(Received for publication, September 27, 1996, and in revised form, January 15, 1997)
From the Third Department of Internal Medicine, Faculty of Medicine, University of Tokyo, 7-3-1 Hongo, Bunkyo-ku, Tokyo 113, Japan
Many growth factors including epidermal growth factor (EGF) induce tyrosine phosphorylation of the c-Cbl proto-oncogene product, whose function, however, remains unclear. Recently, Sli-1, a Caenorhabditis elegans homologue of c-Cbl, was found to be a negative regulator of let-23-mediated vulval induction pathway, suggesting that c-Cbl may negatively regulate EGF receptor (EGFR)-mediated signaling. In this study, by an antisense RNA approach, we examined the effects of expression level of c-Cbl on EGFR signaling and showed that overexpression of c-Cbl reduces and antisense repression of c-Cbl enhances autophosphorylation of EGF receptors and activation of the JAK-STAT pathway. However, in contrast to the Sli-1 protein, the expressed amount of c-Cbl does not affect activation of the Ras pathway, suggesting that the EGFR-mediated signaling pathways are differently regulated by c-Cbl among nematodes and mammals.
The c-Cbl proto-oncogene was originally identified as a cellular homologue of v-Cbl oncogene, which was cloned from the Cas NS-1 murine leukemia virus (1). The c-Cbl gene product is a 120-kDa protein that contains an NH2-terminal domain with a nuclear localization signal, followed by a RING finger motif (2). The COOH-terminal half of the protein contains a proline-rich domain that has been shown to function as a ligand for the SH3 domains of many signaling molecules including Grb2, Nck, Src, and Fyn (3-10). The product of v-Cbl is a truncated form of c-Cbl, which lacks both the RING finger motif and the proline-rich domain (2). The v-Cbl protein has been shown to localize to the nucleus, to bind DNA, and to transform NIH3T3 cells, whereas the c-Cbl protein localizes in the cytoplasm and cannot transform NIH3T3 cells (11). Although previous reports demonstrated that many growth factors including epidermal growth factor (EGF)1 induce tyrosine phosphorylation of c-Cbl (8, 10, 12-16), the function of this molecule in the growth factor receptor-mediated signaling pathway remains unclear. Recently, it was reported that c-Cbl is a homologue of Sli-1, a negative regulator of let-23-mediated signal transduction pathway in Caenorhabditis elegans (17, 18). Therefore, it is expected that c-Cbl negatively regulates EGF receptor (EGFR)-mediated signaling.
To address the possibility, we established a subline of NIH3T3 cells in which the expression of c-Cbl is repressed by the introduction of antisense c-Cbl cDNA. By using this cell line as well as the parental NIH3T3 cells and c-Cbl-overexpressing cells, we analyzed the roles of c-Cbl in regulation of the EGFR signaling.
-NIH3T3 cells and all cell lines derived from NIH3T3 cells were grown in Dulbecco's modified Eagle's medium (DMEM) containing 10% bovine serum.
Anti-c-Cbl antibody and anti-STAT3 antibody were purchased from Santa Cruz Biotechnology Inc. Anti-phosphotyrosine antibody 4G10, anti-Shc antibody, and anti-JAK1 antibody were purchased from Upstate Biotechnology Inc. Anti-Grb2 antibody 3F2 and anti-EGF receptor antibody Ab-1 were purchased from MBL Inc. and Oncogene Science Inc., respectively. The mouse monoclonal antibody to a peptide epitope derived from the hemagglutinin protein of human influenza virus (clone 12CA5) was purchased from Boehringer Mannheim. Anti-Sos1 antibody and anti-MAPK antibody C92 were gifted by T. Kadowaki (University of Tokyo, Tokyo, Japan).
Construction of Vectors Expressing the Antisense and Deletion Mutants of c-Cbl and TransfectionThe human c-cbl
cDNA epitope tagged with a nine-amino acid hemagglutinin peptide
(YPYDYPDYA) from the human influenza virus was a kind from W. Y. Langdon (University of Western Australia). To construct vectors
expressing antisense of c-Cbl, a BamHI-EcoRI fragment that corresponds to 1-578 base pairs or a
HaeII-NcoI fragment that corresponds to 378-811
base pairs of c-cbl cDNA was blunted, linked with
NotI linker, and subcloned into the NotI site of
an expression vector, pUC-CAGGS (19), in a reverse orientation. To
construct deletion mutants of c-Cbl, the
HindIII-HindIII fragments of c-cbl
cDNA corresponding to 724-1618 base pairs (RING-Cbl) or
1619-2776 base pairs (
PD-Cbl) were cut out and ligated. The antisense constructs were co-transfected with pSV2neo into NIH3T3 cells
according to the protocol of Chen and Okayama (20). 12 h after
transfection, cells were washed once with DMEM and cultured in fresh
medium containing 5% fetal calf serum for 24 h followed by the
G418 selection (500 ng/ml), and resistant clones were isolated and
expanded.
Retrovirus vector was used to transfect cDNAs of c-Cbl and deletion
mutants into NIH3T3 cells. Replication-deficient retroviral stocks were
prepared by transient hyperexpression in COS7 cells. These constructs
were transfected together with packaging plasmid by the
DEAE-dextran method. Viral infections were performed by exposing cells
to virus stocks with 8 µg of polybrene/ml at 37 °C for 12 h,
and G418-resistant populations were selected in the presence of 500 µg of G418/ml. To establish EGFR stable transfectants, C2/E10 cells,
and AS21/E4 cells, the expression vector EGFR-pSSR
bsr (21) was
transfected according to the protocol of Chen and Okayama, followed by
blasticidin selection (5 µg/ml) (Funakoshi, Inc.).
Prior to stimulation, cells were starved in DMEM containing 0.5% fetal calf serum for 12 h. Cells were then stimulated with 100 ng/ml of EGF for 5 min at 37 °C, washed twice with ice-cold phosphate-buffered saline, and lysed in Triton lysis buffer (0.5% (v/v) Triton X-100, 50 mM Tris-HCl, pH 7.4, 2 mM phenylmethylsulfonyl fluoride, 10 units/ml aprotinin, 1 mM sodium orthovanadate, 1 mM EDTA). Cell lysates were centrifuged, and the supernatant was collected. For analysis of total cellular proteins, SDS sample buffer was added directly to lysate, and the mixture was denatured for 5 min at 95 °C and subjected to SDS-polyacrylamide gel electrophoresis (PAGE). Immunoprecipitations were performed at 4 °C for 3 h with specific rabbit or mouse antibodies coupled to the protein A-Sepharose beads. Immunoprecipitates were washed five times in the wash buffer (0.1% (v/v) Triton X-100, 50 mM Tris-HCl, pH 7.4), resuspended in SDS sample buffer, and denatured for 5 min at 95 °C prior to loading on the gel. Proteins separated on SDS-PAGE were transferred electrophoretically to a polyvinylidene difluoride membrane (Immobilon, MILLIPORE). The filters were preincubated for an hour with 1% bovine serum albumin in Tris-buffered saline, Triton X-100 (TBST) buffer (10 mM Tris-HCl, pH 8.0, 150 mM NaCl, 0.05% Tween-20), incubated for 2 h at room temperature with the specific antibody, washed three times with TBST buffer, and incubated for another hour with an appropriate secondary antibody. The immunoblots were developed with the ProtoBlot system (Promega) or the ECL system (Amersham Corp.). For in vitro MAP kinase assay, cell lysates were immunoprecipitated with C92, anti-MAP kinase antibody, and the immunoprecipitates were subjected to the in vitro kinase reaction using myelin basic protein (Sigma) as a substrate, as described previously (22).
To investigate the roles of c-Cbl in the intracellular
signaling pathways in fibroblasts, we tried to establish cell lines that express c-Cbl at a low level or at a high level. First, we generated two antisense constructs of c-Cbl (AS1 and AS2) derived from
the NH2-terminal portion of c-Cbl cDNA (Fig.
1A). We then introduced them into NIH3T3
cells, and the cells were subjected to the G418 selection. Resistant
colonies were isolated, and the expression levels of c-Cbl in these
cell lines were examined by the immunoblot with anti-c-Cbl antibody. No
detectable change was observed in AS1-introduced cell lines, but in
several AS2-introduced clones, the expression levels of c-Cbl were
found to be decreased (data not shown). Among these cell lines, AS21
cells were chosen for further analysis because they expressed c-Cbl at
the lowest level (data not shown). We also established C2 cells, an
NIH3T3-derived stable line that overexpresses c-Cbl, by using
retrovirus vector carrying c-Cbl cDNA. The expression levels of
c-Cbl in C2 cells, AS21 cells and mock-transfected cells are shown in
Fig. 1B.
To examine the roles of c-Cbl in the signal transduction pathways through receptor tyrosine kinases, we compared the biological activities of C2 cells and AS21 cells with that of parental NIH3T3 cells. Compared with parental NIH3T3 cells, AS21 cells showed an elongated and spindle shape, resembling a transformed phenotype (Fig. 1C), but their morphological change was less prominent than that of NIH3T3 cells transformed by activated oncogenes such as v-Src (data not shown). Furthermore, they grew in culture as monolayers and did not form foci nor produce colonies in soft agar (data not shown). On the other hand, C2 cells that overexpress c-Cbl showed a slightly flatter morphology than but almost indistinguishable from parental NIH3T3 cells (Fig. 1C). We next examined the growth rate of these cell lines by counting the cell number every 2 days, but no apparent difference was detected (data not shown). These results indicate that the expression levels of c-Cbl do not affect the cell growth or transforming phenotype of NIH3T3 cells.
Overexpression of c-Cbl Suppresses and Antisense Repression of c-Cbl Enhances Autophosphorylation of EGF ReceptorsBy using AS21
cells and C2 cells, we thought that we could evaluate the effects of
c-Cbl on growth factor receptors signaling, because they express
different amounts of c-Cbl. Because recent studies indicate that the
Sli-1 protein, which is a C. elegans homologue of c-Cbl, is
a negative regulator of the LET-23 tyrosine kinase receptor (17, 18),
it is reasonable to expect that c-Cbl negatively regulates EGFR kinase
activity. Because it was difficult to compare the difference of
autophosphorylation levels of EGFR between them due to relatively low
level of endogenous EGFR in NIH3T3 cells, we established stable
transfectants from them by introducing EGFR cDNAs. Among these
transfectants, AS21/E4 and C2/E10 lines were selected for further
analyses because they were found to express approximately the same
amount of EGFR as E10 cells, which are human EGFR stable transfectants
(10) (Fig. 2A). We stimulated AS21/E4 cells
and C2/E10 cells with EGF and examined the autophosphorylation level of
EGFR by the immunoblot with anti-phosphotyrosine antibody. Compared
with the autophosphorylation level of EGFR in E10 cells, that in C2/E10
cells was suppressed, whereas the autophosphorylation level of EGFR in
AS21/E4 cells was apparently enhanced (Fig. 2B). These
results indicate that c-Cbl negatively regulates the
autophosphorylation activity of EGFR. To determine the region of c-Cbl
required for its negative regulatory effects, we constructed deletion
mutants of c-Cbl that lack the RING finger domain (RING-Cbl) or the
proline-rich domain (
PD-Cbl). These constructs were introduced into
E10 cells by the retroviral vector. After the G418 selection for 10 days, resistant cells were stimulated with EGF, and the levels of
autophosphorylation of EGF receptors were examined. In this experiment,
both deletion mutants of c-Cbl could not suppress autophosphorylation
of EGF receptors (Fig. 2C).
The Amount of c-Cbl Does Not Affect Activation of the Ras Pathway
We next investigated if negative regulation of EGFR by
c-Cbl may affect activation of the Ras pathway. We examined the
tyrosine phosphorylation of the Shc adapter protein, which is known to be inducibly phosphorylated by EGF treatment and to regulate activation of the Ras pathway in EGFR signaling (23). AS21/E4 cells, C2/E10 cells
and E10 cells were stimulated with EGF, lysed, and immunoprecipitated with antiShc antibody. The immunoprecipitates were subjected to the
immunoblotting with anti-phosphotyrosine antibody. In this experiment,
contrary to our expectation, tyrosine phosphorylation of Shc in C2/E10
cells was not suppressed but rather modestly increased, whereas that in
AS21/E4 cells was slightly decreased compared with that in E10 cells
(Fig. 3A). Next, we investigated activation
of Sos, which is a guanine nucleotide exchange factor of Ras (24-27),
in these cell lines. When activated with EGF, Sos is known to be
phosphorylated on serine residues, resulting in electrophoretic
mobility shift in SDS-PAGE (28). The total cell lysates from AS21/E4
cells, C2/E10 cells, and E10 cells treated with or without EGF were
subjected to the Western blotting with anti-Sos antibody, and the
mobility shift of Sos was examined. In this experiment, the degree of
mobility shift of Sos was not altered among these cell lines as was the
case with Shc (Fig. 3B). By running the sample on the gel
for a longer period of time, this shift was made more obvious, although
the Sos bands were made slightly blur (Fig. 3B, lower
panel). These results suggest that the amount of Cbl has no
influence on activation of the Ras pathway downstream of EGFR. To
confirm this, the MAP kinase activities in these cells lines, when
treated with EGF, were evaluated by the in vitro kinase
assay of MAP kinase using myelin basic protein as a substrate. As
expected from the results of phosphorylation of Shc and Sos, the MAP
kinase activities of AS21/E4 cells, C2/E10 cells, and E10 cells were
shown to be approximately equal to each other (Fig. 3C).
Recent studies have indicated that the SH3 domains of Grb2 constitutively bind to the proline-rich region of Sos (26, 27) and Cbl (3, 8). Therefore, it is possible that Cbl interferes with the association between Sos and Grb2. If it is the case, overexpression of c-Cbl will decrease the association between Sos and Grb2, and in contrast, suppression of c-Cbl expression by an antisense RNA will increase it. To test this, the same amount of lysates from AS21/E4 cells, C2/E10 cells, and E10 cells were immunoprecipitated with anti-Cbl or anti-Sos antibodies. The immunoprecipitates were subjected to SDS-PAGE and transferred to a polyvinylidene difluoride membrane. The membrane was cut into two parts, and the upper part was immunoblotted with anti-Cbl or anti-Sos antibodies, whereas the lower part was immunoblotted with anti-Grb2 antibody. In this experiment, c-Cbl overexpression resulted in increase of the amount of Grb2 co-precipitated with c-Cbl. However, the amount of Grb2 associated with Sos did not vary among AS21/E4 cells, C2/E10 cells, and E10 cells (Fig. 3D). These data suggest that c-Cbl and Sos utilize different Grb2 molecule and these two molecules do not compete with each other in binding to Grb2. Taken together, c-Cbl does not affect activation of the Ras pathway in EGFR signaling. We also checked the growth rate of AS21/E4 cells, C2/E10 cells, and E10 cells in the presence of EGF, but no significant differences were detected (data not shown). These results are consistent with our observation that the activity of MAPK of these cell lines stimulated with EGF was equal to each other.
Overexpression of c-Cbl Suppresses and Repressed Expression of c-Cbl Enhances Activation of the JAK-STAT PathwayAlthough our
data suggest that c-Cbl negatively regulate autophosphorylation of
EGFR, it did not affect activation of the Ras pathway. We then examined
if other signaling pathways known to exist downstream of EGFR are
affected by the amount of c-Cbl expression. For instance, the JAK-STAT
pathway is shown to be activated by EGFR (29). EGF induces tyrosine
phosphorylation of JAK1, STAT1, and STAT3. STAT1 and STAT3 form
heterodimer and homodimer (SIF A, SIF B, and SIF C complexes) and bind
to the SIE sequence, which exists in c-Fos promoter (30). Therefore, we
examined if c-Cbl regulates their activation in EGFR signaling. Lysates
from AS21/E4 cells, C2/E10 cells, and E10 cells treated with EGF were
immunoprecipitated with anti-JAK1 antibody followed by the
immunoblotting with anti-phosphotyrosine antibody. Compared with
tyrosine phosphorylation level of JAK1 in E10 cells, that of JAK1 in
C2/E10 cells was slightly suppressed, whereas that in AS21/E4 cells was
apparently enhanced (Fig. 4A). The degree of
tyrosine phosphorylation of JAK1 in these cell lines approximately correlates with that of EGFR. We also examined tyrosine phosphorylation of STAT3 in AS21/E4 cells, C2/E10 cells, and E10 cells, because it is a
substrate for JAK1 kinase. The phosphorylation levels of STAT3 were
also changed in proportion to tyrosine phosphorylation levels of EGFR
and JAK1 (Fig. 4B). Tyrosine phosphorylation of STAT1 in
these cell lines showed a similar result to that of STAT3 (data not
shown). These data indicate that activation of the JAK-STAT pathway
approximately correlates with EGFR kinase activity and is negatively
regulated by c-Cbl.
In this study, by an antisense RNA approach, we established NIH3T3 cells in which c-Cbl expression is repressed (AS21 cells). Comparing this cell line with C2 cells that overexpress c-Cbl and with parental NIH3T3 cells, c-Cbl expression level did not affect the growth rate or transforming ability. We introduced EGFR cDNA into these cell lines and established AS21/E4 cells and C2/E10 cells. By using these cell lines and E10 cells, we analyzed the function of c-Cbl in EGFR signaling and found that overexpression of c-Cbl reduces, and antisense repression of c-Cbl enhances, autophosphorylation of EGF receptors. Yet, the amount of c-Cbl does not affect activation of the Ras pathway. However, overexpression of c-Cbl suppresses and antisense repression of c-Cbl enhances activation of the JAK-STAT pathway.
Consistent with our data, Bowtell and Langdon have shown that
overexpression of wild-type c-Cbl reduced the amount of
tyrosine-phosphorylated EGFR associating with Shc following EGF
stimulation, compared with that in parental Balb 3T3 cells (12).
However, the mechanism with which c-Cbl regulates the kinase activity
of EGF receptor is unknown. To determine which domain of c-Cbl is
necessary for this regulatory function, we constructed deletion mutants
of c-Cbl that lack the RING finger domain or the proline-rich domain.
Neither of the mutants were able to suppress autophosphorylation of EGF receptor. From these results, we could conclude that both domains are
required for the negative regulatory effects of c-Cbl. The proline-rich
domain of c-Cbl is a target for the SH3 domain of Grb2, enabling c-Cbl
to associate with EGF receptor upon EGF stimulation. We speculate that
the PD-Cbl mutant cannot bind to EGFR as efficiently as the
wild-type c-Cbl and thus fails to generate the negative signal. On the
other hand, the result showing that the
RING-Cbl mutant could not
suppress autophosphorylation of EGF receptor might imply that this
region plays a critical role for generating the negative regulatory
signal of c-Cbl.
It has been reported that the sli-1 (reduction of function) mutations suppress all known defects of let-23 mutations: (i) viability, (ii) hermaphrodite fertility, (iii) male spicule development, (iv) posterior epidermal development, and (v) vulval differentiation (31) except for sterility. Reduction-of-function mutations in sem-5 and let-60 also display vulvaless (Vul) phenotype (32, 33) like let-23 (sy97), a severe reduction of function allele (31). The sli-1 (sy143) mutation suppresses the Vul phenotype associated with a weakly hypomorphic sem-5 (n2019) and let-60 (rf) mutation, n2021(18). These observations indicate that Sli-1 negatively regulates the let-23-, sem-5-, and let-60-mediated pathway and suggest that c-Cbl might negatively regulate not only EGFR kinase activity but the Ras signaling pathway. Although our data indicate that c-Cbl suppresses autophosphorylation of EGFR, this has no effect on phosphorylation of Shc and Sos and the MAP kinase activity. In contrast, there is a substantial affect on phosphorylation of JAK1 and STAT3. These data partially contradict the results expected from the role of Sli-1 protein in the let-23-mediated vulval induction pathway.
To address the question, we should consider several studies reporting the relationship between EGFR kinase activity and activation of MAP kinase or JAK kinase. Wright et al. reported that a kinase-defective EGF receptor mutant (K721M) can induce phosphorylation of Shc and activate MAP kinase, whereas it cannot induce phosphorylation of JAK1 or STAT1. They discussed that kinase-defective EGFRs activate MAP kinase by heterodimerization with and stimulating kinase activity of c-ErbB2, which enhances phosphorylation of and binding with Shc and activates the Ras pathway (34). Furthermore, of c-ErbB family kinases, only EGFR binds c-Cbl (35). This may imply that c-Cbl can suppress only kinase activity of EGFR but not that of other c-ErbB kinases. From these observations, we speculate that activation of the Ras pathway is not directly dependent upon the kinase activity of EGFR and that c-Cbl does not affect it in EGFR signaling, because the kinase activity of c-ErbB2 can compensate that of EGFR. We also hypothesize that in nematodes this redundancy may not exist, and therefore Sli-1 can directly regulate the let-23-, sem-5-, and let-60-mediated pathway. On the other hand, activation of the JAK-STAT pathway depends on EGFR kinase activity; therefore, c-Cbl negatively regulate activation of the JAK-STAT pathway in proportion to the autophosphorylation level of EGFR.
In this paper, we investigated the relationship among EGFR kinase activity, activation of the Ras pathway and the JAK-STAT pathway. Our data suggest that c-Cbl negatively regulates EGFR kinase activity but in contrast to the Sli-1 protein did not affect activation of signaling molecules of the Ras pathway. On the other hand, activation of the JAK-STAT pathway correlated with EGFR kinase activity and as a result was negatively regulated by c-Cbl. Our report is the first study describing the regulation of the JAK-STAT pathway by c-Cbl, and we speculate that c-Cbl, by coupling to EGFR, negatively regulates its kinase activity and thus regulates activation of the JAK-STAT pathway. We are currently trying to further characterize the mechanism of these negative regulation by c-Cbl protein.
We thank T. Kadowaki for the anti-Sos antibody and anti-MAP kinase antibody, C92. We also thank O. N. Witte and J. Miyazaki for the expression vectors. The human c-Cbl cDNA was a kind gift of W. Y. Langdon.