouse brain cDNA library with a partial JSAP1 cDNA insert
obtained from the yeast two-hybrid screen. The full-length JSAP1 cDNA
was found to encode a protein of 1,305 amino acids with a calculated relative molecular weight of 144,131 (Fig.
1A). Databank searches indicated that
JSAP1 represents a novel protein. However, significant amino acid
sequence homology to a human sperm-specific protein (accession no.
X91879) (40) was found. No function has yet been ascribed to
this human gene. JSAP1 contains a leucine zipper motif with a periodic
repeat of leucines every seven residues (residues 392 to 427 [Fig.
1A]). We analyzed the tissue distributions of mouse JNK3 and JSAP1 by
Northern blotting analysis (Fig. 1B). As in humans (31),
mouse JNK3 mRNA was expressed almost exclusively in the brain. Of the
other tissues tested, only the testis showed JNK3 expression, which was
at a level markedly lower than that seen in the brain. The
approximately 6-kb JSAP1 transcript was also particularly abundant in
the brain, and very weak signals of JSAP1 mRNA were detected in other
tissues. JSAP1 protein was localized to the cytoplasm in P19 cells that
were induced to differentiate by treatment with retinoic acid (data not
shown).
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FIG. 1.
(A) Deduced amino acid sequence of JSAP1. The region
(residues 115 to 504) isolated in the yeast two-hybrid system is shown
by L-shaped arrows. The leucine residues of the leucine zipper are
boxed. (B) Expression of JNK3 and JSAP1 mRNAs in mouse tissues.
Poly(A)+ RNA samples isolated from various mouse tissues
were examined by Northern blotting analysis. The positions of 28S and
18S rRNAs are indicated on the left. -Actin mRNA was included as a
loading control.
|
|
JSAP1 specifically interacts with JNK and not with other mammalian
MAPKs.
The binding specificity of JSAP1 for the various MAPKs was
studied in cotransfection experiments (Fig.
2A). We transiently expressed
His-S-tagged full-length JSAP1 with Flag epitope-tagged JNK1, JNK2,
JNK3, ERK2, or p38 in COS-7 cells. The His-S-JSAP1 proteins were
recovered from the cell extracts by affinity binding to
S-protein-agarose, and the precipitates were examined for the presence
of the MAPKs by immunoblotting with an anti-Flag antibody. JNK1, JNK2,
and JNK3 interacted with JSAP1, while no or very low binding of ERK2
and p38 to JSAP1 was observed. JNK3 showed higher binding affinity
to JSAP1 than did JNK1 or JNK2.
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FIG. 2.
(A) Binding of JSAP1 to mammalian MAPKs. COS-7 cells
were transiently cotransfected with 0.4 µg of pFlag-CMV2-JNK1, -JNK2,
-JNK3, -p38 or -ERK2 along with 1.1 µg of either pcDNA3-His-S
empty vector or pcDNA3-His-S-JSAP1. Cell lysates were precipitated with
S-protein-linked agarose (S-PA) and analyzed by immunoblotting with
anti-Flag antibody. Expression of Flag-MAPKs and His-S-JSAP1 was
examined by immunoblotting 1/10 of the cell lysates used in the binding
reactions. (B) Mapping of the JNK3-binding region on JSAP1. In
vitro-translated 35S-labeled JNK3 was incubated with 0.5 µg of either immobilized Trx-His-S protein or Trx-His-S-tagged
segments of JSAP1. The protein complexes were extensively washed, and
the bound JNK3 was detected by SDS-PAGE and autoradiography. One-tenth
of the 35S-labeled protein used in the binding reactions
was loaded as a positive control.
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To define the region of JSAP1 responsible for its interaction with JNK,
a series of Trx-His-S-JSAP1 fusion proteins containing
various portions
of JSAP1 were expressed in bacteria, purified
by using
S-protein-agarose, and assayed for the ability to bind
JNK. The
agarose-bound fusion proteins were mixed with in vitro-translated
35S-labeled JNK3, recovered, and analyzed by SDS-PAGE and
autoradiography
(Fig.
2B). Essentially the same results were obtained
when JNK1
and JNK2 were used instead of JNK3 (data not shown). The
results
indicate that the JNK-binding region is located between
residues
115 and 233 in
JSAP1.
JSAP1 is phosphorylated by JNK.
We then examined whether JSAP1
could serve as a substrate for JNK, because three potential sites for
phosphorylation by proline-directed serine/threonine kinases, such as
JNK, were located at residues 234, 244, and 255 (Fig.
3A), adjacent to the JNK-binding region (residues 115 to 233). Flag-JNK3 was transiently expressed in COS-7
cells with or without truncated MEKK1 (MEKK), a strong activator of
JNKs in vivo (28, 53), immunoprecipitated with an anti-Flag
antibody, and examined for the ability to phosphorylate Trx-His-S-JSAP1
(residues 115 to 274). GST-c-Jun (residues 1 to 79) was used as a
positive control (8, 11, 22). As shown in Fig. 3A, JSAP1 was
phosphorylated by the activated JNK3 as efficiently as c-Jun (lanes 2 and 4). Several bands were seen, which probably reflected the
phosphorylation of several sites in JSAP1. In fact, three mutant forms
of JSAP1, in which each potential phosphorylation site was intact and
the other two sites were changed to alanine, were all efficiently
phosphorylated (lanes 6 to 8). Essentially the same results were
obtained when JNK1 and JNK2 were used instead of JNK3 (data not shown).
Although residues outside the region (residues 115 to 274) may also be phosphorylation sites for JNK, these results indicate that JSAP1 is an
in vitro substrate for JNK and that all three sites at residues 234, 244, and 255 in JSAP1 can be phosphorylated by JNK.
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FIG. 3.
Phosphorylation of JSAP1 by JNK3 (A) and its effect on
the interaction with JNK3 (B). (A) COS-7 cells were transiently
transfected with 1.5 µg of pFlag-CMV2-JNK3 with or without 0.05 µg
of pEF-3XHA-MEKK. Cell lysates were immunoprecipitated with
anti-Flag antibody, and the in vitro kinase assay was carried out as
described in Materials and Methods. GST-c-Jun (residues 1 to 79) and
Trx-His-S-JSAP1 (residues 115 to 274) were used as substrates. The
mutants of JSAP1 (T-0, T-1, T-2, and T-3) were as indicated. WT, wild
type. The concentration of each substrate was 1 pmol/µl in 30 µl of
total volume. (B) COS-7 cells were transiently transfected with 1.5 µg of pFlag-CMV2-JNK3 with or without 0.05 µg of pEF-3XHA-MEKK.
The unstimulated (lanes 1 to 3) and stimulated (lanes 4 to 6) Flag-JNK3
were precipitated from cell lysates with 0.5 µg of immobilized
Trx-His-S protein (lanes 1 and 4) or the unphosphorylated (lanes 2 and
5) or phosphorylated (lanes 3 and 6) Trx-His-S-JSAP1 and analyzed by
immunoblotting with anti-Flag or anti-His antibody. Expression of
Flag-JNK3 was examined by immunoblotting 1/10 of the cell lysates used
in the binding reactions. The phosphorylated form of Flag-JNK3 was
detected with a phospho-specific JNK (P-JNK) antibody.
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We performed an in vitro association experiment to examine whether the
phosphorylation of JSAP1 has an effect on its interaction
with JNK.
Flag-JNK3 was first transiently expressed with or without
MEKK in
COS-7 cells. Unstimulated and stimulated Flag-JNK3s were
precipitated
with the bacterially expressed, either unphosphorylated
Trx-His-S-JSAP1
(residues 115 to 274) or the corresponding phosphorylated
Trx-His-S-JSAP1 (at residues 234, 244, and 255), respectively.
The
precipitates were analyzed for the presence of JNK3 by Western
blotting
using an anti-Flag antibody (Fig.
3B). The phosphorylation
state of
Trx-His-S-JSAP1 was confirmed by its mobility in the
gel (Fig.
3B). The
results indicated that stimulated JNK3 had
a much lower binding
affinity for both the unphosphorylated and
phosphorylated JSAP1 than
unstimulated JNK3
did.
JSAP1 binds SEK1 MAPKK and MEKK1 MAPKKK.
We next examined
whether SEK1, a MAPKK in the JNK cascade, could bind to JSAP1 (Fig.
4). Flag-SEK1 and the full-length
His-S-JSAP1 expression vectors were cotransfected into
COS-7 cells with or without MEKK expression vector and analyzed as
in the MAPK/JSAP1 binding experiment. Although the unstimulated
Flag-SEK1 and the His-S-JSAP1 were not copurified from the cells,
MEKK, an activator of SEK1 (53), significantly enhanced
the binding affinity of Flag-SEK1 for His-S-JSAP1 (lanes 2 and 3). The
presence of the phosphorylated, activated form of Flag-SEK1 was
confirmed by Western blotting using a phospho-specific SEK1 antibody
(Fig. 4, bottom). Furthermore, the SEK1-binding region in JSAP1 was
mapped using a series of His-S-tagged deletion mutants of JSAP1 (Fig.
4, lanes 5 to 7). The results indicate that the C-terminal region
(residues 1054 to 1305) of JSAP1 is responsible for the interaction
with SEK1. Thus, the SEK1-binding region is distinct from the
JNK-binding region (residues 115 to 233) in JSAP1. MKK7, MEK1, and
MKK6, which are MAPKKs in the JNK, ERK, and p38 cascades, respectively,
were also examined for the ability to bind JSAP1. Interestingly, MEK1, and not MKK7 or MKK6, bound to JSAP1 as efficiently as SEK1 (Fig. 5A). When MKK7, MEK1, and MKK6 MAPKKs
were activated by UV irradiation, truncated Raf-1 (Raf, a
constitutively active Raf-1 [41]), and osmotic shock,
respectively, they showed similar binding profiles for JSAP1 with the
corresponding unstimulated MAPKKs under our assay conditions (data not
shown). Increasing the amount of MEK1 had essentially no effect on the
JSAP1-SEK1 interaction; similarly, increasing the amount of SEK1 did
not affect the JSAP1-MEK1 interaction (Fig. 5B), indicating that the
MEK1-binding site is distinct from the SEK1-binding site in JSAP1.
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FIG. 4.
Binding of JSAP1 to SEK1 MAPKK and mapping of the
SEK1-binding region on JSAP1. COS-7 cells were transiently
cotransfected with 0.4 µg of pcDNA3-Flag-SEK1 and 1.1 µg of
pcDNA3-His-S-JSAP1, -1, -2, or -3 with or without 0.04 µg of
pEF-3XHA-MEKK, as indicated. Cell lysates were precipitated with
S-protein-linked agarose (S-PA) and analyzed by immunoblotting with
anti-Flag antibody. Expression of Flag-SEK1 and His-S-JSAP1, -1,
-2, and -3 was examined by immunoblotting 1/10 of the cell
lysates used in the binding reactions. The phosphorylated form of
Flag-SEK1 was detected using a phospho-specific SEK1 (P-SEK1)
antibody.
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FIG. 5.
(A) Binding of JSAP1 to mammalian MAPKKs. COS-7 cells
were transiently cotransfected with 0.4 µg of pcDNA3-Flag-SEK1,
-MKK7, -MEK1, or -MKK6 with 1.1 µg of either pcDNA3-His-S empty
vector or pcDNA3-His-S-JSAP1 in the absence or presence of 0.04 µg of
pEF-3XHA-MEKK, as indicated. Cell lysates were precipitated with
S-protein-linked agarose (S-PA) and analyzed as for Fig. 2A. Expression
of Flag-MAPKKs and His-S-JSAP1 was examined by immunoblotting 1/10 of
the cell lysates used in the binding reactions. (B) Competition
analysis of SEK1 and MEK1 in the interaction with JSAP1. COS-7 cells
were transiently cotransfected with 0.2 µg of pcDNA3-Flag-SEK1, 0.02 µg of pEF-3XHA-MEKK, and 0.2 µg of either pcDNA3-His-S empty
vector or pcDNA3-His-S-JSAP1 with different amounts of pcDNA3-Myc-MEK1
(0, 0, 0.05, 0.2, and 0.5 µg in lanes 1 to 5, respectively). COS-7
cells were transiently cotransfected with 0.1 µg of pcDNA3-Myc-MEK1,
0.02 µg of pEF-3XHA-MEKK, and 0.2 µg of either pcDNA3-His-S
empty vector or pcDNA3-His-S-JSAP1 with different amounts of
pcDNA3-Flag-SEK1 (0, 0, 0.1, 0.3, and 0.6 µg in lanes 6 to 10, respectively). Total DNA was kept at 1.5 µg per transfection with
pcDNA3-His-S empty vector. Cell lysates were precipitated with
S-protein-linked agarose (S-PA) and analyzed as for Fig. 2A. Expression
of Flag-SEK1, Myc-MEK1, and His-S-JSAP1 was examined by immunoblotting
1/10 of the cell lysates used in the binding reactions.
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We next analyzed whether JSAP1 could bind to MEKK1, a MAPKKK in the JNK
cascade, in cotransfected COS-7 cells. When full-length
MEKK1 was
expressed in these cells, smaller species of MEKK1 were
detected, as
was also observed by Xu et al. (
50), and the expression
level of the full-length protein was very low. We therefore expressed
Flag-tagged portions of MEKK1 in these cells and examined their
ability
to bind to His-S-JSAP1. As shown in Fig.
6A, the N-terminal
region (residues 1 to
640) of MEKK1 (MEKK-N) was found to interact
with full-length JSAP1
(lane 2). None of the other regions of
MEKK1 interacted with
full-length JSAP1 under our assay conditions
(data not shown).
Moreover, the MEKK1-binding region of JSAP1
was mapped by using a
series of His-S-tagged deletion mutants
of JSAP1 (Fig.
6A, lanes 2 to
4). The results indicate that the
internal region (residues 343 to
1053) of JSAP1 is responsible
for the interaction with MEKK1. The
C-terminal SEK1-binding region
of JSAP1 could work as an inhibitor of
the JSAP1-MEKK1 interaction,
because MEKK1 bound to the JSAP1 mutants
that lacked the C-terminal
region with higher affinity than to
full-length JSAP1 (lanes 2
to 4). Since the expression level of a JSAP1
fragment containing
residues 745 to 1053 was very low, we used an in
vitro pull-down
method, as in the JNK3- and JSAP1-binding experiments,
for more
precise mapping of the MEKK1-binding region on JSAP1.
Portions
of JSAP1 were expressed as Trx-His-S-tagged fusion proteins in
bacteria, purified by using S-protein-agarose, and assayed for
the
ability to bind MEKK1. The agarose-bound fusion proteins were
mixed
with in vitro-translated
35S-labeled full-length MEKK1,
recovered, and analyzed by SDS-PAGE
and autoradiography (Fig.
6B). The
results indicate that the MEKK1-binding
region is located between
residues 486 and 744. Thus, the MEKK1-binding
region is distinct from
both the JNK3- and SEK1-binding regions
(residues 115 to 233 and 1054 to 1305, respectively) in JSAP1.
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FIG. 6.
Binding of JSAP1 to MEKK1 MAPKKK, mapping of the
MEKK1-binding region on JSAP1, and binding of MEKK1 MAPKKK to SEK1
MAPKK. (A) COS-7 cells were transiently cotransfected with 0.4 µg of
pcDNA3-Flag-MEKK-N with 1.1 µg of pcDNA3-His-S empty vector or
pcDNA3-His-S-JSAP1, -1, or -4. Cell lysates were precipitated
with S-protein-linked agarose (S-PA) and analyzed as for Fig. 2A.
Expression of Flag-MEKK-N and His-S-JSAP1, -1, and -4 was
examined by immunoblotting 1/10 of the cell lysates used in the binding
reactions. (B) In vitro-translated 35S-labeled full-length
MEKK was incubated with 0.5 µg of either immobilized Trx-His-S
protein or Trx-His-S-tagged segments of JSAP1 and analyzed as for Fig.
2B. One-tenth of the 35S-labeled protein used in the
binding reactions was loaded as a positive control. (C) COS-7 cells
were transiently transfected with 1.5 µg of pcDNA3-Flag-MEKK. Cell
lysate was precipitated with 0.5 µg of either immobilized Trx-His-S
protein (lane 2) or Trx-His-S-SEK1 (lane 3) and analyzed by
immunoblotting with anti-Flag antibody. One-tenth of the cell lysate
used in the binding reactions was loaded as a control (lane 1).
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As only the stimulated SEK1 interacted with JSAP1 (Fig.
4), we further
examined whether MEKK1 could bind to the unstimulated
SEK1 as noted by
Xia et al. (49). Flag-
MEKK was transiently expressed
in COS-7 cells
and pulled down with bacterially expressed, S-protein-agarose-bound
Trx-His-S or Trx-His-S-SEK1. The precipitates were examined for
the
presence of Flag-
MEKK by immunoblotting with an anti-Flag
antibody
(Fig.
7C). The results indicates that
MEKK binds to
the unstimulated
SEK1.
In addition, Raf-1 MAPKKK, which is involved in the ERK cascade, was
examined for its ability to interact with JSAP1 (Fig.
7A). Since the expression level of
full-length Raf-1 was very
low, as was observed for MEKK1 in
transfected COS-7 cells, the
N-terminal half (residues 1 to 327) and
the C-terminal half (residues
316 to 648) of Raf-1 (Raf-N and Raf-C,
respectively) were expressed
separately in the cells, and their
interactions with JSAP1 were
examined. Raf-C, and not Raf-N, bound to
JSAP1; however, the binding
affinity of Raf-C for JSAP1 was very low
compared with that of
MEKK1 with JSAP1 (lanes 4 and 6). Increasing the
amount of MEKK-N
had essentially no effect on the JSAP1-Raf-C
interaction (Fig.
7B), and increasing the amount of Raf-C did not
affect the JSAP1-MEKK-N
interaction (data not shown), indicating that
the MEKK1-binding
site is distinct from the Raf-1-binding site in
JSAP1.
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FIG. 7.
(A) Binding of JSAP1 to mammalian MAPKKKs. COS-7 cells
were transiently cotransfected with 0.4 µg of pcDNA3-Flag-Raf-N,
-Raf-C, or -MEKK-N with 1.1 µg of either pcDNA3-His-S empty vector or
pcDNA3-His-S-JSAP1. (B) Competition analysis of MEKK1 and Raf-1 in the
interaction with JSAP1. COS-7 cells were transiently cotransfected with
0.7 µg of pcDNA3-Flag-Raf-C and 0.2 µg of either pcDNA3-His-S empty
vector or pcDNA3-His-S-JSAP1 with different amounts of
pcDNA3-Flag-MEKK-N (0, 0, 0.05, 0.2 and 0.6 µg in lanes 1 to 5, respectively). Total DNA was kept at 1.5 µg per transfection with
pcDNA3-His-S empty vector. Cell lysates were precipitated with
S-protein-linked agarose (S-PA) and analyzed as for Fig. 2A. Expression
of Flag-MAPKKKs and His-S-JSAP1 was examined by immunoblotting 1/10 of
the cell lysates used in the binding reactions.
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Full-length JSAP1 enhances JNK activation.
The results of our
JSAP1-binding experiments suggest that JSAP1 acts as a scaffold protein
in the JNK cascades. To examine this possibility, we analyzed the
effect of overexpressing full-length JSAP1 on JNK activation by
full-length MEKK1 (Fig. 8A). Flag-JNK1, -JNK2, or -JNK3 was transiently expressed alone or with His-S-MEKK1 in
the absence or presence of His-S-JSAP1 in COS-7 cells. Cell lysates
were immunoprecipitated with an anti-Flag antibody, and the JNK
activity was measured by using GST-c-Jun (residues 1 to 79) as the
substrate. MEKK1 activated JNK1, JNK2, and JNK3 8-, 6.8-, and 2.6-fold,
respectively, and the activation was further enhanced 1.6-, 1.4-, and
3-fold, respectively, in the presence of JSAP1. JSAP1 alone without
MEKK1 had little effect on the activity of JNK1, JNK2, and JNK3 in
COS-7 cells (data not shown).
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FIG. 8.
JSAP1 enhances the activation of JNK3 by MEKK1 and SEK1.
(A) Effect of overexpressing JSAP1 on JNK activation by MEKK1. COS-7
cells were transiently transfected with 0.2 µg of pFlag-CMV2-JNK1
(lane 1), -JNK2 (lane 4), or -JNK3 (lane 7) alone or with 0.02 µg of
pcDNA3-His-S-MEKK1 in the absence or presence of 1 µg of
pcDNA3-His-S-JSAP1, as indicated. (B) Effect of overexpressing SEK1 and
MEK1 on JNK3 activation by JSAP1 and MEKK1. COS-7 cells were
transiently cotransfected with 0.2 µg of pFlag-CMV2-JNK3, 0.06 µg
of pcDNA3-His-S-MEKK1, and 1 µg of pcDNA3-His-S-JSAP1 in the absence
or presence of 0.2 µg of either pcDNA3-His-S-SEK1 or
pcDNA3-His-S-MEK1, as indicated. (C) Effect of overexpressing JSAP1
mutants on JNK3 activation by MEKK1 and SEK1. COS-7 cells were
transiently cotransfected with 0.2 µg of pFlag-CMV2-JNK3, 0.06 µg
of pcDNA3-His-S-MEKK1, and 0.2 µg of pcDNA3-His-S-SEK1 with 1 µg of
pcDNA3-His-S empty vector and pcDNA3-His-S-JSAP1, -J, -M, or
-S, as indicated. Total DNA was kept at 1.5 µg per transfection
with pcDNA3-His-S empty vector. Cell lysates were immunoprecipitated
with anti-Flag antibody, and kinase activity was measured by using
GST-c-Jun (residues 1 to 79) as the substrate. Expression of
Flag-JNKs, His-S-JSAP1, His-S-SEK1, and His-S-MEK1 was examined by
immunoblotting 1/10 of the cell lysates used in the kinase assays.
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We next examined whether SEK1 or MEK1 could activate JNK in the
presence of JSAP1 and MEKK1 (Fig.
8B), since they both interacted
with
JSAP1 (Fig.
5A). Flag-JNK3, His-S-JSAP1, and His-S-MEKK1
were
transiently coexpressed in the absence or presence of either
His-S-SEK1
or His-S-MEK1 in COS-7 cells. The JNK3 activity was
enhanced fourfold
by SEK1 in the presence of JSAP1 and MEKK1.
When JNK1 (or JNK2) was
used instead of JNK3, a modest enhancement
of the JNK activation was
observed (data not shown). MEK1 had
little effect on the JNK3
activation, suggesting that MEK1 could
not activate JNK3 in the
presence of JSAP1 and MEKK1. We further
studied whether JSAP1 mutants
lacking the JNK-, SEK1-, and MEKK1-binding
regions could enhance the
JNK3 activation by MEKK1 and SEK1 as
full-length JSAP1 did in COS-7
cells (Fig.
8C). JSAP1 mutants
lacking the JNK- or MEKK1-binding
regions resulted in significant
reduction of the enhancement of the
JNK3 activation. In contrast,
a JSAP1 mutant lacking the SEK1-binding
region acted similarly
to full-length JSAP1. Taken together, these
results suggest that
JSAP1 functions as a scaffold protein in the JNK3
cascade and
that stimulated SEK1 could activate JNK3 without direct
interaction
with
JSAP1.
| |
DISCUSSION |
In this study we have identified a novel mouse JNK-binding
protein, JSAP1, and examined its interactions with a variety of mammalian MAPKs, MAPKKs, and MAPKKKs through cotransfection studies of
COS-7 cells. JSAP1 coprecipitated with JNK1, JNK2, and JNK3 MAPKs but
not with ERK2 or p38 MAPKs. JNK3 showed higher binding affinity to
JSAP1 than did JNK1 or JNK2. Furthermore, JSAP1 interacted with SEK1
MAPKK and MEKK1 MAPKKK, which are involved in the JNK cascades.
Importantly, the regions of JSAP1 that bound JNK, SEK1, and MEKK1 were
distinct from one another. JNK and MEKK1 also interacted with JSAP1 in
vitro; thus, these interactions are likely to be direct. In contrast,
only the stimulated SEK1 interacted with JSAP1, and the unstimulated
SEK1 interacted with MEKK1. The amino- and carboxy-terminal regions of
MEKK1 interacted with JSAP1 and SEK1, respectively. Thus, SEK1 could
indirectly associate with JSAP1 through MEKK1. Although there is no
direct evidence, the binding properties of JSAP1 and MEKK1 as described
above indicate that JSAP1 may tether JNK MAPK, SEK1 MAPKK, and MEKK1
MAPKKK in a complex, a role similar to that the yeast scaffold protein
Ste5. Ste5 forms a multicomponent complex with Fus3 (or Kss1) MAPK, Ste7 MAPKK, and Ste11 MAPKKK to facilitate the specific and efficient activation of the mating pheromone pathway (3, 21, 27, 34).
Overexpression of full-length JSAP1 in COS-7 cells led to a
considerable enhancement of the JNK3 activation, and modest enhancement of the JNK1 and JNK2 activation, by the MEKK1-SEK1 pathway. Deletion of
the JNK- and MEKK1-binding regions significantly reduced of the
enhancement of the JNK3 activation in COS-7 cells. However, a JSAP1
mutant lacking the SEK1-binding region acted similarly to wild-type
full-length JSAP1. Taken together, these results suggest that JSAP1
functions as a scaffold protein in the JNK3 cascade and that stimulated
SEK1 could activate JNK3 without direct interaction with JSAP1. What is
the role of the binding of the stimulated SEK1 to JSAP1? Although SEK1
can activate both JNK and p38 (9, 26), the SEK1-JSAP1
interaction may prohibit the stimulated SEK1 by JSAP1-associated MEKK1
from activating p38. It is also possible that a JSAP1 complex binding
stimulated SEK1 is involved in amplification of JNK3 activation. At
present, a scaffolding role of JSAP1 in the JNK1 and JNK2 cascades is
not clear. While JNK3 and JSAP1 are expressed predominantly in the brain, both JNK1 and JNK2 are widely expressed. Thus, COS-7 cells, for
example, may include multicomponent complexes containing JNK1 and JNK2,
organized by a scaffold protein(s) other than JSAP1. The higher
activation of JNK1 and JNK2 than of JNK3 by MEKK1 alone (Fig. 8A) might
support this idea. The formation of a complex by the transiently
coexpressed JNK1 (or JNK2), JSAP1, and MEKK1 in COS-7 cells could be
interfered with by the presence of other scaffold proteins. Taking this
into account, we cannot rule out the possibility that JSAP1 can also
function as a scaffold protein in the JNK1 and JNK2 cascades. To
clarify this issue, it should be useful to examine the effect of JSAP1
on the JNK1 (and JNK2) activation in JNK-free system, such as yeast.
Recently, Xia et al. (49) have proposed a sequential
interaction model for the organization of the MEKK1-SEK1-JNK module.
JSAP1 may stabilize this signaling module further.
JSAP1 is an in vitro substrate for JNK, and three sites at residues
234, 244, and 255, adjacent to the JNK-binding region (residues 115 to
233), can be phosphorylated by JNK (Fig. 3A). Although we have not
examined whether the other sites in JSAP1 can also be phosphorylated by
JNK, our preliminary results showed that these three sites, and not
others, are the major phosphorylation sites for JNK (17).
Phosphorylated JSAP1 had little binding affinity for the activated form
of JNK3 (Fig. 3B). Taken together, these data suggest that once
activated, JNK dissociates from JSAP1 by phosphorylating it. Thus, a
mutant JSAP1 containing substitutions at residues 234, 244, and 255 could be developed as a specific inhibitor for the JNK cascades.
JSAP1 contains a leucine zipper motif with six leucine repeats
(residues 392 to 427 [Fig. 1A]), which may mediate the homo- and/or
heterodimerization of JSAP1. In fact, two different epitope-tagged JSAP1 fragments encompassing the leucine zipper motif associated with
each other in cotransfected cells (17). The yeast scaffold protein Ste5 can also self-associate, and importantly, dimerization of
Ste5 is essential for the mating pheromone pathway (51). Thus, it should be interesting to examine whether dimerization of JSAP1
is required for its function.
JSAP1 exhibited different binding affinities for the signaling
components of the ERK cascade in cotransfected COS-7 cells. JSAP1
coprecipitated with MEK1 MAPKK and Raf-1 MAPKKK but not ERK2 MAPK.
Thus, even though MEK1 and Raf-1 did not interfere with the binding of
JSAP1 to SEK1 and MEKK1, respectively, JSAP1 may affect the ERK
cascade. In fact, overexpression of full-length JSAP1 inhibited the
activation of the ERK cascade in COS-7 cells (17). Highly
expressed JSAP1 could absorb MEK1 and/or Raf-1 from an ERK signaling
complex tethered by an unidentified scaffold protein or an adapter
protein such as MP1 (39), resulting in the inhibition of ERK
activation. At present, how JSAP1 is involved in vivo in signaling
pathways other than the JNK cascades is not clear. However, an
interesting possibility is that JSAP1 expression is positively
autoregulated by the JNK cascades, so that the activation of the JNK
cascades leads to the increased expression of JSAP1. Inhibition of the
other cascades by JSAP1 would ensure the specific activation of the JNK
cascades. In support of this idea, our preliminary experiments showed
that a 5.2-kb genomic fragment containing the JSAP1 promoter sequence
increases its transcriptional activity in response to overexpression of
full-length JSAP1 (17). Further study is required to clarify
this issue.
Recently, Whitmarsh et al. (47) reported that JIP-1 works as
a scaffold factor in the JNK cascades. JSAP1 is clearly distinct from
JIP-1, because JSAP1 contains a leucine zipper motif but not an SH3
domain; JIP-1 contains an SH3 domain but not a leucine zipper motif.
More importantly, JSAP1 and JIP-1 bind distinct sets of kinases. JSAP1
organizes the MEKK1-SEK1-JNK signaling module; JIP-1 organizes the
MLK-MKK7-JNK signaling module. In spite of these differences, JSAP1 and
JIP-1 appear to function similarly in cells, selectively enhancing the
activation of signaling pathways. Furthermore, Schaeffer et al.
(39) and Cohen et al. (5) have identified an
adapter protein, MP1, for MEK1 and ERK1, and a scaffold protein, IKAP,
in the I
B kinase complex. In addition, current work in our
laboratory has revealed the existence of other JSAP1 family members.
These scaffold/adapter proteins, together with unidentified related
proteins, could contribute to the specificity determination of
numerous distinct signaling pathways in cells.
| |
ACKNOWLEDGMENTS |
M. Ito and K. Yoshioka contributed equally to this work.
We thank Rikiro Fukunaga for helpful discussion, Atsushi Yamashita for
RNA samples, and Yoshiyuki Sakaki for encouragement.
This work was supported in part by grants from the Kitasato Research
Foundation (M.I.), the Waksman Foundation of Japan Inc. (T.S.),
grants-in-aid from the Ministry of Education, Science, Sports and
Culture in Japan (K. Yoshioka), and the Kato Memorial Foundation (K. Yoshioka).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Molecular Pathology, Cancer Research Institute, Kanazawa University, 13-1 Takaramachi, Kanazawa 920-0934, Japan. Phone: 81-76-265-2757. Fax:
81-76-234-4517. E-mail:
katsuji{at}kenroku.kanazawa-u.ac.jp.
| |
REFERENCES |
| 1.
|
Ausubel, F. M.,
R. Brent,
R. E. Kingston,
D. D. Moore,
J. G. Seidman,
J. A. Smith, and K. Struhl (ed.).
1990.
Current protocols in molecular biology.
John Wiley & Sons, New York, N.Y.
|
| 2.
|
Cano, E., and L. C. Mahadevan.
1995.
Parallel signal processing among mammalian MAPKs.
Trends Biochem. Sci.
20:117-122[Medline].
|
| 3.
|
Choi, K.-Y.,
B. Satterberg,
D. M. Lyons, and E. A. Elion.
1994.
Ste5 tethers multiple protein kinases in the MAP kinase cascade required for mating in S. cerevisiae.
Cell
78:499-512[Medline].
|
| 4.
|
Cobb, M. H., and E. J. Goldsmith.
1995.
How MAP kinases are regulated.
J. Biol. Chem.
270:14843-14846[Free Full Text].
|
| 5.
|
Cohen, L.,
W. J. Henzel, and P. A. Baeuerle.
1998.
IKAP is a scaffold protein of the IB kinase complex.
Nature
395:292-296[Medline].
|
| 6.
|
Cuenda, A.,
G. Alonso,
N. Morrice,
M. Jones,
R. Meier,
P. Cohen, and A. R. Nebreda.
1996.
Purification and cDNA cloning of SAPKK3, the major activator of RK/p38 in stress- and cytokine-stimulated monocytes and epithelial cells.
EMBO J.
15:4156-4164[Medline].
|
| 7.
|
Davis, R. J.
1994.
MAPKs: new JNK expands the group.
Trends Biochem. Sci.
19:470-473[Medline].
|
| 8.
|
Dérijard, B.,
M. Hibi,
I.-H. Wu,
T. Barrett,
B. Su,
T. Deng,
M. Karin, and R. J. Davis.
1994.
JNK1: a protein kinase stimulated by UV light and Ha-Ras that binds and phosphorylates the c-Jun activation domain.
Cell
76:1025-1037[Medline].
|
| 9.
|
Dérijard, B.,
J. Raingeaud,
T. Barrett,
I.-H. Wu,
J. Han,
R. J. Ulevitch, and R. J. Davis.
1995.
Independent human MAP kinase signal transduction pathway defined by MEK and MKK isoforms.
Science
267:682-685[Abstract/Free Full Text].
|
| 10.
|
Gerwins, P.,
J. L. Blank, and G. L. Johnson.
1997.
Cloning of a novel mitogen-activated protein kinase kinase kinase, MEKK4 that selectively regulates the c-Jun amino terminal kinase pathway.
J. Biol. Chem.
272:8288-8295[Abstract/Free Full Text].
|
| 11.
|
Gupta, S.,
T. Barrett,
A. J. Whitmarsh,
J. Cavanagh,
H. K. Sluss,
B. Dérijard, and R. J. Davis.
1996.
Selective interaction of JNK protein isoforms with transcription factors.
EMBO J.
15:2760-2770[Medline].
|
| 12.
|
Han, J.,
J.-D. Lee,
L. Bibbs, and R. J. Ulevitch.
1994.
A MAP kinase targeted by endotoxin and hyperosmolarity in mammalian cell.
Science
265:808-811[Abstract/Free Full Text].
|
| 13.
|
Han, J.,
J.-D. Lee,
Y. Jiang,
Z. Li,
L. Feng, and R. J. Ulevitch.
1996.
Characterization of the structure and function of a novel MAP kinase kinase (MKK6).
J. Biol. Chem.
271:2886-2891[Abstract/Free Full Text].
|
| 14.
|
Herskowitz, I.
1995.
MAP kinase pathway in yeast: for mating and more.
Cell
80:187-197[Medline].
|
| 15.
|
Hibi, M.,
A. Lin,
T. Smeal,
A. Minden, and M. Karin.
1993.
Identification of an oncoprotein- and UV-responsive protein kinase that binds and potentiates the c-Jun activation domain.
Genes Dev.
7:2135-2148[Abstract/Free Full Text].
|
| 16.
|
Ichijo, H.,
E. Nishida,
K. Irie,
P. Dijke,
M. Saitoh,
T. Moriguchi,
M. Takagi,
K. Matsumoto,
K. Miyazono, and Y. Gotoh.
1997.
Induction of Apoptosis by ASK1, a mammalian MAPKKK that activates SAPK/JNK and p38 signaling pathways.
Science
275:90-94[Abstract/Free Full Text].
|
| 17.
| Ito, M., and K. Yoshioka. Unpublished data.
|
| 18.
|
Jiang, Y.,
C. Chen,
Z. Li,
W. Guo,
J. A. Gegner,
S. Lin, and J. Han.
1996.
Characterization of the structure and function of a new mitogen-activated protein kinase (p38).
J. Biol. Chem.
271:17920-17926[Abstract/Free Full Text].
|
| 19.
|
Kallunki, T.,
B. Su,
I. Tsigelny,
H. K. Sluss,
B. Dérijard,
G. Moore,
R. J. Davis, and M. Karin.
1994.
JNK2 contains a specificity-determining region responsible for efficient c-Jun binding and phosphorylation.
Genes Dev.
8:2996-3007[Abstract/Free Full Text].
|
| 20.
|
Kallunki, T.,
T. Deng,
M. Hibi, and M. Karin.
1996.
c-Jun can recruit JNK to phosphorylate dimerization partners via specific docking interactions.
Cell
87:929-939[Medline].
|
| 21.
|
Kranz, J. E.,
B. Satterberg, and E. A. Elion.
1994.
The MAP kinase Fus3 associates with and phosphorylates the upstream signaling component Ste5.
Genes Dev.
8:313-327[Abstract/Free Full Text].
|
| 22.
|
Kyriakis, J. M.,
P. Banerjee,
E. Nikolakaki,
T. Dai,
E. A. Rubie,
M. F. Ahmad,
J. Avruch, and J. R. Woodgett.
1994.
The stress-activated protein kinase subfamily of c-Jun kinases.
Nature
369:156-160[Medline].
|
| 23.
|
Kyriakis, J. M., and J. Avruch.
1996.
Sounding the alarm: protein kinase cascades activated by stress and inflammation.
J. Biol. Chem.
271:24313-24316[Free Full Text].
|
| 24.
|
Lange-Carter, C. A.,
C. M. Pleiman,
A. M. Gardner,
K. J. Blumer, and G. L. Johnson.
1993.
A divergence in the MAP kinase regulatory network defined by MEK kinase and Raf.
Science
260:315-319[Abstract/Free Full Text].
|
| 25.
|
Lee, J. C.,
J. T. Laydon,
P. C. McDonnell,
T. F. Gallagher,
S. Kumar,
D. Green,
D. McNulty,
M. J. Blumenthal,
J. R. Heys,
S. W. Landvatter,
J. E. Strickler,
M. M. McLaughlin,
I. R. Siemens,
S. M. Fisher,
G. P. Livi,
J. R. White,
J. L. Adams, and P. R. Young.
1994.
A protein kinase involved in the regulation of inflammatory cytokine biosynthesis.
Nature
372:739-746[Medline].
|
| 26.
|
Lin, A.,
A. Minden,
H. Martinetto,
F.-X. Claret,
C. Lange-Carter,
F. Mercurio,
G. L. Johnson, and M. Karin.
1995.
Identification of a dual specificity kinase that activates the Jun kinases and p38-Mpk2.
Science
268:286-290[Abstract/Free Full Text].
|
| 27.
|
Marcus, S.,
A. Polverino,
M. Barr, and M. Wigler.
1994.
Complex between STE5 and components of the pheromone-responsive mitogen-activated protein kinase module.
Proc. Natl. Acad. Sci. USA
91:7762-7766[Abstract/Free Full Text].
|
| 28.
|
Minden, A.,
A. Lin,
M. McMahon,
C. Lange-Carter,
B. Dérijard,
R. J. Davis,
G. L. Johnson, and M. Karin.
1994.
Differential activation of ERK and JNK mitogen-activated protein kinases by Raf-1 and MEKK.
Science
266:1719-1723[Abstract/Free Full Text].
|
| 29.
|
Minden, A., and M. Karin.
1997.
Regulation and function of the JNK subgroup of MAP kinases.
Biochim. Biophy. Acta
1333:F85-F104[Medline].
|
| 30.
|
Mizushima, S., and S. Nagata.
1990.
pEF-BOS, a powerful mammalian expression vector.
Nucleic Acids Res.
18:5322[Free Full Text].
|
| 31.
|
Mohit, A. A.,
J. H. Martin, and C. A. Miller.
1995.
p493F12 kinase: a novel MAP kinase expressed in a subset of neurons in the human nervous system.
Neuron
14:67-78[Medline].
|
| 32.
|
Moriguchi, T.,
N. Kuroyanagi,
K. Yamaguchi,
Y. Gotoh,
K. Irie,
T. Kano,
K. Shirakabe,
Y. Muro,
H. Shibuya,
K. Matsumoto,
E. Nishida, and M. Hagiwara.
1996.
A novel kinase cascade mediated by mitogen-activated protein kinase kinase 6 and MKK3.
J. Biol. Chem.
271:13675-13679[Abstract/Free Full Text].
|
| 33.
|
Moriguchi, T.,
F. Toyoshima,
N. Masuyama,
H. Hanafusa,
Y. Gotoh, and E. Nishida.
1997.
A novel SAPK/JNK kinase, MKK7, stimulated by TNF and cellular stresses.
EMBO J.
16:7045-7053[Medline].
|
| 34.
|
Printen, J. A., and G. F. Sprague, Jr.
1994.
Protein-protein interactions in the yeast pheromone response pathway: Ste5p interacts with all members of the MAP kinase cascade.
Genetics
138:609-619[Abstract].
|
| 35.
|
Raingeaud, J.,
A. J. Whitmarsh,
T. Barrett,
B. Dérijard, and R. J. Davis.
1996.
MKK3- and MKK6-regulated gene expression is mediated by the p38 mitogen-activated protein kinase signal transduction pathway.
Mol. Cell. Biol.
16:1247-1255[Abstract].
|
| 36.
|
Robinson, M. J., and M. H. Cobb.
1997.
Mitogen-activated protein kinase pathways.
Curr. Opin. Cell Biol.
9:180-186[Medline].
|
| 37.
|
Rouse, J.,
P. Cohen,
S. Trigon,
M. Morange,
A. Alonso-Llamazares,
D. Zamanillo,
T. Hunt, and A. R. Nebreda.
1994.
A novel kinase cascade triggered by stress and heat shock that stimulates MAPKAP kinase-2 and phosphorylation of the small heat shock proteins.
Cell
78:1027-1037[Medline].
|
| 38.
|
Sánchez, I.,
R. T. Hughes,
B. J. Mayer,
K. Yee,
J. R. Woodgett,
J. Avruch,
J. M. Kyriakis, and L. I. Zon.
1994.
Role of SAPK/ERK kinase-1 in the stress-activated pathway regulating transcription factor c-Jun.
Nature
372:794-798[Medline].
|
| 39.
|
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].
|
| 40.
|
Shankar, S.,
B. Mohapatra, and A. Suri.
1998.
Cloning of a novel human testis mRNA specifically expressed in testicular haploid germ cells, having unique palindromic sequences and encoding a leucine zipper dimerization motif.
Biochem. Biophy. Res. Commun.
243:561-565[Medline].
|
| 41.
|
Stanton, V. P., Jr.,
D. W. Nichols,
A. P. Laudano, and G. M. Cooper.
1989.
Definition of the human raf amino-terminal regulatory region by deletion mutagenesis.
Mol. Cell. Biol.
9:639-647[Abstract/Free Full Text].
|
| 42.
|
Stein, B.,
H. Brady,
M. X. Yang,
D. B. Young, and M. S. Barbosa.
1996.
Cloning and characterization of MEK6, a novel members of the mitogen-activated protein kinase kinase cascade.
J. Biol. Chem.
271:11427-11433[Abstract/Free Full Text].
|
| 43.
|
Tibbles, L. A.,
Y. L. Ing,
F. Kiefer,
J. Chan,
N. Iscove,
J. R. Woodgett, and N. J. Lassam.
1996.
MLK-3 activates the SAPK/JNK and p38/RK pathways via SEK1 and MKK3/6.
EMBO J.
15:7026-7035[Medline].
|
| 44.
|
Tournier, C.,
A. J. Whitmarsh,
J. Cavanagh,
T. Barrett, and R. J. Davis.
1997.
Mitogen-activated protein kinase kinase 7 is an activator of the c-Jun NH2-terminal kinase.
Proc. Natl. Acad. Sci. USA
94:7337-7342[Abstract/Free Full Text].
|
| 45.
|
Treisman, R.
1996.
Regulation of transcription by MAP kinase cascades.
Curr. Opin. Cell Biol.
8:205-215[Medline].
|
| 46.
|
Waskiewicz, A. J., and J. A. Cooper.
1995.
Mitogen and stress response pathway: MAP kinase cascades and phosphatase regulation in mammals and yeast.
Curr. Opin. Cell Biol.
7:798-805[Medline].
|
| 47.
|
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].
|
| 48.
|
Wu, Z.,
J. Wu,
E. Jacinto, and M. Karin.
1997.
Molecular cloning and characterization of human JNKK2, a novel Jun NH2-terminal kinase-specific kinase.
Mol. Cell. Biol.
17:7407-7416[Abstract].
|
| 49.
|
Xia, Y.,
Z. Wu,
B. Su,
B. Murray, and M. Karin.
1998.
JNKK1 organizes a MAP kinase module through specific and sequential interactions with upstream and downstream components mediated by its amino-terminal extension.
Genes Dev.
12:3369-3381[Abstract/Free Full Text].
|
| 50.
|
Xu, S.,
D. J. Robbins,
L. B. Christerson,
J. M. English,
C. A. Vanderbilt, and M. H. Cobb.
1996.
Cloning of Rat MEK kinase 1 cDNA reveals an endogenous membrane-associated 195-kDa protein with a large regulatory domain.
Proc. Natl. Acad. Sci. USA
93:5291-5295[Abstract/Free Full Text].
|
| 51.
|
Yablonski, D.,
I. Marbach, and A. Levitzki.
1996.
Dimerization of Ste5, a mitogen-activated protein kinase cascade scaffold protein, is required for signal transduction.
Proc. Natl. Acad. Sci. USA
93:13864-13869[Abstract/Free Full Text].
|
| 52.
|
Yamaguchi, K.,
K. Shirakabe,
H. Shibuya,
K. Irie,
I. Oishi,
N. Ueno,
T. Taniguchi,
E. Nishida, and K. Matsumoto.
1995.
Identification of a member of the MAPKKK family as a potential mediator of TGF- signal transduction.
Science
270:2008-2011[Abstract/Free Full Text].
|
| 53.
|
Yan, M.,
T. Dai,
J. C. Deak,
J. M. Kyriakis,
L. I. Zon,
J. R. Woodgett, and D. J. Templeton.
1994.
Activation of stress-activated protein kinase by MEKK1 phosphorylation of its activator SEK1.
Nature
372:798-800[Medline].
|
| 54.
|
Yang, D. D.,
C.-Y. Kuan,
A. J. Whitmarsh,
M. Rincón,
T. S. Zheng,
R. J. Davis,
P. Rakic, and R. A. Flavell.
1997.
Absence of excitotoxicity-induced apoptosis in the hippocampus of mice lacking the Jnk3 gene.
Nature
389:865-870[Medline].
|
| 55.
|
Yoshioka, K.,
T. Deng,
M. Cavigelli, and M. Karin.
1995.
Antitumor promotion by phenolic antioxidants: inhibition of AP-1 activity through induction of Fra expression.
Proc. Natl. Acad. Sci. USA
92:4972-4976[Abstract/Free Full Text].
|
| 56.
|
Zervos, A. S.,
L. Faccio,
J. P. Gatto,
J. M. Kyriakis, and R. Brent.
1995.
Mxi2, a mitogen-activated protein kinase that recognizes and phosphorylates Max protein.
Proc. Natl. Acad. Sci. USA
92:10531-10534[Abstract/Free Full Text].
|
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[Abstract]
[Full Text]
-
Xu, P., Yoshioka, K., Yoshimura, D., Tominaga, Y., Nishioka, T., Ito, M., Nakabeppu, Y.
(2003). In Vitro Development of Mouse Embryonic Stem Cells Lacking JNK/Stress-activated Protein Kinase-associated Protein 1 (JSAP1) Scaffold Protein Revealed Its Requirement during Early Embryonic Neurogenesis. J. Biol. Chem.
278: 48422-48433
[Abstract]
[Full Text]
-
Matsuda, S., Matsuda, Y., D'Adamio, L.
(2003). Amyloid {beta} Protein Precursor (A{beta}PP), but Not A{beta}PP-like Protein 2, Is Bridged to the Kinesin Light Chain by the Scaffold Protein JNK-interacting Protein 1. J. Biol. Chem.
278: 38601-38606
[Abstract]
[Full Text]
-
Chow, J. P.H., Siu, W. Y., Fung, T. K., Chan, W. M., Lau, A., Arooz, T., Ng, C.-P., Yamashita, K., Poon, R. Y.C.
(2003). DNA Damage during the Spindle-Assembly Checkpoint Degrades CDC25A, Inhibits Cyclin-CDC2 Complexes, and Reverses Cells to Interphase. Mol. Biol. Cell
14: 3989-4002
[Abstract]
[Full Text]
-
Kelkar, N., Delmotte, M.-H., Weston, C. R., Barrett, T., Sheppard, B. J., Flavell, R. A., Davis, R. J.
(2003). Morphogenesis of the telencephalic commissure requires scaffold protein JNK-interacting protein 3 (JIP3). Proc. Natl. Acad. Sci. USA
100: 9843-9848
[Abstract]
[Full Text]
-
Takino, T., Tamura, M., Miyamori, H., Araki, M., Matsumoto, K., Sato, H., Yamada, K. M.
(2003). Tyrosine phosphorylation of the CrkII adaptor protein modulates cell migration. J. Cell Sci.
116: 3145-3155
[Abstract]
[Full Text]
-
Gindhart, J. G., Chen, J., Faulkner, M., Gandhi, R., Doerner, K., Wisniewski, T., Nandlestadt, A.
(2003). The Kinesin-associated Protein UNC-76 Is Required for Axonal Transport in the Drosophila Nervous System. Mol. Biol. Cell
14: 3356-3365
[Abstract]
[Full Text]
-
Willoughby, E. A., Perkins, G. R., Collins, M. K., Whitmarsh, A. J.
(2003). The JNK-interacting Protein-1 Scaffold Protein Targets MAPK Phosphatase-7 to Dephosphorylate JNK. J. Biol. Chem.
278: 10731-10736
[Abstract]
[Full Text]
-
Lee, C. M., Onesime, D., Reddy, C. D., Dhanasekaran, N., Reddy, E. P.
(2002). JLP: A scaffolding protein that tethers JNK/p38MAPK signaling modules and transcription factors. Proc. Natl. Acad. Sci. USA
99: 14189-14194
[Abstract]
[Full Text]
-
Sato, S., Tatebayashi, Y., Akagi, T., Chui, D.-H., Murayama, M., Miyasaka, T., Planel, E., Tanemura, K., Sun, X., Hashikawa, T., Yoshioka, K., Ishiguro, K., Takashima, A.
(2002). Aberrant Tau Phosphorylation by Glycogen Synthase Kinase-3beta and JNK3 Induces Oligomeric Tau Fibrils in COS-7 Cells. J. Biol. Chem.
277: 42060-42065
[Abstract]
[Full Text]
-
Matsuura, H., Nishitoh, H., Takeda, K., Matsuzawa, A., Amagasa, T., Ito, M., Yoshioka, K., Ichijo, H.
(2002). Phosphorylation-dependent Scaffolding Role of JSAP1/JIP3 in the ASK1-JNK Signaling Pathway. A NEW MODE OF REGULATION OF THE MAP KINASE CASCADE. J. Biol. Chem.
277: 40703-40709
[Abstract]
[Full Text]
-
Chen, Y.-R., Han, J., Kori, R., Kong, A.-N. T., Tan, T.-H.
(2002). Phenylethyl Isothiocyanate Induces Apoptotic Signaling via Suppressing Phosphatase Activity against c-Jun N-terminal Kinase. J. Biol. Chem.
277: 39334-39342
[Abstract]
[Full Text]
-
Holmberg, C., Katz, S., Lerdrup, M., Herdegen, T., Jaattela, M., Aronheim, A., Kallunki, T.
(2002). A Novel Specific Role for Ikappa B Kinase Complex-associated Protein in Cytosolic Stress Signaling. J. Biol. Chem.
277: 31918-31928
[Abstract]
[Full Text]
-
Taru, H., Kirino, Y., Suzuki, T.
(2002). Differential Roles of JIP Scaffold Proteins in the Modulation of Amyloid Precursor Protein Metabolism. J. Biol. Chem.
277: 27567-27574
[Abstract]
[Full Text]
-
Zama, T., Aoki, R., Kamimoto, T., Inoue, K., Ikeda, Y., Hagiwara, M.
(2002). Scaffold Role of a Mitogen-activated Protein Kinase Phosphatase, SKRP1, for the JNK Signaling Pathway. J. Biol. Chem.
277: 23919-23926
[Abstract]
[Full Text]
-
Taru, H., Iijima, K.-i., Hase, M., Kirino, Y., Yagi, Y., Suzuki, T.
(2002). Interaction of Alzheimer's beta -Amyloid Precursor Family Proteins with Scaffold Proteins of the JNK Signaling Cascade. J. Biol. Chem.
277: 20070-20078
[Abstract]
[Full Text]
-
Nguyen, A., Burack, W. R., Stock, J. L., Kortum, R., Chaika, O. V., Afkarian, M., Muller, W. J., Murphy, K. M., Morrison, D. K., Lewis, R. E., McNeish, J., Shaw, A. S.
(2002). Kinase Suppressor of Ras (KSR) Is a Scaffold Which Facilitates Mitogen-Activated Protein Kinase Activation In Vivo. Mol. Cell. Biol.
22: 3035-3045
[Abstract]
[Full Text]
-
Hirai, S.-i., Kawaguchi, A., Hirasawa, R., Baba, M., Ohnishi, T., Ohno, S.
(2002). MAPK-upstream protein kinase (MUK) regulates the radial migration of immature neurons in telencephalon of mouse embryo. Development
129: 4483-4495
[Abstract]
[Full Text]
-
Kampfer, S., Windegger, M., Hochholdinger, F., Schwaiger, W., Pestell, R. G., Baier, G., Grunicke, H. H., Uberall, F.
(2001). Protein Kinase C Isoforms Involved in the Transcriptional Activation of Cyclin D1 by Transforming Ha-Ras. J. Biol. Chem.
276: 42834-42842
[Abstract]
[Full Text]
-
Whitmarsh, A. J., Kuan, C.-Y., Kennedy, N. J., Kelkar, N., Haydar, T. F., Mordes, J. P., Appel, M., Rossini, A. A., Jones, S. N., Flavell, R. A., Rakic, P., Davis, R. J.
(2001). Requirement of the JIP1 scaffold protein for stress-induced JNK activation. Genes Dev.
15: 2421-2432
[Abstract]
[Full Text]
-
Goldstein, L. S. B.
(2001). Kinesin molecular motors: Transport pathways, receptors, and human disease. Proc. Natl. Acad. Sci. USA
98: 6999-7003
[Abstract]
[Full Text]
-
Pearson, G., Robinson, F., Beers Gibson, T., Xu, B.-e, Karandikar, M., Berman, K., Cobb, M. H.
(2001). Mitogen-Activated Protein (MAP) Kinase Pathways: Regulation and Physiological Functions. Endocr. Rev.
22: 153-183
[Abstract]
[Full Text]
-
Kyriakis, J. M., Avruch, J.
(2001). Mammalian Mitogen-Activated Protein Kinase Signal Transduction Pathways Activated by Stress and Inflammation. Physiol. Rev.
81: 807-869
[Abstract]
[Full Text]
-
Verhey, K. J., Meyer, D., Deehan, R., Blenis, J., Schnapp, B. J., Rapoport, T. A., Margolis, B.
(2001). Cargo of Kinesin Identified as Jip Scaffolding Proteins and Associated Signaling Molecules. JCB
152: 959-970
[Abstract]
[Full Text]
-
Corbit, K. C., Soh, J.-W., Yoshida, K., Eves, E. M., Weinstein, I. B., Rosner, M. R.
(2000). Different Protein Kinase C Isoforms Determine Growth Factor Specificity in Neuronal Cells. Mol. Cell. Biol.
20: 5392-5403
[Abstract]
[Full Text]
-
Kargul, G. J., Nagaraja, R., Shimada, T., Grahovac, M. J., Lim, M. K., Nakashima, H., Waeltz, P., Ma, P., Chen, E., Schlessinger, D., Ko, M. S.H.
(2000). Eleven Densely Clustered Genes, Six of them Novel, in 176 kb of Mouse t-complex DNA. Genome Res
10: 916-923
[Abstract]
[Full Text]
-
Kuboki, Y., Ito, M., Takamatsu, N., Yamamoto, K.-i., Shiba, T., Yoshioka, K.
(2000). A Scaffold Protein in the c-Jun NH2-terminal Kinase Signaling Pathways Suppresses the Extracellular Signal-regulated Kinase Signaling Pathways. J. Biol. Chem.
275: 39815-39818
[Abstract]
[Full Text]
-
Holtmann, H., Enninga, J., Kalble, S., Thiefes, A., Dorrie, A., Broemer, M., Winzen, R., Wilhelm, A., Ninomiya-Tsuji, J., Matsumoto, K., Resch, K., Kracht, M.
(2001). The MAPK Kinase Kinase TAK1 Plays a Central Role in Coupling the Interleukin-1 Receptor to Both Transcriptional and RNA-targeted Mechanisms of Gene Regulation. J. Biol. Chem.
276: 3508-3516
[Abstract]
[Full Text]
-
Yamauchi, J., Tsujimoto, G., Kaziro, Y., Itoh, H.
(2001). Parallel Regulation of Mitogen-activated Protein Kinase Kinase 3 (MKK3) and MKK6 in Gq-signaling Cascade. J. Biol. Chem.
276: 23362-23372
[Abstract]
[Full Text]
-
Miller, W. E., McDonald, P. H., Cai, S. F., Field, M. E., Davis, R. J., Lefkowitz, R. J.
(2001). Identification of a Motif in the Carboxyl Terminus of beta -Arrestin2 Responsible for Activation of JNK3. J. Biol. Chem.
276: 27770-27777
[Abstract]
[Full Text]
-
Abe, Y., Matsumoto, S., Kito, K., Ueda, N.
(2000). Cloning and Expression of a Novel MAPKK-like Protein Kinase, Lymphokine-activated Killer T-cell-originated Protein Kinase, Specifically Expressed in the Testis and Activated Lymphoid Cells. J. Biol. Chem.
275: 21525-21531
[Abstract]
[Full Text]
-
Sano, Y., Shimada, T., Nakashima, H., Nicholson, R. H., Eliason, J. F., Kocarek, T. A., Ko, M. S.H.
(2001). Random Monoallelic Expression of Three Genes Clustered within 60 kb of Mouse t Complex Genomic DNA. Genome Res
11: 1833-1841
[Abstract]
[Full Text]
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Abstract
Introduction
