(Received for publication, November 8, 1996, and in revised form, December 23, 1996)
From the Biology Department, Syracuse University, Syracuse, New York 13244
It is well established that mitogens inhibit differentiation of skeletal muscle cells, but the insulin-like growth factors (IGFs), acting through a single receptor, stimulate both proliferation and differentiation of myoblasts. Although the IGF-I mitogenic signaling pathway has been extensively studied in other cell types, little is known about the signaling pathway leading to differentiation in skeletal muscle. By using specific inhibitors of the IGF signal transduction pathway, we have begun to define the signaling intermediates mediating the two responses to IGFs. We found that PD098059, an inhibitor of mitogen-activated protein (MAP) kinase kinase activation, inhibited IGF-stimulated proliferation of L6A1 myoblasts and the events associated with it, such as phosphorylation of the MAP kinases and elevation of c-fos mRNA and cyclin D protein. Surprisingly, PD098059 caused a dramatic enhancement of differentiation, evident both at a morphological (fusion of myoblasts into myotubes) and biochemical level (elevation of myogenin and p21 cyclin-dependent kinase inhibitor expression, as well as creatine kinase activity). In sharp contrast, LY294002, an inhibitor of phosphatidylinositol 3-kinase, and rapamycin, an inhibitor of the activation of p70 S6 kinase (p70S6k), completely abolished IGF stimulation of L6A1 differentiation. We found that p70S6k activity increased substantially during differentiation, and this increase was further enhanced by PD098059. Our results demonstrate that the MAP kinase pathway plays a primary role in the mitogenic response and is inhibitory to the myogenic response in L6A1 myoblasts, while activation of the phosphatidylinositol 3-kinase/p70S6k pathway is essential for IGF-stimulated differentiation. Thus, it appears that signaling from the IGF-I receptor utilizes two distinct pathways leading either to proliferation or differentiation.
It is widely believed that most mitogens stimulate skeletal muscle cell proliferation but inhibit differentiation. However, the insulin-like growth factors (IGF-I and IGF-II)1 are unique among growth factors in that they stimulate both proliferation and differentiation of muscle cells in culture. Recently, it has been shown that IGF actions occur through two phases (reviewed in Ref. 1). This involves an initial mitogenic response in which intracellular mediators of proliferation such as cyclin D mRNA and c-fos mRNA are up-regulated and mediators of the myogenic response such as elevation of myogenin mRNA are suppressed (2), followed by a strong myogenic response characterized by expression of the muscle-specific transcription factor myogenin and fusion of myoblasts into myotubes.
Although IGF binding has been shown for both IGF receptors, the type I IGF-I receptor and the type II IGF-II receptor, most biological actions of IGF-I and IGF-II on L6A1 muscle cells appear to be mediated by the type I IGF-I receptor (3). It is not obvious how stimulation of two mutually exclusive processes such as proliferation and differentiation can be mediated by the same receptor. A likely possibility is that there is a step at which signal transduction pathways leading to proliferation or differentiation diverge. Although many of the signaling intermediates for the mitogenic actions of IGFs have been described for other cell types, little is known about signal transduction pathways leading to muscle differentiation.
The results of studies on signaling by the insulin and IGF-I receptors in other cell types have revealed two primary pathways by which these signals might be transmitted. Binding of IGF-I to the type I receptor induces a conformational change resulting in receptor autophosphorylation, followed by tyrosine phosphorylation of several cellular substrates. Two primary substrates of the activated IGF receptor are IRS-1 and Shc (4, 5). Phosphorylated tyrosines on IRS-1 serve as docking sites for multiple proteins containing SH-2 domains. Among those proteins shown to bind to IRS-1 are the p85 regulatory subunit of PI 3-kinase (6), SH-PTP2 (Syp) (7), the adaptor protein Nck (8), and Grb-2 (9). This latter protein associates with mSos, which activates Ras in turn activating the Raf-1/MAP kinase pathway (10). Phosphorylated Shc also associates with Grb-2 and activates this pathway (5, 11). Although both IRS-I and Shc can link the activated IGF-I receptor with Grb-2/Sos, Sasaoka et al. (12) have recently shown that the Shc·Grb-2/Sos complex is more important for Ras activation.
A second pathway involving PI 3-kinases is also observed in
insulin/IGF-I receptor signal transduction (4, 13). Association of
IRS-1 with p85/p110 PI 3-kinase results in its activation, leading to
downstream phosphorylation and activation of the serine/threonine kinase p70S6k (14). This in turn leads to phosphorylation
of the ribosomal S6 protein and PHAS-I, resulting in an increased
translation of mRNAs containing polypyrimidine tracts (15). In
addition, Weng et al. (16) have shown that constitutively
active PI 3-kinase indirectly activates p70S6k, possibly
through the kinase Akt (17). However, p70S6k may also be
activated through a PI 3-kinase-independent pathway, since mutation of
the PDGF receptor has been shown to abolish PI 3-kinase activation in
transfected 293 cells, while p70S6k activation remains
unaffected (18). In addition, Lenormand et al. (19) have
recently shown that expression of an estradiol-regulated form of Raf-1
(Raf-1:ER) results in p70S6k activation via a
MAPK-independent pathway. Therefore, it appears that multiple signaling
pathways lead to p70S6k activation.
In order to evaluate the relative importance of the MAP kinase and PI 3-kinase pathways in skeletal muscle proliferation and differentiation, we have determined the effect of several inhibitors of these mediators on L6A1 myoblasts. PD098059 is a noncompetitive inhibitor of MEK that functions by blocking the activation of MEK by Raf-1 (20). Its inhibitory effect on the MAP kinase pathway has been shown in several cell types including mouse Swiss 3T3 fibroblasts and PC-12 cells (21) and has been shown to block insulin-stimulated MAP kinase activation in 3T3-L1 adipocytes and L6 myotubes (22) but has no effect on a number of other protein kinases (21). LY294002 is a PI 3-kinase inhibitor (23) that has recently been reported to block differentiation in L6E9 myoblasts (24). Rapamycin is an immunosuppressant drug known to block progression of the cell cycle at the G1 phase. Rapamycin blocks activation of the serine/threonine kinase p70S6k (25), resulting in the dephosphorylation of S6 ribosomal protein or PHAS-I, leading to a decrease in translation of specific, rapamycin-sensitive transcripts (15). Through the use of these inhibitors we have separated the pathways involved in skeletal muscle proliferation and differentiation and have shown that they diverge at a very early point. Our studies demonstrate that the early stimulation of cell proliferation involves the Ras/Raf-1/MAP kinase pathway, and the later stimulation of differentiation utilizes the PI 3-kinase/p70S6k pathway.
The IGF-I analog, R3 IGF-I, was a gift from Paul Walton and John Ballard (GroPep Pty Ltd, Adelaide, Australia). Rapamycin was purchased from ICN Pharmaceuticals, Inc. (Costa Mesa, CA), and LY294002 was purchased from Calbiochem. The MEK inhibitor, PD098059, was a gift from Alan Saltiel (Parke-Davis Pharmaceuticals, Ann Arbor, MI). The c-fos cDNA probe was obtained from ATCC (Rockville, MD), and the myogenin cDNA probe (E26) was a gift from Eric N. Olson (University of Texas Southwestern Medical Center, Dallas, TX). The anti-cyclin D antibody, p70S6k assay kit, and recombinant protein A-agarose were from Upstate Biotechnology, Inc. (Lake Placid, NY). Anti-phospho-MAPK antibody was purchased from New England Biolabs, Inc. (Beverly, MA). Hybridoma cells secreting the anti-myogenin antibody were a gift from W. R. Wright (University of Texas, Austin, TX). Goat anti-rabbit and anti-mouse horseradish peroxidase-conjugated IgG, the BCA protein assay reagents, and the SuperSignal CL-HRP substrate system for enhanced chemiluminescence (ECL) were purchased from Pierce. Tissue culture medium components were purchased from Life Technologies, Inc. All other chemicals were from Sigma.
Cell CultureL6A1 myoblasts were grown in Dulbecco's
modified Eagle's medium (DMEM) containing 10% horse serum, 1% chick
embryo extract, and 1% antibiotic, antimycotic solution (penicillin,
streptomycin, and amphotericin B). Cultures were plated at 1.2 × 105 cells/35-mm dish for cell number and creatine kinase
(CK) determination and at 1.2 × 106 cells/100-mm dish
for RNA extraction or immunoprecipitation of proteins. After incubation
overnight, the cultures were washed with DMEM before the addition of
IGFs or inhibitors in DMEM containing 0.5 mg/ml bovine serum albumin.
Stock solutions of inhibitors were dissolved in Me2SO at
the following concentrations and stored at 20 °C: PD098059, 30 mM; LY294002, 10 mM; rapamycin, 1 mg/ml.
To quantitate cell proliferation, cells were trypsinized and counted in a model ZBI Coulter Counter 1 day after the addition of growth factors and inhibitors. Differentiation was quantitated 3 days after the addition of growth factors and inhibitors by measuring the elevation in CK activity using the NAD-coupled microtiter assay (27); CK levels were normalized to DNA content as described previously (28).
Northern Blot AnalysesTotal RNA was isolated from cultures using the RNeasy total RNA kit (Qiagen, Chatsworth, CA) according to the manufacturer's instructions. Ten-µg samples were analyzed on Northern blots. Consistency of RNA loading was monitored by visualization of ethidium bromide-stained ribosomal RNA bands. 32P-Labeled probe for c-fos mRNA was prepared by random priming of the 1-kilobase pair PstI restriction fragment, for myogenin the 1.1-kilobase pair BamHI/EcoRI restriction fragment, and for p21 the 420-base pair EcoRI restriction fragment. Blots were hybridized at 42 °C and washed as described previously (29). The autoradiographs and photographs were scanned with a Microtek Scanmaker II at 600 dots per inch using Adobe Photoshop software.
Electrophoresis and ImmunoblottingTotal cell lysates were prepared by washing the cell monolayers (100-mm dish) twice with ice-cold PBS followed by lysis in 0.5 ml of boiling 1 × Laemmli sample buffer containing 100 mM dithiothreitol. Proteins (10 µg) were separated by 10% SDS-polyacrylamide gel electrophoresis following the procedures of Laemmli (30) and transferred onto Immobilon-nitrocellulose (Millipore Corp.) in transfer buffer containing 48 mM Tris base, 39 mM glycine, 0.037% SDS, and 20% methanol at 0.8 mA/cm2 for 1 h using a SemiPhor Transfer Unit (Hoefer). The blots were blocked for 1 h at room temperature in blocking buffer containing 5% nonfat dry milk in PBST (10 mM phosphate buffer, pH 7.5, 150 mM NaCl, 0.1% Tween 20) and incubated overnight at 4 °C with antibodies against cyclin D1 (1 µg/ml) or phospho-MAPK (1:1000) in 5% milk, PBST, or myogenin (1:50) in 1% milk, 10% goat serum, PBST. After washing six times in PBST, the membranes were incubated for 1 h at room temperature with horseradish peroxidase-conjugated goat anti-rabbit IgG diluted 1:3000 in 5% milk, PBST (except myogenin, which was incubated with horseradish peroxidase-conjugated goat anti-mouse IgG, 1:2000 dilution). The blots were washed six times in PBST at room temperature, and immunolabeling was detected by ECL according to the manufacturer's directions.
p70 S6 Kinase AssayThe cell monolayers in 100-mm dishes
were washed twice with ice-cold PBS, and the cells were lysed by
incubating the cultures for 20 min in 1 ml of cold modified
radioimmunoprecipitation assay buffer (50 mM Tris-HCl, pH
7.4, 1% Nonidet P-40, 0.25% sodium deoxycholate, 150 mM
NaCl, 1 mM EGTA, 1 mM PMSF, 1 µg/ml
aprotinin, 1 µg/ml leupeptin, 1 µg/ml pepstatin, 1 mM
Na3VO4, 1 mM NaF). The lysates were
centrifuged for 10 min in a microcentrifuge to remove any insoluble
material. The protein content of the supernatants was determined by the
BCA method. p70S6k activities were assayed by following a
modification of the manufacturer's protocols. After cell lysis in
radioimmunoprecipitation assay buffer, 200 µg of protein were
incubated with 1 µg of anti-p70S6k antibody for 1 h
at 4 °C. The immunocomplex was captured with 50 µl of protein
A-agarose (50% slurry) for 1 h at 4 °C. The beads were washed
two times with an equal volume of cold PBS followed by one wash with
assay dilution buffer. The beads were resuspended in 20 µl of assay
dilution buffer, 10 µl of substrate, 10 µl of inhibitor mixture,
and 10 µl of [32P]ATP mixture (75 mM
MgCl2, 500 µM ATP, 10 µCi of
[
32P]ATP). The reaction mixtures were incubated for 10 min at 30 °C and then centrifuged for 1 min. Aliquots (20 µl) of
the supernatants were spotted onto P81 phosphocellulose paper squares
and washed three times in 0.75% phosphoric acid, followed by one wash
in acetone. The squares were transferred to scintillation vials and counted in a Beckman LS 7500 scintillation counter.
The actions of IGF-I are modified by six
IGF-binding proteins (IGFBPs), three of which are secreted by L6A1
muscle cells and have both inhibitory and stimulatory effects on
proliferation and differentiation (Refs.
31-33).2 In order to minimize the actions
of these IGFBPs in this study, we used an analog of IGF-I with a low
affinity for IGFBPs, R3 IGF-I. We have previously reported that several
similar IGF-I analogs with reduced affinity for IGFBPs were not only
more potent than IGF-I in stimulating L6A1 myoblast proliferation and
differentiation, but caused much more extensive myotube formation (31).
The effects of adding increasing concentrations of R3 IGF-I on L6A1
cell proliferation and differentiation are shown in Fig.
1. Stimulation of proliferation after 1 day reached a
maximum at approximately 30-100 ng/ml R3 IGF-I. Maximum stimulation of
differentiation measured after 3 days was attained with 1-3 ng/ml of
R3 IGF-I, while exposure to higher concentrations resulted in
progressively lower CK levels accompanied by decreased fusion of
myoblasts into myotubes as well as increased cell division; this
biphasic response was also seen at higher concentrations of unmodified
IGF-I (34). Therefore, in subsequent studies, R3 IGF-I was used at low
concentrations of 1-3 ng/ml in experiments monitoring inhibitor
effects on differentiation and at higher concentrations of 10-30 ng/ml
when we studied effects on proliferation.
Effects of Specific Inhibitors of the IGF-I Signal Transduction Pathway on L6A1 Myoblast Proliferation and Differentiation
In
order to determine which signaling pathways play a role in mediating R3
IGF-I-stimulated proliferation and differentiation, we used three
compounds that have been reported to inhibit specific signaling
molecules in other cells. PD098059 specifically inhibits the activation
of MEK by Raf-1, thus suppressing MAP kinase activation (20). LY294002
is a specific inhibitor of PI 3-kinase (23), and rapamycin treatment
inhibits p70S6k (25). When these inhibitors were added in
the presence of R3 IGF-I, we observed striking differences in the
response of L6A1 myoblast cultures. Fig. 2 summarizes
the concentration dependences of the effects of each of the three
inhibitors on cell proliferation and differentiation when added in the
presence of 3 ng/ml R3 IGF-I. As shown in Fig. 2, increasing
concentrations of PD098059 gave progressive decreases in the mitogenic
response to R3-IGF-I, inhibiting proliferation approximately 90% at
concentrations of 30 µM, while the same levels of
inhibitor showed a dramatic 3-fold enhancement of R3 IGF-I-stimulated
differentiation quantitated as CK in units/mg of DNA. In sharp
contrast, incubation with increasing concentrations of either LY294002
or rapamycin progressively inhibited the myogenic response to R3 IGF-I
but had much less effect on the mitogenic response. At concentrations
of 10 µM and 1 ng/ml, LY294002 and rapamycin,
respectively, completely abolished R3 IGF-I-stimulated differentiation
but inhibited cell proliferation only 30-40%.
There were equally striking changes in cell morphology following
treatment with these inhibitors. Upon the removal of growth medium,
cells maintained in serum-free DMEM remained relatively quiescent, with
little, if any cell division or fusion into myotubes (Fig.
3A). After the addition of R3 IGF-I to L6A1
cultures, the myoblasts first underwent a round of cell division before
fusing into myotubes; after 2 days the cultures consisted of both
unfused myoblasts and differentiated myotubes (Fig. 3B).
However, when PD098059 was added in the presence of R3 IGF-I, there was
less cell division, and the myoblasts began to differentiate sooner, forming an extensive network of myotubes; after 2 days in culture, few
if any unfused myoblasts could be detected (Fig. 3C). In
sharp contrast, differentiation was completely inhibited in cultures treated with either LY294002 or rapamycin in the presence of R3 IGF-I
(Fig. 3, D and E). Myoblasts treated with these
two inhibitors continued to proliferate, as demonstrated by the
increased cell density when compared with those in DMEM, but they did
not fuse into myotubes. These results (Figs. 2 and 3) suggest that
signaling by the MAP kinase pathway is required for R3 IGF-I-stimulated L6A1 proliferation, but not for differentiation, and that inhibition of
this pathway by PD098059 permits, and even enhances, R3
IGF-I-stimulated L6A1 myoblast differentiation. In contrast, a
functional PI 3-kinase/p70S6k pathway is an absolute
requirement for IGF-stimulated differentiation.
Effects of Combinations of Inhibitors
As shown in Figs. 2 and
3, the inhibitors used here have dramatically opposite effects on
responses of myoblasts to R3 IGF-I. This raises the question of which
effect predominates when cells are incubated with combinations of these
inhibitors. As illustrated in Fig. 4B, the
results are unequivocal; the inhibitory effects of LY294002 and
rapamycin overcome both the stimulation of myogenesis by R3 IGF-I and
its enhancement by PD098059. Differentiation of myoblasts in response
to R3 IGF-I is completely blocked by these inhibitors, both in the
absence and presence of PD098059; morphological differentiation
(i.e. fusion) of the cultures closely parallels the
quantitation by CK levels presented in Fig. 4B. Thus, it
appears that the PI 3-kinase/p70S6k pathway is essential
for myogenesis even when the mitogenic response through MAP kinase is
blocked.
The results presented in Fig. 4A indicate a major effect of the MAP kinase pathway and a smaller contribution of the PI 3-kinase/p70S6k pathway to the mitogenic response; there was much greater inhibition of proliferation by PD098059 than by either of the other inhibitors, but when added in combination with PD098059, there was an even lower level of cell proliferation; indeed, there was some loss of cells below the level found in DMEM controls.
Effect of Inhibitors on Intracellular Mediators of ProliferationWe usually measure proliferative responses of L6A1
myoblasts to mitogenic stimuli by counting the actual number of cells
in the cultures 1 day after the specific treatment. In addition, we
also determined the effects of these inhibitors on several intracellular mediators closely associated with early aspects of the
proliferative response in other cell systems. Of these, c-fos mRNA is an established early marker for cell
proliferation and has been shown to be induced during IGF-I-stimulated
mitogenesis in L6 myoblasts (35, 36). We investigated the effects of
PD098059, LY294002, and rapamycin on c-fos mRNA levels
after 30 min as shown in Fig. 5A. In the
presence of R3 IGF-I, c-fos mRNA levels were enhanced
about 3-fold above control levels. As expected, this increase in
c-fos mRNA was significantly reduced in the presence of
the MEK inhibitor, PD098059. In contrast, LY294002 and rapamycin, at
concentrations that abolished myogenic differentiation, had little or
no effect on c-fos mRNA levels compared with R3 IGF-I treatment alone. Both combinations of inhibitors resulted in decreased c-fos mRNA levels similar to those seen for PD098059
plus R3 IGF-I alone.
Effects of inhibitors on specific mediators of the early proliferative response to R3 IGF-I. L6A1 myoblast cultures were established overnight in growth medium at 1.2 × 106 cells/100-mm dish, washed once with DMEM, and then treated with R3 IGF-I (30 ng/ml for c-fos mRNA and 10 ng/ml for phospho-MAPK and cyclin D determinations) in the absence or presence of PD098059 (30 µM), LY294002 (10 µM), or rapamycin (1 ng/ml). The following analyses were made in parallel cultures. A, c-fos mRNA. Total RNA was prepared 30 min after the addition of R3 IGF-I with or without inhibitors, 10 µg was analyzed on Northern blots (middle part), and c-fos mRNA abundance was quantitated by densitometry (upper part); equal loading was verified with ethidium bromide-stained ribosomal 18 S RNA (lower part). B, phospho-MAPK. Cell lysates were prepared 1 h after the addition of R3 IGF-I with or without inhibitors, and 10 µg of protein was separated by 10% SDS-polyacrylamide gel electrophoresis and immunoblotted with anti-phospho-MAPK. The Western blot for phospho-MAPK is shown in the lower part, and the densitometric quantitation of ERK 1 (bars on left) and ERK 2 (bars on right) is shown in the upper part. C, cyclin D. Cell lysates were prepared 4 h after the addition of R3 IGF-I with or without inhibitors, and 10 µg of protein was separated by 10% SDS-polyacrylamide gel electrophoresis and immunoblotted with an antibody to cyclin D. The Western blot is shown in the lower part, and the densitometric quantitation is shown in the upper part.
The primary substrates of MEK are the p42/p44MAPK isoforms, ERK 2 and ERK 1, respectively (37). PD098059 prevents the activation of MEK, thereby inhibiting phosphorylation and activation of MAP kinases. It has been postulated that the MAP kinases are required for activation of the G1 cyclin-dependent complexes (38). Therefore, levels of phosphorylated MAP kinase were measured in cells incubated with PD098059, LY294002, and rapamycin, both individually and in combination. As shown in Fig. 5B, PD098059 had the expected effect of inhibiting R3 IGF-I-induced phosphorylation of both ERK 1 and 2 within 1 h. LY294002 and rapamycin, on the other hand, had little or no effect. When LY294002 and rapamycin were added in combination with PD098059, the inhibition was equivalent to PD098059 on its own. This confirms that the action of PD098059 is upstream of MAP kinase and that LY294002 and rapamycin have no effect on the MAP kinase pathway or, therefore, on c-fos transcription.
The inhibitory effects of PD098059 on the levels of cyclin D1, a protein essential to cell cycle progression, were similar to, although not as dramatic as those seen for phosphorylated MAP kinase. However, PD098059 in the presence of either LY294002 or rapamycin was almost completely inhibitory (Fig. 5C). This suggests that although proliferation occurs primarily through the MAP kinase pathway, inhibiting this pathway does not block all aspects of the proliferative response, suggesting that the PI 3-kinase/p70S6k pathway may also be involved. However, since R3 IGF-I and LY294002 or rapamycin in the absence of PD098059 had no effect on cyclin D1 levels, the proliferative role of the PI 3-kinase/p70S6k pathway is most probably minor.
Effect of Inhibitors on Intracellular Mediators of MyogenesisIn a similar study on early mediators of
differentiation, we measured levels of myogenin and p21 mRNA 18 and
42 h after the R3 IGF-I addition in the absence or presence of the
inhibitors (Fig. 6). Myogenin is a
basic-helix-loop-helix transcription factor of the MyoD family that is
required for terminal differentiation and myotube formation (reviewed
in Ref. 1). Induction of the mRNA for the
cyclin-dependent kinase inhibitor, p21, is an early event
in myogenic differentiation marking the exit of myoblasts from the cell
cycle (39).
Effects of inhibitors on R3 IGF-I stimulation of myogenin and the cyclin-dependent kinase inhibitor, p21. Cultures were prepared and treated as described under Fig. 5, except that R3 IGF-I was added at 3 ng/ml. The following analyses were made in parallel cultures. A, myogenin mRNA. Total RNA was prepared 18 and 42 h after the addition of R3 IGF-I with or without inhibitors, 10 µg was analyzed on Northern blots (middle part), and myogenin mRNA abundance was quantitated by densitometry (upper part); equal loading was verified with ethidium bromide-stained ribosomal 18 S RNA (lower part). B, myogenin protein. Total cell lysates were prepared, and 10 µg of total protein was separated by 10% SDS-polyacrylamide gel electrophoresis and immunoblotted with anti-myogenin. The Western blot is shown in the lower part, and densitometric quantitation is shown in the upper part. C, p21 mRNA. RNA preparation and Northern analyses were performed as described in A for myogenin.
At early times of incubation (18 h), R3 IGF-I-treated cells exhibited very little increase in myogenin mRNA compared with DMEM control cells (Fig. 6A). In the presence of R3 IGF-I and PD098059, myogenin mRNA levels were elevated more than 3-fold compared with R3 IGF-I treatment alone, indicating an early enhancement of the myogenic response. LY294002 and rapamycin-treated cells showed a significant reduction in myogenin mRNA at that time. The combination of PD098059 with rapamycin and LY294002 reduced the enhancing effect of PD098059 on myogenin mRNA levels, although they were still slightly elevated above control and R3 IGF-I levels.
By 42 h, myogenin mRNA in R3 IGF-I-treated cells was elevated almost 4-fold above DMEM-treated control cells. This is consistent with observations that myogenin mRNA levels rise rather late after the IGF-I addition (2, 29). Cells treated with R3 IGF-I and PD098059 had myogenin levels similar to those in R3 IGF-I-treated cells; i.e. by this late time, myogenin levels in R3 IGF-I-treated cells reached those levels seen in cells treated with both R3 IGF-I and PD098059. LY294002 and rapamycin with R3 IGF-I alone or in combination with PD098059 showed patterns similar to those seen at 18 h.
At 18 h, myogenin protein levels correlated well with mRNA values showing enhanced myogenin protein in the presence of R3 IGF-I and PD098059 (Fig. 6B). The effect of the inhibitors on myogenin protein levels was less pronounced by 48 h, although R3 IGF-I-treated cells showed enhanced levels of myogenin compared with DMEM-treated cells. This suggests that translation of myogenin mRNA may be affected differently than transcription of the myogenin gene in the presence of these inhibitors.
Levels of p21 mRNA were also elevated in the presence of R3 IGF-I and R3 IGF-I plus PD098059 at 18 and 42 h (Fig. 6C). However, the inhibitors LY294002 and rapamycin, alone or in combination with PD098059, completely blocked p21 mRNA expression compared with DMEM-treated cells, again suggesting the importance of the PI 3-kinase/p70S6k pathway in differentiation. These results reflect the well established coordination of cell cycle exit with the onset of myogenic differentiation.
Effects of Inhibitors on p70S6 ActivityResults
with the inhibitors LY294002 and rapamycin strongly indicated a major
role for the PI 3-kinase/p70S6k pathway in the stimulation
of myogenesis by the IGFs, suggesting that p70S6k activity
should be elevated during differentiation. To test this possibility, we
measured the enzymatic activity of p70S6k in lysates from
cells treated with R3 IGF-I as shown in Fig. 7. R3 IGF-I
increased p70S6k activity above control levels over an
extended period of time (48 h), showing an initial increase over
control values (Fig. 7, inset), followed by a much larger
increase at 48 h. The later activity was substantially elevated in
the presence of PD098059, just as was differentiation of the cells.
Treatment with rapamycin and LY294002 reduced p70S6k
activity to the level found in DMEM controls, demonstrating that inhibition of p70S6k activity parallels the effects of
these inhibitors on myogenesis. These results suggest that the early
increase in p70S6k activity may contribute to the
relatively rapid mitogenic response, while the larger subsequent
increase is necessary for the stimulation of L6A1 myoblast
differentiation.
The results presented here represent the first steps toward understanding the signaling pathways involved in two major responses of myoblasts to the IGFs. When we (40) first reported that the known mitogens, IGFs, stimulate differentiation as well as proliferation of skeletal muscle cells in culture, there was some reluctance to accept this observation because of the long held (41) and well supported (42-45) view that mitogens block myogenesis by forcing myoblasts in the G1 stage of the cell cycle to reenter S phase rather than to fuse to form postmitotic myotubes. However, the stimulation of myogenic differentiation by the IGFs has been demonstrated independently in a number of laboratories (reviewed in Ref. 1), and the effect is now well established although not fully explained.
It has been difficult to understand how the same agent, IGF-I (or IGF-II or insulin at high concentrations), acting through a single receptor (3), can stimulate these two responses, which are generally considered to be mutually antagonistic. One suggested explanation for our observations was that IGFs acted only to maintain the cells in a viable state, thus allowing differentiation rather than actively stimulating the process. In earlier studies, we demonstrated that IGFs did not stimulate differentiation solely by preventing cell death by showing that the IGFs caused significant differentiation in medium containing horse serum at levels as high as 5% (34). Another possibility, that the greater fusion rate might result from the higher cell density in cultures stimulated to proliferate by IGF-I, was eliminated by experiments (46) that showed that the stimulation of myogenesis by IGFs was readily detectable in cells incubated under conditions in which DNA synthesis was blocked or proliferating cells were killed by cytosine arabinoside. However, it has recently been shown that IGF-II does, in fact, act as an autocrine survival factor for differentiating myoblasts (47). Although our earlier results show that this does not account for the stimulation of differentiation, we had previously shown that IGF-II was produced by differentiating muscle cells and that the rate of differentiation of different muscle cell lines correlated with the amount of IGF-II secreted by the cell (48). Additional direct evidence implicating IGF-II as an autocrine myogenic factor was provided by Stewart et al. (49) and Quinn et al. (50), who showed that overexpression of IGF-II or the type I IGF-I receptor in C2 cells resulted in greatly accelerated differentiation. Thus, it appears that although the IGFs may act as survival factors and stimulate proliferation, the role of IGFs as positive regulators of myogenesis is firmly established.
A beginning of an explanation of the two responses (proliferation and differentiation) to IGFs was provided by the finding that there is a temporal separation in the responses of myoblasts to IGFs; cells first proliferate and then differentiate (2, 28). But this does not explain how myoblasts can respond in the two different ways or what signals mediate those responses.
The results presented here suggest that the signaling pathways leading to proliferation or differentiation diverge at a very early step, possibly as early as the interaction of the IGF-I receptor or of IRS-1 with intracellular signaling pathways. As in many other cell types, the stimulation of proliferation in L6A1 skeletal muscle cells by IGF appears to be mediated by the Ras/Raf-1/MAP kinase pathway. Several years ago it was shown that overexpression of ras oncogenes in myoblasts inhibited muscle differentiation (51, 52). Since Ras activation is a critical component of the signaling pathway leading to MAP kinase activation and proliferation, it is reasonable to predict that the stimulation of the MAP kinase pathway would inhibit differentiation and that inhibition of the MAP kinase pathway would stimulate differentiation. We have now shown that the addition of PD098059, the specific inhibitor of MEK activation by Raf-1, not only blocked cell proliferation, but resulted in a dramatic increase in myogenesis above that obtained with R3 IGF-I alone (Figs. 2 and 3). This was evident not only by morphologic changes, but also by changes in specific mediators of proliferation and differentiation. Levels of mRNA for the transcription factor, c-fos, an early marker of proliferation, and of cyclin D protein were suppressed by PD098059 (Fig. 5, A and C). In contrast, the increase in myogenin mRNA and protein was significantly enhanced in the presence of PD098059, particularly during early stages of differentiation (18 h) (Fig. 6, A and B) when myogenin levels are not normally elevated in IGF-I-treated myoblasts (2, 29). This suggests the possibility that proliferation is the primary response of muscle cells to IGFs and that differentiation occurs when there is an interruption of the MAP kinase pathway. What external stimuli bring about this inhibition in vivo is unclear. Our results are similar to those of Lazar et al. (22) who, using PD098059 to block MEK activation by insulin, demonstrated that the MAP kinase pathway is not required for many of the metabolic actions of insulin, such as glucose uptake, lipogenesis, and glycogen synthesis. However, in their studies, PD098059 treatment did not result in additional stimulation of any of the metabolic actions as we have observed in the case of IGF-stimulated L6A1 myogenesis.
In apparent disagreement with our finding that activation of the MAP kinase pathway is not required for L6A1 myogenesis, Hashimoto et al. (53) concluded that activation of MAP kinase played a positive role in the expression of myogenin and subsequent differentiation of C2C12 myoblasts. Their conclusion was based on their observations that genistein, a tyrosine kinase inhibitor, inhibited phosphorylation of MAP kinase, myogenin expression, and fusion of myoblasts into myotubes. Since genistein is a general inhibitor that can affect the phosphorylation of many signaling intermediates, it is possible that the inhibitory effects on myogenesis could result from effects on mediators other than MAP kinase. When we added genistein to L6A1 myoblasts at concentrations lower than the 50 µM used by Hashimoto et al., we found that it inhibited proliferation as well as differentiation (data not shown), and concluded that this was not a useful inhibitor for our studies on the separate responses.
The importance of the MAP kinase pathway in proliferation has been shown in several cell types for many different mitogens (37). Lavoie et al. (38) have reported that activation of the p42/p44MAPK isoforms, which leads to activation of various transcription factors, also results in positive regulation of cyclin D1 expression. Growth factor-dependent accumulation of cyclin D1 has been shown to be necessary in order for cells to pass the G1 restriction point of the cell cycle (54).
As shown in Fig. 5, A and B, neither LY294002 nor rapamycin was inhibitory to ERK 1 and 2 phosphorylation or c-fos expression, and neither further enhanced the inhibition of ERK 1 and ERK 2 phosphorylation by PD098059. However, the decrease in cyclin D1 levels at 4 h by PD098059 (Fig. 5C), although significant, was further enhanced by either LY294002 or rapamycin, although neither had any effect individually. Cyclin D1 has been postulated to be the "nuclear sensor" of extracellular signals (38), and our results indicate that cyclin D1 levels may be regulated by both the MAP kinase and the PI 3-kinase/p70S6k pathways. This suggests that although the MAP kinase pathway is essential for proliferation, the p70S6k pathway also plays a role. This is further substantiated by our finding (Fig. 7) that there was an initial increase of p70S6k activity 30 min after R3 IGF-I stimulation, a time when proliferative signals such as c-fos mRNA are up-regulated. IGF-I, at 80 ng/ml, which gives a greater mitogenic response than R3 IGF-I, caused an even greater early increase in p70S6k activity (data not shown), supporting the role of p70S6k in proliferation. At the high levels required for complete suppression of myogenesis, both LY294002 and rapamycin exhibit some (40%) inhibition of the proliferative response to R3 IGF-I.
However, it appears that the PI 3-kinase/p70S6k pathway
plays a much more critical role in the myogenic response to IGFs.
Inhibition of PI 3-kinase or p70S6k by LY294002 or
rapamycin, respectively, resulted in little or no myotube formation
(Fig. 3) accompanied by sharply decreased levels of myogenin and p21
mRNA (Fig. 6). In addition, p70S6k activity increased
with time as R3 IGF-I-stimulated differentiation proceeded (Fig. 7).
This elevated activity was further enhanced by PD098059, suggesting
that inhibition of the MAP kinase pathway stimulates differentiation.
The increase in p70S6k activity was completely abolished in
the presence of LY294002 and rapamycin (Fig. 7), supporting our
interpretation that myogenic signaling proceeds from PI 3-kinase to
p70S6k. Our results are in direct contrast with those
reported by Jayaraman and Marks (55), who concluded that rapamycin
treatment of BC3H1 myoblasts induced differentiation. BC3H1 myoblasts
are not typical of most skeletal muscle cells, since they do not fuse
to form myotubes, and biochemical differentiation can be reversed. In the cited study, much higher levels of rapamycin were used, and elevation of -actin expression was the only myogenic response that
was reported.
Our results also suggest that changes in the expression of biochemical markers alone do not indicate differentiation. Myogenin mRNA and protein levels were elevated at 42 h in cells treated with R3 IGF-I and the combination of PD098059 and LY294002 or rapamycin (Fig. 6). However, under these conditions, no differentiation was seen to occur (Fig. 4B). Therefore, elevated myogenin levels alone are not sufficient to induce differentiation; LY294002 and rapamycin may be inhibiting an additional component of the differentiation pathway, possibly the myogenic factor MEF-2 (56).
As this manuscript was being completed, Pilch's group (57) published the results of a study of effects of FGF and IGF on the proliferative response of C2C12 myoblasts. They found complete inhibition of MAP kinase activation but only partial inhibition of [3H]thymidine incorporation by PD098059 and concluded that a MAP kinase-independent pathway makes a substantial contribution to the mitogenic response to IGF-I. To the extent that they overlap, our results are in good overall agreement with theirs; we too find that PI 3-kinase activation plays some role in the mitogenic response, and the myogenic response is suppressed by LY294002, which was not used by Milasincic et al. (57).
Our findings are consistent with the recent report of Kaliman et al. (24), who also observed that LY294002 and wortmannin inhibited the capacity of L6E9 myoblasts to form myotubes when the cultures were placed in low serum differentiation medium and concluded that PI 3-kinase activation was required for differentiation. The effects of IGFs on their system were not considered, although our previous observations of autocrine expression of IGFs by myoblasts in low serum medium (48) indicate that IGFs may have been acting in those cells as well.
Although other mitogens have been shown to stimulate PI 3-kinase
activity in non-muscle cells, we have found no reports of stimulation
of PI 3-kinase in muscle by FGF, PDGF, or EGF. Milasincic et
al. (57) have recently reported that in C2C12 cells, IGF-I and
insulin increase PI 3-kinase activity by approximately 2-fold, whereas
basic FGF, a potent inhibitor of myogenesis, was inconsistent in
stimulating PI 3-kinase activity. Also, Kudla et al. (58) have shown that PDGF-BB stimulation of MM14 cells overexpressing the
PDGF- receptor resulted in autophosphorylation of the PDGF-
receptor, activation of MAP kinase, and increased jun B and
c-fos mRNA. However, no effect on proliferation or
differentiation was observed. In other muscle cell types, PDGF has been
shown to repress myogenesis and promote proliferation (59-61).
However, the signaling mechanisms involved were not investigated.
We cannot rule out the possibility that these other mitogens may also act through PI 3-kinase in skeletal muscle. It has already been shown that different mitogens acting through the same signaling pathway can generate separate responses. In PC12 cells, FGF or nerve growth factor stimulation results in differentiation, whereas EGF stimulation leads to increased cell proliferation (reviewed in Ref. 62). All of these mitogens stimulate MAP kinase activity; however, the duration of the MAP kinase signal is sustained in FGF/nerve growth factor stimulation but is transient in EGF stimulation. In addition to signal duration, other factors may potentially play a role in modulating signaling pathways for different mitogenic stimuli.
The role of Raf-1 and its importance in linking Ras to the MAP kinase
pathway is well established. However, some studies suggest that Raf-1
may have actions other than activation of the Ras/MAP kinase pathway.
Alessi et al. (21) have reported that inhibition of MEK by
PD098059 in PDGF- and insulin-stimulated Swiss 3T3 cells or
IGF-I-stimulated L6 cells resulted in an increase in Raf-1 activity,
although the consequences of this elevated Raf-1 activity were not
investigated. They suggest that downstream components of the MAP kinase
pathway may act to suppress Raf-1 activity, possibly through
hyperphosphorylation. However, in hippocampal neuronal cells, elevated
levels of Raf-1 activity, but not MEK or ERK, were sufficient for
differentiation (63). Transfection with a Raf-1:estrogen receptor
fusion gene, Raf-1:ER, resulted in increased Raf-1 activity and
extended differentiation following stimulation with estradiol.
Prolonged activation of MAP kinases was not sufficient for
differentiation, suggesting an alternative pathway where Raf-1, but not
MAP kinases, functions in differentiation of neuronal cells. Yen
et al. (64) have reported that expression of an activated
form of Raf-1 accelerates terminal differentiation of promyelocytic
leukemia cells, and this is accompanied by down-regulation of
retinoblastoma gene product phosphorylation. However, Ming et
al. (18) have reported that neither Ras nor Raf-1 plays a role in
activation of p70S6k. Dominant negative mutants of Ras or
Raf-1 both failed to inhibit p70S6k activation by EGF in
human 293 cells but did inhibit MAP kinase activation. We have shown
that p70S6k activity is critical for differentiation in
L6A1 skeletal muscle cells, and we are currently exploring the specific
role that Raf-1 plays in this process.
It is striking that two such different responses of myoblasts to the IGFs are mediated by quite distinct signaling pathways rather than resulting from subtle differences in timing or concentrations of signaling intermediates. Although many recent studies have examined IGF signaling pathways, none have directly addressed the issue of how IGF-I can stimulate both proliferation and differentiation in a single cell type such as skeletal muscle. In this study we have now shown that different signaling pathways are specifically associated with each response; cell proliferation is mediated primarily by the Ras/Raf-1/MAP kinase pathway, whereas stimulation of differentiation utilizes the PI 3-kinase/p70S6k pathway.
We thank Paul Walton and John Ballard (GroPep Pty Ltd, Adelaide, Australia) for a generous gift of R3 IGF-I. We also thank Alan Saltiel (Parke-Davis Pharmaceuticals, Ann Arbor, MI) for the MEK inhibitor, PD098059, Eric Olson (UT Southwestern Medical Center, Dallas, TX) for the myogenin cDNA probe, and W. R. Wright (University of Texas, Austin, TX) for the anti-myogenin antibody. We would especially like to thank Cathleen Jenney for superb technical assistance.