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J. Biol. Chem., Vol. 277, Issue 48, 46226-46232, November 29, 2002
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From the Department of Biochemistry, Boston University School of
Medicine, Boston, Massachusetts 02118
Received for publication, July 31, 2002, and in revised form, September 6, 2002
We demonstrate that exposure of post-confluent
3T3-L1 preadipocytes to insulin, isobutylmethylxanthine (MIX),
dexamethasone (DEX), and fetal bovine serum induces a rapid but
transient activation of MEK1 as indicated by extensive phosphorylation
of ERK1 and ERK2 during the initial 2 h of adipogenesis.
Inhibition of this activity by treating the cells with a MEK1-specific
inhibitor (U0126 or PD98059) prior to the induction of differentiation
significantly attenuated the expression of peroxisome
proliferator-activated receptor (PPAR) The differentiation of preadipocytes into mature
insulin-responsive adipocytes involves exposure of a confluent,
quiescent population of cells to a variety of effectors that activate a cascade of transcription factors commencing with CCAAT/enhancer-binding protein (C/EBP)1 The goal of these studies was to determine whether the MEK/ERK
signaling pathway regulates expression and/or activity of the adipogenic transcription factors during the early phase of
adipogenesis. The results demonstrate that exposure of 3T3-L1
preadipocytes to dexamethasone (DEX), isobutylmethylxanthine (MIX),
insulin (INS), and fetal bovine serum (FBS) induces a robust, transient activation of the MEK/ERK pathway during the initial 1-2 h
post-induction and that this activity is required for subsequent
differentiation. Insulin, together with elevated cAMP levels (MIX
treatment), appears to be the principal regulator of MEK activity, and
promotes differentiation by enhancing the expression of C/EBP Cell Culture--
3T3-L1 preadipocytes were cultured in growth
medium (Dulbecco's modified eagle medium (DMEM) containing 10% calf
serum) until confluent and were then maintained in the same medium for
an additional 2-3 days (5, 20, 21). Differentiation was induced at
2-3 days post-confluence by addition of 1 µM DEX, 0.5 mM MIX, 1.67 µM INS, and 10% FBS for 48 h, at which time the medium was replaced with DMEM containing 0.41 µM insulin and 10% FBS (22). For experiments performed
with U0126 or PD98059, post-confluent 3T3-L1 preadipocytes were
preincubated for 30 min or one hour, respectively, prior to induction
of differentiation.
Reporter Plasmids, Transfections, and CAT Assays--
The
C/EBP Analysis of Protein--
Cells were washed twice with cold
phosphate-buffered saline and scraped in Western lysis buffer (300 µl/60 mm plate or 500 µl/100 mm plate) consisting of the following:
20 mM Tris-HCl, pH 7.4, 150 mM NaCl, 10%
glycerol, 2% Nonidet P-40, 1 mM EDTA, pH 8.0, 20 mM sodium fluoride, 30 mM NaPPi, 0.2%
SDS, 0.5% sodium deoxycholate, 1 mM phenylmethylsulfonyl
fluoride, 1 mM dithiothreitol, 1 mM sodium
vanadate, leupeptin, and aprotonin. Samples were incubated on ice with
frequent vortexing for 15 min and centrifuged for 20 min at 14,000 rpm
at 4 °C. Protein content of each supernatant was quantified using a
BCA kit (Pierce). Eighty micrograms of each supernatant sample
of proteins was separated by electrophoresis through a 12%
polyacrylamide gel and transferred to 0.45 µm Immobilin-P polyvinylidene difluoride membrane (Millipore Corp., Bedford, MA).
Following transfer, membranes were blocked with milk and probed with
the following primary antibodies: activated ERK1/ERK2 (New England
Biolabs, Inc., Beverly, MA.); C/EBP To understand the signaling events regulating the expression of
the adipogenic transcription factors during the early phase of
adipogenesis, we focused on the MEK/ERK pathway. To determine the
precise time of activation of MEK1 activity during the differentiation of 3T3-L1 preadipocytes, confluent cells were exposed to DEX, MIX,
insulin, and FBS. Fig. 1A
demonstrates that these effectors induce a rapid (within 5 min) but
short-lived activation of MEK1, as indicated by its ability to
phosphorylate ERK1 and ERK2, which subsides to quiescent levels by
6 h post-stimulation; interestingly, there is a second burst of
activity at 12 h. The immediate early activation of this signaling
pathway is followed by progression of the cells through the
G1 phase of the cell cycle (data not shown) and subsequent
differentiation as indicated by the induction of C/EBP The data in Fig. 1A demonstrate that the adipogenic
hormones, acting as both mitogens and inducers of terminal
differentiation, stimulate a rapid, transient activation of the MEK/ERK
signaling pathway. Because adipogenesis is induced by exposure of
confluent preadipocytes to a combination of hormones, it was important
to determine which of the effectors contributes to the activation of
MEK1. In the experiment shown in Fig. 1B, total protein was harvested 10 min following treatment of cells with the indicated effectors in the presence of FBS and was subjected to Western blot
analysis using an anti-activated ERK antibody. Lane 3 of this figure demonstrates that elevation of cAMP levels by MIX (i.e. activation of PKA) is a principal mediator of
ERK2 activation, and pretreatment of the cells with the MEK1 inhibitor
PD98059 attenuates the effect of MIX (lane 4). Insulin was a
weak activator of ERK2 (lane 5) but was unable to activate
ERK1; nevertheless, it did potentiate the phosphorylation of both of
these kinases by MIX in the presence or absence of DEX (compare
lanes 11 and 13 with lanes 3 and
7). Furthermore, this process was sensitive to treatment of
the cells with PD98059 (lanes 12 and 14),
suggesting that insulin and cAMP converge on pathways upstream of MEK1.
Stimulation of the cells with FGF-2 in the presence of insulin, MIX,
and DEX resulted in an even greater burst of MEK1 activity (lane
15), which was only slightly sensitive to PD98059 (lane
16).
Insulin Dose-dependent Activation of MEK Activity and
Adipogenic Gene Expression--
Several studies have demonstrated that
insulin and/or insulin-like growth factor 1 functions as an inducer of
adipogenesis in mouse preadipocytes (6, 14, 24-26). In fact, the data
in Fig. 1B demonstrate that insulin in the presence of MIX
also induces MEK1 activity (lane 11). Consequently, we
questioned whether there is a relationship between these effects of
insulin on 3T3-L1 preadipocytes. Fig. 2
shows an insulin dose-dependent increase in C/EBP The Inhibition of Adipogenic Gene Expression by the MEK Inhibitor
U0126 Occurs in a Dose-dependent Manner and Can Be Reversed
by Exposure of Cells to the PPAR
A previous study (27) showed that attenuation of MEK1 activity with
PD98059 blocked clonal expansion during the early phase of
adipogenesis. We also observed that treatment of 3T3-L1 cells with the
more potent MEK1 inhibitor U0126 had the same effect based on its
ability to block the translocation of proliferating cell nuclear
antigen into the nucleus at 24 h post-induction (data not
shown). Because earlier investigations had suggested that clonal
expansion is a prerequisite for adipogenesis (28, 29), we questioned
whether preadipocytes treated with growth-inhibitory doses of U0126 (10 µM) could be induced to differentiate into adipocytes. To
address this question, preadipocytes were treated with U0126 in the
presence or absence of a potent PPAR FGF-2 Induces Adipogenesis in the Presence of U0126--
Our
previous studies (30) in myogenic cells suggested that FGF-2 was a
significantly more potent activator of the MEK/ERK signaling pathway
than insulin or IGF-1. To investigate the role of FGF-2 in regulating
MEK1 activity during adipogenesis, confluent preadipocytes were exposed
to DEX, MIX, and insulin in the presence or absence of FGF-2 and/or
PD98059. Fig. 5A demonstrates
that FGF-2 induces a prolonged (>12 h) stimulation of MEK1 activity compared with the relatively short-lived (<2 h) activation in its
absence (compare lane 19 with lane 9).
Furthermore, it required several hours of exposure to the MEK inhibitor
PD98059 to completely block the FGF-2-associated phosphorylation of
ERK1/2. In fact, FGF-2 was capable of inducing a significant level of
MEK1 activity in the presence of PD98059 during the initial 4-8 h
post-induction. In light of this observation, we questioned whether
FGF-2 might be capable of attenuating the inhibitory effect of U0126 on
adipogenic gene expression by stimulating MEK1 activity. The experiment
presented in Fig. 5B shows that exposure of preadipocytes to
FGF-2 together with DEX, MIX, and insulin results in a significantly
greater activation of MEK1 at 15 min post-induction than treatment with the adipogenic inducers alone (Fig. 5B, compare lane
5 with lane 3). The intense activation of MEK1 in the
presence of FGF-2 could not be completely abrogated by the MEK1
inhibitor U0126; instead, it was attenuated to levels equivalent to
those measured in the absence of FGF-2 (Fig. 5B, compare
lane 6 with lane 3). Furthermore, this residual
level of MEK1 activity was enough to facilitate the induction of
PPAR The MEK/ERK Pathway Regulates C/EBP After several years of investigation it is becoming apparent that
the differentiation of preadipocytes into mature fat cells is a complex
process involving the interplay of many effectors both positive and
negative that regulate a network of signaling pathways, which
eventually converge on the adipogenic gene program. Some of the
pathways operate to "fine tune" the functions of the mature
adipocyte in response to changes in the overall physiologic status of
the organism. For instance, insulin and Establishing a role for the MEK/ERK pathway in regulating adipogenesis
has been difficult because many of the studies have arrived at
completely opposite conclusions. For instance, several studies (15-19)
have shown that stimulating ERK activity in adipocytes by exposure to
mitogens attenuates adipogenic gene expression by mechanisms that
likely involve phosphorylation and inactivation of PPAR The mechanisms that regulate the extent and duration of ERK activity
might, therefore, play an important role in regulating adipogenic gene
expression. The MAPK phosphatases (MKP-1 and MKP-2) that
dephosphorylate and inactivate ERK1 and ERK2 are potential candidates
for regulating ERK activity during adipogenesis. In fact, MKP-1 and
MKP-2 are immediate early genes that are induced when quiescent cells
are exposed to a variety of extracellular signals including mitogens
(33, 34). It is conceivable, therefore, that insulin induces MKP-1/2
very rapidly during the early phase of adipogenesis so that ERK
activity is confined to a limited but precise period of the
differentiation process. In the case of FGF-2, induction of MKP-1 may
be significantly delayed or attenuated, therefore, facilitating
prolongation of ERK activity as observed in Fig. 5A.
What are the potential roles of the activated forms of ERK1 and ERK2 in
promoting adipogenesis? Studies by others and us (4, 5, 20) have
demonstrated a role for C/EBP Induction of adipogenesis also involves suppression of a host of
negative effectors that act to maintain the preadipocyte in an
undifferentiated state. It is conceivable, therefore, that the MEK/ERK
pathway also operates to suppress the activity of these negative
factors. In this regard, Lane and coworkers (37, 38) have recently
shown that the Sp1 and AP-2 families of transcription factors repress
C/EBP In conclusion, we suggest that the MEK/ERK signaling pathway can affect
adipogenesis in different ways depending on its precise time of
activation during the differentiation process. Future studies aimed at
identifying the targets of the pathway should provide greater insight
into the molecular mechanisms regulating the expression of PPAR We thank Yuhong Xie for technical assistance.
We also thank Drs. David Bernlohr and Andrew Greenberg for antibodies
against aP2 and perilipin, respectively.
*
This work was supported by National Institutes of Health
Grant DK51586 and DK58825.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 20, 2002, DOI 10.1074/jbc.M207776200
The abbreviations used are:
C/EBP, CCAAT/enhancer-binding protein;
PPAR, peroxisome proliferator-activated
receptor;
MAPK, mitogen-activated protein kinase;
IGF-1, insulin-like
growth factor 1;
MEK, mitogen-activated protein
kinase/extracellular signal-regulated kinase kinase;
ERK, extracellular
signal-regulated kinase;
DEX, dexamethasone;
MIX, isobutylmethylxanthine;
FBS, fetal bovine serum;
INS, insulin;
CAT, chloramphenicol acetyltransferase;
FGF-2, fibroblast growth factor-2;
aP2, adipocyte-specific fatty acid-binding protein;
PKA, protein kinase
A.
Activation of MEK/ERK Signaling Promotes Adipogenesis by
Enhancing Peroxisome Proliferator-activated Receptor
(PPAR) and
C/EBP
Gene Expression during the Differentiation of 3T3-L1
Preadipocytes*
ABSTRACT
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INTRODUCTION
EXPERIMENTAL PROCEDURES
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DISCUSSION
REFERENCES
, CCAAT/enhancer-binding
protein (C/EBP) 
, perilipin, and adipocyte-specific fatty
acid-binding protein (aP2). Treating the preadipocytes with
troglitazone, a potent PPAR ligand, could circumvent the inhibition
of adipogenic gene expression by U0126. Fibroblast growth factor-2
(FGF-2), in the presence of dexamethasone, isobutylmethylxanthine, and insulin, induces a prolonged activation of
the MEK/ERK signaling pathway, which lasts for at least 12 h
post-induction, and this activity is less sensitive to the MEK inhibitors. Consequently, preadipocytes treated with U0126 in the
presence of fibroblast growth factor-2 (FGF-2) express normal post-induction levels of MEK activity, and, in so doing, are capable of
undergoing adipogenesis. We further show that activation of MEK1
significantly enhances the transactivation of the C/EBP minimal
promoter during the early phase of the differentiation process.
Our results suggest that activation of the MEK/ERK signaling pathway
during the initial 12 h of adipogenesis enhances the activity of
factors that regulate both C/EBP and PPAR expression.
INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
and
C/EBP
, which ultimately induce the expression of C/EBP and
peroxisome proliferator-activated receptor (PPAR) (1, 2).
Terminal differentiation involves the coordinated regulation of several
programs of gene expression by C/EBP and PPAR, which include the
induction of proteins responsible for insulin sensitivity. Using the
3T3-L1 model of adipogenesis, several investigators have demonstrated a
role for cAMP in activating C/EBP and for glucocorticoids in
inducing C/EBP as well as PPAR (3-5). Insulin, acting through
the IGF-1 receptor, is also required to ensure complete conversion of
preadipocytes into adipocytes (6), but the precise role that it plays
in the process is still unclear. The IGF-1 and insulin receptors are
tyrosine kinases that can activate a series of signaling pathways in
different cell types including the Ras-MAPK pathway. The p42 (ERK2) and
p44 (ERK1) MAPKs are activated by phosphorylation on threonine and
tyrosine residues by the dual specificity kinase MEK1, which induces
their translocation into the nucleus where they activate or repress a
variety of transcription factors involved in growth and differentiation (7). Several laboratories have investigated the role of p42/p44 MAPK in
regulating adipogenesis, but the conclusions are somewhat controversial. Some studies claim that activation of MAPK by various effectors blocks adipogenesis (8-10), whereas others suggest that it
promote preadipocyte differentiation (11-14). It is quite possible that both claims are correct. The distinguishing factor might involve
the precise time of MAPK activation during the initial stages of the
differentiation process. For instance, effectors that activate the
MEK/ERK pathway at late stages of adipogenesis are likely to block
adipogenic gene expression due to a MAPK-dependent phosphorylation of PPAR (15-19). Activation of the pathway early during adipogenesis prior to PPAR expression might, on the other hand, promote differentiation by activating transcription factors operating to initiate PPAR and C/EBP expression.
and
PPAR. Furthermore, FGF-2 is also capable of stimulating adipogenesis
under conditions where MEK activity is limiting.
EXPERIMENTAL PROCEDURES
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EXPERIMENTAL PROCEDURES
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DISCUSSION
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minimal promoter/CAT reporter plasmid corresponding to 
270
to +133 bp of the 5' upstream region of the C/EBP gene was generated
as described previously (23). A stable 3T3-L1 preadipocyte cell line
was established by transfecting the C/EBP/CAT vector along with a
plasmid containing a neomycin gene to facilitate selection with G418. A
single colony of G418-resistant preadipocytes (#4-2 cells) was
selected for expression of the reporter gene and ability to undergo
differentiation in response to DEX, MIX, and insulin. Post-confluent
#4-2 cells exposed to different combinations of DEX, MIX, insulin, and
FBS were harvested at different times and lysed by freeze-thawing. CAT
assays were performed in triplicate on the cell lysates as described
previously (23), and CAT activity was expressed relative to equivalent
amounts of protein in the assay.
C/EBP, and PPAR (Santa
Cruz Biotechnology, Santa Cruz, CA.); aP2/aFABP (gift of Dr. D. Bernlohr, University of Minnesota, St. Paul, MN); perilipin (gift of
Dr. A. Greenberg, Tufts University, Boston, MA). Specific proteins were
identified by further incubation of corresponding membranes with
horseradish peroxidase-conjugated secondary antibodies (Sigma) followed
by treatment with enhanced chemiluminescence (Pierce) according to
manufacturers instructions.
RESULTS
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INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
at 1-2 h. By
2 days post-induction, the cells have switched from growth to terminal
differentiation as revealed by an increase in PPAR, C/EBP, and
perilipin expression.
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Fig. 1.
Insulin and MIX induce a transient activation
of MEK/ERK signaling during the early phase of adipogenesis in 3T3-L1
preadipocytes. A, proliferating 3T3-L1 preadipocytes
(P) were cultured in growth medium until they reached
confluence. At 4 days post-confluence (day 0), the quiescent
cells were exposed to DEX, MIX, FBS, and insulin, and total cellular
protein was harvested at the indicated times. Equal amounts (80 µg)
of protein from each sample was subjected to Western blot analysis
using antibodies specific for phospho (P)-ERK1/2, pan-ERK, C/EBP ,
PPAR, C/EBP, and perilipin. B, post-confluent 3T3-L1
cells maintained in FBS were exposed to various combinations of DEX,
MIX, insulin (INS, 1.67 µM), and FGF-2 (1 nM) in the presence or absence of PD98059 (50 µM). Total protein was harvested at 10 min and subjected
to Western blot analysis using the anti-phospho-ERK1/2 antibody.
,
PPAR, and perilipin gene expression on day 5 of differentiation,
which is preceded by a corresponding insulin dose-dependent
stimulation of MEK1 activity at 10 min post-induction. It is important
to mention, however, that maximal ERK1/2 stimulation occurs at a higher
dose of insulin (>664 nM) than that required for the
stimulation of C/EBP (especially the 42 kDa form) and PPAR, which
occurs around 44 nM. Furthermore, exposure of the cells to
the MEK inhibitor U0126 completely blocks the ability of MEK1 to
phosphorylate ERK1 and ERK2 and also attenuates the expression of
C/EBP, PPAR, and perilipin expression.
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Fig. 2.
Insulin dose-dependent induction
of MEK activity and adipogenic gene expression.
Proliferating 3T3-L1 preadipocytes (P) were cultured in
growth medium until confluence. At 4 days post-confluence (day
0), the cells were exposed to increasing doses of insulin in
medium containing DEX, MIX, and FBS. The MEK inhibitor U0126
(U) was also added to the cultures that were treated with
the highest dose of insulin. Cells were harvested at 10 min (MEK
activity) or at day 5 (adipogenic protein expression), and 40 µg of
whole cell proteins were subjected to Western blot analysis using
antibodies against phospho-ERK, C/EBP , PPAR, and perilipin.
Ligand Troglitazone--
To
determine the optimum dose of U0126 required to inhibit both MEK1
activity and adipogenesis, confluent 3T3-L1 preadipocytes were exposed
to increasing concentrations of the drug for 30 min prior to treatment
with DEX, MIX, insulin, and FBS. The corresponding dose of U0126 was
maintained in the culture medium during the initial 24 h of
differentiation, and cells were harvested at either 15 min (MEK1
activity) or 5 days (adipogenic gene expression) post-induction. The
Western blot presented in Fig. 3
demonstrates a U0126 dose-dependent inhibition of MEK
activity and a corresponding dose-dependent attenuation of
PPAR, C/EBP, and aP2 expression. Inhibition of MEK1 activity by
U0126 had no significant effect on the expression of C/EBP,
suggesting that the MEK/ERK pathway is regulating adipogenesis
downstream of C/EBP expression.
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Fig. 3.
U0126 dose-dependent inhibition
of adipogenic gene expression. 3T3-L1 preadipocytes were induced
to differentiate by exposure of a 4 day post-confluent population of
cells (day 0) to DEX, MIX, INS, and FBS in the presence of
increasing concentrations of the MEK inhibitor U0126. The MEK inhibitor
was added to the individual cultures 30 min prior to the inductive
event and was then removed 24 h later by changing the medium.
Cells were harvested at 15 min (MEK activity) or at day 5 (adipogenic
protein expression), and whole cell proteins were subjected to Western
blot analysis using antibodies against phospho-ERK, C/EBP , C/EBP,
PPAR, and aP2.
ligand troglitazone. Fig.
4 also demonstrates that treatment of the
cells with the MEK1 inhibitor for increasing periods of time attenuates PPAR, C/EBP, and aP2 expression without significantly affecting C/EBP. In fact, an exposure time of 24 h is as effective at
inhibiting adipogenesis as exposure times up to 120 h. These data
are consistent with the notion that the MEK/ERK pathway is acting to
regulate adipogenesis during the first few hours following hormonal
induction (Fig. 1A). More importantly, Fig. 4 demonstrates
that treatment of preadipocytes with troglitazone can rescue the
U0126-associated block in adipogenic gene expression at all three
exposure times in a manner that does not involve reactivation of clonal
expansion by the PPAR ligand (data not shown). These data suggest
that adipogenesis can be induced in preadipocytes that are prevented from undergoing clonal expansion due to the presence of U0126. Furthermore, blocking MEK1 activity does not have any significant deleterious effect on the preadipocytes because they respond to troglitazone by inducing the normal level of C/EBP and aP2
expression (Fig. 4, compare lanes 4, 8, and
12 with lanes 1, 5, and
9).
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Fig. 4.
Troglitazone counteracts the inhibitory
effect of U0126 on adipogenic gene expression. Proliferating
3T3-L1 preadipocytes (P) were grown to confluence, and 4 days later (0) the cells were induced to differentiate by
exposure to DEX, MIX, insulin, and FBS in the presence or absence of
U0126 (10 µM) and/or troglitazone (10 µM).
When troglitazone was present it was added to the cultures along with
the inducers, but U0126 was added 30 min prior to this time. Cells were
exposed to U0126 for the indicated times. Total cellular protein was
harvested at day 5 and subjected to Western blot analysis using
antibodies against PPAR , C/EBP, C/EBP, and aP2.
, C/EBP, and perilipin expression in cells that were also
exposed to U0126 (Fig. 5B, compare lane 6 with lane 4). It is important to mention that the preadipocytes
were only exposed to FGF-2 for the initial 6 h of differentiation
to activate MEK activity during this critical period. Prolonged
exposure of cells to FGF-2 for times greater than 12-24 h inhibits
adipogenesis by mechanisms that may also involve activation of the
MEK/ERK pathway. To confirm the result shown in Fig. 5B and
to determine the dose of FGF-2 required to induce adipogenesis under
conditions where MEK1 activity is limiting, preadipocytes were
stimulated to differentiate in the presence of an inhibitory dose of
U0126 with increasing doses of FGF-2 for 6 h. The cells were then
maintained in culture for 5 days. As observed previously, the level of
MEK1 activity at 10 min post-induction in the presence of U0126 is very
low (Fig. 5C, lane 3). Exposure of the
preadipocytes to FGF-2 in the presence of U0126, however, restores this
activity to normal post-induction levels and in so doing induces
PPAR, C/EBP, and perilipin gene in an FGF-2
dose-dependent manner (Fig. 5C, lanes 3-9).
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Fig. 5.
FGF-2 counteracts the inhibitory effect of
the MEK inhibitor U0126 on C/EBP and
PPAR expression by maintaining pro-adipogenic
levels of MEK activity during the initial 8 h of adipogenesis.
A, proliferating 3T3-L1 preadipocytes (P) were
grown to confluence, and 4 days later (0) the cells were
preincubated with PD98059 (50 µM) or vehicle for 1.0 h prior to their induction to differentiate with DEX, MIX, insulin, and
FBS in the presence or absence of 1 nM FGF-2. Total
cellular protein was harvested at the indicated times and subjected to
Western blot analysis using the activated ERK antibody. B
and C, post-confluent 3T3-L1 preadipocytes were induced to
differentiate in the presence or absence of U0126 (10 µM)
and/or FGF-2 (1 nM) (B) or in the presence of
U0126 (10 µM) with increasing concentrations of FGF-2
(C). Cells were harvested at 10 min (MEK activity) or 5 days
(adipogenic gene expression) and subjected to Western blot analysis as
described in the legend to Fig. 2.
Gene Promoter
Activity--
It appears that inhibition of MEK1 activity by either
U0126 or PD98059 (data not shown) significantly blocks adipogenic gene expression without affecting the induction of C/EBP expression during the early phase of preadipocyte differentiation. Studies by
others and us (4, 5, 20) have previously demonstrated a role for
C/EBP in initiating a cascade of transcriptional events that
regulate terminal differentiation. We questioned, therefore, whether
the MEK/ERK pathway potentiates the activity of C/EBP in inducing
C/EBP gene transcription. To address this question, we generated a
stable 3T3-L1 cell line expressing a C/EBP minimal promoter-CAT
reporter gene (referred to as L1#4-2 cells). This minimal promoter
corresponds to a fragment of genomic DNA consisting of 272 to +133 bp
relative to the transcription start site of the C/EBP gene. Previous
studies have identified a C/EBP regulatory element at 170 to 195
and have also demonstrated that transcription from this minimal
promoter requires C/EBP (23). The analyses presented in Fig.
6 demonstrate that expression of this
reporter gene responds positively to effectors that enhance C/EBP in
the L1#4-2 cells. Specifically, exposure of the cells to MIX and
insulin or DEX, MIX, and insulin for different times over a 72 h
period resulted in a peak of CAT activity at 36-60 h (Fig.
6A) with a corresponding increase in C/EBP expression
(Fig. 6B). Exposure to FBS with or without insulin caused a
negligible increase in CAT activity and C/EBP expression. The
observation that the activity of the C/EBP/CAT reporter gene is
transient suggests that additional regulatory elements not found in the
minimal promoter are required to maintain activity throughout the
entire differentiation process. As predicted from the data in Fig. 5,
FGF-2 significantly enhances C/EBP promoter/reporter gene activity
in 3T3-L1#4-2 cells following their exposure to MIX and insulin (Fig.
6C). Furthermore, treatment of the cells with PD98059
significantly attenuated the induction of the reporter gene by MIX and
insulin in the presence or absence of FGF-2.
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Fig. 6.
Activation of the C/EBP
minimal promoter in 3T3-L1 cells by insulin and MIX in the
presence or absence of FGF-2 is significantly attenuated by blocking
MEK activity with PD98059. A, post-confluent
3T3-L1#4-2 cells containing an integrated C/EBP minimal
promoter/CAT reporter gene were exposed to various combinations of DEX,
MIX, insulin, and FBS. Cells were harvested at the indicated times, and
CAT activity was measured in cell extracts containing equal amounts of
protein as described under "Experimental Procedures."
, FBS; 
,
insulin; 
, DEX, MIX, and insulin; 
, MIX and insulin.
B, a set of cultures corresponding to the same effector
conditions were harvested at 40 h post-induction and subjected to
Western blot analysis for expression of the different isoforms of
C/EBP. C, post-confluent 3T3-L1#4-2 cells were exposed
to DEX, MIX, insulin, and FBS in the presence or absence of FGF-2
and/or PD98059, and cell extracts were harvested at the indicated times
for measurement of CAT activity. , DEX, MIX and insulin; , DEX,
MIX, insulin, and 50 µM PD98059; , FGF-2, DEX, MIX,
and insulin; , FGF-2, DEX, MIX, insulin, and 50 µM
PD98059. Data are representative of three independent
experiments.
DISCUSSION
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INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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-adrenergic receptor
activity antagonize each other to regulate lipolysis in response to the
energy needs of the body. Some signaling events, however, function to
regulate the expression and activity of the many transcription factors
that orchestrate the differentiation process. This investigation
provides evidence for a role of the MEK/ERK signaling pathway in
regulating the expression of C/EBP and PPAR during adipogenesis.
Specifically, exposure of 3T3-L1 preadipocytes to a mixture of
adipogenic hormones consisting of DEX, MIX, insulin, and FBS activates
MEK1 during the initial 1-2 h post-induction as indicated by its
ability to phosphorylate ERK1 and ERK2. Inhibition of this activity by
exposure of preadipocytes to the MEK1 inhibitors U0126 or PD98059
significantly attenuates expression of C/EBP and PPAR without
affecting C/EBP expression. Furthermore, FGF-2 can induce adipogenic
gene expression in preadipocytes exposed to U0126 by promoting the
phosphorylation of ERK1/2. One mechanism by which the MEK/ERK pathway
might activate C/EBP expression is to enhance the ability of
C/EBP to transactivate the C/EBP gene promoter.
. Some
studies (9) have shown that drugs or effectors that block adipogenesis
are also potent inducers of ERK activity, and attenuation of this
activity with the MEK inhibitors restores differentiation. Similarly, a
recent study (31) provides evidence for a positive role for the
retinoblastoma protein in facilitating adipogenesis by suppressing ERK
activity. In contrast, several investigations including the present
study have shown that some pro-adipogenic agents stimulate MEK/ERK
activity, and, in some cases, attenuation of this activity with MEK
inhibitors blocks adipogenesis (12, 13, 32). We suggest that
stimulation of the MEK/ERK pathway can both promote and attenuate
adipogenesis depending on its time of activation during the
differentiation process. The data presented in Fig. 1 show that MEK
activity is rapidly induced during the initial few hours following
exposure of 3T3-L1 preadipocytes to insulin, MIX, and DEX. The peak of activity eventually subsides to pre-induction levels by 4-6 h, but
there is a second reproducible burst of activity detected at 12 h.
In addition, exposure of preadipocytes to FGF-2 induces an even greater
induction of MEK activity, which is also confined to the initial
12 h of the differentiation process. In both cases, this
time-restricted burst of MEK activity promotes differentiation by
facilitating the expression of the principal adipogenic transcription factors, PPAR and C/EBP. It appears that activation of MEK1 at
times following the induction of these factors will inhibit adipogenesis by attenuating their transcriptional activity.
, with or without C/EBP, in
initiating a cascade of transcriptional events that lead to expression
of the many hundreds of proteins responsible for the mature fat cell
phenotype. Consequently, factors that influence the ability of C/EBP
to initiate this cascade of gene expression are possible targets of
ERK1/2. In fact, the ERKs might phosphorylate C/EBP during the early
phase of adipogenesis and enhance its ability to activate C/EBP
transcription. Consistent with this notion are studies in other systems
demonstrating that MAPKs can enhance the transactivation properties of
C/EBP via the phosphorylation of Thr-235 (35, 36).
transcription by blocking association of the C/EBPs with the
C/EBP regulatory element within the promoter of the C/EBP gene. The
abundance of Sp1 and AP-2 decreases during 3T3-L1 differentiation;
therefore, it is possible that the MEK/ERK pathway facilitates their
down-regulation. In fact, these authors show that exposure of
growth-arrested 3T3-L1 preadipocytes to agents that increase cAMP
levels induces a rapid (within 2 to 4 h) and transient decrease in
Sp1. They also show that the phosphorylated form of Sp1 decays more
abruptly than the unphosphorylated form. Other studies (39-41) have
shown that the activity of Sp1 is regulated by the ERK signaling
pathway, which involves an ERK-associated phosphorylation of the
transcription factor at a MAPK consensus site. It is possible,
therefore, that elevation of cAMP in response to MIX along with insulin
induces an ERK-associated modification of Sp1, which initiates its
degradation, thus relieving repression on the C/EBP promoter. This
model of ERK regulation of C/EBP promoter activity would also be
consistent with the data presented in Fig. 6 because the 5' region of
the C/EBP/CAT reporter gene contains the Sp1 elements previously
shown by Lane and coworkers (37, 38) to repress C/EBP
transcription. In a similar manner, the MEK/ERK pathway could be
suppressing other known repressors of adipogenesis. Most notable among
these negative effectors is Wnt-10b, which is secreted from
preadipocytes and acts in an autocrine fashion to stimulate the
Wnt/-catenin signaling pathway. Activation of this pathway by
Wnt-10b inhibits GSK3 activity, which leads to the translocation of
-catenin into the nucleus where it co-activates TCF/LEF
transcription factors and, in so doing, inhibits expression of C/EBP
and PPAR (42). Recent studies by MacDougald and coworkers (43)
demonstrate that various components of the Wnt signaling pathway
including Wnt-10b and the frizzled receptors (Fz1, 2, and 5) are
down-regulated during the initial 1-2 days of differentiation. Furthermore, suppression of Wnt-10b production appears to be mediated by a cAMP-associated inhibition of Wnt-10b mRNA expression. It is
possible that the MEK/ERK signaling pathway is also involved in this process.
and
C/EBP during the differentiation of preadipocytes into adipocytes.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: Dept. of
Biochemistry, Boston University School of Medicine, 715 Albany St.,
Boston, MA 02118. Tel.: 617-638-4186; Fax: 617-638-5339; E-mail:
farmer@biochem.bumc.bu.edu.
ABBREVIATIONS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
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J. Xu and K. Liao Protein Kinase B/AKT 1 Plays a Pivotal Role in Insulin-like Growth Factor-1 Receptor Signaling Induced 3T3-L1 Adipocyte Differentiation J. Biol. Chem., August 20, 2004; 279(34): 35914 - 35922. [Abstract] [Full Text] [PDF]
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Y. Tanabe, M. Koga, M. Saito, Y. Matsunaga, and K. Nakayama Inhibition of adipocyte differentiation by mechanical stretching through ERK-mediated downregulation of PPAR{gamma}2 J. Cell Sci., July 15, 2004; 117(16): 3605 - 3614. [Abstract] [Full Text] [PDF]
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X. Su, D. J. Mancuso, P. E. Bickel, C. M. Jenkins, and R. W. Gross Small Interfering RNA Knockdown of Calcium-independent Phospholipases A2 {beta} or {gamma} Inhibits the Hormone-induced Differentiation of 3T3-L1 Preadipocytes J. Biol. Chem., May 21, 2004; 279(21): 21740 - 21748. [Abstract] [Full Text] [PDF]
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N. Arimura, T. Horiba, M. Imagawa, M. Shimizu, and R. Sato The Peroxisome Proliferator-activated Receptor {gamma} Regulates Expression of the Perilipin Gene in Adipocytes J. Biol. Chem., March 12, 2004; 279(11): 10070 - 10076. [Abstract] [Full Text] [PDF]
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Y.-H. Tseng, K. M. Kriauciunas, E. Kokkotou, and C. R. Kahn Differential Roles of Insulin Receptor Substrates in Brown Adipocyte Differentiation Mol. Cell. Biol., March 1, 2004; 24(5): 1918 - 1929. [Abstract] [Full Text] [PDF]
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 J. Novakofski Adipogenesis: Usefulness of in vitro and in vivo experimental models J Anim Sci, March 1, 2004; 82(3): 905 - 915. [Abstract] [Full Text] [PDF]
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K. Omori, K. Naruishi, F. Nishimura, H. Yamada-Naruishi, and S. Takashiba High Glucose Enhances Interleukin-6-induced Vascular Endothelial Growth Factor 165 Expression via Activation of Gp130-mediated p44/42 MAPK-CCAAT/Enhancer Binding Protein Signaling in Gingival Fibroblasts J. Biol. Chem., February 20, 2004; 279(8): 6643 - 6649. [Abstract] [Full Text] [PDF]
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 A. Mouihate, L. Boisse, and Q. J. Pittman A Novel Antipyretic Action of 15-Deoxy-{Delta}12,14-Prostaglandin J2 in the Rat Brain J. Neurosci., February 11, 2004; 24(6): 1312 - 1318. [Abstract] [Full Text] [PDF]
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 K. A. Cole, A. W. Harmon, J. B. Harp, and Y. M. Patel Rb regulates C/EBP{beta}-DNA-binding activity during 3T3-L1 adipogenesis Am J Physiol Cell Physiol, February 1, 2004; 286(2): C349 - C354. [Abstract] [Full Text]
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 D. M. Barnes, P. R. Hanlon, and E. A. Kircher Effects of Inorganic HgCl2 on Adipogenesis Toxicol. Sci., October 1, 2003; 75(2): 368 - 377. [Abstract] [Full Text] [PDF]
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H. Zhang, J. Nohr, C. H. Jensen, R. K. Petersen, E. Bachmann, B. Teisner, L. K. Larsen, S. Mandrup, and K. Kristiansen Insulin-like Growth Factor-1/Insulin Bypasses Pref-1/FA1-mediated Inhibition of Adipocyte Differentiation J. Biol. Chem., May 30, 2003; 278(23): 20906 - 20914. [Abstract] [Full Text] [PDF]
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