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J. Biol. Chem., Vol. 277, Issue 48, 45759-45764, November 29, 2002
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From the Department of Internal Medicine, Division of Hematology,
Washington University School of Medicine,
Saint Louis, Missouri 63110
Received for publication, August 26, 2002, and in revised form, September 23, 2002
The COP9 signalosome (CSN) is a complex of eight
proteins first identified as a repressor of plant photomorphogenesis. A
protein kinase activity associated with the COP9 signalosome has been reported but not identified; we present evidence for inositol 1,3,4-trisphosphate 5/6-kinase (5/6-kinase) as a protein kinase associated with the COP9 signalosome. We have shown that 5/6-kinase exists in a complex with the eight-component COP9 signalosome both when
purified from bovine brain and when transfected into HEK 293 cells.
5/6-kinase phosphorylates the same substrates as those of the COP9
signalosome, including I The most abundant soluble inositol phosphates found in eukaryotic
cells are inositol 1,3,4,5,6-pentakisphosphate
(InsP5)1 and
inositol hexakisphosphate (InsP6) (1-3). In the
InsP6 biosynthetic pathway, inositol 1,3,4-trisphosphate
5/6-kinase (5/6-kinase) is a key regulatory enzyme at the branch point
for the synthesis of InsP4 isomers, InsP5, and
InsP6 (4, 5).2
5/6-kinase utilizes inositol 1,3,4-trisphosphate as a substrate and
generates two distinct products, inositol
1,3,4,6-tetrakisphosphate and inositol
1,3,4,5-tetrakisphosphate, in the ratio of 3:1 (5). In addition,
inositol 3,4,5,6 tetrakisphosphate can be phosphorylated by 5/6-kinase
to produce InsP5 (7). 5/6-kinase, purified from calf brain
or expressed recombinantly from Escherichia coli,
preferentially generates Ins(1,3,4,6)P4 (5), which is a
precursor for the synthesis of InsP5 (6). The enzyme is
conserved from plants to humans and is found even in Entamoeba
histolytica (8, 9).
During the purification of 5/6-kinase from calf brain, a large complex
of proteins was noted to co-purify with 5/6-kinase (5); this complex
was identified as the COP9 signalosome (CSN) by amino-terminal sequence
analysis of the largest subunit (CSN1) and Western blot analysis of the
fifth subunit (CSN5) (10). The COP9 signalosome is composed of eight
distinct proteins (CSN1 to CSN8) and was first identified in plants
defective for photomorphogenesis (11). The COP9 mutants develop a
light-induced phenotype when grown in the dark; the molecular defect
appears to result from decreased degradation of HY5, a positive
regulator of light signaling (12, 13). The largest subunit of the COP9
signalosome (CSN1), also known as G-protein suppressor 1 (GPS1), was
first identified in an extragenic suppressor screen in
Saccharomyces cerevisiae for its ability to rescue mutants
defective for the G Two known functions associated with the COP9 signalosome are
deneddylation and phosphorylation (14). Nedd8 is a member of the
ubiquitin family that may modulate the ubiquitination machinery (15,
16); deneddylation has been postulated to control ubiquitin E3 ligase
functions. The COP9 signalosome also exhibits a serine/threonine protein kinase activity toward c-Jun, I We now report that 5/6-kinase associates with the COP9 signalosome. A
purified fraction of bovine COP9 signalosome and 5/6-kinase co-migrate
upon gel filtration. Of the eight subunits of the complex, only CSN1
co-immunoprecipitates with Myc-tagged 5/6-kinase. Consistent with the
reported activity of the protein kinase associated with the COP9
signalosome, 5/6-kinase phosphorylates I Reagents--
All chemicals and reagents were obtained from
Sigma unless otherwise specified. Goat polyclonal antibody against
human CSN5, mouse monoclonal antibody against human DNA Constructs--
Myc-tagged human 5/6-kinase
containing six repeats of the Myc epitope at the amino terminus was
generated as follows. Full-length 5/6-kinase was excised from
pBAKPAK6-5/6-kinase (10) with EcoRI and EcoRV
and inserted into pCS-MT2 vector (kindly provided by Dr. Greg Longmore)
containing the Myc6 epitope with EcoRI and SmaI. A carboxyl-terminally tagged
His6-5/6-kinase was constructed in pTrcHis2B (Invitrogen)
by excising full-length human 5/6-kinase with EcoRI from
pIND-5/6kinase (10). A human expressed sequence tag clone containing
CSN1, GenBankTM accession number BG831861 (American Type
Culture Collection) was used as a template for amplifying the CSN1 open
reading frame. CSN1 was subcloned into pCMV5-HA (kindly provided by Dr.
Yasuhiro Mochizuki). Each DNA construct was sequenced using ABI Prism
Big Dye Terminator version 3.0 cycle sequencing reagents (PerkinElmer Life Sciences).
Preparation of Enzymes and Protein Kinase
Substrates--
Recombinant human GST-I Kinase Assays--
In vitro protein kinase assays
using recombinant 5/6-kinase purified from Sf21 cells were
performed as described (10). Briefly, 5 ng of enzyme was added to 1 µg of substrate in the presence of 10 µCi
[ Gel Filtration Chromatography--
A fraction of the preparation
of bovine brain 5/6-kinase (5) containing both the signalosome and
5/6-kinase was used for gel filtration. A 600 × 7.5 mm Bio-Sil
SEC-250 high performance liquid chromatography gel filtration column
(Bio-Rad) equilibrated with Buffer A (20 mM HEPES, pH 7.6, 50 mM NaCl, 10% (v/v) glycerol, 1 mM
dithiothreitol, and 1 mM ATP) was run at 0.5 ml/min, and 0.5-ml fractions were collected. The molecular mass standards thyroglobulin (700 kDa), IgG (150 kDa), myoglobin (50 kDa), and cytochrome c (13.4 kDa) were applied to the Bio-Sil column
prior to each sample run. Twenty µg of COP9 signalosome and 1 mg of carrier cytochrome c were applied to the Bio-Sil high
performance liquid chromatography column. One-fifth of each fraction
was separated by SDS-PAGE, and Western blot analysis was performed
using the indicated antibodies. A rabbit polyclonal antibody raised
against a peptide consisting of amino acids 124-311 of human
5/6-kinase was used for detecting bovine 5/6-kinase (10). Rabbit
polyclonal antibody used to detect His-tagged human 5/6-kinase was
generated using a peptide corresponding to the carboxyl-terminal 14 amino acids (401-414) (QHCVASLATKASSQ).
Density Gradient Centrifugation--
HEK 293 cells (1.5 × 107) were lysed in Buffer B (20 mM HEPES, pH
7.6, 10% (v/v) glycerol, 140 mM NaCl, 1 mM
dithiothreitol, 0.1% Nonidet P-40, 1 µM microcystin, and
CompleteTM protease inhibitor tablets from Roche Molecular
Biochemicals) and subjected to density gradient centrifugation
as described (18). Briefly, total cell lysates were separated on
10-40% glycerol gradients, and 2-ml fractions were collected. Eluted
proteins were precipitated by trichloroacetic acid, resolved by
SDS-PAGE, and subjected to Western blot analysis using antibodies to
CSN1 and CSN8.
Transfection and Immunoprecipitation--
HeLa or HEK 293 cells
(2 × 105 cells) were plated on 60-mm dishes 24 h
prior to transfection. LipofectAMINE 2000 (Invitrogen) was used
for each transfection according to the manufacturer's instructions.
Cells were harvested 48 h after transfection, washed with
phosphate-buffered saline, pH 7.4, followed by lysis in Buffer B and
brief sonication. For immunoprecipitation, total lysate was first
precleared using protein A-agarose, and 300 µg of lysate was
incubated for 4 h at 4 °C with 10 µl of anti-Myc
antibody-agarose (Santa Cruz Biotechnology) or anti-CSN1
antibody-protein A-agarose (Sigma). Agarose beads were washed four
times with Buffer C (10 mM sodium phosphate, pH 7.4, 0.1%
Nonidet P-40, and 250 mM NaCl), boiled in SDS sample
buffer, and the proteins were separated by SDS-PAGE for Western blot analysis.
Phospho-amino Acid Analysis--
HEK 293 cells stably expressing
5/6-kinase were grown to confluence in a 60-mm plate and washed twice
with phosphate-free media. Orthophosphate 32P (1 mCi) in
phosphate-free and serum-free media was added to cells for 4 h
before harvesting in Buffer B. Anti-5/6-kinase antibody (2 µg) was
added to cell lysates and incubated overnight at 4 °C followed by 40 µl of a 50% suspension of Protein A-agarose for 1 h. The
immunoprecipitate was washed with 25 mM Tris, pH 7.6, containing 300 mM NaCl and separated by SDS-PAGE, and the labeled protein was detected by autoradiography. The 5/6-kinase was
excised from the gel, electroeluted, and prepared for phospho-amino acid analysis as described previously (10).
Bovine 5/6-Kinase Co-migrates with COP9 Signalosome upon Gel
Filtration--
We previously demonstrated that two subunits of the
COP9 signalosome, CSN1 and CSN5, co-purify with calf-brain 5/6-kinase (10). We now show that all eight subunits of the COP9 signalosome and
5/6-kinase were readily detected in the complex (Fig.
1A). A Coomassie Blue stain of
this fraction demonstrated that the COP9 signalosome subunits are the
major proteins present (10).
We sought to determine whether the COP9 signalosome subunits existed as
an intact complex by using gel filtration to separate any dissociated
subunits from the complex. Free His-5/6-kinase eluted in fraction 35 with an apparent molecular mass of 50 kDa. All eight subunits of the
COP9 signalosome were observed to elute together in fractions 17-23
when stained with Coomassie Blue (data not shown). Western blot
analysis using antibodies against CSN1 and CSN8 showed that the elution
position of the COP9 signalosome corresponds to an apparent molecular
mass of 600 kDa (Fig. 1B), similar to the plant COP9
signalosome (18). Free subunits of the COP9 signalosome were not
detected in the gel filtration experiment. 5/6-kinase was also detected
in fraction 19 (Fig. 1B). Therefore, purified bovine COP9
signalosome and 5/6-kinase co-migrated on a gel filtration.
5/6-Kinase Interacts with Endogenous CSN1--
We
sought to determine which subunit(s) of the COP9 signalosome interacts
with 5/6-kinase by using HEK 293 cells transiently transfected with
Myc-tagged human 5/6-kinase. Endogenous CSN1 was detected bound to the
myc-5/6-kinase agarose as shown (Fig. 2A), whereas protein A-agarose
alone did not bind CSN1. Furthermore, neither CSN8 nor CSN5 was
detected bound to Myc-5/6-kinase, indicating that 5/6-kinase
preferentially interacted with CSN1.
The interaction between 5/6-kinase and CSN1 was confirmed using an
anti-CSN1 antibody for the immunoprecipitation in HeLa cells. Anti-CSN1
antibody was added to the lysates of HeLa cells, transiently
transfected with a plasmid containing 5/6-kinase, and followed by the
addition of protein A-agarose beads. Myc-tagged-5/6-kinase was detected
bound to CSN1 as shown in Fig. 2B; 10% of the
Myc-immunoprecipitate and 50% of the CSN1-immunoprecipitate were
loaded on the gel. All eight subunits of the COP9 signalosome were
bound to anti-CSN1 antibody-agarose as determined by SDS-PAGE followed
by Coomassie Blue staining (data not shown). Protein A agarose
alone did not bind any Myc-tagged 5/6-kinase (Fig. 2B). In
addition, anti-Myc-agarose also failed to bind any 5/6-kinase in
untransfected HeLa cells (data not shown). These results show that, in
HeLa cells, Myc-tagged human 5/6-kinase can interact with endogenous
CSN1 within the COP9 signalosome.
Because endogenous CSN1 can co-immunoprecipitate 5/6-kinase, we
attempted to confirm the interaction between CSN1 and 5/6-kinase by
co-transfection of HeLa cells with plasmids containing HA-tagged CSN1
and Myc-tagged 5/6-kinase. Immunoprecipitation using HeLa cell lysates
indicates that anti-HA monoclonal antibody-agarose pulled down CSN1
(Fig. 2C). Western blot analysis using anti-CSN8 antibody
demonstrated that another COP9 signalosome subunit was also isolated
using the anti-HA antibody-agarose. Because CSN8 is found predominantly
with the signalosome, the isolation of CSN8 indicates that the entire
COP9 signalosome was isolated with HA-tagged CSN1. Anti-Myc antibody
detected 5/6-kinase in the immune complex, indicating that 5/6-kinase
interacts with CSN1. A discrepancy was noted in that, whereas CSN1 was
able to pull down 5/6-kinase and the entire complex, 5/6-kinase
apparently only pulled down CSN1 but not CSN5 and CSN8. To address this
question, a glycerol gradient was performed on HEK 293 cell lysates.
CSN1 was also detected in the complex (Fig. 2D) as well as
free subunits, but CSN8 was found predominantly in the complex.
Although in plants CSN1 has been reported to exist only in the complex,
CSN1 expressed in NIH 3T3 has been shown to exist in the complex as
well as free subunits (22). Therefore, it is possible for 5/6-kinase to
interact with free CSN1 as well as with that in the complex.
The 5/6-Kinase Protein Kinase Profile Is Similar to That of the
COP9 Complex-associated Kinase--
I
To demonstrate that 5/6-kinase expressed in mammalian cells behaves
similarly to the Sf21 cell-expressed protein, we transiently transfected human 5/6-kinase in HEK 293 cells and assayed for kinase
activity toward various substrates. Lysates from transfected HEK 293 cells were immunoprecipitated using anti-Myc antibody-agarose and
subjected to inositol kinase (data not shown) and protein kinase
assays. The protein kinase activity of immunoprecipitated 5/6-kinase
was assayed toward a panel of substrates (Fig. 3B). GST·I Curcumin Can Inhibit Both 5/6-Kinase Inositol and
Protein Kinase Activity--
Curcumin has been reported to inhibit the
COP9 signalosome protein kinase activity (19). To test whether curcumin
inhibits 5/6-kinase, the protein kinase assays were repeated on c-Jun, p53, and I Overexpression of 5/6-Kinase Increases CSN5
Expression--
Overexpression of CSN2 increases de novo
COP9 signalosome complex formation (17); therefore, we tested whether
5/6-kinase overexpression would affect the levels of any of the
proteins in the complex. Stable HEK 293 cell lines expressing
5/6-kinase or vector were generated (10), and the levels of endogenous COP9 signalosome subunits were measured by Western blotting. Of the
eight subunits tested, only the level of CSN5 was shown to have
increased 1.48 + 0.1-fold (average of seven experiments) in cells that
overexpress 5/6-kinase (Fig. 6). An
increase in the levels of CSN5 was observed in stable cell lines
overexpressing 5/6-kinase in the absence of induction with
tetracycline. In these cells there is a leak of 5/6-kinase expression
corresponding to levels 3-fold over that of endogenous enzyme as
measured by inositol kinase activity (data not shown). These results
indicate that 5/6-kinase does not affect the levels of COP9 signalosome
in cells but does affect the levels of CSN5.
Overexpression of CSN1 Inhibits 5/6-Kinase Activity--
We sought
to determine the effect of CSN1 binding to 5/6-kinase by co-expression
of HA-CSN1 and Myc-5/6-kinase in HeLa cells. 5/6-kinase activity was
measured from cells transfected with
plasmids containing either vector
Myc-5/6-kinase, HA-CSN1, or both. As shown in Fig. 7A, the
first-order rate constant3
for 5/6-kinase activity (k The COP9 signalosome complex consists of eight proteins that are
highly conserved from plants to mammals (11). We previously demonstrated that this signalosome co-purifies with 5/6-kinase, a key
enzyme in the synthesis of the higher phosphorylated forms of inositol
(2). In this report, we confirm that 5/6-kinase associates with the
COP9 signalosome using several criteria. 5/6-kinase co-elutes with the
COP9 signalosome upon gel filtration, whereas in the absence of the
complex it behaves as a monomer. In addition, of the eight subunits
present in the complex, only CSN1 coimmunoprecipitates with
5/6-kinase.
The COP9 signalosome has been shown to associate with the 26 S
ubiquitin proteasome and may regulate protein stability (25). The
structural organization of the COP9 signalosome, as revealed by
electron microscopy, resembles the lid of the 19 S regulatory particle
of the 26 S proteasome (26, 27). The COP9 signalosome has been shown to
interact with ubiquitin E3-ligase and exhibit deneddylase activity (28,
30). A reported function of the COP9 signalosome is an associated
protein kinase activity, which has not been identified. Purified COP9
signalosome was reported to exhibit protein kinase activity toward
c-Jun, I We reported previously that 5/6-kinase can phosphorylate c-Jun and
ATF-2 (10). We show here that 5/6-kinase can also phosphorylate I The protein kinase activity of the COP9 signalosome has been reported
to be inhibited by curcumin (19). Studies using curcumin to inhibit the
kinase activity reveal differential regulation of substrate stability.
In the presence of curcumin, p53 levels were enhanced, whereas those of
c-Jun were suppressed (17, 31), suggesting that phosphorylation by the
COP9-associated kinase may affect the stability of these transcription
factors. These studies, using curcumin as an inhibitor of the COP9
signalosome-associated kinase, led to the hypothesis that the
phosphorylation activity of the associated kinase may also modulate the
association between the COP9 complex and the ubiquitin machinery (25).
We show here that both the inositol and protein kinase activities of
5/6-kinase are inhibited by curcumin, consistent with the reported
inhibition of the COP9 signalosome-associated kinase.
Overexpression of the subunits of the COP9 signalosome has been
reported to alter the composition of the signalosome. Transient transfection of CSN2 increases the level of the complex, whereas CSN5
overexpression does not change the level of signalosome subunits (17).
We show that 5/6-kinase expression in HEK 293 cells increases the
levels of CSN5, which has been reported to enhance AP-1 activation and
mediate the nuclear export and degradation of the
cyclin-dependent kinase inhibitor p27 (p27Kip1)
(6). Because CSN5 is known to exist in a complex-bound and a
complex-free form (23), the increase in CSN5 is likely restricted to
the complex-free CSN5. 5/6-kinase induction of CSN5 offers a possible
regulatory mechanism for CSN5 activity.
In addition to the protein kinase activity of 5/6-kinase, we have shown
that 5/6-kinase can interact with the COP9 signalosome. Bovine brain
5/6-kinase was found to be present in the purified COP9 signalosome,
and immunoprecipitation studies showed that CSN1 can interact with
5/6-kinase (Figs. 1 and 2). Because the carboxyl-terminal domain of
CSN1 has been shown to be sufficient for incorporating CSN1 into the
COP9 signalosome (32), it is likely that 5/6-kinase interacts with the
amino-terminal domain of CSN1, which has been shown to inhibit c-Fos
expression and suppress activation of an AP-1 promoter (22). The
association of 5/6-kinase with CSN1 inhibits 5/6-kinase inositol kinase
activity. Co-expression of 5/6-kinase and CSN1 resulted in a
significant inhibition of 5/6-kinase activity, suggesting that a large
portion of 5/6-kinase is associated with CSN1. These results also
provide evidence for a link between inositol phosphate metabolism and the COP9 signalosome.
The COP9 signalosome has been proposed to act as a scaffold complex for
bringing different molecules together (25, 29). Using yeast two-hybrid
screens and electron microscopy, CSN1 is thought to position next to
CSN5 (24). Because 5/6-kinase associates with CSN1, and CSN5 recruits
p53, it is conceivable that one subunit of the complex brings different
substrates to 5/6-kinase for phosphorylation. In addition, CSN1 can
inhibit 5/6-kinase activity, suggesting that the interaction may alter
5/6-kinase enzyme activity under some conditions.
We thank Dr. Shao-chun Chang, Dr. Marina
Kisseleva, John Verbsky, and Heidi Rayala for helpful and critical
reading of the manuscript.
*
This research was supported by National Institutes of Health
Grants RO1-HL55672 and RO1-HL16634 and Training Grant H107088.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.
Published, JBC Papers in Press, September 24, 2002, DOI 10.1074/jbc.M208709200
2
Chang, S. C., Miller, A. L., Feng, Y., Wente, S. R., and Majerus, P. W. (September 9, 2002) J. Biol.
Chem. DOI 10.1074/jbc.M206134200.
3
S/So = e The abbreviations used are:
InsP5, 1,3,4,5,6-pentakisphosphate;
InsP6, inositol hexakisphosphate;
5/6-kinase, inositol 1,3,4-trisphosphate
5/6-kinase;
CSN, COP9 signalosome;
JNK, c-Jun amino-terminal kinase;
GST, glutathione S-transferase;
FH-5/6-kinase, FLAG-His-5/6-kinase.
Inositol 1,3,4-Trisphosphate 5/6-Kinase Associates with the
COP9 Signalosome by Binding to CSN1*
ABSTRACT
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
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B
, p53, and c-Jun but fails to
phosphorylate several other substrates, including c-Jun 1-79, which
are not substrates for the COP9-associated kinase. Both the COP9
signalosome- associated kinase and 5/6-kinase are inhibited by
curcumin. The association of 5/6-kinase with the COP9 signalosome is
through an interaction with CSN1, which immunoprecipitates with
5/6-kinase. In addition, the inositol kinase activity of 5/6-kinase is
inhibited when in a complex with CSN1. We propose that 5/6-kinase is
the previously described COP9 signalosome-associated kinase.
INTRODUCTION
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
subunit (20). Overexpression of full-length CSN1
inhibits c-Jun N-terminal kinase (JNK1) activity as well as
Jun-dependent promoter activation (21). The
carboxyl-terminal region of CSN1 has been shown to be responsible for
incorporating CSN1 into the CSN complex, whereas the amino-terminal
domain has been shown to suppress Fos transcription activation
(22).
B, p105, and p53 (17-19); however, when expressed alone, none of the eight CSN subunits exhibits
protein kinase activity, and the enzyme responsible for this kinase
activity has not been identified. Because no intrinsic kinase activity
was found with the complex, the unknown enzyme was referred to as a
COP9 signalosome-associated kinase. We have previously shown that
5/6-kinase purified from bovine brain and expressed recombinantly in
Sf21 cells exhibit in vitro protein kinase activity
toward c-Jun and ATF-2 (10). Because the COP9 signalosome was found to
co-purify with 5/6-kinase, we postulated that 5/6-kinase may be the
enzyme responsible for the protein kinase activity associated with the
COP9 signalosome (10).
B, c-Jun, and p53 but not
c-Jun 1-79 or NF-B p52 subunit. Curcumin, a potent anti-tumor
agent, was shown to inhibit the COP9-associated kinase activity
in vitro and in vivo (19). We show that curcumin
inhibits both 5/6-kinase protein and inositol kinase activities. In HEK 293 cells overexpressing 5/6-kinase, the level of CSN5/Jab1 increases, suggesting that 5/6-kinase can modulate the levels of at least one
component of the COP9 signalosome. In addition, overexpression of CSN1
inhibited 5/6-kinase activity, suggesting that interaction with the
COP9 signalosome can alter this activity.
MATERIALS AND METHODS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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-tubulin, rabbit
polyclonal antibodies against human p53 and IB, purified
GST·p53, GST·c-Jun 1-79, JNK1, and NFB p52 were obtained
from Santa Cruz Biotechnology. Rabbit polyclonal antibodies against
CSN1 to CSN8 were obtained from Affinity Research Products (Devon,
United Kingdom). Recombinant His-tagged, full-length c-Jun was
obtained from Promega. Curcumin was obtained from Sigma and dissolved
at 0.2% in Me2SO. Restriction enzymes were
purchased from New England Biolabs.
B (a gift from Dr.
Yunfeng Feng) was transformed into E. coli BL21
(Stratagene). After
isopropyl-1-thio-
-D-galactopyranoside (1 mM)
induction for 4 h, cells were harvested, and recombinant protein
was purified using glutathione-agarose (Amersham Biosciences). Amino-terminus-tagged human 5/6-kinase with FLAG and His6
epitopes was expressed in Sf21 cells as reported previously
(10). The recombinant protein was purified on a TALON resin column
(Clontech) followed by an M2 anti-FLAG monoclonal
antibody column (Sigma), according to the manufacturer's instructions.
A His6-tagged 5/6-kinase construct was transformed into
BL21CodonPlus(DE3)-RIL cells (Stratagene) and inoculated in 2× YT
medium (170 mM NaCl, 10 g of yeast extract, and 16 g/liter
tryptone) overnight. Cells were harvested and incubated with 25 mM Tris, pH 7.4, 150 mM NaCl, 1 mM
-mercaptoethanol, 1 mg lysozyme/ml, and 1 mM
phenylmethylsulfonyl fluoride for 30 min at 4 °C. The lysate was
sonicated, and the supernatant was purified on a 1-ml TALON resin column.
-32P]ATP (ICN Pharmaceuticals) in kinase buffer (20 mM Tris, pH 7.6, 1 mM -mercaptoethanol, 1 mM MgCl2, and 10% glycerol). Ten-microliter reactions were incubated at 37 °C for 20 min and terminated by the
addition of 4× SDS sample buffer. The protein samples were separated
by SDS-PAGE and transferred to polyvinylidene difluoride (Millipore)
membranes for autoradiography. Curcumin inhibition of 5/6-kinase
protein kinase activity was performed by preincubation of purified
enzyme with curcumin (50 µM) for 10 min at 37 °C
before the addition of substrates. Inositol 1,3,4-trisphosphate
5/6-kinase assays were performed as described (5). Curcumin was
preincubated with purified 5/6-kinase for 10 min at 37 °C before
assaying for inositol kinase activity.
RESULTS
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ABSTRACT
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MATERIALS AND METHODS
RESULTS
DISCUSSION
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Fig. 1.
5/6-Kinase associates with the COP9
signalosome. A, purified COP9 signalosome and
5/6-kinase were separately analyzed by Western blot analysis
(WB) using antibodies to each subunit of the signalosome and
5/6-kinase (shown above each panel). B, bovine
brain fraction containing purified 5/6-kinase and COP9 signalosome were
applied to a Bio-Sil column. Each fraction was analyzed by Western
blotting using antibodies against CSN1, CSN8, or 5/6-kinase. His-tagged
5/6-kinase was applied to the column to indicate the position of
5/6-kinase alone.
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Fig. 2.
5/6-Kinase interacts with CSN1.
A, HEK 293 cells were transfected with a plasmid containing
Myc-5/6-kinase, and cell lysates were immunoprecipitated using anti-Myc
antibody-agarose (Myc-IP) or protein A-agarose
(Prot.A). Western blot analysis was performed using
antibodies against CSN1, CSN5, CSN8, or 5/6-kinase as indicated to the
left of the panels. B, HeLa cells were
transfected with a plasmid containing Myc-5/6-kinase, and cell lysates
were immunoprecipitated using protein A-agarose, anti-Myc
antibody-agarose, or anti-CSN1 antibodies. Myc-5/6-kinase was
visualized using anti-c-Myc antibody for Western blot analysis.
C, HA-CSN1 and Myc-5/6-kinase plasmids were co-transfected
into HeLa cells, and anti-HA antibody-agarose was used for
immunoprecipitation. Western blot analysis was performed using
antibodies to CSN1, 5/6-kinase, or CSN8 (shown on the left
side of the panel). D, HEK 293 cell lysates
were separated by glycerol gradient, and fractions 7-19 were subjected
to Western blot analysis using antibodies against CSN1 and CSN8 (shown
on the left of the panel). Results shown are
representative of three independent experiments.
B, c-Jun, and p53 have been
identified as substrates for the COP9 signalosome-associated kinase
(18, 19). FLAG-His-5/6-kinase (FH-5/6-kinase) expressed in Sf21
cells was purified to homogeneity as described previously (10). In an
in vitro protein kinase assay, purified FH-5/6-kinase was
autophosphorylated in the presence of -32P-labeled ATP.
In addition, FH-5/6-kinase also phosphorylated full-length His-tagged
c-Jun, GST-tagged IB, and GST-tagged p53 (Fig.
3A), which is consistent with
the substrate profile reported for the COP9 signalosome-associated
kinase (18). IB was the best in vitro substrate for
baculovirus-derived FH-5/6-kinase, followed by p53, c-Jun, and ATF2
(data not shown). GST·c-Jun 1-79, a c-Jun amino-terminal fragment
that is phosphorylated by JNK but not by the COP9 associated kinase
(18), was not a substrate for 5/6-kinase. In addition, neither JNK1
(Fig. 3A) nor NF-B p52 subunit (data not shown) was
phosphorylated by 5/6-kinase.
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Fig. 3.
In vitro protein kinase activity
of 5/6-kinase. A, in vitro protein kinase
assays with I B, c-Jun, c-Jun 1-79, p53, and JNK1 in the absence
or presence of purified 5/6-kinase. B, in vitro
protein kinase assays with IB, c-Jun, c-Jun 1-79, and p53 in the
presence of Myc-5/6-kinase immunoprecipitates from HEK 293 cells
expressing Myc-5/6-kinase. Samples were resolved by SDS-PAGE and
exposed for autoradiography. Phosphorylated proteins are indicated on
the left of the panel. Representative of four
independent experiments. Nonspecific bands are denoted by an
asterisk (*).
B is the best substrate, followed by GST·p53 and
His·c-Jun. Thus, Myc-tagged 5/6-kinase expressed in HEK 293 cells
shows similar substrate specificity to that observed for 5/6-kinase
derived from Sf21 cells. 5/6-kinase purified from Sf21
cells was prominently autophosphorylated (Fig. 3A), whereas
that immunoprecipitated from HEK 293 cells was autophosphorylated to a
much lesser extent (Fig. 3B). To address this
discrepancy, HEK 293 cells stably expressing 5/6-kinase were labeled
with [32P]phosphate for 4 h, cells were
harvested, and 5/6-kinase was immunoprecipitated as described under
"Materials and Methods" and subjected to SDS-PAGE followed by
autoradiography (Fig. 4A). Phospho-amino acid analysis was performed (Fig. 4B) showing
that 5/6-kinase expressed in HEK 293 cells is indeed phosphorylated on
serine and tyrosine residues. It is therefore likely that the 5/6-kinase immunoprecipitated from HEK 293 cells existed in a more
phosphorylated state than baculovirus-derived 5/6-kinase.
View larger version (38K):
[in a new window]
Fig. 4.
Phospho-amino acid analysis of 5/6-kinase
immunoprecipitated from HEK 293 cells. A, in
vivo [32P]phosphate labeling and immunoprecipitation
of 5/6-kinase. 5/6-kinase was immunoprecipitated from
[32P]-phosphate-labeled HEK 293 cells overexpressing
5/6-kinase by using affinity-purified antibody against 5/6-kinase (5 or
10 µl). Bound 5/6-kinase was resolved by SDS-PAGE and exposed for
autoradiography. B, immunoprecipitated 5/6-kinase labeled
with 32P was analyzed, and the phospho-amino acids were
separated by thin layer chromatography and visualized by
autoradiography. p-Ser,
p-Thr, and p-Tyr show the
position of phosphoserine, phosphothreonine, and phosphotyrosine,
respectively.
B in the presence of 50 µM curcumin.
5/6-kinase treated with curcumin exhibited 75% inhibition of activity
toward all substrates and also showed a reduction in
autophosphorylation (Fig. 5A
compared with Fig. 3A). Nonspecific bands on the
autoradiograph such as the ones present in the lane containing c-Jun
1-79 were not affected by the presence of curcumin. As shown in Fig.
5B, curcumin inhibited 5/6-kinase protein kinase activity in
a dose-dependent manner (Fig. 5C is a graph of
the relative intensity of IB in Fig. 5B). The addition
of 50 µM curcumin to 5/6-kinase inhibited inositol kinase
activity by 25% (not shown).
View larger version (33K):
[in a new window]
Fig. 5.
Curcumin inhibition of 5/6-kinase protein
kinase activity. A, autoradiography of in
vitro protein kinase assay using purified 5/6-kinase in the
presence of curcumin. Phosphorylated substrates are indicated on the
left side of the panel. B,
autoradiography of in vitro 5/6-kinase protein kinase assays
with increasing concentrations of I B in the presence of
Me2SO (DMSO) control, 50 µM
curcumin, or 100 µM curcumin. C, the relative
intensity of each band from panel B, as measured
by densitometry, is plotted against the concentration of IB.
Nonspecific bands are denoted by an asterisk (*). Results
shown are representative of three independent experiments.
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[in a new window]
Fig. 6.
Overexpression of 5/6-kinase increases the
levels of CSN5. Stable HEK 293 cell lines expressing 5/6-kinase or
vector control were induced with tetracycline for the indicated number
of hours (shown above). Total cell lysates (30 µg) were used for
Western blot analysis using an anti-CSN5 antibody. The -fold increase
of CSN5, as measured by densitometry, is indicated below the 5/6-kinase
panel.
1) is ~1200
min1 mg1. In the presence of CSN1, the rate
constant drops to ~300 min1 mg1. The
transfection of plasmids containing vector (k1 = 8 min1 mg1) or HA-CSN1
(k1 = 9 min1 mg1)
alone had negligible effect on 5/6-kinase. The level of expression of
Myc-tagged 5/6-kinase and HA-tagged CSN1 in co-transfected cells is
equivalent to the cells expressing only 5/6-kinase or CSN1 as shown in
Fig. 7B.
View larger version (20K):
[in a new window]
Fig. 7.
Overexpression of CSN1 inhibits 5/6-kinase
activity. A, 5/6-kinase activity was measured from
lysates of HeLa cells transiently transfected with vector HA-CSN1,
Myc-5/6-kinase, or both. Each sample represents three separate
transfixions. B, each of the four samples was analyzed by
Western blotting using antibodies against 5/6-kinase, CSN1, and
-tubulin.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
B, p105 (NF-B precursor), and p53 (17-19). However,
none of the eight subunits exhibited protein kinase activity when
expressed alone; therefore, the kinase activity has been attributed to
a COP9-associated protein kinase (18).
B and p53, both known substrates for the COP9
signalosome-associated kinase. In addition, 5/6-kinase did not
phosphorylate the p52 subunit of NF-B or an amino-terminal peptide
of c-Jun, proteins that are not substrates for the COP9 associated
kinase (17, 18). c-Jun phosphorylation by the COP9 signalosome appeared to be independent of the JNK pathway, and the phosphorylation sites on
c-Jun were mapped to the amino-terminal residues serine 63 and serine
73 (17, 18). Because c-Jun lacking its carboxyl-terminal (c-Jun 1-79)
was not phosphorylated by the purified COP9 signalosome, Seeger
et al. (18) proposed that the putative kinase only
recognizes c-Jun dimers, which require the carboxyl-terminal region for
dimerization. 5/6-kinase also exhibited the same specificity, being
active only toward full-length c-Jun but not toward c-Jun 1-79. These
results implicate 5/6-kinase as a candidate for the protein kinase
activity reported to be associated with the COP9 signalosome.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: Dept. of Internal
Medicine, 660 S. Euclid Ave., Campus Box 8125, St. Louis, MO 63110. Tel.: 314-362-8801; Fax: 314-362-8826; E-mail:
phil@im.wustl.edu.
kt,
where k1 is the first order rate constant.
ABBREVIATIONS
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TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES
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