Insulin-like Growth Factor-I Rapidly Activates Multiple Signal Transduction Pathways in Cultured Rat Cardiac Myocytes*

(Received for publication, March 10, 1997, and in revised form, May 8, 1997)

Rocío Foncea Dagger §, Monica Andersson , Albert Ketterman par , Vicky Blakesley **, Mario Sapag-Hagar Dagger , Peter H. Sugden , Derek LeRoith ** and Sergio Lavandero Dagger Dagger Dagger

From the Dagger  Departamento de Bioquímica y Biología Molecular, Facultad Ciencias Químicas y Farmacéuticas, Universidad de Chile, Olivos 1007, Santiago, Chile, the  Division of Cardiac Medicine, Imperial College School of Medicine, National Heart and Lung Institute, London SW3 6LY, United Kingdom, and the ** Diabetes Branch, NIDDK, National Institutes of Health, Bethesda, Maryland 20892-1770

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

In response to insulin-like growth factor-I (IGF-I), neonatal rat cardiac myocytes exhibit a hypertrophic response. The elucidation of the IGF-I signal transduction system in these cells remains unknown. We show here that cardiac myocytes present a single class of high affinity receptors (12,446 ± 3,669 binding sites/cell) with a dissociation constant of 0.36 ± 0.10 nM. Two different beta -subunits of IGF-I receptor were detected, and their autophosphorylation was followed by increases in the phosphotyrosine content of extracellular signal-regulated kinases (ERKs), insulin receptor substrate 1, phospholipase C-gamma 1, and phosphatidylinositol 3-kinase. IGF-I transiently activates c-Raf in cultured neonatal cardiac myocytes, whereas A-raf is activated much less than c-Raf. Two peaks of ERK activity (ERK1 and ERK2) were resolved in cardiac myocytes treated with IGF-I by fast protein liquid chromatography, both being stimulated by IGF-I (with EC50 values for the stimulation of ERK1 and ERK2 by IGF-I of 0.10 and 0.12 nM, respectively). Maximal activation of ERK2 (12-fold) and ERK1 (8.3-fold) activities was attained after a 5-min exposure to IGF-I. Maximal activation of p90 S6 kinase by IGF-I was achieved after 10 min, and then the activity decreased slowly. Interestingly, IGF-I stimulates incorporation of [3H]phenylalanine (1.6-fold) without any effect on [3H]thymidine incorporation. These data suggest that IGF-I activates multiple signal transduction pathways in cardiac myocytes some of which may be relevant to the hypertrophic response of the heart.


INTRODUCTION

Left ventricular hypertrophy is both an important cardiovascular risk factor epidemiologically associated with cardiac failure and a frequent pathology of major significance in cardiovascular medicine. The myocardium is composed of many different cell types with cardiac myocytes contributing the greatest protein mass. In response to hormonal (polypeptide growth factors, endothelin, angiotensin II) and mechanical stimuli (1-6), the myocardium adapts by hypertrophy of individual myocytes. Because these cells are terminally differentiated cells that have lost the ability to proliferate, cardiac growth during hypertrophy results primarily from an increase in cellular protein content, with little or no change in cardiac myocyte number (7). The central features of the myocardial hypertrophic response are increases in the mass, volume, and contractile protein content of the myocytes, the induction of contractile protein gene expression, and the expression of embryonic genes and proto-oncogenes (7, 8).

Among growth factors, insulin-like growth factor-I (IGF-I)1 is significant because it promotes hypertrophy by growth and differentiation in many types of cells (9-11); it also mediates the anabolic and cardiovascular actions of growth hormone in vivo (12). IGF-I and its receptor (IGF-IR) are present on the neonatal rat myocardium, consistent with IGF-I regulating growth and hypertrophy of cardiac myocytes in the developing heart in an autocrine or paracrine manner (13). IGF-I acts directly on cultured neonatal cardiomyocytes to induce myocyte hypertrophy, which leads to increases in mRNA expression and synthesis of contractile proteins (14). The administration of recombinant IGF-I enhances ventricular hypertrophy and function during the onset of experimental heart failure in the rat (15, 16). There is also clear clinical evidence for a role of IGF-I in the initiation and development of left ventricular hypertrophy. Patients with dilated cardiomyopathy and heart failure treated with recombinant growth hormone showed increased myocardial mass and contractile performance accompanied by a doubled serum IGF-I concentration (17, 18). Moreover, cardiac hypertrophy develops in acromegalic patients with concomitantly increased plasma concentrations of both growth hormone and IGF-I (19). Increased plasma IGF-I concentrations have been reported in patients with hypertension and cardiac hypertrophy (20). The hypertension induces significant increases in cardiac IGF-I mRNA and protein in parallel with the onset and early development of experimental cardiac hypertrophy; this is followed by a normalization of the IGF-I mRNA once the hypertrophic response is established (21). A very recent report has established that the overexpression of IGF-I in cardiac myocytes leads to cardiomegaly mediated by an increased number of cells in the heart (22).

The mechanism by which IGF-I exerts its growth effect on cardiac myocytes is still unknown. The IGF-IR is an alpha 2beta 2 heterotetrameric protein with ligand-stimulated tyrosine kinase activity (23). Binding of IGF-I to its receptor induces receptor autophosphorylation in the intracellular kinase domain of the beta -subunit and results in activation of the intrinsic tyrosine kinase activity of the IGF-IR (24, 25). The predominant substrate of the IGF-IR is IRS-1, a docking protein that has multiple tyrosines in YMXM or related motifs known to associate with proteins containing SH2 domains. Phosphorylated IRS-1 regulates the activity of certain SH2 domain-containing proteins such as phosphatidylinositol 3-kinase (PI 3-kinase) (26, 27). IRS-1 also associates with other SH2 domain-containing proteins involved in growth factor signaling pathways, including Grb-2, Nck, and Syp (23). Other phosphotyrosine substrates of the IGF-I signaling pathway are PLC-gamma and Shc (23); and direct association of Shc with activated IGF-IR has also been detected (28). Phosphorylated Shc associates with Grb-2 and subsequently, through a Grb-2·SOS (Son of Sevenless) complex, activates Ras and Raf-1, an intermediate in the Ras-ERK signaling pathway (29). In the ensuing phosphorylation cascade, activation of ERKs occurs after phosphorylation by the mixed function threonine-tyrosine kinase MEK. Some of these kinases, as well as protein kinase C and RSK, can regulate the activities of a diverse array of cellular and nuclear proteins, including transcription factors.

The signaling pathways of other hypertrophic agonists (endothelin and acidic fibroblast growth factor) may converge at or above the level of the ERK cascade in cardiac myocytes (30). The elucidation of the IGF-I signal transduction system, and especially the degree of involvement of the IGF-IR and the ERK cascade during the cardiac hypertrophic process, is of considerable interest and constitutes the aim of this work.


EXPERIMENTAL PROCEDURES

Animals

Harlan Sprague Dawley rats were bred in the Animal Breeding Facilities from the National Heart and Lung Institute (London, U. K.), NIDDK (Bethesda, MD), or the Faculty of Chemical and Pharmaceutical Sciences, University of Chile (Santiago).

Materials

[gamma -32P]ATP, [3H]phenylalanine, and [methyl-3H]thymidine were from Amersham International (Bucks, U. K.), and 125I-IGF-I was from NEN Life Science Products. 12-O-Tetradecanoylphorbol-13-acetate (TPA), Dulbecco's modified Eagle's medium (DMEM), medium 199 (M199), n-octyl beta -D-glucopyranoside, protease inhibitors, protein A-Sepharose, bovine myelin basic protein (MBP), and other biochemicals were purchased from Sigma unless stated otherwise. Culture dishes (Primaria) were from Falcon, and heat-inactivated fetal calf serum and horse serum were from Sera-Lab. Other tissue culture products were from Life Technologies, Inc. Glutathione-Sepharose was from Pharmacia Biotech Inc. Affinity-purified antibodies raised against COOH-terminal peptide sequences of c-Raf (CTLTTSPRLPVF) or A-Raf (CLLSAARLVP), and the corresponding peptides were from Santa Cruz Biotechnology Inc. (Santa Cruz, CA) as were the antibodies raised against IGF-IR beta -subunit, tyrosine-phosphorylated proteins (anti-phosphotyrosine antibody clone 4G10), PLC-gamma 1, and RSK. The polyclonal anti-IGF-IR beta -subunit antibody was raised against the COOH-terminal peptide sequence of the beta -subunit of IGF-IR (AHMNGGRKNERALPLPQSST). We have also assessed that this antibody does not cross-react with insulin receptor beta -subunit using different cell lines that express different numbers of insulin receptor and IGF-IR (31, 32). Enhanced chemiluminescence (ECL) immunoblotting detection reagents, autoradiographic film, and prestained molecular mass standard proteins were from Amersham International. Protein assay reagents were from Bio-Rad. Human recombinant IGF-I was donated by Drs. P. Valenzuela and C. George-Nascimento (Chiron Corp.) or was purchased from Boehringer-Mannheim GmbH (Mannheim, Germany). IRS-1 antibody was a gift from Dr. J. Pierce (NCI, NIH). Clones for Glutathione S-transferase (GST) fusion proteins and anti-murine ERK antibody were donated by Prof. C. J. Marshall (Chester Beatty Laboratories, Institute of Cancer Research, London, U. K.). Recombinant murine ERK2 and MEK1 were expressed as GST fusion proteins in Escherichia coli and were purified by glutathione-Sepharose affinity chromatography as described previously (29). For the assay of MEK phosphorylation by the immunoprecipitated protein kinases, recombinant MEK1 was modified by site-directed mutagenesis to produce GST-MEK1 (R97/A291/A385), a catalytically inactive form of MEK1 in which a Lys residue essential for kinase activity is mutated (K97R) and which also lacks ERK consensus phosphorylation sequences (T291A and T385A). Recombinant GST-ERK2 was stored at -20 °C in 50% (v/v) glycerol (final protein concentration 25 mg/ml), whereas recombinant MEK1 species were stored at -80 °C in 5%(v/v) glycerol (final protein concentration 10 mg/ml).

Primary Culture

Neonatal ventricular myocytes were prepared from hearts of 1-3-day-old Harlan Sprague Dawley rats as described previously (33). Briefly, ventricles were trisected, pooled, and myocytes dissociated in a solution of collagenase and pancreatin. After enzymatic dissociation, the cells were selectively enriched for cardiac myocytes by being preplated in DMEM/M199 (4:1) containing 10% (v/v) horse serum, 5% (v/v) heated-inactivated fetal calf serum, penicillin, and streptomycin (100 units/ml). The myocytes, plated at a final density of 1.0-1.4 × 103/mm2 on gelatin-precoated 35-mm or 60-mm dishes, respectively, were confluent and spontaneously beating after 18 h. Serum was withdrawn for 24 h before the cells were treated further with agonists IGF-I (0-100 nM for 0-60 min) or TPA (1 µM for 3-5 min) in serum-free medium (DMEM/M199) at 37 °C.

IGF-I Binding Assay

IGF-I binding to ventricular cardiac myocytes was quantified using monoiodinated 125I-IGF-I. Confluent cardiac myocytes in 12-well culture plates were washed with 1 ml of binding buffer (100 mM Hepes, pH 7.4, 120 mM NaCl, 1 mM EDTA, 5 mg/ml bovine serum albumin) and incubated in binding buffer containing 25,000 cpm (approximately 20 pM) of 125I-IGF-I and increasing amounts of unlabeled IGF-I (0-1,000 ng/ml) for 5 h at 4 °C. The cells were washed with cold PBS and solubilized in 0.2 M NaOH before being counted with a gamma -counter (GammaTrac 1290, Tm Analytic, Brandon, FL).

IGF-I-stimulated Cardiac Myocyte Tyrosine Phosphorylations

Tyrosine phosphorylation of cellular proteins was analyzed by immunoblotting with an anti-phosphotyrosine antibody. Confluent cardiac myocytes in 60-mm dishes were exposed to IGF-I (0-100 nM) for 0-60 min in serum-free medium at 37 °C. Upon completion of the exposure protocol, the medium was removed by aspiration and the cells washed twice with cold Ca2+/Mg2+-free Dulbecco's PBS. Myocytes were scraped into 150 µl of cold lysis buffer (20 mM Hepes, pH 7.4, 100 mM NaCl, 4 mM sodium pyrophosphate, 2 mM sodium orthovanadate, 10 mM EDTA, 1 mM phenylmethylsulfonyl fluoride (PMSF), 10 mM NaF, 1% (v/v) Triton X-100, 2 µg/ml leupeptin, and 2 µg/ml aprotinin). The protein content of the lysate was determined by Bradford's method (34), and equal amounts of protein were separated by SDS-PAGE on 9% gels. Proteins were then transferred electrophoretically to a nitrocellulose membrane (0.45 µm). The membranes were blocked with 3% (w/v) bovine serum albumin in PBST (80 mM Na2HPO4, 20 mM NaH2PO4, 100 mM NaCl, 0.05% (v/v) Tween 20, pH 7.4) for 1 h at room temperature. Tyrosine-phosphorylated proteins were probed with a monoclonal anti-phosphotyrosine antibody and detected with horseradish peroxidase-conjugated anti-mouse immunoglobulin using an ECL system. The dilutions of the first and second antibodies were 1:1,000 and 1:4,000, respectively. Immunoblots were quantified by densitometry.

Immunoblot Analysis for beta -Subunit of IGF-IR and IRS-1

The amounts of IGF-IR or IRS-1 present were determined by immunoblotting with monoclonal anti-IGF-IR beta -subunit antibody or with polyclonal anti-IRS-1 antibody as described previously (35).

Immunoprecipitation and Immunoblot Analysis of PLC-gamma 1

Cleared cell lysates were prepared as described above. For immunoprecipitation, 400 µg of protein was incubated with 1 µg of an anti-PLC-gamma 1 antibody at 4 °C overnight. Then, 50 µl of 10% protein A-Sepharose in 50 mM Tris-HCl buffer, pH 7.5, was added and incubated at 4 °C for 3 h. The precipitates were washed three times with immunoprecipitation buffer (20 mM Tris, 300 mM NaCl, 2 mM EDTA, 2 mM EGTA, 0.4 mM Na3VO4, 0.4 mM PMSF, pH 7.4) and separated on 9% SDS-PAGE. Resolved proteins were transferred electrophoretically to nitrocellulose membranes. Blots were incubated with anti-phosphotyrosine antibody (1:1,000 dilution) or anti-PLC-gamma 1 (1:1,000 dilution). Both antibodies were detected by horseradish peroxidase-conjugated anti-mouse or anti-rabbit immunoglobulin, respectively (1:4,000 dilution). The blots were then developed by ECL.

PI 3-Kinase Activity

Confluent cardiac myocytes grown in 60-mm dishes were incubated in serum-free DMEM/M199. After 24 h, IGF-I (0-100 nM) was added in fresh serum-free medium, and dishes were reincubated for 5 min at 37 °C. The cells were quickly washed once with ice-cold PBS and twice with wash buffer (20 mM Tris, 137 mM NaCl, 1 mM MgCl2, 1 mM CaCl2, and 100 µM Na3VO4, pH 7.5). Cells were solubilized in 600 µl of wash buffer containing 1% (v/v) Nonidet P-40, 10% (v/v) glycerol, and 0.35 mg/ml PMSF. The lysate was centrifuged at 10,000 × g for 10 min at 4 °C, and tyrosyl-phosphoproteins were immunoprecipitated with a monoclonal anti-phosphotyrosine antibody overnight at 4 °C. Then, 50 µl of 10% protein A-Sepharose in 50 mM Tris-HCl, pH 7.4, was added and incubated for 4 h at 4 °C. The immunoprecipitates were washed once with PBS containing 1% (v/v) Nonidet P-40 and 100 µM Na3VO4, twice with 100 mM Tris, pH 7.5, containing 500 mM LiCl and 100 µM Na3VO4, and once with 10 mM Tris, pH 7.5, containing 100 mM NaCl, 1 mM EDTA, and 100 µM Na3VO4. The pellets were resuspended in 40 µl of 10 mM Tris, pH 7.5, containing 100 mM NaCl and 1 mM EDTA. To each tube was added 10 µl of 100 mM MnCl2 and 20 µg of phosphatidylinositol. The phosphorylation reaction was started by the addition of 10 µl of 440 µM ATP containing 30 µCi of [gamma -32P]ATP. After 10 min the reaction was stopped by the addition of 20 µl of 8 M HCl and 160 µl of CHCl3/methanol (1:1). The organic phase was extracted and applied to a silica gel TLC plate. The plates were developed in CHCl3/CH3OH/H2O/NH4OH (60:47:11.3:2), dried, and visualized by autoradiography. The spots were quantified with a PhosphorImager (Molecular Dynamics, Sunnyvale, CA).

Immunoprecipitation of A-Raf and c-Raf from Cultured Ventricular Myocytes

Serum-starved ventricular myocytes were exposed to agonists in serum-free medium (DMEM/M199). After the medium had been removed by aspiration, cells were washed twice with cold Ca2+/Mg2+-free Dulbecco's PBS and scraped into 200 µl of cold buffer A (20 mM Hepes, 75 mM NaCl, 2.5 mM MgCl2, 20 mM beta -glycerophosphate, 0.5 mM DTT, 0.1 mM EDTA, pH 7.5, containing 0.2 mM Na3VO4, 2 µg/ml leupeptin, 100 µg/ml PMSF, 0.05% (v/v) Triton X-100). Extracts were incubated at 4 °C for 10 min, then centrifuged (10,000 × g, 10 min, 4 °C); supernatant fractions were retained for assay. In control experiments, we determined that the detergent-insoluble pellets did not contain Raf isoforms as assessed by immunoblotting, and the pellets were not analyzed further. The detergent-soluble supernatants (approximately 1.5-2.0 mg protein/ml) were retained. When activation of A-Raf was directly compared with activation of c-Raf, each supernatant was divided equally. Antibodies that recognize c-Raf or A-Raf (3 µl) were added to each portion (90 (µl), and these were incubated with mixing at 4 °C for 2 h. Protein A-Sepharose was added, and the incubation was continued for a further hour. The immunoprecipitates were washed three times with buffer A and twice with buffer B (20 mM Hepes, 75 mM NaCl, 2.5 mM MgCl2, 20 mM beta -glycerophosphate, 0.5 mM DTT, 0.1 mM EDTA, pH 7.5).

Activation of MEK by Immunoprecipitated c-Raf and A-Raf

Protein A-Sepharose immunoprecipitates of c-Raf and A-Raf were assayed for their activation of recombinant GST-MEK1 (36) using a coupled assay in which GST-MEK1 activates GST-ERK2. The activity of GST-ERK2 is subsequently measured by incorporation of 32P from [gamma -32P]ATP into MBP. Immunoprecipitates were resuspended in 30 µl of buffer C (30 mM Tris, 0.1 mM EGTA, pH 7.5, containing 0.1% (v/v) mercaptoethanol, 0.03% (w/v) Brij 35, 10 mM magnesium acetate, and 20 mM n-octyl beta -D-glucopyranoside] that had been supplemented with 80 µM (unlabeled) ATP, 2 µg/ml GST-MEK1, and 20 µg/ml GST-ERK2. The reactions were incubated at 30 °C for 20 min with intermittent mixing, then terminated by mixing 15 µl of the supernatant with 15 µl of ice-cold buffer B containing 1 mg/ml bovine serum albumin. To assay the activity of GST-ERK2, 10 µl of the diluted supernatants was mixed with 40 µl of MBP phosphorylation buffer (50 mM Tris, 0.1 mM EGTA, pH 8.0, containing 0.4 mg/ml MBP, 50 µM ATP, 12.5 mM magnesium acetate, and 1 µCi of [gamma -32P]ATP). Mixtures were incubated for 15 min at 30 °C; the reaction was terminated by spotting onto P-81 paper, which was then washed three times in 75 mM H3PO4. Controls consisted of incubations of antibodies alone with buffer A and protein A-Sepharose; these results were subtracted from each data point. One unit of Raf activity is that amount that catalyzed the activation of sufficient GST-ERK2 to transfer 1 fmol of phosphate from [gamma -32P]ATP to MBP/min in the second stage of the assay. Preliminary experiments showed that no activity from IGF-I-stimulated cells was associated with the protein A-Sepharose after incubation of these detergent-soluble lysates with protein A-Sepharose in the absence of antibodies to c-Raf or A-Raf.

Phosphorylation of MEK1 by Immunoprecipitated c-Raf and A-Raf

Protein A-Sepharose immunoprecipitates of c-Raf and A-Raf were resuspended in 30 µl of buffer C containing 50 µM ATP, 1 mg/ml GST-MEK1 (R97/A291/A385), and 2 µCi [gamma -32P]ATP. The reaction was incubated at 30 °C for 20 min with intermittent mixing. The reaction was stopped by centrifugation of the immunoprecipitated kinases; 15-µl portions of supernatants were then pipetted into SDS-PAGE sample buffer. Samples were boiled for 5 min, and proteins were separated by electrophoresis on 10% SDS-polyacrylamide gels. Gels were stained, dried, and subjected to autoradiography. Preliminary experiments showed that in the absence of antibodies to c-Raf or A-Raf, no MEK phosphorylation activity from detergent-soluble lysates of IGF-I-stimulated cells was associated with the protein A-Sepharose.

FPLC of MEK and ERK

Ventricular myocytes were lysed in buffer A. Extracts were incubated on ice for 10 min, then centrifuged (10,000 × g, 2 × 10 min, 4 °C). Supernatants were applied to Mono Q HR5/5 column (Pharmacia) equilibrated with 50 mM Tris, 2 mM EDTA, 0.5 mM DTT, 5% (v/v) glycerol, 0.1% (v/v) Triton X-100, containing 0.3 mM Na3VO4, 50 µg/ml PMSF, pH 7.5, at a flow rate of 1 ml/min. After washing with 5 ml of equilibration buffer, proteins were eluted with a linear gradient of 0-0.5 M NaCl. Fractions (1 ml) were collected and assayed immediately for MEK and ERK activities.

Assays of ERK and MEK

ERK was assayed by the "direct" assay; supernatant samples were incubated with MBP and [gamma -32P]ATP as described earlier (37). Reactions were terminated by spotting 40 µl of the reaction mixture onto P-81 paper and washing in 75 mM H3PO4 (1 × 5 min, 3 × 30 min). Phosphate incorporation was measured by Cerenkov counting. In these assays, 1 unit of ERK catalyzes the incorporation of 1 pmol of phosphate into MBP/min.

MEK activity was assayed by a two-step assay using the activation of exogenous recombinant GST-ERK2 (30). Supernatant samples were diluted 20-fold in buffer B. After samples (10 µl) had been mixed with 5 µl of GST-ERK2 in Buffer A containing 0.04% (v/v) Brij 35, 0.1% (v/v) 2-mercaptoethanol, and 0.5 µM okadaic acid, the activation of GST-ERK2 was initiated by the addition of 5 µl of 80 mM magnesium acetate and 0.8 µM unlabeled ATP. After 15 min at 30 °C, the activity of GST-ERK2 was assayed by the addition of 25 µl of 0.8 mg/ml MBP in buffer A containing 2.25 µM protein kinase A inhibitor, 2.25 µM okadaic acid, and 5 µl of 40 mM magnesium acetate, 0.4 µM [gamma -32P]ATP (0.5 µCi/assay). After a further 15 min at 30 °C, the reaction was terminated by spotting 40 µl of the reaction mixture onto P-81 paper that was washed with 75 mM H3PO4 as described for the ERK assay above. To correct for endogenous ERK activity in samples, rates in control assays carried out in the absence of GST-ERK2 were subtracted. The autophosphorylation and autoactivation of GST-ERK2 occurring in the incubation of GST-ERK2 with ATP in these assays in the absence of cell lysates were also subtracted. One unit of MEK is the amount that, in 1 min of the preincubation in the presence of unlabeled ATP, specifically catalyzes the activation of exogenous GST-ERK2, sufficient to transfer 1 pmol of phosphate into MBP/min in the subsequent ERK assay.

In-gel ERK Assay and Measurement of ERK Phosphorylation State

Activities of MBP kinases were examined using an in-gel kinase assay (38). Briefly, cells were treated with agonists, lysates were prepared, and proteins resolved in 10% SDS-polyacrylamide gels containing 0.5 mg/ml MBP. ERK1, ERK2 and additional MBP kinase activities were detected by incubation of these gels with [gamma -32P]ATP and autoradiography as described earlier (38). This assay was used to confirm that ERK1 and ERK2 activities changed in parallel with activities measured by the direct assay. Agonist-stimulated phosphorylation of endogenous ERK2 was also determined from the shift in electrophoretic mobility as described (38).

p90 RSK Activity

RSK activity was measured by an immune complex kinase assay using an S6 peptide (RRRLSSLRA) as a substrate as described previously (39). The lysates were prepared from cardiomyocytes grown in 60-mm dishes. After stimulation with IGF-I (10 nM), the cells were removed by scraping and lysed with lysis buffer (10 mM potassium phosphate, pH 7.4, 1 mM EDTA, 5 mM EGTA, 10 mM MgCl2, 50 mM beta -glycerophosphate, 1 mM Na3VO4, 2 mM DTT, 40 µg/ml PMSF, 10 mM okadaic acid, 0.8 µg/ml leupeptin, 10 mM p-nitrophenyl phosphate, and 10 µg/ml aprotinin). Equal amounts of lysate proteins (300 µg) were diluted with 10 volumes of RIPA buffer (10 mM Tris, 150 mM NaCl, 1% (v/v) Triton X-100, 1% (w/v) deoxycholic acid, and 0.1% (w/v) SDS, pH 7.2) and were incubated with 2 µl of anti-S6 kinase antibody for 2 h at 4 °C. Then protein A-Sepharose was added, and the immunoprecipitates were washed with lysis buffer without p-nitrophenyl phosphate. Ten µl of immunoprecipitate was incubated with 12.5 µl of 2 × kinase buffer (50 mM MOPS, 120 mM beta -glycerophosphate, 10 mM EDTA, 30 mM MgCl2, 60 mM p-nitrophenyl phosphate, 2 mM DTT, pH 7.2) containing 2 mM Na3VO4, 2 µM protein kinase A inhibitor, 12.5 µCi of [gamma -32P]ATP, and 12.5 µl of 5 µM S6 peptide (RRRLSSLRA) at 30 °C for 15 min. To stop the reaction, samples were spotted onto Whatman P-81 paper and washed five times (5 min each) with 180 mM H3PO4 and once with 95% ethanol. Radioactivity was determined in a beta -counter.

Thymidine Incorporation

Confluent cardiac myocytes in 12-well plates were grown to quiescence in serum-free DMEM/M199 for 24 h. IGF-I (0-100 nM) in fresh serum-free DMEM/M199 was added, and the cells were incubated for an additional 18 h. [methyl-3H]Thymidine (1 µCi/well) was then added and incubation continued for a further 6 h. Cells were rinsed twice with ice-cold PBS, twice with ice-cold 5% trichloroacetic acid, and twice with ethanol. The cells were dissolved in 0.3 ml of 1 M NaOH; the resulting solutions were neutralized with 0.3 ml of 1 M HCl and counted in a liquid scintillation counter.

Phenylalanine Incorporation

Confluent cells were grown to quiescence in serum-free medium for 24 h. Cardiac myocytes were stimulated with IGF-I (0-100 nM) in fresh serum-free medium for 24 h in the presence of [3H]phenylalanine (5 µCi/well). The cells were washed with ice-cold PBS, and 10% trichloroacetic acid was added at 4 °C for 60 min to precipitate the proteins. The precipitates were washed twice with ethanol and dissolved in 1 M NaOH; the resulting solutions were neutralized with 1 M HCl and counted in a liquid scintillation counter.

Expression of Results

Results are expressed either as means ± S.E. for the number of independent experiments indicated (n) or as examples of representative experiments performed on at least two or three separate occasions. Time course and dose-dependent analysis were performed using analysis of variance, and comparisons between groups were performed using a protected Tukey's t test.


RESULTS

Expression of IGF-IRs on Cultured Neonatal Cardiac Myocytes

Binding of IGF-I to neonatal cardiac myocytes was saturable and specific (Fig. 1). The Scatchard plot was curvilinear, and the analysis (40) suggested the presence of two classes of binding sites (Fig. 1, inset). Cultured cardiac myocytes had high affinity binding sites of 12,446 ± 3,669 binding sites/cell with a dissociation constant for IGF-I of 0.36 ± 0.10 nM (n = 4). Low affinity binding sites (Kd = 27 ± 11 nM), whose number was estimated to be 77,911 ± 7,683 binding sites/cell, were also detected in neonatal cardiac myocytes. Binding studies with 125I-IGF-I(N-3), an IGF-I analog lacking the three NH2-terminal amino acids which binds only to high affinity IGF-IR (41), suggest that low affinity IGF-I binding sites may be correspond to nonreceptor IGF-I-binding proteins (data not shown). Although there are no comparative studies between receptors for insulin and IGF-I in neonatal cardiac myocytes, our results show that insulin receptors appear to be in lesser amount than IGF-IRs (data not shown).


Fig. 1. IGF-I binding assay in cultured neonatal cardiac myocytes. Confluent cardiac myocytes were incubated with 125I-IGF-I and the indicated amounts of unlabeled IGF-I as described under "Experimental Procedures." Maximal binding was determined in the absence of unlabeled IGF-I and represented 3.4 ± 0.1% (n = 4) of the total input radioactivity. Each value is the mean of duplicate determinations in one representative experiment. Similar profiles were obtained with four independent experiments. Inset, Scatchard plot for IGF-I binding to cultured cardiac myocytes.
[View Larger Version of this Image (16K GIF file)]

IGF-IR Autophosphorylation and Phosphorylation of Endogenous Substrates

As shown in Fig. 2 (A and B upper), incubation of cardiac myocytes with IGF-I resulted in increases in the phosphotyrosine content of several proteins with apparent molecular masses of 42, 44, 96, 100, and 185 kDa, corresponding to the two ERK isoenzymes, the two beta -subunits of IGF-IR and IRS-1. IGF-IR autophosphorylation was much greater in neonatal cardiac myocytes exposed to IGF-I concentrations above 5 nM; two separate bands were observed at low levels of receptor autophosphorylation. In contrast, receptor autophosphorylation was undetectable in cells incubated without IGF-I. Membranes shown in Fig. 2 B, upper, were stripped and reblotted with a polyclonal antibody directed against the beta -subunit of IGF-IR to confirm both the presence of two isoforms of the beta -subunit of IGF-IR and that similar amounts of IGF-IR protein were present in all samples (Fig. 2B, lower). Fig. 2C shows the time course of stimulation of cultured cardiac myocytes by 10 nM IGF-I; phosphorylation of the IGF-IR beta -subunit was maximal within 1 min.


Fig. 2. Stimulation of tyrosine phosphorylation in cultured neonatal cardiac myocytes by IGF-I. Lysates of cells treated with IGF-I were subjected to SDS-PAGE on a 9% gel, and proteins containing phosphotyrosine were detected with Western immunoblotting as described under "Experimental Procedures." Cell lysates containing equal amounts of protein (20 and 60 µg for panels A and B, respectively) were loaded in each lane. Results are representative of three independent experiments. The positions of prestained molecular mass markers (kDa) are indicated to the left of each panel. Proteins with increased tyrosine phosphorylation are indicated by the arrows. Panel A, cardiac myocytes were treated with 0-100 nM IGF-I at 37 °C for 1 min. Panel B, cardiac myocytes were treated with IGF-I at the concentrations indicated for 1 min at 37 °C, and cell lysates were subjected to SDS-PAGE on a 9% gel, transferred to nitrocellulose, and blotted with a monoclonal anti-phosphotyrosine antibody (4G10) (upper) and polyclonal anti-beta -subunit of IGF-IR antibody (lower). Cell lysates containing equal amounts of protein (20 µg) were loaded in each lane. Panel C, cardiac myocytes were treated with 10 nM IGF-I at 37 °C for the times indicated. Results are representative of two individual experiments. The positions of prestained molecular mass markers (kDa) are indicated to the left of each panel. The position of beta -subunit of IGF-IR is indicated to the right of the panel by open arrows.
[View Larger Version of this Image (58K GIF file)]

The IRS-1 pathway is activated following IGF-IR phosphorylation (42). We evaluated IRS-1 activation by incubating cells with IGF-I (0-100 nM) for 1 min at 37 °C. Exposure to concentrations of IGF-I above 10 nM was accompanied by phosphorylation of the expected 185-kDa band (Fig. 2A); phosphorylation was apparent 1 min after stimulation with 10 nM IGF-I (Fig. 2C). When membranes were stripped and reblotted with a polyclonal antibody directed against IRS-1, we confirmed the presence of IRS-1 and that similar amounts of IRS-1 protein were present in all samples (results not shown).

Tyrosine Phosphorylation of PLC-gamma 1 and Activation of PI 3-Kinase by IGF-I

Fig. 3A shows the enhancement of tyrosine phosphorylation of PLC-gamma 1 in cells stimulated with IGF-I. Maximum stimulation (5-fold) occurred 2 min after the addition of IGF-I (Fig. 3A). PLC-gamma 1 coprecipitated with a 185-kDa phosphotyrosine protein. When membranes were stripped and reblotted with a polyclonal antibody directed against PLC-gamma 1, we confirmed the identity of PLC-gamma 1 and that similar amounts of PLC-gamma 1 protein were present in all samples (Fig. 3B). Since the 185-kDa phosphorylated protein that coprecipitated with PLC-gamma 1 may correspond to IRS-1, the membrane was reblotted with different anti-IRS-1 polyclonal antibodies (catalog numbers 06-248 and 06-524 from Upstate Biotechnology Inc., Lake Placid, NY, and sc-559 from Santa Cruz Biotechnology, Santa Cruz, CA). However, the presence of IRS-1 in the immunoprecipitates was not detected. A similar result was obtained when IRS-1 was first immunoprecipitated, and the membrane was blotted with an anti-PLC-gamma . PI 3-kinase activity was increased in cardiac myocytes incubated with 10 nM IGF-I for 5 min (Fig. 4A); this increase was maximal (2.5-fold) after 5 min of incubation with 30 nM IGF-I (Fig. 4B).


Fig. 3. Tyrosine phosphorylation of PLC-gamma 1 by IGF-I in cultured cardiac myocytes. Cardiac myocytes were stimulated with 10 nM IGF-I at 37 °C for the times indicated. Cell lysates were treated with an anti-PLC-gamma 1 polyclonal antibody, and immunoprecipitates were isolated, as described under "Experimental Procedures." Immunoprecipitates were analyzed by SDS-PAGE and immunoblotting with antibodies to phosphotyrosine antibody (panel A) and PLC-gamma 1 (panel B) as indicated. Similar amounts of PLC-gamma 1 immunoprecipitates were present in all samples. The positions of PLC-gamma 1 and IRS-1 are indicated by arrows. The result shown is representative of two independent experiments.
[View Larger Version of this Image (19K GIF file)]


Fig. 4. Stimulation of PI-3 kinase activity by IGF-I in cultured cardiac myocytes. Cardiac myocytes were exposed to IGF-I (0-100 nM) for 5 min at 37 °C. PI 3-kinase was immunoprecipitated with anti-phosphotyrosine antibody, and precipitates were assayed for enzymatic activity. Panel A, autoradiogram of a representative experiment with the origin and the relative mobility of phosphatidylinositol bisphosphate (PIP2) are indicated by arrows. Panel B, the radioactivity in the PIP2 shown in panel A was quantified with a PhosphorImager. PI 3-kinase activity is expressed as a percentage of stimulation over the basal level; values are means from two separate experiments.
[View Larger Version of this Image (39K GIF file)]

IGF-I Activates c-Raf Much More Than A-Raf in Cultured Neonatal Cardiac Myocytes

c-Raf is activated after exposure of neonatal cardiomyocytes to agonists acting through protein tyrosine kinase and G-protein receptors (36). Both c-Raf and A-Raf from neonatal cardiac myocytes form a stable complex with kinase inactive GST-MEK1 (R97/A291/A385) (36). Fig. 5A shows that IGF-I (10 nM) activated c-Raf through its ability to activate GST-MEK1 in a coupled assay in vitro. Maximal activation occurred within 3-10 min and returned to basal levels after 30 min. We confirmed that the amounts of immunoprecipitated c-Raf did not vary greatly (data not shown). There was no detectable activity in c-Raf immunoprecipitated from serum-starved ventricular myocytes exposed to serum-free medium. Although A-Raf was present in cultured ventricular myocytes, its activation by IGF-I was much less than c-Raf (closed circles, Fig. 5A). The amounts of A-Raf immunoprecipitates from the cells did not vary (data not shown).


Fig. 5. c-Raf is much more stimulated than A-Raf by IGF-I in cultured cardiac myocytes. Panel A, cardiac myocytes were treated with 10 nM IGF-I or 1 µM TPA for the times indicated at 37 °C. c-Raf and A-Raf were immunoprecipitated from the soluble cell lysates with anti-c-Raf and anti-A-Raf polyclonal antibodies, as described under "Experimental Procedures." Panel A, activity of the immunoprecipitated c-Raf (black-square) or A-Raf (bullet ) was measured in a coupled assay as MEK activating activity as described under "Experimental Procedures." The result shown is representative of two separate experiments. Panels B and C, cardiac myocytes were treated with IGF-I or TPA at 37 °C, immunoprecipitated with anti-c-Raf polyclonal antibody as described under "Experimental Procedures," and the kinase activity of c-Raf directly measured by the phosphorylation of the GST-MEK1 (R97/A291/A385). Blank reactions in which c-Raf antibody was incubated with buffer and protein A-Sepharose were always performed for each experiment (results not shown). Panel B, time course for the stimulation of c-Raf by 10 nM IGF-I. Panel C, individual 60-mm dishes of cardiac myocytes were exposed for 5 min to IGF-I (0-10 nM) or for 3 min to 1 µM TPA. The position of the mutant GST-MEK1 is indicated by the arrows on the right of each panel. The result shown is representative of two separate experiments.
[View Larger Version of this Image (25K GIF file)]

Activity of the immunoprecipitated c-Raf was also studied by the phosphorylation of GST-MEK1 (R97/A291/A385), a recombinant mutant MEK1 unable to undergo autophosphorylation and retrophosphorylation by endogenous ERK (43). This assay confirmed the rapid and transient activation of immunoprecipitated c-Raf (Fig. 5B). The maximum increase in c-Raf activity was 400% of the control value and the EC50 for IGF-I was approximately 0.1 nM (Fig. 5C). In cultured cardiac myocytes, TPA activates different isoenzymes of protein kinase C and causes sustained activation of MEK and ERK (33). Activation of c-Raf (15-fold) and A-Raf (3.3-fold) was attained after a 3-min exposure to TPA (1 µM). c-Raf was 29-fold more activated by TPA than by IGF-I (Fig. 5C).

Activation of MEK by IGF-I in Cultured Neonatal Cardiac Myocytes

Crude extracts of unstimulated cultured cardiac myocytes poorly activate exogenous inactive recombinant GST-ERK2. In contrast, IGF-I-treated cultured cardiac myocytes substantially stimulated MEK activity (results not shown). Supernatant fractions of cultured neonatal ventricular myocytes were subjected to FPLC on a Mono Q column, and fractions were assayed for their ability to phosphorylate and activate GST-ERK2. Extracts of cells exposed to 10 nM IGF-I for 5 min showed two peaks of MEK activity (KK1 and KK2) eluted at 70 and 130 mM NaCl (Fig. 6A), although the second peak was smaller than the first. The combined stimulation of MEK activities approached 10-fold. A similar MEK activity profile was obtained after exposure to 1 µM TPA for 5 min (results not shown). We have demonstrated previously that endogenous ERK activity does not interfere with the assay of GST-ERK2 activity (30).


Fig. 6. IGF-I activates MEK and ERK activity in cultured cardiac myocytes. Four 60-mm dishes of cardiac myocytes were treated with 10 nM IGF-I (solid symbols) for 5 min at 37 °C. Panel A, extracts were prepared and the supernatants combined and subjected to FPLC using a Mono Q column with elution with a linear NaCl gradient (0-0.5 M, dashed line) as described under "Experimental Procedures." Fractions (0.5 ml) were collected and assayed for MEK (square ) or ERK (open circle ). The open symbols represent the profiles of control cell extract activities. The two major peaks for MEK are labeled KK1 and KK2, and the two major peaks for ERK are labeled K1 and K2. Similar elution profiles were obtained with three separate preparations of cardiac myocytes. Panel B, samples of the fractions corresponding to peaks K1 and K2 (in panel A) from cardiac myocytes stimulated with 10 nM IGF-I for 5 min at 37 °C were pooled, concentrated, and examined by the in-gel MBP phosphorylation assay as described under "Experimental Procedures." The numbers to the left of the panel refer to the molecular masses (kDa) of marker proteins. The positions of the isotypes of ERK, ERK1 (44 kDa) and ERK2 (42 kDa), are indicated by the arrows. The result presented is representative of three separate experiments.
[View Larger Version of this Image (51K GIF file)]

Activation of ERK by IGF-I in Crude Extracts of Cultured Neonatal Cardiac Myocytes

To examine whether ERKs are activated by IGF-I, we next measured ERK activity by an in-gel ERK assay. There were only small changes in the intensity of the ERK2 band after the exposure of myocytes to IGF-I between 1 and 3 min, without any change in ERK1 band (Fig. 7A). The maximal intensities of ERK1 (12-fold) and ERK2 (8.3-fold) were attained after a 5-min exposure to IGF-I. Thereafter, activities declined rapidly returning to control values within 30 min (Fig. 7A). The time course for the effects of IGF-I (10 nM) on ERK activity is shown in Fig. 7B. The effect of IGF-I on the time course of ligand-stimulated phosphorylation of ERK2 in cultured cardiac myocytes was determined from the electrophoretic mobility shift of endogenous ERK2. IGF-I provoked a transient increase in ERK2 phosphorylation which followed a time course similar to that determined by the in-gel assay technique (data not shown). The dependence of ERK activation on the concentration of IGF-I was also characterized by in-gel assays (Fig. 7, panels C and D). The EC50 values for the stimulation of ERK1 and ERK2 in cultured cardiac myocytes by IGF-I were 0.10 and 0.12 nM, respectively. When cardiac myocytes were exposed for 5 min to a saturating concentration of IGF-I (10 nM), ERK1 and ERK2 activities were stimulated to 35 and 58%, respectively, of the TPA-induced activity (Fig. 7D). Exposure of cardiac myocytes to increasing concentrations of IGF-I for 5 min also caused phosphorylation of ERK2, as demonstrated by delayed mobility on SDS-PAGE (data not shown).


Fig. 7. Time course for the activation of ERK by IGF-I and dose-dependent effect in cultured cardiac myocytes. Cardiac myocytes in serum-free medium were stimulated with 10 nM IGF-I or 1 µM TPA for the times indicated at 37 °C (panels A and B) or were treated for 5 min at 37 °C with increasing concentrations of IGF-I or 1 µM TPA (panels C and D). Soluble fractions were prepared, and SDS-PAGE sample buffer was added. Samples were subjected to SDS-PAGE in 10% gel containing 0.2 mg/ml MBP. Panels A and C show a representative result of phosphorylation of MBP assayed in situ as described under "Experimental Procedures." The arrows to the right of the panels indicate the positions of ERK2 and ERK1. Panel B and D graphs show results of ERK1 (open circle ) and ERK2 (bullet ) activation from autoradiograms quantified by laser-scanning densitometry of gels depicted on panels A and C, respectively. Results (means ± S.E., n = five to eight separate observations) are expressed relative to ERK activities in extracts from control cells or to ERK activities in extracts from cells treated with 1 µM TPA for 5 min (maximal activation).
[View Larger Version of this Image (22K GIF file)]

Separation by FPLC of IGF-I-activated Isoforms of ERK in Cultured Neonatal Cardiac Myocytes

IGF-I stimulates ERK activity in cultured ventricular myocytes; this can be assayed directly in supernatants with MBP as substrate. FPLC of supernatant fractions from IGF-I-treated cells on the Mono Q (Fig. 6A) revealed two major peaks of MBP kinase activity eluting at 160 (peak K1) and 220 (peak K2) mM NaCl, respectively. The mean stimulation of each peak fraction was 3-fold.

Identification of ERK Isoenzymes Activated by IGF-I

Fractions from peaks K1 and K2 from Mono Q chromatography of extracts from cardiac myocytes incubated with 10 nM IGF-I for 5 min were pooled, concentrated, and analyzed by in situ phosphorylation of MBP gels. Two proteins of 42 and 44 kDa were identified in fractions corresponding to peak K1 and K2, respectively (Fig. 6B).

Stimulation of p90 RSK Activity by IGF-I in Cultured Cardiac Myocytes

p90 RSK is activated by ERK1 and ERK2 both in vivo and in vitro (44). The time course of activation of the p90 RSK by IGF-I (10 nM) in cultured cardiac myocytes is depicted in Fig. 8. p90 RSK activity reached a peak at 10 min and then decreased slowly.


Fig. 8. Activation of RSK in cultured cardiac myocytes incubated with IGF-I. Cardiac myocytes were treated with IGF-I (10 nM) at 37 °C for the times indicated. Immune-complex p90 RSK assays were performed with S6 peptide as substrate as described under "Experimental Procedures." Results are means ± S.E. of four separate experiments. The activity at time zero is designated as 1.0.
[View Larger Version of this Image (17K GIF file)]

Stimulation of Phenylalanine and Thymidine Incorporation by IGF-I in Cultured Cardiac Myocytes

After a 24-h incubation of myocytes with 10 nM IGF-I, incorporation of [3H]phenylalanine was increased 1.6-fold over control levels (Fig. 9A). No IGF-I-dependent stimulation of [3H]thymidine incorporation was observed in cultured cardiac myocytes (Fig. 9B).


Fig. 9. Stimulation of phenylalanine and thymidine incorporation by IGF-I in cultured cardiac myocytes. Cardiac myocytes were exposed for 24 h to indicated concentrations of IGF-I at 37 °C. Protein and DNA synthesis rates were determined by the incorporation of L-[2,6-3H]phenylalanine into protein (panel A) or [3H]thymidine into DNA (panel B) as described under "Experimental Procedures." Values represent the mean ± S.E. of three independent experiments. **p < 0.01 versus control.
[View Larger Version of this Image (14K GIF file)]


DISCUSSION

The development of cardiac hypertrophy constitutes a compensatory adaptation of cardiac myocytes to increased hemodynamic stress or to loss of contractile myocytes. In addition to an overall increase in protein and RNA content, there are alterations at the level of gene expression which distinguish the hypertrophic process from normal maturational growth (7). The mechanisms by which the mechanical stress is sensed by cardiac myocytes and growth-related signals are activated and integrated to regulate gene expression programs selectively during the hypertrophic process are largely unknown. The hypothesis is that growth factors (such as IGF-I) are produced by cardiac non-muscle cells or by the myocytes themselves in response to mechanical stress and that these factors, through specific cell surface receptors and intracellular signaling cascades, regulate protein synthesis and transcription of genes of the contractile apparatus, as well as others genes involved in cell growth. In cultured neonatal cardiac myocytes, IGF-I induces an early and sustained expression of the muscle-specific genes for troponin I and myosin light chain-2 with myocyte size almost doubling after 48 h of treatment with IGF-I (14). An increase in left ventricular IGF-I mRNA and its protein has been described in pressure overload cardiac hypertrophy in various models of hypertension; this suggests that IGF-I may be an important mediator of an adaptive hypertrophic response (21, 45, 46). However, the results of overexpression of IGF-I in transgenic mice have been contradictory (22, 47). For example, when overexpression of IGF-I was restricted to the heart, IGF-I stimulated an increase in ventricular muscle cell number in vivo. Surprisingly, cardiac myocyte cellular hypertrophy was not enhanced (22). Studies with IGF-I knockout mice have shown that lack of IGF-I does not prevent the development of pressure overload hypertrophy, suggesting that IGF-I alone is not the sole precondition for the hypertrophic phenotype (48).

Our results showed that IGF-I binding was specific with a single class of high affinity sites (Kd = 0.36 nM) in neonatal cardiac myocytes (Fig. 1) in agreement with an earlier work (14). Although there are no comparative studies between receptors for insulin and IGF-I in neonatal cardiac myocytes, our results show that there appear to be fewer insulin receptors than IGF-IRs (data not shown). A previous study showed that specific binding for insulin and IGF-I/100 mg of rat cardiac tissue heart reached 52 and 20%, respectively, with Kd values of 0.25 nM for insulin receptors and of 0.40 nM for IGF-IR for its own ligand (49), indicating that insulin receptors are more abundant in non-myocyte cell types.

It is well known that IGF-I stimulates tyrosine phosphorylation of several proteins in various cell types (23, 50, 51). We detected several tyrosine-phosphorylated proteins with apparent molecular mass of 42, 44, 95, 105, and 180 kDa, whose tyrosine phosphorylation in response to IGF-I increased rapidly (Fig. 2). By immunoblotting, these proteins were identified as p42 Erk2, p44 Erk1, IGF-IR beta -subunit, and IRS-1 (Figs. 2 and 7, and data not shown) (52, 53). The results also showed that the autophosphorylation of IGF-IR beta -subunit as well as phosphorylation of IRS-1, both on tyrosines, was IGF-I concentration dependent, although with a different sensitivity. IGF-IR beta -subunit autophosphorylation became evident with 5 nM IGF-I, whereas for IRS-1 phosphorylation was observed after 10 nM (Fig. 2A). The presence of two isoforms for IGF-IR beta -subunits with molecular masses of 95 and 105 kDa (Fig. 2B) was also detected in neonatal cardiac myocytes; similar isoforms have been reported earlier (23). Although it remains unknown whether if each subunit isoform may have a particular signal transduction system and if their expression changes during the myocyte development of cardiac myocytes, the higher and lower molecular masses may correspond to a fetal and adult forms, respectively (54, 55). Other hypertrophic stimuli (stretch, angiotensin II) also stimulate protein tyrosine phosphorylation in cardiac myocytes (56-58), and it has been hypothesized that cardiac hypertrophy might be associated with altered tyrosine phosphorylation of certain proteins (i.e. a 120-kDa cytosolic protein) in the heart (59). Although in cardiac myocytes there is no evidence of cross-talk between angiotensin II and IGF-I, this interaction has been demonstrated at multiple levels in vascular smooth muscle cells (60). Both angiotensin II and thrombin caused rapid tyrosine phosphorylation of the IGF-IR beta -subunit and of IRS-1 in this cellular type (61). IRS and Shc are considered the two major IGF-I signaling pathways. IRS-1 is an adapter protein phosphorylated on multiple tyrosine residues upon receptor stimulation, providing multiple sites of interactions for proteins with SH2 domains such as p85 PI 3-kinase, Nck, Grb-2, and PTP1P (23, 62). PLC-gamma 1 also contains SH2 domains that recognize and bind to the phosphorylated tyrosine residues of the receptor tyrosine kinases (63). In contrast with other RTKs, it is not well established whether PLC-gamma 1 associates with IGF-IR and becomes activated by tyrosine phosphorylation upon receptor stimulation. We demonstrated that IGF-I induces a rapid tyrosine phosphorylation of PLC-gamma 1 reaching 3.5-fold (Fig. 3). Although we have detected coprecipitation of a 185-kDa phosphorylated protein with PLC-gamma 1 which might correspond to IRS-1, our results suggest that both proteins are not associated after IGF-IR activation, and further studies will be required to identify the phosphorylated protein that coprecipitates with PLC-gamma . PI 3-kinase activation in IGF-I signal transduction may play a important role because this enzyme mediates the activation of other protein kinases such as protein kinase C, S6 kinase, and serine-threonine kinase Akt as well as the regulation of cytoskeletal function (63-65). Our results also show that its activation was IGF-I concentration-dependent and that it was activated by tyrosine phosphorylation. IGF-I also causes rapid translocation of two Shc isoforms (46 and 52 kDa) to the membrane fraction with a maximum increase in membrane (6-11-fold) after 30 s with 10 nM IGF-I.2 It has been shown that Shc, like IRS-1, associates with Grb-2, upon tyrosine phosphorylation, and subsequently activates the p21 Ras-ERK pathway via a Grb-2·SOS complex (23). Our results stress that IGF-I has multiple signal transduction pathways through different adapter proteins in cardiac myocytes.

We and others have previously proposed that activation of the p21 Ras-ERK pathway may be involved in the growth response of cardiac myocytes to hypertrophic agonists (66-69). In contrast, others have reported that ERK activation is not sufficient for G-protein receptor-mediated induction of cardiac cell growth and gene expression and is apparently not required for transcriptional activation of the atrial natriuretic factor gene (70).

Diverse hypertrophic agonists converge to produce cardiac hypertrophy following a sequential activation of Raf right-arrow MEK right-arrow ERK. The upstream event in the ERK cascade involves the activation of Raf kinases. We have presented evidence that exposure of cardiac myocytes to IGF-I rapidly activated c-Raf. A-Raf was activated much less than c-Raf in neonatal cardiac myocytes. This finding is similar to that reported previously for acidic fibroblast growth factor in cardiac myocytes but differs from that produced by TPA (36). The reason for this differential activation of Raf isoforms by IGF-I is unclear; and its functional effectors, in addition to Ras and Src, are yet need to be identified (71, 72). The differential activation of both Raf isoforms may also reflect different requirements for effectors or the interaction with other proteins like 14-3-3 proteins (73). We have also demonstrated that IGF-I activated two peaks of MEK (Fig. 6) which were capable of phosphorylating exogenously added recombinant GST-ERK2. Both peaks may correspond to the MEK1 and MEK2 isoforms activated by acidic fibroblast growth factor and endothelin-1 (30). The two isoforms of ERK (ERK1 and ERK2) were coordinately activated by IGF-I (Fig. 7). The maximum extent of phosphorylation of ERK2 elicited by IGF-I corresponded to 44% of the total ERK2 pool (results not shown). This response is similar to that seen with other hypertrophic agonists (endothelin-1, phenylephrine, acidic fibroblast growth factor) (33, 36-38). Nonhypertrophic agents such as bradykinin, carbachol, and ATP do, however, also activate ERK in cardiac myocytes (70, 74). In PC-12 cells the duration of the activation of ERK1 and ERK2 is critical in determining whether the cells differentiate (prolonged activation) or proliferate (transient activation) (75, 76). In neonatal cardiac myocytes in culture activation of ERKs induced by mechanical stretch and angiotensin II is accompanied by sustained activation of p90 RSK (37, 58). We have shown here that IGF-I causes activation of p90 RSK in cardiac myocytes. Last, we have shown that IGF-I stimulates [3H]phenylalanine incorporation into cardiac myocyte proteins without changes in the incorporation of [3H]thymidine into DNA in neonatal cardiac myocytes. This agrees with previous reports showing the hypertrophic action of IGF-I in vitro (14). Our preliminary results using different inhibitors of the IGF-I signal transduction pathway (i.e. PD 098059, an inhibitor of MEK) suggest that IGF-I-induced cardiac hypertrophy may be mediated by the ERK cascade.3

We concluded that IGF-I activates multiple signal transduction pathways that involve tyrosine phosphorylation of IRS-1, PI 3-kinase, and PLC-gamma 1 and the activation of the ERK cascade and p90 RSK in neonatal cardiac myocytes in culture. The use of both selective inhibitors of signal transduction pathways as well as the transient transfection of cardiac myocytes with dominant-negative forms and antisense oligodeoxynucleotide approach for the different components of signal transduction mechanism of IGF-I will allow us to establish their contribution to cardiac myocyte hypertrophy.


FOOTNOTES

*   This work was supported in part by Fondo Nacional de Ciencia y Tecnología Grants 1950452 (to S. L.) and 2950002 (to R. F.) and grants from the Wellcome Trust, British Heart Foundation, and the Biotechnology and Biological Sciences Research Council (to P. H. S).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.
§   Recipient of a Comisión Nacional de Ciencia y Tecnología fellowship (Chile).
par    Present address: Institute of Science and Technology for Research and Development, Mahidol University, Salaya, Nakornprathom, Thailand 73170.
Dagger Dagger    To whom correspondence should be addressed. Tel.: 562-678-2903; Fax: 562-737-8920; E-mail: slavande{at}ll.ciq.uchile.cl.
1   The abbreviations used are: IGF-I, insulin-like growth factor I; IGF-IR, IGF-I receptor; IRS-1, insulin receptor substrate 1; SH2, Src homology 2; PI 3-kinase, phosphatidylinositol 3-kinase; Grb-2, growth factor receptor-binding protein 2; PLC-gamma , phospholipase C-gamma ; Shc, Src homology/collagen; Raf, MEK-activating kinase; MEK, ERK-activating kinase; ERK, extracellular signal-regulated kinase; p90 RSK, p90 S6 kinase; TPA, 12-O-tetradecanoylphorbol-13-acetate; DMEM, Dulbecco's modified Eagle's medium; M199, medium 199; MBP, myelin basic protein; GST, glutathione S-transferase; PBS, phosphate-buffered saline; PMSF, phenylmethylsulfonyl fluoride; PAGE, polyacrylamide gel electrophoresis; DTT, dithiothreitol; FPLC, fast protein liquid chromatography; MOPS, 4-morpholinepropanesulfonic acid.
2   R. Foncea, M. Sapag-Hagar, D. LeRoith, and S. Lavandero, unpublished results.
3   R. Foncea, V. Pérez, M. Sapag-Hagar, D. LeRoith, and S. Lavandero, unpublished results.

ACKNOWLEDGEMENTS

We thank Professor C. I. Pogson for helpful discussion and a critical review of the manuscript.


REFERENCES

  1. Schneider, M. D., and Parker, T. G. (1990) Circulation 81, 1443-1456 [Medline] [Order article via Infotrieve]
  2. Shubeita, H. E., McDonough, P. M., Harris, A. N., Knowlton, K. U., Glembotski, C. C., Brown, J. H., and Chien, K. R. (1990) J. Biol. Chem. 265, 20555-20562 [Abstract/Free Full Text]
  3. Sugden, P. H., and Bogoyevitch, M. A. (1996) Trends Cardiovasc. Med. 6, 87-94 [CrossRef]
  4. Sadoshima, J., and Izumo, S. (1993) Cell 75, 977-984 [Medline] [Order article via Infotrieve]
  5. Komuro, I., and Yazaki, Y. (1993) Annu. Rev. Physiol. 55, 55-75 [CrossRef][Medline] [Order article via Infotrieve]
  6. Dzau, V. J. (1992) Am. J. Cardiol. 70, 4C-11C [Medline] [Order article via Infotrieve]
  7. Chien, K., Knowlton, K. U., Zhu, H., and Chien, S. (1991) FASEB J. 5, 3037-3046 [Abstract/Free Full Text]
  8. Parker, T. G., Packer, S. E., and Schneider, M. D. (1990) J. Clin. Invest. 85, 507-514 [Medline] [Order article via Infotrieve]
  9. D'Ercole, A. J., Stiles, A. D., and Underwood, L. E. (1984) Proc. Natl. Acad. Sci. U. S. A. 81, 935-939 [Abstract]
  10. Froesch, E., Schmid, C., Schwander, J., and Zapf, J. (1985) Annu. Rev. Physiol. 47, 443-467 [CrossRef][Medline] [Order article via Infotrieve]
  11. LeRoith, D., and Roberts, C. T. (1993) Ann. N. Y. Acad. Sci. 692, 1-9
  12. Duerr, R., McKirman, M. D., Gira, R. D., Clark, R., Chien, K., and Ross, J. (1996) Circulation 93, 2188-2196 [Abstract/Free Full Text]
  13. Engelmann, G. L., Boehm, K. D., Haskell, J. F., Khairallah, P. A., and Ilan, J. (1989) Mol. Cell. Endocrinol. 63, 1-14 [CrossRef][Medline] [Order article via Infotrieve]
  14. Ito, H., Hiroe, M., Hirata, Y., Tsujino, M., Adashi, S., Shichiri, M., Koyke, A., Nogami, A., and Marumo, F. (1993) Circulation 87, 1715-1721 [Abstract]
  15. Duerr, R., Huang, S., Miraliakbar, H., Clark, R., Chien, K., and Ross, J. (1995) J. Clin. Invest. 95, 619-627 [Medline] [Order article via Infotrieve]
  16. Cittadini, A., Strömer, H., Hatz, S. E., Clark, R., Moses, A. C., Morgan, J. P., and Douglas, P. S. (1996) Circulation 93, 800-809 [Abstract/Free Full Text]
  17. Fazzio, S., Sabatini, D., Capaldo, B., Vigorito, C., Giordano, A., Guida, R., Pardo, F., Biondi, B., and Sacca, L. (1996) N. Engl. J. Med. 334, 809-814 [Abstract/Free Full Text]
  18. Sacca, L., and Fazzio, S. (1996) Nature Med. 2, 29-31 [Medline] [Order article via Infotrieve]
  19. Klein, I., and Ojamaa, K. (1992) J. Clin. Endocrinol. Metab. 75, 339-344 [Medline] [Order article via Infotrieve]
  20. Laviades, C., Mayor, G., and Díez, J (1991) Arch. Mal. Coeur Vaiss. 84, 1039-1041 [Medline] [Order article via Infotrieve]
  21. Donohue, T. J., Dowrkin, L. D., Lango, M. N., Fliegner, K., Lango, R. P., Benstein, J. A., Slater, W. R., and Catanese, V. M. (1994) Circulation 89, 799-804 [Abstract]
  22. Reiss, K., Cheng, W., Ferber, A., Kajstura, J., Li, P., Li, B., Olivetti, G., Homcy, C. J., Baserga, R., and Anversa, P. (1996) Proc. Natl. Acad. Sci. U. S. A. 93, 8630-8635 [Abstract/Free Full Text]
  23. LeRoith, D., Werner, H., Beitner-Johnson, D., and Roberts, C. T. (1995) Endocr. Rev. 16, 143-163 [Medline] [Order article via Infotrieve]
  24. Kato, H., Faria, T. N., Stannard, B., Roberts, C. T., and LeRoith, D. (1993) J. Biol. Chem. 268, 2655-2661 [Abstract/Free Full Text]
  25. Kato, H., Faria, T. N., Stannard, B., Roberts, C. T., and LeRoith, D. (1994) Mol. Endocrinol. 8, 40-50 [Abstract]
  26. Myers, M. G., Backer, J. M., Sun, X.-J., Shoelson, S. E., Hu, P., Schlessinger, J., Yoakin, M., Schaffhausen, B., and White, M. F. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 10350-10354 [Abstract]
  27. Myers, M. G., Sun, X.-J., Cheatham, B., Jachna, B. R., Glasheen, E. M., Backer, J. M., and White, M. F. (1993) Endocrinology 132, 1421-1430 [Abstract]
  28. Tartare-Deckert, S., Sawka-Verhelle, D., Murdaca, J., and Van Obberghen, E. (1995) J. Biol. Chem. 270, 23456-23460 [Abstract/Free Full Text]
  29. Boguski, M. S., and McConick, F. (1993) Nature 366, 643-653 [CrossRef][Medline] [Order article via Infotrieve]
  30. Bogoyevitch, M. A., Glennon, P. E., Andersson, M. B., Clerk, A., Lazou, A., Marshall, C. J., Parker, P. J., and Sugden, P. H. (1994) J. Biol. Chem. 269, 1110-1119 [Abstract/Free Full Text]
  31. Blakesley, V. A., Kalebic, T., Helman, L. J., Stannard, B., Faria, T. N., Roberts, C. T., and LeRoith, D. (1996) Endocrinology 137, 410-417 [Abstract]
  32. Párrizas, M., Gazit, A., Levitzki, A., Wertheirmer, E., and LeRoith, D. (1997) Endocrinology 138, 1427-1433 [Abstract/Free Full Text]
  33. Clerk, A., Bogoyevitch, M. A., Andersson, M. B., and Sugden, P. H. (1994) J. Biol. Chem. 269, 32848-32857 [Abstract/Free Full Text]
  34. Bradford, M. M. (1976) Anal. Biochem. 72, 248-254 [CrossRef][Medline] [Order article via Infotrieve]
  35. Hernandez-Sanchez, C., Blakesley, V., Kalebic, T., Helman, L., and LeRoith, D. (1995) J. Biol. Chem. 270, 29176-29181 [Abstract/Free Full Text]
  36. Bogoyevitch, M. A., Marshall, C. J., and Sugden, P. H. (1995) J. Biol. Chem. 270, 26303-26310 [Abstract/Free Full Text]
  37. Bogoyevitch, M. A., Glennon, P. E., and Sugden, P. H. (1993) FEBS Lett. 317, 271-275 [CrossRef][Medline] [Order article via Infotrieve]
  38. Lazou, A., Bogoyevitch, M. A., Clerk, A., Fuller, S. J., Marshall, C. J., and Sugden, P. H. (1994) Circ. Res. 75, 932-941 [Abstract]
  39. Yamazaki, T., Tobe, K., Hoh, E., Maemura, K., Kaida, T., Komuro, I., Tanemoto, H., Kadowaki, T., Nagai, R., and Yazaki, Y. (1993) J. Biol. Chem. 268, 12069-12076 [Abstract/Free Full Text]
  40. Scatchard, G. (1949) Ann. N. Y. Acad. Sci. 51, 660-672
  41. Ballard, F. J., Francis, G. L., Ross, L., Bagley, C. J., May, B., and Wallace, J. C. (1987) Biochem. Biophys. Res. Commun. 149, 398-404 [Medline] [Order article via Infotrieve]
  42. Shemer, J., Adamo, M., Wilson, G. L., Heffez, D., Zick, Y., and LeRoith, D. (1987) J. Biol. Chem. 262, 15476-15482 [Abstract/Free Full Text]
  43. Brunet, A., Pages, G., and Pouysségur, J. (1994) FEBS Lett. 346, 299-303 [CrossRef][Medline] [Order article via Infotrieve]
  44. Seger, R., and Krebs, E. G. (1995) FASEB J. 9, 726-735 [Abstract/Free Full Text]
  45. Wählander, H., Isgaard, J., Jennische, E., and Friberg, P. (1992) Hypertension 19, 25-32 [Abstract]
  46. Hanson, M. C., Fath, K. A., Alexander, R. W., and Delafontaine, P. (1993) Am. J. Med. Sci. 306, 69-74 [Medline] [Order article via Infotrieve]
  47. Mathews, L. S., Hammer, R. E., Behringer, R. R., D'Ercole, A. J., Bell, G. I., Brinster, R. L., and Palmiter, R. D. (1988) Endocrinology 123, 2827-2833 [Abstract]
  48. Mao, L., Pusl, L., Hunter, J. J., Powell-Braxton, L., and Chien, K. R. (1995) Circulation 92, 239-330
  49. Gutierrez, J., Pazirras, M., Maestro, M. A., Navarro, I., and Plisetskaya, E. M. (1995) J. Endocrinol. 146, 35-44 [Abstract]
  50. Ullrich, A., and Schlessinger, J. (1990) Cell 61, 203-212 [Medline] [Order article via Infotrieve]
  51. Fantl, W. J., Johnson, D. E., and Williams, L. T. (1993) Annu. Rev. Biochem. 62, 453-481 [CrossRef][Medline] [Order article via Infotrieve]
  52. Adamo, M., Roberts, C. T., and LeRoith, D. (1992) Biofactors 3, 151-157 [Medline] [Order article via Infotrieve]
  53. Margolis, G., Rhee, S. G., Felder, S., Mervic, M., Lyall, R., Levitzki, A., Ullrich, A., Zilberstein, A., and Schlessinger, J. (1989) Cell 57, 1101-1107 [Medline] [Order article via Infotrieve]
  54. Alexandrides, T. K., Chen, J. H., Bueno, R., Giorgino, F., and Smith, R. J. (1993) Regul. Pept. 48, 279-290 [CrossRef][Medline] [Order article via Infotrieve]
  55. Alexandrides, T. K., and Smith, R. J. (1989) J. Biol. Chem. 264, 12922-12930 [Abstract/Free Full Text]
  56. Sadoshima, J., and Izumo, S. (1996) EMBO J. 15, 775-787 [Abstract]
  57. Sadoshima, J., Qiu, Z., Morgan, J. P., and Izumo, S. (1995) Circ. Res. 76, 1-15 [Abstract/Free Full Text]
  58. Sadoshima, J., and Izumo, S. (1993) EMBO J. 12, 1681-1692 [Abstract]
  59. Rabkin, S. W., Damen, J. E., Goutsouliak, V., and Krystal, G. (1996) Am. J. Hypertens. 9, 230-236 [CrossRef][Medline] [Order article via Infotrieve]
  60. Delafontaine, P., Brink, M., and Du, J. (1996) Trends Cardiovasc. Med. 6, 187-193 [CrossRef]
  61. Du, J., Sperling, L. S., Marrero, M. B., Phillips, L., and Delafontaine, P. (1996) Biochem. Biophys. Res. Commun. 218, 934-939 [CrossRef][Medline] [Order article via Infotrieve]
  62. Waters, S. B., and Pessin, J. E. (1996) Trends Cell Biol. 6, 1-4 [CrossRef]
  63. Malarkey, K., Belham, C. M., Paul, A., McLess, A., Scott, P. H., and Plevin, R. (1995) Biochem. J. 309, 361-375 [Medline] [Order article via Infotrieve]
  64. Franke, T. F., Kaplan, D. R., Cantley, L. C., and Toker, A. (1997) Science 275, 665-668 [Abstract/Free Full Text]
  65. Franke, T. F., Yang, S., Chan, T. O., Datta, K., Kazlauskas, A., Morrison, D. K., Kaplan, D. R., and Tsichlis, P. N. (1995) Cell 81, 727-736 [Medline] [Order article via Infotrieve]
  66. Gillespie-Brown, J., Fuller, S. J., Bogoyevitch, M. A., Cowley, S., and Sugden, P. H. (1995) J. Biol. Chem. 270, 28092-28096 [Abstract/Free Full Text]
  67. Thorburn, A., Thorburn, J., Chen, S.-Y., Powers, S., Shubeita, H. E., Feramisco, J. R., and Chien, K. R. (1993) J. Biol. Chem. 268, 2244-2249 [Abstract/Free Full Text]
  68. Thorburn, A. (1994) Biochem. Biophys. Res. Commun. 205, 1417-1422 [CrossRef][Medline] [Order article via Infotrieve]
  69. Thorburn, J., Frost, J. A., and Thorburn, A. (1994) J. Cell Biol. 126, 1565-1572 [Abstract]
  70. Post, G. R., Golstein, D., Thuerau, D. J., Glembotski, C. C., and Brown, J. H. (1996) J. Biol. Chem. 271, 8452-8457 [Abstract/Free Full Text]
  71. Leevers, S. J., Paterson, H. F., and Marshall, C. J. (1994) Nature 369, 411-414 [CrossRef][Medline] [Order article via Infotrieve]
  72. Stokoe, D., MacDonald, S. G., Cadwallader, K., Symons, N., and Hancock, J. F. (1994) Science 264, 1463-1467 [Medline] [Order article via Infotrieve]
  73. Morrison, D. (1994) Science 266, 56-57 [Medline] [Order article via Infotrieve]
  74. Clerk, A., Gillespie-Brown, J., Fuller, S. J., and Sugden, P. H. (1996) Biochem. J. 317, 109-118 [Medline] [Order article via Infotrieve]
  75. Marshall, C. J. (1995) Cell 80, 179-185 [Medline] [Order article via Infotrieve]
  76. Traverse, S., Gómez, N., Paterson, H., Marshall, C. J., and Cohen, P. (1992) Biochem J. 288, 351-355 [Medline] [Order article via Infotrieve]

©1997 by The American Society for Biochemistry and Molecular Biology, Inc.