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Molecular and Cellular Biology, January 1999, p. 461-470, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Functional Role for Protein Kinase C
as a
Regulator of Stress-Activated Protein Kinase Activation and Monocytic
Differentiation of Myeloid Leukemia Cells
Masao
Kaneki,
Surender
Kharbanda,
Pramod
Pandey,
Kiyotsugu
Yoshida,
Mutsuhiro
Takekawa,
Jiing-Ren
Liou,
Richard
Stone, and
Donald
Kufe*
Dana-Farber Cancer Institute, Harvard Medical
School, Boston, Massachusetts 02115
Received 11 December 1997/Returned for modification 21 January
1998/Accepted 1 October 1998
 |
ABSTRACT |
Human myeloid leukemia cells respond to
12-O-tetradecanoylphorbol-13-acetate (TPA) and other
activators of protein kinase C (PKC) with induction of monocytic
differentiation. The present studies demonstrated that treatment of
U-937 and HL-60 myeloid leukemia cells with TPA,
phorbol-12,13-dibutyrate, or bryostatin 1 was associated with the
induction of stress-activated protein kinase (SAPK). In contrast,
TPA-resistant TUR and HL-525 cell variants deficient in PKC
failed
to respond to activators of PKC with the induction of SAPK. A direct
role for PKC in TPA-induced SAPK activity in TUR and HL-525 cells
that stably express PKC was confirmed. We showed that TPA induced
the association of PKC with MEK kinase 1 (MEKK-1), an upstream
effector of the SAPK/ERK kinase 1 (SEK1)
SAPK cascade. The results
also demonstrated that PKC phosphorylated and activated MEKK-1 in
vitro. The functional role of MEKK-1 in TPA-induced SAPK activity was
further supported by the demonstration that the expression of a
dominant negative MEKK-1 mutant abrogated this response. These findings
indicate that PKC activation is necessary for activation of the
MEKK-1SEK1SAPK cascade in the TPA response of myeloid leukemia cells.
| |
INTRODUCTION |
The human U-937 and HL-60 myeloid
leukemia cell lines proliferate autonomously in the absence of
exogenous hematopoietic growth factors (6, 52). These cells,
however, have retained the capacity to respond to inducers of
differentiation with growth arrest and the appearance of a mature
phenotype. In this context, treatment of U-937 and HL-60 cells with
agents that activate protein kinase C (PKC), including
12-O-tetradecanoylphorbol-13-acetate (TPA) and
phorbol-12,13-dibutyrate (PDBu), induces differentiation along the
monocytic lineage. Bryostatin 1, a macrocyclic lactone, also activates
PKC and induces monocytic differentiation of myeloid leukemia cells
(51). While these findings have indicated that factor-independent growth of myeloid leukemia cells is reversible by
activation of PKC-mediated signaling, little is known about the
downstream effectors responsible for induction of the differentiated monocytic phenotype.
PKC is a family of at least 12 serine/threonine protein kinase isoforms
which are involved in diverse cellular responses (24, 43).
The 
, , 
, 
, 
, µ, 
, 
, and 
forms of PKC are
responsive to phorbol esters. The available evidence suggests that
PKC is involved in TPA-induced differentiation of myeloid leukemia
cells. Accordingly, TPA-resistant HL-60 cell variants are deficient in PKC expression (37, 42, 56, 57). Down-regulation of
PKC expression (19) and functional defects in PKC
(31) have also been found for TPA-resistant U-937 cell
variants. In addition, defective translocation of PKC from the
cytosol to the cell membrane has been shown for TPA-resistant variants
of both U-937 and HL-60 cells (19, 64). Importantly,
increased expression of PKC resulting from treatment with retinoic
acid (64) or from transfection of the PKC gene
(56) restores TPA inducibility of growth arrest and a
differentiated monocytic phenotype. PKC is expressed as two
isoforms, I and II, as a result of an alternative splicing mechanism that produces a PKCI protein which is truncated by 50 amino acids at the carboxy terminus (32); the longer
PKCII isoform is expressed in U-937 and HL-60 cells (22,
56).
Treatment of myeloid leukemia cells with TPA is associated with changes
in the expression of certain early- and late-response genes. TPA
down-regulates c-myc transcripts in HL-60 cells
(47) and induces expression of the c-jun gene
(49, 54, 61). Similar findings have been obtained with other
inducers of monocytic differentiation (49), including
okadaic acid, an inhibitor of phosphoserine/threonine protein
phosphatases 1 and 2A (1, 25). Activation of Jun/AP-1 contributes to induction of c-jun transcription
(2) and monocytic differentiation (54). The early
growth response 1 (EGR-1) gene is also activated during TPA- and
okadaic acid-induced monocytic differentiation (27, 29) and
is necessary for the appearance of the monocytic phenotype
(41). Thus, the induction of early response genes and
thereby upstream signals involved in their transcriptional activation
may be directly linked to the reversal of the leukemia phenotype.
Members of the mitogen-activated protein kinase (MAPK) superfamily are
involved in diverse cellular processes, including the induction of
differentiation. Among the three related MAPK families identified to
date, the extracellular signal-regulated protein kinases (ERK) have
been identified as playing a role in differentiation. Activation
of the MAPK kinase (MEK1) is necessary and sufficient for
neuronal differentiation of PC12 rat pheochromocytoma cells (7) and for megakaryocyte differentiation of human K562
erythroleukemia cells (59). In contrast, overexpression of
constitutively active MEK1 in U-937 cells results in growth inhibition
but no phenotypic differentiation (15). In addition,
activation of ERK by TPA in the TPA-resistant UT16 variant of U-937
cells suggests that ERK activation is not sufficient for induction of
human myeloid leukemia cell differentiation (48).
The stress-activated protein kinases (SAPK; also known as Jun kinases
or JNK) are serine/threonine protein kinases related to the MAPK
family. SAPK is activated by tumor necrosis factor, diverse
DNA-damaging agents, UV light, and anisomycin (12, 28, 33).
SAPK phosphorylates Ser-63 and Ser-73 of the c-Jun amino terminus and
thereby activates c-Jun transcription function (12, 33). The
ATF2 and Elk1 transcription factors are also phosphorylated by SAPK
(18, 45, 60). Whereas TPA-induced monocytic differentiation is associated with induction of c-jun (49, 54,
61) and EGR-1 (27, 29) gene expression, SAPK-mediated
activation of c-Jun, ATF2, and Elk1 and thereby early response genes is
associated with the appearance of the differentiated phenotype. MEK
kinase 1 (MEKK-1) (34) preferentially activates SAPK/ERK
kinase 1 (SEK1) (13, 36, 38) and, consequently, SAPK
(46). Of interest, Bck 1p, a MEK1 kinase homolog in yeast,
functions downstream of the PKC homolog PKC 1p (35). The
finding that murine MEKK-1 can also function as a downstream effector
of PKC 1p and can replace Bck 1p has provided support for
potential interactions between PKC and MEKK-1 (3). However,
the link between events activated by TPA and the
MEKK-1SEK1SAPK pathway is unclear.
The present studies demonstrated that PKCII is an upstream effector
of TPA-induced SAPK activation. Similar findings have been obtained
with other activators of PKC that induce monocytic differentiation of
myeloid leukemia cells. We also showed that TPA induces the binding of
PKCII to MEKK-1 and that MEKK-1 is necessary for TPA-induced
activation of SAPK.
| |
MATERIALS AND METHODS |
Cell culture.
Human U-937 myeloid leukemia cells (American
Type Culture Collection [ATCC], Rockville, Md.) and the TPA-resistant
clone TUR (19) were grown in RPMI 1640 medium supplemented
with 10% heat-inactivated fetal bovine serum, 100 U of penicillin per
ml, 100 µg of streptomycin per ml, and 2 mM L-glutamine.
Human HL-60 myeloid leukemia cells (ATCC) and the TPA-resistant clone
HL-525 (23) were grown in RPMI 1640 medium supplemented with
15% heat-inactivated fetal bovine serum, 100 U of penicillin per ml,
100 µg of streptomycin per ml, 1 mM sodium pyruvate, 0.1 mM
nonessential amino acids, and 2 mM L-glutamine. HeLa cells
(ATCC) were grown in Dulbecco modified Eagle medium supplemented with
10% heat-inactivated fetal bovine serum, 100 U of penicillin per ml,
100 µg of streptomycin per ml, and 2 mM L-glutamine.
U-937 and HL-60 cells were suspended at a density of 2.5 × 105/ml and treated with 16 nM TPA (Sigma Chemical Co.), 160 nM PDBu (Sigma), 10 nM bryostatin 1, 40 ng of okadaic acid (Calbiochem) per ml, or 1 µM all-trans-retinoic acid (ATRA; Hoffmann-La
Roche, Basel, Switzerland).
SAPK/JNK kinase assays.
SAPK/JNK kinase assays were
performed as described previously (26) with minor
modifications. Cells were lysed on ice for 30 min in lysis buffer (50 mM Tris-HCl [pH 7.6], 150 mM NaCl, 1% Nonidet P-40 [NP-40], 1 mM
sodium vanadate, 1 mM phenylmethylsulfonyl fluoride [PMSF], 1 mM
dithiothreitol [DTT], 10 µg of aprotinin per ml, 10 µg of
leupeptin per ml, 10 mM sodium fluoride). Equal amounts of protein, as
determined by a protein assay (Bio-Rad Laboratories, Richmond, Calif.),
were incubated with 1 µg of anti-JNK1 antibody (sc-474; Santa Cruz
Biotechnology [SBC]) for 1 h at 4°C or 1 µg of
antihemagglutinin (anti-HA) antibody (clone 12CA5; Boehringer Mannheim
Biochemicals) for 1 h followed by 1 h of incubation with
anti-mouse immunoglobulin G (IgG) antibody (402334; Calbiochem). Protein A-Sepharose beads (Pharmacia) were added for 1 h. The immunocomplexes were washed twice with buffer A (50 mM Tris-HCl [pH
7.6], 150 mM NaCl, 0.1% NP-40, 1 mM sodium vanadate, 1 mM PMSF, 1 mM
DTT, 10 µg of aprotinin per ml, 10 µg of leupeptin per ml, 10 mM
sodium fluoride), washed twice with buffer B (100 mM Tris-HCl [pH
7.6], 0.5 M LiCl, 1 mM PMSF), and then washed once with kinase buffer
I (50 mM HEPES [pH 7.4], 10 mM MgCl2, 2 mM DTT, 0.1 mM
sodium vanadate). The immunoprecipitates were resuspended in kinase
buffer containing glutathione S-transferase (GST)-Jun (amino
acids 2 to 100) and [-32P]ATP and incubated for 10 min
at 30°C before sodium dodecyl sulfate (SDS) sample buffer was added
to terminate the reaction. Samples were analyzed by SDS-10%
polyacrylamide gel electrophoresis (PAGE) and autoradiography. Equal
loading of the lanes was determined by Coomassie blue staining of the
gel. Autoradiograms were scanned, and the intensity of the GST-Jun
signals was quantitated by laser densitometry.
Cell transfections.
pEF2/PKCII was constructed by
subcloning the 2.0-kb BamHI fragment from pAcMP1/PKCII
(ATCC) into the pEF2 vector made by substituting the cytomegalovirus
promoter of pcDNA3 with the elongation factor 1 promoter
(9).
TUR and HL-525 cells were resuspended at 107/ml and
transfected by electroporation (Gene Pulser; Bio-Rad; 0.25 V, 960 µF). TUR cells were cotransfected with pTK-Hyg (Clontech) and
pEF2/PKCII or the empty pEF2 vector (pEF2/neo). HL-525 cells were
transfected with pEF2/PKCII or pEF2/neo. Two days posttransfection,
the cells were cultured in media containing 200 µg of hygromycin B
(Boehringer) per ml and 800 µg of Geneticin sulfate (GIBCO-BRL) per
ml. After 4 weeks of selection, cells were maintained in 100 µg of
hygromycin B per ml or 400 µg of Geneticin sulfate per ml.
The 2.2-kb
EcoRI fragment from a kinase-inactive mutant,
MEKK-1 (K-M) (
21), was subcloned into pSuperCatch
(
17), which
contains the sequence for Flag tag (Eastman
Kodak Co., Rochester,
N.Y.). pEF2/Flag-MEKK-1 (K-M) was constructed by
subcloning the
2.4-kb
HindIII-
EcoRV fragment
from pSuperCatch/MEKK-1 (K-M) into
the pEF2
vector.
HeLa cells were resuspended at 2.5 × 10
7/ml and
transfected by electroporation (Gene Pulser; 0.22 V, 960 µF) with
pEF2/PKC
II,
pEF2/neo, full-length MEKK-1 (
62),
pEF2/PKC
(
9), pEF2/Flag-MEKK-1
(K-M), hemagglutinin
(HA)-tagged SAPK (
33), or pEBG/c-Raf-1
(K-M)
(
58). At 48 h posttransfection, the cells were
harvested
and left untreated or treated with 16 nM TPA for 15 min.
Whole-cell
lysates were then prepared for immunoprecipitation and
immunoblot
analysis.
Immunoprecipitation.
Cells were washed twice with ice-cold
phosphate-buffered saline and lysed in lysis buffer. Soluble proteins
were incubated with anti-PKCII antibody (sc-210; SBC), anti-MEKK-1
antibody (antibody 11612 directed against the carboxy-terminal 15 amino acids [provided by G. Johnson]), or anti-HA antibody for 1 h
followed by 1 h of incubation with anti-mouse IgG antibody.
Protein A-Sepharose beads were added for 1 h. The immune complexes
were washed three times with lysis buffer and subjected to immunoblot analysis.
Subcellular fractionation.
Cytosolic and membrane fractions
were obtained as described previously (64). Cells were
resuspended in TEM lysis buffer (20 mM Tris-HCl [pH 7.5], 0.5 mM
EDTA, 0.5 mM EGTA, 10 mM DTT, 1 mM PMSF, 25 µg of aprotinin per ml,
25 µg of leupeptin per ml, 10 mM -mercaptoethanol) and sonicated.
After sedimentation of the nuclear fraction by centrifugation at 3,500 rpm (Beckman benchtop ultracentrifuge) for 10 min, the cell extracts
were centrifuged at 55,000 rpm (Beckman benchtop ultracentrifuge) for
30 min. The pellets were solubilized in TEM buffer containing 1%
NP-40. The supernatant (cytosolic fraction) and the solubilized
membrane fraction were subjected to immunoblot analysis.
Immunoblot analysis.
Proteins were separated by SDS-PAGE
with 7.5, 10, or 15% polyacrylamide gels and then transferred to
nitrocellulose filters. After being blocked with 5% dried milk in
PBS-Tween, the filters were incubated with the following antibody:
anti-PKC (sc-208; SBC), anti-PKCII, anti-PKC (sc-937;
SBC), anti-MEKK-1 (antibodies 11612 and 95-012 directed against the
kinase domain [provided by G. Johnson]; antibody sc-252 directed
against the carboxy-terminal 22 amino acids [SBC]), anti-HA, or
anti-Flag M2 (F3165; Sigma). After being washed and incubated with
horseradish peroxidase-conjugated anti-rabbit or anti-mouse IgG
(Amersham), the antigen-antibody complexes were visualized by
chemiluminescence (enhanced chemiluminescence detection system; Amersham).
In vitro binding of PKCII and MEKK-1.
Human recombinant
PKCII (2 µl, 0.271 mg/ml; Calbiochem) was incubated in buffer C
(20 mM Tris-HCl [pH 7.6], 20 mM MgCl2, 2 mM
CaCl2, 20 µM ATP, 500 nM TPA) with glutathione-Sepharose beads bound to GST-MEKK-1 or GST for 30 min at 30°C. The adsorbed material obtained by washing three times with lysis buffer was analyzed
by immunoblotting with anti-PKCII antibody.
In vitro phosphorylation of MEKK-1.
GST-MEKK-1 (5 µg,
derived from Escherichia coli; Upstate Biotechnology catalog
no. 14-176) or GST was incubated in buffer C with human recombinant
PKCII (0.5 µl) and [-32P]ATP for 30 min at
30°C. Phosphorylation of the reaction products was assessed by
SDS-PAGE and autoradiography.
MEKK-1 activity assays.
A cDNA containing the
carboxy-terminal portion of 80-kDa MEKK-1 was amplified by PCR with rat
full-length MEKK-1 (62) as a template and cloned into the
yeast p426GAG expression vector, which contains the GST domain under
the control of the yeast GAL1 promoter (55). GST-MEKK-1
(yeast derived) or GST bound to glutathione beads was pretreated with
calf intestinal alkaline phosphatase (1 µl, 27.8 U/µl; GIBCO-BRL)
at 37°C for 1 h. The beads were washed three times with lysis
buffer, twice with 0.5 M LiCl-100 mM Tris-HCl (pH 7.6), and once with
kinase buffer II (20 mM Tris-HCl [pH 7.6], 20 mM MgCl2, 2 mM CaCl2). The beads were then incubated in buffer C with
or without 0.5 µl of PKCII for 30 min at 30°C. After the kinase
reaction, the beads were washed three times with lysis buffer, twice
with 0.5 M LiCl-100 mM Tris-HCl (pH 7.6) containing 1% NP-40 and
0.5% deoxycholic acid, and once with 50 mM HEPES (pH 7.4)-10 mM
MgCl2. The kinase reaction was performed with 50 mM HEPES
(pH 7.4)-10 mM MgCl2-20 µM
ATP-[-32P]ATP containing 5 µg of GST-SEK1 K-R
mutant [SEK1 (K-R)] for 5 min at 30°C. Chelerythrine chloride (200 µM; Sigma) was added as needed. The reaction was terminated by the
addition of SDS sample buffer and boiling. The reaction products were
analyzed by SDS-PAGE and autoradiography.
| |
RESULTS |
Activation of SAPK in myeloid leukemia cells treated with inducers
of differentiation.
Human U-937 and HL-60 myeloid leukemia cells
respond to TPA and other agents that activate PKC, such as PDBu and the
non-phorbol ester bryostatin 1, with induction of monocytic
differentiation. To assess the effects of these agents on SAPK
activity, anti-SAPK antibody immunoprecipitates from treated cells were
assayed for phosphorylation of the GST-Jun substrate. SAPK activity was
induced in U-937 cells by 15 min of TPA treatment, and sustained
activation of SAPK was observed through 24 h (Fig.
1A). Similar findings were obtained for
TPA-treated HL-60 cells (Fig. 1A). PDBu and bryostatin 1 also induced
rapid and sustained increases in SAPK activity in U-937 cells (Fig.
1B). Similar findings were obtained with these agents for HL-60 cells
(data not shown). Okadaic acid, an inhibitor of protein phosphatases 1 and 2A, induces monocytic differentiation of myeloid leukemia cells
(25). Treatment of U-937 and HL-60 cells with okadaic acid
was associated with induction of SAPK by 1 h that was sustained at
24 h (Fig. 1C). These findings supported the induction of SAPK
activity by diverse agents in association with monocytic
differentiation of myeloid leukemia cells.
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FIG. 1.
Activation of SAPK by TPA and other inducers of
monocytic differentiation. (A) U-937 and HL-60 cells were treated with
16 nM TPA. (B) U-937 cells were treated with 160 nM PDBu or 10 nM
bryostatin-1. (C) U-937 and HL-60 cells were treated with 40 ng of
okadaic acid (OA) per ml. Treatment times are shown. The cells were
then lysed and subjected to immunoprecipitation with anti-SAPK
antibody. The immunoprecipitates were incubated with GST-Jun and
[-32P]ATP. GST-Jun phosphorylation was assessed by
SDS-PAGE and autoradiography.
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|
Defective activation of SAPK in TPA-resistant myeloid leukemia
cells.
Whereas TUR and HL-525 cells fail to respond to TPA with
induction of monocytic differentiation (19, 23), we examined if SAPK is induced by activators of PKC in these cells. Treatment of
TUR and HL-525 cells with TPA was associated with substantial abrogation of SAPK induction compared to that in TPA-treated parental U-937 and HL-60 cells (Fig. 2A). Similar
results were obtained following treatment of TUR and HL-525 cells with
PDBu or bryostatin 1 (data not shown). In contrast, TUR and HL-525
cells respond to okadaic acid with induction of monocytic
differentiation (19, 30) and also exhibited okadaic
acid-induced increases in SAPK activity (Fig. 2A). To further assess
the difference in responses to TPA and okadaic acid, dose-response
relationships were studied with U-937 and TUR cells. The results
demonstrated that whereas the induction of SAPK was markedly different
in TPA-treated U-937 and TUR cells, the responses to okadaic acid were
comparable between the two cell types (Fig. 2B). Similar results were
obtained for HL-60 and HL-525 cells (Fig. 2C). These results indicated
that defective activation of SAPK in TPA-treated TUR and HL-525 cells is attributable not to a loss of SAPK responsiveness but rather to
defects in the activation of upstream effectors.
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FIG. 2.
Defective activation of SAPK in TPA-resistant myeloid
leukemia cells. (A) TUR and HL-525 cells were treated with 16 nM TPA
for the indicated times or with 40 ng of okadaic acid (OA) per ml for
6 h. (B and C) U-937 and TUR cells (B) or HL-60 and HL-525 cells
(C) were treated with the indicated concentrations of OA for 6 h.
Anti-SAPK antibody immunoprecipitates were assayed for phosphorylation
of GST-Jun.
|
|
ATRA pretreatment increases PKC expression and responsiveness to
TPA-induced SAPK activity.
Previous studies demonstrated that TUR
and HL-525 cells are deficient in PKC expression (19,
56). The finding that the up-regulation of PKC expression by
ATRA treatment or transfection of the PKC gene restores
responsiveness to TPA supports an essential role for PKC in
TPA-induced monocytic differentiation (56, 64). To address
the potential involvement of PKC in TPA-induced activation of SAPK,
we pretreated HL-525 cells with ATRA for 3 days; as previously shown
(64), this treatment increased the expression of PKCII
4.5-fold (mean of three independent experiments) to nearly that in
wild-type HL-60 cells (Fig. 3A). In
contrast, PKC expression and PKC expression were increased less
than 1.5-fold in ATRA-pretreated HL-525 cells (Fig. 3A). ATRA
pretreatment had little, if any, effect on SAPK activity (data not
shown) but restored the rapid and sustained induction of SAPK activity
in response to TPA exposure (Fig. 3B). These findings supported a
potential role for PKCII in TPA-induced SAPK activation.
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FIG. 3.
Effects of ATRA pretreatment on PKC expression and
responsiveness to TPA-induced SAPK activation. (A) HL-60 and HL-525
cells were cultured in the presence or absence of 1 µM ATRA for 3 days. Lysates from the indicated cells were subjected to immunoblot
analysis with anti-PKCII, anti-PKC, and anti-PKC antibodies.
(B) HL-525 cells were pretreated with ATRA for 3 days and then exposed
to 16 nM TPA for the indicated times. Anti-SAPK antibody
immunoprecipitates were assayed for GST-Jun phosphorylation.
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|
Characterization of PKCII transfectants.
To provide more
definitive evidence for the involvement of PKC as an upstream
effector of SAPK, TUR cells that stably expressed the PKCII gene
were prepared. Separate TUR transfectants expressing the null vector
(TUR/neo) demonstrated PKCII levels comparable to those in TUR cells
(Fig. 4A). In contrast, TUR
transfectants expressing the PKCII gene (TUR/PKCII)
exhibited PKCII levels that approximated those in U-937 cells
(Fig. 4A). Also, there was no apparent effect on the level of PKC or
PKC expression in TUR/neo or TUR/PKCII transfectants (Fig. 4A).
Treatment of U-937 cells with TPA was associated with translocation of
PKCII from the cytosolic to the membrane fraction (Fig. 4B). In
contrast, translocation of PKCII to the membrane fraction was
defective in TPA-treated TUR cells (Fig. 4B). Similar defects in
translocation were observed for the TUR/neo cells (data not shown),
whereas PKCII was translocated to the membrane fraction
following TPA treatment of TUR/PKCII cells (Fig. 4B). These
results indicated that whereas parental TUR cells are deficient in both
PKCII expression and TPA-induced translocation, TUR transfectants
expressing exogenous PKCII display normal membrane association of
PKCII following TPA treatment.
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FIG. 4.
Expression of PKCII in stable TUR transfectants. (A)
TUR cells were stably transfected with pEF2/neo or pEF2/PKCII. After
selection, lysates were subjected to immunoblotting with anti-PKCII,
anti-PKC, and anti-PKC antibodies. (B) The indicated cells were
left untreated or were treated with 16 nM TPA for 15 min. Cytosolic (C)
and membrane (M) fractions were subjected to immunoblotting with
anti-PKCII antibody.
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|
Role for PKCII in induction of SAPK activity.
Treatment of
the TUR/neo clones with TPA demonstrated an attenuated induction of
SAPK activity like that observed for nontransfected TUR cells (Fig.
5A). The TUR/PKCII clones, however,
responded to TPA with a rapid and sustained activation of SAPK
(Fig. 5B). Comparable findings were obtained for the HL-525/neo
and HL-525/PKCII transfectants (Fig.
6A). Whereas the TPA-treated
HL-525/neo transfectants exhibited an attenuated induction of SAPK
activity, the HL-525/PKCII transfectants responded to TPA with
activation of SAPK (Fig. 6B and C). These results supported the
involvement of PKCII in TPA-induced SAPK activation. The
TUR/PKCII and HL-525/PKCII clones also responded to TPA with
cessation of growth, adherence, and increases in nonspecific
esterase (NSE) staining, whereas the TUR/neo and HL-525/neo
clones failed to exhibit these characteristics of monocytic differentiation (Table 1).
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FIG. 5.
Activation of SAPK in TUR transfectants. TUR cells
stably transfected with pEF2/neo (A) or pEF2/PKCII (B) were exposed
to 16 nM TPA for the indicated times. Anti-SAPK antibody
immunoprecipitates were assayed for GST-Jun phosphorylation. Cells were
also treated with 40 ng of OA per ml for 6 h.
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FIG. 6.
TPA-induced activation of SAPK in HL-525 cells stably
expressing PKCII. (A) HL-525 cells were stably transfected with
pEF2/neo or pEF2/PKCII. After selection, lysates were subjected to
immunoblotting with anti-PKCII, anti-PKC, and anti-PKC
antibodies. (B and C) HL-525/neo (B) and HL-525/PKCII (C) clones
were treated with 16 nM TPA for the indicated times. Anti-SAPK antibody
immunoprecipitates were assayed for GST-Jun phosphorylation. Cells were
also treated with 40 ng of OA per ml for 6 h.
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Functional interaction between PKCII and the MEKK-1SAPK
pathway.
SAPK is activated by a cascade involving MEKK-1 and SEK1
(34, 36, 38, 46, 63). To determine whether PKCII
interacts with the MEKK-1SEK1SAPK pathway, anti-PKCII antibody
immunoprecipitates were analyzed by immunoblotting with anti-MEKK-1
antibody 11612. There was no detectable MEKK-1 in the anti-PKCII
antibody immunoprecipitates from untreated U-937 cells (Fig.
7A). In contrast, treatment with TPA
resulted in the association of PKCII and the ~80-kDa fragment (4) of MEKK-1 (Fig. 7A, left panel). Similar findings were obtained for HL-60 cells (Fig. 7A, left panel). Kinetic studies demonstrated that the association between PKCII and MEKK-1 was induced maximally at 1 h of TPA treatment (Fig. 7A, right panel). Compared to immunoprecipitation of control cell lysates with the anti-MEKK-1 antibody, approximately 20 to 25% of total MEKK-1 associated with PKCII at 1 h of TPA treatment (Fig. 7A,
right panel, last lane). The same findings were obtained with
other anti-MEKK-1 antibodies (sc-252 and 95-012) (data not shown). In the reciprocal experiment, anti-MEKK-1 antibody immunoprecipitates were
analyzed with an anti-PKCII antibody. The results confirmed a
TPA-dependent association of PKCII and MEKK-1 (Fig. 7B). These findings suggested that activated PKCII interacts with MEKK-1.
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FIG. 7.
TPA-induced association of PKCII and MEKK-1. (A)
U-937 and HL-60 cells were treated with 16 nM TPA for 1 h (left
panel) or for the indicated times (right panel). Cell lysates were
immunoprecipitated (IP) with anti-PKCII or anti-MEKK-1 antibody
(11612; right panel, last lane). The immunoprecipitates (total applied
to each lane) were subjected to immunoblot (IB) analysis with
anti-PKCII or anti-MEKK-1 antibody. Half of the anti-MEKK-1 antibody
immunoprecipitate was applied to the right panel, last lane. Ig,
immunoglobulin. (B) U-937 and HL-60 cells were treated with 16 nM TPA
for 1 h. Anti-MEKK-1 antibody immunoprecipitates were analyzed by
immunoblotting (IB) with anti-PKCII or anti-MEKK-1 antibody. (C and
D) HeLa cells were cotransfected with 10 µg of pEF2/PKCII and 10 µg of HA-tagged full-length MEKK-1. At 48 h after transfection,
the cells were treated with 16 nM TPA for 15 min. Cell lysates were
immunoprecipitated (IP) with anti-PKCII (C) or anti-HA (D) antibody
and then subjected to immunoblot (IB) analysis with anti-HA (C) or
anti-PKCII (D) antibody. As a control, lysates were subjected
directly to immunoblotting with anti-PKCII antibody (left lane in
panel D).
|
|
To confirm the interaction between PKC
II and MEKK-1, we performed
transient expression studies with HeLa cells which, as
previously shown
(
5), have undetectable levels of PKC
II. HeLa
cells were
cotransfected with pEF2/PKC
II and a vector expressing
HA-tagged
full-length MEKK-1. After 48 h, the transfected cells
were treated
with TPA, and cell lysates were subjected to immunoprecipitation
with anti-PKC
II or anti-HA antibody. Analysis of the precipitates
with anti-HA or anti-PKC
II antibody demonstrated that TPA induced
the association of PKC
II and full-length MEKK-1 (Fig.
7C and
D).
Together with the results of studies with myeloid leukemia
cells, these
findings indicated that PKC
II binds to the truncated
and full-length
forms of MEKK-1 and that this association is induced
by TPA-dependent
activation of PKC
II.
To assess whether the interaction between PKC
II and MEKK-1 is
direct, we incubated purified PKC
II with GST-MEKK-1 or GST.
Analysis of the material adsorbed to glutathione beads demonstrated
binding of PKC
II to GST-MEKK-1 and not GST (Fig.
8A). These findings
indicated that
PKC
II interacts directly with MEKK-1. To determine
whether
PKC
II phosphorylates MEKK-1, we incubated PKC
II with
GST-MEKK-1
or GST in the presence of [
-
32P]ATP. Analysis of
the reaction products demonstrated phosphorylation
of GST-MEKK-1 (Fig.
8B, left lane). Autophosphorylation of PKC
II
was also detectable,
but phosphorylation of GST was not (Fig.
8B, right lane). Because these
findings indicated that PKC
II
phosphorylates MEKK-1, we examined if
PKC
II affects MEKK-1 activity.
GST-MEKK-1 prepared from yeast and
treated with alkaline phosphatase
phosphorylated the kinase-inactive
SEK1 (K-R) substrate (Fig.
8C, lane 1). Preincubation of GST-MEKK-1
with PKC
II and then
removal of the PKC
II led to induction of
MEKK-1 activity (Fig.
8C, lane 2). Similar findings were obtained in
the presence of
the PKC inhibitor chelerythrine chloride (Fig.
8C, lane
3). The
results of three independent experiments demonstrated that
preincubation
of GST-MEKK-1 with PKC
II increased MEKK-1 activity
2.4-fold (mean
of three independent experiments). These findings
indicated that
PKC
II phosphorylates and thereby activates MEKK-1 in
vitro.
View larger version (31K):
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|
FIG. 8.
PKCII phosphorylates and activates MEKK-1 in vitro.
(A) Purified PKCII was incubated with GST-MEKK-1 (lane 2) or GST
(lane 3). As a control, PKCII was omitted from the incubation with
GST-MEKK-1 (lane 1). Material adsorbed to glutathione-agarose beads
was analyzed by immunoblotting (IB) with anti-PKCII antibody. (B)
PKCII was incubated with kinase-inactive GST-MEKK-1 (E. coli derived) or GST in the presence of
[-32P]ATP. As a control, GST-MEKK-1 was incubated
with [-32P]ATP. The reaction products were analyzed by
SDS-PAGE and autoradiography. (C) Kinase-active GST-MEKK-1 (yeast
derived) bound to glutathione beads was incubated with alkaline
phosphatase. After being washed, the beads were incubated in the
absence or presence of purified PKCII and ATP. The
GST-MEKK-1-containing beads were washed again and then incubated with
SEK1 (K-R) and [-32P]ATP. Chelerythrine chloride (200 µM) was added to the incubation shown in lane 3. The reaction
products were analyzed by SDS-PAGE and autoradiography.
|
|
To determine whether PKC
II contributes to TPA-induced SAPK
activation by a MEKK-1-dependent mechanism, cotransfection
studies
were performed with HeLa cells, pEF2/PKC
II, and
HA-tagged SAPK.
Analysis of anti-HA antibody immunoprecipitates for
phosphorylation
of GST-Jun demonstrated that the induction of SAPK by
TPA was
dependent on the level of PKC
II expression (Fig.
9A). In contrast,
overexpression of the
TPA-responsive PKC
isoform had no detectable
effect on TPA-induced
SAPK activation (Fig.
9B). Because these
findings supported the
specificity of PKC
II in the induction
of SAPK, the involvement of
MEKK-1 in a TPA
PKC
II
SAPK cascade
was assessed by
cotransfection with a kinase-inactive, dominant
negative mutant, MEKK-1
(K-M) (
21). The results demonstrated
that while TPA induced
SAPK activation by a PKC
II-dependent mechanism,
the expression of
MEKK-1 (K-M) blocked the response (Fig.
10A).
To extend these
findings by assessing the activation of endogenous
SAPK, similar
experiments were performed with HeLa cells transfected
with
pEF2/PKC
II and pEF2/Flag-MEKK-1 (K-M). Analysis of anti-SAPK
antibody immunoprecipitates for phosphorylation of GST-Jun confirmed
that the induction of endogenous SAPK by TPA was also dependent
on
PKC
II expression and was blocked by the MEKK-1 (K-M) mutant
(Fig.
10B). To show that MEKK-1 (K-M) specifically inhibits TPA-induced
SAPK
activation, we compared the effects of MEKK-1 (K-M) to those
of a
kinase-inactive MEK1 mutant, c-Raf-1 (K-M). In contrast to
the
inhibition by MEKK-1 (K-M), there was no detectable effect
of the
overexpression of c-Raf-1 (K-M) on TPA-induced SAPK activity
(Fig.
10C). The c-Raf-1 (K-M) mutant was, however, effective in
inhibiting TPA-induced ERK2 activity (data not shown).
Collectively,
these findings indicated that PKC
II associates with
MEKK-1 by
a TPA-dependent mechanism and thereby contributes to the
induction
of the MEKK-1
SAPK cascade.
View larger version (33K):
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|
FIG. 9.
PKCII-dependent SAPK activation in TPA-treated HeLa
cells. HeLa cells were transfected with the indicated amounts
(micrograms) of pEF2/PKCII, pEF2/PKC, pEF2/neo, and HA-tagged
SAPK. At 48 h posttransfection, the cells were left untreated or
were treated with 16 nM TPA for 15 min. Cell lysates were
immunoprecipitated with anti-HA antibody, and the anti-HA antibody
immunoprecipitates were assayed for phosphorylation of GST-Jun. Lysates
were also subjected to immunoblot analysis with anti-PKCII, anti-HA,
and anti-PKC antibodies to assess the levels of expression of
transfected PKCII, HA-tagged SAPK, and PKC (lower panels).
Panel A shows a dose dependence on PKCII expression level, and panel
B shows the specificity of PKCII in comparison with PKC.
|
|
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 10.
TPA-induced activation of SAPK by a PKCII- and
MEKK-1-dependent mechanism. (A) HeLa cells were transfected with the
indicated amounts of pEF2/PKCII, pEF2/neo, pEF2/Flag-MEKK-1 (K-M),
and HA-tagged SAPK. At 48 h posttransfection, cells were left
untreated or were treated with 16 nM TPA for 15 min. Anti-HA antibody
immunoprecipitates were assayed for phosphorylation of GST-Jun. Lysates
of the transfected cells were also subjected to immunoblot analysis
with anti-PKCII, anti-Flag M2, and anti-HA antibodies to assess the
levels of expression of transfected PKCII, Flag-MEKK-1 (K-M), and HA-tagged SAPK. The levels of GST-Jun phosphorylation were
quantitated on the basis of the intensity of the signals, and the
results are expressed as the mean ± standard error of three
independent experiments (lowest panel). (B) HeLa cells were transfected
with the indicated amounts of pEF2/PKCII, pEF2/neo, and
pEF2/Flag-MEKK-1 (K-M). HA-tagged SAPK was not transfected in this
experiment. At 48 h posttransfection, cells were left untreated or
were treated with 16 nM TPA for 15 min. Anti-SAPK antibody
immunoprecipitates were assayed for phosphorylation of GST-Jun. (C)
HeLa cells were transfected with the indicated amounts of
pEF2/PKCII, pEF2/neo, pEF2/Flag-MEKK-1 (K-M), and pEBG/c-Raf-1
(K-M). At 48 h posttransfection, cells were left untreated or were
treated with 16 nM TPA for 15 min. Anti-SAPK antibody
immunoprecipitates were analyzed for phosphorylation of GST-Jun.
|
|
| |
DISCUSSION |
Role for PKCII in TPA-induced SAPK activity and monocytic
differentiation.
Initial studies demonstrated that treatment of
human myeloid leukemia cells with TPA and other activators of PKC is
associated with induction of monocytic differentiation (6).
These findings indicated that the growth factor-independent phenotype
of myeloid leukemia cells is reversible. Although certain insights were
available regarding the involvement of PKC activation in inducing
leukemia cell differentiation, the precise roles, if any, of the 12 known isoforms of the PKC family in this process have been unclear. Significantly, myeloid leukemia cells resistant to TPA-induced differentiation were found to be deficient in PKC expression (19, 37, 42, 56, 57). Also, induction of PKC restored TPA-induced growth arrest and monocytic differentiation (56, 64).
The present results demonstrated that TPA-induced SAPK activation is
defective in PKC
-deficient TUR and HL-525 cells. Similar
defects in
SAPK activation were observed for TUR and HL-525 cells
when PDBu and
bryostatin 1 were used as activators of PKC. In
contrast, TUR and
HL-525 cells responded to okadaic acid, an inhibitor
of
phosphoserine/threonine phosphatases, with activation of SAPK.
Other
studies have demonstrated that TUR and HL-525 cells respond
to okadaic
acid with induction of monocytic differentiation (
19,
50).
These findings demonstrated that leukemia cells deficient
in PKC
retain the capacity to differentiate along the monocytic
lineage
through certain agents that induce signals other than
the activation of
PKC. The involvement of PKC
and, particularly,
PKC
II in
TPA-induced monocytic differentiation was directly supported
by stable
transfection of a PKC
II expression vector in TUR and
HL-525 cells.
The PKC
II transfectants responded to TPA with the
activation of
SAPK, growth arrest, and the appearance of a differentiated
monocytic
phenotype. These findings thus support a role for PKC
II
in both
TPA-induced SAPK activity and monocytic
differentiation.
Previous studies showed that TPA has little, if any, effect on SAPK
activation in diverse cell types, including epithelial
HeLa cells
(
12,
33,
38,
63). In contrast, TPA effectively
activates
SAPK in human myeloid leukemia cells (
14-16,
20,
44).
However, the events responsible for cell type-specific induction
of
SAPK activation by TPA have been unclear. PKC
expression is
undetectable in NIH 3T3 cells (
39) and HeLa cells
(
5), which
are unresponsive to TPA in terms of SAPK
activation. Together
with the present results, these findings indicate
that PKC
expression
is necessary for TPA-induced SAPK
activation.
Interaction of PKCII with MEKK-1 in TPA-treated myeloid leukemia
cells.
MEKK-1 is distinct from the MEK activator Raf and functions
as an upstream effector of the SAPK pathway (38, 63). Recent studies demonstrated that MEKK-1 is cleaved by caspases during the
induction of anoikis or apoptosis associated with the loss of
integrin-mediated contacts (4). The cleavage of MEKK-1 is blocked by the cowpox virus CrmA protein, which inhibits certain caspases (4). In U-937 cells, which grow in suspension,
MEKK-1 is constitutively expressed as an ~80-kDa form. Overexpression of CrmA in U-937 cells (9) has no apparent effect on the
expression of the ~80-kDa form of MEKK-1 (data not shown). Similarly,
U-937 cells that overexpress the p35 caspase inhibitor (9)
or the antiapoptotic Bcl-xL protein (10) also
express only the ~80-kDa form of MEKK-1 (data not shown). These
findings suggest that in U-937 cells, the expression of MEKK-1 as an
~80-kDa protein is due to mechanisms other than caspase cleavage.
The present results demonstrate that treatment of U-937 cells with TPA
is associated with the induction of PKC
II binding
to the ~80-kDa
form of MEKK-1. Whereas cleavage can contribute,
at least in part, to
the activation of MEKK-1 (
4), other events
involving
phosphorylation may be required by upstream effectors.
In this context,
our in vitro studies with the ~80-kDa form of
MEKK-1 provide support
for activation by PKC
II. Studies with
cells also provide support for
a functional interaction between
PKC
II and MEKK-1. TPA-induced
activation of SAPK in HeLa cells
was dependent on PKC
II expression,
and this response was blocked
by a dominant negative MEKK-1 mutant.
These findings could also
be explained by an indirect interaction
between PKC
II and MEKK-1
that, for example, involves other proteins
which are activated
by PKC
II and function as upstream effectors of
MEKK-1. However,
the binding of PKC
II to MEKK-1 in vitro and the
PKC
II-induced
activation of MEKK-1 suggest that the interaction
between these
proteins is
direct.
Role for PKC in induction of monocytic differentiation.
Previous work showed that monocytic differentiation of myeloid leukemia
cells is associated with the induction of c-jun,
junB, c-fos, and EGR-1 expression (11, 29,
47, 49). The absence of jun, fos, and EGR-1
gene induction in TPA-treated TUR cells supports a defect in upstream
signals that confer the activation of these genes (19, 30).
HL-525 cells also exhibit attenuated induction of c-jun and
c-fos transcripts in response to TPA treatment (8). The finding that the stable introduction of PKCII
expression in TUR and HL-525 cells restores TPA induction of monocytic
differentiation suggests that the defect in the induction of
early-response gene expression is due to a PKC deficiency. Indeed,
TUR and HL-525 cells that stably express the PKCII vector respond to
TPA with induction of the c-jun and EGR-1 genes (data not shown).
Induction of the c-
fos gene may not be obligatory for the
TPA-induced monocytic differentiation of myeloid leukemia cells
(
40). In contrast, other studies have demonstrated that the
induction of Jun/AP-1 activity and the c-
jun gene is
functionally
related to the induction of monocytic differentiation
(
54).
EGR-1 expression has also been found to be essential
for differentiation
along the monocytic lineage (
41). Thus,
the induction of diverse
early-response genes is probably required for
the activation of
signals responsible for the appearance of the
monocytic phenotype.
Whereas SAPK phosphorylates the c-Jun, ATF2, and
Elk-1 transcription
factors, which contribute to the induction of
early-response gene
expression, activation of the SAPK pathway by
differentiating
agents, such as TPA, may contribute to reversal of the
phenotype
that characterizes myeloid leukemia cells. This notion is
consistent
with the previous observation that c-
jun
overexpression in U-937
cells induces partial differentiation and
facilitates differentiation
induced by TPA (
53). However,
there is no direct evidence that
SAPK activation is essential for the
induction of monocytic differentiation.
The present findings provide
support for the involvement of PKC
as an upstream effector of SAPK
activation, early-response gene
expression, and induction of myeloid
leukemia cell
differentiation.
| |
ACKNOWLEDGMENTS |
We thank M. Cobb for HA-tagged full-length MEKK-1, L. Zon and J. Kyriakis for HA-SAPK, S. Ohno for the kinase-inactive MEKK-1 (K-M)
mutant, A. Yamakawa for pSuperCatch, G. Johnson for anti-MEKK-1 antibodies, G. Tzivion and J. Avruch for c-Raf-1 (K-M), and G. Petit
for bryostatin 1.
This investigation was supported by Public Health Service grants
CA42802 and CA68252 awarded by the National Cancer Institute.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Dana-Farber
Cancer Institute, Harvard Medical School, 44 Binney St., Boston, MA
02115. Phone: (617) 632-3141. Fax: (617) 632-2934. E-mail:
donald_kufe{at}dfci.harvard.edu.
| |
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Molecular and Cellular Biology, January 1999, p. 461-470, Vol. 19, No. 1
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Copyright © 1999, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
