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Molecular and Cellular Biology, November 2000, p. 8103-8111, Vol. 20, No. 21
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Inactivation of Smad-Transforming Growth Factor 
Signaling by Ca2+-Calmodulin-Dependent Protein Kinase
II
Stephen J.
Wicks,1
Stephen
Lui,1,
Nadia
Abdel-Wahab,2
Roger M.
Mason,2 and
Andrew
Chantry1,*
Department of Cancer Medicine, Division of
Medicine, Imperial College School of Medicine, Hammersmith Campus,
London W12 ONN,1 and Department of
Molecular Pathology, Division of Basic Medical Sciences, Imperial
College School of Medicine, South Kensington Campus, London SW7
2AZ,2 United Kingdom
Received 1 June 2000/Returned for modification 5 July 2000/Accepted 27 July 2000
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ABSTRACT |
Members of the transforming growth factor 
(TGF-) family
transduce signals through Smad proteins. Smad signaling can be regulated by the Ras/Erk/mitogen-activated protein pathway in response
to receptor tyrosine kinase activation and the gamma interferon pathway
and also by the functional interaction of Smad2 with
Ca2+-calmodulin. Here we report that
Smad-TGF--dependent transcriptional responses are prevented
by expression of a constitutively activated Ca2+-calmodulin-dependent protein kinase II (Cam kinase
II). Smad2 is a target substrate for Cam kinase II in vitro at
serine-110, -240, and -260. Cam kinase II induces in vivo
phosphorylation of Smad2 and Smad4 and, to a lesser extent, Smad3.
A phosphopeptide antiserum raised against Smad2 phosphoserine-240
reacted with Smad2 in vivo when coexpressed with Cam kinase II and by
activation of the platelet-derived growth factor receptor, the
epidermal growth factor receptor, HER2 (c-erbB2), and the
TGF- receptor. Furthermore, Cam kinase II blocked nuclear
accumulation of a Smad2 and induced Smad2-Smad4 hetero-oligomerization
independently of TGF- receptor activation, while preventing
TGF--dependent Smad2-Smad3 interactions. These findings provide a
novel cross-talk mechanism by which Ca2+-dependent kinases
activated downstream of multiple growth factor receptors antagonize
cell responses to TGF-.
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INTRODUCTION |
The transforming growth factor (TGF-) superfamily which includes TGF-, activins, and bone
morphogenic proteins (BMPs) regulate cell growth, motility,
apoptosis, differentiation, and matrix production and can have
a multifunctional role in tumorigenesis (reviewed in reference
29). Specific cell surface receptors for the TGF-
family possess intrinsic serine-threonine kinase activity, and
signaling is mediated by the type I and type II receptors, which are
able to form a ligand-inducible active heteromeric complex
(42). Identification of the Smad family of transcription factors is beginning to reveal the mechanisms of TGF--mediated signaling from the cell surface to the nucleus. There are three types
of Smad comprising pathway-restricted, common-mediator, and inhibitory
Smads. Pathway-restricted Smad1 and Smad5 are substrates for the BMP
type I receptor, whereas Smad2 and Smad3 are specific targets for
TGF- and activin receptors. Phosphorylation of Smads by the
activated type I receptor kinase induces their release and subsequent
association with a common mediator Smad4 (reviewed in reference
29). This oligomeric complex then translocates to
the nucleus, and cooperation with DNA-binding proteins such as FAST-1
and FAST-2 directs specific transcriptional responses (12, 26,
46).
Phosphorylation of Smads is critical for regulating their activity and
all pathway restricted Smads have a C-terminal SSXS motif in which the
two end serines are phosphorylated by the type I receptor (1,
41). Receptor-mediated phosphorylation of the C-terminal serines
in pathway-restricted Smads is required for transcriptional activity
and facilitates both the association with Smad4 to form
hetero-oligomers and the translocation to the nucleus (reviewed in
reference 29). The MH2 domain of
activated-pathway-restricted Smads comprises a transcriptional
activation domain and is also responsible for interactions with Smad4
and FAST-1 (12). Smad2 is not able to bind DNA directly, and
a ternary bridge complex is formed at appropriate response elements in
which Smad2 interacts with Smad4 and FAST-1 that bind separately to two
specific DNA sequence elements (26, 46). Other nuclear
proteins that interact with Smads and influence their transcriptional
activity include the fos-jun complex, Sp1, the basic helix-loop-helix
leucine zipper protein TFE3, the coactivator p300/CBP, vitamin D
receptor, Evi-1, the Ski oncoprotein, and the corepressor TGIF (for
recent reviews, see references 30 and
36).
Recently, input from other growth factor receptor systems have also
been shown to influence the Smad signaling network and to have an
impact upon responsiveness to members of the TGF- superfamily.
Erk-mitogen-activated protein (MAP) kinase activated in response to
epidermal growth factor (EGF) and hepatocyte growth factor can
phosphorylate the linker region of BMP pathway-specific Smad1 and
inhibit both nuclear translocation and transcriptional activity
(24). Oncogenic ras can also repress
Smad-TGF- signaling in mammary and lung epithelial cells due
to Erk-MAP kinase-mediated phosphorylation of the linker regions of
Smad2 and Smad3 (25). Conversely, MEKK-1, a component
of the stress-activated protein kinase pathway, selectively activates
Smad2-mediated transcription in cultured endothelial cells
(8). Smads and JNK signaling pathways also cooperate to
generate more robust TGF--mediated transcriptional
responses (18). Functional interaction of Smad2 with
Ca2+-calmodulin can inhibit activin-TGF- signaling,
although the precise mechanisms responsible are as yet unknown
(48). In the present study, we investigated whether Smad
function could be controlled by the activation of cytoplasmic
intracellular Ca2+-dependent kinases, more
specifically the ubiquitously expressed Ca2+-calmodulin-dependent protein kinase II (Cam kinase
II). We demonstrate that Cam kinase II prevents Smad2 nuclear
localization and transcriptional function and concomitantly induces
Smad2-Smad4 hetero-oligomerization independently of TGF-
receptor activation while completely preventing TGF--dependent
Smad2-Smad3 hetero-oligomerization. We also present evidence that
specific phosphorylation of Smad2 at novel regulatory sites occurs in
response to activation of several growth factor receptor signaling
pathways. Taken together, our data suggest a novel mechanism for
regulating the activity of Smads through changes in cytoplasmic
Ca2+ linked to the activation of intracellular
Ca2+-dependent kinases that can occur through growth
factors and other extracellular stimuli.
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MATERIALS AND METHODS |
Materials, cell lines, and transfections.
Human embryonic
kidney fibroblasts (HEK-293 cells) and Cos-1 cells were obtained from
the American Type Culture Collection (Rockville, Md.), and were
maintained in Dulbecco modified Eagle medium containing 10% fetal calf
serum. Recombinant TGF-1 was obtained from R&D, thapsigargin was
from Calbiochem, KN-93 was from Sigma, monoclonal anti-flag M2 antibody
was from Sigma, rat monoclonal anti-hemagglutinin (HA) antibody was
from Roche (used for Western blotting), mouse monoclonal anti-HA
antibody was from Clontech (used for immunoprecipitation), polyclonal
anti-green fluorescent protein (GFP) antibody was from Clontech, Smad2
antibody was from TCS Biologicals, and monoclonal anti-Cam kinase
II-
antibody was from Gibco Life Technologies. Rat Cam kinase II- and Cam kinase II1-290 cDNAs were from Tony Means and
subcloned into pCMV1 as described elsewhere (19). The cDNAs
for the human EGF receptor and chimeric receptors comprising the
extracellular domain of the human EGF receptor connected to either the
cytoplasmic domain of the mouse -platelet-derived growth factor
(PDGF) receptor (EP-R) (39), or HER2 (c-erbB2)
(HER-1/2) (27) were provided by Axel Ullrich. The 3TP-lux
reporter plasmids was provided by Jeffrey Wrana, the ARE-lux reporter
was from Malcolm Whitman, and the cDNA for GFP with S65T mutation from
Hans-Hermann Gerdes. Full-length human Smad2 (EST clone 1419-H7), human
Smad3 (provided by Rik Derynck), and human Smad4 (provided by Scott
Kern) were subcloned into pCMV1 incorporating C- or N-terminal HA or
GFP epitopes by PCR. The type I TGF- receptor, provided by
Carl-Henrik Heldin, was subcloned into pCMV1, and the constitutively
active kinase mutant was prepared by mutation of threonine 204 to
aspartic acid. Site-directed mutagenesis was performed as described
earlier (10), and pGEX-2T (Pharmacia) constructs were
prepared by PCR (19). Cells were transfected using calcium
phosphate precipitation (11) or Fugene (Roche).
RNA extraction and RT-PCR analysis.
Total RNA was extracted
using the RNAzol B method (Tel-Test, Inc.). Equal amounts of total RNA
(3 µg) from each sample were first reverse-transcribed into cDNAs
with SuperScript II RNase H+ reverse transcriptase (RT; Gibco-BRL) and
random primers. Equal amounts (1 µl) of the RT reaction (20 µl)
were in turn subjected to PCR amplification for 30 cycles. To quantify
PCR products comparatively and to confirm the use of equal amounts of
the RNAs, we coamplified a housekeeping gene,
glyceraldehyde-3-phosphate dehydrogenase (GAPDH). The amount of RT
reaction used for the amplification (1 µl) was selected as being
nonsaturating for the PCR product of GAPDH after 30 cycles of
amplification. The sequences of primers were all designed from the
published sequence of the human genes as follows: PAI-1 (sense),
5'-GTATCTCAGGAAGTCCAGCC-3'; PAI-1 (antisense), 5'-TCTAAGGTAGTTGAATCCGAGC-3'; GAPDH (sense),
5'-ACCACAGTCCATGCCATCAC-3'; and GAPDH (antisense),
5'-TCCACCACCCTGTTGCTGTA-3'.
Luciferase assays.
Cos-1 cells were transfected in six-well
plates with 2 µg of 3TP-lux or ARE-lux and combinations of empty
pCMV1 vector or pCMV1-Cam kinase II1-290 as indicated in
the figure legends. Cells were starved in medium containing 0.5%
fetal calf serum and 48 h after transfection were treated for
2 h with 1% dimethyl sulfoxide (DMSO) or 1 µM
thapsigargin (100 µM stock solution in DMSO). In some instances,
cells were also pretreated with the specific Cam kinase II inhibitor
KN-93 at a concentration of 10 µM (10 mM aqueous stock solution).
Luciferase activity was measured after 15 h of treatment with 5 ng
of TGF- using the dual-reporter system (Promega).
Phosphorylation assays.
Phosphorylation in vivo,
phosphorylation in vitro of glutathione S-transferase (GST)
proteins, and two-dimensional phosphoamino acid analyses were performed
as described previously (19). Transfected HEK-293 cells were
labeled overnight with 0.5 mCi of [32P]orthophosphate,
and lysates were immunoprecipitated with 10 µg of monoclonal
anti-flag M2 or anti-HA antibody, together with 20 µg of rabbit
anti-mouse immunoglobulin G (IgG) to facilitate the binding of the
monoclonal antibodies to protein A-Sepharose. Smad2-GST fusion proteins
were prepared and phosphorylated with purified Cam kinase II as
described previously (19). GST proteins included the
following Smad2 sequences; Smad2-WT, residues 1 to 467; Smad2-110-WT,
glycine-100 to valine-117; Smad2-227-WT, asparagine-215 to
glutamine-239; Smad2-240-WT, glycine-230 to histidine-259; Smad2-260-WT, threonine-243 to tyrosine-268; and Smad2-465-WT, valine-300 to serine-467. For two-dimensional phosphoamino acid analysis, proteins were transferred to polyvinylidene difluoride (PVDF)
membrane, excised, hydrolyzed in 6 M HCl (110°C, 90 min), and
separated in the presence of 5 µg of unlabeled standard phosphoamino acids on a 20-by-20-cm thin-layer cellulose plate using the HTLE-7000 system (CBS Scientific). The plate was then dried, sprayed with ninhydrin to visualize phosphoamino acid standards, and exposed to
X-ray film.
Phosphopeptide antisera.
Rabbits were immunized with a
phosphoserine-containing peptide
(E-T-S-D-Q-Q-L-N-Q-S-M-D-T-C; corresponding to sequence
containing serine-240 of human Smad2) coupled to keyhole limpet
hemocyanin carrier protein. Antisera were adsorbed with GST-Smad2 to
remove any peptide-specific antibodies and then immunoaffinity purified on a Sepharose column containing the original phosphopeptide
immunogen prepared using Sulpholink-Sepharose (Promega).
Immunofluorescence and nuclear localization assays.
Cos-1
cells were transfected on glass coverslips with 2 µg of
pCMV1-Smad2-GFP together with 2 µg of empty pCMV1 vector or pCMV1-Cam
kinase II1-290 as indicated in the figure legends. The
cells were starved in 0.5% fetal calf serum and treated with TGF-
as indicated. Cells were then fixed in 3% paraformaldehyde, permeabilized with 0.1% Triton X-100, fluorescence visualized with
mounting medium containing DAPI (4',6'-diamidino-2-phenylindole), and
examined by confocal microscopy. Cotransfection with Cam kinase II1-290 was confirmed with anti-Cam kinase II antibody and tetramethyl rhodamine isocyanate (TRITC) secondary antibody.
Immunoprecipitation and immunoblotting.
HEK-293 cells were
transiently transfected with expression constructs for Smads alone or
in combination with the constitutively active type I TGF- receptor
and Cam kinase II. Cells were lysed at 4°C with 1 ml of lysis buffer
(50 mM HEPES [pH 7.5] containing 150 mM NaCl, 5 mM EDTA, 10%
glycerol, 1% Triton X-100, and 50 mM sodium fluoride). Clarified
lysates were then incubated with 10 µg of anti-HA or anti-FLAG M2
monoclonal antibodies, together with 20 µg of polyclonal rabbit
anti-mouse IgG and 30 µl of prewashed protein A-Sepharose. After
2 h at 4°C, immunoprecipitates were washed four times with 1 ml
of wash buffer (lysis buffer plus 0.1% Triton X-100). Samples were
separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis
(SDS-PAGE) and exposed to film (Kodak X-Omat). For immunoblotting,
proteins were transferred onto nitrocellulose and probed with anti-HA,
anti-FLAG, or anti-GFP antibodies that were visualized using the ECL
System (Amersham).
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RESULTS |
Inhibition of TGF--dependent transcriptional activity by
Ca2+ and Cam kinase II.
Receptor tyrosine kinases
(RTKs), such as the EGF and PDGF receptor families, activate multiple
signaling pathways. RTKs can also raise cytoplasmic Ca2+
levels following the recruitment of phospholipase C
and subsequent breakdown of phosphoinositides to inositol trisphosphate, causing release of Ca2+ from intracellular stores (reviewed in
reference 38). In this study, we have investigated
whether both Ca2+ signaling and Cam kinase II
activated in response to RTK signaling could affect TGF--dependent
responses. Thapsigargin, a reagent that inhibits the
Ca2+-ATPase pump to raise intracellular
Ca2+, completely abolished TGF- induction of the
endogenous plasminogen-activator inhibitor 1 (PAI-1) gene in Cos-1
cells (Fig. 1A). A similar
response was found following transfection of Cos-1 cells with the
3TP-lux reporter, which contains TGF- response elements for both
PAI-1 and collagen type 1 linked to luciferase expression. TGF-
increased luciferase activity three- to fourfold, and this effect was
completely blocked by pretreatment with thapsigargin (Fig. 1B). To
confirm that this inhibition was mediated through endogenous Cam kinase II, we used a specific water-soluble inhibitor, KN-93. In the presence
of KN-93, thapsigargin-mediated inhibition of transcription is almost
completely restored (Fig. 1B). Further confirmation for the involvement
of Cam kinase II in the thapsigargin-mediated inhibition was sought
using a constitutively active form of this enzyme. The functional
kinase activity of Cam kinase II is tightly regulated by a C-terminal
autoinhibitory domain, and removal of this region in the Cam kinase
II1-290 construct generates a constitutively activated
form of enzyme that no longer requires Ca2+-calmodulin for
activation (14). Cam kinase II1-290 blocked 3TP-lux reporter activation to an extent similar to that of
thapsigargin (Fig. 1B). Since the 3TP-lux promoter contains three AP-1
sites, we also examined whether Cam kinase II1-290 could
prevent activation of the more specific Smad-FAST-1-restricted ARE-lux reporter. ARE-lux contains DNA sequences derived from the
Xenopus Mix.2 gene that convey TGF--activin
responsiveness through complexes of Smads and FAST-1 (12).
In transfected Cos-1 cells, TGF--induced luciferase activity through
ARE-lux approximately fourfold, and this response was again completely
abolished by thapsigargin and to a greater extent by coexpression with
Cam kinase II1-290 (Fig. 1C). It is unlikely that Cam
kinase II1-290 is mediating this effect by overall
inhibition of cellular transcriptional machinery, since other
promoters, such as the fos AP-1-like element can be stimulated by the
same constitutively active enzyme (3). The
thapsigargin-mediated inhibition could also again be reversed by the
Cam kinase II inhibitor KN-93 (Fig. 1C). In control experiments, treatment of cells with KN-93 and/or thapsigargin had no effect on
basal 3TP-lux and ARE-lux transcriptional activity in the absence of
TGF- (Fig. 1B and C).
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FIG. 1.
Inhibition of TGF--dependent transcriptional
responses by Cam kinase II. (A) The expression of the PAI-1 gene was
monitored in Cos-1 cells by semiquantitative PCR as described in
Materials and Methods. In some instances cells were pretreated with 1 µM thapsigargin in DMSO and then stimulated with 5 ng of TGF- per
ml for 15 h. Expression of GAPDH was monitored as an internal
control. Cos-1 cells were transiently transfected with 2 µg of
pCMV1-Cam kinase II1-290 or empty pCMV1, together with 2 µg of 3TP-lux reporter plasmid (B), or 2 µg of ARE-lux reporter
plasmid (C). In some instances cells were pretreated with 1 µM
thapsigargin in DMSO and then stimulated with 5 ng of TGF- per ml
for 15 h (black bars) as indicated. Some cells were also
pretreated for 1 h with the specific Cam kinase II inhibitor,
KN-93, at a concentration of 10 µM. Control cells, in the absence of
TGF-, were also treated with either KN-93 or KN-93 and
thapsigargin.
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Phosphorylation of Smad proteins by Cam kinase II.
Consensus
phosphorylation sites for Cam kinase II are RXXS/T, and one of these at
serine-465 overlaps with a site of phosphorylation by the type I
TGF- receptor kinase (Fig. 2A). We
have also recently identified an alternative Cam kinase II consensus
motif, SXD, that shows a preference for a hydrophobic amino acid at the
X position (20). Four SXD consensus sites are found in Smad2
at serine-110, -227, -240, and -260, and three of these fulfill the requirement for a hydrophobic residue (Fig. 2A). These sites are clustered in or around the linker region, and an additional site is
found in the middle of the MH1 domain at serine-110 (Fig. 2A). Bacterially expressed GST fusion proteins spanning these consensus sites were prepared and used as in vitro substrates for purified Cam
kinase II. Full-length Smad2 is efficiently phosphorylated by Cam
kinase II, and this was prevented by the mutation of serine-110, -240, and -260 to alanine in the Smad2-CK3SA construct (Fig. 2B). Shorter
fusion proteins representing individual sites revealed that serine-110,
-240, and -260 are sites for Cam kinase II, whereas serine-465 within
the RXXS consensus and serine-227 are not phosphorylated (Fig. 2B). The
phosphorylation of serines-110, -240, and -260 was confirmed by
individual mutation of these sites to alanine in the shorter GST fusion
proteins, which were no longer targeted by Cam kinase II in vitro (Fig.
2B). Phosphorylation of Smad2 by Cam kinase II in vitro occurs only on
serine residues, as determined by two-dimensional phosphoamino acid
analysis (Fig. 2C).
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FIG. 2.
In vitro mapping of Cam kinase II phosphorylation sites
in Smad2. (A) Schematic representation of Smad2 highlighting the linker
region and the highly conserved MH1 and MH2 domains. The location and
sequence of putative RXXS and SXD consensus Cam kinase II sites are
indicated. (B) Smad2-GST fusion proteins were prepared and
phosphorylated in vitro with Cam kinase II as described in Materials
and Methods. Samples were separated by SDS-12.5% PAGE, and gels were
either stained with Coomassie blue (C/B) or dried and exposed to X-ray
film (32P). The migration of autophosphorylated Cam kinase II (*) and
full-length Smad2-GST ( ) are indicated. (C) Separation of
phosphoamino acids in GST-S2-WT (residues 1 to 467) phosphorylated with
Cam kinase II. GST-S2-WT was separated by SDS-12.5% PAGE, blotted
onto PVDF membrane, and acid hydrolyzed, and phosphoamino acids were
separated by thin-layer chromatography (TLC). The migration of the
following phosphoamino acids is indicated: phosphoserine
(p-ser), phosphothreonine (p-thr), and
phosphotyrosine (p-tyr).
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We then examined whether Cam kinase II
1-290 could
phosphorylate any of the pathway-restricted Smads in vivo by
coexpressing
epitope-tagged Smad constructs in HEK-293 cells
metabolically
labeled with [
32P]orthophosphate.
Immunoprecipitated HA-Smad2 shows a basal degree
of phosphorylation
that increases approximately fivefold in the
presence of Cam kinase
II
1-290 (Fig.
3A).
Phosphorylation
of HA-Smad3 increases about twofold, and FLAG-Smad4,
which is
nonphosphorylated in the basal state, is also an in vivo
substrate
for Cam kinase II, although this is relatively weak compared
to
Smad2, and the significance of this requires further study (Fig.
3A). Mutation of serine-110, -240, and -260 to alanine in
Smad2-CK3SA
abolishes most of the in vivo phosphorylation by Cam kinase
II
1-290 (Fig.
3A). Smad2 also appears to be the preferred
substrate, and
two-dimensional phosphoamino acid analysis indicates
that basal
phosphorylation occurs predominantly on serine with some
phosphorylation
of threonine and that Cam kinase II
1-290
significantly increases
both phosphoserine and to a lesser extent
phosphothreonine (Fig.
3B). Quantitation indicates that Cam
kinase II
1-290 increases
phosphoserine by about 10-fold
and phosphothreonine by approximately
3-fold and that, overall, there
is 10-fold more phosphoserine
(Fig.
3C). These data contrast with the
presence of only phosphoserine
in vitro (Fig.
2C) and suggest that Cam
kinase II might also activate
other kinases in vivo that can target
Smad2 at specific threonines.
These data might also explain why Smad2
phosphorylation is not
completely prevented by the mutation of
serine-110, -240, and
-260 to alanine in the Smad2-CK3SA mutant and
that this could
be due to residual threonine phosphorylation (Fig.
3A).
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FIG. 3.
Smads are substrates for Cam kinase II in vivo. HEK-293
cells were transfected with HA-Smad2, HA-Smad2-CK3SA, HA-Smad3, or
FLAG-Smad4 in the presence or absence of Cam kinase
II1-290 and metabolically labeled with
[32P]-orthophosphate. Cell lysates were
immunoprecipitated either with anti-flag M2 antibody or anti-HA
antibody. (A) Immunoprecipitates were separated by SDS-10% PAGE and
stained with Coomassie blue (C/B) to detect total Smad protein, or
phosphoproteins were visualized by autoradiography (32P). (B) HA-Smad2
immunoprecipitates were blotted onto PVDF, HA-Smad2 proteins acid were
hydrolyzed, and phosphoamino acids were separated by TLC. The migration
of the following phosphoamino acids is indicated: phosphoserine
(p-ser), phosphothreonine (p-thr), and
phosphotyrosine (p-tyr). (C) Radioactive phosphoamino acids
were scraped from the TLC plate and quantitated by Cerenkov counting.
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Multiple growth factor receptors induce downstream phosphorylation
of Smad2 at serine-240.
To monitor the phosphorylation status of
the Cam kinase II sites in vivo, we next attempted to generate
phosphopeptide-specific antisera against all three sites using Smad2
synthetic peptide immunogens. Initial screening of the resulting
antisera indicated that both phosphoserine-110- and
phosphoserine-260-containing peptide antisera reacted with both
phosphorylated and nonphosphorylated Smad2 (data not shown). However,
immunoaffinity-purified antisera raised against the
phosphoserine-240-containing peptide reacted exclusively with Smad2
when coexpressed with constitutive Cam kinase II1-290
(Fig. 4A). Mutation of serine-240 to
alanine in Smad2-240SA completely abolished immunoreactivity against
the anti-PS240 antiserum (Fig. 4A). We then used this antiserum to examine whether other growth factor receptors could signal downstream to induce phosphorylation of the negative regulatory site at serine-240 in Smad2. In this instance, 293-HEK cells were cotransfected with HA-Smad2, together with the full-length EGF receptor, or chimeric receptors comprising the extracellular domain of the EGF receptor connected to the respective PDGF receptor (EP-R) or HER2/HER-1/2 intracellular domains. These chimeras have a functional EGF ligand binding domain and mediate cytoplasmic responses that reflect the
nature of the intracellular domain (27, 39). Both PDGF receptor and HER2 coexpression induced a significant level of phosphorylation at serine-240 (Fig. 4A). The EGF receptor induced weaker phosphorylation at serine-240 and, interestingly, a significant degree of phosphorylation was seen in the presence of the
constitutively active type I TGF- receptor (Fig. 4A).
Phosphorylation at serine-240 in Smad2 by the kinase domains of
HER2, TGF- receptor, and PDGF receptor was prevented by the
selective Cam kinase II inhibitor KN-93, indicating that this event was
mediated through endogenous Cam kinase II in HEK-293 cells (Fig. 4A).
We then treated HepG2 cells with the growth factors TGF-, EGF, and
PDGF to examine whether cells expressing physiological levels of
receptors for these ligands could induce phosphorylation of serine-240
on endogenously expressed Smad2. All three ligands induced a
significant degree phosphorylation of serine-240 in Smad2, although in
this system we found that the response with EGF was more pronounced,
which may reflect differences in cell type characteristics or
differential receptor expression levels (Fig. 4B). Importantly, this
growth factor-mediated phosphorylation could be inhibited by KN-93,
indicating that the response was likely to be mediated through
downstream activation of endogenous Cam kinase II (Fig. 4B).
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FIG. 4.
Phosphorylation of serine-240 occurs downstream of
multiple growth factor receptors. (A) HA-tagged Smad2 was expressed in
HEK-293 cells in the presence or absence of Cam kinase
II1-290 and immunoprecipitated with anti-HA, and samples
were probed by Western blotting against anti-HA or anti-PS240
antibodies. Equivalent expression levels were monitored in whole
lysates by anti-HA Western blotting. Expression of Cam kinase
II1-290 was confirmed by using specific antisera (data not
shown). HA-tagged Smad2 was also expressed in HEK-293 cells in the
presence or absence of the constitutively active type I TGF-
receptor (TGFRI*), the human EGF receptor (EGFR), or chimeric
receptors comprising the extracellular domain of the EGF receptor
connected to the respective PDGF (EP-R) or HER2 (HER-1/2) intracellular
domains. The EGF receptor and chimeric receptors were activated with
100 ng of EGF per ml for 30 min immediately prior to lysis. Samples
were immunoprecipitated with anti-HA, and samples were probed by
Western blotting against anti-HA or anti-PS240 antibodies. Equivalent
expression levels were monitored by anti-HA blotting, and the
expression of receptors was confirmed with specific antisera (not
shown). In some instances, cells were pretreated for 1 h with the
specific Cam kinase II inhibitor, KN-93, at a concentration of 10 µM.
(B) HepG2 cells were stimulated for 30 min with the indicated growth
factors. In some instances, cells were pretreated for 1 h with the
specific Cam kinase II inhibitor, KN-93, at a concentration of 10 µM.
Cells were lysed, and samples were probed by Western blotting against
Smad2 or PS-240.
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Nuclear translocation of Smad2 is prevented by Cam kinase II.
We then examined whether Cam kinase II might affect the subcellular
localization of Smad2 analogous to Erk-MAP kinase preventing Smad1 and
Smad2 nuclear translocation (24, 25). GFP-Smad2 was
expressed in Cos-1 cells, and approximately 60% of transfected cells
showed nuclear localized Smad2 following TGF- stimulation relative
to 13% in unstimulated controls (Fig.
5A). Overexpression of Cam kinase
II1-290 prevented GFP-Smad2 from localizing to the nucleus
(Fig. 5A). A similar, or slightly enhanced, degree of TGF--induced
nuclear translocation was seen with Smad2-CK3SA in which Cam kinase II
sites at serine-110, -240, and -260 are mutated to alanine; however,
this was not prevented by overexpression of Cam kinase
II1-290 (Fig. 5B).
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FIG. 5.
Cam kinase II regulates the subcellular localization of
Smad2-GFP. Smad2-GFP fusion proteins were expressed in Cos-1 cells,
grown in 0.5% fetal calf containing medium, and stimulated 48 h
posttransfection with TGF- for 15 h. The percentage of Smad2
localized to the nucleus was determined by counting 100 immunofluorescence-positive cells and is denoted in the top left corner
of each image. Cos-1 cells were also transfected with Smad2-GFP,
together with Cam kinase II1-290, and the percentage of
nuclear-positive cells was assessed as described above only in cells
expressing both the Smad and Cam kinase. Cotransfection was confirmed
with primary Cam kinase II mouse monoclonal antibody (anti-Cam kinase
II) and secondary TRITC-conjugated goat anti-mouse antibody. (A)
Wild-type Smad2. (B) Smad2-CK3SA.
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Cam kinase II induces Smad2-Smad4 interactions independently of
TGF- receptor activation while preventing TGF--dependent
Smad2-Smad3 interactions.
Receptor-mediated phosphorylation of the
C-terminal serines in pathway-restricted Smads by the TGF-
receptor kinase is required for transcriptional activity and
facilitates both homo-oligomerization and the hetero-oligomerization of
Smad2 with Smad3 and Smad4 (23). We therefore examined
whether Cam kinase II could disrupt these interactions by coexpressing
combinations of HA-, FLAG-, or GFP-tagged Smads in HEK-293 cells,
together with the constitutively active type I TGF- receptor or Cam
kinase II1-290. The formation of HA-Smad2 and GFP-Smad2
homo-oligomers was identified by immunoprecipitation with anti-HA, and
the induction of this interaction in the presence of the constitutively
active type I TGF- receptor was not affected by Cam kinase
II1-290 (Fig. 6A). The
HA-Smad2-FLAG-Smad4 hetero-oligomer was identified by anti-FLAG
immunoprecipitation and is induced in the presence of the
constitutively active type I TGF- receptor (Fig. 6B). However,
surprisingly, we found that Cam kinase II1-290 alone also
significantly induces Smad2-Smad4 hetero-oligomerization (Fig. 6B).
Similar results were obtained when Smad4 was coexpressed with
Smad2-CK3SA, indicating that this effect was not due to phosphorylation
at serine-110, -240, and -260 in Smad2 (data not shown). We then probed
the anti-FLAG immunoprecipitates with a phosphopeptide-specific
anti-PS2 antibody raised against the C-terminal TGF- receptor
phosphorylation sites in Smad2 (35). Anti-PS2 reacts only
with Smad4-associated Smad2 when coexpressed with the constitutively
active type I TGF- receptor and does not react with Smad4-associated
Smad2 when expressed with Cam kinase II1-290 alone (Fig.
6B). These data confirm that this induction of Smad2-Smad4
hetero-oligomerization by Cam kinase II1-290 is not due to
activation of endogenous TGF- receptors or to increased endogenous
expression of TGF- ligands.
View larger version (27K):
[in this window]
[in a new window]
|
FIG. 6.
Cam kinase II induces Smad2-Smad4 interactions
independently of TGF- receptor activation. (A) HEK-293 cells were
transfected with N-terminally tagged HA-Smad2 and GFP-Smad2 in the
presence or absence of the constitutively active type I TGF-
receptor (TGFR*), constitutively active Cam kinase II (Cam kinase
II1-290), or both (TGFR* plus Cam kinase
II1-290). Cell lysates were immunoprecipitated with
anti-HA, and samples were probed by immunoblotting against anti-HA or
anti-GFP antibodies. Expression of the TGF- receptor and Cam kinase
II was confirmed using specific antisera (data not shown). (B) HEK-293
cells were transfected with N-terminally tagged HA-Smad2 and
C-terminally tagged FLAG-Smad4 in the presence or absence of the
constitutively active type I TGF- receptor (TGFR*),
constitutively active Cam kinase II (Cam kinase II1-290),
or both (TGFR* plus Cam kinase II1-290). Cell lysates
were immunoprecipitated with anti-FLAG, and samples were probed by
immunoblotting against anti-HA, anti-FLAG, or anti-PS2 antibodies.
Expression of the TGF- receptor and Cam kinase II was confirmed by
using specific antisera (data not shown).
|
|
We then examined whether Smad2 and Smad3 hetero-oligomerization was
affected by coexpressing HA-Smad2 and GFP-Smad3 in HEK-293
cells and
monitoring interactions in anti-HA immunoprecipitates.
The
constitutively active type I TGF-
receptor induced the formation
of
Smad2-Smad3 hetero-oligomers; however, Cam kinase II
1-290 completely prevented TGF-
-induced Smad2-Smad3 hetero-oligomerization
(Fig.
7A). We then performed the same
experiment with Smad3 and
Smad2-CK3SA and found that the loss of
interaction in the presence
of Cam kinase II
1-290 was
restored (Fig.
7B). This indicates
that the Smad2-Smad3 interaction can
be directly regulated by
Cam kinase II-dependent phosphorylation at
serine-110, -240, and
-260 in Smad2.
View larger version (28K):
[in this window]
[in a new window]
|
FIG. 7.
TGF--dependent Smad2-Smad3 interactions are prevented
by Cam kinase II. HEK-293 cells were transfected with N-terminally
tagged HA-Smad2 (A) or HA-Smad2-CK3SA (B), together with GFP-Smad3, in
the presence or absence of the constitutively active type I TGF-
receptor (TGFR*), constitutively active Cam kinase II (Cam kinase
II1-290), or both (TGFR* plus Cam kinase
II1-290). Cell lysates were immunoprecipitated with
anti-HA, and samples were probed by immunoblotting against anti-HA or
anti-GFP antibodies. Expression of the TGF- receptor and Cam kinase
II was confirmed using specific antisera (data not shown).
|
|
| |
DISCUSSION |
Smads play an essential role in transmitting activin, BMP, and
TGF- signals from the cell surface to the nucleus. More recently, it
is becoming apparent that Smads are also extensively regulated by
direct input from a variety of receptor signaling pathways (reviewed in
reference 30). In the present study, we have shown that Smad function can be directly controlled by cytoplasmic
Ca2+-dependent kinases, specifically the ubiquitously
expressed Ca2+-calmodulin-dependent Cam kinase II. These
observations are also consistent with the recent report that
Ca2+-calmodulin can regulate Smad function (48).
The exact mechanism by which phosphorylation at serine-110, -240, and
-260 in Smad2 inhibits Smad-TGF--dependent gene transcription is
likely to be complex. Important features of this process are likely to
involve the location of Cam kinase II phosphorylation sites within
critical Smad functional domains. The recent crystal structure of the
conserved MH1 domain of Smad3 indicates that the main DNA-binding motif
is an 11-residue hairpin that is embedded within the major groove
of DNA (40). Although Smad2 is not able to bind to DNA
directly through this motif, its effector function in the conserved MH2
domain can be repressed by direct contact with the MH1 domain
(21). The Cam kinase II site in Smad2 at serine-110 is on
the edge of the hairpin motif, and it is interesting to speculate
that phosphorylation at this site could inhibit Smad effector function
by stabilizing repressive interactions between the MH1 and the MH2
domains. Similarly, these interactions could also be affected by Cam
kinase II phosphorylation at the serine-260 that is within the
conserved MH2 domain. The third phosphorylation site at serine-240 lies
within the linker region and is immediately adjacent to several
Ser/Thr-Pro sites that are targets for the Ras/Erk/MAP kinase pathway
(25). Phosphorylation at these sites also represses Smad2
function, and it is possible that the stoichiometry of Erk-MAP kinase
modification could be potentiated by Cam kinase targeting of the
adjacent serine-240 site.
The prevention of TGF--dependent Smad2 nuclear translocation by Cam
kinase II represents an important mechanism for the control of
Smad-TGF- signaling. Recently, the presence of a distinct nuclear
localization signal in the MH1 of Smad3 was shown to determine the
ligand-induced nuclear translocation of Smad3 (43).
Phosphorylation of Smad2 by Cam kinase II could mask this domain or,
alternatively may affect interactions with proteins that regulate the
export of transcription factors from the nucleus such as the nuclear export factor CRM-1 (31). In this context of the regulation of Smad2 nuclear import and export it is also important to consider the
normal distribution and subcellular localization of Cam kinases. In the
present study, we have used a constitutively active truncated form of
the neuronal Cam kinase II- that does not contain a nuclear localization sequence but is sufficiently small in size to be able to
diffuse freely between the nucleus and cytoplasm. Multifunctional Cam
kinases comprise a multigene family consisting of Cam kinase I, Cam
kinase II, and Cam kinase IV, which display a common substrate specificity and are widely distributed in mammalian tissue (reviewed in
reference 5). The Cam kinase II subfamily is derived
from four related genes, namely, , , , and 
. The
B, B, and A isoforms share
a common core nuclear localization sequence, and nuclear localization
in vivo of B and B has been reported
(7). Nuclear and cytoplasmic isoforms can be found in most
tissues, although some regions of the brain (7) and also the
heart (17) express predominantly nuclear forms of Cam kinase
II. These observations raise the possibility that, under normal
physiological circumstances, the degree of regulation of Smad signaling
by Cam kinase and the manner in which this might be achieved is likely
to be very tissue specific. In tissues that express cytoplasmic
isoforms of Cam kinase II, activation of this enzyme would block
TGF--dependent gene responses by preventing entry of the Smad
transcriptional complex into the nucleus. Alternatively, in those
tissues expressing nuclear forms of Cam kinase II, the
TGF--dependent assembly and translocation from the cytoplasm would
be unaffected. However, once inside the nucleus activated Cam kinase II
could target the Smad complex to disrupt the Smad2-Smad3 interaction
and directly affect gene responses in situ. The essential role of Smad3
in efficient Smad-TGF--dependent transcriptional activity has been highlighted by a number of recent gene knockout studies (4, 44,
47). Our results also suggest that inhibition of
TGF--dependent transcriptional responses described in the present
study could be explained in part by the fact that Cam kinase II
prevents the TGF--dependent recruitment of Smad3 into the Smad
transcriptional complex.
Recent accumulating evidence has also suggested a role for
Ca2+ in controlling some of the actions of TGF- (2,
22). The type I TGF- receptor interacts with the
immunophilin FKBP12 (13), a ubiquitously expressed
protein that can inhibit the Ca2+-dependent protein
phosphatase calcineurin (28). FKBP12 and calcineurin also
control cytoplasmic calcium levels by stabilizing the inositol
1,4,5-trisphosphate and ryanodine receptors (6, 9).
Interestingly, we find that activation of the TGF- receptor can also
induce the downstream phosphorylation of the regulatory Cam kinase II
site at serine-240 in Smad2. This raises the possibility that this may
form part of an intrinsic negative feedback inhibitory loop in which
cells receive a pulsed signal input through the Smad-TGF- system.
Ca2+ signals can occur as single transients, as
oscillations, or as a sustained plateau, and this triggers the
differential activation and/or inhibition of downstream mediators to
determine signal response, strength, and specificity (16).
Cam kinase II is also thought to be a major decoder of Ca2+
oscillation since its kinase activity reflects the size and frequency of Ca2+ spikes (15). In this regard the
TGF--dependent mobilization of intracellular Ca2+ in
some cell types requires incubation times of more than 1 h (32), whereas Ca2+ mobilization can be
instantaneous in response to RTK signaling. Therefore, differences in
amplitude, duration, and the scheduled delivery of various growth
factor stimuli would be critical in determining the final outcome of
the biological response. In this regard, it will be of interest in
future studies to thoroughly analyze the time course and concentration
dependence of various growth factor agonists by utilizing both the
anti-PS240 (inactive Smad2) and anti-PS2 (active Smad) antisera.
We have also shown that enhanced downstream Cam kinase II signaling in
response to RTK-induced Ca2+ mobilization can upregulate
phosphorylation at serine-240 in Smad2. These observations have
important implications for normal cellular homeostasis, cellular
proliferation, and also neoplastic transformation. TGF- is a
classical suppressor of cell growth, and disruption of components of
the TGF- signaling cascade, including Smads, has been demonstrated
in several types of cancer. Permanent coupling of oncogenic HER2 to
phospholipase C activity and Ca2+ mobilization is also
seen in tumor cells (34). The HER2 gene is amplified in a
variety of human adenocarcinomas arising at a number of sites,
including the breast, colon, and stomach (reviewed in reference
33). Therefore, the present data showing increased phosphorylation of the negative regulatory site (serine-240) in Smad2
by overexpression of the chimeric HER-1/2 protein kinases raises the
intriguing possibility that an important feature of HER2-mediated
oncogenic transformation could involve the shutdown of the
TGF--Smad tumor-suppressive pathway.
In summary, we have defined a novel role for Cam kinase II activation
in the regulation and differential control of Smad-TGF- function.
The molecular detail of this inhibition incorporates phosphorylation at
consensus sites in Smad2, disruption of Smad protein complex formation,
and effects on Smad subcellular localization. We propose that
costimulatory input from multiple growth factors leading to a
differential Ca2+ mobilization provides a potent cross-talk
and intrinsic feedback program that will ultimately coordinate complex
patterns of TGF--dependent gene regulation and cellular
responsiveness. An important goal will be to correlate differential
expression patterns and cytosolic-nuclear compartmentalization of
members of the Cam kinase family with the tissue-specific integration
of growth factor signals. Furthermore, it will be important to address
the complex issue of spatial and temporal Ca2+ mobilization
in response to TGF- and other environmental stimuli, particularly in
the context of recent reports of the direct control of specific gene
transcription by nuclear Ca2+ (37). Finally, the
phosphopeptide antisera generated in this study should permit a
detailed analysis of the importance of Smad2 transmodulation following
oncogenic RTK overexpression in human cancer.
| |
ACKNOWLEDGMENTS |
We thank Tony Means, Hans-Hermann Gerdes, Carl-Henrik Heldin,
Jeffrey Wrana, Scott Kern, Rik Derynck, Malcolm Whitman, and Axel
Ullrich for kindly providing cDNA constructs and Peter ten Dijke
for the PS2 antiserum. We also thank Dylan Edwards and Simak Ali for
helpful discussions.
This study was supported by Wellcome Trust grant 045206/Z/95/Z (A.C.),
The Special Trustees of Charing Cross Hospital (A.C.), and a
Livingstone Studentship from Imperial College (S.J.W.).
| |
FOOTNOTES |
*
Corresponding author. Present address: School of
Biological Sciences, University of East Anglia, Norwich NR4 7TJ, United
Kingdom. Phone: 44-1603-593551. Fax: 44-1603-592250. E-mail:
a.chantry{at}uea.ac.uk.
Present address: Molecular Angiogenesis Laboratory, Imperial Cancer
Research Fund, Institute of Molecular Medicine, University of Oxford,
Oxford OX3 9DS, United Kingdom.
| |
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Molecular and Cellular Biology, November 2000, p. 8103-8111, Vol. 20, No. 21
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Abstract
Introduction
