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J. Biol. Chem., Vol. 275, Issue 28, 21247-21254, July 14, 2000
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From the Departments of
Received for publication, February 23, 2000, and in revised form, April 29, 2000
Mitogen-activated protein kinase upstream
kinase/dual leucine zipper-bearing kinase/leucine-zipper protein kinase
(MUK/DLK/ZPK) is a MAPKKK class protein kinase that induces JNK/SAPK
activation. We report here a protein named MBIP that binds to
MUK/DLK/ZPK. MUK-binding inhibitory protein (MBIP) contains two
tandemly orientated leucine-zipper-like motifs with a cluster of basic
amino acids located between the two motifs. MBIP interacts with one of
the two leucine-zipper-like motifs of MUK/DLK/ZPK and inhibits the activity of MUK/DLK/ZPK to induce JNK/SAPK activation. Notably, no
similar effect was observed with another JNK/SAPK-inducing MAPKKK,
COT/Tpl-2, showing the specificity of MBIP action. Furthermore, the
overexpression of MBIP partially inhibits the activation of JNK by 0.3 M sorbitol in 293T cells. Taken together, these
observations indicate that MBIP can function as a regulator of
MUK/DLK/ZPK, a finding that may provide a clue to understanding the
molecular mechanism of JNK/SAPK activation by hyperosmotic stress.
JNK1/SAPK is essential
for the survival as well as the death of neural cells in developing
mouse brain (1-3). In cultured mammalian cells, JNK/SAPK is well
characterized as a stress-inducing protein kinase that is activated by
several kinds of cellular stresses, including ultraviolet light, heat
shock, protein synthesis inhibitors, and osmotic shock, as well as by
different kinds of cytokines and their receptors, such as TNF Members of the MLK family share a characteristic protein kinase domain
that shows structural features of both tyrosine-specific and
serine/threonine-specific protein kinases and two leucine-zipper-like motifs located at the C-terminal side of the kinase domain (20). Despite these common features, members of the MLK family show considerable differences in their primary structures, and they comprise
two subgroups that can be distinguished by the primary structure of the
kinase domain and the presence or absence of an SH3 domain located at
the N-terminal side of the kinase domain. The SH3-containing group of
MLK includes MLK1, MST/MLK2, and SPRK/MLK3/PTK1. They also contain a
Cdc42 and Rac interactive binding domain conserved among several Cdc42-
and Rac-binding proteins such as PAK and WASP (21); this domain is
heavily degenerated in members of another, non-SH3-containing group of
MLK including MUK/DLK/ZPK and LZK. Such structural differences between
these two groups suggest their different regulatory mechanisms and
physiological functions. However, neither the molecular mechanism of
the regulation of MLK activity nor the physiological function of the
MLK-JNK/SAPK pathway has been explored.
Nevertheless, there are some candidates for the upstream regulators of
the SH3-containing group of MLK. Based on an analogy with a
mitogen-activated protein kinase pathway in budding yeast, it is
expected that an STE20-like protein kinase acts as an activator of
MAPKKK class protein kinases including MLKs. This possibility is
supported by the observations that an STE20-like kinase, HPK1, interacts with SPRK/MLK3/PTK1 through the SH3 domain and that SPRK/MLK3/PTK1 can be phosphorylated by HPK1 in vitro (22). Although the effect of HPK1 interaction on the kinase activity of
SPRK/MLK3/PTK1 has not been explored, this STE20-like kinase is a
strong candidate for an upstream regulator of SH3-containing MLKs. On
the other hand, the presence of a Cdc42 and Rac interactive binding
site in those MLK members suggests the regulation of kinase activity by
Rac and Cdc42, known activators of the JNK/SAPK pathway. In fact, the
GTP-dependent binding of these small GTP-binding proteins
to MST/MLK2 and SPRK/MLK3/PTK1 has been shown by overlay assay and by a
yeast two-hybrid system (21, 23). However, the effect of Rac/Cdc42
binding on MLK activity is obscure, and the binding could be meaningful
in the sense of the targeting of MST/MLK2 and SPRK/MLK3/PTK1 to a
certain subcellular component (23-25).
As to members of the SH3 domain noncontaining group of MLK, MUK/DLK/ZPK
and LZK, information about upstream regulators is quite limited. There
are some reports showing the possible involvement of MUK/DLK/ZPK in
JNK/SAPK activation induced by Rac or C3G (15, 26). However, whether
MUK/DLK/ZPK binds directly to and is activated by these proteins or not
is obscure. On the other hand, MUK/DLK/ZPK as well as other MLKs
include two leucine-zipper-like motifs, putative protein interaction
domains, that could be essential for the MLK activity (13, 27).
Therefore, it is conceivable that the MUK/DLK/ZPK activity is regulated
by a certain protein interacting with these motifs. To identify such a
regulatory protein binding directly to MUK/DLK/ZPK, we employed a yeast
two-hybrid system. By using a part of MUK/DLK/ZPK protein including one
of the two leucine-zipper-like motifs as a bait, we identified a MUK/DLK/ZPK-binding protein that specifically inhibits the MUK/DLK/ZPK activity to induce the activation of the JNK/SAPK pathway.
Library Screening--
Yeast strain Y190 cells were transformed
first with a bait plasmid encoding a LexA DNA binding domain fused to a
part of MUK (amino acids 453-604). A selected bait-containing clone
was then transformed with plasmids containing human brain cDNA
expression library clones fused to DNA encoding a GAL4 activation
domain. From ~2 × 107 transformants, we obtained
339 His+/LacZ+ clones, that originated from six
distinct gene products. To obtain a cDNA clone including the
full-length MBIP coding sequence, we screened a human kidney cDNA
library using one of the initial isolates (clone3-3) encoding amino
acid residues 171-344 of MBIP as a probe. Hybridization was done
overnight at 65° C in 0.9 M NaCl, 90 mM
Tris-HCl, 6 mM EDTA, 5× Denhardt's solution, 0.1% SDS,
100 µg/ml sonicated salmon sperm DNA, and 1 × 106
cpm/ml of the cDNA probe. Filters were subsequently washed with 2×
SSC containing 0.1% SDS twice at room temperature for 10 min and with
0.1× SSC containing 0.1% SDS twice at 65° C for 20 min, and they
were exposed to x-ray films at Northern Blot Analysis--
Multiple human tissue Northern blots
(CLONTECH) were hybridized to a
32P-labeled MBIP cDNA probe at 68° C for 1 h
and washed at 50° C for 40 min to a final stringency of 0.1× SSC,
0.1% (w/v) SDS before exposure to x-ray film.
Expression Vectors--
The expression vectors for MUK and Cot
were constructed with a mammalian expression vector containing an EF1
promoter and a cDNA encoding rat MUK (13) or human Cot (kindly
provided by Dr. Jun Miyoshi). The expression vectors for MBIP and its
deletion mutants were constructed with a mammalian expression vector
SR Cell Transfection--
COS-1 and 293T cells were maintained in
10% fetal bovine serum in Dulbecco's modified Eagle's medium. COS-1
cells were transfected by an electroporation method using 15 µg of
DNA for 6 × 106 cells. After transfection, the cells
were seeded in three 10-cm dishes and further cultured for 40 h
before harvest. 293T cells were transfected by calcium phosphate
co-precipitation methods at a density of 5 × 105
cells/6-cm dish. After a 10-h exposure to the calcium phosphate-DNA precipitate, the medium was changed, and cells were further cultured for 20 h before harvest. We used a relatively large amount of SR Immunofluorescence Microscopy--
COS-1 cells were transfected
by electroporation and seeded on coverslips. The cells were cultured
for 40 h and fixed with 3% paraformaldehyde in PBS for 20 min.
After washing with PBS, the cells were permeabilized with 0.1% Triton
X-100 for 5 min, washed again with PBS, and incubated with TBST (20 mM Tris-HCl, pH 8.0, 150 mM NaCl, 0.05% Tween
20) containing 10% calf serum for 30 min at room temperature. The
cells were then incubated with primary antibodies, anti-MUK antibody
raised against the C-terminal part of MUK or anti-FLAG M2 monoclonal
antibody tag (Sigma), for 60 min at 37° C, and washed three times
for 15 min each with TBST. After incubation with secondary antibodies,
fluorescein isothiocyanate-conjugated goat anti-rabbit IgG (Cappel) and
Cy3-conjugated goat anti-mouse IgG (Amersham Pharmacia Biotech), the
cells were washed three times for 15 min each with TBST. Samples were
observed under an OLYMPUS BX50, and images were captured with a
Princeton Instruments digital camera.
Immunoprecipitation--
COS-1 cells grown in 10-cm dishes were
lysed in 200 µl of lysis buffer consisting 20 mM HEPES,
pH 7.5, 150 mM NaCl, 1 mM EDTA, 10 µg/ml
leupeptine, 1 mM phenylmethylsulfonyl fluoride, 1.0% Triton X-100. The epitope-tagged proteins were
immunoprecipitate-carried at 4° C for 1 h using 1 µg of
anti-T7 tag monoclonal antibody (Novagen) or anti-FLAG M2 monoclonal
antibody tag (Sigma) prefixed on 5 µl of protein G-Sepharose 4 Fast
Flow (Amersham Pharmacia Biotech). The Sepharose resin was washed five
times with lysis buffer. The immunoprecipitated protein was eluted with
SDS-sample buffer for Western blot analysis.
Western Blot Analysis--
293T cells transfected with
expression vectors were collected directly in SDS-sample buffer. After
SDS-polyacrylamide gel electrophoresis, the separated proteins were
electrophoretically transferred to a polyvinylidene difluoride
membrane. The blotted membrane was soaked in PBS containing 5% skim
milk overnight at 4° C. The membrane was then incubated with
appropriately diluted anti-active JNK pAb (pTPpY) (Promega),
phosphospecific SEK1/MKK4 antibody (Thr223) (New England
Biolabs), anti-T7 tag monoclonal antibody (Novagen), anti-FLAG M2
monoclonal antibody (Sigma), or anti-GST antibody in TBST containing
0.1% bovine serum albumin for 1 h at 37° C. After washing with
TBST, the membrane was incubated with peroxidase-conjugated anti-rabbit
or mouse IgG antibody (Amersham Pharmacia Biotech) in TBST containing
0.1% bovine serum albumin. The membrane was washed again and the
specific bands were visualized with an ECL system (Amersham Pharmacia Biotech).
Stimulation of Cells--
293T cells were routinely grown in
Dulbecco's modified Eagle's medium supplemented with 10% fetal
bovine serum (10% fetal bovine serum/Dulbecco's modified Eagle's
medium). The cells were transfected with the MBIP expression vector or
empty vector together with the T7-JNK1 expression vector by calcium
phosphate co-precipitation methods at a density of 2 × 105 cells/6-cm dish. After a 10-h exposure to the calcium
phosphate-DNA precipitate, the medium was changed to fresh 10% fetal
bovine serum/Dulbecco's modified Eagle's medium and the cells were
further cultured for 24 h. The cells were then stimulated with 0.3 M sorbitol for 5, 15, 60, or 120 min, heat shock at 44°
for 15 min, or 100 ng/ml TNF Molecular Cloning of a MUK-binding Protein, MBIP--
To isolate
cDNA clones encoding MUK-binding proteins, we employed a yeast
two-hybrid system using part of MUK including a leucine-zipper-like
motif and a cluster of basic amino acids as bait (see Ref. 13 and Fig.
4). By screening ~2 × 107 clones of a human brain
cDNA library, we identified 339 positive clones originating from
six different gene products. The expression of proteins encoded by one
of these clones, clone 3-3, in 293T cells resulted in the inhibition
of the overexpressed MUK activity to induce JNK activation, whereas no
significant effect was observed with the other clones (data not shown).
Therefore, we chose clone 3-3 for further analyses. To isolate
cDNA clones encoding the entire protein, a human kidney cDNA
library was screened using a 3-3 cDNA fragment as a probe. Among
16 cDNA clones isolated, the complete sequences of 2 clones
containing the 5'- or 3'-parts of the long open reading frame were
determined (Fig. 1, A and B). The open reading frame encodes 344 amino acids, and the
nucleotides franking the initiation codon fulfill Kozack's consensus
sequence (28). In addition, in-frame termination codons were found in the 5'-nontranslated sequence, and a poly(A) addition signal was identified 22 base pairs upstream of the poly (A) tail in the 3'-nontranslated sequence (Fig. 1B). Importantly, the
reading frame is the same as that of clone 3-3 on the yeast expression vector, which covers the C-terminal part (Fig. 1A). Taken
together, these structural features indicate that this open reading
frame is translated into a protein harboring a MUK binding region in the C-terminal part. We named this protein MBIP: MUK
binding inhibitory protein.
MBIP shows no significant homology in its primary structure with any
other proteins in the GenBankTM data base, although we
could find several human expressed sequence tag clones that together
covered almost the entire MBIP sequence. MBIP contains two
leucine-zipper-like motifs that are predicted to form short amphipathic
MBIP Binds Specifically to MUK--
Because the clones we isolated
using the yeast two-hybrid system cover only the C-terminal half of
MBIP, the interaction with MUK could depend on an artificial structure
created by the loss of the N-terminal half. To rule out this
possibility, we tested the binding of the full MBIP and MUK.
Epitope-tagged proteins were transiently overexpressed in COS-1 cells,
and binding was examined by immunoprecipitation followed by Western
blotting analysis. As shown in Fig.
2A, Flag-tagged MBIP
co-precipitated with T7-tagged MUK when anti T7-tag antibody was used
for immunoprecipitation (lane 4, upper panel); no Flag-MBIP
was detectable without T7-MUK overexpression (lane 3,
upper panel). When anti-Flag antibody was used for the
immunoprecipitation, T7-MUK co-precipitated with Flag-MBIP (Fig.
2B). In contrast, the MBIP binding with Cot, another JNK-activating MAPKKK, was barely detectable (Fig. 2C).
These results indicate a stable and specific interaction between MBIP and MUK in mammalian cells.
In the yeast two-hybrid system, the C-terminal half of MBIP binds to
part of MUK used for bait (Fig.
3A), indicating that the
C-terminal half of MBIP includes a MUK binding site. This is confirmed
by the immunoprecipitation experiments using the C-terminal or
N-terminal half of MBIP (Fig. 3A). When T7-MUK was immunoprecipitated, the C-terminal half (amino acids 172-344) but not
the N-terminal half (amino acids 1-228) of MBIP was found in the
immunocomplex (Fig. 3B, lanes 10 and
12, upper panel). Therefore, the C-terminal half
of MBIP including the two leucine-zipper-like motifs is necessary and
sufficient for binding with MUK. It should be noted, however, that the
binding of MUK to the C-terminal appears to be considerably weaker than
the binding to the entire MBIP (Fig. 3B, lanes 8 and 12, upper panel). This indicates that the N-terminal part of MBIP supports MUK binding without being able to bind
stably itself.
Leucine-Zipper-like Motif of MUK Is Essential for MBIP
Binding--
To identify the MBIP binding site on MUK, several MUK
deletion mutants were tested for binding to MBIP (Fig.
4A). MBIP can bind to a
C-terminal deleted mutant of MUK that retains the two leucine-zipper-like motifs (MUK/1-496), whereas binding is abolished by deletion of one of the two leucine-zipper-like motifs (MUK/1-452) (Fig. 4B, lanes 9 and 10, upper
panel). This indicates that the leucine-zipper-like motifs are
essential for MBIP binding. It should also be noted that this
leucine-zipper-like motif flanked by 108 amino acids on the C-terminal
side was used as bait for screening by the yeast two-hybrid system
(Fig. 4A). Taken together, these results strongly suggest
that MBIP interacts with MUK through the leucine-zipper-like
motif.
The Interaction of MBIP and MUK in Vivo--
MUK is mostly located
in the cytoplasm when overexpressed in COS-1 cells (Fig.
5A), whereas much of the MBIP
overexpressed in COS-1 cells is located in the nuclei forming several
patch-like structures (Fig. 5F). The nuclear localization of
MBIP is expected from the presence of nuclear localization sequence
between the two leucine-zipper-like motifs located in the C-terminal
part of MBIP. However, when MBIP was co-expressed with MUK, the nuclear localization was mostly abolished and cytoplasmic localization became
apparent (Fig. 5D). Notably, some MBIP remained in the nuclei cells expressing lower amounts of MUK (arrow in Fig.
5D). Therefore, the cytoplasmic localization of MBIP depends
on the amount of MUK, a dependence that may be caused by MUK covering the nuclear localization sequence or by the anchoring of MBIP in
cytoplasm by MUK. In any case, this observation strongly supports the
idea that the interaction between MUK and MBIP occurs in
vivo.
MBIP Specifically Inhibits the Ability of MUK to Induce JNK
Activation--
To assess the effect of MBIP on the activity of MUK,
MUK and JNK1 were transiently overexpressed in 293T cells, and the
effect of MBIP co-expression on the activation of JNK1 was tested. As shown in Fig. 6A, the
co-expression of MBIP inhibited the ability of MUK to induce JNK
activity as estimated by Western blot analysis using an anti-active JNK
antibody (lanes 3-5, uppermost panel). Importantly, the activity of Cot, another JNK-inducing MAPKKK, was not
affected by MBIP (Fig. 6A, lanes 6-8), showing
the specificity of MBIP action. The effect of MBIP was further
confirmed using SEK1 instead of JNK1 as a reporter of MUK activity.
MBIP also inhibited the ability of MUK to induce SEK1 activity as
estimated by Western blot analysis using phospho-SEK1
(Thr223) antibody (Fig. 6B, lanes 3 and 4, uppermost panel). Again, no inhibitory
effect of MBIP was observed with Cot (Fig. 6B, lanes 7 and 8, uppermost panel). In addition, it
should be noted that the amount of overexpressed MUK as shown by the
anti-T7 antibody did not change upon MBIP co-expression (Fig.
6B, lanes 3 and 4, middle
panel). Instead, the mobility of MUK on SDS-polyacrylamide gel
electrophoresis increased upon MBIP co-expression. This downward shift
of the MUK band on SDS-polyacrylamide gel electrophoresis was more
clearly observed without SEK1 overexpression (Fig. 6B, lanes 5 and 6, middle panel). Because
treatment of the immunoprecipitated MUK with alkaline phosphatase also
caused a similar downward shift of the MUK band on SDS-polyacrylamide
gel electrophoresis, the changes in mobility are likely to depend on
the phosphorylation state of MUK (data not shown). Therefore, MBIP may
modify the phosphorylation state of MUK in correlation with the change
in MUK activity. Taken together, these results show that MBIP is a
specific negative regulator of MUK.
To test whether the MUK binding domain of MBIP is indispensable for the
MUK inhibitory activity, the MBIP deletion mutants tested for MUK
binding (Fig. 3) were used in experiments to assess the effect on MUK
activity. As shown in Fig. 7, the
overexpression of the C-terminal half of MBIP (MBIP-(172-344)), which
binds to MUK, inhibits the ability of MUK to activate SEK1 (lanes
4, 7, and 8, uppermost panel).
Notable is the complete inhibition of SEK1 phosphorylation by high dose
expression of MBIP-(172-344) or the entire MBIP molecule (Fig. 7,
lanes 6 and 8). On the other hand, approximately
the same dose of the N-terminal part of MBIP (MBIP-(1-228)) produces
no such inhibitory effect (Fig. 7, lanes 9 and
10). Therefore, both MUK binding and the inhibitory
activities lie in the C-terminal half of MBIP. Despite the relatively
weak binding activity of MBIP-(172-344) to MUK (Fig. 3), the
inhibitory effect is comparable to that of the complete MBIP molecule
(Fig. 7, lanes 4-8). This difference may be caused by the
more stringent conditions of the immunoprecipitation assay used to test
MUK binding (Fig. 3) compared with conditions in vivo used
for the MUK inhibition assay (Fig. 7).
The Overexpression of MBIP Inhibits the JNK Activity Induced by
Osmotic Stress--
The specific inhibition of MUK activity by MBIP
allowed us to identify the JNK-activating pathway involving MUK by
testing the effect of MBIP overexpression on the activation of JNK by different kinds of extracellular stimuli. Among several JNK-activating pathways tested, the pathway induced by osmotic shock with 0.3 M sorbitol was the most sensitive to MBIP (Fig.
8). Especially, the early phase of JNK
activation by sorbitol, 15 min after the addition of sorbitol, was
inhibited by up to 30% from the control level, whereas the later phase
was mostly unaffected (Fig. 8, A and B).
Transfection of increasing amounts of MBIP expression vector inhibited
osmotic shock-induced JNK activity in a concentrationdependent manner (Fig. 8B). On the other hand, no significant effect
of MBIP overexpression was observed on JNK activation induced by heat
shock (Fig. 8C) or TNF We report here the molecular cloning of MBIP that binds to and
inhibits MUK/DLK/ZPK. No binding protein for MUK/DLK/ZPK has been
reported other than JIP1/2, which has been proposed to act as a
scaffold protein for MLK JNK/SAPK signaling (29, 30). On the other
hand, relatively large numbers of proteins have been reported to bind
to SH3 containing MLKs, SPRK/MLK3/PTK1, and MST/MLK2, including
HPK1(22), Cdc42/Rac (21, 23, 25), KIF3A, hippocalcin, 14-3-3 MBIP interacts with a leucine-zipper-like motif of MUK/DLK/ZPK, and
MBIP itself also contains leucine-zipper-like motifs in the C-terminal
MUK binding region. Therefore, the interaction of these proteins is
likely to be mediated by these structural motifs. Accordingly,
Cot/Tpl-2, a JNK/SAPK-inducing MAPKKK without leucine-zipper-like
motifs, does not bind to nor is it inhibited by MBIP. If a
leucine-zipper-like motif is sufficient for MBIP binding, all MLK
members with leucine-zipper-like motifs would be expected to bind to
MBIP. However, our preliminary results show that MBIP binding to
MST/MLK2, an SH3 containing MLK, is barely detectable. Furthermore,
it's ability to induce JNK activation is only moderately affected, if
at all, by MBIP, whereas LZK, a non-SH3 containing MLK, is also a
target of MBIP.2 This specificity of MBIP action may depend
on the primary structures of the leucine-zipper-like motifs of MLKs,
which are significantly diverged between SH3-containing and
-noncontaining MLKs (18).
How does the binding of MBIP result in the inhibition of MUK/DLK/ZPK
kinase activity? Even though the MBIP binding region lies outside the
MUK/DLK/ZPK kinase domain, the binding of MBIP could physically block
the interaction with the substrate, SEK1/MKK4/JNKK1/SSK1 or
SEK2/MKK7/JNKK2/SSK4 with MUK/DLK/ZPK. Also MBIP binding could induce a
conformational change in the MUK/DLK/ZPK protein to an inactive form.
Deletion of the C-terminal half including the leucine-zipper-like motifs results in the loss of the ability of MUK/DLK/ZPK to induce JNK/SAPK activation (13). In addition, it has been suggested that dimer
formation through the leucine-zipper-like motifs is essential for the
activation of SPRK/MLK3/PTK1 (27). These facts indicate the importance
of the leucine-zipper-like motifs in maintaining the active
conformation, including the dimer of MUK/DLK/ZPK. Therefore, MBIP could
inhibit MUK/DLK/ZPK activity by interfering with this function of the
leucine-zipper-like motif.
MLKs, including MUK/DLK/ZPK, activate the JNK/SAPK pathway in an
extracellular stimuli-independent manner when overexpressed in cultured
cells (13-18). Moreover, the deletion of part of MLK other than the
kinase domain never results in an increase in kinase activity (13, 19),
indicating the absence of a regulatory domain that is often found in
other MAPKKKs, including Raf and mitogen-activated protein
kinase/extracellular signal-regulated kinase kinase kinase 1 (34, 35).
Because the unregulated activation of JNK/SAPK can cause apoptotic cell
death in many cell lines (36-39), the amount of MLK must be tightly
regulated, and the excess fraction degraded rapidly or was inactivated
by other regulatory proteins that interact with MLK. MBIP appears to be
such a regulatory protein for MUK/DLK/ZPK. Then the question arises as
to how the activity of MBIP to suppress MUK/DLK/ZPK is regulated. One
possible way is through a quantitative change in the amount of MBIP or MUK/DLK/ZPK. A decrease in the amount of MBIP or an increase in MUK/DLK/ZPK can produce free active MUK/DLK/ZPK. Another possibility is
a qualitative change in MBIP or MUK/DLK/ZPK; for example, certain post-translational modifications of these molecules might disrupt the
interaction. At present, we do not have data to support either of these possibilities.
Little has been reported concerning the physiological function of MLKs.
MUK/DLK/ZPK mRNA is mainly detected in the brain among those human
or mouse tissues that have been tested (13, 40). Therefore, MUK/DLK/ZPK
may be involved in the formation of the neural network and neural cell
differentiation by modulating JNK activity. On the other hand, MBIP
mRNA is ubiquitously expressed in several human tissues (Fig.
1D). This discrepancy is at least partially explained by the
expression pattern of LZK, another potential target of MBIP, which is
found in the placenta, liver, and pancreas as well as in the brain
(18). In addition, the amount of MUK/DLK/ZPK mRNA might be induced
in a variety of tissues in certain physiological or pathological states
including fracture repair or liver regeneration (41, 42). MBIP may
serve as a pre-existing regulator for the newly synthesized
MUK/DLK/ZPK.
Because the action of MBIP is quite specific to MUK/DLK/ZPK or LZK, we
used this protein to identify signaling pathways involving MUK/DLK/ZPK
or LZK. Among several JNK/SAPK-activating pathways tested, only that
induced by osmotic shock was affected by MBIP overexpression. It
should, however, be noted that the inhibition is partial and restricted
to the early phase of JNK/SAPK activation (Fig. 8A).
Therefore, not only MUK/DLK/ZPK but also other MAPKKKs might be
involved in the activation of JNK/SAPK by osmotic shock. It has been
reported that osmotic shock induces the clustering of the epidermal
growth factor receptor, TNF receptor, and interleukin-1 receptor in
HeLa cells. The combinational activation of these receptors may cause a
strong activation of JNK/SAPK (43), which may be mediated by multiple
kinds of MAPKKKs. One of the responses induced by osmotic shock in
mammalian cell is an alteration in Golgi structure and endoplasmic
reticulum-to-Golgi transport (44). Because MUK/DLK/ZPK has been
reported to be localized in the Golgi apparatus (45), MUK/DLK/ZPK and
MBIP could play some role in cellular response through the regulation
of JNK/SAPK activation. The molecular mechanisms and physiological
significance of JNK/SAPK activation by a variety of extracellular
stimuli including osmotic shock are mostly unknown. MBIP may serve as a
tool for use in investigating these issues.
We thank Dr. Jun Miyoshi for providing human
Cot cDNA.
*
This work was supported in part by Grants in Aid for
Scientific Research from the Ministry of Education, Science, Sports, and Culture of Japan and Grants from the Japan Society for the Promotion of Science.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/EMBL Data Bank with accession number(s) AB038523.
**
To whom correspondence should be addressed: Dept. of Molecular
Biology, Yokohama City University School of Medicine, 3-9, Fukuura,
Kanazawa-ku, Yokohama 236-0004, Japan. Tel.: 81-45-787-2597; Fax:
81-45-785-4140; E-mail: sh3312@med.yokohama-cu.ac.jp.
Published, JBC Papers in Press, May 8, 2000, DOI 10.1074/jbc.M001488200
2
K. Fukuyama, unpublished data.
The abbreviations used are:
JNK, c-Jun
N-terminal kinase;
SAPK, stress-activated protein kinase;
TNF, tumor
necrosis factor;
JNKK, JNK kinase;
MAPKKK, mitogen-activated protein
kinase kinase kinase;
MLK, mixed lineage kinase;
MUK, mitogen-activated
protein kinase upstream kinase;
DLK, dual leucine zipper-bearing
kinase;
ZPK, leucine zipper protein kinase;
MST, MKN28-derived
nonreceptor type of serine/threonine kinase;
SH3, Src homology 3;
MBIP, MUK-binding inhibitory protein;
PBS, phosphate-buffered saline;
GST, glutathione S-transferase;
SEK, SAPK/extracellular
signal-regulated kinase kinase;
LZK, leucine zipper-binding
kinase.
MAPK Upstream Kinase (MUK)-binding Inhibitory Protein, a Negative
Regulator of MUK/Dual Leucine Zipper-bearing Kinase/Leucine Zipper
Protein Kinase*
,
,,, Dermatology, § 1st
Internal Medicine, ¶ Molecular Biology, and Urology,
Yokohama City University School of Medicine, 3-9, Fukuura, Kanazawa-ku,
Yokohama 236-0004, Japan
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURE
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURE
RESULTS
DISCUSSION
REFERENCES
and
Fas (4-7). JNK/SAPK activity is induced by mitogen-activated protein
kinase kinase class protein kinases, SEK1/MKK4/JNKK1/SSK1 or
SEK2/MKK7/JNKK2/SSK4, whose activity is induced by further upstream
kinases. More of such upstream protein kinases, the so-called MAPKKK,
are now reported and include mitogen-activated protein
kinase/extracellular signal-regulated kinase kinase kinase-related
protein kinases (8, 9), TAK (10), Cot/Tpl-2 (11), and ASK1 (12). We and
others have reported that the overexpression of mixed lineage kinases
(MLKs), including MUK/DLK/ZPK, LZK, MST/MLK2, and SPRK/MLK3/PTK1,
induces the activation of JNK/SAPK in mammalian cells (13-18). Using
purified recombinant proteins, we have further shown that MST/MLK2
directly activates protein kinases of the mitogen-activated protein
kinase kinase class, SEK1/MKK4/JNKK1/SSK1 or SEK2/MKK7/JNKK2/SSK4 (17, 19). Therefore, all members of the MLK family may act as MAPKKK in the
JNK/SAPK pathway.
EXPERIMENTAL PROCEDURE
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURE
RESULTS
DISCUSSION
REFERENCES
80° C.
. The expression vector for T7-tagged JNK1 and GST-SEK1 has been described elsewhere (13, 19).
-expression vector compared with the EF-1-expression vector (>100-fold), because the EF-1 promoter is more active than the SR
promoter in 293T cells.
for 15 min, and the cells were washed
with PBS and lysed in SDS-polyacrylamide gel electrophoresis sample buffer.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURE
RESULTS
DISCUSSION
REFERENCES
View larger version (43K):
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Fig. 1.
Structure and expression of MBIP.
A, structure of human cDNA clones encoding MBIP. Clone
3-3 was isolated using the yeast two-hybrid system. Clones 17 and 11 were isolated from a human kidney cDNA library using clone 3-3 as
a probe. The open box represents an open reading frame.
B, nucleotide and amino acid sequences of MBIP.
Underlining in the 5'-noncoding sequence indicates in-frame
stop codons. A poly(A) addition signal found in the 3'-noncoding
sequence is also underlined. Underlined amino
acids are hydrophobic amino acids involved in leucine-zipper-like
motifs. A cluster of basic amino acids related to the SV40 T type
nuclear localization sequence is indicated by double
underlining. C, helical loop analysis of two
leucine-zipper-like motifs starting at Ile271
(left) and Leu314 (right),
respectively. Amino acid residues that may be involved in the formation
of a hydrophobic surface are shadowed. D,
Northern blot showing MBIP mRNA in various human tissues. Multiple
tissue Northern filters (CLONTECH) containing 2 µg each of poly(A)+ RNA were hybridized to the MBIP
cDNA probe. Lane 1, heart; lane 2, brain;
lane 3, placenta; lane 4, lung; lane
5, liver; lane 6, skeletal muscle; lane 7,
kidney; lane 8, pancreas. The arrowhead indicates
the position of the 1.8-kilobase (kb) MBIP mRNA.
-helixes (Fig. 1C). The joining region between the two
leucine-zipper-like motifs is 28 amino acids long and includes a
cluster of basic amino acids related to an SV40T-type nuclear
localization sequence (Fig. 1B). The mouse expressed
sequence tag clone AA879837 covers part of the mouse MBIP including the
leucine-zipper-like motifs; the amino acid sequence of mouse MBIP is
mostly identical to that of human MBIP except that Gln326
is replaced by Arg in the mouse sequence. The mRNA for MBIP is present ubiquitously in different human tissues (Fig. 1D),
with relatively high expression seen in the heart and lung. The length of the mRNA is estimated to be approximately 1.8 kilobases long. Therefore, the nucleotide sequence shown in Fig. 1B covers
nearly the entire MBIP mRNA.
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Fig. 2.
Association of MBIP and MUK in mammalian
cells. COS-1 cells were co-transfected with an expression vector
for Flag-tagged MBIP together with T7-tagged MUK or T7-tagged Cot, as
indicated at the top of each panel. A cell lysate prepared
two days after transfection was used for immunoprecipitation.
A, T7-tagged MUK was immunoprecipitated using anti-T7 tag
antibody (anti-T7), and total cell lysate (lanes
1 and 2) and immunoprecipitated proteins (lanes
3 and 4) were analyzed by Western blotting using
anti-Flag tag antibody (anti-Flag, upper panel) or anti-T7
tag antibody (anti-T7, lower panel). Note the presence of
Flag-tagged MBIP in the immunoprecipitate (IP) (lane
4, upper panel). B, Flag-tagged MBIP was
immunoprecipitated using anti-Flag tag antibody (anti-Flag), and total
cell lysate (lanes 1 and 2) and
immunoprecipitated proteins (lanes 3 and 4) were
analyzed by Western blotting (WB) using anti-T7 tag antibody
(anti-T7, upper panel) or anti-Flag tag antibody (anti-Flag,
lower panel). Note the presence of T7-tagged MUK in the
immunoprecipitate (lane 4, upper panel). C,
T7-tagged Cot was immunoprecipitated using anti-T7 tag antibody
(anti-T7), and total cell lysate (lanes 1 and 2)
and immunoprecipitated proteins (lanes 3 and 4)
were analyzed by Western blotting using anti-Flag tag antibody
(anti-Flag, upper panel) or anti-T7 tag antibody (anti-T7,
lower panel). Note the absence of Flag-tagged MBIP in the
immunoprecipitate (lane 4, upper panel).
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Fig. 3.
The C-terminal part of MBIP is essential for
MUK binding. A, structural features of MBIP and its
deletion mutants used for the binding assay. The region coded by clone
3-3 from the yeast two-hybrid screening is also shown. B,
COS-1 cells were co-transfected with an expression vector for T7-tagged
MUK together with an expression vector for Flag-tagged MBIP or its
deletion mutants, as indicated at the top of each panel.
T7-MUK was immunoprecipitated using anti-T7 tag antibody
(anti-T7), and total cell lysate (lanes 1-6) and
immunoprecipitated proteins (lanes 7-12) were analyzed by
Western blotting using anti-Flag tag antibody (anti-Flag, upper
panel) or anti-T7 tag antibody (anti-T7, lower panel).
Asterisks indicate the position of MBIP and its deletion
mutants. Note the absence of MBIP/1-228 in the immunoprecipitated
fraction (lane 10, upper panel). aa,
amino acids; IP, immunoprecipitate; WB, Western
blot.
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Fig. 4.
The leucine zipper-like motifs of MUK are
essential for MBIP binding. A, structural features of
MUK and its deletion mutants used for the binding assay. The region
used as bait for the yeast two-hybrid screening is also shown.
B, COS-1 cells were co-transfected with an expression vector
for Flag-tagged MBIP together with an expression vector for T7-tagged
MUK or its deletion mutants: lanes 1 and 7,
vector only; lanes 2 and 8, T7-tagged MUK;
lanes 3 and 9, T7-tagged MUK-(1-496);
lanes 4 and 10, T7-tagged MUK-(1-452);
lanes 5 and 11, T7-tagged MUK-(1-413);
lanes 6 and 12, T7-tagged MUK-(132-888).
T7-gagged MUK and its deletion mutants were immunoprecipitated using
anti-T7 tag antibody (anti-T7) and total cell lysate (lanes
1-6), and immunoprecipitated proteins (lanes 7-12)
were analyzed by Western blotting using anti-Flag tag antibody
(anti-Flag, upper panel) or anti-T7 tag antibody (anti-T7,
lower panel). Asterisks indicate the positions of
MUK and its deletion mutants.
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Fig. 5.
Interaction between MBIP and MUK in
situ. COS-1 cells were transfected with an expression
vector for T7-tagged MUK (A and B), Flag-tagged
MBIP (E and F), or both (C and
D). Two days after transfection, the cells were fixed and
protein localization was visualized by immunofluorescence microscopy
using anti-MUK antibody (A, C, and E)
or anti-Flag tag antibody (B, D, and
F). The arrows indicate a cell expressing
moderate amounts of T7-MUK, where significant amounts of Flag-MBIP are
localized in the nucleus.
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Fig. 6.
Inhibition of MUK activity by MBIP.
A, 293T cells grown in a 6-cm dish were transfected with
different combinations of expression vectors for T7-tagged MUK (4 ng),
Cot (3 ng), T7-tagged JNK1 (1 µg), and Flag-tagged MBIP (2 µg or 6 µg), as indicated at the top. The activity (upper
panel) and the expression (middle panel) of T7-tagged
JNK1 were monitored by Western blot analysis using anti-active JNK
antibody (Promega) and anti-T7 tag antibody (Novagen), respectively.
The position of active JNK is indicated as JNK-P. The expression of
Flag-MBIP was also monitored using anti-Flag tag antibody (Sigma)
(lower panel). B, 293T cells were transfected
with different combinations of expression vectors for T7-tagged MUK (50 ng), Cot (40 ng), GST-fused SEK1 (1 µg), and Flag-tagged MBIP (6 µg), as indicated at the top. The activity of SEK1 was
estimated by Western blot analysis using phospho-SEK1
(Thr223) antibody (uppermost panel). The
position of active GST-SEK1 is indicated as SEK1-P. The expression of
each protein was monitored using anti-GST, anti-T7 tag, or anti-Flag
tag antibodies.
View larger version (55K):
[in a new window]
Fig. 7.
The C-terminal part of MBIP is essential for
the inhibition of MUK. 293T cells grown in 6-cm dishes were
co-transfected with expression vectors for T7-tagged MUK (50 ng),
Flag-tagged MBIP, or its deletion mutants (2 µg or 6 µg) together
with an expression vector for GST-SEK1 (1 µg) as indicated at the
top. The activity of GST-SEK1 and the expression of each
protein were estimated as in Fig. 6B.
(Fig. 8D) at any time.
The effect of MBIP was also trivial on the activation of JNK by 10 µg/ml anisomycine (data not shown). These observations suggest the
involvement of MUK in the JNK activation pathway induced by high
osmolality.
View larger version (25K):
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Fig. 8.
MBIP partially inhibits the activation of JNK
induced by hyperosmotic shock. A, 293T cells
transfected with 3 µg of empty vector (lanes 1-5) or
Flag-tagged MBIP expression vector (lanes 6-10) were
exposed to 0.3 M sorbitol for the indicated times. The
activity (upper panel) and expression (lower
panel) of T7-tagged JNK1 co-expressed in these cells were
estimated by Western blot analysis using anti-active JNK antibody
(Promega) and anti-T7 tag antibody, respectively. Asterisks
indicate time points when the inhibitory effect of MBIP is prominent.
B, 293T cells transfected with empty vector or Flag-tagged
MBIP expression vector (1.5 µg or 3.0 µg) were exposed to 0.3 M sorbitol for 15 min. The activity of T7-tagged JNK1
co-expressed was detected as indicated in A and quantified
by densitometry. Average values from three independent experiments are
expressed as a percentage of T7-tagged JNK1 activity in the absence of
MBIP. Bars indicate standard deviations. C, same
as B except that cells were subjected to heat shock
(42 °C) for 15 min. The amount of Flag-tagged MBIP expression vector
used for the transfection was 3.0 µg. D, same as
C except that cells were subjected to TNF (100 ng/ml) for
15 min.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURE
RESULTS
DISCUSSION
REFERENCES
(23),
dynamin (31), -tubulin, and prohibin (32). Even if no effect on
kinase activity is apparent, some of these binding proteins could be
involved in the transportation of MLKs to specific compartments within
cells (23, 31). JIP1/2 binds both SH3-containing and -noncontaining
MLKs, and the binding activates the MLK-JNK/SAPK pathway by
facilitating the interaction with downstream protein kinases,
SEK2/MKK7/JNKK2/SSK4 and JNK/SAPK (29). Most of such scaffold proteins
for mitogen-activated protein kinase pathways have been shown to
activate kinase cascades with the exception of RKIP, which acts as an
inhibitor of the Raf- mitogen-activated protein kinase/extracellular
signal-regulated kinase kinase-extracellular signal-regulated kinase
pathway by binding to and disrupting the interaction of these protein
kinases (33). The possibility that MBIP also acts as a scaffold protein appears quite unlikely, because no binding of MBIP to
SEK2/MKK7/JNKK2/SSK4, SEK1/MKK4/JNKK1/SSK1, or JNK1/SAPK is
obvious.2 Therefore, MBIP may
be defined as an inhibitor of MUK/DLK/ZPK.
ACKNOWLEDGEMENT
FOOTNOTES
ABBREVIATIONS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURE
RESULTS
DISCUSSION
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