(Received for publication, April 9, 1996, and in revised form, August 26, 1996)
From the Section on Molecular and Cellular Physiology, Diabetes Branch, NIDDK, National Institutes of Health, Bethesda, Maryland 20892-1770 and the § Department of Pediatrics, University of California, San Francisco, California 94143
Insulin-like growth factor-I receptor (IGF-IR)
gene expression is regulated by various stimuli, including hormones,
growth factors, and nutritional status. We have investigated the
molecular mechanism by which two growth factors, insulin-like growth
factor-I (IGF-I) and basic fibroblast growth factor (bFGF) regulate
IGF-IR gene expression. bFGF increases the endogenous IGF-IR mRNA
levels and IGF-IR promoter activity. This effect is mediated by a
region of the IGF-IR promoter located between nucleotides 476 and
188 in the 5
-flanking region. In contrast, IGF-I decreases the
IGF-IR mRNA levels. IGF-I down-regulates IGF-IR transcriptional
activity as deduced from experiments in which the levels of
pre-mRNA and mRNA were measured. IGF-I reduced pre-mRNA and
mRNA levels in parallel, while the mRNA stability was found to
be unchanged by IGF-I treatment. While these results strongly suggest
an effect of IGF-I on IGF-IR transcriptional activity, no specific
IGF-I response element was demonstrated in the 5
-untranslated region or 5
-flanking region studied. Thus, bFGF and IGF-I have differential effects on IGF-IR gene transcription, with the IGF-I response region as
yet unidentified.
The insulin-like growth factors (IGFs)1 and the IGF-I receptor (IGF-IR) are important modulators of cell growth and differentiation in many tissues (1). IGF-IR gene expression is highly regulated under many physiological and pathological conditions (for review, see Ref. 2). For instance, IGF-IR mRNA levels and IGF-I binding are tightly regulated by the nutritional status of the animal. In vivo, fasting was shown to increase IGF-I-specific binding in several tissues, and these changes in IGF-I binding were accompanied by a ~2-fold increase in IGF-IR mRNA abundance (3). Since, in some of the tissues, the local levels of IGF-I are decreased after a reduction in caloric intake, it is possible that the increases in IGF-IR expression are secondary to the decrease in local tissue IGF-I concentrations (4). In contrast, some growth disorders such as Laron-type dwarfism are associated with long term reductions of circulating levels of IGF-I. In these disorders the expression of the IGF-IR gene in mononuclear cells is enhanced severalfold, suggesting an effect of circulating IGF-I (5). Drug-induced diabetes in rats is an additional animal model in which the regulation of the IGF-IR gene has been studied. Streptozotocin-treated rats show a reduction in circulating IGF-I levels and increased expression of the IGF-IR in the kidney. Both circulating IGF-I levels and IGF-IR expression returned to control values following insulin treatment (6). Similarly, the levels of IGF-IR in cultured cells are affected by the concentration of IGF-I in the medium. For instance, in cultured IM-9 lymphoid, FRTL-5 thyroid, and endothelial cells, IGF-IR expression is regulated by the concentration of IGF-I in the culture medium (7, 8), with increased IGF-I levels causing a decrease in receptor number. Under certain circumstances this down-regulation involves a translocation of cell-surface receptors to an intracellular pool (9), whereas in other cell types the effect is due to decreased IGF-IR gene expression (10).
A possible mechanism by which competence factors like bFGF and platelet-derived growth factor (PDGF) stimulate entry of cells into the G1 phase of the cell cycle (11, 12) is their ability to increase the expression of the IGF-IR, thus enhancing the progression factor activity of the IGF-I ligand. For instance, bFGF increases IGF-I binding and IGF-IR mRNA levels in the BC3H-1 muscle cell line (13), and this change is associated with a decrease in IGF-II expression in these cells. Similarly, PDGF increases IGF-IR gene expression and ligand binding in cells in culture (14), and this effect is due, at least in part, to PDGF stimulation of IGF-IR gene transcriptional activity. This transcriptional effect is mediated by a ~100-base pair (bp) region located immediately upstream of the transcription start site (15).
In the present report, we studied the molecular mechanisms involved in
the regulation of IGF-IR gene expression by bFGF and IGF-I. We found
that bFGF and IGF-I regulate transcriptional activity of the IGF-IR
gene positively and negatively, respectively. The region responsible
for the response to bFGF is located in the proximal 476 bp of the
5-flanking region, whereas the region responsible for the response to
IGF-I is apparently located outside of the
2350-bp to +640-bp region
of the IGF-IR gene promoter.
Cell culture media and reagents were purchased
from Biofluids, Inc. (Rockville, MD) and Advanced Biotechnologies
(Columbia, MD). Insulin-free bovine serum albumin (fraction V) was
obtained from Armour (Kankakee, IL). Human recombinant IGF-I was a kind gift from Genentech (San Francisco, CA). Recombinant human bFGF, Lipofectin and LipofectAMINE reagents were purchased from Life Technologies, Inc. 5,6-Dichlorobenzimidazole riboside (DRB) was purchased from Sigma. The ECL detection kit and horseradish
peroxidase-conjugated anti-rabbit immunoglobulin were purchased from
Amersham Life Science, Inc. The polyclonal anti-IGF-I receptor
-subunit antibody (C-20) was purchased from Santa Cruz
Biotechnology, Inc (Santa Cruz, CA), and the polyclonal antibody
directed toward the carboxyl terminus of the insulin receptor
substrate-1 (IRS-1) was purchased from Upstate Biotechnology Inc. (Lake
Placid, NY).
C2C12 (mouse muscle) and SH-SY5Y (human neuroblastoma) cells were grown in Dulbecco's modified Eagle's medium supplemented with 100 units/ml penicillin, 100 µg/ml streptomycin, 2.5 µg/ml Fungizone, 2 mM glutamine, and 20 or 10% fetal bovine serum, respectively. Cells were serum-starved overnight prior to growth factor stimulation. Serum-free Dulbecco's modified Eagle's medium containing 0.1% bovine serum albumin, 20 mM Hepes, pH 7.5, and antibiotics was used during serum starvation and growth factor stimulation. Cells were incubated at 37 °C, 5% CO2, and 90% relative humidity.
Plasmids and TransfectionsGenomic DNA fragments extending
from nucleotides 2350 to +640 (nucleotide 1 corresponds to the
transcription start site of the IGF-IR gene),
476 to +640,
455 to
+30, and
188 to +640 were subcloned upstream of a promoterless
firefly luciferase (pOLUC) reporter gene. As a control the expression
plasmid (pSV2LUC) containing the SV40 enhancer/promoter was used. The
reporter plasmids were used for transient transfections. The basal
promoter activity of these fragments has been previously described
(16).
C2C12 cells were transfected using the LipofectAMINE reagent. Cells
were cultured in 6-well plates, and each well received 3 µg of
reporter plasmid and 3 µg of a -galactosidase expression vector
(pCMV
; Clontech, Palo Alto, CA). Eighteen hours after transfection,
the DNA-containing medium was changed to serum-containing medium for
approximately 30 h. Cells were then serum-starved overnight and
incubated with the indicated concentrations of bFGF for various times.
Cells were then lysed and luciferase and
-galactosidase activity
measured as described previously (16).
SH-SY5Y cells were transfected using the Lipofectin reagent. Cells in each 60-mm dish received 10 µg of reporter plasmid (in experiments in which luciferase mRNA was measured) or 10 µg of reporter plasmid plus 10 µg of pGEM-7Z (Promega, Madison, WI) (in experiments in which luciferase activity was measured). Eighteen hours after transfection, the DNA-containing medium was changed to serum-containing medium for approximately 30 h. Cells were then serum-starved overnight and incubated with the indicated concentrations of IGF-I and for various times. Cells were harvested either for luciferase activity measurements or for RNA extraction. Protein content was determined using the Bio-Rad reagent according to manufacturer's directions.
Western Blot AnalysisC2C12 cells were serum-starved
overnight and then incubated with 1 nM bFGF for 24 h.
Cells were lysed in the presence of 50 nM Hepes, pH 7.9, 100 mM NaCl, 10 mM EDTA, 1% Triton X-100, 4 mM sodium pyrophosphate, 2 mM sodium
orthovanadate, 1 mM phenylmethylsulfonyl fluoride, 10 mM sodium fluoride, 2 µg/ml leupeptin, and 2 µg/ml aprotinin. Cell lysates were clarify by centrifugation. Protein content
was determined by the method of Bradford using a protein assay kit
(Bio-Rad). Eighty micrograms of protein were reduced by
-mercaptoethanol and fractionated by 7.5% SDS-polyacrylamide gel
electrophoresis. Resolved proteins were electrophoretically transferred
to nitrocellulose membrane (Schleicher & Schuell). The upper part of
the membrane was incubated with anti-IRS-1 antibody (1 µg/ml) while
the bottom part was incubated with anti-IGF-I receptor
-subunit
antibody (1:1000 dilution) and detected with horseradish
peroxidase-conjugated anti-rabbit immunoglobulin (1:2500 dilution)
using the ECL system. The IGF-IR
-subunit and IRS-1 bands were
quantitated by digitalizing the signal from the x-ray film and
analyzing the signal using NIH image version 1.55 software.
C2C12 and SH-SY5Y cells were lysed in 4 M guanidinium isothiocyanate containing 0.01%
-mercaptoethanol, and RNA was isolated by ultracentrifugation
through a cesium chloride gradient as described previously (17). Total
RNA (20 µg) from C2C12 cells was hybridized with a
32P-labeled mouse antisense IGF-IR RNA probe (2 × 105 dpm). The mouse antisense RNA probe was generated by
transcription of a mouse genomic IGF-IR 417-bp
EcoRI-BamHI fragment, subcloned into a
pBluescript SK+ vector (construct provided by A. Efstratiadis, Columbia
University, New York). Total RNA (10-15 µg) from SH-SY5Y cells was
hybridized with a 32P-labeled human antisense IGF-IR RNA
probe (2 × 105 dpm). The human antisense RNA probe
was generated by transcription of a 379-bp
EcoRI-XhoI fragment of the human IGF-IR cDNA
(18) subcloned into pGEM-3 (19).
To measure the IGF-IR pre-mRNA levels, a fragment of 225 bp, corresponding to 201 bp of exon 2 and 24 bp of intron 2 of the human IGF-IR gene, was generated by the polymerase chain reaction (Perkin-Elmer) and subcloned into a TA cloning vector (Invitrogen, San Diego, CA). The identity and orientation of the construct was verified by sequence analysis. After linearization of this construct with HindIII, a 32P-labeled exon 2-intron 2 antisense RNA probe was generated with T7 RNA polymerase and hybridized with total RNA (50 µg). In all cases, normalization to total RNA was performed by co-hybridizing with an 18 S ribosomal RNA probe (Ambion, Austin, TX). RNase protection assays were carried out as described previously (20). Likewise, an antisense RNA probe corresponding to 551 bp of exon 1 and 90 bp of intron 1 of the human IGF-IR was generated.
Solution Hybridization-RNase Protection Assay of Luciferase mRNALuciferase mRNA was measured by hybridizing 25 µg of total RNA from transfected SH-SY5Y cells with 32P-labeled luciferase antisense RNA probe (2 × 105 dpm). The luciferae antisense probe was generated by linearization of the pGEM-luc DNA vector (Promega) with EcoRV and transcription with T7 RNA polymerase. Hybridization of this 413-bp probe with luciferase RNA results in a protected band of ~365-bp. Normalization with an 18 S ribosomal RNA probe was performed as indicated above.
mRNA StabilitySH-SY5Y cells were serum-starved overnight and then stimulated with 13 nM IGF-I for 6 or 8 h; DRB (final concentration 100 µM) was then added to the culture medium, and incubation was continued for various times. Total RNA was isolated as described above, and the levels of IGF-IR mRNA were measured by solution hybridization/RNase protection assays.
To measure the effect of bFGF on IGF-IR gene expression,
C2C12 cells were serum-starved overnight and then stimulated with 1 nM bFGF for various time periods. Total RNA was isolated,
and the levels of IGF-IR mRNA were measured by solution
hybridization-RNase protection assays as described under
"Experimental Procedures." bFGF increased endogenous IGF-IR
mRNA levels by about 40-50% at 4 h of incubation, with the
maximum effect (~90%) at 16 h (Fig. 1A). A similar (~90%) increase in IGF-IR
mRNA level was seen in SH-SY5Y cells using 1 nM bFGF
for 16 h (Fig. 1B).
Effect of bFGF on IGF-I Receptor Levels
To assess the
relevance of the increase in IGF-IR mRNA levels by bFGF we studied
the bFGF effect on IGF-IR protein. Following overnight serum starvation
C2C12 cells were incubated in the presence of 1 nM bFGF for
24 h. Cell lysates were assayed for IGF-I receptor and IRS-1
protein levels. bFGF specifically caused a 70% increase in the levels
of the IGF-I receptor. Whereas another protein involved in the IGF-I
receptor signaling pathway, namely IRS-1, demonstrated no change (Fig.
2).
Effect of bFGF on IGF-IR Promoter Activity
One mechanism that
may have been responsible for bFGF-induced increase in IGF-IR mRNA
levels was bFGF activation of the IGF-IR gene promoter. To study this
possibility C2C12 cells were transiently transfected with a luciferase
reporter gene under the control of the proximal promoter region of the
IGF-IR gene (476 bp of the 5-flanking region and 640 bp of the
5
-untranslated region (UTR)) (p(
476/+640)LUC) together with a
-galactosidase expression vector (pCMV
). bFGF increased IGF-IR
promoter activity by ~90%, with the maximum effect at 16 h
(Fig. 3A) and at a concentration of 1 nM (Fig. 3B). No effect of bFGF was seen when
the promoterless pOLUC or the unrelated promoter pSV2LUC were used
(data not shown).
Localization of the bFGF Response Region
To localize the
region of the IGF-IR gene promoter responsible for mediating the effect
of bFGF on IGF-IR gene expression, C2C12 cells were transiently
transfected with different fragments of the IGF-IR promoter cloned
upstream of a luciferase reporter gene. After overnight serum
starvation, cells were stimulated with 1 nM bFGF for
18 h. As seen in Fig. 4 the stimulatory effect of
bFGF was lost when the sequence between nucleotides 476 and
188 of
the 5
-flanking region was deleted (compare construct
476/+640 with
188/+640). Removal of the 5
-UTR (compare construct
476/+640 with
455/+30) did not affect bFGF stimulation of transcriptional activity.
These result suggest that the major bFGF-responsive element is located
between nucleotides
476 and
188 of the 5
-flanking region.
Effect of IGF-I on the Steady-state Levels of IGF-IR mRNA
To characterize the IGF-I effect on the IGF-IR mRNA
levels, time course and dose-response experiments were performed in
SH-SY5Y cells. After serum starvation, cells were stimulated with the indicated doses of IGF-I for various periods of time (Fig.
5, B and C). IGF-I decreased
IGF-IR mRNA levels by ~40-50%, with the maximum effect seen at
8 h and at a concentration of 0.1 nM. IGF-I receptor
mRNA down-regulation by IGF-I was similarly seen using C2C12 cells
(Fig. 5A).
Effect of IGF-I on IGF-IR Gene Transcription and on mRNA Stability
To determine whether IGF-I treatment affected
transcriptional activity, we studied the effect of IGF-I on IGF-IR
pre-mRNA levels and on IGF-IR mRNA turnover. An RNA probe
complementary to the exon 2:intron 2 boundary was generated as
described under "Experimental Procedures." This probe allows the
simultaneous measurement of pre-mRNA and processed IGF-IR mRNA.
As shown in Fig. 6, IGF-I down-regulates both IGF-IR
pre-mRNA and mature mRNA levels. The decrease relative to
controls of pre-mRNA and mature mRNA was similar (~45%).
Furthermore, similar results were obtained using an RNA probe
complementary to the exon 1:intron 1 boundary (data not shown).
To study the effect of IGF-I on IGF-IR mRNA stability, cells were
stimulated with IGF-I for 6 or 8 h, and DRB (a specific RNA
polymerase II inhibitor) was then added to the medium for various
periods of time. As shown in Fig. 7 the decay curves for both control and IGF-I-treated cells were similar, thus suggesting that
IGF-I does not significantly affect the turnover rate of the IGF-IR
mRNA. Taken together, these data support the hypothesis that IGF-I
decreases IGF-IR mRNA levels by affecting IGF-IR gene transcription.
Effect of IGF-I on IGF-IR Promoter Activity
To determine the
region of the IGF-IR promoter responsible for mediating this effect of
IGF-I, we transiently transfected SH-SY5Y with different fragments of
the IGF-IR promoter cloned upstream of a luciferase reporter gene.
Surprisingly, IGF-I treatment did not decrease luciferase enzyme
activity (Fig. 8A). To verify the lack of
IGF-I effect on IGF-IR promoter activity, luciferase mRNA levels
were measured. Similarly, IGF-I did not significantly affect luciferase
mRNA levels (Fig. 8B), while in the same experiments we
were able to demonstrate that IGF-I reduced endogenous IGF-IR mRNA
levels (Fig. 8C). This discrepancy between the lack of
regulation of the activity of transfected promoter fragments and the
reduction in endogenous gene expression is not cell type specific,
since similar results were obtained using C2C12 and G401 cells (data not shown). These results suggest that the regulatory element responsible for the IGF-I effect is apparently not present in the
region extending from nucleotide 2350 in the 5
-flanking region to
nucleotide +640 in the 5
-UTR.
The biological actions of the IGFs are mediated through interaction with their specific cell-surface receptor. The IGF-IR is expressed in most body tissues and the levels of IGF-IR mRNA are modulated in a number of physiological and pathological states, including changes in the levels of various circulating and locally acting growth factors. In this study we characterized the molecular mechanisms by which bFGF and IGF-I regulate IGF-IR mRNA levels. While bFGF increases IGF-IR gene promoter activity by 2-fold, IGF-I decreases transcriptional activity by ~50%.
The stimulation of IGF-IR gene promoter activity by bFGF in
transfection experiments correlates with its effect on the expression of the endogenous IGF-IR gene, as measured by mRNA and protein levels; i.e. all three parameters increased approximately
2-fold. By deletional analysis of the IGF-IR promoter region, we
determined that the bFGF-responsive region is localized in the proximal
promoter, between nucleotides 476 and
188 upstream of the
transcription start site. Although within the skeletal
-actin gene
promoter there is a unique serum response element (SRE1) necessary for induction of promoter activity by bFGF (21), no such consensus sequence
was found in the IGF-IR gene proximal promoter. bFGF has also been
shown to stimulate proenkephalin gene expression by synergizing with
cAMP through a cAMP response element (22). We did not find any cAMP
response element in the IGF-IR proximal promoter region; however, there
are a number of AP2 sites, which in the absence of a cAMP response
element may mediate the stimulatory effect of cAMP (23). Further
experiments will be required to address whether these AP2 sites are
relevant to the stimulatory effect of bFGF on IGF-IR promoter. In
addition, there are a number of SP1 sites. However, the significance of
these sites to bFGF action has not been previously described.
bFGF and PDGF are competence factors that stimulate entry of cells into the cell cycle (11, 12). Both growth factors increase IGF-IR gene expression. It has been shown that PDGF stimulates IGF-IR promoter transcriptional activity (15). Likewise, we show in the present study that bFGF stimulates IGF-IR gene expression by activating promoter activity. This stimulatory effect on IGF-IR promoter activity correlates with the IGF-IR transcriptional activation by bFGF recently shown in aortic smooth muscle cells (24).
Both bFGF and PDGF synergize with IGF-I in their biological actions (25, 26). The results of the present study suggest that one mechanism may be the increased expression of the IGF-I receptor by these growth factors. Other investigators have demonstrated that increased expression of the IGF-I receptor enhances cellular responses (27), whereas decreased levels by as little as 50% using antisense technologies decreases responsiveness to IGF-I (28).
bFGF also regulates the expression and secretion of various IGF binding proteins (IGFBPs). For instance, in the newborn rat olfactory bulb, bFGF enhanced IGFBP-2 and IGFBP-4 mRNA levels, whereas IGFBP-5 mRNA was not affected (29). In addition, IGFBP secretion by rat neuronal and glial cells in culture was differentially affected by the presence of bFGF in the culture medium (30). Since IGFBPs modulate both positively and negatively the actions of IGF-I (31-33), the effect of bFGF on the expression of the IGFBPs represent another level of regulation of IGF-I action.
IGF-I is a progression factor that is required by cells to progress through the cell cycle. In this study we have shown that IGF-I down-regulates endogenous IGF-IR mRNA levels in a neuroblastoma cell line and a muscle cell line. Similar results were described previously in a separate muscle cell line (10). The direct demonstration that IGF-I down-regulates IGF-IR gene expression supports the hypothesis that both circulating and locally produced IGF-I are responsible for the regulation of IGF-IR mRNA levels under several physiological and pathological situations in animal models as well as in humans. Futher support of the hypothesis that IGF-I represses expression of the IGF-IR gene "in vivo," comes from developmental studies in which we showed that increasing postnatal levels of IGF-I are correlated with decreased levels of IGF-IR mRNA in developing rats (20).
Results of experiments in which we measured IGF-IR pre-mRNA levels and mRNA stability suggest that down-regulation of IGF-IR mRNA levels by IGF-I is due to a decrease in transcription activity rate with no change in mRNA stability. Thus, IGF-I decreases pre-mRNA and mature mRNA levels to a similar extent as measured with two different exon:intron boundary probes, whereas, on the other hand IGF-I does not affect the IGF-IR mRNA turnover.
We were unable to demonstrate regulation of the IGF-IR promoter by
IGF-I using fragments of the promoter extending from nucleotide 2350
in the 5
-flanking region to nucleotide +640 in the 5
-UTR. The
promoter activity of this region has been previously characterized and
several cis-acting regulatory elements have been described, including
EGR/WT1 binding sites (34), Sp1 binding sites (35), a PDGF response
region (15) and a potential FGF response region (this study). In
addition, the IGF-IR promoter contains a sequence between nucleotides
583 and
555, which is similar to a putative IGF-I response element
described in the elastin gene that mediates activation of the elastin
promoter by IGF-I (36). However, our present data would suggest that
the putative IGF-I response element probably lies entirely outside this
region (
2350/+640) or, alternatively, that it is within this region
but requires other cis- or trans-activating elements for this effect. A
similar discrepancy between transcriptional and promoter activity
regulation has been seen in the transcriptional activation of the
I
B
gene by glucocorticoids (37, 38). Thus, while increasing
transcription from the I
B
gene as measured by run-on
transcription assay, dexamethasone had no effect on I
B
gene
promoter activity. Based on our results we cannot totally exclude the
possibility that the luciferase reporter vector used in this study was
the inappropriate vector, albeit similar results were obtained with two
different luciferase reporter vectors (pOLUC and pGL2) (data not
shown).
In summary we have characterized the regulation of IGF-IR gene expression by two growth factors that exhibit opposite effects on the transcriptional activity of the IGF-IR gene. bFGF increases IGF-IR promoter activity by acting in the proximal promoter region whereas IGF-I down-regulates transcriptional activity through a different mechanism that may involve other as yet uncharacterized, regions of the IGF-IR gene.
We thank Dr. Alan Shuldiner, Johns Hopkins University, for primers to generate the human exon 2:intron 2 RNA probe, and Guck Ooi and Vicky Blakesley for critical review of the manuscript.